// This file is part of Eigen, a lightweight C++ template library // for linear algebra. // // Copyright (C) 2009-2010 Gael Guennebaud <gael.guennebaud@inria.fr> // // This Source Code Form is subject to the terms of the Mozilla // Public License v. 2.0. If a copy of the MPL was not distributed // with this file, You can obtain one at http://mozilla.org/MPL/2.0/. #include "common.h" int EIGEN_BLAS_FUNC(gemm)(char *opa, char *opb, int *m, int *n, int *k, RealScalar *palpha, RealScalar *pa, int *lda, RealScalar *pb, int *ldb, RealScalar *pbeta, RealScalar *pc, int *ldc) { // std::cerr << "in gemm " << *opa << " " << *opb << " " << *m << " " << *n << " " << *k << " " << *lda << " " << *ldb << " " << *ldc << " " << *palpha << " " << *pbeta << "\n"; typedef void (*functype)(DenseIndex, DenseIndex, DenseIndex, const Scalar *, DenseIndex, const Scalar *, DenseIndex, Scalar *, DenseIndex, Scalar, internal::level3_blocking<Scalar,Scalar>&, Eigen::internal::GemmParallelInfo<DenseIndex>*); static functype func[12]; static bool init = false; if(!init) { for(int k=0; k<12; ++k) func[k] = 0; func[NOTR | (NOTR << 2)] = (internal::general_matrix_matrix_product<DenseIndex,Scalar,ColMajor,false,Scalar,ColMajor,false,ColMajor>::run); func[TR | (NOTR << 2)] = (internal::general_matrix_matrix_product<DenseIndex,Scalar,RowMajor,false,Scalar,ColMajor,false,ColMajor>::run); func[ADJ | (NOTR << 2)] = (internal::general_matrix_matrix_product<DenseIndex,Scalar,RowMajor,Conj, Scalar,ColMajor,false,ColMajor>::run); func[NOTR | (TR << 2)] = (internal::general_matrix_matrix_product<DenseIndex,Scalar,ColMajor,false,Scalar,RowMajor,false,ColMajor>::run); func[TR | (TR << 2)] = (internal::general_matrix_matrix_product<DenseIndex,Scalar,RowMajor,false,Scalar,RowMajor,false,ColMajor>::run); func[ADJ | (TR << 2)] = (internal::general_matrix_matrix_product<DenseIndex,Scalar,RowMajor,Conj, Scalar,RowMajor,false,ColMajor>::run); func[NOTR | (ADJ << 2)] = (internal::general_matrix_matrix_product<DenseIndex,Scalar,ColMajor,false,Scalar,RowMajor,Conj, ColMajor>::run); func[TR | (ADJ << 2)] = (internal::general_matrix_matrix_product<DenseIndex,Scalar,RowMajor,false,Scalar,RowMajor,Conj, ColMajor>::run); func[ADJ | (ADJ << 2)] = (internal::general_matrix_matrix_product<DenseIndex,Scalar,RowMajor,Conj, Scalar,RowMajor,Conj, ColMajor>::run); init = true; } Scalar* a = reinterpret_cast<Scalar*>(pa); Scalar* b = reinterpret_cast<Scalar*>(pb); Scalar* c = reinterpret_cast<Scalar*>(pc); Scalar alpha = *reinterpret_cast<Scalar*>(palpha); Scalar beta = *reinterpret_cast<Scalar*>(pbeta); int info = 0; if(OP(*opa)==INVALID) info = 1; else if(OP(*opb)==INVALID) info = 2; else if(*m<0) info = 3; else if(*n<0) info = 4; else if(*k<0) info = 5; else if(*lda<std::max(1,(OP(*opa)==NOTR)?*m:*k)) info = 8; else if(*ldb<std::max(1,(OP(*opb)==NOTR)?*k:*n)) info = 10; else if(*ldc<std::max(1,*m)) info = 13; if(info) return xerbla_(SCALAR_SUFFIX_UP"GEMM ",&info,6); if(beta!=Scalar(1)) { if(beta==Scalar(0)) matrix(c, *m, *n, *ldc).setZero(); else matrix(c, *m, *n, *ldc) *= beta; } internal::gemm_blocking_space<ColMajor,Scalar,Scalar,Dynamic,Dynamic,Dynamic> blocking(*m,*n,*k); int code = OP(*opa) | (OP(*opb) << 2); func[code](*m, *n, *k, a, *lda, b, *ldb, c, *ldc, alpha, blocking, 0); return 0; } int EIGEN_BLAS_FUNC(trsm)(char *side, char *uplo, char *opa, char *diag, int *m, int *n, RealScalar *palpha, RealScalar *pa, int *lda, RealScalar *pb, int *ldb) { // std::cerr << "in trsm " << *side << " " << *uplo << " " << *opa << " " << *diag << " " << *m << "," << *n << " " << *palpha << " " << *lda << " " << *ldb<< "\n"; typedef void (*functype)(DenseIndex, DenseIndex, const Scalar *, DenseIndex, Scalar *, DenseIndex, internal::level3_blocking<Scalar,Scalar>&); static functype func[32]; static bool init = false; if(!init) { for(int k=0; k<32; ++k) func[k] = 0; func[NOTR | (LEFT << 2) | (UP << 3) | (NUNIT << 4)] = (internal::triangular_solve_matrix<Scalar,DenseIndex,OnTheLeft, Upper|0, false,ColMajor,ColMajor>::run); func[TR | (LEFT << 2) | (UP << 3) | (NUNIT << 4)] = (internal::triangular_solve_matrix<Scalar,DenseIndex,OnTheLeft, Lower|0, false,RowMajor,ColMajor>::run); func[ADJ | (LEFT << 2) | (UP << 3) | (NUNIT << 4)] = (internal::triangular_solve_matrix<Scalar,DenseIndex,OnTheLeft, Lower|0, Conj, RowMajor,ColMajor>::run); func[NOTR | (RIGHT << 2) | (UP << 3) | (NUNIT << 4)] = (internal::triangular_solve_matrix<Scalar,DenseIndex,OnTheRight,Upper|0, false,ColMajor,ColMajor>::run); func[TR | (RIGHT << 2) | (UP << 3) | (NUNIT << 4)] = (internal::triangular_solve_matrix<Scalar,DenseIndex,OnTheRight,Lower|0, false,RowMajor,ColMajor>::run); func[ADJ | (RIGHT << 2) | (UP << 3) | (NUNIT << 4)] = (internal::triangular_solve_matrix<Scalar,DenseIndex,OnTheRight,Lower|0, Conj, RowMajor,ColMajor>::run); func[NOTR | (LEFT << 2) | (LO << 3) | (NUNIT << 4)] = (internal::triangular_solve_matrix<Scalar,DenseIndex,OnTheLeft, Lower|0, false,ColMajor,ColMajor>::run); func[TR | (LEFT << 2) | (LO << 3) | (NUNIT << 4)] = (internal::triangular_solve_matrix<Scalar,DenseIndex,OnTheLeft, Upper|0, false,RowMajor,ColMajor>::run); func[ADJ | (LEFT << 2) | (LO << 3) | (NUNIT << 4)] = (internal::triangular_solve_matrix<Scalar,DenseIndex,OnTheLeft, Upper|0, Conj, RowMajor,ColMajor>::run); func[NOTR | (RIGHT << 2) | (LO << 3) | (NUNIT << 4)] = (internal::triangular_solve_matrix<Scalar,DenseIndex,OnTheRight,Lower|0, false,ColMajor,ColMajor>::run); func[TR | (RIGHT << 2) | (LO << 3) | (NUNIT << 4)] = (internal::triangular_solve_matrix<Scalar,DenseIndex,OnTheRight,Upper|0, false,RowMajor,ColMajor>::run); func[ADJ | (RIGHT << 2) | (LO << 3) | (NUNIT << 4)] = (internal::triangular_solve_matrix<Scalar,DenseIndex,OnTheRight,Upper|0, Conj, RowMajor,ColMajor>::run); func[NOTR | (LEFT << 2) | (UP << 3) | (UNIT << 4)] = (internal::triangular_solve_matrix<Scalar,DenseIndex,OnTheLeft, Upper|UnitDiag,false,ColMajor,ColMajor>::run); func[TR | (LEFT << 2) | (UP << 3) | (UNIT << 4)] = (internal::triangular_solve_matrix<Scalar,DenseIndex,OnTheLeft, Lower|UnitDiag,false,RowMajor,ColMajor>::run); func[ADJ | (LEFT << 2) | (UP << 3) | (UNIT << 4)] = (internal::triangular_solve_matrix<Scalar,DenseIndex,OnTheLeft, Lower|UnitDiag,Conj, RowMajor,ColMajor>::run); func[NOTR | (RIGHT << 2) | (UP << 3) | (UNIT << 4)] = (internal::triangular_solve_matrix<Scalar,DenseIndex,OnTheRight,Upper|UnitDiag,false,ColMajor,ColMajor>::run); func[TR | (RIGHT << 2) | (UP << 3) | (UNIT << 4)] = (internal::triangular_solve_matrix<Scalar,DenseIndex,OnTheRight,Lower|UnitDiag,false,RowMajor,ColMajor>::run); func[ADJ | (RIGHT << 2) | (UP << 3) | (UNIT << 4)] = (internal::triangular_solve_matrix<Scalar,DenseIndex,OnTheRight,Lower|UnitDiag,Conj, RowMajor,ColMajor>::run); func[NOTR | (LEFT << 2) | (LO << 3) | (UNIT << 4)] = (internal::triangular_solve_matrix<Scalar,DenseIndex,OnTheLeft, Lower|UnitDiag,false,ColMajor,ColMajor>::run); func[TR | (LEFT << 2) | (LO << 3) | (UNIT << 4)] = (internal::triangular_solve_matrix<Scalar,DenseIndex,OnTheLeft, Upper|UnitDiag,false,RowMajor,ColMajor>::run); func[ADJ | (LEFT << 2) | (LO << 3) | (UNIT << 4)] = (internal::triangular_solve_matrix<Scalar,DenseIndex,OnTheLeft, Upper|UnitDiag,Conj, RowMajor,ColMajor>::run); func[NOTR | (RIGHT << 2) | (LO << 3) | (UNIT << 4)] = (internal::triangular_solve_matrix<Scalar,DenseIndex,OnTheRight,Lower|UnitDiag,false,ColMajor,ColMajor>::run); func[TR | (RIGHT << 2) | (LO << 3) | (UNIT << 