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1 /*
2  * Copyright © 2014 Intel Corporation
3  *
4  * Permission is hereby granted, free of charge, to any person obtaining a
5  * copy of this software and associated documentation files (the "Software"),
6  * to deal in the Software without restriction, including without limitation
7  * the rights to use, copy, modify, merge, publish, distribute, sublicense,
8  * and/or sell copies of the Software, and to permit persons to whom the
9  * Software is furnished to do so, subject to the following conditions:
10  *
11  * The above copyright notice and this permission notice (including the next
12  * paragraph) shall be included in all copies or substantial portions of the
13  * Software.
14  *
15  * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
16  * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
17  * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.  IN NO EVENT SHALL
18  * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
19  * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
20  * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
21  * IN THE SOFTWARE.
22  */
23 
24 #ifdef ENABLE_SHADER_CACHE
25 
26 #include <assert.h>
27 #include <inttypes.h>
28 #include <stdbool.h>
29 #include <stddef.h>
30 #include <stdlib.h>
31 #include <sys/types.h>
32 #include <sys/stat.h>
33 #include <dirent.h>
34 #include <fcntl.h>
35 
36 #include "util/compress.h"
37 #include "util/crc32.h"
38 
39 struct cache_entry_file_data {
40    uint32_t crc32;
41    uint32_t uncompressed_size;
42 };
43 
44 #if DETECT_OS_WINDOWS
45 /* TODO: implement disk cache support on windows */
46 
47 #else
48 
49 #include <dirent.h>
50 #include <errno.h>
51 #include <pwd.h>
52 #include <stdio.h>
53 #include <string.h>
54 #include <sys/file.h>
55 #include <sys/mman.h>
56 #include <sys/types.h>
57 #include <sys/stat.h>
58 #include <unistd.h>
59 
60 #include "util/blob.h"
61 #include "util/crc32.h"
62 #include "util/debug.h"
63 #include "util/disk_cache.h"
64 #include "util/disk_cache_os.h"
65 #include "util/ralloc.h"
66 #include "util/rand_xor.h"
67 
68 /* Create a directory named 'path' if it does not already exist.
69  *
70  * Returns: 0 if path already exists as a directory or if created.
71  *         -1 in all other cases.
72  */
73 static int
mkdir_if_needed(const char * path)74 mkdir_if_needed(const char *path)
75 {
76    struct stat sb;
77 
78    /* If the path exists already, then our work is done if it's a
79     * directory, but it's an error if it is not.
80     */
81    if (stat(path, &sb) == 0) {
82       if (S_ISDIR(sb.st_mode)) {
83          return 0;
84       } else {
85          fprintf(stderr, "Cannot use %s for shader cache (not a directory)"
86                          "---disabling.\n", path);
87          return -1;
88       }
89    }
90 
91    int ret = mkdir(path, 0755);
92    if (ret == 0 || (ret == -1 && errno == EEXIST))
93      return 0;
94 
95    fprintf(stderr, "Failed to create %s for shader cache (%s)---disabling.\n",
96            path, strerror(errno));
97 
98    return -1;
99 }
100 
101 /* Concatenate an existing path and a new name to form a new path.  If the new
102  * path does not exist as a directory, create it then return the resulting
103  * name of the new path (ralloc'ed off of 'ctx').
104  *
105  * Returns NULL on any error, such as:
106  *
107  *      <path> does not exist or is not a directory
108  *      <path>/<name> exists but is not a directory
109  *      <path>/<name> cannot be created as a directory
110  */
111 static char *
concatenate_and_mkdir(void * ctx,const char * path,const char * name)112 concatenate_and_mkdir(void *ctx, const char *path, const char *name)
113 {
114    char *new_path;
115    struct stat sb;
116 
117    if (stat(path, &sb) != 0 || ! S_ISDIR(sb.st_mode))
118       return NULL;
119 
120    new_path = ralloc_asprintf(ctx, "%s/%s", path, name);
121 
122    if (mkdir_if_needed(new_path) == 0)
123       return new_path;
124    else
125       return NULL;
126 }
127 
128 struct lru_file {
129    struct list_head node;
130    char *lru_name;
131    size_t lru_file_size;
132    time_t lru_atime;
133 };
134 
135 static void
free_lru_file_list(struct list_head * lru_file_list)136 free_lru_file_list(struct list_head *lru_file_list)
137 {
138    struct lru_file *e, *next;
139    LIST_FOR_EACH_ENTRY_SAFE(e, next, lru_file_list, node) {
140       free(e->lru_name);
141       free(e);
142    }
143    free(lru_file_list);
144 }
145 
146 /* Given a directory path and predicate function, create a linked list of entrys
147  * with the oldest access time in that directory for which the predicate
148  * returns true.
