Revert "Adding support for Polars structs" (#11171)

Reverts nushell/nushell#10943

The current implementation of `arr_to_value` is unsound, as it allows
casts of arbitrary data to arbitrary types without being marked
`unsafe`.
The full safety requirements to perform both the cast and the following
unchecked access are not as clear that a simple change of `fn
arr_to_value` to `unsafe fn arr_to_value` could be blessed without
further investigation.

cc @ayax79
This commit is contained in:
Stefan Holderbach 2023-11-29 16:33:27 +01:00 committed by GitHub
parent 98952082ae
commit 112306aab5
No known key found for this signature in database
GPG key ID: 4AEE18F83AFDEB23
3 changed files with 118 additions and 692 deletions

1
Cargo.lock generated
View file

@ -2747,7 +2747,6 @@ name = "nu-cmd-dataframe"
version = "0.87.2"
dependencies = [
"chrono",
"chrono-tz",
"fancy-regex",
"indexmap 2.1.0",
"nu-cmd-lang",

View file

@ -19,7 +19,6 @@ nu-protocol = { path = "../nu-protocol", version = "0.87.2" }
# Potential dependencies for extras
chrono = { version = "0.4", features = ["std", "unstable-locales"], default-features = false }
chrono-tz = "0.8"
fancy-regex = "0.11"
indexmap = { version = "2.1" }
num = { version = "0.4", optional = true }

View file

@ -1,31 +1,23 @@
use std::ops::{Deref, DerefMut};
use super::{DataFrameValue, NuDataFrame};
use chrono::{DateTime, Duration, FixedOffset, NaiveTime, TimeZone, Utc};
use chrono_tz::Tz;
use chrono::{DateTime, FixedOffset, NaiveDateTime};
use indexmap::map::{Entry, IndexMap};
use nu_protocol::{Record, ShellError, Span, Value};
use polars::chunked_array::builder::AnonymousOwnedListBuilder;
use polars::chunked_array::object::builder::ObjectChunkedBuilder;
use polars::chunked_array::ChunkedArray;
use polars::datatypes::AnyValue;
use polars::export::arrow::array::{
Array, BooleanArray, Float32Array, Float64Array, Int16Array, Int32Array, Int64Array, Int8Array,
UInt16Array, UInt32Array, UInt64Array, UInt8Array,
};
use polars::export::arrow::Either;
use polars::prelude::{
ArrayRef, DataFrame, DataType, DatetimeChunked, Float64Type, Int64Type, IntoSeries,
LargeBinaryArray, LargeListArray, LargeStringArray, ListBooleanChunkedBuilder,
ListBuilderTrait, ListPrimitiveChunkedBuilder, ListType, ListUtf8ChunkedBuilder, NamedFrom,
NewChunkedArray, ObjectType, Series, StructArray, TemporalMethods, TimeUnit,
DataFrame, DataType, DatetimeChunked, Float64Type, Int64Type, IntoSeries,
ListBooleanChunkedBuilder, ListBuilderTrait, ListPrimitiveChunkedBuilder, ListType,
ListUtf8ChunkedBuilder, NamedFrom, NewChunkedArray, ObjectType, Series, TemporalMethods,
TimeUnit,
};
use std::ops::{Deref, DerefMut};
use nu_protocol::{Record, ShellError, Span, Value};
const SECS_PER_DAY: i64 = 86_400;
use super::{DataFrameValue, NuDataFrame};
const NANOS_PER_DAY: i64 = 86_400_000_000_000;
// The values capacity is for the size of an vec.
// The values capacity is for the size of an internal vec.
// Since this is impossible to determine without traversing every value
// I just picked one. Since this is for converting back and forth
// between nushell tables the values shouldn't be too extremely large for
@ -207,7 +199,7 @@ fn value_to_input_type(value: &Value) -> InputType {
Value::Filesize { .. } => InputType::Filesize,
Value::List { vals, .. } => {
// We need to determined the type inside of the list.
