// Copyright 2009 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package reflect import ( "math" "runtime" "unsafe" ) const ptrSize = uintptr(unsafe.Sizeof((*byte)(nil))) const cannotSet = "cannot set value obtained from unexported struct field" type addr unsafe.Pointer // TODO: This will have to go away when // the new gc goes in. func memmove(adst, asrc addr, n uintptr) { dst := uintptr(adst) src := uintptr(asrc) switch { case src < dst && src+n > dst: // byte copy backward // careful: i is unsigned for i := n; i > 0; { i-- *(*byte)(addr(dst + i)) = *(*byte)(addr(src + i)) } case (n|src|dst)&(ptrSize-1) != 0: // byte copy forward for i := uintptr(0); i < n; i++ { *(*byte)(addr(dst + i)) = *(*byte)(addr(src + i)) } default: // word copy forward for i := uintptr(0); i < n; i += ptrSize { *(*uintptr)(addr(dst + i)) = *(*uintptr)(addr(src + i)) } } } // Value is the common interface to reflection values. // The implementations of Value (e.g., ArrayValue, StructValue) // have additional type-specific methods. type Value interface { // Type returns the value's type. Type() Type // Interface returns the value as an interface{}. Interface() interface{} // CanSet returns true if the value can be changed. // Values obtained by the use of non-exported struct fields // can be used in Get but not Set. // If CanSet returns false, calling the type-specific Set will panic. CanSet() bool // SetValue assigns v to the value; v must have the same type as the value. SetValue(v Value) // CanAddr returns true if the value's address can be obtained with Addr. // Such values are called addressable. A value is addressable if it is // an element of a slice, an element of an addressable array, // a field of an addressable struct, the result of dereferencing a pointer, // or the result of a call to NewValue, MakeChan, MakeMap, or MakeZero. // If CanAddr returns false, calling Addr will panic. CanAddr() bool // Addr returns the address of the value. // If the value is not addressable, Addr panics. // Addr is typically used to obtain a pointer to a struct field or slice element // in order to call a method that requires a pointer receiver. Addr() *PtrValue // UnsafeAddr returns a pointer to the underlying data. // It is for advanced clients that also import the "unsafe" package. UnsafeAddr() uintptr // Method returns a FuncValue corresponding to the value's i'th method. // The arguments to a Call on the returned FuncValue // should not include a receiver; the FuncValue will use // the value as the receiver. Method(i int) *FuncValue getAddr() addr } // flags for value const ( canSet uint32 = 1 << iota // can set value (write to *v.addr) canAddr // can take address of value canStore // can store through value (write to **v.addr) ) // value is the common implementation of most values. // It is embedded in other, public struct types, but always // with a unique tag like "uint" or "float" so that the client cannot // convert from, say, *UintValue to *FloatValue. type value struct { typ Type addr addr flag uint32 } func (v *value) Type() Type { return v.typ } func (v *value) Addr() *PtrValue { if !v.CanAddr() { panic("reflect: cannot take address of value") } a := v.addr flag := canSet if v.CanSet() { flag |= canStore } // We could safely set canAddr here too - // the caller would get the address of a - // but it doesn't match the Go model. // The language doesn't let you say &&v. return newValue(PtrTo(v.typ), addr(&a), flag).(*PtrValue) } func (v *value) UnsafeAddr() uintptr { return uintptr(v.addr) } func (v *value) getAddr() addr { return v.addr } func (v *value) Interface() interface{} { if typ, ok := v.typ.