src/syscall/zx/fidl/encoding.go - third_party/go - Git at Google

 // 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 fidl

 import (
 	"encoding/binary"
 	"math"
 	"reflect"
 	"syscall/zx"
 )

 const (
 	allocPresent uint64 = math.MaxUint64
 	noAlloc             = 0
 )

 const (
 	handlePresent uint32 = math.MaxUint32
 	noHandle             = 0
 )

 const (
 	maxOutOfLineDepth = 32
 )

 var (
 	// TODO(mknyszek): Add support here for process, thread, job, resource,
 	// interrupt, eventpair, fifo, guest, and time once these are actually
 	// supported in the Go runtime.
 	handleType           reflect.Type = reflect.TypeOf(zx.Handle(0))
 	channelType                       = reflect.TypeOf(zx.Channel(0))
 	logType                           = reflect.TypeOf(zx.Log(0))
 	portType                          = reflect.TypeOf(zx.Port(0))
 	vmoType                           = reflect.TypeOf(zx.VMO(0))
 	eventType                         = reflect.TypeOf(zx.Event(0))
 	socketType                        = reflect.TypeOf(zx.Socket(0))
 	vmarType                          = reflect.TypeOf(zx.VMAR(0))
 	interfaceRequestType              = reflect.TypeOf(InterfaceRequest{})
 	proxyType                         = reflect.TypeOf(ChannelProxy{})
 )

 // isHandleType returns true if the reflected type is a Fuchsia handle type.
 func isHandleType(t reflect.Type) bool {
 	switch t {
 	case handleType:
 		fallthrough
 	case channelType:
 		fallthrough
 	case logType:
 		fallthrough
 	case portType:
 		fallthrough
 	case vmoType:
 		fallthrough
 	case eventType:
 		fallthrough
 	case socketType:
 		fallthrough
 	case vmarType:
 		return true
 	}
 	return false
 }

 // align increases size such that size is aligned to bytes, and returns the new size.
 //
 // bytes must be a power of 2.
 func align(size, bytes int) int {
 	alignmentMask := (bytes - 1)
 	return (size + alignmentMask) & ^alignmentMask
 }

 // encoder represents the encoding context that is necessary to maintain across
 // recursive calls within the same FIDL object.
 type encoder struct {
 	// buffer represents the output buffer that the encoder writes into.
 	buffer []byte

 	// handleDispositions are the handle dispositions discovered when traversing
 	// the FIDL data structure. They are referenced from within the serialized
 	// data structure in buffer.
 	handleDispositions []zx.HandleDisposition
 }

 // Allocate a new out of line object of the specified size for encoding.
 // Returns two values: the starting offset of the new object in the buffer and
 // an error indicating that a new object could not be allocated.
 func (e *encoder) newObject(size, currentDepth int) (int, error) {
 	if currentDepth > maxOutOfLineDepth {
 		return 0, newExpectError(ErrExceededMaxOutOfLineDepth, maxOutOfLineDepth, currentDepth+1)
 	}
 	size = align(size, 8)
 	start := len(e.buffer)
 	e.buffer = append(e.buffer, make([]byte, size)...)
 	return start, nil
 }

 // writeUint64 writes a uint64 to the buffer at the next 8-byte aligned position.
 func (e *encoder) writeUint64(offset int, val uint64) {
 	binary.LittleEndian.PutUint64(e.buffer[offset:], val)
 }

 // writeUint32 writes a uint32 to the buffer at the next 4-byte aligned position.
 func (e *encoder) writeUint32(offset int, val uint32) {
 	binary.LittleEndian.PutUint32(e.buffer[offset:], val)
 }

 // writeUint16 writes a uint16 to the buffer at the next 2-byte aligned position.
 func (e *encoder) writeUint16(offset int, val uint16) {
 	binary.LittleEndian.PutUint16(e.buffer[offset:], val)
 }

