Documentation ¶
Index ¶
- Variables
- func IsInfinity(v Value) bool
- func IsNaN(v Value) bool
- func IsNull(v Value) bool
- func IsUndefined(v Value) bool
- func Parse(name, src string, options ...parser.Option) (prg *js_ast.Program, err error)
- type ArrayBuffer
- type AsyncContextTracker
- type Callable
- type CompilerError
- type CompilerReferenceError
- type CompilerSyntaxError
- type Constructor
- type ConstructorCall
- type DynamicArray
- type DynamicObject
- type Exception
- type FieldNameMapper
- type Flag
- type FunctionCall
- type InterruptedError
- type JsonEncodable
- type Now
- type Object
- func (o *Object) ClassName() string
- func (o *Object) DefineAccessorProperty(name string, getter, setter Value, configurable, enumerable Flag) error
- func (o *Object) DefineAccessorPropertySymbol(name *Symbol, getter, setter Value, configurable, enumerable Flag) error
- func (o *Object) DefineDataProperty(name string, value Value, writable, configurable, enumerable Flag) error
- func (o *Object) DefineDataPropertySymbol(name *Symbol, value Value, writable, configurable, enumerable Flag) error
- func (o *Object) Delete(name string) error
- func (o *Object) DeleteSymbol(name *Symbol) error
- func (o *Object) Equals(other Value) bool
- func (o *Object) Export() (ret interface{})
- func (o *Object) ExportType() reflect.Type
- func (o *Object) Get(name string) Value
- func (o *Object) GetSymbol(sym *Symbol) Value
- func (o *Object) Keys() (keys []string)
- func (o *Object) MarshalJSON() ([]byte, error)
- func (o *Object) Prototype() *Object
- func (o *Object) SameAs(other Value) bool
- func (o *Object) Set(name string, value interface{}) error
- func (o *Object) SetPrototype(proto *Object) error
- func (o *Object) SetSymbol(name *Symbol, value interface{}) error
- func (o *Object) StrictEquals(other Value) bool
- func (o *Object) String() string
- func (o *Object) Symbols() []*Symbol
- func (o *Object) ToBoolean() bool
- func (o *Object) ToFloat() float64
- func (o *Object) ToInteger() int64
- func (o *Object) ToNumber() Value
- func (o *Object) ToObject(*Runtime) *Object
- func (o *Object) ToString() Value
- func (o *Object) UnmarshalJSON([]byte) error
- type Program
- type Promise
- type PromiseRejectionOperation
- type PromiseRejectionTracker
- type PromiseState
- type PropertyDescriptor
- type Proxy
- type ProxyTrapConfig
- type RandSource
- type Runtime
- func (r *Runtime) CaptureCallStack(depth int, stack []StackFrame) []StackFrame
- func (r *Runtime) ClearInterrupt()
- func (r *Runtime) CreateObject(proto *Object) *Object
- func (r *Runtime) ExportTo(v Value, target interface{}) error
- func (r *Runtime) Get(name string) (ret Value)
- func (r *Runtime) GlobalObject() *Object
- func (r *Runtime) Interrupt(v interface{})
- func (r *Runtime) New(construct Value, args ...Value) (o *Object, err error)
- func (r *Runtime) NewArray(items ...interface{}) *Object
- func (r *Runtime) NewArrayBuffer(data []byte) ArrayBuffer
- func (r *Runtime) NewDynamicArray(a DynamicArray) *Object
- func (r *Runtime) NewDynamicObject(d DynamicObject) *Object
- func (r *Runtime) NewGoError(err error) *Object
- func (r *Runtime) NewObject() (v *Object)
- func (r *Runtime) NewPromise() (promise *Promise, resolve func(result interface{}), ...)
- func (r *Runtime) NewProxy(target *Object, nativeHandler *ProxyTrapConfig) Proxy
- func (r *Runtime) NewTypeError(args ...interface{}) *Object
- func (r *Runtime) RunProgram(p *Program) (result Value, err error)
- func (r *Runtime) RunScript(name, src string) (Value, error)
- func (r *Runtime) RunString(str string) (Value, error)
- func (r *Runtime) Set(name string, value interface{}) error
- func (r *Runtime) SetAsyncContextTracker(tracker AsyncContextTracker)
- func (r *Runtime) SetFieldNameMapper(mapper FieldNameMapper)
- func (r *Runtime) SetMaxCallStackSize(size int)
- func (r *Runtime) SetParserOptions(opts ...parser.Option)
- func (r *Runtime) SetPromiseRejectionTracker(tracker PromiseRejectionTracker)
- func (r *Runtime) SetRandSource(source RandSource)
- func (r *Runtime) SetTimeSource(now Now)
- func (r *Runtime) ToValue(i interface{}) Value
- type StackFrame
- type StackOverflowError
- type Symbol
- func (s *Symbol) Equals(o Value) bool
- func (s *Symbol) Export() interface{}
- func (s *Symbol) ExportType() reflect.Type
- func (s *Symbol) SameAs(other Value) bool
- func (s *Symbol) StrictEquals(o Value) bool
- func (s *Symbol) String() string
- func (s *Symbol) ToBoolean() bool
- func (s *Symbol) ToFloat() float64
- func (s *Symbol) ToInteger() int64
- func (s *Symbol) ToNumber() Value
- func (s *Symbol) ToObject(r *Runtime) *Object
- func (s *Symbol) ToString() Value
- type Value
Examples ¶
- AssertConstructor
- AssertFunction
- NewSymbol
- Object.Delete
- Object.Export (Map)
- Object.SetSymbol
- Runtime.ExportTo (ArrayLikeToSlice)
- Runtime.ExportTo (Func)
- Runtime.ExportTo (FuncThrow)
- Runtime.ExportTo (FuncVariadic)
- Runtime.ExportTo (IterableToSlice)
- Runtime.ExportTo (MapToMap)
- Runtime.ExportTo (MapToSlice)
- Runtime.ExportTo (MapToTypedSlice)
- Runtime.ExportTo (SetToMap)
- Runtime.ExportTo (SetToSlice)
- Runtime.NewArray
- Runtime.Set (Lexical)
- Runtime.SetParserOptions
- TagFieldNameMapper
- UncapFieldNameMapper
Constants ¶
This section is empty.
Variables ¶
var ( SymHasInstance = newSymbol(asciiString("Symbol.hasInstance")) SymIsConcatSpreadable = newSymbol(asciiString("Symbol.isConcatSpreadable")) SymIterator = newSymbol(asciiString("Symbol.iterator")) SymMatch = newSymbol(asciiString("Symbol.match")) SymMatchAll = newSymbol(asciiString("Symbol.matchAll")) SymReplace = newSymbol(asciiString("Symbol.replace")) SymSearch = newSymbol(asciiString("Symbol.search")) SymSpecies = newSymbol(asciiString("Symbol.species")) SymSplit = newSymbol(asciiString("Symbol.split")) SymToPrimitive = newSymbol(asciiString("Symbol.toPrimitive")) SymToStringTag = newSymbol(asciiString("Symbol.toStringTag")) SymUnscopables = newSymbol(asciiString("Symbol.unscopables")) )
var (
InvalidRuneError = errors.New("invalid rune")
)
Functions ¶
func IsInfinity ¶
IsInfinity returns true if the supplied is (+/-)Infinity
func IsUndefined ¶
IsUndefined returns true if the supplied Value is undefined. Note, it checks against the real undefined, not against the global object's 'undefined' property.
func Parse ¶
Parse takes a source string and produces a parsed AST. Use this function if you want to pass options to the parser, e.g.:
p, err := Parse("test.js", "var a = true", parser.WithDisableSourceMaps) if err != nil { /* ... */ } prg, err := CompileAST(p, true) // ...
