[ViewVC] Diff of: cvs/JSON-XS/XS.xs

Comparing JSON-XS/XS.xs (file contents):
Revision 1.2 by root, Thu Mar 22 17:28:50 2007 UTC vs.
Revision 1.41 by root, Sat Jun 23 22:53:16 2007 UTC

…		…
3	#include "XSUB.h"	3	#include "XSUB.h"
4		4
5	#include "assert.h"	5	#include "assert.h"
6	#include "string.h"	6	#include "string.h"
7	#include "stdlib.h"	7	#include "stdlib.h"
		8	#include "stdio.h"
8		9
		10	#if defined(__BORLANDC__) \|\| defined(_MSC_VER)
		11	# define snprintf _snprintf // C compilers have this in stdio.h
		12	#endif
		13
		14	// some old perls do not have this, try to make it work, no
		15	// guarentees, though.
		16	#ifndef UTF8_MAXBYTES
		17	# define UTF8_MAXBYTES 13
		18	#endif
		19
9	#define F_ASCII 0x00000001	20	#define F_ASCII 0x00000001UL
		21	#define F_LATIN1 0x00000002UL
10	#define F_UTF8 0x00000002	22	#define F_UTF8 0x00000004UL
11	#define F_INDENT 0x00000004	23	#define F_INDENT 0x00000008UL
12	#define F_CANONICAL 0x00000008	24	#define F_CANONICAL 0x00000010UL
13	#define F_SPACE_BEFORE 0x00000010	25	#define F_SPACE_BEFORE 0x00000020UL
14	#define F_SPACE_AFTER 0x00000020	26	#define F_SPACE_AFTER 0x00000040UL
		27	#define F_ALLOW_NONREF 0x00000100UL
15	#define F_JSON_RPC 0x00000040	28	#define F_SHRINK 0x00000200UL
		29	#define F_MAXDEPTH 0xf8000000UL
		30	#define S_MAXDEPTH 27
		31
		32	#define DEC_DEPTH(flags) (1UL << ((flags & F_MAXDEPTH) >> S_MAXDEPTH))
		33
		34	// F_SELFCONVERT? <=> to_json/toJson
		35	// F_BLESSED? <=> { $__class__$ => }
16		36
17	#define F_PRETTY F_INDENT \| F_SPACE_BEFORE \| F_SPACE_AFTER	37	#define F_PRETTY F_INDENT \| F_SPACE_BEFORE \| F_SPACE_AFTER
18	#define F_DEFAULT 0	38	#define F_DEFAULT (9UL << S_MAXDEPTH)
19		39
20	#define INIT_SIZE 32 // initial scalar size to be allocated	40	#define INIT_SIZE 32 // initial scalar size to be allocated
		41	#define INDENT_STEP 3 // spaces per indentation level
		42
		43	#define SHORT_STRING_LEN 16384 // special-case strings of up to this size
21		44
22	#define SB do {	45	#define SB do {
23	#define SE } while (0)	46	#define SE } while (0)
24		47
		48	#if __GNUC__ >= 3
		49	# define expect(expr,value) __builtin_expect ((expr),(value))
		50	# define inline inline
		51	#else
		52	# define expect(expr,value) (expr)
		53	# define inline static
		54	#endif
		55
		56	#define expect_false(expr) expect ((expr) != 0, 0)
		57	#define expect_true(expr) expect ((expr) != 0, 1)
		58
25	static HV *json_stash;	59	static HV *json_stash; // JSON::XS::
		60
		61	/////////////////////////////////////////////////////////////////////////////
		62	// utility functions
		63
		64	static UV *
		65	SvJSON (SV *sv)
		66	{
		67	if (!(SvROK (sv) && SvOBJECT (SvRV (sv)) && SvSTASH (SvRV (sv)) == json_stash))
		68	croak ("object is not of type JSON::XS");
		69
		70	return &SvUVX (SvRV (sv));
		71	}
		72
		73	static void
		74	shrink (SV *sv)
		75	{
		76	sv_utf8_downgrade (sv, 1);
		77	if (SvLEN (sv) > SvCUR (sv) + 1)
		78	{
		79	#ifdef SvPV_shrink_to_cur
		80	SvPV_shrink_to_cur (sv);
		81	#elif defined (SvPV_renew)
		82	SvPV_renew (sv, SvCUR (sv) + 1);
		83	#endif
		84	}
		85	}
		86
		87	// decode an utf-8 character and return it, or (UV)-1 in
		88	// case of an error.
		89	// we special-case "safe" characters from U+80 .. U+7FF,
		90	// but use the very good perl function to parse anything else.
		91	// note that we never call this function for a ascii codepoints
		92	inline UV
		93	decode_utf8 (unsigned char s, STRLEN len, STRLEN clen)
		94	{
		95	if (expect_false (s[0] > 0xdf \|\| s[0] < 0xc2))
		96	return utf8n_to_uvuni (s, len, clen, UTF8_CHECK_ONLY);
		97	else if (len > 1 && s[1] >= 0x80 && s[1] <= 0xbf)
		98	{
		99	*clen = 2;
		100	return ((s[0] & 0x1f) << 6) \| (s[1] & 0x3f);
		101	}
		102	else
		103	{
		104	*clen = (STRLEN)-1;
		105	return (UV)-1;
		106	}
		107	}
		108
		109	/////////////////////////////////////////////////////////////////////////////
		110	// encoder
26		111
27	// structure used for encoding JSON	112	// structure used for encoding JSON
28	typedef struct	113	typedef struct
29	{	114	{
30	char *cur;	115	char *cur; // SvPVX (sv) + current output position
31	STRLEN len; // SvLEN (sv)
32	char *end; // SvEND (sv)	116	char *end; // SvEND (sv)
33	SV *sv;	117	SV *sv; // result scalar
34	UV flags;	118	U32 flags; // F_*
35	int max_recurse;	119	U32 indent; // indentation level
36	int indent;	120	U32 maxdepth; // max. indentation/recursion level
37	} enc_t;	121	} enc_t;
38		122
39	// structure used for decoding JSON	123	inline void
40	typedef struct
41	{
42	char *cur;
43	char *end;
44	char *err;
45	UV flags;
46	} dec_t;
47
48	static UV *
49	SvJSON (SV *sv)
50	{
51	if (!(SvROK (sv) && SvOBJECT (SvRV (sv)) && SvSTASH (SvRV (sv)) == json_stash))
52	croak ("object is not of type JSON::XS");
53
54	return &SvUVX (SvRV (sv));
55	}
56
57	/////////////////////////////////////////////////////////////////////////////
58
59	static void
60	need (enc_t *enc, STRLEN len)	124	need (enc_t *enc, STRLEN len)
61	{	125	{
62	if (enc->cur + len >= enc->end)	126	if (expect_false (enc->cur + len >= enc->end))
63	{	127	{
64	STRLEN cur = enc->cur - SvPVX (enc->sv);	128	STRLEN cur = enc->cur - SvPVX (enc->sv);
65	SvGROW (enc->sv, cur + len + 1);	129	SvGROW (enc->sv, cur + len + 1);
66	enc->cur = SvPVX (enc->sv) + cur;	130	enc->cur = SvPVX (enc->sv) + cur;
67	enc->end = SvEND (enc->sv);	131	enc->end = SvPVX (enc->sv) + SvLEN (enc->sv) - 1;
68	}	132	}
69	}	133	}
70		134
71	static void	135	inline void
72	encode_ch (enc_t *enc, char ch)	136	encode_ch (enc_t *enc, char ch)
73	{	137	{
74	need (enc, 1);	138	need (enc, 1);
