platform_bionic/benchmarks/bionic_benchmarks.cpp
Adhemerval Zanella eda94aa1ae Add option to define ranges sets for benchmarks
This patch add an option to use the pre-define set of ranges along
with macros AT_ONEBUF_MANUAL_ALIGN_* and AT_TWOBUF_MANUAL_ALIGN1_*.

The size argument can be either a number or a string representing
the sets of values:

  * SMALL for values between 1 and 256.
  * MEDIUM for values between 512 and 128KB.
  * LARGE for values between 256KB and 2048KB.

Test: Ran new string test suite with a single bionic iteration.
Change-Id: Ieda81ee9a5019991b0b2f97d4ca3a237127c5848
2018-08-11 00:27:27 +00:00

603 lines
19 KiB
C++

/*
* Copyright (C) 2017 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include <err.h>
#include <getopt.h>
#include <inttypes.h>
#include <math.h>
#include <sys/resource.h>
#include <map>
#include <mutex>
#include <sstream>
#include <string>
#include <utility>
#include <vector>
#include <android-base/file.h>
#include <android-base/stringprintf.h>
#include <android-base/strings.h>
#include <benchmark/benchmark.h>
#include <tinyxml2.h>
#include "util.h"
#define _STR(x) #x
#define STRINGFY(x) _STR(x)
static const std::vector<int> kCommonSizes{
8,
64,
512,
1 * KB,
8 * KB,
16 * KB,
32 * KB,
64 * KB,
128 * KB,
};
static const std::vector<int> kSmallSizes{
// Increment by 1
1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16,
// Increment by 8
24, 32, 40, 48, 56, 64, 72, 80, 88, 96, 104, 112, 120, 128, 136, 144,
// Increment by 16
160, 176, 192, 208, 224, 240, 256,
};
static const std::vector<int> kMediumSizes{
512,
1 * KB,
8 * KB,
16 * KB,
32 * KB,
64 * KB,
128 * KB,
};
static const std::vector<int> kLargeSizes{
256 * KB,
512 * KB,
1024 * KB,
2048 * KB,
};
static std::map<std::string, const std::vector<int> &> kSizes{
{ "SMALL", kSmallSizes },
{ "MEDIUM", kMediumSizes },
{ "LARGE", kLargeSizes },
};
std::map<std::string, std::pair<benchmark_func_t, std::string>> g_str_to_func;
std::mutex g_map_lock;
static struct option g_long_options[] =
{
{"bionic_cpu", required_argument, nullptr, 'c'},
{"bionic_xml", required_argument, nullptr, 'x'},
{"bionic_iterations", required_argument, nullptr, 'i'},
{"bionic_extra", required_argument, nullptr, 'a'},
{"help", no_argument, nullptr, 'h'},
{nullptr, 0, nullptr, 0},
};
typedef std::vector<std::vector<int64_t>> args_vector_t;
void Usage() {
printf("Usage:\n");
printf("bionic_benchmarks [--bionic_cpu=<cpu_to_isolate>]\n");
printf(" [--bionic_xml=<path_to_xml>]\n");
printf(" [--bionic_iterations=<num_iter>]\n");
printf(" [--bionic_extra=\"<fn_name> <arg1> <arg 2> ...\"]\n");
printf(" [<Google benchmark flags>]\n");
printf("Google benchmark flags:\n");
int fake_argc = 2;
char argv0[] = "bionic_benchmarks";
char argv1[] = "--help";
char* fake_argv[3] {argv0, argv1, nullptr};
benchmark::Initialize(&fake_argc, fake_argv);
exit(1);
}
// This function removes any bionic benchmarks command line arguments by checking them
// against g_long_options. It fills new_argv with the filtered args.
void SanitizeOpts(int argc, char** argv, std::vector<char*>* new_argv) {
// TO THOSE ADDING OPTIONS: This currently doesn't support optional arguments.
(*new_argv)[0] = argv[0];
for (int i = 1; i < argc; ++i) {
char* optarg = argv[i];
size_t opt_idx = 0;
// Iterate through g_long_options until either we hit the end or we have a match.
for (opt_idx = 0; g_long_options[opt_idx].name &&
strncmp(g_long_options[opt_idx].name, optarg + 2,
strlen(g_long_options[opt_idx].name)); ++opt_idx) {
}
if (!g_long_options[opt_idx].name) {
new_argv->push_back(optarg);
} else {
if (g_long_options[opt_idx].has_arg == required_argument) {
// If the arg was passed in with an =, it spans one char *.