Otherwise use Compile which combines both steps.
Types ¶
type ArrayBuffer ¶
type ArrayBuffer struct {
// contains filtered or unexported fields
}
ArrayBuffer is a Go wrapper around ECMAScript ArrayBuffer. Calling Runtime.ToValue() on it returns the underlying ArrayBuffer. Calling Export() on an ECMAScript ArrayBuffer returns a wrapper. Use Runtime.NewArrayBuffer([]byte) to create one.
func (ArrayBuffer) Bytes ¶
func (a ArrayBuffer) Bytes() []byte
Bytes returns the underlying []byte for this ArrayBuffer. For detached ArrayBuffers returns nil.
func (ArrayBuffer) Detach ¶
func (a ArrayBuffer) Detach() bool
Detach the ArrayBuffer. After this, the underlying []byte becomes unreferenced and any attempt to use this ArrayBuffer results in a TypeError. Returns false if it was already detached, true otherwise. Note, this method may only be called from the goroutine that 'owns' the Runtime, it may not be called concurrently.
func (ArrayBuffer) Detached ¶
func (a ArrayBuffer) Detached() bool
Detached returns true if the ArrayBuffer is detached.
type AsyncContextTracker ¶
type AsyncContextTracker interface { Suspended() (trackingObject interface{}) Resumed(trackingObject interface{}) Completed() }
AsyncContextTracker is a handler that allows to track async function's execution context. Every time an async function is suspended on 'await', Suspended() is called. The trackingObject it returns is remembered and the next time just before the context is resumed, Resumed is called with the same trackingObject as argument. Completed is called when an async function returns or throws. To register it call Runtime.SetAsyncContextTracker().
type Callable ¶
Callable represents a JavaScript function that can be called from Go.
func AssertFunction ¶
AssertFunction checks if the Value is a function and returns a Callable. Note, for classes this returns a callable and a 'true', however calling it will always result in a TypeError. For classes use AssertConstructor().
Example ¶
vm := New() _, err := vm.RunString(` function sum(a, b) { return a+b; } `) if err != nil { panic(err) } sum, ok := AssertFunction(vm.Get("sum")) if !ok { panic("Not a function") } res, err := sum(Undefined(), vm.ToValue(40), vm.ToValue(2)) if err != nil { panic(err) } fmt.Println(res)
Output: 42
type CompilerReferenceError ¶
type CompilerReferenceError struct {
CompilerError
}
func (*CompilerReferenceError) Error ¶
func (e *CompilerReferenceError) Error() string
type CompilerSyntaxError ¶
type CompilerSyntaxError struct {
CompilerError
}
func (*CompilerSyntaxError) Error ¶
func (e *CompilerSyntaxError) Error() string
type Constructor ¶
Constructor is a type that can be used to call constructors. The first argument (newTarget) can be nil which sets it to the constructor function itself.
func AssertConstructor ¶
func AssertConstructor(v Value) (Constructor, bool)
AssertConstructor checks if the Value is a constructor and returns a Constructor.
Example ¶
vm := New() res, err := vm.RunString(` (class C { constructor(x) { this.x = x; } }) `) if err != nil { panic(err) } if ctor, ok := AssertConstructor(res); ok { obj, err := ctor(nil, vm.ToValue("Test")) if err != nil { panic(err) } fmt.Print(obj.Get("x")) } else { panic("Not a constructor") }
Output: Test
type ConstructorCall ¶
func (ConstructorCall) Argument ¶
func (f ConstructorCall) Argument(idx int) Value
type DynamicArray ¶
type DynamicArray interface { // Len returns the current array length. Len() int // Get an item at index idx. Note that idx may be any integer, negative or beyond the current length. Get(idx int) Value // Set an item at index idx. Note that idx may be any integer, negative or beyond the current length. // The expected behaviour when it's beyond length is that the array's length is increased to accommodate // the item. All elements in the 'new' section of the array should be zeroed. Set(idx int, val Value) bool // SetLen is called when the array's 'length' property is changed. If the length is increased all elements in the // 'new' section of the array should be zeroed. SetLen(int) bool }
DynamicArray is an interface representing a handler for a dynamic array Object. Such an object can be created using the Runtime.NewDynamicArray() method.
Any integer property key or a string property key that can be parsed into an int value (including negative ones) is treated as an index and passed to the trap methods of the DynamicArray. Note this is different from the regular ECMAScript arrays which only support positive indexes up to 2^32-1.
DynamicArray cannot be sparse, i.e. hasOwnProperty(num) will return true for num >= 0 && num < Len(). Deleting such a property is equivalent to setting it to undefined. Note that this creates a slight peculiarity because hasOwnProperty() will still return true, even after deletion.
Note that Runtime.ToValue() does not have any special treatment for DynamicArray. The only way to create a dynamic array is by using the Runtime.NewDynamicArray() method. This is done deliberately to avoid silent code breaks when this interface changes.
type DynamicObject ¶
type DynamicObject interface { // Get a property value for the key. May return nil if the property does not exist. Get(key string) Value // Set a property value for the key. Return true if success, false otherwise. Set(key string, val Value) bool // Has should return true if and only if the property exists. Has(key string) bool // Delete the property for the key. Returns true on success (note, that includes missing property). Delete(key string) bool // Keys returns a list of all existing property keys. There are no checks for duplicates or to make sure // that the order conforms to https://262.ecma-international.org/#sec-ordinaryownpropertykeys Keys() []string }
DynamicObject is an interface representing a handler for a dynamic Object. Such an object can be created using the Runtime.NewDynamicObject() method.
Note that Runtime.ToValue() does not have any special treatment for DynamicObject. The only way to create a dynamic object is by using the Runtime.NewDynamicObject() method. This is done deliberately to avoid silent code breaks when this interface changes.
type FieldNameMapper ¶
type FieldNameMapper interface { // FieldName returns a JavaScript name for the given struct field in the given type. // If this method returns "" the field becomes hidden. FieldName(t reflect.Type, f reflect.StructField) string // MethodName returns a JavaScript name for the given method in the given type. // If this method returns "" the method becomes hidden. MethodName(t reflect.Type, m reflect.Method) string }
FieldNameMapper provides custom mapping between Go and JavaScript property names.
func TagFieldNameMapper ¶
func TagFieldNameMapper(tagName string, uncapMethods bool) FieldNameMapper
TagFieldNameMapper returns a FieldNameMapper that uses the given tagName for struct fields and optionally uncapitalises (making the first letter lower case) method names. The common tag value syntax is supported (name[,options]), however options are ignored. Setting name to anything other than a valid ECMAScript identifier makes the field hidden.
