arrow_cast/cast/
mod.rs

1// Licensed to the Apache Software Foundation (ASF) under one
2// or more contributor license agreements.  See the NOTICE file
3// distributed with this work for additional information
4// regarding copyright ownership.  The ASF licenses this file
5// to you under the Apache License, Version 2.0 (the
6// "License"); you may not use this file except in compliance
7// with the License.  You may obtain a copy of the License at
8//
9//   http://www.apache.org/licenses/LICENSE-2.0
10//
11// Unless required by applicable law or agreed to in writing,
12// software distributed under the License is distributed on an
13// "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
14// KIND, either express or implied.  See the License for the
15// specific language governing permissions and limitations
16// under the License.
17
18//! Cast kernels to convert [`ArrayRef`]  between supported datatypes.
19//!
20//! See [`cast_with_options`] for more information on specific conversions.
21//!
22//! Example:
23//!
24//! ```
25//! # use arrow_array::*;
26//! # use arrow_cast::cast;
27//! # use arrow_schema::DataType;
28//! # use std::sync::Arc;
29//! # use arrow_array::types::Float64Type;
30//! # use arrow_array::cast::AsArray;
31//! // int32 to float64
32//! let a = Int32Array::from(vec![5, 6, 7]);
33//! let b = cast(&a, &DataType::Float64).unwrap();
34//! let c = b.as_primitive::<Float64Type>();
35//! assert_eq!(5.0, c.value(0));
36//! assert_eq!(6.0, c.value(1));
37//! assert_eq!(7.0, c.value(2));
38//! ```
39
40mod decimal;
41mod dictionary;
42mod list;
43mod list_view;
44mod map;
45mod run_array;
46mod string;
47
48use crate::cast::decimal::*;
49use crate::cast::dictionary::*;
50use crate::cast::list::*;
51use crate::cast::map::*;
52use crate::cast::run_array::*;
53use crate::cast::string::*;
54
55use arrow_buffer::IntervalMonthDayNano;
56use arrow_data::ByteView;
57use chrono::{NaiveTime, Offset, TimeZone, Utc};
58use std::cmp::Ordering;
59use std::sync::Arc;
60
61use crate::display::{ArrayFormatter, FormatOptions};
62use crate::parse::{
63    Parser, parse_interval_day_time, parse_interval_month_day_nano, parse_interval_year_month,
64    string_to_datetime,
65};
66use arrow_array::{builder::*, cast::*, temporal_conversions::*, timezone::Tz, types::*, *};
67use arrow_buffer::{ArrowNativeType, OffsetBuffer, i256};
68use arrow_data::ArrayData;
69use arrow_data::transform::MutableArrayData;
70use arrow_schema::*;
71use arrow_select::take::take;
72use num_traits::{NumCast, ToPrimitive, cast::AsPrimitive};
73
74use crate::cast::list_view::{cast_list_to_list_view, cast_list_view, cast_list_view_to_list};
75pub use decimal::{DecimalCast, rescale_decimal};
76
77/// CastOptions provides a way to override the default cast behaviors
78#[derive(Debug, Clone, PartialEq, Eq, Hash)]
79pub struct CastOptions<'a> {
80    /// how to handle cast failures, either return NULL (safe=true) or return ERR (safe=false)
81    pub safe: bool,
82    /// Formatting options when casting from temporal types to string
83    pub format_options: FormatOptions<'a>,
84}
85
86impl Default for CastOptions<'_> {
87    fn default() -> Self {
88        Self {
89            safe: true,
90            format_options: FormatOptions::default(),
91        }
92    }
93}
94
95/// Return true if a value of type `from_type` can be cast into a value of `to_type`.
96///
97/// See [`cast_with_options`] for more information
98pub fn can_cast_types(from_type: &DataType, to_type: &DataType) -> bool {
99    use self::DataType::*;
100    use self::IntervalUnit::*;
101    use self::TimeUnit::*;
102    if from_type == to_type {
103        return true;
104    }
105
106    match (from_type, to_type) {
107        (
108            Null,
109            Boolean
110            | Int8
111            | UInt8
112            | Int16
113            | UInt16
114            | Float16
115            | Int32
116            | UInt32
117            | Float32
118            | Date32
119            | Time32(_)
120            | Int64
121            | UInt64
122            | Float64
123            | Date64
124            | Timestamp(_, _)
125            | Time64(_)
126            | Duration(_)
127            | Interval(_)
128            | FixedSizeBinary(_)
129            | Binary
130            | Utf8
131            | LargeBinary
132            | LargeUtf8
133            | BinaryView
134            | Utf8View
135            | List(_)
136            | LargeList(_)
137            | FixedSizeList(_, _)
138            | Struct(_)
139            | Map(_, _)
140            | Dictionary(_, _),
141        ) => true,
142        // Dictionary/List conditions should be put in front of others
143        (Dictionary(_, from_value_type), Dictionary(_, to_value_type)) => {
144            can_cast_types(from_value_type, to_value_type)
145        }
146        (Dictionary(_, value_type), _) => can_cast_types(value_type, to_type),
147        (RunEndEncoded(_, value_type), _) => can_cast_types(value_type.data_type(), to_type),
148        (_, RunEndEncoded(_, value_type)) => can_cast_types(from_type, value_type.data_type()),
149        (_, Dictionary(_, value_type)) => can_cast_types(from_type, value_type),
150        (List(list_from) | LargeList(list_from), List(list_to) | LargeList(list_to)) => {
151            can_cast_types(list_from.data_type(), list_to.data_type())
152        }
153        (List(list_from) | LargeList(list_from), Utf8 | LargeUtf8) => {
154            can_cast_types(list_from.data_type(), to_type)
155        }
156        (List(list_from) | LargeList(list_from), FixedSizeList(list_to, _)) => {
157            can_cast_types(list_from.data_type(), list_to.data_type())
158        }
159        (List(list_from) | LargeList(list_from), ListView(list_to) | LargeListView(list_to)) => {
160            can_cast_types(list_from.data_type(), list_to.data_type())
161        }
162        (List(_), _) => false,
163        (ListView(list_from) | LargeListView(list_from), List(list_to) | LargeList(list_to)) => {
164            can_cast_types(list_from.data_type(), list_to.data_type())
165        }
166        (ListView(list_from), LargeListView(list_to)) => {
167            can_cast_types(list_from.data_type(), list_to.data_type())
168        }
169        (LargeListView(list_from), ListView(list_to)) => {
170            can_cast_types(list_from.data_type(), list_to.data_type())
171        }
172        (FixedSizeList(list_from, _), List(list_to))
173        | (FixedSizeList(list_from, _), LargeList(list_to)) => {
174            can_cast_types(list_from.data_type(), list_to.data_type())
175        }
176        (FixedSizeList(inner, size), FixedSizeList(inner_to, size_to)) if size == size_to => {
177            can_cast_types(inner.data_type(), inner_to.data_type())
178        }
179        (_, List(list_to)) => can_cast_types(from_type, list_to.data_type()),
180        (_, LargeList(list_to)) => can_cast_types(from_type, list_to.data_type()),
181        (_, FixedSizeList(list_to, size)) if *size == 1 => {
182            can_cast_types(from_type, list_to.data_type())
183        }
184        (FixedSizeList(list_from, size), _) if *size == 1 => {
185            can_cast_types(list_from.data_type(), to_type)
186        }
187        (Map(from_entries, ordered_from), Map(to_entries, ordered_to))
188            if ordered_from == ordered_to =>
189        {
190            match (
191                key_field(from_entries),
192                key_field(to_entries),
193                value_field(from_entries),
194                value_field(to_entries),
195            ) {
196                (Some(from_key), Some(to_key), Some(from_value), Some(to_value)) => {
197                    can_cast_types(from_key.data_type(), to_key.data_type())
198                        && can_cast_types(from_value.data_type(), to_value.data_type())
199                }
200                _ => false,
201            }
202        }
203        // cast one decimal type to another decimal type
204        (
205            Decimal32(_, _) | Decimal64(_, _) | Decimal128(_, _) | Decimal256(_, _),
206            Decimal32(_, _) | Decimal64(_, _) | Decimal128(_, _) | Decimal256(_, _),
207        ) => true,
208        // unsigned integer to decimal
209        (
210            UInt8 | UInt16 | UInt32 | UInt64,
211            Decimal32(_, _) | Decimal64(_, _) | Decimal128(_, _) | Decimal256(_, _),
212        ) => true,
213        // signed numeric to decimal
214        (
215            Null | Int8 | Int16 | Int32 | Int64 | Float32 | Float64,
216            Decimal32(_, _) | Decimal64(_, _) | Decimal128(_, _) | Decimal256(_, _),
217        ) => true,
218        // decimal to unsigned numeric
219        (
220            Decimal32(_, _) | Decimal64(_, _) | Decimal128(_, _) | Decimal256(_, _),
221            UInt8 | UInt16 | UInt32 | UInt64,
222        ) => true,
223        // decimal to signed numeric
224        (
225            Decimal32(_, _) | Decimal64(_, _) | Decimal128(_, _) | Decimal256(_, _),
226            Null | Int8 | Int16 | Int32 | Int64 | Float32 | Float64,
227        ) => true,
228        // decimal to string
229        (
230            Decimal32(_, _) | Decimal64(_, _) | Decimal128(_, _) | Decimal256(_, _),
231            Utf8View | Utf8 | LargeUtf8,
232        ) => true,
233        // string to decimal
234        (
235            Utf8View | Utf8 | LargeUtf8,
236            Decimal32(_, _) | Decimal64(_, _) | Decimal128(_, _) | Decimal256(_, _),
237        ) => true,
238        (Struct(from_fields), Struct(to_fields)) => {
239            if from_fields.len() != to_fields.len() {
240                return false;
241            }
242
243            // fast path, all field names are in the same order and same number of fields
244            if from_fields
245                .iter()
246                .zip(to_fields.iter())
247                .all(|(f1, f2)| f1.name() == f2.name())
248            {
249                return from_fields.iter().zip(to_fields.iter()).all(|(f1, f2)| {
250                    // Assume that nullability between two structs are compatible, if not,
251                    // cast kernel will return error.
252                    can_cast_types(f1.data_type(), f2.data_type())
253                });
254            }
255
256            // slow path, we match the fields by name
257            if to_fields.iter().all(|to_field| {
258                from_fields
259                    .iter()
260                    .find(|from_field| from_field.name() == to_field.name())
261                    .is_some_and(|from_field| {
262                        // Assume that nullability between two structs are compatible, if not,
263                        // cast kernel will return error.
264                        can_cast_types(from_field.data_type(), to_field.data_type())
265                    })
266            }) {
267                return true;
268            }
269
270            // if we couldn't match by name, we try to see if they can be matched by position
271            from_fields
272                .iter()
273                .zip(to_fields.iter())
274                .all(|(f1, f2)| can_cast_types(f1.data_type(), f2.data_type()))
275        }
276        (Struct(_), _) => false,
277        (_, Struct(_)) => false,
278        (_, Boolean) => {
279            DataType::is_integer(from_type)
280                || DataType::is_floating(from_type)
281                || from_type == &Utf8View
282                || from_type == &Utf8
283                || from_type == &LargeUtf8
284        }
285        (Boolean, _) => {
286            DataType::is_integer(to_type)
287                || DataType::is_floating(to_type)
288                || to_type == &Utf8View
289                || to_type == &Utf8
290                || to_type == &LargeUtf8
291        }
292
293        (Binary, LargeBinary | Utf8 | LargeUtf8 | FixedSizeBinary(_) | BinaryView | Utf8View) => {
294            true
295        }
296        (LargeBinary, Binary | Utf8 | LargeUtf8 | FixedSizeBinary(_) | BinaryView | Utf8View) => {
297            true
298        }
299        (FixedSizeBinary(_), Binary | LargeBinary | BinaryView) => true,
300        (
301            Utf8 | LargeUtf8 | Utf8View,
302            Binary
303            | LargeBinary
304            | Utf8
305            | LargeUtf8
306            | Date32
307            | Date64
308            | Time32(Second)
309            | Time32(Millisecond)
310            | Time64(Microsecond)
311            | Time64(Nanosecond)
312            | Timestamp(Second, _)
313            | Timestamp(Millisecond, _)
314            | Timestamp(Microsecond, _)
315            | Timestamp(Nanosecond, _)
316            | Interval(_)
317            | BinaryView,
318        ) => true,
319        (Utf8 | LargeUtf8, Utf8View) => true,
320        (BinaryView, Binary | LargeBinary | Utf8 | LargeUtf8 | Utf8View) => true,
321        (Utf8View | Utf8 | LargeUtf8, _) => to_type.is_numeric() && to_type != &Float16,
322        (_, Utf8 | Utf8View | LargeUtf8) => from_type.is_primitive(),
323
324        (_, Binary | LargeBinary) => from_type.is_integer(),
325
326        // start numeric casts
327        (
328            UInt8 | UInt16 | UInt32 | UInt64 | Int8 | Int16 | Int32 | Int64 | Float16 | Float32
329            | Float64,
330            UInt8 | UInt16 | UInt32 | UInt64 | Int8 | Int16 | Int32 | Int64 | Float16 | Float32
331            | Float64,
332        ) => true,
333        // end numeric casts
334
335        // temporal casts
336        (Int32, Date32 | Date64 | Time32(_)) => true,
337        (Date32, Int32 | Int64) => true,
338        (Time32(_), Int32 | Int64) => true,
339        (Int64, Date64 | Date32 | Time64(_)) => true,
340        (Date64, Int64 | Int32) => true,
341        (Time64(_), Int64) => true,
342        (Date32 | Date64, Date32 | Date64) => true,
343        // time casts
344        (Time32(_), Time32(_)) => true,
345        (Time32(_), Time64(_)) => true,
346        (Time64(_), Time64(_)) => true,
347        (Time64(_), Time32(to_unit)) => {
348            matches!(to_unit, Second | Millisecond)
349        }
350        (Timestamp(_, _), _) if to_type.is_numeric() => true,
351        (_, Timestamp(_, _)) if from_type.is_numeric() => true,
352        (Date64, Timestamp(_, _)) => true,
353        (Date32, Timestamp(_, _)) => true,
354        (
355            Timestamp(_, _),
356            Timestamp(_, _)
357            | Date32
358            | Date64
359            | Time32(Second)
360            | Time32(Millisecond)
361            | Time64(Microsecond)
362            | Time64(Nanosecond),
363        ) => true,
364        (_, Duration(_)) if from_type.is_numeric() => true,
365        (Duration(_), _) if to_type.is_numeric() => true,
366        (Duration(_), Duration(_)) => true,
367        (Interval(from_type), Int64) => {
368            match from_type {
369                YearMonth => true,
370                DayTime => true,
371                MonthDayNano => false, // Native type is i128
372            }
373        }
374        (Int32, Interval(to_type)) => match to_type {
375            YearMonth => true,
376            DayTime => false,
377            MonthDayNano => false,
378        },
379        (Duration(_), Interval(MonthDayNano)) => true,
380        (Interval(MonthDayNano), Duration(_)) => true,
381        (Interval(YearMonth), Interval(MonthDayNano)) => true,
382        (Interval(DayTime), Interval(MonthDayNano)) => true,
383        (_, _) => false,
384    }
385}
386
387/// Cast `array` to the provided data type and return a new Array with type `to_type`, if possible.
388///
389/// See [`cast_with_options`] for more information
390pub fn cast(array: &dyn Array, to_type: &DataType) -> Result<ArrayRef, ArrowError> {
391    cast_with_options(array, to_type, &CastOptions::default())
392}
393
394fn cast_integer_to_decimal<
395    T: ArrowPrimitiveType,
396    D: DecimalType + ArrowPrimitiveType<Native = M>,
397    M,
398>(
399    array: &PrimitiveArray<T>,
400    precision: u8,
401    scale: i8,
402    base: M,
403    cast_options: &CastOptions,
404) -> Result<ArrayRef, ArrowError>
405where
406    <T as ArrowPrimitiveType>::Native: AsPrimitive<M>,
407    M: ArrowNativeTypeOp,
408{
409    let scale_factor = base.pow_checked(scale.unsigned_abs() as u32).map_err(|_| {
410        ArrowError::CastError(format!(
411            "Cannot cast to {:?}({}, {}). The scale causes overflow.",
412            D::PREFIX,
413            precision,
414            scale,
415        ))
416    })?;
417
418    let array = if scale < 0 {
419        match cast_options.safe {
420            true => array.unary_opt::<_, D>(|v| {
421                v.as_()
422                    .div_checked(scale_factor)
423                    .ok()
424                    .and_then(|v| (D::is_valid_decimal_precision(v, precision)).then_some(v))
425            }),
426            false => array.try_unary::<_, D, _>(|v| {
427                v.as_()
428                    .div_checked(scale_factor)
429                    .and_then(|v| D::validate_decimal_precision(v, precision, scale).map(|_| v))
430            })?,
431        }
432    } else {
433        match cast_options.safe {
434            true => array.unary_opt::<_, D>(|v| {
435                v.as_()
436                    .mul_checked(scale_factor)
437                    .ok()
438                    .and_then(|v| (D::is_valid_decimal_precision(v, precision)).then_some(v))
439            }),
440            false => array.try_unary::<_, D, _>(|v| {
441                v.as_()
442                    .mul_checked(scale_factor)
443                    .and_then(|v| D::validate_decimal_precision(v, precision, scale).map(|_| v))
444            })?,
445        }
446    };
447
448    Ok(Arc::new(array.with_precision_and_scale(precision, scale)?))
449}
450
451/// Cast the array from interval year month to month day nano
452fn cast_interval_year_month_to_interval_month_day_nano(
453    array: &dyn Array,
454    _cast_options: &CastOptions,
455) -> Result<ArrayRef, ArrowError> {
456    let array = array.as_primitive::<IntervalYearMonthType>();
457
458    Ok(Arc::new(array.unary::<_, IntervalMonthDayNanoType>(|v| {
459        let months = IntervalYearMonthType::to_months(v);
460        IntervalMonthDayNanoType::make_value(months, 0, 0)
461    })))
462}
463
464/// Cast the array from interval day time to month day nano
465fn cast_interval_day_time_to_interval_month_day_nano(
466    array: &dyn Array,
467    _cast_options: &CastOptions,
468) -> Result<ArrayRef, ArrowError> {
469    let array = array.as_primitive::<IntervalDayTimeType>();
470    let mul = 1_000_000;
471
472    Ok(Arc::new(array.unary::<_, IntervalMonthDayNanoType>(|v| {
473        let (days, ms) = IntervalDayTimeType::to_parts(v);
474        IntervalMonthDayNanoType::make_value(0, days, ms as i64 * mul)
475    })))
476}
477
478/// Cast the array from interval to duration
479fn cast_month_day_nano_to_duration<D: ArrowTemporalType<Native = i64>>(
480    array: &dyn Array,
481    cast_options: &CastOptions,
482) -> Result<ArrayRef, ArrowError> {
483    let array = array.as_primitive::<IntervalMonthDayNanoType>();
484    let scale = match D::DATA_TYPE {
485        DataType::Duration(TimeUnit::Second) => 1_000_000_000,
486        DataType::Duration(TimeUnit::Millisecond) => 1_000_000,
487        DataType::Duration(TimeUnit::Microsecond) => 1_000,
488        DataType::Duration(TimeUnit::Nanosecond) => 1,
489        _ => unreachable!(),
490    };
491
492    if cast_options.safe {
493        let iter = array.iter().map(|v| {
494            v.and_then(|v| (v.days == 0 && v.months == 0).then_some(v.nanoseconds / scale))
495        });
496        Ok(Arc::new(unsafe {
497            PrimitiveArray::<D>::from_trusted_len_iter(iter)
498        }))
499    } else {
500        let vec = array
501            .iter()
502            .map(|v| {
503                v.map(|v| match v.days == 0 && v.months == 0 {
504                    true => Ok((v.nanoseconds) / scale),
505                    _ => Err(ArrowError::ComputeError(
506                        "Cannot convert interval containing non-zero months or days to duration"
507                            .to_string(),
508                    )),
509                })
510                .transpose()
511            })
512            .collect::<Result<Vec<_>, _>>()?;
513        Ok(Arc::new(unsafe {
514            PrimitiveArray::<D>::from_trusted_len_iter(vec.iter())
515        }))
516    }
517}
518
519/// Cast the array from duration and interval
520fn cast_duration_to_interval<D: ArrowTemporalType<Native = i64>>(
521    array: &dyn Array,
522    cast_options: &CastOptions,
523) -> Result<ArrayRef, ArrowError> {
524    let array = array
525        .as_any()
526        .downcast_ref::<PrimitiveArray<D>>()
527        .ok_or_else(|| {
528            ArrowError::ComputeError(
529                "Internal Error: Cannot cast duration to DurationArray of expected type"
530                    .to_string(),
531            )
532        })?;
533
534    let scale = match array.data_type() {
535        DataType::Duration(TimeUnit::Second) => 1_000_000_000,
536        DataType::Duration(TimeUnit::Millisecond) => 1_000_000,
537        DataType::Duration(TimeUnit::Microsecond) => 1_000,
538        DataType::Duration(TimeUnit::Nanosecond) => 1,
539        _ => unreachable!(),
540    };
541
542    if cast_options.safe {
543        let iter = array.iter().map(|v| {
544            v.and_then(|v| {
545                v.checked_mul(scale)
546                    .map(|v| IntervalMonthDayNano::new(0, 0, v))
547            })
548        });
549        Ok(Arc::new(unsafe {
550            PrimitiveArray::<IntervalMonthDayNanoType>::from_trusted_len_iter(iter)
551        }))
552    } else {
553        let vec = array
554            .iter()
555            .map(|v| {
556                v.map(|v| {
557                    if let Ok(v) = v.mul_checked(scale) {
558                        Ok(IntervalMonthDayNano::new(0, 0, v))
559                    } else {
560                        Err(ArrowError::ComputeError(format!(
561                            "Cannot cast to {:?}. Overflowing on {:?}",
562                            IntervalMonthDayNanoType::DATA_TYPE,
563                            v
564                        )))
565                    }
566                })
567                .transpose()
568            })
569            .collect::<Result<Vec<_>, _>>()?;
570        Ok(Arc::new(unsafe {
571            PrimitiveArray::<IntervalMonthDayNanoType>::from_trusted_len_iter(vec.iter())
572        }))
573    }
574}
575
576/// Cast the primitive array using [`PrimitiveArray::reinterpret_cast`]
577fn cast_reinterpret_arrays<I: ArrowPrimitiveType, O: ArrowPrimitiveType<Native = I::Native>>(
578    array: &dyn Array,
579) -> Result<ArrayRef, ArrowError> {
580    Ok(Arc::new(array.as_primitive::<I>().reinterpret_cast::<O>()))
581}
582
583fn make_timestamp_array(
584    array: &PrimitiveArray<Int64Type>,
585    unit: TimeUnit,
586    tz: Option<Arc<str>>,
587) -> ArrayRef {
588    match unit {
589        TimeUnit::Second => Arc::new(
590            array
591                .reinterpret_cast::<TimestampSecondType>()
592                .with_timezone_opt(tz),
593        ),
594        TimeUnit::Millisecond => Arc::new(
595            array
596                .reinterpret_cast::<TimestampMillisecondType>()
597                .with_timezone_opt(tz),
598        ),
599        TimeUnit::Microsecond => Arc::new(
600            array
601                .reinterpret_cast::<TimestampMicrosecondType>()
602                .with_timezone_opt(tz),
603        ),
604        TimeUnit::Nanosecond => Arc::new(
605            array
606                .reinterpret_cast::<TimestampNanosecondType>()
607                .with_timezone_opt(tz),
608        ),
609    }
610}
611
612fn make_duration_array(array: &PrimitiveArray<Int64Type>, unit: TimeUnit) -> ArrayRef {
613    match unit {
614        TimeUnit::Second => Arc::new(array.reinterpret_cast::<DurationSecondType>()),
615        TimeUnit::Millisecond => Arc::new(array.reinterpret_cast::<DurationMillisecondType>()),
616        TimeUnit::Microsecond => Arc::new(array.reinterpret_cast::<DurationMicrosecondType>()),
617        TimeUnit::Nanosecond => Arc::new(array.reinterpret_cast::<DurationNanosecondType>()),
618    }
619}
620
621fn as_time_res_with_timezone<T: ArrowPrimitiveType>(
622    v: i64,
623    tz: Option<Tz>,
624) -> Result<NaiveTime, ArrowError> {
625    let time = match tz {
626        Some(tz) => as_datetime_with_timezone::<T>(v, tz).map(|d| d.time()),
627        None => as_datetime::<T>(v).map(|d| d.time()),
628    };
629
630    time.ok_or_else(|| {
631        ArrowError::CastError(format!(
632            "Failed to create naive time with {} {}",
633            std::any::type_name::<T>(),
634            v
635        ))
636    })
637}
638
639fn timestamp_to_date32<T: ArrowTimestampType>(
640    array: &PrimitiveArray<T>,
641) -> Result<ArrayRef, ArrowError> {
642    let err = |x: i64| {
643        ArrowError::CastError(format!(
644            "Cannot convert {} {x} to datetime",
645            std::any::type_name::<T>()
646        ))
647    };
648
649    let array: Date32Array = match array.timezone() {
650        Some(tz) => {
651            let tz: Tz = tz.parse()?;
652            array.try_unary(|x| {
653                as_datetime_with_timezone::<T>(x, tz)
654                    .ok_or_else(|| err(x))
655                    .map(|d| Date32Type::from_naive_date(d.date_naive()))
656            })?
657        }
658        None => array.try_unary(|x| {
659            as_datetime::<T>(x)
660                .ok_or_else(|| err(x))
661                .map(|d| Date32Type::from_naive_date(d.date()))
662        })?,
663    };
664    Ok(Arc::new(array))
665}
666
667/// Try to cast `array` to `to_type` if possible.
668///
669/// Returns a new Array with type `to_type` if possible.
670///
671/// Accepts [`CastOptions`] to specify cast behavior. See also [`cast()`].
672///
673/// # Behavior
674/// * `Boolean` to `Utf8`: `true` => '1', `false` => `0`
675/// * `Utf8` to `Boolean`: `true`, `yes`, `on`, `1` => `true`, `false`, `no`, `off`, `0` => `false`,
676///   short variants are accepted, other strings return null or error
677/// * `Utf8` to Numeric: strings that can't be parsed to numbers return null, float strings
678///   in integer casts return null
679/// * Numeric to `Boolean`: 0 returns `false`, any other value returns `true`
680/// * `List` to `List`: the underlying data type is cast
681/// * `List` to `FixedSizeList`: the underlying data type is cast. If safe is true and a list element
682///   has the wrong length it will be replaced with NULL, otherwise an error will be returned
683/// * Primitive to `List`: a list array with 1 value per slot is created
684/// * `Date32` and `Date64`: precision lost when going to higher interval
685/// * `Time32 and `Time64`: precision lost when going to higher interval
686/// * `Timestamp` and `Date{32|64}`: precision lost when going to higher interval
687/// * Temporal to/from backing Primitive: zero-copy with data type change
688/// * `Float32/Float64` to `Decimal(precision, scale)` rounds to the `scale` decimals
689///   (i.e. casting `6.4999` to `Decimal(10, 1)` becomes `6.5`).
690/// * `Decimal` to `Float32/Float64` is lossy and values outside the representable
691///   range become `INFINITY` or `-INFINITY` without error.
692///
693/// Unsupported Casts (check with `can_cast_types` before calling):
694/// * To or from `StructArray`
695/// * `List` to `Primitive`
696/// * `Interval` and `Duration`
697///
698/// # Durations and Intervals
699///
700/// Casting integer types directly to interval types such as
701/// [`IntervalMonthDayNano`] is not supported because the meaning of the integer
702/// is ambiguous. For example, the integer  could represent either nanoseconds
703/// or months.
704///
705/// To cast an integer type to an interval type, first convert to a Duration
706/// type, and then cast that to the desired interval type.
707///
708/// For example, to convert an `Int64` representing nanoseconds to an
709/// `IntervalMonthDayNano` you would first convert the `Int64` to a
710/// `DurationNanoseconds`, and then cast that to `IntervalMonthDayNano`.
711///
712/// # Timestamps and Timezones
713///
714/// Timestamps are stored with an optional timezone in Arrow.
715///
716/// ## Casting timestamps to a timestamp without timezone / UTC
717/// ```
718/// # use arrow_array::Int64Array;
719/// # use arrow_array::types::TimestampSecondType;
720/// # use arrow_cast::{cast, display};
721/// # use arrow_array::cast::AsArray;
722/// # use arrow_schema::{DataType, TimeUnit};
723/// // can use "UTC" if chrono-tz feature is enabled, here use offset based timezone
724/// let data_type = DataType::Timestamp(TimeUnit::Second, None);
725/// let a = Int64Array::from(vec![1_000_000_000, 2_000_000_000, 3_000_000_000]);
726/// let b = cast(&a, &data_type).unwrap();
727/// let b = b.as_primitive::<TimestampSecondType>(); // downcast to result type
728/// assert_eq!(2_000_000_000, b.value(1)); // values are the same as the type has no timezone
729/// // use display to show them (note has no trailing Z)
730/// assert_eq!("2033-05-18T03:33:20", display::array_value_to_string(&b, 1).unwrap());
731/// ```
732///
733/// ## Casting timestamps to a timestamp with timezone
734///
735/// Similarly to the previous example, if you cast numeric values to a timestamp
736/// with timezone, the cast kernel will not change the underlying values
737/// but display and other functions will interpret them as being in the provided timezone.
738///
739/// ```
740/// # use arrow_array::Int64Array;
741/// # use arrow_array::types::TimestampSecondType;
742/// # use arrow_cast::{cast, display};
743/// # use arrow_array::cast::AsArray;
744/// # use arrow_schema::{DataType, TimeUnit};
745/// // can use "Americas/New_York" if chrono-tz feature is enabled, here use offset based timezone
746/// let data_type = DataType::Timestamp(TimeUnit::Second, Some("-05:00".into()));
747/// let a = Int64Array::from(vec![1_000_000_000, 2_000_000_000, 3_000_000_000]);
748/// let b = cast(&a, &data_type).unwrap();
749/// let b = b.as_primitive::<TimestampSecondType>(); // downcast to result type
750/// assert_eq!(2_000_000_000, b.value(1)); // values are still the same
751/// // displayed in the target timezone (note the offset -05:00)
752/// assert_eq!("2033-05-17T22:33:20-05:00", display::array_value_to_string(&b, 1).unwrap());
753/// ```
754/// # Casting timestamps without timezone to timestamps with timezone
755///
756/// When casting from a timestamp without timezone to a timestamp with
757/// timezone, the cast kernel interprets the timestamp values as being in
758/// the destination timezone and then adjusts the underlying value to UTC as required
759///
760/// However, note that when casting from a timestamp with timezone BACK to a
761/// timestamp without timezone the cast kernel does not adjust the values.
762///
763/// Thus round trip casting a timestamp without timezone to a timestamp with
764/// timezone and back to a timestamp without timezone results in different
765/// values than the starting values.
766///
767/// ```
768/// # use arrow_array::Int64Array;
769/// # use arrow_array::types::{TimestampSecondType};
770/// # use arrow_cast::{cast, display};
771/// # use arrow_array::cast::AsArray;
772/// # use arrow_schema::{DataType, TimeUnit};
773/// let data_type  = DataType::Timestamp(TimeUnit::Second, None);
774/// let data_type_tz = DataType::Timestamp(TimeUnit::Second, Some("-05:00".into()));
775/// let a = Int64Array::from(vec![1_000_000_000, 2_000_000_000, 3_000_000_000]);
776/// let b = cast(&a, &data_type).unwrap(); // cast to timestamp without timezone
777/// let b = b.as_primitive::<TimestampSecondType>(); // downcast to result type
778/// assert_eq!(2_000_000_000, b.value(1)); // values are still the same
779/// // displayed without a timezone (note lack of offset or Z)
780/// assert_eq!("2033-05-18T03:33:20", display::array_value_to_string(&b, 1).unwrap());
781///
782/// // Convert timestamps without a timezone to timestamps with a timezone
783/// let c = cast(&b, &data_type_tz).unwrap();
784/// let c = c.as_primitive::<TimestampSecondType>(); // downcast to result type
785/// assert_eq!(2_000_018_000, c.value(1)); // value has been adjusted by offset
786/// // displayed with the target timezone offset (-05:00)
787/// assert_eq!("2033-05-18T03:33:20-05:00", display::array_value_to_string(&c, 1).unwrap());
788///
789/// // Convert from timestamp with timezone back to timestamp without timezone
790/// let d = cast(&c, &data_type).unwrap();
791/// let d = d.as_primitive::<TimestampSecondType>(); // downcast to result type
792/// assert_eq!(2_000_018_000, d.value(1)); // value has not been adjusted
793/// // NOTE: the timestamp is adjusted (08:33:20 instead of 03:33:20 as in previous example)
794/// assert_eq!("2033-05-18T08:33:20", display::array_value_to_string(&d, 1).unwrap());
795/// ```
796pub fn cast_with_options(
797    array: &dyn Array,
798    to_type: &DataType,
799    cast_options: &CastOptions,
800) -> Result<ArrayRef, ArrowError> {
801    use DataType::*;
802    let from_type = array.data_type();
803    // clone array if types are the same
804    if from_type == to_type {
805        return Ok(make_array(array.to_data()));
806    }
807    match (from_type, to_type) {
808        (
809            Null,
810            Boolean
811            | Int8
812            | UInt8
813            | Int16
814            | UInt16
815            | Float16
816            | Int32
817            | UInt32
818            | Float32
819            | Date32
820            | Time32(_)
821            | Int64
822            | UInt64
823            | Float64
824            | Date64
825            | Timestamp(_, _)
826            | Time64(_)
827            | Duration(_)
828            | Interval(_)
829            | FixedSizeBinary(_)
830            | Binary
831            | Utf8
832            | LargeBinary
833            | LargeUtf8
834            | BinaryView
835            | Utf8View
836            | List(_)
837            | LargeList(_)
838            | FixedSizeList(_, _)
839            | Struct(_)
840            | Map(_, _)
841            | Dictionary(_, _),
842        ) => Ok(new_null_array(to_type, array.len())),
843        (RunEndEncoded(index_type, _), _) => match index_type.data_type() {
844            Int16 => run_end_encoded_cast::<Int16Type>(array, to_type, cast_options),
845            Int32 => run_end_encoded_cast::<Int32Type>(array, to_type, cast_options),
846            Int64 => run_end_encoded_cast::<Int64Type>(array, to_type, cast_options),
847            _ => Err(ArrowError::CastError(format!(
848                "Casting from run end encoded type {from_type:?} to {to_type:?} not supported",
849            ))),
850        },
851        (_, RunEndEncoded(index_type, value_type)) => {
852            let array_ref = make_array(array.to_data());
853            match index_type.data_type() {
854                Int16 => cast_to_run_end_encoded::<Int16Type>(
855                    &array_ref,
856                    value_type.data_type(),
857                    cast_options,
858                ),
859                Int32 => cast_to_run_end_encoded::<Int32Type>(
860                    &array_ref,
861                    value_type.data_type(),
862                    cast_options,
863                ),
864                Int64 => cast_to_run_end_encoded::<Int64Type>(
865                    &array_ref,
866                    value_type.data_type(),
867                    cast_options,
868                ),
869                _ => Err(ArrowError::CastError(format!(
870                    "Casting from type {from_type:?} to run end encoded type {to_type:?} not supported",
871                ))),
872            }
873        }
874        (Dictionary(index_type, _), _) => match **index_type {
875            Int8 => dictionary_cast::<Int8Type>(array, to_type, cast_options),
876            Int16 => dictionary_cast::<Int16Type>(array, to_type, cast_options),
877            Int32 => dictionary_cast::<Int32Type>(array, to_type, cast_options),
878            Int64 => dictionary_cast::<Int64Type>(array, to_type, cast_options),
879            UInt8 => dictionary_cast::<UInt8Type>(array, to_type, cast_options),
880            UInt16 => dictionary_cast::<UInt16Type>(array, to_type, cast_options),
881            UInt32 => dictionary_cast::<UInt32Type>(array, to_type, cast_options),
882            UInt64 => dictionary_cast::<UInt64Type>(array, to_type, cast_options),
883            _ => Err(ArrowError::CastError(format!(
884                "Casting from dictionary type {from_type} to {to_type} not supported",
885            ))),
886        },
887        (_, Dictionary(index_type, value_type)) => match **index_type {
888            Int8 => cast_to_dictionary::<Int8Type>(array, value_type, cast_options),
889            Int16 => cast_to_dictionary::<Int16Type>(array, value_type, cast_options),
890            Int32 => cast_to_dictionary::<Int32Type>(array, value_type, cast_options),
891            Int64 => cast_to_dictionary::<Int64Type>(array, value_type, cast_options),
892            UInt8 => cast_to_dictionary::<UInt8Type>(array, value_type, cast_options),
893            UInt16 => cast_to_dictionary::<UInt16Type>(array, value_type, cast_options),
894            UInt32 => cast_to_dictionary::<UInt32Type>(array, value_type, cast_options),
895            UInt64 => cast_to_dictionary::<UInt64Type>(array, value_type, cast_options),
896            _ => Err(ArrowError::CastError(format!(
897                "Casting from type {from_type} to dictionary type {to_type} not supported",
898            ))),
899        },
900        (List(_), List(to)) => cast_list_values::<i32>(array, to, cast_options),
901        (LargeList(_), LargeList(to)) => cast_list_values::<i64>(array, to, cast_options),
902        (List(_), LargeList(list_to)) => cast_list::<i32, i64>(array, list_to, cast_options),
903        (LargeList(_), List(list_to)) => cast_list::<i64, i32>(array, list_to, cast_options),
904        (List(_), FixedSizeList(field, size)) => {
905            let array = array.as_list::<i32>();
906            cast_list_to_fixed_size_list::<i32>(array, field, *size, cast_options)
907        }
908        (LargeList(_), FixedSizeList(field, size)) => {
909            let array = array.as_list::<i64>();
910            cast_list_to_fixed_size_list::<i64>(array, field, *size, cast_options)
911        }
912        (ListView(_), List(list_to)) => cast_list_view_to_list::<i32>(array, list_to, cast_options),
913        (LargeListView(_), LargeList(list_to)) => {
914            cast_list_view_to_list::<i64>(array, list_to, cast_options)
915        }
916        (ListView(_), LargeListView(list_to)) => {
917            cast_list_view::<i32, i64>(array, list_to, cast_options)
918        }
919        (LargeListView(_), ListView(list_to)) => {
920            cast_list_view::<i64, i32>(array, list_to, cast_options)
921        }
922        (List(_), ListView(_)) => cast_list_to_list_view::<i32>(array),
923        (LargeList(_), LargeListView(_)) => cast_list_to_list_view::<i64>(array),
924        (List(_) | LargeList(_), _) => match to_type {
925            Utf8 => value_to_string::<i32>(array, cast_options),
926            LargeUtf8 => value_to_string::<i64>(array, cast_options),
927            _ => Err(ArrowError::CastError(
928                "Cannot cast list to non-list data types".to_string(),
929            )),
930        },
931        (FixedSizeList(list_from, size), List(list_to)) => {
932            if list_to.data_type() != list_from.data_type() {
933                // To transform inner type, can first cast to FSL with new inner type.
934                let fsl_to = DataType::FixedSizeList(list_to.clone(), *size);
935                let array = cast_with_options(array, &fsl_to, cast_options)?;
936                cast_fixed_size_list_to_list::<i32>(array.as_ref())
937            } else {
938                cast_fixed_size_list_to_list::<i32>(array)
939            }
940        }
941        (FixedSizeList(list_from, size), LargeList(list_to)) => {
942            if list_to.data_type() != list_from.data_type() {
943                // To transform inner type, can first cast to FSL with new inner type.
944                let fsl_to = DataType::FixedSizeList(list_to.clone(), *size);
945                let array = cast_with_options(array, &fsl_to, cast_options)?;
946                cast_fixed_size_list_to_list::<i64>(array.as_ref())
947            } else {
948                cast_fixed_size_list_to_list::<i64>(array)
949            }
950        }
951        (FixedSizeList(_, size_from), FixedSizeList(list_to, size_to)) => {
952            if size_from != size_to {
953                return Err(ArrowError::CastError(
954                    "cannot cast fixed-size-list to fixed-size-list with different size".into(),
955                ));
956            }
957            let array = array.as_any().downcast_ref::<FixedSizeListArray>().unwrap();
958            let values = cast_with_options(array.values(), list_to.data_type(), cast_options)?;
959            Ok(Arc::new(FixedSizeListArray::try_new(
960                list_to.clone(),
961                *size_from,
962                values,
963                array.nulls().cloned(),
964            )?))
965        }
966        (_, List(to)) => cast_values_to_list::<i32>(array, to, cast_options),
967        (_, LargeList(to)) => cast_values_to_list::<i64>(array, to, cast_options),
968        (_, FixedSizeList(to, size)) if *size == 1 => {
969            cast_values_to_fixed_size_list(array, to, *size, cast_options)
970        }
971        (FixedSizeList(_, size), _) if *size == 1 => {
972            cast_single_element_fixed_size_list_to_values(array, to_type, cast_options)
973        }
974        (Map(_, ordered1), Map(_, ordered2)) if ordered1 == ordered2 => {
975            cast_map_values(array.as_map(), to_type, cast_options, ordered1.to_owned())
976        }
977        // Decimal to decimal, same width
978        (Decimal32(p1, s1), Decimal32(p2, s2)) => {
979            cast_decimal_to_decimal_same_type::<Decimal32Type>(
980                array.as_primitive(),
981                *p1,
982                *s1,
983                *p2,
984                *s2,
985                cast_options,
986            )
987        }
988        (Decimal64(p1, s1), Decimal64(p2, s2)) => {
989            cast_decimal_to_decimal_same_type::<Decimal64Type>(
990                array.as_primitive(),
991                *p1,
992                *s1,
993                *p2,
994                *s2,
995                cast_options,
996            )
997        }
998        (Decimal128(p1, s1), Decimal128(p2, s2)) => {
999            cast_decimal_to_decimal_same_type::<Decimal128Type>(
1000                array.as_primitive(),
1001                *p1,
1002                *s1,
1003                *p2,
1004                *s2,
1005                cast_options,
1006            )
1007        }
1008        (Decimal256(p1, s1), Decimal256(p2, s2)) => {
1009            cast_decimal_to_decimal_same_type::<Decimal256Type>(
1010                array.as_primitive(),
1011                *p1,
1012                *s1,
1013                *p2,
1014                *s2,
1015                cast_options,
1016            )
1017        }
1018        // Decimal to decimal, different width
1019        (Decimal32(p1, s1), Decimal64(p2, s2)) => {
1020            cast_decimal_to_decimal::<Decimal32Type, Decimal64Type>(
1021                array.as_primitive(),
1022                *p1,
1023                *s1,
1024                *p2,
1025                *s2,
1026                cast_options,
1027            )
1028        }
1029        (Decimal32(p1, s1), Decimal128(p2, s2)) => {
1030            cast_decimal_to_decimal::<Decimal32Type, Decimal128Type>(
1031                array.as_primitive(),
1032                *p1,
1033                *s1,
1034                *p2,
1035                *s2,
1036                cast_options,
1037            )
1038        }
1039        (Decimal32(p1, s1), Decimal256(p2, s2)) => {
1040            cast_decimal_to_decimal::<Decimal32Type, Decimal256Type>(
1041                array.as_primitive(),
1042                *p1,
1043                *s1,
1044                *p2,
1045                *s2,
1046                cast_options,
1047            )
1048        }
1049        (Decimal64(p1, s1), Decimal32(p2, s2)) => {
1050            cast_decimal_to_decimal::<Decimal64Type, Decimal32Type>(
1051                array.as_primitive(),
1052                *p1,
1053                *s1,
1054                *p2,
1055                *s2,
1056                cast_options,
1057            )
1058        }
1059        (Decimal64(p1, s1), Decimal128(p2, s2)) => {
1060            cast_decimal_to_decimal::<Decimal64Type, Decimal128Type>(
1061                array.as_primitive(),
1062                *p1,
1063                *s1,
1064                *p2,
1065                *s2,
1066                cast_options,
1067            )
1068        }
1069        (Decimal64(p1, s1), Decimal256(p2, s2)) => {
1070            cast_decimal_to_decimal::<Decimal64Type, Decimal256Type>(
1071                array.as_primitive(),
1072                *p1,
1073                *s1,
1074                *p2,
1075                *s2,
1076                cast_options,
1077            )
1078        }
1079        (Decimal128(p1, s1), Decimal32(p2, s2)) => {
1080            cast_decimal_to_decimal::<Decimal128Type, Decimal32Type>(
1081                array.as_primitive(),
1082                *p1,
1083                *s1,
1084                *p2,
1085                *s2,
1086                cast_options,
1087            )
1088        }
1089        (Decimal128(p1, s1), Decimal64(p2, s2)) => {
1090            cast_decimal_to_decimal::<Decimal128Type, Decimal64Type>(
1091                array.as_primitive(),
1092                *p1,
1093                *s1,
1094                *p2,
1095                *s2,
1096                cast_options,
1097            )
1098        }
1099        (Decimal128(p1, s1), Decimal256(p2, s2)) => {
1100            cast_decimal_to_decimal::<Decimal128Type, Decimal256Type>(
1101                array.as_primitive(),
1102                *p1,
1103                *s1,
1104                *p2,
1105                *s2,
1106                cast_options,
1107            )
1108        }
1109        (Decimal256(p1, s1), Decimal32(p2, s2)) => {
1110            cast_decimal_to_decimal::<Decimal256Type, Decimal32Type>(
1111                array.as_primitive(),
1112                *p1,
1113                *s1,
1114                *p2,
1115                *s2,
1116                cast_options,
1117            )
1118        }
1119        (Decimal256(p1, s1), Decimal64(p2, s2)) => {
1120            cast_decimal_to_decimal::<Decimal256Type, Decimal64Type>(
1121                array.as_primitive(),
1122                *p1,
1123                *s1,
1124                *p2,
1125                *s2,
1126                cast_options,
1127            )
1128        }
1129        (Decimal256(p1, s1), Decimal128(p2, s2)) => {
1130            cast_decimal_to_decimal::<Decimal256Type, Decimal128Type>(
1131                array.as_primitive(),
1132                *p1,
1133                *s1,
1134                *p2,
1135                *s2,
1136                cast_options,
1137            )
1138        }
1139        // Decimal to non-decimal
1140        (Decimal32(_, scale), _) if !to_type.is_temporal() => {
1141            cast_from_decimal::<Decimal32Type, _>(
1142                array,
1143                10_i32,
1144                scale,
1145                from_type,
1146                to_type,
1147                |x: i32| x as f64,
1148                cast_options,
1149            )
1150        }
1151        (Decimal64(_, scale), _) if !to_type.is_temporal() => {
1152            cast_from_decimal::<Decimal64Type, _>(
1153                array,
1154                10_i64,
1155                scale,
1156                from_type,
1157                to_type,
1158                |x: i64| x as f64,
1159                cast_options,
1160            )
1161        }
1162        (Decimal128(_, scale), _) if !to_type.is_temporal() => {
1163            cast_from_decimal::<Decimal128Type, _>(
1164                array,
1165                10_i128,
1166                scale,
1167                from_type,
1168                to_type,
1169                |x: i128| x as f64,
1170                cast_options,
1171            )
1172        }
1173        (Decimal256(_, scale), _) if !to_type.is_temporal() => {
1174            cast_from_decimal::<Decimal256Type, _>(
1175                array,
1176                i256::from_i128(10_i128),
1177                scale,
1178                from_type,
1179                to_type,
1180                |x: i256| x.to_f64().expect("All i256 values fit in f64"),
1181                cast_options,
1182            )
1183        }
1184        // Non-decimal to decimal
1185        (_, Decimal32(precision, scale)) if !from_type.is_temporal() => {
1186            cast_to_decimal::<Decimal32Type, _>(
1187                array,
1188                10_i32,
1189                precision,
1190                scale,
1191                from_type,
1192                to_type,
1193                cast_options,
1194            )
1195        }
1196        (_, Decimal64(precision, scale)) if !from_type.is_temporal() => {
1197            cast_to_decimal::<Decimal64Type, _>(
1198                array,
1199                10_i64,
1200                precision,
1201                scale,
1202                from_type,
1203                to_type,
1204                cast_options,
1205            )
1206        }
1207        (_, Decimal128(precision, scale)) if !from_type.is_temporal() => {
1208            cast_to_decimal::<Decimal128Type, _>(
1209                array,
1210                10_i128,
1211                precision,
1212                scale,
1213                from_type,
1214                to_type,
1215                cast_options,
1216            )
1217        }
1218        (_, Decimal256(precision, scale)) if !from_type.is_temporal() => {
1219            cast_to_decimal::<Decimal256Type, _>(
1220                array,
1221                i256::from_i128(10_i128),
1222                precision,
1223                scale,
1224                from_type,
1225                to_type,
1226                cast_options,
1227            )
1228        }
1229        (Struct(from_fields), Struct(to_fields)) => cast_struct_to_struct(
1230            array.as_struct(),
1231            from_fields.clone(),
1232            to_fields.clone(),
1233            cast_options,
1234        ),
1235        (Struct(_), _) => Err(ArrowError::CastError(format!(
1236            "Casting from {from_type} to {to_type} not supported"
1237        ))),
1238        (_, Struct(_)) => Err(ArrowError::CastError(format!(
1239            "Casting from {from_type} to {to_type} not supported"
1240        ))),
1241        (_, Boolean) => match from_type {
1242            UInt8 => cast_numeric_to_bool::<UInt8Type>(array),
1243            UInt16 => cast_numeric_to_bool::<UInt16Type>(array),
1244            UInt32 => cast_numeric_to_bool::<UInt32Type>(array),
1245            UInt64 => cast_numeric_to_bool::<UInt64Type>(array),
1246            Int8 => cast_numeric_to_bool::<Int8Type>(array),
1247            Int16 => cast_numeric_to_bool::<Int16Type>(array),
1248            Int32 => cast_numeric_to_bool::<Int32Type>(array),
1249            Int64 => cast_numeric_to_bool::<Int64Type>(array),
1250            Float16 => cast_numeric_to_bool::<Float16Type>(array),
1251            Float32 => cast_numeric_to_bool::<Float32Type>(array),
1252            Float64 => cast_numeric_to_bool::<Float64Type>(array),
1253            Utf8View => cast_utf8view_to_boolean(array, cast_options),
1254            Utf8 => cast_utf8_to_boolean::<i32>(array, cast_options),
1255            LargeUtf8 => cast_utf8_to_boolean::<i64>(array, cast_options),
1256            _ => Err(ArrowError::CastError(format!(
1257                "Casting from {from_type} to {to_type} not supported",
1258            ))),
1259        },
1260        (Boolean, _) => match to_type {
1261            UInt8 => cast_bool_to_numeric::<UInt8Type>(array, cast_options),
1262            UInt16 => cast_bool_to_numeric::<UInt16Type>(array, cast_options),
1263            UInt32 => cast_bool_to_numeric::<UInt32Type>(array, cast_options),
1264            UInt64 => cast_bool_to_numeric::<UInt64Type>(array, cast_options),
1265            Int8 => cast_bool_to_numeric::<Int8Type>(array, cast_options),
1266            Int16 => cast_bool_to_numeric::<Int16Type>(array, cast_options),
1267            Int32 => cast_bool_to_numeric::<Int32Type>(array, cast_options),
1268            Int64 => cast_bool_to_numeric::<Int64Type>(array, cast_options),
1269            Float16 => cast_bool_to_numeric::<Float16Type>(array, cast_options),
1270            Float32 => cast_bool_to_numeric::<Float32Type>(array, cast_options),
1271            Float64 => cast_bool_to_numeric::<Float64Type>(array, cast_options),
1272            Utf8View => value_to_string_view(array, cast_options),
1273            Utf8 => value_to_string::<i32>(array, cast_options),
1274            LargeUtf8 => value_to_string::<i64>(array, cast_options),
1275            _ => Err(ArrowError::CastError(format!(
1276                "Casting from {from_type} to {to_type} not supported",
1277            ))),
1278        },
1279        (Utf8, _) => match to_type {
1280            UInt8 => parse_string::<UInt8Type, i32>(array, cast_options),
1281            UInt16 => parse_string::<UInt16Type, i32>(array, cast_options),
1282            UInt32 => parse_string::<UInt32Type, i32>(array, cast_options),
1283            UInt64 => parse_string::<UInt64Type, i32>(array, cast_options),
1284            Int8 => parse_string::<Int8Type, i32>(array, cast_options),
1285            Int16 => parse_string::<Int16Type, i32>(array, cast_options),
1286            Int32 => parse_string::<Int32Type, i32>(array, cast_options),
1287            Int64 => parse_string::<Int64Type, i32>(array, cast_options),
1288            Float32 => parse_string::<Float32Type, i32>(array, cast_options),
1289            Float64 => parse_string::<Float64Type, i32>(array, cast_options),
1290            Date32 => parse_string::<Date32Type, i32>(array, cast_options),
1291            Date64 => parse_string::<Date64Type, i32>(array, cast_options),
1292            Binary => Ok(Arc::new(BinaryArray::from(
1293                array.as_string::<i32>().clone(),
1294            ))),
1295            LargeBinary => {
1296                let binary = BinaryArray::from(array.as_string::<i32>().clone());
1297                cast_byte_container::<BinaryType, LargeBinaryType>(&binary)
1298            }
1299            Utf8View => Ok(Arc::new(StringViewArray::from(array.as_string::<i32>()))),
1300            BinaryView => Ok(Arc::new(
1301                StringViewArray::from(array.as_string::<i32>()).to_binary_view(),
1302            )),
1303            LargeUtf8 => cast_byte_container::<Utf8Type, LargeUtf8Type>(array),
1304            Time32(TimeUnit::Second) => parse_string::<Time32SecondType, i32>(array, cast_options),
1305            Time32(TimeUnit::Millisecond) => {
1306                parse_string::<Time32MillisecondType, i32>(array, cast_options)
1307            }
1308            Time64(TimeUnit::Microsecond) => {
1309                parse_string::<Time64MicrosecondType, i32>(array, cast_options)
1310            }
1311            Time64(TimeUnit::Nanosecond) => {
1312                parse_string::<Time64NanosecondType, i32>(array, cast_options)
1313            }
1314            Timestamp(TimeUnit::Second, to_tz) => {
1315                cast_string_to_timestamp::<i32, TimestampSecondType>(array, to_tz, cast_options)
1316            }
1317            Timestamp(TimeUnit::Millisecond, to_tz) => cast_string_to_timestamp::<
1318                i32,
1319                TimestampMillisecondType,
1320            >(array, to_tz, cast_options),
1321            Timestamp(TimeUnit::Microsecond, to_tz) => cast_string_to_timestamp::<
1322                i32,
1323                TimestampMicrosecondType,
1324            >(array, to_tz, cast_options),
1325            Timestamp(TimeUnit::Nanosecond, to_tz) => {
1326                cast_string_to_timestamp::<i32, TimestampNanosecondType>(array, to_tz, cast_options)
1327            }
1328            Interval(IntervalUnit::YearMonth) => {
1329                cast_string_to_year_month_interval::<i32>(array, cast_options)
1330            }
1331            Interval(IntervalUnit::DayTime) => {
1332                cast_string_to_day_time_interval::<i32>(array, cast_options)
1333            }
1334            Interval(IntervalUnit::MonthDayNano) => {
1335                cast_string_to_month_day_nano_interval::<i32>(array, cast_options)
1336            }
1337            _ => Err(ArrowError::CastError(format!(
1338                "Casting from {from_type} to {to_type} not supported",
1339            ))),
1340        },
1341        (Utf8View, _) => match to_type {
1342            UInt8 => parse_string_view::<UInt8Type>(array, cast_options),
1343            UInt16 => parse_string_view::<UInt16Type>(array, cast_options),
1344            UInt32 => parse_string_view::<UInt32Type>(array, cast_options),
1345            UInt64 => parse_string_view::<UInt64Type>(array, cast_options),
1346            Int8 => parse_string_view::<Int8Type>(array, cast_options),
1347            Int16 => parse_string_view::<Int16Type>(array, cast_options),
1348            Int32 => parse_string_view::<Int32Type>(array, cast_options),
1349            Int64 => parse_string_view::<Int64Type>(array, cast_options),
1350            Float32 => parse_string_view::<Float32Type>(array, cast_options),
1351            Float64 => parse_string_view::<Float64Type>(array, cast_options),
1352            Date32 => parse_string_view::<Date32Type>(array, cast_options),
1353            Date64 => parse_string_view::<Date64Type>(array, cast_options),
1354            Binary => cast_view_to_byte::<StringViewType, GenericBinaryType<i32>>(array),
1355            LargeBinary => cast_view_to_byte::<StringViewType, GenericBinaryType<i64>>(array),
1356            BinaryView => Ok(Arc::new(array.as_string_view().clone().to_binary_view())),
1357            Utf8 => cast_view_to_byte::<StringViewType, GenericStringType<i32>>(array),
1358            LargeUtf8 => cast_view_to_byte::<StringViewType, GenericStringType<i64>>(array),
1359            Time32(TimeUnit::Second) => parse_string_view::<Time32SecondType>(array, cast_options),
1360            Time32(TimeUnit::Millisecond) => {
1361                parse_string_view::<Time32MillisecondType>(array, cast_options)
1362            }
1363            Time64(TimeUnit::Microsecond) => {
1364                parse_string_view::<Time64MicrosecondType>(array, cast_options)
1365            }
1366            Time64(TimeUnit::Nanosecond) => {
1367                parse_string_view::<Time64NanosecondType>(array, cast_options)
1368            }
1369            Timestamp(TimeUnit::Second, to_tz) => {
1370                cast_view_to_timestamp::<TimestampSecondType>(array, to_tz, cast_options)
1371            }
1372            Timestamp(TimeUnit::Millisecond, to_tz) => {
1373                cast_view_to_timestamp::<TimestampMillisecondType>(array, to_tz, cast_options)
1374            }
1375            Timestamp(TimeUnit::Microsecond, to_tz) => {
1376                cast_view_to_timestamp::<TimestampMicrosecondType>(array, to_tz, cast_options)
1377            }
1378            Timestamp(TimeUnit::Nanosecond, to_tz) => {
1379                cast_view_to_timestamp::<TimestampNanosecondType>(array, to_tz, cast_options)
1380            }
1381            Interval(IntervalUnit::YearMonth) => {
1382                cast_view_to_year_month_interval(array, cast_options)
1383            }
1384            Interval(IntervalUnit::DayTime) => cast_view_to_day_time_interval(array, cast_options),
1385            Interval(IntervalUnit::MonthDayNano) => {
1386                cast_view_to_month_day_nano_interval(array, cast_options)
1387            }
1388            _ => Err(ArrowError::CastError(format!(
1389                "Casting from {from_type} to {to_type} not supported",
1390            ))),
1391        },
1392        (LargeUtf8, _) => match to_type {
1393            UInt8 => parse_string::<UInt8Type, i64>(array, cast_options),
1394            UInt16 => parse_string::<UInt16Type, i64>(array, cast_options),
1395            UInt32 => parse_string::<UInt32Type, i64>(array, cast_options),
1396            UInt64 => parse_string::<UInt64Type, i64>(array, cast_options),
1397            Int8 => parse_string::<Int8Type, i64>(array, cast_options),
1398            Int16 => parse_string::<Int16Type, i64>(array, cast_options),
1399            Int32 => parse_string::<Int32Type, i64>(array, cast_options),
1400            Int64 => parse_string::<Int64Type, i64>(array, cast_options),
1401            Float32 => parse_string::<Float32Type, i64>(array, cast_options),
1402            Float64 => parse_string::<Float64Type, i64>(array, cast_options),
1403            Date32 => parse_string::<Date32Type, i64>(array, cast_options),
1404            Date64 => parse_string::<Date64Type, i64>(array, cast_options),
1405            Utf8 => cast_byte_container::<LargeUtf8Type, Utf8Type>(array),
1406            Binary => {
1407                let large_binary = LargeBinaryArray::from(array.as_string::<i64>().clone());
1408                cast_byte_container::<LargeBinaryType, BinaryType>(&large_binary)
1409            }
1410            LargeBinary => Ok(Arc::new(LargeBinaryArray::from(
1411                array.as_string::<i64>().clone(),
1412            ))),
1413            Utf8View => Ok(Arc::new(StringViewArray::from(array.as_string::<i64>()))),
1414            BinaryView => Ok(Arc::new(BinaryViewArray::from(
1415                array
1416                    .as_string::<i64>()
1417                    .into_iter()
1418                    .map(|x| x.map(|x| x.as_bytes()))
1419                    .collect::<Vec<_>>(),
1420            ))),
1421            Time32(TimeUnit::Second) => parse_string::<Time32SecondType, i64>(array, cast_options),
1422            Time32(TimeUnit::Millisecond) => {
1423                parse_string::<Time32MillisecondType, i64>(array, cast_options)
1424            }
1425            Time64(TimeUnit::Microsecond) => {
1426                parse_string::<Time64MicrosecondType, i64>(array, cast_options)
1427            }
1428            Time64(TimeUnit::Nanosecond) => {
1429                parse_string::<Time64NanosecondType, i64>(array, cast_options)
1430            }
1431            Timestamp(TimeUnit::Second, to_tz) => {
1432                cast_string_to_timestamp::<i64, TimestampSecondType>(array, to_tz, cast_options)
1433            }
1434            Timestamp(TimeUnit::Millisecond, to_tz) => cast_string_to_timestamp::<
1435                i64,
1436                TimestampMillisecondType,
1437            >(array, to_tz, cast_options),
1438            Timestamp(TimeUnit::Microsecond, to_tz) => cast_string_to_timestamp::<
1439                i64,
1440                TimestampMicrosecondType,
1441            >(array, to_tz, cast_options),
1442            Timestamp(TimeUnit::Nanosecond, to_tz) => {
