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buildx/vendor/google.golang.org/protobuf/internal/impl/legacy_enum.go
Jonathan A. Sternberg b35a0f4718
protobuf: remove gogoproto 
Removes gogo/protobuf from buildx and updates to a version of
moby/buildkit where gogo is removed.

This also changes how the proto files are generated. This is because
newer versions of protobuf are more strict about name conflicts. If two
files have the same name (even if they are relative paths) and are used
in different protoc commands, they'll conflict in the registry.

Since protobuf file generation doesn't work very well with
`paths=source_relative`, this removes the `go:generate` expression and
just relies on the dockerfile to perform the generation.

Signed-off-by: Jonathan A. Sternberg <jonathan.sternberg@docker.com>
2024-10-02 15:51:59 -05:00

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// Copyright 2018 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package impl
import (
"fmt"
"reflect"
"strings"
"sync"
"google.golang.org/protobuf/internal/filedesc"
"google.golang.org/protobuf/internal/strs"
"google.golang.org/protobuf/reflect/protoreflect"
)
// legacyEnumName returns the name of enums used in legacy code.
// It is neither the protobuf full name nor the qualified Go name,
// but rather an odd hybrid of both.
func legacyEnumName(ed protoreflect.EnumDescriptor) string {
var protoPkg string
enumName := string(ed.FullName())
if fd := ed.ParentFile(); fd != nil {
protoPkg = string(fd.Package())
enumName = strings.TrimPrefix(enumName, protoPkg+".")
}
if protoPkg == "" {
return strs.GoCamelCase(enumName)
}
return protoPkg + "." + strs.GoCamelCase(enumName)
}
// legacyWrapEnum wraps v as a protoreflect.Enum,
// where v must be a int32 kind and not implement the v2 API already.
func legacyWrapEnum(v reflect.Value) protoreflect.Enum {
et := legacyLoadEnumType(v.Type())
return et.New(protoreflect.EnumNumber(v.Int()))
}
var legacyEnumTypeCache sync.Map // map[reflect.Type]protoreflect.EnumType
// legacyLoadEnumType dynamically loads a protoreflect.EnumType for t,
// where t must be an int32 kind and not implement the v2 API already.
func legacyLoadEnumType(t reflect.Type) protoreflect.EnumType {
// Fast-path: check if a EnumType is cached for this concrete type.
if et, ok := legacyEnumTypeCache.Load(t); ok {
return et.(protoreflect.EnumType)
}
// Slow-path: derive enum descriptor and initialize EnumType.
var et protoreflect.EnumType
ed := LegacyLoadEnumDesc(t)
et = &legacyEnumType{
desc: ed,
goType: t,
}
if et, ok := legacyEnumTypeCache.LoadOrStore(t, et); ok {
return et.(protoreflect.EnumType)
}
return et
}
type legacyEnumType struct {
desc protoreflect.EnumDescriptor
goType reflect.Type
m sync.Map // map[protoreflect.EnumNumber]proto.Enum
}
func (t *legacyEnumType) New(n protoreflect.EnumNumber) protoreflect.Enum {
if e, ok := t.m.Load(n); ok {
return e.(protoreflect.Enum)
}
e := &legacyEnumWrapper{num: n, pbTyp: t, goTyp: t.goType}
t.m.Store(n, e)
return e
}
func (t *legacyEnumType) Descriptor() protoreflect.EnumDescriptor {
return t.desc
}
type legacyEnumWrapper struct {
num protoreflect.EnumNumber
pbTyp protoreflect.EnumType
goTyp reflect.Type
}
func (e *legacyEnumWrapper) Descriptor() protoreflect.EnumDescriptor {
return e.pbTyp.Descriptor()
}
func (e *legacyEnumWrapper) Type() protoreflect.EnumType {
return e.pbTyp
}
func (e *legacyEnumWrapper) Number() protoreflect.EnumNumber {
return e.num
}
func (e *legacyEnumWrapper) ProtoReflect() protoreflect.Enum {
return e
}
func (e *legacyEnumWrapper) protoUnwrap() interface{} {
v := reflect.New(e.goTyp).Elem()
v.SetInt(int64(e.num))
return v.Interface()
}
var (
_ protoreflect.Enum = (*legacyEnumWrapper)(nil)
_ unwrapper = (*legacyEnumWrapper)(nil)
)
