/* * Copyright (c) 2007-2009, Novell Inc. * * This program is licensed under the BSD license, read LICENSE.BSD * for further information */ /* * rules.c * * SAT based dependency solver */ #include #include #include #include #include #include "solver.h" #include "solver_private.h" #include "bitmap.h" #include "pool.h" #include "poolarch.h" #include "util.h" #include "evr.h" #include "policy.h" #include "solverdebug.h" #include "linkedpkg.h" #include "cplxdeps.h" #define RULES_BLOCK 63 static void addpkgruleinfo(Solver *solv, Id p, Id p2, Id d, int type, Id dep); static void solver_createcleandepsmap(Solver *solv, Map *cleandepsmap, int unneeded); /*------------------------------------------------------------------- * Check if dependency is possible * * mirrors solver_dep_fulfilled but uses map m instead of the decisionmap. * used in solver_addpkgrulesforweak and solver_createcleandepsmap. */ static inline int dep_possible(Solver *solv, Id dep, Map *m) { Pool *pool = solv->pool; Id p, pp; if (ISRELDEP(dep)) { Reldep *rd = GETRELDEP(pool, dep); if (rd->flags >= 8) { if (rd->flags == REL_COND) return 1; if (rd->flags == REL_AND) { if (!dep_possible(solv, rd->name, m)) return 0; return dep_possible(solv, rd->evr, m); } if (rd->flags == REL_OR) { if (dep_possible(solv, rd->name, m)) return 1; return dep_possible(solv, rd->evr, m); } if (rd->flags == REL_NAMESPACE && rd->name == NAMESPACE_SPLITPROVIDES) return solver_splitprovides(solv, rd->evr, m); } } FOR_PROVIDES(p, pp, dep) { if (MAPTST(m, p)) return 1; } return 0; } static inline int is_otherproviders_dep(Pool *pool, Id dep) { if (ISRELDEP(dep)) { Reldep *rd = GETRELDEP(pool, dep); if (rd->flags == REL_NAMESPACE && rd->name == NAMESPACE_OTHERPROVIDERS) return 1; } return 0; } /******************************************************************** * * Rule handling * * - unify rules, remove duplicates */ /*------------------------------------------------------------------- * * compare rules for unification sort * */ static int unifyrules_sortcmp(const void *ap, const void *bp, void *dp) { Pool *pool = dp; Rule *a = (Rule *)ap; Rule *b = (Rule *)bp; Id *ad, *bd; int x; x = a->p - b->p; if (x) return x; /* p differs */ /* identical p */ if (a->d == 0 && b->d == 0) return a->w2 - b->w2; /* assertion: return w2 diff */ if (a->d == 0) /* a is assertion, b not */ { x = a->w2 - pool->whatprovidesdata[b->d]; return x ? x : -1; } if (b->d == 0) /* b is assertion, a not */ { x = pool->whatprovidesdata[a->d] - b->w2; return x ? x : 1; } /* compare whatprovidesdata */ ad = pool->whatprovidesdata + a->d; bd = pool->whatprovidesdata + b->d; while (*bd) if ((x = *ad++ - *bd++) != 0) return x; return *ad; } int solver_rulecmp(Solver *solv, Rule *r1, Rule *r2) { return unifyrules_sortcmp(r1, r2, solv->pool); } /*------------------------------------------------------------------- * * unify rules * go over all rules and remove duplicates */ void solver_unifyrules(Solver *solv) { Pool *pool = solv->pool; int i, j; Rule *ir, *jr; if (solv->nrules <= 2) /* nothing to unify */ return; /* sort rules first */ solv_sort(solv->rules + 1, solv->nrules - 1, sizeof(Rule), unifyrules_sortcmp, solv->pool); /* prune rules * i = unpruned * j = pruned */ jr = 0; for (i = j = 1, ir = solv->rules + i; i < solv->nrules; i++, ir++) { if (jr && !unifyrules_sortcmp(ir, jr, pool)) continue; /* prune! */ jr = solv->rules + j++; /* keep! */ if (ir != jr) *jr = *ir; } /* reduced count from nrules to j rules */ POOL_DEBUG(SOLV_DEBUG_STATS, "pruned rules from %d to %d\n", solv->nrules, j); /* adapt rule buffer */ solv->nrules = j; solv->rules = solv_extend_resize(solv->rules, solv->nrules, sizeof(Rule), RULES_BLOCK); /* * debug: log rule statistics */ IF_POOLDEBUG (SOLV_DEBUG_STATS) { int binr = 0; int lits = 0; Id *dp; Rule *r; for (i = 1; i < solv->nrules; i++) { r = solv->rules + i; if (r->d == 0) binr++; else { dp = solv->pool->whatprovidesdata + r->d; while (*dp++) lits++; } } POOL_DEBUG(SOLV_DEBUG_STATS, " binary: %d\n", binr); POOL_DEBUG(SOLV_DEBUG_STATS, " normal: %d, %d literals\n", solv->nrules - 1 - binr, lits); } } #if 0 /* * hash rule */ static Hashval hashrule(Solver *solv, Id p, Id d, int n) { unsigned int x = (unsigned int)p; int *dp; if (n <= 1) return (x * 37) ^ (unsigned int)d; dp = solv->pool->whatprovidesdata + d; while (*dp) x = (x * 37) ^ (unsigned int)*dp++; return x; } #endif /*------------------------------------------------------------------- * */ /* * add rule * * A requires b, b provided by B1,B2,B3 => (-A|B1|B2|B3) * * p < 0 : pkg id of A * d > 0 : Offset in whatprovidesdata (list of providers of b) * * A conflicts b, b provided by B1,B2,B3 => (-A|-B1), (-A|-B2), (-A|-B3) * p < 0 : pkg id of A * p2 < 0 : Id of solvable (e.g. B1) * * d == 0, p2 == 0: unary rule, assertion => (A) or (-A) * * Install: p > 0, d = 0 (A) user requested install * Remove: p < 0, d = 0 (-A) user requested remove (also: uninstallable) * Requires: p < 0, d > 0 (-A|B1|B2|...) d: * Updates: p > 0, d > 0 (A|B1|B2|...) d: * Conflicts: p < 0, p2 < 0 (-A|-B) either p (conflict issuer) or d (conflict provider) (binary rule) * also used for obsoletes * No-op ?: p = 0, d = 0 (null) (used as placeholder in update/feature rules) * * resulting watches: * ------------------ * Direct assertion (no watch needed) --> d = 0, w1 = p, w2 = 0 * Binary rule: p = first literal, d = 0, w2 = second literal, w1 = p * every other : w1 = p, w2 = whatprovidesdata[d]; * * always returns a rule for non-pkg rules */ Rule * solver_addrule(Solver *solv, Id p, Id p2, Id d) { Pool *pool = solv->pool; Rule *r; if (d) { assert(!p2 && d > 0); if (!pool->whatprovidesdata[d]) d = 0; else if (!pool->whatprovidesdata[d + 1]) { p2 = pool->whatprovidesdata[d]; d = 0; } } /* now we have two cases: * 1 or 2 literals: d = 0, p, p2 contain the literals * 3 or more literals: d > 0, p2 == 0, d is offset into whatprovidesdata */ /* it often happenes that requires lead to adding the same pkg rule * multiple times, so we prune those duplicates right away to make * the work for unifyrules a bit easier */ if (!solv->pkgrules_end) /* we add pkg rules */ { r = solv->rules + solv->nrules - 1; if (d) { Id *dp; /* check if rule is identical */ if (r->p == p) { Id *dp2; if (r->d == d) return r; dp2 = pool->whatprovidesdata + r->d; for (dp = pool->whatprovidesdata + d; *dp; dp++, dp2++) if (*dp != *dp2) break; if (*dp == *dp2) return r; } /* check if rule is self-fulfilling */ for (dp = pool->whatprovidesdata + d; *dp; dp++) if (*dp == -p) return 0; /* rule is self-fulfilling */ } else { if (p2 && p > p2) { Id o = p; /* switch p1 and p2 */ p = p2; p2 = o; } if (r->p == p && !r->d && r->w2 == p2) return r; if (p == -p2) return 0; /* rule is self-fulfilling */ } } solv->rules = solv_extend(solv->rules, solv->nrules, 1, sizeof(Rule), RULES_BLOCK); r = solv->rules + solv->nrules++; /* point to rule space */ r->p = p; r->d = d; r->w1 = p; r->w2 = d ? pool->whatprovidesdata[d] : p2; r->n1 = 0; r->n2 = 0; IF_POOLDEBUG (SOLV_DEBUG_RULE_CREATION) { POOL_DEBUG(SOLV_DEBUG_RULE_CREATION, " Add rule: "); solver_printrule(solv, SOLV_DEBUG_RULE_CREATION, r); } return r; } void solver_shrinkrules(Solver *solv, int nrules) { solv->nrules = nrules; solv->rules = solv_extend_resize(solv->rules, solv->nrules, sizeof(Rule), RULES_BLOCK); } /****************************************************************************** *** *** pkg rule part: create rules representing the package dependencies *** ***/ /* * special multiversion patch conflict handling: * a patch conflict is also satisfied if some other * version with the same name/arch that doesn't conflict * gets installed. The generated rule is thus: * -patch|-cpack|opack1|opack2|... */ static Id makemultiversionconflict(Solver *solv, Id n, Id con) { Pool *pool = solv->pool; Solvable *s, *sn; Queue q; Id p, pp, qbuf[64]; sn = pool->solvables + n; queue_init_buffer(&q, qbuf, sizeof(qbuf)/sizeof(*qbuf)); queue_push(&q, -n); FOR_PROVIDES(p, pp, sn->name) { s = pool->solvables + p; if (s->name != sn->name || s->arch != sn->arch) continue; if (!MAPTST(&solv->multiversion, p)) continue; if (pool_match_nevr(pool, pool->solvables + p, con)) continue; /* here we have a multiversion solvable that doesn't conflict */ /* thus we're not in conflict if it is installed */ queue_push(&q, p); } if (q.count == 1) n = 0; /* no other package found, normal conflict handling */ else n = pool_queuetowhatprovides(pool, &q); queue_free(&q); return n; } static inline void addpkgrule(Solver *solv, Id p, Id p2, Id d, int type, Id dep) { if (!solv->ruleinfoq) solver_addrule(solv, p, p2, d); else addpkgruleinfo(solv, p, p2, d, type, dep); } #ifdef ENABLE_LINKED_PKGS static void addlinks(Solver *solv, Solvable *s, Id req, Queue *qr, Id prv, Queue *qp, Map *m, Queue *workq) { Pool *pool = solv->pool; int i; if (!qr->count) return; #if 0 printf("ADDLINKS %s\n -> %s\n", pool_solvable2str(pool, s), pool_dep2str(pool, req)); for (i = 0; i < qr->count; i++) printf(" - %s\n", pool_solvid2str(pool, qr->elements[i])); printf(" <- %s\n", pool_dep2str(pool, prv)); for (i = 0; i < qp->count; i++) printf(" - %s\n", pool_solvid2str(pool, qp->elements[i])); #endif if (qr->count == 1) addpkgrule(solv, -(s - pool->solvables), qr->elements[0], 0, SOLVER_RULE_PKG_REQUIRES, req); else addpkgrule(solv, -(s - pool->solvables), 0, pool_queuetowhatprovides(pool, qr), SOLVER_RULE_PKG_REQUIRES, req); if (qp->count > 1) { Id d = pool_queuetowhatprovides(pool, qp); for (i = 0; i < qr->count; i++) addpkgrule(solv, -qr->elements[i], 0, d, SOLVER_RULE_PKG_REQUIRES, prv); } else if (qp->count) { for (i = 0; i < qr->count; i++) addpkgrule(solv, -qr->elements[i], qp->elements[0], 0, SOLVER_RULE_PKG_REQUIRES, prv); } if (!m) return; /* nothing more to do if called from getpkgruleinfos() */ for (i = 0; i < qr->count; i++) if (!MAPTST(m, qr->elements[i])) queue_push(workq, qr->elements[i]); for (i = 0; i < qp->count; i++) if (!MAPTST(m, qp->elements[i])) queue_push(workq, qp->elements[i]); if (solv->installed && s->repo == solv->installed) { Repo *installed = solv->installed; /* record installed buddies */ if (!solv->instbuddy) solv->instbuddy = solv_calloc(installed->end - installed->start, sizeof(Id)); if (qr->count == 1) solv->instbuddy[s - pool->solvables - installed->start] = qr->elements[0]; for (i = 0; i < qr->count; i++) { Id p = qr->elements[i]; if (pool->solvables[p].repo != installed) continue; /* huh? */ if (qp->count > 1 || (solv->instbuddy[p - installed->start] != 0 && solv->instbuddy[p - installed->start] != s - pool->solvables)) solv->instbuddy[p - installed->start] = 1; /* 1: ambiguous buddy */ else solv->instbuddy[p - installed->start] = s - pool->solvables; } } } static void add_package_link(Solver *solv, Solvable *s, Map *m, Queue *workq) { Queue qr, qp; Id req = 0, prv = 0; queue_init(&qr); queue_init(&qp); find_package_link(solv->pool, s, &req, &qr, &prv, &qp); if (qr.count) addlinks(solv, s, req, &qr, prv, &qp, m, workq); queue_free(&qr); queue_free(&qp); } #endif #ifdef ENABLE_COMPLEX_DEPS static void add_complex_deprules(Solver *solv, Id p, Id dep, int type, int dontfix, Queue *workq, Map *m) { Pool *pool = solv->pool; Repo *installed = solv->installed; int i, j, flags; Queue bq; queue_init(&bq); flags = dontfix ? CPLXDEPS_DONTFIX : 0; /* CNF expansion for requires, DNF + INVERT expansion for conflicts */ if (type == SOLVER_RULE_PKG_CONFLICTS) flags |= CPLXDEPS_TODNF | CPLXDEPS_EXPAND | CPLXDEPS_INVERT; i = pool_normalize_complex_dep(pool, dep, &bq, flags); /* handle special cases */ if (i == 0) { if (dontfix) { POOL_DEBUG(SOLV_DEBUG_RULE_CREATION, "ignoring broken dependency %s of installed package %s\n", pool_dep2str(pool, dep), pool_solvid2str(pool, p)); } else { POOL_DEBUG(SOLV_DEBUG_RULE_CREATION, "package %s [%d] is not installable (%s)\n", pool_solvid2str(pool, p), p, pool_dep2str(pool, dep)); addpkgrule(solv, -p, 0, 0, type == SOLVER_RULE_PKG_REQUIRES ? SOLVER_RULE_PKG_NOTHING_PROVIDES_DEP : type, dep); } queue_free(&bq); return; } if (i == 1) { queue_free(&bq); return; } /* go through all blocks and add a rule for each block */ for (i = 0; i < bq.count; i++) { if (!bq.elements[i]) continue; /* huh? */ if (bq.elements[i] == pool->nsolvables) { /* conventional requires (cannot be a conflicts as they have been expanded) */ Id *dp = pool->whatprovidesdata + bq.elements[i + 1]; i += 2; if (dontfix) { for (j = 0; dp[j] != 0; j++) if (pool->solvables[dp[j]].repo == installed) break; /* provider was installed */ if (!dp[j]) continue; } /* check if the rule contains both p and -p */ for (j = 0; dp[j] != 0; j++) if (dp[j] == p) break; if (dp[j]) continue; addpkgrule(solv, -p, 0, dp - pool->whatprovidesdata, SOLVER_RULE_PKG_REQUIRES, dep); /* push all non-visited providers on the work queue */ if (m) for (; *dp; dp++) if (!MAPTST(m, *dp)) queue_push(workq, *dp); continue; } if (!bq.elements[i + 1]) { Id p2 = bq.elements[i++]; /* simple rule with just two literals, we'll add a (-p, p2) rule */ if (dontfix) { if (p2 < 0 && pool->solvables[-p2].repo == installed) continue; if (p2 > 0 && pool->solvables[p2].repo != installed) continue; } if (-p == p2) { if (type == SOLVER_RULE_PKG_CONFLICTS) { if (pool->forbidselfconflicts && !is_otherproviders_dep(pool, dep)) addpkgrule(solv, -p, 0, 0, SOLVER_RULE_PKG_SELF_CONFLICT, dep); continue; } addpkgrule(solv, -p, 0, 0, type, dep); continue; } /* check if the rule contains both p and -p */ if (p == p2) continue; addpkgrule(solv, -p, p2, 0, type, dep); if (m && p2 > 0 && !MAPTST(m, p2)) queue_push(workq, p2); } else { Id *qele; int qcnt; qele = bq.elements + i; qcnt = i; while (bq.elements[i]) i++; qcnt = i - qcnt; if (dontfix) { for (j = 0; j < qcnt; j++) { if (qele[j] > 0 && pool->solvables[qele[j]].repo == installed) break; if (qele[j] < 0 && pool->solvables[-qele[j]].repo != installed) break; } if (j == qcnt) continue; } /* add -p to (ordered) rule (overwriting the trailing zero) */ for (j = 0; ; j++) { if (j == qcnt || qele[j] > -p) { if (j < qcnt) memmove(qele + j + 1, qele + j, (qcnt - j) * sizeof(Id)); qele[j] = -p; qcnt++; break; } if (qele[j] == -p) break; } /* check if the rule contains both p and -p */ for (j = 0; j < qcnt; j++) if (qele[j] == p) break; if (j < qcnt) continue; addpkgrule(solv, qele[0], 0, pool_ids2whatprovides(pool, qele + 1, qcnt - 1), type, dep); if (m) for (j = 0; j < qcnt; j++) if (qele[j] > 0 && !MAPTST(m, qele[j])) queue_push(workq, qele[j]); } } queue_free(&bq); } #endif /*------------------------------------------------------------------- * * add (install) rules for solvable * * s: Solvable for which to add rules * m: m[s] = 1 for solvables which have rules, prevent rule duplication * * Algorithm: 'visit all nodes of a graph'. The graph nodes are * solvables, the edges their dependencies. * Starting from an installed solvable, this will create all rules * representing the graph created by the solvables dependencies. * * for unfulfilled requirements, conflicts, obsoletes,.... * add a negative assertion for solvables that are not installable * * It will also create rules for all solvables referenced by 's' * i.e. descend to all providers of requirements of 's' * */ void solver_addpkgrulesforsolvable(Solver *solv, Solvable *s, Map *m) { Pool *pool = solv->pool; Repo *installed = solv->installed; Queue workq; /* list of solvables we still have to work on */ Id workqbuf[64]; int i; int dontfix; /* ignore dependency errors for installed solvables */ Id req, *reqp; Id con, *conp; Id obs, *obsp; Id rec, *recp; Id sug, *sugp; Id p, pp; /* whatprovides loops */ Id *dp; /* ptr to 'whatprovides' */ Id n; /* Id for current solvable 's' */ queue_init_buffer(&workq, workqbuf, sizeof(workqbuf)/sizeof(*workqbuf)); queue_push(&workq, s - pool->solvables); /* push solvable Id to work queue */ /* loop until there's no more work left */ while (workq.count) { /* * n: Id of solvable * s: Pointer to solvable */ n = queue_shift(&workq); /* 'pop' next solvable to work on from queue */ if (m) { if (MAPTST(m, n)) /* continue if already visited */ continue; MAPSET(m, n); /* mark as visited */ } s = pool->solvables + n; dontfix = 0; if (installed /* Installed system available */ && s->repo == installed /* solvable is installed */ && !solv->fixmap_all /* NOT repair errors in dependency graph */ && !(solv->fixmap.size && MAPTST(&solv->fixmap, n - installed->start))) { dontfix = 1; /* dont care about broken deps */ } if (!dontfix) { if (s->arch == ARCH_SRC || s->arch == ARCH_NOSRC ? pool_disabled_solvable(pool, s) : !pool_installable(pool, s)) { POOL_DEBUG(SOLV_DEBUG_RULE_CREATION, "package %s [%d] is not installable\n", pool_solvid2str(pool, n), n); addpkgrule(solv, -n, 0, 0, SOLVER_RULE_PKG_NOT_INSTALLABLE, 0); } } #ifdef ENABLE_LINKED_PKGS /* add pseudo-package <-> real-package links */ if (has_package_link(pool, s)) add_package_link(solv, s, m, &workq); #endif /*----------------------------------------- * check requires of s */ if (s->requires) { reqp = s->repo->idarraydata + s->requires; while ((req = *reqp++) != 0) /* go through all requires */ { if (req == SOLVABLE_PREREQMARKER) /* skip the marker */ continue; #ifdef ENABLE_COMPLEX_DEPS if (pool_is_complex_dep(pool, req)) { /* we have AND/COND deps, normalize */ add_complex_deprules(solv, n, req, SOLVER_RULE_PKG_REQUIRES, dontfix, &workq, m); continue; } #endif /* find list of solvables providing 'req' */ dp = pool_whatprovides_ptr(pool, req); if (*dp == SYSTEMSOLVABLE) /* always installed */ continue; if (dontfix) { /* the strategy here is to not insist on dependencies * that are already broken. so if we find one provider * that was already installed, we know that the * dependency was not broken before so we enforce it */ for (i = 0; (p = dp[i]) != 0; i++) if (pool->solvables[p].repo == installed) break; /* found installed provider */ if (!p) { /* didn't find an installed provider: previously broken dependency */ POOL_DEBUG(SOLV_DEBUG_RULE_CREATION, "ignoring broken requires %s of installed package %s\n", pool_dep2str(pool, req), pool_solvable2str(pool, s)); continue; } } if (!*dp) { POOL_DEBUG(SOLV_DEBUG_RULE_CREATION, "package %s [%d] is not installable (%s)\n", pool_solvid2str(pool, n), n, pool_dep2str(pool, req)); addpkgrule(solv, -n, 0, 0, SOLVER_RULE_PKG_NOTHING_PROVIDES_DEP, req); continue; } for (i = 0; dp[i] != 0; i++) if (n == dp[i]) break; if (dp[i]) continue; /* provided by itself, no need to add rule */ IF_POOLDEBUG (SOLV_DEBUG_RULE_CREATION) { POOL_DEBUG(SOLV_DEBUG_RULE_CREATION," %s requires %s\n", pool_solvable2str(pool, s), pool_dep2str(pool, req)); for (i = 0; dp[i]; i++) POOL_DEBUG(SOLV_DEBUG_RULE_CREATION, " provided by %s\n", pool_solvid2str(pool, dp[i])); } /* add 'requires' dependency */ /* rule: (-requestor|provider1|provider2|...|providerN) */ addpkgrule(solv, -n, 0, dp - pool->whatprovidesdata, SOLVER_RULE_PKG_REQUIRES, req); /* push all non-visited providers on the work queue */ if (m) for (; *dp; dp++) if (!MAPTST(m, *dp)) queue_push(&workq, *dp); } } /* that's all we check for src packages */ if (s->arch == ARCH_SRC || s->arch == ARCH_NOSRC) continue; /*----------------------------------------- * check conflicts of s */ if (s->conflicts) { int ispatch = 0; /* we treat conflicts in patches a bit differen: * - nevr matching * - multiversion handling * XXX: we should really handle this different, looking * at the name is a bad hack */ if (!strncmp("patch:", pool_id2str(pool, s->name), 6)) ispatch = 1; conp = s->repo->idarraydata + s->conflicts; /* foreach conflicts of 's' */ while ((con = *conp++) != 0) { #ifdef ENABLE_COMPLEX_DEPS if (!ispatch && pool_is_complex_dep(pool, con)) { /* we have AND/COND deps, normalize */ add_complex_deprules(solv, n, con, SOLVER_RULE_PKG_CONFLICTS, dontfix, &workq, m); continue; } #endif /* foreach providers of a conflict of 's' */ FOR_PROVIDES(p, pp, con) { if (ispatch && !pool_match_nevr(pool, pool->solvables + p, con)) continue; /* dontfix: dont care about conflicts with already installed packs */ if (dontfix && pool->solvables[p].repo == installed) continue; if (p == n) /* p == n: self conflict */ { if (!pool->forbidselfconflicts || is_otherproviders_dep(pool, con)) continue; addpkgrule(solv, -n, 0, 0, SOLVER_RULE_PKG_SELF_CONFLICT, con); continue; } if (ispatch && solv->multiversion.size && MAPTST(&solv->multiversion, p) && ISRELDEP(con)) { /* our patch conflicts with a multiversion package */ Id d = makemultiversionconflict(solv, p, con); if (d) { addpkgrule(solv, -n, 0, d, SOLVER_RULE_PKG_CONFLICTS, con); continue; } } if (p == SYSTEMSOLVABLE) p = 0; /* rule: -n|-p: either solvable _or_ provider of conflict */ addpkgrule(solv, -n, -p, 0, SOLVER_RULE_PKG_CONFLICTS, con); } } } /*----------------------------------------- * check obsoletes and implicit obsoletes of a package * if ignoreinstalledsobsoletes is not set, we're also checking * obsoletes of installed packages (like newer rpm versions) */ if ((!installed || s->repo != installed) || !pool->noinstalledobsoletes) { int multi = solv->multiversion.size && MAPTST(&solv->multiversion, n); int isinstalled = (installed && s->repo == installed); if (s->obsoletes && (!multi || solv->keepexplicitobsoletes)) { obsp = s->repo->idarraydata + s->obsoletes; /* foreach obsoletes */ while ((obs = *obsp++) != 0) { /* foreach provider of an obsoletes of 's' */ FOR_PROVIDES(p, pp, obs) { Solvable *ps = pool->solvables + p; if (p == n) continue; if (isinstalled && dontfix && ps->repo == installed) continue; /* don't repair installed/installed problems */ if (!pool->obsoleteusesprovides /* obsoletes are matched names, not provides */ && !pool_match_nevr(pool, ps, obs)) continue; if (pool->obsoleteusescolors && !pool_colormatch(pool, s, ps)) continue; if (p == SYSTEMSOLVABLE) p = 0; if (!isinstalled) addpkgrule(solv, -n, -p, 0, SOLVER_RULE_PKG_OBSOLETES, obs); else addpkgrule(solv, -n, -p, 0, SOLVER_RULE_PKG_INSTALLED_OBSOLETES, obs); } } } /* check implicit obsoletes * for installed packages we only need to check installed/installed problems (and * only when dontfix is not set), as the others are picked up when looking at the * uninstalled package. */ if (!isinstalled || !dontfix) { FOR_PROVIDES(p, pp, s->name) { Solvable *ps = pool->solvables + p; if (p == n) continue; if (isinstalled && ps->repo != installed) continue; /* we still obsolete packages with same nevra, like rpm does */ /* (actually, rpm mixes those packages. yuck...) */ if (multi && (s->name != ps->name || s->evr != ps->evr || s->arch != ps->arch)) { if (isinstalled || ps->repo != installed) continue; /* also check the installed package for multi-ness */ if (MAPTST(&solv->multiversion, p)) continue; } if (!pool->implicitobsoleteusesprovides && s->name != ps->name) continue; if (pool->implicitobsoleteusescolors && !pool_colormatch(pool, s, ps)) continue; if (p == SYSTEMSOLVABLE) p = 0; if (s->name == ps->name) { /* optimization: do not add the same-name conflict rule if it was * already added when we looked at the other package. * (this assumes pool_colormatch is symmetric) */ if (p && m && ps->repo != installed && MAPTST(m, p) && (ps->arch != ARCH_SRC && ps->arch != ARCH_NOSRC) && !(solv->multiversion.size && MAPTST(&solv->multiversion, p))) continue; addpkgrule(solv, -n, -p, 0, SOLVER_RULE_PKG_SAME_NAME, 0); } else addpkgrule(solv, -n, -p, 0, SOLVER_RULE_PKG_IMPLICIT_OBSOLETES, s->name); } } } if (m && pool->implicitobsoleteusescolors && (s->arch > pool->lastarch || pool->id2arch[s->arch] != 1)) { int a = pool->id2arch[s->arch]; /* check lock-step candidates */ FOR_PROVIDES(p, pp, s->name) { Solvable *ps = pool->solvables + p; if (s->name != ps->name || s->evr != ps->evr || MAPTST(m, p)) continue; if (ps->arch > pool->lastarch || pool->id2arch[ps->arch] == 1 || pool->id2arch[ps->arch] >= a) continue; queue_push(&workq, p); } } /*----------------------------------------- * add recommends/suggests to the work queue */ if (s->recommends && m) { recp = s->repo->idarraydata + s->recommends; while ((rec = *recp++) != 0) { #ifdef ENABLE_COMPLEX_DEPS if (pool_is_complex_dep(pool, rec)) { pool_add_pos_literals_complex_dep(pool, rec, &workq, m, 0); continue; } #endif FOR_PROVIDES(p, pp, rec) if (!MAPTST(m, p)) queue_push(&workq, p); } } if (s->suggests && m) { sugp = s->repo->idarraydata + s->suggests; while ((sug = *sugp++) != 0) { #ifdef ENABLE_COMPLEX_DEPS if (pool_is_complex_dep(pool, sug)) { pool_add_pos_literals_complex_dep(pool, sug, &workq, m, 0); continue; } #endif FOR_PROVIDES(p, pp, sug) if (!MAPTST(m, p)) queue_push(&workq, p); } } } queue_free(&workq); } #ifdef ENABLE_LINKED_PKGS void solver_addpkgrulesforlinked(Solver *solv, Map *m) { Pool *pool = solv->pool; Solvable *s; int i, j; Queue qr; queue_init(&qr); for (i = 1; i < pool->nsolvables; i++) { if (MAPTST(m, i)) continue; s = pool->solvables + i; if (!s->repo || s->repo == solv->installed) continue; if (!strchr(pool_id2str(pool, s->name), ':')) continue; if (!pool_installable(pool, s)) continue; find_package_link(pool, s, 0, &qr, 0, 0); if (qr.count) { for (j = 0; j < qr.count; j++) if (MAPTST(m, qr.elements[j])) { solver_addpkgrulesforsolvable(solv, s, m); break; } queue_empty(&qr); } } queue_free(&qr); } #endif /*------------------------------------------------------------------- * * Add rules for packages possibly selected in by weak dependencies * * m: already added solvables */ void solver_addpkgrulesforweak(Solver *solv, Map *m) { Pool *pool = solv->pool; Solvable *s; Id sup, *supp; int i, n; /* foreach solvable in pool */ for (i = n = 1; n < pool->nsolvables; i++, n++) { if (i == pool->nsolvables) /* wrap i */ i = 1; if (MAPTST(m, i)) /* already added that one */ continue; s = pool->solvables + i; if (!s->repo) continue; if (s->repo != pool->installed && !pool_installable(pool, s)) continue; /* only look at installable ones */ sup = 0; if (s->supplements) { /* find possible supplements */ supp = s->repo->idarraydata + s->supplements; while ((sup = *supp++) != 0) if (dep_possible(solv, sup, m)) break; } /* if nothing found, check for enhances */ if (!sup && s->enhances) { supp = s->repo->idarraydata + s->enhances; while ((sup = *supp++) != 0) if (dep_possible(solv, sup, m)) break; } /* if nothing found, goto next solvables */ if (!sup) continue; solver_addpkgrulesforsolvable(solv, s, m); n = 0; /* check all solvables again because we added solvables to m */ } } /*------------------------------------------------------------------- * * add package rules for possible updates * * s: solvable * m: map of already visited solvables * allow_all: 0 = dont allow downgrades, 1 = allow all candidates */ void solver_addpkgrulesforupdaters(Solver *solv, Solvable *s, Map *m, int allow_all) { Pool *pool = solv->pool; int i; /* queue and buffer for it */ Queue qs; Id qsbuf[64]; queue_init_buffer(&qs, qsbuf, sizeof(qsbuf)/sizeof(*qsbuf)); /* find update candidates for 's' */ policy_findupdatepackages(solv, s, &qs, allow_all); /* add rule for 's' if not already done */ if (!MAPTST(m, s - pool->solvables)) solver_addpkgrulesforsolvable(solv, s, m); /* foreach update candidate, add rule if not already done */ for (i = 0; i < qs.count; i++) if (!MAPTST(m, qs.elements[i])) solver_addpkgrulesforsolvable(solv, pool->solvables + qs.elements[i], m); queue_free(&qs); } /*********************************************************************** *** *** Update/Feature rule part *** *** Those rules make sure an installed package isn't silently deleted *** ***/ static Id finddistupgradepackages(Solver *solv, Solvable *s, Queue *qs, int allow_all) { Pool *pool = solv->pool; int i; policy_findupdatepackages(solv, s, qs, allow_all ? allow_all : 2); if (!qs->count) { if (allow_all) return 0; /* orphaned, don't create feature rule */ /* check if this is an orphaned package */ policy_findupdatepackages(solv, s, qs, 1); if (!qs->count) return 0; /* orphaned, don't create update rule */ qs->count = 0; return -SYSTEMSOLVABLE; /* supported but not installable */ } if (allow_all) return s - pool->solvables; /* check if