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gotosocial/vendor/github.com/ugorji/go/codec/simple.mono.generated.go
kim 8b0ea56027 [chore] update go dependencies (#4304) 
- github.com/KimMachineGun/automemlimit v0.7.2 => v0.7.3
- github.com/gin-contrib/cors v1.7.5 => v1.7.6
- github.com/minio/minio-go/v7 v7.0.92 => v7.0.94
- github.com/spf13/cast v1.8.0 => v1.9.2
- github.com/uptrace/bun{,/*} v1.2.11 => v1.2.14
- golang.org/x/image v0.27.0 => v0.28.0
- golang.org/x/net v0.40.0 => v0.41.0
- code.superseriousbusiness.org/go-swagger v0.31.0-gts-go1.23-fix => v0.32.3-gts-go1.23-fix

Reviewed-on: https://codeberg.org/superseriousbusiness/gotosocial/pulls/4304
Co-authored-by: kim <grufwub@gmail.com>
Co-committed-by: kim <grufwub@gmail.com>
2025-06-30 15:19:09 +02:00

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//go:build !notmono && !codec.notmono
// Copyright (c) 2012-2020 Ugorji Nwoke. All rights reserved.
// Use of this source code is governed by a MIT license found in the LICENSE file.
package codec
import (
"encoding"
"io"
"math"
"reflect"
"slices"
"sort"
"strconv"
"sync"
"time"
)
type helperEncDriverSimpleBytes struct{}
type encFnSimpleBytes struct {
i encFnInfo
fe func(*encoderSimpleBytes, *encFnInfo, reflect.Value)
}
type encRtidFnSimpleBytes struct {
rtid uintptr
fn *encFnSimpleBytes
}
type encoderSimpleBytes struct {
dh helperEncDriverSimpleBytes
fp *fastpathEsSimpleBytes
e simpleEncDriverBytes
encoderBase
}
type helperDecDriverSimpleBytes struct{}
type decFnSimpleBytes struct {
i decFnInfo
fd func(*decoderSimpleBytes, *decFnInfo, reflect.Value)
}
type decRtidFnSimpleBytes struct {
rtid uintptr
fn *decFnSimpleBytes
}
type decoderSimpleBytes struct {
dh helperDecDriverSimpleBytes
fp *fastpathDsSimpleBytes
d simpleDecDriverBytes
decoderBase
}
type simpleEncDriverBytes struct {
noBuiltInTypes
encDriverNoopContainerWriter
encDriverNoState
encDriverContainerNoTrackerT
encInit2er
h *SimpleHandle
e *encoderBase
w bytesEncAppender
}
type simpleDecDriverBytes struct {
h *SimpleHandle
d *decoderBase
r bytesDecReader
bdAndBdread
noBuiltInTypes
decDriverNoopContainerReader
decInit2er
}
func (e *encoderSimpleBytes) rawExt(_ *encFnInfo, rv reflect.Value) {
if re := rv2i(rv).(*RawExt); re == nil {
e.e.EncodeNil()
} else {
e.e.EncodeRawExt(re)
}
}
func (e *encoderSimpleBytes) ext(f *encFnInfo, rv reflect.Value) {
e.e.EncodeExt(rv2i(rv), f.ti.rt, f.xfTag, f.xfFn)
}
func (e *encoderSimpleBytes) selferMarshal(_ *encFnInfo, rv reflect.Value) {
rv2i(rv).(Selfer).CodecEncodeSelf(&Encoder{e})
}
func (e *encoderSimpleBytes) binaryMarshal(_ *encFnInfo, rv reflect.Value) {
bs, fnerr := rv2i(rv).(encoding.BinaryMarshaler).MarshalBinary()
e.marshalRaw(bs, fnerr)
}
func (e *encoderSimpleBytes) textMarshal(_ *encFnInfo, rv reflect.Value) {
bs, fnerr := rv2i(rv).(encoding.TextMarshaler).MarshalText()
e.marshalUtf8(bs, fnerr)
}
func (e *encoderSimpleBytes) jsonMarshal(_ *encFnInfo, rv reflect.Value) {
bs, fnerr := rv2i(rv).(jsonMarshaler).MarshalJSON()
e.marshalAsis(bs, fnerr)
}
func (e *encoderSimpleBytes) raw(_ *encFnInfo, rv reflect.Value) {
e.rawBytes(rv2i(rv).(Raw))
}
func (e *encoderSimpleBytes) encodeComplex64(v complex64) {
if imag(v) != 0 {
halt.errorf("cannot encode complex number: %v, with imaginary values: %v", any(v), any(imag(v)))
}
e.e.EncodeFloat32(real(v))
}
func (e *encoderSimpleBytes) encodeComplex128(v complex128) {
if imag(v) != 0 {
halt.errorf("cannot encode complex number: %v, with imaginary values: %v", any(v), any(imag(v)))
}
e.e.EncodeFloat64(real(v))
}
func (e *encoderSimpleBytes) kBool(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeBool(rvGetBool(rv))
}
func (e *encoderSimpleBytes) kTime(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeTime(rvGetTime(rv))
}
func (e *encoderSimpleBytes) kString(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeString(rvGetString(rv))
}
func (e *encoderSimpleBytes) kFloat32(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeFloat32(rvGetFloat32(rv))
}
func (e *encoderSimpleBytes) kFloat64(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeFloat64(rvGetFloat64(rv))
}
func (e *encoderSimpleBytes) kComplex64(_ *encFnInfo, rv reflect.Value) {
e.encodeComplex64(rvGetComplex64(rv))
}
func (e *encoderSimpleBytes) kComplex128(_ *encFnInfo, rv reflect.Value) {
e.encodeComplex128(rvGetComplex128(rv))
}
func (e *encoderSimpleBytes) kInt(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeInt(int64(rvGetInt(rv)))
}
func (e *encoderSimpleBytes) kInt8(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeInt(int64(rvGetInt8(rv)))
}
func (e *encoderSimpleBytes) kInt16(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeInt(int64(rvGetInt16(rv)))
}
func (e *encoderSimpleBytes) kInt32(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeInt(int64(rvGetInt32(rv)))
}
func (e *encoderSimpleBytes) kInt64(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeInt(int64(rvGetInt64(rv)))
}
func (e *encoderSimpleBytes) kUint(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeUint(uint64(rvGetUint(rv)))
}
func (e *encoderSimpleBytes) kUint8(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeUint(uint64(rvGetUint8(rv)))
}
func (e *encoderSimpleBytes) kUint16(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeUint(uint64(rvGetUint16(rv)))
}
func (e *encoderSimpleBytes) kUint32(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeUint(uint64(rvGetUint32(rv)))
}
func (e *encoderSimpleBytes) kUint64(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeUint(uint64(rvGetUint64(rv)))
}
func (e *encoderSimpleBytes) kUintptr(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeUint(uint64(rvGetUintptr(rv)))
}
func (e *encoderSimpleBytes) kSeqFn(rt reflect.Type) (fn *encFnSimpleBytes) {
if rt = baseRT(rt); rt.Kind() != reflect.Interface {
fn = e.fn(rt)
}
return
}
func (e *encoderSimpleBytes) kArrayWMbs(rv reflect.Value, ti *typeInfo, isSlice bool) {
var l int
if isSlice {
l = rvLenSlice(rv)
} else {
l = rv.Len()
}
if l == 0 {
e.e.WriteMapEmpty()
return
}
e.haltOnMbsOddLen(l)
e.mapStart(l >> 1)
var fn *encFnSimpleBytes
builtin := ti.tielem.flagEncBuiltin
if !builtin {
fn = e.kSeqFn(ti.elem)
}
j := 0
e.c = containerMapKey
e.e.WriteMapElemKey(true)
for {
rvv := rvArrayIndex(rv, j, ti, isSlice)
if builtin {
e.encodeIB(rv2i(baseRVRV(rvv)))
} else {
e.encodeValue(rvv, fn)
}
j++
if j == l {
break
}
if j&1 == 0 {
e.c = containerMapKey
e.e.WriteMapElemKey(false)
} else {
e.mapElemValue()
}
}
e.c = 0
e.e.WriteMapEnd()
}
func (e *encoderSimpleBytes) kArrayW(rv reflect.Value, ti *typeInfo, isSlice bool) {
var l int
if isSlice {
l = rvLenSlice(rv)
} else {
l = rv.Len()
}
if l <= 0 {
e.e.WriteArrayEmpty()
return
}
e.arrayStart(l)
var fn *encFnSimpleBytes
if !ti.tielem.flagEncBuiltin {
fn = e.kSeqFn(ti.elem)
}
j := 0
e.c = containerArrayElem
e.e.WriteArrayElem(true)
builtin := ti.tielem.flagEncBuiltin
for {
rvv := rvArrayIndex(rv, j, ti, isSlice)
if builtin {
e.encodeIB(rv2i(baseRVRV(rvv)))
} else {
e.encodeValue(rvv, fn)
}
j++
if j == l {
break
}
e.c = containerArrayElem
e.e.WriteArrayElem(false)
}
e.c = 0
e.e.WriteArrayEnd()
}
func (e *encoderSimpleBytes) kChan(f *encFnInfo, rv reflect.Value) {
if f.ti.chandir&uint8(reflect.RecvDir) == 0 {
halt.errorStr("send-only channel cannot be encoded")
}
if !f.ti.mbs && uint8TypId == rt2id(f.ti.elem) {
e.kSliceBytesChan(rv)
return
}
rtslice := reflect.SliceOf(f.ti.elem)
rv = chanToSlice(rv, rtslice, e.h.ChanRecvTimeout)
ti := e.h.getTypeInfo(rt2id(rtslice), rtslice)
if f.ti.mbs {
e.kArrayWMbs(rv, ti, true)
} else {
e.kArrayW(rv, ti, true)
}
}
func (e *encoderSimpleBytes) kSlice(f *encFnInfo, rv reflect.Value) {
if f.ti.mbs {
e.kArrayWMbs(rv, f.ti, true)
} else if f.ti.rtid == uint8SliceTypId || uint8TypId == rt2id(f.ti.elem) {
e.e.EncodeBytes(rvGetBytes(rv))
} else {
e.kArrayW(rv, f.ti, true)
}
}
func (e *encoderSimpleBytes) kArray(f *encFnInfo, rv reflect.Value) {
if f.ti.mbs {
e.kArrayWMbs(rv, f.ti, false)
} else if handleBytesWithinKArray && uint8TypId == rt2id(f.ti.elem) {
e.e.EncodeStringBytesRaw(rvGetArrayBytes(rv, nil))
} else {
e.kArrayW(rv, f.ti, false)
}
}
func (e *encoderSimpleBytes) kSliceBytesChan(rv reflect.Value) {
bs0 := e.blist.peek(32, true)
bs := bs0
irv := rv2i(rv)
ch, ok := irv.(<-chan byte)
if !ok {
ch = irv.(chan byte)
}
L1:
switch timeout := e.h.ChanRecvTimeout; {
case timeout == 0:
for {
select {
case b := <-ch:
bs = append(bs, b)
default:
break L1
}
}
case timeout > 0:
tt := time.NewTimer(timeout)
for {
select {
case b := <-ch:
bs = append(bs, b)
case <-tt.C:
break L1
}
}
default:
for b := range ch {
bs = append(bs, b)
}
}
e.e.EncodeBytes(bs)
e.blist.put(bs)
if !byteSliceSameData(bs0, bs) {
e.blist.put(bs0)
}
}
func (e *encoderSimpleBytes) kStructFieldKey(keyType valueType, encName string) {
if keyType == valueTypeString {
e.e.EncodeString(encName)
} else if keyType == valueTypeInt {
e.e.EncodeInt(must.Int(strconv.ParseInt(encName, 10, 64)))
} else if keyType == valueTypeUint {
e.e.EncodeUint(must.Uint(strconv.ParseUint(encName, 10, 64)))
} else if keyType == valueTypeFloat {
e.e.EncodeFloat64(must.Float(strconv.ParseFloat(encName, 64)))
} else {
halt.errorStr2("invalid struct key type: ", keyType.String())
}
}
func (e *encoderSimpleBytes) kStructSimple(f *encFnInfo, rv reflect.Value) {
_ = e.e
tisfi := f.ti.sfi.source()
chkCirRef := e.h.CheckCircularRef
var si *structFieldInfo
var j int
if f.ti.toArray || e.h.StructToArray {
if len(tisfi) == 0 {
e.e.WriteArrayEmpty()
return
}
e.arrayStart(len(tisfi))
for j, si = range tisfi {
e.c = containerArrayElem
e.e.WriteArrayElem(j == 0)
if si.encBuiltin {
e.encodeIB(rv2i(si.fieldNoAlloc(rv, true)))
} else {
e.encodeValue(si.fieldNoAlloc(rv, !chkCirRef), nil)
}
}
e.c = 0
e.e.WriteArrayEnd()
} else {
if len(tisfi) == 0 {
e.e.WriteMapEmpty()
return
}
if e.h.Canonical {
tisfi = f.ti.sfi.sorted()
}
e.mapStart(len(tisfi))
for j, si = range tisfi {
e.c = containerMapKey
e.e.WriteMapElemKey(j == 0)
e.e.EncodeStringNoEscape4Json(si.encName)
e.mapElemValue()
if si.encBuiltin {
e.encodeIB(rv2i(si.fieldNoAlloc(rv, true)))
} else {
e.encodeValue(si.fieldNoAlloc(rv, !chkCirRef), nil)
}
}
e.c = 0
e.e.WriteMapEnd()
}
}
func (e *encoderSimpleBytes) kStruct(f *encFnInfo, rv reflect.Value) {
_ = e.e
ti := f.ti
toMap := !(ti.toArray || e.h.StructToArray)
var mf map[string]interface{}
if ti.flagMissingFielder {
toMap = true
mf = rv2i(rv).(MissingFielder).CodecMissingFields()
} else if ti.flagMissingFielderPtr {
toMap = true
if rv.CanAddr() {
mf = rv2i(rvAddr(rv, ti.ptr)).(MissingFielder).CodecMissingFields()
} else {
mf = rv2i(e.addrRV(rv, ti.rt, ti.ptr)).(MissingFielder).CodecMissingFields()
}
}
newlen := len(mf)
tisfi := ti.sfi.source()
newlen += len(tisfi)
var fkvs = e.slist.get(newlen)[:newlen]
recur := e.h.RecursiveEmptyCheck
chkCirRef := e.h.CheckCircularRef
var xlen int
var kv sfiRv
var j int
var sf encStructFieldObj
if toMap {
newlen = 0
if e.h.Canonical {
tisfi = f.ti.sfi.sorted()
}
for _, si := range tisfi {
if si.omitEmpty {
kv.r = si.fieldNoAlloc(rv, false)
if isEmptyValue(kv.r, e.h.TypeInfos, recur) {
continue
}
} else {
kv.r = si.fieldNoAlloc(rv, si.encBuiltin || !chkCirRef)
}
kv.v = si
fkvs[newlen] = kv
newlen++
}
var mf2s []stringIntf
if len(mf) != 0 {
mf2s = make([]stringIntf, 0, len(mf))
for k, v := range mf {
if k == "" {
continue
}
if ti.infoFieldOmitempty && isEmptyValue(reflect.ValueOf(v), e.h.TypeInfos, recur) {
continue
}
mf2s = append(mf2s, stringIntf{k, v})
}
}
xlen = newlen + len(mf2s)
if xlen == 0 {
e.e.WriteMapEmpty()
goto END
}
e.mapStart(xlen)
if len(mf2s) != 0 && e.h.Canonical {
mf2w := make([]encStructFieldObj, newlen+len(mf2s))
for j = 0; j < newlen; j++ {
kv = fkvs[j]
mf2w[j] = encStructFieldObj{kv.v.encName, kv.r, nil, true,
!kv.v.encNameEscape4Json, kv.v.encBuiltin}
}
for _, v := range mf2s {
mf2w[j] = encStructFieldObj{v.v, reflect.Value{}, v.i, false, false, false}
j++
}
sort.Sort((encStructFieldObjSlice)(mf2w))
for j, sf = range mf2w {
e.c = containerMapKey
e.e.WriteMapElemKey(j == 0)
if ti.keyType == valueTypeString && sf.noEsc4json {
e.e.EncodeStringNoEscape4Json(sf.key)
} else {
e.kStructFieldKey(ti.keyType, sf.key)
}
e.mapElemValue()
if sf.isRv {
if sf.builtin {
e.encodeIB(rv2i(baseRVRV(sf.rv)))
} else {
e.encodeValue(sf.rv, nil)
}
} else {
if !e.encodeBuiltin(sf.intf) {
e.encodeR(reflect.ValueOf(sf.intf))
}
}
}
} else {
keytyp := ti.keyType
for j = 0; j < newlen; j++ {
kv = fkvs[j]
e.c = containerMapKey
e.e.WriteMapElemKey(j == 0)
if ti.keyType == valueTypeString && !kv.v.encNameEscape4Json {
e.e.EncodeStringNoEscape4Json(kv.v.encName)
} else {
e.kStructFieldKey(keytyp, kv.v.encName)
}
e.mapElemValue()
if kv.v.encBuiltin {
e.encodeIB(rv2i(baseRVRV(kv.r)))
} else {
e.encodeValue(kv.r, nil)
}
}
for _, v := range mf2s {
e.c = containerMapKey
e.e.WriteMapElemKey(j == 0)
e.kStructFieldKey(keytyp, v.v)
e.mapElemValue()
if !e.encodeBuiltin(v.i) {
e.encodeR(reflect.ValueOf(v.i))
}
j++
}
}
e.c = 0
e.e.WriteMapEnd()
} else {
newlen = len(tisfi)
for i, si := range tisfi {
if si.omitEmpty {
kv.r = si.fieldNoAlloc(rv, false)
if isEmptyContainerValue(kv.r, e.h.TypeInfos, recur) {
kv.r = reflect.Value{}
}
} else {
kv.r = si.fieldNoAlloc(rv, si.encBuiltin || !chkCirRef)
}
kv.v = si
fkvs[i] = kv
}
if newlen == 0 {
e.e.WriteArrayEmpty()
goto END
}
e.arrayStart(newlen)
for j = 0; j < newlen; j++ {
e.c = containerArrayElem
e.e.WriteArrayElem(j == 0)
kv = fkvs[j]
if !kv.r.IsValid() {
e.e.EncodeNil()
} else if kv.v.encBuiltin {
e.encodeIB(rv2i(baseRVRV(kv.r)))
} else {
e.encodeValue(kv.r, nil)
}
}
e.c = 0
e.e.WriteArrayEnd()
}
END:
e.slist.put(fkvs)
}
func (e *encoderSimpleBytes) kMap(f *encFnInfo, rv reflect.Value) {
_ = e.e
l := rvLenMap(rv)
if l == 0 {
e.e.WriteMapEmpty()
return
}
e.mapStart(l)
var keyFn, valFn *encFnSimpleBytes
ktypeKind := reflect.Kind(f.ti.keykind)
vtypeKind := reflect.Kind(f.ti.elemkind)
rtval := f.ti.elem
rtvalkind := vtypeKind
for rtvalkind == reflect.Ptr {
rtval = rtval.Elem()
rtvalkind = rtval.Kind()
}
if rtvalkind != reflect.Interface {
valFn = e.fn(rtval)
}
var rvv = mapAddrLoopvarRV(f.ti.elem, vtypeKind)
rtkey := f.ti.key
var keyTypeIsString = stringTypId == rt2id(rtkey)
if keyTypeIsString {
keyFn = e.fn(rtkey)
} else {
for rtkey.Kind() == reflect.Ptr {
rtkey = rtkey.Elem()
}
if rtkey.Kind() != reflect.Interface {
keyFn = e.fn(rtkey)
}
}
if e.h.Canonical {
e.kMapCanonical(f.ti, rv, rvv, keyFn, valFn)
e.c = 0
e.e.WriteMapEnd()
return
}
var rvk = mapAddrLoopvarRV(f.ti.key, ktypeKind)
var it mapIter
mapRange(&it, rv, rvk, rvv, true)
kbuiltin := f.ti.tikey.flagEncBuiltin
vbuiltin := f.ti.tielem.flagEncBuiltin
for j := 0; it.Next(); j++ {
rv = it.Key()
e.c = containerMapKey
e.e.WriteMapElemKey(j == 0)
if keyTypeIsString {
e.e.EncodeString(rvGetString(rv))
} else if kbuiltin {
e.encodeIB(rv2i(baseRVRV(rv)))
} else {
e.encodeValue(rv, keyFn)
}
e.mapElemValue()
rv = it.Value()
if vbuiltin {
e.encodeIB(rv2i(baseRVRV(rv)))
} else {
e.encodeValue(it.Value(), valFn)
}
}
it.Done()
e.c = 0
e.e.WriteMapEnd()
}
func (e *encoderSimpleBytes) kMapCanonical(ti *typeInfo, rv, rvv reflect.Value, keyFn, valFn *encFnSimpleBytes) {
_ = e.e
rtkey := ti.key
rtkeydecl := rtkey.PkgPath() == "" && rtkey.Name() != ""
mks := rv.MapKeys()
rtkeyKind := rtkey.Kind()
mparams := getMapReqParams(ti)
switch rtkeyKind {
case reflect.Bool:
if len(mks) == 2 && mks[0].Bool() {
mks[0], mks[1] = mks[1], mks[0]
}
for i := range mks {
e.c = containerMapKey
e.e.WriteMapElemKey(i == 0)
if rtkeydecl {
e.e.EncodeBool(mks[i].Bool())
} else {
e.encodeValueNonNil(mks[i], keyFn)
}
e.mapElemValue()
e.encodeValue(mapGet(rv, mks[i], rvv, mparams), valFn)
}
case reflect.String:
mksv := make([]orderedRv[string], len(mks))
for i, k := range mks {
v := &mksv[i]
v.r = k
v.v = rvGetString(k)
}
slices.SortFunc(mksv, cmpOrderedRv)
for i := range mksv {
e.c = containerMapKey
e.e.WriteMapElemKey(i == 0)
if rtkeydecl {
e.e.EncodeString(mksv[i].v)
} else {
e.encodeValueNonNil(mksv[i].r, keyFn)
}
e.mapElemValue()
e.encodeValue(mapGet(rv, mksv[i].r, rvv, mparams), valFn)
}
case reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64, reflect.Uint, reflect.Uintptr:
mksv := make([]orderedRv[uint64], len(mks))
for i, k := range mks {
v := &mksv[i]
v.r = k
v.v = k.Uint()
}
slices.SortFunc(mksv, cmpOrderedRv)
for i := range mksv {
e.c = containerMapKey
e.e.WriteMapElemKey(i == 0)
if rtkeydecl {
e.e.EncodeUint(mksv[i].v)
} else {
e.encodeValueNonNil(mksv[i].r, keyFn)
}
e.mapElemValue()
e.encodeValue(mapGet(rv, mksv[i].r, rvv, mparams), valFn)
}
case reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64, reflect.Int:
mksv := make([]orderedRv[int64], len(mks))
for i, k := range mks {
v := &mksv[i]
v.r = k
v.v = k.Int()
}
slices.SortFunc(mksv, cmpOrderedRv)
for i := range mksv {
e.c = containerMapKey
e.e.WriteMapElemKey(i == 0)
if rtkeydecl {
e.e.EncodeInt(mksv[i].v)
} else {
e.encodeValueNonNil(mksv[i].r, keyFn)
}
e.mapElemValue()
e.encodeValue(mapGet(rv, mksv[i].r, rvv, mparams), valFn)
}
case reflect.Float32:
mksv := make([]orderedRv[float64], len(mks))
for i, k := range mks {
v := &mksv[i]
v.r = k
v.v = k.Float()
}
slices.SortFunc(mksv, cmpOrderedRv)
for i := range mksv {
e.c = containerMapKey
e.e.WriteMapElemKey(i == 0)
if rtkeydecl {
e.e.EncodeFloat32(float32(mksv[i].v))
} else {
e.encodeValueNonNil(mksv[i].r, keyFn)
}
e.mapElemValue()
e.encodeValue(mapGet(rv, mksv[i].r, rvv, mparams), valFn)
}
case reflect.Float64:
mksv := make([]orderedRv[float64], len(mks))
for i, k := range mks {
v := &mksv[i]
v.r = k
v.v = k.Float()
}
slices.SortFunc(mksv, cmpOrderedRv)
for i := range mksv {
e.c = containerMapKey
e.e.WriteMapElemKey(i == 0)
if rtkeydecl {
e.e.EncodeFloat64(mksv[i].v)
} else {
e.encodeValueNonNil(mksv[i].r, keyFn)
}
e.mapElemValue()
e.encodeValue(mapGet(rv, mksv[i].r, rvv, mparams), valFn)
}
default:
if rtkey == timeTyp {
mksv := make([]timeRv, len(mks))
for i, k := range mks {
v := &mksv[i]
v.r = k
v.v = rv2i(k).(time.Time)
}
slices.SortFunc(mksv, cmpTimeRv)
for i := range mksv {
e.c = containerMapKey
e.e.WriteMapElemKey(i == 0)
e.e.EncodeTime(mksv[i].v)
e.mapElemValue()
e.encodeValue(mapGet(rv, mksv[i].r, rvv, mparams), valFn)
}
break
}
bs0 := e.blist.get(len(mks) * 16)
mksv := bs0
mksbv := make([]bytesRv, len(mks))
sideEncode(e.hh, &e.h.sideEncPool, func(se encoderI) {
se.ResetBytes(&mksv)
for i, k := range mks {
v := &mksbv[i]
l := len(mksv)
se.setContainerState(containerMapKey)
se.encodeR(baseRVRV(k))
se.atEndOfEncode()
se.writerEnd()
v.r = k
v.v = mksv[l:]
}
})
slices.SortFunc(mksbv, cmpBytesRv)
for j := range mksbv {
e.c = containerMapKey
e.e.WriteMapElemKey(j == 0)
e.e.writeBytesAsis(mksbv[j].v)
e.mapElemValue()
e.encodeValue(mapGet(rv, mksbv[j].r, rvv, mparams), valFn)
}
e.blist.put(mksv)
if !byteSliceSameData(bs0, mksv) {
e.blist.put(bs0)
}
}
}
func (e *encoderSimpleBytes) init(h Handle) {
initHandle(h)
callMake(&e.e)
e.hh = h
e.h = h.getBasicHandle()
e.err = errEncoderNotInitialized
e.fp = e.e.init(h, &e.encoderBase, e).(*fastpathEsSimpleBytes)
if e.bytes {
e.rtidFn = &e.h.rtidFnsEncBytes
e.rtidFnNoExt = &e.h.rtidFnsEncNoExtBytes
} else {
e.rtidFn = &e.h.rtidFnsEncIO
e.rtidFnNoExt = &e.h.rtidFnsEncNoExtIO
}
e.reset()
}
func (e *encoderSimpleBytes) reset() {
e.e.reset()
if e.ci != nil {
e.ci = e.ci[:0]
}
e.c = 0
e.calls = 0
e.seq = 0
e.err = nil
}
func (e *encoderSimpleBytes) Encode(v interface{}) (err error) {
defer panicValToErr(e, callRecoverSentinel, &e.err, &err, debugging)
e.mustEncode(v)
return
}
func (e *encoderSimpleBytes) MustEncode(v interface{}) {
defer panicValToErr(e, callRecoverSentinel, &e.err, nil, true)
e.mustEncode(v)
return
}
func (e *encoderSimpleBytes) mustEncode(v interface{}) {
halt.onerror(e.err)
if e.hh == nil {
halt.onerror(errNoFormatHandle)
}
e.calls++
if !e.encodeBuiltin(v) {
e.encodeR(reflect.ValueOf(v))
}
e.calls--
if e.calls == 0 {
e.e.atEndOfEncode()
e.e.writerEnd()
}
}
func (e *encoderSimpleBytes) encodeI(iv interface{}) {
if !e.encodeBuiltin(iv) {
e.encodeR(reflect.ValueOf(iv))
}
}
func (e *encoderSimpleBytes) encodeIB(iv interface{}) {
