/// @file parallel_matrix_op.c /// @brief the standard implementations for functions in parallel_matrix_op.h /// /// the standard implementations for functions in parallel_matrix_op.h /// #include "blas.h" #include "blas_comm.h" #include "parallel_matrix_op.h" /// /// @brief Calculate the corresponding index in an array for an upper-triangle(UT) matrix. /// /// @param[in] i_row - the i-th row in an upper-triangle matrix. /// @param[in] j_col - the j-th column in an upper-triangle matrix. /// @param[in] dim - the dimension of the upper-triangle matrix, i.e., an dim x dim matrix. /// @return the corresponding index in an array storage. /// unsigned PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_idx_of_trimat( unsigned i_row, unsigned j_col, unsigned dim ) { return (dim + dim - i_row + 1 ) * i_row / 2 + j_col - i_row; } /// /// @brief Calculate the corresponding index in an array for an upper-triangle or lower-triangle matrix. /// /// @param[in] i_row - the i-th row in a triangle matrix. /// @param[in] j_col - the j-th column in a triangle matrix. /// @param[in] dim - the dimension of the triangle matrix, i.e., an dim x dim matrix. /// @return the corresponding index in an array storage. /// static inline unsigned idx_of_2trimat( unsigned i_row, unsigned j_col, unsigned n_var ) { if ( i_row > j_col ) { return PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_idx_of_trimat(j_col, i_row, n_var); } return PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_idx_of_trimat(i_row, j_col, n_var); } void PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_UpperTrianglize( unsigned char *btriC, const unsigned char *bA, unsigned Awidth, unsigned size_batch ) { unsigned char *runningC = btriC; unsigned Aheight = Awidth; for (unsigned i = 0; i < Aheight; i++) { for (unsigned j = 0; j < i; j++) { unsigned idx = PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_idx_of_trimat(j, i, Aheight); gf256v_add( btriC + idx * size_batch, bA + size_batch * (i * Awidth + j), size_batch ); } gf256v_add( runningC, bA + size_batch * (i * Awidth + i), size_batch * (Aheight - i) ); runningC += size_batch * (Aheight - i); } } void PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_batch_trimat_madd_gf256( unsigned char *bC, const unsigned char *btriA, const unsigned char *B, unsigned Bheight, unsigned size_Bcolvec, unsigned Bwidth, unsigned size_batch ) { unsigned Awidth = Bheight; unsigned Aheight = Awidth; for (unsigned i = 0; i < Aheight; i++) { for (unsigned j = 0; j < Bwidth; j++) { for (unsigned k = 0; k < Bheight; k++) { if (k < i) { continue; } gf256v_madd( bC, & btriA[ (k - i)*size_batch ], PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256v_get_ele( &B[j * size_Bcolvec], k ), size_batch ); } bC += size_batch; } btriA += (Aheight - i) * size_batch; } } void PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_batch_trimatTr_madd_gf256( unsigned char *bC, const unsigned char *btriA, const unsigned char *B, unsigned Bheight, unsigned size_Bcolvec, unsigned Bwidth, unsigned size_batch ) { unsigned Aheight = Bheight; for (unsigned i = 0; i < Aheight; i++) { for (unsigned j = 0; j < Bwidth; j++) { for (unsigned k = 0; k < Bheight; k++) { if (i < k) { continue; } gf256v_madd( bC, & btriA[ size_batch * (PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_idx_of_trimat(k, i, Aheight)) ], PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256v_get_ele( &B[j * size_Bcolvec], k ), size_batch ); } bC += size_batch; } } } void PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_batch_2trimat_madd_gf256( unsigned char *bC, const unsigned char *btriA, const unsigned char *B, unsigned Bheight, unsigned size_Bcolvec, unsigned Bwidth, unsigned size_batch ) { unsigned Aheight = Bheight; for (unsigned i = 0; i < Aheight; i++) { for (unsigned