protobuf-go/reflect/protopath/step.go

// Copyright 2020 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 protopath

import (
	"fmt"
	"strconv"
	"strings"

	"google.golang.org/protobuf/internal/encoding/text"
	"google.golang.org/protobuf/reflect/protoreflect"
)

// StepKind identifies the kind of step operation.
// Each kind of step corresponds with some protobuf reflection operation.
type StepKind int

const (
	invalidStep StepKind = iota
	// RootStep identifies a step as the Root step operation.
	RootStep
	// FieldAccessStep identifies a step as the FieldAccess step operation.
	FieldAccessStep
	// UnknownAccessStep identifies a step as the UnknownAccess step operation.
	UnknownAccessStep
	// ListIndexStep identifies a step as the ListIndex step operation.
	ListIndexStep
	// MapIndexStep identifies a step as the MapIndex step operation.
	MapIndexStep
	// AnyExpandStep identifies a step as the AnyExpand step operation.
	AnyExpandStep
)

func (k StepKind) String() string {
	switch k {
	case invalidStep:
		return "<invalid>"
	case RootStep:
		return "Root"
	case FieldAccessStep:
		return "FieldAccess"
	case UnknownAccessStep:
		return "UnknownAccess"
	case ListIndexStep:
		return "ListIndex"
	case MapIndexStep:
		return "MapIndex"
	case AnyExpandStep:
		return "AnyExpand"
	default:
		return fmt.Sprintf("<unknown:%d>", k)
	}
}

// Step is a union where only one step operation may be specified at a time.
// The different kinds of steps are specified by the constants defined for
// the StepKind type.
type Step struct {
	kind StepKind
	desc protoreflect.Descriptor
	key  protoreflect.Value
}

// Root indicates the root message that a path is relative to.
// It should always (and only ever) be the first step in a path.
func Root(md protoreflect.MessageDescriptor) Step {
	if md == nil {
		panic("nil message descriptor")
	}
	return Step{kind: RootStep, desc: md}
}

// FieldAccess describes access of a field within a message.
// Extension field accesses are also represented using a FieldAccess and
// must be provided with a protoreflect.FieldDescriptor
//
// Within the context of Values,
// the type of the previous step value is always a message, and
// the type of the current step value is determined by the field descriptor.
func FieldAccess(fd protoreflect.FieldDescriptor) Step {
	if fd == nil {
		panic("nil field descriptor")
	} else if _, ok := fd.(protoreflect.ExtensionTypeDescriptor); !ok && fd.IsExtension() {
		panic(fmt.Sprintf("extension field %q must implement protoreflect.ExtensionTypeDescriptor", fd.FullName()))
	}
	return Step{kind: FieldAccessStep, desc: fd}
}

// UnknownAccess describes access to the unknown fields within a message.
//
// Within the context of Values,
// the type of the previous step value is always a message, and
// the type of the current step value is always a bytes type.
func UnknownAccess() Step {
	return Step{kind: UnknownAccessStep}
}

// ListIndex describes index of an element within a list.
//
// Within the context of Values,
// the type of the previous, previous step value is always a message,
// the type of the previous step value is always a list, and
// the type of the current step value is determined by the field descriptor.
func ListIndex(i int) Step {
	if i < 0 {
		panic(fmt.Sprintf("invalid list index: %v", i))
	}
	return Step{kind: ListIndexStep, key: protoreflect.ValueOfInt64(int64(i))}
}

// MapIndex describes index of an entry within a map.
// The key type is determined by field descriptor that the map belongs to.
//
// Within the context of Values,
// the type of the previous previous step value is always a message,
// the type of the previous step value is always a map, and
// the type of the current step value is determined by the field descriptor.
func MapIndex(k protoreflect.MapKey) Step {
	if !k.IsValid() {
		panic("invalid map index")
	}
	return Step{kind: MapIndexStep, key: k.Value()}
}

// AnyExpand describes expansion of a google.protobuf.Any message into
// a structured representation of the underlying message.
//
// Within the context of Values,
// the type of the previous step value is always a google.protobuf.Any message, and
// the type of the current step value is always a message.
func AnyExpand(md protoreflect.MessageDescriptor) Step {
	if md == nil {
		panic("nil message descriptor")
	}
	return Step{kind: AnyExpandStep, desc: md}
}