75	*enc->cur++ = ch;	139	*enc->cur++ = ch;
76	}	140	}
…		…
78	static void	142	static void
79	encode_str (enc_t enc, char str, STRLEN len, int is_utf8)	143	encode_str (enc_t enc, char str, STRLEN len, int is_utf8)
80	{	144	{
81	char *end = str + len;	145	char *end = str + len;
82		146
		147	need (enc, len);
		148
83	while (str < end)	149	while (str < end)
84	{	150	{
85	unsigned char ch = (unsigned char )str;	151	unsigned char ch = (unsigned char )str;
		152
86	if (ch >= 0x20 && ch < 0x80) // most common case	153	if (expect_true (ch >= 0x20 && ch < 0x80)) // most common case
87	{	154	{
		155	if (expect_false (ch == '"')) // but with slow exceptions
		156	{
		157	need (enc, len += 1);
		158	*enc->cur++ = '\\';
		159	*enc->cur++ = '"';
		160	}
		161	else if (expect_false (ch == '\\'))
		162	{
		163	need (enc, len += 1);
		164	*enc->cur++ = '\\';
		165	*enc->cur++ = '\\';
		166	}
		167	else
88	*enc->cur++ = ch;	168	*enc->cur++ = ch;
		169
89	str++;	170	++str;
90	}	171	}
91	else	172	else
92	{	173	{
93	STRLEN clen;	174	switch (ch)
94	UV uch;
95
96	if (is_utf8)
97	{	175	{
98	uch = utf8n_to_uvuni (str, end - str, &clen, UTF8_CHECK_ONLY);	176	case '\010': need (enc, len += 1); enc->cur++ = '\\'; enc->cur++ = 'b'; ++str; break;
99	if (clen < 0)	177	case '\011': need (enc, len += 1); enc->cur++ = '\\'; enc->cur++ = 't'; ++str; break;
100	croak ("malformed UTF-8 character in string, cannot convert to JSON");	178	case '\012': need (enc, len += 1); enc->cur++ = '\\'; enc->cur++ = 'n'; ++str; break;
101	}	179	case '\014': need (enc, len += 1); enc->cur++ = '\\'; enc->cur++ = 'f'; ++str; break;
102	else	180	case '\015': need (enc, len += 1); enc->cur++ = '\\'; enc->cur++ = 'r'; ++str; break;
103	{
104	uch = ch;
105	clen = 1;
106	}
107		181
108	need (enc, len += 6);	182	default:
109
110	if (uch < 0xa0 \|\| enc->flags & F_ASCII)
111	{
112	if (uch > 0xFFFFUL)
113	{	183	{
		184	STRLEN clen;
		185	UV uch;
		186
		187	if (is_utf8)
		188	{
		189	uch = decode_utf8 (str, end - str, &clen);
		190	if (clen == (STRLEN)-1)
		191	croak ("malformed or illegal unicode character in string [%.11s], cannot convert to JSON", str);
		192	}
		193	else
		194	{
		195	uch = ch;
114	len += 6;	196	clen = 1;
		197	}
		198
		199	if (uch > 0x10FFFFUL)
		200	croak ("out of range codepoint (0x%lx) encountered, unrepresentable in JSON", (unsigned long)uch);
		201
		202	if (uch < 0x80 \|\| enc->flags & F_ASCII \|\| (enc->flags & F_LATIN1 && uch > 0xFF))
		203	{
		204	if (uch > 0xFFFFUL)
		205	{
115	need (enc, len += 6);	206	need (enc, len += 11);
116	sprintf (enc->cur, "\\u%04x\\u%04x",	207	sprintf (enc->cur, "\\u%04x\\u%04x",
117	(uch - 0x10000) / 0x400 + 0xD800,	208	(int)((uch - 0x10000) / 0x400 + 0xD800),
118	(uch - 0x10000) % 0x400 + 0xDC00);	209	(int)((uch - 0x10000) % 0x400 + 0xDC00));
119	enc->cur += 12;	210	enc->cur += 12;
		211	}
		212	else
		213	{
		214	static char hexdigit [16] = "0123456789abcdef";
		215	need (enc, len += 5);
		216	*enc->cur++ = '\\';
		217	*enc->cur++ = 'u';
		218	*enc->cur++ = hexdigit [ uch >> 12 ];
		219	*enc->cur++ = hexdigit [(uch >> 8) & 15];
		220	*enc->cur++ = hexdigit [(uch >> 4) & 15];
		221	*enc->cur++ = hexdigit [(uch >> 0) & 15];
		222	}
		223
		224	str += clen;
120	}	225	}
		226	else if (enc->flags & F_LATIN1)
		227	{
		228	*enc->cur++ = uch;
		229	str += clen;
		230	}
		231	else if (is_utf8)
		232	{
		233	need (enc, len += clen);
		234	do
		235	{
		236	enc->cur++ = str++;
		237	}
		238	while (--clen);
		239	}
121	else	240	else
122	{	241	{
123	sprintf (enc->cur, "\\u%04x", uch);	242	need (enc, len += UTF8_MAXBYTES - 1); // never more than 11 bytes needed
124	enc->cur += 6;	243	enc->cur = uvuni_to_utf8_flags (enc->cur, uch, 0);
		244	++str;
		245	}
125	}	246	}
126	}	247	}
127	else if (is_utf8)
128	{
129	memcpy (enc->cur, str, clen);
130	enc->cur += clen;
131	}
132	else
133	enc->cur = uvuni_to_utf8_flags (enc->cur, uch, 0);
134
135	str += clen;
136	}	248	}
137		249
138	--len;	250	--len;
139	}	251	}
140	}	252	}
141		253
142	#define INDENT SB \	254	inline void
		255	encode_indent (enc_t *enc)
		256	{
143	if (enc->flags & F_INDENT) \	257	if (enc->flags & F_INDENT)
144	{ \	258	{
145	int i_; \	259	int spaces = enc->indent * INDENT_STEP;
146	need (enc, enc->indent); \
147	for (i_ = enc->indent * 3; i_--; )\
148	encode_ch (enc, ' '); \
149	} \
150	SE
151		260
152	#define SPACE SB need (enc, 1); encode_ch (enc, ' '); SE	261	need (enc, spaces);
153	#define NL SB if (enc->flags & F_INDENT) { need (enc, 1); encode_ch (enc, '\n'); } SE	262	memset (enc->cur, ' ', spaces);
154	#define COMMA SB \	263	enc->cur += spaces;
		264	}
		265	}
		266
		267	inline void
		268	encode_space (enc_t *enc)
		269	{
		270	need (enc, 1);
155	encode_ch (enc, ','); \	271	encode_ch (enc, ' ');
		272	}
		273
		274	inline void
		275	encode_nl (enc_t *enc)
		276	{
156	if (enc->flags & F_INDENT) \	277	if (enc->flags & F_INDENT)
157	NL; \	278	{
		279	need (enc, 1);
		280	encode_ch (enc, '\n');
		281	}
		282	}
		283
		284	inline void
		285	encode_comma (enc_t *enc)
		286	{
		287	encode_ch (enc, ',');
		288
		289	if (enc->flags & F_INDENT)
		290	encode_nl (enc);
158	else if (enc->flags & F_SPACE_AFTER) \	291	else if (enc->flags & F_SPACE_AFTER)
159	SPACE; \	292	encode_space (enc);
160	SE	293	}
161		294
162	static void encode_sv (enc_t enc, SV sv);	295	static void encode_sv (enc_t enc, SV sv);
163		296
164	static void	297	static void
165	encode_av (enc_t enc, AV av)	298	encode_av (enc_t enc, AV av)
166	{	299	{
167	int i, len = av_len (av);	300	int i, len = av_len (av);
168		301