// Otherwise, we skip a spot for the argument.
if (!strchr(optarg, '=')) {
i++;
}
}
}
}
new_argv->push_back(nullptr);
}
bench_opts_t ParseOpts(int argc, char** argv) {
bench_opts_t opts;
int opt;
int option_index = 0;
// To make this parser handle the benchmark options silently:
extern int opterr;
opterr = 0;
while ((opt = getopt_long(argc, argv, "c:x:i:a:h", g_long_options, &option_index)) != -1) {
if (opt == -1) {
break;
}
switch (opt) {
case 'c':
if (*optarg) {
char* check_null;
opts.cpu_to_lock = strtol(optarg, &check_null, 10);
if (*check_null) {
errx(1, "ERROR: Args %s is not a valid integer.", optarg);
}
} else {
printf("ERROR: no argument specified for bionic_cpu\n");
Usage();
}
break;
case 'x':
if (*optarg) {
opts.xmlpath = optarg;
} else {
printf("ERROR: no argument specified for bionic_xml\n");
Usage();
}
break;
case 'a':
if (*optarg) {
opts.extra_benchmarks.push_back(optarg);
} else {
printf("ERROR: no argument specified for bionic_extra\n");
Usage();
}
break;
case 'i':
if (*optarg){
char* check_null;
opts.num_iterations = strtol(optarg, &check_null, 10);
if (*check_null != '\0' or opts.num_iterations < 0) {
errx(1, "ERROR: Args %s is not a valid number of iterations.", optarg);
}
} else {
printf("ERROR: no argument specified for bionic_iterations\n");
Usage();
}
break;
case 'h':
Usage();
break;
case '?':
break;
default:
exit(1);
}
}
return opts;
}
// This is a wrapper for every function call for per-benchmark cpu pinning.
void LockAndRun(benchmark::State& state, benchmark_func_t func_to_bench, int cpu_to_lock) {
if (cpu_to_lock >= 0) LockToCPU(cpu_to_lock);
// To avoid having to link against Google benchmarks in libutil,
// benchmarks are kept without parameter information, necessitating this cast.
reinterpret_cast<void(*) (benchmark::State&)>(func_to_bench)(state);
}
static constexpr char kOnebufManualStr[] = "AT_ONEBUF_MANUAL_ALIGN_";
static constexpr char kTwobufManualStr[] = "AT_TWOBUF_MANUAL_ALIGN1_";
static bool ParseOnebufManualStr(std::string& arg, args_vector_t* to_populate) {
// The format of this is:
// AT_ONEBUF_MANUAL_ALIGN_XX_SIZE_YY
// Where:
// XX is the alignment
// YY is the size
// The YY size can be either a number or a string representing the pre-defined
// sets of values:
// SMALL (for values between 1 and 256)
// MEDIUM (for values between 512 and 128KB)
// LARGE (for values between 256KB and 2048KB)
int64_t align;
int64_t size;
char sizes[32] = { 0 };
int ret;
ret = sscanf(arg.c_str(), "AT_ONEBUF_MANUAL_ALIGN_%" SCNd64 "_SIZE_%" SCNd64,
&align, &size);
if (ret == 1) {
ret = sscanf(arg.c_str(), "AT_ONEBUF_MANUAL_ALIGN_%" SCNd64 "_SIZE_"
"%" STRINGFY(sizeof(sizes)-1) "s", &align, sizes);
}
if (ret != 2) {
return false;
}
// Verify the alignment is powers of 2.