j = 0; j < Bwidth; j++) { for (unsigned k = 0; k < Bheight; k++) { if (i == k) { continue; } gf256v_madd( bC, & btriA[ size_batch * (idx_of_2trimat(i, k, Aheight)) ], PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256v_get_ele( &B[j * size_Bcolvec], k ), size_batch ); } bC += size_batch; } } } void PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_batch_matTr_madd_gf256( unsigned char *bC, const unsigned char *A_to_tr, unsigned Aheight, unsigned size_Acolvec, unsigned Awidth, const unsigned char *bB, unsigned Bwidth, unsigned size_batch ) { unsigned Atr_height = Awidth; unsigned Atr_width = Aheight; for (unsigned i = 0; i < Atr_height; i++) { for (unsigned j = 0; j < Atr_width; j++) { gf256v_madd( bC, & bB[ j * Bwidth * size_batch ], PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256v_get_ele( &A_to_tr[size_Acolvec * i], j ), size_batch * Bwidth ); } bC += size_batch * Bwidth; } } void PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_batch_bmatTr_madd_gf256( unsigned char *bC, const unsigned char *bA_to_tr, unsigned Awidth_before_tr, const unsigned char *B, unsigned Bheight, unsigned size_Bcolvec, unsigned Bwidth, unsigned size_batch ) { const unsigned char *bA = bA_to_tr; unsigned Aheight = Awidth_before_tr; for (unsigned i = 0; i < Aheight; i++) { for (unsigned j = 0; j < Bwidth; j++) { for (unsigned k = 0; k < Bheight; k++) { gf256v_madd( bC, & bA[ size_batch * (i + k * Aheight) ], PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256v_get_ele( &B[j * size_Bcolvec], k ), size_batch ); } bC += size_batch; } } } void PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_batch_mat_madd_gf256( unsigned char *bC, const unsigned char *bA, unsigned Aheight, const unsigned char *B, unsigned Bheight, unsigned size_Bcolvec, unsigned Bwidth, unsigned size_batch ) { unsigned Awidth = Bheight; for (unsigned i = 0; i < Aheight; i++) { for (unsigned j = 0; j < Bwidth; j++) { for (unsigned k = 0; k < Bheight; k++) { gf256v_madd( bC, & bA[ k * size_batch ], PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256v_get_ele( &B[j * size_Bcolvec], k ), size_batch ); } bC += size_batch; } bA += (Awidth) * size_batch; } } void PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_batch_quad_trimat_eval_gf256( unsigned char *y, const unsigned char *trimat, const unsigned char *x, unsigned dim, unsigned size_batch ) { unsigned char tmp[256]; unsigned char _x[256]; for (unsigned i = 0; i < dim; i++) { _x[i] = PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256v_get_ele( x, i ); } PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256v_set_zero( y, size_batch ); for (unsigned i = 0; i < dim; i++) { PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256v_set_zero( tmp, size_batch ); for (unsigned j = i; j < dim; j++) { gf256v_madd( tmp, trimat, _x[j], size_batch ); trimat += size_batch; } gf256v_madd( y, tmp, _x[i], size_batch ); } } void PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_batch_quad_recmat_eval_gf256( unsigned char *z, const unsigned char *y, unsigned dim_y, const unsigned char *mat, const unsigned char *x, unsigned dim_x, unsigned size_batch ) { unsigned char tmp[128]; unsigned char _x[128]; for (unsigned i = 0; i < dim_x; i++) { _x[i] = PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256v_get_ele( x, i ); } unsigned char _y[128]; for (unsigned i = 0; i < dim_y; i++) { _y[i] = PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256v_get_ele( y, i ); } PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256v_set_zero( z, size_batch ); for (unsigned i = 0; i < dim_y; i++) { PQCLEAN_RAINBOWIIICCLASSIC_CLEAN_gf256v_set_zero( tmp, size_batch ); for (unsigned j = 0; j < dim_x; j++) { gf256v_madd( tmp, mat, _x[j], size_batch ); mat += size_batch; } gf256v_madd( z, tmp, _y[i], size_batch ); } }