On Mon, Apr 19, 2021 at 2:15 AM Matheus Tavares <matheus.bernardino@xxxxxx> wrote: > > Co-authored-by: Jeff Hostetler <jeffhost@xxxxxxxxxxxxx> > Signed-off-by: Matheus Tavares <matheus.bernardino@xxxxxx> > --- > Documentation/Makefile | 1 + > Documentation/technical/parallel-checkout.txt | 271 ++++++++++++++++++ > 2 files changed, 272 insertions(+) > create mode 100644 Documentation/technical/parallel-checkout.txt > > diff --git a/Documentation/Makefile b/Documentation/Makefile > index 81d1bf7a04..af236927c9 100644 > --- a/Documentation/Makefile > +++ b/Documentation/Makefile > @@ -90,6 +90,7 @@ TECH_DOCS += technical/multi-pack-index > TECH_DOCS += technical/pack-format > TECH_DOCS += technical/pack-heuristics > TECH_DOCS += technical/pack-protocol > +TECH_DOCS += technical/parallel-checkout > TECH_DOCS += technical/partial-clone > TECH_DOCS += technical/protocol-capabilities > TECH_DOCS += technical/protocol-common > diff --git a/Documentation/technical/parallel-checkout.txt b/Documentation/technical/parallel-checkout.txt > new file mode 100644 > index 0000000000..fddb0ed4fd > --- /dev/null > +++ b/Documentation/technical/parallel-checkout.txt > @@ -0,0 +1,271 @@ > +Parallel Checkout Design Notes > +============================== > + > +The "Parallel Checkout" feature attempts to use multiple processes to > +parallelize the work of uncompressing the blobs, applying in-core > +filters, and writing the resulting contents to the working tree during a > +checkout operation. It can be used by all checkout-related commands, > +such as `clone`, `checkout`, `reset`, `sparse-checkout`, and others. > + > +These commands share the following basic structure: > + > +* Step 1: Read the current index file into memory. > + > +* Step 2: Modify the in-memory index based upon the command, and > + temporarily mark all cache entries that need to be updated. > + > +* Step 3: Populate the working tree to match the new candidate index. > + This includes iterating over all of the to-be-updated cache entries > + and delete, create, or overwrite the associated files in the working > + tree. > + > +* Step 4: Write the new index to disk. > + > +Step 3 is the focus of the "parallel checkout" effort described here. > +It dominates the execution time for most of the above command types. Maybe: s/command types/checkout-related commands/ > +Sequential Implementation > +------------------------- > + > +For the purposes of discussion here, the current sequential > +implementation of Step 3 is divided in 3 parts, each one implemented in > +its own function: > + > +* Step 3a: `unpack-trees.c:check_updates()` contains a series of > + sequential loops iterating over the `cache_entry`'s array. The main > + loop in this function calls the Step 3b function for each of the > + to-be-updated entries. > + > +* Step 3b: `entry.c:checkout_entry()` examines the existing working tree > + for file conflicts, collisions, and unsaved changes. It removes files > + and creates leading directories as necessary. It calls the Step 3c > + function for each entry to be written. > + > +* Step 3c: `entry.c:write_entry()` loads the blob into memory, smudges > + it if necessary, creates the file in the working tree, writes the > + smudged contents, calls `fstat()` or `lstat()`, and updates the > + associated `cache_entry` struct with the stat information gathered. > + > +It wouldn't be safe to perform Step 3b in parallel, as there could be > +race conditions between file creations and removals. Instead, the > +parallel checkout framework lets the sequential code handle Step 3b, > +and use parallel workers to replace the sequential s/use/uses/ > +`entry.c:write_entry()` calls from Step 3c. > + > +Rejected Multi-Threaded Solution > +-------------------------------- > + > +The most "straightforward" implementation would be to spread the set of > +to-be-updated cache entries across multiple threads. But due to the > +thread-unsafe functions in the ODB code, we would have to use locks to > +coordinate the parallel operation. An early prototype of this solution > +showed that the multi-threaded checkout would bring performance > +improvements over the sequential code, but there was still too much lock > +contention. A `perf` profiling indicated that around 20% of the runtime > +during a local Linux clone (on an SSD) was spent in locking functions. > +For this reason this approach was rejected in favor of using multiple > +child processes, which led to a better performance. > + > +Multi-Process Solution > +---------------------- > + > +Parallel checkout alters the aforementioned Step 3 to use multiple > +`checkout--worker` background processes to distribute the work. The > +long-running worker processes are controlled by the foreground Git > +command