169	encode_ch (enc, '['); NL;	302	if (enc->indent >= enc->maxdepth)
		303	croak ("data structure too deep (hit recursion limit)");
		304
		305	encode_ch (enc, '['); encode_nl (enc);
170	++enc->indent;	306	++enc->indent;
171		307
172	for (i = 0; i <= len; ++i)	308	for (i = 0; i <= len; ++i)
173	{	309	{
174	INDENT;	310	encode_indent (enc);
175	encode_sv (enc, *av_fetch (av, i, 0));	311	encode_sv (enc, *av_fetch (av, i, 0));
176		312
177	if (i < len)	313	if (i < len)
178	COMMA;	314	encode_comma (enc);
179	}	315	}
180		316
181	NL;	317	encode_nl (enc);
182		318
183	--enc->indent;	319	--enc->indent;
184	INDENT; encode_ch (enc, ']');	320	encode_indent (enc); encode_ch (enc, ']');
185	}	321	}
186		322
187	static void	323	static void
188	encode_he (enc_t enc, HE he)	324	encode_he (enc_t enc, HE he)
189	{	325	{
…		…
191		327
192	if (HeKLEN (he) == HEf_SVKEY)	328	if (HeKLEN (he) == HEf_SVKEY)
193	{	329	{
194	SV *sv = HeSVKEY (he);	330	SV *sv = HeSVKEY (he);
195	STRLEN len;	331	STRLEN len;
		332	char *str;
		333
		334	SvGETMAGIC (sv);
196	char *str = SvPV (sv, len);	335	str = SvPV (sv, len);
197		336
198	encode_str (enc, str, len, SvUTF8 (sv));	337	encode_str (enc, str, len, SvUTF8 (sv));
199	}	338	}
200	else	339	else
201	encode_str (enc, HeKEY (he), HeKLEN (he), HeKUTF8 (he));	340	encode_str (enc, HeKEY (he), HeKLEN (he), HeKUTF8 (he));
202		341
203	encode_ch (enc, '"');	342	encode_ch (enc, '"');
204		343
205	if (enc->flags & F_SPACE_BEFORE) SPACE;	344	if (enc->flags & F_SPACE_BEFORE) encode_space (enc);
206	encode_ch (enc, ':');	345	encode_ch (enc, ':');
207	if (enc->flags & F_SPACE_AFTER ) SPACE;	346	if (enc->flags & F_SPACE_AFTER ) encode_space (enc);
208	encode_sv (enc, HeVAL (he));	347	encode_sv (enc, HeVAL (he));
209	}	348	}
210		349
211	// compare hash entries, used when all keys are bytestrings	350	// compare hash entries, used when all keys are bytestrings
212	static int	351	static int
…		…
218	HE b = (HE **)b_;	357	HE b = (HE **)b_;
219		358
220	STRLEN la = HeKLEN (a);	359	STRLEN la = HeKLEN (a);
221	STRLEN lb = HeKLEN (b);	360	STRLEN lb = HeKLEN (b);
222		361
223	if (!(cmp == memcmp (HeKEY (a), HeKEY (b), la < lb ? la : lb)))	362	if (!(cmp = memcmp (HeKEY (a), HeKEY (b), la < lb ? la : lb)))
224	cmp = la < lb ? -1 : la == lb ? 0 : 1;	363	cmp = la - lb;
225		364
226	return cmp;	365	return cmp;
227	}	366	}
228		367
229	// compare hash entries, used when some keys are sv's or utf-x	368	// compare hash entries, used when some keys are sv's or utf-x
…		…
236	static void	375	static void
237	encode_hv (enc_t enc, HV hv)	376	encode_hv (enc_t enc, HV hv)
238	{	377	{
239	int count, i;	378	int count, i;
240		379
		380	if (enc->indent >= enc->maxdepth)
		381	croak ("data structure too deep (hit recursion limit)");
		382
241	encode_ch (enc, '{'); NL; ++enc->indent;	383	encode_ch (enc, '{'); encode_nl (enc); ++enc->indent;
242		384
243	if ((count = hv_iterinit (hv)))	385	if ((count = hv_iterinit (hv)))
244	{	386	{
245	// for canonical output we have to sort by keys first	387	// for canonical output we have to sort by keys first
246	// actually, this is mostly due to the stupid so-called	388	// actually, this is mostly due to the stupid so-called
247	// security workaround added somewhere in 5.8.x.	389	// security workaround added somewhere in 5.8.x.
248	// that randomises hash orderings	390	// that randomises hash orderings
249	if (enc->flags & F_CANONICAL)	391	if (enc->flags & F_CANONICAL)
250	{	392	{
251	HE he, hes [count];
252	int fast = 1;	393	int fast = 1;
		394	HE *he;
		395	#if defined(__BORLANDC__) \|\| defined(_MSC_VER)
		396	HE *hes = _alloca (count sizeof (HE));
		397	#else
		398	HE *hes [count]; // if your compiler dies here, you need to enable C99 mode
		399	#endif
253		400
254	i = 0;	401	i = 0;
255	while ((he = hv_iternext (hv)))	402	while ((he = hv_iternext (hv)))
256	{	403	{
257	hes [i++] = he;	404	hes [i++] = he;
…		…
263		410
264	if (fast)	411	if (fast)
265	qsort (hes, count, sizeof (HE *), he_cmp_fast);	412	qsort (hes, count, sizeof (HE *), he_cmp_fast);
266	else	413	else
267	{	414	{
268	// hack to disable "use bytes"	415	// hack to forcefully disable "use bytes"
269	COP *oldcop = PL_curcop, cop;	416	COP cop = *PL_curcop;
270	cop.op_private = 0;	417	cop.op_private = 0;
		418
		419	ENTER;
		420	SAVETMPS;
		421
		422	SAVEVPTR (PL_curcop);
271	PL_curcop = &cop;	423	PL_curcop = &cop;
272		424
273	SAVETMPS;
274	qsort (hes, count, sizeof (HE *), he_cmp_slow);	425	qsort (hes, count, sizeof (HE *), he_cmp_slow);
		426
275	FREETMPS;	427	FREETMPS;
276		428	LEAVE;
277	PL_curcop = oldcop;
278	}	429	}
279		430
280	for (i = 0; i < count; ++i)	431	for (i = 0; i < count; ++i)
281	{	432	{
282	INDENT;	433	encode_indent (enc);
283	encode_he (enc, hes [i]);	434	encode_he (enc, hes [i]);
284		435
285	if (i < count - 1)	436	if (i < count - 1)
286	COMMA;	437	encode_comma (enc);
287	}	438	}
288		439
289	NL;	440	encode_nl (enc);
290	}	441	}
291	else	442	else
292	{	443	{
293	SV *sv;
294	HE *he = hv_iternext (hv);	444	HE *he = hv_iternext (hv);
295		445
296	for (;;)	446	for (;;)
297	{	447	{
298	INDENT;	448	encode_indent (enc);
299	encode_he (enc, he);	449	encode_he (enc, he);
300		450
301	if (!(he = hv_iternext (hv)))	451	if (!(he = hv_iternext (hv)))
302	break;	452	break;
303		453
304	COMMA;	454	encode_comma (enc);
305	}	455	}
306		456
307	NL;	457	encode_nl (enc);
308	}	458	}
309	}	459	}
310		460
311	--enc->indent; INDENT; encode_ch (enc, '}');	461	--enc->indent; encode_indent (enc); encode_ch (enc, '}');
		462	}
		463
		464	// encode objects, arrays and special \0=false and \1=true values.