 // writeUint8 writes a uint8 to the buffer.
 func (e *encoder) writeUint8(offset int, val uint8) {
 	e.buffer[offset] = val
 }

 // decoder represents the decoding context that is necessary to maintain
 // across recursive calls within the same FIDL object.
 type decoder struct {
 	// nextObject is the byte index of the next out-of-line object in buffer.
 	nextObject int

 	// buffer represents the buffer we're decoding from.
 	buffer []byte

 	// handleInfos represents the input untyped handles we're decoding.
 	// These objects contain additional information on rights.
 	handleInfos []zx.HandleInfo
 }

 // Allocate a new out of line object of the specified size for decoding.
 // Returns two values: the starting offset of the new object in the buffer and
 // an error indicating that a new object could not be allocated.
 func (d *decoder) newObject(size, currentDepth int) (int, error) {
 	if currentDepth > maxOutOfLineDepth {
 		return 0, newExpectError(ErrExceededMaxOutOfLineDepth, maxOutOfLineDepth, currentDepth+1)
 	}
 	start := d.nextObject
 	end := start + align(size, 8)
 	if end > len(d.buffer) {
 		return 0, ErrPayloadTooSmall
 	}
 	for i := d.nextObject + size; i < end; i++ {
 		if d.buffer[i] != 0 {
 			return 0, newValueError(ErrNonZeroPadding, d.buffer[i])
 		}
 	}
 	d.nextObject = end
 	return start, nil
 }

 // readUint64 reads a uint64 from the buffer.
 func (d *decoder) readUint64(offset int) uint64 {
 	return binary.LittleEndian.Uint64(d.buffer[offset:])
 }

 // readUint32 reads a uint32 from the buffer.
 func (d *decoder) readUint32(offset int) uint32 {
 	return binary.LittleEndian.Uint32(d.buffer[offset:])
 }

 // readUint16 reads a uint16 from the buffer.
 func (d *decoder) readUint16(offset int) uint16 {
 	return binary.LittleEndian.Uint16(d.buffer[offset:])
 }

 // readUint8 reads a uint8 from the buffer.
 func (d *decoder) readUint8(offset int) uint8 {
 	return d.buffer[offset]
 }
	// 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 fidl

	import (
	"encoding/binary"
	"math"
	"reflect"
	"syscall/zx"
	)

	const (
	allocPresent uint64 = math.MaxUint64
	noAlloc = 0
	)

	const (
	handlePresent uint32 = math.MaxUint32
	noHandle = 0
	)

	const (
	maxOutOfLineDepth = 32
	)

	var (
	// TODO(mknyszek): Add support here for process, thread, job, resource,
	// interrupt, eventpair, fifo, guest, and time once these are actually
	// supported in the Go runtime.
	handleType reflect.Type = reflect.TypeOf(zx.Handle(0))
	channelType = reflect.TypeOf(zx.Channel(0))
	logType = reflect.TypeOf(zx.Log(0))
	portType = reflect.TypeOf(zx.Port(0))
	vmoType = reflect.TypeOf(zx.VMO(0))
	eventType = reflect.TypeOf(zx.Event(0))
	socketType = reflect.TypeOf(zx.Socket(0))
	vmarType = reflect.TypeOf(zx.VMAR(0))
	interfaceRequestType = reflect.TypeOf(InterfaceRequest{})
	proxyType = reflect.TypeOf(ChannelProxy{})
	)

	// isHandleType returns true if the reflected type is a Fuchsia handle type.
	func isHandleType(t reflect.Type) bool {
	switch t {
	case handleType:
	fallthrough
	case channelType:
	fallthrough
	case logType:
	fallthrough
	case portType:
	fallthrough
	case vmoType:
	fallthrough
	case eventType:
	fallthrough
	case socketType:
	fallthrough
	case vmarType:
	return true
	}
	return false
	}

	// align increases size such that size is aligned to bytes, and returns the new size.
	//
	// bytes must be a power of 2.
	func align(size, bytes int) int {
	alignmentMask := (bytes - 1)
	return (size + alignmentMask) & ^alignmentMask
	}