1443                cast_string_to_timestamp::<i64, TimestampNanosecondType>(array, to_tz, cast_options)
1444            }
1445            Interval(IntervalUnit::YearMonth) => {
1446                cast_string_to_year_month_interval::<i64>(array, cast_options)
1447            }
1448            Interval(IntervalUnit::DayTime) => {
1449                cast_string_to_day_time_interval::<i64>(array, cast_options)
1450            }
1451            Interval(IntervalUnit::MonthDayNano) => {
1452                cast_string_to_month_day_nano_interval::<i64>(array, cast_options)
1453            }
1454            _ => Err(ArrowError::CastError(format!(
1455                "Casting from {from_type} to {to_type} not supported",
1456            ))),
1457        },
1458        (Binary, _) => match to_type {
1459            Utf8 => cast_binary_to_string::<i32>(array, cast_options),
1460            LargeUtf8 => {
1461                let array = cast_binary_to_string::<i32>(array, cast_options)?;
1462                cast_byte_container::<Utf8Type, LargeUtf8Type>(array.as_ref())
1463            }
1464            LargeBinary => cast_byte_container::<BinaryType, LargeBinaryType>(array),
1465            FixedSizeBinary(size) => {
1466                cast_binary_to_fixed_size_binary::<i32>(array, *size, cast_options)
1467            }
1468            BinaryView => Ok(Arc::new(BinaryViewArray::from(array.as_binary::<i32>()))),
1469            Utf8View => Ok(Arc::new(StringViewArray::from(
1470                cast_binary_to_string::<i32>(array, cast_options)?.as_string::<i32>(),
1471            ))),
1472            _ => Err(ArrowError::CastError(format!(
1473                "Casting from {from_type} to {to_type} not supported",
1474            ))),
1475        },
1476        (LargeBinary, _) => match to_type {
1477            Utf8 => {
1478                let array = cast_binary_to_string::<i64>(array, cast_options)?;
1479                cast_byte_container::<LargeUtf8Type, Utf8Type>(array.as_ref())
1480            }
1481            LargeUtf8 => cast_binary_to_string::<i64>(array, cast_options),
1482            Binary => cast_byte_container::<LargeBinaryType, BinaryType>(array),
1483            FixedSizeBinary(size) => {
1484                cast_binary_to_fixed_size_binary::<i64>(array, *size, cast_options)
1485            }
1486            BinaryView => Ok(Arc::new(BinaryViewArray::from(array.as_binary::<i64>()))),
1487            Utf8View => {
1488                let array = cast_binary_to_string::<i64>(array, cast_options)?;
1489                Ok(Arc::new(StringViewArray::from(array.as_string::<i64>())))
1490            }
1491            _ => Err(ArrowError::CastError(format!(
1492                "Casting from {from_type} to {to_type} not supported",
1493            ))),
1494        },
1495        (FixedSizeBinary(size), _) => match to_type {
1496            Binary => cast_fixed_size_binary_to_binary::<i32>(array, *size),
1497            LargeBinary => cast_fixed_size_binary_to_binary::<i64>(array, *size),
1498            BinaryView => cast_fixed_size_binary_to_binary_view(array, *size),
1499            _ => Err(ArrowError::CastError(format!(
1500                "Casting from {from_type} to {to_type} not supported",
1501            ))),
1502        },
1503        (BinaryView, Binary) => cast_view_to_byte::<BinaryViewType, GenericBinaryType<i32>>(array),
1504        (BinaryView, LargeBinary) => {
1505            cast_view_to_byte::<BinaryViewType, GenericBinaryType<i64>>(array)
1506        }
1507        (BinaryView, Utf8) => {
1508            let binary_arr = cast_view_to_byte::<BinaryViewType, GenericBinaryType<i32>>(array)?;
1509            cast_binary_to_string::<i32>(&binary_arr, cast_options)
1510        }
1511        (BinaryView, LargeUtf8) => {
1512            let binary_arr = cast_view_to_byte::<BinaryViewType, GenericBinaryType<i64>>(array)?;
1513            cast_binary_to_string::<i64>(&binary_arr, cast_options)
1514        }
1515        (BinaryView, Utf8View) => cast_binary_view_to_string_view(array, cast_options),
1516        (BinaryView, _) => Err(ArrowError::CastError(format!(
1517            "Casting from {from_type} to {to_type} not supported",
1518        ))),
1519        (from_type, Utf8View) if from_type.is_primitive() => {
1520            value_to_string_view(array, cast_options)
1521        }
1522        (from_type, LargeUtf8) if from_type.is_primitive() => {
1523            value_to_string::<i64>(array, cast_options)
1524        }
1525        (from_type, Utf8) if from_type.is_primitive() => {
1526            value_to_string::<i32>(array, cast_options)
1527        }
1528        (from_type, Binary) if from_type.is_integer() => match from_type {
1529            UInt8 => cast_numeric_to_binary::<UInt8Type, i32>(array),
1530            UInt16 => cast_numeric_to_binary::<UInt16Type, i32>(array),
1531            UInt32 => cast_numeric_to_binary::<UInt32Type, i32>(array),
1532            UInt64 => cast_numeric_to_binary::<UInt64Type, i32>(array),
1533            Int8 => cast_numeric_to_binary::<Int8Type, i32>(array),
1534            Int16 => cast_numeric_to_binary::<Int16Type, i32>(array),
1535            Int32 => cast_numeric_to_binary::<Int32Type, i32>(array),
1536            Int64 => cast_numeric_to_binary::<Int64Type, i32>(array),
1537            _ => unreachable!(),
1538        },
1539        (from_type, LargeBinary) if from_type.is_integer() => match from_type {
1540            UInt8 => cast_numeric_to_binary::<UInt8Type, i64>(array),
1541            UInt16 => cast_numeric_to_binary::<UInt16Type, i64>(array),
1542            UInt32 => cast_numeric_to_binary::<UInt32Type, i64>(array),
1543            UInt64 => cast_numeric_to_binary::<UInt64Type, i64>(array),
1544            Int8 => cast_numeric_to_binary::<Int8Type, i64>(array),
1545            Int16 => cast_numeric_to_binary::<Int16Type, i64>(array),
1546            Int32 => cast_numeric_to_binary::<Int32Type, i64>(array),
1547            Int64 => cast_numeric_to_binary::<Int64Type, i64>(array),
1548            _ => unreachable!(),
1549        },
1550        // start numeric casts
1551        (UInt8, UInt16) => cast_numeric_arrays::<UInt8Type, UInt16Type>(array, cast_options),
1552        (UInt8, UInt32) => cast_numeric_arrays::<UInt8Type, UInt32Type>(array, cast_options),
1553        (UInt8, UInt64) => cast_numeric_arrays::<UInt8Type, UInt64Type>(array, cast_options),
1554        (UInt8, Int8) => cast_numeric_arrays::<UInt8Type, Int8Type>(array, cast_options),
1555        (UInt8, Int16) => cast_numeric_arrays::<UInt8Type, Int16Type>(array, cast_options),
1556        (UInt8, Int32) => cast_numeric_arrays::<UInt8Type, Int32Type>(array, cast_options),
1557        (UInt8, Int64) => cast_numeric_arrays::<UInt8Type, Int64Type>(array, cast_options),
1558        (UInt8, Float16) => cast_numeric_arrays::<UInt8Type, Float16Type>(array, cast_options),
1559        (UInt8, Float32) => cast_numeric_arrays::<UInt8Type, Float32Type>(array, cast_options),
1560        (UInt8, Float64) => cast_numeric_arrays::<UInt8Type, Float64Type>(array, cast_options),
1561
1562        (UInt16, UInt8) => cast_numeric_arrays::<UInt16Type, UInt8Type>(array, cast_options),
1563        (UInt16, UInt32) => cast_numeric_arrays::<UInt16Type, UInt32Type>(array, cast_options),
1564        (UInt16, UInt64) => cast_numeric_arrays::<UInt16Type, UInt64Type>(array, cast_options),
1565        (UInt16, Int8) => cast_numeric_arrays::<UInt16Type, Int8Type>(array, cast_options),
1566        (UInt16, Int16) => cast_numeric_arrays::<UInt16Type, Int16Type>(array, cast_options),
1567        (UInt16, Int32) => cast_numeric_arrays::<UInt16Type, Int32Type>(array, cast_options),
1568        (UInt16, Int64) => cast_numeric_arrays::<UInt16Type, Int64Type>(array, cast_options),
1569        (UInt16, Float16) => cast_numeric_arrays::<UInt16Type, Float16Type>(array, cast_options),
1570        (UInt16, Float32) => cast_numeric_arrays::<UInt16Type, Float32Type>(array, cast_options),
1571        (UInt16, Float64) => cast_numeric_arrays::<UInt16Type, Float64Type>(array, cast_options),
1572
1573        (UInt32, UInt8) => cast_numeric_arrays::<UInt32Type, UInt8Type>(array, cast_options),
1574        (UInt32, UInt16) => cast_numeric_arrays::<UInt32Type, UInt16Type>(array, cast_options),
1575        (UInt32, UInt64) => cast_numeric_arrays::<UInt32Type, UInt64Type>(array, cast_options),
1576        (UInt32, Int8) => cast_numeric_arrays::<UInt32Type, Int8Type>(array, cast_options),
1577        (UInt32, Int16) => cast_numeric_arrays::<UInt32Type, Int16Type>(array, cast_options),
1578        (UInt32, Int32) => cast_numeric_arrays::<UInt32Type, Int32Type>(array, cast_options),
1579        (UInt32, Int64) => cast_numeric_arrays::<UInt32Type, Int64Type>(array, cast_options),
1580        (UInt32, Float16) => cast_numeric_arrays::<UInt32Type, Float16Type>(array, cast_options),
1581        (UInt32, Float32) => cast_numeric_arrays::<UInt32Type, Float32Type>(array, cast_options),
1582        (UInt32, Float64) => cast_numeric_arrays::<UInt32Type, Float64Type>(array, cast_options),
1583
1584        (UInt64, UInt8) => cast_numeric_arrays::<UInt64Type, UInt8Type>(array, cast_options),
1585        (UInt64, UInt16) => cast_numeric_arrays::<UInt64Type, UInt16Type>(array, cast_options),
1586        (UInt64, UInt32) => cast_numeric_arrays::<UInt64Type, UInt32Type>(array, cast_options),
1587        (UInt64, Int8) => cast_numeric_arrays::<UInt64Type, Int8Type>(array, cast_options),
1588        (UInt64, Int16) => cast_numeric_arrays::<UInt64Type, Int16Type>(array, cast_options),
1589        (UInt64, Int32) => cast_numeric_arrays::<UInt64Type, Int32Type>(array, cast_options),
1590        (UInt64, Int64) => cast_numeric_arrays::<UInt64Type, Int64Type>(array, cast_options),
1591        (UInt64, Float16) => cast_numeric_arrays::<UInt64Type, Float16Type>(array, cast_options),
1592        (UInt64, Float32) => cast_numeric_arrays::<UInt64Type, Float32Type>(array, cast_options),
1593        (UInt64, Float64) => cast_numeric_arrays::<UInt64Type, Float64Type>(array, cast_options),
1594
1595        (Int8, UInt8) => cast_numeric_arrays::<Int8Type, UInt8Type>(array, cast_options),
1596        (Int8, UInt16) => cast_numeric_arrays::<Int8Type, UInt16Type>(array, cast_options),
1597        (Int8, UInt32) => cast_numeric_arrays::<Int8Type, UInt32Type>(array, cast_options),
1598        (Int8, UInt64) => cast_numeric_arrays::<Int8Type, UInt64Type>(array, cast_options),
1599        (Int8, Int16) => cast_numeric_arrays::<Int8Type, Int16Type>(array, cast_options),
1600        (Int8, Int32) => cast_numeric_arrays::<Int8Type, Int32Type>(array, cast_options),
1601        (Int8, Int64) => cast_numeric_arrays::<Int8Type, Int64Type>(array, cast_options),
1602        (Int8, Float16) => cast_numeric_arrays::<Int8Type, Float16Type>(array, cast_options),
1603        (Int8, Float32) => cast_numeric_arrays::<Int8Type, Float32Type>(array, cast_options),
1604        (Int8, Float64) => cast_numeric_arrays::<Int8Type, Float64Type>(array, cast_options),
1605
1606        (Int16, UInt8) => cast_numeric_arrays::<Int16Type, UInt8Type>(array, cast_options),
1607        (Int16, UInt16) => cast_numeric_arrays::<Int16Type, UInt16Type>(array, cast_options),
1608        (Int16, UInt32) => cast_numeric_arrays::<Int16Type, UInt32Type>(array, cast_options),
1609        (Int16, UInt64) => cast_numeric_arrays::<Int16Type, UInt64Type>(array, cast_options),
1610        (Int16, Int8) => cast_numeric_arrays::<Int16Type, Int8Type>(array, cast_options),
1611        (Int16, Int32) => cast_numeric_arrays::<Int16Type, Int32Type>(array, cast_options),
1612        (Int16, Int64) => cast_numeric_arrays::<Int16Type, Int64Type>(array, cast_options),
1613        (Int16, Float16) => cast_numeric_arrays::<Int16Type, Float16Type>(array, cast_options),
1614        (Int16, Float32) => cast_numeric_arrays::<Int16Type, Float32Type>(array, cast_options),
1615        (Int16, Float64) => cast_numeric_arrays::<Int16Type, Float64Type>(array, cast_options),
1616
1617        (Int32, UInt8) => cast_numeric_arrays::<Int32Type, UInt8Type>(array, cast_options),
1618        (Int32, UInt16) => cast_numeric_arrays::<Int32Type, UInt16Type>(array, cast_options),
1619        (Int32, UInt32) => cast_numeric_arrays::<Int32Type, UInt32Type>(array, cast_options),
1620        (Int32, UInt64) => cast_numeric_arrays::<Int32Type, UInt64Type>(array, cast_options),
1621        (Int32, Int8) => cast_numeric_arrays::<Int32Type, Int8Type>(array, cast_options),
1622        (Int32, Int16) => cast_numeric_arrays::<Int32Type, Int16Type>(array, cast_options),
1623        (Int32, Int64) => cast_numeric_arrays::<Int32Type, Int64Type>(array, cast_options),
1624        (Int32, Float16) => cast_numeric_arrays::<Int32Type, Float16Type>(array, cast_options),
1625        (Int32, Float32) => cast_numeric_arrays::<Int32Type, Float32Type>(array, cast_options),
1626        (Int32, Float64) => cast_numeric_arrays::<Int32Type, Float64Type>(array, cast_options),
1627
1628        (Int64, UInt8) => cast_numeric_arrays::<Int64Type, UInt8Type>(array, cast_options),
1629        (Int64, UInt16) => cast_numeric_arrays::<Int64Type, UInt16Type>(array, cast_options),
1630        (Int64, UInt32) => cast_numeric_arrays::<Int64Type, UInt32Type>(array, cast_options),
1631        (Int64, UInt64) => cast_numeric_arrays::<Int64Type, UInt64Type>(array, cast_options),
1632        (Int64, Int8) => cast_numeric_arrays::<Int64Type, Int8Type>(array, cast_options),
1633        (Int64, Int16) => cast_numeric_arrays::<Int64Type, Int16Type>(array, cast_options),
1634        (Int64, Int32) => cast_numeric_arrays::<Int64Type, Int32Type>(array, cast_options),
1635        (Int64, Float16) => cast_numeric_arrays::<Int64Type, Float16Type>(array, cast_options),
1636        (Int64, Float32) => cast_numeric_arrays::<Int64Type, Float32Type>(array, cast_options),
1637        (Int64, Float64) => cast_numeric_arrays::<Int64Type, Float64Type>(array, cast_options),
1638
1639        (Float16, UInt8) => cast_numeric_arrays::<Float16Type, UInt8Type>(array, cast_options),
1640        (Float16, UInt16) => cast_numeric_arrays::<Float16Type, UInt16Type>(array, cast_options),
1641        (Float16, UInt32) => cast_numeric_arrays::<Float16Type, UInt32Type>(array, cast_options),
1642        (Float16, UInt64) => cast_numeric_arrays::<Float16Type, UInt64Type>(array, cast_options),
1643        (Float16, Int8) => cast_numeric_arrays::<Float16Type, Int8Type>(array, cast_options),
1644        (Float16, Int16) => cast_numeric_arrays::<Float16Type, Int16Type>(array, cast_options),
1645        (Float16, Int32) => cast_numeric_arrays::<Float16Type, Int32Type>(array, cast_options),
1646        (Float16, Int64) => cast_numeric_arrays::<Float16Type, Int64Type>(array, cast_options),
1647        (Float16, Float32) => cast_numeric_arrays::<Float16Type, Float32Type>(array, cast_options),
1648        (Float16, Float64) => cast_numeric_arrays::<Float16Type, Float64Type>(array, cast_options),
1649
1650        (Float32, UInt8) => cast_numeric_arrays::<Float32Type, UInt8Type>(array, cast_options),
1651        (Float32, UInt16) => cast_numeric_arrays::<Float32Type, UInt16Type>(array, cast_options),
1652        (Float32, UInt32) => cast_numeric_arrays::<Float32Type, UInt32Type>(array, cast_options),
1653        (Float32, UInt64) => cast_numeric_arrays::<Float32Type, UInt64Type>(array, cast_options),
1654        (Float32, Int8) => cast_numeric_arrays::<Float32Type, Int8Type>(array, cast_options),
1655        (Float32, Int16) => cast_numeric_arrays::<Float32Type, Int16Type>(array, cast_options),
1656        (Float32, Int32) => cast_numeric_arrays::<Float32Type, Int32Type>(array, cast_options),
1657        (Float32, Int64) => cast_numeric_arrays::<Float32Type, Int64Type>(array, cast_options),
1658        (Float32, Float16) => cast_numeric_arrays::<Float32Type, Float16Type>(array, cast_options),
1659        (Float32, Float64) => cast_numeric_arrays::<Float32Type, Float64Type>(array, cast_options),
1660
1661        (Float64, UInt8) => cast_numeric_arrays::<Float64Type, UInt8Type>(array, cast_options),
1662        (Float64, UInt16) => cast_numeric_arrays::<Float64Type, UInt16Type>(array, cast_options),
1663        (Float64, UInt32) => cast_numeric_arrays::<Float64Type, UInt32Type>(array, cast_options),
1664        (Float64, UInt64) => cast_numeric_arrays::<Float64Type, UInt64Type>(array, cast_options),
1665        (Float64, Int8) => cast_numeric_arrays::<Float64Type, Int8Type>(array, cast_options),
1666        (Float64, Int16) => cast_numeric_arrays::<Float64Type, Int16Type>(array, cast_options),
1667        (Float64, Int32) => cast_numeric_arrays::<Float64Type, Int32Type>(array, cast_options),
1668        (Float64, Int64) => cast_numeric_arrays::<Float64Type, Int64Type>(array, cast_options),
1669        (Float64, Float16) => cast_numeric_arrays::<Float64Type, Float16Type>(array, cast_options),
1670        (Float64, Float32) => cast_numeric_arrays::<Float64Type, Float32Type>(array, cast_options),
1671        // end numeric casts
1672
1673        // temporal casts
1674        (Int32, Date32) => cast_reinterpret_arrays::<Int32Type, Date32Type>(array),
1675        (Int32, Date64) => cast_with_options(
1676            &cast_with_options(array, &Date32, cast_options)?,
1677            &Date64,
1678            cast_options,
1679        ),
1680        (Int32, Time32(TimeUnit::Second)) => {
1681            cast_reinterpret_arrays::<Int32Type, Time32SecondType>(array)
1682        }
1683        (Int32, Time32(TimeUnit::Millisecond)) => {
1684            cast_reinterpret_arrays::<Int32Type, Time32MillisecondType>(array)
1685        }
1686        // No support for microsecond/nanosecond with i32
1687        (Date32, Int32) => cast_reinterpret_arrays::<Date32Type, Int32Type>(array),
1688        (Date32, Int64) => cast_with_options(
1689            &cast_with_options(array, &Int32, cast_options)?,
1690            &Int64,
1691            cast_options,
1692        ),
1693        (Time32(TimeUnit::Second), Int32) => {
1694            cast_reinterpret_arrays::<Time32SecondType, Int32Type>(array)
1695        }
1696        (Time32(TimeUnit::Millisecond), Int32) => {
1697            cast_reinterpret_arrays::<Time32MillisecondType, Int32Type>(array)
1698        }
1699        (Time32(TimeUnit::Second), Int64) => cast_with_options(
1700            &cast_with_options(array, &Int32, cast_options)?,
1701            &Int64,
1702            cast_options,
1703        ),
1704        (Time32(TimeUnit::Millisecond), Int64) => cast_with_options(
1705            &cast_with_options(array, &Int32, cast_options)?,
1706            &Int64,
1707            cast_options,
1708        ),
1709        (Int64, Date64) => cast_reinterpret_arrays::<Int64Type, Date64Type>(array),
1710        (Int64, Date32) => cast_with_options(
1711            &cast_with_options(array, &Int32, cast_options)?,
1712            &Date32,
1713            cast_options,
1714        ),
1715        // No support for second/milliseconds with i64
1716        (Int64, Time64(TimeUnit::Microsecond)) => {
1717            cast_reinterpret_arrays::<Int64Type, Time64MicrosecondType>(array)
1718        }
1719        (Int64, Time64(TimeUnit::Nanosecond)) => {
1720            cast_reinterpret_arrays::<Int64Type, Time64NanosecondType>(array)
1721        }
1722
1723        (Date64, Int64) => cast_reinterpret_arrays::<Date64Type, Int64Type>(array),
1724        (Date64, Int32) => cast_with_options(
1725            &cast_with_options(array, &Int64, cast_options)?,
1726            &Int32,
1727            cast_options,
1728        ),
1729        (Time64(TimeUnit::Microsecond), Int64) => {
1730            cast_reinterpret_arrays::<Time64MicrosecondType, Int64Type>(array)
1731        }
1732        (Time64(TimeUnit::Nanosecond), Int64) => {
1733            cast_reinterpret_arrays::<Time64NanosecondType, Int64Type>(array)
1734        }
1735        (Date32, Date64) => Ok(Arc::new(
1736            array
1737                .as_primitive::<Date32Type>()
1738                .unary::<_, Date64Type>(|x| x as i64 * MILLISECONDS_IN_DAY),
1739        )),
1740        (Date64, Date32) => Ok(Arc::new(
1741            array
1742                .as_primitive::<Date64Type>()
1743                .unary::<_, Date32Type>(|x| (x / MILLISECONDS_IN_DAY) as i32),
1744        )),
1745
1746        (Time32(TimeUnit::Second), Time32(TimeUnit::Millisecond)) => Ok(Arc::new(
1747            array
1748                .as_primitive::<Time32SecondType>()
1749                .unary::<_, Time32MillisecondType>(|x| x * MILLISECONDS as i32),
1750        )),
1751        (Time32(TimeUnit::Second), Time64(TimeUnit::Microsecond)) => Ok(Arc::new(
1752            array
1753                .as_primitive::<Time32SecondType>()
1754                .unary::<_, Time64MicrosecondType>(|x| x as i64 * MICROSECONDS),
1755        )),
1756        (Time32(TimeUnit::Second), Time64(TimeUnit::Nanosecond)) => Ok(Arc::new(
1757            array
1758                .as_primitive::<Time32SecondType>()
1759                .unary::<_, Time64NanosecondType>(|x| x as i64 * NANOSECONDS),
1760        )),
1761
1762        (Time32(TimeUnit::Millisecond), Time32(TimeUnit::Second)) => Ok(Arc::new(
1763            array
1764                .as_primitive::<Time32MillisecondType>()
1765                .unary::<_, Time32SecondType>(|x| x / MILLISECONDS as i32),
1766        )),
1767        (Time32(TimeUnit::Millisecond), Time64(TimeUnit::Microsecond)) => Ok(Arc::new(
1768            array
1769                .as_primitive::<Time32MillisecondType>()
1770                .unary::<_, Time64MicrosecondType>(|x| x as i64 * (MICROSECONDS / MILLISECONDS)),
1771        )),
1772        (Time32(TimeUnit::Millisecond), Time64(TimeUnit::Nanosecond)) => Ok(Arc::new(
1773            array
1774                .as_primitive::<Time32MillisecondType>()
1775                .unary::<_, Time64NanosecondType>(|x| x as i64 * (MICROSECONDS / NANOSECONDS)),
1776        )),
1777
1778        (Time64(TimeUnit::Microsecond), Time32(TimeUnit::Second)) => Ok(Arc::new(
1779            array
1780                .as_primitive::<Time64MicrosecondType>()
1781                .unary::<_, Time32SecondType>(|x| (x / MICROSECONDS) as i32),
1782        )),
1783        (Time64(TimeUnit::Microsecond), Time32(TimeUnit::Millisecond)) => Ok(Arc::new(
1784            array
1785                .as_primitive::<Time64MicrosecondType>()
1786                .unary::<_, Time32MillisecondType>(|x| (x / (MICROSECONDS / MILLISECONDS)) as i32),
1787        )),
1788        (Time64(TimeUnit::Microsecond), Time64(TimeUnit::Nanosecond)) => Ok(Arc::new(
1789            array
1790                .as_primitive::<Time64MicrosecondType>()
1791                .unary::<_, Time64NanosecondType>(|x| x * (NANOSECONDS / MICROSECONDS)),
1792        )),
1793
1794        (Time64(TimeUnit::Nanosecond), Time32(TimeUnit::Second)) => Ok(Arc::new(
1795            array
1796                .as_primitive::<Time64NanosecondType>()
1797                .unary::<_, Time32SecondType>(|x| (x / NANOSECONDS) as i32),
1798        )),
1799        (Time64(TimeUnit::Nanosecond), Time32(TimeUnit::Millisecond)) => Ok(Arc::new(
1800            array
1801                .as_primitive::<Time64NanosecondType>()
1802                .unary::<_, Time32MillisecondType>(|x| (x / (NANOSECONDS / MILLISECONDS)) as i32),
1803        )),
1804        (Time64(TimeUnit::Nanosecond), Time64(TimeUnit::Microsecond)) => Ok(Arc::new(
1805            array
1806                .as_primitive::<Time64NanosecondType>()
1807                .unary::<_, Time64MicrosecondType>(|x| x / (NANOSECONDS / MICROSECONDS)),
1808        )),
1809
1810        // Timestamp to integer/floating/decimals
1811        (Timestamp(TimeUnit::Second, _), _) if to_type.is_numeric() => {
1812            let array = cast_reinterpret_arrays::<TimestampSecondType, Int64Type>(array)?;
1813            cast_with_options(&array, to_type, cast_options)
1814        }
1815        (Timestamp(TimeUnit::Millisecond, _), _) if to_type.is_numeric() => {
1816            let array = cast_reinterpret_arrays::<TimestampMillisecondType, Int64Type>(array)?;
1817            cast_with_options(&array, to_type, cast_options)
1818        }
1819        (Timestamp(TimeUnit::Microsecond, _), _) if to_type.is_numeric() => {
1820            let array = cast_reinterpret_arrays::<TimestampMicrosecondType, Int64Type>(array)?;
1821            cast_with_options(&array, to_type, cast_options)
1822        }
1823        (Timestamp(TimeUnit::Nanosecond, _), _) if to_type.is_numeric() => {
1824            let array = cast_reinterpret_arrays::<TimestampNanosecondType, Int64Type>(array)?;
1825            cast_with_options(&array, to_type, cast_options)
1826        }
1827
1828        (_, Timestamp(unit, tz)) if from_type.is_numeric() => {
1829            let array = cast_with_options(array, &Int64, cast_options)?;
1830            Ok(make_timestamp_array(
1831                array.as_primitive(),
1832                *unit,
1833                tz.clone(),
1834            ))
1835        }
1836
1837        (Timestamp(from_unit, from_tz), Timestamp(to_unit, to_tz)) => {
1838            let array = cast_with_options(array, &Int64, cast_options)?;
1839            let time_array = array.as_primitive::<Int64Type>();
1840            let from_size = time_unit_multiple(from_unit);
1841            let to_size = time_unit_multiple(to_unit);
1842            // we either divide or multiply, depending on size of each unit
1843            // units are never the same when the types are the same
1844            let converted = match from_size.cmp(&to_size) {
1845                Ordering::Greater => {
1846                    let divisor = from_size / to_size;
1847                    time_array.unary::<_, Int64Type>(|o| o / divisor)
1848                }
1849                Ordering::Equal => time_array.clone(),
1850                Ordering::Less => {
1851                    let mul = to_size / from_size;
1852                    if cast_options.safe {
1853                        time_array.unary_opt::<_, Int64Type>(|o| o.checked_mul(mul))
1854                    } else {
1855                        time_array.try_unary::<_, Int64Type, _>(|o| o.mul_checked(mul))?
1856                    }
1857                }
1858            };
1859            // Normalize timezone
1860            let adjusted = match (from_tz, to_tz) {
1861                // Only this case needs to be adjusted because we're casting from
1862                // unknown time offset to some time offset, we want the time to be
1863                // unchanged.
1864                //
1865                // i.e. Timestamp('2001-01-01T00:00', None) -> Timestamp('2001-01-01T00:00', '+0700')
1866                (None, Some(to_tz)) => {
1867                    let to_tz: Tz = to_tz.parse()?;
1868                    match to_unit {
1869                        TimeUnit::Second => adjust_timestamp_to_timezone::<TimestampSecondType>(
1870                            converted,
1871                            &to_tz,
1872                            cast_options,
1873                        )?,
1874                        TimeUnit::Millisecond => adjust_timestamp_to_timezone::<
1875                            TimestampMillisecondType,
1876                        >(
1877                            converted, &to_tz, cast_options
1878                        )?,
1879                        TimeUnit::Microsecond => adjust_timestamp_to_timezone::<
1880                            TimestampMicrosecondType,
1881                        >(
1882                            converted, &to_tz, cast_options
1883                        )?,
1884                        TimeUnit::Nanosecond => adjust_timestamp_to_timezone::<
1885                            TimestampNanosecondType,
1886                        >(
1887                            converted, &to_tz, cast_options
1888                        )?,
1889                    }
1890                }
1891                _ => converted,
1892            };
1893            Ok(make_timestamp_array(&adjusted, *to_unit, to_tz.clone()))
1894        }
1895        (Timestamp(TimeUnit::Microsecond, _), Date32) => {
1896            timestamp_to_date32(array.as_primitive::<TimestampMicrosecondType>())
1897        }
1898        (Timestamp(TimeUnit::Millisecond, _), Date32) => {
1899            timestamp_to_date32(array.as_primitive::<TimestampMillisecondType>())
1900        }
1901        (Timestamp(TimeUnit::Second, _), Date32) => {
1902            timestamp_to_date32(array.as_primitive::<TimestampSecondType>())
1903        }
1904        (Timestamp(TimeUnit::Nanosecond, _), Date32) => {
1905            timestamp_to_date32(array.as_primitive::<TimestampNanosecondType>())
1906        }
1907        (Timestamp(TimeUnit::Second, _), Date64) => Ok(Arc::new(match cast_options.safe {
1908            true => {
1909                // change error to None
1910                array
1911                    .as_primitive::<TimestampSecondType>()
1912                    .unary_opt::<_, Date64Type>(|x| x.checked_mul(MILLISECONDS))
1913            }
1914            false => array
1915                .as_primitive::<TimestampSecondType>()
1916                .try_unary::<_, Date64Type, _>(|x| x.mul_checked(MILLISECONDS))?,
1917        })),
1918        (Timestamp(TimeUnit::Millisecond, _), Date64) => {
1919            cast_reinterpret_arrays::<TimestampMillisecondType, Date64Type>(array)
1920        }
1921        (Timestamp(TimeUnit::Microsecond, _), Date64) => Ok(Arc::new(
1922            array
1923                .as_primitive::<TimestampMicrosecondType>()
1924                .unary::<_, Date64Type>(|x| x / (MICROSECONDS / MILLISECONDS)),
1925        )),
1926        (Timestamp(TimeUnit::Nanosecond, _), Date64) => Ok(Arc::new(
1927            array
1928                .as_primitive::<TimestampNanosecondType>()
1929                .unary::<_, Date64Type>(|x| x / (NANOSECONDS / MILLISECONDS)),
1930        )),
1931        (Timestamp(TimeUnit::Second, tz), Time64(TimeUnit::Microsecond)) => {
1932            let tz = tz.as_ref().map(|tz| tz.parse()).transpose()?;
1933            Ok(Arc::new(
1934                array
1935                    .as_primitive::<TimestampSecondType>()
1936                    .try_unary::<_, Time64MicrosecondType, ArrowError>(|x| {
1937                        Ok(time_to_time64us(as_time_res_with_timezone::<
1938                            TimestampSecondType,
1939                        >(x, tz)?))
1940                    })?,
1941            ))
1942        }
1943        (Timestamp(TimeUnit::Second, tz), Time64(TimeUnit::Nanosecond)) => {
1944            let tz = tz.as_ref().map(|tz| tz.parse()).transpose()?;
1945            Ok(Arc::new(
1946                array
1947                    .as_primitive::<TimestampSecondType>()
1948                    .try_unary::<_, Time64NanosecondType, ArrowError>(|x| {
1949                        Ok(time_to_time64ns(as_time_res_with_timezone::<
1950                            TimestampSecondType,
1951                        >(x, tz)?))
1952                    })?,
1953            ))
1954        }
1955        (Timestamp(TimeUnit::Millisecond, tz), Time64(TimeUnit::Microsecond)) => {
1956            let tz = tz.as_ref().map(|tz| tz.parse()).transpose()?;
1957            Ok(Arc::new(
1958                array
1959                    .as_primitive::<TimestampMillisecondType>()
1960                    .try_unary::<_, Time64MicrosecondType, ArrowError>(|x| {
1961                        Ok(time_to_time64us(as_time_res_with_timezone::<
1962                            TimestampMillisecondType,
1963                        >(x, tz)?))
1964                    })?,
1965            ))
1966        }
1967        (Timestamp(TimeUnit::Millisecond, tz), Time64(TimeUnit::Nanosecond)) => {
1968            let tz = tz.as_ref().map(|tz| tz.parse()).transpose()?;
1969            Ok(Arc::new(
1970                array
1971                    .as_primitive::<TimestampMillisecondType>()
1972                    .try_unary::<_, Time64NanosecondType, ArrowError>(|x| {
1973                        Ok(time_to_time64ns(as_time_res_with_timezone::<
1974                            TimestampMillisecondType,
1975                        >(x, tz)?))
1976                    })?,
1977            ))
1978        }
1979        (Timestamp(TimeUnit::Microsecond, tz), Time64(TimeUnit::Microsecond)) => {
1980            let tz = tz.as_ref().map(|tz| tz.parse()).transpose()?;
1981            Ok(Arc::new(
1982                array
1983                    .as_primitive::<TimestampMicrosecondType>()
1984                    .try_unary::<_, Time64MicrosecondType, ArrowError>(|x| {
1985                        Ok(time_to_time64us(as_time_res_with_timezone::<
1986                            TimestampMicrosecondType,
1987                        >(x, tz)?))
1988                    })?,
1989            ))
1990        }
1991        (Timestamp(TimeUnit::Microsecond, tz), Time64(TimeUnit::Nanosecond)) => {
1992            let tz = tz.as_ref().map(|tz| tz.parse()).transpose()?;
1993            Ok(Arc::new(
1994                array
1995                    .as_primitive::<TimestampMicrosecondType>()
1996                    .try_unary::<_, Time64NanosecondType, ArrowError>(|x| {
1997                        Ok(time_to_time64ns(as_time_res_with_timezone::<
1998                            TimestampMicrosecondType,
1999                        >(x, tz)?))
2000                    })?,
2001            ))
2002        }
2003        (Timestamp(TimeUnit::Nanosecond, tz), Time64(TimeUnit::Microsecond)) => {
2004            let tz = tz.as_ref().map(|tz| tz.parse()).transpose()?;
2005            Ok(Arc::new(
2006                array
2007                    .as_primitive::<TimestampNanosecondType>()
2008                    .try_unary::<_, Time64MicrosecondType, ArrowError>(|x| {
2009                        Ok(time_to_time64us(as_time_res_with_timezone::<
2010                            TimestampNanosecondType,
2011                        >(x, tz)?))
2012                    })?,
2013            ))
2014        }
2015        (Timestamp(TimeUnit::Nanosecond, tz), Time64(TimeUnit::Nanosecond)) => {
2016            let tz = tz.as_ref().map(|tz| tz.parse()).transpose()?;
2017            Ok(Arc::new(
2018                array
2019                    .as_primitive::<TimestampNanosecondType>()
2020                    .try_unary::<_, Time64NanosecondType, ArrowError>(|x| {
2021                        Ok(time_to_time64ns(as_time_res_with_timezone::<
2022                            TimestampNanosecondType,
2023                        >(x, tz)?))
2024                    })?,
2025            ))
2026        }
2027        (Timestamp(TimeUnit::Second, tz), Time32(TimeUnit::Second)) => {
2028            let tz = tz.as_ref().map(|tz| tz.parse()).transpose()?;
2029            Ok(Arc::new(
2030                array
2031                    .as_primitive::<TimestampSecondType>()
2032                    .try_unary::<_, Time32SecondType, ArrowError>(|x| {
2033                        Ok(time_to_time32s(as_time_res_with_timezone::<
2034                            TimestampSecondType,
2035                        >(x, tz)?))
2036                    })?,
2037            ))
2038        }
2039        (Timestamp(TimeUnit::Second, tz), Time32(TimeUnit::Millisecond)) => {
2040            let tz = tz.as_ref().map(|tz| tz.parse()).transpose()?;
2041            Ok(Arc::new(
2042                array
2043                    .as_primitive::<TimestampSecondType>()
2044                    .try_unary::<_, Time32MillisecondType, ArrowError>(|x| {
2045                        Ok(time_to_time32ms(as_time_res_with_timezone::<
2046                            TimestampSecondType,
2047                        >(x, tz)?))
2048                    })?,
2049            ))
2050        }
2051        (Timestamp(TimeUnit::Millisecond, tz), Time32(TimeUnit::Second)) => {
2052            let tz = tz.as_ref().map(|tz| tz.parse()).transpose()?;
2053            Ok(Arc::new(
2054                array
2055                    .as_primitive::<TimestampMillisecondType>()
2056                    .try_unary::<_, Time32SecondType, ArrowError>(|x| {
2057                        Ok(time_to_time32s(as_time_res_with_timezone::<
2058                            TimestampMillisecondType,
2059                        >(x, tz)?))
2060                    })?,
2061            ))
2062        }
2063        (Timestamp(TimeUnit::Millisecond, tz), Time32(TimeUnit::Millisecond)) => {
2064            let tz = tz.as_ref().map(|tz| tz.parse()).transpose()?;
2065            Ok(Arc::new(
2066                array
2067                    .as_primitive::<TimestampMillisecondType>()
2068                    .try_unary::<_, Time32MillisecondType, ArrowError>(|x| {
2069                        Ok(time_to_time32ms(as_time_res_with_timezone::<
2070                            TimestampMillisecondType,
2071                        >(x, tz)?))
2072                    })?,
2073            ))
2074        }
2075        (Timestamp(TimeUnit::Microsecond, tz), Time32(TimeUnit::Second)) => {
2076            let tz = tz.as_ref().map(|tz| tz.parse()).transpose()?;
2077            Ok(Arc::new(
2078                array
2079                    .as_primitive::<TimestampMicrosecondType>()
2080                    .try_unary::<_, Time32SecondType, ArrowError>(|x| {
2081                        Ok(time_to_time32s(as_time_res_with_timezone::<
2082                            TimestampMicrosecondType,
2083                        >(x, tz)?))
2084                    })?,
2085            ))
2086        }
2087        (Timestamp(TimeUnit::Microsecond, tz), Time32(TimeUnit::Millisecond)) => {
2088            let tz = tz.as_ref().map(|tz| tz.parse()).transpose()?;
2089            Ok(Arc::new(
2090                array
2091                    .as_primitive::<TimestampMicrosecondType>()
2092                    .try_unary::<_, Time32MillisecondType, ArrowError>(|x| {
2093                        Ok(time_to_time32ms(as_time_res_with_timezone::<
2094                            TimestampMicrosecondType,
2095                        >(x, tz)?))
2096                    })?,
2097            ))
2098        }
2099        (Timestamp(TimeUnit::Nanosecond, tz), Time32(TimeUnit::Second)) => {
2100            let tz = tz.as_ref().map(|tz| tz.parse()).transpose()?;
2101            Ok(Arc::new(
2102                array
2103                    .as_primitive::<TimestampNanosecondType>()
2104                    .try_unary::<_, Time32SecondType, ArrowError>(|x| {
2105                        Ok(time_to_time32s(as_time_res_with_timezone::<
2106                            TimestampNanosecondType,
2107                        >(x, tz)?))
2108                    })?,
2109            ))
2110        }
2111        (Timestamp(TimeUnit::Nanosecond, tz), Time32(TimeUnit::Millisecond)) => {
2112            let tz = tz.as_ref().map(|tz| tz.parse()).transpose()?;
2113            Ok(Arc::new(
2114                array
2115                    .as_primitive::<TimestampNanosecondType>()
2116                    .try_unary::<_, Time32MillisecondType, ArrowError>(|x| {
2117                        Ok(time_to_time32ms(as_time_res_with_timezone::<
2118                            TimestampNanosecondType,
2119                        >(x, tz)?))
2120                    })?,
2121            ))
2122        }
2123        (Date64, Timestamp(TimeUnit::Second, _)) => {
2124            let array = array
2125                .as_primitive::<Date64Type>()
2126                .unary::<_, TimestampSecondType>(|x| x / MILLISECONDS);
2127
2128            cast_with_options(&array, to_type, cast_options)
2129        }
2130        (Date64, Timestamp(TimeUnit::Millisecond, _)) => {
2131            let array = array
2132                .as_primitive::<Date64Type>()
2133                .reinterpret_cast::<TimestampMillisecondType>();
2134
2135            cast_with_options(&array, to_type, cast_options)
2136        }
2137
2138        (Date64, Timestamp(TimeUnit::Microsecond, _)) => {
2139            let array = array
2140                .as_primitive::<Date64Type>()
2141                .unary::<_, TimestampMicrosecondType>(|x| x * (MICROSECONDS / MILLISECONDS));
2142
2143            cast_with_options(&array, to_type, cast_options)
2144        }
2145        (Date64, Timestamp(TimeUnit::Nanosecond, _)) => {
2146            let array = array
2147                .as_primitive::<Date64Type>()
2148                .unary::<_, TimestampNanosecondType>(|x| x * (NANOSECONDS / MILLISECONDS));
2149
2150            cast_with_options(&array, to_type, cast_options)
2151        }
2152        (Date32, Timestamp(TimeUnit::Second, _)) => {
2153            let array = array
2154                .as_primitive::<Date32Type>()
2155                .unary::<_, TimestampSecondType>(|x| (x as i64) * SECONDS_IN_DAY);
2156
2157            cast_with_options(&array, to_type, cast_options)
2158        }
2159        (Date32, Timestamp(TimeUnit::Millisecond, _)) => {
2160            let array = array
2161                .as_primitive::<Date32Type>()
2162                .unary::<_, TimestampMillisecondType>(|x| (x as i64) * MILLISECONDS_IN_DAY);
2163
2164            cast_with_options(&array, to_type, cast_options)
2165        }
2166        (Date32, Timestamp(TimeUnit::Microsecond, _)) => {
2167            let array = array
2168                .as_primitive::<Date32Type>()
2169                .unary::<_, TimestampMicrosecondType>(|x| (x as i64) * MICROSECONDS_IN_DAY);
2170
2171            cast_with_options(&array, to_type, cast_options)
2172        }
2173        (Date32, Timestamp(TimeUnit::Nanosecond, _)) => {
2174            let array = array
2175                .as_primitive::<Date32Type>()
2176                .unary::<_, TimestampNanosecondType>(|x| (x as i64) * NANOSECONDS_IN_DAY);
2177
2178            cast_with_options(&array, to_type, cast_options)
2179        }
2180
2181        (_, Duration(unit)) if from_type.is_numeric() => {
2182            let array = cast_with_options(array, &Int64, cast_options)?;
2183            Ok(make_duration_array(array.as_primitive(), *unit))
2184        }
2185        (Duration(TimeUnit::Second), _) if to_type.is_numeric() => {
2186            let array = cast_reinterpret_arrays::<DurationSecondType, Int64Type>(array)?;
2187            cast_with_options(&array, to_type, cast_options)
2188        }
2189        (Duration(TimeUnit::Millisecond), _) if to_type.is_numeric() => {
2190            let array = cast_reinterpret_arrays::<DurationMillisecondType, Int64Type>(array)?;
2191            cast_with_options(&array, to_type, cast_options)
2192        }
2193        (Duration(TimeUnit::Microsecond), _) if to_type.is_numeric() => {
2194            let array = cast_reinterpret_arrays::<DurationMicrosecondType, Int64Type>(array)?;
2195            cast_with_options(&array, to_type, cast_options)
2196        }
2197        (Duration(TimeUnit::Nanosecond), _) if to_type.is_numeric() => {
2198            let array = cast_reinterpret_arrays::<DurationNanosecondType, Int64Type>(array)?;
2199            cast_with_options(&array, to_type, cast_options)
2200        }
2201
2202        (Duration(from_unit), Duration(to_unit)) => {
2203            let array = cast_with_options(array, &Int64, cast_options)?;
2204            let time_array = array.as_primitive::<Int64Type>();
2205            let from_size = time_unit_multiple(from_unit);
2206            let to_size = time_unit_multiple(to_unit);
2207            // we either divide or multiply, depending on size of each unit
2208            // units are never the same when the types are the same
2209            let converted = match from_size.cmp(&to_size) {
2210                Ordering::Greater => {
2211                    let divisor = from_size / to_size;
2212                    time_array.unary::<_, Int64Type>(|o| o / divisor)
2213                }
2214                Ordering::Equal => time_array.clone(),
2215                Ordering::Less => {
2216                    let mul = to_size / from_size;
2217                    if cast_options.safe {
2218                        time_array.unary_opt::<_, Int64Type>(|o| o.checked_mul(mul))
2219                    } else {
2220                        time_array.try_unary::<_, Int64Type, _>(|o| o.mul_checked(mul))?
2221                    }
2222                }
2223            };
2224            Ok(make_duration_array(&converted, *to_unit))
2225        }
2226
2227        (Duration(TimeUnit::Second), Interval(IntervalUnit::MonthDayNano)) => {
2228            cast_duration_to_interval::<DurationSecondType>(array, cast_options)
2229        }
2230        (Duration(TimeUnit::Millisecond), Interval(IntervalUnit::MonthDayNano)) => {
2231            cast_duration_to_interval::<DurationMillisecondType>(array, cast_options)
2232        }
2233        (Duration(TimeUnit::Microsecond), Interval(IntervalUnit::MonthDayNano)) => {
2234            cast_duration_to_interval::<DurationMicrosecondType>(array, cast_options)
2235        }
2236        (Duration(TimeUnit::Nanosecond), Interval(IntervalUnit::MonthDayNano)) => {
2237            cast_duration_to_interval::<DurationNanosecondType>(array, cast_options)
2238        }
2239        (Interval(IntervalUnit::MonthDayNano), Duration(TimeUnit::Second)) => {
2240            cast_month_day_nano_to_duration::<DurationSecondType>(array, cast_options)
2241        }
2242        (Interval(IntervalUnit::MonthDayNano), Duration(TimeUnit::Millisecond)) => {
2243            cast_month_day_nano_to_duration::<DurationMillisecondType>(array, cast_options)
2244        }
2245        (Interval(IntervalUnit::MonthDayNano), Duration(TimeUnit::Microsecond)) => {
2246            cast_month_day_nano_to_duration::<DurationMicrosecondType>(array, cast_options)
2247        }
2248        (Interval(IntervalUnit::MonthDayNano), Duration(TimeUnit::Nanosecond)) => {
2249            cast_month_day_nano_to_duration::<DurationNanosecondType>(array, cast_options)
2250        }
2251        (Interval(IntervalUnit::YearMonth), Interval(IntervalUnit::MonthDayNano)) => {
2252            cast_interval_year_month_to_interval_month_day_nano(array, cast_options)
2253        }
2254        (Interval(IntervalUnit::DayTime), Interval(IntervalUnit::MonthDayNano)) => {
2255            cast_interval_day_time_to_interval_month_day_nano(array, cast_options)
2256        }
2257        (Int32, Interval(IntervalUnit::YearMonth)) => {
2258            cast_reinterpret_arrays::<Int32Type, IntervalYearMonthType>(array)
2259        }
2260        (_, _) => Err(ArrowError::CastError(format!(
2261            "Casting from {from_type} to {to_type} not supported",
2262        ))),
2263    }
2264}
2265
2266fn cast_struct_to_struct(
2267    array: &StructArray,
2268    from_fields: Fields,
2269    to_fields: Fields,
2270    cast_options: &CastOptions,
2271) -> Result<ArrayRef, ArrowError> {
2272    // Fast path: if field names are in the same order, we can just zip and cast
2273    let fields_match_order = from_fields.len() == to_fields.len()
2274        && from_fields
2275            .iter()
2276            .zip(to_fields.iter())
2277            .all(|(f1, f2)| f1.name() == f2.name());
2278
2279    let fields = if fields_match_order {
2280        // Fast path: cast columns in order if their names match
2281        cast_struct_fields_in_order(array, to_fields.clone(), cast_options)?
2282    } else {
2283        let all_fields_match_by_name = to_fields.iter().all(|to_field| {
2284            from_fields
2285                .iter()
2286                .any(|from_field| from_field.name() == to_field.name())
2287        });
2288
2289        if all_fields_match_by_name {
2290            // Slow path: match fields by name and reorder
2291            cast_struct_fields_by_name(array, from_fields.clone(), to_fields.clone(), cast_options)?
2292        } else {
2293            // Fallback: cast field by field in order
2294            cast_struct_fields_in_order(array, to_fields.clone(), cast_options)?
2295        }
2296    };
2297
2298    let array = StructArray::try_new(to_fields.clone(), fields, array.nulls().cloned())?;
2299    Ok(Arc::new(array) as ArrayRef)
2300}
2301
2302fn cast_struct_fields_by_name(
2303    array: &StructArray,
2304    from_fields: Fields,
2305    to_fields: Fields,
2306    cast_options: &CastOptions,
2307) -> Result<Vec<ArrayRef>, ArrowError> {
2308    to_fields
2309        .iter()
2310        .map(|to_field| {
2311            let from_field_idx = from_fields
2312                .iter()
2313                .position(|from_field| from_field.name() == to_field.name())
2314                .unwrap(); // safe because we checked above
2315            let column = array.column(from_field_idx);
2316            cast_with_options(column, to_field.data_type(), cast_options)
2317        })
2318        .collect::<Result<Vec<ArrayRef>, ArrowError>>()
2319}
2320
2321fn cast_struct_fields_in_order(
2322    array: &StructArray,
2323    to_fields: Fields,
2324    cast_options: &CastOptions,
2325) -> Result<Vec<ArrayRef>, ArrowError> {
2326    array
2327        .columns()
2328        .iter()
2329        .zip(to_fields.iter())
2330        .map(|(l, field)| cast_with_options(l, field.data_type(), cast_options))
2331        .collect::<Result<Vec<ArrayRef>, ArrowError>>()
2332}
2333
2334fn cast_from_decimal<D, F>(
2335    array: &dyn Array,
2336    base: D::Native,
2337    scale: &i8,
2338    from_type: &DataType,
2339    to_type: &DataType,
2340    as_float: F,
2341    cast_options: &CastOptions,
2342) -> Result<ArrayRef, ArrowError>
2343where
2344    D: DecimalType + ArrowPrimitiveType,
2345    <D as ArrowPrimitiveType>::Native: ArrowNativeTypeOp + ToPrimitive,
2346    F: Fn(D::Native) -> f64,
2347{
2348    use DataType::*;
2349    // cast decimal to other type
2350    match to_type {
2351        UInt8 => cast_decimal_to_integer::<D, UInt8Type>(array, base, *scale, cast_options),
2352        UInt16 => cast_decimal_to_integer::<D, UInt16Type>(array, base, *scale, cast_options),
2353        UInt32 => cast_decimal_to_integer::<D, UInt32Type>(array, base, *scale, cast_options),
2354        UInt64 => cast_decimal_to_integer::<D, UInt64Type>(array, base, *scale, cast_options),
2355        Int8 => cast_decimal_to_integer::<D, Int8Type>(array, base, *scale, cast_options),
2356        Int16 => cast_decimal_to_integer::<D, Int16Type>(array, base, *scale, cast_options),
2357        Int32 => cast_decimal_to_integer::<D, Int32Type>(array, base, *scale, cast_options),
2358        Int64 => cast_decimal_to_integer::<D, Int64Type>(array, base, *scale, cast_options),
2359        Float32 => cast_decimal_to_float::<D, Float32Type, _>(array, |x| {
2360            (as_float(x) / 10_f64.powi(*scale as i32)) as f32
2361        }),
2362        Float64 => cast_decimal_to_float::<D, Float64Type, _>(array, |x| {
2363            as_float(x) / 10_f64.powi(*scale as i32)
2364        }),
2365        Utf8View => value_to_string_view(array, cast_options),
2366        Utf8 => value_to_string::<i32>(array, cast_options),
2367        LargeUtf8 => value_to_string::<i64>(array, cast_options),
2368        Null => Ok(new_null_array(to_type, array.len())),
2369        _ => Err(ArrowError::CastError(format!(
2370            "Casting from {from_type} to {to_type} not supported"
2371        ))),
2372    }
2373}
2374
2375fn cast_to_decimal<D, M>(
2376    array: &dyn Array,
2377    base: M,
2378    precision: &u8,
2379    scale: &i8,
2380    from_type: &DataType,
2381    to_type: &DataType,
2382    cast_options: &CastOptions,
2383) -> Result<ArrayRef, ArrowError>
2384where
2385    D: DecimalType + ArrowPrimitiveType<Native = M>,
2386    M: ArrowNativeTypeOp + DecimalCast,
2387    u8: num_traits::AsPrimitive<M>,
2388    u16: num_traits::AsPrimitive<M>,
2389    u32: num_traits::AsPrimitive<M>,
2390    u64: num_traits::AsPrimitive<M>,
2391    i8: num_traits::AsPrimitive<M>,
2392    i16: num_traits::AsPrimitive<M>,
2393    i32: num_traits::AsPrimitive<M>,
2394    i64: num_traits::AsPrimitive<M>,
2395{
2396    use DataType::*;
2397    // cast data to decimal
2398    match from_type {
2399        UInt8 => cast_integer_to_decimal::<_, D, M>(
2400            array.as_primitive::<UInt8Type>(),
2401            *precision,
2402            *scale,
2403            base,
2404            cast_options,
2405        ),
2406        UInt16 => cast_integer_to_decimal::<_, D, _>(
2407            array.as_primitive::<UInt16Type>(),
2408            *precision,
2409            *scale,
2410            base,
2411            cast_options,
2412        ),
2413        UInt32 => cast_integer_to_decimal::<_, D, _>(
2414            array.as_primitive::<UInt32Type>(),
2415            *precision,
2416            *scale,
2417            base,
2418            cast_options,
2419        ),
2420        UInt64 => cast_integer_to_decimal::<_, D, _>(
2421            array.as_primitive::<UInt64Type>(),
2422            *precision,
2423            *scale,
2424            base,
2425            cast_options,
2426        ),
2427        Int8 => cast_integer_to_decimal::<_, D, _>(
2428            array.as_primitive::<Int8Type>(),
2429            *precision,
2430            *scale,
2431            base,
2432            cast_options,
2433        ),
2434        Int16 => cast_integer_to_decimal::<_, D, _>(
2435            array.as_primitive::<Int16Type>(),
2436            *precision,
2437            *scale,
2438            base,
2439            cast_options,
2440        ),
2441        Int32 => cast_integer_to_decimal::<_, D, _>(
2442            array.as_primitive::<Int32Type>(),
2443            *precision,
2444            *scale,
2445            base,
2446            cast_options,
2447        ),
2448        Int64 => cast_integer_to_decimal::<_, D, _>(
2449            array.as_primitive::<Int64Type>(),
2450            *precision,
2451            *scale,
2452            base,
2453            cast_options,
2454        ),
2455        Float32 => cast_floating_point_to_decimal::<_, D>(
2456            array.as_primitive::<Float32Type>(),
2457            *precision,
2458            *scale,
2459            cast_options,
2460        ),
2461        Float64 => cast_floating_point_to_decimal::<_, D>(
2462            array.as_primitive::<Float64Type>(),
2463            *precision,
2464            *scale,
2465            cast_options,
2466        ),
2467        Utf8View | Utf8 => {
2468            cast_string_to_decimal::<D, i32>(array, *precision, *scale, cast_options)
2469        }
2470        LargeUtf8 => cast_string_to_decimal::<D, i64>(array, *precision, *scale, cast_options),
2471        Null => Ok(new_null_array(to_type, array.len())),
2472        _ => Err(ArrowError::CastError(format!(
2473            "Casting from {from_type} to {to_type} not supported"
2474        ))),
2475    }
2476}
2477
2478/// Get the time unit as a multiple of a second
2479const fn time_unit_multiple(unit: &TimeUnit) -> i64 {
2480    match unit {
2481        TimeUnit::Second => 1,
2482        TimeUnit::Millisecond => MILLISECONDS,
2483        TimeUnit::Microsecond => MICROSECONDS,
2484        TimeUnit::Nanosecond => NANOSECONDS,
2485    }
2486}
2487
2488/// Convert Array into a PrimitiveArray of type, and apply numeric cast
2489fn cast_numeric_arrays<FROM, TO>(
2490    from: &dyn Array,
2491    cast_options: &CastOptions,
2492) -> Result<ArrayRef, ArrowError>
2493where
2494    FROM: ArrowPrimitiveType,
2495    TO: ArrowPrimitiveType,
2496    FROM::Native: NumCast,
2497    TO::Native: NumCast,
2498{
2499    if cast_options.safe {
2500        // If the value can't be casted to the `TO::Native`, return null
2501        Ok(Arc::new(numeric_cast::<FROM, TO>(
2502            from.as_primitive::<FROM>(),
2503        )))
2504    } else {
2505        // If the value can't be casted to the `TO::Native`, return error
2506        Ok(Arc::new(try_numeric_cast::<FROM, TO>(
2507            from.as_primitive::<FROM>(),
2508        )?))
2509    }
2510}
2511
2512// Natural cast between numeric types
2513// If the value of T can't be casted to R, will throw error
2514fn try_numeric_cast<T, R>(from: &PrimitiveArray<T>) -> Result<PrimitiveArray<R>, ArrowError>
2515where
2516    T: ArrowPrimitiveType,
2517    R: ArrowPrimitiveType,
2518    T::Native: NumCast,
2519    R::Native: NumCast,
2520{
2521    from.try_unary(|value| {
2522        num_traits::cast::cast::<T::Native, R::Native>(value).ok_or_else(|| {
2523            ArrowError::CastError(format!(
2524                "Can't cast value {:?} to type {}",
2525                value,
2526                R::DATA_TYPE
2527            ))
2528        })
2529    })
2530}
2531
2532// Natural cast between numeric types
2533// If the value of T can't be casted to R, it will be converted to null
2534fn numeric_cast<T, R>(from: &PrimitiveArray<T>) -> PrimitiveArray<R>
2535where
2536    T: ArrowPrimitiveType,
2537    R: ArrowPrimitiveType,
2538    T::Native: NumCast,
2539    R::Native: NumCast,
2540{
2541    from.unary_opt::<_, R>(num_traits::cast::cast::<T::Native, R::Native>)
2542}
2543
2544fn cast_numeric_to_binary<FROM: ArrowPrimitiveType, O: OffsetSizeTrait>(
2545    array: &dyn Array,
2546) -> Result<ArrayRef, ArrowError> {
2547    let array = array.as_primitive::<FROM>();
2548    let size = std::mem::size_of::<FROM::Native>();
2549    let offsets = OffsetBuffer::from_repeated_length(size, array.len());
2550    Ok(Arc::new(GenericBinaryArray::<O>::try_new(
2551        offsets,
2552        array.values().inner().clone(),
2553        array.nulls().cloned(),
2554    )?))
2555}
2556
2557fn adjust_timestamp_to_timezone<T: ArrowTimestampType>(
2558    array: PrimitiveArray<Int64Type>,
2559    to_tz: &Tz,
2560    cast_options: &CastOptions,
2561) -> Result<PrimitiveArray<Int64Type>, ArrowError> {
2562    let adjust = |o| {
2563        let local = as_datetime::<T>(o)?;
2564        let offset = to_tz.offset_from_local_datetime(&local).single()?;
2565        T::make_value(local - offset.fix())
2566    };
2567    let adjusted = if cast_options.safe {
2568        array.unary_opt::<_, Int64Type>(adjust)
2569    } else {
2570        array.try_unary::<_, Int64Type, _>(|o| {
2571            adjust(o).ok_or_else(|| {
2572                ArrowError::CastError("Cannot cast timezone to different timezone".to_string())
2573            })
2574        })?
2575    };
2576    Ok(adjusted)
2577}
2578
2579/// Cast numeric types to Boolean
2580///
2581/// Any zero value returns `false` while non-zero returns `true`
2582fn cast_numeric_to_bool<FROM>(from: &dyn Array) -> Result<ArrayRef, ArrowError>
2583where
2584    FROM: ArrowPrimitiveType,
2585{
2586    numeric_to_bool_cast::<FROM>(from.as_primitive::<FROM>()).map(|to| Arc::new(to) as ArrayRef)
2587}
2588
2589fn numeric_to_bool_cast<T>(from: &PrimitiveArray<T>) -> Result<BooleanArray, ArrowError>
2590where
2591    T: ArrowPrimitiveType + ArrowPrimitiveType,
2592{
2593    let mut b = BooleanBuilder::with_capacity(from.len());
2594
2595    for i in 0..from.len() {
2596        if from.is_null(i) {
2597            b.append_null();
2598        } else if from.value(i) != T::default_value() {
2599            b.append_value(true);
2600        } else {
2601            b.append_value(false);
2602        }
2603    }
2604
2605    Ok(b.finish())
2606}
2607
2608/// Cast Boolean types to numeric
2609///
2610/// `false` returns 0 while `true` returns 1
2611fn cast_bool_to_numeric<TO>(
2612    from: &dyn Array,
2613    cast_options: &CastOptions,
2614) -> Result<ArrayRef, ArrowError>
2615where
2616    TO: ArrowPrimitiveType,
2617    TO::Native: num_traits::cast::NumCast,
2618{
2619    Ok(Arc::new(bool_to_numeric_cast::<TO>(
2620        from.as_any().downcast_ref::<BooleanArray>().unwrap(),
2621        cast_options,
2622    )))
2623}
2624
2625fn bool_to_numeric_cast<T>(from: &BooleanArray, _cast_options: &CastOptions) -> PrimitiveArray<T>
2626where
2627    T: ArrowPrimitiveType,
2628    T::Native: num_traits::NumCast,
2629{
2630    let iter = (0..from.len()).map(|i| {
2631        if from.is_null(i) {
2632            None
2633        } else if from.value(i) {
2634            // a workaround to cast a primitive to T::Native, infallible
2635            num_traits::cast::cast(1)
2636        } else {
2637            Some(T::default_value())
2638        }
2639    });
2640    // Benefit:
2641    //     20% performance improvement
2642    // Soundness:
2643    //     The iterator is trustedLen because it comes from a Range
2644    unsafe { PrimitiveArray::<T>::from_trusted_len_iter(iter) }
2645}
2646
2647/// Helper function to cast from one `BinaryArray` or 'LargeBinaryArray' to 'FixedSizeBinaryArray'.
2648fn cast_binary_to_fixed_size_binary<O: OffsetSizeTrait>(
2649    array: &dyn Array,
2650    byte_width: i32,
2651    cast_options: &CastOptions,
2652) -> Result<ArrayRef, ArrowError> {
2653    let array = array.as_binary::<O>();
2654    let mut builder = FixedSizeBinaryBuilder::with_capacity(array.len(), byte_width);
2655
2656    for i in 0..array.len() {
2657        if array.is_null(i) {
2658            builder.append_null();
2659        } else {
2660            match builder.append_value(array.value(i)) {
2661                Ok(_) => {}
2662                Err(e) => match cast_options.safe {
2663                    true => builder.append_null(),
2664                    false => return Err(e),
2665                },
2666            }
2667        }
2668    }
2669
2670    Ok(Arc::new(builder.finish()))
2671}
2672
2673/// Helper function to cast from 'FixedSizeBinaryArray' to one `BinaryArray` or 'LargeBinaryArray'.
2674/// If the target one is too large for the source array it will return an Error.
2675fn cast_fixed_size_binary_to_binary<O: OffsetSizeTrait>(
2676    array: &dyn Array,
2677    byte_width: i32,
2678) -> Result<ArrayRef, ArrowError> {
2679    let array = array
2680        .as_any()
2681        .downcast_ref::<FixedSizeBinaryArray>()
2682        .unwrap();
2683
2684    let offsets: i128 = byte_width as i128 * array.len() as i128;
2685
2686    let is_binary = matches!(GenericBinaryType::<O>::DATA_TYPE, DataType::Binary);
2687    if is_binary && offsets > i32::MAX as i128 {
2688        return Err(ArrowError::ComputeError(
2689            "FixedSizeBinary array too large to cast to Binary array".to_string(),
2690        ));
2691    } else if !is_binary && offsets > i64::MAX as i128 {
2692        return Err(ArrowError::ComputeError(
2693            "FixedSizeBinary array too large to cast to LargeBinary array".to_string(),
2694        ));
2695    }
2696
2697    let mut builder = GenericBinaryBuilder::<O>::with_capacity(array.len(), array.len());
2698
2699    for i in 0..array.len() {
2700        if array.is_null(i) {
2701            builder.append_null();
2702        } else {
2703            builder.append_value(array.value(i));
2704        }
2705    }
2706
2707    Ok(Arc::new(builder.finish()))
2708}
2709
2710fn cast_fixed_size_binary_to_binary_view(
2711    array: &dyn Array,
2712    _byte_width: i32,
2713) -> Result<ArrayRef, ArrowError> {
2714    let array = array
2715        .as_any()
2716        .downcast_ref::<FixedSizeBinaryArray>()
2717        .unwrap();
2718
2719    let mut builder = BinaryViewBuilder::with_capacity(array.len());
2720    for i in 0..array.len() {
2721        if array.is_null(i) {
2722            builder.append_null();
2723        } else {
2724            builder.append_value(array.value(i));
2725        }
2726    }
2727
2728    Ok(Arc::new(builder.finish()))
2729}
2730
2731/// Helper function to cast from one `ByteArrayType` to another and vice versa.
2732/// If the target one (e.g., `LargeUtf8`) is too large for the source array it will return an Error.
