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fuchsia / third_party / github.com / gonum / gonum / refs/tags/v0.13.0 / . / cmplxs / cmplxs_test.go
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// Copyright ©2013 The Gonum Authors. All rights reserved.
// Use of this code is governed by a BSD-style
// license that can be found in the LICENSE file
package cmplxs
import (
"fmt"
"math"
"math/cmplx"
"strconv"
"testing"
"golang.org/x/exp/rand"
"gonum.org/v1/gonum/cmplxs/cscalar"
"gonum.org/v1/gonum/floats"
)
const (
EqTolerance = 1e-14
Small = 10
Medium = 1000
Large = 100000
Huge = 10000000
)
func areSlicesEqual(t *testing.T, truth, comp []complex128, str string) {
if !EqualApprox(comp, truth, EqTolerance) {
t.Errorf(str+". Expected %v, returned %v", truth, comp)
}
}
func areSlicesSame(t *testing.T, truth, comp []complex128, str string) {
ok := len(truth) == len(comp)
if ok {
for i, a := range truth {
if !cscalar.EqualWithinAbsOrRel(a, comp[i], EqTolerance, EqTolerance) && !cscalar.Same(a, comp[i]) {
ok = false
break
}
}
}
if !ok {
t.Errorf(str+". Expected %v, returned %v", truth, comp)
}
}
func Panics(fun func()) (b bool) {
defer func() {
err := recover()
if err != nil {
b = true
}
}()
fun()
return
}
func TestAdd(t *testing.T) {
a := []complex128{1 + 1i, 2 + 2i, 3 + 3i}
b := []complex128{4 + 4i, 5 + 5i, 6 + 6i}
c := []complex128{7 + 7i, 8 + 8i, 9 + 9i}
truth := []complex128{12 + 12i, 15 + 15i, 18 + 18i}
n := make([]complex128, len(a))
Add(n, a)
Add(n, b)
Add(n, c)
areSlicesEqual(t, truth, n, "Wrong addition of slices new receiver")
Add(a, b)
Add(a, c)
areSlicesEqual(t, truth, n, "Wrong addition of slices for no new receiver")
// Test that it panics
if !Panics(func() { Add(make([]complex128, 2), make([]complex128, 3)) }) {
t.Errorf("Did not panic with length mismatch")
}
}
func TestAddTo(t *testing.T) {
a := []complex128{1 + 1i, 2 + 2i, 3 + 3i}
b := []complex128{4 + 4i, 5 + 5i, 6 + 6i}
truth := []complex128{5 + 5i, 7 + 7i, 9 + 9i}
n1 := make([]complex128, len(a))
n2 := AddTo(n1, a, b)
areSlicesEqual(t, truth, n1, "Bad addition from mutator")
areSlicesEqual(t, truth, n2, "Bad addition from returned slice")
// Test that it panics
if !Panics(func() { AddTo(make([]complex128, 2), make([]complex128, 3), make([]complex128, 3)) }) {
t.Errorf("Did not panic with length mismatch")
}
if !Panics(func() { AddTo(make([]complex128, 3), make([]complex128, 3), make([]complex128, 2)) }) {
t.Errorf("Did not panic with length mismatch")
}
}
func TestAddConst(t *testing.T) {
s := []complex128{3 + 1i, 4 + 2i, 1 + 3i, 7 + 4i, 5 + 5i}
c := 6 + 1i
truth := []complex128{9 + 2i, 10 + 3i, 7 + 4i, 13 + 5i, 11 + 6i}
AddConst(c, s)
areSlicesEqual(t, truth, s, "Wrong addition of constant")
}
func TestAddScaled(t *testing.T) {
s := []complex128{3, 4, 1, 7, 5}
alpha := 6 + 1i
dst := []complex128{1, 2, 3, 4, 5}
ans := []complex128{19 + 3i, 26 + 4i, 9 + 1i, 46 + 7i, 35 + 5i}
AddScaled(dst, alpha, s)
if !EqualApprox(dst, ans, EqTolerance) {
t.Errorf("Adding scaled did not match. Expected %v, returned %v", ans, dst)
}
short := []complex128{1}
if !Panics(func() { AddScaled(dst, alpha, short) }) {
t.Errorf("Doesn't panic if s is smaller than dst")
}
if !Panics(func() { AddScaled(short, alpha, s) }) {
t.Errorf("Doesn't panic if dst is smaller than s")
}
}
func TestAddScaledTo(t *testing.T) {
s := []complex128{3, 4, 1, 7, 5}
alpha := 6 + 1i
y := []complex128{1, 2, 3, 4, 5}
dst1 := make([]complex128, 5)
ans := []complex128{19 + 3i, 26 + 4i, 9 + 1i, 46 + 7i, 35 + 5i}
dst2 := AddScaledTo(dst1, y, alpha, s)
if !EqualApprox(dst1, ans, EqTolerance) {
t.Errorf("AddScaledTo did not match for mutator")
}
if !EqualApprox(dst2, ans, EqTolerance) {
t.Errorf("AddScaledTo did not match for returned slice")
}
AddScaledTo(dst1, y, alpha, s)
if !EqualApprox(dst1, ans, EqTolerance) {
t.Errorf("Reusing dst did not match")
}
short := []complex128{1}
if !Panics(func() { AddScaledTo(dst1, y, alpha, short) }) {
t.Errorf("Doesn't panic if s is smaller than dst")
}
if !Panics(func() { AddScaledTo(short, y, alpha, s) }) {
t.Errorf("Doesn't panic if dst is smaller than s")
}
if !Panics(func() { AddScaledTo(dst1, short, alpha, s) }) {
t.Errorf("Doesn't panic if y is smaller than dst")
}
}
func TestCount(t *testing.T) {
s := []complex128{3, 4, 1, 7, 5}
f := func(v complex128) bool { return cmplx.Abs(v) > 3.5 }
truth := 3
n := Count(f, s)
if n != truth {
t.Errorf("Wrong number of elements counted")
}
}
func TestCumProd(t *testing.T) {
s := []complex128{3 + 1i, 4 + 2i, 1 + 3i, 7 + 4i, 5 + 5i}
receiver := make([]complex128, len(s))
result := CumProd(receiver, s)
truth := []complex128{3 + 1i, 10 + 10i, -20 + 40i, -300 + 200i, -2500 - 500i}
