1 #define USE_THE_REPOSITORY_VARIABLE
3 #include "git-compat-util.h"
9 #include "parallel-checkout.h"
12 #include "read-cache-ll.h"
13 #include "run-command.h"
15 #include "streaming.h"
17 #include "thread-utils.h"
21 struct child_process cp
;
22 size_t next_item_to_complete
, nr_items_to_complete
;
25 struct parallel_checkout
{
26 enum pc_status status
;
27 struct parallel_checkout_item
*items
; /* The parallel checkout queue. */
29 struct progress
*progress
;
30 unsigned int *progress_cnt
;
33 static struct parallel_checkout parallel_checkout
;
35 enum pc_status
parallel_checkout_status(void)
37 return parallel_checkout
.status
;
40 static const int DEFAULT_THRESHOLD_FOR_PARALLELISM
= 100;
41 static const int DEFAULT_NUM_WORKERS
= 1;
43 void get_parallel_checkout_configs(int *num_workers
, int *threshold
)
45 char *env_workers
= getenv("GIT_TEST_CHECKOUT_WORKERS");
47 if (env_workers
&& *env_workers
) {
48 if (strtol_i(env_workers
, 10, num_workers
)) {
49 die(_("invalid value for '%s': '%s'"),
50 "GIT_TEST_CHECKOUT_WORKERS", env_workers
);
53 *num_workers
= online_cpus();
59 if (git_config_get_int("checkout.workers", num_workers
))
60 *num_workers
= DEFAULT_NUM_WORKERS
;
61 else if (*num_workers
< 1)
62 *num_workers
= online_cpus();
64 if (git_config_get_int("checkout.thresholdForParallelism", threshold
))
65 *threshold
= DEFAULT_THRESHOLD_FOR_PARALLELISM
;
68 void init_parallel_checkout(void)
70 if (parallel_checkout
.status
!= PC_UNINITIALIZED
)
71 BUG("parallel checkout already initialized");
73 parallel_checkout
.status
= PC_ACCEPTING_ENTRIES
;
76 static void finish_parallel_checkout(void)
78 if (parallel_checkout
.status
== PC_UNINITIALIZED
)
79 BUG("cannot finish parallel checkout: not initialized yet");
81 free(parallel_checkout
.items
);
82 memset(¶llel_checkout
, 0, sizeof(parallel_checkout
));
85 static int is_eligible_for_parallel_checkout(const struct cache_entry
*ce
,
86 const struct conv_attrs
*ca
)
88 enum conv_attrs_classification c
;
89 size_t packed_item_size
;
92 * Symlinks cannot be checked out in parallel as, in case of path
93 * collision, they could racily replace leading directories of other
94 * entries being checked out. Submodules are checked out in child
95 * processes, which have their own parallel checkout queues.
97 if (!S_ISREG(ce
->ce_mode
))
100 packed_item_size
= sizeof(struct pc_item_fixed_portion
) + ce
->ce_namelen
+
101 (ca
->working_tree_encoding
? strlen(ca
->working_tree_encoding
) : 0);
104 * The amount of data we send to the workers per checkout item is
105 * typically small (75~300B). So unless we find an insanely huge path
106 * of 64KB, we should never reach the 65KB limit of one pkt-line. If
107 * that does happen, we let the sequential code handle the item.
109 if (packed_item_size
> LARGE_PACKET_DATA_MAX
)
112 c
= classify_conv_attrs(ca
);
114 case CA_CLASS_INCORE
:
117 case CA_CLASS_INCORE_FILTER
:
119 * It would be safe to allow concurrent instances of
120 * single-file smudge filters, like rot13, but we should not
121 * assume that all filters are parallel-process safe. So we
126 case CA_CLASS_INCORE_PROCESS
:
128 * The parallel queue and the delayed queue are not compatible,
129 * so they must be kept completely separated. And we can't tell
130 * if a long-running process will delay its response without
131 * actually asking it to perform the filtering. Therefore, this
132 * type of filter is not allowed in parallel checkout.
