ref: f7a16b5e2cc38aed7985b0144bb2655d14ea6f5a
dir: /sys/src/9/port/chan.c/
#include "u.h" #include "../port/lib.h" #include "mem.h" #include "dat.h" #include "fns.h" #include "../port/error.h" enum { PATHSLOP = 20, PATHMSLOP = 20, }; static struct Chanalloc { Lock; int fid; Chan *free; Chan *list; }chanalloc; typedef struct Elemlist Elemlist; struct Elemlist { char *aname; /* original name */ char *name; /* copy of name, so '/' can be overwritten */ int nelems; char **elems; int *off; int mustbedir; int nerror; int prefix; }; char* chanpath(Chan *c) { if(c == nil) return "<nil chan>"; if(c->path == nil) return "<nil path>"; if(c->path->s == nil) return "<nil path.s>"; return c->path->s; } int isdotdot(char *p) { return p[0]=='.' && p[1]=='.' && p[2]=='\0'; } long incref(Ref *r) { long old, new; do { old = r->ref; new = old+1; } while(!cmpswap(&r->ref, old, new)); return new; } long decref(Ref *r) { long old, new; do { old = r->ref; if(old <= 0) panic("decref pc=%#p", getcallerpc(&r)); new = old-1; } while(!cmpswap(&r->ref, old, new)); return new; } /* * Rather than strncpy, which zeros the rest of the buffer, kstrcpy * truncates if necessary, always zero terminates, does not zero fill, * and puts ... at the end of the string if it's too long. Usually used to * save a string in up->genbuf; */ void kstrcpy(char *s, char *t, int ns) { int nt; nt = strlen(t); if(nt < ns){ memmove(s, t, nt); s[nt] = '\0'; return; } /* too long, truncate */ nt = ns-1; memmove(s, t, nt); s[nt] = '\0'; /* append ... if there is space */ ns -= 4; if(ns < 0) return; /* look for first byte of UTF-8 sequence by skipping continuation bytes */ while(ns>0 && (s[--ns]&0xC0)==0x80) ; strcpy(s+ns, "..."); } int emptystr(char *s) { if(s == nil) return 1; if(s[0] == '\0') return 1; return 0; } /* * Atomically replace *p with copy of s */ void kstrdup(char **p, char *s) { int n; char *t, *prev; n = strlen(s); /* if it's a user, we can wait for memory; if not, something's very wrong */ if(up != nil) t = smalloc(n+1); else{ t = malloc(n+1); if(t == nil) panic("kstrdup: no memory"); } setmalloctag(t, getcallerpc(&p)); memmove(t, s, n); t[n] = '\0'; prev = *p; *p = t; free(prev); } void chandevreset(void) { int i; todinit(); /* avoid later reentry causing infinite recursion */ for(i=0; devtab[i] != nil; i++) devtab[i]->reset(); } static void closeproc(void*); void chandevinit(void) { int i; for(i=0; devtab[i] != nil; i++) devtab[i]->init(); kproc("closeproc", closeproc, nil); } void chandevshutdown(void) { int i; /* shutdown in reverse order */ for(i=0; devtab[i] != nil; i++) ; for(i--; i >= 0; i--) devtab[i]->shutdown(); } Chan* newchan(void) { Chan *c; lock(&chanalloc); c = chanalloc.free; if(c != nil){ chanalloc.free = c->next; c->next = nil; } else { unlock(&chanalloc); c = smalloc(sizeof(Chan)); lock(&chanalloc); c->link = chanalloc.list; chanalloc.list = c; } if(c->fid == 0) c->fid = ++chanalloc.fid; unlock(&chanalloc); /* if you get an error before associating with a dev, close calls rootclose, a nop */ c->type = 0; c->flag = 0; c->ref = 1; c->dev = 0; c->offset = 0; c->devoffset = 0; c->iounit = 0; c->umh = nil; c->umc = nil; c->uri = 0; c->dri = 0; c->dirrock = nil; c->nrock = 0; c->mrock = 0; c->ismtpt = 0; c->mcp = nil; c->mux = nil; c->aux = nil; c->mchan = nil; memset(&c->mqid, 0, sizeof(c->mqid)); c->path = nil; c->srvname = nil; return c; } Path* newpath(char *s) { int i; Path *p; p = smalloc(sizeof(Path)); i = strlen(s); p->len = i; p->alen = i+PATHSLOP; p->s = smalloc(p->alen); memmove(p->s, s, i+1); p->ref = 1; /* * Cannot use newpath for arbitrary names because the mtpt * array will not be populated correctly. The names #/ and / are * allowed, but other names with / in them draw warnings. */ if(strchr(s, '/') != nil && strcmp(s, "#/") != 0 && strcmp(s, "/") != 0) print("newpath: %s from %#p\n", s, getcallerpc(&s)); p->mlen = 1; p->malen = PATHMSLOP; p->mtpt = smalloc(p->malen*sizeof p->mtpt[0]); return p; } static Path* copypath(Path *p) { int i; Path *pp; pp = smalloc(sizeof(Path)); pp->ref = 1; pp->len = p->len; pp->alen = p->alen; pp->s = smalloc(p->alen); memmove(pp->s, p->s, p->len+1); pp->mlen = p->mlen; pp->malen = p->malen; pp->mtpt = smalloc(p->malen*sizeof pp->mtpt[0]); for(i=0; i<pp->mlen; i++){ pp->mtpt[i] = p->mtpt[i]; if(pp->mtpt[i] != nil) incref(pp->mtpt[i]); } return pp; } void pathclose(Path *p) { int i; if(p == nil || decref(p)) return; for(i=0; i<p->mlen; i++) if(p->mtpt[i] != nil) cclose(p->mtpt[i]); free(p->mtpt); free(p->s); free(p); } /* * In place, rewrite name to compress multiple /, eliminate ., and process .. * (Really only called to remove a trailing .. that has been added. * Otherwise would need to update n->mtpt as well.) */ static void fixdotdotname(Path *p) { char *r; if(p->s[0] == '#'){ r = strchr(p->s, '/'); if(r == nil) return; cleanname(r); /* * The correct name is #i rather than #i/, * but the correct name of #/ is #/. */ if(strcmp(r, "/")==0 && p->s[1] != '/') *r = '\0'; }else cleanname(p->s); p->len = strlen(p->s); } static Path* uniquepath(Path *p) { Path *new; if(p->ref > 1){ /* copy on write */ new = copypath(p); pathclose(p); p = new; } return p; } static Path* addelem(Path *p, char *s, Chan *from) { char *t; int a, i; Chan *c, **tt; if(s[0]=='.' && s[1]=='\0') return p; p = uniquepath(p); i = strlen(s); a = p->len+1+i+1; if(a > p->alen){ a += PATHSLOP; t = smalloc(a); memmove(t, p->s, p->len+1); free(p->s); p->s = t; p->alen = a; } /* don't insert extra slash if one is present */ if(p->len>0 && p->s[p->len-1]!='/' && s[0]!='/') p->s[p->len++] = '/'; memmove(p->s+p->len, s, i+1); p->len += i; if(isdotdot(s)){ fixdotdotname(p); if(p->mlen > 1 && (c = p->mtpt[--p->mlen]) != nil){ p->mtpt[p->mlen] = nil; cclose(c); } }else{ if(p->mlen >= p->malen){ p->malen = p->mlen+1+PATHMSLOP; tt = smalloc(p->malen*sizeof tt[0]); memmove(tt, p->mtpt, p->mlen*sizeof tt[0]); free(p->mtpt); p->mtpt = tt; } p->mtpt[p->mlen++] = from; if(from != nil) incref(from); } return p; } void chanfree(Chan *c) { c->flag = CFREE; if(c->dirrock != nil){ free(c->dirrock); c->dirrock = nil; c->nrock = 0; c->mrock = 0; } if(c->umh != nil){ putmhead(c->umh); c->umh = nil; } if(c->umc != nil){ cclose(c->umc); c->umc = nil; } if(c->mux != nil){ muxclose(c->mux); c->mux = nil; } if(c->mchan != nil){ cclose(c->mchan); c->mchan = nil; } if(c->srvname != nil){ free(c->srvname); c->srvname = nil; } pathclose(c->path); c->path = nil; lock(&chanalloc); c->next = chanalloc.free; chanalloc.free = c; unlock(&chanalloc); } /* * Queue a chan to be closed by one of the clunk procs. */ struct { Chan *head; Chan *tail; ulong nqueued; ulong nclosed; Lock l; QLock q; Rendez r; } clunkq; static int clunkwork(void*) { return clunkq.head != nil; } static void closechanq(Chan *c) { lock(&clunkq.l); clunkq.nqueued++; c->next = nil; if(clunkq.head != nil) clunkq.tail->next = c; else clunkq.head = c; clunkq.tail = c; unlock(&clunkq.l); wakeup(&clunkq.r); } static Chan* closechandeq(void) { Chan *c; lock(&clunkq.l); c = clunkq.head; if(c != nil) { clunkq.head = c->next; clunkq.nclosed++; } unlock(&clunkq.l); return c; } static void closeproc(void *) { Chan *c; for(;;){ c = closechandeq(); if(c == nil) { qlock(&clunkq.q); if(!waserror()) { tsleep(&clunkq.r, clunkwork, nil, 500); poperror(); } c = closechandeq(); if(c == nil) { if(clunkq.q.head != nil) { qunlock(&clunkq.q); pexit("no work", 1); } qunlock(&clunkq.q); continue; } if(clunkq.q.head == nil) { if(!waserror()) { kproc("closeproc", closeproc, nil); poperror(); } } qunlock(&clunkq.q); } if(!waserror()){ devtab[c->type]->close(c); poperror(); } chanfree(c); } } void cclose(Chan *c) { if(c == nil || c->ref < 1 || c->flag&CFREE) panic("cclose %#p", getcallerpc(&c)); if(decref(c)) return; if(devtab[c->type]->dc == L'M') if((c->flag&COPEN) == 0 || (c->flag&(CRCLOSE|CCACHE)) == CCACHE) if((c->qid.type&(QTEXCL|QTMOUNT|QTAUTH)) == 0) if((clunkq.nqueued - clunkq.nclosed) < 64){ closechanq(c); return; } if(!waserror()){ devtab[c->type]->close(c); poperror(); } chanfree(c); } void ccloseq(Chan *c) { if(c == nil || c->ref < 1 || c->flag&CFREE) panic("ccloseq %#p", getcallerpc(&c)); if(decref(c) == 0) closechanq(c); } /* * Make sure we have the only copy of c. (Copy on write.) */ Chan* cunique(Chan *c) { Chan *nc; if(c->ref != 1){ nc = cclone(c); cclose(c); c = nc; } if(c->umh != nil){ //BUG print("cunique umh != nil from %#p\n", getcallerpc(&c)); putmhead(c->umh); c->umh = nil; } return c; } int eqqid(Qid a, Qid b) { return a.path==b.path && a.vers==b.vers; } int eqchan(Chan *a, Chan *b, int skipvers) { if(a->qid.path != b->qid.path) return 0; if(!skipvers && a->qid.vers!=b->qid.vers) return 0; if(a->type != b->type) return 0; if(a->dev != b->dev) return 0; return 1; } int eqchantdqid(Chan *a, int type, int dev, Qid qid, int skipvers) { if(a->qid.path != qid.path) return 0; if(!skipvers && a->qid.vers!=qid.vers) return 0; if(a->type != type) return 0; if(a->dev != dev) return 0; return 1; } Mhead* newmhead(Chan *from) { Mhead *mh; mh = smalloc(sizeof(Mhead)); mh->ref = 1; mh->from = from; incref(from); setmalloctag(mh, getcallerpc(&from)); return mh; } /* * This is necessary because there are many * pointers to the top of a given mount list: * * - the mhead in the namespace hash table * - the mhead in chans returned from findmount: * used in namec and then by unionread. * - the mhead in chans returned from createdir: * used in the open/create race protect, which is gone. * * The RWlock in the Mhead protects the mount list it contains. * The mount list is deleted in cunmount() and closepgrp(). * The RWlock ensures that nothing is using the mount list at that time. * * It is okay to replace c->mh with whatever you want as * long as you are sure you have a unique reference to it. * * This comment might belong somewhere else. */ void putmhead(Mhead *m) { if(m == nil) return; if(decref(m)) return; assert(m->mount == nil); cclose(m->from); free(m); } int cmount(Chan *new, Chan *old, int flag, char *spec) { int order; Mhead *m, **l, *mh; Mount *nm, *f, *um; Pgrp *pg; if(old->umh != nil) print("cmount: unexpected umh, caller %#p\n", getcallerpc(&new)); if(QTDIR & (old->qid.type^new->qid.type)) error(Emount); order = flag&MORDER; if((old->qid.type&QTDIR) == 0 && order != MREPL) error(Emount); nm = newmount(new, flag, spec); mh = new->umh; if(mh != nil) { rlock(&mh->lock); if(waserror()) { runlock(&mh->lock); mountfree(nm); nexterror(); } um = mh->mount; if(um != nil){ /* * Not allowed to bind when the old directory is itself a union. * (Maybe it should be allowed, but I don't see what the semantics * would be.) * * We need to check mh->mount->next to tell unions apart from * simple mount points, so that things like * mount -c fd /root * bind -c /root / * work. * * The check of mount->mflag allows things like * mount fd /root * bind -c /root / * * This is far more complicated than it should be, but I don't * see an easier way at the moment. */ if((flag&MCREATE) != 0 && (um->next != nil || (um->mflag&MCREATE) == 0)) error(Emount); /* * copy a union when binding it onto a directory */ f = nm; for(um = um->next; um != nil; um = um->next){ f->next = newmount(um->to, order==MREPL? MAFTER: order, um->spec); f = f->next; } } runlock(&mh->lock); poperror(); } pg = up->pgrp; wlock(&pg->ns); l = &MOUNTH(pg, old->qid); for(m = *l; m != nil; m = m->hash){ if(eqchan(m->from, old, 1)) break; l = &m->hash; } if(m == nil){ /* * nothing mounted here yet. create a mount * head and add to the hash table. */ m = newmhead(old); /* * if this is a union mount, add the old * node to the mount chain. */ if(order != MREPL) m->mount = newmount(old, 0, nil); *l = m; } wlock(&m->lock); um = m->mount; if(um != nil && order == MAFTER){ for(f = um; f->next != nil; f = f->next) ; f->next = nm; um = nil; } else { if(order != MREPL){ for(f = nm; f->next != nil; f = f->next) ; f->next = um; um = nil; } m->mount = nm; } wunlock(&m->lock); wunlock(&pg->ns); mountfree(um); return 0; } void cunmount(Chan *mnt, Chan *mounted) { Pgrp *pg; Mhead *m, **l; Mount *f, **p; if(mnt->umh != nil) /* should not happen */ print("cunmount newp extra umh %p has %p\n", mnt, mnt->umh); /* * It _can_ happen that mounted->umh is non-nil, * because mounted is the result of namec(Aopen) * (see sysfile.c:/^sysunmount). * If we open a union directory, it will have a umh. * Although surprising, this is okay, since the * cclose will take care of freeing the umh. */ pg = up->pgrp; wlock(&pg->ns); l = &MOUNTH(pg, mnt->qid); for(m = *l; m != nil; m = m->hash){ if(eqchan(m->from, mnt, 1)) break; l = &m->hash; } if(m == nil){ wunlock(&pg->ns); error(Eunmount); } wlock(&m->lock); f = m->mount; if(mounted == nil){ *l = m->hash; m->mount = nil; wunlock(&m->lock); wunlock(&pg->ns); mountfree(f); putmhead(m); return; } for(p = &m->mount; f != nil; f = f->next){ if(eqchan(f->to, mounted, 1) || (f->to->mchan != nil && eqchan(f->to->mchan, mounted, 1))){ *p = f->next; f->next = nil; if(m->mount == nil){ *l = m->hash; wunlock(&m->lock); wunlock(&pg->ns); mountfree(f); putmhead(m); return; } wunlock(&m->lock); wunlock(&pg->ns); mountfree(f); return; } p = &f->next; } wunlock(&m->lock); wunlock(&pg->ns); error(Eunion); } Chan* cclone(Chan *c) { Chan *nc; Walkqid *wq; if(c == nil || c->ref < 1 || c->flag&CFREE) panic("cclone: %#p", getcallerpc(&c)); wq = devtab[c->type]->walk(c, nil, nil, 0); if(wq == nil) error("clone failed"); nc = wq->clone; free(wq); if((nc->path = c->path) != nil) incref(c->path); return nc; } /* also used by sysfile.c:/^mountfix */ int findmount(Chan **cp, Mhead **mp, int type, int dev, Qid qid) { Chan *to; Pgrp *pg; Mhead *m; pg = up->pgrp; rlock(&pg->ns); for(m = MOUNTH(pg, qid); m != nil; m = m->hash){ if(eqchantdqid(m->from, type, dev, qid, 1)){ if(mp != nil) incref(m); rlock(&m->lock); to = m->mount->to; incref(to); runlock(&m->lock); runlock(&pg->ns); if(mp != nil){ putmhead(*mp); *mp = m; } if(*cp != nil) cclose(*cp); *cp = to; return 1; } } runlock(&pg->ns); return 0; } /* * Calls findmount but also updates path. */ static int domount(Chan **cp, Mhead **mp, Path **path) { Chan **lc, *from; Path *p; if(findmount(cp, mp, (*cp)->type, (*cp)->dev, (*cp)->qid) == 0) return 0; if(path != nil){ p = *path; p = uniquepath(p); if(p->mlen <= 0) print("domount: path %s has mlen==%d\n", p->s, p->mlen); else{ from = (*mp)->from; incref(from); lc = &p->mtpt[p->mlen-1]; if(*lc != nil) cclose(*lc); *lc = from; } *path = p; } return 1; } /* * If c is the right-hand-side of a mount point, returns the left hand side. * Changes name to reflect the fact that we've uncrossed the mountpoint, * so name had better be ours to change! */ static Chan* undomount(Chan *c, Path *path) { Chan *nc; if(path->ref != 1 || path->mlen == 0) print("undomount: path %s ref %ld mlen %d caller %#p\n", path->s, path->ref, path->mlen, getcallerpc(&c)); if(path->mlen > 0 && (nc = path->mtpt[path->mlen-1]) != nil){ cclose(c); path->mtpt[path->mlen-1] = nil; c = nc; } return c; } /* * Call dev walk but catch errors. */ static Walkqid* ewalk(Chan *c, Chan *nc, char **name, int nname) { Walkqid *wq; if(waserror()) return nil; wq = devtab[c->type]->walk(c, nc, name, nname); poperror(); return wq; } /* * Either walks all the way or not at all. No partial results in *cp. * *nerror is the number of names to display in an error message. */ static char Edoesnotexist[] = "does not exist"; int walk(Chan **cp, char **names, int nnames, int nomount, int *nerror) { int dev, didmount, dotdot, i, n, nhave, ntry, type; Chan *c, *nc, *mtpt; Path *path; Mhead *mh, *nmh; Mount *f; Walkqid *wq; c = *cp; incref(c); path = c->path; incref(path); mh = nil; /* * While we haven't gotten all the way down the path: * 1. step through a mount point, if any * 2. send a walk request for initial dotdot or initial prefix without dotdot * 3. move to the first mountpoint along the way. * 4. repeat. * * Each time through the loop: * * If didmount==0, c is on the undomount side of the mount point. * If didmount==1, c is on the domount side of