4)] = (internal::triangular_solve_matrix<Scalar,DenseIndex,OnTheRight,Upper|UnitDiag,false,RowMajor,ColMajor>::run); func[ADJ | (RIGHT << 2) | (LO << 3) | (UNIT << 4)] = (internal::triangular_solve_matrix<Scalar,DenseIndex,OnTheRight,Upper|UnitDiag,Conj, RowMajor,ColMajor>::run); init = true; } Scalar* a = reinterpret_cast<Scalar*>(pa); Scalar* b = reinterpret_cast<Scalar*>(pb); Scalar alpha = *reinterpret_cast<Scalar*>(palpha); int info = 0; if(SIDE(*side)==INVALID) info = 1; else if(UPLO(*uplo)==INVALID) info = 2; else if(OP(*opa)==INVALID) info = 3; else if(DIAG(*diag)==INVALID) info = 4; else if(*m<0) info = 5; else if(*n<0) info = 6; else if(*lda<std::max(1,(SIDE(*side)==LEFT)?*m:*n)) info = 9; else if(*ldb<std::max(1,*m)) info = 11; if(info) return xerbla_(SCALAR_SUFFIX_UP"TRSM ",&info,6); int code = OP(*opa) | (SIDE(*side) << 2) | (UPLO(*uplo) << 3) | (DIAG(*diag) << 4); if(SIDE(*side)==LEFT) { internal::gemm_blocking_space<ColMajor,Scalar,Scalar,Dynamic,Dynamic,Dynamic,4> blocking(*m,*n,*m); func[code](*m, *n, a, *lda, b, *ldb, blocking); } else { internal::gemm_blocking_space<ColMajor,Scalar,Scalar,Dynamic,Dynamic,Dynamic,4> blocking(*m,*n,*n); func[code](*n, *m, a, *lda, b, *ldb, blocking); } if(alpha!=Scalar(1)) matrix(b,*m,*n,*ldb) *= alpha; return 0; } // b = alpha*op(a)*b for side = 'L'or'l' // b = alpha*b*op(a) for side = 'R'or'r' int EIGEN_BLAS_FUNC(trmm)(char *side, char *uplo, char *opa, char *diag, int *m, int *n, RealScalar *palpha, RealScalar *pa, int *lda, RealScalar *pb, int *ldb) { // std::cerr << "in trmm " << *side << " " << *uplo << " " << *opa << " " << *diag << " " << *m << " " << *n << " " << *lda << " " << *ldb << " " << *palpha << "\n"; typedef void (*functype)(DenseIndex, DenseIndex, DenseIndex, const Scalar *, DenseIndex, const Scalar *, DenseIndex, Scalar *, DenseIndex, const Scalar&, internal::level3_blocking<Scalar,Scalar>&); static functype func[32]; static bool init = false; if(!init) { for(int k=0; k<32; ++k) func[k] = 0; func[NOTR | (LEFT << 2) | (UP << 3) | (NUNIT << 4)] = (internal::product_triangular_matrix_matrix<Scalar,DenseIndex,Upper|0, true, ColMajor,false,ColMajor,false,ColMajor>::run); func[TR | (LEFT << 2) | (UP << 3) | (NUNIT << 4)] = (internal::product_triangular_matrix_matrix<Scalar,DenseIndex,Lower|0, true, RowMajor,false,ColMajor,false,ColMajor>::run); func[ADJ | (LEFT << 2) | (UP << 3) | (NUNIT << 4)] = (internal::product_triangular_matrix_matrix<Scalar,DenseIndex,Lower|0, true, RowMajor,Conj, ColMajor,false,ColMajor>::run); func[NOTR | (RIGHT << 2) | (UP << 3) | (NUNIT << 4)] = (internal::product_triangular_matrix_matrix<Scalar,DenseIndex,Upper|0, false,ColMajor,false,ColMajor,false,ColMajor>::run); func[TR | (RIGHT << 2) | (UP << 3) | (NUNIT << 4)] = (internal::product_triangular_matrix_matrix<Scalar,DenseIndex,Lower|0, false,ColMajor,false,RowMajor,false,ColMajor>::run); func[ADJ | (RIGHT << 2) | (UP << 3) | (NUNIT << 4)] = (internal::product_triangular_matrix_matrix<Scalar,DenseIndex,Lower|0, false,ColMajor,false,RowMajor,Conj, ColMajor>::run); func[NOTR | (LEFT << 2) | (LO << 3) | (NUNIT << 4)] = (internal::product_triangular_matrix_matrix<Scalar,DenseIndex,Lower|0, true, ColMajor,false,ColMajor,false,ColMajor>::run); func[TR | (LEFT << 2) | (LO << 3) | (NUNIT << 4)] = (internal::product_triangular_matrix_matrix<Scalar,DenseIndex,Upper|0, true, RowMajor,false,ColMajor,false,ColMajor>::run); func[ADJ | (LEFT << 2) | (LO << 3) | (NUNIT << 4)] = (internal::product_triangular_matrix_matrix<Scalar,DenseIndex,Upper|0, true, RowMajor,Conj, ColMajor,false,ColMajor>::run); func[NOTR | (RIGHT << 2) | (LO << 3) | (NUNIT << 4)] = (internal::product_triangular_matrix_matrix<Scalar,DenseIndex,Lower|0, false,ColMajor,false,ColMajor,false,ColMajor>::run); func[TR | (RIGHT << 2) | (LO << 3) | (NUNIT << 4)] = (internal::product_triangular_matrix_matrix<Scalar,DenseIndex,Upper|0, false,ColMajor,false,RowMajor,false,ColMajor>::run); func[ADJ | (RIGHT << 2) | (LO << 3) | (NUNIT << 4)] = (internal::product_triangular_matrix_matrix<Scalar,DenseIndex,Upper|0, false,ColMajor,false,RowMajor,Conj, ColMajor>::run); func[NOTR | (LEFT << 2) | (UP << 3) | (UNIT << 4)] = (internal::product_triangular_matrix_matrix<Scalar,DenseIndex,Upper|UnitDiag,true, ColMajor,false,ColMajor,false,ColMajor>::run); func[TR | (LEFT << 2) | (UP << 3) | (UNIT << 4)] = (internal::product_triangular_matrix_matrix<Scalar,DenseIndex,Lower|UnitDiag,true, RowMajor,false,ColMajor,false,ColMajor>::run); func[ADJ | (LEFT << 2) | (UP << 3) | (UNIT << 4)] = (internal::product_triangular_matrix_matrix<Scalar,DenseIndex,Lower|UnitDiag,true, RowMajor,Conj, ColMajor,false,ColMajor>::run); func[NOTR | (RIGHT << 2) | (UP << 3) | (UNIT << 4)] = (internal::product_triangular_matrix_matrix<Scalar,DenseIndex,Upper|UnitDiag,false,ColMajor,false,ColMajor,false,ColMajor>::run); func[TR | (RIGHT << 2) | (UP << 3) | (UNIT << 4)] = (internal::product_triangular_matrix_matrix<Scalar,DenseIndex,Lower|UnitDiag,false,ColMajor,false,RowMajor,false,ColMajor>::run); func[ADJ | (RIGHT << 2) | (UP << 3) | (UNIT << 4)] = (internal::product_triangular_matrix_matrix<Scalar,DenseIndex,Lower|UnitDiag,false,ColMajor,false,RowMajor,Conj, ColMajor>::run); func[NOTR | (LEFT << 2) | (LO << 3) | (UNIT << 4)] = (internal::product_triangular_matrix_matrix<Scalar,DenseIndex,Lower|UnitDiag,true, ColMajor,false,ColMajor,false,ColMajor>::run); func[TR | (LEFT << 2) | (LO << 3) | (UNIT << 4)] = (internal::product_triangular_matrix_matrix<Scalar,DenseIndex,Upper|UnitDiag,true, RowMajor,false,ColMajor,false,ColMajor>::run); func[ADJ | (LEFT << 2) | (LO << 3) | (UNIT << 4)] = (internal::product_triangular_matrix_matrix<Scalar,DenseIndex,Upper|UnitDiag,true, RowMajor,Conj, ColMajor,false,ColMajor>::run); func[NOTR | (RIGHT << 2) | (LO << 3) | (UNIT << 4)] = (internal::product_triangular_matrix_matrix<Scalar,DenseIndex,Lower|UnitDiag,false,ColMajor,false,ColMajor,false,ColMajor>::run); func[TR | (RIGHT << 2) | (LO << 3) | (UNIT << 4)] = (internal::product_triangular_matrix_matrix<Scalar,DenseIndex,Upper|UnitDiag,false,ColMajor,false,RowMajor,false,ColMajor>::run); func[ADJ | (RIGHT << 2) | (LO << 3) | (UNIT << 4)] = (internal::product_triangular_matrix_matrix<Scalar,DenseIndex,Upper|UnitDiag,false,ColMajor,false,RowMajor,Conj, ColMajor>::run); init = true; } Scalar* a = reinterpret_cast<Scalar*>(pa); Scalar* b = reinterpret_cast<Scalar*>(pb); Scalar alpha = *reinterpret_cast<Scalar*>(palpha); int info = 0; if(SIDE(*side)==INVALID) info = 1; else if(UPLO(*uplo)==INVALID) info = 2; else if(OP(*opa)==INVALID) info = 3; else if(DIAG(*diag)==INVALID) info = 4; else if(*m<0) info = 5; else if(*n<0) info = 6; else if(*lda<std::max(1,(SIDE(*side)==LEFT)?*m:*n)) info = 9; else if(*ldb<std::max(1,*m)) info = 11; if(info) return xerbla_(SCALAR_SUFFIX_UP"TRMM ",&info,6); int code = OP(*opa) | (SIDE(*side) << 2) | (UPLO(*uplo) << 3) | (DIAG(*diag) << 4); if(*m==0 || *n==0) return 1; // FIXME find a way to avoid this copy Matrix<Scalar,Dynamic,Dynamic,ColMajor> tmp = matrix(b,*m,*n,*ldb); matrix(b,*m,*n,*ldb).setZero(); if(SIDE(*side)==LEFT) { internal::gemm_blocking_space<ColMajor,Scalar,Scalar,Dynamic,Dynamic,Dynamic,4> blocking(*m,*n,*m); func[code](*m, *n, *m, a, *lda, tmp.data(), tmp.outerStride(), b, *ldb, alpha, blocking); } else { internal::gemm_blocking_space<ColMajor,Scalar,Scalar,Dynamic,Dynamic,Dynamic,4> blocking(*m,*n,*n); func[code](*m, *n, *n, tmp.data(), tmp.outerStride(), a, *lda, b, *ldb, alpha, blocking); } return 