if !e.encodeBuiltin(iv) {
halt.errorStr("[should not happen] invalid type passed to encodeBuiltin")
}
}
func (e *encoderSimpleBytes) encodeR(base reflect.Value) {
e.encodeValue(base, nil)
}
func (e *encoderSimpleBytes) encodeBuiltin(iv interface{}) (ok bool) {
ok = true
switch v := iv.(type) {
case nil:
e.e.EncodeNil()
case Raw:
e.rawBytes(v)
case string:
e.e.EncodeString(v)
case bool:
e.e.EncodeBool(v)
case int:
e.e.EncodeInt(int64(v))
case int8:
e.e.EncodeInt(int64(v))
case int16:
e.e.EncodeInt(int64(v))
case int32:
e.e.EncodeInt(int64(v))
case int64:
e.e.EncodeInt(v)
case uint:
e.e.EncodeUint(uint64(v))
case uint8:
e.e.EncodeUint(uint64(v))
case uint16:
e.e.EncodeUint(uint64(v))
case uint32:
e.e.EncodeUint(uint64(v))
case uint64:
e.e.EncodeUint(v)
case uintptr:
e.e.EncodeUint(uint64(v))
case float32:
e.e.EncodeFloat32(v)
case float64:
e.e.EncodeFloat64(v)
case complex64:
e.encodeComplex64(v)
case complex128:
e.encodeComplex128(v)
case time.Time:
e.e.EncodeTime(v)
case []byte:
e.e.EncodeBytes(v)
default:
ok = !skipFastpathTypeSwitchInDirectCall && e.dh.fastpathEncodeTypeSwitch(iv, e)
}
return
}
func (e *encoderSimpleBytes) encodeValue(rv reflect.Value, fn *encFnSimpleBytes) {
var ciPushes int
var rvp reflect.Value
var rvpValid bool
RV:
switch rv.Kind() {
case reflect.Ptr:
if rvIsNil(rv) {
e.e.EncodeNil()
goto END
}
rvpValid = true
rvp = rv
rv = rv.Elem()
if e.h.CheckCircularRef && e.ci.canPushElemKind(rv.Kind()) {
e.ci.push(rv2i(rvp))
ciPushes++
}
goto RV
case reflect.Interface:
if rvIsNil(rv) {
e.e.EncodeNil()
goto END
}
rvpValid = false
rvp = reflect.Value{}
rv = rv.Elem()
fn = nil
goto RV
case reflect.Map:
if rvIsNil(rv) {
if e.h.NilCollectionToZeroLength {
e.e.WriteMapEmpty()
} else {
e.e.EncodeNil()
}
goto END
}
case reflect.Slice, reflect.Chan:
if rvIsNil(rv) {
if e.h.NilCollectionToZeroLength {
e.e.WriteArrayEmpty()
} else {
e.e.EncodeNil()
}
goto END
}
case reflect.Invalid, reflect.Func:
e.e.EncodeNil()
goto END
}
if fn == nil {
fn = e.fn(rv.Type())
}
if !fn.i.addrE {
} else if rvpValid {
rv = rvp
} else if rv.CanAddr() {
rv = rvAddr(rv, fn.i.ti.ptr)
} else {
rv = e.addrRV(rv, fn.i.ti.rt, fn.i.ti.ptr)
}
fn.fe(e, &fn.i, rv)
END:
if ciPushes > 0 {
e.ci.pop(ciPushes)
}
}
func (e *encoderSimpleBytes) encodeValueNonNil(rv reflect.Value, fn *encFnSimpleBytes) {
if fn.i.addrE {
if rv.CanAddr() {
rv = rvAddr(rv, fn.i.ti.ptr)
} else {
rv = e.addrRV(rv, fn.i.ti.rt, fn.i.ti.ptr)
}
}
fn.fe(e, &fn.i, rv)
}
func (e *encoderSimpleBytes) encodeAs(v interface{}, t reflect.Type, ext bool) {
if ext {
e.encodeValue(baseRV(v), e.fn(t))
} else {
e.encodeValue(baseRV(v), e.fnNoExt(t))
}
}
func (e *encoderSimpleBytes) marshalUtf8(bs []byte, fnerr error) {
halt.onerror(fnerr)
if bs == nil {
e.e.EncodeNil()
} else {
e.e.EncodeString(stringView(bs))
}
}
func (e *encoderSimpleBytes) marshalAsis(bs []byte, fnerr error) {
halt.onerror(fnerr)
if bs == nil {
e.e.EncodeNil()
} else {
e.e.writeBytesAsis(bs)
}
}
func (e *encoderSimpleBytes) marshalRaw(bs []byte, fnerr error) {
halt.onerror(fnerr)
e.e.EncodeBytes(bs)
}
func (e *encoderSimpleBytes) rawBytes(vv Raw) {
v := []byte(vv)
if !e.h.Raw {
halt.errorBytes("Raw values cannot be encoded: ", v)
}
e.e.writeBytesAsis(v)
}
func (e *encoderSimpleBytes) fn(t reflect.Type) *encFnSimpleBytes {
return e.dh.encFnViaBH(t, e.rtidFn, e.h, e.fp, false)
}
func (e *encoderSimpleBytes) fnNoExt(t reflect.Type) *encFnSimpleBytes {
return e.dh.encFnViaBH(t, e.rtidFnNoExt, e.h, e.fp, true)
}
func (e *encoderSimpleBytes) mapStart(length int) {
e.e.WriteMapStart(length)
e.c = containerMapStart
}
func (e *encoderSimpleBytes) mapElemValue() {
e.e.WriteMapElemValue()
e.c = containerMapValue
}
func (e *encoderSimpleBytes) arrayStart(length int) {
e.e.WriteArrayStart(length)
e.c = containerArrayStart
}
func (e *encoderSimpleBytes) writerEnd() {
e.e.writerEnd()
}
func (e *encoderSimpleBytes) atEndOfEncode() {
e.e.atEndOfEncode()
}
func (e *encoderSimpleBytes) Reset(w io.Writer) {
if e.bytes {
halt.onerror(errEncNoResetBytesWithWriter)
}
e.reset()
if w == nil {
w = io.Discard
}
e.e.resetOutIO(w)
}
func (e *encoderSimpleBytes) ResetBytes(out *[]byte) {
if !e.bytes {
halt.onerror(errEncNoResetWriterWithBytes)
}
e.resetBytes(out)
}
func (e *encoderSimpleBytes) resetBytes(out *[]byte) {
e.reset()
if out == nil {
out = &bytesEncAppenderDefOut
}
e.e.resetOutBytes(out)
}
func (helperEncDriverSimpleBytes) newEncoderBytes(out *[]byte, h Handle) *encoderSimpleBytes {
var c1 encoderSimpleBytes
c1.bytes = true
c1.init(h)
c1.ResetBytes(out)
return &c1
}
func (helperEncDriverSimpleBytes) newEncoderIO(out io.Writer, h Handle) *encoderSimpleBytes {
var c1 encoderSimpleBytes
c1.bytes = false
c1.init(h)
c1.Reset(out)
return &c1
}
func (helperEncDriverSimpleBytes) encFnloadFastpathUnderlying(ti *typeInfo, fp *fastpathEsSimpleBytes) (f *fastpathESimpleBytes, u reflect.Type) {
rtid := rt2id(ti.fastpathUnderlying)
idx, ok := fastpathAvIndex(rtid)
if !ok {
return
}
f = &fp[idx]
if uint8(reflect.Array) == ti.kind {
u = reflect.ArrayOf(ti.rt.Len(), ti.elem)
} else {
u = f.rt
}
return
}
func (helperEncDriverSimpleBytes) encFindRtidFn(s []encRtidFnSimpleBytes, rtid uintptr) (i uint, fn *encFnSimpleBytes) {
var h uint
var j = uint(len(s))
LOOP:
if i < j {
h = (i + j) >> 1
if s[h].rtid < rtid {
i = h + 1
} else {
j = h
}
goto LOOP
}
if i < uint(len(s)) && s[i].rtid == rtid {
fn = s[i].fn
}
return
}
func (helperEncDriverSimpleBytes) encFromRtidFnSlice(fns *atomicRtidFnSlice) (s []encRtidFnSimpleBytes) {
if v := fns.load(); v != nil {
s = *(lowLevelToPtr[[]encRtidFnSimpleBytes](v))
}
return
}
func (dh helperEncDriverSimpleBytes) encFnViaBH(rt reflect.Type, fns *atomicRtidFnSlice,
x *BasicHandle, fp *fastpathEsSimpleBytes, checkExt bool) (fn *encFnSimpleBytes) {
return dh.encFnVia(rt, fns, x.typeInfos(), &x.mu, x.extHandle, fp,
checkExt, x.CheckCircularRef, x.timeBuiltin, x.binaryHandle, x.jsonHandle)
}
func (dh helperEncDriverSimpleBytes) encFnVia(rt reflect.Type, fns *atomicRtidFnSlice,
tinfos *TypeInfos, mu *sync.Mutex, exth extHandle, fp *fastpathEsSimpleBytes,
checkExt, checkCircularRef, timeBuiltin, binaryEncoding, json bool) (fn *encFnSimpleBytes) {
rtid := rt2id(rt)
var sp []encRtidFnSimpleBytes = dh.encFromRtidFnSlice(fns)
if sp != nil {
_, fn = dh.encFindRtidFn(sp, rtid)
}
if fn == nil {
fn = dh.encFnViaLoader(rt, rtid, fns, tinfos, mu, exth, fp, checkExt, checkCircularRef, timeBuiltin, binaryEncoding, json)
}
return
}
func (dh helperEncDriverSimpleBytes) encFnViaLoader(rt reflect.Type, rtid uintptr, fns *atomicRtidFnSlice,
tinfos *TypeInfos, mu *sync.Mutex, exth extHandle, fp *fastpathEsSimpleBytes,
checkExt, checkCircularRef, timeBuiltin, binaryEncoding, json bool) (fn *encFnSimpleBytes) {
fn = dh.encFnLoad(rt, rtid, tinfos, exth, fp, checkExt, checkCircularRef, timeBuiltin, binaryEncoding, json)
var sp []encRtidFnSimpleBytes
mu.Lock()
sp = dh.encFromRtidFnSlice(fns)
if sp == nil {
sp = []encRtidFnSimpleBytes{{rtid, fn}}
fns.store(ptrToLowLevel(&sp))
} else {
idx, fn2 := dh.encFindRtidFn(sp, rtid)
if fn2 == nil {
sp2 := make([]encRtidFnSimpleBytes, len(sp)+1)
copy(sp2[idx+1:], sp[idx:])
copy(sp2, sp[:idx])
sp2[idx] = encRtidFnSimpleBytes{rtid, fn}
fns.store(ptrToLowLevel(&sp2))
}
}
mu.Unlock()
return
}
func (dh helperEncDriverSimpleBytes) encFnLoad(rt reflect.Type, rtid uintptr, tinfos *TypeInfos,
exth extHandle, fp *fastpathEsSimpleBytes,
checkExt, checkCircularRef, timeBuiltin, binaryEncoding, json bool) (fn *encFnSimpleBytes) {
fn = new(encFnSimpleBytes)
fi := &(fn.i)
ti := tinfos.get(rtid, rt)
fi.ti = ti
rk := reflect.Kind(ti.kind)
if rtid == timeTypId && timeBuiltin {
fn.fe = (*encoderSimpleBytes).kTime
} else if rtid == rawTypId {
fn.fe = (*encoderSimpleBytes).raw
} else if rtid == rawExtTypId {
fn.fe = (*encoderSimpleBytes).rawExt
fi.addrE = true
} else if xfFn := exth.getExt(rtid, checkExt); xfFn != nil {
fi.xfTag, fi.xfFn = xfFn.tag, xfFn.ext
fn.fe = (*encoderSimpleBytes).ext
if rk == reflect.Struct || rk == reflect.Array {
fi.addrE = true
}
} else if ti.flagSelfer || ti.flagSelferPtr {
fn.fe = (*encoderSimpleBytes).selferMarshal
fi.addrE = ti.flagSelferPtr
} else if supportMarshalInterfaces && binaryEncoding &&
(ti.flagBinaryMarshaler || ti.flagBinaryMarshalerPtr) &&
(ti.flagBinaryUnmarshaler || ti.flagBinaryUnmarshalerPtr) {
fn.fe = (*encoderSimpleBytes).binaryMarshal
fi.addrE = ti.flagBinaryMarshalerPtr
} else if supportMarshalInterfaces && !binaryEncoding && json &&
(ti.flagJsonMarshaler || ti.flagJsonMarshalerPtr) &&
(ti.flagJsonUnmarshaler || ti.flagJsonUnmarshalerPtr) {
fn.fe = (*encoderSimpleBytes).jsonMarshal
fi.addrE = ti.flagJsonMarshalerPtr
} else if supportMarshalInterfaces && !binaryEncoding &&
(ti.flagTextMarshaler || ti.flagTextMarshalerPtr) &&
(ti.flagTextUnmarshaler || ti.flagTextUnmarshalerPtr) {
fn.fe = (*encoderSimpleBytes).textMarshal
fi.addrE = ti.flagTextMarshalerPtr
} else {
if fastpathEnabled && (rk == reflect.Map || rk == reflect.Slice || rk == reflect.Array) {
var rtid2 uintptr
if !ti.flagHasPkgPath {
rtid2 = rtid
if rk == reflect.Array {
rtid2 = rt2id(ti.key)
}
if idx, ok := fastpathAvIndex(rtid2); ok {
fn.fe = fp[idx].encfn
}
} else {
xfe, xrt := dh.encFnloadFastpathUnderlying(ti, fp)
if xfe != nil {
xfnf := xfe.encfn
fn.fe = func(e *encoderSimpleBytes, xf *encFnInfo, xrv reflect.Value) {
xfnf(e, xf, rvConvert(xrv, xrt))
}
}
}
}
if fn.fe == nil {
switch rk {
case reflect.Bool:
fn.fe = (*encoderSimpleBytes).kBool
case reflect.String:
fn.fe = (*encoderSimpleBytes).kString
case reflect.Int:
fn.fe = (*encoderSimpleBytes).kInt
case reflect.Int8:
fn.fe = (*encoderSimpleBytes).kInt8
case reflect.Int16:
fn.fe = (*encoderSimpleBytes).kInt16
case reflect.Int32:
fn.fe = (*encoderSimpleBytes).kInt32
case reflect.Int64:
fn.fe = (*encoderSimpleBytes).kInt64
case reflect.Uint:
fn.fe = (*encoderSimpleBytes).kUint
case reflect.Uint8:
fn.fe = (*encoderSimpleBytes).kUint8
case reflect.Uint16:
fn.fe = (*encoderSimpleBytes).kUint16
case reflect.Uint32:
fn.fe = (*encoderSimpleBytes).kUint32
case reflect.Uint64:
fn.fe = (*encoderSimpleBytes).kUint64
case reflect.Uintptr:
fn.fe = (*encoderSimpleBytes).kUintptr
case reflect.Float32:
fn.fe = (*encoderSimpleBytes).kFloat32
case reflect.Float64:
fn.fe = (*encoderSimpleBytes).kFloat64
case reflect.Complex64:
fn.fe = (*encoderSimpleBytes).kComplex64
case reflect.Complex128:
fn.fe = (*encoderSimpleBytes).kComplex128
case reflect.Chan:
fn.fe = (*encoderSimpleBytes).kChan
case reflect.Slice:
fn.fe = (*encoderSimpleBytes).kSlice
case reflect.Array:
fn.fe = (*encoderSimpleBytes).kArray
case reflect.Struct:
if ti.simple {
fn.fe = (*encoderSimpleBytes).kStructSimple
} else {
fn.fe = (*encoderSimpleBytes).kStruct
}
case reflect.Map:
fn.fe = (*encoderSimpleBytes).kMap
case reflect.Interface:
fn.fe = (*encoderSimpleBytes).kErr
default:
fn.fe = (*encoderSimpleBytes).kErr
}
}
}
return
}
func (d *decoderSimpleBytes) rawExt(f *decFnInfo, rv reflect.Value) {
d.d.DecodeRawExt(rv2i(rv).(*RawExt))
}
func (d *decoderSimpleBytes) ext(f *decFnInfo, rv reflect.Value) {
d.d.DecodeExt(rv2i(rv), f.ti.rt, f.xfTag, f.xfFn)
}
func (d *decoderSimpleBytes) selferUnmarshal(_ *decFnInfo, rv reflect.Value) {
rv2i(rv).(Selfer).CodecDecodeSelf(&Decoder{d})
}
func (d *decoderSimpleBytes) binaryUnmarshal(_ *decFnInfo, rv reflect.Value) {
bm := rv2i(rv).(encoding.BinaryUnmarshaler)
xbs, _ := d.d.DecodeBytes()
fnerr := bm.UnmarshalBinary(xbs)
halt.onerror(fnerr)
}
func (d *decoderSimpleBytes) textUnmarshal(_ *decFnInfo, rv reflect.Value) {
tm := rv2i(rv).(encoding.TextUnmarshaler)
fnerr := tm.UnmarshalText(bytesOKs(d.d.DecodeStringAsBytes()))
halt.onerror(fnerr)
}
func (d *decoderSimpleBytes) jsonUnmarshal(_ *decFnInfo, rv reflect.Value) {
d.jsonUnmarshalV(rv2i(rv).(jsonUnmarshaler))
}
func (d *decoderSimpleBytes) jsonUnmarshalV(tm jsonUnmarshaler) {
halt.onerror(tm.UnmarshalJSON(d.d.nextValueBytes()))
}
func (d *decoderSimpleBytes) kErr(_ *decFnInfo, rv reflect.Value) {
halt.errorf("unsupported decoding kind: %s, for %#v", rv.Kind(), rv)
}
func (d *decoderSimpleBytes) raw(_ *decFnInfo, rv reflect.Value) {
rvSetBytes(rv, d.rawBytes())
}
func (d *decoderSimpleBytes) kString(_ *decFnInfo, rv reflect.Value) {
rvSetString(rv, d.detach2Str(d.d.DecodeStringAsBytes()))
}
func (d *decoderSimpleBytes) kBool(_ *decFnInfo, rv reflect.Value) {
rvSetBool(rv, d.d.DecodeBool())
}
func (d *decoderSimpleBytes) kTime(_ *decFnInfo, rv reflect.Value) {
rvSetTime(rv, d.d.DecodeTime())
}
func (d *decoderSimpleBytes) kFloat32(_ *decFnInfo, rv reflect.Value) {
rvSetFloat32(rv, d.d.DecodeFloat32())
}
func (d *decoderSimpleBytes) kFloat64(_ *decFnInfo, rv reflect.Value) {
rvSetFloat64(rv, d.d.DecodeFloat64())
}
func (d *decoderSimpleBytes) kComplex64(_ *decFnInfo, rv reflect.Value) {
rvSetComplex64(rv, complex(d.d.DecodeFloat32(), 0))
}
func (d *decoderSimpleBytes) kComplex128(_ *decFnInfo, rv reflect.Value) {
rvSetComplex128(rv, complex(d.d.DecodeFloat64(), 0))
}
func (d *decoderSimpleBytes) kInt(_ *decFnInfo, rv reflect.Value) {
rvSetInt(rv, int(chkOvf.IntV(d.d.DecodeInt64(), intBitsize)))
}
func (d *decoderSimpleBytes) kInt8(_ *decFnInfo, rv reflect.Value) {
rvSetInt8(rv, int8(chkOvf.IntV(d.d.DecodeInt64(), 8)))
}
func (d *decoderSimpleBytes) kInt16(_ *decFnInfo, rv reflect.Value) {
rvSetInt16(rv, int16(chkOvf.IntV(d.d.DecodeInt64(), 16)))
}
func (d *decoderSimpleBytes) kInt32(_ *decFnInfo, rv reflect.Value) {
rvSetInt32(rv, int32(chkOvf.IntV(d.d.DecodeInt64(), 32)))
}
func (d *decoderSimpleBytes) kInt64(_ *decFnInfo, rv reflect.Value) {
rvSetInt64(rv, d.d.DecodeInt64())
}
func (d *decoderSimpleBytes) kUint(_ *decFnInfo, rv reflect.Value) {
rvSetUint(rv, uint(chkOvf.UintV(d.d.DecodeUint64(), uintBitsize)))
}
func (d *decoderSimpleBytes) kUintptr(_ *decFnInfo, rv reflect.Value) {
rvSetUintptr(rv, uintptr(chkOvf.UintV(d.d.DecodeUint64(), uintBitsize)))
}
func (d *decoderSimpleBytes) kUint8(_ *decFnInfo, rv reflect.Value) {
rvSetUint8(rv, uint8(chkOvf.UintV(d.d.DecodeUint64(), 8)))
}
func (d *decoderSimpleBytes) kUint16(_ *decFnInfo, rv reflect.Value) {
rvSetUint16(rv, uint16(chkOvf.UintV(d.d.DecodeUint64(), 16)))
}
func (d *decoderSimpleBytes) kUint32(_ *decFnInfo, rv reflect.Value) {
rvSetUint32(rv, uint32(chkOvf.UintV(d.d.DecodeUint64(), 32)))
}
func (d *decoderSimpleBytes) kUint64(_ *decFnInfo, rv reflect.Value) {
rvSetUint64(rv, d.d.DecodeUint64())
}
func (d *decoderSimpleBytes) kInterfaceNaked(f *decFnInfo) (rvn reflect.Value) {
n := d.naked()
d.d.DecodeNaked()
if decFailNonEmptyIntf && f.ti.numMeth > 0 {
halt.errorf("cannot decode non-nil codec value into nil %v (%v methods)", f.ti.rt, f.ti.numMeth)
}
switch n.v {
case valueTypeMap:
mtid := d.mtid
if mtid == 0 {
if d.jsms {
mtid = mapStrIntfTypId
} else {
mtid = mapIntfIntfTypId
}
}
if mtid == mapStrIntfTypId {
var v2 map[string]interface{}
d.decode(&v2)
rvn = rv4iptr(&v2).Elem()
} else if mtid == mapIntfIntfTypId {
var v2 map[interface{}]interface{}
d.decode(&v2)
rvn = rv4iptr(&v2).Elem()
} else if d.mtr {
rvn = reflect.New(d.h.MapType)
d.decode(rv2i(rvn))
rvn = rvn.Elem()
} else {
rvn = rvZeroAddrK(d.h.MapType, reflect.Map)
d.decodeValue(rvn, nil)
}
case valueTypeArray:
if d.stid == 0 || d.stid == intfSliceTypId {
var v2 []interface{}
d.decode(&v2)
rvn = rv4iptr(&v2).Elem()
} else if d.str {
rvn = reflect.New(d.h.SliceType)
d.decode(rv2i(rvn))
rvn = rvn.Elem()
} else {
rvn = rvZeroAddrK(d.h.SliceType, reflect.Slice)
d.decodeValue(rvn, nil)
}
if d.h.PreferArrayOverSlice {
rvn = rvGetArray4Slice(rvn)
}
case valueTypeExt:
tag, bytes := n.u, n.l
bfn := d.h.getExtForTag(tag)
var re = RawExt{Tag: tag}
if bytes == nil {
if bfn == nil {
d.decode(&re.Value)
rvn = rv4iptr(&re).Elem()
} else if bfn.ext == SelfExt {
rvn = rvZeroAddrK(bfn.rt, bfn.rt.Kind())
d.decodeValue(rvn, d.fnNoExt(bfn.rt))
} else {
rvn = reflect.New(bfn.rt)
d.interfaceExtConvertAndDecode(rv2i(rvn), bfn.ext)
rvn = rvn.Elem()
}
} else {
if bfn == nil {
re.setData(bytes, false)
rvn = rv4iptr(&re).Elem()
} else {
rvn = reflect.New(bfn.rt)
if bfn.ext == SelfExt {
sideDecode(d.hh, &d.h.sideDecPool, func(sd decoderI) { oneOffDecode(sd, rv2i(rvn), bytes, bfn.rt, true) })
} else {
bfn.ext.ReadExt(rv2i(rvn), bytes)
}
rvn = rvn.Elem()
}
}
if d.h.PreferPointerForStructOrArray && rvn.CanAddr() {
if rk := rvn.Kind(); rk == reflect.Array || rk == reflect.Struct {
rvn = rvn.Addr()
}
}
case valueTypeNil:
case valueTypeInt:
rvn = n.ri()
case valueTypeUint:
rvn = n.ru()
case valueTypeFloat:
rvn = n.rf()
case valueTypeBool:
rvn = n.rb()
case valueTypeString, valueTypeSymbol:
rvn = n.rs()
case valueTypeBytes:
rvn = n.rl()
case valueTypeTime:
rvn = n.rt()
default:
halt.errorStr2("kInterfaceNaked: unexpected valueType: ", n.v.String())
}
return
}
func (d *decoderSimpleBytes) kInterface(f *decFnInfo, rv reflect.Value) {
isnilrv := rvIsNil(rv)
var rvn reflect.Value
if d.h.InterfaceReset {
rvn = d.h.intf2impl(f.ti.rtid)
if !rvn.IsValid() {
rvn = d.kInterfaceNaked(f)
if rvn.IsValid() {
rvSetIntf(rv, rvn)
} else if !isnilrv {
decSetNonNilRV2Zero4Intf(rv)
}
return
}
} else if isnilrv {
rvn = d.h.intf2impl(f.ti.rtid)
if !rvn.IsValid() {
rvn = d.kInterfaceNaked(f)
if rvn.IsValid() {
rvSetIntf(rv, rvn)
}
return
}
} else {
rvn = rv.Elem()
}
canDecode, _ := isDecodeable(rvn)
if !canDecode {
rvn2 := d.oneShotAddrRV(rvn.Type(), rvn.Kind())
rvSetDirect(rvn2, rvn)
rvn = rvn2
}
d.decodeValue(rvn, nil)
rvSetIntf(rv, rvn)
}
func (d *decoderSimpleBytes) kStructField(si *structFieldInfo, rv reflect.Value) {
if d.d.TryNil() {
rv = si.fieldNoAlloc(rv, true)
if rv.IsValid() {
decSetNonNilRV2Zero(rv)
}
} else if si.decBuiltin {
rv = rvAddr(si.fieldAlloc(rv), si.ptrTyp)
d.decode(rv2i(rv))
} else {
fn := d.fn(si.baseTyp)
rv = si.fieldAlloc(rv)
if fn.i.addrD {
rv = rvAddr(rv, si.ptrTyp)
}
fn.fd(d, &fn.i, rv)
}
}
func (d *decoderSimpleBytes) kStructSimple(f *decFnInfo, rv reflect.Value) {
_ = d.d
ctyp := d.d.ContainerType()
ti := f.ti
if ctyp == valueTypeMap {
containerLen := d.mapStart(d.d.ReadMapStart())
if containerLen == 0 {
d.mapEnd()
return
}
hasLen := containerLen >= 0
var rvkencname []byte
for j := 0; d.containerNext(j, containerLen, hasLen); j++ {
d.mapElemKey(j == 0)
sab, att := d.d.DecodeStringAsBytes()
rvkencname = d.usableStructFieldNameBytes(rvkencname, sab, att)
d.mapElemValue()
if si := ti.siForEncName(rvkencname); si != nil {
d.kStructField(si, rv)
} else {
d.structFieldNotFound(-1, stringView(rvkencname))
}
}
d.mapEnd()
} else if ctyp == valueTypeArray {
containerLen := d.arrayStart(d.d.ReadArrayStart())
if containerLen == 0 {
d.arrayEnd()
return
}
tisfi := ti.sfi.source()
hasLen := containerLen >= 0
for j := 0; d.containerNext(j, containerLen, hasLen); j++ {
d.arrayElem(j == 0)
if j < len(tisfi) {
d.kStructField(tisfi[j], rv)
} else {
d.structFieldNotFound(j, "")
}
}
d.arrayEnd()
} else {
halt.onerror(errNeedMapOrArrayDecodeToStruct)
}
}
func (d *decoderSimpleBytes) kStruct(f *decFnInfo, rv reflect.Value) {
_ = d.d
ctyp := d.d.ContainerType()
ti := f.ti
var mf MissingFielder
if ti.flagMissingFielder {
mf = rv2i(rv).(MissingFielder)
} else if ti.flagMissingFielderPtr {
mf = rv2i(rvAddr(rv, ti.ptr)).(MissingFielder)
}
if ctyp == valueTypeMap {
containerLen := d.mapStart(d.d.ReadMapStart())
if containerLen == 0 {
d.mapEnd()
return
}
hasLen := containerLen >= 0
var name2 []byte
var rvkencname []byte
tkt := ti.keyType
for j := 0; d.containerNext(j, containerLen, hasLen); j++ {
d.mapElemKey(j == 0)
if tkt == valueTypeString {
sab, att := d.d.DecodeStringAsBytes()
rvkencname = d.usableStructFieldNameBytes(rvkencname, sab, att)
} else if tkt == valueTypeInt {
rvkencname = strconv.AppendInt(d.b[:0], d.d.DecodeInt64(), 10)
} else if tkt == valueTypeUint {
rvkencname = strconv.AppendUint(d.b[:0], d.d.DecodeUint64(), 10)
} else if tkt == valueTypeFloat {
rvkencname = strconv.AppendFloat(d.b[:0], d.d.DecodeFloat64(), 'f', -1, 64)
} else {
halt.errorStr2("invalid struct key type: ", ti.keyType.String())
}
d.mapElemValue()
if si := ti.siForEncName(rvkencname); si != nil {
d.kStructField(si, rv)
} else if mf != nil {
name2 = append(name2[:0], rvkencname...)
