// Copyright 2015 Google Inc. All rights reserved. // // 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 #include #include #include // for setprecision #include #include #include #include #include #include "benchmark/benchmark.h" #include "complexity.h" #include "string_util.h" #include "timers.h" namespace benchmark { namespace { std::string StrEscape(const std::string& s) { std::string tmp; tmp.reserve(s.size()); for (char c : s) { switch (c) { case '\b': tmp += "\\b"; break; case '\f': tmp += "\\f"; break; case '\n': tmp += "\\n"; break; case '\r': tmp += "\\r"; break; case '\t': tmp += "\\t"; break; case '\\': tmp += "\\\\"; break; case '"': tmp += "\\\""; break; default: tmp += c; break; } } return tmp; } std::string FormatKV(std::string const& key, std::string const& value) { return StrFormat("\"%s\": \"%s\"", StrEscape(key).c_str(), StrEscape(value).c_str()); } std::string FormatKV(std::string const& key, const char* value) { return StrFormat("\"%s\": \"%s\"", StrEscape(key).c_str(), StrEscape(value).c_str()); } std::string FormatKV(std::string const& key, bool value) { return StrFormat("\"%s\": %s", StrEscape(key).c_str(), value ? "true" : "false"); } std::string FormatKV(std::string const& key, int64_t value) { std::stringstream ss; ss << '"' << StrEscape(key) << "\": " << value; return ss.str(); } std::string FormatKV(std::string const& key, double value) { std::stringstream ss; ss << '"' << StrEscape(key) << "\": "; if (std::isnan(value)) ss << (value < 0 ? "-" : "") << "NaN"; else if (std::isinf(value)) ss << (value < 0 ? "-" : "") << "Infinity"; else { const auto max_digits10 = std::numeric_limits::max_digits10; const auto max_fractional_digits10 = max_digits10 - 1; ss << std::scientific << std::setprecision(max_fractional_digits10) << value; } return ss.str(); } int64_t RoundDouble(double v) { return std::lround(v); } } // end namespace bool JSONReporter::ReportContext(const Context& context) { std::ostream& out = GetOutputStream(); out << "{\n"; std::string inner_indent(2, ' '); // Open context block and print context information. out << inner_indent << "\"context\": {\n"; std::string indent(4, ' '); std::string walltime_value = LocalDateTimeString(); out << indent << FormatKV("date", walltime_value) << ",\n"; out << indent << FormatKV("host_name", context.sys_info.name) << ",\n"; if (Context::executable_name) { out << indent << FormatKV("executable", Context::executable_name) << ",\n"; } CPUInfo const& info = context.cpu_info; out << indent << FormatKV("num_cpus", static_cast(info.num_cpus)) << ",\n"; out << indent << FormatKV("mhz_per_cpu", RoundDouble(info.cycles_per_second / 1000000.0)) << ",\n"; if (CPUInfo::Scaling::UNKNOWN != info.scaling) { out << indent << FormatKV("cpu_scaling_enabled", info.scaling == CPUInfo::Scaling::ENABLED ? true : false) << ",\n"; } out << indent << "\"caches\": [\n"; indent = std::string(6, ' '); std::string cache_indent(8, ' '); for (size_t i = 0; i < info.caches.size(); ++i) { auto& CI = info.caches[i]; out << indent << "{\n"; out << cache_indent << FormatKV("type", CI.type) << ",\n"; out << cache_indent << FormatKV("level", static_cast(CI.level)) << ",\n"; out << cache_indent << FormatKV("size", static_cast(CI.size)) << ",\n"; out << cache_indent << FormatKV("num_sharing", static_cast(CI.num_sharing)) << "\n"; out << indent << "}"; if (i != info.caches.size() - 1) out << ","; out << "\n"; } indent = std::string(4, ' '); out << indent << "],\n"; out << indent << "\"load_avg\": ["; for (auto it = info.load_avg.begin(); it != info.load_avg.end();) { out << *it++; if (it != info.load_avg.end()) out << ","; } out << "],\n"; #if defined(NDEBUG) const char build_type[] = "release"; #else const char build_type[] = "debug"; #endif out << indent << FormatKV("library_build_type", build_type); std::map* global_context = internal::GetGlobalContext(); if (global_context != nullptr) { for (const auto& kv : *global_context) { out << ",\n"; out << indent << FormatKV(kv.first, kv.second); } } out << "\n"; // Close context block and open the list of