package goja import ( "fmt" "math" "sort" "unsafe" "github.com/dop251/goja/unistring" ) type typedArraySortCtx struct { ta *typedArrayObject compare func(FunctionCall) Value needValidate bool } func (ctx *typedArraySortCtx) Len() int { return ctx.ta.length } func (ctx *typedArraySortCtx) Less(i, j int) bool { if ctx.needValidate { ctx.ta.viewedArrayBuf.ensureNotDetached(true) ctx.needValidate = false } offset := ctx.ta.offset if ctx.compare != nil { x := ctx.ta.typedArray.get(offset + i) y := ctx.ta.typedArray.get(offset + j) res := ctx.compare(FunctionCall{ This: _undefined, Arguments: []Value{x, y}, }).ToNumber() ctx.needValidate = true if i, ok := res.(valueInt); ok { return i < 0 } f := res.ToFloat() if f < 0 { return true } if f > 0 { return false } if math.Signbit(f) { return true } return false } return ctx.ta.typedArray.less(offset+i, offset+j) } func (ctx *typedArraySortCtx) Swap(i, j int) { if ctx.needValidate { ctx.ta.viewedArrayBuf.ensureNotDetached(true) ctx.needValidate = false } offset := ctx.ta.offset ctx.ta.typedArray.swap(offset+i, offset+j) } func allocByteSlice(size int) (b []byte) { defer func() { if x := recover(); x != nil { panic(rangeError(fmt.Sprintf("Buffer size is too large: %d", size))) } }() if size < 0 { panic(rangeError(fmt.Sprintf("Invalid buffer size: %d", size))) } b = make([]byte, size) return } func (r *Runtime) builtin_newArrayBuffer(args []Value, newTarget *Object) *Object { if newTarget == nil { panic(r.needNew("ArrayBuffer")) } b := r._newArrayBuffer(r.getPrototypeFromCtor(newTarget, r.global.ArrayBuffer, r.global.ArrayBufferPrototype), nil) if len(args) > 0 { b.data = allocByteSlice(r.toIndex(args[0])) } return b.val } func (r *Runtime) arrayBufferProto_getByteLength(call FunctionCall) Value { o := r.toObject(call.This) if b, ok := o.self.(*arrayBufferObject); ok { if b.ensureNotDetached(false) { return intToValue(int64(len(b.data))) } return intToValue(0) } panic(r.NewTypeError("Object is not ArrayBuffer: %s", o)) } func (r *Runtime) arrayBufferProto_slice(call FunctionCall) Value { o := r.toObject(call.This) if b, ok := o.self.(*arrayBufferObject); ok { l := int64(len(b.data)) start := relToIdx(call.Argument(0).ToInteger(), l) var stop int64 if arg := call.Argument(1); arg != _undefined { stop = arg.ToInteger() } else { stop = l } stop = relToIdx(stop, l) newLen := max(stop-start, 0) ret := r.speciesConstructor(o, r.global.ArrayBuffer)([]Value{intToValue(newLen)}, nil) if ab, ok := ret.self.(*arrayBufferObject); ok { if newLen > 0 { b.ensureNotDetached(true) if ret == o { panic(r.NewTypeError("Species constructor returned the same ArrayBuffer")) } if int64(len(ab.data)) < newLen { panic(r.NewTypeError("Species constructor returned an ArrayBuffer that is too small: %d", len(ab.data))) } ab.ensureNotDetached(true) copy(ab.data, b.data[start:stop]) } return ret } panic(r.NewTypeError("Species constructor did not return an ArrayBuffer: %s", ret.String())) } panic(r.NewTypeError("Object is not ArrayBuffer: %s", o)) } func (r *Runtime) arrayBuffer_isView(call FunctionCall) Value { if o, ok := call.Argument(0).(*Object); ok { if _, ok := o.self.(*dataViewObject); ok { return valueTrue } if _, ok := o.self.(*typedArrayObject); ok { return valueTrue } } return valueFalse } func (r *Runtime) newDataView(args []Value, newTarget *Object) *Object { if newTarget == nil { panic(r.needNew("DataView")) } proto := r.getPrototypeFromCtor(newTarget, r.global.DataView, r.global.DataViewPrototype) var bufArg Value if len(args) > 0 { bufArg = args[0] } var buffer *arrayBufferObject if o, ok := bufArg.(*Object); ok { if b, ok := o.self.(*arrayBufferObject); ok { buffer = b } } if buffer == nil { panic(r.NewTypeError("First argument to DataView constructor must be an ArrayBuffer")) } var byteOffset, byteLen int if len(args) > 1 { offsetArg := nilSafe(args[1]) byteOffset = r.toIndex(offsetArg) buffer.ensureNotDetached(true) if byteOffset > len(buffer.data) { panic(r.newError(r.global.RangeError, "Start offset %s is outside the bounds of the buffer", offsetArg.String())) } } if len(args) > 2 && args[2] != nil && args[2] != _undefined { byteLen = r.toIndex(args[2]) if byteOffset+byteLen > len(buffer.data) { panic(r.newError(r.global.RangeError, "Invalid DataView length %d", byteLen)) } } else { byteLen = len(buffer.data) - byteOffset } o := &Object{runtime: r} b := &dataViewObject{ baseObject: baseObject{ class: classObject, val: o, prototype: proto, extensible: true, }, viewedArrayBuf: buffer, byteOffset: byteOffset, byteLen: byteLen, } o.self = b b.init() return o } func (r *Runtime) dataViewProto_getBuffer(call FunctionCall) Value { if dv, ok := r.toObject(call.This).self.(*dataViewObject); ok { return dv.viewedArrayBuf.val } panic(r.NewTypeError("Method get DataView.prototype.buffer called on incompatible receiver %s", call.This.String())) } func (r *Runtime) dataViewProto_getByteLen(call FunctionCall) Value { if dv, ok := r.toObject(call.This).self.(*dataViewObject); ok { dv.viewedArrayBuf.ensureNotDetached(true) return intToValue(int64(dv.byteLen)) } panic(r.NewTypeError("Method get DataView.prototype.byteLength called on incompatible receiver %s", call.This.String())) } func (r *Runtime) dataViewProto_getByteOffset(call FunctionCall) Value { if dv, ok := r.toObject(call.This).self.(*dataViewObject); ok { dv.viewedArrayBuf.ensureNotDetached(true) return intToValue(int64(dv.byteOffset)) } panic(r.NewTypeError("Method get DataView.prototype.byteOffset called on incompatible receiver %s", call.This.String())) } func (r *Runtime) dataViewProto_getFloat32(call FunctionCall) Value { if dv, ok := r.toObject(call.This).self.(*dataViewObject); ok { return floatToValue(float64(dv.viewedArrayBuf.getFloat32(dv.getIdxAndByteOrder(call.Argument(0), call.Argument(1), 4)))) } panic(r.NewTypeError("Method DataView.prototype.getFloat32 called on incompatible receiver %s", call.This.String())) } func (r *Runtime) dataViewProto_getFloat64(call FunctionCall) Value { if dv, ok := r.toObject(call.This).self.