Crate binrw[−][src]
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binrw helps you write maintainable & easy-to-read declarative binary data readers and writers using ✨macro magic✨.
Adding #[binrw]
(or #[derive(BinRead, BinWrite)]
) to a struct or enum
generates a parser that can read that type from raw data and a writer that
can write it back to bytes:
use binrw::binrw; // #[binrw] attribute
use binrw::{BinReaderExt, BinWrite, io::Cursor}; // reading/writing utilities
#[binrw]
#[br(little)]
struct Point(i16, i16);
// Read a point from bytes
let point: Point = Cursor::new(b"\x80\x02\xe0\x01").read_le().unwrap();
assert_eq!(point, Point(640, 480));
// Write the point back to bytes
let mut writer = Cursor::new(Vec::new());
point.write_to(&mut writer).unwrap();
assert_eq!(&writer.into_inner()[..], b"\x80\x02\xe0\x01");
These types are composable, allowing you to use BinRead
/BinWrite
types within
others without any special logic:
#[derive(BinRead)]
#[br(big, magic = b"SHAP")]
enum Shape {
#[br(magic(0u8))] Rect {
left: i16, top: i16, right: i16, bottom: i16
},
#[br(magic(1u8))] Oval { origin: Point, rx: u8, ry: u8 }
}
let oval = Shape::read(&mut Cursor::new(b"SHAP\x01\x80\x02\xe0\x01\x2a\x15")).unwrap();
assert_eq!(oval, Shape::Oval { origin: Point(640, 480), rx: 42, ry: 21 });
Types that can’t implement BinRead
directly (e.g. types from third party
crates) can also be read using
free parser functions or by
mapping values.
Unlike “zero-copy” libraries, the in-memory representation of binrw structs doesn’t need to match the raw data. This can allow for better memory performance, especially on architectures where unaligned memory access is slow. Also, because data is never transmuted, there is no risk of undefined behaviour.
Input
BinRead
reads data from any object that implements io::Read
+
io::Seek
. This means that data can come from memory, network, disk, or
any other streaming source. It also means that low-level data operations
like buffering and compression are efficient and easy to implement.
BinRead
also includes an extension trait for reading types
directly from input objects:
use binrw::{BinReaderExt, io::Cursor};
let mut reader = Cursor::new(b"\x00\x0A");
let val: u16 = reader.read_be().unwrap();
assert_eq!(val, 10);
Directives
Handling things like magic numbers, byte ordering, and padding & alignment
is typical when working with binary data, so binrw includes a variety of
built-in directives for these common cases that can be applied
using the #[br]
attribute:
#[derive(BinRead)]
#[br(magic = b"DOG", assert(name.len() != 0))]
struct Dog {
bone_pile_count: u8,
#[br(big, count = bone_pile_count)]
bone_piles: Vec<u16>,
#[br(align_before = 0xA)]
name: NullString
}
let mut data = Cursor::new(b"DOG\x02\x00\x01\x00\x12\0\0Rudy\0");
let dog = Dog::read(&mut data).unwrap();
assert_eq!(dog.bone_piles, &[0x1, 0x12]);
assert_eq!(dog.name.into_string(), "Rudy")
Directives can also reference earlier fields by name. For tuple types,
earlier fields are addressable by self_N
, where N
is the index of the
field.
See the attribute module for the full list of available directives.
Built-in implementations
Implementations for all primitive data types, arrays, tuples, and standard
Rust types like Vec
are included, along with parsers for other
frequently used binary data patterns like
null-terminated strings and
indirect addressing using offsets. Convenient access into
bitfields is possible using crates like
modular-bitfield.
See the BinRead
trait for the full list of
built-in implementations.
no_std support
binrw supports no_std and includes a compatible subset of io
functionality. The alloc
crate is required.
Modules
Documentation-only module for binrw’s directives used in the #[br]
, #[bw]
, and #[brw]
attributes.
Type definitions for byte order handling.
Functions and type definitions for handling errors.
Type definitions for wrappers which represent a layer of indirection within a file.
Helper functions for reading data.
Traits, helpers, and type definitions for core I/O functionality.
The binrw prelude.
Type definitions for wrappers which parse interleaved data.
Macros
A macro for creating a binrw argument type
Structs
A wrapper type which represents a layer of indirection within a file.
A null-terminated 8-bit string.
A null-terminated 16-bit string.
A wrapper that stores a value’s position alongside the value.
Runtime options for
BinRead::read_options()
.
Arguments passed to the binread impl for Vec
Options for how data should be written
Enums
Traits
The BinRead
trait reads data from streams and converts it into objects.
Extension methods for reading BinRead
objects directly from a reader.
A trait for writing a given type to a writer
Extension methods for writing BinWrite
objects directly to a writer.
A trait indicating a struct can be constructured using a binrw named arguments builder.
A trait to allow for binrw types to provide a means of accessing their magic
Functions
A helper similar to #[br(count = N)]
which can be used with any collection.
Read items until a condition is met. The final item will be included.
Read items until the end of the file is hit.
Read items until a condition is met. The last item will not be included.
Type Definitions
A type alias for FilePtr
with 128-bit offsets.
Attribute Macros
The attribute version of the derive macro for BinRead
. Use this instead
of #[derive(BinRead)]
to enable temporary variables.
The attribute version of the derive macro for both BinRead
and BinWrite
. Use
instead of #[derive(BinRead, BinWrite)]
to enable temporary variables.
The attribute version of the derive macro for BinRead
. Use this instead
of #[derive(BinRead)]
to enable temporary variables.