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//------------------------------------------------------------------------------
// GB_bitmap_assign_M_noaccum: assign to C bitmap
//------------------------------------------------------------------------------
// SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2022, All Rights Reserved.
// SPDX-License-Identifier: Apache-2.0
//------------------------------------------------------------------------------
// C<M>(I,J) = A assign
// C(I,J)<M> = A subassign
// C<M,repl>(I,J) = A assign
// C(I,J)<M,repl> = A subassign
//------------------------------------------------------------------------------
// C: bitmap
// M: present, hypersparse or sparse, (not bitmap or full)
// Mask_comp: false
// Mask_struct: true or false
// C_replace: true or false
// accum: not present
// A: matrix (hyper, sparse, bitmap, or full), or scalar
// kind: assign, row assign, col assign, or subassign
#include "GB_bitmap_assign_methods.h"
#define GB_FREE_ALL \
{ \
GB_WERK_POP (M_ek_slicing, int64_t) ; \
}
GrB_Info GB_bitmap_assign_M_noaccum
(
// input/output:
GrB_Matrix C, // input/output matrix in bitmap format
// inputs:
const bool C_replace, // descriptor for C
const GrB_Index *I, // I index list
const int64_t nI,
const int Ikind,
const int64_t Icolon [3],
const GrB_Index *J, // J index list
const int64_t nJ,
const int Jkind,
const int64_t Jcolon [3],
const GrB_Matrix M, // mask matrix, which is not NULL here
// const bool Mask_comp, // false here
const bool Mask_struct, // true if M is structural, false if valued
// const GrB_BinaryOp accum, // not present
const GrB_Matrix A, // input matrix, not transposed
const void *scalar, // input scalar
const GrB_Type scalar_type, // type of input scalar
const int assign_kind, // row assign, col assign, assign, or subassign
GB_Context Context
)
{
//--------------------------------------------------------------------------
// check inputs
//--------------------------------------------------------------------------
GBURBLE_BITMAP_ASSIGN ("bit4", M, false, NULL,
Ikind, Jkind, assign_kind) ;
ASSERT (GB_IS_HYPERSPARSE (M) || GB_IS_SPARSE (M)) ;
ASSERT_MATRIX_OK (C, "C for bitmap assign, M, noaccum", GB0) ;
ASSERT_MATRIX_OK (M, "M for bitmap assign, M, noaccum", GB0) ;
ASSERT_MATRIX_OK_OR_NULL (A, "A for bitmap assign, M, noaccum", GB0) ;
//--------------------------------------------------------------------------
// get inputs
//--------------------------------------------------------------------------
GB_GET_C_BITMAP ; // C must be bitmap
GB_SLICE_M
GB_GET_A_AND_SCALAR
//--------------------------------------------------------------------------
// C<M,repl or !repl>(I,J) = A or scalar
//--------------------------------------------------------------------------
//--------------------------------------------------------------------------
// scatter M into C
//--------------------------------------------------------------------------
// Cb [pC] += 2 for each entry M(i,j) in the mask
GB_bitmap_M_scatter (C, I, nI, Ikind, Icolon, J, nJ, Jkind, Jcolon,
M, Mask_struct, assign_kind, GB_BITMAP_M_SCATTER_PLUS_2,
M_ek_slicing, M_ntasks, M_nthreads, Context) ;
// Cb (i,j) = 0: mij == 0, cij not present
// Cb (i,j) = 1: mij == 0, cij present
// Cb (i,j) = 2: mij == 1, cij not present, can be assigned
// Cb (i,j) = 3: mij == 1, cij present, can be assigned
// below:
// Cb (i,j) = 4: mij == 1, cij present, has been assigned
//--------------------------------------------------------------------------
// scatter A or the scalar into C(I,J)
//--------------------------------------------------------------------------
if (A == NULL)
{
//----------------------------------------------------------------------
// scalar assignment: C<M>(I,J) = scalar or C(I,J)<M> = scalar
//----------------------------------------------------------------------
// if C FULL: if C_replace false, no deletion occurs
// otherwise: convert C to bitmap
if (assign_kind == GB_SUBASSIGN)
{
//------------------------------------------------------------------
// scalar subassign: C(I,J)<M,repl or !repl> = scalar
//------------------------------------------------------------------
// for all IxJ
#undef GB_IXJ_WORK
#define GB_IXJ_WORK(pC,ignore) \
{ \
int8_t cb = Cb [pC] ; \