(*dataViewObject); ok { return floatToValue(dv.viewedArrayBuf.getFloat64(dv.getIdxAndByteOrder(call.Argument(0), call.Argument(1), 8))) } panic(r.NewTypeError("Method DataView.prototype.getFloat64 called on incompatible receiver %s", call.This.String())) } func (r *Runtime) dataViewProto_getInt8(call FunctionCall) Value { if dv, ok := r.toObject(call.This).self.(*dataViewObject); ok { idx, _ := dv.getIdxAndByteOrder(call.Argument(0), call.Argument(1), 1) return intToValue(int64(dv.viewedArrayBuf.getInt8(idx))) } panic(r.NewTypeError("Method DataView.prototype.getInt8 called on incompatible receiver %s", call.This.String())) } func (r *Runtime) dataViewProto_getInt16(call FunctionCall) Value { if dv, ok := r.toObject(call.This).self.(*dataViewObject); ok { return intToValue(int64(dv.viewedArrayBuf.getInt16(dv.getIdxAndByteOrder(call.Argument(0), call.Argument(1), 2)))) } panic(r.NewTypeError("Method DataView.prototype.getInt16 called on incompatible receiver %s", call.This.String())) } func (r *Runtime) dataViewProto_getInt32(call FunctionCall) Value { if dv, ok := r.toObject(call.This).self.(*dataViewObject); ok { return intToValue(int64(dv.viewedArrayBuf.getInt32(dv.getIdxAndByteOrder(call.Argument(0), call.Argument(1), 4)))) } panic(r.NewTypeError("Method DataView.prototype.getInt32 called on incompatible receiver %s", call.This.String())) } func (r *Runtime) dataViewProto_getUint8(call FunctionCall) Value { if dv, ok := r.toObject(call.This).self.(*dataViewObject); ok { idx, _ := dv.getIdxAndByteOrder(call.Argument(0), call.Argument(1), 1) return intToValue(int64(dv.viewedArrayBuf.getUint8(idx))) } panic(r.NewTypeError("Method DataView.prototype.getUint8 called on incompatible receiver %s", call.This.String())) } func (r *Runtime) dataViewProto_getUint16(call FunctionCall) Value { if dv, ok := r.toObject(call.This).self.(*dataViewObject); ok { return intToValue(int64(dv.viewedArrayBuf.getUint16(dv.getIdxAndByteOrder(call.Argument(0), call.Argument(1), 2)))) } panic(r.NewTypeError("Method DataView.prototype.getUint16 called on incompatible receiver %s", call.This.String())) } func (r *Runtime) dataViewProto_getUint32(call FunctionCall) Value { if dv, ok := r.toObject(call.This).self.(*dataViewObject); ok { return intToValue(int64(dv.viewedArrayBuf.getUint32(dv.getIdxAndByteOrder(call.Argument(0), call.Argument(1), 4)))) } panic(r.NewTypeError("Method DataView.prototype.getUint32 called on incompatible receiver %s", call.This.String())) } func (r *Runtime) dataViewProto_setFloat32(call FunctionCall) Value { if dv, ok := r.toObject(call.This).self.(*dataViewObject); ok { val := toFloat32(call.Argument(1)) idx, bo := dv.getIdxAndByteOrder(call.Argument(0), call.Argument(2), 4) dv.viewedArrayBuf.setFloat32(idx, val, bo) return _undefined } panic(r.NewTypeError("Method DataView.prototype.setFloat32 called on incompatible receiver %s", call.This.String())) } func (r *Runtime) dataViewProto_setFloat64(call FunctionCall) Value { if dv, ok := r.toObject(call.This).self.(*dataViewObject); ok { val := call.Argument(1).ToFloat() idx, bo := dv.getIdxAndByteOrder(call.Argument(0), call.Argument(2), 8) dv.viewedArrayBuf.setFloat64(idx, val, bo) return _undefined } panic(r.NewTypeError("Method DataView.prototype.setFloat64 called on incompatible receiver %s", call.This.String())) } func (r *Runtime) dataViewProto_setInt8(call FunctionCall) Value { if dv, ok := r.toObject(call.This).self.(*dataViewObject); ok { val := toInt8(call.Argument(1)) idx, _ := dv.getIdxAndByteOrder(call.Argument(0), call.Argument(2), 1) dv.viewedArrayBuf.setInt8(idx, val) return _undefined } panic(r.NewTypeError("Method DataView.prototype.setInt8 called on incompatible receiver %s", call.This.String())) } func (r *Runtime) dataViewProto_setInt16(call FunctionCall) Value { if dv, ok := r.toObject(call.This).self.(*dataViewObject); ok { val := toInt16(call.Argument(1)) idx, bo := dv.getIdxAndByteOrder(call.Argument(0), call.Argument(2), 2) dv.viewedArrayBuf.setInt16(idx, val, bo) return _undefined } panic(r.NewTypeError("Method DataView.prototype.setInt16 called on incompatible receiver %s", call.This.String())) } func (r *Runtime) dataViewProto_setInt32(call FunctionCall) Value { if dv, ok := r.toObject(call.This).self.(*dataViewObject); ok { val := toInt32(call.Argument(1)) idx, bo := dv.getIdxAndByteOrder(call.Argument(0), call.Argument(2), 4) dv.viewedArrayBuf.setInt32(idx, val, bo) return _undefined } panic(r.NewTypeError("Method DataView.prototype.setInt32 called on incompatible receiver %s", call.This.String())) } func (r *Runtime) dataViewProto_setUint8(call FunctionCall) Value { if dv, ok := r.toObject(call.This).self.(*dataViewObject); ok { val := toUint8(call.Argument(1)) idx, _ := dv.getIdxAndByteOrder(call.Argument(0), call.Argument(2), 1) dv.viewedArrayBuf.setUint8(idx, val) return _undefined } panic(r.NewTypeError("Method DataView.prototype.setUint8 called on incompatible receiver %s", call.This.String())) } func (r *Runtime) dataViewProto_setUint16(call FunctionCall) Value { if dv, ok := r.toObject(call.This).self.(*dataViewObject); ok { val := toUint16(call.Argument(1)) idx, bo := dv.getIdxAndByteOrder(call.Argument(0), call.Argument(2), 2) dv.viewedArrayBuf.setUint16(idx, val, bo) return _undefined } panic(r.NewTypeError("Method DataView.prototype.setUint16 called on incompatible receiver %s", call.This.String())) } func (r *Runtime) dataViewProto_setUint32(call FunctionCall) Value { if dv, ok := r.toObject(call.This).self.(*dataViewObject); ok { val := toUint32(call.Argument(1)) idx, bo := dv.getIdxAndByteOrder(call.Argument(0), call.Argument(2), 4) dv.viewedArrayBuf.setUint32(idx, val, bo) return _undefined } panic(r.NewTypeError("Method DataView.prototype.setUint32 called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_getBuffer(call FunctionCall) Value { if ta, ok := r.toObject(call.This).self.(*typedArrayObject); ok { return ta.viewedArrayBuf.val } panic(r.NewTypeError("Method get TypedArray.prototype.buffer called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_getByteLen(call FunctionCall) Value { if ta, ok := r.toObject(call.This).self.