// MessageDescriptor returns the message descriptor for Root or AnyExpand steps,
// otherwise it returns nil.
func (s Step) MessageDescriptor() protoreflect.MessageDescriptor {
	switch s.kind {
	case RootStep, AnyExpandStep:
		return s.desc.(protoreflect.MessageDescriptor)
	default:
		return nil
	}
}

// FieldDescriptor returns the field descriptor for FieldAccess steps,
// otherwise it returns nil.
func (s Step) FieldDescriptor() protoreflect.FieldDescriptor {
	switch s.kind {
	case FieldAccessStep:
		return s.desc.(protoreflect.FieldDescriptor)
	default:
		return nil
	}
}

// ListIndex returns the list index for ListIndex steps,
// otherwise it returns 0.
func (s Step) ListIndex() int {
	switch s.kind {
	case ListIndexStep:
		return int(s.key.Int())
	default:
		return 0
	}
}

// MapIndex returns the map key for MapIndex steps,
// otherwise it returns an invalid map key.
func (s Step) MapIndex() protoreflect.MapKey {
	switch s.kind {
	case MapIndexStep:
		return s.key.MapKey()
	default:
		return protoreflect.MapKey{}
	}
}

// Kind reports which kind of step this is.
func (s Step) Kind() StepKind {
	return s.kind
}

func (s Step) String() string {
	return string(s.appendString(nil))
}

func (s Step) appendString(b []byte) []byte {
	switch s.kind {
	case RootStep:
		b = append(b, '(')
		b = append(b, s.desc.FullName()...)
		b = append(b, ')')
	case FieldAccessStep:
		b = append(b, '.')
		if fd := s.desc.(protoreflect.FieldDescriptor); fd.IsExtension() {
			b = append(b, '(')
			b = append(b, strings.Trim(fd.TextName(), "[]")...)
			b = append(b, ')')
		} else {
			b = append(b, fd.TextName()...)
		}
	case UnknownAccessStep:
		b = append(b, '.')
		b = append(b, '?')
	case ListIndexStep:
		b = append(b, '[')
		b = strconv.AppendInt(b, s.key.Int(), 10)
		b = append(b, ']')
	case MapIndexStep:
		b = append(b, '[')
		switch k := s.key.Interface().(type) {
		case bool:
			b = strconv.AppendBool(b, bool(k)) // e.g., "true" or "false"
		case int32:
			b = strconv.AppendInt(b, int64(k), 10) // e.g., "-32"
		case int64:
			b = strconv.AppendInt(b, int64(k), 10) // e.g., "-64"
		case uint32:
			b = strconv.AppendUint(b, uint64(k), 10) // e.g., "32"
		case uint64:
			b = strconv.AppendUint(b, uint64(k), 10) // e.g., "64"
		case string:
			b = text.AppendString(b, k) // e.g., `"hello, world"`
		}
		b = append(b, ']')
	case AnyExpandStep:
		b = append(b, '.')
		b = append(b, '(')
		b = append(b, s.desc.FullName()...)
		b = append(b, ')')
	default:
		b = append(b, "<invalid>"...)
	}
	return b
}
reflect: add protopath and protorange packages The protopath package provides a means to programmatically represent a sequence of protobuf reflection operations. The protorange package traverses through a message and calls a user-provided function as it iterates. This feature sets the groundwork for the often requested feature of being able to exclude certain fields when merging or serializing. package protopath type Path []Step type Step struct{ ... } func Root(protoreflect.MessageDescriptor) Step func FieldAccess(protoreflect.FieldDescriptor) Step func UnknownAccess() Step func ListIndex(int) Step func MapIndex(protoreflect.MapKey) Step func AnyExpand(protoreflect.MessageDescriptor) Step func (Step) Kind() StepKind func (Step) FieldDescriptor() protoreflect.FieldDescriptor func (Step) MessageDescriptor() protoreflect.MessageDescriptor func (Step) ListIndex() int func (Step) MapIndex() protoreflect.MapKey func (Step) String() string type StepKind int const RootStep StepKind const FieldAccessStep StepKind const UnknownAccessStep StepKind const ListIndexStep StepKind const MapIndexStep StepKind const AnyExpandStep StepKind type Values struct { Path Path Values []protoreflect.Value } func (Values) Index(int) (out struct{ ... }) func (Values) Len() int func (Values) String() string package protorange var Break error var Terminate error func Range(protoreflect.Message, func(protopath.Values) error) error type Options struct { Stable bool Resolver interface { ... } } func (Options) Range(m protoreflect.Message, push, pop func(protopath.Values) error) error Change-Id: I29cbd5142fe169d78367d54a95d37801888b64f4 Reviewed-on: https://go-review.googlesource.com/c/protobuf/+/236540 Trust: Joe Tsai <joetsai@digital-static.net> Reviewed-by: Damien Neil <dneil@google.com> 2020-05-12 00:47:32 +00:00			`// Copyright 2020 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 protopath`

