/*$Id: aij.c,v 1.385 2001/09/07 20:09:22 bsmith Exp $*/ /* Defines the basic matrix operations for the AIJ (compressed row) matrix storage format. */ #include "src/mat/impls/aij/seq/aij.h" /*I "petscmat.h" I*/ #include "src/vec/vecimpl.h" #include "src/inline/spops.h" #include "src/inline/dot.h" #include "petscbt.h" EXTERN int MatToSymmetricIJ_SeqAIJ(int,int*,int*,int,int,int**,int**); #undef __FUNCT__ #define __FUNCT__ "MatGetRowIJ_SeqAIJ" int MatGetRowIJ_SeqAIJ(Mat A,int oshift,PetscTruth symmetric,int *m,int **ia,int **ja,PetscTruth *done) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; int ierr,i,ishift; PetscFunctionBegin; *m = A->m; if (!ia) PetscFunctionReturn(0); ishift = a->indexshift; if (symmetric && !A->structurally_symmetric) { ierr = MatToSymmetricIJ_SeqAIJ(A->m,a->i,a->j,ishift,oshift,ia,ja);CHKERRQ(ierr); } else if (oshift == 0 && ishift == -1) { int nz = a->i[A->m] - 1; /* malloc space and subtract 1 from i and j indices */ ierr = PetscMalloc((A->m+1)*sizeof(int),ia);CHKERRQ(ierr); ierr = PetscMalloc((nz+1)*sizeof(int),ja);CHKERRQ(ierr); for (i=0; ij[i] - 1; for (i=0; im+1; i++) (*ia)[i] = a->i[i] - 1; } else if (oshift == 1 && ishift == 0) { int nz = a->i[A->m]; /* malloc space and add 1 to i and j indices */ ierr = PetscMalloc((A->m+1)*sizeof(int),ia);CHKERRQ(ierr); ierr = PetscMalloc((nz+1)*sizeof(int),ja);CHKERRQ(ierr); for (i=0; ij[i] + 1; for (i=0; im+1; i++) (*ia)[i] = a->i[i] + 1; } else { *ia = a->i; *ja = a->j; } PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatRestoreRowIJ_SeqAIJ" int MatRestoreRowIJ_SeqAIJ(Mat A,int oshift,PetscTruth symmetric,int *n,int **ia,int **ja,PetscTruth *done) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; int ishift = a->indexshift,ierr; PetscFunctionBegin; if (!ia) PetscFunctionReturn(0); if ((symmetric && !A->structurally_symmetric) || (oshift == 0 && ishift == -1) || (oshift == 1 && ishift == 0)) { ierr = PetscFree(*ia);CHKERRQ(ierr); ierr = PetscFree(*ja);CHKERRQ(ierr); } PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatGetColumnIJ_SeqAIJ" int MatGetColumnIJ_SeqAIJ(Mat A,int oshift,PetscTruth symmetric,int *nn,int **ia,int **ja,PetscTruth *done) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; int ierr,i,ishift = a->indexshift,*collengths,*cia,*cja,n = A->n,m = A->m; int nz = a->i[m]+ishift,row,*jj,mr,col; PetscFunctionBegin; *nn = A->n; if (!ia) PetscFunctionReturn(0); if (symmetric) { ierr = MatToSymmetricIJ_SeqAIJ(A->m,a->i,a->j,ishift,oshift,ia,ja);CHKERRQ(ierr); } else { ierr = PetscMalloc((n+1)*sizeof(int),&collengths);CHKERRQ(ierr); ierr = PetscMemzero(collengths,n*sizeof(int));CHKERRQ(ierr); ierr = PetscMalloc((n+1)*sizeof(int),&cia);CHKERRQ(ierr); ierr = PetscMalloc((nz+1)*sizeof(int),&cja);CHKERRQ(ierr); jj = a->j; for (i=0; ij; for (row=0; rowi[row+1] - a->i[row]; for (i=0; idata; int *rp,k,low,high,t,ii,row,nrow,i,col,l,rmax,N,sorted = a->sorted; int *imax = a->imax,*ai = a->i,*ailen = a->ilen; int *aj = a->j,nonew = a->nonew,shift = a->indexshift,ierr; PetscScalar *ap,value,*aa = a->a; PetscTruth ignorezeroentries = ((a->ignorezeroentries && is == ADD_VALUES) ? PETSC_TRUE:PETSC_FALSE); PetscTruth roworiented = a->roworiented; PetscFunctionBegin; for (k=0; k= A->m) SETERRQ2(PETSC_ERR_ARG_OUTOFRANGE,"Row too large: row %d max %d",row,A->m); #endif rp = aj + ai[row] + shift; ap = aa + ai[row] + shift; rmax = imax[row]; nrow = ailen[row]; low = 0; for (l=0; l= A->n) SETERRQ2(PETSC_ERR_ARG_OUTOFRANGE,"Column too large: col %d max %d",in[l],A->n); #endif col = in[l] - shift; if (roworiented) { value = v[l + k*n]; } else { value = v[k + l*m]; } if (value == 0.0 && ignorezeroentries) continue; if (!sorted) low = 0; high = nrow; while (high-low > 5) { t = (low+high)/2; if (rp[t] > col) high = t; else low = t; } for (i=low; i col) break; if (rp[i] == col) { if (is == ADD_VALUES) ap[i] += value; else ap[i] = value; goto noinsert; } } if (nonew == 1) goto noinsert; else if (nonew == -1) SETERRQ2(PETSC_ERR_ARG_OUTOFRANGE,"Inserting a new nonzero at (%d,%d) in the matrix",row,col); if (nrow >= rmax) { /* there is no extra room in row, therefore enlarge */ int new_nz = ai[A->m] + CHUNKSIZE,*new_i,*new_j; size_t len; PetscScalar *new_a; if (nonew == -2) SETERRQ2(PETSC_ERR_ARG_OUTOFRANGE,"Inserting a new nonzero at (%d,%d) in the matrix requiring new malloc()",row,col); /* malloc new storage space */ len = ((size_t) new_nz)*(sizeof(int)+sizeof(PetscScalar))+(A->m+1)*sizeof(int); ierr = PetscMalloc(len,&new_a);CHKERRQ(ierr); new_j = (int*)(new_a + new_nz); new_i = new_j + new_nz; /* copy over old data into new slots */ for (ii=0; iim+1; ii++) {new_i[ii] = ai[ii]+CHUNKSIZE;} ierr = PetscMemcpy(new_j,aj,(ai[row]+nrow+shift)*sizeof(int));CHKERRQ(ierr); len = (((size_t) new_nz) - CHUNKSIZE - ai[row] - nrow - shift); ierr = PetscMemcpy(new_j+ai[row]+shift+nrow+CHUNKSIZE,aj+ai[row]+shift+nrow,len*sizeof(int));CHKERRQ(ierr); ierr = PetscMemcpy(new_a,aa,(((size_t) ai[row])+nrow+shift)*sizeof(PetscScalar));CHKERRQ(ierr); ierr = PetscMemcpy(new_a+ai[row]+shift+nrow+CHUNKSIZE,aa+ai[row]+shift+nrow,len*sizeof(PetscScalar));CHKERRQ(ierr); /* free up old matrix storage */ ierr = PetscFree(a->a);CHKERRQ(ierr); if (!a->singlemalloc) { ierr = PetscFree(a->i);CHKERRQ(ierr); ierr = PetscFree(a->j);CHKERRQ(ierr); } aa = a->a = new_a; ai = a->i = new_i; aj = a->j = new_j; a->singlemalloc = PETSC_TRUE; rp = aj + ai[row] + shift; ap = aa + ai[row] + shift; rmax = imax[row] = imax[row] + CHUNKSIZE; PetscLogObjectMemory(A,CHUNKSIZE*(sizeof(int) + sizeof(PetscScalar))); a->maxnz += CHUNKSIZE; a->reallocs++; } N = nrow++ - 1; a->nz++; /* shift up all the later entries in this row */ for (ii=N; ii>=i; ii--) { rp[ii+1] = rp[ii]; ap[ii+1] = ap[ii]; } rp[i] = col; ap[i] = value; noinsert:; low = i + 1; } ailen[row] = nrow; } PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatGetValues_SeqAIJ" int MatGetValues_SeqAIJ(Mat A,int m,int *im,int n,int *in,PetscScalar *v) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; int *rp,k,low,high,t,row,nrow,i,col,l,*aj = a->j; int *ai = a->i,*ailen = a->ilen,shift = a->indexshift; PetscScalar *ap,*aa = a->a,zero = 0.0; PetscFunctionBegin; for (k=0; k= A->m) SETERRQ1(PETSC_ERR_ARG_OUTOFRANGE,"Row too large: %d",row); rp = aj + ai[row] + shift; ap = aa + ai[row] + shift; nrow = ailen[row]; for (l=0; l= A->n) SETERRQ1(PETSC_ERR_ARG_OUTOFRANGE,"Column too large: %d",in[l]); col = in[l] - shift; high = nrow; low = 0; /* assume unsorted */ while (high-low > 5) { t = (low+high)/2; if (rp[t] > col) high = t; else low = t; } for (i=low; i col) break; if (rp[i] == col) { *v++ = ap[i]; goto finished; } } *v++ = zero; finished:; } } PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatView_SeqAIJ_Binary" int MatView_SeqAIJ_Binary(Mat A,PetscViewer viewer) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; int i,fd,*col_lens,ierr; PetscFunctionBegin; ierr = PetscViewerBinaryGetDescriptor(viewer,&fd);CHKERRQ(ierr); ierr = PetscMalloc((4+A->m)*sizeof(int),&col_lens);CHKERRQ(ierr); col_lens[0] = MAT_FILE_COOKIE; col_lens[1] = A->m; col_lens[2] = A->n; col_lens[3] = a->nz; /* store lengths of each row and write (including header) to file */ for (i=0; im; i++) { col_lens[4+i] = a->i[i+1] - a->i[i]; } ierr = PetscBinaryWrite(fd,col_lens,4+A->m,PETSC_INT,1);CHKERRQ(ierr); ierr = PetscFree(col_lens);CHKERRQ(ierr); /* store column indices (zero start index) */ if (a->indexshift) { for (i=0; inz; i++) a->j[i]--; } ierr = PetscBinaryWrite(fd,a->j,a->nz,PETSC_INT,0);CHKERRQ(ierr); if (a->indexshift) { for (i=0; inz; i++) a->j[i]++; } /* store nonzero values */ ierr = PetscBinaryWrite(fd,a->a,a->nz,PETSC_SCALAR,0);CHKERRQ(ierr); PetscFunctionReturn(0); } extern int MatSeqAIJFactorInfo_SuperLU(Mat,PetscViewer); extern int MatMPIAIJFactorInfo_SuperLu(Mat,PetscViewer); extern int MatFactorInfo_Spooles(Mat,PetscViewer); extern int MatSeqAIJFactorInfo_UMFPACK(Mat,PetscViewer); extern int MatSeqAIJFactorInfo_Matlab(Mat,PetscViewer); #undef __FUNCT__ #define __FUNCT__ "MatView_SeqAIJ_ASCII" int MatView_SeqAIJ_ASCII(Mat A,PetscViewer viewer) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; int ierr,i,j,m = A->m,shift = a->indexshift; char *name; PetscViewerFormat format; PetscFunctionBegin; ierr = PetscObjectGetName((PetscObject)A,&name);CHKERRQ(ierr); ierr = PetscViewerGetFormat(viewer,&format);CHKERRQ(ierr); if (format == PETSC_VIEWER_ASCII_INFO_DETAIL || format == PETSC_VIEWER_ASCII_INFO) { if (a->inode.size) { ierr = PetscViewerASCIIPrintf(viewer,"using I-node routines: found %d nodes, limit used is %d\n",a->inode.node_count,a->inode.limit);CHKERRQ(ierr); } else { ierr = PetscViewerASCIIPrintf(viewer,"not using I-node routines\n");CHKERRQ(ierr); } } else if (format == PETSC_VIEWER_ASCII_MATLAB) { int nofinalvalue = 0; if ((a->i[m] == a->i[m-1]) || (a->j[a->nz-1] != A->n-!shift)) { nofinalvalue = 1; } ierr = PetscViewerASCIIUseTabs(viewer,PETSC_NO);CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer,"%% Size = %d %d \n",m,A->n);CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer,"%% Nonzeros = %d \n",a->nz);CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer,"zzz = zeros(%d,3);\n",a->nz+nofinalvalue);CHKERRQ(ierr); ierr = PetscViewerASCIIPrintf(viewer,"zzz = [\n");CHKERRQ(ierr); for (i=0; ii[i]+shift; ji[i+1]+shift; j++) { #if defined(PETSC_USE_COMPLEX) ierr = PetscViewerASCIIPrintf(viewer,"%d %d %18.16e + %18.16ei \n",i+1,a->j[j]+!shift,PetscRealPart(a->a[j]),PetscImaginaryPart(a->a[j]));CHKERRQ(ierr); #else ierr = PetscViewerASCIIPrintf(viewer,"%d %d %18.16e\n",i+1,a->j[j]+!shift,a->a[j]);CHKERRQ(ierr); #endif } } if (nofinalvalue) { ierr = PetscViewerASCIIPrintf(viewer,"%d %d %18.16e\n",m,A->n,0.0);CHKERRQ(ierr); } ierr = PetscViewerASCIIPrintf(viewer,"];\n %s = spconvert(zzz);\n",name);CHKERRQ(ierr); ierr = PetscViewerASCIIUseTabs(viewer,PETSC_YES);CHKERRQ(ierr); } else if (format == PETSC_VIEWER_ASCII_FACTOR_INFO) { #if defined(PETSC_HAVE_SUPERLU) && !defined(PETSC_USE_SINGLE) && !defined(PETSC_USE_COMPLEX) ierr = MatSeqAIJFactorInfo_SuperLU(A,viewer);CHKERRQ(ierr); #endif #if defined(PETSC_HAVE_SUPERLUDIST) && !defined(PETSC_USE_SINGLE) && !defined(PETSC_USE_COMPLEX) ierr = MatMPIAIJFactorInfo_SuperLu(A,viewer);CHKERRQ(ierr); #endif #if