1. blas
  2. Documentation
    1. Naming conventions for routines
    2. Vector copy routines
    3. BLAS level 1 routines
      1. Conventions
      2. Apply plane rotation
      3. Scale vector
      4. Swap the elements of two vectors
      5. Real vector dot product
      6. Complex vector dot product
      7. Hermitian vector dot product
      8. Vector multiply-add
      9. Vector multiply-add with optional offset
      10. Euclidean norm of a vector
      11. Sum of absolute values of the elements in a vector
      12. Sum of absolute values of the elements in a vector
    4. BLAS level 2 routines
      1. Conventions
      2. General matrix-vector multiply-add
      3. Banded matrix-vector multiply-add
      4. Hermitian matrix-vector multiply-add
      5. Hermitian banded matrix-vector multiply-add
      6. Symmetric matrix-vector multiply-add
      7. Banded symmetric matrix-vector multiply-add
      8. Triangular matrix-vector multiply-add
      9. Banded triangular matrix-vector multiply-add
      10. Triangular matrix equation solve
      11. Banded triangular matrix equation solve
      12. Rank 1 operation
      13. Rank 1 operation with optional offset
      14. Rank 1 operation on complex matrices and vectors
      15. Rank 1 operation on complex matrices and vectors
      16. Hermitian rank 1 operation
      17. Hermitian rank 2 operation
      18. Symmetric rank 1 operation
      19. Symmetric rank 2 operation
    5. BLAS level 3 routines
      1. Conventions
      2. General matrix multiply-add
      3. Symmetric matrix multiply-add
      4. Symmetric rank k operation
      5. Hermitian rank k operation
      6. Symmetric rank 2k operation
      7. Hermitian rank 2k operation
      8. Triangular matrix multiply
      9. Triangular matrix equation solve
  3. Examples
  4. About this egg
    1. Author
    2. Repository
    3. Version history
    4. License

blas

An interface to level 1, 2 and 3 BLAS linear algebra routines.

Documentation

Naming conventions for routines

Every routine in the BLAS library comes in four flavors, each prefixed by the letters S, D, C, and Z, respectively. Each letter indicates the format of input data:

In addition, each BLAS routine in this egg comes in three flavors:

Safe routines check the sizes of their input arguments. For example, if a routine is supplied arguments that indicate that an input matrix is of dimensions M-by-N, then the argument corresponding to that matrix is checked that it is of size M * N.

Pure routines do not alter their arguments in any way. A new matrix or vector is allocated for the return value of the routine.

Safe routines check the sizes of their input arguments. For example, if a routine is supplied arguments that indicate that an input matrix is of dimensions M-by-N, then the argument corresponding to that matrix is checked that it is of size M * N.

Destructive routines can modify some or all of their arguments. They are given names ending in exclamation mark. Please consult the BLAS documentation to determine which functions modify their input arguments.

Unsafe routines do not check the sizes of their input arguments. They invoke the corresponding BLAS routines directly. Unsafe routines do not have pure variants.

For example, function xGEMM (matrix-matrix multiplication) comes in the following variants:

BLAS name Safe, pure Safe, destructive Unsafe, destructive
SGEMM sgemm sgemm! unsafe-sgemm!
DGEMM dgemm dgemm! unsafe-dgemm!
CGEMM cgemm cgemm! unsafe-cgemm!
ZGEMM zgemm zgemm! unsafe-zgemm!

Vector copy routines

[procedure] scopy:: F32VECTOR -> F32VECTOR
[procedure] dcopy:: F64VECTOR -> F64VECTOR
[procedure] ccopy:: F32VECTOR -> F32VECTOR
[procedure] zcopy:: F64VECTOR -> F64VECTOR

These procedures return a copy of given input SRFI-4 vector. The returned vector is allocated with the corresponding SRFI-4 constructor, and the input vector is copied to it by the corresponding BLAS copy procedure.

BLAS level 1 routines

Conventions

The BLAS level 1 procedures in this egg differ from the actual routines they invoke by the position of the vector increment arguments (INCX and INCY). In this egg, these arguments are optional; the default value of INCX and INCY is 1.

In the procedure signatures below, these optional arguments are indicated by [ and ] (square brackets).

