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Add a script for visualizing the JSON output generated by existing glibc string microbenchmarks. Overview: plot_strings.py is capable of plotting benchmark results in the following formats, which are controlled with the -p or --plot argument: 1. absolute timings (-p time): plot the timings as they are in the input benchmark results file. 2. relative timings (-p rel): plot relative timing difference with respect to a chosen ifunc (controlled with -b argument). 3. performance relative to max (-p max): for each varied parameter value, plot 1/timing as the percentage of the maximum value out of the plotted ifuncs. 4. throughput (-p thru): plot varied parameter value over timing For all types of graphs, there is an option to explicitly specify the subset of ifuncs to plot using the --ifuncs parameter. For plot types 1. and 4. one can hide/expose exact benchmark figures using the --values flag. When plotting relative timing differences between ifuncs, the first ifunc listed in the input JSON file is the baseline, unless the baseline implementation is explicitly chosen with the --baseline parameter. For the ease of reading, the script marks the statistically insignificant range on the graphs. The default is +-5% but this value can be controlled with the --threshold parameter. To accommodate for the heterogeneity in benchmark results files, one can control i.e the x-axis scale, the resolution (dpi) of the generated figures or the key to access the varied parameter value in the JSON file. The corresponding options are --logarithmic, --resolution or --key. The --key parameter ensures that plot_strings.py works with all files which pass JSON schema validation. The schema can be chosen with the --schema parameter. If a window manager is available, one can enable interactive figure display using the --display flag. Finally, one can use the --grid flag to enable grid lines in the generated figures. Implementation: plot_strings.py traverses the JSON tree until a 'results' array is found and generates a separate figure for each such array. The figure is then saved to a file in one of the available formats (controlled with the --extension parameter). As the tree is traversed, the recursive function tracks the metadata about the test being run, so that each figure has a unique and meaningful title and filename. While plot_strings.py works with existing benchmarks, provisions have been made to allow adding more structure and metadata to these benchmarks. Currently, many benchmarks produce multiple timing values for the same value of the varied parameter (typically 'length'). Mutiple data points for the same parameter usually mean that some other parameter was varied as well, for example, if memmove's src and dst buffers overlap or not (see bench-memmove-walk.c and bench-memmove-walk.out). Unfortunately, this information is not exposed in the benchmark output file, so plot_strings.py has to resort to computing the geometric mean of these multiple values. In the process, useful information about the benchmark configuration is lost. Also, averaging the timings for different alignments can hide useful characterstics of the benchmarked ifuncs. Testing: plot_strings.py has been tested on all existing string microbenchmarks which produce results in JSON format. The script was tested on both Windows 10 and Ubuntu 16.04.2 LTS. It runs on both python 2 and 3 (2.7.12 and 3.5.12 tested). Useful commands: 1. Plot timings for all ifuncs in bench-strlen.out: $ ./plot_strings.py bench-strlen.out 2. Display help: $ ./plot_strings.py -h 3. Plot throughput for __memset_avx512_unaligned_erms and __memset_avx512_unaligned. Save the generated figure in pdf format to 'results/'. Use logarithmic x-axis scale, show grid lines and expose the performance numbers: $ ./plot_strings.py bench.out -o results/ -lgv -e pdf -p thru \ -i __memset_avx512_unaligned_erms __memset_avx512_unaligned 4. Plot relative timings for all ifuncs in bench.out with __generic_memset as baseline. Display percentage difference threshold of +-10%: $ ./plot_strings.py bench.out -p rel -b __generic_memset -t 10 Discussion: 1. I would like to propose relaxing the benchout_strings.schema.json to allow specifying either a 'results' array with 'timings' (as before) or a 'variants' array. See below example: { "timing_type": "hp_timing", "functions": { "memcpy": { "bench-variant": "default", "ifuncs": ["generic_memcpy", "__memcpy_thunderx"], "variants": [ { "name": "powers of 2", "variants": [ { "name": "both aligned", "results": [ { "length": 1, "align1": 0, "align2": 0, "timings": [x, y] }, { "length": 2, "align1": 0, "align2": 0, "timings": [x, y] }, ... { "length": 65536, "align1": 0, "align2": 0, "timings": [x, y] }] }, { "name": "dst misaligned", "results": [ { "length": 1, "align1": 0, "align2": 0, "timings": [x, y] }, { "length": 2, "align1": 0, "align2": 1, "timings": [x, y] }, ... 