areSlicesEqual(t, truth, receiver, "Wrong cumprod mutated with new receiver")
areSlicesEqual(t, truth, result, "Wrong cumprod result with new receiver")
CumProd(receiver, s)
areSlicesEqual(t, truth, receiver, "Wrong cumprod returned with reused receiver")
// Test that it panics
if !Panics(func() { CumProd(make([]complex128, 2), make([]complex128, 3)) }) {
t.Errorf("Did not panic with length mismatch")
}
// Test empty CumProd
emptyReceiver := make([]complex128, 0)
truth = []complex128{}
CumProd(emptyReceiver, emptyReceiver)
areSlicesEqual(t, truth, emptyReceiver, "Wrong cumprod returned with empty receiver")
}
func TestComplex(t *testing.T) {
for i, test := range []struct {
dst []complex128
real, imag []float64
want []complex128
panics bool
}{
{},
{
dst: make([]complex128, 4),
real: []float64{1, 2, 3, 4},
imag: []float64{1, 2, 3, 4},
want: []complex128{1 + 1i, 2 + 2i, 3 + 3i, 4 + 4i},
},
{
dst: make([]complex128, 3),
real: []float64{1, 2, 3, 4},
imag: []float64{1, 2, 3, 4},
panics: true,
},
{
dst: make([]complex128, 4),
real: []float64{1, 2, 3},
imag: []float64{1, 2, 3, 4},
panics: true,
},
{
dst: make([]complex128, 4),
real: []float64{1, 2, 3, 4},
imag: []float64{1, 2, 3},
panics: true,
},
{
dst: make([]complex128, 4),
real: []float64{1, 2, 3, 4},
imag: []float64{1, 2, 3, math.NaN()},
want: []complex128{1 + 1i, 2 + 2i, 3 + 3i, cmplx.NaN()},
},
} {
var got []complex128
panicked := Panics(func() {
got = Complex(test.dst, test.real, test.imag)
})
if panicked != test.panics {
if panicked {
t.Errorf("unexpected panic for test %d", i)
} else {
t.Errorf("expected panic for test %d", i)
}
}
if panicked || test.panics {
continue
}
if !Same(got, test.dst) {
t.Errorf("mismatch between dst and return test %d: got:%v want:%v", i, got, test.dst)
}
if !Same(got, test.want) {
t.Errorf("unexpected result for test %d: got:%v want:%v", i, got, test.want)
}
}
}
func TestCumSum(t *testing.T) {
s := []complex128{3 + 1i, 4 + 2i, 1 + 3i, 7 + 4i, 5 + 5i}
receiver := make([]complex128, len(s))
result := CumSum(receiver, s)
truth := []complex128{3 + 1i, 7 + 3i, 8 + 6i, 15 + 10i, 20 + 15i}
areSlicesEqual(t, truth, receiver, "Wrong cumsum mutated with new receiver")
areSlicesEqual(t, truth, result, "Wrong cumsum returned with new receiver")
CumSum(receiver, s)
areSlicesEqual(t, truth, receiver, "Wrong cumsum returned with reused receiver")
// Test that it panics
if !Panics(func() { CumSum(make([]complex128, 2), make([]complex128, 3)) }) {
t.Errorf("Did not panic with length mismatch")
}
// Test empty CumSum
emptyReceiver := make([]complex128, 0)
truth = []complex128{}
CumSum(emptyReceiver, emptyReceiver)
areSlicesEqual(t, truth, emptyReceiver, "Wrong cumsum returned with empty receiver")
}
func TestDistance(t *testing.T) {
norms := []float64{1, 2, 4, math.Inf(1)}
slices := []struct {
s []complex128
t []complex128
}{
{
nil,
nil,
},
{
[]complex128{8 + 1i, 9 + 2i, 10 + 3i, -12 + 4i},
[]complex128{8 + 1i, 9 + 2i, 10 + 3i, -12 + 4i},
},
{
[]complex128{1 + 1i, 2 + 2i, 3 + 3i, -4 + 4i, -5 + 5i, 8 + 6i},
[]complex128{-9.2 - 1i, -6.8 - 2i, 9 - 3i, -3 - 4i, -2 - 5i, 1 - 6i},
},
}
for j, test := range slices {
tmp := make([]complex128, len(test.s))
for i, L := range norms {
dist := Distance(test.s, test.t, L)
copy(tmp, test.s)
Sub(tmp, test.t)
norm := Norm(tmp, L)
if dist != norm { // Use equality because they should be identical.
t.Errorf("Distance does not match norm for case %v, %v. Expected %v, Found %v.", i, j, norm, dist)
}
}
}
if !Panics(func() { Distance([]complex128{}, []complex128{1}, 1) }) {
t.Errorf("Did not panic with unequal lengths")
}
}
func TestDiv(t *testing.T) {
s1 := []complex128{5 - 5i, 12 + 2i, 27 - 3i}
s2 := []complex128{1 - 1i, 2 + 2i, 3 - 1i}
ans := []complex128{5 + 0i, 3.5 - 2.5i, 8.4 + 1.8i}
Div(s1, s2)
if !EqualApprox(s1, ans, EqTolerance) {
t.Errorf("Div doesn't give correct answer. Expected %v, Found %v.", ans, s1)
}
s1short := []complex128{1}
if !Panics(func() { Div(s1short, s2) }) {
t.Errorf("Did not panic with unequal lengths")
}
s2short := []complex128{1}
if !Panics(func() { Div(s1, s2short) }) {
t.Errorf("Did not panic with unequal lengths")
}
}
func TestDivTo(t *testing.T) {
s1 := []complex128{5 - 5i, 12 + 2i, 27 - 3i}
s1orig := []complex128{5 - 5i, 12 + 2i, 27 - 3i}
s2 := []complex128{1 - 1i, 2 + 2i, 3 - 1i}
s2orig := []complex128{1 - 1i, 2 + 2i, 3 - 1i}
dst1 := make([]complex128, 3)
ans := []complex128{5 + 0i, 3.5 - 2.5i, 8.4 + 1.8i}
dst2 := DivTo(dst1, s1, s2)
if !EqualApprox(dst1, ans, EqTolerance) {
t.Errorf("DivTo doesn't give correct answer in mutated slice")
}
if !EqualApprox(dst2, ans, EqTolerance) {
t.Errorf("DivTo doesn't give correct answer in returned slice")
}
if !EqualApprox(s1, s1orig, EqTolerance) {