it is ok to keep the installed package */ if (solv->dupmap.size && MAPTST(&solv->dupmap, s - pool->solvables)) return s - pool->solvables; for (i = 0; i < qs->count; i++) { Solvable *ns = pool->solvables + qs->elements[i]; if (s->evr == ns->evr && solvable_identical(s, ns)) return s - pool->solvables; } /* nope, it must be some other package */ return -SYSTEMSOLVABLE; } #if 0 /* add packages from the dup repositories to the update candidates * this isn't needed for the global dup mode as all packages are * from dup repos in that case */ static void addduppackages(Solver *solv, Solvable *s, Queue *qs) { Queue dupqs; Id p, dupqsbuf[64]; int i; int oldnoupdateprovide = solv->noupdateprovide; queue_init_buffer(&dupqs, dupqsbuf, sizeof(dupqsbuf)/sizeof(*dupqsbuf)); solv->noupdateprovide = 1; policy_findupdatepackages(solv, s, &dupqs, 2); solv->noupdateprovide = oldnoupdateprovide; for (i = 0; i < dupqs.count; i++) { p = dupqs.elements[i]; if (MAPTST(&solv->dupmap, p)) queue_pushunique(qs, p); } queue_free(&dupqs); } #endif /* stash away the original updaters for multiversion packages. We do this so that * we can update the package later */ static inline void set_specialupdaters(Solver *solv, Solvable *s, Id d) { Repo *installed = solv->installed; if (!solv->specialupdaters) solv->specialupdaters = solv_calloc(installed->end - installed->start, sizeof(Id)); solv->specialupdaters[s - solv->pool->solvables - installed->start] = d; } /*------------------------------------------------------------------- * * add rule for update * (A|A1|A2|A3...) An = update candidates for A * * s = (installed) solvable */ void solver_addupdaterule(Solver *solv, Solvable *s, int allow_all) { /* installed packages get a special upgrade allowed rule */ Pool *pool = solv->pool; Id p, d; Queue qs; Id qsbuf[64]; int isorphaned = 0; queue_init_buffer(&qs, qsbuf, sizeof(qsbuf)/sizeof(*qsbuf)); p = s - pool->solvables; /* find update candidates for 's' */ if (solv->dupmap_all || (solv->dupinvolvedmap.size && MAPTST(&solv->dupinvolvedmap, p))) p = finddistupgradepackages(solv, s, &qs, allow_all); else policy_findupdatepackages(solv, s, &qs, allow_all); #ifdef ENABLE_LINKED_PKGS if (solv->instbuddy && solv->instbuddy[s - pool->solvables - solv->installed->start]) { const char *name = pool_id2str(pool, s->name); if (strncmp(name, "pattern:", 8) == 0 || strncmp(name, "application:", 12) == 0) { /* a linked pseudo package. As it is linked, we do not need an update/feature rule */ /* nevertheless we set specialupdaters so we can update */ solver_addrule(solv, 0, 0, 0); if (!allow_all && qs.count) { if (p != -SYSTEMSOLVABLE) queue_unshift(&qs, p); if (qs.count) set_specialupdaters(solv, s, pool_queuetowhatprovides(pool, &qs)); } queue_free(&qs); return; } } #endif if (!allow_all && !p) /* !p implies qs.count == 0 */ { queue_push(&solv->orphaned, s - pool->solvables); /* an orphaned package */ if (solv->keep_orphans && !(solv->droporphanedmap_all || (solv->droporphanedmap.size && MAPTST(&solv->droporphanedmap, s - pool->solvables - solv->installed->start)))) p = s - pool->solvables; /* keep this orphaned package installed */ queue_free(&qs); solver_addrule(solv, p, 0, 0); return; } if (!allow_all && qs.count && solv->multiversion.size) { int i, j; for (i = 0; i < qs.count; i++) if (MAPTST(&solv->multiversion, qs.elements[i])) break; if (i < qs.count) { /* filter out all multiversion packages as they don't update */ d = pool_queuetowhatprovides(pool, &qs); /* save qs away */ for (j = i; i < qs.count; i++) { if (MAPTST(&solv->multiversion, qs.elements[i])) { Solvable *ps = pool->solvables + qs.elements[i]; /* if keepexplicitobsoletes is set and the name is different, * we assume that there is an obsoletes. XXX: not 100% correct */ if (solv->keepexplicitobsoletes && ps->name != s->name) { qs.elements[j++] = qs.elements[i]; continue; } /* it's ok if they have same nevra */ if (ps->name != s->name || ps->evr != s->evr || ps->arch != s->arch) continue; } qs.elements[j++] = qs.elements[i]; } if (j < qs.count) /* filtered at least one package? */ { if (j == 0 && p == -SYSTEMSOLVABLE) { /* this is a multiversion orphan */ queue_push(&solv->orphaned, s - pool->solvables); set_specialupdaters(solv, s, d); if (solv->keep_orphans && !(solv->droporphanedmap_all || (solv->droporphanedmap.size && MAPTST(&solv->droporphanedmap, s - pool->solvables - solv->installed->start)))) { /* we need to keep the orphan */ queue_free(&qs); solver_addrule(solv, s - pool->solvables, 0, 0); return; } /* we can drop it as long as we update */ isorphaned = 1; j = qs.count; /* force the update */ } else if (d && (solv->updatemap_all || (solv->updatemap.size && MAPTST(&solv->updatemap, s - pool->solvables - solv->installed->start)))) { /* non-orphan multiversion package, set special updaters if we want an update */ set_specialupdaters(solv, s, d); } qs.count = j; } else if (p != -SYSTEMSOLVABLE) { /* could fallthrough, but then we would do pool_queuetowhatprovides twice */ queue_free(&qs); solver_addrule(solv, s - pool->solvables, 0, d); /* allow update of s */ return; } } } if (!isorphaned && p == -SYSTEMSOLVABLE && qs.count && solv->dupmap.size) p = s - pool->solvables; /* let the dup rules sort it out */ if (qs.count && p == -SYSTEMSOLVABLE) p = queue_shift(&qs); if (qs.count > 1) { d = pool_queuetowhatprovides(pool, &qs); queue_free(&qs); solver_addrule(solv, p, 0, d); /* allow update of s */ } else { d = qs.count ? qs.elements[0] : 0; queue_free(&qs); solver_addrule(solv, p, d, 0); /* allow update of s */ } } static inline void disableupdaterule(Solver *solv, Id p) { Rule *r; MAPSET(&solv->noupdate, p - solv->installed->start); r = solv->rules + solv->updaterules + (p - solv->installed->start); if (r->p && r->d >= 0) solver_disablerule(solv, r); r = solv->rules + solv->featurerules + (p - solv->installed->start); if (r->p && r->d >= 0) solver_disablerule(solv, r); if (solv->bestrules_pkg) { int i, ni; ni = solv->bestrules_end - solv->bestrules; for (i = 0; i < ni; i++) if (solv->bestrules_pkg[i] == p) solver_disablerule(solv, solv->rules + solv->bestrules + i); } } static inline void reenableupdaterule(Solver *solv, Id p) { Pool *pool = solv->pool; Rule *r; MAPCLR(&solv->noupdate, p - solv->installed->start); r = solv->rules + solv->updaterules + (p - solv->installed->start); if (r->p) { if (r->d < 0) { solver_enablerule(solv, r); IF_POOLDEBUG (SOLV_DEBUG_SOLUTIONS) { POOL_DEBUG(SOLV_DEBUG_SOLUTIONS, "@@@ re-enabling "); solver_printruleclass(solv, SOLV_DEBUG_SOLUTIONS, r); } } } else { r = solv->rules + solv->featurerules + (p - solv->installed->start); if (r->p && r->d < 0) { solver_enablerule(solv, r); IF_POOLDEBUG (SOLV_DEBUG_SOLUTIONS) { POOL_DEBUG(SOLV_DEBUG_SOLUTIONS, "@@@ re-enabling "); solver_printruleclass(solv, SOLV_DEBUG_SOLUTIONS, r); } } } if (solv->bestrules_pkg) { int i, ni; ni = solv->bestrules_end - solv->bestrules; for (i = 0; i < ni; i++) if (solv->bestrules_pkg[i] == p) solver_enablerule(solv, solv->rules + solv->bestrules + i); } } /*********************************************************************** *** *** Infarch rule part *** *** Infarch rules make sure the solver uses the best architecture of *** a package if multiple archetectures are available *** ***/ void solver_addinfarchrules(Solver *solv, Map *addedmap) { Pool *pool = solv->pool; Repo *installed = pool->installed; int first, i, j; Id p, pp, a, aa, bestarch; Solvable *s, *ps, *bests; Queue badq, allowedarchs; Queue lsq; queue_init(&badq); queue_init(&allowedarchs); queue_init(&lsq); solv->infarchrules = solv->nrules; for (i = 1; i < pool->nsolvables; i++) { if (i == SYSTEMSOLVABLE || !MAPTST(addedmap, i)) continue; s = pool->solvables + i; first = i; bestarch = 0; bests = 0; queue_empty(&allowedarchs); FOR_PROVIDES(p, pp, s->name) { ps = pool->solvables + p; if (ps->name != s->name || !MAPTST(addedmap, p)) continue; if (p == i) first = 0; if (first) break; a = ps->arch; a = (a <= pool->lastarch) ? pool->id2arch[a] : 0; if (a != 1 && installed && ps->repo == installed) { if (!solv->dupmap_all && !(solv->dupinvolvedmap.size && MAPTST(&solv->dupinvolvedmap, p))) queue_pushunique(&allowedarchs, ps->arch); /* also ok to keep this architecture */ continue; /* ignore installed solvables when calculating the best arch */ } if (a && a != 1 && (!bestarch || a < bestarch)) { bestarch = a; bests = ps; } } if (first) continue; /* speed up common case where installed package already has best arch */ if (allowedarchs.count == 1 && bests && allowedarchs.elements[0] == bests->arch) allowedarchs.count--; /* installed arch is best */ if (allowedarchs.count && pool->implicitobsoleteusescolors && installed && bestarch) { /* need an extra pass for lockstep checking: we only allow to keep an inferior arch * if the corresponding installed package is not lock-stepped */ queue_empty(&allowedarchs); FOR_PROVIDES(p, pp, s->name) { Id p2, pp2; ps = pool->solvables + p; if (ps->name != s->name || ps->repo != installed || !MAPTST(addedmap, p)) continue; if (solv->dupmap_all || (solv->dupinvolvedmap.size && MAPTST(&solv->dupinvolvedmap, p))) continue; a = ps->arch; a = (a <= pool->lastarch) ? pool->id2arch[a] : 0; if (!a) { queue_pushunique(&allowedarchs, ps->arch); /* strange arch, allow */ continue; } if (a == 1 || ((a ^ bestarch) & 0xffff0000) == 0) continue; /* have installed package with inferior arch, check if lock-stepped */ FOR_PROVIDES(p2, pp2, s->name) { Solvable *s2 = pool->solvables + p2; Id a2; if (p2 == p || s2->name != s->name || s2->evr != pool->solvables[p].evr || s2->arch == pool->solvables[p].arch) continue; a2 = s2->arch; a2 = (a2 <= pool->lastarch) ? pool->id2arch[a2] : 0; if (a2 && (a2 == 1 || ((a2 ^ bestarch) & 0xffff0000) == 0)) break; } if (!p2) queue_pushunique(&allowedarchs, ps->arch); } } /* find all bad packages */ queue_empty(&badq); FOR_PROVIDES(p, pp, s->name) { ps = pool->solvables + p; if (ps->name != s->name || !MAPTST(addedmap, p)) continue; a = ps->arch; a = (a <= pool->lastarch) ? pool->id2arch[a] : 0; if (a != 1 && bestarch && ((a ^ bestarch) & 0xffff0000) != 0) { if (installed && ps->repo == installed) { if (pool->implicitobsoleteusescolors) queue_push(&badq, p); /* special lock-step handling, see below */ continue; /* always ok to keep an installed package */ } for (j = 0; j < allowedarchs.count; j++) { aa = allowedarchs.elements[j]; if (ps->arch == aa) break; aa = (aa <= pool->lastarch) ? pool->id2arch[aa] : 0; if (aa && ((a ^ aa) & 0xffff0000) == 0) break; /* compatible */ } if (j == allowedarchs.count) queue_push(&badq, p); } } /* block all solvables in the badq! */ for (j = 0; j < badq.count; j++) { p = badq.elements[j]; /* lock-step */ if (pool->implicitobsoleteusescolors) { Id p2; int haveinstalled = 0; queue_empty(&lsq); FOR_PROVIDES(p2, pp, s->name) { Solvable *s2 = pool->solvables + p2; if (p2 == p || s2->name != s->name || s2->evr != pool->solvables[p].evr || s2->arch == pool->solvables[p].arch) continue; a = s2->arch; a = (a <= pool->lastarch) ? pool->id2arch[a] : 0; if (a && (a == 1 || ((a ^ bestarch) & 0xffff000) == 0)) { queue_push(&lsq, p2); if (installed && s2->repo == installed) haveinstalled = 1; } } if (installed && pool->solvables[p].repo == installed && !haveinstalled) continue; /* installed package not in lock-step */ } if (lsq.count < 2) solver_addrule(solv, -p, lsq.count ? lsq.elements[0] : 0, 0); else solver_addrule(solv, -p, 0, pool_queuetowhatprovides(pool, &lsq)); } } queue_free(&lsq); queue_free(&badq); queue_free(&allowedarchs); solv->infarchrules_end = solv->nrules; } static inline void disableinfarchrule(Solver *solv, Id name) { Pool *pool = solv->pool; Rule *r; int i; for (i = solv->infarchrules, r = solv->rules + i; i < solv->infarchrules_end; i++, r++) { if (r->p < 0 && r->d >= 0 && pool->solvables[-r->p].name == name) solver_disablerule(solv, r); } } static inline void reenableinfarchrule(Solver *solv, Id name) { Pool *pool = solv->pool; Rule *r; int i; for (i = solv->infarchrules, r = solv->rules + i; i < solv->infarchrules_end; i++, r++) { if (r->p < 0 && r->d < 0 && pool->solvables[-r->p].name == name) { solver_enablerule(solv, r); IF_POOLDEBUG (SOLV_DEBUG_SOLUTIONS) { POOL_DEBUG(SOLV_DEBUG_SOLUTIONS, "@@@ re-enabling "); solver_printruleclass(solv, SOLV_DEBUG_SOLUTIONS, r); } } } } /*********************************************************************** *** *** Dup rule part *** *** Dup rules make sure a package is selected from the specified dup *** repositories if an update candidate is included in one of them. *** ***/ static inline void add_cleandeps_package(Solver *solv, Id p) { if (!solv->cleandeps_updatepkgs) { solv->cleandeps_updatepkgs = solv_calloc(1, sizeof(Queue)); queue_init(solv->cleandeps_updatepkgs); } queue_pushunique(solv->cleandeps_updatepkgs, p); } static void solver_addtodupmaps(Solver *solv, Id p, Id how, int targeted) { Pool *pool = solv->pool; Solvable *ps, *s = pool->solvables + p; Repo *installed = solv->installed; Id pi, pip, obs, *obsp; MAPSET(&solv->dupinvolvedmap, p); if (targeted) MAPSET(&solv->dupmap, p); FOR_PROVIDES(pi, pip, s->name) { ps = pool->solvables + pi; if (ps->name != s->name) continue; MAPSET(&solv->dupinvolvedmap, pi); if (targeted && ps->repo == installed && solv->obsoletes && solv->obsoletes[pi - installed->start]) { Id *opp, pi2; for (opp = solv->obsoletes_data + solv->obsoletes[pi - installed->start]; (pi2 = *opp++) != 0;) if (pool->solvables[pi2].repo != installed) MAPSET(&solv->dupinvolvedmap, pi2); } if (ps->repo == installed && (how & SOLVER_FORCEBEST) != 0) { if (!solv->bestupdatemap.size) map_grow(&solv->bestupdatemap, installed->end - installed->start); MAPSET(&solv->bestupdatemap, pi - installed->start); } if (ps->repo == installed && (how & SOLVER_CLEANDEPS) != 0) add_cleandeps_package(solv, pi); if (!targeted && ps->repo != installed) MAPSET(&solv->dupmap, pi); } if (s->repo == installed && solv->obsoletes && solv->obsoletes[p - installed->start]) { Id *opp; for (opp = solv->obsoletes_data + solv->obsoletes[p - installed->start]; (pi = *opp++) != 0;) { ps = pool->solvables + pi; if (ps->repo == installed) continue; MAPSET(&solv->dupinvolvedmap, pi); if (!targeted) MAPSET(&solv->dupmap, pi); } } if (targeted && s->repo != installed && s->obsoletes) { /* XXX: check obsoletes/provides combination */ obsp = s->repo->idarraydata + s->obsoletes; while ((obs = *obsp++) != 0) { FOR_PROVIDES(pi, pip, obs) { Solvable *ps = pool->solvables + pi; if (!pool->obsoleteusesprovides && !pool_match_nevr(pool, ps, obs)) continue; if (pool->obsoleteusescolors && !pool_colormatch(pool, s, ps)) continue; MAPSET(&solv->dupinvolvedmap, pi); if (targeted && ps->repo == installed && solv->obsoletes && solv->obsoletes[pi - installed->start]) { Id *opp, pi2; for (opp = solv->obsoletes_data + solv->obsoletes[pi - installed->start]; (pi2 = *opp++) != 0;) if (pool->solvables[pi2].repo != installed) MAPSET(&solv->dupinvolvedmap, pi2); } if (ps->repo == installed && (how & SOLVER_FORCEBEST) != 0) { if (!solv->bestupdatemap.size) map_grow(&solv->bestupdatemap, installed->end - installed->start); MAPSET(&solv->bestupdatemap, pi - installed->start); } if (ps->repo == installed && (how & SOLVER_CLEANDEPS) != 0) add_cleandeps_package(solv, pi); } } } } void solver_createdupmaps(Solver *solv) { Queue *job = &solv->job; Pool *pool = solv->pool; Repo *installed = solv->installed; Id select, how, what, p, pp; Solvable *s; int i, targeted; map_init(&solv->dupmap, pool->nsolvables); map_init(&solv->dupinvolvedmap, pool->nsolvables); for (i = 0; i < job->count; i += 2) { how = job->elements[i]; select = job->elements[i] & SOLVER_SELECTMASK; what = job->elements[i + 1]; switch (how & SOLVER_JOBMASK) { case SOLVER_DISTUPGRADE: if (select == SOLVER_SOLVABLE_REPO) { Repo *repo; if (what <= 0 || what > pool->nrepos) break; repo = pool_id2repo(pool, what); if (!repo) break; if (repo != installed && !