// Copyright 2021 The Go 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 slices_test import ( "cmp" "internal/asan" "internal/msan" "internal/race" "internal/testenv" "math" . "slices" "strings" "testing" "unsafe" ) var equalIntTests = []struct { s1, s2 []int want bool }{ { []int{1}, nil, false, }, { []int{}, nil, true, }, { []int{1, 2, 3}, []int{1, 2, 3}, true, }, { []int{1, 2, 3}, []int{1, 2, 3, 4}, false, }, } var equalFloatTests = []struct { s1, s2 []float64 wantEqual bool wantEqualNaN bool }{ { []float64{1, 2}, []float64{1, 2}, true, true, }, { []float64{1, 2, math.NaN()}, []float64{1, 2, math.NaN()}, false, true, }, } func TestEqual(t *testing.T) { for _, test := range equalIntTests { if got := Equal(test.s1, test.s2); got != test.want { t.Errorf("Equal(%v, %v) = %t, want %t", test.s1, test.s2, got, test.want) } } for _, test := range equalFloatTests { if got := Equal(test.s1, test.s2); got != test.wantEqual { t.Errorf("Equal(%v, %v) = %t, want %t", test.s1, test.s2, got, test.wantEqual) } } } // equal is simply ==. func equal[T comparable](v1, v2 T) bool { return v1 == v2 } // equalNaN is like == except that all NaNs are equal. func equalNaN[T comparable](v1, v2 T) bool { isNaN := func(f T) bool { return f != f } return v1 == v2 || (isNaN(v1) && isNaN(v2)) } // offByOne returns true if integers v1 and v2 differ by 1. func offByOne(v1, v2 int) bool { return v1 == v2+1 || v1 == v2-1 } func TestEqualFunc(t *testing.T) { for _, test := range equalIntTests { if got := EqualFunc(test.s1, test.s2, equal[int]); got != test.want { t.Errorf("EqualFunc(%v, %v, equal[int]) = %t, want %t", test.s1, test.s2, got, test.want) } } for _, test := range equalFloatTests { if got := EqualFunc(test.s1, test.s2, equal[float64]); got != test.wantEqual { t.Errorf("Equal(%v, %v, equal[float64]) = %t, want %t", test.s1, test.s2, got, test.wantEqual) } if got := EqualFunc(test.s1, test.s2, equalNaN[float64]); got != test.wantEqualNaN { t.Errorf("Equal(%v, %v, equalNaN[float64]) = %t, want %t", test.s1, test.s2, got, test.wantEqualNaN) } } s1 := []int{1, 2, 3} s2 := []int{2, 3, 4} if EqualFunc(s1, s1, offByOne) { t.Errorf("EqualFunc(%v, %v, offByOne) = true, want false", s1, s1) } if !EqualFunc(s1, s2, offByOne) { t.Errorf("EqualFunc(%v, %v, offByOne) = false, want true", s1, s2) } s3 := []string{"a", "b", "c"} s4 := []string{"A", "B", "C"} if !EqualFunc(s3, s4, strings.EqualFold) { t.Errorf("EqualFunc(%v, %v, strings.EqualFold) = false, want true", s3, s4) } cmpIntString := func(v1 int, v2 string) bool { return string(rune(v1)-1+'a') == v2 } if !EqualFunc(s1, s3, cmpIntString) { t.Errorf("EqualFunc(%v, %v, cmpIntString) = false, want true", s1, s3) } } func BenchmarkEqualFunc_Large(b *testing.B) { type Large [4 * 1024]byte xs := make([]Large, 1024) ys := make([]Large, 1024) for i := 0; i < b.N; i++ { _ = EqualFunc(xs, ys, func(x, y Large) bool { return x == y }) } } var compareIntTests = []struct { s1, s2 []int want int }{ { []int{1}, []int{1}, 0, }, { []int{1}, []int{}, 1, }, { []int{}, []int{1}, -1, }, { []int{}, []int{}, 0, }, { []int{1, 2, 3}, []int{1, 2, 3}, 0, }, { []int{1, 2, 3}, []int{1, 2, 3, 4}, -1, }, { []int{1, 2, 3, 4}, []int{1, 2, 3}, +1, }, { []int{1, 2, 3}, []int{1, 4, 3}, -1, }, { []int{1, 4, 3}, []int{1, 2, 3}, +1, }, { []int{1, 4, 3}, []int{1, 2, 3, 8, 9}, +1, }, } var compareFloatTests = []struct { s1, s2 []float64 want int }{ { []float64{}, []float64{}, 0, }, { []float64{1}, []float64{1}, 0, }, { []float64{math.NaN()}, []float64{math.NaN()}, 0, }, { []float64{1, 2, math.NaN()}, []float64{1, 2, math.NaN()}, 0, }, { []float64{1, math.NaN(), 3}, []float64{1, math.NaN(), 4}, -1, }, { []float64{1, math.NaN(), 3}, []float64{1, 2, 4}, -1, }, { []float64{1, math.NaN(), 3}, []float64{1, 2, math.NaN()}, -1, }, { []float64{1, 2, 3}, []float64{1, 2, math.NaN()}, +1, }, { []float64{1, 2, 3}, []float64{1, math.NaN(), 3}, +1, }, { []float64{1, math.NaN(), 3, 4}, []float64{1, 2, math.NaN()}, -1, }, } func TestCompare(t *testing.T) { intWant := func(want bool) string { if want { return "0" } return "!