		465	static void
		466	encode_rv (enc_t enc, SV sv)
		467	{
		468	svtype svt;
		469
		470	SvGETMAGIC (sv);
		471	svt = SvTYPE (sv);
		472
		473	if (svt == SVt_PVHV)
		474	encode_hv (enc, (HV *)sv);
		475	else if (svt == SVt_PVAV)
		476	encode_av (enc, (AV *)sv);
		477	else if (svt < SVt_PVAV)
		478	{
		479	if (SvNIOK (sv) && SvIV (sv) == 0)
		480	encode_str (enc, "false", 5, 0);
		481	else if (SvNIOK (sv) && SvIV (sv) == 1)
		482	encode_str (enc, "true", 4, 0);
		483	else
		484	croak ("cannot encode reference to scalar '%s' unless the scalar is 0 or 1",
		485	SvPV_nolen (sv_2mortal (newRV_inc (sv))));
		486	}
		487	else
		488	croak ("encountered %s, but JSON can only represent references to arrays or hashes",
		489	SvPV_nolen (sv_2mortal (newRV_inc (sv))));
312	}	490	}
313		491
314	static void	492	static void
315	encode_sv (enc_t enc, SV sv)	493	encode_sv (enc_t enc, SV sv)
316	{	494	{
		495	SvGETMAGIC (sv);
		496
317	if (SvPOKp (sv))	497	if (SvPOKp (sv))
318	{	498	{
319	STRLEN len;	499	STRLEN len;
320	char *str = SvPV (sv, len);	500	char *str = SvPV (sv, len);
321	encode_ch (enc, '"');	501	encode_ch (enc, '"');
322	encode_str (enc, str, len, SvUTF8 (sv));	502	encode_str (enc, str, len, SvUTF8 (sv));
323	encode_ch (enc, '"');	503	encode_ch (enc, '"');
324	}	504	}
325	else if (SvNOKp (sv))	505	else if (SvNOKp (sv))
326	{	506	{
		507	// trust that perl will do the right thing w.r.t. JSON syntax.
327	need (enc, NV_DIG + 32);	508	need (enc, NV_DIG + 32);
328	Gconvert (SvNVX (sv), NV_DIG, 0, enc->cur);	509	Gconvert (SvNVX (sv), NV_DIG, 0, enc->cur);
329	enc->cur += strlen (enc->cur);	510	enc->cur += strlen (enc->cur);
330	}	511	}
331	else if (SvIOKp (sv))	512	else if (SvIOKp (sv))
332	{	513	{
333	need (enc, 64);	514	// we assume we can always read an IV as a UV
		515	if (SvUV (sv) & ~(UV)0x7fff)
		516	{
		517	// large integer, use the (rather slow) snprintf way.
		518	need (enc, sizeof (UV) * 3);
334	enc->cur +=	519	enc->cur +=
335	SvIsUV(sv)	520	SvIsUV(sv)
336	? snprintf (enc->cur, 64, "%"UVuf, (UV)SvUVX (sv))	521	? snprintf (enc->cur, sizeof (UV) * 3, "%"UVuf, (UV)SvUVX (sv))
337	: snprintf (enc->cur, 64, "%"IVdf, (IV)SvIVX (sv));	522	: snprintf (enc->cur, sizeof (UV) * 3, "%"IVdf, (IV)SvIVX (sv));
		523	}
		524	else
		525	{
		526	// optimise the "small number case"
		527	// code will likely be branchless and use only a single multiplication
		528	I32 i = SvIV (sv);
		529	U32 u;
		530	char digit, nz = 0;
		531
		532	need (enc, 6);
		533
		534	*enc->cur = '-'; enc->cur += i < 0 ? 1 : 0;
		535	u = i < 0 ? -i : i;
		536
		537	// convert to 4.28 fixed-point representation
		538	u = u * ((0xfffffff + 10000) / 10000); // 10**5, 5 fractional digits
		539
		540	// now output digit by digit, each time masking out the integer part
		541	// and multiplying by 5 while moving the decimal point one to the right,
		542	// resulting in a net multiplication by 10.
		543	// we always write the digit to memory but conditionally increment
		544	// the pointer, to ease the usage of conditional move instructions.
		545	digit = u >> 28; enc->cur = digit + '0'; enc->cur += (nz = nz \|\| digit); u = (u & 0xfffffff) 5;
		546	digit = u >> 27; enc->cur = digit + '0'; enc->cur += (nz = nz \|\| digit); u = (u & 0x7ffffff) 5;
		547	digit = u >> 26; enc->cur = digit + '0'; enc->cur += (nz = nz \|\| digit); u = (u & 0x3ffffff) 5;
		548	digit = u >> 25; enc->cur = digit + '0'; enc->cur += (nz = nz \|\| digit); u = (u & 0x1ffffff) 5;
		549	digit = u >> 24; *enc->cur = digit + '0'; enc->cur += 1; // correctly generate '0'
		550	}
338	}	551	}
339	else if (SvROK (sv))	552	else if (SvROK (sv))
340	{	553	encode_rv (enc, SvRV (sv));
341	if (!--enc->max_recurse)
342	croak ("data structure too deep (hit recursion limit)");
343
344	sv = SvRV (sv);
345
346	switch (SvTYPE (sv))
347	{
348	case SVt_PVAV: encode_av (enc, (AV *)sv); break;
349	case SVt_PVHV: encode_hv (enc, (HV *)sv); break;
350
351	default:
352	croak ("JSON can only represent references to arrays or hashes");
353	}
354	}
355	else if (!SvOK (sv))	554	else if (!SvOK (sv))
356	encode_str (enc, "null", 4, 0);	555	encode_str (enc, "null", 4, 0);
357	else	556	else
358	croak ("encountered perl type that JSON cannot handle");	557	croak ("encountered perl type (%s,0x%x) that JSON cannot handle, you might want to report this",
		558	SvPV_nolen (sv), SvFLAGS (sv));
359	}	559	}
360		560
361	static SV *	561	static SV *
362	encode_json (SV *scalar, UV flags)	562	encode_json (SV *scalar, U32 flags)
363	{	563	{
364	enc_t enc;	564	enc_t enc;
		565
		566	if (!(flags & F_ALLOW_NONREF) && !SvROK (scalar))
		567	croak ("hash- or arrayref expected (not a simple scalar, use allow_nonref to allow this)");
		568
365	enc.flags = flags;	569	enc.flags = flags;
366	enc.sv = sv_2mortal (NEWSV (0, INIT_SIZE));	570	enc.sv = sv_2mortal (NEWSV (0, INIT_SIZE));
367	enc.cur = SvPVX (enc.sv);	571	enc.cur = SvPVX (enc.sv);
368	enc.end = SvEND (enc.sv);	572	enc.end = SvEND (enc.sv);
369	enc.max_recurse = 0;
370	enc.indent = 0;	573	enc.indent = 0;
		574	enc.maxdepth = DEC_DEPTH (flags);
371		575
372	SvPOK_only (enc.sv);	576	SvPOK_only (enc.sv);
373	encode_sv (&enc, scalar);	577	encode_sv (&enc, scalar);
374		578
		579	SvCUR_set (enc.sv, enc.cur - SvPVX (enc.sv));
		580	*SvEND (enc.sv) = 0; // many xs functions expect a trailing 0 for text strings
		581
375	if (!(flags & (F_ASCII \| F_UTF8)))	582	if (!(flags & (F_ASCII \| F_LATIN1 \| F_UTF8)))
376	SvUTF8_on (enc.sv);	583	SvUTF8_on (enc.sv);
377		584
378	SvCUR_set (enc.sv, enc.cur - SvPVX (enc.sv));	585	if (enc.flags & F_SHRINK)
		586	shrink (enc.sv);
		587
379	return enc.sv;	588	return enc.sv;
380	}	589	}
381		590