if (cb >= 2) \
{ \
/* Cx [pC] = scalar */ \
GB_ASSIGN_SCALAR (pC) ; \
Cb [pC] = 1 ; \
task_cnvals += (cb == 2) ; \
} \
else if (C_replace && cb == 1) \
{ \
/* delete this entry */ \
Cb [pC] = 0 ; \
task_cnvals-- ; \
} \
}
#include "GB_bitmap_assign_IxJ_template.c"
}
else // assign_kind == GB_ASSIGN
{
//------------------------------------------------------------------
// scalar assign: C<M,repl or !repl>(I,J) = scalar
//------------------------------------------------------------------
int keep = C_replace ? 4 : 1 ;
// for all IxJ
#undef GB_IXJ_WORK
#define GB_IXJ_WORK(pC,ignore) \
{ \
int8_t cb = Cb [pC] ; \
if (cb >= 2) \
{ \
/* Cx [pC] = scalar */ \
GB_ASSIGN_SCALAR (pC) ; \
Cb [pC] = keep ; \
task_cnvals += (cb == 2) ; \
} \
}
#include "GB_bitmap_assign_IxJ_template.c"
if (C_replace)
{
// for all of C
#undef GB_CIJ_WORK
#define GB_CIJ_WORK(pC) \
{ \
int8_t cb = Cb [pC] ; \
Cb [pC] = (cb == 4 || cb == 3) ; \
task_cnvals -= (cb == 1) ; \
}
#include "GB_bitmap_assign_C_template.c"
}
else
{
// clear the mask
// Cb [pC] %= 2 for each entry M(i,j) in the mask
GB_bitmap_M_scatter (C,
I, nI, Ikind, Icolon, J, nJ, Jkind, Jcolon,
M, Mask_struct, GB_ASSIGN, GB_BITMAP_M_SCATTER_MOD_2,
M_ek_slicing, M_ntasks, M_nthreads, Context) ;
}
}
}
else
{
//----------------------------------------------------------------------
// matrix assignment: C<M,repl or !repl>(I,J) = A
//----------------------------------------------------------------------
// for all entries aij in A (A can be hyper, sparse, bitmap, or full)
// if Cb(p) == 0 or 1 // do nothing
// if Cb(p) == 2
// Cx(p) = aij // C(iC,jC) is now present, insert
// Cb(p) = 4 // keep it
// task_cnvals++ ;
// if Cb(p) == 3
// Cx(p) = aij // C(iC,jC) is present, update it
// Cb(p) = 4 // keep it
#define GB_AIJ_WORK(pC,pA) \
{ \
int8_t cb = Cb [pC] ; \
if (cb >= 2) \
{ \
/* Cx [pC] = Ax [pA] ; */ \
GB_ASSIGN_AIJ (pC, pA) ; \
Cb [pC] = 4 ; \
task_cnvals += (cb == 2) ; \
} \
}
#include "GB_bitmap_assign_A_template.c"
//----------------------------------------------------------------------
// clear M from C and handle C_replace for row/col/assign
//----------------------------------------------------------------------
if (assign_kind == GB_SUBASSIGN)
{
//------------------------------------------------------------------
// subassign case
//------------------------------------------------------------------
if (C_replace)
{
// for all IxJ
#undef GB_IXJ_WORK
#define GB_IXJ_WORK(pC,ignore) \
{ \
int8_t cb = Cb [pC] ; \
Cb [pC] = (cb == 4) ; \
task_cnvals -= (cb == 1 || cb == 3) ; \
}
#include "GB_bitmap_assign_IxJ_template.c"
}
else
{
// for all IxJ
#undef GB_IXJ_WORK
#define GB_IXJ_WORK(pC,ignore) \
{ \
int8_t cb = Cb [pC] ; \
Cb [pC] = (cb == 4 || cb == 1) ; \
task_cnvals -= (cb == 3) ; \
}
#include "GB_bitmap_assign_IxJ_template.c"
}
}
else
{
//------------------------------------------------------------------
// row/col/assign case
//------------------------------------------------------------------
#define GB_NO_SUBASSIGN_CASE
if (C_replace)
{
// for all IxJ
#undef GB_IXJ_WORK
#define GB_IXJ_WORK(pC,ignore) \
{ \
int8_t cb = Cb [pC] ; \
Cb [pC] = (cb == 4) ? 3 : 0 ; \
task_cnvals -= (cb == 1 || cb == 3) ; \
}
#include "GB_bitmap_assign_IxJ_template.c"
// for all of C
#undef GB_CIJ_WORK
#define GB_CIJ_WORK(pC) \
{ \
int8_t cb = Cb [pC] ; \
ASSERT (cb != 4) ; \
Cb [pC] = (cb == 3) ; \
task_cnvals -= (cb == 1) ; \
}
#include "GB_bitmap_assign_C_template.c"
}
else
{
// for all IxJ
#undef GB_IXJ_WORK
#define GB_IXJ_WORK(pC,ignore) \
{ \
int8_t cb = Cb [pC] ; \
Cb [pC] = (cb == 4 || cb == 1) ; \
task_cnvals -= (cb == 3) ; \
}
#include "GB_bitmap_assign_IxJ_template.c"
// clear M from C
// Cb [pC] %= 2 for each entry M(i,j) in the mask
GB_bitmap_M_scatter (C,
I, nI, Ikind, Icolon, J, nJ, Jkind, Jcolon,
M, Mask_struct, assign_kind, GB_BITMAP_M_SCATTER_MOD_2,
M_ek_slicing, M_ntasks, M_nthreads, Context) ;
}
}
}
//--------------------------------------------------------------------------
// free workspace and return result
//--------------------------------------------------------------------------
C->nvals = cnvals ;
GB_FREE_ALL ;
ASSERT_MATRIX_OK (C, "final C for bitmap assign, M, noaccum", GB0) ;
return (GrB_SUCCESS) ;
}
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