t.Errorf("S1 changes during multo")
}
if !EqualApprox(s2, s2orig, EqTolerance) {
t.Errorf("s2 changes during multo")
}
DivTo(dst1, s1, s2)
if !EqualApprox(dst1, ans, EqTolerance) {
t.Errorf("DivTo doesn't give correct answer reusing dst")
}
dstShort := []complex128{1}
if !Panics(func() { DivTo(dstShort, s1, s2) }) {
t.Errorf("Did not panic with s1 wrong length")
}
s1short := []complex128{1}
if !Panics(func() { DivTo(dst1, s1short, s2) }) {
t.Errorf("Did not panic with s1 wrong length")
}
s2short := []complex128{1}
if !Panics(func() { DivTo(dst1, s1, s2short) }) {
t.Errorf("Did not panic with s2 wrong length")
}
}
func TestDot(t *testing.T) {
s1 := []complex128{1 + 1i, 2 + 2i, 3 + 3i, 4 + 4i}
s2 := []complex128{-3 + 4i, 4 + 3i, 5 + 2i, -6 + 1i}
truth := 16 + 24i
ans := Dot(s1, s2)
if ans != truth {
t.Errorf("Dot product computed incorrectly. Expected %v, Found %v.", truth, ans)
}
// Test that it panics
if !Panics(func() { Dot(make([]complex128, 2), make([]complex128, 3)) }) {
t.Errorf("Did not panic with length mismatch")
}
}
func TestEquals(t *testing.T) {
s1 := []complex128{1 + 1i, 2 + 4i, 3 + 8i, 4 + 16i}
s2 := []complex128{1 + 1i, 2 + 4i, 3 + 8i, 4 + 16i}
if !Equal(s1, s2) {
t.Errorf("Equal slices returned as unequal")
}
s2 = []complex128{1 + 1i, 2 + 4i, 3 + 8i, 4 + 16i + 1e-14}
if Equal(s1, s2) {
t.Errorf("Unequal slices returned as equal")
}
if Equal(s1, []complex128{}) {
t.Errorf("Unequal slice lengths returned as equal")
}
}
func TestEqualApprox(t *testing.T) {
s1 := []complex128{1 + 1i, 2 + 4i, 3 + 8i, 4 + 16i}
s2 := []complex128{1 + 1i, 2 + 4i, 3 + 8i, 4 + 16i + 1e-10}
if EqualApprox(s1, s2, 1e-13) {
t.Errorf("Unequal slices returned as equal for absolute")
}
if !EqualApprox(s1, s2, 1e-5) {
t.Errorf("Equal slices returned as unequal for absolute")
}
s1 = []complex128{1 + 1i, 2 + 4i, 3 + 8i, 1000 + 1000i}
s2 = []complex128{1 + 1i, 2 + 4i, 3 + 8i, (1000 + 1000i) * (1 + 1e-7)}
if EqualApprox(s1, s2, 1e-8) {
t.Errorf("Unequal slices returned as equal for relative")
}
if !EqualApprox(s1, s2, 1e-5) {
t.Errorf("Equal slices returned as unequal for relative")
}
if EqualApprox(s1, []complex128{}, 1e-5) {
t.Errorf("Unequal slice lengths returned as equal")
}
}
func TestEqualFunc(t *testing.T) {
s1 := []complex128{1 + 1i, 2 + 4i, 3 + 8i, 4 + 16i}
s2 := []complex128{1 + 1i, 2 + 4i, 3 + 8i, 4 + 16i}
eq := func(x, y complex128) bool { return x == y }
if !EqualFunc(s1, s2, eq) {
t.Errorf("Equal slices returned as unequal")
}
s2 = []complex128{1 + 1i, 2 + 4i, 3 + 8i, 4 + 16i + 1e-14}
if EqualFunc(s1, s2, eq) {
t.Errorf("Unequal slices returned as equal")
}
if EqualFunc(s1, []complex128{}, eq) {
t.Errorf("Unequal slice lengths returned as equal")
}
}
func TestEqualLengths(t *testing.T) {
s1 := []complex128{1 + 1i, 2 + 2i, 3 + 3i, 4 + 4i}
s2 := []complex128{1 + 1i, 2 + 2i, 3 + 3i, 4 + 4i}
s3 := []complex128{1 + 1i, 2 + 2i, 3 + 3i}
if !EqualLengths(s1, s2) {
t.Errorf("Equal lengths returned as unequal")
}
if EqualLengths(s1, s3) {
t.Errorf("Unequal lengths returned as equal")
}
if !EqualLengths(s1) {
t.Errorf("Single slice returned as unequal")
}
if !EqualLengths() {
t.Errorf("No slices returned as unequal")
}
}
func eqIntSlice(one, two []int) string {
if len(one) != len(two) {
return "Length mismatch"
}
for i, val := range one {
if val != two[i] {
return "Index " + strconv.Itoa(i) + " mismatch"
}
}
return ""
}
func TestFind(t *testing.T) {
s := []complex128{3 + 1i, 4 - 1i, 1 + 2i, 7 + 10i, 5 - 100i}
f := func(v complex128) bool { return cmplx.Abs(v) > 3.5 }
allTrueInds := []int{1, 3, 4}
// Test finding first two elements
inds, err := Find(nil, f, s, 2)
if err != nil {
t.Errorf("Find first two: Improper error return")
}
trueInds := allTrueInds[:2]
str := eqIntSlice(inds, trueInds)
if str != "" {
t.Errorf("Find first two: " + str)
}
// Test finding no elements with non nil slice
inds = []int{1, 2, 3, 4, 5, 6}
inds, err = Find(inds, f, s, 0)
if err != nil {
t.Errorf("Find no elements: Improper error return")
}
str = eqIntSlice(inds, []int{})
if str != "" {
t.Errorf("Find no non-nil: " + str)
}
// Test finding first two elements with non nil slice
inds = []int{1, 2, 3, 4, 5, 6}
inds, err = Find(inds, f, s, 2)
if err != nil {
t.Errorf("Find first two non-nil: Improper error return")
}
str = eqIntSlice(inds, trueInds)
if str != "" {
t.Errorf("Find first two non-nil: " + str)
}
// Test finding too many elements
inds, err = Find(inds, f, s, 4)
if err == nil {
t.Errorf("Request too many: No error returned")
}
str = eqIntSlice(inds, allTrueInds)
if str != "" {
t.Errorf("Request too many: Does not match all of the inds: " + str)
}
// Test finding all elements
inds, err = Find(nil, f, s, -1)
if err != nil {
