photoprism-client-go/vendor/github.com/ugorji/go/codec/helper.go

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// 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
// Contains code shared by both encode and decode.
// Some shared ideas around encoding/decoding
// ------------------------------------------
//
// If an interface{} is passed, we first do a type assertion to see if it is
// a primitive type or a map/slice of primitive types, and use a fastpath to handle it.
//
// If we start with a reflect.Value, we are already in reflect.Value land and
// will try to grab the function for the underlying Type and directly call that function.
// This is more performant than calling reflect.Value.Interface().
//
// This still helps us bypass many layers of reflection, and give best performance.
//
// Containers
// ------------
// Containers in the stream are either associative arrays (key-value pairs) or
// regular arrays (indexed by incrementing integers).
//
// Some streams support indefinite-length containers, and use a breaking
// byte-sequence to denote that the container has come to an end.
//
// Some streams also are text-based, and use explicit separators to denote the
// end/beginning of different values.
//
// Philosophy
// ------------
// On decode, this codec will update containers appropriately:
// - If struct, update fields from stream into fields of struct.
// If field in stream not found in struct, handle appropriately (based on option).
// If a struct field has no corresponding value in the stream, leave it AS IS.
// If nil in stream, set value to nil/zero value.
// - If map, update map from stream.
// If the stream value is NIL, set the map to nil.
// - if slice, try to update up to length of array in stream.
// if container len is less than stream array length,
// and container cannot be expanded, handled (based on option).
// This means you can decode 4-element stream array into 1-element array.
//
// ------------------------------------
// On encode, user can specify omitEmpty. This means that the value will be omitted
// if the zero value. The problem may occur during decode, where omitted values do not affect
// the value being decoded into. This means that if decoding into a struct with an
// int field with current value=5, and the field is omitted in the stream, then after
// decoding, the value will still be 5 (not 0).
// omitEmpty only works if you guarantee that you always decode into zero-values.
//
// ------------------------------------
// We could have truncated a map to remove keys not available in the stream,
// or set values in the struct which are not in the stream to their zero values.
// We decided against it because there is no efficient way to do it.
// We may introduce it as an option later.
// However, that will require enabling it for both runtime and code generation modes.
//
// To support truncate, we need to do 2 passes over the container:
// map
// - first collect all keys (e.g. in k1)
// - for each key in stream, mark k1 that the key should not be removed
// - after updating map, do second pass and call delete for all keys in k1 which are not marked
// struct:
// - for each field, track the *typeInfo s1
// - iterate through all s1, and for each one not marked, set value to zero
// - this involves checking the possible anonymous fields which are nil ptrs.
// too much work.
//
// ------------------------------------------
// Error Handling is done within the library using panic.
//
// This way, the code doesn't have to keep checking if an error has happened,
// and we don't have to keep sending the error value along with each call
// or storing it in the En|Decoder and checking it constantly along the way.
//
// We considered storing the error is En|Decoder.
// - once it has its err field set, it cannot be used again.
// - panicing will be optional, controlled by const flag.
// - code should always check error first and return early.
//
// We eventually decided against it as it makes the code clumsier to always
// check for these error conditions.
//
// ------------------------------------------
// We use sync.Pool only for the aid of long-lived objects shared across multiple goroutines.
// Encoder, Decoder, enc|decDriver, reader|writer, etc do not fall into this bucket.
//
// Also, GC is much better now, eliminating some of the reasons to use a shared pool structure.
// Instead, the short-lived objects use free-lists that live as long as the object exists.
//
// ------------------------------------------
// Performance is affected by the following:
// - Bounds Checking
// - Inlining
// - Pointer chasing
// This package tries hard to manage the performance impact of these.
//
// ------------------------------------------
// To alleviate performance due to pointer-chasing:
// - Prefer non-pointer values in a struct field
// - Refer to these directly within helper classes
// e.g. json.go refers directly to d.d.decRd
//
// We made the changes to embed En/Decoder in en/decDriver,
// but we had to explicitly reference the fields as opposed to using a function
// to get the better performance that we were looking for.
// For example, we explicitly call d.d.decRd.fn() instead of d.d.r().fn().
//
// ------------------------------------------
// Bounds Checking
// - Allow bytesDecReader to incur "bounds check error", and
// recover that as an io.EOF.
// This allows the bounds check branch to always be taken by the branch predictor,
// giving better performance (in theory), while ensuring that the code is shorter.
//
// ------------------------------------------
// Escape Analysis
// - Prefer to return non-pointers if the value is used right away.
// Newly allocated values returned as pointers will be heap-allocated as they escape.
//
// Prefer functions and methods that
// - take no parameters and
// - return no results and
// - do not allocate.
// These are optimized by the runtime.
// For example, in json, we have dedicated functions for ReadMapElemKey, etc
// which do not delegate to readDelim, as readDelim takes a parameter.
// The difference in runtime was as much as 5%.
//
// ------------------------------------------
// Handling Nil
// - In dynamic (reflection) mode, decodeValue and encodeValue handle nil at the top
// - Consequently, methods used with them as a parent in the chain e.g. kXXX
// methods do not handle nil.
// - Fastpath methods also do not handle nil.
// The switch called in (en|de)code(...) handles it so the dependent calls don't have to.
// - codecgen will handle nil before calling into the library for further work also.
//
// ------------------------------------------
// Passing reflect.Kind to functions that take a reflect.Value
// - Note that reflect.Value.Kind() is very cheap, as its fundamentally a binary AND of 2 numbers
import (
"encoding"
"encoding/binary"
"errors"
"fmt"
"io"
"math"
"reflect"
"runtime"
"sort"
"strconv"
"strings"
"sync"
"sync/atomic"
"time"
"unicode/utf8"
)
const (
// containerLenUnknown is length returned from Read(Map|Array)Len
// when a format doesn't know apiori.
// For example, json doesn't pre-determine the length of a container (sequence/map).
containerLenUnknown = -1
// containerLenNil is length returned from Read(Map|Array)Len
// when a 'nil' was encountered in the stream.
containerLenNil = math.MinInt32
// Support encoding.(Binary|Text)(Unm|M)arshaler.
// This constant flag will enable or disable it.
supportMarshalInterfaces = true
// bytesFreeListNoCache is used for debugging, when we want to skip using a cache of []byte.
bytesFreeListNoCache = false
// size of the cacheline: defaulting to value for archs: amd64, arm64, 386
// should use "runtime/internal/sys".CacheLineSize, but that is not exposed.
cacheLineSize = 64
wordSizeBits = 32 << (^uint(0) >> 63) // strconv.IntSize
wordSize = wordSizeBits / 8
// MARKER: determines whether to skip calling fastpath(En|De)codeTypeSwitch.
// Calling the fastpath switch in encode() or decode() could be redundant,
// as we still have to introspect it again within fnLoad
// to determine the function to use for values of that type.
skipFastpathTypeSwitchInDirectCall = false
)
const cpu32Bit = ^uint(0)>>32 == 0
var (
must mustHdl
halt panicHdl
digitCharBitset bitset256
numCharBitset bitset256
whitespaceCharBitset bitset256
asciiAlphaNumBitset bitset256
// numCharWithExpBitset64 bitset64
// numCharNoExpBitset64 bitset64
// whitespaceCharBitset64 bitset64
// refBitset sets bit for all kinds which are direct internal references
refBitset bitset32
// isnilBitset sets bit for all kinds which can be compared to nil
isnilBitset bitset32
// scalarBitset sets bit for all kinds which are scalars/primitives and thus immutable
scalarBitset bitset32
// codecgen is set to true by codecgen, so that tests, etc can use this information as needed.
codecgen bool
oneByteArr [1]byte
zeroByteSlice = oneByteArr[:0:0]
eofReader devNullReader
)
var (
errMapTypeNotMapKind = errors.New("MapType MUST be of Map Kind")
errSliceTypeNotSliceKind = errors.New("SliceType MUST be of Slice Kind")
errExtFnWriteExtUnsupported = errors.New("BytesExt.WriteExt is not supported")
errExtFnReadExtUnsupported = errors.New("BytesExt.ReadExt is not supported")
errExtFnConvertExtUnsupported = errors.New("InterfaceExt.ConvertExt is not supported")
errExtFnUpdateExtUnsupported = errors.New("InterfaceExt.UpdateExt is not supported")
errPanicUndefined = errors.New("panic: undefined error")
errHandleInited = errors.New("cannot modify initialized Handle")
errNoFormatHandle = errors.New("no handle (cannot identify format)")
)
var pool4tiload = sync.Pool{
New: func() interface{} {
return &typeInfoLoad{
etypes: make([]uintptr, 0, 4),
sfis: make([]structFieldInfo, 0, 4),
sfiNames: make(map[string]uint16, 4),
}
},
}
func init() {
scalarBitset.
set(byte(reflect.Bool)).
set(byte(reflect.Int)).
set(byte(reflect.Int8)).
set(byte(reflect.Int16)).
set(byte(reflect.Int32)).
set(byte(reflect.Int64)).
set(byte(reflect.Uint)).
set(byte(reflect.Uint8)).
set(byte(reflect.Uint16)).
set(byte(reflect.Uint32)).
set(byte(reflect.Uint64)).
set(byte(reflect.Uintptr)).
set(byte(reflect.Float32)).
set(byte(reflect.Float64)).
set(byte(reflect.Complex64)).
set(byte(reflect.Complex128)).
set(byte(reflect.String))
// MARKER: reflect.Array is not a scalar, as its contents can be modified
refBitset.
set(byte(reflect.Map)).
set(byte(reflect.Ptr)).
set(byte(reflect.Func)).
set(byte(reflect.Chan)).
set(byte(reflect.UnsafePointer))
isnilBitset = refBitset
isnilBitset.
set(byte(reflect.Interface)).
set(byte(reflect.Slice))
for i := byte(0); i <= utf8.RuneSelf; i++ {
if (i >= '0' && i <= '9') || (i >= 'a' && i <= 'z') || (i >= 'A' && i <= 'Z') {
asciiAlphaNumBitset.set(i)
}
switch i {
case ' ', '\t', '\r', '\n':
whitespaceCharBitset.set(i)
// whitespaceCharBitset64.set(i)
case '0', '1', '2', '3', '4', '5', '6', '7', '8', '9':
digitCharBitset.set(i)
numCharBitset.set(i)
// numCharWithExpBitset64.set(i - 42)
// numCharNoExpBitset64.set(i)
case '.', '+', '-':
numCharBitset.set(i)
// numCharWithExpBitset64.set(i - 42)
// numCharNoExpBitset64.set(i)
case 'e', 'E':
numCharBitset.set(i)
// numCharWithExpBitset64.set(i - 42)
}
}
}
type handleFlag uint8
const (
initedHandleFlag handleFlag = 1 << iota
binaryHandleFlag
jsonHandleFlag
)
type clsErr struct {
err error // error on closing
closed bool // is it closed?
