/* solver.c - Alpine Package Keeper (APK)
* A backtracking, forward checking dependency graph solver.
*
* Copyright (C) 2008-2012 Timo Teräs <timo.teras@iki.fi>
* All rights reserved.
*
* This program is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License version 2 as published
* by the Free Software Foundation. See http://www.gnu.org/ for details.
*/
#include <stdint.h>
#include "apk_defines.h"
#include "apk_database.h"
#include "apk_package.h"
#include "apk_solver.h"
#include "apk_print.h"
//#define DEBUG_PRINT
#define DEBUG_CHECKS
#ifdef DEBUG_PRINT
#include <stdio.h>
#define dbg_printf(args...) fprintf(stderr, args)
#else
#define dbg_printf(args...)
#endif
#if defined(DEBUG_PRINT) || defined(DEBUG_CHECKS)
#define ASSERT(cond, fmt...) \
if (!(cond)) { fprintf(stderr, fmt); *(char*)NULL = 0; }
#else
#define ASSERT(cond, fmt...)
#endif
struct apk_score {
union {
struct {
#if __BYTE_ORDER__ == __ORDER_LITTLE_ENDIAN__
unsigned short preference;
unsigned short non_preferred_actions;
unsigned int conflicts;
#elif __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__
unsigned int conflicts;
unsigned short non_preferred_actions;
unsigned short preference;
#else
#error Unknown endianess.
#endif
};
uint64_t score;
};
};
#define SCORE_FMT "{%d/%d/%d}"
#define SCORE_PRINTF(s) (s)->conflicts, (s)->non_preferred_actions, (s)->preference
enum {
DECISION_ASSIGN = 0,
DECISION_EXCLUDE
};
enum {
BRANCH_NO,
BRANCH_YES,
};
struct apk_decision {
union {
struct apk_name *name;
struct apk_package *pkg;
};
#ifdef DEBUG_CHECKS
struct apk_score saved_score;
unsigned short saved_requirers;
#endif
unsigned no_package : 1;
unsigned type : 1;
unsigned branching_point : 1;
unsigned topology_position : 1;
unsigned found_solution : 1;
};
struct apk_package_state {
unsigned int topology_soft;
unsigned short conflicts;
unsigned char preference;
unsigned handle_install_if : 1;
unsigned locked : 1;
};
struct apk_name_state {
struct list_head unsolved_list;
struct apk_name *name;
struct apk_package *chosen;
struct apk_score minimum_penalty;
unsigned short requirers;
unsigned short install_ifs;
/* set on startup */
unsigned short preferred_pinning;
unsigned short maybe_pinning;
/* dynamic */
unsigned int last_touched_decision;
unsigned short allowed_pinning;
unsigned short inherited_pinning[APK_MAX_TAGS];
unsigned short inherited_upgrade;
unsigned short inherited_reinstall;
/* one time prepare/finish flags */
unsigned solver_flags_local : 4;
unsigned solver_flags_local_mask : 4;
unsigned solver_flags_maybe : 4;
unsigned decision_counted : 1;
unsigned originally_installed : 1;
unsigned has_available_pkgs : 1;
unsigned in_changeset : 1;
unsigned in_world_dependency : 1;
/* dynamic state flags */
unsigned none_excluded : 1;
unsigned locked : 1;
unsigned name_touched : 1;
};
struct apk_solver_state {
struct apk_database *db;
struct apk_decision *decisions;
struct list_head unsolved_list_head;
unsigned int num_topology_positions;
unsigned int num_decisions, max_decisions;
unsigned int topology_position;
unsigned int assigned_names;
struct apk_solution_array *best_solution;
struct apk_score score;
struct apk_score minimum_penalty;
struct apk_score best_score;
