/* pkg_depends.c - the itsy package management system Steven M. Ayer Copyright (C) 2002 Compaq Computer Corporation This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. */ #include "ipkg.h" #include #include #include "pkg.h" #include "ipkg_utils.h" #include "pkg_hash.h" #include "ipkg_message.h" #include "pkg_parse.h" #include "hash_table.h" static int parseDepends(compound_depend_t *compound_depend, hash_table_t * hash, char * depend_str); static depend_t * depend_init(void); static void depend_deinit(depend_t *d); static char ** add_unresolved_dep(pkg_t * pkg, char ** the_lost, int ref_ndx); static char ** merge_unresolved(char ** oldstuff, char ** newstuff); static int is_pkg_in_pkg_vec(pkg_vec_t * vec, pkg_t * pkg); static int pkg_installed_and_constraint_satisfied(pkg_t *pkg, void *cdata) { depend_t *depend = (depend_t *)cdata; if ((pkg->state_status == SS_INSTALLED || pkg->state_status == SS_UNPACKED) && version_constraints_satisfied(depend, pkg)) return 1; else return 0; } static int pkg_constraint_satisfied(pkg_t *pkg, void *cdata) { depend_t *depend = (depend_t *)cdata; #if 0 pkg_t * temp = pkg_new(); int comparison; parseVersion(temp, depend->version); comparison = pkg_compare_versions(pkg, temp); free(temp); fprintf(stderr, "%s: pkg=%s pkg->version=%s constraint=%p type=%d version=%s comparison=%d satisfied=%d\n", __FUNCTION__, pkg->name, pkg->version, depend, depend->constraint, depend->version, comparison, version_constraints_satisfied(depend, pkg)); #endif if (version_constraints_satisfied(depend, pkg)) return 1; else return 0; } /* returns ndependences or negative error value */ int pkg_hash_fetch_unsatisfied_dependencies(ipkg_conf_t *conf, pkg_t * pkg, pkg_vec_t *unsatisfied, char *** unresolved) { pkg_t * satisfier_entry_pkg; register int i, j, k; int count, found; char ** the_lost; abstract_pkg_t * ab_pkg; /* * this is a setup to check for redundant/cyclic dependency checks, * which are marked at the abstract_pkg level */ if (!(ab_pkg = pkg->parent)) { fprintf(stderr, "%s:%d: something terribly wrong with pkg %s\n", __FUNCTION__, __LINE__, pkg->name); *unresolved = NULL; return 0; } if (ab_pkg->dependencies_checked) { /* avoid duplicate or cyclic checks */ *unresolved = NULL; return 0; } else { ab_pkg->dependencies_checked = 1; /* mark it for subsequent visits */ } /**/ count = pkg->pre_depends_count + pkg->depends_count + pkg->recommends_count + pkg->suggests_count; if (!count){ *unresolved = NULL; return 0; } the_lost = NULL; /* foreach dependency */ for (i = 0; i < count; i++) { compound_depend_t * compound_depend = &pkg->depends[i]; depend_t ** possible_satisfiers = compound_depend->possibilities;; found = 0; satisfier_entry_pkg = NULL; if (compound_depend->type == GREEDY_DEPEND) { /* foreach possible satisfier */ for (j = 0; j < compound_depend->possibility_count; j++) { /* foreach provided_by, which includes the abstract_pkg itself */ abstract_pkg_t *abpkg = possible_satisfiers[j]->pkg; abstract_pkg_vec_t *ab_provider_vec = abpkg->provided_by; int nposs = ab_provider_vec->len; abstract_pkg_t **ab_providers = ab_provider_vec->pkgs; int l; for (l = 0; l < nposs; l++) { pkg_vec_t *test_vec = ab_providers[l]->pkgs; /* if no depends on this one, try the first package that Provides this one */ if (!test_vec){ /* no pkg_vec hooked up to the abstract_pkg! (need another feed?) */ continue; } /* cruise