(how & SOLVER_TARGETED) && solv->noautotarget) break; targeted = repo != installed || (how & SOLVER_TARGETED) != 0; FOR_REPO_SOLVABLES(repo, p, s) { if (repo != installed && !pool_installable(pool, s)) continue; solver_addtodupmaps(solv, p, how, targeted); } } else if (select == SOLVER_SOLVABLE_ALL) { FOR_POOL_SOLVABLES(p) { MAPSET(&solv->dupinvolvedmap, p); if (installed && pool->solvables[p].repo != installed) MAPSET(&solv->dupmap, p); } } else { targeted = how & SOLVER_TARGETED ? 1 : 0; if (installed && !targeted && !solv->noautotarget) { FOR_JOB_SELECT(p, pp, select, what) if (pool->solvables[p].repo == installed) break; targeted = p == 0; } else if (!installed && !solv->noautotarget) targeted = 1; FOR_JOB_SELECT(p, pp, select, what) { Solvable *s = pool->solvables + p; if (!s->repo) continue; if (s->repo != installed && !targeted) continue; if (s->repo != installed && !pool_installable(pool, s)) continue; solver_addtodupmaps(solv, p, how, targeted); } } break; default: break; } } MAPCLR(&solv->dupinvolvedmap, SYSTEMSOLVABLE); } void solver_freedupmaps(Solver *solv) { map_free(&solv->dupmap); /* we no longer free solv->dupinvolvedmap as we need it in * policy's priority pruning code. sigh. */ } void solver_addduprules(Solver *solv, Map *addedmap) { Pool *pool = solv->pool; Repo *installed = solv->installed; Id p, pp; Solvable *s, *ps; int first, i; Rule *r; solv->duprules = solv->nrules; for (i = 1; i < pool->nsolvables; i++) { if (i == SYSTEMSOLVABLE || !MAPTST(addedmap, i)) continue; s = pool->solvables + i; first = i; FOR_PROVIDES(p, pp, s->name) { ps = pool->solvables + p; if (ps->name != s->name || !MAPTST(addedmap, p)) continue; if (p == i) first = 0; if (first) break; if (!MAPTST(&solv->dupinvolvedmap, p)) continue; if (installed && ps->repo == installed) { if (!solv->updatemap.size) map_grow(&solv->updatemap, installed->end - installed->start); MAPSET(&solv->updatemap, p - installed->start); if (!MAPTST(&solv->dupmap, p)) { Id ip, ipp; /* is installed identical to a good one? */ FOR_PROVIDES(ip, ipp, ps->name) { Solvable *is = pool->solvables + ip; if (!MAPTST(&solv->dupmap, ip)) continue; if (is->evr == ps->evr && solvable_identical(ps, is)) break; } if (ip) { /* ok, found a good one. we may keep this package. */ MAPSET(&solv->dupmap, p); /* for best rules processing */ continue; } r = solv->rules + solv->updaterules + (p - installed->start); if (!r->p) r = solv->rules + solv->featurerules + (p - installed->start); if (r->p && solv->specialupdaters && solv->specialupdaters[p - installed->start]) { /* this is a multiversion orphan, we're good if an update is installed */ solver_addrule(solv, -p, 0, solv->specialupdaters[p - installed->start]); continue; } if (!r->p || (r->p == p && !r->d && !r->w2)) { /* this is an orphan */ MAPSET(&solv->dupmap, p); /* for best rules processing */ continue; } solver_addrule(solv, -p, 0, 0); /* no match, sorry */ } } else if (!MAPTST(&solv->dupmap, p)) solver_addrule(solv, -p, 0, 0); } } solv->duprules_end = solv->nrules; } static inline void disableduprule(Solver *solv, Id name) { Pool *pool = solv->pool; Rule *r; int i; for (i = solv->duprules, r = solv->rules + i; i < solv->duprules_end; i++, r++) { if (r->p < 0 && r->d >= 0 && pool->solvables[-r->p].name == name) solver_disablerule(solv, r); } } static inline void reenableduprule(Solver *solv, Id name) { Pool *pool = solv->pool; Rule *r; int i; for (i = solv->duprules, r = solv->rules + i; i < solv->duprules_end; i++, r++) { if (r->p < 0 && r->d < 0 && pool->solvables[-r->p].name == name) { solver_enablerule(solv, r); IF_POOLDEBUG (SOLV_DEBUG_SOLUTIONS) { POOL_DEBUG(SOLV_DEBUG_SOLUTIONS, "@@@ re-enabling "); solver_printruleclass(solv, SOLV_DEBUG_SOLUTIONS, r); } } } } /*********************************************************************** *** *** Policy rule disabling/reenabling *** *** Disable all policy rules that conflict with our jobs. If a job *** gets disabled later on, reenable the involved policy rules again. *** ***/ #define DISABLE_UPDATE 1 #define DISABLE_INFARCH 2 #define DISABLE_DUP 3 /* * add all installed packages that package p obsoletes to Queue q. * Package p is not installed. Also, we know that if * solv->keepexplicitobsoletes is not set, p is not in the multiversion map. * Entries may get added multiple times. */ static void add_obsoletes(Solver *solv, Id p, Queue *q) { Pool *pool = solv->pool; Repo *installed = solv->installed; Id p2, pp2; Solvable *s = pool->solvables + p; Id obs, *obsp; Id lastp2 = 0; if (!solv->keepexplicitobsoletes || !(solv->multiversion.size && MAPTST(&solv->multiversion, p))) { FOR_PROVIDES(p2, pp2, s->name) { Solvable *ps = pool->solvables + p2; if (ps->repo != installed) continue; if (!pool->implicitobsoleteusesprovides && ps->name != s->name) continue; if (pool->implicitobsoleteusescolors && !pool_colormatch(pool, s, ps)) continue; queue_push(q, p2); lastp2 = p2; } } if (!s->obsoletes) return; obsp = s->repo->idarraydata + s->obsoletes; while ((obs = *obsp++) != 0) FOR_PROVIDES(p2, pp2, obs) { Solvable *ps = pool->solvables + p2; if (ps->repo != installed) continue; if (!pool->obsoleteusesprovides && !pool_match_nevr(pool, ps, obs)) continue; if (pool->obsoleteusescolors && !pool_colormatch(pool, s, ps)) continue; if (p2 == lastp2) continue; queue_push(q, p2); lastp2 = p2; } } /* * Call add_obsoletes and intersect the result with the * elements in Queue q starting at qstart. * Assumes that it's the first call if qstart == q->count. * May use auxillary map m for the intersection process, all * elements of q starting at qstart must have their bit cleared. * (This is also true after the function returns.) */ static void intersect_obsoletes(Solver *solv, Id p, Queue *q, int qstart, Map *m) { int i, j; int qcount = q->count; add_obsoletes(solv, p, q); if (qcount == qstart) return; /* first call */ if (qcount == q->count) j = qstart; else if (qcount == qstart + 1) { /* easy if there's just one element */ j = qstart; for (i = qcount; i < q->count; i++) if (q->elements[i] == q->elements[qstart]) { j++; /* keep the element */ break; } } else if (!m->size && q->count - qstart <= 8) { /* faster than a map most of the time */ int k; for (i = j = qstart; i < qcount; i++) { Id ip = q->elements[i]; for (k = qcount; k < q->count; k++) if (q->elements[k] == ip) { q->elements[j++] = ip; break; } } } else { /* for the really pathologic cases we use the map */ Repo *installed = solv->installed; if (!m->size) map_init(m, installed->end - installed->start); for (i = qcount; i < q->count; i++) MAPSET(m, q->elements[i] - installed->start); for (i = j = qstart; i < qcount; i++) if (MAPTST(m, q->elements[i] - installed->start)) { MAPCLR(m, q->elements[i] - installed->start); q->elements[j++] = q->elements[i]; } } queue_truncate(q, j); } static void jobtodisablelist(Solver *solv, Id how, Id what, Queue *q) { Pool *pool = solv->pool; Id select, p, pp; Repo *installed; Solvable *s; int i, j, set, qstart; Map omap; installed = solv->installed; select = how & SOLVER_SELECTMASK; switch (how & SOLVER_JOBMASK) { case SOLVER_INSTALL: set = how & SOLVER_SETMASK; if (!(set & SOLVER_NOAUTOSET)) { /* automatically add set bits by analysing the job */ if (select == SOLVER_SOLVABLE_NAME) set |= SOLVER_SETNAME; if (select == SOLVER_SOLVABLE) set |= SOLVER_SETNAME | SOLVER_SETARCH | SOLVER_SETVENDOR | SOLVER_SETREPO | SOLVER_SETEVR; else if ((select == SOLVER_SOLVABLE_NAME || select == SOLVER_SOLVABLE_PROVIDES) && ISRELDEP(what)) { Reldep *rd = GETRELDEP(pool, what); if (rd->flags == REL_EQ && select == SOLVER_SOLVABLE_NAME) { if (pool->disttype != DISTTYPE_DEB) { const char *rel = strrchr(pool_id2str(pool, rd->evr), '-'); set |= rel ? SOLVER_SETEVR : SOLVER_SETEV; } else set |= SOLVER_SETEVR; } if (rd->flags <= 7 && ISRELDEP(rd->name)) rd = GETRELDEP(pool, rd->name); if (rd->flags == REL_ARCH) set |= SOLVER_SETARCH; } } else set &= ~SOLVER_NOAUTOSET; if (!set) return; if ((set & SOLVER_SETARCH) != 0 && solv->infarchrules != solv->infarchrules_end) { if (select == SOLVER_SOLVABLE) queue_push2(q, DISABLE_INFARCH, pool->solvables[what].name); else { int qcnt = q->count; /* does not work for SOLVER_SOLVABLE_ALL and SOLVER_SOLVABLE_REPO, but they are not useful for SOLVER_INSTALL jobs anyway */ FOR_JOB_SELECT(p, pp, select, what) { s = pool->solvables + p; /* unify names */ for (i = qcnt; i < q->count; i += 2) if (q->elements[i + 1] == s->name) break; if (i < q->count) continue; queue_push2(q, DISABLE_INFARCH, s->name); } } } if ((set & SOLVER_SETREPO) != 0 && solv->duprules != solv->duprules_end) { if (select == SOLVER_SOLVABLE) queue_push2(q, DISABLE_DUP, pool->solvables[what].name); else { int qcnt = q->count; FOR_JOB_SELECT(p, pp, select, what) { s = pool->solvables + p; /* unify names */ for (i = qcnt; i < q->count; i += 2) if (q->elements[i + 1] == s->name) break; if (i < q->count) continue; queue_push2(q, DISABLE_DUP, s->name); } } } if (!installed || installed->end == installed->start) return; /* now the hard part: disable some update rules */ /* first check if we have multiversion or installed packages in the job */ i = j = 0; FOR_JOB_SELECT(p, pp, select, what) { if (pool->solvables[p].repo == installed) j = p; else if (solv->multiversion.size && MAPTST(&solv->multiversion, p) && !solv->keepexplicitobsoletes) return; i++; } if (j) /* have installed packages */ { /* this is for dupmap_all jobs, it can go away if we create * duprules for them */ if (i == 1 && (set & SOLVER_SETREPO) != 0) queue_push2(q, DISABLE_UPDATE, j); return; } omap.size = 0; qstart = q->count; FOR_JOB_SELECT(p, pp, select, what) { intersect_obsoletes(solv, p, q, qstart, &omap); if (q->count == qstart) break; } if (omap.size) map_free(&omap); if (qstart == q->count) return; /* nothing to prune */ /* convert result to (DISABLE_UPDATE, p) pairs */ i = q->count; for (j = qstart; j < i; j++) queue_push(q, q->elements[j]); for (j = qstart; j < q->count; j += 2) { q->elements[j] = DISABLE_UPDATE; q->elements[j + 1] = q->elements[i++]; } /* now that we know which installed packages are obsoleted check each of them */ if ((set & (SOLVER_SETEVR | SOLVER_SETARCH | SOLVER_SETVENDOR)) == (SOLVER_SETEVR | SOLVER_SETARCH | SOLVER_SETVENDOR)) return; /* all is set, nothing to do */ for (i = j = qstart; i < q->count; i += 2) { Solvable *is = pool->solvables + q->elements[i + 1]; FOR_JOB_SELECT(p, pp, select, what) { int illegal = 0; s = pool->solvables + p; if ((set & SOLVER_SETEVR) != 0) illegal |= POLICY_ILLEGAL_DOWNGRADE; /* ignore */ if ((set & SOLVER_SETNAME) != 0) illegal |= POLICY_ILLEGAL_NAMECHANGE; /* ignore */ if ((set & SOLVER_SETARCH) != 0) illegal |= POLICY_ILLEGAL_ARCHCHANGE; /* ignore */ if ((set & SOLVER_SETVENDOR) != 0) illegal |= POLICY_ILLEGAL_VENDORCHANGE; /* ignore */ illegal = policy_is_illegal(solv, is, s, illegal); if (illegal && illegal == POLICY_ILLEGAL_DOWNGRADE && (set & SOLVER_SETEV) != 0) { /* it's ok if the EV is different */ if (pool_evrcmp(pool, is->evr, s->evr, EVRCMP_COMPARE_EVONLY) != 0) illegal = 0; } if (illegal) break; } if (!p) { /* no package conflicts with the update rule */ /* thus keep the DISABLE_UPDATE */ q->elements[j + 1] = q->elements[i + 1]; j += 2; } } queue_truncate(q, j); return; case SOLVER_ERASE: if (!installed) break; if (select == SOLVER_SOLVABLE_ALL || (select == SOLVER_SOLVABLE_REPO && what == installed->repoid)) FOR_REPO_SOLVABLES(installed, p, s) queue_push2(q, DISABLE_UPDATE, p); FOR_JOB_SELECT(p, pp, select, what) if (pool->solvables[p].repo == installed) { queue_push2(q, DISABLE_UPDATE, p); #ifdef ENABLE_LINKED_PKGS if (solv->instbuddy && solv->instbuddy[p - installed->start] > 1) queue_push2(q, DISABLE_UPDATE, solv->instbuddy[p - installed->start]); #endif } return; default: return; } } /* disable all policy rules that are in conflict with our job list */ void solver_disablepolicyrules(Solver *solv) { Queue *job = &solv->job; int i, j; Queue allq; Rule *r; Id lastjob = -1; Id allqbuf[128]; queue_init_buffer(&allq, allqbuf, sizeof(allqbuf)/sizeof(*allqbuf)); for (i = solv->jobrules; i < solv->jobrules_end; i++) { r = solv->rules + i; if (r->d < 0) /* disabled? */ continue; j = solv->ruletojob.elements[i - solv->jobrules]; if (j == lastjob) continue; lastjob = j; jobtodisablelist(solv, job->elements[j], job->elements[j + 1], &allq); } if (solv->cleandepsmap.size) { solver_createcleandepsmap(solv, &solv->cleandepsmap, 0); for (i = solv->installed->start; i < solv->installed->end; i++) if (MAPTST(&solv->cleandepsmap, i - solv->installed->start)) queue_push2(&allq, DISABLE_UPDATE, i); } MAPZERO(&solv->noupdate); for (i = 0; i < allq.count; i += 2) { Id type = allq.elements[i], arg = allq.elements[i + 1]; switch(type) { case DISABLE_UPDATE: disableupdaterule(solv, arg); break; case DISABLE_INFARCH: disableinfarchrule(solv, arg); break; case DISABLE_DUP: disableduprule(solv, arg); break; default: break; } } queue_free(&allq); } /* we just disabled job #jobidx, now reenable all policy rules that were * disabled because of this job */ void solver_reenablepolicyrules(Solver *solv, int jobidx) { Queue *job = &solv->job; int i, j, k, ai; Queue q, allq; Rule *r; Id lastjob = -1; Id qbuf[32], allqbuf[32]; queue_init_buffer(&q, qbuf, sizeof(qbuf)/sizeof(*qbuf)); jobtodisablelist(solv, job->elements[jobidx - 1], job->elements[jobidx], &q); if (!q.count) { queue_free(&q); return; } /* now remove everything from q that is disabled by other jobs */ /* first remove cleandeps packages, they count as DISABLE_UPDATE */ if (solv->cleandepsmap.size) { solver_createcleandepsmap(solv, &solv->cleandepsmap, 0); for (j = k = 0; j < q.count; j += 2) { if (q.elements[j] == DISABLE_UPDATE) { Id p = q.elements[j + 1]; if (p >= solv->installed->start && p < solv->installed->end && MAPTST(&solv->cleandepsmap, p - solv->installed->start)) continue; /* remove element from q */ } q.elements[k++] = q.elements[j]; q.elements[k++] = q.elements[j + 1]; } q.count = k; if (!q.count) { queue_free(&q); return; } } /* now go through the disable list of all other jobs */ queue_init_buffer(&allq, allqbuf, sizeof(allqbuf)/sizeof(*allqbuf)); for (i = solv->jobrules; i < solv->jobrules_end; i++) { r = solv->rules + i; if (r->d < 0) /* disabled? */ continue; j = solv->ruletojob.elements[i - solv->jobrules]; if (j == lastjob) continue; lastjob = j; jobtodisablelist(solv, job->elements[j], job->elements[j + 1], &allq); if (!allq.count) continue; /* remove all elements in allq from q */ for (j = k = 0; j < q.count; j += 2) { Id type = q.elements[j], arg = q.elements[j + 1]; for (ai = 0; ai < allq.count; ai += 2) if (allq.elements[ai] == type && allq.elements[ai + 1] == arg) break; if (ai < allq.count) continue; /* found it in allq, remove element from q */ q.elements[k++] = q.elements[j]; q.elements[k++] = q.elements[j + 1]; } q.count = k; if (!q.count) { queue_free(&q); queue_free(&allq); return; } queue_empty(&allq); } queue_free(&allq); /* now re-enable anything that's left in q */ for (j = 0; j < q.count; j += 2) { Id type = q.elements[j], arg = q.elements[j + 1]; switch(type) { case DISABLE_UPDATE: reenableupdaterule(solv, arg); break; case DISABLE_INFARCH: reenableinfarchrule(solv, arg); break; case DISABLE_DUP: reenableduprule(solv, arg); break; } } queue_free(&q); } /* we just removed a package from the cleandeps map, now reenable all policy rules that were * disabled because of this */ void solver_reenablepolicyrules_cleandeps(Solver *solv, Id pkg) { Queue *job = &solv->job; int i, j; Queue allq; Rule *r; Id lastjob = -1; Id allqbuf[128]; queue_init_buffer(&allq, allqbuf, sizeof(allqbuf)/sizeof(*allqbuf)); for (i = solv->jobrules; i < solv->jobrules_end; i++) { r = solv->rules + i; if (r->d < 0) /* disabled? */ continue; j = solv->ruletojob.elements[i - solv->jobrules]; if (j == lastjob) continue; lastjob = j; jobtodisablelist(solv, job->elements[j], job->elements[j + 1], &allq); } for (i = 0; i < allq.count; i += 2) if (allq.elements[i] == DISABLE_UPDATE && allq.elements[i + 1] == pkg) break; if (i == allq.count) reenableupdaterule(solv, pkg); queue_free(&allq); } /*********************************************************************** *** *** Rule info part, tell the user what the rule is about. *** ***/ static void addpkgruleinfo(Solver *solv, Id p, Id p2, Id d, int type, Id dep) { Pool *pool = solv->pool; Rule *r; if (d) { assert(!p2 && d > 0); if (!pool->whatprovidesdata[d]) d = 0; else if (!pool->whatprovidesdata[d + 1]) { p2 = pool->whatprovidesdata[d]; d = 0; } } /* check if this creates the rule we're searching for */ r = solv->rules + solv->ruleinfoq->elements[0]; if (d) { /* three or more literals */ Id od = r->d < 0 ? -r->d - 1 : r->d; if (p != r->p && !od) return; if (d != od) { Id *dp = pool->whatprovidesdata + d; Id *odp = pool->whatprovidesdata + od; while (*dp) if (*dp++ != *odp++) return; if (*odp) return; } if (p < 0 && pool->whatprovidesdata[d] < 0 && type == SOLVER_RULE_PKG_CONFLICTS) p2 = pool->whatprovidesdata[d]; } else { /* one or two literals */ Id op = p, op2 = p2; if (op2 && op > op2) /* normalize */ { Id o = op; op = op2; op2 = o; } if (r->p != op || r->w2 != op2 || (r->d && r->d != -1)) return; if (type == SOLVER_RULE_PKG_CONFLICTS && !p2) p2 = -SYSTEMSOLVABLE; if (type == SOLVER_RULE_PKG_SAME_NAME) { p = op; /* we normalize same name order */ p2 = op2; } } /* yep, rule matches. record info */ queue_push(solv->ruleinfoq, type); queue_push(solv->ruleinfoq, p < 0 ? -p : 0); queue_push(solv->ruleinfoq, p2 < 0 ? -p2 : 0); queue_push(solv->ruleinfoq, dep); } static int solver_allruleinfos_cmp(const void *ap, const void *bp, void *dp) { const Id *a = ap, *b = bp; int r; r = a[0] - b[0]; if (r) return r; r = a[1] - b[1]; if (r) return r; r = a[2] - b[2]; if (r) return r; r = a[3] - b[3]; if (r) return r; return 0; } static void getpkgruleinfos(Solver *solv, Rule *r, Queue *rq) { Pool *pool = solv->pool; Id l, pp; if (r->p >= 0) return; queue_push(rq, r - solv->rules); /* push the rule we're interested in */ solv->ruleinfoq = rq; FOR_RULELITERALS(l, pp, r) { if (l >= 0) break; solver_addpkgrulesforsolvable(solv, pool->solvables - l, 0); } #ifdef ENABLE_LINKED_PKGS FOR_RULELITERALS(l, pp, r) { if (l < 0) { if (l == r->p) continue; break; } if (!strchr(pool_id2str(pool, pool->solvables[l].name), ':') || !has_package_link(pool, pool->solvables + l)) break; add_package_link(solv, pool->solvables + l, 0, 0); } #endif solv->ruleinfoq = 0; queue_shift(rq); } int solver_allruleinfos(Solver *solv, Id rid, Queue *rq) { Rule *r = solv->rules + rid; int i, j; queue_empty(rq); if (rid <= 0 || rid >= solv->pkgrules_end) { Id type, from, to, dep; type = solver_ruleinfo(solv, rid, &from, &to, &dep); queue_push(rq, type); queue_push(rq, from); queue_push(rq, to); queue_push(rq, dep); return 1; } getpkgruleinfos(solv, r, rq); /* now sort & unify em */ if (!rq->count) return 0; solv_sort(rq->elements, rq->count / 4, 4 * sizeof(Id), solver_allruleinfos_cmp, 0); /* throw out identical entries */ for (i = j = 0; i < rq->count; i += 4) { if (j) { if (rq->elements[i] == rq->elements[j - 4] && rq->elements[i + 1] == rq->elements[j - 3] && rq->elements[i + 2] == rq->elements[j - 2] && rq->elements[i + 3] == rq->elements[j - 1]) continue; } rq->elements[j++] = rq->elements[i]; rq->elements[j++] = rq->elements[i + 1]; rq->elements[j++] = rq->elements[i + 2]; rq->elements[j++] = rq->elements[i + 3]; } rq->count = j; return j / 4; } SolverRuleinfo solver_ruleinfo(Solver *solv, Id rid, Id *fromp, Id *top, Id *depp) { Pool *pool = solv->pool; Rule *r = solv->rules + rid; SolverRuleinfo type = SOLVER_RULE_UNKNOWN; if (fromp) *fromp = 0; if (top) *top = 0; if (depp) *depp = 0; if (rid > 0 && rid < solv->pkgrules_end) { Queue rq; int i; if (r->p >= 0) return SOLVER_RULE_PKG; if (fromp) *fromp = -r->p; queue_init(&rq); getpkgruleinfos(solv, r, &rq); type = SOLVER_RULE_PKG; for (i = 0; i < rq.count; i += 4) { Id qt, qo, qp, qd; qt = rq.elements[i]; qp = rq.elements[i + 1]; qo = rq.elements[i + 2]; qd = rq.elements[i + 3]; if (type == SOLVER_RULE_PKG || type > qt) { type = qt; if (fromp) *fromp = qp; if (top) *top = qo; if (depp) *depp = qd; } } queue_free(&rq); return type; } if (rid >= solv->jobrules && rid < solv->jobrules_end) { Id jidx = solv->ruletojob.elements[rid - solv->jobrules]; if (fromp) *fromp = jidx; if (top) *top = solv->job.elements[jidx]; if (depp) *depp = solv->job.elements[jidx + 1]; if ((r->d == 0 || r->d == -1) && r->w2 == 0 && r->p == -SYSTEMSOLVABLE) { Id how = solv->job.elements[jidx]; if ((how & (SOLVER_JOBMASK|SOLVER_SELECTMASK)) == (SOLVER_INSTALL|SOLVER_SOLVABLE_NAME)) return SOLVER_RULE_JOB_UNKNOWN_PACKAGE; if ((how & (SOLVER_JOBMASK|SOLVER_SELECTMASK)) == (SOLVER_INSTALL|SOLVER_SOLVABLE_PROVIDES)) return SOLVER_RULE_JOB_NOTHING_PROVIDES_DEP; if ((how & (SOLVER_JOBMASK|SOLVER_SELECTMASK)) == (SOLVER_ERASE|SOLVER_SOLVABLE_NAME)) return SOLVER_RULE_JOB_PROVIDED_BY_SYSTEM; if ((how & (SOLVER_JOBMASK|SOLVER_SELECTMASK)) == (SOLVER_ERASE|SOLVER_SOLVABLE_PROVIDES)) return SOLVER_RULE_JOB_PROVIDED_BY_SYSTEM; return SOLVER_RULE_JOB_UNSUPPORTED; } return SOLVER_RULE_JOB; } if (rid >= solv->updaterules && rid < solv->updaterules_end) { if (fromp) *fromp = solv->installed->start + (rid - solv->updaterules); return SOLVER_RULE_UPDATE; } if (rid >= solv->featurerules && rid < solv->featurerules_end) { if (fromp) *fromp = solv->installed->start + (rid - solv->featurerules); return SOLVER_RULE_FEATURE; } if (rid >= solv->duprules && rid < solv->duprules_end) { if (fromp) *fromp = -r->p; if (depp) *depp = pool->solvables[-r->p].name; return SOLVER_RULE_DISTUPGRADE; } if (rid >= solv->infarchrules && rid < solv->infarchrules_end) { if (fromp) *fromp = -r->p; if (depp) *depp = pool->solvables[-r->p].name; return SOLVER_RULE_INFARCH; } if (rid >= solv->bestrules && rid < solv->bestrules_end) { if (fromp && solv->bestrules_pkg[rid - solv->bestrules] > 0) *fromp = solv->bestrules_pkg[rid - solv->bestrules]; return SOLVER_RULE_BEST; } if (rid >= solv->yumobsrules && rid < solv->yumobsrules_end) { if (fromp) *fromp = -r->p; if (top) { /* first solvable is enough, we just need it for the name */ if (!r->d || r->d == -1) *top = r->w2; else *top = pool->whatprovidesdata[r->d < 0 ? -r->d : r->d]; } if (depp) *depp = solv->yumobsrules_info[rid - solv->yumobsrules]; return SOLVER_RULE_YUMOBS; } if (rid >= solv->choicerules && rid < solv->choicerules_end) { return SOLVER_RULE_CHOICE; } if (rid >= solv->learntrules) { return SOLVER_RULE_LEARNT; } return SOLVER_RULE_UNKNOWN; } SolverRuleinfo solver_ruleclass(Solver *solv, Id rid) { if (rid <= 0) return SOLVER_RULE_UNKNOWN; if (rid > 0 && rid < solv->pkgrules_end) return SOLVER_RULE_PKG; if (rid >= solv->jobrules && rid < solv->jobrules_end) return SOLVER_RULE_JOB; if (rid >= solv->updaterules && rid < solv->updaterules_end) return SOLVER_RULE_UPDATE; if (rid >= solv->featurerules && rid < solv->featurerules_end) return SOLVER_RULE_FEATURE; if (rid >= solv->duprules && rid < solv->duprules_end) return SOLVER_RULE_DISTUPGRADE; if (rid >= solv->infarchrules && rid < solv->infarchrules_end) return SOLVER_RULE_INFARCH; if (rid >= solv->bestrules && rid < solv->bestrules_end) return SOLVER_RULE_BEST; if (rid >= solv->yumobsrules && rid < solv->yumobsrules_end) return SOLVER_RULE_YUMOBS; if (rid >= solv->choicerules && rid < solv->choicerules_end) return SOLVER_RULE_CHOICE; if (rid >= solv->learntrules && rid < solv->nrules) return SOLVER_RULE_LEARNT; return SOLVER_RULE_UNKNOWN; } void solver_ruleliterals(Solver *solv, Id rid, Queue *q) { Pool *pool = solv->pool; Id p, pp; Rule *r; queue_empty(q); r = solv->rules + rid; FOR_RULELITERALS(p, pp, r) if (p != -SYSTEMSOLVABLE) queue_push(q, p); if (!q->count) queue_push(q, -SYSTEMSOLVABLE); /* hmm, better to return an empty result? */ } int solver_rule2jobidx(Solver *solv, Id rid) { if (rid < solv->jobrules || rid >= solv->jobrules_end) return 0; return solv->ruletojob.elements[rid - solv->jobrules] + 1; } /* job rule introspection */ Id solver_rule2job(Solver *solv, Id rid, Id *whatp) { int idx; if (rid < solv->jobrules || rid >= solv->jobrules_end) { if (whatp) *whatp = 0; return 0; } idx = solv->ruletojob.elements[rid - solv->jobrules]; if (whatp) *whatp = solv->job.elements[idx + 1]; return solv->job.elements[idx]; } /* update/feature rule introspection */ Id solver_rule2solvable(Solver *solv, Id rid) { if (rid >= solv->updaterules && rid < solv->updaterules_end) return rid - solv->updaterules; if (rid >= solv->featurerules && rid < solv->featurerules_end) return rid - solv->featurerules; return 0; } Id solver_rule2pkgrule(Solver *solv, Id rid) { if (rid >= solv->choicerules && rid < solv->choicerules_end) return solv->choicerules_ref[rid - solv->choicerules]; return 0; } static void solver_rule2rules_rec(Solver *solv, Id rid, Queue *q, Map *seen) { int i; Id rid2; if (seen) MAPSET(seen, rid); for (i = solv->learnt_why.elements[rid - solv->learntrules]; (rid2 = solv->learnt_pool.elements[i]) != 0; i++) { if (seen) { if (MAPTST(seen, rid2)) continue; if (rid2 >= solv->learntrules) solver_rule2rules_rec(solv, rid2, q, seen); continue; } queue_push(q, rid2); } } /* learnt rule introspection */ void solver_rule2rules(Solver *solv, Id rid, Queue *q, int recursive) { queue_empty(q); if (rid < solv->learntrules || rid >= solv->nrules) return; if (recursive) { Map seen; map_init(&seen, solv->nrules); solver_rule2rules_rec(solv, rid, q, &seen); map_free(&seen); } else solver_rule2rules_rec(solv, rid, q, 0); } /* check if the newest versions of pi still provides the dependency we're looking for */ static int solver_choicerulecheck(Solver *solv, Id pi, Rule *r, Map *m, Queue *q) { Pool *pool = solv->pool; Rule *ur; Id p, pp; int i; if (!q->count || q->elements[0] != pi) { if (q->count) queue_empty(q); ur = solv->rules + solv->updaterules + (pi - pool->installed->start); if (!ur->p) ur = solv->rules + solv->featurerules + (pi - pool->installed->start); if (!ur->p) return 0; queue_push2(q, pi, 0); FOR_RULELITERALS(p, pp, ur) if (p > 0) queue_push(q, p); } if (q->count == 2) return 1; if (q->count == 3) { p = q->elements[2]; return MAPTST(m, p) ? 