virtual void run()
{
size_t stage = 0;
while( true )
{
stage += STAGESIZE;
stage_.waitGE( stage );
if( stage_ == std::numeric_limits< size_t >::max( ))
return;
if( vector )
{
for( size_t i = 0; i < LOOPSIZE; ++i )
{
if( i < vector->size( ))
{
const size_t value = (*vector)[ i ];
TESTINFO( i == value || value == 0,
i << " - " << value << " - " << (*vector)[i]<<
": " << *vector );
}
}
rTime_ = _clock.getTimef();
}
++stage_;
}
}
virtual void run()
{
Vector_t copy;
copy = *vector;
*vector = copy;
TEST( copy.size() >= vector->size( ));
cTime_ = _clock.getTimef();
}
template< class T > void _test()
{
T* lock = new T;
lock->set();
#ifdef LUNCHBOX_USE_OPENMP
const size_t nThreads = LB_MIN( lunchbox::OMP::getNThreads() * 3,
MAXTHREADS );
#else
const size_t nThreads = 16;
#endif
Thread< T > threads[MAXTHREADS];
for( size_t i = 1; i <= nThreads; i = i << 1 )
{
_running = true;
for( size_t j = 0; j < i; ++j )
{
threads[j].lock = lock;
TEST( threads[j].start( ));
}
lunchbox::sleep( 10 ); // let threads initialize
_clock.reset();
lock->unset();
lunchbox::sleep( TIME ); // let threads run
_running = false;
for( size_t j = 0; j < i; ++j )
TEST( threads[j].join( ));
const float time = _clock.getTimef();
TEST( !lock->isSet( ));
lock->set();
size_t ops = 0;
for( size_t j = 0; j < nThreads; ++j )
ops += threads[j].ops;
std::cout << std::setw(20) << lunchbox::className( lock ) << ", "
<< std::setw(12) << /*set, test, unset*/ 3 * ops / time
<< ", " << std::setw(3) << i << std::endl;
}
delete lock;
}
virtual void run()
{
const size_t pos = vector->size() / 2;
Vector_t::iterator i = vector->begin() + pos;
Vector_t::iterator j = vector->erase( i );
TEST( j != vector->end( ));
TEST( i == j );
eTime_ = _clock.getTimef();
}
virtual void run()
{
size_t hits = 0;
size_t ops = 0;
while( _clock.getTime64() < RUNTIME )
{
const co::uint128_t key( _rng.get< uint16_t >(), 0 );
if( _cache[ key ] != co::InstanceCache::Data::NONE )
{
++hits;
_cache.release( key, 1 );
}
++ops;
}
const uint64_t time = _clock.getTime64();
std::cout << hits << " read hits in " << ops << " operations, "
<< ops / time << " ops/ms" << std::endl;
}
virtual void run()
{
ops = 0;
sTime = 0.;
while( LB_LIKELY( _running ))
{
lock->setRead();
TEST( lock->isSetRead( ));
if( hold > 0 ) // static, optimized out
{
const double begin = _clock.getTimed();
lunchbox::sleep( hold );
sTime += _clock.getTimef() - begin;
}
lock->unsetRead();
++ops;
}
}
int main( const int argc, char** argv )
{
eq::NodeFactory nodeFactory;
TEST( eq::init( argc, argv, &nodeFactory ));
eq::Config* config = eq::getConfig( argc, argv );
TEST( config );
size_t nLoops = 0;
const lunchbox::Clock clock;
while( clock.getTime64() < RUNTIME )
{
TEST( config->update( ));
++nLoops;
}
const float time = clock.getTimef();
std::cout << nLoops << " Config::update in " << time << " ms (" <<
time/float(nLoops) << " ms/update)" << std::endl;
eq::releaseConfig( config );
eq::exit();
return EXIT_SUCCESS;
}
virtual void run()
