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/*
* JSON lexer
*
* Copyright IBM, Corp. 2009
*
* Authors:
* Anthony Liguori <aliguori@us.ibm.com>
*
* This work is licensed under the terms of the GNU LGPL, version 2.1 or later.
* See the COPYING.LIB file in the top-level directory.
*
*/
#include "qemu/osdep.h"
#include "json-parser-int.h"
#define MAX_TOKEN_SIZE (64ULL << 20)
/*
* From RFC 8259 "The JavaScript Object Notation (JSON) Data
* Interchange Format", with [comments in brackets]:
*
* The set of tokens includes six structural characters, strings,
* numbers, and three literal names.
*
* These are the six structural characters:
*
* begin-array = ws %x5B ws ; [ left square bracket
* begin-object = ws %x7B ws ; { left curly bracket
* end-array = ws %x5D ws ; ] right square bracket
* end-object = ws %x7D ws ; } right curly bracket
* name-separator = ws %x3A ws ; : colon
* value-separator = ws %x2C ws ; , comma
*
* Insignificant whitespace is allowed before or after any of the six
* structural characters.
* [This lexer accepts it before or after any token, which is actually
* the same, as the grammar always has structural characters between
* other tokens.]
*
* ws = *(
* %x20 / ; Space
* %x09 / ; Horizontal tab
* %x0A / ; Line feed or New line
* %x0D ) ; Carriage return
*
* [...] three literal names:
* false null true
* [This lexer accepts [a-z]+, and leaves rejecting unknown literal
* names to the parser.]
*
* [Numbers:]
*
* number = [ minus ] int [ frac ] [ exp ]
* decimal-point = %x2E ; .
* digit1-9 = %x31-39 ; 1-9
* e = %x65 / %x45 ; e E
* exp = e [ minus / plus ] 1*DIGIT
* frac = decimal-point 1*DIGIT
* int = zero / ( digit1-9 *DIGIT )
* minus = %x2D ; -
* plus = %x2B ; +
* zero = %x30 ; 0
*
* [Strings:]
* string = quotation-mark *char quotation-mark
*
* char = unescaped /
* escape (
* %x22 / ; " quotation mark U+0022
* %x5C / ; \ reverse solidus U+005C
* %x2F / ; / solidus U+002F
* %x62 / ; b backspace U+0008
* %x66 / ; f form feed U+000C
* %x6E / ; n line feed U+000A
* %x72 / ; r carriage return U+000D
* %x74 / ; t tab U+0009
* %x75 4HEXDIG ) ; uXXXX U+XXXX
* escape = %x5C ; \
* quotation-mark = %x22 ; "
* unescaped = %x20-21 / %x23-5B / %x5D-10FFFF
* [This lexer accepts any non-control character after escape, and
* leaves rejecting invalid ones to the parser.]
*
*
* Extensions over RFC 8259:
* - Extra escape sequence in strings:
* 0x27 (apostrophe) is recognized after escape, too
* - Single-quoted strings:
* Like double-quoted strings, except they're delimited by %x27
* (apostrophe) instead of %x22 (quotation mark), and can't contain
* unescaped apostrophe, but can contain unescaped quotation mark.
* - Interpolation, if enabled:
* The lexer accepts %[A-Za-z0-9]*, and leaves rejecting invalid
* ones to the parser.
*
* Note:
* - Input must be encoded in modified UTF-8.
* - Decoding and validating is left to the parser.