Apply plane rotation

[procedure] srot:: N * X * Y * C * S [INCX * INCY] -> F32VECTOR * F32VECTOR
[procedure] drot:: N * X * Y * C * S [INCX * INCY] -> F64VECTOR * F64VECTOR

xROT applies a plane rotation matrix to a sequence of ordered pairs: (x_i , y_i), for i = 1, 2, ..., n.

X and Y are vector of dimensions (N-1) * abs(incx) + 1 and (N-1) * abs(incy) + 1, respectively.

C and S are respectively the cosine and sine of the plane of rotation.

Scale vector

[procedure] sscal:: N * ALPHA * X [INCX] -> F32VECTOR
[procedure] dscal:: N * ALPHA * X [INCX] -> F64VECTOR
[procedure] cscal:: N * ALPHA * X [INCX] -> F32VECTOR
[procedure] zscal:: N * ALPHA * X [INCX] -> F64VECTOR

xSCAL scales a vector with a scalar: x := alpha * x.

Swap the elements of two vectors

[procedure] sswap:: N * X * Y [INCX * INCY] -> F32VECTOR
[procedure] dswap:: N * X * Y [INCX * INCY] -> F64VECTOR
[procedure] cswap:: N * X * Y [INCX * INCY] -> F32VECTOR
[procedure] zswap:: N * X * Y [INCX * INCY] -> F64VECTOR

xSWAP interchanges the elements of two vectors: x <-> y.

Real vector dot product

[procedure] sdot:: N * X * Y [INCX * INCY] -> NUMBER
[procedure] ddot:: N * X * Y [INCX * INCY] -> NUMBER

xDOT computes the dot product of two vectors of real values: dot := x'*y = \Sum_{i=1}^{n} (x_i * y_i).

Complex vector dot product

[procedure] cdotu:: N * X * Y [INCX * INCY] -> NUMBER
[procedure] zdotu:: N * X * Y [INCX * INCY] -> NUMBER

xDOTU computes the dot product of two vectors of complex values: dotu := x'*y = \Sum_{i=1}^{n} (x_i * y_i).

Hermitian vector dot product

[procedure] cdotc:: N * X * Y [INCX * INCY] -> NUMBER
[procedure] zdotc:: N * X * Y [INCX * INCY] -> NUMBER

xDOTC computes the dot product of the conjugates of two complex vectors: dotu := conjg(x')*y = \Sum_{i=1}^{n} (conjg(x_i) * y_i), for i = 1, 2, ..., n.

Vector multiply-add

[procedure] saxpy:: N * ALPHA * X * Y [INCX * INCY] -> F32VECTOR
[procedure] daxpy:: N * ALPHA * X * Y [INCX * INCY] -> F64VECTOR
[procedure] caxpy:: N * ALPHA * X * Y [INCX * INCY] -> F32VECTOR
[procedure] zaxpy:: N * ALPHA * X * Y [INCX * INCY] -> F64VECTOR

xAXPY adds a scalar multiple of a vector to another vector: y := alpha * x + y.

Vector multiply-add with optional offset

[procedure] siaxpy:: N * ALPHA * X * Y [INCX * INCY * XOFS * YOFS] -> F32VECTOR
[procedure] diaxpy:: N * ALPHA * X * Y [INCX * INCY * XOFS * YOFS] -> F64VECTOR
[procedure] ciaxpy:: N * ALPHA * X * Y [INCX * INCY * XOFS * YOFS] -> F32VECTOR
[procedure] ziaxpy:: N * ALPHA * X * Y [INCX * INCY * XOFS * YOFS] -> F64VECTOR

xIAXPY adds a scalar multiple of a vector to another vector, where the beginning of each vector argument can be offset: y[yofs:n] := alpha * x[xofs:n] + y[yofs:n].

Euclidean norm of a vector

[procedure] snrm2:: N * X [INCX] -> NUMBER
[procedure] dnrm2:: N * X [INCX] -> NUMBER
[procedure] cnrm2:: N * X [INCX] -> NUMBER
[procedure] znrm2:: N * X [INCX] -> NUMBER

xNRM2 computes the Euclidean (L2) norm of a vector.