= 0" } for _, test := range equalIntTests { if got := Compare(test.s1, test.s2); (got == 0) != test.want { t.Errorf("Compare(%v, %v) = %d, want %s", test.s1, test.s2, got, intWant(test.want)) } } for _, test := range equalFloatTests { if got := Compare(test.s1, test.s2); (got == 0) != test.wantEqualNaN { t.Errorf("Compare(%v, %v) = %d, want %s", test.s1, test.s2, got, intWant(test.wantEqualNaN)) } } for _, test := range compareIntTests { if got := Compare(test.s1, test.s2); got != test.want { t.Errorf("Compare(%v, %v) = %d, want %d", test.s1, test.s2, got, test.want) } } for _, test := range compareFloatTests { if got := Compare(test.s1, test.s2); got != test.want { t.Errorf("Compare(%v, %v) = %d, want %d", test.s1, test.s2, got, test.want) } } } func equalToCmp[T comparable](eq func(T, T) bool) func(T, T) int { return func(v1, v2 T) int { if eq(v1, v2) { return 0 } return 1 } } func TestCompareFunc(t *testing.T) { intWant := func(want bool) string { if want { return "0" } return "!= 0" } for _, test := range equalIntTests { if got := CompareFunc(test.s1, test.s2, equalToCmp(equal[int])); (got == 0) != test.want { t.Errorf("CompareFunc(%v, %v, equalToCmp(equal[int])) = %d, want %s", test.s1, test.s2, got, intWant(test.want)) } } for _, test := range equalFloatTests { if got := CompareFunc(test.s1, test.s2, equalToCmp(equal[float64])); (got == 0) != test.wantEqual { t.Errorf("CompareFunc(%v, %v, equalToCmp(equal[float64])) = %d, want %s", test.s1, test.s2, got, intWant(test.wantEqual)) } } for _, test := range compareIntTests { if got := CompareFunc(test.s1, test.s2, cmp.Compare[int]); got != test.want { t.Errorf("CompareFunc(%v, %v, cmp[int]) = %d, want %d", test.s1, test.s2, got, test.want) } } for _, test := range compareFloatTests { if got := CompareFunc(test.s1, test.s2, cmp.Compare[float64]); got != test.want { t.Errorf("CompareFunc(%v, %v, cmp[float64]) = %d, want %d", test.s1, test.s2, got, test.want) } } s1 := []int{1, 2, 3} s2 := []int{2, 3, 4} if got := CompareFunc(s1, s2, equalToCmp(offByOne)); got != 0 { t.Errorf("CompareFunc(%v, %v, offByOne) = %d, want 0", s1, s2, got) } s3 := []string{"a", "b", "c"} s4 := []string{"A", "B", "C"} if got := CompareFunc(s3, s4, strings.Compare); got != 1 { t.Errorf("CompareFunc(%v, %v, strings.Compare) = %d, want 1", s3, s4, got) } compareLower := func(v1, v2 string) int { return strings.Compare(strings.ToLower(v1), strings.ToLower(v2)) } if got := CompareFunc(s3, s4, compareLower); got != 0 { t.Errorf("CompareFunc(%v, %v, compareLower) = %d, want 0", s3, s4, got) } cmpIntString := func(v1 int, v2 string) int { return strings.Compare(string(rune(v1)-1+'a'), v2) } if got := CompareFunc(s1, s3, cmpIntString); got != 0 { t.Errorf("CompareFunc(%v, %v, cmpIntString) = %d, want 0", s1, s3, got) } } var indexTests = []struct { s []int v int want int }{ { nil, 0, -1, }, { []int{}, 0, -1, }, { []int{1, 2, 3}, 2, 1, }, { []int{1, 2, 2, 3}, 2, 1, }, { []int{1, 2, 3, 2}, 2, 1, }, } func TestIndex(t *testing.T) { for _, test := range indexTests { if got := Index(test.s, test.v); got != test.want { t.Errorf("Index(%v, %v) = %d, want %d", test.s, test.v, got, test.want) } } } func equalToIndex[T any](f func(T, T) bool, v1 T) func(T) bool { return func(v2 T) bool { return f(v1, v2) } } func BenchmarkIndex_Large(b *testing.B) { type Large [4 * 1024]byte ss := make([]Large, 1024) for i := 0; i < b.N; i++ { _ = Index(ss, Large{1}) } } func TestIndexFunc(t *testing.T) { for _, test := range indexTests { if got := IndexFunc(test.s, equalToIndex(equal[int], test.v)); got != test.want { t.Errorf("IndexFunc(%v, equalToIndex(equal[int], %v)) = %d, want %d", test.s, test.v, got, test.want) } } s1 := []string{"hi", "HI"} if got := IndexFunc(s1, equalToIndex(equal[string], "HI")); got != 1 { t.Errorf("IndexFunc(%v, equalToIndex(equal[string], %q)) = %d, want %d", s1, "HI", got, 1) } if got := IndexFunc(s1, equalToIndex(strings.EqualFold, "HI")); got != 0 { t.Errorf("IndexFunc(%v, equalToIndex(strings.EqualFold, %q)) = %d, want %d", s1, "HI", got, 0) } } func BenchmarkIndexFunc_Large(b *testing.B) { type Large [4 * 1024]byte ss := make([]Large, 1024) for i := 0; i < b.N; i++ { _ = IndexFunc(ss, func(e Large) bool { return e == Large{1} }) } } func TestContains(t *testing.T) { for _, test := range indexTests { if got := Contains(test.s, test.v); got != (test.want != -1) { t.Errorf("Contains(%v, %v) = %t, want %t", test.s, test.v, got, test.want != -1) } } } func TestContainsFunc(t *testing.T) { for _, test := range indexTests { if got := ContainsFunc(test.s, equalToIndex(equal[int], test.v)); got != (test.want != -1) { t.Errorf("ContainsFunc(%v, equalToIndex(equal[int], %v)) = %t, want %t", test.s, test.v, got, test.want != -1) } } s1 := []string{"hi", "HI"} if got := ContainsFunc(s1, equalToIndex(equal[string], "HI")); got != true { t.Errorf("ContainsFunc(%v, equalToContains(equal[string], %q)) = %t, want %t", s1, "HI", got, true) } if got := ContainsFunc(s1, equalToIndex(equal[string], "hI")); got != false { t.Errorf("ContainsFunc(%v, equalToContains(strings.EqualFold, %q)) = %t, want %t", s1, "hI", got, false) } if got := ContainsFunc(s1, equalToIndex(strings.EqualFold, "hI")); got != true { t.Errorf("ContainsFunc(%v, equalToContains(strings.EqualFold, %q)) = %t, want %t", s1, "hI", got, true) } } var insertTests = []struct { s []int i int add []int want []int }{ { []int{1, 2, 3}, 0, []int{4}, []int{4, 1, 2, 3}, }, { []int{1, 2, 3}, 1, []int{4}, []int{1, 4, 2, 3}, }, { []int{1, 2, 3}, 3, []int{4}, []int{1, 2, 3, 4}, }, { []int{1, 2, 3}, 2, []int{4, 5}, []int{1, 2, 4, 5, 3}, }, } func TestInsert(t *testing.T) { s := []int{1, 2, 3} if got := Insert(s, 0); !Equal(got, s) { t.Errorf("Insert(%v, 0) = %v, want %v", s, got, s) } for _, test := range insertTests { copy := Clone(test.s) if got := Insert(copy, test.i, test.add...); !Equal(got, test.want) { t.Errorf("Insert(%v, %d, %v...) = %v, want %v", test.s, test.i, test.add, got, test.want) } } if !testenv.OptimizationOff() && !race.Enabled && !asan.Enabled && !msan.Enabled { // Allocations should be amortized. const count = 50 n := testing.AllocsPerRun(10, func() { s := []int{1, 2, 3} for i := 0; i < count; i++ { s = Insert(s, 0, 1) } }) if n > count/2 { t.Errorf("too many allocations inserting %d elements: got %v, want less than %d", count, n, count/2) } } } func TestInsertOverlap(t *testing.T) { const N = 10 a := make([]int, N) want := make([]int, 2*N) for n := 0; n <= N; n++ { // length for i := 0; i <= n; i++ { // insertion point for x := 0; x <= N; x++ { // start of inserted data for y := x; y <= N; y++ { // end of inserted data for k := 0; k < N; k++ { a[k] = k } want = want[:0] want = append(want, a[:i]...) want = append(want, a[x:y]...) want = append(want, a[i:n]...) got := Insert(a[:n], i, a[x:y]...) if !Equal(got, want) { t.Errorf("Insert with overlap failed n=%d i=%d x=%d y=%d, got %v want %v", n, i, x, y, got, want) } } } } } } func TestInsertPanics(t *testing.T) { a := [3]int{} b := [1]int{} for _, test := range []struct { name string s []int i int v []int }{ // There are no values. {"with negative index", a[:1:1], -1, nil}, {"with out-of-bounds index and > cap", a[:1:1], 2, nil}, {"with out-of-bounds index and = cap", a[:1:2], 2, nil}, {"with out-of-bounds index and < cap", a[:1:3], 2, nil}, // There are values. {"with negative index", a[:1:1], -1, b[:]}, {"with out-of-bounds index and > cap", a[:1:1], 2, b[:]}, {"with out-of-bounds index and = cap", a[:1:2], 2, b[:]}, {"with out-of-bounds index and < cap", a[:1:3], 2, b[:]}, } { if !panics(func() { _ = Insert(test.s, test.i, test.v...) }) { t.Errorf("Insert %s: got no panic, want panic", test.name) } } } var deleteTests = []struct { s []int i, j int want []int }{ { []int{1, 2, 3}, 0, 0, []int{1, 2, 3}, }, { []int{1, 2, 3}, 0, 1, []int{2, 3}, }, { []int{1, 2, 3}, 3, 3, []int{1, 2, 3}, }, { []int{1, 2, 3}, 