#include "u.h" #include "../port/lib.h" #include "mem.h" #include "dat.h" #include "fns.h" #include "../port/error.h" static void imagereclaim(void); static void imagechanreclaim(void); #include "io.h" /* * Attachable segment types */ static Physseg physseg[10] = { { SG_SHARED, "shared", 0, SEGMAXSIZE, 0, 0 }, { SG_BSS, "memory", 0, SEGMAXSIZE, 0, 0 }, { 0, 0, 0, 0, 0, 0 }, }; static Lock physseglock; #define NFREECHAN 64 #define IHASHSIZE 64 #define ihash(s) imagealloc.hash[s%IHASHSIZE] static struct Imagealloc { Lock; Image *free; Image *hash[IHASHSIZE]; QLock ireclaim; /* mutex on reclaiming free images */ Chan **freechan; /* free image channels */ int nfreechan; /* number of free channels */ int szfreechan; /* size of freechan array */ QLock fcreclaim; /* mutex on reclaiming free channels */ }imagealloc; Segment* (*_globalsegattach)(Proc*, char*); void initseg(void) { Image *i, *ie; imagealloc.free = xalloc(conf.nimage*sizeof(Image)); ie = &imagealloc.free[conf.nimage-1]; for(i = imagealloc.free; i < ie; i++) i->next = i+1; i->next = 0; imagealloc.freechan = malloc(NFREECHAN * sizeof(Chan*)); imagealloc.szfreechan = NFREECHAN; } Segment * newseg(int type, ulong base, ulong size) { Segment *s; int mapsize; if(size > (SEGMAPSIZE*PTEPERTAB)) error(Enovmem); if(swapfull()) error(Enoswap); s = smalloc(sizeof(Segment)); s->ref = 1; s->type = type; s->base = base; s->top = base+(size*BY2PG); s->size = size; s->sema.prev = &s->sema; s->sema.next = &s->sema; mapsize = ROUND(size, PTEPERTAB)/PTEPERTAB; if(mapsize > nelem(s->ssegmap)){ mapsize *= 2; if(mapsize > (SEGMAPSIZE*PTEPERTAB)) mapsize = (SEGMAPSIZE*PTEPERTAB); s->map = smalloc(mapsize*sizeof(Pte*)); s->mapsize = mapsize; } else{ s->map = s->ssegmap; s->mapsize = nelem(s->ssegmap); } return s; } void putseg(Segment *s) { Pte **pp, **emap; Image *i; if(s == 0) return; i = s->image; if(i != 0) { lock(i); lock(s); if(i->s == s && s->ref == 1) i->s = 0; unlock(i); } else lock(s); s->ref--; if(s->ref != 0) { unlock(s); return; } unlock(s); qlock(&s->lk); if(i) putimage(i); emap = &s->map[s->mapsize]; for(pp = s->map; pp < emap; pp++) if(*pp) freepte(s, *pp); qunlock(&s->lk); if(s->map != s->ssegmap) free(s->map); if(s->profile != 0) free(s->profile); free(s); } void relocateseg(Segment *s, ulong offset) { Page **pg, *x; Pte *pte, **p, **endpte; endpte = &s->map[s->mapsize]; for(p = s->map; p < endpte; p++) { if(*p == 0) continue; pte = *p; for(pg = pte->first; pg <= pte->last; pg++) { if(x = *pg) x->va += offset; } } } Segment* dupseg(Segment **seg, int segno, int share) { int i, size; Pte *pte; Segment *n, *s; SET(n); s = seg[segno]; qlock(&s->lk); if(waserror()){ qunlock(&s->lk); nexterror(); } switch(s->type&SG_TYPE) { case SG_TEXT: /* New segment shares pte set */ case SG_SHARED: case SG_PHYSICAL: goto sameseg; case SG_STACK: n = newseg(s->type, s->base, s->size); break; case SG_BSS: /* Just copy on write */ if(share) goto sameseg; n = newseg(s->type, s->base, s->size); break; case SG_DATA: /* Copy on write plus demand load info */ if(segno == TSEG){ poperror(); qunlock(&s->lk); return data2txt(s); } if(share) goto sameseg; n = newseg(s->type, s->base, s->size); incref(s->image); n->image = s->image; n->fstart = s->fstart; n->flen = s->flen; break; } size = s->mapsize; for(i = 0; i < size; i++) if(pte = s->map[i]) n->map[i] = ptecpy(pte); n->flushme = s->flushme; if(s->ref > 1) procflushseg(s); poperror(); qunlock(&s->lk); return n; sameseg: incref(s); poperror(); qunlock(&s->lk); return s; } void segpage(Segment *s, Page *p) { Pte **pte; ulong off; Page **pg; if(p->va < s->base || p->va >= s->top) panic("segpage"); off = p->va - s->base; pte = &s->map[off/PTEMAPMEM]; if(*pte == 0) *pte = ptealloc(); pg = &(*pte)->pages[(off&(PTEMAPMEM-1))/BY2PG]; *pg = p; if(pg < (*pte)->first) (*pte)->first = pg; if(pg > (*pte)->last) (*pte)->last = pg; } Image* attachimage(int type, Chan *c, ulong base, ulong len) { Image *i, **l; /* reclaim any free channels from reclaimed segments */ if(imagealloc.nfreechan) imagechanreclaim(); lock(&imagealloc); /* * Search the image cache for remains of the text from a previous * or currently running incarnation */ for(i = ihash(c->qid.path); i; i = i->hash) { if(c->qid.path == i->qid.path) { lock(i); if(eqqid(c->qid, i->qid) && eqqid(c->mqid, i->mqid) && c->mchan == i->mchan && c->type == i->type) { goto found; } unlock(i); } } /* * imagereclaim dumps pages from the free list which are cached by image * structures. This should free some image structures. */ while(!(i = imagealloc.free)) { unlock(&imagealloc); imagereclaim(); sched(); lock(&imagealloc); } imagealloc.free = i->next; lock(i); incref(c); i->c = c; i->type = c->type; i->qid = c->qid; i->mqid = c->mqid; i->mchan = c->mchan; l = &ihash(c->qid.path); i->hash = *l; *l = i; found: unlock(&imagealloc); if(i->s == 0) { /* Disaster after commit in exec */ if(waserror()) { unlock(i); pexit(Enovmem, 1); } i->s = newseg(type, base, len); i->s->image = i; i->ref++; poperror(); } else incref(i->s); return i; } static struct { int calls; /* times imagereclaim was called */ int loops; /* times the main loop was run */ uvlong ticks; /* total time in the main loop */ uvlong maxt; /* longest time in main loop */ } irstats; static void imagereclaim(void) { int n; Page *p; uvlong ticks; irstats.calls++; /* Somebody is already cleaning the page cache */ if(!canqlock(&imagealloc.ireclaim)) return; lock(&palloc); ticks = fastticks(nil); n = 0; /* * All the pages with images backing them are at the * end of the list (see putpage) so start there and work * backward. */ for(p = palloc.tail; p && p->image && n<1000; p = p->prev) { if(p->ref == 0 && canlock(p)) { if(p->ref == 0) { n++; uncachepage(p); } unlock(p); } } ticks = fastticks(nil) - ticks; unlock(&palloc); irstats.loops++; irstats.ticks += ticks; if(ticks > irstats.maxt) irstats.maxt = ticks; //print("T%llud+", ticks); qunlock(&imagealloc.ireclaim); } /* * since close can block, this has to be called outside of * spin locks. */ static void imagechanreclaim(void) { Chan *c; /* Somebody is already cleaning the image chans */ if(!canqlock(&imagealloc.fcreclaim)) return; /* * We don't have to recheck that nfreechan > 0 after we * acquire the lock, because we're the only ones who decrement * it (the other lock contender increments it), and there's only * one of us thanks to the qlock above. */ while(imagealloc.nfreechan > 0){ lock(&imagealloc); imagealloc.nfreechan--; c = imagealloc.freechan[imagealloc.nfreechan]; unlock(&imagealloc); cclose(c); } qunlock(&imagealloc.fcreclaim); } void putimage(Image *i) { Chan *c, **cp; Image *f, **l; if(i->notext) return; lock(i); if(--i->ref == 0) { l = &ihash(i->qid.path); mkqid(&i->qid, ~0, ~0, QTFILE); unlock(i); c = i->c; lock(&imagealloc); for(f = *l; f; f = f->hash) { if(f == i) { *l = i->hash; break; } l = &f->hash; } i->next = imagealloc.free; imagealloc.free = i; /* defer freeing channel till we're out of spin lock's */ if(imagealloc.nfreechan == imagealloc.szfreechan){ imagealloc.szfreechan += NFREECHAN; cp = malloc(imagealloc.szfreechan*sizeof(Chan*)); if(cp == nil) panic("putimage"); memmove(cp, imagealloc.freechan, imagealloc.nfreechan*sizeof(Chan*)); free(imagealloc.freechan); imagealloc.freechan = cp; } imagealloc.freechan[imagealloc.nfreechan++] = c; unlock(&imagealloc); return; } unlock(i); } long ibrk(ulong addr, int seg) { Segment *s, *ns; ulong newtop, newsize; int i, mapsize; Pte **map; s = up->seg[seg]; if(s == 0) error(Ebadarg); if(addr == 0) return s->base; qlock(&s->lk); /* We may start with the bss overlapping the data */ if(addr < s->base) { if(seg != BSEG || up->seg[DSEG] == 0 || addr < up->seg[DSEG]->base) { qunlock(&s->lk); error(Enovmem); } addr = s->base; } newtop = PGROUND(addr); newsize = (newtop-s->base)/BY2PG; if(newtop < s->top) { mfreeseg(s, newtop, (s->top-newtop)/BY2PG); s->top = newtop; s->size = newsize; qunlock(&s->lk); flushmmu(); return 0; } if(swapfull()){ qunlock(&s->lk); error(Enoswap); } for(i = 0; i < NSEG; i++) { ns = up->seg[i]; if(ns == 0 || ns == s) continue; if(newtop >= ns->base && newtop < ns->top) { qunlock(&s->lk); error(Esoverlap); } } if(newsize > (SEGMAPSIZE*PTEPERTAB)) { qunlock(&s->lk); error(Enovmem); } mapsize = ROUND(newsize, PTEPERTAB)/PTEPERTAB; if(mapsize > s->mapsize){ map = smalloc(mapsize*sizeof(Pte*)); memmove(map, s->map, s->mapsize*sizeof(Pte*)); if(s->map != s->ssegmap) free(s->map); s->map = map; s->mapsize = mapsize; } s->top = newtop; s->size = newsize; qunlock(&s->lk); return 0; } /* * called with s->lk locked */ void mfreeseg(Segment *s, ulong start, int pages) { int i, j, size; ulong soff; Page *pg; Page *list; soff = start-s->base; j = (soff&(PTEMAPMEM-1))/BY2PG; size = s->mapsize; list = nil; for(i = soff/PTEMAPMEM; i < size; i++) { if(pages <= 0) break; if(s->map[i] == 0) { pages -= PTEPERTAB-j; j = 0; continue; } while(j < PTEPERTAB) { pg = s->map[i]->pages[j]; /* * We want to zero s->map[i]->page[j] and putpage(pg), * but we have to make sure other processors flush the * entry from their TLBs before the page is freed. * We construct a list of the pages to be freed, zero * the entries, then (below) call procflushseg, and call * putpage on the whole list. * * Swapped-out pages don't appear in TLBs, so it's okay * to putswap those pages before procflushseg. */ if(pg){ if(onswap(pg)) putswap(pg); else{ pg->next = list; list = pg; } s->map[i]->pages[j] = 0; } if(--pages == 0) goto out; j++; } j = 0; } out: /* flush this seg in all other processes */ if(s->ref > 1) procflushseg(s); /* free the pages */ for(pg = list; pg != nil; pg = list){ list = list->next; putpage(pg); } } Segment* isoverlap(Proc *p, ulong va, int len) { int i; Segment *ns; ulong newtop; newtop = va+len; for(i = 0; i < NSEG; i++) { ns = p->seg[i]; if(ns == 0) continue; if((newtop > ns->base && newtop <= ns->top) || (va >= ns->base && va < ns->top)) return ns; } return nil; } int addphysseg(Physseg* new) { Physseg *ps; /* * Check not already entered and there is room * for a new entry and the terminating null entry. */ lock(&physseglock); for(ps = physseg; ps->name; ps++){ if(strcmp(ps->name, new->name) == 0){ unlock(&physseglock); return -1; } } if(ps-physseg >= nelem(physseg)-2){ unlock(&physseglock); return -1; } *ps = *new; unlock(&physseglock); return 0; } int isphysseg(char *name) { Physseg *ps; int rv = 0; lock(&physseglock); for(ps = physseg; ps->name; ps++){ if(strcmp(ps->name, name) == 0){ rv = 1; break; } } unlock(&physseglock); return rv; } ulong segattach(Proc *p, ulong attr, char *name, ulong va, ulong len) { int sno; Segment *s, *os; Physseg *ps; if(va != 0 && va >= USTKTOP) error(Ebadarg); validaddr((ulong)name, 1, 0); vmemchr(name, 0, ~0); for(sno = 0; sno < NSEG; sno++) if(p->seg[sno] == nil && sno != ESEG) break; if(sno == NSEG) error(Enovmem); /* * first look for a global segment with the * same name */ if(_globalsegattach != nil){ s = (*_globalsegattach)(p, name); if(s != nil){ p->seg[sno] = s; return s->base; } } len = PGROUND(len); if(len == 0) error(Ebadarg); /* * Find a hole in the address space. * Starting at the lowest possible stack address - len, * check for an overlapping segment, and repeat at the * base of that segment - len until either a hole is found * or the address space is exhausted. */ if(va == 0) { va = p->seg[SSEG]->base - len; for(;;) { os = isoverlap(p, va, len); if(os == nil) break; va = os->base; if(len > va) error(Enovmem); va -= len; } } va = va&~(BY2PG-1); if(isoverlap(p, va, len) != nil) error(Esoverlap); for(ps = physseg; ps->name; ps++) if(strcmp(name, ps->name) == 0) goto found; error(Ebadarg); found: if(len > ps->size) error(Enovmem); attr &= ~SG_TYPE; /* Turn off what is not allowed */ attr |= ps->attr; /* Copy in defaults */ s = newseg(attr, va, len/BY2PG); s->pseg = ps; p->seg[sno] = s; return va; } void pteflush(Pte *pte, int s, int e) { int i; Page *p; for(i = s; i < e; i++) { p = pte->pages[i]; if(pagedout(p) == 0) memset(p->cachectl, PG_TXTFLUSH, sizeof(p->cachectl)); } } long syssegflush(ulong *arg) { Segment *s; ulong addr, l; Pte *pte; int chunk, ps, pe, len; addr = arg[0]; len = arg[1]; while(len > 0) { s = seg(up, addr, 1); if(s == 0) error(Ebadarg); s->flushme = 1; more: l = len; if(addr+l > s->top) l = s->top - addr; ps = addr-s->base; pte = s->map[ps/PTEMAPMEM]; ps &= PTEMAPMEM-1; pe = PTEMAPMEM; if(pe-ps > l){ pe = ps + l; pe = (pe+BY2PG-1)&~(BY2PG-1); } if(pe == ps) { qunlock(&s->lk); error(Ebadarg); } if(pte) pteflush(pte, ps/BY2PG, pe/BY2PG); chunk = pe-ps; len -= chunk; addr += chunk; if(len > 0 && addr < s->top) goto more; qunlock(&s->lk); } flushmmu(); return 0; } void segclock(ulong pc) { Segment *s; s = up->seg[TSEG]; if(s == 0 || s->profile == 0) return; s->profile[0] += TK2MS(1); if(pc >= s->base && pc < s->top) { pc -= s->base; s->profile[pc>>LRESPROF] += TK2MS(1); } }