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diff_test.go
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diff_test.go
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// Copyright 2020 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 json_test
import (
"errors"
"math"
"path"
"reflect"
"strings"
"testing"
"time"
jsonv1 "encoding/json"
jsonv2 "github.com/go-json-experiment/json"
)
// NOTE: This file serves as a list of semantic differences between v1 and v2.
// Each test explains how v1 behaves, how v2 behaves, and
// a rationale for why the behavior was changed.
var jsonPackages = []struct {
Version string
Marshal func(any) ([]byte, error)
Unmarshal func([]byte, any) error
}{
{"v1", jsonv1.Marshal, jsonv1.Unmarshal},
{"v2",
func(in any) ([]byte, error) { return jsonv2.Marshal(in) },
func(in []byte, out any) error { return jsonv2.Unmarshal(in, out) }},
}
// In v1, unmarshal matches struct fields using a case-insensitive match.
// In v2, unmarshal matches struct fields using a case-sensitive match.
//
// Case-insensitive matching is a surprising default and
// incurs significant performance cost when unmarshaling unknown fields.
// In v2, we can opt into v1-like behavior with the `nocase` tag option.
// The case-insensitive matching performed by v2 is looser than that of v1
// where it also ignores dashes and underscores.
// This allows v2 to match fields regardless of whether the name is in
// snake_case, camelCase, or kebab-case.
//
// Related issue:
//
// https://go.dev/issue/14750
func TestCaseSensitivity(t *testing.T) {
type Fields struct {
FieldA bool
FieldB bool `json:"fooBar"`
FieldC bool `json:"fizzBuzz,nocase"` // `nocase` is used by v2 to explicitly enable case-insensitive matching
}
for _, json := range jsonPackages {
t.Run(path.Join("Unmarshal", json.Version), func(t *testing.T) {
// This is a mapping from Go field names to JSON member names to
// whether the JSON member name would match the Go field name.
type goName = string
type jsonName = string
onlyV1 := json.Version == "v1"
onlyV2 := json.Version == "v2"
allMatches := map[goName]map[jsonName]bool{
"FieldA": {
"FieldA": true, // exact match
"fielda": onlyV1, // v1 is case-insensitive by default
"fieldA": onlyV1, // v1 is case-insensitive by default
"FIELDA": onlyV1, // v1 is case-insensitive by default
"FieldB": false,
"FieldC": false,
},
"FieldB": {
"fooBar": true, // exact match for explicitly specified JSON name
"FooBar": onlyV1, // v1 is case-insensitive even if an explicit JSON name is provided
"foobar": onlyV1, // v1 is case-insensitive even if an explicit JSON name is provided
"FOOBAR": onlyV1, // v1 is case-insensitive even if an explicit JSON name is provided
"fizzBuzz": false,
"FieldA": false,
"FieldB": false, // explicit JSON name means that the Go field name is not used for matching
"FieldC": false,
},
"FieldC": {
"fizzBuzz": true, // exact match for explicitly specified JSON name
"fizzbuzz": true, // v2 is case-insensitive due to `nocase` tag
"FIZZBUZZ": true, // v2 is case-insensitive due to `nocase` tag
"fizz_buzz": onlyV2, // case-insensitivity in v2 ignores dashes and underscores
"fizz-buzz": onlyV2, // case-insensitivity in v2 ignores dashes and underscores
"fooBar": false,
"FieldA": false,
"FieldC": false, // explicit JSON name means that the Go field name is not used for matching
"FieldB": false,
},
}
for goFieldName, matches := range allMatches {
for jsonMemberName, wantMatch := range matches {
in := `{"` + jsonMemberName + `":true}`
var s Fields
if err := json.Unmarshal([]byte(in), &s); err != nil {
t.Fatalf("json.Unmarshal error: %v", err)
}
gotMatch := reflect.ValueOf(s).FieldByName(goFieldName).Bool()
if gotMatch != wantMatch {
t.Fatalf("%T.%s = %v, want %v", s, goFieldName, gotMatch, wantMatch)
}
}
}
})
}
}
// In v1, the "omitempty" option specifies that a struct field is omitted
// when marshaling if it is an empty Go value, which is defined as
// false, 0, a nil pointer, a nil interface value, and
// any empty array, slice, map, or string.
//
// In v2, the "omitempty" option specifies that a struct field is omitted
// when marshaling if it is an empty JSON value, which is defined as
// a JSON null or empty JSON string, object, or array.
//
// In v2, we also provide the "omitzero" option which specifies that a field
// is omitted if it is the zero Go value or if it implements an "IsZero() bool"
// method that reports true. Together, "omitzero" and "omitempty" can cover
// all the prior use cases of the v1 definition of "omitempty".