}
type charEncoding uint8
const (
_ charEncoding = iota // make 0 unset
cUTF8
cUTF16LE
cUTF16BE
cUTF32LE
cUTF32BE
// Deprecated: not a true char encoding value
cRAW charEncoding = 255
)
// valueType is the stream type
type valueType uint8
const (
valueTypeUnset valueType = iota
valueTypeNil
valueTypeInt
valueTypeUint
valueTypeFloat
valueTypeBool
valueTypeString
valueTypeSymbol
valueTypeBytes
valueTypeMap
valueTypeArray
valueTypeTime
valueTypeExt
// valueTypeInvalid = 0xff
)
var valueTypeStrings = [...]string{
"Unset",
"Nil",
"Int",
"Uint",
"Float",
"Bool",
"String",
"Symbol",
"Bytes",
"Map",
"Array",
"Timestamp",
"Ext",
}
func (x valueType) String() string {
if int(x) < len(valueTypeStrings) {
return valueTypeStrings[x]
}
return strconv.FormatInt(int64(x), 10)
}
type seqType uint8
const (
_ seqType = iota
seqTypeArray
seqTypeSlice
seqTypeChan
)
// note that containerMapStart and containerArraySend are not sent.
// This is because the ReadXXXStart and EncodeXXXStart already does these.
type containerState uint8
const (
_ containerState = iota
containerMapStart
containerMapKey
containerMapValue
containerMapEnd
containerArrayStart
containerArrayElem
containerArrayEnd
)
// do not recurse if a containing type refers to an embedded type
// which refers back to its containing type (via a pointer).
// The second time this back-reference happens, break out,
// so as not to cause an infinite loop.
const rgetMaxRecursion = 2
// fauxUnion is used to keep track of the primitives decoded.
//
// Without it, we would have to decode each primitive and wrap it
// in an interface{}, causing an allocation.
// In this model, the primitives are decoded in a "pseudo-atomic" fashion,
// so we can rest assured that no other decoding happens while these
// primitives are being decoded.
//
// maps and arrays are not handled by this mechanism.
type fauxUnion struct {
// r RawExt // used for RawExt, uint, []byte.
// primitives below
u uint64
i int64
f float64
l []byte
s string
// ---- cpu cache line boundary?
t time.Time
b bool
// state
v valueType
}
// typeInfoLoad is a transient object used while loading up a typeInfo.
type typeInfoLoad struct {
etypes []uintptr
sfis []structFieldInfo
sfiNames map[string]uint16
}
func (x *typeInfoLoad) reset() {
x.etypes = x.etypes[:0]
x.sfis = x.sfis[:0]
for k := range x.sfiNames { // optimized to zero the map
delete(x.sfiNames, k)
}
}
// mirror json.Marshaler and json.Unmarshaler here,
// so we don't import the encoding/json package
type jsonMarshaler interface {
MarshalJSON() ([]byte, error)
}
type jsonUnmarshaler interface {
UnmarshalJSON([]byte) error
}
type isZeroer interface {
IsZero() bool
}
type isCodecEmptyer interface {
IsCodecEmpty() bool
}
type codecError struct {
err error
name string
pos int
encode bool
}
func (e *codecError) Cause() error {
return e.err
}
func (e *codecError) Error() string {
if e.encode {
return fmt.Sprintf("%s encode error: %v", e.name, e.err)
}
return fmt.Sprintf("%s decode error [pos %d]: %v", e.name, e.pos, e.err)
}
func wrapCodecErr(in error, name string, numbytesread int, encode bool) (out error) {
if x, ok := in.(*codecError); ok && x.pos == numbytesread && x.name == name && x.encode == encode {
return in
}
return &codecError{in, name, numbytesread, encode}
}
var (
bigen bigenHelper
bigenstd = binary.BigEndian
structInfoFieldName = "_struct"
mapStrIntfTyp = reflect.TypeOf(map[string]interface{}(nil))
mapIntfIntfTyp = reflect.TypeOf(map[interface{}]interface{}(nil))
intfSliceTyp = reflect.TypeOf([]interface{}(nil))
intfTyp = intfSliceTyp.Elem()
reflectValTyp = reflect.TypeOf((*reflect.Value)(nil)).Elem()
stringTyp = reflect.TypeOf("")
timeTyp = reflect.TypeOf(time.Time{})
rawExtTyp = reflect.TypeOf(RawExt{})
rawTyp = reflect.TypeOf(Raw{})
uintptrTyp = reflect.TypeOf(uintptr(0))
uint8Typ = reflect.TypeOf(uint8(0))
uint8SliceTyp = reflect.TypeOf([]uint8(nil))
uintTyp = reflect.TypeOf(uint(0))
intTyp = reflect.TypeOf(int(0))
mapBySliceTyp = reflect.TypeOf((*MapBySlice)(nil)).Elem()
binaryMarshalerTyp = reflect.TypeOf((*encoding.BinaryMarshaler)(nil)).Elem()
binaryUnmarshalerTyp = reflect.TypeOf((*encoding.BinaryUnmarshaler)(nil)).Elem()
textMarshalerTyp = reflect.TypeOf((*encoding.TextMarshaler)(nil)).Elem()
textUnmarshalerTyp = reflect.TypeOf((*encoding.TextUnmarshaler)(nil)).Elem()
jsonMarshalerTyp = reflect.TypeOf((*jsonMarshaler)(nil)).Elem()
jsonUnmarshalerTyp = reflect.TypeOf((*jsonUnmarshaler)(nil)).Elem()
selferTyp = reflect.TypeOf((*Selfer)(nil)).Elem()
missingFielderTyp = reflect.TypeOf((*MissingFielder)(nil)).Elem()
iszeroTyp = reflect.TypeOf((*isZeroer)(nil)).Elem()
isCodecEmptyerTyp = reflect.TypeOf((*isCodecEmptyer)(nil)).Elem()
uint8TypId = rt2id(uint8Typ)
uint8SliceTypId = rt2id(uint8SliceTyp)
rawExtTypId = rt2id(rawExtTyp)
rawTypId = rt2id(rawTyp)
intfTypId = rt2id(intfTyp)
timeTypId = rt2id(timeTyp)
stringTypId = rt2id(stringTyp)
mapStrIntfTypId = rt2id(mapStrIntfTyp)
mapIntfIntfTypId = rt2id(mapIntfIntfTyp)
intfSliceTypId = rt2id(intfSliceTyp)
// mapBySliceTypId = rt2id(mapBySliceTyp)
intBitsize = uint8(intTyp.Bits())
uintBitsize = uint8(uintTyp.Bits())
// bsAll0x00 = []byte{0, 0, 0, 0, 0, 0, 0, 0}
bsAll0xff = []byte{0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff}
chkOvf checkOverflow
)
var defTypeInfos = NewTypeInfos([]string{"codec", "json"})
// SelfExt is a sentinel extension signifying that types
// registered with it SHOULD be encoded and decoded
// based on the native mode of the format.
//
// This allows users to define a tag for an extension,
// but signify that the types should be encoded/decoded as the native encoding.
// This way, users need not also define how to encode or decode the extension.
var SelfExt = &extFailWrapper{}
// Selfer defines methods by which a value can encode or decode itself.
//
// Any type which implements Selfer will be able to encode or decode itself.
// Consequently, during (en|de)code, this takes precedence over
// (text|binary)(M|Unm)arshal or extension support.
//
// By definition, it is not allowed for a Selfer to directly call Encode or Decode on itself.
// If that is done, Encode/Decode will rightfully fail with a Stack Overflow style error.
// For example, the snippet below will cause such an error.
// type testSelferRecur struct{}
// func (s *testSelferRecur) CodecEncodeSelf(e *Encoder) { e.MustEncode(s) }
// func (s *testSelferRecur) CodecDecodeSelf(d *Decoder) { d.MustDecode(s) }
//
// Note: *the first set of bytes of any value MUST NOT represent nil in the format*.
// This is because, during each decode, we first check the the next set of bytes
// represent nil, and if so, we just set the value to nil.
type Selfer interface {
CodecEncodeSelf(*Encoder)
CodecDecodeSelf(*Decoder)
}
// MissingFielder defines the interface allowing structs to internally decode or encode
// values which do not map to struct fields.
//
// We expect that this interface is bound to a pointer type (so the mutation function works).
//
// A use-case is if a version of a type unexports a field, but you want compatibility between
// both versions during encoding and decoding.
//
// Note that the interface is completely ignored during codecgen.
type MissingFielder interface {
// CodecMissingField is called to set a missing field and value pair.
//
// It returns true if the missing field was set on the struct.
CodecMissingField(field []byte, value interface{}) bool
// CodecMissingFields returns the set of fields which are not struct fields.
//
// Note that the returned map may be mutated by the caller.
CodecMissingFields() map[string]interface{}
}
// MapBySlice is a tag interface that denotes the slice or array value should encode as a map
// in the stream, and can be decoded from a map in the stream.
//
// The slice or array must contain a sequence of key-value pairs.
// The length of the slice or array must be even (fully divisible by 2).
//
// This affords storing a map in a specific sequence in the stream.
//
// Example usage:
// type T1 []string // or []int or []Point or any other "slice" type
// func (_ T1) MapBySlice{} // T1 now implements MapBySlice, and will be encoded as a map
// type T2 struct { KeyValues T1 }
//
// var kvs = []string{"one", "1", "two", "2", "three", "3"}
// var v2 = T2{ KeyValues: T1(kvs) }
// // v2 will be encoded like the map: {"KeyValues": {"one": "1", "two": "2", "three": "3"} }
//
// The support of MapBySlice affords the following:
// - A slice or array type which implements MapBySlice will be encoded as a map
// - A slice can be decoded from a map in the stream
type MapBySlice interface {
MapBySlice()
}
// BasicHandle encapsulates the common options and extension functions.
