📄 dcscsm_c.c
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/*-------------------------------------------------------|| NIST SPARSE BLAS v. 0.9 (Sat Jul 6 14:27:21 EDT 1996) || || Authors: || Karin A. Remington and Roldan Pozo || National Institute of Standards and Technology || || Based on the interface standard proposed in: | | "A Revised Proposal for a Sparse BLAS Toolkit" by || S. Carney and K. Wu -- University of Minnesota || M. Heroux and G. Li -- Cray Research | | R. Pozo and K.A. Remington -- NIST || || Contact: || Karin A. Remington, email: kremington@nist.gov |--------------------------------------------------------*/#include <stdlib.h>#include <stdio.h>#include "spblas.h"#include "dcscmtsl.h"#include "dcscvtsl.h"#include "dcsrmtsl.h"#include "dcsrvtsl.h"/* Sparse BLAS Toolkit interface routine: */void dcscsm( const int transa, const int m, const int n, const int unitd, const double dv[], const double alpha, const int descra[], const double val[], const int indx[], const int pntrb[], const int pntre[], const double b[], const int ldb, const double beta, double c[], const int ldc, double work[], const int lwork){/* ------------ begin interface description ------------ Toolkit interface: dcscsm -- compressed sparse column format triangular solve C <- alpha D A^(-1) B + beta C C <- alpha D A'^(-1) B + beta C C <- alpha A^(-1) D B + beta C C <- alpha A'^(-1) D B + beta C ( ' indicates matrix transpose) Arguments: int transa Indicates how to operate with the sparse matrix 0 : operate with matrix 1 : operate with transpose matrix int m Number of rows in matrix c int n Number of columns in matrix c int unitd Type of scaling: 1 : Identity matrix (argument dv[] is ignored) 2 : Scale on left (row scaling) 3 : Scale on right (column scaling) double alpha Scalar parameter double beta Scalar parameter int descra[] Descriptor argument. Nine element integer array descra[0] matrix structure 0 : general 1 : symmetric 2 : Hermitian 3 : Triangular 4 : Skew(Anti-Symmetric 5 : Diagonal descra[1] upper/lower triangular indicator 1 : lower 2 : upper descra[2] main diagonal type 0 : non-unit 1 : unit descra[3] Array base 0 : C/C++ compatible 1 : Fortran compatible descra[4] repeated indices? 0 : unknown 1 : no repeated indices double *val scalar array of length nnz containing matrix entries int *indx integer array of length nnz containing row indices int *pntrb integer array of length k such that pntrb(j)-pntrb(1) points to location in val of the first nonzero element in column j int *pntre integer array of length k such that pntre(j)-pntrb(1) points to location in val of the last nonzero element in column j double *b rectangular array with first dimension ldb double *c rectangular array with first dimension ldc double *work scratch array of length lwork. lwork should be at least (n*m) ------------ end interface description --------------*/int ind_base = descra[3]; if (lwork < m*n ){ printf("Insufficient work space for dcscsm.\n"); printf(" lwork must be at least (n*m) = %d \n",m*n); return; }if (alpha == 0.0) { ScaleArray_double(m, n, c, ldc, beta); return;} switch (descra[0]) {case 3: /* Matrix MUST be triangular, of course */ switch (transa) { case 0: switch ( 10*descra[1]+descra[2] ) { case 10: /* Lower triangular, non-unit diagonal */ switch (n) { case 1: /* Vec Mult */ if (alpha == 1) { if (beta == 1) { switch (unitd) { case 1: /* No scaling */ CSC_VecTriangSlvLD_CABC_double(m, val, indx, pntrb, pntre, b, c, work, ind_base); break; case 2: /* Left scaling */ CSC_VecTriangSlvLD_CDABC_double(m, dv, val, indx, pntrb, pntre, b, c, work, ind_base); break; case 3: /* Right scaling */ CSC_VecTriangSlvLD_CADBC_double(m, dv, val, indx, pntrb, pntre, b, c, work, ind_base); break; default: printf("Invalid argument unitd in dcscsm. Use 1-3. \n"); break; } /* end switch on unitd */#if (0) } else if (beta == -1) { switch (unitd) { case 1: /* No scaling */ CSC_VecTriangSlvLD_CABmC_double(m, val, indx, pntrb, pntre, b, c, work, ind_base); break; case 2: /* Left