var f interface{}
d.decode(&f)
if !mf.CodecMissingField(name2, f) && d.h.ErrorIfNoField {
halt.errorStr2("no matching struct field when decoding stream map with key: ", stringView(name2))
}
} else {
d.structFieldNotFound(-1, stringView(rvkencname))
}
}
d.mapEnd()
} else if ctyp == valueTypeArray {
containerLen := d.arrayStart(d.d.ReadArrayStart())
if containerLen == 0 {
d.arrayEnd()
return
}
tisfi := ti.sfi.source()
hasLen := containerLen >= 0
for j := 0; d.containerNext(j, containerLen, hasLen); j++ {
d.arrayElem(j == 0)
if j < len(tisfi) {
d.kStructField(tisfi[j], rv)
} else {
d.structFieldNotFound(j, "")
}
}
d.arrayEnd()
} else {
halt.onerror(errNeedMapOrArrayDecodeToStruct)
}
}
func (d *decoderSimpleBytes) kSlice(f *decFnInfo, rv reflect.Value) {
_ = d.d
ti := f.ti
rvCanset := rv.CanSet()
ctyp := d.d.ContainerType()
if ctyp == valueTypeBytes || ctyp == valueTypeString {
if !(ti.rtid == uint8SliceTypId || ti.elemkind == uint8(reflect.Uint8)) {
halt.errorf("bytes/string in stream must decode into slice/array of bytes, not %v", ti.rt)
}
rvbs := rvGetBytes(rv)
if rvCanset {
bs2, bst := d.decodeBytesInto(rvbs, false)
if bst != dBytesIntoParamOut {
rvSetBytes(rv, bs2)
}
} else {
d.decodeBytesInto(rvbs[:len(rvbs):len(rvbs)], true)
}
return
}
var containerLenS int
isArray := ctyp == valueTypeArray
if isArray {
containerLenS = d.arrayStart(d.d.ReadArrayStart())
} else if ctyp == valueTypeMap {
containerLenS = d.mapStart(d.d.ReadMapStart()) * 2
} else {
halt.errorStr2("decoding into a slice, expect map/array - got ", ctyp.String())
}
if containerLenS == 0 {
if rvCanset {
if rvIsNil(rv) {
rvSetDirect(rv, rvSliceZeroCap(ti.rt))
} else {
rvSetSliceLen(rv, 0)
}
}
if isArray {
d.arrayEnd()
} else {
d.mapEnd()
}
return
}
rtelem0Mut := !scalarBitset.isset(ti.elemkind)
rtelem := ti.elem
for k := reflect.Kind(ti.elemkind); k == reflect.Ptr; k = rtelem.Kind() {
rtelem = rtelem.Elem()
}
var fn *decFnSimpleBytes
var rvChanged bool
var rv0 = rv
var rv9 reflect.Value
rvlen := rvLenSlice(rv)
rvcap := rvCapSlice(rv)
maxInitLen := d.maxInitLen()
hasLen := containerLenS >= 0
if hasLen {
if containerLenS > rvcap {
oldRvlenGtZero := rvlen > 0
rvlen1 := int(decInferLen(containerLenS, maxInitLen, uint(ti.elemsize)))
if rvlen1 == rvlen {
} else if rvlen1 <= rvcap {
if rvCanset {
rvlen = rvlen1
rvSetSliceLen(rv, rvlen)
}
} else if rvCanset {
rvlen = rvlen1
rv, rvCanset = rvMakeSlice(rv, f.ti, rvlen, rvlen)
rvcap = rvlen
rvChanged = !rvCanset
} else {
halt.errorStr("cannot decode into non-settable slice")
}
if rvChanged && oldRvlenGtZero && rtelem0Mut {
rvCopySlice(rv, rv0, rtelem)
}
} else if containerLenS != rvlen {
if rvCanset {
rvlen = containerLenS
rvSetSliceLen(rv, rvlen)
}
}
}
var elemReset = d.h.SliceElementReset
var rtelemIsPtr bool
var rtelemElem reflect.Type
builtin := ti.tielem.flagDecBuiltin
if builtin {
rtelemIsPtr = ti.elemkind == uint8(reflect.Ptr)
if rtelemIsPtr {
rtelemElem = ti.elem.Elem()
}
}
var j int
for ; d.containerNext(j, containerLenS, hasLen); j++ {
if j == 0 {
if rvIsNil(rv) {
if rvCanset {
rvlen = int(decInferLen(containerLenS, maxInitLen, uint(ti.elemsize)))
rv, rvCanset = rvMakeSlice(rv, f.ti, rvlen, rvlen)
rvcap = rvlen
rvChanged = !rvCanset
} else {
halt.errorStr("cannot decode into non-settable slice")
}
}
if fn == nil {
fn = d.fn(rtelem)
}
}
if ctyp == valueTypeArray {
d.arrayElem(j == 0)
} else if j&1 == 0 {
d.mapElemKey(j == 0)
} else {
d.mapElemValue()
}
if j >= rvlen {
if rvlen < rvcap {
rvlen = rvcap
if rvCanset {
rvSetSliceLen(rv, rvlen)
} else if rvChanged {
rv = rvSlice(rv, rvlen)
} else {
halt.onerror(errExpandSliceCannotChange)
}
} else {
if !(rvCanset || rvChanged) {
halt.onerror(errExpandSliceCannotChange)
}
rv, rvcap, rvCanset = rvGrowSlice(rv, f.ti, rvcap, 1)
rvlen = rvcap
rvChanged = !rvCanset
}
}
rv9 = rvArrayIndex(rv, j, f.ti, true)
if elemReset {
rvSetZero(rv9)
}
if d.d.TryNil() {
rvSetZero(rv9)
} else if builtin {
if rtelemIsPtr {
if rvIsNil(rv9) {
rvSetDirect(rv9, reflect.New(rtelemElem))
}
d.decode(rv2i(rv9))
} else {
d.decode(rv2i(rvAddr(rv9, ti.tielem.ptr)))
}
} else {
d.decodeValueNoCheckNil(rv9, fn)
}
}
if j < rvlen {
if rvCanset {
rvSetSliceLen(rv, j)
} else if rvChanged {
rv = rvSlice(rv, j)
}
} else if j == 0 && rvIsNil(rv) {
if rvCanset {
rv = rvSliceZeroCap(ti.rt)
rvCanset = false
rvChanged = true
}
}
if isArray {
d.arrayEnd()
} else {
d.mapEnd()
}
if rvChanged {
rvSetDirect(rv0, rv)
}
}
func (d *decoderSimpleBytes) kArray(f *decFnInfo, rv reflect.Value) {
_ = d.d
ti := f.ti
ctyp := d.d.ContainerType()
if handleBytesWithinKArray && (ctyp == valueTypeBytes || ctyp == valueTypeString) {
if ti.elemkind != uint8(reflect.Uint8) {
halt.errorf("bytes/string in stream can decode into array of bytes, but not %v", ti.rt)
}
rvbs := rvGetArrayBytes(rv, nil)
d.decodeBytesInto(rvbs, true)
return
}
var containerLenS int
isArray := ctyp == valueTypeArray
if isArray {
containerLenS = d.arrayStart(d.d.ReadArrayStart())
} else if ctyp == valueTypeMap {
containerLenS = d.mapStart(d.d.ReadMapStart()) * 2
} else {
halt.errorStr2("decoding into a slice, expect map/array - got ", ctyp.String())
}
if containerLenS == 0 {
if isArray {
d.arrayEnd()
} else {
d.mapEnd()
}
return
}
rtelem := ti.elem
for k := reflect.Kind(ti.elemkind); k == reflect.Ptr; k = rtelem.Kind() {
rtelem = rtelem.Elem()
}
var rv9 reflect.Value
rvlen := rv.Len()
hasLen := containerLenS >= 0
if hasLen && containerLenS > rvlen {
halt.errorf("cannot decode into array with length: %v, less than container length: %v", any(rvlen), any(containerLenS))
}
var elemReset = d.h.SliceElementReset
var rtelemIsPtr bool
var rtelemElem reflect.Type
var fn *decFnSimpleBytes
builtin := ti.tielem.flagDecBuiltin
if builtin {
rtelemIsPtr = ti.elemkind == uint8(reflect.Ptr)
if rtelemIsPtr {
rtelemElem = ti.elem.Elem()
}
} else {
fn = d.fn(rtelem)
}
for j := 0; d.containerNext(j, containerLenS, hasLen); j++ {
if ctyp == valueTypeArray {
d.arrayElem(j == 0)
} else if j&1 == 0 {
d.mapElemKey(j == 0)
} else {
d.mapElemValue()
}
if j >= rvlen {
d.arrayCannotExpand(rvlen, j+1)
d.swallow()
continue
}
rv9 = rvArrayIndex(rv, j, f.ti, false)
if elemReset {
rvSetZero(rv9)
}
if d.d.TryNil() {
rvSetZero(rv9)
} else if builtin {
if rtelemIsPtr {
if rvIsNil(rv9) {
rvSetDirect(rv9, reflect.New(rtelemElem))
}
d.decode(rv2i(rv9))
} else {
d.decode(rv2i(rvAddr(rv9, ti.tielem.ptr)))
}
} else {
d.decodeValueNoCheckNil(rv9, fn)
}
}
if isArray {
d.arrayEnd()
} else {
d.mapEnd()
}
}
func (d *decoderSimpleBytes) kChan(f *decFnInfo, rv reflect.Value) {
_ = d.d
ti := f.ti
if ti.chandir&uint8(reflect.SendDir) == 0 {
halt.errorStr("receive-only channel cannot be decoded")
}
ctyp := d.d.ContainerType()
if ctyp == valueTypeBytes || ctyp == valueTypeString {
if !(ti.rtid == uint8SliceTypId || ti.elemkind == uint8(reflect.Uint8)) {
halt.errorf("bytes/string in stream must decode into slice/array of bytes, not %v", ti.rt)
}
bs2, _ := d.d.DecodeBytes()
irv := rv2i(rv)
ch, ok := irv.(chan<- byte)
if !ok {
ch = irv.(chan byte)
}
for _, b := range bs2 {
ch <- b
}
return
}
var rvCanset = rv.CanSet()
var containerLenS int
isArray := ctyp == valueTypeArray
if isArray {
containerLenS = d.arrayStart(d.d.ReadArrayStart())
} else if ctyp == valueTypeMap {
containerLenS = d.mapStart(d.d.ReadMapStart()) * 2
} else {
halt.errorStr2("decoding into a slice, expect map/array - got ", ctyp.String())
}
if containerLenS == 0 {
if rvCanset && rvIsNil(rv) {
rvSetDirect(rv, reflect.MakeChan(ti.rt, 0))
}
if isArray {
d.arrayEnd()
} else {
d.mapEnd()
}
return
}
rtelem := ti.elem
useTransient := decUseTransient && ti.elemkind != byte(reflect.Ptr) && ti.tielem.flagCanTransient
for k := reflect.Kind(ti.elemkind); k == reflect.Ptr; k = rtelem.Kind() {
rtelem = rtelem.Elem()
}
var fn *decFnSimpleBytes
var rvChanged bool
var rv0 = rv
var rv9 reflect.Value
var rvlen int
hasLen := containerLenS >= 0
maxInitLen := d.maxInitLen()
for j := 0; d.containerNext(j, containerLenS, hasLen); j++ {
if j == 0 {
if rvIsNil(rv) {
if hasLen {
rvlen = int(decInferLen(containerLenS, maxInitLen, uint(ti.elemsize)))
} else {
rvlen = decDefChanCap
}
if rvCanset {
rv = reflect.MakeChan(ti.rt, rvlen)
rvChanged = true
} else {
halt.errorStr("cannot decode into non-settable chan")
}
}
if fn == nil {
fn = d.fn(rtelem)
}
}
if ctyp == valueTypeArray {
d.arrayElem(j == 0)
} else if j&1 == 0 {
d.mapElemKey(j == 0)
} else {
d.mapElemValue()
}
if rv9.IsValid() {
rvSetZero(rv9)
} else if useTransient {
rv9 = d.perType.TransientAddrK(ti.elem, reflect.Kind(ti.elemkind))
} else {
rv9 = rvZeroAddrK(ti.elem, reflect.Kind(ti.elemkind))
}
if !d.d.TryNil() {
d.decodeValueNoCheckNil(rv9, fn)
}
rv.Send(rv9)
}
if isArray {
d.arrayEnd()
} else {
d.mapEnd()
}
if rvChanged {
rvSetDirect(rv0, rv)
}
}
func (d *decoderSimpleBytes) kMap(f *decFnInfo, rv reflect.Value) {
_ = d.d
containerLen := d.mapStart(d.d.ReadMapStart())
ti := f.ti
if rvIsNil(rv) {
rvlen := int(decInferLen(containerLen, d.maxInitLen(), uint(ti.keysize+ti.elemsize)))
rvSetDirect(rv, makeMapReflect(ti.rt, rvlen))
}
if containerLen == 0 {
d.mapEnd()
return
}
ktype, vtype := ti.key, ti.elem
ktypeId := rt2id(ktype)
vtypeKind := reflect.Kind(ti.elemkind)
ktypeKind := reflect.Kind(ti.keykind)
mparams := getMapReqParams(ti)
vtypePtr := vtypeKind == reflect.Ptr
ktypePtr := ktypeKind == reflect.Ptr
vTransient := decUseTransient && !vtypePtr && ti.tielem.flagCanTransient
kTransient := vTransient && !ktypePtr && ti.tikey.flagCanTransient
var vtypeElem reflect.Type
var keyFn, valFn *decFnSimpleBytes
var ktypeLo, vtypeLo = ktype, vtype
if ktypeKind == reflect.Ptr {
for ktypeLo = ktype.Elem(); ktypeLo.Kind() == reflect.Ptr; ktypeLo = ktypeLo.Elem() {
}
}
if vtypePtr {
vtypeElem = vtype.Elem()
for vtypeLo = vtypeElem; vtypeLo.Kind() == reflect.Ptr; vtypeLo = vtypeLo.Elem() {
}
}
rvkMut := !scalarBitset.isset(ti.keykind)
rvvMut := !scalarBitset.isset(ti.elemkind)
rvvCanNil := isnilBitset.isset(ti.elemkind)
var rvk, rvkn, rvv, rvvn, rvva, rvvz reflect.Value
var doMapGet, doMapSet bool
if !d.h.MapValueReset {
if rvvMut && (vtypeKind != reflect.Interface || !d.h.InterfaceReset) {
doMapGet = true
rvva = mapAddrLoopvarRV(vtype, vtypeKind)
}
}
ktypeIsString := ktypeId == stringTypId
ktypeIsIntf := ktypeId == intfTypId
hasLen := containerLen >= 0
var kstr2bs []byte
var kstr string
var mapKeyStringSharesBytesBuf bool
var att dBytesAttachState
var vElem, kElem reflect.Type
kbuiltin := ti.tikey.flagDecBuiltin && ti.keykind != uint8(reflect.Slice)
vbuiltin := ti.tielem.flagDecBuiltin
if kbuiltin && ktypePtr {
kElem = ti.key.Elem()
}
if vbuiltin && vtypePtr {
vElem = ti.elem.Elem()
}
for j := 0; d.containerNext(j, containerLen, hasLen); j++ {
mapKeyStringSharesBytesBuf = false
kstr = ""
if j == 0 {
if kTransient {
rvk = d.perType.TransientAddr2K(ktype, ktypeKind)
} else {
rvk = rvZeroAddrK(ktype, ktypeKind)
}
if !rvkMut {
rvkn = rvk
}
if !rvvMut {
if vTransient {
rvvn = d.perType.TransientAddrK(vtype, vtypeKind)
} else {
rvvn = rvZeroAddrK(vtype, vtypeKind)
}
}
if !ktypeIsString && keyFn == nil {
keyFn = d.fn(ktypeLo)
}
if valFn == nil {
valFn = d.fn(vtypeLo)
}
} else if rvkMut {
rvSetZero(rvk)
} else {
rvk = rvkn
}
d.mapElemKey(j == 0)
if d.d.TryNil() {
rvSetZero(rvk)
} else if ktypeIsString {
kstr2bs, att = d.d.DecodeStringAsBytes()
kstr, mapKeyStringSharesBytesBuf = d.bytes2Str(kstr2bs, att)
rvSetString(rvk, kstr)
} else {
if kbuiltin {
if ktypePtr {
if rvIsNil(rvk) {
rvSetDirect(rvk, reflect.New(kElem))
}
d.decode(rv2i(rvk))
} else {
d.decode(rv2i(rvAddr(rvk, ti.tikey.ptr)))
}
} else {
d.decodeValueNoCheckNil(rvk, keyFn)
}
if ktypeIsIntf {
if rvk2 := rvk.Elem(); rvk2.IsValid() && rvk2.Type() == uint8SliceTyp {
kstr2bs = rvGetBytes(rvk2)
kstr, mapKeyStringSharesBytesBuf = d.bytes2Str(kstr2bs, dBytesAttachView)
rvSetIntf(rvk, rv4istr(kstr))
}
}
}
if mapKeyStringSharesBytesBuf && d.bufio {
if ktypeIsString {
rvSetString(rvk, d.detach2Str(kstr2bs, att))
} else {
rvSetIntf(rvk, rv4istr(d.detach2Str(kstr2bs, att)))
}
mapKeyStringSharesBytesBuf = false
}
d.mapElemValue()
if d.d.TryNil() {
if mapKeyStringSharesBytesBuf {
if ktypeIsString {
rvSetString(rvk, d.detach2Str(kstr2bs, att))
} else {
rvSetIntf(rvk, rv4istr(d.detach2Str(kstr2bs, att)))
}
}
if !rvvz.IsValid() {
rvvz = rvZeroK(vtype, vtypeKind)
}
mapSet(rv, rvk, rvvz, mparams)
continue
}
doMapSet = true
if !rvvMut {
rvv = rvvn
} else if !doMapGet {
goto NEW_RVV
} else {
rvv = mapGet(rv, rvk, rvva, mparams)
if !rvv.IsValid() || (rvvCanNil && rvIsNil(rvv)) {
goto NEW_RVV
}
switch vtypeKind {
case reflect.Ptr, reflect.Map:
doMapSet = false
case reflect.Interface:
rvvn = rvv.Elem()
if k := rvvn.Kind(); (k == reflect.Ptr || k == reflect.Map) && !rvIsNil(rvvn) {
d.decodeValueNoCheckNil(rvvn, nil)
continue
}
rvvn = rvZeroAddrK(vtype, vtypeKind)
rvSetIntf(rvvn, rvv)
rvv = rvvn
default:
if vTransient {
rvvn = d.perType.TransientAddrK(vtype, vtypeKind)
} else {
rvvn = rvZeroAddrK(vtype, vtypeKind)
}
rvSetDirect(rvvn, rvv)
rvv = rvvn
}
}
goto DECODE_VALUE_NO_CHECK_NIL
NEW_RVV:
if vtypePtr {
rvv = reflect.New(vtypeElem)
} else if vTransient {
rvv = d.perType.TransientAddrK(vtype, vtypeKind)
} else {
rvv = rvZeroAddrK(vtype, vtypeKind)
}
DECODE_VALUE_NO_CHECK_NIL:
if doMapSet && mapKeyStringSharesBytesBuf {
if ktypeIsString {
rvSetString(rvk, d.detach2Str(kstr2bs, att))
} else {
rvSetIntf(rvk, rv4istr(d.detach2Str(kstr2bs, att)))
}
}
if vbuiltin {
if vtypePtr {
if rvIsNil(rvv) {
rvSetDirect(rvv, reflect.New(vElem))
}
d.decode(rv2i(rvv))
} else {
d.decode(rv2i(rvAddr(rvv, ti.tielem.ptr)))
}
} else {
d.decodeValueNoCheckNil(rvv, valFn)
}
if doMapSet {
mapSet(rv, rvk, rvv, mparams)
}
}
d.mapEnd()
}
func (d *decoderSimpleBytes) init(h Handle) {
initHandle(h)
callMake(&d.d)
d.hh = h
d.h = h.getBasicHandle()
d.err = errDecoderNotInitialized
if d.h.InternString && d.is == nil {
d.is.init()
}
d.fp = d.d.init(h, &d.decoderBase, d).(*fastpathDsSimpleBytes)
if d.bytes {
d.rtidFn = &d.h.rtidFnsDecBytes
d.rtidFnNoExt = &d.h.rtidFnsDecNoExtBytes
} else {
d.bufio = d.h.ReaderBufferSize > 0
d.rtidFn = &d.h.rtidFnsDecIO
d.rtidFnNoExt = &d.h.rtidFnsDecNoExtIO
}
d.reset()
}
func (d *decoderSimpleBytes) reset() {
d.d.reset()
d.err = nil
d.c = 0
d.depth = 0
d.calls = 0
d.maxdepth = decDefMaxDepth
if d.h.MaxDepth > 0 {
d.maxdepth = d.h.MaxDepth
}
d.mtid = 0
d.stid = 0
d.mtr = false
d.str = false
if d.h.MapType != nil {
d.mtid = rt2id(d.h.MapType)
_, d.mtr = fastpathAvIndex(d.mtid)
}
if d.h.SliceType != nil {
d.stid = rt2id(d.h.SliceType)
_, d.str = fastpathAvIndex(d.stid)
}
}
func (d *decoderSimpleBytes) Reset(r io.Reader) {
if d.bytes {
halt.onerror(errDecNoResetBytesWithReader)
}
d.reset()
if r == nil {
r = &eofReader
}
d.d.resetInIO(r)
}
func (d *decoderSimpleBytes) ResetBytes(in []byte) {
if !d.bytes {
halt.onerror(errDecNoResetReaderWithBytes)
}
d.resetBytes(in)
}
func (d *decoderSimpleBytes) resetBytes(in []byte) {
d.reset()
if in == nil {
in = zeroByteSlice
}
d.d.resetInBytes(in)
}
func (d *decoderSimpleBytes) ResetString(s string) {
d.ResetBytes(bytesView(s))
}
func (d *decoderSimpleBytes) Decode(v interface{}) (err error) {
defer panicValToErr(d, callRecoverSentinel, &d.err, &err, debugging)
d.mustDecode(v)
return
}
func (d *decoderSimpleBytes) MustDecode(v interface{}) {
defer panicValToErr(d, callRecoverSentinel, &d.err, nil, true)
d.mustDecode(v)
return
}
func (d *decoderSimpleBytes) mustDecode(v interface{}) {
halt.onerror(d.err)
if d.hh == nil {
halt.onerror(errNoFormatHandle)
}
d.calls++
d.decode(v)
d.calls--
}
func (d *decoderSimpleBytes) Release() {}
func (d *decoderSimpleBytes) swallow() {
d.d.nextValueBytes()
}
func (d *decoderSimpleBytes) nextValueBytes() []byte {
return d.d.nextValueBytes()
}
func (d *decoderSimpleBytes) decode(iv interface{}) {
_ = d.d
rv, ok := isNil(iv, true)
if ok {
halt.onerror(errCannotDecodeIntoNil)
}
switch v := iv.(type) {
case *string:
*v = d.detach2Str(d.d.DecodeStringAsBytes())
case *bool:
*v = d.d.DecodeBool()
case *int:
*v = int(chkOvf.IntV(d.d.DecodeInt64(), intBitsize))
case *int8:
*v = int8(chkOvf.IntV(d.d.DecodeInt64(), 8))
case *int16:
*v = int16(chkOvf.IntV(d.d.DecodeInt64(), 16))
case *int32:
*v = int32(chkOvf.IntV(d.d.DecodeInt64(), 32))
case *int64:
*v = d.d.DecodeInt64()
case *uint:
*v = uint(chkOvf.UintV(d.d.DecodeUint64(), uintBitsize))
case *uint8:
*v = uint8(chkOvf.UintV(d.d.DecodeUint64(), 8))
case *uint16:
*v = uint16(chkOvf.UintV(d.d.DecodeUint64(), 16))
case *uint32:
*v = uint32(chkOvf.UintV(d.d.DecodeUint64(), 32))
case *uint64:
*v = d.d.DecodeUint64()
case *uintptr:
*v = uintptr(chkOvf.UintV(d.d.DecodeUint64(), uintBitsize))
case *float32:
*v = d.d.DecodeFloat32()
case *float64:
*v = d.d.DecodeFloat64()
case *complex64:
*v = complex(d.d.DecodeFloat32(), 0)
case *complex128:
*v = complex(d.d.DecodeFloat64(), 0)
case *[]byte:
*v, _ = d.decodeBytesInto(*v, false)
case []byte:
d.decodeBytesInto(v[:len(v):len(v)], true)
case *time.Time:
*v = d.d.DecodeTime()
case *Raw:
*v = d.rawBytes()
case *interface{}:
d.decodeValue(rv4iptr(v), nil)
case reflect.Value:
if ok, _ = isDecodeable(v); !ok {
d.haltAsNotDecodeable(v)
}
d.decodeValue(v, nil)
default:
if skipFastpathTypeSwitchInDirectCall || !d.dh.fastpathDecodeTypeSwitch(iv, d) {
if !rv.IsValid() {
rv = reflect.ValueOf(iv)
}
if ok, _ = isDecodeable(rv); !ok {
d.haltAsNotDecodeable(rv)
}
d.decodeValue(rv, nil)
}
}
}
func (d *decoderSimpleBytes) decodeValue(rv reflect.Value, fn *decFnSimpleBytes) {
if d.d.TryNil() {
decSetNonNilRV2Zero(rv)
} else {
d.decodeValueNoCheckNil(rv, fn)
}
}
func (d *decoderSimpleBytes) decodeValueNoCheckNil(rv reflect.Value, fn *decFnSimpleBytes) {
var rvp reflect.Value
var rvpValid bool
PTR:
if rv.Kind() == reflect.Ptr {
rvpValid = true
if rvIsNil(rv) {
rvSetDirect(rv, reflect.New(rv.Type().Elem()))
}
rvp = rv
rv = rv.Elem()
goto PTR
}
if fn == nil {
fn = d.fn(rv.Type())
}
if fn.i.addrD {
if rvpValid {
rv = rvp
} else if rv.CanAddr() {
rv = rvAddr(rv, fn.i.ti.ptr)
} else if fn.i.addrDf {
halt.errorStr("cannot decode into a non-pointer value")
}
}
fn.fd(d, &fn.i, rv)
}
func (d *decoderSimpleBytes) decodeAs(v interface{}, t reflect.Type, ext bool) {
if ext {
d.decodeValue(baseRV(v), d.fn(t))
} else {
d.decodeValue(baseRV(v), d.fnNoExt(t))
}
}
func (d *decoderSimpleBytes) structFieldNotFound(index int, rvkencname string) {
if d.h.ErrorIfNoField {
if index >= 0 {
halt.errorInt("no matching struct field found when decoding stream array at index ", int64(index))
} else if rvkencname != "" {
halt.errorStr2("no matching struct field found when decoding stream map with key ", rvkencname)
}
}
d.swallow()
}
func (d *decoderSimpleBytes) decodeBytesInto(out []byte, mustFit bool) (v []byte, state dBytesIntoState) {
v, att := d.d.DecodeBytes()
if cap(v) == 0 || (att >= dBytesAttachViewZerocopy && !mustFit) {
return
}
if len(v) == 0 {
v = zeroByteSlice
return
}
if len(out) == len(v) {
state = dBytesIntoParamOut
} else if cap(out) >= len(v) {
out = out[:len(v)]
state = dBytesIntoParamOutSlice
} else if mustFit {
halt.errorf("bytes capacity insufficient for decoded bytes: got/expected: %d/%d", len(v), len(out))
} else {
out = make([]byte, len(v))
state = dBytesIntoNew
}
copy(out, v)
v = out
return
}
func (d *decoderSimpleBytes) rawBytes() (v []byte) {
v = d.d.nextValueBytes()
if d.bytes && !d.h.ZeroCopy {
vv := make([]byte, len(v))
copy(vv, v)
v = vv
}
return
}
func (d *decoderSimpleBytes) wrapErr(v error, err *error) {
*err = wrapCodecErr(v, d.hh.Name(), d.d.NumBytesRead(), false)
}
func (d *decoderSimpleBytes) NumBytesRead() int {
return d.d.NumBytesRead()
}
func (d *decoderSimpleBytes) containerNext(j, containerLen int, hasLen bool) bool {
if hasLen {
return j < containerLen
}
return !d.d.CheckBreak()
}
func (d *decoderSimpleBytes) mapElemKey(firstTime bool) {
d.d.ReadMapElemKey(firstTime)
d.c = containerMapKey
}
func (d *decoderSimpleBytes) mapElemValue() {
d.d.ReadMapElemValue()
d.c = containerMapValue
}
func (d *decoderSimpleBytes) mapEnd() {
d.d.ReadMapEnd()
d.depthDecr()
d.c = 0
}
func (d *decoderSimpleBytes) arrayElem(firstTime bool) {
d.d.ReadArrayElem(firstTime)
d.c = containerArrayElem
}
func (d *decoderSimpleBytes) arrayEnd() {
d.d.ReadArrayEnd()
d.depthDecr()
d.c = 0
}