(*InterfaceType); ok { // There are two different representations of interface values, // one if the interface type has methods and one if it doesn't. // These two representations require different expressions // to extract correctly. if typ.NumMethod() == 0 { // Extract as interface value without methods. return *(*interface{})(v.addr) } // Extract from v.addr as interface value with methods. return *(*interface { m() })(v.addr) } return unsafe.Unreflect(v.typ, unsafe.Pointer(v.addr)) } func (v *value) CanSet() bool { return v.flag&canSet != 0 } func (v *value) CanAddr() bool { return v.flag&canAddr != 0 } /* * basic types */ // BoolValue represents a bool value. type BoolValue struct { value "bool" } // Get returns the underlying bool value. func (v *BoolValue) Get() bool { return *(*bool)(v.addr) } // Set sets v to the value x. func (v *BoolValue) Set(x bool) { if !v.CanSet() { panic(cannotSet) } *(*bool)(v.addr) = x } // Set sets v to the value x. func (v *BoolValue) SetValue(x Value) { v.Set(x.(*BoolValue).Get()) } // FloatValue represents a float value. type FloatValue struct { value "float" } // Get returns the underlying int value. func (v *FloatValue) Get() float64 { switch v.typ.Kind() { case Float32: return float64(*(*float32)(v.addr)) case Float64: return *(*float64)(v.addr) } panic("reflect: invalid float kind") } // Set sets v to the value x. func (v *FloatValue) Set(x float64) { if !v.CanSet() { panic(cannotSet) } switch v.typ.Kind() { default: panic("reflect: invalid float kind") case Float32: *(*float32)(v.addr) = float32(x) case Float64: *(*float64)(v.addr) = x } } // Overflow returns true if x cannot be represented by the type of v. func (v *FloatValue) Overflow(x float64) bool { if v.typ.Size() == 8 { return false } if x < 0 { x = -x } return math.MaxFloat32 < x && x <= math.MaxFloat64 } // Set sets v to the value x. func (v *FloatValue) SetValue(x Value) { v.Set(x.(*FloatValue).Get()) } // ComplexValue represents a complex value. type ComplexValue struct { value "complex" } // Get returns the underlying complex value. func (v *ComplexValue) Get() complex128 { switch v.typ.Kind() { case Complex64: return complex128(*(*complex64)(v.addr)) case Complex128: return *(*complex128)(v.addr) } panic("reflect: invalid complex kind") } // Set sets v to the value x. func (v *ComplexValue) Set(x complex128) { if !v.CanSet() { panic(cannotSet) } switch v.typ.Kind() { default: panic("reflect: invalid complex kind") case Complex64: *(*complex64)(v.addr) = complex64(x) case Complex128: *(*complex128)(v.addr) = x } } // Set sets v to the value x. func (v *ComplexValue) SetValue(x Value) { v.Set(x.(*ComplexValue).Get()) } // IntValue represents an int value. type IntValue struct { value "int" } // Get returns the underlying int value. func (v *IntValue) Get() int64 { switch v.typ.Kind() { case Int: return int64(*(*int)(v.addr)) case Int8: return int64(*(*int8)(v.addr)) case Int16: return int64(*(*int16)(v.addr)) case Int32: return int64(*(*int32)(v.addr)) case Int64: return *(*int64)(v.addr) } panic("reflect: invalid int kind") } // Set sets v to the value x. func (v *IntValue) Set(x int64) { if !v.CanSet() { panic(cannotSet) } switch v.typ.Kind() { default: panic("reflect: invalid int kind") case Int: *(*int)(v.addr) = int(x) case Int8: *(*int8)(v.addr) = int8(x) case Int16: *(*int16)(v.addr) = int16(x) case Int32: *(*int32)(v.addr) = int32(x) case Int64: *(*int64)(v.addr) = x } } // Set sets v to the value x. func (v *IntValue) SetValue(x Value) { v.Set(x.(*IntValue).Get()) } // Overflow returns true if x cannot be represented by the type of v. func (v *IntValue) Overflow(x int64) bool { bitSize := uint(v.typ.Bits()) trunc := (x << (64 - bitSize)) >> (64 - bitSize) return x != trunc } // StringHeader is the runtime representation of a string. type StringHeader struct { Data uintptr Len int } // StringValue represents a string value. type StringValue struct { value "string" } // Get returns the underlying string value. func (v *StringValue) Get() string { return *(*string)(v.addr) } // Set sets v to the value x. func (v *StringValue) Set(x string) { if !v.CanSet() { panic(cannotSet) } *(*string)(v.addr) = x } // Set sets v to the value x. func (v *StringValue) SetValue(x Value) { v.Set(x.