//
// Deprecated: DO NOT USE DIRECTLY. EXPORTED FOR GODOC BENEFIT. WILL BE REMOVED.
type BasicHandle struct {
// BasicHandle is always a part of a different type.
// It doesn't have to fit into it own cache lines.
// TypeInfos is used to get the type info for any type.
//
// If not configured, the default TypeInfos is used, which uses struct tag keys: codec, json
TypeInfos *TypeInfos
// Note: BasicHandle is not comparable, due to these slices here (extHandle, intf2impls).
// If *[]T is used instead, this becomes comparable, at the cost of extra indirection.
// Thses slices are used all the time, so keep as slices (not pointers).
extHandle
// these are used during runtime.
// At init time, they should have nothing in them.
rtidFns atomicRtidFnSlice
rtidFnsNoExt atomicRtidFnSlice
// ---- cache line
DecodeOptions
// ---- cache line
EncodeOptions
intf2impls
mu sync.Mutex
inited uint32 // holds if inited, and also handle flags (binary encoding, json handler, etc)
RPCOptions
// TimeNotBuiltin configures whether time.Time should be treated as a builtin type.
//
// All Handlers should know how to encode/decode time.Time as part of the core
// format specification, or as a standard extension defined by the format.
//
// However, users can elect to handle time.Time as a custom extension, or via the
// standard library's encoding.Binary(M|Unm)arshaler or Text(M|Unm)arshaler interface.
// To elect this behavior, users can set TimeNotBuiltin=true.
//
// Note: Setting TimeNotBuiltin=true can be used to enable the legacy behavior
// (for Cbor and Msgpack), where time.Time was not a builtin supported type.
//
// Note: DO NOT CHANGE AFTER FIRST USE.
//
// Once a Handle has been initialized (used), do not modify this option. It will be ignored.
TimeNotBuiltin bool
// timeBuiltin is initialized from TimeNotBuiltin, and used internally.
// once initialized, it cannot be changed, as the function for encoding/decoding time.Time
// will have been cached and the TimeNotBuiltin value will not be consulted thereafter.
timeBuiltin bool
// ExplicitRelease configures whether Release() is implicitly called after an encode or
// decode call.
//
// If you will hold onto an Encoder or Decoder for re-use, by calling Reset(...)
// on it or calling (Must)Encode repeatedly into a given []byte or io.Writer,
// then you do not want it to be implicitly closed after each Encode/Decode call.
// Doing so will unnecessarily return resources to the shared pool, only for you to
// grab them right after again to do another Encode/Decode call.
//
// Instead, you configure ExplicitRelease=true, and you explicitly call Release() when
// you are truly done.
//
// As an alternative, you can explicitly set a finalizer - so its resources
// are returned to the shared pool before it is garbage-collected. Do it as below:
// runtime.SetFinalizer(e, (*Encoder).Release)
// runtime.SetFinalizer(d, (*Decoder).Release)
//
// Deprecated: This is not longer used as pools are only used for long-lived objects
// which are shared across goroutines.
// Setting this value has no effect. It is maintained for backward compatibility.
ExplicitRelease bool
// ---- cache line
}
// initHandle does a one-time initialization of the handle.
// After this is run, do not modify the Handle, as some modifications are ignored
// e.g. extensions, registered interfaces, TimeNotBuiltIn, etc
func initHandle(hh Handle) {
x := hh.getBasicHandle()
// ** We need to simulate once.Do, to ensure no data race within the block.
// ** Consequently, below would not work.
// if atomic.CompareAndSwapUint32(&x.inited, 0, 1) {
// x.be = hh.isBinary()
// _, x.js = hh.(*JsonHandle)
// x.n = hh.Name()[0]
// }
// simulate once.Do using our own stored flag and mutex as a CompareAndSwap
// is not sufficient, since a race condition can occur within init(Handle) function.
// init is made noinline, so that this function can be inlined by its caller.
if atomic.LoadUint32(&x.inited) == 0 {
x.initHandle(hh)
}
}
func (x *BasicHandle) basicInit() {
x.rtidFns.store(nil)
x.rtidFnsNoExt.store(nil)
x.timeBuiltin = !x.TimeNotBuiltin
}
func (x *BasicHandle) init() {}
func (x *BasicHandle) isInited() bool {
return atomic.LoadUint32(&x.inited) != 0
}
// clearInited: DANGEROUS - only use in testing, etc
func (x *BasicHandle) clearInited() {
atomic.StoreUint32(&x.inited, 0)
}
// TimeBuiltin returns whether time.Time OOTB support is used,
// based on the initial configuration of TimeNotBuiltin
func (x *BasicHandle) TimeBuiltin() bool {
return x.timeBuiltin
}
func (x *BasicHandle) isJs() bool {
return handleFlag(x.inited)&jsonHandleFlag != 0
}
func (x *BasicHandle) isBe() bool {
return handleFlag(x.inited)&binaryHandleFlag != 0
}
//go:noinline
func (x *BasicHandle) initHandle(hh Handle) {
// make it uninlineable, as it is called at most once
x.mu.Lock()
defer x.mu.Unlock() // use defer, as halt may panic below
if x.inited == 0 {
var f = initedHandleFlag
if hh.isBinary() {
f |= binaryHandleFlag
}
if _, b := hh.(*JsonHandle); b {
f |= jsonHandleFlag
}
// ensure MapType and SliceType are of correct type
if x.MapType != nil && x.MapType.Kind() != reflect.Map {
halt.onerror(errMapTypeNotMapKind)
}
if x.SliceType != nil && x.SliceType.Kind() != reflect.Slice {
halt.onerror(errSliceTypeNotSliceKind)
}
x.basicInit()
hh.init()
atomic.StoreUint32(&x.inited, uint32(f))
}
}
func (x *BasicHandle) getBasicHandle() *BasicHandle {
return x
}
func (x *BasicHandle) getTypeInfo(rtid uintptr, rt reflect.Type) (pti *typeInfo) {
if x.TypeInfos == nil {
return defTypeInfos.get(rtid, rt)
}
return x.TypeInfos.get(rtid, rt)
}
func findRtidFn(s []codecRtidFn, rtid uintptr) (i uint, fn *codecFn) {
// binary search. adapted from sort/search.go.
// Note: we use goto (instead of for loop) so this can be inlined.
// h, i, j := 0, 0, len(s)
var h uint // var h, i uint
var j = uint(len(s))
LOOP:
if i < j {
h = (i + j) >> 1 // avoid overflow when computing h // h = i + (j-i)/2
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 (x *BasicHandle) fn(rt reflect.Type) (fn *codecFn) {
return x.fnVia(rt, &x.rtidFns, true)
}
func (x *BasicHandle) fnNoExt(rt reflect.Type) (fn *codecFn) {
return x.fnVia(rt, &x.rtidFnsNoExt, false)
}
func (x *BasicHandle) fnVia(rt reflect.Type, fs *atomicRtidFnSlice, checkExt bool) (fn *codecFn) {
rtid := rt2id(rt)
sp := fs.load()
if sp != nil {
if _, fn = findRtidFn(sp, rtid); fn != nil {
return
}
}
fn = x.fnLoad(rt, rtid, checkExt)
x.mu.Lock()
sp = fs.load()
// since this is an atomic load/store, we MUST use a different array each time,
// else we have a data race when a store is happening simultaneously with a findRtidFn call.
if sp == nil {
sp = []codecRtidFn{{rtid, fn}}
fs.store(sp)
} else {
idx, fn2 := findRtidFn(sp, rtid)
if fn2 == nil {
sp2 := make([]codecRtidFn, len(sp)+1)
copy(sp2, sp[:idx])
copy(sp2[idx+1:], sp[idx:])
sp2[idx] = codecRtidFn{rtid, fn}
fs.store(sp2)
}
}
x.mu.Unlock()
return
}
func (x *BasicHandle) fnLoad(rt reflect.Type, rtid uintptr, checkExt bool) (fn *codecFn) {
fn = new(codecFn)
fi := &(fn.i)
ti := x.getTypeInfo(rtid, rt)
fi.ti = ti
rk := reflect.Kind(ti.kind)
// anything can be an extension except the built-in ones: time, raw and rawext.
// ensure we check for these types, then if extension, before checking if
// it implementes one of the pre-declared interfaces.
fi.addrDf = true
fi.addrEf = true
if rtid == timeTypId && x.timeBuiltin {
fn.fe = (*Encoder).kTime
fn.fd = (*Decoder).kTime
} else if rtid == rawTypId {
fn.fe = (*Encoder).raw
fn.fd = (*Decoder).raw
} else if rtid == rawExtTypId {
fn.fe = (*Encoder).rawExt
fn.fd = (*Decoder).rawExt
fi.addrD = true
fi.addrE = true
} else if xfFn := x.getExt(rtid, checkExt); xfFn != nil {
fi.xfTag, fi.xfFn = xfFn.tag, xfFn.ext
fn.fe = (*Encoder).ext
fn.fd = (*Decoder).ext
fi.addrD = true
if rk == reflect.Struct || rk == reflect.Array {
fi.addrE = true
}
} else if ti.flagSelfer || ti.flagSelferPtr {
fn.fe = (*Encoder).selferMarshal
fn.fd = (*Decoder).selferUnmarshal
fi.addrD = ti.flagSelferPtr
fi.addrE = ti.flagSelferPtr
} else if supportMarshalInterfaces && x.isBe() &&
(ti.flagBinaryMarshaler || ti.flagBinaryMarshalerPtr) &&
(ti.flagBinaryUnmarshaler || ti.flagBinaryUnmarshalerPtr) {
fn.fe = (*Encoder).binaryMarshal
fn.fd = (*Decoder).binaryUnmarshal
fi.addrD = ti.flagBinaryUnmarshalerPtr
fi.addrE = ti.flagBinaryMarshalerPtr
} else if supportMarshalInterfaces && !x.isBe() && x.isJs() &&
(ti.flagJsonMarshaler || ti.flagJsonMarshalerPtr) &&
(ti.flagJsonUnmarshaler || ti.flagJsonUnmarshalerPtr) {
//If JSON, we should check JSONMarshal before textMarshal
fn.fe = (*Encoder).jsonMarshal
fn.fd = (*Decoder).jsonUnmarshal
fi.addrD = ti.flagJsonUnmarshalerPtr
fi.addrE = ti.flagJsonMarshalerPtr
} else if supportMarshalInterfaces && !x.isBe() &&
(ti.flagTextMarshaler || ti.flagTextMarshalerPtr) &&
(ti.flagTextUnmarshaler || ti.flagTextUnmarshalerPtr) {
fn.fe = (*Encoder).textMarshal
fn.fd = (*Decoder).textUnmarshal
fi.addrD = ti.flagTextUnmarshalerPtr
fi.addrE = ti.flagTextMarshalerPtr
} else {
if fastpathEnabled && (rk == reflect.Map || rk == reflect.Slice) {
if ti.pkgpath == "" { // un-named slice or map
if idx := fastpathAvIndex(rtid); idx != -1 {
fn.fe = fastpathAv[idx].encfn
fn.fd = fastpathAv[idx].decfn
fi.addrD = true
fi.addrDf = false
}
} else {
// use mapping for underlying type if there
var rtu reflect.Type
if rk == reflect.Map {
rtu = reflect.MapOf(ti.key, ti.elem)
} else {
rtu = reflect.SliceOf(ti.elem)
}
rtuid := rt2id(rtu)
if idx := fastpathAvIndex(rtuid); idx != -1 {
xfnf := fastpathAv[idx].encfn
xrt := fastpathAv[idx].rt
fn.fe = func(e *Encoder, xf *codecFnInfo, xrv reflect.Value) {
xfnf(e, xf, rvConvert(xrv, xrt))
}
fi.addrD = true
fi.addrDf = false // meaning it can be an address(ptr) or a value
xfnf2 := fastpathAv[idx].decfn
xptr2rt := reflect.PtrTo(xrt)
fn.fd = func(d *Decoder, xf *codecFnInfo, xrv reflect.Value) {
if xrv.Kind() == reflect.Ptr {
xfnf2(d, xf, rvConvert(xrv, xptr2rt))
} else {
xfnf2(d, xf, rvConvert(xrv, xrt))
}
}
}
}
}
if fn.fe == nil && fn.fd == nil {
switch rk {
case reflect.Bool:
fn.fe = (*Encoder).kBool
fn.fd = (*Decoder).kBool
case reflect.String:
// Do not use different functions based on StringToRaw option,
// as that will statically set the function for a string type,
// and if the Handle is modified thereafter, behaviour is non-deterministic.
