hipblasztrmmstridedbatched Interface Reference

hipblasztrmmstridedbatched Interface Reference#

HIPFORT API Reference: hipfort_hipblas::hipblasztrmmstridedbatched Interface Reference

BLAS Level 3 API. More...

Public Member Functions
integer(kind(hipblas_status_success)) function	hipblasztrmmstridedbatched_ (handle, side, uplo, transA, diag, m, n, alpha, A, lda, strideA, B, ldb, strideB, batchCount)

integer(kind(hipblas_status_success)) function	hipblasztrmmstridedbatched_full_rank (handle, side, uplo, transA, diag, m, n, alpha, A, lda, strideA, B, ldb, strideB, batchCount)

integer(kind(hipblas_status_success)) function	hipblasztrmmstridedbatched_rank_0 (handle, side, uplo, transA, diag, m, n, alpha, A, lda, strideA, B, ldb, strideB, batchCount)

integer(kind(hipblas_status_success)) function	hipblasztrmmstridedbatched_rank_1 (handle, side, uplo, transA, diag, m, n, alpha, A, lda, strideA, B, ldb, strideB, batchCount)

Detailed Description

BLAS Level 3 API.

trmmStridedBatched performs one of the strided_batched matrix-matrix operations

B_i := alpha*op( A_i )*B_i, or B_i := alpha*B_i*op( A_i ) for i = 0, 1, ... batchCount -1

where alpha is a scalar, B_i is an m by n matrix, A_i is a unit, or non-unit, upper or lower triangular matrix and op( A_i ) is one of

op( A_i ) = A_i   or   op( A_i ) = A_i^T   or   op( A_i ) = A_i^H.

Parameters

[in]	handle	[hipblasHandle_t] handle to the hipblas library context queue.
[in]	side	[hipblasSideMode_t] Specifies whether op(A_i) multiplies B_i from the left or right as follows: HIPBLAS_SIDE_LEFT: B_i := alphaop( A_i )B_i. HIPBLAS_SIDE_RIGHT: B_i := alphaB_iop( A_i ).
[in]	uplo	[hipblasFillMode_t] Specifies whether the matrix A is an upper or lower triangular matrix as follows: HIPBLAS_FILL_MODE_UPPER: A is an upper triangular matrix. HIPBLAS_FILL_MODE_LOWER: A is a lower triangular matrix.
[in]	transA	[hipblasOperation_t] Specifies the form of op(A_i) to be used in the matrix multiplication as follows: HIPBLAS_OP_N: op(A_i) = A_i. HIPBLAS_OP_T: op(A_i) = A_i^T. HIPBLAS_OP_C: op(A_i) = A_i^H.
[in]	diag	[hipblasDiagType_t] Specifies whether or not A_i is unit triangular as follows: HIPBLAS_DIAG_UNIT: A_i is assumed to be unit triangular. HIPBLAS_DIAG_NON_UNIT: A_i is not assumed to be unit triangular.
[in]	m	[int] m specifies the number of rows of B_i. m >= 0.
[in]	n	[int] n specifies the number of columns of B_i. n >= 0.
[in]	alpha	alpha specifies the scalar alpha. When alpha is zero then A_i is not referenced and B_i need not be set before entry.
[in]	A	Device pointer to the first matrix A_0 on the GPU. Each A_i is of dimension ( lda, k ), where k is m when side == HIPBLAS_SIDE_LEFT and is n when side == HIPBLAS_SIDE_RIGHT.

When uplo == HIPBLAS_FILL_MODE_UPPER the leading k by k upper triangular part of the array A must contain the upper triangular matrix and the strictly lower triangular part of A is not referenced.

When uplo == HIPBLAS_FILL_MODE_LOWER the leading k by k lower triangular part of the array A must contain the lower triangular matrix and the strictly upper triangular part of A is not referenced.

Note that when diag == HIPBLAS_DIAG_UNIT the diagonal elements of A_i are not referenced either, but are assumed to be unity.

Parameters

[in]	lda	[int] lda specifies the first dimension of A. if side == HIPBLAS_SIDE_LEFT, lda >= max( 1, m ), if side == HIPBLAS_SIDE_RIGHT, lda >= max( 1, n ).
[in]	strideA	[hipblasStride] stride from the start of one matrix (A_i) and the next one (A_i+1)
[in,out]	B	Device pointer to the first matrix B_0 on the GPU. On entry, the leading m by n part of the array B_i must contain the matrix B_i, and on exit is overwritten by the transformed matrix.
[in]	ldb	[int] ldb specifies the first dimension of B_i. ldb >= max( 1, m ).
[in]	strideB	[hipblasStride] stride from the start of one matrix (B_i) and the next one (B_i+1)
[in]	batchCount	[int] number of instances i in the batch.

Member Function/Subroutine Documentation