(*StringValue).Get()) } // UintValue represents a uint value. type UintValue struct { value "uint" } // Get returns the underlying uuint value. func (v *UintValue) Get() uint64 { switch v.typ.Kind() { case Uint: return uint64(*(*uint)(v.addr)) case Uint8: return uint64(*(*uint8)(v.addr)) case Uint16: return uint64(*(*uint16)(v.addr)) case Uint32: return uint64(*(*uint32)(v.addr)) case Uint64: return *(*uint64)(v.addr) case Uintptr: return uint64(*(*uintptr)(v.addr)) } panic("reflect: invalid uint kind") } // Set sets v to the value x. func (v *UintValue) Set(x uint64) { if !v.CanSet() { panic(cannotSet) } switch v.typ.Kind() { default: panic("reflect: invalid uint kind") case Uint: *(*uint)(v.addr) = uint(x) case Uint8: *(*uint8)(v.addr) = uint8(x) case Uint16: *(*uint16)(v.addr) = uint16(x) case Uint32: *(*uint32)(v.addr) = uint32(x) case Uint64: *(*uint64)(v.addr) = x case Uintptr: *(*uintptr)(v.addr) = uintptr(x) } } // Overflow returns true if x cannot be represented by the type of v. func (v *UintValue) Overflow(x uint64) bool { bitSize := uint(v.typ.Bits()) trunc := (x << (64 - bitSize)) >> (64 - bitSize) return x != trunc } // Set sets v to the value x. func (v *UintValue) SetValue(x Value) { v.Set(x.(*UintValue).Get()) } // UnsafePointerValue represents an unsafe.Pointer value. type UnsafePointerValue struct { value "unsafe.Pointer" } // Get returns the underlying uintptr value. // Get returns uintptr, not unsafe.Pointer, so that // programs that do not import "unsafe" cannot // obtain a value of unsafe.Pointer type from "reflect". func (v *UnsafePointerValue) Get() uintptr { return uintptr(*(*unsafe.Pointer)(v.addr)) } // Set sets v to the value x. func (v *UnsafePointerValue) Set(x unsafe.Pointer) { if !v.CanSet() { panic(cannotSet) } *(*unsafe.Pointer)(v.addr) = x } // Set sets v to the value x. func (v *UnsafePointerValue) SetValue(x Value) { v.Set(unsafe.Pointer(x.(*UnsafePointerValue).Get())) } func typesMustMatch(t1, t2 Type) { if t1 != t2 { panic("type mismatch: " + t1.String() + " != " + t2.String()) } } /* * array */ // ArrayOrSliceValue is the common interface // implemented by both ArrayValue and SliceValue. type ArrayOrSliceValue interface { Value Len() int Cap() int Elem(i int) Value addr() addr } // grow grows the slice s so that it can hold extra more values, allocating // more capacity if needed. It also returns the old and new slice lengths. func grow(s *SliceValue, extra int) (*SliceValue, int, int) { i0 := s.Len() i1 := i0 + extra if i1 < i0 { panic("append: slice overflow") } m := s.Cap() if i1 <= m { return s.Slice(0, i1), i0, i1 } if m == 0 { m = extra } else { for m < i1 { if i0 < 1024 { m += m } else { m += m / 4 } } } t := MakeSlice(s.Type().(*SliceType), i1, m) Copy(t, s) return t, i0, i1 } // Append appends the values x to a slice s and returns the resulting slice. // Each x must have the same type as s' element type. func Append(s *SliceValue, x ...Value) *SliceValue { s, i0, i1 := grow(s, len(x)) for i, j := i0, 0; i < i1; i, j = i+1, j+1 { s.Elem(i).SetValue(x[j]) } return s } // AppendSlice appends a slice t to a slice s and returns the resulting slice. // The slices s and t must have the same element type. func AppendSlice(s, t *SliceValue) *SliceValue { s, i0, i1 := grow(s, t.Len()) Copy(s.Slice(i0, i1), t) return s } // Copy copies the contents of src into dst until either // dst has been filled or src has been exhausted. // It returns the number of elements copied. // The arrays dst and src must have the same element type. func Copy(dst, src ArrayOrSliceValue) int { // TODO: This will have to move into the runtime // once the real gc goes in. de := dst.Type().(ArrayOrSliceType).Elem() se := src.Type().