t.Errorf("Find all: Improper error returned")
}
str = eqIntSlice(inds, allTrueInds)
if str != "" {
t.Errorf("Find all: Does not match all of the inds: " + str)
}
}
func TestHasNaN(t *testing.T) {
for i, test := range []struct {
s []complex128
ans bool
}{
{},
{
s: []complex128{1 + 1i, 2 + 2i, 3 + 3i, 4 + 4i},
},
{
s: []complex128{1 + 1i, cmplx.NaN(), 3 + 3i, 4 + 4i},
ans: true,
},
{
s: []complex128{1 + 1i, 2 + 2i, 3 + 3i, cmplx.NaN()},
ans: true,
},
} {
b := HasNaN(test.s)
if b != test.ans {
t.Errorf("HasNaN mismatch case %d. Expected %v, Found %v", i, test.ans, b)
}
}
}
func TestImag(t *testing.T) {
for i, test := range []struct {
dst []float64
src []complex128
want []float64
panics bool
}{
{},
{
dst: make([]float64, 4),
src: []complex128{1 + 1i, 2 + 2i, 3 + 3i, 4 + 4i},
want: []float64{1, 2, 3, 4},
},
{
dst: make([]float64, 3),
src: []complex128{1 + 1i, 2 + 2i, 3 + 3i, 4 + 4i},
panics: true,
},
{
dst: make([]float64, 4),
src: []complex128{1 + 1i, 2 + 2i, 3 + 3i, cmplx.NaN()},
want: []float64{1, 2, 3, math.NaN()},
},
} {
var got []float64
panicked := Panics(func() {
got = Imag(test.dst, test.src)
})
if panicked != test.panics {
if panicked {
t.Errorf("unexpected panic for test %d", i)
} else {
t.Errorf("expected panic for test %d", i)
}
}
if panicked || test.panics {
continue
}
if !floats.Same(got, test.dst) {
t.Errorf("mismatch between dst and return test %d: got:%v want:%v", i, got, test.dst)
}
if !floats.Same(got, test.want) {
t.Errorf("unexpected result for test %d: got:%v want:%v", i, got, test.want)
}
}
}
func TestLogSpan(t *testing.T) {
// FIXME(kortschak)
receiver1 := make([]complex128, 6)
truth := []complex128{0.001, 0.01, 0.1, 1, 10, 100}
receiver2 := LogSpan(receiver1, 0.001, 100)
tst := make([]complex128, 6)
for i := range truth {
tst[i] = receiver1[i] / truth[i]
}
comp := make([]complex128, 6)
for i := range comp {
comp[i] = 1
}
areSlicesEqual(t, comp, tst, "Improper logspace from mutator")
for i := range truth {
tst[i] = receiver2[i] / truth[i]
}
areSlicesEqual(t, comp, tst, "Improper logspace from returned slice")
if !Panics(func() { LogSpan(nil, 1, 5) }) {
t.Errorf("Span accepts nil argument")
}
if !Panics(func() { LogSpan(make([]complex128, 1), 1, 5) }) {
t.Errorf("Span accepts argument of len = 1")
}
}
func TestMaxAbsAndIdx(t *testing.T) {
for _, test := range []struct {
in []complex128
wantIdx int
wantVal complex128
desc string
}{
{
in: []complex128{3 + 1i, 4 + 1i, 1 + 1i, 7 + 1i, 5 + 1i},
wantIdx: 3,
wantVal: 7 + 1i,
desc: "with only finite entries",
},
{
in: []complex128{cmplx.NaN(), 4 + 1i, 1 + 1i, 7 + 1i, 5 + 1i},
wantIdx: 3,
wantVal: 7 + 1i,
desc: "with leading NaN",
},
{
in: []complex128{cmplx.NaN(), cmplx.NaN(), cmplx.NaN()},
wantIdx: 0,
wantVal: cmplx.NaN(),
desc: "when only NaN elements exist",
},
{
in: []complex128{cmplx.NaN(), cmplx.Inf()},
wantIdx: 1,
wantVal: cmplx.Inf(),
desc: "leading NaN followed by Inf",
},
} {
ind := MaxAbsIdx(test.in)
if ind != test.wantIdx {
t.Errorf("Wrong index "+test.desc+": got:%d want:%d", ind, test.wantIdx)
}
val := MaxAbs(test.in)
if !cscalar.Same(val, test.wantVal) {
t.Errorf("Wrong value "+test.desc+": got:%f want:%f", val, test.wantVal)
}
}
}
func TestMinAbsAndIdx(t *testing.T) {
for _, test := range []struct {
in []complex128
wantIdx int
wantVal complex128
desc string
}{
{
in: []complex128{3 + 1i, 4 + 1i, 1 + 1i, 7 + 1i, 5 + 1i},
wantIdx: 2,
wantVal: 1 + 1i,
desc: "with only finite entries",
},
{
in: []complex128{cmplx.NaN(), 4 + 1i, 1 + 1i, 7 + 1i, 5 + 1i},
wantIdx: 2,
wantVal: 1 + 1i,
desc: "with leading NaN",
},
{
in: []complex128{cmplx.NaN(), cmplx.NaN(), cmplx.NaN()},
wantIdx: 0,
wantVal: cmplx.NaN(),
desc: "when only NaN elements exist",
},
{
in: []complex128{cmplx.NaN(), cmplx.Inf()},
wantIdx: 1,
wantVal: cmplx.Inf(),
desc: "leading NaN followed by Inf",
},
} {
ind := MinAbsIdx(test.in)
if ind != test.wantIdx {
t.Errorf("Wrong index "+test.desc+": got:%d want:%d", ind, test.wantIdx)
}
val := MinAbs(test.in)
if !cscalar.Same(val, test.wantVal) {
t.Errorf("Wrong value "+test.desc+": got:%f want:%f", val, test.wantVal)
}
}
}
func TestMul(t *testing.T) {
s1 := []complex128{1 + 1i, 2 + 2i, 3 + 3i}
s2 := []complex128{1 + 1i, 2 + 2i, 3 + 3i}
ans := []complex128{0 + 2i, 0 + 8i, 0 + 18i}
Mul(s1, s2)
if !EqualApprox(s1, ans, EqTolerance) {
t.Errorf("Mul doesn't give correct answer. Expected %v, Found %v", ans, s1)
}
s1short := []complex128{1}
if !Panics(func() { Mul(s1short, s2) }) {
t.Errorf("Did not panic with unequal lengths")
}
s2short := []complex128{1}
if !Panics(func() { Mul(s1, s2short) }) {
t.Errorf("Did not panic with unequal lengths")
}
}
func TestMulConj(t *testing.T) {
s1 := []complex128{2 + 1i, 3 + 2i, 4 + 3i}
