func main() { mpi.Start(false) defer func() { mpi.Stop(false) }() myrank := mpi.Rank() if myrank == 0 { chk.PrintTitle("Test MUMPS Sol 05") } ndim := 10 id, sz := mpi.Rank(), mpi.Size() start, endp1 := (id*ndim)/sz, ((id+1)*ndim)/sz if mpi.Size() > ndim { chk.Panic("the number of processors must be smaller than or equal to %d", ndim) } n := 10 b := make([]complex128, n) x_correct := make([]complex128, n) // Let exact solution = 1 + 0.5i for i := 0; i < ndim; i++ { x_correct[i] = complex(float64(i+1), float64(i+1)/10.0) } var t la.TripletC t.Init(ndim, ndim, ndim, true) // assemble a and b for i := start; i < endp1; i++ { // Some very fake diagonals. Should take exactly 20 GMRES steps ar := 10.0 + float64(i)/(float64(ndim)/10.0) ac := 10.0 - float64(i)/(float64(ndim)/10.0) t.Put(i, i, ar, ac) // Generate RHS to match exact solution b[i] = complex(ar*real(x_correct[i])-ac*imag(x_correct[i]), ar*imag(x_correct[i])+ac*real(x_correct[i])) } sum_b_to_root := true la.RunMumpsTestC(&t, 1e-14, b, x_correct, sum_b_to_root) }
func main() { mpi.Start(false) defer func() { mpi.Stop(false) }() myrank := mpi.Rank() if myrank == 0 { chk.PrintTitle("Test MUMPS Sol 04") } ndim := 10 id, sz := mpi.Rank(), mpi.Size() start, endp1 := (id*ndim)/sz, ((id+1)*ndim)/sz if mpi.Size() > ndim { chk.Panic("the number of processors must be smaller than or equal to %d", ndim) } b := make([]complex128, ndim) var t la.TripletC t.Init(ndim, ndim, ndim*ndim, true) for i := start; i < endp1; i++ { j := i if i > 0 { j = i - 1 } for ; j < 10; j++ { val := 10.0 - float64(j) if i > j { val -= 1.0 } t.Put(i, j, val, 0) } b[i] = complex(float64(i+1), 0.0) } x_correct := []complex128{-1, 8, -65, 454, -2725, 13624, -54497, 163490, -326981, 326991} sum_b_to_root := true la.RunMumpsTestC(&t, 1e-4, b, x_correct, sum_b_to_root) }
func main() { mpi.Start(false) defer func() { mpi.Stop(false) }() myrank := mpi.Rank() if myrank == 0 { chk.PrintTitle("Test MUMPS Sol 03") } var t la.TripletC switch mpi.Size() { case 1: t.Init(5, 5, 13, true) t.Put(0, 0, 1.0, 0) t.Put(0, 0, 1.0, 0) t.Put(1, 0, 3.0, 0) t.Put(0, 1, 3.0, 0) t.Put(2, 1, -1.0, 0) t.Put(4, 1, 4.0, 0) t.Put(1, 2, 4.0, 0) t.Put(2, 2, -3.0, 0) t.Put(3, 2, 1.0, 0) t.Put(4, 2, 2.0, 0) t.Put(2, 3, 2.0, 0) t.Put(1, 4, 6.0, 0) t.Put(4, 4, 1.0, 0) case 2: if myrank == 0 { t.Init(5, 5, 6, true) t.Put(0, 0, 1.0, 0) t.Put(0, 0, 1.0, 0) t.Put(1, 0, 3.0, 0) t.Put(0, 1, 3.0, 0) t.Put(2, 1, -1.0, 0) t.Put(4, 1, 4.0, 0) } else { t.Init(5, 5, 7, true) t.Put(1, 2, 4.0, 0) t.Put(2, 2, -3.0, 0) t.Put(3, 2, 1.0, 0) t.Put(4, 2, 2.0, 0) t.Put(2, 3, 2.0, 0) t.Put(1, 4, 6.0, 0) t.Put(4, 4, 1.0, 0) } default: chk.Panic("this test needs 1 or 2 procs") } b := []complex128{8.0, 45.0, -3.0, 3.0, 19.0} x_correct := []complex128{1, 2, 3, 4, 5} sum_b_to_root := false la.RunMumpsTestC(&t, 1e-14, b, x_correct, sum_b_to_root) }
func main() { // given the following matrix of complex numbers: // _ _ // | 19.73 12.11-i 5i 0 0 | // | -0.51i 32.3+7i 23.07 i 0 | // A = | 0 -0.51i 70+7.3i 3.95 19+31.83i | // | 0 0 1+1.1i 50.17 45.51 | // |_ 0 0 0 -9.351i 55 _| // // and the following vector: // _ _ // | 77.38+8.82i | // | 157.48+19.8i | // b = | 1175.62+20.69i | // | 912.12-801.75i | // |_ 550-1060.4i _| // // solve: // A.x = b // // the solution is: // _ _ // | 3.3-i | // | 1+0.17i | // x = | 5.5 | // | 9 | // |_ 10-17.75i _| // flag indicating to store (real,complex) values in monolithic form => 1D array