hypre_BoxArray * hypre_BoxArrayCreate( int size ) { hypre_BoxArray *box_array; box_array = hypre_TAlloc(hypre_BoxArray, 1); hypre_BoxArrayBoxes(box_array) = hypre_CTAlloc(hypre_Box, size); hypre_BoxArraySize(box_array) = size; hypre_BoxArrayAllocSize(box_array) = size; return box_array; }
hypre_BoxArray * hypre_BoxArrayDuplicate( hypre_BoxArray *box_array ) { hypre_BoxArray *new_box_array; int i; new_box_array = hypre_BoxArrayCreate(hypre_BoxArraySize(box_array)); hypre_ForBoxI(i, box_array) { hypre_CopyBox(hypre_BoxArrayBox(box_array, i), hypre_BoxArrayBox(new_box_array, i)); }
int hypre_StructVectorInitializeShell( hypre_StructVector *vector ) { int ierr = 0; hypre_StructGrid *grid; int *num_ghost; hypre_BoxArray *data_space; hypre_BoxArray *boxes; hypre_Box *box; hypre_Box *data_box; int *data_indices; int data_size; int i, d; /*----------------------------------------------------------------------- * Set up data_space *-----------------------------------------------------------------------*/ grid = hypre_StructVectorGrid(vector); if (hypre_StructVectorDataSpace(vector) == NULL) { num_ghost = hypre_StructVectorNumGhost(vector); boxes = hypre_StructGridBoxes(grid); data_space = hypre_BoxArrayCreate(hypre_BoxArraySize(boxes)); hypre_ForBoxI(i, boxes) { box = hypre_BoxArrayBox(boxes, i); data_box = hypre_BoxArrayBox(data_space, i); hypre_CopyBox(box, data_box); for (d = 0; d < 3; d++) { hypre_BoxIMinD(data_box, d) -= num_ghost[2*d]; hypre_BoxIMaxD(data_box, d) += num_ghost[2*d + 1]; } }
hypre_BoxArrayArray * hypre_GrowBoxArrayByStencil( hypre_BoxArray *box_array, hypre_StructStencil *stencil, int transpose ) { hypre_BoxArrayArray *grow_box_array_array; int i; grow_box_array_array = hypre_BoxArrayArrayCreate(hypre_BoxArraySize(box_array)); hypre_ForBoxI(i, box_array) { hypre_BoxArrayDestroy( hypre_BoxArrayArrayBoxArray(grow_box_array_array, i)); hypre_BoxArrayArrayBoxArray(grow_box_array_array, i) = hypre_GrowBoxByStencil(hypre_BoxArrayBox(box_array, i), stencil, transpose); }
int hypre_SStructGraphFindSGridEndpts(hypre_SStructGraph *graph, int part, int var, int proc, int endpt, int *endpts) { hypre_SStructGrid *grid = hypre_SStructGraphGrid(graph); hypre_StructGrid *sgrid; hypre_BoxArray *boxes; int i; sgrid= hypre_SStructPGridSGrid(hypre_SStructGridPGrid(grid, part), var); boxes= hypre_StructGridBoxes(sgrid); /* get the endpts using hypre_SStructGraphFindBoxEndpt */ for (i= 0; i< hypre_BoxArraySize(boxes); i++) { endpts[i]= hypre_SStructGraphFindBoxEndpt(graph, part, var, proc, endpt, i); } return 0; }
int hypre_BoxArraySetSize( hypre_BoxArray *box_array, int size ) { int ierr = 0; int alloc_size; alloc_size = hypre_BoxArrayAllocSize(box_array); if (size > alloc_size) { alloc_size = size + hypre_BoxArrayExcess; hypre_BoxArrayBoxes(box_array) = hypre_TReAlloc(hypre_BoxArrayBoxes(box_array), hypre_Box, alloc_size); hypre_BoxArrayAllocSize(box_array) = alloc_size; } hypre_BoxArraySize(box_array) = size; return ierr; }
int hypre_PointRelaxSetup( void *relax_vdata, hypre_StructMatrix *A, hypre_StructVector *b, hypre_StructVector *x ) { hypre_PointRelaxData *relax_data = (hypre_PointRelaxData *)relax_vdata; int num_pointsets = (relax_data -> num_pointsets); int *pointset_sizes = (relax_data -> pointset_sizes); hypre_Index *pointset_strides = (relax_data -> pointset_strides); hypre_Index **pointset_indices = (relax_data -> pointset_indices); hypre_StructVector *t; int diag_rank; hypre_ComputePkg **compute_pkgs; hypre_Index unit_stride; hypre_Index diag_index; hypre_IndexRef stride; hypre_IndexRef index; hypre_StructGrid *grid; hypre_StructStencil *stencil; hypre_BoxArrayArray *send_boxes; hypre_BoxArrayArray *recv_boxes; int **send_processes; int **recv_processes; hypre_BoxArrayArray *indt_boxes; hypre_BoxArrayArray *dept_boxes; hypre_BoxArrayArray *orig_indt_boxes; hypre_BoxArrayArray *orig_dept_boxes; hypre_BoxArrayArray *box_aa; hypre_BoxArray *box_a; hypre_Box *box; int box_aa_size; int box_a_size; hypre_BoxArrayArray *new_box_aa; hypre_BoxArray *new_box_a; hypre_Box *new_box; double scale; int frac; int i, j, k, p, m, compute_i; int ierr = 0; /*---------------------------------------------------------- * Set up the temp vector *----------------------------------------------------------*/ if ((relax_data -> t) == NULL) { t = hypre_StructVectorCreate(hypre_StructVectorComm(b), hypre_StructVectorGrid(b)); hypre_StructVectorSetNumGhost(t, hypre_StructVectorNumGhost(b)); hypre_StructVectorInitialize(t); hypre_StructVectorAssemble(t); (relax_data -> t) = t; } /*---------------------------------------------------------- * Find the matrix diagonal *----------------------------------------------------------*/ grid = hypre_StructMatrixGrid(A); stencil = hypre_StructMatrixStencil(A); hypre_SetIndex(diag_index, 0, 0, 0); diag_rank = hypre_StructStencilElementRank(stencil, diag_index); /*---------------------------------------------------------- * Set up the compute packages *----------------------------------------------------------*/ hypre_SetIndex(unit_stride, 1, 1, 1); compute_pkgs = hypre_CTAlloc(hypre_ComputePkg *, num_pointsets); for (p = 0; p < num_pointsets; p++) { hypre_CreateComputeInfo(grid, stencil, &send_boxes, &recv_boxes, &send_processes, &recv_processes, &orig_indt_boxes, &orig_dept_boxes); stride = pointset_strides[p]; for (compute_i = 0; compute_i < 2; compute_i++) { switch(compute_i) { case 0: box_aa = orig_indt_boxes; break; case 1: box_aa = orig_dept_boxes; break; } box_aa_size = hypre_BoxArrayArraySize(box_aa); new_box_aa = hypre_BoxArrayArrayCreate(box_aa_size); for (i = 0; i < box_aa_size; i++) { box_a = hypre_BoxArrayArrayBoxArray(box_aa, i); box_a_size = hypre_BoxArraySize(box_a); new_box_a = hypre_BoxArrayArrayBoxArray(new_box_aa, i); hypre_BoxArraySetSize(new_box_a, box_a_size * pointset_sizes[p]); k = 0; for (m = 0; m < pointset_sizes[p]; m++) { index = pointset_indices[p][m]; for (j = 0; j < box_a_size; j++) { box = hypre_BoxArrayBox(box_a, j); new_box = hypre_BoxArrayBox(new_box_a, k); hypre_CopyBox(box, new_box); hypre_ProjectBox(new_box, index, stride); k++; } } } switch(compute_i) { case 0: indt_boxes = new_box_aa; break; case 1: dept_boxes = new_box_aa; break; } } hypre_ComputePkgCreate(send_boxes, recv_boxes, unit_stride, unit_stride, send_processes, recv_processes, indt_boxes, dept_boxes, stride, grid, hypre_StructVectorDataSpace(x), 1, &compute_pkgs[p]); hypre_BoxArrayArrayDestroy(orig_indt_boxes); hypre_BoxArrayArrayDestroy(orig_dept_boxes); } /*---------------------------------------------------------- * Set up the relax data structure *----------------------------------------------------------*/ (relax_data -> A) = hypre_StructMatrixRef(A); (relax_data -> x) = hypre_StructVectorRef(x); (relax_data -> b) = hypre_StructVectorRef(b); (relax_data -> diag_rank) = diag_rank; (relax_data -> compute_pkgs) = compute_pkgs; /*----------------------------------------------------- * Compute flops *-----------------------------------------------------*/ scale = 0.0; for (p = 0; p < num_pointsets; p++) { stride = pointset_strides[p]; frac = hypre_IndexX(stride); frac *= hypre_IndexY(stride); frac *= hypre_IndexZ(stride); scale += (pointset_sizes[p] / frac); } (relax_data -> flops) = scale * (hypre_StructMatrixGlobalSize(A) + hypre_StructVectorGlobalSize(x)); return ierr; }