134 * Furthermore, there should only be one instance of the
135 * long-running process filter as we don't know how it is
136 * managing its own concurrency. So, spreading the entries that
137 * requisite such a filter among the parallel workers would
138 * require a lot more inter-process communication. We would
139 * probably have to designate a single process to interact with
140 * the filter and send all the necessary data to it, for each
145 case CA_CLASS_STREAMABLE
:
149 BUG("unsupported conv_attrs classification '%d'", c
);
153 int enqueue_checkout(struct cache_entry
*ce
, struct conv_attrs
*ca
,
154 int *checkout_counter
)
156 struct parallel_checkout_item
*pc_item
;
158 if (parallel_checkout
.status
!= PC_ACCEPTING_ENTRIES
||
159 !is_eligible_for_parallel_checkout(ce
, ca
))
162 ALLOC_GROW(parallel_checkout
.items
, parallel_checkout
.nr
+ 1,
163 parallel_checkout
.alloc
);
165 pc_item
= ¶llel_checkout
.items
[parallel_checkout
.nr
];
167 memcpy(&pc_item
->ca
, ca
, sizeof(pc_item
->ca
));
168 pc_item
->status
= PC_ITEM_PENDING
;
169 pc_item
->id
= parallel_checkout
.nr
;
170 pc_item
->checkout_counter
= checkout_counter
;
171 parallel_checkout
.nr
++;
176 size_t pc_queue_size(void)
178 return parallel_checkout
.nr
;
181 static void advance_progress_meter(void)
183 if (parallel_checkout
.progress
) {
184 (*parallel_checkout
.progress_cnt
)++;
185 display_progress(parallel_checkout
.progress
,
186 *parallel_checkout
.progress_cnt
);
190 static int handle_results(struct checkout
*state
)
194 int have_pending
= 0;
197 * We first update the successfully written entries with the collected
198 * stat() data, so that they can be found by mark_colliding_entries(),
199 * in the next loop, when necessary.
201 for (i
= 0; i
< parallel_checkout
.nr
; i
++) {
202 struct parallel_checkout_item
*pc_item
= ¶llel_checkout
.items
[i
];
203 if (pc_item
->status
== PC_ITEM_WRITTEN
)
204 update_ce_after_write(state
, pc_item
->ce
, &pc_item
->st
);
207 for (i
= 0; i
< parallel_checkout
.nr
; i
++) {
208 struct parallel_checkout_item
*pc_item
= ¶llel_checkout
.items
[i
];
210 switch(pc_item
->status
) {
211 case PC_ITEM_WRITTEN
:
212 if (pc_item
->checkout_counter
)
213 (*pc_item
->checkout_counter
)++;
215 case PC_ITEM_COLLIDED
:
217 * The entry could not be checked out due to a path
218 * collision with another entry. Since there can only
219 * be one entry of each colliding group on the disk, we
220 * could skip trying to check out this one and move on.
221 * However, this would leave the unwritten entries with
222 * null stat() fields on the index, which could
223 * potentially slow down subsequent operations that
224 * require refreshing it: git would not be able to
225 * trust st_size and would have to go to the filesystem
226 * to see if the contents match (see ie_modified()).
228 * Instead, let's pay the overhead only once, now, and
229 * call checkout_entry_ca() again for this file, to
230 * have its stat() data stored in the index. This also
231 * has the benefit of adding this entry and its
232 * colliding pair to the collision report message.
233 * Additionally, this overwriting behavior is consistent
234 * with what the sequential checkout does, so it doesn't
235 * add any extra overhead.