func (d *decoderSimpleBytes) interfaceExtConvertAndDecode(v interface{}, ext InterfaceExt) {
var vv interface{}
d.decode(&vv)
ext.UpdateExt(v, vv)
}
func (d *decoderSimpleBytes) fn(t reflect.Type) *decFnSimpleBytes {
return d.dh.decFnViaBH(t, d.rtidFn, d.h, d.fp, false)
}
func (d *decoderSimpleBytes) fnNoExt(t reflect.Type) *decFnSimpleBytes {
return d.dh.decFnViaBH(t, d.rtidFnNoExt, d.h, d.fp, true)
}
func (helperDecDriverSimpleBytes) newDecoderBytes(in []byte, h Handle) *decoderSimpleBytes {
var c1 decoderSimpleBytes
c1.bytes = true
c1.init(h)
c1.ResetBytes(in)
return &c1
}
func (helperDecDriverSimpleBytes) newDecoderIO(in io.Reader, h Handle) *decoderSimpleBytes {
var c1 decoderSimpleBytes
c1.init(h)
c1.Reset(in)
return &c1
}
func (helperDecDriverSimpleBytes) decFnloadFastpathUnderlying(ti *typeInfo, fp *fastpathDsSimpleBytes) (f *fastpathDSimpleBytes, u reflect.Type) {
rtid := rt2id(ti.fastpathUnderlying)
idx, ok := fastpathAvIndex(rtid)
if !ok {
return
}
f = &fp[idx]
if uint8(reflect.Array) == ti.kind {
u = reflect.ArrayOf(ti.rt.Len(), ti.elem)
} else {
u = f.rt
}
return
}
func (helperDecDriverSimpleBytes) decFindRtidFn(s []decRtidFnSimpleBytes, rtid uintptr) (i uint, fn *decFnSimpleBytes) {
var h uint
var j = uint(len(s))
LOOP:
if i < j {
h = (i + j) >> 1
if s[h].rtid < rtid {
i = h + 1
} else {
j = h
}
goto LOOP
}
if i < uint(len(s)) && s[i].rtid == rtid {
fn = s[i].fn
}
return
}
func (helperDecDriverSimpleBytes) decFromRtidFnSlice(fns *atomicRtidFnSlice) (s []decRtidFnSimpleBytes) {
if v := fns.load(); v != nil {
s = *(lowLevelToPtr[[]decRtidFnSimpleBytes](v))
}
return
}
func (dh helperDecDriverSimpleBytes) decFnViaBH(rt reflect.Type, fns *atomicRtidFnSlice, x *BasicHandle, fp *fastpathDsSimpleBytes,
checkExt bool) (fn *decFnSimpleBytes) {
return dh.decFnVia(rt, fns, x.typeInfos(), &x.mu, x.extHandle, fp,
checkExt, x.CheckCircularRef, x.timeBuiltin, x.binaryHandle, x.jsonHandle)
}
func (dh helperDecDriverSimpleBytes) decFnVia(rt reflect.Type, fns *atomicRtidFnSlice,
tinfos *TypeInfos, mu *sync.Mutex, exth extHandle, fp *fastpathDsSimpleBytes,
checkExt, checkCircularRef, timeBuiltin, binaryEncoding, json bool) (fn *decFnSimpleBytes) {
rtid := rt2id(rt)
var sp []decRtidFnSimpleBytes = dh.decFromRtidFnSlice(fns)
if sp != nil {
_, fn = dh.decFindRtidFn(sp, rtid)
}
if fn == nil {
fn = dh.decFnViaLoader(rt, rtid, fns, tinfos, mu, exth, fp, checkExt, checkCircularRef, timeBuiltin, binaryEncoding, json)
}
return
}
func (dh helperDecDriverSimpleBytes) decFnViaLoader(rt reflect.Type, rtid uintptr, fns *atomicRtidFnSlice,
tinfos *TypeInfos, mu *sync.Mutex, exth extHandle, fp *fastpathDsSimpleBytes,
checkExt, checkCircularRef, timeBuiltin, binaryEncoding, json bool) (fn *decFnSimpleBytes) {
fn = dh.decFnLoad(rt, rtid, tinfos, exth, fp, checkExt, checkCircularRef, timeBuiltin, binaryEncoding, json)
var sp []decRtidFnSimpleBytes
mu.Lock()
sp = dh.decFromRtidFnSlice(fns)
if sp == nil {
sp = []decRtidFnSimpleBytes{{rtid, fn}}
fns.store(ptrToLowLevel(&sp))
} else {
idx, fn2 := dh.decFindRtidFn(sp, rtid)
if fn2 == nil {
sp2 := make([]decRtidFnSimpleBytes, len(sp)+1)
copy(sp2[idx+1:], sp[idx:])
copy(sp2, sp[:idx])
sp2[idx] = decRtidFnSimpleBytes{rtid, fn}
fns.store(ptrToLowLevel(&sp2))
}
}
mu.Unlock()
return
}
func (dh helperDecDriverSimpleBytes) decFnLoad(rt reflect.Type, rtid uintptr, tinfos *TypeInfos,
exth extHandle, fp *fastpathDsSimpleBytes,
checkExt, checkCircularRef, timeBuiltin, binaryEncoding, json bool) (fn *decFnSimpleBytes) {
fn = new(decFnSimpleBytes)
fi := &(fn.i)
ti := tinfos.get(rtid, rt)
fi.ti = ti
rk := reflect.Kind(ti.kind)
fi.addrDf = true
if rtid == timeTypId && timeBuiltin {
fn.fd = (*decoderSimpleBytes).kTime
} else if rtid == rawTypId {
fn.fd = (*decoderSimpleBytes).raw
} else if rtid == rawExtTypId {
fn.fd = (*decoderSimpleBytes).rawExt
fi.addrD = true
} else if xfFn := exth.getExt(rtid, checkExt); xfFn != nil {
fi.xfTag, fi.xfFn = xfFn.tag, xfFn.ext
fn.fd = (*decoderSimpleBytes).ext
fi.addrD = true
} else if ti.flagSelfer || ti.flagSelferPtr {
fn.fd = (*decoderSimpleBytes).selferUnmarshal
fi.addrD = ti.flagSelferPtr
} else if supportMarshalInterfaces && binaryEncoding &&
(ti.flagBinaryMarshaler || ti.flagBinaryMarshalerPtr) &&
(ti.flagBinaryUnmarshaler || ti.flagBinaryUnmarshalerPtr) {
fn.fd = (*decoderSimpleBytes).binaryUnmarshal
fi.addrD = ti.flagBinaryUnmarshalerPtr
} else if supportMarshalInterfaces && !binaryEncoding && json &&
(ti.flagJsonMarshaler || ti.flagJsonMarshalerPtr) &&
(ti.flagJsonUnmarshaler || ti.flagJsonUnmarshalerPtr) {
fn.fd = (*decoderSimpleBytes).jsonUnmarshal
fi.addrD = ti.flagJsonUnmarshalerPtr
} else if supportMarshalInterfaces && !binaryEncoding &&
(ti.flagTextMarshaler || ti.flagTextMarshalerPtr) &&
(ti.flagTextUnmarshaler || ti.flagTextUnmarshalerPtr) {
fn.fd = (*decoderSimpleBytes).textUnmarshal
fi.addrD = ti.flagTextUnmarshalerPtr
} else {
if fastpathEnabled && (rk == reflect.Map || rk == reflect.Slice || rk == reflect.Array) {
var rtid2 uintptr
if !ti.flagHasPkgPath {
rtid2 = rtid
if rk == reflect.Array {
rtid2 = rt2id(ti.key)
}
if idx, ok := fastpathAvIndex(rtid2); ok {
fn.fd = fp[idx].decfn
fi.addrD = true
fi.addrDf = false
if rk == reflect.Array {
fi.addrD = false
}
}
} else {
xfe, xrt := dh.decFnloadFastpathUnderlying(ti, fp)
if xfe != nil {
xfnf2 := xfe.decfn
if rk == reflect.Array {
fi.addrD = false
fn.fd = func(d *decoderSimpleBytes, xf *decFnInfo, xrv reflect.Value) {
xfnf2(d, xf, rvConvert(xrv, xrt))
}
} else {
fi.addrD = true
fi.addrDf = false
xptr2rt := reflect.PointerTo(xrt)
fn.fd = func(d *decoderSimpleBytes, xf *decFnInfo, xrv reflect.Value) {
if xrv.Kind() == reflect.Ptr {
xfnf2(d, xf, rvConvert(xrv, xptr2rt))
} else {
xfnf2(d, xf, rvConvert(xrv, xrt))
}
}
}
}
}
}
if fn.fd == nil {
switch rk {
case reflect.Bool:
fn.fd = (*decoderSimpleBytes).kBool
case reflect.String:
fn.fd = (*decoderSimpleBytes).kString
case reflect.Int:
fn.fd = (*decoderSimpleBytes).kInt
case reflect.Int8:
fn.fd = (*decoderSimpleBytes).kInt8
case reflect.Int16:
fn.fd = (*decoderSimpleBytes).kInt16
case reflect.Int32:
fn.fd = (*decoderSimpleBytes).kInt32
case reflect.Int64:
fn.fd = (*decoderSimpleBytes).kInt64
case reflect.Uint:
fn.fd = (*decoderSimpleBytes).kUint
case reflect.Uint8:
fn.fd = (*decoderSimpleBytes).kUint8
case reflect.Uint16:
fn.fd = (*decoderSimpleBytes).kUint16
case reflect.Uint32:
fn.fd = (*decoderSimpleBytes).kUint32
case reflect.Uint64:
fn.fd = (*decoderSimpleBytes).kUint64
case reflect.Uintptr:
fn.fd = (*decoderSimpleBytes).kUintptr
case reflect.Float32:
fn.fd = (*decoderSimpleBytes).kFloat32
case reflect.Float64:
fn.fd = (*decoderSimpleBytes).kFloat64
case reflect.Complex64:
fn.fd = (*decoderSimpleBytes).kComplex64
case reflect.Complex128:
fn.fd = (*decoderSimpleBytes).kComplex128
case reflect.Chan:
fn.fd = (*decoderSimpleBytes).kChan
case reflect.Slice:
fn.fd = (*decoderSimpleBytes).kSlice
case reflect.Array:
fi.addrD = false
fn.fd = (*decoderSimpleBytes).kArray
case reflect.Struct:
if ti.simple {
fn.fd = (*decoderSimpleBytes).kStructSimple
} else {
fn.fd = (*decoderSimpleBytes).kStruct
}
case reflect.Map:
fn.fd = (*decoderSimpleBytes).kMap
case reflect.Interface:
fn.fd = (*decoderSimpleBytes).kInterface
default:
fn.fd = (*decoderSimpleBytes).kErr
}
}
}
return
}
func (e *simpleEncDriverBytes) EncodeNil() {
e.w.writen1(simpleVdNil)
}
func (e *simpleEncDriverBytes) EncodeBool(b bool) {
if e.h.EncZeroValuesAsNil && e.e.c != containerMapKey && !b {
e.EncodeNil()
return
}
if b {
e.w.writen1(simpleVdTrue)
} else {
e.w.writen1(simpleVdFalse)
}
}
func (e *simpleEncDriverBytes) EncodeFloat32(f float32) {
if e.h.EncZeroValuesAsNil && e.e.c != containerMapKey && f == 0.0 {
e.EncodeNil()
return
}
e.w.writen1(simpleVdFloat32)
e.w.writen4(bigen.PutUint32(math.Float32bits(f)))
}
func (e *simpleEncDriverBytes) EncodeFloat64(f float64) {
if e.h.EncZeroValuesAsNil && e.e.c != containerMapKey && f == 0.0 {
e.EncodeNil()
return
}
e.w.writen1(simpleVdFloat64)
e.w.writen8(bigen.PutUint64(math.Float64bits(f)))
}
func (e *simpleEncDriverBytes) EncodeInt(v int64) {
if v < 0 {
e.encUint(uint64(-v), simpleVdNegInt)
} else {
e.encUint(uint64(v), simpleVdPosInt)
}
}
func (e *simpleEncDriverBytes) EncodeUint(v uint64) {
e.encUint(v, simpleVdPosInt)
}
func (e *simpleEncDriverBytes) encUint(v uint64, bd uint8) {
if e.h.EncZeroValuesAsNil && e.e.c != containerMapKey && v == 0 {
e.EncodeNil()
return
}
if v <= math.MaxUint8 {
e.w.writen2(bd, uint8(v))
} else if v <= math.MaxUint16 {
e.w.writen1(bd + 1)
e.w.writen2(bigen.PutUint16(uint16(v)))
} else if v <= math.MaxUint32 {
e.w.writen1(bd + 2)
e.w.writen4(bigen.PutUint32(uint32(v)))
} else {
e.w.writen1(bd + 3)
e.w.writen8(bigen.PutUint64(v))
}
}
func (e *simpleEncDriverBytes) encLen(bd byte, length int) {
if length == 0 {
e.w.writen1(bd)
} else if length <= math.MaxUint8 {
e.w.writen1(bd + 1)
e.w.writen1(uint8(length))
} else if length <= math.MaxUint16 {
e.w.writen1(bd + 2)
e.w.writen2(bigen.PutUint16(uint16(length)))
} else if int64(length) <= math.MaxUint32 {
e.w.writen1(bd + 3)
e.w.writen4(bigen.PutUint32(uint32(length)))
} else {
e.w.writen1(bd + 4)
e.w.writen8(bigen.PutUint64(uint64(length)))
}
}
func (e *simpleEncDriverBytes) EncodeExt(v interface{}, basetype reflect.Type, xtag uint64, ext Ext) {
var bs0, bs []byte
if ext == SelfExt {
bs0 = e.e.blist.get(1024)
bs = bs0
sideEncode(e.h, &e.h.sideEncPool, func(se encoderI) { oneOffEncode(se, v, &bs, basetype, true) })
} else {
bs = ext.WriteExt(v)
}
if bs == nil {
e.writeNilBytes()
goto END
}
e.encodeExtPreamble(uint8(xtag), len(bs))
e.w.writeb(bs)
END:
if ext == SelfExt {
e.e.blist.put(bs)
if !byteSliceSameData(bs0, bs) {
e.e.blist.put(bs0)
}
}
}
func (e *simpleEncDriverBytes) EncodeRawExt(re *RawExt) {
e.encodeExtPreamble(uint8(re.Tag), len(re.Data))
e.w.writeb(re.Data)
}
func (e *simpleEncDriverBytes) encodeExtPreamble(xtag byte, length int) {
e.encLen(simpleVdExt, length)
e.w.writen1(xtag)
}
func (e *simpleEncDriverBytes) WriteArrayStart(length int) {
e.encLen(simpleVdArray, length)
}
func (e *simpleEncDriverBytes) WriteMapStart(length int) {
e.encLen(simpleVdMap, length)
}
func (e *simpleEncDriverBytes) WriteArrayEmpty() {
e.w.writen1(simpleVdArray)
}
func (e *simpleEncDriverBytes) WriteMapEmpty() {
e.w.writen1(simpleVdMap)
}
func (e *simpleEncDriverBytes) EncodeString(v string) {
if e.h.EncZeroValuesAsNil && e.e.c != containerMapKey && v == "" {
e.EncodeNil()
return
}
if e.h.StringToRaw {
e.encLen(simpleVdByteArray, len(v))
} else {
e.encLen(simpleVdString, len(v))
}
e.w.writestr(v)
}
func (e *simpleEncDriverBytes) EncodeStringNoEscape4Json(v string) { e.EncodeString(v) }
func (e *simpleEncDriverBytes) EncodeStringBytesRaw(v []byte) {
e.encLen(simpleVdByteArray, len(v))
e.w.writeb(v)
}
func (e *simpleEncDriverBytes) EncodeBytes(v []byte) {
if v == nil {
e.writeNilBytes()
return
}
e.EncodeStringBytesRaw(v)
}
func (e *simpleEncDriverBytes) encodeNilBytes() {
b := byte(simpleVdNil)
if e.h.NilCollectionToZeroLength {
b = simpleVdArray
}
e.w.writen1(b)
}
func (e *simpleEncDriverBytes) writeNilOr(v byte) {
if !e.h.NilCollectionToZeroLength {
v = simpleVdNil
}
e.w.writen1(v)
}
func (e *simpleEncDriverBytes) writeNilArray() {
e.writeNilOr(simpleVdArray)
}
func (e *simpleEncDriverBytes) writeNilMap() {
e.writeNilOr(simpleVdMap)
}
func (e *simpleEncDriverBytes) writeNilBytes() {
e.writeNilOr(simpleVdByteArray)
}
func (e *simpleEncDriverBytes) EncodeTime(t time.Time) {
if t.IsZero() {
e.EncodeNil()
return
}
v, err := t.MarshalBinary()
halt.onerror(err)
e.w.writen2(simpleVdTime, uint8(len(v)))
e.w.writeb(v)
}
func (d *simpleDecDriverBytes) readNextBd() {
d.bd = d.r.readn1()
d.bdRead = true
}
func (d *simpleDecDriverBytes) advanceNil() (null bool) {
if !d.bdRead {
d.readNextBd()
}
if d.bd == simpleVdNil {
d.bdRead = false
return true
}
return
}
func (d *simpleDecDriverBytes) ContainerType() (vt valueType) {
if !d.bdRead {
d.readNextBd()
}
switch d.bd {
case simpleVdNil:
d.bdRead = false
return valueTypeNil
case simpleVdByteArray, simpleVdByteArray + 1,
simpleVdByteArray + 2, simpleVdByteArray + 3, simpleVdByteArray + 4:
return valueTypeBytes
case simpleVdString, simpleVdString + 1,
simpleVdString + 2, simpleVdString + 3, simpleVdString + 4:
return valueTypeString
case simpleVdArray, simpleVdArray + 1,
simpleVdArray + 2, simpleVdArray + 3, simpleVdArray + 4:
return valueTypeArray
case simpleVdMap, simpleVdMap + 1,
simpleVdMap + 2, simpleVdMap + 3, simpleVdMap + 4:
return valueTypeMap
}
return valueTypeUnset
}
func (d *simpleDecDriverBytes) TryNil() bool {
return d.advanceNil()
}
func (d *simpleDecDriverBytes) decFloat() (f float64, ok bool) {
ok = true
switch d.bd {
case simpleVdFloat32:
f = float64(math.Float32frombits(bigen.Uint32(d.r.readn4())))
case simpleVdFloat64:
f = math.Float64frombits(bigen.Uint64(d.r.readn8()))
default:
ok = false
}
return
}
func (d *simpleDecDriverBytes) decInteger() (ui uint64, neg, ok bool) {
ok = true
switch d.bd {
case simpleVdPosInt:
ui = uint64(d.r.readn1())
case simpleVdPosInt + 1:
ui = uint64(bigen.Uint16(d.r.readn2()))
case simpleVdPosInt + 2:
ui = uint64(bigen.Uint32(d.r.readn4()))
case simpleVdPosInt + 3:
ui = uint64(bigen.Uint64(d.r.readn8()))
case simpleVdNegInt:
ui = uint64(d.r.readn1())
neg = true
case simpleVdNegInt + 1:
ui = uint64(bigen.Uint16(d.r.readn2()))
neg = true
case simpleVdNegInt + 2:
ui = uint64(bigen.Uint32(d.r.readn4()))
neg = true
case simpleVdNegInt + 3:
ui = uint64(bigen.Uint64(d.r.readn8()))
neg = true
default:
ok = false
}
return
}
func (d *simpleDecDriverBytes) DecodeInt64() (i int64) {
if d.advanceNil() {
return
}
v1, v2, v3 := d.decInteger()
i = decNegintPosintFloatNumberHelper{d}.int64(v1, v2, v3, false)
d.bdRead = false
return
}
func (d *simpleDecDriverBytes) DecodeUint64() (ui uint64) {
if d.advanceNil() {
return
}
ui = decNegintPosintFloatNumberHelper{d}.uint64(d.decInteger())
d.bdRead = false
return
}
func (d *simpleDecDriverBytes) DecodeFloat64() (f float64) {
if d.advanceNil() {
return
}
v1, v2 := d.decFloat()
f = decNegintPosintFloatNumberHelper{d}.float64(v1, v2, false)
d.bdRead = false
return
}
func (d *simpleDecDriverBytes) DecodeBool() (b bool) {
if d.advanceNil() {
return
}
if d.bd == simpleVdFalse {
} else if d.bd == simpleVdTrue {
b = true
} else {
halt.errorf("cannot decode bool - %s: %x", msgBadDesc, d.bd)
}
d.bdRead = false
return
}
func (d *simpleDecDriverBytes) ReadMapStart() (length int) {
if d.advanceNil() {
return containerLenNil
}
d.bdRead = false
return d.decLen()
}
func (d *simpleDecDriverBytes) ReadArrayStart() (length int) {
if d.advanceNil() {
return containerLenNil
}
d.bdRead = false
return d.decLen()
}
func (d *simpleDecDriverBytes) uint2Len(ui uint64) int {
if chkOvf.Uint(ui, intBitsize) {
halt.errorf("overflow integer: %v", ui)
}
return int(ui)
}
func (d *simpleDecDriverBytes) decLen() int {
switch d.bd & 7 {
case 0:
return 0
case 1:
return int(d.r.readn1())
case 2:
return int(bigen.Uint16(d.r.readn2()))
case 3:
return d.uint2Len(uint64(bigen.Uint32(d.r.readn4())))
case 4:
return d.uint2Len(bigen.Uint64(d.r.readn8()))
}
halt.errorf("cannot read length: bd%%8 must be in range 0..4. Got: %d", d.bd%8)
return -1
}
func (d *simpleDecDriverBytes) DecodeStringAsBytes() ([]byte, dBytesAttachState) {
return d.DecodeBytes()
}
func (d *simpleDecDriverBytes) DecodeBytes() (bs []byte, state dBytesAttachState) {
if d.advanceNil() {
return
}
var cond bool
if d.bd >= simpleVdArray && d.bd <= simpleVdArray+4 {
slen := d.ReadArrayStart()
bs, cond = usableByteSlice(d.d.buf, slen)
for i := 0; i < len(bs); i++ {
bs[i] = uint8(chkOvf.UintV(d.DecodeUint64(), 8))
}
for i := len(bs); i < slen; i++ {
bs = append(bs, uint8(chkOvf.UintV(d.DecodeUint64(), 8)))
}
if cond {
d.d.buf = bs
}
state = dBytesAttachBuffer
return
}
clen := d.decLen()
d.bdRead = false
bs, cond = d.r.readxb(uint(clen))
state = d.d.attachState(cond)
return
}
func (d *simpleDecDriverBytes) DecodeTime() (t time.Time) {
if d.advanceNil() {
return
}
if d.bd != simpleVdTime {
halt.errorf("invalid descriptor for time.Time - expect 0x%x, received 0x%x", simpleVdTime, d.bd)
}
d.bdRead = false
clen := uint(d.r.readn1())
b := d.r.readx(clen)
halt.onerror((&t).UnmarshalBinary(b))
return
}
func (d *simpleDecDriverBytes) DecodeExt(rv interface{}, basetype reflect.Type, xtag uint64, ext Ext) {
xbs, _, _, ok := d.decodeExtV(ext != nil, xtag)
if !ok {
return
}
if ext == SelfExt {
sideDecode(d.h, &d.h.sideDecPool, func(sd decoderI) { oneOffDecode(sd, rv, xbs, basetype, true) })
} else {
ext.ReadExt(rv, xbs)
}
}
func (d *simpleDecDriverBytes) DecodeRawExt(re *RawExt) {
xbs, realxtag, state, ok := d.decodeExtV(false, 0)
if !ok {
return
}
re.Tag = uint64(realxtag)
re.setData(xbs, state >= dBytesAttachViewZerocopy)
}
func (d *simpleDecDriverBytes) decodeExtV(verifyTag bool, xtagIn uint64) (xbs []byte, xtag byte, bstate dBytesAttachState, ok bool) {
if xtagIn > 0xff {
halt.errorf("ext: tag must be <= 0xff; got: %v", xtagIn)
}
if d.advanceNil() {
return
}
tag := uint8(xtagIn)
switch d.bd {
case simpleVdExt, simpleVdExt + 1, simpleVdExt + 2, simpleVdExt + 3, simpleVdExt + 4:
l := d.decLen()
xtag = d.r.readn1()
if verifyTag && xtag != tag {
halt.errorf("wrong extension tag. Got %b. Expecting: %v", xtag, tag)
}
xbs, ok = d.r.readxb(uint(l))
bstate = d.d.attachState(ok)
case simpleVdByteArray, simpleVdByteArray + 1,
simpleVdByteArray + 2, simpleVdByteArray + 3, simpleVdByteArray + 4:
xbs, bstate = d.DecodeBytes()
default:
halt.errorf("ext - %s - expecting extensions/bytearray, got: 0x%x", msgBadDesc, d.bd)
}
d.bdRead = false
ok = true
return
}
func (d *simpleDecDriverBytes) DecodeNaked() {
if !d.bdRead {
d.readNextBd()
}
n := d.d.naked()
var decodeFurther bool
switch d.bd {
case simpleVdNil:
n.v = valueTypeNil
case simpleVdFalse:
n.v = valueTypeBool
n.b = false
case simpleVdTrue:
n.v = valueTypeBool
n.b = true
case simpleVdPosInt, simpleVdPosInt + 1, simpleVdPosInt + 2, simpleVdPosInt + 3:
if d.h.SignedInteger {
n.v = valueTypeInt
n.i = d.DecodeInt64()
} else {
n.v = valueTypeUint
n.u = d.DecodeUint64()
}
case simpleVdNegInt, simpleVdNegInt + 1, simpleVdNegInt + 2, simpleVdNegInt + 3:
n.v = valueTypeInt
n.i = d.DecodeInt64()
case simpleVdFloat32:
n.v = valueTypeFloat
n.f = d.DecodeFloat64()
case simpleVdFloat64:
n.v = valueTypeFloat
n.f = d.DecodeFloat64()
case simpleVdTime:
n.v = valueTypeTime
n.t = d.DecodeTime()
case simpleVdString, simpleVdString + 1,
simpleVdString + 2, simpleVdString + 3, simpleVdString + 4:
n.v = valueTypeString
n.s = d.d.detach2Str(d.DecodeStringAsBytes())
case simpleVdByteArray, simpleVdByteArray + 1,
simpleVdByteArray + 2, simpleVdByteArray + 3, simpleVdByteArray + 4:
d.d.fauxUnionReadRawBytes(d, false, d.h.RawToString)
case simpleVdExt, simpleVdExt + 1, simpleVdExt + 2, simpleVdExt + 3, simpleVdExt + 4:
n.v = valueTypeExt
l := d.decLen()
n.u = uint64(d.r.readn1())
n.l = d.r.readx(uint(l))
case simpleVdArray, simpleVdArray + 1, simpleVdArray + 2,
simpleVdArray + 3, simpleVdArray + 4:
n.v = valueTypeArray
decodeFurther = true
case simpleVdMap, simpleVdMap + 1, simpleVdMap + 2, simpleVdMap + 3, simpleVdMap + 4:
n.v = valueTypeMap
decodeFurther = true
default:
halt.errorf("cannot infer value - %s 0x%x", msgBadDesc, d.bd)
}
if !decodeFurther {
d.bdRead = false
}
}
func (d *simpleDecDriverBytes) nextValueBytes() (v []byte) {
if !d.bdRead {
d.readNextBd()
}
d.r.startRecording()
d.nextValueBytesBdReadR()
v = d.r.stopRecording()
d.bdRead = false
return
}
func (d *simpleDecDriverBytes) nextValueBytesBdReadR() {
c := d.bd
var length uint
switch c {
case simpleVdNil, simpleVdFalse, simpleVdTrue, simpleVdString, simpleVdByteArray:
case simpleVdPosInt, simpleVdNegInt:
d.r.readn1()
case simpleVdPosInt + 1, simpleVdNegInt + 1:
d.r.skip(2)
case simpleVdPosInt + 2, simpleVdNegInt + 2, simpleVdFloat32:
d.r.skip(4)
case simpleVdPosInt + 3, simpleVdNegInt + 3, simpleVdFloat64:
d.r.skip(8)
case simpleVdTime:
c = d.r.readn1()
d.r.skip(uint(c))
default:
switch c & 7 {
case 0:
length = 0
case 1:
b := d.r.readn1()
length = uint(b)
case 2:
x := d.r.readn2()
length = uint(bigen.Uint16(x))
case 3:
x := d.r.readn4()
length = uint(bigen.Uint32(x))
case 4:
x := d.r.readn8()
length = uint(bigen.Uint64(x))
}
bExt := c >= simpleVdExt && c <= simpleVdExt+7