// Note that "omitempty" is defined in terms of the Go type system in v1,
// but now defined in terms of the JSON type system in v2.
//
// Related issues:
//
// https://go.dev/issue/11939
// https://go.dev/issue/22480
// https://go.dev/issue/29310
// https://go.dev/issue/32675
// https://go.dev/issue/45669
// https://go.dev/issue/45787
// https://go.dev/issue/50480
// https://go.dev/issue/52803
func TestOmitEmptyOption(t *testing.T) {
type Struct struct {
Foo string `json:",omitempty"`
Bar []int `json:",omitempty"`
Baz *Struct `json:",omitempty"`
}
type Types struct {
Bool bool `json:",omitempty"`
StringA string `json:",omitempty"`
StringB string `json:",omitempty"`
BytesA []byte `json:",omitempty"`
BytesB []byte `json:",omitempty"`
BytesC []byte `json:",omitempty"`
Int int `json:",omitempty"`
MapA map[string]string `json:",omitempty"`
MapB map[string]string `json:",omitempty"`
MapC map[string]string `json:",omitempty"`
StructA Struct `json:",omitempty"`
StructB Struct `json:",omitempty"`
StructC Struct `json:",omitempty"`
SliceA []string `json:",omitempty"`
SliceB []string `json:",omitempty"`
SliceC []string `json:",omitempty"`
Array [1]string `json:",omitempty"`
PointerA *string `json:",omitempty"`
PointerB *string `json:",omitempty"`
PointerC *string `json:",omitempty"`
InterfaceA any `json:",omitempty"`
InterfaceB any `json:",omitempty"`
InterfaceC any `json:",omitempty"`
InterfaceD any `json:",omitempty"`
}
something := "something"
for _, json := range jsonPackages {
t.Run(path.Join("Marshal", json.Version), func(t *testing.T) {
in := Types{
Bool: false,
StringA: "",
StringB: something,
BytesA: nil,
BytesB: []byte{},
BytesC: []byte(something),
Int: 0,
MapA: nil,
MapB: map[string]string{},
MapC: map[string]string{something: something},
StructA: Struct{},
StructB: Struct{Bar: []int{}, Baz: new(Struct)},
StructC: Struct{Foo: something},
SliceA: nil,
SliceB: []string{},
SliceC: []string{something},
Array: [1]string{something},
PointerA: nil,
PointerB: new(string),
PointerC: &something,
InterfaceA: nil,
InterfaceB: (*string)(nil),
InterfaceC: new(string),
InterfaceD: &something,
}
b, err := json.Marshal(in)
if err != nil {
t.Fatalf("json.Marshal error: %v", err)
}
var out map[string]any
if err := json.Unmarshal(b, &out); err != nil {
t.Fatalf("json.Unmarshal error: %v", err)
}
onlyV1 := json.Version == "v1"
onlyV2 := json.Version == "v2"
wantPresent := map[string]bool{
"Bool": onlyV2, // false is an empty Go bool, but is NOT an empty JSON value
"StringA": false,
"StringB": true,
"BytesA": false,
"BytesB": false,
"BytesC": true,
"Int": onlyV2, // 0 is an empty Go integer, but NOT an empty JSON value
"MapA": false,
"MapB": false,
"MapC": true,
"StructA": onlyV1, // Struct{} is NOT an empty Go value, but {} is an empty JSON value
"StructB": onlyV1, // Struct{...} is NOT an empty Go value, but {} is an empty JSON value
"StructC": true,
"SliceA": false,
"SliceB": false,
"SliceC": true,
"Array": true,
"PointerA": false,
"PointerB": onlyV1, // new(string) is NOT a nil Go pointer, but "" is an empty JSON value
"PointerC": true,
"InterfaceA": false,
"InterfaceB": onlyV1, // (*string)(nil) is NOT a nil Go interface, but null is an empty JSON value
"InterfaceC": onlyV1, // new(string) is NOT a nil Go interface, but "" is an empty JSON value
"InterfaceD": true,
}
for field, want := range wantPresent {
_, got := out[field]
if got != want {
t.Fatalf("%T.%s = %v, want %v", in, field, got, want)
}
}
})
}
}
func addr[T any](v T) *T {
return &v
}
// In v1, the "string" option specifies that Go bools and numeric values are
// encoded within a JSON string when marshaling and are unmarshaled from
// either the native JSON representation (i.e., a JSON bool or number) or
// its native representation escaped within a JSON string.