2733fn cast_byte_container<FROM, TO>(array: &dyn Array) -> Result<ArrayRef, ArrowError>
2734where
2735    FROM: ByteArrayType,
2736    TO: ByteArrayType<Native = FROM::Native>,
2737    FROM::Offset: OffsetSizeTrait + ToPrimitive,
2738    TO::Offset: OffsetSizeTrait + NumCast,
2739{
2740    let data = array.to_data();
2741    assert_eq!(data.data_type(), &FROM::DATA_TYPE);
2742    let str_values_buf = data.buffers()[1].clone();
2743    let offsets = data.buffers()[0].typed_data::<FROM::Offset>();
2744
2745    let mut offset_builder = BufferBuilder::<TO::Offset>::new(offsets.len());
2746    offsets
2747        .iter()
2748        .try_for_each::<_, Result<_, ArrowError>>(|offset| {
2749            let offset =
2750                <<TO as ByteArrayType>::Offset as NumCast>::from(*offset).ok_or_else(|| {
2751                    ArrowError::ComputeError(format!(
2752                        "{}{} array too large to cast to {}{} array",
2753                        FROM::Offset::PREFIX,
2754                        FROM::PREFIX,
2755                        TO::Offset::PREFIX,
2756                        TO::PREFIX
2757                    ))
2758                })?;
2759            offset_builder.append(offset);
2760            Ok(())
2761        })?;
2762
2763    let offset_buffer = offset_builder.finish();
2764
2765    let dtype = TO::DATA_TYPE;
2766
2767    let builder = ArrayData::builder(dtype)
2768        .offset(array.offset())
2769        .len(array.len())
2770        .add_buffer(offset_buffer)
2771        .add_buffer(str_values_buf)
2772        .nulls(data.nulls().cloned());
2773
2774    let array_data = unsafe { builder.build_unchecked() };
2775
2776    Ok(Arc::new(GenericByteArray::<TO>::from(array_data)))
2777}
2778
2779/// Helper function to cast from one `ByteViewType` array to `ByteArrayType` array.
2780fn cast_view_to_byte<FROM, TO>(array: &dyn Array) -> Result<ArrayRef, ArrowError>
2781where
2782    FROM: ByteViewType,
2783    TO: ByteArrayType,
2784    FROM::Native: AsRef<TO::Native>,
2785{
2786    let data = array.to_data();
2787    let view_array = GenericByteViewArray::<FROM>::from(data);
2788
2789    let len = view_array.len();
2790    let bytes = view_array
2791        .views()
2792        .iter()
2793        .map(|v| ByteView::from(*v).length as usize)
2794        .sum::<usize>();
2795
2796    let mut byte_array_builder = GenericByteBuilder::<TO>::with_capacity(len, bytes);
2797
2798    for val in view_array.iter() {
2799        byte_array_builder.append_option(val);
2800    }
2801
2802    Ok(Arc::new(byte_array_builder.finish()))
2803}
2804
2805#[cfg(test)]
2806mod tests {
2807    use super::*;
2808    use DataType::*;
2809    use arrow_array::{Int64Array, RunArray, StringArray};
2810    use arrow_buffer::{Buffer, IntervalDayTime, NullBuffer};
2811    use arrow_buffer::{ScalarBuffer, i256};
2812    use arrow_schema::{DataType, Field};
2813    use chrono::NaiveDate;
2814    use half::f16;
2815    use std::sync::Arc;
2816
2817    #[derive(Clone)]
2818    struct DecimalCastTestConfig {
2819        input_prec: u8,
2820        input_scale: i8,
2821        input_repr: i128,
2822        output_prec: u8,
2823        output_scale: i8,
2824        expected_output_repr: Result<i128, String>, // the error variant can contain a string
2825                                                    // template where the "{}" will be
2826                                                    // replaced with the decimal type name
2827                                                    // (e.g. Decimal128)
2828    }
2829
2830    macro_rules! generate_cast_test_case {
2831        ($INPUT_ARRAY: expr, $OUTPUT_TYPE_ARRAY: ident, $OUTPUT_TYPE: expr, $OUTPUT_VALUES: expr) => {
2832            let output =
2833                $OUTPUT_TYPE_ARRAY::from($OUTPUT_VALUES).with_data_type($OUTPUT_TYPE.clone());
2834
2835            // assert cast type
2836            let input_array_type = $INPUT_ARRAY.data_type();
2837            assert!(can_cast_types(input_array_type, $OUTPUT_TYPE));
2838            let result = cast($INPUT_ARRAY, $OUTPUT_TYPE).unwrap();
2839            assert_eq!($OUTPUT_TYPE, result.data_type());
2840            assert_eq!(result.as_ref(), &output);
2841
2842            let cast_option = CastOptions {
2843                safe: false,
2844                format_options: FormatOptions::default(),
2845            };
2846            let result = cast_with_options($INPUT_ARRAY, $OUTPUT_TYPE, &cast_option).unwrap();
2847            assert_eq!($OUTPUT_TYPE, result.data_type());
2848            assert_eq!(result.as_ref(), &output);
2849        };
2850    }
2851
2852    fn run_decimal_cast_test_case<I, O>(t: DecimalCastTestConfig)
2853    where
2854        I: DecimalType,
2855        O: DecimalType,
2856        I::Native: DecimalCast,
2857        O::Native: DecimalCast,
2858    {
2859        let array = vec![I::Native::from_decimal(t.input_repr)];
2860        let array = array
2861            .into_iter()
2862            .collect::<PrimitiveArray<I>>()
2863            .with_precision_and_scale(t.input_prec, t.input_scale)
2864            .unwrap();
2865        let input_type = array.data_type();
2866        let output_type = O::TYPE_CONSTRUCTOR(t.output_prec, t.output_scale);
2867        assert!(can_cast_types(input_type, &output_type));
2868
2869        let options = CastOptions {
2870            safe: false,
2871            ..Default::default()
2872        };
2873        let result = cast_with_options(&array, &output_type, &options);
2874
2875        match t.expected_output_repr {
2876            Ok(v) => {
2877                let expected_array = vec![O::Native::from_decimal(v)];
2878                let expected_array = expected_array
2879                    .into_iter()
2880                    .collect::<PrimitiveArray<O>>()
2881                    .with_precision_and_scale(t.output_prec, t.output_scale)
2882                    .unwrap();
2883                assert_eq!(*result.unwrap(), expected_array);
2884            }
2885            Err(expected_output_message_template) => {
2886                assert!(result.is_err());
2887                let expected_error_message =
2888                    expected_output_message_template.replace("{}", O::PREFIX);
2889                assert_eq!(result.unwrap_err().to_string(), expected_error_message);
2890            }
2891        }
2892    }
2893
2894    fn create_decimal32_array(
2895        array: Vec<Option<i32>>,
2896        precision: u8,
2897        scale: i8,
2898    ) -> Result<Decimal32Array, ArrowError> {
2899        array
2900            .into_iter()
2901            .collect::<Decimal32Array>()
2902            .with_precision_and_scale(precision, scale)
2903    }
2904
2905    fn create_decimal64_array(
2906        array: Vec<Option<i64>>,
2907        precision: u8,
2908        scale: i8,
2909    ) -> Result<Decimal64Array, ArrowError> {
2910        array
2911            .into_iter()
2912            .collect::<Decimal64Array>()
2913            .with_precision_and_scale(precision, scale)
2914    }
2915
2916    fn create_decimal128_array(
2917        array: Vec<Option<i128>>,
2918        precision: u8,
2919        scale: i8,
2920    ) -> Result<Decimal128Array, ArrowError> {
2921        array
2922            .into_iter()
2923            .collect::<Decimal128Array>()
2924            .with_precision_and_scale(precision, scale)
2925    }
2926
2927    fn create_decimal256_array(
2928        array: Vec<Option<i256>>,
2929        precision: u8,
2930        scale: i8,
2931    ) -> Result<Decimal256Array, ArrowError> {
2932        array
2933            .into_iter()
2934            .collect::<Decimal256Array>()
2935            .with_precision_and_scale(precision, scale)
2936    }
2937
2938    #[test]
2939    #[cfg(not(feature = "force_validate"))]
2940    #[should_panic(
2941        expected = "Cannot cast to Decimal128(20, 3). Overflowing on 57896044618658097711785492504343953926634992332820282019728792003956564819967"
2942    )]
2943    fn test_cast_decimal_to_decimal_round_with_error() {
2944        // decimal256 to decimal128 overflow
2945        let array = vec![
2946            Some(i256::from_i128(1123454)),
2947            Some(i256::from_i128(2123456)),
2948            Some(i256::from_i128(-3123453)),
2949            Some(i256::from_i128(-3123456)),
2950            None,
2951            Some(i256::MAX),
2952            Some(i256::MIN),
2953        ];
2954        let input_decimal_array = create_decimal256_array(array, 76, 4).unwrap();
2955        let array = Arc::new(input_decimal_array) as ArrayRef;
2956        let input_type = DataType::Decimal256(76, 4);
2957        let output_type = DataType::Decimal128(20, 3);
2958        assert!(can_cast_types(&input_type, &output_type));
2959        generate_cast_test_case!(
2960            &array,
2961            Decimal128Array,
2962            &output_type,
2963            vec![
2964                Some(112345_i128),
2965                Some(212346_i128),
2966                Some(-312345_i128),
2967                Some(-312346_i128),
2968                None,
2969                None,
2970                None,
2971            ]
2972        );
2973    }
2974
2975    #[test]
2976    #[cfg(not(feature = "force_validate"))]
2977    fn test_cast_decimal_to_decimal_round() {
2978        let array = vec![
2979            Some(1123454),
2980            Some(2123456),
2981            Some(-3123453),
2982            Some(-3123456),
2983            None,
2984        ];
2985        let array = create_decimal128_array(array, 20, 4).unwrap();
2986        // decimal128 to decimal128
2987        let input_type = DataType::Decimal128(20, 4);
2988        let output_type = DataType::Decimal128(20, 3);
2989        assert!(can_cast_types(&input_type, &output_type));
2990        generate_cast_test_case!(
2991            &array,
2992            Decimal128Array,
2993            &output_type,
2994            vec![
2995                Some(112345_i128),
2996                Some(212346_i128),
2997                Some(-312345_i128),
2998                Some(-312346_i128),
2999                None
3000            ]
3001        );
3002
3003        // decimal128 to decimal256
3004        let input_type = DataType::Decimal128(20, 4);
3005        let output_type = DataType::Decimal256(20, 3);
3006        assert!(can_cast_types(&input_type, &output_type));
3007        generate_cast_test_case!(
3008            &array,
3009            Decimal256Array,
3010            &output_type,
3011            vec![
3012                Some(i256::from_i128(112345_i128)),
3013                Some(i256::from_i128(212346_i128)),
3014                Some(i256::from_i128(-312345_i128)),
3015                Some(i256::from_i128(-312346_i128)),
3016                None
3017            ]
3018        );
3019
3020        // decimal256
3021        let array = vec![
3022            Some(i256::from_i128(1123454)),
3023            Some(i256::from_i128(2123456)),
3024            Some(i256::from_i128(-3123453)),
3025            Some(i256::from_i128(-3123456)),
3026            None,
3027        ];
3028        let array = create_decimal256_array(array, 20, 4).unwrap();
3029
3030        // decimal256 to decimal256
3031        let input_type = DataType::Decimal256(20, 4);
3032        let output_type = DataType::Decimal256(20, 3);
3033        assert!(can_cast_types(&input_type, &output_type));
3034        generate_cast_test_case!(
3035            &array,
3036            Decimal256Array,
3037            &output_type,
3038            vec![
3039                Some(i256::from_i128(112345_i128)),
3040                Some(i256::from_i128(212346_i128)),
3041                Some(i256::from_i128(-312345_i128)),
3042                Some(i256::from_i128(-312346_i128)),
3043                None
3044            ]
3045        );
3046        // decimal256 to decimal128
3047        let input_type = DataType::Decimal256(20, 4);
3048        let output_type = DataType::Decimal128(20, 3);
3049        assert!(can_cast_types(&input_type, &output_type));
3050        generate_cast_test_case!(
3051            &array,
3052            Decimal128Array,
3053            &output_type,
3054            vec![
3055                Some(112345_i128),
3056                Some(212346_i128),
3057                Some(-312345_i128),
3058                Some(-312346_i128),
3059                None
3060            ]
3061        );
3062    }
3063
3064    #[test]
3065    fn test_cast_decimal32_to_decimal32() {
3066        // test changing precision
3067        let input_type = DataType::Decimal32(9, 3);
3068        let output_type = DataType::Decimal32(9, 4);
3069        assert!(can_cast_types(&input_type, &output_type));
3070        let array = vec![Some(1123456), Some(2123456), Some(3123456), None];
3071        let array = create_decimal32_array(array, 9, 3).unwrap();
3072        generate_cast_test_case!(
3073            &array,
3074            Decimal32Array,
3075            &output_type,
3076            vec![
3077                Some(11234560_i32),
3078                Some(21234560_i32),
3079                Some(31234560_i32),
3080                None
3081            ]
3082        );
3083        // negative test
3084        let array = vec![Some(123456), None];
3085        let array = create_decimal32_array(array, 9, 0).unwrap();
3086        let result_safe = cast(&array, &DataType::Decimal32(2, 2));
3087        assert!(result_safe.is_ok());
3088        let options = CastOptions {
3089            safe: false,
3090            ..Default::default()
3091        };
3092
3093        let result_unsafe = cast_with_options(&array, &DataType::Decimal32(2, 2), &options);
3094        assert_eq!(
3095            "Invalid argument error: 123456.00 is too large to store in a Decimal32 of precision 2. Max is 0.99",
3096            result_unsafe.unwrap_err().to_string()
3097        );
3098    }
3099
3100    #[test]
3101    fn test_cast_decimal64_to_decimal64() {
3102        // test changing precision
3103        let input_type = DataType::Decimal64(17, 3);
3104        let output_type = DataType::Decimal64(17, 4);
3105        assert!(can_cast_types(&input_type, &output_type));
3106        let array = vec![Some(1123456), Some(2123456), Some(3123456), None];
3107        let array = create_decimal64_array(array, 17, 3).unwrap();
3108        generate_cast_test_case!(
3109            &array,
3110            Decimal64Array,
3111            &output_type,
3112            vec![
3113                Some(11234560_i64),
3114                Some(21234560_i64),
3115                Some(31234560_i64),
3116                None
3117            ]
3118        );
3119        // negative test
3120        let array = vec![Some(123456), None];
3121        let array = create_decimal64_array(array, 9, 0).unwrap();
3122        let result_safe = cast(&array, &DataType::Decimal64(2, 2));
3123        assert!(result_safe.is_ok());
3124        let options = CastOptions {
3125            safe: false,
3126            ..Default::default()
3127        };
3128
3129        let result_unsafe = cast_with_options(&array, &DataType::Decimal64(2, 2), &options);
3130        assert_eq!(
3131            "Invalid argument error: 123456.00 is too large to store in a Decimal64 of precision 2. Max is 0.99",
3132            result_unsafe.unwrap_err().to_string()
3133        );
3134    }
3135
3136    #[test]
3137    fn test_cast_decimal128_to_decimal128() {
3138        // test changing precision
3139        let input_type = DataType::Decimal128(20, 3);
3140        let output_type = DataType::Decimal128(20, 4);
3141        assert!(can_cast_types(&input_type, &output_type));
3142        let array = vec![Some(1123456), Some(2123456), Some(3123456), None];
3143        let array = create_decimal128_array(array, 20, 3).unwrap();
3144        generate_cast_test_case!(
3145            &array,
3146            Decimal128Array,
3147            &output_type,
3148            vec![
3149                Some(11234560_i128),
3150                Some(21234560_i128),
3151                Some(31234560_i128),
3152                None
3153            ]
3154        );
3155        // negative test
3156        let array = vec![Some(123456), None];
3157        let array = create_decimal128_array(array, 10, 0).unwrap();
3158        let result_safe = cast(&array, &DataType::Decimal128(2, 2));
3159        assert!(result_safe.is_ok());
3160        let options = CastOptions {
3161            safe: false,
3162            ..Default::default()
3163        };
3164
3165        let result_unsafe = cast_with_options(&array, &DataType::Decimal128(2, 2), &options);
3166        assert_eq!(
3167            "Invalid argument error: 123456.00 is too large to store in a Decimal128 of precision 2. Max is 0.99",
3168            result_unsafe.unwrap_err().to_string()
3169        );
3170    }
3171
3172    #[test]
3173    fn test_cast_decimal32_to_decimal32_dict() {
3174        let p = 9;
3175        let s = 3;
3176        let input_type = DataType::Decimal32(p, s);
3177        let output_type = DataType::Dictionary(
3178            Box::new(DataType::Int32),
3179            Box::new(DataType::Decimal32(p, s)),
3180        );
3181        assert!(can_cast_types(&input_type, &output_type));
3182        let array = vec![Some(1123456), Some(2123456), Some(3123456), None];
3183        let array = create_decimal32_array(array, p, s).unwrap();
3184        let cast_array = cast_with_options(&array, &output_type, &CastOptions::default()).unwrap();
3185        assert_eq!(cast_array.data_type(), &output_type);
3186    }
3187
3188    #[test]
3189    fn test_cast_decimal64_to_decimal64_dict() {
3190        let p = 15;
3191        let s = 3;
3192        let input_type = DataType::Decimal64(p, s);
3193        let output_type = DataType::Dictionary(
3194            Box::new(DataType::Int32),
3195            Box::new(DataType::Decimal64(p, s)),
3196        );
3197        assert!(can_cast_types(&input_type, &output_type));
3198        let array = vec![Some(1123456), Some(2123456), Some(3123456), None];
3199        let array = create_decimal64_array(array, p, s).unwrap();
3200        let cast_array = cast_with_options(&array, &output_type, &CastOptions::default()).unwrap();
3201        assert_eq!(cast_array.data_type(), &output_type);
3202    }
3203
3204    #[test]
3205    fn test_cast_decimal128_to_decimal128_dict() {
3206        let p = 20;
3207        let s = 3;
3208        let input_type = DataType::Decimal128(p, s);
3209        let output_type = DataType::Dictionary(
3210            Box::new(DataType::Int32),
3211            Box::new(DataType::Decimal128(p, s)),
3212        );
3213        assert!(can_cast_types(&input_type, &output_type));
3214        let array = vec![Some(1123456), Some(2123456), Some(3123456), None];
3215        let array = create_decimal128_array(array, p, s).unwrap();
3216        let cast_array = cast_with_options(&array, &output_type, &CastOptions::default()).unwrap();
3217        assert_eq!(cast_array.data_type(), &output_type);
3218    }
3219
3220    #[test]
3221    fn test_cast_decimal256_to_decimal256_dict() {
3222        let p = 20;
3223        let s = 3;
3224        let input_type = DataType::Decimal256(p, s);
3225        let output_type = DataType::Dictionary(
3226            Box::new(DataType::Int32),
3227            Box::new(DataType::Decimal256(p, s)),
3228        );
3229        assert!(can_cast_types(&input_type, &output_type));
3230        let array = vec![Some(1123456), Some(2123456), Some(3123456), None];
3231        let array = create_decimal128_array(array, p, s).unwrap();
3232        let cast_array = cast_with_options(&array, &output_type, &CastOptions::default()).unwrap();
3233        assert_eq!(cast_array.data_type(), &output_type);
3234    }
3235
3236    #[test]
3237    fn test_cast_decimal32_to_decimal32_overflow() {
3238        let input_type = DataType::Decimal32(9, 3);
3239        let output_type = DataType::Decimal32(9, 9);
3240        assert!(can_cast_types(&input_type, &output_type));
3241
3242        let array = vec![Some(i32::MAX)];
3243        let array = create_decimal32_array(array, 9, 3).unwrap();
3244        let result = cast_with_options(
3245            &array,
3246            &output_type,
3247            &CastOptions {
3248                safe: false,
3249                format_options: FormatOptions::default(),
3250            },
3251        );
3252        assert_eq!(
3253            "Cast error: Cannot cast to Decimal32(9, 9). Overflowing on 2147483647",
3254            result.unwrap_err().to_string()
3255        );
3256    }
3257
3258    #[test]
3259    fn test_cast_decimal32_to_decimal32_large_scale_reduction() {
3260        let array = vec![Some(-999999999), Some(0), Some(999999999), None];
3261        let array = create_decimal32_array(array, 9, 3).unwrap();
3262
3263        // Divide out all digits of precision -- rounding could still produce +/- 1
3264        let output_type = DataType::Decimal32(9, -6);
3265        assert!(can_cast_types(array.data_type(), &output_type));
3266        generate_cast_test_case!(
3267            &array,
3268            Decimal32Array,
3269            &output_type,
3270            vec![Some(-1), Some(0), Some(1), None]
3271        );
3272
3273        // Divide out more digits than we have precision -- all-zero result
3274        let output_type = DataType::Decimal32(9, -7);
3275        assert!(can_cast_types(array.data_type(), &output_type));
3276        generate_cast_test_case!(
3277            &array,
3278            Decimal32Array,
3279            &output_type,
3280            vec![Some(0), Some(0), Some(0), None]
3281        );
3282    }
3283
3284    #[test]
3285    fn test_cast_decimal64_to_decimal64_overflow() {
3286        let input_type = DataType::Decimal64(18, 3);
3287        let output_type = DataType::Decimal64(18, 18);
3288        assert!(can_cast_types(&input_type, &output_type));
3289
3290        let array = vec![Some(i64::MAX)];
3291        let array = create_decimal64_array(array, 18, 3).unwrap();
3292        let result = cast_with_options(
3293            &array,
3294            &output_type,
3295            &CastOptions {
3296                safe: false,
3297                format_options: FormatOptions::default(),
3298            },
3299        );
3300        assert_eq!(
3301            "Cast error: Cannot cast to Decimal64(18, 18). Overflowing on 9223372036854775807",
3302            result.unwrap_err().to_string()
3303        );
3304    }
3305
3306    #[test]
3307    fn test_cast_decimal64_to_decimal64_large_scale_reduction() {
3308        let array = vec![
3309            Some(-999999999999999999),
3310            Some(0),
3311            Some(999999999999999999),
3312            None,
3313        ];
3314        let array = create_decimal64_array(array, 18, 3).unwrap();
3315
3316        // Divide out all digits of precision -- rounding could still produce +/- 1
3317        let output_type = DataType::Decimal64(18, -15);
3318        assert!(can_cast_types(array.data_type(), &output_type));
3319        generate_cast_test_case!(
3320            &array,
3321            Decimal64Array,
3322            &output_type,
3323            vec![Some(-1), Some(0), Some(1), None]
3324        );
3325
3326        // Divide out more digits than we have precision -- all-zero result
3327        let output_type = DataType::Decimal64(18, -16);
3328        assert!(can_cast_types(array.data_type(), &output_type));
3329        generate_cast_test_case!(
3330            &array,
3331            Decimal64Array,
3332            &output_type,
3333            vec![Some(0), Some(0), Some(0), None]
3334        );
3335    }
3336
3337    #[test]
3338    fn test_cast_floating_to_decimals() {
3339        for output_type in [
3340            DataType::Decimal32(9, 3),
3341            DataType::Decimal64(9, 3),
3342            DataType::Decimal128(9, 3),
3343            DataType::Decimal256(9, 3),
3344        ] {
3345            let input_type = DataType::Float64;
3346            assert!(can_cast_types(&input_type, &output_type));
3347
3348            let array = vec![Some(1.1_f64)];
3349            let array = PrimitiveArray::<Float64Type>::from_iter(array);
3350            let result = cast_with_options(
3351                &array,
3352                &output_type,
3353                &CastOptions {
3354                    safe: false,
3355                    format_options: FormatOptions::default(),
3356                },
3357            );
3358            assert!(
3359                result.is_ok(),
3360                "Failed to cast to {output_type} with: {}",
3361                result.unwrap_err()
3362            );
3363        }
3364    }
3365
3366    #[test]
3367    fn test_cast_decimal128_to_decimal128_overflow() {
3368        let input_type = DataType::Decimal128(38, 3);
3369        let output_type = DataType::Decimal128(38, 38);
3370        assert!(can_cast_types(&input_type, &output_type));
3371
3372        let array = vec![Some(i128::MAX)];
3373        let array = create_decimal128_array(array, 38, 3).unwrap();
3374        let result = cast_with_options(
3375            &array,
3376            &output_type,
3377            &CastOptions {
3378                safe: false,
3379                format_options: FormatOptions::default(),
3380            },
3381        );
3382        assert_eq!(
3383            "Cast error: Cannot cast to Decimal128(38, 38). Overflowing on 170141183460469231731687303715884105727",
3384            result.unwrap_err().to_string()
3385        );
3386    }
3387
3388    #[test]
3389    fn test_cast_decimal128_to_decimal256_overflow() {
3390        let input_type = DataType::Decimal128(38, 3);
3391        let output_type = DataType::Decimal256(76, 76);
3392        assert!(can_cast_types(&input_type, &output_type));
3393
3394        let array = vec![Some(i128::MAX)];
3395        let array = create_decimal128_array(array, 38, 3).unwrap();
3396        let result = cast_with_options(
3397            &array,
3398            &output_type,
3399            &CastOptions {
3400                safe: false,
3401                format_options: FormatOptions::default(),
3402            },
3403        );
3404        assert_eq!(
3405            "Cast error: Cannot cast to Decimal256(76, 76). Overflowing on 170141183460469231731687303715884105727",
3406            result.unwrap_err().to_string()
3407        );
3408    }
3409
3410    #[test]
3411    fn test_cast_decimal32_to_decimal256() {
3412        let input_type = DataType::Decimal32(8, 3);
3413        let output_type = DataType::Decimal256(20, 4);
3414        assert!(can_cast_types(&input_type, &output_type));
3415        let array = vec![Some(1123456), Some(2123456), Some(3123456), None];
3416        let array = create_decimal32_array(array, 8, 3).unwrap();
3417        generate_cast_test_case!(
3418            &array,
3419            Decimal256Array,
3420            &output_type,
3421            vec![
3422                Some(i256::from_i128(11234560_i128)),
3423                Some(i256::from_i128(21234560_i128)),
3424                Some(i256::from_i128(31234560_i128)),
3425                None
3426            ]
3427        );
3428    }
3429    #[test]
3430    fn test_cast_decimal64_to_decimal256() {
3431        let input_type = DataType::Decimal64(12, 3);
3432        let output_type = DataType::Decimal256(20, 4);
3433        assert!(can_cast_types(&input_type, &output_type));
3434        let array = vec![Some(1123456), Some(2123456), Some(3123456), None];
3435        let array = create_decimal64_array(array, 12, 3).unwrap();
3436        generate_cast_test_case!(
3437            &array,
3438            Decimal256Array,
3439            &output_type,
3440            vec![
3441                Some(i256::from_i128(11234560_i128)),
3442                Some(i256::from_i128(21234560_i128)),
3443                Some(i256::from_i128(31234560_i128)),
3444                None
3445            ]
3446        );
3447    }
3448    #[test]
3449    fn test_cast_decimal128_to_decimal256() {
3450        let input_type = DataType::Decimal128(20, 3);
3451        let output_type = DataType::Decimal256(20, 4);
3452        assert!(can_cast_types(&input_type, &output_type));
3453        let array = vec![Some(1123456), Some(2123456), Some(3123456), None];
3454        let array = create_decimal128_array(array, 20, 3).unwrap();
3455        generate_cast_test_case!(
3456            &array,
3457            Decimal256Array,
3458            &output_type,
3459            vec![
3460                Some(i256::from_i128(11234560_i128)),
3461                Some(i256::from_i128(21234560_i128)),
3462                Some(i256::from_i128(31234560_i128)),
3463                None
3464            ]
3465        );
3466    }
3467
3468    #[test]
3469    fn test_cast_decimal256_to_decimal128_overflow() {
3470        let input_type = DataType::Decimal256(76, 5);
3471        let output_type = DataType::Decimal128(38, 7);
3472        assert!(can_cast_types(&input_type, &output_type));
3473        let array = vec![Some(i256::from_i128(i128::MAX))];
3474        let array = create_decimal256_array(array, 76, 5).unwrap();
3475        let result = cast_with_options(
3476            &array,
3477            &output_type,
3478            &CastOptions {
3479                safe: false,
3480                format_options: FormatOptions::default(),
3481            },
3482        );
3483        assert_eq!(
3484            "Cast error: Cannot cast to Decimal128(38, 7). Overflowing on 170141183460469231731687303715884105727",
3485            result.unwrap_err().to_string()
3486        );
3487    }
3488
3489    #[test]
3490    fn test_cast_decimal256_to_decimal256_overflow() {
3491        let input_type = DataType::Decimal256(76, 5);
3492        let output_type = DataType::Decimal256(76, 55);
3493        assert!(can_cast_types(&input_type, &output_type));
3494        let array = vec![Some(i256::from_i128(i128::MAX))];
3495        let array = create_decimal256_array(array, 76, 5).unwrap();
3496        let result = cast_with_options(
3497            &array,
3498            &output_type,
3499            &CastOptions {
3500                safe: false,
3501                format_options: FormatOptions::default(),
3502            },
3503        );
3504        assert_eq!(
3505            "Cast error: Cannot cast to Decimal256(76, 55). Overflowing on 170141183460469231731687303715884105727",
3506            result.unwrap_err().to_string()
3507        );
3508    }
3509
3510    #[test]
3511    fn test_cast_decimal256_to_decimal128() {
3512        let input_type = DataType::Decimal256(20, 3);
3513        let output_type = DataType::Decimal128(20, 4);
3514        assert!(can_cast_types(&input_type, &output_type));
3515        let array = vec![
3516            Some(i256::from_i128(1123456)),
3517            Some(i256::from_i128(2123456)),
3518            Some(i256::from_i128(3123456)),
3519            None,
3520        ];
3521        let array = create_decimal256_array(array, 20, 3).unwrap();
3522        generate_cast_test_case!(
3523            &array,
3524            Decimal128Array,
3525            &output_type,
3526            vec![
3527                Some(11234560_i128),
3528                Some(21234560_i128),
3529                Some(31234560_i128),
3530                None
3531            ]
3532        );
3533    }
3534
3535    #[test]
3536    fn test_cast_decimal256_to_decimal256() {
3537        let input_type = DataType::Decimal256(20, 3);
3538        let output_type = DataType::Decimal256(20, 4);
3539        assert!(can_cast_types(&input_type, &output_type));
3540        let array = vec![
3541            Some(i256::from_i128(1123456)),
3542            Some(i256::from_i128(2123456)),
3543            Some(i256::from_i128(3123456)),
3544            None,
3545        ];
3546        let array = create_decimal256_array(array, 20, 3).unwrap();
3547        generate_cast_test_case!(
3548            &array,
3549            Decimal256Array,
3550            &output_type,
3551            vec![
3552                Some(i256::from_i128(11234560_i128)),
3553                Some(i256::from_i128(21234560_i128)),
3554                Some(i256::from_i128(31234560_i128)),
3555                None
3556            ]
3557        );
3558    }
3559
3560    fn generate_decimal_to_numeric_cast_test_case<T>(array: &PrimitiveArray<T>)
3561    where
3562        T: ArrowPrimitiveType + DecimalType,
3563    {
3564        // u8
3565        generate_cast_test_case!(
3566            array,
3567            UInt8Array,
3568            &DataType::UInt8,
3569            vec![Some(1_u8), Some(2_u8), Some(3_u8), None, Some(5_u8)]
3570        );
3571        // u16
3572        generate_cast_test_case!(
3573            array,
3574            UInt16Array,
3575            &DataType::UInt16,
3576            vec![Some(1_u16), Some(2_u16), Some(3_u16), None, Some(5_u16)]
3577        );
3578        // u32
3579        generate_cast_test_case!(
3580            array,
3581            UInt32Array,
3582            &DataType::UInt32,
3583            vec![Some(1_u32), Some(2_u32), Some(3_u32), None, Some(5_u32)]
3584        );
3585        // u64
3586        generate_cast_test_case!(
3587            array,
3588            UInt64Array,
3589            &DataType::UInt64,
3590            vec![Some(1_u64), Some(2_u64), Some(3_u64), None, Some(5_u64)]
3591        );
3592        // i8
3593        generate_cast_test_case!(
3594            array,
3595            Int8Array,
3596            &DataType::Int8,
3597            vec![Some(1_i8), Some(2_i8), Some(3_i8), None, Some(5_i8)]
3598        );
3599        // i16
3600        generate_cast_test_case!(
3601            array,
3602            Int16Array,
3603            &DataType::Int16,
3604            vec![Some(1_i16), Some(2_i16), Some(3_i16), None, Some(5_i16)]
3605        );
3606        // i32
3607        generate_cast_test_case!(
3608            array,
3609            Int32Array,
3610            &DataType::Int32,
3611            vec![Some(1_i32), Some(2_i32), Some(3_i32), None, Some(5_i32)]
3612        );
3613        // i64
3614        generate_cast_test_case!(
3615            array,
3616            Int64Array,
3617            &DataType::Int64,
3618            vec![Some(1_i64), Some(2_i64), Some(3_i64), None, Some(5_i64)]
3619        );
3620        // f32
3621        generate_cast_test_case!(
3622            array,
3623            Float32Array,
3624            &DataType::Float32,
3625            vec![
3626                Some(1.25_f32),
3627                Some(2.25_f32),
3628                Some(3.25_f32),
3629                None,
3630                Some(5.25_f32)
3631            ]
3632        );
3633        // f64
3634        generate_cast_test_case!(
3635            array,
3636            Float64Array,
3637            &DataType::Float64,
3638            vec![
3639                Some(1.25_f64),
3640                Some(2.25_f64),
3641                Some(3.25_f64),
3642                None,
3643                Some(5.25_f64)
3644            ]
3645        );
3646    }
3647
3648    #[test]
3649    fn test_cast_decimal32_to_numeric() {
3650        let value_array: Vec<Option<i32>> = vec![Some(125), Some(225), Some(325), None, Some(525)];
3651        let array = create_decimal32_array(value_array, 8, 2).unwrap();
3652
3653        generate_decimal_to_numeric_cast_test_case(&array);
3654    }
3655
3656    #[test]
3657    fn test_cast_decimal64_to_numeric() {
3658        let value_array: Vec<Option<i64>> = vec![Some(125), Some(225), Some(325), None, Some(525)];
3659        let array = create_decimal64_array(value_array, 8, 2).unwrap();
3660
3661        generate_decimal_to_numeric_cast_test_case(&array);
3662    }
3663
3664    #[test]
3665    fn test_cast_decimal128_to_numeric() {
3666        let value_array: Vec<Option<i128>> = vec![Some(125), Some(225), Some(325), None, Some(525)];
3667        let array = create_decimal128_array(value_array, 38, 2).unwrap();
3668
3669        generate_decimal_to_numeric_cast_test_case(&array);
3670
3671        // overflow test: out of range of max u8
3672        let value_array: Vec<Option<i128>> = vec![Some(51300)];
3673        let array = create_decimal128_array(value_array, 38, 2).unwrap();
3674        let casted_array = cast_with_options(
3675            &array,
3676            &DataType::UInt8,
3677            &CastOptions {
3678                safe: false,
3679                format_options: FormatOptions::default(),
3680            },
3681        );
3682        assert_eq!(
3683            "Cast error: value of 513 is out of range UInt8".to_string(),
3684            casted_array.unwrap_err().to_string()
3685        );
3686
3687        let casted_array = cast_with_options(
3688            &array,
3689            &DataType::UInt8,
3690            &CastOptions {
3691                safe: true,
3692                format_options: FormatOptions::default(),
3693            },
3694        );
3695        assert!(casted_array.is_ok());
3696        assert!(casted_array.unwrap().is_null(0));
3697
3698        // overflow test: out of range of max i8
3699        let value_array: Vec<Option<i128>> = vec![Some(24400)];
3700        let array = create_decimal128_array(value_array, 38, 2).unwrap();
3701        let casted_array = cast_with_options(
3702            &array,
3703            &DataType::Int8,
3704            &CastOptions {
3705                safe: false,
3706                format_options: FormatOptions::default(),
3707            },
3708        );
3709        assert_eq!(
3710            "Cast error: value of 244 is out of range Int8".to_string(),
3711            casted_array.unwrap_err().to_string()
3712        );
3713
3714        let casted_array = cast_with_options(
3715            &array,
3716            &DataType::Int8,
3717            &CastOptions {
3718                safe: true,
3719                format_options: FormatOptions::default(),
3720            },
3721        );
3722        assert!(casted_array.is_ok());
3723        assert!(casted_array.unwrap().is_null(0));
3724
3725        // loss the precision: convert decimal to f32、f64
3726        // f32
3727        // 112345678_f32 and 112345679_f32 are same, so the 112345679_f32 will lose precision.
3728        let value_array: Vec<Option<i128>> = vec![
3729            Some(125),
3730            Some(225),
3731            Some(325),
3732            None,
3733            Some(525),
3734            Some(112345678),
3735            Some(112345679),
3736        ];
3737        let array = create_decimal128_array(value_array, 38, 2).unwrap();
3738        generate_cast_test_case!(
3739            &array,
3740            Float32Array,
3741            &DataType::Float32,
3742            vec![
3743                Some(1.25_f32),
3744                Some(2.25_f32),
3745                Some(3.25_f32),
3746                None,
3747                Some(5.25_f32),
3748                Some(1_123_456.7_f32),
3749                Some(1_123_456.7_f32)
3750            ]
3751        );
3752
3753        // f64
3754        // 112345678901234568_f64 and 112345678901234560_f64 are same, so the 112345678901234568_f64 will lose precision.
3755        let value_array: Vec<Option<i128>> = vec![
3756            Some(125),
3757            Some(225),
3758            Some(325),
3759            None,
3760            Some(525),
3761            Some(112345678901234568),
3762            Some(112345678901234560),
3763        ];
3764        let array = create_decimal128_array(value_array, 38, 2).unwrap();
3765        generate_cast_test_case!(
3766            &array,
3767            Float64Array,
3768            &DataType::Float64,
3769            vec![
3770                Some(1.25_f64),
3771                Some(2.25_f64),
3772                Some(3.25_f64),
3773                None,
3774                Some(5.25_f64),
3775                Some(1_123_456_789_012_345.6_f64),
3776                Some(1_123_456_789_012_345.6_f64),
3777            ]
3778        );
3779    }
3780
3781    #[test]
3782    fn test_cast_decimal256_to_numeric() {
3783        let value_array: Vec<Option<i256>> = vec![
3784            Some(i256::from_i128(125)),
3785            Some(i256::from_i128(225)),
3786            Some(i256::from_i128(325)),
3787            None,
3788            Some(i256::from_i128(525)),
3789        ];
3790        let array = create_decimal256_array(value_array, 38, 2).unwrap();
3791        // u8
3792        generate_cast_test_case!(
3793            &array,
3794            UInt8Array,
3795            &DataType::UInt8,
3796            vec![Some(1_u8), Some(2_u8), Some(3_u8), None, Some(5_u8)]
3797        );
3798        // u16
3799        generate_cast_test_case!(
3800            &array,
3801            UInt16Array,
3802            &DataType::UInt16,
3803            vec![Some(1_u16), Some(2_u16), Some(3_u16), None, Some(5_u16)]
3804        );
3805        // u32
3806        generate_cast_test_case!(
3807            &array,
3808            UInt32Array,
3809            &DataType::UInt32,
3810            vec![Some(1_u32), Some(2_u32), Some(3_u32), None, Some(5_u32)]
3811        );
3812        // u64
3813        generate_cast_test_case!(
3814            &array,
3815            UInt64Array,
3816            &DataType::UInt64,
3817            vec![Some(1_u64), Some(2_u64), Some(3_u64), None, Some(5_u64)]
3818        );
3819        // i8
3820        generate_cast_test_case!(
3821            &array,
3822            Int8Array,
3823            &DataType::Int8,
3824            vec![Some(1_i8), Some(2_i8), Some(3_i8), None, Some(5_i8)]
3825        );
3826        // i16
3827        generate_cast_test_case!(
3828            &array,
3829            Int16Array,
3830            &DataType::Int16,
3831            vec![Some(1_i16), Some(2_i16), Some(3_i16), None, Some(5_i16)]
3832        );
3833        // i32
3834        generate_cast_test_case!(
3835            &array,
3836            Int32Array,
3837            &DataType::Int32,
3838            vec![Some(1_i32), Some(2_i32), Some(3_i32), None, Some(5_i32)]
3839        );
3840        // i64
3841        generate_cast_test_case!(
3842            &array,
3843            Int64Array,
3844            &DataType::Int64,
3845            vec![Some(1_i64), Some(2_i64), Some(3_i64), None, Some(5_i64)]
3846        );
3847        // f32
3848        generate_cast_test_case!(
3849            &array,
3850            Float32Array,
3851            &DataType::Float32,
3852            vec![
3853                Some(1.25_f32),
3854                Some(2.25_f32),
3855                Some(3.25_f32),
3856                None,
3857                Some(5.25_f32)
3858            ]
3859        );
3860        // f64
3861        generate_cast_test_case!(
3862            &array,
3863            Float64Array,
3864            &DataType::Float64,
3865            vec![
3866                Some(1.25_f64),
3867                Some(2.25_f64),
3868                Some(3.25_f64),
3869                None,
3870                Some(5.25_f64)
3871            ]
3872        );
3873
3874        // overflow test: out of range of max i8
3875        let value_array: Vec<Option<i256>> = vec![Some(i256::from_i128(24400))];
3876        let array = create_decimal256_array(value_array, 38, 2).unwrap();
3877        let casted_array = cast_with_options(
3878            &array,
3879            &DataType::Int8,
3880            &CastOptions {
3881                safe: false,
3882                format_options: FormatOptions::default(),
3883            },
3884        );
3885        assert_eq!(
3886            "Cast error: value of 244 is out of range Int8".to_string(),
3887            casted_array.unwrap_err().to_string()
3888        );
3889
3890        let casted_array = cast_with_options(
3891            &array,
3892            &DataType::Int8,
3893            &CastOptions {
3894                safe: true,
3895                format_options: FormatOptions::default(),
3896            },
3897        );
3898        assert!(casted_array.is_ok());
3899        assert!(casted_array.unwrap().is_null(0));
3900
3901        // loss the precision: convert decimal to f32、f64
3902        // f32
3903        // 112345678_f32 and 112345679_f32 are same, so the 112345679_f32 will lose precision.
3904        let value_array: Vec<Option<i256>> = vec![
3905            Some(i256::from_i128(125)),
3906            Some(i256::from_i128(225)),
3907            Some(i256::from_i128(325)),
3908            None,
3909            Some(i256::from_i128(525)),
3910            Some(i256::from_i128(112345678)),
3911            Some(i256::from_i128(112345679)),
3912        ];
3913        let array = create_decimal256_array(value_array, 76, 2).unwrap();
3914        generate_cast_test_case!(
3915            &array,
3916            Float32Array,
3917            &DataType::Float32,
3918            vec![
3919                Some(1.25_f32),
3920                Some(2.25_f32),
3921                Some(3.25_f32),
3922                None,
3923                Some(5.25_f32),
3924                Some(1_123_456.7_f32),
3925                Some(1_123_456.7_f32)
3926            ]
3927        );
3928
3929        // f64
3930        // 112345678901234568_f64 and 112345678901234560_f64 are same, so the 112345678901234568_f64 will lose precision.
3931        let value_array: Vec<Option<i256>> = vec![
3932            Some(i256::from_i128(125)),
3933            Some(i256::from_i128(225)),
3934            Some(i256::from_i128(325)),
3935            None,
3936            Some(i256::from_i128(525)),
3937            Some(i256::from_i128(112345678901234568)),
3938            Some(i256::from_i128(112345678901234560)),
3939        ];
3940        let array = create_decimal256_array(value_array, 76, 2).unwrap();
3941        generate_cast_test_case!(
3942            &array,
3943            Float64Array,
3944            &DataType::Float64,
3945            vec![
3946                Some(1.25_f64),
3947                Some(2.25_f64),
3948                Some(3.25_f64),
3949                None,
3950                Some(5.25_f64),
3951                Some(1_123_456_789_012_345.6_f64),
3952                Some(1_123_456_789_012_345.6_f64),
3953            ]
3954        );
3955    }
3956
3957    #[test]
3958    fn test_cast_numeric_to_decimal128() {
3959        let decimal_type = DataType::Decimal128(38, 6);
3960        // u8, u16, u32, u64
3961        let input_datas = vec![
3962            Arc::new(UInt8Array::from(vec![
3963                Some(1),
3964                Some(2),
3965                Some(3),
3966                None,
3967                Some(5),
3968            ])) as ArrayRef, // u8
3969            Arc::new(UInt16Array::from(vec![
3970                Some(1),
3971                Some(2),
3972                Some(3),
3973                None,
3974                Some(5),
3975            ])) as ArrayRef, // u16
3976            Arc::new(UInt32Array::from(vec![
3977                Some(1),
3978                Some(2),
3979                Some(3),
3980                None,
3981                Some(5),
3982            ])) as ArrayRef, // u32
3983            Arc::new(UInt64Array::from(vec![
3984                Some(1),
3985                Some(2),
3986                Some(3),
3987                None,
3988                Some(5),
3989            ])) as ArrayRef, // u64
3990        ];
3991
3992        for array in input_datas {
3993            generate_cast_test_case!(
3994                &array,
3995                Decimal128Array,
3996                &decimal_type,
3997                vec![
3998                    Some(1000000_i128),
3999                    Some(2000000_i128),
4000                    Some(3000000_i128),
4001                    None,
4002                    Some(5000000_i128)
4003                ]
4004            );
4005        }
4006
4007        // i8, i16, i32, i64
4008        let input_datas = vec![
4009            Arc::new(Int8Array::from(vec![
4010                Some(1),
4011                Some(2),
4012                Some(3),
4013                None,
4014                Some(5),
4015            ])) as ArrayRef, // i8
4016            Arc::new(Int16Array::from(vec![
4017                Some(1),
4018                Some(2),
4019                Some(3),
4020                None,
4021                Some(5),
4022            ])) as ArrayRef, // i16
4023            Arc::new(Int32Array::from(vec![
4024                Some(1),
4025                Some(2),
4026                Some(3),
4027                None,
4028                Some(5),
4029            ])) as ArrayRef, // i32
4030            Arc::new(Int64Array::from(vec![
4031                Some(1),
4032                Some(2),
4033                Some(3),
4034                None,
4035                Some(5),
4036            ])) as ArrayRef, // i64
4037        ];
4038        for array in input_datas {
4039            generate_cast_test_case!(
4040                &array,
4041                Decimal128Array,
4042                &decimal_type,
4043                vec![
4044                    Some(1000000_i128),
4045                    Some(2000000_i128),
4046                    Some(3000000_i128),
4047                    None,
4048                    Some(5000000_i128)
4049                ]
4050            );
4051        }
4052
4053        // test u8 to decimal type with overflow the result type
4054        // the 100 will be converted to 1000_i128, but it is out of range for max value in the precision 3.
4055        let array = UInt8Array::from(vec![1, 2, 3, 4, 100]);
4056        let casted_array = cast(&array, &DataType::Decimal128(3, 1));
4057        assert!(casted_array.is_ok());
4058        let array = casted_array.unwrap();
4059        let array: &Decimal128Array = array.as_primitive();
4060        assert!(array.is_null(4));
4061
4062        // test i8 to decimal type with overflow the result type
4063        // the 100 will be converted to 1000_i128, but it is out of range for max value in the precision 3.
4064        let array = Int8Array::from(vec![1, 2, 3, 4, 100]);
4065        let casted_array = cast(&array, &DataType::Decimal128(3, 1));
4066        assert!(casted_array.is_ok());
4067        let array = casted_array.unwrap();
4068        let array: &Decimal128Array = array.as_primitive();
4069        assert!(array.is_null(4));
4070
4071        // test f32 to decimal type
4072        let array = Float32Array::from(vec![
4073            Some(1.1),
4074            Some(2.2),
4075            Some(4.4),
4076            None,
4077            Some(1.123_456_4), // round down
4078            Some(1.123_456_7), // round up
4079        ]);
4080        let array = Arc::new(array) as ArrayRef;
4081        generate_cast_test_case!(
4082            &array,
4083            Decimal128Array,
4084            &decimal_type,
4085            vec![
4086                Some(1100000_i128),
4087                Some(2200000_i128),
4088                Some(4400000_i128),
4089                None,
4090                Some(1123456_i128), // round down
4091                Some(1123457_i128), // round up
4092            ]
4093        );
4094
4095        // test f64 to decimal type
4096        let array = Float64Array::from(vec![
4097            Some(1.1),
4098            Some(2.2),
4099            Some(4.4),
4100            None,
4101            Some(1.123_456_489_123_4),     // round up
4102            Some(1.123_456_789_123_4),     // round up
4103            Some(1.123_456_489_012_345_6), // round down
4104            Some(1.123_456_789_012_345_6), // round up
4105        ]);
4106        generate_cast_test_case!(
4107            &array,
4108            Decimal128Array,
4109            &decimal_type,
4110            vec![
4111                Some(1100000_i128),
4112                Some(2200000_i128),
4113                Some(4400000_i128),
4114                None,
4115                Some(1123456_i128), // round down
4116                Some(1123457_i128), // round up
4117                Some(1123456_i128), // round down
4118                Some(1123457_i128), // round up
4119            ]
4120        );
4121    }
4122
4123    #[test]
4124    fn test_cast_numeric_to_decimal256() {
4125        let decimal_type = DataType::Decimal256(76, 6);
4126        // u8, u16, u32, u64
4127        let input_datas = vec![
4128            Arc::new(UInt8Array::from(vec![
4129                Some(1),
4130                Some(2),
4131                Some(3),
4132                None,
4133                Some(5),
4134            ])) as ArrayRef, // u8
4135            Arc::new(UInt16Array::from(vec![
4136                Some(1),
4137                Some(2),
4138                Some(3),
4139                None,
4140                Some(5),
4141            ])) as ArrayRef, // u16
4142            Arc::new(UInt32Array::from(vec![
4143                Some(1),
4144                Some(2),
4145                Some(3),
4146                None,
4147                Some(5),
4148            ])) as ArrayRef, // u32
4149            Arc::new(UInt64Array::from(vec![
4150                Some(1),
4151                Some(2),
4152                Some(3),
4153                None,
4154                Some(5),
4155            ])) as ArrayRef, // u64
4156        ];
4157
4158        for array in input_datas {
4159            generate_cast_test_case!(
4160                &array,
4161                Decimal256Array,
4162                &decimal_type,
4163                vec![
4164                    Some(i256::from_i128(1000000_i128)),
4165                    Some(i256::from_i128(2000000_i128)),
4166                    Some(i256::from_i128(3000000_i128)),
4167                    None,
4168                    Some(i256::from_i128(5000000_i128))
4169                ]
4170            );
4171        }
4172
4173        // i8, i16, i32, i64
4174        let input_datas = vec![
4175            Arc::new(Int8Array::from(vec![
4176                Some(1),
4177                Some(2),
4178                Some(3),
4179                None,
4180                Some(5),
4181            ])) as ArrayRef, // i8
4182            Arc::new(Int16Array::from(vec![
4183                Some(1),
4184                Some(2),
4185                Some(3),
4186                None,
4187                Some(5),
4188            ])) as ArrayRef, // i16
4189            Arc::new(Int32Array::from(vec![
4190                Some(1),
4191                Some(2),
4192                Some(3),
4193                None,
4194                Some(5),
4195            ])) as ArrayRef, // i32
4196            Arc::new(Int64Array::from(vec![
4197                Some(1),
4198                Some(2),
4199                Some(3),
4200                None,
4201                Some(5),
4202            ])) as ArrayRef, // i64
4203        ];
4204        for array in input_datas {
4205            generate_cast_test_case!(
4206                &array,
4207                Decimal256Array,
4208                &decimal_type,
4209                vec![
4210                    Some(i256::from_i128(1000000_i128)),
4211                    Some(i256::from_i128(2000000_i128)),
4212                    Some(i256::from_i128(3000000_i128)),
4213                    None,
4214                    Some(i256::from_i128(5000000_i128))
4215                ]
4216            );
4217        }
4218
4219        // test i8 to decimal type with overflow the result type
4220        // the 100 will be converted to 1000_i128, but it is out of range for max value in the precision 3.