int hypre_SStructUMatrixInitialize( hypre_SStructMatrix *matrix ) { HYPRE_IJMatrix ijmatrix = hypre_SStructMatrixIJMatrix(matrix); hypre_SStructGraph *graph = hypre_SStructMatrixGraph(matrix); hypre_SStructGrid *grid = hypre_SStructGraphGrid(graph); int nparts = hypre_SStructGraphNParts(graph); hypre_SStructPGrid **pgrids = hypre_SStructGraphPGrids(graph); hypre_SStructStencil ***stencils = hypre_SStructGraphStencils(graph); int nUventries = hypre_SStructGraphNUVEntries(graph); int *iUventries = hypre_SStructGraphIUVEntries(graph); hypre_SStructUVEntry **Uventries = hypre_SStructGraphUVEntries(graph); int **nvneighbors = hypre_SStructGridNVNeighbors(grid); hypre_StructGrid *sgrid; hypre_SStructStencil *stencil; int *split; int nvars; int nrows, nnzs ; int part, var, entry, i, j, k,m,b; int *row_sizes; int max_row_size; int matrix_type = hypre_SStructMatrixObjectType(matrix); hypre_Box *gridbox; hypre_Box *loopbox; hypre_Box *ghostbox; hypre_BoxArray *boxes; int *num_ghost; HYPRE_IJMatrixSetObjectType(ijmatrix, HYPRE_PARCSR); /* GEC1002 the ghlocalsize is used to set the number of rows */ if (matrix_type == HYPRE_PARCSR) { nrows = hypre_SStructGridLocalSize(grid); } if (matrix_type == HYPRE_SSTRUCT || matrix_type == HYPRE_STRUCT) { nrows = hypre_SStructGridGhlocalSize(grid) ; } /* set row sizes */ m = 0; row_sizes = hypre_CTAlloc(int, nrows); max_row_size = 0; for (part = 0; part < nparts; part++) { nvars = hypre_SStructPGridNVars(pgrids[part]); for (var = 0; var < nvars; var++) { sgrid = hypre_SStructPGridSGrid(pgrids[part], var); stencil = stencils[part][var]; split = hypre_SStructMatrixSplit(matrix, part, var); nnzs = 0; for (entry = 0; entry < hypre_SStructStencilSize(stencil); entry++) { if (split[entry] == -1) { nnzs++; } } #if 0 /* TODO: For now, assume stencil is full/complete */ if (hypre_SStructMatrixSymmetric(matrix)) { nnzs = 2*nnzs - 1; } #endif /**************/ boxes = hypre_StructGridBoxes(sgrid) ; num_ghost = hypre_StructGridNumGhost(sgrid); for (b = 0; b < hypre_BoxArraySize(boxes); b++) { gridbox = hypre_BoxArrayBox(boxes, b); ghostbox = hypre_BoxCreate(); loopbox = hypre_BoxCreate(); hypre_CopyBox(gridbox,ghostbox); hypre_BoxExpand(ghostbox,num_ghost); if (matrix_type == HYPRE_SSTRUCT || matrix_type == HYPRE_STRUCT) { hypre_CopyBox(ghostbox,loopbox); } if (matrix_type == HYPRE_PARCSR) { hypre_CopyBox(gridbox,loopbox); } for (k = hypre_BoxIMinZ(loopbox); k <= hypre_BoxIMaxZ(loopbox); k++) { for (j = hypre_BoxIMinY(loopbox); j <= hypre_BoxIMaxY(loopbox); j++) { for (i = hypre_BoxIMinX(loopbox); i <= hypre_BoxIMaxX(loopbox); i++) { if ( ( ( i>=hypre_BoxIMinX(gridbox) ) && ( j>=hypre_BoxIMinY(gridbox) ) ) && ( k>=hypre_BoxIMinZ(gridbox) ) ) { if ( ( ( i<=hypre_BoxIMaxX(gridbox) ) && ( j<=hypre_BoxIMaxY(gridbox) ) ) && ( k<=hypre_BoxIMaxZ(gridbox) ) ) { row_sizes[m] = nnzs; max_row_size = hypre_max(max_row_size, row_sizes[m]); } } m++; } } } hypre_BoxDestroy(ghostbox); hypre_BoxDestroy(loopbox); } if (nvneighbors[part][var]) { max_row_size = hypre_max(max_row_size, hypre_SStructStencilSize(stencil)); } /*********************/ } } /* GEC0902 essentially for each UVentry we figure out how many extra columns * we need to add to the rowsizes */ for (entry = 0; entry < nUventries; entry++) { i = iUventries[entry]; row_sizes[i] += hypre_SStructUVEntryNUEntries(Uventries[i]); max_row_size = hypre_max(max_row_size, row_sizes[i]); } /* ZTODO: Update row_sizes based on neighbor off-part couplings */ HYPRE_IJMatrixSetRowSizes (ijmatrix, (const int *) row_sizes); hypre_TFree(row_sizes); hypre_SStructMatrixTmpColCoords(matrix) = hypre_CTAlloc(HYPRE_BigInt, max_row_size); hypre_SStructMatrixTmpCoeffs(matrix) = hypre_CTAlloc(double, max_row_size); /* GEC1002 at this point the processor has the partitioning (creation of ij) */ HYPRE_IJMatrixInitialize(ijmatrix); return hypre_error_flag; }
HYPRE_Int hypre_CreateCommInfoFromStencil( hypre_StructGrid *grid, hypre_StructStencil *stencil, hypre_CommInfo **comm_info_ptr ) { HYPRE_Int i,j,k, d, m, s; hypre_BoxArrayArray *send_boxes; hypre_BoxArrayArray *recv_boxes; HYPRE_Int **send_procs; HYPRE_Int **recv_procs; HYPRE_Int **send_rboxnums; HYPRE_Int **recv_rboxnums; hypre_BoxArrayArray *send_rboxes; hypre_BoxArrayArray *recv_rboxes; hypre_BoxArray *local_boxes; HYPRE_Int num_boxes; HYPRE_Int *local_ids; hypre_BoxManager *boxman; hypre_Index *stencil_shape; hypre_IndexRef stencil_offset; hypre_IndexRef pshift; hypre_Box *box; hypre_Box *hood_box; hypre_Box *grow_box; hypre_Box *extend_box; hypre_Box *int_box; hypre_Box *periodic_box; HYPRE_Int stencil_grid[3][3][3]; HYPRE_Int grow[3][2]; hypre_BoxManEntry **entries; hypre_BoxManEntry *entry; HYPRE_Int num_entries; hypre_BoxArray *neighbor_boxes = NULL; HYPRE_Int *neighbor_procs = NULL; HYPRE_Int *neighbor_ids = NULL; HYPRE_Int *neighbor_shifts = NULL; HYPRE_Int neighbor_count; HYPRE_Int neighbor_alloc; hypre_Index ilower, iupper; hypre_BoxArray *send_box_array; hypre_BoxArray *recv_box_array; hypre_BoxArray *send_rbox_array; hypre_BoxArray *recv_rbox_array; hypre_Box **cboxes; hypre_Box *cboxes_mem; HYPRE_Int *cboxes_neighbor_location; HYPRE_Int num_cboxes, cbox_alloc; HYPRE_Int istart[3], istop[3]; HYPRE_Int sgindex[3]; HYPRE_Int num_periods, loc, box_id, id, proc_id; HYPRE_Int myid; MPI_Comm comm; /*------------------------------------------------------ * Initializations *------------------------------------------------------*/ local_boxes = hypre_StructGridBoxes(grid); local_ids = hypre_StructGridIDs(grid); num_boxes = hypre_BoxArraySize(local_boxes); num_periods = hypre_StructGridNumPeriods(grid); boxman = hypre_StructGridBoxMan(grid); comm = hypre_StructGridComm(grid); hypre_MPI_Comm_rank(comm, &myid); for (k = 0; k < 3; k++) { for (j = 0; j < 3; j++) { for (i = 0; i < 3; i++) { stencil_grid[i][j][k] = 0; } } } /*------------------------------------------------------ * Compute the "grow" information from the stencil *------------------------------------------------------*/ stencil_shape = hypre_StructStencilShape(stencil); for (d = 0; d < 3; d++) { grow[d][0] = 0; grow[d][1] = 0; } for (s = 0; s < hypre_StructStencilSize(stencil); s++) { stencil_offset = stencil_shape[s]; for (d = 0; d < 3; d++) { m = stencil_offset[d]; istart[d] = 1; istop[d] = 1; if (m < 0) { istart[d] = 0; grow[d][0] = hypre_max(grow[d][0], -m); } else if (m > 0) { istop[d] = 2; grow[d][1] = hypre_max(grow[d][1], m); } } /* update stencil grid from the grow_stencil */ for (k = istart[2]; k <= istop[2]; k++) { for (j = istart[1]; j <= istop[1]; j++) { for (i = istart[0]; i <= istop[0]; i++) { stencil_grid[i][j][k] = 1; } } } } /*------------------------------------------------------ * Compute send/recv boxes and procs for each local box *------------------------------------------------------*/ /* initialize: for each local box, we create an array of send/recv info */ send_boxes = hypre_BoxArrayArrayCreate(num_boxes); recv_boxes = hypre_BoxArrayArrayCreate(num_boxes); send_procs = hypre_CTAlloc(HYPRE_Int *, num_boxes); recv_procs = hypre_CTAlloc(HYPRE_Int *, num_boxes); /* Remote boxnums and boxes describe data on the opposing processor, so some shifting of boxes is needed below for periodic neighbor boxes. Remote box info is also needed for receives to allow for reverse communication. */ send_rboxnums = hypre_CTAlloc(HYPRE_Int *, num_boxes); send_rboxes = hypre_BoxArrayArrayCreate(num_boxes); recv_rboxnums = hypre_CTAlloc(HYPRE_Int *, num_boxes); recv_rboxes = hypre_BoxArrayArrayCreate(num_boxes); grow_box = hypre_BoxCreate(); extend_box = hypre_BoxCreate(); int_box = hypre_BoxCreate(); periodic_box = hypre_BoxCreate(); /* storage we will use and keep track of the neighbors */ neighbor_alloc = 30; /* initial guess at max size */ neighbor_boxes = hypre_BoxArrayCreate(neighbor_alloc); neighbor_procs = hypre_CTAlloc(HYPRE_Int, neighbor_alloc); neighbor_ids = hypre_CTAlloc(HYPRE_Int, neighbor_alloc); neighbor_shifts = hypre_CTAlloc(HYPRE_Int, neighbor_alloc); /* storage we will use to collect all of the intersected boxes (the send and recv regions for box i (this may not be enough in the case of periodic boxes, so we will have to check) */ cbox_alloc = hypre_BoxManNEntries(boxman); cboxes_neighbor_location = hypre_CTAlloc(HYPRE_Int, cbox_alloc); cboxes = hypre_CTAlloc(hypre_Box *, cbox_alloc); cboxes_mem = hypre_CTAlloc(hypre_Box, cbox_alloc); /******* loop through each local box **************/ for (i = 0; i < num_boxes; i++) { /* get the box */ box = hypre_BoxArrayBox(local_boxes, i); /* box_id = local_ids[i]; the box id in the Box Manager is the box number, * and we use this to find out if a box has intersected with itself */ box_id = i; /* grow box local i according to the stencil*/ hypre_CopyBox(box, grow_box); for (d = 0; d < 3; d++) { hypre_BoxIMinD(grow_box, d) -= grow[d][0]; hypre_BoxIMaxD(grow_box, d) += grow[d][1]; } /* extend_box - to find the list of potential neighbors, we need to grow the local box a bit differently in case, for example, the stencil grows in one dimension [0] and not the other [1] */ hypre_CopyBox(box, extend_box); for (d = 0; d < 3; d++) { hypre_BoxIMinD(extend_box, d) -= hypre_max(grow[d][0],grow[d][1]); hypre_BoxIMaxD(extend_box, d) += hypre_max(grow[d][0],grow[d][1]); } /*------------------------------------------------ * Determine the neighbors of box i *------------------------------------------------*/ /* Do this by intersecting the extend box with the BoxManager. We must also check for periodic neighbors. */ neighbor_count = 0; hypre_BoxArraySetSize(neighbor_boxes, 0); /* shift the box by each period (k=0 is original box) */ for (k = 0; k < num_periods; k++) { hypre_CopyBox(extend_box, periodic_box); pshift = hypre_StructGridPShift(grid, k); hypre_BoxShiftPos(periodic_box, pshift); /* get the intersections */ hypre_BoxManIntersect(boxman, hypre_BoxIMin(periodic_box) , hypre_BoxIMax(periodic_box) , &entries , &num_entries); /* note: do we need to remove the intersection with our original box? no if periodic, yes if non-periodic (k=0) */ /* unpack entries (first check storage) */ if (neighbor_count + num_entries > neighbor_alloc) { neighbor_alloc = neighbor_count + num_entries + 5; neighbor_procs = hypre_TReAlloc(neighbor_procs, HYPRE_Int, neighbor_alloc); neighbor_ids = hypre_TReAlloc(neighbor_ids, HYPRE_Int, neighbor_alloc); neighbor_shifts = hypre_TReAlloc(neighbor_shifts, HYPRE_Int, neighbor_alloc); } /* check storage for the array */ hypre_BoxArraySetSize(neighbor_boxes, neighbor_count + num_entries); /* now unpack */ for (j = 0; j < num_entries; j++) { entry = entries[j]; proc_id = hypre_BoxManEntryProc(entry); id = hypre_BoxManEntryId(entry); /* don't keep box i in the non-periodic case*/ if (!k) { if((myid == proc_id) && (box_id == id)) { continue; } } hypre_BoxManEntryGetExtents(entry, ilower, iupper); hypre_BoxSetExtents(hypre_BoxArrayBox(neighbor_boxes, neighbor_count), ilower, iupper); /* shift the periodic boxes (needs to be the opposite of above) */ if (k) { hypre_BoxShiftNeg( hypre_BoxArrayBox(neighbor_boxes, neighbor_count), pshift); } neighbor_procs[neighbor_count] = proc_id; neighbor_ids[neighbor_count] = id; neighbor_shifts[neighbor_count] = k; neighbor_count++; } hypre_BoxArraySetSize(neighbor_boxes, neighbor_count); hypre_TFree(entries); } /* end of loop through periods k */ /* Now we have a list of all of the neighbors for box i! */ /* note: we don't want/need to remove duplicates - they should have different intersections (TO DO: put more thought into if there are ever any exceptions to this? - the intersection routine already eliminates duplicates - so what i mean is eliminating duplicates from multiple intersection calls in periodic case) */ /*------------------------------------------------ * Compute recv_box_array for box i *------------------------------------------------*/ /* check size of storage for cboxes */ /* let's make sure that we have enough storage in case each neighbor produces a send/recv region */ if (neighbor_count > cbox_alloc) { cbox_alloc = neighbor_count; cboxes_neighbor_location = hypre_TReAlloc(cboxes_neighbor_location, HYPRE_Int, cbox_alloc); cboxes = hypre_TReAlloc(cboxes, hypre_Box *, cbox_alloc); cboxes_mem = hypre_TReAlloc(cboxes_mem, hypre_Box, cbox_alloc); } /* Loop through each neighbor box. If the neighbor box intersects the grown box i (grown according to our stencil), then the intersection is a recv region. If the neighbor box was shifted to handle periodicity, we need to (positive) shift it back. */ num_cboxes = 0; for (k = 0; k < neighbor_count; k++) { hood_box = hypre_BoxArrayBox(neighbor_boxes, k); /* check the stencil grid to see if it makes sense to intersect */ for (d = 0; d < 3; d++) { sgindex[d] = 1; s = hypre_BoxIMinD(hood_box, d) - hypre_BoxIMaxD(box, d); if (s > 0) { sgindex[d] = 2; } s = hypre_BoxIMinD(box, d) - hypre_BoxIMaxD(hood_box, d); if (s > 0) { sgindex[d] = 0; } } /* it makes sense only if we have at least one non-zero entry */ if (stencil_grid[sgindex[0]][sgindex[1]][sgindex[2]]) { /* intersect - result is int_box */ hypre_IntersectBoxes(grow_box, hood_box, int_box); /* if we have a positive volume box, this is a recv region */ if (hypre_BoxVolume(int_box)) { /* keep track of which neighbor: k... */ cboxes_neighbor_location[num_cboxes] = k; cboxes[num_cboxes] = &cboxes_mem[num_cboxes]; /* keep the intersected box */ hypre_CopyBox(int_box, cboxes[num_cboxes]); num_cboxes++; } } } /* end of loop through each neighbor */ /* create recv_box_array and recv_procs for box i */ recv_box_array = hypre_BoxArrayArrayBoxArray(recv_boxes, i); hypre_BoxArraySetSize(recv_box_array, num_cboxes); recv_procs[i] = hypre_CTAlloc(HYPRE_Int, num_cboxes); recv_rboxnums[i] = hypre_CTAlloc(HYPRE_Int, num_cboxes); recv_rbox_array = hypre_BoxArrayArrayBoxArray(recv_rboxes, i); hypre_BoxArraySetSize(recv_rbox_array, num_cboxes); for (m = 0; m < num_cboxes; m++) { loc = cboxes_neighbor_location[m]; recv_procs[i][m] = neighbor_procs[loc]; recv_rboxnums[i][m] = neighbor_ids[loc]; hypre_CopyBox(cboxes[m], hypre_BoxArrayBox(recv_box_array, m)); /* if periodic, positive shift before copying to the rbox_array */ if (neighbor_shifts[loc]) /* periodic if shift != 0 */ { pshift = hypre_StructGridPShift(grid, neighbor_shifts[loc]); hypre_BoxShiftPos(cboxes[m], pshift); } hypre_CopyBox(cboxes[m], hypre_BoxArrayBox(recv_rbox_array, m)); cboxes[m] = NULL; } /*------------------------------------------------ * Compute send_box_array for box i *------------------------------------------------*/ /* Loop through each neighbor box. If the grown neighbor box intersects box i, then the intersection is a send region. If the neighbor box was shifted to handle periodicity, we need to (positive) shift it back. */ num_cboxes = 0; for (k = 0; k < neighbor_count; k++) { hood_box = hypre_BoxArrayBox(neighbor_boxes, k); /* check the stencil grid to see if it makes sense to intersect */ for (d = 0; d < 3; d++) { sgindex[d] = 1; s = hypre_BoxIMinD(box, d) - hypre_BoxIMaxD(hood_box, d); if (s > 0) { sgindex[d] = 2; } s = hypre_BoxIMinD(hood_box, d) - hypre_BoxIMaxD(box, d); if (s > 0) { sgindex[d] = 0; } } /* it makes sense only if we have at least one non-zero entry */ if (stencil_grid[sgindex[0]][sgindex[1]][sgindex[2]]) { /* grow the neighbor box and intersect */ hypre_CopyBox(hood_box, grow_box); for (d = 0; d < 3; d++) { hypre_BoxIMinD(grow_box, d) -= grow[d][0]; hypre_BoxIMaxD(grow_box, d) += grow[d][1]; } hypre_IntersectBoxes(box, grow_box, int_box); /* if we have a positive volume box, this is a send region */ if (hypre_BoxVolume(int_box)) { /* keep track of which neighbor: k... */ cboxes_neighbor_location[num_cboxes] = k; cboxes[num_cboxes] = &cboxes_mem[num_cboxes]; /* keep the intersected box */ hypre_CopyBox(int_box, cboxes[num_cboxes]); num_cboxes++; } } }/* end of loop through neighbors */ /* create send_box_array and send_procs for box i */ send_box_array = hypre_BoxArrayArrayBoxArray(send_boxes, i); hypre_BoxArraySetSize(send_box_array, num_cboxes); send_procs[i] = hypre_CTAlloc(HYPRE_Int, num_cboxes); send_rboxnums[i] = hypre_CTAlloc(HYPRE_Int, num_cboxes); send_rbox_array = hypre_BoxArrayArrayBoxArray(send_rboxes, i); hypre_BoxArraySetSize(send_rbox_array, num_cboxes); for (m = 0; m < num_cboxes; m++) { loc = cboxes_neighbor_location[m]; send_procs[i][m] = neighbor_procs[loc]; send_rboxnums[i][m] = neighbor_ids[loc]; hypre_CopyBox(cboxes[m], hypre_BoxArrayBox(send_box_array, m)); /* if periodic, positive shift before copying to the rbox_array */ if (neighbor_shifts[loc]) /* periodic if shift != 0 */ { pshift = hypre_StructGridPShift(grid, neighbor_shifts[loc]); hypre_BoxShiftPos(cboxes[m], pshift); } hypre_CopyBox(cboxes[m], hypre_BoxArrayBox(send_rbox_array, m)); cboxes[m] = NULL; } } /* end of loop through each local box */
double hypre_StructOverlapInnerProd( hypre_StructVector *x, hypre_StructVector *y ) { double final_innerprod_result; double local_result, overlap_result; double process_result; hypre_Box *x_data_box; hypre_Box *y_data_box; hypre_BoxArray *overlap_boxes; HYPRE_Int xi; HYPRE_Int yi; double *xp; double *yp; hypre_BoxArray *boxes; hypre_Box *boxi, *boxj, intersect_box; hypre_StructGrid *grid= hypre_StructVectorGrid(y); hypre_BoxManager *boxman = hypre_StructGridBoxMan(grid); hypre_BoxArray *neighbor_boxes; HYPRE_Int *neighbors_procs= NULL; hypre_BoxArray *selected_nboxes; hypre_BoxArray *tmp_box_array, *tmp2_box_array; hypre_Index loop_size; hypre_IndexRef start; hypre_Index unit_stride; HYPRE_Int i, j; HYPRE_Int myid; HYPRE_Int boxarray_size; HYPRE_Int loopi, loopj, loopk; #ifdef HYPRE_USE_PTHREADS HYPRE_Int threadid = hypre_GetThreadID(); #endif local_result = 0.0; process_result = 0.0; hypre_SetIndex(unit_stride, 1, 1, 1); hypre_MPI_Comm_rank(hypre_StructVectorComm(y), &myid); /*----------------------------------------------------------------------- * Determine the overlapped boxes on this local processor. *-----------------------------------------------------------------------*/ boxes = hypre_StructGridBoxes(hypre_StructVectorGrid(y)); boxarray_size= hypre_BoxArraySize(boxes); /*----------------------------------------------------------------------- * To compute the inner product over this local processor, given a box, * the inner product between x & y is computed over the whole box and * over any overlapping between this box and overlap_boxes. The latter * result is subtracted from the former. Overlapping between more than * two boxes are handled. *-----------------------------------------------------------------------*/ hypre_ForBoxI(i, boxes) { boxi = hypre_BoxArrayBox(boxes, i); start = hypre_BoxIMin(boxi); x_data_box = hypre_BoxArrayBox(hypre_StructVectorDataSpace(x), i); y_data_box = hypre_BoxArrayBox(hypre_StructVectorDataSpace(y), i); xp = hypre_StructVectorBoxData(x, i); yp = hypre_StructVectorBoxData(y, i); hypre_BoxGetSize(boxi, loop_size); #ifdef HYPRE_USE_PTHREADS local_result_ref[threadid] = &local_result; #endif hypre_BoxLoop2Begin(loop_size, x_data_box, start, unit_stride, xi, y_data_box, start, unit_stride, yi); #define HYPRE_BOX_SMP_PRIVATE loopk,loopi,loopj,xi,yi #define HYPRE_SMP_REDUCTION_OP + #define HYPRE_SMP_REDUCTION_VARS local_result #include "hypre_box_smp_forloop.h" hypre_BoxLoop2For(loopi, loopj, loopk, xi, yi) { local_result += xp[xi] * yp[yi]; }
int hypre_StructCoarsen( hypre_StructGrid *fgrid, hypre_Index index, hypre_Index stride, int prune, hypre_StructGrid **cgrid_ptr ) { int ierr = 0; hypre_StructGrid *cgrid; MPI_Comm comm; int dim; hypre_BoxNeighbors *neighbors; hypre_BoxArray *hood_boxes; int num_hood; int *hood_procs; int *hood_ids; int first_local; int num_local; int num_periodic; int max_distance; hypre_Box *bounding_box; hypre_Index periodic; MPI_Request *send_requests; MPI_Status *send_status; int *send_buffer; int send_size; MPI_Request *recv_requests; MPI_Status *recv_status; int **recv_buffers; int *recv_sizes; int my_rank; int *send_procs; int *recv_procs; int num_sends; int num_recvs; hypre_BoxArray *new_hood_boxes; int new_num_hood; int *new_hood_procs; int *new_hood_ids; int new_first_local; int new_num_local; int new_num_periodic; hypre_Box *box; hypre_Box *local_box; hypre_Box *neighbor_box; hypre_Box *local_cbox; hypre_Box *neighbor_cbox; hypre_Index imin; hypre_Index imax; int alloc_size; double perimeter_count, cperimeter_count; /*double diff, distance, perimeter_count, cperimeter_count;*/ int *iarray; int *jrecv; int i, j, d, ilocal; int data_id, min_id, jj; /*----------------------------------------- * Copy needed info from fgrid *-----------------------------------------*/ comm = hypre_StructGridComm(fgrid); dim = hypre_StructGridDim(fgrid); neighbors = hypre_StructGridNeighbors(fgrid); hood_boxes = hypre_BoxArrayDuplicate(hypre_BoxNeighborsBoxes(neighbors)); num_hood = hypre_BoxArraySize(hood_boxes); iarray = hypre_BoxNeighborsProcs(neighbors); hood_procs = hypre_TAlloc(int, num_hood); for (i = 0; i < num_hood; i++) { hood_procs[i] = iarray[i]; } iarray = hypre_BoxNeighborsIDs(neighbors); hood_ids = hypre_TAlloc(int, num_hood); for (i = 0; i < num_hood; i++) { hood_ids[i] = iarray[i]; } first_local = hypre_BoxNeighborsFirstLocal(neighbors); num_local = hypre_BoxNeighborsNumLocal(neighbors); num_periodic = hypre_BoxNeighborsNumPeriodic(neighbors); max_distance = hypre_StructGridMaxDistance(fgrid); bounding_box = hypre_BoxDuplicate(hypre_StructGridBoundingBox(fgrid)); hypre_CopyIndex(hypre_StructGridPeriodic(fgrid), periodic); MPI_Comm_rank(comm, &my_rank); #if DEBUG sprintf(filename, "zcoarsen.