// Since Value::List does not have any kind of
// Since Value::List does not have any kind of internal
// type information, we need to look inside the list.
// This will cause errors if lists have inconsistent types.
// Basically, if a list column needs to be converted to dataframe,
@ -813,21 +805,28 @@ fn series_to_values(
)),
Some(ca) => {
let it = ca.into_iter();
let values: Vec<Value> =
if let (Some(size), Some(from_row)) = (maybe_size, maybe_from_row) {
Either::Left(it.skip(from_row).take(size))
} else {
Either::Right(it)
}
.map(|ca| {
let sublist: Vec<Value> = if let Some(ref s) = ca {
series_to_values(s, None, None, Span::unknown())?
} else {
// empty item
let sublist = ca
.map(|ref s| {
match series_to_values(s, None, None, Span::unknown()) {
Ok(v) => v,
Err(e) => {
eprintln!("Error list values: {e}");
vec![]
};
Ok(Value::list(sublist, span))
}
}
})
.collect::<Result<Vec<Value>, ShellError>>()
.unwrap_or(vec![]);
Value::list(sublist, span)
})
.collect::<Vec<Value>>();
Ok(values)
}
}
}
@ -850,16 +849,51 @@ fn series_to_values(
}
.map(|v| match v {
Some(a) => {
let nanos = nanos_per_day(a);
let datetime = datetime_from_epoch_nanos(nanos, &None, span)?;
Ok(Value::date(datetime, span))
// elapsed time in day since 1970-01-01
let seconds = a as i64 * SECS_PER_DAY;
let naive_datetime = match NaiveDateTime::from_timestamp_opt(seconds, 0) {
Some(val) => val,
None => {
return Value::error(
ShellError::UnsupportedInput {
msg: "The given local datetime representation is invalid."
.to_string(),
input: format!("timestamp is {a:?}"),
msg_span: span,
input_span: Span::unknown(),
},
span,
)
}
None => Ok(Value::nothing(span)),
};
// Zero length offset
let offset = match FixedOffset::east_opt(0) {
Some(val) => val,
None => {
return Value::error(
ShellError::UnsupportedInput {
msg: "The given local datetime representation is invalid."
.to_string(),
input: format!("timestamp is {a:?}"),
msg_span: span,
input_span: Span::unknown(),
},
span,
)
}
};
let datetime =
DateTime::<FixedOffset>::from_naive_utc_and_offset(naive_datetime, offset);
Value::date(datetime, span)
}
None => Value::nothing(span),
})
.collect::<Result<Vec<Value>, ShellError>>()?;
.collect::<Vec<Value>>();
Ok(values)
}
DataType::Datetime(time_unit, tz) => {
DataType::Datetime(time_unit, _) => {
let casted = series.datetime().map_err(|e| {
ShellError::GenericError(
"Error casting column to datetime".into(),
@ -878,47 +912,54 @@ fn series_to_values(
}
.map(|v| match v {
Some(a) => {
let unit_divisor = match time_unit {
TimeUnit::Nanoseconds => 1_000_000_000,
TimeUnit::Microseconds => 1_000_000,
TimeUnit::Milliseconds => 1_000,
};
// elapsed time in nano/micro/milliseconds since 1970-01-01
let nanos = nanos_from_timeunit(a, *time_unit);
let datetime = datetime_from_epoch_nanos(nanos, tz, span)?;
Ok(Value::date(datetime, span))
}
None => Ok(Value::nothing(span)),
})
.collect::<Result<Vec<Value>, ShellError>>()?;
Ok(values)
}
DataType::Struct(polar_fields) => {
let casted = series.struct_().map_err(|e| {
ShellError::GenericError(
"Error casting column to struct".into(),
"".to_string(),
None,
Some(e.to_string()),
Vec::new(),
let seconds = a / unit_divisor;
let naive_datetime = match NaiveDateTime::from_timestamp_opt(seconds, 0) {
Some(val) => val,
None => {
return Value::error(
ShellError::UnsupportedInput {
msg: "The given local datetime representation is invalid."