*/
enum json_lexer_state {
IN_ERROR = 0, /* must really be 0, see json_lexer[] */
IN_RECOVERY,
IN_DQ_STRING_ESCAPE,
IN_DQ_STRING,
IN_SQ_STRING_ESCAPE,
IN_SQ_STRING,
IN_ZERO,
IN_EXP_DIGITS,
IN_EXP_SIGN,
IN_EXP_E,
IN_MANTISSA,
IN_MANTISSA_DIGITS,
IN_DIGITS,
IN_SIGN,
IN_KEYWORD,
IN_INTERP,
IN_WHITESPACE,
IN_START,
IN_START_INTERP, /* must be IN_START + 1 */
};
QEMU_BUILD_BUG_ON((int)JSON_MIN <= (int)IN_START_INTERP);
QEMU_BUILD_BUG_ON(JSON_MAX >= 0x80);
QEMU_BUILD_BUG_ON(IN_START_INTERP != IN_START + 1);
#define LOOKAHEAD 0x80
#define TERMINAL(state) [0 ... 0xFF] = ((state) | LOOKAHEAD)
static const uint8_t json_lexer[][256] = {
/* Relies on default initialization to IN_ERROR! */
/* error recovery */
[IN_RECOVERY] = {
/*
* Skip characters until a structural character, an ASCII
* control character other than '\t', or impossible UTF-8
* bytes '\xFE', '\xFF'. Structural characters and line
* endings are promising resynchronization points. Clients
* may use the others to force the JSON parser into known-good
* state; see docs/interop/qmp-spec.txt.
*/
[0 ... 0x1F] = IN_START | LOOKAHEAD,
[0x20 ... 0xFD] = IN_RECOVERY,
[0xFE ... 0xFF] = IN_START | LOOKAHEAD,
['\t'] = IN_RECOVERY,
['['] = IN_START | LOOKAHEAD,
[']'] = IN_START | LOOKAHEAD,
['{'] = IN_START | LOOKAHEAD,
['}'] = IN_START | LOOKAHEAD,
[':'] = IN_START | LOOKAHEAD,
[','] = IN_START | LOOKAHEAD,
},
/* double quote string */
[IN_DQ_STRING_ESCAPE] = {
[0x20 ... 0xFD] = IN_DQ_STRING,
},
[IN_DQ_STRING] = {
[0x20 ... 0xFD] = IN_DQ_STRING,
['\\'] = IN_DQ_STRING_ESCAPE,
['"'] = JSON_STRING,
},
/* single quote string */
[IN_SQ_STRING_ESCAPE] = {
[0x20 ... 0xFD] = IN_SQ_STRING,
},
[IN_SQ_STRING] = {
[0x20 ... 0xFD] = IN_SQ_STRING,
['\\'] = IN_SQ_STRING_ESCAPE,
['\''] = JSON_STRING,
},
/* Zero */
[IN_ZERO] = {
TERMINAL(JSON_INTEGER),
['0' ... '9'] = IN_ERROR,
['.'] = IN_MANTISSA,
},
/* Float */
[IN_EXP_DIGITS] = {
TERMINAL(JSON_FLOAT),
['0' ... '9'] = IN_EXP_DIGITS,
},
[IN_EXP_SIGN] = {
['0' ... '9'] = IN_EXP_DIGITS,
},
[IN_EXP_E] = {
['-'] = IN_EXP_SIGN,
['+'] = IN_EXP_SIGN,
['0' ... '9'] = IN_EXP_DIGITS,
},
[IN_MANTISSA_DIGITS] = {
TERMINAL(JSON_FLOAT),
['0' ... '9'] = IN_MANTISSA_DIGITS,
['e'] = IN_EXP_E,
['E'] = IN_EXP_E,
},
[IN_MANTISSA] = {
['0' ... '9'] = IN_MANTISSA_DIGITS,
},
/* Number */
[IN_DIGITS] = {
TERMINAL(JSON_INTEGER),
['0' ... '9'] = IN_DIGITS,
['e'] = IN_EXP_E,
['E'] = IN_EXP_E,
['.'] = IN_MANTISSA,
},
[IN_SIGN] = {
['0'] = IN_ZERO,
['1' ... '9'] = IN_DIGITS,
},
/* keywords */
[IN_KEYWORD] = {
TERMINAL(JSON_KEYWORD),
['a' ... 'z'] = IN_KEYWORD,
},
/* whitespace */
[IN_WHITESPACE] = {
TERMINAL(JSON_SKIP),
[' '] = IN_WHITESPACE,
['\t'] = IN_WHITESPACE,
['\r'] = IN_WHITESPACE,
['\n'] = IN_WHITESPACE,
},
/* interpolation */
[IN_INTERP] = {
TERMINAL(JSON_INTERP),
['A' ... 'Z'] = IN_INTERP,
['a' ... 'z'] = IN_INTERP,
['0' ... '9'] = IN_INTERP,
},
/*
* Two start states:
* - IN_START recognizes JSON tokens with our string extensions
* - IN_START_INTERP additionally recognizes interpolation.