Example ¶
vm := New() vm.SetFieldNameMapper(TagFieldNameMapper("json", true)) type S struct { Field int `json:"field"` } vm.Set("s", S{Field: 42}) res, _ := vm.RunString(`s.field`) fmt.Println(res.Export())
Output: 42
func UncapFieldNameMapper ¶
func UncapFieldNameMapper() FieldNameMapper
UncapFieldNameMapper returns a FieldNameMapper that uncapitalises struct field and method names making the first letter lower case.
Example ¶
vm := New() s := testGoReflectMethod_O{ Test: "passed", } vm.SetFieldNameMapper(UncapFieldNameMapper()) vm.Set("s", s) res, _ := vm.RunString(`s.test + " and " + s.method("passed too")`) fmt.Println(res.Export())
Output: passed and passed too
type FunctionCall ¶
func (FunctionCall) Argument ¶
func (f FunctionCall) Argument(idx int) Value
type InterruptedError ¶
type InterruptedError struct {
// contains filtered or unexported fields
}
func (*InterruptedError) Error ¶
func (e *InterruptedError) Error() string
func (*InterruptedError) String ¶
func (e *InterruptedError) String() string
func (*InterruptedError) Unwrap ¶
func (e *InterruptedError) Unwrap() error
func (*InterruptedError) Value ¶
func (e *InterruptedError) Value() interface{}
type JsonEncodable ¶
type JsonEncodable interface {
JsonEncodable() interface{}
}
JsonEncodable allows custom JSON encoding by JSON.stringify() Note that if the returned value itself also implements JsonEncodable, it won't have any effect.
type Object ¶
type Object struct {
// contains filtered or unexported fields
}
func NewSharedDynamicArray ¶
func NewSharedDynamicArray(a DynamicArray) *Object
NewSharedDynamicArray is similar to Runtime.NewDynamicArray but the resulting Object can be shared across multiple Runtimes. The Object's prototype will be null. If you need to run Array's methods on it, use Array.prototype.[...].call(a, ...). The provided DynamicArray must be goroutine-safe.
func NewSharedDynamicObject ¶
func NewSharedDynamicObject(d DynamicObject) *Object
NewSharedDynamicObject is similar to Runtime.NewDynamicObject but the resulting Object can be shared across multiple Runtimes. The Object's prototype will be null. The provided DynamicObject must be goroutine-safe.
func (*Object) DefineAccessorProperty ¶
func (o *Object) DefineAccessorProperty(name string, getter, setter Value, configurable, enumerable Flag) error
DefineAccessorProperty is a Go equivalent of Object.defineProperty(o, name, {get: getter, set: setter, configurable: configurable, enumerable: enumerable})
func (*Object) DefineAccessorPropertySymbol ¶
func (o *Object) DefineAccessorPropertySymbol(name *Symbol, getter, setter Value, configurable, enumerable Flag) error
DefineAccessorPropertySymbol is a Go equivalent of Object.defineProperty(o, name, {get: getter, set: setter, configurable: configurable, enumerable: enumerable})
func (*Object) DefineDataProperty ¶
func (o *Object) DefineDataProperty(name string, value Value, writable, configurable, enumerable Flag) error
DefineDataProperty is a Go equivalent of Object.defineProperty(o, name, {value: value, writable: writable, configurable: configurable, enumerable: enumerable})
func (*Object) DefineDataPropertySymbol ¶
func (o *Object) DefineDataPropertySymbol(name *Symbol, value Value, writable, configurable, enumerable Flag) error
DefineDataPropertySymbol is a Go equivalent of Object.defineProperty(o, name, {value: value, writable: writable, configurable: configurable, enumerable: enumerable})
func (*Object) Delete ¶
Example ¶
vm := New() obj := vm.NewObject() _ = obj.Set("test", true) before := obj.Get("test") _ = obj.Delete("test") after := obj.Get("test") fmt.Printf("before: %v, after: %v", before, after)
Output: before: true, after: <nil>
func (*Object) DeleteSymbol ¶
func (*Object) Export ¶
func (o *Object) Export() (ret interface{})
Export the Object to a plain Go type. If the Object is a wrapped Go value (created using ToValue()) returns the original value.
If the Object is a function, returns func(FunctionCall) Value. Note that exceptions thrown inside the function result in panics, which can also leave the Runtime in an unusable state. Therefore, these values should only be used inside another ES function implemented in Go. For calling a function from Go, use AssertFunction() or Runtime.ExportTo() as described in the README.
For a Map, returns the list of entries as [][2]interface{}.
For a Set, returns the list of elements as []interface{}.
For a Proxy, returns Proxy.
For a Promise, returns Promise.
For a DynamicObject or a DynamicArray, returns the underlying handler.
For an array, returns its items as []interface{}.
In all other cases returns own enumerable non-symbol properties as map[string]interface{}.
This method will panic with an *Exception if a JavaScript exception is thrown in the process.
Example (Map) ¶
vm := New() m, err := vm.RunString(` new Map([[1, true], [2, false]]); `) if err != nil { panic(err) } exp := m.Export() fmt.Printf("%T, %v\n", exp, exp)
Output: [][2]interface {}, [[1 true] [2 false]]
func (*Object) ExportType ¶
ExportType returns the type of the value that is returned by Export().
func (*Object) Get ¶
Get an object's property by name. This method will panic with an *Exception if a JavaScript exception is thrown in the process.
func (*Object) GetSymbol ¶
GetSymbol returns the value of a symbol property. Use one of the Sym* values for well-known symbols (such as SymIterator, SymToStringTag, etc...). This method will panic with an *Exception if a JavaScript exception is thrown in the process.
func (*Object) Keys ¶
Keys returns a list of Object's enumerable keys. This method will panic with an *Exception if a JavaScript exception is thrown in the process.
func (*Object) MarshalJSON ¶
MarshalJSON returns JSON representation of the Object. It is equivalent to JSON.stringify(o). Note, this implements json.Marshaler so that json.Marshal() can be used without the need to Export().
func (*Object) Prototype ¶
Prototype returns the Object's prototype, same as Object.getPrototypeOf(). If the prototype is null returns nil.
func (*Object) SetPrototype ¶
SetPrototype sets the Object's prototype, same as Object.setPrototypeOf(). Setting proto to nil is an equivalent of Object.setPrototypeOf(null).
func (*Object) SetSymbol ¶
Example ¶
type IterResult struct { Done bool Value Value } vm := New() vm.SetFieldNameMapper(UncapFieldNameMapper()) // to use IterResult o := vm.NewObject() o.SetSymbol(SymIterator, func() *Object { count := 0 iter := vm.NewObject() iter.Set("next", func() IterResult { if count < 10 { count++ return IterResult{ Value: vm.ToValue(count), } } return IterResult{ Done: true, } }) return iter }) vm.Set("o", o) res, err := vm.RunString(` var acc = ""; for (var v of o) { acc += v + " "; } acc; `) if err != nil { panic(err) } fmt.Println(res)
Output: 1 2 3 4 5 6 7 8 9 10
func (*Object) StrictEquals ¶
func (*Object) Symbols ¶
Symbols returns a list of Object's enumerable symbol properties. This method will panic with an *Exception if a JavaScript exception is thrown in the process.