using the existing run-command API. > + > +Overview > +~~~~~~~~ > + > +Step 3b is only slightly altered; for each entry to be checked out, the > +main process performs the following steps: > + > +* M1: Check whether there is any untracked or unclean file in the > + working tree which would be overwritten by this entry, and decide > + whether to proceed (removing the file(s)) or not. > + > +* M2: Create the leading directories. > + > +* M3: Load the conversion attributes for the entry's path. > + > +* M4: Check, based on the entry's type and conversion attributes, > + whether the entry is eligible for parallel checkout (more on this > + later). If it is eligible, enqueue the entry and the loaded > + attributes to later write the entry in parallel. If not, write the > + entry right away, using the default sequential code. > + > +Note: we save the conversion attributes associated with each entry > +because the workers don't have access to the main process' index state, > +so they can't load the attributes by themselves (and the attributes are > +needed to properly smudge the entry). Additionally, this has a positive > +impact on performance as (1) we don't need to load the attributes twice > +and (2) the attributes machinery is optimized to handle paths in > +sequential order. > + > +After all entries have passed through the above steps, the main process > +checks if the number of enqueued entries is sufficient to spread among > +the workers. If not, it just writes them sequentially. Otherwise, it > +spawns the workers and distributes the queued entries uniformly in > +continuous chunks. This aims to minimize the chances of two workers > +writing to the same directory simultaneously, which could increase lock > +contention in the kernel. > + > +Then, for each assigned item, each worker: > + > +* W1: Checks if there is any non-directory file in the leading part of > + the entry's path or if there already exists a file at the entry' path. > + If so, mark the entry with `PC_ITEM_COLLIDED` and skip it (more on > + this later). > + > +* W2: Creates the file (with O_CREAT and O_EXCL). > + > +* W3: Loads the blob into memory (inflating and delta reconstructing > + it). > + > +* W4: Applies any required in-process filter, like end-of-line > + conversion and re-encoding. > + > +* W5: Writes the result to the file descriptor opened at W2. > + > +* W6: Calls `fstat()` or lstat()` on the just-written path, and sends > + the result back to the main process, together with the end status of > + the operation and the item's identification number. > + > +Note that, when possible, steps W3 to W5 are delegated to the streaming > +machinery, removing the need to keep the entire blob in memory. > + > +If the worker fails to read the blob or to write it to the working tree, > +it removes the created file to avoid leaving empty files behind. This is > +the *only* time a worker is allowed to remove a file. > + > +As mentioned earlier, it is the responsibility of the main process to > +remove any file that blocks the checkout operation (or abort if the > +removal(s) would cause data loss and the user didn't ask to `--force`). > +This is crucial to avoid race conditions and also to properly detect > +path collisions at Step W1. > + > +After the workers finish writing the items and sending back the required > +information, the main process handles the results in two steps: > + > +- First, it updates the in-memory index with the `lstat()` information > + sent by the workers. (This must be done first as this information > + might me required in the following step.) > + > +- Then it writes the items which collided on disk (i.e. items marked > + with `PC_ITEM_COLLIDED`). More on this below. > + > +Path Collisions > +--------------- > + > +Path collisions happen when two different paths correspond to the same > +entry in the file system. E.g. the paths 'a' and 'A' would collide in a > +case-insensitive file system. > + > +The sequential checkout deals with collisions in the same way that it > +deals with files that were already present in the working tree before > +checkout. Basically, it checks if the path that it wants to write > +already exists on disk, makes sure the existing file doesn't have > +unsaved data, and then overwrites it. (To be more pedantic: it deletes > +the existing file and creates the new one.) So, if there are multiple > +colliding files to be checked out, the sequential code will write each > +one of them but only the last will actually survive on disk. > + > +Parallel checkout aims to reproduce the same behavior. However, we > +cannot let the workers racily write to the same file on disk. Instead, > +the workers detect when the entry that they want to check out would > +collide with an existing