// The "string" option is not applied recursively, and
// so does not affect bools and numeric values within a Go slice or map, but
// does have special handling to affect the underlying value within a pointer.
// When unmarshaling, the "string" option permits decoding from a JSON null
// escaped within a JSON string in some inconsistent cases.
//
// In v2, the "string" option specifies that only numeric values are encoded as
// a JSON number within a JSON string when marshaling and are unmarshaled
// from either a JSON number or a JSON string containing a JSON number.
// The "string" option is applied recursively to all numeric sub-values,
// and thus affects numeric values within a Go slice or map.
// There is no support for escaped JSON nulls within a JSON string.
//
// The main utility for stringifying JSON primitives (i.e., bools and numbers)
// is because JSON parsers often represents numbers as IEEE 754
// floating-point numbers. This results in a loss of precision when trying to
// represent 64-bit integer values. Consequently, many JSON-based APIs actually
// requires that such values be encoded within a JSON string.
// Given the main utility of stringification is for numeric values,
// v2 limits the effect of the "string" option to just numeric Go types.
// According to all code known by the Go module proxy,
// there are close to zero usages of the "string" option with a Go bool.
//
// Regarding the recursive application of the "string" option,
// there have been a number of issues filed about users being surprised that
// the "string" option does not recursively affect numeric values
// within a composite type like a Go map, slice, or interface value.
// In v1, specifying the "string" option on composite type has no effect
// and so this would be a largely backwards compatible change.
//
// The ability to decode from a JSON null wrapped within a JSON string
// is removed in v2 because this behavior was surprising and inconsistent in v1.
//
// Related issues:
//
// https://go.dev/issue/15624
// https://go.dev/issue/20651
// https://go.dev/issue/22177
// https://go.dev/issue/32055
// https://go.dev/issue/32117
// https://go.dev/issue/50997
func TestStringOption(t *testing.T) {
type Types struct {
Bool bool `json:",string"`
Int int `json:",string"`
Float float64 `json:",string"`
Map map[string]int `json:",string"`
Struct struct{ Field int } `json:",string"`
Slice []int `json:",string"`
Array [1]int `json:",string"`
PointerA *int `json:",string"`
PointerB *int `json:",string"`
PointerC **int `json:",string"`
InterfaceA any `json:",string"`
InterfaceB any `json:",string"`
}
for _, json := range jsonPackages {
t.Run(path.Join("Marshal", json.Version), func(t *testing.T) {
in := Types{
Bool: true,
Int: 1,
Float: 1,
Map: map[string]int{"Name": 1},
Struct: struct{ Field int }{1},
Slice: []int{1},
Array: [1]int{1},
PointerA: nil,
PointerB: addr(1),
PointerC: addr(addr(1)),
InterfaceA: nil,
InterfaceB: 1,
}
quote := func(s string) string { return `"` + s + `"` }
quoteOnlyV1 := func(s string) string {
if json.Version == "v1" {
s = quote(s)
}
return s
}
quoteOnlyV2 := func(s string) string {
if json.Version == "v2" {
s = quote(s)
}
return s
}
want := strings.Join([]string{
`{`,
`"Bool":` + quoteOnlyV1("true") + `,`, // in v1, Go bool are also stringified
`"Int":` + quote("1") + `,`,
`"Float":` + quote("1") + `,`,
`"Map":{"Name":` + quoteOnlyV2("1") + `},`, // in v2, numbers are recursively stringified
`"Struct":{"Field":` + quoteOnlyV2("1") + `},`, // in v2, numbers are recursively stringified
`"Slice":[` + quoteOnlyV2("1") + `],`, // in v2, numbers are recursively stringified
`"Array":[` + quoteOnlyV2("1") + `],`, // in v2, numbers are recursively stringified
`"PointerA":null,`,
`"PointerB":` + quote("1") + `,`, // in v1, numbers are stringified after a single pointer indirection
`"PointerC":` + quoteOnlyV2("1") + `,`, // in v2, numbers are recursively stringified
`"InterfaceA":null,`,
`"InterfaceB":` + quoteOnlyV2("1") + ``, // in v2, numbers are recursively stringified
`}`}, "")
got, err := json.Marshal(in)
if err != nil {
t.Fatalf("json.Marshal error: %v", err)
}
if string(got) != want {
t.Fatalf("json.Marshal = %s, want %s", got, want)