'variants' array consists of objects such that each object has a 'name' attribute to describe the configuration of a particular test in the benchmark. This can be a description, for example, of how the parameter was varied or what was the buffer alignment tested. The 'name' attribute is then followed by another 'variants' array or a 'results' array. The nesting of variants allows arbitrary grouping of benchmark timings, while allowing description of these groups. Using recusion, it is possible to proceduraly create titles and filenames for the figures being generated. |
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.. | ||
scripts | ||
strcoll-inputs | ||
acos-inputs | ||
acosh-inputs | ||
asin-inputs | ||
asinh-inputs | ||
atan-inputs | ||
atanh-inputs | ||
bench-malloc-simple.c | ||
bench-malloc-thread.c | ||
bench-math-inlines.c | ||
bench-memccpy.c | ||
bench-memchr.c | ||
bench-memcmp.c | ||
bench-memcpy-large.c | ||
bench-memcpy-random.c | ||
bench-memcpy-walk.c | ||
bench-memcpy.c | ||
bench-memmem.c | ||
bench-memmove-large.c | ||
bench-memmove-walk.c | ||
bench-memmove.c | ||
bench-mempcpy.c | ||
bench-memrchr.c | ||
bench-memset-large.c | ||
bench-memset-walk.c | ||
bench-memset.c | ||
bench-rawmemchr.c | ||
bench-skeleton.c | ||
bench-stpcpy_chk.c | ||
bench-stpcpy.c | ||
bench-stpncpy.c | ||
bench-strcasecmp.c | ||
bench-strcasestr.c | ||
bench-strcat.c | ||
bench-strchr.c | ||
bench-strchrnul.c | ||
bench-strcmp.c | ||
bench-strcoll.c | ||
bench-strcpy_chk.c | ||
bench-strcpy.c | ||
bench-strcspn.c | ||
bench-string.h | ||
bench-strlen.c | ||
bench-strncasecmp.c | ||
bench-strncat.c | ||
bench-strncmp.c | ||
bench-strncpy.c | ||
bench-strnlen.c | ||
bench-strpbrk.c | ||
bench-strrchr.c | ||
bench-strsep.c | ||
bench-strspn.c | ||
bench-strstr.c | ||
bench-strtod.c | ||
bench-strtok.c | ||
bench-timing-type.c | ||
bench-timing.h | ||
bench-util.c | ||
bench-util.h | ||
bench-wcpcpy.c | ||
bench-wcpncpy.c | ||
bench-wcscat.c | ||
bench-wcschr.c | ||
bench-wcschrnul.c | ||
bench-wcscmp.c | ||
bench-wcscpy.c | ||
bench-wcscspn.c | ||
bench-wcslen.c | ||
bench-wcsncat.c | ||
bench-wcsncmp.c | ||
bench-wcsncpy.c | ||
bench-wcsnlen.c | ||
bench-wcspbrk.c | ||
bench-wcsrchr.c | ||
bench-wcsspn.c | ||
bench-wmemchr.c | ||
bench-wmemcmp.c | ||
bench-wmemset.c | ||
cos-inputs | ||
cosf-inputs | ||
cosh-inputs | ||
exp2-inputs | ||
exp2f-inputs | ||
exp-inputs | ||
expf-inputs | ||
ffs-inputs | ||
ffsll-inputs | ||
fmax-inputs | ||
fmaxf-inputs | ||
fmin-inputs | ||
fminf-inputs | ||
hypot-inputs | ||
isfinite-inputs | ||
isinf-inputs | ||
isnan-inputs | ||
json-lib.c | ||
json-lib.h | ||
log2-inputs | ||
log2f-inputs | ||
log-inputs | ||
logb-inputs | ||
logbf-inputs | ||
logf-inputs | ||
Makefile | ||
modf-inputs | ||
pow-inputs | ||
powf-inputs | ||
pthread_once-inputs | ||
pthread_once-source.c | ||
README | ||
rint-inputs | ||
sin-inputs | ||
sincos-inputs | ||
sincosf-inputs | ||
sinf-inputs | ||
sinh-inputs | ||
sprintf-inputs | ||
sprintf-source.c | ||
sqrt-inputs | ||
tan-inputs | ||
tanh-inputs | ||
thread_create-inputs | ||
thread_create-source.c | ||
trunc-inputs | ||
truncf-inputs |
Using the glibc microbenchmark suite ==================================== The glibc microbenchmark suite automatically generates code for specified functions, builds and calls them repeatedly for given inputs to give some basic performance properties of the function. Running the benchmark: ===================== The benchmark needs python 2.7 or later in addition to the dependencies required to build the GNU C Library. One may run the benchmark by invoking make as follows: $ make bench This runs each function for 10 seconds and appends its output to benchtests/bench.out. To ensure that the tests are rebuilt, one could run: $ make bench-clean The duration of each test can be configured setting the BENCH_DURATION variable in the call to make. One should run `make bench-clean' before changing BENCH_DURATION. $ make BENCH_DURATION=1 bench The benchmark suite does function call measurements using architecture-specific high precision timing instructions whenever available. When such support is not available, it uses clock_gettime (CLOCK_MONOTONIC). On x86 processors, RDTSCP instruction provides more precise timing data than RDTSC instruction. All x86 processors since 2010 support RDTSCP instruction. One can force the benchmark to use RDTSCP by invoking make as follows: $ make USE_RDTSCP=1 bench One must run `make bench-clean' before