if (align != 0 && (align & (align - 1)) != 0) {
return false;
}
auto sit = kSizes.find(sizes);
if (sit == kSizes.cend()) {
to_populate->push_back({size, align});
} else {
for (auto ssize : sit->second) {
to_populate->push_back({ssize, align});
}
}
return true;
}
static bool ParseTwobufManualStr(std::string& arg, args_vector_t* to_populate) {
// The format of this is:
// AT_TWOBUF_MANUAL_ALIGN1_XX_ALIGN2_YY_SIZE_ZZ
// Where:
// XX is the alignment of the first argument
// YY is the alignment of the second argument
// ZZ is the size
// The ZZ size can be either a number or a string representing the pre-defined
// sets of values:
// SMALL (for values between 1 and 256)
// MEDIUM (for values between 512 and 128KB)
// LARGE (for values between 256KB and 2048KB)
int64_t align1;
int64_t align2;
int64_t size;
char sizes[32] = { 0 };
int ret;
ret = sscanf(arg.c_str(), "AT_TWOBUF_MANUAL_ALIGN1_%" SCNd64 "_ALIGN2_%" SCNd64 "_SIZE_%" SCNd64,
&align1, &align2, &size);
if (ret == 2) {
ret = sscanf(arg.c_str(), "AT_TWOBUF_MANUAL_ALIGN1_%" SCNd64 "_ALIGN2_%" SCNd64 "_SIZE_"
"%" STRINGFY(sizeof(sizes)-1) "s",
&align1, &align2, sizes);
}
if (ret != 3) {
return false;
}
// Verify the alignments are powers of 2.
if ((align1 != 0 && (align1 & (align1 - 1)) != 0)
|| (align2 != 0 && (align2 & (align2 - 1)) != 0)) {
return false;
}
auto sit = kSizes.find(sizes);
if (sit == kSizes.cend()) {
to_populate->push_back({size, align1, align2});
} else {
for (auto ssize : sit->second) {
to_populate->push_back({ssize, align1, align2});
}
}
return true;
}
args_vector_t* ResolveArgs(args_vector_t* to_populate, std::string args,
std::map<std::string, args_vector_t>& args_shorthand) {
// args is either a space-separated list of ints, a macro name, or
// special free form macro.
// To ease formatting in XML files, args is left and right trimmed.
if (args_shorthand.count(args)) {
return &args_shorthand[args];
}
// Check for free form macro.
if (android::base::StartsWith(args, kOnebufManualStr)) {
if (!ParseOnebufManualStr(args, to_populate)) {
errx(1, "ERROR: Bad format of macro %s, should be AT_ONEBUF_MANUAL_ALIGN_XX_SIZE_YY",
args.c_str());
}
return to_populate;
} else if (android::base::StartsWith(args, kTwobufManualStr)) {
if (!ParseTwobufManualStr(args, to_populate)) {
errx(1,
"ERROR: Bad format of macro %s, should be AT_TWOBUF_MANUAL_ALIGN1_XX_ALIGNE2_YY_SIZE_ZZ",
args.c_str());
}
return to_populate;
}
to_populate->push_back(std::vector<int64_t>());
std::stringstream sstream(args);
std::string argstr;
while (sstream >> argstr) {
char* check_null;
int converted = static_cast<int>(strtol(argstr.c_str(), &check_null, 10));
if (*check_null) {
errx(1, "ERROR: Args str %s contains an invalid macro or int.", args.c_str());
}
(*to_populate)[0].push_back(converted);
}
return to_populate;
}
void RegisterGoogleBenchmarks(bench_opts_t primary_opts, bench_opts_t secondary_opts,
const std::string& fn_name, args_vector_t* run_args) {
if (g_str_to_func.find(fn_name) == g_str_to_func.end()) {
errx(1, "ERROR: No benchmark for function %s", fn_name.c_str());
}
long iterations_to_use = primary_opts.num_iterations ? primary_opts.num_iterations :
secondary_opts.num_iterations;
int cpu_to_use = -1;
if (primary_opts.cpu_to_lock >= 0) {
cpu_to_use = primary_opts.cpu_to_lock;
} else if (secondary_opts.cpu_to_lock >= 0) {
cpu_to_use = secondary_opts.cpu_to_lock;
}
benchmark_func_t benchmark_function = g_str_to_func.at(fn_name).first;
for (const std::vector<int64_t>& args : (*run_args)) {
auto registration = benchmark::RegisterBenchmark(fn_name.c_str(), LockAndRun,
benchmark_function,
cpu_to_use)->Args(args);
if (iterations_to_use > 0) {
registration->Iterations(iterations_to_use);
}
}
}
void RegisterCliBenchmarks(bench_opts_t cmdline_opts,
std::map<std::string, args_vector_t>& args_shorthand) {
// Register any of the extra benchmarks that were specified in the options.