149  *
150  * Returns: A malloc'ed linkd list for the paths of chosen files, (or
151  * NULL on any error). The caller should free the linked list via
152  * free_lru_file_list() when finished.
153  */
154 static struct list_head *
choose_lru_file_matching(const char * dir_path,bool (* predicate)(const char * dir_path,const struct stat *,const char *,const size_t))155 choose_lru_file_matching(const char *dir_path,
156                          bool (*predicate)(const char *dir_path,
157                                            const struct stat *,
158                                            const char *, const size_t))
159 {
160    DIR *dir;
161    struct dirent *dir_ent;
162 
163    dir = opendir(dir_path);
164    if (dir == NULL)
165       return NULL;
166 
167    /* First count the number of files in the directory */
168    unsigned total_file_count = 0;
169    while ((dir_ent = readdir(dir)) != NULL) {
170       if (dir_ent->d_type == DT_REG) { /* If the entry is a regular file */
171          total_file_count++;
172       }
173    }
174 
175    /* Reset to the start of the directory */
176    rewinddir(dir);
177 
178    /* Collect 10% of files in this directory for removal. Note: This should work
179     * out to only be around 0.04% of total cache items.
180     */
181    unsigned lru_file_count = total_file_count > 10 ? total_file_count / 10 : 1;
182    struct list_head *lru_file_list = malloc(sizeof(struct list_head));
183    list_inithead(lru_file_list);
184 
185    unsigned processed_files = 0;
186    while (1) {
187       dir_ent = readdir(dir);
188       if (dir_ent == NULL)
189          break;
190 
191       struct stat sb;
192       if (fstatat(dirfd(dir), dir_ent->d_name, &sb, 0) == 0) {
193          struct lru_file *entry = NULL;
194          if (!list_is_empty(lru_file_list))
195             entry = list_first_entry(lru_file_list, struct lru_file, node);
196 
197          if (!entry|| sb.st_atime < entry->lru_atime) {
198             size_t len = strlen(dir_ent->d_name);
199             if (!predicate(dir_path, &sb, dir_ent->d_name, len))
200                continue;
201 
202             bool new_entry = false;
203             if (processed_files < lru_file_count) {
204                entry = calloc(1, sizeof(struct lru_file));
205                new_entry = true;
206             }
207             processed_files++;
208 
209             char *tmp = realloc(entry->lru_name, len + 1);
210             if (tmp) {
211                /* Find location to insert new lru item. We want to keep the
212                 * list ordering from most recently used to least recently used.
213                 * This allows us to just evict the head item from the list as
214                 * we process the directory and find older entrys.
