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-rw-r--r--cache.c427
-rw-r--r--cache.h38
-rw-r--r--cgit.c166
-rw-r--r--cgit.h1
-rw-r--r--cmd.c21
-rwxr-xr-xtests/setup.sh2
-rwxr-xr-xtests/t0020-validate-cache.sh67
7 files changed, 506 insertions, 216 deletions
diff --git a/cache.c b/cache.c
index 89f7ecd..b701e13 100644
--- a/cache.c
+++ b/cache.c
@@ -4,117 +4,408 @@
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 *
8 *
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).
11 * Each file contains the full key followed by the cached content for that
12 * key.
13 *
7 */ 14 */
8 15
9#include "cgit.h" 16#include "cgit.h"
10#include "cache.h" 17#include "cache.h"
11 18
12const int NOLOCK = -1; 19#define CACHE_BUFSIZE (1024 * 4)
13 20
14char *cache_safe_filename(const char *unsafe) 21struct cache_slot {
22 const char *key;
23 int keylen;
24 int ttl;
25 cache_fill_fn fn;
26 void *cbdata;
27 int cache_fd;
28 int lock_fd;
29 const char *cache_name;
30 const char *lock_name;
31 int match;
32 struct stat cache_st;
33 struct stat lock_st;
34 int bufsize;
35 char buf[CACHE_BUFSIZE];
36};
37
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
40 * and errno otherwise.
41 */
42static int open_slot(struct cache_slot *slot)
15{ 43{
16 static char buf[4][PATH_MAX]; 44 char *bufz;
17 static int bufidx; 45 int bufkeylen = -1;
18 char *s; 46
19 char c; 47 slot->cache_fd = open(slot->cache_name, O_RDONLY);
20 48 if (slot->cache_fd == -1)
21 bufidx++; 49 return errno;
22 bufidx &= 3; 50
23 s = buf[bufidx]; 51 if (fstat(slot->cache_fd, &slot->cache_st))
24 52 return errno;
25 while(unsafe && (c = *unsafe++) != 0) { 53
26 if (c == '/' || c == ' ' || c == '&' || c == '|' || 54 slot->bufsize = read(slot->cache_fd, slot->buf, sizeof(slot->buf));
27 c == '>' || c == '<' || c == '.') 55 if (slot->bufsize == 0)
28 c = '_'; 56 return errno;
29 *s++ = c; 57
30 } 58 bufz = memchr(slot->buf, 0, slot->bufsize);
31 *s = '\0'; 59 if (bufz)
32 return buf[bufidx]; 60 bufkeylen = bufz - slot->buf;
61
62 slot->match = bufkeylen == slot->keylen &&
63 !memcmp(slot->key, slot->buf, bufkeylen + 1);
64
65 return 0;
33} 66}
34 67
35int cache_exist(struct cacheitem *item) 68/* Close the active cache slot */
69static void close_slot(struct cache_slot *slot)
36{ 70{
37 if (stat(item->name, &item->st)) { 71 if (slot->cache_fd > 0) {
38 item->st.st_mtime = 0; 72 close(slot->cache_fd);
39 return 0; 73 slot->cache_fd = -1;
40 } 74 }
41 return 1;
42} 75}
43 76
44int cache_create_dirs() 77/* Print the content of the active cache slot (but skip the key). */
78static int print_slot(struct cache_slot *slot)
45{ 79{
46 char *path; 80 ssize_t i, j = 0;
81
82 i = lseek(slot->cache_fd, slot->keylen + 1, SEEK_SET);
83 if (i != slot->keylen + 1)
84 return errno;
85
86 while((i=read(slot->cache_fd, slot->buf, sizeof(slot->buf))) > 0)
87 j = write(STDOUT_FILENO, slot->buf, i);
47 88
48 path = fmt("%s", ctx.cfg.cache_root); 89 if (j < 0)
49 if (mkdir(path, S_IRWXU) && errno!=EEXIST) 90 return errno;
91 else
50 return 0; 92 return 0;
93}
51 94
52 if (!ctx.repo) 95/* Check if the slot has expired */
96static int is_expired(struct cache_slot *slot)
97{
98 if (slot->ttl < 0)
53 return 0; 99 return 0;
100 else
101 return slot->cache_st.st_mtime + slot->ttl*60 < time(NULL);
102}
54 103
55 path = fmt("%s/%s", ctx.cfg.cache_root, 104/* Check if the slot has been modified since we opened it.
56 cache_safe_filename(ctx.repo->url)); 105 * NB: If stat() fails, we pretend the file is modified.