bStr := c >= simpleVdString && c <= simpleVdString+7
bByteArray := c >= simpleVdByteArray && c <= simpleVdByteArray+7
bArray := c >= simpleVdArray && c <= simpleVdArray+7
bMap := c >= simpleVdMap && c <= simpleVdMap+7
if !(bExt || bStr || bByteArray || bArray || bMap) {
halt.errorf("cannot infer value - %s 0x%x", msgBadDesc, c)
}
if bExt {
d.r.readn1()
}
if length == 0 {
break
}
if bArray {
for i := uint(0); i < length; i++ {
d.readNextBd()
d.nextValueBytesBdReadR()
}
} else if bMap {
for i := uint(0); i < length; i++ {
d.readNextBd()
d.nextValueBytesBdReadR()
d.readNextBd()
d.nextValueBytesBdReadR()
}
} else {
d.r.skip(length)
}
}
return
}
func (d *simpleEncDriverBytes) init(hh Handle, shared *encoderBase, enc encoderI) (fp interface{}) {
callMake(&d.w)
d.h = hh.(*SimpleHandle)
d.e = shared
if shared.bytes {
fp = simpleFpEncBytes
} else {
fp = simpleFpEncIO
}
d.init2(enc)
return
}
func (e *simpleEncDriverBytes) writeBytesAsis(b []byte) { e.w.writeb(b) }
func (e *simpleEncDriverBytes) writerEnd() { e.w.end() }
func (e *simpleEncDriverBytes) resetOutBytes(out *[]byte) {
e.w.resetBytes(*out, out)
}
func (e *simpleEncDriverBytes) resetOutIO(out io.Writer) {
e.w.resetIO(out, e.h.WriterBufferSize, &e.e.blist)
}
func (d *simpleDecDriverBytes) init(hh Handle, shared *decoderBase, dec decoderI) (fp interface{}) {
callMake(&d.r)
d.h = hh.(*SimpleHandle)
d.d = shared
if shared.bytes {
fp = simpleFpDecBytes
} else {
fp = simpleFpDecIO
}
d.init2(dec)
return
}
func (d *simpleDecDriverBytes) NumBytesRead() int {
return int(d.r.numread())
}
func (d *simpleDecDriverBytes) resetInBytes(in []byte) {
d.r.resetBytes(in)
}
func (d *simpleDecDriverBytes) resetInIO(r io.Reader) {
d.r.resetIO(r, d.h.ReaderBufferSize, d.h.MaxInitLen, &d.d.blist)
}
func (d *simpleDecDriverBytes) descBd() string {
return sprintf("%v (%s)", d.bd, simpledesc(d.bd))
}
func (d *simpleDecDriverBytes) DecodeFloat32() (f float32) {
return float32(chkOvf.Float32V(d.DecodeFloat64()))
}
type helperEncDriverSimpleIO struct{}
type encFnSimpleIO struct {
i encFnInfo
fe func(*encoderSimpleIO, *encFnInfo, reflect.Value)
}
type encRtidFnSimpleIO struct {
rtid uintptr
fn *encFnSimpleIO
}
type encoderSimpleIO struct {
dh helperEncDriverSimpleIO
fp *fastpathEsSimpleIO
e simpleEncDriverIO
encoderBase
}
type helperDecDriverSimpleIO struct{}
type decFnSimpleIO struct {
i decFnInfo
fd func(*decoderSimpleIO, *decFnInfo, reflect.Value)
}
type decRtidFnSimpleIO struct {
rtid uintptr
fn *decFnSimpleIO
}
type decoderSimpleIO struct {
dh helperDecDriverSimpleIO
fp *fastpathDsSimpleIO
d simpleDecDriverIO
decoderBase
}
type simpleEncDriverIO struct {
noBuiltInTypes
encDriverNoopContainerWriter
encDriverNoState
encDriverContainerNoTrackerT
encInit2er
h *SimpleHandle
e *encoderBase
w bufioEncWriter
}
type simpleDecDriverIO struct {
h *SimpleHandle
d *decoderBase
r ioDecReader
bdAndBdread
noBuiltInTypes
decDriverNoopContainerReader
decInit2er
}
func (e *encoderSimpleIO) rawExt(_ *encFnInfo, rv reflect.Value) {
if re := rv2i(rv).(*RawExt); re == nil {
e.e.EncodeNil()
} else {
e.e.EncodeRawExt(re)
}
}
func (e *encoderSimpleIO) ext(f *encFnInfo, rv reflect.Value) {
e.e.EncodeExt(rv2i(rv), f.ti.rt, f.xfTag, f.xfFn)
}
func (e *encoderSimpleIO) selferMarshal(_ *encFnInfo, rv reflect.Value) {
rv2i(rv).(Selfer).CodecEncodeSelf(&Encoder{e})
}
func (e *encoderSimpleIO) binaryMarshal(_ *encFnInfo, rv reflect.Value) {
bs, fnerr := rv2i(rv).(encoding.BinaryMarshaler).MarshalBinary()
e.marshalRaw(bs, fnerr)
}
func (e *encoderSimpleIO) textMarshal(_ *encFnInfo, rv reflect.Value) {
bs, fnerr := rv2i(rv).(encoding.TextMarshaler).MarshalText()
e.marshalUtf8(bs, fnerr)
}
func (e *encoderSimpleIO) jsonMarshal(_ *encFnInfo, rv reflect.Value) {
bs, fnerr := rv2i(rv).(jsonMarshaler).MarshalJSON()
e.marshalAsis(bs, fnerr)
}
func (e *encoderSimpleIO) raw(_ *encFnInfo, rv reflect.Value) {
e.rawBytes(rv2i(rv).(Raw))
}
func (e *encoderSimpleIO) encodeComplex64(v complex64) {
if imag(v) != 0 {
halt.errorf("cannot encode complex number: %v, with imaginary values: %v", any(v), any(imag(v)))
}
e.e.EncodeFloat32(real(v))
}
func (e *encoderSimpleIO) encodeComplex128(v complex128) {
if imag(v) != 0 {
halt.errorf("cannot encode complex number: %v, with imaginary values: %v", any(v), any(imag(v)))
}
e.e.EncodeFloat64(real(v))
}
func (e *encoderSimpleIO) kBool(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeBool(rvGetBool(rv))
}
func (e *encoderSimpleIO) kTime(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeTime(rvGetTime(rv))
}
func (e *encoderSimpleIO) kString(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeString(rvGetString(rv))
}
func (e *encoderSimpleIO) kFloat32(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeFloat32(rvGetFloat32(rv))
}
func (e *encoderSimpleIO) kFloat64(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeFloat64(rvGetFloat64(rv))
}
func (e *encoderSimpleIO) kComplex64(_ *encFnInfo, rv reflect.Value) {
e.encodeComplex64(rvGetComplex64(rv))
}
func (e *encoderSimpleIO) kComplex128(_ *encFnInfo, rv reflect.Value) {
e.encodeComplex128(rvGetComplex128(rv))
}
func (e *encoderSimpleIO) kInt(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeInt(int64(rvGetInt(rv)))
}
func (e *encoderSimpleIO) kInt8(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeInt(int64(rvGetInt8(rv)))
}
func (e *encoderSimpleIO) kInt16(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeInt(int64(rvGetInt16(rv)))
}
func (e *encoderSimpleIO) kInt32(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeInt(int64(rvGetInt32(rv)))
}
func (e *encoderSimpleIO) kInt64(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeInt(int64(rvGetInt64(rv)))
}
func (e *encoderSimpleIO) kUint(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeUint(uint64(rvGetUint(rv)))
}
func (e *encoderSimpleIO) kUint8(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeUint(uint64(rvGetUint8(rv)))
}
func (e *encoderSimpleIO) kUint16(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeUint(uint64(rvGetUint16(rv)))
}
func (e *encoderSimpleIO) kUint32(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeUint(uint64(rvGetUint32(rv)))
}
func (e *encoderSimpleIO) kUint64(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeUint(uint64(rvGetUint64(rv)))
}
func (e *encoderSimpleIO) kUintptr(_ *encFnInfo, rv reflect.Value) {
e.e.EncodeUint(uint64(rvGetUintptr(rv)))
}
func (e *encoderSimpleIO) kSeqFn(rt reflect.Type) (fn *encFnSimpleIO) {
if rt = baseRT(rt); rt.Kind() != reflect.Interface {
fn = e.fn(rt)
}
return
}
func (e *encoderSimpleIO) kArrayWMbs(rv reflect.Value, ti *typeInfo, isSlice bool) {
var l int
if isSlice {
l = rvLenSlice(rv)
} else {
l = rv.Len()
}
if l == 0 {
e.e.WriteMapEmpty()
return
}
e.haltOnMbsOddLen(l)
e.mapStart(l >> 1)
var fn *encFnSimpleIO
builtin := ti.tielem.flagEncBuiltin
if !builtin {
fn = e.kSeqFn(ti.elem)
}
j := 0
e.c = containerMapKey
e.e.WriteMapElemKey(true)
for {
rvv := rvArrayIndex(rv, j, ti, isSlice)
if builtin {
e.encodeIB(rv2i(baseRVRV(rvv)))
} else {
e.encodeValue(rvv, fn)
}
j++
if j == l {
break
}
if j&1 == 0 {
e.c = containerMapKey
e.e.WriteMapElemKey(false)
} else {
e.mapElemValue()
}
}
e.c = 0
e.e.WriteMapEnd()
}
func (e *encoderSimpleIO) kArrayW(rv reflect.Value, ti *typeInfo, isSlice bool) {
var l int
if isSlice {
l = rvLenSlice(rv)
} else {
l = rv.Len()
}
if l <= 0 {
e.e.WriteArrayEmpty()
return
}
e.arrayStart(l)
var fn *encFnSimpleIO
if !ti.tielem.flagEncBuiltin {
fn = e.kSeqFn(ti.elem)
}
j := 0
e.c = containerArrayElem
e.e.WriteArrayElem(true)
builtin := ti.tielem.flagEncBuiltin
for {
rvv := rvArrayIndex(rv, j, ti, isSlice)
if builtin {
e.encodeIB(rv2i(baseRVRV(rvv)))
} else {
e.encodeValue(rvv, fn)
}
j++
if j == l {
break
}
e.c = containerArrayElem
e.e.WriteArrayElem(false)
}
e.c = 0
e.e.WriteArrayEnd()
}
func (e *encoderSimpleIO) kChan(f *encFnInfo, rv reflect.Value) {
if f.ti.chandir&uint8(reflect.RecvDir) == 0 {
halt.errorStr("send-only channel cannot be encoded")
}
if !f.ti.mbs && uint8TypId == rt2id(f.ti.elem) {
e.kSliceBytesChan(rv)
return
}
rtslice := reflect.SliceOf(f.ti.elem)
rv = chanToSlice(rv, rtslice, e.h.ChanRecvTimeout)
ti := e.h.getTypeInfo(rt2id(rtslice), rtslice)
if f.ti.mbs {
e.kArrayWMbs(rv, ti, true)
} else {
e.kArrayW(rv, ti, true)
}
}
func (e *encoderSimpleIO) kSlice(f *encFnInfo, rv reflect.Value) {
if f.ti.mbs {
e.kArrayWMbs(rv, f.ti, true)
} else if f.ti.rtid == uint8SliceTypId || uint8TypId == rt2id(f.ti.elem) {
e.e.EncodeBytes(rvGetBytes(rv))
} else {
e.kArrayW(rv, f.ti, true)
}
}
func (e *encoderSimpleIO) kArray(f *encFnInfo, rv reflect.Value) {
if f.ti.mbs {
e.kArrayWMbs(rv, f.ti, false)
} else if handleBytesWithinKArray && uint8TypId == rt2id(f.ti.elem) {
e.e.EncodeStringBytesRaw(rvGetArrayBytes(rv, nil))
} else {
e.kArrayW(rv, f.ti, false)
}
}
func (e *encoderSimpleIO) kSliceBytesChan(rv reflect.Value) {
bs0 := e.blist.peek(32, true)
bs := bs0
irv := rv2i(rv)
ch, ok := irv.(<-chan byte)
if !ok {
ch = irv.(chan byte)
}
L1:
switch timeout := e.h.ChanRecvTimeout; {
case timeout == 0:
for {
select {
case b := <-ch:
bs = append(bs, b)
default:
break L1
}
}
case timeout > 0:
tt := time.NewTimer(timeout)
for {
select {
case b := <-ch:
bs = append(bs, b)
case <-tt.C:
break L1
}
}
default:
for b := range ch {
bs = append(bs, b)
}
}
e.e.EncodeBytes(bs)
e.blist.put(bs)
if !byteSliceSameData(bs0, bs) {
e.blist.put(bs0)
}
}
func (e *encoderSimpleIO) kStructFieldKey(keyType valueType, encName string) {
if keyType == valueTypeString {
e.e.EncodeString(encName)
} else if keyType == valueTypeInt {
e.e.EncodeInt(must.Int(strconv.ParseInt(encName, 10, 64)))
} else if keyType == valueTypeUint {
e.e.EncodeUint(must.Uint(strconv.ParseUint(encName, 10, 64)))
} else if keyType == valueTypeFloat {
e.e.EncodeFloat64(must.Float(strconv.ParseFloat(encName, 64)))
} else {
halt.errorStr2("invalid struct key type: ", keyType.String())
}
}
func (e *encoderSimpleIO) kStructSimple(f *encFnInfo, rv reflect.Value) {
_ = e.e
tisfi := f.ti.sfi.source()
chkCirRef := e.h.CheckCircularRef
var si *structFieldInfo
var j int
if f.ti.toArray || e.h.StructToArray {
if len(tisfi) == 0 {
e.e.WriteArrayEmpty()
return
}
e.arrayStart(len(tisfi))
for j, si = range tisfi {
e.c = containerArrayElem
e.e.WriteArrayElem(j == 0)
if si.encBuiltin {
e.encodeIB(rv2i(si.fieldNoAlloc(rv, true)))
} else {
e.encodeValue(si.fieldNoAlloc(rv, !chkCirRef), nil)
}
}
e.c = 0
e.e.WriteArrayEnd()
} else {
if len(tisfi) == 0 {
e.e.WriteMapEmpty()
return
}
if e.h.Canonical {
tisfi = f.ti.sfi.sorted()
}
e.mapStart(len(tisfi))
for j, si = range tisfi {
e.c = containerMapKey
e.e.WriteMapElemKey(j == 0)
e.e.EncodeStringNoEscape4Json(si.encName)
e.mapElemValue()
if si.encBuiltin {
e.encodeIB(rv2i(si.fieldNoAlloc(rv, true)))
} else {
e.encodeValue(si.fieldNoAlloc(rv, !chkCirRef), nil)
}
}
e.c = 0
e.e.WriteMapEnd()
}
}
func (e *encoderSimpleIO) kStruct(f *encFnInfo, rv reflect.Value) {
_ = e.e
ti := f.ti
toMap := !(ti.toArray || e.h.StructToArray)
var mf map[string]interface{}
if ti.flagMissingFielder {
toMap = true
mf = rv2i(rv).(MissingFielder).CodecMissingFields()
} else if ti.flagMissingFielderPtr {
toMap = true
if rv.CanAddr() {
mf = rv2i(rvAddr(rv, ti.ptr)).(MissingFielder).CodecMissingFields()
} else {
mf = rv2i(e.addrRV(rv, ti.rt, ti.ptr)).(MissingFielder).CodecMissingFields()
}
}
newlen := len(mf)
tisfi := ti.sfi.source()
newlen += len(tisfi)
var fkvs = e.slist.get(newlen)[:newlen]
recur := e.h.RecursiveEmptyCheck
chkCirRef := e.h.CheckCircularRef
var xlen int
var kv sfiRv
var j int
var sf encStructFieldObj
if toMap {
newlen = 0
if e.h.Canonical {
tisfi = f.ti.sfi.sorted()
}
for _, si := range tisfi {
if si.omitEmpty {
kv.r = si.fieldNoAlloc(rv, false)
if isEmptyValue(kv.r, e.h.TypeInfos, recur) {
continue
}
} else {
kv.r = si.fieldNoAlloc(rv, si.encBuiltin || !chkCirRef)
}
kv.v = si
fkvs[newlen] = kv
newlen++
}
var mf2s []stringIntf
if len(mf) != 0 {
mf2s = make([]stringIntf, 0, len(mf))
for k, v := range mf {
if k == "" {
continue
}
if ti.infoFieldOmitempty && isEmptyValue(reflect.ValueOf(v), e.h.TypeInfos, recur) {
continue
}
mf2s = append(mf2s, stringIntf{k, v})
}
}
xlen = newlen + len(mf2s)
if xlen == 0 {
e.e.WriteMapEmpty()
goto END
}
e.mapStart(xlen)
if len(mf2s) != 0 && e.h.Canonical {
mf2w := make([]encStructFieldObj, newlen+len(mf2s))
for j = 0; j < newlen; j++ {
kv = fkvs[j]
mf2w[j] = encStructFieldObj{kv.v.encName, kv.r, nil, true,
!kv.v.encNameEscape4Json, kv.v.encBuiltin}
}
for _, v := range mf2s {
mf2w[j] = encStructFieldObj{v.v, reflect.Value{}, v.i, false, false, false}
j++
}
sort.Sort((encStructFieldObjSlice)(mf2w))
for j, sf = range mf2w {
e.c = containerMapKey
e.e.WriteMapElemKey(j == 0)
if ti.keyType == valueTypeString && sf.noEsc4json {
e.e.EncodeStringNoEscape4Json(sf.key)
} else {
e.kStructFieldKey(ti.keyType, sf.key)
}
e.mapElemValue()
if sf.isRv {
if sf.builtin {
e.encodeIB(rv2i(baseRVRV(sf.rv)))
} else {
e.encodeValue(sf.rv, nil)
}
} else {
if !e.encodeBuiltin(sf.intf) {
e.encodeR(reflect.ValueOf(sf.intf))
}
}
}
} else {
keytyp := ti.keyType
for j = 0; j < newlen; j++ {
kv = fkvs[j]
e.c = containerMapKey
e.e.WriteMapElemKey(j == 0)
if ti.keyType == valueTypeString && !kv.v.encNameEscape4Json {
e.e.EncodeStringNoEscape4Json(kv.v.encName)
} else {
e.kStructFieldKey(keytyp, kv.v.encName)
}
e.mapElemValue()
if kv.v.encBuiltin {
e.encodeIB(rv2i(baseRVRV(kv.r)))
} else {
e.encodeValue(kv.r, nil)
}
}
for _, v := range mf2s {
e.c = containerMapKey
e.e.WriteMapElemKey(j == 0)
e.kStructFieldKey(keytyp, v.v)
e.mapElemValue()
if !e.encodeBuiltin(v.i) {
e.encodeR(reflect.ValueOf(v.i))
}
j++
}
}
e.c = 0
e.e.WriteMapEnd()
} else {
newlen = len(tisfi)
for i, si := range tisfi {
if si.omitEmpty {
kv.r = si.fieldNoAlloc(rv, false)
if isEmptyContainerValue(kv.r, e.h.TypeInfos, recur) {
kv.r = reflect.Value{}
}
} else {
kv.r = si.fieldNoAlloc(rv, si.encBuiltin || !chkCirRef)
}
kv.v = si
fkvs[i] = kv
}
if newlen == 0 {
e.e.WriteArrayEmpty()
goto END
}
e.arrayStart(newlen)
for j = 0; j < newlen; j++ {
e.c = containerArrayElem
e.e.WriteArrayElem(j == 0)
kv = fkvs[j]
if !kv.r.IsValid() {
e.e.EncodeNil()
} else if kv.v.encBuiltin {
e.encodeIB(rv2i(baseRVRV(kv.r)))
} else {
e.encodeValue(kv.r, nil)
}
}
e.c = 0
e.e.WriteArrayEnd()
}
END:
e.slist.put(fkvs)
}
func (e *encoderSimpleIO) kMap(f *encFnInfo, rv reflect.Value) {
_ = e.e
l := rvLenMap(rv)
if l == 0 {
e.e.WriteMapEmpty()
return
}
e.mapStart(l)
var keyFn, valFn *encFnSimpleIO
ktypeKind := reflect.Kind(f.ti.keykind)
vtypeKind := reflect.Kind(f.ti.elemkind)
rtval := f.ti.elem
rtvalkind := vtypeKind
for rtvalkind == reflect.Ptr {
rtval = rtval.Elem()
rtvalkind = rtval.Kind()
}
if rtvalkind != reflect.Interface {
valFn = e.fn(rtval)
}
var rvv = mapAddrLoopvarRV(f.ti.elem, vtypeKind)
rtkey := f.ti.key
var keyTypeIsString = stringTypId == rt2id(rtkey)
if keyTypeIsString {
keyFn = e.fn(rtkey)
} else {
for rtkey.Kind() == reflect.Ptr {
rtkey = rtkey.Elem()
}
if rtkey.Kind() != reflect.Interface {
keyFn = e.fn(rtkey)
}
}
if e.h.Canonical {
e.kMapCanonical(f.ti, rv, rvv, keyFn, valFn)
e.c = 0
e.e.WriteMapEnd()
return
}
var rvk = mapAddrLoopvarRV(f.ti.key, ktypeKind)
var it mapIter
mapRange(&it, rv, rvk, rvv, true)
kbuiltin := f.ti.tikey.flagEncBuiltin
vbuiltin := f.ti.tielem.flagEncBuiltin
for j := 0; it.Next(); j++ {
rv = it.Key()
e.c = containerMapKey
e.e.WriteMapElemKey(j == 0)
if keyTypeIsString {
e.e.EncodeString(rvGetString(rv))
} else if kbuiltin {
e.encodeIB(rv2i(baseRVRV(rv)))
} else {
e.encodeValue(rv, keyFn)
}
e.mapElemValue()
rv = it.Value()
if vbuiltin {
e.encodeIB(rv2i(baseRVRV(rv)))
} else {
e.encodeValue(it.Value(), valFn)
}
}
it.Done()
e.c = 0
e.e.WriteMapEnd()
}
func (e *encoderSimpleIO) kMapCanonical(ti *typeInfo, rv, rvv reflect.Value, keyFn, valFn *encFnSimpleIO) {
_ = e.e
rtkey := ti.key
rtkeydecl := rtkey.PkgPath() == "" && rtkey.Name() != ""
mks := rv.MapKeys()
rtkeyKind := rtkey.Kind()
mparams := getMapReqParams(ti)
switch rtkeyKind {
case reflect.Bool:
if len(mks) == 2 && mks[0].Bool() {
mks[0], mks[1] = mks[1], mks[0]
}
for i := range mks {
e.c = containerMapKey
e.e.WriteMapElemKey(i == 0)
if rtkeydecl {
e.e.EncodeBool(mks[i].Bool())
} else {
e.encodeValueNonNil(mks[i], keyFn)
}
e.mapElemValue()
e.encodeValue(mapGet(rv, mks[i], rvv, mparams), valFn)
}
case reflect.String:
mksv := make([]orderedRv[string], len(mks))
for i, k := range mks {
v := &mksv[i]
v.r = k
v.v = rvGetString(k)
}
slices.SortFunc(mksv, cmpOrderedRv)
for i := range mksv {
e.c = containerMapKey
e.e.WriteMapElemKey(i == 0)
if rtkeydecl {
e.e.EncodeString(mksv[i].v)
} else {
e.encodeValueNonNil(mksv[i].r, keyFn)
}
e.mapElemValue()
e.encodeValue(mapGet(rv, mksv[i].r, rvv, mparams), valFn)
}
case reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64, reflect.Uint, reflect.Uintptr:
mksv := make([]orderedRv[uint64], len(mks))
for i, k := range mks {
v := &mksv[i]
v.r = k
v.v = k.Uint()
}
slices.SortFunc(mksv, cmpOrderedRv)
for i := range mksv {
e.c = containerMapKey
e.e.WriteMapElemKey(i == 0)
if rtkeydecl {
e.e.EncodeUint(mksv[i].v)
} else {
e.encodeValueNonNil(mksv[i].r, keyFn)
}
e.mapElemValue()
e.encodeValue(mapGet(rv, mksv[i].r, rvv, mparams), valFn)
}
case reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64, reflect.Int:
mksv := make([]orderedRv[int64], len(mks))
for i, k := range mks {
v := &mksv[i]
v.r = k
v.v = k.Int()
}
slices.SortFunc(mksv, cmpOrderedRv)
for i := range mksv {
e.c = containerMapKey
e.e.WriteMapElemKey(i == 0)
if rtkeydecl {
e.e.EncodeInt(mksv[i].v)
} else {
e.encodeValueNonNil(mksv[i].r, keyFn)
}
e.mapElemValue()
e.encodeValue(mapGet(rv, mksv[i].r, rvv, mparams), valFn)
}
case reflect.Float32:
mksv := make([]orderedRv[float64], len(mks))
for i, k := range mks {
v := &mksv[i]
v.r = k
v.v = k.Float()
}
slices.SortFunc(mksv, cmpOrderedRv)
for i := range mksv {
e.c = containerMapKey
e.e.WriteMapElemKey(i == 0)
if rtkeydecl {
e.e.EncodeFloat32(float32(mksv[i].v))
} else {
e.encodeValueNonNil(mksv[i].r, keyFn)
}
e.mapElemValue()
e.encodeValue(mapGet(rv, mksv[i].r, rvv, mparams), valFn)
}
case reflect.Float64:
mksv := make([]orderedRv[float64], len(mks))
for i, k := range mks {
v := &mksv[i]
v.r = k
v.v = k.Float()
}
slices.SortFunc(mksv, cmpOrderedRv)
for i := range mksv {
e.c = containerMapKey
e.e.WriteMapElemKey(i == 0)
if rtkeydecl {
e.e.EncodeFloat64(mksv[i].v)
} else {
e.encodeValueNonNil(mksv[i].r, keyFn)
}
e.mapElemValue()
e.encodeValue(mapGet(rv, mksv[i].r, rvv, mparams), valFn)
}
default:
if rtkey == timeTyp {
mksv := make([]timeRv, len(mks))
for i, k := range mks {
v := &mksv[i]
v.r = k
v.v = rv2i(k).(time.Time)
}
slices.SortFunc(mksv, cmpTimeRv)
for i := range mksv {
e.c = containerMapKey
e.e.WriteMapElemKey(i == 0)
e.e.EncodeTime(mksv[i].v)
e.mapElemValue()
e.encodeValue(mapGet(rv, mksv[i].r, rvv, mparams), valFn)
}
break
}
bs0 := e.blist.get(len(mks) * 16)
mksv := bs0
mksbv := make([]bytesRv, len(mks))
sideEncode(e.hh, &e.h.sideEncPool, func(se encoderI) {
se.ResetBytes(&mksv)
for i, k := range mks {
v := &mksbv[i]
l := len(mksv)
se.setContainerState(containerMapKey)
se.encodeR(baseRVRV(k))
se.atEndOfEncode()
se.writerEnd()
v.r = k
v.v = mksv[l:]
}
})
slices.SortFunc(mksbv, cmpBytesRv)
for j := range mksbv {
e.c = containerMapKey
e.e.WriteMapElemKey(j == 0)
e.e.writeBytesAsis(mksbv[j].v)
e.mapElemValue()
e.encodeValue(mapGet(rv, mksbv[j].r, rvv, mparams), valFn)
}
e.blist.put(mksv)
if !byteSliceSameData(bs0, mksv) {
e.blist.put(bs0)
}
}
}
func (e *encoderSimpleIO) init(h Handle) {
initHandle(h)
callMake(&e.e)
e.hh = h
e.h = h.getBasicHandle()
e.err = errEncoderNotInitialized
e.fp = e.e.init(h, &e.encoderBase, e).(*fastpathEsSimpleIO)
if e.bytes {
e.rtidFn = &e.h.rtidFnsEncBytes
e.rtidFnNoExt = &e.h.rtidFnsEncNoExtBytes
} else {
e.rtidFn = &e.h.rtidFnsEncIO
e.rtidFnNoExt = &e.h.rtidFnsEncNoExtIO
}
e.reset()
}
func (e *encoderSimpleIO) reset() {
e.e.reset()
if e.ci != nil {
e.ci = e.ci[:0]
}
e.c = 0
e.calls = 0
e.seq = 0
e.err = nil
}
func (e *encoderSimpleIO) Encode(v interface{}) (err error) {
defer panicValToErr(e, callRecoverSentinel, &e.err, &err, debugging)
e.mustEncode(v)
return
}
func (e *encoderSimpleIO) MustEncode(v interface{}) {