unsigned solver_flags : 4;
};
typedef enum {
SOLVERR_SOLUTION = 0,
SOLVERR_PRUNED,
SOLVERR_EXPAND,
SOLVERR_STOP,
} solver_result_t;
static void apply_constraint(struct apk_solver_state *ss, struct apk_dependency *dep);
static void undo_constraint(struct apk_solver_state *ss, struct apk_dependency *dep);
static solver_result_t push_decision(struct apk_solver_state *ss,
struct apk_name *name,
struct apk_package *pkg,
int primary_decision,
int branching_point,
int topology_position);
#if 0
static void addscore(struct apk_score *a, struct apk_score *b)
{
a->conflicts += b->conflicts;
a->non_preferred_actions += b->non_preferred_actions;
a->preference += b->preference;
}
static void subscore(struct apk_score *a, struct apk_score *b)
{
a->conflicts -= b->conflicts;
a->non_preferred_actions -= b->non_preferred_actions;
a->preference -= b->preference;
}
static inline int cmpscore(struct apk_score *a, struct apk_score *b)
{
if (a->conflicts < b->conflicts)
return -1;
if (a->conflicts > b->conflicts)
return 1;
if (a->non_preferred_actions < b->non_preferred_actions)
return -1;
if (a->non_preferred_actions > b->non_preferred_actions)
return 1;
if (a->preference < b->preference)
return -1;
if (a->preference > b->preference)
return 1;
return 0;
}
static inline int cmpscore2(struct apk_score *a1, struct apk_score *a2, struct apk_score *b)
{
if (a1->conflicts + a2->conflicts < b->conflicts)
return -1;
if (a1->conflicts + a2->conflicts > b->conflicts)
return 1;
if (a1->non_preferred_actions + a2->non_preferred_actions < b->non_preferred_actions)
return -1;
if (a1->non_preferred_actions + a2->non_preferred_actions > b->non_preferred_actions)
return 1;
if (a1->preference + a2->preference < b->preference)
return -1;
if (a1->preference + a2->preference > b->preference)
return 1;
return 0;
}
#else
static void addscore(struct apk_score *a, struct apk_score *b)
{
a->score += b->score;
}
static void subscore(struct apk_score *a, struct apk_score *b)
{
a->score -= b->score;
}
static inline int cmpscore(struct apk_score *a, struct apk_score *b)
{
if (a->score < b->score) return -1;
if (a->score > b->score) return 1;
return 0;
}
static inline int cmpscore2(struct apk_score *a1, struct apk_score *a2, struct apk_score *b)
{
struct apk_score a;
a.score = a1->score + a2->score;
if (a.score < b->score) return -1;
if (a.score > b->score) return 1;
return 0;
}
#endif
static struct apk_name *decision_to_name(struct apk_decision *d)
{
if (d->no_package)
return d->name;
return d->pkg->name;
}
static struct apk_package *decision_to_pkg(struct apk_decision *d)
{
if (d->no_package)
return NULL;
return d->pkg;
}
static struct apk_package_state *pkg_to_ps(struct apk_package *pkg)
{
return (struct apk_package_state*) pkg->state_ptr;
}
static struct apk_name_state *name_to_ns(struct apk_name *name)
{
return (struct apk_name_state*) name->state_ptr;
}
static struct apk_name_state *name_to_ns_alloc(struct apk_name *name)
{
struct apk_name_state *ns;
int i;
if (name->state_ptr == NULL) {
ns = calloc(1, sizeof(struct apk_name_state));
ns->name = name;
for (i = 0; i < name->pkgs->num; i++) {
if (name->pkgs->item[i]->repos != 0) {
ns->has_available_pkgs = 1;