0, 2, []int{3}, }, { []int{1, 2, 3}, 0, 3, []int{}, }, } func TestDelete(t *testing.T) { for _, test := range deleteTests { copy := Clone(test.s) if got := Delete(copy, test.i, test.j); !Equal(got, test.want) { t.Errorf("Delete(%v, %d, %d) = %v, want %v", test.s, test.i, test.j, got, test.want) } } } var deleteFuncTests = []struct { s []int fn func(int) bool want []int }{ { nil, func(int) bool { return true }, nil, }, { []int{1, 2, 3}, func(int) bool { return true }, nil, }, { []int{1, 2, 3}, func(int) bool { return false }, []int{1, 2, 3}, }, { []int{1, 2, 3}, func(i int) bool { return i > 2 }, []int{1, 2}, }, { []int{1, 2, 3}, func(i int) bool { return i < 2 }, []int{2, 3}, }, { []int{10, 2, 30}, func(i int) bool { return i >= 10 }, []int{2}, }, } func TestDeleteFunc(t *testing.T) { for i, test := range deleteFuncTests { copy := Clone(test.s) if got := DeleteFunc(copy, test.fn); !Equal(got, test.want) { t.Errorf("DeleteFunc case %d: got %v, want %v", i, got, test.want) } } } func panics(f func()) (b bool) { defer func() { if x := recover(); x != nil { b = true } }() f() return false } func TestDeletePanics(t *testing.T) { s := []int{0, 1, 2, 3, 4} s = s[0:2] _ = s[0:4] // this is a valid slice of s for _, test := range []struct { name string s []int i, j int }{ {"with negative first index", []int{42}, -2, 1}, {"with negative second index", []int{42}, 1, -1}, {"with out-of-bounds first index", []int{42}, 2, 3}, {"with out-of-bounds second index", []int{42}, 0, 2}, {"with out-of-bounds both indexes", []int{42}, 2, 2}, {"with invalid i>j", []int{42}, 1, 0}, {"s[i:j] is valid and j > len(s)", s, 0, 4}, {"s[i:j] is valid and i == j > len(s)", s, 3, 3}, } { if !panics(func() { _ = Delete(test.s, test.i, test.j) }) { t.Errorf("Delete %s: got no panic, want panic", test.name) } } } func TestDeleteClearTail(t *testing.T) { mem := []*int{new(int), new(int), new(int), new(int), new(int), new(int)} s := mem[0:5] // there is 1 element beyond len(s), within cap(s) s = Delete(s, 2, 4) if mem[3] != nil || mem[4] != nil { // Check that potential memory leak is avoided t.Errorf("Delete: want nil discarded elements, got %v, %v", mem[3], mem[4]) } if mem[5] == nil { t.Errorf("Delete: want unchanged elements beyond original len, got nil") } } func TestDeleteFuncClearTail(t *testing.T) { mem := []*int{new(int), new(int), new(int), new(int), new(int), new(int)} *mem[2], *mem[3] = 42, 42 s := mem[0:5] // there is 1 element beyond len(s), within cap(s) s = DeleteFunc(s, func(i *int) bool { return i != nil && *i == 42 }) if mem[3] != nil || mem[4] != nil { // Check that potential memory leak is avoided t.Errorf("DeleteFunc: want nil discarded elements, got %v, %v", mem[3], mem[4]) } if mem[5] == nil { t.Errorf("DeleteFunc: want unchanged elements beyond original len, got nil") } } func TestClone(t *testing.T) { s1 := []int{1, 2, 3} s2 := Clone(s1) if !Equal(s1, s2) { t.Errorf("Clone(%v) = %v, want %v", s1, s2, s1) } s1[0] = 4 want := []int{1, 2, 3} if !Equal(s2, want) { t.Errorf("Clone(%v) changed unexpectedly to %v", want, s2) } if got := Clone([]int(nil)); got != nil { t.Errorf("Clone(nil) = %#v, want nil", got) } if got := Clone(s1[:0]); got == nil || len(got) != 0 { t.Errorf("Clone(%v) = %#v, want %#v", s1[:0], got, s1[:0]) } } var compactTests = []struct { name string s []int want []int }{ { "nil", nil, nil, }, { "one", []int{1}, []int{1}, }, { "sorted", []int{1, 2, 3}, []int{1, 2, 3}, }, { "2 items", []int{1, 1, 2}, []int{1, 2}, }, { "unsorted", []int{1, 2, 1}, []int{1, 2, 1}, }, { "many", []int{1, 2, 2, 3, 3, 4}, []int{1, 2, 3, 4}, }, } func TestCompact(t *testing.T) { for _, test := range compactTests { copy := Clone(test.s) if got := Compact(copy); !Equal(got, test.want) { t.Errorf("Compact(%v) = %v, want %v", test.s, got, test.want) } } } func BenchmarkCompact(b *testing.B) { for _, c := range compactTests { b.Run(c.name, func(b *testing.B) { ss := make([]int, 0, 64) for k := 0; k < b.N; k++ { ss = ss[:0] ss = append(ss, c.s...) _ = Compact(ss) } }) } } func BenchmarkCompact_Large(b *testing.B) { type Large [16]int const N = 1024 b.Run("all_dup", func(b *testing.B) { ss := make([]Large, N) b.ResetTimer() for i := 0; i < b.N; i++ { _ = Compact(ss) } }) b.Run("no_dup", func(b *testing.B) { ss := make([]Large, N) for i := range ss { ss[i][0] = i } b.ResetTimer() for i := 0; i < b.N; i++ { _ = Compact(ss) } }) } func TestCompactFunc(t *testing.T) { for _, test := range compactTests { copy := Clone(test.s) if got := CompactFunc(copy, equal[int]); !Equal(got, test.want) { t.Errorf("CompactFunc(%v, equal[int]) = %v, want %v", test.s, got, test.want) } } s1 := []string{"a", "a", "A", "B", "b"} copy := Clone(s1) want := []string{"a", "B"} if got := CompactFunc(copy, strings.EqualFold); !Equal(got, want) { t.Errorf("CompactFunc(%v, strings.EqualFold) = %v, want %v", s1, got, want) } } func TestCompactClearTail(t *testing.T) { one, two, three, four := 1, 2, 3, 4 mem := []*int{&one, &one, &two, &two, &three, &four} s := mem[0:5] // there is 1 element beyond len(s), within cap(s) copy := Clone(s) s = Compact(s) if want := []*int{&one, &two, &three}; !Equal(s, want) { t.Errorf("Compact(%v) = %v, want %v", copy, s, want) } if mem[3] != nil || mem[4] != nil { // Check that potential memory leak is avoided t.Errorf("Compact: want nil discarded elements, got %v, %v", mem[3], mem[4]) } if mem[5] != &four { t.Errorf("Compact: want unchanged element beyond original len, got %v", mem[5]) } } func TestCompactFuncClearTail(t *testing.T) { a, b, c, d, e, f := 1, 1, 2, 2, 3, 4 mem := []*int{&a, &b, &c, &d, &e, &f} s := mem[0:5] // there is 1 element beyond len(s), within cap(s) copy := Clone(s) s = CompactFunc(s, func(x, y *int) bool { if x == nil || y == nil { return x == y } return *x == *y }) if want := []*int{&a, &c, &e}; !Equal(s, want) { t.Errorf("CompactFunc(%v) = %v, want %v", copy, s, want) } if mem[3] != nil || mem[4] != nil { // Check that potential memory leak is avoided t.Errorf("CompactFunc: want nil discarded elements, got %v, %v", mem[3], mem[4]) } if mem[5] != &f { t.Errorf("CompactFunc: want unchanged elements beyond original len, got %v", mem[5]) } } func BenchmarkCompactFunc(b *testing.B) { for _, c := range compactTests { b.Run(c.name, func(b *testing.B) { ss := make([]int, 0, 64) for k := 0; k < b.N; k++ { ss = ss[:0] ss = append(ss, c.s...) _ = CompactFunc(ss, func(a, b int) bool { return a == b }) } }) } } func BenchmarkCompactFunc_Large(b *testing.B) { type Element = int const N = 1024 * 1024 b.Run("all_dup", func(b *testing.B) { ss := make([]Element, N) b.ResetTimer() for i := 0; i < b.N; i++ { _ = CompactFunc(ss, func(a, b Element) bool { return a == b }) } }) b.Run("no_dup", func(b *testing.B) { ss := make([]Element, N) for i := range ss { ss[i] = i } b.ResetTimer() for i := 0; i < b.N; i++ { _ = CompactFunc(ss, func(a, b Element) bool { return a == b }) } }) } func TestGrow(t *testing.T) { s1 := []int{1, 2, 3} copy := Clone(s1) s2 := Grow(copy, 1000) if !Equal(s1, s2) { t.Errorf("Grow(%v) = %v, want %v", s1, s2, s1) } if cap(s2) < 1000+len(s1) { t.Errorf("after Grow(%v) cap = %d, want >= %d", s1, cap(s2), 1000+len(s1)) } // Test mutation of elements between length and capacity. copy = Clone(s1) s3 := Grow(copy[:1], 2)[:3] if !Equal(s1, s3) { t.Errorf("Grow should not mutate elements between length and capacity") } s3 = Grow(copy[:1], 1000)[:3] if !Equal(s1, s3) { t.Errorf("Grow should not mutate elements between length and capacity") } // Test number of allocations. if n := testing.AllocsPerRun(100, func() { _ = Grow(s2, cap(s2)-len(s2)) }); n != 0 { t.Errorf("Grow should not allocate when given sufficient capacity; allocated %v times", n) } if n := testing.AllocsPerRun(100, func() { _ = Grow(s2, cap(s2)-len(s2)+1) }); n != 1 { errorf := t.Errorf if race.Enabled || msan.Enabled || asan.Enabled || testenv.OptimizationOff() { errorf = t.Logf // this allocates multiple times in race detector mode } errorf("Grow should allocate once