382	/////////////////////////////////////////////////////////////////////////////	591	/////////////////////////////////////////////////////////////////////////////
		592	// decoder
383		593
384	#define WS \	594	// structure used for decoding JSON
		595	typedef struct
		596	{
		597	char *cur; // current parser pointer
		598	char *end; // end of input string
		599	const char *err; // parse error, if != 0
		600	U32 flags; // F_*
		601	U32 depth; // recursion depth
		602	U32 maxdepth; // recursion depth limit
		603	} dec_t;
		604
		605	inline void
		606	decode_ws (dec_t *dec)
		607	{
385	for (;;) \	608	for (;;)
386	{ \	609	{
387	char ch = *dec->cur; \	610	char ch = *dec->cur;
		611
388	if (ch > 0x20 \	612	if (ch > 0x20
389	\|\| (ch != 0x20 && ch != 0x0a && ch != 0x0d && ch != 0x09)) \	613	\|\| (ch != 0x20 && ch != 0x0a && ch != 0x0d && ch != 0x09))
390	break; \	614	break;
		615
391	++dec->cur; \	616	++dec->cur;
392	}	617	}
		618	}
393		619
394	#define ERR(reason) SB dec->err = reason; goto fail; SE	620	#define ERR(reason) SB dec->err = reason; goto fail; SE
		621
395	#define EXPECT_CH(ch) SB \	622	#define EXPECT_CH(ch) SB \
396	if (*dec->cur != ch) \	623	if (*dec->cur != ch) \
397	ERR (# ch " expected"); \	624	ERR (# ch " expected"); \
398	++dec->cur; \	625	++dec->cur; \
399	SE	626	SE
400		627
		628	#define DEC_INC_DEPTH if (++dec->depth > dec->maxdepth) ERR ("json datastructure exceeds maximum nesting level (set a higher max_depth)")
		629	#define DEC_DEC_DEPTH --dec->depth
		630
401	static SV decode_sv (dec_t dec);	631	static SV decode_sv (dec_t dec);
402
403	#define APPEND_CH(ch) SB \
404	SvGROW (sv, cur + 1 + 1); \
405	SvPVX (sv)[cur++] = (ch); \
406	SE
407		632
408	static signed char decode_hexdigit[256];	633	static signed char decode_hexdigit[256];
409		634
410	static UV	635	static UV
411	decode_4hex (dec_t *dec)	636	decode_4hex (dec_t *dec)
412	{	637	{
413	signed char d1, d2, d3, d4;	638	signed char d1, d2, d3, d4;
		639	unsigned char cur = (unsigned char )dec->cur;
414		640
415	d1 = decode_hexdigit [((unsigned char *)dec->cur) [0]];	641	d1 = decode_hexdigit [cur [0]]; if (expect_false (d1 < 0)) ERR ("exactly four hexadecimal digits expected");
416	if (d1 < 0) ERR ("four hexadecimal digits expected");	642	d2 = decode_hexdigit [cur [1]]; if (expect_false (d2 < 0)) ERR ("exactly four hexadecimal digits expected");
417	d2 = decode_hexdigit [((unsigned char *)dec->cur) [1]];	643	d3 = decode_hexdigit [cur [2]]; if (expect_false (d3 < 0)) ERR ("exactly four hexadecimal digits expected");
418	if (d2 < 0) ERR ("four hexadecimal digits expected");	644	d4 = decode_hexdigit [cur [3]]; if (expect_false (d4 < 0)) ERR ("exactly four hexadecimal digits expected");
419	d3 = decode_hexdigit [((unsigned char *)dec->cur) [2]];
420	if (d3 < 0) ERR ("four hexadecimal digits expected");
421	d4 = decode_hexdigit [((unsigned char *)dec->cur) [3]];
422	if (d4 < 0) ERR ("four hexadecimal digits expected");
423		645
424	dec->cur += 4;	646	dec->cur += 4;
425		647
426	return ((UV)d1) << 12	648	return ((UV)d1) << 12
427	\| ((UV)d2) << 8	649	\| ((UV)d2) << 8
…		…
433	}	655	}
434		656
435	static SV *	657	static SV *
436	decode_str (dec_t *dec)	658	decode_str (dec_t *dec)
437	{	659	{
438	SV *sv = NEWSV (0,2);	660	SV *sv = 0;
439	STRLEN cur = 0;
440	int utf8 = 0;	661	int utf8 = 0;
		662	char *dec_cur = dec->cur;
441		663
442	for (;;)	664	do
443	{	665	{
444	unsigned char ch = (unsigned char )dec->cur;	666	char buf [SHORT_STRING_LEN + UTF8_MAXBYTES];
		667	char *cur = buf;
445		668
446	if (ch == '"')	669	do
447	break;
448	else if (ch == '\\')
449	{	670	{
450	switch (*++dec->cur)	671	unsigned char ch = (unsigned char )dec_cur++;
		672
		673	if (expect_false (ch == '"'))
451	{	674	{
452	case '\\':	675	--dec_cur;
453	case '/':	676	break;
454	case '"': APPEND_CH (*dec->cur++); break;	677	}
455		678	else if (expect_false (ch == '\\'))
456	case 'b': APPEND_CH ('\010'); ++dec->cur; break;	679	{
457	case 't': APPEND_CH ('\011'); ++dec->cur; break;	680	switch (*dec_cur)
458	case 'n': APPEND_CH ('\012'); ++dec->cur; break;
459	case 'f': APPEND_CH ('\014'); ++dec->cur; break;
460	case 'r': APPEND_CH ('\015'); ++dec->cur; break;
461
462	case 'u':
463	{	681	{
464	UV lo, hi;	682	case '\\':
465	++dec->cur;	683	case '/':
		684	case '"': cur++ = dec_cur++; break;
466		685
467	hi = decode_4hex (dec);	686	case 'b': ++dec_cur; *cur++ = '\010'; break;
468	if (hi == (UV)-1)	687	case 't': ++dec_cur; *cur++ = '\011'; break;
469	goto fail;	688	case 'n': ++dec_cur; *cur++ = '\012'; break;
		689	case 'f': ++dec_cur; *cur++ = '\014'; break;
		690	case 'r': ++dec_cur; *cur++ = '\015'; break;
470		691
471	// possibly a surrogate pair	692	case 'u':
472	if (hi >= 0xd800 && hi < 0xdc00)
473	{	693	{
474	if (dec->cur [0] != '\\' \|\| dec->cur [1] != 'u')	694	UV lo, hi;
475	ERR ("illegal surrogate character");	695	++dec_cur;
476		696
477	dec->cur += 2;	697	dec->cur = dec_cur;
478
479	lo = decode_4hex (dec);	698	hi = decode_4hex (dec);
		699	dec_cur = dec->cur;
480	if (lo == (UV)-1)	700	if (hi == (UV)-1)
481	goto fail;	701	goto fail;
482		702
		703	// possibly a surrogate pair
		704	if (hi >= 0xd800)
		705	if (hi < 0xdc00)
		706	{
		707	if (dec_cur [0] != '\\' \|\| dec_cur [1] != 'u')
		708	ERR ("missing low surrogate character in surrogate pair");
		709
		710	dec_cur += 2;
		711
		712	dec->cur = dec_cur;
		713	lo = decode_4hex (dec);
		714	dec_cur = dec->cur;
		715	if (lo == (UV)-1)
		716	goto fail;
		717
483	if (lo < 0xdc00 \|\| lo >= 0xe000)	718	if (lo < 0xdc00 \|\| lo >= 0xe000)
484	ERR ("surrogate pair expected");	719	ERR ("surrogate pair expected");
485		720
486	hi = (hi - 0xD800) * 0x400 + (lo - 0xDC00) + 0x10000;	721	hi = (hi - 0xD800) * 0x400 + (lo - 0xDC00) + 0x10000;