defer panicValToErr(e, callRecoverSentinel, &e.err, nil, true)
e.mustEncode(v)
return
}
func (e *encoderSimpleIO) mustEncode(v interface{}) {
halt.onerror(e.err)
if e.hh == nil {
halt.onerror(errNoFormatHandle)
}
e.calls++
if !e.encodeBuiltin(v) {
e.encodeR(reflect.ValueOf(v))
}
e.calls--
if e.calls == 0 {
e.e.atEndOfEncode()
e.e.writerEnd()
}
}
func (e *encoderSimpleIO) encodeI(iv interface{}) {
if !e.encodeBuiltin(iv) {
e.encodeR(reflect.ValueOf(iv))
}
}
func (e *encoderSimpleIO) encodeIB(iv interface{}) {
if !e.encodeBuiltin(iv) {
halt.errorStr("[should not happen] invalid type passed to encodeBuiltin")
}
}
func (e *encoderSimpleIO) encodeR(base reflect.Value) {
e.encodeValue(base, nil)
}
func (e *encoderSimpleIO) encodeBuiltin(iv interface{}) (ok bool) {
ok = true
switch v := iv.(type) {
case nil:
e.e.EncodeNil()
case Raw:
e.rawBytes(v)
case string:
e.e.EncodeString(v)
case bool:
e.e.EncodeBool(v)
case int:
e.e.EncodeInt(int64(v))
case int8:
e.e.EncodeInt(int64(v))
case int16:
e.e.EncodeInt(int64(v))
case int32:
e.e.EncodeInt(int64(v))
case int64:
e.e.EncodeInt(v)
case uint:
e.e.EncodeUint(uint64(v))
case uint8:
e.e.EncodeUint(uint64(v))
case uint16:
e.e.EncodeUint(uint64(v))
case uint32:
e.e.EncodeUint(uint64(v))
case uint64:
e.e.EncodeUint(v)
case uintptr:
e.e.EncodeUint(uint64(v))
case float32:
e.e.EncodeFloat32(v)
case float64:
e.e.EncodeFloat64(v)
case complex64:
e.encodeComplex64(v)
case complex128:
e.encodeComplex128(v)
case time.Time:
e.e.EncodeTime(v)
case []byte:
e.e.EncodeBytes(v)
default:
ok = !skipFastpathTypeSwitchInDirectCall && e.dh.fastpathEncodeTypeSwitch(iv, e)
}
return
}
func (e *encoderSimpleIO) encodeValue(rv reflect.Value, fn *encFnSimpleIO) {
var ciPushes int
var rvp reflect.Value
var rvpValid bool
RV:
switch rv.Kind() {
case reflect.Ptr:
if rvIsNil(rv) {
e.e.EncodeNil()
goto END
}
rvpValid = true
rvp = rv
rv = rv.Elem()
if e.h.CheckCircularRef && e.ci.canPushElemKind(rv.Kind()) {
e.ci.push(rv2i(rvp))
ciPushes++
}
goto RV
case reflect.Interface:
if rvIsNil(rv) {
e.e.EncodeNil()
goto END
}
rvpValid = false
rvp = reflect.Value{}
rv = rv.Elem()
fn = nil
goto RV
case reflect.Map:
if rvIsNil(rv) {
if e.h.NilCollectionToZeroLength {
e.e.WriteMapEmpty()
} else {
e.e.EncodeNil()
}
goto END
}
case reflect.Slice, reflect.Chan:
if rvIsNil(rv) {
if e.h.NilCollectionToZeroLength {
e.e.WriteArrayEmpty()
} else {
e.e.EncodeNil()
}
goto END
}
case reflect.Invalid, reflect.Func:
e.e.EncodeNil()
goto END
}
if fn == nil {
fn = e.fn(rv.Type())
}
if !fn.i.addrE {
} else if rvpValid {
rv = rvp
} else if rv.CanAddr() {
rv = rvAddr(rv, fn.i.ti.ptr)
} else {
rv = e.addrRV(rv, fn.i.ti.rt, fn.i.ti.ptr)
}
fn.fe(e, &fn.i, rv)
END:
if ciPushes > 0 {
e.ci.pop(ciPushes)
}
}
func (e *encoderSimpleIO) encodeValueNonNil(rv reflect.Value, fn *encFnSimpleIO) {
if fn.i.addrE {
if rv.CanAddr() {
rv = rvAddr(rv, fn.i.ti.ptr)
} else {
rv = e.addrRV(rv, fn.i.ti.rt, fn.i.ti.ptr)
}
}
fn.fe(e, &fn.i, rv)
}
func (e *encoderSimpleIO) encodeAs(v interface{}, t reflect.Type, ext bool) {
if ext {
e.encodeValue(baseRV(v), e.fn(t))
} else {
e.encodeValue(baseRV(v), e.fnNoExt(t))
}
}
func (e *encoderSimpleIO) marshalUtf8(bs []byte, fnerr error) {
halt.onerror(fnerr)
if bs == nil {
e.e.EncodeNil()
} else {
e.e.EncodeString(stringView(bs))
}
}
func (e *encoderSimpleIO) marshalAsis(bs []byte, fnerr error) {
halt.onerror(fnerr)
if bs == nil {
e.e.EncodeNil()
} else {
e.e.writeBytesAsis(bs)
}
}
func (e *encoderSimpleIO) marshalRaw(bs []byte, fnerr error) {
halt.onerror(fnerr)
e.e.EncodeBytes(bs)
}
func (e *encoderSimpleIO) rawBytes(vv Raw) {
v := []byte(vv)
if !e.h.Raw {
halt.errorBytes("Raw values cannot be encoded: ", v)
}
e.e.writeBytesAsis(v)
}
func (e *encoderSimpleIO) fn(t reflect.Type) *encFnSimpleIO {
return e.dh.encFnViaBH(t, e.rtidFn, e.h, e.fp, false)
}
func (e *encoderSimpleIO) fnNoExt(t reflect.Type) *encFnSimpleIO {
return e.dh.encFnViaBH(t, e.rtidFnNoExt, e.h, e.fp, true)
}
func (e *encoderSimpleIO) mapStart(length int) {
e.e.WriteMapStart(length)
e.c = containerMapStart
}
func (e *encoderSimpleIO) mapElemValue() {
e.e.WriteMapElemValue()
e.c = containerMapValue
}
func (e *encoderSimpleIO) arrayStart(length int) {
e.e.WriteArrayStart(length)
e.c = containerArrayStart
}
func (e *encoderSimpleIO) writerEnd() {
e.e.writerEnd()
}
func (e *encoderSimpleIO) atEndOfEncode() {
e.e.atEndOfEncode()
}
func (e *encoderSimpleIO) Reset(w io.Writer) {
if e.bytes {
halt.onerror(errEncNoResetBytesWithWriter)
}
e.reset()
if w == nil {
w = io.Discard
}
e.e.resetOutIO(w)
}
func (e *encoderSimpleIO) ResetBytes(out *[]byte) {
if !e.bytes {
halt.onerror(errEncNoResetWriterWithBytes)
}
e.resetBytes(out)
}
func (e *encoderSimpleIO) resetBytes(out *[]byte) {
e.reset()
if out == nil {
out = &bytesEncAppenderDefOut
}
e.e.resetOutBytes(out)
}
func (helperEncDriverSimpleIO) newEncoderBytes(out *[]byte, h Handle) *encoderSimpleIO {
var c1 encoderSimpleIO
c1.bytes = true
c1.init(h)
c1.ResetBytes(out)
return &c1
}
func (helperEncDriverSimpleIO) newEncoderIO(out io.Writer, h Handle) *encoderSimpleIO {
var c1 encoderSimpleIO
c1.bytes = false
c1.init(h)
c1.Reset(out)
return &c1
}
func (helperEncDriverSimpleIO) encFnloadFastpathUnderlying(ti *typeInfo, fp *fastpathEsSimpleIO) (f *fastpathESimpleIO, u reflect.Type) {
rtid := rt2id(ti.fastpathUnderlying)
idx, ok := fastpathAvIndex(rtid)
if !ok {
return
}
f = &fp[idx]
if uint8(reflect.Array) == ti.kind {
u = reflect.ArrayOf(ti.rt.Len(), ti.elem)
} else {
u = f.rt
}
return
}
func (helperEncDriverSimpleIO) encFindRtidFn(s []encRtidFnSimpleIO, rtid uintptr) (i uint, fn *encFnSimpleIO) {
var h uint
var j = uint(len(s))
LOOP:
if i < j {
h = (i + j) >> 1
if s[h].rtid < rtid {
i = h + 1
} else {
j = h
}
goto LOOP
}
if i < uint(len(s)) && s[i].rtid == rtid {
fn = s[i].fn
}
return
}
func (helperEncDriverSimpleIO) encFromRtidFnSlice(fns *atomicRtidFnSlice) (s []encRtidFnSimpleIO) {
if v := fns.load(); v != nil {
s = *(lowLevelToPtr[[]encRtidFnSimpleIO](v))
}
return
}
func (dh helperEncDriverSimpleIO) encFnViaBH(rt reflect.Type, fns *atomicRtidFnSlice,
x *BasicHandle, fp *fastpathEsSimpleIO, checkExt bool) (fn *encFnSimpleIO) {
return dh.encFnVia(rt, fns, x.typeInfos(), &x.mu, x.extHandle, fp,
checkExt, x.CheckCircularRef, x.timeBuiltin, x.binaryHandle, x.jsonHandle)
}
func (dh helperEncDriverSimpleIO) encFnVia(rt reflect.Type, fns *atomicRtidFnSlice,
tinfos *TypeInfos, mu *sync.Mutex, exth extHandle, fp *fastpathEsSimpleIO,
checkExt, checkCircularRef, timeBuiltin, binaryEncoding, json bool) (fn *encFnSimpleIO) {
rtid := rt2id(rt)
var sp []encRtidFnSimpleIO = dh.encFromRtidFnSlice(fns)
if sp != nil {
_, fn = dh.encFindRtidFn(sp, rtid)
}
if fn == nil {
fn = dh.encFnViaLoader(rt, rtid, fns, tinfos, mu, exth, fp, checkExt, checkCircularRef, timeBuiltin, binaryEncoding, json)
}
return
}
func (dh helperEncDriverSimpleIO) encFnViaLoader(rt reflect.Type, rtid uintptr, fns *atomicRtidFnSlice,
tinfos *TypeInfos, mu *sync.Mutex, exth extHandle, fp *fastpathEsSimpleIO,
checkExt, checkCircularRef, timeBuiltin, binaryEncoding, json bool) (fn *encFnSimpleIO) {
fn = dh.encFnLoad(rt, rtid, tinfos, exth, fp, checkExt, checkCircularRef, timeBuiltin, binaryEncoding, json)
var sp []encRtidFnSimpleIO
mu.Lock()
sp = dh.encFromRtidFnSlice(fns)
if sp == nil {
sp = []encRtidFnSimpleIO{{rtid, fn}}
fns.store(ptrToLowLevel(&sp))
} else {
idx, fn2 := dh.encFindRtidFn(sp, rtid)
if fn2 == nil {
sp2 := make([]encRtidFnSimpleIO, len(sp)+1)
copy(sp2[idx+1:], sp[idx:])
copy(sp2, sp[:idx])
sp2[idx] = encRtidFnSimpleIO{rtid, fn}
fns.store(ptrToLowLevel(&sp2))
}
}
mu.Unlock()
return
}
func (dh helperEncDriverSimpleIO) encFnLoad(rt reflect.Type, rtid uintptr, tinfos *TypeInfos,
exth extHandle, fp *fastpathEsSimpleIO,
checkExt, checkCircularRef, timeBuiltin, binaryEncoding, json bool) (fn *encFnSimpleIO) {
fn = new(encFnSimpleIO)
fi := &(fn.i)
ti := tinfos.get(rtid, rt)
fi.ti = ti
rk := reflect.Kind(ti.kind)
if rtid == timeTypId && timeBuiltin {
fn.fe = (*encoderSimpleIO).kTime
} else if rtid == rawTypId {
fn.fe = (*encoderSimpleIO).raw
} else if rtid == rawExtTypId {
fn.fe = (*encoderSimpleIO).rawExt
fi.addrE = true
} else if xfFn := exth.getExt(rtid, checkExt); xfFn != nil {
fi.xfTag, fi.xfFn = xfFn.tag, xfFn.ext
fn.fe = (*encoderSimpleIO).ext
if rk == reflect.Struct || rk == reflect.Array {
fi.addrE = true
}
} else if ti.flagSelfer || ti.flagSelferPtr {
fn.fe = (*encoderSimpleIO).selferMarshal
fi.addrE = ti.flagSelferPtr
} else if supportMarshalInterfaces && binaryEncoding &&
(ti.flagBinaryMarshaler || ti.flagBinaryMarshalerPtr) &&
(ti.flagBinaryUnmarshaler || ti.flagBinaryUnmarshalerPtr) {
fn.fe = (*encoderSimpleIO).binaryMarshal
fi.addrE = ti.flagBinaryMarshalerPtr
} else if supportMarshalInterfaces && !binaryEncoding && json &&
(ti.flagJsonMarshaler || ti.flagJsonMarshalerPtr) &&
(ti.flagJsonUnmarshaler || ti.flagJsonUnmarshalerPtr) {
fn.fe = (*encoderSimpleIO).jsonMarshal
fi.addrE = ti.flagJsonMarshalerPtr
} else if supportMarshalInterfaces && !binaryEncoding &&
(ti.flagTextMarshaler || ti.flagTextMarshalerPtr) &&
(ti.flagTextUnmarshaler || ti.flagTextUnmarshalerPtr) {
fn.fe = (*encoderSimpleIO).textMarshal
fi.addrE = ti.flagTextMarshalerPtr
} else {
if fastpathEnabled && (rk == reflect.Map || rk == reflect.Slice || rk == reflect.Array) {
var rtid2 uintptr
if !ti.flagHasPkgPath {
rtid2 = rtid
if rk == reflect.Array {
rtid2 = rt2id(ti.key)
}
if idx, ok := fastpathAvIndex(rtid2); ok {
fn.fe = fp[idx].encfn
}
} else {
xfe, xrt := dh.encFnloadFastpathUnderlying(ti, fp)
if xfe != nil {
xfnf := xfe.encfn
fn.fe = func(e *encoderSimpleIO, xf *encFnInfo, xrv reflect.Value) {
xfnf(e, xf, rvConvert(xrv, xrt))
}
}
}
}
if fn.fe == nil {
switch rk {
case reflect.Bool:
fn.fe = (*encoderSimpleIO).kBool
case reflect.String:
fn.fe = (*encoderSimpleIO).kString
case reflect.Int:
fn.fe = (*encoderSimpleIO).kInt
case reflect.Int8:
fn.fe = (*encoderSimpleIO).kInt8
case reflect.Int16:
fn.fe = (*encoderSimpleIO).kInt16
case reflect.Int32:
fn.fe = (*encoderSimpleIO).kInt32
case reflect.Int64:
fn.fe = (*encoderSimpleIO).kInt64
case reflect.Uint:
fn.fe = (*encoderSimpleIO).kUint
case reflect.Uint8:
fn.fe = (*encoderSimpleIO).kUint8
case reflect.Uint16:
fn.fe = (*encoderSimpleIO).kUint16
case reflect.Uint32:
fn.fe = (*encoderSimpleIO).kUint32
case reflect.Uint64:
fn.fe = (*encoderSimpleIO).kUint64
case reflect.Uintptr:
fn.fe = (*encoderSimpleIO).kUintptr
case reflect.Float32:
fn.fe = (*encoderSimpleIO).kFloat32
case reflect.Float64:
fn.fe = (*encoderSimpleIO).kFloat64
case reflect.Complex64:
fn.fe = (*encoderSimpleIO).kComplex64
case reflect.Complex128:
fn.fe = (*encoderSimpleIO).kComplex128
case reflect.Chan:
fn.fe = (*encoderSimpleIO).kChan
case reflect.Slice:
fn.fe = (*encoderSimpleIO).kSlice
case reflect.Array:
fn.fe = (*encoderSimpleIO).kArray
case reflect.Struct:
if ti.simple {
fn.fe = (*encoderSimpleIO).kStructSimple
} else {
fn.fe = (*encoderSimpleIO).kStruct
}
case reflect.Map:
fn.fe = (*encoderSimpleIO).kMap
case reflect.Interface:
fn.fe = (*encoderSimpleIO).kErr
default:
fn.fe = (*encoderSimpleIO).kErr
}
}
}
return
}
func (d *decoderSimpleIO) rawExt(f *decFnInfo, rv reflect.Value) {
d.d.DecodeRawExt(rv2i(rv).(*RawExt))
}
func (d *decoderSimpleIO) ext(f *decFnInfo, rv reflect.Value) {
d.d.DecodeExt(rv2i(rv), f.ti.rt, f.xfTag, f.xfFn)
}
func (d *decoderSimpleIO) selferUnmarshal(_ *decFnInfo, rv reflect.Value) {
rv2i(rv).(Selfer).CodecDecodeSelf(&Decoder{d})
}
func (d *decoderSimpleIO) binaryUnmarshal(_ *decFnInfo, rv reflect.Value) {
bm := rv2i(rv).(encoding.BinaryUnmarshaler)
xbs, _ := d.d.DecodeBytes()
fnerr := bm.UnmarshalBinary(xbs)
halt.onerror(fnerr)
}
func (d *decoderSimpleIO) textUnmarshal(_ *decFnInfo, rv reflect.Value) {
tm := rv2i(rv).(encoding.TextUnmarshaler)
fnerr := tm.UnmarshalText(bytesOKs(d.d.DecodeStringAsBytes()))
halt.onerror(fnerr)
}
func (d *decoderSimpleIO) jsonUnmarshal(_ *decFnInfo, rv reflect.Value) {
d.jsonUnmarshalV(rv2i(rv).(jsonUnmarshaler))
}
func (d *decoderSimpleIO) jsonUnmarshalV(tm jsonUnmarshaler) {
halt.onerror(tm.UnmarshalJSON(d.d.nextValueBytes()))
}
func (d *decoderSimpleIO) kErr(_ *decFnInfo, rv reflect.Value) {
halt.errorf("unsupported decoding kind: %s, for %#v", rv.Kind(), rv)
}
func (d *decoderSimpleIO) raw(_ *decFnInfo, rv reflect.Value) {
rvSetBytes(rv, d.rawBytes())
}
func (d *decoderSimpleIO) kString(_ *decFnInfo, rv reflect.Value) {
rvSetString(rv, d.detach2Str(d.d.DecodeStringAsBytes()))
}
func (d *decoderSimpleIO) kBool(_ *decFnInfo, rv reflect.Value) {
rvSetBool(rv, d.d.DecodeBool())
}
func (d *decoderSimpleIO) kTime(_ *decFnInfo, rv reflect.Value) {
rvSetTime(rv, d.d.DecodeTime())
}
func (d *decoderSimpleIO) kFloat32(_ *decFnInfo, rv reflect.Value) {
rvSetFloat32(rv, d.d.DecodeFloat32())
}
func (d *decoderSimpleIO) kFloat64(_ *decFnInfo, rv reflect.Value) {
rvSetFloat64(rv, d.d.DecodeFloat64())
}
func (d *decoderSimpleIO) kComplex64(_ *decFnInfo, rv reflect.Value) {
rvSetComplex64(rv, complex(d.d.DecodeFloat32(), 0))
}
func (d *decoderSimpleIO) kComplex128(_ *decFnInfo, rv reflect.Value) {
rvSetComplex128(rv, complex(d.d.DecodeFloat64(), 0))
}
func (d *decoderSimpleIO) kInt(_ *decFnInfo, rv reflect.Value) {
rvSetInt(rv, int(chkOvf.IntV(d.d.DecodeInt64(), intBitsize)))
}
func (d *decoderSimpleIO) kInt8(_ *decFnInfo, rv reflect.Value) {
rvSetInt8(rv, int8(chkOvf.IntV(d.d.DecodeInt64(), 8)))
}
func (d *decoderSimpleIO) kInt16(_ *decFnInfo, rv reflect.Value) {
rvSetInt16(rv, int16(chkOvf.IntV(d.d.DecodeInt64(), 16)))
}
func (d *decoderSimpleIO) kInt32(_ *decFnInfo, rv reflect.Value) {
rvSetInt32(rv, int32(chkOvf.IntV(d.d.DecodeInt64(), 32)))
}
func (d *decoderSimpleIO) kInt64(_ *decFnInfo, rv reflect.Value) {
rvSetInt64(rv, d.d.DecodeInt64())
}
func (d *decoderSimpleIO) kUint(_ *decFnInfo, rv reflect.Value) {
rvSetUint(rv, uint(chkOvf.UintV(d.d.DecodeUint64(), uintBitsize)))
}
func (d *decoderSimpleIO) kUintptr(_ *decFnInfo, rv reflect.Value) {
rvSetUintptr(rv, uintptr(chkOvf.UintV(d.d.DecodeUint64(), uintBitsize)))
}
func (d *decoderSimpleIO) kUint8(_ *decFnInfo, rv reflect.Value) {
rvSetUint8(rv, uint8(chkOvf.UintV(d.d.DecodeUint64(), 8)))
}
func (d *decoderSimpleIO) kUint16(_ *decFnInfo, rv reflect.Value) {
rvSetUint16(rv, uint16(chkOvf.UintV(d.d.DecodeUint64(), 16)))
}
func (d *decoderSimpleIO) kUint32(_ *decFnInfo, rv reflect.Value) {
rvSetUint32(rv, uint32(chkOvf.UintV(d.d.DecodeUint64(), 32)))
}
func (d *decoderSimpleIO) kUint64(_ *decFnInfo, rv reflect.Value) {
rvSetUint64(rv, d.d.DecodeUint64())
}
func (d *decoderSimpleIO) kInterfaceNaked(f *decFnInfo) (rvn reflect.Value) {
n := d.naked()
d.d.DecodeNaked()
if decFailNonEmptyIntf && f.ti.numMeth > 0 {
halt.errorf("cannot decode non-nil codec value into nil %v (%v methods)", f.ti.rt, f.ti.numMeth)
}
switch n.v {
case valueTypeMap:
mtid := d.mtid
if mtid == 0 {
if d.jsms {
mtid = mapStrIntfTypId
} else {
mtid = mapIntfIntfTypId
}
}
if mtid == mapStrIntfTypId {
var v2 map[string]interface{}
d.decode(&v2)
rvn = rv4iptr(&v2).Elem()
} else if mtid == mapIntfIntfTypId {
var v2 map[interface{}]interface{}
d.decode(&v2)
rvn = rv4iptr(&v2).Elem()
} else if d.mtr {
rvn = reflect.New(d.h.MapType)
d.decode(rv2i(rvn))
rvn = rvn.Elem()
} else {
rvn = rvZeroAddrK(d.h.MapType, reflect.Map)
d.decodeValue(rvn, nil)
}
case valueTypeArray:
if d.stid == 0 || d.stid == intfSliceTypId {
var v2 []interface{}
d.decode(&v2)
rvn = rv4iptr(&v2).Elem()
} else if d.str {
rvn = reflect.New(d.h.SliceType)
d.decode(rv2i(rvn))
rvn = rvn.Elem()
} else {
rvn = rvZeroAddrK(d.h.SliceType, reflect.Slice)
d.decodeValue(rvn, nil)
}
if d.h.PreferArrayOverSlice {
rvn = rvGetArray4Slice(rvn)
}
case valueTypeExt:
tag, bytes := n.u, n.l
bfn := d.h.getExtForTag(tag)
var re = RawExt{Tag: tag}
if bytes == nil {
if bfn == nil {
d.decode(&re.Value)
rvn = rv4iptr(&re).Elem()
} else if bfn.ext == SelfExt {
rvn = rvZeroAddrK(bfn.rt, bfn.rt.Kind())
d.decodeValue(rvn, d.fnNoExt(bfn.rt))
} else {
rvn = reflect.New(bfn.rt)
d.interfaceExtConvertAndDecode(rv2i(rvn), bfn.ext)
rvn = rvn.Elem()
}
} else {
if bfn == nil {
re.setData(bytes, false)
rvn = rv4iptr(&re).Elem()
} else {
rvn = reflect.New(bfn.rt)
if bfn.ext == SelfExt {
sideDecode(d.hh, &d.h.sideDecPool, func(sd decoderI) { oneOffDecode(sd, rv2i(rvn), bytes, bfn.rt, true) })
} else {
bfn.ext.ReadExt(rv2i(rvn), bytes)
}
rvn = rvn.Elem()
}
}
if d.h.PreferPointerForStructOrArray && rvn.CanAddr() {
if rk := rvn.Kind(); rk == reflect.Array || rk == reflect.Struct {
rvn = rvn.Addr()
}
}
case valueTypeNil:
case valueTypeInt:
rvn = n.ri()
case valueTypeUint:
rvn = n.ru()
case valueTypeFloat:
rvn = n.rf()
case valueTypeBool:
rvn = n.rb()
case valueTypeString, valueTypeSymbol:
rvn = n.rs()
case valueTypeBytes:
rvn = n.rl()
case valueTypeTime:
rvn = n.rt()
default:
halt.errorStr2("kInterfaceNaked: unexpected valueType: ", n.v.String())
}
return
}
func (d *decoderSimpleIO) kInterface(f *decFnInfo, rv reflect.Value) {
isnilrv := rvIsNil(rv)
var rvn reflect.Value
if d.h.InterfaceReset {
rvn = d.h.intf2impl(f.ti.rtid)
if !rvn.IsValid() {
rvn = d.kInterfaceNaked(f)
if rvn.IsValid() {
rvSetIntf(rv, rvn)
} else if !isnilrv {
decSetNonNilRV2Zero4Intf(rv)
}
return
}
} else if isnilrv {
rvn = d.h.intf2impl(f.ti.rtid)
if !rvn.IsValid() {
rvn = d.kInterfaceNaked(f)
if rvn.IsValid() {
rvSetIntf(rv, rvn)
}
return
}
} else {
rvn = rv.Elem()
}
canDecode, _ := isDecodeable(rvn)
if !canDecode {
rvn2 := d.oneShotAddrRV(rvn.Type(), rvn.Kind())
rvSetDirect(rvn2, rvn)
rvn = rvn2
}
d.decodeValue(rvn, nil)
rvSetIntf(rv, rvn)
}
func (d *decoderSimpleIO) kStructField(si *structFieldInfo, rv reflect.Value) {
if d.d.TryNil() {
rv = si.fieldNoAlloc(rv, true)
if rv.IsValid() {
decSetNonNilRV2Zero(rv)
}
} else if si.decBuiltin {
rv = rvAddr(si.fieldAlloc(rv), si.ptrTyp)
d.decode(rv2i(rv))
} else {
fn := d.fn(si.baseTyp)
rv = si.fieldAlloc(rv)
if fn.i.addrD {
rv = rvAddr(rv, si.ptrTyp)
}
fn.fd(d, &fn.i, rv)
}
}
func (d *decoderSimpleIO) kStructSimple(f *decFnInfo, rv reflect.Value) {
_ = d.d
ctyp := d.d.ContainerType()
ti := f.ti
if ctyp == valueTypeMap {
containerLen := d.mapStart(d.d.ReadMapStart())
if containerLen == 0 {
d.mapEnd()
return
}
hasLen := containerLen >= 0
var rvkencname []byte
for j := 0; d.containerNext(j, containerLen, hasLen); j++ {
d.mapElemKey(j == 0)
sab, att := d.d.DecodeStringAsBytes()
rvkencname = d.usableStructFieldNameBytes(rvkencname, sab, att)
d.mapElemValue()
if si := ti.siForEncName(rvkencname); si != nil {
d.kStructField(si, rv)
} else {
d.structFieldNotFound(-1, stringView(rvkencname))
}
}
d.mapEnd()
} else if ctyp == valueTypeArray {
containerLen := d.arrayStart(d.d.ReadArrayStart())
if containerLen == 0 {
d.arrayEnd()
return
}
tisfi := ti.sfi.source()
hasLen := containerLen >= 0
for j := 0; d.containerNext(j, containerLen, hasLen); j++ {
d.arrayElem(j == 0)
if j < len(tisfi) {
d.kStructField(tisfi[j], rv)
} else {
d.structFieldNotFound(j, "")
}
}
d.arrayEnd()
} else {
halt.onerror(errNeedMapOrArrayDecodeToStruct)
}
}
func (d *decoderSimpleIO) kStruct(f *decFnInfo, rv reflect.Value) {
_ = d.d
ctyp := d.d.ContainerType()
ti := f.ti
var mf MissingFielder
if ti.flagMissingFielder {
mf = rv2i(rv).(MissingFielder)
} else if ti.flagMissingFielderPtr {
mf = rv2i(rvAddr(rv, ti.ptr)).(MissingFielder)
}
if ctyp == valueTypeMap {
containerLen := d.mapStart(d.d.ReadMapStart())
if containerLen == 0 {
d.mapEnd()
return
}
hasLen := containerLen >= 0
var name2 []byte
var rvkencname []byte
tkt := ti.keyType
for j := 0; d.containerNext(j, containerLen, hasLen); j++ {
d.mapElemKey(j == 0)
if tkt == valueTypeString {
sab, att := d.d.DecodeStringAsBytes()
rvkencname = d.usableStructFieldNameBytes(rvkencname, sab, att)
} else if tkt == valueTypeInt {
rvkencname = strconv.AppendInt(d.b[:0], d.d.DecodeInt64(), 10)
} else if tkt == valueTypeUint {
rvkencname = strconv.AppendUint(d.b[:0], d.d.DecodeUint64(), 10)
} else if tkt == valueTypeFloat {
rvkencname = strconv.AppendFloat(d.b[:0], d.d.DecodeFloat64(), 'f', -1, 64)
} else {
halt.errorStr2("invalid struct key type: ", ti.keyType.String())
}
d.mapElemValue()
if si := ti.siForEncName(rvkencname); si != nil {
d.kStructField(si, rv)
} else if mf != nil {
name2 = append(name2[:0], rvkencname...)
