/** \ingroup rpmdep * \file lib/rpmte.c * Routine(s) to handle an "rpmte" transaction element. */ #include "system.h" #include #include #include #define _RPMTE_INTERNAL #include #include #include "debug.h" int _rpmte_debug = 0; void rpmteCleanDS(rpmte te) { te->this = rpmdsFree(te->this); te->provides = rpmdsFree(te->provides); te->requires = rpmdsFree(te->requires); te->conflicts = rpmdsFree(te->conflicts); te->obsoletes = rpmdsFree(te->obsoletes); } /** * Destroy transaction element data. * @param p transaction element */ static void delTE(rpmte p) { rpmRelocation * r; if (p->relocs) { for (r = p->relocs; (r->oldPath || r->newPath); r++) { r->oldPath = _free(r->oldPath); r->newPath = _free(r->newPath); } p->relocs = _free(p->relocs); } rpmteCleanDS(p); p->fi = rpmfiFree(p->fi); if (p->fd != NULL) p->fd = fdFree(p->fd, "delTE"); p->os = _free(p->os); p->arch = _free(p->arch); p->epoch = _free(p->epoch); p->name = _free(p->name); p->NEVR = _free(p->NEVR); p->NEVRA = _free(p->NEVRA); p->h = headerFree(p->h); memset(p, 0, sizeof(*p)); /* XXX trash and burn */ /* FIX: p->{NEVR,name} annotations */ return; } /** * Initialize transaction element data from header. * @param ts transaction set * @param p transaction element * @param h header * @param key (TR_ADDED) package retrieval key (e.g. file name) * @param relocs (TR_ADDED) package file relocations */ static void addTE(rpmts ts, rpmte p, Header h, fnpyKey key, rpmRelocation * relocs) { int scareMem = 0; HGE_t hge = (HGE_t)headerGetEntryMinMemory; rpmte savep; int32_t * ep; const char * arch, * os; char * t; size_t nb; int xx; p->NEVR = hGetNEVR(h, NULL); p->name = xstrdup(p->NEVR); if ((p->release = strrchr(p->name, '-')) != NULL) *p->release++ = '\0'; if ((p->version = strrchr(p->name, '-')) != NULL) *p->version++ = '\0'; /* Set db_instance to 0 as it has not been installed * necessarily yet. */ p->db_instance = 0; arch = NULL; xx = hge(h, RPMTAG_ARCH, NULL, (void **)&arch, NULL); if (arch != NULL) { p->arch = xstrdup(arch); p->archScore = rpmMachineScore(RPM_MACHTABLE_INSTARCH, arch); } else { p->arch = NULL; p->archScore = 0; } os = NULL; xx = hge(h, RPMTAG_OS, NULL, (void **)&os, NULL); if (os != NULL) { p->os = xstrdup(os); p->osScore = rpmMachineScore(RPM_MACHTABLE_INSTOS, os); } else { p->os = NULL; p->osScore = 0; } p->isSource = headerIsEntry(h, RPMTAG_SOURCEPACKAGE); nb = strlen(p->NEVR) + 1; if (p->isSource) nb += sizeof("src"); else if (p->arch) nb += strlen(p->arch) + 1; t = xmalloc(nb); p->NEVRA = t; *t = '\0'; t = stpcpy(t, p->NEVR); if (p->isSource) t = stpcpy( t, ".src"); else if (p->arch) t = stpcpy( stpcpy( t, "."), p->arch); ep = NULL; xx = hge(h, RPMTAG_EPOCH, NULL, (void **)&ep, NULL); if (ep) { p->epoch = xmalloc(20); sprintf(p->epoch, "%d", *ep); } else p->epoch = NULL; p->nrelocs = 0; p->relocs = NULL; if (relocs != NULL) { rpmRelocation * r; int