			`import (`
			`"fmt"`
			`"strconv"`
			`"strings"`

			`"google.golang.org/protobuf/internal/encoding/text"`
			`"google.golang.org/protobuf/reflect/protoreflect"`
			`)`

			`// StepKind identifies the kind of step operation.`
			`// Each kind of step corresponds with some protobuf reflection operation.`
			`type StepKind int`

			`const (`
			`invalidStep StepKind = iota`
			`// RootStep identifies a step as the Root step operation.`
			`RootStep`
			`// FieldAccessStep identifies a step as the FieldAccess step operation.`
			`FieldAccessStep`
			`// UnknownAccessStep identifies a step as the UnknownAccess step operation.`
			`UnknownAccessStep`
			`// ListIndexStep identifies a step as the ListIndex step operation.`
			`ListIndexStep`
			`// MapIndexStep identifies a step as the MapIndex step operation.`
			`MapIndexStep`
			`// AnyExpandStep identifies a step as the AnyExpand step operation.`
			`AnyExpandStep`
			`)`

			`func (k StepKind) String() string {`
			`switch k {`
			`case invalidStep:`
			`return "<invalid>"`
			`case RootStep:`
			`return "Root"`
			`case FieldAccessStep:`
			`return "FieldAccess"`
			`case UnknownAccessStep:`
			`return "UnknownAccess"`
			`case ListIndexStep:`
			`return "ListIndex"`
			`case MapIndexStep:`
			`return "MapIndex"`
			`case AnyExpandStep:`
			`return "AnyExpand"`
			`default:`
			`return fmt.Sprintf("<unknown:%d>", k)`
			`}`
			`}`

			`// Step is a union where only one step operation may be specified at a time.`
			`// The different kinds of steps are specified by the constants defined for`
			`// the StepKind type.`
			`type Step struct {`
			`kind StepKind`
			`desc protoreflect.Descriptor`
			`key protoreflect.Value`
			`}`

			`// Root indicates the root message that a path is relative to.`
			`// It should always (and only ever) be the first step in a path.`
			`func Root(md protoreflect.MessageDescriptor) Step {`
			`if md == nil {`
			`panic("nil message descriptor")`
			`}`
			`return Step{kind: RootStep, desc: md}`
			`}`

			`// FieldAccess describes access of a field within a message.`
			`// Extension field accesses are also represented using a FieldAccess and`
			`// must be provided with a protoreflect.FieldDescriptor`
			`//`
			`// Within the context of Values,`
			`// the type of the previous step value is always a message, and`
			`// the type of the current step value is determined by the field descriptor.`
			`func FieldAccess(fd protoreflect.FieldDescriptor) Step {`
			`if fd == nil {`
			`panic("nil field descriptor")`
			`} else if _, ok := fd.(protoreflect.ExtensionTypeDescriptor); !ok && fd.IsExtension() {`
			`panic(fmt.Sprintf("extension field %q must implement protoreflect.ExtensionTypeDescriptor", fd.FullName()))`
			`}`
			`return Step{kind: FieldAccessStep, desc: fd}`
			`}`

			`// UnknownAccess describes access to the unknown fields within a message.`
			`//`
			`// Within the context of Values,`
			`// the type of the previous step value is always a message, and`
			`// the type of the current step value is always a bytes type.`
			`func UnknownAccess() Step {`
			`return Step{kind: UnknownAccessStep}`
			`}`

			`// ListIndex describes index of an element within a list.`
			`//`
			`// Within the context of Values,`
			`// the type of the previous, previous step value is always a message,`
			`// the type of the previous step value is always a list, and`
			`// the type of the current step value is determined by the field descriptor.`
			`func ListIndex(i int) Step {`
			`if i < 0 {`
			`panic(fmt.Sprintf("invalid list index: %v", i))`
			`}`
			`return Step{kind: ListIndexStep, key: protoreflect.ValueOfInt64(int64(i))}`
			`}`

