/* Code for manipulating distributed regular arrays in parallel. */ #include /*I "petscdmda.h" I*/ /* This allows the DMDA vectors to properly tell MATLAB their dimensions */ #if defined(PETSC_HAVE_MATLAB_ENGINE) #include /* MATLAB include file */ #include /* MATLAB include file */ EXTERN_C_BEGIN #undef __FUNCT__ #define __FUNCT__ "VecMatlabEnginePut_DA2d" PetscErrorCode VecMatlabEnginePut_DA2d(PetscObject obj,void *mengine) { PetscErrorCode ierr; PetscInt n,m; Vec vec = (Vec)obj; PetscScalar *array; mxArray *mat; DM da; PetscFunctionBegin; ierr = VecGetDM(vec, &da);CHKERRQ(ierr); if (!da) SETERRQ(((PetscObject)vec)->comm,PETSC_ERR_ARG_WRONGSTATE,"Vector not associated with a DMDA"); ierr = DMDAGetGhostCorners(da,0,0,0,&m,&n,0);CHKERRQ(ierr); ierr = VecGetArray(vec,&array);CHKERRQ(ierr); #if !defined(PETSC_USE_COMPLEX) mat = mxCreateDoubleMatrix(m,n,mxREAL); #else mat = mxCreateDoubleMatrix(m,n,mxCOMPLEX); #endif ierr = PetscMemcpy(mxGetPr(mat),array,n*m*sizeof(PetscScalar));CHKERRQ(ierr); ierr = PetscObjectName(obj);CHKERRQ(ierr); engPutVariable((Engine*)mengine,obj->name,mat); ierr = VecRestoreArray(vec,&array);CHKERRQ(ierr); PetscFunctionReturn(0); } EXTERN_C_END #endif #undef __FUNCT__ #define __FUNCT__ "DMCreateLocalVector_DA" PetscErrorCode DMCreateLocalVector_DA(DM da,Vec *g) { PetscErrorCode ierr; DM_DA *dd = (DM_DA*)da->data; PetscFunctionBegin; PetscValidHeaderSpecific(da,DM_CLASSID,1); PetscValidPointer(g,2); if (da->defaultSection) { ierr = DMCreateLocalVector_Section_Private(da,g);CHKERRQ(ierr); } else { ierr = VecCreate(PETSC_COMM_SELF,g);CHKERRQ(ierr); ierr = VecSetSizes(*g,dd->nlocal,PETSC_DETERMINE);CHKERRQ(ierr); ierr = VecSetBlockSize(*g,dd->w);CHKERRQ(ierr); ierr = VecSetType(*g,da->vectype);CHKERRQ(ierr); ierr = VecSetDM(*g, da);CHKERRQ(ierr); #if defined(PETSC_HAVE_MATLAB_ENGINE) if (dd->w == 1 && dd->dim == 2) { ierr = PetscObjectComposeFunctionDynamic((PetscObject)*g,"PetscMatlabEnginePut_C","VecMatlabEnginePut_DA2d",VecMatlabEnginePut_DA2d);CHKERRQ(ierr); } #endif } PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "DMDAGetNumCells" PetscErrorCode DMDAGetNumCells(DM dm, PetscInt *numCells) { DM_DA *da = (DM_DA*) dm->data; const PetscInt dim = da->dim; const PetscInt mx = (da->Xe - da->Xs)/da->w, my = da->Ye - da->Ys, mz = da->Ze - da->Zs; const PetscInt nC = (mx)*(dim > 1 ? (my)*(dim > 2 ? (mz) : 1) : 1); PetscFunctionBegin; if (numCells) { PetscValidIntPointer(numCells,2); *numCells = nC; } PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "DMDAGetNumVertices" PetscErrorCode DMDAGetNumVertices(DM dm, PetscInt *numVerticesX, PetscInt *numVerticesY, PetscInt *numVerticesZ, PetscInt *numVertices) { DM_DA *da = (DM_DA*) dm->data; const PetscInt dim = da->dim; const PetscInt mx = (da->Xe - da->Xs)/da->w, my = da->Ye - da->Ys, mz = da->Ze - da->Zs; const PetscInt nVx = mx+1; const PetscInt nVy = dim > 1 ? (my+1) : 1; const PetscInt nVz = dim > 2 ? (mz+1) : 1; const PetscInt nV = nVx*nVy*nVz; PetscFunctionBegin; if (numVerticesX) { PetscValidIntPointer(numVerticesX,2); *numVerticesX = nVx; } if (numVerticesY) { PetscValidIntPointer(numVerticesY,3); *numVerticesY = nVy; } if (numVerticesZ) { PetscValidIntPointer(numVerticesZ,4); *numVerticesZ = nVz; } if (numVertices) { PetscValidIntPointer(numVertices,5); *numVertices = nV; } PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "DMDAGetNumFaces" PetscErrorCode