source: doc/theses/thierry_delisle_PhD/code/readQ_example/proto-gui/main.cpp @ 9feb34b

#include "thrdlib/thread.hpp"

#include <cassert>

#include <algorithm>
#include <atomic>
#include <iostream>
#include <memory>
#include <vector>

#include <getopt.h>
using thrdlib::thread_t;

//--------------------
// Constants
unsigned nframes;
unsigned fsize;
unsigned nproduce;

//--------------------
// Frame management

class Frame {
        static const thread_t reset;
        static const thread_t set;
        std::atomic<thread_t> rdy_state = { reset };
        std::atomic<thread_t> rnd_state = { set };
public:
        unsigned number;
        std::unique_ptr<unsigned char[]> data;

private:
        inline bool wait( thread_t self, std::atomic<thread_t> & state, std::atomic<thread_t> & other ) {
                bool ret;
                while(true) {
                        thread_t expected = state;
                        if( expected == set ) { ret = false; goto END; }
                        assert( expected == reset );
                        if( std::atomic_compare_exchange_strong( &state, &expected, self) ) {
                                thrdlib::park( self );
                                ret = true;
                                goto END;
                        }
                }
                END:
                assert( state == set );
                assert( other != set );
                state = reset;
                return ret;
        }

        inline bool publish(  std::atomic<thread_t> & state ) {
                thread_t got = std::atomic_exchange( &state, set );
                assert( got != set );

                if( got == reset ) return false;

                thrdlib::unpark( got );
                return true;
        }

public:
        inline bool wait_rendered( thread_t self ) {
                return wait( self, rnd_state, rdy_state );
        }

        inline bool wait_ready   ( thread_t self ) {
                return wait( self, rdy_state, rnd_state );
        }

        inline bool publish() {
                return publish( rdy_state );
        }

        inline bool release() {
                return publish( rnd_state );
        }
};

const thread_t Frame::reset = nullptr;
const thread_t Frame::set   = reinterpret_cast<thread_t>(1);

std::unique_ptr<Frame[]> frames;
volatile unsigned last_produced = 0;

//--------------------
// Threads
thread_t volatile the_stats_thread = nullptr;

inline void fence(void) {
        std::atomic_thread_fence(std::memory_order_seq_cst);
}

struct {
        struct {
                volatile unsigned long long   parks = 0;
                volatile unsigned long long unparks = 0;
        } sim;
        struct {
                volatile unsigned long long   parks = 0;
                volatile unsigned long long unparks = 0;
        } rend;

        struct {
                volatile unsigned long long ran = 0;
                volatile unsigned long long saw = 0;
        } stats;
} thrd_stats;

void Stats( thread_t self ) {
        the_stats_thread = self;
        fence();
        thrdlib::park( self );

        std::vector<bool> seen;
        seen.resize(nproduce, false);

        while(last_produced < nproduce) {
                thrdlib::yield();
                thrd_stats.stats.ran++;
                if( last_produced > 0 ) seen.at(last_produced - 1) = true;
        }

        thrd_stats.stats.saw = std::count(seen.begin(), seen.end(), true);
}

typedef uint64_t __wyhash64_state_t;
static inline uint64_t __wyhash64( __wyhash64_state_t & state ) {
        state += 0x60bee2bee120fc15;
        __uint128_t tmp;
        tmp = (__uint128_t) state * 0xa3b195354a39b70d;
        uint64_t m1 = (tmp >> 64) ^ tmp;
        tmp = (__uint128_t)m1 * 0x1b03738712fad5c9;
        uint64_t m2 = (tmp >> 64) ^ tmp;
        return m2;
}

void Simulator( thread_t self ) {
        for(unsigned i = 0; i < nproduce; i++) {
                auto & frame = frames[i % nframes];
                // Wait for the frames to be rendered
                if( frame.wait_rendered( self ) ) {
                        thrd_stats.sim.parks++;
                }

                __wyhash64_state_t state = 0;

                // Write the frame information
                frame.number = i;
                for( unsigned x = 0; x < fsize; x++ ) {
                        frame.data[x] = __wyhash64(state);
                }
                std::cout << "Simulated " << i << std::endl;
                last_produced = i+1;

                // Publish it
                if( frame.publish()  ) {
                        thrd_stats.sim.unparks++;
                }
        }
}

void Renderer( thread_t self ) {
        thrdlib::unpark( the_stats_thread );
        for(unsigned i = 0; i < nproduce; i++) {
                auto & frame = frames[i % nframes];
                // Wait for the frames to be ready
                if( frame.wait_ready( self ) ) {
                        thrd_stats.rend.parks++;
                }