var f interface{}
d.decode(&f)
if !mf.CodecMissingField(name2, f) && d.h.ErrorIfNoField {
halt.errorStr2("no matching struct field when decoding stream map with key: ", stringView(name2))
}
} else {
d.structFieldNotFound(-1, stringView(rvkencname))
}
}
d.mapEnd()
} else if ctyp == valueTypeArray {
containerLen := d.arrayStart(d.d.ReadArrayStart())
if containerLen == 0 {
d.arrayEnd()
return
}
tisfi := ti.sfi.source()
hasLen := containerLen >= 0
for j := 0; d.containerNext(j, containerLen, hasLen); j++ {
d.arrayElem(j == 0)
if j < len(tisfi) {
d.kStructField(tisfi[j], rv)
} else {
d.structFieldNotFound(j, "")
}
}
d.arrayEnd()
} else {
halt.onerror(errNeedMapOrArrayDecodeToStruct)
}
}
func (d *decoderSimpleIO) kSlice(f *decFnInfo, rv reflect.Value) {
_ = d.d
ti := f.ti
rvCanset := rv.CanSet()
ctyp := d.d.ContainerType()
if ctyp == valueTypeBytes || ctyp == valueTypeString {
if !(ti.rtid == uint8SliceTypId || ti.elemkind == uint8(reflect.Uint8)) {
halt.errorf("bytes/string in stream must decode into slice/array of bytes, not %v", ti.rt)
}
rvbs := rvGetBytes(rv)
if rvCanset {
bs2, bst := d.decodeBytesInto(rvbs, false)
if bst != dBytesIntoParamOut {
rvSetBytes(rv, bs2)
}
} else {
d.decodeBytesInto(rvbs[:len(rvbs):len(rvbs)], true)
}
return
}
var containerLenS int
isArray := ctyp == valueTypeArray
if isArray {
containerLenS = d.arrayStart(d.d.ReadArrayStart())
} else if ctyp == valueTypeMap {
containerLenS = d.mapStart(d.d.ReadMapStart()) * 2
} else {
halt.errorStr2("decoding into a slice, expect map/array - got ", ctyp.String())
}
if containerLenS == 0 {
if rvCanset {
if rvIsNil(rv) {
rvSetDirect(rv, rvSliceZeroCap(ti.rt))
} else {
rvSetSliceLen(rv, 0)
}
}
if isArray {
d.arrayEnd()
} else {
d.mapEnd()
}
return
}
rtelem0Mut := !scalarBitset.isset(ti.elemkind)
rtelem := ti.elem
for k := reflect.Kind(ti.elemkind); k == reflect.Ptr; k = rtelem.Kind() {
rtelem = rtelem.Elem()
}
var fn *decFnSimpleIO
var rvChanged bool
var rv0 = rv
var rv9 reflect.Value
rvlen := rvLenSlice(rv)
rvcap := rvCapSlice(rv)
maxInitLen := d.maxInitLen()
hasLen := containerLenS >= 0
if hasLen {
if containerLenS > rvcap {
oldRvlenGtZero := rvlen > 0
rvlen1 := int(decInferLen(containerLenS, maxInitLen, uint(ti.elemsize)))
if rvlen1 == rvlen {
} else if rvlen1 <= rvcap {
if rvCanset {
rvlen = rvlen1
rvSetSliceLen(rv, rvlen)
}
} else if rvCanset {
rvlen = rvlen1
rv, rvCanset = rvMakeSlice(rv, f.ti, rvlen, rvlen)
rvcap = rvlen
rvChanged = !rvCanset
} else {
halt.errorStr("cannot decode into non-settable slice")
}
if rvChanged && oldRvlenGtZero && rtelem0Mut {
rvCopySlice(rv, rv0, rtelem)
}
} else if containerLenS != rvlen {
if rvCanset {
rvlen = containerLenS
rvSetSliceLen(rv, rvlen)
}
}
}
var elemReset = d.h.SliceElementReset
var rtelemIsPtr bool
var rtelemElem reflect.Type
builtin := ti.tielem.flagDecBuiltin
if builtin {
rtelemIsPtr = ti.elemkind == uint8(reflect.Ptr)
if rtelemIsPtr {
rtelemElem = ti.elem.Elem()
}
}
var j int
for ; d.containerNext(j, containerLenS, hasLen); j++ {
if j == 0 {
if rvIsNil(rv) {
if rvCanset {
rvlen = int(decInferLen(containerLenS, maxInitLen, uint(ti.elemsize)))
rv, rvCanset = rvMakeSlice(rv, f.ti, rvlen, rvlen)
rvcap = rvlen
rvChanged = !rvCanset
} else {
halt.errorStr("cannot decode into non-settable slice")
}
}
if fn == nil {
fn = d.fn(rtelem)
}
}
if ctyp == valueTypeArray {
d.arrayElem(j == 0)
} else if j&1 == 0 {
d.mapElemKey(j == 0)
} else {
d.mapElemValue()
}
if j >= rvlen {
if rvlen < rvcap {
rvlen = rvcap
if rvCanset {
rvSetSliceLen(rv, rvlen)
} else if rvChanged {
rv = rvSlice(rv, rvlen)
} else {
halt.onerror(errExpandSliceCannotChange)
}
} else {
if !(rvCanset || rvChanged) {
halt.onerror(errExpandSliceCannotChange)
}
rv, rvcap, rvCanset = rvGrowSlice(rv, f.ti, rvcap, 1)
rvlen = rvcap
rvChanged = !rvCanset
}
}
rv9 = rvArrayIndex(rv, j, f.ti, true)
if elemReset {
rvSetZero(rv9)
}
if d.d.TryNil() {
rvSetZero(rv9)
} else if builtin {
if rtelemIsPtr {
if rvIsNil(rv9) {
rvSetDirect(rv9, reflect.New(rtelemElem))
}
d.decode(rv2i(rv9))
} else {
d.decode(rv2i(rvAddr(rv9, ti.tielem.ptr)))
}
} else {
d.decodeValueNoCheckNil(rv9, fn)
}
}
if j < rvlen {
if rvCanset {
rvSetSliceLen(rv, j)
} else if rvChanged {
rv = rvSlice(rv, j)
}
} else if j == 0 && rvIsNil(rv) {
if rvCanset {
rv = rvSliceZeroCap(ti.rt)
rvCanset = false
rvChanged = true
}
}
if isArray {
d.arrayEnd()
} else {
d.mapEnd()
}
if rvChanged {
rvSetDirect(rv0, rv)
}
}
func (d *decoderSimpleIO) kArray(f *decFnInfo, rv reflect.Value) {
_ = d.d
ti := f.ti
ctyp := d.d.ContainerType()
if handleBytesWithinKArray && (ctyp == valueTypeBytes || ctyp == valueTypeString) {
if ti.elemkind != uint8(reflect.Uint8) {
halt.errorf("bytes/string in stream can decode into array of bytes, but not %v", ti.rt)
}
rvbs := rvGetArrayBytes(rv, nil)
d.decodeBytesInto(rvbs, true)
return
}
var containerLenS int
isArray := ctyp == valueTypeArray
if isArray {
containerLenS = d.arrayStart(d.d.ReadArrayStart())
} else if ctyp == valueTypeMap {
containerLenS = d.mapStart(d.d.ReadMapStart()) * 2
} else {
halt.errorStr2("decoding into a slice, expect map/array - got ", ctyp.String())
}
if containerLenS == 0 {
if isArray {
d.arrayEnd()
} else {
d.mapEnd()
}
return
}
rtelem := ti.elem
for k := reflect.Kind(ti.elemkind); k == reflect.Ptr; k = rtelem.Kind() {
rtelem = rtelem.Elem()
}
var rv9 reflect.Value
rvlen := rv.Len()
hasLen := containerLenS >= 0
if hasLen && containerLenS > rvlen {
halt.errorf("cannot decode into array with length: %v, less than container length: %v", any(rvlen), any(containerLenS))
}
var elemReset = d.h.SliceElementReset
var rtelemIsPtr bool
var rtelemElem reflect.Type
var fn *decFnSimpleIO
builtin := ti.tielem.flagDecBuiltin
if builtin {
rtelemIsPtr = ti.elemkind == uint8(reflect.Ptr)
if rtelemIsPtr {
rtelemElem = ti.elem.Elem()
}
} else {
fn = d.fn(rtelem)
}
for j := 0; d.containerNext(j, containerLenS, hasLen); j++ {
if ctyp == valueTypeArray {
d.arrayElem(j == 0)
} else if j&1 == 0 {
d.mapElemKey(j == 0)
} else {
d.mapElemValue()
}
if j >= rvlen {
d.arrayCannotExpand(rvlen, j+1)
d.swallow()
continue
}
rv9 = rvArrayIndex(rv, j, f.ti, false)
if elemReset {
rvSetZero(rv9)
}
if d.d.TryNil() {
rvSetZero(rv9)
} else if builtin {
if rtelemIsPtr {
if rvIsNil(rv9) {
rvSetDirect(rv9, reflect.New(rtelemElem))
}
d.decode(rv2i(rv9))
} else {
d.decode(rv2i(rvAddr(rv9, ti.tielem.ptr)))
}
} else {
d.decodeValueNoCheckNil(rv9, fn)
}
}
if isArray {
d.arrayEnd()
} else {
d.mapEnd()
}
}
func (d *decoderSimpleIO) kChan(f *decFnInfo, rv reflect.Value) {
_ = d.d
ti := f.ti
if ti.chandir&uint8(reflect.SendDir) == 0 {
halt.errorStr("receive-only channel cannot be decoded")
}
ctyp := d.d.ContainerType()
if ctyp == valueTypeBytes || ctyp == valueTypeString {
if !(ti.rtid == uint8SliceTypId || ti.elemkind == uint8(reflect.Uint8)) {
halt.errorf("bytes/string in stream must decode into slice/array of bytes, not %v", ti.rt)
}
bs2, _ := d.d.DecodeBytes()
irv := rv2i(rv)
ch, ok := irv.(chan<- byte)
if !ok {
ch = irv.(chan byte)
}
for _, b := range bs2 {
ch <- b
}
return
}
var rvCanset = rv.CanSet()
var containerLenS int
isArray := ctyp == valueTypeArray
if isArray {
containerLenS = d.arrayStart(d.d.ReadArrayStart())
} else if ctyp == valueTypeMap {
containerLenS = d.mapStart(d.d.ReadMapStart()) * 2
} else {
halt.errorStr2("decoding into a slice, expect map/array - got ", ctyp.String())
}
if containerLenS == 0 {
if rvCanset && rvIsNil(rv) {
rvSetDirect(rv, reflect.MakeChan(ti.rt, 0))
}
if isArray {
d.arrayEnd()
} else {
d.mapEnd()
}
return
}
rtelem := ti.elem
useTransient := decUseTransient && ti.elemkind != byte(reflect.Ptr) && ti.tielem.flagCanTransient
for k := reflect.Kind(ti.elemkind); k == reflect.Ptr; k = rtelem.Kind() {
rtelem = rtelem.Elem()
}
var fn *decFnSimpleIO
var rvChanged bool
var rv0 = rv
var rv9 reflect.Value
var rvlen int
hasLen := containerLenS >= 0
maxInitLen := d.maxInitLen()
for j := 0; d.containerNext(j, containerLenS, hasLen); j++ {
if j == 0 {
if rvIsNil(rv) {
if hasLen {
rvlen = int(decInferLen(containerLenS, maxInitLen, uint(ti.elemsize)))
} else {
rvlen = decDefChanCap
}
if rvCanset {
rv = reflect.MakeChan(ti.rt, rvlen)
rvChanged = true
} else {
halt.errorStr("cannot decode into non-settable chan")
}
}
if fn == nil {
fn = d.fn(rtelem)
}
}
if ctyp == valueTypeArray {
d.arrayElem(j == 0)
} else if j&1 == 0 {
d.mapElemKey(j == 0)
} else {
d.mapElemValue()
}
if rv9.IsValid() {
rvSetZero(rv9)
} else if useTransient {
rv9 = d.perType.TransientAddrK(ti.elem, reflect.Kind(ti.elemkind))
} else {
rv9 = rvZeroAddrK(ti.elem, reflect.Kind(ti.elemkind))
}
if !d.d.TryNil() {
d.decodeValueNoCheckNil(rv9, fn)
}
rv.Send(rv9)
}
if isArray {
d.arrayEnd()
} else {
d.mapEnd()
}
if rvChanged {
rvSetDirect(rv0, rv)
}
}
func (d *decoderSimpleIO) kMap(f *decFnInfo, rv reflect.Value) {
_ = d.d
containerLen := d.mapStart(d.d.ReadMapStart())
ti := f.ti
if rvIsNil(rv) {
rvlen := int(decInferLen(containerLen, d.maxInitLen(), uint(ti.keysize+ti.elemsize)))
rvSetDirect(rv, makeMapReflect(ti.rt, rvlen))
}
if containerLen == 0 {
d.mapEnd()
return
}
ktype, vtype := ti.key, ti.elem
ktypeId := rt2id(ktype)
vtypeKind := reflect.Kind(ti.elemkind)
ktypeKind := reflect.Kind(ti.keykind)
mparams := getMapReqParams(ti)
vtypePtr := vtypeKind == reflect.Ptr
ktypePtr := ktypeKind == reflect.Ptr
vTransient := decUseTransient && !vtypePtr && ti.tielem.flagCanTransient
kTransient := vTransient && !ktypePtr && ti.tikey.flagCanTransient
var vtypeElem reflect.Type
var keyFn, valFn *decFnSimpleIO
var ktypeLo, vtypeLo = ktype, vtype
if ktypeKind == reflect.Ptr {
for ktypeLo = ktype.Elem(); ktypeLo.Kind() == reflect.Ptr; ktypeLo = ktypeLo.Elem() {
}
}
if vtypePtr {
vtypeElem = vtype.Elem()
for vtypeLo = vtypeElem; vtypeLo.Kind() == reflect.Ptr; vtypeLo = vtypeLo.Elem() {
}
}
rvkMut := !scalarBitset.isset(ti.keykind)
rvvMut := !scalarBitset.isset(ti.elemkind)
rvvCanNil := isnilBitset.isset(ti.elemkind)
var rvk, rvkn, rvv, rvvn, rvva, rvvz reflect.Value
var doMapGet, doMapSet bool
if !d.h.MapValueReset {
if rvvMut && (vtypeKind != reflect.Interface || !d.h.InterfaceReset) {
doMapGet = true
rvva = mapAddrLoopvarRV(vtype, vtypeKind)
}
}
ktypeIsString := ktypeId == stringTypId
ktypeIsIntf := ktypeId == intfTypId
hasLen := containerLen >= 0
var kstr2bs []byte
var kstr string
var mapKeyStringSharesBytesBuf bool
var att dBytesAttachState
var vElem, kElem reflect.Type
kbuiltin := ti.tikey.flagDecBuiltin && ti.keykind != uint8(reflect.Slice)
vbuiltin := ti.tielem.flagDecBuiltin
if kbuiltin && ktypePtr {
kElem = ti.key.Elem()
}
if vbuiltin && vtypePtr {
vElem = ti.elem.Elem()
}
for j := 0; d.containerNext(j, containerLen, hasLen); j++ {
mapKeyStringSharesBytesBuf = false
kstr = ""
if j == 0 {
if kTransient {
rvk = d.perType.TransientAddr2K(ktype, ktypeKind)
} else {
rvk = rvZeroAddrK(ktype, ktypeKind)
}
if !rvkMut {
rvkn = rvk
}
if !rvvMut {
if vTransient {
rvvn = d.perType.TransientAddrK(vtype, vtypeKind)
} else {
rvvn = rvZeroAddrK(vtype, vtypeKind)
}
}
if !ktypeIsString && keyFn == nil {
keyFn = d.fn(ktypeLo)
}
if valFn == nil {
valFn = d.fn(vtypeLo)
}
} else if rvkMut {
rvSetZero(rvk)
} else {
rvk = rvkn
}
d.mapElemKey(j == 0)
if d.d.TryNil() {
rvSetZero(rvk)
} else if ktypeIsString {
kstr2bs, att = d.d.DecodeStringAsBytes()
kstr, mapKeyStringSharesBytesBuf = d.bytes2Str(kstr2bs, att)
rvSetString(rvk, kstr)
} else {
if kbuiltin {
if ktypePtr {
if rvIsNil(rvk) {
rvSetDirect(rvk, reflect.New(kElem))
}
d.decode(rv2i(rvk))
} else {
d.decode(rv2i(rvAddr(rvk, ti.tikey.ptr)))
}
} else {
d.decodeValueNoCheckNil(rvk, keyFn)
}
if ktypeIsIntf {
if rvk2 := rvk.Elem(); rvk2.IsValid() && rvk2.Type() == uint8SliceTyp {
kstr2bs = rvGetBytes(rvk2)
kstr, mapKeyStringSharesBytesBuf = d.bytes2Str(kstr2bs, dBytesAttachView)
rvSetIntf(rvk, rv4istr(kstr))
}
}
}
if mapKeyStringSharesBytesBuf && d.bufio {
if ktypeIsString {
rvSetString(rvk, d.detach2Str(kstr2bs, att))
} else {
rvSetIntf(rvk, rv4istr(d.detach2Str(kstr2bs, att)))
}
mapKeyStringSharesBytesBuf = false
}
d.mapElemValue()
if d.d.TryNil() {
if mapKeyStringSharesBytesBuf {
if ktypeIsString {
rvSetString(rvk, d.detach2Str(kstr2bs, att))
} else {
rvSetIntf(rvk, rv4istr(d.detach2Str(kstr2bs, att)))
}
}
if !rvvz.IsValid() {
rvvz = rvZeroK(vtype, vtypeKind)
}
mapSet(rv, rvk, rvvz, mparams)
continue
}
doMapSet = true
if !rvvMut {
rvv = rvvn
} else if !doMapGet {
goto NEW_RVV
} else {
rvv = mapGet(rv, rvk, rvva, mparams)
if !rvv.IsValid() || (rvvCanNil && rvIsNil(rvv)) {
goto NEW_RVV
}
switch vtypeKind {
case reflect.Ptr, reflect.Map:
doMapSet = false
case reflect.Interface:
rvvn = rvv.Elem()
if k := rvvn.Kind(); (k == reflect.Ptr || k == reflect.Map) && !rvIsNil(rvvn) {
d.decodeValueNoCheckNil(rvvn, nil)
continue
}
rvvn = rvZeroAddrK(vtype, vtypeKind)
rvSetIntf(rvvn, rvv)
rvv = rvvn
default:
if vTransient {
rvvn = d.perType.TransientAddrK(vtype, vtypeKind)
} else {
rvvn = rvZeroAddrK(vtype, vtypeKind)
}
rvSetDirect(rvvn, rvv)
rvv = rvvn
}
}
goto DECODE_VALUE_NO_CHECK_NIL
NEW_RVV:
if vtypePtr {
rvv = reflect.New(vtypeElem)
} else if vTransient {
rvv = d.perType.TransientAddrK(vtype, vtypeKind)
} else {
rvv = rvZeroAddrK(vtype, vtypeKind)
}
DECODE_VALUE_NO_CHECK_NIL:
if doMapSet && mapKeyStringSharesBytesBuf {
if ktypeIsString {
rvSetString(rvk, d.detach2Str(kstr2bs, att))
} else {
rvSetIntf(rvk, rv4istr(d.detach2Str(kstr2bs, att)))
}
}
if vbuiltin {
if vtypePtr {
if rvIsNil(rvv) {
rvSetDirect(rvv, reflect.New(vElem))
}
d.decode(rv2i(rvv))
} else {
d.decode(rv2i(rvAddr(rvv, ti.tielem.ptr)))
}
} else {
d.decodeValueNoCheckNil(rvv, valFn)
}
if doMapSet {
mapSet(rv, rvk, rvv, mparams)
}
}
d.mapEnd()
}
func (d *decoderSimpleIO) init(h Handle) {
initHandle(h)
callMake(&d.d)
d.hh = h
d.h = h.getBasicHandle()
d.err = errDecoderNotInitialized
if d.h.InternString && d.is == nil {
d.is.init()
}
d.fp = d.d.init(h, &d.decoderBase, d).(*fastpathDsSimpleIO)
if d.bytes {
d.rtidFn = &d.h.rtidFnsDecBytes
d.rtidFnNoExt = &d.h.rtidFnsDecNoExtBytes
} else {
d.bufio = d.h.ReaderBufferSize > 0
d.rtidFn = &d.h.rtidFnsDecIO
d.rtidFnNoExt = &d.h.rtidFnsDecNoExtIO
}
d.reset()
}
func (d *decoderSimpleIO) reset() {
d.d.reset()
d.err = nil
d.c = 0
d.depth = 0
d.calls = 0
d.maxdepth = decDefMaxDepth
if d.h.MaxDepth > 0 {
d.maxdepth = d.h.MaxDepth
}
d.mtid = 0
d.stid = 0
d.mtr = false
d.str = false
if d.h.MapType != nil {
d.mtid = rt2id(d.h.MapType)
_, d.mtr = fastpathAvIndex(d.mtid)
}
if d.h.SliceType != nil {
d.stid = rt2id(d.h.SliceType)
_, d.str = fastpathAvIndex(d.stid)
}
}
func (d *decoderSimpleIO) Reset(r io.Reader) {
if d.bytes {
halt.onerror(errDecNoResetBytesWithReader)
}
d.reset()
if r == nil {
r = &eofReader
}
d.d.resetInIO(r)
}
func (d *decoderSimpleIO) ResetBytes(in []byte) {
if !d.bytes {
halt.onerror(errDecNoResetReaderWithBytes)
}
d.resetBytes(in)
}
func (d *decoderSimpleIO) resetBytes(in []byte) {
d.reset()
if in == nil {
in = zeroByteSlice
}
d.d.resetInBytes(in)
}
func (d *decoderSimpleIO) ResetString(s string) {
d.ResetBytes(bytesView(s))
}
func (d *decoderSimpleIO) Decode(v interface{}) (err error) {
defer panicValToErr(d, callRecoverSentinel, &d.err, &err, debugging)
d.mustDecode(v)
return
}
func (d *decoderSimpleIO) MustDecode(v interface{}) {
defer panicValToErr(d, callRecoverSentinel, &d.err, nil, true)
d.mustDecode(v)
return
}
func (d *decoderSimpleIO) mustDecode(v interface{}) {
halt.onerror(d.err)
if d.hh == nil {
halt.onerror(errNoFormatHandle)
}
d.calls++
d.decode(v)
d.calls--
}
func (d *decoderSimpleIO) Release() {}
func (d *decoderSimpleIO) swallow() {
d.d.nextValueBytes()
}
func (d *decoderSimpleIO) nextValueBytes() []byte {
return d.d.nextValueBytes()
}
func (d *decoderSimpleIO) decode(iv interface{}) {
_ = d.d
rv, ok := isNil(iv, true)
if ok {
halt.onerror(errCannotDecodeIntoNil)
}
switch v := iv.(type) {
case *string:
*v = d.detach2Str(d.d.DecodeStringAsBytes())
case *bool:
*v = d.d.DecodeBool()
case *int:
*v = int(chkOvf.IntV(d.d.DecodeInt64(), intBitsize))
case *int8:
*v = int8(chkOvf.IntV(d.d.DecodeInt64(), 8))
case *int16:
*v = int16(chkOvf.IntV(d.d.DecodeInt64(), 16))
case *int32:
*v = int32(chkOvf.IntV(d.d.DecodeInt64(), 32))
case *int64:
*v = d.d.DecodeInt64()
case *uint:
*v = uint(chkOvf.UintV(d.d.DecodeUint64(), uintBitsize))
case *uint8:
*v = uint8(chkOvf.UintV(d.d.DecodeUint64(), 8))
case *uint16:
*v = uint16(chkOvf.UintV(d.d.DecodeUint64(), 16))
case *uint32:
*v = uint32(chkOvf.UintV(d.d.DecodeUint64(), 32))
case *uint64:
*v = d.d.DecodeUint64()
case *uintptr:
*v = uintptr(chkOvf.UintV(d.d.DecodeUint64(), uintBitsize))
case *float32:
*v = d.d.DecodeFloat32()
case *float64:
*v = d.d.DecodeFloat64()
case *complex64:
*v = complex(d.d.DecodeFloat32(), 0)
case *complex128:
*v = complex(d.d.DecodeFloat64(), 0)
case *[]byte:
*v, _ = d.decodeBytesInto(*v, false)
case []byte:
d.decodeBytesInto(v[:len(v):len(v)], true)
case *time.Time:
*v = d.d.DecodeTime()
case *Raw:
*v = d.rawBytes()
case *interface{}:
d.decodeValue(rv4iptr(v), nil)
case reflect.Value:
if ok, _ = isDecodeable(v); !ok {
d.haltAsNotDecodeable(v)
}
d.decodeValue(v, nil)
default:
if skipFastpathTypeSwitchInDirectCall || !d.dh.fastpathDecodeTypeSwitch(iv, d) {
if !rv.IsValid() {
rv = reflect.ValueOf(iv)
}
if ok, _ = isDecodeable(rv); !ok {
d.haltAsNotDecodeable(rv)
}
d.decodeValue(rv, nil)
}
}
}
func (d *decoderSimpleIO) decodeValue(rv reflect.Value, fn *decFnSimpleIO) {
if d.d.TryNil() {
decSetNonNilRV2Zero(rv)
} else {
d.decodeValueNoCheckNil(rv, fn)
}
}
func (d *decoderSimpleIO) decodeValueNoCheckNil(rv reflect.Value, fn *decFnSimpleIO) {
var rvp reflect.Value
var rvpValid bool
PTR:
if rv.Kind() == reflect.Ptr {
rvpValid = true
if rvIsNil(rv) {
rvSetDirect(rv, reflect.New(rv.Type().Elem()))
}
rvp = rv
rv = rv.Elem()
goto PTR
}
if fn == nil {
fn = d.fn(rv.Type())
}
if fn.i.addrD {
if rvpValid {
rv = rvp
} else if rv.CanAddr() {
rv = rvAddr(rv, fn.i.ti.ptr)
} else if fn.i.addrDf {
halt.errorStr("cannot decode into a non-pointer value")
}
}
fn.fd(d, &fn.i, rv)
}
func (d *decoderSimpleIO) decodeAs(v interface{}, t reflect.Type, ext bool) {
if ext {
d.decodeValue(baseRV(v), d.fn(t))
} else {
d.decodeValue(baseRV(v), d.fnNoExt(t))
}
}
func (d *decoderSimpleIO) structFieldNotFound(index int, rvkencname string) {
if d.h.ErrorIfNoField {
if index >= 0 {
halt.errorInt("no matching struct field found when decoding stream array at index ", int64(index))
} else if rvkencname != "" {
halt.errorStr2("no matching struct field found when decoding stream map with key ", rvkencname)
}
}
d.swallow()
}
func (d *decoderSimpleIO) decodeBytesInto(out []byte, mustFit bool) (v []byte, state dBytesIntoState) {
v, att := d.d.DecodeBytes()
if cap(v) == 0 || (att >= dBytesAttachViewZerocopy && !mustFit) {
return
}
if len(v) == 0 {
v = zeroByteSlice
return
}
if len(out) == len(v) {
state = dBytesIntoParamOut
} else if cap(out) >= len(v) {
out = out[:len(v)]
state = dBytesIntoParamOutSlice
} else if mustFit {
halt.errorf("bytes capacity insufficient for decoded bytes: got/expected: %d/%d", len(v), len(out))
} else {
out = make([]byte, len(v))
state = dBytesIntoNew
}
copy(out, v)
v = out
return
}
func (d *decoderSimpleIO) rawBytes() (v []byte) {
v = d.d.nextValueBytes()
if d.bytes && !d.h.ZeroCopy {
vv := make([]byte, len(v))
copy(vv, v)
v = vv
}
return
}
func (d *decoderSimpleIO) wrapErr(v error, err *error) {
*err = wrapCodecErr(v, d.hh.Name(), d.d.NumBytesRead(), false)
}
func (d *decoderSimpleIO) NumBytesRead() int {
return d.d.NumBytesRead()
}
func (d *decoderSimpleIO) containerNext(j, containerLen int, hasLen bool) bool {
if hasLen {
return j < containerLen
}
return !d.d.CheckBreak()
}
func (d *decoderSimpleIO) mapElemKey(firstTime bool) {
d.d.ReadMapElemKey(firstTime)
d.c = containerMapKey
}
func (d *decoderSimpleIO) mapElemValue() {
d.d.ReadMapElemValue()
d.c = containerMapValue
}
func (d *decoderSimpleIO) mapEnd() {
d.d.ReadMapEnd()
d.depthDecr()
d.c = 0
}
func (d *decoderSimpleIO) arrayElem(firstTime bool) {
d.d.ReadArrayElem(firstTime)
d.c = containerArrayElem
}
func (d *decoderSimpleIO) arrayEnd() {
d.d.ReadArrayEnd()
d.depthDecr()
d.c = 0
}
func (d *decoderSimpleIO) interfaceExtConvertAndDecode(v interface{}, ext InterfaceExt) {
var vv interface{}
d.decode(&vv)
ext.UpdateExt(v, vv)
}
func (d *decoderSimpleIO) fn(t reflect.Type) *decFnSimpleIO {
return d.dh.decFnViaBH(t, d.rtidFn, d.h, d.fp, false)
}
func (d *decoderSimpleIO) fnNoExt(t reflect.Type) *decFnSimpleIO {
return d.dh.decFnViaBH(t, d.rtidFnNoExt, d.h, d.fp, true)
}
func (helperDecDriverSimpleIO) newDecoderBytes(in []byte, h Handle) *decoderSimpleIO {
var c1 decoderSimpleIO
c1.bytes = true
c1.init(h)
c1.ResetBytes(in)
return &c1
}
func (helperDecDriverSimpleIO) newDecoderIO(in io.Reader, h Handle) *decoderSimpleIO {
var c1 decoderSimpleIO
c1.init(h)
c1.Reset(in)
return &c1
}
func (helperDecDriverSimpleIO) decFnloadFastpathUnderlying(ti *typeInfo, fp *fastpathDsSimpleIO) (f *fastpathDSimpleIO, u reflect.Type) {
rtid := rt2id(ti.fastpathUnderlying)
idx, ok := fastpathAvIndex(rtid)
