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Diffstat (limited to 'src/reflect/all_test.go')
| -rw-r--r-- | src/reflect/all_test.go | 4158 |
1 files changed, 4158 insertions, 0 deletions
diff --git a/src/reflect/all_test.go b/src/reflect/all_test.go new file mode 100644 index 000000000..7a01c95d8 --- /dev/null +++ b/src/reflect/all_test.go @@ -0,0 +1,4158 @@ +// Copyright 2009 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 reflect_test + +import ( + "bytes" + "encoding/base64" + "flag" + "fmt" + "io" + "math/rand" + "os" + . "reflect" + "runtime" + "sort" + "strings" + "sync" + "testing" + "time" + "unsafe" +) + +func TestBool(t *testing.T) { + v := ValueOf(true) + if v.Bool() != true { + t.Fatal("ValueOf(true).Bool() = false") + } +} + +type integer int +type T struct { + a int + b float64 + c string + d *int +} + +type pair struct { + i interface{} + s string +} + +func isDigit(c uint8) bool { return '0' <= c && c <= '9' } + +func assert(t *testing.T, s, want string) { + if s != want { + t.Errorf("have %#q want %#q", s, want) + } +} + +func typestring(i interface{}) string { return TypeOf(i).String() } + +var typeTests = []pair{ + {struct{ x int }{}, "int"}, + {struct{ x int8 }{}, "int8"}, + {struct{ x int16 }{}, "int16"}, + {struct{ x int32 }{}, "int32"}, + {struct{ x int64 }{}, "int64"}, + {struct{ x uint }{}, "uint"}, + {struct{ x uint8 }{}, "uint8"}, + {struct{ x uint16 }{}, "uint16"}, + {struct{ x uint32 }{}, "uint32"}, + {struct{ x uint64 }{}, "uint64"}, + {struct{ x float32 }{}, "float32"}, + {struct{ x float64 }{}, "float64"}, + {struct{ x int8 }{}, "int8"}, + {struct{ x (**int8) }{}, "**int8"}, + {struct{ x (**integer) }{}, "**reflect_test.integer"}, + {struct{ x ([32]int32) }{}, "[32]int32"}, + {struct{ x ([]int8) }{}, "[]int8"}, + {struct{ x (map[string]int32) }{}, "map[string]int32"}, + {struct{ x (chan<- string) }{}, "chan<- string"}, + {struct { + x struct { + c chan *int32 + d float32 + } + }{}, + "struct { c chan *int32; d float32 }", + }, + {struct{ x (func(a int8, b int32)) }{}, "func(int8, int32)"}, + {struct { + x struct { + c func(chan *integer, *int8) + } + }{}, + "struct { c func(chan *reflect_test.integer, *int8) }", + }, + {struct { + x struct { + a int8 + b int32 + } + }{}, + "struct { a int8; b int32 }", + }, + {struct { + x struct { + a int8 + b int8 + c int32 + } + }{}, + "struct { a int8; b int8; c int32 }", + }, + {struct { + x struct { + a int8 + b int8 + c int8 + d int32 + } + }{}, + "struct { a int8; b int8; c int8; d int32 }", + }, + {struct { + x struct { + a int8 + b int8 + c int8 + d int8 + e int32 + } + }{}, + "struct { a int8; b int8; c int8; d int8; e int32 }", + }, + {struct { + x struct { + a int8 + b int8 + c int8 + d int8 + e int8 + f int32 + } + }{}, + "struct { a int8; b int8; c int8; d int8; e int8; f int32 }", + }, + {struct { + x struct { + a int8 `reflect:"hi there"` + } + }{}, + `struct { a int8 "reflect:\"hi there\"" }`, + }, + {struct { + x struct { + a int8 `reflect:"hi \x00there\t\n\"\\"` + } + }{}, + `struct { a int8 "reflect:\"hi \\x00there\\t\\n\\\"\\\\\"" }`, + }, + {struct { + x struct { + f func(args ...int) + } + }{}, + "struct { f func(...int) }", + }, + {struct { + x (interface { + a(func(func(int) int) func(func(int)) int) + b() + }) + }{}, + "interface { reflect_test.a(func(func(int) int) func(func(int)) int); reflect_test.b() }", + }, +} + +var valueTests = []pair{ + {new(int), "132"}, + {new(int8), "8"}, + {new(int16), "16"}, + {new(int32), "32"}, + {new(int64), "64"}, + {new(uint), "132"}, + {new(uint8), "8"}, + {new(uint16), "16"}, + {new(uint32), "32"}, + {new(uint64), "64"}, + {new(float32), "256.25"}, + {new(float64), "512.125"}, + {new(complex64), "532.125+10i"}, + {new(complex128), "564.25+1i"}, + {new(string), "stringy cheese"}, + {new(bool), "true"}, + {new(*int8), "*int8(0)"}, + {new(**int8), "**int8(0)"}, + {new([5]int32), "[5]int32{0, 0, 0, 0, 0}"}, + {new(**integer), "**reflect_test.integer(0)"}, + {new(map[string]int32), "map[string]int32{<can't iterate on maps>}"}, + {new(chan<- string), "chan<- string"}, + {new(func(a int8, b int32)), "func(int8, int32)(0)"}, + {new(struct { + c chan *int32 + d float32 + }), + "struct { c chan *int32; d float32 }{chan *int32, 0}", + }, + {new(struct{ c func(chan *integer, *int8) }), + "struct { c func(chan *reflect_test.integer, *int8) }{func(chan *reflect_test.integer, *int8)(0)}", + }, + {new(struct { + a int8 + b int32 + }), + "struct { a int8; b int32 }{0, 0}", + }, + {new(struct { + a int8 + b int8 + c int32 + }), + "struct { a int8; b int8; c int32 }{0, 0, 0}", + }, +} + +func testType(t *testing.T, i int, typ Type, want string) { + s := typ.String() + if s != want { + t.Errorf("#%d: have %#q, want %#q", i, s, want) + } +} + +func TestTypes(t *testing.T) { + for i, tt := range typeTests { + testType(t, i, ValueOf(tt.i).Field(0).Type(), tt.s) + } +} + +func TestSet(t *testing.T) { + for i, tt := range valueTests { + v := ValueOf(tt.i) + v = v.Elem() + switch v.Kind() { + case Int: + v.SetInt(132) + case Int8: + v.SetInt(8) + case Int16: + v.SetInt(16) + case Int32: + v.SetInt(32) + case Int64: + v.SetInt(64) + case Uint: + v.SetUint(132) + case Uint8: + v.SetUint(8) + case Uint16: + v.SetUint(16) + case Uint32: + v.SetUint(32) + case Uint64: + v.SetUint(64) + case Float32: + v.SetFloat(256.25) + case Float64: + v.SetFloat(512.125) + case Complex64: + v.SetComplex(532.125 + 10i) + case Complex128: + v.SetComplex(564.25 + 1i) + case String: + v.SetString("stringy cheese") + case Bool: + v.SetBool(true) + } + s := valueToString(v) + if s != tt.s { + t.Errorf("#%d: have %#q, want %#q", i, s, tt.s) + } + } +} + +func TestSetValue(t *testing.T) { + for i, tt := range valueTests { + v := ValueOf(tt.i).Elem() + switch v.Kind() { + case Int: + v.Set(ValueOf(int(132))) + case Int8: + v.Set(ValueOf(int8(8))) + case Int16: + v.Set(ValueOf(int16(16))) + case Int32: + v.Set(ValueOf(int32(32))) + case Int64: + v.Set(ValueOf(int64(64))) + case Uint: + v.Set(ValueOf(uint(132))) + case Uint8: + v.Set(ValueOf(uint8(8))) + case Uint16: + v.Set(ValueOf(uint16(16))) + case Uint32: + v.Set(ValueOf(uint32(32))) + case Uint64: + v.Set(ValueOf(uint64(64))) + case Float32: + v.Set(ValueOf(float32(256.25))) + case Float64: + v.Set(ValueOf(512.125)) + case Complex64: + v.Set(ValueOf(complex64(532.125 + 10i))) + case Complex128: + v.Set(ValueOf(complex128(564.25 + 1i))) + case String: + v.Set(ValueOf("stringy cheese")) + case Bool: + v.Set(ValueOf(true)) + } + s := valueToString(v) + if s != tt.s { + t.Errorf("#%d: have %#q, want %#q", i, s, tt.s) + } + } +} + +var _i = 7 + +var valueToStringTests = []pair{ + {123, "123"}, + {123.5, "123.5"}, + {byte(123), "123"}, + {"abc", "abc"}, + {T{123, 456.75, "hello", &_i}, "reflect_test.T{123, 456.75, hello, *int(&7)}"}, + {new(chan *T), "*chan *reflect_test.T(&chan *reflect_test.T)"}, + {[10]int{1, 2, 3, 4, 5, 6, 7, 8, 9, 10}, "[10]int{1, 2, 3, 4, 5, 6, 7, 8, 9, 10}"}, + {&[10]int{1, 2, 3, 4, 5, 6, 7, 8, 9, 10}, "*[10]int(&[10]int{1, 2, 3, 4, 5, 6, 7, 8, 9, 10})"}, + {[]int{1, 2, 3, 4, 5, 6, 7, 8, 9, 10}, "[]int{1, 2, 3, 4, 5, 6, 7, 8, 9, 10}"}, + {&[]int{1, 2, 3, 4, 5, 6, 7, 8, 9, 10}, "*[]int(&[]int{1, 2, 3, 4, 5, 6, 7, 8, 9, 10})"}, +} + +func TestValueToString(t *testing.T) { + for i, test := range valueToStringTests { + s := valueToString(ValueOf(test.i)) + if s != test.s { + t.Errorf("#%d: have %#q, want %#q", i, s, test.s) + } + } +} + +func TestArrayElemSet(t *testing.T) { + v := ValueOf(&[10]int{1, 2, 3, 4, 5, 6, 7, 8, 9, 10}).Elem() + v.Index(4).SetInt(123) + s := valueToString(v) + const want = "[10]int{1, 2, 3, 4, 123, 6, 7, 8, 9, 10}" + if s != want { + t.Errorf("[10]int: have %#q want %#q", s, want) + } + + v = ValueOf([]int{1, 2, 3, 4, 5, 6, 7, 8, 9, 10}) + v.Index(4).SetInt(123) + s = valueToString(v) + const want1 = "[]int{1, 2, 3, 4, 123, 6, 7, 8, 9, 10}" + if s != want1 { + t.Errorf("[]int: have %#q want %#q", s, want1) + } +} + +func TestPtrPointTo(t *testing.T) { + var ip *int32 + var i int32 = 1234 + vip := ValueOf(&ip) + vi := ValueOf(&i).Elem() + vip.Elem().Set(vi.Addr()) + if *ip != 1234 { + t.Errorf("got %d, want 1234", *ip) + } + + ip = nil + vp := ValueOf(&ip).Elem() + vp.Set(Zero(vp.Type())) + if ip != nil { + t.Errorf("got non-nil (%p), want nil", ip) + } +} + +func TestPtrSetNil(t *testing.T) { + var i int32 = 1234 + ip := &i + vip := ValueOf(&ip) + vip.Elem().Set(Zero(vip.Elem().Type())) + if ip != nil { + t.Errorf("got non-nil (%d), want nil", *ip) + } +} + +func TestMapSetNil(t *testing.T) { + m := make(map[string]int) + vm := ValueOf(&m) + vm.Elem().Set(Zero(vm.Elem().Type())) + if m != nil { + t.Errorf("got non-nil (%p), want nil", m) + } +} + +func TestAll(t *testing.T) { + testType(t, 1, TypeOf((int8)(0)), "int8") + testType(t, 2, TypeOf((*int8)(nil)).Elem(), "int8") + + typ := TypeOf((*struct { + c chan *int32 + d float32 + })(nil)) + testType(t, 3, typ, "*struct { c chan *int32; d float32 }") + etyp := typ.Elem() + testType(t, 4, etyp, "struct { c chan *int32; d float32 }") + styp := etyp + f := styp.Field(0) + testType(t, 5, f.Type, "chan *int32") + + f, present := styp.FieldByName("d") + if !present { + t.Errorf("FieldByName says present field is absent") + } + testType(t, 6, f.Type, "float32") + + f, present = styp.FieldByName("absent") + if present { + t.Errorf("FieldByName says absent field is present") + } + + typ = TypeOf([32]int32{}) + testType(t, 7, typ, "[32]int32") + testType(t, 8, typ.Elem(), "int32") + + typ = TypeOf((map[string]*int32)(nil)) + testType(t, 9, typ, "map[string]*int32") + mtyp := typ + testType(t, 10, mtyp.Key(), "string") + testType(t, 11, mtyp.Elem(), "*int32") + + typ = TypeOf((chan<- string)(nil)) + testType(t, 12, typ, "chan<- string") + testType(t, 13, typ.Elem(), "string") + + // make sure tag strings are not part of element type + typ = TypeOf(struct { + d []uint32 `reflect:"TAG"` + }{}).Field(0).Type + testType(t, 14, typ, "[]uint32") +} + +func TestInterfaceGet(t *testing.T) { + var inter struct { + E interface{} + } + inter.E = 123.456 + v1 := ValueOf(&inter) + v2 := v1.Elem().Field(0) + assert(t, v2.Type().String(), "interface {}") + i2 := v2.Interface() + v3 := ValueOf(i2) + assert(t, v3.Type().String(), "float64") +} + +func TestInterfaceValue(t *testing.T) { + var inter struct { + E interface{} + } + inter.E = 123.456 + v1 := ValueOf(&inter) + v2 := v1.Elem().Field(0) + assert(t, v2.Type().String(), "interface {}") + v3 := v2.Elem() + assert(t, v3.Type().String(), "float64") + + i3 := v2.Interface() + if _, ok := i3.(float64); !ok { + t.Error("v2.Interface() did not return float64, got ", TypeOf(i3)) + } +} + +func TestFunctionValue(t *testing.T) { + var x interface{} = func() {} + v := ValueOf(x) + if fmt.Sprint(v.Interface()) != fmt.Sprint(x) { + t.Fatalf("TestFunction returned wrong pointer") + } + assert(t, v.Type().String(), "func()") +} + +var appendTests = []struct { + orig, extra []int +}{ + {make([]int, 2, 4), []int{22}}, + {make([]int, 2, 4), []int{22, 33, 44}}, +} + +func sameInts(x, y []int) bool { + if len(x) != len(y) { + return false + } + for i, xx := range x { + if xx != y[i] { + return false + } + } + return true +} + +func TestAppend(t *testing.T) { + for i, test := range appendTests { + origLen, extraLen := len(test.orig), len(test.extra) + want := append(test.orig, test.extra...) + // Convert extra from []int to []Value. + e0 := make([]Value, len(test.extra)) + for j, e := range test.extra { + e0[j] = ValueOf(e) + } + // Convert extra from []int to *SliceValue. + e1 := ValueOf(test.extra) + // Test Append. + a0 := ValueOf(test.orig) + have0 := Append(a0, e0...).Interface().([]int) + if !sameInts(have0, want) { + t.Errorf("Append #%d: have %v, want %v (%p %p)", i, have0, want, test.orig, have0) + } + // Check that the orig and extra slices were not modified. + if len(test.orig) != origLen { + t.Errorf("Append #%d origLen: have %v, want %v", i, len(test.orig), origLen) + } + if len(test.extra) != extraLen { + t.Errorf("Append #%d extraLen: have %v, want %v", i, len(test.extra), extraLen) + } + // Test AppendSlice. + a1 := ValueOf(test.orig) + have1 := AppendSlice(a1, e1).Interface().