DMDAGetNumFaces(DM dm, PetscInt *numXFacesX, PetscInt *numXFaces, PetscInt *numYFacesY, PetscInt *numYFaces, PetscInt *numZFacesZ, PetscInt *numZFaces) { DM_DA *da = (DM_DA*) dm->data; const PetscInt dim = da->dim; const PetscInt mx = (da->Xe - da->Xs)/da->w, my = da->Ye - da->Ys, mz = da->Ze - da->Zs; const PetscInt nxF = (dim > 1 ? (my)*(dim > 2 ? (mz) : 1) : 1); const PetscInt nXF = (mx+1)*nxF; const PetscInt nyF = mx*(dim > 2 ? mz : 1); const PetscInt nYF = dim > 1 ? (my+1)*nyF : 0; const PetscInt nzF = mx*(dim > 1 ? my : 0); const PetscInt nZF = dim > 2 ? (mz+1)*nzF : 0; PetscFunctionBegin; if (numXFacesX) { PetscValidIntPointer(numXFacesX,2); *numXFacesX = nxF; } if (numXFaces) { PetscValidIntPointer(numXFaces,3); *numXFaces = nXF; } if (numYFacesY) { PetscValidIntPointer(numYFacesY,4); *numYFacesY = nyF; } if (numYFaces) { PetscValidIntPointer(numYFaces,5); *numYFaces = nYF; } if (numZFacesZ) { PetscValidIntPointer(numZFacesZ,6); *numZFacesZ = nzF; } if (numZFaces) { PetscValidIntPointer(numZFaces,7); *numZFaces = nZF; } PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "DMDAGetHeightStratum" PetscErrorCode DMDAGetHeightStratum(DM dm, PetscInt height, PetscInt *pStart, PetscInt *pEnd) { DM_DA *da = (DM_DA*) dm->data; const PetscInt dim = da->dim; PetscInt nC, nV, nXF, nYF, nZF; PetscErrorCode ierr; PetscFunctionBegin; if (pStart) PetscValidIntPointer(pStart,3); if (pEnd) PetscValidIntPointer(pEnd,4); ierr = DMDAGetNumCells(dm, &nC);CHKERRQ(ierr); ierr = DMDAGetNumVertices(dm, PETSC_NULL, PETSC_NULL, PETSC_NULL, &nV);CHKERRQ(ierr); ierr = DMDAGetNumFaces(dm, PETSC_NULL, &nXF, PETSC_NULL, &nYF, PETSC_NULL, &nZF);CHKERRQ(ierr); if (height == 0) { /* Cells */ if (pStart) *pStart = 0; if (pEnd) *pEnd = nC; } else if (height == 1) { /* Faces */ if (pStart) *pStart = nC+nV; if (pEnd) *pEnd = nC+nV+nXF+nYF+nZF; } else if (height == dim) { /* Vertices */ if (pStart) *pStart = nC; if (pEnd) *pEnd = nC+nV; } else if (height < 0) { /* All points */ if (pStart) *pStart = 0; if (pEnd) *pEnd = nC+nV+nXF+nYF+nZF; } else SETERRQ1(((PetscObject) dm)->comm, PETSC_ERR_ARG_OUTOFRANGE, "No points of height %d in the DA", height); PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "DMDACreateSection" /*@C DMDACreateSection - Create a PetscSection inside the DMDA that describes data layout. This allows multiple fields with different numbers of dofs on vertices, cells, and faces in each direction. Input Parameters: + dm- The DMDA . numFields - The number of fields . numComp - The number of components in each field, or PETSC_NULL for 1 . numVertexDof - The number of dofs per vertex for each field, or PETSC_NULL . numFaceDof - The number of dofs per face for each field and direction, or PETSC_NULL - numCellDof - The number of dofs per cell for each field, or PETSC_NULL Level: developer Note: The default DMDA numbering is as follows: - Cells: [0, nC) - Vertices: [nC, nC+nV) - X-Faces: [nC+nV, nC+nV+nXF) normal is +- x-dir - Y-Faces: [nC+nV+nXF, nC+nV+nXF+nYF) normal is +- y-dir - Z-Faces: [nC+nV+nXF+nYF, nC+nV+nXF+nYF+nZF) normal is +- z-dir We interpret the default DMDA partition as a cell partition, and the data assignment as a cell assignment. @*/ PetscErrorCode DMDACreateSection(DM dm, PetscInt numComp[], PetscInt numVertexDof[], PetscInt numFaceDof[], PetscInt numCellDof[]) { DM_DA *da = (DM_DA*) dm->data; const PetscInt dim = da->dim; PetscInt numFields, numVertexTotDof = 0, numCellTotDof = 0, numFaceTotDof[3] = {0, 0, 0}; PetscSF sf; PetscMPIInt rank; const PetscMPIInt *neighbors; PetscInt *localPoints; PetscSFNode *remotePoints; PetscInt nleaves = 0, nleavesCheck = 0, nL = 0; PetscInt nC, nVx, nVy, nVz, nV, nxF, nXF, nyF, nYF, nzF, nZF; PetscInt pStart, pEnd, cStart, cEnd, vStart, vEnd, fStart, fEnd, xfStart, xfEnd, yfStart, yfEnd, zfStart, zfEnd; PetscInt f, v, c, xf, yf, zf, xn, yn, zn; PetscErrorCode ierr; PetscFunctionBegin; PetscValidHeaderSpecific(dm, DM_CLASSID, 1); ierr = MPI_Comm_rank(((PetscObject) dm)->comm, &rank);CHKERRQ(ierr); ierr = DMDAGetNumCells(dm, &nC);CHKERRQ(ierr); ierr = DMDAGetNumVertices(dm, &nVx, &nVy, &nVz, &nV);CHKERRQ(ierr); ierr = DMDAGetNumFaces(dm, &nxF, &nXF, &nyF, &nYF, &nzF, &nZF);CHKERRQ(ierr); ierr = DMDAGetHeightStratum(dm, -1, &pStart, &pEnd);CHKERRQ(ierr); ierr = DMDAGetHeightStratum(dm, 0, &cStart, &cEnd);CHKERRQ(ierr); ierr = DMDAGetHeightStratum(dm, 1, &fStart, &fEnd);CHKERRQ(ierr); ierr = DMDAGetHeightStratum(dm, dim, &vStart, &vEnd);CHKERRQ(ierr); xfStart = vEnd; xfEnd = xfStart+nXF; yfStart = xfEnd; yfEnd = yfStart+nYF; zfStart = yfEnd; zfEnd = zfStart+nZF; if (zfEnd != fEnd) SETERRQ2(((PetscObject) dm)->comm, PETSC_ERR_PLIB, "Invalid face end %d, should be %d", zfEnd, fEnd); /* Create local section */ ierr = DMDAGetInfo(dm, 0,0,0,0,0,0,0, &numFields, 0,0,0,0,0);CHKERRQ(ierr); for (f = 0; f < numFields; ++f) { if (numVertexDof) numVertexTotDof += numVertexDof[f]; if (numCellDof) numCellTotDof += numCellDof[f]; if (numFaceDof) { numFaceTotDof[0] += numFaceDof[f*dim+0]; numFaceTotDof[1] += dim > 1 ? numFaceDof[f*dim+1] : 0; numFaceTotDof[2] += dim > 2 ? numFaceDof[f*dim+2] : 0; } } ierr = PetscSectionCreate(((PetscObject) dm)->comm, &dm->defaultSection);CHKERRQ(ierr); if (numFields > 1) { ierr = PetscSectionSetNumFields(dm->defaultSection, numFields);CHKERRQ(ierr); for (f = 0; f < numFields; ++f) { const char *name; ierr = DMDAGetFieldName(dm, f, &name);CHKERRQ(ierr); ierr = PetscSectionSetFieldName(dm->defaultSection, f, name);CHKERRQ(ierr); if (numComp) { ierr = PetscSectionSetFieldComponents(dm->defaultSection, f, numComp[f]);CHKERRQ(ierr); } } } else { numFields = 0; } ierr = PetscSectionSetChart(dm->defaultSection, pStart, pEnd);CHKERRQ(ierr); if (numVertexDof) { for (v = vStart; v < vEnd; ++v) { for (f = 0; f < numFields; ++f) { ierr = PetscSectionSetFieldDof(dm->defaultSection, v, f, numVertexDof[f]);CHKERRQ(ierr); } ierr = PetscSectionSetDof(dm->defaultSection, v, numVertexTotDof);CHKERRQ(ierr); } } if (numFaceDof) { for (xf = xfStart; xf < xfEnd; ++xf) { for (f = 0; f < numFields; ++f) { ierr = PetscSectionSetFieldDof(dm->defaultSection, xf, f, numFaceDof[f*dim+0]);CHKERRQ(ierr); } ierr = PetscSectionSetDof(dm->defaultSection, xf, numFaceTotDof[0]);CHKERRQ(ierr); } for (yf = yfStart; yf < yfEnd; ++yf) { for (f = 0; f < numFields; ++f) { ierr = PetscSectionSetFieldDof(dm->defaultSection, yf, f, numFaceDof[f*dim+1]);CHKERRQ(ierr); } ierr = PetscSectionSetDof(dm->defaultSection, yf, numFaceTotDof[1]);CHKERRQ(ierr); } for (zf = zfStart; zf < zfEnd; ++zf) { for (f = 0; f < numFields; ++f) { ierr = PetscSectionSetFieldDof(dm->defaultSection, zf, f, numFaceDof[f*dim+2]);CHKERRQ(ierr); } ierr = PetscSectionSetDof(dm->defaultSection, zf, numFaceTotDof[2]);CHKERRQ(ierr); } } if (numCellDof) { for (c = cStart; c < cEnd; ++c) { for (f = 0; f < numFields; ++f) { ierr = PetscSectionSetFieldDof(dm->defaultSection, c, f, numCellDof[f]);CHKERRQ(ierr); } ierr = PetscSectionSetDof(dm->defaultSection, c, numCellTotDof);CHKERRQ(ierr); } } ierr = PetscSectionSetUp(dm->defaultSection);CHKERRQ(ierr); /* Create mesh point SF */ ierr = DMDAGetNeighbors(dm, &neighbors);CHKERRQ(ierr); for (zn = 0; zn < (dim > 2 ? 