// 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 text
import (
"bytes"
"fmt"
"io"
"strconv"
"unicode/utf8"
"google.golang.org/protobuf/internal/errors"
)
// Decoder is a token-based textproto decoder.
type Decoder struct {
// lastCall is last method called, either readCall or peekCall.
// Initial value is readCall.
lastCall call
// lastToken contains the last read token.
lastToken Token
// lastErr contains the last read error.
lastErr error
// openStack is a stack containing the byte characters for MessageOpen and
// ListOpen kinds. The top of stack represents the message or the list that
// the current token is nested in. An empty stack means the current token is
// at the top level message. The characters '{' and '<' both represent the
// MessageOpen kind.
openStack []byte
// orig is used in reporting line and column.
orig []byte
// in contains the unconsumed input.
in []byte
}
// NewDecoder returns a Decoder to read the given []byte.
func NewDecoder(b []byte) *Decoder {
return &Decoder{orig: b, in: b}
}
// ErrUnexpectedEOF means that EOF was encountered in the middle of the input.
var ErrUnexpectedEOF = errors.New("%v", io.ErrUnexpectedEOF)
// call specifies which Decoder method was invoked.
type call uint8
const (
readCall call = iota
peekCall
)
// Peek looks ahead and returns the next token and error without advancing a read.
func (d *Decoder) Peek() (Token, error) {
defer func() { d.lastCall = peekCall }()
if d.lastCall == readCall {
d.lastToken, d.lastErr = d.Read()
}
return d.lastToken, d.lastErr
}
// Read returns the next token.
// It will return an error if there is no valid token.
func (d *Decoder) Read() (Token, error) {
defer func() { d.lastCall = readCall }()
if d.lastCall == peekCall {
return d.lastToken, d.lastErr
}
tok, err := d.parseNext(d.lastToken.kind)
if err != nil {
return Token{}, err
}
switch tok.kind {
case comma, semicolon:
tok, err = d.parseNext(tok.kind)
if err != nil {
return Token{}, err
}
}
d.lastToken = tok
return tok, nil
}
const (
mismatchedFmt = "mismatched close character %q"
unexpectedFmt = "unexpected character %q"
)
// parseNext parses the next Token based on given last kind.
func (d *Decoder) parseNext(lastKind Kind) (Token, error) {
// Trim leading spaces.
d.consume(0)
isEOF := false
if len(d.in) == 0 {
isEOF = true
}
switch lastKind {
case EOF:
return d.consumeToken(EOF, 0, 0), nil
case bof:
// Start of top level message. Next token can be EOF or Name.
if isEOF {
return d.consumeToken(EOF, 0, 0), nil
}
return d.parseFieldName()
case Name:
// Next token can be MessageOpen, ListOpen or Scalar.
if isEOF {
return Token{}, ErrUnexpectedEOF
}
switch ch := d.in[0]; ch {
case '{', '<':
d.pushOpenStack(ch)
return d.consumeToken(MessageOpen, 1, 0), nil
case '[':
d.pushOpenStack(ch)
return d.consumeToken(ListOpen, 1, 0), nil
default:
return d.parseScalar()
}
case Scalar:
openKind, closeCh := d.currentOpenKind()
switch openKind {
case bof:
// Top level message.
// Next token can be EOF, comma, semicolon or Name.
if isEOF {
return d.consumeToken(EOF, 0, 0), nil
}
switch d.in[0] {
case ',':
return d.consumeToken(comma, 1, 0), nil
case ';':
return d.consumeToken(semicolon, 1, 0), nil
default:
return d.parseFieldName()
}
case MessageOpen:
// Next token can be MessageClose, comma, semicolon or Name.
if isEOF {
return Token{}, ErrUnexpectedEOF
}
switch ch := d.in[0]; ch {
case closeCh:
d.popOpenStack()
return d.consumeToken(MessageClose, 1, 0), nil
case otherCloseChar[closeCh]:
return Token{}, d.newSyntaxError(mismatchedFmt, ch)
case ',':
return d.consumeToken(comma, 1, 0), nil
case ';':
return d.consumeToken(semicolon, 1, 0), nil
default:
return d.parseFieldName()
}
case ListOpen:
// Next token can be ListClose or comma.
if isEOF {
return Token{}, ErrUnexpectedEOF
}
switch ch := d.in[0]; ch {
case ']':
d.popOpenStack()
return d.consumeToken(ListClose, 1, 0), nil
case ',':
return d.consumeToken(comma, 1, 0), nil
default:
return Token{}, d.newSyntaxError(unexpectedFmt, ch)
}
}
case MessageOpen:
// Next token can be MessageClose or Name.
if isEOF {
return Token{}, ErrUnexpectedEOF
}
_, closeCh := d.currentOpenKind()
switch ch := d.in[0]; ch {
case closeCh:
d.popOpenStack()
return d.consumeToken(MessageClose, 1, 0), nil
case otherCloseChar[closeCh]:
return Token{}, d.newSyntaxError(mismatchedFmt, ch)
default:
return d.parseFieldName()
}
case MessageClose:
openKind, closeCh := d.currentOpenKind()
switch openKind {
case bof:
// Top level message.