}
})
}
for _, json := range jsonPackages {
t.Run(path.Join("Unmarshal/Null", json.Version), func(t *testing.T) {
var got Types
err := json.Unmarshal([]byte(`{
"Bool": "null",
"Int": "null",
"PointerA": "null"
}`), &got)
switch {
case !reflect.DeepEqual(got, Types{}):
t.Fatalf("json.Unmarshal = %v, want %v", got, Types{})
case json.Version == "v1" && err != nil:
t.Fatalf("json.Unmarshal error: %v", err)
case json.Version == "v2" && err == nil:
t.Fatal("json.Unmarshal error is nil, want non-nil")
}
})
t.Run(path.Join("Unmarshal/Bool", json.Version), func(t *testing.T) {
var got Types
want := map[string]Types{
"v1": {Bool: true},
"v2": {Bool: false},
}[json.Version]
err := json.Unmarshal([]byte(`{"Bool": "true"}`), &got)
switch {
case !reflect.DeepEqual(got, want):
t.Fatalf("json.Unmarshal = %v, want %v", got, want)
case json.Version == "v1" && err != nil:
t.Fatalf("json.Unmarshal error: %v", err)
case json.Version == "v2" && err == nil:
t.Fatal("json.Unmarshal error is nil, want non-nil")
}
})
t.Run(path.Join("Unmarshal/Shallow", json.Version), func(t *testing.T) {
var got Types
want := Types{Int: 1, PointerB: addr(1)}
err := json.Unmarshal([]byte(`{
"Int": "1",
"PointerB": "1"
}`), &got)
switch {
case !reflect.DeepEqual(got, want):
t.Fatalf("json.Unmarshal = %v, want %v", got, want)
case err != nil:
t.Fatalf("json.Unmarshal error: %v", err)
}
})
t.Run(path.Join("Unmarshal/Deep", json.Version), func(t *testing.T) {
var got Types
want := map[string]Types{
"v1": {
Map: map[string]int{"Name": 0},
Slice: []int{0},
PointerC: addr(addr(0)),
},
"v2": {
Map: map[string]int{"Name": 1},
Struct: struct{ Field int }{1},
Slice: []int{1},
Array: [1]int{1},
PointerC: addr(addr(1)),
},
}[json.Version]
err := json.Unmarshal([]byte(`{
"Map": {"Name":"1"},
"Struct": {"Field":"1"},
"Slice": ["1"],
"Array": ["1"],
"PointerC": "1"
}`), &got)
switch {
case !reflect.DeepEqual(got, want):
t.Fatalf("json.Unmarshal =\n%v, want\n%v", got, want)
case json.Version == "v1" && err == nil:
t.Fatal("json.Unmarshal error is nil, want non-nil")
case json.Version == "v2" && err != nil:
t.Fatalf("json.Unmarshal error: %v", err)
}
})
}
}
// In v1, nil slices and maps are marshaled as a JSON null.
// In v2, nil slices and maps are marshaled as an empty JSON object or array.
//
// Users of v2 can opt into the v1 behavior by setting
// the "format:emitnull" option in the `json` struct field tag:
//
// struct {
// S []string `json:",format:emitnull"`
// M map[string]string `json:",format:emitnull"`
// }
//
// JSON is a language-agnostic data interchange format.
// The fact that maps and slices are nil-able in Go is a semantic detail of the
// Go language. We should avoid leaking such details to the JSON representation.
// When JSON implementations leak language-specific details,
// it complicates transition to/from languages with different type systems.
//
// Furthermore, consider two related Go types: string and []byte.
// It's an asymmetric oddity of v1 that zero values of string and []byte marshal
// as an empty JSON string for the former, while the latter as a JSON null.
// The non-zero values of those types always marshal as JSON strings.
//
// Related issues:
//
// https://go.dev/issue/27589
// https://go.dev/issue/37711
func TestNilSlicesAndMaps(t *testing.T) {
type Composites struct {
B []byte // always encoded in v2 as a JSON string
S []string // always encoded in v2 as a JSON array
M map[string]string // always encoded in v2 as a JSON object
}
for _, json := range jsonPackages {
t.Run(path.Join("Marshal", json.Version), func(t *testing.T) {
in := []Composites{
{B: []byte(nil), S: []string(nil), M: map[string]string(nil)},
{B: []byte{}, S: []string{}, M: map[string]string{}},
}
want := map[string]string{
"v1": `[{"B":null,"S":null,"M":null},{"B":"","S":[],"M":{}}]`,
"v2": `[{"B":"","S":[],"M":{}},{"B":"","S":[],"M":{}}]`, // v2 emits nil slices and maps as empty JSON objects and arrays
}[json.Version]
got, err := json.Marshal(in)
if err != nil {
t.Fatalf("json.Marshal error: %v", err)
}
if string(got) != want {
t.Fatalf("json.Marshal = %s, want %s", got, want)
}
})
}
}
// In v1, unmarshaling into a Go array permits JSON arrays with any length.