1; } // c = alpha*a*b + beta*c for side = 'L'or'l' // c = alpha*b*a + beta*c for side = 'R'or'r int EIGEN_BLAS_FUNC(symm)(char *side, char *uplo, int *m, int *n, RealScalar *palpha, RealScalar *pa, int *lda, RealScalar *pb, int *ldb, RealScalar *pbeta, RealScalar *pc, int *ldc) { // std::cerr << "in symm " << *side << " " << *uplo << " " << *m << "x" << *n << " lda:" << *lda << " ldb:" << *ldb << " ldc:" << *ldc << " alpha:" << *palpha << " beta:" << *pbeta << "\n"; Scalar* a = reinterpret_cast<Scalar*>(pa); Scalar* b = reinterpret_cast<Scalar*>(pb); Scalar* c = reinterpret_cast<Scalar*>(pc); Scalar alpha = *reinterpret_cast<Scalar*>(palpha); Scalar beta = *reinterpret_cast<Scalar*>(pbeta); int info = 0; if(SIDE(*side)==INVALID) info = 1; else if(UPLO(*uplo)==INVALID) info = 2; else if(*m<0) info = 3; else if(*n<0) info = 4; else if(*lda<std::max(1,(SIDE(*side)==LEFT)?*m:*n)) info = 7; else if(*ldb<std::max(1,*m)) info = 9; else if(*ldc<std::max(1,*m)) info = 12; if(info) return xerbla_(SCALAR_SUFFIX_UP"SYMM ",&info,6); if(beta!=Scalar(1)) { if(beta==Scalar(0)) matrix(c, *m, *n, *ldc).setZero(); else matrix(c, *m, *n, *ldc) *= beta; } if(*m==0 || *n==0) { return 1; } #if ISCOMPLEX // FIXME add support for symmetric complex matrix int size = (SIDE(*side)==LEFT) ? (*m) : (*n); Matrix<Scalar,Dynamic,Dynamic,ColMajor> matA(size,size); if(UPLO(*uplo)==UP) { matA.triangularView<Upper>() = matrix(a,size,size,*lda); matA.triangularView<Lower>() = matrix(a,size,size,*lda).transpose(); } else if(UPLO(*uplo)==LO) { matA.triangularView<Lower>() = matrix(a,size,size,*lda); matA.triangularView<Upper>() = matrix(a,size,size,*lda).transpose(); } if(SIDE(*side)==LEFT) matrix(c, *m, *n, *ldc) += alpha * matA * matrix(b, *m, *n, *ldb); else if(SIDE(*side)==RIGHT) matrix(c, *m, *n, *ldc) += alpha * matrix(b, *m, *n, *ldb) * matA; #else if(SIDE(*side)==LEFT) if(UPLO(*uplo)==UP) internal::product_selfadjoint_matrix<Scalar, DenseIndex, RowMajor,true,false, ColMajor,false,false, ColMajor>::run(*m, *n, a, *lda, b, *ldb, c, *ldc, alpha); else if(UPLO(*uplo)==LO) internal::product_selfadjoint_matrix<Scalar, DenseIndex, ColMajor,true,false, ColMajor,false,false, ColMajor>::run(*m, *n, a, *lda, b, *ldb, c, *ldc, alpha); else return 0; else if(SIDE(*side)==RIGHT) if(UPLO(*uplo)==UP) internal::product_selfadjoint_matrix<Scalar, DenseIndex, ColMajor,false,false, RowMajor,true,false, ColMajor>::run(*m, *n, b, *ldb, a, *lda, c, *ldc, alpha); else if(UPLO(*uplo)==LO) internal::product_selfadjoint_matrix<Scalar, DenseIndex, ColMajor,false,false, ColMajor,true,false, ColMajor>::run(*m, *n, b, *ldb, a, *lda, c, *ldc, alpha); else return 0; else return 0; #endif return 0; } // c = alpha*a*a' + beta*c for op = 'N'or'n' // c = alpha*a'*a + beta*c for op = 'T'or't','C'or'c' int EIGEN_BLAS_FUNC(syrk)(char *uplo, char *op, int *n, int *k, RealScalar *palpha, RealScalar *pa, int *lda, RealScalar *pbeta, RealScalar *pc, int *ldc) { // std::cerr << "in syrk " << *uplo << " " << *op << " " << *n << " " << *k << " " << *palpha << " " << *lda << " " << *pbeta << " " << *ldc << "\n"; #if !ISCOMPLEX typedef void (*functype)(DenseIndex, DenseIndex, const Scalar *, DenseIndex, const Scalar *, DenseIndex, Scalar *, DenseIndex, const Scalar&); static functype func[8]; static bool init = false; if(!init) { for(int k=0; k<8; ++k) func[k] = 0; func[NOTR | (UP << 2)] = (internal::general_matrix_matrix_triangular_product<DenseIndex,Scalar,ColMajor,false,Scalar,RowMajor,ColMajor,Conj, Upper>::run); func[TR | (UP << 2)] = (internal::general_matrix_matrix_triangular_product<DenseIndex,Scalar,RowMajor,false,Scalar,ColMajor,ColMajor,Conj, Upper>::run); func[ADJ | (UP << 