4221        let array = Int8Array::from(vec![1, 2, 3, 4, 100]);
4222        let array = Arc::new(array) as ArrayRef;
4223        let casted_array = cast(&array, &DataType::Decimal256(3, 1));
4224        assert!(casted_array.is_ok());
4225        let array = casted_array.unwrap();
4226        let array: &Decimal256Array = array.as_primitive();
4227        assert!(array.is_null(4));
4228
4229        // test f32 to decimal type
4230        let array = Float32Array::from(vec![
4231            Some(1.1),
4232            Some(2.2),
4233            Some(4.4),
4234            None,
4235            Some(1.123_456_4), // round down
4236            Some(1.123_456_7), // round up
4237        ]);
4238        generate_cast_test_case!(
4239            &array,
4240            Decimal256Array,
4241            &decimal_type,
4242            vec![
4243                Some(i256::from_i128(1100000_i128)),
4244                Some(i256::from_i128(2200000_i128)),
4245                Some(i256::from_i128(4400000_i128)),
4246                None,
4247                Some(i256::from_i128(1123456_i128)), // round down
4248                Some(i256::from_i128(1123457_i128)), // round up
4249            ]
4250        );
4251
4252        // test f64 to decimal type
4253        let array = Float64Array::from(vec![
4254            Some(1.1),
4255            Some(2.2),
4256            Some(4.4),
4257            None,
4258            Some(1.123_456_489_123_4),     // round down
4259            Some(1.123_456_789_123_4),     // round up
4260            Some(1.123_456_489_012_345_6), // round down
4261            Some(1.123_456_789_012_345_6), // round up
4262        ]);
4263        generate_cast_test_case!(
4264            &array,
4265            Decimal256Array,
4266            &decimal_type,
4267            vec![
4268                Some(i256::from_i128(1100000_i128)),
4269                Some(i256::from_i128(2200000_i128)),
4270                Some(i256::from_i128(4400000_i128)),
4271                None,
4272                Some(i256::from_i128(1123456_i128)), // round down
4273                Some(i256::from_i128(1123457_i128)), // round up
4274                Some(i256::from_i128(1123456_i128)), // round down
4275                Some(i256::from_i128(1123457_i128)), // round up
4276            ]
4277        );
4278    }
4279
4280    #[test]
4281    fn test_cast_i32_to_f64() {
4282        let array = Int32Array::from(vec![5, 6, 7, 8, 9]);
4283        let b = cast(&array, &DataType::Float64).unwrap();
4284        let c = b.as_primitive::<Float64Type>();
4285        assert_eq!(5.0, c.value(0));
4286        assert_eq!(6.0, c.value(1));
4287        assert_eq!(7.0, c.value(2));
4288        assert_eq!(8.0, c.value(3));
4289        assert_eq!(9.0, c.value(4));
4290    }
4291
4292    #[test]
4293    fn test_cast_i32_to_u8() {
4294        let array = Int32Array::from(vec![-5, 6, -7, 8, 100000000]);
4295        let b = cast(&array, &DataType::UInt8).unwrap();
4296        let c = b.as_primitive::<UInt8Type>();
4297        assert!(!c.is_valid(0));
4298        assert_eq!(6, c.value(1));
4299        assert!(!c.is_valid(2));
4300        assert_eq!(8, c.value(3));
4301        // overflows return None
4302        assert!(!c.is_valid(4));
4303    }
4304
4305    #[test]
4306    #[should_panic(expected = "Can't cast value -5 to type UInt8")]
4307    fn test_cast_int32_to_u8_with_error() {
4308        let array = Int32Array::from(vec![-5, 6, -7, 8, 100000000]);
4309        // overflow with the error
4310        let cast_option = CastOptions {
4311            safe: false,
4312            format_options: FormatOptions::default(),
4313        };
4314        let result = cast_with_options(&array, &DataType::UInt8, &cast_option);
4315        assert!(result.is_err());
4316        result.unwrap();
4317    }
4318
4319    #[test]
4320    fn test_cast_i32_to_u8_sliced() {
4321        let array = Int32Array::from(vec![-5, 6, -7, 8, 100000000]);
4322        assert_eq!(0, array.offset());
4323        let array = array.slice(2, 3);
4324        let b = cast(&array, &DataType::UInt8).unwrap();
4325        assert_eq!(3, b.len());
4326        let c = b.as_primitive::<UInt8Type>();
4327        assert!(!c.is_valid(0));
4328        assert_eq!(8, c.value(1));
4329        // overflows return None
4330        assert!(!c.is_valid(2));
4331    }
4332
4333    #[test]
4334    fn test_cast_i32_to_i32() {
4335        let array = Int32Array::from(vec![5, 6, 7, 8, 9]);
4336        let b = cast(&array, &DataType::Int32).unwrap();
4337        let c = b.as_primitive::<Int32Type>();
4338        assert_eq!(5, c.value(0));
4339        assert_eq!(6, c.value(1));
4340        assert_eq!(7, c.value(2));
4341        assert_eq!(8, c.value(3));
4342        assert_eq!(9, c.value(4));
4343    }
4344
4345    #[test]
4346    fn test_cast_i32_to_list_i32() {
4347        let array = Int32Array::from(vec![5, 6, 7, 8, 9]);
4348        let b = cast(
4349            &array,
4350            &DataType::List(Arc::new(Field::new_list_field(DataType::Int32, true))),
4351        )
4352        .unwrap();
4353        assert_eq!(5, b.len());
4354        let arr = b.as_list::<i32>();
4355        assert_eq!(&[0, 1, 2, 3, 4, 5], arr.value_offsets());
4356        assert_eq!(1, arr.value_length(0));
4357        assert_eq!(1, arr.value_length(1));
4358        assert_eq!(1, arr.value_length(2));
4359        assert_eq!(1, arr.value_length(3));
4360        assert_eq!(1, arr.value_length(4));
4361        let c = arr.values().as_primitive::<Int32Type>();
4362        assert_eq!(5, c.value(0));
4363        assert_eq!(6, c.value(1));
4364        assert_eq!(7, c.value(2));
4365        assert_eq!(8, c.value(3));
4366        assert_eq!(9, c.value(4));
4367    }
4368
4369    #[test]
4370    fn test_cast_i32_to_list_i32_nullable() {
4371        let array = Int32Array::from(vec![Some(5), None, Some(7), Some(8), Some(9)]);
4372        let b = cast(
4373            &array,
4374            &DataType::List(Arc::new(Field::new_list_field(DataType::Int32, true))),
4375        )
4376        .unwrap();
4377        assert_eq!(5, b.len());
4378        assert_eq!(0, b.null_count());
4379        let arr = b.as_list::<i32>();
4380        assert_eq!(&[0, 1, 2, 3, 4, 5], arr.value_offsets());
4381        assert_eq!(1, arr.value_length(0));
4382        assert_eq!(1, arr.value_length(1));
4383        assert_eq!(1, arr.value_length(2));
4384        assert_eq!(1, arr.value_length(3));
4385        assert_eq!(1, arr.value_length(4));
4386
4387        let c = arr.values().as_primitive::<Int32Type>();
4388        assert_eq!(1, c.null_count());
4389        assert_eq!(5, c.value(0));
4390        assert!(!c.is_valid(1));
4391        assert_eq!(7, c.value(2));
4392        assert_eq!(8, c.value(3));
4393        assert_eq!(9, c.value(4));
4394    }
4395
4396    #[test]
4397    fn test_cast_i32_to_list_f64_nullable_sliced() {
4398        let array = Int32Array::from(vec![Some(5), None, Some(7), Some(8), None, Some(10)]);
4399        let array = array.slice(2, 4);
4400        let b = cast(
4401            &array,
4402            &DataType::List(Arc::new(Field::new_list_field(DataType::Float64, true))),
4403        )
4404        .unwrap();
4405        assert_eq!(4, b.len());
4406        assert_eq!(0, b.null_count());
4407        let arr = b.as_list::<i32>();
4408        assert_eq!(&[0, 1, 2, 3, 4], arr.value_offsets());
4409        assert_eq!(1, arr.value_length(0));
4410        assert_eq!(1, arr.value_length(1));
4411        assert_eq!(1, arr.value_length(2));
4412        assert_eq!(1, arr.value_length(3));
4413        let c = arr.values().as_primitive::<Float64Type>();
4414        assert_eq!(1, c.null_count());
4415        assert_eq!(7.0, c.value(0));
4416        assert_eq!(8.0, c.value(1));
4417        assert!(!c.is_valid(2));
4418        assert_eq!(10.0, c.value(3));
4419    }
4420
4421    #[test]
4422    fn test_cast_int_to_utf8view() {
4423        let inputs = vec![
4424            Arc::new(Int8Array::from(vec![None, Some(8), Some(9), Some(10)])) as ArrayRef,
4425            Arc::new(Int16Array::from(vec![None, Some(8), Some(9), Some(10)])) as ArrayRef,
4426            Arc::new(Int32Array::from(vec![None, Some(8), Some(9), Some(10)])) as ArrayRef,
4427            Arc::new(Int64Array::from(vec![None, Some(8), Some(9), Some(10)])) as ArrayRef,
4428            Arc::new(UInt8Array::from(vec![None, Some(8), Some(9), Some(10)])) as ArrayRef,
4429            Arc::new(UInt16Array::from(vec![None, Some(8), Some(9), Some(10)])) as ArrayRef,
4430            Arc::new(UInt32Array::from(vec![None, Some(8), Some(9), Some(10)])) as ArrayRef,
4431            Arc::new(UInt64Array::from(vec![None, Some(8), Some(9), Some(10)])) as ArrayRef,
4432        ];
4433        let expected: ArrayRef = Arc::new(StringViewArray::from(vec![
4434            None,
4435            Some("8"),
4436            Some("9"),
4437            Some("10"),
4438        ]));
4439
4440        for array in inputs {
4441            assert!(can_cast_types(array.data_type(), &DataType::Utf8View));
4442            let arr = cast(&array, &DataType::Utf8View).unwrap();
4443            assert_eq!(expected.as_ref(), arr.as_ref());
4444        }
4445    }
4446
4447    #[test]
4448    fn test_cast_float_to_utf8view() {
4449        let inputs = vec![
4450            Arc::new(Float16Array::from(vec![
4451                Some(f16::from_f64(1.5)),
4452                Some(f16::from_f64(2.5)),
4453                None,
4454            ])) as ArrayRef,
4455            Arc::new(Float32Array::from(vec![Some(1.5), Some(2.5), None])) as ArrayRef,
4456            Arc::new(Float64Array::from(vec![Some(1.5), Some(2.5), None])) as ArrayRef,
4457        ];
4458
4459        let expected: ArrayRef =
4460            Arc::new(StringViewArray::from(vec![Some("1.5"), Some("2.5"), None]));
4461
4462        for array in inputs {
4463            assert!(can_cast_types(array.data_type(), &DataType::Utf8View));
4464            let arr = cast(&array, &DataType::Utf8View).unwrap();
4465            assert_eq!(expected.as_ref(), arr.as_ref());
4466        }
4467    }
4468
4469    #[test]
4470    fn test_cast_utf8_to_i32() {
4471        let array = StringArray::from(vec!["5", "6", "seven", "8", "9.1"]);
4472        let b = cast(&array, &DataType::Int32).unwrap();
4473        let c = b.as_primitive::<Int32Type>();
4474        assert_eq!(5, c.value(0));
4475        assert_eq!(6, c.value(1));
4476        assert!(!c.is_valid(2));
4477        assert_eq!(8, c.value(3));
4478        assert!(!c.is_valid(4));
4479    }
4480
4481    #[test]
4482    fn test_cast_utf8view_to_i32() {
4483        let array = StringViewArray::from(vec!["5", "6", "seven", "8", "9.1"]);
4484        let b = cast(&array, &DataType::Int32).unwrap();
4485        let c = b.as_primitive::<Int32Type>();
4486        assert_eq!(5, c.value(0));
4487        assert_eq!(6, c.value(1));
4488        assert!(!c.is_valid(2));
4489        assert_eq!(8, c.value(3));
4490        assert!(!c.is_valid(4));
4491    }
4492
4493    #[test]
4494    fn test_cast_utf8view_to_f32() {
4495        let array = StringViewArray::from(vec!["3", "4.56", "seven", "8.9"]);
4496        let b = cast(&array, &DataType::Float32).unwrap();
4497        let c = b.as_primitive::<Float32Type>();
4498        assert_eq!(3.0, c.value(0));
4499        assert_eq!(4.56, c.value(1));
4500        assert!(!c.is_valid(2));
4501        assert_eq!(8.9, c.value(3));
4502    }
4503
4504    #[test]
4505    fn test_cast_utf8view_to_decimal128() {
4506        let array = StringViewArray::from(vec![None, Some("4"), Some("5.6"), Some("7.89")]);
4507        let arr = Arc::new(array) as ArrayRef;
4508        generate_cast_test_case!(
4509            &arr,
4510            Decimal128Array,
4511            &DataType::Decimal128(4, 2),
4512            vec![None, Some(400_i128), Some(560_i128), Some(789_i128)]
4513        );
4514    }
4515
4516    #[test]
4517    fn test_cast_with_options_utf8_to_i32() {
4518        let array = StringArray::from(vec!["5", "6", "seven", "8", "9.1"]);
4519        let result = cast_with_options(
4520            &array,
4521            &DataType::Int32,
4522            &CastOptions {
4523                safe: false,
4524                format_options: FormatOptions::default(),
4525            },
4526        );
4527        match result {
4528            Ok(_) => panic!("expected error"),
4529            Err(e) => {
4530                assert!(
4531                    e.to_string()
4532                        .contains("Cast error: Cannot cast string 'seven' to value of Int32 type",),
4533                    "Error: {e}"
4534                )
4535            }
4536        }
4537    }
4538
4539    #[test]
4540    fn test_cast_utf8_to_bool() {
4541        let strings = StringArray::from(vec!["true", "false", "invalid", " Y ", ""]);
4542        let casted = cast(&strings, &DataType::Boolean).unwrap();
4543        let expected = BooleanArray::from(vec![Some(true), Some(false), None, Some(true), None]);
4544        assert_eq!(*as_boolean_array(&casted), expected);
4545    }
4546
4547    #[test]
4548    fn test_cast_utf8view_to_bool() {
4549        let strings = StringViewArray::from(vec!["true", "false", "invalid", " Y ", ""]);
4550        let casted = cast(&strings, &DataType::Boolean).unwrap();
4551        let expected = BooleanArray::from(vec![Some(true), Some(false), None, Some(true), None]);
4552        assert_eq!(*as_boolean_array(&casted), expected);
4553    }
4554
4555    #[test]
4556    fn test_cast_with_options_utf8_to_bool() {
4557        let strings = StringArray::from(vec!["true", "false", "invalid", " Y ", ""]);
4558        let casted = cast_with_options(
4559            &strings,
4560            &DataType::Boolean,
4561            &CastOptions {
4562                safe: false,
4563                format_options: FormatOptions::default(),
4564            },
4565        );
4566        match casted {
4567            Ok(_) => panic!("expected error"),
4568            Err(e) => {
4569                assert!(
4570                    e.to_string().contains(
4571                        "Cast error: Cannot cast value 'invalid' to value of Boolean type"
4572                    )
4573                )
4574            }
4575        }
4576    }
4577
4578    #[test]
4579    fn test_cast_bool_to_i32() {
4580        let array = BooleanArray::from(vec![Some(true), Some(false), None]);
4581        let b = cast(&array, &DataType::Int32).unwrap();
4582        let c = b.as_primitive::<Int32Type>();
4583        assert_eq!(1, c.value(0));
4584        assert_eq!(0, c.value(1));
4585        assert!(!c.is_valid(2));
4586    }
4587
4588    #[test]
4589    fn test_cast_bool_to_utf8view() {
4590        let array = BooleanArray::from(vec![Some(true), Some(false), None]);
4591        let b = cast(&array, &DataType::Utf8View).unwrap();
4592        let c = b.as_any().downcast_ref::<StringViewArray>().unwrap();
4593        assert_eq!("true", c.value(0));
4594        assert_eq!("false", c.value(1));
4595        assert!(!c.is_valid(2));
4596    }
4597
4598    #[test]
4599    fn test_cast_bool_to_utf8() {
4600        let array = BooleanArray::from(vec![Some(true), Some(false), None]);
4601        let b = cast(&array, &DataType::Utf8).unwrap();
4602        let c = b.as_any().downcast_ref::<StringArray>().unwrap();
4603        assert_eq!("true", c.value(0));
4604        assert_eq!("false", c.value(1));
4605        assert!(!c.is_valid(2));
4606    }
4607
4608    #[test]
4609    fn test_cast_bool_to_large_utf8() {
4610        let array = BooleanArray::from(vec![Some(true), Some(false), None]);
4611        let b = cast(&array, &DataType::LargeUtf8).unwrap();
4612        let c = b.as_any().downcast_ref::<LargeStringArray>().unwrap();
4613        assert_eq!("true", c.value(0));
4614        assert_eq!("false", c.value(1));
4615        assert!(!c.is_valid(2));
4616    }
4617
4618    #[test]
4619    fn test_cast_bool_to_f64() {
4620        let array = BooleanArray::from(vec![Some(true), Some(false), None]);
4621        let b = cast(&array, &DataType::Float64).unwrap();
4622        let c = b.as_primitive::<Float64Type>();
4623        assert_eq!(1.0, c.value(0));
4624        assert_eq!(0.0, c.value(1));
4625        assert!(!c.is_valid(2));
4626    }
4627
4628    #[test]
4629    fn test_cast_integer_to_timestamp() {
4630        let array = Int64Array::from(vec![Some(2), Some(10), None]);
4631        let expected = cast(&array, &DataType::Timestamp(TimeUnit::Microsecond, None)).unwrap();
4632
4633        let array = Int8Array::from(vec![Some(2), Some(10), None]);
4634        let actual = cast(&array, &DataType::Timestamp(TimeUnit::Microsecond, None)).unwrap();
4635
4636        assert_eq!(&actual, &expected);
4637
4638        let array = Int16Array::from(vec![Some(2), Some(10), None]);
4639        let actual = cast(&array, &DataType::Timestamp(TimeUnit::Microsecond, None)).unwrap();
4640
4641        assert_eq!(&actual, &expected);
4642
4643        let array = Int32Array::from(vec![Some(2), Some(10), None]);
4644        let actual = cast(&array, &DataType::Timestamp(TimeUnit::Microsecond, None)).unwrap();
4645
4646        assert_eq!(&actual, &expected);
4647
4648        let array = UInt8Array::from(vec![Some(2), Some(10), None]);
4649        let actual = cast(&array, &DataType::Timestamp(TimeUnit::Microsecond, None)).unwrap();
4650
4651        assert_eq!(&actual, &expected);
4652
4653        let array = UInt16Array::from(vec![Some(2), Some(10), None]);
4654        let actual = cast(&array, &DataType::Timestamp(TimeUnit::Microsecond, None)).unwrap();
4655
4656        assert_eq!(&actual, &expected);
4657
4658        let array = UInt32Array::from(vec![Some(2), Some(10), None]);
4659        let actual = cast(&array, &DataType::Timestamp(TimeUnit::Microsecond, None)).unwrap();
4660
4661        assert_eq!(&actual, &expected);
4662
4663        let array = UInt64Array::from(vec![Some(2), Some(10), None]);
4664        let actual = cast(&array, &DataType::Timestamp(TimeUnit::Microsecond, None)).unwrap();
4665
4666        assert_eq!(&actual, &expected);
4667    }
4668
4669    #[test]
4670    fn test_cast_timestamp_to_integer() {
4671        let array = TimestampMillisecondArray::from(vec![Some(5), Some(1), None])
4672            .with_timezone("UTC".to_string());
4673        let expected = cast(&array, &DataType::Int64).unwrap();
4674
4675        let actual = cast(&cast(&array, &DataType::Int8).unwrap(), &DataType::Int64).unwrap();
4676        assert_eq!(&actual, &expected);
4677
4678        let actual = cast(&cast(&array, &DataType::Int16).unwrap(), &DataType::Int64).unwrap();
4679        assert_eq!(&actual, &expected);
4680
4681        let actual = cast(&cast(&array, &DataType::Int32).unwrap(), &DataType::Int64).unwrap();
4682        assert_eq!(&actual, &expected);
4683
4684        let actual = cast(&cast(&array, &DataType::UInt8).unwrap(), &DataType::Int64).unwrap();
4685        assert_eq!(&actual, &expected);
4686
4687        let actual = cast(&cast(&array, &DataType::UInt16).unwrap(), &DataType::Int64).unwrap();
4688        assert_eq!(&actual, &expected);
4689
4690        let actual = cast(&cast(&array, &DataType::UInt32).unwrap(), &DataType::Int64).unwrap();
4691        assert_eq!(&actual, &expected);
4692
4693        let actual = cast(&cast(&array, &DataType::UInt64).unwrap(), &DataType::Int64).unwrap();
4694        assert_eq!(&actual, &expected);
4695    }
4696
4697    #[test]
4698    fn test_cast_floating_to_timestamp() {
4699        let array = Int64Array::from(vec![Some(2), Some(10), None]);
4700        let expected = cast(&array, &DataType::Timestamp(TimeUnit::Microsecond, None)).unwrap();
4701
4702        let array = Float16Array::from(vec![
4703            Some(f16::from_f32(2.0)),
4704            Some(f16::from_f32(10.6)),
4705            None,
4706        ]);
4707        let actual = cast(&array, &DataType::Timestamp(TimeUnit::Microsecond, None)).unwrap();
4708
4709        assert_eq!(&actual, &expected);
4710
4711        let array = Float32Array::from(vec![Some(2.0), Some(10.6), None]);
4712        let actual = cast(&array, &DataType::Timestamp(TimeUnit::Microsecond, None)).unwrap();
4713
4714        assert_eq!(&actual, &expected);
4715
4716        let array = Float64Array::from(vec![Some(2.1), Some(10.2), None]);
4717        let actual = cast(&array, &DataType::Timestamp(TimeUnit::Microsecond, None)).unwrap();
4718
4719        assert_eq!(&actual, &expected);
4720    }
4721
4722    #[test]
4723    fn test_cast_timestamp_to_floating() {
4724        let array = TimestampMillisecondArray::from(vec![Some(5), Some(1), None])
4725            .with_timezone("UTC".to_string());
4726        let expected = cast(&array, &DataType::Int64).unwrap();
4727
4728        let actual = cast(&cast(&array, &DataType::Float16).unwrap(), &DataType::Int64).unwrap();
4729        assert_eq!(&actual, &expected);
4730
4731        let actual = cast(&cast(&array, &DataType::Float32).unwrap(), &DataType::Int64).unwrap();
4732        assert_eq!(&actual, &expected);
4733
4734        let actual = cast(&cast(&array, &DataType::Float64).unwrap(), &DataType::Int64).unwrap();
4735        assert_eq!(&actual, &expected);
4736    }
4737
4738    #[test]
4739    fn test_cast_decimal_to_timestamp() {
4740        let array = Int64Array::from(vec![Some(2), Some(10), None]);
4741        let expected = cast(&array, &DataType::Timestamp(TimeUnit::Microsecond, None)).unwrap();
4742
4743        let array = Decimal128Array::from(vec![Some(200), Some(1000), None])
4744            .with_precision_and_scale(4, 2)
4745            .unwrap();
4746        let actual = cast(&array, &DataType::Timestamp(TimeUnit::Microsecond, None)).unwrap();
4747
4748        assert_eq!(&actual, &expected);
4749
4750        let array = Decimal256Array::from(vec![
4751            Some(i256::from_i128(2000)),
4752            Some(i256::from_i128(10000)),
4753            None,
4754        ])
4755        .with_precision_and_scale(5, 3)
4756        .unwrap();
4757        let actual = cast(&array, &DataType::Timestamp(TimeUnit::Microsecond, None)).unwrap();
4758
4759        assert_eq!(&actual, &expected);
4760    }
4761
4762    #[test]
4763    fn test_cast_timestamp_to_decimal() {
4764        let array = TimestampMillisecondArray::from(vec![Some(5), Some(1), None])
4765            .with_timezone("UTC".to_string());
4766        let expected = cast(&array, &DataType::Int64).unwrap();
4767
4768        let actual = cast(
4769            &cast(&array, &DataType::Decimal128(5, 2)).unwrap(),
4770            &DataType::Int64,
4771        )
4772        .unwrap();
4773        assert_eq!(&actual, &expected);
4774
4775        let actual = cast(
4776            &cast(&array, &DataType::Decimal256(10, 5)).unwrap(),
4777            &DataType::Int64,
4778        )
4779        .unwrap();
4780        assert_eq!(&actual, &expected);
4781    }
4782
4783    #[test]
4784    fn test_cast_list_i32_to_list_u16() {
4785        let values = vec![
4786            Some(vec![Some(0), Some(0), Some(0)]),
4787            Some(vec![Some(-1), Some(-2), Some(-1)]),
4788            Some(vec![Some(2), Some(100000000)]),
4789        ];
4790        let list_array = ListArray::from_iter_primitive::<Int32Type, _, _>(values);
4791
4792        let target_type = DataType::List(Arc::new(Field::new("item", DataType::UInt16, true)));
4793        assert!(can_cast_types(list_array.data_type(), &target_type));
4794        let cast_array = cast(&list_array, &target_type).unwrap();
4795
4796        // For the ListArray itself, there are no null values (as there were no nulls when they went in)
4797        //
4798        // 3 negative values should get lost when casting to unsigned,
4799        // 1 value should overflow
4800        assert_eq!(0, cast_array.null_count());
4801
4802        // offsets should be the same
4803        let array = cast_array.as_list::<i32>();
4804        assert_eq!(list_array.value_offsets(), array.value_offsets());
4805
4806        assert_eq!(DataType::UInt16, array.value_type());
4807        assert_eq!(3, array.value_length(0));
4808        assert_eq!(3, array.value_length(1));
4809        assert_eq!(2, array.value_length(2));
4810
4811        // expect 4 nulls: negative numbers and overflow
4812        let u16arr = array.values().as_primitive::<UInt16Type>();
4813        assert_eq!(4, u16arr.null_count());
4814
4815        // expect 4 nulls: negative numbers and overflow
4816        let expected: UInt16Array =
4817            vec![Some(0), Some(0), Some(0), None, None, None, Some(2), None]
4818                .into_iter()
4819                .collect();
4820
4821        assert_eq!(u16arr, &expected);
4822    }
4823
4824    #[test]
4825    fn test_cast_list_i32_to_list_timestamp() {
4826        // Construct a value array
4827        let value_data = Int32Array::from(vec![0, 0, 0, -1, -2, -1, 2, 8, 100000000]).into_data();
4828
4829        let value_offsets = Buffer::from_slice_ref([0, 3, 6, 9]);
4830
4831        // Construct a list array from the above two
4832        let list_data_type = DataType::List(Arc::new(Field::new_list_field(DataType::Int32, true)));
4833        let list_data = ArrayData::builder(list_data_type)
4834            .len(3)
4835            .add_buffer(value_offsets)
4836            .add_child_data(value_data)
4837            .build()
4838            .unwrap();
4839        let list_array = Arc::new(ListArray::from(list_data)) as ArrayRef;
4840
4841        let actual = cast(
4842            &list_array,
4843            &DataType::List(Arc::new(Field::new_list_field(
4844                DataType::Timestamp(TimeUnit::Microsecond, None),
4845                true,
4846            ))),
4847        )
4848        .unwrap();
4849
4850        let expected = cast(
4851            &cast(
4852                &list_array,
4853                &DataType::List(Arc::new(Field::new_list_field(DataType::Int64, true))),
4854            )
4855            .unwrap(),
4856            &DataType::List(Arc::new(Field::new_list_field(
4857                DataType::Timestamp(TimeUnit::Microsecond, None),
4858                true,
4859            ))),
4860        )
4861        .unwrap();
4862
4863        assert_eq!(&actual, &expected);
4864    }
4865
4866    #[test]
4867    fn test_cast_date32_to_date64() {
4868        let a = Date32Array::from(vec![10000, 17890]);
4869        let array = Arc::new(a) as ArrayRef;
4870        let b = cast(&array, &DataType::Date64).unwrap();
4871        let c = b.as_primitive::<Date64Type>();
4872        assert_eq!(864000000000, c.value(0));
4873        assert_eq!(1545696000000, c.value(1));
4874    }
4875
4876    #[test]
4877    fn test_cast_date64_to_date32() {
4878        let a = Date64Array::from(vec![Some(864000000005), Some(1545696000001), None]);
4879        let array = Arc::new(a) as ArrayRef;
4880        let b = cast(&array, &DataType::Date32).unwrap();
4881        let c = b.as_primitive::<Date32Type>();
4882        assert_eq!(10000, c.value(0));
4883        assert_eq!(17890, c.value(1));
4884        assert!(c.is_null(2));
4885    }
4886
4887    #[test]
4888    fn test_cast_string_to_integral_overflow() {
4889        let str = Arc::new(StringArray::from(vec![
4890            Some("123"),
4891            Some("-123"),
4892            Some("86374"),
4893            None,
4894        ])) as ArrayRef;
4895
4896        let options = CastOptions {
4897            safe: true,
4898            format_options: FormatOptions::default(),
4899        };
4900        let res = cast_with_options(&str, &DataType::Int16, &options).expect("should cast to i16");
4901        let expected =
4902            Arc::new(Int16Array::from(vec![Some(123), Some(-123), None, None])) as ArrayRef;
4903        assert_eq!(&res, &expected);
4904    }
4905
4906    #[test]
4907    fn test_cast_string_to_timestamp() {
4908        let a0 = Arc::new(StringViewArray::from(vec![
4909            Some("2020-09-08T12:00:00.123456789+00:00"),
4910            Some("Not a valid date"),
4911            None,
4912        ])) as ArrayRef;
4913        let a1 = Arc::new(StringArray::from(vec![
4914            Some("2020-09-08T12:00:00.123456789+00:00"),
4915            Some("Not a valid date"),
4916            None,
4917        ])) as ArrayRef;
4918        let a2 = Arc::new(LargeStringArray::from(vec![
4919            Some("2020-09-08T12:00:00.123456789+00:00"),
4920            Some("Not a valid date"),
4921            None,
4922        ])) as ArrayRef;
4923        for array in &[a0, a1, a2] {
4924            for time_unit in &[
4925                TimeUnit::Second,
4926                TimeUnit::Millisecond,
4927                TimeUnit::Microsecond,
4928                TimeUnit::Nanosecond,
4929            ] {
4930                let to_type = DataType::Timestamp(*time_unit, None);
4931                let b = cast(array, &to_type).unwrap();
4932
4933                match time_unit {
4934                    TimeUnit::Second => {
4935                        let c = b.as_primitive::<TimestampSecondType>();
4936                        assert_eq!(1599566400, c.value(0));
4937                        assert!(c.is_null(1));
4938                        assert!(c.is_null(2));
4939                    }
4940                    TimeUnit::Millisecond => {
4941                        let c = b
4942                            .as_any()
4943                            .downcast_ref::<TimestampMillisecondArray>()
4944                            .unwrap();
4945                        assert_eq!(1599566400123, c.value(0));
4946                        assert!(c.is_null(1));
4947                        assert!(c.is_null(2));
4948                    }
4949                    TimeUnit::Microsecond => {
4950                        let c = b
4951                            .as_any()
4952                            .downcast_ref::<TimestampMicrosecondArray>()
4953                            .unwrap();
4954                        assert_eq!(1599566400123456, c.value(0));
4955                        assert!(c.is_null(1));
4956                        assert!(c.is_null(2));
4957                    }
4958                    TimeUnit::Nanosecond => {
4959                        let c = b
4960                            .as_any()
4961                            .downcast_ref::<TimestampNanosecondArray>()
4962                            .unwrap();
4963                        assert_eq!(1599566400123456789, c.value(0));
4964                        assert!(c.is_null(1));
4965                        assert!(c.is_null(2));
4966                    }
4967                }
4968
4969                let options = CastOptions {
4970                    safe: false,
4971                    format_options: FormatOptions::default(),
4972                };
4973                let err = cast_with_options(array, &to_type, &options).unwrap_err();
4974                assert_eq!(
4975                    err.to_string(),
4976                    "Parser error: Error parsing timestamp from 'Not a valid date': error parsing date"
4977                );
4978            }
4979        }
4980    }
4981
4982    #[test]
4983    fn test_cast_string_to_timestamp_overflow() {
4984        let array = StringArray::from(vec!["9800-09-08T12:00:00.123456789"]);
4985        let result = cast(&array, &DataType::Timestamp(TimeUnit::Second, None)).unwrap();
4986        let result = result.as_primitive::<TimestampSecondType>();
4987        assert_eq!(result.values(), &[247112596800]);
4988    }
4989
4990    #[test]
4991    fn test_cast_string_to_date32() {
4992        let a0 = Arc::new(StringViewArray::from(vec![
4993            Some("2018-12-25"),
4994            Some("Not a valid date"),
4995            None,
4996        ])) as ArrayRef;
4997        let a1 = Arc::new(StringArray::from(vec![
4998            Some("2018-12-25"),
4999            Some("Not a valid date"),
5000            None,
5001        ])) as ArrayRef;
5002        let a2 = Arc::new(LargeStringArray::from(vec![
5003            Some("2018-12-25"),
5004            Some("Not a valid date"),
5005            None,
5006        ])) as ArrayRef;
5007        for array in &[a0, a1, a2] {
5008            let to_type = DataType::Date32;
5009            let b = cast(array, &to_type).unwrap();
5010            let c = b.as_primitive::<Date32Type>();
5011            assert_eq!(17890, c.value(0));
5012            assert!(c.is_null(1));
5013            assert!(c.is_null(2));
5014
5015            let options = CastOptions {
5016                safe: false,
5017                format_options: FormatOptions::default(),
5018            };
5019            let err = cast_with_options(array, &to_type, &options).unwrap_err();
5020            assert_eq!(
5021                err.to_string(),
5022                "Cast error: Cannot cast string 'Not a valid date' to value of Date32 type"
5023            );
5024        }
5025    }
5026
5027    #[test]
5028    fn test_cast_string_with_large_date_to_date32() {
5029        let array = Arc::new(StringArray::from(vec![
5030            Some("+10999-12-31"),
5031            Some("-0010-02-28"),
5032            Some("0010-02-28"),
5033            Some("0000-01-01"),
5034            Some("-0000-01-01"),
5035            Some("-0001-01-01"),
5036        ])) as ArrayRef;
5037        let to_type = DataType::Date32;
5038        let options = CastOptions {
5039            safe: false,
5040            format_options: FormatOptions::default(),
5041        };
5042        let b = cast_with_options(&array, &to_type, &options).unwrap();
5043        let c = b.as_primitive::<Date32Type>();
5044        assert_eq!(3298139, c.value(0)); // 10999-12-31
5045        assert_eq!(-723122, c.value(1)); // -0010-02-28
5046        assert_eq!(-715817, c.value(2)); // 0010-02-28
5047        assert_eq!(c.value(3), c.value(4)); // Expect 0000-01-01 and -0000-01-01 to be parsed the same
5048        assert_eq!(-719528, c.value(3)); // 0000-01-01
5049        assert_eq!(-719528, c.value(4)); // -0000-01-01
5050        assert_eq!(-719893, c.value(5)); // -0001-01-01
5051    }
5052
5053    #[test]
5054    fn test_cast_invalid_string_with_large_date_to_date32() {
5055        // Large dates need to be prefixed with a + or - sign, otherwise they are not parsed correctly
5056        let array = Arc::new(StringArray::from(vec![Some("10999-12-31")])) as ArrayRef;
5057        let to_type = DataType::Date32;
5058        let options = CastOptions {
5059            safe: false,
5060            format_options: FormatOptions::default(),
5061        };
5062        let err = cast_with_options(&array, &to_type, &options).unwrap_err();
5063        assert_eq!(
5064            err.to_string(),
5065            "Cast error: Cannot cast string '10999-12-31' to value of Date32 type"
5066        );
5067    }
5068
5069    #[test]
5070    fn test_cast_string_format_yyyymmdd_to_date32() {
5071        let a0 = Arc::new(StringViewArray::from(vec![
5072            Some("2020-12-25"),
5073            Some("20201117"),
5074        ])) as ArrayRef;
5075        let a1 = Arc::new(StringArray::from(vec![
5076            Some("2020-12-25"),
5077            Some("20201117"),
5078        ])) as ArrayRef;
5079        let a2 = Arc::new(LargeStringArray::from(vec![
5080            Some("2020-12-25"),
5081            Some("20201117"),
5082        ])) as ArrayRef;
5083
5084        for array in &[a0, a1, a2] {
5085            let to_type = DataType::Date32;
5086            let options = CastOptions {
5087                safe: false,
5088                format_options: FormatOptions::default(),
5089            };
5090            let result = cast_with_options(&array, &to_type, &options).unwrap();
5091            let c = result.as_primitive::<Date32Type>();
5092            assert_eq!(
5093                chrono::NaiveDate::from_ymd_opt(2020, 12, 25),
5094                c.value_as_date(0)
5095            );
5096            assert_eq!(
5097                chrono::NaiveDate::from_ymd_opt(2020, 11, 17),
5098                c.value_as_date(1)
5099            );
5100        }
5101    }
5102
5103    #[test]
5104    fn test_cast_string_to_time32second() {
5105        let a0 = Arc::new(StringViewArray::from(vec![
5106            Some("08:08:35.091323414"),
5107            Some("08:08:60.091323414"), // leap second
5108            Some("08:08:61.091323414"), // not valid
5109            Some("Not a valid time"),
5110            None,
5111        ])) as ArrayRef;
5112        let a1 = Arc::new(StringArray::from(vec![
5113            Some("08:08:35.091323414"),
5114            Some("08:08:60.091323414"), // leap second
5115            Some("08:08:61.091323414"), // not valid
5116            Some("Not a valid time"),
5117            None,
5118        ])) as ArrayRef;
5119        let a2 = Arc::new(LargeStringArray::from(vec![
5120            Some("08:08:35.091323414"),
5121            Some("08:08:60.091323414"), // leap second
5122            Some("08:08:61.091323414"), // not valid
5123            Some("Not a valid time"),
5124            None,
5125        ])) as ArrayRef;
5126        for array in &[a0, a1, a2] {
5127            let to_type = DataType::Time32(TimeUnit::Second);
5128            let b = cast(array, &to_type).unwrap();
5129            let c = b.as_primitive::<Time32SecondType>();
5130            assert_eq!(29315, c.value(0));
5131            assert_eq!(29340, c.value(1));
5132            assert!(c.is_null(2));
5133            assert!(c.is_null(3));
5134            assert!(c.is_null(4));
5135
5136            let options = CastOptions {
5137                safe: false,
5138                format_options: FormatOptions::default(),
5139            };
5140            let err = cast_with_options(array, &to_type, &options).unwrap_err();
5141            assert_eq!(
5142                err.to_string(),
5143                "Cast error: Cannot cast string '08:08:61.091323414' to value of Time32(s) type"
5144            );
5145        }
5146    }
5147
5148    #[test]
5149    fn test_cast_string_to_time32millisecond() {
5150        let a0 = Arc::new(StringViewArray::from(vec![
5151            Some("08:08:35.091323414"),
5152            Some("08:08:60.091323414"), // leap second
5153            Some("08:08:61.091323414"), // not valid
5154            Some("Not a valid time"),
5155            None,
5156        ])) as ArrayRef;
5157        let a1 = Arc::new(StringArray::from(vec![
5158            Some("08:08:35.091323414"),
5159            Some("08:08:60.091323414"), // leap second
5160            Some("08:08:61.091323414"), // not valid
5161            Some("Not a valid time"),
5162            None,
5163        ])) as ArrayRef;
5164        let a2 = Arc::new(LargeStringArray::from(vec![
5165            Some("08:08:35.091323414"),
5166            Some("08:08:60.091323414"), // leap second
5167            Some("08:08:61.091323414"), // not valid
5168            Some("Not a valid time"),
5169            None,
5170        ])) as ArrayRef;
5171        for array in &[a0, a1, a2] {
5172            let to_type = DataType::Time32(TimeUnit::Millisecond);
5173            let b = cast(array, &to_type).unwrap();
5174            let c = b.as_primitive::<Time32MillisecondType>();
5175            assert_eq!(29315091, c.value(0));
5176            assert_eq!(29340091, c.value(1));
5177            assert!(c.is_null(2));
5178            assert!(c.is_null(3));
5179            assert!(c.is_null(4));
5180
5181            let options = CastOptions {
5182                safe: false,
5183                format_options: FormatOptions::default(),
5184            };
5185            let err = cast_with_options(array, &to_type, &options).unwrap_err();
5186            assert_eq!(
5187                err.to_string(),
5188                "Cast error: Cannot cast string '08:08:61.091323414' to value of Time32(ms) type"
5189            );
5190        }
5191    }
5192
5193    #[test]
5194    fn test_cast_string_to_time64microsecond() {
5195        let a0 = Arc::new(StringViewArray::from(vec![
5196            Some("08:08:35.091323414"),
5197            Some("Not a valid time"),
5198            None,
5199        ])) as ArrayRef;
5200        let a1 = Arc::new(StringArray::from(vec![
5201            Some("08:08:35.091323414"),
5202            Some("Not a valid time"),
5203            None,
5204        ])) as ArrayRef;
5205        let a2 = Arc::new(LargeStringArray::from(vec![
5206            Some("08:08:35.091323414"),
5207            Some("Not a valid time"),
5208            None,
5209        ])) as ArrayRef;
5210        for array in &[a0, a1, a2] {
5211            let to_type = DataType::Time64(TimeUnit::Microsecond);
5212            let b = cast(array, &to_type).unwrap();
5213            let c = b.as_primitive::<Time64MicrosecondType>();
5214            assert_eq!(29315091323, c.value(0));
5215            assert!(c.is_null(1));
5216            assert!(c.is_null(2));
5217
5218            let options = CastOptions {
5219                safe: false,
5220                format_options: FormatOptions::default(),
5221            };
5222            let err = cast_with_options(array, &to_type, &options).unwrap_err();
5223            assert_eq!(
5224                err.to_string(),
5225                "Cast error: Cannot cast string 'Not a valid time' to value of Time64(µs) type"
5226            );
5227        }
5228    }
5229
5230    #[test]
5231    fn test_cast_string_to_time64nanosecond() {
5232        let a0 = Arc::new(StringViewArray::from(vec![
5233            Some("08:08:35.091323414"),
5234            Some("Not a valid time"),
5235            None,
5236        ])) as ArrayRef;
5237        let a1 = Arc::new(StringArray::from(vec![
5238            Some("08:08:35.091323414"),
5239            Some("Not a valid time"),
5240            None,
5241        ])) as ArrayRef;
5242        let a2 = Arc::new(LargeStringArray::from(vec![
5243            Some("08:08:35.091323414"),
5244            Some("Not a valid time"),
5245            None,
5246        ])) as ArrayRef;
5247        for array in &[a0, a1, a2] {
5248            let to_type = DataType::Time64(TimeUnit::Nanosecond);
5249            let b = cast(array, &to_type).unwrap();
5250            let c = b.as_primitive::<Time64NanosecondType>();
5251            assert_eq!(29315091323414, c.value(0));
5252            assert!(c.is_null(1));
5253            assert!(c.is_null(2));
5254
5255            let options = CastOptions {
5256                safe: false,
5257                format_options: FormatOptions::default(),
5258            };
5259            let err = cast_with_options(array, &to_type, &options).unwrap_err();
5260            assert_eq!(
5261                err.to_string(),
5262                "Cast error: Cannot cast string 'Not a valid time' to value of Time64(ns) type"
5263            );
5264        }
5265    }
5266
5267    #[test]
5268    fn test_cast_string_to_date64() {
5269        let a0 = Arc::new(StringViewArray::from(vec![
5270            Some("2020-09-08T12:00:00"),
5271            Some("Not a valid date"),
5272            None,
5273        ])) as ArrayRef;
5274        let a1 = Arc::new(StringArray::from(vec![
5275            Some("2020-09-08T12:00:00"),
5276            Some("Not a valid date"),
5277            None,
5278        ])) as ArrayRef;
5279        let a2 = Arc::new(LargeStringArray::from(vec![
5280            Some("2020-09-08T12:00:00"),
5281            Some("Not a valid date"),
5282            None,
5283        ])) as ArrayRef;
5284        for array in &[a0, a1, a2] {
5285            let to_type = DataType::Date64;
5286            let b = cast(array, &to_type).unwrap();
5287            let c = b.as_primitive::<Date64Type>();
5288            assert_eq!(1599566400000, c.value(0));
5289            assert!(c.is_null(1));
5290            assert!(c.is_null(2));
5291
5292            let options = CastOptions {
5293                safe: false,
5294                format_options: FormatOptions::default(),
5295            };
5296            let err = cast_with_options(array, &to_type, &options).unwrap_err();
5297            assert_eq!(
5298                err.to_string(),
5299                "Cast error: Cannot cast string 'Not a valid date' to value of Date64 type"
5300            );
5301        }
5302    }
5303
5304    macro_rules! test_safe_string_to_interval {
5305        ($data_vec:expr, $interval_unit:expr, $array_ty:ty, $expect_vec:expr) => {
5306            let source_string_array = Arc::new(StringArray::from($data_vec.clone())) as ArrayRef;
5307
5308            let options = CastOptions {
5309                safe: true,
5310                format_options: FormatOptions::default(),
5311            };
5312
5313            let target_interval_array = cast_with_options(
5314                &source_string_array.clone(),
5315                &DataType::Interval($interval_unit),
5316                &options,
5317            )
5318            .unwrap()
5319            .as_any()
5320            .downcast_ref::<$array_ty>()
5321            .unwrap()
5322            .clone() as $array_ty;
5323
5324            let target_string_array =
5325                cast_with_options(&target_interval_array, &DataType::Utf8, &options)
5326                    .unwrap()
5327                    .as_any()
5328                    .downcast_ref::<StringArray>()
5329                    .unwrap()
5330                    .clone();
5331
5332            let expect_string_array = StringArray::from($expect_vec);
5333
5334            assert_eq!(target_string_array, expect_string_array);
5335
5336            let target_large_string_array =
5337                cast_with_options(&target_interval_array, &DataType::LargeUtf8, &options)
5338                    .unwrap()
5339                    .as_any()
5340                    .downcast_ref::<LargeStringArray>()
5341                    .unwrap()
5342                    .clone();
5343
5344            let expect_large_string_array = LargeStringArray::from($expect_vec);
5345
5346            assert_eq!(target_large_string_array, expect_large_string_array);
5347        };
5348    }
5349
5350    #[test]
5351    fn test_cast_string_to_interval_year_month() {
5352        test_safe_string_to_interval!(
5353            vec![
5354                Some("1 year 1 month"),
5355                Some("1.5 years 13 month"),
5356                Some("30 days"),
5357                Some("31 days"),
5358                Some("2 months 31 days"),
5359                Some("2 months 31 days 1 second"),
5360                Some("foobar"),
5361            ],
5362            IntervalUnit::YearMonth,
5363            IntervalYearMonthArray,
5364            vec![
5365                Some("1 years 1 mons"),
5366                Some("2 years 7 mons"),
5367                None,
5368                None,
5369                None,
5370                None,
5371                None,
5372            ]
5373        );
5374    }
5375
5376    #[test]
5377    fn test_cast_string_to_interval_day_time() {
5378        test_safe_string_to_interval!(
5379            vec![
5380                Some("1 year 1 month"),
5381                Some("1.5 years 13 month"),
5382                Some("30 days"),
5383                Some("1 day 2 second 3.5 milliseconds"),
5384                Some("foobar"),
5385            ],
5386            IntervalUnit::DayTime,
5387            IntervalDayTimeArray,
5388            vec![
5389                Some("390 days"),
5390                Some("930 days"),
5391                Some("30 days"),
5392                None,
5393                None,
5394            ]
5395        );
5396    }
5397
5398    #[test]
5399    fn test_cast_string_to_interval_month_day_nano() {
5400        test_safe_string_to_interval!(
5401            vec![
5402                Some("1 year 1 month 1 day"),
5403                None,
5404                Some("1.5 years 13 month 35 days 1.4 milliseconds"),
5405                Some("3 days"),
5406                Some("8 seconds"),
5407                None,
5408                Some("1 day 29800 milliseconds"),
5409                Some("3 months 1 second"),
5410                Some("6 minutes 120 second"),
5411                Some("2 years 39 months 9 days 19 hours 1 minute 83 seconds 399222 milliseconds"),
5412                Some("foobar"),
5413            ],
5414            IntervalUnit::MonthDayNano,
5415            IntervalMonthDayNanoArray,
5416            vec![
5417                Some("13 mons 1 days"),
5418                None,
5419                Some("31 mons 35 days 0.001400000 secs"),
5420                Some("3 days"),
5421                Some("8.000000000 secs"),
5422                None,
5423                Some("1 days 29.800000000 secs"),
5424                Some("3 mons 1.000000000 secs"),
5425                Some("8 mins"),
5426                Some("63 mons 9 days 19 hours 9 mins 2.222000000 secs"),
5427                None,
5428            ]
5429        );
5430    }
5431
5432    macro_rules! test_unsafe_string_to_interval_err {
5433        ($data_vec:expr, $interval_unit:expr, $error_msg:expr) => {
5434            let string_array = Arc::new(StringArray::from($data_vec.clone())) as ArrayRef;
5435            let options = CastOptions {
5436                safe: false,
5437                format_options: FormatOptions::default(),
5438            };
5439            let arrow_err = cast_with_options(
5440                &string_array.clone(),
5441                &DataType::Interval($interval_unit),
5442                &options,
5443            )
5444            .unwrap_err();
5445            assert_eq!($error_msg, arrow_err.to_string());
5446        };
5447    }
5448
5449    #[test]
5450    fn test_cast_string_to_interval_err() {
5451        test_unsafe_string_to_interval_err!(
5452            vec![Some("foobar")],
5453            IntervalUnit::YearMonth,
5454            r#"Parser error: Invalid input syntax for type interval: "foobar""#
5455        );
5456        test_unsafe_string_to_interval_err!(
5457            vec![Some("foobar")],
5458            IntervalUnit::DayTime,
5459            r#"Parser error: Invalid input syntax for type interval: "foobar""#
5460        );
5461        test_unsafe_string_to_interval_err!(
5462            vec![Some("foobar")],
5463            IntervalUnit::MonthDayNano,
5464            r#"Parser error: Invalid input syntax for type interval: "foobar""#
5465        );
5466        test_unsafe_string_to_interval_err!(
5467            vec![Some("2 months 31 days 1 second")],
5468            IntervalUnit::YearMonth,
5469            r#"Cast error: Cannot cast 2 months 31 days 1 second to IntervalYearMonth. Only year and month fields are allowed."#
5470        );
5471        test_unsafe_string_to_interval_err!(
5472            vec![Some("1 day 1.5 milliseconds")],
5473            IntervalUnit::DayTime,
5474            r#"Cast error: Cannot cast 1 day 1.5 milliseconds to IntervalDayTime because the nanos part isn't multiple of milliseconds"#
5475        );
5476
5477        // overflow
5478        test_unsafe_string_to_interval_err!(
5479            vec![Some(format!(
5480                "{} century {} year {} month",
5481                i64::MAX - 2,
5482                i64::MAX - 2,
5483                i64::MAX - 2
5484            ))],
5485            IntervalUnit::DayTime,
5486            format!(
5487                "Arithmetic overflow: Overflow happened on: {} * 100",
5488                i64::MAX - 2
5489            )
5490        );
5491        test_unsafe_string_to_interval_err!(
5492            vec![Some(format!(
5493                "{} year {} month {} day",
5494                i64::MAX - 2,
5495                i64::MAX - 2,
5496                i64::MAX - 2
5497            ))],
5498            IntervalUnit::MonthDayNano,
5499            format!(
5500                "Arithmetic overflow: Overflow happened on: {} * 12",
5501                i64::MAX - 2
5502            )
5503        );
5504    }
5505
5506    #[test]
5507    fn test_cast_binary_to_fixed_size_binary() {
5508        let bytes_1 = "Hiiii".as_bytes();
5509        let bytes_2 = "Hello".as_bytes();
5510
5511        let binary_data = vec![Some(bytes_1), Some(bytes_2), None];
5512        let a1 = Arc::new(BinaryArray::from(binary_data.clone())) as ArrayRef;
5513        let a2 = Arc::new(LargeBinaryArray::from(binary_data)) as ArrayRef;
5514
5515        let array_ref = cast(&a1, &DataType::FixedSizeBinary(5)).unwrap();
5516        let down_cast = array_ref
5517            .as_any()
5518            .downcast_ref::<FixedSizeBinaryArray>()
5519            .unwrap();
5520        assert_eq!(bytes_1, down_cast.value(0));
5521        assert_eq!(bytes_2, down_cast.value(1));
5522        assert!(down_cast.is_null(2));
5523
5524        let array_ref = cast(&a2, &DataType::FixedSizeBinary(5)).unwrap();
5525        let down_cast = array_ref
5526            .as_any()
5527            .downcast_ref::<FixedSizeBinaryArray>()
5528            .unwrap();
5529        assert_eq!(bytes_1, down_cast.value(0));
5530        assert_eq!(bytes_2, down_cast.value(1));
5531        assert!(down_cast.is_null(2));
5532
5533        // test error cases when the length of binary are not same
5534        let bytes_1 = "Hi".as_bytes();
5535        let bytes_2 = "Hello".as_bytes();
5536
5537        let binary_data = vec![Some(bytes_1), Some(bytes_2), None];
5538        let a1 = Arc::new(BinaryArray::from(binary_data.clone())) as ArrayRef;
5539        let a2 = Arc::new(LargeBinaryArray::from(binary_data)) as ArrayRef;
5540
5541        let array_ref = cast_with_options(
5542            &a1,
5543            &DataType::FixedSizeBinary(5),
5544            &CastOptions {
5545                safe: false,
5546                format_options: FormatOptions::default(),
5547            },
5548        );
5549        assert!(array_ref.is_err());
5550
5551        let array_ref = cast_with_options(
5552            &a2,
5553            &DataType::FixedSizeBinary(5),
5554            &CastOptions {
5555                safe: false,
5556                format_options: FormatOptions::default(),
5557            },
5558        );
5559        assert!(array_ref.is_err());
5560    }
5561
5562    #[test]
5563    fn test_fixed_size_binary_to_binary() {
5564        let bytes_1 = "Hiiii".as_bytes();
5565        let bytes_2 = "Hello".as_bytes();
5566
5567        let binary_data = vec![Some(bytes_1), Some(bytes_2), None];
5568        let a1 = Arc::new(FixedSizeBinaryArray::from(binary_data.clone())) as ArrayRef;
5569
5570        let array_ref = cast(&a1, &DataType::Binary).unwrap();
5571        let down_cast = array_ref.as_binary::<i32>();
5572        assert_eq!(bytes_1, down_cast.value(0));
5573        assert_eq!(bytes_2, down_cast.value(1));
5574        assert!(down_cast.is_null(2));
5575
5576        let array_ref = cast(&a1, &DataType::LargeBinary).unwrap();
5577        let down_cast = array_ref.as_binary::<i64>();
5578        assert_eq!(bytes_1, down_cast.value(0));
5579        assert_eq!(bytes_2, down_cast.value(1));
5580        assert!(down_cast.is_null(2));
5581
5582        let array_ref = cast(&a1, &DataType::BinaryView).unwrap();
5583        let down_cast = array_ref.as_binary_view();
5584        assert_eq!(bytes_1, down_cast.value(0));
5585        assert_eq!(bytes_2, down_cast.value(1));
5586        assert!(down_cast.is_null(2));
5587    }
5588
5589    #[test]
5590    fn test_fixed_size_binary_to_dictionary() {
5591        let bytes_1 = "Hiiii".as_bytes();
5592        let bytes_2 = "Hello".as_bytes();
5593
5594        let binary_data = vec![Some(bytes_1), Some(bytes_2), Some(bytes_1), None];
5595        let a1 = Arc::new(FixedSizeBinaryArray::from(binary_data.clone())) as ArrayRef;
5596
5597        let cast_type = DataType::Dictionary(
5598            Box::new(DataType::Int8),
5599            Box::new(DataType::FixedSizeBinary(5)),
5600        );
5601        let cast_array = cast(&a1, &cast_type).unwrap();
5602        assert_eq!(cast_array.data_type(), &cast_type);
5603        assert_eq!(
5604            array_to_strings(&cast_array),
5605            vec!["4869696969", "48656c6c6f", "4869696969", "null"]
5606        );
5607        // dictionary should only have two distinct values
5608        let dict_array = cast_array
5609            .as_any()
5610            .downcast_ref::<DictionaryArray<Int8Type>>()
5611            .unwrap();
5612        assert_eq!(dict_array.values().len(), 2);
5613    }
5614
5615    #[test]
5616    fn test_binary_to_dictionary() {
5617        let mut builder = GenericBinaryBuilder::<i32>::new();
5618        builder.append_value(b"hello");
5619        builder.append_value(b"hiiii");
5620        builder.append_value(b"hiiii"); // duplicate
5621        builder.append_null();
5622        builder.append_value(b"rustt");
5623
5624        let a1 = builder.finish();
5625
5626        let cast_type = DataType::Dictionary(
5627            Box::new(DataType::Int8),
5628            Box::new(DataType::FixedSizeBinary(5)),
5629        );
5630        let cast_array = cast(&a1, &cast_type).unwrap();
5631        assert_eq!(cast_array.data_type(), &cast_type);
5632        assert_eq!(
5633            array_to_strings(&cast_array),
5634            vec![
5635                "68656c6c6f",
5636                "6869696969",
5637                "6869696969",
5638                "null",
5639                "7275737474"
5640            ]
5641        );
5642        // dictionary should only have three distinct values
5643        let dict_array = cast_array
5644            .as_any()
5645            .downcast_ref::<DictionaryArray<Int8Type>>()
5646            .unwrap();
5647        assert_eq!(dict_array.values().len(), 3);
5648    }
5649
5650    #[test]
5651    fn test_numeric_to_binary() {
5652        let a = Int16Array::from(vec![Some(1), Some(511), None]);
5653
5654        let array_ref = cast(&a, &DataType::Binary).unwrap();
5655        let down_cast = array_ref.as_binary::<i32>();
5656        assert_eq!(&1_i16.to_le_bytes(), down_cast.value(0));
5657        assert_eq!(&511_i16.to_le_bytes(), down_cast.value(1));
5658        assert!(down_cast.is_null(2));
5659
5660        let a = Int64Array::from(vec![Some(-1), Some(123456789), None]);
5661
5662        let array_ref = cast(&a, &DataType::Binary).unwrap();
5663        let down_cast = array_ref.as_binary::<i32>();
5664        assert_eq!(&(-1_i64).to_le_bytes(), down_cast.value(0));
5665        assert_eq!(&123456789_i64.to_le_bytes(), down_cast.value(1));
5666        assert!(down_cast.is_null(2));
5667    }
5668
5669    #[test]
5670    fn test_numeric_to_large_binary() {
5671        let a = Int16Array::from(vec![Some(1), Some(511), None]);
5672
5673        let array_ref = cast(&a, &DataType::LargeBinary).unwrap();
5674        let down_cast = array_ref.as_binary::<i64>();
5675        assert_eq!(&1_i16.to_le_bytes(), down_cast.value(0));
5676        assert_eq!(&511_i16.to_le_bytes(), down_cast.value(1));
5677        assert!(down_cast.is_null(2));
5678
5679        let a = Int64Array::from(vec![Some(-1), Some(123456789), None]);
5680
5681        let array_ref = cast(&a, &DataType::LargeBinary).unwrap();
5682        let down_cast = array_ref.as_binary::<i64>();
5683        assert_eq!(&(-1_i64).to_le_bytes(), down_cast.value(0));
5684        assert_eq!(&123456789_i64.to_le_bytes(), down_cast.value(1));
5685        assert!(down_cast.is_null(2));
5686    }
5687
5688    #[test]
5689    fn test_cast_date32_to_int32() {
5690        let array = Date32Array::from(vec![10000, 17890]);
5691        let b = cast(&array, &DataType::Int32).unwrap();
5692        let c = b.as_primitive::<Int32Type>();
5693        assert_eq!(10000, c.value(0));
5694        assert_eq!(17890, c.value(1));
5695    }
5696
5697    #[test]
5698    fn test_cast_int32_to_date32() {
5699        let array = Int32Array::from(vec![10000, 17890]);
5700        let b = cast(&array, &DataType::Date32).unwrap();
5701        let c = b.as_primitive::<Date32Type>();
5702        assert_eq!(10000, c.value(0));
5703        assert_eq!(17890, c.value(1));
5704    }
5705
5706    #[test]
5707    fn test_cast_timestamp_to_date32() {
5708        let array =
5709            TimestampMillisecondArray::from(vec![Some(864000000005), Some(1545696000001), None])
5710                .with_timezone("+00:00".to_string());
5711        let b = cast(&array, &DataType::Date32).unwrap();
5712        let c = b.as_primitive::<Date32Type>();
5713        assert_eq!(10000, c.value(0));
5714        assert_eq!(17890, c.value(1));
5715        assert!(c.is_null(2));
5716    }
5717    #[test]
5718    fn test_cast_timestamp_to_date32_zone() {
5719        let strings = StringArray::from_iter([
5720            Some("1970-01-01T00:00:01"),
5721            Some("1970-01-01T23:59:59"),
5722            None,
5723            Some("2020-03-01T02:00:23+00:00"),
5724        ]);
5725        let dt = DataType::Timestamp(TimeUnit::Millisecond, Some("-07:00".into()));
5726        let timestamps = cast(&strings, &dt).unwrap();
5727        let dates = cast(timestamps.as_ref(), &DataType::Date32).unwrap();
5728
5729        let c = dates.as_primitive::<Date32Type>();
5730        let expected = NaiveDate::from_ymd_opt(1970, 1, 1).unwrap();
5731        assert_eq!(c.value_as_date(0).unwrap(), expected);
5732        assert_eq!(c.value_as_date(1).unwrap(), expected);
5733        assert!(c.is_null(2));
5734        let expected = NaiveDate::from_ymd_opt(2020, 2, 29).unwrap();
5735        assert_eq!(c.value_as_date(3).unwrap(), expected);
5736    }
5737    #[test]
5738    fn test_cast_timestamp_to_date64() {
5739        let array =
5740            TimestampMillisecondArray::from(vec![Some(864000000005), Some(1545696000001), None]);
5741        let b = cast(&array, &DataType::Date64).unwrap();
5742        let c = b.as_primitive::<Date64Type>();
5743        assert_eq!(864000000005, c.value(0));
5744        assert_eq!(1545696000001, c.value(1));
5745        assert!(c.is_null(2));
5746
5747        let array = TimestampSecondArray::from(vec![Some(864000000005), Some(1545696000001)]);
5748        let b = cast(&array, &DataType::Date64).unwrap();
5749        let c = b.as_primitive::<Date64Type>();
5750        assert_eq!(864000000005000, c.value(0));
5751        assert_eq!(1545696000001000, c.value(1));
5752
5753        // test overflow, safe cast
5754        let array = TimestampSecondArray::from(vec![Some(i64::MAX)]);
5755        let b = cast(&array, &DataType::Date64).unwrap();
5756        assert!(b.is_null(0));
5757        // test overflow, unsafe cast
5758        let array = TimestampSecondArray::from(vec![Some(i64::MAX)]);
5759        let options = CastOptions {
5760            safe: false,
5761            format_options: FormatOptions::default(),
5762        };
5763        let b = cast_with_options(&array, &DataType::Date64, &options);
5764        assert!(b.is_err());
5765    }
5766
5767    #[test]
5768    fn test_cast_timestamp_to_time64() {
5769        // test timestamp secs
5770        let array = TimestampSecondArray::from(vec![Some(86405), Some(1), None])
5771            .with_timezone("+01:00".to_string());
5772        let b = cast(&array, &DataType::Time64(TimeUnit::Microsecond)).unwrap();
5773        let c = b.as_primitive::<Time64MicrosecondType>();
5774        assert_eq!(3605000000, c.value(0));
5775        assert_eq!(3601000000, c.value(1));
5776        assert!(c.is_null(2));
5777        let b = cast(&array, &DataType::Time64(TimeUnit::Nanosecond)).unwrap();
5778        let c = b.as_primitive::<Time64NanosecondType>();
5779        assert_eq!(3605000000000, c.value(0));
5780        assert_eq!(3601000000000, c.value(1));
5781        assert!(c.is_null(2));
5782
5783        // test timestamp milliseconds
5784        let a = TimestampMillisecondArray::from(vec![Some(86405000), Some(1000), None])
5785            .with_timezone("+01:00".to_string());
5786        let array = Arc::new(a) as ArrayRef;
5787        let b = cast(&array, &DataType::Time64(TimeUnit::Microsecond)).unwrap();
5788        let c = b.as_primitive::<Time64MicrosecondType>();
5789        assert_eq!(3605000000, c.value(0));
5790        assert_eq!(3601000000, c.value(1));
5791        assert!(c.is_null(2));
5792        let b = cast(&array, &DataType::Time64(TimeUnit::Nanosecond)).unwrap();
5793        let c = b.as_primitive::<Time64NanosecondType>();
5794        assert_eq!(3605000000000, c.value(0));
5795        assert_eq!(3601000000000, c.value(1));
5796        assert!(c.is_null(2));
5797
5798        // test timestamp microseconds
5799        let a = TimestampMicrosecondArray::from(vec![Some(86405000000), Some(1000000), None])
5800            .with_timezone("+01:00".to_string());
5801        let array = Arc::new(a) as ArrayRef;
5802        let b = cast(&array, &DataType::Time64(TimeUnit::Microsecond)).unwrap();
5803        let c = b.as_primitive::<Time64MicrosecondType>();
5804        assert_eq!(3605000000, c.value(0));
5805        assert_eq!(3601000000, c.value(1));
5806        assert!(c.is_null(2));
5807        let b = cast(&array, &DataType::Time64(TimeUnit::Nanosecond)).unwrap();
5808        let c = b.as_primitive::<Time64NanosecondType>();
5809        assert_eq!(3605000000000, c.value(0));
5810        assert_eq!(3601000000000, c.value(1));
5811        assert!(c.is_null(2));
5812
5813        // test timestamp nanoseconds
5814        let a = TimestampNanosecondArray::from(vec![Some(86405000000000), Some(1000000000), None])
5815            .with_timezone("+01:00".to_string());
5816        let array = Arc::new(a) as ArrayRef;
5817        let b = cast(&array, &DataType::Time64(TimeUnit::Microsecond)).unwrap();
5818        let c = b.as_primitive::<Time64MicrosecondType>();
5819        assert_eq!(3605000000, c.value(0));
5820        assert_eq!(3601000000, c.value(1));
5821        assert!(c.is_null(2));
5822        let b = cast(&array, &DataType::Time64(TimeUnit::Nanosecond)).unwrap();
5823        let c = b.as_primitive::<Time64NanosecondType>();
5824        assert_eq!(3605000000000, c.value(0));
5825        assert_eq!(3601000000000, c.value(1));
5826        assert!(c.is_null(2));
5827
5828        // test overflow
5829        let a =
5830            TimestampSecondArray::from(vec![Some(i64::MAX)]).with_timezone("+01:00".to_string());
5831        let array = Arc::new(a) as ArrayRef;
5832        let b = cast(&array, &DataType::Time64(TimeUnit::Microsecond));
5833        assert!(b.is_err());
5834        let b = cast(&array, &DataType::Time64(TimeUnit::Nanosecond));
5835        assert!(b.is_err());
5836        let b = cast(&array, &DataType::Time64(TimeUnit::Millisecond));
5837        assert!(b.is_err());
5838    }
5839
5840    #[test]
5841    fn test_cast_timestamp_to_time32() {
5842        // test timestamp secs
5843        let a = TimestampSecondArray::from(vec![Some(86405), Some(1), None])
5844            .with_timezone("+01:00".to_string());
5845        let array = Arc::new(a) as ArrayRef;
5846        let b = cast(&array, &DataType::Time32(TimeUnit::Second)).unwrap();
5847        let c = b.as_primitive::<Time32SecondType>();
5848        assert_eq!(3605, c.value(0));
5849        assert_eq!(3601, c.value(1));
5850        assert!(c.is_null(2));
5851        let b = cast(&array, &DataType::Time32(TimeUnit::Millisecond)).unwrap();
5852        let c = b.as_primitive::<Time32MillisecondType>();
5853        assert_eq!(3605000, c.value(0));
5854        assert_eq!(3601000, c.value(1));
5855        assert!(c.is_null(2));
5856
5857        // test timestamp milliseconds
5858        let a = TimestampMillisecondArray::from(vec![Some(86405000), Some(1000), None])
5859            .with_timezone("+01:00".to_string());
5860        let array = Arc::new(a) as ArrayRef;
5861        let b = cast(&array, &DataType::Time32(TimeUnit::Second)).unwrap();
5862        let c = b.as_primitive::<Time32SecondType>();
5863        assert_eq!(3605, c.value(0));
5864        assert_eq!(3601, c.value(1));
5865        assert!(c.is_null(2));
5866        let b = cast(&array, &DataType::Time32(TimeUnit::Millisecond)).unwrap();
5867        let c = b.as_primitive::<Time32MillisecondType>();
5868        assert_eq!(3605000, c.value(0));
5869        assert_eq!(3601000, c.value(1));
5870        assert!(c.is_null(2));
5871
5872        // test timestamp microseconds
5873        let a = TimestampMicrosecondArray::from(vec![Some(86405000000), Some(1000000), None])
5874            .with_timezone("+01:00".to_string());
5875        let array = Arc::new(a) as ArrayRef;
5876        let b = cast(&array, &DataType::Time32(TimeUnit::Second)).unwrap();
5877        let c = b.as_primitive::<Time32SecondType>();
5878        assert_eq!(3605, c.value(0));
5879        assert_eq!(3601, c.value(1));
5880        assert!(c.is_null(2));
5881        let b = cast(&array, &DataType::Time32(TimeUnit::Millisecond)).unwrap();
5882        let c = b.as_primitive::<Time32MillisecondType>();
5883        assert_eq!(3605000, c.value(0));
5884        assert_eq!(3601000, c.value(1));
5885        assert!(c.is_null(2));
5886
5887        // test timestamp nanoseconds
5888        let a = TimestampNanosecondArray::from(vec![Some(86405000000000), Some(1000000000), None])
5889            .with_timezone("+01:00".to_string());
5890        let array = Arc::new(a) as ArrayRef;
5891        let b = cast(&array, &DataType::Time32(TimeUnit::Second)).unwrap();
5892        let c = b.as_primitive::<Time32SecondType>();
5893        assert_eq!(3605, c.value(0));
5894        assert_eq!(3601, c.value(1));
5895        assert!(c.is_null(2));
5896        let b = cast(&array, &DataType::Time32(TimeUnit::Millisecond)).unwrap();
5897        let c = b.as_primitive::<Time32MillisecondType>();
5898        assert_eq!(3605000, c.value(0));
5899        assert_eq!(3601000, c.value(1));
5900        assert!(c.is_null(2));
5901
5902        // test overflow