this possiblity's pkg_vec looking for an installed version */ for (k = 0; k < test_vec->len; k++) { pkg_t *pkg_scout = test_vec->pkgs[k]; /* not installed, and not already known about? */ if ((pkg_scout->state_want != SW_INSTALL) && !pkg_scout->parent->dependencies_checked && !is_pkg_in_pkg_vec(unsatisfied, pkg_scout)) { char ** newstuff = NULL; int rc; pkg_vec_t *tmp_vec = pkg_vec_alloc (); /* check for not-already-installed dependencies */ rc = pkg_hash_fetch_unsatisfied_dependencies(conf, pkg_scout, tmp_vec, &newstuff); if (newstuff == NULL) { int i; int ok = 1; for (i = 0; i < rc; i++) { pkg_t *p = tmp_vec->pkgs[i]; if (p->state_want == SW_INSTALL) continue; ipkg_message(conf, IPKG_DEBUG, "not installing %s due to requirement for %s\n", pkg_scout->name, p->name); ok = 0; break; } pkg_vec_free (tmp_vec); if (ok) { /* mark this one for installation */ ipkg_message(conf, IPKG_NOTICE, "Adding satisfier for greedy dependence: %s\n", pkg_scout->name); pkg_vec_insert(unsatisfied, pkg_scout); } } else { ipkg_message(conf, IPKG_DEBUG, "not installing %s due to broken depends \n", pkg_scout->name); free (newstuff); } } } } } continue; } /* foreach possible satisfier, look for installed package */ for (j = 0; j < compound_depend->possibility_count; j++) { /* foreach provided_by, which includes the abstract_pkg itself */ depend_t *dependence_to_satisfy = possible_satisfiers[j]; abstract_pkg_t *satisfying_apkg = possible_satisfiers[j]->pkg; pkg_t *satisfying_pkg = pkg_hash_fetch_best_installation_candidate(conf, satisfying_apkg, pkg_installed_and_constraint_satisfied, dependence_to_satisfy, 1); /* Being that I can't test constraing in pkg_hash, I will test it here */ if (satisfying_pkg != NULL) { if (!pkg_installed_and_constraint_satisfied ( satisfying_pkg,dependence_to_satisfy)) { satisfying_pkg = NULL; } } ipkg_message(conf, IPKG_DEBUG, "%s:%d: satisfying_pkg=%p \n", __FILE__, __LINE__, satisfying_pkg); if (satisfying_pkg != NULL) { found = 1; break; } } /* if nothing installed matches, then look for uninstalled satisfier */ if (!found) { /* foreach possible satisfier, look for installed package */ for (j = 0; j < compound_depend->possibility_count; j++) { /* foreach provided_by, which includes the abstract_pkg itself */ depend_t *dependence_to_satisfy = possible_satisfiers[j]; abstract_pkg_t *satisfying_apkg = possible_satisfiers[j]->pkg; pkg_t *satisfying_pkg = pkg_hash_fetch_best_installation_candidate(conf, satisfying_apkg, pkg_constraint_satisfied, dependence_to_satisfy, 1); /* Being that I can't test constraing in pkg_hash, I will test it here too */ if (satisfying_pkg != NULL) { if (!pkg_constraint_satisfied ( satisfying_pkg,dependence_to_satisfy)) { satisfying_pkg = NULL; } } /* user request overrides package recommendation */ if (satisfying_pkg != NULL && (compound_depend->type == RECOMMEND || compound_depend->type == SUGGEST) && (satisfying_pkg->state_want == SW_DEINSTALL || satisfying_pkg->state_want == SW_PURGE)) { ipkg_message (conf, IPKG_NOTICE, "%s: ignoring recommendation for %s at user request\n", pkg->name, satisfying_pkg->name); continue; } ipkg_message(conf, IPKG_DEBUG, "%s:%d: satisfying_pkg=%p\n", __FILE__, __LINE__, satisfying_pkg); if (satisfying_pkg != NULL) { satisfier_entry_pkg = satisfying_pkg; break; } } } /* we didn't find one, add something to the unsatisfied vector */ if (!found) { if (!satisfier_entry_pkg) { /* failure to meet recommendations is not an error */ if (compound_depend->type != RECOMMEND && compound_depend->type != SUGGEST) the_lost = add_unresolved_dep(pkg, the_lost, i); else ipkg_message (conf, IPKG_NOTICE, "%s: unsatisfied recommendation for %s\n", pkg->name, compound_depend->possibilities[0]->pkg->name); } else { if (compound_depend->type == SUGGEST) { /* just mention it politely */ ipkg_message (conf, IPKG_NOTICE, "package %s suggests installing %s\n", pkg->name, satisfier_entry_pkg->name); } else { char ** newstuff = NULL; if (satisfier_entry_pkg != pkg && !is_pkg_in_pkg_vec(unsatisfied, satisfier_entry_pkg)) { pkg_vec_insert(unsatisfied, satisfier_entry_pkg); pkg_hash_fetch_unsatisfied_dependencies(conf, satisfier_entry_pkg, unsatisfied, &newstuff); the_lost = merge_unresolved(the_lost, newstuff); } } } } } *unresolved = the_lost; return unsatisfied->len; } /*checking for conflicts !in replaces If a packages conflicts with another but is also replacing it, I should not consider it a really conflicts returns 0 if conflicts <> replaces or 1 if conflicts == replaces */ int is_pkg_a_replaces(pkg_t *pkg_scout,pkg_t *pkg) { int i ; int replaces_count = pkg->replaces_count; abstract_pkg_t **replaces; if (pkg->replaces_count==0) // No replaces, it's surely a conflict return 0; replaces = pkg->replaces; for (i = 0; i < replaces_count; i++) { if (strcmp(pkg_scout->name,pkg->replaces[i]->name)==0) { // Found ipkg_message(NULL, IPKG_DEBUG2, "Seems I've found a replace %s %s \n",pkg_scout->name,pkg->replaces[i]->name); return 1; } } return 0; } /* Abhaya: added support for conflicts */ pkg_vec_t * pkg_hash_fetch_conflicts(hash_table_t * hash, pkg_t * pkg) { pkg_vec_t * installed_conflicts, * test_vec; compound_depend_t * conflicts; depend_t ** possible_satisfiers; depend_t * possible_satisfier; register int i, j, k; int count; abstract_pkg_t * ab_pkg; pkg_t **pkg_scouts; pkg_t *pkg_scout; /* * this is a setup to check for redundant/cyclic dependency checks, * which are marked at the abstract_pkg level */ if(!(ab_pkg = pkg->parent)){ fprintf(stderr, "dependency check error. pkg %s isn't in hash table\n", pkg->name); return (pkg_vec_t *)NULL; } conflicts = pkg->conflicts; if(!conflicts){ return (pkg_vec_t *)NULL; } installed_conflicts = pkg_vec_alloc(); count = pkg->conflicts_count; /* foreach conflict */ for(i = 0; i < pkg->conflicts_count; i++){ possible_satisfiers = conflicts->possibilities; /* foreach possible satisfier */ for(j = 0; j < conflicts->possibility_count; j++){ possible_satisfier = possible_satisfiers[j]; if (!possible_satisfier) fprintf(stderr, "%s:%d: possible_satisfier is null\n", __FUNCTION__, __LINE__); if (!possible_satisfier->pkg) fprintf(stderr, "%s:%d: possible_satisfier->pkg is null\n", __FUNCTION__, __LINE__); test_vec = possible_satisfier->pkg->pkgs; if (test_vec) { /* pkg_vec found, it is an actual package conflict * cruise this possiblity's pkg_vec looking for an installed version */ pkg_scouts = test_vec->pkgs; for(k = 0; k < test_vec->len; k++){ pkg_scout = pkg_scouts[k]; if (!pkg_scout) { fprintf(stderr, "%s: null pkg scout\n", __FUNCTION__); continue; } if ((pkg_scout->state_status == SS_INSTALLED || pkg_scout->state_want == SW_INSTALL) && version_constraints_satisfied(possible_satisfier, pkg_scout) && !is_pkg_a_replaces(pkg_scout,pkg)){ if (!is_pkg_in_pkg_vec(installed_conflicts, pkg_scout)){ pkg_vec_insert(installed_conflicts, pkg_scout); } } } } } conflicts++; } if (installed_conflicts->len) return installed_conflicts; pkg_vec_free(installed_conflicts); return (pkg_vec_t *)NULL; } int version_constraints_satisfied(depend_t * depends, pkg_t * pkg) { pkg_t * temp; int comparison; if(depends->constraint == NONE) return 1; temp = pkg_new(); parseVersion(temp, depends->version); comparison = pkg_compare_versions(pkg, temp); free(temp); if((depends->constraint == EARLIER) && (comparison < 0)) return 1; else if((depends->constraint == LATER) && (comparison > 0)) return 1; else if(comparison == 0) return 1; else if((depends->constraint == LATER_EQUAL) && (comparison >= 0)) return 1; else if((depends->constraint == EARLIER_EQUAL) && (comparison <= 0)) return 1; return 0; } int pkg_dependence_satisfiable(ipkg_conf_t *conf, depend_t *depend) { abstract_pkg_t *apkg = depend->pkg; abstract_pkg_vec_t *provider_apkgs = apkg->provided_by; int n_providers = provider_apkgs->len; abstract_pkg_t **apkgs = provider_apkgs->pkgs; pkg_vec_t *pkg_vec; int n_pkgs ; int i; int j; for (i = 0; i < n_providers; i++) { abstract_pkg_t *papkg = apkgs[i]; pkg_vec = papkg->pkgs; if (pkg_vec) { n_pkgs = pkg_vec->len; for (j = 0; j < n_pkgs; j++) { pkg_t *pkg = pkg_vec->pkgs[j]; if (version_constraints_satisfied(depend, pkg)) { return 1; } } } } return 0; } int pkg_dependence_satisfied(ipkg_conf_t *conf, depend_t *depend) { abstract_pkg_t *apkg = depend->pkg; abstract_pkg_vec_t *provider_apkgs = apkg->provided_by; int n_providers = provider_apkgs->len; abstract_pkg_t **apkgs = provider_apkgs->pkgs; int i; int n_pkgs; int j; for (i = 0; i < n_providers; i++) { abstract_pkg_t *papkg = apkgs[i]; pkg_vec_t *pkg_vec = papkg->pkgs; if (pkg_vec) { n_pkgs = pkg_vec->len; for (j = 0; j < n_pkgs; j++) { pkg_t *pkg = pkg_vec->pkgs[j]; if (version_constraints_satisfied(depend, pkg)) { if (pkg->state_status == SS_INSTALLED || pkg->state_status == SS_UNPACKED) return 1; } } } } return 0; } static int is_pkg_in_pkg_vec(pkg_vec_t * vec, pkg_t * pkg) { register int i; pkg_t ** pkgs = vec->pkgs; for(i = 0; i < vec->len; i++) if((strcmp(pkg->name, (*(pkgs + i))->name) == 0) && (pkg_compare_versions(pkg, *(pkgs + i)) == 0) && (strcmp(pkg->architecture, (*(pkgs + i))->architecture) == 0)) return 1; return 0; } #ifdef DeadCode /** * pkg_has_common_provides returns 1 if pkg and replacee both provide * the same abstract package and 0 otherwise. */ int pkg_has_common_provides(pkg_t *pkg, pkg_t *replacee) { abstract_pkg_t **provides = pkg->provides; int provides_count = pkg->provides_count; abstract_pkg_t **replacee_provides = replacee->provides; int replacee_provides_count = replacee->provides_count; int i, j; for (i = 0; i < provides_count; i++) { abstract_pkg_t *apkg = provides[i]; for (j = 0; j < replacee_provides_count; j++) { abstract_pkg_t *replacee_apkg = replacee_provides[i]; if (apkg == replacee_apkg) return 1; } } return 0; } #endif /** * pkg_provides_abstract returns 1 if pkg->provides contains providee * and 0 otherwise. */ int pkg_provides_abstract(pkg_t *pkg, abstract_pkg_t *providee) { abstract_pkg_t **provides = pkg->provides; int provides_count = pkg->provides_count; int i; for (i = 0; i < provides_count; i++) { if (provides[i] == providee) return 1; } return 0; } /** * pkg_replaces returns 1 if pkg->replaces contains one of replacee's