		722	}
		723	else if (hi < 0xe000)
		724	ERR ("missing high surrogate character in surrogate pair");
		725
		726	if (hi >= 0x80)
		727	{
		728	utf8 = 1;
		729
		730	cur = (char *)uvuni_to_utf8_flags (cur, hi, 0);
		731	}
		732	else
		733	*cur++ = hi;
487	}	734	}
488	else if (lo >= 0xdc00 && lo < 0xe000)
489	ERR ("illegal surrogate character");
490
491	if (hi >= 0x80)
492	{	735	break;
493	utf8 = 1;
494		736
495	SvGROW (sv, cur + 4 + 1); // at most 4 bytes for 21 bits
496	cur = (char *)uvuni_to_utf8_flags (SvPVX (sv) + cur, hi, 0) - SvPVX (sv);
497	}
498	else	737	default:
499	APPEND_CH (hi);	738	--dec_cur;
		739	ERR ("illegal backslash escape sequence in string");
500	}	740	}
		741	}
		742	else if (expect_true (ch >= 0x20 && ch <= 0x7f))
		743	*cur++ = ch;
		744	else if (ch >= 0x80)
		745	{
		746	STRLEN clen;
		747	UV uch;
		748
		749	--dec_cur;
		750
		751	uch = decode_utf8 (dec_cur, dec->end - dec_cur, &clen);
		752	if (clen == (STRLEN)-1)
		753	ERR ("malformed UTF-8 character in JSON string");
		754
		755	do
		756	cur++ = dec_cur++;
		757	while (--clen);
		758
		759	utf8 = 1;
		760	}
		761	else
		762	{
		763	--dec_cur;
		764
		765	if (!ch)
		766	ERR ("unexpected end of string while parsing JSON string");
501	break;	767	else
		768	ERR ("invalid character encountered while parsing JSON string");
502	}	769	}
503	}	770	}
504	else if (ch >= 0x20 && ch <= 0x7f)	771	while (cur < buf + SHORT_STRING_LEN);
505	APPEND_CH (*dec->cur++);	772
506	else if (ch >= 0x80)	773	{
		774	STRLEN len = cur - buf;
		775
		776	if (sv)
507	{	777	{
508	STRLEN clen;	778	SvGROW (sv, SvCUR (sv) + len + 1);
509	UV uch = utf8n_to_uvuni (dec->cur, dec->end - dec->cur, &clen, UTF8_CHECK_ONLY);	779	memcpy (SvPVX (sv) + SvCUR (sv), buf, len);
510	if (clen < 0)	780	SvCUR_set (sv, SvCUR (sv) + len);
511	ERR ("malformed UTF-8 character in string, cannot convert to JSON");
512
513	SvGROW (sv, cur + clen + 1); // at most 4 bytes for 21 bits
514	memcpy (SvPVX (sv) + cur, dec->cur, clen);
515	dec->cur += clen;
516	}	781	}
517	else	782	else
518	ERR ("invalid character encountered");	783	sv = newSVpvn (buf, len);
519	}	784	}
		785	}
		786	while (*dec_cur != '"');
520		787
521	++dec->cur;	788	++dec_cur;
522		789
		790	if (sv)
		791	{
523	SvPOK_only (sv);	792	SvPOK_only (sv);
524
525	SvCUR_set (sv, cur);
526	*SvEND (sv) = 0;	793	*SvEND (sv) = 0;
527		794
528	if (utf8)	795	if (utf8)
529	SvUTF8_on (sv);	796	SvUTF8_on (sv);
		797	}
		798	else
		799	sv = newSVpvn ("", 0);
530		800
		801	dec->cur = dec_cur;
531	return sv;	802	return sv;
532		803
533	fail:	804	fail:
534	SvREFCNT_dec (sv);	805	dec->cur = dec_cur;
535	return 0;	806	return 0;
536	}	807	}
537		808
538	static SV *	809	static SV *
539	decode_num (dec_t *dec)	810	decode_num (dec_t *dec)
…		…
549	{	820	{
550	++dec->cur;	821	++dec->cur;
551	if (dec->cur >= '0' && dec->cur <= '9')	822	if (dec->cur >= '0' && dec->cur <= '9')
552	ERR ("malformed number (leading zero must not be followed by another digit)");	823	ERR ("malformed number (leading zero must not be followed by another digit)");
553	}	824	}
554		825	else if (dec->cur < '0' \|\| dec->cur > '9')
555	// int	826	ERR ("malformed number (no digits after initial minus)");
		827	else
		828	do
		829	{
		830	++dec->cur;
		831	}
556	while (dec->cur >= '0' && dec->cur <= '9')	832	while (dec->cur >= '0' && dec->cur <= '9');
557	++dec->cur;
558		833
559	// [frac]	834	// [frac]
560	if (*dec->cur == '.')	835	if (*dec->cur == '.')
561	{	836	{
562	is_nv = 1;	837	++dec->cur;
		838
		839	if (dec->cur < '0' \|\| dec->cur > '9')
		840	ERR ("malformed number (no digits after decimal point)");
563		841
564	do	842	do
565	{	843	{
566	++dec->cur;	844	++dec->cur;
567	}	845	}
568	while (dec->cur >= '0' && dec->cur <= '9');	846	while (dec->cur >= '0' && dec->cur <= '9');
		847
		848	is_nv = 1;
569	}	849	}
570		850
571	// [exp]	851	// [exp]
572	if (dec->cur == 'e' \|\| dec->cur == 'E')	852	if (dec->cur == 'e' \|\| dec->cur == 'E')
573	{	853	{
574	is_nv = 1;
575
576	++dec->cur;	854	++dec->cur;
		855
577	if (dec->cur == '-' \|\| dec->cur == '+')	856	if (dec->cur == '-' \|\| dec->cur == '+')
578	++dec->cur;	857	++dec->cur;
579		858
		859	if (dec->cur < '0' \|\| dec->cur > '9')
		860	ERR ("malformed number (no digits after exp sign)");
		861
		862	do
		863	{
		864	++dec->cur;
		865	}
580	while (dec->cur >= '0' && dec->cur <= '9')	866	while (dec->cur >= '0' && dec->cur <= '9');
581	++dec->cur;	867
		868	is_nv = 1;
582	}	869	}
583		870
584	if (!is_nv)	871	if (!is_nv)
585	{	872	{
586	UV uv;	873	// special case the rather common 1..4-digit-int case, assumes 32 bit ints or so
587	int numtype = grok_number (start, dec->cur - start, &uv);	874	if (*start == '-')
588	if (numtype & IS_NUMBER_IN_UV)	875	switch (dec->cur - start)
589	if (numtype & IS_NUMBER_NEG)
590	{	876	{
591	if (uv < (UV)IV_MIN)	877	case 2: return newSViv (-( start [1] - '0' * 1));
592	return newSViv (-(IV)uv);	878	case 3: return newSViv (-( start [1] * 10 + start [2] - '0' * 11));
		879	case 4: return newSViv (-( start [1] * 100 + start [2] * 10 + start [3] - '0' * 111));
		880	case 5: return newSViv (-(start [1] * 1000 + start [2] * 100 + start [3] * 10 + start [4] - '0' * 1111));
593	}	881	}
		882	else
		883	switch (dec->cur - start)
		884	{
		885	case 1: return newSViv ( start [0] - '0' * 1);
		886	case 2: return newSViv ( start [0] * 10 + start [1] - '0' * 11);
		887	case 3: return newSViv ( start [0] * 100 + start [1] * 10 + start [2] - '0' * 111);
		888	case 4: return newSViv ( start [0] * 1000 + start [1] * 100 + start [2] * 10 + start [3] - '0' * 1111);
		889	}
		890
		891	{
		892	UV uv;
		893	int numtype = grok_number (start, dec->cur - start, &uv);