215                 */
216                struct list_head *list_node = lru_file_list;
217                struct lru_file *e;
218                LIST_FOR_EACH_ENTRY(e, lru_file_list, node) {
219                   if (sb.st_atime < entry->lru_atime) {
220                      list_node = &e->node;
221                      break;
222                   }
223                }
224 
225                if (new_entry) {
226                   list_addtail(&entry->node, list_node);
227                } else {
228                   if (list_node != lru_file_list) {
229                      list_del(lru_file_list);
230                      list_addtail(lru_file_list, list_node);
231                   }
232                }
233 
234                entry->lru_name = tmp;
235                memcpy(entry->lru_name, dir_ent->d_name, len + 1);
236                entry->lru_atime = sb.st_atime;
237                entry->lru_file_size = sb.st_blocks * 512;
238             }
239          }
240       }
241    }
242 
243    if (list_is_empty(lru_file_list)) {
244       closedir(dir);
245       free(lru_file_list);
246       return NULL;
247    }
248 
249    /* Create the full path for the file list we found */
250    struct lru_file *e;
251    LIST_FOR_EACH_ENTRY(e, lru_file_list, node) {
252       char *filename = e->lru_name;
253       if (asprintf(&e->lru_name, "%s/%s", dir_path, filename) < 0)
254          e->lru_name = NULL;
255 
256       free(filename);
257    }
258 
259    closedir(dir);
260 
261    return lru_file_list;
262 }
263 
264 /* Is entry a regular file, and not having a name with a trailing
265  * ".tmp"
266  */
267 static bool
is_regular_non_tmp_file(const char * path,const struct stat * sb,const char * d_name,const size_t len)268 is_regular_non_tmp_file(const char *path, const struct stat *sb,
269                         const char *d_name, const size_t len)
270 {
271    if (!S_ISREG(sb->st_mode))
272       return false;
273 
274    if (len >= 4 && strcmp(&d_name[len-4], ".tmp") == 0)
275       return false;
276 
277    return true;
278 }
279 
280 /* Returns the size of the deleted file, (or 0 on any error). */
281 static size_t
unlink_lru_file_from_directory(const char * path)282 unlink_lru_file_from_directory(const char *path)
283 {
284    struct list_head *lru_file_list =
285       choose_lru_file_matching(path, is_regular_non_tmp_file);
286    if (lru_file_list == NULL)
287       return 0;
288 
289    assert(!list_is_empty(lru_file_list));
290 
291    size_t total_unlinked_size = 0;
292    struct lru_file *e;
293    LIST_FOR_EACH_ENTRY(e, lru_file_list, node) {
294       if (unlink(e->lru_name) == 0)
295          total_unlinked_size += e->lru_file_size;
296    }
297    free_lru_file_list(lru_file_list);
298 
299    return total_unlinked_size;
300 }
301 
302 /* Is entry a directory with a two-character name, (and not the
303  * special name of ".."). We also return false if the dir is empty.
304  */
305 static bool
is_two_character_sub_directory(const char * path,const struct stat * sb,const char * d_name,const size_t len)306 is_two_character_sub_directory(const char *path, const struct stat *sb,
307                                const char *d_name, const size_t len)
308 {
309    if (!S_ISDIR(sb->st_mode))
310       return false;
311 
312    if (len != 2)
313       return false;
314 
315    if (strcmp(d_name, "..") == 0)
316       return false;
317 
318    char *subdir;
319    if (asprintf(&subdir, "%s/%s", path, d_name) == -1)
320       return false;
321    DIR *dir = opendir(subdir);
322    free(subdir);
323 
324    if (dir == NULL)
325      return false;
326 
327    unsigned subdir_entries = 0;
328    struct dirent *d;
329    while ((d = readdir(dir)) != NULL) {
330       if(++subdir_entries > 2)
331          break;
332    }
333    closedir(dir);
334 
335    /* If dir only contains '.' and '..' it must be empty */
336    if (subdir_entries <= 2)
337       return false;
338 
339    return true;
340 }
341 
342 /* Create the directory that will be needed for the cache file for \key.
343  *
344  * Obviously, the implementation here must closely match
345  * _get_cache_file above.
346 */
347 static void
make_cache_file_directory(struct disk_cache * cache,const cache_key key)348 make_cache_file_directory(struct disk_cache *cache, const cache_key key)
349 {
350    char *dir;
351    char buf[41];
352 
353    _mesa_sha1_format(buf, key);
354    if (asprintf(&dir, "%s/%c%c", cache->path, buf[0], buf[1]) == -1)
355       return;
356 
357    mkdir_if_needed(dir);
358    free(dir);
359 }
360 
361 static ssize_t
read_all(int fd,void * buf,size_t count)362 read_all(int fd, void *buf, size_t count)
363 {
364    char *in = buf;
365    ssize_t read_ret;
366    size_t done;
367 
368    for (done = 0; done < count; done += read_ret) {
369       read_ret = read(fd, in + done, count - done);
370       if (read_ret == -1 || read_ret == 0)
371          return -1;
372    }
373    return done;
374 }
375 
376 static ssize_t
write_all(int fd,const void * buf,size_t count)377 write_all(int fd, const void *buf, size_t count)
378 {
379    const char *out = buf;
380    ssize_t written;
381    size_t done;
382 
383    for (done = 0; done < count; done += written) {
384       written = write(fd, out + done, count - done);
385       if (written == -1)
386          return -1;
387    }
388    return done;
389 }
390 
391 /* Evict least recently used cache item */
392 void
disk_cache_evict_lru_item(struct disk_cache * cache)393 disk_cache_evict_lru_item(struct disk_cache *cache)
394 {
395    char *dir_path;
396 
397    /* With a reasonably-sized, full cache, (and with keys generated
398     * from a cryptographic hash), we can choose two random hex digits
399     * and reasonably expect the directory to exist with a file in it.
