Crates.io | gf256 |
lib.rs | gf256 |
version | 0.3.0 |
source | src |
created_at | 2021-11-08 05:33:43.408882 |
updated_at | 2022-05-09 10:14:05.78691 |
description | A Rust library containing Galois-field types and utilities |
homepage | |
repository | https://github.com/geky/gf256 |
max_upload_size | |
id | 478331 |
size | 813,221 |
A Rust library containing Galois-field types and utilities, leveraging hardware instructions when available.
This project started as a learning project to learn more about these "Galois-field thingies" after seeing them pop up in far too many subjects. So this crate may be more educational than practical.
use ::gf256::*;
let a = gf256(0xfd);
let b = gf256(0xfe);
let c = gf256(0xff);
assert_eq!(a*(b+c), a*b + a*c);
If you, like me, are interested in learning more about the fascinating utility of Galois-fields, take a look at the documentation of gf256's modules. I've tried to comprehensively capture what I've learned, hopefully provided a decent entry point into learning more about this useful field of math.
I also want to point out that the Rust examples in each module are completely functional and tested in CI thanks to Rust's doctest runner. Feel free to copy and tweak them to see what happens.
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Galois-fields, also called finite-fields, are a finite set of "numbers" (for some definition of number), that you can do "math" on (for some definition of math).
More specifically, Galois-fields support addition, subtraction, multiplication, and division, which follow a set of rules called "field axioms":
Subtraction is the inverse of addition, and division is the inverse of multiplication:
# use ::gf256::*;
#
# let a = gf256(1);
# let b = gf256(2);
assert_eq!((a+b)-b, a);
assert_eq!((a*b)/b, a);
Except for 0
, over which division is undefined:
# use ::gf256::*;
#
# let a = gf256(1);
assert_eq!(a.checked_div(gf256(0)), None);
There exists an element 0
that is the identity of addition, and an element
1
that is the identity of multiplication:
# use ::gf256::*;
#
# let a = gf256(1);
assert_eq!(a + gf256(0), a);
assert_eq!(a * gf256(1), a);
Addition and multiplication are associative:
# use ::gf256::*;
#
# let a = gf256(1);
# let b = gf256(2);
# let c = gf256(3);
assert_eq!(a+(b+c), (a+b)+c);
assert_eq!(a*(b*c), (a*b)*c);
Addition and multiplication are commutative:
# use ::gf256::*;
#
# let a = gf256(1);
# let b = gf256(2);
assert_eq!(a+b, b+a);
assert_eq!(a*b, b*a);
Multiplication is distributive over addition:
# use ::gf256::*;
#
# let a = gf256(1);
# let b = gf256(2);
# let c = gf256(3);
assert_eq!(a*(b+c), a*b + a*c);
Keep in mind these aren't your normal integer operations! The operations defined in a Galois-field types satisfy the above rules, but they may have unintuitive results:
# use ::gf256::*;
#
assert_eq!(gf256(1) + gf256(1), gf256(0));
This also means not all of math works in a Galois-field:
# use ::gf256::*;
#
# let a = gf256(1);
assert_ne!(a + a, gf256(2)*a);
Finite-fields can be very useful for applying high-level math onto machine
words, since machine words (u8
, u16
, u32
, etc) are inherently finite.
Normally we just ignore this until an integer overflow occurs and then we just
wave our hands around wailing that math has failed us.
In Rust this has the fun side-effect that the Galois-field types are incapable of overflowing, so Galois-field types don't need the set of overflowing operations normally found in other Rust types:
# use ::gf256::*;
#
let a = (u8::MAX).checked_add(1); // overflows :(
let b = gf256(u8::MAX) + gf256(1); // does not overflow :)
For more information on Galois-fields and how we construct them, see the
relevant documentation in gf
's module-level documentation.