break;
}
}
name->state_ptr = ns;
} else {
ns = (struct apk_name_state*) name->state_ptr;
}
return ns;
}
static inline int pkg_available(struct apk_solver_state *ss, struct apk_package *pkg)
{
struct apk_database *db = ss->db;
struct apk_name_state *ns = name_to_ns(pkg->name);
/* virtual packages - only deps used; no real .apk */
if (pkg->installed_size == 0)
return TRUE;
/* obviously present */
if (pkg->in_cache || pkg->filename != NULL)
return TRUE;
/* can download */
if ((pkg->repos & ~db->bad_repos) && !(apk_flags & APK_NO_NETWORK))
return TRUE;
/* installed, and no reinstall needed */
if ((pkg->ipkg != NULL) &&
(ns->inherited_reinstall == 0) &&
((ns->solver_flags_local|ss->solver_flags) & APK_SOLVERF_REINSTALL) == 0)
return TRUE;
return FALSE;
}
static void foreach_dependency_pkg(
struct apk_solver_state *ss, struct apk_dependency_array *depends,
void (*cb)(struct apk_solver_state *ss, struct apk_package *dependency))
{
int i, j;
/* And sort the main dependencies */
for (i = 0; i < depends->num; i++) {
struct apk_dependency *dep = &depends->item[i];
struct apk_name *name0 = dep->name;
for (j = 0; j < name0->pkgs->num; j++) {
struct apk_package *pkg0 = name0->pkgs->item[j];
/* conflict depends on all to be not installed */
if (!apk_dep_is_satisfied(dep, pkg0))
continue;
cb(ss, pkg0);
}
}
}
static void foreach_rinstall_if_pkg(
struct apk_solver_state *ss, struct apk_package *pkg,
void (*cb)(struct apk_solver_state *ss, struct apk_package *rinstall_if))
{
struct apk_name *name = pkg->name;
int i, j, k;
for (i = 0; i < pkg->name->rinstall_if->num; i++) {
struct apk_name *name0 = pkg->name->rinstall_if->item[i];
dbg_printf(PKG_VER_FMT ": rinstall_if %s\n",
PKG_VER_PRINTF(pkg), name0->name);
for (j = 0; j < name0->pkgs->num; j++) {
struct apk_package *pkg0 = name0->pkgs->item[j];
for (k = 0; k < pkg0->install_if->num; k++) {
struct apk_dependency *dep = &pkg0->install_if->item[k];
if (dep->name == name &&
apk_dep_is_satisfied(dep, pkg))
break;
}
if (k >= pkg0->install_if->num)
continue;
/* pkg depends (via install_if) on pkg0 */
cb(ss, pkg0);
}
}
}
static unsigned int get_pinning_mask_repos(struct apk_database *db, unsigned short pinning_mask)
{
unsigned int repository_mask = 0;
int i;
for (i = 0; i < db->num_repo_tags && pinning_mask; i++) {
if (!(BIT(i) & pinning_mask))
continue;
pinning_mask &= ~BIT(i);
repository_mask |= db->repo_tags[i].allowed_repos;
}
return repository_mask;
}
static void get_topology_score(
struct apk_solver_state *ss,
struct apk_name_state *ns,
struct apk_package *pkg,
struct apk_score *_score)
{
struct apk_package_state *ps = pkg_to_ps(pkg);
struct apk_score score;
unsigned int repos;
unsigned short preferred_pinning, allowed_pinning;
unsigned int preferred_repos, allowed_repos;
score = (struct apk_score) {
.conflicts = ps->conflicts,
.preference = ps->preference,
};
if (ss->solver_flags & APK_SOLVERF_AVAILABLE) {
/* not upgrading: it is not preferred to change package */
if ((pkg->repos == 0) && ns->has_available_pkgs)
score.non_preferred_actions++;
} else if ((ns->inherited_upgrade) == 0 &&
((ns->solver_flags_local|ss->solver_flags) & APK_SOLVERF_UPGRADE) == 0 &&