func (*Object) UnmarshalJSON ¶
UnmarshalJSON implements the json.Unmarshaler interface. It is added to compliment MarshalJSON, because some alternative JSON encoders refuse to use MarshalJSON unless UnmarshalJSON is also present. It is a no-op and always returns nil.
type Program ¶
type Program struct {
// contains filtered or unexported fields
}
func Compile ¶
Compile creates an internal representation of the JavaScript code that can be later run using the Runtime.RunProgram() method. This representation is not linked to a runtime in any way and can be run in multiple runtimes (possibly at the same time).
func CompileAST ¶
CompileAST creates an internal representation of the JavaScript code that can be later run using the Runtime.RunProgram() method. This representation is not linked to a runtime in any way and can be run in multiple runtimes (possibly at the same time).
func MustCompile ¶
MustCompile is like Compile but panics if the code cannot be compiled. It simplifies safe initialization of global variables holding compiled JavaScript code.
type Promise ¶
type Promise struct {
// contains filtered or unexported fields
}
Promise is a Go wrapper around ECMAScript Promise. Calling Runtime.ToValue() on it returns the underlying Object. Calling Export() on a Promise Object returns a Promise.
Use Runtime.NewPromise() to create one. Calling Runtime.ToValue() on a zero object or nil returns null Value.
WARNING: Instances of Promise are not goroutine-safe. See Runtime.NewPromise() for more details.
func (*Promise) State ¶
func (p *Promise) State() PromiseState
type PromiseRejectionOperation ¶
type PromiseRejectionOperation int
const ( PromiseRejectionReject PromiseRejectionOperation = iota PromiseRejectionHandle )
type PromiseRejectionTracker ¶
type PromiseRejectionTracker func(p *Promise, operation PromiseRejectionOperation)
type PromiseState ¶
type PromiseState int
const ( PromiseStatePending PromiseState = iota PromiseStateFulfilled PromiseStateRejected )
type PropertyDescriptor ¶
type PropertyDescriptor struct { Value Value Writable, Configurable, Enumerable Flag Getter, Setter Value // contains filtered or unexported fields }
func (*PropertyDescriptor) Empty ¶
func (p *PropertyDescriptor) Empty() bool
func (*PropertyDescriptor) IsAccessor ¶
func (p *PropertyDescriptor) IsAccessor() bool
func (*PropertyDescriptor) IsData ¶
func (p *PropertyDescriptor) IsData() bool
func (*PropertyDescriptor) IsGeneric ¶
func (p *PropertyDescriptor) IsGeneric() bool
type Proxy ¶
type Proxy struct {
// contains filtered or unexported fields
}
Proxy is a Go wrapper around ECMAScript Proxy. Calling Runtime.ToValue() on it returns the underlying Proxy. Calling Export() on an ECMAScript Proxy returns a wrapper. Use Runtime.NewProxy() to create one.
type ProxyTrapConfig ¶
type ProxyTrapConfig struct { // A trap for Object.getPrototypeOf, Reflect.getPrototypeOf, __proto__, Object.prototype.isPrototypeOf, instanceof GetPrototypeOf func(target *Object) (prototype *Object) // A trap for Object.setPrototypeOf, Reflect.setPrototypeOf SetPrototypeOf func(target *Object, prototype *Object) (success bool) // A trap for Object.isExtensible, Reflect.isExtensible IsExtensible func(target *Object) (success bool) // A trap for Object.preventExtensions, Reflect.preventExtensions PreventExtensions func(target *Object) (success bool) // A trap for Object.getOwnPropertyDescriptor, Reflect.getOwnPropertyDescriptor (string properties) GetOwnPropertyDescriptor func(target *Object, prop string) (propertyDescriptor PropertyDescriptor) // A trap for Object.getOwnPropertyDescriptor, Reflect.getOwnPropertyDescriptor (integer properties) GetOwnPropertyDescriptorIdx func(target *Object, prop int) (propertyDescriptor PropertyDescriptor) // A trap for Object.getOwnPropertyDescriptor, Reflect.getOwnPropertyDescriptor (Symbol properties) GetOwnPropertyDescriptorSym func(target *Object, prop *Symbol) (propertyDescriptor PropertyDescriptor) // A trap for Object.defineProperty, Reflect.defineProperty (string properties) DefineProperty func(target *Object, key string, propertyDescriptor PropertyDescriptor) (success bool) // A trap for Object.defineProperty, Reflect.defineProperty (integer properties) DefinePropertyIdx func(target *Object, key int, propertyDescriptor PropertyDescriptor) (success bool) // A trap for Object.defineProperty, Reflect.defineProperty (Symbol properties) DefinePropertySym func(target *Object, key *Symbol, propertyDescriptor PropertyDescriptor) (success bool) // A trap for the in operator, with operator, Reflect.has (string properties) Has func(target *Object, property string) (available bool) // A trap for the in operator, with operator, Reflect.has (integer properties) HasIdx func(target *Object, property int) (available bool) // A trap for the in operator, with operator, Reflect.has (Symbol properties) HasSym func(target *Object, property *Symbol) (available bool) // A trap for getting property values, Reflect.get (string properties) Get func(target *Object, property string, receiver Value) (value Value) // A trap for getting property values, Reflect.get (integer properties) GetIdx func(target *Object, property int, receiver Value) (value Value) // A trap for getting property values, Reflect.get (Symbol properties) GetSym func(target *Object, property *Symbol, receiver Value) (value Value) // A trap for setting property values, Reflect.set (string properties) Set func(target *Object, property string, value Value, receiver Value) (success bool) // A trap for setting property values, Reflect.set (integer properties) SetIdx func(target *Object, property int, value Value, receiver Value) (success bool) // A trap for setting property values, Reflect.set (Symbol properties) SetSym func(target *Object, property *Symbol, value Value, receiver Value) (success bool) // A trap for the delete operator, Reflect.deleteProperty (string properties) DeleteProperty func(target *Object, property string) (success bool) // A trap for the delete operator, Reflect.deleteProperty (integer properties) DeletePropertyIdx func(target *Object, property int) (success bool) // A trap for the delete operator, Reflect.deleteProperty (Symbol properties) DeletePropertySym func(target *Object, property *Symbol) (success bool) // A trap for Object.getOwnPropertyNames, Object.getOwnPropertySymbols, Object.keys, Reflect.ownKeys OwnKeys func(target *Object) (object *Object) // A trap for a function call, Function.prototype.apply, Function.prototype.call, Reflect.apply Apply func(target *Object, this Value, argumentsList []Value) (value Value) // A trap for the new operator, Reflect.construct Construct func(target *Object, argumentsList []Value, newTarget *Object) (value *Object) }
ProxyTrapConfig provides a simplified Go-friendly API for implementing Proxy traps. If an *Idx trap is defined it gets called for integer property keys, including negative ones. Note that this only includes string property keys that represent a canonical integer (i.e. "0", "123", but not "00", "01", " 1" or "-0"). For efficiency strings representing integers exceeding 2^53 are not checked to see if they are canonical, i.e. the *Idx traps will receive "9007199254740993" as well as "9007199254740994", even though the former is not a canonical representation in ECMAScript (Number("9007199254740993") === 9007199254740992). See https://262.ecma-international.org/#sec-canonicalnumericindexstring If an *Idx trap is not set, the corresponding string one is used.
