Actual source code: sbaijfact4.c
petsc-3.13.6 2020-09-29
2: #include <../src/mat/impls/sbaij/seq/sbaij.h>
3: #include <petsc/private/kernels/blockinvert.h>
5: /*
6: Version for when blocks are 3 by 3 Using natural ordering
7: */
8: PetscErrorCode MatCholeskyFactorNumeric_SeqSBAIJ_3_NaturalOrdering(Mat C,Mat A,const MatFactorInfo *info)
9: {
10: Mat_SeqSBAIJ *a = (Mat_SeqSBAIJ*)A->data,*b = (Mat_SeqSBAIJ*)C->data;
12: PetscInt i,j,mbs=a->mbs,*bi=b->i,*bj=b->j;
13: PetscInt *ai,*aj,k,k1,jmin,jmax,*jl,*il,vj,nexti,ili;
14: MatScalar *ba = b->a,*aa,*ap,*dk,*uik;
15: MatScalar *u,*diag,*rtmp,*rtmp_ptr;
16: PetscReal shift = info->shiftamount;
17: PetscBool allowzeropivot,zeropivotdetected;
20: /* initialization */
21: allowzeropivot = PetscNot(A->erroriffailure);
22: PetscCalloc1(9*mbs,&rtmp);
23: PetscMalloc2(mbs,&il,mbs,&jl);
24: il[0] = 0;
25: for (i=0; i<mbs; i++) jl[i] = mbs;
26:
27: PetscMalloc2(9,&dk,9,&uik);
28: ai = a->i; aj = a->j; aa = a->a;
30: /* for each row k */
31: for (k = 0; k<mbs; k++) {
33: /*initialize k-th row with elements nonzero in row k of A */
34: jmin = ai[k]; jmax = ai[k+1];
35: if (jmin < jmax) {
36: ap = aa + jmin*9;
37: for (j = jmin; j < jmax; j++) {
38: vj = aj[j]; /* block col. index */
39: rtmp_ptr = rtmp + vj*9;
40: for (i=0; i<9; i++) *rtmp_ptr++ = *ap++;
41: }
42: }
44: /* modify k-th row by adding in those rows i with U(i,k) != 0 */
45: PetscArraycpy(dk,rtmp+k*9,9);
46: i = jl[k]; /* first row to be added to k_th row */
48: while (i < mbs) {
49: nexti = jl[i]; /* next row to be added to k_th row */
51: /* compute multiplier */
52: ili = il[i]; /* index of first nonzero element in U(i,k:bms-1) */
54: /* uik = -inv(Di)*U_bar(i,k) */
55: diag = ba + i*9;
56: u = ba + ili*9;
58: uik[0] = -(diag[0]*u[0] + diag[3]*u[1] + diag[6]*u[2]);
59: uik[1] = -(diag[1]*u[0] + diag[4]*u[1] + diag[7]*u[2]);
60: uik[2] = -(diag[2]*u[0] + diag[5]*u[1] + diag[8]*u[2]);
62: uik[3] = -(diag[0]*u[3] + diag[3]*u[4] + diag[6]*u[5]);
63: uik[4] = -(diag[1]*u[3] + diag[4]*u[4] + diag[7]*u[5]);
64: uik[5] = -(diag[2]*u[3] + diag[5]*u[4] + diag[8]*u[5]);
66: uik[6] = -(diag[0]*u[6] + diag[3]*u[7] + diag[6]*u[8]);
67: uik[7] = -(diag[1]*u[6] + diag[4]*u[7] + diag[7]*u[8]);
68: uik[8] = -(diag[2]*u[6] + diag[5]*u[7] + diag[8]*u[8]);
70: /* update D(k) += -U(i,k)^T * U_bar(i,k) */
71: dk[0] += uik[0]*u[0] + uik[1]*u[1] + uik[2]*u[2];
72: dk[1] += uik[3]*u[0] + uik[4]*u[1] + uik[5]*u[2];
73: dk[2] += uik[6]*u[0] + uik[7]*u[1] + uik[8]*u[2];
75: dk[3] += uik[0]*u[3] + uik[1]*u[4] + uik[2]*u[5];
76: dk[4] += uik[3]*u[3] + uik[4]*u[4] + uik[5]*u[5];
