1 #include <../src/mat/impls/aij/mpi/mpiaij.h> /*I "petscmat.h" I*/ 2 #include <../src/mat/impls/sell/mpi/mpisell.h> /*I "petscmat.h" I*/ 3 #include <petsc/private/vecimpl.h> 4 #include <petsc/private/isimpl.h> 5 #include <petscblaslapack.h> 6 #include <petscsf.h> 7 8 /*MC 9 MATSELL - MATSELL = "sell" - A matrix type to be used for sparse matrices. 10 11 This matrix type is identical to `MATSEQSELL` when constructed with a single process communicator, 12 and `MATMPISELL` otherwise. As a result, for single process communicators, 13 `MatSeqSELLSetPreallocation()` is supported, and similarly `MatMPISELLSetPreallocation()` is supported 14 for communicators controlling multiple processes. It is recommended that you call both of 15 the above preallocation routines for simplicity. 16 17 Options Database Keys: 18 . -mat_type sell - sets the matrix type to `MATSELL` during a call to `MatSetFromOptions()` 19 20 Level: beginner 21 22 .seealso: `Mat`, `MATAIJ`, `MATBAIJ`, `MATSBAIJ`, `MatCreateSELL()`, `MatCreateSeqSELL()`, `MATSEQSELL`, `MATMPISELL` 23 M*/ 24 25 static PetscErrorCode MatDiagonalSet_MPISELL(Mat Y, Vec D, InsertMode is) 26 { 27 Mat_MPISELL *sell = (Mat_MPISELL *)Y->data; 28 29 PetscFunctionBegin; 30 if (Y->assembled && Y->rmap->rstart == Y->cmap->rstart && Y->rmap->rend == Y->cmap->rend) { 31 PetscCall(MatDiagonalSet(sell->A, D, is)); 32 } else { 33 PetscCall(MatDiagonalSet_Default(Y, D, is)); 34 } 35 PetscFunctionReturn(PETSC_SUCCESS); 36 } 37 38 /* 39 Local utility routine that creates a mapping from the global column 40 number to the local number in the off-diagonal part of the local 41 storage of the matrix. When PETSC_USE_CTABLE is used this is scalable at 42 a slightly higher hash table cost; without it it is not scalable (each processor 43 has an order N integer array but is fast to access. 44 */ 45 PetscErrorCode MatCreateColmap_MPISELL_Private(Mat mat) 46 { 47 Mat_MPISELL *sell = (Mat_MPISELL *)mat->data; 48 PetscInt n = sell->B->cmap->n, i; 49 50 PetscFunctionBegin; 51 PetscCheck(sell->garray, PETSC_COMM_SELF, PETSC_ERR_PLIB, "MPISELL Matrix was assembled but is missing garray"); 52 #if defined(PETSC_USE_CTABLE) 53 PetscCall(PetscHMapICreateWithSize(n, &sell->colmap)); 54 for (i = 0; i < n; i++) PetscCall(PetscHMapISet(sell->colmap, sell->garray[i] + 1, i + 1)); 55 #else 56 PetscCall(PetscCalloc1(mat->cmap->N + 1, &sell->colmap)); 57 for (i = 0; i < n; i++) sell->colmap[sell->garray[i]] = i + 1; 58 #endif 59 PetscFunctionReturn(PETSC_SUCCESS); 60 } 61 62 #define MatSetValues_SeqSELL_A_Private(row, col, value, addv, orow, ocol) \ 63 { \ 64 if (col <= lastcol1) low1 = 0; \ 65 else high1 = nrow1; \ 66 lastcol1 = col; \ 67 while (high1 - low1 > 5) { \ 68 t = (low1 + high1) / 2; \ 69 if (cp1[sliceheight * t] > col) high1 = t; \ 70 else low1 = t; \ 71 } \ 72 for (_i = low1; _i < high1; _i++) { \ 73 if (cp1[sliceheight * _i] > col) break; \ 74 if (cp1[sliceheight * _i] == col) { \ 75 if (addv == ADD_VALUES) vp1[sliceheight * _i] += value; \ 76 else vp1[sliceheight * _i] = value; \ 77 inserted = PETSC_TRUE; \ 78 goto a_noinsert; \ 79 } \ 80 } \ 81 if (value == 0.0 && ignorezeroentries) { \ 82 low1 = 0; \ 83 high1 = nrow1; \ 84 goto a_noinsert; \ 85 } \ 86 if (nonew == 1) { \ 87 low1 = 0; \ 88 high1 = nrow1; \ 89 goto a_noinsert; \ 90 } \ 91 PetscCheck(nonew != -1, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "Inserting a new nonzero at global row/column (%" PetscInt_FMT ", %" PetscInt_FMT ") into matrix", orow, ocol); \ 92 MatSeqXSELLReallocateSELL(A, am, 1, nrow1, a->sliidx, a->sliceheight, row / sliceheight, row, col, a->colidx, a->val, cp1, vp1, nonew, MatScalar); \ 93 /* shift up all the later entries in this row */ \ 94 for (ii = nrow1 - 1; ii >= _i; ii--) { \ 95 cp1[sliceheight * (ii + 1)] = cp1[sliceheight * ii]; \ 96 vp1[sliceheight * (ii + 1)] = vp1[sliceheight * ii]; \ 97 } \ 98 cp1[sliceheight * _i] = col; \ 99 vp1[sliceheight * _i] = value; \ 100 a->nz++; \ 101 nrow1++; \ 102 a_noinsert:; \ 103 a->rlen[row] = nrow1; \ 104 } 105 106 #define MatSetValues_SeqSELL_B_Private(row, col, value, addv, orow, ocol) \ 107 { \ 108 if (col <= lastcol2) low2 = 0; \ 109 else high2 = nrow2; \ 110 lastcol2 = col; \ 111 while (high2 - low2 > 5) { \ 112 t = (low2 + high2) / 2; \ 113 if (cp2[sliceheight * t] > col) high2 = t; \ 114 else low2 = t; \ 115 } \ 116 for (_i = low2; _i < high2; _i++) { \ 117 if (cp2[sliceheight * _i] > col) break; \ 118 if (cp2[sliceheight * _i] == col) { \ 119 if (addv == ADD_VALUES) vp2[sliceheight * _i] += value; \ 120 else vp2[sliceheight * _i] = value; \ 121 inserted = PETSC_TRUE; \ 122 goto b_noinsert; \ 123 } \ 124 } \ 125 if (value == 0.0 && ignorezeroentries) { \ 126 low2 = 0; \ 127 high2 = nrow2; \ 128 goto b_noinsert; \ 129 } \ 130 if (nonew == 1) { \ 131 low2 = 0; \ 132 high2 = nrow2; \ 133 goto b_noinsert; \ 134 } \ 135 PetscCheck(nonew != -1, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "Inserting a new nonzero at global row/column (%" PetscInt_FMT ", %" PetscInt_FMT ") into matrix", orow, ocol); \ 136 MatSeqXSELLReallocateSELL(B, bm, 1, nrow2, b->sliidx, b->sliceheight, row / sliceheight, row, col, b->colidx, b->val, cp2, vp2, nonew, MatScalar); \ 137 /* shift up all the later entries in this row */ \ 138 for (ii = nrow2 - 1; ii >= _i; ii--) { \ 139 cp2[sliceheight * (ii + 1)] = cp2[sliceheight * ii]; \ 140 vp2[sliceheight * (ii + 1)] = vp2[sliceheight * ii]; \ 141 } \ 142 cp2[sliceheight * _i] = col; \ 143 vp2[sliceheight * _i] = value; \ 144 b->nz++; \ 145 nrow2++; \ 146 b_noinsert:; \ 147 b->rlen[row] = nrow2; \ 148 } 149 150 static PetscErrorCode MatSetValues_MPISELL(Mat mat, PetscInt m, const PetscInt im[], PetscInt n, const PetscInt in[], const PetscScalar v[], InsertMode addv) 151 { 152 Mat_MPISELL *sell = (Mat_MPISELL *)mat->data; 153 PetscScalar value; 154 PetscInt i, j, rstart = mat->rmap->rstart, rend = mat->rmap->rend, shift1, shift2; 155 PetscInt cstart = mat->cmap->rstart, cend = mat->cmap->rend, row, col; 156 PetscBool roworiented = sell->roworiented; 157 158 /* Some Variables required in the macro */ 159 Mat A = sell->A; 160 Mat_SeqSELL *a = (Mat_SeqSELL *)A->data; 161 PetscBool ignorezeroentries = a->ignorezeroentries, found; 162 Mat B = sell->B; 163 Mat_SeqSELL *b = (Mat_SeqSELL *)B->data; 164 PetscInt *cp1, *cp2, ii, _i, nrow1, nrow2, low1, high1, low2, high2, t, lastcol1, lastcol2, sliceheight = a->sliceheight; 165 MatScalar *vp1, *vp2; 166 167 PetscFunctionBegin; 168 for (i = 0; i < m; i++) { 169 if (im[i] < 0) continue; 170 PetscCheck(im[i] < mat->rmap->N, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "Row too large: row %" PetscInt_FMT " max %" PetscInt_FMT, im[i], mat->rmap->N - 1); 171 if (im[i] >= rstart && im[i] < rend) { 172 row = im[i] - rstart; 173 lastcol1 = -1; 174 shift1 = a->sliidx[row / sliceheight] + (row % sliceheight); /* starting index of the row */ 175 cp1 = PetscSafePointerPlusOffset(a->colidx, shift1); 176 vp1 = PetscSafePointerPlusOffset(a->val, shift1); 177 nrow1 = a->rlen[row]; 178 low1 = 0; 179 high1 = nrow1; 180 lastcol2 = -1; 181 shift2 = b->sliidx[row / sliceheight] + (row % sliceheight); /* starting index of the row */ 182 cp2 = PetscSafePointerPlusOffset(b->colidx, shift2); 183 vp2 = PetscSafePointerPlusOffset(b->val, shift2); 184 nrow2 = b->rlen[row]; 185 low2 = 0; 186 high2 = nrow2; 187 188 for (j = 0; j < n; j++) { 189 if (roworiented) value = v[i * n + j]; 190 else value = v[i + j * m]; 191 if (ignorezeroentries && value == 0.0 && (addv == ADD_VALUES)) continue; 192 if (in[j] >= cstart && in[j] < cend) { 193 col = in[j] - cstart; 194 MatSetValue_SeqSELL_Private(A, row, col, value, addv, im[i], in[j], cp1, vp1, lastcol1, low1, high1); /* set one value */ 195 #if defined(PETSC_HAVE_CUDA) 196 if (A->offloadmask != PETSC_OFFLOAD_UNALLOCATED && found) A->offloadmask = PETSC_OFFLOAD_CPU; 197 #endif 198 } else if (in[j] < 0) { 199 continue; 200 } else { 201 PetscCheck(in[j] < mat->cmap->N, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "Column too large: col %" PetscInt_FMT " max %" PetscInt_FMT, in[j], mat->cmap->N - 1); 202 if (mat->was_assembled) { 203 if (!sell->colmap) PetscCall(MatCreateColmap_MPISELL_Private(mat)); 204 #if defined(PETSC_USE_CTABLE) 205 PetscCall(PetscHMapIGetWithDefault(sell->colmap, in[j] + 1, 0, &col)); 206 col--; 207 #else 208 col = sell->colmap[in[j]] - 1; 209 #endif 210 if (col < 0 && !