type RandSource ¶
type RandSource func() float64
type Runtime ¶
type Runtime struct {
// contains filtered or unexported fields
}
func New ¶
func New() *Runtime
New creates an instance of a Javascript runtime that can be used to run code. Multiple instances may be created and used simultaneously, however it is not possible to pass JS values across runtimes.
func (*Runtime) CaptureCallStack ¶
func (r *Runtime) CaptureCallStack(depth int, stack []StackFrame) []StackFrame
CaptureCallStack appends the current call stack frames to the stack slice (which may be nil) up to the specified depth. The most recent frame will be the first one. If depth <= 0 or more than the number of available frames, returns the entire stack. This method is not safe for concurrent use and should only be called by a Go function that is called from a running script.
func (*Runtime) ClearInterrupt ¶
func (r *Runtime) ClearInterrupt()
ClearInterrupt resets the interrupt flag. Typically this needs to be called before the runtime is made available for re-use if there is a chance it could have been interrupted with Interrupt(). Otherwise if Interrupt() was called when runtime was not running (e.g. if it had already finished) so that Interrupt() didn't actually trigger, an attempt to use the runtime will immediately cause an interruption. It is up to the user to ensure proper synchronisation so that ClearInterrupt() is only called when the runtime has finished and there is no chance of a concurrent Interrupt() call.
func (*Runtime) CreateObject ¶
CreateObject creates an object with given prototype. Equivalent of Object.create(proto).
func (*Runtime) ExportTo ¶
ExportTo converts a JavaScript value into the specified Go value. The second parameter must be a non-nil pointer. Returns error if conversion is not possible.
Notes on specific cases:
Empty interface ¶
Exporting to an interface{} results in a value of the same type as Value.Export() would produce.
Numeric types ¶
Exporting to numeric types uses the standard ECMAScript conversion operations, same as used when assigning values to non-clamped typed array items, e.g. https://262.ecma-international.org/#sec-toint32.
Functions ¶
Exporting to a 'func' creates a strictly typed 'gateway' into an ES function which can be called from Go. The arguments are converted into ES values using Runtime.ToValue(). If the func has no return values, the return value is ignored. If the func has exactly one return value, it is converted to the appropriate type using ExportTo(). If the last return value is 'error', exceptions are caught and returned as *Exception (instances of GoError are unwrapped, i.e. their 'value' is returned instead). In all other cases exceptions result in a panic. Any extra return values are zeroed.
'this' value will always be set to 'undefined'.
For a more low-level mechanism see AssertFunction().
Map types ¶
An ES Map can be exported into a Go map type. If any exported key value is non-hashable, the operation panics (as reflect.Value.SetMapIndex() would). Symbol.iterator is ignored.
Exporting an ES Set into a map type results in the map being populated with (element) -> (zero value) key/value pairs. If any value is non-hashable, the operation panics (as reflect.Value.SetMapIndex() would). Symbol.iterator is ignored.
Any other Object populates the map with own enumerable non-symbol properties.
Slice types ¶
Exporting an ES Set into a slice type results in its elements being exported.
Exporting any Object that implements the iterable protocol (https://developer.mozilla.org/en-US/docs/Web/JavaScript/Reference/Iteration_protocols#the_iterable_protocol) into a slice type results in the slice being populated with the results of the iteration.
Array is treated as iterable (i.e. overwriting Symbol.iterator affects the result).
If an object has a 'length' property and is not a function it is treated as array-like. The resulting slice will contain obj[0], ... obj[length-1].
For any other Object an error is returned.
Array types ¶
Anything that can be exported to a slice type can also be exported to an array type, as long as the lengths match. If they do not, an error is returned.
Proxy ¶
Proxy objects are treated the same way as if they were accessed from ES code in regard to their properties (such as 'length' or [Symbol.iterator]). This means exporting them to slice types works, however exporting a proxied Map into a map type does not produce its contents, because the Proxy is not recognised as a Map. Same applies to a proxied Set.
Example (ArrayLikeToSlice) ¶
vm := New() v, err := vm.RunString(` ({ length: 3, 0: 1, 1: 2, 2: 3 }); `) if err != nil { panic(err) } var arr []int err = vm.ExportTo(v, &arr) if err != nil { panic(err) } fmt.Println(arr)
Output: [1 2 3]
Example (Func) ¶
const SCRIPT = ` function f(param) { return +param + 2; } ` vm := New() _, err := vm.RunString(SCRIPT) if err != nil { panic(err) } var fn func(string) string err = vm.ExportTo(vm.Get("f"), &fn) if err != nil { panic(err) } fmt.Println(fn("40")) // note, _this_ value in the function will be undefined.
Output: 42
Example (FuncThrow) ¶
const SCRIPT = ` function f(param) { throw new Error("testing"); } ` vm := New() _, err := vm.RunString(SCRIPT) if err != nil { panic(err) } var fn func(string) (string, error) err = vm.ExportTo(vm.Get("f"), &fn) if err != nil { panic(err) } _, err = fn("") fmt.Println(err)
Output: Error: testing at f (<eval>:3:9(3))
Example (FuncVariadic) ¶
const SCRIPT = ` function f() { return Array.prototype.join.call(arguments, ","); } ` vm := New() _, err := vm.RunString(SCRIPT) if err != nil { panic(err) } var fn func(args ...interface{}) string err = vm.ExportTo(vm.Get("f"), &fn) if err != nil { panic(err) } fmt.Println(fn("a", "b", 42))
Output: a,b,42
Example (IterableToSlice) ¶
vm := New() v, err := vm.RunString(` function reverseIterator() { const arr = this; let idx = arr.length; return { next: () => idx > 0 ? {value: arr[--idx]} : {done: true} } } const arr = [1,2,3]; arr[Symbol.iterator] = reverseIterator; arr; `) if err != nil { panic(err) } var arr []int err = vm.ExportTo(v, &arr) if err != nil { panic(err) } fmt.Println(arr)
Output: [3 2 1]
Example (MapToMap) ¶
vm := New() m, err := vm.RunString(` new Map([[1, true], [2, false]]); `) if err != nil { panic(err) } exp := make(map[int]bool) err = vm.ExportTo(m, &exp) if err != nil { panic(err) } fmt.Println(exp)
Output: map[1:true 2:false]
Example (MapToSlice) ¶
vm := New() m, err := vm.RunString(` new Map([[1, true], [2, false]]); `) if err != nil { panic(err) } exp := make([][]interface{}, 0) err = vm.ExportTo(m, &exp) if err != nil { panic(err) } fmt.Println(exp)
Output: [[1 true] [2 false]]
Example (MapToTypedSlice) ¶
vm := New() m, err := vm.RunString(` new Map([[1, true], [2, false]]); `) if err != nil { panic(err) } exp := make([][2]interface{}, 0) err = vm.ExportTo(m, &exp) if err != nil { panic(err) } fmt.Println(exp)
Output: [[1 true] [2 false]]
Example (SetToMap) ¶
vm := New() s, err := vm.RunString(` new Set([1, 2, 3]) `) if err != nil { panic(err) } m := make(map[int]struct{}) err = vm.ExportTo(s, &m) if err != nil { panic(err) } fmt.Println(m)
Output: map[1:{} 2:{} 3:{}]
Example (SetToSlice) ¶
vm := New() s, err := vm.RunString(` new Set([1, 2, 3]) `) if err != nil { panic(err) } var a []int err = vm.ExportTo(s, &a) if err != nil { panic(err) } fmt.Println(a)
Output: [1 2 3]
func (*Runtime) Get ¶
Get the specified variable in the global context. Equivalent to dereferencing a variable by name in non-strict mode. If variable is not defined returns nil. Note, this is not the same as GlobalObject().Get(name), because if a global lexical binding (let or const) exists, it is used instead. This method will panic with an *Exception if a JavaScript exception is thrown in the process.
