cache.c: read(2) returns -1 on error, not 0

Noticed-by: Jim Meyering <jim@meyering.net> Signed-off-by: Lars Hjemli <hjemli@gmail.com>
author: Lars Hjemli <hjemli@gmail.com> 2008-05-18 21:10:05 (UTC)
committer: Lars Hjemli <hjemli@gmail.com> 2008-05-18 21:10:05 (UTC)
commit: 6102bcfce46fd357566941d565b95f78510af79b (patch) (unidiff)
tree: 95794eda3bdf84e72a6fb32bfa96fb4e0cb147b9
parent: c3de425acbc4ae1190ca99e733a72da56c6a082b (diff)
download: cgit-6102bcfce46fd357566941d565b95f78510af79b.zip
cgit-6102bcfce46fd357566941d565b95f78510af79b.tar.gz
cgit-6102bcfce46fd357566941d565b95f78510af79b.tar.bz2
1 files changed, 1 insertions, 1 deletions
diff --git a/cache.c b/cache.c
index b701e13..add647e 100644
--- a/cache.c
+++ b/cache.c
@@ -1,247 +1,247 @@
 /* cache.c: cache management
 *
 * Copyright (C) 2006 Lars Hjemli
 *
 * Licensed under GNU General Public License v2
 *   (see COPYING for full license text)
 *
 *
 * The cache is just a directory structure where each file is a cache slot,
 * and each filename is based on the hash of some key (e.g. the cgit url).
 * Each file contains the full key followed by the cached content for that
 * key.
 *
 */
 #include "cgit.h"
 #include "cache.h"
 #define CACHE_BUFSIZE (1024 * 4)
 struct cache_slot {
        const char *key;
        int keylen;
        int ttl;
        cache_fill_fn fn;
        void *cbdata;
        int cache_fd;
        int lock_fd;
        const char *cache_name;
        const char *lock_name;
        int match;
        struct stat cache_st;
        struct stat lock_st;
        int bufsize;
        char buf[CACHE_BUFSIZE];
 };
 /* Open an existing cache slot and fill the cache buffer with
 * (part of) the content of the cache file. Return 0 on success
 * and errno otherwise.
 */
 static int open_slot(struct cache_slot *slot)
 {
        char *bufz;
        int bufkeylen = -1;
        slot->cache_fd = open(slot->cache_name, O_RDONLY);
        if (slot->cache_fd == -1)
                return errno;
        if (fstat(slot->cache_fd, &slot->cache_st))
                return errno;
        slot->bufsize = read(slot->cache_fd, slot->buf, sizeof(slot->buf));
-        if (slot->bufsize == 0)
+        if (slot->bufsize < 0)
                return errno;
        bufz = memchr(slot->buf, 0, slot->bufsize);
        if (bufz)
                bufkeylen = bufz - slot->buf;
        slot->match = bufkeylen == slot->keylen &&
            !memcmp(slot->key, slot->buf, bufkeylen + 1);
        return 0;
 }
 /* Close the active cache slot */
 static void close_slot(struct cache_slot *slot)
 {
        if (slot->cache_fd > 0) {
                close(slot->cache_fd);
                slot->cache_fd = -1;
        }
 }
 /* Print the content of the active cache slot (but skip the key). */
 static int print_slot(struct cache_slot *slot)
 {
        ssize_t i, j = 0;
        i = lseek(slot->cache_fd, slot->keylen + 1, SEEK_SET);
        if (i != slot->keylen + 1)
                return errno;
        while((i=read(slot->cache_fd, slot->buf, sizeof(slot->buf))) > 0)
                j = write(STDOUT_FILENO, slot->buf, i);
        if (j < 0)
                return errno;
        else
                return 0;
 }
 /* Check if the slot has expired */
 static int is_expired(struct cache_slot *slot)
 {
        if (slot->ttl < 0)
                return 0;
        else
                return slot->cache_st.st_mtime + slot->ttl*60 < time(NULL);
 }
 /* Check if the slot has been modified since we opened it.
 * NB: If stat() fails, we pretend the file is modified.