when given insufficient capacity; allocated %v times", n) } // Test for negative growth sizes. var gotPanic bool func() { defer func() { gotPanic = recover() != nil }() _ = Grow(s1, -1) }() if !gotPanic { t.Errorf("Grow(-1) did not panic; expected a panic") } } func TestClip(t *testing.T) { s1 := []int{1, 2, 3, 4, 5, 6}[:3] orig := Clone(s1) if len(s1) != 3 { t.Errorf("len(%v) = %d, want 3", s1, len(s1)) } if cap(s1) < 6 { t.Errorf("cap(%v[:3]) = %d, want >= 6", orig, cap(s1)) } s2 := Clip(s1) if !Equal(s1, s2) { t.Errorf("Clip(%v) = %v, want %v", s1, s2, s1) } if cap(s2) != 3 { t.Errorf("cap(Clip(%v)) = %d, want 3", orig, cap(s2)) } } func TestReverse(t *testing.T) { even := []int{3, 1, 4, 1, 5, 9} // len = 6 Reverse(even) if want := []int{9, 5, 1, 4, 1, 3}; !Equal(even, want) { t.Errorf("Reverse(even) = %v, want %v", even, want) } odd := []int{3, 1, 4, 1, 5, 9, 2} // len = 7 Reverse(odd) if want := []int{2, 9, 5, 1, 4, 1, 3}; !Equal(odd, want) { t.Errorf("Reverse(odd) = %v, want %v", odd, want) } words := strings.Fields("one two three") Reverse(words) if want := strings.Fields("three two one"); !Equal(words, want) { t.Errorf("Reverse(words) = %v, want %v", words, want) } singleton := []string{"one"} Reverse(singleton) if want := []string{"one"}; !Equal(singleton, want) { t.Errorf("Reverse(singeleton) = %v, want %v", singleton, want) } Reverse[[]string](nil) } // naiveReplace is a baseline implementation to the Replace function. func naiveReplace[S ~[]E, E any](s S, i, j int, v ...E) S { s = Delete(s, i, j) s = Insert(s, i, v...) return s } func TestReplace(t *testing.T) { for _, test := range []struct { s, v []int i, j int }{ {}, // all zero value { s: []int{1, 2, 3, 4}, v: []int{5}, i: 1, j: 2, }, { s: []int{1, 2, 3, 4}, v: []int{5, 6, 7, 8}, i: 1, j: 2, }, { s: func() []int { s := make([]int, 3, 20) s[0] = 0 s[1] = 1 s[2] = 2 return s }(), v: []int{3, 4, 5, 6, 7}, i: 0, j: 1, }, } { ss, vv := Clone(test.s), Clone(test.v) want := naiveReplace(ss, test.i, test.j, vv...) got := Replace(test.s, test.i, test.j, test.v...) if !Equal(got, want) { t.Errorf("Replace(%v, %v, %v, %v) = %v, want %v", test.s, test.i, test.j, test.v, got, want) } } } func TestReplacePanics(t *testing.T) { s := []int{0, 1, 2, 3, 4} s = s[0:2] _ = s[0:4] // this is a valid slice of s for _, test := range []struct { name string s, v []int i, j int }{ {"indexes out of order", []int{1, 2}, []int{3}, 2, 1}, {"large index", []int{1, 2}, []int{3}, 1, 10}, {"negative index", []int{1, 2}, []int{3}, -1, 2}, {"s[i:j] is valid and j > len(s)", s, nil, 0, 4}, } { ss, vv := Clone(test.s), Clone(test.v) if !panics(func() { _ = Replace(ss, test.i, test.j, vv...) }) { t.Errorf("Replace %s: should have panicked", test.name) } } } func TestReplaceGrow(t *testing.T) { // When Replace needs to allocate a new slice, we want the original slice // to not be changed. a, b, c, d, e, f := 1, 2, 3, 4, 5, 6 mem := []*int{&a, &b, &c, &d, &e, &f} memcopy := Clone(mem) s := mem[0:5] // there is 1 element beyond len(s), within cap(s) copy := Clone(s) original := s // The new elements don't fit within cap(s), so Replace will allocate. z := 99 s = Replace(s, 1, 3, &z, &z, &z, &z) if want := []*int{&a, &z, &z, &z, &z, &d, &e}; !Equal(s, want) { t.Errorf("Replace(%v, 1, 3, %v, %v, %v, %v) = %v, want %v", copy, &z, &z, &z, &z, s, want) } if !Equal(original, copy) { t.Errorf("original slice has changed, got %v, want %v", original, copy) } if !Equal(mem, memcopy) { // Changing the original tail s[len(s):cap(s)] is unwanted t.Errorf("original backing memory has changed, got %v, want %v", mem, memcopy) } } func TestReplaceClearTail(t *testing.T) { a, b, c, d, e, f := 1, 2, 3, 4, 5, 6 mem := []*int{&a, &b, &c, &d, &e, &f} s := mem[0:5] // there is 1 element beyond len(s), within cap(s) copy := Clone(s) y, z := 8, 9 s = Replace(s, 1, 4, &y, &z) if want := []*int{&a, &y, &z, &e}; !Equal(s, want) { t.Errorf("Replace(%v) = %v, want %v", copy, s, want) } if mem[4] != nil { // Check