5903        let a =
5904            TimestampSecondArray::from(vec![Some(i64::MAX)]).with_timezone("+01:00".to_string());
5905        let array = Arc::new(a) as ArrayRef;
5906        let b = cast(&array, &DataType::Time32(TimeUnit::Second));
5907        assert!(b.is_err());
5908        let b = cast(&array, &DataType::Time32(TimeUnit::Millisecond));
5909        assert!(b.is_err());
5910    }
5911
5912    // Cast Timestamp(_, None) -> Timestamp(_, Some(timezone))
5913    #[test]
5914    fn test_cast_timestamp_with_timezone_1() {
5915        let string_array: Arc<dyn Array> = Arc::new(StringArray::from(vec![
5916            Some("2000-01-01T00:00:00.123456789"),
5917            Some("2010-01-01T00:00:00.123456789"),
5918            None,
5919        ]));
5920        let to_type = DataType::Timestamp(TimeUnit::Nanosecond, None);
5921        let timestamp_array = cast(&string_array, &to_type).unwrap();
5922
5923        let to_type = DataType::Timestamp(TimeUnit::Microsecond, Some("+0700".into()));
5924        let timestamp_array = cast(&timestamp_array, &to_type).unwrap();
5925
5926        let string_array = cast(&timestamp_array, &DataType::Utf8).unwrap();
5927        let result = string_array.as_string::<i32>();
5928        assert_eq!("2000-01-01T00:00:00.123456+07:00", result.value(0));
5929        assert_eq!("2010-01-01T00:00:00.123456+07:00", result.value(1));
5930        assert!(result.is_null(2));
5931    }
5932
5933    // Cast Timestamp(_, Some(timezone)) -> Timestamp(_, None)
5934    #[test]
5935    fn test_cast_timestamp_with_timezone_2() {
5936        let string_array: Arc<dyn Array> = Arc::new(StringArray::from(vec![
5937            Some("2000-01-01T07:00:00.123456789"),
5938            Some("2010-01-01T07:00:00.123456789"),
5939            None,
5940        ]));
5941        let to_type = DataType::Timestamp(TimeUnit::Millisecond, Some("+0700".into()));
5942        let timestamp_array = cast(&string_array, &to_type).unwrap();
5943
5944        // Check intermediate representation is correct
5945        let string_array = cast(&timestamp_array, &DataType::Utf8).unwrap();
5946        let result = string_array.as_string::<i32>();
5947        assert_eq!("2000-01-01T07:00:00.123+07:00", result.value(0));
5948        assert_eq!("2010-01-01T07:00:00.123+07:00", result.value(1));
5949        assert!(result.is_null(2));
5950
5951        let to_type = DataType::Timestamp(TimeUnit::Nanosecond, None);
5952        let timestamp_array = cast(&timestamp_array, &to_type).unwrap();
5953
5954        let string_array = cast(&timestamp_array, &DataType::Utf8).unwrap();
5955        let result = string_array.as_string::<i32>();
5956        assert_eq!("2000-01-01T00:00:00.123", result.value(0));
5957        assert_eq!("2010-01-01T00:00:00.123", result.value(1));
5958        assert!(result.is_null(2));
5959    }
5960
5961    // Cast Timestamp(_, Some(timezone)) -> Timestamp(_, Some(timezone))
5962    #[test]
5963    fn test_cast_timestamp_with_timezone_3() {
5964        let string_array: Arc<dyn Array> = Arc::new(StringArray::from(vec![
5965            Some("2000-01-01T07:00:00.123456789"),
5966            Some("2010-01-01T07:00:00.123456789"),
5967            None,
5968        ]));
5969        let to_type = DataType::Timestamp(TimeUnit::Microsecond, Some("+0700".into()));
5970        let timestamp_array = cast(&string_array, &to_type).unwrap();
5971
5972        // Check intermediate representation is correct
5973        let string_array = cast(&timestamp_array, &DataType::Utf8).unwrap();
5974        let result = string_array.as_string::<i32>();
5975        assert_eq!("2000-01-01T07:00:00.123456+07:00", result.value(0));
5976        assert_eq!("2010-01-01T07:00:00.123456+07:00", result.value(1));
5977        assert!(result.is_null(2));
5978
5979        let to_type = DataType::Timestamp(TimeUnit::Second, Some("-08:00".into()));
5980        let timestamp_array = cast(&timestamp_array, &to_type).unwrap();
5981
5982        let string_array = cast(&timestamp_array, &DataType::Utf8).unwrap();
5983        let result = string_array.as_string::<i32>();
5984        assert_eq!("1999-12-31T16:00:00-08:00", result.value(0));
5985        assert_eq!("2009-12-31T16:00:00-08:00", result.value(1));
5986        assert!(result.is_null(2));
5987    }
5988
5989    #[test]
5990    fn test_cast_date64_to_timestamp() {
5991        let array = Date64Array::from(vec![Some(864000000005), Some(1545696000001), None]);
5992        let b = cast(&array, &DataType::Timestamp(TimeUnit::Second, None)).unwrap();
5993        let c = b.as_primitive::<TimestampSecondType>();
5994        assert_eq!(864000000, c.value(0));
5995        assert_eq!(1545696000, c.value(1));
5996        assert!(c.is_null(2));
5997    }
5998
5999    #[test]
6000    fn test_cast_date64_to_timestamp_ms() {
6001        let array = Date64Array::from(vec![Some(864000000005), Some(1545696000001), None]);
6002        let b = cast(&array, &DataType::Timestamp(TimeUnit::Millisecond, None)).unwrap();
6003        let c = b
6004            .as_any()
6005            .downcast_ref::<TimestampMillisecondArray>()
6006            .unwrap();
6007        assert_eq!(864000000005, c.value(0));
6008        assert_eq!(1545696000001, c.value(1));
6009        assert!(c.is_null(2));
6010    }
6011
6012    #[test]
6013    fn test_cast_date64_to_timestamp_us() {
6014        let array = Date64Array::from(vec![Some(864000000005), Some(1545696000001), None]);
6015        let b = cast(&array, &DataType::Timestamp(TimeUnit::Microsecond, None)).unwrap();
6016        let c = b
6017            .as_any()
6018            .downcast_ref::<TimestampMicrosecondArray>()
6019            .unwrap();
6020        assert_eq!(864000000005000, c.value(0));
6021        assert_eq!(1545696000001000, c.value(1));
6022        assert!(c.is_null(2));
6023    }
6024
6025    #[test]
6026    fn test_cast_date64_to_timestamp_ns() {
6027        let array = Date64Array::from(vec![Some(864000000005), Some(1545696000001), None]);
6028        let b = cast(&array, &DataType::Timestamp(TimeUnit::Nanosecond, None)).unwrap();
6029        let c = b
6030            .as_any()
6031            .downcast_ref::<TimestampNanosecondArray>()
6032            .unwrap();
6033        assert_eq!(864000000005000000, c.value(0));
6034        assert_eq!(1545696000001000000, c.value(1));
6035        assert!(c.is_null(2));
6036    }
6037
6038    #[test]
6039    fn test_cast_timestamp_to_i64() {
6040        let array =
6041            TimestampMillisecondArray::from(vec![Some(864000000005), Some(1545696000001), None])
6042                .with_timezone("UTC".to_string());
6043        let b = cast(&array, &DataType::Int64).unwrap();
6044        let c = b.as_primitive::<Int64Type>();
6045        assert_eq!(&DataType::Int64, c.data_type());
6046        assert_eq!(864000000005, c.value(0));
6047        assert_eq!(1545696000001, c.value(1));
6048        assert!(c.is_null(2));
6049    }
6050
6051    macro_rules! assert_cast {
6052        ($array:expr, $datatype:expr, $output_array_type: ty, $expected:expr) => {{
6053            assert!(can_cast_types($array.data_type(), &$datatype));
6054            let out = cast(&$array, &$datatype).unwrap();
6055            let actual = out
6056                .as_any()
6057                .downcast_ref::<$output_array_type>()
6058                .unwrap()
6059                .into_iter()
6060                .collect::<Vec<_>>();
6061            assert_eq!(actual, $expected);
6062        }};
6063        ($array:expr, $datatype:expr, $output_array_type: ty, $options:expr, $expected:expr) => {{
6064            assert!(can_cast_types($array.data_type(), &$datatype));
6065            let out = cast_with_options(&$array, &$datatype, &$options).unwrap();
6066            let actual = out
6067                .as_any()
6068                .downcast_ref::<$output_array_type>()
6069                .unwrap()
6070                .into_iter()
6071                .collect::<Vec<_>>();
6072            assert_eq!(actual, $expected);
6073        }};
6074    }
6075
6076    #[test]
6077    fn test_cast_date32_to_string() {
6078        let array = Date32Array::from(vec![Some(0), Some(10000), Some(13036), Some(17890), None]);
6079        let expected = vec![
6080            Some("1970-01-01"),
6081            Some("1997-05-19"),
6082            Some("2005-09-10"),
6083            Some("2018-12-25"),
6084            None,
6085        ];
6086
6087        assert_cast!(array, DataType::Utf8View, StringViewArray, expected);
6088        assert_cast!(array, DataType::Utf8, StringArray, expected);
6089        assert_cast!(array, DataType::LargeUtf8, LargeStringArray, expected);
6090    }
6091
6092    #[test]
6093    fn test_cast_date64_to_string() {
6094        let array = Date64Array::from(vec![
6095            Some(0),
6096            Some(10000 * 86400000),
6097            Some(13036 * 86400000),
6098            Some(17890 * 86400000),
6099            None,
6100        ]);
6101        let expected = vec![
6102            Some("1970-01-01T00:00:00"),
6103            Some("1997-05-19T00:00:00"),
6104            Some("2005-09-10T00:00:00"),
6105            Some("2018-12-25T00:00:00"),
6106            None,
6107        ];
6108
6109        assert_cast!(array, DataType::Utf8View, StringViewArray, expected);
6110        assert_cast!(array, DataType::Utf8, StringArray, expected);
6111        assert_cast!(array, DataType::LargeUtf8, LargeStringArray, expected);
6112    }
6113
6114    #[test]
6115    fn test_cast_date32_to_timestamp_and_timestamp_with_timezone() {
6116        let tz = "+0545"; // UTC + 0545 is Asia/Kathmandu
6117        let a = Date32Array::from(vec![Some(18628), None, None]); // 2021-1-1, 2022-1-1
6118        let array = Arc::new(a) as ArrayRef;
6119
6120        let b = cast(
6121            &array,
6122            &DataType::Timestamp(TimeUnit::Second, Some(tz.into())),
6123        )
6124        .unwrap();
6125        let c = b.as_primitive::<TimestampSecondType>();
6126        let string_array = cast(&c, &DataType::Utf8).unwrap();
6127        let result = string_array.as_string::<i32>();
6128        assert_eq!("2021-01-01T00:00:00+05:45", result.value(0));
6129
6130        let b = cast(&array, &DataType::Timestamp(TimeUnit::Second, None)).unwrap();
6131        let c = b.as_primitive::<TimestampSecondType>();
6132        let string_array = cast(&c, &DataType::Utf8).unwrap();
6133        let result = string_array.as_string::<i32>();
6134        assert_eq!("2021-01-01T00:00:00", result.value(0));
6135    }
6136
6137    #[test]
6138    fn test_cast_date32_to_timestamp_with_timezone() {
6139        let tz = "+0545"; // UTC + 0545 is Asia/Kathmandu
6140        let a = Date32Array::from(vec![Some(18628), Some(18993), None]); // 2021-1-1, 2022-1-1
6141        let array = Arc::new(a) as ArrayRef;
6142        let b = cast(
6143            &array,
6144            &DataType::Timestamp(TimeUnit::Second, Some(tz.into())),
6145        )
6146        .unwrap();
6147        let c = b.as_primitive::<TimestampSecondType>();
6148        assert_eq!(1609438500, c.value(0));
6149        assert_eq!(1640974500, c.value(1));
6150        assert!(c.is_null(2));
6151
6152        let string_array = cast(&c, &DataType::Utf8).unwrap();
6153        let result = string_array.as_string::<i32>();
6154        assert_eq!("2021-01-01T00:00:00+05:45", result.value(0));
6155        assert_eq!("2022-01-01T00:00:00+05:45", result.value(1));
6156    }
6157
6158    #[test]
6159    fn test_cast_date32_to_timestamp_with_timezone_ms() {
6160        let tz = "+0545"; // UTC + 0545 is Asia/Kathmandu
6161        let a = Date32Array::from(vec![Some(18628), Some(18993), None]); // 2021-1-1, 2022-1-1
6162        let array = Arc::new(a) as ArrayRef;
6163        let b = cast(
6164            &array,
6165            &DataType::Timestamp(TimeUnit::Millisecond, Some(tz.into())),
6166        )
6167        .unwrap();
6168        let c = b.as_primitive::<TimestampMillisecondType>();
6169        assert_eq!(1609438500000, c.value(0));
6170        assert_eq!(1640974500000, c.value(1));
6171        assert!(c.is_null(2));
6172
6173        let string_array = cast(&c, &DataType::Utf8).unwrap();
6174        let result = string_array.as_string::<i32>();
6175        assert_eq!("2021-01-01T00:00:00+05:45", result.value(0));
6176        assert_eq!("2022-01-01T00:00:00+05:45", result.value(1));
6177    }
6178
6179    #[test]
6180    fn test_cast_date32_to_timestamp_with_timezone_us() {
6181        let tz = "+0545"; // UTC + 0545 is Asia/Kathmandu
6182        let a = Date32Array::from(vec![Some(18628), Some(18993), None]); // 2021-1-1, 2022-1-1
6183        let array = Arc::new(a) as ArrayRef;
6184        let b = cast(
6185            &array,
6186            &DataType::Timestamp(TimeUnit::Microsecond, Some(tz.into())),
6187        )
6188        .unwrap();
6189        let c = b.as_primitive::<TimestampMicrosecondType>();
6190        assert_eq!(1609438500000000, c.value(0));
6191        assert_eq!(1640974500000000, c.value(1));
6192        assert!(c.is_null(2));
6193
6194        let string_array = cast(&c, &DataType::Utf8).unwrap();
6195        let result = string_array.as_string::<i32>();
6196        assert_eq!("2021-01-01T00:00:00+05:45", result.value(0));
6197        assert_eq!("2022-01-01T00:00:00+05:45", result.value(1));
6198    }
6199
6200    #[test]
6201    fn test_cast_date32_to_timestamp_with_timezone_ns() {
6202        let tz = "+0545"; // UTC + 0545 is Asia/Kathmandu
6203        let a = Date32Array::from(vec![Some(18628), Some(18993), None]); // 2021-1-1, 2022-1-1
6204        let array = Arc::new(a) as ArrayRef;
6205        let b = cast(
6206            &array,
6207            &DataType::Timestamp(TimeUnit::Nanosecond, Some(tz.into())),
6208        )
6209        .unwrap();
6210        let c = b.as_primitive::<TimestampNanosecondType>();
6211        assert_eq!(1609438500000000000, c.value(0));
6212        assert_eq!(1640974500000000000, c.value(1));
6213        assert!(c.is_null(2));
6214
6215        let string_array = cast(&c, &DataType::Utf8).unwrap();
6216        let result = string_array.as_string::<i32>();
6217        assert_eq!("2021-01-01T00:00:00+05:45", result.value(0));
6218        assert_eq!("2022-01-01T00:00:00+05:45", result.value(1));
6219    }
6220
6221    #[test]
6222    fn test_cast_date64_to_timestamp_with_timezone() {
6223        let array = Date64Array::from(vec![Some(864000000005), Some(1545696000001), None]);
6224        let tz = "+0545"; // UTC + 0545 is Asia/Kathmandu
6225        let b = cast(
6226            &array,
6227            &DataType::Timestamp(TimeUnit::Second, Some(tz.into())),
6228        )
6229        .unwrap();
6230
6231        let c = b.as_primitive::<TimestampSecondType>();
6232        assert_eq!(863979300, c.value(0));
6233        assert_eq!(1545675300, c.value(1));
6234        assert!(c.is_null(2));
6235
6236        let string_array = cast(&c, &DataType::Utf8).unwrap();
6237        let result = string_array.as_string::<i32>();
6238        assert_eq!("1997-05-19T00:00:00+05:45", result.value(0));
6239        assert_eq!("2018-12-25T00:00:00+05:45", result.value(1));
6240    }
6241
6242    #[test]
6243    fn test_cast_date64_to_timestamp_with_timezone_ms() {
6244        let array = Date64Array::from(vec![Some(864000000005), Some(1545696000001), None]);
6245        let tz = "+0545"; // UTC + 0545 is Asia/Kathmandu
6246        let b = cast(
6247            &array,
6248            &DataType::Timestamp(TimeUnit::Millisecond, Some(tz.into())),
6249        )
6250        .unwrap();
6251
6252        let c = b.as_primitive::<TimestampMillisecondType>();
6253        assert_eq!(863979300005, c.value(0));
6254        assert_eq!(1545675300001, c.value(1));
6255        assert!(c.is_null(2));
6256
6257        let string_array = cast(&c, &DataType::Utf8).unwrap();
6258        let result = string_array.as_string::<i32>();
6259        assert_eq!("1997-05-19T00:00:00.005+05:45", result.value(0));
6260        assert_eq!("2018-12-25T00:00:00.001+05:45", result.value(1));
6261    }
6262
6263    #[test]
6264    fn test_cast_date64_to_timestamp_with_timezone_us() {
6265        let array = Date64Array::from(vec![Some(864000000005), Some(1545696000001), None]);
6266        let tz = "+0545"; // UTC + 0545 is Asia/Kathmandu
6267        let b = cast(
6268            &array,
6269            &DataType::Timestamp(TimeUnit::Microsecond, Some(tz.into())),
6270        )
6271        .unwrap();
6272
6273        let c = b.as_primitive::<TimestampMicrosecondType>();
6274        assert_eq!(863979300005000, c.value(0));
6275        assert_eq!(1545675300001000, c.value(1));
6276        assert!(c.is_null(2));
6277
6278        let string_array = cast(&c, &DataType::Utf8).unwrap();
6279        let result = string_array.as_string::<i32>();
6280        assert_eq!("1997-05-19T00:00:00.005+05:45", result.value(0));
6281        assert_eq!("2018-12-25T00:00:00.001+05:45", result.value(1));
6282    }
6283
6284    #[test]
6285    fn test_cast_date64_to_timestamp_with_timezone_ns() {
6286        let array = Date64Array::from(vec![Some(864000000005), Some(1545696000001), None]);
6287        let tz = "+0545"; // UTC + 0545 is Asia/Kathmandu
6288        let b = cast(
6289            &array,
6290            &DataType::Timestamp(TimeUnit::Nanosecond, Some(tz.into())),
6291        )
6292        .unwrap();
6293
6294        let c = b.as_primitive::<TimestampNanosecondType>();
6295        assert_eq!(863979300005000000, c.value(0));
6296        assert_eq!(1545675300001000000, c.value(1));
6297        assert!(c.is_null(2));
6298
6299        let string_array = cast(&c, &DataType::Utf8).unwrap();
6300        let result = string_array.as_string::<i32>();
6301        assert_eq!("1997-05-19T00:00:00.005+05:45", result.value(0));
6302        assert_eq!("2018-12-25T00:00:00.001+05:45", result.value(1));
6303    }
6304
6305    #[test]
6306    fn test_cast_timestamp_to_strings() {
6307        // "2018-12-25T00:00:02.001", "1997-05-19T00:00:03.005", None
6308        let array =
6309            TimestampMillisecondArray::from(vec![Some(864000003005), Some(1545696002001), None]);
6310        let expected = vec![
6311            Some("1997-05-19T00:00:03.005"),
6312            Some("2018-12-25T00:00:02.001"),
6313            None,
6314        ];
6315
6316        assert_cast!(array, DataType::Utf8View, StringViewArray, expected);
6317        assert_cast!(array, DataType::Utf8, StringArray, expected);
6318        assert_cast!(array, DataType::LargeUtf8, LargeStringArray, expected);
6319    }
6320
6321    #[test]
6322    fn test_cast_timestamp_to_strings_opt() {
6323        let ts_format = "%Y-%m-%d %H:%M:%S%.6f";
6324        let tz = "+0545"; // UTC + 0545 is Asia/Kathmandu
6325        let cast_options = CastOptions {
6326            safe: true,
6327            format_options: FormatOptions::default()
6328                .with_timestamp_format(Some(ts_format))
6329                .with_timestamp_tz_format(Some(ts_format)),
6330        };
6331
6332        // "2018-12-25T00:00:02.001", "1997-05-19T00:00:03.005", None
6333        let array_without_tz =
6334            TimestampMillisecondArray::from(vec![Some(864000003005), Some(1545696002001), None]);
6335        let expected = vec![
6336            Some("1997-05-19 00:00:03.005000"),
6337            Some("2018-12-25 00:00:02.001000"),
6338            None,
6339        ];
6340        assert_cast!(
6341            array_without_tz,
6342            DataType::Utf8View,
6343            StringViewArray,
6344            cast_options,
6345            expected
6346        );
6347        assert_cast!(
6348            array_without_tz,
6349            DataType::Utf8,
6350            StringArray,
6351            cast_options,
6352            expected
6353        );
6354        assert_cast!(
6355            array_without_tz,
6356            DataType::LargeUtf8,
6357            LargeStringArray,
6358            cast_options,
6359            expected
6360        );
6361
6362        let array_with_tz =
6363            TimestampMillisecondArray::from(vec![Some(864000003005), Some(1545696002001), None])
6364                .with_timezone(tz.to_string());
6365        let expected = vec![
6366            Some("1997-05-19 05:45:03.005000"),
6367            Some("2018-12-25 05:45:02.001000"),
6368            None,
6369        ];
6370        assert_cast!(
6371            array_with_tz,
6372            DataType::Utf8View,
6373            StringViewArray,
6374            cast_options,
6375            expected
6376        );
6377        assert_cast!(
6378            array_with_tz,
6379            DataType::Utf8,
6380            StringArray,
6381            cast_options,
6382            expected
6383        );
6384        assert_cast!(
6385            array_with_tz,
6386            DataType::LargeUtf8,
6387            LargeStringArray,
6388            cast_options,
6389            expected
6390        );
6391    }
6392
6393    #[test]
6394    fn test_cast_between_timestamps() {
6395        let array =
6396            TimestampMillisecondArray::from(vec![Some(864000003005), Some(1545696002001), None]);
6397        let b = cast(&array, &DataType::Timestamp(TimeUnit::Second, None)).unwrap();
6398        let c = b.as_primitive::<TimestampSecondType>();
6399        assert_eq!(864000003, c.value(0));
6400        assert_eq!(1545696002, c.value(1));
6401        assert!(c.is_null(2));
6402    }
6403
6404    #[test]
6405    fn test_cast_duration_to_i64() {
6406        let base = vec![5, 6, 7, 8, 100000000];
6407
6408        let duration_arrays = vec![
6409            Arc::new(DurationNanosecondArray::from(base.clone())) as ArrayRef,
6410            Arc::new(DurationMicrosecondArray::from(base.clone())) as ArrayRef,
6411            Arc::new(DurationMillisecondArray::from(base.clone())) as ArrayRef,
6412            Arc::new(DurationSecondArray::from(base.clone())) as ArrayRef,
6413        ];
6414
6415        for arr in duration_arrays {
6416            assert!(can_cast_types(arr.data_type(), &DataType::Int64));
6417            let result = cast(&arr, &DataType::Int64).unwrap();
6418            let result = result.as_primitive::<Int64Type>();
6419            assert_eq!(base.as_slice(), result.values());
6420        }
6421    }
6422
6423    #[test]
6424    fn test_cast_between_durations_and_numerics() {
6425        fn test_cast_between_durations<FromType, ToType>()
6426        where
6427            FromType: ArrowPrimitiveType<Native = i64>,
6428            ToType: ArrowPrimitiveType<Native = i64>,
6429            PrimitiveArray<FromType>: From<Vec<Option<i64>>>,
6430        {
6431            let from_unit = match FromType::DATA_TYPE {
6432                DataType::Duration(unit) => unit,
6433                _ => panic!("Expected a duration type"),
6434            };
6435            let to_unit = match ToType::DATA_TYPE {
6436                DataType::Duration(unit) => unit,
6437                _ => panic!("Expected a duration type"),
6438            };
6439            let from_size = time_unit_multiple(&from_unit);
6440            let to_size = time_unit_multiple(&to_unit);
6441
6442            let (v1_before, v2_before) = (8640003005, 1696002001);
6443            let (v1_after, v2_after) = if from_size >= to_size {
6444                (
6445                    v1_before / (from_size / to_size),
6446                    v2_before / (from_size / to_size),
6447                )
6448            } else {
6449                (
6450                    v1_before * (to_size / from_size),
6451                    v2_before * (to_size / from_size),
6452                )
6453            };
6454
6455            let array =
6456                PrimitiveArray::<FromType>::from(vec![Some(v1_before), Some(v2_before), None]);
6457            let b = cast(&array, &ToType::DATA_TYPE).unwrap();
6458            let c = b.as_primitive::<ToType>();
6459            assert_eq!(v1_after, c.value(0));
6460            assert_eq!(v2_after, c.value(1));
6461            assert!(c.is_null(2));
6462        }
6463
6464        // between each individual duration type
6465        test_cast_between_durations::<DurationSecondType, DurationMillisecondType>();
6466        test_cast_between_durations::<DurationSecondType, DurationMicrosecondType>();
6467        test_cast_between_durations::<DurationSecondType, DurationNanosecondType>();
6468        test_cast_between_durations::<DurationMillisecondType, DurationSecondType>();
6469        test_cast_between_durations::<DurationMillisecondType, DurationMicrosecondType>();
6470        test_cast_between_durations::<DurationMillisecondType, DurationNanosecondType>();
6471        test_cast_between_durations::<DurationMicrosecondType, DurationSecondType>();
6472        test_cast_between_durations::<DurationMicrosecondType, DurationMillisecondType>();
6473        test_cast_between_durations::<DurationMicrosecondType, DurationNanosecondType>();
6474        test_cast_between_durations::<DurationNanosecondType, DurationSecondType>();
6475        test_cast_between_durations::<DurationNanosecondType, DurationMillisecondType>();
6476        test_cast_between_durations::<DurationNanosecondType, DurationMicrosecondType>();
6477
6478        // cast failed
6479        let array = DurationSecondArray::from(vec![
6480            Some(i64::MAX),
6481            Some(8640203410378005),
6482            Some(10241096),
6483            None,
6484        ]);
6485        let b = cast(&array, &DataType::Duration(TimeUnit::Nanosecond)).unwrap();
6486        let c = b.as_primitive::<DurationNanosecondType>();
6487        assert!(c.is_null(0));
6488        assert!(c.is_null(1));
6489        assert_eq!(10241096000000000, c.value(2));
6490        assert!(c.is_null(3));
6491
6492        // durations to numerics
6493        let array = DurationSecondArray::from(vec![
6494            Some(i64::MAX),
6495            Some(8640203410378005),
6496            Some(10241096),
6497            None,
6498        ]);
6499        let b = cast(&array, &DataType::Int64).unwrap();
6500        let c = b.as_primitive::<Int64Type>();
6501        assert_eq!(i64::MAX, c.value(0));
6502        assert_eq!(8640203410378005, c.value(1));
6503        assert_eq!(10241096, c.value(2));
6504        assert!(c.is_null(3));
6505
6506        let b = cast(&array, &DataType::Int32).unwrap();
6507        let c = b.as_primitive::<Int32Type>();
6508        assert_eq!(0, c.value(0));
6509        assert_eq!(0, c.value(1));
6510        assert_eq!(10241096, c.value(2));
6511        assert!(c.is_null(3));
6512
6513        // numerics to durations
6514        let array = Int32Array::from(vec![Some(i32::MAX), Some(802034103), Some(10241096), None]);
6515        let b = cast(&array, &DataType::Duration(TimeUnit::Second)).unwrap();
6516        let c = b.as_any().downcast_ref::<DurationSecondArray>().unwrap();
6517        assert_eq!(i32::MAX as i64, c.value(0));
6518        assert_eq!(802034103, c.value(1));
6519        assert_eq!(10241096, c.value(2));
6520        assert!(c.is_null(3));
6521    }
6522
6523    #[test]
6524    fn test_cast_to_strings() {
6525        let a = Int32Array::from(vec![1, 2, 3]);
6526        let out = cast(&a, &DataType::Utf8).unwrap();
6527        let out = out
6528            .as_any()
6529            .downcast_ref::<StringArray>()
6530            .unwrap()
6531            .into_iter()
6532            .collect::<Vec<_>>();
6533        assert_eq!(out, vec![Some("1"), Some("2"), Some("3")]);
6534        let out = cast(&a, &DataType::LargeUtf8).unwrap();
6535        let out = out
6536            .as_any()
6537            .downcast_ref::<LargeStringArray>()
6538            .unwrap()
6539            .into_iter()
6540            .collect::<Vec<_>>();
6541        assert_eq!(out, vec![Some("1"), Some("2"), Some("3")]);
6542    }
6543
6544    #[test]
6545    fn test_str_to_str_casts() {
6546        for data in [
6547            vec![Some("foo"), Some("bar"), Some("ham")],
6548            vec![Some("foo"), None, Some("bar")],
6549        ] {
6550            let a = LargeStringArray::from(data.clone());
6551            let to = cast(&a, &DataType::Utf8).unwrap();
6552            let expect = a
6553                .as_any()
6554                .downcast_ref::<LargeStringArray>()
6555                .unwrap()
6556                .into_iter()
6557                .collect::<Vec<_>>();
6558            let out = to
6559                .as_any()
6560                .downcast_ref::<StringArray>()
6561                .unwrap()
6562                .into_iter()
6563                .collect::<Vec<_>>();
6564            assert_eq!(expect, out);
6565
6566            let a = StringArray::from(data);
6567            let to = cast(&a, &DataType::LargeUtf8).unwrap();
6568            let expect = a
6569                .as_any()
6570                .downcast_ref::<StringArray>()
6571                .unwrap()
6572                .into_iter()
6573                .collect::<Vec<_>>();
6574            let out = to
6575                .as_any()
6576                .downcast_ref::<LargeStringArray>()
6577                .unwrap()
6578                .into_iter()
6579                .collect::<Vec<_>>();
6580            assert_eq!(expect, out);
6581        }
6582    }
6583
6584    const VIEW_TEST_DATA: [Option<&str>; 5] = [
6585        Some("hello"),
6586        Some("repeated"),
6587        None,
6588        Some("large payload over 12 bytes"),
6589        Some("repeated"),
6590    ];
6591
6592    #[test]
6593    fn test_string_view_to_binary_view() {
6594        let string_view_array = StringViewArray::from_iter(VIEW_TEST_DATA);
6595
6596        assert!(can_cast_types(
6597            string_view_array.data_type(),
6598            &DataType::BinaryView
6599        ));
6600
6601        let binary_view_array = cast(&string_view_array, &DataType::BinaryView).unwrap();
6602        assert_eq!(binary_view_array.data_type(), &DataType::BinaryView);
6603
6604        let expect_binary_view_array = BinaryViewArray::from_iter(VIEW_TEST_DATA);
6605        assert_eq!(binary_view_array.as_ref(), &expect_binary_view_array);
6606    }
6607
6608    #[test]
6609    fn test_binary_view_to_string_view() {
6610        let binary_view_array = BinaryViewArray::from_iter(VIEW_TEST_DATA);
6611
6612        assert!(can_cast_types(
6613            binary_view_array.data_type(),
6614            &DataType::Utf8View
6615        ));
6616
6617        let string_view_array = cast(&binary_view_array, &DataType::Utf8View).unwrap();
6618        assert_eq!(string_view_array.data_type(), &DataType::Utf8View);
6619
6620        let expect_string_view_array = StringViewArray::from_iter(VIEW_TEST_DATA);
6621        assert_eq!(string_view_array.as_ref(), &expect_string_view_array);
6622    }
6623
6624    #[test]
6625    fn test_binary_view_to_string_view_with_invalid_utf8() {
6626        let binary_view_array = BinaryViewArray::from_iter(vec![
6627            Some("valid".as_bytes()),
6628            Some(&[0xff]),
6629            Some("utf8".as_bytes()),
6630            None,
6631        ]);
6632
6633        let strict_options = CastOptions {
6634            safe: false,
6635            ..Default::default()
6636        };
6637
6638        assert!(
6639            cast_with_options(&binary_view_array, &DataType::Utf8View, &strict_options).is_err()
6640        );
6641
6642        let safe_options = CastOptions {
6643            safe: true,
6644            ..Default::default()
6645        };
6646
6647        let string_view_array =
6648            cast_with_options(&binary_view_array, &DataType::Utf8View, &safe_options).unwrap();
6649        assert_eq!(string_view_array.data_type(), &DataType::Utf8View);
6650
6651        let values: Vec<_> = string_view_array.as_string_view().iter().collect();
6652
6653        assert_eq!(values, vec![Some("valid"), None, Some("utf8"), None]);
6654    }
6655
6656    #[test]
6657    fn test_string_to_view() {
6658        _test_string_to_view::<i32>();
6659        _test_string_to_view::<i64>();
6660    }
6661
6662    fn _test_string_to_view<O>()
6663    where
6664        O: OffsetSizeTrait,
6665    {
6666        let string_array = GenericStringArray::<O>::from_iter(VIEW_TEST_DATA);
6667
6668        assert!(can_cast_types(
6669            string_array.data_type(),
6670            &DataType::Utf8View
6671        ));
6672
6673        assert!(can_cast_types(
6674            string_array.data_type(),
6675            &DataType::BinaryView
6676        ));
6677
6678        let string_view_array = cast(&string_array, &DataType::Utf8View).unwrap();
6679        assert_eq!(string_view_array.data_type(), &DataType::Utf8View);
6680
6681        let binary_view_array = cast(&string_array, &DataType::BinaryView).unwrap();
6682        assert_eq!(binary_view_array.data_type(), &DataType::BinaryView);
6683
6684        let expect_string_view_array = StringViewArray::from_iter(VIEW_TEST_DATA);
6685        assert_eq!(string_view_array.as_ref(), &expect_string_view_array);
6686
6687        let expect_binary_view_array = BinaryViewArray::from_iter(VIEW_TEST_DATA);
6688        assert_eq!(binary_view_array.as_ref(), &expect_binary_view_array);
6689    }
6690
6691    #[test]
6692    fn test_bianry_to_view() {
6693        _test_binary_to_view::<i32>();
6694        _test_binary_to_view::<i64>();
6695    }
6696
6697    fn _test_binary_to_view<O>()
6698    where
6699        O: OffsetSizeTrait,
6700    {
6701        let binary_array = GenericBinaryArray::<O>::from_iter(VIEW_TEST_DATA);
6702
6703        assert!(can_cast_types(
6704            binary_array.data_type(),
6705            &DataType::Utf8View
6706        ));
6707
6708        assert!(can_cast_types(
6709            binary_array.data_type(),
6710            &DataType::BinaryView
6711        ));
6712
6713        let string_view_array = cast(&binary_array, &DataType::Utf8View).unwrap();
6714        assert_eq!(string_view_array.data_type(), &DataType::Utf8View);
6715
6716        let binary_view_array = cast(&binary_array, &DataType::BinaryView).unwrap();
6717        assert_eq!(binary_view_array.data_type(), &DataType::BinaryView);
6718
6719        let expect_string_view_array = StringViewArray::from_iter(VIEW_TEST_DATA);
6720        assert_eq!(string_view_array.as_ref(), &expect_string_view_array);
6721
6722        let expect_binary_view_array = BinaryViewArray::from_iter(VIEW_TEST_DATA);
6723        assert_eq!(binary_view_array.as_ref(), &expect_binary_view_array);
6724    }
6725
6726    #[test]
6727    fn test_dict_to_view() {
6728        let values = StringArray::from_iter(VIEW_TEST_DATA);
6729        let keys = Int8Array::from_iter([Some(1), Some(0), None, Some(3), None, Some(1), Some(4)]);
6730        let string_dict_array =
6731            DictionaryArray::<Int8Type>::try_new(keys, Arc::new(values)).unwrap();
6732        let typed_dict = string_dict_array.downcast_dict::<StringArray>().unwrap();
6733
6734        let string_view_array = {
6735            let mut builder = StringViewBuilder::new().with_fixed_block_size(8); // multiple buffers.
6736            for v in typed_dict.into_iter() {
6737                builder.append_option(v);
6738            }
6739            builder.finish()
6740        };
6741        let expected_string_array_type = string_view_array.data_type();
6742        let casted_string_array = cast(&string_dict_array, expected_string_array_type).unwrap();
6743        assert_eq!(casted_string_array.data_type(), expected_string_array_type);
6744        assert_eq!(casted_string_array.as_ref(), &string_view_array);
6745
6746        let binary_buffer = cast(&typed_dict.values(), &DataType::Binary).unwrap();
6747        let binary_dict_array =
6748            DictionaryArray::<Int8Type>::new(typed_dict.keys().clone(), binary_buffer);
6749        let typed_binary_dict = binary_dict_array.downcast_dict::<BinaryArray>().unwrap();
6750
6751        let binary_view_array = {
6752            let mut builder = BinaryViewBuilder::new().with_fixed_block_size(8); // multiple buffers.
6753            for v in typed_binary_dict.into_iter() {
6754                builder.append_option(v);
6755            }
6756            builder.finish()
6757        };
6758        let expected_binary_array_type = binary_view_array.data_type();
6759        let casted_binary_array = cast(&binary_dict_array, expected_binary_array_type).unwrap();
6760        assert_eq!(casted_binary_array.data_type(), expected_binary_array_type);
6761        assert_eq!(casted_binary_array.as_ref(), &binary_view_array);
6762    }
6763
6764    #[test]
6765    fn test_view_to_dict() {
6766        let string_view_array = StringViewArray::from_iter(VIEW_TEST_DATA);
6767        let string_dict_array: DictionaryArray<Int8Type> = VIEW_TEST_DATA.into_iter().collect();
6768        let casted_type = string_dict_array.data_type();
6769        let casted_dict_array = cast(&string_view_array, casted_type).unwrap();
6770        assert_eq!(casted_dict_array.data_type(), casted_type);
6771        assert_eq!(casted_dict_array.as_ref(), &string_dict_array);
6772
6773        let binary_view_array = BinaryViewArray::from_iter(VIEW_TEST_DATA);
6774        let binary_dict_array = string_dict_array.downcast_dict::<StringArray>().unwrap();
6775        let binary_buffer = cast(&binary_dict_array.values(), &DataType::Binary).unwrap();
6776        let binary_dict_array =
6777            DictionaryArray::<Int8Type>::new(binary_dict_array.keys().clone(), binary_buffer);
6778        let casted_type = binary_dict_array.data_type();
6779        let casted_binary_array = cast(&binary_view_array, casted_type).unwrap();
6780        assert_eq!(casted_binary_array.data_type(), casted_type);
6781        assert_eq!(casted_binary_array.as_ref(), &binary_dict_array);
6782    }
6783
6784    #[test]
6785    fn test_view_to_string() {
6786        _test_view_to_string::<i32>();
6787        _test_view_to_string::<i64>();
6788    }
6789
6790    fn _test_view_to_string<O>()
6791    where
6792        O: OffsetSizeTrait,
6793    {
6794        let string_view_array = {
6795            let mut builder = StringViewBuilder::new().with_fixed_block_size(8); // multiple buffers.
6796            for s in VIEW_TEST_DATA.iter() {
6797                builder.append_option(*s);
6798            }
6799            builder.finish()
6800        };
6801
6802        let binary_view_array = BinaryViewArray::from_iter(VIEW_TEST_DATA);
6803
6804        let expected_string_array = GenericStringArray::<O>::from_iter(VIEW_TEST_DATA);
6805        let expected_type = expected_string_array.data_type();
6806
6807        assert!(can_cast_types(string_view_array.data_type(), expected_type));
6808        assert!(can_cast_types(binary_view_array.data_type(), expected_type));
6809
6810        let string_view_casted_array = cast(&string_view_array, expected_type).unwrap();
6811        assert_eq!(string_view_casted_array.data_type(), expected_type);
6812        assert_eq!(string_view_casted_array.as_ref(), &expected_string_array);
6813
6814        let binary_view_casted_array = cast(&binary_view_array, expected_type).unwrap();
6815        assert_eq!(binary_view_casted_array.data_type(), expected_type);
6816        assert_eq!(binary_view_casted_array.as_ref(), &expected_string_array);
6817    }
6818
6819    #[test]
6820    fn test_view_to_binary() {
6821        _test_view_to_binary::<i32>();
6822        _test_view_to_binary::<i64>();
6823    }
6824
6825    fn _test_view_to_binary<O>()
6826    where
6827        O: OffsetSizeTrait,
6828    {
6829        let view_array = {
6830            let mut builder = BinaryViewBuilder::new().with_fixed_block_size(8); // multiple buffers.
6831            for s in VIEW_TEST_DATA.iter() {
6832                builder.append_option(*s);
6833            }
6834            builder.finish()
6835        };
6836
6837        let expected_binary_array = GenericBinaryArray::<O>::from_iter(VIEW_TEST_DATA);
6838        let expected_type = expected_binary_array.data_type();
6839
6840        assert!(can_cast_types(view_array.data_type(), expected_type));
6841
6842        let binary_array = cast(&view_array, expected_type).unwrap();
6843        assert_eq!(binary_array.data_type(), expected_type);
6844
6845        assert_eq!(binary_array.as_ref(), &expected_binary_array);
6846    }
6847
6848    #[test]
6849    fn test_cast_from_f64() {
6850        let f64_values: Vec<f64> = vec![
6851            i64::MIN as f64,
6852            i32::MIN as f64,
6853            i16::MIN as f64,
6854            i8::MIN as f64,
6855            0_f64,
6856            u8::MAX as f64,
6857            u16::MAX as f64,
6858            u32::MAX as f64,
6859            u64::MAX as f64,
6860        ];
6861        let f64_array: ArrayRef = Arc::new(Float64Array::from(f64_values));
6862
6863        let f64_expected = vec![
6864            -9223372036854776000.0,
6865            -2147483648.0,
6866            -32768.0,
6867            -128.0,
6868            0.0,
6869            255.0,
6870            65535.0,
6871            4294967295.0,
6872            18446744073709552000.0,
6873        ];
6874        assert_eq!(
6875            f64_expected,
6876            get_cast_values::<Float64Type>(&f64_array, &DataType::Float64)
6877                .iter()
6878                .map(|i| i.parse::<f64>().unwrap())
6879                .collect::<Vec<f64>>()
6880        );
6881
6882        let f32_expected = vec![
6883            -9223372000000000000.0,
6884            -2147483600.0,
6885            -32768.0,
6886            -128.0,
6887            0.0,
6888            255.0,
6889            65535.0,
6890            4294967300.0,
6891            18446744000000000000.0,
6892        ];
6893        assert_eq!(
6894            f32_expected,
6895            get_cast_values::<Float32Type>(&f64_array, &DataType::Float32)
6896                .iter()
6897                .map(|i| i.parse::<f32>().unwrap())
6898                .collect::<Vec<f32>>()
6899        );
6900
6901        let f16_expected = vec![
6902            f16::from_f64(-9223372000000000000.0),
6903            f16::from_f64(-2147483600.0),
6904            f16::from_f64(-32768.0),
6905            f16::from_f64(-128.0),
6906            f16::from_f64(0.0),
6907            f16::from_f64(255.0),
6908            f16::from_f64(65535.0),
6909            f16::from_f64(4294967300.0),
6910            f16::from_f64(18446744000000000000.0),
6911        ];
6912        assert_eq!(
6913            f16_expected,
6914            get_cast_values::<Float16Type>(&f64_array, &DataType::Float16)
6915                .iter()
6916                .map(|i| i.parse::<f16>().unwrap())
6917                .collect::<Vec<f16>>()
6918        );
6919
6920        let i64_expected = vec![
6921            "-9223372036854775808",
6922            "-2147483648",
6923            "-32768",
6924            "-128",
6925            "0",
6926            "255",
6927            "65535",
6928            "4294967295",
6929            "null",
6930        ];
6931        assert_eq!(
6932            i64_expected,
6933            get_cast_values::<Int64Type>(&f64_array, &DataType::Int64)
6934        );
6935
6936        let i32_expected = vec![
6937            "null",
6938            "-2147483648",
6939            "-32768",
6940            "-128",
6941            "0",
6942            "255",
6943            "65535",
6944            "null",
6945            "null",
6946        ];
6947        assert_eq!(
6948            i32_expected,
6949            get_cast_values::<Int32Type>(&f64_array, &DataType::Int32)
6950        );
6951
6952        let i16_expected = vec![
6953            "null", "null", "-32768", "-128", "0", "255", "null", "null", "null",
6954        ];
6955        assert_eq!(
6956            i16_expected,
6957            get_cast_values::<Int16Type>(&f64_array, &DataType::Int16)
6958        );
6959
6960        let i8_expected = vec![
6961            "null", "null", "null", "-128", "0", "null", "null", "null", "null",
6962        ];
6963        assert_eq!(
6964            i8_expected,
6965            get_cast_values::<Int8Type>(&f64_array, &DataType::Int8)
6966        );
6967
6968        let u64_expected = vec![
6969            "null",
6970            "null",
6971            "null",
6972            "null",
6973            "0",
6974            "255",
6975            "65535",
6976            "4294967295",
6977            "null",
6978        ];
6979        assert_eq!(
6980            u64_expected,
6981            get_cast_values::<UInt64Type>(&f64_array, &DataType::UInt64)
6982        );
6983
6984        let u32_expected = vec![
6985            "null",
6986            "null",
6987            "null",
6988            "null",
6989            "0",
6990            "255",
6991            "65535",
6992            "4294967295",
6993            "null",
6994        ];
6995        assert_eq!(
6996            u32_expected,
6997            get_cast_values::<UInt32Type>(&f64_array, &DataType::UInt32)
6998        );
6999
7000        let u16_expected = vec![
7001            "null", "null", "null", "null", "0", "255", "65535", "null", "null",
7002        ];
7003        assert_eq!(
7004            u16_expected,
7005            get_cast_values::<UInt16Type>(&f64_array, &DataType::UInt16)
7006        );
7007
7008        let u8_expected = vec![
7009            "null", "null", "null", "null", "0", "255", "null", "null", "null",
7010        ];
7011        assert_eq!(
7012            u8_expected,
7013            get_cast_values::<UInt8Type>(&f64_array, &DataType::UInt8)
7014        );
7015    }
7016
7017    #[test]
7018    fn test_cast_from_f32() {
7019        let f32_values: Vec<f32> = vec![
7020            i32::MIN as f32,
7021            i32::MIN as f32,
7022            i16::MIN as f32,
7023            i8::MIN as f32,
7024            0_f32,
7025            u8::MAX as f32,
7026            u16::MAX as f32,
7027            u32::MAX as f32,
7028            u32::MAX as f32,
7029        ];
7030        let f32_array: ArrayRef = Arc::new(Float32Array::from(f32_values));
7031
7032        let f64_expected = vec![
7033            "-2147483648.0",
7034            "-2147483648.0",
7035            "-32768.0",
7036            "-128.0",
7037            "0.0",
7038            "255.0",
7039            "65535.0",
7040            "4294967296.0",
7041            "4294967296.0",
7042        ];
7043        assert_eq!(
7044            f64_expected,
7045            get_cast_values::<Float64Type>(&f32_array, &DataType::Float64)
7046        );
7047
7048        let f32_expected = vec![
7049            "-2147483600.0",
7050            "-2147483600.0",
7051            "-32768.0",
7052            "-128.0",
7053            "0.0",
7054            "255.0",
7055            "65535.0",
7056            "4294967300.0",
7057            "4294967300.0",
7058        ];
7059        assert_eq!(
7060            f32_expected,
7061            get_cast_values::<Float32Type>(&f32_array, &DataType::Float32)
7062        );
7063
7064        let f16_expected = vec![
7065            "-inf", "-inf", "-32768.0", "-128.0", "0.0", "255.0", "inf", "inf", "inf",
7066        ];
7067        assert_eq!(
7068            f16_expected,
7069            get_cast_values::<Float16Type>(&f32_array, &DataType::Float16)
7070        );
7071
7072        let i64_expected = vec![
7073            "-2147483648",
7074            "-2147483648",
7075            "-32768",
7076            "-128",
7077            "0",
7078            "255",
7079            "65535",
7080            "4294967296",
7081            "4294967296",
7082        ];
7083        assert_eq!(
7084            i64_expected,
7085            get_cast_values::<Int64Type>(&f32_array, &DataType::Int64)
7086        );
7087
7088        let i32_expected = vec![
7089            "-2147483648",
7090            "-2147483648",
7091            "-32768",
7092            "-128",
7093            "0",
7094            "255",
7095            "65535",
7096            "null",
7097            "null",
7098        ];
7099        assert_eq!(
7100            i32_expected,
7101            get_cast_values::<Int32Type>(&f32_array, &DataType::Int32)
7102        );
7103
7104        let i16_expected = vec![
7105            "null", "null", "-32768", "-128", "0", "255", "null", "null", "null",
7106        ];
7107        assert_eq!(
7108            i16_expected,
7109            get_cast_values::<Int16Type>(&f32_array, &DataType::Int16)
7110        );
7111
7112        let i8_expected = vec![
7113            "null", "null", "null", "-128", "0", "null", "null", "null", "null",
7114        ];
7115        assert_eq!(
7116            i8_expected,
7117            get_cast_values::<Int8Type>(&f32_array, &DataType::Int8)
7118        );
7119
7120        let u64_expected = vec![
7121            "null",
7122            "null",
7123            "null",
7124            "null",
7125            "0",
7126            "255",
7127            "65535",
7128            "4294967296",
7129            "4294967296",
7130        ];
7131        assert_eq!(
7132            u64_expected,
7133            get_cast_values::<UInt64Type>(&f32_array, &DataType::UInt64)
7134        );
7135
7136        let u32_expected = vec![
7137            "null", "null", "null", "null", "0", "255", "65535", "null", "null",
7138        ];
7139        assert_eq!(
7140            u32_expected,
7141            get_cast_values::<UInt32Type>(&f32_array, &DataType::UInt32)
7142        );
7143
7144        let u16_expected = vec![
7145            "null", "null", "null", "null", "0", "255", "65535", "null", "null",
7146        ];
7147        assert_eq!(
7148            u16_expected,
7149            get_cast_values::<UInt16Type>(&f32_array, &DataType::UInt16)
7150        );
7151
7152        let u8_expected = vec![
7153            "null", "null", "null", "null", "0", "255", "null", "null", "null",
7154        ];
7155        assert_eq!(
7156            u8_expected,
7157            get_cast_values::<UInt8Type>(&f32_array, &DataType::UInt8)
7158        );
7159    }
7160
7161    #[test]
7162    fn test_cast_from_uint64() {
7163        let u64_values: Vec<u64> = vec![
7164            0,
7165            u8::MAX as u64,
7166            u16::MAX as u64,
7167            u32::MAX as u64,
7168            u64::MAX,
7169        ];
7170        let u64_array: ArrayRef = Arc::new(UInt64Array::from(u64_values));
7171
7172        let f64_expected = vec![0.0, 255.0, 65535.0, 4294967295.0, 18446744073709552000.0];
7173        assert_eq!(
7174            f64_expected,
7175            get_cast_values::<Float64Type>(&u64_array, &DataType::Float64)
7176                .iter()
7177                .map(|i| i.parse::<f64>().unwrap())
7178                .collect::<Vec<f64>>()
7179        );
7180
7181        let f32_expected = vec![0.0, 255.0, 65535.0, 4294967300.0, 18446744000000000000.0];
7182        assert_eq!(
7183            f32_expected,
7184            get_cast_values::<Float32Type>(&u64_array, &DataType::Float32)
7185                .iter()
7186                .map(|i| i.parse::<f32>().unwrap())
7187                .collect::<Vec<f32>>()
7188        );
7189
7190        let f16_expected = vec![
7191            f16::from_f64(0.0),
7192            f16::from_f64(255.0),
7193            f16::from_f64(65535.0),
7194            f16::from_f64(4294967300.0),
7195            f16::from_f64(18446744000000000000.0),
7196        ];
7197        assert_eq!(
7198            f16_expected,
7199            get_cast_values::<Float16Type>(&u64_array, &DataType::Float16)
7200                .iter()
7201                .map(|i| i.parse::<f16>().unwrap())
7202                .collect::<Vec<f16>>()
7203        );
7204
7205        let i64_expected = vec!["0", "255", "65535", "4294967295", "null"];
7206        assert_eq!(
7207            i64_expected,
7208            get_cast_values::<Int64Type>(&u64_array, &DataType::Int64)
7209        );
7210
7211        let i32_expected = vec!["0", "255", "65535", "null", "null"];
7212        assert_eq!(
7213            i32_expected,
7214            get_cast_values::<Int32Type>(&u64_array, &DataType::Int32)
7215        );
7216
7217        let i16_expected = vec!["0", "255", "null", "null", "null"];
7218        assert_eq!(
7219            i16_expected,
7220            get_cast_values::<Int16Type>(&u64_array, &DataType::Int16)
7221        );
7222
7223        let i8_expected = vec!["0", "null", "null", "null", "null"];
7224        assert_eq!(
7225            i8_expected,
7226            get_cast_values::<Int8Type>(&u64_array, &DataType::Int8)
7227        );
7228
7229        let u64_expected = vec!["0", "255", "65535", "4294967295", "18446744073709551615"];
7230        assert_eq!(
7231            u64_expected,
7232            get_cast_values::<UInt64Type>(&u64_array, &DataType::UInt64)
7233        );
7234
7235        let u32_expected = vec!["0", "255", "65535", "4294967295", "null"];
7236        assert_eq!(
7237            u32_expected,
7238            get_cast_values::<UInt32Type>(&u64_array, &DataType::UInt32)
7239        );
7240
7241        let u16_expected = vec!["0", "255", "65535", "null", "null"];
7242        assert_eq!(
7243            u16_expected,
7244            get_cast_values::<UInt16Type>(&u64_array, &DataType::UInt16)
7245        );
7246
7247        let u8_expected = vec!["0", "255", "null", "null", "null"];
7248        assert_eq!(
7249            u8_expected,
7250            get_cast_values::<UInt8Type>(&u64_array, &DataType::UInt8)
7251        );
7252    }
7253
7254    #[test]
7255    fn test_cast_from_uint32() {
7256        let u32_values: Vec<u32> = vec![0, u8::MAX as u32, u16::MAX as u32, u32::MAX];
7257        let u32_array: ArrayRef = Arc::new(UInt32Array::from(u32_values));
7258
7259        let f64_expected = vec!["0.0", "255.0", "65535.0", "4294967295.0"];
7260        assert_eq!(
7261            f64_expected,
7262            get_cast_values::<Float64Type>(&u32_array, &DataType::Float64)
7263        );
7264
7265        let f32_expected = vec!["0.0", "255.0", "65535.0", "4294967300.0"];
7266        assert_eq!(
7267            f32_expected,
7268            get_cast_values::<Float32Type>(&u32_array, &DataType::Float32)
7269        );
7270
7271        let f16_expected = vec!["0.0", "255.0", "inf", "inf"];
7272        assert_eq!(
7273            f16_expected,
7274            get_cast_values::<Float16Type>(&u32_array, &DataType::Float16)
7275        );
7276
7277        let i64_expected = vec!["0", "255", "65535", "4294967295"];
7278        assert_eq!(
7279            i64_expected,
7280            get_cast_values::<Int64Type>(&u32_array, &DataType::Int64)
7281        );
7282
7283        let i32_expected = vec!["0", "255", "65535", "null"];
7284        assert_eq!(
7285            i32_expected,
7286            get_cast_values::<Int32Type>(&u32_array, &DataType::Int32)
7287        );
7288
7289        let i16_expected = vec!["0", "255", "null", "null"];
7290        assert_eq!(
7291            i16_expected,
7292            get_cast_values::<Int16Type>(&u32_array, &DataType::Int16)
7293        );
7294
7295        let i8_expected = vec!["0", "null", "null", "null"];
7296        assert_eq!(
7297            i8_expected,
7298            get_cast_values::<Int8Type>(&u32_array, &DataType::Int8)
7299        );
7300
7301        let u64_expected = vec!["0", "255", "65535", "4294967295"];
7302        assert_eq!(
7303            u64_expected,
7304            get_cast_values::<UInt64Type>(&u32_array, &DataType::UInt64)
7305        );
7306
7307        let u32_expected = vec!["0", "255", "65535", "4294967295"];
7308        assert_eq!(
7309            u32_expected,
7310            get_cast_values::<UInt32Type>(&u32_array, &DataType::UInt32)
7311        );
7312
7313        let u16_expected = vec!["0", "255", "65535", "null"];
7314        assert_eq!(
7315            u16_expected,
7316            get_cast_values::<UInt16Type>(&u32_array, &DataType::UInt16)
7317        );
7318
7319        let u8_expected = vec!["0", "255", "null", "null"];
7320        assert_eq!(
7321            u8_expected,
7322            get_cast_values::<UInt8Type>(&u32_array, &DataType::UInt8)
7323        );
7324    }
7325
7326    #[test]
7327    fn test_cast_from_uint16() {
7328        let u16_values: Vec<u16> = vec![0, u8::MAX as u16, u16::MAX];
7329        let u16_array: ArrayRef = Arc::new(UInt16Array::from(u16_values));
7330
7331        let f64_expected = vec!["0.0", "255.0", "65535.0"];
7332        assert_eq!(
7333            f64_expected,
7334            get_cast_values::<Float64Type>(&u16_array, &DataType::Float64)
7335        );
7336
7337        let f32_expected = vec!["0.0", "255.0", "65535.0"];
7338        assert_eq!(
7339            f32_expected,
7340            get_cast_values::<Float32Type>(&u16_array, &DataType::Float32)
7341        );
7342
7343        let f16_expected = vec!["0.0", "255.0", "inf"];
7344        assert_eq!(
7345            f16_expected,
7346            get_cast_values::<Float16Type>(&u16_array, &DataType::Float16)
7347        );
7348
7349        let i64_expected = vec!["0", "255", "65535"];
7350        assert_eq!(
7351            i64_expected,
7352            get_cast_values::<Int64Type>(&u16_array, &DataType::Int64)
7353        );
7354
7355        let i32_expected = vec!["0", "255", "65535"];
7356        assert_eq!(
7357            i32_expected,
7358            get_cast_values::<Int32Type>(&u16_array, &DataType::Int32)
7359        );
7360
7361        let i16_expected = vec!["0", "255", "null"];
7362        assert_eq!(
7363            i16_expected,
7364            get_cast_values::<Int16Type>(&u16_array, &DataType::Int16)
7365        );
7366
7367        let i8_expected = vec!["0", "null", "null"];
7368        assert_eq!(
7369            i8_expected,
7370            get_cast_values::<Int8Type>(&u16_array, &DataType::Int8)
7371        );
7372
7373        let u64_expected = vec!["0", "255", "65535"];
7374        assert_eq!(
7375            u64_expected,
7376            get_cast_values::<UInt64Type>(&u16_array, &DataType::UInt64)
7377        );
7378
7379        let u32_expected = vec!["0", "255", "65535"];
7380        assert_eq!(
7381            u32_expected,
7382            get_cast_values::<UInt32Type>(&u16_array, &DataType::UInt32)
7383        );
7384
7385        let u16_expected = vec!["0", "255", "65535"];
7386        assert_eq!(
7387            u16_expected,
7388            get_cast_values::<UInt16Type>(&u16_array, &DataType::UInt16)
7389        );
7390
7391        let u8_expected = vec!["0", "255", "null"];
7392        assert_eq!(
7393            u8_expected,
7394            get_cast_values::<UInt8Type>(&u16_array, &DataType::UInt8)
7395        );
7396    }
7397
7398    #[test]
7399    fn test_cast_from_uint8() {
7400        let u8_values: Vec<u8> = vec![0, u8::MAX];
7401        let u8_array: ArrayRef = Arc::new(UInt8Array::from(u8_values));
7402
7403        let f64_expected = vec!["0.0", "255.0"];
7404        assert_eq!(
7405            f64_expected,
7406            get_cast_values::<Float64Type>(&u8_array, &DataType::Float64)
7407        );
7408
7409        let f32_expected = vec!["0.0", "255.0"];
7410        assert_eq!(
7411            f32_expected,
7412            get_cast_values::<Float32Type>(&u8_array, &DataType::Float32)
7413        );
7414
7415        let f16_expected = vec!["0.0", "255.0"];
7416        assert_eq!(
7417            f16_expected,
7418            get_cast_values::<Float16Type>(&u8_array, &DataType::Float16)
7419        );
7420
7421        let i64_expected = vec!["0", "255"];
7422        assert_eq!(
7423            i64_expected,
7424            get_cast_values::<Int64Type>(&u8_array, &DataType::Int64)
7425        );
7426
7427        let i32_expected = vec!["0", "255"];
7428        assert_eq!(
7429            i32_expected,
7430            get_cast_values::<Int32Type>(&u8_array, &DataType::Int32)
7431        );
7432
7433        let i16_expected = vec!["0", "255"];
7434        assert_eq!(
7435            i16_expected,
7436            get_cast_values::<Int16Type>(&u8_array, &DataType::Int16)
7437        );
7438
7439        let i8_expected = vec!["0", "null"];
7440        assert_eq!(
7441            i8_expected,
7442            get_cast_values::<Int8Type>(&u8_array, &DataType::Int8)
7443        );
7444
7445        let u64_expected = vec!["0", "255"];
7446        assert_eq!(
7447            u64_expected,
7448            get_cast_values::<UInt64Type>(&u8_array, &DataType::UInt64)
7449        );
7450
7451        let u32_expected = vec!["0", "255"];
7452        assert_eq!(
7453            u32_expected,
7454            get_cast_values::<UInt32Type>(&u8_array, &DataType::UInt32)
7455        );
7456
7457        let u16_expected = vec!["0", "255"];
7458        assert_eq!(
7459            u16_expected,
7460            get_cast_values::<UInt16Type>(&u8_array, &DataType::UInt16)
7461        );
7462
7463        let u8_expected = vec!["0", "255"];
7464        assert_eq!(
7465            u8_expected,
7466            get_cast_values::<UInt8Type>(&u8_array, &DataType::UInt8)
7467        );
7468    }
7469
7470    #[test]
7471    fn test_cast_from_int64() {
7472        let i64_values: Vec<i64> = vec![
7473            i64::MIN,
7474            i32::MIN as i64,
7475            i16::MIN as i64,
7476            i8::MIN as i64,
7477            0,
7478            i8::MAX as i64,
7479            i16::MAX as i64,
7480            i32::MAX as i64,
7481            i64::MAX,
7482        ];
7483        let i64_array: ArrayRef = Arc::new(Int64Array::from(i64_values));
7484
7485        let f64_expected = vec![
7486            -9223372036854776000.0,
7487            -2147483648.0,
7488            -32768.0,
7489            -128.0,
7490            0.0,
7491            127.0,
7492            32767.0,
7493            2147483647.0,
7494            9223372036854776000.0,
7495        ];
7496        assert_eq!(
7497            f64_expected,
7498            get_cast_values::<Float64Type>(&i64_array, &DataType::Float64)
7499                .iter()
7500                .map(|i| i.parse::<f64>().unwrap())
7501                .collect::<Vec<f64>>()
7502        );
7503
7504        let f32_expected = vec![
7505            -9223372000000000000.0,
7506            -2147483600.0,
7507            -32768.0,
7508            -128.0,
7509            0.0,
7510            127.0,
7511            32767.0,
7512            2147483600.0,
7513            9223372000000000000.0,
7514        ];
7515        assert_eq!(
7516            f32_expected,
7517            get_cast_values::<Float32Type>(&i64_array, &DataType::Float32)
7518                .iter()
7519                .map(|i| i.parse::<f32>().unwrap())
7520                .collect::<Vec<f32>>()
7521        );
7522
7523        let f16_expected = vec![
7524            f16::from_f64(-9223372000000000000.0),
7525            f16::from_f64(-2147483600.0),
7526            f16::from_f64(-32768.0),
7527            f16::from_f64(-128.0),
7528            f16::from_f64(0.0),
7529            f16::from_f64(127.0),
7530            f16::from_f64(32767.0),
7531            f16::from_f64(2147483600.0),
7532            f16::from_f64(9223372000000000000.0),
7533        ];
7534        assert_eq!(
7535            f16_expected,
7536            get_cast_values::<Float16Type>(&i64_array, &DataType::Float16)
7537                .iter()
7538                .map(|i| i.parse::<f16>().unwrap())
7539                .collect::<Vec<f16>>()
7540        );
7541
7542        let i64_expected = vec![
7543            "-9223372036854775808",
7544            "-2147483648",
7545            "-32768",
7546            "-128",
7547            "0",
7548            "127",
7549            "32767",
7550            "2147483647",
7551            "9223372036854775807",
7552        ];
7553        assert_eq!(
7554            i64_expected,
7555            get_cast_values::<Int64Type>(&i64_array, &DataType::Int64)
7556        );
7557
7558        let i32_expected = vec![
7559            "null",
7560            "-2147483648",
7561            "-32768",
7562            "-128",
7563            "0",
7564            "127",
7565            "32767",
7566            "2147483647",
7567            "null",
7568        ];
7569        assert_eq!(
7570            i32_expected,
7571            get_cast_values::<Int32Type>(&i64_array, &DataType::Int32)
7572        );
7573
7574        assert_eq!(
7575            i32_expected,
7576            get_cast_values::<Date32Type>(&i64_array, &DataType::Date32)
7577        );
7578
7579        let i16_expected = vec![
7580            "null", "null", "-32768", "-128", "0", "127", "32767", "null", "null",
7581        ];
7582        assert_eq!(
7583            i16_expected,
7584            get_cast_values::<Int16Type>(&i64_array, &DataType::Int16)
7585        );
7586
7587        let i8_expected = vec![
7588            "null", "null", "null", "-128", "0", "127", "null", "null", "null",
7589        ];
7590        assert_eq!(
7591            i8_expected,
7592            get_cast_values::<Int8Type>(&i64_array, &DataType::Int8)
7593        );
7594
7595        let u64_expected = vec![
7596            "null",
7597            "null",
7598            "null",
7599            "null",
7600            "0",
7601            "127",
7602            "32767",
7603            "2147483647",
7604            "9223372036854775807",
7605        ];
7606        assert_eq!(
7607            u64_expected,
7608            get_cast_values::<UInt64Type>(&i64_array, &DataType::UInt64)
7609        );
7610
7611        let u32_expected = vec![
7612            "null",
7613            "null",
7614            "null",
7615            "null",
7616            "0",
7617            "127",
7618            "32767",
7619            "2147483647",
7620            "null",
7621        ];
7622        assert_eq!(
7623            u32_expected,
7624            get_cast_values::<UInt32Type>(&i64_array, &DataType::UInt32)
7625        );
7626
7627        let u16_expected = vec![
7628            "null", "null", "null", "null", "0", "127", "32767", "null", "null",
7629        ];
7630        assert_eq!(
7631            u16_expected,
7632            get_cast_values::<UInt16Type>(&i64_array, &DataType::UInt16)
7633        );
7634
7635        let u8_expected = vec![
7636            "null", "null", "null", "null", "0", "127", "null", "null", "null",
7637        ];
7638        assert_eq!(
7639            u8_expected,
7640            get_cast_values::<UInt8Type>(&i64_array, &DataType::UInt8)
7641        );
7642    }
7643
7644    #[test]
7645    fn test_cast_from_int32() {
7646        let i32_values: Vec<i32> = vec![
7647            i32::MIN,
7648            i16::MIN as i32,
7649            i8::MIN as i32,
7650            0,
7651            i8::MAX as i32,
7652            i16::MAX as i32,
7653            i32::MAX,
7654        ];
7655        let i32_array: ArrayRef = Arc::new(Int32Array::from(i32_values));
7656
7657        let f64_expected = vec![
7658            "-2147483648.0",
7659            "-32768.0",
7660            "-128.0",
7661            "0.0",
7662            "127.0",
7663            "32767.0",
7664            "2147483647.0",
7665        ];
7666        assert_eq!(
7667            f64_expected,
7668            get_cast_values::<Float64Type>(&i32_array, &DataType::Float64)
7669        );
7670
7671        let f32_expected = vec![
7672            "-2147483600.0",
7673            "-32768.0",
7674            "-128.0",
7675            "0.0",
7676            "127.0",
7677            "32767.0",
7678            "2147483600.0",
7679        ];
7680        assert_eq!(
7681            f32_expected,
7682            get_cast_values::<Float32Type>(&i32_array, &DataType::Float32)
7683        );
7684
7685        let f16_expected = vec![
7686            f16::from_f64(-2147483600.0),
7687            f16::from_f64(-32768.0),
7688            f16::from_f64(-128.0),
7689            f16::from_f64(0.0),
7690            f16::from_f64(127.0),
7691            f16::from_f64(32767.0),
7692            f16::from_f64(2147483600.0),
7693        ];
7694        assert_eq!(
7695            f16_expected,
7696            get_cast_values::<Float16Type>(&i32_array, &DataType::Float16)
7697                .iter()
7698                .map(|i| i.parse::<f16>().unwrap())
7699                .collect::<Vec<f16>>()
7700        );
7701
7702        let i16_expected = vec!["null", "-32768", "-128", "0", "127", "32767", "null"];
7703        assert_eq!(
7704            i16_expected,
7705            get_cast_values::<Int16Type>(&i32_array, &DataType::Int16)
7706        );
7707
7708        let i8_expected = vec!["null", "null", "-128", "0", "127", "null", "null"];
7709        assert_eq!(
7710            i8_expected,
7711            get_cast_values::<Int8Type>(&i32_array, &DataType::Int8)
7712        );
7713
7714        let u64_expected = vec!["null", "null", "null", "0", "127", "32767", "2147483647"];
7715        assert_eq!(
7716            u64_expected,
7717            get_cast_values::<UInt64Type>(&i32_array, &DataType::UInt64)
7718        );
7719
7720        let u32_expected = vec!["null", "null", "null", "0", "127", "32767", "2147483647"];
7721        assert_eq!(
7722            u32_expected,
7723            get_cast_values::<UInt32Type>(&i32_array, &DataType::UInt32)
7724        );
7725
7726        let u16_expected = vec!["null", "null", "null", "0", "127", "32767", "null"];
7727        assert_eq!(
7728            u16_expected,
7729            get_cast_values::<UInt16Type>(&i32_array, &DataType::UInt16)
7730        );
7731
7732        let u8_expected = vec!["null", "null", "null", "0", "127", "null", "null"];
7733        assert_eq!(
7734            u8_expected,
7735            get_cast_values::<UInt8Type>(&i32_array, &DataType::UInt8)
7736        );
7737
7738        // The date32 to date64 cast increases the numerical values in order to keep the same dates.