([]int) + if !sameInts(have1, want) { + t.Errorf("AppendSlice #%d: have %v, want %v", i, have1, want) + } + // Check that the orig and extra slices were not modified. + if len(test.orig) != origLen { + t.Errorf("AppendSlice #%d origLen: have %v, want %v", i, len(test.orig), origLen) + } + if len(test.extra) != extraLen { + t.Errorf("AppendSlice #%d extraLen: have %v, want %v", i, len(test.extra), extraLen) + } + } +} + +func TestCopy(t *testing.T) { + a := []int{1, 2, 3, 4, 10, 9, 8, 7} + b := []int{11, 22, 33, 44, 1010, 99, 88, 77, 66, 55, 44} + c := []int{11, 22, 33, 44, 1010, 99, 88, 77, 66, 55, 44} + for i := 0; i < len(b); i++ { + if b[i] != c[i] { + t.Fatalf("b != c before test") + } + } + a1 := a + b1 := b + aa := ValueOf(&a1).Elem() + ab := ValueOf(&b1).Elem() + for tocopy := 1; tocopy <= 7; tocopy++ { + aa.SetLen(tocopy) + Copy(ab, aa) + aa.SetLen(8) + for i := 0; i < tocopy; i++ { + if a[i] != b[i] { + t.Errorf("(i) tocopy=%d a[%d]=%d, b[%d]=%d", + tocopy, i, a[i], i, b[i]) + } + } + for i := tocopy; i < len(b); i++ { + if b[i] != c[i] { + if i < len(a) { + t.Errorf("(ii) tocopy=%d a[%d]=%d, b[%d]=%d, c[%d]=%d", + tocopy, i, a[i], i, b[i], i, c[i]) + } else { + t.Errorf("(iii) tocopy=%d b[%d]=%d, c[%d]=%d", + tocopy, i, b[i], i, c[i]) + } + } else { + t.Logf("tocopy=%d elem %d is okay\n", tocopy, i) + } + } + } +} + +func TestCopyArray(t *testing.T) { + a := [8]int{1, 2, 3, 4, 10, 9, 8, 7} + b := [11]int{11, 22, 33, 44, 1010, 99, 88, 77, 66, 55, 44} + c := b + aa := ValueOf(&a).Elem() + ab := ValueOf(&b).Elem() + Copy(ab, aa) + for i := 0; i < len(a); i++ { + if a[i] != b[i] { + t.Errorf("(i) a[%d]=%d, b[%d]=%d", i, a[i], i, b[i]) + } + } + for i := len(a); i < len(b); i++ { + if b[i] != c[i] { + t.Errorf("(ii) b[%d]=%d, c[%d]=%d", i, b[i], i, c[i]) + } else { + t.Logf("elem %d is okay\n", i) + } + } +} + +func TestBigUnnamedStruct(t *testing.T) { + b := struct{ a, b, c, d int64 }{1, 2, 3, 4} + v := ValueOf(b) + b1 := v.Interface().(struct { + a, b, c, d int64 + }) + if b1.a != b.a || b1.b != b.b || b1.c != b.c || b1.d != b.d { + t.Errorf("ValueOf(%v).Interface().(*Big) = %v", b, b1) + } +} + +type big struct { + a, b, c, d, e int64 +} + +func TestBigStruct(t *testing.T) { + b := big{1, 2, 3, 4, 5} + v := ValueOf(b) + b1 := v.Interface().(big) + if b1.a != b.a || b1.b != b.b || b1.c != b.c || b1.d != b.d || b1.e != b.e { + t.Errorf("ValueOf(%v).Interface().(big) = %v", b, b1) + } +} + +type Basic struct { + x int + y float32 +} + +type NotBasic Basic + +type DeepEqualTest struct { + a, b interface{} + eq bool +} + +// Simple functions for DeepEqual tests. +var ( + fn1 func() // nil. + fn2 func() // nil. + fn3 = func() { fn1() } // Not nil. +) + +var deepEqualTests = []DeepEqualTest{ + // Equalities + {nil, nil, true}, + {1, 1, true}, + {int32(1), int32(1), true}, + {0.5, 0.5, true}, + {float32(0.5), float32(0.5), true}, + {"hello", "hello", true}, + {make([]int, 10), make([]int, 10), true}, + {&[3]int{1, 2, 3}, &[3]int{1, 2, 3}, true}, + {Basic{1, 0.5}, Basic{1, 0.5}, true}, + {error(nil), error(nil), true}, + {map[int]string{1: "one", 2: "two"}, map[int]string{2: "two", 1: "one"}, true}, + {fn1, fn2, true}, + + // Inequalities + {1, 2, false}, + {int32(1), int32(2), false}, + {0.5, 0.6, false}, + {float32(0.5), float32(0.6), false}, + {"hello", "hey", false}, + {make([]int, 10), make([]int, 11), false}, + {&[3]int{1, 2, 3}, &[3]int{1, 2, 4}, false}, + {Basic{1, 0.5}, Basic{1, 0.6}, false}, + {Basic{1, 0}, Basic{2, 0}, false}, + {map[int]string{1: "one", 3: "two"}, map[int]string{2: "two", 1: "one"}, false}, + {map[int]string{1: "one", 2: "txo"}, map[int]string{2: "two", 1: "one"}, false}, + {map[int]string{1: "one"}, map[int]string{2: "two", 1: "one"}, false}, + {map[int]string{2: "two", 1: "one"}, map[int]string{1: "one"}, false}, + {nil, 1, false}, + {1, nil, false}, + {fn1, fn3, false}, + {fn3, fn3, false}, + {[][]int{{1}}, [][]int{{2}}, false}, + + // Nil vs empty: not the same. + {[]int{}, []int(nil), false}, + {[]int{}, []int{}, true}, + {[]int(nil), []int(nil), true}, + {map[int]int{}, map[int]int(nil), false}, + {map[int]int{}, map[int]int{}, true}, + {map[int]int(nil), map[int]int(nil), true}, + + // Mismatched types + {1, 1.0, false}, + {int32(1), int64(1), false}, + {0.5, "hello", false}, + {[]int{1, 2, 3}, [3]int{1, 2, 3}, false}, + {&[3]interface{}{1, 2, 4}, &[3]interface{}{1, 2, "s"}, false}, + {Basic{1, 0.5}, NotBasic{1, 0.5}, false}, + {map[uint]string{1: "one", 2: "two"}, map[int]string{2: "two", 1: "one"}, false}, +} + +func TestDeepEqual(t *testing.T) { + for _, test := range deepEqualTests { + if r := DeepEqual(test.a, test.b); r != test.eq { + t.Errorf("DeepEqual(%v, %v) = %v, want %v", test.a, test.b, r, test.eq) + } + } +} + +func TestTypeOf(t *testing.T) { + // Special case for nil + if typ := TypeOf(nil); typ != nil { + t.Errorf("expected nil type for nil value; got %v", typ) + } + for _, test := range deepEqualTests { + v := ValueOf(test.a) + if !v.IsValid() { + continue + } + typ := TypeOf(test.a) + if typ != v.Type() { + t.Errorf("TypeOf(%v) = %v, but ValueOf(%v).Type() = %v", test.a, typ, test.a, v.Type()) + } + } +} + +type Recursive struct { + x int + r *Recursive +} + +func TestDeepEqualRecursiveStruct(t *testing.T) { + a, b := new(Recursive), new(Recursive) + *a = Recursive{12, a} + *b = Recursive{12, b} + if !DeepEqual(a, b) { + t.Error("DeepEqual(recursive same) = false, want true") + } +} + +type _Complex struct { + a int + b [3]*_Complex + c *string + d map[float64]float64 +} + +func TestDeepEqualComplexStruct(t *testing.T) { + m := make(map[float64]float64) + stra, strb := "hello", "hello" + a, b := new(_Complex), new(_Complex) + *a = _Complex{5, [3]*_Complex{a, b, a}, &stra, m} + *b = _Complex{5, [3]*_Complex{b, a, a}, &strb, m} + if !DeepEqual(a, b) { + t.Error("DeepEqual(complex same) = false, want true") + } +} + +func TestDeepEqualComplexStructInequality(t *testing.T) { + m := make(map[float64]float64) + stra, strb := "hello", "helloo" // Difference is here + a, b := new(_Complex), new(_Complex) + *a = _Complex{5, [3]*_Complex{a, b, a}, &stra, m} + *b = _Complex{5, [3]*_Complex{b, a, a}, &strb, m} + if DeepEqual(a, b) { + t.Error("DeepEqual(complex different) = true, want false") + } +} + +type UnexpT struct { + m map[int]int +} + +func TestDeepEqualUnexportedMap(t *testing.T) { + // Check that DeepEqual can look at unexported fields. + x1 := UnexpT{map[int]int{1: 2}} + x2 := UnexpT{map[int]int{1: 2}} + if !DeepEqual(&x1, &x2) { + t.Error("DeepEqual(x1, x2) = false, want true") + } + + y1 := UnexpT{map[int]int{2: 3}} + if DeepEqual(&x1, &y1) { + t.Error("DeepEqual(x1, y1) = true, want false") + } +} + +func check2ndField(x interface{}, offs uintptr, t *testing.T) { + s := ValueOf(x) + f := s.Type().Field(1) + if f.Offset != offs { + t.Error("mismatched offsets in structure alignment:", f.Offset, offs) + } +} + +// Check that structure alignment & offsets viewed through reflect agree with those +// from the compiler itself. +func TestAlignment(t *testing.T) { + type T1inner struct { + a int + } + type T1 struct { + T1inner + f int + } + type T2inner struct { + a, b int + } + type T2 struct { + T2inner + f int + } + + x := T1{T1inner{2}, 17} + check2ndField(x, uintptr(unsafe.Pointer(&x.f))-uintptr(unsafe.Pointer(&x)), t) + + x1 := T2{T2inner{2, 3}, 17} + check2ndField(x1, uintptr(unsafe.Pointer(&x1.f))-uintptr(unsafe.Pointer(&x1)), t) +} + +func Nil(a interface{}, t *testing.T) { + n := ValueOf(a).Field(0) + if !n.IsNil() { + t.Errorf("%v should be nil", a) + } +} + +func NotNil(a interface{}, t *testing.T) { + n := ValueOf(a).Field(0) + if n.IsNil() { + t.Errorf("value of type %v should not be nil", ValueOf(a).Type().String()) + } +} + +func TestIsNil(t *testing.T) { + // These implement IsNil. + // Wrap in extra struct to hide interface type. + doNil := []interface{}{ + struct{ x *int }{}, + struct{ x interface{} }{}, + struct{ x map[string]int }{}, + struct{ x func() bool }{}, + struct{ x chan int }{}, + struct{ x []string }{}, + } + for _, ts := range doNil { + ty := TypeOf(ts).Field(0).Type + v := Zero(ty) + v.IsNil() // panics if not okay to call + } + + // Check the implementations + var pi struct { + x *int + } + Nil(pi, t) + pi.x = new(int) + NotNil(pi, t) + + var si struct { + x []int + } + Nil(si, t) + si.x = make([]int, 10) + NotNil(si, t) + + var ci struct { + x chan int + } + Nil(ci, t) + ci.x = make(chan int) + NotNil(ci, t) + + var mi struct { + x map[int]int + } + Nil(mi, t) + mi.x = make(map[int]int) + NotNil(mi, t) + + var ii struct { + x interface{} + } + Nil(ii, t) + ii.x = 2 + NotNil(ii, t) + + var fi struct { + x func(t *testing.T) + } + Nil(fi, t) + fi.x = TestIsNil + NotNil(fi, t) +} + +func TestInterfaceExtraction(t *testing.T) { + var s struct { + W io.Writer + } + + s.W = os.Stdout + v := Indirect(ValueOf(&s)).Field(0).Interface() + if v != s.W.(interface{}) { + t.Error("Interface() on interface: ", v, s.W) + } +} + +func TestNilPtrValueSub(t *testing.T) { + var pi *int + if pv := ValueOf(pi); pv.Elem().IsValid() { + t.Error("ValueOf((*int)(nil)).Elem().IsValid()") + } +} + +func TestMap(t *testing.T) { + m := map[string]int{"a": 1, "b": 2} + mv := ValueOf(m) + if n := mv.Len(); n != len(m) { + t.Errorf("Len = %d, want %d", n, len(m)) + } + keys := mv.MapKeys() + newmap := MakeMap(mv.Type()) + for k, v := range m { + // Check that returned Keys match keys in range. + // These aren't required to be in the same order. + seen := false + for _, kv := range keys { + if kv.String() == k { + seen = true + break + } + } + if !seen { + t.Errorf("Missing key %q", k) + } + + // Check that value lookup is correct. + vv := mv.MapIndex(ValueOf(k)) + if vi := vv.Int(); vi != int64(v) { + t.Errorf("Key %q: have value %d, want %d", k, vi, v) + } + + // Copy into new map. + newmap.SetMapIndex(ValueOf(k), ValueOf(v)) + } + vv := mv.MapIndex(ValueOf("not-present")) + if vv.IsValid() { + t.Errorf("Invalid key: got non-nil value %s", valueToString(vv)) + } + + newm := newmap.Interface().(map[string]int) + if len(newm) != len(m) { + t.Errorf("length after copy: newm=%d, m=%d", len(newm), len(m)) + } + + for k, v := range newm { + mv, ok := m[k] + if mv != v { + t.Errorf("newm[%q] = %d, but m[%q] = %d, %v", k, v, k, mv, ok) + } + } + + newmap.SetMapIndex(ValueOf("a"), Value{}) + v, ok := newm["a"] + if ok { + t.Errorf("newm[\"a\"] = %d after delete", v) + } + + mv = ValueOf(&m).Elem() + mv.Set(Zero(mv.Type())) + if m != nil { + t.Errorf("mv.Set(nil) failed") + } +} + +func TestNilMap(t *testing.T) { + var m map[string]int + mv := ValueOf(m) + keys := mv.MapKeys() + if len(keys) != 0 { + t.Errorf(">0 keys for nil map: %v", keys) + } + + // Check that value for missing key is zero. + x := mv.MapIndex(ValueOf("hello")) + if x.Kind() != Invalid { + t.Errorf("m.MapIndex(\"hello\") for nil map = %v, want Invalid Value", x) + } + + // Check big value too. + var mbig map[string][10 << 20]byte + x = ValueOf(mbig).MapIndex(ValueOf("hello")) + if x.Kind() != Invalid { + t.Errorf("mbig.MapIndex(\"hello\") for nil map = %v, want Invalid Value", x) + } + + // Test that deletes from a nil map succeed. + mv.SetMapIndex(ValueOf("hi"), Value{}) +} + +func TestChan(t *testing.T) { + for loop := 0; loop < 2; loop++ { + var c chan int + var cv Value + + // check both ways to allocate channels + switch loop { + case 1: + c = make(chan int, 1) + cv = ValueOf(c) + case 0: + cv = MakeChan(TypeOf(c), 1) + c = cv.Interface().(chan int) + } + + // Send + cv.Send(ValueOf(2)) + if i := <-c; i != 2 { + t.Errorf("reflect Send 2, native recv %d", i) + } + + // Recv + c <- 3 + if i, ok := cv.Recv(); i.Int() != 3 || !ok { + t.Errorf("native send 3, reflect Recv %d, %t", i.Int(), ok) + } + + // TryRecv fail + val, ok := cv.TryRecv() + if val.IsValid() || ok { + t.Errorf("TryRecv on empty chan: %s, %t", valueToString(val), ok) + } + + // TryRecv success + c <- 4 + val, ok = cv.TryRecv() + if !val.IsValid() { + t.Errorf("TryRecv on ready chan got nil") + } else if i := val.Int(); i != 4 || !ok { + t.Errorf("native send 4, TryRecv %d, %t", i, ok) + } + + // TrySend fail + c <- 100 + ok = cv.TrySend(ValueOf(5)) + i := <-c + if ok { + t.Errorf("TrySend on full chan succeeded: value %d", i) + } + + // TrySend success + ok = cv.TrySend(ValueOf(6)) + if !ok { + t.Errorf("TrySend on empty chan failed") + } else { + if i = <-c; i != 6 { + t.Errorf("TrySend 6, recv %d", i) + } + } + + // Close + c <- 123 + cv.Close() + if i, ok := cv.Recv(); i.Int() != 123 || !ok { + t.Errorf("send 123 then close; Recv %d, %t", i.Int(), ok) + } + if i, ok := cv.Recv(); i.Int() != 0 || ok { + t.Errorf("after close Recv %d, %t", i.Int(), ok) + } + } + + // check creation of unbuffered channel + var c chan int + cv := MakeChan(TypeOf(c), 0) + c = cv.Interface().(chan int) + if cv.TrySend(ValueOf(7)) { + t.Errorf("TrySend on sync chan succeeded") + } + if v, ok := cv.TryRecv(); v.IsValid() || ok { + t.Errorf("TryRecv on sync chan succeeded: isvalid=%v ok=%v", v.IsValid(), ok) + } + + // len/cap + cv = MakeChan(TypeOf(c), 10) + c = cv.Interface().(chan int) + for i := 0; i < 3; i++ { + c <- i + } + if l, m := cv.Len(), cv.Cap(); l != len(c) || m != cap(c) { + t.Errorf("Len/Cap = %d/%d want %d/%d", l, m, len(c), cap(c)) + } +} + +// caseInfo describes a single case in a select test. +type caseInfo struct { + desc string + canSelect bool + recv Value + closed bool + helper func() + panic bool +} + +var allselect = flag.Bool("allselect", false, "exhaustive select test") + +func TestSelect(t *testing.T) { + selectWatch.once.Do(func() { go selectWatcher() }) + + var x exhaustive + nch := 0 + newop := func(n int, cap int) (ch, val Value) { + nch++ + if nch%101%2 == 1 { + c := make(chan int, cap) + ch = ValueOf(c) + val = ValueOf(n) + } else { + c := make(chan string, cap) + ch = ValueOf(c) + val = ValueOf(fmt.Sprint(n)) + } + return + } + + for n := 0; x.Next(); n++ { + if testing.Short() && n >= 1000 { + break + } + if n >= 100000 && !