xzmono := false // input matrix in Complex Triplet format var A la.TripletC A.Init(5, 5, 16, xzmono) // 5 x 5 matrix with 16 non-zeros // first column A.Put(0, 0, 19.73, 0) // i=0, j=0, real=19.73, complex=0 A.Put(1, 0, 0, -0.51) // i=1, j=0, real=0, complex=-0.51 // second column A.Put(0, 1, 12.11, -1) // i=0, j=1, real=12.11, complex=-1 A.Put(1, 1, 32.3, 7) A.Put(2, 1, 0, -0.51) // third column A.Put(0, 2, 0, 5) A.Put(1, 2, 23.07, 0) A.Put(2, 2, 70, 7.3) A.Put(3, 2, 1, 1.1) // fourth column A.Put(1, 3, 0, 1) A.Put(2, 3, 3.95, 0) A.Put(3, 3, 50.17, 0) A.Put(4, 3, 0, -9.351) // fifth column A.Put(2, 4, 19, 31.83) A.Put(3, 4, 45.51, 0) A.Put(4, 4, 55, 0) // right-hand-side b := []complex128{ 77.38 + 8.82i, 157.48 + 19.8i, 1175.62 + 20.69i, 912.12 - 801.75i, 550 - 1060.4i, } // allocate solver lis := la.GetSolver("umfpack") defer lis.Clean() // info symmetric := false verbose := false timing := false // initialise solver (C)omplex err := lis.InitC(&A, symmetric, verbose, timing) if err != nil { io.Pfred("solver failed:\n%v", err) return } // factorise err = lis.Fact() if err != nil { io.Pfred("solver failed:\n%v", err) return } // auxiliary variables bR, bC := la.ComplexToRC(b) // real and complex components of b xR := make([]float64, len(b)) // real compoments of x xC := make([]float64, len(b)) // complex compoments of x // solve (C)omplex var dummy bool err = lis.SolveC(xR, xC, bR, bC, dummy) // x := inv(A) * b if err != nil { io.Pfred("solver failed:\n%v", err) return } // join solution vector x := la.RCtoComplex(xR, xC) // output a := A.ToMatrix(nil) io.Pforan("A.x = b\n") la.PrintMatC("A", a.ToDense(), "(%5g", "%+6gi) ", false) la.PrintVecC("b", b, "(%g", "%+gi) ", false) la.PrintVecC("x", x, "(%.3f", "%+.3fi) ", false) }
func main() { // given the following matrix of complex numbers: // _ _ // | 19.73 12.11-i 5i 0 0 | // | -0.51i 32.3+7i 23.07 i 0 | // A = | 0 -0.51i 70+7.3i 3.95 19+31.83i | // | 0 0 1+1.1i 50.17 45.51 | // |_ 0 0 0 -9.351i 55 _| // // and the following vector: // _ _ // | 77.38+8.82i | // | 157.48+19.8i | // b = | 1175.62+20.69i | // | 912.12-801.75i | // |_ 550-1060.4i _| // // solve: // A.x = b // // the solution is: // _ _ // | 3.3-i | // | 1+0.17i | // x = | 5.5 | // | 9 | // |_ 10-17.75i _| // flag indicating to store (real,complex) values in monolithic form => 1D array xzmono := false // input matrix in Complex Triplet format var A la.TripletC A.Init(5, 5, 16, xzmono) // 5 x 5 matrix with 16 non-zeros // first column A.Put(0, 0, 19.73, 0) // i=0, j=0, real=19.73, complex=0 A.Put(1, 0, 0, -0.51) // i=1, j=0, real=0, complex=-0.51 // second column A.Put(0, 1, 12.11, -1) // i=0, j=1, real=12.11, complex=-1 A.Put(1, 1, 32.3, 7) A.Put(2, 1, 0, -0.51) // third column A.Put(0, 2, 0, 5) A.Put(1, 2, 23.07, 0) A.Put(2, 2, 70, 7.3) A.Put(3, 2, 1, 1.1) // fourth column A.Put(1, 3, 0, 1) A.Put(2, 3, 3.95, 0) A.Put(3, 3, 50.17, 0) A.Put(4, 3, 0, -9.351) // fifth column A.Put(2, 4, 19, 31.83) A.Put(3, 4, 45.51, 0) A.Put(4, 4, 55, 0) // right-hand-side b := []complex128{ 77.38 + 8.82i, 157.48 + 19.8i, 1175.62 + 20.69i, 912.12 - 801.75i, 550 - 1060.4i, } // solve x, err := la.SolveComplexLinSys(&A, b) if err != nil { io.Pfred("solver failed:\n%v", err) return } // output a := A.ToMatrix(nil) io.Pforan("A.x = b\n") la.PrintMatC("A", a.ToDense(), "(%5g", "%+6gi) ", false) la.PrintVecC("b", b, "(%g", "%+gi) ", false) la.PrintVecC("x", x, "(%.3f", "%+.3fi) ", false) }