((ns->solver_flags_maybe & APK_SOLVERF_UPGRADE) == 0 || (ps->locked))) {
/* not upgrading: it is not preferred to change package */
if (pkg->ipkg == NULL && ns->originally_installed)
score.non_preferred_actions++;
}
repos = pkg->repos | (pkg->ipkg ? ss->db->repo_tags[pkg->ipkg->repository_tag].allowed_repos : 0);
preferred_pinning = ns->preferred_pinning ?: APK_DEFAULT_PINNING_MASK;
preferred_repos = get_pinning_mask_repos(ss->db, preferred_pinning);
if (!(repos & preferred_repos))
score.non_preferred_actions++;
if (ns->locked || (ns->allowed_pinning | ns->maybe_pinning) == ns->allowed_pinning) {
allowed_pinning = ns->allowed_pinning | preferred_pinning | APK_DEFAULT_PINNING_MASK;
allowed_repos = get_pinning_mask_repos(ss->db, allowed_pinning);
if (!(repos & allowed_repos))
score.non_preferred_actions+=2;
}
*_score = score;
}
static int is_topology_optimum(struct apk_solver_state *ss,
struct apk_package *pkg)
{
struct apk_name *name = pkg->name;
struct apk_name_state *ns = name_to_ns(name);
struct apk_score score;
int i;
get_topology_score(ss, ns, pkg, &score);
for (i = 0; i < name->pkgs->num; i++) {
struct apk_package *pkg0 = name->pkgs->item[i];
struct apk_package_state *ps0 = pkg_to_ps(pkg0);
struct apk_score score0;
if (pkg0 == pkg)
continue;
if (ps0 == NULL || ps0->locked ||
ss->topology_position < pkg->topology_hard)
continue;
get_topology_score(ss, ns, pkg0, &score0);
if (cmpscore(&score0, &score) < 0)
return 0;
}
return 1;
}
static int compare_absolute_package_preference(
struct apk_package *pkgA,
struct apk_package *pkgB)
{
/* specified on command line directly */
if (pkgA->filename && !pkgB->filename)
return 1;
if (pkgB->filename && !pkgA->filename)
return -1;
/* upgrading, or neither of the package is installed, so
* we just fall back comparing to versions */
switch (apk_pkg_version_compare(pkgA, pkgB)) {
case APK_VERSION_GREATER:
return 1;
case APK_VERSION_LESS:
return -1;
}
/* prefer the installed package */
if (pkgA->ipkg != NULL && pkgB->ipkg == NULL)
return 1;
if (pkgB->ipkg != NULL && pkgA->ipkg == NULL)
return -1;
/* prefer the one with lowest available repository */
return ffsl(pkgB->repos) - ffsl(pkgA->repos);
}
static void calculate_pkg_preference(struct apk_package *pkg)
{
struct apk_name *name = pkg->name;
struct apk_package_state *ps = pkg_to_ps(pkg);
int i;
for (i = 0; i < name->pkgs->num; i++) {
struct apk_package *pkg0 = name->pkgs->item[i];
if (pkg == pkg0)
continue;
if (compare_absolute_package_preference(pkg, pkg0) < 0)
ps->preference++;
}
}
static void count_name(struct apk_solver_state *ss, struct apk_name_state *ns)
{
if (!ns->decision_counted) {
ss->max_decisions++;
ns->decision_counted = 1;
}
}
static void sort_hard_dependencies(struct apk_solver_state *ss, struct apk_package *pkg)
{
struct apk_package_state *ps;
struct apk_name_state *ns;
if (pkg->state_ptr == NULL)
pkg->state_ptr = calloc(1, sizeof(struct apk_package_state));
ps = pkg_to_ps(pkg);
if (ps->topology_soft)
return;
pkg->topology_hard = -1;
ps->topology_soft = -1;
calculate_pkg_preference(pkg);
/* Consider hard dependencies only */
foreach_dependency_pkg(ss, pkg->depends, sort_hard_dependencies);
foreach_dependency_pkg(ss, pkg->install_if, sort_hard_dependencies);