if !ok {
return
}
f = &fp[idx]
if uint8(reflect.Array) == ti.kind {
u = reflect.ArrayOf(ti.rt.Len(), ti.elem)
} else {
u = f.rt
}
return
}
func (helperDecDriverSimpleIO) decFindRtidFn(s []decRtidFnSimpleIO, rtid uintptr) (i uint, fn *decFnSimpleIO) {
var h uint
var j = uint(len(s))
LOOP:
if i < j {
h = (i + j) >> 1
if s[h].rtid < rtid {
i = h + 1
} else {
j = h
}
goto LOOP
}
if i < uint(len(s)) && s[i].rtid == rtid {
fn = s[i].fn
}
return
}
func (helperDecDriverSimpleIO) decFromRtidFnSlice(fns *atomicRtidFnSlice) (s []decRtidFnSimpleIO) {
if v := fns.load(); v != nil {
s = *(lowLevelToPtr[[]decRtidFnSimpleIO](v))
}
return
}
func (dh helperDecDriverSimpleIO) decFnViaBH(rt reflect.Type, fns *atomicRtidFnSlice, x *BasicHandle, fp *fastpathDsSimpleIO,
checkExt bool) (fn *decFnSimpleIO) {
return dh.decFnVia(rt, fns, x.typeInfos(), &x.mu, x.extHandle, fp,
checkExt, x.CheckCircularRef, x.timeBuiltin, x.binaryHandle, x.jsonHandle)
}
func (dh helperDecDriverSimpleIO) decFnVia(rt reflect.Type, fns *atomicRtidFnSlice,
tinfos *TypeInfos, mu *sync.Mutex, exth extHandle, fp *fastpathDsSimpleIO,
checkExt, checkCircularRef, timeBuiltin, binaryEncoding, json bool) (fn *decFnSimpleIO) {
rtid := rt2id(rt)
var sp []decRtidFnSimpleIO = dh.decFromRtidFnSlice(fns)
if sp != nil {
_, fn = dh.decFindRtidFn(sp, rtid)
}
if fn == nil {
fn = dh.decFnViaLoader(rt, rtid, fns, tinfos, mu, exth, fp, checkExt, checkCircularRef, timeBuiltin, binaryEncoding, json)
}
return
}
func (dh helperDecDriverSimpleIO) decFnViaLoader(rt reflect.Type, rtid uintptr, fns *atomicRtidFnSlice,
tinfos *TypeInfos, mu *sync.Mutex, exth extHandle, fp *fastpathDsSimpleIO,
checkExt, checkCircularRef, timeBuiltin, binaryEncoding, json bool) (fn *decFnSimpleIO) {
fn = dh.decFnLoad(rt, rtid, tinfos, exth, fp, checkExt, checkCircularRef, timeBuiltin, binaryEncoding, json)
var sp []decRtidFnSimpleIO
mu.Lock()
sp = dh.decFromRtidFnSlice(fns)
if sp == nil {
sp = []decRtidFnSimpleIO{{rtid, fn}}
fns.store(ptrToLowLevel(&sp))
} else {
idx, fn2 := dh.decFindRtidFn(sp, rtid)
if fn2 == nil {
sp2 := make([]decRtidFnSimpleIO, len(sp)+1)
copy(sp2[idx+1:], sp[idx:])
copy(sp2, sp[:idx])
sp2[idx] = decRtidFnSimpleIO{rtid, fn}
fns.store(ptrToLowLevel(&sp2))
}
}
mu.Unlock()
return
}
func (dh helperDecDriverSimpleIO) decFnLoad(rt reflect.Type, rtid uintptr, tinfos *TypeInfos,
exth extHandle, fp *fastpathDsSimpleIO,
checkExt, checkCircularRef, timeBuiltin, binaryEncoding, json bool) (fn *decFnSimpleIO) {
fn = new(decFnSimpleIO)
fi := &(fn.i)
ti := tinfos.get(rtid, rt)
fi.ti = ti
rk := reflect.Kind(ti.kind)
fi.addrDf = true
if rtid == timeTypId && timeBuiltin {
fn.fd = (*decoderSimpleIO).kTime
} else if rtid == rawTypId {
fn.fd = (*decoderSimpleIO).raw
} else if rtid == rawExtTypId {
fn.fd = (*decoderSimpleIO).rawExt
fi.addrD = true
} else if xfFn := exth.getExt(rtid, checkExt); xfFn != nil {
fi.xfTag, fi.xfFn = xfFn.tag, xfFn.ext
fn.fd = (*decoderSimpleIO).ext
fi.addrD = true
} else if ti.flagSelfer || ti.flagSelferPtr {
fn.fd = (*decoderSimpleIO).selferUnmarshal
fi.addrD = ti.flagSelferPtr
} else if supportMarshalInterfaces && binaryEncoding &&
(ti.flagBinaryMarshaler || ti.flagBinaryMarshalerPtr) &&
(ti.flagBinaryUnmarshaler || ti.flagBinaryUnmarshalerPtr) {
fn.fd = (*decoderSimpleIO).binaryUnmarshal
fi.addrD = ti.flagBinaryUnmarshalerPtr
} else if supportMarshalInterfaces && !binaryEncoding && json &&
(ti.flagJsonMarshaler || ti.flagJsonMarshalerPtr) &&
(ti.flagJsonUnmarshaler || ti.flagJsonUnmarshalerPtr) {
fn.fd = (*decoderSimpleIO).jsonUnmarshal
fi.addrD = ti.flagJsonUnmarshalerPtr
} else if supportMarshalInterfaces && !binaryEncoding &&
(ti.flagTextMarshaler || ti.flagTextMarshalerPtr) &&
(ti.flagTextUnmarshaler || ti.flagTextUnmarshalerPtr) {
fn.fd = (*decoderSimpleIO).textUnmarshal
fi.addrD = ti.flagTextUnmarshalerPtr
} else {
if fastpathEnabled && (rk == reflect.Map || rk == reflect.Slice || rk == reflect.Array) {
var rtid2 uintptr
if !ti.flagHasPkgPath {
rtid2 = rtid
if rk == reflect.Array {
rtid2 = rt2id(ti.key)
}
if idx, ok := fastpathAvIndex(rtid2); ok {
fn.fd = fp[idx].decfn
fi.addrD = true
fi.addrDf = false
if rk == reflect.Array {
fi.addrD = false
}
}
} else {
xfe, xrt := dh.decFnloadFastpathUnderlying(ti, fp)
if xfe != nil {
xfnf2 := xfe.decfn
if rk == reflect.Array {
fi.addrD = false
fn.fd = func(d *decoderSimpleIO, xf *decFnInfo, xrv reflect.Value) {
xfnf2(d, xf, rvConvert(xrv, xrt))
}
} else {
fi.addrD = true
fi.addrDf = false
xptr2rt := reflect.PointerTo(xrt)
fn.fd = func(d *decoderSimpleIO, xf *decFnInfo, xrv reflect.Value) {
if xrv.Kind() == reflect.Ptr {
xfnf2(d, xf, rvConvert(xrv, xptr2rt))
} else {
xfnf2(d, xf, rvConvert(xrv, xrt))
}
}
}
}
}
}
if fn.fd == nil {
switch rk {
case reflect.Bool:
fn.fd = (*decoderSimpleIO).kBool
case reflect.String:
fn.fd = (*decoderSimpleIO).kString
case reflect.Int:
fn.fd = (*decoderSimpleIO).kInt
case reflect.Int8:
fn.fd = (*decoderSimpleIO).kInt8
case reflect.Int16:
fn.fd = (*decoderSimpleIO).kInt16
case reflect.Int32:
fn.fd = (*decoderSimpleIO).kInt32
case reflect.Int64:
fn.fd = (*decoderSimpleIO).kInt64
case reflect.Uint:
fn.fd = (*decoderSimpleIO).kUint
case reflect.Uint8:
fn.fd = (*decoderSimpleIO).kUint8
case reflect.Uint16:
fn.fd = (*decoderSimpleIO).kUint16
case reflect.Uint32:
fn.fd = (*decoderSimpleIO).kUint32
case reflect.Uint64:
fn.fd = (*decoderSimpleIO).kUint64
case reflect.Uintptr:
fn.fd = (*decoderSimpleIO).kUintptr
case reflect.Float32:
fn.fd = (*decoderSimpleIO).kFloat32
case reflect.Float64:
fn.fd = (*decoderSimpleIO).kFloat64
case reflect.Complex64:
fn.fd = (*decoderSimpleIO).kComplex64
case reflect.Complex128:
fn.fd = (*decoderSimpleIO).kComplex128
case reflect.Chan:
fn.fd = (*decoderSimpleIO).kChan
case reflect.Slice:
fn.fd = (*decoderSimpleIO).kSlice
case reflect.Array:
fi.addrD = false
fn.fd = (*decoderSimpleIO).kArray
case reflect.Struct:
if ti.simple {
fn.fd = (*decoderSimpleIO).kStructSimple
} else {
fn.fd = (*decoderSimpleIO).kStruct
}
case reflect.Map:
fn.fd = (*decoderSimpleIO).kMap
case reflect.Interface:
fn.fd = (*decoderSimpleIO).kInterface
default:
fn.fd = (*decoderSimpleIO).kErr
}
}
}
return
}
func (e *simpleEncDriverIO) EncodeNil() {
e.w.writen1(simpleVdNil)
}
func (e *simpleEncDriverIO) EncodeBool(b bool) {
if e.h.EncZeroValuesAsNil && e.e.c != containerMapKey && !b {
e.EncodeNil()
return
}
if b {
e.w.writen1(simpleVdTrue)
} else {
e.w.writen1(simpleVdFalse)
}
}
func (e *simpleEncDriverIO) EncodeFloat32(f float32) {
if e.h.EncZeroValuesAsNil && e.e.c != containerMapKey && f == 0.0 {
e.EncodeNil()
return
}
e.w.writen1(simpleVdFloat32)
e.w.writen4(bigen.PutUint32(math.Float32bits(f)))
}
func (e *simpleEncDriverIO) EncodeFloat64(f float64) {
if e.h.EncZeroValuesAsNil && e.e.c != containerMapKey && f == 0.0 {
e.EncodeNil()
return
}
e.w.writen1(simpleVdFloat64)
e.w.writen8(bigen.PutUint64(math.Float64bits(f)))
}
func (e *simpleEncDriverIO) EncodeInt(v int64) {
if v < 0 {
e.encUint(uint64(-v), simpleVdNegInt)
} else {
e.encUint(uint64(v), simpleVdPosInt)
}
}
func (e *simpleEncDriverIO) EncodeUint(v uint64) {
e.encUint(v, simpleVdPosInt)
}
func (e *simpleEncDriverIO) encUint(v uint64, bd uint8) {
if e.h.EncZeroValuesAsNil && e.e.c != containerMapKey && v == 0 {
e.EncodeNil()
return
}
if v <= math.MaxUint8 {
e.w.writen2(bd, uint8(v))
} else if v <= math.MaxUint16 {
e.w.writen1(bd + 1)
e.w.writen2(bigen.PutUint16(uint16(v)))
} else if v <= math.MaxUint32 {
e.w.writen1(bd + 2)
e.w.writen4(bigen.PutUint32(uint32(v)))
} else {
e.w.writen1(bd + 3)
e.w.writen8(bigen.PutUint64(v))
}
}
func (e *simpleEncDriverIO) encLen(bd byte, length int) {
if length == 0 {
e.w.writen1(bd)
} else if length <= math.MaxUint8 {
e.w.writen1(bd + 1)
e.w.writen1(uint8(length))
} else if length <= math.MaxUint16 {
e.w.writen1(bd + 2)
e.w.writen2(bigen.PutUint16(uint16(length)))
} else if int64(length) <= math.MaxUint32 {
e.w.writen1(bd + 3)
e.w.writen4(bigen.PutUint32(uint32(length)))
} else {
e.w.writen1(bd + 4)
e.w.writen8(bigen.PutUint64(uint64(length)))
}
}
func (e *simpleEncDriverIO) EncodeExt(v interface{}, basetype reflect.Type, xtag uint64, ext Ext) {
var bs0, bs []byte
if ext == SelfExt {
bs0 = e.e.blist.get(1024)
bs = bs0
sideEncode(e.h, &e.h.sideEncPool, func(se encoderI) { oneOffEncode(se, v, &bs, basetype, true) })
} else {
bs = ext.WriteExt(v)
}
if bs == nil {
e.writeNilBytes()
goto END
}
e.encodeExtPreamble(uint8(xtag), len(bs))
e.w.writeb(bs)
END:
if ext == SelfExt {
e.e.blist.put(bs)
if !byteSliceSameData(bs0, bs) {
e.e.blist.put(bs0)
}
}
}
func (e *simpleEncDriverIO) EncodeRawExt(re *RawExt) {
e.encodeExtPreamble(uint8(re.Tag), len(re.Data))
e.w.writeb(re.Data)
}
func (e *simpleEncDriverIO) encodeExtPreamble(xtag byte, length int) {
e.encLen(simpleVdExt, length)
e.w.writen1(xtag)
}
func (e *simpleEncDriverIO) WriteArrayStart(length int) {
e.encLen(simpleVdArray, length)
}
func (e *simpleEncDriverIO) WriteMapStart(length int) {
e.encLen(simpleVdMap, length)
}
func (e *simpleEncDriverIO) WriteArrayEmpty() {
e.w.writen1(simpleVdArray)
}
func (e *simpleEncDriverIO) WriteMapEmpty() {
e.w.writen1(simpleVdMap)
}
func (e *simpleEncDriverIO) EncodeString(v string) {
if e.h.EncZeroValuesAsNil && e.e.c != containerMapKey && v == "" {
e.EncodeNil()
return
}
if e.h.StringToRaw {
e.encLen(simpleVdByteArray, len(v))
} else {
e.encLen(simpleVdString, len(v))
}
e.w.writestr(v)
}
func (e *simpleEncDriverIO) EncodeStringNoEscape4Json(v string) { e.EncodeString(v) }
func (e *simpleEncDriverIO) EncodeStringBytesRaw(v []byte) {
e.encLen(simpleVdByteArray, len(v))
e.w.writeb(v)
}
func (e *simpleEncDriverIO) EncodeBytes(v []byte) {
if v == nil {
e.writeNilBytes()
return
}
e.EncodeStringBytesRaw(v)
}
func (e *simpleEncDriverIO) encodeNilBytes() {
b := byte(simpleVdNil)
if e.h.NilCollectionToZeroLength {
b = simpleVdArray
}
e.w.writen1(b)
}
func (e *simpleEncDriverIO) writeNilOr(v byte) {
if !e.h.NilCollectionToZeroLength {
v = simpleVdNil
}
e.w.writen1(v)
}
func (e *simpleEncDriverIO) writeNilArray() {
e.writeNilOr(simpleVdArray)
}
func (e *simpleEncDriverIO) writeNilMap() {
e.writeNilOr(simpleVdMap)
}
func (e *simpleEncDriverIO) writeNilBytes() {
e.writeNilOr(simpleVdByteArray)
}
func (e *simpleEncDriverIO) EncodeTime(t time.Time) {
if t.IsZero() {
e.EncodeNil()
return
}
v, err := t.MarshalBinary()
halt.onerror(err)
e.w.writen2(simpleVdTime, uint8(len(v)))
e.w.writeb(v)
}
func (d *simpleDecDriverIO) readNextBd() {
d.bd = d.r.readn1()
d.bdRead = true
}
func (d *simpleDecDriverIO) advanceNil() (null bool) {
if !d.bdRead {
d.readNextBd()
}
if d.bd == simpleVdNil {
d.bdRead = false
return true
}
return
}
func (d *simpleDecDriverIO) ContainerType() (vt valueType) {
if !d.bdRead {
d.readNextBd()
}
switch d.bd {
case simpleVdNil:
d.bdRead = false
return valueTypeNil
case simpleVdByteArray, simpleVdByteArray + 1,
simpleVdByteArray + 2, simpleVdByteArray + 3, simpleVdByteArray + 4:
return valueTypeBytes
case simpleVdString, simpleVdString + 1,
simpleVdString + 2, simpleVdString + 3, simpleVdString + 4:
return valueTypeString
case simpleVdArray, simpleVdArray + 1,
simpleVdArray + 2, simpleVdArray + 3, simpleVdArray + 4:
return valueTypeArray
case simpleVdMap, simpleVdMap + 1,
simpleVdMap + 2, simpleVdMap + 3, simpleVdMap + 4:
return valueTypeMap
}
return valueTypeUnset
}
func (d *simpleDecDriverIO) TryNil() bool {
return d.advanceNil()
}
func (d *simpleDecDriverIO) decFloat() (f float64, ok bool) {
ok = true
switch d.bd {
case simpleVdFloat32:
f = float64(math.Float32frombits(bigen.Uint32(d.r.readn4())))
case simpleVdFloat64:
f = math.Float64frombits(bigen.Uint64(d.r.readn8()))
default:
ok = false
}
return
}
func (d *simpleDecDriverIO) decInteger() (ui uint64, neg, ok bool) {
ok = true
switch d.bd {
case simpleVdPosInt:
ui = uint64(d.r.readn1())
case simpleVdPosInt + 1:
ui = uint64(bigen.Uint16(d.r.readn2()))
case simpleVdPosInt + 2:
ui = uint64(bigen.Uint32(d.r.readn4()))
case simpleVdPosInt + 3:
ui = uint64(bigen.Uint64(d.r.readn8()))
case simpleVdNegInt:
ui = uint64(d.r.readn1())
neg = true
case simpleVdNegInt + 1:
ui = uint64(bigen.Uint16(d.r.readn2()))
neg = true
case simpleVdNegInt + 2:
ui = uint64(bigen.Uint32(d.r.readn4()))
neg = true
case simpleVdNegInt + 3:
ui = uint64(bigen.Uint64(d.r.readn8()))
neg = true
default:
ok = false
}
return
}
func (d *simpleDecDriverIO) DecodeInt64() (i int64) {
if d.advanceNil() {
return
}
v1, v2, v3 := d.decInteger()
i = decNegintPosintFloatNumberHelper{d}.int64(v1, v2, v3, false)
d.bdRead = false
return
}
func (d *simpleDecDriverIO) DecodeUint64() (ui uint64) {
if d.advanceNil() {
return
}
ui = decNegintPosintFloatNumberHelper{d}.uint64(d.decInteger())
d.bdRead = false
return
}
func (d *simpleDecDriverIO) DecodeFloat64() (f float64) {
if d.advanceNil() {
return
}
v1, v2 := d.decFloat()
f = decNegintPosintFloatNumberHelper{d}.float64(v1, v2, false)
d.bdRead = false
return
}
func (d *simpleDecDriverIO) DecodeBool() (b bool) {
if d.advanceNil() {
return
}
if d.bd == simpleVdFalse {
} else if d.bd == simpleVdTrue {
b = true
} else {
halt.errorf("cannot decode bool - %s: %x", msgBadDesc, d.bd)
}
d.bdRead = false
return
}
func (d *simpleDecDriverIO) ReadMapStart() (length int) {
if d.advanceNil() {
return containerLenNil
}
d.bdRead = false
return d.decLen()
}
func (d *simpleDecDriverIO) ReadArrayStart() (length int) {
if d.advanceNil() {
return containerLenNil
}
d.bdRead = false
return d.decLen()
}
func (d *simpleDecDriverIO) uint2Len(ui uint64) int {
if chkOvf.Uint(ui, intBitsize) {
halt.errorf("overflow integer: %v", ui)
}
return int(ui)
}
func (d *simpleDecDriverIO) decLen() int {
switch d.bd & 7 {
case 0:
return 0
case 1:
return int(d.r.readn1())
case 2:
return int(bigen.Uint16(d.r.readn2()))
case 3:
return d.uint2Len(uint64(bigen.Uint32(d.r.readn4())))
case 4:
return d.uint2Len(bigen.Uint64(d.r.readn8()))
}
halt.errorf("cannot read length: bd%%8 must be in range 0..4. Got: %d", d.bd%8)
return -1
}
func (d *simpleDecDriverIO) DecodeStringAsBytes() ([]byte, dBytesAttachState) {
return d.DecodeBytes()
}
func (d *simpleDecDriverIO) DecodeBytes() (bs []byte, state dBytesAttachState) {
if d.advanceNil() {
return
}
var cond bool
if d.bd >= simpleVdArray && d.bd <= simpleVdArray+4 {
slen := d.ReadArrayStart()
bs, cond = usableByteSlice(d.d.buf, slen)
for i := 0; i < len(bs); i++ {
bs[i] = uint8(chkOvf.UintV(d.DecodeUint64(), 8))
}
for i := len(bs); i < slen; i++ {
bs = append(bs, uint8(chkOvf.UintV(d.DecodeUint64(), 8)))
}
if cond {
d.d.buf = bs
}
state = dBytesAttachBuffer
return
}
clen := d.decLen()
d.bdRead = false
bs, cond = d.r.readxb(uint(clen))
state = d.d.attachState(cond)
return
}
func (d *simpleDecDriverIO) DecodeTime() (t time.Time) {
if d.advanceNil() {
return
}
if d.bd != simpleVdTime {
halt.errorf("invalid descriptor for time.Time - expect 0x%x, received 0x%x", simpleVdTime, d.bd)
}
d.bdRead = false
clen := uint(d.r.readn1())
b := d.r.readx(clen)
halt.onerror((&t).UnmarshalBinary(b))
return
}
func (d *simpleDecDriverIO) DecodeExt(rv interface{}, basetype reflect.Type, xtag uint64, ext Ext) {
xbs, _, _, ok := d.decodeExtV(ext != nil, xtag)
if !ok {
return
}
if ext == SelfExt {
sideDecode(d.h, &d.h.sideDecPool, func(sd decoderI) { oneOffDecode(sd, rv, xbs, basetype, true) })
} else {
ext.ReadExt(rv, xbs)
}
}
func (d *simpleDecDriverIO) DecodeRawExt(re *RawExt) {
xbs, realxtag, state, ok := d.decodeExtV(false, 0)
if !ok {
return
}
re.Tag = uint64(realxtag)
re.setData(xbs, state >= dBytesAttachViewZerocopy)
}
func (d *simpleDecDriverIO) decodeExtV(verifyTag bool, xtagIn uint64) (xbs []byte, xtag byte, bstate dBytesAttachState, ok bool) {
if xtagIn > 0xff {
halt.errorf("ext: tag must be <= 0xff; got: %v", xtagIn)
}
if d.advanceNil() {
return
}
tag := uint8(xtagIn)
switch d.bd {
case simpleVdExt, simpleVdExt + 1, simpleVdExt + 2, simpleVdExt + 3, simpleVdExt + 4:
l := d.decLen()
xtag = d.r.readn1()
if verifyTag && xtag != tag {
halt.errorf("wrong extension tag. Got %b. Expecting: %v", xtag, tag)
}
xbs, ok = d.r.readxb(uint(l))
bstate = d.d.attachState(ok)
case simpleVdByteArray, simpleVdByteArray + 1,
simpleVdByteArray + 2, simpleVdByteArray + 3, simpleVdByteArray + 4:
xbs, bstate = d.DecodeBytes()
default:
halt.errorf("ext - %s - expecting extensions/bytearray, got: 0x%x", msgBadDesc, d.bd)
}
d.bdRead = false
ok = true
return
}
func (d *simpleDecDriverIO) DecodeNaked() {
if !d.bdRead {
d.readNextBd()
}
n := d.d.naked()
var decodeFurther bool
switch d.bd {
case simpleVdNil:
n.v = valueTypeNil
case simpleVdFalse:
n.v = valueTypeBool
n.b = false
case simpleVdTrue:
n.v = valueTypeBool
n.b = true
case simpleVdPosInt, simpleVdPosInt + 1, simpleVdPosInt + 2, simpleVdPosInt + 3:
if d.h.SignedInteger {
n.v = valueTypeInt
n.i = d.DecodeInt64()
} else {
n.v = valueTypeUint
n.u = d.DecodeUint64()
}
case simpleVdNegInt, simpleVdNegInt + 1, simpleVdNegInt + 2, simpleVdNegInt + 3:
n.v = valueTypeInt
n.i = d.DecodeInt64()
case simpleVdFloat32:
n.v = valueTypeFloat
n.f = d.DecodeFloat64()
case simpleVdFloat64:
n.v = valueTypeFloat
n.f = d.DecodeFloat64()
case simpleVdTime:
n.v = valueTypeTime
n.t = d.DecodeTime()
case simpleVdString, simpleVdString + 1,
simpleVdString + 2, simpleVdString + 3, simpleVdString + 4:
n.v = valueTypeString
n.s = d.d.detach2Str(d.DecodeStringAsBytes())
case simpleVdByteArray, simpleVdByteArray + 1,
simpleVdByteArray + 2, simpleVdByteArray + 3, simpleVdByteArray + 4:
d.d.fauxUnionReadRawBytes(d, false, d.h.RawToString)
case simpleVdExt, simpleVdExt + 1, simpleVdExt + 2, simpleVdExt + 3, simpleVdExt + 4:
n.v = valueTypeExt
l := d.decLen()
n.u = uint64(d.r.readn1())
n.l = d.r.readx(uint(l))
case simpleVdArray, simpleVdArray + 1, simpleVdArray + 2,
simpleVdArray + 3, simpleVdArray + 4:
n.v = valueTypeArray
decodeFurther = true
case simpleVdMap, simpleVdMap + 1, simpleVdMap + 2, simpleVdMap + 3, simpleVdMap + 4:
n.v = valueTypeMap
decodeFurther = true
default:
halt.errorf("cannot infer value - %s 0x%x", msgBadDesc, d.bd)
}
if !decodeFurther {
d.bdRead = false
}
}
func (d *simpleDecDriverIO) nextValueBytes() (v []byte) {
if !d.bdRead {
d.readNextBd()
}
d.r.startRecording()
d.nextValueBytesBdReadR()
v = d.r.stopRecording()
d.bdRead = false
return
}
func (d *simpleDecDriverIO) nextValueBytesBdReadR() {
c := d.bd
var length uint
switch c {
case simpleVdNil, simpleVdFalse, simpleVdTrue, simpleVdString, simpleVdByteArray:
case simpleVdPosInt, simpleVdNegInt:
d.r.readn1()
case simpleVdPosInt + 1, simpleVdNegInt + 1:
d.r.skip(2)
case simpleVdPosInt + 2, simpleVdNegInt + 2, simpleVdFloat32:
d.r.skip(4)
case simpleVdPosInt + 3, simpleVdNegInt + 3, simpleVdFloat64:
d.r.skip(8)
case simpleVdTime:
c = d.r.readn1()
d.r.skip(uint(c))
default:
switch c & 7 {
case 0:
length = 0
case 1:
b := d.r.readn1()
length = uint(b)
case 2:
x := d.r.readn2()
length = uint(bigen.Uint16(x))
case 3:
x := d.r.readn4()
length = uint(bigen.Uint32(x))
case 4:
x := d.r.readn8()
length = uint(bigen.Uint64(x))
}
bExt := c >= simpleVdExt && c <= simpleVdExt+7
bStr := c >= simpleVdString && c <= simpleVdString+7
bByteArray := c >= simpleVdByteArray && c <= simpleVdByteArray+7
bArray := c >= simpleVdArray && c <= simpleVdArray+7
bMap := c >= simpleVdMap && c <= simpleVdMap+7
if !(bExt || bStr || bByteArray || bArray || bMap) {
halt.errorf("cannot infer value - %s 0x%x", msgBadDesc, c)
}
if bExt {
d.r.readn1()
}
if length == 0 {
break
}
if bArray {
for i := uint(0); i < length; i++ {
d.readNextBd()
d.nextValueBytesBdReadR()
}
} else if bMap {
for i := uint(0); i < length; i++ {
d.readNextBd()
d.nextValueBytesBdReadR()
d.readNextBd()
d.nextValueBytesBdReadR()
}
} else {
d.r.skip(length)
}
}
return
}
func (d *simpleEncDriverIO) init(hh Handle, shared *encoderBase, enc encoderI) (fp interface{}) {
callMake(&d.w)
d.h = hh.(*SimpleHandle)
d.e = shared
if shared.bytes {
fp = simpleFpEncBytes
} else {
fp = simpleFpEncIO
}
d.init2(enc)
return
}
func (e *simpleEncDriverIO) writeBytesAsis(b []byte) { e.w.writeb(b) }
func (e *simpleEncDriverIO) writerEnd() { e.w.end() }
func (e *simpleEncDriverIO) resetOutBytes(out *[]byte) {
e.w.resetBytes(*out, out)
}
func (e *simpleEncDriverIO) resetOutIO(out io.Writer) {
e.w.resetIO(out, e.h.WriterBufferSize, &e.e.blist)
}
func (d *simpleDecDriverIO) init(hh Handle, shared *decoderBase, dec decoderI) (fp interface{}) {
callMake(&d.r)
d.h = hh.(*SimpleHandle)
d.d = shared
if shared.bytes {
fp = simpleFpDecBytes
} else {
fp = simpleFpDecIO
}
d.init2(dec)
return
}
func (d *simpleDecDriverIO) NumBytesRead() int {
return int(d.r.numread())
}
func (d *simpleDecDriverIO) resetInBytes(in []byte) {
d.r.resetBytes(in)
}
func (d *simpleDecDriverIO) resetInIO(r io.Reader) {
d.r.resetIO(r, d.h.ReaderBufferSize, d.h.MaxInitLen, &d.d.blist)
}
func (d *simpleDecDriverIO) descBd() string {
return sprintf("%v (%s)", d.bd, simpledesc(d.bd))
}
func (d *simpleDecDriverIO) DecodeFloat32() (f float32) {
return float32(chkOvf.Float32V(d.DecodeFloat64()))
}
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