			`// MapIndex describes index of an entry within a map.`
			`// The key type is determined by field descriptor that the map belongs to.`
			`//`
			`// Within the context of Values,`
			`// the type of the previous previous step value is always a message,`
			`// the type of the previous step value is always a map, and`
			`// the type of the current step value is determined by the field descriptor.`
			`func MapIndex(k protoreflect.MapKey) Step {`
			`if !k.IsValid() {`
			`panic("invalid map index")`
			`}`
			`return Step{kind: MapIndexStep, key: k.Value()}`
			`}`

			`// AnyExpand describes expansion of a google.protobuf.Any message into`
			`// a structured representation of the underlying message.`
			`//`
			`// Within the context of Values,`
			`// the type of the previous step value is always a google.protobuf.Any message, and`
			`// the type of the current step value is always a message.`
			`func AnyExpand(md protoreflect.MessageDescriptor) Step {`
			`if md == nil {`
			`panic("nil message descriptor")`
			`}`
			`return Step{kind: AnyExpandStep, desc: md}`
			`}`

			`// MessageDescriptor returns the message descriptor for Root or AnyExpand steps,`
			`// otherwise it returns nil.`
			`func (s Step) MessageDescriptor() protoreflect.MessageDescriptor {`
			`switch s.kind {`
			`case RootStep, AnyExpandStep:`
			`return s.desc.(protoreflect.MessageDescriptor)`
			`default:`
			`return nil`
			`}`
			`}`

			`// FieldDescriptor returns the field descriptor for FieldAccess steps,`
			`// otherwise it returns nil.`
			`func (s Step) FieldDescriptor() protoreflect.FieldDescriptor {`
			`switch s.kind {`
			`case FieldAccessStep:`
			`return s.desc.(protoreflect.FieldDescriptor)`
			`default:`
			`return nil`
			`}`
			`}`

			`// ListIndex returns the list index for ListIndex steps,`
			`// otherwise it returns 0.`
			`func (s Step) ListIndex() int {`
			`switch s.kind {`
			`case ListIndexStep:`
			`return int(s.key.Int())`
			`default:`
			`return 0`
			`}`
			`}`

			`// MapIndex returns the map key for MapIndex steps,`
			`// otherwise it returns an invalid map key.`
			`func (s Step) MapIndex() protoreflect.MapKey {`
			`switch s.kind {`
			`case MapIndexStep:`
			`return s.key.MapKey()`
			`default:`
			`return protoreflect.MapKey{}`
			`}`
			`}`

			`// Kind reports which kind of step this is.`
			`func (s Step) Kind() StepKind {`
			`return s.kind`
			`}`

			`func (s Step) String() string {`
			`return string(s.appendString(nil))`
			`}`

			`func (s Step) appendString(b []byte) []byte {`
			`switch s.kind {`
			`case RootStep:`
			`b = append(b, '(')`
			`b = append(b, s.desc.FullName()...)`
			`b = append(b, ')')`
			`case FieldAccessStep:`
			`b = append(b, '.')`
			`if fd := s.desc.(protoreflect.FieldDescriptor); fd.IsExtension() {`
			`b = append(b, '(')`
			`b = append(b, strings.Trim(fd.TextName(), "[]")...)`
			`b = append(b, ')')`
			`} else {`
			`b = append(b, fd.TextName()...)`
			`}`
			`case UnknownAccessStep:`
			`b = append(b, '.')`
			`b = append(b, '?')`
			`case ListIndexStep:`
			`b = append(b, '[')`
			`b = strconv.AppendInt(b, s.key.Int(), 10)`
			`b = append(b, ']')`
			`case MapIndexStep:`
			`b = append(b, '[')`
			`switch k := s.key.Interface().(type) {`
			`case bool:`
			`b = strconv.AppendBool(b, bool(k)) // e.g., "true" or "false"`
			`case int32:`
			`b = strconv.AppendInt(b, int64(k), 10) // e.g., "-32"`
			`case int64:`
			`b = strconv.AppendInt(b, int64(k), 10) // e.g., "-64"`
			`case uint32:`
			`b = strconv.AppendUint(b, uint64(k), 10) // e.g., "32"`
			`case uint64:`
			`b = strconv.AppendUint(b, uint64(k), 10) // e.g., "64"`
			`case string:`
			b = text.AppendString(b, k) // e.g., `"hello, world"`
			`}`
			`b = append(b, ']')`
			`case AnyExpandStep:`
			`b = append(b, '.')`
			`b = append(b, '(')`
			`b = append(b, s.desc.FullName()...)`
			`b = append(b, ')')`
			`default:`
			`b = append(b, "<invalid>"...)`
			`}`
			`return b`
			`}`