// i.e. DO NOT DO:
// if x.StringToRaw {
// fn.fe = (*Encoder).kStringToRaw
// } else {
// fn.fe = (*Encoder).kStringEnc
// }
fn.fe = (*Encoder).kString
fn.fd = (*Decoder).kString
case reflect.Int:
fn.fd = (*Decoder).kInt
fn.fe = (*Encoder).kInt
case reflect.Int8:
fn.fe = (*Encoder).kInt8
fn.fd = (*Decoder).kInt8
case reflect.Int16:
fn.fe = (*Encoder).kInt16
fn.fd = (*Decoder).kInt16
case reflect.Int32:
fn.fe = (*Encoder).kInt32
fn.fd = (*Decoder).kInt32
case reflect.Int64:
fn.fe = (*Encoder).kInt64
fn.fd = (*Decoder).kInt64
case reflect.Uint:
fn.fd = (*Decoder).kUint
fn.fe = (*Encoder).kUint
case reflect.Uint8:
fn.fe = (*Encoder).kUint8
fn.fd = (*Decoder).kUint8
case reflect.Uint16:
fn.fe = (*Encoder).kUint16
fn.fd = (*Decoder).kUint16
case reflect.Uint32:
fn.fe = (*Encoder).kUint32
fn.fd = (*Decoder).kUint32
case reflect.Uint64:
fn.fe = (*Encoder).kUint64
fn.fd = (*Decoder).kUint64
case reflect.Uintptr:
fn.fe = (*Encoder).kUintptr
fn.fd = (*Decoder).kUintptr
case reflect.Float32:
fn.fe = (*Encoder).kFloat32
fn.fd = (*Decoder).kFloat32
case reflect.Float64:
fn.fe = (*Encoder).kFloat64
fn.fd = (*Decoder).kFloat64
case reflect.Chan:
fi.seq = seqTypeChan
fn.fe = (*Encoder).kChan
fn.fd = (*Decoder).kSliceForChan
case reflect.Slice:
fi.seq = seqTypeSlice
fn.fe = (*Encoder).kSlice
fn.fd = (*Decoder).kSlice
case reflect.Array:
fi.seq = seqTypeArray
fn.fe = (*Encoder).kArray
rt2 := reflect.SliceOf(ti.elem)
fn.fd = func(d *Decoder, xf *codecFnInfo, xrv reflect.Value) {
// call fnVia directly, so fn(...) is not recursive, and this can be inlined
d.h.fnVia(rt2, &x.rtidFns, true).fd(d, xf, rvGetSlice4Array(xrv, rt2))
}
case reflect.Struct:
if ti.anyOmitEmpty ||
ti.flagMissingFielder ||
ti.flagMissingFielderPtr {
fn.fe = (*Encoder).kStruct
} else {
fn.fe = (*Encoder).kStructNoOmitempty
}
fn.fd = (*Decoder).kStruct
case reflect.Map:
fn.fe = (*Encoder).kMap
fn.fd = (*Decoder).kMap
case reflect.Interface:
// encode: reflect.Interface are handled already by preEncodeValue
fn.fd = (*Decoder).kInterface
fn.fe = (*Encoder).kErr
default:
// reflect.Ptr and reflect.Interface are handled already by preEncodeValue
fn.fe = (*Encoder).kErr
fn.fd = (*Decoder).kErr
}
}
}
return
}
// Handle defines a specific encoding format. It also stores any runtime state
// used during an Encoding or Decoding session e.g. stored state about Types, etc.
//
// Once a handle is configured, it can be shared across multiple Encoders and Decoders.
//
// Note that a Handle is NOT safe for concurrent modification.
//
// A Handle also should not be modified after it is configured and has
// been used at least once. This is because stored state may be out of sync with the
// new configuration, and a data race can occur when multiple goroutines access it.
// i.e. multiple Encoders or Decoders in different goroutines.
//
// Consequently, the typical usage model is that a Handle is pre-configured
// before first time use, and not modified while in use.
// Such a pre-configured Handle is safe for concurrent access.
type Handle interface {
Name() string
getBasicHandle() *BasicHandle
newEncDriver() encDriver
newDecDriver() decDriver
isBinary() bool
// desc describes the current byte descriptor, or returns "unknown[XXX]" if not understood.
desc(bd byte) string
// init initializes the handle based on handle-specific info (beyond what is in BasicHandle)
init()
}
// Raw represents raw formatted bytes.
// We "blindly" store it during encode and retrieve the raw bytes during decode.
// Note: it is dangerous during encode, so we may gate the behaviour
// behind an Encode flag which must be explicitly set.
type Raw []byte
// RawExt represents raw unprocessed extension data.
// Some codecs will decode extension data as a *RawExt
// if there is no registered extension for the tag.
//
// Only one of Data or Value is nil.
// If Data is nil, then the content of the RawExt is in the Value.
type RawExt struct {
Tag uint64
// Data is the []byte which represents the raw ext. If nil, ext is exposed in Value.
// Data is used by codecs (e.g. binc, msgpack, simple) which do custom serialization of types
Data []byte
// Value represents the extension, if Data is nil.
// Value is used by codecs (e.g. cbor, json) which leverage the format to do
// custom serialization of the types.
Value interface{}
}
func (re *RawExt) setData(xbs []byte, zerocopy bool) {
if zerocopy {
re.Data = xbs
} else {
if len(re.Data) > 0 {
re.Data = re.Data[:0]
}
re.Data = append(re.Data, xbs...)
}
}
// BytesExt handles custom (de)serialization of types to/from []byte.
// It is used by codecs (e.g. binc, msgpack, simple) which do custom serialization of the types.
type BytesExt interface {
// WriteExt converts a value to a []byte.
//
// Note: v is a pointer iff the registered extension type is a struct or array kind.
WriteExt(v interface{}) []byte
// ReadExt updates a value from a []byte.
//
// Note: dst is always a pointer kind to the registered extension type.
ReadExt(dst interface{}, src []byte)
}
// InterfaceExt handles custom (de)serialization of types to/from another interface{} value.
// The Encoder or Decoder will then handle the further (de)serialization of that known type.
//
// It is used by codecs (e.g. cbor, json) which use the format to do custom serialization of types.
type InterfaceExt interface {
// ConvertExt converts a value into a simpler interface for easy encoding
// e.g. convert time.Time to int64.
//
// Note: v is a pointer iff the registered extension type is a struct or array kind.
ConvertExt(v interface{}) interface{}
// UpdateExt updates a value from a simpler interface for easy decoding
// e.g. convert int64 to time.Time.
//
// Note: dst is always a pointer kind to the registered extension type.
UpdateExt(dst interface{}, src interface{})
}
// Ext handles custom (de)serialization of custom types / extensions.
type Ext interface {
BytesExt
InterfaceExt
}
// addExtWrapper is a wrapper implementation to support former AddExt exported method.
type addExtWrapper struct {
encFn func(reflect.Value) ([]byte, error)
decFn func(reflect.Value, []byte) error
}
func (x addExtWrapper) WriteExt(v interface{}) []byte {
bs, err := x.encFn(rv4i(v))
halt.onerror(err)
return bs
}
func (x addExtWrapper) ReadExt(v interface{}, bs []byte) {
halt.onerror(x.decFn(rv4i(v), bs))
}
func (x addExtWrapper) ConvertExt(v interface{}) interface{} {
return x.WriteExt(v)
}
func (x addExtWrapper) UpdateExt(dest interface{}, v interface{}) {
x.ReadExt(dest, v.([]byte))
}
type bytesExtFailer struct{}
func (bytesExtFailer) WriteExt(v interface{}) []byte {
halt.onerror(errExtFnWriteExtUnsupported)
return nil
}
func (bytesExtFailer) ReadExt(v interface{}, bs []byte) {
halt.onerror(errExtFnReadExtUnsupported)
}
type interfaceExtFailer struct{}
func (interfaceExtFailer) ConvertExt(v interface{}) interface{} {
halt.onerror(errExtFnConvertExtUnsupported)
return nil
}
func (interfaceExtFailer) UpdateExt(dest interface{}, v interface{}) {
halt.onerror(errExtFnUpdateExtUnsupported)
}
type bytesExtWrapper struct {
interfaceExtFailer
BytesExt
}
type interfaceExtWrapper struct {
bytesExtFailer
InterfaceExt
}
type extFailWrapper struct {
bytesExtFailer
interfaceExtFailer
}
type binaryEncodingType struct{}
func (binaryEncodingType) isBinary() bool { return true }
type textEncodingType struct{}
func (textEncodingType) isBinary() bool { return false }
// noBuiltInTypes is embedded into many types which do not support builtins
// e.g. msgpack, simple, cbor.
type noBuiltInTypes struct{}
func (noBuiltInTypes) EncodeBuiltin(rt uintptr, v interface{}) {}
func (noBuiltInTypes) DecodeBuiltin(rt uintptr, v interface{}) {}
// bigenHelper handles ByteOrder operations directly using
// arrays of bytes (not slice of bytes).