400     * Provides pseudo-LRU eviction to reduce checking all cache files.
401     */
402    uint64_t rand64 = rand_xorshift128plus(cache->seed_xorshift128plus);
403    if (asprintf(&dir_path, "%s/%02" PRIx64 , cache->path, rand64 & 0xff) < 0)
404       return;
405 
406    size_t size = unlink_lru_file_from_directory(dir_path);
407 
408    free(dir_path);
409 
410    if (size) {
411       p_atomic_add(cache->size, - (uint64_t)size);
412       return;
413    }
414 
415    /* In the case where the random choice of directory didn't find
416     * something, we choose the least recently accessed from the
417     * existing directories.
418     *
419     * Really, the only reason this code exists is to allow the unit
420     * tests to work, (which use an artificially-small cache to be able
421     * to force a single cached item to be evicted).
422     */
423    struct list_head *lru_file_list =
424       choose_lru_file_matching(cache->path, is_two_character_sub_directory);
425    if (lru_file_list == NULL)
426       return;
427 
428    assert(!list_is_empty(lru_file_list));
429 
430    struct lru_file *lru_file_dir =
431       list_first_entry(lru_file_list, struct lru_file, node);
432 
433    size = unlink_lru_file_from_directory(lru_file_dir->lru_name);
434 
435    free_lru_file_list(lru_file_list);
436 
437    if (size)
438       p_atomic_add(cache->size, - (uint64_t)size);
439 }
440 
441 void
disk_cache_evict_item(struct disk_cache * cache,char * filename)442 disk_cache_evict_item(struct disk_cache *cache, char *filename)
443 {
444    struct stat sb;
445    if (stat(filename, &sb) == -1) {
446       free(filename);
447       return;
448    }
449 
450    unlink(filename);
451    free(filename);
452 
453    if (sb.st_blocks)
454       p_atomic_add(cache->size, - (uint64_t)sb.st_blocks * 512);
455 }
456 
457 static void *
parse_and_validate_cache_item(struct disk_cache * cache,void * cache_item,size_t cache_item_size,size_t * size)458 parse_and_validate_cache_item(struct disk_cache *cache, void *cache_item,
459                               size_t cache_item_size, size_t *size)
460 {
461    uint8_t *uncompressed_data = NULL;
462 
463    struct blob_reader ci_blob_reader;
464    blob_reader_init(&ci_blob_reader, cache_item, cache_item_size);
465 
466    size_t header_size = cache->driver_keys_blob_size;
467    const void *keys_blob = blob_read_bytes(&ci_blob_reader, header_size);
468    if (ci_blob_reader.overrun)
469       goto fail;
470 
471    /* Check for extremely unlikely hash collisions */
472    if (memcmp(cache->driver_keys_blob, keys_blob, header_size) != 0) {
473       assert(!"Mesa cache keys mismatch!");
474       goto fail;
475    }
476 
477    uint32_t md_type = blob_read_uint32(&ci_blob_reader);
478    if (ci_blob_reader.overrun)
479       goto fail;
480 
481    if (md_type == CACHE_ITEM_TYPE_GLSL) {
482       uint32_t num_keys = blob_read_uint32(&ci_blob_reader);
483       if (ci_blob_reader.overrun)
484          goto fail;
485 
486       /* The cache item metadata is currently just used for distributing
487        * precompiled shaders, they are not used by Mesa so just skip them for
488        * now.
489        * TODO: pass the metadata back to the caller and do some basic
490        * validation.