(*typedArrayObject); ok { if ta.viewedArrayBuf.data == nil { return _positiveZero } return intToValue(int64(ta.length) * int64(ta.elemSize)) } panic(r.NewTypeError("Method get TypedArray.prototype.byteLength called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_getLength(call FunctionCall) Value { if ta, ok := r.toObject(call.This).self.(*typedArrayObject); ok { if ta.viewedArrayBuf.data == nil { return _positiveZero } return intToValue(int64(ta.length)) } panic(r.NewTypeError("Method get TypedArray.prototype.length called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_getByteOffset(call FunctionCall) Value { if ta, ok := r.toObject(call.This).self.(*typedArrayObject); ok { if ta.viewedArrayBuf.data == nil { return _positiveZero } return intToValue(int64(ta.offset) * int64(ta.elemSize)) } panic(r.NewTypeError("Method get TypedArray.prototype.byteOffset called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_copyWithin(call FunctionCall) Value { if ta, ok := r.toObject(call.This).self.(*typedArrayObject); ok { ta.viewedArrayBuf.ensureNotDetached(true) l := int64(ta.length) var relEnd int64 to := toIntStrict(relToIdx(call.Argument(0).ToInteger(), l)) from := toIntStrict(relToIdx(call.Argument(1).ToInteger(), l)) if end := call.Argument(2); end != _undefined { relEnd = end.ToInteger() } else { relEnd = l } final := toIntStrict(relToIdx(relEnd, l)) data := ta.viewedArrayBuf.data offset := ta.offset elemSize := ta.elemSize if final > from { ta.viewedArrayBuf.ensureNotDetached(true) copy(data[(offset+to)*elemSize:], data[(offset+from)*elemSize:(offset+final)*elemSize]) } return call.This } panic(r.NewTypeError("Method TypedArray.prototype.copyWithin called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_entries(call FunctionCall) Value { if ta, ok := r.toObject(call.This).self.(*typedArrayObject); ok { ta.viewedArrayBuf.ensureNotDetached(true) return r.createArrayIterator(ta.val, iterationKindKeyValue) } panic(r.NewTypeError("Method TypedArray.prototype.entries called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_every(call FunctionCall) Value { if ta, ok := r.toObject(call.This).self.(*typedArrayObject); ok { ta.viewedArrayBuf.ensureNotDetached(true) callbackFn := r.toCallable(call.Argument(0)) fc := FunctionCall{ This: call.Argument(1), Arguments: []Value{nil, nil, call.This}, } for k := 0; k < ta.length; k++ { ta.viewedArrayBuf.ensureNotDetached(true) fc.Arguments[0] = ta.typedArray.get(ta.offset + k) fc.Arguments[1] = intToValue(int64(k)) if !callbackFn(fc).ToBoolean() { return valueFalse } } return valueTrue } panic(r.NewTypeError("Method TypedArray.prototype.every called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_fill(call FunctionCall) Value { if ta, ok := r.toObject(call.This).self.(*typedArrayObject); ok { ta.viewedArrayBuf.ensureNotDetached(true) l := int64(ta.length) k := toIntStrict(relToIdx(call.Argument(1).ToInteger(), l)) var relEnd int64 if endArg := call.Argument(2); endArg != _undefined { relEnd = endArg.ToInteger() } else { relEnd = l } final := toIntStrict(relToIdx(relEnd, l)) value := ta.typedArray.toRaw(call.Argument(0)) ta.viewedArrayBuf.ensureNotDetached(true) for ; k < final; k++ { ta.typedArray.setRaw(ta.offset+k, value) } return call.This } panic(r.NewTypeError("Method TypedArray.prototype.fill called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_filter(call FunctionCall) Value { o := r.toObject(call.This) if ta, ok := o.self.(*typedArrayObject); ok { ta.viewedArrayBuf.ensureNotDetached(true) callbackFn := r.toCallable(call.Argument(0)) fc := FunctionCall{ This: call.Argument(1), Arguments: []Value{nil, nil, call.This}, } buf := make([]byte, 0, ta.length*ta.elemSize) captured := 0 for k := 0; k < ta.length; k++ { ta.viewedArrayBuf.ensureNotDetached(true) fc.Arguments[0] = ta.typedArray.get(k) fc.Arguments[1] = intToValue(int64(k)) if callbackFn(fc).ToBoolean() { i := (ta.offset + k) * ta.elemSize buf = append(buf, ta.viewedArrayBuf.data[i:i+ta.elemSize]...) captured++ } } c := r.speciesConstructorObj(o, ta.defaultCtor) ab := r._newArrayBuffer(r.global.ArrayBufferPrototype, nil) ab.data = buf kept := r.toConstructor(ta.defaultCtor)([]Value{ab.val}, ta.defaultCtor) if c == ta.defaultCtor { return kept } else { ret := r.typedArrayCreate(c, []Value{intToValue(int64(captured))}) keptTa := kept.self.(*typedArrayObject) for i := 0; i < captured; i++ { ret.typedArray.set(i, keptTa.typedArray.get(i)) } return ret.val } } panic(r.NewTypeError("Method TypedArray.prototype.filter called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_find(call FunctionCall) Value { if ta, ok := r.toObject(call.This).self.(*typedArrayObject); ok { ta.viewedArrayBuf.ensureNotDetached(true) predicate := r.toCallable(call.Argument(0)) fc := FunctionCall{ This: call.Argument(1), Arguments: []Value{nil, nil, call.This}, } for k := 0; k < ta.length; k++ { ta.viewedArrayBuf.ensureNotDetached(true) val := ta.typedArray.get(ta.offset + k) fc.Arguments[0] = val fc.Arguments[1] = intToValue(int64(k)) if predicate(fc).ToBoolean() { return val } } return _undefined } panic(r.NewTypeError("Method TypedArray.prototype.find called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_findIndex(call FunctionCall) Value { if ta, ok := r.toObject(call.This).self.(*typedArrayObject); ok { ta.viewedArrayBuf.ensureNotDetached(true) predicate := r.toCallable(call.Argument(0)) fc := FunctionCall{ This: call.Argument(1), Arguments: []Value{nil, nil, call.This}, } for k := 0; k < ta.length; k++ { ta.viewedArrayBuf.ensureNotDetached(true) fc.Arguments[0] = ta.typedArray.get(ta.offset + k) fc.Arguments[1] = intToValue(int64(k)) if predicate(fc).ToBoolean() { return fc.Arguments[1] } } return intToValue(-1) } panic(r.NewTypeError("Method TypedArray.prototype.findIndex called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_forEach(call FunctionCall) Value { if ta, ok := r.toObject(call.This).self.