0 : 1; } if (!q->elements[1]) { for (i = 2; i < q->count; i++) if (!MAPTST(m, q->elements[i])) break; if (i == q->count) return 0; /* all provide it, no need to filter */ /* some don't provide it, have to filter */ queue_deleten(q, 0, 2); policy_filter_unwanted(solv, q, POLICY_MODE_CHOOSE); queue_unshift(q, 1); /* filter mark */ queue_unshift(q, pi); } for (i = 2; i < q->count; i++) if (MAPTST(m, q->elements[i])) return 0; /* at least one provides it */ return 1; /* none of the new packages provided it */ } static inline void queue_removeelement(Queue *q, Id el) { int i, j; for (i = 0; i < q->count; i++) if (q->elements[i] == el) break; if (i < q->count) { for (j = i++; i < q->count; i++) if (q->elements[i] != el) q->elements[j++] = q->elements[i]; queue_truncate(q, j); } } void solver_addchoicerules(Solver *solv) { Pool *pool = solv->pool; Map m, mneg; Rule *r; Queue q, qi, qcheck; int i, j, rid, havechoice; Id p, d, pp; Id p2, pp2; Solvable *s, *s2; Id lastaddedp, lastaddedd; int lastaddedcnt; unsigned int now; solv->choicerules = solv->nrules; if (!pool->installed) { solv->choicerules_end = solv->nrules; return; } now = solv_timems(0); solv->choicerules_ref = solv_calloc(solv->pkgrules_end, sizeof(Id)); queue_init(&q); queue_init(&qi); queue_init(&qcheck); map_init(&m, pool->nsolvables); map_init(&mneg, pool->nsolvables); /* set up negative assertion map from infarch and dup rules */ for (rid = solv->infarchrules, r = solv->rules + rid; rid < solv->infarchrules_end; rid++, r++) if (r->p < 0 && !r->w2 && (r->d == 0 || r->d == -1)) MAPSET(&mneg, -r->p); for (rid = solv->duprules, r = solv->rules + rid; rid < solv->duprules_end; rid++, r++) if (r->p < 0 && !r->w2 && (r->d == 0 || r->d == -1)) MAPSET(&mneg, -r->p); lastaddedp = 0; lastaddedd = 0; lastaddedcnt = 0; for (rid = 1; rid < solv->pkgrules_end ; rid++) { r = solv->rules + rid; if (r->p >= 0 || ((r->d == 0 || r->d == -1) && r->w2 <= 0)) continue; /* only look at requires rules */ /* solver_printrule(solv, SOLV_DEBUG_RESULT, r); */ queue_empty(&q); queue_empty(&qi); havechoice = 0; FOR_RULELITERALS(p, pp, r) { if (p < 0) continue; s = pool->solvables + p; if (!s->repo) continue; if (s->repo == pool->installed) { queue_push(&q, p); continue; } /* check if this package is "blocked" by a installed package */ s2 = 0; FOR_PROVIDES(p2, pp2, s->name) { s2 = pool->solvables + p2; if (s2->repo != pool->installed) continue; if (!pool->implicitobsoleteusesprovides && s->name != s2->name) continue; if (pool->implicitobsoleteusescolors && !pool_colormatch(pool, s, s2)) continue; break; } if (p2) { /* found installed package p2 that we can update to p */ if (MAPTST(&mneg, p)) continue; if (policy_is_illegal(solv, s2, s, 0)) continue; #if 0 if (solver_choicerulecheck(solv, p2, r, &m)) continue; queue_push(&qi, p2); #else queue_push2(&qi, p2, p); #endif queue_push(&q, p); continue; } if (s->obsoletes) { Id obs, *obsp = s->repo->idarraydata + s->obsoletes; s2 = 0; while ((obs = *obsp++) != 0) { FOR_PROVIDES(p2, pp2, obs) { s2 = pool->solvables + p2; if (s2->repo != pool->installed) continue; if (!pool->obsoleteusesprovides && !pool_match_nevr(pool, pool->solvables + p2, obs)) continue; if (pool->obsoleteusescolors && !pool_colormatch(pool, s, s2)) continue; break; } if (p2) break; } if (obs) { /* found installed package p2 that we can update to p */ if (MAPTST(&mneg, p)) continue; if (policy_is_illegal(solv, s2, s, 0)) continue; #if 0 if (solver_choicerulecheck(solv, p2, r, &m)) continue; queue_push(&qi, p2); #else queue_push2(&qi, p2, p); #endif queue_push(&q, p); continue; } } /* package p is independent of the installed ones */ havechoice = 1; } if (!havechoice || !q.count || !qi.count) continue; /* no choice */ FOR_RULELITERALS(p, pp, r) if (p > 0) MAPSET(&m, p); /* do extra checking */ for (i = j = 0; i < qi.count; i += 2) { p2 = qi.elements[i]; if (!p2) continue; if (solver_choicerulecheck(solv, p2, r, &m, &qcheck)) { /* oops, remove element p from q */ queue_removeelement(&q, qi.elements[i + 1]); continue; } qi.elements[j++] = p2; } queue_truncate(&qi, j); if (!q.count || !qi.count) { FOR_RULELITERALS(p, pp, r) if (p > 0) MAPCLR(&m, p); continue; } /* now check the update rules of the installed package. * if all packages of the update rules are contained in * the dependency rules, there's no need to set up the choice rule */ for (i = 0; i < qi.count; i++) { Rule *ur; if (!qi.elements[i]) continue; ur = solv->rules + solv->updaterules + (qi.elements[i] - pool->installed->start); if (!ur->p) ur = solv->rules + solv->featurerules + (qi.elements[i] - pool->installed->start); if (!ur->p) continue; FOR_RULELITERALS(p, pp, ur) if (!MAPTST(&m, p)) break; if (p) break; for (j = i + 1; j < qi.count; j++) if (qi.elements[i] == qi.elements[j]) qi.elements[j] = 0; } /* empty map again */ FOR_RULELITERALS(p, pp, r) if (p > 0) MAPCLR(&m, p); if (i == qi.count) { #if 0 printf("skipping choice "); solver_printrule(solv, SOLV_DEBUG_RESULT, solv->rules + rid); #endif continue; } /* don't add identical rules */ if (lastaddedp == r->p && lastaddedcnt == q.count) { for (i = 0; i < q.count; i++) if (q.elements[i] != pool->whatprovidesdata[lastaddedd + i]) break; if (i == q.count) continue; /* already added that one */ } d = q.count ? pool_queuetowhatprovides(pool, &q) : 0; lastaddedp = r->p; lastaddedd = d; lastaddedcnt = q.count; solver_addrule(solv, r->p, 0, d); queue_push(&solv->weakruleq, solv->nrules - 1); solv->choicerules_ref[solv->nrules - 1 - solv->choicerules] = rid; #if 0 printf("OLD "); solver_printrule(solv, SOLV_DEBUG_RESULT, solv->rules + rid); printf("WEAK CHOICE "); solver_printrule(solv, SOLV_DEBUG_RESULT, solv->rules + solv->nrules - 1); #endif } queue_free(&q); queue_free(&qi); queue_free(&qcheck); map_free(&m); map_free(&mneg); solv->choicerules_end = solv->nrules; /* shrink choicerules_ref */ solv->choicerules_ref = solv_realloc2(solv->choicerules_ref, solv->choicerules_end - solv->choicerules, sizeof(Id)); POOL_DEBUG(SOLV_DEBUG_STATS, "choice rule creation took %d ms\n", solv_timems(now)); } /* called when a choice rule is disabled by analyze_unsolvable. We also * have to disable all other choice rules so that the best packages get * picked */ void solver_disablechoicerules(Solver *solv, Rule *r) { Id rid, p, pp; Pool *pool = solv->pool; Map m; Rule *or; or = solv->rules + solv->choicerules_ref[(r - solv->rules) - solv->choicerules]; map_init(&m, pool->nsolvables); FOR_RULELITERALS(p, pp, or) if (p > 0) MAPSET(&m, p); FOR_RULELITERALS(p, pp, r) if (p > 0) MAPCLR(&m, p); for (rid = solv->choicerules; rid < solv->choicerules_end; rid++) { r = solv->rules + rid; if (r->d < 0) continue; or = solv->rules + solv->choicerules_ref[(r - solv->rules) - solv->choicerules]; FOR_RULELITERALS(p, pp, or) if (p > 0 && MAPTST(&m, p)) break; if (p) solver_disablerule(solv, r); } } static void prune_to_update_targets(Solver *solv, Id *cp, Queue *q) { int i, j; Id p, *cp2; for (i = j = 0; i < q->count; i++) { p = q->elements[i]; for (cp2 = cp; *cp2; cp2++) if (*cp2 == p) { q->elements[j++] = p; break; } } queue_truncate(q, j); } static void prune_to_dup_packages(Solver *solv, Id p, Queue *q) { int i, j; for (i = j = 0; i < q->count; i++) { Id p = q->elements[i]; if (MAPTST(&solv->dupmap, p)) q->elements[j++] = p; } queue_truncate(q, j); } void solver_addbestrules(Solver *solv, int havebestinstalljobs) { Pool *pool = solv->pool; Id p; Solvable *s; Repo *installed = solv->installed; Queue q, q2; Rule *r; Queue r2pkg; int i, oldcnt; solv->bestrules = solv->nrules; if (!installed) { solv->bestrules_end = solv->nrules; return; } queue_init(&q); queue_init(&q2); queue_init(&r2pkg); if (havebestinstalljobs) { for (i = 0; i < solv->job.count; i += 2) { if ((solv->job.elements[i] & (SOLVER_JOBMASK | SOLVER_FORCEBEST)) == (SOLVER_INSTALL | SOLVER_FORCEBEST)) { int j; Id p2, pp2; for (j = 0; j < solv->ruletojob.count; j++) if (solv->ruletojob.elements[j] == i) break; if (j == solv->ruletojob.count) continue; r = solv->rules + solv->jobrules + j; queue_empty(&q); FOR_RULELITERALS(p2, pp2, r) if (p2 > 0) queue_push(&q, p2); if (!q.count) continue; /* orphaned */ /* select best packages, just look at prio and version */ oldcnt = q.count; policy_filter_unwanted(solv, &q, POLICY_MODE_RECOMMEND); if (q.count == oldcnt) continue; /* nothing filtered */ p2 = queue_shift(&q); if (q.count < 2) solver_addrule(solv, p2, q.count ? q.elements[0] : 0, 0); else solver_addrule(solv, p2, 0, pool_queuetowhatprovides(pool, &q)); queue_push(&r2pkg, -(solv->jobrules + j)); } } } if (solv->bestupdatemap_all || solv->bestupdatemap.size) { FOR_REPO_SOLVABLES(installed, p, s) { Id d, p2, pp2; if (!solv->updatemap_all && (!solv->updatemap.size || !MAPTST(&solv->updatemap, p - installed->start))) continue; if (!solv->bestupdatemap_all && (!solv->bestupdatemap.size || !MAPTST(&solv->bestupdatemap, p - installed->start))) continue; queue_empty(&q); if (solv->bestobeypolicy) r = solv->rules + solv->updaterules + (p - installed->start); else { r = solv->rules + solv->featurerules + (p - installed->start); if (!r->p) /* identical to update rule? */ r = solv->rules + solv->updaterules + (p - installed->start); } if (solv->specialupdaters && (d = solv->specialupdaters[p - installed->start]) != 0 && r == solv->rules + solv->updaterules + (p - installed->start)) { /* need to check specialupdaters */ if (r->p == p) /* be careful with the dup case */ queue_push(&q, p); while ((p2 = pool->whatprovidesdata[d++]) != 0) queue_push(&q, p2); } else { FOR_RULELITERALS(p2, pp2, r) if (p2 > 0) queue_push(&q, p2); } if (solv->update_targets && solv->update_targets->elements[p - installed->start]) prune_to_update_targets(solv, solv->update_targets->elements + solv->update_targets->elements[p - installed->start], &q); if (solv->dupinvolvedmap.size && MAPTST(&solv->dupinvolvedmap, p)) prune_to_dup_packages(solv, p, &q); /* select best packages, just look at prio and version */ policy_filter_unwanted(solv, &q, POLICY_MODE_RECOMMEND); if (!q.count) continue; /* orphaned */ if (solv->bestobeypolicy) { /* also filter the best of the feature rule packages and add them */ r = solv->rules + solv->featurerules + (p - installed->start); if (r->p) { int j; queue_empty(&q2); FOR_RULELITERALS(p2, pp2, r) if (p2 > 0) queue_push(&q2, p2); if (solv->update_targets && solv->update_targets->elements[p - installed->start]) prune_to_update_targets(solv, solv->update_targets->elements + solv->update_targets->elements[p - installed->start], &q2); if (solv->dupinvolvedmap.size && MAPTST(&solv->dupinvolvedmap, p)) prune_to_dup_packages(solv, p, &q2); policy_filter_unwanted(solv, &q2, POLICY_MODE_RECOMMEND); for (j = 0; j < q2.count; j++) queue_pushunique(&q, q2.elements[j]); } } p2 = queue_shift(&q); if (q.count < 2) solver_addrule(solv, p2, q.count ? q.elements[0] : 0, 0); else solver_addrule(solv, p2, 0, pool_queuetowhatprovides(pool, &q)); queue_push(&r2pkg, p); } } if (r2pkg.count) solv->bestrules_pkg = solv_memdup2(r2pkg.elements, r2pkg.count, sizeof(Id)); solv->bestrules_end = solv->nrules; queue_free(&q); queue_free(&q2); queue_free(&r2pkg); } /* yumobs rule handling */ static void find_obsolete_group(Solver *solv, Id obs, Queue *q) { Pool *pool = solv->pool; Queue qn; Id p2, pp2, op, *opp, opp2; int i, j, qnc, ncnt; queue_empty(q); FOR_PROVIDES(p2, pp2, obs) { Solvable *s2 = pool->solvables + p2; if (s2->repo != pool->installed) continue; if (!pool->obsoleteusesprovides && !pool_match_nevr(pool, pool->solvables + p2, obs)) continue; /* we obsolete installed package s2 with obs. now find all other packages that have the same dep */ for (opp = solv->obsoletes_data + solv->obsoletes[p2 - solv->installed->start]; (op = *opp++) != 0;) { Solvable *os = pool->solvables + op; Id obs2, *obsp2; if (!os->obsoletes) continue; if (pool->obsoleteusescolors && !pool_colormatch(pool, s2, os)) continue; obsp2 = os->repo->idarraydata + os->obsoletes; while ((obs2 = *obsp2++) != 0) if (obs2 == obs) break; if (obs2) queue_pushunique(q, op); } /* also search packages with the same name */ FOR_PROVIDES(op, opp2, s2->name) { Solvable *os = pool->solvables + op; Id obs2, *obsp2; if (os->name != s2->name) continue; if (!os->obsoletes) continue; if (pool->obsoleteusescolors && !pool_colormatch(pool, s2, os)) continue; obsp2 = os->repo->idarraydata + os->obsoletes; while ((obs2 = *obsp2++) != 0) if (obs2 == obs) break; if (obs2) queue_pushunique(q, op); } } /* find names so that we can build groups */ queue_init_clone(&qn, q); prune_to_best_version(solv->pool, &qn); #if 0 { for (i = 0; i < qn.count; i++) printf(" + %s\n", pool_solvid2str(pool, qn.elements[i])); } #endif /* filter into name groups */ qnc = qn.count; if (qnc == 1) { queue_free(&qn); queue_empty(q); return; } ncnt = 0; for (i = 0; i < qnc; i++) { Id n = pool->solvables[qn.elements[i]].name; int got = 0; for (j = 0; j < q->count; j++) { Id p = q->elements[j]; if (pool->solvables[p].name == n) { queue_push(&qn, p); got = 1; } } if (got) { queue_push(&qn, 0); ncnt++; } } if (ncnt <= 1) { queue_empty(q); } else { queue_empty(q); queue_insertn(q, 0, qn.count - qnc, qn.elements + qnc); } queue_free(&qn); } void solver_addyumobsrules(Solver *solv) { Pool *pool = solv->pool; Repo *installed = solv->installed; Id p, op, *opp; Solvable *s; Queue qo, qq, yumobsinfoq; int i, j, k; unsigned int now; solv->yumobsrules = solv->nrules; if (!installed || !solv->obsoletes) { solv->yumobsrules_end = solv->nrules; return; } now = solv_timems(0); queue_init(&qo); FOR_REPO_SOLVABLES(installed, p, s) { if (!solv->obsoletes[p - installed->start]) continue; #if 0 printf("checking yumobs for %s\n", pool_solvable2str(pool, s)); #endif queue_empty(&qo); for (opp = solv->obsoletes_data + solv->obsoletes[p - installed->start]; (op = *opp++) != 0;) { Solvable *os = pool->solvables + op; Id obs, *obsp = os->repo->idarraydata + os->obsoletes; Id p2, pp2; while ((obs = *obsp++) != 0) { FOR_PROVIDES(p2, pp2, obs) { Solvable *s2 = pool->solvables + p2; if (s2->repo != installed) continue; if (!pool->obsoleteusesprovides && !pool_match_nevr(pool, pool->solvables + p2, obs)) continue; if (pool->obsoleteusescolors && !pool_colormatch(pool, s, s2)) continue; queue_pushunique(&qo, obs); break; } } } } if (!qo.count) { queue_free(&qo); return; } queue_init(&yumobsinfoq); queue_init(&qq); for (i = 0; i < qo.count; i++) { int group, groupk, groupstart; queue_empty(&qq); #if 0 printf("investigating %s\n", pool_dep2str(pool, qo.elements[i])); #endif find_obsolete_group(solv, qo.elements[i], &qq); #if 0 printf("result:\n"); for (j = 0; j < qq.count; j++) if (qq.elements[j] == 0) printf("---\n"); else printf("%s\n", pool_solvid2str(pool, qq.elements[j])); #endif if (!qq.count) continue; /* at least two goups, build rules */ group = 0; for (j = 0; j < qq.count; j++) { p = qq.elements[j]; if (!p) { group++; continue; } if (pool->solvables[p].repo == installed) continue; groupk = 0; groupstart = 0; for (k = 0; k < qq.count; k++) { Id pk = qq.elements[k]; if (pk) continue; if (group != groupk && k > groupstart) { /* add the rule */ if (k - groupstart == 1) solver_addrule(solv, -p, qq.elements[groupstart], 0); else solver_addrule(solv, -p, 0, pool_ids2whatprovides(pool, qq.elements + groupstart, k - groupstart)); queue_push(&yumobsinfoq, qo.elements[i]); } groupstart = k + 1; groupk++; } } } if (yumobsinfoq.count) solv->yumobsrules_info = solv_memdup2(yumobsinfoq.elements, yumobsinfoq.count, sizeof(Id)); queue_free(&yumobsinfoq); queue_free(&qq); queue_free(&qo); solv->yumobsrules_end = solv->nrules; POOL_DEBUG(SOLV_DEBUG_STATS, "yumobs rule creation took %d ms\n", solv_timems(now)); } #undef CLEANDEPSDEBUG /* * This functions collects all packages that are looked at * when a dependency is checked. We need it to "pin" installed * packages when removing a supplemented package in createcleandepsmap. * Here's an not uncommon example: * A contains "Supplements: packageand(B, C)" * B contains "Requires: A" * Now if we remove C, the supplements is no longer true, * thus we also remove A. Without the dep_pkgcheck function, we * would now also remove B, but this is wrong, as adding back * C doesn't make the supplements true again. Thus we "pin" B * when we remove A. * There's probably a better way to do this, but I haven't come * up with it yet ;) */ static inline void dep_pkgcheck(Solver *solv, Id dep, Map *m, Queue *q) { Pool *pool = solv->pool; Id p, pp; if (ISRELDEP(dep)) { Reldep *rd = GETRELDEP(pool, dep); if (rd->flags >= 8) { if (rd->flags == REL_AND) { dep_pkgcheck(solv, rd->name, m, q); dep_pkgcheck(solv, rd->evr, m, q); return; } if (rd->flags == REL_NAMESPACE && rd->name == NAMESPACE_SPLITPROVIDES) return; } } FOR_PROVIDES(p, pp, dep) if (!m || MAPTST(m, p)) queue_push(q, p); } static int check_xsupp(Solver *solv, Queue *depq, Id dep) { Pool *pool = solv->pool; Id p, pp; if (ISRELDEP(dep)) { Reldep *rd = GETRELDEP(pool, dep); if (rd->flags >= 8) { if (rd->flags == REL_AND) { if (!check_xsupp(solv, depq, rd->name)) return 0; return check_xsupp(solv, depq, rd->evr); } if (rd->flags == REL_OR) { if (check_xsupp(solv, depq, rd->name)) return 1; return check_xsupp(solv, depq, rd->evr); } if (rd->flags == REL_NAMESPACE && rd->name == NAMESPACE_SPLITPROVIDES) #if 0 return solver_splitprovides(solv, rd->evr); #else return 0; #endif } if (depq && rd->flags == REL_NAMESPACE) { int i; for (i = 0; i < depq->count; i++) if (depq->elements[i] == dep || depq->elements[i] == rd->name) return 1; } } FOR_PROVIDES(p, pp, dep) if (p == SYSTEMSOLVABLE || pool->solvables[p].repo == solv->installed) return 1; return 0; } static inline int queue_contains(Queue *q, Id id) { int i; for (i = 0; i < q->count; i++) if (q->elements[i] == id) return 1; return 0; } #ifdef ENABLE_COMPLEX_DEPS static void complex_cleandeps_remove(Pool *pool, Id ip, Id req, Map *im, Map *installedm, Queue *iq) { int i; Queue dq; Id p; queue_init(&dq); i = pool_normalize_complex_dep(pool, req, &dq, CPLXDEPS_EXPAND); if (i == 0 || i == 1) { queue_free(&dq); return; } for (i = 0; i < dq.count; i++) { for (; (p = dq.elements[i]) != 0; i++) { if (p < 0) { if (!MAPTST(installedm, -p)) break; continue; } if (p != SYSTEMSOLVABLE && MAPTST(im, p)) { #ifdef CLEANDEPSDEBUG printf("%s requires/recommends %s\n", pool_solvid2str(pool, ip), pool_solvid2str(pool, p)); #endif queue_push(iq, p); } } while (dq.elements[i]) i++; } queue_free(&dq); } static void complex_cleandeps_addback(Pool *pool, Id ip, Id req, Map *im, Map *installedm, Queue *iq, Map *userinstalled) { int i, blk; Queue dq; Id p; queue_init(&dq); i = pool_normalize_complex_dep(pool, req, &dq, CPLXDEPS_EXPAND); if (i == 0 || i == 1) { queue_free(&dq); return; } for (i = 0; i < dq.count; i++) { blk = i; for (; (p = dq.elements[i]) != 0; i++) { if (p < 0) { if (!MAPTST(installedm, -p)) break; continue; } if (MAPTST(im, p)) break; } if (!p) { for (i = blk; (p = dq.elements[i]) != 0; i++) { if (p < 0) continue; if (!MAPTST(installedm, p)) continue; if (p == ip || MAPTST(userinstalled, p - pool->installed->start)) continue; #ifdef CLEANDEPSDEBUG printf("%s requires/recommends %s\n", pool_solvid2str(pool, ip), pool_solvid2str(pool, p)); #endif MAPSET(im, p); queue_push(iq, p); } } while (dq.elements[i]) i++; } queue_free(&dq); } #endif /* * Find all installed packages that are no longer * needed regarding the current solver job. * * The algorithm is: * - remove pass: remove all packages that could have * been dragged in by the obsoleted packages. * i.e. if package A is obsolete and contains "Requires: B", * also remove B, as installing A will have pulled in B. * after this pass, we have a set of still installed packages * with broken dependencies. * - add back pass: * now add back all packages that the still installed packages * require. * * The cleandeps packages are the packages removed in the first * pass and not added back in the second pass. * * If we search for unneeded packages (unneeded is true), we * simply remove all packages except the userinstalled ones in * the first pass. */ static void solver_createcleandepsmap(Solver *solv, Map *cleandepsmap, int unneeded) { Pool *pool = solv->pool; Repo *installed = solv->installed; Queue *job = &solv->job; Map userinstalled; Map im; Map installedm; Rule *r; Id rid, how, what, select; Id p, pp, ip, jp; Id req, *reqp, sup, *supp; Solvable *s; Queue iq, iqcopy, xsuppq; int i; map_empty(cleandepsmap); if (!installed || installed->end == installed->start) return; map_init(&userinstalled, installed->end - installed->start); map_init(&im, pool->nsolvables); map_init(&installedm, pool->nsolvables); queue_init(&iq); queue_init(&xsuppq); for (i = 0; i < job->count; i += 2) { how = job->elements[i]; if ((how & SOLVER_JOBMASK) == SOLVER_USERINSTALLED) { what = job->elements[i + 1]; select = how & SOLVER_SELECTMASK; if (select == SOLVER_SOLVABLE_ALL || (select == SOLVER_SOLVABLE_REPO && what == installed->repoid)) FOR_REPO_SOLVABLES(installed, p, s) MAPSET(&userinstalled, p - installed->start); FOR_JOB_SELECT(p, pp, select, what) if (pool->solvables[p].repo == installed) MAPSET(&userinstalled, p - installed->start); } if ((how & (SOLVER_JOBMASK | SOLVER_SELECTMASK)) == (SOLVER_ERASE | SOLVER_SOLVABLE_PROVIDES)) { what = job->elements[i + 1]; if (ISRELDEP(what)) { Reldep *rd = GETRELDEP(pool, what); if (rd->flags != REL_NAMESPACE) continue; if (rd->evr == 0) { queue_pushunique(&iq, rd->name); continue; } FOR_PROVIDES(p, pp, what) if (p) break; if (p) continue; queue_pushunique(&iq, what); } } } /* have special namespace cleandeps erases */ if (iq.count) { for (ip = installed->start; ip < installed->end; ip++) { s = pool->solvables + ip; if (s->repo != installed) continue; if (!s->supplements) continue; supp = s->repo->idarraydata + s->supplements; while ((sup = *supp++) != 0) if (ISRELDEP(sup) && check_xsupp(solv, &iq, sup) && !check_xsupp(solv, 0, sup)) { #ifdef CLEANDEPSDEBUG printf("xsupp %s from %s\n", pool_dep2str(pool, sup), pool_solvid2str(pool, ip)); #endif queue_pushunique(&xsuppq, sup); } } queue_empty(&iq); } /* also add visible patterns to userinstalled for openSUSE */ if (1) { Dataiterator di; dataiterator_init(&di, pool, 0, 0, SOLVABLE_ISVISIBLE, 0, 0); while (dataiterator_step(&di)) { Id *dp; if (di.solvid <= 0) continue; s = pool->solvables + di.solvid; if (!s->repo || !s->requires) continue; if (s->repo != installed && !pool_installable(pool, s)) continue; if (strncmp(pool_id2str(pool, s->name), "pattern:", 8) != 0) continue; dp = s->repo->idarraydata + s->requires; for (dp = s->repo->idarraydata + s->requires; *dp; dp++) FOR_PROVIDES(p, pp, *dp) if (pool->solvables[p].repo == installed) { if (strncmp(pool_id2str(pool, pool->solvables[p].name), "pattern", 7) != 0) continue; MAPSET(&userinstalled, p - installed->start); } } dataiterator_free(&di); } if (1) { /* all products and their buddies are userinstalled */ for (p = installed->start; p < installed->end; p++) { Solvable *s = pool->solvables + p; if (s->repo != installed) continue; if (!strncmp("product:", pool_id2str(pool, s->name), 8)) { MAPSET(&userinstalled, p - installed->start); #ifdef ENABLE_LINKED_PKGS if (solv->instbuddy && solv->instbuddy[p - installed->start] > 1) { Id buddy = solv->instbuddy[p - installed->start]; if (buddy >= installed->start && buddy < installed->end) MAPSET(&userinstalled, buddy - installed->start); } #endif } } } /* add all positive elements (e.g. locks) to "userinstalled" */ for (rid = solv->jobrules; rid < solv->jobrules_end; rid++) { r = solv->rules + rid; if (r->d < 0) continue; i = solv->ruletojob.elements[rid - solv->jobrules]; if ((job->elements[i] & SOLVER_CLEANDEPS) == SOLVER_CLEANDEPS) continue; FOR_RULELITERALS(p, jp, r) if (p > 0 && pool->solvables[p].repo == installed) MAPSET(&userinstalled, p - installed->start); } /* add all cleandeps candidates to iq */ for (rid = solv->jobrules; rid < solv->jobrules_end; rid++) { r = solv->rules + rid; if (r->d < 0) /* disabled? */ continue; if (r->d == 0 && r->p < 0 && r->w2 == 0) /* negative assertion (erase job)? */ { p = -r->p; if (pool->solvables[p].repo != installed) continue; MAPCLR(&userinstalled, p - installed->start); if (unneeded) continue; i = solv->ruletojob.elements[rid - solv->jobrules]; how = job->elements[i]; if ((how & (SOLVER_JOBMASK|SOLVER_CLEANDEPS)) == (SOLVER_ERASE|SOLVER_CLEANDEPS)) queue_push(&iq, p); } else if (r->p > 0) /* install job */ { if (unneeded) continue; i = solv->ruletojob.elements[rid - solv->jobrules]; if ((job->elements[i] & SOLVER_CLEANDEPS) == SOLVER_CLEANDEPS) { /* check if the literals all obsolete some installed package */ Map om; int iqstart; /* just one installed literal */ if (r->d == 0 && r->w2 == 0 && pool->solvables[r->p].repo == installed) continue; /* multiversion is bad */ if (solv->multiversion.size && !solv->keepexplicitobsoletes) { FOR_RULELITERALS(p, jp, r) if (MAPTST(&solv->multiversion, p)) break; if (p) continue; } om.size = 0; iqstart = iq.count; FOR_RULELITERALS(p, jp, r) { if (p < 0) { queue_truncate(&iq, iqstart); /* abort */ break; } if (pool->solvables[p].repo == installed) { if (iq.count == iqstart) queue_push(&iq, p); else { for (i = iqstart; i < iq.count; i++) if (iq.elements[i] == p) break; queue_truncate(&iq, iqstart); if (i < iq.count) queue_push(&iq, p); } } else intersect_obsoletes(solv, p, &iq, iqstart, &om); if (iq.count == iqstart) break; } if (om.size) map_free(&om); } } } queue_init_clone(&iqcopy, &iq); if (!unneeded) { if (solv->cleandeps_updatepkgs) for (i = 0; i < solv->cleandeps_updatepkgs->count; i++) queue_push(&iq, solv->cleandeps_updatepkgs->elements[i]); } if (unneeded) queue_empty(&iq); /* just in case... */ /* clear userinstalled bit for the packages we really want to delete/update */ for (i = 0; i < iq.count; i++) { p = iq.elements[i]; if (pool->solvables[p].repo != installed) continue; MAPCLR(&userinstalled, p - installed->start); } for (p = installed->start; p < installed->end; p++) { if (pool->solvables[p].repo != installed) continue; MAPSET(&installedm, p); if (unneeded && !MAPTST(&userinstalled, p - installed->start)) continue; MAPSET(&im, p); } MAPSET(&installedm, SYSTEMSOLVABLE); MAPSET(&im, SYSTEMSOLVABLE); #ifdef CLEANDEPSDEBUG printf("REMOVE PASS\n"); #endif for (;;) { if (!iq.count) { if (unneeded) break; /* supplements pass */ for (ip = installed->start; ip < installed->end; ip++) { if (!MAPTST(&installedm, ip)) continue; s = pool->solvables + ip; if (!s->supplements) continue; if (!MAPTST(&im, ip)) continue; if (MAPTST(&userinstalled, ip - installed->start)) continue; supp = s->repo->idarraydata + s->supplements; while ((sup = *supp++) != 0) if (dep_possible(solv, sup, &im)) break; if (!sup) { supp = s->repo->idarraydata + s->supplements; while ((sup = *supp++) != 0) if (dep_possible(solv, sup, &installedm) || (xsuppq.count && queue_contains(&xsuppq, sup))) { /* no longer supplemented, also erase */ int iqcount = iq.count; /* pin packages, see comment above dep_pkgcheck */ dep_pkgcheck(solv, sup, &im, &iq); for (i = iqcount; i < iq.count; i++) { Id pqp = iq.elements[i]; if (pool->solvables[pqp].repo == installed) MAPSET(&userinstalled, pqp - installed->start); } queue_truncate(&iq, iqcount); #ifdef CLEANDEPSDEBUG printf("%s supplemented [%s]\n", pool_solvid2str(pool, ip), pool_dep2str(pool, sup)); #endif queue_push(&iq, ip); } } } if (!iq.count) break; /* no supplementing package found, we're done */ } ip = queue_shift(&iq); s = pool->solvables + ip; if (!MAPTST(&im, ip)) continue; if (!MAPTST(&installedm, ip)) continue; if (s->repo == installed && MAPTST(&userinstalled, ip - installed->start)) continue; MAPCLR(&im, ip); #ifdef CLEANDEPSDEBUG printf("removing %s\n", pool_solvable2str(pool, s)); #endif if (s->requires) { reqp = s->repo->idarraydata + s->requires; while ((req = *reqp++) != 0) { if (req == SOLVABLE_PREREQMARKER) continue; #ifdef ENABLE_COMPLEX_DEPS if (pool_is_complex_dep(pool, req)) { complex_cleandeps_remove(pool, ip, req, &im, &installedm, &iq); continue; } #endif