s2 := []complex128{1 + 2i, 2 + 3i, 3 + 4i}
s2orig := []complex128{1 + 2i, 2 + 3i, 3 + 4i}
ans := []complex128{4 - 3i, 12 - 5i, 24 - 7i}
MulConj(s1, s2)
if !Equal(s1, ans) {
t.Errorf("MulConj doesn't give correct answer. Expected %v, Found %v", ans, s1)
}
if !Equal(s2, s2orig) {
t.Errorf("s2 changes during MulTo")
}
s1short := []complex128{1}
if !Panics(func() { MulConj(s1short, s2) }) {
t.Errorf("Did not panic with unequal lengths")
}
s2short := []complex128{1}
if !Panics(func() { MulConj(s1, s2short) }) {
t.Errorf("Did not panic with unequal lengths")
}
}
func TestMulConjTo(t *testing.T) {
s1 := []complex128{2 + 1i, 3 + 2i, 4 + 3i}
s1orig := []complex128{2 + 1i, 3 + 2i, 4 + 3i}
s2 := []complex128{1 + 2i, 2 + 3i, 3 + 4i}
s2orig := []complex128{1 + 2i, 2 + 3i, 3 + 4i}
dst1 := make([]complex128, 3)
ans := []complex128{4 - 3i, 12 - 5i, 24 - 7i}
dst2 := MulConjTo(dst1, s1, s2)
if !Equal(dst1, ans) {
t.Errorf("MulConjTo doesn't give correct answer in mutated slice")
}
if !Equal(dst2, ans) {
t.Errorf("MulConjTo doesn't give correct answer in returned slice")
}
if !Equal(s1, s1orig) {
t.Errorf("S1 changes during MulConjTo")
}
if !Equal(s2, s2orig) {
t.Errorf("s2 changes during MulConjTo")
}
MulConjTo(dst1, s1, s2)
if !Equal(dst1, ans) {
t.Errorf("MulConjTo doesn't give correct answer reusing dst")
}
dstShort := []complex128{1}
if !Panics(func() { MulConjTo(dstShort, s1, s2) }) {
t.Errorf("Did not panic with dst wrong length")
}
s1short := []complex128{1}
if !Panics(func() { MulConjTo(dst1, s1short, s2) }) {
t.Errorf("Did not panic with s1 wrong length")
}
s2short := []complex128{1}
if !Panics(func() { MulConjTo(dst1, s1, s2short) }) {
t.Errorf("Did not panic with s2 wrong length")
}
}
func TestMulTo(t *testing.T) {
s1 := []complex128{1 + 1i, 2 + 2i, 3 + 3i}
s1orig := []complex128{1 + 1i, 2 + 2i, 3 + 3i}
s2 := []complex128{1 + 1i, 2 + 2i, 3 + 3i}
s2orig := []complex128{1 + 1i, 2 + 2i, 3 + 3i}
dst1 := make([]complex128, 3)
ans := []complex128{0 + 2i, 0 + 8i, 0 + 18i}
dst2 := MulTo(dst1, s1, s2)
if !EqualApprox(dst1, ans, EqTolerance) {
t.Errorf("MulTo doesn't give correct answer in mutated slice")
}
if !EqualApprox(dst2, ans, EqTolerance) {
t.Errorf("MulTo doesn't give correct answer in returned slice")
}
if !EqualApprox(s1, s1orig, EqTolerance) {
t.Errorf("S1 changes during multo")
}
if !EqualApprox(s2, s2orig, EqTolerance) {
t.Errorf("s2 changes during multo")
}
MulTo(dst1, s1, s2)
if !EqualApprox(dst1, ans, EqTolerance) {
t.Errorf("MulTo doesn't give correct answer reusing dst")
}
dstShort := []complex128{1}
if !Panics(func() { MulTo(dstShort, s1, s2) }) {
t.Errorf("Did not panic with s1 wrong length")
}
s1short := []complex128{1}
if !Panics(func() { MulTo(dst1, s1short, s2) }) {
t.Errorf("Did not panic with s1 wrong length")
}
s2short := []complex128{1}
if !Panics(func() { MulTo(dst1, s1, s2short) }) {
t.Errorf("Did not panic with s2 wrong length")
}
}
// Complexify
func TestNearestIdx(t *testing.T) {
for _, test := range []struct {
in []complex128
query complex128
want int
desc string
}{
{
in: []complex128{6.2, 3, 5, 6.2, 8},
query: 2,
want: 1,
desc: "Wrong index returned when value is less than all of elements",
},
{
in: []complex128{6.2, 3, 5, 6.2, 8},
query: 9,
want: 4,
desc: "Wrong index returned when value is greater than all of elements",
},
{
in: []complex128{6.2, 3, 5, 6.2, 8},
query: 3.1,
want: 1,
desc: "Wrong index returned when value is greater than closest element",
},
{
in: []complex128{6.2, 3, 5, 6.2, 8},
query: 2.9,
want: 1,
desc: "Wrong index returned when value is less than closest element",
},
{
in: []complex128{6.2, 3, 5, 6.2, 8},
query: 3,
want: 1,
desc: "Wrong index returned when value is equal to element",
},
{
in: []complex128{6.2, 3, 5, 6.2, 8},
query: 6.2,
want: 0,
desc: "Wrong index returned when value is equal to several elements",
},
{
in: []complex128{6.2, 3, 5, 6.2, 8},
query: 4,
want: 1,
desc: "Wrong index returned when value is exactly between two closest elements",
},
{
in: []complex128{cmplx.NaN(), 3, 2, -1},
query: 2,
want: 2,
desc: "Wrong index returned when initial element is NaN",
},
{
in: []complex128{0, cmplx.NaN(), -1, 2},
query: cmplx.NaN(),
want: 0,
desc: "Wrong index returned when query is NaN and a NaN element exists",
},
{
in: []complex128{0, cmplx.NaN(), -1, 2},
query: cmplx.Inf(),
want: 3,
desc: "Wrong index returned when query is Inf and no Inf element exists",
},
{
in: []complex128{cmplx.NaN(), cmplx.NaN(), cmplx.NaN()},
query: 1,
want: 0,
desc: "Wrong index returned when query is a number and only NaN elements exist",
},
{
in: []complex128{cmplx.NaN(), cmplx.Inf()},
query: 1,
want: 1,
desc: "Wrong index returned when query is a number and single NaN precedes Inf",