3 : 1); ++zn) { for (yn = 0; yn < (dim > 1 ? 3 : 1); ++yn) { for (xn = 0; xn < 3; ++xn) { const PetscInt xp = xn-1, yp = dim > 1 ? yn-1 : 0, zp = dim > 2 ? zn-1 : 0; const PetscInt neighbor = neighbors[(zn*3+yn)*3+xn]; if (neighbor >= 0 && neighbor < rank) { nleaves += (!xp ? nVx : 1) * (!yp ? nVy : 1) * (!zp ? nVz : 1); /* vertices */ if (xp && !yp && !zp) { nleaves += nxF; /* x faces */ } else if (yp && !zp && !xp) { nleaves += nyF; /* y faces */ } else if (zp && !xp && !yp) { nleaves += nzF; /* z faces */ } } } } } ierr = PetscMalloc2(nleaves,PetscInt,&localPoints,nleaves,PetscSFNode,&remotePoints);CHKERRQ(ierr); for (zn = 0; zn < (dim > 2 ? 3 : 1); ++zn) { for (yn = 0; yn < (dim > 1 ? 3 : 1); ++yn) { for (xn = 0; xn < 3; ++xn) { const PetscInt xp = xn-1, yp = dim > 1 ? yn-1 : 0, zp = dim > 2 ? zn-1 : 0; const PetscInt neighbor = neighbors[(zn*3+yn)*3+xn]; PetscInt xv, yv, zv; if (neighbor >= 0 && neighbor < rank) { if (xp < 0) { /* left */ if (yp < 0) { /* bottom */ if (zp < 0) { /* back */ const PetscInt localVertex = ( 0*nVy + 0)*nVx + 0 + nC; const PetscInt remoteVertex = ((nVz-1)*nVy + nVy-1)*nVx + nVx-1 + nC; /* TODO: Correct this for neighbor sizes */ nleavesCheck += 1; /* left bottom back vertex */ localPoints[nL] = localVertex; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteVertex; ++nL; } else if (zp > 0) { /* front */ const PetscInt localVertex = ((nVz-1)*nVy + 0)*nVx + 0 + nC; const PetscInt remoteVertex = ( 0*nVy + nVy-1)*nVx + nVx-1 + nC; /* TODO: Correct this for neighbor sizes */ nleavesCheck += 1; /* left bottom front vertex */ localPoints[nL] = localVertex; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteVertex; ++nL; } else { nleavesCheck += nVz; /* left bottom vertices */ for (zv = 0; zv < nVz; ++zv, ++nL) { const PetscInt localVertex = (zv*nVy + 0)*nVx + 0 + nC; const PetscInt remoteVertex = (zv*nVy + nVy-1)*nVx + nVx-1 + nC; /* TODO: Correct this for neighbor sizes */ localPoints[nL] = localVertex; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteVertex; } } } else if (yp > 0) { /* top */ if (zp < 0) { /* back */ const PetscInt localVertex = ( 0*nVy + nVy-1)*nVx + 0 + nC; const PetscInt remoteVertex = ((nVz-1)*nVy + 0)*nVx + nVx-1 + nC; /* TODO: Correct this for neighbor sizes */ nleavesCheck += 1; /* left top back vertex */ localPoints[nL] = localVertex; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteVertex; ++nL; } else if (zp > 0) { /* front */ const PetscInt localVertex = ((nVz-1)*nVy + nVy-1)*nVx + 0 + nC; const PetscInt remoteVertex = ( 0*nVy + 0)*nVx + nVx-1 + nC; /* TODO: Correct this for neighbor sizes */ nleavesCheck += 1; /* left top front vertex */ localPoints[nL] = localVertex; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteVertex; ++nL; } else { nleavesCheck += nVz; /* left top vertices */ for (zv = 0; zv < nVz; ++zv, ++nL) { const PetscInt localVertex = (zv*nVy + nVy-1)*nVx + 0 + nC; const PetscInt