ref: 0aae832ac3f3ae5d136563e980e9c32ceb0d1444
dir: /sys/src/9/port/edf.c/
/* EDF scheduling */ #include <u.h> #include "../port/lib.h" #include "mem.h" #include "dat.h" #include "fns.h" #include "../port/error.h" #include "../port/edf.h" #include <trace.h> /* debugging */ enum { Dontprint = 1, }; #define DPRINT if(Dontprint){}else print static long now; /* Low order 32 bits of time in µs */ extern ulong delayedscheds; extern Schedq runq[Nrq]; extern int nrdy; extern ulong runvec; /* Statistics stuff */ ulong nilcount; ulong scheds; ulong edfnrun; int misseddeadlines; /* Edfschedlock protects modification of admission params */ int edfinited; QLock edfschedlock; static Lock thelock; enum{ Dl, /* Invariant for schedulability test: Dl < Rl */ Rl, }; static char *testschedulability(Proc*); static Proc *qschedulability; enum { Onemicrosecond = 1, Onemillisecond = 1000, Onesecond = 1000000, OneRound = Onemillisecond/2, }; static int timeconv(Fmt *f) { char buf[128], *sign; vlong t; buf[0] = 0; switch(f->r) { case 'U': t = va_arg(f->args, uvlong); break; case 't': /* vlong in nanoseconds */ t = va_arg(f->args, long); break; default: return fmtstrcpy(f, "(timeconv)"); } if (t < 0) { sign = "-"; t = -t; } else sign = ""; if (t > Onesecond){ t += OneRound; sprint(buf, "%s%d.%.3ds", sign, (int)(t / Onesecond), (int)(t % Onesecond)/Onemillisecond); }else if (t > Onemillisecond) sprint(buf, "%s%d.%.3dms", sign, (int)(t / Onemillisecond), (int)(t % Onemillisecond)); else sprint(buf, "%s%dµs", sign, (int)t); return fmtstrcpy(f, buf); } long edfcycles; Edf* edflock(Proc *p) { Edf *e; if (p->edf == nil) return nil; ilock(&thelock); if((e = p->edf) && (e->flags & Admitted)){ thelock.pc = getcallerpc(&p); #ifdef EDFCYCLES edfcycles -= lcycles(); #endif now = µs(); return e; } iunlock(&thelock); return nil; } void edfunlock(void) { #ifdef EDFCYCLES edfcycles += lcycles(); #endif edfnrun++; iunlock(&thelock); } void edfinit(Proc*p) { if(!edfinited){ fmtinstall('t', timeconv); edfinited++; } now = µs(); DPRINT("%lud edfinit %lud[%s]\n", now, p->pid, statename[p->state]); p->edf = malloc(sizeof(Edf)); if(p->edf == nil) error(Enomem); return; } static void deadlineintr(Ureg*, Timer *t) { /* Proc reached deadline */ Proc *p; void (*pt)(Proc*, int, vlong); if(panicking || active.exiting) return; p = t->ta; now = µs(); DPRINT("%lud deadlineintr %lud[%s]\n", now, p->pid, statename[p->state]); /* If we're interrupting something other than the proc pointed to by t->a, * we've already achieved recheduling, so we need not do anything * Otherwise, we must cause a reschedule, but if we call sched() * here directly, the timer interrupt routine will not finish its business * Instead, we cause the resched to happen when the interrupted proc * returns to user space */ if(p == up){ if(up->trace && (pt = proctrace)) pt(up, SInts, 0); up->delaysched++; delayedscheds++; } } static void release(Proc *p) { /* Called with edflock held */ Edf *e; void (*pt)(Proc*, int, vlong); long n; vlong nowns; e = p->edf; e->flags &= ~Yield; if(e->d - now < 0){ e->periods++; e->r = now; if((e->flags & Sporadic) == 0){ /* * Non sporadic processes stay true to their period; * calculate next release time. * Second test limits duration of while loop. */ if((n = now - e->t) > 0){ if(n < e->T) e->t += e->T; else e->t = now + e->T - (n % e->T); } }else{ /* Sporadic processes may not be released earlier than * one period after this release */ e->t = e->r + e->T; } e->d = e->r + e->D; e->S = e->C; DPRINT("%lud release %lud[%s], r=%lud, d=%lud, t=%lud, S=%lud\n", now, p->pid, statename[p->state], e->r, e->d, e->t, e->S); if(pt = proctrace){ nowns = todget(nil); pt(p, SRelease, nowns); pt(p, SDeadline, nowns + 1000LL*e->D); } }else{ DPRINT("%lud release %lud[%s], too late t=%lud, called from %#p\n", now, p->pid, statename[p->state], e->t, getcallerpc(&p)); } } static void releaseintr(Ureg *u, Timer *t) { Proc *p; if(panicking || active.exiting) return; p = t->ta; if((edflock(p)) == nil) return; DPRINT("%lud releaseintr %lud[%s]\n", now, p->pid, statename[p->state]); switch(p->state){ default: edfunlock(); return; case Ready: /* remove proc from current runq */ if(dequeueproc(&runq[p->priority], p) != p){ DPRINT("releaseintr: can't find proc or lock race\n"); release(p); /* It'll start best effort */ edfunlock(); return; } /* fall through */ case Waitrelease: p->state = Scheding; release(p); edfunlock(); ready(p); if(up){ up->delaysched++; delayedscheds++; } return; case Running: release(p); edfrun(p, 1); break; case Wakeme: release(p); edfunlock(); twakeup(u, t); if(up){ up->delaysched++; delayedscheds++; } return; } edfunlock(); } void edfrecord(Proc *p) { long used; Edf *e; void (*pt)(Proc*, int, vlong); if((e = edflock(p)) == nil) return; used = now - e->s; if(e->d - now <= 0) e->edfused += used; else e->extraused += used; if(e->S > 0){ if(e->S <= used){ if(pt = proctrace) pt(p, SSlice, 0); DPRINT("%lud edfrecord slice used up\n", now); e->d = now; e->S = 0; }else e->S -= used; } e->s = now; edfunlock(); } void edfrun(Proc *p, int edfpri) { Edf *e; void (*pt)(Proc*, int, vlong); long tns; e = p->edf; /* Called with edflock held */ if(edfpri){ tns = e->d - now; if(tns <= 0 || e->S == 0){ /* Deadline reached or resources exhausted, * deschedule forthwith */ p->delaysched++; delayedscheds++; e->s = now; return; } if(e->S < tns) tns = e->S; if(tns < 20) tns = 20; e->tns = 1000LL * tns; /* µs to ns */ if(e->tt == nil || e->tf != deadlineintr){ DPRINT("%lud edfrun, deadline=%lud\n", now, tns); }else{ DPRINT("v"); } if(p->trace && (pt = proctrace)) pt(p, SInte, todget(nil) + e->tns); e->tmode = Trelative; e->tf = deadlineintr; e->ta = p; timeradd(e); }else{ DPRINT("<"); } e->s = now; } char * edfadmit(Proc *p) { char *err; Edf *e; int i; Proc *r; void (*pt)(Proc*, int, vlong); long tns; e = p->edf; if (e->flags & Admitted) return "task state"; /* should never happen */ /* simple sanity checks */ if (e->T == 0) return "T not set"; if (e->C == 0) return "C not set"; if (e->D > e->T) return "D > T"; if (e->D == 0) /* if D is not set, set it to T */ e->D = e->T; if (e->C > e->D) return "C > D"; qlock(&edfschedlock); if (err = testschedulability(p)){ qunlock(&edfschedlock); return err; } e->flags |= Admitted; edflock(p); if(p->trace && (pt = proctrace)) pt(p, SAdmit, 0); /* Look for another proc with the same period to synchronize to */ for(i=0; (r = proctab(i)) != nil; i++) { if(r->state <= New || r == p) continue; if(r->edf == nil || (r->edf->flags & Admitted) == 0) continue; if(r->edf->T == e->T) break; } if(r == nil){ /* Can't synchronize to another proc, release now */ e->t = now; e->d = 0; release(p); if (p == up){ DPRINT("%lud edfadmit self %lud[%s], release now: r=%lud d=%lud t=%lud\n", now, p->pid, statename[p->state], e->r, e->d, e->t); /* We're already running */ edfrun(p, 1); }else{ /* We're releasing another proc */ DPRINT("%lud edfadmit other %lud[%s], release now: r=%lud d=%lud t=%lud\n", now, p->pid, statename[p->state], e->r, e->d, e->t); p->ta = p; edfunlock(); qunlock(&edfschedlock); releaseintr(nil, p); return nil; } }else{ /* Release in synch to something else */ e->t = r->edf->t; if (p == up){ DPRINT("%lud edfadmit self %lud[%s], release at %lud\n", now, p->pid, statename[p->state], e->t); edfunlock(); qunlock(&edfschedlock); return nil; }else{ DPRINT("%lud edfadmit other %lud[%s], release at %lud\n", now, p->pid, statename[p->state], e->t); if(e->tt == nil){ tns = e->t - now; if(tns < 20) tns = 20; e->tns = 1000LL * tns; e->tmode = Trelative; e->tf = releaseintr; e->ta = p; timeradd(e); } } } edfunlock(); qunlock(&edfschedlock); return nil; } void edfstop(Proc *p) { Edf *e; void (*pt)(Proc*, int, vlong); if(e = edflock(p)){ DPRINT("%lud edfstop %lud[%s]\n", now, p->pid, statename[p->state]); if(p->trace && (pt = proctrace)) pt(p, SExpel, 0); e->flags &= ~Admitted; timerdel(e); edfunlock(); } } static int yfn(void *) { now = µs(); return up->trend == nil || now - up->edf->r >= 0; } void edfyield(void) { /* sleep until next release */ Edf *e; void (*pt)(Proc*, int, vlong); long n; if((e = edflock(up)) == nil) return; if(up->trace && (pt = proctrace)) pt(up, SYield, 0); if((n = now - e->t) > 0){ if(n < e->T) e->t += e->T; else e->t = now + e->T - (n % e->T); } e->r = e->t; e->flags |= Yield; e->d = now; n = e->t - now; if(n < 20) n = 20; up->tns = 1000LL * n; up->tmode = Trelative; up->tf = releaseintr; up->ta = up; up->trend = &up->sleep; timeradd(up); edfunlock(); if(waserror()){ up->trend = nil; timerdel(up); nexterror(); } sleep(&up->sleep, yfn, nil); up->trend = nil; timerdel(up); poperror(); } int edfready(Proc *p) { Edf *e; long n; if((e = edflock(p)) == nil) return 0; if(e->d - now <= 0){ /* past deadline, arrange for next release */ if((e->flags & Sporadic) == 0){ /* * Non sporadic processes stay true to their period; * calculate next release time. */ if((n = now - e->t) > 0){ if(n < e->T) e->t += e->T; else e->t = now + e->T - (n % e->T); } } if(now - e->t < 0){ /* Next release is in the future, schedule it */ if(e->tt == nil || e->tf != releaseintr){ n = e->t - now; if(n < 20) n = 20; e->tns = 1000LL * n; e->tmode = Trelative; e->tf = releaseintr; e->ta = p; timeradd(e); DPRINT("%lud edfready %lud[%s], release=%lud\n", now, p->pid, statename[p->state], e->t); } if(p->state == Running && (e->flags & (Yield|Yieldonblock)) == 0 && (e->flags & Extratime)){ /* If we were running, we've overrun our CPU allocation * or missed the deadline, continue running best-effort at low priority * Otherwise we were blocked. If we don't yield on block, we continue * best effort */ DPRINT(">"); p->basepri = PriExtra; p->fixedpri = 1; edfunlock(); return 0; /* Stick on runq[PriExtra] */ } DPRINT("%lud edfready %lud[%s] wait release at %lud\n", now, p->pid, statename[p->state], e->t); p->state = Waitrelease; edfunlock(); return -1; /* Make runnable later */ } DPRINT("%lud edfready %lud %s release now\n", now, p->pid, statename[p->state]); /* release now */ release(p); } edfunlock(); DPRINT("^"); return 1; } static void testenq(Proc *p) { Proc *xp, **xpp; Edf *e; e = p->edf; e->testnext = nil; if (qschedulability == nil) { qschedulability = p; return; } SET(xp); for (xpp = &qschedulability; *xpp; xpp = &xp->edf->testnext) { xp = *xpp; if (e->testtime - xp->edf->testtime < 0 || (e->testtime == xp->edf->testtime && e->testtype < xp->edf->testtype)){ e->testnext = xp; *xpp = p; return; } } assert(xp->edf->testnext == nil); xp->edf->testnext = p; } static char * testschedulability(Proc *theproc) { Proc *p; long H, G, Cb, ticks; int steps, i; /* initialize */ DPRINT("schedulability test %lud\n", theproc->pid); qschedulability = nil; for(i=0; (p = proctab(i)) != nil; i++) { if(p->state == Dead) continue; if((p->edf == nil || (p->edf->flags & Admitted) == 0) && p != theproc) continue; p->edf->testtype = Rl; p->edf->testtime = 0; DPRINT("\tInit: edfenqueue %lud\n", p->pid); testenq(p); } H=0; G=0; for(steps = 0; steps < Maxsteps; steps++){ p = qschedulability; qschedulability = p->edf->testnext; ticks = p->edf->testtime; switch (p->edf->testtype){ case Dl: H += p->edf->C; Cb = 0; DPRINT("\tStep %3d, Ticks %lud, pid %lud, deadline, H += %lud → %lud, Cb = %lud\n", steps, ticks, p->pid, p->edf->C, H, Cb); if (H+Cb>ticks){ DPRINT("not schedulable\n"); return "not schedulable"; } p->edf->testtime += p->edf->T - p->edf->D; p->edf->testtype = Rl; testenq(p); break; case Rl: DPRINT("\tStep %3d, Ticks %lud, pid %lud, release, G %lud, C%lud\n", steps, ticks, p->pid, p->edf->C, G); if(ticks && G <= ticks){ DPRINT("schedulable\n"); return nil; } G += p->edf->C; p->edf->testtime += p->edf->D; p->edf->testtype = Dl; testenq(p); break; default: assert(0); } } DPRINT("probably not schedulable\n"); return "probably not schedulable"; }