3 unstable releases
0.2.1 | Nov 26, 2020 |
---|---|
0.2.0 | Oct 10, 2020 |
0.1.0 | Oct 8, 2020 |
#1481 in Encoding
595KB
4K
SLoC
Table of Contents
- Overview
- Features
- Getting started
- Examples
- Supported Codecs
- Using the avrow-cli tool
- Benchmarks
- Todo
- Changelog
- Contributions
- Support
- MSRV
- License
Overview
Avrow is a pure Rust implementation of the Avro specification: a row based data serialization system. The Avro data serialization format finds its use quite a lot in big data streaming systems such as Kafka and Spark. Within avro's context, an avro encoded file or byte stream is called a "data file". To write data in avro encoded format, one needs a schema which is provided in json format. Here's an example of an avro schema represented in json:
{
"type": "record",
"name": "LongList",
"aliases": ["LinkedLongs"],
"fields" : [
{"name": "value", "type": "long"},
{"name": "next", "type": ["null", "LongList"]}
]
}
The above schema is of type record with fields and represents a linked list of 64-bit integers. In most implementations, this schema is then fed to a Writer
instance along with a buffer to write encoded data to. One can then call one
of the write
methods on the writer to write data. One distinguishing aspect of avro is that the schema for the encoded data is written on the header of the data file. This means that for reading data you don't need to provide a schema to a Reader
instance. The spec also allows providing a reader schema to filter data when reading.
The Avro specification provides two kinds of encoding:
- Binary encoding - Efficent and takes less space on disk.
- JSON encoding - When you want a readable version of avro encoded data. Also used for debugging purposes.
This crate implements only the binary encoding as that's the format practically used for performance and storage reasons.
Features
- Full support for recursive self-referential schemas with Serde serialization/deserialization.
- All compressions codecs (
deflate
,bzip2
,snappy
,xz
,zstd
) supported as per spec. - Simple and intuitive API - As the underlying structures in use are
Read
andWrite
types, avrow tries to mimic the same APIs as Rust's standard library APIs for minimal learning overhead. Writing avro values is simply callingwrite
orserialize
(with serde) and reading avro values is simply using iterators. - Less bloat / Lightweight - Compile times in Rust are costly. Avrow tries to use minimal third-party crates. Compression codec and schema fingerprinting support are feature gated by default. To use them, compile with respective feature flags (e.g.
--features zstd
). - Schema evolution - One can configure the avrow
Reader
with a reader schema and only read data relevant to their use case. - Schema's in avrow supports querying their canonical form and have fingerprinting (
rabin64
,sha256
,md5
) support.
Note: This is not a complete spec implemention and remaining features being implemented are listed under Todo section.
Getting started:
Add avrow as a dependency to Cargo.toml
:
[dependencies]
avrow = "0.2.0"
Examples:
Writing avro data
use anyhow::Error;
use avrow::{Schema, Writer};
use std::str::FromStr;
fn main() -> Result<(), Error> {
// Create schema from json
let schema = Schema::from_str(r##"{"type":"string"}"##)?;
// or from a path
let schema2 = Schema::from_path("./string_schema.avsc")?;
// Create an output stream
let stream = Vec::new();
// Create a writer
let writer = Writer::new(&schema, stream.as_slice())?;
// Write your data!
let res = writer.write("Hey")?;
// or using serialize method for serde derived types.
let res = writer.serialize("there!")?;
Ok(())
}
For simple and native Rust types, avrow provides a From
impl to convert to Avro value types. For compound or user defined types (structs or enums), one can use the serialize
method which relies on serde. Alternatively, one can construct avrow::Value
instances which is a more verbose way to write avro values and should be a last resort.
Reading avro data
fn main() -> Result<(), Error> {
let schema = Schema::from_str(r##""null""##);
let data = vec![
79, 98, 106, 1, 4, 22, 97, 118, 114, 111, 46, 115, 99, 104, 101,
109, 97, 32, 123, 34, 116, 121, 112, 101, 34, 58, 34, 98, 121, 116,
101, 115, 34, 125, 20, 97, 118, 114, 111, 46, 99, 111, 100, 101,
99, 14, 100, 101, 102, 108, 97, 116, 101, 0, 145, 85, 112, 15, 87,
201, 208, 26, 183, 148, 48, 236, 212, 250, 38, 208, 2, 18, 227, 97,
96, 100, 98, 102, 97, 5, 0, 145, 85, 112, 15, 87, 201, 208, 26,
183, 148, 48, 236, 212, 250, 38, 208,
];
// Create a Reader
let reader = Reader::with_schema(v.as_slice(), &schema)?;
for i in reader {
dbg!(&i);
}
Ok(())
}
Self-referential recursive schema example
use anyhow::Error;
use avrow::{from_value, Codec, Reader, Schema, Writer};
use serde::{Deserialize, Serialize};
#[derive(Debug, Serialize, Deserialize)]
struct LongList {
value: i64,
next: Option<Box<LongList>>,
}
fn main() -> Result<(), Error> {
let schema = r##"
{
"type": "record",
"name": "LongList",
"aliases": ["LinkedLongs"],
"fields" : [
{"name": "value", "type": "long"},
{"name": "next", "type": ["null", "LongList"]}
]
}
"##;
let schema = Schema::from_str(schema)?;
let mut writer = Writer::with_codec(&schema, vec![], Codec::Null)?;
let value = LongList {
value: 1i64,
next: Some(Box::new(LongList {
value: 2i64,
next: Some(Box::new(LongList {
value: 3i64,
next: Some(Box::new(LongList {
value: 4i64,
next: Some(Box::new(LongList {
value: 5i64,
next: None,
})),
})),
})),
})),
};
writer.serialize(value)?;
// Calling into_inner performs flush internally. Alternatively, one can call flush explicitly.
