// Copyright ©2018 The Gonum Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package testblas import ( "fmt" "testing" "golang.org/x/exp/rand" "gonum.org/v1/gonum/blas" ) type Zgbmver interface { Zgbmv(trans blas.Transpose, m, n, kL, kU int, alpha complex128, ab []complex128, ldab int, x []complex128, incX int, beta complex128, y []complex128, incY int) Zgemver } func ZgbmvTest(t *testing.T, impl Zgbmver) { rnd := rand.New(rand.NewSource(1)) for _, trans := range []blas.Transpose{blas.NoTrans, blas.Trans, blas.ConjTrans} { // Generate all possible size combinations. for _, mn := range allPairs([]int{1, 2, 3, 5}, []int{1, 2, 3, 5}) { m := mn[0] n := mn[1] // Generate all possible numbers of lower and upper // diagonals. Use slices to reduce indentation. kLs := make([]int, max(1, m)) for i := range kLs { kLs[i] = i } kUs := make([]int, max(1, n)) for i := range kUs { kUs[i] = i } for _, ks := range allPairs(kLs, kUs) { kL := ks[0] kU := ks[1] for _, ab := range []struct { alpha complex128 beta complex128 }{ // All potentially relevant values of // alpha and beta. {0, 0}, {0, 1}, {0, complex(rnd.NormFloat64(), rnd.NormFloat64())}, {complex(rnd.NormFloat64(), rnd.NormFloat64()), 0}, {complex(rnd.NormFloat64(), rnd.NormFloat64()), 1}, {complex(rnd.NormFloat64(), rnd.NormFloat64()), complex(rnd.NormFloat64(), rnd.NormFloat64())}, } { for _, ldab := range []int{kL + kU + 1, kL + kU + 20} { for _, inc := range allPairs([]int{-3, -2, -1, 1, 2, 3}, []int{-3, -2, -1, 1, 2, 3}) { incX := inc[0] incY := inc[1] testZgbmv(t, impl, rnd, trans, m, n, kL, kU, ab.alpha, ab.beta, ldab, incX, incY) } } } } } } } // testZgbmv tests Zgbmv by comparing its output to that of Zgemv. func testZgbmv(t *testing.T, impl Zgbmver, rnd *rand.Rand, trans blas.Transpose, m, n, kL, kU int, alpha, beta complex128, ldab, incX, incY int) { const tol = 1e-13 // Allocate a dense-storage band matrix filled with NaNs that will be // used as the reference matrix for Zgemv. lda := max(1, n) a := makeZGeneral(nil, m, n, lda) // Fill the matrix with zeros. for i := 0; i < m; i++ { for j := 0; j < n; j++ { a[i*lda+j] = 0 } } // Fill the band with random data. for i := 0; i < m; i++ { for j := max(0, i-kL); j < min(n, i+kU+1); j++ { re := rnd.NormFloat64() im := rnd.NormFloat64() a[i*lda+j] = complex(re, im) } } // Create the actual band matrix. ab := zPackBand(kL, kU, ldab, m, n, a, lda) abCopy := make([]complex128, len(ab)) copy(abCopy, ab) // Compute correct lengths of vectors x and y. var lenX, lenY int switch trans { case blas.NoTrans: lenX = n lenY = m case blas.Trans, blas.ConjTrans: lenX = m lenY = n } // Generate a random complex vector x. xtest := make([]complex128, lenX) for i := range xtest { re := rnd.NormFloat64() im := rnd.NormFloat64() xtest[i] = complex(re, im) } x := makeZVector(xtest, incX) xCopy := make([]complex128, len(x)) copy(xCopy, x) // Generate a random complex vector y. ytest := make([]complex128, lenY) for i := range ytest { re := rnd.NormFloat64() im := rnd.NormFloat64() ytest[i] = complex(re, im) } y := makeZVector(ytest, incY) want := make([]complex128, len(y)) copy(want, y) // Compute the reference result of alpha*op(A)*x + beta*y, storing it // into want. impl.Zgemv(trans, m, n, alpha, a, lda, x, incX, beta, want, incY) // Compute alpha*op(A)*x + beta*y, storing the result in-place into y. impl.Zgbmv(trans, m, n, kL, kU, alpha, ab, ldab, x, incX, beta, y, incY) name := fmt.Sprintf("trans=%v,m=%v,n=%v,kL=%v,kU=%v,lda=%v,incX=%v,incY=%v", trans, m, n, kL, kU, lda, incX, incY) if !zsame(ab, abCopy) { t.Errorf("%v: unexpected modification of ab", name) } if !zsame(x, xCopy) { t.Errorf("%v: unexpected modification of x", name) } if !zSameAtNonstrided(y, want, incY) { t.Errorf("%v: unexpected modification of y", name) } if !zEqualApproxAtStrided(y, want, incY, tol) { t.Errorf("%v: unexpected result\ngot %v\nwant %v\n", name, y, want) } }