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symposium.c
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symposium.c
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#include <stdio.h>
#include <stdlib.h>
#include <math.h>
#include <assert.h>
#include <string.h>
#include "util.h"
#include "bios.h"
#include "tinyos.h"
#include "symposium.h"
#define QUIET 0 /* Use 1 for supperssing printing (for timing tests), 0 for normal printing */
/*
This file contains a number of example programs for tinyos.
*/
void adjust_symposium(symposium_t* symp, int dBASE, int dGAP)
{
symp->fmin = FBASE + dBASE -
(int)( log((double)(2*symp->N*symp->bites))/log(.5+.5*sqrt(5.)));
symp->fmax = symp->fmin + FGAP +dGAP;
}
/* We use the recursive definition of Fibonacci numbers, implemented by the routines below,
to "burn" CPU cycles. The complexity of the routine is exponential in n.
*/
int fiborand(int fmin, int fmax) { return lrand48() % (fmax-fmin+1) + fmin; }
unsigned int fibo(unsigned int n) /* Very slow routine */
{
if(n<2) return n;
else return fibo(n-1)+fibo(n-2);
}
/*
Dining Philosophers.
In this implementation of the Dining Philosohpers problem, each philosopher
is thinking about Fibonacci numbers...
The implementation follows the monitor pattern.
*/
/* utilities */
int LEFT(int i, int N) { return (i+1) % N; }
int RIGHT(int i, int N) { return (i+N-1) % N; }
/* Prints the current state given a change (described by fmt) for
philosopher ph */
void print_state(int N, PHIL* state, const char* fmt, int ph)
{
#if QUIET==0
int i;
if(N<100) {
for(i=0;i<N;i++) {
char c= (".THE")[state[i]];
if(i==ph) printf("[%c]", c);
else printf(" %c ", c);
}
}
printf(fmt, ph);
#endif
}
/* Functions think and eat (just burn CPU cycles). */
void think(int fmin, int fmax) { fibo(fiborand(fmin, fmax)); }
void eat(int fmin, int fmax) { think(fmin, fmax); }
/* Attempt to make a (hungry) philosopher i to start eating */
void trytoeat(SymposiumTable* S, int i)
{
int N = S->symp->N;
PHIL* state = S->state;
if(state[i]==HUNGRY && state[LEFT(i,N)]!=EATING && state[RIGHT(i,N)]!=EATING) {
state[i] = EATING;
print_state(N, state, " %d is eating\n",i);
Cond_Signal(&(S->hungry[i]));
}
}
void SymposiumTable_philosopher(SymposiumTable* S, int i)
{
/* cache locally for convenience */
int N = S->symp->N;
int bites = S->symp->bites;
int fmin = S->symp->fmin;
int fmax = S->symp->fmax;
PHIL* state = S->state;
Mutex_Lock(& S->mx); /* Philosopher arrives in thinking state */
state[i] = THINKING;
print_state(N, state, " %d has arrived\n",i);
Mutex_Unlock(& S->mx);
for(int j=0; j<bites; j++) { /* Number of bites (mpoykies) */
think(fmin, fmax);
Mutex_Lock(& S->mx);
state[i] = HUNGRY;
trytoeat(S,i); /* This may not succeed */
while(state[i]==HUNGRY) {
print_state(N, state, " %d waits hungry\n",i);
Cond_Wait(& S->mx, &(S->hungry[i])); /* If hungry we sleep. trytoeat(i) will wake us. */
}
assert(state[i]==EATING);
Mutex_Unlock(& S->mx);
eat(fmin, fmax);
Mutex_Lock(& S->mx);
state[i] = THINKING; /* We are done eating, think again */
print_state(N, state, " %d is thinking\n",i);
trytoeat(S, LEFT(i,N)); /* Check if our left and right can eat NOW. */
trytoeat(S, RIGHT(i,N));
Mutex_Unlock(& S->mx);
}
Mutex_Lock(& S->mx);
state[i] = NOTHERE; /* We are done (eaten all the bites) */
print_state(N, state, " %d is leaving\n",i);
Mutex_Unlock(& S->mx);
}
void SymposiumTable_init(SymposiumTable* table, symposium_t* symp)
{
table->symp = symp;
table->mx = MUTEX_INIT;
table->state = (PHIL*) xmalloc(symp->N * sizeof(PHIL));
table->hungry = (CondVar*) xmalloc(symp->N * sizeof(CondVar));
for(int i=0; i<symp->N; i++) {
table->state[i] = NOTHERE;
table->hungry[i] = COND_INIT;
}
}
void SymposiumTable_destroy(SymposiumTable* table)
{
free(table->state);
free(table->hungry);
}
typedef struct { int i; SymposiumTable* S; } philosopher_args;
/* Philosopher process */
int PhilosopherProcess(int argl, void* args)
{
assert(argl == sizeof(philosopher_args));
philosopher_args* A = args;
SymposiumTable_philosopher(A->S, A->i);
return 0;
}
/*
This process executes a "symposium" for a number of philosophers.
*/
int SymposiumOfProcesses(int argl, void* args)
{
assert(argl == sizeof(symposium_t));
symposium_t* symp = args;
int N = symp->N;
/* Initialize structures */
SymposiumTable S;
SymposiumTable_init(&S, symp);
/* Execute philosophers */
for(int i=0;i<N;i++) {
philosopher_args Args;
Args.i = i;
Args.S = &S;
Exec(PhilosopherProcess, sizeof(Args), &Args);
}
/* Wait for philosophers to exit */
for(int i=0;i<N;i++) {
WaitChild(NOPROC, NULL);
}
SymposiumTable_destroy(&S);
return 0;
}
int PhilosopherThread(int i, void* symp)
{
SymposiumTable_philosopher((SymposiumTable*) symp, i);
return 0;
}
/*
This process executes a "symposium" for a number of philosophers.
Each philosopher is a thread.
*/
int SymposiumOfThreads(int argl, void* args)
{
assert(argl == sizeof(symposium_t));
symposium_t* symp = args;
int N = symp->N;
/* Initialize structures */
SymposiumTable S;
SymposiumTable_init(&S, symp);
/* Execute philosophers */
Tid_t thread[symp->N];
for(int i=0;i<N;i++) {
thread[i] = CreateThread(PhilosopherThread, i, &S);
}
/* Wait for philosophers to exit */
for(int i=0;i<N;i++) {
ThreadJoin(thread[i],NULL);
}
SymposiumTable_destroy(&S);
return 0;
}