 */
 static int is_modified(struct cache_slot *slot)
 {
        struct stat st;
        if (stat(slot->cache_name, &st))
                return 1;
        return (st.st_ino != slot->cache_st.st_ino ||
                st.st_mtime != slot->cache_st.st_mtime ||
                st.st_size != slot->cache_st.st_size);
 }
 /* Close an open lockfile */
 static void close_lock(struct cache_slot *slot)
 {
        if (slot->lock_fd > 0) {
                close(slot->lock_fd);
                slot->lock_fd = -1;
        }
 }
 /* Create a lockfile used to store the generated content for a cache
 * slot, and write the slot key + \0 into it.
 * Returns 0 on success and errno otherwise.
 */
 static int lock_slot(struct cache_slot *slot)
 {
        slot->lock_fd = open(slot->lock_name, O_RDWR|O_CREAT|O_EXCL,
                             S_IRUSR|S_IWUSR);
        if (slot->lock_fd == -1)
                return errno;
        write(slot->lock_fd, slot->key, slot->keylen + 1);
        return 0;
 }
 /* Release the current lockfile. If `replace_old_slot` is set the
 * lockfile replaces the old cache slot, otherwise the lockfile is
 * just deleted.
 */
 static int unlock_slot(struct cache_slot *slot, int replace_old_slot)
 {
        int err;
        if (replace_old_slot)
                err = rename(slot->lock_name, slot->cache_name);
        else
                err = unlink(slot->lock_name);
        return err;
 }
 /* Generate the content for the current cache slot by redirecting
 * stdout to the lock-fd and invoking the callback function
 */
 static int fill_slot(struct cache_slot *slot)
 {
        int tmp;
        /* Preserve stdout */
        tmp = dup(STDOUT_FILENO);
        if (tmp == -1)
                return errno;
        /* Redirect stdout to lockfile */
        if (dup2(slot->lock_fd, STDOUT_FILENO) == -1)
                return errno;
        /* Generate cache content */
        slot->fn(slot->cbdata);
        /* Restore stdout */
        if (dup2(tmp, STDOUT_FILENO) == -1)
                return errno;
        /* Close the temporary filedescriptor */
        close(tmp);
        return 0;
 }
 /* Crude implementation of 32-bit FNV-1 hash algorithm,
 * see http://www.isthe.com/chongo/tech/comp/fnv/ for details
 * about the magic numbers.
 */
 #define FNV_OFFSET 0x811c9dc5
 #define FNV_PRIME  0x01000193
 unsigned long hash_str(const char *str)
 {
        unsigned long h = FNV_OFFSET;
        unsigned char *s = (unsigned char *)str;
        if (!s)
                return h;
        while(*s) {
                h *= FNV_PRIME;
                h ^= *s++;
        }
        return h;
 }
 static int process_slot(struct cache_slot *slot)
 {
        int err;
        err = open_slot(slot);
        if (!err && slot->match) {
                if (is_expired(slot)) {
                        if (!lock_slot(slot)) {
                                /* If the cachefile has been replaced between
                                 * `open_slot` and `lock_slot`, we'll just
                                 * serve the stale content from the original
                                 * cachefile. This way we avoid pruning the
                                 * newly generated slot. The same code-path
                                 * is chosen if fill_slot() fails for some
                                 * reason.
                                 *
                                 * TODO? check if the new slot contains the
                                 * same key as the old one, since we would
                                 * prefer to serve the newest content.
                                 * This will require us to open yet another
                                 * file-descriptor and read and compare the
                                 * key from the new file, so for now we're
                                 * lazy and just ignore the new file.