(*typedArrayObject); ok { ta.viewedArrayBuf.ensureNotDetached(true) callbackFn := r.toCallable(call.Argument(0)) fc := FunctionCall{ This: call.Argument(1), Arguments: []Value{nil, nil, call.This}, } for k := 0; k < ta.length; k++ { ta.viewedArrayBuf.ensureNotDetached(true) if val := ta.typedArray.get(k); val != nil { fc.Arguments[0] = val fc.Arguments[1] = intToValue(int64(k)) callbackFn(fc) } } return _undefined } panic(r.NewTypeError("Method TypedArray.prototype.forEach called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_includes(call FunctionCall) Value { if ta, ok := r.toObject(call.This).self.(*typedArrayObject); ok { ta.viewedArrayBuf.ensureNotDetached(true) length := int64(ta.length) if length == 0 { return valueFalse } n := call.Argument(1).ToInteger() if n >= length { return valueFalse } if n < 0 { n = max(length+n, 0) } ta.viewedArrayBuf.ensureNotDetached(true) searchElement := call.Argument(0) if searchElement == _negativeZero { searchElement = _positiveZero } if ta.typedArray.typeMatch(searchElement) { se := ta.typedArray.toRaw(searchElement) for k := toIntStrict(n); k < ta.length; k++ { if ta.typedArray.getRaw(ta.offset+k) == se { return valueTrue } } } return valueFalse } panic(r.NewTypeError("Method TypedArray.prototype.includes called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_indexOf(call FunctionCall) Value { if ta, ok := r.toObject(call.This).self.(*typedArrayObject); ok { ta.viewedArrayBuf.ensureNotDetached(true) length := int64(ta.length) if length == 0 { return intToValue(-1) } n := call.Argument(1).ToInteger() if n >= length { return intToValue(-1) } if n < 0 { n = max(length+n, 0) } ta.viewedArrayBuf.ensureNotDetached(true) searchElement := call.Argument(0) if searchElement == _negativeZero { searchElement = _positiveZero } if !IsNaN(searchElement) && ta.typedArray.typeMatch(searchElement) { se := ta.typedArray.toRaw(searchElement) for k := toIntStrict(n); k < ta.length; k++ { if ta.typedArray.getRaw(ta.offset+k) == se { return intToValue(int64(k)) } } } return intToValue(-1) } panic(r.NewTypeError("Method TypedArray.prototype.indexOf called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_join(call FunctionCall) Value { if ta, ok := r.toObject(call.This).self.(*typedArrayObject); ok { ta.viewedArrayBuf.ensureNotDetached(true) s := call.Argument(0) var sep valueString if s != _undefined { sep = s.toString() } else { sep = asciiString(",") } l := ta.length if l == 0 { return stringEmpty } var buf valueStringBuilder ta.viewedArrayBuf.ensureNotDetached(true) element0 := ta.typedArray.get(0) if element0 != nil && element0 != _undefined && element0 != _null { buf.WriteString(element0.toString()) } for i := 1; i < l; i++ { ta.viewedArrayBuf.ensureNotDetached(true) buf.WriteString(sep) element := ta.typedArray.get(i) if element != nil && element != _undefined && element != _null { buf.WriteString(element.toString()) } } return buf.String() } panic(r.NewTypeError("Method TypedArray.prototype.join called on incompatible receiver")) } func (r *Runtime) typedArrayProto_keys(call FunctionCall) Value { if ta, ok := r.toObject(call.This).self.(*typedArrayObject); ok { ta.viewedArrayBuf.ensureNotDetached(true) return r.createArrayIterator(ta.val, iterationKindKey) } panic(r.NewTypeError("Method TypedArray.prototype.keys called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_lastIndexOf(call FunctionCall) Value { if ta, ok := r.toObject(call.This).self.(*typedArrayObject); ok { ta.viewedArrayBuf.ensureNotDetached(true) length := int64(ta.length) if length == 0 { return intToValue(-1) } var fromIndex int64 if len(call.Arguments) < 2 { fromIndex = length - 1 } else { fromIndex = call.Argument(1).ToInteger() if fromIndex >= 0 { fromIndex = min(fromIndex, length-1) } else { fromIndex += length if fromIndex < 0 { fromIndex = -1 // prevent underflow in toIntStrict() on 32-bit platforms } } } ta.viewedArrayBuf.ensureNotDetached(true) searchElement := call.Argument(0) if searchElement == _negativeZero { searchElement = _positiveZero } if !IsNaN(searchElement) && ta.typedArray.typeMatch(searchElement) { se := ta.typedArray.toRaw(searchElement) for k := toIntStrict(fromIndex); k >= 0; k-- { if ta.typedArray.getRaw(ta.offset+k) == se { return intToValue(int64(k)) } } } return intToValue(-1) } panic(r.NewTypeError("Method TypedArray.prototype.lastIndexOf called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_map(call FunctionCall) Value { if ta, ok := r.toObject(call.This).self.(*typedArrayObject); ok { ta.viewedArrayBuf.ensureNotDetached(true) callbackFn := r.toCallable(call.Argument(0)) fc := FunctionCall{ This: call.Argument(1), Arguments: []Value{nil, nil, call.This}, } dst := r.typedArraySpeciesCreate(ta, []Value{intToValue(int64(ta.length))}) for i := 0; i < ta.length; i++ { ta.viewedArrayBuf.ensureNotDetached(true) fc.Arguments[0] = ta.typedArray.get(ta.offset + i) fc.Arguments[1] = intToValue(int64(i)) dst.typedArray.set(i, callbackFn(fc)) } return dst.val } panic(r.NewTypeError("Method TypedArray.prototype.map called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_reduce(call FunctionCall) Value { if ta, ok := r.toObject(call.This).self.(*typedArrayObject); ok { ta.viewedArrayBuf.ensureNotDetached(true) callbackFn := r.toCallable(call.Argument(0)) fc := FunctionCall{ This: _undefined, Arguments: []Value{nil, nil, nil, call.This}, } k := 0 if len(call.Arguments) >= 2 { fc.Arguments[0] = call.Argument(1) } else { if ta.length > 0 { fc.Arguments[0] = ta.typedArray.get(ta.offset + 0) k = 1 } } if fc.Arguments[0] == nil { panic(r.NewTypeError("Reduce of empty array with no initial value")) } for ; k < ta.length; k++ { ta.viewedArrayBuf.ensureNotDetached(true) idx := valueInt(k) fc.Arguments[1] = ta.typedArray.get(ta.offset + k) fc.Arguments[2] = idx fc.Arguments[0] = callbackFn(fc) } return fc.Arguments[0] } panic(r.NewTypeError("Method TypedArray.prototype.reduce called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_reduceRight(call FunctionCall) Value { if ta, ok := r.toObject(call.This).self.