1 Parallel Checkout Design Notes
2 ==============================
4 The "Parallel Checkout" feature attempts to use multiple processes to
5 parallelize the work of uncompressing the blobs, applying in-core
6 filters, and writing the resulting contents to the working tree during a
7 checkout operation. It can be used by all checkout-related commands,
8 such as `clone`, `checkout`, `reset`, `sparse-checkout`, and others.
10 These commands share the following basic structure:
12 * Step 1: Read the current index file into memory.
14 * Step 2: Modify the in-memory index based upon the command, and
15 temporarily mark all cache entries that need to be updated.
17 * Step 3: Populate the working tree to match the new candidate index.
18 This includes iterating over all of the to-be-updated cache entries
19 and delete, create, or overwrite the associated files in the working
22 * Step 4: Write the new index to disk.
24 Step 3 is the focus of the "parallel checkout" effort described here.
26 Sequential Implementation
27 -------------------------
29 For the purposes of discussion here, the current sequential
30 implementation of Step 3 is divided in 3 parts, each one implemented in
33 * Step 3a: `unpack-trees.c:check_updates()` contains a series of
34 sequential loops iterating over the `cache_entry`'s array. The main
35 loop in this function calls the Step 3b function for each of the
36 to-be-updated entries.
38 * Step 3b: `entry.c:checkout_entry()` examines the existing working tree
39 for file conflicts, collisions, and unsaved changes. It removes files
40 and creates leading directories as necessary. It calls the Step 3c
41 function for each entry to be written.
43 * Step 3c: `entry.c:write_entry()` loads the blob into memory, smudges
44 it if necessary, creates the file in the working tree, writes the
45 smudged contents, calls `fstat()` or `lstat()`, and updates the
46 associated `cache_entry` struct with the stat information gathered.
48 It wouldn't be safe to perform Step 3b in parallel, as there could be
49 race conditions between file creations and removals. Instead, the
50 parallel checkout framework lets the sequential code handle Step 3b,
51 and uses parallel workers to replace the sequential
52 `entry.c:write_entry()` calls from Step 3c.
54 Rejected Multi-Threaded Solution
55 --------------------------------
57 The most "straightforward" implementation would be to spread the set of
58 to-be-updated cache entries across multiple threads. But due to the
59 thread-unsafe functions in the ODB code, we would have to use locks to
60 coordinate the parallel operation. An early prototype of this solution
61 showed that the multi-threaded checkout would bring performance
62 improvements over the sequential code, but there was still too much lock
63 contention. A `perf` profiling indicated that around 20% of the runtime
64 during a local Linux clone (on an SSD) was spent in locking functions.
65 For this reason this approach was rejected in favor of using multiple
66 child processes, which led to a better performance.
68 Multi-Process Solution
69 ----------------------
71 Parallel checkout alters the aforementioned Step 3 to use multiple
72 `checkout--worker` background processes to distribute the work. The
73 long-running worker processes are controlled by the foreground Git
74 command using the existing run-command API.
79 Step 3b is only slightly altered; for each entry to be checked out, the
80 main process performs the following steps:
82 * M1: Check whether there is any untracked or unclean file in the
83 working tree which would be overwritten by this entry, and decide
84 whether to proceed (removing the file(s)) or not.
86 * M2: Create the leading directories.
88 * M3: Load the conversion attributes for the entry's path.
90 * M4: Check, based on the entry's type and conversion attributes,
91 whether the entry is eligible for parallel checkout (more on this
92 later). If it is eligible, enqueue the entry and the loaded
93 attributes to later write the entry in parallel. If not, write the
94 entry right away, using the default sequential code.
96 Note: we save the conversion attributes associated with each entry
97 because the workers don't have access to the main process' index state,
98 so they can't load the attributes by themselves (and the attributes are
99 needed to properly smudge the entry). Additionally, this has a positive
100 impact on performance as (1) we don't need to load the attributes twice
101 and (2) the attributes machinery is optimized to handle paths in
104 After all entries have passed through the above steps, the main process
105 checks if the number of enqueued entries is sufficient to spread among
106 the workers. If not, it just writes them sequentially. Otherwise, it
107 spawns the workers and distributes the queued entries uniformly in
108 continuous chunks. This aims to minimize the chances of two workers
109 writing to the same directory simultaneously, which could increase lock
110 contention in the kernel.
112 Then, for each assigned item, each worker:
114 * W1: Checks if there is any non-directory file in the leading part of
115 the entry's path or if there already exists a file at the entry' path.
116 If so, mark the entry with `PC_ITEM_COLLIDED` and skip it (more on
119 * W2: Creates the file (with O_CREAT and O_EXCL).
121 * W3: Loads the blob into memory (inflating and delta reconstructing
124 * W4: Applies any required in-process filter, like end-of-line
125 conversion and re-encoding.
127 * W5: Writes the result to the file descriptor opened at W2.
129 * W6: Calls `fstat()` or lstat()` on the just-written path, and sends
130 the result back to the main process, together with the end status of
131 the operation and the item's identification number.
133 Note that, when possible, steps W3 to W5 are delegated to the streaming
134 machinery, removing the need to keep the entire blob in memory.
136 If the worker fails to read the blob or to write it to the working tree,
137 it removes the created file to avoid leaving empty files behind. This is
138 the *only* time a worker is allowed to remove a file.