args_vector_t arg_vector;
args_vector_t* run_args = &arg_vector;
for (const std::string& extra_fn : cmdline_opts.extra_benchmarks) {
android::base::Trim(extra_fn);
size_t first_space_pos = extra_fn.find(' ');
std::string fn_name = extra_fn.substr(0, first_space_pos);
std::string cmd_args;
if (first_space_pos != std::string::npos) {
cmd_args = extra_fn.substr(extra_fn.find(' ') + 1);
} else {
cmd_args = "";
}
run_args = ResolveArgs(run_args, cmd_args, args_shorthand);
RegisterGoogleBenchmarks(bench_opts_t(), cmdline_opts, fn_name, run_args);
run_args = &arg_vector;
arg_vector.clear();
}
}
int RegisterXmlBenchmarks(bench_opts_t cmdline_opts,
std::map<std::string, args_vector_t>& args_shorthand) {
// Structure of the XML file:
// - Element "fn" Function to benchmark.
// - - Element "iterations" Number of iterations to run. Leaving this blank uses
// Google benchmarks' convergence heuristics.
// - - Element "cpu" CPU to isolate to, if any.
// - - Element "args" Whitespace-separated list of per-function integer arguments, or
// one of the macros defined in util.h.
tinyxml2::XMLDocument doc;
if (doc.LoadFile(cmdline_opts.xmlpath.c_str()) != tinyxml2::XML_SUCCESS) {
doc.PrintError();
return doc.ErrorID();
}
// Read and register the functions.
tinyxml2::XMLNode* fn = doc.FirstChildElement("fn");
while (fn) {
if (fn == fn->ToComment()) {
// Skip comments.
fn = fn->NextSibling();
continue;
}
auto fn_elem = fn->FirstChildElement("name");
if (!fn_elem) {
errx(1, "ERROR: Malformed XML entry: missing name element.");
}
std::string fn_name = fn_elem->GetText();
if (fn_name.empty()) {
errx(1, "ERROR: Malformed XML entry: error parsing name text.");
}
auto* xml_args = fn->FirstChildElement("args");
args_vector_t arg_vector;
args_vector_t* run_args = ResolveArgs(&arg_vector,
xml_args ? android::base::Trim(xml_args->GetText()) : "",
args_shorthand);
// XML values for CPU and iterations take precedence over those passed in via CLI.
bench_opts_t xml_opts{};
auto* num_iterations_elem = fn->FirstChildElement("iterations");
if (num_iterations_elem) {
int temp;
num_iterations_elem->QueryIntText(&temp);
xml_opts.num_iterations = temp;
}
auto* cpu_to_lock_elem = fn->FirstChildElement("cpu");
if (cpu_to_lock_elem) {
int temp;
cpu_to_lock_elem->QueryIntText(&temp);
xml_opts.cpu_to_lock = temp;
}
RegisterGoogleBenchmarks(xml_opts, cmdline_opts, fn_name, run_args);
fn = fn->NextSibling();
}
return 0;
}
static void SetArgs(const std::vector<int>& sizes, args_vector_t* args) {
for (int size : sizes) {
args->push_back({size});
}
}
static void SetArgs(const std::vector<int>& sizes, int align, args_vector_t* args) {
for (int size : sizes) {
args->push_back({size, align});
}
}
static void SetArgs(const std::vector<int>& sizes, int align1, int align2, args_vector_t* args) {
for (int size : sizes) {
args->push_back({size, align1, align2});
}
}
static args_vector_t GetArgs(const std::vector<int>& sizes) {
args_vector_t args;
SetArgs(sizes, &args);
return args;
}
static args_vector_t GetArgs(const std::vector<int>& sizes, int align) {
args_vector_t args;
SetArgs(sizes, align, &args);
return args;
}
static args_vector_t GetArgs(const std::vector<int>& sizes, int align1, int align2) {
args_vector_t args;
SetArgs(sizes, align1, align2, &args);
return args;
}
std::map<std::string, args_vector_t> GetShorthand() {
std::vector<int> all_sizes(kSmallSizes);
all_sizes.insert(all_sizes.end(), kMediumSizes.begin(), kMediumSizes.end());
all_sizes.insert(all_sizes.end(), kLargeSizes.begin(), kLargeSizes.end());
std::map<std::string, args_vector_t> args_shorthand {
{"AT_COMMON_SIZES", GetArgs(kCommonSizes)},
{"AT_SMALL_SIZES", GetArgs(kSmallSizes)},
{"AT_MEDIUM_SIZES", GetArgs(kMediumSizes)},
{"AT_LARGE_SIZES", GetArgs(kLargeSizes)},
{"AT_ALL_SIZES", GetArgs(all_sizes)},
{"AT_ALIGNED_ONEBUF", GetArgs(kCommonSizes, 0)},
{"AT_ALIGNED_ONEBUF_SMALL", GetArgs(kSmallSizes, 0)},
{"AT_ALIGNED_ONEBUF_MEDIUM", GetArgs(kMediumSizes, 0)},
{"AT_ALIGNED_ONEBUF_LARGE", GetArgs(kLargeSizes, 0)},
{"AT_ALIGNED_ONEBUF_ALL", GetArgs(all_sizes, 0)},
{"AT_ALIGNED_TWOBUF", GetArgs(kCommonSizes, 0, 0)},
{"AT_ALIGNED_TWOBUF_SMALL", GetArgs(kSmallSizes, 0, 0)},
{"AT_ALIGNED_TWOBUF_MEDIUM", GetArgs(kMediumSizes, 0, 0)},
{"AT_ALIGNED_TWOBUF_LARGE", GetArgs(kLargeSizes, 0, 0)},
{"AT_ALIGNED_TWOBUF_ALL", GetArgs(all_sizes, 0, 0)},
// Do not exceed 512. that is about the largest number of properties
// that can be created with the current property area size.