(ArrayOrSliceType).Elem() typesMustMatch(de, se) n := dst.Len() if xn := src.Len(); n > xn { n = xn } memmove(dst.addr(), src.addr(), uintptr(n)*de.Size()) return n } // An ArrayValue represents an array. type ArrayValue struct { value "array" } // Len returns the length of the array. func (v *ArrayValue) Len() int { return v.typ.(*ArrayType).Len() } // Cap returns the capacity of the array (equal to Len()). func (v *ArrayValue) Cap() int { return v.typ.(*ArrayType).Len() } // addr returns the base address of the data in the array. func (v *ArrayValue) addr() addr { return v.value.addr } // Set assigns x to v. // The new value x must have the same type as v. func (v *ArrayValue) Set(x *ArrayValue) { if !v.CanSet() { panic(cannotSet) } typesMustMatch(v.typ, x.typ) Copy(v, x) } // Set sets v to the value x. func (v *ArrayValue) SetValue(x Value) { v.Set(x.(*ArrayValue)) } // Elem returns the i'th element of v. func (v *ArrayValue) Elem(i int) Value { typ := v.typ.(*ArrayType).Elem() n := v.Len() if i < 0 || i >= n { panic("array index out of bounds") } p := addr(uintptr(v.addr()) + uintptr(i)*typ.Size()) return newValue(typ, p, v.flag) } /* * slice */ // runtime representation of slice type SliceHeader struct { Data uintptr Len int Cap int } // A SliceValue represents a slice. type SliceValue struct { value "slice" } func (v *SliceValue) slice() *SliceHeader { return (*SliceHeader)(v.value.addr) } // IsNil returns whether v is a nil slice. func (v *SliceValue) IsNil() bool { return v.slice().Data == 0 } // Len returns the length of the slice. func (v *SliceValue) Len() int { return int(v.slice().Len) } // Cap returns the capacity of the slice. func (v *SliceValue) Cap() int { return int(v.slice().Cap) } // addr returns the base address of the data in the slice. func (v *SliceValue) addr() addr { return addr(v.slice().Data) } // SetLen changes the length of v. // The new length n must be between 0 and the capacity, inclusive. func (v *SliceValue) SetLen(n int) { s := v.slice() if n < 0 || n > int(s.Cap) { panic("reflect: slice length out of range in SetLen") } s.Len = n } // Set assigns x to v. // The new value x must have the same type as v. func (v *SliceValue) Set(x *SliceValue) { if !v.CanSet() { panic(cannotSet) } typesMustMatch(v.typ, x.typ) *v.slice() = *x.slice() } // Set sets v to the value x. func (v *SliceValue) SetValue(x Value) { v.Set(x.(*SliceValue)) } // Get returns the uintptr address of the v.Cap()'th element. This gives // the same result for all slices of the same array. // It is mainly useful for printing. func (v *SliceValue) Get() uintptr { typ := v.typ.(*SliceType) return uintptr(v.addr()) + uintptr(v.Cap())*typ.Elem().Size() } // Slice returns a sub-slice of the slice v. func (v *SliceValue) Slice(beg, end int) *SliceValue { cap := v.Cap() if beg < 0 || end < beg || end > cap { panic("slice index out of bounds") } typ := v.typ.(*SliceType) s := new(SliceHeader) s.Data = uintptr(v.addr()) + uintptr(beg)*typ.Elem().Size() s.Len = end - beg s.Cap = cap - beg // Like the result of Addr, we treat Slice as an // unaddressable temporary, so don't set canAddr. flag := canSet if v.flag&canStore != 0 { flag |= canStore } return newValue(typ, addr(s), flag).(*SliceValue) } // Elem returns the i'th element of v. func (v *SliceValue) Elem(i int) Value { typ := v.typ.(*SliceType).Elem() n := v.Len() if i < 0 || i >= n { panic("reflect: slice index out of range") } p := addr(uintptr(v.addr()) + uintptr(i)*typ.Size()) flag := canAddr if v.flag&canStore != 0 { flag |= canSet | canStore } return newValue(typ, p, flag) } // MakeSlice creates a new zero-initialized slice value // for the specified slice type, length, and capacity. func MakeSlice(typ *SliceType, len, cap int) *SliceValue { s := &SliceHeader{ Data: uintptr(unsafe.NewArray(typ.Elem(), cap)), Len: len, Cap: cap, } return newValue(typ, addr(s), canAddr|canSet|canStore).