Difference between revisions of "GPU610/DPS915 BLAS Documentation"

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There are 2 main functions to use
 
There are 2 main functions to use
  
==segmv==
+
Example Page @ [https://scs.senecac.on.ca/~gpu610/pages/content/lines.html GPU/DPS915 Course Site]
 +
 
 +
==sgemv==
 
* compute the matrix-vector product for a general matrix
 
* compute the matrix-vector product for a general matrix
  
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'''''lda'''''
 
'''''lda'''''
:is the leading dimension of the array specified by a. The leading dimension must be greater than zero. The leading dimension must be greater than or equal to 1 and greater than or equal to the value specified in m.
+
:is the leading dimension of the array specified by a. The leading dimension must be greater than zero. The leading dimension must be greater than or equal to 1 and greater than or equal to the value specified in m. See the 'Understanding Strides' section below for more information.
  
 
'''''x'''''
 
'''''x'''''
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:is the stride for vector y. It must not be zero.
 
:is the stride for vector y. It must not be zero.
  
==segmm==
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==sgemm==
 
*  perform combined matrix multiplication and addition for general matrices  
 
*  perform combined matrix multiplication and addition for general matrices  
  
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'''''lda'''''
 
'''''lda'''''
:is the leading dimension of the array specified by a. The leading dimension must be greater than zero. If transa is specified as 'N' or 'n', the leading dimension must be greater than or equal to 1. If transa is specified as 'T' or 't', the leading dimension must be greater than or equal to the value specified in m.
+
:is the leading dimension of the array specified by a. The leading dimension must be greater than zero. If transa is specified as 'N' or 'n', the leading dimension must be greater than or equal to 1. If transa is specified as 'T' or 't', the leading dimension must be greater than or equal to the value specified in m. See the 'Understanding Strides' section below for more information.
  
 
'''''B'''''
 
'''''B'''''
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'''''ldb'''''
 
'''''ldb'''''
:is the leading dimension of the array specified by b. The leading dimension must be greater than zero. If transb is specified as 'N' or 'n', the leading dimension must be greater than or equal to the value specified in m. If transa is specified as 'T' or 't', the leading dimension must be greater than or equal to the value specified in n.
+
:is the leading dimension of the array specified by b. The leading dimension must be greater than zero. If transb is specified as 'N' or 'n', the leading dimension must be greater than or equal to the value specified in m. If transa is specified as 'T' or 't', the leading dimension must be greater than or equal to the value specified in n. See the 'Understanding Strides' section below for more information.
  
 
'''''beta'''''
 
'''''beta'''''
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'''''ldc'''''
 
'''''ldc'''''
:is the leading dimension of the array specified by c. The leading dimension must be greater than zero. If transb is specified as 'N' or 'n', the leading dimension must be greater than or equal to 0 and greater than or equal to the value specified in l.
+
:is the leading dimension of the array specified by c. The leading dimension must be greater than zero. If transb is specified as 'N' or 'n', the leading dimension must be greater than or equal to 0 and greater than or equal to the value specified in l. See the 'Understanding Strides' section below for more information.
 +
 
 +
==Understanding Strides (lda, ldb, ldc)==
 +
 
 +
The elements of a matrix (i.e a 2D array) are stored contiguously in memory. However, they may be stored in either column-major or row-major fashion. The stride represents the distance in memory between elements in adjacent rows (if row-major) or in adjacent columns (if column-major). This means that the stride is usually equal to the number of rows/columns in the matrix.
 +
 
 +
<pre>
 +
Matrix A =
 +
[1 2 3]
 +
[4 5 6]
 +
</pre>
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Row-major stores values as {1,2,3,4,5,6}<br />
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Stride here is 3
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 +
Col-major stores values as {1, 4, 2, 5, 3, 6}<br />
 +
Stride here is 2
 +
<pre>
 +
Matrix B =
 +
[1 2 3]
 +
[4 5 6]
 +
[7 8 9]
 +
</pre>
 +
Col-major storage is {1, 4, 7, 2, 5, 8, 3, 6, 9}<br />
 +
Stride here is 3
 +
 
  
https://scs.senecac.on.ca/~gpu610/pages/content/lines.html
+
[http://www.physicsforums.com/showthread.php?t=543110 Source]

Latest revision as of 23:02, 3 October 2015

BLAS Documentation

Note: This information applies to the gsl_cblas library

There are 2 main functions to use

Example Page @ GPU/DPS915 Course Site

sgemv

  • compute the matrix-vector product for a general matrix

void cblas_sgemv (const enum CBLAS_ORDER order, const enum CBLAS_TRANSPOSE TransA, const int M, const int N, const float alpha, const float *A, const int lda, const float * x, const int incx, const float beta, float * y, const intincy)12 3


order

Whether matrices are row major order (C-Style) for column major order (Fortran-style). One of enum CblasRowMajor or CblasColMajor.