*/
[IN_START ... IN_START_INTERP] = {
['"'] = IN_DQ_STRING,
['\''] = IN_SQ_STRING,
['0'] = IN_ZERO,
['1' ... '9'] = IN_DIGITS,
['-'] = IN_SIGN,
['{'] = JSON_LCURLY,
['}'] = JSON_RCURLY,
['['] = JSON_LSQUARE,
[']'] = JSON_RSQUARE,
[','] = JSON_COMMA,
[':'] = JSON_COLON,
['a' ... 'z'] = IN_KEYWORD,
[' '] = IN_WHITESPACE,
['\t'] = IN_WHITESPACE,
['\r'] = IN_WHITESPACE,
['\n'] = IN_WHITESPACE,
},
[IN_START_INTERP]['%'] = IN_INTERP,
};
static inline uint8_t next_state(JSONLexer *lexer, char ch, bool flush,
bool *char_consumed)
{
uint8_t next;
assert(lexer->state <= ARRAY_SIZE(json_lexer));
next = json_lexer[lexer->state][(uint8_t)ch];
*char_consumed = !flush && !(next & LOOKAHEAD);
return next & ~LOOKAHEAD;
}
void json_lexer_init(JSONLexer *lexer, bool enable_interpolation)
{
lexer->start_state = lexer->state = enable_interpolation
? IN_START_INTERP : IN_START;
lexer->token = g_string_sized_new(3);
lexer->x = lexer->y = 0;
}
static void json_lexer_feed_char(JSONLexer *lexer, char ch, bool flush)
{
int new_state;
bool char_consumed = false;
lexer->x++;
if (ch == '\n') {
lexer->x = 0;
lexer->y++;
}
while (flush ? lexer->state != lexer->start_state : !char_consumed) {
new_state = next_state(lexer, ch, flush, &char_consumed);
if (char_consumed) {
assert(!flush);
g_string_append_c(lexer->token, ch);
}
switch (new_state) {
case JSON_LCURLY:
case JSON_RCURLY:
case JSON_LSQUARE:
case JSON_RSQUARE:
case JSON_COLON:
case JSON_COMMA:
case JSON_INTERP:
case JSON_INTEGER:
case JSON_FLOAT:
case JSON_KEYWORD:
case JSON_STRING:
json_message_process_token(lexer, lexer->token, new_state,
lexer->x, lexer->y);
/* fall through */
case JSON_SKIP:
g_string_truncate(lexer->token, 0);
/* fall through */
case IN_START:
new_state = lexer->start_state;
break;
case IN_ERROR:
json_message_process_token(lexer, lexer->token, JSON_ERROR,
lexer->x, lexer->y);
new_state = IN_RECOVERY;
/* fall through */
case IN_RECOVERY:
g_string_truncate(lexer->token, 0);
break;
default:
break;
}
lexer->state = new_state;
}
/* Do not let a single token grow to an arbitrarily large size,
* this is a security consideration.
*/
if (lexer->token->len > MAX_TOKEN_SIZE) {
json_message_process_token(lexer, lexer->token, lexer->state,
lexer->x, lexer->y);
g_string_truncate(lexer->token, 0);
lexer->state = lexer->start_state;
}
}
void json_lexer_feed(JSONLexer *lexer, const char *buffer, size_t size)
{
size_t i;
for (i = 0; i < size; i++) {
json_lexer_feed_char(lexer, buffer[i], false);
}
}
void json_lexer_flush(JSONLexer *lexer)
{
json_lexer_feed_char(lexer, 0, true);
assert(lexer->state == lexer->start_state);
json_message_process_token(lexer, lexer->token, JSON_END_OF_INPUT,
lexer->x, lexer->y);
}
void json_lexer_destroy(JSONLexer *lexer)
{
g_string_free(lexer->token, true);
}
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