	// encoder represents the encoding context that is necessary to maintain across
	// recursive calls within the same FIDL object.
	type encoder struct {
	// buffer represents the output buffer that the encoder writes into.
	buffer []byte

	// handleDispositions are the handle dispositions discovered when traversing
	// the FIDL data structure. They are referenced from within the serialized
	// data structure in buffer.
	handleDispositions []zx.HandleDisposition
	}

	// Allocate a new out of line object of the specified size for encoding.
	// Returns two values: the starting offset of the new object in the buffer and
	// an error indicating that a new object could not be allocated.
	func (e *encoder) newObject(size, currentDepth int) (int, error) {
	if currentDepth > maxOutOfLineDepth {
	return 0, newExpectError(ErrExceededMaxOutOfLineDepth, maxOutOfLineDepth, currentDepth+1)
	}
	size = align(size, 8)
	start := len(e.buffer)
	e.buffer = append(e.buffer, make([]byte, size)...)
	return start, nil
	}

	// writeUint64 writes a uint64 to the buffer at the next 8-byte aligned position.
	func (e *encoder) writeUint64(offset int, val uint64) {
	binary.LittleEndian.PutUint64(e.buffer[offset:], val)
	}

	// writeUint32 writes a uint32 to the buffer at the next 4-byte aligned position.
	func (e *encoder) writeUint32(offset int, val uint32) {
	binary.LittleEndian.PutUint32(e.buffer[offset:], val)
	}

	// writeUint16 writes a uint16 to the buffer at the next 2-byte aligned position.
	func (e *encoder) writeUint16(offset int, val uint16) {
	binary.LittleEndian.PutUint16(e.buffer[offset:], val)
	}

	// writeUint8 writes a uint8 to the buffer.
	func (e *encoder) writeUint8(offset int, val uint8) {
	e.buffer[offset] = val
	}

	// decoder represents the decoding context that is necessary to maintain
	// across recursive calls within the same FIDL object.
	type decoder struct {
	// nextObject is the byte index of the next out-of-line object in buffer.
	nextObject int

	// buffer represents the buffer we're decoding from.
	buffer []byte

	// handleInfos represents the input untyped handles we're decoding.
	// These objects contain additional information on rights.
	handleInfos []zx.HandleInfo
	}

	// Allocate a new out of line object of the specified size for decoding.
	// Returns two values: the starting offset of the new object in the buffer and
	// an error indicating that a new object could not be allocated.
	func (d *decoder) newObject(size, currentDepth int) (int, error) {
	if currentDepth > maxOutOfLineDepth {
	return 0, newExpectError(ErrExceededMaxOutOfLineDepth, maxOutOfLineDepth, currentDepth+1)
	}
	start := d.nextObject
	end := start + align(size, 8)
	if end > len(d.buffer) {
	return 0, ErrPayloadTooSmall
	}
	for i := d.nextObject + size; i < end; i++ {
	if d.buffer[i] != 0 {
	return 0, newValueError(ErrNonZeroPadding, d.buffer[i])
	}
	}
	d.nextObject = end
	return start, nil
	}

	// readUint64 reads a uint64 from the buffer.
	func (d *decoder) readUint64(offset int) uint64 {
	return binary.LittleEndian.Uint64(d.buffer[offset:])
	}

	// readUint32 reads a uint32 from the buffer.
	func (d *decoder) readUint32(offset int) uint32 {
	return binary.LittleEndian.Uint32(d.buffer[offset:])
	}

	// readUint16 reads a uint16 from the buffer.
	func (d *decoder) readUint16(offset int) uint16 {
	return binary.LittleEndian.Uint16(d.buffer[offset:])
	}

	// readUint8 reads a uint8 from the buffer.
	func (d *decoder) readUint8(offset int) uint8 {
	return d.buffer[offset]
	}