gf256 contains a bit more than the Galois-field types. It also contains a number of other utilities that rely on the math around finite-fields:
use ::gf256::*;
let a = p32(0x1234);
let b = p32(0x5678);
assert_eq!(a+b, p32(0x444c));
assert_eq!(a*b, p32(0x05c58160));
use ::gf256::*;
let a = gf256(0xfd);
let b = gf256(0xfe);
let c = gf256(0xff);
assert_eq!(a*(b+c), a*b + a*c);
LFSR structs (requires feature lfsr
)
use gf256::lfsr::Lfsr16;
let mut lfsr = Lfsr16::new(1);
assert_eq!(lfsr.next(16), 0x0001);
assert_eq!(lfsr.next(16), 0x002d);
assert_eq!(lfsr.next(16), 0x0451);
assert_eq!(lfsr.next(16), 0xbdad);
assert_eq!(lfsr.prev(16), 0xbdad);
assert_eq!(lfsr.prev(16), 0x0451);
assert_eq!(lfsr.prev(16), 0x002d);
assert_eq!(lfsr.prev(16), 0x0001);
CRC functions (requires feature crc
)
use gf256::crc::crc32c;
assert_eq!(crc32c(b"Hello World!", 0), 0xfe6cf1dc);
Shamir secret-sharing functions (requires features shamir
and thread-rng
)
use gf256::shamir::shamir;
// generate shares
let shares = shamir::generate(b"secret secret secret!", 5, 4);
// <4 can't reconstruct secret
assert_ne!(shamir::reconstruct(&shares[..1]), b"secret secret secret!");
assert_ne!(shamir::reconstruct(&shares[..2]), b"secret secret secret!");
assert_ne!(shamir::reconstruct(&shares[..3]), b"secret secret secret!");
// >=4 can reconstruct secret
assert_eq!(shamir::reconstruct(&shares[..4]), b"secret secret secret!");
assert_eq!(shamir::reconstruct(&shares[..5]), b"secret secret secret!");
RAID-parity functions (requires feature raid
)
use gf256::raid::raid7;
// format
let mut buf = b"Hello World!".to_vec();
let mut parity1 = vec![0u8; 4];
let mut parity2 = vec![0u8; 4];
let mut parity3 = vec![0u8; 4];
let slices = buf.chunks(4).collect::<Vec<_>>();
raid7::format(&slices, &mut parity1, &mut parity2, &mut parity3);
// corrupt
buf[0..8].fill(b'x');
// repair
let mut slices = buf.chunks_mut(4).collect::<Vec<_>>();
raid7::repair(&mut slices, &mut parity1, &mut parity2, &mut parity3, &[0, 1]);
assert_eq!(&buf, b"Hello World!");
Reed-Solomon error-correction functions (requires feature rs
)
use gf256::rs::rs255w223;
// encode
let mut buf = b"Hello World!".to_vec();
buf.resize(buf.len()+32, 0u8);
rs255w223::encode(&mut buf);
// corrupt
buf[0..16].fill(b'x');
// correct
rs255w223::correct_errors(&mut buf)?;
assert_eq!(&buf[0..12], b"Hello World!");
# Ok::<(), rs255w223::Error>(())
Since this math depends on some rather arbitrary constants, each of these
utilities is available as both a normal Rust API, defined using reasonable
defaults, and as a highly configurable proc_macro
:
# pub use ::gf256::*;
use gf256::gf::gf;
#[gf(polynomial=0x11b, generator=0x3)]
type gf256_rijndael;
# fn main() {
let a = gf256_rijndael(0xfd);
let b = gf256_rijndael(0xfe);
let c = gf256_rijndael(0xff);
assert_eq!(a*(b+c), a*b + a*c);
# }
Most modern 64-bit hardware contains instructions for accelerating this sort of math. This usually comes in the form of a carry-less multiplication instruction.
Carry-less multiplication, also called polynomial multiplication and xor multiplication, is the multiplication analog for xor. Where traditional multiplication can be implemented as a series of shifts and adds, carry-less multiplication can be implemented as a series of shifts and xors:
Multiplication:
1011 * 1101 = 1011
+ 1011
+ 1011
----------
= 10001111
Carry-less multiplication:
1011 * 1101 = 1011
^ 1011
^ 1011
----------
= 01111111
64-bit carry-less multiplication is available on x86_64 with the
pclmulqdq
, and on aarch64 with the slightly less wordy
pmull
instruction.
gf256 takes advantage of these instructions when possible. However, at the time
of writing, pmull
support in Rust is only available on nightly.