Sum of absolute values of the elements in a vector

[procedure] sasum:: N * X [INCX] -> NUMBER
[procedure] dasum:: N * X [INCX] -> NUMBER
[procedure] casum:: N * X [INCX] -> NUMBER
[procedure] zasum:: N * X [INCX] -> NUMBER

xASUM sums the absolute values of the elements in a vector.

Sum of absolute values of the elements in a vector

[procedure] samax:: N * X [INCX] -> INDEX
[procedure] damax:: N * X [INCX] -> INDEX
[procedure] camax:: N * X [INCX] -> INDEX
[procedure] zamax:: N * X [INCX] -> INDEX

xAMAX searches a vector for the first occurrence of its maximum absolute value, and returns the index of that element.

BLAS level 2 routines

Conventions

The BLAS level 2 procedures in this egg differ from the actual routines they invoke by the position of the leading dimension argument (LDA) and the vector increment arguments (INCX and INCY). In this egg, these arguments are optional; the default value of LDAis the largest matrix dimension, depending on the semantics of the respective operation, and the default value of INCX and INCY is 1.

In the procedure signatures below, these optional arguments are indicated by [ and ] (square brackets).

Argument ORDER is one of RowMajor or ColMajor to indicate that the input and output matrices are in row-major or column-major form, respectively.

Where present, argument TRANS can be one of NoTrans or Trans to indicate whether the input matrix is to be transposed or not.

Where present, argument UPLO can be one of Upper or Lower to indicate whether the upper or lower triangular part of an input symmetric matrix is to referenced,or to specify the type of an input triangular matrix.

Where present, argument DIAG can be one of NonUnit or Unit to indicate whether an input triangular matrix is unit triangular or not.

General matrix-vector multiply-add

[procedure] sgemv:: ORDER * TRANS * M * N * ALPHA * A * X * BETA * Y [LDA * INCX * INCY] -> F32VECTOR
[procedure] dgemv:: ORDER * TRANS * M * N * ALPHA * A * X * BETA * Y [LDA * INCX * INCY] -> F64VECTOR
[procedure] cgemv:: ORDER * TRANS * M * N * ALPHA * A * X * BETA * Y [LDA * INCX * INCY] -> F32VECTOR
[procedure] zgemv:: ORDER * TRANS * M * N * ALPHA * A * X * BETA * Y [LDA * INCX * INCY] -> F64VECTOR

xGEMV performs the matrix-vector multiply-add operation of the form y := alpha*op( A )*x + beta*y, where op( X ) is one of op( A ) = A or op( A ) = A'.

ALPHA and BETA are scalars, and A is an M x N matrix.

X is a vector of size (1 + ( N - 1 ) * abs(INCX)) when argument TRANS is NoTrans, and (1 + ( M - 1 ) * abs(INCX)) otherwise. Y is a vector of size (1 + ( M - 1 ) * abs(INCY)) when argument TRANS is NoTrans, and (1 + ( N - 1 ) * abs(INCY)) otherwise.

Banded matrix-vector multiply-add

[procedure] sgbmv:: ORDER * TRANS * M * N * KL * KU * ALPHA * A * X * BETA * Y [LDA * INCX * INCY] -> F32VECTOR
[procedure] dgbmv:: ORDER * TRANS * M * N * KL * KU * ALPHA * A * X * BETA * Y [LDA * INCX * INCY] -> F64VECTOR
[procedure] cgbmv:: ORDER * TRANS * M * N * KL * KU * ALPHA * A * X * BETA * Y [LDA * INCX * INCY] -> F32VECTOR
[procedure] zgbmv:: ORDER * TRANS * M * N * KL * KU * ALPHA * A * X * BETA * Y [LDA * INCX * INCY] -> F64VECTOR

xGBMV performs the matrix-vector multiply-add operation of the form y := alpha*op( A )*x + beta*y, where op( X ) is one of op( A ) = A or op( A ) = A'.

ALPHA and BETA are scalars, and A is an M x N banded matrix, with KL sub-diagonals and KU super-diagonals.

X is a vector of size (1 + ( N - 1 ) * abs(INCX)) when argument TRANS is NoTrans, and (1 + ( M - 1 ) * abs(INCX)) otherwise. Y is a vector of size (1 + ( M - 1 ) * abs(INCY)) when argument TRANS is NoTrans, and (1 + ( N - 1 ) * abs(INCY)) otherwise.