//
// Since byteorder operations are very common for encoding and decoding
// numbers, lengths, etc - it is imperative that this operation is as
// fast as possible. Removing indirection (pointer chasing) to look
// at up to 8 bytes helps a lot here.
//
// For times where it is expedient to use a slice, delegate to the
// bigenstd (equal to the binary.BigEndian value).
//
// retrofitted from stdlib: encoding/binary/BigEndian (ByteOrder)
type bigenHelper struct{}
func (z bigenHelper) PutUint16(v uint16) (b [2]byte) {
return [...]byte{
byte(v >> 8),
byte(v),
}
}
func (z bigenHelper) PutUint32(v uint32) (b [4]byte) {
return [...]byte{
byte(v >> 24),
byte(v >> 16),
byte(v >> 8),
byte(v),
}
}
func (z bigenHelper) PutUint64(v uint64) (b [8]byte) {
return [...]byte{
byte(v >> 56),
byte(v >> 48),
byte(v >> 40),
byte(v >> 32),
byte(v >> 24),
byte(v >> 16),
byte(v >> 8),
byte(v),
}
}
func (z bigenHelper) Uint16(b [2]byte) (v uint16) {
return uint16(b[1]) |
uint16(b[0])<<8
}
func (z bigenHelper) Uint32(b [4]byte) (v uint32) {
return uint32(b[3]) |
uint32(b[2])<<8 |
uint32(b[1])<<16 |
uint32(b[0])<<24
}
func (z bigenHelper) Uint64(b [8]byte) (v uint64) {
return uint64(b[7]) |
uint64(b[6])<<8 |
uint64(b[5])<<16 |
uint64(b[4])<<24 |
uint64(b[3])<<32 |
uint64(b[2])<<40 |
uint64(b[1])<<48 |
uint64(b[0])<<56
}
func (z bigenHelper) writeUint16(w *encWr, v uint16) {
x := z.PutUint16(v)
w.writen2(x[0], x[1])
}
func (z bigenHelper) writeUint32(w *encWr, v uint32) {
w.writen4(z.PutUint32(v))
}
func (z bigenHelper) writeUint64(w *encWr, v uint64) {
w.writen8(z.PutUint64(v))
}
type extTypeTagFn struct {
rtid uintptr
rtidptr uintptr
rt reflect.Type
tag uint64
ext Ext
}
type extHandle []extTypeTagFn
// AddExt registes an encode and decode function for a reflect.Type.
// To deregister an Ext, call AddExt with nil encfn and/or nil decfn.
//
// Deprecated: Use SetBytesExt or SetInterfaceExt on the Handle instead.
func (x *BasicHandle) AddExt(rt reflect.Type, tag byte,
encfn func(reflect.Value) ([]byte, error),
decfn func(reflect.Value, []byte) error) (err error) {
if encfn == nil || decfn == nil {
return x.SetExt(rt, uint64(tag), nil)
}
return x.SetExt(rt, uint64(tag), addExtWrapper{encfn, decfn})
}
// SetExt will set the extension for a tag and reflect.Type.
// Note that the type must be a named type, and specifically not a pointer or Interface.
// An error is returned if that is not honored.
// To Deregister an ext, call SetExt with nil Ext.
//
// Deprecated: Use SetBytesExt or SetInterfaceExt on the Handle instead.
func (x *BasicHandle) SetExt(rt reflect.Type, tag uint64, ext Ext) (err error) {
if x.isInited() {
return errHandleInited
}
rk := rt.Kind()
for rk == reflect.Ptr {
rt = rt.Elem()
rk = rt.Kind()
}
if rt.PkgPath() == "" || rk == reflect.Interface { // || rk == reflect.Ptr {
return fmt.Errorf("codec.Handle.SetExt: Takes named type, not a pointer or interface: %v", rt)
}
rtid := rt2id(rt)
switch rtid {
case timeTypId, rawTypId, rawExtTypId:
// all natively supported type, so cannot have an extension.
// However, we do not return an error for these, as we do not document that.
// Instead, we silently treat as a no-op, and return.
return
}
for i := range x.extHandle {
v := &x.extHandle[i]
if v.rtid == rtid {
v.tag, v.ext = tag, ext
return
}
}
rtidptr := rt2id(reflect.PtrTo(rt))
x.extHandle = append(x.extHandle, extTypeTagFn{rtid, rtidptr, rt, tag, ext})
return
}
func (o extHandle) getExtForI(x interface{}) (v *extTypeTagFn) {
if len(o) > 0 {
v = o.getExt(i2rtid(x), true)
}
return
}
func (o extHandle) getExt(rtid uintptr, check bool) (v *extTypeTagFn) {
if !check {
return
}
for i := range o {
v = &o[i]
if v.rtid == rtid || v.rtidptr == rtid {
return
}
}
return nil
}
func (o extHandle) getExtForTag(tag uint64) (v *extTypeTagFn) {
for i := range o {
v = &o[i]
if v.tag == tag {
return
}
}
return nil
}
type intf2impl struct {
rtid uintptr // for intf
impl reflect.Type
}
type intf2impls []intf2impl
// Intf2Impl maps an interface to an implementing type.
// This allows us support infering the concrete type
// and populating it when passed an interface.
// e.g. var v io.Reader can be decoded as a bytes.Buffer, etc.
//
// Passing a nil impl will clear the mapping.
func (o *intf2impls) Intf2Impl(intf, impl reflect.Type) (err error) {
if impl != nil && !impl.Implements(intf) {
return fmt.Errorf("Intf2Impl: %v does not implement %v", impl, intf)
}
rtid := rt2id(intf)
o2 := *o
for i := range o2 {
v := &o2[i]
if v.rtid == rtid {
v.impl = impl
return
}
}
*o = append(o2, intf2impl{rtid, impl})
return
}
func (o intf2impls) intf2impl(rtid uintptr) (rv reflect.Value) {
for i := range o {
v := &o[i]
if v.rtid == rtid {
if v.impl == nil {
return
}
vkind := v.impl.Kind()
if vkind == reflect.Ptr {
return reflect.New(v.impl.Elem())
}
return rvZeroAddrK(v.impl, vkind)
}
}
return
}
// structFieldinfopathNode is a node in a tree, which allows us easily
// walk the anonymous path.
//
// In the typical case, the node is not embedded/anonymous, and thus the parent
// will be nil and this information becomes a value (not needing any indirection).
type structFieldInfoPathNode struct {
parent *structFieldInfoPathNode
offset uint16
index uint16
kind uint8
numderef uint8
// encNameAsciiAlphaNum and omitEmpty should be in structFieldInfo,
// but are kept here for tighter packaging.
encNameAsciiAlphaNum bool // the encName only contains ascii alphabet and numbers
omitEmpty bool
typ reflect.Type
}
// depth returns number of valid nodes in the hierachy
func (path *structFieldInfoPathNode) depth() (d int) {
TOP:
if path != nil {
d++
path = path.parent
goto TOP
}
return
}
// field returns the field of the struct.
func (path *structFieldInfoPathNode) field(v reflect.Value) (rv2 reflect.Value) {
if parent := path.parent; parent != nil {
v = parent.field(v)
for j, k := uint8(0), parent.numderef; j < k; j++ {
if rvIsNil(v) {
return
}
v = v.Elem()
}
}
return path.rvField(v)
}
// fieldAlloc returns the field of the struct.
// It allocates if a nil value was seen while searching.
func (path *structFieldInfoPathNode) fieldAlloc(v reflect.Value) (rv2 reflect.Value) {
if parent := path.parent; parent != nil {
v = parent.fieldAlloc(v)
for j, k := uint8(0), parent.numderef; j < k; j++ {
if rvIsNil(v) {
rvSetDirect(v, reflect.New(rvType(v).Elem()))
}
v = v.Elem()
}
}
return path.rvField(v)
}
type structFieldInfo struct {
encName string // encode name
// fieldName string // currently unused
// encNameAsciiAlphaNum and omitEmpty should be here,
// but are stored in structFieldInfoPathNode for tighter packaging.
path structFieldInfoPathNode
}
func parseStructInfo(stag string) (toArray, omitEmpty bool, keytype valueType) {
keytype = valueTypeString // default
if stag == "" {
return
}
for _, s := range strings.Split(stag, ",")[1:] {
switch s {
case "omitempty":
omitEmpty = true
case "toarray":
toArray = true
case "int":
keytype = valueTypeInt
case "uint":
keytype = valueTypeUint
case "float":
keytype = valueTypeFloat
// case "bool":
// keytype = valueTypeBool
case "string":
keytype = valueTypeString
}
}
return
}
func (si *structFieldInfo) parseTag(stag string) {
if stag == "" {
return
}
for i, s := range strings.Split(stag, ",") {
if i == 0 {
if s != "" {
si.encName = s
}
} else {
switch s {
case "omitempty":
si.path.omitEmpty = true
}
}
}
}
type sfiSortedByEncName []*structFieldInfo
func (p sfiSortedByEncName) Len() int { return len(p) }
func (p sfiSortedByEncName) Less(i, j int) bool { return p[uint(i)].encName < p[uint(j)].encName }
func (p sfiSortedByEncName) Swap(i, j int) { p[uint(i)], p[uint(j)] = p[uint(j)], p[uint(i)] }
// typeInfo keeps static (non-changing readonly)information
// about each (non-ptr) type referenced in the encode/decode sequence.