((Mat_SeqSELL *)sell->B->data)->nonew) { 211 PetscCall(MatDisAssemble_MPISELL(mat)); 212 col = in[j]; 213 /* Reinitialize the variables required by MatSetValues_SeqSELL_B_Private() */ 214 B = sell->B; 215 b = (Mat_SeqSELL *)B->data; 216 shift2 = b->sliidx[row / sliceheight] + (row % sliceheight); /* starting index of the row */ 217 cp2 = b->colidx + shift2; 218 vp2 = b->val + shift2; 219 nrow2 = b->rlen[row]; 220 low2 = 0; 221 high2 = nrow2; 222 found = PETSC_FALSE; 223 } else { 224 PetscCheck(col >= 0, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "Inserting a new nonzero at global row/column (%" PetscInt_FMT ", %" PetscInt_FMT ") into matrix", im[i], in[j]); 225 } 226 } else col = in[j]; 227 MatSetValue_SeqSELL_Private(B, row, col, value, addv, im[i], in[j], cp2, vp2, lastcol2, low2, high2); /* set one value */ 228 #if defined(PETSC_HAVE_CUDA) 229 if (B->offloadmask != PETSC_OFFLOAD_UNALLOCATED && found) B->offloadmask = PETSC_OFFLOAD_CPU; 230 #endif 231 } 232 } 233 } else { 234 PetscCheck(!mat->nooffprocentries, PETSC_COMM_SELF, PETSC_ERR_ARG_WRONG, "Setting off process row %" PetscInt_FMT " even though MatSetOption(,MAT_NO_OFF_PROC_ENTRIES,PETSC_TRUE) was set", im[i]); 235 if (!sell->donotstash) { 236 mat->assembled = PETSC_FALSE; 237 if (roworiented) { 238 PetscCall(MatStashValuesRow_Private(&mat->stash, im[i], n, in, v + i * n, (PetscBool)(ignorezeroentries && (addv == ADD_VALUES)))); 239 } else { 240 PetscCall(MatStashValuesCol_Private(&mat->stash, im[i], n, in, v + i, m, (PetscBool)(ignorezeroentries && (addv == ADD_VALUES)))); 241 } 242 } 243 } 244 } 245 PetscFunctionReturn(PETSC_SUCCESS); 246 } 247 248 static PetscErrorCode MatGetValues_MPISELL(Mat mat, PetscInt m, const PetscInt idxm[], PetscInt n, const PetscInt idxn[], PetscScalar v[]) 249 { 250 Mat_MPISELL *sell = (Mat_MPISELL *)mat->data; 251 PetscInt i, j, rstart = mat->rmap->rstart, rend = mat->rmap->rend; 252 PetscInt cstart = mat->cmap->rstart, cend = mat->cmap->rend, row, col; 253 254 PetscFunctionBegin; 255 for (i = 0; i < m; i++) { 256 if (idxm[i] < 0) continue; /* negative row */ 257 PetscCheck(idxm[i] < mat->rmap->N, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "Row too large: row %" PetscInt_FMT " max %" PetscInt_FMT, idxm[i], mat->rmap->N - 1); 258 PetscCheck(idxm[i] >= rstart && idxm[i] < rend, PETSC_COMM_SELF, PETSC_ERR_SUP, "Only local values currently supported"); 259 row = idxm[i] - rstart; 260 for (j = 0; j < n; j++) { 261 if (idxn[j] < 0) continue; /* negative column */ 262 PetscCheck(idxn[j] < mat->cmap->N, PETSC_COMM_SELF, PETSC_ERR_ARG_OUTOFRANGE, "Column too large: col %" PetscInt_FMT " max %" PetscInt_FMT, idxn[j], mat->cmap->N - 1); 263 if (idxn[j] >= cstart && idxn[j] < cend) { 264 col = idxn[j] - cstart; 265 PetscCall(MatGetValues(sell->A, 1, &row, 1, &col, v + i * n + j)); 266 } else { 267 if (!sell->colmap) PetscCall(MatCreateColmap_MPISELL_Private(mat)); 268 #if defined(PETSC_USE_CTABLE) 269 PetscCall(PetscHMapIGetWithDefault(sell->colmap, idxn[j] + 1, 0, &col)); 270 col--; 271 #else 272 col = sell->colmap[idxn[j]] - 1; 273 #endif 274 if (col < 0 || sell->garray[col] != idxn[j]) *(v + i * n + j) = 0.0; 275 else PetscCall(MatGetValues(sell->B, 1, &row, 1, &col, v + i * n + j)); 276 } 277 } 278 } 279 PetscFunctionReturn(PETSC_SUCCESS); 280 } 281 282 static PetscErrorCode MatAssemblyBegin_MPISELL(Mat mat, MatAssemblyType mode) 283 { 284 Mat_MPISELL *sell = (Mat_MPISELL *)mat->data; 285 PetscInt nstash, reallocs; 286 287 PetscFunctionBegin; 288 if (sell->donotstash || mat->nooffprocentries) PetscFunctionReturn(PETSC_SUCCESS); 289 290 PetscCall(MatStashScatterBegin_Private(mat, &mat->stash, mat->rmap->range)); 291 PetscCall(MatStashGetInfo_Private(&mat->stash, &nstash, &reallocs)); 292 PetscCall(PetscInfo(sell->A, "Stash has %" PetscInt_FMT " entries, uses %" PetscInt_FMT " mallocs.\n", nstash, reallocs)); 293 PetscFunctionReturn(PETSC_SUCCESS); 294 } 295 296 PetscErrorCode MatAssemblyEnd_MPISELL(Mat mat, MatAssemblyType mode) 297 { 298 Mat_MPISELL *sell = (Mat_MPISELL *)mat->data; 299 PetscMPIInt n; 300 PetscInt i, flg; 301 PetscInt *row, *col; 302 PetscScalar *val; 303 PetscBool all_assembled; 304 /* do not use 'b = (Mat_SeqSELL*)sell->B->data' as B can be reset in disassembly */ 305 PetscFunctionBegin; 306 if (!sell->donotstash && !mat->nooffprocentries) { 307 while (1) { 308 PetscCall(MatStashScatterGetMesg_Private(&mat->stash, &n, &row, &col, &val, &flg)); 309 if (!flg) break; 310 311 for (i = 0; i < n; i++) { /* assemble one by one */ 312 PetscCall(MatSetValues_MPISELL(mat, 1, row + i, 1, col + i, val + i, mat->insertmode)); 313 } 314 } 315 PetscCall(MatStashScatterEnd_Private(&mat->stash)); 316 } 317 #if defined(PETSC_HAVE_CUDA) 318 if (mat->offloadmask == PETSC_OFFLOAD_CPU) sell->A->offloadmask = PETSC_OFFLOAD_CPU; 319 #endif 320 PetscCall(MatAssemblyBegin(sell->A, mode)); 321 PetscCall(MatAssemblyEnd(sell->A, mode)); 322 323 /* 324 determine if any process has disassembled, if so we must 325 also disassemble ourselves, in order that we may reassemble. 326 */ 327 /* 328 if nonzero structure of submatrix B cannot change then we know that 329 no process disassembled thus we can skip this stuff 330 */ 331 if (!((Mat_SeqSELL *)sell->B->data)->nonew) { 332 PetscCallMPI(MPIU_Allreduce(&mat->was_assembled, &all_assembled, 1, MPI_C_BOOL, MPI_LAND, PetscObjectComm((PetscObject)mat))); 333 if (mat->was_assembled && !all_assembled) PetscCall(MatDisAssemble_MPISELL(mat)); 334 } 335 if (!mat->was_assembled && mode == MAT_FINAL_ASSEMBLY) PetscCall(MatSetUpMultiply_MPISELL(mat)); 336 #if defined(PETSC_HAVE_CUDA) 337 if (mat->offloadmask == PETSC_OFFLOAD_CPU && sell->B->offloadmask != PETSC_OFFLOAD_UNALLOCATED) sell->B->offloadmask = PETSC_OFFLOAD_CPU; 338 #endif 339 PetscCall(MatAssemblyBegin(sell->B, mode)); 340 PetscCall(MatAssemblyEnd(sell->B, mode)); 341 PetscCall(PetscFree2(sell->rowvalues, sell->rowindices)); 342 sell->rowvalues = NULL; 343 PetscCall(VecDestroy(&sell->diag)); 344 345 /* if no new nonzero locations are allowed in matrix then only set the matrix state the first time through */ 346 if ((!mat->was_assembled && mode == MAT_FINAL_ASSEMBLY) || !((Mat_SeqSELL *)sell->A->data)->nonew) { 347 PetscObjectState state = sell->A->nonzerostate + sell->B->nonzerostate; 348 PetscCallMPI(MPIU_Allreduce(&state, &mat->nonzerostate, 1, MPIU_INT64, MPI_SUM, PetscObjectComm((PetscObject)mat))); 349 } 350 #if defined(PETSC_HAVE_CUDA) 351 mat->offloadmask = PETSC_OFFLOAD_BOTH; 352 #endif 353 PetscFunctionReturn(PETSC_SUCCESS); 354 } 355 356 static PetscErrorCode MatZeroEntries_MPISELL(Mat A) 357 { 358 Mat_MPISELL *l = (Mat_MPISELL *)A->data; 359 360 PetscFunctionBegin; 361 PetscCall(MatZeroEntries(l->A)); 362 PetscCall(MatZeroEntries(l->B)); 363 PetscFunctionReturn(PETSC_SUCCESS); 364 } 365 366 static PetscErrorCode MatMult_MPISELL(Mat A, Vec xx, Vec yy) 367 { 368 Mat_MPISELL *a = (Mat_MPISELL *)A->data; 369 PetscInt nt; 370 371 PetscFunctionBegin; 372 PetscCall(VecGetLocalSize(xx, &nt)); 373 PetscCheck(nt == A->cmap->n, PETSC_COMM_SELF, PETSC_ERR_ARG_SIZ, "Incompatible partition of A (%" PetscInt_FMT ") and xx (%" PetscInt_FMT ")", A->cmap->n, nt); 374 PetscCall(VecScatterBegin(a->Mvctx, xx, a->lvec, INSERT_VALUES, SCATTER_FORWARD)); 375 PetscCall((*a->A->ops->mult)(a->A, xx, yy)); 376 PetscCall(VecScatterEnd(a->Mvctx, xx, a->lvec, INSERT_VALUES, SCATTER_FORWARD)); 377 PetscCall((*a->B->ops->multadd)(a->B, a->lvec, yy, yy)); 378 PetscFunctionReturn(PETSC_SUCCESS); 379 } 380 381 static PetscErrorCode MatMultDiagonalBlock_MPISELL(Mat A, Vec bb, Vec xx) 382 { 383 Mat_MPISELL *a = (Mat_MPISELL *)A->data; 384 385 PetscFunctionBegin; 386 PetscCall(MatMultDiagonalBlock(a->A, bb, xx)); 387 PetscFunctionReturn(PETSC_SUCCESS); 388 } 389 390 static PetscErrorCode MatMultAdd_MPISELL(Mat A, Vec xx, Vec yy, Vec zz) 391 { 392 Mat_MPISELL *a = (Mat_MPISELL *)A->data; 393 394 PetscFunctionBegin; 395 PetscCall(VecScatterBegin(a->Mvctx, xx, a->lvec, INSERT_VALUES, SCATTER_FORWARD)); 396 PetscCall((*a->A->ops->multadd)(a->A, xx, yy, zz)); 397 PetscCall(VecScatterEnd(a->Mvctx, xx, a->lvec, INSERT_VALUES, SCATTER_FORWARD)); 398 PetscCall((*a->B->ops->multadd)(a->B, a->lvec, zz, zz)); 399 PetscFunctionReturn(PETSC_SUCCESS); 400 } 401 402 static PetscErrorCode MatMultTranspose_MPISELL(Mat A, Vec xx, Vec yy) 403 { 404 Mat_MPISELL *a = (Mat_MPISELL *)A->data; 405 406 PetscFunctionBegin; 407 /* do nondiagonal part */ 408 PetscCall((*a->B->ops->multtranspose)(a->B, xx, a->lvec)); 409 /* do local part */ 410 PetscCall((*a->A->ops->multtranspose)(a->A, xx, yy)); 411 /* add partial results together */ 412 PetscCall(VecScatterBegin(a->Mvctx, a->lvec, yy, ADD_VALUES, SCATTER_REVERSE)); 413 PetscCall(VecScatterEnd(a->Mvctx, a->lvec, yy, ADD_VALUES, SCATTER_REVERSE)); 414 PetscFunctionReturn(PETSC_SUCCESS); 415 } 416 417 static PetscErrorCode MatIsTranspose_MPISELL(Mat Amat, Mat Bmat, PetscReal tol, PetscBool *f) 418 { 419 MPI_Comm comm; 420 Mat_MPISELL *Asell = (Mat_MPISELL *)Amat->data, *Bsell; 421 Mat Adia = Asell->A, Bdia, Aoff, Boff, *Aoffs, *Boffs; 422 IS Me, Notme; 423 PetscInt M, N, first, last, *notme, i; 424 PetscMPIInt size; 425 426 PetscFunctionBegin; 427 /* Easy test: symmetric diagonal block */ 428 Bsell = (Mat_MPISELL *)Bmat->data; 429 Bdia = Bsell->A; 430 PetscCall(MatIsTranspose(Adia, Bdia, tol, f)); 431 if (!