provides and 0 * otherwise. */ int pkg_replaces(pkg_t *pkg, pkg_t *replacee) { abstract_pkg_t **replaces = pkg->replaces; int replaces_count = pkg->replaces_count; /* abstract_pkg_t **replacee_provides = pkg->provides; int replacee_provides_count = pkg->provides_count; */ int i, j; for (i = 0; i < replaces_count; i++) { abstract_pkg_t *abstract_replacee = replaces[i]; for (j = 0; j < replaces_count; j++) { /* ipkg_message(NULL, IPKG_DEBUG2, "Searching pkg-name %s repprovname %s absrepname %s \n", pkg->name,replacee->provides[j]->name, abstract_replacee->name); */ if (replacee->provides[j] == abstract_replacee) return 1; } } return 0; } /** * pkg_conflicts_abstract returns 1 if pkg->conflicts contains conflictee and 0 * otherwise. */ int pkg_conflicts_abstract(pkg_t *pkg, abstract_pkg_t *conflictee) { compound_depend_t *conflicts = pkg->conflicts; int conflicts_count = pkg->conflicts_count; int i, j; for (i = 0; i < conflicts_count; i++) { int possibility_count = conflicts[i].possibility_count; struct depend **possibilities = conflicts[i].possibilities; for (j = 0; j < possibility_count; j++) { if (possibilities[j]->pkg == conflictee) { return 1; } } } return 0; } /** * pkg_conflicts returns 1 if pkg->conflicts contains one of * conflictee's provides and 0 otherwise. */ int pkg_conflicts(pkg_t *pkg, pkg_t *conflictee) { compound_depend_t *conflicts = pkg->conflicts; int conflicts_count = pkg->conflicts_count; abstract_pkg_t **conflictee_provides = conflictee->provides; int conflictee_provides_count = conflictee->provides_count; int i, j, k; int possibility_count; struct depend **possibilities; abstract_pkg_t *possibility ; for (i = 0; i < conflicts_count; i++) { possibility_count = conflicts[i].possibility_count; possibilities = conflicts[i].possibilities; for (j = 0; j < possibility_count; j++) { possibility = possibilities[j]->pkg; for (k = 0; k < conflictee_provides_count; k++) { if (possibility == conflictee_provides[k]) { return 1; } } } } return 0; } static char ** merge_unresolved(char ** oldstuff, char ** newstuff) { int oldlen = 0, newlen = 0; char ** result; register int i, j; if(!newstuff) return oldstuff; while(oldstuff && oldstuff[oldlen]) oldlen++; while(newstuff && newstuff[newlen]) newlen++; result = (char **)realloc(oldstuff, sizeof(char *) * (oldlen + newlen + 1)); if (result == NULL) { fprintf(stderr, "%s: out of memory\n", __FUNCTION__); return NULL; } for(i = oldlen, j = 0; i < (oldlen + newlen); i++, j++) *(result + i) = *(newstuff + j); *(result + i) = NULL; return result; } /* * a kinda kludgy way to back out depends str from two different arrays (reg'l'r 'n pre) * this is null terminated, no count is carried around */ char ** add_unresolved_dep(pkg_t * pkg, char ** the_lost, int ref_ndx) { int count; char ** resized; char *depend_str = pkg_depend_str(pkg, ref_ndx); count = 0; while(the_lost && the_lost[count]) count++; count++; /* need one to hold the null */ resized = (char **)realloc(the_lost, sizeof(char *) * (count + 1)); if (resized == NULL) { fprintf(stderr, "%s: out of memory\n", __FUNCTION__); return NULL; } resized[count - 1] = strdup(depend_str); resized[count] = NULL; return resized; } void printDepends(pkg_t * pkg) { register int i, j; compound_depend_t * depend; int count; count = pkg->pre_depends_count + pkg->depends_count; depend = pkg->depends; if(!depend){ fprintf(stderr, "Depends pointer