Hermitian matrix-vector multiply-add

[procedure] chemv:: ORDER * UPLO * N * ALPHA * A * X * BETA * Y [LDA * INCX * INCY] -> F32VECTOR
[procedure] zhemv:: ORDER * UPLO * N * ALPHA * A * X * BETA * Y [LDA * INCX * INCY] -> F64VECTOR

xHEMV performs the matrix-vector multiply-add operation of the form y := alpha*op( A )*x + beta*y, where op( X ) is one of op( A ) = A or op( A ) = A'.

ALPHA and BETA are scalars, and A is an N x N Hermitian matrix.

X and Y are N element vectors.

Hermitian banded matrix-vector multiply-add

[procedure] chbmv:: ORDER * UPLO * N * K * ALPHA * A * X * BETA * Y [LDA * INCX * INCY] -> F32VECTOR
[procedure] zhbmv:: ORDER * UPLO * N * K * ALPHA * A * X * BETA * Y [LDA * INCX * INCY] -> F64VECTOR

xHBMV performs the matrix-vector multiply-add operation of the form y := alpha*op( A )*x + beta*y, where op( X ) is one of op( A ) = A or op( A ) = A'.

ALPHA and BETA are scalars, and A is an N x N Hermitian banded matrix, with K super-diagonals.

X and Y are N element vectors.

Symmetric matrix-vector multiply-add

[procedure] ssymv:: ORDER * UPLO * N * ALPHA * A * X * BETA * Y [LDA * INCX * INCY] -> F32VECTOR
[procedure] dsymv:: ORDER * UPLO * N * ALPHA * A * X * BETA * Y [LDA * INCX * INCY] -> F64VECTOR

xSYMV performs matrix-vector multiply-add operation of the form y := alpha*A*x + beta*y.

ALPHA and BETA are scalars, and A is an N x N symmetric matrix.

X and Y are N element vectors.

Banded symmetric matrix-vector multiply-add

[procedure] ssbmv:: ORDER * UPLO * N * K * ALPHA * A * X * BETA * Y [LDA * INCX * INCY] -> F32VECTOR
[procedure] dsbmv:: ORDER * UPLO * N * K * ALPHA * A * X * BETA * Y [LDA * INCX * INCY] -> F64VECTOR

xSBMV performs matrix-vector multiply-add operation of the form y := alpha*A*B + beta*y.

ALPHA and BETA are scalars, and A is an N x N symmetric banded matrix, with K super-diagonals.

X and Y are N element vectors.

Triangular matrix-vector multiply-add

[procedure] strmv:: ORDER * UPLO * TRANS * DIAG * N * A * X [LDA * INCX] -> F32VECTOR
[procedure] dtrmv:: ORDER * UPLO * TRANS * DIAG * N * A * X [LDA * INCX] -> F64VECTOR
[procedure] ctrmv:: ORDER * UPLO * TRANS * DIAG * N * A * X [LDA * INCX] -> F32VECTOR
[procedure] ztrmv:: ORDER * UPLO * TRANS * DIAG * N * A * X [LDA * INCX] -> F64VECTOR

xTRMV performs matrix-vector multiply-add operation of the form y := alpha*op( A )*x, where op ( A ) = A or op ( A ) = A'

ALPHA and BETA are scalars, and A is an N x N upper or lower triangular matrix.

X is a vector of length (1 + (n - 1) * abs(INCX)).

Banded triangular matrix-vector multiply-add

[procedure] stbmv:: ORDER * UPLO * TRANS * DIAG * N * K * A * X [LDA * INCX] -> F32VECTOR
[procedure] dtbmv:: ORDER * UPLO * TRANS * DIAG * N * K * A * X [LDA * INCX] -> F64VECTOR
[procedure] ctbmv:: ORDER * UPLO * TRANS * DIAG * N * K * A * X [LDA * INCX] -> F32VECTOR
[procedure] ztbmv:: ORDER * UPLO * TRANS * DIAG * N * K * A * X [LDA * INCX] -> F64VECTOR

xTBMV performs matrix-vector multiply-add operation of the form y := alpha*A*B + beta*y, where op ( A ) = A or op ( A ) = A'

ALPHA and BETA are scalars, and A is an N x N upper or lower triangular banded matrix, with K+1 diagonals.