the mount point. * Either way, c's full path is path. */ didmount = 0; for(nhave=0; nhave<nnames; nhave+=n){ if((c->qid.type&QTDIR) == 0){ if(nerror) *nerror = nhave; pathclose(path); cclose(c); kstrcpy(up->errstr, Enotdir, ERRMAX); putmhead(mh); return -1; } ntry = nnames - nhave; if(ntry > MAXWELEM) ntry = MAXWELEM; dotdot = 0; for(i=0; i<ntry; i++){ if(isdotdot(names[nhave+i])){ if(i==0){ dotdot = 1; ntry = 1; }else ntry = i; break; } } if(!dotdot && !nomount && !didmount) domount(&c, &mh, &path); type = c->type; dev = c->dev; if((wq = ewalk(c, nil, names+nhave, ntry)) == nil){ /* try a union mount, if any */ if(mh != nil && !nomount){ /* * mh->mount->to == c, so start at mh->mount->next */ rlock(&mh->lock); if((f = mh->mount) != nil) f = f->next; for(; f != nil; f = f->next) if((wq = ewalk(f->to, nil, names+nhave, ntry)) != nil){ type = f->to->type; dev = f->to->dev; break; } runlock(&mh->lock); } if(wq == nil){ cclose(c); pathclose(path); if(nerror) *nerror = nhave+1; putmhead(mh); return -1; } } didmount = 0; if(dotdot){ assert(wq->nqid == 1); assert(wq->clone != nil); path = addelem(path, "..", nil); nc = undomount(wq->clone, path); nmh = nil; n = 1; }else{ nc = nil; nmh = nil; if(!nomount){ for(i=0; i<wq->nqid && i<ntry-1; i++){ if(findmount(&nc, &nmh, type, dev, wq->qid[i])){ didmount = 1; break; } } } if(nc == nil){ /* no mount points along path */ if(wq->clone == nil){ cclose(c); pathclose(path); if(wq->nqid == 0 || (wq->qid[wq->nqid-1].type&QTDIR) != 0){ if(nerror) *nerror = nhave+wq->nqid+1; kstrcpy(up->errstr, Edoesnotexist, ERRMAX); }else{ if(nerror) *nerror = nhave+wq->nqid; kstrcpy(up->errstr, Enotdir, ERRMAX); } free(wq); putmhead(mh); return -1; } n = wq->nqid; nc = wq->clone; }else{ /* stopped early, at a mount point */ assert(didmount); if(wq->clone != nil){ cclose(wq->clone); wq->clone = nil; } n = i+1; } for(i=0; i<n; i++){ mtpt = nil; if(i==n-1 && nmh!=nil) mtpt = nmh->from; path = addelem(path, names[nhave+i], mtpt); } } cclose(c); c = nc; putmhead(mh); mh = nmh; free(wq); } putmhead(mh); c = cunique(c); pathclose(c->path); c->path = path; cclose(*cp); *cp = c; if(nerror) *nerror = nhave; return 0; } /* * c is a mounted non-creatable directory. find a creatable one. */ Chan* createdir(Chan *c, Mhead *m) { Chan *nc; Mount *f; rlock(&m->lock); if(waserror()){ runlock(&m->lock); nexterror(); } for(f = m->mount; f != nil; f = f->next){ if((f->mflag&MCREATE) != 0){ nc = cclone(f->to); runlock(&m->lock); poperror(); cclose(c); return nc; } } error(Enocreate); return 0; } void saveregisters(void) { } static void growparse(Elemlist *e) { char **new; int *inew; enum { Delta = 8 }; if((e->nelems % Delta) == 0){ new = smalloc((e->nelems+Delta) * sizeof(char*)); memmove(new, e->elems, e->nelems*sizeof(char*)); free(e->elems); e->elems = new; inew = smalloc((e->nelems+Delta+1) * sizeof(int)); memmove(inew, e->off, (e->nelems+1)*sizeof(int)); free(e->off); e->off = inew; } } /* * The name is known to be valid. * Copy the name so slashes can be overwritten. * An empty string will set nelem=0. * A path ending in / or /. or /.//./ etc. will have * e.mustbedir = 1, so that we correctly * reject, e.g., "/adm/users/." when /adm/users is a file * rather than a directory. */ static void parsename(char *aname, Elemlist *e) { char *name, *slash; kstrdup(&e->name, aname); name = e->name; e->nelems = 0; e->elems = nil; e->off = smalloc(sizeof(int)); e->off[0] = skipslash(name) - name; for(;;){ name = skipslash(name); if(*name == '\0'){ e->off[e->nelems] = name+strlen(name) - e->name; e->mustbedir = 1; break; } growparse(e); e->elems[e->nelems++] = name; slash = utfrune(name, '/'); if(slash == nil){ e->off[e->nelems] = name+strlen(name) - e->name; e->mustbedir = 0; break; } e->off[e->nelems] = slash - e->name; *slash++ = '\0'; name = slash; } } static void namelenerror(char *aname, int len, char *err) { char *ename, *name, *next; int i, errlen; /* * If the name is short enough, just use the whole thing. */ errlen = strlen(err); if(len < ERRMAX/3 || len+errlen < 2*ERRMAX/3) snprint(up->genbuf, sizeof up->genbuf, "%.