(*typedArrayObject); ok { ta.viewedArrayBuf.ensureNotDetached(true) callbackFn := r.toCallable(call.Argument(0)) fc := FunctionCall{ This: _undefined, Arguments: []Value{nil, nil, nil, call.This}, } k := ta.length - 1 if len(call.Arguments) >= 2 { fc.Arguments[0] = call.Argument(1) } else { if k >= 0 { fc.Arguments[0] = ta.typedArray.get(ta.offset + k) k-- } } if fc.Arguments[0] == nil { panic(r.NewTypeError("Reduce of empty array with no initial value")) } for ; k >= 0; k-- { ta.viewedArrayBuf.ensureNotDetached(true) idx := valueInt(k) fc.Arguments[1] = ta.typedArray.get(ta.offset + k) fc.Arguments[2] = idx fc.Arguments[0] = callbackFn(fc) } return fc.Arguments[0] } panic(r.NewTypeError("Method TypedArray.prototype.reduceRight called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_reverse(call FunctionCall) Value { if ta, ok := r.toObject(call.This).self.(*typedArrayObject); ok { ta.viewedArrayBuf.ensureNotDetached(true) l := ta.length middle := l / 2 for lower := 0; lower != middle; lower++ { upper := l - lower - 1 ta.typedArray.swap(ta.offset+lower, ta.offset+upper) } return call.This } panic(r.NewTypeError("Method TypedArray.prototype.reverse called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_set(call FunctionCall) Value { if ta, ok := r.toObject(call.This).self.(*typedArrayObject); ok { srcObj := call.Argument(0).ToObject(r) targetOffset := toIntStrict(call.Argument(1).ToInteger()) if targetOffset < 0 { panic(r.newError(r.global.RangeError, "offset should be >= 0")) } ta.viewedArrayBuf.ensureNotDetached(true) targetLen := ta.length if src, ok := srcObj.self.(*typedArrayObject); ok { src.viewedArrayBuf.ensureNotDetached(true) srcLen := src.length if x := srcLen + targetOffset; x < 0 || x > targetLen { panic(r.newError(r.global.RangeError, "Source is too large")) } if src.defaultCtor == ta.defaultCtor { copy(ta.viewedArrayBuf.data[(ta.offset+targetOffset)*ta.elemSize:], src.viewedArrayBuf.data[src.offset*src.elemSize:(src.offset+srcLen)*src.elemSize]) } else { curSrc := uintptr(unsafe.Pointer(&src.viewedArrayBuf.data[src.offset*src.elemSize])) endSrc := curSrc + uintptr(srcLen*src.elemSize) curDst := uintptr(unsafe.Pointer(&ta.viewedArrayBuf.data[(ta.offset+targetOffset)*ta.elemSize])) dstOffset := ta.offset + targetOffset srcOffset := src.offset if ta.elemSize == src.elemSize { if curDst <= curSrc || curDst >= endSrc { for i := 0; i < srcLen; i++ { ta.typedArray.set(dstOffset+i, src.typedArray.get(srcOffset+i)) } } else { for i := srcLen - 1; i >= 0; i-- { ta.typedArray.set(dstOffset+i, src.typedArray.get(srcOffset+i)) } } } else { x := int(curDst-curSrc) / (src.elemSize - ta.elemSize) if x < 0 { x = 0 } else if x > srcLen { x = srcLen } if ta.elemSize < src.elemSize { for i := x; i < srcLen; i++ { ta.typedArray.set(dstOffset+i, src.typedArray.get(srcOffset+i)) } for i := x - 1; i >= 0; i-- { ta.typedArray.set(dstOffset+i, src.typedArray.get(srcOffset+i)) } } else { for i := 0; i < x; i++ { ta.typedArray.set(dstOffset+i, src.typedArray.get(srcOffset+i)) } for i := srcLen - 1; i >= x; i-- { ta.typedArray.set(dstOffset+i, src.typedArray.get(srcOffset+i)) } } } } } else { targetLen := ta.length srcLen := toIntStrict(toLength(srcObj.self.getStr("length", nil))) if x := srcLen + targetOffset; x < 0 || x > targetLen { panic(r.newError(r.global.RangeError, "Source is too large")) } for i := 0; i < srcLen; i++ { val := nilSafe(srcObj.self.getIdx(valueInt(i), nil)) ta.viewedArrayBuf.ensureNotDetached(true) ta.typedArray.set(targetOffset+i, val) } } return _undefined } panic(r.NewTypeError("Method TypedArray.prototype.set called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_slice(call FunctionCall) Value { if ta, ok := r.toObject(call.This).self.(*typedArrayObject); ok { ta.viewedArrayBuf.ensureNotDetached(true) length := int64(ta.length) start := toIntStrict(relToIdx(call.Argument(0).ToInteger(), length)) var e int64 if endArg := call.Argument(1); endArg != _undefined { e = endArg.ToInteger() } else { e = length } end := toIntStrict(relToIdx(e, length)) count := end - start if count < 0 { count = 0 } dst := r.typedArraySpeciesCreate(ta, []Value{intToValue(int64(count))}) if dst.defaultCtor == ta.defaultCtor { if count > 0 { ta.viewedArrayBuf.ensureNotDetached(true) offset := ta.offset elemSize := ta.elemSize copy(dst.viewedArrayBuf.data, ta.viewedArrayBuf.data[(offset+start)*elemSize:(offset+start+count)*elemSize]) } } else { for i := 0; i < count; i++ { ta.viewedArrayBuf.ensureNotDetached(true) dst.typedArray.set(i, ta.typedArray.get(ta.offset+start+i)) } } return dst.val } panic(r.NewTypeError("Method TypedArray.prototype.slice called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_some(call FunctionCall) Value { if ta, ok := r.toObject(call.This).self.(*typedArrayObject); ok { ta.viewedArrayBuf.ensureNotDetached(true) callbackFn := r.toCallable(call.Argument(0)) fc := FunctionCall{ This: call.Argument(1), Arguments: []Value{nil, nil, call.This}, } for k := 0; k < ta.length; k++ { ta.viewedArrayBuf.ensureNotDetached(true) fc.Arguments[0] = ta.typedArray.get(ta.offset + k) fc.Arguments[1] = intToValue(int64(k)) if callbackFn(fc).ToBoolean() { return valueTrue } } return valueFalse } panic(r.NewTypeError("Method TypedArray.prototype.some called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_sort(call FunctionCall) Value { if ta, ok := r.toObject(call.This).self.(*typedArrayObject); ok { ta.viewedArrayBuf.ensureNotDetached(true) var compareFn func(FunctionCall) Value if arg := call.Argument(0); arg != _undefined { compareFn = r.toCallable(arg) } ctx := typedArraySortCtx{ ta: ta, compare: compareFn, } sort.Stable(&ctx) return call.This } panic(r.NewTypeError("Method TypedArray.prototype.sort called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_subarray(call FunctionCall) Value { if ta, ok := r.toObject(call.This).self.(*typedArrayObject); ok { l := int64(ta.length) beginIdx := relToIdx(call.Argument(0).ToInteger(), l) var relEnd int64 if endArg := call.Argument(1); endArg != _undefined { relEnd = endArg.ToInteger() } else { relEnd = l } endIdx := relToIdx(relEnd, l) newLen := max(endIdx-beginIdx, 0) return r.typedArraySpeciesCreate(ta, []Value{ta.viewedArrayBuf.val, intToValue((int64(ta.offset) + beginIdx) * int64(ta.elemSize)), intToValue(newLen), }).val } panic(r.NewTypeError("Method TypedArray.prototype.subarray called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_toLocaleString(call FunctionCall) Value { if ta, ok := r.toObject(call.This).self.