defined(PETSC_HAVE_SPOOLES) && !defined(PETSC_USE_SINGLE) && !defined(PETSC_USE_COMPLEX) ierr = MatFactorInfo_Spooles(A,viewer);CHKERRQ(ierr); #endif #if defined(PETSC_HAVE_UMFPACK) && !defined(PETSC_USE_SINGLE) && !defined(PETSC_USE_COMPLEX) ierr = MatSeqAIJFactorInfo_UMFPACK(A,viewer);CHKERRQ(ierr); #endif #if defined(PETSC_HAVE_MATLAB_ENGINE) && !defined(PETSC_USE_SINGLE) && !defined(PETSC_USE_COMPLEX) ierr = MatSeqAIJFactorInfo_Matlab(A,viewer);CHKERRQ(ierr); #endif PetscFunctionReturn(0); } else if (format == PETSC_VIEWER_ASCII_COMMON) { ierr = PetscViewerASCIIUseTabs(viewer,PETSC_NO);CHKERRQ(ierr); for (i=0; ii[i]+shift; ji[i+1]+shift; j++) { #if defined(PETSC_USE_COMPLEX) if (PetscImaginaryPart(a->a[j]) > 0.0 && PetscRealPart(a->a[j]) != 0.0) { ierr = PetscViewerASCIIPrintf(viewer," (%d, %g + %g i)",a->j[j]+shift,PetscRealPart(a->a[j]),PetscImaginaryPart(a->a[j]));CHKERRQ(ierr); } else if (PetscImaginaryPart(a->a[j]) < 0.0 && PetscRealPart(a->a[j]) != 0.0) { ierr = PetscViewerASCIIPrintf(viewer," (%d, %g - %g i)",a->j[j]+shift,PetscRealPart(a->a[j]),-PetscImaginaryPart(a->a[j]));CHKERRQ(ierr); } else if (PetscRealPart(a->a[j]) != 0.0) { ierr = PetscViewerASCIIPrintf(viewer," (%d, %g) ",a->j[j]+shift,PetscRealPart(a->a[j]));CHKERRQ(ierr); } #else if (a->a[j] != 0.0) {ierr = PetscViewerASCIIPrintf(viewer," (%d, %g) ",a->j[j]+shift,a->a[j]);CHKERRQ(ierr);} #endif } ierr = PetscViewerASCIIPrintf(viewer,"\n");CHKERRQ(ierr); } ierr = PetscViewerASCIIUseTabs(viewer,PETSC_YES);CHKERRQ(ierr); } else if (format == PETSC_VIEWER_ASCII_SYMMODU) { int nzd=0,fshift=1,*sptr; ierr = PetscViewerASCIIUseTabs(viewer,PETSC_NO);CHKERRQ(ierr); ierr = PetscMalloc((m+1)*sizeof(int),&sptr);CHKERRQ(ierr); for (i=0; ii[i]+shift; ji[i+1]+shift; j++) { if (a->j[j] >= i) { #if defined(PETSC_USE_COMPLEX) if (PetscImaginaryPart(a->a[j]) != 0.0 || PetscRealPart(a->a[j]) != 0.0) nzd++; #else if (a->a[j] != 0.0) nzd++; #endif } } } sptr[m] = nzd+1; ierr = PetscViewerASCIIPrintf(viewer," %d %d\n\n",m,nzd);CHKERRQ(ierr); for (i=0; ii[i]+shift; ji[i+1]+shift; j++) { if (a->j[j] >= i) {ierr = PetscViewerASCIIPrintf(viewer," %d ",a->j[j]+fshift);CHKERRQ(ierr);} } ierr = PetscViewerASCIIPrintf(viewer,"\n");CHKERRQ(ierr); } ierr = PetscViewerASCIIPrintf(viewer,"\n");CHKERRQ(ierr); for (i=0; ii[i]+shift; ji[i+1]+shift; j++) { if (a->j[j] >= i) { #if defined(PETSC_USE_COMPLEX) if (PetscImaginaryPart(a->a[j]) != 0.0 || PetscRealPart(a->a[j]) != 0.0) { ierr = PetscViewerASCIIPrintf(viewer," %18.16e %18.16e ",PetscRealPart(a->a[j]),PetscImaginaryPart(a->a[j]));CHKERRQ(ierr); } #else if (a->a[j] != 0.0) {ierr = PetscViewerASCIIPrintf(viewer," %18.16e ",a->a[j]);CHKERRQ(ierr);} #endif } } ierr = PetscViewerASCIIPrintf(viewer,"\n");CHKERRQ(ierr); } ierr = PetscViewerASCIIUseTabs(viewer,PETSC_YES);CHKERRQ(ierr); } else if (format == PETSC_VIEWER_ASCII_DENSE) { int cnt = 0,jcnt; PetscScalar value; ierr = PetscViewerASCIIUseTabs(viewer,PETSC_NO);CHKERRQ(ierr); for (i=0; in; j++) { if (jcnt < a->i[i+1]-a->i[i] && j == a->j[cnt]) { value = a->a[cnt++]; jcnt++; } else { value = 0.0; } #if defined(PETSC_USE_COMPLEX) ierr = PetscViewerASCIIPrintf(viewer," %7.5e+%7.5e i ",PetscRealPart(value),PetscImaginaryPart(value));CHKERRQ(ierr); #else ierr = PetscViewerASCIIPrintf(viewer," %7.5e ",value);CHKERRQ(ierr); #endif } ierr = PetscViewerASCIIPrintf(viewer,"\n");CHKERRQ(ierr); } ierr = PetscViewerASCIIUseTabs(viewer,PETSC_YES);CHKERRQ(ierr); } else { ierr = PetscViewerASCIIUseTabs(viewer,PETSC_NO);CHKERRQ(ierr); for (i=0; ii[i]+shift; ji[i+1]+shift; j++) { #if defined(PETSC_USE_COMPLEX) if (PetscImaginaryPart(a->a[j]) > 0.0) { ierr = PetscViewerASCIIPrintf(viewer," (%d, %g + %g i)",a->j[j]+shift,PetscRealPart(a->a[j]),PetscImaginaryPart(a->a[j]));CHKERRQ(ierr); } else if (PetscImaginaryPart(a->a[j]) < 0.0) { ierr = PetscViewerASCIIPrintf(viewer," (%d, %g - %g i)",a->j[j]+shift,PetscRealPart(a->a[j]),-PetscImaginaryPart(a->a[j]));CHKERRQ(ierr); } else { ierr = PetscViewerASCIIPrintf(viewer," (%d, %g) ",a->j[j]+shift,PetscRealPart(a->a[j]));CHKERRQ(ierr); } #else ierr = PetscViewerASCIIPrintf(viewer," (%d, %g) ",a->j[j]+shift,a->a[j]);CHKERRQ(ierr); #endif } ierr = PetscViewerASCIIPrintf(viewer,"\n");CHKERRQ(ierr); } ierr = PetscViewerASCIIUseTabs(viewer,PETSC_YES);CHKERRQ(ierr); } ierr = PetscViewerFlush(viewer);CHKERRQ(ierr); PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatView_SeqAIJ_Draw_Zoom" int MatView_SeqAIJ_Draw_Zoom(PetscDraw draw,void *Aa) { Mat A = (Mat) Aa; Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; int ierr,i,j,m = A->m,shift = a->indexshift,color; PetscReal xl,yl,xr,yr,x_l,x_r,y_l,y_r,maxv = 0.0; PetscViewer viewer; PetscViewerFormat format; PetscFunctionBegin; ierr = PetscObjectQuery((PetscObject)A,"Zoomviewer",(PetscObject*)&viewer);CHKERRQ(ierr); ierr = PetscViewerGetFormat(viewer,&format);CHKERRQ(ierr); ierr = PetscDrawGetCoordinates(draw,&xl,&yl,&xr,&yr);CHKERRQ(ierr); /* loop over matrix elements drawing boxes */ if (format != PETSC_VIEWER_DRAW_CONTOUR) { /* Blue for negative, Cyan for zero and Red for positive */ color = PETSC_DRAW_BLUE; for (i=0; ii[i]+shift; ji[i+1]+shift; j++) { x_l = a->j[j] + shift; x_r = x_l + 1.0; #if defined(PETSC_USE_COMPLEX) if (PetscRealPart(a->a[j]) >= 0.) continue; #else if (a->a[j] >= 0.) continue; #endif ierr = PetscDrawRectangle(draw,x_l,y_l,x_r,y_r,color,color,color,color);CHKERRQ(ierr); } } color = PETSC_DRAW_CYAN; for (i=0; ii[i]+shift; ji[i+1]+shift; j++) { x_l = a->j[j] + shift; x_r = x_l + 1.0; if (a->a[j] != 0.) continue; ierr = PetscDrawRectangle(draw,x_l,y_l,x_r,y_r,color,color,color,color);CHKERRQ(ierr); } } color = PETSC_DRAW_RED; for (i=0; ii[i]+shift; ji[i+1]+shift; j++) { x_l = a->j[j] + shift; x_r = x_l + 1.0; #if defined(PETSC_USE_COMPLEX) if (PetscRealPart(a->a[j]) <= 0.) continue; #else if (a->a[j] <= 0.) continue; #endif ierr = PetscDrawRectangle(draw,x_l,y_l,x_r,y_r,color,color,color,color);CHKERRQ(ierr); } } } else { /* use contour shading to indicate magnitude of values */ /* first determine max of all nonzero values */ int nz = a->nz,count; PetscDraw popup; PetscReal scale; for (i=0; ia[i]) > maxv) maxv = PetscAbsScalar(a->a[i]); } scale = (245.0 - PETSC_DRAW_BASIC_COLORS)/maxv; ierr = PetscDrawGetPopup(draw,&popup);CHKERRQ(ierr); if (popup) {ierr = PetscDrawScalePopup(popup,0.0,maxv);CHKERRQ(ierr);} count = 0; for (i=0; ii[i]+shift; ji[i+1]+shift; j++) { x_l = a->j[j] + shift; x_r = x_l + 1.0; color = PETSC_DRAW_BASIC_COLORS + (int)(scale*PetscAbsScalar(a->a[count])); ierr = PetscDrawRectangle(draw,x_l,y_l,x_r,y_r,color,color,color,color);CHKERRQ(ierr); count++; } } } PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatView_SeqAIJ_Draw" int MatView_SeqAIJ_Draw(Mat A,PetscViewer viewer) { int ierr; PetscDraw draw; PetscReal xr,yr,xl,yl,h,w; PetscTruth isnull; PetscFunctionBegin; ierr = PetscViewerDrawGetDraw(viewer,0,&draw);CHKERRQ(ierr); ierr = PetscDrawIsNull(draw,&isnull);CHKERRQ(ierr); if (isnull) PetscFunctionReturn(0); ierr = PetscObjectCompose((PetscObject)A,"Zoomviewer",(PetscObject)viewer);CHKERRQ(ierr); xr = A->n; yr = A->m; h = yr/10.0; w = xr/10.0; xr += w; yr += h; xl = -w; yl = -h; ierr = PetscDrawSetCoordinates(draw,xl,yl,xr,yr);CHKERRQ(ierr); ierr = PetscDrawZoom(draw,MatView_SeqAIJ_Draw_Zoom,A);CHKERRQ(ierr); ierr = PetscObjectCompose((PetscObject)A,"Zoomviewer",PETSC_NULL);CHKERRQ(ierr); PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatView_SeqAIJ" int MatView_SeqAIJ(Mat A,PetscViewer viewer) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; int ierr; PetscTruth issocket,isascii,isbinary,isdraw; PetscFunctionBegin; ierr = PetscTypeCompare((PetscObject)viewer,PETSC_VIEWER_SOCKET,&issocket);CHKERRQ(ierr); ierr = PetscTypeCompare((PetscObject)viewer,PETSC_VIEWER_ASCII,&isascii);CHKERRQ(ierr); ierr = PetscTypeCompare((PetscObject)viewer,PETSC_VIEWER_BINARY,&isbinary);CHKERRQ(ierr); ierr = PetscTypeCompare((PetscObject)viewer,PETSC_VIEWER_DRAW,&isdraw);CHKERRQ(ierr); if (issocket) { if (a->indexshift) { SETERRQ(1,"Can only socket send sparse matrix with 0 based indexing"); } ierr = PetscViewerSocketPutSparse_Private(viewer,A->m,A->n,a->nz,a->a,a->i,a->j);CHKERRQ(ierr); } else if (isascii) { ierr = MatView_SeqAIJ_ASCII(A,viewer);CHKERRQ(ierr); } else if (isbinary) { ierr = MatView_SeqAIJ_Binary(A,viewer);CHKERRQ(ierr); } else if (isdraw) { ierr = MatView_SeqAIJ_Draw(A,viewer);CHKERRQ(ierr); } else { SETERRQ1(1,"Viewer type %s not supported by SeqAIJ matrices",((PetscObject)viewer)->type_name); } PetscFunctionReturn(0); } EXTERN int Mat_AIJ_CheckInode(Mat,PetscTruth); #undef __FUNCT__ #define __FUNCT__ "MatAssemblyEnd_SeqAIJ" int MatAssemblyEnd_SeqAIJ(Mat A,MatAssemblyType mode) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; int fshift = 0,i,j,*ai = a->i,*aj = a->j,*imax = a->imax,ierr; int m = A->m,*ip,N,*ailen = a->ilen,shift = a->indexshift,rmax = 0; PetscScalar *aa = a->a,*ap; #if defined(PETSC_HAVE_SUPERLUDIST) || defined(PETSC_HAVE_SPOOLES) || defined(PETSC_HAVE_UMFPACK) PetscTruth flag; #endif PetscFunctionBegin; if (mode == MAT_FLUSH_ASSEMBLY) PetscFunctionReturn(0); if (m) rmax = ailen[0]; /* determine row with most nonzeros */ for (i=1; inz = ai[m] + shift; /* diagonals may have moved, so kill the diagonal pointers */ if (fshift && a->diag) { ierr = PetscFree(a->diag);CHKERRQ(ierr); PetscLogObjectMemory(A,-(m+1)*sizeof(int)); a->diag = 0; } PetscLogInfo(A,"MatAssemblyEnd_SeqAIJ:Matrix size: %d X %d; storage space: %d unneeded,%d used\n",m,A->n,fshift,a->nz); PetscLogInfo(A,"MatAssemblyEnd_SeqAIJ:Number of mallocs during MatSetValues() is %d\n",a->reallocs); PetscLogInfo(A,"MatAssemblyEnd_SeqAIJ:Most nonzeros in any row is %d\n",rmax); a->reallocs = 0; A->info.nz_unneeded = (double)fshift; a->rmax = rmax; /* check out for identical nodes. If found, use inode functions */ ierr = Mat_AIJ_CheckInode(A,(PetscTruth)(!fshift));CHKERRQ(ierr); #if defined(PETSC_HAVE_SUPERLUDIST) ierr = PetscOptionsHasName(A->prefix,"-mat_aij_superlu_dist",&flag);CHKERRQ(ierr); if (flag) { ierr = MatUseSuperLU_DIST_MPIAIJ(A);CHKERRQ(ierr); } #endif #if defined(PETSC_HAVE_SPOOLES) ierr = PetscOptionsHasName(A->prefix,"-mat_aij_spooles",&flag);CHKERRQ(ierr); if (flag) { ierr = MatUseSpooles_SeqAIJ(A);CHKERRQ(ierr); } #endif #if