//
// During an encode/decode sequence, we work as below:
// - If base is a built in type, en/decode base value
// - If base is registered as an extension, en/decode base value
// - If type is binary(M/Unm)arshaler, call Binary(M/Unm)arshal method
// - If type is text(M/Unm)arshaler, call Text(M/Unm)arshal method
// - Else decode appropriately based on the reflect.Kind
type typeInfo struct {
rt reflect.Type
elem reflect.Type
pkgpath string
rtid uintptr
numMeth uint16 // number of methods
kind uint8
chandir uint8
anyOmitEmpty bool // true if a struct, and any of the fields are tagged "omitempty"
toArray bool // whether this (struct) type should be encoded as an array
keyType valueType // if struct, how is the field name stored in a stream? default is string
mbs bool // base type (T or *T) is a MapBySlice
// ---- cpu cache line boundary?
sfiSort []*structFieldInfo // sorted. Used when enc/dec struct to map.
sfiSrc []*structFieldInfo // unsorted. Used when enc/dec struct to array.
sfi4Name map[string]*structFieldInfo
key reflect.Type
// ---- cpu cache line boundary?
size, keysize, elemsize uint32
// other flags, with individual bits representing if set.
flagComparable bool
flagIsZeroer bool
flagIsZeroerPtr bool
flagIsCodecEmptyer bool
flagIsCodecEmptyerPtr bool
flagBinaryMarshaler bool
flagBinaryMarshalerPtr bool
flagBinaryUnmarshaler bool
flagBinaryUnmarshalerPtr bool
flagTextMarshaler bool
flagTextMarshalerPtr bool
flagTextUnmarshaler bool
flagTextUnmarshalerPtr bool
flagJsonMarshaler bool
flagJsonMarshalerPtr bool
flagJsonUnmarshaler bool
flagJsonUnmarshalerPtr bool
flagSelfer bool
flagSelferPtr bool
flagMissingFielder bool
flagMissingFielderPtr bool
infoFieldOmitempty bool
keykind, elemkind uint8
}
func (ti *typeInfo) siForEncName(name string) (si *structFieldInfo) {
// binary search for map lookup is expensive, as it has to compare strings byte by byte.
// map (hash) lookup is faster, as it can leverage string length in disambiguation.
return ti.sfi4Name[name]
}
func (ti *typeInfo) resolve(x []structFieldInfo, ss map[string]uint16) (n int) {
n = len(x)
for i := range x {
ui := uint16(i)
xn := x[ui].encName // fieldName or encName? use encName for now.
j, ok := ss[xn]
if ok {
i2clear := ui // index to be cleared
if x[ui].path.depth() < x[j].path.depth() { // this one is shallower
ss[xn] = ui
i2clear = j
}
if x[i2clear].encName != "" {
x[i2clear].encName = ""
n--
}
} else {
ss[xn] = ui
}
}
return
}
func (ti *typeInfo) init(x []structFieldInfo, n int) {
var anyOmitEmpty bool
// remove all the nils (non-ready)
m := make(map[string]*structFieldInfo)
w := make([]structFieldInfo, n)
y := make([]*structFieldInfo, n)
n = 0
for i := range x {
if x[i].encName == "" {
continue
}
if !anyOmitEmpty && x[i].path.omitEmpty {
anyOmitEmpty = true
}
w[n] = x[i]
y[n] = &w[n]
m[x[i].encName] = &w[n]
n++
}
if n != len(y) {
halt.errorf("failure reading struct %v - expecting %d of %d valid fields, got %d", ti.rt, len(y), len(x), n)
}
z := make([]*structFieldInfo, len(y))
copy(z, y)
sort.Sort(sfiSortedByEncName(z))
ti.anyOmitEmpty = anyOmitEmpty
ti.sfiSrc = y
ti.sfiSort = z
ti.sfi4Name = m
}
type rtid2ti struct {
rtid uintptr
ti *typeInfo
}
// TypeInfos caches typeInfo for each type on first inspection.
//
// It is configured with a set of tag keys, which are used to get
// configuration for the type.
type TypeInfos struct {
infos atomicTypeInfoSlice
mu sync.Mutex
_ uint64 // padding (cache-aligned)
tags []string
_ uint64 // padding (cache-aligned)
}
// NewTypeInfos creates a TypeInfos given a set of struct tags keys.
//
// This allows users customize the struct tag keys which contain configuration
// of their types.
func NewTypeInfos(tags []string) *TypeInfos {
return &TypeInfos{tags: tags}
}
func (x *TypeInfos) structTag(t reflect.StructTag) (s string) {
// check for tags: codec, json, in that order.
// this allows seamless support for many configured structs.
for _, x := range x.tags {
s = t.Get(x)
if s != "" {
return s
}
}
return
}
func findTypeInfo(s []rtid2ti, rtid uintptr) (i uint, ti *typeInfo) {
// binary search. adapted from sort/search.go.
// Note: we use goto (instead of for loop) so this can be inlined.
var h uint
var j = uint(len(s))
LOOP:
if i < j {
h = (i + j) >> 1 // avoid overflow when computing h // h = i + (j-i)/2
if s[h].rtid < rtid {
i = h + 1
} else {
j = h
}
goto LOOP
}
if i < uint(len(s)) && s[i].rtid == rtid {
ti = s[i].ti
}
return
}
func (x *TypeInfos) get(rtid uintptr, rt reflect.Type) (pti *typeInfo) {
sp := x.infos.load()
if sp != nil {
_, pti = findTypeInfo(sp, rtid)
if pti != nil {
return
}
}
rk := rt.Kind()
if rk == reflect.Ptr { // || (rk == reflect.Interface && rtid != intfTypId) {
halt.errorf("invalid kind passed to TypeInfos.get: %v - %v", rk, rt)
}
// do not hold lock while computing this.
// it may lead to duplication, but that's ok.
ti := typeInfo{
rt: rt,
rtid: rtid,
kind: uint8(rk),
size: uint32(rt.Size()),
numMeth: uint16(rt.NumMethod()),
pkgpath: rt.PkgPath(),
keyType: valueTypeString, // default it - so it's never 0
}
bset := func(when bool, b *bool) {
if when {
*b = true
}
}
var b1, b2 bool
b1, b2 = implIntf(rt, binaryMarshalerTyp)
bset(b1, &ti.flagBinaryMarshaler)
bset(b2, &ti.flagBinaryMarshalerPtr)
b1, b2 = implIntf(rt, binaryUnmarshalerTyp)
bset(b1, &ti.flagBinaryUnmarshaler)
bset(b2, &ti.flagBinaryUnmarshalerPtr)
b1, b2 = implIntf(rt, textMarshalerTyp)
bset(b1, &ti.flagTextMarshaler)
bset(b2, &ti.flagTextMarshalerPtr)
b1, b2 = implIntf(rt, textUnmarshalerTyp)
bset(b1, &ti.flagTextUnmarshaler)
bset(b2, &ti.flagTextUnmarshalerPtr)
b1, b2 = implIntf(rt, jsonMarshalerTyp)
bset(b1, &ti.flagJsonMarshaler)
bset(b2, &ti.flagJsonMarshalerPtr)
b1, b2 = implIntf(rt, jsonUnmarshalerTyp)
bset(b1, &ti.flagJsonUnmarshaler)
bset(b2, &ti.flagJsonUnmarshalerPtr)
b1, b2 = implIntf(rt, selferTyp)
bset(b1, &ti.flagSelfer)
bset(b2, &ti.flagSelferPtr)
b1, b2 = implIntf(rt, missingFielderTyp)
bset(b1, &ti.flagMissingFielder)
bset(b2, &ti.flagMissingFielderPtr)
b1, b2 = implIntf(rt, iszeroTyp)
bset(b1, &ti.flagIsZeroer)
bset(b2, &ti.flagIsZeroerPtr)
b1, b2 = implIntf(rt, isCodecEmptyerTyp)
bset(b1, &ti.flagIsCodecEmptyer)
bset(b2, &ti.flagIsCodecEmptyerPtr)
b1 = rt.Comparable()
bset(b1, &ti.flagComparable)
switch rk {
case reflect.Struct:
var omitEmpty bool
if f, ok := rt.FieldByName(structInfoFieldName); ok {
ti.toArray, omitEmpty, ti.keyType = parseStructInfo(x.structTag(f.Tag))
ti.infoFieldOmitempty = omitEmpty
} else {
ti.keyType = valueTypeString
}
pp, pi := &pool4tiload, pool4tiload.Get()
pv := pi.(*typeInfoLoad)
pv.reset()
pv.etypes = append(pv.etypes, ti.rtid)
x.rget(rt, rtid, omitEmpty, nil, pv)
n := ti.resolve(pv.sfis, pv.sfiNames)
ti.init(pv.sfis, n)
pp.Put(pi)
case reflect.Map:
ti.elem = rt.Elem()
ti.elemkind = uint8(ti.elem.Kind())
ti.elemsize = uint32(ti.elem.Size())
ti.key = rt.Key()
ti.keykind = uint8(ti.key.Kind())
ti.keysize = uint32(ti.key.Size())
case reflect.Slice:
ti.mbs, b2 = implIntf(rt, mapBySliceTyp)
if !ti.mbs && b2 {
ti.mbs = b2
}
ti.elem = rt.Elem()
ti.elemkind = uint8(ti.elem.Kind())
ti.elemsize = uint32(ti.elem.Size())
case reflect.Chan:
ti.elem = rt.Elem()
ti.elemkind = uint8(ti.elem.Kind())
ti.elemsize = uint32(ti.elem.Size())
ti.chandir = uint8(rt.ChanDir())
case reflect.Array:
ti.mbs, b2 = implIntf(rt, mapBySliceTyp)
if !ti.mbs && b2 {
ti.mbs = b2
}
ti.elem = rt.Elem()
ti.elemkind = uint8(ti.elem.Kind())
ti.elemsize = uint32(ti.elem.Size())
case reflect.Ptr:
ti.elem = rt.Elem()
ti.elemkind = uint8(ti.elem.Kind())
ti.elemsize = uint32(ti.elem.Size())
}
x.mu.Lock()
sp = x.infos.load()
// since this is an atomic load/store, we MUST use a different array each time,
// else we have a data race when a store is happening simultaneously with a findRtidFn call.
if sp == nil {
pti = &ti
sp = []rtid2ti{{rtid, pti}}
x.infos.store(sp)
} else {
var idx uint
idx, pti = findTypeInfo(sp, rtid)
if pti == nil {
pti = &ti
sp2 := make([]rtid2ti, len(sp)+1)
copy(sp2, sp[:idx])
copy(sp2[idx+1:], sp[idx:])
sp2[idx] = rtid2ti{rtid, pti}
x.infos.store(sp2)
}
}
x.mu.Unlock()
return
}
func (x *TypeInfos) rget(rt reflect.Type, rtid uintptr, omitEmpty bool,
path *structFieldInfoPathNode, pv *typeInfoLoad) {
// Read up fields and store how to access the value.
