github.com/gopherd/gonum@v0.0.4/lapack/testlapack/dgehd2.go (about) 1 // Copyright ©2016 The Gonum Authors. All rights reserved. 2 // Use of this source code is governed by a BSD-style 3 // license that can be found in the LICENSE file. 4 5 package testlapack 6 7 import ( 8 "fmt" 9 "math" 10 "testing" 11 12 "math/rand" 13 14 "github.com/gopherd/gonum/blas" 15 "github.com/gopherd/gonum/blas/blas64" 16 ) 17 18 type Dgehd2er interface { 19 Dgehd2(n, ilo, ihi int, a []float64, lda int, tau, work []float64) 20 } 21 22 func Dgehd2Test(t *testing.T, impl Dgehd2er) { 23 rnd := rand.New(rand.NewSource(1)) 24 for _, n := range []int{1, 2, 3, 4, 5, 7, 10, 30} { 25 for _, extra := range []int{0, 1, 13} { 26 for cas := 0; cas < 100; cas++ { 27 testDgehd2(t, impl, n, extra, rnd) 28 } 29 } 30 } 31 } 32 33 func testDgehd2(t *testing.T, impl Dgehd2er, n, extra int, rnd *rand.Rand) { 34 const tol = 1e-14 35 36 ilo := rnd.Intn(n) 37 ihi := rnd.Intn(n) 38 if ilo > ihi { 39 ilo, ihi = ihi, ilo 40 } 41 42 tau := nanSlice(n - 1) 43 work := nanSlice(n) 44 45 a := randomGeneral(n, n, n+extra, rnd) 46 // NaN out elements under the diagonal except 47 // for the [ilo:ihi,ilo:ihi] block. 48 for i := 1; i <= ihi; i++ { 49 for j := 0; j < min(ilo, i); j++ { 50 a.Data[i*a.Stride+j] = math.NaN() 51 } 52 } 53 for i := ihi + 1; i < n; i++ { 54 for j := 0; j < i; j++ { 55 a.Data[i*a.Stride+j] = math.NaN() 56 } 57 } 58 aCopy := a 59 aCopy.Data = make([]float64, len(a.Data)) 60 copy(aCopy.Data, a.Data) 61 62 impl.Dgehd2(n, ilo, ihi, a.Data, a.Stride, tau, work) 63 64 prefix := fmt.Sprintf("Case n=%v, ilo=%v, ihi=%v, extra=%v", n, ilo, ihi, extra) 65 66 // Check any invalid modifications of a. 67 if !generalOutsideAllNaN(a) { 68 t.Errorf("%v: out-of-range write to A\n%v", prefix, a.Data) 69 } 70 for i := ilo; i <= ihi; i++ { 71 for j := 0; j < min(ilo, i); j++ { 72 if !math.IsNaN(a.Data[i*a.Stride+j]) { 73 t.Errorf("%v: expected NaN at A[%v,%v]", prefix, i, j) 74 } 75 } 76 } 77 for i := ihi + 1; i < n; i++ { 78 for j := 0; j < i; j++ { 79 if !math.IsNaN(a.Data[i*a.Stride+j]) { 80 t.Errorf("%v: expected NaN at A[%v,%v]", prefix, i, j) 81 } 82 } 83 } 84 for i := 0; i <= ilo; i++ { 85 for j := i; j < ilo+1; j++ { 86 if a.Data[i*a.Stride+j] != aCopy.Data[i*aCopy.Stride+j] { 87 t.Errorf("%v: unexpected modification at A[%v,%v]", prefix, i, j) 88 } 89 } 90 for j := ihi + 1; j < n; j++ { 91 if a.Data[i*a.Stride+j] != aCopy.Data[i*aCopy.Stride+j] { 92 t.Errorf("%v: unexpected modification at A[%v,%v]", prefix, i, j) 93 } 94 } 95 } 96 for i := ihi + 1; i < n; i++ { 97 for j := i; j < n; j++ { 98 if a.Data[i*a.Stride+j] != aCopy.Data[i*aCopy.Stride+j] { 99 t.Errorf("%v: unexpected modification at A[%v,%v]", prefix, i, j) 100 } 101 } 102 } 103 104 // Check that tau has been assigned properly. 