237 ret
|= checkout_entry_ca(pc_item
->ce
, &pc_item
->ca
,
239 pc_item
->checkout_counter
);
240 advance_progress_meter();
242 case PC_ITEM_PENDING
:
249 BUG("unknown checkout item status in parallel checkout");
254 error("parallel checkout finished with pending entries");
259 static int reset_fd(int fd
, const char *path
)
261 if (lseek(fd
, 0, SEEK_SET
) != 0)
262 return error_errno("failed to rewind descriptor of '%s'", path
);
263 if (ftruncate(fd
, 0))
264 return error_errno("failed to truncate file '%s'", path
);
268 static int write_pc_item_to_fd(struct parallel_checkout_item
*pc_item
, int fd
,
272 struct stream_filter
*filter
;
273 struct strbuf buf
= STRBUF_INIT
;
279 assert(is_eligible_for_parallel_checkout(pc_item
->ce
, &pc_item
->ca
));
281 filter
= get_stream_filter_ca(&pc_item
->ca
, &pc_item
->ce
->oid
);
283 if (stream_blob_to_fd(fd
, &pc_item
->ce
->oid
, filter
, 1)) {
284 /* On error, reset fd to try writing without streaming */
285 if (reset_fd(fd
, path
))
292 blob
= read_blob_entry(pc_item
->ce
, &size
);
294 return error("cannot read object %s '%s'",
295 oid_to_hex(&pc_item
->ce
->oid
), pc_item
->ce
->name
);
298 * checkout metadata is used to give context for external process
299 * filters. Files requiring such filters are not eligible for parallel
300 * checkout, so pass NULL. Note: if that changes, the metadata must also
301 * be passed from the main process to the workers.
303 ret
= convert_to_working_tree_ca(&pc_item
->ca
, pc_item
->ce
->name
,
304 blob
, size
, &buf
, NULL
);
309 blob
= strbuf_detach(&buf
, &newsize
);
313 wrote
= write_in_full(fd
, blob
, size
);
316 return error("unable to write file '%s'", path
);
321 static int close_and_clear(int *fd
)
333 void write_pc_item(struct parallel_checkout_item
*pc_item
,
334 struct checkout
*state
)
336 unsigned int mode
= (pc_item
->ce
->ce_mode
& 0100) ? 0777 : 0666;
337 int fd
= -1, fstat_done
= 0;
338 struct strbuf path
= STRBUF_INIT
;
341 strbuf_add(&path
, state
->base_dir
, state
->base_dir_len
);
342 strbuf_add(&path
, pc_item
->ce
->name
, pc_item
->ce
->ce_namelen
);
344 dir_sep
= find_last_dir_sep(path
.buf
);
347 * The leading dirs should have been already created by now. But, in
348 * case of path collisions, one of the dirs could have been replaced by
349 * a symlink (checked out after we enqueued this entry for parallel
350 * checkout). Thus, we must check the leading dirs again.
352 if (dir_sep
&& !has_dirs_only_path(path
.buf
, dir_sep
- path
.buf
,
353 state
->base_dir_len
)) {
354 pc_item
->status
= PC_ITEM_COLLIDED
;
355 trace2_data_string("pcheckout", NULL
, "collision/dirname", path
.buf
);
359 fd
= open(path
.buf
, O_WRONLY
| O_CREAT
| O_EXCL
, mode
);
362 if (errno
== EEXIST
|| errno
== EISDIR
) {
364 * Errors which probably represent a path collision.
365 * Suppress the error message and mark the item to be
366 * retried later, sequentially. ENOTDIR and ENOENT are
367 * also interesting, but the above has_dirs_only_path()
368 * call should have already caught these cases.
370 pc_item
->status
= PC_ITEM_COLLIDED
;
371 trace2_data_string("pcheckout", NULL
,
372 "collision/basename", path
.buf
);
374 error_errno("failed to open file '%s'", path
.buf
);
375 pc_item
->status
= PC_ITEM_FAILED
;
380 if (write_pc_item_to_fd(pc_item
, fd
, path
.buf
)) {
381 /* Error was already reported. */
382 pc_item
->status
= PC_ITEM_FAILED
;
383 close_and_clear(&fd
);
388 fstat_done
= fstat_checkout_output(fd
, state
, &pc_item
->st
);
390 if (close_and_clear(&fd
)) {
391 error_errno("unable to close file '%s'", path
.buf
);
392 pc_item
->status
= PC_ITEM_FAILED
;
396 if (state
->refresh_cache
&& !fstat_done
&& lstat(path
.buf
, &pc_item
->st
) < 0) {
397 error_errno("unable to stat just-written file '%s'", path
.buf
);
398 pc_item
->status
= PC_ITEM_FAILED
;
402 pc_item
->status
= PC_ITEM_WRITTEN
;
405 strbuf_release(&path
);
408 static void send_one_item(int fd
, struct parallel_checkout_item
*pc_item
)
411 char *data
, *variant
;
412 struct pc_item_fixed_portion
*fixed_portion
;
413 const char *working_tree_encoding
= pc_item
->ca
.working_tree_encoding
;
414 size_t name_len
= pc_item
->ce
->ce_namelen
;
415 size_t working_tree_encoding_len
= working_tree_encoding
?
