// +build !safe // +build !appengine // +build go1.7 // Copyright (c) 2012-2018 Ugorji Nwoke. All rights reserved. // Use of this source code is governed by a MIT license found in the LICENSE file. package codec import ( "reflect" "sync/atomic" "time" "unsafe" ) // This file has unsafe variants of some helper methods. // NOTE: See helper_not_unsafe.go for the usage information. // For reflect.Value code, we decided to do the following: // - if we know the kind, we can elide conditional checks for // - SetXXX (Int, Uint, String, Bool, etc) // - SetLen // // We can also optimize // - IsNil const safeMode = false // keep in sync with GO_ROOT/src/reflect/value.go const ( unsafeFlagIndir = 1 << 7 unsafeFlagAddr = 1 << 8 unsafeFlagKindMask = (1 << 5) - 1 // 5 bits for 27 kinds (up to 31) // unsafeTypeKindDirectIface = 1 << 5 ) type unsafeString struct { Data unsafe.Pointer Len int } type unsafeSlice struct { Data unsafe.Pointer Len int Cap int } type unsafeIntf struct { typ unsafe.Pointer word unsafe.Pointer } type unsafeReflectValue struct { typ unsafe.Pointer ptr unsafe.Pointer flag uintptr } func stringView(v []byte) string { if len(v) == 0 { return "" } bx := (*unsafeSlice)(unsafe.Pointer(&v)) return *(*string)(unsafe.Pointer(&unsafeString{bx.Data, bx.Len})) } func bytesView(v string) []byte { if len(v) == 0 { return zeroByteSlice } sx := (*unsafeString)(unsafe.Pointer(&v)) return *(*[]byte)(unsafe.Pointer(&unsafeSlice{sx.Data, sx.Len, sx.Len})) } // // isNilRef says whether the interface is a nil reference or not. // // // // A reference here is a pointer-sized reference i.e. map, ptr, chan, func, unsafepointer. // // It is optional to extend this to also check if slices or interfaces are nil also. // // // // NOTE: There is no global way of checking if an interface is nil. // // For true references (map, ptr, func, chan), you can just look // // at the word of the interface. // // However, for slices, you have to dereference // // the word, and get a pointer to the 3-word interface value. // func isNilRef(v interface{}) (rv reflect.Value, isnil bool) { // isnil = ((*unsafeIntf)(unsafe.Pointer(&v))).word == nil // return // } func isNil(v interface{}) (rv reflect.Value, isnil bool) { var ui = (*unsafeIntf)(unsafe.Pointer(&v)) if ui.word == nil { isnil = true return } rv = rv4i(v) // reflect.value is cheap and inline'able tk := rv.Kind() isnil = (tk == reflect.Interface || tk == reflect.Slice) && *(*unsafe.Pointer)(ui.word) == nil return } func rv2ptr(urv *unsafeReflectValue) (ptr unsafe.Pointer) { // true references (map, func, chan, ptr - NOT slice) may be double-referenced? as flagIndir if refBitset.isset(byte(urv.flag&unsafeFlagKindMask)) && urv.flag&unsafeFlagIndir != 0 { ptr = *(*unsafe.Pointer)(urv.ptr) } else { ptr = urv.ptr } return } func rv4i(i interface{}) (rv reflect.Value) { // Unfortunately, we cannot get the "kind" of the interface directly here. // We need the 'rtype', whose structure changes in different go versions. // Finally, it's not clear that there is benefit to reimplementing it, // as the "escapes(i)" is not clearly expensive since we want i to exist on the heap. return reflect.ValueOf(i) } func rv2i(rv reflect.Value) interface{} { // We tap into implememtation details from // the source go stdlib reflect/value.go, and trims the implementation. urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) return *(*interface{})(unsafe.Pointer(&unsafeIntf{typ: urv.typ, word: rv2ptr(urv)})) } func rvIsNil(rv reflect.Value) bool { urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) if urv.flag&unsafeFlagIndir != 0 { return *(*unsafe.Pointer)(urv.ptr) == nil } return urv.ptr == nil } func rvSetSliceLen(rv reflect.Value, length int) { urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) (*unsafeString)(urv.ptr).Len = length } func rvZeroAddrK(t reflect.Type, k reflect.Kind) (rv reflect.Value) { urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) urv.flag = uintptr(k) | unsafeFlagIndir | unsafeFlagAddr urv.typ = ((*unsafeIntf)(unsafe.Pointer(&t))).word urv.ptr = unsafe_New(urv.typ) return } func rvConvert(v reflect.Value, t reflect.Type) (rv reflect.Value) { uv := (*unsafeReflectValue)(unsafe.Pointer(&v)) urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) *urv = *uv urv.typ = ((*unsafeIntf)(unsafe.Pointer(&t))).word return } func rt2id(rt reflect.Type) uintptr { return uintptr(((*unsafeIntf)(unsafe.Pointer(&rt))).word) } func i2rtid(i interface{}) uintptr { return uintptr(((*unsafeIntf)(unsafe.Pointer(&i))).typ) } // -------------------------- func isEmptyValue(v reflect.Value, tinfos *TypeInfos, deref, checkStruct bool) bool { urv := (*unsafeReflectValue)(unsafe.Pointer(&v)) if urv.flag == 0 { return true } switch v.Kind() { case reflect.Invalid: return true case reflect.String: return (*unsafeString)(urv.ptr).Len == 0 case reflect.Slice: return (*unsafeSlice)(urv.ptr).Len == 0 case reflect.Bool: return !*(*bool)(urv.ptr) case reflect.Int: return *(*int)(urv.ptr) == 0 case reflect.Int8: return *(*int8)(urv.ptr) == 0 case reflect.Int16: return *(*int16)(urv.ptr) == 0 case reflect.Int32: return *(*int32)(urv.ptr) == 0 case reflect.Int64: return *(*int64)(urv.ptr) == 0 case reflect.Uint: return *(*uint)(urv.ptr) == 0 case reflect.Uint8: return *(*uint8)(urv.ptr) == 0 case reflect.Uint16: return *(*uint16)(urv.ptr) == 0 case reflect.Uint32: return *(*uint32)(urv.ptr) == 0 case reflect.Uint64: return *(*uint64)(urv.ptr) == 0 case reflect.Uintptr: return *(*uintptr)(urv.ptr) == 0 case reflect.Float32: return *(*float32)(urv.ptr) == 0 case reflect.Float64: return *(*float64)(urv.ptr) == 0 case reflect.Interface: isnil := urv.ptr == nil || *(*unsafe.Pointer)(urv.ptr) == nil if deref { if isnil { return true } return isEmptyValue(v.Elem(), tinfos, deref, checkStruct) } return isnil case reflect.Ptr: // isnil := urv.ptr == nil // (not sufficient, as a pointer value encodes the type) isnil := urv.ptr == nil || *(*unsafe.Pointer)(urv.ptr) == nil if deref { if isnil { return true } return isEmptyValue(v.Elem(), tinfos, deref, checkStruct) } return isnil case reflect.Struct: return isEmptyStruct(v, tinfos, deref, checkStruct) case reflect.Map, reflect.Array, reflect.Chan: return v.Len() == 0 } return false } // -------------------------- // atomicXXX is expected to be 2 words (for symmetry with atomic.Value) // // Note that we do not atomically load/store length and data pointer separately, // as this could lead to some races. Instead, we atomically load/store cappedSlice. // // Note: with atomic.