X is a vector of length (1 + (n - 1) * abs(INCX)).

Triangular matrix equation solve

[procedure] strsv:: ORDER * UPLO * TRANS * DIAG * N * ALPHA * A * B * [LDA * INCB] -> F32VECTOR
[procedure] dtrsv:: ORDER * UPLO * TRANS * DIAG * N * A * B * [LDA * INCB] -> F64VECTOR
[procedure] ctrsv:: ORDER * UPLO * TRANS * DIAG * N * A * B * [LDA * INCB] -> F32VECTOR
[procedure] ztrsv:: ORDER * UPLO * TRANS * DIAG * N * A * B * [LDA * INCB] -> F64VECTOR

xTRSV solves one of the systems of equations A*x = b or A'*x = b.

ALPHA and BETA are scalars, A is a upper or lower triangular matrix, and B is a N element vector.

Banded triangular matrix equation solve

[procedure] stbsv:: ORDER * UPLO * TRANS * DIAG * N * K * A * B * [LDA * INCB] -> F32VECTOR
[procedure] dtbsv:: ORDER * UPLO * TRANS * DIAG * N * K * A * B * [LDA * INCB] -> F64VECTOR
[procedure] ctbsv:: ORDER * UPLO * TRANS * DIAG * N * K * A * B * [LDA * INCB] -> F32VECTOR
[procedure] ztbsv:: ORDER * UPLO * TRANS * DIAG * N * K * A * B * [LDA * INCB] -> F64VECTOR

xTBSV solves one of the systems of equations A*x = b or A'*x = b.

ALPHA and BETA are scalars, A is a upper or lower banded triangular matrix with K+1 diagonals, and B is a N element vector.

Rank 1 operation

[procedure] sger:: ORDER * M * N * ALPHA * X * Y * A [LDA * INCX * INCY] -> F32VECTOR
[procedure] dger:: ORDER * M * N * ALPHA * X * Y * A [LDA * INCX * INCY] -> F64VECTOR

xGER performs the rank 1 operation A := alpha*x*y' + A.

ALPHA is a scalar, X is an M element vector, Y is an N element vector, and A is an M x N matrix.

Rank 1 operation with optional offset

[procedure] siger:: ORDER * M * N * ALPHA * X * Y * A [LDA * INCX * INCY * XOFS * YOFS] -> F32VECTOR
[procedure] diger:: ORDER * M * N * ALPHA * X * Y * A [LDA * INCX * INCY * XOFS * YOFS] -> F64VECTOR

xIGER performs the rank 1 operation A := alpha*x[xofs:M]*y'[yofs:N] + A.

ALPHA is a scalar, X is an M element vector, Y is an N element vector, and A is an M x N matrix.

Rank 1 operation on complex matrices and vectors

[procedure] cgeru:: ORDER * M * N * ALPHA * X * Y * A [LDA * INCX * INCY] -> F32VECTOR
[procedure] zgeru:: ORDER * M * N * ALPHA * X * Y * A [LDA * INCX * INCY] -> F64VECTOR

xGERU performs the rank 1 operation A := alpha*x*y' + A.

ALPHA is a scalar, X is an M element vector, Y is an N element vector, and A is an M x N matrix.

Rank 1 operation on complex matrices and vectors

[procedure] cgerc:: ORDER * M * N * ALPHA * X * Y * A [LDA * INCX * INCY] -> F32VECTOR
[procedure] zgerc:: ORDER * M * N * ALPHA * X * Y * A [LDA * INCX * INCY] -> F64VECTOR

xGERC performs the rank 1 operation A := alpha*x*conjg(y') + A.

ALPHA is a scalar, X is an M element vector, Y is an N element vector, and A is an M x N matrix.

Hermitian rank 1 operation

[procedure] cher:: ORDER * UPLO * N * ALPHA * X * A [LDA * INCX] -> F32VECTOR
[procedure] zher:: ORDER * UPLO * N * ALPHA * X * A [LDA * INCX] -> F64VECTOR

xHER performs the Hermitian rank 1 operation A := alpha*x*conjg(x') + A.