*allselect { + break + } + if n%100000 == 0 && testing.Verbose() { + println("TestSelect", n) + } + var cases []SelectCase + var info []caseInfo + + // Ready send. + if x.Maybe() { + ch, val := newop(len(cases), 1) + cases = append(cases, SelectCase{ + Dir: SelectSend, + Chan: ch, + Send: val, + }) + info = append(info, caseInfo{desc: "ready send", canSelect: true}) + } + + // Ready recv. + if x.Maybe() { + ch, val := newop(len(cases), 1) + ch.Send(val) + cases = append(cases, SelectCase{ + Dir: SelectRecv, + Chan: ch, + }) + info = append(info, caseInfo{desc: "ready recv", canSelect: true, recv: val}) + } + + // Blocking send. + if x.Maybe() { + ch, val := newop(len(cases), 0) + cases = append(cases, SelectCase{ + Dir: SelectSend, + Chan: ch, + Send: val, + }) + // Let it execute? + if x.Maybe() { + f := func() { ch.Recv() } + info = append(info, caseInfo{desc: "blocking send", helper: f}) + } else { + info = append(info, caseInfo{desc: "blocking send"}) + } + } + + // Blocking recv. + if x.Maybe() { + ch, val := newop(len(cases), 0) + cases = append(cases, SelectCase{ + Dir: SelectRecv, + Chan: ch, + }) + // Let it execute? + if x.Maybe() { + f := func() { ch.Send(val) } + info = append(info, caseInfo{desc: "blocking recv", recv: val, helper: f}) + } else { + info = append(info, caseInfo{desc: "blocking recv"}) + } + } + + // Zero Chan send. + if x.Maybe() { + // Maybe include value to send. + var val Value + if x.Maybe() { + val = ValueOf(100) + } + cases = append(cases, SelectCase{ + Dir: SelectSend, + Send: val, + }) + info = append(info, caseInfo{desc: "zero Chan send"}) + } + + // Zero Chan receive. + if x.Maybe() { + cases = append(cases, SelectCase{ + Dir: SelectRecv, + }) + info = append(info, caseInfo{desc: "zero Chan recv"}) + } + + // nil Chan send. + if x.Maybe() { + cases = append(cases, SelectCase{ + Dir: SelectSend, + Chan: ValueOf((chan int)(nil)), + Send: ValueOf(101), + }) + info = append(info, caseInfo{desc: "nil Chan send"}) + } + + // nil Chan recv. + if x.Maybe() { + cases = append(cases, SelectCase{ + Dir: SelectRecv, + Chan: ValueOf((chan int)(nil)), + }) + info = append(info, caseInfo{desc: "nil Chan recv"}) + } + + // closed Chan send. + if x.Maybe() { + ch := make(chan int) + close(ch) + cases = append(cases, SelectCase{ + Dir: SelectSend, + Chan: ValueOf(ch), + Send: ValueOf(101), + }) + info = append(info, caseInfo{desc: "closed Chan send", canSelect: true, panic: true}) + } + + // closed Chan recv. + if x.Maybe() { + ch, val := newop(len(cases), 0) + ch.Close() + val = Zero(val.Type()) + cases = append(cases, SelectCase{ + Dir: SelectRecv, + Chan: ch, + }) + info = append(info, caseInfo{desc: "closed Chan recv", canSelect: true, closed: true, recv: val}) + } + + var helper func() // goroutine to help the select complete + + // Add default? Must be last case here, but will permute. + // Add the default if the select would otherwise + // block forever, and maybe add it anyway. + numCanSelect := 0 + canProceed := false + canBlock := true + canPanic := false + helpers := []int{} + for i, c := range info { + if c.canSelect { + canProceed = true + canBlock = false + numCanSelect++ + if c.panic { + canPanic = true + } + } else if c.helper != nil { + canProceed = true + helpers = append(helpers, i) + } + } + if !canProceed || x.Maybe() { + cases = append(cases, SelectCase{ + Dir: SelectDefault, + }) + info = append(info, caseInfo{desc: "default", canSelect: canBlock}) + numCanSelect++ + } else if canBlock { + // Select needs to communicate with another goroutine. + cas := &info[helpers[x.Choose(len(helpers))]] + helper = cas.helper + cas.canSelect = true + numCanSelect++ + } + + // Permute cases and case info. + // Doing too much here makes the exhaustive loop + // too exhausting, so just do two swaps. + for loop := 0; loop < 2; loop++ { + i := x.Choose(len(cases)) + j := x.Choose(len(cases)) + cases[i], cases[j] = cases[j], cases[i] + info[i], info[j] = info[j], info[i] + } + + if helper != nil { + // We wait before kicking off a goroutine to satisfy a blocked select. + // The pause needs to be big enough to let the select block before + // we run the helper, but if we lose that race once in a while it's okay: the + // select will just proceed immediately. Not a big deal. + // For short tests we can grow [sic] the timeout a bit without fear of taking too long + pause := 10 * time.Microsecond + if testing.Short() { + pause = 100 * time.Microsecond + } + time.AfterFunc(pause, helper) + } + + // Run select. + i, recv, recvOK, panicErr := runSelect(cases, info) + if panicErr != nil && !canPanic { + t.Fatalf("%s\npanicked unexpectedly: %v", fmtSelect(info), panicErr) + } + if panicErr == nil && canPanic && numCanSelect == 1 { + t.Fatalf("%s\nselected #%d incorrectly (should panic)", fmtSelect(info), i) + } + if panicErr != nil { + continue + } + + cas := info[i] + if !cas.canSelect { + recvStr := "" + if recv.IsValid() { + recvStr = fmt.Sprintf(", received %v, %v", recv.Interface(), recvOK) + } + t.Fatalf("%s\nselected #%d incorrectly%s", fmtSelect(info), i, recvStr) + continue + } + if cas.panic { + t.Fatalf("%s\nselected #%d incorrectly (case should panic)", fmtSelect(info), i) + continue + } + + if cases[i].Dir == SelectRecv { + if !recv.IsValid() { + t.Fatalf("%s\nselected #%d but got %v, %v, want %v, %v", fmtSelect(info), i, recv, recvOK, cas.recv.Interface(), !cas.closed) + } + if !cas.recv.IsValid() { + t.Fatalf("%s\nselected #%d but internal error: missing recv value", fmtSelect(info), i) + } + if recv.Interface() != cas.recv.Interface() || recvOK != !cas.closed { + if recv.Interface() == cas.recv.Interface() && recvOK == !cas.closed { + t.Fatalf("%s\nselected #%d, got %#v, %v, and DeepEqual is broken on %T", fmtSelect(info), i, recv.Interface(), recvOK, recv.Interface()) + } + t.Fatalf("%s\nselected #%d but got %#v, %v, want %#v, %v", fmtSelect(info), i, recv.Interface(), recvOK, cas.recv.Interface(), !cas.closed) + } + } else { + if recv.IsValid() || recvOK { + t.Fatalf("%s\nselected #%d but got %v, %v, want %v, %v", fmtSelect(info), i, recv, recvOK, Value{}, false) + } + } + } +} + +// selectWatch and the selectWatcher are a watchdog mechanism for running Select. +// If the selectWatcher notices that the select has been blocked for >1 second, it prints +// an error describing the select and panics the entire test binary. +var selectWatch struct { + sync.Mutex + once sync.Once + now time.Time + info []caseInfo +} + +func selectWatcher() { + for { + time.Sleep(1 * time.Second) + selectWatch.Lock() + if selectWatch.info != nil && time.Since(selectWatch.now) > 1*time.Second { + fmt.Fprintf(os.Stderr, "TestSelect:\n%s blocked indefinitely\n", fmtSelect(selectWatch.info)) + panic("select stuck") + } + selectWatch.Unlock() + } +} + +// runSelect runs a single select test. +// It returns the values returned by Select but also returns +// a panic value if the Select panics. +func runSelect(cases []SelectCase, info []caseInfo) (chosen int, recv Value, recvOK bool, panicErr interface{}) { + defer func() { + panicErr = recover() + + selectWatch.Lock() + selectWatch.info = nil + selectWatch.Unlock() + }() + + selectWatch.Lock() + selectWatch.now = time.Now() + selectWatch.info = info + selectWatch.Unlock() + + chosen, recv, recvOK = Select(cases) + return +} + +// fmtSelect formats the information about a single select test. +func fmtSelect(info []caseInfo) string { + var buf bytes.Buffer + fmt.Fprintf(&buf, "\nselect {\n") + for i, cas := range info { + fmt.Fprintf(&buf, "%d: %s", i, cas.desc) + if cas.recv.IsValid() { + fmt.Fprintf(&buf, " val=%#v", cas.recv.Interface()) + } + if cas.canSelect { + fmt.Fprintf(&buf, " canselect") + } + if cas.panic { + fmt.Fprintf(&buf, " panic") + } + fmt.Fprintf(&buf, "\n") + } + fmt.Fprintf(&buf, "}") + return buf.String() +} + +type two [2]uintptr + +// Difficult test for function call because of +// implicit padding between arguments. +func dummy(b byte, c int, d byte, e two, f byte, g float32, h byte) (i byte, j int, k byte, l two, m byte, n float32, o byte) { + return b, c, d, e, f, g, h +} + +func TestFunc(t *testing.T) { + ret := ValueOf(dummy).Call([]Value{ + ValueOf(byte(10)), + ValueOf(20), + ValueOf(byte(30)), + ValueOf(two{40, 50}), + ValueOf(byte(60)), + ValueOf(float32(70)), + ValueOf(byte(80)), + }) + if len(ret) != 7 { + t.Fatalf("Call returned %d values, want 7", len(ret)) + } + + i := byte(ret[0].Uint()) + j := int(ret[1].Int()) + k := byte(ret[2].Uint()) + l := ret[3].Interface().(two) + m := byte(ret[4].Uint()) + n := float32(ret[5].Float()) + o := byte(ret[6].Uint()) + + if i != 10 || j != 20 || k != 30 || l != (two{40, 50}) || m != 60 || n != 70 || o != 80 { + t.Errorf("Call returned %d, %d, %d, %v, %d, %g, %d; want 10, 20, 30, [40, 50], 60, 70, 80", i, j, k, l, m, n, o) + } +} + +type emptyStruct struct{} + +type nonEmptyStruct struct { + member int +} + +func returnEmpty() emptyStruct { + return emptyStruct{} +} + +func takesEmpty(e emptyStruct) { +} + +func returnNonEmpty(i int) nonEmptyStruct { + return nonEmptyStruct{member: i} +} + +func takesNonEmpty(n nonEmptyStruct) int { + return n.member +} + +func TestCallWithStruct(t *testing.T) { + r := ValueOf(returnEmpty).Call(nil) + if len(r) != 1 || r[0].Type() != TypeOf(emptyStruct{}) { + t.Errorf("returning empty struct returned %#v instead", r) + } + r = ValueOf(takesEmpty).Call([]Value{ValueOf(emptyStruct{})}) + if len(r) != 0 { + t.Errorf("takesEmpty returned values: %#v", r) + } + r = ValueOf(returnNonEmpty).Call([]Value{ValueOf(42)}) + if len(r) != 1 || r[0].Type() != TypeOf(nonEmptyStruct{}) || r[0].Field(0).Int() != 42 { + t.Errorf("returnNonEmpty returned %#v", r) + } + r = ValueOf(takesNonEmpty).Call([]Value{ValueOf(nonEmptyStruct{member: 42})}) + if len(r) != 1 || r[0].Type() != TypeOf(1) || r[0].Int() != 42 { + t.Errorf("takesNonEmpty returned %#v", r) + } +} + +func TestMakeFunc(t *testing.T) { + f := dummy + fv := MakeFunc(TypeOf(f), func(in []Value) []Value { return in }) + ValueOf(&f).Elem().Set(fv) + + // Call g with small arguments so that there is + // something predictable (and different from the + // correct results) in those positions on the stack. + g := dummy + g(1, 2, 3, two{4, 5}, 6, 7, 8) + + // Call constructed function f. + i, j, k, l, m, n, o := f(10, 20, 30, two{40, 50}, 60, 70, 80) + if i != 10 || j != 20 || k != 30 || l != (two{40, 50}) || m != 60 || n != 70 || o != 80 { + t.Errorf("Call returned %d, %d, %d, %v, %d, %g, %d; want 10, 20, 30, [40, 50], 60, 70, 80", i, j, k, l, m, n, o) + } +} + +func TestMakeFuncInterface(t *testing.T) { + fn := func(i int) int { return i } + incr := func(in []Value) []Value { + return []Value{ValueOf(int(in[0].Int() + 1))} + } + fv := MakeFunc(TypeOf(fn), incr) + ValueOf(&fn).Elem().Set(fv) + if r := fn(2); r != 3 { + t.Errorf("Call returned %d, want 3", r) + } + if r := fv.Call([]Value{ValueOf(14)})[0].Int(); r != 15 { + t.Errorf("Call returned %d, want 15", r) + } + if r := fv.Interface().(func(int) int)(26); r != 27 { + t.Errorf("Call returned %d, want 27", r) + } +} + +func TestMakeFuncVariadic(t *testing.T) { + // Test that variadic arguments are packed into a slice and passed as last arg + fn := func(_ int, is ...int) []int { return nil } + fv := MakeFunc(TypeOf(fn), func(in []Value) []Value { return in[1:2] }) + ValueOf(&fn).Elem().Set(fv) + + r := fn(1, 2, 3) + if r[0] != 2 || r[1] != 3 { + t.Errorf("Call returned [%v, %v]; want 2, 3", r[0], r[1]) + } + + r = fn(1, []int{2, 3}...) + if r[0] != 2 || r[1] != 3 { + t.Errorf("Call returned [%v, %v]; want 2, 3", r[0], r[1]) + } + + r = fv.Call([]Value{ValueOf(1), ValueOf(2), ValueOf(3)})[0].Interface().([]int) + if r[0] != 2 || r[1] != 3 { + t.Errorf("Call returned [%v, %v]; want 2, 3", r[0], r[1]) + } + + r = fv.CallSlice([]Value{ValueOf(1), ValueOf([]int{2, 3})})[0].Interface().([]int) + if r[0] != 2 || r[1] != 3 { + t.Errorf("Call returned [%v, %v]; want 2, 3", r[0], r[1]) + } + + f := fv.Interface().