static bool dependsOn(iterator next, iterator dependee, InstructionSet& visited,
DependenceMap& savedDependencies)
{
auto dependence = InstructionPair(next->instruction, dependee->instruction);
auto savedDependence = savedDependencies.find(dependence);
if(savedDependence != savedDependencies.end())
{
return savedDependence->second;
}
if(!visited.insert(next->instruction).second) return false;
if(next == dependee) return true;
for(auto successor : next->successors)
{
if(dependsOn(successor, dependee, visited, savedDependencies))
{
return true;
}
savedDependencies.insert(std::make_pair(
InstructionPair(next->instruction, successor->instruction), true));
}
savedDependencies.insert(std::make_pair(
InstructionPair(next->instruction, dependee->instruction), false));
return false;
}
static InstructionSet getControlDependentInstructions(
const PTXInstruction* branch, const InstructionSet& instructions,
analysis::ControlDependenceAnalysis* controlDependenceAnalysis)
{
InstructionSet controlDependentInstructions;
for(auto instruction : instructions)
{
if(controlDependenceAnalysis->dependsOn(branch, instruction))
{
controlDependentInstructions.insert(instruction);
}
}
return controlDependentInstructions;
}
static void addPredecessors(InstructionSet& predecessors,
ir::BasicBlock::const_iterator instruction)
{
auto end = (*instruction)->block->rend();
auto position = ir::BasicBlock::const_reverse_iterator(instruction);
for(; position != end; ++position)
{
if(!hasDependence(**position, **instruction)) continue;
report(" " << (*position)->toString() << " (" << (*position)->index()
<< ") -> " << (*instruction)->toString() << " ("
<< (*instruction)->index() << ")");
predecessors.insert(*position);
}
}
static InstructionSet getInstructionsThatCanObserveSideEffects(ir::IRKernel& k)
{
InstructionSet instructions;
report(" Getting instructions that can observe side-effects");
for(auto& block : *k.cfg())
{
for(auto instruction : block.instructions)
{
auto ptxInstruction = static_cast<ir::PTXInstruction*>(instruction);
if(ptxInstruction->canObserveSideEffects())
{
report(" " << ptxInstruction->toString());
instructions.insert(ptxInstruction);
}
}
}
return instructions;
}
void ParallelismTraceAnalyzer::parallelism() const
{
typedef std::vector< ParallelismTraceGenerator::Event > EventVector;
typedef std::set< long long unsigned int > InstructionSet;
double averageSIMD = 0;
double averageMIMD = 0;
double averageCTAs = 0;
for( KernelMap::const_iterator vector = _kernels.begin();
vector != _kernels.end(); ++vector )
{
std::cout << " From program \"" << vector->first << "\".\n";
double localSIMD = 0;
double localMIMD = 0;
double localCTAs = 0;
for( KernelVector::const_iterator kernel = vector->second.begin();
kernel != vector->second.end(); ++kernel )
{
std::ifstream hstream( kernel->header.c_str() );
boost::archive::text_iarchive harchive( hstream );
ParallelismTraceGenerator::Header header;
harchive >> header;
assert( header.format
== TraceGenerator::ParallelismTraceFormat );
hstream.close();
std::ifstream stream( kernel->path.c_str() );
if( !stream.is_open() )
{
throw hydrazine::Exception(
"Failed to open ParallelismTrace kernel trace file "
+ kernel->path );
}
boost::archive::text_iarchive archive( stream );
EventVector events( header.dimensions );
for( EventVector::iterator event = events.begin();
event != events.end(); ++event )
{
archive >> *event;
}
std::cout << " From file " << kernel->path << "\n";
std::cout << " kernel: " << kernel->name << "\n";
std::cout << " module: " << kernel->module << "\n";
std::cout << " statistics:\n";
std::cout << " ctas: " << header.dimensions << "\n";
std::cout << " threads: " << header.threads << "\n";
InstructionSet instructions;
long long unsigned int totalInstructions = 0;
double activity = 0;
for( EventVector::iterator event = events.begin();
event != events.end(); ++event )
{
totalInstructions += event->instructions;
instructions.insert( event->instructions );
activity += event->activity * event->instructions;
}
activity /= totalInstructions + DBL_EPSILON;
unsigned int previous = 0;
unsigned int count = header.dimensions;
double mimd = 0;
for( InstructionSet::iterator
instruction = instructions.begin();
instruction != instructions.end(); ++instruction )
{
mimd += (*instruction - previous) * count;
previous = *instruction;
--count;
}
if( !instructions.empty() )
{
mimd /= *(--instructions.end()) + DBL_EPSILON;
}
std::cout << " SIMD parallelism: " << activity
<< "\n";
std::cout << " MIMD parallelism: " << mimd << "\n";
localSIMD += activity;
localMIMD += mimd;
localCTAs += header.dimensions;
}
localSIMD /= vector->second.size() + DBL_EPSILON;
localMIMD /= vector->second.size() + DBL_EPSILON;
localCTAs /= vector->second.size() + DBL_EPSILON;
std::cout << " Kernel " << vector->first << " statistics:\n";
std::cout << " average CTAs: " << localCTAs << "\n";
std::cout << " average SIMD parallelism: " << localSIMD << "\n";
std::cout << " average MIMD parallelism: " << localMIMD << "\n";
averageSIMD += localSIMD;
averageMIMD += localMIMD;
averageCTAs += localCTAs;
}
averageSIMD /= _kernels.size() + DBL_EPSILON;
averageMIMD /= _kernels.size() + DBL_EPSILON;
averageCTAs /= _kernels.size() + DBL_EPSILON;
std::cout << "Aggregate statistics:\n";
std::cout << " average CTAs: " << averageCTAs << "\n";
std::cout << " average SIMD parallelism: " << averageSIMD << "\n";
std::cout << " average MIMD parallelism: " << averageMIMD << "\n";
}
