5 unstable releases
0.3.0 | Jul 24, 2024 |
---|---|
0.2.0 | Jul 21, 2024 |
0.1.3 | Jul 17, 2024 |
0.1.2 | Jul 16, 2024 |
0.1.1 | Jul 14, 2024 |
#253 in Data structures
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SLoC
blas-array2
Parameter-optional BLAS wrapper by ndarray::Array
(Ix1
or Ix2
) in rust.
And now the wind blows against my stride (leading dimension)
And I'm losing ground to enmies on all sides (
'L'
/'R'
)--- Dark Sun..., OP2 of PERSONA5 the Animation
Additional documents:
- Document for develop (link for github, link for docs.rs)
- List of BLAS wrapper structs (link for github, link for docs.rs)
- Efficiency demonstration (link for github, link for docs.rs)
After v0.2, this crate have implemented most planned functionalities. This crate is considered to be almost finished, and may not be actively maintained or updated. However, we also welcome issues and PRs to further increase new features or bug fixes.
Example of simple case
For simple illustration to this package, we perform $\mathbf{C} = \mathbf{A} \mathbf{B}$ (dgemm
):
use blas_array2::prelude::*;
use ndarray::prelude::*;
let a = array![[1.0, 2.0, 3.0], [3.0, 4.0, 5.0]];
let b = array![[-1.0, -2.0], [-3.0, -4.0], [-5.0, -6.0]];
let c_out = DGEMM::default()
.a(a.view())
.b(b.view())
.run().unwrap()
.into_owned();
println!("{:7.3?}", c_out);
Important points are
- using
::default()
to initialize struct; .a
,.b
are setter functions;.run().unwrap()
will perform computation;.into_owned()
will return result matrix asArray2<f64>
.
Functionality
Core Functionality
- BLAS2/BLAS3 Functionality: All (legacy) BLAS2/BLAS3 functions have been implemented.
- Optional Parameters: Convention similar to BLAST Fortran 95 binding or
scipy.linalg.blas
. Shape of matrix, and information of leading dimension will be checked and parsed properly, so users do not need to give these values. - Row-major Layout: Row-major support to Fortran 77 API (CBLAS functionality without CBLAS functions). You can safely use the default
libopenblas.so
shipped by debian withblas-sys
, where CBLAS is not automatically integrated, for example. - Generics: For example,
GEMM<F> where F: GEMMNum
forf32
,f64
,Complex<f32>
,Complex<f64>
types, in one generic (template) class. The same toSYRK
orGEMV
, etc. Original names such asDGEMM
,ZSYR2K
are also available. - Avoid explicit copy if possible: All input in row-major (or col-major) should not involve unnecessary transpositions with explicit copy. Further more, for some BLAS3 functions (GEMM, SYRK, TRMM, TRSM), if transposition does not involve
BLASConjTrans
, then mixed row-major or col-major also does not involve explicit transposition. Also note that in many cases, sub-matrices (sliced matrix) are also considered as row-major (or col-major), if data is stored contiguously in any dimension.
Other Functionality
- Arbitary Layout: Supports any stride that
ndarray
allows. - FFI: Currently, this crate uses its custom FFI binding in
blas_array2::ffi::blas
as BLAS binding, similar to blas-sys. Additionally, this crate plans to (or already) support some BLAS extensions and ILP64 (by cargo features).
Cargo Features
no_std
: Disable crate featurestd
will be compatible to#![no_std]
. However, currently thoseno_std
features will requirealloc
.ilp64
: By default, FFI binding is LP64 (32-bit integer). Crate featureilp64
will enable ILP64 (64-bit integer).- BLAS Extension: Some crate features will enable extension of BLAS.
gemmt
: GEMMTR (triangular output matrix multiplication). For OpenBLAS, version 0.3.27 is required (0.3.26 will fail some tests).
warn_on_copy
: If input matrix layout is not consistent, and explicit memory copy / transposition / complex conjugate is required, then a warning message will be printed on stderr.error_on_copy
: Similar towarn_on_copy
, but will directly raiseBLASError
.