.to_string(),
input: format!("timestamp is {a:?}"),
msg_span: span,
input_span: Span::unknown(),
},
span,
)
})?;
let it = casted.into_iter();
let values: Result<Vec<Value>, ShellError> =
if let (Some(size), Some(from_row)) = (maybe_size, maybe_from_row) {
Either::Left(it.skip(from_row).take(size))
} else {
Either::Right(it)
}
.map(|any_values| {
let vals: Result<Vec<Value>, ShellError> = any_values
.iter()
.map(|v| any_value_to_value(v, span))
.collect();
let cols: Vec<String> = polar_fields
.iter()
.map(|field| field.name.to_string())
.collect();
let record = Record { cols, vals: vals? };
Ok(Value::record(record, span))
};
// Zero length offset
let offset = match FixedOffset::east_opt(0) {
Some(val) => val,
None => {
return Value::error(
ShellError::UnsupportedInput {
msg: "The given local datetime representation is invalid."
.to_string(),
input: format!("timestamp is {a:?}"),
msg_span: span,
input_span: Span::unknown(),
},
span,
)
}
};
let datetime =
DateTime::<FixedOffset>::from_naive_utc_and_offset(naive_datetime, offset);
Value::date(datetime, span)
}
None => Value::nothing(span),
})
.collect();
values
.collect::<Vec<Value>>();
Ok(values)
}
DataType::Time => {
let casted = series.timestamp(TimeUnit::Nanoseconds).map_err(|e| {
@ -955,252 +996,10 @@ fn series_to_values(
}
}
fn any_value_to_value(any_value: &AnyValue, span: Span) -> Result<Value, ShellError> {
match any_value {
AnyValue::Null => Ok(Value::nothing(span)),
AnyValue::Boolean(b) => Ok(Value::bool(*b, span)),
AnyValue::Utf8(s) => Ok(Value::string(s.to_string(), span)),
AnyValue::UInt8(i) => Ok(Value::int(*i as i64, span)),
AnyValue::UInt16(i) => Ok(Value::int(*i as i64, span)),
AnyValue::UInt32(i) => Ok(Value::int(*i as i64, span)),
AnyValue::UInt64(i) => Ok(Value::int(*i as i64, span)),
AnyValue::Int8(i) => Ok(Value::int(*i as i64, span)),
AnyValue::Int16(i) => Ok(Value::int(*i as i64, span)),
AnyValue::Int32(i) => Ok(Value::int(*i as i64, span)),
AnyValue::Int64(i) => Ok(Value::int(*i, span)),
AnyValue::Float32(f) => Ok(Value::float(*f as f64, span)),
AnyValue::Float64(f) => Ok(Value::float(*f, span)),
AnyValue::Date(d) => {
let nanos = nanos_per_day(*d);
datetime_from_epoch_nanos(nanos, &None, span)
.map(|datetime| Value::date(datetime, span))
}
AnyValue::Datetime(a, time_unit, tz) => {
let nanos = nanos_from_timeunit(*a, *time_unit);
datetime_from_epoch_nanos(nanos, tz, span).map(|datetime| Value::date(datetime, span))
}
AnyValue::Duration(a, time_unit) => {
let nanos = match time_unit {
TimeUnit::Nanoseconds => *a,
TimeUnit::Microseconds => *a * 1_000,
TimeUnit::Milliseconds => *a * 1_000_000,
};
Ok(Value::duration(nanos, span))
}
// AnyValue::Time represents the current time since midnight.
// Unfortunately, there is no timezone related information.
// Given this, calculate the current date from UTC and add the time.