// In v2, unmarshaling into a Go array requires that the JSON array
// have the exact same number of elements as the Go array.
//
// Go arrays are often used because the exact length has significant meaning.
// Ignoring this detail seems like a mistake. Also, the v1 behavior leads to
// silent data loss when excess JSON array elements are discarded.
func TestArrays(t *testing.T) {
for _, json := range jsonPackages {
t.Run(path.Join("Unmarshal/TooFew", json.Version), func(t *testing.T) {
var got [2]int
err := json.Unmarshal([]byte(`[1]`), &got)
switch {
case got != [2]int{1, 0}:
t.Fatalf(`json.Unmarshal = %v, want [1 0]`, got)
case json.Version == "v1" && err != nil:
t.Fatalf("json.Unmarshal error: %v", err)
case json.Version == "v2" && err == nil:
t.Fatal("json.Unmarshal error is nil, want non-nil")
}
})
}
for _, json := range jsonPackages {
t.Run(path.Join("Unmarshal/TooMany", json.Version), func(t *testing.T) {
var got [2]int
err := json.Unmarshal([]byte(`[1,2,3]`), &got)
switch {
case got != [2]int{1, 2}:
t.Fatalf(`json.Unmarshal = %v, want [1 2]`, got)
case json.Version == "v1" && err != nil:
t.Fatalf("json.Unmarshal error: %v", err)
case json.Version == "v2" && err == nil:
t.Fatal("json.Unmarshal error is nil, want non-nil")
}
})
}
}
// In v1, byte arrays are treated as arrays of unsigned integers.
// In v2, byte arrays are treated as binary values (similar to []byte).
// This is to make the behavior of [N]byte and []byte more consistent.
//
// Users of v2 can opt into the v1 behavior by setting
// the "format:array" option in the `json` struct field tag:
//
// struct {
// B [32]byte `json:",format:array"`
// }
func TestByteArrays(t *testing.T) {
for _, json := range jsonPackages {
t.Run(path.Join("Marshal", json.Version), func(t *testing.T) {
in := [4]byte{1, 2, 3, 4}
got, err := json.Marshal(in)
if err != nil {
t.Fatalf("json.Marshal error: %v", err)
}
want := map[string]string{
"v1": `[1,2,3,4]`,
"v2": `"AQIDBA=="`,
}[json.Version]
if string(got) != want {
t.Fatalf("json.Marshal = %s, want %s", got, want)
}
})
}
for _, json := range jsonPackages {
t.Run(path.Join("Unmarshal", json.Version), func(t *testing.T) {
in := map[string]string{
"v1": `[1,2,3,4]`,
"v2": `"AQIDBA=="`,
}[json.Version]
var got [4]byte
err := json.Unmarshal([]byte(in), &got)
switch {
case err != nil:
t.Fatalf("json.Unmarshal error: %v", err)
case got != [4]byte{1, 2, 3, 4}:
t.Fatalf("json.Unmarshal = %v, want [1 2 3 4]", got)
}
})
}
}
// CallCheck implements json.{Marshaler,Unmarshaler} on a pointer receiver.
type CallCheck string
// MarshalJSON always returns a JSON string with the literal "CALLED".
func (*CallCheck) MarshalJSON() ([]byte, error) {
return []byte(`"CALLED"`), nil
}
// UnmarshalJSON always stores a string with the literal "CALLED".
func (v *CallCheck) UnmarshalJSON([]byte) error {
*v = `CALLED`
return nil
}
// In v1, the implementation is inconsistent about whether it calls
// MarshalJSON and UnmarshalJSON methods declared on pointer receivers
// when it has an unaddressable value (per reflect.Value.CanAddr) on hand.
// When marshaling, it never boxes the value on the heap to make it addressable,
// while it sometimes boxes values (e.g., for map entries) when unmarshaling.
//
// In v2, the implementation always calls MarshalJSON and UnmarshalJSON methods
// by boxing the value on the heap if necessary.
//
// The v1 behavior is surprising at best and buggy at worst.
// Unfortunately, it cannot be changed without breaking existing usages.