TransA

Whether to transpose matrix A. One of enum CblasNoTrans, CBlasTrans.

M

represents:
the number of rows in input matrix a
The number of rows must be greater than or equal to zero, and less than the leading dimension of the matrix a (specified in lda)

N

represents:
the number of columns in input matrix a
The number of columns must be greater than or equal to zero.

alpha

is the scaling constant for matrix a

A

is the input matrix of float (for sgemv) or double (for dgemv) values

lda

is the leading dimension of the array specified by a. The leading dimension must be greater than zero. The leading dimension must be greater than or equal to 1 and greater than or equal to the value specified in m. See the 'Understanding Strides' section below for more information.

x

is the input vector of float (for sgemv) or double (for dgemv) values.

incx

is the stride for vector x. It can have any value.

beta

is the scaling constant for vector y

y

is the output vector of float (for sgemv) or double (for dgemv) values.

incy

is the stride for vector y. It must not be zero.

sgemm

  • perform combined matrix multiplication and addition for general matrices

void cblas_sgemm (const enum CBLAS_ORDER Order, const enum CBLAS_TRANSPOSE TransA, const enum CBLAS_TRANSPOSE TransB, const int M, const int N, const int K, const float alpha, const float * A, const int lda, const float * B, const int ldb, const float beta, float * C, const intldc)12 3


Order

Whether matrices are row major order (C-Style) for column major order (Fortran-style). One of enum CblasRowMajor or CblasColMajor.

TransA

Whether to transpose matrix A. One of enum CblasNoTrans, CBlasTrans, CBlasConjTrans

TransB

Whether to transpose matrix B. One of enum CblasNoTrans, CBlasTrans, CBlasConjTrans.

M

is the number of Rows in matrices A and C
M must be greater than or equal to zero.

N

is the number of Columns in Matrices B and C

K

is the number of Columns in matrix A and Rows in matrix B

alpha

is the scaling constant for matrix a

A

is the input matrix a of float (for sgemm).

lda

is the leading dimension of the array specified by a. The leading dimension must be greater than zero. If transa is specified as 'N' or 'n', the leading dimension must be greater than or equal to 1. If transa is specified as 'T' or 't', the leading dimension must be greater than or equal to the value specified in m. See the 'Understanding Strides' section below for more information.

B

is the input matrix b of float (for sgemm).

ldb

is the leading dimension of the array specified by b. The leading dimension must be greater than zero. If transb is specified as 'N' or 'n', the leading dimension must be greater than or equal to the value specified in m. If transa is specified as 'T' or 't', the leading dimension must be greater than or equal to the value specified in n. See the 'Understanding Strides' section below for more information.

beta

is the scaling constant for matrix c

C

is the output matrix c of float (for sgemm) or double (for dgemm) values.

ldc

is the leading dimension of the array specified by c. The leading dimension must be greater than zero. If transb is specified as 'N' or 'n', the leading dimension must be greater than or equal to 0 and greater than or equal to the value specified in l. See the 'Understanding Strides' section below for more information.

Understanding Strides (lda, ldb, ldc)

The elements of a matrix (i.e a 2D array) are stored contiguously in memory. However, they may be stored in either column-major or row-major fashion. The stride represents the distance in memory between elements in adjacent rows (if row-major) or in adjacent columns (if column-major). This means that the stride is usually equal to the number of rows/columns in the matrix.

Matrix A =
[1 2 3]
[4 5 6]

Row-major stores values as {1,2,3,4,5,6}
Stride here is 3

Col-major stores values as {1, 4, 2, 5, 3, 6}
Stride here is 2

Matrix B =
[1 2 3]
[4 5 6]
[7 8 9]

Col-major storage is {1, 4, 7, 2, 5, 8, 3, 6, 9}
Stride here is 3


Source