//
// It uses go's rules for message selectors,
// which say that the field with the shallowest depth is selected.
//
// Note: we consciously use slices, not a map, to simulate a set.
// Typically, types have < 16 fields,
// and iteration using equals is faster than maps there
flen := rt.NumField()
LOOP:
for j, jlen := uint16(0), uint16(flen); j < jlen; j++ {
f := rt.Field(int(j))
fkind := f.Type.Kind()
// skip if a func type, or is unexported, or structTag value == "-"
switch fkind {
case reflect.Func, reflect.Complex64, reflect.Complex128, reflect.UnsafePointer:
continue LOOP
}
isUnexported := f.PkgPath != ""
if isUnexported && !f.Anonymous {
continue
}
stag := x.structTag(f.Tag)
if stag == "-" {
continue
}
var si structFieldInfo
var numderef uint8 = 0
for xft := f.Type; xft.Kind() == reflect.Ptr; xft = xft.Elem() {
numderef++
}
var parsed bool
// if anonymous and no struct tag (or it's blank),
// and a struct (or pointer to struct), inline it.
if f.Anonymous && fkind != reflect.Interface {
// ^^ redundant but ok: per go spec, an embedded pointer type cannot be to an interface
ft := f.Type
isPtr := ft.Kind() == reflect.Ptr
for ft.Kind() == reflect.Ptr {
ft = ft.Elem()
}
isStruct := ft.Kind() == reflect.Struct
// Ignore embedded fields of unexported non-struct types.
// Also, from go1.10, ignore pointers to unexported struct types
// because unmarshal cannot assign a new struct to an unexported field.
// See https://golang.org/issue/21357
if (isUnexported && !isStruct) || (!allowSetUnexportedEmbeddedPtr && isUnexported && isPtr) {
continue
}
doInline := stag == ""
if !doInline {
si.parseTag(stag)
parsed = true
doInline = si.encName == "" // si.isZero()
}
if doInline && isStruct {
// if etypes contains this, don't call rget again (as fields are already seen here)
ftid := rt2id(ft)
// We cannot recurse forever, but we need to track other field depths.
// So - we break if we see a type twice (not the first time).
// This should be sufficient to handle an embedded type that refers to its
// owning type, which then refers to its embedded type.
processIt := true
numk := 0
for _, k := range pv.etypes {
if k == ftid {
numk++
if numk == rgetMaxRecursion {
processIt = false
break
}
}
}
if processIt {
pv.etypes = append(pv.etypes, ftid)
path2 := &structFieldInfoPathNode{
parent: path,
typ: f.Type,
offset: uint16(f.Offset),
index: j,
kind: uint8(fkind),
numderef: numderef,
}
x.rget(ft, ftid, omitEmpty, path2, pv)
}
continue
}
}
// after the anonymous dance: if an unexported field, skip
if isUnexported || f.Name == "" { // f.Name cannot be "", but defensively handle it
continue
}
si.path = structFieldInfoPathNode{
parent: path,
typ: f.Type,
offset: uint16(f.Offset),
index: j,
kind: uint8(fkind),
numderef: numderef,
// set asciiAlphaNum to true (default); checked and may be set to false below
encNameAsciiAlphaNum: true,
// note: omitEmpty might have been set in an earlier parseTag call, etc - so carry it forward
omitEmpty: si.path.omitEmpty,
}
if !parsed {
si.encName = f.Name
si.parseTag(stag)
parsed = true
} else if si.encName == "" {
si.encName = f.Name
}
if omitEmpty {
si.path.omitEmpty = true
}
// si.fieldName = f.Name
// si.path.encNameAsciiAlphaNum = true
for i := len(si.encName) - 1; i >= 0; i-- { // bounds-check elimination
if !asciiAlphaNumBitset.isset(si.encName[i]) {
si.path.encNameAsciiAlphaNum = false
break
}
}
pv.sfis = append(pv.sfis, si)
}
}
func implIntf(rt, iTyp reflect.Type) (base bool, indir bool) {
// return rt.Implements(iTyp), reflect.PtrTo(rt).Implements(iTyp)
// if I's method is defined on T (ie T implements I), then *T implements I.
// The converse is not true.
// Type.Implements can be expensive, as it does a simulataneous linear search across 2 lists
// with alphanumeric string comparisons.
// If we can avoid running one of these 2 calls, we should.
base = rt.Implements(iTyp)
if base {
indir = true
} else {
indir = reflect.PtrTo(rt).Implements(iTyp)
}
return
}
// isEmptyStruct is only called from isEmptyValue, and checks if a struct is empty:
// - does it implement IsZero() bool
// - is it comparable, and can i compare directly using ==
// - if checkStruct, then walk through the encodable fields
// and check if they are empty or not.
func isEmptyStruct(v reflect.Value, tinfos *TypeInfos, recursive bool) bool {
// v is a struct kind - no need to check again.
// We only check isZero on a struct kind, to reduce the amount of times
// that we lookup the rtid and typeInfo for each type as we walk the tree.
vt := rvType(v)
rtid := rt2id(vt)
if tinfos == nil {
tinfos = defTypeInfos
}
ti := tinfos.get(rtid, vt)
if ti.rtid == timeTypId {
return rv2i(v).(time.Time).IsZero()
}
if ti.flagIsZeroer {
return rv2i(v).(isZeroer).IsZero()
}
if ti.flagIsZeroerPtr && v.CanAddr() {
return rv2i(v.Addr()).(isZeroer).IsZero()
}
if ti.flagIsCodecEmptyer {
return rv2i(v).(isCodecEmptyer).IsCodecEmpty()
}
if ti.flagIsCodecEmptyerPtr && v.CanAddr() {
return rv2i(v.Addr()).(isCodecEmptyer).IsCodecEmpty()
}
if ti.flagComparable {
return rv2i(v) == rv2i(rvZeroK(vt, reflect.Struct))
}
if !recursive {
return false
}
// We only care about what we can encode/decode,
// so that is what we use to check omitEmpty.
for _, si := range ti.sfiSrc {
sfv := si.path.field(v)
if sfv.IsValid() && !isEmptyValue(sfv, tinfos, recursive) {
return false
}
}
return true
}
func panicToErr(h errDecorator, err *error) {
// Note: This method MUST be called directly from defer i.e. defer panicToErr ...
// else it seems the recover is not fully handled
if x := recover(); x != nil {
panicValToErr(h, x, err)
}
}
func isSliceBoundsError(s string) bool {
return strings.Contains(s, "index out of range") ||
strings.Contains(s, "slice bounds out of range")
}
func panicValToErr(h errDecorator, v interface{}, err *error) {
if v == *err {
return
}
switch xerr := v.(type) {
case nil:
case runtime.Error:
d, dok := h.(*Decoder)
if dok && d.bytes && isSliceBoundsError(xerr.Error()) {
*err = io.EOF
} else {
h.wrapErr(xerr, err)
}
case error:
switch xerr {
case nil:
case io.EOF, io.ErrUnexpectedEOF, errEncoderNotInitialized, errDecoderNotInitialized:
// treat as special (bubble up)
*err = xerr
default:
h.wrapErr(xerr, err)
}
default:
// we don't expect this to happen (as this library always panics with an error)
h.wrapErr(fmt.Errorf("%v", v), err)
}
}
func isImmutableKind(k reflect.Kind) (v bool) {
return scalarBitset.isset(byte(k))
}
func usableByteSlice(bs []byte, slen int) (out []byte, changed bool) {
if slen <= 0 {
return []byte{}, true
}
if cap(bs) < slen {
return make([]byte, slen), true
}
return bs[:slen], false
}
// func notNilBytes(v []byte) []byte {
// if v == nil {
// return []byte{}
// }
// return v
// }
// ----
type codecFnInfo struct {
ti *typeInfo
xfFn Ext
xfTag uint64
seq seqType
addrD bool
addrDf bool // force: if addrD, then decode function MUST take a ptr
addrE bool
addrEf bool // force: if addrE, then encode function MUST take a ptr
}
// codecFn encapsulates the captured variables and the encode function.
// This way, we only do some calculations one times, and pass to the
// code block that should be called (encapsulated in a function)
// instead of executing the checks every time.
type codecFn struct {
i codecFnInfo
fe func(*Encoder, *codecFnInfo, reflect.Value)
fd func(*Decoder, *codecFnInfo, reflect.Value)
_ [1]uint64 // padding (cache-aligned)
}
type codecRtidFn struct {
rtid uintptr
fn *codecFn
}
func makeExt(ext interface{}) Ext {
if ext == nil {
return &extFailWrapper{}
}
switch t := ext.(type) {
case nil:
return &extFailWrapper{}
case Ext:
return t
case BytesExt:
return &bytesExtWrapper{BytesExt: t}
case InterfaceExt:
return &interfaceExtWrapper{InterfaceExt: t}
}
return &extFailWrapper{}
}
func baseRV(v interface{}) (rv reflect.Value) {
for rv = rv4i(v); rv.Kind() == reflect.Ptr; rv = rv.Elem() {
}
return
}
// ----
// these "checkOverflow" functions must be inlinable, and not call anybody.
// Overflow means that the value cannot be represented without wrapping/overflow.