Example of complicated case
For complicated situation, we perform $\mathbf{C} = \mathbf{A} \mathbf{B}^\mathrm{T}$ by SGEMM = GEMM<f32>
:
use blas_array2::prelude::*;
use ndarray::prelude::*;
let a = array![[1.0, 2.0, 3.0], [3.0, 4.0, 5.0]];
let b = array![[-1.0, -2.0], [-3.0, -4.0], [-5.0, -6.0]];
let mut c = Array::ones((3, 3).f());
let c_out = GEMM::<f32>::default()
.a(a.slice(s![.., ..2]))
.b(b.view())
.c(c.slice_mut(s![0..3;2, ..]))
.transb('T')
.beta(1.5)
.run()
.unwrap();
// one can get the result as an owned array
// but the result may not refer to the same memory location as `c`
println!("{:4.3?}", c_out.into_owned());
// this modification on `c` is actually performed in-place
// so if `c` is pre-defined, not calling `into_owned` could be more efficient
println!("{:4.3?}", c);
Important points are
.c
is (optional) output setter, which consumesArrayViewMut2<f64>
; this matrix will be modified in-place;.transb
,.beta
are optional setters; default oftransb
is'N'
, while default ofbeta
is zero, which are the same convention to scipy's implementation to python interface of BLAS. You may change these default values by feeding values into optional setters.- There are three ways to utilize output:
c_out.into_owned()
returns output (submatrix ifc
was sliced when passed into setter) asArray2<f64>
. Note that this output does not share the same memory address tomut c
.c_out.view()
orc_out.view_mut()
returns view ofc
; these views share the same memory address tomut c
.- Or you may use
c
directly. DGEMM operation is performed inplace if output matrixc
is given.
To make clear of the code above, this code spinnet performs matrix multiplication in-place
c = alpha * a * transpose(b) + beta * c
where
alpha = 1.0 (by default)
beta = 1.5
a = [[1.0, 2.0, ___],
[3.0, 4.0, ___]]
(sliced by `s![.., ..2]`)
b = [[-1.0, -2.0],
[-3.0, -4.0],
[-5.0, -6.0]]
c = [[1.0, 1.0, 1.0],
[___, ___, ___],
[1.0, 1.0, 1.0]]
(Column-major, sliced by `s![0..3;2, ..]`)
Output of c
is
[[-3.500, -9.500, -15.500],
[ 1.000, 1.000, 1.000],
[-9.500, -23.500, -37.500]]
Example of generic
After v0.3, this crate now supports (somehow) simple generic usage. For example of GEMM and TRMM,
use blas_array2::prelude::*;
use ndarray::prelude::*;
fn demo<F>()
where
F: GEMMNum + TRMMNum,
{
let a = Array2::<F>::ones((3, 3));
let b = Array2::<F>::ones((3, 3));
let mut c = GEMM::<F>::default().a(a.view()).b(b.view()).run().unwrap().into_owned();
TRMM::<F>::default().a(a.view()).b(c.view_mut()).run().unwrap();
println!("{:}", c);
}
fn main() {
demo::<f64>();
demo::<c64>();
}
This will give result of
[[9, 9, 9],
[6, 6, 6],
[3, 3, 3]]
[[9+0i, 9+0i, 9+0i],
[6+0i, 6+0i, 6+0i],
[3+0i, 3+0i, 3+0i]]
Installation
This crate is available on crates.io.
If there's any difficulties encountered in compilation, then please check if BLAS library is linked properly. May be resolved by declaring
RUSTFLAGS="-lopenblas"
if using OpenBLAS as backend.
Some features (such as ilp64
, gemmt
) requires BLAS to be compiled with 64-bit integer, or certain BLAS extensions.
Acknowledges
This project is developed as a side project from REST.
Dependencies
~2.5MB
~52K SLoC