%05d", my_rank); if ((file = fopen(filename, "a")) == NULL) { printf("Error: can't open output file %s\n", filename); exit(1); } fprintf(file, "\n\n============================\n\n"); fprintf(file, "\n\n%d\n\n", debug_count++); fprintf(file, "num_hood = %d\n", num_hood); for (i = 0; i < num_hood; i++) { box = hypre_BoxArrayBox(hood_boxes, i); fprintf(file, "(%d,%d,%d) X (%d,%d,%d) ; (%d,%d); %d\n", hypre_BoxIMinX(box),hypre_BoxIMinY(box),hypre_BoxIMinZ(box), hypre_BoxIMaxX(box),hypre_BoxIMaxY(box),hypre_BoxIMaxZ(box), hood_procs[i], hood_ids[i], hypre_BoxVolume(box)); } fprintf(file, "first_local = %d\n", first_local); fprintf(file, "num_local = %d\n", num_local); fprintf(file, "num_periodic = %d\n", num_periodic); #endif /*----------------------------------------- * Coarsen bounding box *-----------------------------------------*/ hypre_StructCoarsenBox(bounding_box, index, stride); /*----------------------------------------- * Coarsen neighborhood boxes & determine * send / recv procs * * NOTE: Currently, this always communicates * with all neighboring processes. *-----------------------------------------*/ local_cbox = hypre_BoxCreate(); neighbor_cbox = hypre_BoxCreate(); num_recvs = 0; num_sends = 0; recv_procs = NULL; send_procs = NULL; for (i = 0; i < num_hood; i++) { if (hood_procs[i] != my_rank) { for (j = 0; j < num_local; j++) { ilocal = first_local + j; local_box = hypre_BoxArrayBox(hood_boxes, ilocal); neighbor_box = hypre_BoxArrayBox(hood_boxes, i); /* coarsen boxes being considered */ hypre_CopyBox(local_box, local_cbox); hypre_StructCoarsenBox(local_cbox, index, stride); hypre_CopyBox(neighbor_box, neighbor_cbox); hypre_StructCoarsenBox(neighbor_cbox, index, stride); /*----------------------- * Receive info? *-----------------------*/ /* always communicate */ #if 0 perimeter_count = 0; cperimeter_count = 0; for (d = 0; d < 3; d++) { distance = max_distance; diff = hypre_BoxIMaxD(neighbor_box, d) - hypre_BoxIMaxD(local_box, d); if (diff > 0) { distance = hypre_min(distance, diff); } diff = hypre_BoxIMinD(local_box, d) - hypre_BoxIMinD(neighbor_box, d); if (diff > 0) { distance = hypre_min(distance, diff); } if (distance < max_distance) { perimeter_count++; } distance = max_distance; diff = hypre_BoxIMaxD(neighbor_cbox, d) - hypre_BoxIMaxD(local_cbox, d); if (diff > 0) { distance = hypre_min(distance, diff); } diff = hypre_BoxIMinD(local_cbox, d) - hypre_BoxIMinD(neighbor_cbox, d); if (diff > 0) { distance = hypre_min(distance, diff); } if (distance < max_distance) { cperimeter_count++; } } #else perimeter_count = 0; cperimeter_count = 1; #endif if (cperimeter_count > perimeter_count) { if (num_recvs == 0) { recv_procs = hypre_TAlloc(int, num_hood); recv_procs[num_recvs] = hood_procs[i]; num_recvs++; } else if (hood_procs[i] != recv_procs[num_recvs-1]) { recv_procs[num_recvs] = hood_procs[i]; num_recvs++; } } /*----------------------- * Send info? *-----------------------*/ /* always communicate */ #if 0 perimeter_count = 0; cperimeter_count = 0; for (d = 0; d < 3; d++) { distance = max_distance; diff = hypre_BoxIMaxD(local_box, d) - hypre_BoxIMaxD(neighbor_box, d); if (diff > 0) { distance = hypre_min(distance, diff); } diff = hypre_BoxIMinD(neighbor_box, d) - hypre_BoxIMinD(local_box, d); if (diff > 0) { distance = hypre_min(distance, diff); } if (distance < max_distance) { perimeter_count++; } distance = max_distance; diff = hypre_BoxIMaxD(local_cbox, d) - hypre_BoxIMaxD(neighbor_cbox, d); if (diff > 0) { distance = hypre_min(distance, diff); } diff = hypre_BoxIMinD(neighbor_cbox, d) - hypre_BoxIMinD(local_cbox, d); if (diff > 0) { distance = hypre_min(distance, diff); } if (distance < max_distance) { cperimeter_count++; } } #else perimeter_count = 0; cperimeter_count = 1; #endif if (cperimeter_count > perimeter_count) { if (num_sends == 0) { send_procs = hypre_TAlloc(int, num_hood); send_procs[num_sends] = hood_procs[i]; num_sends++; } else if (hood_procs[i] != send_procs[num_sends-1]) { send_procs[num_sends] = hood_procs[i]; num_sends++; } }
hypre_BoxIMinD(cbox, d) = hypre_BoxIMaxD(cbox, d) - border[d][1] + 1; hypre_BoxIMaxD(rembox, d) = hypre_BoxIMaxD(cbox, d) - border[d][1]; cbox_array_size++; } } hypre_BoxArraySetSize(cbox_array, cbox_array_size); } hypre_BoxDestroy(rembox); /*------------------------------------------------------ * Set up the independent boxes *------------------------------------------------------*/ indt_boxes = hypre_BoxArrayArrayCreate(hypre_BoxArraySize(boxes)); hypre_ForBoxI(i, boxes) { cbox_array = hypre_BoxArrayArrayBoxArray(indt_boxes, i); hypre_BoxArraySetSize(cbox_array, 1); cbox = hypre_BoxArrayBox(cbox_array, 0); hypre_CopyBox(hypre_BoxArrayBox(boxes, i), cbox); for (d = 0; d < 3; d++) { if ( (border[d][0]) ) { hypre_BoxIMinD(cbox, d) += border[d][0]; } if ( (border[d][1]) )
hypre_SStructSendInfoData * hypre_SStructSendInfo( hypre_StructGrid *fgrid, hypre_BoxManager *cboxman, hypre_Index rfactor ) { hypre_SStructSendInfoData *sendinfo_data; MPI_Comm comm= hypre_SStructVectorComm(fgrid); hypre_BoxArray *grid_boxes; hypre_Box *grid_box, cbox; hypre_Box *intersect_box, boxman_entry_box; hypre_BoxManEntry **boxman_entries; HYPRE_Int nboxman_entries; hypre_BoxArrayArray *send_boxes; HYPRE_Int **send_processes; HYPRE_Int **send_remote_boxnums; hypre_Index ilower, iupper, index; HYPRE_Int myproc, proc; HYPRE_Int cnt; HYPRE_Int i, j; hypre_ClearIndex(index); hypre_MPI_Comm_rank(comm, &myproc); sendinfo_data= hypre_CTAlloc(hypre_SStructSendInfoData, 1); /*------------------------------------------------------------------------ * Create the structured sendbox patterns. * * send_boxes are obtained by intersecting this proc's fgrid boxes * with cgrid's box_man. Intersecting BoxManEntries not on this proc * will give boxes that we will need to send data to- i.e., we scan * through the boxes of grid and find the processors that own a chunk * of it. *------------------------------------------------------------------------*/ intersect_box = hypre_CTAlloc(hypre_Box, 1); grid_boxes = hypre_StructGridBoxes(fgrid); send_boxes= hypre_BoxArrayArrayCreate(hypre_BoxArraySize(grid_boxes)); send_processes= hypre_CTAlloc(HYPRE_Int *, hypre_BoxArraySize(grid_boxes)); send_remote_boxnums= hypre_CTAlloc(HYPRE_Int *, hypre_BoxArraySize(grid_boxes)); hypre_ForBoxI(i, grid_boxes) { grid_box= hypre_BoxArrayBox(grid_boxes, i); /*--------------------------------------------------------------------- * Find the boxarray that must be sent. BoxManIntersect returns * the full extents of the boxes that intersect with the given box. * We further need to intersect each box in the list with the given * box to determine the actual box that needs to be sent. *---------------------------------------------------------------------*/ hypre_SStructIndexScaleF_C(hypre_BoxIMin(grid_box), index, rfactor, hypre_BoxIMin(&cbox)); hypre_SStructIndexScaleF_C(hypre_BoxIMax(grid_box), index, rfactor, hypre_BoxIMax(&cbox)); hypre_BoxManIntersect(cboxman, hypre_BoxIMin(&cbox), hypre_BoxIMax(&cbox), &boxman_entries, &nboxman_entries); cnt= 0; for (j= 0; j< nboxman_entries; j++) { hypre_SStructBoxManEntryGetProcess(boxman_entries[j], &proc); if (proc != myproc) { cnt++; } } send_processes[i] = hypre_CTAlloc(HYPRE_Int, cnt); send_remote_boxnums[i]= hypre_CTAlloc(HYPRE_Int, cnt); cnt= 0; for (j= 0; j< nboxman_entries; j++) { hypre_SStructBoxManEntryGetProcess(boxman_entries[j], &proc); /* determine the chunk of the boxman_entries[j] box that is needed */ hypre_BoxManEntryGetExtents(boxman_entries[j], ilower, iupper); hypre_BoxSetExtents(&boxman_entry_box, ilower, iupper); hypre_IntersectBoxes(&boxman_entry_box, &cbox, &boxman_entry_box); if (proc != myproc) { send_processes[i][cnt] = proc; hypre_SStructBoxManEntryGetBoxnum(boxman_entries[j], &send_remote_boxnums[i][cnt]); hypre_AppendBox(&boxman_entry_box, hypre_BoxArrayArrayBoxArray(send_boxes, i)); cnt++; } } hypre_TFree(boxman_entries); } /* hypre_ForBoxI(i, grid_boxes) */