AnyValue::Time(nanos) => time_from_midnight(*nanos, span),
AnyValue::List(series) => {
series_to_values(series, None, None, span).map(|values| Value::list(values, span))
}
AnyValue::Struct(idx, struct_array, s_fields) => {
let cols: Vec<String> = s_fields.iter().map(|f| f.name().to_string()).collect();
let vals: Result<Vec<Value>, ShellError> = struct_array
.values()
.iter()
.enumerate()
.map(|(pos, v)| {
let f = &s_fields[pos];
arr_to_value(&f.dtype, &**v, *idx, span)
})
.collect();
let record = Record { cols, vals: vals? };
Ok(Value::record(record, span))
}
AnyValue::StructOwned(struct_tuple) => {
let values: Result<Vec<Value>, ShellError> = struct_tuple
.0
.iter()
.map(|s| any_value_to_value(s, span))
.collect();
let fields = struct_tuple
.1
.iter()
.map(|f| f.name().to_string())
.collect();
Ok(Value::Record {
val: Record {
cols: fields,
vals: values?,
},
internal_span: span,
})
}
AnyValue::Utf8Owned(s) => Ok(Value::string(s.to_string(), span)),
AnyValue::Binary(bytes) => Ok(Value::binary(*bytes, span)),
AnyValue::BinaryOwned(bytes) => Ok(Value::binary(bytes.to_owned(), span)),
e => Err(ShellError::GenericError(
"Error creating Value".into(),
"".to_string(),
None,
Some(format!("Value not supported in nushell: {e}")),
Vec::new(),
)),
}
}
#[inline]
fn arr_to_value(
dt: &DataType,
arr: &dyn Array,
idx: usize,
span: Span,
) -> Result<Value, ShellError> {
macro_rules! downcast {
($casttype:ident) => {{
let arr = &*(arr as *const dyn Array as *const $casttype);
arr.value_unchecked(idx)
}};
}
// Not loving the unsafe here, however this largely based off the one
// example I found for converting Array values in:
// polars_core::chunked_array::ops::any_value::arr_to_any_value
unsafe {
match dt {
DataType::Boolean => Ok(Value::bool(downcast!(BooleanArray), span)),
DataType::UInt8 => Ok(Value::int(downcast!(UInt8Array) as i64, span)),
DataType::UInt16 => Ok(Value::int(downcast!(UInt16Array) as i64, span)),
DataType::UInt32 => Ok(Value::int(downcast!(UInt32Array) as i64, span)),
DataType::UInt64 => Ok(Value::int(downcast!(UInt64Array) as i64, span)),
DataType::Int8 => Ok(Value::int(downcast!(Int8Array) as i64, span)),
DataType::Int16 => Ok(Value::int(downcast!(Int16Array) as i64, span)),
DataType::Int32 => Ok(Value::int(downcast!(Int32Array) as i64, span)),
DataType::Int64 => Ok(Value::int(downcast!(Int64Array), span)),
DataType::Float32 => Ok(Value::float(downcast!(Float32Array) as f64, span)),
DataType::Float64 => Ok(Value::float(downcast!(Float64Array), span)),
// DataType::Decimal(_, _) => {}
DataType::Utf8 => Ok(Value::string(downcast!(LargeStringArray).to_string(), span)),
DataType::Binary => Ok(Value::binary(downcast!(LargeBinaryArray).to_owned(), span)),
DataType::Date => {
let date = downcast!(Int32Array);
let nanos = nanos_per_day(date);
datetime_from_epoch_nanos(nanos, &None, span)
.map(|datetime| Value::date(datetime, span))
}
DataType::Datetime(time_unit, tz) => {
let nanos = nanos_from_timeunit(downcast!(Int64Array), *time_unit);
datetime_from_epoch_nanos(nanos, tz, span)
.map(|datetime| Value::date(datetime, span))
}
// DataType::Duration(_) => {}
DataType::Time => {
let t = downcast!(Int64Array);
time_from_midnight(t, span)