ALPHA is a scalar, X is an N element vector, and A is an N x N Hermitian matrix.

Hermitian rank 2 operation

[procedure] cher2:: ORDER * UPLO * N * ALPHA * X * Y * A [LDA * INCX * INCY] -> F32VECTOR
[procedure] zher2:: ORDER * UPLO * N * ALPHA * X * Y * A [LDA * INCX * INCY] -> F64VECTOR

xHER2 performs the Hermitian rank 2 operation A := alpha*x*conjg(y') + conjg(alpha)*y*conjg(x') + A.

ALPHA is a scalar, X and Y are N element vectors, and A is an N x N Hermitian matrix.

Symmetric rank 1 operation

[procedure] ssyr:: ORDER * UPLO * N * ALPHA * X * A [LDA * INCX] -> F32VECTOR
[procedure] dsyr:: ORDER * UPLO * N * ALPHA * X * A [LDA * INCX] -> F64VECTOR

xSYR performs the symmetric rank 1 operation A := alpha*x*x' + A.

ALPHA is a scalar, X is an N element vector, and A is an N x N symmetric matrix.

Symmetric rank 2 operation

[procedure] ssyr2:: ORDER * UPLO * N * ALPHA * X * Y * A [LDA * INCX * INCY] -> F32VECTOR
[procedure] dsyr2:: ORDER * UPLO * N * ALPHA * X * Y * A [LDA * INCX * INCY] -> F64VECTOR

xSYR2 performs the symmetric rank 2 operation A := alpha*x*y' + alpha*y*x' + A.

ALPHA is a scalar, X and Y are N element vectors, and A is an N x N symmetric matrix.

BLAS level 3 routines

Conventions

The BLAS level 3 procedures in this egg differ from the actual routines they invoke by the position of the leading dimension arguments (LDA, LDB, and LDC). In this egg, these arguments are optional, and their default values are set to the largest matrix dimension, depending on the semantics of the respective operation.

In the procedure signatures below, these optional arguments are indicated by [ and ] (square brackets).

Argument ORDER is one of RowMajor or ColMajor to indicate that the input and output matrices are in row-major or column-major form, respectively.

Where present, arguments TRANS, TRANSA, TRANSB can be one of NoTrans or Trans to indicate whether the respective input matrices are to be transposed or not.

Where present, argument SIDE can be one of Left or Right to indicate whether an input symmetric matrix appears on the left or right in the respective operation.

Where present, argument UPLO can be one of Upper or Lower to indicate whether the upper or lower triangular part of an input symmetric matrix is to referenced,or to specify the type of an input triangular matrix.

Where present, argument DIAG can be one of NonUnit or Unit to indicate whether an input triangular matrix is unit triangular or not.

General matrix multiply-add

[procedure] sgemm:: ORDER * TRANSA * TRANSB * M * N * K * ALPHA * A * B * BETA * C [LDA * LDB * LDC] -> F32VECTOR
[procedure] dgemm:: ORDER * TRANSA * TRANSB * M * N * K * ALPHA * A * B * BETA * C [LDA * LDB * LDC] -> F64VECTOR
[procedure] cgemm:: ORDER * TRANSA * TRANSB * M * N * K * ALPHA * A * B * BETA * C [LDA * LDB * LDC] -> F32VECTOR
[procedure] zgemm:: ORDER * TRANSA * TRANSB * M * N * K * ALPHA * A * B * BETA * C [LDA * LDB * LDC] -> F64VECTOR

xGEMM performs matrix-matrix multiply-add operation of the form C := alpha*op( A )*op( B ) + beta*C, where op( X ) is one of op( X ) = X or op( X ) = X'.

ALPHA and BETA are scalars, and A, B and C are matrices, with op( A ) an M x K matrix, op( B ) a K x N matrix and C an M x N matrix.