HYPRE_Int hypre_StructCoarsen( hypre_StructGrid *fgrid, hypre_Index index, hypre_Index stride, HYPRE_Int prune, hypre_StructGrid **cgrid_ptr ) { hypre_StructGrid *cgrid; MPI_Comm comm; HYPRE_Int ndim; hypre_BoxArray *my_boxes; hypre_Index periodic; hypre_Index ilower, iupper; hypre_Box *box; hypre_Box *new_box; hypre_Box *bounding_box; HYPRE_Int i, j, myid, count; HYPRE_Int info_size, max_nentries; HYPRE_Int num_entries; HYPRE_Int *fids, *cids; hypre_Index new_dist; hypre_IndexRef max_distance; HYPRE_Int proc, id; HYPRE_Int coarsen_factor, known; HYPRE_Int num, last_proc; #if 0 hypre_StructAssumedPart *fap = NULL, *cap = NULL; #endif hypre_BoxManager *fboxman, *cboxman; hypre_BoxManEntry *entries; hypre_BoxManEntry *entry; void *entry_info = NULL; #if TIME_DEBUG HYPRE_Int tindex; char new_title[80]; hypre_sprintf(new_title,"Coarsen.%d",s_coarsen_num); tindex = hypre_InitializeTiming(new_title); s_coarsen_num++; hypre_BeginTiming(tindex); #endif hypre_SetIndex(ilower, 0); hypre_SetIndex(iupper, 0); /* get relevant information from the fine grid */ fids = hypre_StructGridIDs(fgrid); fboxman = hypre_StructGridBoxMan(fgrid); comm = hypre_StructGridComm(fgrid); ndim = hypre_StructGridNDim(fgrid); max_distance = hypre_StructGridMaxDistance(fgrid); /* initial */ hypre_MPI_Comm_rank(comm, &myid ); /* create new coarse grid */ hypre_StructGridCreate(comm, ndim, &cgrid); /* coarsen my boxes and create the coarse grid ids (same as fgrid) */ my_boxes = hypre_BoxArrayDuplicate(hypre_StructGridBoxes(fgrid)); cids = hypre_TAlloc(HYPRE_Int, hypre_BoxArraySize(my_boxes)); for (i = 0; i < hypre_BoxArraySize(my_boxes); i++) { box = hypre_BoxArrayBox(my_boxes, i); hypre_StructCoarsenBox(box, index, stride); cids[i] = fids[i]; } /* prune? */ /* zero volume boxes are needed when forming P and P^T */ if (prune) { count = 0; hypre_ForBoxI(i, my_boxes) { box = hypre_BoxArrayBox(my_boxes, i); if (hypre_BoxVolume(box)) { hypre_CopyBox(box, hypre_BoxArrayBox(my_boxes, count)); cids[count] = cids[i]; count++; } } hypre_BoxArraySetSize(my_boxes, count); }
hypre_SStructGridBoxProcFindBoxManEntry(node_grid, part, 0, i, myproc, &entry); pgrid = hypre_SStructGridPGrid(node_grid, part); var_grid= hypre_SStructPGridSGrid(pgrid, 0); boxes = hypre_StructGridBoxes(var_grid); box = hypre_BoxArrayBox(boxes, 0); hypre_SStructBoxManEntryGetGlobalCSRank(entry, hypre_BoxIMin(box), &jlower); /* upper rank */ part= nparts-1; pgrid = hypre_SStructGridPGrid(edge_grid, part); nvars = hypre_SStructPGridNVars(pgrid); var_grid= hypre_SStructPGridSGrid(pgrid, nvars-1); boxes = hypre_StructGridBoxes(var_grid); box = hypre_BoxArrayBox(boxes, hypre_BoxArraySize(boxes)-1); hypre_SStructGridBoxProcFindBoxManEntry(edge_grid, part, nvars-1, hypre_BoxArraySize(boxes)-1, myproc, &entry); hypre_SStructBoxManEntryGetGlobalCSRank(entry, hypre_BoxIMax(box), &iupper); pgrid = hypre_SStructGridPGrid(node_grid, part); nvars = hypre_SStructPGridNVars(pgrid); var_grid= hypre_SStructPGridSGrid(pgrid, nvars-1); boxes = hypre_StructGridBoxes(var_grid); box = hypre_BoxArrayBox(boxes, hypre_BoxArraySize(boxes)-1); hypre_SStructGridBoxProcFindBoxManEntry(node_grid, part, nvars-1, hypre_BoxArraySize(boxes)-1, myproc, &entry);
int hypre_SubtractBoxes( hypre_Box *box1, hypre_Box *box2, hypre_BoxArray *box_array ) { int ierr = 0; hypre_Box *box; hypre_Box *rembox; int d, size; /*------------------------------------------------------ * Set the box array size to the maximum possible, * plus one, to have space for the remainder box. *------------------------------------------------------*/ size = hypre_BoxArraySize(box_array); hypre_BoxArraySetSize(box_array, (size + 7)); /*------------------------------------------------------ * Subtract the boxes by cutting box1 in x, y, then z *------------------------------------------------------*/ rembox = hypre_BoxArrayBox(box_array, (size + 6)); hypre_CopyBox(box1, rembox); for (d = 0; d < 3; d++) { /* if the boxes do not intersect, the subtraction is trivial */ if ( (hypre_BoxIMinD(box2, d) > hypre_BoxIMaxD(rembox, d)) || (hypre_BoxIMaxD(box2, d) < hypre_BoxIMinD(rembox, d)) ) { size = hypre_BoxArraySize(box_array) - 7; hypre_CopyBox(box1, hypre_BoxArrayBox(box_array, size)); size++; break; } /* update the box array */ else { if ( hypre_BoxIMinD(box2, d) > hypre_BoxIMinD(rembox, d) ) { box = hypre_BoxArrayBox(box_array, size); hypre_CopyBox(rembox, box); hypre_BoxIMaxD(box, d) = hypre_BoxIMinD(box2, d) - 1; hypre_BoxIMinD(rembox, d) = hypre_BoxIMinD(box2, d); if ( hypre_BoxVolume(box)>0 ) size++; } if ( hypre_BoxIMaxD(box2, d) < hypre_BoxIMaxD(rembox, d) ) { box = hypre_BoxArrayBox(box_array, size); hypre_CopyBox(rembox, box); hypre_BoxIMinD(box, d) = hypre_BoxIMaxD(box2, d) + 1; hypre_BoxIMaxD(rembox, d) = hypre_BoxIMaxD(box2, d); if ( hypre_BoxVolume(box)>0 ) size++; } } } hypre_BoxArraySetSize(box_array, size); return ierr; }
/*-------------------------------------------------------------------------- * hypre_CFInterfaceExtents: Given a cgrid_box, a fgrid_box, and stencils, * find the extents of the C/F interface (interface nodes in the C box). * Boxes corresponding to stencil shifts are stored in the first stencil_size * boxes, and the union of these are appended to the end of the returned * box_array. *--------------------------------------------------------------------------*/ hypre_BoxArray * hypre_CFInterfaceExtents( hypre_Box *fgrid_box, hypre_Box *cgrid_box, hypre_StructStencil *stencils, hypre_Index rfactors ) { hypre_BoxArray *stencil_box_extents; hypre_BoxArray *union_boxes; hypre_Box *cfine_box; hypre_Box *box; hypre_Index stencil_shape, cstart, zero_index, neg_index; HYPRE_Int stencil_size; HYPRE_Int abs_stencil; HYPRE_Int ndim= hypre_StructStencilDim(stencils); HYPRE_Int i, j; hypre_ClearIndex(zero_index); hypre_ClearIndex(neg_index); for (i= 0; i< ndim; i++) { neg_index[i]= -1; } hypre_CopyIndex(hypre_BoxIMin(cgrid_box), cstart); stencil_size = hypre_StructStencilSize(stencils); stencil_box_extents= hypre_BoxArrayCreate(stencil_size); union_boxes = hypre_BoxArrayCreate(0); for (i= 