491        */
492       const void UNUSED *metadata =
493          blob_read_bytes(&ci_blob_reader, num_keys * sizeof(cache_key));
494       if (ci_blob_reader.overrun)
495          goto fail;
496    }
497 
498    /* Load the CRC that was created when the file was written. */
499    struct cache_entry_file_data *cf_data =
500       (struct cache_entry_file_data *)
501          blob_read_bytes(&ci_blob_reader, sizeof(struct cache_entry_file_data));
502    if (ci_blob_reader.overrun)
503       goto fail;
504 
505    size_t cache_data_size = ci_blob_reader.end - ci_blob_reader.current;
506    const uint8_t *data = (uint8_t *) blob_read_bytes(&ci_blob_reader, cache_data_size);
507 
508    /* Check the data for corruption */
509    if (cf_data->crc32 != util_hash_crc32(data, cache_data_size))
510       goto fail;
511 
512    /* Uncompress the cache data */
513    uncompressed_data = malloc(cf_data->uncompressed_size);
514    if (!util_compress_inflate(data, cache_data_size, uncompressed_data,
515                               cf_data->uncompressed_size))
516       goto fail;
517 
518    if (size)
519       *size = cf_data->uncompressed_size;
520 
521    return uncompressed_data;
522 
523  fail:
524    if (uncompressed_data)
525       free(uncompressed_data);
526 
527    return NULL;
528 }
529 
530 void *
disk_cache_load_item(struct disk_cache * cache,char * filename,size_t * size)531 disk_cache_load_item(struct disk_cache *cache, char *filename, size_t *size)
532 {
533    uint8_t *data = NULL;
534 
535    int fd = open(filename, O_RDONLY | O_CLOEXEC);
536    if (fd == -1)
537       goto fail;
538 
539    struct stat sb;
540    if (fstat(fd, &sb) == -1)
541       goto fail;
542 
543    data = malloc(sb.st_size);
544    if (data == NULL)
545       goto fail;
546 
547    /* Read entire file into memory */
548    int ret = read_all(fd, data, sb.st_size);
549    if (ret == -1)
550       goto fail;
551 
552     uint8_t *uncompressed_data =
553        parse_and_validate_cache_item(cache, data, sb.st_size, size);
554    if (!uncompressed_data)
555       goto fail;
556 
557    free(data);
558    free(filename);
559    close(fd);
560 
561    return uncompressed_data;
562 
563  fail:
564    if (data)
565       free(data);
566    if (filename)
567       free(filename);
568    if (fd != -1)
569       close(fd);
570 
571    return NULL;
572 }
573 
574 /* Return a filename within the cache's directory corresponding to 'key'.
575  *
576  * Returns NULL if out of memory.
577  */
578 char *
disk_cache_get_cache_filename(struct disk_cache * cache,const cache_key key)579 disk_cache_get_cache_filename(struct disk_cache *cache, const cache_key key)
580 {
581    char buf[41];
582    char *filename;
583 
584    if (cache->path_init_failed)
585       return NULL;
586 
587    _mesa_sha1_format(buf, key);
588    if (asprintf(&filename, "%s/%c%c/%s", cache->path, buf[0],
589                 buf[1], buf + 2) == -1)
590       return NULL;
591 
592    return filename;
593 }
594 
595 static bool
create_cache_item_header_and_blob(struct disk_cache_put_job * dc_job,struct blob * cache_blob)596 create_cache_item_header_and_blob(struct disk_cache_put_job *dc_job,
597                                   struct blob *cache_blob)
598 {
599 
600    /* Compress the cache item data */
601    size_t max_buf = util_compress_max_compressed_len(dc_job->size);
602    void *compressed_data = malloc(max_buf);
603    if (compressed_data == NULL)
604       return false;
605 
606    size_t compressed_size =
607       util_compress_deflate(dc_job->data, dc_job->size,
608                             compressed_data, max_buf);
609    if (compressed_size == 0)
610       goto fail;
611 
612    /* Copy the driver_keys_blob, this can be used find information about the
613     * mesa version that produced the entry or deal with hash collisions,
614     * should that ever become a real problem.
615     */
616    if (!blob_write_bytes(cache_blob, dc_job->cache->driver_keys_blob,
617                          dc_job->cache->driver_keys_blob_size))
618       goto fail;
619 
620    /* Write the cache item metadata. This data can be used to deal with
621     * hash collisions, as well as providing useful information to 3rd party
622     * tools reading the cache files.