*f) PetscFunctionReturn(PETSC_SUCCESS); 432 PetscCall(PetscObjectGetComm((PetscObject)Amat, &comm)); 433 PetscCallMPI(MPI_Comm_size(comm, &size)); 434 if (size == 1) PetscFunctionReturn(PETSC_SUCCESS); 435 436 /* Hard test: off-diagonal block. This takes a MatCreateSubMatrix. */ 437 PetscCall(MatGetSize(Amat, &M, &N)); 438 PetscCall(MatGetOwnershipRange(Amat, &first, &last)); 439 PetscCall(PetscMalloc1(N - last + first, ¬me)); 440 for (i = 0; i < first; i++) notme[i] = i; 441 for (i = last; i < M; i++) notme[i - last + first] = i; 442 PetscCall(ISCreateGeneral(MPI_COMM_SELF, N - last + first, notme, PETSC_COPY_VALUES, &Notme)); 443 PetscCall(ISCreateStride(MPI_COMM_SELF, last - first, first, 1, &Me)); 444 PetscCall(MatCreateSubMatrices(Amat, 1, &Me, &Notme, MAT_INITIAL_MATRIX, &Aoffs)); 445 Aoff = Aoffs[0]; 446 PetscCall(MatCreateSubMatrices(Bmat, 1, &Notme, &Me, MAT_INITIAL_MATRIX, &Boffs)); 447 Boff = Boffs[0]; 448 PetscCall(MatIsTranspose(Aoff, Boff, tol, f)); 449 PetscCall(MatDestroyMatrices(1, &Aoffs)); 450 PetscCall(MatDestroyMatrices(1, &Boffs)); 451 PetscCall(ISDestroy(&Me)); 452 PetscCall(ISDestroy(&Notme)); 453 PetscCall(PetscFree(notme)); 454 PetscFunctionReturn(PETSC_SUCCESS); 455 } 456 457 static PetscErrorCode MatMultTransposeAdd_MPISELL(Mat A, Vec xx, Vec yy, Vec zz) 458 { 459 Mat_MPISELL *a = (Mat_MPISELL *)A->data; 460 461 PetscFunctionBegin; 462 /* do nondiagonal part */ 463 PetscCall((*a->B->ops->multtranspose)(a->B, xx, a->lvec)); 464 /* do local part */ 465 PetscCall((*a->A->ops->multtransposeadd)(a->A, xx, yy, zz)); 466 /* add partial results together */ 467 PetscCall(VecScatterBegin(a->Mvctx, a->lvec, zz, ADD_VALUES, SCATTER_REVERSE)); 468 PetscCall(VecScatterEnd(a->Mvctx, a->lvec, zz, ADD_VALUES, SCATTER_REVERSE)); 469 PetscFunctionReturn(PETSC_SUCCESS); 470 } 471 472 /* 473 This only works correctly for square matrices where the subblock A->A is the 474 diagonal block 475 */ 476 static PetscErrorCode MatGetDiagonal_MPISELL(Mat A, Vec v) 477 { 478 Mat_MPISELL *a = (Mat_MPISELL *)A->data; 479 480 PetscFunctionBegin; 481 PetscCheck(A->rmap->N == A->cmap->N, PetscObjectComm((PetscObject)A), PETSC_ERR_SUP, "Supports only square matrix where A->A is diag block"); 482 PetscCheck(A->rmap->rstart == A->cmap->rstart && A->rmap->rend == A->cmap->rend, PETSC_COMM_SELF, PETSC_ERR_ARG_SIZ, "row partition must equal col partition"); 483 PetscCall(MatGetDiagonal(a->A, v)); 484 PetscFunctionReturn(PETSC_SUCCESS); 485 } 486 487 static PetscErrorCode MatScale_MPISELL(Mat A, PetscScalar aa) 488 { 489 Mat_MPISELL *a = (Mat_MPISELL *)A->data; 490 491 PetscFunctionBegin; 492 PetscCall(MatScale(a->A, aa)); 493 PetscCall(MatScale(a->B, aa)); 494 PetscFunctionReturn(PETSC_SUCCESS); 495 } 496 497 PetscErrorCode MatDestroy_MPISELL(Mat mat) 498 { 499 Mat_MPISELL *sell = (Mat_MPISELL *)mat->data; 500 501 PetscFunctionBegin; 502 PetscCall(PetscLogObjectState((PetscObject)mat, "Rows=%" PetscInt_FMT ", Cols=%" PetscInt_FMT, mat->rmap->N, mat->cmap->N)); 503 PetscCall(MatStashDestroy_Private(&mat->stash)); 504 PetscCall(VecDestroy(&sell->diag)); 505 PetscCall(MatDestroy(&sell->A)); 506 PetscCall(MatDestroy(&sell->B)); 507 #if defined(PETSC_USE_CTABLE) 508 PetscCall(PetscHMapIDestroy(&sell->colmap)); 509 #else 510 PetscCall(PetscFree(sell->colmap)); 511 #endif 512 PetscCall(PetscFree(sell->garray)); 513 PetscCall(VecDestroy(&sell->lvec)); 514 PetscCall(VecScatterDestroy(&sell->Mvctx)); 515 PetscCall(PetscFree2(sell->rowvalues, sell->rowindices)); 516 PetscCall(PetscFree(sell->ld)); 517 PetscCall(PetscFree(mat->data)); 518 519 PetscCall(PetscObjectChangeTypeName((PetscObject)mat, NULL)); 520 PetscCall(PetscObjectComposeFunction((PetscObject)mat, "MatStoreValues_C", NULL)); 521 PetscCall(PetscObjectComposeFunction((PetscObject)mat, "MatRetrieveValues_C", NULL)); 522 PetscCall(PetscObjectComposeFunction((PetscObject)mat, "MatIsTranspose_C", NULL)); 523 PetscCall(PetscObjectComposeFunction((PetscObject)mat, "MatMPISELLSetPreallocation_C", NULL)); 524 PetscCall(PetscObjectComposeFunction((PetscObject)mat, "MatConvert_mpisell_mpiaij_C", NULL)); 525 #if defined(PETSC_HAVE_CUDA) 526 PetscCall(PetscObjectComposeFunction((PetscObject)mat, "MatConvert_mpisell_mpisellcuda_C", NULL)); 527 #endif 528 PetscCall(PetscObjectComposeFunction((PetscObject)mat, "MatDiagonalScaleLocal_C", NULL)); 529 PetscFunctionReturn(PETSC_SUCCESS); 530 } 531 532 #include <petscdraw.h> 533 static PetscErrorCode MatView_MPISELL_ASCIIorDraworSocket(Mat mat, PetscViewer viewer) 534 { 535 Mat_MPISELL *sell = (Mat_MPISELL *)mat->data; 536 PetscMPIInt rank = sell->rank, size = sell->size; 537 PetscBool isdraw, isascii, isbinary; 538 PetscViewer sviewer; 539 PetscViewerFormat format; 540 541 PetscFunctionBegin; 542 PetscCall(PetscObjectTypeCompare((PetscObject)viewer, PETSCVIEWERDRAW, &isdraw)); 543 PetscCall(PetscObjectTypeCompare((PetscObject)viewer, PETSCVIEWERASCII, &isascii)); 544 PetscCall(PetscObjectTypeCompare((PetscObject)viewer, PETSCVIEWERBINARY, &isbinary)); 545 if (isascii) { 546 PetscCall(PetscViewerGetFormat(viewer, &format)); 547 if (format == PETSC_VIEWER_ASCII_INFO_DETAIL) { 548 MatInfo info; 549 PetscInt *inodes; 550 551 PetscCallMPI(MPI_Comm_rank(PetscObjectComm((PetscObject)mat), &rank)); 552 PetscCall(MatGetInfo(mat, MAT_LOCAL, &info)); 553 PetscCall(MatInodeGetInodeSizes(sell->A, NULL, &inodes, NULL)); 554 PetscCall(PetscViewerASCIIPushSynchronized(viewer)); 555 if (!inodes) { 556 PetscCall(PetscViewerASCIISynchronizedPrintf(viewer, "[%d] Local rows %" PetscInt_FMT " nz %" PetscInt_FMT " nz alloced %" PetscInt_FMT " mem %" PetscInt_FMT ", not using I-node routines\n", rank, mat->rmap->n, (PetscInt)info.nz_used, 557 (PetscInt)info.nz_allocated, (PetscInt)info.memory)); 558 } else { 559 PetscCall(PetscViewerASCIISynchronizedPrintf(viewer, "[%d] Local rows %" PetscInt_FMT " nz %" PetscInt_FMT " nz alloced %" PetscInt_FMT " mem %" PetscInt_FMT ", using I-node routines\n", rank, mat->rmap->n, (PetscInt)info.nz_used, 560 (PetscInt)info.nz_allocated, (PetscInt)info.memory)); 561 } 562 PetscCall(MatGetInfo(sell->A, MAT_LOCAL, &info)); 563 PetscCall(PetscViewerASCIISynchronizedPrintf(viewer, "[%d] on-diagonal part: nz %" PetscInt_FMT " \n", rank, (PetscInt)info.nz_used)); 564 PetscCall(MatGetInfo(sell->B, MAT_LOCAL, &info)); 565 PetscCall(PetscViewerASCIISynchronizedPrintf(viewer, "[%d] off-diagonal part: nz %" PetscInt_FMT " \n", rank, (PetscInt)info.nz_used)); 566 PetscCall(PetscViewerFlush(viewer)); 567 PetscCall(PetscViewerASCIIPopSynchronized(viewer)); 568 PetscCall(PetscViewerASCIIPrintf(viewer, "Information on VecScatter used in matrix-vector product: \n")); 569 PetscCall(VecScatterView(sell->Mvctx, viewer)); 570 PetscFunctionReturn(PETSC_SUCCESS); 571 } else if (format == PETSC_VIEWER_ASCII_INFO) { 572 PetscInt inodecount, inodelimit, *inodes; 573 PetscCall(MatInodeGetInodeSizes(sell->A, &inodecount, &inodes, &inodelimit)); 574 if (inodes) { 575 PetscCall(PetscViewerASCIIPrintf(viewer, "using I-node (on process 0) routines: found %" PetscInt_FMT " nodes, limit used is %" PetscInt_FMT "\n", inodecount, inodelimit)); 576 } else { 577 PetscCall(PetscViewerASCIIPrintf(viewer, "not using I-node (on process 0) routines\n")); 578 } 579 PetscFunctionReturn(PETSC_SUCCESS); 580 } else if (format == PETSC_VIEWER_ASCII_FACTOR_INFO) { 581 PetscFunctionReturn(PETSC_SUCCESS); 582 } 583 } else if (isbinary) { 584 if (size == 1) { 585 PetscCall(PetscObjectSetName((PetscObject)sell->A, ((PetscObject)mat)->name)); 586 PetscCall(MatView(sell->A, viewer)); 587 } else { 588 /* PetscCall(MatView_MPISELL_Binary(mat,viewer)); */ 589 } 590 PetscFunctionReturn(PETSC_SUCCESS); 591 } else if (isdraw) { 592 PetscDraw draw; 593 PetscBool isnull; 594 PetscCall(PetscViewerDrawGetDraw(viewer, 0, &draw)); 595 PetscCall(PetscDrawIsNull(draw, &isnull)); 596 if (isnull) PetscFunctionReturn(PETSC_SUCCESS); 597 } 598 599 { 600 /* assemble the entire matrix onto first processor. */ 601 Mat A; 602 Mat_SeqSELL *Aloc; 603 PetscInt M = mat->rmap->N, N = mat->cmap->N, *acolidx, row, col, i, j; 604 MatScalar *aval; 605 PetscBool isnonzero; 606 607 PetscCall(MatCreate(PetscObjectComm((PetscObject)mat), &A)); 608 if (rank == 0) { 609 PetscCall(MatSetSizes(A, M, N, M, N)); 610 } else { 611 PetscCall(MatSetSizes(A, 0, 0, M, N)); 612 } 613 /* This is just a temporary matrix, so explicitly using MATMPISELL is probably best */ 614 PetscCall(MatSetType(A, MATMPISELL)); 615 PetscCall(MatMPISELLSetPreallocation(A, 0, NULL, 0, NULL)); 616 PetscCall(MatSetOption(A, MAT_NEW_NONZERO_LOCATION_ERR, PETSC_FALSE)); 617 618 /* copy over the A part */ 619 Aloc = (Mat_SeqSELL *)sell->A->data; 620 acolidx = Aloc->colidx; 621 aval = Aloc->val; 622 for (i = 0; i < Aloc->totalslices; i++) { /* loop over slices */ 623 for (j = Aloc->sliidx[i]; j < Aloc->sliidx[i + 1]; j++) { 624 isnonzero = (PetscBool)((j - Aloc->sliidx[i]) / Aloc->sliceheight < Aloc->rlen[i * Aloc->sliceheight + j % Aloc->sliceheight]); 625 if (isnonzero) { /* check the mask bit */ 626 row = i * Aloc->sliceheight + j % Aloc->sliceheight + mat->rmap->rstart; 627 col = *acolidx + mat->rmap->rstart; 628 PetscCall(MatSetValues(A, 1, &row, 1, &col, aval, INSERT_VALUES)); 629 } 630 aval++; 631 