(func(int, ...int) []int) + + r = f(1, 2, 3) + if r[0] != 2 || r[1] != 3 { + t.Errorf("Call returned [%v, %v]; want 2, 3", r[0], r[1]) + } + r = f(1, []int{2, 3}...) + if r[0] != 2 || r[1] != 3 { + t.Errorf("Call returned [%v, %v]; want 2, 3", r[0], r[1]) + } +} + +type Point struct { + x, y int +} + +// This will be index 0. +func (p Point) AnotherMethod(scale int) int { + return -1 +} + +// This will be index 1. +func (p Point) Dist(scale int) int { + //println("Point.Dist", p.x, p.y, scale) + return p.x*p.x*scale + p.y*p.y*scale +} + +// This will be index 2. +func (p Point) GCMethod(k int) int { + runtime.GC() + return k + p.x +} + +// This will be index 3. +func (p Point) TotalDist(points ...Point) int { + tot := 0 + for _, q := range points { + dx := q.x - p.x + dy := q.y - p.y + tot += dx*dx + dy*dy // Should call Sqrt, but it's just a test. + + } + return tot +} + +func TestMethod(t *testing.T) { + // Non-curried method of type. + p := Point{3, 4} + i := TypeOf(p).Method(1).Func.Call([]Value{ValueOf(p), ValueOf(10)})[0].Int() + if i != 250 { + t.Errorf("Type Method returned %d; want 250", i) + } + + m, ok := TypeOf(p).MethodByName("Dist") + if !ok { + t.Fatalf("method by name failed") + } + i = m.Func.Call([]Value{ValueOf(p), ValueOf(11)})[0].Int() + if i != 275 { + t.Errorf("Type MethodByName returned %d; want 275", i) + } + + i = TypeOf(&p).Method(1).Func.Call([]Value{ValueOf(&p), ValueOf(12)})[0].Int() + if i != 300 { + t.Errorf("Pointer Type Method returned %d; want 300", i) + } + + m, ok = TypeOf(&p).MethodByName("Dist") + if !ok { + t.Fatalf("ptr method by name failed") + } + i = m.Func.Call([]Value{ValueOf(&p), ValueOf(13)})[0].Int() + if i != 325 { + t.Errorf("Pointer Type MethodByName returned %d; want 325", i) + } + + // Curried method of value. + tfunc := TypeOf((func(int) int)(nil)) + v := ValueOf(p).Method(1) + if tt := v.Type(); tt != tfunc { + t.Errorf("Value Method Type is %s; want %s", tt, tfunc) + } + i = v.Call([]Value{ValueOf(14)})[0].Int() + if i != 350 { + t.Errorf("Value Method returned %d; want 350", i) + } + v = ValueOf(p).MethodByName("Dist") + if tt := v.Type(); tt != tfunc { + t.Errorf("Value MethodByName Type is %s; want %s", tt, tfunc) + } + i = v.Call([]Value{ValueOf(15)})[0].Int() + if i != 375 { + t.Errorf("Value MethodByName returned %d; want 375", i) + } + + // Curried method of pointer. + v = ValueOf(&p).Method(1) + if tt := v.Type(); tt != tfunc { + t.Errorf("Pointer Value Method Type is %s; want %s", tt, tfunc) + } + i = v.Call([]Value{ValueOf(16)})[0].Int() + if i != 400 { + t.Errorf("Pointer Value Method returned %d; want 400", i) + } + v = ValueOf(&p).MethodByName("Dist") + if tt := v.Type(); tt != tfunc { + t.Errorf("Pointer Value MethodByName Type is %s; want %s", tt, tfunc) + } + i = v.Call([]Value{ValueOf(17)})[0].Int() + if i != 425 { + t.Errorf("Pointer Value MethodByName returned %d; want 425", i) + } + + // Curried method of interface value. + // Have to wrap interface value in a struct to get at it. + // Passing it to ValueOf directly would + // access the underlying Point, not the interface. + var x interface { + Dist(int) int + } = p + pv := ValueOf(&x).Elem() + v = pv.Method(0) + if tt := v.Type(); tt != tfunc { + t.Errorf("Interface Method Type is %s; want %s", tt, tfunc) + } + i = v.Call([]Value{ValueOf(18)})[0].Int() + if i != 450 { + t.Errorf("Interface Method returned %d; want 450", i) + } + v = pv.MethodByName("Dist") + if tt := v.Type(); tt != tfunc { + t.Errorf("Interface MethodByName Type is %s; want %s", tt, tfunc) + } + i = v.Call([]Value{ValueOf(19)})[0].Int() + if i != 475 { + t.Errorf("Interface MethodByName returned %d; want 475", i) + } +} + +func TestMethodValue(t *testing.T) { + p := Point{3, 4} + var i int64 + + // Curried method of value. + tfunc := TypeOf((func(int) int)(nil)) + v := ValueOf(p).Method(1) + if tt := v.Type(); tt != tfunc { + t.Errorf("Value Method Type is %s; want %s", tt, tfunc) + } + i = ValueOf(v.Interface()).Call([]Value{ValueOf(10)})[0].Int() + if i != 250 { + t.Errorf("Value Method returned %d; want 250", i) + } + v = ValueOf(p).MethodByName("Dist") + if tt := v.Type(); tt != tfunc { + t.Errorf("Value MethodByName Type is %s; want %s", tt, tfunc) + } + i = ValueOf(v.Interface()).Call([]Value{ValueOf(11)})[0].Int() + if i != 275 { + t.Errorf("Value MethodByName returned %d; want 275", i) + } + + // Curried method of pointer. + v = ValueOf(&p).Method(1) + if tt := v.Type(); tt != tfunc { + t.Errorf("Pointer Value Method Type is %s; want %s", tt, tfunc) + } + i = ValueOf(v.Interface()).Call([]Value{ValueOf(12)})[0].Int() + if i != 300 { + t.Errorf("Pointer Value Method returned %d; want 300", i) + } + v = ValueOf(&p).MethodByName("Dist") + if tt := v.Type(); tt != tfunc { + t.Errorf("Pointer Value MethodByName Type is %s; want %s", tt, tfunc) + } + i = ValueOf(v.Interface()).Call([]Value{ValueOf(13)})[0].Int() + if i != 325 { + t.Errorf("Pointer Value MethodByName returned %d; want 325", i) + } + + // Curried method of pointer to pointer. + pp := &p + v = ValueOf(&pp).Elem().Method(1) + if tt := v.Type(); tt != tfunc { + t.Errorf("Pointer Pointer Value Method Type is %s; want %s", tt, tfunc) + } + i = ValueOf(v.Interface()).Call([]Value{ValueOf(14)})[0].Int() + if i != 350 { + t.Errorf("Pointer Pointer Value Method returned %d; want 350", i) + } + v = ValueOf(&pp).Elem().MethodByName("Dist") + if tt := v.Type(); tt != tfunc { + t.Errorf("Pointer Pointer Value MethodByName Type is %s; want %s", tt, tfunc) + } + i = ValueOf(v.Interface()).Call([]Value{ValueOf(15)})[0].Int() + if i != 375 { + t.Errorf("Pointer Pointer Value MethodByName returned %d; want 375", i) + } + + // Curried method of interface value. + // Have to wrap interface value in a struct to get at it. + // Passing it to ValueOf directly would + // access the underlying Point, not the interface. + var s = struct { + X interface { + Dist(int) int + } + }{p} + pv := ValueOf(s).Field(0) + v = pv.Method(0) + if tt := v.Type(); tt != tfunc { + t.Errorf("Interface Method Type is %s; want %s", tt, tfunc) + } + i = ValueOf(v.Interface()).Call([]Value{ValueOf(16)})[0].Int() + if i != 400 { + t.Errorf("Interface Method returned %d; want 400", i) + } + v = pv.MethodByName("Dist") + if tt := v.Type(); tt != tfunc { + t.Errorf("Interface MethodByName Type is %s; want %s", tt, tfunc) + } + i = ValueOf(v.Interface()).Call([]Value{ValueOf(17)})[0].Int() + if i != 425 { + t.Errorf("Interface MethodByName returned %d; want 425", i) + } +} + +func TestVariadicMethodValue(t *testing.T) { + p := Point{3, 4} + points := []Point{{20, 21}, {22, 23}, {24, 25}} + want := int64(p.TotalDist(points[0], points[1], points[2])) + + // Curried method of value. + tfunc := TypeOf((func(...Point) int)(nil)) + v := ValueOf(p).Method(3) + if tt := v.Type(); tt != tfunc { + t.Errorf("Variadic Method Type is %s; want %s", tt, tfunc) + } + i := ValueOf(v.Interface()).Call([]Value{ValueOf(points[0]), ValueOf(points[1]), ValueOf(points[2])})[0].Int() + if i != want { + t.Errorf("Variadic Method returned %d; want %d", i, want) + } + i = ValueOf(v.Interface()).CallSlice([]Value{ValueOf(points)})[0].Int() + if i != want { + t.Errorf("Variadic Method CallSlice returned %d; want %d", i, want) + } + + f := v.Interface().(func(...Point) int) + i = int64(f(points[0], points[1], points[2])) + if i != want { + t.Errorf("Variadic Method Interface returned %d; want %d", i, want) + } + i = int64(f(points...)) + if i != want { + t.Errorf("Variadic Method Interface Slice returned %d; want %d", i, want) + } +} + +// Reflect version of $GOROOT/test/method5.go + +// Concrete types implementing M method. +// Smaller than a word, word-sized, larger than a word. +// Value and pointer receivers. + +type Tinter interface { + M(int, byte) (byte, int) +} + +type Tsmallv byte + +func (v Tsmallv) M(x int, b byte) (byte, int) { return b, x + int(v) } + +type Tsmallp byte + +func (p *Tsmallp) M(x int, b byte) (byte, int) { return b, x + int(*p) } + +type Twordv uintptr + +func (v Twordv) M(x int, b byte) (byte, int) { return b, x + int(v) } + +type Twordp uintptr + +func (p *Twordp) M(x int, b byte) (byte, int) { return b, x + int(*p) } + +type Tbigv [2]uintptr + +func (v Tbigv) M(x int, b byte) (byte, int) { return b, x + int(v[0]) + int(v[1]) } + +type Tbigp [2]uintptr + +func (p *Tbigp) M(x int, b byte) (byte, int) { return b, x + int(p[0]) + int(p[1]) } + +// Again, with an unexported method. + +type tsmallv byte + +func (v tsmallv) m(x int, b byte) (byte, int) { return b, x + int(v) } + +type tsmallp byte + +func (p *tsmallp) m(x int, b byte) (byte, int) { return b, x + int(*p) } + +type twordv uintptr + +func (v twordv) m(x int, b byte) (byte, int) { return b, x + int(v) } + +type twordp uintptr + +func (p *twordp) m(x int, b byte) (byte, int) { return b, x + int(*p) } + +type tbigv [2]uintptr + +func (v tbigv) m(x int, b byte) (byte, int) { return b, x + int(v[0]) + int(v[1]) } + +type tbigp [2]uintptr + +func (p *tbigp) m(x int, b byte) (byte, int) { return b, x + int(p[0]) + int(p[1]) } + +type tinter interface { + m(int, byte) (byte, int) +} + +// Embedding via pointer. + +type Tm1 struct { + Tm2 +} + +type Tm2 struct { + *Tm3 +} + +type Tm3 struct { + *Tm4 +} + +type Tm4 struct { +} + +func (t4 Tm4) M(x int, b byte) (byte, int) { return b, x + 40 } + +func TestMethod5(t *testing.T) { + CheckF := func(name string, f func(int, byte) (byte, int), inc int) { + b, x := f(1000, 99) + if b != 99 || x != 1000+inc { + t.Errorf("%s(1000, 99) = %v, %v, want 99, %v", name, b, x, 1000+inc) + } + } + + CheckV := func(name string, i Value, inc int) { + bx := i.Method(0).Call([]Value{ValueOf(1000), ValueOf(byte(99))}) + b := bx[0].Interface() + x := bx[1].Interface() + if b != byte(99) || x != 1000+inc { + t.Errorf("direct %s.M(1000, 99) = %v, %v, want 99, %v", name, b, x, 1000+inc) + } + + CheckF(name+".M", i.Method(0).Interface().(func(int, byte) (byte, int)), inc) + } + + var TinterType = TypeOf(new(Tinter)).Elem() + var tinterType = TypeOf(new(tinter)).Elem() + + CheckI := func(name string, i interface{}, inc int) { + v := ValueOf(i) + CheckV(name, v, inc) + CheckV("(i="+name+")", v.Convert(TinterType), inc) + } + + sv := Tsmallv(1) + CheckI("sv", sv, 1) + CheckI("&sv", &sv, 1) + + sp := Tsmallp(2) + CheckI("&sp", &sp, 2) + + wv := Twordv(3) + CheckI("wv", wv, 3) + CheckI("&wv", &wv, 3) + + wp := Twordp(4) + CheckI("&wp", &wp, 4) + + bv := Tbigv([2]uintptr{5, 6}) + CheckI("bv", bv, 11) + CheckI("&bv", &bv, 11) + + bp := Tbigp([2]uintptr{7, 8}) + CheckI("&bp", &bp, 15) + + t4 := Tm4{} + t3 := Tm3{&t4} + t2 := Tm2{&t3} + t1 := Tm1{t2} + CheckI("t4", t4, 40) + CheckI("&t4", &t4, 40) + CheckI("t3", t3, 40) + CheckI("&t3", &t3, 40) + CheckI("t2", t2, 40) + CheckI("&t2", &t2, 40) + CheckI("t1", t1, 40) + CheckI("&t1", &t1, 40) + + methodShouldPanic := func(name string, i interface{}) { + v := ValueOf(i) + m := v.Method(0) + shouldPanic(func() { m.Call([]Value{ValueOf(1000), ValueOf(byte(99))}) }) + shouldPanic(func() { m.Interface() }) + + v = v.Convert(tinterType) + m = v.Method(0) + shouldPanic(func() { m.Call([]Value{ValueOf(1000), ValueOf(byte(99))}) }) + shouldPanic(func() { m.Interface() }) + } + + _sv := tsmallv(1) + methodShouldPanic("_sv", _sv) + methodShouldPanic("&_sv", &_sv) + + _sp := tsmallp(2) + methodShouldPanic("&_sp", &_sp) + + _wv := twordv(3) + methodShouldPanic("_wv", _wv) + methodShouldPanic("&_wv", &_wv) + + _wp := twordp(4) + methodShouldPanic("&_wp", &_wp) + + _bv := tbigv([2]uintptr{5, 6}) + methodShouldPanic("_bv", _bv) + methodShouldPanic("&_bv", &_bv) + + _bp := tbigp([2]uintptr{7, 8}) + methodShouldPanic("&_bp", &_bp) + + var tnil Tinter + vnil := ValueOf(&tnil).Elem() + shouldPanic(func() { vnil.Method(0) }) +} + +func TestInterfaceSet(t *testing.T) { + p := &Point{3, 4} + + var s struct { + I interface{} + P interface { + Dist(int) int + } + } + sv := ValueOf(&s).Elem() + sv.Field(0).Set(ValueOf(p)) + if q := s.I.(*Point); q != p { + t.Errorf("i: have %p want %p", q, p) + } + + pv := sv.Field(1) + pv.Set(ValueOf(p)) + if q := s.P.(*Point); q != p { + t.Errorf("i: have %p want %p", q, p) + } + + i := pv.Method(0).Call([]Value{ValueOf(10)})[0].Int() + if i != 250 { + t.Errorf("Interface Method returned %d; want 250", i) + } +} + +type T1 struct { + a string + int +} + +func TestAnonymousFields(t *testing.T) { + var field StructField + var ok bool + var t1 T1 + type1 := TypeOf(t1) + if field, ok = type1.FieldByName("int"); !ok { + t.Fatal("no field 'int'") + } + if field.Index[0] != 1 { + t.Error("field index should be 1; is", field.Index) + } +} + +type FTest struct { + s interface{} + name string + index []int + value int +} + +type D1 struct { + d int +} +type D2 struct { + d int +} + +type S0 struct { + A, B, C int + D1 + D2 +} + +type S1 struct { + B int + S0 +} + +type S2 struct { + A int + *S1 +} + +type S1x struct { + S1 +} + +type S1y struct { + S1 +} + +type S3 struct { + S1x + S2 + D, E int + *S1y +} + +type S4 struct { + *S4 + A int +} + +// The X in S6 and S7 annihilate, but they also block the X in S8.S9. +type S5 struct { + S6 + S7 + S8 +} + +type S6 struct { + X int +} + +type S7 S6 + +type S8 struct { + S9 +} + +type S9 struct { + X int + Y int +} + +// The X in S11.S6 and S12.S6 annihilate, but they also block the X in S13.S8.S9. +type S10 struct { + S11 + S12 + S13 +} + +type S11 struct { + S6 +} + +type S12 struct { + S6 +} + +type S13 struct { + S8 +} + +// The X in S15.S11.S1 and S16.S11.S1 annihilate. +type S14 struct { + S15 + S16 +} + +type S15 struct { + S11 +} + +type S16 struct { + S11 +} + +var fieldTests = []FTest{ + {struct{}{}, "", nil, 0}, + {struct{}{}, "Foo", nil, 0}, + {S0{A: 'a'}, "A", []int{0}, 'a'}, + {S0{}, "D", nil, 0}, + {S1{S0: S0{A: 'a'}}, "A", []int{1, 0}, 'a'}, + {S1{B: 'b'}, "B", []int{0}, 'b'}, + {S1{}, "S0", []int{1}, 0}, + {S1{S0: S0{C: 'c'}}, "C", []int{1, 2}, 'c'}, + {S2{A: 'a'}, "A", []int{0}, 'a'}, + {S2{}, "S1", []int{1}, 0}, + {S2{S1: &S1{B: 'b'}}, "B", []int{1, 0}, 'b'}, + {S2{S1: &S1{S0: S0{C: 'c'}}}, "C", []int{1, 1, 2}, 'c'}, + {S2{}, "D", nil, 0}, + {S3{}, "S1", nil, 0}, + {S3{S2: S2{A: 'a'}}, "A", []int{1, 0}, 'a'}, + {S3{}, "B", nil, 0}, + {S3{D: 'd'}, "D", []int{2}, 0}, + {S3{E: 'e'}, "E", []int{3}, 'e'}, + {S4{A: 'a'}, "A", []int{1}, 'a'}, + {S4{}, "B", nil, 0}, + {S5{}, "X", nil, 0}, + {S5{}, "Y", []int{2, 0, 1}, 0}, + {S10{}, "X", nil, 0}, + {S10{}, "Y", []int{2, 0, 0, 1}, 0}, + {S14{}, "X", nil, 0}, +} + +func TestFieldByIndex(t *testing.T) { + for _, test := range fieldTests { + s := TypeOf(test.s) + f := s.FieldByIndex(test.index) + if f.Name != "" { + if test.index != nil { + if f.Name != test.name { + t.Errorf("%s.