Actual source code: butterfly.c

slepc-3.11.2 2019-07-30
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  1: /*
  2:    - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
  3:    SLEPc - Scalable Library for Eigenvalue Problem Computations
  4:    Copyright (c) 2002-2019, Universitat Politecnica de Valencia, Spain

  6:    This file is part of SLEPc.
  7:    SLEPc is distributed under a 2-clause BSD license (see LICENSE).
  8:    - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
  9: */
 10: /*
 11:    This example implements one of the problems found at
 12:        NLEVP: A Collection of Nonlinear Eigenvalue Problems,
 13:        The University of Manchester.
 14:    The details of the collection can be found at:
 15:        [1] T. Betcke et al., "NLEVP: A Collection of Nonlinear Eigenvalue
 16:            Problems", ACM Trans. Math. Software 39(2), Article 7, 2013.

 18:    The butterfly problem is a quartic PEP with T-even structure.
 19: */

 21: static char help[] = "Quartic polynomial eigenproblem with T-even structure.\n\n"
 22:   "The command line options are:\n"
 23:   "  -m <m>, grid size, the dimension of the matrices is n=m*m.\n"
 24:   "  -c <array>, problem parameters, must be 10 comma-separated real values.\n\n";

 26: #include <slepcpep.h>

 28: #define NMAT 5

 30: int main(int argc,char **argv)
 31: {
 32:   Mat            A[NMAT];         /* problem matrices */
 33:   PEP            pep;             /* polynomial eigenproblem solver context */
 34:   PetscInt       n,m=8,k,II,Istart,Iend,i,j;
 35:   PetscReal      c[10] = { 0.6, 1.3, 1.3, 0.1, 0.1, 1.2, 1.0, 1.0, 1.2, 1.0 };
 36:   PetscBool      flg;
 37:   PetscBool      terse;

 40:   SlepcInitialize(&argc,&argv,(char*)0,help);if (ierr) return ierr;

 42:   PetscOptionsGetInt(NULL,NULL,"-m",&m,NULL);
 43:   n = m*m;
 44:   k = 10;
 45:   PetscOptionsGetRealArray(NULL,NULL,"-c",c,&k,&flg);
 46:   if (flg && k!=10) SETERRQ1(PETSC_COMM_WORLD,1,"The number of parameters -c should be 10, you provided %D",k);
 47:   PetscPrintf(PETSC_COMM_WORLD,"\nButterfly problem, n=%D (m=%D)\n\n",n,m);

 49:   /* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
 50:                      Compute the polynomial matrices
 51:      - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

 53:   /* initialize matrices */
 54:   for (i=0;i<NMAT;i++) {
 55:     MatCreate(PETSC_COMM_WORLD,&A[i]);
 56:     MatSetSizes(A[i],PETSC_DECIDE,PETSC_DECIDE,n,n);
 57:     MatSetFromOptions(A[i]);
 58:     MatSetUp(A[i]);
 59:   }
 60:   MatGetOwnershipRange(A[0],&Istart,&Iend);

 62:   /* A0 */
 63:   for (II=Istart;II<Iend;II++) {
 64:     i = II/m; j = II-i*m;
 65:     MatSetValue(A[0],II,II,4.0*c[0]/6.0+4.0*c[1]/6.0,INSERT_VALUES);
 66:     if (j>0) { MatSetValue(A[0],II,II-1,c[0]/6.0,INSERT_VALUES); }
 67:     if (j<m-1) { MatSetValue(A[0],II,II+1,c[0]/6.0,INSERT_VALUES); }
 68:     if (i>0) { MatSetValue(A[0],II,II-m,c[1]/6.0,INSERT_VALUES); }
 69:     if (i<m-1) { MatSetValue(A[0],II,II+m,c[1]/6.0,INSERT_VALUES); }
 70:   }

 72:   /* A1 */
 73:   for (II=Istart;II<Iend;II++) {
 74:     i = II/m; j = II-i*m;
 75:     if (j>0) { MatSetValue(A[1],II,II-1,c[2],INSERT_VALUES); }
 76:     if (j<m-1) { MatSetValue(A[1],II,II+1,-c[2],INSERT_VALUES); }
 77:     if (i>0) { MatSetValue(A[1],II,II-m,c[3],INSERT_VALUES); }
 78:     if (i<m-1) { MatSetValue(A[1],II,II+m,-c[3],INSERT_VALUES); }
 79:   }