acolidx++; 632 } 633 } 634 635 /* copy over the B part */ 636 Aloc = (Mat_SeqSELL *)sell->B->data; 637 acolidx = Aloc->colidx; 638 aval = Aloc->val; 639 for (i = 0; i < Aloc->totalslices; i++) { 640 for (j = Aloc->sliidx[i]; j < Aloc->sliidx[i + 1]; j++) { 641 isnonzero = (PetscBool)((j - Aloc->sliidx[i]) / Aloc->sliceheight < Aloc->rlen[i * Aloc->sliceheight + j % Aloc->sliceheight]); 642 if (isnonzero) { 643 row = i * Aloc->sliceheight + j % Aloc->sliceheight + mat->rmap->rstart; 644 col = sell->garray[*acolidx]; 645 PetscCall(MatSetValues(A, 1, &row, 1, &col, aval, INSERT_VALUES)); 646 } 647 aval++; 648 acolidx++; 649 } 650 } 651 652 PetscCall(MatAssemblyBegin(A, MAT_FINAL_ASSEMBLY)); 653 PetscCall(MatAssemblyEnd(A, MAT_FINAL_ASSEMBLY)); 654 /* 655 Everyone has to call to draw the matrix since the graphics waits are 656 synchronized across all processors that share the PetscDraw object 657 */ 658 PetscCall(PetscViewerGetSubViewer(viewer, PETSC_COMM_SELF, &sviewer)); 659 if (rank == 0) { 660 PetscCall(PetscObjectSetName((PetscObject)((Mat_MPISELL *)A->data)->A, ((PetscObject)mat)->name)); 661 PetscCall(MatView_SeqSELL(((Mat_MPISELL *)A->data)->A, sviewer)); 662 } 663 PetscCall(PetscViewerRestoreSubViewer(viewer, PETSC_COMM_SELF, &sviewer)); 664 PetscCall(MatDestroy(&A)); 665 } 666 PetscFunctionReturn(PETSC_SUCCESS); 667 } 668 669 static PetscErrorCode MatView_MPISELL(Mat mat, PetscViewer viewer) 670 { 671 PetscBool isascii, isdraw, issocket, isbinary; 672 673 PetscFunctionBegin; 674 PetscCall(PetscObjectTypeCompare((PetscObject)viewer, PETSCVIEWERASCII, &isascii)); 675 PetscCall(PetscObjectTypeCompare((PetscObject)viewer, PETSCVIEWERDRAW, &isdraw)); 676 PetscCall(PetscObjectTypeCompare((PetscObject)viewer, PETSCVIEWERBINARY, &isbinary)); 677 PetscCall(PetscObjectTypeCompare((PetscObject)viewer, PETSCVIEWERSOCKET, &issocket)); 678 if (isascii || isdraw || isbinary || issocket) PetscCall(MatView_MPISELL_ASCIIorDraworSocket(mat, viewer)); 679 PetscFunctionReturn(PETSC_SUCCESS); 680 } 681 682 static PetscErrorCode MatGetGhosts_MPISELL(Mat mat, PetscInt *nghosts, const PetscInt *ghosts[]) 683 { 684 Mat_MPISELL *sell = (Mat_MPISELL *)mat->data; 685 686 PetscFunctionBegin; 687 PetscCall(MatGetSize(sell->B, NULL, nghosts)); 688 if (ghosts) *ghosts = sell->garray; 689 PetscFunctionReturn(PETSC_SUCCESS); 690 } 691 692 static PetscErrorCode MatGetInfo_MPISELL(Mat matin, MatInfoType flag, MatInfo *info) 693 { 694 Mat_MPISELL *mat = (Mat_MPISELL *)matin->data; 695 Mat A = mat->A, B = mat->B; 696 PetscLogDouble isend[5], irecv[5]; 697 698 PetscFunctionBegin; 699 info->block_size = 1.0; 700 PetscCall(MatGetInfo(A, MAT_LOCAL, info)); 701 702 isend[0] = info->nz_used; 703 isend[1] = info->nz_allocated; 704 isend[2] = info->nz_unneeded; 705 isend[3] = info->memory; 706 isend[4] = info->mallocs; 707 708 PetscCall(MatGetInfo(B, MAT_LOCAL, info)); 709 710 isend[0] += info->nz_used; 711 isend[1] += info->nz_allocated; 712 isend[2] += info->nz_unneeded; 713 isend[3] += info->memory; 714 isend[4] += info->mallocs; 715 if (flag == MAT_LOCAL) { 716 info->nz_used = isend[0]; 717 info->nz_allocated = isend[1]; 718 info->nz_unneeded = isend[2]; 719 info->memory = isend[3]; 720 info->mallocs = isend[4]; 721 } else if (flag == MAT_GLOBAL_MAX) { 722 PetscCallMPI(MPIU_Allreduce(isend, irecv, 5, MPIU_PETSCLOGDOUBLE, MPI_MAX, PetscObjectComm((PetscObject)matin))); 723 724 info->nz_used = irecv[0]; 725 info->nz_allocated = irecv[1]; 726 info->nz_unneeded = irecv[2]; 727 info->memory = irecv[3]; 728 info->mallocs = irecv[4]; 729 } else if (flag == MAT_GLOBAL_SUM) { 730 PetscCallMPI(MPIU_Allreduce(isend, irecv, 5, MPIU_PETSCLOGDOUBLE, MPI_SUM, PetscObjectComm((PetscObject)matin))); 731 732 info->nz_used = irecv[0]; 733 info->nz_allocated = irecv[1]; 734 info->nz_unneeded = irecv[2]; 735 info->memory = irecv[3]; 736 info->mallocs = irecv[4]; 737 } 738 info->fill_ratio_given = 0; /* no parallel LU/ILU/Cholesky */ 739 info->fill_ratio_needed = 0; 740 info->factor_mallocs = 0; 741 PetscFunctionReturn(PETSC_SUCCESS); 742 } 743 744 static PetscErrorCode MatSetOption_MPISELL(Mat A, MatOption op, PetscBool flg) 745 { 746 Mat_MPISELL *a = (Mat_MPISELL *)A->data; 747 748 PetscFunctionBegin; 749 switch (op) { 750 case MAT_NEW_NONZERO_LOCATIONS: 751 case MAT_NEW_NONZERO_ALLOCATION_ERR: 752 case MAT_UNUSED_NONZERO_LOCATION_ERR: 753 case MAT_KEEP_NONZERO_PATTERN: 754 case MAT_NEW_NONZERO_LOCATION_ERR: 755 case MAT_USE_INODES: 756 case MAT_IGNORE_ZERO_ENTRIES: 757 MatCheckPreallocated(A, 1); 758 PetscCall(MatSetOption(a->A, op, flg)); 759 PetscCall(MatSetOption(a->B, op, flg)); 760 break; 761 case MAT_ROW_ORIENTED: 762 MatCheckPreallocated(A, 1); 763 a->roworiented = flg; 764 765 PetscCall(MatSetOption(a->A, op, flg)); 766 PetscCall(MatSetOption(a->B, op, flg)); 767 break; 768 case MAT_IGNORE_OFF_PROC_ENTRIES: 769 a->donotstash = flg; 770 break; 771 case MAT_SYMMETRIC: 772 MatCheckPreallocated(A, 1); 773 PetscCall(MatSetOption(a->A, op, flg)); 774 break; 775 case MAT_STRUCTURALLY_SYMMETRIC: 776 MatCheckPreallocated(A, 1); 777 PetscCall(MatSetOption(a->A, op, flg)); 778 break; 779 case MAT_HERMITIAN: 780 MatCheckPreallocated(A, 1); 781 PetscCall(MatSetOption(a->A, op, flg)); 782 break; 783 case MAT_SYMMETRY_ETERNAL: 784 MatCheckPreallocated(A, 1); 785 PetscCall(MatSetOption(a->A, op, flg)); 786 break; 787 case MAT_STRUCTURAL_SYMMETRY_ETERNAL: 788 MatCheckPreallocated(A, 1); 789 PetscCall(MatSetOption(a->A, op, flg)); 790 break; 791 default: 792 break; 793 } 794 PetscFunctionReturn(PETSC_SUCCESS); 795 } 796 797 static PetscErrorCode MatDiagonalScale_MPISELL(Mat mat, Vec ll, Vec rr) 798 { 799 Mat_MPISELL *sell = (Mat_MPISELL *)mat->data; 800 Mat a = sell->A, b = sell->B; 801 PetscInt s1, s2, s3; 802 803 PetscFunctionBegin; 804 PetscCall(MatGetLocalSize(mat, &s2, &s3)); 805 if (rr) { 806 PetscCall(VecGetLocalSize(rr, &s1)); 807 PetscCheck(s1 == s3, PETSC_COMM_SELF, PETSC_ERR_ARG_SIZ, "right vector non-conforming local size"); 808 /* Overlap communication with computation. */ 809 PetscCall(VecScatterBegin(sell->Mvctx, rr, sell->lvec, INSERT_VALUES, SCATTER_FORWARD)); 810 } 811 if (ll) { 812 PetscCall(VecGetLocalSize(ll, &s1)); 813 PetscCheck(s1 == s2, PETSC_COMM_SELF, PETSC_ERR_ARG_SIZ, "left vector non-conforming local size"); 814 PetscUseTypeMethod(b, diagonalscale, ll, NULL); 815 } 816 /* scale the diagonal block */ 817 PetscUseTypeMethod(a, diagonalscale, ll, rr); 818 819 if (rr) { 820 /* Do a scatter end and then right scale the off-diagonal block */ 821 PetscCall(VecScatterEnd(sell->Mvctx, rr, sell->lvec, INSERT_VALUES, SCATTER_FORWARD)); 822 PetscUseTypeMethod(b, diagonalscale, NULL, sell->lvec); 823 } 824 PetscFunctionReturn(PETSC_SUCCESS); 825 } 826 827 static PetscErrorCode MatSetUnfactored_MPISELL(Mat A) 828 { 829 Mat_MPISELL *a = (Mat_MPISELL *)A->data; 830 831 PetscFunctionBegin; 832 PetscCall(MatSetUnfactored(a->A)); 833 PetscFunctionReturn(PETSC_SUCCESS); 834 } 835 836 static PetscErrorCode MatEqual_MPISELL(Mat A, Mat B, PetscBool *flag) 837 { 838 Mat_MPISELL *matB = (Mat_MPISELL *)B->data, *matA = (Mat_MPISELL *)A->data; 839 Mat a, b, c, d; 840 PetscBool flg; 841 842 PetscFunctionBegin; 843 a = matA->A; 844 b = matA->B; 845 c = matB->A; 846 d = matB->B; 847 848 PetscCall(MatEqual(a, c, &flg)); 849 if (flg) PetscCall(MatEqual(b, d, &flg)); 850 PetscCallMPI(MPIU_Allreduce(&flg, flag, 1, MPI_C_BOOL, MPI_LAND, PetscObjectComm((PetscObject)A))); 851 PetscFunctionReturn(PETSC_SUCCESS); 852 } 853 854 static PetscErrorCode MatCopy_MPISELL(Mat A, Mat B, MatStructure str) 855 { 856 Mat_MPISELL *a = (Mat_MPISELL *)A->data; 857 Mat_MPISELL *b = (Mat_MPISELL *)B->data; 858 859 PetscFunctionBegin; 860 /* If the two matrices don't have the same copy implementation, they aren't compatible for fast copy. */ 861 if ((str != SAME_NONZERO_PATTERN) || (A->ops->copy != B->ops->copy)) { 862 /* because of the column compression in the off-processor part of the matrix a->B, 863 the number of columns in a->B and b->B may be different, hence we cannot call 864 the MatCopy() directly on the two parts. If need be, we can provide a more 865 efficient copy than the MatCopy_Basic() by first uncompressing the a->B matrices 866 then copying the submatrices */ 867 PetscCall(MatCopy_Basic(A, B, str)); 868 } else { 869 PetscCall(MatCopy(a->A, b->A, str)); 870 PetscCall(MatCopy(a->B, b->B, str)); 871 } 872 PetscFunctionReturn(PETSC_SUCCESS); 873 } 874 875 static PetscErrorCode MatSetUp_MPISELL(Mat A) 876 { 877 PetscFunctionBegin; 878 PetscCall(MatMPISELLSetPreallocation(A, PETSC_DEFAULT, NULL, PETSC_DEFAULT, NULL)); 879 PetscFunctionReturn(PETSC_SUCCESS); 880 } 881 882 static PetscErrorCode MatConjugate_MPISELL(Mat mat) 883 { 884 Mat_MPISELL *sell = (Mat_MPISELL *)mat->data; 885 886 PetscFunctionBegin; 887 PetscCall(MatConjugate_SeqSELL(sell->A)); 888 PetscCall(MatConjugate_SeqSELL(sell->B)); 889 PetscFunctionReturn(PETSC_SUCCESS); 890 } 891 892 static PetscErrorCode MatInvertBlockDiagonal_MPISELL(Mat