		894	if (numtype & IS_NUMBER_IN_UV)
		895	if (numtype & IS_NUMBER_NEG)
		896	{
		897	if (uv < (UV)IV_MIN)
		898	return newSViv (-(IV)uv);
		899	}
594	else	900	else
595	return newSVuv (uv);	901	return newSVuv (uv);
		902
		903	// here would likely be the place for bigint support
596	}	904	}
		905	}
597		906
		907	// if we ever support bigint or bigfloat, this is the place for bigfloat
598	return newSVnv (Atof (start));	908	return newSVnv (Atof (start));
599		909
600	fail:	910	fail:
601	return 0;	911	return 0;
602	}	912	}
…		…
604	static SV *	914	static SV *
605	decode_av (dec_t *dec)	915	decode_av (dec_t *dec)
606	{	916	{
607	AV *av = newAV ();	917	AV *av = newAV ();
608		918
		919	DEC_INC_DEPTH;
		920	decode_ws (dec);
		921
		922	if (*dec->cur == ']')
		923	++dec->cur;
		924	else
609	for (;;)	925	for (;;)
610	{	926	{
611	SV *value;	927	SV *value;
612		928
613	value = decode_sv (dec);	929	value = decode_sv (dec);
614	if (!value)	930	if (!value)
615	goto fail;	931	goto fail;
616		932
617	av_push (av, value);	933	av_push (av, value);
618		934
619	WS;	935	decode_ws (dec);
620		936
621	if (*dec->cur == ']')	937	if (*dec->cur == ']')
622	{	938	{
623	++dec->cur;	939	++dec->cur;
624	break;	940	break;
		941	}
625	}	942
626
627	if (*dec->cur != ',')	943	if (*dec->cur != ',')
628	ERR (", or ] expected while parsing array");	944	ERR (", or ] expected while parsing array");
629		945
630	++dec->cur;	946	++dec->cur;
631	}	947	}
632		948
		949	DEC_DEC_DEPTH;
633	return newRV_noinc ((SV *)av);	950	return newRV_noinc ((SV *)av);
634		951
635	fail:	952	fail:
636	SvREFCNT_dec (av);	953	SvREFCNT_dec (av);
		954	DEC_DEC_DEPTH;
637	return 0;	955	return 0;
638	}	956	}
639		957
640	static SV *	958	static SV *
641	decode_hv (dec_t *dec)	959	decode_hv (dec_t *dec)
642	{	960	{
643	HV *hv = newHV ();	961	HV *hv = newHV ();
644		962
		963	DEC_INC_DEPTH;
		964	decode_ws (dec);
		965
		966	if (*dec->cur == '}')
		967	++dec->cur;
		968	else
645	for (;;)	969	for (;;)
646	{	970	{
647	SV key, value;	971	SV key, value;
648		972
649	WS; EXPECT_CH ('"');	973	decode_ws (dec); EXPECT_CH ('"');
650		974
651	key = decode_str (dec);	975	key = decode_str (dec);
652	if (!key)	976	if (!key)
653	goto fail;
654
655	WS; EXPECT_CH (':');
656
657	value = decode_sv (dec);
658	if (!value)
659	{
660	SvREFCNT_dec (key);
661	goto fail;	977	goto fail;
		978
		979	decode_ws (dec); EXPECT_CH (':');
		980
		981	value = decode_sv (dec);
		982	if (!value)
		983	{
		984	SvREFCNT_dec (key);
		985	goto fail;
662	}	986	}
663		987
664	//TODO: optimise
665	hv_store_ent (hv, key, value, 0);	988	hv_store_ent (hv, key, value, 0);
		989	SvREFCNT_dec (key);
666		990
667	WS;	991	decode_ws (dec);
668		992
669	if (*dec->cur == '}')	993	if (*dec->cur == '}')
670	{	994	{
671	++dec->cur;	995	++dec->cur;
672	break;	996	break;
673	}	997	}
674		998
675	if (*dec->cur != ',')	999	if (*dec->cur != ',')
676	ERR (", or } expected while parsing object/hash");	1000	ERR (", or } expected while parsing object/hash");
677		1001
678	++dec->cur;	1002	++dec->cur;
679	}	1003	}
680		1004
		1005	DEC_DEC_DEPTH;
681	return newRV_noinc ((SV *)hv);	1006	return newRV_noinc ((SV *)hv);
682		1007
683	fail:	1008	fail:
684	SvREFCNT_dec (hv);	1009	SvREFCNT_dec (hv);
		1010	DEC_DEC_DEPTH;
685	return 0;	1011	return 0;
686	}	1012	}
687		1013
688	static SV *	1014	static SV *
689	decode_sv (dec_t *dec)	1015	decode_sv (dec_t *dec)
690	{	1016	{
691	WS;	1017	decode_ws (dec);
		1018
		1019	// the beauty of JSON: you need exactly one character lookahead
		1020	// to parse anything.
692	switch (*dec->cur)	1021	switch (*dec->cur)
693	{	1022	{
694	case '"': ++dec->cur; return decode_str (dec);	1023	case '"': ++dec->cur; return decode_str (dec);
695	case '[': ++dec->cur; return decode_av (dec);	1024	case '[': ++dec->cur; return decode_av (dec);
696	case '{': ++dec->cur; return decode_hv (dec);	1025	case '{': ++dec->cur; return decode_hv (dec);
…		…
724		1053
725	case 'n':	1054	case 'n':
726	if (dec->end - dec->cur >= 4 && !memcmp (dec->cur, "null", 4))	1055	if (dec->end - dec->cur >= 4 && !memcmp (dec->cur, "null", 4))
727	{	1056	{
728	dec->cur += 4;	1057	dec->cur += 4;
729	return newSViv (1);	1058	return newSVsv (&PL_sv_undef);
730	}	1059	}
731	else	1060	else
732	ERR ("'null' expected");	1061	ERR ("'null' expected");
733		1062
734	break;	1063	break;
735		1064
736	default:	1065	default:
737	ERR ("malformed json string");	1066	ERR ("malformed JSON string, neither array, object, number, string or atom");
738	break;	1067	break;
739	}	1068	}
740		1069
741	fail:	1070	fail:
742	return 0;	1071	return 0;
743	}	1072	}
744		1073
745	static SV *	1074	static SV *
746	decode_json (SV *string, UV flags)	1075	decode_json (SV string, U32 flags, UV offset_return)
747	{	1076	{
		1077	dec_t dec;
		1078	UV offset;
748	SV *sv;	1079	SV *sv;
749		1080
		1081	SvGETMAGIC (string);
		1082	SvUPGRADE (string, SVt_PV);
		1083
750	if (!(flags & F_UTF8))	1084	if (flags & F_UTF8)
		1085	sv_utf8_downgrade (string, 0);
		1086	else
751	sv_utf8_upgrade (string);	1087	sv_utf8_upgrade (string);
752		1088
753	SvGROW (string, SvCUR (string) + 1); // should basically be a NOP	1089	SvGROW (string, SvCUR (string) + 1); // should basically be a NOP
754		1090
755	dec_t dec;
756	dec.flags = flags;	1091	dec.flags = flags;
757	dec.cur = SvPVX (string);	1092	dec.cur = SvPVX (string);
758	dec.end = SvEND (string);	1093	dec.end = SvEND (string);
759	dec.err = 0;	1094	dec.err = 0;
		1095	dec.depth = 0;
		1096	dec.maxdepth = DEC_DEPTH (dec.flags);
760		1097
761	*dec.end = 1; // invalid anywhere	1098	*dec.end = 0; // this should basically be a nop, too, but make sure it's there
762	sv = decode_sv (&dec);	1099	sv = decode_sv (&dec);