// Next token can be EOF, comma, semicolon or Name.
if isEOF {
return d.consumeToken(EOF, 0, 0), nil
}
switch ch := d.in[0]; ch {
case ',':
return d.consumeToken(comma, 1, 0), nil
case ';':
return d.consumeToken(semicolon, 1, 0), nil
default:
return d.parseFieldName()
}
case MessageOpen:
// Next token can be MessageClose, comma, semicolon or Name.
if isEOF {
return Token{}, ErrUnexpectedEOF
}
switch ch := d.in[0]; ch {
case closeCh:
d.popOpenStack()
return d.consumeToken(MessageClose, 1, 0), nil
case otherCloseChar[closeCh]:
return Token{}, d.newSyntaxError(mismatchedFmt, ch)
case ',':
return d.consumeToken(comma, 1, 0), nil
case ';':
return d.consumeToken(semicolon, 1, 0), nil
default:
return d.parseFieldName()
}
case ListOpen:
// Next token can be ListClose or comma
if isEOF {
return Token{}, ErrUnexpectedEOF
}
switch ch := d.in[0]; ch {
case closeCh:
d.popOpenStack()
return d.consumeToken(ListClose, 1, 0), nil
case ',':
return d.consumeToken(comma, 1, 0), nil
default:
return Token{}, d.newSyntaxError(unexpectedFmt, ch)
}
}
case ListOpen:
// Next token can be ListClose, MessageStart or Scalar.
if isEOF {
return Token{}, ErrUnexpectedEOF
}
switch ch := d.in[0]; ch {
case ']':
d.popOpenStack()
return d.consumeToken(ListClose, 1, 0), nil
case '{', '<':
d.pushOpenStack(ch)
return d.consumeToken(MessageOpen, 1, 0), nil
default:
return d.parseScalar()
}
case ListClose:
openKind, closeCh := d.currentOpenKind()
switch openKind {
case bof:
// Top level message.
// Next token can be EOF, comma, semicolon or Name.
if isEOF {
return d.consumeToken(EOF, 0, 0), nil
}
switch ch := d.in[0]; ch {
case ',':
return d.consumeToken(comma, 1, 0), nil
case ';':
return d.consumeToken(semicolon, 1, 0), nil
default:
return d.parseFieldName()
}
case MessageOpen:
// Next token can be MessageClose, comma, semicolon or Name.
if isEOF {
return Token{}, ErrUnexpectedEOF
}
switch ch := d.in[0]; ch {
case closeCh:
d.popOpenStack()
return d.consumeToken(MessageClose, 1, 0), nil
case otherCloseChar[closeCh]:
return Token{}, d.newSyntaxError(mismatchedFmt, ch)
case ',':
return d.consumeToken(comma, 1, 0), nil
case ';':
return d.consumeToken(semicolon, 1, 0), nil
default:
return d.parseFieldName()
}
default:
// It is not possible to have this case. Let it panic below.
}
case comma, semicolon:
openKind, closeCh := d.currentOpenKind()
switch openKind {
case bof:
// Top level message. Next token can be EOF or Name.
if isEOF {
return d.consumeToken(EOF, 0, 0), nil
}
return d.parseFieldName()
case MessageOpen:
// Next token can be MessageClose or Name.
if isEOF {
return Token{}, ErrUnexpectedEOF
}
switch ch := d.in[0]; ch {
case closeCh:
d.popOpenStack()
return d.consumeToken(MessageClose, 1, 0), nil
case otherCloseChar[closeCh]:
return Token{}, d.newSyntaxError(mismatchedFmt, ch)
default:
return d.parseFieldName()
}
case ListOpen:
if lastKind == semicolon {
// It is not be possible to have this case as logic here
// should not have produced a semicolon Token when inside a
// list. Let it panic below.
break
}
// Next token can be MessageOpen or Scalar.
if isEOF {
return Token{}, ErrUnexpectedEOF
}
switch ch := d.in[0]; ch {
case '{', '<':
d.pushOpenStack(ch)
return d.consumeToken(MessageOpen, 1, 0), nil
default:
return d.parseScalar()
}
}
}
line, column := d.Position(len(d.orig) - len(d.in))
panic(fmt.Sprintf("Decoder.parseNext: bug at handling line %d:%d with lastKind=%v", line, column, lastKind))
}
var otherCloseChar = map[byte]byte{
'}': '>',
'>': '}',
}
// currentOpenKind indicates whether current position is inside a message, list
// or top-level message by returning MessageOpen, ListOpen or bof respectively.