(*SliceValue) } /* * chan */ // A ChanValue represents a chan. type ChanValue struct { value "chan" } // IsNil returns whether v is a nil channel. func (v *ChanValue) IsNil() bool { return *(*uintptr)(v.addr) == 0 } // Set assigns x to v. // The new value x must have the same type as v. func (v *ChanValue) Set(x *ChanValue) { if !v.CanSet() { panic(cannotSet) } typesMustMatch(v.typ, x.typ) *(*uintptr)(v.addr) = *(*uintptr)(x.addr) } // Set sets v to the value x. func (v *ChanValue) SetValue(x Value) { v.Set(x.(*ChanValue)) } // Get returns the uintptr value of v. // It is mainly useful for printing. func (v *ChanValue) Get() uintptr { return *(*uintptr)(v.addr) } // implemented in ../pkg/runtime/reflect.cgo func makechan(typ *runtime.ChanType, size uint32) (ch *byte) func chansend(ch, val *byte, pres *bool) func chanrecv(ch, val *byte, pres *bool) func chanclosed(ch *byte) bool func chanclose(ch *byte) func chanlen(ch *byte) int32 func chancap(ch *byte) int32 // Closed returns the result of closed(c) on the underlying channel. func (v *ChanValue) Closed() bool { ch := *(**byte)(v.addr) return chanclosed(ch) } // Close closes the channel. func (v *ChanValue) Close() { ch := *(**byte)(v.addr) chanclose(ch) } func (v *ChanValue) Len() int { ch := *(**byte)(v.addr) return int(chanlen(ch)) } func (v *ChanValue) Cap() int { ch := *(**byte)(v.addr) return int(chancap(ch)) } // internal send; non-blocking if b != nil func (v *ChanValue) send(x Value, b *bool) { t := v.Type().(*ChanType) if t.Dir()&SendDir == 0 { panic("send on recv-only channel") } typesMustMatch(t.Elem(), x.Type()) ch := *(**byte)(v.addr) chansend(ch, (*byte)(x.getAddr()), b) } // internal recv; non-blocking if b != nil func (v *ChanValue) recv(b *bool) Value { t := v.Type().(*ChanType) if t.Dir()&RecvDir == 0 { panic("recv on send-only channel") } ch := *(**byte)(v.addr) x := MakeZero(t.Elem()) chanrecv(ch, (*byte)(x.getAddr()), b) return x } // Send sends x on the channel v. func (v *ChanValue) Send(x Value) { v.send(x, nil) } // Recv receives and returns a value from the channel v. func (v *ChanValue) Recv() Value { return v.recv(nil) } // TrySend attempts to sends x on the channel v but will not block. // It returns true if the value was sent, false otherwise. func (v *ChanValue) TrySend(x Value) bool { var ok bool v.send(x, &ok) return ok } // TryRecv attempts to receive a value from the channel v but will not block. // It returns the value if one is received, nil otherwise. func (v *ChanValue) TryRecv() Value { var ok bool x := v.recv(&ok) if !ok { return nil } return x } // MakeChan creates a new channel with the specified type and buffer size. func MakeChan(typ *ChanType, buffer int) *ChanValue { if buffer < 0 { panic("MakeChan: negative buffer size") } if typ.Dir() != BothDir { panic("MakeChan: unidirectional channel type") } v := MakeZero(typ).(*ChanValue) *(**byte)(v.addr) = makechan((*runtime.ChanType)(unsafe.Pointer(typ)), uint32(buffer)) return v } /* * func */ // A FuncValue represents a function value. type FuncValue struct { value "func" first *value isInterface bool } // IsNil returns whether v is a nil function. func (v *FuncValue) IsNil() bool { return *(*uintptr)(v.addr) == 0 } // Get returns the uintptr value of v. // It is mainly useful for printing. func (v *FuncValue) Get() uintptr { return *(*uintptr)(v.addr) } // Set assigns x to v. // The new value x must have the same type as v. func (v *FuncValue) Set(x *FuncValue) { if !v.CanSet() { panic(cannotSet) } typesMustMatch(v.typ, x.typ) *(*uintptr)(v.addr) = *(*uintptr)(x.addr) } // Set sets v to the value x. func (v *FuncValue) SetValue(x Value) { v.Set(x.