is NULL\n"); return; } for(i = 0; i < count; i++){ fprintf(stderr, "%s has %d possibilities:\n", (depend->type == GREEDY_DEPEND) ? "Greedy-Depend" : ((depend->type == DEPEND) ? "Depend" : "Pre-Depend"), depend->possibility_count); for(j = 0; j < depend->possibility_count; j++) fprintf(stderr, "\t%s version %s (%d)\n", depend->possibilities[j]->pkg->name, depend->possibilities[j]->version, depend->possibilities[j]->constraint); depend++; } } int buildProvides(hash_table_t * hash, abstract_pkg_t * ab_pkg, pkg_t * pkg) { register int i, j; /* every pkg provides itself */ abstract_pkg_vec_insert(ab_pkg->provided_by, ab_pkg); if (!pkg->provides_count) return 0; pkg->provides = (abstract_pkg_t **)malloc(sizeof(abstract_pkg_t *) * (pkg->provides_count + 1)); if (pkg->provides == NULL) { fprintf(stderr, "%s: out of memory\n", __FUNCTION__); return -1 ; } pkg->provides[0] = ab_pkg; // if (strcmp(ab_pkg->name, pkg->name)) // fprintf(stderr, __FUNCTION__ ": ab_pkg=%s pkg=%s\n", ab_pkg->name, pkg->name); for(i = 0; i < pkg->provides_count; i++){ abstract_pkg_t *provided_abpkg = ensure_abstract_pkg_by_name(hash, pkg->provides_str[i]); pkg->provides[i+1] = provided_abpkg; j = 0; abstract_pkg_vec_insert(provided_abpkg->provided_by, ab_pkg); } return 0; } /* Abhaya: added conflicts support */ int buildConflicts(hash_table_t * hash, abstract_pkg_t * ab_pkg, pkg_t * pkg) { register int i; compound_depend_t * conflicts; if (!pkg->conflicts_count) return 0; conflicts = pkg->conflicts = malloc(sizeof(compound_depend_t) * pkg->conflicts_count); if (conflicts == NULL) { fprintf(stderr, "%s: out of memory\n", __FUNCTION__); return -1; } for (i = 0; i < pkg->conflicts_count; i++) { conflicts->type = CONFLICTS; parseDepends(conflicts, hash, pkg->conflicts_str[i]); #if 0 for (j = 0; j < conflicts->possibility_count; j++) { depend_t *possibility = conflicts->possibilities[j]; abstract_pkg_t *conflicting_apkg = possibility->pkg; pkg_add_conflict_pair(ab_pkg, conflicting_apkg); } #endif conflicts++; } return 0; } int buildReplaces(hash_table_t * hash, abstract_pkg_t * ab_pkg, pkg_t * pkg) { register int i, j; if (!pkg->replaces_count) return 0; pkg->replaces = (abstract_pkg_t **)malloc(sizeof(abstract_pkg_t *) * pkg->replaces_count); if (pkg->replaces == NULL) { fprintf(stderr, "%s: out of memory\n", __FUNCTION__); return -1; } // if (strcmp(ab_pkg->name, pkg->name)) // fprintf(stderr, __FUNCTION__ ": ab_pkg=%s pkg=%s\n", ab_pkg->name, pkg->name); for(i = 0; i < pkg->replaces_count; i++){ abstract_pkg_t *old_abpkg = ensure_abstract_pkg_by_name(hash, pkg->replaces_str[i]); pkg->replaces[i] = old_abpkg; j = 0; if (!old_abpkg->replaced_by) old_abpkg->replaced_by = abstract_pkg_vec_alloc(); if ( old_abpkg->replaced_by == NULL ){ return -1; } /* if a package pkg both replaces and conflicts old_abpkg, * then add it to the replaced_by vector so that old_abpkg * will be upgraded to ab_pkg automatically */ if (pkg_conflicts_abstract(pkg, old_abpkg)) abstract_pkg_vec_insert(old_abpkg->replaced_by, ab_pkg); } return 0; } int buildDepends(hash_table_t * hash, pkg_t * pkg) { int count; register int i; compound_depend_t * depends; if(!