},
} {
ind := NearestIdx(test.in, test.query)
if ind != test.want {
t.Errorf(test.desc+": got:%d want:%d", ind, test.want)
}
}
}
func TestNorm(t *testing.T) {
s := []complex128{-1, -3.4, 5, -6}
val := Norm(s, math.Inf(1))
truth := 6.0
if math.Abs(val-truth) > EqTolerance {
t.Errorf("Doesn't match for inf norm. %v expected, %v found", truth, val)
}
// http://www.wolframalpha.com/input/?i=%28%28-1%29%5E2+%2B++%28-3.4%29%5E2+%2B+5%5E2%2B++6%5E2%29%5E%281%2F2%29
val = Norm(s, 2)
truth = 8.5767126569566267590651614132751986658027271236078592
if math.Abs(val-truth) > EqTolerance {
t.Errorf("Doesn't match for inf norm. %v expected, %v found", truth, val)
}
// http://www.wolframalpha.com/input/?i=%28%28%7C-1%7C%29%5E3+%2B++%28%7C-3.4%7C%29%5E3+%2B+%7C5%7C%5E3%2B++%7C6%7C%5E3%29%5E%281%2F3%29
val = Norm(s, 3)
truth = 7.2514321388020228478109121239004816430071237369356233
if math.Abs(val-truth) > EqTolerance {
t.Errorf("Doesn't match for inf norm. %v expected, %v found", truth, val)
}
//http://www.wolframalpha.com/input/?i=%7C-1%7C+%2B+%7C-3.4%7C+%2B+%7C5%7C%2B++%7C6%7C
val = Norm(s, 1)
truth = 15.4
if math.Abs(val-truth) > EqTolerance {
t.Errorf("Doesn't match for inf norm. %v expected, %v found", truth, val)
}
}
func TestProd(t *testing.T) {
s := []complex128{}
val := Prod(s)
if val != 1 {
t.Errorf("Val not returned as default when slice length is zero")
}
s = []complex128{3, 4, 1, 7, 5}
val = Prod(s)
if val != 420 {
t.Errorf("Wrong prod returned. Expected %v returned %v", 420, val)
}
}
func TestReverse(t *testing.T) {
for _, s := range [][]complex128{
{0},
{1, 0},
{2, 1, 0},
{3, 2, 1, 0},
{9, 8, 7, 6, 5, 4, 3, 2, 1, 0},
} {
Reverse(s)
for i, v := range s {
if v != complex(float64(i), 0) {
t.Errorf("unexpected values for element %d: got:%v want:%v", i, v, i)
}
}
}
}
func TestReal(t *testing.T) {
for i, test := range []struct {
dst []float64
src []complex128
want []float64
panics bool
}{
{},
{
dst: make([]float64, 4),
src: []complex128{1 + 1i, 2 + 2i, 3 + 3i, 4 + 4i},
want: []float64{1, 2, 3, 4},
},
{
dst: make([]float64, 3),
src: []complex128{1 + 1i, 2 + 2i, 3 + 3i, 4 + 4i},
panics: true,
},
{
dst: make([]float64, 4),
src: []complex128{1 + 1i, 2 + 2i, 3 + 3i, cmplx.NaN()},
want: []float64{1, 2, 3, math.NaN()},
},
} {
var got []float64
panicked := Panics(func() {
got = Real(test.dst, test.src)
})
if panicked != test.panics {
if panicked {
t.Errorf("unexpected panic for test %d", i)
} else {
t.Errorf("expected panic for test %d", i)
}
}
if panicked || test.panics {
continue
}
if !floats.Same(got, test.dst) {
t.Errorf("mismatch between dst and return test %d: got:%v want:%v", i, got, test.dst)
}
if !floats.Same(got, test.want) {
t.Errorf("unexpected result for test %d: got:%v want:%v", i, got, test.want)
}
}
}
func TestSame(t *testing.T) {
s1 := []complex128{1 + 1i, 2 + 2i, 3 + 3i, 4 + 4i}
s2 := []complex128{1 + 1i, 2 + 2i, 3 + 3i, 4 + 4i}
if !Same(s1, s2) {
t.Errorf("Equal slices returned as unequal")
}
s2 = []complex128{1 + 1i, 2 + 2i, 3 + 3i, 4 + 4i + 1e-14}
if Same(s1, s2) {
t.Errorf("Unequal slices returned as equal")
}
if Same(s1, []complex128{}) {
t.Errorf("Unequal slice lengths returned as equal")
}
s1 = []complex128{1 + 1i, 2 + 2i, cmplx.NaN(), 4 + 4i}
s2 = []complex128{1 + 1i, 2 + 2i, cmplx.NaN(), 4 + 4i}
if !Same(s1, s2) {
t.Errorf("Slices with matching NaN values returned as unequal")
}
s1 = []complex128{1 + 1i, 2 + 2i, cmplx.NaN(), 4 + 4i}
s2 = []complex128{1 + 1i, cmplx.NaN(), 3 + 3i, 4 + 4i}
if Same(s1, s2) {
t.Errorf("Slices with unmatching NaN values returned as equal")
}
}
func TestScale(t *testing.T) {
s := []complex128{3, 4, 1, 7, 5}
c := 4 + 5i
truth := []complex128{12 + 15i, 16 + 20i, 4 + 5i, 28 + 35i, 20 + 25i}
Scale(c, s)
areSlicesEqual(t, truth, s, "Bad scaling")
}
func TestScaleReal(t *testing.T) {
s := []complex128{3 + 4i, 4 + 5i, 1 + 2i, 7 + 6i, 5 + 2i}
f := 5.0
truth := []complex128{15 + 20i, 20 + 25i, 5 + 10i, 35 + 30i, 25 + 10i}
ScaleReal(f, s)
areSlicesEqual(t, truth, s, "Bad scaling")
}
func TestScaleRealTo(t *testing.T) {
s := []complex128{3 + 4i, 4 + 5i, 1 + 2i, 7 + 6i, 5 + 2i}
sCopy := make([]complex128, len(s))
copy(sCopy, s)
f := 5.0
truth := []complex128{15 + 20i, 20 + 25i, 5 + 10i, 35 + 30i, 25 + 10i}
dst := make([]complex128, len(s))
ScaleRealTo(dst, f, s)
if !Same(dst, truth) {
t.Errorf("ScaleRealTo dst does not match. Got %v, want %v", dst, truth)
}
if !Same(s, sCopy) {
t.Errorf("SourceRealTo s modified during call. Got %v, want %v", s, sCopy)
}
}
func TestScaleTo(t *testing.T) {
s := []complex128{3, 4, 1, 7, 5}
sCopy := make([]complex128, len(s))
copy(sCopy, s)
c := 4 + 5i
truth := []complex128{12 + 15i, 16 + 20i, 4 + 5i, 28 + 35i, 20 + 25i}
dst := make([]complex128, len(s))