(*FuncValue)) } // Method returns a FuncValue corresponding to v's i'th method. // The arguments to a Call on the returned FuncValue // should not include a receiver; the FuncValue will use v // as the receiver. func (v *value) Method(i int) *FuncValue { t := v.Type().uncommon() if t == nil || i < 0 || i >= len(t.methods) { return nil } p := &t.methods[i] fn := p.tfn fv := &FuncValue{value: value{runtimeToType(p.typ), addr(&fn), 0}, first: v, isInterface: false} return fv } // implemented in ../pkg/runtime/*/asm.s func call(typ *FuncType, fnaddr *byte, isInterface bool, params *addr, results *addr) // Interface returns the fv as an interface value. // If fv is a method obtained by invoking Value.Method // (as opposed to Type.Method), Interface cannot return an // interface value, so it panics. func (fv *FuncValue) Interface() interface{} { if fv.first != nil { panic("FuncValue: cannot create interface value for method with bound receiver") } return fv.value.Interface() } // Call calls the function fv with input parameters in. // It returns the function's output parameters as Values. func (fv *FuncValue) Call(in []Value) []Value { t := fv.Type().(*FuncType) nin := len(in) if fv.first != nil && !fv.isInterface { nin++ } if nin != t.NumIn() { panic("FuncValue: wrong argument count") } if fv.first != nil && fv.isInterface { nin++ } nout := t.NumOut() params := make([]addr, nin) delta := 0 off := 0 if v := fv.first; v != nil { // Hard-wired first argument. if fv.isInterface { // v is a single uninterpreted word params[0] = v.getAddr() } else { // v is a real value tv := v.Type() // This is a method, so we need to always pass // a pointer. vAddr := v.getAddr() if ptv, ok := tv.(*PtrType); ok { typesMustMatch(t.In(0), tv) } else { p := addr(new(addr)) *(*addr)(p) = vAddr vAddr = p typesMustMatch(t.In(0).(*PtrType).Elem(), tv) } params[0] = vAddr delta = 1 } off = 1 } for i, v := range in { tv := v.Type() tf := t.In(i + delta) // If this is really a method, and we are explicitly // passing the object, then we need to pass the address // of the object instead. Unfortunately, we don't // have any way to know that this is a method, so we just // check the type. FIXME: This is ugly. vAddr := v.getAddr() if i == 0 && tf != tv { if ptf, ok := tf.(*PtrType); ok { p := addr(new(addr)) *(*addr)(p) = vAddr vAddr = p tf = ptf.Elem() } } typesMustMatch(tf, tv) params[i+off] = vAddr } ret := make([]Value, nout) results := make([]addr, nout) for i := 0; i < nout; i++ { tv := t.Out(i) v := MakeZero(tv) results[i] = v.getAddr() ret[i] = v } call(t, *(**byte)(fv.addr), fv.isInterface, ¶ms[0], &results[0]) return ret } /* * interface */ // An InterfaceValue represents an interface value. type InterfaceValue struct { value "interface" } // IsNil returns whether v is a nil interface value. func (v *InterfaceValue) IsNil() bool { return v.Interface() == nil } // No single uinptr Get because v.Interface() is available. // Get returns the two words that represent an interface in the runtime. // Those words are useful only when playing unsafe games. func (v *InterfaceValue) Get() [2]uintptr { return *(*[2]uintptr)(v.addr) } // Elem returns the concrete value stored in the interface value v. func (v *InterfaceValue) Elem() Value { return NewValue(v.Interface()) } // ../runtime/reflect.cgo func setiface(typ *InterfaceType, x *interface{}, addr addr) // Set assigns x to v. func (v *InterfaceValue) Set(x Value) { var i interface{} if x != nil { i = x.Interface() } if !v.CanSet() { panic(cannotSet) } // Two different representations; see comment in Get. // Empty interface is easy. t := v.typ.(*InterfaceType) if t.NumMethod() == 0 { *(*interface{})(v.addr) = i return } // Non-empty interface requires a runtime check. setiface(t, &i, v.addr) } // Set sets v to the value x. func (v *InterfaceValue) SetValue(x Value) { v.Set(x) } // Method returns a FuncValue corresponding to v's i'th method. // The arguments to a Call on the returned FuncValue // should not include a receiver; the FuncValue will use v // as the receiver. func (v *InterfaceValue) Method(i int) *FuncValue { t := v.Type().