7 releases (4 breaking)
0.5.0 | May 9, 2023 |
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0.4.2 | Feb 12, 2023 |
0.3.2 | Sep 30, 2022 |
0.3.0 | Aug 25, 2022 |
0.1.0 | Mar 3, 2022 |
#749 in Parser implementations
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arrow2_convert
Provides an API on top of arrow2
to convert between rust types and Arrow.
The Arrow ecosystem provides many ways to convert between Arrow and other popular formats across several languages. This project aims to serve the need for rust-centric data pipelines to easily convert to/from Arrow with strong typing and arbitrary nesting.
Example
The example below performs a round trip conversion of a struct with a single field.
Please see the complex_example.rs for usage of the full functionality.
/// Simple example
use arrow2::array::Array;
use arrow2_convert::{deserialize::TryIntoCollection, serialize::TryIntoArrow, ArrowField, ArrowSerialize, ArrowDeserialize};
#[derive(Debug, Clone, PartialEq, ArrowField, ArrowSerialize, ArrowDeserialize)]
pub struct Foo {
name: String,
}
fn main() {
// an item
let original_array = [
Foo { name: "hello".to_string() },
Foo { name: "one more".to_string() },
Foo { name: "good bye".to_string() },
];
// serialize to an arrow array. try_into_arrow() is enabled by the TryIntoArrow trait
let arrow_array: Box<dyn Array> = original_array.try_into_arrow().unwrap();
// which can be cast to an Arrow StructArray and be used for all kinds of IPC, FFI, etc.
// supported by `arrow2`
let struct_array= arrow_array.as_any().downcast_ref::<arrow2::array::StructArray>().unwrap();
assert_eq!(struct_array.len(), 3);
// deserialize back to our original vector via TryIntoCollection trait.
let round_trip_array: Vec<Foo> = arrow_array.try_into_collection().unwrap();
assert_eq!(round_trip_array, original_array);
}
API
Types that implement the ArrowField
, ArrowSerialize
and ArrowDeserialize
traits can be converted to/from Arrow via the try_into_arrow
and the try_into_collection
methods.
The ArrowField
, ArrowSerialize
and ArrowDeserialize
derive macros can be used to generate implementations of these traits for structs and enums. Custom implementations can also be defined for any type that needs to convert to/from Arrow by manually implementing the traits.
For serializing to arrow, TryIntoArrow::try_into_arrow
can be used to serialize any iterable into an arrow2::Array
or a arrow2::Chunk
. arrow2::Array
represents the in-memory Arrow layout. arrow2::Chunk
represents a column group and can be used with arrow2
API for other functionality such converting to parquet and arrow flight RPC.
For deserializing from arrow, the TryIntoCollection::try_into_collection
can be used to deserialize from an arrow2::Array
representation into any container that implements FromIterator
.
Default implementations
Default implementations of the above traits are provided for the following:
- Numeric types
- [
u8
], [u16
], [u32
], [u64
], [i8
], [i16
], [i32
], [i64
], [f32
], [f64
] i128
is supported via thetype
attribute. Please see the i128 section for more details.
- [
- Other types:
- Temporal types:
- Option if T implements
ArrowField
- Vec if T implements
ArrowField
- Large Arrow types
LargeBinary
,LargeString
,LargeList
are supported via thetype
attribute. Please see the complex_example.rs for usage. - Fixed size types
FixedSizeBinary
,FixedSizeList
are supported via theFixedSizeVec
type override.- Note: nesting of
FixedSizeList
is not supported.
- Note: nesting of
Enums
Enums are still an experimental feature and need to be integrated tested. Rust enum arrays are converted to a Arrow::UnionArray
. Some additional notes on enums:
- Rust unit variants are represented using as the
bool
data type.
i128
i128 represents a decimal number and requires the precision and scale to be specified to be used as an Arrow data type. The precision and scale can be specified by using a type override via the I128
type.
For example to use i128
as a field in a struct:
use arrow2_convert::field::I128;
use arrow2_convert::ArrowField;
#[derive(Debug, ArrowField)]
struct S {
#[arrow_field(type = "I128<32, 32>")]
field: i128,
}
A vec<i128>
can be converted. to/from arrow by using the arrow_serialize_to_mutable_array
and arrow_array_deserialize_iterator_as_type
methods.
use arrow2::array::{Array, MutableArray};
use arrow2_convert::serialize::arrow_serialize_to_mutable_array;
use arrow2_convert::deserialize::arrow_array_deserialize_iterator_as_type;
use arrow2_convert::field::I128;
use std::borrow::Borrow;
fn convert_i128() {
let original_array = vec![1 as i128, 2, 3];
let b: Box<dyn Array> = arrow_serialize_to_mutable_array::<_, I128<32,32>, _>(
&original_array).unwrap().as_box();
let round_trip: Vec<i128> = arrow_array_deserialize_iterator_as_type::<_, I128<32,32>>(
b.borrow()).unwrap().collect();
assert_eq!(original_array, round_trip);
}
Nested Option Types
Since the Arrow format only supports one level of validity, nested option types such as Option<Option<T>>
, after serialization to Arrow, will lose any intermediate nesting of None values. For example, Some(None)
will be serialized to None
,
Missing Features
- Support for generics, slices and reference is currently missing.
This is not an exhaustive list. Please open an issue if you need a feature.
Memory
Pass-thru conversions perform a single memory copy. Deserialization performs a copy from arrow2 to the destination. Serialization performs a copy from the source to arrow2. In-place deserialization is theoretically possible but currently not supported.
Internals
Similarities with Serde
The design is inspired by serde. The ArrowSerialize
and ArrowDeserialize
are analogs of serde's Serialize
and Deserialize
respectively.
However unlike serde's traits provide an exhaustive and flexible mapping to the serde data model, arrow2_convert's traits provide a much more narrower mapping to arrow2's data structures.
Specifically, the ArrowSerialize
trait provides the logic to serialize a type to the corresponding arrow2::array::MutableArray
. The ArrowDeserialize
trait deserializes a type from the corresponding arrow2::array::ArrowArray
.
Workarounds
Features such as partial implementation specialization and generic associated types (currently only available in nightly builds) can greatly simplify the underlying implementation.
For example custom types need to explicitly enable Vec serialization via the arrow_enable_vec_for_type
macro on the primitive type. This is needed since Vec is a special type in Arrow, but without implementation specialization there's no way to special-case it.
Availability of generaic associated types would simplify the implementation for large and fixed types, since a generic MutableArray can be defined. Ideally for code reusability, we wouldn’t have to reimplement ArrowSerialize
and ArrowDeserialize
for large and fixed size types since the primitive types are the same. However, this requires the trait functions to take a generic bounded mutable array as an argument instead of a single array type. This requires the ArrowSerialize
and ArrowDeserialize
implementations to be able to specify the bounds as part of the associated type, which is not possible without generic associated types.
As a result, we’re forced to sacrifice code reusability and introduce a little bit of complexity by providing separate ArrowSerialize
and ArrowDeserialize
implementations for large and fixed size types via placeholder structures. This also requires introducing the Type
associated type to ArrowField
so that the arrow type can be overriden via a macro field attribute without affecting the actual type.
License
Licensed under either of
- Apache License, Version 2.0 (LICENSE-APACHE or http://www.apache.org/licenses/LICENSE-2.0)
- MIT license (LICENSE-MIT or http://opensource.org/licenses/MIT)
at your option.
Contribution
Unless you explicitly state otherwise, any contribution intentionally submitted for inclusion in the work by you, as defined in the Apache-2.0 license, shall be dual licensed as above, without any additional terms or conditions.
Dependencies
~7MB
~141K SLoC