0; i< stencil_size; i++) { hypre_CopyIndex(hypre_StructStencilElement(stencils, i), stencil_shape); AbsStencilShape(stencil_shape, abs_stencil); if (abs_stencil) /* only do if not the centre stencil */ { cfine_box= hypre_CF_StenBox(fgrid_box, cgrid_box, stencil_shape, rfactors, ndim); if ( hypre_BoxVolume(cfine_box) ) { hypre_AppendBox(cfine_box, union_boxes); hypre_CopyBox(cfine_box, hypre_BoxArrayBox(stencil_box_extents, i)); for (j= 0; j< ndim; j++) { hypre_BoxIMin(cfine_box)[j]-= cstart[j]; hypre_BoxIMax(cfine_box)[j]-= cstart[j]; } hypre_CopyBox(cfine_box, hypre_BoxArrayBox(stencil_box_extents, i)); } else { hypre_BoxSetExtents(hypre_BoxArrayBox(stencil_box_extents, i), zero_index, neg_index); } hypre_BoxDestroy(cfine_box); } else /* centre */ { hypre_BoxSetExtents(hypre_BoxArrayBox(stencil_box_extents, i), zero_index, neg_index); } } /*-------------------------------------------------------------------------- * Union the stencil_box_extents to get the full CF extents and append to * the end of the stencil_box_extents BoxArray. Then shift the unioned boxes * by cstart. *--------------------------------------------------------------------------*/ if (hypre_BoxArraySize(union_boxes) > 1) { hypre_UnionBoxes(union_boxes); } hypre_ForBoxI(i, union_boxes) { hypre_AppendBox(hypre_BoxArrayBox(union_boxes, i), stencil_box_extents); }
int hypre_StructMatrixInitializeShell( hypre_StructMatrix *matrix ) { int ierr = 0; hypre_StructGrid *grid; hypre_StructStencil *user_stencil; hypre_StructStencil *stencil; hypre_Index *stencil_shape; int stencil_size; int num_values; int *symm_elements; int *num_ghost; int extra_ghost[] = {0, 0, 0, 0, 0, 0}; hypre_BoxArray *data_space; hypre_BoxArray *boxes; hypre_Box *box; hypre_Box *data_box; int **data_indices; int data_size; int data_box_volume; int i, j, d; grid = hypre_StructMatrixGrid(matrix); /*----------------------------------------------------------------------- * Set up stencil and num_values: * The stencil is a "symmetrized" version of the user's stencil * as computed by hypre_StructStencilSymmetrize. * * The `symm_elements' array is used to determine what data is * explicitely stored (symm_elements[i] < 0) and what data does is * not explicitely stored (symm_elements[i] >= 0), but is instead * stored as the transpose coefficient at a neighboring grid point. *-----------------------------------------------------------------------*/ if (hypre_StructMatrixStencil(matrix) == NULL) { user_stencil = hypre_StructMatrixUserStencil(matrix); hypre_StructStencilSymmetrize(user_stencil, &stencil, &symm_elements); stencil_shape = hypre_StructStencilShape(stencil); stencil_size = hypre_StructStencilSize(stencil); if (!hypre_StructMatrixSymmetric(matrix)) { /* store all element data */ for (i = 0; i < stencil_size; i++) symm_elements[i] = -1; num_values = stencil_size; } else { num_values = (stencil_size + 1) / 2; } hypre_StructMatrixStencil(matrix) = stencil; hypre_StructMatrixSymmElements(matrix) = symm_elements; hypre_StructMatrixNumValues(matrix) = num_values; } /*----------------------------------------------------------------------- * Set ghost-layer size for symmetric storage * - All stencil coeffs are to be available at each point in the * grid, as well as in the user-specified ghost layer. *-----------------------------------------------------------------------*/ num_ghost = hypre_StructMatrixNumGhost(matrix); stencil = hypre_StructMatrixStencil(matrix); stencil_shape = hypre_StructStencilShape(stencil); stencil_size = hypre_StructStencilSize(stencil); symm_elements = hypre_StructMatrixSymmElements(matrix); for (i = 0; i < stencil_size; i++) { if (symm_elements[i] >= 0) { for (d = 0; d < 3; d++) { extra_ghost[2*d] = hypre_max(extra_ghost[2*d], -hypre_IndexD(stencil_shape[i], d)); extra_ghost[2*d + 1] = hypre_max(extra_ghost[2*d + 1], hypre_IndexD(stencil_shape[i], d)); } } } for (d = 0; d < 3; d++) { num_ghost[2*d] += extra_ghost[2*d]; num_ghost[2*d + 1] += extra_ghost[2*d + 1]; } /*----------------------------------------------------------------------- * Set up data_space *-----------------------------------------------------------------------*/ if (hypre_StructMatrixDataSpace(matrix) == NULL) { boxes = hypre_StructGridBoxes(grid); data_space = hypre_BoxArrayCreate(hypre_BoxArraySize(boxes)); hypre_ForBoxI(i, boxes) { box = hypre_BoxArrayBox(boxes, i); data_box = hypre_BoxArrayBox(data_space, i); hypre_CopyBox(box, data_box); for (d = 0; d < 3; d++) { hypre_BoxIMinD(data_box, d) -= num_ghost[2*d]; hypre_BoxIMaxD(data_box, d) += num_ghost[2*d + 1]; } }
int hypre_StructGridAssembleWithAP( hypre_StructGrid *grid ) { int ierr = 0; int tmp_i; int size, global_num_boxes, num_local_boxes; int i, j, d, k, index; int num_procs, myid; int *sendbuf8, *recvbuf8, *sendbuf2, *recvbuf2; int min_box_size, max_box_size; int global_min_box_size, global_max_box_size; int *ids; int max_regions, max_refinements, ologp; double gamma; hypre_Index min_index, max_index; int prune; hypre_Box *box; MPI_Comm comm = hypre_StructGridComm(grid); hypre_Box *bounding_box = hypre_StructGridBoundingBox(grid); hypre_BoxArray *local_boxes = hypre_StructGridBoxes(grid); int dim = hypre_StructGridDim(grid); hypre_BoxNeighbors *neighbors = hypre_StructGridNeighbors(grid); int max_distance = hypre_StructGridMaxDistance(grid); hypre_IndexRef periodic = hypre_StructGridPeriodic(grid); int *local_boxnums; double dbl_global_size, tmp_dbl; hypre_BoxArray *my_partition; int *part_ids, *part_boxnums; int *proc_array, proc_count, proc_alloc, count; int *tmp_proc_ids = NULL; int max_response_size; int *ap_proc_ids, *send_buf, *send_buf_starts; int *response_buf, *response_buf_starts; hypre_BoxArray *neighbor_boxes, *n_boxes_copy; int *neighbor_proc_ids, *neighbor_boxnums; int *order_index, *delete_array; int tmp_id, start, first_local; int grow, grow_array[6]; hypre_Box *grow_box; int *numghost; int ghostsize; hypre_Box *ghostbox; hypre_StructAssumedPart *assumed_part; hypre_DataExchangeResponse response_obj; int px = hypre_IndexX(periodic); int py = hypre_IndexY(periodic); int pz = hypre_IndexZ(periodic); int i_periodic = px ? 1 : 0; int j_periodic = py ? 1 : 0; int k_periodic = pz ? 