                                 */
                                if (is_modified(slot) || fill_slot(slot)) {
                                        unlock_slot(slot, 0);
                                        close_lock(slot);
                                } else {
                                        close_slot(slot);
                                        unlock_slot(slot, 1);
                                        slot->cache_fd = slot->lock_fd;
                                }
                        }
                }
                print_slot(slot);
                close_slot(slot);
                return 0;
        }
        /* If the cache slot does not exist (or its key doesn't match the
         * current key), lets try to create a new cache slot for this
         * request. If this fails (for whatever reason), lets just generate
author	Lars Hjemli <hjemli@gmail.com>	2008-05-18 21:10:05 (UTC)
committer	Lars Hjemli <hjemli@gmail.com>	2008-05-18 21:10:05 (UTC)
commit	6102bcfce46fd357566941d565b95f78510af79b (patch) (unidiff)
tree	95794eda3bdf84e72a6fb32bfa96fb4e0cb147b9
parent	c3de425acbc4ae1190ca99e733a72da56c6a082b (diff)
download	cgit-6102bcfce46fd357566941d565b95f78510af79b.zip cgit-6102bcfce46fd357566941d565b95f78510af79b.tar.gz cgit-6102bcfce46fd357566941d565b95f78510af79b.tar.bz2

diff --git a/cache.c b/cache.c index b701e13..add647e 100644 --- a/cache.c +++ b/cache.c
@@ -1,247 +1,247 @@
1	/* cache.c: cache management	1	/* cache.c: cache management
2	*	2	*
3	* Copyright (C) 2006 Lars Hjemli	3	* Copyright (C) 2006 Lars Hjemli
4	*	4	*
5	* Licensed under GNU General Public License v2	5	* Licensed under GNU General Public License v2
6	* (see COPYING for full license text)	6	* (see COPYING for full license text)
7	*	7	*
8	*	8	*
9	* The cache is just a directory structure where each file is a cache slot,	9	* The cache is just a directory structure where each file is a cache slot,
10	* and each filename is based on the hash of some key (e.g. the cgit url).	10	* and each filename is based on the hash of some key (e.g. the cgit url).
11	* Each file contains the full key followed by the cached content for that	11	* Each file contains the full key followed by the cached content for that
12	* key.	12	* key.
13	*	13	*
14	*/	14	*/
15		15
16	#include "cgit.h"	16	#include "cgit.h"
17	#include "cache.h"	17	#include "cache.h"
18		18
19	#define CACHE_BUFSIZE (1024 * 4)	19	#define CACHE_BUFSIZE (1024 * 4)
20		20
21	struct cache_slot {	21	struct cache_slot {
22	const char *key;	22	const char *key;
23	int keylen;	23	int keylen;
24	int ttl;	24	int ttl;
25	cache_fill_fn fn;	25	cache_fill_fn fn;
26	void *cbdata;	26	void *cbdata;
27	int cache_fd;	27	int cache_fd;
28	int lock_fd;	28	int lock_fd;
29	const char *cache_name;	29	const char *cache_name;
30	const char *lock_name;	30	const char *lock_name;
31	int match;	31	int match;
32	struct stat cache_st;	32	struct stat cache_st;
33	struct stat lock_st;	33	struct stat lock_st;
34	int bufsize;	34	int bufsize;
35	char buf[CACHE_BUFSIZE];	35	char buf[CACHE_BUFSIZE];
36	};	36	};
37		37
38	/* Open an existing cache slot and fill the cache buffer with	38	/* Open an existing cache slot and fill the cache buffer with
39	* (part of) the content of the cache file. Return 0 on success	39	* (part of) the content of the cache file. Return 0 on success
40	* and errno otherwise.	40	* and errno otherwise.