// Overflow=false does not mean that the value can be represented without losing precision
// (especially for floating point).
type checkOverflow struct{}
func (checkOverflow) Float32(v float64) (overflow bool) {
if v < 0 {
v = -v
}
return math.MaxFloat32 < v && v <= math.MaxFloat64
}
func (checkOverflow) Uint(v uint64, bitsize uint8) (overflow bool) {
if v != 0 && v != (v<<(64-bitsize))>>(64-bitsize) {
overflow = true
}
return
}
func (checkOverflow) Int(v int64, bitsize uint8) (overflow bool) {
if v != 0 && v != (v<<(64-bitsize))>>(64-bitsize) {
overflow = true
}
return
}
func (checkOverflow) Uint2Int(v uint64, neg bool) (overflow bool) {
return (neg && v > 1<<63) || (!neg && v >= 1<<63)
}
func (checkOverflow) SignedInt(v uint64) (overflow bool) {
//e.g. -127 to 128 for int8
pos := (v >> 63) == 0
ui2 := v & 0x7fffffffffffffff
if pos {
if ui2 > math.MaxInt64 {
overflow = true
}
} else {
if ui2 > math.MaxInt64-1 {
overflow = true
}
}
return
}
func (x checkOverflow) Float32V(v float64) float64 {
if x.Float32(v) {
halt.errorf("float32 overflow: %v", v)
}
return v
}
func (x checkOverflow) UintV(v uint64, bitsize uint8) uint64 {
if x.Uint(v, bitsize) {
halt.errorf("uint64 overflow: %v", v)
}
return v
}
func (x checkOverflow) IntV(v int64, bitsize uint8) int64 {
if x.Int(v, bitsize) {
halt.errorf("int64 overflow: %v", v)
}
return v
}
func (x checkOverflow) SignedIntV(v uint64) int64 {
if x.SignedInt(v) {
halt.errorf("uint64 to int64 overflow: %v", v)
}
return int64(v)
}
// ------------------ FLOATING POINT -----------------
func isNaN64(f float64) bool { return f != f }
func isWhitespaceChar(v byte) bool {
// these are in order of speed below ...
return v < 33
// return v < 33 && whitespaceCharBitset64.isset(v)
// return v < 33 && (v == ' ' || v == '\n' || v == '\t' || v == '\r')
// return v == ' ' || v == '\n' || v == '\t' || v == '\r'
// return whitespaceCharBitset.isset(v)
}
func isNumberChar(v byte) bool {
// these are in order of speed below ...
return numCharBitset.isset(v)
// return v < 64 && numCharNoExpBitset64.isset(v) || v == 'e' || v == 'E'
// return v > 42 && v < 102 && numCharWithExpBitset64.isset(v-42)
}
// func isDigitChar(v byte) bool {
// // these are in order of speed below ...
// return digitCharBitset.isset(v)
// // return v >= '0' && v <= '9'
// }
// -----------------------
type ioFlusher interface {
Flush() error
}
// type ioPeeker interface {
// Peek(int) ([]byte, error)
// }
type ioBuffered interface {
Buffered() int
}
// -----------------------
type sfiRv struct {
v *structFieldInfo
r reflect.Value
}
// ------
// bitset types are better than [256]bool, because they permit the whole
// bitset array being on a single cache line and use less memory.
//
// Also, since pos is a byte (0-255), there's no bounds checks on indexing (cheap).
//
// We previously had bitset128 [16]byte, and bitset32 [4]byte, but those introduces
// bounds checking, so we discarded them, and everyone uses bitset256.
//
// given x > 0 and n > 0 and x is exactly 2^n, then pos/x === pos>>n AND pos%x === pos&(x-1).
// consequently, pos/32 === pos>>5, pos/16 === pos>>4, pos/8 === pos>>3, pos%8 == pos&7
//
// Note that using >> or & is faster than using / or %, as division is quite expensive if not optimized.
// MARKER:
// We noticed a little performance degradation when using bitset256 as [32]byte (or bitset32 as uint32).
// For example, json encoding went from 188K ns/op to 168K ns/op (~ 10% reduction).
// Consequently, we are using a [NNN]bool for bitsetNNN.
// To eliminate bounds-checking, we use x % v as that is guaranteed to be within bounds.
// ----
type bitset32 [32]bool
func (x *bitset32) set(pos byte) *bitset32 {
x[pos&31] = true // x[pos%32] = true
return x
}
func (x *bitset32) isset(pos byte) bool {
return x[pos&31] // x[pos%32]
}
// type bitset64 [64]bool
// func (x *bitset64) set(pos byte) *bitset64 {
// x[pos%64] = true
// return x
// }
// func (x *bitset64) isset(pos byte) bool {
// return x[pos%64]
// }
type bitset256 [256]bool
func (x *bitset256) set(pos byte) *bitset256 {
x[pos] = true
return x
}
func (x *bitset256) isset(pos byte) bool {
return x[pos]
}
// ----
// type bitset32 uint32
// func (x *bitset32) set(pos byte) *bitset32 {
// *x = *x | (1 << pos)
// return x
// }
// func (x bitset32) isset(pos byte) bool {
// return uint32(x)&(1<<pos) != 0
// }
// type bitset64 uint64
// func (x *bitset64) set(pos byte) *bitset64 {
// *x = *x | (1 << pos)
// return x
// }
// func (x bitset64) isset(pos byte) bool {
// return uint64(x)&(1<<pos) != 0
// }
// type bitset256 [32]byte
// func (x *bitset256) set(pos byte) *bitset256 {
// x[pos>>3] |= (1 << (pos & 7))
// return x
// }
// func (x *bitset256) check(pos byte) uint8 {
// return x[pos>>3] & (1 << (pos & 7))
// }
// func (x *bitset256) isset(pos byte) bool {
// return x.check(pos) != 0
// // return x[pos>>3]&(1<<(pos&7)) != 0
// }
// ------------
type panicHdl struct{}
// errorv will panic if err is defined (not nil)
func (panicHdl) onerror(err error) {
if err != nil {
panic(err)
}
}
// errorf will always panic, using the parameters passed.
//go:noinline
func (panicHdl) errorf(format string, params ...interface{}) {
if format == "" {
panic(errPanicUndefined)
}
if len(params) == 0 {
panic(errors.New(format))
}
panic(fmt.Errorf(format, params...))
}
// ----------------------------------------------------
type errDecorator interface {
wrapErr(in error, out *error)
}
type errDecoratorDef struct{}
func (errDecoratorDef) wrapErr(v error, e *error) { *e = v }
// ----------------------------------------------------
type mustHdl struct{}
func (mustHdl) String(s string, err error) string {
halt.onerror(err)
return s
}
func (mustHdl) Int(s int64, err error) int64 {
halt.onerror(err)
return s
}
func (mustHdl) Uint(s uint64, err error) uint64 {
halt.onerror(err)
return s
}
func (mustHdl) Float(s float64, err error) float64 {
halt.onerror(err)
return s
}
// -------------------
func freelistCapacity(length int) (capacity int) {
for capacity = 8; capacity <= length; capacity *= 2 {
}
return
}
// bytesFreelist is a list of byte buffers, sorted by cap.
//
// In anecdotal testing (running go test -tsd 1..6), we couldn't get
// the length ofthe list > 4 at any time. So we believe a linear search
// without bounds checking is sufficient.
type bytesFreelist [][]byte
// return a slice of possibly non-zero'ed bytes, with len=0,
// and with cap >= length requested.
func (x *bytesFreelist) get(length int) (out []byte) {
if bytesFreeListNoCache {
return make([]byte, 0, freelistCapacity(length))
}
y := *x
for i, v := range y {
if cap(v) >= length {
// *x = append(y[:i], y[i+1:]...)
copy(y[i:], y[i+1:])
*x = y[:len(y)-1]
return v
}
}
return make([]byte, 0, freelistCapacity(length))
}
func (x *bytesFreelist) put(v []byte) {
if bytesFreeListNoCache || cap(v) == 0 {
return
}
if len(v) != 0 {
v = v[:0]
}
// append the new value, then try to put it in a better position
y := append(*x, v)
*x = y
for i, z := range y[:len(y)-1] {
if cap(z) > cap(v) {
copy(y[i+1:], y[i:])
y[i] = v
return
}
}
}
func (x *bytesFreelist) check(v []byte, length int) (out []byte) {
if cap(v) >= length {
return v[:0]
}
x.put(v)
return x.get(length)
}
// -------------------------
// sfiRvFreelist is used by Encoder for encoding structs,
// where we have to gather the fields first and then
// analyze them for omitEmpty, before knowing the length of the array/map to encode.
//
// Typically, the length here will depend on the number of cycles e.g.
// if type T1 has reference to T1, or T1 has reference to type T2 which has reference to T1.
//
// In the general case, the length of this list at most times is 1,
// so linear search is fine.
type sfiRvFreelist [][]sfiRv
func (x *sfiRvFreelist) get(length int) (out []sfiRv) {
y := *x
for i, v := range y {
if cap(v) >= length {
// *x = append(y[:i], y[i+1:]...)
copy(y[i:], y[i+1:])
*x = y[:len(y)-1]
return v
}
}
return make([]sfiRv, 0, freelistCapacity(length))
}
func (x *sfiRvFreelist) put(v []sfiRv) {
if len(v) != 0 {
v = v[:0]
}
// append the new value, then try to put it in a better position
y := append(*x, v)
*x = y
for i, z := range y[:len(y)-1] {
if cap(z) > cap(v) {
copy(y[i+1:], y[i:])
y[i] = v
return
}
}
}
// ---- multiple interner implementations ----
// Hard to tell which is most performant:
// - use a map[string]string - worst perf, no collisions, and unlimited entries
// - use a linear search with move to front heuristics - no collisions, and maxed at 64 entries
// - use a computationally-intensive hash - best performance, some collisions, maxed at 64 entries
const (
internMaxStrLen = 16 // if more than 16 bytes, faster to copy than compare bytes
internCap = 64 * 2 // 64 uses 1K bytes RAM, so 128 (anecdotal sweet spot) uses 2K bytes
)
type internerMap map[string]string
func (x *internerMap) init() {
*x = make(map[string]string, internCap)
}
func (x internerMap) string(v []byte) (s string) {
s, ok := x[string(v)] // no allocation here, per go implementation
if !ok {
s = string(v) // new allocation here
x[s] = s
}
return
}
/*
type internerHash struct {
v *[internCap]string
}
func (x *internerHash) init() {
var v [internCap]string
x.v = &v
}
func (x *internerHash) string(v []byte) (s string) {
h := hashShortString(v) % internCap
s = x.v[h]
if s != string(v) {
s = string(v)
x.v[h] = s
}
return
}
type internerLinearSearch struct {
v *[internCap]string
}
func (x *internerLinearSearch) init() {
var v [internCap]string
x.v = &v
}
func (x *internerLinearSearch) string(v []byte) (s string) {
// MARKER: should we move to front, given that we typically might see the field names in sequence?
// if most values are encoded in sequence based on field names, then moving is busy work.
// Howeer, if most values are accessed randomly, then moving has advantages.
const moveToFront = true
var i int
for i, s = range x.v {
if s == "" {
s = string(v)
x.v[i] = s
goto END
}
if s == string(v) {
goto END
}
}
s = string(v)
END:
if moveToFront && i > 0 {
copy(x.v[1:], x.v[:i])
x.v[0] = s
}
return s
}
*/