//
// Related issues:
//
// https://go.dev/issue/27722
// https://go.dev/issue/33993
// https://go.dev/issue/42508
func TestPointerReceiver(t *testing.T) {
type Values struct {
S []CallCheck
A [1]CallCheck
M map[string]CallCheck
V CallCheck
I any
}
for _, json := range jsonPackages {
t.Run(path.Join("Marshal", json.Version), func(t *testing.T) {
var cc CallCheck
in := Values{
S: []CallCheck{cc},
A: [1]CallCheck{cc}, // MarshalJSON not called on v1
M: map[string]CallCheck{"": cc}, // MarshalJSON not called on v1
V: cc, // MarshalJSON not called on v1
I: cc, // MarshalJSON not called on v1
}
want := map[string]string{
"v1": `{"S":["CALLED"],"A":[""],"M":{"":""},"V":"","I":""}`,
"v2": `{"S":["CALLED"],"A":["CALLED"],"M":{"":"CALLED"},"V":"CALLED","I":"CALLED"}`,
}[json.Version]
got, err := json.Marshal(in)
if err != nil {
t.Fatalf("json.Marshal error: %v", err)
}
if string(got) != want {
t.Fatalf("json.Marshal = %s, want %s", got, want)
}
})
}
for _, json := range jsonPackages {
t.Run(path.Join("Unmarshal", json.Version), func(t *testing.T) {
in := `{"S":[""],"A":[""],"M":{"":""},"V":"","I":""}`
called := CallCheck("CALLED") // resulting state if UnmarshalJSON is called
want := map[string]Values{
"v1": {
S: []CallCheck{called},
A: [1]CallCheck{called},
M: map[string]CallCheck{"": called},
V: called,
I: "", // UnmarshalJSON not called on v1; replaced with Go string
},
"v2": {
S: []CallCheck{called},
A: [1]CallCheck{called},
M: map[string]CallCheck{"": called},
V: called,
I: called,
},
}[json.Version]
got := Values{
A: [1]CallCheck{CallCheck("")},
S: []CallCheck{CallCheck("")},
M: map[string]CallCheck{"": CallCheck("")},
V: CallCheck(""),
I: CallCheck(""),
}
if err := json.Unmarshal([]byte(in), &got); err != nil {
t.Fatalf("json.Unmarshal error: %v", err)
}
if !reflect.DeepEqual(got, want) {
t.Fatalf("json.Unmarshal = %v, want %v", got, want)
}
})
}
}
// In v1, maps are marshaled in a deterministic order.
// In v2, maps are marshaled in a non-deterministic order.
//
// The reason for the change is that v2 prioritizes performance and
// the guarantee that marshaling operates primarily in a streaming manner.
//
// The v2 API provides jsontext.Value.Canonicalize if stability is needed:
//
// (*jsontext.Value)(&b).Canonicalize()
//
// Related issue:
//
// https://go.dev/issue/7872
// https://go.dev/issue/33714
func TestMapDeterminism(t *testing.T) {
const iterations = 10
in := map[int]int{0: 0, 1: 1, 2: 2, 3: 3, 4: 4, 5: 5, 6: 6, 7: 7, 8: 8, 9: 9}
for _, json := range jsonPackages {
t.Run(path.Join("Marshal", json.Version), func(t *testing.T) {
outs := make(map[string]bool)
for range iterations {
b, err := json.Marshal(in)
if err != nil {
t.Fatalf("json.Marshal error: %v", err)
}
outs[string(b)] = true
}
switch {
case json.Version == "v1" && len(outs) != 1:
t.Fatalf("json.Marshal encoded to %d unique forms, expected 1", len(outs))
case json.Version == "v2" && len(outs) == 1:
t.Logf("json.Marshal encoded to 1 unique form by chance; are you feeling lucky?")
}
})
}
}
// In v1, JSON string encoding escapes special characters related to HTML.
// In v2, JSON string encoding uses a normalized representation (per RFC 8785).
//
// Users of v2 can opt into the v1 behavior by setting EscapeForHTML and EscapeForJS.
//
// Escaping HTML-specific characters in a JSON library is a layering violation.
// It presumes that JSON is always used with HTML and ignores other
// similar classes of injection attacks (e.g., SQL injection).
// Users of JSON with HTML should either manually ensure that embedded JSON is
// properly escaped or be relying on a module like "github.com/google/safehtml"
// to handle safe interoperability of JSON and HTML.
func TestEscapeHTML(t *testing.T) {
for _, json := range jsonPackages {
t.Run(path.Join("Marshal", json.Version), func(t *testing.T) {
const in = `<script> console.log("Hello, world!"); </script>`
got, err := json.Marshal(in)
if err != nil {
t.Fatalf("json.Marshal error: %v", err)
}
want := map[string]string{
"v1": `"\u003cscript\u003e console.log(\"Hello, world!\"); \u003c/script\u003e"`,
"v2": `"<script> console.log(\"Hello, world!\"); </script>"`,
}[json.Version]
if string(got) != want {
t.Fatalf("json.Marshal = %s, want %s", got, want)
}
})
}
}
// In v1, JSON serialization silently ignored invalid UTF-8 by
// replacing such bytes with the Unicode replacement character.