}
DataType::List(dt) => {
let v: ArrayRef = downcast!(LargeListArray);
let values_result = if dt.is_primitive() {
let s = Series::from_chunks_and_dtype_unchecked("", vec![v], dt);
series_to_values(&s, None, None, span)
} else {
let s = Series::from_chunks_and_dtype_unchecked("", vec![v], &dt.to_physical())
.cast_unchecked(dt)
.map_err(|e| {
ShellError::GenericError(
"Error creating Value from polars LargeListArray".into(),
e.to_string(),
Some(span),
None,
Vec::new(),
)
})?;
series_to_values(&s, None, None, span)
};
values_result.map(|values| Value::list(values, span))
}
DataType::Null => Ok(Value::nothing(span)),
DataType::Struct(fields) => {
let arr = &*(arr as *const dyn Array as *const StructArray);
let vals: Result<Vec<Value>, ShellError> = arr
.values()
.iter()
.enumerate()
.map(|(pos, v)| {
let f = &fields[pos];
arr_to_value(&f.dtype, &**v, 0, span)
})
.collect();
let cols = fields.iter().map(|f| f.name().to_string()).collect();
Ok(Value::record(Record { cols, vals: vals? }, span))
}
DataType::Unknown => Ok(Value::nothing(span)),
_ => Err(ShellError::CantConvert {
to_type: dt.to_string(),
from_type: "polars array".to_string(),
span,
help: Some(format!(
"Could not convert polars array of type {:?} to value",
dt
)),
}),
}
}
}
fn nanos_per_day(days: i32) -> i64 {
days as i64 * NANOS_PER_DAY
}
fn nanos_from_timeunit(a: i64, time_unit: TimeUnit) -> i64 {
a * match time_unit {
TimeUnit::Microseconds => 1_000, // Convert microseconds to nanoseconds
TimeUnit::Milliseconds => 1_000_000, // Convert milliseconds to nanoseconds
TimeUnit::Nanoseconds => 1, // Already in nanoseconds
}
}
fn datetime_from_epoch_nanos(
nanos: i64,
timezone: &Option<String>,
span: Span,
) -> Result<DateTime<FixedOffset>, ShellError> {
let tz: Tz = if let Some(polars_tz) = timezone {
polars_tz.parse::<Tz>().map_err(|_| {
ShellError::GenericError(
format!("Could not parse polars timezone: {polars_tz}"),
"".to_string(),
Some(span),
None,
vec![],
)
})?
} else {
Tz::UTC
};
Ok(tz.timestamp_nanos(nanos).fixed_offset())
}
fn time_from_midnight(nanos: i64, span: Span) -> Result<Value, ShellError> {
let today = Utc::now().date_naive();
NaiveTime::from_hms_opt(0, 0, 0) // midnight
.map(|time| time + Duration::nanoseconds(nanos)) // current time
.map(|time| today.and_time(time)) // current date and time
.and_then(|datetime| {
FixedOffset::east_opt(0) // utc
.map(|offset| {
DateTime::<FixedOffset>::from_naive_utc_and_offset(datetime, offset)
})
})
.map(|datetime| Value::date(datetime, span)) // current date and time
.ok_or(ShellError::CantConvert {
to_type: "datetime".to_string(),
from_type: "polars time".to_string(),
span,
help: Some("Could not convert polars time of {nanos} to datetime".to_string()),
})
}
#[cfg(test)]
mod tests {
use indexmap::indexmap;
use polars::export::arrow::array::{ListArray, NullArray, PrimitiveArray};
use polars::export::arrow::buffer::Buffer;
use polars::prelude::Field;
use super::*;
use indexmap::indexmap;
#[test]
fn test_parsed_column_string_list() -> Result<(), Box<dyn std::error::Error>> {
@ -1235,375 +1034,4 @@ mod tests {
Ok(())
}
#[test]
fn test_any_value_to_value() -> Result<(), Box<dyn std::error::Error>> {
let span = Span::test_data();