7739        let i64_expected = vec![
7740            "-185542587187200000",
7741            "-2831155200000",
7742            "-11059200000",
7743            "0",
7744            "10972800000",
7745            "2831068800000",
7746            "185542587100800000",
7747        ];
7748        assert_eq!(
7749            i64_expected,
7750            get_cast_values::<Date64Type>(&i32_array, &DataType::Date64)
7751        );
7752    }
7753
7754    #[test]
7755    fn test_cast_from_int16() {
7756        let i16_values: Vec<i16> = vec![i16::MIN, i8::MIN as i16, 0, i8::MAX as i16, i16::MAX];
7757        let i16_array: ArrayRef = Arc::new(Int16Array::from(i16_values));
7758
7759        let f64_expected = vec!["-32768.0", "-128.0", "0.0", "127.0", "32767.0"];
7760        assert_eq!(
7761            f64_expected,
7762            get_cast_values::<Float64Type>(&i16_array, &DataType::Float64)
7763        );
7764
7765        let f32_expected = vec!["-32768.0", "-128.0", "0.0", "127.0", "32767.0"];
7766        assert_eq!(
7767            f32_expected,
7768            get_cast_values::<Float32Type>(&i16_array, &DataType::Float32)
7769        );
7770
7771        let f16_expected = vec![
7772            f16::from_f64(-32768.0),
7773            f16::from_f64(-128.0),
7774            f16::from_f64(0.0),
7775            f16::from_f64(127.0),
7776            f16::from_f64(32767.0),
7777        ];
7778        assert_eq!(
7779            f16_expected,
7780            get_cast_values::<Float16Type>(&i16_array, &DataType::Float16)
7781                .iter()
7782                .map(|i| i.parse::<f16>().unwrap())
7783                .collect::<Vec<f16>>()
7784        );
7785
7786        let i64_expected = vec!["-32768", "-128", "0", "127", "32767"];
7787        assert_eq!(
7788            i64_expected,
7789            get_cast_values::<Int64Type>(&i16_array, &DataType::Int64)
7790        );
7791
7792        let i32_expected = vec!["-32768", "-128", "0", "127", "32767"];
7793        assert_eq!(
7794            i32_expected,
7795            get_cast_values::<Int32Type>(&i16_array, &DataType::Int32)
7796        );
7797
7798        let i16_expected = vec!["-32768", "-128", "0", "127", "32767"];
7799        assert_eq!(
7800            i16_expected,
7801            get_cast_values::<Int16Type>(&i16_array, &DataType::Int16)
7802        );
7803
7804        let i8_expected = vec!["null", "-128", "0", "127", "null"];
7805        assert_eq!(
7806            i8_expected,
7807            get_cast_values::<Int8Type>(&i16_array, &DataType::Int8)
7808        );
7809
7810        let u64_expected = vec!["null", "null", "0", "127", "32767"];
7811        assert_eq!(
7812            u64_expected,
7813            get_cast_values::<UInt64Type>(&i16_array, &DataType::UInt64)
7814        );
7815
7816        let u32_expected = vec!["null", "null", "0", "127", "32767"];
7817        assert_eq!(
7818            u32_expected,
7819            get_cast_values::<UInt32Type>(&i16_array, &DataType::UInt32)
7820        );
7821
7822        let u16_expected = vec!["null", "null", "0", "127", "32767"];
7823        assert_eq!(
7824            u16_expected,
7825            get_cast_values::<UInt16Type>(&i16_array, &DataType::UInt16)
7826        );
7827
7828        let u8_expected = vec!["null", "null", "0", "127", "null"];
7829        assert_eq!(
7830            u8_expected,
7831            get_cast_values::<UInt8Type>(&i16_array, &DataType::UInt8)
7832        );
7833    }
7834
7835    #[test]
7836    fn test_cast_from_date32() {
7837        let i32_values: Vec<i32> = vec![
7838            i32::MIN,
7839            i16::MIN as i32,
7840            i8::MIN as i32,
7841            0,
7842            i8::MAX as i32,
7843            i16::MAX as i32,
7844            i32::MAX,
7845        ];
7846        let date32_array: ArrayRef = Arc::new(Date32Array::from(i32_values));
7847
7848        let i64_expected = vec![
7849            "-2147483648",
7850            "-32768",
7851            "-128",
7852            "0",
7853            "127",
7854            "32767",
7855            "2147483647",
7856        ];
7857        assert_eq!(
7858            i64_expected,
7859            get_cast_values::<Int64Type>(&date32_array, &DataType::Int64)
7860        );
7861    }
7862
7863    #[test]
7864    fn test_cast_from_int8() {
7865        let i8_values: Vec<i8> = vec![i8::MIN, 0, i8::MAX];
7866        let i8_array = Int8Array::from(i8_values);
7867
7868        let f64_expected = vec!["-128.0", "0.0", "127.0"];
7869        assert_eq!(
7870            f64_expected,
7871            get_cast_values::<Float64Type>(&i8_array, &DataType::Float64)
7872        );
7873
7874        let f32_expected = vec!["-128.0", "0.0", "127.0"];
7875        assert_eq!(
7876            f32_expected,
7877            get_cast_values::<Float32Type>(&i8_array, &DataType::Float32)
7878        );
7879
7880        let f16_expected = vec!["-128.0", "0.0", "127.0"];
7881        assert_eq!(
7882            f16_expected,
7883            get_cast_values::<Float16Type>(&i8_array, &DataType::Float16)
7884        );
7885
7886        let i64_expected = vec!["-128", "0", "127"];
7887        assert_eq!(
7888            i64_expected,
7889            get_cast_values::<Int64Type>(&i8_array, &DataType::Int64)
7890        );
7891
7892        let i32_expected = vec!["-128", "0", "127"];
7893        assert_eq!(
7894            i32_expected,
7895            get_cast_values::<Int32Type>(&i8_array, &DataType::Int32)
7896        );
7897
7898        let i16_expected = vec!["-128", "0", "127"];
7899        assert_eq!(
7900            i16_expected,
7901            get_cast_values::<Int16Type>(&i8_array, &DataType::Int16)
7902        );
7903
7904        let i8_expected = vec!["-128", "0", "127"];
7905        assert_eq!(
7906            i8_expected,
7907            get_cast_values::<Int8Type>(&i8_array, &DataType::Int8)
7908        );
7909
7910        let u64_expected = vec!["null", "0", "127"];
7911        assert_eq!(
7912            u64_expected,
7913            get_cast_values::<UInt64Type>(&i8_array, &DataType::UInt64)
7914        );
7915
7916        let u32_expected = vec!["null", "0", "127"];
7917        assert_eq!(
7918            u32_expected,
7919            get_cast_values::<UInt32Type>(&i8_array, &DataType::UInt32)
7920        );
7921
7922        let u16_expected = vec!["null", "0", "127"];
7923        assert_eq!(
7924            u16_expected,
7925            get_cast_values::<UInt16Type>(&i8_array, &DataType::UInt16)
7926        );
7927
7928        let u8_expected = vec!["null", "0", "127"];
7929        assert_eq!(
7930            u8_expected,
7931            get_cast_values::<UInt8Type>(&i8_array, &DataType::UInt8)
7932        );
7933    }
7934
7935    /// Convert `array` into a vector of strings by casting to data type dt
7936    fn get_cast_values<T>(array: &dyn Array, dt: &DataType) -> Vec<String>
7937    where
7938        T: ArrowPrimitiveType,
7939    {
7940        let c = cast(array, dt).unwrap();
7941        let a = c.as_primitive::<T>();
7942        let mut v: Vec<String> = vec![];
7943        for i in 0..array.len() {
7944            if a.is_null(i) {
7945                v.push("null".to_string())
7946            } else {
7947                v.push(format!("{:?}", a.value(i)));
7948            }
7949        }
7950        v
7951    }
7952
7953    #[test]
7954    fn test_cast_utf8_dict() {
7955        // FROM a dictionary with of Utf8 values
7956        let mut builder = StringDictionaryBuilder::<Int8Type>::new();
7957        builder.append("one").unwrap();
7958        builder.append_null();
7959        builder.append("three").unwrap();
7960        let array: ArrayRef = Arc::new(builder.finish());
7961
7962        let expected = vec!["one", "null", "three"];
7963
7964        // Test casting TO StringArray
7965        let cast_type = Utf8;
7966        let cast_array = cast(&array, &cast_type).expect("cast to UTF-8 failed");
7967        assert_eq!(cast_array.data_type(), &cast_type);
7968        assert_eq!(array_to_strings(&cast_array), expected);
7969
7970        // Test casting TO Dictionary (with different index sizes)
7971
7972        let cast_type = Dictionary(Box::new(Int16), Box::new(Utf8));
7973        let cast_array = cast(&array, &cast_type).expect("cast failed");
7974        assert_eq!(cast_array.data_type(), &cast_type);
7975        assert_eq!(array_to_strings(&cast_array), expected);
7976
7977        let cast_type = Dictionary(Box::new(Int32), Box::new(Utf8));
7978        let cast_array = cast(&array, &cast_type).expect("cast failed");
7979        assert_eq!(cast_array.data_type(), &cast_type);
7980        assert_eq!(array_to_strings(&cast_array), expected);
7981
7982        let cast_type = Dictionary(Box::new(Int64), Box::new(Utf8));
7983        let cast_array = cast(&array, &cast_type).expect("cast failed");
7984        assert_eq!(cast_array.data_type(), &cast_type);
7985        assert_eq!(array_to_strings(&cast_array), expected);
7986
7987        let cast_type = Dictionary(Box::new(UInt8), Box::new(Utf8));
7988        let cast_array = cast(&array, &cast_type).expect("cast failed");
7989        assert_eq!(cast_array.data_type(), &cast_type);
7990        assert_eq!(array_to_strings(&cast_array), expected);
7991
7992        let cast_type = Dictionary(Box::new(UInt16), Box::new(Utf8));
7993        let cast_array = cast(&array, &cast_type).expect("cast failed");
7994        assert_eq!(cast_array.data_type(), &cast_type);
7995        assert_eq!(array_to_strings(&cast_array), expected);
7996
7997        let cast_type = Dictionary(Box::new(UInt32), Box::new(Utf8));
7998        let cast_array = cast(&array, &cast_type).expect("cast failed");
7999        assert_eq!(cast_array.data_type(), &cast_type);
8000        assert_eq!(array_to_strings(&cast_array), expected);
8001
8002        let cast_type = Dictionary(Box::new(UInt64), Box::new(Utf8));
8003        let cast_array = cast(&array, &cast_type).expect("cast failed");
8004        assert_eq!(cast_array.data_type(), &cast_type);
8005        assert_eq!(array_to_strings(&cast_array), expected);
8006    }
8007
8008    #[test]
8009    fn test_cast_dict_to_dict_bad_index_value_primitive() {
8010        // test converting from an array that has indexes of a type
8011        // that are out of bounds for a particular other kind of
8012        // index.
8013
8014        let mut builder = PrimitiveDictionaryBuilder::<Int32Type, Int64Type>::new();
8015
8016        // add 200 distinct values (which can be stored by a
8017        // dictionary indexed by int32, but not a dictionary indexed
8018        // with int8)
8019        for i in 0..200 {
8020            builder.append(i).unwrap();
8021        }
8022        let array: ArrayRef = Arc::new(builder.finish());
8023
8024        let cast_type = Dictionary(Box::new(Int8), Box::new(Utf8));
8025        let res = cast(&array, &cast_type);
8026        assert!(res.is_err());
8027        let actual_error = format!("{res:?}");
8028        let expected_error = "Could not convert 72 dictionary indexes from Int32 to Int8";
8029        assert!(
8030            actual_error.contains(expected_error),
8031            "did not find expected error '{actual_error}' in actual error '{expected_error}'"
8032        );
8033    }
8034
8035    #[test]
8036    fn test_cast_dict_to_dict_bad_index_value_utf8() {
8037        // Same test as test_cast_dict_to_dict_bad_index_value but use
8038        // string values (and encode the expected behavior here);
8039
8040        let mut builder = StringDictionaryBuilder::<Int32Type>::new();
8041
8042        // add 200 distinct values (which can be stored by a
8043        // dictionary indexed by int32, but not a dictionary indexed
8044        // with int8)
8045        for i in 0..200 {
8046            let val = format!("val{i}");
8047            builder.append(&val).unwrap();
8048        }
8049        let array = builder.finish();
8050
8051        let cast_type = Dictionary(Box::new(Int8), Box::new(Utf8));
8052        let res = cast(&array, &cast_type);
8053        assert!(res.is_err());
8054        let actual_error = format!("{res:?}");
8055        let expected_error = "Could not convert 72 dictionary indexes from Int32 to Int8";
8056        assert!(
8057            actual_error.contains(expected_error),
8058            "did not find expected error '{actual_error}' in actual error '{expected_error}'"
8059        );
8060    }
8061
8062    #[test]
8063    fn test_cast_primitive_dict() {
8064        // FROM a dictionary with of INT32 values
8065        let mut builder = PrimitiveDictionaryBuilder::<Int8Type, Int32Type>::new();
8066        builder.append(1).unwrap();
8067        builder.append_null();
8068        builder.append(3).unwrap();
8069        let array: ArrayRef = Arc::new(builder.finish());
8070
8071        let expected = vec!["1", "null", "3"];
8072
8073        // Test casting TO PrimitiveArray, different dictionary type
8074        let cast_array = cast(&array, &Utf8).expect("cast to UTF-8 failed");
8075        assert_eq!(array_to_strings(&cast_array), expected);
8076        assert_eq!(cast_array.data_type(), &Utf8);
8077
8078        let cast_array = cast(&array, &Int64).expect("cast to int64 failed");
8079        assert_eq!(array_to_strings(&cast_array), expected);
8080        assert_eq!(cast_array.data_type(), &Int64);
8081    }
8082
8083    #[test]
8084    fn test_cast_primitive_array_to_dict() {
8085        let mut builder = PrimitiveBuilder::<Int32Type>::new();
8086        builder.append_value(1);
8087        builder.append_null();
8088        builder.append_value(3);
8089        let array: ArrayRef = Arc::new(builder.finish());
8090
8091        let expected = vec!["1", "null", "3"];
8092
8093        // Cast to a dictionary (same value type, Int32)
8094        let cast_type = Dictionary(Box::new(UInt8), Box::new(Int32));
8095        let cast_array = cast(&array, &cast_type).expect("cast failed");
8096        assert_eq!(cast_array.data_type(), &cast_type);
8097        assert_eq!(array_to_strings(&cast_array), expected);
8098
8099        // Cast to a dictionary (different value type, Int8)
8100        let cast_type = Dictionary(Box::new(UInt8), Box::new(Int8));
8101        let cast_array = cast(&array, &cast_type).expect("cast failed");
8102        assert_eq!(cast_array.data_type(), &cast_type);
8103        assert_eq!(array_to_strings(&cast_array), expected);
8104    }
8105
8106    #[test]
8107    fn test_cast_time_array_to_dict() {
8108        use DataType::*;
8109
8110        let array = Arc::new(Date32Array::from(vec![Some(1000), None, Some(2000)])) as ArrayRef;
8111
8112        let expected = vec!["1972-09-27", "null", "1975-06-24"];
8113
8114        let cast_type = Dictionary(Box::new(UInt8), Box::new(Date32));
8115        let cast_array = cast(&array, &cast_type).expect("cast failed");
8116        assert_eq!(cast_array.data_type(), &cast_type);
8117        assert_eq!(array_to_strings(&cast_array), expected);
8118    }
8119
8120    #[test]
8121    fn test_cast_timestamp_array_to_dict() {
8122        use DataType::*;
8123
8124        let array = Arc::new(
8125            TimestampSecondArray::from(vec![Some(1000), None, Some(2000)]).with_timezone_utc(),
8126        ) as ArrayRef;
8127
8128        let expected = vec!["1970-01-01T00:16:40", "null", "1970-01-01T00:33:20"];
8129
8130        let cast_type = Dictionary(Box::new(UInt8), Box::new(Timestamp(TimeUnit::Second, None)));
8131        let cast_array = cast(&array, &cast_type).expect("cast failed");
8132        assert_eq!(cast_array.data_type(), &cast_type);
8133        assert_eq!(array_to_strings(&cast_array), expected);
8134    }
8135
8136    #[test]
8137    fn test_cast_string_array_to_dict() {
8138        use DataType::*;
8139
8140        let array = Arc::new(StringArray::from(vec![Some("one"), None, Some("three")])) as ArrayRef;
8141
8142        let expected = vec!["one", "null", "three"];
8143
8144        // Cast to a dictionary (same value type, Utf8)
8145        let cast_type = Dictionary(Box::new(UInt8), Box::new(Utf8));
8146        let cast_array = cast(&array, &cast_type).expect("cast failed");
8147        assert_eq!(cast_array.data_type(), &cast_type);
8148        assert_eq!(array_to_strings(&cast_array), expected);
8149    }
8150
8151    #[test]
8152    fn test_cast_null_array_to_from_decimal_array() {
8153        let data_type = DataType::Decimal128(12, 4);
8154        let array = new_null_array(&DataType::Null, 4);
8155        assert_eq!(array.data_type(), &DataType::Null);
8156        let cast_array = cast(&array, &data_type).expect("cast failed");
8157        assert_eq!(cast_array.data_type(), &data_type);
8158        for i in 0..4 {
8159            assert!(cast_array.is_null(i));
8160        }
8161
8162        let array = new_null_array(&data_type, 4);
8163        assert_eq!(array.data_type(), &data_type);
8164        let cast_array = cast(&array, &DataType::Null).expect("cast failed");
8165        assert_eq!(cast_array.data_type(), &DataType::Null);
8166        assert_eq!(cast_array.len(), 4);
8167        assert_eq!(cast_array.logical_nulls().unwrap().null_count(), 4);
8168    }
8169
8170    #[test]
8171    fn test_cast_null_array_from_and_to_primitive_array() {
8172        macro_rules! typed_test {
8173            ($ARR_TYPE:ident, $DATATYPE:ident, $TYPE:tt) => {{
8174                {
8175                    let array = Arc::new(NullArray::new(6)) as ArrayRef;
8176                    let expected = $ARR_TYPE::from(vec![None; 6]);
8177                    let cast_type = DataType::$DATATYPE;
8178                    let cast_array = cast(&array, &cast_type).expect("cast failed");
8179                    let cast_array = cast_array.as_primitive::<$TYPE>();
8180                    assert_eq!(cast_array.data_type(), &cast_type);
8181                    assert_eq!(cast_array, &expected);
8182                }
8183            }};
8184        }
8185
8186        typed_test!(Int16Array, Int16, Int16Type);
8187        typed_test!(Int32Array, Int32, Int32Type);
8188        typed_test!(Int64Array, Int64, Int64Type);
8189
8190        typed_test!(UInt16Array, UInt16, UInt16Type);
8191        typed_test!(UInt32Array, UInt32, UInt32Type);
8192        typed_test!(UInt64Array, UInt64, UInt64Type);
8193
8194        typed_test!(Float16Array, Float16, Float16Type);
8195        typed_test!(Float32Array, Float32, Float32Type);
8196        typed_test!(Float64Array, Float64, Float64Type);
8197
8198        typed_test!(Date32Array, Date32, Date32Type);
8199        typed_test!(Date64Array, Date64, Date64Type);
8200    }
8201
8202    fn cast_from_null_to_other(data_type: &DataType) {
8203        // Cast from null to data_type
8204        {
8205            let array = new_null_array(&DataType::Null, 4);
8206            assert_eq!(array.data_type(), &DataType::Null);
8207            let cast_array = cast(&array, data_type).expect("cast failed");
8208            assert_eq!(cast_array.data_type(), data_type);
8209            for i in 0..4 {
8210                assert!(cast_array.is_null(i));
8211            }
8212        }
8213    }
8214
8215    #[test]
8216    fn test_cast_null_from_and_to_variable_sized() {
8217        cast_from_null_to_other(&DataType::Utf8);
8218        cast_from_null_to_other(&DataType::LargeUtf8);
8219        cast_from_null_to_other(&DataType::Binary);
8220        cast_from_null_to_other(&DataType::LargeBinary);
8221    }
8222
8223    #[test]
8224    fn test_cast_null_from_and_to_nested_type() {
8225        // Cast null from and to map
8226        let data_type = DataType::Map(
8227            Arc::new(Field::new_struct(
8228                "entry",
8229                vec![
8230                    Field::new("key", DataType::Utf8, false),
8231                    Field::new("value", DataType::Int32, true),
8232                ],
8233                false,
8234            )),
8235            false,
8236        );
8237        cast_from_null_to_other(&data_type);
8238
8239        // Cast null from and to list
8240        let data_type = DataType::List(Arc::new(Field::new_list_field(DataType::Int32, true)));
8241        cast_from_null_to_other(&data_type);
8242        let data_type = DataType::LargeList(Arc::new(Field::new_list_field(DataType::Int32, true)));
8243        cast_from_null_to_other(&data_type);
8244        let data_type =
8245            DataType::FixedSizeList(Arc::new(Field::new_list_field(DataType::Int32, true)), 4);
8246        cast_from_null_to_other(&data_type);
8247
8248        // Cast null from and to dictionary
8249        let values = vec![None, None, None, None] as Vec<Option<&str>>;
8250        let array: DictionaryArray<Int8Type> = values.into_iter().collect();
8251        let array = Arc::new(array) as ArrayRef;
8252        let data_type = array.data_type().to_owned();
8253        cast_from_null_to_other(&data_type);
8254
8255        // Cast null from and to struct
8256        let data_type = DataType::Struct(vec![Field::new("data", DataType::Int64, false)].into());
8257        cast_from_null_to_other(&data_type);
8258    }
8259
8260    /// Print the `DictionaryArray` `array` as a vector of strings
8261    fn array_to_strings(array: &ArrayRef) -> Vec<String> {
8262        let options = FormatOptions::new().with_null("null");
8263        let formatter = ArrayFormatter::try_new(array.as_ref(), &options).unwrap();
8264        (0..array.len())
8265            .map(|i| formatter.value(i).to_string())
8266            .collect()
8267    }
8268
8269    #[test]
8270    fn test_cast_utf8_to_date32() {
8271        use chrono::NaiveDate;
8272        let from_ymd = chrono::NaiveDate::from_ymd_opt;
8273        let since = chrono::NaiveDate::signed_duration_since;
8274
8275        let a = StringArray::from(vec![
8276            "2000-01-01",          // valid date with leading 0s
8277            "2000-01-01T12:00:00", // valid datetime, will throw away the time part
8278            "2000-2-2",            // valid date without leading 0s
8279            "2000-00-00",          // invalid month and day
8280            "2000",                // just a year is invalid
8281        ]);
8282        let array = Arc::new(a) as ArrayRef;
8283        let b = cast(&array, &DataType::Date32).unwrap();
8284        let c = b.as_primitive::<Date32Type>();
8285
8286        // test valid inputs
8287        let date_value = since(
8288            NaiveDate::from_ymd_opt(2000, 1, 1).unwrap(),
8289            from_ymd(1970, 1, 1).unwrap(),
8290        )
8291        .num_days() as i32;
8292        assert!(c.is_valid(0)); // "2000-01-01"
8293        assert_eq!(date_value, c.value(0));
8294
8295        assert!(c.is_valid(1)); // "2000-01-01T12:00:00"
8296        assert_eq!(date_value, c.value(1));
8297
8298        let date_value = since(
8299            NaiveDate::from_ymd_opt(2000, 2, 2).unwrap(),
8300            from_ymd(1970, 1, 1).unwrap(),
8301        )
8302        .num_days() as i32;
8303        assert!(c.is_valid(2)); // "2000-2-2"
8304        assert_eq!(date_value, c.value(2));
8305
8306        // test invalid inputs
8307        assert!(!c.is_valid(3)); // "2000-00-00"
8308        assert!(!c.is_valid(4)); // "2000"
8309    }
8310
8311    #[test]
8312    fn test_cast_utf8_to_date64() {
8313        let a = StringArray::from(vec![
8314            "2000-01-01T12:00:00", // date + time valid
8315            "2020-12-15T12:34:56", // date + time valid
8316            "2020-2-2T12:34:56",   // valid date time without leading 0s
8317            "2000-00-00T12:00:00", // invalid month and day
8318            "2000-01-01 12:00:00", // missing the 'T'
8319            "2000-01-01",          // just a date is invalid
8320        ]);
8321        let array = Arc::new(a) as ArrayRef;
8322        let b = cast(&array, &DataType::Date64).unwrap();
8323        let c = b.as_primitive::<Date64Type>();
8324
8325        // test valid inputs
8326        assert!(c.is_valid(0)); // "2000-01-01T12:00:00"
8327        assert_eq!(946728000000, c.value(0));
8328        assert!(c.is_valid(1)); // "2020-12-15T12:34:56"
8329        assert_eq!(1608035696000, c.value(1));
8330        assert!(!c.is_valid(2)); // "2020-2-2T12:34:56"
8331
8332        assert!(!c.is_valid(3)); // "2000-00-00T12:00:00"
8333        assert!(c.is_valid(4)); // "2000-01-01 12:00:00"
8334        assert_eq!(946728000000, c.value(4));
8335        assert!(c.is_valid(5)); // "2000-01-01"
8336        assert_eq!(946684800000, c.value(5));
8337    }
8338
8339    #[test]
8340    fn test_can_cast_fsl_to_fsl() {
8341        let from_array = Arc::new(
8342            FixedSizeListArray::from_iter_primitive::<Float32Type, _, _>(
8343                [Some([Some(1.0), Some(2.0)]), None],
8344                2,
8345            ),
8346        ) as ArrayRef;
8347        let to_array = Arc::new(
8348            FixedSizeListArray::from_iter_primitive::<Float16Type, _, _>(
8349                [
8350                    Some([Some(f16::from_f32(1.0)), Some(f16::from_f32(2.0))]),
8351                    None,
8352                ],
8353                2,
8354            ),
8355        ) as ArrayRef;
8356
8357        assert!(can_cast_types(from_array.data_type(), to_array.data_type()));
8358        let actual = cast(&from_array, to_array.data_type()).unwrap();
8359        assert_eq!(actual.data_type(), to_array.data_type());
8360
8361        let invalid_target =
8362            DataType::FixedSizeList(Arc::new(Field::new_list_field(DataType::Binary, true)), 2);
8363        assert!(!can_cast_types(from_array.data_type(), &invalid_target));
8364
8365        let invalid_size =
8366            DataType::FixedSizeList(Arc::new(Field::new_list_field(DataType::Float16, true)), 5);
8367        assert!(!can_cast_types(from_array.data_type(), &invalid_size));
8368    }
8369
8370    #[test]
8371    fn test_can_cast_types_fixed_size_list_to_list() {
8372        // DataType::List
8373        let array1 = Arc::new(make_fixed_size_list_array()) as ArrayRef;
8374        assert!(can_cast_types(
8375            array1.data_type(),
8376            &DataType::List(Arc::new(Field::new("", DataType::Int32, false)))
8377        ));
8378
8379        // DataType::LargeList
8380        let array2 = Arc::new(make_fixed_size_list_array_for_large_list()) as ArrayRef;
8381        assert!(can_cast_types(
8382            array2.data_type(),
8383            &DataType::LargeList(Arc::new(Field::new("", DataType::Int64, false)))
8384        ));
8385    }
8386
8387    #[test]
8388    fn test_cast_fixed_size_list_to_list() {
8389        // Important cases:
8390        // 1. With/without nulls
8391        // 2. LargeList and List
8392        // 3. With and without inner casts
8393
8394        let cases = [
8395            // fixed_size_list<i32, 2> => list<i32>
8396            (
8397                Arc::new(FixedSizeListArray::from_iter_primitive::<Int32Type, _, _>(
8398                    [[1, 1].map(Some), [2, 2].map(Some)].map(Some),
8399                    2,
8400                )) as ArrayRef,
8401                Arc::new(ListArray::from_iter_primitive::<Int32Type, _, _>([
8402                    Some([Some(1), Some(1)]),
8403                    Some([Some(2), Some(2)]),
8404                ])) as ArrayRef,
8405            ),
8406            // fixed_size_list<i32, 2> => list<i32> (nullable)
8407            (
8408                Arc::new(FixedSizeListArray::from_iter_primitive::<Int32Type, _, _>(
8409                    [None, Some([Some(2), Some(2)])],
8410                    2,
8411                )) as ArrayRef,
8412                Arc::new(ListArray::from_iter_primitive::<Int32Type, _, _>([
8413                    None,
8414                    Some([Some(2), Some(2)]),
8415                ])) as ArrayRef,
8416            ),
8417            // fixed_size_list<i32, 2> => large_list<i64>
8418            (
8419                Arc::new(FixedSizeListArray::from_iter_primitive::<Int32Type, _, _>(
8420                    [[1, 1].map(Some), [2, 2].map(Some)].map(Some),
8421                    2,
8422                )) as ArrayRef,
8423                Arc::new(LargeListArray::from_iter_primitive::<Int64Type, _, _>([
8424                    Some([Some(1), Some(1)]),
8425                    Some([Some(2), Some(2)]),
8426                ])) as ArrayRef,
8427            ),
8428            // fixed_size_list<i32, 2> => large_list<i64> (nullable)
8429            (
8430                Arc::new(FixedSizeListArray::from_iter_primitive::<Int32Type, _, _>(
8431                    [None, Some([Some(2), Some(2)])],
8432                    2,
8433                )) as ArrayRef,
8434                Arc::new(LargeListArray::from_iter_primitive::<Int64Type, _, _>([
8435                    None,
8436                    Some([Some(2), Some(2)]),
8437                ])) as ArrayRef,
8438            ),
8439        ];
8440
8441        for (array, expected) in cases {
8442            let array = Arc::new(array) as ArrayRef;
8443
8444            assert!(
8445                can_cast_types(array.data_type(), expected.data_type()),
8446                "can_cast_types claims we cannot cast {:?} to {:?}",
8447                array.data_type(),
8448                expected.data_type()
8449            );
8450
8451            let list_array = cast(&array, expected.data_type())
8452                .unwrap_or_else(|_| panic!("Failed to cast {array:?} to {expected:?}"));
8453            assert_eq!(
8454                list_array.as_ref(),
8455                &expected,
8456                "Incorrect result from casting {array:?} to {expected:?}",
8457            );
8458        }
8459    }
8460
8461    #[test]
8462    fn test_cast_utf8_to_list() {
8463        // DataType::List
8464        let array = Arc::new(StringArray::from(vec!["5"])) as ArrayRef;
8465        let field = Arc::new(Field::new("", DataType::Int32, false));
8466        let list_array = cast(&array, &DataType::List(field.clone())).unwrap();
8467        let actual = list_array.as_list_opt::<i32>().unwrap();
8468        let expect = ListArray::from_iter_primitive::<Int32Type, _, _>([Some([Some(5)])]);
8469        assert_eq!(&expect.value(0), &actual.value(0));
8470
8471        // DataType::LargeList
8472        let list_array = cast(&array, &DataType::LargeList(field.clone())).unwrap();
8473        let actual = list_array.as_list_opt::<i64>().unwrap();
8474        let expect = LargeListArray::from_iter_primitive::<Int32Type, _, _>([Some([Some(5)])]);
8475        assert_eq!(&expect.value(0), &actual.value(0));
8476
8477        // DataType::FixedSizeList
8478        let list_array = cast(&array, &DataType::FixedSizeList(field.clone(), 1)).unwrap();
8479        let actual = list_array.as_fixed_size_list_opt().unwrap();
8480        let expect =
8481            FixedSizeListArray::from_iter_primitive::<Int32Type, _, _>([Some([Some(5)])], 1);
8482        assert_eq!(&expect.value(0), &actual.value(0));
8483    }
8484
8485    #[test]
8486    fn test_cast_single_element_fixed_size_list() {
8487        // FixedSizeList<T>[1] => T
8488        let from_array = Arc::new(FixedSizeListArray::from_iter_primitive::<Int16Type, _, _>(
8489            [(Some([Some(5)]))],
8490            1,
8491        )) as ArrayRef;
8492        let casted_array = cast(&from_array, &DataType::Int32).unwrap();
8493        let actual: &Int32Array = casted_array.as_primitive();
8494        let expected = Int32Array::from(vec![Some(5)]);
8495        assert_eq!(&expected, actual);
8496
8497        // FixedSizeList<T>[1] => FixedSizeList<U>[1]
8498        let from_array = Arc::new(FixedSizeListArray::from_iter_primitive::<Int16Type, _, _>(
8499            [(Some([Some(5)]))],
8500            1,
8501        )) as ArrayRef;
8502        let to_field = Arc::new(Field::new("dummy", DataType::Float32, false));
8503        let actual = cast(&from_array, &DataType::FixedSizeList(to_field.clone(), 1)).unwrap();
8504        let expected = Arc::new(FixedSizeListArray::new(
8505            to_field.clone(),
8506            1,
8507            Arc::new(Float32Array::from(vec![Some(5.0)])) as ArrayRef,
8508            None,
8509        )) as ArrayRef;
8510        assert_eq!(*expected, *actual);
8511
8512        // FixedSizeList<T>[1] => FixedSizeList<FixdSizedList<U>[1]>[1]
8513        let from_array = Arc::new(FixedSizeListArray::from_iter_primitive::<Int16Type, _, _>(
8514            [(Some([Some(5)]))],
8515            1,
8516        )) as ArrayRef;
8517        let to_field_inner = Arc::new(Field::new_list_field(DataType::Float32, false));
8518        let to_field = Arc::new(Field::new(
8519            "dummy",
8520            DataType::FixedSizeList(to_field_inner.clone(), 1),
8521            false,
8522        ));
8523        let actual = cast(&from_array, &DataType::FixedSizeList(to_field.clone(), 1)).unwrap();
8524        let expected = Arc::new(FixedSizeListArray::new(
8525            to_field.clone(),
8526            1,
8527            Arc::new(FixedSizeListArray::new(
8528                to_field_inner.clone(),
8529                1,
8530                Arc::new(Float32Array::from(vec![Some(5.0)])) as ArrayRef,
8531                None,
8532            )) as ArrayRef,
8533            None,
8534        )) as ArrayRef;
8535        assert_eq!(*expected, *actual);
8536
8537        // T => FixedSizeList<T>[1] (non-nullable)
8538        let field = Arc::new(Field::new("dummy", DataType::Float32, false));
8539        let from_array = Arc::new(Int8Array::from(vec![Some(5)])) as ArrayRef;
8540        let casted_array = cast(&from_array, &DataType::FixedSizeList(field.clone(), 1)).unwrap();
8541        let actual = casted_array.as_fixed_size_list();
8542        let expected = Arc::new(FixedSizeListArray::new(
8543            field.clone(),
8544            1,
8545            Arc::new(Float32Array::from(vec![Some(5.0)])) as ArrayRef,
8546            None,
8547        )) as ArrayRef;
8548        assert_eq!(expected.as_ref(), actual);
8549
8550        // T => FixedSizeList<T>[1] (nullable)
8551        let field = Arc::new(Field::new("nullable", DataType::Float32, true));
8552        let from_array = Arc::new(Int8Array::from(vec![None])) as ArrayRef;
8553        let casted_array = cast(&from_array, &DataType::FixedSizeList(field.clone(), 1)).unwrap();
8554        let actual = casted_array.as_fixed_size_list();
8555        let expected = Arc::new(FixedSizeListArray::new(
8556            field.clone(),
8557            1,
8558            Arc::new(Float32Array::from(vec![None])) as ArrayRef,
8559            None,
8560        )) as ArrayRef;
8561        assert_eq!(expected.as_ref(), actual);
8562    }
8563
8564    #[test]
8565    fn test_cast_list_containers() {
8566        // large-list to list
8567        let array = Arc::new(make_large_list_array()) as ArrayRef;
8568        let list_array = cast(
8569            &array,
8570            &DataType::List(Arc::new(Field::new("", DataType::Int32, false))),
8571        )
8572        .unwrap();
8573        let actual = list_array.as_any().downcast_ref::<ListArray>().unwrap();
8574        let expected = array.as_any().downcast_ref::<LargeListArray>().unwrap();
8575
8576        assert_eq!(&expected.value(0), &actual.value(0));
8577        assert_eq!(&expected.value(1), &actual.value(1));
8578        assert_eq!(&expected.value(2), &actual.value(2));
8579
8580        // list to large-list
8581        let array = Arc::new(make_list_array()) as ArrayRef;
8582        let large_list_array = cast(
8583            &array,
8584            &DataType::LargeList(Arc::new(Field::new("", DataType::Int32, false))),
8585        )
8586        .unwrap();
8587        let actual = large_list_array
8588            .as_any()
8589            .downcast_ref::<LargeListArray>()
8590            .unwrap();
8591        let expected = array.as_any().downcast_ref::<ListArray>().unwrap();
8592
8593        assert_eq!(&expected.value(0), &actual.value(0));
8594        assert_eq!(&expected.value(1), &actual.value(1));
8595        assert_eq!(&expected.value(2), &actual.value(2));
8596    }
8597
8598    #[test]
8599    fn test_cast_list_to_fsl() {
8600        // There four noteworthy cases we should handle:
8601        // 1. No nulls
8602        // 2. Nulls that are always empty
8603        // 3. Nulls that have varying lengths
8604        // 4. Nulls that are correctly sized (same as target list size)
8605
8606        // Non-null case
8607        let field = Arc::new(Field::new_list_field(DataType::Int32, true));
8608        let values = vec![
8609            Some(vec![Some(1), Some(2), Some(3)]),
8610            Some(vec![Some(4), Some(5), Some(6)]),
8611        ];
8612        let array = Arc::new(ListArray::from_iter_primitive::<Int32Type, _, _>(
8613            values.clone(),
8614        )) as ArrayRef;
8615        let expected = Arc::new(FixedSizeListArray::from_iter_primitive::<Int32Type, _, _>(
8616            values, 3,
8617        )) as ArrayRef;
8618        let actual = cast(array.as_ref(), &DataType::FixedSizeList(field.clone(), 3)).unwrap();
8619        assert_eq!(expected.as_ref(), actual.as_ref());
8620
8621        // Null cases
8622        // Array is [[1, 2, 3], null, [4, 5, 6], null]
8623        let cases = [
8624            (
8625                // Zero-length nulls
8626                vec![1, 2, 3, 4, 5, 6],
8627                vec![3, 0, 3, 0],
8628            ),
8629            (
8630                // Varying-length nulls
8631                vec![1, 2, 3, 0, 0, 4, 5, 6, 0],
8632                vec![3, 2, 3, 1],
8633            ),
8634            (
8635                // Correctly-sized nulls
8636                vec![1, 2, 3, 0, 0, 0, 4, 5, 6, 0, 0, 0],
8637                vec![3, 3, 3, 3],
8638            ),
8639            (
8640                // Mixed nulls
8641                vec![1, 2, 3, 4, 5, 6, 0, 0, 0],
8642                vec![3, 0, 3, 3],
8643            ),
8644        ];
8645        let null_buffer = NullBuffer::from(vec![true, false, true, false]);
8646
8647        let expected = Arc::new(FixedSizeListArray::from_iter_primitive::<Int32Type, _, _>(
8648            vec![
8649                Some(vec![Some(1), Some(2), Some(3)]),
8650                None,
8651                Some(vec![Some(4), Some(5), Some(6)]),
8652                None,
8653            ],
8654            3,
8655        )) as ArrayRef;
8656
8657        for (values, lengths) in cases.iter() {
8658            let array = Arc::new(ListArray::new(
8659                field.clone(),
8660                OffsetBuffer::from_lengths(lengths.clone()),
8661                Arc::new(Int32Array::from(values.clone())),
8662                Some(null_buffer.clone()),
8663            )) as ArrayRef;
8664            let actual = cast(array.as_ref(), &DataType::FixedSizeList(field.clone(), 3)).unwrap();
8665            assert_eq!(expected.as_ref(), actual.as_ref());
8666        }
8667    }
8668
8669    #[test]
8670    fn test_cast_list_to_fsl_safety() {
8671        let values = vec![
8672            Some(vec![Some(1), Some(2), Some(3)]),
8673            Some(vec![Some(4), Some(5)]),
8674            Some(vec![Some(6), Some(7), Some(8), Some(9)]),
8675            Some(vec![Some(3), Some(4), Some(5)]),
8676        ];
8677        let array = Arc::new(ListArray::from_iter_primitive::<Int32Type, _, _>(
8678            values.clone(),
8679        )) as ArrayRef;
8680
8681        let res = cast_with_options(
8682            array.as_ref(),
8683            &DataType::FixedSizeList(Arc::new(Field::new_list_field(DataType::Int32, true)), 3),
8684            &CastOptions {
8685                safe: false,
8686                ..Default::default()
8687            },
8688        );
8689        assert!(res.is_err());
8690        assert!(
8691            format!("{res:?}")
8692                .contains("Cannot cast to FixedSizeList(3): value at index 1 has length 2")
8693        );
8694
8695        // When safe=true (default), the cast will fill nulls for lists that are
8696        // too short and truncate lists that are too long.
8697        let res = cast(
8698            array.as_ref(),
8699            &DataType::FixedSizeList(Arc::new(Field::new_list_field(DataType::Int32, true)), 3),
8700        )
8701        .unwrap();
8702        let expected = Arc::new(FixedSizeListArray::from_iter_primitive::<Int32Type, _, _>(
8703            vec![
8704                Some(vec![Some(1), Some(2), Some(3)]),
8705                None, // Too short -> replaced with null
8706                None, // Too long -> replaced with null
8707                Some(vec![Some(3), Some(4), Some(5)]),
8708            ],
8709            3,
8710        )) as ArrayRef;
8711        assert_eq!(expected.as_ref(), res.as_ref());
8712
8713        // The safe option is false and the source array contains a null list.
8714        // issue: https://github.com/apache/arrow-rs/issues/5642
8715        let array = Arc::new(ListArray::from_iter_primitive::<Int32Type, _, _>(vec![
8716            Some(vec![Some(1), Some(2), Some(3)]),
8717            None,
8718        ])) as ArrayRef;
8719        let res = cast_with_options(
8720            array.as_ref(),
8721            &DataType::FixedSizeList(Arc::new(Field::new_list_field(DataType::Int32, true)), 3),
8722            &CastOptions {
8723                safe: false,
8724                ..Default::default()
8725            },
8726        )
8727        .unwrap();
8728        let expected = Arc::new(FixedSizeListArray::from_iter_primitive::<Int32Type, _, _>(
8729            vec![Some(vec![Some(1), Some(2), Some(3)]), None],
8730            3,
8731        )) as ArrayRef;
8732        assert_eq!(expected.as_ref(), res.as_ref());
8733    }
8734
8735    #[test]
8736    fn test_cast_large_list_to_fsl() {
8737        let values = vec![Some(vec![Some(1), Some(2)]), Some(vec![Some(3), Some(4)])];
8738        let array = Arc::new(LargeListArray::from_iter_primitive::<Int32Type, _, _>(
8739            values.clone(),
8740        )) as ArrayRef;
8741        let expected = Arc::new(FixedSizeListArray::from_iter_primitive::<Int32Type, _, _>(
8742            values, 2,
8743        )) as ArrayRef;
8744        let actual = cast(
8745            array.as_ref(),
8746            &DataType::FixedSizeList(Arc::new(Field::new_list_field(DataType::Int32, true)), 2),
8747        )
8748        .unwrap();
8749        assert_eq!(expected.as_ref(), actual.as_ref());
8750    }
8751
8752    #[test]
8753    fn test_cast_list_to_fsl_subcast() {
8754        let array = Arc::new(LargeListArray::from_iter_primitive::<Int32Type, _, _>(
8755            vec![
8756                Some(vec![Some(1), Some(2)]),
8757                Some(vec![Some(3), Some(i32::MAX)]),
8758            ],
8759        )) as ArrayRef;
8760        let expected = Arc::new(FixedSizeListArray::from_iter_primitive::<Int64Type, _, _>(
8761            vec![
8762                Some(vec![Some(1), Some(2)]),
8763                Some(vec![Some(3), Some(i32::MAX as i64)]),
8764            ],
8765            2,
8766        )) as ArrayRef;
8767        let actual = cast(
8768            array.as_ref(),
8769            &DataType::FixedSizeList(Arc::new(Field::new_list_field(DataType::Int64, true)), 2),
8770        )
8771        .unwrap();
8772        assert_eq!(expected.as_ref(), actual.as_ref());
8773
8774        let res = cast_with_options(
8775            array.as_ref(),
8776            &DataType::FixedSizeList(Arc::new(Field::new_list_field(DataType::Int16, true)), 2),
8777            &CastOptions {
8778                safe: false,
8779                ..Default::default()
8780            },
8781        );
8782        assert!(res.is_err());
8783        assert!(format!("{res:?}").contains("Can't cast value 2147483647 to type Int16"));
8784    }
8785
8786    #[test]
8787    fn test_cast_list_to_fsl_empty() {
8788        let field = Arc::new(Field::new_list_field(DataType::Int32, true));
8789        let array = new_empty_array(&DataType::List(field.clone()));
8790
8791        let target_type = DataType::FixedSizeList(field.clone(), 3);
8792        let expected = new_empty_array(&target_type);
8793
8794        let actual = cast(array.as_ref(), &target_type).unwrap();
8795        assert_eq!(expected.as_ref(), actual.as_ref());
8796    }
8797
8798    fn make_list_array() -> ListArray {
8799        // Construct a value array
8800        let value_data = ArrayData::builder(DataType::Int32)
8801            .len(8)
8802            .add_buffer(Buffer::from_slice_ref([0, 1, 2, 3, 4, 5, 6, 7]))
8803            .build()
8804            .unwrap();
8805
8806        // Construct a buffer for value offsets, for the nested array:
8807        //  [[0, 1, 2], [3, 4, 5], [6, 7]]
8808        let value_offsets = Buffer::from_slice_ref([0, 3, 6, 8]);
8809
8810        // Construct a list array from the above two
8811        let list_data_type = DataType::List(Arc::new(Field::new_list_field(DataType::Int32, true)));
8812        let list_data = ArrayData::builder(list_data_type)
8813            .len(3)
8814            .add_buffer(value_offsets)
8815            .add_child_data(value_data)
8816            .build()
8817            .unwrap();
8818        ListArray::from(list_data)
8819    }
8820
8821    fn make_large_list_array() -> LargeListArray {
8822        // Construct a value array
8823        let value_data = ArrayData::builder(DataType::Int32)
8824            .len(8)
8825            .add_buffer(Buffer::from_slice_ref([0, 1, 2, 3, 4, 5, 6, 7]))
8826            .build()
8827            .unwrap();
8828
8829        // Construct a buffer for value offsets, for the nested array:
8830        //  [[0, 1, 2], [3, 4, 5], [6, 7]]
8831        let value_offsets = Buffer::from_slice_ref([0i64, 3, 6, 8]);
8832
8833        // Construct a list array from the above two
8834        let list_data_type =
8835            DataType::LargeList(Arc::new(Field::new_list_field(DataType::Int32, true)));
8836        let list_data = ArrayData::builder(list_data_type)
8837            .len(3)
8838            .add_buffer(value_offsets)
8839            .add_child_data(value_data)
8840            .build()
8841            .unwrap();
8842        LargeListArray::from(list_data)
8843    }
8844
8845    fn make_fixed_size_list_array() -> FixedSizeListArray {
8846        // Construct a value array
8847        let value_data = ArrayData::builder(DataType::Int32)
8848            .len(8)
8849            .add_buffer(Buffer::from_slice_ref([0, 1, 2, 3, 4, 5, 6, 7]))
8850            .build()
8851            .unwrap();
8852
8853        let list_data_type =
8854            DataType::FixedSizeList(Arc::new(Field::new_list_field(DataType::Int32, true)), 4);
8855        let list_data = ArrayData::builder(list_data_type)
8856            .len(2)
8857            .add_child_data(value_data)
8858            .build()
8859            .unwrap();
8860        FixedSizeListArray::from(list_data)
8861    }
8862
8863    fn make_fixed_size_list_array_for_large_list() -> FixedSizeListArray {
8864        // Construct a value array
8865        let value_data = ArrayData::builder(DataType::Int64)
8866            .len(8)
8867            .add_buffer(Buffer::from_slice_ref([0i64, 1, 2, 3, 4, 5, 6, 7]))
8868            .build()
8869            .unwrap();
8870
8871        let list_data_type =
8872            DataType::FixedSizeList(Arc::new(Field::new_list_field(DataType::Int64, true)), 4);
8873        let list_data = ArrayData::builder(list_data_type)
8874            .len(2)
8875            .add_child_data(value_data)
8876            .build()
8877            .unwrap();
8878        FixedSizeListArray::from(list_data)
8879    }
8880
8881    #[test]
8882    fn test_cast_map_dont_allow_change_of_order() {
8883        let string_builder = StringBuilder::new();
8884        let value_builder = StringBuilder::new();
8885        let mut builder = MapBuilder::new(
8886            Some(MapFieldNames {
8887                entry: "entries".to_string(),
8888                key: "key".to_string(),
8889                value: "value".to_string(),
8890            }),
8891            string_builder,
8892            value_builder,
8893        );
8894
8895        builder.keys().append_value("0");
8896        builder.values().append_value("test_val_1");
8897        builder.append(true).unwrap();
8898        builder.keys().append_value("1");
8899        builder.values().append_value("test_val_2");
8900        builder.append(true).unwrap();
8901
8902        // map builder returns unsorted map by default
8903        let array = builder.finish();
8904
8905        let new_ordered = true;
8906        let new_type = DataType::Map(
8907            Arc::new(Field::new(
8908                "entries",
8909                DataType::Struct(
8910                    vec![
8911                        Field::new("key", DataType::Utf8, false),
8912                        Field::new("value", DataType::Utf8, false),
8913                    ]
8914                    .into(),
8915                ),
8916                false,
8917            )),
8918            new_ordered,
8919        );
8920
8921        let new_array_result = cast(&array, &new_type.clone());
8922        assert!(!can_cast_types(array.data_type(), &new_type));
8923        let Err(ArrowError::CastError(t)) = new_array_result else {
8924            panic!();
8925        };
8926        assert_eq!(
8927            t,
8928            r#"Casting from Map("entries": non-null Struct("key": non-null Utf8, "value": Utf8), unsorted) to Map("entries": non-null Struct("key": non-null Utf8, "value": non-null Utf8), sorted) not supported"#
8929        );
8930    }
8931
8932    #[test]
8933    fn test_cast_map_dont_allow_when_container_cant_cast() {
8934        let string_builder = StringBuilder::new();
8935        let value_builder = IntervalDayTimeArray::builder(2);
8936        let mut builder = MapBuilder::new(
8937            Some(MapFieldNames {
8938                entry: "entries".to_string(),
8939                key: "key".to_string(),
8940                value: "value".to_string(),
8941            }),
8942            string_builder,
8943            value_builder,
8944        );
8945
8946        builder.keys().append_value("0");
8947        builder.values().append_value(IntervalDayTime::new(1, 1));
8948        builder.append(true).unwrap();
8949        builder.keys().append_value("1");
8950        builder.values().append_value(IntervalDayTime::new(2, 2));
8951        builder.append(true).unwrap();
8952
8953        // map builder returns unsorted map by default
8954        let array = builder.finish();
8955
8956        let new_ordered = true;
8957        let new_type = DataType::Map(
8958            Arc::new(Field::new(
8959                "entries",
8960                DataType::Struct(
8961                    vec![
8962                        Field::new("key", DataType::Utf8, false),
8963                        Field::new("value", DataType::Duration(TimeUnit::Second), false),
8964                    ]
8965                    .into(),
8966                ),
8967                false,
8968            )),
8969            new_ordered,
8970        );
8971
8972        let new_array_result = cast(&array, &new_type.clone());
8973        assert!(!can_cast_types(array.data_type(), &new_type));
8974        let Err(ArrowError::CastError(t)) = new_array_result else {
8975            panic!();
8976        };
8977        assert_eq!(
8978            t,
8979            r#"Casting from Map("entries": non-null Struct("key": non-null Utf8, "value": Interval(DayTime)), unsorted) to Map("entries": non-null Struct("key": non-null Utf8, "value": non-null Duration(s)), sorted) not supported"#
8980        );
8981    }
8982
8983    #[test]
8984    fn test_cast_map_field_names() {
8985        let string_builder = StringBuilder::new();
8986        let value_builder = StringBuilder::new();
8987        let mut builder = MapBuilder::new(
8988            Some(MapFieldNames {
8989                entry: "entries".to_string(),
8990                key: "key".to_string(),
8991                value: "value".to_string(),
8992            }),
8993            string_builder,
8994            value_builder,
8995        );
8996
8997        builder.keys().append_value("0");
8998        builder.values().append_value("test_val_1");
8999        builder.append(true).unwrap();
9000        builder.keys().append_value("1");
9001        builder.values().append_value("test_val_2");
9002        builder.append(true).unwrap();
9003        builder.append(false).unwrap();
9004
9005        let array = builder.finish();
9006
9007        let new_type = DataType::Map(
9008            Arc::new(Field::new(
9009                "entries_new",
9010                DataType::Struct(
9011                    vec![
9012                        Field::new("key_new", DataType::Utf8, false),
9013                        Field::new("value_values", DataType::Utf8, false),
9014                    ]
9015                    .into(),
9016                ),
9017                false,
9018            )),
9019            false,
9020        );
9021
9022        assert_ne!(new_type, array.data_type().clone());
9023
9024        let new_array = cast(&array, &new_type.clone()).unwrap();
9025        assert_eq!(new_type, new_array.data_type().clone());
9026        let map_array = new_array.as_map();
9027
9028        assert_ne!(new_type, array.data_type().clone());
9029        assert_eq!(new_type, map_array.data_type().clone());
9030
9031        let key_string = map_array
9032            .keys()
9033            .as_any()
9034            .downcast_ref::<StringArray>()
9035            .unwrap()
9036            .into_iter()
9037            .flatten()
9038            .collect::<Vec<_>>();
9039        assert_eq!(&key_string, &vec!["0", "1"]);
9040
9041        let values_string_array = cast(map_array.values(), &DataType::Utf8).unwrap();
9042        let values_string = values_string_array
9043            .as_any()
9044            .downcast_ref::<StringArray>()
9045            .unwrap()
9046            .into_iter()
9047            .flatten()
9048            .collect::<Vec<_>>();
9049        assert_eq!(&values_string, &vec!["test_val_1", "test_val_2"]);
9050
9051        assert_eq!(
9052            map_array.nulls(),
9053            Some(&NullBuffer::from(vec![true, true, false]))
9054        );
9055    }
9056
9057    #[test]
9058    fn test_cast_map_contained_values() {
9059        let string_builder = StringBuilder::new();
9060        let value_builder = Int8Builder::new();
9061        let mut builder = MapBuilder::new(
9062            Some(MapFieldNames {
9063                entry: "entries".to_string(),
9064                key: "key".to_string(),
9065                value: "value".to_string(),
9066            }),
9067            string_builder,
9068            value_builder,
9069        );
9070
9071        builder.keys().append_value("0");
9072        builder.values().append_value(44);
9073        builder.append(true).unwrap();
9074        builder.keys().append_value("1");
9075        builder.values().append_value(22);
9076        builder.append(true).unwrap();
9077
9078        let array = builder.finish();
9079
9080        let new_type = DataType::Map(
9081            Arc::new(Field::new(
9082                "entries",
9083                DataType::Struct(
9084                    vec![
9085                        Field::new("key", DataType::Utf8, false),
9086                        Field::new("value", DataType::Utf8, false),
9087                    ]
9088                    .into(),
9089                ),
9090                false,
9091            )),
9092            false,
9093        );
9094
9095        let new_array = cast(&array, &new_type.clone()).unwrap();
9096        assert_eq!(new_type, new_array.data_type().clone());
9097        let map_array = new_array.as_map();
9098
9099        assert_ne!(new_type, array.data_type().clone());
9100        assert_eq!(new_type, map_array.data_type().clone());
9101
9102        let key_string = map_array
9103            .keys()
9104            .as_any()
9105            .downcast_ref::<StringArray>()
9106            .unwrap()
9107            .into_iter()
9108            .flatten()
9109            .collect::<Vec<_>>();
9110        assert_eq!(&key_string, &vec!["0", "1"]);
9111
9112        let values_string_array = cast(map_array.values(), &DataType::Utf8).unwrap();
9113        let values_string = values_string_array
9114            .as_any()
9115            .downcast_ref::<StringArray>()
9116            .unwrap()
9117            .into_iter()
9118            .flatten()
9119            .collect::<Vec<_>>();
9120        assert_eq!(&values_string, &vec!["44", "22"]);
9121    }
9122
9123    #[test]
9124    fn test_utf8_cast_offsets() {
9125        // test if offset of the array is taken into account during cast
9126        let str_array = StringArray::from(vec!["a", "b", "c"]);
9127        let str_array = str_array.slice(1, 2);
9128
9129        let out = cast(&str_array, &DataType::LargeUtf8).unwrap();
9130
9131        let large_str_array = out.as_any().downcast_ref::<LargeStringArray>().unwrap();
9132        let strs = large_str_array.into_iter().flatten().collect::<Vec<_>>();
9133        assert_eq!(strs, &["b", "c"])
9134    }
9135
9136    #[test]
9137    fn test_list_cast_offsets() {
9138        // test if offset of the array is taken into account during cast
9139        let array1 = make_list_array().slice(1, 2);
9140        let array2 = Arc::new(make_list_array()) as ArrayRef;
9141
9142        let dt = DataType::LargeList(Arc::new(Field::new_list_field(DataType::Int32, true)));
9143        let out1 = cast(&array1, &dt).unwrap();
9144        let out2 = cast(&array2, &dt).unwrap();
9145
9146        assert_eq!(&out1, &out2.slice(1, 2))
9147    }
9148
9149    #[test]
9150    fn test_list_to_string() {
9151        let str_array = StringArray::from(vec!["a", "b", "c", "d", "e", "f", "g", "h"]);
9152        let value_offsets = Buffer::from_slice_ref([0, 3, 6, 8]);
9153        let value_data = str_array.into_data();
9154
9155        let list_data_type = DataType::List(Arc::new(Field::new_list_field(DataType::Utf8, true)));
9156        let list_data = ArrayData::builder(list_data_type)
9157            .len(3)
9158            .add_buffer(value_offsets)
9159            .add_child_data(value_data)
9160            .build()
9161            .unwrap();
9162        let array = Arc::new(ListArray::from(list_data)) as ArrayRef;
9163
9164        let out = cast(&array, &DataType::Utf8).unwrap();
9165        let out = out
9166            .as_any()
9167            .downcast_ref::<StringArray>()
9168            .unwrap()
9169            .into_iter()
9170            .flatten()
9171            .collect::<Vec<_>>();
9172        assert_eq!(&out, &vec!["[a, b, c]", "[d, e, f]", "[g, h]"]);
9173
9174        let out = cast(&array, &DataType::LargeUtf8).unwrap();
9175        let out = out
9176            .as_any()
9177            .downcast_ref::<LargeStringArray>()
9178            .unwrap()
9179            .into_iter()
9180            .flatten()
9181            .collect::<Vec<_>>();
9182        assert_eq!(&out, &vec!["[a, b, c]", "[d, e, f]", "[g, h]"]);
9183
9184        let array = Arc::new(make_list_array()) as ArrayRef;
9185        let out = cast(&array, &DataType::Utf8).unwrap();
9186        let out = out
9187            .as_any()
9188            .downcast_ref::<StringArray>()
9189            .unwrap()
9190            .into_iter()
9191            .flatten()
9192            .collect::<Vec<_>>();
9193        assert_eq!(&out, &vec!["[0, 1, 2]", "[3, 4, 5]", "[6, 7]"]);
9194
9195        let array = Arc::new(make_large_list_array()) as ArrayRef;
9196        let out = cast(&array, &DataType::LargeUtf8).unwrap();
9197        let out = out
9198            .as_any()
9199            .downcast_ref::<LargeStringArray>()
9200            .unwrap()
9201            .into_iter()
9202            .flatten()
9203            .collect::<Vec<_>>();
9204        assert_eq!(&out, &vec!["[0, 1, 2]", "[3, 4, 5]", "[6, 7]"]);
9205    }
9206
9207    #[test]
9208    fn test_cast_f64_to_decimal128() {
9209        // to reproduce https://github.com/apache/arrow-rs/issues/2997
9210
9211        let decimal_type = DataType::Decimal128(18, 2);
9212        let array = Float64Array::from(vec![
9213            Some(0.0699999999),
9214            Some(0.0659999999),
9215            Some(0.0650000000),
9216            Some(0.0649999999),
9217        ]);
9218        let array = Arc::new(array) as ArrayRef;
9219        generate_cast_test_case!(
9220            &array,
9221            Decimal128Array,
9222            &decimal_type,
9223            vec![
9224                Some(7_i128), // round up
9225                Some(7_i128), // round up
9226                Some(7_i128), // round up
9227                Some(6_i128), // round down
9228            ]
9229        );
9230
9231        let decimal_type = DataType::Decimal128(18, 3);
9232        let array = Float64Array::from(vec![
9233            Some(0.0699999999),
9234            Some(0.0659999999),
9235            Some(0.0650000000),
9236            Some(0.0649999999),
9237        ]);
9238        let array = Arc::new(array) as ArrayRef;
9239        generate_cast_test_case!(
9240            &array,
9241            Decimal128Array,
9242            &decimal_type,
9243            vec![
9244                Some(70_i128), // round up
9245                Some(66_i128), // round up
9246                Some(65_i128), // round down
9247                Some(65_i128), // round up
9248            ]
9249        );
9250    }
9251
9252    #[test]
9253    fn test_cast_numeric_to_decimal128_overflow() {
9254        let array = Int64Array::from(vec![i64::MAX]);
9255        let array = Arc::new(array) as ArrayRef;
9256        let casted_array = cast_with_options(
9257            &array,
9258            &DataType::Decimal128(38, 30),
9259            &CastOptions {
9260                safe: true,
9261                format_options: FormatOptions::default(),
9262            },
9263        );
9264        assert!(casted_array.is_ok());
9265        assert!(casted_array.unwrap().is_null(0));
9266
9267        let casted_array = cast_with_options(
9268            &array,
9269            &DataType::Decimal128(38, 30),
9270            &CastOptions {
9271                safe: false,
9272                format_options: FormatOptions::default(),
9273            },
9274        );
9275        assert!(casted_array.is_err());
9276    }
9277
9278    #[test]
9279    fn test_cast_numeric_to_decimal256_overflow() {
9280        let array = Int64Array::from(vec![i64::MAX]);
9281        let array = Arc::new(array) as ArrayRef;
9282        let casted_array = cast_with_options(
9283            &array,
9284            &DataType::Decimal256(76, 76),
9285            &CastOptions {
9286                safe: true,
9287                format_options: FormatOptions::default(),
9288            },
9289        );
9290        assert!(casted_array.is_ok());
9291        assert!(casted_array.unwrap().is_null(0));
9292
9293        let casted_array = cast_with_options(
9294            &array,
9295            &DataType::Decimal256(76, 76),
9296            &CastOptions {
9297                safe: false,
9298                format_options: FormatOptions::default(),
9299            },
9300        );
9301        assert!(casted_array.is_err());
9302    }
9303
9304    #[test]
9305    fn test_cast_floating_point_to_decimal128_precision_overflow() {
9306        let array = Float64Array::from(vec![1.1]);
9307        let array = Arc::new(array) as ArrayRef;
9308        let casted_array = cast_with_options(
9309            &array,
9310            &DataType::Decimal128(2, 2),
9311            &CastOptions {
9312                safe: true,
9313                format_options: FormatOptions::default(),
9314            },
9315        );
9316        assert!(casted_array.is_ok());
9317        assert!(casted_array.unwrap().is_null(0));
9318
9319        let casted_array = cast_with_options(
9320            &array,
9321            &DataType::Decimal128(2, 2),
9322            &CastOptions {
9323                safe: false,
9324                format_options: FormatOptions::default(),
9325            },
9326        );
9327        let err = casted_array.unwrap_err().to_string();
9328        let expected_error = "Invalid argument error: 1.10 is too large to store in a Decimal128 of precision 2. Max is 0.99";
9329        assert!(
9330            err.contains(expected_error),
9331            "did not find expected error '{expected_error}' in actual error '{err}'"
9332        );
9333    }
9334
9335    #[test]
9336    fn test_cast_floating_point_to_decimal256_precision_overflow() {
9337        let array = Float64Array::from(vec![1.1]);
9338        let array = Arc::new(array) as ArrayRef;
9339        let casted_array = cast_with_options(
9340            &array,
9341            &DataType::Decimal256(2, 2),
9342            &CastOptions {
9343                safe: true,
9344                format_options: FormatOptions::default(),
9345            },
9346        );
9347        assert!(casted_array.is_ok());
9348        assert!(casted_array.unwrap().is_null(0));
9349
9350        let casted_array = cast_with_options(
9351            &array,
9352            &DataType::Decimal256(2, 2),
9353            &CastOptions {
9354                safe: false,
9355                format_options: FormatOptions::default(),
9356            },
9357        );
9358        let err = casted_array.unwrap_err().to_string();
9359        let expected_error = "Invalid argument error: 1.10 is too large to store in a Decimal256 of precision 2. Max is 0.99";
9360        assert_eq!(err, expected_error);
9361    }
9362
9363    #[test]
9364    fn test_cast_floating_point_to_decimal128_overflow() {
9365        let array = Float64Array::from(vec![f64::MAX]);
9366        let array = Arc::new(array) as ArrayRef;
9367        let casted_array = cast_with_options(
9368            &array,
9369            &DataType::Decimal128(38, 30),
9370            &CastOptions {
9371                safe: true,
9372                format_options: FormatOptions::default(),
9373            },
9374        );
9375        assert!(casted_array.is_ok());
9376        assert!(casted_array.unwrap().is_null(0));
9377
9378        let casted_array = cast_with_options(
9379            &array,
9380            &DataType::Decimal128(38, 30),
9381            &CastOptions {
9382                safe: false,
9383                format_options: FormatOptions::default(),
9384            },
9385        );
9386        let err = casted_array.unwrap_err().to_string();