A, const PetscScalar **values) 893 { 894 Mat_MPISELL *a = (Mat_MPISELL *)A->data; 895 896 PetscFunctionBegin; 897 PetscCall(MatInvertBlockDiagonal(a->A, values)); 898 A->factorerrortype = a->A->factorerrortype; 899 PetscFunctionReturn(PETSC_SUCCESS); 900 } 901 902 static PetscErrorCode MatSetRandom_MPISELL(Mat x, PetscRandom rctx) 903 { 904 Mat_MPISELL *sell = (Mat_MPISELL *)x->data; 905 906 PetscFunctionBegin; 907 PetscCall(MatSetRandom(sell->A, rctx)); 908 PetscCall(MatSetRandom(sell->B, rctx)); 909 PetscCall(MatAssemblyBegin(x, MAT_FINAL_ASSEMBLY)); 910 PetscCall(MatAssemblyEnd(x, MAT_FINAL_ASSEMBLY)); 911 PetscFunctionReturn(PETSC_SUCCESS); 912 } 913 914 static PetscErrorCode MatSetFromOptions_MPISELL(Mat A, PetscOptionItems PetscOptionsObject) 915 { 916 PetscFunctionBegin; 917 PetscOptionsHeadBegin(PetscOptionsObject, "MPISELL options"); 918 PetscOptionsHeadEnd(); 919 PetscFunctionReturn(PETSC_SUCCESS); 920 } 921 922 static PetscErrorCode MatShift_MPISELL(Mat Y, PetscScalar a) 923 { 924 Mat_MPISELL *msell = (Mat_MPISELL *)Y->data; 925 Mat_SeqSELL *sell = (Mat_SeqSELL *)msell->A->data; 926 927 PetscFunctionBegin; 928 if (!Y->preallocated) { 929 PetscCall(MatMPISELLSetPreallocation(Y, 1, NULL, 0, NULL)); 930 } else if (!sell->nz) { 931 PetscInt nonew = sell->nonew; 932 PetscCall(MatSeqSELLSetPreallocation(msell->A, 1, NULL)); 933 sell->nonew = nonew; 934 } 935 PetscCall(MatShift_Basic(Y, a)); 936 PetscFunctionReturn(PETSC_SUCCESS); 937 } 938 939 static PetscErrorCode MatGetDiagonalBlock_MPISELL(Mat A, Mat *a) 940 { 941 PetscFunctionBegin; 942 *a = ((Mat_MPISELL *)A->data)->A; 943 PetscFunctionReturn(PETSC_SUCCESS); 944 } 945 946 static PetscErrorCode MatStoreValues_MPISELL(Mat mat) 947 { 948 Mat_MPISELL *sell = (Mat_MPISELL *)mat->data; 949 950 PetscFunctionBegin; 951 PetscCall(MatStoreValues(sell->A)); 952 PetscCall(MatStoreValues(sell->B)); 953 PetscFunctionReturn(PETSC_SUCCESS); 954 } 955 956 static PetscErrorCode MatRetrieveValues_MPISELL(Mat mat) 957 { 958 Mat_MPISELL *sell = (Mat_MPISELL *)mat->data; 959 960 PetscFunctionBegin; 961 PetscCall(MatRetrieveValues(sell->A)); 962 PetscCall(MatRetrieveValues(sell->B)); 963 PetscFunctionReturn(PETSC_SUCCESS); 964 } 965 966 static PetscErrorCode MatMPISELLSetPreallocation_MPISELL(Mat B, PetscInt d_rlenmax, const PetscInt d_rlen[], PetscInt o_rlenmax, const PetscInt o_rlen[]) 967 { 968 Mat_MPISELL *b; 969 970 PetscFunctionBegin; 971 PetscCall(PetscLayoutSetUp(B->rmap)); 972 PetscCall(PetscLayoutSetUp(B->cmap)); 973 b = (Mat_MPISELL *)B->data; 974 975 if (!B->preallocated) { 976 /* Explicitly create 2 MATSEQSELL matrices. */ 977 PetscCall(MatCreate(PETSC_COMM_SELF, &b->A)); 978 PetscCall(MatSetSizes(b->A, B->rmap->n, B->cmap->n, B->rmap->n, B->cmap->n)); 979 PetscCall(MatSetBlockSizesFromMats(b->A, B, B)); 980 PetscCall(MatSetType(b->A, MATSEQSELL)); 981 PetscCall(MatCreate(PETSC_COMM_SELF, &b->B)); 982 PetscCall(MatSetSizes(b->B, B->rmap->n, B->cmap->N, B->rmap->n, B->cmap->N)); 983 PetscCall(MatSetBlockSizesFromMats(b->B, B, B)); 984 PetscCall(MatSetType(b->B, MATSEQSELL)); 985 } 986 987 PetscCall(MatSeqSELLSetPreallocation(b->A, d_rlenmax, d_rlen)); 988 PetscCall(MatSeqSELLSetPreallocation(b->B, o_rlenmax, o_rlen)); 989 B->preallocated = PETSC_TRUE; 990 B->was_assembled = PETSC_FALSE; 991 /* 992 critical for MatAssemblyEnd to work. 993 MatAssemblyBegin checks it to set up was_assembled 994 and MatAssemblyEnd checks was_assembled to determine whether to build garray 995 */ 996 B->assembled = PETSC_FALSE; 997 PetscFunctionReturn(PETSC_SUCCESS); 998 } 999 1000 static PetscErrorCode MatDuplicate_MPISELL(Mat matin, MatDuplicateOption cpvalues, Mat *newmat) 1001 { 1002 Mat mat; 1003 Mat_MPISELL *a, *oldmat = (Mat_MPISELL *)matin->data; 1004 1005 PetscFunctionBegin; 1006 *newmat = NULL; 1007 PetscCall(MatCreate(PetscObjectComm((PetscObject)matin), &mat)); 1008 PetscCall(MatSetSizes(mat, matin->rmap->n, matin->cmap->n, matin->rmap->N, matin->cmap->N)); 1009 PetscCall(MatSetBlockSizesFromMats(mat, matin, matin)); 1010 PetscCall(MatSetType(mat, ((PetscObject)matin)->type_name)); 1011 a = (Mat_MPISELL *)mat->data; 1012 1013 mat->factortype = matin->factortype; 1014 mat->assembled = PETSC_TRUE; 1015 mat->insertmode = NOT_SET_VALUES; 1016 mat->preallocated = PETSC_TRUE; 1017 1018 a->size = oldmat->size; 1019 a->rank = oldmat->rank; 1020 a->donotstash = oldmat->donotstash; 1021 a->roworiented = oldmat->roworiented; 1022 a->rowindices = NULL; 1023 a->rowvalues = NULL; 1024 a->getrowactive = PETSC_FALSE; 1025 1026 PetscCall(PetscLayoutReference(matin->rmap, &mat->rmap)); 1027 PetscCall(PetscLayoutReference(matin->cmap, &mat->cmap)); 1028 1029 if (oldmat->colmap) { 1030 #if defined(PETSC_USE_CTABLE) 1031 PetscCall(PetscHMapIDuplicate(oldmat->colmap, &a->colmap)); 1032 #else 1033 PetscCall(PetscMalloc1(mat->cmap->N, &a->colmap)); 1034 PetscCall(PetscArraycpy(a->colmap, oldmat->colmap, mat->cmap->N)); 1035 #endif 1036 } else a->colmap = NULL; 1037 if (oldmat->garray) { 1038 PetscInt len; 1039 len = oldmat->B->cmap->n; 1040 PetscCall(PetscMalloc1(len + 1, &a->garray)); 1041 if (len) PetscCall(PetscArraycpy(a->garray, oldmat->garray, len)); 1042 } else a->garray = NULL; 1043 1044 PetscCall(VecDuplicate(oldmat->lvec, &a->lvec)); 1045 PetscCall(VecScatterCopy(oldmat->Mvctx, &a->Mvctx)); 1046 PetscCall(MatDuplicate(oldmat->A, cpvalues, &a->A)); 1047 PetscCall(MatDuplicate(oldmat->B, cpvalues, &a->B)); 1048 PetscCall(PetscFunctionListDuplicate(((PetscObject)matin)->qlist, &((PetscObject)mat)->qlist)); 1049 *newmat = mat; 1050 PetscFunctionReturn(PETSC_SUCCESS); 1051 } 1052 1053 static const struct _MatOps MatOps_Values = {MatSetValues_MPISELL, 1054 NULL, 1055 NULL, 1056 MatMult_MPISELL, 1057 /* 4*/ MatMultAdd_MPISELL, 1058 MatMultTranspose_MPISELL, 1059 MatMultTransposeAdd_MPISELL, 1060 NULL, 1061 NULL, 1062 NULL, 1063 /*10*/ NULL, 1064 NULL, 1065 NULL, 1066 MatSOR_MPISELL, 1067 NULL, 1068 /*15*/ MatGetInfo_MPISELL, 1069 MatEqual_MPISELL, 1070 MatGetDiagonal_MPISELL, 1071 MatDiagonalScale_MPISELL, 1072 NULL, 1073 /*20*/ MatAssemblyBegin_MPISELL, 1074 MatAssemblyEnd_MPISELL, 1075 MatSetOption_MPISELL, 1076 MatZeroEntries_MPISELL, 1077 /*24*/ NULL, 1078 NULL, 1079 NULL, 1080 NULL, 1081 NULL, 1082 /*29*/ MatSetUp_MPISELL, 1083 NULL, 1084 NULL, 1085 MatGetDiagonalBlock_MPISELL, 1086 NULL, 1087 /*34*/ MatDuplicate_MPISELL, 1088 NULL, 1089 NULL, 1090 NULL, 1091 NULL, 1092 /*39*/ NULL, 1093 NULL, 1094 NULL, 1095 MatGetValues_MPISELL, 1096 MatCopy_MPISELL, 1097 /*44*/ NULL, 1098 MatScale_MPISELL, 1099 MatShift_MPISELL, 1100 MatDiagonalSet_MPISELL, 1101 NULL, 1102 /*49*/ MatSetRandom_MPISELL, 1103 NULL, 1104 NULL, 1105 NULL, 1106 NULL, 1107 /*54*/ MatFDColoringCreate_MPIXAIJ, 1108 NULL, 1109 MatSetUnfactored_MPISELL, 1110 NULL, 1111 NULL, 1112 /*59*/ NULL, 1113 MatDestroy_MPISELL, 1114 MatView_MPISELL, 1115 NULL, 1116 NULL, 1117 /*64*/ NULL, 1118 NULL, 1119 NULL, 1120 NULL, 1121 NULL, 1122 /*69*/ NULL, 1123 NULL, 1124 NULL, 1125 MatFDColoringApply_AIJ, /* reuse AIJ function */ 1126 MatSetFromOptions_MPISELL, 1127 NULL, 1128 /*75*/ NULL, 1129 NULL, 1130 NULL, 1131 NULL, 1132 NULL, 1133 /*80*/ NULL, 1134 NULL, 1135 NULL, 1136 /*83*/ NULL, 1137 NULL, 1138 NULL, 1139 NULL, 1140 NULL, 1141 NULL, 1142 /*89*/ NULL, 1143 NULL, 1144 NULL, 1145 NULL, 1146 MatConjugate_MPISELL, 1147 /*94*/ NULL, 1148 NULL, 1149 NULL, 1150 NULL, 1151 NULL, 1152 /*99*/ NULL, 1153 NULL, 1154 NULL, 1155 NULL, 1156 NULL, 1157 /*104*/ NULL, 1158 NULL, 1159 MatGetGhosts_MPISELL, 1160 NULL, 1161 NULL, 1162 /*109*/ MatMultDiagonalBlock_MPISELL, 1163 NULL, 1164 NULL, 1165 NULL, 1166 NULL, 1167 /*114*/ NULL, 1168 NULL, 1169 MatInvertBlockDiagonal_MPISELL, 1170 NULL, 1171 /*119*/ NULL, 1172 NULL, 1173 NULL, 1174 NULL, 1175 NULL, 1176 /*124*/ NULL, 1177 NULL, 1178 NULL, 1179 NULL, 1180 NULL, 1181 /*129*/ MatFDColoringSetUp_MPIXAIJ, 1182 NULL, 1183 NULL, 1184 NULL, 1185 NULL, 1186 /*134*/ NULL, 1187 NULL, 1188 NULL, 1189 NULL, 1190 NULL, 1191 /*139*/ NULL, 1192 NULL, 1193 NULL, 1194 NULL, 1195 NULL, 1196 NULL}; 1197 1198 /*@C 1199 MatMPISELLSetPreallocation - Preallocates memory for a `MATMPISELL` sparse parallel matrix in sell format. 1200 For good matrix assembly performance the user should preallocate the matrix storage by 1201 setting the parameters `d_nz` (or `d_nnz`) and `o_nz` (or `o_nnz`). 1202 1203 Collective 1204 1205 Input Parameters: 1206 + B - the matrix 1207 . d_nz - number of nonzeros per row in DIAGONAL portion of local submatrix 1208 (same value is used for all local rows) 1209 . d_nnz - array containing the number of nonzeros in the various rows of the 1210 DIAGONAL portion of the local submatrix (possibly different for each row) 1211 or NULL (`PETSC_NULL_INTEGER` in Fortran), if `d_nz` is used to specify the nonzero structure. 1212 The size of this array is equal to the number of local rows, i.e 'm'. 