{"NUM_PROPS", args_vector_t{ {1}, {4}, {16}, {64}, {128}, {256}, {512} }},
{"MATH_COMMON", args_vector_t{ {0}, {1}, {2}, {3} }},
{"MATH_SINCOS_COMMON", args_vector_t{ {0}, {1}, {2}, {3}, {4}, {5}, {6}, {7} }},
};
args_vector_t args_onebuf;
args_vector_t args_twobuf;
for (int size : all_sizes) {
args_onebuf.push_back({size, 0});
args_twobuf.push_back({size, 0, 0});
// Skip alignments on zero sizes.
if (size == 0) {
continue;
}
for (int align1 = 1; align1 <= 32; align1 <<= 1) {
args_onebuf.push_back({size, align1});
for (int align2 = 1; align2 <= 32; align2 <<= 1) {
args_twobuf.push_back({size, align1, align2});
}
}
}
args_shorthand.emplace("AT_MANY_ALIGNED_ONEBUF", args_onebuf);
args_shorthand.emplace("AT_MANY_ALIGNED_TWOBUF", args_twobuf);
return args_shorthand;
}
static bool FileExists(const std::string& file) {
struct stat st;
return stat(file.c_str(), &st) != -1 && S_ISREG(st.st_mode);
}
void RegisterAllBenchmarks(const bench_opts_t& opts,
std::map<std::string, args_vector_t>& args_shorthand) {
for (auto& entry : g_str_to_func) {
auto& function_info = entry.second;
args_vector_t arg_vector;
args_vector_t* run_args = ResolveArgs(&arg_vector, function_info.second,
args_shorthand);
RegisterGoogleBenchmarks(bench_opts_t(), opts, entry.first, run_args);
}
}
int main(int argc, char** argv) {
std::map<std::string, args_vector_t> args_shorthand = GetShorthand();
bench_opts_t opts = ParseOpts(argc, argv);
std::vector<char*> new_argv(argc);
SanitizeOpts(argc, argv, &new_argv);
if (opts.xmlpath.empty()) {
// Don't add the default xml file if a user is specifying the tests to run.
if (opts.extra_benchmarks.empty()) {
RegisterAllBenchmarks(opts, args_shorthand);
}
} else if (!FileExists(opts.xmlpath)) {
// See if this is a file in the suites directory.
std::string file(android::base::GetExecutableDirectory() + "/suites/" + opts.xmlpath);
if (opts.xmlpath[0] == '/' || !FileExists(file)) {
printf("Cannot find xml file %s: does not exist or is not a file.\n", opts.xmlpath.c_str());
return 1;
}
opts.xmlpath = file;
}
if (!opts.xmlpath.empty()) {
if (int err = RegisterXmlBenchmarks(opts, args_shorthand)) {
return err;
}
}
RegisterCliBenchmarks(opts, args_shorthand);
// Set the thread priority to the maximum.
if (setpriority(PRIO_PROCESS, 0, -20)) {
perror("Failed to raise priority of process. Are you root?\n");
}
int new_argc = new_argv.size();
benchmark::Initialize(&new_argc, new_argv.data());
benchmark::RunSpecifiedBenchmarks();
}