2)] = (internal::general_matrix_matrix_triangular_product<DenseIndex,Scalar,RowMajor,Conj, Scalar,ColMajor,ColMajor,false,Upper>::run); func[NOTR | (LO << 2)] = (internal::general_matrix_matrix_triangular_product<DenseIndex,Scalar,ColMajor,false,Scalar,RowMajor,ColMajor,Conj, Lower>::run); func[TR | (LO << 2)] = (internal::general_matrix_matrix_triangular_product<DenseIndex,Scalar,RowMajor,false,Scalar,ColMajor,ColMajor,Conj, Lower>::run); func[ADJ | (LO << 2)] = (internal::general_matrix_matrix_triangular_product<DenseIndex,Scalar,RowMajor,Conj, Scalar,ColMajor,ColMajor,false,Lower>::run); init = true; } #endif Scalar* a = reinterpret_cast<Scalar*>(pa); Scalar* c = reinterpret_cast<Scalar*>(pc); Scalar alpha = *reinterpret_cast<Scalar*>(palpha); Scalar beta = *reinterpret_cast<Scalar*>(pbeta); int info = 0; if(UPLO(*uplo)==INVALID) info = 1; else if(OP(*op)==INVALID) info = 2; else if(*n<0) info = 3; else if(*k<0) info = 4; else if(*lda<std::max(1,(OP(*op)==NOTR)?*n:*k)) info = 7; else if(*ldc<std::max(1,*n)) info = 10; if(info) return xerbla_(SCALAR_SUFFIX_UP"SYRK ",&info,6); if(beta!=Scalar(1)) { if(UPLO(*uplo)==UP) if(beta==Scalar(0)) matrix(c, *n, *n, *ldc).triangularView<Upper>().setZero(); else matrix(c, *n, *n, *ldc).triangularView<Upper>() *= beta; else if(beta==Scalar(0)) matrix(c, *n, *n, *ldc).triangularView<Lower>().setZero(); else matrix(c, *n, *n, *ldc).triangularView<Lower>() *= beta; } #if ISCOMPLEX // FIXME add support for symmetric complex matrix if(UPLO(*uplo)==UP) { if(OP(*op)==NOTR) matrix(c, *n, *n, *ldc).triangularView<Upper>() += alpha * matrix(a,*n,*k,*lda) * matrix(a,*n,*k,*lda).transpose(); else matrix(c, *n, *n, *ldc).triangularView<Upper>() += alpha * matrix(a,*k,*n,*lda).transpose() * matrix(a,*k,*n,*lda); } else { if(OP(*op)==NOTR) matrix(c, *n, *n, *ldc).triangularView<Lower>() += alpha * matrix(a,*n,*k,*lda) * matrix(a,*n,*k,*lda).transpose(); else matrix(c, *n, *n, *ldc).triangularView<Lower>() += alpha * matrix(a,*k,*n,*lda).transpose() * matrix(a,*k,*n,*lda); } #else int code = OP(*op) | (UPLO(*uplo) << 2); func[code](*n, *k, a, *lda, a, *lda, c, *ldc, alpha); #endif return 0; } // c = alpha*a*b' + alpha*b*a' + beta*c for op = 'N'or'n' // c = alpha*a'*b + alpha*b'*a + beta*c for op = 'T'or't' int EIGEN_BLAS_FUNC(syr2k)(char *uplo, char *op, int *n, int *k, RealScalar *palpha, RealScalar *pa, int *lda, RealScalar *pb, int *ldb, RealScalar *pbeta, RealScalar *pc, int *ldc) { Scalar* a = reinterpret_cast<Scalar*>(pa); Scalar* b = reinterpret_cast<Scalar*>(pb); Scalar* c = reinterpret_cast<Scalar*>(pc); Scalar alpha = *reinterpret_cast<Scalar*>(palpha); Scalar beta = *reinterpret_cast<Scalar*>(pbeta); int info = 0; if(UPLO(*uplo)==INVALID) info = 1; else if(OP(*op)==INVALID) info = 2; else if(*n<0) info = 3; else if(*k<0) info = 4; else if(*lda<std::max(1,(OP(*op)==NOTR)?*n:*k)) info = 7; else if(*ldb<std::max(1,(OP(*op)==NOTR)?*n:*k)) info = 9; else if(*ldc<std::max(1,*n)) info = 12; if(info) return xerbla_(SCALAR_SUFFIX_UP"SYR2K",&info,6); if(beta!=Scalar(1)) { if(UPLO(*uplo)==UP) if(beta==Scalar(0)) matrix(c, *n, *n, *ldc).triangularView<Upper>().setZero(); else matrix(c, *n, *n, *ldc).triangularView<Upper>() *= beta; else if(beta==Scalar(0)) matrix(c, *n, *n, *ldc).triangularView<Lower>().setZero(); else matrix(c, *n, *n, *ldc).triangularView<Lower>() *= beta; } if(*k==0) return 1; if(OP(*op)==NOTR) { if(UPLO(*uplo)==UP) { matrix(c, *n, *n, *ldc).triangularView<Upper>() += alpha *matrix(a, *n, *k, *lda)*matrix(b, *n, *k, *ldb).transpose() + alpha*matrix(b, *n, *k, *ldb)*matrix(a, *n, *k, *lda).transpose(); } else if(UPLO(*uplo)==LO) matrix(c, *n, *n, *ldc).triangularView<Lower>() += alpha*matrix(a, *n, *k, *lda)*matrix(b, *n, *k, *ldb).transpose() + alpha*matrix(b, *n, *k, *ldb)*matrix(a, *n, *k, *lda).transpose(); } else