i; for (r = relocs; r->oldPath || r->newPath; r++) p->nrelocs++; p->relocs = xmalloc((p->nrelocs + 1) * sizeof(*p->relocs)); for (i = 0, r = relocs; r->oldPath || r->newPath; i++, r++) { p->relocs[i].oldPath = r->oldPath ? xstrdup(r->oldPath) : NULL; p->relocs[i].newPath = r->newPath ? xstrdup(r->newPath) : NULL; } p->relocs[i].oldPath = NULL; p->relocs[i].newPath = NULL; } p->autorelocatex = -1; p->key = key; p->fd = NULL; p->pkgFileSize = 0; p->this = rpmdsThis(h, RPMTAG_PROVIDENAME, RPMSENSE_EQUAL); p->provides = rpmdsNew(h, RPMTAG_PROVIDENAME, scareMem); p->requires = rpmdsNew(h, RPMTAG_REQUIRENAME, scareMem); p->conflicts = rpmdsNew(h, RPMTAG_CONFLICTNAME, scareMem); p->obsoletes = rpmdsNew(h, RPMTAG_OBSOLETENAME, scareMem); savep = rpmtsSetRelocateElement(ts, p); p->fi = rpmfiNew(ts, h, RPMTAG_BASENAMES, scareMem); (void) rpmtsSetRelocateElement(ts, savep); rpmteColorDS(p, RPMTAG_PROVIDENAME); rpmteColorDS(p, RPMTAG_REQUIRENAME); return; } rpmte rpmteFree(rpmte te) { if (te != NULL) { delTE(te); memset(te, 0, sizeof(*te)); /* XXX trash and burn */ te = _free(te); } return NULL; } rpmte rpmteNew(const rpmts ts, Header h, rpmElementType type, fnpyKey key, rpmRelocation * relocs, int dboffset, rpmalKey pkgKey) { rpmte p = xcalloc(1, sizeof(*p)); int32_t * ep; int xx; p->type = type; addTE(ts, p, h, key, relocs); switch (type) { case TR_ADDED: p->u.addedKey = pkgKey; ep = NULL; xx = headerGetEntry(h, RPMTAG_SIGSIZE, NULL, (void **)&ep, NULL); /* XXX 256 is only an estimate of signature header. */ if (ep != NULL) p->pkgFileSize += 96 + 256 + *ep; break; case TR_REMOVED: p->u.removed.dependsOnKey = pkgKey; p->u.removed.dboffset = dboffset; break; } return p; } /* Get the DB Instance value */ unsigned int rpmteDBInstance(rpmte te) { return (te != NULL ? te->db_instance : 0); } /* Set the DB Instance value */ void rpmteSetDBInstance(rpmte te, unsigned int instance) { if (te != NULL) te->db_instance = instance; } Header rpmteHeader(rpmte te) { return (te != NULL && te->h != NULL ? headerLink(te->h) : NULL); } Header rpmteSetHeader(rpmte te, Header h) { if (te != NULL) { te->h = headerFree(te->h); if (h != NULL) te->h = headerLink(h); } return NULL; } rpmElementType rpmteType(rpmte te) { return (te != NULL ? te->type : -1); } const char * rpmteN(rpmte te) { return (te != NULL ? te->name : NULL); } const char * rpmteE(rpmte te) { return (te != NULL ? te->epoch : NULL); } const char * rpmteV(rpmte te) { return (te != NULL ? te->version : NULL); } const char * rpmteR(rpmte te) { return (te != NULL ? te->release : NULL); } const char * rpmteA(rpmte te) { return (te != NULL ? te->arch : NULL); } const char * rpmteO(rpmte te) { return (te != NULL ? te->os : NULL); } int rpmteIsSource(rpmte te) { return (te != NULL ? te->isSource : 0); } uint32_t rpmteColor(rpmte te) { return (te != NULL ? te->color : 0); } uint32_t rpmteSetColor(rpmte