ss->max_decisions++;
ns = name_to_ns_alloc(pkg->name);
count_name(ss, ns);
ps->topology_soft = pkg->topology_hard = ++ss->num_topology_positions;
dbg_printf(PKG_VER_FMT ": topology_hard=%d\n",
PKG_VER_PRINTF(pkg), pkg->topology_hard);
}
static void sort_soft_dependencies(struct apk_solver_state *ss, struct apk_package *pkg)
{
struct apk_package_state *ps;
sort_hard_dependencies(ss, pkg);
ps = pkg_to_ps(pkg);
if (ps->topology_soft != pkg->topology_hard)
return;
ps->topology_soft = -1;
/* Soft reverse dependencies aka. install_if */
foreach_rinstall_if_pkg(ss, pkg, sort_hard_dependencies);
foreach_dependency_pkg(ss, pkg->depends, sort_soft_dependencies);
/* Assign a topology sorting order */
ps->topology_soft = ++ss->num_topology_positions;
dbg_printf(PKG_VER_FMT ": topology_soft=%d\n",
PKG_VER_PRINTF(pkg), ps->topology_soft);
}
static void recalculate_maybe(struct apk_solver_state *ss, struct apk_name *name,
unsigned short flags, unsigned short pinning)
{
struct apk_name_state *ns = name_to_ns_alloc(name);
int propagate = FALSE;
int i, j;
if ((ns->maybe_pinning & pinning) != pinning) {
ns->maybe_pinning |= pinning;
propagate = TRUE;
}
if ((ns->solver_flags_maybe & flags) != flags) {
ns->solver_flags_maybe |= flags;
propagate = TRUE;
}
if (!propagate)
return;
for (i = 0; i < name->pkgs->num; i++) {
struct apk_package *pkg = name->pkgs->item[i];
for (j = 0; j < pkg->depends->num; j++) {
struct apk_dependency *dep = &pkg->depends->item[j];
struct apk_name *name0 = dep->name;
recalculate_maybe(ss, name0, flags, pinning);
}
}
for (i = 0; i < name->rinstall_if->num; i++) {
struct apk_name *name0 = name->rinstall_if->item[i];
recalculate_maybe(ss, name0, flags, pinning);
}
}
static void sort_name(struct apk_solver_state *ss, struct apk_name *name)
{
struct apk_name_state *ns = name_to_ns_alloc(name);
int i;
for (i = 0; i < name->pkgs->num; i++)
sort_soft_dependencies(ss, name->pkgs->item[i]);
count_name(ss, ns);
recalculate_maybe(ss, name,
ns->solver_flags_local & ns->solver_flags_local_mask,
ns->maybe_pinning);
}
static void foreach_dependency(struct apk_solver_state *ss, struct apk_dependency_array *deps,
void (*func)(struct apk_solver_state *ss, struct apk_dependency *dep))
{
int i;
for (i = 0; i < deps->num; i++)
func(ss, &deps->item[i]);
}
static int install_if_missing(struct apk_solver_state *ss, struct apk_package *pkg)
{
struct apk_name_state *ns;
int i, missing = 0;
for (i = 0; i < pkg->install_if->num; i++) {
struct apk_dependency *dep = &pkg->install_if->item[i];
ns = name_to_ns(dep->name);
/* ns can be NULL, if the install_if has a name with
* no packages */
if (ns == NULL || !ns->locked || !apk_dep_is_satisfied(dep, ns->chosen))
missing++;
}
return missing;
}
static void get_unassigned_score(struct apk_name *name, struct apk_score *score)
{
struct apk_name_state *ns = name_to_ns(name);
*score = (struct apk_score){
.conflicts = ns->requirers,
.preference = name->pkgs->num,
};
}
static int update_name_state(struct apk_solver_state *ss, struct apk_name *name)
{
struct apk_name_state *ns = name_to_ns(name);
struct apk_package *best_pkg = NULL, *preferred_pkg = NULL;
struct apk_score preferred_score;
