CPP-catch
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src/catch.hpp view on Meta::CPAN
#include <cstdint>
#include <string>
namespace Catch {
class BenchmarkLooper {
std::string m_name;
std::size_t m_count = 0;
std::size_t m_iterationsToRun = 1;
uint64_t m_resolution;
Timer m_timer;
static auto getResolution() -> uint64_t;
public:
// Keep most of this inline as it's on the code path that is being timed
BenchmarkLooper( StringRef name )
: m_name( name ),
m_resolution( getResolution() )
{
reportStart();
m_timer.start();
}
explicit operator bool() {
if( m_count < m_iterationsToRun )
return true;
return needsMoreIterations();
}
void increment() {
++m_count;
}
void reportStart();
auto needsMoreIterations() -> bool;
src/catch.hpp view on Meta::CPAN
TestRunInfo runInfo;
Totals totals;
bool aborting;
};
struct BenchmarkInfo {
std::string name;
};
struct BenchmarkStats {
BenchmarkInfo info;
std::size_t iterations;
uint64_t elapsedTimeInNanoseconds;
};
struct IStreamingReporter {
virtual ~IStreamingReporter() = default;
// Implementing class must also provide the following static methods:
// static std::string getDescription();
// static std::set<Verbosity> getSupportedVerbosities()
src/catch.hpp view on Meta::CPAN
auto BenchmarkLooper::getResolution() -> uint64_t {
return getEstimatedClockResolution() * getCurrentContext().getConfig()->benchmarkResolutionMultiple();
}
void BenchmarkLooper::reportStart() {
getResultCapture().benchmarkStarting( { m_name } );
}
auto BenchmarkLooper::needsMoreIterations() -> bool {
auto elapsed = m_timer.getElapsedNanoseconds();
// Exponentially increasing iterations until we're confident in our timer resolution
if( elapsed < m_resolution ) {
m_iterationsToRun *= 10;
return true;
}
getResultCapture().benchmarkEnded( { { m_name }, m_count, elapsed } );
return false;
}
} // end namespace Catch
// end catch_benchmark.cpp
// start catch_capture_matchers.cpp
src/catch.hpp view on Meta::CPAN
namespace Catch {
auto getCurrentNanosecondsSinceEpoch() -> uint64_t {
return std::chrono::duration_cast<std::chrono::nanoseconds>( std::chrono::high_resolution_clock::now().time_since_epoch() ).count();
}
namespace {
auto estimateClockResolution() -> uint64_t {
uint64_t sum = 0;
static const uint64_t iterations = 1000000;
auto startTime = getCurrentNanosecondsSinceEpoch();
for( std::size_t i = 0; i < iterations; ++i ) {
uint64_t ticks;
uint64_t baseTicks = getCurrentNanosecondsSinceEpoch();
do {
ticks = getCurrentNanosecondsSinceEpoch();
} while( ticks == baseTicks );
auto delta = ticks - baseTicks;
sum += delta;
// If we have been calibrating for over 3 seconds -- the clock
// is terrible and we should move on.
// TBD: How to signal that the measured resolution is probably wrong?
if (ticks > startTime + 3 * nanosecondsInSecond) {
return sum / i;
}
}
// We're just taking the mean, here. To do better we could take the std. dev and exclude outliers
// - and potentially do more iterations if there's a high variance.
return sum/iterations;
}
}
auto getEstimatedClockResolution() -> uint64_t {
static auto s_resolution = estimateClockResolution();
return s_resolution;
}
void Timer::start() {
m_nanoseconds = getCurrentNanosecondsSinceEpoch();
}
src/catch.hpp view on Meta::CPAN
for (auto line : nameCol) {
if (!firstLine)
(*m_tablePrinter) << ColumnBreak() << ColumnBreak() << ColumnBreak();
else
firstLine = false;
(*m_tablePrinter) << line << ColumnBreak();
}
}
void ConsoleReporter::benchmarkEnded(BenchmarkStats const& stats) {
Duration average(stats.elapsedTimeInNanoseconds / stats.iterations);
(*m_tablePrinter)
<< stats.iterations << ColumnBreak()
<< stats.elapsedTimeInNanoseconds << ColumnBreak()
<< average << ColumnBreak();
}
void ConsoleReporter::testCaseEnded(TestCaseStats const& _testCaseStats) {
m_tablePrinter->close();
StreamingReporterBase::testCaseEnded(_testCaseStats);
m_headerPrinted = false;
}
void ConsoleReporter::testGroupEnded(TestGroupStats const& _testGroupStats) {
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