assert_eq!(
any_value_to_value(&AnyValue::Null, span)?,
Value::nothing(span)
);
let test_bool = true;
assert_eq!(
any_value_to_value(&AnyValue::Boolean(test_bool), span)?,
Value::bool(test_bool, span)
);
let test_str = "foo";
assert_eq!(
any_value_to_value(&AnyValue::Utf8(test_str), span)?,
Value::string(test_str.to_string(), span)
);
assert_eq!(
any_value_to_value(&AnyValue::Utf8Owned(test_str.into()), span)?,
Value::string(test_str.to_owned(), span)
);
let tests_uint8 = 4;
assert_eq!(
any_value_to_value(&AnyValue::UInt8(tests_uint8), span)?,
Value::int(tests_uint8 as i64, span)
);
let tests_uint16 = 233;
assert_eq!(
any_value_to_value(&AnyValue::UInt16(tests_uint16), span)?,
Value::int(tests_uint16 as i64, span)
);
let tests_uint32 = 897688233;
assert_eq!(
any_value_to_value(&AnyValue::UInt32(tests_uint32), span)?,
Value::int(tests_uint32 as i64, span)
);
let tests_uint64 = 903225135897388233;
assert_eq!(
any_value_to_value(&AnyValue::UInt64(tests_uint64), span)?,
Value::int(tests_uint64 as i64, span)
);
let tests_float32 = 903225135897388233.3223353;
assert_eq!(
any_value_to_value(&AnyValue::Float32(tests_float32), span)?,
Value::float(tests_float32 as f64, span)
);
let tests_float64 = 9064251358973882322333.64233533232;
assert_eq!(
any_value_to_value(&AnyValue::Float64(tests_float64), span)?,
Value::float(tests_float64, span)
);
let test_days = 10_957;
let comparison_date = Utc
.with_ymd_and_hms(2000, 1, 1, 0, 0, 0)
.unwrap()
.fixed_offset();
assert_eq!(
any_value_to_value(&AnyValue::Date(test_days), span)?,
Value::date(comparison_date, span)
);
let test_millis = 946_684_800_000;
assert_eq!(
any_value_to_value(
&AnyValue::Datetime(test_millis, TimeUnit::Milliseconds, &None),
span
)?,
Value::date(comparison_date, span)
);
let test_duration_millis = 99_999;
let test_duration_micros = 99_999_000;
let test_duration_nanos = 99_999_000_000;
assert_eq!(
any_value_to_value(
&AnyValue::Duration(test_duration_nanos, TimeUnit::Nanoseconds),
span
)?,
Value::duration(test_duration_nanos, span)
);
assert_eq!(
any_value_to_value(
&AnyValue::Duration(test_duration_micros, TimeUnit::Microseconds),
span
)?,
Value::duration(test_duration_nanos, span)
);
assert_eq!(
any_value_to_value(
&AnyValue::Duration(test_duration_millis, TimeUnit::Milliseconds),
span
)?,
Value::duration(test_duration_nanos, span)
);
let test_binary = b"sdf2332f32q3f3afwaf3232f32";
assert_eq!(
any_value_to_value(&AnyValue::Binary(test_binary), span)?,
Value::binary(test_binary.to_vec(), span)
);
assert_eq!(
any_value_to_value(&AnyValue::BinaryOwned(test_binary.to_vec()), span)?,
Value::binary(test_binary.to_vec(), span)
);
let test_time_nanos = 54_000_000_000_000;
let test_time = DateTime::<FixedOffset>::from_naive_utc_and_offset(
Utc::now()
.date_naive()
.and_time(NaiveTime::from_hms_opt(15, 00, 00).unwrap()),
FixedOffset::east_opt(0).unwrap(),
);
assert_eq!(
any_value_to_value(&AnyValue::Time(test_time_nanos), span)?,
Value::date(test_time, span)
);
let test_list_series = Series::new("int series", &[1, 2, 3]);
let comparison_list_series = Value::list(
vec![
Value::int(1, span),
Value::int(2, span),
Value::int(3, span),
],
span,
);
assert_eq!(