if(OP(*op)==TR || OP(*op)==ADJ) { if(UPLO(*uplo)==UP) matrix(c, *n, *n, *ldc).triangularView<Upper>() += alpha*matrix(a, *k, *n, *lda).transpose()*matrix(b, *k, *n, *ldb) + alpha*matrix(b, *k, *n, *ldb).transpose()*matrix(a, *k, *n, *lda); else if(UPLO(*uplo)==LO) matrix(c, *n, *n, *ldc).triangularView<Lower>() += alpha*matrix(a, *k, *n, *lda).transpose()*matrix(b, *k, *n, *ldb) + alpha*matrix(b, *k, *n, *ldb).transpose()*matrix(a, *k, *n, *lda); } return 0; } #if ISCOMPLEX // c = alpha*a*b + beta*c for side = 'L'or'l' // c = alpha*b*a + beta*c for side = 'R'or'r int EIGEN_BLAS_FUNC(hemm)(char *side, char *uplo, int *m, int *n, RealScalar *palpha, RealScalar *pa, int *lda, RealScalar *pb, int *ldb, RealScalar *pbeta, RealScalar *pc, int *ldc) { Scalar* a = reinterpret_cast<Scalar*>(pa); Scalar* b = reinterpret_cast<Scalar*>(pb); Scalar* c = reinterpret_cast<Scalar*>(pc); Scalar alpha = *reinterpret_cast<Scalar*>(palpha); Scalar beta = *reinterpret_cast<Scalar*>(pbeta); // std::cerr << "in hemm " << *side << " " << *uplo << " " << *m << " " << *n << " " << alpha << " " << *lda << " " << beta << " " << *ldc << "\n"; int info = 0; if(SIDE(*side)==INVALID) info = 1; else if(UPLO(*uplo)==INVALID) info = 2; else if(*m<0) info = 3; else if(*n<0) info = 4; else if(*lda<std::max(1,(SIDE(*side)==LEFT)?*m:*n)) info = 7; else if(*ldb<std::max(1,*m)) info = 9; else if(*ldc<std::max(1,*m)) info = 12; if(info) return xerbla_(SCALAR_SUFFIX_UP"HEMM ",&info,6); if(beta==Scalar(0)) matrix(c, *m, *n, *ldc).setZero(); else if(beta!=Scalar(1)) matrix(c, *m, *n, *ldc) *= beta; if(*m==0 || *n==0) { return 1; } if(SIDE(*side)==LEFT) { if(UPLO(*uplo)==UP) internal::product_selfadjoint_matrix<Scalar,DenseIndex,RowMajor,true,Conj, ColMajor,false,false, ColMajor> ::run(*m, *n, a, *lda, b, *ldb, c, *ldc, alpha); else if(UPLO(*uplo)==LO) internal::product_selfadjoint_matrix<Scalar,DenseIndex,ColMajor,true,false, ColMajor,false,false, ColMajor> ::run(*m, *n, a, *lda, b, *ldb, c, *ldc, alpha); else return 0; } else if(SIDE(*side)==RIGHT) { if(UPLO(*uplo)==UP) matrix(c,*m,*n,*ldc) += alpha * matrix(b,*m,*n,*ldb) * matrix(a,*n,*n,*lda).selfadjointView<Upper>();/*internal::product_selfadjoint_matrix<Scalar,DenseIndex,ColMajor,false,false, RowMajor,true,Conj, ColMajor> ::run(*m, *n, b, *ldb, a, *lda, c, *ldc, alpha);*/ else if(UPLO(*uplo)==LO) internal::product_selfadjoint_matrix<Scalar,DenseIndex,ColMajor,false,false, ColMajor,true,false, ColMajor> ::run(*m, *n, b, *ldb, a, *lda, c, *ldc, alpha); else return 0; } else { return 0; } return 0; } // c = alpha*a*conj(a') + beta*c for op = 'N'or'n' // c = alpha*conj(a')*a + beta*c for op = 'C'or'c' int EIGEN_BLAS_FUNC(herk)(char *uplo, char *op, int *n, int *k, RealScalar *palpha, RealScalar *pa, int *lda, RealScalar *pbeta, RealScalar *pc, int *ldc) { typedef void (*functype)(DenseIndex, DenseIndex, const Scalar *, DenseIndex, const Scalar *, DenseIndex, Scalar *, DenseIndex, const Scalar&); static functype func[8]; static bool init = false; if(!init) { for(int k=0; k<8; ++k) func[k] = 0; func[NOTR | (UP << 2)] = (internal::general_matrix_matrix_triangular_product<DenseIndex,Scalar,ColMajor,false,Scalar,RowMajor,Conj, ColMajor,Upper>::run); func[ADJ | (UP << 2)] = (internal::general_matrix_matrix_triangular_product<DenseIndex,Scalar,RowMajor,Conj, Scalar,ColMajor,false,ColMajor,Upper>::run); func[NOTR | (LO << 2)] = (internal::general_matrix_matrix_triangular_product<DenseIndex,Scalar,ColMajor,false,Scalar,RowMajor,Conj, ColMajor,Lower>::run); func[ADJ | (LO << 2)] = (internal::general_matrix_matrix_triangular_product<DenseIndex,Scalar,RowMajor,Conj, Scalar,ColMajor,false,ColMajor,Lower>::run); init = true; } Scalar* a = reinterpret_cast<Scalar*>(pa); Scalar* c = reinterpret_cast<Scalar*>(pc); RealScalar alpha = *palpha; RealScalar beta = *pbeta; // std::cerr << "in herk " << *uplo << " " << *op << " " << *n << " " << *k << " " << alpha << " " << *lda << " " << beta << " " << *ldc << "\n"; int info = 0; if(UPLO(*uplo)==INVALID) info = 1; else if((OP(*op)==INVALID) || (OP(*op)==TR)) info = 2; else if(*n<0) info = 3; else if(*k<0) info = 4; else if(*lda<std::max(1,(OP(*op)==NOTR)?