Symmetric matrix multiply-add

[procedure] ssymm:: ORDER * SIDE * UPLO * M * N * ALPHA * A * B * BETA * C [LDA * LDB * LDC] -> F32VECTOR
[procedure] dsymm:: ORDER * SIDE * UPLO * M * N * ALPHA * A * B * BETA * C [LDA * LDB * LDC] -> F64VECTOR
[procedure] csymm:: ORDER * SIDE * UPLO * M * N * ALPHA * A * B * BETA * C [LDA * LDB * LDC] -> F32VECTOR
[procedure] zsymm:: ORDER * SIDE * UPLO * M * N * ALPHA * A * B * BETA * C [LDA * LDB * LDC] -> F64VECTOR

xSYMM performs matrix-matrix multiply-add operation of the form C := alpha*A*B + beta*C or C := alpha*B*A + beta*C.

ALPHA and BETA are scalars, A is a symmetric matrix, and B and C are M x N matrices.

Symmetric rank k operation

[procedure] ssyrk:: ORDER * UPLO * TRANS * N * K * ALPHA * A * BETA * C [LDA * LDB * LDC] -> F32VECTOR
[procedure] dsyrk:: ORDER * UPLO * TRANS * N * K * ALPHA * A * BETA * C [LDA * LDB * LDC] -> F64VECTOR
[procedure] csyrk:: ORDER * UPLO * TRANS * N * K * ALPHA * A * BETA * C [LDA * LDB * LDC] -> F64VECTOR
[procedure] zsyrk:: ORDER * UPLO * TRANS * N * K * ALPHA * A * BETA * C [LDA * LDB * LDC] -> F64VECTOR

xSYRK performs one of the symmetric rank k operations

{{C := alpha*A*A' + beta*C}} or {{C := alpha*A'*A + beta*C}}. 

ALPHA and BETA are scalars, A is an N x K or K x N matrix, and C is an N x N symmetric matrix.

Hermitian rank k operation

[procedure] cherk:: ORDER * UPLO * TRANS * N * K * ALPHA * A * BETA * C [LDA * LDB * LDC] -> F32VECTOR
[procedure] zherk:: ORDER * UPLO * TRANS * N * K * ALPHA * A * BETA * C [LDA * LDB * LDC] -> F64VECTOR

xHERK performs one of the hermitian rank k operations C := alpha*A*conjg(A') + beta*C or C := alpha*conjg(A')*A + beta*C.

ALPHA and BETA are scalars, A is an N x K or K x N matrix, and C is an N x N hermitian matrix.

Symmetric rank 2k operation

[procedure] ssyr2k:: ORDER * UPLO * TRANS * N * K * ALPHA * A * B * BETA * C [LDA * LDB * LDC] -> F32VECTOR
[procedure] dsyr2k:: ORDER * UPLO * TRANS * N * K * ALPHA * A * B * BETA * C [LDA * LDB * LDC] -> F64VECTOR
[procedure] csyr2k:: ORDER * UPLO * TRANS * N * K * ALPHA * A * B * BETA * C [LDA * LDB * LDC] -> F64VECTOR
[procedure] zsyr2k:: ORDER * UPLO * TRANS * N * K * ALPHA * A * B * BETA * C [LDA * LDB * LDC] -> F64VECTOR

xSYR2K performs one of the symmetric rank 2k operations C := alpha*A*B' + beta*C or C := alpha*B'*A + beta*C.

ALPHA and BETA are scalars, A and B are N x K or K x N matrices, and C is an N x N symmetric matrix.

Hermitian rank 2k operation

[procedure] cher2k:: ORDER * UPLO * TRANS * N * K * ALPHA * A * B * BETA * C [LDA * LDB * LDC] -> F32VECTOR
[procedure] zher2k:: ORDER * UPLO * TRANS * N * K * ALPHA * A * B * BETA * C [LDA * LDB * LDC] -> F64VECTOR

xHER2K performs one of the hermitian rank 2k operations C := alpha*A*conjg(B') + beta*C or C := alpha*conjg(B')*A + beta*C.

ALPHA and BETA are scalars, A and B are N x K or K x N matrices, and C is an N x N hermitian matrix.

