#memory #pod #memory-safe #ffi #byte-array

no-std plain

A small Rust library that allows users to reinterpret data of certain types safely

4 releases (2 breaking)

Uses old Rust 2015

0.2.3 Nov 24, 2017
0.2.2 Nov 24, 2017
0.2.1 Jul 29, 2017
0.1.0 Apr 11, 2017
0.0.2 Apr 4, 2017

#248 in Data structures

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Used in 966 crates (27 directly)

MIT/Apache

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libplain

Build Status Current Crates.io Version Current Documentation

A small Rust library that allows users to interpret arrays of bytes as certain kinds of structures safely.

This crate provides an unsafe trait Plain, which the user of the crate uses to mark types for which operations of this library are safe. See Plain for the contractual obligation.

Other than that, everything else in this crate is perfectly safe to use as long as the Plain trait is not implemented on inadmissible types (similar to how Send and Sync in the standard library work).

Purpose

In low level systems development, it is sometimes necessary to interpret locations in memory as data structures. Functions of this crate serve to avoid pitfalls associated with that, without having to resort to big, full-featured (de)serialization libraries.

On the other hand, this crate contains no provisions when it comes to handling differences in encoding and byte ordering between platforms. As such, it is entirely unsuitable for processing external data such as file contents or network packets.

Examples

To start using the crate, simply do extern crate plain;.

If you want your plain types to have methods from this crate, also include use plain.Plain;.

Then it's just a matter of marking the right types and using them.


extern crate plain;
use plain::Plain;
use std::mem;


#[repr(C)]
#[derive(Default)]
struct ELF64Header {
    pub e_ident: [u8; 16],
    pub e_type: u16,
    pub e_machine: u16,
    pub e_version: u32,
    pub e_entry: u64,
    pub e_phoff: u64,
    pub e_shoff: u64,
    pub e_flags: u32,
    pub e_ehsize: u16,
    pub e_phentsize: u16,
    pub e_phnum: u16,
    pub e_shentsize: u16,
    pub e_shnum: u16,
    pub e_shstrndx: u16,
}

// SAFE: ELF64Header satisfies all the requirements of `Plain`.
unsafe impl Plain for ELF64Header {}

impl ELF64Header {
	fn from_bytes(buf: &[u8]) -> &ELF64Header {
			plain::from_bytes(buf).expect("The buffer is either too short or not aligned!")
		}

		fn from_mut_bytes(buf: &mut [u8]) -> &mut ELF64Header {
			plain::from_mut_bytes(buf).expect("The buffer is either too short or not aligned!")
		}

		fn copy_from_bytes(buf: &[u8]) -> ELF64Header {
			let mut h = ELF64Header::default();
			h.copy_from_bytes(buf).expect("The buffer is too short!");
			h
		}
}

# fn process_elf(elf: &ELF64Header) {}

// Conditional copying for ultimate hackery.
fn opportunistic_elf_processing(buf: &[u8]) {
	if plain::is_aligned::<ELF64Header>(buf) {
        // No copy necessary.
			let elf_ref = ELF64Header::from_bytes(buf);
			process_elf(elf_ref);
    } else {
        // Not aligned properly, copy to stack first.
			let elf = ELF64Header::copy_from_bytes(buf);
			process_elf(&elf);
    }
}

#[repr(C)]
#[derive(Default, Copy, Clone)]
struct ArrayEntry {
    pub name: [u8; 32],
    pub tag: u32,
    pub score: u32,
}

// SAFE: ArrayEntry satisfies all the requirements of `Plain`.
unsafe impl Plain for ArrayEntry {}

fn array_from_bytes(buf: &[u8]) -> &[ArrayEntry] {
    // NOTE: length is not a concern here,
    // since slice_from_bytes() can return empty slice.

    match plain::slice_from_bytes(buf) {
        Err(_) => panic!("The buffer is not aligned!"),
        Ok(arr) => arr,
    }
}

fn array_from_unaligned_bytes(buf: &[u8]) -> Vec<ArrayEntry> {
		let length = buf.len() / mem::size_of::<ArrayEntry>();
	let mut result = vec![ArrayEntry::default(); length];
 	(&mut result).copy_from_bytes(buf).expect("Cannot fail here.");
		result
}

# fn main() {}

Comparison to pod

pod is another crate created to help working with plain data. The major difference between pod and plain is scope.

plain currently provides only a few functions (+method wrappers) and its implementation involves very few lines of unsafe code. It can be used in no_std code. Also, it doesn't deal with endianness in any way, so it is only suitable for certain kinds of low-level work.

pod, on the other hand, provides a wide arsenal of various methods, most of which may be unnecessary for a given use case. It has dependencies on std as well as other crates, but among other things it provides tools to handle endianness properly.

In short, plain is much, much plainer...

No runtime deps