// If the returned kind is either a MessageOpen or ListOpen, it also returns the
// corresponding closing character.
func (d *Decoder) currentOpenKind() (Kind, byte) {
if len(d.openStack) == 0 {
return bof, 0
}
openCh := d.openStack[len(d.openStack)-1]
switch openCh {
case '{':
return MessageOpen, '}'
case '<':
return MessageOpen, '>'
case '[':
return ListOpen, ']'
}
panic(fmt.Sprintf("Decoder: openStack contains invalid byte %c", openCh))
}
func (d *Decoder) pushOpenStack(ch byte) {
d.openStack = append(d.openStack, ch)
}
func (d *Decoder) popOpenStack() {
d.openStack = d.openStack[:len(d.openStack)-1]
}
// parseFieldName parses field name and separator.
func (d *Decoder) parseFieldName() (tok Token, err error) {
defer func() {
if err == nil && d.tryConsumeChar(':') {
tok.attrs |= hasSeparator
}
}()
// Extension or Any type URL.
if d.in[0] == '[' {
return d.parseTypeName()
}
// Identifier.
if size := parseIdent(d.in, false); size > 0 {
return d.consumeToken(Name, size, uint8(IdentName)), nil
}
// Field number. Identify if input is a valid number that is not negative
// and is decimal integer within 32-bit range.
if num := parseNumber(d.in); num.size > 0 {
if !num.neg && num.kind == numDec {
if _, err := strconv.ParseInt(string(d.in[:num.size]), 10, 32); err == nil {
return d.consumeToken(Name, num.size, uint8(FieldNumber)), nil
}
}
return Token{}, d.newSyntaxError("invalid field number: %s", d.in[:num.size])
}
return Token{}, d.newSyntaxError("invalid field name: %s", errId(d.in))
}
// parseTypeName parses Any type URL or extension field name. The name is
// enclosed in [ and ] characters. The C++ parser does not handle many legal URL
// strings. This implementation is more liberal and allows for the pattern
// ^[-_a-zA-Z0-9]+([./][-_a-zA-Z0-9]+)*`). Whitespaces and comments are allowed
// in between [ ], '.', '/' and the sub names.
func (d *Decoder) parseTypeName() (Token, error) {
startPos := len(d.orig) - len(d.in)
// Use alias s to advance first in order to use d.in for error handling.
// Caller already checks for [ as first character.
s := consume(d.in[1:], 0)
if len(s) == 0 {
return Token{}, ErrUnexpectedEOF
}
var name []byte
for len(s) > 0 && isTypeNameChar(s[0]) {
name = append(name, s[0])
s = s[1:]
}
s = consume(s, 0)
var closed bool
for len(s) > 0 && !closed {
switch {
case s[0] == ']':
s = s[1:]
closed = true
case s[0] == '/', s[0] == '.':
if len(name) > 0 && (name[len(name)-1] == '/' || name[len(name)-1] == '.') {
return Token{}, d.newSyntaxError("invalid type URL/extension field name: %s",
d.orig[startPos:len(d.orig)-len(s)+1])
}
name = append(name, s[0])
s = s[1:]
s = consume(s, 0)
for len(s) > 0 && isTypeNameChar(s[0]) {
name = append(name, s[0])
s = s[1:]
}
s = consume(s, 0)
default:
return Token{}, d.newSyntaxError(
"invalid type URL/extension field name: %s", d.orig[startPos:len(d.orig)-len(s)+1])
}
}
if !closed {
return Token{}, ErrUnexpectedEOF
}
// First character cannot be '.'. Last character cannot be '.' or '/'.
size := len(name)
if size == 0 || name[0] == '.' || name[size-1] == '.' || name[size-1] == '/' {
return Token{}, d.newSyntaxError("invalid type URL/extension field name: %s",
d.orig[startPos:len(d.orig)-len(s)])
}
d.in = s
endPos := len(d.orig) - len(d.in)
d.consume(0)
return Token{
kind: Name,
attrs: uint8(TypeName),
pos: startPos,
raw: d.orig[startPos:endPos],
str: string(name),
}, nil
}
func isTypeNameChar(b byte) bool {
return (b == '-' || b == '_' ||
('0' <= b && b <= '9') ||
('a' <= b && b <= 'z') ||
('A' <= b && b <= 'Z'))
}
func isWhiteSpace(b byte) bool {
switch b {
case ' ', '\n', '\r', '\t':
return true
default:
return false
}
}
// parseIdent parses an unquoted proto identifier and returns size.