%s found; want %s", s.Name(), f.Name, test.name) + } + } else { + t.Errorf("%s.%s found", s.Name(), f.Name) + } + } else if len(test.index) > 0 { + t.Errorf("%s.%s not found", s.Name(), test.name) + } + + if test.value != 0 { + v := ValueOf(test.s).FieldByIndex(test.index) + if v.IsValid() { + if x, ok := v.Interface().(int); ok { + if x != test.value { + t.Errorf("%s%v is %d; want %d", s.Name(), test.index, x, test.value) + } + } else { + t.Errorf("%s%v value not an int", s.Name(), test.index) + } + } else { + t.Errorf("%s%v value not found", s.Name(), test.index) + } + } + } +} + +func TestFieldByName(t *testing.T) { + for _, test := range fieldTests { + s := TypeOf(test.s) + f, found := s.FieldByName(test.name) + if found { + if test.index != nil { + // Verify field depth and index. + if len(f.Index) != len(test.index) { + t.Errorf("%s.%s depth %d; want %d: %v vs %v", s.Name(), test.name, len(f.Index), len(test.index), f.Index, test.index) + } else { + for i, x := range f.Index { + if x != test.index[i] { + t.Errorf("%s.%s.Index[%d] is %d; want %d", s.Name(), test.name, i, x, test.index[i]) + } + } + } + } else { + t.Errorf("%s.%s found", s.Name(), f.Name) + } + } else if len(test.index) > 0 { + t.Errorf("%s.%s not found", s.Name(), test.name) + } + + if test.value != 0 { + v := ValueOf(test.s).FieldByName(test.name) + if v.IsValid() { + if x, ok := v.Interface().(int); ok { + if x != test.value { + t.Errorf("%s.%s is %d; want %d", s.Name(), test.name, x, test.value) + } + } else { + t.Errorf("%s.%s value not an int", s.Name(), test.name) + } + } else { + t.Errorf("%s.%s value not found", s.Name(), test.name) + } + } + } +} + +func TestImportPath(t *testing.T) { + tests := []struct { + t Type + path string + }{ + {TypeOf(&base64.Encoding{}).Elem(), "encoding/base64"}, + {TypeOf(int(0)), ""}, + {TypeOf(int8(0)), ""}, + {TypeOf(int16(0)), ""}, + {TypeOf(int32(0)), ""}, + {TypeOf(int64(0)), ""}, + {TypeOf(uint(0)), ""}, + {TypeOf(uint8(0)), ""}, + {TypeOf(uint16(0)), ""}, + {TypeOf(uint32(0)), ""}, + {TypeOf(uint64(0)), ""}, + {TypeOf(uintptr(0)), ""}, + {TypeOf(float32(0)), ""}, + {TypeOf(float64(0)), ""}, + {TypeOf(complex64(0)), ""}, + {TypeOf(complex128(0)), ""}, + {TypeOf(byte(0)), ""}, + {TypeOf(rune(0)), ""}, + {TypeOf([]byte(nil)), ""}, + {TypeOf([]rune(nil)), ""}, + {TypeOf(string("")), ""}, + {TypeOf((*interface{})(nil)).Elem(), ""}, + {TypeOf((*byte)(nil)), ""}, + {TypeOf((*rune)(nil)), ""}, + {TypeOf((*int64)(nil)), ""}, + {TypeOf(map[string]int{}), ""}, + {TypeOf((*error)(nil)).Elem(), ""}, + } + for _, test := range tests { + if path := test.t.PkgPath(); path != test.path { + t.Errorf("%v.PkgPath() = %q, want %q", test.t, path, test.path) + } + } +} + +func TestVariadicType(t *testing.T) { + // Test example from Type documentation. + var f func(x int, y ...float64) + typ := TypeOf(f) + if typ.NumIn() == 2 && typ.In(0) == TypeOf(int(0)) { + sl := typ.In(1) + if sl.Kind() == Slice { + if sl.Elem() == TypeOf(0.0) { + // ok + return + } + } + } + + // Failed + t.Errorf("want NumIn() = 2, In(0) = int, In(1) = []float64") + s := fmt.Sprintf("have NumIn() = %d", typ.NumIn()) + for i := 0; i < typ.NumIn(); i++ { + s += fmt.Sprintf(", In(%d) = %s", i, typ.In(i)) + } + t.Error(s) +} + +type inner struct { + x int +} + +type outer struct { + y int + inner +} + +func (*inner) m() {} +func (*outer) m() {} + +func TestNestedMethods(t *testing.T) { + typ := TypeOf((*outer)(nil)) + if typ.NumMethod() != 1 || typ.Method(0).Func.Pointer() != ValueOf((*outer).m).Pointer() { + t.Errorf("Wrong method table for outer: (m=%p)", (*outer).m) + for i := 0; i < typ.NumMethod(); i++ { + m := typ.Method(i) + t.Errorf("\t%d: %s %#x\n", i, m.Name, m.Func.Pointer()) + } + } +} + +type InnerInt struct { + X int +} + +type OuterInt struct { + Y int + InnerInt +} + +func (i *InnerInt) M() int { + return i.X +} + +func TestEmbeddedMethods(t *testing.T) { + typ := TypeOf((*OuterInt)(nil)) + if typ.NumMethod() != 1 || typ.Method(0).Func.Pointer() != ValueOf((*OuterInt).M).Pointer() { + t.Errorf("Wrong method table for OuterInt: (m=%p)", (*OuterInt).M) + for i := 0; i < typ.NumMethod(); i++ { + m := typ.Method(i) + t.Errorf("\t%d: %s %#x\n", i, m.Name, m.Func.Pointer()) + } + } + + i := &InnerInt{3} + if v := ValueOf(i).Method(0).Call(nil)[0].Int(); v != 3 { + t.Errorf("i.M() = %d, want 3", v) + } + + o := &OuterInt{1, InnerInt{2}} + if v := ValueOf(o).Method(0).Call(nil)[0].Int(); v != 2 { + t.Errorf("i.M() = %d, want 2", v) + } + + f := (*OuterInt).M + if v := f(o); v != 2 { + t.Errorf("f(o) = %d, want 2", v) + } +} + +func TestPtrTo(t *testing.T) { + var i int + + typ := TypeOf(i) + for i = 0; i < 100; i++ { + typ = PtrTo(typ) + } + for i = 0; i < 100; i++ { + typ = typ.Elem() + } + if typ != TypeOf(i) { + t.Errorf("after 100 PtrTo and Elem, have %s, want %s", typ, TypeOf(i)) + } +} + +func TestPtrToGC(t *testing.T) { + type T *uintptr + tt := TypeOf(T(nil)) + pt := PtrTo(tt) + const n = 100 + var x []interface{} + for i := 0; i < n; i++ { + v := New(pt) + p := new(*uintptr) + *p = new(uintptr) + **p = uintptr(i) + v.Elem().Set(ValueOf(p).Convert(pt)) + x = append(x, v.Interface()) + } + runtime.GC() + + for i, xi := range x { + k := ValueOf(xi).Elem().Elem().Elem().Interface().(uintptr) + if k != uintptr(i) { + t.Errorf("lost x[%d] = %d, want %d", i, k, i) + } + } +} + +func TestAddr(t *testing.T) { + var p struct { + X, Y int + } + + v := ValueOf(&p) + v = v.Elem() + v = v.Addr() + v = v.Elem() + v = v.Field(0) + v.SetInt(2) + if p.X != 2 { + t.Errorf("Addr.Elem.Set failed to set value") + } + + // Again but take address of the ValueOf value. + // Exercises generation of PtrTypes not present in the binary. + q := &p + v = ValueOf(&q).Elem() + v = v.Addr() + v = v.Elem() + v = v.Elem() + v = v.Addr() + v = v.Elem() + v = v.Field(0) + v.SetInt(3) + if p.X != 3 { + t.Errorf("Addr.Elem.Set failed to set value") + } + + // Starting without pointer we should get changed value + // in interface. + qq := p + v = ValueOf(&qq).Elem() + v0 := v + v = v.Addr() + v = v.Elem() + v = v.Field(0) + v.SetInt(4) + if p.X != 3 { // should be unchanged from last time + t.Errorf("somehow value Set changed original p") + } + p = v0.Interface().(struct { + X, Y int + }) + if p.X != 4 { + t.Errorf("Addr.Elem.Set valued to set value in top value") + } + + // Verify that taking the address of a type gives us a pointer + // which we can convert back using the usual interface + // notation. + var s struct { + B *bool + } + ps := ValueOf(&s).Elem().Field(0).Addr().Interface() + *(ps.(**bool)) = new(bool) + if s.B == nil { + t.Errorf("Addr.Interface direct assignment failed") + } +} + +func noAlloc(t *testing.T, n int, f func(int)) { + if testing.Short() { + t.Skip("skipping malloc count in short mode") + } + if runtime.GOMAXPROCS(0) > 1 { + t.Skip("skipping; GOMAXPROCS>1") + } + i := -1 + allocs := testing.AllocsPerRun(n, func() { + f(i) + i++ + }) + if allocs > 0 { + t.Errorf("%d iterations: got %v mallocs, want 0", n, allocs) + } +} + +func TestAllocations(t *testing.T) { + noAlloc(t, 100, func(j int) { + var i interface{} + var v Value + + // We can uncomment this when compiler escape analysis + // is good enough to see that the integer assigned to i + // does not escape and therefore need not be allocated. + // + // i = 42 + j + // v = ValueOf(i) + // if int(v.Int()) != 42+j { + // panic("wrong int") + // } + + i = func(j int) int { return j } + v = ValueOf(i) + if v.Interface().(func(int) int)(j) != j { + panic("wrong result") + } + }) +} + +func TestSmallNegativeInt(t *testing.T) { + i := int16(-1) + v := ValueOf(i) + if v.Int() != -1 { + t.Errorf("int16(-1).Int() returned %v", v.Int()) + } +} + +func TestIndex(t *testing.T) { + xs := []byte{1, 2, 3, 4, 5, 6, 7, 8} + v := ValueOf(xs).Index(3).Interface().(byte) + if v != xs[3] { + t.Errorf("xs.Index(3) = %v; expected %v", v, xs[3]) + } + xa := [8]byte{10, 20, 30, 40, 50, 60, 70, 80} + v = ValueOf(xa).Index(2).Interface().(byte) + if v != xa[2] { + t.Errorf("xa.Index(2) = %v; expected %v", v, xa[2]) + } + s := "0123456789" + v = ValueOf(s).Index(3).Interface().(byte) + if v != s[3] { + t.Errorf("s.Index(3) = %v; expected %v", v, s[3]) + } +} + +func TestSlice(t *testing.T) { + xs := []int{1, 2, 3, 4, 5, 6, 7, 8} + v := ValueOf(xs).Slice(3, 5).Interface().([]int) + if len(v) != 2 { + t.Errorf("len(xs.Slice(3, 5)) = %d", len(v)) + } + if cap(v) != 5 { + t.Errorf("cap(xs.Slice(3, 5)) = %d", cap(v)) + } + if !DeepEqual(v[0:5], xs[3:]) { + t.Errorf("xs.Slice(3, 5)[0:5] = %v", v[0:5]) + } + xa := [8]int{10, 20, 30, 40, 50, 60, 70, 80} + v = ValueOf(&xa).Elem().Slice(2, 5).Interface().([]int) + if len(v) != 3 { + t.Errorf("len(xa.Slice(2, 5)) = %d", len(v)) + } + if cap(v) != 6 { + t.Errorf("cap(xa.Slice(2, 5)) = %d", cap(v)) + } + if !DeepEqual(v[0:6], xa[2:]) { + t.Errorf("xs.Slice(2, 5)[0:6] = %v", v[0:6]) + } + s := "0123456789" + vs := ValueOf(s).Slice(3, 5).Interface().(string) + if vs != s[3:5] { + t.Errorf("s.Slice(3, 5) = %q; expected %q", vs, s[3:5]) + } + + rv := ValueOf(&xs).Elem() + rv = rv.Slice(3, 4) + ptr2 := rv.Pointer() + rv = rv.Slice(5, 5) + ptr3 := rv.Pointer() + if ptr3 != ptr2 { + t.Errorf("xs.Slice(3,4).Slice3(5,5).Pointer() = %#x, want %#x", ptr3, ptr2) + } +} + +func TestSlice3(t *testing.T) { + xs := []int{1, 2, 3, 4, 5, 6, 7, 8} + v := ValueOf(xs).Slice3(3, 5, 7).Interface().([]int) + if len(v) != 2 { + t.Errorf("len(xs.Slice3(3, 5, 7)) = %d", len(v)) + } + if cap(v) != 4 { + t.Errorf("cap(xs.Slice3(3, 5, 7)) = %d", cap(v)) + } + if !DeepEqual(v[0:4], xs[3:7:7]) { + t.Errorf("xs.Slice3(3, 5, 7)[0:4] = %v", v[0:4]) + } + rv := ValueOf(&xs).Elem() + shouldPanic(func() { rv.Slice3(1, 2, 1) }) + shouldPanic(func() { rv.Slice3(1, 1, 11) }) + shouldPanic(func() { rv.Slice3(2, 2, 1) }) + + xa := [8]int{10, 20, 30, 40, 50, 60, 70, 80} + v = ValueOf(&xa).Elem().Slice3(2, 5, 6).Interface().([]int) + if len(v) != 3 { + t.Errorf("len(xa.Slice(2, 5, 6)) = %d", len(v)) + } + if cap(v) != 4 { + t.Errorf("cap(xa.Slice(2, 5, 6)) = %d", cap(v)) + } + if !DeepEqual(v[0:4], xa[2:6:6]) { + t.Errorf("xs.Slice(2, 5, 6)[0:4] = %v", v[0:4]) + } + rv = ValueOf(&xa).Elem() + shouldPanic(func() { rv.Slice3(1, 2, 1) }) + shouldPanic(func() { rv.Slice3(1, 1, 11) }) + shouldPanic(func() { rv.Slice3(2, 2, 1) }) + + s := "hello world" + rv = ValueOf(&s).Elem() + shouldPanic(func() { rv.Slice3(1, 2, 3) }) + + rv = ValueOf(&xs).Elem() + rv = rv.Slice3(3, 5, 7) + ptr2 := rv.Pointer() + rv = rv.Slice3(4, 4, 4) + ptr3 := rv.Pointer() + if ptr3 != ptr2 { + t.Errorf("xs.Slice3(3,5,7).Slice3(4,4,4).Pointer() = %#x, want %#x", ptr3, ptr2) + } +} + +func TestSetLenCap(t *testing.T) { + xs := []int{1, 2, 3, 4, 5, 6, 7, 8} + xa := [8]int{10, 20, 30, 40, 50, 60, 70, 80} + + vs := ValueOf(&xs).Elem() + shouldPanic(func() { vs.SetLen(10) }) + shouldPanic(func() { vs.SetCap(10) }) + shouldPanic(func() { vs.SetLen(-1) }) + shouldPanic(func() { vs.SetCap(-1) }) + shouldPanic(func() { vs.SetCap(6) }) // smaller than len + vs.SetLen(5) + if len(xs) != 5 || cap(xs) != 8 { + t.Errorf("after SetLen(5), len, cap = %d, %d, want 5, 8", len(xs), cap(xs)) + } + vs.SetCap(6) + if len(xs) != 5 || cap(xs) != 6 { + t.Errorf("after SetCap(6), len, cap = %d, %d, want 5, 6", len(xs), cap(xs)) + } + vs.SetCap(5) + if len(xs) != 5 || cap(xs) != 5 { + t.Errorf("after SetCap(5), len, cap = %d, %d, want 5, 5", len(xs), cap(xs)) + } + shouldPanic(func() { vs.SetCap(4) }) // smaller than len + shouldPanic(func() { vs.SetLen(6) }) // bigger than cap + + va := ValueOf(&xa).Elem() + shouldPanic(func() { va.SetLen(8) }) + shouldPanic(func() { va.SetCap(8) }) +} + +func TestVariadic(t *testing.T) { + var b bytes.Buffer + V := ValueOf + + b.Reset() + V(fmt.Fprintf).Call([]Value{V(&b), V("%s, %d world"), V("hello"), V(42)}) + if b.String() != "hello, 42 world" { + t.Errorf("after Fprintf Call: %q != %q", b.String(), "hello 42 world") + } + + b.Reset() + V(fmt.Fprintf).CallSlice([]Value{V(&b), V("%s, %d world"), V([]interface{}{"hello", 42})}) + if b.String() != "hello, 42 world" { + t.Errorf("after Fprintf CallSlice: %q != %q", b.String(), "hello 42 world") + } +} + +func TestFuncArg(t *testing.T) { + f1 := func(i int, f func(int) int) int { return f(i) } + f2 := func(i int) int { return i + 1 } + r := ValueOf(f1).Call([]Value{ValueOf(100), ValueOf(f2)}) + if r[0].Int() != 101 { + t.Errorf("function returned %d, want 101", r[0].Int()) + } +} + +func TestStructArg(t *testing.T) { + type padded struct { + B string + C int32 + } + var ( + gotA padded + gotB uint32 + wantA = padded{"3", 4} + wantB = uint32(5) + ) + f := func(a padded, b uint32) { + gotA, gotB = a, b + } + ValueOf(f).Call([]Value{ValueOf(wantA), ValueOf(wantB)}) + if gotA != wantA || gotB != wantB { + t.Errorf("function called with (%v, %v), want (%v, %v)", gotA, gotB, wantA, wantB) + } +} + +var tagGetTests = []struct { + Tag StructTag + Key string + Value string +}{ + {`protobuf:"PB(1,2)"`, `protobuf`, `PB(1,2)`}, + {`protobuf:"PB(1,2)"`, `foo`, ``}, + {`protobuf:"PB(1,2)"`, `rotobuf`, ``}, + {`protobuf:"PB(1,2)" json:"name"`, `json`, `name`}, + {`protobuf:"PB(1,2)" json:"name"`, `protobuf`, `PB(1,2)`}, +} + +func TestTagGet(t *testing.T) { + for _, tt := range tagGetTests { + if v := tt.Tag.Get(tt.Key); v != tt.Value { + t.Errorf("StructTag(%#q).Get(%#q) = %#q, want %#q", tt.Tag, tt.Key, v, tt.Value) + } + } +} + +func TestBytes(t *testing.T) { + type B []byte + x := B{1, 2, 3, 4} + y := ValueOf(x).Bytes() + if !bytes.Equal(x, y) { + t.Fatalf("ValueOf(%v).Bytes() = %v", x, y) + } + if &x[0] != &y[0] { + t.Errorf("ValueOf(%p).Bytes() = %p", &x[0], &y[0]) + } +} + +func TestSetBytes(t *testing.T) { + type B []byte + var x B + y := []byte{1, 2, 3, 4} + ValueOf(&x).Elem().SetBytes(y) + if !bytes.Equal(x, y) { + t.Fatalf("ValueOf(%v).Bytes() = %v", x, y) + } + if &x[0] != &y[0] { + t.Errorf("ValueOf(%p).Bytes() = %p", &x[0], &y[0]) + } +} + +type Private struct { + x int + y **int +} + +func (p *Private) m() { +} + +type Public struct { + X int + Y **int +} + +func (p *Public) M() { +} + +func TestUnexported(t *testing.T) { + var pub Public + v := ValueOf(&pub) + isValid(v.Elem().Field(0)) + isValid(v.Elem().Field(1)) + isValid(v.Elem().FieldByName("X")) + isValid(v.Elem().FieldByName("Y")) + isValid(v.Type().Method(0).Func) + isNonNil(v.Elem().Field(0).Interface()) + isNonNil(v.Elem().Field(1).Interface()) + isNonNil(v.Elem().FieldByName("X").Interface()) + isNonNil(v.Elem().FieldByName("Y").Interface()) + isNonNil(v.Type().Method(0).Func.Interface()) + + var priv Private + v = ValueOf(&priv) + isValid(v.Elem().Field(0)) + isValid(v.Elem().Field(1)) + isValid(v.Elem().FieldByName("x")) + isValid(v.Elem().FieldByName("y")) + isValid(v.Type().Method(0).Func) + shouldPanic(func() { v.Elem().Field(0).Interface() }) + shouldPanic(func() { v.Elem().Field(1).Interface() }) + shouldPanic(func() { v.Elem().FieldByName("x").Interface() }) + shouldPanic(func() { v.Elem().FieldByName("y").Interface() }) + shouldPanic(func() { v.Type().Method(0).Func.Interface() }) +} + +func shouldPanic(f func()) { + defer func() { + if recover() == nil { + panic("did not panic") + } + }() + f() +} + +func isNonNil(x interface{}) { + if x == nil { + panic("nil interface") + } +} + +func isValid(v Value) { + if !v.IsValid() { + panic("zero Value") + } +} + +func TestAlias(t *testing.T) { + x := string("hello") + v := ValueOf(&x).Elem() + oldvalue := v.Interface() + v.SetString("world") + newvalue := v.Interface() + + if oldvalue != "hello" || newvalue != "world" { + t.Errorf("aliasing: old=%q new=%q, want hello, world", oldvalue, newvalue) + } +} + +var V = ValueOf + +func EmptyInterfaceV(x interface{}) Value { + return ValueOf(&x).Elem() +} + +func ReaderV(x io.Reader) Value { + return ValueOf(&x).Elem() +} + +func ReadWriterV(x io.ReadWriter) Value { + return ValueOf(&x).Elem() +} + +type Empty struct{} +type MyString string +type MyBytes []byte +type MyRunes []int32 +type MyFunc func() +type MyByte byte + +var convertTests = []struct { + in Value + out Value +}{ + // numbers + /* + Edit .+1,/\*\//-1>cat >/tmp/x.go && go run /tmp/x.go + + package main + + import "fmt" + + var numbers = []string{ + "int8", "uint8", "int16", "uint16", + "int32", "uint32", "int64", "uint64", + "int", "uint", "uintptr", + "float32", "float64", + } + + func main() { + // all pairs but in an unusual order, + // to emit all the int8, uint8 cases + // before n grows too big. + n := 1 + for i, f := range numbers { + for _, g := range numbers[i:] { + fmt.Printf("\t{V(%s(%d)), V(%s(%d))},\n", f, n, g, n) + n++ + if f != g { + fmt.Printf("\t{V(%s(%d)), V(%s(%d))},\n", g, n, f, n) + n++ + } + } + } + } + */ + {V(int8(1)), V(int8(1))}, + {V(int8(2)), V(uint8(2))}, + {V(uint8(3)), V(int8(3))}, + {V(int8(4)), V(int16(4))}, + {V(int16(5)), V(int8(5))}, + {V(int8(6)), V(uint16(6))}, + {V(uint16(7)), V(int8(7))}, + {V(int8(8)), V(int32(8))}, + {V(int32(9)), V(int8(9))}, + {V(int8(10)), V(uint32(10))}, + {V(uint32(11)), V(int8(11))}, + {V(int8(12)), V(int64(12))}, + {V(int64(13)), V(int8(13))}, + {V(int8(14)), V(uint64(14))}, + {V(uint64(15)), V(int8(15))}, + {V(int8(16)), V(int(16))}, + {V(int(17)), V(int8(17))}, + {V(int8(18)), V(uint(18))}, + {V(uint(19)), V(int8(19))}, + {V(int8(20)), V(uintptr(20))}, + {V(uintptr(21)), V(int8(21))}, + {V(int8(22)), V(float32(22))}, + {V(float32(23)), V(int8(23))}, + {V(int8(24)), V(float64(24))}, + {V(float64(25)), V(int8(25))}, + {V(uint8(26)), V(uint8(26))}, + {V(uint8(27)), V(int16(27))}, + {V(int16(28)), V(uint8(28))}, + {V(uint8(29)), V(uint16(29))}, + {V(uint16(30)), V(uint8(30))}, + {V(uint8(31)), V(int32(31))}, + {V(int32(32)), V(uint8(32))}, + {V(uint8(33)), V(uint32(33))}, + {V(uint32(34)), V(uint8(34))}, + {V(uint8(35)), V(int64(35))}, + {V(int64(36)), V(uint8(36))}, + {V(uint8(37)), V(uint64(37))}, + {V(uint64(38)), V(uint8(38))}, + {V(uint8(39)), V(int(39))}, + {V(int(40)), V(uint8(40))}, + {V(uint8(41)), V(uint(41))}, + {V(uint(42)), V(uint8(42))}, + {V(uint8(43)), V(uintptr(43))}, + {V(uintptr(44)), V(uint8(44))}, + {V(uint8(45)), V(float32(45))}, + {V(float32(46)), V(uint8(46))}, + {V(uint8(47)), V(float64(47))}, + {V(float64(48)), V(uint8(48))}, + {V(int16(49)), V(int16(49))}, + {V(int16(50)), V(uint16(50))}, + {V(uint16(51)), V(int16(51))}, + {V(int16(52)), V(int32(52))}, + {V(int32(53)), V(int16(53))}, + {V(int16(54)), V(uint32(54))}, + {V(uint32(55)), V(int16(55))}, + {V(int16(56)), V(int64(56))}, + {V(int64(57)), V(int16(57))}, + {V(int16(58)), V(uint64(58))}, + {V(uint64(59)), V(int16(59))}, + {V(int16(60)), V(int(60))}, + {V(int(61)), V(int16(61))}, + {V(int16(62)), V(uint(62))}, + {V(uint(63)), V(int16(63))}, + {V(int16(64)), V(uintptr(64))}, + {V(uintptr(65)), V(int16(65))}, + {V(int16(66)), V(float32(66))}, + {V(float32(67)), V(int16(67))}, + {V(int16(68)), V(float64(68))}, + {V(float64(69)), V(int16(69))}, + {V(uint16(70)), V(uint16(70))}, + {V(uint16(71)), V(int32(71))}, + {V(int32(72)), V(uint16(72))}, + {V(uint16(73)), V(uint32(73))}, + {V(uint32(74)), V(uint16(74))}, + {V(uint16(75)), V(int64(75))}, + {V(int64(76)), V(uint16(76))}, + {V(uint16(77)), V(uint64(77))}, + {V(uint64(78)), V(uint16(78))}, + {V(uint16(79)), V(int(79))}, + {V(int(80)), V(uint16(80))}, + {V(uint16(81)), V(uint(81))}, + {V(uint(82)), V(uint16(82))}, + {V(uint16(83)), V(uintptr(83))}, + {V(uintptr(84)), V(uint16(84))}, + {V(uint16(85)), V(float32(85))}, + {V(float32(86)), V(uint16(86))}, + {V(uint16(87)), V(float64(87))}, + {V(float64(88)), V(uint16(88))}, + {V(int32(89)), V(int32(89))}, + {V(int32(90)), V(uint32(90))}, + {V(uint32(91)), V(int32(91))}, + {V(int32(92)), V(int64(92))}, + {V(int64(93)), V(int32(93))}, + {V(int32(94)), V(uint64(94))}, + {V(uint64(95)), V(int32(95))}, + {V(int32(96)), V(int(96))}, + {V(int(97)), V(int32(97))}, + {V(int32(98)), V(uint(98))}, + {V(uint(99)), V(int32(99))}, + {V(int32(100)), V(uintptr(100))}, + {V(uintptr(101)), V(int32(101))}, + {V(int32(102)), V(float32(102))}, + {V(float32(103)), V(int32(103))}, + {V(int32(104)), V(float64(104))}, + {V(float64(105)), V(int32(105))}, + {V(uint32(106)), V(uint32(106))}, + {V(uint32(107)), V(int64(107))}, + {V(int64(108)), V(uint32(108))}, + {V(uint32(109)), V(uint64(109))}, + {V(uint64(110)), V(uint32(110))}, + {V(uint32(111)), V(int(111))}, + {V(int(112)), V(uint32(112))}, + {V(uint32(113)), V(uint(113))}, + {V(uint(114)), V(uint32(114))}, + {V(uint32(115)), V(uintptr(115))}, + {V(uintptr(116)), V(uint32(116))}, + {V(uint32(117)), V(float32(117))}, + {V(float32(118)), V(uint32(118))}, + {V(uint32(119)), V(float64(119))}, + {V(float64(120)), V(uint32(120))}, + {V(int64(121)), V(int64(121))}, + {V(int64(122)), V(uint64(122))}, + {V(uint64(123)), V(int64(123))}, + {V(int64(124)), V(int(124))}, + {V(int(125)), V(int64(125))}, + {V(int64(126)), V(uint(126))}, + {V(uint(127)), V(int64(127))}, + {V(int64(128)), V(uintptr(128))}, + {V(uintptr(129)), V(int64(129))}, + {V(int64(130)), V(float32(130))}, + {V(float32(131)), V(int64(131))}, + {V(int64(132)), V(float64(132))}, + {V(float64(133)), V(int64(133))}, + {V(uint64(134)), V(uint64(134))}, + {V(uint64(135)), V(int(135))}, + {V(int(136)), V(uint64(136))}, + {V(uint64(137)), V(uint(137))}, + {V(uint(138)), V(uint64(138))}, + {V(uint64(139)), V(uintptr(139))}, + {V(uintptr(140)), V(uint64(140))}, + {V(uint64(141)), V(float32(141))}, + {V(float32(142)), V(uint64(142))}, + {V(uint64(143)), V(float64(143))}, + {V(float64(144)), V(uint64(144))}, + {V(int(145)), V(int(145))}, + {V(int(146)), V(uint(146))}, + {V(uint(147)), V(int(147))}, + {V(int(148)), V(uintptr(148))}, + {V(uintptr(149)), V(int(149))}, + {V(int(150)), V(float32(150))}, + {V(float32(151)), V(int(151))}, + {V(int(152)), V(float64(152))}, + {V(float64(153)), V(int(153))}, + {V(uint(154)), V(uint(154))}, + {V(uint(155)), V(uintptr(155))}, + {V(uintptr(156)), V(uint(156))}, + {V(uint(157)), V(float32(157))}, + {V(float32(158)), V(uint(158))}, + {V(uint(159)), V(float64(159))}, + {V(float64(160)), V(uint(160))}, + {V(uintptr(161)), V(uintptr(161))}, + {V(uintptr(162)), V(float32(162))}, + {V(float32(163)), V(uintptr(163))}, + {V(uintptr(164)), V(float64(164))}, + {V(float64(165)), V(uintptr(165))}, + {V(float32(166)), V(float32(166))}, + {V(float32(167)), V(float64(167))}, + {V(float64(168)), V(float32(168))}, + {V(float64(169)), V(float64(169))}, + + // truncation + {V(float64(1.5)), V(int(1))}, + + // complex + {V(complex64(1i)), V(complex64(1i))}, + {V(complex64(2i)), V(complex128(2i))}, + {V(complex128(3i)), V(complex64(3i))}, + {V(complex128(4i)), V(complex128(4i))}, + + // string + {V(string("hello")), V(string("hello"))}, + {V(string("bytes1")), V([]byte("bytes1"))}, + {V([]byte("bytes2")), V(string("bytes2"))}, + {V([]byte("bytes3")), V([]byte("bytes3"))}, + {V(string("runes♝")), V([]rune("runes♝"))}, + {V([]rune("runes♕")), V(string("runes♕"))}, + {V([]rune("runes🙈🙉🙊")), V([]rune("runes🙈🙉🙊"))}, + {V(int('a')), V(string("a"))}, + {V(int8('a')), V(string("a"))}, + {V(int16('a')), V(string("a"))}, + {V(int32('a')), V(string("a"))}, + {V(int64('a')), V(string("a"))}, + {V(uint('a')), V(string("a"))}, + {V(uint8('a')), V(string("a"))}, + {V(uint16('a')), V(string("a"))}, + {V(uint32('a')), V(string("a"))}, + {V(uint64('a')), V(string("a"))}, + {V(uintptr('a')), V(string("a"))}, + {V(int(-1)), V(string("\uFFFD"))}, + {V(int8(-2)), V(string("\uFFFD"))}, + {V(int16(-3)), V(string("\uFFFD"))}, + {V(int32(-4)), V(string("\uFFFD"))}, + {V(int64(-5)), V(string("\uFFFD"))}, + {V(uint(0x110001)), V(string("\uFFFD"))}, + {V(uint32(0x110002)), V(string("\uFFFD"))}, + {V(uint64(0x110003)), V(string("\uFFFD"))}, + {V(uintptr(0x110004)), V(string("\uFFFD"))}, + + // named string + {V(MyString("hello")), V(string("hello"))}, + {V(string("hello")), V(MyString("hello"))}, + {V(string("hello")), V(string("hello"))}, + {V(MyString("hello")), V(MyString("hello"))}, + {V(MyString("bytes1")), V([]byte("bytes1"))}, + {V([]byte("bytes2")), V(MyString("bytes2"))}, + {V([]byte("bytes3")), V([]byte("bytes3"))}, + {V(MyString("runes♝")), V([]rune("runes♝"))}, + {V([]rune("runes♕")), V(MyString("runes♕"))}, + {V([]rune("runes🙈🙉🙊")), V([]rune("runes🙈🙉🙊"))}, + {V([]rune("runes🙈🙉🙊")), V(MyRunes("runes🙈🙉🙊"))}, + {V(MyRunes("runes🙈🙉🙊")), V([]rune("runes🙈🙉🙊"))}, + {V(int('a')), V(MyString("a"))}, + {V(int8('a')), V(MyString("a"))}, + {V(int16('a')), V(MyString("a"))}, + {V(int32('a')), V(MyString("a"))}, + {V(int64('a')), V(MyString("a"))}, + {V(uint('a')), V(MyString("a"))}, + {V(uint8('a')), V(MyString("a"))}, + {V(uint16('a')), V(MyString("a"))}, + {V(uint32('a')), V(MyString("a"))}, + {V(uint64('a')), V(MyString("a"))}, + {V(uintptr('a')), V(MyString("a"))}, + {V(int(-1)), V(MyString("\uFFFD"))}, + {V(int8(-2)), V(MyString("\uFFFD"))}, + {V(int16(-3)), V(MyString("\uFFFD"))}, + {V(int32(-4)), V(MyString("\uFFFD"))}, + {V(int64(-5)), V(MyString("\uFFFD"))}, + {V(uint(0x110001)), V(MyString("\uFFFD"))}, + {V(uint32(0x110002)), V(MyString("\uFFFD"))}, + {V(uint64(0x110003)), V(MyString("\uFFFD"))}, + {V(uintptr(0x110004)), V(MyString("\uFFFD"))}, + + // named []byte + {V(string("bytes1")), V(MyBytes("bytes1"))}, + {V(MyBytes("bytes2")), V(string("bytes2"))}, + {V(MyBytes("bytes3")), V(MyBytes("bytes3"))}, + {V(MyString("bytes1")), V(MyBytes("bytes1"))}, + {V(MyBytes("bytes2")), V(MyString("bytes2"))}, + + // named []rune + {V(string("runes♝")), V(MyRunes("runes♝"))}, + {V(MyRunes("runes♕")), V(string("runes♕"))}, + {V(MyRunes("runes🙈🙉🙊")), V(MyRunes("runes🙈🙉🙊"))}, + {V(MyString("runes♝")), V(MyRunes("runes♝"))}, + {V(MyRunes("runes♕")), V(MyString("runes♕"))}, + + // named