140 As mentioned earlier, it is the responsibility of the main process to
141 remove any file that blocks the checkout operation (or abort if the
142 removal(s) would cause data loss and the user didn't ask to `--force`).
143 This is crucial to avoid race conditions and also to properly detect
144 path collisions at Step W1.
146 After the workers finish writing the items and sending back the required
147 information, the main process handles the results in two steps:
149 - First, it updates the in-memory index with the `lstat()` information
150 sent by the workers. (This must be done first as this information
151 might me required in the following step.)
153 - Then it writes the items which collided on disk (i.e. items marked
154 with `PC_ITEM_COLLIDED`). More on this below.
159 Path collisions happen when two different paths correspond to the same
160 entry in the file system. E.g. the paths 'a' and 'A' would collide in a
161 case-insensitive file system.
163 The sequential checkout deals with collisions in the same way that it
164 deals with files that were already present in the working tree before
165 checkout. Basically, it checks if the path that it wants to write
166 already exists on disk, makes sure the existing file doesn't have
167 unsaved data, and then overwrites it. (To be more pedantic: it deletes
168 the existing file and creates the new one.) So, if there are multiple
169 colliding files to be checked out, the sequential code will write each
170 one of them but only the last will actually survive on disk.
172 Parallel checkout aims to reproduce the same behavior. However, we
173 cannot let the workers racily write to the same file on disk. Instead,
174 the workers detect when the entry that they want to check out would
175 collide with an existing file, and mark it with `PC_ITEM_COLLIDED`.
176 Later, the main process can sequentially feed these entries back to
177 `checkout_entry()` without the risk of race conditions. On clone, this
178 also has the effect of marking the colliding entries to later emit a
179 warning for the user, like the classic sequential checkout does.
181 The workers are able to detect both collisions among the entries being
182 concurrently written and collisions between a parallel-eligible entry
183 and an ineligible entry. The general idea for collision detection is
184 quite straightforward: for each parallel-eligible entry, the main
185 process must remove all files that prevent this entry from being written
186 (before enqueueing it). This includes any non-directory file in the
187 leading path of the entry. Later, when a worker gets assigned the entry,
188 it looks again for the non-directories files and for an already existing
189 file at the entry's path. If any of these checks finds something, the
190 worker knows that there was a path collision.
192 Because parallel checkout can distinguish path collisions from the case
193 where the file was already present in the working tree before checkout,
194 we could alternatively choose to skip the checkout of colliding entries.
195 However, each entry that doesn't get written would have NULL `lstat()`
196 fields on the index. This could cause performance penalties for
197 subsequent commands that need to refresh the index, as they would have
198 to go to the file system to see if the entry is dirty. Thus, if we have
199 N entries in a colliding group and we decide to write and `lstat()` only
200 one of them, every subsequent `git-status` will have to read, convert,
201 and hash the written file N - 1 times. By checking out all colliding
202 entries (like the sequential code does), we only pay the overhead once,
205 Eligible Entries for Parallel Checkout
206 --------------------------------------
208 As previously mentioned, not all entries passed to `checkout_entry()`
209 will be considered eligible for parallel checkout. More specifically, we
212 - Symbolic links; to avoid race conditions that, in combination with
213 path collisions, could cause workers to write files at the wrong
214 place. For example, if we were to concurrently check out a symlink
215 'a' -> 'b' and a regular file 'A/f' in a case-insensitive file system,
216 we could potentially end up writing the file 'A/f' at 'a/f', due to a
219 - Regular files that require external filters (either "one shot" filters
220 or long-running process filters). These filters are black-boxes to Git
221 and may have their own internal locking or non-concurrent assumptions.
222 So it might not be safe to run multiple instances in parallel.
224 Besides, long-running filters may use the delayed checkout feature to
225 postpone the return of some filtered blobs. The delayed checkout queue
226 and the parallel checkout queue are not compatible and should remain
229 Note: regular files that only require internal filters, like end-of-line
230 conversion and re-encoding, are eligible for parallel checkout.
232 Ineligible entries are checked out by the classic sequential codepath
233 *before* spawning workers.
235 Note: submodules's files are also eligible for parallel checkout (as
236 long as they don't fall into any of the excluding categories mentioned
237 above). But since each submodule is checked out in its own child
238 process, we don't mix the superproject's and the submodules' files in
239 the same parallel checkout process or queue.
244 The parallel checkout API was designed with the goal of minimizing
245 changes to the current users of the checkout machinery. This means that
246 they don't have to call a different function for sequential or parallel
247 checkout. As already mentioned, `checkout_entry()` will automatically
248 insert the given entry in the parallel checkout queue when this feature
249 is enabled and the entry is eligible; otherwise, it will just write the
250 entry right away, using the sequential code. In general, callers of the
251 parallel checkout API should look similar to this:
253 ----------------------------------------------
254 int pc_workers, pc_threshold, err = 0;
255 struct checkout state;
257 get_parallel_checkout_configs(&pc_workers, &pc_threshold);
260 * This check is not strictly required, but it
261 * should save some time in sequential mode.
264 init_parallel_checkout();
266 for (each cache_entry ce to-be-updated)
267 err |= checkout_entry(ce, &state, NULL, NULL);
269 err |= run_parallel_checkout(&state, pc_workers, pc_threshold, NULL, NULL);
270 ----------------------------------------------