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opencv/modules/gapi/samples/pipeline_modeling_tool/pipeline.hpp

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#ifndef OPENCV_GAPI_PIPELINE_MODELING_TOOL_PIPELINE_HPP
#define OPENCV_GAPI_PIPELINE_MODELING_TOOL_PIPELINE_HPP
#include <iomanip>
struct PerfReport {
std::string name;
double avg_latency = 0.0;
int64_t min_latency = 0;
int64_t max_latency = 0;
int64_t first_latency = 0;
double throughput = 0.0;
int64_t elapsed = 0;
int64_t warmup_time = 0;
int64_t num_late_frames = 0;
std::vector<int64_t> latencies;
std::string toStr(bool expanded = false) const;
};
std::string PerfReport::toStr(bool expand) const {
std::stringstream ss;
ss << name << ": \n"
<< " Warm up time: " << warmup_time << " ms\n"
<< " Execution time: " << elapsed << " ms\n"
<< " Frames: " << num_late_frames << "/" << latencies.size() << " (late/all)\n"
<< " Latency:\n"
<< " first: " << first_latency << " ms\n"
<< " min: " << min_latency << " ms\n"
<< " max: " << max_latency << " ms\n"
<< " avg: " << std::fixed << std::setprecision(3) << avg_latency << " ms\n"
<< " Throughput: " << std::fixed << std::setprecision(3) << throughput << " FPS";
if (expand) {
for (size_t i = 0; i < latencies.size(); ++i) {
ss << "\nFrame:" << i << "\nLatency: "
<< latencies[i] << " ms";
}
}
return ss.str();
}
class StopCriteria {
public:
using Ptr = std::unique_ptr<StopCriteria>;
virtual void start() = 0;
virtual void iter() = 0;
virtual bool done() = 0;
virtual ~StopCriteria() = default;
};
class Pipeline {
public:
using Ptr = std::shared_ptr<Pipeline>;
Pipeline(std::string&& name,
cv::GComputation&& comp,
std::shared_ptr<DummySource>&& src,
StopCriteria::Ptr stop_criteria,
cv::GCompileArgs&& args,
const size_t num_outputs);
void compile();
void run();
const PerfReport& report() const;
const std::string& name() const { return m_name;}
virtual ~Pipeline() = default;
protected:
virtual void _compile() = 0;
virtual int64_t run_iter() = 0;
virtual void init() {};
virtual void deinit() {};
std::string m_name;
cv::GComputation m_comp;
std::shared_ptr<DummySource> m_src;
StopCriteria::Ptr m_stop_criteria;
cv::GCompileArgs m_args;
size_t m_num_outputs;
PerfReport m_perf;
};
Pipeline::Pipeline(std::string&& name,
cv::GComputation&& comp,
std::shared_ptr<DummySource>&& src,
StopCriteria::Ptr stop_criteria,
cv::GCompileArgs&& args,
const size_t num_outputs)
: m_name(std::move(name)),
m_comp(std::move(comp)),
m_src(std::move(src)),
m_stop_criteria(std::move(stop_criteria)),
m_args(std::move(args)),
m_num_outputs(num_outputs) {
m_perf.name = m_name;
}
void Pipeline::compile() {
m_perf.warmup_time =
utils::measure<std::chrono::milliseconds>([this]() {
_compile();
});
}
void Pipeline::run() {
using namespace std::chrono;
init();
auto start = high_resolution_clock::now();
m_stop_criteria->start();
while (true) {
m_perf.latencies.push_back(run_iter());
m_perf.elapsed = duration_cast<milliseconds>(high_resolution_clock::now() - start).count();
m_stop_criteria->iter();
if (m_stop_criteria->done()) {
deinit();
break;
}
}
m_perf.avg_latency = utils::avg(m_perf.latencies);
m_perf.min_latency = utils::min(m_perf.latencies);
m_perf.max_latency = utils::max(m_perf.latencies);
m_perf.first_latency = m_perf.latencies[0];
// NB: Count how many executions don't fit into camera latency interval.
m_perf.num_late_frames =
std::count_if(m_perf.latencies.begin(), m_perf.latencies.end(),
[this](int64_t latency) {
return static_cast<double>(latency) > m_src->latency();
});
m_perf.throughput =
(m_perf.latencies.size() / static_cast<double>(m_perf.elapsed)) * 1000;
}
const PerfReport& Pipeline::report() const {
return m_perf;
}
class StreamingPipeline : public Pipeline {
public:
using Pipeline::Pipeline;
private:
void _compile() override {
m_compiled =
m_comp.compileStreaming({m_src->descr_of()},
cv::GCompileArgs(m_args));
}
virtual void init() override {
using namespace std::chrono;
// NB: N-1 buffers + timestamp.
m_out_mats.resize(m_num_outputs - 1);
for (auto& m : m_out_mats) {
m_pipeline_outputs += cv::gout(m);
}
m_pipeline_outputs += cv::gout(m_start_ts);
m_compiled.setSource(m_src);
m_compiled.start();
}
virtual void deinit() override {
m_compiled.stop();
}
virtual int64_t run_iter() override {
m_compiled.pull(cv::GRunArgsP{m_pipeline_outputs});
return utils::timestamp<std::chrono::milliseconds>() - m_start_ts;
}
cv::GStreamingCompiled m_compiled;
cv::GRunArgsP m_pipeline_outputs;
std::vector<cv::Mat> m_out_mats;
int64_t m_start_ts;
};
class RegularPipeline : public Pipeline {
public:
using Pipeline::Pipeline;
private:
void _compile() override {
m_compiled =
m_comp.compile({m_src->descr_of()},
cv::GCompileArgs(m_args));
}
virtual void init() override {
m_out_mats.resize(m_num_outputs);
for (auto& m : m_out_mats) {
m_pipeline_outputs += cv::gout(m);
}
}
virtual int64_t run_iter() override {
using namespace std::chrono;
cv::gapi::wip::Data d;
m_src->pull(d);
auto in_mat = cv::util::get<cv::Mat>(d);
return utils::measure<milliseconds>([&]{
m_compiled(cv::gin(in_mat), cv::GRunArgsP{m_pipeline_outputs});
});
}
cv::GCompiled m_compiled;
cv::GRunArgsP m_pipeline_outputs;
std::vector<cv::Mat> m_out_mats;
};
enum class PLMode {
REGULAR,
STREAMING
};
#endif // OPENCV_GAPI_PIPELINE_MODELING_TOOL_PIPELINE_HPP