106 */
107static int is_modified(struct cache_slot *slot)
108{
109 struct stat st;
57 110
58 if (mkdir(path, S_IRWXU) && errno!=EEXIST) 111 if (stat(slot->cache_name, &st))
59 return 0; 112 return 1;
113 return (st.st_ino != slot->cache_st.st_ino ||
114 st.st_mtime != slot->cache_st.st_mtime ||
115 st.st_size != slot->cache_st.st_size);
116}
60 117
61 if (ctx.qry.page) { 118/* Close an open lockfile */
62 path = fmt("%s/%s/%s", ctx.cfg.cache_root, 119static void close_lock(struct cache_slot *slot)
63 cache_safe_filename(ctx.repo->url), 120{
64 ctx.qry.page); 121 if (slot->lock_fd > 0) {
65 if (mkdir(path, S_IRWXU) && errno!=EEXIST) 122 close(slot->lock_fd);
66 return 0; 123 slot->lock_fd = -1;
67 } 124 }
68 return 1;
69} 125}
70 126
71int cache_refill_overdue(const char *lockfile) 127/* Create a lockfile used to store the generated content for a cache
128 * slot, and write the slot key + \0 into it.
129 * Returns 0 on success and errno otherwise.
130 */
131static int lock_slot(struct cache_slot *slot)
72{ 132{
73 struct stat st; 133 slot->lock_fd = open(slot->lock_name, O_RDWR|O_CREAT|O_EXCL,
134 S_IRUSR|S_IWUSR);
135 if (slot->lock_fd == -1)
136 return errno;
137 write(slot->lock_fd, slot->key, slot->keylen + 1);
138 return 0;
139}
74 140
75 if (stat(lockfile, &st)) 141/* Release the current lockfile. If `replace_old_slot` is set the
76 return 0; 142 * lockfile replaces the old cache slot, otherwise the lockfile is
143 * just deleted.
144 */
145static int unlock_slot(struct cache_slot *slot, int replace_old_slot)
146{
147 int err;
148
149 if (replace_old_slot)
150 err = rename(slot->lock_name, slot->cache_name);
77 else 151 else
78 return (time(NULL) - st.st_mtime > ctx.cfg.cache_max_create_time); 152 err = unlink(slot->lock_name);
153 return err;
79} 154}
80 155
81int cache_lock(struct cacheitem *item) 156/* Generate the content for the current cache slot by redirecting
157 * stdout to the lock-fd and invoking the callback function
158 */
159static int fill_slot(struct cache_slot *slot)
82{ 160{
83 int i = 0; 161 int tmp;
84 char *lockfile = xstrdup(fmt("%s.lock", item->name));
85 162
86 top: 163 /* Preserve stdout */
87 if (++i > ctx.cfg.max_lock_attempts) 164 tmp = dup(STDOUT_FILENO);
88 die("cache_lock: unable to lock %s: %s", 165 if (tmp == -1)
89 item->name, strerror(errno)); 166 return errno;
90 167
91 item->fd = open(lockfile, O_WRONLY|O_CREAT|O_EXCL, S_IRUSR|S_IWUSR); 168 /* Redirect stdout to lockfile */
169 if (dup2(slot->lock_fd, STDOUT_FILENO) == -1)
170 return errno;
92 171
93 if (item->fd == NOLOCK && errno == ENOENT && cache_create_dirs()) 172 /* Generate cache content */
94 goto top; 173 slot->fn(slot->cbdata);
95 174
96 if (item->fd == NOLOCK && errno == EEXIST && 175 /* Restore stdout */
97 cache_refill_overdue(lockfile) && !unlink(lockfile)) 176 if (dup2(tmp, STDOUT_FILENO) == -1)
98 goto top; 177 return errno;
99 178
100 free(lockfile); 179 /* Close the temporary filedescriptor */
101 return (item->fd > 0); 180 close(tmp);
181 return 0;
102} 182}
103 183
104int cache_unlock(struct cacheitem *item) 184/* Crude implementation of 32-bit FNV-1 hash algorithm,
185 * see http://www.isthe.com/chongo/tech/comp/fnv/ for details
186 * about the magic numbers.
187 */
188#define FNV_OFFSET 0x811c9dc5
189#define FNV_PRIME 0x01000193
190
191unsigned long hash_str(const char *str)
105{ 192{
106 close(item->fd); 193 unsigned long h = FNV_OFFSET;
107 return (rename(fmt("%s.lock", item->name), item->name) == 0); 194 unsigned char *s = (unsigned char *)str;
195
196 if (!s)
197 return h;
198
199 while(*s) {
200 h *= FNV_PRIME;
201 h ^= *s++;
202 }
203 return h;
108} 204}
109 205
110int cache_cancel_lock(struct cacheitem *item) 206static int process_slot(struct cache_slot *slot)
111{ 207{
112 return (unlink(fmt("%s.lock", item->name)) == 0); 208 int err;
209
210 err = open_slot(slot);
211 if (!err && slot->match) {
212 if (is_expired(slot)) {
213 if (!lock_slot(slot)) {
214 /* If the cachefile has been replaced between
215 * `open_slot` and `lock_slot`, we'll just
216 * serve the stale content from the original
217 * cachefile. This way we avoid pruning the
218 * newly generated slot. The same code-path
219 * is chosen if fill_slot() fails for some
220 * reason.