func (*Runtime) GlobalObject ¶
GlobalObject returns the global object.
func (*Runtime) Interrupt ¶
func (r *Runtime) Interrupt(v interface{})
Interrupt a running JavaScript. The corresponding Go call will return an *InterruptedError containing v. If the interrupt propagates until the stack is empty the currently queued promise resolve/reject jobs will be cleared without being executed. This is the same time they would be executed otherwise. Note, it only works while in JavaScript code, it does not interrupt native Go functions (which includes all built-ins). If the runtime is currently not running, it will be immediately interrupted on the next Run*() call. To avoid that use ClearInterrupt()
func (*Runtime) New ¶
New is an equivalent of the 'new' operator allowing to call it directly from Go.
func (*Runtime) NewArray ¶
Example ¶
vm := New() array := vm.NewArray(1, 2, true) vm.Set("array", array) res, err := vm.RunString(` var acc = ""; for (var v of array) { acc += v + " "; } acc; `) if err != nil { panic(err) } fmt.Println(res)
Output: 1 2 true
func (*Runtime) NewArrayBuffer ¶
func (r *Runtime) NewArrayBuffer(data []byte) ArrayBuffer
func (*Runtime) NewDynamicArray ¶
func (r *Runtime) NewDynamicArray(a DynamicArray) *Object
NewDynamicArray creates an array Object backed by the provided DynamicArray handler. It is similar to NewDynamicObject, the differences are:
- the Object is an array (i.e. Array.isArray() will return true and it will have the length property).
- the prototype will be initially set to Array.prototype.
- the Object cannot have any own string properties except for the 'length'.
func (*Runtime) NewDynamicObject ¶
func (r *Runtime) NewDynamicObject(d DynamicObject) *Object
NewDynamicObject creates an Object backed by the provided DynamicObject handler.
All properties of this Object are Writable, Enumerable and Configurable data properties. Any attempt to define a property that does not conform to this will fail.
The Object is always extensible and cannot be made non-extensible. Object.preventExtensions() will fail.
The Object's prototype is initially set to Object.prototype, but can be changed using regular mechanisms (Object.SetPrototype() in Go or Object.setPrototypeOf() in JS).
The Object cannot have own Symbol properties, however its prototype can. If you need an iterator support for example, you could create a regular object, set Symbol.iterator on that object and then use it as a prototype. See TestDynamicObjectCustomProto for more details.
Export() returns the original DynamicObject.
This mechanism is similar to ECMAScript Proxy, however because all properties are enumerable and the object is always extensible there is no need for invariant checks which removes the need to have a target object and makes it a lot more efficient.
func (*Runtime) NewGoError ¶
func (*Runtime) NewPromise ¶
func (r *Runtime) NewPromise() (promise *Promise, resolve func(result interface{}), reject func(reason interface{}))
NewPromise creates and returns a Promise and resolving functions for it.
WARNING: The returned values are not goroutine-safe and must not be called in parallel with VM running. In order to make use of this method you need an event loop such as the one in goja_nodejs (https://github.com/dop251/goja_nodejs) where it can be used like this:
loop := NewEventLoop() loop.Start() defer loop.Stop() loop.RunOnLoop(func(vm *goja.Runtime) { p, resolve, _ := vm.NewPromise() vm.Set("p", p) go func() { time.Sleep(500 * time.Millisecond) // or perform any other blocking operation loop.RunOnLoop(func(*goja.Runtime) { // resolve() must be called on the loop, cannot call it here resolve(result) }) }() }
func (*Runtime) NewProxy ¶
func (r *Runtime) NewProxy(target *Object, nativeHandler *ProxyTrapConfig) Proxy
func (*Runtime) NewTypeError ¶
func (*Runtime) RunProgram ¶
RunProgram executes a pre-compiled (see Compile()) code in the global context.
func (*Runtime) Set ¶
Set the specified variable in the global context. Equivalent to running "name = value" in non-strict mode. The value is first converted using ToValue(). Note, this is not the same as GlobalObject().Set(name, value), because if a global lexical binding (let or const) exists, it is set instead.
Example (Lexical) ¶
r := New() _, err := r.RunString("let x") if err != nil { panic(err) } err = r.Set("x", 1) if err != nil { panic(err) } fmt.Print(r.Get("x"), r.GlobalObject().Get("x"))
Output: 1 <nil>
func (*Runtime) SetAsyncContextTracker ¶
func (r *Runtime) SetAsyncContextTracker(tracker AsyncContextTracker)
SetAsyncContextTracker registers a handler that allows to track async execution contexts. See AsyncContextTracker documentation for more details. Setting it to nil disables the functionality. This method (as Runtime in general) is not goroutine-safe.
func (*Runtime) SetFieldNameMapper ¶
func (r *Runtime) SetFieldNameMapper(mapper FieldNameMapper)
SetFieldNameMapper sets a custom field name mapper for Go types. It can be called at any time, however the mapping for any given value is fixed at the point of creation. Setting this to nil restores the default behaviour which is all exported fields and methods are mapped to their original unchanged names.
func (*Runtime) SetMaxCallStackSize ¶
SetMaxCallStackSize sets the maximum function call depth. When exceeded, a *StackOverflowError is thrown and returned by RunProgram or by a Callable call. This is useful to prevent memory exhaustion caused by an infinite recursion. The default value is math.MaxInt32. This method (as the rest of the Set* methods) is not safe for concurrent use and may only be called from the vm goroutine or when the vm is not running.
func (*Runtime) SetParserOptions ¶
SetParserOptions sets parser options to be used by RunString, RunScript and eval() within the code.
Example ¶
vm := New() vm.SetParserOptions(parser.WithDisableSourceMaps) res, err := vm.RunString(` "I did not hang!"; //# sourceMappingURL=/dev/zero`) if err != nil { panic(err) } fmt.Println(res.String())
Output: I did not hang!
func (*Runtime) SetPromiseRejectionTracker ¶
func (r *Runtime) SetPromiseRejectionTracker(tracker PromiseRejectionTracker)
SetPromiseRejectionTracker registers a function that will be called in two scenarios: when a promise is rejected without any handlers (with operation argument set to PromiseRejectionReject), and when a handler is added to a rejected promise for the first time (with operation argument set to PromiseRejectionHandle).