763	*dec.end = 0;	1100
		1101	if (!(offset_return \|\| !sv))
		1102	{
		1103	// check for trailing garbage
		1104	decode_ws (&dec);
		1105
		1106	if (*dec.cur)
		1107	{
		1108	dec.err = "garbage after JSON object";
		1109	SvREFCNT_dec (sv);
		1110	sv = 0;
		1111	}
		1112	}
		1113
		1114	if (offset_return \|\| !sv)
		1115	{
		1116	offset = dec.flags & F_UTF8
		1117	? dec.cur - SvPVX (string)
		1118	: utf8_distance (dec.cur, SvPVX (string));
		1119
		1120	if (offset_return)
		1121	*offset_return = offset;
		1122	}
764		1123
765	if (!sv)	1124	if (!sv)
766	{	1125	{
767	IV offset = utf8_distance (dec.cur, SvPVX (string));
768	SV *uni = sv_newmortal ();	1126	SV *uni = sv_newmortal ();
769		1127
		1128	// horrible hack to silence warning inside pv_uni_display
		1129	COP cop = *PL_curcop;
		1130	cop.cop_warnings = pWARN_NONE;
		1131	ENTER;
		1132	SAVEVPTR (PL_curcop);
		1133	PL_curcop = &cop;
770	pv_uni_display (uni, dec.cur, dec.end - dec.cur, 20, UNI_DISPLAY_QQ);	1134	pv_uni_display (uni, dec.cur, dec.end - dec.cur, 20, UNI_DISPLAY_QQ);
		1135	LEAVE;
		1136
771	croak ("%s, at character %d (%s)",	1137	croak ("%s, at character offset %d [\"%s\"]",
772	dec.err,	1138	dec.err,
773	(int)offset,	1139	(int)offset,
774	dec.cur != dec.end ? SvPV_nolen (uni) : "(end of string)");	1140	dec.cur != dec.end ? SvPV_nolen (uni) : "(end of string)");
775	}	1141	}
776		1142
777	sv_dump (sv);//D
778	return sv_2mortal (sv);	1143	sv = sv_2mortal (sv);
		1144
		1145	if (!(dec.flags & F_ALLOW_NONREF) && !SvROK (sv))
		1146	croak ("JSON text must be an object or array (but found number, string, true, false or null, use allow_nonref to allow this)");
		1147
		1148	return sv;
779	}	1149	}
		1150
		1151	/////////////////////////////////////////////////////////////////////////////
		1152	// XS interface functions
780		1153
781	MODULE = JSON::XS PACKAGE = JSON::XS	1154	MODULE = JSON::XS PACKAGE = JSON::XS
782		1155
783	BOOT:	1156	BOOT:
784	{	1157	{
785	int i;	1158	int i;
786		1159
787	memset (decode_hexdigit, 0xff, 256);
788	for (i = 10; i--; )	1160	for (i = 0; i < 256; ++i)
789	decode_hexdigit ['0' + i] = i;	1161	decode_hexdigit [i] =
790		1162	i >= '0' && i <= '9' ? i - '0'
791	for (i = 6; --i; )	1163	: i >= 'a' && i <= 'f' ? i - 'a' + 10
792	{	1164	: i >= 'A' && i <= 'F' ? i - 'A' + 10
793	decode_hexdigit ['a' + i] = 10 + i;	1165	: -1;
794	decode_hexdigit ['A' + i] = 10 + i;
795	}
796		1166
797	json_stash = gv_stashpv ("JSON::XS", 1);	1167	json_stash = gv_stashpv ("JSON::XS", 1);
798	}	1168	}
		1169
		1170	PROTOTYPES: DISABLE
799		1171
800	SV new (char dummy)	1172	SV new (char dummy)
801	CODE:	1173	CODE:
802	RETVAL = sv_bless (newRV_noinc (newSVuv (F_DEFAULT)), json_stash);	1174	RETVAL = sv_bless (newRV_noinc (newSVuv (F_DEFAULT)), json_stash);
803	OUTPUT:	1175	OUTPUT:
804	RETVAL	1176	RETVAL
805		1177
806	SV ascii (SV self, int enable)	1178	SV ascii (SV self, int enable = 1)
807	ALIAS:	1179	ALIAS:
808	ascii = F_ASCII	1180	ascii = F_ASCII
		1181	latin1 = F_LATIN1
809	utf8 = F_UTF8	1182	utf8 = F_UTF8
810	indent = F_INDENT	1183	indent = F_INDENT
811	canonical = F_CANONICAL	1184	canonical = F_CANONICAL
812	space_before = F_SPACE_BEFORE	1185	space_before = F_SPACE_BEFORE
813	space_after = F_SPACE_AFTER	1186	space_after = F_SPACE_AFTER
814	json_rpc = F_JSON_RPC
815	pretty = F_PRETTY	1187	pretty = F_PRETTY
		1188	allow_nonref = F_ALLOW_NONREF
		1189	shrink = F_SHRINK
816	CODE:	1190	CODE:
817	{	1191	{
818	UV *uv = SvJSON (self);	1192	UV *uv = SvJSON (self);
819	if (enable)	1193	if (enable)
820	*uv \|= ix;	1194	*uv \|= ix;
…		…
824	RETVAL = newSVsv (self);	1198	RETVAL = newSVsv (self);
825	}	1199	}
826	OUTPUT:	1200	OUTPUT:
827	RETVAL	1201	RETVAL
828		1202
		1203	SV max_depth (SV self, UV max_depth = 0x80000000UL)
		1204	CODE:
		1205	{
		1206	UV *uv = SvJSON (self);
		1207	UV log2 = 0;
		1208
		1209	if (max_depth > 0x80000000UL) max_depth = 0x80000000UL;
		1210
		1211	while ((1UL << log2) < max_depth)
		1212	++log2;
		1213
		1214	uv = uv & ~F_MAXDEPTH \| (log2 << S_MAXDEPTH);
		1215
		1216	RETVAL = newSVsv (self);
		1217	}
		1218	OUTPUT:
		1219	RETVAL
		1220
829	void encode (SV self, SV scalar)	1221	void encode (SV self, SV scalar)
830	PPCODE:	1222	PPCODE:
831	XPUSHs (encode_json (scalar, *SvJSON (self)));	1223	XPUSHs (encode_json (scalar, *SvJSON (self)));
832		1224
833	void decode (SV self, SV jsonstr)	1225	void decode (SV self, SV jsonstr)
834	PPCODE:	1226	PPCODE:
835	XPUSHs (decode_json (jsonstr, *SvJSON (self)));	1227	XPUSHs (decode_json (jsonstr, *SvJSON (self), 0));
		1228
		1229	void decode_prefix (SV self, SV jsonstr)
		1230	PPCODE:
		1231	{
		1232	UV offset;
		1233	EXTEND (SP, 2);
		1234	PUSHs (decode_json (jsonstr, *SvJSON (self), &offset));
		1235	PUSHs (sv_2mortal (newSVuv (offset)));
		1236	}
		1237
		1238	PROTOTYPES: ENABLE
836		1239
837	void to_json (SV *scalar)	1240	void to_json (SV *scalar)
		1241	ALIAS:
		1242	objToJson = 0
838	PPCODE:	1243	PPCODE:
839	XPUSHs (encode_json (scalar, F_UTF8));	1244	XPUSHs (encode_json (scalar, F_DEFAULT \| F_UTF8));
840		1245
841	void from_json (SV *jsonstr)	1246	void from_json (SV *jsonstr)
		1247	ALIAS:
		1248	jsonToObj = 0
842	PPCODE:	1249	PPCODE:
843	XPUSHs (decode_json (jsonstr, F_UTF8));	1250	XPUSHs (decode_json (jsonstr, F_DEFAULT \| F_UTF8, 0));
844		1251

Diff Legend

-–
+Removed lines
-+
+Added lines
-<
+Changed lines
->
+Changed lines

Comparing JSON-XS/XS.xs (file contents): Revision 1.2 by root, Thu Mar 22 17:28:50 2007 UTC vs. Revision 1.41 by root, Sat Jun 23 22:53:16 2007 UTC

Diff Legend

Comparing JSON-XS/XS.xs (file contents):
Revision 1.2 by root, Thu Mar 22 17:28:50 2007 UTC vs.
Revision 1.41 by root, Sat Jun 23 22:53:16 2007 UTC