any_value_to_value(&AnyValue::List(test_list_series), span)?,
comparison_list_series
);
let field_value_0 = AnyValue::Int32(1);
let field_value_1 = AnyValue::Boolean(true);
let values = vec![field_value_0, field_value_1];
let field_name_0 = "num_field";
let field_name_1 = "bool_field";
let fields = vec![
Field::new(field_name_0, DataType::Int32),
Field::new(field_name_1, DataType::Boolean),
];
let test_owned_struct = AnyValue::StructOwned(Box::new((values, fields.clone())));
let comparison_owned_record = Value::record(
Record {
cols: vec![field_name_0.to_owned(), field_name_1.to_owned()],
vals: vec![Value::int(1, span), Value::bool(true, span)],
},
span,
);
assert_eq!(
any_value_to_value(&test_owned_struct, span)?,
comparison_owned_record.clone()
);
let test_int_arr = PrimitiveArray::from([Some(1_i32)]);
let test_bool_arr = BooleanArray::from([Some(true)]);
let test_struct_arr = StructArray::new(
DataType::Struct(fields.clone()).to_arrow(),
vec![Box::new(test_int_arr), Box::new(test_bool_arr)],
None,
);
assert_eq!(
any_value_to_value(
&AnyValue::Struct(0, &test_struct_arr, fields.as_slice()),
span
)?,
comparison_owned_record
);
Ok(())
}
#[test]
fn test_arr_to_value() -> Result<(), Box<dyn std::error::Error>> {
let test_bool_arr = BooleanArray::from([Some(true)]);
assert_eq!(
arr_to_value(&DataType::Boolean, &test_bool_arr, 0, Span::test_data())?,
Value::bool(true, Span::test_data())
);
let test_uint8_arr = PrimitiveArray::from([Some(9_u8)]);
assert_eq!(
arr_to_value(&DataType::UInt8, &test_uint8_arr, 0, Span::test_data())?,
Value::int(9, Span::test_data())
);
let test_uint16_arr = PrimitiveArray::from([Some(3223_u16)]);
assert_eq!(
arr_to_value(&DataType::UInt16, &test_uint16_arr, 0, Span::test_data())?,
Value::int(3223, Span::test_data())
);
let test_uint32_arr = PrimitiveArray::from([Some(33_u32)]);
assert_eq!(
arr_to_value(&DataType::UInt32, &test_uint32_arr, 0, Span::test_data())?,
Value::int(33, Span::test_data())
);
let test_uint64_arr = PrimitiveArray::from([Some(33_3232_u64)]);
assert_eq!(
arr_to_value(&DataType::UInt64, &test_uint64_arr, 0, Span::test_data())?,
Value::int(33_3232, Span::test_data())
);
let test_int8_arr = PrimitiveArray::from([Some(9_i8)]);
assert_eq!(
arr_to_value(&DataType::Int8, &test_int8_arr, 0, Span::test_data())?,
Value::int(9, Span::test_data())
);
let test_int16_arr = PrimitiveArray::from([Some(3223_i16)]);
assert_eq!(
arr_to_value(&DataType::Int16, &test_int16_arr, 0, Span::test_data())?,
Value::int(3223, Span::test_data())
);
let test_int32_arr = PrimitiveArray::from([Some(33_i32)]);
assert_eq!(
arr_to_value(&DataType::Int32, &test_int32_arr, 0, Span::test_data())?,
Value::int(33, Span::test_data())
);
let test_int64_arr = PrimitiveArray::from([Some(33_3232_i64)]);
assert_eq!(
arr_to_value(&DataType::Int64, &test_int64_arr, 0, Span::test_data())?,
Value::int(33_3232, Span::test_data())
);
let test_float32_arr = PrimitiveArray::from([Some(33.32_f32)]);
assert_eq!(
arr_to_value(&DataType::Float32, &test_float32_arr, 0, Span::test_data())?,
Value::float(33.32_f32 as f64, Span::test_data())
);
let test_float64_arr = PrimitiveArray::from([Some(33_3232.999_f64)]);
assert_eq!(