Triangular matrix multiply

[procedure] strmm:: ORDER * SIDE * UPLO * TRANSA * DIAG * M * N * ALPHA * A * B [LDA * LDB] -> F32VECTOR
[procedure] dtrmm:: ORDER * SIDE * UPLO * TRANSA * DIAG * M * N * ALPHA * A * B [LDA * LDB] -> F64VECTOR
[procedure] ctrmm:: ORDER * SIDE * UPLO * TRANSA * DIAG * M * N * ALPHA * A * B [LDA * LDB] -> F32VECTOR
[procedure] ztrmm:: ORDER * SIDE * UPLO * TRANSA * DIAG * M * N * ALPHA * A * B [LDA * LDB] -> F64VECTOR

xTRMM performs matrix-matrix multiply operation of the form B := alpha*op( A )*B or B := alpha*B*op( A ).

ALPHA is a scalar, A is an upper or lower triangular matrix, and B is an M x N matrix.

Triangular matrix equation solve

[procedure] strsm:: ORDER * SIDE * UPLO * TRANSA * DIAG * M * N * ALPHA * A * B * [LDA * LDB * LDC] -> F32VECTOR
[procedure] dtrsm:: ORDER * SIDE * UPLO * TRANSA * DIAG * M * N * ALPHA * A * B * [LDA * LDB * LDC] -> F64VECTOR
[procedure] ctrsm:: ORDER * SIDE * UPLO * TRANSA * DIAG * M * N * ALPHA * A * B * [LDA * LDB * LDC] -> F32VECTOR
[procedure] ztrsm:: ORDER * SIDE * UPLO * TRANSA * DIAG * M * N * ALPHA * A * B * [LDA * LDB * LDC] -> F64VECTOR

xTRSM solves one of the matrix equations

{{op( A )*X = alpha*B}} or {{X*op( A ) = alpha*B}}. 

op( A ) is one of op( A ) = A or op( A ) = A'.

ALPHA and BETA are scalars, A is a upper or lower triangular matrix, and B is a M x N matrix.

Examples


(import srfi-4 blas)

(define order ColMajor)
(define transa NoTrans)

(define m 4)
(define n 4)

(define alpha 1)
(define beta 0)

(define a				; column-major order!
  (f64vector 1 2 3 4
	     1 1 1 1
	     3 4 5 6
	     5 6 7 8) )

(define x (f64vector 1 2 1 1))
(define y (f64vector 0 0 0 0))
   
(dgemv! order transa m n alpha a x beta y)

(print y)

About this egg

Author

Felix Winkelmann and Ivan Raikov

Repository

This egg is hosted on the CHICKEN Subversion repository:

https://anonymous@code.call-cc.org/svn/chicken-eggs/release/5/blas

If you want to check out the source code repository of this egg and you are not familiar with Subversion, see this page.

Version history

4.1
Fixed use of memq [thanks to Moritz Heidkamp]
4.0
Using bind instead of easyffi
3.1
Updated test script to return proper exit code
3.0
Eliminated reduntant blas: prefix from names of exported symbols
2.8
Eliminated use of noop
2.7
Switched to wiki documentation
2.6
Ported to Chicken 4
2.5
Build script updated for better cross-platform compatibility
2.4
Added iger procedures; fixed a bug in the default arguments of level 2 routines
2.3
Added iaxpy procedures; fixed a bug in the default arguments of level 1 routines
2.2
Fixed a bug in the renaming of C routines
2.1
Added eggdoc property to meta file
2.0
An overhaul of the library to introduce safe, unsafe, and pure variants of each routine
1.8
Added icopy procedures [by Ivan Raikov]
1.7
Support for Mac OS X added [by Will Farr]
1.6
Fixed bug in blas library test code
1.5
Added support for CLAPACK [by Ivan Raikov]
1.4
Added support for atlas CBLAS library [by Stu Glaser]
1.3
Tries to find a proper CBLAS library (currently only GSL)
1.2
Adapted to new FFI macro-names
1.1
Adapted to new setup scheme

License

Copyright (c) 2003-2006, Felix L. Winkelmann 
Copyright (c) 2007-2018 Ivan Raikov

All rights reserved.

Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:

  Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.

  Redistributions in binary form must reproduce the above copyright
notice, this list of conditions and the following disclaimer in the
documentation and/or other materials provided with the distribution.

  Neither the name of the author nor the names of its contributors may
be used to endorse or promote products derived from this software
without specific prior written permission.

THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND
CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING,
BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND
FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
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BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
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