*s", utfnlen(aname, len), aname); else{ /* * Print a suffix of the name, but try to get a little info. */ ename = aname+len; next = ename; do{ name = next; if(next == aname) break; while(next > aname) if(*--next == '/') break; len = ename-next; }while(len < ERRMAX/3 || len + errlen < 2*ERRMAX/3); /* * If the name is ridiculously long, chop it. */ if(name == ename){ name = ename-ERRMAX/4; if(name <= aname) panic("bad math in namelenerror"); /* walk out of current UTF sequence */ for(i=0; (*name&0xC0)==0x80 && i<UTFmax; i++) name++; } snprint(up->genbuf, sizeof up->genbuf, "...%.*s", utfnlen(name, ename-name), name); } snprint(up->errstr, ERRMAX, "%#q %s", up->genbuf, err); nexterror(); } void nameerror(char *name, char *err) { namelenerror(name, strlen(name), err); } /* * Turn a name into a channel. * &name[0] is known to be a valid address. It may be a kernel address. * * Opening with amode Aopen, Acreate, Aremove, or Aaccess guarantees * that the result will be the only reference to that particular fid. * This is necessary since we might pass the result to * devtab[]->remove(). * * Opening Atodir or Amount does not guarantee this. * * Under certain circumstances, opening Aaccess will cause * an unnecessary clone in order to get a cunique Chan so it * can attach the correct name. Sysstat and sys_stat need the * correct name so they can rewrite the stat info. */ Chan* namec(char *aname, int amode, int omode, ulong perm) { int len, n, t, nomount, devunmount; Chan *c; Chan *volatile cnew; Path *volatile path; Elemlist e; Rune r; Mhead *m; char *err; char *name; if(aname[0] == '\0') error("empty file name"); aname = validnamedup(aname, 1); if(waserror()){ free(aname); nexterror(); } name = aname; /* * When unmounting, the name parameter must be accessed * using Aopen in order to get the real chan from * something like /srv/cs or /fd/0. However when sandboxing, * unmounting a sharp from a union is a valid operation even * if the device is blocked. */ devunmount = 0; if(amode == Aunmount){ /* * Doing any walks down the device could leak information * about the existence of files. */ if(name[0] == '#' && utflen(name) == 2) devunmount = 1; amode = Aopen; } /* * Find the starting off point (the current slash, the root of * a device tree, or the current dot) as well as the name to * evaluate starting there. */ nomount = 0; switch(name[0]){ case '/': c = up->slash; incref(c); break; case '#': nomount = 1; up->genbuf[0] = '\0'; n = 0; while(*name != '\0' && (*name != '/' || n < 2)){ if(n >= sizeof(up->genbuf)-1) error(Efilename); up->genbuf[n++] = *name++; } up->genbuf[n] = '\0'; n = chartorune(&r, up->genbuf+1)+1; t = devno(r, 1); if(t == -1) error(Ebadsharp); if(!devunmount && !devallowed(up->pgrp, r)) error(Enoattach); c = devtab[t]->attach(up->genbuf+n); break; default: c = up->dot; incref(c); break; } e.aname = aname; e.prefix = name - aname; e.name = nil; e.elems = nil; e.off = nil; e.nelems = 0; e.nerror = 0; if(waserror()){ cclose(c); free(e.name); free(e.elems); /* * Prepare nice error, showing first e.nerror elements of name. */ if(e.nerror == 0) nexterror(); if(e.off[e.nerror]==0) print("nerror=%d but off=%d\n", e.nerror, e.off[e.nerror]); len = e.prefix+e.off[e.nerror]; free(e.off); err = up->errstr; up->errstr = up->syserrstr; up->syserrstr = err; namelenerror(aname, len, err); } /* * Build a list of elements in the name. */ parsename(name, &e); /* * On create, .... */ if(amode == Acreate){ /* perm must have DMDIR if last element is / or /. */ if(e.mustbedir && !