changing the measurement method. Running benchmarks on another target: ==================================== If the target where you want to run benchmarks is not capable of building the code or you're cross-building, you could build and execute the benchmark in separate steps. On the build system run: $ make bench-build and then copy the source and build directories to the target and run the benchmarks from the build directory as usual: $ make bench make sure the copy preserves timestamps by using either rsync or scp -p otherwise the above command may try to build the benchmark again. Benchmarks that require generated code to be executed during the build are skipped when cross-building. Running subsets of benchmarks: ============================== To run only a subset of benchmarks, one may invoke make as follows $ make bench BENCHSET="bench-pthread bench-math malloc-thread" where BENCHSET may be a space-separated list of the following values: bench-math bench-pthread bench-string string-benchset wcsmbs-benchset stdlib-benchset stdio-common-benchset math-benchset malloc-thread Adding a function to benchtests: =============================== If the name of the function is `foo', then the following procedure should allow one to add `foo' to the bench tests: - Append the function name to the bench variable in the Makefile. - Make a file called `foo-inputs` to provide the definition and input for the function. The file should have some directives telling the parser script about the function and then one input per line. Directives are lines that have a special meaning for the parser and they begin with two hashes '##'. The following directives are recognized: - args: This should be assigned a colon separated list of types of the input arguments. This directive may be skipped if the function does not take any inputs. One may identify output arguments by nesting them in <>. The generator will create variables to get outputs from the calling function. - ret: This should be assigned the type that the function returns. This directive may be skipped if the function does not return a value. - includes: This should be assigned a comma-separated list of headers that need to be included to provide declarations for the function and types it may need (specifically, this includes using "#include <header>"). - include-sources: This should be assigned a comma-separated list of source files that need to be included to provide definitions of global variables and functions (specifically, this includes using "#include "source"). See pthread_once-inputs and pthreads_once-source.c for an example of how to use this to benchmark a function that needs state across several calls. - init: Name of an initializer function to call to initialize the benchtest. - name: See following section for instructions on how to use this directive. Lines beginning with a single hash '#' are treated as comments. See pow-inputs for an example of an input file. Multiple execution units per function: ===================================== Some functions have distinct performance characteristics for different input domains and it may be necessary to measure those separately. For example, some math functions perform computations at different levels of precision (64-bit vs 240-bit vs 768-bit) and mixing them does not give a very useful picture of the performance of these functions. One could separate inputs for these domains in the same file by using the `name' directive that looks something like this: ##name: 240bit See the pow-inputs file for an example of what such a partitioned input file would look like. It is also possible to measure throughput of a (partial) trace extracted from a real workload. In this case the whole trace is iterated over multiple times rather than repeating every input multiple times. This can be done via: ##name: workload-<name> Benchmark Sets: ============== In addition to standard benchmarking of functions, one may also generate custom outputs for a set of functions. This is currently used by string function benchmarks where the aim is to compare performance between implementations at various alignments and for various sizes. To add a benchset for `foo': - Add `foo' to the benchset variable. - Write your bench-foo.c that prints out the measurements to stdout. - On execution, a bench-foo.out is created in $(objpfx) with the contents of stdout. Reading String Benchmark Results: ================================ Some of the string benchmark results are now in JSON to make it easier to read in scripts. Use the benchtests/compare_strings.py script to show the results in a tabular format, generate graphs and more. Run benchtests/scripts/compare_strings.py -h for usage information.