(Load|Store)Pointer, we MUST work with an unsafe.Pointer directly. // ---------------------- type atomicTypeInfoSlice struct { v unsafe.Pointer // *[]rtid2ti _ uint64 // padding (atomicXXX expected to be 2 words) } func (x *atomicTypeInfoSlice) load() (s []rtid2ti) { x2 := atomic.LoadPointer(&x.v) if x2 != nil { s = *(*[]rtid2ti)(x2) } return } func (x *atomicTypeInfoSlice) store(p []rtid2ti) { atomic.StorePointer(&x.v, unsafe.Pointer(&p)) } // -------------------------- type atomicRtidFnSlice struct { v unsafe.Pointer // *[]codecRtidFn _ uint64 // padding (atomicXXX expected to be 2 words) (make 1 word so JsonHandle fits) } func (x *atomicRtidFnSlice) load() (s []codecRtidFn) { x2 := atomic.LoadPointer(&x.v) if x2 != nil { s = *(*[]codecRtidFn)(x2) } return } func (x *atomicRtidFnSlice) store(p []codecRtidFn) { atomic.StorePointer(&x.v, unsafe.Pointer(&p)) } // -------------------------- type atomicClsErr struct { v unsafe.Pointer // *clsErr _ uint64 // padding (atomicXXX expected to be 2 words) } func (x *atomicClsErr) load() (e clsErr) { x2 := (*clsErr)(atomic.LoadPointer(&x.v)) if x2 != nil { e = *x2 } return } func (x *atomicClsErr) store(p clsErr) { atomic.StorePointer(&x.v, unsafe.Pointer(&p)) } // -------------------------- // to create a reflect.Value for each member field of decNaked, // we first create a global decNaked, and create reflect.Value // for them all. // This way, we have the flags and type in the reflect.Value. // Then, when a reflect.Value is called, we just copy it, // update the ptr to the decNaked's, and return it. type unsafeDecNakedWrapper struct { decNaked ru, ri, rf, rl, rs, rb, rt reflect.Value // mapping to the primitives above } func (n *unsafeDecNakedWrapper) init() { n.ru = rv4i(&n.u).Elem() n.ri = rv4i(&n.i).Elem() n.rf = rv4i(&n.f).Elem() n.rl = rv4i(&n.l).Elem() n.rs = rv4i(&n.s).Elem() n.rt = rv4i(&n.t).Elem() n.rb = rv4i(&n.b).Elem() // n.rr[] = rv4i(&n.) } var defUnsafeDecNakedWrapper unsafeDecNakedWrapper func init() { defUnsafeDecNakedWrapper.init() } func (n *decNaked) ru() (v reflect.Value) { v = defUnsafeDecNakedWrapper.ru ((*unsafeReflectValue)(unsafe.Pointer(&v))).ptr = unsafe.Pointer(&n.u) return } func (n *decNaked) ri() (v reflect.Value) { v = defUnsafeDecNakedWrapper.ri ((*unsafeReflectValue)(unsafe.Pointer(&v))).ptr = unsafe.Pointer(&n.i) return } func (n *decNaked) rf() (v reflect.Value) { v = defUnsafeDecNakedWrapper.rf ((*unsafeReflectValue)(unsafe.Pointer(&v))).ptr = unsafe.Pointer(&n.f) return } func (n *decNaked) rl() (v reflect.Value) { v = defUnsafeDecNakedWrapper.rl ((*unsafeReflectValue)(unsafe.Pointer(&v))).ptr = unsafe.Pointer(&n.l) return } func (n *decNaked) rs() (v reflect.Value) { v = defUnsafeDecNakedWrapper.rs ((*unsafeReflectValue)(unsafe.Pointer(&v))).ptr = unsafe.Pointer(&n.s) return } func (n *decNaked) rt() (v reflect.Value) { v = defUnsafeDecNakedWrapper.rt ((*unsafeReflectValue)(unsafe.Pointer(&v))).ptr = unsafe.Pointer(&n.t) return } func (n *decNaked) rb() (v reflect.Value) { v = defUnsafeDecNakedWrapper.rb ((*unsafeReflectValue)(unsafe.Pointer(&v))).ptr = unsafe.Pointer(&n.b) return } // -------------------------- func rvSetBytes(rv reflect.Value, v []byte) { urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) *(*[]byte)(urv.ptr) = v } func rvSetString(rv reflect.Value, v string) { urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) *(*string)(urv.ptr) = v } func rvSetBool(rv reflect.Value, v bool) { urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) *(*bool)(urv.ptr) = v } func rvSetTime(rv reflect.Value, v time.Time) { urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) *(*time.Time)(urv.ptr) = v } func rvSetFloat32(rv reflect.Value, v float32) { urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) *(*float32)(urv.ptr) = v } func rvSetFloat64(rv reflect.Value, v float64) { urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) *(*float64)(urv.ptr) = v } func rvSetInt(rv reflect.Value, v int) { urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) *(*int)(urv.ptr) = v } func rvSetInt8(rv reflect.Value, v int8) { urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) *(*int8)(urv.ptr) = v } func rvSetInt16(rv reflect.Value, v int16) { urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) *(*int16)(urv.ptr) = v } func rvSetInt32(rv reflect.Value, v int32) { urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) *(*int32)(urv.ptr) = v } func rvSetInt64(rv reflect.Value, v int64) { urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) *(*int64)(urv.ptr) = v } func rvSetUint(rv reflect.Value, v uint) { urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) *(*uint)(urv.ptr) = v } func rvSetUintptr(rv reflect.Value, v uintptr) { urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) *(*uintptr)(urv.ptr) = v } func rvSetUint8(rv reflect.Value, v uint8) { urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) *(*uint8)(urv.ptr) = v } func rvSetUint16(rv reflect.Value, v uint16) { urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) *(*uint16)(urv.ptr) = v } func rvSetUint32(rv reflect.Value, v uint32) { urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) *(*uint32)(urv.ptr) = v } func rvSetUint64(rv reflect.Value, v uint64) { urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) *(*uint64)(urv.ptr) = v } // ---------------- // rvSetDirect is rv.Set for all kinds except reflect.Interface func rvSetDirect(rv reflect.Value, v reflect.Value) { urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) uv := (*unsafeReflectValue)(unsafe.Pointer(&v)) if uv.flag&unsafeFlagIndir == 0 { *(*unsafe.Pointer)(urv.ptr) = uv.ptr } else { typedmemmove(urv.typ, urv.ptr, uv.ptr) } } // rvSlice returns a slice of the slice of lenth func rvSlice(rv reflect.Value, length int) (v reflect.Value) { urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) uv := (*unsafeReflectValue)(unsafe.Pointer(&v)) *uv = *urv var x []unsafe.Pointer uv.ptr = unsafe.Pointer(&x) *(*unsafeSlice)(uv.ptr) = *(*unsafeSlice)(urv.ptr) (*unsafeSlice)(uv.ptr).Len = length return } // ------------ func rvSliceIndex(rv reflect.Value, i int, ti *typeInfo) (v reflect.Value) { urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) uv := (*unsafeReflectValue)(unsafe.Pointer(&v)) uv.ptr = unsafe.Pointer(uintptr(((*unsafeSlice)(urv.ptr)).Data) + (ti.elemsize * uintptr(i))) uv.typ = ((*unsafeIntf)(unsafe.Pointer(&ti.elem))).word uv.flag = uintptr(ti.elemkind) | unsafeFlagIndir | unsafeFlagAddr return } func rvGetSliceLen(rv reflect.Value) int { urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) return (*unsafeSlice)(urv.ptr).Len } func rvGetSliceCap(rv reflect.Value) int { urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) return (*unsafeSlice)(urv.ptr).Cap } func rvGetArrayBytesRO(rv reflect.Value, scratch []byte) (bs []byte) { l := rv.Len() urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) bx := (*unsafeSlice)(unsafe.Pointer(&bs)) bx.Data = urv.ptr bx.Len, bx.Cap = l, l return } func rvGetArray4Slice(rv reflect.Value) (v reflect.Value) { // It is possible that this slice is based off an array with a larger // len that we want (where array len == slice cap). // However, it is ok to create an array type that is a subset of the full // e.g. full slice is based off a *[16]byte, but we can create a *[4]byte // off of it. That is ok. // // Consequently, we use rvGetSliceLen, not rvGetSliceCap. t := reflectArrayOf(rvGetSliceLen(rv), rv.Type().Elem()) // v = rvZeroAddrK(t, reflect.Array) uv := (*unsafeReflectValue)(unsafe.Pointer(&v)) uv.flag = uintptr(reflect.Array) | unsafeFlagIndir | unsafeFlagAddr uv.typ = ((*unsafeIntf)(unsafe.Pointer(&t))).word urv := (*unsafeReflectValue)(unsafe.Pointer(&rv)) uv.ptr = *(*unsafe.Pointer)(urv.ptr) // slice rv has a ptr to the slice. return } func rvGetSlice4Array(rv reflect.Value, tslice reflect.Type) (v reflect.Value) { uv := (*unsafeReflectValue)(unsafe.Pointer(&v)) var x []unsafe.Pointer uv.ptr = unsafe.Pointer(&x) uv.typ = ((*unsafeIntf)(unsafe.Pointer(&tslice))).word uv.flag = unsafeFlagIndir | uintptr(reflect.Slice) s := (*unsafeSlice)(uv.ptr) s.Data = ((*unsafeReflectValue)(unsafe.Pointer(&rv))).ptr s.Len = rv.Len() s.Cap = s.Len return } func rvCopySlice(dest, src reflect.Value) { t := dest.Type().Elem() urv := (*unsafeReflectValue)(unsafe.Pointer(&dest)) destPtr := urv.ptr urv = (*unsafeReflectValue)(unsafe.Pointer(&src)) typedslicecopy((*unsafeIntf)(unsafe.Pointer(&t)).word, *(*unsafeSlice)(destPtr), *(*unsafeSlice)(urv.ptr)) } // ------------ func rvGetBool(rv reflect.Value) bool { v := (*unsafeReflectValue)(unsafe.Pointer(&rv)) return *(*bool)(v.ptr) } func rvGetBytes(rv reflect.Value) []byte { v := (*unsafeReflectValue)(unsafe.Pointer(&rv)) return *(*[]byte)(v.ptr) } func rvGetTime(rv reflect.Value) time.Time { v := (*unsafeReflectValue)(unsafe.Pointer(&rv)) return *(*time.Time)(v.ptr) } func rvGetString(rv reflect.Value) string { v := (*unsafeReflectValue)(unsafe.Pointer(&rv)) return *(*string)(v.ptr) } func rvGetFloat64(rv reflect.Value) float64 { v := (*unsafeReflectValue)(unsafe.Pointer(&rv)) return *(*float64)(v.ptr) } func rvGetFloat32(rv reflect.Value) float32 { v := (*unsafeReflectValue)(unsafe.Pointer(&rv)) return *(*float32)(v.ptr) } func rvGetInt(rv reflect.Value) int { v := (*unsafeReflectValue)(unsafe.Pointer(&rv)) return *(*int)(v.ptr) } func rvGetInt8(rv reflect.Value) int8 { v := (*unsafeReflectValue)(unsafe.Pointer(&rv)) return *(*int8)(v.ptr) } func rvGetInt16(rv reflect.Value) int16 { v := (*unsafeReflectValue)(unsafe.Pointer(&rv)) return *(*int16)(v.ptr) } func rvGetInt32(rv reflect.Value) int32 { v := (*unsafeReflectValue)(unsafe.Pointer(&rv)) return *(*int32)(v.ptr) } func rvGetInt64(rv reflect.Value) int64 { v := (*unsafeReflectValue)(unsafe.Pointer(&rv)) return *(*int64)(v.ptr) } func rvGetUint(rv reflect.Value) uint { v := (*unsafeReflectValue)(unsafe.Pointer(&rv)) return *(*uint)(v.ptr) } func rvGetUint8(rv reflect.Value) uint8 { v := (*unsafeReflectValue)(unsafe.Pointer(&rv)) return *(*uint8)(v.ptr) } func rvGetUint16(rv reflect.Value) uint16 { v := (*unsafeReflectValue)(unsafe.Pointer(&rv)) return *(*uint16)(v.ptr) } func rvGetUint32(rv reflect.Value) uint32 { v := (*unsafeReflectValue)(unsafe.Pointer(&rv)) return *(*uint32)(v.ptr) } func rvGetUint64(rv reflect.Value) uint64 { v := (*unsafeReflectValue)(unsafe.Pointer(&rv)) return *(*uint64)(v.ptr) } func rvGetUintptr(rv reflect.Value) uintptr { v := (*unsafeReflectValue)(unsafe.Pointer(&rv)) return *(*uintptr)(v.ptr) } // ------------ map range and map indexing ---------- // regular calls to map via reflection: MapKeys, MapIndex, MapRange/MapIter etc // will always allocate for each map key or value. // // It is more performant to provide a value that the map entry is set into, // and that elides the allocation. // unsafeMapHashIter // // go 1.4+ has runtime/hashmap.go or runtime/map.go which has a // hIter struct with the first 2 values being key and value // of the current iteration. // // This *hIter is passed to mapiterinit, mapiternext, mapiterkey, mapiterelem. // We bypass the reflect wrapper functions and just use the *hIter directly. // // Though *hIter has many fields, we only care about the first 2. type unsafeMapHashIter struct { key, value unsafe.Pointer // other fields are ignored } type mapIter struct { unsafeMapIter } type unsafeMapIter struct { it *unsafeMapHashIter // k, v reflect.Value mtyp, ktyp, vtyp unsafe.Pointer mptr, kptr, vptr unsafe.Pointer kisref, visref bool mapvalues bool done bool started bool // _ [2]uint64 // padding (cache-aligned) } func (t *unsafeMapIter) ValidKV() (r bool) { return false } func (t *unsafeMapIter) Next() (r bool) { if t == nil || t.done { return } if t.started { mapiternext((unsafe.Pointer)(t.it)) } else { t.started = true } t.done = t.it.key == nil if t.done { return } unsafeMapSet(t.kptr, t.ktyp, t.it.key, t.kisref) if t.mapvalues { unsafeMapSet(t.vptr, t.vtyp, t.it.value, t.visref) } return true } func (t *unsafeMapIter) Key() (r reflect.Value) { return } func (t *unsafeMapIter) Value() (r reflect.Value) { return } func (t *unsafeMapIter) Done() { } func unsafeMapSet(p, ptyp, p2 unsafe.Pointer, isref bool) { if isref { *(*unsafe.Pointer)(p) = *(*unsafe.Pointer)(p2) // p2 } else { typedmemmove(ptyp, p, p2) // *(*unsafe.Pointer)(p2)) // p2) } } func unsafeMapKVPtr(urv *unsafeReflectValue) unsafe.Pointer { if urv.flag&unsafeFlagIndir == 0 { return unsafe.Pointer(&urv.ptr) } return urv.ptr } func mapRange(t *mapIter, m, k, v reflect.Value, mapvalues bool) { if rvIsNil(m) { t.done = true return } t.done = false t.started = false t.mapvalues = mapvalues var urv *unsafeReflectValue urv = (*unsafeReflectValue)(unsafe.Pointer(&m)) t.mtyp = urv.typ t.mptr = rv2ptr(urv) t.it = (*unsafeMapHashIter)(mapiterinit(t.mtyp, t.mptr)) urv = (*unsafeReflectValue)(unsafe.Pointer(&k)) t.ktyp = urv.typ t.kptr = urv.ptr t.kisref = refBitset.isset(byte(k.Kind())) if mapvalues { urv = (*unsafeReflectValue)(unsafe.Pointer(&v)) t.vtyp = urv.typ t.vptr = urv.ptr t.visref = refBitset.isset(byte(v.Kind())) } else { t.vtyp = nil t.vptr = nil } } func mapGet(m, k, v reflect.Value) (vv reflect.Value) { var urv = (*unsafeReflectValue)(unsafe.Pointer(&k)) var kptr = unsafeMapKVPtr(urv) urv = (*unsafeReflectValue)(unsafe.Pointer(&m)) vvptr := mapaccess(urv.typ, rv2ptr(urv), kptr) if vvptr == nil { return } // vvptr = *(*unsafe.Pointer)(vvptr) urv = (*unsafeReflectValue)(unsafe.Pointer(&v)) unsafeMapSet(urv.ptr, urv.typ, vvptr, refBitset.isset(byte(v.Kind()))) return v } func mapSet(m, k, v reflect.Value) { var urv = (*unsafeReflectValue)(unsafe.Pointer(&k)) var kptr = unsafeMapKVPtr(urv) urv = (*unsafeReflectValue)(unsafe.Pointer(&v)) var vptr = unsafeMapKVPtr(urv) urv = (*unsafeReflectValue)(unsafe.Pointer(&m)) mapassign(urv.typ, rv2ptr(urv), kptr, vptr) } // func mapDelete(m, k reflect.Value) { // var urv = (*unsafeReflectValue)(unsafe.Pointer(&k)) // var kptr = unsafeMapKVPtr(urv) // urv = (*unsafeReflectValue)(unsafe.Pointer(&m)) // mapdelete(urv.typ, rv2ptr(urv), kptr) // } // return an addressable reflect value that can be used in mapRange and mapGet operations. // // all calls to mapGet or mapRange will call here to get an addressable reflect.Value. func mapAddressableRV(t reflect.Type, k reflect.Kind) (r reflect.Value) { // return reflect.New(t).Elem() return rvZeroAddrK(t, k) } //go:linkname mapiterinit reflect.mapiterinit //go:noescape func mapiterinit(typ unsafe.Pointer, it unsafe.Pointer) (key unsafe.Pointer) //go:linkname mapiternext reflect.mapiternext //go:noescape func mapiternext(it unsafe.Pointer) (key unsafe.Pointer) //go:linkname mapaccess reflect.mapaccess //go:noescape func mapaccess(typ unsafe.Pointer, m unsafe.Pointer, key unsafe.Pointer) (val unsafe.Pointer) //go:linkname mapassign reflect.mapassign //go:noescape func mapassign(typ unsafe.Pointer, m unsafe.Pointer, key, val unsafe.Pointer) //go:linkname mapdelete reflect.mapdelete //go:noescape func mapdelete(typ unsafe.Pointer, m unsafe.Pointer, key unsafe.Pointer) //go:linkname typedmemmove reflect.typedmemmove //go:noescape func typedmemmove(typ unsafe.Pointer, dst, src unsafe.Pointer) //go:linkname unsafe_New reflect.unsafe_New //go:noescape func unsafe_New(typ unsafe.Pointer) unsafe.Pointer //go:linkname typedslicecopy reflect.typedslicecopy //go:noescape func typedslicecopy(elemType unsafe.Pointer, dst, src unsafeSlice) int // ---------- ENCODER optimized --------------- func (e *Encoder) jsondriver() *jsonEncDriver { return (*jsonEncDriver)((*unsafeIntf)(unsafe.Pointer(&e.e)).word) } // ---------- DECODER optimized --------------- func (d *Decoder) checkBreak() bool { // jsonDecDriver.CheckBreak() CANNOT be inlined. // Consequently, there's no benefit in incurring the cost of this // wrapping function checkBreak. // // It is faster to just call the interface method directly. // if d.js { // return d.jsondriver().CheckBreak() // } // if d.cbor { // return d.cbordriver().CheckBreak() // } return d.d.CheckBreak() } func (d *Decoder) jsondriver() *jsonDecDriver { return (*jsonDecDriver)((*unsafeIntf)(unsafe.Pointer(&d.d)).word) } // func (d *Decoder) cbordriver() *cborDecDriver { // return (*cborDecDriver)((*unsafeIntf)(unsafe.Pointer(&d.d)).word) // }