that potential memory leak is avoided t.Errorf("Replace: want nil discarded element, got %v", mem[4]) } if mem[5] != &f { t.Errorf("Replace: want unchanged elements beyond original len, got %v", mem[5]) } } func TestReplaceOverlap(t *testing.T) { const N = 10 a := make([]int, N) want := make([]int, 2*N) for n := 0; n <= N; n++ { // length for i := 0; i <= n; i++ { // insertion point 1 for j := i; j <= n; j++ { // insertion point 2 for x := 0; x <= N; x++ { // start of inserted data for y := x; y <= N; y++ { // end of inserted data for k := 0; k < N; k++ { a[k] = k } want = want[:0] want = append(want, a[:i]...) want = append(want, a[x:y]...) want = append(want, a[j:n]...) got := Replace(a[:n], i, j, a[x:y]...) if !Equal(got, want) { t.Errorf("Insert with overlap failed n=%d i=%d j=%d x=%d y=%d, got %v want %v", n, i, j, x, y, got, want) } } } } } } } func TestReplaceEndClearTail(t *testing.T) { s := []int{11, 22, 33} v := []int{99} // case when j == len(s) i, j := 1, 3 s = Replace(s, i, j, v...) x := s[:3][2] if want := 0; x != want { t.Errorf("TestReplaceEndClearTail: obsolete element is %d, want %d", x, want) } } func BenchmarkReplace(b *testing.B) { cases := []struct { name string s, v func() []int i, j int }{ { name: "fast", s: func() []int { return make([]int, 100) }, v: func() []int { return make([]int, 20) }, i: 10, j: 40, }, { name: "slow", s: func() []int { return make([]int, 100) }, v: func() []int { return make([]int, 20) }, i: 0, j: 2, }, } for _, c := range cases { b.Run("naive-"+c.name, func(b *testing.B) { for k := 0; k < b.N; k++ { s := c.s() v := c.v() _ = naiveReplace(s, c.i, c.j, v...) } }) b.Run("optimized-"+c.name, func(b *testing.B) { for k := 0; k < b.N; k++ { s := c.s() v := c.v() _ = Replace(s, c.i, c.j, v...) } }) } } func TestInsertGrowthRate(t *testing.T) { b := make([]byte, 1) maxCap := cap(b) nGrow := 0 const N = 1e6 for i := 0; i < N; i++ { b = Insert(b, len(b)-1, 0) if cap(b) > maxCap { maxCap = cap(b) nGrow++ } } want := int(math.Log(N) / math.Log(1.25)) // 1.25 == growth rate for large slices if nGrow > want { t.Errorf("too many grows. got:%d want:%d", nGrow, want) } } func TestReplaceGrowthRate(t *testing.T) { b := make([]byte, 2) maxCap := cap(b) nGrow := 0 const N = 1e6 for i := 0; i < N; i++ { b = Replace(b, len(b)-2, len(b)-1, 0, 0) if cap(b) > maxCap { maxCap = cap(b) nGrow++ } } want := int(math.Log(N) / math.Log(1.25)) // 1.25 == growth rate for large slices if nGrow > want { t.Errorf("too many grows. got:%d want:%d", nGrow, want) } } func apply[T any](v T, f func(T)) { f(v) } // Test type inference with a named slice type. func TestInference(t *testing.T) { s1 := []int{1, 2, 3} apply(s1, Reverse) if want := []int{3, 2, 1}; !Equal(s1, want) { t.Errorf("Reverse(%v) = %v, want %v", []int{1, 2, 3}, s1, want) } type S []int s2 := S{4, 5, 6} apply(s2, Reverse) if want := (S{6, 5, 4}); !Equal(s2, want) { t.Errorf("Reverse(%v) = %v, want %v", S{4, 5, 6}, s2, want) } } func TestConcat(t *testing.T) { cases := []struct { s [][]int want []int }{ { s: [][]int{nil}, want: nil, }, { s: [][]int{{1}}, want: []int{1}, }, { s: [][]int{{1}, {2}}, want: []int{1, 2}, }, { s: [][]int{{1}, nil, {2}}, want: []int{1, 2}, }, } for _, tc := range cases { got := Concat(tc.s...) if !Equal(tc.want, got) { t.Errorf("Concat(%v) = %v, want %v", tc.s, got, tc.want) } var sink []int allocs := testing.AllocsPerRun(5, func() { sink = Concat(tc.s...) }) _ = sink if allocs > 1 { errorf := t.Errorf if testenv.OptimizationOff() || race.Enabled || asan.Enabled || msan.Enabled { errorf = t.Logf } errorf("Concat(%v) allocated %v times; want 1", tc.s, allocs) } } } func TestConcat_too_large(t *testing.T) { // Use zero length element to minimize memory in testing type void struct{} cases := []struct { lengths []int shouldPanic bool }{ { lengths: []int{0, 0}, shouldPanic: false, }, { lengths: []int{math.MaxInt, 0}, shouldPanic: false, }, { lengths: []int{0, math.MaxInt}, shouldPanic: false, }, { lengths: []int{math.MaxInt - 1, 1}, shouldPanic: false, }, { lengths: []int{math.MaxInt - 1, 1, 1}, shouldPanic: true, }, { lengths: []int{math.MaxInt, 1}, shouldPanic: true, }, { lengths: []int{math.MaxInt, math.MaxInt}, shouldPanic: true, }, } for _, tc := range cases { var r any ss := make([][]void, 0, len(tc.lengths)) for _, l := range tc.lengths { s := make([]void, l) ss = append(ss, s) } func() { defer func() { r = recover() }() _ = Concat(ss...) }() if didPanic := r != nil; didPanic != tc.shouldPanic { t.Errorf("slices.Concat(lens(%v)) got panic == %v", tc.lengths, didPanic) } } } func TestRepeat(t *testing.T) { // normal cases for _, tc := range []struct { x []int count int want []int }{ {x: []int(nil), count: 0, want: []int{}}, {x: []int(nil), count: 1, want: []int{}}, {x: []int(nil), count: math.MaxInt, want: []int{}}, {x: []int{}, count: 0, want: []int{}}, {x: []int{}, count: 1, want: []int{}}, {x: []int{}, count: math.MaxInt, want: []int{}}, {x: []int{0}, count: 0, want: []int{}}, {x: []int{0}, count: 1, want: []int{0}}, {x: []int{0}, count: 2, want: []int{0, 0}}, {x: []int{0}, count: 3, want: []int{0, 0, 0}}, {x: []int{0}, count: 4, want: []int{0, 0, 0, 0}}, {x: []int{0, 1}, count: 0, want: []int{}}, {x: []int{0, 1}, count: 1, want: []int{0, 1}}, {x: []int{0, 1}, count: 2, want: []int{0, 1, 0, 1}}, {x: []int{0, 1}, count: 3, want: []int{0, 1, 0, 1, 0, 1}}, {x: []int{0, 1}, count: 4, want: []int{0, 1, 0, 1, 0, 1, 0, 1}}, {x: []int{0, 1, 2}, count: 0, want: []int{}}, {x: []int{0, 1, 2}, count: 1, want: []int{0, 1, 2}}, {x: []int{0, 1, 2}, count: 2, want: []int{0, 1, 2, 0, 1, 2}}, {x: []int{0, 1, 2}, count: 3, want: []int{0, 1, 2, 0, 1, 2, 0, 1, 2}}, {x: []int{0, 1, 2}, count: 4, want: []int{0, 1, 2, 0, 1, 2, 0, 1, 2, 0, 1, 2}}, } { if got := Repeat(tc.x, tc.count); got == nil || cap(got) != cap(tc.want) || !Equal(got, tc.want) { t.Errorf("Repeat(%v, %v): got: %v, want: %v, (got == nil): %v, cap(got): %v, cap(want): %v", tc.x, tc.count, got, tc.want, got == nil, cap(got), cap(tc.want)) } } // big slices for _, tc := range []struct { x []struct{} count int want []struct{} }{ {x: make([]struct{}, math.MaxInt/1-0), count: 1, want: make([]struct{}, 1*(math.MaxInt/1-0))}, {x: make([]struct{}, math.MaxInt/2-1), count: 2, want: make([]struct{}, 2*(math.MaxInt/2-1))}, {x: make([]struct{}, math.MaxInt/3-2), count: 3, want: make([]struct{}, 3*(math.MaxInt/3-2))}, {x: make([]struct{}, math.MaxInt/4-3), count: 4, want: make([]struct{}, 4*(math.MaxInt/4-3))}, {x: make([]struct{}, math.MaxInt/5-4), count: 5, want: make([]struct{}, 5*(math.MaxInt/5-4))}, {x: make([]struct{}, math.MaxInt/6-5), count: 6, want: make([]struct{}, 6*(math.MaxInt/6-5))}, {x: make([]struct{}, math.MaxInt/7-6), count: 7, want: make([]struct{}, 7*(math.MaxInt/7-6))}, {x: make([]struct{}, math.MaxInt/8-7), count: 8, want: make([]struct{}, 8*(math.MaxInt/8-7))}, {x: make([]struct{}, math.MaxInt/9-8), count: 9, want: make([]struct{}, 9*(math.MaxInt/9-8))}, } { if got := Repeat(tc.x, tc.count); got == nil || len(got) != len(tc.want) || cap(got) != cap(tc.want) { t.Errorf("Repeat(make([]struct{}, %v), %v): (got == nil): %v, len(got): %v, len(want): %v, cap(got): %v, cap(want): %v", len(tc.x), tc.count, got == nil, len(got), len(tc.want), cap(got), cap(tc.want)) } } } func TestRepeatPanics(t *testing.T) { for _, test := range []struct { name string x []struct{} count int }{ {name: "cannot be negative", x: make([]struct{}, 0), count: -1}, {name: "the result of (len(x) * count) overflows, hi > 0", x: make([]struct{}, 3), count: math.MaxInt}, {name: "the result of (len(x) * count) overflows, lo > maxInt", x: make([]struct{}, 2), count: 1 + math.MaxInt/2}, } { if !panics(func() { _ = Repeat(test.x, test.count) }) { t.Errorf("Repeat %s: got no panic, want panic", test.name) } } } func TestIssue68488(t *testing.T) { s := make([]int, 3) clone := Clone(s[1:1]) switch unsafe.SliceData(clone) { case &s[0], &s[1], &s[2]: t.Error("clone keeps alive s due to array overlap") } }