Files
qemu-qemu/qobject/json-lexer.c
Paolo Bonzini b6368e7c77 json-parser: add location to JSON parsing errors
Now that all calls to parse_error have a token, add the line and column
to the message.  As far as I can see the two important TODOs (better
errors and better EOI handling) are done, and the others (token range
information and "parsed size"?) do not really matter or are handled
better by json-streamer.c.  So remove the list, which had sat unchanged
since 2009.

This needs some adjustments to provide a good x and y for error messages.
First of all, they switch from zero-based to one-based, which is safe
because they were both sitting unused.  Second, right now the x and y
are those of the *last* character in the token.  Modify json-lexer.c to
freeze tok->x and tok->y at the first character added to the GString.

Signed-off-by: Paolo Bonzini <pbonzini@redhat.com>
Message-ID: <20260626101727.1727389-7-pbonzini@redhat.com>
Reviewed-by: Markus Armbruster <armbru@redhat.com>
Signed-off-by: Markus Armbruster <armbru@redhat.com>
2026-07-02 13:56:35 +02:00

369 lines
10 KiB
C

/*
* 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_RECOVERY = 1,
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_START,
IN_START_INTERP, /* must be IN_START + 1 */
};
QEMU_BUILD_BUG_ON(JSON_ERROR != 0);
QEMU_BUILD_BUG_ON(IN_RECOVERY != JSON_ERROR + 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.rst.
*/
[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'] = JSON_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,
},
/* 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_START,
['\t'] = IN_START,
['\r'] = IN_START,
['\n'] = IN_START,
},
[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->cur_x = lexer->cur_y = 1;
lexer->x = lexer->y = 1;
}
static void json_lexer_feed_char(JSONLexer *lexer, char ch, bool flush)
{
int new_state;
bool char_consumed = false;
lexer->cur_x++;
if (ch == '\n') {
lexer->cur_x = 1;
lexer->cur_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 IN_START:
g_string_truncate(lexer->token, 0);
new_state = lexer->start_state;
lexer->x = lexer->cur_x;
lexer->y = lexer->cur_y;
break;
case JSON_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);
}