41	*/	41	*/
42	static int open_slot(struct cache_slot *slot)	42	static int open_slot(struct cache_slot *slot)
43	{	43	{
44	char *bufz;	44	char *bufz;
45	int bufkeylen = -1;	45	int bufkeylen = -1;
46		46
47	slot->cache_fd = open(slot->cache_name, O_RDONLY);	47	slot->cache_fd = open(slot->cache_name, O_RDONLY);
48	if (slot->cache_fd == -1)	48	if (slot->cache_fd == -1)
49	return errno;	49	return errno;
50		50
51	if (fstat(slot->cache_fd, &slot->cache_st))	51	if (fstat(slot->cache_fd, &slot->cache_st))
52	return errno;	52	return errno;
53		53
54	slot->bufsize = read(slot->cache_fd, slot->buf, sizeof(slot->buf));	54	slot->bufsize = read(slot->cache_fd, slot->buf, sizeof(slot->buf));
55	if (slot->bufsize == 0)	55	if (slot->bufsize < 0)
56	return errno;	56	return errno;
57		57
58	bufz = memchr(slot->buf, 0, slot->bufsize);	58	bufz = memchr(slot->buf, 0, slot->bufsize);
59	if (bufz)	59	if (bufz)
60	bufkeylen = bufz - slot->buf;	60	bufkeylen = bufz - slot->buf;
61		61
62	slot->match = bufkeylen == slot->keylen &&	62	slot->match = bufkeylen == slot->keylen &&
63	!memcmp(slot->key, slot->buf, bufkeylen + 1);	63	!memcmp(slot->key, slot->buf, bufkeylen + 1);
64		64
65	return 0;	65	return 0;
66	}	66	}
67		67
68	/* Close the active cache slot */	68	/* Close the active cache slot */
69	static void close_slot(struct cache_slot *slot)	69	static void close_slot(struct cache_slot *slot)
70	{	70	{
71	if (slot->cache_fd > 0) {	71	if (slot->cache_fd > 0) {
72	close(slot->cache_fd);	72	close(slot->cache_fd);
73	slot->cache_fd = -1;	73	slot->cache_fd = -1;
74	}	74	}
75	}	75	}
76		76
77	/* Print the content of the active cache slot (but skip the key). */	77	/* Print the content of the active cache slot (but skip the key). */
78	static int print_slot(struct cache_slot *slot)	78	static int print_slot(struct cache_slot *slot)
79	{	79	{
80	ssize_t i, j = 0;	80	ssize_t i, j = 0;
81		81
82	i = lseek(slot->cache_fd, slot->keylen + 1, SEEK_SET);	82	i = lseek(slot->cache_fd, slot->keylen + 1, SEEK_SET);
83	if (i != slot->keylen + 1)	83	if (i != slot->keylen + 1)
84	return errno;	84	return errno;
85		85
86	while((i=read(slot->cache_fd, slot->buf, sizeof(slot->buf))) > 0)	86	while((i=read(slot->cache_fd, slot->buf, sizeof(slot->buf))) > 0)
87	j = write(STDOUT_FILENO, slot->buf, i);	87	j = write(STDOUT_FILENO, slot->buf, i);
88		88
89	if (j < 0)	89	if (j < 0)
90	return errno;	90	return errno;
91	else	91	else
92	return 0;	92	return 0;
93	}	93	}
94		94
95	/* Check if the slot has expired */	95	/* Check if the slot has expired */
96	static int is_expired(struct cache_slot *slot)	96	static int is_expired(struct cache_slot *slot)
97	{	97	{
98	if (slot->ttl < 0)	98	if (slot->ttl < 0)
99	return 0;	99	return 0;
100	else	100	else
101	return slot->cache_st.st_mtime + slot->ttl*60 < time(NULL);	101	return slot->cache_st.st_mtime + slot->ttl*60 < time(NULL);
102	}	102	}
103		103
104	/* Check if the slot has been modified since we opened it.	104	/* Check if the slot has been modified since we opened it.
105	* NB: If stat() fails, we pretend the file is modified.	105	* NB: If stat() fails, we pretend the file is modified.
106	*/	106	*/
107	static int is_modified(struct cache_slot *slot)	107	static int is_modified(struct cache_slot *slot)
108	{	108	{
109	struct stat st;	109	struct stat st;
110		110
111	if (stat(slot->cache_name, &st))	111	if (stat(slot->cache_name, &st))
112	return 1;	112	return 1;
113	return (st.st_ino != slot->cache_st.st_ino \|\|	113	return (st.st_ino != slot->cache_st.st_ino \|\|
114	st.st_mtime != slot->cache_st.st_mtime \|\|	114	st.st_mtime != slot->cache_st.st_mtime \|\|
115	st.st_size != slot->cache_st.st_size);	115	st.st_size != slot->cache_st.st_size);
116	}	116	}
117		117
118	/* Close an open lockfile */	118	/* Close an open lockfile */
119	static void close_lock(struct cache_slot *slot)	119	static void close_lock(struct cache_slot *slot)
120	{	120	{
121	if (slot->lock_fd > 0) {	121	if (slot->lock_fd > 0) {
122	close(slot->lock_fd);	122	close(slot->lock_fd);
123	slot->lock_fd = -1;	123	slot->lock_fd = -1;
124	}	124	}
125	}	125	}
126		126
127	/* Create a lockfile used to store the generated content for a cache	127	/* Create a lockfile used to store the generated content for a cache
128	* slot, and write the slot key + \0 into it.	128	* slot, and write the slot key + \0 into it.