types and equal underlying types + {V(new(int)), V(new(integer))}, + {V(new(integer)), V(new(int))}, + {V(Empty{}), V(struct{}{})}, + {V(new(Empty)), V(new(struct{}))}, + {V(struct{}{}), V(Empty{})}, + {V(new(struct{})), V(new(Empty))}, + {V(Empty{}), V(Empty{})}, + {V(MyBytes{}), V([]byte{})}, + {V([]byte{}), V(MyBytes{})}, + {V((func())(nil)), V(MyFunc(nil))}, + {V((MyFunc)(nil)), V((func())(nil))}, + + // can convert *byte and *MyByte + {V((*byte)(nil)), V((*MyByte)(nil))}, + {V((*MyByte)(nil)), V((*byte)(nil))}, + + // cannot convert mismatched array sizes + {V([2]byte{}), V([2]byte{})}, + {V([3]byte{}), V([3]byte{})}, + + // cannot convert other instances + {V((**byte)(nil)), V((**byte)(nil))}, + {V((**MyByte)(nil)), V((**MyByte)(nil))}, + {V((chan byte)(nil)), V((chan byte)(nil))}, + {V((chan MyByte)(nil)), V((chan MyByte)(nil))}, + {V(([]byte)(nil)), V(([]byte)(nil))}, + {V(([]MyByte)(nil)), V(([]MyByte)(nil))}, + {V((map[int]byte)(nil)), V((map[int]byte)(nil))}, + {V((map[int]MyByte)(nil)), V((map[int]MyByte)(nil))}, + {V((map[byte]int)(nil)), V((map[byte]int)(nil))}, + {V((map[MyByte]int)(nil)), V((map[MyByte]int)(nil))}, + {V([2]byte{}), V([2]byte{})}, + {V([2]MyByte{}), V([2]MyByte{})}, + + // other + {V((***int)(nil)), V((***int)(nil))}, + {V((***byte)(nil)), V((***byte)(nil))}, + {V((***int32)(nil)), V((***int32)(nil))}, + {V((***int64)(nil)), V((***int64)(nil))}, + {V((chan int)(nil)), V((<-chan int)(nil))}, + {V((chan int)(nil)), V((chan<- int)(nil))}, + {V((chan string)(nil)), V((<-chan string)(nil))}, + {V((chan string)(nil)), V((chan<- string)(nil))}, + {V((chan byte)(nil)), V((chan byte)(nil))}, + {V((chan MyByte)(nil)), V((chan MyByte)(nil))}, + {V((map[int]bool)(nil)), V((map[int]bool)(nil))}, + {V((map[int]byte)(nil)), V((map[int]byte)(nil))}, + {V((map[uint]bool)(nil)), V((map[uint]bool)(nil))}, + {V([]uint(nil)), V([]uint(nil))}, + {V([]int(nil)), V([]int(nil))}, + {V(new(interface{})), V(new(interface{}))}, + {V(new(io.Reader)), V(new(io.Reader))}, + {V(new(io.Writer)), V(new(io.Writer))}, + + // interfaces + {V(int(1)), EmptyInterfaceV(int(1))}, + {V(string("hello")), EmptyInterfaceV(string("hello"))}, + {V(new(bytes.Buffer)), ReaderV(new(bytes.Buffer))}, + {ReadWriterV(new(bytes.Buffer)), ReaderV(new(bytes.Buffer))}, + {V(new(bytes.Buffer)), ReadWriterV(new(bytes.Buffer))}, +} + +func TestConvert(t *testing.T) { + canConvert := map[[2]Type]bool{} + all := map[Type]bool{} + + for _, tt := range convertTests { + t1 := tt.in.Type() + if !t1.ConvertibleTo(t1) { + t.Errorf("(%s).ConvertibleTo(%s) = false, want true", t1, t1) + continue + } + + t2 := tt.out.Type() + if !t1.ConvertibleTo(t2) { + t.Errorf("(%s).ConvertibleTo(%s) = false, want true", t1, t2) + continue + } + + all[t1] = true + all[t2] = true + canConvert[[2]Type{t1, t2}] = true + + // vout1 represents the in value converted to the in type. + v1 := tt.in + vout1 := v1.Convert(t1) + out1 := vout1.Interface() + if vout1.Type() != tt.in.Type() || !DeepEqual(out1, tt.in.Interface()) { + t.Errorf("ValueOf(%T(%[1]v)).Convert(%s) = %T(%[3]v), want %T(%[4]v)", tt.in.Interface(), t1, out1, tt.in.Interface()) + } + + // vout2 represents the in value converted to the out type. + vout2 := v1.Convert(t2) + out2 := vout2.Interface() + if vout2.Type() != tt.out.Type() || !DeepEqual(out2, tt.out.Interface()) { + t.Errorf("ValueOf(%T(%[1]v)).Convert(%s) = %T(%[3]v), want %T(%[4]v)", tt.in.Interface(), t2, out2, tt.out.Interface()) + } + + // vout3 represents a new value of the out type, set to vout2. This makes + // sure the converted value vout2 is really usable as a regular value. + vout3 := New(t2).Elem() + vout3.Set(vout2) + out3 := vout3.Interface() + if vout3.Type() != tt.out.Type() || !DeepEqual(out3, tt.out.Interface()) { + t.Errorf("Set(ValueOf(%T(%[1]v)).Convert(%s)) = %T(%[3]v), want %T(%[4]v)", tt.in.Interface(), t2, out3, tt.out.Interface()) + } + + if IsRO(v1) { + t.Errorf("table entry %v is RO, should not be", v1) + } + if IsRO(vout1) { + t.Errorf("self-conversion output %v is RO, should not be", vout1) + } + if IsRO(vout2) { + t.Errorf("conversion output %v is RO, should not be", vout2) + } + if IsRO(vout3) { + t.Errorf("set(conversion output) %v is RO, should not be", vout3) + } + if !IsRO(MakeRO(v1).Convert(t1)) { + t.Errorf("RO self-conversion output %v is not RO, should be", v1) + } + if !IsRO(MakeRO(v1).Convert(t2)) { + t.Errorf("RO conversion output %v is not RO, should be", v1) + } + } + + // Assume that of all the types we saw during the tests, + // if there wasn't an explicit entry for a conversion between + // a pair of types, then it's not to be allowed. This checks for + // things like 'int64' converting to '*int'. + for t1 := range all { + for t2 := range all { + expectOK := t1 == t2 || canConvert[[2]Type{t1, t2}] || t2.Kind() == Interface && t2.NumMethod() == 0 + if ok := t1.ConvertibleTo(t2); ok != expectOK { + t.Errorf("(%s).ConvertibleTo(%s) = %v, want %v", t1, t2, ok, expectOK) + } + } + } +} + +type ComparableStruct struct { + X int +} + +type NonComparableStruct struct { + X int + Y map[string]int +} + +var comparableTests = []struct { + typ Type + ok bool +}{ + {TypeOf(1), true}, + {TypeOf("hello"), true}, + {TypeOf(new(byte)), true}, + {TypeOf((func())(nil)), false}, + {TypeOf([]byte{}), false}, + {TypeOf(map[string]int{}), false}, + {TypeOf(make(chan int)), true}, + {TypeOf(1.5), true}, + {TypeOf(false), true}, + {TypeOf(1i), true}, + {TypeOf(ComparableStruct{}), true}, + {TypeOf(NonComparableStruct{}), false}, + {TypeOf([10]map[string]int{}), false}, + {TypeOf([10]string{}), true}, + {TypeOf(new(interface{})).Elem(), true}, +} + +func TestComparable(t *testing.T) { + for _, tt := range comparableTests { + if ok := tt.typ.Comparable(); ok != tt.ok { + t.Errorf("TypeOf(%v).Comparable() = %v, want %v", tt.typ, ok, tt.ok) + } + } +} + +func TestOverflow(t *testing.T) { + if ovf := V(float64(0)).OverflowFloat(1e300); ovf { + t.Errorf("%v wrongly overflows float64", 1e300) + } + + maxFloat32 := float64((1<<24 - 1) << (127 - 23)) + if ovf := V(float32(0)).OverflowFloat(maxFloat32); ovf { + t.Errorf("%v wrongly overflows float32", maxFloat32) + } + ovfFloat32 := float64((1<<24-1)<<(127-23) + 1<<(127-52)) + if ovf := V(float32(0)).OverflowFloat(ovfFloat32); !ovf { + t.Errorf("%v should overflow float32", ovfFloat32) + } + if ovf := V(float32(0)).OverflowFloat(-ovfFloat32); !ovf { + t.Errorf("%v should overflow float32", -ovfFloat32) + } + + maxInt32 := int64(0x7fffffff) + if ovf := V(int32(0)).OverflowInt(maxInt32); ovf { + t.Errorf("%v wrongly overflows int32", maxInt32) + } + if ovf := V(int32(0)).OverflowInt(-1 << 31); ovf { + t.Errorf("%v wrongly overflows int32", -int64(1)<<31) + } + ovfInt32 := int64(1 << 31) + if ovf := V(int32(0)).OverflowInt(ovfInt32); !ovf { + t.Errorf("%v should overflow int32", ovfInt32) + } + + maxUint32 := uint64(0xffffffff) + if ovf := V(uint32(0)).OverflowUint(maxUint32); ovf { + t.Errorf("%v wrongly overflows uint32", maxUint32) + } + ovfUint32 := uint64(1 << 32) + if ovf := V(uint32(0)).OverflowUint(ovfUint32); !ovf { + t.Errorf("%v should overflow uint32", ovfUint32) + } +} + +func checkSameType(t *testing.T, x, y interface{}) { + if TypeOf(x) != TypeOf(y) { + t.Errorf("did not find preexisting type for %s (vs %s)", TypeOf(x), TypeOf(y)) + } +} + +func TestArrayOf(t *testing.T) { + // TODO(rsc): Finish ArrayOf and enable-test. + t.Skip("ArrayOf is not finished (and not exported)") + + // check construction and use of type not in binary + type T int + at := ArrayOf(10, TypeOf(T(1))) + v := New(at).Elem() + for i := 0; i < v.Len(); i++ { + v.Index(i).Set(ValueOf(T(i))) + } + s := fmt.Sprint(v.Interface()) + want := "[0 1 2 3 4 5 6 7 8 9]" + if s != want { + t.Errorf("constructed array = %s, want %s", s, want) + } + + // check that type already in binary is found + checkSameType(t, Zero(ArrayOf(5, TypeOf(T(1)))).Interface(), [5]T{}) +} + +func TestSliceOf(t *testing.T) { + // check construction and use of type not in binary + type T int + st := SliceOf(TypeOf(T(1))) + v := MakeSlice(st, 10, 10) + runtime.GC() + for i := 0; i < v.Len(); i++ { + v.Index(i).Set(ValueOf(T(i))) + runtime.GC() + } + s := fmt.Sprint(v.Interface()) + want := "[0 1 2 3 4 5 6 7 8 9]" + if s != want { + t.Errorf("constructed slice = %s, want %s", s, want) + } + + // check that type already in binary is found + type T1 int + checkSameType(t, Zero(SliceOf(TypeOf(T1(1)))).Interface(), []T1{}) +} + +func TestSliceOverflow(t *testing.T) { + // check that MakeSlice panics when size of slice overflows uint + const S = 1e6 + s := uint(S) + l := (1<<(unsafe.Sizeof((*byte)(nil))*8)-1)/s + 1 + if l*s >= s { + t.Fatal("slice size does not overflow") + } + var x [S]byte + st := SliceOf(TypeOf(x)) + defer func() { + err := recover() + if err == nil { + t.Fatal("slice overflow does not panic") + } + }() + MakeSlice(st, int(l), int(l)) +} + +func TestSliceOfGC(t *testing.T) { + type T *uintptr + tt := TypeOf(T(nil)) + st := SliceOf(tt) + const n = 100 + var x []interface{} + for i := 0; i < n; i++ { + v := MakeSlice(st, n, n) + for j := 0; j < v.Len(); j++ { + p := new(uintptr) + *p = uintptr(i*n + j) + v.Index(j).Set(ValueOf(p).Convert(tt)) + } + x = append(x, v.Interface()) + } + runtime.GC() + + for i, xi := range x { + v := ValueOf(xi) + for j := 0; j < v.Len(); j++ { + k := v.Index(j).Elem().Interface() + if k != uintptr(i*n+j) { + t.Errorf("lost x[%d][%d] = %d, want %d", i, j, k, i*n+j) + } + } + } +} + +func TestChanOf(t *testing.T) { + // check construction and use of type not in binary + type T string + ct := ChanOf(BothDir, TypeOf(T(""))) + v := MakeChan(ct, 2) + runtime.GC() + v.Send(ValueOf(T("hello"))) + runtime.GC() + v.Send(ValueOf(T("world"))) + runtime.GC() + + sv1, _ := v.Recv() + sv2, _ := v.Recv() + s1 := sv1.String() + s2 := sv2.String() + if s1 != "hello" || s2 != "world" { + t.Errorf("constructed chan: have %q, %q, want %q, %q", s1, s2, "hello", "world") + } + + // check that type already in binary is found + type T1 int + checkSameType(t, Zero(ChanOf(BothDir, TypeOf(T1(1)))).Interface(), (chan T1)(nil)) +} + +func TestChanOfGC(t *testing.T) { + done := make(chan bool, 1) + go func() { + select { + case <-done: + case <-time.After(5 * time.Second): + panic("deadlock in TestChanOfGC") + } + }() + + defer func() { + done <- true + }() + + type T *uintptr + tt := TypeOf(T(nil)) + ct := ChanOf(BothDir, tt) + + // NOTE: The garbage collector handles allocated channels specially, + // so we have to save pointers to channels in x; the pointer code will + // use the gc info in the newly constructed chan type. + const n = 100 + var x []interface{} + for i := 0; i < n; i++ { + v := MakeChan(ct, n) + for j := 0; j < n; j++ { + p := new(uintptr) + *p = uintptr(i*n + j) + v.Send(ValueOf(p).Convert(tt)) + } + pv := New(ct) + pv.Elem().Set(v) + x = append(x, pv.Interface()) + } + runtime.GC() + + for i, xi := range x { + v := ValueOf(xi).Elem() + for j := 0; j < n; j++ { + pv, _ := v.Recv() + k := pv.Elem().Interface() + if k != uintptr(i*n+j) { + t.Errorf("lost x[%d][%d] = %d, want %d", i, j, k, i*n+j) + } + } + } +} + +func TestMapOf(t *testing.T) { + // check construction and use of type not in binary + type K string + type V float64 + + v := MakeMap(MapOf(TypeOf(K("")), TypeOf(V(0)))) + runtime.GC() + v.SetMapIndex(ValueOf(K("a")), ValueOf(V(1))) + runtime.GC() + + s := fmt.Sprint(v.Interface()) + want := "map[a:1]" + if s != want { + t.Errorf("constructed map = %s, want %s", s, want) + } + + // check that type already in binary is found + checkSameType(t, Zero(MapOf(TypeOf(V(0)), TypeOf(K("")))).Interface(), map[V]K(nil)) + + // check that invalid key type panics + shouldPanic(func() { MapOf(TypeOf((func())(nil)), TypeOf(false)) }) +} + +func TestMapOfGCKeys(t *testing.T) { + type T *uintptr + tt := TypeOf(T(nil)) + mt := MapOf(tt, TypeOf(false)) + + // NOTE: The garbage collector handles allocated maps specially, + // so we have to save pointers to maps in x; the pointer code will + // use the gc info in the newly constructed map type. + const n = 100 + var x []interface{} + for i := 0; i < n; i++ { + v := MakeMap(mt) + for j := 0; j < n; j++ { + p := new(uintptr) + *p = uintptr(i*n + j) + v.SetMapIndex(ValueOf(p).Convert(tt), ValueOf(true)) + } + pv := New(mt) + pv.Elem().Set(v) + x = append(x, pv.Interface()) + } + runtime.GC() + + for i, xi := range x { + v := ValueOf(xi).Elem() + var out []int + for _, kv := range v.MapKeys() { + out = append(out, int(kv.Elem().Interface().(uintptr))) + } + sort.Ints(out) + for j, k := range out { + if k != i*n+j { + t.Errorf("lost x[%d][%d] = %d, want %d", i, j, k, i*n+j) + } + } + } +} + +func TestMapOfGCValues(t *testing.T) { + type T *uintptr + tt := TypeOf(T(nil)) + mt := MapOf(TypeOf(1), tt) + + // NOTE: The garbage collector handles allocated maps specially, + // so we have to save pointers to maps in x; the pointer code will + // use the gc info in the newly constructed map type. + const n = 100 + var x []interface{} + for i := 0; i < n; i++ { + v := MakeMap(mt) + for j := 0; j < n; j++ { + p := new(uintptr) + *p = uintptr(i*n + j) + v.SetMapIndex(ValueOf(j), ValueOf(p).Convert(tt)) + } + pv := New(mt) + pv.Elem().Set(v) + x = append(x, pv.Interface()) + } + runtime.GC() + + for i, xi := range x { + v := ValueOf(xi).Elem() + for j := 0; j < n; j++ { + k := v.MapIndex(ValueOf(j)).Elem().Interface().