// In v2, JSON serialization reports an error if invalid UTF-8 is encountered.
//
// Users of v2 can opt into the v1 behavior by setting [AllowInvalidUTF8].
//
// Silently allowing invalid UTF-8 causes data corruption that can be difficult
// to detect until it is too late. Once it has been discovered, strict UTF-8
// behavior sometimes cannot be enabled since other logic may be depending
// on the current behavior due to Hyrum's Law.
//
// Tim Bray, the author of RFC 8259 recommends that implementations should
// go beyond RFC 8259 and instead target compliance with RFC 7493,
// which makes strict decisions about behavior left undefined in RFC 8259.
// In particular, RFC 7493 rejects the presence of invalid UTF-8.
// See https://www.tbray.org/ongoing/When/201x/2017/12/14/RFC-8259-STD-90
func TestInvalidUTF8(t *testing.T) {
for _, json := range jsonPackages {
t.Run(path.Join("Marshal", json.Version), func(t *testing.T) {
got, err := json.Marshal("\xff")
switch {
case json.Version == "v1" && err != nil:
t.Fatalf("json.Marshal error: %v", err)
case json.Version == "v1" && string(got) != `"\ufffd"`:
t.Fatalf(`json.Marshal = %s, want "\ufffd"`, got)
case json.Version == "v2" && err == nil:
t.Fatal("json.Marshal error is nil, want non-nil")
}
})
}
for _, json := range jsonPackages {
t.Run(path.Join("Unmarshal", json.Version), func(t *testing.T) {
const in = "\"\xff\""
var got string
err := json.Unmarshal([]byte(in), &got)
switch {
case json.Version == "v1" && err != nil:
t.Fatalf("json.Unmarshal error: %v", err)
case json.Version == "v1" && got != "\ufffd":
t.Fatalf(`json.Unmarshal = %q, want "\ufffd"`, got)
case json.Version == "v2" && err == nil:
t.Fatal("json.Unmarshal error is nil, want non-nil")
}
})
}
}
// In v1, duplicate JSON object names are permitted by default where
// they follow the inconsistent and difficult-to-explain merge semantics of v1.
// In v2, duplicate JSON object names are rejected by default where
// they follow the merge semantics of v2 based on RFC 7396.
//
// Users of v2 can opt into the v1 behavior by setting [AllowDuplicateNames].
//
// Per RFC 8259, the handling of duplicate names is left as undefined behavior.
// Rejecting such inputs is within the realm of valid behavior.
// Tim Bray, the author of RFC 8259 recommends that implementations should
// go beyond RFC 8259 and instead target compliance with RFC 7493,
// which makes strict decisions about behavior left undefined in RFC 8259.
// In particular, RFC 7493 rejects the presence of duplicate object names.
// See https://www.tbray.org/ongoing/When/201x/2017/12/14/RFC-8259-STD-90
//
// The lack of duplicate name rejection has correctness implications where
// roundtrip unmarshal/marshal do not result in semantically equivalent JSON.
// This is surprising behavior for users when they accidentally
// send JSON objects with duplicate names.
//
// The lack of duplicate name rejection may have security implications since it
// becomes difficult for a security tool to validate the semantic meaning of a
// JSON object since meaning is undefined in the presence of duplicate names.
// See https://labs.bishopfox.com/tech-blog/an-exploration-of-json-interoperability-vulnerabilities
//
// Related issue:
//
// https://go.dev/issue/48298
func TestDuplicateNames(t *testing.T) {
for _, json := range jsonPackages {
t.Run(path.Join("Unmarshal", json.Version), func(t *testing.T) {
const in = `{"Name":1,"Name":2}`
var got struct{ Name int }
err := json.Unmarshal([]byte(in), &got)
switch {
case json.Version == "v1" && err != nil:
t.Fatalf("json.Unmarshal error: %v", err)
case json.Version == "v1" && got != struct{ Name int }{2}:
t.Fatalf(`json.Unmarshal = %v, want {2}`, got)
case json.Version == "v2" && err == nil:
t.Fatal("json.Unmarshal error is nil, want non-nil")
}
})
}
}
// In v1, unmarshaling a JSON null into a non-empty value was inconsistent
// in that sometimes it would be ignored and other times clear the value.
// In v2, unmarshaling a JSON null into a non-empty value would consistently
// always clear the value regardless of the value's type.