                // Render the frame
                unsigned total = 0;
                for( unsigned x = 0; x < fsize; x++ ) {
                        total += frame.data[x];
                }

                std::cout << "Rendered " << i << std::endl;
                // assert(total == i * fsize);

                // Release
                if( frame.release() ) {
                        thrd_stats.rend.unparks++;
                }
        }

}



int main(int argc, char * argv[]) {
        nframes  = 3;
        fsize    = 3840 * 2160 * 4 * 4;
        nproduce = 60;

        for(;;) {
                static struct option options[] = {
                        {"buff",  required_argument, 0, 'b'},
                        {"nprod",  required_argument, 0, 'p'},
                        {"fsize",   required_argument, 0, 'f'},
                        {0, 0, 0, 0}
                };

                int idx = 0;
                int opt = getopt_long(argc, argv, "b:p:f:", options, &idx);

                std::string arg = optarg ? optarg : "";
                size_t len = 0;
                switch(opt) {
                        // Exit Case
                        case -1:
                                goto run;
                        case 'b':
                                try {
                                        nframes = std::stoul(optarg, &len);
                                        if(nframes == 0 || len != arg.size()) { throw std::invalid_argument(""); }
                                } catch(std::invalid_argument &) {
                                        std::cerr << "Number of buffered frames must be at least 1, was" << arg << std::endl;
                                        goto usage;
                                }
                                break;
                        case 'p':
                                try {
                                        nproduce = std::stoul(optarg, &len);
                                        if(nproduce == 0 || len != arg.size()) { throw std::invalid_argument(""); }
                                } catch(std::invalid_argument &) {
                                        std::cerr << "Number of produced frames must be at least 1, was" << arg << std::endl;
                                        goto usage;
                                }
                                break;
                        case 'f':
                                try {
                                        fsize = std::stoul(optarg, &len);
                                        if(fsize == 0 || len != arg.size()) { throw std::invalid_argument(""); }
                                } catch(std::invalid_argument &) {
                                        std::cerr << "Size of produced frames must be at least 1, was" << arg << std::endl;
                                        goto usage;
                                }
                                break;
                        // Other cases
                        default: /* ? */
                                std::cerr << opt << std::endl;
                        usage:
                                std::cerr << "Usage: " << argv[0] << " [options]" << std::endl;
                                std::cerr << std::endl;
                                std::cerr << "  -b, --buff=COUNT    Number of frames to buffer" << std::endl;
                                std::cerr << "  -p, --nprod=COUNT   Number of frames to produce" << std::endl;
                                std::cerr << "  -f, --fsize=SIZE    Size of each frame in bytes" << std::endl;
                                std::exit(1);
                }
        }
        run:
        frames.reset(new Frame[nframes]);
        for(unsigned i = 0; i < nframes; i++) {
                frames[i].number = 0;
                frames[i].data.reset(new unsigned char[fsize]);
        }
        std::cout << "Created frames of " << fsize << " bytes" << std::endl;
        std::cout << "(Buffering " << nframes << ")" << std::endl;

        thrdlib::init( 2 );

        thread_t stats     = thrdlib::create( Stats );
        std::cout << "Created Stats Thread" << std::endl;
        while( the_stats_thread == nullptr ) thrdlib::yield();

        std::cout << "Creating Main Threads" << std::endl;
        thread_t renderer  = thrdlib::create( Renderer  );
        thread_t simulator = thrdlib::create( Simulator );

        std::cout << "Running" << std::endl;

        thrdlib::join( simulator );
        thrdlib::join( renderer  );
        thrdlib::join( stats     );

        thrdlib::clean();

        std::cout << "----------" << std::endl;
        std::cout << "# Parks" << std::endl;
        std::cout << "  Renderer   park: " << thrd_stats. sim.  parks << std::endl;
        std::cout << "  Renderer unpark: " << thrd_stats. sim.unparks << std::endl;
        std::cout << " Simulator   park: " << thrd_stats.rend.  parks << std::endl;
        std::cout << " Simulator unpark: " << thrd_stats.rend.unparks << std::endl;

        std::cout << "Stats thread" << std::endl;
        std::cout << " Ran             : " << thrd_stats.stats.ran << " times" << std::endl;
        std::cout << " Saw             : " << thrd_stats.stats.saw << " (" << ((100.f * thrd_stats.stats.saw) / nproduce) << "%)" << std::endl;
}