*n:*k)) info = 7; else if(*ldc<std::max(1,*n)) info = 10; if(info) return xerbla_(SCALAR_SUFFIX_UP"HERK ",&info,6); int code = OP(*op) | (UPLO(*uplo) << 2); if(beta!=RealScalar(1)) { if(UPLO(*uplo)==UP) if(beta==Scalar(0)) matrix(c, *n, *n, *ldc).triangularView<Upper>().setZero(); else matrix(c, *n, *n, *ldc).triangularView<StrictlyUpper>() *= beta; else if(beta==Scalar(0)) matrix(c, *n, *n, *ldc).triangularView<Lower>().setZero(); else matrix(c, *n, *n, *ldc).triangularView<StrictlyLower>() *= beta; if(beta!=Scalar(0)) { matrix(c, *n, *n, *ldc).diagonal().real() *= beta; matrix(c, *n, *n, *ldc).diagonal().imag().setZero(); } } if(*k>0 && alpha!=RealScalar(0)) { func[code](*n, *k, a, *lda, a, *lda, c, *ldc, alpha); matrix(c, *n, *n, *ldc).diagonal().imag().setZero(); } return 0; } // c = alpha*a*conj(b') + conj(alpha)*b*conj(a') + beta*c, for op = 'N'or'n' // c = alpha*conj(a')*b + conj(alpha)*conj(b')*a + beta*c, for op = 'C'or'c' int EIGEN_BLAS_FUNC(her2k)(char *uplo, char *op, int *n, int *k, RealScalar *palpha, RealScalar *pa, int *lda, RealScalar *pb, int *ldb, RealScalar *pbeta, RealScalar *pc, int *ldc) { Scalar* a = reinterpret_cast<Scalar*>(pa); Scalar* b = reinterpret_cast<Scalar*>(pb); Scalar* c = reinterpret_cast<Scalar*>(pc); Scalar alpha = *reinterpret_cast<Scalar*>(palpha); RealScalar beta = *pbeta; int info = 0; if(UPLO(*uplo)==INVALID) info = 1; else if((OP(*op)==INVALID) || (OP(*op)==TR)) info = 2; else if(*n<0) info = 3; else if(*k<0) info = 4; else if(*lda<std::max(1,(OP(*op)==NOTR)?*n:*k)) info = 7; else if(*lda<std::max(1,(OP(*op)==NOTR)?*n:*k)) info = 9; else if(*ldc<std::max(1,*n)) info = 12; if(info) return xerbla_(SCALAR_SUFFIX_UP"HER2K",&info,6); if(beta!=RealScalar(1)) { if(UPLO(*uplo)==UP) if(beta==Scalar(0)) matrix(c, *n, *n, *ldc).triangularView<Upper>().setZero(); else matrix(c, *n, *n, *ldc).triangularView<StrictlyUpper>() *= beta; else if(beta==Scalar(0)) matrix(c, *n, *n, *ldc).triangularView<Lower>().setZero(); else matrix(c, *n, *n, *ldc).triangularView<StrictlyLower>() *= beta; if(beta!=Scalar(0)) { matrix(c, *n, *n, *ldc).diagonal().real() *= beta; matrix(c, *n, *n, *ldc).diagonal().imag().setZero(); } } else if(*k>0 && alpha!=Scalar(0)) matrix(c, *n, *n, *ldc).diagonal().imag().setZero(); if(*k==0) return 1; if(OP(*op)==NOTR) { if(UPLO(*uplo)==UP) { matrix(c, *n, *n, *ldc).triangularView<Upper>() += alpha *matrix(a, *n, *k, *lda)*matrix(b, *n, *k, *ldb).adjoint() + numext::conj(alpha)*matrix(b, *n, *k, *ldb)*matrix(a, *n, *k, *lda).adjoint(); } else if(UPLO(*uplo)==LO) matrix(c, *n, *n, *ldc).triangularView<Lower>() += alpha*matrix(a, *n, *k, *lda)*matrix(b, *n, *k, *ldb).adjoint() + numext::conj(alpha)*matrix(b, *n, *k, *ldb)*matrix(a, *n, *k, *lda).adjoint(); } else if(OP(*op)==ADJ) { if(UPLO(*uplo)==UP) matrix(c, *n, *n, *ldc).triangularView<Upper>() += alpha*matrix(a, *k, *n, *lda).adjoint()*matrix(b, *k, *n, *ldb) + numext::conj(alpha)*matrix(b, *k, *n, *ldb).adjoint()*matrix(a, *k, *n, *lda); else if(UPLO(*uplo)==LO) matrix(c, *n, *n, *ldc).triangularView<Lower>() += alpha*matrix(a, *k, *n, *lda).adjoint()*matrix(b, *k, *n, *ldb) + numext::conj(alpha)*matrix(b, *k, *n, *ldb).adjoint()*matrix(a, *k, *n, *lda); } return 1; } #endif // ISCOMPLEX