unsigned int best_topology = 0;
int i, options = 0;
if (ns->locked)
return ns->chosen != NULL;
subscore(&ss->minimum_penalty, &ns->minimum_penalty);
ns->minimum_penalty = (struct apk_score) { .score = 0 };
ns->name_touched = 1;
get_unassigned_score(name, &preferred_score);
for (i = 0; i < name->pkgs->num; i++) {
struct apk_package *pkg0 = name->pkgs->item[i];
struct apk_package_state *ps0 = pkg_to_ps(pkg0);
struct apk_score pkg0_score;
if (ps0 == NULL || ps0->locked ||
ss->topology_position < pkg0->topology_hard ||
!pkg_available(ss, pkg0))
continue;
/* preferred - currently most optimal for end solution */
get_topology_score(ss, ns, pkg0, &pkg0_score);
if (preferred_pkg == NULL ||
cmpscore(&pkg0_score, &preferred_score) < 0) {
preferred_pkg = pkg0;
preferred_score = pkg0_score;
}
/* next in topology order - next to get locked in */
if (ps0->topology_soft < ss->topology_position &&
ps0->topology_soft > best_topology)
best_pkg = pkg0, best_topology = ps0->topology_soft;
else if (pkg0->topology_hard > best_topology)
best_pkg = pkg0, best_topology = pkg0->topology_hard;
options++;
}
if (ns->requirers == 0 && ns->install_ifs == 0) {
/* No one really needs this name (anymore). */
if (list_hashed(&ns->unsolved_list)) {
list_del(&ns->unsolved_list);
list_init(&ns->unsolved_list);
}
ns->chosen = NULL;
dbg_printf("%s: not required\n", name->name);
return options + 1;
}
if (!list_hashed(&ns->unsolved_list))
list_add_tail(&ns->unsolved_list, &ss->unsolved_list_head);
/* So far decided that something will be installed for this
* name. So assign the minimum penalty, and next position. */
ns->chosen = best_pkg;
ns->minimum_penalty = preferred_score;
addscore(&ss->minimum_penalty, &ns->minimum_penalty);
dbg_printf("%s: min.pen. " SCORE_FMT ", %d requirers, %d install_ifs, %d options (next topology %d)\n",
name->name,
SCORE_PRINTF(&ns->minimum_penalty),
ns->requirers, ns->install_ifs,
options, best_topology);
if (!ns->none_excluded) {
dbg_printf("%s: none not excluded yet\n", name->name);
return options + 1;
}
return options;
}
static void inherit_name_state(struct apk_database *db, struct apk_name *to, struct apk_name *from)
{
struct apk_name_state *tns = name_to_ns(to);
struct apk_name_state *fns = name_to_ns(from);
int i;
if ((fns->solver_flags_local & fns->solver_flags_local_mask & APK_SOLVERF_REINSTALL) ||
fns->inherited_reinstall)
tns->inherited_reinstall++;
if ((fns->solver_flags_local & fns->solver_flags_local_mask & APK_SOLVERF_UPGRADE) ||
fns->inherited_upgrade)
tns->inherited_upgrade++;
if (fns->allowed_pinning) {
for (i = 0; i < db->num_repo_tags; i++) {
if (!(fns->allowed_pinning & BIT(i)))
continue;
if (tns->inherited_pinning[i]++ == 0)
tns->allowed_pinning |= BIT(i);
}
}
}
static void uninherit_name_state(struct apk_database *db, struct apk_name *to, struct apk_name *from)
{
struct apk_name_state *tns = name_to_ns(to);
struct apk_name_state *fns = name_to_ns(from);
int i;
if ((fns->solver_flags_local & fns->solver_flags_local_mask & APK_SOLVERF_REINSTALL) ||
fns->inherited_reinstall)
tns->inherited_reinstall--;
if ((fns->solver_flags_local & fns->solver_flags_local_mask & APK_SOLVERF_UPGRADE) ||
fns->inherited_upgrade)