te, uint32_t color) { int ocolor = 0; if (te != NULL) { ocolor = te->color; te->color = color; } return ocolor; } uint32_t rpmtePkgFileSize(rpmte te) { return (te != NULL ? te->pkgFileSize : 0); } int rpmteDepth(rpmte te) { return (te != NULL ? te->depth : 0); } int rpmteSetDepth(rpmte te, int ndepth) { int odepth = 0; if (te != NULL) { odepth = te->depth; te->depth = ndepth; } return odepth; } int rpmteBreadth(rpmte te) { return (te != NULL ? te->depth : 0); } int rpmteSetBreadth(rpmte te, int nbreadth) { int obreadth = 0; if (te != NULL) { obreadth = te->breadth; te->breadth = nbreadth; } return obreadth; } int rpmteNpreds(rpmte te) { return (te != NULL ? te->npreds : 0); } int rpmteSetNpreds(rpmte te, int npreds) { int opreds = 0; if (te != NULL) { opreds = te->npreds; te->npreds = npreds; } return opreds; } int rpmteTree(rpmte te) { return (te != NULL ? te->tree : 0); } int rpmteSetTree(rpmte te, int ntree) { int otree = 0; if (te != NULL) { otree = te->tree; te->tree = ntree; } return otree; } rpmte rpmteParent(rpmte te) { return (te != NULL ? te->parent : NULL); } rpmte rpmteSetParent(rpmte te, rpmte pte) { rpmte opte = NULL; if (te != NULL) { opte = te->parent; te->parent = pte; } return opte; } int rpmteDegree(rpmte te) { return (te != NULL ? te->degree : 0); } int rpmteSetDegree(rpmte te, int ndegree) { int odegree = 0; if (te != NULL) { odegree = te->degree; te->degree = ndegree; } return odegree; } tsortInfo rpmteTSI(rpmte te) { return te->tsi; } void rpmteFreeTSI(rpmte te) { if (te != NULL && rpmteTSI(te) != NULL) { tsortInfo tsi; /* Clean up tsort remnants (if any). */ while ((tsi = rpmteTSI(te)->tsi_next) != NULL) { rpmteTSI(te)->tsi_next = tsi->tsi_next; tsi->tsi_next = NULL; tsi = _free(tsi); } te->tsi = _free(te->tsi); } /* FIX: te->tsi is NULL */ return; } void rpmteNewTSI(rpmte te) { if (te != NULL) { rpmteFreeTSI(te); te->tsi = xcalloc(1, sizeof(*te->tsi)); } } rpmalKey rpmteAddedKey(rpmte te) { return (te != NULL ? te->u.addedKey : RPMAL_NOMATCH); } rpmalKey rpmteSetAddedKey(rpmte te, rpmalKey npkgKey) { rpmalKey opkgKey = RPMAL_NOMATCH; if (te != NULL) { opkgKey = te->u.addedKey; te->u.addedKey = npkgKey; } return opkgKey; } rpmalKey rpmteDependsOnKey(rpmte te) { return (te != NULL ? te->u.removed.dependsOnKey : RPMAL_NOMATCH); } int rpmteDBOffset(rpmte te) { return (te != NULL ? te->u.removed.dboffset : 0); } const char * rpmteNEVR(rpmte te) { return (te != NULL ? te->NEVR : NULL); } const char * rpmteNEVRA(rpmte te) { return (te != NULL ? te->NEVRA : NULL); } FD_t rpmteFd(rpmte te) { return (te != NULL ? te->fd : NULL); } fnpyKey rpmteKey(rpmte te) { return (te != NULL ? te->key : NULL); } rpmds rpmteDS(rpmte te, rpmTag tag) { if (te == NULL) return NULL; if (tag == RPMTAG_NAME) return te->this; else if (tag == RPMTAG_PROVIDENAME) return te->provides; else if (tag == RPMTAG_REQUIRENAME) return