defined(PETSC_HAVE_UMFPACK) ierr = PetscOptionsHasName(A->prefix,"-mat_aij_umfpack",&flag);CHKERRQ(ierr); if (flag) { ierr = MatUseUMFPACK_SeqAIJ(A);CHKERRQ(ierr); } #endif PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatZeroEntries_SeqAIJ" int MatZeroEntries_SeqAIJ(Mat A) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; int ierr; PetscFunctionBegin; ierr = PetscMemzero(a->a,(a->i[A->m]+a->indexshift)*sizeof(PetscScalar));CHKERRQ(ierr); PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatDestroy_SeqAIJ" int MatDestroy_SeqAIJ(Mat A) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; int ierr; PetscFunctionBegin; #if defined(PETSC_USE_LOG) PetscLogObjectState((PetscObject)A,"Rows=%d, Cols=%d, NZ=%d",A->m,A->n,a->nz); #endif if (a->freedata) { ierr = PetscFree(a->a);CHKERRQ(ierr); if (!a->singlemalloc) { ierr = PetscFree(a->i);CHKERRQ(ierr); ierr = PetscFree(a->j);CHKERRQ(ierr); } } if (a->row) { ierr = ISDestroy(a->row);CHKERRQ(ierr); } if (a->col) { ierr = ISDestroy(a->col);CHKERRQ(ierr); } if (a->diag) {ierr = PetscFree(a->diag);CHKERRQ(ierr);} if (a->ilen) {ierr = PetscFree(a->ilen);CHKERRQ(ierr);} if (a->imax) {ierr = PetscFree(a->imax);CHKERRQ(ierr);} if (a->idiag) {ierr = PetscFree(a->idiag);CHKERRQ(ierr);} if (a->solve_work) {ierr = PetscFree(a->solve_work);CHKERRQ(ierr);} if (a->inode.size) {ierr = PetscFree(a->inode.size);CHKERRQ(ierr);} if (a->icol) {ierr = ISDestroy(a->icol);CHKERRQ(ierr);} if (a->saved_values) {ierr = PetscFree(a->saved_values);CHKERRQ(ierr);} if (a->coloring) {ierr = ISColoringDestroy(a->coloring);CHKERRQ(ierr);} ierr = PetscFree(a);CHKERRQ(ierr); PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatCompress_SeqAIJ" int MatCompress_SeqAIJ(Mat A) { PetscFunctionBegin; PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatSetOption_SeqAIJ" int MatSetOption_SeqAIJ(Mat A,MatOption op) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; PetscFunctionBegin; switch (op) { case MAT_ROW_ORIENTED: a->roworiented = PETSC_TRUE; break; case MAT_KEEP_ZEROED_ROWS: a->keepzeroedrows = PETSC_TRUE; break; case MAT_COLUMN_ORIENTED: a->roworiented = PETSC_FALSE; break; case MAT_COLUMNS_SORTED: a->sorted = PETSC_TRUE; break; case MAT_COLUMNS_UNSORTED: a->sorted = PETSC_FALSE; break; case MAT_NO_NEW_NONZERO_LOCATIONS: a->nonew = 1; break; case MAT_NEW_NONZERO_LOCATION_ERR: a->nonew = -1; break; case MAT_NEW_NONZERO_ALLOCATION_ERR: a->nonew = -2; break; case MAT_YES_NEW_NONZERO_LOCATIONS: a->nonew = 0; break; case MAT_IGNORE_ZERO_ENTRIES: a->ignorezeroentries = PETSC_TRUE; break; case MAT_USE_INODES: a->inode.use = PETSC_TRUE; break; case MAT_DO_NOT_USE_INODES: a->inode.use = PETSC_FALSE; break; case MAT_ROWS_SORTED: case MAT_ROWS_UNSORTED: case MAT_YES_NEW_DIAGONALS: case MAT_IGNORE_OFF_PROC_ENTRIES: case MAT_USE_HASH_TABLE: PetscLogInfo(A,"MatSetOption_SeqAIJ:Option ignored\n"); break; case MAT_NO_NEW_DIAGONALS: SETERRQ(PETSC_ERR_SUP,"MAT_NO_NEW_DIAGONALS"); case MAT_INODE_LIMIT_1: a->inode.limit = 1; break; case MAT_INODE_LIMIT_2: a->inode.limit = 2; break; case MAT_INODE_LIMIT_3: a->inode.limit = 3; break; case MAT_INODE_LIMIT_4: a->inode.limit = 4; break; case MAT_INODE_LIMIT_5: a->inode.limit = 5; break; default: SETERRQ(PETSC_ERR_SUP,"unknown option"); } PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatGetDiagonal_SeqAIJ" int MatGetDiagonal_SeqAIJ(Mat A,Vec v) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; int i,j,n,shift = a->indexshift,ierr; PetscScalar *x,zero = 0.0; PetscFunctionBegin; ierr = VecSet(&zero,v);CHKERRQ(ierr); ierr = VecGetArray(v,&x);CHKERRQ(ierr); ierr = VecGetLocalSize(v,&n);CHKERRQ(ierr); if (n != A->m) SETERRQ(PETSC_ERR_ARG_SIZ,"Nonconforming matrix and vector"); for (i=0; im; i++) { for (j=a->i[i]+shift; ji[i+1]+shift; j++) { if (a->j[j]+shift == i) { x[i] = a->a[j]; break; } } } ierr = VecRestoreArray(v,&x);CHKERRQ(ierr); PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatMultTransposeAdd_SeqAIJ" int MatMultTransposeAdd_SeqAIJ(Mat A,Vec xx,Vec zz,Vec yy) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; PetscScalar *x,*y; int ierr,m = A->m,shift = a->indexshift; #if !defined(PETSC_USE_FORTRAN_KERNEL_MULTTRANSPOSEAIJ) PetscScalar *v,alpha; int n,i,*idx; #endif PetscFunctionBegin; if (zz != yy) {ierr = VecCopy(zz,yy);CHKERRQ(ierr);} ierr = VecGetArray(xx,&x);CHKERRQ(ierr); ierr = VecGetArray(yy,&y);CHKERRQ(ierr); y = y + shift; /* shift for Fortran start by 1 indexing */ #if defined(PETSC_USE_FORTRAN_KERNEL_MULTTRANSPOSEAIJ) fortranmulttransposeaddaij_(&m,x,a->i,a->j+shift,a->a+shift,y); #else for (i=0; ij + a->i[i] + shift; v = a->a + a->i[i] + shift; n = a->i[i+1] - a->i[i]; alpha = x[i]; while (n-->0) {y[*idx++] += alpha * *v++;} } #endif PetscLogFlops(2*a->nz); ierr = VecRestoreArray(xx,&x);CHKERRQ(ierr); ierr = VecRestoreArray(yy,&y);CHKERRQ(ierr); PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatMultTranspose_SeqAIJ" int MatMultTranspose_SeqAIJ(Mat A,Vec xx,Vec yy) { PetscScalar zero = 0.0; int ierr; PetscFunctionBegin; ierr = VecSet(&zero,yy);CHKERRQ(ierr); ierr = MatMultTransposeAdd_SeqAIJ(A,xx,yy,yy);CHKERRQ(ierr); PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatMult_SeqAIJ" int MatMult_SeqAIJ(Mat A,Vec xx,Vec yy) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; PetscScalar *x,*y,*v; int ierr,m = A->m,*idx,shift = a->indexshift,*ii; #if !defined(PETSC_USE_FORTRAN_KERNEL_MULTAIJ) int n,i,jrow,j; PetscScalar sum; #endif #if defined(PETSC_HAVE_PRAGMA_DISJOINT) #pragma disjoint(*x,*y,*v) #endif PetscFunctionBegin; ierr = VecGetArray(xx,&x);CHKERRQ(ierr); ierr = VecGetArray(yy,&y);CHKERRQ(ierr); x = x + shift; /* shift for Fortran start by 1 indexing */ idx = a->j; v = a->a; ii = a->i; #if defined(PETSC_USE_FORTRAN_KERNEL_MULTAIJ) fortranmultaij_(&m,x,ii,idx+shift,v+shift,y); #else v += shift; /* shift for Fortran start by 1 indexing */ idx += shift; for (i=0; inz - m); ierr = VecRestoreArray(xx,&x);CHKERRQ(ierr); ierr = VecRestoreArray(yy,&y);CHKERRQ(ierr); PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatMultAdd_SeqAIJ" int MatMultAdd_SeqAIJ(Mat A,Vec xx,Vec yy,Vec zz) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; PetscScalar *x,*y,*z,*v; int ierr,m = A->m,*idx,shift = a->indexshift,*ii; #if !defined(PETSC_USE_FORTRAN_KERNEL_MULTADDAIJ) int n,i,jrow,j; PetscScalar sum; #endif PetscFunctionBegin; ierr = VecGetArray(xx,&x);CHKERRQ(ierr); ierr = VecGetArray(yy,&y);CHKERRQ(ierr); if (zz != yy) { ierr = VecGetArray(zz,&z);CHKERRQ(ierr); } else { z = y; } x = x + shift; /* shift for Fortran start by 1 indexing */ idx = a->j; v = a->a; ii = a->i; #if defined(PETSC_USE_FORTRAN_KERNEL_MULTADDAIJ) fortranmultaddaij_(&m,x,ii,idx+shift,v+shift,y,z); #else v += shift; /* shift for Fortran start by 1 indexing */ idx += shift; for (i=0; inz); ierr = VecRestoreArray(xx,&x);CHKERRQ(ierr); ierr = VecRestoreArray(yy,&y);CHKERRQ(ierr); if (zz != yy) { ierr = VecRestoreArray(zz,&z);CHKERRQ(ierr); } PetscFunctionReturn(0); } /* Adds diagonal pointers to sparse matrix structure. */ #undef __FUNCT__ #define __FUNCT__ "MatMarkDiagonal_SeqAIJ" int MatMarkDiagonal_SeqAIJ(Mat A) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; int i,j,*diag,m = A->m,shift = a->indexshift,ierr; PetscFunctionBegin; if (a->diag) PetscFunctionReturn(0); ierr = PetscMalloc((m+1)*sizeof(int),&diag);CHKERRQ(ierr); PetscLogObjectMemory(A,(m+1)*sizeof(int)); for (i=0; im; i++) { diag[i] = a->i[i+1]; for (j=a->i[i]+shift; ji[i+1]+shift; j++) { if (a->j[j]+shift == i) { diag[i] = j - shift; break; } } } a->diag = diag; PetscFunctionReturn(0); } /* Checks for missing diagonals */ #undef __FUNCT__ #define __FUNCT__ "MatMissingDiagonal_SeqAIJ" int MatMissingDiagonal_SeqAIJ(Mat A) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; int *diag,*jj = a->j,i,shift = a->indexshift,ierr; PetscFunctionBegin; ierr = MatMarkDiagonal_SeqAIJ(A);CHKERRQ(ierr); diag = a->diag; for (i=0; im; i++) { if (jj[diag[i]+shift] != i-shift) { SETERRQ1(1,"Matrix is missing diagonal number %d",i); } } PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatRelax_SeqAIJ" int MatRelax_SeqAIJ(Mat A,Vec bb,PetscReal omega,MatSORType flag,PetscReal fshift,int its,int lits,Vec xx) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; PetscScalar *x,*b,*bs, d,*xs,sum,*v = a->a,*t=0,scale,*ts,*xb,*idiag=0; int ierr,*idx,*diag,n = A->n,m = A->m,i,shift = a->indexshift; PetscFunctionBegin; its = its*lits; if (its <= 0) SETERRQ2(PETSC_ERR_ARG_WRONG,"Relaxation requires global its %d and local its %d both positive",its,lits); ierr = VecGetArray(xx,&x);CHKERRQ(ierr); if (xx != bb) { ierr = VecGetArray(bb,&b);CHKERRQ(ierr); } else { b = x; } if (!a->diag) {ierr = MatMarkDiagonal_SeqAIJ(A);CHKERRQ(ierr);} diag = a->diag; xs = x + shift; /* shifted by one for index start of a or a->j*/ if (flag == SOR_APPLY_UPPER) { /* apply (U + D/omega) to the vector */ bs = b + shift; for (i=0; ia[diag[i] + shift]; n = a->i[i+1] - diag[i] - 1; PetscLogFlops(2*n-1); idx = a->j + diag[i] + (!shift); v = a->a + diag[i] + (!shift); sum = b[i]*d/omega; SPARSEDENSEDOT(sum,bs,v,idx,n); x[i] = sum; } ierr = VecRestoreArray(xx,&x);CHKERRQ(ierr); if (bb != xx) {ierr = VecRestoreArray(bb,&b);CHKERRQ(ierr);} PetscFunctionReturn(0); } /* setup workspace for Eisenstat */ if (flag & SOR_EISENSTAT) { if (!a->idiag) { ierr = PetscMalloc(2*m*sizeof(PetscScalar),&a->idiag);CHKERRQ(ierr); a->ssor = a->idiag + m; v = a->a; for (i=0; iidiag[i] = 1.0/v[diag[i]];} } t = a->ssor; idiag = a->idiag; } /* Let A = L + U + D; where L is lower trianglar, U is upper triangular, E is diagonal; This routine applies (L + E)^{-1} A (U + E)^{-1} to a vector efficiently using Eisenstat's trick. This is for the case of SSOR preconditioner, so E is D/omega where omega is the relaxation factor. */ if (flag == SOR_APPLY_LOWER) { SETERRQ(PETSC_ERR_SUP,"SOR_APPLY_LOWER is not implemented"); } else if ((flag & SOR_EISENSTAT) && omega == 1.0 && shift == 0 && fshift == 0.0) { /* special case for omega = 1.0 saves flops and some integer ops */ PetscScalar *v2; v2 = a->a; /* x = (E + U)^{-1} b */ for (i=m-1; i>=0; i--) { n = a->i[i+1] - diag[i] - 1; idx = a->j + diag[i] + 1; v = a->a + diag[i] + 1; sum = b[i]; SPARSEDENSEMDOT(sum,xs,v,idx,n); x[i] = sum*idiag[i]; /* t = b - (2*E - D)x */ t[i] = b[i] - (v2[diag[i]])*x[i]; } /* t = (E + L)^{-1}t */ diag = a->diag; for (i=0; ii[i]; idx = a->j + a->i[i]; v = a->a + a->i[i]; sum = t[i]; SPARSEDENSEMDOT(sum,t,v,idx,n); t[i] = sum*idiag[i]; /* x = x + t */ x[i] += t[i]; } PetscLogFlops(3*m-1 + 2*a->nz); ierr = VecRestoreArray(xx,&x);CHKERRQ(ierr); if (bb != xx) {ierr = VecRestoreArray(bb,&b);CHKERRQ(ierr);} PetscFunctionReturn(0); } else if (flag & SOR_EISENSTAT) { /* Let A = L + U + D; where L is lower trianglar, U is upper triangular, E is diagonal; This routine applies (L + E)^{-1} A (U + E)^{-1} to a vector efficiently using Eisenstat's trick. This is for the case of SSOR preconditioner, so E is D/omega where omega is the relaxation factor. */ scale = (2.0/omega) - 1.0; /* x = (E + U)^{-1} b */ for (i=m-1; i>=0; i--) { d = fshift + a->a[diag[i] + shift]; n = a->i[i+1] - diag[i] - 1; idx = a->j + diag[i] + (!shift); v = a->a + diag[i] + (!shift); sum = b[i]; SPARSEDENSEMDOT(sum,xs,v,idx,n); x[i] = omega*(sum/d); } /* t = b - (2*E - D)x */ v = a->a; for (i=0; ij*/ diag = a->diag; for (i=0; ia[diag[i]+shift]; n = diag[i] - a->i[i]; idx = a->j + a->i[i] + shift; v = a->a + a->i[i] + shift; sum = t[i]; SPARSEDENSEMDOT(sum,ts,v,idx,n); t[i] = omega*(sum/d); /* x = x + t */ x[i] += t[i]; } PetscLogFlops(6*m-1 + 2*a->nz); ierr = VecRestoreArray(xx,&x);CHKERRQ(ierr); if (bb != xx) {ierr = VecRestoreArray(bb,&b);CHKERRQ(ierr);} PetscFunctionReturn(0); } if (flag & SOR_ZERO_INITIAL_GUESS) { if (flag & SOR_FORWARD_SWEEP || flag & SOR_LOCAL_FORWARD_SWEEP){ #if defined(PETSC_USE_FORTRAN_KERNEL_RELAXAIJ) fortranrelaxaijforwardzero_(&m,&omega,x,a->i,a->j,diag,a->a,b); #else for (i=0; ia[diag[i]+shift]; n = diag[i] - a->i[i]; PetscLogFlops(2*n-1); idx = a->j + a->i[i] + shift; v = a->a + a->i[i] + shift; sum = b[i]; SPARSEDENSEMDOT(sum,xs,v,idx,n); x[i] = omega*(sum/d); } #endif xb = x; } else xb = b; if ((flag & SOR_FORWARD_SWEEP || flag & SOR_LOCAL_FORWARD_SWEEP) && (flag & SOR_BACKWARD_SWEEP || flag & SOR_LOCAL_BACKWARD_SWEEP)) { for (i=0; ia[diag[i]+shift]; } PetscLogFlops(m); } if (flag & SOR_BACKWARD_SWEEP || flag & SOR_LOCAL_BACKWARD_SWEEP){ #if defined(PETSC_USE_FORTRAN_KERNEL_RELAXAIJ) fortranrelaxaijbackwardzero_(&m,&omega,x,a->i,a->j,diag,a->a,xb); #else for (i=m-1; i>=0; i--) { d = fshift + a->a[diag[i] + shift]; n = a->i[i+1] - diag[i] - 1; PetscLogFlops(2*n-1); idx = a->j + diag[i] + (!shift); v = a->a + diag[i] + (!shift); sum = xb[i]; SPARSEDENSEMDOT(sum,xs,v,idx,n); x[i] = omega*(sum/d); } #endif } its--; } while (its--) { if (flag & SOR_FORWARD_SWEEP || flag & SOR_LOCAL_FORWARD_SWEEP){ #if defined(PETSC_USE_FORTRAN_KERNEL_RELAXAIJ) fortranrelaxaijforward_(&m,&omega,x,a->i,a->j,diag,a->a,b); #else for (i=0; ia[diag[i]+shift]; n = a->i[i+1] - a->i[i]; PetscLogFlops(2*n-1); idx = a->j + a->i[i] + shift; v = a->a + a->i[i] + shift; sum = b[i]; SPARSEDENSEMDOT(sum,xs,v,idx,n); x[i] = (1. - omega)*x[i] + omega*(sum + a->a[diag[i]+shift]*x[i])/d; } #endif } if (flag & SOR_BACKWARD_SWEEP || flag & SOR_LOCAL_BACKWARD_SWEEP){ #if defined(PETSC_USE_FORTRAN_KERNEL_RELAXAIJ) fortranrelaxaijbackward_(&m,&omega,x,a->i,a->j,diag,a->a,b); #else for (i=m-1; i>=0; i--) { d = fshift + a->a[diag[i] + shift]; n = a->i[i+1] - a->i[i]; PetscLogFlops(2*n-1); idx = a->j + a->i[i] + shift; v = a->a + a->i[i] + shift; sum = b[i]; SPARSEDENSEMDOT(sum,xs,v,idx,n); x[i] = (1. - omega)*x[i] + omega*(sum + a->a[diag[i]+shift]*x[i])/d; } #endif } } ierr = VecRestoreArray(xx,&x);CHKERRQ(ierr); if (bb != xx) {ierr = VecRestoreArray(bb,&b);CHKERRQ(ierr);} PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatGetInfo_SeqAIJ" int MatGetInfo_SeqAIJ(Mat A,MatInfoType flag,MatInfo *info) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; PetscFunctionBegin; info->rows_global = (double)A->m; info->columns_global = (double)A->n; info->rows_local = (double)A->m; info->columns_local = (double)A->n; info->block_size = 1.0; info->nz_allocated = (double)a->maxnz; info->nz_used = (double)a->nz; info->nz_unneeded = (double)(a->maxnz - a->nz); info->assemblies = (double)A->num_ass; info->mallocs = (double)a->reallocs; info->memory = A->mem; if (A->factor) { info->fill_ratio_given = A->info.fill_ratio_given; info->fill_ratio_needed = A->info.fill_ratio_needed; info->factor_mallocs = A->info.factor_mallocs; } else { info->fill_ratio_given = 0; info->fill_ratio_needed = 0; info->factor_mallocs = 0; } PetscFunctionReturn(0); } EXTERN int MatLUFactorSymbolic_SeqAIJ(Mat,IS,IS,MatLUInfo*,Mat*); EXTERN int MatLUFactorNumeric_SeqAIJ(Mat,Mat*); EXTERN int MatLUFactor_SeqAIJ(Mat,IS,IS,MatLUInfo*); EXTERN int MatSolve_SeqAIJ(Mat,Vec,Vec); EXTERN int MatSolveAdd_SeqAIJ(Mat,Vec,Vec,Vec); EXTERN int MatSolveTranspose_SeqAIJ(Mat,Vec,Vec); EXTERN int MatSolveTransposeAdd_SeqAIJ(Mat,Vec,Vec,Vec); #undef __FUNCT__ #define __FUNCT__ "MatZeroRows_SeqAIJ" int MatZeroRows_SeqAIJ(Mat A,IS is,PetscScalar *diag) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; int i,ierr,N,*rows,m = A->m - 1,shift = a->indexshift; PetscFunctionBegin; ierr = ISGetLocalSize(is,&N);CHKERRQ(ierr); ierr = ISGetIndices(is,&rows);CHKERRQ(ierr); if (a->keepzeroedrows) { for (i=0; i m) SETERRQ(PETSC_ERR_ARG_OUTOFRANGE,"row out of range"); ierr = PetscMemzero(&a->a[a->i[rows[i]]+shift],a->ilen[rows[i]]*sizeof(PetscScalar));CHKERRQ(ierr); } if (diag) { ierr = MatMissingDiagonal_SeqAIJ(A);CHKERRQ(ierr); ierr = MatMarkDiagonal_SeqAIJ(A);CHKERRQ(ierr); for (i=0; ia[a->diag[rows[i]]] = *diag; } } } else { if (diag) { for (i=0; i m) SETERRQ(PETSC_ERR_ARG_OUTOFRANGE,"row out of range"); if (a->ilen[rows[i]] > 0) { a->ilen[rows[i]] = 1; a->a[a->i[rows[i]]+shift] = *diag; a->j[a->i[rows[i]]+shift] = rows[i]+shift; } else { /* in case row was completely empty */ ierr = MatSetValues_SeqAIJ(A,1,&rows[i],1,&rows[i],diag,INSERT_VALUES);CHKERRQ(ierr); } } } else { for (i=0; i m) SETERRQ(PETSC_ERR_ARG_OUTOFRANGE,"row out of range"); a->ilen[rows[i]] = 0; } } } ierr = ISRestoreIndices(is,&rows);CHKERRQ(ierr); ierr = MatAssemblyEnd_SeqAIJ(A,MAT_FINAL_ASSEMBLY);CHKERRQ(ierr); PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatGetRow_SeqAIJ" int MatGetRow_SeqAIJ(Mat A,int row,int *nz,int **idx,PetscScalar **v) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; int *itmp,i,shift = a->indexshift,ierr; PetscFunctionBegin; if (row < 0 || row >= A->m) SETERRQ1(PETSC_ERR_ARG_OUTOFRANGE,"Row %d out of range",row); *nz = a->i[row+1] - a->i[row]; if (v) *v = a->a + a->i[row] + shift; if (idx) { itmp = a->j + a->i[row] + shift; if (*nz && shift) { ierr = PetscMalloc((*nz)*sizeof(int),idx);CHKERRQ(ierr); for (i=0; i<(*nz); i++) {(*idx)[i] = itmp[i] + shift;} } else if (*nz) { *idx = itmp; } else *idx = 0; } PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatRestoreRow_SeqAIJ" int MatRestoreRow_SeqAIJ(Mat A,int row,int *nz,int **idx,PetscScalar **v) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; int ierr; PetscFunctionBegin; if (idx) {if (*idx && a->indexshift) {ierr = PetscFree(*idx);CHKERRQ(ierr);}} PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatNorm_SeqAIJ" int MatNorm_SeqAIJ(Mat A,NormType type,PetscReal *nrm) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; PetscScalar *v = a->a; PetscReal sum = 0.0; int i,j,shift = a->indexshift,ierr; PetscFunctionBegin; if (type == NORM_FROBENIUS) { for (i=0; inz; i++) { #if defined(PETSC_USE_COMPLEX) sum += PetscRealPart(PetscConj(*v)*(*v)); v++; #else sum += (*v)*(*v); v++; #endif } *nrm = sqrt(sum); } else if (type == NORM_1) { PetscReal *tmp; int *jj = a->j; ierr = PetscMalloc((A->n+1)*sizeof(PetscReal),&tmp);CHKERRQ(ierr); ierr = PetscMemzero(tmp,A->n*sizeof(PetscReal));CHKERRQ(ierr); *nrm = 0.0; for (j=0; jnz; j++) { tmp[*jj++ + shift] += PetscAbsScalar(*v); v++; } for (j=0; jn; j++) { if (tmp[j] > *nrm) *nrm = tmp[j]; } ierr = PetscFree(tmp);CHKERRQ(ierr); } else if (type == NORM_INFINITY) { *nrm = 0.0; for (j=0; jm; j++) { v = a->a + a->i[j] + shift; sum = 0.0; for (i=0; ii[j+1]-a->i[j]; i++) { sum += PetscAbsScalar(*v); v++; } if (sum > *nrm) *nrm = sum; } } else { SETERRQ(PETSC_ERR_SUP,"No support for two norm"); } PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatTranspose_SeqAIJ" int MatTranspose_SeqAIJ(Mat A,Mat *B) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; Mat C; int i,ierr,*aj = a->j,*ai = a->i,m = A->m,len,*col; int shift = a->indexshift; PetscScalar *array = a->a; PetscFunctionBegin; if (!B && m != A->n) SETERRQ(PETSC_ERR_ARG_SIZ,"Square matrix only for in-place"); ierr = PetscMalloc((1+A->n)*sizeof(int),&col);CHKERRQ(ierr); ierr = PetscMemzero(col,(1+A->n)*sizeof(int));CHKERRQ(ierr); if (shift) { for (i=0; icomm,A->n,m,0,col,&C);CHKERRQ(ierr); ierr = PetscFree(col);CHKERRQ(ierr); for (i=0; idata; PetscScalar *l,*r,x,*v; int ierr,i,j,m = A->m,n = A->n,M,nz = a->nz,*jj,shift = a->indexshift; PetscFunctionBegin; if (ll) { /* The local size is used so that VecMPI can be passed to this routine by MatDiagonalScale_MPIAIJ */ ierr = VecGetLocalSize(ll,&m);CHKERRQ(ierr); if (m != A->m) SETERRQ(PETSC_ERR_ARG_SIZ,"Left scaling vector wrong length"); ierr = VecGetArray(ll,&l);CHKERRQ(ierr); v = a->a; for (i=0; ii[i+1] - a->i[i]; for (j=0; jn) SETERRQ(PETSC_ERR_ARG_SIZ,"Right scaling vector wrong length"); ierr = VecGetArray(rr,&r);CHKERRQ(ierr); v = a->a; jj = a->j; for (i=0; idata,*c; int *smap,i,k,kstart,kend,ierr,oldcols = A->n,*lens; int row,mat_i,*mat_j,tcol,first,step,*mat_ilen,sum,lensi; int *irow,*icol,nrows,ncols,shift = a->indexshift,*ssmap; int *starts,*j_new,*i_new,*aj = a->j,*ai = a->i,ii,*ailen = a->ilen; PetscScalar *a_new,*mat_a; Mat C; PetscTruth stride; PetscFunctionBegin; ierr = ISSorted(isrow,(PetscTruth*)&i);CHKERRQ(ierr); if (!i) SETERRQ(PETSC_ERR_ARG_WRONGSTATE,"ISrow is not sorted"); ierr = ISSorted(iscol,(PetscTruth*)&i);CHKERRQ(ierr); if (!i) SETERRQ(PETSC_ERR_ARG_WRONGSTATE,"IScol is not sorted"); ierr = ISGetIndices(isrow,&irow);CHKERRQ(ierr); ierr = ISGetLocalSize(isrow,&nrows);CHKERRQ(ierr); ierr = ISGetLocalSize(iscol,&ncols);CHKERRQ(ierr); ierr = ISStrideGetInfo(iscol,&first,&step);CHKERRQ(ierr); ierr = ISStride(iscol,&stride);CHKERRQ(ierr); if (stride && step == 1) { /* special case of contiguous rows */ ierr = PetscMalloc((2*nrows+1)*sizeof(int),&lens);CHKERRQ(ierr); starts = lens + nrows; /* loop over