221 *
222 * TODO? check if the new slot contains the
223 * same key as the old one, since we would
224 * prefer to serve the newest content.
225 * This will require us to open yet another
226 * file-descriptor and read and compare the
227 * key from the new file, so for now we're
228 * lazy and just ignore the new file.
229 */
230 if (is_modified(slot) || fill_slot(slot)) {
231 unlock_slot(slot, 0);
232 close_lock(slot);
233 } else {
234 close_slot(slot);
235 unlock_slot(slot, 1);
236 slot->cache_fd = slot->lock_fd;
237 }
238 }
239 }
240 print_slot(slot);
241 close_slot(slot);
242 return 0;
243 }
244
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
247 * request. If this fails (for whatever reason), lets just generate
248 * the content without caching it and fool the caller to belive
249 * everything worked out (but print a warning on stdout).
250 */
251
252 close_slot(slot);
253 if ((err = lock_slot(slot)) != 0) {
254 cache_log("[cgit] Unable to lock slot %s: %s (%d)\n",
255 slot->lock_name, strerror(err), err);
256 slot->fn(slot->cbdata);
257 return 0;
258 }
259
260 if ((err = fill_slot(slot)) != 0) {
261 cache_log("[cgit] Unable to fill slot %s: %s (%d)\n",
262 slot->lock_name, strerror(err), err);
263 unlock_slot(slot, 0);
264 close_lock(slot);
265 slot->fn(slot->cbdata);
266 return 0;
267 }
268 // We've got a valid cache slot in the lock file, which
269 // is about to replace the old cache slot. But if we
270 // release the lockfile and then try to open the new cache
271 // slot, we might get a race condition with a concurrent
272 // writer for the same cache slot (with a different key).
273 // Lets avoid such a race by just printing the content of
274 // the lock file.
275 slot->cache_fd = slot->lock_fd;
276 unlock_slot(slot, 1);
277 err = print_slot(slot);
278 close_slot(slot);
279 return err;
113} 280}
114 281
115int cache_expired(struct cacheitem *item) 282/* Print cached content to stdout, generate the content if necessary. */
283int cache_process(int size, const char *path, const char *key, int ttl,
284 cache_fill_fn fn, void *cbdata)
116{ 285{
117 if (item->ttl < 0) 286 unsigned long hash;
287 int len, i;
288 char filename[1024];
289 char lockname[1024 + 5]; /* 5 = ".lock" */
290 struct cache_slot slot;
291
292 /* If the cache is disabled, just generate the content */
293 if (size <= 0) {
294 fn(cbdata);
295 return 0;
296 }
297
298 /* Verify input, calculate filenames */
299 if (!path) {
300 cache_log("[cgit] Cache path not specified, caching is disabled\n");
301 fn(cbdata);
118 return 0; 302 return 0;
119 return item->st.st_mtime + item->ttl * 60 < time(NULL); 303 }
304 len = strlen(path);
305 if (len > sizeof(filename) - 10) { /* 10 = "/01234567\0" */
306 cache_log("[cgit] Cache path too long, caching is disabled: %s\n",
307 path);
308 fn(cbdata);
309 return 0;
310 }
311 if (!key)
312 key = "";
313 hash = hash_str(key) % size;
314 strcpy(filename, path);
315 if (filename[len - 1] != '/')
316 filename[len++] = '/';
317 for(i = 0; i < 8; i++) {
318 sprintf(filename + len++, "%x",
319 (unsigned char)(hash & 0xf));
320 hash >>= 4;
321 }
322 filename[len] = '\0';
323 strcpy(lockname, filename);
324 strcpy(lockname + len, ".lock");
325 slot.fn = fn;
326 slot.cbdata = cbdata;
327 slot.ttl = ttl;
328 slot.cache_name = filename;
329 slot.lock_name = lockname;
330 slot.key = key;
331 slot.keylen = strlen(key);
332 return process_slot(&slot);
120} 333}
334
335/* Return a strftime formatted date/time
336 * NB: the result from this function is to shared memory
337 */
338char *sprintftime(const char *format, time_t time)
339{
340 static char buf[64];
341 struct tm *tm;
342
343 if (!time)
344 return NULL;
345 tm = gmtime(&time);
346 strftime(buf, sizeof(buf)-1, format, tm);
347 return buf;
348}
349
350int cache_ls(const char *path)
351{
352 DIR *dir;
353 struct dirent *ent;
354 int err = 0;
355 struct cache_slot slot;
356 char fullname[1024];
357 char *name;
358
359 if (!path) {
360 cache_log("[cgit] cache path not specified\n");
361 return -1;