{
size_t stage = 0;
while( true )
{
stage += STAGESIZE;
stage_.waitGE( stage );
if( stage_ == std::numeric_limits< size_t >::max( ))
return;
if( vector )
{
while( vector->size() < LOOPSIZE )
vector->push_back( 0 );
pTime_ = _clock.getTimef();
}
++stage_;
}
}
virtual void run()
{
size_t stage = 0;
while( true )
{
stage += STAGESIZE;
stage_.waitGE( stage );
if( stage_ == std::numeric_limits< size_t >::max( ))
return;
if( vector )
{
for( size_t i = 0; i < LOOPSIZE; ++i )
{
if( i < vector->size( ))
(*vector)[ i ] = i;
}
wTime_ = _clock.getTimef();
}
++stage_;
}
}
int main( int, char** )
{
#ifdef LUNCHBOX_USE_OPENMP
const size_t nThreads = lunchbox::OMP::getNThreads() * 3;
#else
const size_t nThreads = 16;
#endif
std::cout << " read, write, push, copy, erase, "
<< " flush/ms, rd, other #threads" << std::endl;
_runSerialTest< std::vector< size_t >, size_t >();
_runSerialTest< Vector_t, size_t >();
std::vector< Reader > readers(nThreads);
std::vector< Writer > writers(nThreads);
std::vector< Pusher > pushers(nThreads);
stage_ = 1;
size_t stage = 0;
for( size_t l = 0; l < nThreads; ++l )
{
readers[l].start();
writers[l].start();
pushers[l].start();
}
lunchbox::sleep( 10 );
for( size_t i = 1; i <= nThreads; i = i<<1 )
for( size_t j = 1; j <= nThreads; j = j<<1 )
{
// concurrent read, write, push
Vector_t vector;
for( size_t k = 0; k < nThreads; ++k )
{
readers[k].vector = k < i ? &vector : 0;
writers[k].vector = k < j ? &vector : 0;
pushers[k].vector = k < j ? &vector : 0;
}
const size_t nextStage = ++stage * STAGESIZE;
_clock.reset();
stage_ = nextStage;
stage_.waitEQ( nextStage + (3 * nThreads) );
TEST( vector.size() >= LOOPSIZE );
// multi-threaded copy
std::vector< Copier > copiers(j);
_clock.reset();
for( size_t k = 0; k < j; ++k )
{
copiers[k].vector = &vector;
copiers[k].start();
}
for( size_t k = 0; k < j; ++k )
copiers[k].join();
for( size_t k = 0; k < vector.size(); ++k )
TEST( vector[k] == k || vector[k] == 0 );
// multi-threaded erase
std::vector< Eraser > erasers(j);
_clock.reset();
for( size_t k = 0; k < j; ++k )
{
erasers[k].vector = &vector;
erasers[k].start();
}
for( size_t k = 0; k < j; ++k )
erasers[k].join();
for( size_t k = 0; k < vector.size(); ++k )
{
if( vector[k] == 0 )
break;
if( k > vector.size() / 2 )
{
TEST( vector[k] > vector[k-1] );
}
else
{
TEST( vector[k] == k );
}
}
// multi-threaded pop_back
const size_t fOps = vector.size();
std::vector< Flusher > flushers(j);
_clock.reset();
for( size_t k = 0; k < j; ++k )
{
flushers[k].vector = &vector;
flushers[k].start();
}
for( size_t k = 0; k < j; ++k )
flushers[k].join();
const float fTime = _clock.getTimef();
TEST( vector.empty( ));
std::cerr << std::setw(11) << float(i*LOOPSIZE)/rTime_ << ", "
<< std::setw(11) << float(j*LOOPSIZE)/wTime_ << ", "
<< std::setw(11) << float(LOOPSIZE)/pTime_ << ", "
<< std::setw(9) << float(j)/cTime_ << ", "
<< std::setw(9) << float(j)/eTime_ << ", "
<< std::setw(9) << float(fOps)/fTime << ", "