(*typedArrayObject); ok { length := ta.length var buf valueStringBuilder for i := 0; i < length; i++ { ta.viewedArrayBuf.ensureNotDetached(true) if i > 0 { buf.WriteRune(',') } item := ta.typedArray.get(i) r.writeItemLocaleString(item, &buf) } return buf.String() } panic(r.NewTypeError("Method TypedArray.prototype.toLocaleString called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_values(call FunctionCall) Value { if ta, ok := r.toObject(call.This).self.(*typedArrayObject); ok { ta.viewedArrayBuf.ensureNotDetached(true) return r.createArrayIterator(ta.val, iterationKindValue) } panic(r.NewTypeError("Method TypedArray.prototype.values called on incompatible receiver %s", call.This.String())) } func (r *Runtime) typedArrayProto_toStringTag(call FunctionCall) Value { if obj, ok := call.This.(*Object); ok { if ta, ok := obj.self.(*typedArrayObject); ok { return nilSafe(ta.defaultCtor.self.getStr("name", nil)) } } return _undefined } func (r *Runtime) newTypedArray([]Value, *Object) *Object { panic(r.NewTypeError("Abstract class TypedArray not directly constructable")) } func (r *Runtime) typedArray_from(call FunctionCall) Value { mapFn := call.Argument(1) if mapFn == _undefined { mapFn = nil } return r.typedArrayFrom(r.toObject(call.This), call.Argument(0).ToObject(r), mapFn, call.Argument(2)) } func (r *Runtime) typedArray_of(call FunctionCall) Value { ta := r.typedArrayCreate(r.toObject(call.This), []Value{intToValue(int64(len(call.Arguments)))}) for i, val := range call.Arguments { ta.typedArray.set(i, val) } return ta.val } func (r *Runtime) allocateTypedArray(newTarget *Object, length int, taCtor typedArrayObjectCtor) *Object { buf := r._newArrayBuffer(r.global.ArrayBufferPrototype, nil) ta := taCtor(buf, 0, length, r.getPrototypeFromCtor(newTarget, nil, r.global.TypedArrayPrototype)) if length > 0 { buf.data = allocByteSlice(length * ta.elemSize) } return ta.val } func (r *Runtime) typedArraySpeciesCreate(ta *typedArrayObject, args []Value) *typedArrayObject { return r.typedArrayCreate(r.speciesConstructorObj(ta.val, ta.defaultCtor), args) } func (r *Runtime) typedArrayCreate(ctor *Object, args []Value) *typedArrayObject { o := r.toConstructor(ctor)(args, ctor) if ta, ok := o.self.(*typedArrayObject); ok { ta.viewedArrayBuf.ensureNotDetached(true) if len(args) == 1 { if l, ok := args[0].(valueInt); ok { if ta.length < int(l) { panic(r.NewTypeError("Derived TypedArray constructor created an array which was too small")) } } } return ta } panic(r.NewTypeError("Invalid TypedArray: %s", o)) } func (r *Runtime) typedArrayFrom(ctor, items *Object, mapFn, thisValue Value) *Object { var mapFc func(call FunctionCall) Value if mapFn != nil { mapFc = r.toCallable(mapFn) if thisValue == nil { thisValue = _undefined } } usingIter := toMethod(items.self.getSym(SymIterator, nil)) if usingIter != nil { iter := r.getIterator(items, usingIter) var values []Value r.iterate(iter, func(item Value) { values = append(values, item) }) ta := r.typedArrayCreate(ctor, []Value{intToValue(int64(len(values)))}) if mapFc == nil { for idx, val := range values { ta.typedArray.set(idx, val) } } else { fc := FunctionCall{ This: thisValue, Arguments: []Value{nil, nil}, } for idx, val := range values { fc.Arguments[0], fc.Arguments[1] = val, intToValue(int64(idx)) val = mapFc(fc) ta.typedArray.set(idx, val) } } return ta.val } length := toIntStrict(toLength(items.self.getStr("length", nil))) ta := r.typedArrayCreate(ctor, []Value{intToValue(int64(length))}) if mapFc == nil { for i := 0; i < length; i++ { ta.typedArray.set(i, nilSafe(items.self.getIdx(valueInt(i), nil))) } } else { fc := FunctionCall{ This: thisValue, Arguments: []Value{nil, nil}, } for i := 0; i < length; i++ { idx := valueInt(i) fc.Arguments[0], fc.Arguments[1] = items.self.getIdx(idx, nil), idx ta.typedArray.set(i, mapFc(fc)) } } return ta.val } func (r *Runtime) _newTypedArrayFromArrayBuffer(ab *arrayBufferObject, args []Value, newTarget *Object, taCtor typedArrayObjectCtor) *Object { ta := taCtor(ab, 0, 0, r.getPrototypeFromCtor(newTarget, nil, r.global.TypedArrayPrototype)) var byteOffset int if len(args) > 1 && args[1] != nil && args[1] != _undefined { byteOffset = r.toIndex(args[1]) if byteOffset%ta.elemSize != 0 { panic(r.newError(r.global.RangeError, "Start offset of %s should be a multiple of %d", newTarget.self.getStr("name", nil), ta.elemSize)) } } ab.ensureNotDetached(true) var length int if len(args) > 2 && args[2] != nil && args[2] != _undefined { length = r.toIndex(args[2]) if byteOffset+length*ta.elemSize > len(ab.data) { panic(r.newError(r.global.RangeError, "Invalid typed array length: %d", length)) } } else { if len(ab.data)%ta.elemSize != 0 { panic(r.newError(r.global.RangeError, "Byte length of %s should be a multiple of %d", newTarget.self.getStr("name", nil), ta.elemSize)) } length = (len(ab.data) - byteOffset) / ta.elemSize } ta.offset = byteOffset / ta.elemSize ta.length = length return ta.val } func (r *Runtime) _newTypedArrayFromTypedArray(src *typedArrayObject, newTarget *Object) *Object { dst := r.typedArrayCreate(newTarget, []Value{_positiveZero}) src.viewedArrayBuf.ensureNotDetached(true) l := src.length dst.viewedArrayBuf.prototype = r.getPrototypeFromCtor(r.toObject(src.viewedArrayBuf.getStr("constructor", nil)), r.global.ArrayBuffer, r.global.ArrayBufferPrototype) dst.viewedArrayBuf.data = allocByteSlice(toIntStrict(int64(l) * int64(dst.elemSize))) if src.defaultCtor == dst.defaultCtor { copy(dst.viewedArrayBuf.data, src.viewedArrayBuf.data[src.offset*src.elemSize:]) dst.length = src.length return dst.val } dst.length = l for i := 0; i < l; i++ { dst.typedArray.set(i, src.typedArray.get(src.offset+i)) } return dst.val } func (r *Runtime) _newTypedArray(args []Value, newTarget *Object, taCtor typedArrayObjectCtor) *Object { if newTarget == nil { panic(r.needNew("TypedArray")) } if len(args) > 0 { if obj, ok := args[0].(*Object); ok { switch o := obj.self.