# use ::gf256::*;
#
// uses carry-less multiplication instructions if available
let a = p32(0b1011);
let b = p32(0b1101);
assert_eq!(a * b, p32(0b01111111));
gf256 also exposes the flag [HAS_XMUL
], which can be used to choose
algorithms based on whether or not hardware accelerated carry-less
multiplication is available:
# use gf256::p::p32;
#
let a = p32(0b1011);
let b = if gf256::HAS_XMUL {
a * p32(0b11)
} else {
(a << 1) ^ a
};
gf256 also leverages the hardware accelerated carry-less addition instructions, sometimes called polynomial addition, or simply xor. But this is much less notable.
const fn
supportDue to the use of traits and intrinsics, it's not possible to use the
polynomial/Galois-field operators in const fns
.
As an alternative, gf256 provides a set of "naive" functions, which provide less efficient, well, naive, implementations that can be used in const fns.
These are very useful for calculating complex constants at compile-time, which is common in these sort of algorithms:
# use ::gf256::*;
#
const POLYNOMIAL: p64 = p64(0x104c11db7);
const CRC_TABLE: [u32; 256] = {
let mut table = [0; 256];
let mut i = 0;
while i < table.len() {
let x = (i as u32).reverse_bits();
let x = p64((x as u64) << 8).naive_rem(POLYNOMIAL).0 as u32;
table[i] = x.reverse_bits();
i += 1;
}
table
};
no_std
supportgf256 is just a pile of math, so it is mostly no_std
compatible.
The exceptions are the extra utilities rs
and shamir
, which
currently require alloc
.
gf256 provides "best-effort" constant-time implementations for certain useful operations. Though it should be emphasized this was primarily an educational project, so the constant-time properties should be externally evaluated before use, and you use this library at your own risk.
Polynomial multiplication
Polynomial multiplication in gf256 should always be constant-time.
The assumption is that any hardware accelerated carry-less multiplication instructions complete in a fixed number of cycles, which is generally true.
If carry-less multiplication instructions are not available, a branch-less loop implementation of carry-less multiplication is used.
Galois-field operations
Galois-field types in barret
mode rely only on carry-less multiplication
and xors, and should always execute in constant time.
The other Galois-field implementations are NOT constant-time due to the use of lookup tables, which may be susceptible to cache-timing attacks. Note that the default Galois-field types likely use a table-based implementation.
You will need to declare a custom Galois-field type using barret
mode if you
want constant-time finite-field operations:
# pub use ::gf256::*;
use gf256::gf::gf;
#[gf(polynomial=0x11b, generator=0x3, barret)]
type gf256_rijndael;
#
# fn main() {}
Shamir secret-sharing
The default Shamir secret-sharing implementation internally uses a custom
Galois-field type in barret
mode and should (keyword should) be
constant-time.
no-xmul
- Disables carry-less multiplication instructions, forcing the use
of naive bitwise implementations
This is mostly available for testing/benchmarking purposes.
no-tables
- Disables lookup tables, relying only on hardware instructions
or naive implementations
This may be useful on memory constrained devices
small-tables
- Limits lookup tables to "small tables", tables with <=16
elements
This provides a compromise between full 256-byte tables and no-tables, which may be useful on memory constrained devices
thread-rng
- Enables features that depend on ThreadRng
Note this requires std
This is used to provide a default Rng implementation for Shamir's secret-sharing implementations
lfsr
- Makes LFSR structs and macros available
crc
- Makes CRC functions and macros available
shamir
- Makes Shamir secret-sharing functions and macros available
Note this requires alloc
and rand
You may also want to enable the thread-rng
feature, which is required for
a default rng
raid
- Makes RAID-parity functions and macros available
rs
- Makes Reed-Solomon functions and macros available
Note this requires alloc
gf256 comes with a number of tests implemented in Rust's test runner, these can be run with make:
make test
Additionally all of the code samples in these docs can be ran with Rust's doctest runner:
make docs
gf256 also has a number of benchmarks implemented in Criterion. These were used to determine the best default implementations, and can be ran with make:
make bench
A full summary of the benchmark results can be found in BENCHMARKS.md.