file, and mark it with `PC_ITEM_COLLIDED`. > +Later, the main process can sequentially feed these entries back to > +`checkout_entry()` without the risk of race conditions. On clone, this > +also has the effect of marking the colliding entries to later emit a > +warning for the user, like the classic sequential checkout does. > + > +The workers are able to detect both collisions among the entries being > +concurrently written and collisions among parallel-eligible and > +ineligible entries. I am not sure I understand the above correctly. Does this mean that if there are 2 parallel-ineligible entries that collide the workers will detect that? How is that possible if the parallel-ineligible entries are not processed by the workers? Or maybe s/among/between/ would make things clearer. For example: "The workers are able to detect both collisions among entries being concurrently written and collisions between a parallel-eligible entry and one or more ineligible entries." > The general idea for collision detection is quite > +straightforward: for each parallel-eligible entry, the main process must > +remove all files that prevent this entry from being written (before > +enqueueing it). This includes any non-directory file in the leading path > +of the entry. Later, when a worker gets assigned the entry, it looks > +again for the non-directories files and for an already existing file at > +the entry's path. If any of these checks finds something, the worker > +knows that there was a path collision. > + > +Because parallel checkout can distinguish path collisions from the case > +where the file was already present in the working tree before checkout, > +we could alternatively choose to skip the checkout of colliding entries. > +However, each entry that doesn't get written would have NULL `lstat()` > +fields on the index. This could cause performance penalties for > +subsequent commands that need to refresh the index, as they would have > +to go to the file system to see if the entry is dirty. Thus, if we have > +N entries in a colliding group and we decide to write and `lstat()` only > +one of them, every subsequent `git-status` will have to read, convert, > +and hash the written file N - 1 times. By checking out all colliding > +entries (like the sequential code does), we only pay the overhead once, > +during checkout. > + > +Eligible Entries for Parallel Checkout > +-------------------------------------- > + > +As previously mentioned, not all entries passed to `checkout_entry()` > +will be considered eligible for parallel checkout. More specifically, we > +exclude: > + > +- Symbolic links; to avoid race conditions that, in combination with > + path collisions, could cause workers to write files at the wrong > + place. For example, if we were to concurrently check out a symlink > + 'a' -> 'b' and a regular file 'A/f' in a case-insensitive file system, > + we could potentially end up writing the file 'A/f' at 'a/f', due to a > + race condition. > + > +- Regular files that require external filters (either "one shot" filters > + or long-running process filters). These filters are black-boxes to Git > + and may have their own internal locking or non-concurrent assumptions. > + So it might not be safe to run multiple instances in parallel. > ++ > +Besides, long-running filters may use the delayed checkout feature to > +postpone the return of some filtered blobs. The delayed checkout queue > +and the parallel checkout queue are not compatible and should remain > +separated. Maybe: s/separated/separate/ > +Note: regular files that only require internal filters, like end-of-line > +conversion and re-encoding, are eligible for parallel checkout. > + > +Ineligible entries are checked out by the classic sequential codepath > +*before* spawning workers. > + > +Note: submodules's files are also eligible for parallel checkout (as > +long as they don't fall into any of the excluding categories mentioned > +above). But since each submodule is checked out in its own child > +process, we don't mix the superproject's and the submodules' files in > +the same parallel checkout process or queue. > + > +The API > +------- > + > +The parallel checkout API was designed with the goal to minimize changes s/to minimize/of minimizing/ > +to the current users of the checkout machinery. This means that they > +don't have to call a different function for sequential or parallel > +checkout. As already mentioned, `checkout_entry()` will automatically > +insert the given entry in the parallel checkout queue when this feature > +is enabled and the entry is eligible; otherwise, it will just write the > +entry right away, using the sequential code. In general, callers of the > +parallel checkout API should look similar to this: