source: doc/theses/colby_parsons_MMAth/benchmarks/waituntil/cfa/contend.cfa @ 8b84973

#include <select.hfa>
#include <thread.hfa>
#include <channel.hfa>
#include <locks.hfa>
#include <fstream.hfa>
#include <stdio.h>
#include <time.hfa>
#include <string.h>

// #define NUM_CHANS 1
#define GLUE_HELPER(x, y) x##y
#define FN_GLUE(x, y) GLUE_HELPER(x, y)

size_t Processors = 2, Producers = 1, Consumers = 1, ChannelSize = 10;

channel(size_t) * chans;

static inline void cons_wait_1( size_t & val ) { waituntil( val << chans[0] ) {} }
static inline void cons_wait_2( size_t & val ) { waituntil( val << chans[0] ) {} or waituntil( val << chans[1] ) {} }
static inline void cons_wait_3( size_t & val ) { waituntil( val << chans[0] ) {} or waituntil( val << chans[1] ) {} or waituntil( val << chans[2] ) {} }
static inline void cons_wait_4( size_t & val ) { waituntil( val << chans[0] ) {} or waituntil( val << chans[1] ) {} or waituntil( val << chans[2] ) {} or waituntil( val << chans[3] ) {} }
static inline void cons_wait_5( size_t & val ) { waituntil( val << chans[0] ) {} or waituntil( val << chans[1] ) {} or waituntil( val << chans[2] ) {} or waituntil( val << chans[3] ) {} or waituntil( val << chans[4] ) {} }
static inline void cons_wait_6( size_t & val ) { waituntil( val << chans[0] ) {} or waituntil( val << chans[1] ) {} or waituntil( val << chans[2] ) {} or waituntil( val << chans[3] ) {} or waituntil( val << chans[4] ) {} or waituntil( val << chans[5] ) {} }
static inline void cons_wait_7( size_t & val ) { waituntil( val << chans[0] ) {} or waituntil( val << chans[1] ) {} or waituntil( val << chans[2] ) {} or waituntil( val << chans[3] ) {} or waituntil( val << chans[4] ) {} or waituntil( val << chans[5] ) {} or waituntil( val << chans[6] ) {} }
static inline void cons_wait_8( size_t & val ) { waituntil( val << chans[0] ) {} or waituntil( val << chans[1] ) {} or waituntil( val << chans[2] ) {} or waituntil( val << chans[3] ) {} or waituntil( val << chans[4] ) {} or waituntil( val << chans[5] ) {} or waituntil( val << chans[6] ) {} or waituntil( val << chans[7] ) {}}

static inline void prods_wait_1( size_t val ) { waituntil( chans[0] << val ) {} }
static inline void prods_wait_2( size_t val ) { waituntil( chans[0] << val ) {} or waituntil( chans[1] << val ) {} }
static inline void prods_wait_3( size_t val ) { waituntil( chans[0] << val ) {} or waituntil( chans[1] << val ) {} or waituntil( chans[2] << val ) {} }
static inline void prods_wait_4( size_t val ) { waituntil( chans[0] << val ) {} or waituntil( chans[1] << val ) {} or waituntil( chans[2] << val ) {} or waituntil( chans[3] << val ) {} }
static inline void prods_wait_5( size_t val ) { waituntil( chans[0] << val ) {} or waituntil( chans[1] << val ) {} or waituntil( chans[2] << val ) {} or waituntil( chans[3] << val ) {} or waituntil( chans[4] << val ) {} }
static inline void prods_wait_6( size_t val ) { waituntil( chans[0] << val ) {} or waituntil( chans[1] << val ) {} or waituntil( chans[2] << val ) {} or waituntil( chans[3] << val ) {} or waituntil( chans[4] << val ) {} or waituntil( chans[5] << val ) {} }
static inline void prods_wait_7( size_t val ) { waituntil( chans[0] << val ) {} or waituntil( chans[1] << val ) {} or waituntil( chans[2] << val ) {} or waituntil( chans[3] << val ) {} or waituntil( chans[4] << val ) {} or waituntil( chans[5] << val ) {} or waituntil( chans[6] << val ) {} }
static inline void prods_wait_8( size_t val ) { waituntil( chans[0] << val ) {} or waituntil( chans[1] << val ) {} or waituntil( chans[2] << val ) {} or waituntil( chans[3] << val ) {} or waituntil( chans[4] << val ) {} or waituntil( chans[5] << val ) {} or waituntil( chans[6] << val ) {} or waituntil( chans[7] << val ) {}}

size_t globalTotal = 0;

thread Consumer {};
void main( Consumer & this ) {
    size_t val, i = 0;
    try {
        for(;; i++ ) {
            FN_GLUE(cons_wait_, NUM_CHANS)(val);
        }
    } catch( channel_closed * e ) {}
    __atomic_fetch_add( &globalTotal, i, __ATOMIC_SEQ_CST );
}

thread Producer {};
void main( Producer & this ) {
    try {
        for( size_t i = 0;; i++ ) {
            FN_GLUE(prods_wait_, NUM_CHANS)(i);
        }
    } catch( channel_closed * e ) {}
}

int main( int argc, char * argv[] ) {
    switch ( argc ) {
          case 3:
                if ( strcmp( argv[2], "d" ) != 0 ) {                    // default ?
                        ChannelSize = atoi( argv[2] );
                } // if
          case 2:
                if ( strcmp( argv[1], "d" ) != 0 ) {                    // default ?
                        Processors = atoi( argv[1] );
                        if ( Processors < 1 ) goto Usage;
                } // if
          case 1:                                                                                       // use defaults
                break;
          default:
          Usage:
                sout | "Usage: " | argv[0]
             | " [ processors (> 0) | 'd' (default " | Processors
                         | ") ] [ channel size (>= 0) | 'd' (default " | ChannelSize
                         | ") ]" ;
                exit( EXIT_FAILURE );
        } // switch
    Producers = Processors / 2;
    Consumers = Processors / 2;

    processor p[Processors - 1];

    chans = aalloc( NUM_CHANS );
    for ( i; NUM_CHANS )
        chans[i]{ ChannelSize };

    {
        Producer p[Producers];
        Consumer c[Consumers];

        sleep(10`s);

        for ( i; NUM_CHANS )
            close( chans[i] );
    }
    adelete( chans );
    printf("%zu\n", globalTotal);
}