arr_to_value(&DataType::Float64, &test_float64_arr, 0, Span::test_data())?,
Value::float(33_3232.999, Span::test_data())
);
let test_str = "hello world";
let test_str_arr = LargeStringArray::from(vec![Some(test_str.to_string())]);
assert_eq!(
arr_to_value(&DataType::Utf8, &test_str_arr, 0, Span::test_data())?,
Value::string(test_str.to_string(), Span::test_data())
);
let test_bin = b"asdlfkjadsf";
let test_bin_arr = LargeBinaryArray::from(vec![Some(test_bin.to_vec())]);
assert_eq!(
arr_to_value(&DataType::Binary, &test_bin_arr, 0, Span::test_data())?,
Value::binary(test_bin.to_vec(), Span::test_data())
);
let test_days = 10_957_i32;
let comparison_date = Utc
.with_ymd_and_hms(2000, 1, 1, 0, 0, 0)
.unwrap()
.fixed_offset();
let test_date_arr = PrimitiveArray::from([Some(test_days)]);
assert_eq!(
arr_to_value(&DataType::Date, &test_date_arr, 0, Span::test_data())?,
Value::date(comparison_date, Span::test_data())
);
let test_dt_nanos = 1_357_488_900_000_000_000_i64;
let test_dt_arr = PrimitiveArray::from([Some(test_dt_nanos)]);
let test_dt = Utc.timestamp_nanos(test_dt_nanos).fixed_offset();
assert_eq!(
arr_to_value(
&DataType::Datetime(TimeUnit::Nanoseconds, Some("UTC".to_owned())),
&test_dt_arr,
0,
Span::test_data()
)?,
Value::date(test_dt, Span::test_data())
);
let test_time_nanos = 54_000_000_000_000_i64;
let test_dt_arr = PrimitiveArray::from([Some(test_time_nanos)]);
let test_time = DateTime::<FixedOffset>::from_naive_utc_and_offset(
Utc::now()
.date_naive()
.and_time(NaiveTime::from_hms_opt(15, 00, 00).unwrap()),
FixedOffset::east_opt(0).unwrap(),
);
assert_eq!(
arr_to_value(&DataType::Time, &test_dt_arr, 0, Span::test_data())?,
Value::date(test_time, Span::test_data())
);
let values = Buffer::from(vec![1, 2, 3]);
let values = PrimitiveArray::<i64>::new(DataType::Int64.to_arrow(), values, None);
let data_type = ListArray::<i64>::default_datatype(DataType::Int64.to_arrow());
let array = ListArray::<i64>::new(
data_type,
vec![0, 3].try_into().unwrap(),
Box::new(values),
None,
);
let comparison_list_series = Value::list(
vec![
Value::int(1, Span::test_data()),
Value::int(2, Span::test_data()),
Value::int(3, Span::test_data()),
],
Span::test_data(),
);
assert_eq!(
arr_to_value(
&DataType::List(Box::new(DataType::Int64)),
&array,
0,
Span::test_data()
)?,
comparison_list_series
);
let field_name_0 = "num_field";
let field_name_1 = "bool_field";
let fields = vec![
Field::new(field_name_0, DataType::Int32),
Field::new(field_name_1, DataType::Boolean),
];
let test_int_arr = PrimitiveArray::from([Some(1_i32)]);
let test_struct_arr = StructArray::new(
DataType::Struct(fields.clone()).to_arrow(),
vec![Box::new(test_int_arr), Box::new(test_bool_arr)],
None,
);
let comparison_owned_record = Value::record(
Record {
cols: vec![field_name_0.to_owned(), field_name_1.to_owned()],
vals: vec![
Value::int(1, Span::test_data()),
Value::bool(true, Span::test_data()),
],
},
Span::test_data(),
);
assert_eq!(
arr_to_value(
&DataType::Struct(fields),
&test_struct_arr,
0,
Span::test_data(),
)?,
comparison_owned_record
);
assert_eq!(
arr_to_value(
&DataType::Null,
&NullArray::new(DataType::Null.to_arrow(), 0),
0,
Span::test_data()
)?,
Value::nothing(Span::test_data())
);
Ok(())
}
}