105 for i, v := range tau { 106 if i < ilo || i >= ihi { 107 if !math.IsNaN(v) { 108 t.Errorf("%v: expected NaN at tau[%v]", prefix, i) 109 } 110 } else { 111 if math.IsNaN(v) { 112 t.Errorf("%v: unexpected NaN at tau[%v]", prefix, i) 113 } 114 } 115 } 116 117 // Extract Q and check that it is orthogonal. 118 q := blas64.General{ 119 Rows: n, 120 Cols: n, 121 Stride: n, 122 Data: make([]float64, n*n), 123 } 124 for i := 0; i < q.Rows; i++ { 125 q.Data[i*q.Stride+i] = 1 126 } 127 qCopy := q 128 qCopy.Data = make([]float64, len(q.Data)) 129 for j := ilo; j < ihi; j++ { 130 h := blas64.General{ 131 Rows: n, 132 Cols: n, 133 Stride: n, 134 Data: make([]float64, n*n), 135 } 136 for i := 0; i < h.Rows; i++ { 137 h.Data[i*h.Stride+i] = 1 138 } 139 v := blas64.Vector{ 140 Inc: 1, 141 Data: make([]float64, n), 142 } 143 v.Data[j+1] = 1 144 for i := j + 2; i < ihi+1; i++ { 145 v.Data[i] = a.Data[i*a.Stride+j] 146 } 147 blas64.Ger(-tau[j], v, v, h) 148 copy(qCopy.Data, q.Data) 149 blas64.Gemm(blas.NoTrans, blas.NoTrans, 1, qCopy, h, 0, q) 150 } 151 if resid := residualOrthogonal(q, false); resid > tol { 152 t.Errorf("%v: Q is not orthogonal; resid=%v, want<=%v", prefix, resid, tol) 153 } 154 155 // Overwrite NaN elements of aCopy with zeros 156 // (we will multiply with it below). 157 for i := 1; i <= ihi; i++ { 158 for j := 0; j < min(ilo, i); j++ { 159 aCopy.Data[i*aCopy.Stride+j] = 0 160 } 161 } 162 for i := ihi + 1; i < n; i++ { 163 for j := 0; j < i; j++ { 164 aCopy.Data[i*aCopy.Stride+j] = 0 165 } 166 } 167 168 // Construct Qᵀ * AOrig * Q and check that it is 169 // equal to A from Dgehd2. 170 aq := blas64.General{ 171 Rows: n, 172 Cols: n, 173 Stride: n, 174 Data: make([]float64, n*n), 175 } 176 blas64.Gemm(blas.NoTrans, blas.NoTrans, 1, aCopy, q, 0, aq) 177 qaq := blas64.General{ 178 Rows: n, 179 Cols: n, 180 Stride: n, 181 Data: make([]float64, n*n), 182 } 183 blas64.Gemm(blas.Trans, blas.NoTrans, 1, q, aq, 0, qaq) 184 for i := ilo; i <= ihi; i++ { 185 for j := ilo; j <= ihi; j++ { 186 qaqij := qaq.Data[i*qaq.Stride+j] 187 if j < i-1 { 188 if math.Abs(qaqij) > tol { 189 t.Errorf("%v: Qᵀ*A*Q is not upper Hessenberg, [%v,%v]=%v", prefix, i, j, qaqij) 190 } 191 continue 192 } 193 diff := qaqij - a.Data[i*a.Stride+j] 194 if math.Abs(diff) > tol { 195 t.Errorf("%v: Qᵀ*AOrig*Q and A are not equal, diff at [%v,%v]=%v", prefix, i, j, diff) 196 } 197 } 198 } 199 }