new rows determining lens and starting points */ for (i=0; i= first) { starts[i] = k; break; } } sum = 0; while (k < kend) { if (aj[k++]+shift >= first+ncols) break; sum++; } lens[i] = sum; } /* create submatrix */ if (scall == MAT_REUSE_MATRIX) { int n_cols,n_rows; ierr = MatGetSize(*B,&n_rows,&n_cols);CHKERRQ(ierr); if (n_rows != nrows || n_cols != ncols) SETERRQ(PETSC_ERR_ARG_SIZ,"Reused submatrix wrong size"); ierr = MatZeroEntries(*B);CHKERRQ(ierr); C = *B; } else { ierr = MatCreateSeqAIJ(A->comm,nrows,ncols,0,lens,&C);CHKERRQ(ierr); } c = (Mat_SeqAIJ*)C->data; /* loop over rows inserting into submatrix */ a_new = c->a; j_new = c->j; i_new = c->i; i_new[0] = -shift; for (i=0; ia + starts[i],lensi*sizeof(PetscScalar));CHKERRQ(ierr); a_new += lensi; i_new[i+1] = i_new[i] + lensi; c->ilen[i] = lensi; } ierr = PetscFree(lens);CHKERRQ(ierr); } else { ierr = ISGetIndices(iscol,&icol);CHKERRQ(ierr); ierr = PetscMalloc((1+oldcols)*sizeof(int),&smap);CHKERRQ(ierr); ssmap = smap + shift; ierr = PetscMalloc((1+nrows)*sizeof(int),&lens);CHKERRQ(ierr); ierr = PetscMemzero(smap,oldcols*sizeof(int));CHKERRQ(ierr); for (i=0; iilen[irow[i]]; lens[i] = 0; for (k=kstart; kdata); if ((*B)->m != nrows || (*B)->n != ncols) SETERRQ(PETSC_ERR_ARG_SIZ,"Cannot reuse matrix. wrong size"); ierr = PetscMemcmp(c->ilen,lens,(*B)->m*sizeof(int),&equal);CHKERRQ(ierr); if (!equal) { SETERRQ(PETSC_ERR_ARG_SIZ,"Cannot reuse matrix. wrong no of nonzeros"); } ierr = PetscMemzero(c->ilen,(*B)->m*sizeof(int));CHKERRQ(ierr); C = *B; } else { ierr = MatCreateSeqAIJ(A->comm,nrows,ncols,0,lens,&C);CHKERRQ(ierr); } c = (Mat_SeqAIJ *)(C->data); for (i=0; iilen[row]; mat_i = c->i[i]+shift; mat_j = c->j + mat_i; mat_a = c->a + mat_i; mat_ilen = c->ilen + i; for (k=kstart; kj[k]])) { *mat_j++ = tcol - (!shift); *mat_a++ = a->a[k]; (*mat_ilen)++; } } } /* Free work space */ ierr = ISRestoreIndices(iscol,&icol);CHKERRQ(ierr); ierr = PetscFree(smap);CHKERRQ(ierr); ierr = PetscFree(lens);CHKERRQ(ierr); } ierr = MatAssemblyBegin(C,MAT_FINAL_ASSEMBLY);CHKERRQ(ierr); ierr = MatAssemblyEnd(C,MAT_FINAL_ASSEMBLY);CHKERRQ(ierr); ierr = ISRestoreIndices(isrow,&irow);CHKERRQ(ierr); *B = C; PetscFunctionReturn(0); } /* */ #undef __FUNCT__ #define __FUNCT__ "MatILUFactor_SeqAIJ" int MatILUFactor_SeqAIJ(Mat inA,IS row,IS col,MatILUInfo *info) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)inA->data; int ierr; Mat outA; PetscTruth row_identity,col_identity; PetscFunctionBegin; if (info->levels != 0) SETERRQ(PETSC_ERR_SUP,"Only levels=0 supported for in-place ilu"); ierr = ISIdentity(row,&row_identity);CHKERRQ(ierr); ierr = ISIdentity(col,&col_identity);CHKERRQ(ierr); if (!row_identity || !col_identity) { SETERRQ(1,"Row and column permutations must be identity for in-place ILU"); } outA = inA; inA->factor = FACTOR_LU; a->row = row; a->col = col; ierr = PetscObjectReference((PetscObject)row);CHKERRQ(ierr); ierr = PetscObjectReference((PetscObject)col);CHKERRQ(ierr); /* Create the inverse permutation so that it can be used in MatLUFactorNumeric() */ if (a->icol) {ierr = ISDestroy(a->icol);CHKERRQ(ierr);} /* need to remove old one */ ierr = ISInvertPermutation(col,PETSC_DECIDE,&a->icol);CHKERRQ(ierr); PetscLogObjectParent(inA,a->icol); if (!a->solve_work) { /* this matrix may have been factored before */ ierr = PetscMalloc((inA->m+1)*sizeof(PetscScalar),&a->solve_work);CHKERRQ(ierr); } if (!a->diag) { ierr = MatMarkDiagonal_SeqAIJ(inA);CHKERRQ(ierr); } ierr = MatLUFactorNumeric_SeqAIJ(inA,&outA);CHKERRQ(ierr); PetscFunctionReturn(0); } #include "petscblaslapack.h" #undef __FUNCT__ #define __FUNCT__ "MatScale_SeqAIJ" int MatScale_SeqAIJ(PetscScalar *alpha,Mat inA) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)inA->data; int one = 1; PetscFunctionBegin; BLscal_(&a->nz,alpha,a->a,&one); PetscLogFlops(a->nz); PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatGetSubMatrices_SeqAIJ" int MatGetSubMatrices_SeqAIJ(Mat A,int n,IS *irow,IS *icol,MatReuse scall,Mat **B) { int ierr,i; PetscFunctionBegin; if (scall == MAT_INITIAL_MATRIX) { ierr = PetscMalloc((n+1)*sizeof(Mat),B);CHKERRQ(ierr); } for (i=0; idata; int shift,row,i,j,k,l,m,n,*idx,ierr,*nidx,isz,val; int start,end,*ai,*aj; PetscBT table; PetscFunctionBegin; shift = a->indexshift; m = A->m; ai = a->i; aj = a->j+shift; if (ov < 0) SETERRQ(PETSC_ERR_ARG_OUTOFRANGE,"illegal overlap value used"); ierr = PetscMalloc((m+1)*sizeof(int),&nidx);CHKERRQ(ierr); ierr = PetscBTCreate(m,table);CHKERRQ(ierr); for (i=0; idata; PetscScalar *vwork; int i,ierr,nz,m = A->m,n = A->n,*cwork; int *row,*col,*cnew,j,*lens; IS icolp,irowp; PetscFunctionBegin; ierr = ISInvertPermutation(rowp,PETSC_DECIDE,&irowp);CHKERRQ(ierr); ierr = ISGetIndices(irowp,&row);CHKERRQ(ierr); ierr = ISInvertPermutation(colp,PETSC_DECIDE,&icolp);CHKERRQ(ierr); ierr = ISGetIndices(icolp,&col);CHKERRQ(ierr); /* determine lengths of permuted rows */ ierr = PetscMalloc((m+1)*sizeof(int),&lens);CHKERRQ(ierr); for (i=0; ii[i+1] - a->i[i]; } ierr = MatCreateSeqAIJ(A->comm,m,n,0,lens,B);CHKERRQ(ierr); ierr = PetscFree(lens);CHKERRQ(ierr); ierr = PetscMalloc(n*sizeof(int),&cnew);CHKERRQ(ierr); for (i=0; icomm; int ierr; PetscFunctionBegin; if (called) {PetscFunctionReturn(0);} else called = PETSC_TRUE; ierr = (*PetscHelpPrintf)(comm," Options for MATSEQAIJ and MATMPIAIJ matrix formats (the defaults):\n");CHKERRQ(ierr); ierr = (*PetscHelpPrintf)(comm," -mat_lu_pivotthreshold : Set pivoting threshold\n");CHKERRQ(ierr); ierr = (*PetscHelpPrintf)(comm," -mat_aij_oneindex: internal indices begin at 1 instead of the default 0.\n");CHKERRQ(ierr); ierr = (*PetscHelpPrintf)(comm," -mat_aij_no_inode: Do not use inodes\n");CHKERRQ(ierr); ierr = (*PetscHelpPrintf)(comm," -mat_aij_inode_limit : Set inode limit (max limit=5)\n");CHKERRQ(ierr); #if defined(PETSC_HAVE_ESSL) ierr = (*PetscHelpPrintf)(comm," -mat_aij_essl: Use IBM sparse LU factorization and solve.\n");CHKERRQ(ierr); #endif #if defined(PETSC_HAVE_LUSOL) ierr = (*PetscHelpPrintf)(comm," -mat_aij_lusol: Use the Stanford LUSOL sparse factorization and solve.\n");CHKERRQ(ierr); #endif #if defined(PETSC_HAVE_MATLAB_ENGINE) && !defined(PETSC_USE_COMPLEX) && !defined(PETSC_USE_SINGLE) ierr = (*PetscHelpPrintf)(comm," -mat_aij_matlab: Use Matlab engine sparse LU factorization and solve.\n");CHKERRQ(ierr); #endif PetscFunctionReturn(0); } EXTERN int MatEqual_SeqAIJ(Mat A,Mat B,PetscTruth* flg); EXTERN int MatFDColoringCreate_SeqAIJ(Mat,ISColoring,MatFDColoring); EXTERN int MatILUDTFactor_SeqAIJ(Mat,MatILUInfo*,IS,IS,Mat*); #undef __FUNCT__ #define __FUNCT__ "MatCopy_SeqAIJ" int MatCopy_SeqAIJ(Mat A,Mat B,MatStructure str) { int ierr; PetscTruth flg; PetscFunctionBegin; ierr = PetscTypeCompare((PetscObject)B,MATSEQAIJ,&flg);CHKERRQ(ierr); if (str == SAME_NONZERO_PATTERN && flg) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; Mat_SeqAIJ *b = (Mat_SeqAIJ*)B->data; if (a->i[A->m]+a->indexshift != b->i[B->m]+a->indexshift) { SETERRQ(1,"Number of nonzeros in two matrices are different"); } ierr = PetscMemcpy(b->a,a->a,(a->i[A->m]+a->indexshift)*sizeof(PetscScalar));CHKERRQ(ierr); } else { ierr = MatCopy_Basic(A,B,str);CHKERRQ(ierr); } PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatSetUpPreallocation_SeqAIJ" int MatSetUpPreallocation_SeqAIJ(Mat A) { int ierr; PetscFunctionBegin; ierr = MatSeqAIJSetPreallocation(A,PETSC_DEFAULT,0);CHKERRQ(ierr); PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatGetArray_SeqAIJ" int MatGetArray_SeqAIJ(Mat A,PetscScalar **array) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; PetscFunctionBegin; *array = a->a; PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatRestoreArray_SeqAIJ" int MatRestoreArray_SeqAIJ(Mat A,PetscScalar **array) { PetscFunctionBegin; PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatFDColoringApply_SeqAIJ" int MatFDColoringApply_SeqAIJ(Mat J,MatFDColoring coloring,Vec x1,MatStructure *flag,void *sctx) { int (*f)(void *,Vec,Vec,void*) = (int (*)(void *,Vec,Vec,void *))coloring->f; int k,ierr,N,start,end,l,row,col,srow,**vscaleforrow,m1,m2; PetscScalar dx,mone = -1.0,*y,*xx,*w3_array; PetscScalar *vscale_array; PetscReal epsilon = coloring->error_rel,umin = coloring->umin; Vec w1,w2,w3; void *fctx = coloring->fctx; PetscTruth flg; PetscFunctionBegin; if (!coloring->w1) { ierr = VecDuplicate(x1,&coloring->w1);CHKERRQ(ierr); PetscLogObjectParent(coloring,coloring->w1); ierr = VecDuplicate(x1,&coloring->w2);CHKERRQ(ierr); PetscLogObjectParent(coloring,coloring->w2); ierr = VecDuplicate(x1,&coloring->w3);CHKERRQ(ierr); PetscLogObjectParent(coloring,coloring->w3); } w1 = coloring->w1; w2 = coloring->w2; w3 = coloring->w3; ierr = MatSetUnfactored(J);CHKERRQ(ierr); ierr = PetscOptionsHasName(coloring->prefix,"-mat_fd_coloring_dont_rezero",&flg);CHKERRQ(ierr); if (flg) { PetscLogInfo(coloring,"MatFDColoringApply_SeqAIJ: Not calling MatZeroEntries()\n"); } else { ierr = MatZeroEntries(J);CHKERRQ(ierr); } ierr = VecGetOwnershipRange(x1,&start,&end);CHKERRQ(ierr); ierr = VecGetSize(x1,&N);CHKERRQ(ierr); /* This is a horrible, horrible, hack. See DMMGComputeJacobian_Multigrid() it inproperly sets coloring->F for the coarser grids from the finest */ if (coloring->F) { ierr = VecGetLocalSize(coloring->F,&m1);CHKERRQ(ierr); ierr = VecGetLocalSize(w1,&m2);CHKERRQ(ierr); if (m1 != m2) { coloring->F = 0; } } if (coloring->F) { w1 = coloring->F; coloring->F = 0; } else { ierr = (*f)(sctx,x1,w1,fctx);CHKERRQ(ierr); } /* Compute all the scale factors and share with other processors */ ierr = VecGetArray(x1,&xx);CHKERRQ(ierr);xx = xx - start; ierr = VecGetArray(coloring->vscale,&vscale_array);CHKERRQ(ierr);vscale_array = vscale_array - start; for (k=0; kncolors; k++) { /* Loop over each column associated with color adding the perturbation to the vector w3. */ for (l=0; lncolumns[k]; l++) { col = coloring->columns[k][l]; /* column of the matrix we are probing for */ dx = xx[col]; if (dx == 0.0) dx = 1.0; #if !defined(PETSC_USE_COMPLEX) if (dx < umin && dx >= 0.0) dx = umin; else if (dx < 0.0 && dx > -umin) dx = -umin; #else if (PetscAbsScalar(dx) < umin && PetscRealPart(dx) >= 0.0) dx = umin; else if (PetscRealPart(dx) < 0.0 && PetscAbsScalar(dx) < umin) dx = -umin; #endif dx *= epsilon; vscale_array[col] = 