benchmarks. out << inner_indent << "},\n"; out << inner_indent << "\"benchmarks\": [\n"; return true; } void JSONReporter::ReportRuns(std::vector const& reports) { if (reports.empty()) { return; } std::string indent(4, ' '); std::ostream& out = GetOutputStream(); if (!first_report_) { out << ",\n"; } first_report_ = false; for (auto it = reports.begin(); it != reports.end(); ++it) { out << indent << "{\n"; PrintRunData(*it); out << indent << '}'; auto it_cp = it; if (++it_cp != reports.end()) { out << ",\n"; } } } void JSONReporter::Finalize() { // Close the list of benchmarks and the top level object. GetOutputStream() << "\n ]\n}\n"; } void JSONReporter::PrintRunData(Run const& run) { std::string indent(6, ' '); std::ostream& out = GetOutputStream(); out << indent << FormatKV("name", run.benchmark_name()) << ",\n"; out << indent << FormatKV("family_index", run.family_index) << ",\n"; out << indent << FormatKV("per_family_instance_index", run.per_family_instance_index) << ",\n"; out << indent << FormatKV("run_name", run.run_name.str()) << ",\n"; out << indent << FormatKV("run_type", [&run]() -> const char* { switch (run.run_type) { case BenchmarkReporter::Run::RT_Iteration: return "iteration"; case BenchmarkReporter::Run::RT_Aggregate: return "aggregate"; } BENCHMARK_UNREACHABLE(); }()) << ",\n"; out << indent << FormatKV("repetitions", run.repetitions) << ",\n"; if (run.run_type != BenchmarkReporter::Run::RT_Aggregate) { out << indent << FormatKV("repetition_index", run.repetition_index) << ",\n"; } out << indent << FormatKV("threads", run.threads) << ",\n"; if (run.run_type == BenchmarkReporter::Run::RT_Aggregate) { out << indent << FormatKV("aggregate_name", run.aggregate_name) << ",\n"; out << indent << FormatKV("aggregate_unit", [&run]() -> const char* { switch (run.aggregate_unit) { case StatisticUnit::kTime: return "time"; case StatisticUnit::kPercentage: return "percentage"; } BENCHMARK_UNREACHABLE(); }()) << ",\n"; } if (run.error_occurred) { out << indent << FormatKV("error_occurred", run.error_occurred) << ",\n"; out << indent << FormatKV("error_message", run.error_message) << ",\n"; } if (!run.report_big_o && !run.report_rms) { out << indent << FormatKV("iterations", run.iterations) << ",\n"; if (run.run_type != Run::RT_Aggregate || run.aggregate_unit == StatisticUnit::kTime) { out << indent << FormatKV("real_time", run.GetAdjustedRealTime()) << ",\n"; out << indent << FormatKV("cpu_time", run.GetAdjustedCPUTime()); } else { assert(run.aggregate_unit == StatisticUnit::kPercentage); out << indent << FormatKV("real_time", run.real_accumulated_time) << ",\n"; out << indent << FormatKV("cpu_time", run.cpu_accumulated_time); } out << ",\n" << indent << FormatKV("time_unit", GetTimeUnitString(run.time_unit)); } else if (run.report_big_o) { out << indent << FormatKV("cpu_coefficient", run.GetAdjustedCPUTime()) << ",\n"; out << indent << FormatKV("real_coefficient", run.GetAdjustedRealTime()) << ",\n"; out << indent << FormatKV("big_o", GetBigOString(run.complexity)) << ",\n"; out << indent << FormatKV("time_unit", GetTimeUnitString(run.time_unit)); } else if (run.report_rms) { out << indent << FormatKV("rms", run.GetAdjustedCPUTime()); } for (auto& c : run.counters) { out << ",\n" << indent << FormatKV(c.first, c.second); } if (run.memory_result) { const MemoryManager::Result memory_result = *run.memory_result; out << ",\n" << indent << FormatKV("allocs_per_iter", run.allocs_per_iter); out << ",\n" << indent << FormatKV("max_bytes_used", memory_result.max_bytes_used); auto report_if_present = [&out, &indent](const char* label, int64_t val) { if (val != MemoryManager::TombstoneValue) out << ",\n" << indent << FormatKV(label, val); }; report_if_present("total_allocated_bytes", memory_result.total_allocated_bytes); report_if_present("net_heap_growth", memory_result.net_heap_growth); } if (!run.report_label.empty()) { out << ",\n" << indent << FormatKV("label", run.report_label); } out << '\n'; } const int64_t MemoryManager::TombstoneValue = std::numeric_limits::max(); } // end namespace benchmark