1213 For matrices that will be factored, you must leave room for (and set) 1214 the diagonal entry even if it is zero. 1215 . o_nz - number of nonzeros per row in the OFF-DIAGONAL portion of local 1216 submatrix (same value is used for all local rows). 1217 - o_nnz - array containing the number of nonzeros in the various rows of the 1218 OFF-DIAGONAL portion of the local submatrix (possibly different for 1219 each row) or NULL (`PETSC_NULL_INTEGER` in Fortran), if `o_nz` is used to specify the nonzero 1220 structure. The size of this array is equal to the number 1221 of local rows, i.e 'm'. 1222 1223 Example usage: 1224 Consider the following 8x8 matrix with 34 non-zero values, that is 1225 assembled across 3 processors. Lets assume that proc0 owns 3 rows, 1226 proc1 owns 3 rows, proc2 owns 2 rows. This division can be shown 1227 as follows 1228 1229 .vb 1230 1 2 0 | 0 3 0 | 0 4 1231 Proc0 0 5 6 | 7 0 0 | 8 0 1232 9 0 10 | 11 0 0 | 12 0 1233 ------------------------------------- 1234 13 0 14 | 15 16 17 | 0 0 1235 Proc1 0 18 0 | 19 20 21 | 0 0 1236 0 0 0 | 22 23 0 | 24 0 1237 ------------------------------------- 1238 Proc2 25 26 27 | 0 0 28 | 29 0 1239 30 0 0 | 31 32 33 | 0 34 1240 .ve 1241 1242 This can be represented as a collection of submatrices as 1243 1244 .vb 1245 A B C 1246 D E F 1247 G H I 1248 .ve 1249 1250 Where the submatrices A,B,C are owned by proc0, D,E,F are 1251 owned by proc1, G,H,I are owned by proc2. 1252 1253 The 'm' parameters for proc0,proc1,proc2 are 3,3,2 respectively. 1254 The 'n' parameters for proc0,proc1,proc2 are 3,3,2 respectively. 1255 The 'M','N' parameters are 8,8, and have the same values on all procs. 1256 1257 The DIAGONAL submatrices corresponding to proc0,proc1,proc2 are 1258 submatrices [A], [E], [I] respectively. The OFF-DIAGONAL submatrices 1259 corresponding to proc0,proc1,proc2 are [BC], [DF], [GH] respectively. 1260 Internally, each processor stores the DIAGONAL part, and the OFF-DIAGONAL 1261 part as `MATSEQSELL` matrices. For example, proc1 will store [E] as a `MATSEQSELL` 1262 matrix, and [DF] as another SeqSELL matrix. 1263 1264 When `d_nz`, `o_nz` parameters are specified, `d_nz` storage elements are 1265 allocated for every row of the local DIAGONAL submatrix, and o_nz 1266 storage locations are allocated for every row of the OFF-DIAGONAL submatrix. 1267 One way to choose `d_nz` and `o_nz` is to use the maximum number of nonzeros over 1268 the local rows for each of the local DIAGONAL, and the OFF-DIAGONAL submatrices. 1269 In this case, the values of d_nz,o_nz are 1270 .vb 1271 proc0 dnz = 2, o_nz = 2 1272 proc1 dnz = 3, o_nz = 2 1273 proc2 dnz = 1, o_nz = 4 1274 .ve 1275 We are allocating m*(d_nz+o_nz) storage locations for every proc. This 1276 translates to 3*(2+2)=12 for proc0, 3*(3+2)=15 for proc1, 2*(1+4)=10 1277 for proc3. i.e we are using 12+15+10=37 storage locations to store 1278 34 values. 1279 1280 When `d_nnz`, `o_nnz` parameters are specified, the storage is specified 1281 for every row, corresponding to both DIAGONAL and OFF-DIAGONAL submatrices. 1282 In the above case the values for d_nnz,o_nnz are 1283 .vb 1284 proc0 d_nnz = [2,2,2] and o_nnz = [2,2,2] 1285 proc1 d_nnz = [3,3,2] and o_nnz = [2,1,1] 1286 proc2 d_nnz = [1,1] and o_nnz = [4,4] 1287 .ve 1288 Here the space allocated is according to nz (or maximum values in the nnz 1289 if nnz is provided) for DIAGONAL and OFF-DIAGONAL submatrices, i.e (2+2+3+2)*3+(1+4)*2=37 1290 1291 Level: intermediate 1292 1293 Notes: 1294 If the *_nnz parameter is given then the *_nz parameter is ignored 1295 1296 The stored row and column indices begin with zero. 1297 1298 The parallel matrix is partitioned such that the first m0 rows belong to 1299 process 0, the next m1 rows belong to process 1, the next m2 rows belong 1300 to process 2 etc.. where m0,m1,m2... are the input parameter 'm'. 1301 1302 The DIAGONAL portion of the local submatrix of a processor can be defined 1303 as the submatrix which is obtained by extraction the part corresponding to 1304 the rows r1-r2 and columns c1-c2 of the global matrix, where r1 is the 1305 first row that belongs to the processor, r2 is the last row belonging to 1306 the this processor, and c1-c2 is range of indices of the local part of a 1307 vector suitable for applying the matrix to. This is an mxn matrix. In the 1308 common case of a square matrix, the row and column ranges are the same and 1309 the DIAGONAL part is also square. The remaining portion of the local 1310 submatrix (mxN) constitute the OFF-DIAGONAL portion. 1311 1312 If `o_nnz`, `d_nnz` are specified, then `o_nz`, and `d_nz` are ignored. 1313 1314 You can call `MatGetInfo()` to get information on how effective the preallocation was; 1315 for example the fields mallocs,nz_allocated,nz_used,nz_unneeded; 1316 You can also run with the option -info and look for messages with the string 1317 malloc in them to see if additional memory allocation was needed. 1318 1319 .seealso: `Mat`, `MatCreate()`, `MatCreateSeqSELL()`, `MatSetValues()`, `MatCreateSELL()`, 1320 `MATMPISELL`, `MatGetInfo()`, `PetscSplitOwnership()`, `MATSELL` 1321 @*/ 1322 PetscErrorCode MatMPISELLSetPreallocation(Mat B, PetscInt d_nz, const PetscInt d_nnz[], PetscInt o_nz, const PetscInt o_nnz[]) 1323 { 1324 PetscFunctionBegin; 1325 PetscValidHeaderSpecific(B, MAT_CLASSID, 1); 1326 PetscValidType(B, 1); 1327 PetscTryMethod(B, "MatMPISELLSetPreallocation_C", (Mat, PetscInt, const PetscInt[], PetscInt, const PetscInt[]), (B, d_nz, d_nnz, o_nz, o_nnz)); 1328 PetscFunctionReturn(PETSC_SUCCESS); 1329 } 1330 1331 /*MC 1332 MATMPISELL - MATMPISELL = "mpisell" - A matrix type to be used for MPI sparse matrices, 1333 based on the sliced Ellpack format 1334 1335 Options Database Key: 1336 . -mat_type sell - sets the matrix type to `MATSELL` during a call to `MatSetFromOptions()` 1337 1338 Level: beginner 1339 1340 .seealso: `Mat`, `MatCreateSELL()`, `MATSEQSELL`, `MATSELL`, `MATSEQAIJ`, `MATAIJ`, `MATMPIAIJ` 1341 M*/ 1342 1343 /*@C 1344 MatCreateSELL - Creates a sparse parallel matrix in `MATSELL` format. 1345 1346 Collective 1347 1348 Input Parameters: 1349 + comm - MPI communicator 1350 . m - number of local rows (or `PETSC_DECIDE` to have calculated if M is given) 1351 This value should be the same as the local size used in creating the 1352 y vector for the matrix-vector product y = Ax. 1353 . n - This value should be the same as the local size used in creating the 1354 x vector for the matrix-vector product y = Ax. (or `PETSC_DECIDE` to have 1355 calculated if `N` is given) For square matrices n is almost always `m`. 1356 . M - number of global rows (or `PETSC_DETERMINE` to have calculated if `m` is given) 1357 . N - number of global columns (or `PETSC_DETERMINE` to have calculated if `n` is given) 1358 . d_rlenmax - max number of nonzeros per row in DIAGONAL portion of local submatrix 1359 (same value is used for all local rows) 1360 . d_rlen - array containing the number of nonzeros in the various rows of the 1361 DIAGONAL portion of the local submatrix (possibly different for each row) 1362 or `NULL`, if d_rlenmax is used to specify the nonzero structure. 1363 The size of this array is equal to the number of local rows, i.e `m`. 1364 . o_rlenmax - max number of nonzeros per row in the OFF-DIAGONAL portion of local 1365 submatrix (same value is used for all local rows). 1366 - o_rlen - array containing the number of nonzeros in the various rows of the 1367 OFF-DIAGONAL portion of the local submatrix (possibly different for 1368 each row) or `NULL`, if `o_rlenmax` is used to specify the nonzero 1369 structure. The size of this array is equal to the number 1370 of local rows, i.e `m`. 1371 1372 Output Parameter: 1373 . A - the matrix 1374 1375 Options Database Key: 1376 . -mat_sell_oneindex - Internally use indexing starting at 1 1377 rather than 0. When calling `MatSetValues()`, 1378 the user still MUST index entries starting at 0! 1379 1380 Example: 1381 Consider the following 8x8 matrix with 34 non-zero values, that is 1382 assembled across 3 processors. Lets assume that proc0 owns 3 rows, 1383 proc1 owns 3 rows, proc2 owns 2 rows. This division can be shown 1384 as follows 1385 1386 .vb 1387 1 2 0 | 0 3 0 | 0 4 1388 Proc0 0 5 6 | 7 0 0 | 8 0 1389 9 0 10 | 11 0 0 | 12 0 1390 ------------------------------------- 1391 13 0 14 | 15 16 17 | 0 0 1392 Proc1 0 18 0 | 19 20 21 | 0 0 1393 0 0 0 | 22 23 0 | 24 0 1394 ------------------------------------- 1395 Proc2 25 26 27 | 0 0 28 | 29 0 1396 30 0 0 | 31 32 33 | 0 34 1397 .ve 1398 1399 This can be represented as a collection of submatrices as 1400 .vb 1401 A B C 1402 D E F 1403 G H I 1404 .ve 1405 1406 Where the submatrices A,B,C are owned by proc0, D,E,F are 1407 owned by proc1, G,H,I are owned by proc2. 1408 1409 The 'm' parameters for proc0,proc1,proc2 are 3,3,2 respectively. 1410 The 'n' parameters for proc0,proc1,proc2 are 3,3,2 respectively. 1411 The 'M','N' parameters are 8,8, and have the same values on all procs. 1412 1413 The DIAGONAL submatrices corresponding to proc0,proc1,proc2 are 1414 submatrices [A], [E], [I] respectively. The OFF-DIAGONAL submatrices 1415 corresponding to proc0,proc1,proc2 are [BC], [DF], [GH] respectively. 