(*InterfaceType) if t == nil || i < 0 || i >= len(t.methods) { return nil } p := &t.methods[i] // Interface is two words: itable, data. tab := *(**[10000]addr)(v.addr) data := &value{Typeof((*byte)(nil)), addr(uintptr(v.addr) + ptrSize), 0} fn := tab[i+1] fv := &FuncValue{value: value{runtimeToType(p.typ), addr(&fn), 0}, first: data, isInterface: true} return fv } /* * map */ // A MapValue represents a map value. type MapValue struct { value "map" } // IsNil returns whether v is a nil map value. func (v *MapValue) IsNil() bool { return *(*uintptr)(v.addr) == 0 } // Set assigns x to v. // The new value x must have the same type as v. func (v *MapValue) Set(x *MapValue) { if !v.CanSet() { panic(cannotSet) } if x == nil { *(**uintptr)(v.addr) = nil return } typesMustMatch(v.typ, x.typ) *(*uintptr)(v.addr) = *(*uintptr)(x.addr) } // Set sets v to the value x. func (v *MapValue) SetValue(x Value) { if x == nil { v.Set(nil) return } v.Set(x.(*MapValue)) } // Get returns the uintptr value of v. // It is mainly useful for printing. func (v *MapValue) Get() uintptr { return *(*uintptr)(v.addr) } // implemented in ../pkg/runtime/reflect.cgo func mapaccess(m, key, val *byte) bool func mapassign(m, key, val *byte) func maplen(m *byte) int32 func mapiterinit(m *byte) *byte func mapiternext(it *byte) func mapiterkey(it *byte, key *byte) bool func makemap(t *runtime.MapType) *byte // Elem returns the value associated with key in the map v. // It returns nil if key is not found in the map. func (v *MapValue) Elem(key Value) Value { t := v.Type().(*MapType) typesMustMatch(t.Key(), key.Type()) m := *(**byte)(v.addr) if m == nil { return nil } newval := MakeZero(t.Elem()) if !mapaccess(m, (*byte)(key.getAddr()), (*byte)(newval.getAddr())) { return nil } return newval } // SetElem sets the value associated with key in the map v to val. // If val is nil, Put deletes the key from map. func (v *MapValue) SetElem(key, val Value) { t := v.Type().(*MapType) typesMustMatch(t.Key(), key.Type()) var vaddr *byte if val != nil { typesMustMatch(t.Elem(), val.Type()) vaddr = (*byte)(val.getAddr()) } m := *(**byte)(v.addr) mapassign(m, (*byte)(key.getAddr()), vaddr) } // Len returns the number of keys in the map v. func (v *MapValue) Len() int { m := *(**byte)(v.addr) if m == nil { return 0 } return int(maplen(m)) } // Keys returns a slice containing all the keys present in the map, // in unspecified order. func (v *MapValue) Keys() []Value { tk := v.Type().(*MapType).Key() m := *(**byte)(v.addr) mlen := int32(0) if m != nil { mlen = maplen(m) } it := mapiterinit(m) a := make([]Value, mlen) var i int for i = 0; i < len(a); i++ { k := MakeZero(tk) if !mapiterkey(it, (*byte)(k.getAddr())) { break } a[i] = k mapiternext(it) } return a[0:i] } // MakeMap creates a new map of the specified type. func MakeMap(typ *MapType) *MapValue { v := MakeZero(typ).(*MapValue) *(**byte)(v.addr) = makemap((*runtime.MapType)(unsafe.Pointer(typ))) return v } /* * ptr */ // A PtrValue represents a pointer. type PtrValue struct { value "ptr" } // IsNil returns whether v is a nil pointer. func (v *PtrValue) IsNil() bool { return *(*uintptr)(v.addr) == 0 } // Get returns the uintptr value of v. // It is mainly useful for printing. func (v *PtrValue) Get() uintptr { return *(*uintptr)(v.addr) } // Set assigns x to v. // The new value x must have the same type as v, and x.Elem().CanSet() must be true. func (v *PtrValue) Set(x *PtrValue) { if x == nil { *(**uintptr)(v.addr) = nil return } if !v.CanSet() { panic(cannotSet) } if x.flag&canStore == 0 { panic("cannot copy pointer obtained from unexported struct field") } typesMustMatch(v.typ, x.typ) // TODO: This will have to move into the runtime // once the new gc goes in *(*uintptr)(v.addr) = *(*uintptr)(x.addr) } // Set sets v to the value x. func (v *PtrValue) SetValue(x Value) { if x == nil { v.Set(nil) return } v.Set(x.(*PtrValue)) } // PointTo changes v to point to x. // If x is a nil Value, PointTo sets v to nil. func (v *PtrValue) PointTo(x Value) { if x == nil { *(**uintptr)(v.addr) = nil return } if !x.CanSet() { panic("cannot set x; cannot point to x") } typesMustMatch(v.typ.