 81:   /* A2 */
 82:   for (II=Istart;II<Iend;II++) {
 83:     i = II/m; j = II-i*m;
 84:     MatSetValue(A[2],II,II,-2.0*c[4]-2.0*c[5],INSERT_VALUES);
 85:     if (j>0) { MatSetValue(A[2],II,II-1,c[4],INSERT_VALUES); }
 86:     if (j<m-1) { MatSetValue(A[2],II,II+1,c[4],INSERT_VALUES); }
 87:     if (i>0) { MatSetValue(A[2],II,II-m,c[5],INSERT_VALUES); }
 88:     if (i<m-1) { MatSetValue(A[2],II,II+m,c[5],INSERT_VALUES); }
 89:   }

 91:   /* A3 */
 92:   for (II=Istart;II<Iend;II++) {
 93:     i = II/m; j = II-i*m;
 94:     if (j>0) { MatSetValue(A[3],II,II-1,c[6],INSERT_VALUES); }
 95:     if (j<m-1) { MatSetValue(A[3],II,II+1,-c[6],INSERT_VALUES); }
 96:     if (i>0) { MatSetValue(A[3],II,II-m,c[7],INSERT_VALUES); }
 97:     if (i<m-1) { MatSetValue(A[3],II,II+m,-c[7],INSERT_VALUES); }
 98:   }

100:   /* A4 */
101:   for (II=Istart;II<Iend;II++) {
102:     i = II/m; j = II-i*m;
103:     MatSetValue(A[4],II,II,2.0*c[8]+2.0*c[9],INSERT_VALUES);
104:     if (j>0) { MatSetValue(A[4],II,II-1,-c[8],INSERT_VALUES); }
105:     if (j<m-1) { MatSetValue(A[4],II,II+1,-c[8],INSERT_VALUES); }
106:     if (i>0) { MatSetValue(A[4],II,II-m,-c[9],INSERT_VALUES); }
107:     if (i<m-1) { MatSetValue(A[4],II,II+m,-c[9],INSERT_VALUES); }
108:   }

110:   /* assemble matrices */
111:   for (i=0;i<NMAT;i++) {
112:     MatAssemblyBegin(A[i],MAT_FINAL_ASSEMBLY);
113:   }
114:   for (i=0;i<NMAT;i++) {
115:     MatAssemblyEnd(A[i],MAT_FINAL_ASSEMBLY);
116:   }

118:   /* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
119:                 Create the eigensolver and solve the problem
120:      - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

122:   PEPCreate(PETSC_COMM_WORLD,&pep);
123:   PEPSetOperators(pep,NMAT,A);
124:   PEPSetFromOptions(pep);
125:   PEPSolve(pep);

127:   /* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
128:                     Display solution and clean up
129:      - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */

131:   /* show detailed info unless -terse option is given by user */
132:   PetscOptionsHasName(NULL,NULL,"-terse",&terse);
133:   if (terse) {
134:     PEPErrorView(pep,PEP_ERROR_BACKWARD,NULL);
135:   } else {
136:     PetscViewerPushFormat(PETSC_VIEWER_STDOUT_WORLD,PETSC_VIEWER_ASCII_INFO_DETAIL);
137:     PEPReasonView(pep,PETSC_VIEWER_STDOUT_WORLD);
138:     PEPErrorView(pep,PEP_ERROR_BACKWARD,PETSC_VIEWER_STDOUT_WORLD);
139:     PetscViewerPopFormat(PETSC_VIEWER_STDOUT_WORLD);
140:   }
141:   PEPDestroy(&pep);
142:   for (i=0;i<NMAT;i++) {
143:     MatDestroy(&A[i]);
144:   }
145:   SlepcFinalize();
146:   return ierr;
147: }

149: /*TEST

151:    testset:
152:       args: -pep_nev 4 -st_type sinvert -pep_target 0.01 -terse
153:       requires: !complex
154:       output_file: output/butterfly_1.out
155:       test:
156:          suffix: 1_toar
157:          args: -pep_type toar -pep_toar_restart 0.3
158:       test:
159:          suffix: 1_linear
160:          args: -pep_type linear

162:    test:
163:       suffix: 2
164:       args: -pep_type {{toar linear}} -pep_nev 4 -terse
165:       requires: double !complex !define(PETSC_USE_64BIT_INDICES)

167: TEST*/