623     */
624    if (!blob_write_uint32(cache_blob, dc_job->cache_item_metadata.type))
625       goto fail;
626 
627    if (dc_job->cache_item_metadata.type == CACHE_ITEM_TYPE_GLSL) {
628       if (!blob_write_uint32(cache_blob, dc_job->cache_item_metadata.num_keys))
629          goto fail;
630 
631       size_t metadata_keys_size =
632          dc_job->cache_item_metadata.num_keys * sizeof(cache_key);
633       if (!blob_write_bytes(cache_blob, dc_job->cache_item_metadata.keys[0],
634                             metadata_keys_size))
635          goto fail;
636    }
637 
638    /* Create CRC of the compressed data. We will read this when restoring the
639     * cache and use it to check for corruption.
640     */
641    struct cache_entry_file_data cf_data;
642    cf_data.crc32 = util_hash_crc32(compressed_data, compressed_size);
643    cf_data.uncompressed_size = dc_job->size;
644 
645    if (!blob_write_bytes(cache_blob, &cf_data, sizeof(cf_data)))
646       goto fail;
647 
648    /* Finally copy the compressed cache blob */
649    if (!blob_write_bytes(cache_blob, compressed_data, compressed_size))
650       goto fail;
651 
652    free(compressed_data);
653    return true;
654 
655  fail:
656    free(compressed_data);
657    return false;
658 }
659 
660 void
disk_cache_write_item_to_disk(struct disk_cache_put_job * dc_job,char * filename)661 disk_cache_write_item_to_disk(struct disk_cache_put_job *dc_job,
662                               char *filename)
663 {
664    int fd = -1, fd_final = -1;
665    struct blob cache_blob;
666    blob_init(&cache_blob);
667 
668    /* Write to a temporary file to allow for an atomic rename to the
669     * final destination filename, (to prevent any readers from seeing
670     * a partially written file).
671     */
672    char *filename_tmp = NULL;
673    if (asprintf(&filename_tmp, "%s.tmp", filename) == -1)
674       goto done;
675 
676    fd = open(filename_tmp, O_WRONLY | O_CLOEXEC | O_CREAT, 0644);
677 
678    /* Make the two-character subdirectory within the cache as needed. */
679    if (fd == -1) {
680       if (errno != ENOENT)
681          goto done;
682 
683       make_cache_file_directory(dc_job->cache, dc_job->key);
684 
685       fd = open(filename_tmp, O_WRONLY | O_CLOEXEC | O_CREAT, 0644);
686       if (fd == -1)
687          goto done;
688    }
689 
690    /* With the temporary file open, we take an exclusive flock on
691     * it. If the flock fails, then another process still has the file
692     * open with the flock held. So just let that file be responsible
693     * for writing the file.
694     */
695 #ifdef HAVE_FLOCK
696    int err = flock(fd, LOCK_EX | LOCK_NB);
697 #else
698    struct flock lock = {
699       .l_start = 0,
700       .l_len = 0, /* entire file */
701       .l_type = F_WRLCK,
702       .l_whence = SEEK_SET
703    };
704    int err = fcntl(fd, F_SETLK, &lock);
705 #endif
706    if (err == -1)
707       goto done;
708 
709    /* Now that we have the lock on the open temporary file, we can
710     * check to see if the destination file already exists. If so,
711     * another process won the race between when we saw that the file
712     * didn't exist and now. In this case, we don't do anything more,
713     * (to ensure the size accounting of the cache doesn't get off).
714     */
715    fd_final = open(filename, O_RDONLY | O_CLOEXEC);
716    if (fd_final != -1) {
717       unlink(filename_tmp);
718       goto done;
719    }
720 
721    /* OK, we're now on the hook to write out a file that we know is
722     * not in the cache, and is also not being written out to the cache
723     * by some other process.
724     */
725    if (!create_cache_item_header_and_blob(dc_job, &cache_blob)) {
726       unlink(filename_tmp);
727       goto done;
728    }
729 
730    /* Now, finally, write out the contents to the temporary file, then
731     * rename them atomically to the destination filename, and also
732     * perform an atomic increment of the total cache size.