remoteVertex = (zv*nVy + 0)*nVx + nVx-1 + nC; /* TODO: Correct this for neighbor sizes */ localPoints[nL] = localVertex; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteVertex; } } } else { if (zp < 0) { /* back */ nleavesCheck += nVy; /* left back vertices */ for (yv = 0; yv < nVy; ++yv, ++nL) { const PetscInt localVertex = ( 0*nVy + yv)*nVx + 0 + nC; const PetscInt remoteVertex = ((nVz-1)*nVy + yv)*nVx + nVx-1 + nC; /* TODO: Correct this for neighbor sizes */ localPoints[nL] = localVertex; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteVertex; } } else if (zp > 0) { /* front */ nleavesCheck += nVy; /* left front vertices */ for (yv = 0; yv < nVy; ++yv, ++nL) { const PetscInt localVertex = ((nVz-1)*nVy + yv)*nVx + 0 + nC; const PetscInt remoteVertex = ( 0*nVy + yv)*nVx + nVx-1 + nC; /* TODO: Correct this for neighbor sizes */ localPoints[nL] = localVertex; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteVertex; } } else { nleavesCheck += nVy*nVz; /* left vertices */ for (zv = 0; zv < nVz; ++zv) { for (yv = 0; yv < nVy; ++yv, ++nL) { const PetscInt localVertex = (zv*nVy + yv)*nVx + 0 + nC; const PetscInt remoteVertex = (zv*nVy + yv)*nVx + nVx-1 + nC; /* TODO: Correct this for neighbor sizes */ localPoints[nL] = localVertex; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteVertex; } } nleavesCheck += nxF; /* left faces */ for (xf = 0; xf < nxF; ++xf, ++nL) { /* THIS IS WRONG */ const PetscInt localFace = 0 + nC+nV; const PetscInt remoteFace = 0 + nC+nV; localPoints[nL] = localFace; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteFace; } } } } else if (xp > 0) { /* right */ if (yp < 0) { /* bottom */ if (zp < 0) { /* back */ const PetscInt localVertex = ( 0*nVy + 0)*nVx + nVx-1 + nC; const PetscInt remoteVertex = ((nVz-1)*nVy + nVy-1)*nVx + 0 + nC; /* TODO: Correct this for neighbor sizes */ nleavesCheck += 1; /* right bottom back vertex */ localPoints[nL] = localVertex; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteVertex; ++nL; } else if (zp > 0) { /* front */ const PetscInt localVertex = ((nVz-1)*nVy + 0)*nVx + nVx-1 + nC; const PetscInt remoteVertex = ( 0*nVy + nVy-1)*nVx + 0 + nC; /* TODO: Correct this for neighbor sizes */ nleavesCheck += 1; /* right bottom front vertex */ localPoints[nL] = localVertex; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteVertex; ++nL; } else { nleavesCheck += nVz; /* right bottom vertices */ for (zv = 0; zv < nVz; ++zv, ++nL) { const PetscInt localVertex = (zv*nVy + 0)*nVx + nVx-1 + nC; const PetscInt remoteVertex = (zv*nVy + nVy-1)*nVx + 0 + nC; /* TODO: Correct this for neighbor sizes */ localPoints[nL] = localVertex; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteVertex; } } } else if (yp > 0) { /* top */ if (zp < 0) { /* back */ const PetscInt localVertex = ( 0*nVy + nVy-1)*nVx + nVx-1 + nC; const PetscInt remoteVertex = ((nVz-1)*nVy + 0)*nVx + 0 + nC; /* TODO: Correct this for neighbor sizes */ nleavesCheck += 1; /* right top back vertex */ localPoints[nL] = localVertex; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteVertex; ++nL; } else if (zp > 0) { /* front */ const PetscInt localVertex = ((nVz-1)*nVy + nVy-1)*nVx + nVx-1 + nC; const PetscInt remoteVertex = ( 0*nVy + 0)*nVx + 0 + nC; /* TODO: Correct this for neighbor sizes */ nleavesCheck += 1; /* right top front vertex */ localPoints[nL] = localVertex; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteVertex; ++nL; } else { nleavesCheck += nVz; /* right top vertices */ for (zv = 0; zv < nVz; ++zv, ++nL) { const PetscInt localVertex = (zv*nVy + nVy-1)*nVx + nVx-1 + nC; const PetscInt remoteVertex = (zv*nVy + 0)*nVx + 0 + nC; /* TODO: Correct this for neighbor sizes */ localPoints[nL] = localVertex; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteVertex; } } } else { if (zp < 0) { /* back */ nleavesCheck += nVy; /* right back vertices */ for (yv = 0; yv < nVy; ++yv, ++nL) { const PetscInt localVertex = ( 0*nVy + yv)*nVx + nVx-1 + nC; const PetscInt remoteVertex = ((nVz-1)*nVy + yv)*nVx + 0 + nC; /* TODO: Correct this for neighbor sizes */ localPoints[nL] = localVertex; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteVertex; } } else if (zp > 0) { /* front */ nleavesCheck += nVy; /* right front vertices */ for (yv = 0; yv < nVy; ++yv, ++nL) { const PetscInt localVertex = ((nVz-1)*nVy + yv)*nVx + nVx-1 + nC; const PetscInt remoteVertex = ( 0*nVy + yv)*nVx + 0 + nC; /* TODO: Correct this for neighbor sizes */ localPoints[nL] = localVertex; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteVertex; } } else { nleavesCheck += nVy*nVz; /* right vertices */ for (zv = 0; zv < nVz; ++zv) { for (yv = 0; yv < nVy; ++yv, ++nL) { const PetscInt localVertex = (zv*nVy + yv)*nVx + nVx-1 + nC; const PetscInt remoteVertex = (zv*nVy + yv)*nVx + 0 + nC; /* TODO: Correct this for neighbor sizes */ localPoints[nL] = localVertex; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteVertex; } } nleavesCheck += nxF; /* right faces */ for (xf = 0; xf < nxF; ++xf, ++nL) { /* THIS IS WRONG */ const PetscInt localFace = 0 + nC+nV; const PetscInt remoteFace = 0 + nC+nV; localPoints[nL] = localFace; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteFace; } } } } else { if (yp < 0) { /* bottom */ if (zp < 0) { /* back */ nleavesCheck += nVx; /* bottom back vertices */ for (xv = 0; xv < nVx; ++xv, ++nL) { const PetscInt localVertex = ( 0*nVy + 0)*nVx + xv + nC; const PetscInt remoteVertex = ((nVz-1)*nVy + nVy-1)*nVx + xv + nC; /* TODO: Correct this for neighbor sizes */ localPoints[nL] = localVertex; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteVertex; } } else if (zp > 0) { /* front */ nleavesCheck += nVx; /* bottom front vertices */ for (xv = 0; xv < nVx; ++xv, ++nL) { const PetscInt localVertex = ((nVz-1)*nVy + 0)*nVx + xv + nC; const PetscInt remoteVertex = ( 0*nVy + nVy-1)*nVx + xv + nC; /* TODO: Correct this for neighbor sizes */ localPoints[nL] = localVertex; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteVertex; } } else { nleavesCheck += nVx*nVz; /* bottom vertices */ for (zv = 0; zv < nVz; ++zv) { for (xv = 0; xv < nVx; ++xv, ++nL) { const PetscInt localVertex = (zv*nVy + 0)*nVx + xv + nC; const PetscInt remoteVertex = (zv*nVy + nVy-1)*nVx + xv + nC; /* TODO: Correct this for neighbor sizes */ localPoints[nL] = localVertex; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteVertex; } } nleavesCheck += nyF; /* bottom faces */ for (yf = 0; yf < nyF; ++yf, ++nL) { /* THIS IS WRONG */ const PetscInt localFace = 0 + nC+nV; const PetscInt remoteFace = 0 + nC+nV; localPoints[nL] = localFace; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteFace; } } } else if (yp > 0) { /* top */ if (zp < 0) { /* back */ nleavesCheck += nVx; /* top back vertices */ for (xv = 0; xv < nVx; ++xv, ++nL) { const PetscInt localVertex = ( 0*nVy + nVy-1)*nVx + xv + nC; const PetscInt remoteVertex = ((nVz-1)*nVy + 0)*nVx + xv + nC; /* TODO: Correct this for neighbor sizes */ localPoints[nL] = localVertex; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteVertex; } } else if (zp > 0) { /* front */ nleavesCheck += nVx; /* top front vertices */ for (xv = 0; xv < nVx; ++xv, ++nL) { const PetscInt localVertex = ((nVz-1)*nVy + nVy-1)*nVx + xv + nC; const PetscInt remoteVertex = ( 0*nVy + 0)*nVx + xv + nC; /* TODO: Correct this for neighbor sizes */ localPoints[nL] = localVertex; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteVertex; } } else { nleavesCheck += nVx*nVz; /* top vertices */ for (zv = 0; zv < nVz; ++zv) { for (xv = 0; xv < nVx; ++xv, ++nL) { const PetscInt localVertex = (zv*nVy + nVy-1)*nVx + xv + nC; const PetscInt remoteVertex = (zv*nVy + 0)*nVx + xv + nC; /* TODO: Correct this for neighbor sizes */ localPoints[nL] = localVertex; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteVertex; } } nleavesCheck += nyF; /* top faces */ for (yf = 0; yf < nyF; ++yf, ++nL) { /* THIS IS WRONG */ const PetscInt localFace = 0 + nC+nV; const PetscInt remoteFace = 0 + nC+nV; localPoints[nL] = localFace; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteFace; } } } else { if (zp < 0) { /* back */ nleavesCheck += nVx*nVy; /* back vertices */ for (yv = 0; yv < nVy; ++yv) { for (xv = 0; xv < nVx; ++xv, ++nL) { const PetscInt localVertex = ( 0*nVy + yv)*nVx + xv + nC; const PetscInt remoteVertex = ((nVz-1)*nVy + yv)*nVx + xv + nC; /* TODO: Correct this for neighbor sizes */ localPoints[nL] = localVertex; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteVertex; } } nleavesCheck += nzF; /* back faces */ for (zf = 0; zf < nzF; ++zf, ++nL) { /* THIS IS WRONG */ const PetscInt localFace = 0 + nC+nV; const PetscInt remoteFace = 0 + nC+nV; localPoints[nL] = localFace; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteFace; } } else if (zp > 0) { /* front */ nleavesCheck += nVx*nVy; /* front vertices */ for (yv = 0; yv < nVy; ++yv) { for (xv = 0; xv < nVx; ++xv, ++nL) { const PetscInt localVertex = ((nVz-1)*nVy + yv)*nVx + xv + nC; const PetscInt remoteVertex = ( 0*nVy + yv)*nVx + xv + nC; /* TODO: Correct this for neighbor sizes */ localPoints[nL] = localVertex; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteVertex; } } nleavesCheck += nzF; /* front faces */ for (zf = 0; zf < nzF; ++zf, ++nL) { /* THIS IS WRONG */ const PetscInt localFace = 0 + nC+nV; const PetscInt remoteFace = 0 + nC+nV; localPoints[nL] = localFace; remotePoints[nL].rank = neighbor; remotePoints[nL].index = remoteFace; } } else { /* Nothing is shared from the interior */ } } } } } } } /* TODO: Remove duplication in leaf determination */ if (nleaves != nleavesCheck) SETERRQ2(((PetscObject) dm)->comm, PETSC_ERR_PLIB, "The number of leaves %d did not match the number of remote leaves %d", nleaves, nleavesCheck); ierr = PetscSFCreate(((PetscObject) dm)->comm, &sf);CHKERRQ(ierr); ierr = PetscSFSetGraph(sf, pEnd, nleaves, localPoints, PETSC_OWN_POINTER, remotePoints, PETSC_OWN_POINTER);CHKERRQ(ierr); /* Create global section */ ierr = PetscSectionCreateGlobalSection(dm->defaultSection, sf, PETSC_FALSE, &dm->defaultGlobalSection);CHKERRQ(ierr); ierr = PetscSFDestroy(&sf);CHKERRQ(ierr); /* Create default