(count = pkg->pre_depends_count + pkg->depends_count + pkg->recommends_count + pkg->suggests_count)) return 0; if (0 && pkg->pre_depends_count) fprintf(stderr, "pkg=%s pre_depends_count=%d depends_count=%d\n", pkg->name, pkg->pre_depends_count, pkg->depends_count); depends = pkg->depends = malloc(sizeof(compound_depend_t) * count); if (depends == NULL) { fprintf(stderr, "%s: out of memory\n", __FUNCTION__); return -1; } for(i = 0; i < pkg->pre_depends_count; i++){ parseDepends(depends, hash, pkg->pre_depends_str[i]); if (0 && pkg->pre_depends_count) fprintf(stderr, " pre_depends_str=%s depends=%p possibility_count=%x\n", pkg->pre_depends_str[i], depends, depends->possibility_count); depends->type = PREDEPEND; depends++; } for(i = 0; i < pkg->recommends_count; i++){ parseDepends(depends, hash, pkg->recommends_str[i]); if (0 && pkg->recommends_count) fprintf(stderr, " recommends_str=%s depends=%p possibility_count=%x\n", pkg->recommends_str[i], depends, depends->possibility_count); depends->type = RECOMMEND; depends++; } for(i = 0; i < pkg->suggests_count; i++){ parseDepends(depends, hash, pkg->suggests_str[i]); if (0 && pkg->suggests_count) fprintf(stderr, " suggests_str=%s depends=%p possibility_count=%x\n", pkg->suggests_str[i], depends, depends->possibility_count); depends->type = SUGGEST; depends++; } for(i = 0; i < pkg->depends_count; i++){ parseDepends(depends, hash, pkg->depends_str[i]); if (0 && pkg->depends_count) fprintf(stderr, " depends_str=%s depends=%p possibility_count=%x\n", pkg->depends_str[i], depends, depends->possibility_count); depends++; } return 0; } /* * pkg_depend_string: returns the depends string specified by index. * All 4 kinds of dependences: dependence, pre-dependence, recommend, and suggest are number starting from 0. * [0,npredepends) -> returns pre_depends_str[index] * [npredepends,npredepends+nrecommends) -> returns recommends_str[index] * [npredepends+nrecommends,npredepends+nrecommends+nsuggests) -> returns recommends_str[index] * [npredepends+nrecommends+nsuggests,npredepends+nrecommends+nsuggests+ndepends) -> returns depends_str[index] */ char *pkg_depend_str(pkg_t *pkg, int index) { if (index < pkg->pre_depends_count) { return pkg->pre_depends_str[index]; } index -= pkg->pre_depends_count; if (index < pkg->recommends_count) { return pkg->recommends_str[index]; } index -= pkg->recommends_count; if (index < pkg->suggests_count) { return pkg->suggests_str[index]; } index -= pkg->suggests_count; if (index < pkg->depends_count) { return pkg->depends_str[index]; } fprintf(stderr, "pkg_depend_str: index %d out of range for pkg=%s\n", index, pkg->name); return NULL; } void freeDepends(pkg_t *pkg) { int i; if (pkg == NULL || pkg->depends == NULL) { return; } fprintf(stderr, "Freeing depends=%p\n", pkg->depends); for (i=0; i < pkg->depends->possibility_count; i++) { depend_deinit(pkg->depends->possibilities[i]); } free(pkg->depends->possibilities); free(pkg->depends); pkg->depends = NULL; } void buildDependedUponBy(pkg_t * pkg, abstract_pkg_t * ab_pkg) { compound_depend_t * depends; int count, othercount; register int i, j; abstract_pkg_t * ab_depend; abstract_pkg_t ** temp; count = pkg->pre_depends_count + pkg->depends_count; depends = pkg->depends; if (0 && pkg->pre_depends_count) fprintf(stderr, "pkg=%s pre_depends_count=%d depends_count=%d\n", pkg->name, pkg->pre_depends_count, pkg->depends_count); for (i = 0; i < count; i++) { if (0 && pkg->pre_depends_count) fprintf(stderr, " i=%d possibility_count=%x depends=%p\n", i, depends->possibility_count, depends); for (j = 0; j < depends->possibility_count; j++){ ab_depend = depends->possibilities[j]->pkg; if(!ab_depend->depended_upon_by) ab_depend->depended_upon_by = (abstract_pkg_t **)calloc(1, sizeof(abstract_pkg_t *)); temp = ab_depend->depended_upon_by; othercount = 1; while(*temp){ temp++; othercount++; } *temp = ab_pkg; ab_depend->depended_upon_by = (abstract_pkg_t **)realloc(ab_depend->depended_upon_by, (othercount + 1) * sizeof(abstract_pkg_t *)); /* the array may have moved */ temp = ab_depend->depended_upon_by + othercount; *temp = NULL; } depends++; } } static depend_t * depend_init(void) { depend_t * d = (depend_t *)malloc(sizeof(depend_t)); if ( d==NULL ){ fprintf(stderr, "%s: out of memory\n", __FUNCTION__); return NULL; } d->constraint = NONE; d->version = NULL; d->pkg = NULL; return d; } static void depend_deinit(depend_t *d) { free(d); } static int parseDepends(compound_depend_t *compound_depend, hash_table_t * hash, char * depend_str) { char * pkg_name, buffer[2048]; int num_of_ors = 0; register int i; register char * src, * dest; depend_t ** possibilities; /* first count the number of ored possibilities for satisfying dependency */ src = depend_str; while(*src) if(*src++ == '|') num_of_ors++; compound_depend->type = DEPEND; compound_depend->possibility_count = num_of_ors + 1; possibilities = (depend_t **)malloc(sizeof(depend_t *) * (num_of_ors + 1)); if (!possibilities) return -ENOMEM; compound_depend->possibilities = possibilities; src = depend_str; for(i = 0; i < num_of_ors + 1; i++){ possibilities[i] = depend_init(); if (!possibilities[i]) return -ENOMEM; /* gobble up just the name first */ dest = buffer; while(*src && !isspace(*src) && (*src != '(') && (*src != '*') && (*src != '|')) *dest++ = *src++; *dest = '\0'; pkg_name = trim_alloc(buffer); if (pkg_name == NULL ) return -ENOMEM; /* now look at possible version info */ /* skip to next chars */ if(isspace(*src)) while(*src && isspace(*src)) src++; /* extract constraint and version */ if(*src == '('){ src++; if(!strncmp(src, "<<", 2)){ possibilities[i]->constraint = EARLIER; src += 2; } else if(!strncmp(src, "<=", 2)){ possibilities[i]->constraint = EARLIER_EQUAL; src += 2; } else if(!strncmp(src, ">=", 2)){ possibilities[i]->constraint = LATER_EQUAL; src += 2; } else if(!strncmp(src, ">>", 2)){ possibilities[i]->constraint = LATER; src += 2; } else if(!strncmp(src, "=", 1)){ possibilities[i]->constraint = EQUAL; src++; } /* should these be here to support deprecated designations; dpkg does */ else if(!strncmp(src, "<", 1)){ possibilities[i]->constraint = EARLIER_EQUAL; src++; } else if(!strncmp(src, ">", 1)){ possibilities[i]->constraint = LATER_EQUAL; src++; } /* now we have any constraint, pass space to version string */ while(isspace(*src)) src++; /* this would be the version string */ dest = buffer; while(*src && *src != ')') *dest++ = *src++; *dest = '\0'; possibilities[i]->version = trim_alloc(buffer); /* fprintf(stderr, "let's print the depends version string:"); fprintf(stderr, "version %s\n", possibilities[i]->version);*/ if (possibilities[i]->version == NULL ) return -ENOMEM; } /* hook up the dependency to its abstract pkg */ possibilities[i]->pkg = ensure_abstract_pkg_by_name(hash, pkg_name); free(pkg_name); /* now get past the ) and any possible | chars */ while(*src && (isspace(*src) || (*src == ')') || (*src == '|'))) src++; if (*src == '*') { compound_depend->type = GREEDY_DEPEND; src++; } } return 0; }