1416 Internally, each processor stores the DIAGONAL part, and the OFF-DIAGONAL 1417 part as `MATSEQSELL` matrices. For example, proc1 will store [E] as a `MATSEQSELL` 1418 matrix, and [DF] as another `MATSEQSELL` matrix. 1419 1420 When d_rlenmax, o_rlenmax parameters are specified, d_rlenmax storage elements are 1421 allocated for every row of the local DIAGONAL submatrix, and o_rlenmax 1422 storage locations are allocated for every row of the OFF-DIAGONAL submatrix. 1423 One way to choose `d_rlenmax` and `o_rlenmax` is to use the maximum number of nonzeros over 1424 the local rows for each of the local DIAGONAL, and the OFF-DIAGONAL submatrices. 1425 In this case, the values of d_rlenmax,o_rlenmax are 1426 .vb 1427 proc0 - d_rlenmax = 2, o_rlenmax = 2 1428 proc1 - d_rlenmax = 3, o_rlenmax = 2 1429 proc2 - d_rlenmax = 1, o_rlenmax = 4 1430 .ve 1431 We are allocating m*(d_rlenmax+o_rlenmax) storage locations for every proc. This 1432 translates to 3*(2+2)=12 for proc0, 3*(3+2)=15 for proc1, 2*(1+4)=10 1433 for proc3. i.e we are using 12+15+10=37 storage locations to store 1434 34 values. 1435 1436 When `d_rlen`, `o_rlen` parameters are specified, the storage is specified 1437 for every row, corresponding to both DIAGONAL and OFF-DIAGONAL submatrices. 1438 In the above case the values for `d_nnz`, `o_nnz` are 1439 .vb 1440 proc0 - d_nnz = [2,2,2] and o_nnz = [2,2,2] 1441 proc1 - d_nnz = [3,3,2] and o_nnz = [2,1,1] 1442 proc2 - d_nnz = [1,1] and o_nnz = [4,4] 1443 .ve 1444 Here the space allocated is still 37 though there are 34 nonzeros because 1445 the allocation is always done according to rlenmax. 1446 1447 Level: intermediate 1448 1449 Notes: 1450 It is recommended that one use the `MatCreate()`, `MatSetType()` and/or `MatSetFromOptions()`, 1451 MatXXXXSetPreallocation() paradigm instead of this routine directly. 1452 [MatXXXXSetPreallocation() is, for example, `MatSeqSELLSetPreallocation()`] 1453 1454 If the *_rlen parameter is given then the *_rlenmax parameter is ignored 1455 1456 `m`, `n`, `M`, `N` parameters specify the size of the matrix, and its partitioning across 1457 processors, while `d_rlenmax`, `d_rlen`, `o_rlenmax` , `o_rlen` parameters specify the approximate 1458 storage requirements for this matrix. 1459 1460 If `PETSC_DECIDE` or `PETSC_DETERMINE` is used for a particular argument on one 1461 processor than it must be used on all processors that share the object for 1462 that argument. 1463 1464 The user MUST specify either the local or global matrix dimensions 1465 (possibly both). 1466 1467 The parallel matrix is partitioned across processors such that the 1468 first m0 rows belong to process 0, the next m1 rows belong to 1469 process 1, the next m2 rows belong to process 2 etc.. where 1470 m0,m1,m2,.. are the input parameter 'm'. i.e each processor stores 1471 values corresponding to [`m` x `N`] submatrix. 1472 1473 The columns are logically partitioned with the n0 columns belonging 1474 to 0th partition, the next n1 columns belonging to the next 1475 partition etc.. where n0,n1,n2... are the input parameter `n`. 1476 1477 The DIAGONAL portion of the local submatrix on any given processor 1478 is the submatrix corresponding to the rows and columns `m`, `n` 1479 corresponding to the given processor. i.e diagonal matrix on 1480 process 0 is [m0 x n0], diagonal matrix on process 1 is [m1 x n1] 1481 etc. The remaining portion of the local submatrix [m x (N-n)] 1482 constitute the OFF-DIAGONAL portion. The example below better 1483 illustrates this concept. 1484 1485 For a square global matrix we define each processor's diagonal portion 1486 to be its local rows and the corresponding columns (a square submatrix); 1487 each processor's off-diagonal portion encompasses the remainder of the 1488 local matrix (a rectangular submatrix). 1489 1490 If `o_rlen`, `d_rlen` are specified, then `o_rlenmax`, and `d_rlenmax` are ignored. 1491 1492 When calling this routine with a single process communicator, a matrix of 1493 type `MATSEQSELL` is returned. If a matrix of type `MATMPISELL` is desired for this 1494 type of communicator, use the construction mechanism 1495 .vb 1496 MatCreate(...,&A); 1497 MatSetType(A,MATMPISELL); 1498 MatSetSizes(A, m,n,M,N); 1499 MatMPISELLSetPreallocation(A,...); 1500 .ve 1501 1502 .seealso: `Mat`, `MATSELL`, `MatCreate()`, `MatCreateSeqSELL()`, `MatSetValues()`, `MatMPISELLSetPreallocation()`, `MATMPISELL` 1503 @*/ 1504 PetscErrorCode MatCreateSELL(MPI_Comm comm, PetscInt m, PetscInt n, PetscInt M, PetscInt N, PetscInt d_rlenmax, const PetscInt d_rlen[], PetscInt o_rlenmax, const PetscInt o_rlen[], Mat *A) 1505 { 1506 PetscMPIInt size; 1507 1508 PetscFunctionBegin; 1509 PetscCall(MatCreate(comm, A)); 1510 PetscCall(MatSetSizes(*A, m, n, M, N)); 1511 PetscCallMPI(MPI_Comm_size(comm, &size)); 1512 if (size > 1) { 1513 PetscCall(MatSetType(*A, MATMPISELL)); 1514 PetscCall(MatMPISELLSetPreallocation(*A, d_rlenmax, d_rlen, o_rlenmax, o_rlen)); 1515 } else { 1516 PetscCall(MatSetType(*A, MATSEQSELL)); 1517 PetscCall(MatSeqSELLSetPreallocation(*A, d_rlenmax, d_rlen)); 1518 } 1519 PetscFunctionReturn(PETSC_SUCCESS); 1520 } 1521 1522 /*@C 1523 MatMPISELLGetSeqSELL - Returns the local pieces of this distributed matrix 1524 1525 Not Collective 1526 1527 Input Parameter: 1528 . A - the `MATMPISELL` matrix 1529 1530 Output Parameters: 1531 + Ad - The diagonal portion of `A` 1532 . Ao - The off-diagonal portion of `A` 1533 - colmap - An array mapping local column numbers of `Ao` to global column numbers of the parallel matrix 1534 1535 Level: advanced 1536 1537 .seealso: `Mat`, `MATSEQSELL`, `MATMPISELL` 1538 @*/ 1539 PetscErrorCode MatMPISELLGetSeqSELL(Mat A, Mat *Ad, Mat *Ao, const PetscInt *colmap[]) 1540 { 1541 Mat_MPISELL *a = (Mat_MPISELL *)A->data; 1542 PetscBool flg; 1543 1544 PetscFunctionBegin; 1545 PetscCall(PetscObjectTypeCompare((PetscObject)A, MATMPISELL, &flg)); 1546 PetscCheck(flg, PetscObjectComm((PetscObject)A), PETSC_ERR_SUP, "This function requires a MATMPISELL matrix as input"); 1547 if (Ad) *Ad = a->A; 1548 if (Ao) *Ao = a->B; 1549 if (colmap) *colmap = a->garray; 1550 PetscFunctionReturn(PETSC_SUCCESS); 1551 } 1552 1553 /*@C 1554 MatMPISELLGetLocalMatCondensed - Creates a `MATSEQSELL` matrix from an `MATMPISELL` matrix by 1555 taking all its local rows and NON-ZERO columns 1556 1557 Not Collective 1558 1559 Input Parameters: 1560 + A - the matrix 1561 . scall - either `MAT_INITIAL_MATRIX` or `MAT_REUSE_MATRIX` 1562 . row - index sets of rows to extract (or `NULL`) 1563 - col - index sets of columns to extract (or `NULL`) 1564 1565 Output Parameter: 1566 . A_loc - the local sequential matrix generated 1567 1568 Level: advanced 1569 1570 .seealso: `Mat`, `MATSEQSELL`, `MATMPISELL`, `MatGetOwnershipRange()`, `MatMPISELLGetLocalMat()` 1571 @*/ 1572 PetscErrorCode MatMPISELLGetLocalMatCondensed(Mat A, MatReuse scall, IS *row, IS *col, Mat *A_loc) 1573 { 1574 Mat_MPISELL *a = (Mat_MPISELL *)A->data; 1575 PetscInt i, start, end, ncols, nzA, nzB, *cmap, imark, *idx; 1576 IS isrowa, iscola; 1577 Mat *aloc; 1578 PetscBool match; 1579 1580 PetscFunctionBegin; 1581 PetscCall(PetscObjectTypeCompare((PetscObject)A, MATMPISELL, &match)); 1582 PetscCheck(match, PetscObjectComm((PetscObject)A), PETSC_ERR_SUP, "Requires MATMPISELL matrix as input"); 1583 PetscCall(PetscLogEventBegin(MAT_Getlocalmatcondensed, A, 0, 0, 0)); 1584 if (!row) { 1585 start = A->rmap->rstart; 1586 end = A->rmap->rend; 1587 PetscCall(ISCreateStride(PETSC_COMM_SELF, end - start, start, 1, &isrowa)); 1588 } else { 1589 isrowa = *row; 1590 } 1591 if (!col) { 1592 start = A->cmap->rstart; 1593 cmap = a->garray; 1594 nzA = a->A->cmap->n; 1595 nzB = a->B->cmap->n; 1596 PetscCall(PetscMalloc1(nzA + nzB, &idx)); 1597 ncols = 0; 1598 for (i = 0; i < nzB; i++) { 1599 if (cmap[i] < start) idx[ncols++] = cmap[i]; 1600 else break; 1601 } 1602 imark = i; 1603 for (i = 0; i < nzA; i++) idx[ncols++] = start + i; 1604 for (i = imark; i < nzB; i++) idx[ncols++] = cmap[i]; 1605 PetscCall(ISCreateGeneral(PETSC_COMM_SELF, ncols, idx, PETSC_OWN_POINTER, &iscola)); 1606 } else { 1607 iscola = *col; 1608 } 1609 if (scall != MAT_INITIAL_MATRIX) { 1610 PetscCall(PetscMalloc1(1, &aloc)); 1611 aloc[0] = *A_loc; 1612 } 1613 PetscCall(MatCreateSubMatrices(A, 1, &isrowa, &iscola, scall, &aloc)); 1614 *A_loc = aloc[0]; 1615 PetscCall(PetscFree(aloc)); 1616 if (!row) PetscCall(ISDestroy(&isrowa)); 1617 if (!col) PetscCall(ISDestroy(&iscola)); 1618 PetscCall(PetscLogEventEnd(MAT_Getlocalmatcondensed, A, 0, 0, 0)); 1619 PetscFunctionReturn(PETSC_SUCCESS); 1620 } 1621 1622 #include <../src/mat/impls/aij/mpi/mpiaij.h> 1623 1624 PetscErrorCode MatConvert_MPISELL_MPIAIJ(Mat A, MatType newtype, MatReuse reuse, Mat *newmat) 1625 { 1626 Mat_MPISELL *a = (Mat_MPISELL *)A->data; 1627 Mat B; 1628 Mat_MPIAIJ *b; 1629 1630 PetscFunctionBegin; 1631 