readme.md - mozsearch

# Bincode↩

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<img align="right" src="./logo.png" />↩

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![CI](https://github.com/servo/bincode/workflows/CI/badge.svg)↩

[![](https://meritbadge.herokuapp.com/bincode)](https://crates.io/crates/bincode)↩

[![](https://img.shields.io/badge/license-MIT-blue.svg)](https://opensource.org/licenses/MIT)↩

[![](https://img.shields.io/badge/bincode-rustc_1.18+-lightgray.svg)](https://blog.rust-lang.org/2017/06/08/Rust-1.18.html)↩

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A compact encoder / decoder pair that uses a binary zero-fluff encoding scheme.↩

The size of the encoded object will be the same or smaller than the size that↩

the object takes up in memory in a running Rust program.↩

↩

In addition to exposing two simple functions↩

(one that encodes to `Vec<u8>`, and one that decodes from `&[u8]`),↩

binary-encode exposes a Reader/Writer API that makes it work↩

perfectly with other stream-based APIs such as Rust files, network streams,↩

and the [flate2-rs](https://github.com/alexcrichton/flate2-rs) compression↩

library.↩

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## [API Documentation](https://docs.rs/bincode/)↩

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## Bincode in the wild↩

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* [google/tarpc](https://github.com/google/tarpc): Bincode is used to serialize and deserialize networked RPC messages.↩

* [servo/webrender](https://github.com/servo/webrender): Bincode records webrender API calls for record/replay-style graphics debugging.↩

* [servo/ipc-channel](https://github.com/servo/ipc-channel): IPC-Channel uses Bincode to send structs between processes using a channel-like API.↩

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## Example↩

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```rust↩

use serde::{Serialize, Deserialize};↩

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#[derive(Serialize, Deserialize, PartialEq, Debug)]↩

struct Entity {↩

    x: f32,↩

    y: f32,↩

}↩

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#[derive(Serialize, Deserialize, PartialEq, Debug)]↩

struct World(Vec<Entity>);↩

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fn main() {↩

    let world = World(vec![Entity { x: 0.0, y: 4.0 }, Entity { x: 10.0, y: 20.5 }]);↩

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    let encoded: Vec<u8> = bincode::serialize(&world).unwrap();↩

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    // 8 bytes for the length of the vector, 4 bytes per float.↩

    assert_eq!(encoded.len(), 8 + 4 * 4);↩

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    let decoded: World = bincode::deserialize(&encoded[..]).unwrap();↩

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    assert_eq!(world, decoded);↩

}↩

```↩

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## Details↩

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The encoding (and thus decoding) proceeds unsurprisingly -- primitive↩

types are encoded according to the underlying `Writer`, tuples and↩

structs are encoded by encoding their fields one-by-one, and enums are↩

encoded by first writing out the tag representing the variant and↩

then the contents.↩

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However, there are some implementation details to be aware of:↩

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* `isize`/`usize` are encoded as `i64`/`u64`, for portability.↩

* enums variants are encoded as a `u32` instead of a `usize`.↩

  `u32` is enough for all practical uses.↩

* `str` is encoded as `(u64, &[u8])`, where the `u64` is the number of↩

  bytes contained in the encoded string.↩

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## Specification↩

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Bincode's format will eventually be codified into a specification, along with↩

its configuration options and default configuration. In the meantime, here are↩

some frequently asked questions regarding use of the crate:↩

↩

### Is Bincode suitable for storage?↩

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The encoding format is stable across minor revisions, provided the same↩

configuration is used. This should ensure that later versions can still read↩

data produced by a previous versions of the library if no major version change↩

has occured.↩

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Bincode is invariant over byte-order in the default configuration↩

(`bincode::options::DefaultOptions`), making an exchange between different↩

architectures possible. It is also rather space efficient, as it stores no↩

metadata like struct field names in the output format and writes long streams of↩

binary data without needing any potentially size-increasing encoding.↩

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As a result, Bincode is suitable for storing data. Be aware that it does not↩

implement any sort of data versioning scheme or file headers, as these↩

features are outside the scope of this crate.↩

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### Is Bincode suitable for untrusted inputs?↩

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Bincode attempts to protect against hostile data. There is a maximum size↩

configuration available (`bincode::config::Bounded`), but not enabled in the↩

default configuration. Enabling it causes pre-allocation size to be limited to↩

prevent against memory exhaustion attacks.↩

↩

Deserializing any incoming data will not cause undefined behavior or memory↩

issues, assuming that the deserialization code for the struct is safe itself.↩

↩

Bincode can be used for untrusted inputs in the sense that it will not create a↩

security issues in your application, provided the configuration is changed to enable a↩

maximum size limit. Malicious inputs will fail upon deserialization.↩

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### What is Bincode's MSRV (minimum supported Rust version)?↩

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Bincode 1.0 maintains support for rust 1.18.0. Any changes to this are considered a breaking change for semver purposes.