733     */
734    int ret = write_all(fd, cache_blob.data, cache_blob.size);
735    if (ret == -1) {
736       unlink(filename_tmp);
737       goto done;
738    }
739 
740    ret = rename(filename_tmp, filename);
741    if (ret == -1) {
742       unlink(filename_tmp);
743       goto done;
744    }
745 
746    struct stat sb;
747    if (stat(filename, &sb) == -1) {
748       /* Something went wrong remove the file */
749       unlink(filename);
750       goto done;
751    }
752 
753    p_atomic_add(dc_job->cache->size, sb.st_blocks * 512);
754 
755  done:
756    if (fd_final != -1)
757       close(fd_final);
758    /* This close finally releases the flock, (now that the final file
759     * has been renamed into place and the size has been added).
760     */
761    if (fd != -1)
762       close(fd);
763    free(filename_tmp);
764    blob_finish(&cache_blob);
765 }
766 
767 /* Determine path for cache based on the first defined name as follows:
768  *
769  *   $MESA_GLSL_CACHE_DIR
770  *   $XDG_CACHE_HOME/mesa_shader_cache
771  *   <pwd.pw_dir>/.cache/mesa_shader_cache
772  */
773 char *
disk_cache_generate_cache_dir(void * mem_ctx,const char * gpu_name,const char * driver_id)774 disk_cache_generate_cache_dir(void *mem_ctx, const char *gpu_name,
775                               const char *driver_id)
776 {
777    char *cache_dir_name = CACHE_DIR_NAME;
778    if (env_var_as_boolean("MESA_DISK_CACHE_SINGLE_FILE", false))
779       cache_dir_name = CACHE_DIR_NAME_SF;
780 
781    char *path = getenv("MESA_GLSL_CACHE_DIR");
782    if (path) {
783       if (mkdir_if_needed(path) == -1)
784          return NULL;
785 
786       path = concatenate_and_mkdir(mem_ctx, path, cache_dir_name);
787       if (!path)
788          return NULL;
789    }
790 
791    if (path == NULL) {
792       char *xdg_cache_home = getenv("XDG_CACHE_HOME");
793 
794       if (xdg_cache_home) {
795          if (mkdir_if_needed(xdg_cache_home) == -1)
796             return NULL;
797 
798          path = concatenate_and_mkdir(mem_ctx, xdg_cache_home, cache_dir_name);
799          if (!path)
800             return NULL;
801       }
802    }
803 
804    if (!path) {
805       char *buf;
806       size_t buf_size;
807       struct passwd pwd, *result;
808 
809       buf_size = sysconf(_SC_GETPW_R_SIZE_MAX);
810       if (buf_size == -1)
811          buf_size = 512;
812 
813       /* Loop until buf_size is large enough to query the directory */
814       while (1) {
815          buf = ralloc_size(mem_ctx, buf_size);
816 
817          getpwuid_r(getuid(), &pwd, buf, buf_size, &result);
818          if (result)
819             break;
820 
821          if (errno == ERANGE) {
822             ralloc_free(buf);
823             buf = NULL;
824             buf_size *= 2;
825          } else {
826             return NULL;
827          }
828       }
829 
830       path = concatenate_and_mkdir(mem_ctx, pwd.pw_dir, ".cache");
831       if (!path)
832          return NULL;
833 
834       path = concatenate_and_mkdir(mem_ctx, path, cache_dir_name);
835       if (!path)
836          return NULL;
837    }
838 
839    if (env_var_as_boolean("MESA_DISK_CACHE_SINGLE_FILE", false)) {
840       path = concatenate_and_mkdir(mem_ctx, path, driver_id);
841       if (!path)
842          return NULL;
843 
844       path = concatenate_and_mkdir(mem_ctx, path, gpu_name);
845       if (!path)
846          return NULL;
847    }
848 
849    return path;
850 }
851 
852 bool
disk_cache_enabled()853 disk_cache_enabled()
854 {
855    /* If running as a users other than the real user disable cache */
856    if (geteuid() != getuid())
857       return false;
858 
859    /* At user request, disable shader cache entirely. */
860 #ifdef SHADER_CACHE_DISABLE_BY_DEFAULT
861    bool disable_by_default = true;
862 #else
863    bool disable_by_default = false;
864 #endif
865    if (env_var_as_boolean("MESA_GLSL_CACHE_DISABLE", disable_by_default))