// If allowNeg is true, it allows '-' to be the first character in the
// identifier. This is used when parsing literal values like -infinity, etc.
// Regular expression matches an identifier: `^[_a-zA-Z][_a-zA-Z0-9]*`
func parseIdent(input []byte, allowNeg bool) int {
var size int
s := input
if len(s) == 0 {
return 0
}
if allowNeg && s[0] == '-' {
s = s[1:]
size++
if len(s) == 0 {
return 0
}
}
switch {
case s[0] == '_',
'a' <= s[0] && s[0] <= 'z',
'A' <= s[0] && s[0] <= 'Z':
s = s[1:]
size++
default:
return 0
}
for len(s) > 0 && (s[0] == '_' ||
'a' <= s[0] && s[0] <= 'z' ||
'A' <= s[0] && s[0] <= 'Z' ||
'0' <= s[0] && s[0] <= '9') {
s = s[1:]
size++
}
if len(s) > 0 && !isDelim(s[0]) {
return 0
}
return size
}
// parseScalar parses for a string, literal or number value.
func (d *Decoder) parseScalar() (Token, error) {
if d.in[0] == '"' || d.in[0] == '\'' {
return d.parseStringValue()
}
if tok, ok := d.parseLiteralValue(); ok {
return tok, nil
}
if tok, ok := d.parseNumberValue(); ok {
return tok, nil
}
return Token{}, d.newSyntaxError("invalid scalar value: %s", errId(d.in))
}
// parseLiteralValue parses a literal value. A literal value is used for
// bools, special floats and enums. This function simply identifies that the
// field value is a literal.
func (d *Decoder) parseLiteralValue() (Token, bool) {
size := parseIdent(d.in, true)
if size == 0 {
return Token{}, false
}
return d.consumeToken(Scalar, size, literalValue), true
}
// consumeToken constructs a Token for given Kind from d.in and consumes given
// size-length from it.
func (d *Decoder) consumeToken(kind Kind, size int, attrs uint8) Token {
// Important to compute raw and pos before consuming.
tok := Token{
kind: kind,
attrs: attrs,
pos: len(d.orig) - len(d.in),
raw: d.in[:size],
}
d.consume(size)
return tok
}
// newSyntaxError returns a syntax error with line and column information for
// current position.
func (d *Decoder) newSyntaxError(f string, x ...interface{}) error {
e := errors.New(f, x...)
line, column := d.Position(len(d.orig) - len(d.in))
return errors.New("syntax error (line %d:%d): %v", line, column, e)
}
// Position returns line and column number of given index of the original input.
// It will panic if index is out of range.
func (d *Decoder) Position(idx int) (line int, column int) {
b := d.orig[:idx]
line = bytes.Count(b, []byte("\n")) + 1
if i := bytes.LastIndexByte(b, '\n'); i >= 0 {
b = b[i+1:]
}
column = utf8.RuneCount(b) + 1 // ignore multi-rune characters
return line, column
}
func (d *Decoder) tryConsumeChar(c byte) bool {
if len(d.in) > 0 && d.in[0] == c {
d.consume(1)
return true
}
return false
}
// consume consumes n bytes of input and any subsequent whitespace or comments.
func (d *Decoder) consume(n int) {
d.in = consume(d.in, n)
return
}
// consume consumes n bytes of input and any subsequent whitespace or comments.
func consume(b []byte, n int) []byte {
b = b[n:]
for len(b) > 0 {
switch b[0] {
case ' ', '\n', '\r', '\t':
b = b[1:]
case '#':
if i := bytes.IndexByte(b, '\n'); i >= 0 {
b = b[i+len("\n"):]
} else {
b = nil
}
default:
return b
}
}
return b
}
// errId extracts a byte sequence that looks like an invalid ID
// (for the purposes of error reporting).
func errId(seq []byte) []byte {
const maxLen = 32
for i := 0; i < len(seq); {
if i > maxLen {
return append(seq[:i:i], "…"...)
}
r, size := utf8.DecodeRune(seq[i:])
if r > utf8.RuneSelf || (r != '/' && isDelim(byte(r))) {
if i == 0 {
// Either the first byte is invalid UTF-8 or a
// delimiter, or the first rune is non-ASCII.
// Return it as-is.
i = size
}
return seq[:i:i]
}
i += size
}
// No delimiter found.
return seq
}
// isDelim returns true if given byte is a delimiter character.
func isDelim(c byte) bool {
return !(c == '-' || c == '+' || c == '.' || c == '_' ||
('a' <= c && c <= 'z') ||
('A' <= c && c <= 'Z') ||
('0' <= c && c <= '9'))
}