9387        let expected_error = "Cast error: Cannot cast to Decimal128(38, 30)";
9388        assert!(
9389            err.contains(expected_error),
9390            "did not find expected error '{expected_error}' in actual error '{err}'"
9391        );
9392    }
9393
9394    #[test]
9395    fn test_cast_floating_point_to_decimal256_overflow() {
9396        let array = Float64Array::from(vec![f64::MAX]);
9397        let array = Arc::new(array) as ArrayRef;
9398        let casted_array = cast_with_options(
9399            &array,
9400            &DataType::Decimal256(76, 50),
9401            &CastOptions {
9402                safe: true,
9403                format_options: FormatOptions::default(),
9404            },
9405        );
9406        assert!(casted_array.is_ok());
9407        assert!(casted_array.unwrap().is_null(0));
9408
9409        let casted_array = cast_with_options(
9410            &array,
9411            &DataType::Decimal256(76, 50),
9412            &CastOptions {
9413                safe: false,
9414                format_options: FormatOptions::default(),
9415            },
9416        );
9417        let err = casted_array.unwrap_err().to_string();
9418        let expected_error = "Cast error: Cannot cast to Decimal256(76, 50)";
9419        assert!(
9420            err.contains(expected_error),
9421            "did not find expected error '{expected_error}' in actual error '{err}'"
9422        );
9423    }
9424    #[test]
9425    fn test_cast_decimal256_to_f64_no_overflow() {
9426        // Test casting i256::MAX: should produce a large finite positive value
9427        let array = vec![Some(i256::MAX)];
9428        let array = create_decimal256_array(array, 76, 2).unwrap();
9429        let array = Arc::new(array) as ArrayRef;
9430
9431        let result = cast(&array, &DataType::Float64).unwrap();
9432        let result = result.as_primitive::<Float64Type>();
9433        assert!(result.value(0).is_finite());
9434        assert!(result.value(0) > 0.0); // Positive result
9435
9436        // Test casting i256::MIN: should produce a large finite negative value
9437        let array = vec![Some(i256::MIN)];
9438        let array = create_decimal256_array(array, 76, 2).unwrap();
9439        let array = Arc::new(array) as ArrayRef;
9440
9441        let result = cast(&array, &DataType::Float64).unwrap();
9442        let result = result.as_primitive::<Float64Type>();
9443        assert!(result.value(0).is_finite());
9444        assert!(result.value(0) < 0.0); // Negative result
9445    }
9446
9447    #[test]
9448    fn test_cast_decimal128_to_decimal128_negative_scale() {
9449        let input_type = DataType::Decimal128(20, 0);
9450        let output_type = DataType::Decimal128(20, -1);
9451        assert!(can_cast_types(&input_type, &output_type));
9452        let array = vec![Some(1123450), Some(2123455), Some(3123456), None];
9453        let input_decimal_array = create_decimal128_array(array, 20, 0).unwrap();
9454        let array = Arc::new(input_decimal_array) as ArrayRef;
9455        generate_cast_test_case!(
9456            &array,
9457            Decimal128Array,
9458            &output_type,
9459            vec![
9460                Some(112345_i128),
9461                Some(212346_i128),
9462                Some(312346_i128),
9463                None
9464            ]
9465        );
9466
9467        let casted_array = cast(&array, &output_type).unwrap();
9468        let decimal_arr = casted_array.as_primitive::<Decimal128Type>();
9469
9470        assert_eq!("1123450", decimal_arr.value_as_string(0));
9471        assert_eq!("2123460", decimal_arr.value_as_string(1));
9472        assert_eq!("3123460", decimal_arr.value_as_string(2));
9473    }
9474
9475    #[test]
9476    fn decimal128_min_max_to_f64() {
9477        // Ensure Decimal128 i128::MIN/MAX round-trip cast
9478        let min128 = i128::MIN;
9479        let max128 = i128::MAX;
9480        assert_eq!(min128 as f64, min128 as f64);
9481        assert_eq!(max128 as f64, max128 as f64);
9482    }
9483
9484    #[test]
9485    fn test_cast_numeric_to_decimal128_negative() {
9486        let decimal_type = DataType::Decimal128(38, -1);
9487        let array = Arc::new(Int32Array::from(vec![
9488            Some(1123456),
9489            Some(2123456),
9490            Some(3123456),
9491        ])) as ArrayRef;
9492
9493        let casted_array = cast(&array, &decimal_type).unwrap();
9494        let decimal_arr = casted_array.as_primitive::<Decimal128Type>();
9495
9496        assert_eq!("1123450", decimal_arr.value_as_string(0));
9497        assert_eq!("2123450", decimal_arr.value_as_string(1));
9498        assert_eq!("3123450", decimal_arr.value_as_string(2));
9499
9500        let array = Arc::new(Float32Array::from(vec![
9501            Some(1123.456),
9502            Some(2123.456),
9503            Some(3123.456),
9504        ])) as ArrayRef;
9505
9506        let casted_array = cast(&array, &decimal_type).unwrap();
9507        let decimal_arr = casted_array.as_primitive::<Decimal128Type>();
9508
9509        assert_eq!("1120", decimal_arr.value_as_string(0));
9510        assert_eq!("2120", decimal_arr.value_as_string(1));
9511        assert_eq!("3120", decimal_arr.value_as_string(2));
9512    }
9513
9514    #[test]
9515    fn test_cast_decimal128_to_decimal128_negative() {
9516        let input_type = DataType::Decimal128(10, -1);
9517        let output_type = DataType::Decimal128(10, -2);
9518        assert!(can_cast_types(&input_type, &output_type));
9519        let array = vec![Some(123)];
9520        let input_decimal_array = create_decimal128_array(array, 10, -1).unwrap();
9521        let array = Arc::new(input_decimal_array) as ArrayRef;
9522        generate_cast_test_case!(&array, Decimal128Array, &output_type, vec![Some(12_i128),]);
9523
9524        let casted_array = cast(&array, &output_type).unwrap();
9525        let decimal_arr = casted_array.as_primitive::<Decimal128Type>();
9526
9527        assert_eq!("1200", decimal_arr.value_as_string(0));
9528
9529        let array = vec![Some(125)];
9530        let input_decimal_array = create_decimal128_array(array, 10, -1).unwrap();
9531        let array = Arc::new(input_decimal_array) as ArrayRef;
9532        generate_cast_test_case!(&array, Decimal128Array, &output_type, vec![Some(13_i128),]);
9533
9534        let casted_array = cast(&array, &output_type).unwrap();
9535        let decimal_arr = casted_array.as_primitive::<Decimal128Type>();
9536
9537        assert_eq!("1300", decimal_arr.value_as_string(0));
9538    }
9539
9540    #[test]
9541    fn test_cast_decimal128_to_decimal256_negative() {
9542        let input_type = DataType::Decimal128(10, 3);
9543        let output_type = DataType::Decimal256(10, 5);
9544        assert!(can_cast_types(&input_type, &output_type));
9545        let array = vec![Some(123456), Some(-123456)];
9546        let input_decimal_array = create_decimal128_array(array, 10, 3).unwrap();
9547        let array = Arc::new(input_decimal_array) as ArrayRef;
9548
9549        let hundred = i256::from_i128(100);
9550        generate_cast_test_case!(
9551            &array,
9552            Decimal256Array,
9553            &output_type,
9554            vec![
9555                Some(i256::from_i128(123456).mul_wrapping(hundred)),
9556                Some(i256::from_i128(-123456).mul_wrapping(hundred))
9557            ]
9558        );
9559    }
9560
9561    #[test]
9562    fn test_parse_string_to_decimal() {
9563        assert_eq!(
9564            Decimal128Type::format_decimal(
9565                parse_string_to_decimal_native::<Decimal128Type>("123.45", 2).unwrap(),
9566                38,
9567                2,
9568            ),
9569            "123.45"
9570        );
9571        assert_eq!(
9572            Decimal128Type::format_decimal(
9573                parse_string_to_decimal_native::<Decimal128Type>("12345", 2).unwrap(),
9574                38,
9575                2,
9576            ),
9577            "12345.00"
9578        );
9579        assert_eq!(
9580            Decimal128Type::format_decimal(
9581                parse_string_to_decimal_native::<Decimal128Type>("0.12345", 2).unwrap(),
9582                38,
9583                2,
9584            ),
9585            "0.12"
9586        );
9587        assert_eq!(
9588            Decimal128Type::format_decimal(
9589                parse_string_to_decimal_native::<Decimal128Type>(".12345", 2).unwrap(),
9590                38,
9591                2,
9592            ),
9593            "0.12"
9594        );
9595        assert_eq!(
9596            Decimal128Type::format_decimal(
9597                parse_string_to_decimal_native::<Decimal128Type>(".1265", 2).unwrap(),
9598                38,
9599                2,
9600            ),
9601            "0.13"
9602        );
9603        assert_eq!(
9604            Decimal128Type::format_decimal(
9605                parse_string_to_decimal_native::<Decimal128Type>(".1265", 2).unwrap(),
9606                38,
9607                2,
9608            ),
9609            "0.13"
9610        );
9611
9612        assert_eq!(
9613            Decimal256Type::format_decimal(
9614                parse_string_to_decimal_native::<Decimal256Type>("123.45", 3).unwrap(),
9615                38,
9616                3,
9617            ),
9618            "123.450"
9619        );
9620        assert_eq!(
9621            Decimal256Type::format_decimal(
9622                parse_string_to_decimal_native::<Decimal256Type>("12345", 3).unwrap(),
9623                38,
9624                3,
9625            ),
9626            "12345.000"
9627        );
9628        assert_eq!(
9629            Decimal256Type::format_decimal(
9630                parse_string_to_decimal_native::<Decimal256Type>("0.12345", 3).unwrap(),
9631                38,
9632                3,
9633            ),
9634            "0.123"
9635        );
9636        assert_eq!(
9637            Decimal256Type::format_decimal(
9638                parse_string_to_decimal_native::<Decimal256Type>(".12345", 3).unwrap(),
9639                38,
9640                3,
9641            ),
9642            "0.123"
9643        );
9644        assert_eq!(
9645            Decimal256Type::format_decimal(
9646                parse_string_to_decimal_native::<Decimal256Type>(".1265", 3).unwrap(),
9647                38,
9648                3,
9649            ),
9650            "0.127"
9651        );
9652    }
9653
9654    fn test_cast_string_to_decimal(array: ArrayRef) {
9655        // Decimal128
9656        let output_type = DataType::Decimal128(38, 2);
9657        assert!(can_cast_types(array.data_type(), &output_type));
9658
9659        let casted_array = cast(&array, &output_type).unwrap();
9660        let decimal_arr = casted_array.as_primitive::<Decimal128Type>();
9661
9662        assert_eq!("123.45", decimal_arr.value_as_string(0));
9663        assert_eq!("1.23", decimal_arr.value_as_string(1));
9664        assert_eq!("0.12", decimal_arr.value_as_string(2));
9665        assert_eq!("0.13", decimal_arr.value_as_string(3));
9666        assert_eq!("1.26", decimal_arr.value_as_string(4));
9667        assert_eq!("12345.00", decimal_arr.value_as_string(5));
9668        assert_eq!("12345.00", decimal_arr.value_as_string(6));
9669        assert_eq!("0.12", decimal_arr.value_as_string(7));
9670        assert_eq!("12.23", decimal_arr.value_as_string(8));
9671        assert!(decimal_arr.is_null(9));
9672        assert_eq!("0.00", decimal_arr.value_as_string(10));
9673        assert_eq!("0.00", decimal_arr.value_as_string(11));
9674        assert!(decimal_arr.is_null(12));
9675        assert_eq!("-1.23", decimal_arr.value_as_string(13));
9676        assert_eq!("-1.24", decimal_arr.value_as_string(14));
9677        assert_eq!("0.00", decimal_arr.value_as_string(15));
9678        assert_eq!("-123.00", decimal_arr.value_as_string(16));
9679        assert_eq!("-123.23", decimal_arr.value_as_string(17));
9680        assert_eq!("-0.12", decimal_arr.value_as_string(18));
9681        assert_eq!("1.23", decimal_arr.value_as_string(19));
9682        assert_eq!("1.24", decimal_arr.value_as_string(20));
9683        assert_eq!("0.00", decimal_arr.value_as_string(21));
9684        assert_eq!("123.00", decimal_arr.value_as_string(22));
9685        assert_eq!("123.23", decimal_arr.value_as_string(23));
9686        assert_eq!("0.12", decimal_arr.value_as_string(24));
9687        assert!(decimal_arr.is_null(25));
9688        assert!(decimal_arr.is_null(26));
9689        assert!(decimal_arr.is_null(27));
9690        assert_eq!("0.00", decimal_arr.value_as_string(28));
9691        assert_eq!("0.00", decimal_arr.value_as_string(29));
9692        assert_eq!("12345.00", decimal_arr.value_as_string(30));
9693        assert_eq!(decimal_arr.len(), 31);
9694
9695        // Decimal256
9696        let output_type = DataType::Decimal256(76, 3);
9697        assert!(can_cast_types(array.data_type(), &output_type));
9698
9699        let casted_array = cast(&array, &output_type).unwrap();
9700        let decimal_arr = casted_array.as_primitive::<Decimal256Type>();
9701
9702        assert_eq!("123.450", decimal_arr.value_as_string(0));
9703        assert_eq!("1.235", decimal_arr.value_as_string(1));
9704        assert_eq!("0.123", decimal_arr.value_as_string(2));
9705        assert_eq!("0.127", decimal_arr.value_as_string(3));
9706        assert_eq!("1.263", decimal_arr.value_as_string(4));
9707        assert_eq!("12345.000", decimal_arr.value_as_string(5));
9708        assert_eq!("12345.000", decimal_arr.value_as_string(6));
9709        assert_eq!("0.123", decimal_arr.value_as_string(7));
9710        assert_eq!("12.234", decimal_arr.value_as_string(8));
9711        assert!(decimal_arr.is_null(9));
9712        assert_eq!("0.000", decimal_arr.value_as_string(10));
9713        assert_eq!("0.000", decimal_arr.value_as_string(11));
9714        assert!(decimal_arr.is_null(12));
9715        assert_eq!("-1.235", decimal_arr.value_as_string(13));
9716        assert_eq!("-1.236", decimal_arr.value_as_string(14));
9717        assert_eq!("0.000", decimal_arr.value_as_string(15));
9718        assert_eq!("-123.000", decimal_arr.value_as_string(16));
9719        assert_eq!("-123.234", decimal_arr.value_as_string(17));
9720        assert_eq!("-0.123", decimal_arr.value_as_string(18));
9721        assert_eq!("1.235", decimal_arr.value_as_string(19));
9722        assert_eq!("1.236", decimal_arr.value_as_string(20));
9723        assert_eq!("0.000", decimal_arr.value_as_string(21));
9724        assert_eq!("123.000", decimal_arr.value_as_string(22));
9725        assert_eq!("123.234", decimal_arr.value_as_string(23));
9726        assert_eq!("0.123", decimal_arr.value_as_string(24));
9727        assert!(decimal_arr.is_null(25));
9728        assert!(decimal_arr.is_null(26));
9729        assert!(decimal_arr.is_null(27));
9730        assert_eq!("0.000", decimal_arr.value_as_string(28));
9731        assert_eq!("0.000", decimal_arr.value_as_string(29));
9732        assert_eq!("12345.000", decimal_arr.value_as_string(30));
9733        assert_eq!(decimal_arr.len(), 31);
9734    }
9735
9736    #[test]
9737    fn test_cast_utf8_to_decimal() {
9738        let str_array = StringArray::from(vec![
9739            Some("123.45"),
9740            Some("1.2345"),
9741            Some("0.12345"),
9742            Some("0.1267"),
9743            Some("1.263"),
9744            Some("12345.0"),
9745            Some("12345"),
9746            Some("000.123"),
9747            Some("12.234000"),
9748            None,
9749            Some(""),
9750            Some(" "),
9751            None,
9752            Some("-1.23499999"),
9753            Some("-1.23599999"),
9754            Some("-0.00001"),
9755            Some("-123"),
9756            Some("-123.234000"),
9757            Some("-000.123"),
9758            Some("+1.23499999"),
9759            Some("+1.23599999"),
9760            Some("+0.00001"),
9761            Some("+123"),
9762            Some("+123.234000"),
9763            Some("+000.123"),
9764            Some("1.-23499999"),
9765            Some("-1.-23499999"),
9766            Some("--1.23499999"),
9767            Some("0"),
9768            Some("000.000"),
9769            Some("0000000000000000012345.000"),
9770        ]);
9771        let array = Arc::new(str_array) as ArrayRef;
9772
9773        test_cast_string_to_decimal(array);
9774
9775        let test_cases = [
9776            (None, None),
9777            // (Some(""), None),
9778            // (Some("   "), None),
9779            (Some("0"), Some("0")),
9780            (Some("000.000"), Some("0")),
9781            (Some("12345"), Some("12345")),
9782            (Some("000000000000000000000000000012345"), Some("12345")),
9783            (Some("-123"), Some("-123")),
9784            (Some("+123"), Some("123")),
9785        ];
9786        let inputs = test_cases.iter().map(|entry| entry.0).collect::<Vec<_>>();
9787        let expected = test_cases.iter().map(|entry| entry.1).collect::<Vec<_>>();
9788
9789        let array = Arc::new(StringArray::from(inputs)) as ArrayRef;
9790        test_cast_string_to_decimal_scale_zero(array, &expected);
9791    }
9792
9793    #[test]
9794    fn test_cast_large_utf8_to_decimal() {
9795        let str_array = LargeStringArray::from(vec![
9796            Some("123.45"),
9797            Some("1.2345"),
9798            Some("0.12345"),
9799            Some("0.1267"),
9800            Some("1.263"),
9801            Some("12345.0"),
9802            Some("12345"),
9803            Some("000.123"),
9804            Some("12.234000"),
9805            None,
9806            Some(""),
9807            Some(" "),
9808            None,
9809            Some("-1.23499999"),
9810            Some("-1.23599999"),
9811            Some("-0.00001"),
9812            Some("-123"),
9813            Some("-123.234000"),
9814            Some("-000.123"),
9815            Some("+1.23499999"),
9816            Some("+1.23599999"),
9817            Some("+0.00001"),
9818            Some("+123"),
9819            Some("+123.234000"),
9820            Some("+000.123"),
9821            Some("1.-23499999"),
9822            Some("-1.-23499999"),
9823            Some("--1.23499999"),
9824            Some("0"),
9825            Some("000.000"),
9826            Some("0000000000000000012345.000"),
9827        ]);
9828        let array = Arc::new(str_array) as ArrayRef;
9829
9830        test_cast_string_to_decimal(array);
9831
9832        let test_cases = [
9833            (None, None),
9834            (Some(""), None),
9835            (Some("   "), None),
9836            (Some("0"), Some("0")),
9837            (Some("000.000"), Some("0")),
9838            (Some("12345"), Some("12345")),
9839            (Some("000000000000000000000000000012345"), Some("12345")),
9840            (Some("-123"), Some("-123")),
9841            (Some("+123"), Some("123")),
9842        ];
9843        let inputs = test_cases.iter().map(|entry| entry.0).collect::<Vec<_>>();
9844        let expected = test_cases.iter().map(|entry| entry.1).collect::<Vec<_>>();
9845
9846        let array = Arc::new(LargeStringArray::from(inputs)) as ArrayRef;
9847        test_cast_string_to_decimal_scale_zero(array, &expected);
9848    }
9849
9850    fn test_cast_string_to_decimal_scale_zero(
9851        array: ArrayRef,
9852        expected_as_string: &[Option<&str>],
9853    ) {
9854        // Decimal128
9855        let output_type = DataType::Decimal128(38, 0);
9856        assert!(can_cast_types(array.data_type(), &output_type));
9857        let casted_array = cast(&array, &output_type).unwrap();
9858        let decimal_arr = casted_array.as_primitive::<Decimal128Type>();
9859        assert_decimal_array_contents(decimal_arr, expected_as_string);
9860
9861        // Decimal256
9862        let output_type = DataType::Decimal256(76, 0);
9863        assert!(can_cast_types(array.data_type(), &output_type));
9864        let casted_array = cast(&array, &output_type).unwrap();
9865        let decimal_arr = casted_array.as_primitive::<Decimal256Type>();
9866        assert_decimal_array_contents(decimal_arr, expected_as_string);
9867    }
9868
9869    fn assert_decimal_array_contents<T>(
9870        array: &PrimitiveArray<T>,
9871        expected_as_string: &[Option<&str>],
9872    ) where
9873        T: DecimalType + ArrowPrimitiveType,
9874    {
9875        assert_eq!(array.len(), expected_as_string.len());
9876        for (i, expected) in expected_as_string.iter().enumerate() {
9877            let actual = if array.is_null(i) {
9878                None
9879            } else {
9880                Some(array.value_as_string(i))
9881            };
9882            let actual = actual.as_ref().map(|s| s.as_ref());
9883            assert_eq!(*expected, actual, "Expected at position {i}");
9884        }
9885    }
9886
9887    #[test]
9888    fn test_cast_invalid_utf8_to_decimal() {
9889        let str_array = StringArray::from(vec!["4.4.5", ". 0.123"]);
9890        let array = Arc::new(str_array) as ArrayRef;
9891
9892        // Safe cast
9893        let output_type = DataType::Decimal128(38, 2);
9894        let casted_array = cast(&array, &output_type).unwrap();
9895        assert!(casted_array.is_null(0));
9896        assert!(casted_array.is_null(1));
9897
9898        let output_type = DataType::Decimal256(76, 2);
9899        let casted_array = cast(&array, &output_type).unwrap();
9900        assert!(casted_array.is_null(0));
9901        assert!(casted_array.is_null(1));
9902
9903        // Non-safe cast
9904        let output_type = DataType::Decimal128(38, 2);
9905        let str_array = StringArray::from(vec!["4.4.5"]);
9906        let array = Arc::new(str_array) as ArrayRef;
9907        let option = CastOptions {
9908            safe: false,
9909            format_options: FormatOptions::default(),
9910        };
9911        let casted_err = cast_with_options(&array, &output_type, &option).unwrap_err();
9912        assert!(
9913            casted_err
9914                .to_string()
9915                .contains("Cannot cast string '4.4.5' to value of Decimal128(38, 10) type")
9916        );
9917
9918        let str_array = StringArray::from(vec![". 0.123"]);
9919        let array = Arc::new(str_array) as ArrayRef;
9920        let casted_err = cast_with_options(&array, &output_type, &option).unwrap_err();
9921        assert!(
9922            casted_err
9923                .to_string()
9924                .contains("Cannot cast string '. 0.123' to value of Decimal128(38, 10) type")
9925        );
9926    }
9927
9928    fn test_cast_string_to_decimal128_overflow(overflow_array: ArrayRef) {
9929        let output_type = DataType::Decimal128(38, 2);
9930        let casted_array = cast(&overflow_array, &output_type).unwrap();
9931        let decimal_arr = casted_array.as_primitive::<Decimal128Type>();
9932
9933        assert!(decimal_arr.is_null(0));
9934        assert!(decimal_arr.is_null(1));
9935        assert!(decimal_arr.is_null(2));
9936        assert_eq!(
9937            "999999999999999999999999999999999999.99",
9938            decimal_arr.value_as_string(3)
9939        );
9940        assert_eq!(
9941            "100000000000000000000000000000000000.00",
9942            decimal_arr.value_as_string(4)
9943        );
9944    }
9945
9946    #[test]
9947    fn test_cast_string_to_decimal128_precision_overflow() {
9948        let array = StringArray::from(vec!["1000".to_string()]);
9949        let array = Arc::new(array) as ArrayRef;
9950        let casted_array = cast_with_options(
9951            &array,
9952            &DataType::Decimal128(10, 8),
9953            &CastOptions {
9954                safe: true,
9955                format_options: FormatOptions::default(),
9956            },
9957        );
9958        assert!(casted_array.is_ok());
9959        assert!(casted_array.unwrap().is_null(0));
9960
9961        let err = cast_with_options(
9962            &array,
9963            &DataType::Decimal128(10, 8),
9964            &CastOptions {
9965                safe: false,
9966                format_options: FormatOptions::default(),
9967            },
9968        );
9969        assert_eq!(
9970            "Invalid argument error: 1000.00000000 is too large to store in a Decimal128 of precision 10. Max is 99.99999999",
9971            err.unwrap_err().to_string()
9972        );
9973    }
9974
9975    #[test]
9976    fn test_cast_utf8_to_decimal128_overflow() {
9977        let overflow_str_array = StringArray::from(vec![
9978            i128::MAX.to_string(),
9979            i128::MIN.to_string(),
9980            "99999999999999999999999999999999999999".to_string(),
9981            "999999999999999999999999999999999999.99".to_string(),
9982            "99999999999999999999999999999999999.999".to_string(),
9983        ]);
9984        let overflow_array = Arc::new(overflow_str_array) as ArrayRef;
9985
9986        test_cast_string_to_decimal128_overflow(overflow_array);
9987    }
9988
9989    #[test]
9990    fn test_cast_large_utf8_to_decimal128_overflow() {
9991        let overflow_str_array = LargeStringArray::from(vec![
9992            i128::MAX.to_string(),
9993            i128::MIN.to_string(),
9994            "99999999999999999999999999999999999999".to_string(),
9995            "999999999999999999999999999999999999.99".to_string(),
9996            "99999999999999999999999999999999999.999".to_string(),
9997        ]);
9998        let overflow_array = Arc::new(overflow_str_array) as ArrayRef;
9999
10000        test_cast_string_to_decimal128_overflow(overflow_array);
10001    }
10002
10003    fn test_cast_string_to_decimal256_overflow(overflow_array: ArrayRef) {
10004        let output_type = DataType::Decimal256(76, 2);
10005        let casted_array = cast(&overflow_array, &output_type).unwrap();
10006        let decimal_arr = casted_array.as_primitive::<Decimal256Type>();
10007
10008        assert_eq!(
10009            "170141183460469231731687303715884105727.00",
10010            decimal_arr.value_as_string(0)
10011        );
10012        assert_eq!(
10013            "-170141183460469231731687303715884105728.00",
10014            decimal_arr.value_as_string(1)
10015        );
10016        assert_eq!(
10017            "99999999999999999999999999999999999999.00",
10018            decimal_arr.value_as_string(2)
10019        );
10020        assert_eq!(
10021            "999999999999999999999999999999999999.99",
10022            decimal_arr.value_as_string(3)
10023        );
10024        assert_eq!(
10025            "100000000000000000000000000000000000.00",
10026            decimal_arr.value_as_string(4)
10027        );
10028        assert!(decimal_arr.is_null(5));
10029        assert!(decimal_arr.is_null(6));
10030    }
10031
10032    #[test]
10033    fn test_cast_string_to_decimal256_precision_overflow() {
10034        let array = StringArray::from(vec!["1000".to_string()]);
10035        let array = Arc::new(array) as ArrayRef;
10036        let casted_array = cast_with_options(
10037            &array,
10038            &DataType::Decimal256(10, 8),
10039            &CastOptions {
10040                safe: true,
10041                format_options: FormatOptions::default(),
10042            },
10043        );
10044        assert!(casted_array.is_ok());
10045        assert!(casted_array.unwrap().is_null(0));
10046
10047        let err = cast_with_options(
10048            &array,
10049            &DataType::Decimal256(10, 8),
10050            &CastOptions {
10051                safe: false,
10052                format_options: FormatOptions::default(),
10053            },
10054        );
10055        assert_eq!(
10056            "Invalid argument error: 1000.00000000 is too large to store in a Decimal256 of precision 10. Max is 99.99999999",
10057            err.unwrap_err().to_string()
10058        );
10059    }
10060
10061    #[test]
10062    fn test_cast_utf8_to_decimal256_overflow() {
10063        let overflow_str_array = StringArray::from(vec![
10064            i128::MAX.to_string(),
10065            i128::MIN.to_string(),
10066            "99999999999999999999999999999999999999".to_string(),
10067            "999999999999999999999999999999999999.99".to_string(),
10068            "99999999999999999999999999999999999.999".to_string(),
10069            i256::MAX.to_string(),
10070            i256::MIN.to_string(),
10071        ]);
10072        let overflow_array = Arc::new(overflow_str_array) as ArrayRef;
10073
10074        test_cast_string_to_decimal256_overflow(overflow_array);
10075    }
10076
10077    #[test]
10078    fn test_cast_large_utf8_to_decimal256_overflow() {
10079        let overflow_str_array = LargeStringArray::from(vec![
10080            i128::MAX.to_string(),
10081            i128::MIN.to_string(),
10082            "99999999999999999999999999999999999999".to_string(),
10083            "999999999999999999999999999999999999.99".to_string(),
10084            "99999999999999999999999999999999999.999".to_string(),
10085            i256::MAX.to_string(),
10086            i256::MIN.to_string(),
10087        ]);
10088        let overflow_array = Arc::new(overflow_str_array) as ArrayRef;
10089
10090        test_cast_string_to_decimal256_overflow(overflow_array);
10091    }
10092
10093    #[test]
10094    fn test_cast_outside_supported_range_for_nanoseconds() {
10095        const EXPECTED_ERROR_MESSAGE: &str = "The dates that can be represented as nanoseconds have to be between 1677-09-21T00:12:44.0 and 2262-04-11T23:47:16.854775804";
10096
10097        let array = StringArray::from(vec![Some("1650-01-01 01:01:01.000001")]);
10098
10099        let cast_options = CastOptions {
10100            safe: false,
10101            format_options: FormatOptions::default(),
10102        };
10103
10104        let result = cast_string_to_timestamp::<i32, TimestampNanosecondType>(
10105            &array,
10106            &None::<Arc<str>>,
10107            &cast_options,
10108        );
10109
10110        let err = result.unwrap_err();
10111        assert_eq!(
10112            err.to_string(),
10113            format!(
10114                "Cast error: Overflow converting {} to Nanosecond. {}",
10115                array.value(0),
10116                EXPECTED_ERROR_MESSAGE
10117            )
10118        );
10119    }
10120
10121    #[test]
10122    fn test_cast_date32_to_timestamp() {
10123        let a = Date32Array::from(vec![Some(18628), Some(18993), None]); // 2021-1-1, 2022-1-1
10124        let array = Arc::new(a) as ArrayRef;
10125        let b = cast(&array, &DataType::Timestamp(TimeUnit::Second, None)).unwrap();
10126        let c = b.as_primitive::<TimestampSecondType>();
10127        assert_eq!(1609459200, c.value(0));
10128        assert_eq!(1640995200, c.value(1));
10129        assert!(c.is_null(2));
10130    }
10131
10132    #[test]
10133    fn test_cast_date32_to_timestamp_ms() {
10134        let a = Date32Array::from(vec![Some(18628), Some(18993), None]); // 2021-1-1, 2022-1-1
10135        let array = Arc::new(a) as ArrayRef;
10136        let b = cast(&array, &DataType::Timestamp(TimeUnit::Millisecond, None)).unwrap();
10137        let c = b
10138            .as_any()
10139            .downcast_ref::<TimestampMillisecondArray>()
10140            .unwrap();
10141        assert_eq!(1609459200000, c.value(0));
10142        assert_eq!(1640995200000, c.value(1));
10143        assert!(c.is_null(2));
10144    }
10145
10146    #[test]
10147    fn test_cast_date32_to_timestamp_us() {
10148        let a = Date32Array::from(vec![Some(18628), Some(18993), None]); // 2021-1-1, 2022-1-1
10149        let array = Arc::new(a) as ArrayRef;
10150        let b = cast(&array, &DataType::Timestamp(TimeUnit::Microsecond, None)).unwrap();
10151        let c = b
10152            .as_any()
10153            .downcast_ref::<TimestampMicrosecondArray>()
10154            .unwrap();
10155        assert_eq!(1609459200000000, c.value(0));
10156        assert_eq!(1640995200000000, c.value(1));
10157        assert!(c.is_null(2));
10158    }
10159
10160    #[test]
10161    fn test_cast_date32_to_timestamp_ns() {
10162        let a = Date32Array::from(vec![Some(18628), Some(18993), None]); // 2021-1-1, 2022-1-1
10163        let array = Arc::new(a) as ArrayRef;
10164        let b = cast(&array, &DataType::Timestamp(TimeUnit::Nanosecond, None)).unwrap();
10165        let c = b
10166            .as_any()
10167            .downcast_ref::<TimestampNanosecondArray>()
10168            .unwrap();
10169        assert_eq!(1609459200000000000, c.value(0));
10170        assert_eq!(1640995200000000000, c.value(1));
10171        assert!(c.is_null(2));
10172    }
10173
10174    #[test]
10175    fn test_timezone_cast() {
10176        let a = StringArray::from(vec![
10177            "2000-01-01T12:00:00", // date + time valid
10178            "2020-12-15T12:34:56", // date + time valid
10179        ]);
10180        let array = Arc::new(a) as ArrayRef;
10181        let b = cast(&array, &DataType::Timestamp(TimeUnit::Nanosecond, None)).unwrap();
10182        let v = b.as_primitive::<TimestampNanosecondType>();
10183
10184        assert_eq!(v.value(0), 946728000000000000);
10185        assert_eq!(v.value(1), 1608035696000000000);
10186
10187        let b = cast(
10188            &b,
10189            &DataType::Timestamp(TimeUnit::Nanosecond, Some("+00:00".into())),
10190        )
10191        .unwrap();
10192        let v = b.as_primitive::<TimestampNanosecondType>();
10193
10194        assert_eq!(v.value(0), 946728000000000000);
10195        assert_eq!(v.value(1), 1608035696000000000);
10196
10197        let b = cast(
10198            &b,
10199            &DataType::Timestamp(TimeUnit::Millisecond, Some("+02:00".into())),
10200        )
10201        .unwrap();
10202        let v = b.as_primitive::<TimestampMillisecondType>();
10203
10204        assert_eq!(v.value(0), 946728000000);
10205        assert_eq!(v.value(1), 1608035696000);
10206    }
10207
10208    #[test]
10209    fn test_cast_utf8_to_timestamp() {
10210        fn test_tz(tz: Arc<str>) {
10211            let valid = StringArray::from(vec![
10212                "2023-01-01 04:05:06.789000-08:00",
10213                "2023-01-01 04:05:06.789000-07:00",
10214                "2023-01-01 04:05:06.789 -0800",
10215                "2023-01-01 04:05:06.789 -08:00",
10216                "2023-01-01 040506 +0730",
10217                "2023-01-01 040506 +07:30",
10218                "2023-01-01 04:05:06.789",
10219                "2023-01-01 04:05:06",
10220                "2023-01-01",
10221            ]);
10222
10223            let array = Arc::new(valid) as ArrayRef;
10224            let b = cast_with_options(
10225                &array,
10226                &DataType::Timestamp(TimeUnit::Nanosecond, Some(tz.clone())),
10227                &CastOptions {
10228                    safe: false,
10229                    format_options: FormatOptions::default(),
10230                },
10231            )
10232            .unwrap();
10233
10234            let tz = tz.as_ref().parse().unwrap();
10235
10236            let as_tz =
10237                |v: i64| as_datetime_with_timezone::<TimestampNanosecondType>(v, tz).unwrap();
10238
10239            let as_utc = |v: &i64| as_tz(*v).naive_utc().to_string();
10240            let as_local = |v: &i64| as_tz(*v).naive_local().to_string();
10241
10242            let values = b.as_primitive::<TimestampNanosecondType>().values();
10243            let utc_results: Vec<_> = values.iter().map(as_utc).collect();
10244            let local_results: Vec<_> = values.iter().map(as_local).collect();
10245
10246            // Absolute timestamps should be parsed preserving the same UTC instant
10247            assert_eq!(
10248                &utc_results[..6],
10249                &[
10250                    "2023-01-01 12:05:06.789".to_string(),
10251                    "2023-01-01 11:05:06.789".to_string(),
10252                    "2023-01-01 12:05:06.789".to_string(),
10253                    "2023-01-01 12:05:06.789".to_string(),
10254                    "2022-12-31 20:35:06".to_string(),
10255                    "2022-12-31 20:35:06".to_string(),
10256                ]
10257            );
10258            // Non-absolute timestamps should be parsed preserving the same local instant
10259            assert_eq!(
10260                &local_results[6..],
10261                &[
10262                    "2023-01-01 04:05:06.789".to_string(),
10263                    "2023-01-01 04:05:06".to_string(),
10264                    "2023-01-01 00:00:00".to_string()
10265                ]
10266            )
10267        }
10268
10269        test_tz("+00:00".into());
10270        test_tz("+02:00".into());
10271    }
10272
10273    #[test]
10274    fn test_cast_invalid_utf8() {
10275        let v1: &[u8] = b"\xFF invalid";
10276        let v2: &[u8] = b"\x00 Foo";
10277        let s = BinaryArray::from(vec![v1, v2]);
10278        let options = CastOptions {
10279            safe: true,
10280            format_options: FormatOptions::default(),
10281        };
10282        let array = cast_with_options(&s, &DataType::Utf8, &options).unwrap();
10283        let a = array.as_string::<i32>();
10284        a.to_data().validate_full().unwrap();
10285
10286        assert_eq!(a.null_count(), 1);
10287        assert_eq!(a.len(), 2);
10288        assert!(a.is_null(0));
10289        assert_eq!(a.value(0), "");
10290        assert_eq!(a.value(1), "\x00 Foo");
10291    }
10292
10293    #[test]
10294    fn test_cast_utf8_to_timestamptz() {
10295        let valid = StringArray::from(vec!["2023-01-01"]);
10296
10297        let array = Arc::new(valid) as ArrayRef;
10298        let b = cast(
10299            &array,
10300            &DataType::Timestamp(TimeUnit::Nanosecond, Some("+00:00".into())),
10301        )
10302        .unwrap();
10303
10304        let expect = DataType::Timestamp(TimeUnit::Nanosecond, Some("+00:00".into()));
10305
10306        assert_eq!(b.data_type(), &expect);
10307        let c = b
10308            .as_any()
10309            .downcast_ref::<TimestampNanosecondArray>()
10310            .unwrap();
10311        assert_eq!(1672531200000000000, c.value(0));
10312    }
10313
10314    #[test]
10315    fn test_cast_decimal_to_string() {
10316        assert!(can_cast_types(
10317            &DataType::Decimal32(9, 4),
10318            &DataType::Utf8View
10319        ));
10320        assert!(can_cast_types(
10321            &DataType::Decimal64(16, 4),
10322            &DataType::Utf8View
10323        ));
10324        assert!(can_cast_types(
10325            &DataType::Decimal128(10, 4),
10326            &DataType::Utf8View
10327        ));
10328        assert!(can_cast_types(
10329            &DataType::Decimal256(38, 10),
10330            &DataType::Utf8View
10331        ));
10332
10333        macro_rules! assert_decimal_values {
10334            ($array:expr) => {
10335                let c = $array;
10336                assert_eq!("1123.454", c.value(0));
10337                assert_eq!("2123.456", c.value(1));
10338                assert_eq!("-3123.453", c.value(2));
10339                assert_eq!("-3123.456", c.value(3));
10340                assert_eq!("0.000", c.value(4));
10341                assert_eq!("0.123", c.value(5));
10342                assert_eq!("1234.567", c.value(6));
10343                assert_eq!("-1234.567", c.value(7));
10344                assert!(c.is_null(8));
10345            };
10346        }
10347
10348        fn test_decimal_to_string<IN: ArrowPrimitiveType, OffsetSize: OffsetSizeTrait>(
10349            output_type: DataType,
10350            array: PrimitiveArray<IN>,
10351        ) {
10352            let b = cast(&array, &output_type).unwrap();
10353
10354            assert_eq!(b.data_type(), &output_type);
10355            match b.data_type() {
10356                DataType::Utf8View => {
10357                    let c = b.as_string_view();
10358                    assert_decimal_values!(c);
10359                }
10360                DataType::Utf8 | DataType::LargeUtf8 => {
10361                    let c = b.as_string::<OffsetSize>();
10362                    assert_decimal_values!(c);
10363                }
10364                _ => (),
10365            }
10366        }
10367
10368        let array32: Vec<Option<i32>> = vec![
10369            Some(1123454),
10370            Some(2123456),
10371            Some(-3123453),
10372            Some(-3123456),
10373            Some(0),
10374            Some(123),
10375            Some(123456789),
10376            Some(-123456789),
10377            None,
10378        ];
10379        let array64: Vec<Option<i64>> = array32.iter().map(|num| num.map(|x| x as i64)).collect();
10380        let array128: Vec<Option<i128>> =
10381            array64.iter().map(|num| num.map(|x| x as i128)).collect();
10382        let array256: Vec<Option<i256>> = array128
10383            .iter()
10384            .map(|num| num.map(i256::from_i128))
10385            .collect();
10386
10387        test_decimal_to_string::<Decimal32Type, i32>(
10388            DataType::Utf8View,
10389            create_decimal32_array(array32.clone(), 7, 3).unwrap(),
10390        );
10391        test_decimal_to_string::<Decimal32Type, i32>(
10392            DataType::Utf8,
10393            create_decimal32_array(array32.clone(), 7, 3).unwrap(),
10394        );
10395        test_decimal_to_string::<Decimal32Type, i64>(
10396            DataType::LargeUtf8,
10397            create_decimal32_array(array32, 7, 3).unwrap(),
10398        );
10399
10400        test_decimal_to_string::<Decimal64Type, i32>(
10401            DataType::Utf8View,
10402            create_decimal64_array(array64.clone(), 7, 3).unwrap(),
10403        );
10404        test_decimal_to_string::<Decimal64Type, i32>(
10405            DataType::Utf8,
10406            create_decimal64_array(array64.clone(), 7, 3).unwrap(),
10407        );
10408        test_decimal_to_string::<Decimal64Type, i64>(
10409            DataType::LargeUtf8,
10410            create_decimal64_array(array64, 7, 3).unwrap(),
10411        );
10412
10413        test_decimal_to_string::<Decimal128Type, i32>(
10414            DataType::Utf8View,
10415            create_decimal128_array(array128.clone(), 7, 3).unwrap(),
10416        );
10417        test_decimal_to_string::<Decimal128Type, i32>(
10418            DataType::Utf8,
10419            create_decimal128_array(array128.clone(), 7, 3).unwrap(),
10420        );
10421        test_decimal_to_string::<Decimal128Type, i64>(
10422            DataType::LargeUtf8,
10423            create_decimal128_array(array128, 7, 3).unwrap(),
10424        );
10425
10426        test_decimal_to_string::<Decimal256Type, i32>(
10427            DataType::Utf8View,
10428            create_decimal256_array(array256.clone(), 7, 3).unwrap(),
10429        );
10430        test_decimal_to_string::<Decimal256Type, i32>(
10431            DataType::Utf8,
10432            create_decimal256_array(array256.clone(), 7, 3).unwrap(),
10433        );
10434        test_decimal_to_string::<Decimal256Type, i64>(
10435            DataType::LargeUtf8,
10436            create_decimal256_array(array256, 7, 3).unwrap(),
10437        );
10438    }
10439
10440    #[test]
10441    fn test_cast_numeric_to_decimal128_precision_overflow() {
10442        let array = Int64Array::from(vec![1234567]);
10443        let array = Arc::new(array) as ArrayRef;
10444        let casted_array = cast_with_options(
10445            &array,
10446            &DataType::Decimal128(7, 3),
10447            &CastOptions {
10448                safe: true,
10449                format_options: FormatOptions::default(),
10450            },
10451        );
10452        assert!(casted_array.is_ok());
10453        assert!(casted_array.unwrap().is_null(0));
10454
10455        let err = cast_with_options(
10456            &array,
10457            &DataType::Decimal128(7, 3),
10458            &CastOptions {
10459                safe: false,
10460                format_options: FormatOptions::default(),
10461            },
10462        );
10463        assert_eq!(
10464            "Invalid argument error: 1234567.000 is too large to store in a Decimal128 of precision 7. Max is 9999.999",
10465            err.unwrap_err().to_string()
10466        );
10467    }
10468
10469    #[test]
10470    fn test_cast_numeric_to_decimal256_precision_overflow() {
10471        let array = Int64Array::from(vec![1234567]);
10472        let array = Arc::new(array) as ArrayRef;
10473        let casted_array = cast_with_options(
10474            &array,
10475            &DataType::Decimal256(7, 3),
10476            &CastOptions {
10477                safe: true,
10478                format_options: FormatOptions::default(),
10479            },
10480        );
10481        assert!(casted_array.is_ok());
10482        assert!(casted_array.unwrap().is_null(0));
10483
10484        let err = cast_with_options(
10485            &array,
10486            &DataType::Decimal256(7, 3),
10487            &CastOptions {
10488                safe: false,
10489                format_options: FormatOptions::default(),
10490            },
10491        );
10492        assert_eq!(
10493            "Invalid argument error: 1234567.000 is too large to store in a Decimal256 of precision 7. Max is 9999.999",
10494            err.unwrap_err().to_string()
10495        );
10496    }
10497
10498    /// helper function to test casting from duration to interval
10499    fn cast_from_duration_to_interval<T: ArrowTemporalType<Native = i64>>(
10500        array: Vec<i64>,
10501        cast_options: &CastOptions,
10502    ) -> Result<PrimitiveArray<IntervalMonthDayNanoType>, ArrowError> {
10503        let array = PrimitiveArray::<T>::new(array.into(), None);
10504        let array = Arc::new(array) as ArrayRef;
10505        let interval = DataType::Interval(IntervalUnit::MonthDayNano);
10506        let out = cast_with_options(&array, &interval, cast_options)?;
10507        let out = out.as_primitive::<IntervalMonthDayNanoType>().clone();
10508        Ok(out)
10509    }
10510
10511    #[test]
10512    fn test_cast_from_duration_to_interval() {
10513        // from duration second to interval month day nano
10514        let array = vec![1234567];
10515        let casted_array =
10516            cast_from_duration_to_interval::<DurationSecondType>(array, &CastOptions::default())
10517                .unwrap();
10518        assert_eq!(
10519            casted_array.data_type(),
10520            &DataType::Interval(IntervalUnit::MonthDayNano)
10521        );
10522        assert_eq!(
10523            casted_array.value(0),
10524            IntervalMonthDayNano::new(0, 0, 1234567000000000)
10525        );
10526
10527        let array = vec![i64::MAX];
10528        let casted_array = cast_from_duration_to_interval::<DurationSecondType>(
10529            array.clone(),
10530            &CastOptions::default(),
10531        )
10532        .unwrap();
10533        assert!(!casted_array.is_valid(0));
10534
10535        let casted_array = cast_from_duration_to_interval::<DurationSecondType>(
10536            array,
10537            &CastOptions {
10538                safe: false,
10539                format_options: FormatOptions::default(),
10540            },
10541        );
10542        assert!(casted_array.is_err());
10543
10544        // from duration millisecond to interval month day nano
10545        let array = vec![1234567];
10546        let casted_array = cast_from_duration_to_interval::<DurationMillisecondType>(
10547            array,
10548            &CastOptions::default(),
10549        )
10550        .unwrap();
10551        assert_eq!(
10552            casted_array.data_type(),
10553            &DataType::Interval(IntervalUnit::MonthDayNano)
10554        );
10555        assert_eq!(
10556            casted_array.value(0),
10557            IntervalMonthDayNano::new(0, 0, 1234567000000)
10558        );
10559
10560        let array = vec![i64::MAX];
10561        let casted_array = cast_from_duration_to_interval::<DurationMillisecondType>(
10562            array.clone(),
10563            &CastOptions::default(),
10564        )
10565        .unwrap();
10566        assert!(!casted_array.is_valid(0));
10567
10568        let casted_array = cast_from_duration_to_interval::<DurationMillisecondType>(
10569            array,
10570            &CastOptions {
10571                safe: false,
10572                format_options: FormatOptions::default(),
10573            },
10574        );
10575        assert!(casted_array.is_err());
10576
10577        // from duration microsecond to interval month day nano
10578        let array = vec![1234567];
10579        let casted_array = cast_from_duration_to_interval::<DurationMicrosecondType>(
10580            array,
10581            &CastOptions::default(),
10582        )
10583        .unwrap();
10584        assert_eq!(
10585            casted_array.data_type(),
10586            &DataType::Interval(IntervalUnit::MonthDayNano)
10587        );
10588        assert_eq!(
10589            casted_array.value(0),
10590            IntervalMonthDayNano::new(0, 0, 1234567000)
10591        );
10592
10593        let array = vec![i64::MAX];
10594        let casted_array = cast_from_duration_to_interval::<DurationMicrosecondType>(
10595            array.clone(),
10596            &CastOptions::default(),
10597        )
10598        .unwrap();
10599        assert!(!casted_array.is_valid(0));
10600
10601        let casted_array = cast_from_duration_to_interval::<DurationMicrosecondType>(
10602            array,
10603            &CastOptions {
10604                safe: false,
10605                format_options: FormatOptions::default(),
10606            },
10607        );
10608        assert!(casted_array.is_err());
10609
10610        // from duration nanosecond to interval month day nano
10611        let array = vec![1234567];
10612        let casted_array = cast_from_duration_to_interval::<DurationNanosecondType>(
10613            array,
10614            &CastOptions::default(),
10615        )
10616        .unwrap();
10617        assert_eq!(
10618            casted_array.data_type(),
10619            &DataType::Interval(IntervalUnit::MonthDayNano)
10620        );
10621        assert_eq!(
10622            casted_array.value(0),
10623            IntervalMonthDayNano::new(0, 0, 1234567)
10624        );
10625
10626        let array = vec![i64::MAX];
10627        let casted_array = cast_from_duration_to_interval::<DurationNanosecondType>(
10628            array,
10629            &CastOptions {
10630                safe: false,
10631                format_options: FormatOptions::default(),
10632            },
10633        )
10634        .unwrap();
10635        assert_eq!(
10636            casted_array.value(0),
10637            IntervalMonthDayNano::new(0, 0, i64::MAX)
10638        );
10639    }
10640
10641    /// helper function to test casting from interval to duration
10642    fn cast_from_interval_to_duration<T: ArrowTemporalType>(
10643        array: &IntervalMonthDayNanoArray,
10644        cast_options: &CastOptions,
10645    ) -> Result<PrimitiveArray<T>, ArrowError> {
10646        let casted_array = cast_with_options(&array, &T::DATA_TYPE, cast_options)?;
10647        casted_array
10648            .as_any()
10649            .downcast_ref::<PrimitiveArray<T>>()
10650            .ok_or_else(|| {
10651                ArrowError::ComputeError(format!("Failed to downcast to {}", T::DATA_TYPE))
10652            })
10653            .cloned()
10654    }
10655
10656    #[test]
10657    fn test_cast_from_interval_to_duration() {
10658        let nullable = CastOptions::default();
10659        let fallible = CastOptions {
10660            safe: false,
10661            format_options: FormatOptions::default(),
10662        };
10663        let v = IntervalMonthDayNano::new(0, 0, 1234567);
10664
10665        // from interval month day nano to duration second
10666        let array = vec![v].into();
10667        let casted_array: DurationSecondArray =
10668            cast_from_interval_to_duration(&array, &nullable).unwrap();
10669        assert_eq!(casted_array.value(0), 0);
10670
10671        let array = vec![IntervalMonthDayNano::MAX].into();
10672        let casted_array: DurationSecondArray =
10673            cast_from_interval_to_duration(&array, &nullable).unwrap();
10674        assert!(!casted_array.is_valid(0));
10675
10676        let res = cast_from_interval_to_duration::<DurationSecondType>(&array, &fallible);
10677        assert!(res.is_err());
10678
10679        // from interval month day nano to duration millisecond
10680        let array = vec![v].into();
10681        let casted_array: DurationMillisecondArray =
10682            cast_from_interval_to_duration(&array, &nullable).unwrap();
10683        assert_eq!(casted_array.value(0), 1);
10684
10685        let array = vec![IntervalMonthDayNano::MAX].into();
10686        let casted_array: DurationMillisecondArray =
10687            cast_from_interval_to_duration(&array, &nullable).unwrap();
10688        assert!(!casted_array.is_valid(0));
10689
10690        let res = cast_from_interval_to_duration::<DurationMillisecondType>(&array, &fallible);
10691        assert!(res.is_err());
10692
10693        // from interval month day nano to duration microsecond
10694        let array = vec![v].into();
10695        let casted_array: DurationMicrosecondArray =
10696            cast_from_interval_to_duration(&array, &nullable).unwrap();
10697        assert_eq!(casted_array.value(0), 1234);
10698
10699        let array = vec![IntervalMonthDayNano::MAX].into();
10700        let casted_array =
10701            cast_from_interval_to_duration::<DurationMicrosecondType>(&array, &nullable).unwrap();
10702        assert!(!casted_array.is_valid(0));
10703
10704        let casted_array =
10705            cast_from_interval_to_duration::<DurationMicrosecondType>(&array, &fallible);
10706        assert!(casted_array.is_err());
10707
10708        // from interval month day nano to duration nanosecond
10709        let array = vec![v].into();
10710        let casted_array: DurationNanosecondArray =
10711            cast_from_interval_to_duration(&array, &nullable).unwrap();
10712        assert_eq!(casted_array.value(0), 1234567);
10713
10714        let array = vec![IntervalMonthDayNano::MAX].into();
10715        let casted_array: DurationNanosecondArray =
10716            cast_from_interval_to_duration(&array, &nullable).unwrap();
10717        assert!(!casted_array.is_valid(0));
10718
10719        let casted_array =
10720            cast_from_interval_to_duration::<DurationNanosecondType>(&array, &fallible);
10721        assert!(casted_array.is_err());
10722
10723        let array = vec![
10724            IntervalMonthDayNanoType::make_value(0, 1, 0),
10725            IntervalMonthDayNanoType::make_value(-1, 0, 0),
10726            IntervalMonthDayNanoType::make_value(1, 1, 0),
10727            IntervalMonthDayNanoType::make_value(1, 0, 1),
10728            IntervalMonthDayNanoType::make_value(0, 0, -1),
10729        ]
10730        .into();
10731        let casted_array =
10732            cast_from_interval_to_duration::<DurationNanosecondType>(&array, &nullable).unwrap();
10733        assert!(!casted_array.is_valid(0));
10734        assert!(!casted_array.is_valid(1));
10735        assert!(!casted_array.is_valid(2));
10736        assert!(!casted_array.is_valid(3));
10737        assert!(casted_array.is_valid(4));
10738        assert_eq!(casted_array.value(4), -1);
10739    }
10740
10741    /// helper function to test casting from interval year month to interval month day nano
10742    fn cast_from_interval_year_month_to_interval_month_day_nano(
10743        array: Vec<i32>,
10744        cast_options: &CastOptions,
10745    ) -> Result<PrimitiveArray<IntervalMonthDayNanoType>, ArrowError> {
10746        let array = PrimitiveArray::<IntervalYearMonthType>::from(array);
10747        let array = Arc::new(array) as ArrayRef;
10748        let casted_array = cast_with_options(
10749            &array,
10750            &DataType::Interval(IntervalUnit::MonthDayNano),
10751            cast_options,
10752        )?;
10753        casted_array
10754            .as_any()
10755            .downcast_ref::<IntervalMonthDayNanoArray>()
10756            .ok_or_else(|| {
10757                ArrowError::ComputeError(
10758                    "Failed to downcast to IntervalMonthDayNanoArray".to_string(),
10759                )
10760            })
10761            .cloned()
10762    }
10763
10764    #[test]
10765    fn test_cast_from_interval_year_month_to_interval_month_day_nano() {
10766        // from interval year month to interval month day nano
10767        let array = vec![1234567];
10768        let casted_array = cast_from_interval_year_month_to_interval_month_day_nano(
10769            array,
10770            &CastOptions::default(),
10771        )
10772        .unwrap();
10773        assert_eq!(
10774            casted_array.data_type(),
10775            &DataType::Interval(IntervalUnit::MonthDayNano)
10776        );
10777        assert_eq!(
10778            casted_array.value(0),
10779            IntervalMonthDayNano::new(1234567, 0, 0)
10780        );
10781    }
10782
10783    /// helper function to test casting from interval day time to interval month day nano
10784    fn cast_from_interval_day_time_to_interval_month_day_nano(
10785        array: Vec<IntervalDayTime>,
10786        cast_options: &CastOptions,
10787    ) -> Result<PrimitiveArray<IntervalMonthDayNanoType>, ArrowError> {
10788        let array = PrimitiveArray::<IntervalDayTimeType>::from(array);
10789        let array = Arc::new(array) as ArrayRef;
10790        let casted_array = cast_with_options(
10791            &array,
10792            &DataType::Interval(IntervalUnit::MonthDayNano),
10793            cast_options,
10794        )?;
10795        Ok(casted_array
10796            .as_primitive::<IntervalMonthDayNanoType>()
10797            .clone())
10798    }
10799
10800    #[test]
10801    fn test_cast_from_interval_day_time_to_interval_month_day_nano() {
10802        // from interval day time to interval month day nano
10803        let array = vec![IntervalDayTime::new(123, 0)];
10804        let casted_array =
10805            cast_from_interval_day_time_to_interval_month_day_nano(array, &CastOptions::default())
10806                .unwrap();
10807        assert_eq!(
10808            casted_array.data_type(),
10809            &DataType::Interval(IntervalUnit::MonthDayNano)
10810        );
10811        assert_eq!(casted_array.value(0), IntervalMonthDayNano::new(0, 123, 0));
10812    }
10813
10814    #[test]
10815    fn test_cast_below_unixtimestamp() {
10816        let valid = StringArray::from(vec![
10817            "1900-01-03 23:59:59",
10818            "1969-12-31 00:00:01",
10819            "1989-12-31 00:00:01",
10820        ]);
10821
10822        let array = Arc::new(valid) as ArrayRef;
10823        let casted_array = cast_with_options(
10824            &array,
10825            &DataType::Timestamp(TimeUnit::Nanosecond, Some("+00:00".into())),
10826            &CastOptions {
10827                safe: false,
10828                format_options: FormatOptions::default(),
10829            },
10830        )
10831        .unwrap();
10832
10833        let ts_array = casted_array
10834            .as_primitive::<TimestampNanosecondType>()
10835            .values()
10836            .iter()
10837            .map(|ts| ts / 1_000_000)
10838            .collect::<Vec<_>>();
10839
10840        let array = TimestampMillisecondArray::from(ts_array).with_timezone("+00:00".to_string());
10841        let casted_array = cast(&array, &DataType::Date32).unwrap();
10842        let date_array = casted_array.as_primitive::<Date32Type>();
10843        let casted_array = cast(&date_array, &DataType::Utf8).unwrap();
10844        let string_array = casted_array.as_string::<i32>();
10845        assert_eq!("1900-01-03", string_array.value(0));
10846        assert_eq!("1969-12-31", string_array.value(1));
10847        assert_eq!("1989-12-31", string_array.value(2));
10848    }
10849
10850    #[test]
10851    fn test_nested_list() {
10852        let mut list = ListBuilder::new(Int32Builder::new());
10853        list.append_value([Some(1), Some(2), Some(3)]);
10854        list.append_value([Some(4), None, Some(6)]);
10855        let list = list.finish();
10856
10857        let to_field = Field::new("nested", list.data_type().clone(), false);
10858        let to = DataType::List(Arc::new(to_field));
10859        let out = cast(&list, &to).unwrap();
10860        let opts = FormatOptions::default().with_null("null");
10861        let formatted = ArrayFormatter::try_new(out.as_ref(), &opts).unwrap();
10862
10863        assert_eq!(formatted.value(0).to_string(), "[[1], [2], [3]]");
10864        assert_eq!(formatted.value(1).to_string(), "[[4], [null], [6]]");
10865    }
10866
10867    #[test]
10868    fn test_nested_list_cast() {
10869        let mut builder = ListBuilder::new(ListBuilder::new(Int32Builder::new()));
10870        builder.append_value([Some([Some(1), Some(2), None]), None]);
10871        builder.append_value([None, Some([]), None]);
10872        builder.append_null();
10873        builder.append_value([Some([Some(2), Some(3)])]);
10874        let start = builder.finish();
10875
10876        let mut builder = LargeListBuilder::new(LargeListBuilder::new(Int8Builder::new()));
10877        builder.append_value([Some([Some(1), Some(2), None]), None]);
10878        builder.append_value([None, Some([]), None]);
10879        builder.append_null();
10880        builder.append_value([Some([Some(2), Some(3)])]);
10881        let expected = builder.finish();
10882
10883        let actual = cast(&start, expected.data_type()).unwrap();
10884        assert_eq!(actual.as_ref(), &expected);
10885    }
10886
10887    const CAST_OPTIONS: CastOptions<'static> = CastOptions {
10888        safe: true,
10889        format_options: FormatOptions::new(),
10890    };
10891
10892    #[test]
10893    #[allow(clippy::assertions_on_constants)]
10894    fn test_const_options() {
10895        assert!(CAST_OPTIONS.safe)
10896    }
10897
10898    #[test]
10899    fn test_list_format_options() {
10900        let options = CastOptions {
10901            safe: false,
10902            format_options: FormatOptions::default().with_null("null"),
10903        };
10904        let array = ListArray::from_iter_primitive::<Int32Type, _, _>(vec![
10905            Some(vec![Some(0), Some(1), Some(2)]),
10906            Some(vec![Some(0), None, Some(2)]),
10907        ]);
10908        let a = cast_with_options(&array, &DataType::Utf8, &options).unwrap();
10909        let r: Vec<_> = a.as_string::<i32>().iter().flatten().collect();
10910        assert_eq!(r, &["[0, 1, 2]", "[0, null, 2]"]);
10911    }
10912    #[test]
10913    fn test_cast_string_to_timestamp_invalid_tz() {
10914        // content after Z should be ignored
10915        let bad_timestamp = "2023-12-05T21:58:10.45ZZTOP";
10916        let array = StringArray::from(vec![Some(bad_timestamp)]);
10917
10918        let data_types = [
10919            DataType::Timestamp(TimeUnit::Second, None),
10920            DataType::Timestamp(TimeUnit::Millisecond, None),
10921            DataType::Timestamp(TimeUnit::Microsecond, None),
10922            DataType::Timestamp(TimeUnit::Nanosecond, None),
10923        ];
10924
10925        let cast_options = CastOptions {
10926            safe: false,
10927            ..Default::default()
10928        };
10929
10930        for dt in data_types {
10931            assert_eq!(
10932                cast_with_options(&array, &dt, &cast_options)
10933                    .unwrap_err()
10934                    .to_string(),
10935                "Parser error: Invalid timezone \"ZZTOP\": only offset based timezones supported without chrono-tz feature"
10936            );
10937        }
10938    }
10939    #[test]
10940    fn test_cast_struct_to_struct() {
10941        let struct_type = DataType::Struct(
10942            vec![
10943                Field::new("a", DataType::Boolean, false),
10944                Field::new("b", DataType::Int32, false),
10945            ]
10946            .into(),
10947        );
10948        let to_type = DataType::Struct(
10949            vec![
10950                Field::new("a", DataType::Utf8, false),
10951                Field::new("b", DataType::Utf8, false),
10952            ]
10953            .into(),
10954        );
10955        let boolean = Arc::new(BooleanArray::from(vec![false, false, true, true]));
10956        let int = Arc::new(Int32Array::from(vec![42, 28, 19, 31]));
10957        let struct_array = StructArray::from(vec![
10958            (
10959                Arc::new(Field::new("b", DataType::Boolean, false)),
10960                boolean.clone() as ArrayRef,
10961            ),
10962            (
10963                Arc::new(Field::new("c", DataType::Int32, false)),
10964                int.clone() as ArrayRef,
10965            ),
10966        ]);
10967        let casted_array = cast(&struct_array, &to_type).unwrap();
10968        let casted_array = casted_array.as_struct();
10969        assert_eq!(casted_array.data_type(), &to_type);
10970        let casted_boolean_array = casted_array
10971            .column(0)
10972            .as_string::<i32>()
10973            .into_iter()
10974            .flatten()
10975            .collect::<Vec<_>>();
10976        let casted_int_array = casted_array
10977            .column(1)
10978            .as_string::<i32>()
10979            .into_iter()
10980            .flatten()
10981            .collect::<Vec<_>>();
10982        assert_eq!(casted_boolean_array, vec!["false", "false", "true", "true"]);
10983        assert_eq!(casted_int_array, vec!["42", "28", "19", "31"]);
10984
10985        // test for can't cast
10986        let to_type = DataType::Struct(
10987            vec![
10988                Field::new("a", DataType::Date32, false),
10989                Field::new("b", DataType::Utf8, false),
10990            ]
10991            .into(),
10992        );
10993        assert!(!can_cast_types(&struct_type, &to_type));
10994        let result = cast(&struct_array, &to_type);
10995        assert_eq!(
10996            "Cast error: Casting from Boolean to Date32 not supported",