SF */ ierr = DMCreateDefaultSF(dm, dm->defaultSection, dm->defaultGlobalSection);CHKERRQ(ierr); PetscFunctionReturn(0); } /* ------------------------------------------------------------------- */ #undef __FUNCT__ #define __FUNCT__ "DMDAGetArray" /*@C DMDAGetArray - Gets a work array for a DMDA Input Parameter: + da - information about my local patch - ghosted - do you want arrays for the ghosted or nonghosted patch Output Parameters: . vptr - array data structured Note: The vector values are NOT initialized and may have garbage in them, so you may need to zero them. Level: advanced .seealso: DMDARestoreArray() @*/ PetscErrorCode DMDAGetArray(DM da,PetscBool ghosted,void *vptr) { PetscErrorCode ierr; PetscInt j,i,xs,ys,xm,ym,zs,zm; char *iarray_start; void **iptr = (void**)vptr; DM_DA *dd = (DM_DA*)da->data; PetscFunctionBegin; PetscValidHeaderSpecific(da,DM_CLASSID,1); if (ghosted) { for (i=0; iarrayghostedin[i]) { *iptr = dd->arrayghostedin[i]; iarray_start = (char*)dd->startghostedin[i]; dd->arrayghostedin[i] = PETSC_NULL; dd->startghostedin[i] = PETSC_NULL; goto done; } } xs = dd->Xs; ys = dd->Ys; zs = dd->Zs; xm = dd->Xe-dd->Xs; ym = dd->Ye-dd->Ys; zm = dd->Ze-dd->Zs; } else { for (i=0; iarrayin[i]) { *iptr = dd->arrayin[i]; iarray_start = (char*)dd->startin[i]; dd->arrayin[i] = PETSC_NULL; dd->startin[i] = PETSC_NULL; goto done; } } xs = dd->xs; ys = dd->ys; zs = dd->zs; xm = dd->xe-dd->xs; ym = dd->ye-dd->ys; zm = dd->ze-dd->zs; } switch (dd->dim) { case 1: { void *ptr; ierr = PetscMalloc(xm*sizeof(PetscScalar),&iarray_start);CHKERRQ(ierr); ptr = (void*)(iarray_start - xs*sizeof(PetscScalar)); *iptr = (void*)ptr; break; } case 2: { void **ptr; ierr = PetscMalloc((ym+1)*sizeof(void*)+xm*ym*sizeof(PetscScalar),&iarray_start);CHKERRQ(ierr); ptr = (void**)(iarray_start + xm*ym*sizeof(PetscScalar) - ys*sizeof(void*)); for (j=ys; jcomm,PETSC_ERR_SUP,"Dimension %D not supported",dd->dim); } done: /* add arrays to the checked out list */ if (ghosted) { for (i=0; iarrayghostedout[i]) { dd->arrayghostedout[i] = *iptr; dd->startghostedout[i] = iarray_start; break; } } } else { for (i=0; iarrayout[i]) { dd->arrayout[i] = *iptr; dd->startout[i] = iarray_start; break; } } } PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "DMDARestoreArray" /*@C DMDARestoreArray - Restores an array of derivative types for a DMDA Input Parameter: + da - information about my local patch . ghosted - do you want arrays for the ghosted or nonghosted patch - vptr - array data structured to be passed to ad_FormFunctionLocal() Level: advanced .seealso: DMDAGetArray() @*/ PetscErrorCode DMDARestoreArray(DM da,PetscBool ghosted,void *vptr) { PetscInt i; void **iptr = (void**)vptr,*iarray_start = 0; DM_DA *dd = (DM_DA*)da->data; PetscFunctionBegin; PetscValidHeaderSpecific(da,DM_CLASSID,1); if (ghosted) { for (i=0; iarrayghostedout[i] == *iptr) { iarray_start = dd->startghostedout[i]; dd->arrayghostedout[i] = PETSC_NULL; dd->startghostedout[i] = PETSC_NULL; break; } } for (i=0; iarrayghostedin[i]) { dd->arrayghostedin[i] = *iptr; dd->startghostedin[i] = iarray_start; break; } } } else { for (i=0; iarrayout[i] == *iptr) { iarray_start = dd->startout[i]; dd->arrayout[i] = PETSC_NULL; dd->startout[i] = PETSC_NULL; break; } } for (i=0; iarrayin[i]) { dd->arrayin[i] = *iptr; dd->startin[i] = iarray_start; break; } } } PetscFunctionReturn(0); }