(uintptr) + if k != uintptr(i*n+j) { + t.Errorf("lost x[%d][%d] = %d, want %d", i, j, k, i*n+j) + } + } + } +} + +type B1 struct { + X int + Y int + Z int +} + +func BenchmarkFieldByName1(b *testing.B) { + t := TypeOf(B1{}) + for i := 0; i < b.N; i++ { + t.FieldByName("Z") + } +} + +func BenchmarkFieldByName2(b *testing.B) { + t := TypeOf(S3{}) + for i := 0; i < b.N; i++ { + t.FieldByName("B") + } +} + +type R0 struct { + *R1 + *R2 + *R3 + *R4 +} + +type R1 struct { + *R5 + *R6 + *R7 + *R8 +} + +type R2 R1 +type R3 R1 +type R4 R1 + +type R5 struct { + *R9 + *R10 + *R11 + *R12 +} + +type R6 R5 +type R7 R5 +type R8 R5 + +type R9 struct { + *R13 + *R14 + *R15 + *R16 +} + +type R10 R9 +type R11 R9 +type R12 R9 + +type R13 struct { + *R17 + *R18 + *R19 + *R20 +} + +type R14 R13 +type R15 R13 +type R16 R13 + +type R17 struct { + *R21 + *R22 + *R23 + *R24 +} + +type R18 R17 +type R19 R17 +type R20 R17 + +type R21 struct { + X int +} + +type R22 R21 +type R23 R21 +type R24 R21 + +func TestEmbed(t *testing.T) { + typ := TypeOf(R0{}) + f, ok := typ.FieldByName("X") + if ok { + t.Fatalf(`FieldByName("X") should fail, returned %v`, f.Index) + } +} + +func BenchmarkFieldByName3(b *testing.B) { + t := TypeOf(R0{}) + for i := 0; i < b.N; i++ { + t.FieldByName("X") + } +} + +type S struct { + i1 int64 + i2 int64 +} + +func BenchmarkInterfaceBig(b *testing.B) { + v := ValueOf(S{}) + for i := 0; i < b.N; i++ { + v.Interface() + } + b.StopTimer() +} + +func TestAllocsInterfaceBig(t *testing.T) { + if testing.Short() { + t.Skip("skipping malloc count in short mode") + } + v := ValueOf(S{}) + if allocs := testing.AllocsPerRun(100, func() { v.Interface() }); allocs > 0 { + t.Error("allocs:", allocs) + } +} + +func BenchmarkInterfaceSmall(b *testing.B) { + v := ValueOf(int64(0)) + for i := 0; i < b.N; i++ { + v.Interface() + } +} + +func TestAllocsInterfaceSmall(t *testing.T) { + if testing.Short() { + t.Skip("skipping malloc count in short mode") + } + v := ValueOf(int64(0)) + if allocs := testing.AllocsPerRun(100, func() { v.Interface() }); allocs > 0 { + t.Error("allocs:", allocs) + } +} + +// An exhaustive is a mechanism for writing exhaustive or stochastic tests. +// The basic usage is: +// +// for x.Next() { +// ... code using x.Maybe() or x.Choice(n) to create test cases ... +// } +// +// Each iteration of the loop returns a different set of results, until all +// possible result sets have been explored. It is okay for different code paths +// to make different method call sequences on x, but there must be no +// other source of non-determinism in the call sequences. +// +// When faced with a new decision, x chooses randomly. Future explorations +// of that path will choose successive values for the result. Thus, stopping +// the loop after a fixed number of iterations gives somewhat stochastic +// testing. +// +// Example: +// +// for x.Next() { +// v := make([]bool, x.Choose(4)) +// for i := range v { +// v[i] = x.Maybe() +// } +// fmt.Println(v) +// } +// +// prints (in some order): +// +// [] +// [false] +// [true] +// [false false] +// [false true] +// ... +// [true true] +// [false false false] +// ... +// [true true true] +// [false false false false] +// ... +// [true true true true] +// +type exhaustive struct { + r *rand.Rand + pos int + last []choice +} + +type choice struct { + off int + n int + max int +} + +func (x *exhaustive) Next() bool { + if x.r == nil { + x.r = rand.New(rand.NewSource(time.Now().UnixNano())) + } + x.pos = 0 + if x.last == nil { + x.last = []choice{} + return true + } + for i := len(x.last) - 1; i >= 0; i-- { + c := &x.last[i] + if c.n+1 < c.max { + c.n++ + x.last = x.last[:i+1] + return true + } + } + return false +} + +func (x *exhaustive) Choose(max int) int { + if x.pos >= len(x.last) { + x.last = append(x.last, choice{x.r.Intn(max), 0, max}) + } + c := &x.last[x.pos] + x.pos++ + if c.max != max { + panic("inconsistent use of exhaustive tester") + } + return (c.n + c.off) % max +} + +func (x *exhaustive) Maybe() bool { + return x.Choose(2) == 1 +} + +func GCFunc(args []Value) []Value { + runtime.GC() + return []Value{} +} + +func TestReflectFuncTraceback(t *testing.T) { + f := MakeFunc(TypeOf(func() {}), GCFunc) + f.Call([]Value{}) +} + +func TestReflectMethodTraceback(t *testing.T) { + p := Point{3, 4} + m := ValueOf(p).MethodByName("GCMethod") + i := ValueOf(m.Interface()).Call([]Value{ValueOf(5)})[0].Int() + if i != 8 { + t.Errorf("Call returned %d; want 8", i) + } +} + +func TestBigZero(t *testing.T) { + const size = 1 << 10 + var v [size]byte + z := Zero(ValueOf(v).Type()).Interface().([size]byte) + for i := 0; i < size; i++ { + if z[i] != 0 { + t.Fatalf("Zero object not all zero, index %d", i) + } + } +} + +func TestFieldByIndexNil(t *testing.T) { + type P struct { + F int + } + type T struct { + *P + } + v := ValueOf(T{}) + + v.FieldByName("P") // should be fine + + defer func() { + if err := recover(); err == nil { + t.Fatalf("no error") + } else if !strings.Contains(fmt.Sprint(err), "nil pointer to embedded struct") { + t.Fatalf(`err=%q, wanted error containing "nil pointer to embedded struct"`, err) + } + }() + v.FieldByName("F") // should panic + + t.Fatalf("did not panic") +} + +// Given +// type Outer struct { +// *Inner +// ... +// } +// the compiler generates the implementation of (*Outer).M dispatching to the embedded Inner. +// The implementation is logically: +// func (p *Outer) M() { +// (p.Inner).M() +// } +// but since the only change here is the replacement of one pointer receiver with another, +// the actual generated code overwrites the original receiver with the p.Inner pointer and +// then jumps to the M method expecting the *Inner receiver. +// +// During reflect.Value.Call, we create an argument frame and the associated data structures +// to describe it to the garbage collector, populate the frame, call reflect.call to +// run a function call using that frame, and then copy the results back out of the frame. +// The reflect.call function does a memmove of the frame structure onto the +// stack (to set up the inputs), runs the call, and the memmoves the stack back to +// the frame structure (to preserve the outputs). +// +// Originally reflect.call did not distinguish inputs from outputs: both memmoves +// were for the full stack frame. However, in the case where the called function was +// one of these wrappers, the rewritten receiver is almost certainly a different type +// than the original receiver. This is not a problem on the stack, where we use the +// program counter to determine the type information and understand that +// during (*Outer).M the receiver is an *Outer while during (*Inner).M the receiver in the same +// memory word is now an *Inner. But in the statically typed argument frame created +// by reflect, the receiver is always an *Outer. Copying the modified receiver pointer +// off the stack into the frame will store an *Inner there, and then if a garbage collection +// happens to scan that argument frame before it is discarded, it will scan the *Inner +// memory as if it were an *Outer. If the two have different memory layouts, the +// collection will intepret the memory incorrectly. +// +// One such possible incorrect interpretation is to treat two arbitrary memory words +// (Inner.P1 and Inner.P2 below) as an interface (Outer.R below). Because interpreting +// an interface requires dereferencing the itab word, the misinterpretation will try to +// deference Inner.P1, causing a crash during garbage collection. +// +// This came up in a real program in issue 7725. + +type Outer struct { + *Inner + R io.Reader +} + +type Inner struct { + X *Outer + P1 uintptr + P2 uintptr +} + +func (pi *Inner) M() { + // Clear references to pi so that the only way the + // garbage collection will find the pointer is in the + // argument frame, typed as a *Outer. + pi.X.Inner = nil + + // Set up an interface value that will cause a crash. + // P1 = 1 is a non-zero, so the interface looks non-nil. + // P2 = pi ensures that the data word points into the + // allocated heap; if not the collection skips the interface + // value as irrelevant, without dereferencing P1. + pi.P1 = 1 + pi.P2 = uintptr(unsafe.Pointer(pi)) +} + +func TestCallMethodJump(t *testing.T) { + // In reflect.Value.Call, trigger a garbage collection after reflect.call + // returns but before the args frame has been discarded. + // This is a little clumsy but makes the failure repeatable. + *CallGC = true + + p := &Outer{Inner: new(Inner)} + p.Inner.X = p + ValueOf(p).Method(0).Call(nil) + + // Stop garbage collecting during reflect.call. + *CallGC = false +} + +func TestMakeFuncStackCopy(t *testing.T) { + target := func(in []Value) []Value { + runtime.GC() + useStack(16) + return []Value{ValueOf(9)} + } + + var concrete func(*int, int) int + fn := MakeFunc(ValueOf(concrete).Type(), target) + ValueOf(&concrete).Elem().Set(fn) + x := concrete(nil, 7) + if x != 9 { + t.Errorf("have %#q want 9", x) + } +} + +// use about n KB of stack +func useStack(n int) { + if n == 0 { + return + } + var b [1024]byte // makes frame about 1KB + useStack(n - 1 + int(b[99])) +} + +type Impl struct{} + +func (Impl) f() {} + +func TestValueString(t *testing.T) { + rv := ValueOf(Impl{}) + if rv.String() != "<reflect_test.Impl Value>" { + t.Errorf("ValueOf(Impl{}).String() = %q, want %q", rv.String(), "<reflect_test.Impl Value>") + } + + method := rv.Method(0) + if method.String() != "<func() Value>" { + t.Errorf("ValueOf(Impl{}).Method(0).String() = %q, want %q", method.String(), "<func() Value>") + } +} + +func TestInvalid(t *testing.T) { + // Used to have inconsistency between IsValid() and Kind() != Invalid. + type T struct{ v interface{} } + + v := ValueOf(T{}).Field(0) + if v.IsValid() != true || v.Kind() != Interface { + t.Errorf("field: IsValid=%v, Kind=%v, want true, Interface", v.IsValid(), v.Kind()) + } + v = v.Elem() + if v.IsValid() != false || v.Kind() != Invalid { + t.Errorf("field elem: IsValid=%v, Kind=%v, want false, Invalid", v.IsValid(), v.Kind()) + } +} + +// Issue 8917. +func TestLargeGCProg(t *testing.T) { + fv := ValueOf(func([256]*byte) {}) + fv.Call([]Value{ValueOf([256]*byte{})}) +} + +// Issue 9179. +func TestCallGC(t *testing.T) { + f := func(a, b, c, d, e string) { + } + g := func(in []Value) []Value { + runtime.GC() + return nil + } + typ := ValueOf(f).Type() + f2 := MakeFunc(typ, g).Interface().(func(string, string, string, string, string)) + f2("four", "five5", "six666", "seven77", "eight888") +} + +type funcLayoutTest struct { + rcvr, t Type + argsize, retOffset uintptr + stack []byte +} + +var funcLayoutTests []funcLayoutTest + +func init() { + var argAlign = PtrSize + if runtime.GOARCH == "amd64p32" { + argAlign = 2 * PtrSize + } + roundup := func(x uintptr, a uintptr) uintptr { + return (x + a - 1) / a * a + } + + funcLayoutTests = append(funcLayoutTests, + funcLayoutTest{ + nil, + ValueOf(func(a, b string) string { return "" }).Type(), + 4 * PtrSize, + 4 * PtrSize, + []byte{BitsPointer, BitsScalar, BitsPointer}, + }) + + var r []byte + if PtrSize == 4 { + r = []byte{BitsScalar, BitsScalar, BitsScalar, BitsPointer} + } else { + r = []byte{BitsScalar, BitsScalar, BitsPointer} + } + funcLayoutTests = append(funcLayoutTests, + funcLayoutTest{ + nil, + ValueOf(func(a, b, c uint32, p *byte, d uint16) {}).Type(), + roundup(3*4, PtrSize) + PtrSize + 2, + roundup(roundup(3*4, PtrSize)+PtrSize+2, argAlign), + r, + }) + + funcLayoutTests = append(funcLayoutTests, + funcLayoutTest{ + nil, + ValueOf(func(a map[int]int, b uintptr, c interface{}) {}).Type(), + 4 * PtrSize, + 4 * PtrSize, + []byte{BitsPointer, BitsScalar, BitsPointer, BitsPointer}, + }) + + type S struct { + a, b uintptr + c, d *byte + } + funcLayoutTests = append(funcLayoutTests, + funcLayoutTest{ + nil, + ValueOf(func(a S) {}).Type(), + 4 * PtrSize, + 4 * PtrSize, + []byte{BitsScalar, BitsScalar, BitsPointer, BitsPointer}, + }) + + funcLayoutTests = append(funcLayoutTests, + funcLayoutTest{ + ValueOf((*byte)(nil)).Type(), + ValueOf(func(a uintptr, b *int) {}).Type(), + 3 * PtrSize, + roundup(3*PtrSize, argAlign), + []byte{BitsPointer, BitsScalar, BitsPointer}, + }) +} + +func TestFuncLayout(t *testing.T) { + for _, lt := range funcLayoutTests { + _, argsize, retOffset, stack := FuncLayout(lt.t, lt.rcvr) + if argsize != lt.argsize { + t.Errorf("funcLayout(%v, %v).argsize=%d, want %d", lt.t, lt.rcvr, argsize, lt.argsize) + } + if retOffset != lt.retOffset { + t.Errorf("funcLayout(%v, %v).retOffset=%d, want %d", lt.t, lt.rcvr, retOffset, lt.retOffset) + } + if !bytes.Equal(stack, lt.stack) { + t.Errorf("funcLayout(%v, %v).stack=%v, want %v", lt.t, lt.rcvr, stack, lt.stack) + } + } +} |