let buf = writer.into_inner()?;
// read
let reader = Reader::with_schema(buf.as_slice(), &schema)?;
for i in reader {
let a: LongList = from_value(&i)?;
dbg!(a);
}
Ok(())
}
An example of writing a json object with a confirming schema. The json object maps to the avrow::Record
type.
use anyhow::Error;
use avrow::{from_value, Reader, Record, Schema, Writer};
use serde::{Deserialize, Serialize};
use std::str::FromStr;
#[derive(Debug, Serialize, Deserialize)]
struct Mentees {
id: i32,
username: String,
}
#[derive(Debug, Serialize, Deserialize)]
struct RustMentors {
name: String,
github_handle: String,
active: bool,
mentees: Mentees,
}
fn main() -> Result<(), Error> {
let schema = Schema::from_str(
r##"
{
"name": "rust_mentors",
"type": "record",
"fields": [
{
"name": "name",
"type": "string"
},
{
"name": "github_handle",
"type": "string"
},
{
"name": "active",
"type": "boolean"
},
{
"name":"mentees",
"type": {
"name":"mentees",
"type": "record",
"fields": [
{"name":"id", "type": "int"},
{"name":"username", "type": "string"}
]
}
}
]
}
"##,
)?;
let json_data = serde_json::from_str(
r##"
{ "name": "bob",
"github_handle":"ghbob",
"active": true,
"mentees":{"id":1, "username":"alice"} }"##,
)?;
let rec = Record::from_json(json_data, &schema)?;
let mut writer = crate::Writer::new(&schema, vec![])?;
writer.write(rec)?;
let avro_data = writer.into_inner()?;
let reader = crate::Reader::new(avro_data.as_slice())?;
for value in reader {
let mentors: RustMentors = from_value(&value)?;
dbg!(mentors);
}
Ok(())
}
Writer customization
If you want to have more control over the parameters of Writer
, consider using WriterBuilder
as shown below:
use anyhow::Error;
use avrow::{Codec, Reader, Schema, WriterBuilder};
fn main() -> Result<(), Error> {
let schema = Schema::from_str(r##""null""##)?;
let v = vec![];
let mut writer = WriterBuilder::new()
.set_codec(Codec::Null)
.set_schema(&schema)
.set_datafile(v)
// set any custom metadata in the header
.set_metadata("hello", "world")
// set after how many bytes, the writer should flush
.set_flush_interval(128_000)
.build()
.unwrap();
writer.serialize(())?;
let v = writer.into_inner()?;
let reader = Reader::with_schema(v.as_slice(), schema)?;
for i in reader {
dbg!(i?);
}
Ok(())
}
Refer to examples for more code examples.
Supported Codecs
In order to facilitate efficient encoding, avro spec also defines compression codecs to use when serializing data.
Avrow supports all compression codecs as per spec:
These are feature-gated behind their respective flags. Check Cargo.toml
features
section for more details.
Using avrow-cli tool:
Quite often you will need a quick way to examine avro file for debugging purposes.
For that, this repository also comes with the avrow-cli
tool (av)
by which one can examine avro datafiles from the command line.
See avrow-cli repository for more details.
Installing avrow-cli:
cd avrow-cli
cargo install avrow-cli
Using avrow-cli (binary name is av
):
av read -d data.avro
The read
subcommand will print all rows in data.avro
to standard out in debug format.
Rust native types to Avro value mapping (via Serde)
Primitives
Rust native types (primitive types) | Avro (Value ) |
---|---|
(), Option::None |
null |
bool |
boolean |
i8, u8, i16, u16, i32, u32 |
int |
i64, u64 |
long |
f32 |
float |
f64 |
double |
&[u8], Vec<u8> |
bytes |
&str, String |
string |
Complex
Rust native types (complex types) | Avro |
---|---|
struct Foo {..} |
record |
enum Foo {A,B} (variants cannot have data in them) |
enum |
Vec<T> where T: Into<Value> |
array |
HashMap<String, T> where T: Into<Value> |
map |
T where T: Into<Value> |
union |
Vec<u8> : Length equal to size defined in schema |
fixed |
Todo
- Logical types support.
- Sorted reads.
- Single object encoding.
- Schema Registry as a trait - would allow avrow to read from and write to remote schema registries.
- AsyncRead + AsyncWrite Reader and Writers.
- Avro protocol message and RPC support.
- Benchmarks and optimizations.
Changelog
Please see the CHANGELOG for a release history.
Contributions
All kinds of contributions are welcome.
Head over to CONTRIBUTING.md for contribution guidelines.
Support
MSRV
Avrow works on stable Rust, starting 1.37+. It does not use any nightly features.
License
Dual licensed under either of Apache License, Version 2.0 or MIT license at your option.
Unless you explicitly state otherwise, any contribution intentionally submitted for inclusion in this crate by you, as defined in the Apache-2.0 license, shall be dual licensed as above, without any additional terms or conditions.
Dependencies
~2–4.5MB
~81K SLoC