te->requires; else if (tag == RPMTAG_CONFLICTNAME) return te->conflicts; else if (tag == RPMTAG_OBSOLETENAME) return te->obsoletes; else return NULL; } rpmfi rpmteFI(rpmte te, rpmTag tag) { if (te == NULL) return NULL; if (tag == RPMTAG_BASENAMES) return te->fi; else return NULL; } void rpmteColorDS(rpmte te, rpmTag tag) { rpmfi fi = rpmteFI(te, RPMTAG_BASENAMES); rpmds ds = rpmteDS(te, tag); char deptype = 'R'; char mydt; const uint32_t * ddict; int32_t * colors; int32_t * refs; int32_t val; int Count; size_t nb; unsigned ix; int ndx, i; if (!(te && (Count = rpmdsCount(ds)) > 0 && rpmfiFC(fi) > 0)) return; switch (tag) { default: return; break; case RPMTAG_PROVIDENAME: deptype = 'P'; break; case RPMTAG_REQUIRENAME: deptype = 'R'; break; } nb = Count * sizeof(*colors); colors = memset(alloca(nb), 0, nb); nb = Count * sizeof(*refs); refs = memset(alloca(nb), -1, nb); /* Calculate dependency color and reference count. */ fi = rpmfiInit(fi, 0); if (fi != NULL) while (rpmfiNext(fi) >= 0) { val = rpmfiFColor(fi); ddict = NULL; ndx = rpmfiFDepends(fi, &ddict); if (ddict != NULL) while (ndx-- > 0) { ix = *ddict++; mydt = ((ix >> 24) & 0xff); if (mydt != deptype) continue; ix &= 0x00ffffff; assert (ix < Count); colors[ix] |= val; refs[ix]++; } } /* Set color/refs values in dependency set. */ ds = rpmdsInit(ds); while ((i = rpmdsNext(ds)) >= 0) { val = colors[i]; te->color |= val; (void) rpmdsSetColor(ds, val); val = refs[i]; if (val >= 0) val++; (void) rpmdsSetRefs(ds, val); } } int rpmtsiOc(rpmtsi tsi) { return tsi->ocsave; } rpmtsi XrpmtsiFree(rpmtsi tsi, const char * fn, unsigned int ln) { /* XXX watchout: a funky recursion segfaults here iff nrefs is wrong. */ if (tsi) tsi->ts = rpmtsFree(tsi->ts); if (_rpmte_debug) fprintf(stderr, "*** tsi %p -- %s:%d\n", tsi, fn, ln); return _free(tsi); } rpmtsi XrpmtsiInit(rpmts ts, const char * fn, unsigned int ln) { rpmtsi tsi = NULL; tsi = xcalloc(1, sizeof(*tsi)); tsi->ts = rpmtsLink(ts, "rpmtsi"); tsi->reverse = ((rpmtsFlags(ts) & RPMTRANS_FLAG_REVERSE) ? 1 : 0); tsi->oc = (tsi->reverse ? (rpmtsNElements(ts) - 1) : 0); tsi->ocsave = tsi->oc; if (_rpmte_debug) fprintf(stderr, "*** tsi %p ++ %s:%d\n", tsi, fn, ln); return tsi; } /** * Return next transaction element. * @param tsi transaction element iterator * @return transaction element, NULL on termination */ static rpmte rpmtsiNextElement(rpmtsi tsi) { rpmte te = NULL; int oc = -1; if (tsi == NULL || tsi->ts == NULL || rpmtsNElements(tsi->ts) <= 0) return te; if (tsi->reverse) { if (tsi->oc >= 0) oc = tsi->oc--; } else { if (tsi->oc < rpmtsNElements(tsi->ts)) oc = tsi->oc++; } tsi->ocsave = oc; if (oc != -1) te = rpmtsElement(tsi->ts, oc); return te; } rpmte rpmtsiNext(rpmtsi tsi, rpmElementType type) { rpmte te; while ((te = rpmtsiNextElement(tsi)) != NULL) { if (type == 0 || (te->type & type) != 0) break; } return te; }