416 strlen(working_tree_encoding
) : 0;
419 * Any changes in the calculation of the message size must also be made
420 * in is_eligible_for_parallel_checkout().
422 len_data
= sizeof(struct pc_item_fixed_portion
) + name_len
+
423 working_tree_encoding_len
;
425 data
= xmalloc(len_data
);
427 fixed_portion
= (struct pc_item_fixed_portion
*)data
;
428 fixed_portion
->id
= pc_item
->id
;
429 fixed_portion
->ce_mode
= pc_item
->ce
->ce_mode
;
430 fixed_portion
->crlf_action
= pc_item
->ca
.crlf_action
;
431 fixed_portion
->ident
= pc_item
->ca
.ident
;
432 fixed_portion
->name_len
= name_len
;
433 fixed_portion
->working_tree_encoding_len
= working_tree_encoding_len
;
434 oidcpy(&fixed_portion
->oid
, &pc_item
->ce
->oid
);
436 variant
= data
+ sizeof(*fixed_portion
);
437 if (working_tree_encoding_len
) {
438 memcpy(variant
, working_tree_encoding
, working_tree_encoding_len
);
439 variant
+= working_tree_encoding_len
;
441 memcpy(variant
, pc_item
->ce
->name
, name_len
);
443 packet_write(fd
, data
, len_data
);
448 static void send_batch(int fd
, size_t start
, size_t nr
)
451 sigchain_push(SIGPIPE
, SIG_IGN
);
452 for (i
= 0; i
< nr
; i
++)
453 send_one_item(fd
, ¶llel_checkout
.items
[start
+ i
]);
455 sigchain_pop(SIGPIPE
);
458 static struct pc_worker
*setup_workers(struct checkout
*state
, int num_workers
)
460 struct pc_worker
*workers
;
461 int i
, workers_with_one_extra_item
;
462 size_t base_batch_size
, batch_beginning
= 0;
464 ALLOC_ARRAY(workers
, num_workers
);
466 for (i
= 0; i
< num_workers
; i
++) {
467 struct child_process
*cp
= &workers
[i
].cp
;
469 child_process_init(cp
);
473 cp
->clean_on_exit
= 1;
474 strvec_push(&cp
->args
, "checkout--worker");
475 if (state
->base_dir_len
)
476 strvec_pushf(&cp
->args
, "--prefix=%s", state
->base_dir
);
477 if (start_command(cp
))
478 die("failed to spawn checkout worker");
481 base_batch_size
= parallel_checkout
.nr
/ num_workers
;
482 workers_with_one_extra_item
= parallel_checkout
.nr
% num_workers
;
484 for (i
= 0; i
< num_workers
; i
++) {
485 struct pc_worker
*worker
= &workers
[i
];
486 size_t batch_size
= base_batch_size
;
488 /* distribute the extra work evenly */
489 if (i
< workers_with_one_extra_item
)
492 send_batch(worker
->cp
.in
, batch_beginning
, batch_size
);
493 worker
->next_item_to_complete
= batch_beginning
;
494 worker
->nr_items_to_complete
= batch_size
;
496 batch_beginning
+= batch_size
;
502 static void finish_workers(struct pc_worker
*workers
, int num_workers
)
507 * Close pipes before calling finish_command() to let the workers
508 * exit asynchronously and avoid spending extra time on wait().
510 for (i
= 0; i
< num_workers
; i
++) {
511 struct child_process
*cp
= &workers
[i
].cp
;
518 for (i
= 0; i
< num_workers
; i
++) {
519 int rc
= finish_command(&workers
[i
].cp
);
522 * For a normal non-zero exit, the worker should have
523 * already printed something useful to stderr. But a
524 * death by signal should be mentioned to the user.
