Goal: Lowest possible total transfer time - to be only hardware limited (disc or network bandwidth not latency) and as efficient as possible (low CPU/memory/resources utilization)
We keep dependencies minimal in order to maximize portability and ensure a small binary size. As a bonus, this also minimizes compile time.
We aren't using exceptions for performance reasons and because using exceptions would make it harder to reason about the control flow of the library. We also believe the WDT library is easier to integrate as a result. Our philosophy is to write moderately structured and encapsulated C code as opposed to using every feature of C++.
We try to minimize the number of system calls, which is one of the reasons we are using blocking thread IOs. We can maximize system throughput because at any given point some threads are reading while others are writing, and data is buffered on both paths - keeping each subsystem busy while minimizing kernel to userspace switches.
While WDT is primarily a library, we also have a small command line tool which we use for tests and which is useful by itself. Here is a quick example:
Receiver side: (starts the server indicating destination directory)
[ldemailly@devbig074]$ wdt -directory /data/users/ldemailly/transfer1
Sender side: (discover and sends all files in a directory tree to destination)
[root@dev443]$ wdt -directory /usr/bin -destination devbig074.prn2
[=================================================] 100% 588.8 Mbytes/s
I0720 21:48:08.446014 3245296 Sender.cpp:314] Total sender time = 2.68699
seconds (0.00640992 dirTime). Transfer summary : Transfer status = OK. Number
of files transferred = 1887. Data Mbytes = 1582.08. Header kBytes = 62.083
(0.00383215% overhead). Total bytes = 1658999858. Wasted bytes due to
failure = 0 (0% overhead). Total sender throughput = 588.816 Mbytes/sec
(590.224 Mbytes/sec pure transf rate)
Note that in this simple example with lots of small files (/usr/bin from a linux distribution), but not much data (~1.5Gbyte), the maximum speed isn't as good as it would with more data (as there is still a TCP ramp up time even though it's faster because of parallelization) like when we use it in our production use cases.
See "wcp.sh" (which installs as "wcp") for a more detailed example.
In an internal use at Facebook to transfer RocksDB snapshot between hosts we are able to transfer data at a throttled 600 Mbytes/sec even across long distance, high latency links (e.g. Sweden to Oregon). That's 3x the speed of the previous highly optimized HTTP-based solution and with less strain on the system. When not throttling, we are able to easily saturate a 40 Gbit/s NIC and get near theoretical link speed (above 4 Gbytes/sec).
We have so far optimized WDT for servers with fast IOs - in particular flash card or in-memory read/writes. If you use disks throughput won't be as good, but we do plan on optimizing for disks as well in the future.
CMake for building WDT - See BUILD.md
gflags (google flags library) but only for the command line, the library doesn't depend on that
gmock and gtest (google testing) but only for tests
glog (google logging library)
Parts of Facebook's Folly open source library (as set in the CMakefile) Mostly conv, threadlocal and checksum support.
You can build and embed wdt as a library with as little as a C++11 compiler and glog - and you could macro away glog or replace it by printing to stderr if needed.
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deps/ Dependencies (open source version)
-
fbonly/ Stuff specific to facebook/ (not in open source version)
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bench/ Benchmark generation tools
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CMakeLists.txt, BUILD.md, .travis.yml, travis_linux.sh, travis_osx.sh Build definition file - use CMake to generate a Makefile or a project file for your favorite IDE - details in BUILD.md
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wdtCmdline.cpp
Main program which allows to have a server or client process to exercise the library (for end 2 end test as well as a standalone utility)
- wcp.sh
A script to use wdt like scp for single big files - pending splitting support inside wdt proper the script does the splitting for you. install as "wcp".
- WdtOptions.{h|cpp}
To specify the behavior of wdt. If wdt is used as a library, then the caller get the mutable object of options and set different options accordingly. When wdt is run in a standalone mode, behavior is changed through gflags in wdtCmdLine.cpp
- WdtBase.{h|cpp}
Common functionality and settings between Sender and Receiver
- WdtResourceController.{h|cpp}
Optional factory for Sender/Receiver with limit on number being created.