ScaleTo(dst, c, s)
if !Same(dst, truth) {
t.Errorf("ScaleTo dst does not match. Got %v, want %v", dst, truth)
}
if !Same(s, sCopy) {
t.Errorf("SourceTo s modified during call. Got %v, want %v", s, sCopy)
}
}
func TestSpan(t *testing.T) {
receiver1 := make([]complex128, 5)
truth := []complex128{1 + 1i, 2 + 2i, 3 + 3i, 4 + 4i, 5 + 5i}
receiver2 := Span(receiver1, 1+1i, 5+5i)
areSlicesEqual(t, truth, receiver1, "Improper linspace from mutator")
areSlicesEqual(t, truth, receiver2, "Improper linspace from returned slice")
receiver1 = make([]complex128, 6)
truth = []complex128{0, 0.2 + 0.4i, 0.4 + 0.8i, 0.6 + 1.2i, 0.8 + 1.6i, 1 + 2i}
Span(receiver1, 0, 1+2i)
areSlicesEqual(t, truth, receiver1, "Improper linspace")
if !Panics(func() { Span(nil, 1, 5) }) {
t.Errorf("Span accepts nil argument")
}
if !Panics(func() { Span(make([]complex128, 1), 1, 5) }) {
t.Errorf("Span accepts argument of len = 1")
}
for _, test := range []struct {
n int
l, u complex128
want []complex128
}{
{
n: 5, l: cmplx.Inf(), u: cmplx.Inf(),
want: []complex128{cmplx.Inf(), cmplx.Inf(), cmplx.Inf(), cmplx.Inf(), cmplx.Inf()},
},
{
n: 5, l: cmplx.Inf(), u: cmplx.NaN(),
want: []complex128{cmplx.Inf(), cmplx.NaN(), cmplx.NaN(), cmplx.NaN(), cmplx.NaN()},
},
{
n: 5, l: cmplx.NaN(), u: cmplx.Inf(),
want: []complex128{cmplx.NaN(), cmplx.NaN(), cmplx.NaN(), cmplx.NaN(), cmplx.Inf()},
},
{
n: 5, l: 42, u: cmplx.Inf(),
want: []complex128{42, cmplx.Inf(), cmplx.Inf(), cmplx.Inf(), cmplx.Inf()},
},
{
n: 5, l: 42, u: cmplx.NaN(),
want: []complex128{42, cmplx.NaN(), cmplx.NaN(), cmplx.NaN(), cmplx.NaN()},
},
{
n: 5, l: cmplx.Inf(), u: 42,
want: []complex128{cmplx.Inf(), cmplx.Inf(), cmplx.Inf(), cmplx.Inf(), 42},
},
{
n: 5, l: cmplx.NaN(), u: 42,
want: []complex128{cmplx.NaN(), cmplx.NaN(), cmplx.NaN(), cmplx.NaN(), 42},
},
} {
got := Span(make([]complex128, test.n), test.l, test.u)
areSlicesSame(t, test.want, got,
fmt.Sprintf("Unexpected slice of length %d for %f to %f", test.n, test.l, test.u))
}
}
func TestSub(t *testing.T) {
s := []complex128{3 + 2i, 4 + 3i, 1 + 7i, 7 + 1i, 5 - 1i}
v := []complex128{1 + 1i, 2 + 4i, 3, 4, 5 - 1i}
truth := []complex128{2 + 1i, 2 - 1i, -2 + 7i, 3 + 1i, 0}
Sub(s, v)
areSlicesEqual(t, truth, s, "Bad subtract")
// Test that it panics
if !Panics(func() { Sub(make([]complex128, 2), make([]complex128, 3)) }) {
t.Errorf("Did not panic with length mismatch")
}
}
func TestSubTo(t *testing.T) {
s := []complex128{3 + 2i, 4 + 3i, 1 + 7i, 7 + 1i, 5 - 1i}
v := []complex128{1 + 1i, 2 + 4i, 3, 4, 5 - 1i}
truth := []complex128{2 + 1i, 2 - 1i, -2 + 7i, 3 + 1i, 0}
dst1 := make([]complex128, len(s))
dst2 := SubTo(dst1, s, v)
areSlicesEqual(t, truth, dst1, "Bad subtract from mutator")
areSlicesEqual(t, truth, dst2, "Bad subtract from returned slice")
// Test that all mismatch combinations panic
if !Panics(func() { SubTo(make([]complex128, 2), make([]complex128, 3), make([]complex128, 3)) }) {
t.Errorf("Did not panic with dst different length")
}
if !Panics(func() { SubTo(make([]complex128, 3), make([]complex128, 2), make([]complex128, 3)) }) {
t.Errorf("Did not panic with subtractor different length")
}
if !Panics(func() { SubTo(make([]complex128, 3), make([]complex128, 3), make([]complex128, 2)) }) {
t.Errorf("Did not panic with subtractee different length")
}
}
func TestSum(t *testing.T) {
s := []complex128{}
val := Sum(s)
if val != 0 {
t.Errorf("Val not returned as default when slice length is zero")
}
s = []complex128{3 + 1i, 4 + 2i, 1 + 3i, 7 + 4i, 5 + 5i}
val = Sum(s)
if val != 20+15i {
t.Errorf("Wrong sum returned")
}
}
func randomSlice(l int, src rand.Source) []complex128 {
rnd := rand.New(src)
s := make([]complex128, l)
for i := range s {
s[i] = complex(rnd.Float64(), rnd.Float64())
}
return s
}
func benchmarkAdd(b *testing.B, size int) {
src := rand.NewSource(1)
s1 := randomSlice(size, src)
s2 := randomSlice(size, src)
b.ResetTimer()
for i := 0; i < b.N; i++ {
Add(s1, s2)
}
}
func BenchmarkAddSmall(b *testing.B) { benchmarkAdd(b, Small) }
func BenchmarkAddMed(b *testing.B) { benchmarkAdd(b, Medium) }
func BenchmarkAddLarge(b *testing.B) { benchmarkAdd(b, Large) }
func BenchmarkAddHuge(b *testing.B) { benchmarkAdd(b, Huge) }
func benchmarkAddTo(b *testing.B, size int) {
src := rand.NewSource(1)
s1 := randomSlice(size, src)
s2 := randomSlice(size, src)
dst := randomSlice(size, src)
b.ResetTimer()
for i := 0; i < b.N; i++ {
AddTo(dst, s1, s2)
}
}
func BenchmarkAddToSmall(b *testing.B) { benchmarkAddTo(b, Small) }
func BenchmarkAddToMed(b *testing.B) { benchmarkAddTo(b, Medium) }
func BenchmarkAddToLarge(b *testing.B) { benchmarkAddTo(b, Large) }
func BenchmarkAddToHuge(b *testing.B) { benchmarkAddTo(b, Huge) }
func benchmarkCumProd(b *testing.B, size int) {
src := rand.NewSource(1)
s := randomSlice(size, src)
dst := randomSlice(size, src)
b.ResetTimer()
for i := 0; i < b.N; i++ {
CumProd(dst, s)
}
}
func BenchmarkCumProdSmall(b *testing.B) { benchmarkCumProd(b, Small) }
func BenchmarkCumProdMed(b *testing.B) { benchmarkCumProd(b, Medium) }
func BenchmarkCumProdLarge(b *testing.B) { benchmarkCumProd(b, Large) }
func BenchmarkCumProdHuge(b *testing.B) { benchmarkCumProd(b, Huge) }
func benchmarkCumSum(b *testing.B, size int) {
src := rand.NewSource(1)
s := randomSlice(size, src)
dst := randomSlice(size, src)
b.ResetTimer()
for i := 0; i < b.N; i++ {
CumSum(dst, s)
}
}
func BenchmarkCumSumSmall(b *testing.B) { benchmarkCumSum(b, Small) }
func BenchmarkCumSumMed(b *testing.B) { benchmarkCumSum(b, Medium) }
func BenchmarkCumSumLarge(b *testing.B) { benchmarkCumSum(b, Large) }
func BenchmarkCumSumHuge(b *testing.B) { benchmarkCumSum(b, Huge) }
func benchmarkDiv(b *testing.B, size int) {
src := rand.NewSource(1)
s := randomSlice(size, src)
dst := randomSlice(size, src)
b.ResetTimer()
for i := 0; i < b.N; i++ {
Div(dst, s)
}
}
func BenchmarkDivSmall(b *testing.B) { benchmarkDiv(b, Small) }
func BenchmarkDivMed(b *testing.B) { benchmarkDiv(b, Medium) }
func BenchmarkDivLarge(b *testing.B) { benchmarkDiv(b, Large) }
func BenchmarkDivHuge(b *testing.B) { benchmarkDiv(b, Huge) }
func benchmarkDivTo(b *testing.B, size int) {
src := rand.NewSource(1)
s1 := randomSlice(size, src)
s2 := randomSlice(size, src)
dst := randomSlice(size, src)
b.ResetTimer()
for i := 0; i < b.N; i++ {
DivTo(dst, s1, s2)
}
}
func BenchmarkDivToSmall(b *testing.B) { benchmarkDivTo(b, Small) }
func BenchmarkDivToMed(b *testing.B) { benchmarkDivTo(b, Medium) }
func BenchmarkDivToLarge(b *testing.B) { benchmarkDivTo(b, Large) }
func BenchmarkDivToHuge(b *testing.B) { benchmarkDivTo(b, Huge) }
func benchmarkSub(b *testing.B, size int) {
src := rand.NewSource(1)
s1 := randomSlice(size, src)
s2 := randomSlice(size, src)
b.ResetTimer()
for i := 0; i < b.N; i++ {
Sub(s1, s2)
}
}
func BenchmarkSubSmall(b *testing.B) { benchmarkSub(b, Small) }
func BenchmarkSubMed(b *testing.B) { benchmarkSub(b, Medium) }
func BenchmarkSubLarge(b *testing.B) { benchmarkSub(b, Large) }
func BenchmarkSubHuge(b *testing.B) { benchmarkSub(b, Huge) }
func benchmarkSubTo(b *testing.B, size int) {
src := rand.NewSource(1)
s1 := randomSlice(size, src)
s2 := randomSlice(size, src)
dst := randomSlice(size, src)
b.ResetTimer()
for i := 0; i < b.N; i++ {
SubTo(dst, s1, s2)
}
}
func BenchmarkSubToSmall(b *testing.B) { benchmarkSubTo(b, Small) }
func BenchmarkSubToMed(b *testing.B) { benchmarkSubTo(b, Medium) }
func BenchmarkSubToLarge(b *testing.B) { benchmarkSubTo(b, Large) }
func BenchmarkSubToHuge(b *testing.B) { benchmarkSubTo(b, Huge) }
func benchmarkDot(b *testing.B, size int) {
src := rand.NewSource(1)
s1 := randomSlice(size, src)
s2 := randomSlice(size, src)
b.ResetTimer()
for i := 0; i < b.N; i++ {
Dot(s1, s2)
}
}
func BenchmarkDotSmall(b *testing.B) { benchmarkDot(b, Small) }
func BenchmarkDotMed(b *testing.B) { benchmarkDot(b, Medium) }
func BenchmarkDotLarge(b *testing.B) { benchmarkDot(b, Large) }
func BenchmarkDotHuge(b *testing.B) { benchmarkDot(b, Huge) }
func benchmarkAddScaledTo(b *testing.B, size int) {
src := rand.NewSource(1)
dst := randomSlice(size, src)
y := randomSlice(size, src)
s := randomSlice(size, src)
b.ResetTimer()
for i := 0; i < b.N; i++ {
AddScaledTo(dst, y, 2.3, s)
}
}
func BenchmarkAddScaledToSmall(b *testing.B) { benchmarkAddScaledTo(b, Small) }
func BenchmarkAddScaledToMedium(b *testing.B) { benchmarkAddScaledTo(b, Medium) }
func BenchmarkAddScaledToLarge(b *testing.B) { benchmarkAddScaledTo(b, Large) }
func BenchmarkAddScaledToHuge(b *testing.B) { benchmarkAddScaledTo(b, Huge) }
func benchmarkScale(b *testing.B, size int) {
src := rand.NewSource(1)
dst := randomSlice(size, src)
b.ResetTimer()
for i := 0; i < b.N; i += 2 {
Scale(2.0, dst)
Scale(0.5, dst)
}
}
func BenchmarkScaleSmall(b *testing.B) { benchmarkScale(b, Small) }
func BenchmarkScaleMedium(b *testing.B) { benchmarkScale(b, Medium) }
func BenchmarkScaleLarge(b *testing.B) { benchmarkScale(b, Large) }
func BenchmarkScaleHuge(b *testing.B) { benchmarkScale(b, Huge) }
func benchmarkNorm2(b *testing.B, size int) {
src := rand.NewSource(1)
s := randomSlice(size, src)
b.ResetTimer()
for i := 0; i < b.N; i++ {
Norm(s, 2)
}
}
func BenchmarkNorm2Small(b *testing.B) { benchmarkNorm2(b, Small) }
func BenchmarkNorm2Medium(b *testing.B) { benchmarkNorm2(b, Medium) }
func BenchmarkNorm2Large(b *testing.B) { benchmarkNorm2(b, Large) }
func BenchmarkNorm2Huge(b *testing.B) { benchmarkNorm2(b, Huge) }