77: dk[5] += uik[6]*u[3] + uik[7]*u[4] + uik[8]*u[5];
79: dk[6] += uik[0]*u[6] + uik[1]*u[7] + uik[2]*u[8];
80: dk[7] += uik[3]*u[6] + uik[4]*u[7] + uik[5]*u[8];
81: dk[8] += uik[6]*u[6] + uik[7]*u[7] + uik[8]*u[8];
83: PetscLogFlops(27.0*4.0);
85: /* update -U(i,k) */
86: PetscArraycpy(ba+ili*9,uik,9);
88: /* add multiple of row i to k-th row ... */
89: jmin = ili + 1; jmax = bi[i+1];
90: if (jmin < jmax) {
91: for (j=jmin; j<jmax; j++) {
92: /* rtmp += -U(i,k)^T * U_bar(i,j) */
93: rtmp_ptr = rtmp + bj[j]*9;
94: u = ba + j*9;
95: rtmp_ptr[0] += uik[0]*u[0] + uik[1]*u[1] + uik[2]*u[2];
96: rtmp_ptr[1] += uik[3]*u[0] + uik[4]*u[1] + uik[5]*u[2];
97: rtmp_ptr[2] += uik[6]*u[0] + uik[7]*u[1] + uik[8]*u[2];
99: rtmp_ptr[3] += uik[0]*u[3] + uik[1]*u[4] + uik[2]*u[5];
100: rtmp_ptr[4] += uik[3]*u[3] + uik[4]*u[4] + uik[5]*u[5];
101: rtmp_ptr[5] += uik[6]*u[3] + uik[7]*u[4] + uik[8]*u[5];
103: rtmp_ptr[6] += uik[0]*u[6] + uik[1]*u[7] + uik[2]*u[8];
104: rtmp_ptr[7] += uik[3]*u[6] + uik[4]*u[7] + uik[5]*u[8];
105: rtmp_ptr[8] += uik[6]*u[6] + uik[7]*u[7] + uik[8]*u[8];
106: }
107: PetscLogFlops(2.0*27.0*(jmax-jmin));
109: /* ... add i to row list for next nonzero entry */
110: il[i] = jmin; /* update il(i) in column k+1, ... mbs-1 */
111: j = bj[jmin];
112: jl[i] = jl[j]; jl[j] = i; /* update jl */
113: }
114: i = nexti;
115: }
117: /* save nonzero entries in k-th row of U ... */
119: /* invert diagonal block */
120: diag = ba+k*9;
121: PetscArraycpy(diag,dk,9);
122: PetscKernel_A_gets_inverse_A_3(diag,shift,allowzeropivot,&zeropivotdetected);
123: if (zeropivotdetected) C->factorerrortype = MAT_FACTOR_NUMERIC_ZEROPIVOT;
125: jmin = bi[k]; jmax = bi[k+1];
126: if (jmin < jmax) {
127: for (j=jmin; j<jmax; j++) {
128: vj = bj[j]; /* block col. index of U */
129: u = ba + j*9;
130: rtmp_ptr = rtmp + vj*9;
131: for (k1=0; k1<9; k1++) {
132: *u++ = *rtmp_ptr;
133: *rtmp_ptr++ = 0.0;
134: }
135: }
137: /* ... add k to row list for first nonzero entry in k-th row */
138: il[k] = jmin;
139: i = bj[jmin];
140: jl[k] = jl[i]; jl[i] = k;
141: }
142: }
144: PetscFree(rtmp);
145: PetscFree2(il,jl);
146: PetscFree2(dk,uik);
148: C->ops->solve = MatSolve_SeqSBAIJ_3_NaturalOrdering_inplace;
149: C->ops->solvetranspose = MatSolve_SeqSBAIJ_3_NaturalOrdering_inplace;
150: C->ops->forwardsolve = MatForwardSolve_SeqSBAIJ_3_NaturalOrdering_inplace;
151: C->ops->backwardsolve = MatBackwardSolve_SeqSBAIJ_3_NaturalOrdering_inplace;
153: C->assembled = PETSC_TRUE;
154: C->preallocated = PETSC_TRUE;
156: PetscLogFlops(1.3333*27*b->mbs); /* from inverting diagonal blocks */
157: return(0);
158: }