1 : 0; int num_periods, multiple_ap, p; hypre_Box *result_box, *period_box; hypre_Index *pshifts; hypre_IndexRef pshift; #if NEIGH_PRINT double start_time, end_time; #endif /*--------------------------------------------- Step 1: Initializations -----------------------------------------------*/ prune = 1; /* default is to prune */ num_local_boxes = hypre_BoxArraySize(local_boxes); num_periods = (1+2*i_periodic) * (1+2*j_periodic) * (1+2*k_periodic); MPI_Comm_size(comm, &num_procs); MPI_Comm_rank(comm, &myid); /*--------------------------------------------- Step 2: Determine the global size, total number of boxes, and global bounding box. Also get the min and max box sizes since it is convenient to do so. -----------------------------------------------*/ if (neighbors == NULL) { /*these may not be needed - check later */ ids = hypre_TAlloc(int, num_local_boxes); /* for the vol and number of boxes */ sendbuf2 = hypre_CTAlloc(int, 2); recvbuf2 = hypre_CTAlloc(int, 2); size = 0; bounding_box = hypre_BoxCreate(); grow_box = hypre_BoxCreate(); if (num_local_boxes) { min_box_size = hypre_BoxVolume( hypre_BoxArrayBox(local_boxes, 0)); max_box_size = hypre_BoxVolume( hypre_BoxArrayBox(local_boxes, 0)); /* initialize min and max */ for (d=0; d<3; d++) { hypre_IndexD(min_index, d) = pow(2,30); hypre_IndexD(max_index, d) = -pow(2,30); } hypre_ForBoxI(i, local_boxes) { box = hypre_BoxArrayBox(local_boxes, i); /* get global size and number of boxes */ tmp_i = hypre_BoxVolume(box); size += tmp_i; min_box_size = hypre_min(min_box_size, tmp_i); max_box_size = hypre_max(max_box_size, tmp_i); /* set id */ ids[i] = i; /* 1/3/05 we need this for the case of holes in the domain. (I had commented it out on 12/04 - as I thought this was not necessary. */ /* zero volume boxes - still look at for getting the bounding box */ if (hypre_BoxVolume(box) == 0) /* zero volume boxes - still count */ { hypre_CopyBox(box, grow_box); for (d = 0; d < 3; d++) { if(!hypre_BoxSizeD(box, d)) { grow = (hypre_BoxIMinD(box, d) - hypre_BoxIMaxD(box, d) + 1)/2; grow_array[2*d] = grow; grow_array[2*d+1] = grow; } else { grow_array[2*d] = 0; grow_array[2*d+1] = 0; } } /* expand the box */ hypre_BoxExpand(grow_box, grow_array); box = grow_box; /*pointer copy*/ } /*now we have a vol > 0 box */ for (d = 0; d < dim; d++) /* for each dimension */ { hypre_IndexD(min_index, d) = hypre_min( hypre_IndexD(min_index, d), hypre_BoxIMinD(box, d)); hypre_IndexD(max_index, d) = hypre_max( hypre_IndexD(max_index, d), hypre_BoxIMaxD(box, d)); } }/*end for each box loop */ /* bounding box extents */ hypre_BoxSetExtents(bounding_box, min_index, max_index); }
int hypre_CreateComputeInfo( hypre_StructGrid *grid, hypre_StructStencil *stencil, hypre_ComputeInfo **compute_info_ptr ) { int ierr = 0; hypre_CommInfo *comm_info; hypre_BoxArrayArray *indt_boxes; hypre_BoxArrayArray *dept_boxes; hypre_BoxArray *boxes; hypre_BoxArray *cbox_array; hypre_Box *cbox; int i; #ifdef HYPRE_OVERLAP_COMM_COMP hypre_Box *rembox; hypre_Index *stencil_shape; int border[3][2] = {{0, 0}, {0, 0}, {0, 0}}; int cbox_array_size; int s, d; #endif /*------------------------------------------------------ * Extract needed grid info *------------------------------------------------------*/ boxes = hypre_StructGridBoxes(grid); /*------------------------------------------------------ * Get communication info *------------------------------------------------------*/ hypre_CreateCommInfoFromStencil(grid, stencil, &comm_info); #ifdef HYPRE_OVERLAP_COMM_COMP /*------------------------------------------------------ * Compute border info *------------------------------------------------------*/ stencil_shape = hypre_StructStencilShape(stencil); for (s = 0; s < hypre_StructStencilSize(stencil); s++) { for (d = 0; d < 3; d++) { i = hypre_IndexD(stencil_shape[s], d); if (i < 0) { border[d][0] = hypre_max(border[d][0], -i); } else if (i > 0) { border[d][1] = hypre_max(border[d][1], i); } } } /*------------------------------------------------------ * Set up the dependent boxes *------------------------------------------------------*/ dept_boxes = hypre_BoxArrayArrayCreate(hypre_BoxArraySize(boxes)); rembox = hypre_BoxCreate(); hypre_ForBoxI(i, boxes) { cbox_array = hypre_BoxArrayArrayBoxArray(dept_boxes, i); hypre_BoxArraySetSize(cbox_array, 6); hypre_CopyBox(hypre_BoxArrayBox(boxes, i), rembox); cbox_array_size = 0; for (d = 0; d < 3; d++) { if ( (hypre_BoxVolume(rembox)) && (border[d][0]) ) { cbox = hypre_BoxArrayBox(cbox_array, cbox_array_size); hypre_CopyBox(rembox, cbox); hypre_BoxIMaxD(cbox, d) = hypre_BoxIMinD(cbox, d) + border[d][0] - 1; hypre_BoxIMinD(rembox, d) = hypre_BoxIMinD(cbox, d) + border[d][0]; cbox_array_size++; } if ( (hypre_BoxVolume(rembox)) && (border[d][1]) ) { cbox = hypre_BoxArrayBox(cbox_array, cbox_array_size); hypre_CopyBox(rembox, cbox); hypre_BoxIMinD(cbox, d) = hypre_BoxIMaxD(cbox, d) - border[d][1] + 1; hypre_BoxIMaxD(rembox, d) = hypre_BoxIMaxD(cbox, d) - border[d][1]; cbox_array_size++; } } hypre_BoxArraySetSize(cbox_array, cbox_array_size); }
HYPRE_Int hypre_Maxwell_PhysBdy( hypre_SStructGrid **grid_l, HYPRE_Int num_levels, hypre_Index rfactors, HYPRE_Int ***BdryRanksl_ptr, HYPRE_Int **BdryRanksCntsl_ptr ) { MPI_Comm comm= (grid_l[0]-> comm); HYPRE_Int **BdryRanks_l; HYPRE_Int *BdryRanksCnts_l; HYPRE_Int *npts; HYPRE_Int *ranks, *upper_rank, *lower_rank; hypre_BoxManEntry *boxman_entry; hypre_SStructGrid *grid; hypre_SStructPGrid *pgrid; hypre_StructGrid *cell_fgrid, *cell_cgrid, *sgrid; hypre_BoxArrayArray ****bdry; hypre_BoxArrayArray *fbdry; hypre_BoxArrayArray *cbdry; hypre_BoxArray *box_array; hypre_BoxArray *fboxes, *cboxes; hypre_Box *fbox, *cbox; hypre_Box *box, *contract_fbox, rbox; hypre_Box intersect; HYPRE_Int **cbox_mapping, **fbox_mapping; HYPRE_Int **boxes_with_bdry; HYPRE_Int ndim, nvars; HYPRE_Int nboxes, nfboxes; HYPRE_Int boxi; hypre_Index zero_shift, upper_shift, lower_shift; hypre_Index loop_size, start, index, lindex; HYPRE_Int i, j, k, l, m, n, p; HYPRE_Int d; HYPRE_Int cnt; HYPRE_Int part= 0; /* NOTE, ASSUMING ONE PART */ HYPRE_Int matrix_type= HYPRE_PARCSR; HYPRE_Int myproc; HYPRE_Int ierr= 0; hypre_MPI_Comm_rank(comm, &myproc); ndim= hypre_SStructGridNDim(grid_l[0]); hypre_SetIndex3(zero_shift, 0, 0, 0); hypre_BoxInit(&intersect, ndim); /* bounding global ranks of this processor & allocate boundary box markers. */ upper_rank= hypre_CTAlloc(HYPRE_Int, num_levels); lower_rank= hypre_CTAlloc(HYPRE_Int, num_levels); boxes_with_bdry= hypre_TAlloc(HYPRE_Int *, num_levels); for (i= 0; i< num_levels; i++) { grid = grid_l[i]; lower_rank[i]= hypre_SStructGridStartRank(grid); /* note we are assuming only one part */ pgrid= hypre_SStructGridPGrid(grid, part); nvars= hypre_SStructPGridNVars(pgrid); sgrid= hypre_SStructPGridSGrid(pgrid, nvars-1); box_array= hypre_StructGridBoxes(sgrid); box = hypre_BoxArrayBox(box_array, hypre_BoxArraySize(box_array)-1); hypre_SStructGridBoxProcFindBoxManEntry(grid, part, nvars-1, hypre_BoxArraySize(box_array)-1, myproc, &boxman_entry); hypre_SStructBoxManEntryGetGlobalCSRank(boxman_entry, hypre_BoxIMax(box), &upper_rank[i]); sgrid= hypre_SStructPGridCellSGrid(pgrid); box_array= hypre_StructGridBoxes(sgrid); boxes_with_bdry[i]= hypre_CTAlloc(HYPRE_Int, hypre_BoxArraySize(box_array)); } /*----------------------------------------------------------------------------- * construct box_number mapping between levels, and offset strides because of * projection coarsening. Note: from the way the coarse boxes are created and * numbered, to determine the coarse box that matches the fbox, we need to * only check the tail end of the list of cboxes. In fact, given fbox_i, * if it's coarsened extents do not interesect with the first coarse box of the * tail end, then this fbox vanishes in the coarsening. * c/fbox_mapping gives the fine/coarse box mapping between two consecutive levels * of the multilevel hierarchy. *-----------------------------------------------------------------------------*/ if (num_levels > 1) { cbox_mapping= hypre_CTAlloc(HYPRE_Int *, num_levels); fbox_mapping= hypre_CTAlloc(HYPRE_Int *, num_levels); }