526 error("checkout worker %d died of signal %d", i
, rc
- 128);
533 static inline void assert_pc_item_result_size(int got
, int exp
)
536 BUG("wrong result size from checkout worker (got %dB, exp %dB)",
540 static void parse_and_save_result(const char *buffer
, int len
,
541 struct pc_worker
*worker
)
543 struct pc_item_result
*res
;
544 struct parallel_checkout_item
*pc_item
;
545 struct stat
*st
= NULL
;
547 if (len
< PC_ITEM_RESULT_BASE_SIZE
)
548 BUG("too short result from checkout worker (got %dB, exp >=%dB)",
549 len
, (int)PC_ITEM_RESULT_BASE_SIZE
);
551 res
= (struct pc_item_result
*)buffer
;
554 * Worker should send either the full result struct on success, or
555 * just the base (i.e. no stat data), otherwise.
557 if (res
->status
== PC_ITEM_WRITTEN
) {
558 assert_pc_item_result_size(len
, (int)sizeof(struct pc_item_result
));
561 assert_pc_item_result_size(len
, (int)PC_ITEM_RESULT_BASE_SIZE
);
564 if (!worker
->nr_items_to_complete
)
565 BUG("received result from supposedly finished checkout worker");
566 if (res
->id
!= worker
->next_item_to_complete
)
567 BUG("unexpected item id from checkout worker (got %"PRIuMAX
", exp %"PRIuMAX
")",
568 (uintmax_t)res
->id
, (uintmax_t)worker
->next_item_to_complete
);
570 worker
->next_item_to_complete
++;
571 worker
->nr_items_to_complete
--;
573 pc_item
= ¶llel_checkout
.items
[res
->id
];
574 pc_item
->status
= res
->status
;
578 if (res
->status
!= PC_ITEM_COLLIDED
)
579 advance_progress_meter();
582 static void gather_results_from_workers(struct pc_worker
*workers
,
585 int i
, active_workers
= num_workers
;
588 CALLOC_ARRAY(pfds
, num_workers
);
589 for (i
= 0; i
< num_workers
; i
++) {
590 pfds
[i
].fd
= workers
[i
].cp
.out
;
591 pfds
[i
].events
= POLLIN
;
594 while (active_workers
) {
595 int nr
= poll(pfds
, num_workers
, -1);
600 die_errno("failed to poll checkout workers");
603 for (i
= 0; i
< num_workers
&& nr
> 0; i
++) {
604 struct pc_worker
*worker
= &workers
[i
];
605 struct pollfd
*pfd
= &pfds
[i
];
610 if (pfd
->revents
& POLLIN
) {
611 int len
= packet_read(pfd
->fd
, packet_buffer
,
612 sizeof(packet_buffer
), 0);
615 BUG("packet_read() returned negative value");
620 parse_and_save_result(packet_buffer
,
623 } else if (pfd
->revents
& POLLHUP
) {
626 } else if (pfd
->revents
& (POLLNVAL
| POLLERR
)) {
627 die("error polling from checkout worker");
637 static void write_items_sequentially(struct checkout
*state
)
641 for (i
= 0; i
< parallel_checkout
.nr
; i
++) {
642 struct parallel_checkout_item
*pc_item
= ¶llel_checkout
.items
[i
];
643 write_pc_item(pc_item
, state
);
644 if (pc_item
->status
!= PC_ITEM_COLLIDED
)
645 advance_progress_meter();
649 int run_parallel_checkout(struct checkout
*state
, int num_workers
, int threshold
,
650 struct progress
*progress
, unsigned int *progress_cnt
)
654 if (parallel_checkout
.status
!= PC_ACCEPTING_ENTRIES
)
655 BUG("cannot run parallel checkout: uninitialized or already running");
657 parallel_checkout
.status
= PC_RUNNING
;
658 parallel_checkout
.progress
= progress
;
659 parallel_checkout
.progress_cnt
= progress_cnt
;
661 if (parallel_checkout
.nr
< num_workers
)
662 num_workers
= parallel_checkout
.nr
;
664 if (num_workers
<= 1 || parallel_checkout
.nr
< threshold
) {
665 write_items_sequentially(state
);
667 struct pc_worker
*workers
= setup_workers(state
, num_workers
);
668 gather_results_from_workers(workers
, num_workers
);
669 finish_workers(workers
, num_workers
);
672 ret
= handle_results(state
);
674 finish_parallel_checkout();