866       return false;
867 
868    return true;
869 }
870 
871 void *
disk_cache_load_item_foz(struct disk_cache * cache,const cache_key key,size_t * size)872 disk_cache_load_item_foz(struct disk_cache *cache, const cache_key key,
873                          size_t *size)
874 {
875    size_t cache_tem_size = 0;
876    void *cache_item = foz_read_entry(&cache->foz_db, key, &cache_tem_size);
877    if (!cache_item)
878       return NULL;
879 
880    uint8_t *uncompressed_data =
881        parse_and_validate_cache_item(cache, cache_item, cache_tem_size, size);
882    free(cache_item);
883 
884    return uncompressed_data;
885 }
886 
887 bool
disk_cache_write_item_to_disk_foz(struct disk_cache_put_job * dc_job)888 disk_cache_write_item_to_disk_foz(struct disk_cache_put_job *dc_job)
889 {
890    struct blob cache_blob;
891    blob_init(&cache_blob);
892 
893    if (!create_cache_item_header_and_blob(dc_job, &cache_blob))
894       return false;
895 
896    bool r = foz_write_entry(&dc_job->cache->foz_db, dc_job->key,
897                             cache_blob.data, cache_blob.size);
898 
899    blob_finish(&cache_blob);
900    return r;
901 }
902 
903 bool
disk_cache_load_cache_index(void * mem_ctx,struct disk_cache * cache)904 disk_cache_load_cache_index(void *mem_ctx, struct disk_cache *cache)
905 {
906    /* Load cache index into a hash map (from fossilise files) */
907    return foz_prepare(&cache->foz_db, cache->path);
908 }
909 
910 bool
disk_cache_mmap_cache_index(void * mem_ctx,struct disk_cache * cache,char * path)911 disk_cache_mmap_cache_index(void *mem_ctx, struct disk_cache *cache,
912                             char *path)
913 {
914    int fd = -1;
915    bool mapped = false;
916 
917    path = ralloc_asprintf(mem_ctx, "%s/index", cache->path);
918    if (path == NULL)
919       goto path_fail;
920 
921    fd = open(path, O_RDWR | O_CREAT | O_CLOEXEC, 0644);
922    if (fd == -1)
923       goto path_fail;
924 
925    struct stat sb;
926    if (fstat(fd, &sb) == -1)
927       goto path_fail;
928 
929    /* Force the index file to be the expected size. */
930    size_t size = sizeof(*cache->size) + CACHE_INDEX_MAX_KEYS * CACHE_KEY_SIZE;
931    if (sb.st_size != size) {
932       if (ftruncate(fd, size) == -1)
933          goto path_fail;
934    }
935 
936    /* We map this shared so that other processes see updates that we
937     * make.
938     *
939     * Note: We do use atomic addition to ensure that multiple
940     * processes don't scramble the cache size recorded in the
941     * index. But we don't use any locking to prevent multiple
942     * processes from updating the same entry simultaneously. The idea
943     * is that if either result lands entirely in the index, then
944     * that's equivalent to a well-ordered write followed by an
945     * eviction and a write. On the other hand, if the simultaneous
946     * writes result in a corrupt entry, that's not really any
947     * different than both entries being evicted, (since within the
948     * guarantees of the cryptographic hash, a corrupt entry is
949     * unlikely to ever match a real cache key).
950     */
951    cache->index_mmap = mmap(NULL, size, PROT_READ | PROT_WRITE,
952                             MAP_SHARED, fd, 0);
953    if (cache->index_mmap == MAP_FAILED)
954       goto path_fail;
955    cache->index_mmap_size = size;
956 
957    cache->size = (uint64_t *) cache->index_mmap;
958    cache->stored_keys = cache->index_mmap + sizeof(uint64_t);
959    mapped = true;
960 
961 path_fail:
962    if (fd != -1)
963       close(fd);
964 
965    return mapped;
966 }
967 
968 void
disk_cache_destroy_mmap(struct disk_cache * cache)969 disk_cache_destroy_mmap(struct disk_cache *cache)
970 {
971    munmap(cache->index_mmap, cache->index_mmap_size);
972 }
973 #endif
974 
975 #endif /* ENABLE_SHADER_CACHE */
976