(*PtrType).Elem(), x.Type()) // TODO: This will have to move into the runtime // once the new gc goes in. *(*uintptr)(v.addr) = x.UnsafeAddr() } // Elem returns the value that v points to. // If v is a nil pointer, Elem returns a nil Value. func (v *PtrValue) Elem() Value { if v.IsNil() { return nil } flag := canAddr if v.flag&canStore != 0 { flag |= canSet | canStore } return newValue(v.typ.(*PtrType).Elem(), *(*addr)(v.addr), flag) } // Indirect returns the value that v points to. // If v is a nil pointer, Indirect returns a nil Value. // If v is not a pointer, Indirect returns v. func Indirect(v Value) Value { if pv, ok := v.(*PtrValue); ok { return pv.Elem() } return v } /* * struct */ // A StructValue represents a struct value. type StructValue struct { value "struct" } // Set assigns x to v. // The new value x must have the same type as v. func (v *StructValue) Set(x *StructValue) { // TODO: This will have to move into the runtime // once the gc goes in. if !v.CanSet() { panic(cannotSet) } typesMustMatch(v.typ, x.typ) memmove(v.addr, x.addr, v.typ.Size()) } // Set sets v to the value x. func (v *StructValue) SetValue(x Value) { v.Set(x.(*StructValue)) } // Field returns the i'th field of the struct. func (v *StructValue) Field(i int) Value { t := v.typ.(*StructType) if i < 0 || i >= t.NumField() { return nil } f := t.Field(i) flag := v.flag if f.PkgPath != "" { // unexported field flag &^= canSet | canStore } return newValue(f.Type, addr(uintptr(v.addr)+f.Offset), flag) } // FieldByIndex returns the nested field corresponding to index. func (t *StructValue) FieldByIndex(index []int) (v Value) { v = t for i, x := range index { if i > 0 { if p, ok := v.(*PtrValue); ok { v = p.Elem() } if s, ok := v.(*StructValue); ok { t = s } else { v = nil return } } v = t.Field(x) } return } // FieldByName returns the struct field with the given name. // The result is nil if no field was found. func (t *StructValue) FieldByName(name string) Value { if f, ok := t.Type().(*StructType).FieldByName(name); ok { return t.FieldByIndex(f.Index) } return nil } // FieldByNameFunc returns the struct field with a name that satisfies the // match function. // The result is nil if no field was found. func (t *StructValue) FieldByNameFunc(match func(string) bool) Value { if f, ok := t.Type().(*StructType).FieldByNameFunc(match); ok { return t.FieldByIndex(f.Index) } return nil } // NumField returns the number of fields in the struct. func (v *StructValue) NumField() int { return v.typ.(*StructType).NumField() } /* * constructors */ // NewValue returns a new Value initialized to the concrete value // stored in the interface i. NewValue(nil) returns nil. func NewValue(i interface{}) Value { if i == nil { return nil } t, a := unsafe.Reflect(i) return newValue(canonicalize(toType(t)), addr(a), canSet|canAddr|canStore) } func newValue(typ Type, addr addr, flag uint32) Value { v := value{typ, addr, flag} switch typ.(type) { case *ArrayType: return &ArrayValue{v} case *BoolType: return &BoolValue{v} case *ChanType: return &ChanValue{v} case *FloatType: return &FloatValue{v} case *FuncType: return &FuncValue{value: v} case *ComplexType: return &ComplexValue{v} case *IntType: return &IntValue{v} case *InterfaceType: return &InterfaceValue{v} case *MapType: return &MapValue{v} case *PtrType: return &PtrValue{v} case *SliceType: return &SliceValue{v} case *StringType: return &StringValue{v} case *StructType: return &StructValue{v} case *UintType: return &UintValue{v} case *UnsafePointerType: return &UnsafePointerValue{v} } panic("newValue" + typ.String()) } // MakeZero returns a zero Value for the specified Type. func MakeZero(typ Type) Value { if typ == nil { return nil } return newValue(typ, addr(unsafe.New(typ)), canSet|canAddr|canStore) }