FOR_PROVIDES(p, pp, req) { if (p != SYSTEMSOLVABLE && MAPTST(&im, p)) { #ifdef CLEANDEPSDEBUG printf("%s requires %s\n", pool_solvid2str(pool, ip), pool_solvid2str(pool, p)); #endif queue_push(&iq, p); } } } } if (s->recommends) { reqp = s->repo->idarraydata + s->recommends; while ((req = *reqp++) != 0) { #ifdef ENABLE_COMPLEX_DEPS if (pool_is_complex_dep(pool, req)) { complex_cleandeps_remove(pool, ip, req, &im, &installedm, &iq); continue; } #endif FOR_PROVIDES(p, pp, req) { if (p != SYSTEMSOLVABLE && MAPTST(&im, p)) { #ifdef CLEANDEPSDEBUG printf("%s recommends %s\n", pool_solvid2str(pool, ip), pool_solvid2str(pool, p)); #endif queue_push(&iq, p); } } } } } /* turn userinstalled into remove set for pruning */ map_empty(&userinstalled); for (rid = solv->jobrules; rid < solv->jobrules_end; rid++) { r = solv->rules + rid; if (r->p >= 0 || r->d != 0 || r->w2 != 0) continue; /* disabled or not erase */ p = -r->p; MAPCLR(&im, p); if (pool->solvables[p].repo == installed) MAPSET(&userinstalled, p - installed->start); } if (!unneeded && solv->cleandeps_updatepkgs) { for (i = 0; i < solv->cleandeps_updatepkgs->count; i++) { p = solv->cleandeps_updatepkgs->elements[i]; if (pool->solvables[p].repo == installed) MAPSET(&userinstalled, p - installed->start); } } MAPSET(&im, SYSTEMSOLVABLE); /* in case we cleared it above */ for (p = installed->start; p < installed->end; p++) if (MAPTST(&im, p)) queue_push(&iq, p); for (rid = solv->jobrules; rid < solv->jobrules_end; rid++) { r = solv->rules + rid; if (r->d < 0) continue; FOR_RULELITERALS(p, jp, r) if (p > 0) queue_push(&iq, p); } /* also put directly addressed packages on the install queue * so we can mark patterns as installed */ for (i = 0; i < job->count; i += 2) { how = job->elements[i]; if ((how & SOLVER_JOBMASK) == SOLVER_USERINSTALLED) { what = job->elements[i + 1]; select = how & SOLVER_SELECTMASK; if (select == SOLVER_SOLVABLE && pool->solvables[what].repo != installed) queue_push(&iq, what); } } #ifdef CLEANDEPSDEBUG printf("ADDBACK PASS\n"); #endif for (;;) { if (!iq.count) { /* supplements pass */ for (ip = installed->start; ip < installed->end; ip++) { if (!MAPTST(&installedm, ip)) continue; if (MAPTST(&userinstalled, ip - installed->start)) continue; s = pool->solvables + ip; if (!s->supplements) continue; if (MAPTST(&im, ip)) continue; supp = s->repo->idarraydata + s->supplements; while ((sup = *supp++) != 0) if (dep_possible(solv, sup, &im)) break; if (sup) { #ifdef CLEANDEPSDEBUG printf("%s supplemented\n", pool_solvid2str(pool, ip)); #endif MAPSET(&im, ip); queue_push(&iq, ip); } } if (!iq.count) break; } ip = queue_shift(&iq); s = pool->solvables + ip; #ifdef CLEANDEPSDEBUG printf("adding back %s\n", pool_solvable2str(pool, s)); #endif if (s->requires) { reqp = s->repo->idarraydata + s->requires; while ((req = *reqp++) != 0) { #ifdef ENABLE_COMPLEX_DEPS if (pool_is_complex_dep(pool, req)) { complex_cleandeps_addback(pool, ip, req, &im, &installedm, &iq, &userinstalled); continue; } #endif FOR_PROVIDES(p, pp, req) if (MAPTST(&im, p)) break; if (p) continue; FOR_PROVIDES(p, pp, req) { if (MAPTST(&installedm, p)) { if (p == ip) continue; if (MAPTST(&userinstalled, p - installed->start)) continue; #ifdef CLEANDEPSDEBUG printf("%s requires %s\n", pool_solvid2str(pool, ip), pool_solvid2str(pool, p)); #endif MAPSET(&im, p); queue_push(&iq, p); } } } } if (s->recommends) { reqp = s->repo->idarraydata + s->recommends; while ((req = *reqp++) != 0) { #ifdef ENABLE_COMPLEX_DEPS if (pool_is_complex_dep(pool, req)) { complex_cleandeps_addback(pool, ip, req, &im, &installedm, &iq, &userinstalled); continue; } #endif FOR_PROVIDES(p, pp, req) if (MAPTST(&im, p)) break; if (p) continue; FOR_PROVIDES(p, pp, req) { if (MAPTST(&installedm, p)) { if (p == ip) continue; if (MAPTST(&userinstalled, p - installed->start)) continue; #ifdef CLEANDEPSDEBUG printf("%s recommends %s\n", pool_solvid2str(pool, ip), pool_solvid2str(pool, p)); #endif MAPSET(&im, p); queue_push(&iq, p); } } } } } queue_free(&iq); /* make sure the updatepkgs and mistakes are not in the cleandeps map */ if (solv->cleandeps_updatepkgs) for (i = 0; i < solv->cleandeps_updatepkgs->count; i++) MAPSET(&im, solv->cleandeps_updatepkgs->elements[i]); if (solv->cleandeps_mistakes) for (i = 0; i < solv->cleandeps_mistakes->count; i++) MAPSET(&im, solv->cleandeps_mistakes->elements[i]); /* also remove original iq packages */ for (i = 0; i < iqcopy.count; i++) MAPSET(&im, iqcopy.elements[i]); queue_free(&iqcopy); for (p = installed->start; p < installed->end; p++) { if (pool->solvables[p].repo != installed) continue; if (!MAPTST(&im, p)) MAPSET(cleandepsmap, p - installed->start); } map_free(&im); map_free(&installedm); map_free(&userinstalled); queue_free(&xsuppq); #ifdef CLEANDEPSDEBUG printf("=== final cleandeps map:\n"); for (p = installed->start; p < installed->end; p++) if (MAPTST(cleandepsmap, p - installed->start)) printf(" - %s\n", pool_solvid2str(pool, p)); #endif } struct trj_data { Queue *edges; Id *low; Id idx; Id nstack; Id firstidx; }; /* Tarjan's SCC algorithm, slightly modifed */ static void trj_visit(struct trj_data *trj, Id node) { Id *low = trj->low; Queue *edges = trj->edges; Id nnode, myidx, stackstart; int i; low[node] = myidx = trj->idx++; low[(stackstart = trj->nstack++)] = node; for (i = edges->elements[node]; (nnode = edges->elements[i]) != 0; i++) { Id l = low[nnode]; if (!l) { if (!edges->elements[edges->elements[nnode]]) { trj->idx++; low[nnode] = -1; continue; } trj_visit(trj, nnode); l = low[nnode]; } if (l < 0) continue; if (l < trj->firstidx) { int k; for (k = l; low[low[k]] == l; k++) low[low[k]] = -1; } else if (l < low[node]) low[node] = l; } if (low[node] == myidx) { if (myidx != trj->firstidx) myidx = -1; for (i = stackstart; i < trj->nstack; i++) low[low[i]] = myidx; trj->nstack = stackstart; } } #ifdef ENABLE_COMPLEX_DEPS static void complex_unneeded(Pool *pool, Id ip, Id req, Queue *edges, Map *cleandepsmap, Queue *unneededq) { int i, j; Queue dq; Id p; queue_init(&dq); i = pool_normalize_complex_dep(pool, req, &dq, CPLXDEPS_EXPAND); if (i == 0 || i == 1) { queue_free(&dq); return; } for (i = 0; i < dq.count; i++) { for (; (p = dq.elements[i]) != 0; i++) { if (p < 0) { if (pool->solvables[-p].repo != pool->installed) break; continue; } if (p == ip || pool->solvables[p].repo != pool->installed || !MAPTST(cleandepsmap, p - pool->installed->start)) continue; for (j = 0; j < unneededq->count; j++) if (p == unneededq->elements[j]) { if (edges->elements[edges->count - 1] != j + 1) queue_push(edges, j + 1); break; } } while (dq.elements[i]) i++; } queue_free(&dq); } #endif void solver_get_unneeded(Solver *solv, Queue *unneededq, int filtered) { Repo *installed = solv->installed; int i; Map cleandepsmap; queue_empty(unneededq); if (!installed || installed->end == installed->start) return; map_init(&cleandepsmap, installed->end - installed->start); solver_createcleandepsmap(solv, &cleandepsmap, 1); for (i = installed->start; i < installed->end; i++) if (MAPTST(&cleandepsmap, i - installed->start)) queue_push(unneededq, i); if (filtered && unneededq->count > 1) { Pool *pool = solv->pool; Queue edges; Id *nrequires; Map installedm; int j, pass, count = unneededq->count; Id *low; map_init(&installedm, pool->nsolvables); for (i = installed->start; i < installed->end; i++) if (pool->solvables[i].repo == installed) MAPSET(&installedm, i); nrequires = solv_calloc(count, sizeof(Id)); queue_init(&edges); queue_prealloc(&edges, count * 4 + 10); /* pre-size */ /* * Go through the solvables in the nodes queue and create edges for * all requires/recommends/supplements between the nodes. * The edges are stored in the edges queue, we add 1 to the node * index so that nodes in the edges queue are != 0 and we can * terminate the edge list with 0. * Thus for node element 5, the edges are stored starting at * edges.elements[6] and are 0-terminated. */ /* leave first element zero to make things easier */ /* also add trailing zero */ queue_insertn(&edges, 0, 1 + count + 1, 0); /* first requires and recommends */ for (i = 0; i < count; i++) { Solvable *s = pool->solvables + unneededq->elements[i]; int oldcount = edges.count; edges.elements[i + 1] = oldcount; for (pass = 0; pass < 2; pass++) { unsigned int off = pass == 0 ? s->requires : s->recommends; Id p, pp, dep, *dp; if (off) for (dp = s->repo->idarraydata + off; (dep = *dp) != 0; dp++) { #ifdef ENABLE_COMPLEX_DEPS if (pool_is_complex_dep(pool, dep)) { complex_unneeded(pool, s - pool->solvables, dep, &edges, &cleandepsmap, unneededq); continue; } #endif FOR_PROVIDES(p, pp, dep) { Solvable *sp = pool->solvables + p; if (s == sp || sp->repo != installed || !MAPTST(&cleandepsmap, p - installed->start)) continue; for (j = 0; j < count; j++) if (p == unneededq->elements[j]) { if (edges.elements[edges.count - 1] != j + 1) queue_push(&edges, j + 1); } } } if (pass == 0) nrequires[i] = edges.count - oldcount; } queue_push(&edges, 0); } #if 0 printf("requires + recommends\n"); for (i = 0; i < count; i++) { int j; printf(" %s (%d requires):\n", pool_solvid2str(pool, unneededq->elements[i]), nrequires[i]); for (j = edges.elements[i + 1]; edges.elements[j]; j++) printf(" - %s\n", pool_solvid2str(pool, unneededq->elements[edges.elements[j] - 1])); } #endif /* then add supplements */ for (i = 0; i < count; i++) { Solvable *s = pool->solvables + unneededq->elements[i]; if (s->supplements) { Id *dp; int k; for (dp = s->repo->idarraydata + s->supplements; *dp; dp++) if (dep_possible(solv, *dp, &installedm)) { Queue iq; Id iqbuf[16]; queue_init_buffer(&iq, iqbuf, sizeof(iqbuf)/sizeof(*iqbuf)); dep_pkgcheck(solv, *dp, 0, &iq); for (k = 0; k < iq.count; k++) { Id p = iq.elements[k]; Solvable *sp = pool->solvables + p; if (p == unneededq->elements[i] || sp->repo != installed || !MAPTST(&cleandepsmap, p - installed->start)) continue; for (j = 0; j < count; j++) if (p == unneededq->elements[j]) break; /* now add edge from j + 1 to i + 1 */ queue_insert(&edges, edges.elements[j + 1] + nrequires[j], i + 1); /* addapt following edge pointers */ for (j = j + 2; j < count + 1; j++) edges.elements[j]++; } queue_free(&iq); } } } #if 0 /* print result */ printf("+ supplements\n"); for (i = 0; i < count; i++) { int j; printf(" %s (%d requires):\n", pool_solvid2str(pool, unneededq->elements[i]), nrequires[i]); for (j = edges.elements[i + 1]; edges.elements[j]; j++) printf(" - %s\n", pool_solvid2str(pool, unneededq->elements[edges.elements[j] - 1])); } #endif map_free(&installedm); /* now run SCC algo two times, first with requires+recommends+supplements, * then again without the requires. We run it the second time to get rid * of packages that got dragged in via recommends/supplements */ /* * low will contain the result of the SCC search. * it must be of at least size 2 * (count + 1) and * must be zero initialized. * The layout is: * 0 low low ... low stack stack ...stack 0 * count count */ low = solv_calloc(count + 1, 2 * sizeof(Id)); for (pass = 0; pass < 2; pass++) { struct trj_data trj; if (pass) { memset(low, 0, (count + 1) * (2 * sizeof(Id))); for (i = 0; i < count; i++) { edges.elements[i + 1] += nrequires[i]; if (!unneededq->elements[i]) low[i + 1] = -1; /* ignore this node */ } } trj.edges = &edges; trj.low = low; trj.idx = count + 1; /* stack starts here */ for (i = 1; i <= count; i++) { if (low[i]) continue; if (edges.elements[edges.elements[i]]) { trj.firstidx = trj.nstack = trj.idx; trj_visit(&trj, i); } else { Id myidx = trj.idx++; low[i] = myidx; low[myidx] = i; } } /* prune packages */ for (i = 0; i < count; i++) if (low[i + 1] <= 0) unneededq->elements[i] = 0; } solv_free(low); solv_free(nrequires); queue_free(&edges); /* finally remove all pruned entries from unneededq */ for (i = j = 0; i < count; i++) if (unneededq->elements[i]) unneededq->elements[j++] = unneededq->elements[i]; queue_truncate(unneededq, j); } map_free(&cleandepsmap); } void solver_breakorphans(Solver *solv) { Pool *pool = solv->pool; Repo *installed = solv->installed; int i, rid; Map m; if (!installed || solv->droporphanedmap_all) return; solv->brokenorphanrules = solv_calloc(1, sizeof(Queue)); queue_init(solv->brokenorphanrules); map_init(&m, installed->end - installed->start); for (i = 0; i < solv->orphaned.count; i++) { Id p = solv->orphaned.elements[i]; if (pool->solvables[p].repo != installed) continue; if (solv->droporphanedmap.size && MAPTST(&solv->droporphanedmap, p - installed->start)) continue; MAPSET(&m, p - installed->start); } for (rid = 1; rid < solv->pkgrules_end ; rid++) { Id p, *dp; Rule *r = solv->rules + rid; /* ignore non-deps and simple conflicts */ if (r->p >= 0 || ((r->d == 0 || r->d == -1) && r->w2 < 0)) continue; p = -r->p; if (p < installed->start || p >= installed->end || !MAPTST(&m, p - installed->start)) { /* need to check other literals */ if (r->d == 0 || r->d == -1) continue; for (dp = pool->whatprovidesdata + (r->d < 0 ? -r->d - 1 : r->d); *dp < 0; dp++) { p = -*dp; if (p >= installed->start && p < installed->end && MAPTST(&m, p - installed->start)) break; } if (*dp >= 0) continue; } /* ok, disable this rule */ queue_push(solv->brokenorphanrules, rid); if (r->d >= 0) solver_disablerule(solv, r); } map_free(&m); if (!solv->brokenorphanrules->count) { queue_free(solv->brokenorphanrules); solv->brokenorphanrules = solv_free(solv->brokenorphanrules); } } void solver_check_brokenorphanrules(Solver *solv, Queue *dq) { Pool *pool = solv->pool; int i; Id l, pp; queue_empty(dq); if (!solv->brokenorphanrules) return; for (i = 0; i < solv->brokenorphanrules->count; i++) { int rid = solv->brokenorphanrules->elements[i]; Rule *r = solv->rules + rid; FOR_RULELITERALS(l, pp, r) { if (l < 0) { if (solv->decisionmap[-l] <= 0) break; } else { if (solv->decisionmap[l] > 0 && pool->solvables[l].repo != solv->installed) break; } } if (l) continue; FOR_RULELITERALS(l, pp, r) if (l > 0 && solv->decisionmap[l] == 0 && pool->solvables[l].repo != solv->installed) queue_pushunique(dq, l); } }