129	* Returns 0 on success and errno otherwise.	129	* Returns 0 on success and errno otherwise.
130	*/	130	*/
131	static int lock_slot(struct cache_slot *slot)	131	static int lock_slot(struct cache_slot *slot)
132	{	132	{
133	slot->lock_fd = open(slot->lock_name, O_RDWR\|O_CREAT\|O_EXCL,	133	slot->lock_fd = open(slot->lock_name, O_RDWR\|O_CREAT\|O_EXCL,
134	S_IRUSR\|S_IWUSR);	134	S_IRUSR\|S_IWUSR);
135	if (slot->lock_fd == -1)	135	if (slot->lock_fd == -1)
136	return errno;	136	return errno;
137	write(slot->lock_fd, slot->key, slot->keylen + 1);	137	write(slot->lock_fd, slot->key, slot->keylen + 1);
138	return 0;	138	return 0;
139	}	139	}
140		140
141	/* Release the current lockfile. If `replace_old_slot` is set the	141	/* Release the current lockfile. If `replace_old_slot` is set the
142	* lockfile replaces the old cache slot, otherwise the lockfile is	142	* lockfile replaces the old cache slot, otherwise the lockfile is
143	* just deleted.	143	* just deleted.
144	*/	144	*/
145	static int unlock_slot(struct cache_slot *slot, int replace_old_slot)	145	static int unlock_slot(struct cache_slot *slot, int replace_old_slot)
146	{	146	{
147	int err;	147	int err;
148		148
149	if (replace_old_slot)	149	if (replace_old_slot)
150	err = rename(slot->lock_name, slot->cache_name);	150	err = rename(slot->lock_name, slot->cache_name);
151	else	151	else
152	err = unlink(slot->lock_name);	152	err = unlink(slot->lock_name);
153	return err;	153	return err;
154	}	154	}
155		155
156	/* Generate the content for the current cache slot by redirecting	156	/* Generate the content for the current cache slot by redirecting
157	* stdout to the lock-fd and invoking the callback function	157	* stdout to the lock-fd and invoking the callback function
158	*/	158	*/
159	static int fill_slot(struct cache_slot *slot)	159	static int fill_slot(struct cache_slot *slot)
160	{	160	{
161	int tmp;	161	int tmp;
162		162
163	/* Preserve stdout */	163	/* Preserve stdout */
164	tmp = dup(STDOUT_FILENO);	164	tmp = dup(STDOUT_FILENO);
165	if (tmp == -1)	165	if (tmp == -1)
166	return errno;	166	return errno;
167		167
168	/* Redirect stdout to lockfile */	168	/* Redirect stdout to lockfile */
169	if (dup2(slot->lock_fd, STDOUT_FILENO) == -1)	169	if (dup2(slot->lock_fd, STDOUT_FILENO) == -1)
170	return errno;	170	return errno;
171		171
172	/* Generate cache content */	172	/* Generate cache content */
173	slot->fn(slot->cbdata);	173	slot->fn(slot->cbdata);
174		174
175	/* Restore stdout */	175	/* Restore stdout */
176	if (dup2(tmp, STDOUT_FILENO) == -1)	176	if (dup2(tmp, STDOUT_FILENO) == -1)
177	return errno;	177	return errno;
178		178
179	/* Close the temporary filedescriptor */	179	/* Close the temporary filedescriptor */
180	close(tmp);	180	close(tmp);
181	return 0;	181	return 0;
182	}	182	}
183		183
184	/* Crude implementation of 32-bit FNV-1 hash algorithm,	184	/* Crude implementation of 32-bit FNV-1 hash algorithm,
185	* see http://www.isthe.com/chongo/tech/comp/fnv/ for details	185	* see http://www.isthe.com/chongo/tech/comp/fnv/ for details
186	* about the magic numbers.	186	* about the magic numbers.