(type) { case *arrayBufferObject: return r._newTypedArrayFromArrayBuffer(o, args, newTarget, taCtor) case *typedArrayObject: return r._newTypedArrayFromTypedArray(o, newTarget) default: return r.typedArrayFrom(newTarget, obj, nil, nil) } } } var l int if len(args) > 0 { if arg0 := args[0]; arg0 != nil { l = r.toIndex(arg0) } } return r.allocateTypedArray(newTarget, l, taCtor) } func (r *Runtime) newUint8Array(args []Value, newTarget *Object) *Object { return r._newTypedArray(args, newTarget, r.newUint8ArrayObject) } func (r *Runtime) newUint8ClampedArray(args []Value, newTarget *Object) *Object { return r._newTypedArray(args, newTarget, r.newUint8ClampedArrayObject) } func (r *Runtime) newInt8Array(args []Value, newTarget *Object) *Object { return r._newTypedArray(args, newTarget, r.newInt8ArrayObject) } func (r *Runtime) newUint16Array(args []Value, newTarget *Object) *Object { return r._newTypedArray(args, newTarget, r.newUint16ArrayObject) } func (r *Runtime) newInt16Array(args []Value, newTarget *Object) *Object { return r._newTypedArray(args, newTarget, r.newInt16ArrayObject) } func (r *Runtime) newUint32Array(args []Value, newTarget *Object) *Object { return r._newTypedArray(args, newTarget, r.newUint32ArrayObject) } func (r *Runtime) newInt32Array(args []Value, newTarget *Object) *Object { return r._newTypedArray(args, newTarget, r.newInt32ArrayObject) } func (r *Runtime) newFloat32Array(args []Value, newTarget *Object) *Object { return r._newTypedArray(args, newTarget, r.newFloat32ArrayObject) } func (r *Runtime) newFloat64Array(args []Value, newTarget *Object) *Object { return r._newTypedArray(args, newTarget, r.newFloat64ArrayObject) } func (r *Runtime) createArrayBufferProto(val *Object) objectImpl { b := newBaseObjectObj(val, r.global.ObjectPrototype, classObject) byteLengthProp := &valueProperty{ accessor: true, configurable: true, getterFunc: r.newNativeFunc(r.arrayBufferProto_getByteLength, nil, "get byteLength", nil, 0), } b._put("byteLength", byteLengthProp) b._putProp("constructor", r.global.ArrayBuffer, true, false, true) b._putProp("slice", r.newNativeFunc(r.arrayBufferProto_slice, nil, "slice", nil, 2), true, false, true) b._putSym(SymToStringTag, valueProp(asciiString("ArrayBuffer"), false, false, true)) return b } func (r *Runtime) createArrayBuffer(val *Object) objectImpl { o := r.newNativeConstructOnly(val, r.builtin_newArrayBuffer, r.global.ArrayBufferPrototype, "ArrayBuffer", 1) o._putProp("isView", r.newNativeFunc(r.arrayBuffer_isView, nil, "isView", nil, 1), true, false, true) o._putSym(SymSpecies, &valueProperty{ getterFunc: r.newNativeFunc(r.returnThis, nil, "get [Symbol.species]", nil, 0), accessor: true, configurable: true, }) return o } func (r *Runtime) createDataViewProto(val *Object) objectImpl { b := newBaseObjectObj(val, r.global.ObjectPrototype, classObject) b._put("buffer", &valueProperty{ accessor: true, configurable: true, getterFunc: r.newNativeFunc(r.dataViewProto_getBuffer, nil, "get buffer", nil, 0), }) b._put("byteLength", &valueProperty{ accessor: true, configurable: true, getterFunc: r.newNativeFunc(r.dataViewProto_getByteLen, nil, "get byteLength", nil, 0), }) b._put("byteOffset", &valueProperty{ accessor: true, configurable: true, getterFunc: r.newNativeFunc(r.dataViewProto_getByteOffset, nil, "get byteOffset", nil, 0), }) b._putProp("constructor", r.global.DataView, true, false, true) b._putProp("getFloat32", r.newNativeFunc(r.dataViewProto_getFloat32, nil, "getFloat32", nil, 1), true, false, true) b._putProp("getFloat64", r.newNativeFunc(r.dataViewProto_getFloat64, nil, "getFloat64", nil, 1), true, false, true) b._putProp("getInt8", r.newNativeFunc(r.dataViewProto_getInt8, nil, "getInt8", nil, 1), true, false, true) b._putProp("getInt16", r.newNativeFunc(r.dataViewProto_getInt16, nil, "getInt16", nil, 1), true, false, true) b._putProp("getInt32", r.newNativeFunc(r.dataViewProto_getInt32, nil, "getInt32", nil, 1), true, false, true) b._putProp("getUint8", r.newNativeFunc(r.dataViewProto_getUint8, nil, "getUint8", nil, 1), true, false, true) b._putProp("getUint16", r.newNativeFunc(r.dataViewProto_getUint16, nil, "getUint16", nil, 1), true, false, true) b._putProp("getUint32", r.newNativeFunc(r.dataViewProto_getUint32, nil, "getUint32", nil, 1), true, false, true) b._putProp("setFloat32", r.newNativeFunc(r.dataViewProto_setFloat32, nil, "setFloat32", nil, 2), true, false, true) b._putProp("setFloat64", r.newNativeFunc(r.dataViewProto_setFloat64, nil, "setFloat64", nil, 2), true, false, true) b._putProp("setInt8", r.newNativeFunc(r.dataViewProto_setInt8, nil, "setInt8", nil, 2), true, false, true) b._putProp("setInt16", r.newNativeFunc(r.dataViewProto_setInt16, nil, "setInt16", nil, 2), true, false, true) b._putProp("setInt32", r.newNativeFunc(r.dataViewProto_setInt32, nil, "setInt32", nil, 2), true, false, true) b._putProp("setUint8", r.newNativeFunc(r.dataViewProto_setUint8, nil, "setUint8", nil, 2), true, false, true) b._putProp("setUint16", r.newNativeFunc(r.dataViewProto_setUint16, nil, "setUint16", nil, 2), true, false, true) b._putProp("setUint32", r.newNativeFunc(r.dataViewProto_setUint32, nil, "setUint32", nil, 2), true, false, true) b._putSym(SymToStringTag, valueProp(asciiString("DataView"), false, false, true)) return b } func (r *Runtime) createDataView(val *Object) objectImpl { o := r.newNativeConstructOnly(val, r.newDataView, r.global.DataViewPrototype, "DataView", 3) return o } func (r *Runtime) createTypedArrayProto(val *Object) objectImpl { b := newBaseObjectObj(val, r.global.ObjectPrototype, classObject) b._put("buffer", &valueProperty{ accessor: true, configurable: true, getterFunc: r.newNativeFunc(r.typedArrayProto_getBuffer, nil, "get buffer", nil, 0), }) b._put("byteLength", &valueProperty{ accessor: true, configurable: true, getterFunc: r.newNativeFunc(r.typedArrayProto_getByteLen, nil, "get byteLength", nil, 0), }) b._put("byteOffset", &valueProperty{ accessor: true, configurable: true, getterFunc: r.newNativeFunc(r.typedArrayProto_getByteOffset, nil, "get byteOffset", nil, 0), }) b._putProp("constructor", r.global.TypedArray, true, false, true) b._putProp("copyWithin", r.newNativeFunc(r.typedArrayProto_copyWithin, nil, "copyWithin", nil, 