10997            result.unwrap_err().to_string()
10998        );
10999    }
11000
11001    #[test]
11002    fn test_cast_struct_to_struct_nullability() {
11003        let boolean = Arc::new(BooleanArray::from(vec![false, false, true, true]));
11004        let int = Arc::new(Int32Array::from(vec![Some(42), None, Some(19), None]));
11005        let struct_array = StructArray::from(vec![
11006            (
11007                Arc::new(Field::new("b", DataType::Boolean, false)),
11008                boolean.clone() as ArrayRef,
11009            ),
11010            (
11011                Arc::new(Field::new("c", DataType::Int32, true)),
11012                int.clone() as ArrayRef,
11013            ),
11014        ]);
11015
11016        // okay: nullable to nullable
11017        let to_type = DataType::Struct(
11018            vec![
11019                Field::new("a", DataType::Utf8, false),
11020                Field::new("b", DataType::Utf8, true),
11021            ]
11022            .into(),
11023        );
11024        cast(&struct_array, &to_type).expect("Cast nullable to nullable struct field should work");
11025
11026        // error: nullable to non-nullable
11027        let to_type = DataType::Struct(
11028            vec![
11029                Field::new("a", DataType::Utf8, false),
11030                Field::new("b", DataType::Utf8, false),
11031            ]
11032            .into(),
11033        );
11034        cast(&struct_array, &to_type)
11035            .expect_err("Cast nullable to non-nullable struct field should fail");
11036
11037        let boolean = Arc::new(BooleanArray::from(vec![false, false, true, true]));
11038        let int = Arc::new(Int32Array::from(vec![i32::MAX, 25, 1, 100]));
11039        let struct_array = StructArray::from(vec![
11040            (
11041                Arc::new(Field::new("b", DataType::Boolean, false)),
11042                boolean.clone() as ArrayRef,
11043            ),
11044            (
11045                Arc::new(Field::new("c", DataType::Int32, false)),
11046                int.clone() as ArrayRef,
11047            ),
11048        ]);
11049
11050        // okay: non-nullable to non-nullable
11051        let to_type = DataType::Struct(
11052            vec![
11053                Field::new("a", DataType::Utf8, false),
11054                Field::new("b", DataType::Utf8, false),
11055            ]
11056            .into(),
11057        );
11058        cast(&struct_array, &to_type)
11059            .expect("Cast non-nullable to non-nullable struct field should work");
11060
11061        // err: non-nullable to non-nullable but overflowing return null during casting
11062        let to_type = DataType::Struct(
11063            vec![
11064                Field::new("a", DataType::Utf8, false),
11065                Field::new("b", DataType::Int8, false),
11066            ]
11067            .into(),
11068        );
11069        cast(&struct_array, &to_type).expect_err(
11070            "Cast non-nullable to non-nullable struct field returning null should fail",
11071        );
11072    }
11073
11074    #[test]
11075    fn test_cast_struct_to_non_struct() {
11076        let boolean = Arc::new(BooleanArray::from(vec![true, false]));
11077        let struct_array = StructArray::from(vec![(
11078            Arc::new(Field::new("a", DataType::Boolean, false)),
11079            boolean.clone() as ArrayRef,
11080        )]);
11081        let to_type = DataType::Utf8;
11082        let result = cast(&struct_array, &to_type);
11083        assert_eq!(
11084            r#"Cast error: Casting from Struct("a": non-null Boolean) to Utf8 not supported"#,
11085            result.unwrap_err().to_string()
11086        );
11087    }
11088
11089    #[test]
11090    fn test_cast_non_struct_to_struct() {
11091        let array = StringArray::from(vec!["a", "b"]);
11092        let to_type = DataType::Struct(vec![Field::new("a", DataType::Boolean, false)].into());
11093        let result = cast(&array, &to_type);
11094        assert_eq!(
11095            r#"Cast error: Casting from Utf8 to Struct("a": non-null Boolean) not supported"#,
11096            result.unwrap_err().to_string()
11097        );
11098    }
11099
11100    #[test]
11101    fn test_cast_struct_with_different_field_order() {
11102        // Test slow path: fields are in different order
11103        let boolean = Arc::new(BooleanArray::from(vec![false, false, true, true]));
11104        let int = Arc::new(Int32Array::from(vec![42, 28, 19, 31]));
11105        let string = Arc::new(StringArray::from(vec!["foo", "bar", "baz", "qux"]));
11106
11107        let struct_array = StructArray::from(vec![
11108            (
11109                Arc::new(Field::new("a", DataType::Boolean, false)),
11110                boolean.clone() as ArrayRef,
11111            ),
11112            (
11113                Arc::new(Field::new("b", DataType::Int32, false)),
11114                int.clone() as ArrayRef,
11115            ),
11116            (
11117                Arc::new(Field::new("c", DataType::Utf8, false)),
11118                string.clone() as ArrayRef,
11119            ),
11120        ]);
11121
11122        // Target has fields in different order: c, a, b instead of a, b, c
11123        let to_type = DataType::Struct(
11124            vec![
11125                Field::new("c", DataType::Utf8, false),
11126                Field::new("a", DataType::Utf8, false), // Boolean to Utf8
11127                Field::new("b", DataType::Utf8, false), // Int32 to Utf8
11128            ]
11129            .into(),
11130        );
11131
11132        let result = cast(&struct_array, &to_type).unwrap();
11133        let result_struct = result.as_struct();
11134
11135        assert_eq!(result_struct.data_type(), &to_type);
11136        assert_eq!(result_struct.num_columns(), 3);
11137
11138        // Verify field "c" (originally position 2, now position 0) remains Utf8
11139        let c_column = result_struct.column(0).as_string::<i32>();
11140        assert_eq!(
11141            c_column.into_iter().flatten().collect::<Vec<_>>(),
11142            vec!["foo", "bar", "baz", "qux"]
11143        );
11144
11145        // Verify field "a" (originally position 0, now position 1) was cast from Boolean to Utf8
11146        let a_column = result_struct.column(1).as_string::<i32>();
11147        assert_eq!(
11148            a_column.into_iter().flatten().collect::<Vec<_>>(),
11149            vec!["false", "false", "true", "true"]
11150        );
11151
11152        // Verify field "b" (originally position 1, now position 2) was cast from Int32 to Utf8
11153        let b_column = result_struct.column(2).as_string::<i32>();
11154        assert_eq!(
11155            b_column.into_iter().flatten().collect::<Vec<_>>(),
11156            vec!["42", "28", "19", "31"]
11157        );
11158    }
11159
11160    #[test]
11161    fn test_cast_struct_with_missing_field() {
11162        // Test that casting fails when target has a field not present in source
11163        let boolean = Arc::new(BooleanArray::from(vec![false, true]));
11164        let struct_array = StructArray::from(vec![(
11165            Arc::new(Field::new("a", DataType::Boolean, false)),
11166            boolean.clone() as ArrayRef,
11167        )]);
11168
11169        let to_type = DataType::Struct(
11170            vec![
11171                Field::new("a", DataType::Utf8, false),
11172                Field::new("b", DataType::Int32, false), // Field "b" doesn't exist in source
11173            ]
11174            .into(),
11175        );
11176
11177        let result = cast(&struct_array, &to_type);
11178        assert!(result.is_err());
11179        assert_eq!(
11180            result.unwrap_err().to_string(),
11181            "Invalid argument error: Incorrect number of arrays for StructArray fields, expected 2 got 1"
11182        );
11183    }
11184
11185    #[test]
11186    fn test_cast_struct_with_subset_of_fields() {
11187        // Test casting to a struct with fewer fields (selecting a subset)
11188        let boolean = Arc::new(BooleanArray::from(vec![false, false, true, true]));
11189        let int = Arc::new(Int32Array::from(vec![42, 28, 19, 31]));
11190        let string = Arc::new(StringArray::from(vec!["foo", "bar", "baz", "qux"]));
11191
11192        let struct_array = StructArray::from(vec![
11193            (
11194                Arc::new(Field::new("a", DataType::Boolean, false)),
11195                boolean.clone() as ArrayRef,
11196            ),
11197            (
11198                Arc::new(Field::new("b", DataType::Int32, false)),
11199                int.clone() as ArrayRef,
11200            ),
11201            (
11202                Arc::new(Field::new("c", DataType::Utf8, false)),
11203                string.clone() as ArrayRef,
11204            ),
11205        ]);
11206
11207        // Target has only fields "c" and "a", omitting "b"
11208        let to_type = DataType::Struct(
11209            vec![
11210                Field::new("c", DataType::Utf8, false),
11211                Field::new("a", DataType::Utf8, false),
11212            ]
11213            .into(),
11214        );
11215
11216        let result = cast(&struct_array, &to_type).unwrap();
11217        let result_struct = result.as_struct();
11218
11219        assert_eq!(result_struct.data_type(), &to_type);
11220        assert_eq!(result_struct.num_columns(), 2);
11221
11222        // Verify field "c" remains Utf8
11223        let c_column = result_struct.column(0).as_string::<i32>();
11224        assert_eq!(
11225            c_column.into_iter().flatten().collect::<Vec<_>>(),
11226            vec!["foo", "bar", "baz", "qux"]
11227        );
11228
11229        // Verify field "a" was cast from Boolean to Utf8
11230        let a_column = result_struct.column(1).as_string::<i32>();
11231        assert_eq!(
11232            a_column.into_iter().flatten().collect::<Vec<_>>(),
11233            vec!["false", "false", "true", "true"]
11234        );
11235    }
11236
11237    #[test]
11238    fn test_can_cast_struct_rename_field() {
11239        // Test that can_cast_types returns false when target has a field not in source
11240        let from_type = DataType::Struct(
11241            vec![
11242                Field::new("a", DataType::Int32, false),
11243                Field::new("b", DataType::Utf8, false),
11244            ]
11245            .into(),
11246        );
11247
11248        let to_type = DataType::Struct(
11249            vec![
11250                Field::new("a", DataType::Int64, false),
11251                Field::new("c", DataType::Boolean, false), // Field "c" not in source
11252            ]
11253            .into(),
11254        );
11255
11256        assert!(can_cast_types(&from_type, &to_type));
11257    }
11258
11259    fn run_decimal_cast_test_case_between_multiple_types(t: DecimalCastTestConfig) {
11260        run_decimal_cast_test_case::<Decimal128Type, Decimal128Type>(t.clone());
11261        run_decimal_cast_test_case::<Decimal128Type, Decimal256Type>(t.clone());
11262        run_decimal_cast_test_case::<Decimal256Type, Decimal128Type>(t.clone());
11263        run_decimal_cast_test_case::<Decimal256Type, Decimal256Type>(t.clone());
11264    }
11265
11266    #[test]
11267    fn test_decimal_to_decimal_coverage() {
11268        let test_cases = [
11269            // increase precision, increase scale, infallible
11270            DecimalCastTestConfig {
11271                input_prec: 5,
11272                input_scale: 1,
11273                input_repr: 99999, // 9999.9
11274                output_prec: 10,
11275                output_scale: 6,
11276                expected_output_repr: Ok(9999900000), // 9999.900000
11277            },
11278            // increase precision, increase scale, fallible, safe
11279            DecimalCastTestConfig {
11280                input_prec: 5,
11281                input_scale: 1,
11282                input_repr: 99, // 9999.9
11283                output_prec: 7,
11284                output_scale: 6,
11285                expected_output_repr: Ok(9900000), // 9.900000
11286            },
11287            // increase precision, increase scale, fallible, unsafe
11288            DecimalCastTestConfig {
11289                input_prec: 5,
11290                input_scale: 1,
11291                input_repr: 99999, // 9999.9
11292                output_prec: 7,
11293                output_scale: 6,
11294                expected_output_repr: Err("Invalid argument error: 9999.900000 is too large to store in a {} of precision 7. Max is 9.999999".to_string()) // max is 9.999999
11295            },
11296            // increase precision, decrease scale, always infallible
11297            DecimalCastTestConfig {
11298                input_prec: 5,
11299                input_scale: 3,
11300                input_repr: 99999, // 99.999
11301                output_prec: 10,
11302                output_scale: 2,
11303                expected_output_repr: Ok(10000), // 100.00
11304            },
11305            // increase precision, decrease scale, no rouding
11306            DecimalCastTestConfig {
11307                input_prec: 5,
11308                input_scale: 3,
11309                input_repr: 99994, // 99.994
11310                output_prec: 10,
11311                output_scale: 2,
11312                expected_output_repr: Ok(9999), // 99.99
11313            },
11314            // increase precision, don't change scale, always infallible
11315            DecimalCastTestConfig {
11316                input_prec: 5,
11317                input_scale: 3,
11318                input_repr: 99999, // 99.999
11319                output_prec: 10,
11320                output_scale: 3,
11321                expected_output_repr: Ok(99999), // 99.999
11322            },
11323            // decrease precision, increase scale, safe
11324            DecimalCastTestConfig {
11325                input_prec: 10,
11326                input_scale: 5,
11327                input_repr: 999999, // 9.99999
11328                output_prec: 8,
11329                output_scale: 7,
11330                expected_output_repr: Ok(99999900), // 9.9999900
11331            },
11332            // decrease precision, increase scale, unsafe
11333            DecimalCastTestConfig {
11334                input_prec: 10,
11335                input_scale: 5,
11336                input_repr: 9999999, // 99.99999
11337                output_prec: 8,
11338                output_scale: 7,
11339                expected_output_repr: Err("Invalid argument error: 99.9999900 is too large to store in a {} of precision 8. Max is 9.9999999".to_string()) // max is 9.9999999
11340            },
11341            // decrease precision, decrease scale, safe, infallible
11342            DecimalCastTestConfig {
11343                input_prec: 7,
11344                input_scale: 4,
11345                input_repr: 9999999, // 999.9999
11346                output_prec: 6,
11347                output_scale: 2,
11348                expected_output_repr: Ok(100000),
11349            },
11350            // decrease precision, decrease scale, safe, fallible
11351            DecimalCastTestConfig {
11352                input_prec: 10,
11353                input_scale: 5,
11354                input_repr: 12345678, // 123.45678
11355                output_prec: 8,
11356                output_scale: 3,
11357                expected_output_repr: Ok(123457), // 123.457
11358            },
11359            // decrease precision, decrease scale, unsafe
11360            DecimalCastTestConfig {
11361                input_prec: 10,
11362                input_scale: 5,
11363                input_repr: 9999999, // 99.99999
11364                output_prec: 4,
11365                output_scale: 3,
11366                expected_output_repr: Err("Invalid argument error: 100.000 is too large to store in a {} of precision 4. Max is 9.999".to_string()) // max is 9.999
11367            },
11368            // decrease precision, same scale, safe
11369            DecimalCastTestConfig {
11370                input_prec: 10,
11371                input_scale: 5,
11372                input_repr: 999999, // 9.99999
11373                output_prec: 6,
11374                output_scale: 5,
11375                expected_output_repr: Ok(999999), // 9.99999
11376            },
11377            // decrease precision, same scale, unsafe
11378            DecimalCastTestConfig {
11379                input_prec: 10,
11380                input_scale: 5,
11381                input_repr: 9999999, // 99.99999
11382                output_prec: 6,
11383                output_scale: 5,
11384                expected_output_repr: Err("Invalid argument error: 99.99999 is too large to store in a {} of precision 6. Max is 9.99999".to_string()) // max is 9.99999
11385            },
11386            // same precision, increase scale, safe
11387            DecimalCastTestConfig {
11388                input_prec: 7,
11389                input_scale: 4,
11390                input_repr: 12345, // 1.2345
11391                output_prec: 7,
11392                output_scale: 6,
11393                expected_output_repr: Ok(1234500), // 1.234500
11394            },
11395            // same precision, increase scale, unsafe
11396            DecimalCastTestConfig {
11397                input_prec: 7,
11398                input_scale: 4,
11399                input_repr: 123456, // 12.3456
11400                output_prec: 7,
11401                output_scale: 6,
11402                expected_output_repr: Err("Invalid argument error: 12.345600 is too large to store in a {} of precision 7. Max is 9.999999".to_string()) // max is 9.99999
11403            },
11404            // same precision, decrease scale, infallible
11405            DecimalCastTestConfig {
11406                input_prec: 7,
11407                input_scale: 5,
11408                input_repr: 1234567, // 12.34567
11409                output_prec: 7,
11410                output_scale: 4,
11411                expected_output_repr: Ok(123457), // 12.3457
11412            },
11413            // same precision, same scale, infallible
11414            DecimalCastTestConfig {
11415                input_prec: 7,
11416                input_scale: 5,
11417                input_repr: 9999999, // 99.99999
11418                output_prec: 7,
11419                output_scale: 5,
11420                expected_output_repr: Ok(9999999), // 99.99999
11421            },
11422            // precision increase, input scale & output scale = 0, infallible
11423            DecimalCastTestConfig {
11424                input_prec: 7,
11425                input_scale: 0,
11426                input_repr: 1234567, // 1234567
11427                output_prec: 8,
11428                output_scale: 0,
11429                expected_output_repr: Ok(1234567), // 1234567
11430            },
11431            // precision decrease, input scale & output scale = 0, failure
11432            DecimalCastTestConfig {
11433                input_prec: 7,
11434                input_scale: 0,
11435                input_repr: 1234567, // 1234567
11436                output_prec: 6,
11437                output_scale: 0,
11438                expected_output_repr: Err("Invalid argument error: 1234567 is too large to store in a {} of precision 6. Max is 999999".to_string())
11439            },
11440            // precision decrease, input scale & output scale = 0, success
11441            DecimalCastTestConfig {
11442                input_prec: 7,
11443                input_scale: 0,
11444                input_repr: 123456, // 123456
11445                output_prec: 6,
11446                output_scale: 0,
11447                expected_output_repr: Ok(123456), // 123456
11448            },
11449        ];
11450
11451        for t in test_cases {
11452            run_decimal_cast_test_case_between_multiple_types(t);
11453        }
11454    }
11455
11456    #[test]
11457    fn test_decimal_to_decimal_increase_scale_and_precision_unchecked() {
11458        let test_cases = [
11459            DecimalCastTestConfig {
11460                input_prec: 5,
11461                input_scale: 0,
11462                input_repr: 99999,
11463                output_prec: 10,
11464                output_scale: 5,
11465                expected_output_repr: Ok(9999900000),
11466            },
11467            DecimalCastTestConfig {
11468                input_prec: 5,
11469                input_scale: 0,
11470                input_repr: -99999,
11471                output_prec: 10,
11472                output_scale: 5,
11473                expected_output_repr: Ok(-9999900000),
11474            },
11475            DecimalCastTestConfig {
11476                input_prec: 5,
11477                input_scale: 2,
11478                input_repr: 99999,
11479                output_prec: 10,
11480                output_scale: 5,
11481                expected_output_repr: Ok(99999000),
11482            },
11483            DecimalCastTestConfig {
11484                input_prec: 5,
11485                input_scale: -2,
11486                input_repr: -99999,
11487                output_prec: 10,
11488                output_scale: 3,
11489                expected_output_repr: Ok(-9999900000),
11490            },
11491            DecimalCastTestConfig {
11492                input_prec: 5,
11493                input_scale: 3,
11494                input_repr: -12345,
11495                output_prec: 6,
11496                output_scale: 5,
11497                expected_output_repr: Err("Invalid argument error: -12.34500 is too small to store in a {} of precision 6. Min is -9.99999".to_string())
11498            },
11499        ];
11500
11501        for t in test_cases {
11502            run_decimal_cast_test_case_between_multiple_types(t);
11503        }
11504    }
11505
11506    #[test]
11507    fn test_decimal_to_decimal_decrease_scale_and_precision_unchecked() {
11508        let test_cases = [
11509            DecimalCastTestConfig {
11510                input_prec: 5,
11511                input_scale: 0,
11512                input_repr: 99999,
11513                output_scale: -3,
11514                output_prec: 3,
11515                expected_output_repr: Ok(100),
11516            },
11517            DecimalCastTestConfig {
11518                input_prec: 5,
11519                input_scale: 0,
11520                input_repr: -99999,
11521                output_prec: 1,
11522                output_scale: -5,
11523                expected_output_repr: Ok(-1),
11524            },
11525            DecimalCastTestConfig {
11526                input_prec: 10,
11527                input_scale: 2,
11528                input_repr: 123456789,
11529                output_prec: 5,
11530                output_scale: -2,
11531                expected_output_repr: Ok(12346),
11532            },
11533            DecimalCastTestConfig {
11534                input_prec: 10,
11535                input_scale: 4,
11536                input_repr: -9876543210,
11537                output_prec: 7,
11538                output_scale: 0,
11539                expected_output_repr: Ok(-987654),
11540            },
11541            DecimalCastTestConfig {
11542                input_prec: 7,
11543                input_scale: 4,
11544                input_repr: 9999999,
11545                output_prec: 6,
11546                output_scale: 3,
11547                expected_output_repr:
11548                    Err("Invalid argument error: 1000.000 is too large to store in a {} of precision 6. Max is 999.999".to_string()),
11549            },
11550        ];
11551        for t in test_cases {
11552            run_decimal_cast_test_case_between_multiple_types(t);
11553        }
11554    }
11555
11556    #[test]
11557    fn test_decimal_to_decimal_throw_error_on_precision_overflow_same_scale() {
11558        let array = vec![Some(123456789)];
11559        let array = create_decimal128_array(array, 24, 2).unwrap();
11560        let input_type = DataType::Decimal128(24, 2);
11561        let output_type = DataType::Decimal128(6, 2);
11562        assert!(can_cast_types(&input_type, &output_type));
11563
11564        let options = CastOptions {
11565            safe: false,
11566            ..Default::default()
11567        };
11568        let result = cast_with_options(&array, &output_type, &options);
11569        assert_eq!(
11570            result.unwrap_err().to_string(),
11571            "Invalid argument error: 1234567.89 is too large to store in a Decimal128 of precision 6. Max is 9999.99"
11572        );
11573    }
11574
11575    #[test]
11576    fn test_decimal_to_decimal_same_scale() {
11577        let array = vec![Some(520)];
11578        let array = create_decimal128_array(array, 4, 2).unwrap();
11579        let input_type = DataType::Decimal128(4, 2);
11580        let output_type = DataType::Decimal128(3, 2);
11581        assert!(can_cast_types(&input_type, &output_type));
11582
11583        let options = CastOptions {
11584            safe: false,
11585            ..Default::default()
11586        };
11587        let result = cast_with_options(&array, &output_type, &options);
11588        assert_eq!(
11589            result.unwrap().as_primitive::<Decimal128Type>().value(0),
11590            520
11591        );
11592
11593        // Cast 0 of decimal(3, 0) type to decimal(2, 0)
11594        assert_eq!(
11595            &cast(
11596                &create_decimal128_array(vec![Some(0)], 3, 0).unwrap(),
11597                &DataType::Decimal128(2, 0)
11598            )
11599            .unwrap(),
11600            &(Arc::new(create_decimal128_array(vec![Some(0)], 2, 0).unwrap()) as ArrayRef)
11601        );
11602    }
11603
11604    #[test]
11605    fn test_decimal_to_decimal_throw_error_on_precision_overflow_lower_scale() {
11606        let array = vec![Some(123456789)];
11607        let array = create_decimal128_array(array, 24, 4).unwrap();
11608        let input_type = DataType::Decimal128(24, 4);
11609        let output_type = DataType::Decimal128(6, 2);
11610        assert!(can_cast_types(&input_type, &output_type));
11611
11612        let options = CastOptions {
11613            safe: false,
11614            ..Default::default()
11615        };
11616        let result = cast_with_options(&array, &output_type, &options);
11617        assert_eq!(
11618            result.unwrap_err().to_string(),
11619            "Invalid argument error: 12345.68 is too large to store in a Decimal128 of precision 6. Max is 9999.99"
11620        );
11621    }
11622
11623    #[test]
11624    fn test_decimal_to_decimal_throw_error_on_precision_overflow_greater_scale() {
11625        let array = vec![Some(123456789)];
11626        let array = create_decimal128_array(array, 24, 2).unwrap();
11627        let input_type = DataType::Decimal128(24, 2);
11628        let output_type = DataType::Decimal128(6, 3);
11629        assert!(can_cast_types(&input_type, &output_type));
11630
11631        let options = CastOptions {
11632            safe: false,
11633            ..Default::default()
11634        };
11635        let result = cast_with_options(&array, &output_type, &options);
11636        assert_eq!(
11637            result.unwrap_err().to_string(),
11638            "Invalid argument error: 1234567.890 is too large to store in a Decimal128 of precision 6. Max is 999.999"
11639        );
11640    }
11641
11642    #[test]
11643    fn test_decimal_to_decimal_throw_error_on_precision_overflow_diff_type() {
11644        let array = vec![Some(123456789)];
11645        let array = create_decimal128_array(array, 24, 2).unwrap();
11646        let input_type = DataType::Decimal128(24, 2);
11647        let output_type = DataType::Decimal256(6, 2);
11648        assert!(can_cast_types(&input_type, &output_type));
11649
11650        let options = CastOptions {
11651            safe: false,
11652            ..Default::default()
11653        };
11654        let result = cast_with_options(&array, &output_type, &options).unwrap_err();
11655        assert_eq!(
11656            result.to_string(),
11657            "Invalid argument error: 1234567.89 is too large to store in a Decimal256 of precision 6. Max is 9999.99"
11658        );
11659    }
11660
11661    #[test]
11662    fn test_first_none() {
11663        let array = Arc::new(ListArray::from_iter_primitive::<Int64Type, _, _>(vec![
11664            None,
11665            Some(vec![Some(1), Some(2)]),
11666        ])) as ArrayRef;
11667        let data_type =
11668            DataType::FixedSizeList(FieldRef::new(Field::new("item", DataType::Int64, true)), 2);
11669        let opt = CastOptions::default();
11670        let r = cast_with_options(&array, &data_type, &opt).unwrap();
11671
11672        let fixed_array = Arc::new(FixedSizeListArray::from_iter_primitive::<Int64Type, _, _>(
11673            vec![None, Some(vec![Some(1), Some(2)])],
11674            2,
11675        )) as ArrayRef;
11676        assert_eq!(*fixed_array, *r);
11677    }
11678
11679    #[test]
11680    fn test_first_last_none() {
11681        let array = Arc::new(ListArray::from_iter_primitive::<Int64Type, _, _>(vec![
11682            None,
11683            Some(vec![Some(1), Some(2)]),
11684            None,
11685        ])) as ArrayRef;
11686        let data_type =
11687            DataType::FixedSizeList(FieldRef::new(Field::new("item", DataType::Int64, true)), 2);
11688        let opt = CastOptions::default();
11689        let r = cast_with_options(&array, &data_type, &opt).unwrap();
11690
11691        let fixed_array = Arc::new(FixedSizeListArray::from_iter_primitive::<Int64Type, _, _>(
11692            vec![None, Some(vec![Some(1), Some(2)]), None],
11693            2,
11694        )) as ArrayRef;
11695        assert_eq!(*fixed_array, *r);
11696    }
11697
11698    #[test]
11699    fn test_cast_decimal_error_output() {
11700        let array = Int64Array::from(vec![1]);
11701        let error = cast_with_options(
11702            &array,
11703            &DataType::Decimal32(1, 1),
11704            &CastOptions {
11705                safe: false,
11706                format_options: FormatOptions::default(),
11707            },
11708        )
11709        .unwrap_err();
11710        assert_eq!(
11711            error.to_string(),
11712            "Invalid argument error: 1.0 is too large to store in a Decimal32 of precision 1. Max is 0.9"
11713        );
11714
11715        let array = Int64Array::from(vec![-1]);
11716        let error = cast_with_options(
11717            &array,
11718            &DataType::Decimal32(1, 1),
11719            &CastOptions {
11720                safe: false,
11721                format_options: FormatOptions::default(),
11722            },
11723        )
11724        .unwrap_err();
11725        assert_eq!(
11726            error.to_string(),
11727            "Invalid argument error: -1.0 is too small to store in a Decimal32 of precision 1. Min is -0.9"
11728        );
11729    }
11730
11731    #[test]
11732    fn test_run_end_encoded_to_primitive() {
11733        // Create a RunEndEncoded array: [1, 1, 2, 2, 2, 3]
11734        let run_ends = Int32Array::from(vec![2, 5, 6]);
11735        let values = Int32Array::from(vec![1, 2, 3]);
11736        let run_array = RunArray::<Int32Type>::try_new(&run_ends, &values).unwrap();
11737        let array_ref = Arc::new(run_array) as ArrayRef;
11738        // Cast to Int64
11739        let cast_result = cast(&array_ref, &DataType::Int64).unwrap();
11740        // Verify the result is a RunArray with Int64 values
11741        let result_run_array = cast_result.as_any().downcast_ref::<Int64Array>().unwrap();
11742        assert_eq!(
11743            result_run_array.values(),
11744            &[1i64, 1i64, 2i64, 2i64, 2i64, 3i64]
11745        );
11746    }
11747
11748    #[test]
11749    #[should_panic = "assertion `left == right` failed\n  left: ScalarBuffer([1, 1, 2])\n right: [2, 2, 3]"]
11750    // TODO: fix cast of RunArrays to account for sliced RunArray's
11751    // https://github.com/apache/arrow-rs/issues/9018
11752    fn test_sliced_run_end_encoded_to_primitive() {
11753        let run_ends = Int32Array::from(vec![2, 5, 6]);
11754        let values = Int32Array::from(vec![1, 2, 3]);
11755        // [1, 1, 2, 2, 2, 3]
11756        let run_array = RunArray::<Int32Type>::try_new(&run_ends, &values).unwrap();
11757        let run_array = run_array.slice(3, 3); // [2, 2, 3]
11758        let array_ref = Arc::new(run_array) as ArrayRef;
11759
11760        let cast_result = cast(&array_ref, &DataType::Int64).unwrap();
11761        let result_run_array = cast_result.as_primitive::<Int64Type>();
11762        assert_eq!(result_run_array.values(), &[2, 2, 3]);
11763    }
11764
11765    #[test]
11766    fn test_run_end_encoded_to_string() {
11767        let run_ends = Int32Array::from(vec![2, 3, 5]);
11768        let values = Int32Array::from(vec![10, 20, 30]);
11769        let run_array = RunArray::<Int32Type>::try_new(&run_ends, &values).unwrap();
11770        let array_ref = Arc::new(run_array) as ArrayRef;
11771
11772        // Cast to String
11773        let cast_result = cast(&array_ref, &DataType::Utf8).unwrap();
11774
11775        // Verify the result is a RunArray with String values
11776        let result_array = cast_result.as_any().downcast_ref::<StringArray>().unwrap();
11777        // Check that values are correct
11778        assert_eq!(result_array.value(0), "10");
11779        assert_eq!(result_array.value(1), "10");
11780        assert_eq!(result_array.value(2), "20");
11781    }
11782
11783    #[test]
11784    fn test_primitive_to_run_end_encoded() {
11785        // Create an Int32 array with repeated values: [1, 1, 2, 2, 2, 3]
11786        let source_array = Int32Array::from(vec![1, 1, 2, 2, 2, 3]);
11787        let array_ref = Arc::new(source_array) as ArrayRef;
11788
11789        // Cast to RunEndEncoded<Int32, Int32>
11790        let target_type = DataType::RunEndEncoded(
11791            Arc::new(Field::new("run_ends", DataType::Int32, false)),
11792            Arc::new(Field::new("values", DataType::Int32, true)),
11793        );
11794        let cast_result = cast(&array_ref, &target_type).unwrap();
11795
11796        // Verify the result is a RunArray
11797        let result_run_array = cast_result
11798            .as_any()
11799            .downcast_ref::<RunArray<Int32Type>>()
11800            .unwrap();
11801
11802        // Check run structure: runs should end at positions [2, 5, 6]
11803        assert_eq!(result_run_array.run_ends().values(), &[2, 5, 6]);
11804
11805        // Check values: should be [1, 2, 3]
11806        let values_array = result_run_array.values().as_primitive::<Int32Type>();
11807        assert_eq!(values_array.values(), &[1, 2, 3]);
11808    }
11809
11810    #[test]
11811    fn test_primitive_to_run_end_encoded_with_nulls() {
11812        let source_array = Int32Array::from(vec![
11813            Some(1),
11814            Some(1),
11815            None,
11816            None,
11817            Some(2),
11818            Some(2),
11819            Some(3),
11820            Some(3),
11821            None,
11822            None,
11823            Some(4),
11824            Some(4),
11825            Some(5),
11826            Some(5),
11827            None,
11828            None,
11829        ]);
11830        let array_ref = Arc::new(source_array) as ArrayRef;
11831        let target_type = DataType::RunEndEncoded(
11832            Arc::new(Field::new("run_ends", DataType::Int32, false)),
11833            Arc::new(Field::new("values", DataType::Int32, true)),
11834        );
11835        let cast_result = cast(&array_ref, &target_type).unwrap();
11836        let result_run_array = cast_result
11837            .as_any()
11838            .downcast_ref::<RunArray<Int32Type>>()
11839            .unwrap();
11840        assert_eq!(
11841            result_run_array.run_ends().values(),
11842            &[2, 4, 6, 8, 10, 12, 14, 16]
11843        );
11844        assert_eq!(
11845            result_run_array
11846                .values()
11847                .as_primitive::<Int32Type>()
11848                .values(),
11849            &[1, 0, 2, 3, 0, 4, 5, 0]
11850        );
11851        assert_eq!(result_run_array.values().null_count(), 3);
11852    }
11853
11854    #[test]
11855    fn test_primitive_to_run_end_encoded_with_nulls_consecutive() {
11856        let source_array = Int64Array::from(vec![
11857            Some(1),
11858            Some(1),
11859            None,
11860            None,
11861            None,
11862            None,
11863            None,
11864            None,
11865            None,
11866            None,
11867            Some(4),
11868            Some(20),
11869            Some(500),
11870            Some(500),
11871            None,
11872            None,
11873        ]);
11874        let array_ref = Arc::new(source_array) as ArrayRef;
11875        let target_type = DataType::RunEndEncoded(
11876            Arc::new(Field::new("run_ends", DataType::Int16, false)),
11877            Arc::new(Field::new("values", DataType::Int64, true)),
11878        );
11879        let cast_result = cast(&array_ref, &target_type).unwrap();
11880        let result_run_array = cast_result
11881            .as_any()
11882            .downcast_ref::<RunArray<Int16Type>>()
11883            .unwrap();
11884        assert_eq!(
11885            result_run_array.run_ends().values(),
11886            &[2, 10, 11, 12, 14, 16]
11887        );
11888        assert_eq!(
11889            result_run_array
11890                .values()
11891                .as_primitive::<Int64Type>()
11892                .values(),
11893            &[1, 0, 4, 20, 500, 0]
11894        );
11895        assert_eq!(result_run_array.values().null_count(), 2);
11896    }
11897
11898    #[test]
11899    fn test_string_to_run_end_encoded() {
11900        // Create a String array with repeated values: ["a", "a", "b", "c", "c"]
11901        let source_array = StringArray::from(vec!["a", "a", "b", "c", "c"]);
11902        let array_ref = Arc::new(source_array) as ArrayRef;
11903
11904        // Cast to RunEndEncoded<Int32, String>
11905        let target_type = DataType::RunEndEncoded(
11906            Arc::new(Field::new("run_ends", DataType::Int32, false)),
11907            Arc::new(Field::new("values", DataType::Utf8, true)),
11908        );
11909        let cast_result = cast(&array_ref, &target_type).unwrap();
11910
11911        // Verify the result is a RunArray
11912        let result_run_array = cast_result
11913            .as_any()
11914            .downcast_ref::<RunArray<Int32Type>>()
11915            .unwrap();
11916
11917        // Check run structure: runs should end at positions [2, 3, 5]
11918        assert_eq!(result_run_array.run_ends().values(), &[2, 3, 5]);
11919
11920        // Check values: should be ["a", "b", "c"]
11921        let values_array = result_run_array.values().as_string::<i32>();
11922        assert_eq!(values_array.value(0), "a");
11923        assert_eq!(values_array.value(1), "b");
11924        assert_eq!(values_array.value(2), "c");
11925    }
11926
11927    #[test]
11928    fn test_empty_array_to_run_end_encoded() {
11929        // Create an empty Int32 array
11930        let source_array = Int32Array::from(Vec::<i32>::new());
11931        let array_ref = Arc::new(source_array) as ArrayRef;
11932
11933        // Cast to RunEndEncoded<Int32, Int32>
11934        let target_type = DataType::RunEndEncoded(
11935            Arc::new(Field::new("run_ends", DataType::Int32, false)),
11936            Arc::new(Field::new("values", DataType::Int32, true)),
11937        );
11938        let cast_result = cast(&array_ref, &target_type).unwrap();
11939
11940        // Verify the result is an empty RunArray
11941        let result_run_array = cast_result
11942            .as_any()
11943            .downcast_ref::<RunArray<Int32Type>>()
11944            .unwrap();
11945
11946        // Check that both run_ends and values are empty
11947        assert_eq!(result_run_array.run_ends().len(), 0);
11948        assert_eq!(result_run_array.values().len(), 0);
11949    }
11950
11951    #[test]
11952    fn test_run_end_encoded_with_nulls() {
11953        // Create a RunEndEncoded array with nulls: [1, 1, null, 2, 2]
11954        let run_ends = Int32Array::from(vec![2, 3, 5]);
11955        let values = Int32Array::from(vec![Some(1), None, Some(2)]);
11956        let run_array = RunArray::<Int32Type>::try_new(&run_ends, &values).unwrap();
11957        let array_ref = Arc::new(run_array) as ArrayRef;
11958
11959        // Cast to String
11960        let cast_result = cast(&array_ref, &DataType::Utf8).unwrap();
11961
11962        // Verify the result preserves nulls
11963        let result_run_array = cast_result.as_any().downcast_ref::<StringArray>().unwrap();
11964        assert_eq!(result_run_array.value(0), "1");
11965        assert!(result_run_array.is_null(2));
11966        assert_eq!(result_run_array.value(4), "2");
11967    }
11968
11969    #[test]
11970    fn test_different_index_types() {
11971        // Test with Int16 index type
11972        let source_array = Int32Array::from(vec![1, 1, 2, 3, 3]);
11973        let array_ref = Arc::new(source_array) as ArrayRef;
11974
11975        let target_type = DataType::RunEndEncoded(
11976            Arc::new(Field::new("run_ends", DataType::Int16, false)),
11977            Arc::new(Field::new("values", DataType::Int32, true)),
11978        );
11979        let cast_result = cast(&array_ref, &target_type).unwrap();
11980        assert_eq!(cast_result.data_type(), &target_type);
11981
11982        // Verify the cast worked correctly: values are [1, 2, 3]
11983        // and run-ends are [2, 3, 5]
11984        let run_array = cast_result
11985            .as_any()
11986            .downcast_ref::<RunArray<Int16Type>>()
11987            .unwrap();
11988        assert_eq!(run_array.values().as_primitive::<Int32Type>().value(0), 1);
11989        assert_eq!(run_array.values().as_primitive::<Int32Type>().value(1), 2);
11990        assert_eq!(run_array.values().as_primitive::<Int32Type>().value(2), 3);
11991        assert_eq!(run_array.run_ends().values(), &[2i16, 3i16, 5i16]);
11992
11993        // Test again with Int64 index type
11994        let target_type = DataType::RunEndEncoded(
11995            Arc::new(Field::new("run_ends", DataType::Int64, false)),
11996            Arc::new(Field::new("values", DataType::Int32, true)),
11997        );
11998        let cast_result = cast(&array_ref, &target_type).unwrap();
11999        assert_eq!(cast_result.data_type(), &target_type);
12000
12001        // Verify the cast worked correctly: values are [1, 2, 3]
12002        // and run-ends are [2, 3, 5]
12003        let run_array = cast_result
12004            .as_any()
12005            .downcast_ref::<RunArray<Int64Type>>()
12006            .unwrap();
12007        assert_eq!(run_array.values().as_primitive::<Int32Type>().value(0), 1);
12008        assert_eq!(run_array.values().as_primitive::<Int32Type>().value(1), 2);
12009        assert_eq!(run_array.values().as_primitive::<Int32Type>().value(2), 3);
12010        assert_eq!(run_array.run_ends().values(), &[2i64, 3i64, 5i64]);
12011    }
12012
12013    #[test]
12014    fn test_unsupported_cast_to_run_end_encoded() {
12015        // Create a Struct array - complex nested type that might not be supported
12016        let field = Field::new("item", DataType::Int32, false);
12017        let struct_array = StructArray::from(vec![(
12018            Arc::new(field),
12019            Arc::new(Int32Array::from(vec![1, 2, 3])) as ArrayRef,
12020        )]);
12021        let array_ref = Arc::new(struct_array) as ArrayRef;
12022
12023        // This should fail because:
12024        // 1. The target type is not RunEndEncoded
12025        // 2. The target type is not supported for casting from StructArray
12026        let cast_result = cast(&array_ref, &DataType::FixedSizeBinary(10));
12027
12028        // Expect this to fail
12029        assert!(cast_result.is_err());
12030    }
12031
12032    /// Test casting RunEndEncoded<Int64, String> to RunEndEncoded<Int16, String> should fail
12033    #[test]
12034    fn test_cast_run_end_encoded_int64_to_int16_should_fail() {
12035        // Construct a valid REE array with Int64 run-ends
12036        let run_ends = Int64Array::from(vec![100_000, 400_000, 700_000]); // values too large for Int16
12037        let values = StringArray::from(vec!["a", "b", "c"]);
12038
12039        let ree_array = RunArray::<Int64Type>::try_new(&run_ends, &values).unwrap();
12040        let array_ref = Arc::new(ree_array) as ArrayRef;
12041
12042        // Attempt to cast to RunEndEncoded<Int16, Utf8>
12043        let target_type = DataType::RunEndEncoded(
12044            Arc::new(Field::new("run_ends", DataType::Int16, false)),
12045            Arc::new(Field::new("values", DataType::Utf8, true)),
12046        );
12047        let cast_options = CastOptions {
12048            safe: false, // This should make it fail instead of returning nulls
12049            format_options: FormatOptions::default(),
12050        };
12051
12052        // This should fail due to run-end overflow
12053        let result: Result<Arc<dyn Array + 'static>, ArrowError> =
12054            cast_with_options(&array_ref, &target_type, &cast_options);
12055
12056        let e = result.expect_err("Cast should have failed but succeeded");
12057        assert!(
12058            e.to_string()
12059                .contains("Cast error: Can't cast value 100000 to type Int16")
12060        );
12061    }
12062
12063    #[test]
12064    fn test_cast_run_end_encoded_int64_to_int16_with_safe_should_fail_with_null_invalid_error() {
12065        // Construct a valid REE array with Int64 run-ends
12066        let run_ends = Int64Array::from(vec![100_000, 400_000, 700_000]); // values too large for Int16
12067        let values = StringArray::from(vec!["a", "b", "c"]);
12068
12069        let ree_array = RunArray::<Int64Type>::try_new(&run_ends, &values).unwrap();
12070        let array_ref = Arc::new(ree_array) as ArrayRef;
12071
12072        // Attempt to cast to RunEndEncoded<Int16, Utf8>
12073        let target_type = DataType::RunEndEncoded(
12074            Arc::new(Field::new("run_ends", DataType::Int16, false)),
12075            Arc::new(Field::new("values", DataType::Utf8, true)),
12076        );
12077        let cast_options = CastOptions {
12078            safe: true,
12079            format_options: FormatOptions::default(),
12080        };
12081
12082        // This fails even though safe is true because the run_ends array has null values
12083        let result: Result<Arc<dyn Array + 'static>, ArrowError> =
12084            cast_with_options(&array_ref, &target_type, &cast_options);
12085        let e = result.expect_err("Cast should have failed but succeeded");
12086        assert!(
12087            e.to_string()
12088                .contains("Invalid argument error: Found null values in run_ends array. The run_ends array should not have null values.")
12089        );
12090    }
12091
12092    /// Test casting RunEndEncoded<Int16, String> to RunEndEncoded<Int64, String> should succeed
12093    #[test]
12094    fn test_cast_run_end_encoded_int16_to_int64_should_succeed() {
12095        // Construct a valid REE array with Int16 run-ends
12096        let run_ends = Int16Array::from(vec![2, 5, 8]); // values that fit in Int16
12097        let values = StringArray::from(vec!["a", "b", "c"]);
12098
12099        let ree_array = RunArray::<Int16Type>::try_new(&run_ends, &values).unwrap();
12100        let array_ref = Arc::new(ree_array) as ArrayRef;
12101
12102        // Attempt to cast to RunEndEncoded<Int64, Utf8> (upcast should succeed)
12103        let target_type = DataType::RunEndEncoded(
12104            Arc::new(Field::new("run_ends", DataType::Int64, false)),
12105            Arc::new(Field::new("values", DataType::Utf8, true)),
12106        );
12107        let cast_options = CastOptions {
12108            safe: false,
12109            format_options: FormatOptions::default(),
12110        };
12111
12112        // This should succeed due to valid upcast
12113        let result: Result<Arc<dyn Array + 'static>, ArrowError> =
12114            cast_with_options(&array_ref, &target_type, &cast_options);
12115
12116        let array_ref = result.expect("Cast should have succeeded but failed");
12117        // Downcast to RunArray<Int64Type>
12118        let run_array = array_ref
12119            .as_any()
12120            .downcast_ref::<RunArray<Int64Type>>()
12121            .unwrap();
12122
12123        // Verify the cast worked correctly
12124        // Assert the values were cast correctly
12125        assert_eq!(run_array.run_ends().values(), &[2i64, 5i64, 8i64]);
12126        assert_eq!(run_array.values().as_string::<i32>().value(0), "a");
12127        assert_eq!(run_array.values().as_string::<i32>().value(1), "b");
12128        assert_eq!(run_array.values().as_string::<i32>().value(2), "c");
12129    }
12130
12131    #[test]
12132    fn test_cast_run_end_encoded_dictionary_to_run_end_encoded() {
12133        // Construct a valid dictionary encoded array
12134        let values = StringArray::from_iter([Some("a"), Some("b"), Some("c")]);
12135        let keys = UInt64Array::from_iter(vec![1, 1, 1, 0, 0, 0, 2, 2, 2]);
12136        let array_ref = Arc::new(DictionaryArray::new(keys, Arc::new(values))) as ArrayRef;
12137
12138        // Attempt to cast to RunEndEncoded<Int64, Utf8>
12139        let target_type = DataType::RunEndEncoded(
12140            Arc::new(Field::new("run_ends", DataType::Int64, false)),
12141            Arc::new(Field::new("values", DataType::Utf8, true)),
12142        );
12143        let cast_options = CastOptions {
12144            safe: false,
12145            format_options: FormatOptions::default(),
12146        };
12147
12148        // This should succeed
12149        let result = cast_with_options(&array_ref, &target_type, &cast_options)
12150            .expect("Cast should have succeeded but failed");
12151
12152        // Verify the cast worked correctly
12153        // Assert the values were cast correctly
12154        let run_array = result
12155            .as_any()
12156            .downcast_ref::<RunArray<Int64Type>>()
12157            .unwrap();
12158        assert_eq!(run_array.values().as_string::<i32>().value(0), "b");
12159        assert_eq!(run_array.values().as_string::<i32>().value(1), "a");
12160        assert_eq!(run_array.values().as_string::<i32>().value(2), "c");
12161
12162        // Verify the run-ends were cast correctly (run ends at 3, 6, 9)
12163        assert_eq!(run_array.run_ends().values(), &[3i64, 6i64, 9i64]);
12164    }
12165
12166    fn int32_list_values() -> Vec<Option<Vec<Option<i32>>>> {
12167        vec![
12168            Some(vec![Some(1), Some(2), Some(3)]),
12169            Some(vec![Some(4), Some(5), Some(6)]),
12170            None,
12171            Some(vec![Some(7), Some(8), Some(9)]),
12172            Some(vec![None, Some(10)]),
12173        ]
12174    }
12175
12176    #[test]
12177    fn test_cast_list_view_to_list() {
12178        let list_view = ListViewArray::from_iter_primitive::<Int32Type, _, _>(int32_list_values());
12179        let target_type = DataType::List(Arc::new(Field::new("item", DataType::Int32, true)));
12180        assert!(can_cast_types(list_view.data_type(), &target_type));
12181        let cast_result = cast(&list_view, &target_type).unwrap();
12182        let got_list = cast_result.as_any().downcast_ref::<ListArray>().unwrap();
12183        let expected_list = ListArray::from_iter_primitive::<Int32Type, _, _>(int32_list_values());
12184        assert_eq!(got_list, &expected_list);
12185    }
12186
12187    #[test]
12188    fn test_cast_list_to_list_view() {
12189        let list = ListArray::from_iter_primitive::<Int32Type, _, _>(int32_list_values());
12190        let target_type = DataType::ListView(Arc::new(Field::new("item", DataType::Int32, true)));
12191        assert!(can_cast_types(list.data_type(), &target_type));
12192        let cast_result = cast(&list, &target_type).unwrap();
12193
12194        let got_list_view = cast_result
12195            .as_any()
12196            .downcast_ref::<ListViewArray>()
12197            .unwrap();
12198        let expected_list_view =
12199            ListViewArray::from_iter_primitive::<Int32Type, _, _>(int32_list_values());
12200        assert_eq!(got_list_view, &expected_list_view);
12201    }
12202
12203    #[test]
12204    fn test_cast_large_list_view_to_large_list() {
12205        let list_view =
12206            LargeListViewArray::from_iter_primitive::<Int32Type, _, _>(int32_list_values());
12207        let target_type = DataType::LargeList(Arc::new(Field::new("item", DataType::Int32, true)));
12208        assert!(can_cast_types(list_view.data_type(), &target_type));
12209        let cast_result = cast(&list_view, &target_type).unwrap();
12210        let got_list = cast_result
12211            .as_any()
12212            .downcast_ref::<LargeListArray>()
12213            .unwrap();
12214
12215        let expected_list =
12216            LargeListArray::from_iter_primitive::<Int32Type, _, _>(int32_list_values());
12217        assert_eq!(got_list, &expected_list);
12218    }
12219
12220    #[test]
12221    fn test_cast_large_list_to_large_list_view() {
12222        let list = LargeListArray::from_iter_primitive::<Int32Type, _, _>(int32_list_values());
12223        let target_type =
12224            DataType::LargeListView(Arc::new(Field::new("item", DataType::Int32, true)));
12225        assert!(can_cast_types(list.data_type(), &target_type));
12226        let cast_result = cast(&list, &target_type).unwrap();
12227
12228        let got_list_view = cast_result
12229            .as_any()
12230            .downcast_ref::<LargeListViewArray>()
12231            .unwrap();
12232        let expected_list_view =
12233            LargeListViewArray::from_iter_primitive::<Int32Type, _, _>(int32_list_values());
12234        assert_eq!(got_list_view, &expected_list_view);
12235    }
12236
12237    #[test]
12238    fn test_cast_list_view_to_list_out_of_order() {
12239        let list_view = ListViewArray::new(
12240            Arc::new(Field::new("item", DataType::Int32, true)),
12241            ScalarBuffer::from(vec![0, 6, 3]),
12242            ScalarBuffer::from(vec![3, 3, 3]),
12243            Arc::new(Int32Array::from(vec![1, 2, 3, 4, 5, 6, 7, 8, 9])),
12244            None,
12245        );
12246        let target_type = DataType::List(Arc::new(Field::new("item", DataType::Int32, true)));
12247        assert!(can_cast_types(list_view.data_type(), &target_type));
12248        let cast_result = cast(&list_view, &target_type).unwrap();
12249        let got_list = cast_result.as_any().downcast_ref::<ListArray>().unwrap();
12250        let expected_list = ListArray::from_iter_primitive::<Int32Type, _, _>(vec![
12251            Some(vec![Some(1), Some(2), Some(3)]),
12252            Some(vec![Some(7), Some(8), Some(9)]),
12253            Some(vec![Some(4), Some(5), Some(6)]),
12254        ]);
12255        assert_eq!(got_list, &expected_list);
12256    }
12257
12258    #[test]
12259    fn test_cast_list_view_to_list_overlapping() {
12260        let list_view = ListViewArray::new(
12261            Arc::new(Field::new("item", DataType::Int32, true)),
12262            ScalarBuffer::from(vec![0, 0]),
12263            ScalarBuffer::from(vec![1, 2]),
12264            Arc::new(Int32Array::from(vec![1, 2])),
12265            None,
12266        );
12267        let target_type = DataType::List(Arc::new(Field::new("item", DataType::Int32, true)));
12268        assert!(can_cast_types(list_view.data_type(), &target_type));
12269        let cast_result = cast(&list_view, &target_type).unwrap();
12270        let got_list = cast_result.as_any().downcast_ref::<ListArray>().unwrap();
12271        let expected_list = ListArray::from_iter_primitive::<Int32Type, _, _>(vec![
12272            Some(vec![Some(1)]),
12273            Some(vec![Some(1), Some(2)]),
12274        ]);
12275        assert_eq!(got_list, &expected_list);
12276    }
12277
12278    #[test]
12279    fn test_cast_list_view_to_list_empty() {
12280        let values: Vec<Option<Vec<Option<i32>>>> = vec![];
12281        let list_view = ListViewArray::from_iter_primitive::<Int32Type, _, _>(values.clone());
12282        let target_type = DataType::List(Arc::new(Field::new("item", DataType::Int32, true)));
12283        assert!(can_cast_types(list_view.data_type(), &target_type));
12284        let cast_result = cast(&list_view, &target_type).unwrap();
12285        let got_list = cast_result.as_any().downcast_ref::<ListArray>().unwrap();
12286        let expected_list = ListArray::from_iter_primitive::<Int32Type, _, _>(values);
12287        assert_eq!(got_list, &expected_list);
12288    }
12289
12290    #[test]
12291    fn test_cast_list_view_to_list_different_inner_type() {
12292        let values = int32_list_values();
12293        let list_view = ListViewArray::from_iter_primitive::<Int32Type, _, _>(values.clone());
12294        let target_type = DataType::List(Arc::new(Field::new("item", DataType::Int64, true)));
12295        assert!(can_cast_types(list_view.data_type(), &target_type));
12296        let cast_result = cast(&list_view, &target_type).unwrap();
12297        let got_list = cast_result.as_any().downcast_ref::<ListArray>().unwrap();
12298
12299        let expected_list =
12300            ListArray::from_iter_primitive::<Int64Type, _, _>(values.into_iter().map(|list| {
12301                list.map(|list| {
12302                    list.into_iter()
12303                        .map(|v| v.map(|v| v as i64))
12304                        .collect::<Vec<_>>()
12305                })
12306            }));
12307        assert_eq!(got_list, &expected_list);
12308    }
12309
12310    #[test]
12311    fn test_cast_list_view_to_list_out_of_order_with_nulls() {
12312        let list_view = ListViewArray::new(
12313            Arc::new(Field::new("item", DataType::Int32, true)),
12314            ScalarBuffer::from(vec![0, 6, 3]),
12315            ScalarBuffer::from(vec![3, 3, 3]),
12316            Arc::new(Int32Array::from(vec![1, 2, 3, 4, 5, 6, 7, 8, 9])),
12317            Some(NullBuffer::from(vec![false, true, false])),
12318        );
12319        let target_type = DataType::List(Arc::new(Field::new("item", DataType::Int32, true)));
12320        assert!(can_cast_types(list_view.data_type(), &target_type));
12321        let cast_result = cast(&list_view, &target_type).unwrap();
12322        let got_list = cast_result.as_any().downcast_ref::<ListArray>().unwrap();
12323        let expected_list = ListArray::new(
12324            Arc::new(Field::new("item", DataType::Int32, true)),
12325            OffsetBuffer::from_lengths([3, 3, 3]),
12326            Arc::new(Int32Array::from(vec![1, 2, 3, 7, 8, 9, 4, 5, 6])),
12327            Some(NullBuffer::from(vec![false, true, false])),
12328        );
12329        assert_eq!(got_list, &expected_list);
12330    }
12331
12332    #[test]
12333    fn test_cast_list_view_to_large_list_view() {
12334        let list_view = ListViewArray::from_iter_primitive::<Int32Type, _, _>(int32_list_values());
12335        let target_type =
12336            DataType::LargeListView(Arc::new(Field::new("item", DataType::Int32, true)));
12337        assert!(can_cast_types(list_view.data_type(), &target_type));
12338        let cast_result = cast(&list_view, &target_type).unwrap();
12339        let got = cast_result
12340            .as_any()
12341            .downcast_ref::<LargeListViewArray>()
12342            .unwrap();
12343
12344        let expected =
12345            LargeListViewArray::from_iter_primitive::<Int32Type, _, _>(int32_list_values());
12346        assert_eq!(got, &expected);
12347    }
12348
12349    #[test]
12350    fn test_cast_large_list_view_to_list_view() {
12351        let list_view =
12352            LargeListViewArray::from_iter_primitive::<Int32Type, _, _>(int32_list_values());
12353        let target_type = DataType::ListView(Arc::new(Field::new("item", DataType::Int32, true)));
12354        assert!(can_cast_types(list_view.data_type(), &target_type));
12355        let cast_result = cast(&list_view, &target_type).unwrap();
12356        let got = cast_result
12357            .as_any()
12358            .downcast_ref::<ListViewArray>()
12359            .unwrap();
12360
12361        let expected = ListViewArray::from_iter_primitive::<Int32Type, _, _>(int32_list_values());
12362        assert_eq!(got, &expected);
12363    }
12364
12365    #[test]
12366    fn test_cast_time32_second_to_int64() {
12367        let array = Time32SecondArray::from(vec![1000, 2000, 3000]);
12368        let array = Arc::new(array) as Arc<dyn Array>;
12369        let to_type = DataType::Int64;
12370        let cast_options = CastOptions::default();
12371
12372        assert!(can_cast_types(array.data_type(), &to_type));
12373
12374        let result = cast_with_options(&array, &to_type, &cast_options);
12375        assert!(
12376            result.is_ok(),
12377            "Failed to cast Time32(Second) to Int64: {:?}",
12378            result.err()
12379        );
12380
12381        let cast_array = result.unwrap();
12382        let cast_array = cast_array.as_any().downcast_ref::<Int64Array>().unwrap();
12383
12384        assert_eq!(cast_array.value(0), 1000);
12385        assert_eq!(cast_array.value(1), 2000);
12386        assert_eq!(cast_array.value(2), 3000);
12387    }
12388
12389    #[test]
12390    fn test_cast_time32_millisecond_to_int64() {
12391        let array = Time32MillisecondArray::from(vec![1000, 2000, 3000]);
12392        let array = Arc::new(array) as Arc<dyn Array>;
12393        let to_type = DataType::Int64;
12394        let cast_options = CastOptions::default();
12395
12396        assert!(can_cast_types(array.data_type(), &to_type));
12397
12398        let result = cast_with_options(&array, &to_type, &cast_options);
12399        assert!(
12400            result.is_ok(),
12401            "Failed to cast Time32(Millisecond) to Int64: {:?}",
12402            result.err()
12403        );
12404
12405        let cast_array = result.unwrap();
12406        let cast_array = cast_array.as_any().downcast_ref::<Int64Array>().unwrap();
12407
12408        assert_eq!(cast_array.value(0), 1000);
12409        assert_eq!(cast_array.value(1), 2000);
12410        assert_eq!(cast_array.value(2), 3000);
12411    }
12412
12413    #[test]
12414    fn test_cast_string_to_time32_second_to_int64() {
12415        // Mimic: select arrow_cast('03:12:44'::time, 'Time32(Second)')::bigint;
12416        // raised in https://github.com/apache/datafusion/issues/19036
12417        let array = StringArray::from(vec!["03:12:44"]);
12418        let array = Arc::new(array) as Arc<dyn Array>;
12419        let cast_options = CastOptions::default();
12420
12421        // 1. Cast String to Time32(Second)
12422        let time32_type = DataType::Time32(TimeUnit::Second);
12423        let time32_array = cast_with_options(&array, &time32_type, &cast_options).unwrap();
12424
12425        // 2. Cast Time32(Second) to Int64
12426        let int64_type = DataType::Int64;
12427        assert!(can_cast_types(time32_array.data_type(), &int64_type));
12428
12429        let result = cast_with_options(&time32_array, &int64_type, &cast_options);
12430
12431        assert!(
12432            result.is_ok(),
12433            "Failed to cast Time32(Second) to Int64: {:?}",
12434            result.err()
12435        );
12436
12437        let cast_array = result.unwrap();
12438        let cast_array = cast_array.as_any().downcast_ref::<Int64Array>().unwrap();
12439
12440        // 03:12:44 = 3*3600 + 12*60 + 44 = 10800 + 720 + 44 = 11564
12441        assert_eq!(cast_array.value(0), 11564);
12442    }
12443    #[test]
12444    fn test_string_dicts_to_binary_view() {
12445        let expected = BinaryViewArray::from_iter(vec![
12446            VIEW_TEST_DATA[1],
12447            VIEW_TEST_DATA[0],
12448            None,
12449            VIEW_TEST_DATA[3],
12450            None,
12451            VIEW_TEST_DATA[1],
12452            VIEW_TEST_DATA[4],
12453        ]);
12454
12455        let values_arrays: [ArrayRef; _] = [
12456            Arc::new(StringArray::from_iter(VIEW_TEST_DATA)),
12457            Arc::new(StringViewArray::from_iter(VIEW_TEST_DATA)),
12458            Arc::new(LargeStringArray::from_iter(VIEW_TEST_DATA)),
12459        ];
12460        for values in values_arrays {
12461            let keys =
12462                Int8Array::from_iter([Some(1), Some(0), None, Some(3), None, Some(1), Some(4)]);
12463            let string_dict_array =
12464                DictionaryArray::<Int8Type>::try_new(keys, Arc::new(values)).unwrap();
12465
12466            let casted = cast(&string_dict_array, &DataType::BinaryView).unwrap();
12467            assert_eq!(casted.as_ref(), &expected);
12468        }
12469    }
12470
12471    #[test]
12472    fn test_binary_dicts_to_string_view() {
12473        let expected = StringViewArray::from_iter(vec![
12474            VIEW_TEST_DATA[1],
12475            VIEW_TEST_DATA[0],
12476            None,
12477            VIEW_TEST_DATA[3],
12478            None,
12479            VIEW_TEST_DATA[1],
12480            VIEW_TEST_DATA[4],
12481        ]);
12482
12483        let values_arrays: [ArrayRef; _] = [
12484            Arc::new(BinaryArray::from_iter(VIEW_TEST_DATA)),
12485            Arc::new(BinaryViewArray::from_iter(VIEW_TEST_DATA)),
12486            Arc::new(LargeBinaryArray::from_iter(VIEW_TEST_DATA)),
12487        ];
12488        for values in values_arrays {
12489            let keys =
12490                Int8Array::from_iter([Some(1), Some(0), None, Some(3), None, Some(1), Some(4)]);
12491            let string_dict_array =
12492                DictionaryArray::<Int8Type>::try_new(keys, Arc::new(values)).unwrap();
12493
12494            let casted = cast(&string_dict_array, &DataType::Utf8View).unwrap();
12495            assert_eq!(casted.as_ref(), &expected);
12496        }
12497    }
12498}
arrow_cast/cast/mod.rs

arrow_cast/cast/
mod.rs