<< std::setw(3) << i << ", " << std::setw(3) << j
<< std::endl;
}
stage_ = std::numeric_limits< size_t >::max();
for( size_t k = 0; k < nThreads; ++k )
{
readers[k].join();
writers[k].join();
pushers[k].join();
}
return EXIT_SUCCESS;
}
template< class V, class T > void _runSerialTest()
{
V vector;
_clock.reset();
while( vector.size() < LOOPSIZE*10 )
vector.push_back( T( 0 ));
pTime_ = _clock.getTimef();
_clock.reset();
for( size_t i = 0; i < LOOPSIZE*10; ++i )
{
if( i < vector.size( ))
vector[ i ] = i;
}
wTime_ = _clock.getTimef();
_clock.reset();
typename V::const_iterator it = vector.begin();
for( size_t i = 0; i < LOOPSIZE*10; ++i )
{
const size_t value = *it;
TESTINFO( i == value || value == 0, i << ", " << value );
++it;
if( it == vector.end( ))
it = vector.begin();
}
rTime_ = _clock.getTimef();
_clock.reset();
for( size_t i = 0; i < 10; ++i )
{
V copy;
copy = vector;
vector = copy;
TEST( copy.size() >= vector.size( ));
}
cTime_ = _clock.getTimef();
_clock.reset();
const size_t pos = vector.size() / 2;
typename V::iterator i = vector.begin() + pos;
typename V::iterator j = vector.erase( i );
TEST( j != vector.end( ));
TEST( *j == 0 || *j >= pos );
eTime_ = _clock.getTimef();
_clock.reset();
while( !vector.empty( ))
vector.pop_back();
const float fTime = _clock.getTimef();
std::cerr << std::setw(11) << float(LOOPSIZE*10)/rTime_ << ", "
<< std::setw(11) << float(LOOPSIZE*10)/wTime_ << ", "
<< std::setw(11) << float(LOOPSIZE*10)/pTime_ << ", "
<< std::setw(9) << float(10)/cTime_ << ", "
<< std::setw(9) << float(10)/eTime_ << ", "
<< std::setw(9) << float(LOOPSIZE*10)/fTime << ", "
<< std::setw(3) << 0 << ", " << std::setw(3) << 0
<< std::endl;
vector.push_back( 42 );
i = vector.begin();
i = vector.erase( i );
TEST( i == vector.begin( ));
TEST( vector.empty( ));
vector.push_back( 42 );
vector.push_back( 17 );
vector.resize( 1 );
TEST( vector.size() == 1 );
TEST( vector[0] == 42 );
vector.resize( 10, 17 );
TEST( vector.size() == 10 );
TEST( vector[0] == 42 );
TEST( vector[1] == 17 );
TEST( vector[9] == 17 );
}
template< class T, uint32_t hold > void _test()
{
T* lock = new T;
lock->set();
#ifdef LUNCHBOX_USE_OPENMP
const size_t nThreads = LB_MIN( lunchbox::OMP::getNThreads()*3, MAXTHREADS );
#else
const size_t nThreads = 16;
#endif
WriteThread< T, hold > writers[MAXTHREADS];
ReadThread< T, hold > readers[MAXTHREADS];
std::cout << " Class, write ops/ms, read ops/ms, w threads, "
<< "r threads" << std::endl;
for( size_t nWrite = 0; nWrite <= nThreads;
nWrite = (nWrite == 0) ? 1 : nWrite << 1 )
{
for( size_t i = 1; i <= nThreads; i = i << 1 )
{
if( i < nWrite )
continue;
const size_t nRead = i - nWrite;
_running = true;
for( size_t j = 0; j < nWrite; ++j )
{
writers[j].lock = lock;
TEST( writers[j].start( ));
}
for( size_t j = 0; j < nRead; ++j )
{
readers[j].lock = lock;
TESTINFO( readers[j].start(), j );
}
lunchbox::sleep( 10 ); // let threads initialize
_clock.reset();
lock->unset();
lunchbox::sleep( TIME ); // let threads run
_running = false;
for( size_t j = 0; j < nWrite; ++j )
TEST( writers[j].join( ));
for( size_t j = 0; j < nRead; ++j )
TEST( readers[j].join( ));
const double time = _clock.getTimed();
TEST( !lock->isSet( ));
lock->set();
size_t nWriteOps = 0;
double wTime = time * double( nWrite );
for( size_t j = 0; j < nWrite; ++j )
{
nWriteOps += writers[j].ops;
wTime -= writers[j].sTime;
}
if( nWrite > 0 )
wTime /= double( nWrite );
if( wTime == 0.f )
wTime = std::numeric_limits< double >::epsilon();
size_t nReadOps = 0;
double rTime = time * double( nRead );
for( size_t j = 0; j < nRead; ++j )
{
nReadOps += readers[j].ops;
rTime -= readers[j].sTime;
}
if( nRead > 0 )
rTime /= double( nRead );
if( rTime == 0.f )
rTime = std::numeric_limits< double >::epsilon();
std::cout << std::setw(20)<< lunchbox::className( lock ) << ", "
<< std::setw(12) << 3 * nWriteOps / wTime << ", "
<< std::setw(12) << 3 * nReadOps / rTime << ", "
<< std::setw(9) << nWrite << ", " << std::setw(9) << nRead
<< std::endl;
}
}
delete lock;
}
int main( int argc, char **argv )
{
co::init( argc, argv );
co::ObjectDataOCommand out( co::Connections(), co::CMD_NODE_OBJECT_INSTANCE,
co::COMMANDTYPE_NODE, co::uint128_t(), 0,
co::uint128_t(1), 0, 0, COMMAND_SIZE, true, 0 );
co::LocalNodePtr node = new co::LocalNode;
co::ObjectDataICommand in = out._getCommand( node );
TESTINFO( in.isValid(), in );
TEST( in.isLast( ));
Reader** readers = static_cast< Reader** >(
alloca( N_READER * sizeof( Reader* )));
co::InstanceCache cache;
lunchbox::RNG rng;
size_t hits = 0;
size_t ops = 0;
for( co::uint128_t key; key.low() < 65536; ++key ) // Fill cache
if( !cache.add( co::ObjectVersion( key, co::uint128_t(1) ), 1, in ))
break;
_clock.reset();
for( size_t i = 0; i < N_READER; ++i )
{
readers[ i ] = new Reader( cache );
readers[ i ]->start();
}
while( _clock.getTime64() < RUNTIME )
{
const co::uint128_t id( 0, rng.get< uint16_t >( ));
const co::ObjectVersion key( id, co::uint128_t(1) );
if( cache[ key.identifier ] != co::InstanceCache::Data::NONE )
{
TEST( cache.release( key.identifier, 1 ));
++ops;
if( cache.erase( key.identifier ))
{
TEST( cache.add( key, 1, in ));
ops += 2;
hits += 2;
}
}
else if( cache.add( key, 1, in ))
++hits;
++ops;
}
const uint64_t time = _clock.getTime64();
std::cout << hits << " write hits in " << ops << " operations, "
<< ops / time << " ops/ms" << std::endl;
for( size_t i = 0; i < N_READER; ++i )
{
readers[ i ]->join();
delete readers[ i ];
}
std::cout << cache << std::endl;
for( co::uint128_t key; key.low() < 65536; ++key ) // Fill cache
{
if( cache[ key ] != co::InstanceCache::Data::NONE )
{
TEST( cache.release( key, 1 ));
TEST( cache.erase( key ));
}
}
for( co::uint128_t key; key.low() < 65536; ++key ) // Fill cache
{
TEST( cache[ key ] == co::InstanceCache::Data::NONE );
}
std::cout << cache << std::endl;
TESTINFO( cache.getSize() == 0, cache.getSize( ));
TEST( co::exit( ));
return EXIT_SUCCESS;
}