1.0/dx; } } vscale_array = vscale_array + start;ierr = VecRestoreArray(coloring->vscale,&vscale_array);CHKERRQ(ierr); ierr = VecGhostUpdateBegin(coloring->vscale,INSERT_VALUES,SCATTER_FORWARD);CHKERRQ(ierr); ierr = VecGhostUpdateEnd(coloring->vscale,INSERT_VALUES,SCATTER_FORWARD);CHKERRQ(ierr); /* ierr = VecView(coloring->vscale,PETSC_VIEWER_STDOUT_WORLD); ierr = VecView(x1,PETSC_VIEWER_STDOUT_WORLD);*/ if (coloring->vscaleforrow) vscaleforrow = coloring->vscaleforrow; else vscaleforrow = coloring->columnsforrow; ierr = VecGetArray(coloring->vscale,&vscale_array);CHKERRQ(ierr); /* Loop over each color */ for (k=0; kncolors; k++) { coloring->currentcolor = k; ierr = VecCopy(x1,w3);CHKERRQ(ierr); ierr = VecGetArray(w3,&w3_array);CHKERRQ(ierr);w3_array = w3_array - start; /* Loop over each column associated with color adding the perturbation to the vector w3. */ for (l=0; lncolumns[k]; l++) { col = coloring->columns[k][l]; /* column of the matrix we are probing for */ dx = xx[col]; if (dx == 0.0) dx = 1.0; #if !defined(PETSC_USE_COMPLEX) if (dx < umin && dx >= 0.0) dx = umin; else if (dx < 0.0 && dx > -umin) dx = -umin; #else if (PetscAbsScalar(dx) < umin && PetscRealPart(dx) >= 0.0) dx = umin; else if (PetscRealPart(dx) < 0.0 && PetscAbsScalar(dx) < umin) dx = -umin; #endif dx *= epsilon; if (!PetscAbsScalar(dx)) SETERRQ(1,"Computed 0 differencing parameter"); w3_array[col] += dx; } w3_array = w3_array + start; ierr = VecRestoreArray(w3,&w3_array);CHKERRQ(ierr); /* Evaluate function at x1 + dx (here dx is a vector of perturbations) */ ierr = (*f)(sctx,w3,w2,fctx);CHKERRQ(ierr); ierr = VecAXPY(&mone,w1,w2);CHKERRQ(ierr); /* Loop over rows of vector, putting results into Jacobian matrix */ ierr = VecGetArray(w2,&y);CHKERRQ(ierr); for (l=0; lnrows[k]; l++) { row = coloring->rows[k][l]; col = coloring->columnsforrow[k][l]; y[row] *= vscale_array[vscaleforrow[k][l]]; srow = row + start; ierr = MatSetValues_SeqAIJ(J,1,&srow,1,&col,y+row,INSERT_VALUES);CHKERRQ(ierr); } ierr = VecRestoreArray(w2,&y);CHKERRQ(ierr); } coloring->currentcolor = k; ierr = VecRestoreArray(coloring->vscale,&vscale_array);CHKERRQ(ierr); xx = xx + start; ierr = VecRestoreArray(x1,&xx);CHKERRQ(ierr); ierr = MatAssemblyBegin(J,MAT_FINAL_ASSEMBLY);CHKERRQ(ierr); ierr = MatAssemblyEnd(J,MAT_FINAL_ASSEMBLY);CHKERRQ(ierr); PetscFunctionReturn(0); } #include "petscblaslapack.h" #undef __FUNCT__ #define __FUNCT__ "MatAXPY_SeqAIJ" int MatAXPY_SeqAIJ(PetscScalar *a,Mat X,Mat Y,MatStructure str) { int ierr,one=1; Mat_SeqAIJ *x = (Mat_SeqAIJ *)X->data,*y = (Mat_SeqAIJ *)Y->data; PetscFunctionBegin; if (str == SAME_NONZERO_PATTERN) { BLaxpy_(&x->nz,a,x->a,&one,y->a,&one); } else { ierr = MatAXPY_Basic(a,X,Y,str);CHKERRQ(ierr); } PetscFunctionReturn(0); } /* -------------------------------------------------------------------*/ static struct _MatOps MatOps_Values = {MatSetValues_SeqAIJ, MatGetRow_SeqAIJ, MatRestoreRow_SeqAIJ, MatMult_SeqAIJ, MatMultAdd_SeqAIJ, MatMultTranspose_SeqAIJ, MatMultTransposeAdd_SeqAIJ, MatSolve_SeqAIJ, MatSolveAdd_SeqAIJ, MatSolveTranspose_SeqAIJ, MatSolveTransposeAdd_SeqAIJ, MatLUFactor_SeqAIJ, 0, MatRelax_SeqAIJ, MatTranspose_SeqAIJ, MatGetInfo_SeqAIJ, MatEqual_SeqAIJ, MatGetDiagonal_SeqAIJ, MatDiagonalScale_SeqAIJ, MatNorm_SeqAIJ, 0, MatAssemblyEnd_SeqAIJ, MatCompress_SeqAIJ, MatSetOption_SeqAIJ, MatZeroEntries_SeqAIJ, MatZeroRows_SeqAIJ, MatLUFactorSymbolic_SeqAIJ, MatLUFactorNumeric_SeqAIJ, 0, MatCholeskyFactorNumeric_SeqAIJ, MatSetUpPreallocation_SeqAIJ, MatILUFactorSymbolic_SeqAIJ, MatICCFactorSymbolic_SeqAIJ, MatGetArray_SeqAIJ, MatRestoreArray_SeqAIJ, MatDuplicate_SeqAIJ, 0, 0, MatILUFactor_SeqAIJ, 0, MatAXPY_SeqAIJ, MatGetSubMatrices_SeqAIJ, MatIncreaseOverlap_SeqAIJ, MatGetValues_SeqAIJ, MatCopy_SeqAIJ, MatPrintHelp_SeqAIJ, MatScale_SeqAIJ, 0, 0, MatILUDTFactor_SeqAIJ, MatGetBlockSize_SeqAIJ, MatGetRowIJ_SeqAIJ, MatRestoreRowIJ_SeqAIJ, MatGetColumnIJ_SeqAIJ, MatRestoreColumnIJ_SeqAIJ, MatFDColoringCreate_SeqAIJ, 0, 0, MatPermute_SeqAIJ, 0, 0, MatDestroy_SeqAIJ, MatView_SeqAIJ, MatGetPetscMaps_Petsc, 0, 0, 0, 0, 0, 0, 0, 0, MatSetColoring_SeqAIJ, MatSetValuesAdic_SeqAIJ, MatSetValuesAdifor_SeqAIJ, MatFDColoringApply_SeqAIJ}; EXTERN_C_BEGIN #undef __FUNCT__ #define __FUNCT__ "MatSeqAIJSetColumnIndices_SeqAIJ" int MatSeqAIJSetColumnIndices_SeqAIJ(Mat mat,int *indices) { Mat_SeqAIJ *aij = (Mat_SeqAIJ *)mat->data; int i,nz,n; PetscFunctionBegin; nz = aij->maxnz; n = mat->n; for (i=0; ij[i] = indices[i]; } aij->nz = nz; for (i=0; iilen[i] = aij->imax[i]; } PetscFunctionReturn(0); } EXTERN_C_END #undef __FUNCT__ #define __FUNCT__ "MatSeqAIJSetColumnIndices" /*@ MatSeqAIJSetColumnIndices - Set the column indices for all the rows in the matrix. Input Parameters: + mat - the SeqAIJ matrix - indices - the column indices Level: advanced Notes: This can be called if you have precomputed the nonzero structure of the matrix and want to provide it to the matrix object to improve the performance of the MatSetValues() operation. You MUST have set the correct numbers of nonzeros per row in the call to MatCreateSeqAIJ(). MUST be called before any calls to MatSetValues(); The indices should start with zero, not one. @*/ int MatSeqAIJSetColumnIndices(Mat mat,int *indices) { int ierr,(*f)(Mat,int *); PetscFunctionBegin; PetscValidHeaderSpecific(mat,MAT_COOKIE); ierr = PetscObjectQueryFunction((PetscObject)mat,"MatSeqAIJSetColumnIndices_C",(void (**)(void))&f);CHKERRQ(ierr); if (f) { ierr = (*f)(mat,indices);CHKERRQ(ierr); } else { SETERRQ(1,"Wrong type of matrix to set column indices"); } PetscFunctionReturn(0); } /* ----------------------------------------------------------------------------------------*/ EXTERN_C_BEGIN #undef __FUNCT__ #define __FUNCT__ "MatStoreValues_SeqAIJ" int MatStoreValues_SeqAIJ(Mat mat) { Mat_SeqAIJ *aij = (Mat_SeqAIJ *)mat->data; size_t nz = aij->i[mat->m]+aij->indexshift,ierr; PetscFunctionBegin; if (aij->nonew != 1) { SETERRQ(1,"Must call MatSetOption(A,MAT_NO_NEW_NONZERO_LOCATIONS);first"); } /* allocate space for values if not already there */ if (!aij->saved_values) { ierr = PetscMalloc((nz+1)*sizeof(PetscScalar),&aij->saved_values);CHKERRQ(ierr); } /* copy values over */ ierr = PetscMemcpy(aij->saved_values,aij->a,nz*sizeof(PetscScalar));CHKERRQ(ierr); PetscFunctionReturn(0); } EXTERN_C_END #undef __FUNCT__ #define __FUNCT__ "MatStoreValues" /*@ MatStoreValues - Stashes a copy of the matrix values; this allows, for example, reuse of the linear part of a Jacobian, while recomputing the nonlinear portion. Collect on Mat Input Parameters: . mat - the matrix (currently on AIJ matrices support this option) Level: advanced Common Usage, with SNESSolve(): $ Create Jacobian matrix $ Set linear terms into matrix $ Apply boundary conditions to matrix, at this time matrix must have $ final nonzero structure (i.e. setting the nonlinear terms and applying $ boundary conditions again will not change the nonzero structure $ ierr = MatSetOption(mat,MAT_NO_NEW_NONZERO_LOCATIONS); $ ierr = MatStoreValues(mat); $ Call SNESSetJacobian() with matrix $ In your Jacobian routine $ ierr = MatRetrieveValues(mat); $ Set nonlinear terms in matrix Common Usage without SNESSolve(), i.e. when you handle nonlinear solve yourself: $ // build linear portion of Jacobian $ ierr = MatSetOption(mat,MAT_NO_NEW_NONZERO_LOCATIONS); $ ierr = MatStoreValues(mat); $ loop over nonlinear iterations $ ierr = MatRetrieveValues(mat); $ // call MatSetValues(mat,...) to set nonliner portion of Jacobian $ // call MatAssemblyBegin/End() on matrix $ Solve linear system with Jacobian $ endloop Notes: Matrix must already be assemblied before calling this routine Must set the matrix option MatSetOption(mat,MAT_NO_NEW_NONZERO_LOCATIONS); before calling this routine. .seealso: MatRetrieveValues() @*/ int MatStoreValues(Mat mat) { int ierr,(*f)(Mat); PetscFunctionBegin; PetscValidHeaderSpecific(mat,MAT_COOKIE); if (!mat->assembled) SETERRQ(PETSC_ERR_ARG_WRONGSTATE,"Not for unassembled matrix"); if (mat->factor) SETERRQ(PETSC_ERR_ARG_WRONGSTATE,"Not for factored matrix"); ierr = PetscObjectQueryFunction((PetscObject)mat,"MatStoreValues_C",(void (**)(void))&f);CHKERRQ(ierr); if (f) { ierr = (*f)(mat);CHKERRQ(ierr); } else { SETERRQ(1,"Wrong type of matrix to store values"); } PetscFunctionReturn(0); } EXTERN_C_BEGIN #undef __FUNCT__ #define __FUNCT__ "MatRetrieveValues_SeqAIJ" int MatRetrieveValues_SeqAIJ(Mat mat) { Mat_SeqAIJ *aij = (Mat_SeqAIJ *)mat->data; int nz = aij->i[mat->m]+aij->indexshift,ierr; PetscFunctionBegin; if (aij->nonew != 1) { SETERRQ(1,"Must call MatSetOption(A,MAT_NO_NEW_NONZERO_LOCATIONS);first"); } if (!aij->saved_values) { SETERRQ(1,"Must call MatStoreValues(A);first"); } /* copy values over */ ierr = PetscMemcpy(aij->a,aij->saved_values,nz*sizeof(PetscScalar));CHKERRQ(ierr); PetscFunctionReturn(0); } EXTERN_C_END #undef __FUNCT__ #define __FUNCT__ "MatRetrieveValues" /*@ MatRetrieveValues - Retrieves the copy of the matrix values; this allows, for example, reuse of the linear part of a Jacobian, while recomputing the nonlinear portion. Collect on Mat Input Parameters: . mat - the matrix (currently on AIJ matrices support this option) Level: advanced .seealso: MatStoreValues() @*/ int MatRetrieveValues(Mat mat) { int ierr,(*f)(Mat); PetscFunctionBegin; PetscValidHeaderSpecific(mat,MAT_COOKIE); if (!mat->assembled) SETERRQ(PETSC_ERR_ARG_WRONGSTATE,"Not for unassembled matrix"); if (mat->factor) SETERRQ(PETSC_ERR_ARG_WRONGSTATE,"Not for factored matrix"); ierr = PetscObjectQueryFunction((PetscObject)mat,"MatRetrieveValues_C",(void (**)(void))&f);CHKERRQ(ierr); if (f) { ierr = (*f)(mat);CHKERRQ(ierr); } else { SETERRQ(1,"Wrong type of matrix to retrieve values"); } PetscFunctionReturn(0); } /* This allows SeqAIJ matrices to be passed to the matlab engine */ #if defined(PETSC_HAVE_MATLAB_ENGINE) && !defined(PETSC_USE_COMPLEX) && !defined(PETSC_USE_SINGLE) #include "engine.h" /* Matlab include file */ #include "mex.h" /* Matlab include file */ EXTERN_C_BEGIN #undef __FUNCT__ #define __FUNCT__ "MatMatlabEnginePut_SeqAIJ" int MatMatlabEnginePut_SeqAIJ(PetscObject obj,void *mengine) { int ierr,i,*ai,*aj; Mat B = (Mat)obj; mxArray *mat; Mat_SeqAIJ *aij = (Mat_SeqAIJ*)B->data; PetscFunctionBegin; mat = mxCreateSparse(B->n,B->m,aij->nz,mxREAL); ierr = PetscMemcpy(mxGetPr(mat),aij->a,aij->nz*sizeof(PetscScalar));CHKERRQ(ierr); /* Matlab stores by column, not row so we pass in the transpose of the matrix */ ierr = PetscMemcpy(mxGetIr(mat),aij->j,aij->nz*sizeof(int));CHKERRQ(ierr); ierr = PetscMemcpy(mxGetJc(mat),aij->i,(B->m+1)*sizeof(int));CHKERRQ(ierr); /* Matlab indices start at 0 for sparse (what a surprise) */ if (aij->indexshift) { ai = mxGetJc(mat); for (i=0; im+1; i++) { ai[i]--; } aj = mxGetIr(mat); for (i=0; inz; i++) { aj[i]--; } } ierr = PetscObjectName(obj);CHKERRQ(ierr); mxSetName(mat,obj->name); engPutArray((Engine *)mengine,mat); PetscFunctionReturn(0); } EXTERN_C_END EXTERN_C_BEGIN #undef __FUNCT__ #define __FUNCT__ "MatMatlabEngineGet_SeqAIJ" int MatMatlabEngineGet_SeqAIJ(PetscObject obj,void *mengine) { int ierr,ii; Mat mat = (Mat)obj; Mat_SeqAIJ *aij = (Mat_SeqAIJ*)mat->data; mxArray *mmat; PetscFunctionBegin; ierr = PetscFree(aij->a);CHKERRQ(ierr); aij->indexshift = 0; mmat = engGetArray((Engine *)mengine,obj->name); aij->nz = (mxGetJc(mmat))[mat->m]; ierr = PetscMalloc(((size_t) aij->nz)*(sizeof(int)+sizeof(PetscScalar))+(mat->m+1)*sizeof(int),&aij->a);CHKERRQ(ierr); aij->j = (int*)(aij->a + aij->nz); aij->i = aij->j + aij->nz; aij->singlemalloc = PETSC_TRUE; aij->freedata = PETSC_TRUE; ierr = PetscMemcpy(aij->a,mxGetPr(mmat),aij->nz*sizeof(PetscScalar));CHKERRQ(ierr); /* Matlab stores by column, not row so we pass in the transpose of the matrix */ ierr = PetscMemcpy(aij->j,mxGetIr(mmat),aij->nz*sizeof(int));CHKERRQ(ierr); ierr = PetscMemcpy(aij->i,mxGetJc(mmat),(mat->m+1)*sizeof(int));CHKERRQ(ierr); for (ii=0; iim; ii++) { aij->ilen[ii] = aij->imax[ii] = aij->i[ii+1] - aij->i[ii]; } ierr = MatAssemblyBegin(mat,MAT_FINAL_ASSEMBLY);CHKERRQ(ierr); ierr = MatAssemblyEnd(mat,MAT_FINAL_ASSEMBLY);CHKERRQ(ierr); PetscFunctionReturn(0); } EXTERN_C_END #endif /* --------------------------------------------------------------------------------*/ #undef __FUNCT__ #define __FUNCT__ "MatCreateSeqAIJ" /*@C MatCreateSeqAIJ - Creates a sparse matrix in AIJ (compressed row) format (the default parallel PETSc format). For good matrix assembly performance the user should preallocate the matrix storage by setting the parameter nz (or the array nnz). By setting these parameters accurately, performance during matrix assembly can be increased by more than a factor of 50. Collective on MPI_Comm Input Parameters: + comm - MPI communicator, set to PETSC_COMM_SELF . m - number of rows . n - number of columns . nz - number of nonzeros per row (same for all rows) - nnz - array containing the number of nonzeros in the various rows (possibly different for each row) or PETSC_NULL Output Parameter: . A - the matrix Notes: The AIJ format (also called the Yale sparse matrix format or compressed row storage), is fully compatible with standard Fortran 77 storage. That is, the stored row and column indices can begin at either one (as in Fortran) or zero. See the users' manual for details. Specify the preallocated storage with either nz or nnz (not both). Set nz=PETSC_DEFAULT and nnz=PETSC_NULL for PETSc to control dynamic memory allocation. For large problems you MUST preallocate memory or you will get TERRIBLE performance, see the users' manual chapter on matrices. By default, this format uses inodes (identical nodes) when possible, to improve numerical efficiency of matrix-vector products and solves. We search for consecutive rows with the same nonzero structure, thereby reusing matrix information to achieve increased efficiency. Options Database Keys: + -mat_aij_no_inode - Do not use inodes . -mat_aij_inode_limit - Sets inode limit (max limit=5) - -mat_aij_oneindex - Internally use indexing starting at 1 rather than 0. Note that when calling MatSetValues(), the user still MUST index entries starting at 0! Level: intermediate .seealso: MatCreate(), MatCreateMPIAIJ(), MatSetValues(), MatSeqAIJSetColumnIndices(), MatCreateSeqAIJWithArrays() @*/ int MatCreateSeqAIJ(MPI_Comm comm,int m,int n,int nz,int *nnz,Mat *A) { int ierr; PetscFunctionBegin; ierr = MatCreate(comm,m,n,m,n,A);CHKERRQ(ierr); ierr = MatSetType(*A,MATSEQAIJ);CHKERRQ(ierr); ierr = MatSeqAIJSetPreallocation(*A,nz,nnz);CHKERRQ(ierr); PetscFunctionReturn(0); } #define SKIP_ALLOCATION -4 #undef __FUNCT__ #define __FUNCT__ "MatSeqAIJSetPreallocation" /*@C MatSeqAIJSetPreallocation - For good matrix assembly performance the user should preallocate the matrix storage by setting the parameter nz (or the array nnz). By setting these parameters accurately, performance during matrix assembly can be increased by more than a factor of 50. Collective on MPI_Comm Input Parameters: + comm - MPI communicator, set to PETSC_COMM_SELF . m - number of rows . n - number of columns . nz - number of nonzeros per row (same for all rows) - nnz - array containing the number of nonzeros in the various rows (possibly different for each row) or PETSC_NULL Output Parameter: . A - the matrix Notes: The AIJ format (also called the Yale sparse matrix format or compressed row storage), is fully compatible with standard Fortran 77 storage. That is, the stored row and column indices can begin at either one (as in Fortran) or zero. See the users' manual for details. Specify the preallocated storage with either nz or nnz (not both). Set nz=PETSC_DEFAULT and nnz=PETSC_NULL for PETSc to control dynamic memory allocation. For large problems you MUST preallocate memory or you will get TERRIBLE performance, see the users' manual chapter on matrices. By default, this format uses inodes (identical nodes) when possible, to improve numerical efficiency of matrix-vector products and solves. We search for consecutive rows with the same nonzero structure, thereby reusing matrix information to achieve increased efficiency. Options Database Keys: + -mat_aij_no_inode - Do not use inodes . -mat_aij_inode_limit - Sets inode limit (max limit=5) - -mat_aij_oneindex - Internally use indexing starting at 1 rather than 0. Note that when calling MatSetValues(), the user still MUST index entries starting at 0! Level: intermediate .seealso: MatCreate(), MatCreateMPIAIJ(), MatSetValues(), MatSeqAIJSetColumnIndices(), MatCreateSeqAIJWithArrays() @*/ int MatSeqAIJSetPreallocation(Mat B,int nz,int *nnz) { Mat_SeqAIJ *b; size_t len = 0; PetscTruth flg2,skipallocation = PETSC_FALSE; int i,ierr; PetscFunctionBegin; ierr = PetscTypeCompare((PetscObject)B,MATSEQAIJ,&flg2);CHKERRQ(ierr); if (!flg2) PetscFunctionReturn(0); if (nz == SKIP_ALLOCATION) { skipallocation = PETSC_TRUE; nz = 0; } if (nz == PETSC_DEFAULT || nz == PETSC_DECIDE) nz = 5; if (nz < 0) SETERRQ1(PETSC_ERR_ARG_OUTOFRANGE,"nz cannot be less than 0: value %d",nz); if (nnz) { for (i=0; im; i++) { if (nnz[i] < 0) SETERRQ2(PETSC_ERR_ARG_OUTOFRANGE,"nnz cannot be less than 0: local row %d value %d",i,nnz[i]); if (nnz[i] > B->n) SETERRQ3(PETSC_ERR_ARG_OUTOFRANGE,"nnz cannot be greater than row length: local row %d value %d rowlength %d",i,nnz[i],B->n); } } B->preallocated = PETSC_TRUE; b = (Mat_SeqAIJ*)B->data; ierr = PetscMalloc((B->m+1)*sizeof(int),&b->imax);CHKERRQ(ierr); if (!nnz) { if (nz == PETSC_DEFAULT || nz == PETSC_DECIDE) nz = 10; else if (nz <= 0) nz = 1; for (i=0; im; i++) b->imax[i] = nz; nz = nz*B->m; } else { nz = 0; for (i=0; im; i++) {b->imax[i] = nnz[i]; nz += nnz[i];} } if (!skipallocation) { /* allocate the matrix space */ len = ((size_t) nz)*(sizeof(int) + sizeof(PetscScalar)) + (B->m+1)*sizeof(int); ierr = PetscMalloc(len,&b->a);CHKERRQ(ierr); b->j = (int*)(b->a + nz); ierr = PetscMemzero(b->j,nz*sizeof(int));CHKERRQ(ierr); b->i = b->j + nz; b->i[0] = -b->indexshift; for (i=1; im+1; i++) { b->i[i] = b->i[i-1] + b->imax[i-1]; } b->singlemalloc = PETSC_TRUE; b->freedata = PETSC_TRUE; } else { b->freedata = PETSC_FALSE; } /* b->ilen will count nonzeros in each row so far. */ ierr = PetscMalloc((B->m+1)*sizeof(int),&b->ilen);CHKERRQ(ierr); PetscLogObjectMemory(B,len+2*(B->m+1)*sizeof(int)+sizeof(struct _p_Mat)+sizeof(Mat_SeqAIJ)); for (i=0; im; i++) { b->ilen[i] = 0;} b->nz = 0; b->maxnz = nz; B->info.nz_unneeded = (double)b->maxnz; PetscFunctionReturn(0); } EXTERN int RegisterApplyPtAPRoutines_Private(Mat); EXTERN_C_BEGIN extern int MatConvert_SeqAIJ_SeqSBAIJ(Mat,MatType,Mat*); EXTERN_C_END EXTERN_C_BEGIN #undef __FUNCT__ #define __FUNCT__ "MatCreate_SeqAIJ" int MatCreate_SeqAIJ(Mat B) { Mat_SeqAIJ *b; int ierr,size; PetscTruth flg; PetscFunctionBegin; ierr = MPI_Comm_size(B->comm,&size);CHKERRQ(ierr); if (size > 1) SETERRQ(PETSC_ERR_ARG_OUTOFRANGE,"Comm must be of size 1"); B->m = B->M = PetscMax(B->m,B->M); B->n = B->N = PetscMax(B->n,B->N); ierr = PetscNew(Mat_SeqAIJ,&b);CHKERRQ(ierr); B->data = (void*)b; ierr = PetscMemzero(b,sizeof(Mat_SeqAIJ));CHKERRQ(ierr); ierr = PetscMemcpy(B->ops,&MatOps_Values,sizeof(struct _MatOps));CHKERRQ(ierr); B->factor = 0; B->lupivotthreshold = 1.0; B->mapping = 0; ierr = PetscOptionsGetReal(B->prefix,"-mat_lu_pivotthreshold",&B->lupivotthreshold,PETSC_NULL);CHKERRQ(ierr); ierr = PetscOptionsHasName(B->prefix,"-pc_ilu_preserve_row_sums",&b->ilu_preserve_row_sums);CHKERRQ(ierr); b->row = 0; b->col = 0; b->icol = 0; b->indexshift = 0; b->reallocs = 0; ierr = PetscOptionsHasName(B->prefix,"-mat_aij_oneindex",&flg);CHKERRQ(ierr); if (flg) b->indexshift = -1; ierr = PetscMapCreateMPI(B->comm,B->m,B->m,&B->rmap);CHKERRQ(ierr); ierr = PetscMapCreateMPI(B->comm,B->n,B->n,&B->cmap);CHKERRQ(ierr); b->sorted = PETSC_FALSE; b->ignorezeroentries = PETSC_FALSE; b->roworiented = PETSC_TRUE; b->nonew = 0; b->diag = 0; b->solve_work = 0; B->spptr = 0; b->inode.use = PETSC_TRUE; b->inode.node_count = 0; b->inode.size = 0; b->inode.limit = 5; b->inode.max_limit = 5; b->saved_values = 0; b->idiag = 0; b->ssor = 0; b->keepzeroedrows = PETSC_FALSE; ierr = PetscObjectChangeTypeName((PetscObject)B,MATSEQAIJ);CHKERRQ(ierr); #if defined(PETSC_HAVE_SUPERLU) ierr = PetscOptionsHasName(B->prefix,"-mat_aij_superlu",&flg);CHKERRQ(ierr); if (flg) { ierr = MatUseSuperLU_SeqAIJ(B);CHKERRQ(ierr); } #endif ierr = PetscOptionsHasName(B->prefix,"-mat_aij_essl",&flg);CHKERRQ(ierr); if (flg) { ierr = MatUseEssl_SeqAIJ(B);CHKERRQ(ierr); } ierr = PetscOptionsHasName(B->prefix,"-mat_aij_lusol",&flg);CHKERRQ(ierr); if (flg) { ierr = MatUseLUSOL_SeqAIJ(B);CHKERRQ(ierr); } ierr = PetscOptionsHasName(B->prefix,"-mat_aij_matlab",&flg);CHKERRQ(ierr); if (flg) {ierr = MatUseMatlab_SeqAIJ(B);CHKERRQ(ierr);} ierr = PetscOptionsHasName(B->prefix,"-mat_aij_dxml",&flg);CHKERRQ(ierr); if (flg) { if (!b->indexshift) SETERRQ(PETSC_ERR_LIB,"need -mat_aij_oneindex with -mat_aij_dxml"); ierr = MatUseDXML_SeqAIJ(B);CHKERRQ(ierr); } ierr = PetscObjectComposeFunctionDynamic((PetscObject)B,"MatSeqAIJSetColumnIndices_C", "MatSeqAIJSetColumnIndices_SeqAIJ", MatSeqAIJSetColumnIndices_SeqAIJ);CHKERRQ(ierr); ierr = PetscObjectComposeFunctionDynamic((PetscObject)B,"MatStoreValues_C", "MatStoreValues_SeqAIJ", MatStoreValues_SeqAIJ);CHKERRQ(ierr); ierr = PetscObjectComposeFunctionDynamic((PetscObject)B,"MatRetrieveValues_C", "MatRetrieveValues_SeqAIJ", MatRetrieveValues_SeqAIJ);CHKERRQ(ierr); ierr = PetscObjectComposeFunctionDynamic((PetscObject)B,"MatConvert_seqaij_seqsbaij_C", "MatConvert_SeqAIJ_SeqSBAIJ", MatConvert_SeqAIJ_SeqSBAIJ);CHKERRQ(ierr); #if defined(PETSC_HAVE_MATLAB_ENGINE) && !defined(PETSC_USE_COMPLEX) && !defined(PETSC_USE_SINGLE) ierr = PetscObjectComposeFunctionDynamic((PetscObject)B,"PetscMatlabEnginePut_C","MatMatlabEnginePut_SeqAIJ",MatMatlabEnginePut_SeqAIJ);CHKERRQ(ierr); ierr = PetscObjectComposeFunctionDynamic((PetscObject)B,"PetscMatlabEngineGet_C","MatMatlabEngineGet_SeqAIJ",MatMatlabEngineGet_SeqAIJ);CHKERRQ(ierr); #endif ierr = RegisterApplyPtAPRoutines_Private(B);CHKERRQ(ierr); PetscFunctionReturn(0); } EXTERN_C_END #undef __FUNCT__ #define __FUNCT__ "MatDuplicate_SeqAIJ" int MatDuplicate_SeqAIJ(Mat A,MatDuplicateOption cpvalues,Mat *B) { Mat C; Mat_SeqAIJ *c,*a = (Mat_SeqAIJ*)A->data; int i,m = A->m,shift = a->indexshift,ierr; size_t len; PetscFunctionBegin; *B = 0; ierr = MatCreate(A->comm,A->m,A->n,A->m,A->n,&C);CHKERRQ(ierr); ierr = MatSetType(C,MATSEQAIJ);CHKERRQ(ierr); c = (Mat_SeqAIJ*)C->data; C->factor = A->factor; c->row = 0; c->col = 0; c->icol = 0; c->indexshift = shift; c->keepzeroedrows = a->keepzeroedrows; C->assembled = PETSC_TRUE; C->M = A->m; C->N = A->n; ierr = PetscMalloc((m+1)*sizeof(int),&c->imax);CHKERRQ(ierr); ierr = PetscMalloc((m+1)*sizeof(int),&c->ilen);CHKERRQ(ierr); for (i=0; iimax[i] = a->imax[i]; c->ilen[i] = a->ilen[i]; } /* allocate the matrix space */ c->singlemalloc = PETSC_TRUE; len = ((size_t) (m+1))*sizeof(int)+(a->i[m])*(sizeof(PetscScalar)+sizeof(int)); ierr = PetscMalloc(len,&c->a);CHKERRQ(ierr); c->j = (int*)(c->a + a->i[m] + shift); c->i = c->j + a->i[m] + shift; ierr = PetscMemcpy(c->i,a->i,(m+1)*sizeof(int));CHKERRQ(ierr); if (m > 0) { ierr = PetscMemcpy(c->j,a->j,(a->i[m]+shift)*sizeof(int));CHKERRQ(ierr); if (cpvalues == MAT_COPY_VALUES) { ierr = PetscMemcpy(c->a,a->a,(a->i[m]+shift)*sizeof(PetscScalar));CHKERRQ(ierr); } else { ierr = PetscMemzero(c->a,(a->i[m]+shift)*sizeof(PetscScalar));CHKERRQ(ierr); } } PetscLogObjectMemory(C,len+2*(m+1)*sizeof(int)+sizeof(struct _p_Mat)+sizeof(Mat_SeqAIJ)); c->sorted = a->sorted; c->roworiented = a->roworiented; c->nonew = a->nonew; c->ilu_preserve_row_sums = a->ilu_preserve_row_sums; c->saved_values = 0; c->idiag = 0; c->ssor = 0; c->ignorezeroentries = a->ignorezeroentries; c->freedata = PETSC_TRUE; if (a->diag) { ierr = PetscMalloc((m+1)*sizeof(int),&c->diag);CHKERRQ(ierr); PetscLogObjectMemory(C,(m+1)*sizeof(int)); for (i=0; idiag[i] = a->diag[i]; } } else c->diag = 0; c->inode.use = a->inode.use; c->inode.limit = a->inode.limit; c->inode.max_limit = a->inode.max_limit; if (a->inode.size){ ierr = PetscMalloc((m+1)*sizeof(int),&c->inode.size);CHKERRQ(ierr); c->inode.node_count = a->inode.node_count; ierr = PetscMemcpy(c->inode.size,a->inode.size,(m+1)*sizeof(int));CHKERRQ(ierr); } else { c->inode.size = 0; c->inode.node_count = 0; } c->nz = a->nz; c->maxnz = a->maxnz; c->solve_work = 0; C->spptr = 0; /* Dangerous -I'm throwing away a->spptr */ C->preallocated = PETSC_TRUE; *B = C; ierr = PetscFListDuplicate(A->qlist,&C->qlist);CHKERRQ(ierr); PetscFunctionReturn(0); } EXTERN_C_BEGIN #undef __FUNCT__ #define __FUNCT__ "MatLoad_SeqAIJ" int MatLoad_SeqAIJ(PetscViewer viewer,MatType type,Mat *A) { Mat_SeqAIJ *a; Mat B; int i,nz,ierr,fd,header[4],size,*rowlengths = 0,M,N,shift; MPI_Comm comm; PetscFunctionBegin; ierr = PetscObjectGetComm((PetscObject)viewer,&comm);CHKERRQ(ierr); ierr = MPI_Comm_size(comm,&size);CHKERRQ(ierr); if (size > 1) SETERRQ(PETSC_ERR_ARG_SIZ,"view must have one processor"); ierr = PetscViewerBinaryGetDescriptor(viewer,&fd);CHKERRQ(ierr); ierr = PetscBinaryRead(fd,header,4,PETSC_INT);CHKERRQ(ierr); if (header[0] != MAT_FILE_COOKIE) SETERRQ(PETSC_ERR_FILE_UNEXPECTED,"not matrix object in file"); M = header[1]; N = header[2]; nz = header[3]; if (nz < 0) { SETERRQ(PETSC_ERR_FILE_UNEXPECTED,"Matrix stored in special format on disk,cannot load as SeqAIJ"); } /* read in row lengths */ ierr = PetscMalloc(M*sizeof(int),&rowlengths);CHKERRQ(ierr); ierr = PetscBinaryRead(fd,rowlengths,M,PETSC_INT);CHKERRQ(ierr); /* create our matrix */ ierr = MatCreateSeqAIJ(comm,M,N,0,rowlengths,A);CHKERRQ(ierr); B = *A; a = (Mat_SeqAIJ*)B->data; shift = a->indexshift; /* read in column indices and adjust for Fortran indexing*/ ierr = PetscBinaryRead(fd,a->j,nz,PETSC_INT);CHKERRQ(ierr); if (shift) { for (i=0; ij[i] += 1; } } /* read in nonzero values */ ierr = PetscBinaryRead(fd,a->a,nz,PETSC_SCALAR);CHKERRQ(ierr); /* set matrix "i" values */ a->i[0] = -shift; for (i=1; i<= M; i++) { a->i[i] = a->i[i-1] + rowlengths[i-1]; a->ilen[i-1] = rowlengths[i-1]; } ierr = PetscFree(rowlengths);CHKERRQ(ierr); ierr = MatAssemblyBegin(B,MAT_FINAL_ASSEMBLY);CHKERRQ(ierr); ierr = MatAssemblyEnd(B,MAT_FINAL_ASSEMBLY);CHKERRQ(ierr); PetscFunctionReturn(0); } EXTERN_C_END #undef __FUNCT__ #define __FUNCT__ "MatEqual_SeqAIJ" int MatEqual_SeqAIJ(Mat A,Mat B,PetscTruth* flg) { Mat_SeqAIJ *a = (Mat_SeqAIJ *)A->data,*b = (Mat_SeqAIJ *)B->data; int ierr; PetscTruth flag; PetscFunctionBegin; ierr = PetscTypeCompare((PetscObject)B,MATSEQAIJ,&flag);CHKERRQ(ierr); if (!flag) SETERRQ(PETSC_ERR_ARG_INCOMP,"Matrices must be same type"); /* If the matrix dimensions are not equal,or no of nonzeros or shift */ if ((A->m != B->m) || (A->n != B->n) ||(a->nz != b->nz)|| (a->indexshift != b->indexshift)) { *flg = PETSC_FALSE; PetscFunctionReturn(0); } /* if the a->i are the same */ ierr = PetscMemcmp(a->i,b->i,(A->m+1)*sizeof(int),flg);CHKERRQ(ierr); if (*flg == PETSC_FALSE) PetscFunctionReturn(0); /* if a->j are the same */ ierr = PetscMemcmp(a->j,b->j,(a->nz)*sizeof(int),flg);CHKERRQ(ierr); if (*flg == PETSC_FALSE) PetscFunctionReturn(0); /* if a->a are the same */ ierr = PetscMemcmp(a->a,b->a,(a->nz)*sizeof(PetscScalar),flg);CHKERRQ(ierr); PetscFunctionReturn(0); } #undef __FUNCT__ #define __FUNCT__ "MatCreateSeqAIJWithArrays" /*@C MatCreateSeqAIJWithArrays - Creates an sequential AIJ matrix using matrix elements (in CSR format) provided by the user. Coolective on MPI_Comm Input Parameters: + comm - must be an MPI communicator of size 1 . m - number of rows . n - number of columns . i - row indices . j - column indices - a - matrix values Output Parameter: . mat - the matrix Level: intermediate Notes: The i, j, and a arrays are not copied by this routine, the user must free these arrays once the matrix is destroyed You cannot set new nonzero locations into this matrix, that will generate an error. The i and j indices can be either 0- or 1 based .seealso: MatCreate(), MatCreateMPIAIJ(), MatCreateSeqAIJ() @*/ int MatCreateSeqAIJWithArrays(MPI_Comm comm,int m,int n,int* i,int*j,PetscScalar *a,Mat *mat) { int ierr,ii; Mat_SeqAIJ *aij; PetscFunctionBegin; ierr = MatCreateSeqAIJ(comm,m,n,SKIP_ALLOCATION,0,mat);CHKERRQ(ierr); aij = (Mat_SeqAIJ*)(*mat)->data; if (i[0] == 1) { aij->indexshift = -1; } else if (i[0]) { SETERRQ(1,"i (row indices) do not start with 0 or 1"); } aij->i = i; aij->j = j; aij->a = a; aij->singlemalloc = PETSC_FALSE; aij->nonew = -1; /*this indicates that inserting a new value in the matrix that generates a new nonzero is an error*/ aij->freedata = PETSC_FALSE; for (ii=0; iiilen[ii] = aij->imax[ii] = i[ii+1] - i[ii]; #if defined(PETSC_USE_BOPT_g) if (i[ii+1] - i[ii] < 0) SETERRQ2(1,"Negative row length in i (row indices) row = %d length = %d",ii,i[ii+1] - i[ii]); #endif } #if defined(PETSC_USE_BOPT_g) for (ii=0; iii[m]; ii++) { if (j[ii] < -aij->indexshift) SETERRQ2(1,"Negative column index at location = %d index = %d",ii,j[ii]); if (j[ii] > n - 1 -aij->indexshift) SETERRQ2(1,"Column index to large at location = %d index = %d",ii,j[ii]); } #endif /* changes indices to start at 0 */ if (i[0]) { aij->indexshift = 0; for (ii=0; iidata; PetscFunctionBegin; if (coloring->ctype == IS_COLORING_LOCAL) { ierr = ISColoringReference(coloring);CHKERRQ(ierr); a->coloring = coloring; } else if (coloring->ctype == IS_COLORING_GHOSTED) { int *colors,i,*larray; ISColoring ocoloring; /* set coloring for diagonal portion */ ierr = PetscMalloc((A->n+1)*sizeof(int),&larray);CHKERRQ(ierr); for (i=0; in; i++) { larray[i] = i; } ierr = ISGlobalToLocalMappingApply(A->mapping,IS_GTOLM_MASK,A->n,larray,PETSC_NULL,larray);CHKERRQ(ierr); ierr = PetscMalloc((A->n+1)*sizeof(int),&colors);CHKERRQ(ierr); for (i=0; in; i++) { colors[i] = coloring->colors[larray[i]]; } ierr = PetscFree(larray);CHKERRQ(ierr); ierr = ISColoringCreate(PETSC_COMM_SELF,A->n,colors,&ocoloring);CHKERRQ(ierr); a->coloring = ocoloring; } PetscFunctionReturn(0); } #if defined(PETSC_HAVE_ADIC) && !defined(PETSC_USE_COMPLEX) && !defined(PETSC_USE_SINGLE) EXTERN_C_BEGIN #include "adic/ad_utils.h" EXTERN_C_END #undef __FUNCT__ #define __FUNCT__ "MatSetValuesAdic_SeqAIJ" int MatSetValuesAdic_SeqAIJ(Mat A,void *advalues) { Mat_SeqAIJ *a = (Mat_SeqAIJ*)A->data; int m = A->m,*ii = a->i,*jj = a->j,nz,i,*color,j,nlen; PetscScalar *v = a->a,*values; char *cadvalues = (char *)advalues; PetscFunctionBegin; if (!a->coloring) SETERRQ(1,"Coloring not set for matrix"); nlen = PetscADGetDerivTypeSize(); color = a->coloring->colors; /* loop over rows */ for (i=0; idata; int m = A->m,*ii = a->i,*jj = a->j,nz,i,*color,j; PetscScalar *v = a->a,*values = (PetscScalar *)advalues; PetscFunctionBegin; if (!a->coloring) SETERRQ(1,"Coloring not set for matrix"); color = a->coloring->colors; /* loop over rows */ for (i=0; i