//
// The purpose of this change is to have consistent behavior with how JSON nulls
// are handled during Unmarshal. This semantic detail has no effect
// when Unmarshaling into a empty value.
//
// Related issues:
//
// https://go.dev/issue/22177
// https://go.dev/issue/33835
func TestMergeNull(t *testing.T) {
type Types struct {
Bool bool
String string
Bytes []byte
Int int
Map map[string]string
Struct struct{ Field string }
Slice []string
Array [1]string
Pointer *string
Interface any
}
for _, json := range jsonPackages {
t.Run(path.Join("Unmarshal", json.Version), func(t *testing.T) {
// Start with a non-empty value where all fields are populated.
in := Types{
Bool: true,
String: "old",
Bytes: []byte("old"),
Int: 1234,
Map: map[string]string{"old": "old"},
Struct: struct{ Field string }{"old"},
Slice: []string{"old"},
Array: [1]string{"old"},
Pointer: new(string),
Interface: "old",
}
// Unmarshal a JSON null into every field.
if err := json.Unmarshal([]byte(`{
"Bool": null,
"String": null,
"Bytes": null,
"Int": null,
"Map": null,
"Struct": null,
"Slice": null,
"Array": null,
"Pointer": null,
"Interface": null
}`), &in); err != nil {
t.Fatalf("json.Unmarshal error: %v", err)
}
want := map[string]Types{
"v1": {
Bool: true,
String: "old",
Int: 1234,
Struct: struct{ Field string }{"old"},
Array: [1]string{"old"},
},
"v2": {}, // all fields are zeroed
}[json.Version]
if !reflect.DeepEqual(in, want) {
t.Fatalf("json.Unmarshal = %+v, want %+v", in, want)
}
})
}
}
// In v1, merge semantics are inconsistent and difficult to explain.
// In v2, merge semantics replaces the destination value for anything
// other than a JSON object, and recursively merges JSON objects.
//
// Merge semantics in v1 are inconsistent and difficult to explain
// largely because the behavior came about organically, rather than
// having a principled approach to how the semantics should operate.
// In v2, merging follows behavior based on RFC 7396.
//
// Related issues:
//
// https://go.dev/issue/21092
// https://go.dev/issue/26946
// https://go.dev/issue/27172
// https://go.dev/issue/30701
// https://go.dev/issue/31924
// https://go.dev/issue/43664
func TestMergeComposite(t *testing.T) {
type Tuple struct{ Old, New bool }
type Composites struct {
Slice []Tuple
Array [1]Tuple
Map map[string]Tuple
MapPointer map[string]*Tuple
Struct struct{ Tuple Tuple }
StructPointer *struct{ Tuple Tuple }
Interface any
InterfacePointer any
}
for _, json := range jsonPackages {
t.Run(path.Join("Unmarshal", json.Version), func(t *testing.T) {
// Start with a non-empty value where all fields are populated.
in := Composites{
Slice: []Tuple{{Old: true}, {Old: true}}[:1],
Array: [1]Tuple{{Old: true}},
Map: map[string]Tuple{"Tuple": {Old: true}},
MapPointer: map[string]*Tuple{"Tuple": {Old: true}},
Struct: struct{ Tuple Tuple }{Tuple{Old: true}},
StructPointer: &struct{ Tuple Tuple }{Tuple{Old: true}},
Interface: Tuple{Old: true},
InterfacePointer: &Tuple{Old: true},
}
// Unmarshal into every pre-populated field.
if err := json.Unmarshal([]byte(`{
"Slice": [{"New":true}, {"New":true}],
"Array": [{"New":true}],
"Map": {"Tuple": {"New":true}},
"MapPointer": {"Tuple": {"New":true}},
"Struct": {"Tuple": {"New":true}},
"StructPointer": {"Tuple": {"New":true}},
"Interface": {"New":true},
"InterfacePointer": {"New":true}
}`), &in); err != nil {
t.Fatalf("json.Unmarshal error: %v", err)
}
merged := Tuple{Old: true, New: true}
replaced := Tuple{Old: false, New: true}
want := map[string]Composites{
"v1": {
Slice: []Tuple{merged, merged}, // merged
Array: [1]Tuple{merged}, // merged
Map: map[string]Tuple{"Tuple": replaced}, // replaced
MapPointer: map[string]*Tuple{"Tuple": &replaced}, // replaced
Struct: struct{ Tuple Tuple }{merged}, // merged (same as v2)
StructPointer: &struct{ Tuple Tuple }{merged}, // merged (same as v2)
Interface: map[string]any{"New": true}, // replaced
InterfacePointer: &merged, // merged (same as v2)