scaling */ CSC_VecTriangSlvLD_CDABmC_double(m, dv, val, indx, pntrb, pntre, b, c, work, ind_base); break; case 3: /* Right scaling */ CSC_VecTriangSlvLD_CADBmC_double(m, dv, val, indx, pntrb, pntre, b, c, work, ind_base); break; default: printf("Invalid argument unitd in dcscsm. Use 1-3. \n"); break; } /* end switch on unitd */#endif } else if (beta == 0) { switch (unitd) { case 1: /* No scaling */ CSC_VecTriangSlvLD_CAB_double(m, val, indx, pntrb, pntre, b, c, ind_base); break; case 2: /* Left scaling */ CSC_VecTriangSlvLD_CDAB_double(m, dv, val, indx, pntrb, pntre, b, c, work, ind_base); break; case 3: /* Right scaling */ CSC_VecTriangSlvLD_CADB_double(m, dv, val, indx, pntrb, pntre, b, c, ind_base); break; default: printf("Invalid argument unitd in dcscsm. Use 1-3. \n"); break; } /* end switch on unitd */ } else { /* beta is general nonzero */ switch (unitd) { case 1: /* No scaling */ CSC_VecTriangSlvLD_CABbC_double(m, val, indx, pntrb, pntre, b, beta, c, work, ind_base); break; case 2: /* Left scaling */ CSC_VecTriangSlvLD_CDABbC_double(m, dv, val, indx, pntrb, pntre, b, beta, c, work, ind_base); break; case 3: /* Right scaling */ CSC_VecTriangSlvLD_CADBbC_double(m, dv, val, indx, pntrb, pntre, b, beta, c, work, ind_base); break; default: printf("Invalid argument unitd in dcscsm. Use 1-3. \n"); break; } /* end switch on unitd */ } } else { /* alpha is general nonzero */ if (beta == 1) { switch (unitd) { case 1: /* No scaling */ CSC_VecTriangSlvLD_CaABC_double(m, alpha, val, indx, pntrb, pntre, b, c, work, ind_base); break; case 2: /* Left scaling */ CSC_VecTriangSlvLD_CaDABC_double(m, dv, alpha, val, indx, pntrb, pntre, b, c, work, ind_base); break; case 3: /* Right scaling */ CSC_VecTriangSlvLD_CaADBC_double(m, dv, alpha, val, indx, pntrb, pntre, b, c, work, ind_base); break; default: printf("Invalid argument unitd in dcscsm. Use 1-3. \n"); break; } /* end switch on unitd */#if (0) } else if (beta == -1) { switch (unitd) { case 1: /* No scaling */ CSC_VecTriangSlvLD_CaABmC_double(m, alpha, val, indx, pntrb, pntre, b, c, work, ind_base); break; case 2: /* Left scaling */ CSC_VecTriangSlvLD_CaDABmC_double(m, dv, alpha, val, indx, pntrb, pntre, b, c, work, ind_base); break; case 3: /* Right scaling */ CSC_VecTriangSlvLD_CaADBmC_double(m, dv, alpha, val, indx, pntrb, pntre, b, c, work, ind_base); break; default: printf("Invalid argument unitd in dcscsm. Use 1-3. \n"); break; } /* end switch on unitd */#endif } else if (beta == 0) { switch (unitd) { case 1: /* No scaling */ CSC_VecTriangSlvLD_CaAB_double(m, alpha, val, indx, pntrb, pntre, b, c, ind_base); break; case 2: /* Left scaling */ CSC_VecTriangSlvLD_CaDAB_double(m, dv, alpha, val, indx, pntrb, pntre, b, c, work, ind_base); break; case 3: /* Right scaling */ CSC_VecTriangSlvLD_CaADB_double(m, dv, alpha, val, indx, pntrb, pntre, b, c, ind_base); break; default: printf("Invalid argument unitd in dcscsm. Use 1-3. \n"); break; } /* end switch on unitd */ } else { /* beta is general nonzero */ switch (unitd) { case 1: /* No scaling */ CSC_VecTriangSlvLD_CaABbC_double(m, alpha, val, indx, pntrb, pntre, b, beta, c, work, ind_base); break; case 2: /* Left scaling */ CSC_VecTriangSlvLD_CaDABbC_double(m, dv, alpha, val, indx, pntrb, pntre, b, beta, c, work, ind_base); break; case 3: /* Right scaling */ CSC_VecTriangSlvLD_CaADBbC_double(m, dv, alpha, val, indx, pntrb, pntre, b, beta, c, work, ind_base); break; default: printf("Invalid argument unitd in dcscsm. Use 1-3. \n"); break; } /* end switch on unitd */ } } break; default: /* Mat Mult */ if (alpha == 1) { if (beta == 1) { switch (unitd) { case 1: /* No scaling */ CSC_MatTriangSlvLD_CABC_double(m, n, val, indx, pntrb, pntre, b, ldb, c, ldc, work, ind_base); break; case 2: /* Left scaling */ CSC_MatTriangSlvLD_CDABC_double(m, n, dv, val, indx, pntrb, pntre, b, ldb, c, ldc, work, ind_base); break; case 3: /* Right scaling */ CSC_MatTriangSlvLD_CADBC_double(m, n, dv, val, indx, pntrb, pntre, ⌨️ 快捷键说明
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