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- Christopher Celio
- [email protected]
- UC Berkeley, Parlab
- 2010 Nov ##############################################################################
This repository contains a collection of small micro-kernels to stress-test memory systems and processors. See ./docs for more in-depth material on the theory behind these micro-benchmarks.
The github wiki shows some of the latest results on some interesting machines (examples include the RISC-V Rocket processor and the ARM Cortex A9).
See what happens! (works best if matplotlib is installed)
$ ./runall.sh
The "runall.sh" script is the preferred way to compile benchmarks, run the tests, collect the data, and plot the results.
You will need matplotlib installed to graph results. The 'open' command is also used, which only works on OSX (comment it out otherwise).
Set the desired tests to use through the $TEST variable in the script. If $RUN_LOCAL is set to 1, the tests will run on the local machine. Otherwise, you can provide the IP addresses in $remote_hosts to run the tests remotely (set up loginless login for best results). You will also need to get the corresponding $architecture(s) variable to specify the target ISA.
How to Run the "caches" benchmark:
$ cd $CCBENCH/caches
$ make clean; make
$ ./run_test.py -i large
$ open plots/caches.pdf
This runs the "caches" benchmark using the "large" input set (see input.txt for other set types). Data is written to the ./report/report.txt file (actually, a generated report file based on the current timestamp is used). If matplotlib is installed, ./run_test.py will also plot the results to a *.pdf file.
If the data is collected on a machine without matplotlib, you can plot the data by copying the report.txt file to a machine with matplotlib, and then running ./run_test.py using the "-n" flag ("no-run").
laptop$ cd $CCBENCH/caches
laptop$ scp $LINUX_BOX:~/ccbench/caches/report/report.txt ./report/report.txt
labtop$ ./run_test.py -n
laptop$ open plots/caches.pdf
You can feed it a specific report file using "-r my_report_name.txt".
Use the "-h" flag to ./run_test.py to learn about some of its other options, which includes specialized annotations for some processors.
The ccbench suite currently supports benchmarking processors (or emulators) running the following ISAs: x86, ARM, Tilera's TILE64, and UCB's RISC-V.
The easiest method is to use the "runall.sh" top-level script and specify the machine under the $architecture(s) variable (x86, arm, tile64, riscv). This drives the Makefile to compile the benchmark as appropriate and supplies the run_test.py script with the appropriate "-a" flag to invoke the proper target machine.
To add your own, new architecture (or to specialize your compiler/invocation settings), make of a copy of one of the directories in $CCBENCH/arch and change as needed. For example, you may want to use a different compiler with its own set of compiler flags, even when running on a particular x86 machine. Second, modify $CCBENCH/common/Makefile.tests to invoke your new architecture's Makefile fragment. No modifications are required to the python run_test.py scripts.
By default, a "generic" architecture setting is used in which gcc is called to compile the benchmark. The benchmark is then executed directly on the machine. This will work for both x86 and ARM. However, to get more specific compiler flags (as well as for targets that require cross-compiling), it is recommended that you specify exactly the desired target architecture.
An expected use-case is wanting to easily benchmark a zoo of processors that reside remotely. Typically, these processors will not have matplotlib installed. Using "runall.sh", one can easily specify a list of IP addresses, processor names, and architecture types of each of these target machines.
You will need to copy the ccbench directory on each remote host machine and point to this directory using the $HOST_CC_DIR variable in "runall.sh". Python is required, but matplotlib is not.
The "runall.sh" script can be run on your personal machine, which then ssh's into the remote host machine, compiles the benchmark, and invokes the benchmark on the target processor (either the same as the remote host machine, or could be an attached accelerator, etc.). The resulting data is dumped to a report file, which is then copied back to your local machine. Then, the data can be graphed locally.
To make life easier, it is recommended that you have passwordless login.
- run_tests.py - main CLI program to run and plot tests. Python code that invokes C code through bash. Found inside each micro-benchmark directory, and customized to plot data for the given micro-benchmark.
- common/ - Contains code shared by all tests. Includes a pthreads barrier implementation for platforms that do not natively support pthreads_barrier_t (i.e., OS X), and an abstracted clock interface.
- common/Makefile.tests - Main makefile used by all ukernels.
- reports/report.txt - Auto-generated by run_tests.py. Stores the results of all of the runs from its latest invocation (actual name is auto-generated and involves the current timestamp).
- plots/ - Contains plots generated by run_tests.py
- input.txt - Contains input sets used by run_tests.py
- caches - cache sizes, access latencies (pointer chase)
- cache2cache - cache-to-cache latency, bandwidth (ping pong arrays between threads)
- band_req - number of outstanding requests (pointer chase with multiple streams).
- band_req_mc - machine total bandwidth (pointer chase with multiple streams, with multiple threads)
- strided - strided memory acccesses: cache sizes, access latencies. Mostly ineffectual due to prefetching.
- peakflops - Prints out max flops of the machine. Does NOT plot anything (and so doesn't fit within the normal flow of runall.sh, etc.). Saves results to results.txt file.
- incluexclu - figure out if a LLC is inclusive (one thread runs out of L1, the other thread attempts to blow out the LLC). (Very experimental, not recommended for use).
- mem_interleaving- preliminary attempt to measure best interleaving of multiple threads with different memory distances between threads (very experimental, not recommended for use).
By setting the "architecture" variable as RISC-V (e.g., runall.sh), ccbench will run on the RISC-V processor "emulator" binary.*
Requirements:
- Your RISC-V C++ emulator binary must be named "emulator".
- The "emulator" binary must be in your path.
- The "dramsim2_ini" directory should be located in the same directory as
the benchmark binary (dramsim2 is used to simulate the off-chip memory).
This means a copy must exist in
$CCBENCH/caches, $ $CCBENCH/band_req, etc. Hopefully this restriction will be addressed at a later date. - patience. You CANNOT run RISC-V emulator using the same input sets you use with the other processors. We're talking a ~10,000x difference in run-time.
*Unless you specify the "proc" is "spike", in which case the RISC-V ISA simulator spike will be used. It is recommended that you begin all tests with "spike" first, as it is ~1000x faster than "emulator" and can suss out any bugs or issues that may arise.
Currently, this suite provides no support for multi-thread RISC-V operations. For example, the barrier code is completely ifdef'ed out. Currently, ccbench runs on top of the RISC-V proxy kernel (pk).
See LICENSE for details.
Buyer beware. Feel free to provide feedback as well as contribution.
The CS267 report provided in $CCBENCH/docs is out-of-date, so do not completely trust the graphs/results provided in it (but the theory behind the benchmarks is still relevant).
- make easier to use, extend
- improve RISC-V code performance (currently too many instructions in inner loops, etc.).
- improve RISC-V support (multi-thread, dramsim2 installation, etc.)
- modify peakflops to excercise FMA unit
- modify peakflops to better fit with other benchmarks, more capable of compiling to all architectures
- serial flag for c2c bandwidth (see if matchs intel's)
- make c2c pick between lat and band (or run and report both numbers?)
- different strides for c2c
- more work on mem_interleaving
- measure cache2cache with MSR prefetching turned off