PetscCheck(A->assembled, PetscObjectComm((PetscObject)A), PETSC_ERR_SUP, "Matrix must be assembled"); 1632 1633 if (reuse == MAT_REUSE_MATRIX) { 1634 B = *newmat; 1635 } else { 1636 PetscCall(MatCreate(PetscObjectComm((PetscObject)A), &B)); 1637 PetscCall(MatSetType(B, MATMPIAIJ)); 1638 PetscCall(MatSetSizes(B, A->rmap->n, A->cmap->n, A->rmap->N, A->cmap->N)); 1639 PetscCall(MatSetBlockSizes(B, A->rmap->bs, A->cmap->bs)); 1640 PetscCall(MatSeqAIJSetPreallocation(B, 0, NULL)); 1641 PetscCall(MatMPIAIJSetPreallocation(B, 0, NULL, 0, NULL)); 1642 } 1643 b = (Mat_MPIAIJ *)B->data; 1644 1645 if (reuse == MAT_REUSE_MATRIX) { 1646 PetscCall(MatConvert_SeqSELL_SeqAIJ(a->A, MATSEQAIJ, MAT_REUSE_MATRIX, &b->A)); 1647 PetscCall(MatConvert_SeqSELL_SeqAIJ(a->B, MATSEQAIJ, MAT_REUSE_MATRIX, &b->B)); 1648 } else { 1649 PetscCall(MatDestroy(&b->A)); 1650 PetscCall(MatDestroy(&b->B)); 1651 PetscCall(MatDisAssemble_MPISELL(A)); 1652 PetscCall(MatConvert_SeqSELL_SeqAIJ(a->A, MATSEQAIJ, MAT_INITIAL_MATRIX, &b->A)); 1653 PetscCall(MatConvert_SeqSELL_SeqAIJ(a->B, MATSEQAIJ, MAT_INITIAL_MATRIX, &b->B)); 1654 PetscCall(MatAssemblyBegin(B, MAT_FINAL_ASSEMBLY)); 1655 PetscCall(MatAssemblyEnd(B, MAT_FINAL_ASSEMBLY)); 1656 PetscCall(MatAssemblyBegin(A, MAT_FINAL_ASSEMBLY)); 1657 PetscCall(MatAssemblyEnd(A, MAT_FINAL_ASSEMBLY)); 1658 } 1659 1660 if (reuse == MAT_INPLACE_MATRIX) { 1661 PetscCall(MatHeaderReplace(A, &B)); 1662 } else { 1663 *newmat = B; 1664 } 1665 PetscFunctionReturn(PETSC_SUCCESS); 1666 } 1667 1668 PetscErrorCode MatConvert_MPIAIJ_MPISELL(Mat A, MatType newtype, MatReuse reuse, Mat *newmat) 1669 { 1670 Mat_MPIAIJ *a = (Mat_MPIAIJ *)A->data; 1671 Mat B; 1672 Mat_MPISELL *b; 1673 1674 PetscFunctionBegin; 1675 PetscCheck(A->assembled, PetscObjectComm((PetscObject)A), PETSC_ERR_SUP, "Matrix must be assembled"); 1676 1677 if (reuse == MAT_REUSE_MATRIX) { 1678 B = *newmat; 1679 } else { 1680 Mat_SeqAIJ *Aa = (Mat_SeqAIJ *)a->A->data, *Ba = (Mat_SeqAIJ *)a->B->data; 1681 PetscInt i, d_nz = 0, o_nz = 0, m = A->rmap->N, n = A->cmap->N, lm = A->rmap->n, ln = A->cmap->n; 1682 PetscInt *d_nnz, *o_nnz; 1683 PetscCall(PetscMalloc2(lm, &d_nnz, lm, &o_nnz)); 1684 for (i = 0; i < lm; i++) { 1685 d_nnz[i] = Aa->i[i + 1] - Aa->i[i]; 1686 o_nnz[i] = Ba->i[i + 1] - Ba->i[i]; 1687 if (d_nnz[i] > d_nz) d_nz = d_nnz[i]; 1688 if (o_nnz[i] > o_nz) o_nz = o_nnz[i]; 1689 } 1690 PetscCall(MatCreate(PetscObjectComm((PetscObject)A), &B)); 1691 PetscCall(MatSetType(B, MATMPISELL)); 1692 PetscCall(MatSetSizes(B, lm, ln, m, n)); 1693 PetscCall(MatSetBlockSizes(B, A->rmap->bs, A->cmap->bs)); 1694 PetscCall(MatSeqSELLSetPreallocation(B, d_nz, d_nnz)); 1695 PetscCall(MatMPISELLSetPreallocation(B, d_nz, d_nnz, o_nz, o_nnz)); 1696 PetscCall(PetscFree2(d_nnz, o_nnz)); 1697 } 1698 b = (Mat_MPISELL *)B->data; 1699 1700 if (reuse == MAT_REUSE_MATRIX) { 1701 PetscCall(MatConvert_SeqAIJ_SeqSELL(a->A, MATSEQSELL, MAT_REUSE_MATRIX, &b->A)); 1702 PetscCall(MatConvert_SeqAIJ_SeqSELL(a->B, MATSEQSELL, MAT_REUSE_MATRIX, &b->B)); 1703 } else { 1704 PetscCall(MatDestroy(&b->A)); 1705 PetscCall(MatDestroy(&b->B)); 1706 PetscCall(MatConvert_SeqAIJ_SeqSELL(a->A, MATSEQSELL, MAT_INITIAL_MATRIX, &b->A)); 1707 PetscCall(MatConvert_SeqAIJ_SeqSELL(a->B, MATSEQSELL, MAT_INITIAL_MATRIX, &b->B)); 1708 PetscCall(MatAssemblyBegin(A, MAT_FINAL_ASSEMBLY)); 1709 PetscCall(MatAssemblyEnd(A, MAT_FINAL_ASSEMBLY)); 1710 PetscCall(MatAssemblyBegin(B, MAT_FINAL_ASSEMBLY)); 1711 PetscCall(MatAssemblyEnd(B, MAT_FINAL_ASSEMBLY)); 1712 } 1713 1714 if (reuse == MAT_INPLACE_MATRIX) { 1715 PetscCall(MatHeaderReplace(A, &B)); 1716 } else { 1717 *newmat = B; 1718 } 1719 PetscFunctionReturn(PETSC_SUCCESS); 1720 } 1721 1722 PetscErrorCode MatSOR_MPISELL(Mat matin, Vec bb, PetscReal omega, MatSORType flag, PetscReal fshift, PetscInt its, PetscInt lits, Vec xx) 1723 { 1724 Mat_MPISELL *mat = (Mat_MPISELL *)matin->data; 1725 Vec bb1 = NULL; 1726 1727 PetscFunctionBegin; 1728 if (flag == SOR_APPLY_UPPER) { 1729 PetscCall((*mat->A->ops->sor)(mat->A, bb, omega, flag, fshift, lits, 1, xx)); 1730 PetscFunctionReturn(PETSC_SUCCESS); 1731 } 1732 1733 if (its > 1 || ~flag & SOR_ZERO_INITIAL_GUESS || flag & SOR_EISENSTAT) PetscCall(VecDuplicate(bb, &bb1)); 1734 1735 if ((flag & SOR_LOCAL_SYMMETRIC_SWEEP) == SOR_LOCAL_SYMMETRIC_SWEEP) { 1736 if (flag & SOR_ZERO_INITIAL_GUESS) { 1737 PetscCall((*mat->A->ops->sor)(mat->A, bb, omega, flag, fshift, lits, 1, xx)); 1738 its--; 1739 } 1740 1741 while (its--) { 1742 PetscCall(VecScatterBegin(mat->Mvctx, xx, mat->lvec, INSERT_VALUES, SCATTER_FORWARD)); 1743 PetscCall(VecScatterEnd(mat->Mvctx, xx, mat->lvec, INSERT_VALUES, SCATTER_FORWARD)); 1744 1745 /* update rhs: bb1 = bb - B*x */ 1746 PetscCall(VecScale(mat->lvec, -1.0)); 1747 PetscCall((*mat->B->ops->multadd)(mat->B, mat->lvec, bb, bb1)); 1748 1749 /* local sweep */ 1750 PetscCall((*mat->A->ops->sor)(mat->A, bb1, omega, SOR_SYMMETRIC_SWEEP, fshift, lits, 1, xx)); 1751 } 1752 } else if (flag & SOR_LOCAL_FORWARD_SWEEP) { 1753 if (flag & SOR_ZERO_INITIAL_GUESS) { 1754 PetscCall((*mat->A->ops->sor)(mat->A, bb, omega, flag, fshift, lits, 1, xx)); 1755 its--; 1756 } 1757 while (its--) { 1758 PetscCall(VecScatterBegin(mat->Mvctx, xx, mat->lvec, INSERT_VALUES, SCATTER_FORWARD)); 1759 PetscCall(VecScatterEnd(mat->Mvctx, xx, mat->lvec, INSERT_VALUES, SCATTER_FORWARD)); 1760 1761 /* update rhs: bb1 = bb - B*x */ 1762 PetscCall(VecScale(mat->lvec, -1.0)); 1763 PetscCall((*mat->B->ops->multadd)(mat->B, mat->lvec, bb, bb1)); 1764 1765 /* local sweep */ 1766 PetscCall((*mat->A->ops->sor)(mat->A, bb1, omega, SOR_FORWARD_SWEEP, fshift, lits, 1, xx)); 1767 } 1768 } else if (flag & SOR_LOCAL_BACKWARD_SWEEP) { 1769 if (flag & SOR_ZERO_INITIAL_GUESS) { 1770 PetscCall((*mat->A->ops->sor)(mat->A, bb, omega, flag, fshift, lits, 1, xx)); 1771 its--; 1772 } 1773 while (its--) { 1774 PetscCall(VecScatterBegin(mat->Mvctx, xx, mat->lvec, INSERT_VALUES, SCATTER_FORWARD)); 1775 PetscCall(VecScatterEnd(mat->Mvctx, xx, mat->lvec, INSERT_VALUES, SCATTER_FORWARD)); 1776 1777 /* update rhs: bb1 = bb - B*x */ 1778 PetscCall(VecScale(mat->lvec, -1.0)); 1779 PetscCall((*mat->B->ops->multadd)(mat->B, mat->lvec, bb, bb1)); 1780 1781 /* local sweep */ 1782 PetscCall((*mat->A->ops->sor)(mat->A, bb1, omega, SOR_BACKWARD_SWEEP, fshift, lits, 1, xx)); 1783 } 1784 } else SETERRQ(PetscObjectComm((PetscObject)matin), PETSC_ERR_SUP, "Parallel SOR not supported"); 1785 1786 PetscCall(VecDestroy(&bb1)); 1787 1788 matin->factorerrortype = mat->A->factorerrortype; 1789 PetscFunctionReturn(PETSC_SUCCESS); 1790 } 1791 1792 #if defined(PETSC_HAVE_CUDA) 1793 PETSC_INTERN PetscErrorCode MatConvert_MPISELL_MPISELLCUDA(Mat, MatType, MatReuse, Mat *); 1794 #endif 1795 1796 /*MC 1797 MATMPISELL - MATMPISELL = "MPISELL" - A matrix type to be used for parallel sparse matrices. 1798 1799 Options Database Keys: 1800 . -mat_type mpisell - sets the matrix type to `MATMPISELL` during a call to `MatSetFromOptions()` 1801 1802 Level: beginner 1803 1804 .seealso: `Mat`, `MATSELL`, `MATSEQSELL` `MatCreateSELL()` 1805 M*/ 1806 PETSC_EXTERN PetscErrorCode MatCreate_MPISELL(Mat B) 1807 { 1808 Mat_MPISELL *b; 1809 PetscMPIInt size; 1810 1811 PetscFunctionBegin; 1812 PetscCallMPI(MPI_Comm_size(PetscObjectComm((PetscObject)B), &size)); 1813 PetscCall(PetscNew(&b)); 1814 B->data = (void *)b; 1815 B->ops[0] = MatOps_Values; 1816 B->assembled = PETSC_FALSE; 1817 B->insertmode = NOT_SET_VALUES; 1818 b->size = size; 1819 PetscCallMPI(MPI_Comm_rank(PetscObjectComm((PetscObject)B), &b->rank)); 1820 /* build cache for off array entries formed */ 1821 PetscCall(MatStashCreate_Private(PetscObjectComm((PetscObject)B), 1, &B->stash)); 1822 1823 b->donotstash = PETSC_FALSE; 1824 b->colmap = NULL; 1825 b->garray = NULL; 1826 b->roworiented = PETSC_TRUE; 1827 1828 /* stuff used for matrix vector multiply */ 1829 b->lvec = NULL; 1830 b->Mvctx = NULL; 1831 1832 /* stuff for MatGetRow() */ 1833 b->rowindices = NULL; 1834 b->rowvalues = NULL; 1835 b->getrowactive = PETSC_FALSE; 1836 1837 PetscCall(PetscObjectComposeFunction((PetscObject)B, "MatStoreValues_C", MatStoreValues_MPISELL)); 1838 PetscCall(PetscObjectComposeFunction((PetscObject)B, "MatRetrieveValues_C", MatRetrieveValues_MPISELL)); 1839 PetscCall(PetscObjectComposeFunction((PetscObject)B, "MatIsTranspose_C", MatIsTranspose_MPISELL)); 1840 PetscCall(PetscObjectComposeFunction((PetscObject)B, "MatMPISELLSetPreallocation_C", MatMPISELLSetPreallocation_MPISELL)); 1841 PetscCall(PetscObjectComposeFunction((PetscObject)B, "MatConvert_mpisell_mpiaij_C", MatConvert_MPISELL_MPIAIJ)); 1842 #if defined(PETSC_HAVE_CUDA) 1843 PetscCall(PetscObjectComposeFunction((PetscObject)B, "MatConvert_mpisell_mpisellcuda_C", MatConvert_MPISELL_MPISELLCUDA)); 1844 #endif 1845 PetscCall(PetscObjectComposeFunction((PetscObject)B, "MatDiagonalScaleLocal_C", MatDiagonalScaleLocal_MPISELL)); 1846 PetscCall(PetscObjectChangeTypeName((PetscObject)B, MATMPISELL)); 1847 PetscFunctionReturn(PETSC_SUCCESS); 1848 } 1849