var legacyEnumDescCache sync.Map // map[reflect.Type]protoreflect.EnumDescriptor
// LegacyLoadEnumDesc returns an EnumDescriptor derived from the Go type,
// which must be an int32 kind and not implement the v2 API already.
//
// This is exported for testing purposes.
func LegacyLoadEnumDesc(t reflect.Type) protoreflect.EnumDescriptor {
// Fast-path: check if an EnumDescriptor is cached for this concrete type.
if ed, ok := legacyEnumDescCache.Load(t); ok {
return ed.(protoreflect.EnumDescriptor)
}
// Slow-path: initialize EnumDescriptor from the raw descriptor.
ev := reflect.Zero(t).Interface()
if _, ok := ev.(protoreflect.Enum); ok {
panic(fmt.Sprintf("%v already implements proto.Enum", t))
}
edV1, ok := ev.(enumV1)
if !ok {
return aberrantLoadEnumDesc(t)
}
b, idxs := edV1.EnumDescriptor()
var ed protoreflect.EnumDescriptor
if len(idxs) == 1 {
ed = legacyLoadFileDesc(b).Enums().Get(idxs[0])
} else {
md := legacyLoadFileDesc(b).Messages().Get(idxs[0])
for _, i := range idxs[1 : len(idxs)-1] {
md = md.Messages().Get(i)
}
ed = md.Enums().Get(idxs[len(idxs)-1])
}
if ed, ok := legacyEnumDescCache.LoadOrStore(t, ed); ok {
return ed.(protoreflect.EnumDescriptor)
}
return ed
}
var aberrantEnumDescCache sync.Map // map[reflect.Type]protoreflect.EnumDescriptor
// aberrantLoadEnumDesc returns an EnumDescriptor derived from the Go type,
// which must not implement protoreflect.Enum or enumV1.
//
// If the type does not implement enumV1, then there is no reliable
// way to derive the original protobuf type information.
// We are unable to use the global enum registry since it is
// unfortunately keyed by the protobuf full name, which we also do not know.
// Thus, this produces some bogus enum descriptor based on the Go type name.
func aberrantLoadEnumDesc(t reflect.Type) protoreflect.EnumDescriptor {
// Fast-path: check if an EnumDescriptor is cached for this concrete type.
if ed, ok := aberrantEnumDescCache.Load(t); ok {
return ed.(protoreflect.EnumDescriptor)
}
// Slow-path: construct a bogus, but unique EnumDescriptor.
ed := &filedesc.Enum{L2: new(filedesc.EnumL2)}
ed.L0.FullName = AberrantDeriveFullName(t) // e.g., github_com.user.repo.MyEnum
ed.L0.ParentFile = filedesc.SurrogateProto3
ed.L1.EditionFeatures = ed.L0.ParentFile.L1.EditionFeatures
ed.L2.Values.List = append(ed.L2.Values.List, filedesc.EnumValue{})
// TODO: Use the presence of a UnmarshalJSON method to determine proto2?
vd := &ed.L2.Values.List[0]
vd.L0.FullName = ed.L0.FullName + "_UNKNOWN" // e.g., github_com.user.repo.MyEnum_UNKNOWN
vd.L0.ParentFile = ed.L0.ParentFile
vd.L0.Parent = ed
// TODO: We could use the String method to obtain some enum value names by
// starting at 0 and print the enum until it produces invalid identifiers.
// An exhaustive query is clearly impractical, but can be best-effort.
if ed, ok := aberrantEnumDescCache.LoadOrStore(t, ed); ok {
return ed.(protoreflect.EnumDescriptor)
}
return ed
}
// AberrantDeriveFullName derives a fully qualified protobuf name for the given Go type
// The provided name is not guaranteed to be stable nor universally unique.
// It should be sufficiently unique within a program.
//
// This is exported for testing purposes.
func AberrantDeriveFullName(t reflect.Type) protoreflect.FullName {
sanitize := func(r rune) rune {
switch {
case r == '/':
return '.'
case 'a' <= r && r <= 'z', 'A' <= r && r <= 'Z', '0' <= r && r <= '9':
return r
default:
return '_'
}
}
prefix := strings.Map(sanitize, t.PkgPath())
suffix := strings.Map(sanitize, t.Name())
if suffix == "" {
suffix = fmt.Sprintf("UnknownX%X", reflect.ValueOf(t).Pointer())
}
ss := append(strings.Split(prefix, "."), suffix)
for i, s := range ss {
if s == "" || ('0' <= s[0] && s[0] <= '9') {
ss[i] = "x" + s
}
}
return protoreflect.FullName(strings.Join(ss, "."))
}
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