- ByteSource.h
Interface for a data element to be sent/transferred
- FileByteSource.{h|cpp}
Implementation/concrete subclass of ByteSource for a file identified as a relative path from a root dir. The identifier (path) sent remotely is the relative path
- SourceQueue.h
Interface for producing next ByteSource to be sent
- DirectorySourceQueue.{h|cpp}
Concrete implementation of SourceQueue producing all the files in a given directory, sorted by decreasing size (as they are discovered, you can start pulling from the queue even before all the files are found, it will return the current largest file)
- Sender.{h|cpp}
Formerly wdtlib.cpp - main code sending files
- FileCreator.{h|cpp}
Creates file and directories necessary for said file (mkdir -p like)
- Receiver.{h|cpp}
Formerly wdtlib.cpp - main code receiving files
- ServerSocket.{h|.cpp}
Encapsulate a server socket listening on a port and giving a file descriptor to be used to communicate with the client
- ClientSocket.{h|cpp}
Client socket wrapper - connection to a server port -> fd
- Protocol.{h|cpp}
Decodes/Encodes meta information needed to interpret the data stream: the id (file path) and size (byte length of the data)
- SocketUtils.{h|cpp}
Common socket related utilities (both client/server, sender/receiver side use)
- Throttler.{h|cpp}
Throttling code
- ErrorCodes.h
Header file for error codes
- Reporting.{h|cpp}
Class representing transfer stats and reports
The current implementation works well and has high efficiency. It is also extensible by implementing different byte sources both in and out. But inserting processing units isn't as easy.
For that we plan on restructuring the code to use a Zero copy stream/buffer pipeline: To maintain efficiency, the best overall total transfer time and time to first byte we can see WDT's internal architecture as chainable units
[Disk/flash/Storage IO] -> [Compression] -> [Protocol handling] -> [Encryption] -> [Network IO]
And the reverse chain on the receiving/writing end The trick is the data is variable length input and some units can change length and we need to process things by blocks Constraints/Design:
- No locking / contention when possible
- (Hard) Limits on memory used
- Minimal number of copies/moving memory around
- Still works the same for simple read file fd -> control -> write socked fd current basic implementation
Possible Solution(?) API:
- Double linked list of Units
- read/pull from left (pull() ?)
- push to the right (push() ?)
- end of stream from left
- propagate last bytes to right
Can still be fully synchronous / blocking, works thanks to eof handling (synchronous gives us lock free/single thread - internally a unit is free to use parallelization like the compression stage is likely to want/need)
Another thing we touched on is processing chunks out of order - by changing header to be ( fileid, offset, size ) instead of ( filename, size ) and assuming everything is following in 1 continuous block (will also help the use case of small number of large files/chunks) : mmap'in the target/destination file The issue then is who creates it in what order - similar to the directory creation problem - we could use a meta info channel to avoid locking/contention but that requires synchronization
We want things to work with even up to 1 second latency without incurring a 1 second delay before we send the first payload byte
See CONTRIBUTING.md
Please run the tests
CTEST_OUTPUT_ON_FAILURE=1 make test
And ideally also the manual tests (integration/porting upcoming)
wdt_e2e_test.sh wdt_download_resumption_test.sh wdt_network_test.sh wdt_max_send_test.sh
(facebook only:) Make sure to do the following, before "arc diff":
(cd wdt ; ./clangformat.sh )
fbconfig --clang --with-project-version clang:dev -r wdt
fbmake runtests
fbmake runtests_opt
fbmake opt
wdt/wdt_max_send_test.sh
and check the output of the last step to make sure one of the 3 runs is still above 20,000 Mbytes/sec (you may need to make sure you /dev/shm is mostly empty to get the best memory throughput, as well as not having a ton of random processes running during the test)
Also :
- Update this file
- Make sure your diff has a task
- Put (relevant) log output of sender/receiver in the diff test plan or comment
- Depending on the changes
- Perf: wdt/wdt_e2e_test.sh has a mix of ~ > 700 files, > 8 Gbytes/sec
- do run remote network tests (wdt/wdt_remote_test.sh)
- do run profiler and check profile results (wdt/fbonly/wdt_prof.sh) 80k small files at > 1.6 Gbyte/sec