2), true, false, true) b._putProp("entries", r.newNativeFunc(r.typedArrayProto_entries, nil, "entries", nil, 0), true, false, true) b._putProp("every", r.newNativeFunc(r.typedArrayProto_every, nil, "every", nil, 1), true, false, true) b._putProp("fill", r.newNativeFunc(r.typedArrayProto_fill, nil, "fill", nil, 1), true, false, true) b._putProp("filter", r.newNativeFunc(r.typedArrayProto_filter, nil, "filter", nil, 1), true, false, true) b._putProp("find", r.newNativeFunc(r.typedArrayProto_find, nil, "find", nil, 1), true, false, true) b._putProp("findIndex", r.newNativeFunc(r.typedArrayProto_findIndex, nil, "findIndex", nil, 1), true, false, true) b._putProp("forEach", r.newNativeFunc(r.typedArrayProto_forEach, nil, "forEach", nil, 1), true, false, true) b._putProp("includes", r.newNativeFunc(r.typedArrayProto_includes, nil, "includes", nil, 1), true, false, true) b._putProp("indexOf", r.newNativeFunc(r.typedArrayProto_indexOf, nil, "indexOf", nil, 1), true, false, true) b._putProp("join", r.newNativeFunc(r.typedArrayProto_join, nil, "join", nil, 1), true, false, true) b._putProp("keys", r.newNativeFunc(r.typedArrayProto_keys, nil, "keys", nil, 0), true, false, true) b._putProp("lastIndexOf", r.newNativeFunc(r.typedArrayProto_lastIndexOf, nil, "lastIndexOf", nil, 1), true, false, true) b._put("length", &valueProperty{ accessor: true, configurable: true, getterFunc: r.newNativeFunc(r.typedArrayProto_getLength, nil, "get length", nil, 0), }) b._putProp("map", r.newNativeFunc(r.typedArrayProto_map, nil, "map", nil, 1), true, false, true) b._putProp("reduce", r.newNativeFunc(r.typedArrayProto_reduce, nil, "reduce", nil, 1), true, false, true) b._putProp("reduceRight", r.newNativeFunc(r.typedArrayProto_reduceRight, nil, "reduceRight", nil, 1), true, false, true) b._putProp("reverse", r.newNativeFunc(r.typedArrayProto_reverse, nil, "reverse", nil, 0), true, false, true) b._putProp("set", r.newNativeFunc(r.typedArrayProto_set, nil, "set", nil, 1), true, false, true) b._putProp("slice", r.newNativeFunc(r.typedArrayProto_slice, nil, "slice", nil, 2), true, false, true) b._putProp("some", r.newNativeFunc(r.typedArrayProto_some, nil, "some", nil, 1), true, false, true) b._putProp("sort", r.newNativeFunc(r.typedArrayProto_sort, nil, "sort", nil, 1), true, false, true) b._putProp("subarray", r.newNativeFunc(r.typedArrayProto_subarray, nil, "subarray", nil, 2), true, false, true) b._putProp("toLocaleString", r.newNativeFunc(r.typedArrayProto_toLocaleString, nil, "toLocaleString", nil, 0), true, false, true) b._putProp("toString", r.global.arrayToString, true, false, true) valuesFunc := r.newNativeFunc(r.typedArrayProto_values, nil, "values", nil, 0) b._putProp("values", valuesFunc, true, false, true) b._putSym(SymIterator, valueProp(valuesFunc, true, false, true)) b._putSym(SymToStringTag, &valueProperty{ getterFunc: r.newNativeFunc(r.typedArrayProto_toStringTag, nil, "get [Symbol.toStringTag]", nil, 0), accessor: true, configurable: true, }) return b } func (r *Runtime) createTypedArray(val *Object) objectImpl { o := r.newNativeConstructOnly(val, r.newTypedArray, r.global.TypedArrayPrototype, "TypedArray", 0) o._putProp("from", r.newNativeFunc(r.typedArray_from, nil, "from", nil, 1), true, false, true) o._putProp("of", r.newNativeFunc(r.typedArray_of, nil, "of", nil, 0), true, false, true) o._putSym(SymSpecies, &valueProperty{ getterFunc: r.newNativeFunc(r.returnThis, nil, "get [Symbol.species]", nil, 0), accessor: true, configurable: true, }) return o } func (r *Runtime) addPrototype(ctor *Object, proto *Object) *baseObject { p := r.newBaseObject(proto, classObject) p._putProp("constructor", ctor, true, false, true) ctor.self._putProp("prototype", p.val, false, false, false) return p } func (r *Runtime) typedArrayCreator(ctor func(args []Value, newTarget *Object) *Object, name unistring.String, bytesPerElement int) func(val *Object) objectImpl { return func(val *Object) objectImpl { o := r.newNativeConstructOnly(val, ctor, nil, name, 3) o.prototype = r.global.TypedArray proto := r.addPrototype(o.val, r.global.TypedArrayPrototype) bpe := intToValue(int64(bytesPerElement)) o._putProp("BYTES_PER_ELEMENT", bpe, false, false, false) proto._putProp("BYTES_PER_ELEMENT", bpe, false, false, false) return o } } func (r *Runtime) initTypedArrays() { r.global.ArrayBufferPrototype = r.newLazyObject(r.createArrayBufferProto) r.global.ArrayBuffer = r.newLazyObject(r.createArrayBuffer) r.addToGlobal("ArrayBuffer", r.global.ArrayBuffer) r.global.DataViewPrototype = r.newLazyObject(r.createDataViewProto) r.global.DataView = r.newLazyObject(r.createDataView) r.addToGlobal("DataView", r.global.DataView) r.global.TypedArrayPrototype = r.newLazyObject(r.createTypedArrayProto) r.global.TypedArray = r.newLazyObject(r.createTypedArray) r.global.Uint8Array = r.newLazyObject(r.typedArrayCreator(r.newUint8Array, "Uint8Array", 1)) r.addToGlobal("Uint8Array", r.global.Uint8Array) r.global.Uint8ClampedArray = r.newLazyObject(r.typedArrayCreator(r.newUint8ClampedArray, "Uint8ClampedArray", 1)) r.addToGlobal("Uint8ClampedArray", r.global.Uint8ClampedArray) r.global.Int8Array = r.newLazyObject(r.typedArrayCreator(r.newInt8Array, "Int8Array", 1)) r.addToGlobal("Int8Array", r.global.Int8Array) r.global.Uint16Array = r.newLazyObject(r.typedArrayCreator(r.newUint16Array, "Uint16Array", 2)) r.addToGlobal("Uint16Array", r.global.Uint16Array) r.global.Int16Array = r.newLazyObject(r.typedArrayCreator(r.newInt16Array, "Int16Array", 2)) r.addToGlobal("Int16Array", r.global.Int16Array) r.global.Uint32Array = r.newLazyObject(r.typedArrayCreator(r.newUint32Array, "Uint32Array", 4)) r.addToGlobal("Uint32Array", r.global.Uint32Array) r.global.Int32Array = r.newLazyObject(r.typedArrayCreator(r.newInt32Array, "Int32Array", 4)) r.addToGlobal("Int32Array", r.global.Int32Array) r.global.Float32Array = r.newLazyObject(r.typedArrayCreator(r.newFloat32Array, "Float32Array", 4)) r.addToGlobal("Float32Array", r.global.Float32Array) r.global.Float64Array = r.newLazyObject(r.typedArrayCreator(r.newFloat64Array, "Float64Array", 8)) r.addToGlobal("Float64Array", r.global.Float64Array) }