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author | David Oberhollenzer <david.oberhollenzer@sigma-star.at> | 2020-02-22 17:28:52 +0100 |
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committer | David Oberhollenzer <david.oberhollenzer@sigma-star.at> | 2020-02-22 17:37:35 +0100 |
commit | 61bceccd5a9506d670bbe2ec225c0bb37bec1e9b (patch) | |
tree | 17ae5bad026fea691ac1d116f2699bae0d9ec52b | |
parent | 3d444455ee62eedc91b2eeeddb01d39ec0bcfecb (diff) |
Try to clarify the parallel block processor documentation
Signed-off-by: David Oberhollenzer <david.oberhollenzer@sigma-star.at>
-rw-r--r-- | doc/parallelism.txt | 108 |
1 files changed, 62 insertions, 46 deletions
diff --git a/doc/parallelism.txt b/doc/parallelism.txt index 142444f..046c559 100644 --- a/doc/parallelism.txt +++ b/doc/parallelism.txt @@ -39,58 +39,74 @@ 1) Thread Pool Based Block Processor ************************************ - The main challenge of parallelizing the block processor lies in the fact the - output HAS TO BE byte-for-byte equivalent to the serial reference - implementation. - - This means: - - File blocks have to be written in the exact same order as they - are submitted. - - If storing a fragment overflows the fragment block, the resulting - fragment block has to be written next, no file data. - - - The current implementation in winpthread.c (based on pthread or Windows - native threads, depending on whats available) uses the following approach: - - - Each submitted data block or fragment gets an incremental sequence number - and is appended to a FIFO queue. - - Multiple threads consume blocks from the queue and use the function - from common.c to process the dequeued blocks. - - Completed blocks are inserted into a "done" queue, sorted by their - sequence number. - - The main thread that submits blocks also dequeues the completed ones, - in order of their sequence number. - - Data blocks are given an "i/o sequence number" and inserted into - an I/O queue in order by this number. - - For fragments, it and calls the respective function from common.c - to deduplicate and append to the current fragment block. - - If the current fragment block overflows, it is given the next free - **I/O sequence number** and inserted into the **processing queue**. - - Completed fragment blocks are inserted into the I/O queue with - regard to the I/O sequence number they already have - - The main thread also dequeues I/O blocks ordered by their I/O sequence - number, and passes them to the respective common.c function that eventually - forwards it to the block writer. - - To make sure the queue doesn't fill all RAM, submitted blocks are counted. The - counter is also incremented when submitting to the I/O queue. The counter is - decremented when dequeueing completed blocks or blocks from the I/O queue. - - The block submission function tries to add blocks only if the counter is below - a pre-set threshold. If it is above, it first tries to dequeue I/O block, and - if there are no I/O blocks, dequeue and handle "done" blocks. If the "done" - queue is also empty, it uses signal/await to wait for the worker threads to - complete some blocks to process. The main thread in turn uses signal/await to - tell the worker threads it has submitted block (they wait if the work queue is - empty). + 1.1) Goals and Challanges + + In addition to the goal of boosting performance, the thread pool based block + processor must meet the following requirements: + + - Output MUST be deterministic and reproducible. I.e. feeding byte-for-byte + the same input MUST ALWAYS produce byte-for-byte the same output. + - Blocks the belong to a single file MUST be written in the order that + they were submitted. + - Output MUST be byte-for-byte equivalent to the serial reference + implementation. Changing the serial reference implementation to + achieve this is OK. + - I/O cannot be done in worker threads. The underlying back-end must be + assumed to not be thread safe and may get very confused by suddenly running + in a different thread, even if only one thread at a time uses it. + + + 1.2) The Current Approach + + The current implementation is in winpthread.c (based on pthread or Windows + native threads, depending on whats available). + + It keeps track of blocks in 3 different FIFO queues: + - A "work queue" that freshly submitted blocks go to. Worker threads take + blocks from this queue for processing. + - A "done queue" that worker threads submit blocks to, once completed. + - An "I/O queue" that contains blocks ready to be written to disk. + + + When the main thread submits a block, it gives it an incremental "processing" + sequence number and appends it to the "work queue". Thread pool workers take + the first best block of the queue, process it and added it to the "done" + queue, sorted by its processing sequence number. + + The main thread dequeues blocks from the done queue sorted by their processing + sequence number, using a second counter to make sure blocks are dequeued in + the exact same order as they were added to the work queue. + + Regular data blocks from the "done queue" are given an incremental I/O + sequence number and added to the "I/O queue", sorted by this number. + + Fragments are deduplicated and consolidated into a fragment block. If this + block overflows, it is appended to the "work queue" the exact same way as + regular blocks, but it is **already given an I/O sequence number**. + + If a block dequeued from the "done queue" turns out to be a fragment block, it + is added to the "I/O queue", sorted by its I/O sequence number **that it + already has**, i.e. no new sequence number is allocated. + + The I/O queue is dequeued in the same fashion as the "done queue", using a + second counter to enforce ordering. + + + The actual implementation interleaves enqueueing and dequeueing in the block + submission function. It dequeues blocks if the queues reach a pre-set maximum + backlog. In that case, it tries to dequeue from the I/O queue first and if + that fails, tries to dequeue from the "done queue". If that also fails, it + uses signal/await to be woken up by a worker thread once it adds a block to + the "done queue". Fragment post-processing and re-queueing of blocks is done + inside the critical region, but the actual I/O is obviously done outside. + Profiling on small filesystems using perf shows that the outlined approach seems to perform quite well for CPU bound compressors like XZ, but doesn't add a lot for I/O bound compressors like zstd. Actual measurements still need to be done. - If you have a more insights or a better idea, please let me know. + If you have a better idea how to do this, please let me know. 2) Benchmarks |