Setting a tracker replaces any existing one. Setting it to nil disables the functionality.
See https://tc39.es/ecma262/#sec-host-promise-rejection-tracker for more details.
func (*Runtime) SetRandSource ¶
func (r *Runtime) SetRandSource(source RandSource)
SetRandSource sets random source for this Runtime. If not called, the default math/rand is used.
func (*Runtime) SetTimeSource ¶
SetTimeSource sets the current time source for this Runtime. If not called, the default time.Now() is used.
func (*Runtime) ToValue ¶
ToValue converts a Go value into a JavaScript value of a most appropriate type. Structural types (such as structs, maps and slices) are wrapped so that changes are reflected on the original value which can be retrieved using Value.Export().
WARNING! These wrapped Go values do not behave in the same way as native ECMAScript values. If you plan to modify them in ECMAScript, bear in mind the following caveats:
1. If a regular JavaScript Object is assigned as an element of a wrapped Go struct, map or array, it is Export()'ed and therefore copied. This may result in an unexpected behaviour in JavaScript:
m := map[string]interface{}{} vm.Set("m", m) vm.RunString(` var obj = {test: false}; m.obj = obj; // obj gets Export()'ed, i.e. copied to a new map[string]interface{} and then this map is set as m["obj"] obj.test = true; // note, m.obj.test is still false `) fmt.Println(m["obj"].(map[string]interface{})["test"]) // prints "false"
2. Be careful with nested non-pointer compound types (structs, slices and arrays) if you modify them in ECMAScript. Better avoid it at all if possible. One of the fundamental differences between ECMAScript and Go is in the former all Objects are references whereas in Go you can have a literal struct or array. Consider the following example:
type S struct { Field int } a := []S{{1}, {2}} // slice of literal structs vm.Set("a", &a) vm.RunString(` let tmp = {Field: 1}; a[0] = tmp; a[1] = tmp; tmp.Field = 2; `)
In ECMAScript one would expect a[0].Field and a[1].Field to be equal to 2, but this is really not possible (or at least non-trivial without some complex reference tracking).
To cover the most common use cases and to avoid excessive memory allocation, the following 'copy-on-change' mechanism is implemented (for both arrays and structs):
* When a nested compound value is accessed, the returned ES value becomes a reference to the literal value. This ensures that things like 'a[0].Field = 1' work as expected and simple access to 'a[0].Field' does not result in copying of a[0].
* The original container ('a' in our case) keeps track of the returned reference value and if a[0] is reassigned (e.g. by direct assignment, deletion or shrinking the array) the old a[0] is copied and the earlier returned value becomes a reference to the copy:
let tmp = a[0]; // no copy, tmp is a reference to a[0] tmp.Field = 1; // a[0].Field === 1 after this a[0] = {Field: 2}; // tmp is now a reference to a copy of the old value (with Field === 1) a[0].Field === 2 && tmp.Field === 1; // true
* Array value swaps caused by in-place sort (using Array.prototype.sort()) do not count as re-assignments, instead the references are adjusted to point to the new indices.
* Assignment to an inner compound value always does a copy (and sometimes type conversion):
a[1] = tmp; // a[1] is now a copy of tmp tmp.Field = 3; // does not affect a[1].Field
3. Non-addressable structs, slices and arrays get copied. This sometimes may lead to a confusion as assigning to inner fields does not appear to work:
a1 := []interface{}{S{1}, S{2}} vm.Set("a1", &a1) vm.RunString(` a1[0].Field === 1; // true a1[0].Field = 2; a1[0].Field === 2; // FALSE, because what it really did was copy a1[0] set its Field to 2 and immediately drop it `)
An alternative would be making a1[0].Field a non-writable property which would probably be more in line with ECMAScript, however it would require to manually copy the value if it does need to be modified which may be impractical.
Note, the same applies to slices. If a slice is passed by value (not as a pointer), resizing the slice does not reflect on the original value. Moreover, extending the slice may result in the underlying array being re-allocated and copied. For example:
a := []interface{}{1} vm.Set("a", a) vm.RunString(`a.push(2); a[0] = 0;`) fmt.Println(a[0]) // prints "1"
Notes on individual types:
Primitive types ¶
Primitive types (numbers, string, bool) are converted to the corresponding JavaScript primitives.
Strings ¶
Because of the difference in internal string representation between ECMAScript (which uses UTF-16) and Go (which uses UTF-8) conversion from JS to Go may be lossy. In particular, code points that can be part of UTF-16 surrogate pairs (0xD800-0xDFFF) cannot be represented in UTF-8 unless they form a valid surrogate pair and are replaced with utf8.RuneError.
The string value must be a valid UTF-8. If it is not, invalid characters are replaced with utf8.RuneError, but the behaviour of a subsequent Export() is unspecified (it may return the original value, or a value with replaced invalid characters).
Nil ¶
Nil is converted to null.
Functions ¶
func(FunctionCall) Value is treated as a native JavaScript function. This increases performance because there are no automatic argument and return value type conversions (which involves reflect). Attempting to use the function as a constructor will result in a TypeError.
func(FunctionCall, *Runtime) Value is treated as above, except the *Runtime is also passed as a parameter.
func(ConstructorCall) *Object is treated as a native constructor, allowing to use it with the new operator:
func MyObject(call goja.ConstructorCall) *goja.Object { // call.This contains the newly created object as per http://www.ecma-international.org/ecma-262/5.1/index.html#sec-13.2.2 // call.Arguments contain arguments passed to the function call.This.Set("method", method) //... // If return value is a non-nil *Object, it will be used instead of call.This // This way it is possible to return a Go struct or a map converted // into goja.Value using ToValue(), however in this case // instanceof will not work as expected, unless you set the prototype: // // instance := &myCustomStruct{} // instanceValue := vm.ToValue(instance).(*Object) // instanceValue.SetPrototype(call.This.Prototype()) // return instanceValue return nil } runtime.Set("MyObject", MyObject)
Then it can be used in JS as follows:
var o = new MyObject(arg); var o1 = MyObject(arg); // same thing o instanceof MyObject && o1 instanceof MyObject; // true
When a native constructor is called directly (without the new operator) its behavior depends on this value: if it's an Object, it is passed through, otherwise a new one is created exactly as if it was called with the new operator. In either case call.NewTarget will be nil.
func(ConstructorCall, *Runtime) *Object is treated as above, except the *Runtime is also passed as a parameter.
Any other Go function is wrapped so that the arguments are automatically converted into the required Go types and the return value is converted to a JavaScript value (using this method). If conversion is not possible, a TypeError is thrown.
Functions with multiple return values return an Array. If the last return value is an `error` it is not returned but converted into a JS exception. If the error is *Exception, it is thrown as is, otherwise it's wrapped in a GoEerror. Note that if there are exactly two return values and the last is an `error`, the function returns the first value as is, not an Array.
Structs ¶
Structs are converted to Object-like values. Fields and methods are available as properties, their values are results of this method (ToValue()) applied to the corresponding Go value.
Field properties are writable and non-configurable. Method properties are non-writable and non-configurable.
Attempt to define a new property or delete an existing property will fail (throw in strict mode) unless it's a Symbol property. Symbol properties only exist in the wrapper and do not affect the underlying Go value. Note that because a wrapper is created every time a property is accessed it may lead to unexpected results such as this:
type Field struct{ } type S struct { Field *Field } var s = S{ Field: &Field{}, } vm := New() vm.Set("s", &s) res, err := vm.RunString(` var sym = Symbol(66); var field1 = s.Field; field1[sym] = true; var field2 = s.Field; field1 === field2; // true, because the equality operation compares the wrapped values, not the wrappers field1[sym] === true; // true field2[sym] === undefined; // also true `)
The same applies to values from maps and slices as well.
Handling of time.Time ¶
time.Time does not get special treatment and therefore is converted just like any other `struct` providing access to all its methods. This is done deliberately instead of converting it to a `Date` because these two types are not fully compatible: `time.Time` includes zone, whereas JS `Date` doesn't. Doing the conversion implicitly therefore would result in a loss of information.
If you need to convert it to a `Date`, it can be done either in JS:
var d = new Date(goval.UnixNano()/1e6);
... or in Go:
now := time.Now() vm := New() val, err := vm.New(vm.Get("Date").ToObject(vm), vm.ToValue(now.UnixNano()/1e6)) if err != nil { ... } vm.Set("d", val)
Note that Value.Export() for a `Date` value returns time.Time in local timezone.
Maps ¶
Maps with string or integer key type are converted into host objects that largely behave like a JavaScript Object.
Maps with methods ¶
If a map type has at least one method defined, the properties of the resulting Object represent methods, not map keys. This is because in JavaScript there is no distinction between 'object.key` and `object[key]`, unlike Go. If access to the map values is required, it can be achieved by defining another method or, if it's not possible, by defining an external getter function.
Slices ¶
Slices are converted into host objects that behave largely like JavaScript Array. It has the appropriate prototype and all the usual methods should work. There is, however, a caveat: converted Arrays may not contain holes (because Go slices cannot). This means that hasOwnProperty(n) always returns `true` if n < length. Deleting an item with an index < length will set it to a zero value (but the property will remain). Nil slice elements are be converted to `null`. Accessing an element beyond `length` returns `undefined`. Also see the warning above about passing slices as values (as opposed to pointers).
Arrays ¶
Arrays are converted similarly to slices, except the resulting Arrays are not resizable (and therefore the 'length' property is non-writable).
Any other type is converted to a generic reflect based host object. Depending on the underlying type it behaves similar to a Number, String, Boolean or Object.
Note that the underlying type is not lost, calling Export() returns the original Go value. This applies to all reflect based types.
type StackFrame ¶
type StackFrame struct {
// contains filtered or unexported fields
}
func (*StackFrame) FuncName ¶
func (f *StackFrame) FuncName() string
func (*StackFrame) Position ¶
func (f *StackFrame) Position() file.Position
func (*StackFrame) SrcName ¶
func (f *StackFrame) SrcName() string
func (*StackFrame) Write ¶
func (f *StackFrame) Write(b *bytes.Buffer)
func (*StackFrame) WriteToValueBuilder ¶
func (f *StackFrame) WriteToValueBuilder(b *valueStringBuilder)
type StackOverflowError ¶
type StackOverflowError struct {
// contains filtered or unexported fields
}
type Symbol ¶
type Symbol struct {
// contains filtered or unexported fields
}
*Symbol is a Value containing ECMAScript Symbol primitive. Symbols must only be created using NewSymbol(). Zero values and copying of values (i.e. *s1 = *s2) are not permitted. Well-known Symbols can be accessed using Sym* package variables (SymIterator, etc...) Symbols can be shared by multiple Runtimes.
func NewSymbol ¶
Example ¶
sym1 := NewSymbol("66") sym2 := NewSymbol("66") fmt.Printf("%s %s %v", sym1, sym2, sym1.Equals(sym2))
Output: 66 66 false
func (*Symbol) ExportType ¶
func (*Symbol) StrictEquals ¶
type Value ¶
type Value interface { ToInteger() int64 ToString() Value String() string ToFloat() float64 ToNumber() Value ToBoolean() bool ToObject(*Runtime) *Object SameAs(Value) bool Equals(Value) bool StrictEquals(Value) bool Export() interface{} ExportType() reflect.Type // contains filtered or unexported methods }
Value represents an ECMAScript value.
Export returns a "plain" Go value which type depends on the type of the Value.
For integer numbers it's int64.
For any other numbers (including Infinities, NaN and negative zero) it's float64.
For string it's a string. Note that unicode strings are converted into UTF-8 with invalid code points replaced with utf8.RuneError.
For boolean it's bool.
For null and undefined it's nil.
For Object it depends on the Object type, see Object.Export() for more details.
Source Files ¶
- array.go
- array_sparse.go
- builtin_array.go
- builtin_boolean.go
- builtin_date.go
- builtin_error.go
- builtin_function.go
- builtin_global.go
- builtin_json.go
- builtin_map.go
- builtin_math.go
- builtin_number.go
- builtin_object.go
- builtin_promise.go
- builtin_proxy.go
- builtin_reflect.go
- builtin_regexp.go
- builtin_set.go
- builtin_string.go
- builtin_symbol.go
- builtin_typedarrays.go
- builtin_weakmap.go
- builtin_weakset.go
- compiler.go
- compiler_expr.go
- compiler_stmt.go
- date.go
- date_parser.go
- destruct.go
- func.go
- ipow.go
- map.go
- object.go
- object_args.go
- object_dynamic.go
- object_goarray_reflect.go
- object_gomap.go
- object_gomap_reflect.go
- object_goreflect.go
- object_goslice.go
- object_goslice_reflect.go
- object_lazy.go
- proxy.go
- regexp.go
- runtime.go
- string.go
- string_ascii.go
- string_imported.go
- string_unicode.go
- typedarrays.go
- value.go
- vm.go
Directories ¶
Path | Synopsis |
---|---|
Package ast declares types representing a JavaScript AST.
|
Package ast declares types representing a JavaScript AST. |
Package file encapsulates the file abstractions used by the ast & parser.
|
Package file encapsulates the file abstractions used by the ast & parser. |
Package ftoa provides ECMAScript-compliant floating point number conversion to string.
|
Package ftoa provides ECMAScript-compliant floating point number conversion to string. |
internal/fast
Package fast contains code ported from V8 (https://github.com/v8/v8/blob/master/src/numbers/fast-dtoa.cc)
|
Package fast contains code ported from V8 (https://github.com/v8/v8/blob/master/src/numbers/fast-dtoa.cc) |
Package parser implements a parser for JavaScript.
|
Package parser implements a parser for JavaScript. |
Package token defines constants representing the lexical tokens of JavaScript (ECMA5).
|
Package token defines constants representing the lexical tokens of JavaScript (ECMA5). |
Package unistring contains an implementation of a hybrid ASCII/UTF-16 string.
|
Package unistring contains an implementation of a hybrid ASCII/UTF-16 string. |