187	*/	187	*/
188	#define FNV_OFFSET 0x811c9dc5	188	#define FNV_OFFSET 0x811c9dc5
189	#define FNV_PRIME 0x01000193	189	#define FNV_PRIME 0x01000193
190		190
191	unsigned long hash_str(const char *str)	191	unsigned long hash_str(const char *str)
192	{	192	{
193	unsigned long h = FNV_OFFSET;	193	unsigned long h = FNV_OFFSET;
194	unsigned char s = (unsigned char )str;	194	unsigned char s = (unsigned char )str;
195		195
196	if (!s)	196	if (!s)
197	return h;	197	return h;
198		198
199	while(*s) {	199	while(*s) {
200	h *= FNV_PRIME;	200	h *= FNV_PRIME;
201	h ^= *s++;	201	h ^= *s++;
202	}	202	}
203	return h;	203	return h;
204	}	204	}
205		205
206	static int process_slot(struct cache_slot *slot)	206	static int process_slot(struct cache_slot *slot)
207	{	207	{
208	int err;	208	int err;
209		209
210	err = open_slot(slot);	210	err = open_slot(slot);
211	if (!err && slot->match) {	211	if (!err && slot->match) {
212	if (is_expired(slot)) {	212	if (is_expired(slot)) {
213	if (!lock_slot(slot)) {	213	if (!lock_slot(slot)) {
214	/* If the cachefile has been replaced between	214	/* If the cachefile has been replaced between
215	* `open_slot` and `lock_slot`, we'll just	215	* `open_slot` and `lock_slot`, we'll just
216	* serve the stale content from the original	216	* serve the stale content from the original
217	* cachefile. This way we avoid pruning the	217	* cachefile. This way we avoid pruning the
218	* newly generated slot. The same code-path	218	* newly generated slot. The same code-path
219	* is chosen if fill_slot() fails for some	219	* is chosen if fill_slot() fails for some
220	* reason.	220	* reason.
221	*	221	*
222	* TODO? check if the new slot contains the	222	* TODO? check if the new slot contains the
223	* same key as the old one, since we would	223	* same key as the old one, since we would
224	* prefer to serve the newest content.	224	* prefer to serve the newest content.
225	* This will require us to open yet another	225	* This will require us to open yet another
226	* file-descriptor and read and compare the	226	* file-descriptor and read and compare the
227	* key from the new file, so for now we're	227	* key from the new file, so for now we're
228	* lazy and just ignore the new file.	228	* lazy and just ignore the new file.
229	*/	229	*/
230	if (is_modified(slot) \|\| fill_slot(slot)) {	230	if (is_modified(slot) \|\| fill_slot(slot)) {
231	unlock_slot(slot, 0);	231	unlock_slot(slot, 0);
232	close_lock(slot);	232	close_lock(slot);
233	} else {	233	} else {
234	close_slot(slot);	234	close_slot(slot);
235	unlock_slot(slot, 1);	235	unlock_slot(slot, 1);
236	slot->cache_fd = slot->lock_fd;	236	slot->cache_fd = slot->lock_fd;
237	}	237	}
238	}	238	}
239	}	239	}
240	print_slot(slot);	240	print_slot(slot);
241	close_slot(slot);	241	close_slot(slot);
242	return 0;	242	return 0;
243	}	243	}
244		244
245	/* If the cache slot does not exist (or its key doesn't match the	245	/* If the cache slot does not exist (or its key doesn't match the
246	* current key), lets try to create a new cache slot for this	246	* current key), lets try to create a new cache slot for this
247	* request. If this fails (for whatever reason), lets just generate	247	* request. If this fails (for whatever reason), lets just generate