(perm&DMDIR)){ e.nerror = e.nelems; error("create without DMDIR"); } /* don't try to walk the last path element just yet. */ if(e.nelems == 0) error(Eexist); e.nelems--; } if(walk(&c, e.elems, e.nelems, nomount, &e.nerror) < 0){ if(e.nerror < 0 || e.nerror > e.nelems){ print("namec %s walk error nerror=%d\n", aname, e.nerror); e.nerror = 0; } nexterror(); } if(e.mustbedir && (c->qid.type&QTDIR) == 0) error("not a directory"); if(amode == Aopen && (omode&3) == OEXEC && (c->qid.type&QTDIR) != 0) error("cannot exec directory"); switch(amode){ case Abind: /* no need to maintain path - cannot dotdot an Abind */ m = nil; if(!nomount) domount(&c, &m, nil); if(waserror()){ putmhead(m); nexterror(); } c = cunique(c); c->umh = m; poperror(); break; case Aaccess: case Aremove: case Aopen: Open: /* save&update the name; domount might change c */ path = c->path; incref(path); if(waserror()){ pathclose(path); nexterror(); } m = nil; if(!nomount) domount(&c, &m, &path); if(waserror()){ putmhead(m); nexterror(); } /* our own copy to open or remove */ c = cunique(c); poperror(); /* now it's our copy anyway, we can put the name back */ pathclose(c->path); c->path = path; poperror(); /* record whether c is on a mount point */ c->ismtpt = m!=nil; switch(amode){ case Aaccess: case Aremove: putmhead(m); break; case Aopen: case Acreate: /* only save the mount head if it's a multiple element union */ if(m != nil) { rlock(&m->lock); if(m->mount != nil && m->mount->next != nil) { c->umh = m; runlock(&m->lock); } else { runlock(&m->lock); putmhead(m); } } /* save registers else error() in open has wrong value of c saved */ saveregisters(); c = devtab[c->type]->open(c, omode&~OCEXEC); if(omode & ORCLOSE) c->flag |= CRCLOSE; break; } break; case Atodir: /* * Directories (e.g. for cd) are left before the mount point, * so one may mount on / or . and see the effect. */ if((c->qid.type&QTDIR) == 0) error(Enotdir); break; case Amount: /* * When mounting on an already mounted upon directory, * one wants subsequent mounts to be attached to the * original directory, not the replacement. Don't domount. */ break; case Acreate: /* * We've already walked all but the last element. * If the last exists, try to open it OTRUNC. * If omode&OEXCL is set, just give up. */ e.nelems++; e.nerror++; if(walk(&c, e.elems+e.nelems-1, 1, nomount, nil) == 0){ if(omode&OEXCL) error(Eexist); omode |= OTRUNC; goto Open; } /* * The semantics of the create(2) system call are that if the * file exists and can be written, it is to be opened with truncation. * On the other hand, the create(5) message fails if the file exists. * If we get two create(2) calls happening simultaneously, * they might both get here and send create(5) messages, but only * one of the messages will succeed. To provide the expected create(2) * semantics, the call with the failed message needs to try the above * walk again, opening for truncation. This correctly solves the * create/create race, in the sense that any observable outcome can * be explained as one happening before the other. * The create/create race is quite common. For example, it happens * when two rc subshells simultaneously update the same * environment variable. * * The implementation still admits a create/create/remove race: * (A) walk to file, fails * (B) walk to file, fails * (A) create file, succeeds, returns * (B) create file, fails * (A) remove file, succeeds, returns * (B) walk to file, return failure. * * This is hardly as common as the create/create race, and is really * not too much worse than what might happen if (B) got a hold of a * file descriptor and then the file was removed -- either way (B) can't do * anything with the result of the create call. So we don't care about this race. * * Applications that care about more fine-grained decision of the races * can use the OEXCL flag to get at the underlying create(5) semantics; * by default we provide the common case. * * We need to stay behind the mount point in case we * need to do the first walk again (should the create fail). * * We also need to cross the mount point and find the directory * in the union in which we should be creating. * * The channel staying behind is c, the one moving forward is cnew. */ m = nil; cnew = nil; /* is this assignment necessary? */ if(!waserror()){ /* try create */ if(!nomount && findmount(&cnew, &m, c->type, c->dev, c->qid)) cnew = createdir(cnew, m); else{ cnew = c; incref(cnew); } /* * We need our own copy of the Chan because we're * about to send a create, which will move it. Once we have * our own copy, we can fix the name, which might be wrong * if findmount gave us a new Chan. */ cnew = cunique(cnew); pathclose(cnew->path); cnew->path = c->path; incref(cnew->path); cnew = devtab[cnew->type]->create(cnew, e.elems[e.nelems-1], omode&~(OEXCL|OCEXEC), perm); if(omode & ORCLOSE) cnew->flag |= CRCLOSE; poperror(); putmhead(m); cclose(c); c = cnew; c->path = addelem(c->path, e.elems[e.nelems-1], nil); break; } /* create failed */ cclose(cnew); putmhead(m); if(omode & OEXCL) nexterror(); /* save error */ err = up->errstr; up->errstr = up->syserrstr; up->syserrstr = err; /* note: we depend that walk does not error */ if(walk(&c, e.elems+e.nelems-1, 1, nomount, nil) < 0) error(err); /* report true error */ /* restore error */ err = up->syserrstr; up->syserrstr = up->errstr; up->errstr = err; omode |= OTRUNC; goto Open; default: panic("unknown namec access %d", amode); } /* place final element in genbuf for e.g. exec */ if(e.nelems > 0) kstrcpy(up->genbuf, e.elems[e.nelems-1], sizeof up->genbuf); else kstrcpy(up->genbuf, ".", sizeof up->genbuf); free(e.name); free(e.elems); free(e.off); poperror(); /* e c */ free(aname); poperror(); /* aname */ return c; } /* * name is valid. skip leading / and ./ as much as possible */ char* skipslash(char *name) { while(name[0]=='/' || (name[0]=='.' && (name[1]==0 || name[1]=='/'))) name++; return name; } char isfrog[256]={ /*NUL*/ 1, 1, 1, 1, 1, 1, 1, 1, /*BKS*/ 1, 1, 1, 1, 1, 1, 1, 1, /*DLE*/ 1, 1, 1, 1, 1, 1, 1, 1, /*CAN*/ 1, 1, 1, 1, 1, 1, 1, 1, ['/'] 1, [0x7f] 1, }; /* * Check that the name * a) is in valid memory. * b) is shorter than 2^16 bytes, so it can fit in a 9P string field. * c) contains no frogs. * The first byte is known to be addressible by the requester, so the * routine works for kernel and user memory both. * The parameter slashok flags whether a slash character is an error * or a valid character. * * The parameter dup flags whether the string should be copied * out of user space before being scanned the second time. * (Otherwise a malicious thread could remove the NUL, causing us * to access unchecked addresses.) */ static char* validname0(char *aname, int slashok, int dup, uintptr pc) { char *ename, *name, *s; int c, n; Rune r; name = aname; if((uintptr)name < KZERO){ if(!dup) print("warning: validname called from %#p with user pointer", pc); ename = vmemchr(name, 0, (1<<16)); }else ename = memchr(name, 0, (1<<16)); if(ename==nil || ename-name>=(1<<16)) error(Etoolong); s = nil; if(dup){ n = ename-name; s = smalloc(n+1); memmove(s, name, n); s[n] = 0; aname = s; name = s; setmalloctag(s, pc); } while(*name){ /* all characters above '~' are ok */ c = *(uchar*)name; if(c >= Runeself) name += chartorune(&r, name); else{ if(isfrog[c]) if(!slashok || c!='/'){ snprint(up->genbuf, sizeof(up->genbuf), "%s: %q", Ebadchar, aname); free(s); error(up->genbuf); } name++; } } return s; } void validname(char *aname, int slashok) { validname0(aname, slashok, 0, getcallerpc(&aname)); } char* validnamedup(char *aname, int slashok) { return validname0(aname, slashok, 1, getcallerpc(&aname)); } void isdir(Chan *c) { if(c->qid.type & QTDIR) return; error(Enotdir); } enum { DIRSIZE = STATFIXLEN + 16 * 4 /* enough for encoded stat buf + some reasonable strings */ }; Dir* dirchanstat(Chan *c) { Dir *d; uchar *buf; int n, nd, i; nd = DIRSIZE; for(i=0; i<2; i++){ /* should work by the second try */ d = smalloc(sizeof(Dir) + BIT16SZ + nd); if(waserror()){ free(d); nexterror(); } buf = (uchar*)&d[1]; n = devtab[c->type]->stat(c, buf, BIT16SZ+nd); if(n < BIT16SZ) error(Eshortstat); nd = GBIT16(buf); /* upper bound on size of Dir + strings */ if(nd <= n){ if(convM2D(buf, n, d, (char*)&d[1]) == 0) error(Eshortstat); poperror(); return d; } /* else sizeof(Dir)+BIT16SZ+nd is plenty */ free(d); poperror(); } error(Eshortstat); return nil; }