tns->inherited_upgrade--;
if (fns->allowed_pinning) {
for (i = 0; i < db->num_repo_tags; i++) {
if (!(fns->allowed_pinning & BIT(i)))
continue;
if (--tns->inherited_pinning[i] == 0)
tns->allowed_pinning &= ~BIT(i);
}
}
}
static void trigger_install_if(struct apk_solver_state *ss,
struct apk_package *pkg)
{
if (install_if_missing(ss, pkg) == 0) {
struct apk_name *name0 = decision_to_name(&ss->decisions[ss->num_decisions]);
struct apk_name_state *ns = name_to_ns(pkg->name);
dbg_printf("trigger_install_if: " PKG_VER_FMT " triggered\n",
PKG_VER_PRINTF(pkg));
ns->install_ifs++;
inherit_name_state(ss->db, pkg->name, name0);
update_name_state(ss, pkg->name);
}
}
static void untrigger_install_if(struct apk_solver_state *ss,
struct apk_package *pkg)
{
if (install_if_missing(ss, pkg) != 1) {
struct apk_name *name0 = decision_to_name(&ss->decisions[ss->num_decisions]);
struct apk_name_state *ns = name_to_ns(pkg->name);
dbg_printf("untrigger_install_if: " PKG_VER_FMT " no longer triggered\n",
PKG_VER_PRINTF(pkg));
ns->install_ifs--;
uninherit_name_state(ss->db, pkg->name, name0);
update_name_state(ss, pkg->name);
}
}
static solver_result_t apply_decision(struct apk_solver_state *ss,
struct apk_decision *d)
{
struct apk_name *name = decision_to_name(d);
struct apk_name_state *ns = name_to_ns(name);
struct apk_package *pkg = decision_to_pkg(d);
struct apk_score score;
ns->name_touched = 1;
if (pkg != NULL) {
struct apk_package_state *ps = pkg_to_ps(pkg);
dbg_printf("-->apply_decision: " PKG_VER_FMT " %s\n",
PKG_VER_PRINTF(pkg),
(d->type == DECISION_ASSIGN) ? "ASSIGN" : "EXCLUDE");
ps->locked = 1;
ps->handle_install_if = 0;
if (d->topology_position) {
if (ps->topology_soft < ss->topology_position) {
if (d->type == DECISION_ASSIGN) {
ps->handle_install_if = 1;
dbg_printf("triggers due to " PKG_VER_FMT "\n",
PKG_VER_PRINTF(pkg));
}
ss->topology_position = ps->topology_soft;
} else {
ss->topology_position = pkg->topology_hard;
}
}
if (d->type == DECISION_ASSIGN) {
subscore(&ss->minimum_penalty, &ns->minimum_penalty);
ns->minimum_penalty = (struct apk_score) { .score = 0 };
ns->locked = 1;
get_topology_score(ss, ns, pkg, &score);
addscore(&ss->score, &score);
if (cmpscore2(&ss->score, &ss->minimum_penalty, &ss->best_score) >= 0) {
dbg_printf("install causing "SCORE_FMT", penalty too big: "SCORE_FMT"+"SCORE_FMT">="SCORE_FMT"\n",
SCORE_PRINTF(&score),
SCORE_PRINTF(&ss->score),
SCORE_PRINTF(&ss->minimum_penalty),
SCORE_PRINTF(&ss->best_score));
subscore(&ss->score, &score);
ns->locked = 0;
return SOLVERR_PRUNED;
}
ss->assigned_names++;
ns->chosen = pkg;
list_del(&ns->unsolved_list);
list_init(&ns->unsolved_list);
foreach_dependency(ss, pkg->depends, apply_constraint);
foreach_rinstall_if_pkg(ss, pkg, trigger_install_if);
}
} else {
dbg_printf("-->apply_decision: %s %s NOTHING\n",
name->name,
(d->type == DECISION_ASSIGN) ? "ASSIGN" : "EXCLUDE");
if (d->type == DECISION_ASSIGN) {
subscore(&ss->minimum_penalty, &ns->minimum_penalty);
ns->minimum_penalty = (struct apk_score) { .score = 0 };
get_unassigned_score(name, &score);
addscore(&ss->score, &score);
ns->chosen = NULL;
ns->locked = 1;
list_del(&ns->unsolved_list);
list_init(&ns->unsolved_list);
} else {
ns->none_excluded = 1;
}
}
if (d->type == DECISION_EXCLUDE) {
if (update_name_state(ss, name) == 0) {
dbg_printf("%s: %s would prune name to empty\n",
name->name,
(d->type == DECISION_ASSIGN) ? "ASSIGN" : "EXCLUDE");
return SOLVERR_PRUNED;
}
}
if (cmpscore2(&ss->score, &ss->minimum_penalty, &ss->best_score) >= 0) {
dbg_printf("%s: %s penalty too big: "SCORE_FMT"+"SCORE_FMT">="SCORE_FMT"\n",
name->name,
(d->type == DECISION_ASSIGN) ? "ASSIGN" : "EXCLUDE",
SCORE_PRINTF(&ss->score),
SCORE_PRINTF(&ss->minimum_penalty),
SCORE_PRINTF(&ss->best_score));
return SOLVERR_PRUNED;
}
return SOLVERR_EXPAND;
}
static void undo_decision(struct apk_solver_state *ss,
struct apk_decision *d)
{
struct apk_name *name = decision_to_name(d);
struct apk_name_state *ns = name_to_ns(name);
struct apk_package *pkg = decision_to_pkg(d);
struct apk_score score;
ns->name_touched = 1;
if (pkg != NULL) {
struct apk_package_state *ps = pkg_to_ps(pkg);
dbg_printf("-->undo_decision: " PKG_VER_FMT " %s\n",
PKG_VER_PRINTF(pkg),
(d->type == DECISION_ASSIGN) ? "ASSIGN" : "EXCLUDE");
if (d->topology_position) {
if (ps->handle_install_if)
ss->topology_position = ps->topology_soft;
else
ss->topology_position = pkg->topology_hard;
}
if (ns->locked) {
ss->assigned_names--;
foreach_rinstall_if_pkg(ss, pkg, untrigger_install_if);
foreach_dependency(ss, pkg->depends, undo_constraint);
get_topology_score(ss, ns, pkg, &score);
subscore(&ss->score, &score);
}
ps->locked = 0;
} else {
dbg_printf("-->undo_decision: %s %s NOTHING\n",
name->name,
(d->type == DECISION_ASSIGN) ? "ASSIGN" : "EXCLUDE");
if (d->type == DECISION_ASSIGN) {
get_unassigned_score(name, &score);
subscore(&ss->score, &score);
} else {
ns->none_excluded = 0;
}
}
ns->locked = 0;
ns->chosen = NULL;
update_name_state(ss, name);
}
static solver_result_t push_decision(struct apk_solver_state *ss,
struct apk_name *name,
struct apk_package *pkg,
int primary_decision,
int branching_point,
int topology_position)
{
struct apk_decision *d;
ASSERT(ss->num_decisions <= ss->max_decisions,
"Decision tree overflow.\n");
ss->num_decisions++;
d = &ss->decisions[ss->num_decisions];
#ifdef DEBUG_CHECKS
d->saved_score = ss->score;
d->saved_requirers = name_to_ns(name)->requirers;
#endif
d->type = primary_decision;
d->branching_point = branching_point;
d->topology_position = topology_position;
d->found_solution = 0;
if (pkg == NULL) {
d->name = name;
d->no_package = 1;
} else {
d->pkg = pkg;
d->no_package = 0;
}
return apply_decision(ss, d);
}
static int next_branch(struct apk_solver_state *ss)
{
unsigned int backup_until = ss->num_decisions;
while (ss->num_decisions > 0) {
struct apk_decision *d = &ss->decisions[ss->num_decisions];
struct apk_name *name = decision_to_name(d);
struct apk_name_state *ns = name_to_ns(name);
undo_decision(ss, d);
#ifdef DEBUG_CHECKS
ASSERT(cmpscore(&d->saved_score, &ss->score) == 0,
"ERROR! saved_score "SCORE_FMT" != score "SCORE_FMT"\n",
SCORE_PRINTF(&d->saved_score),
SCORE_PRINTF(&ss->score));
ASSERT(d->saved_requirers == ns->requirers,
"ERROR! requirers not restored between decisions\n");
#endif
if (backup_until >= ss->num_decisions &&
d->branching_point == BRANCH_YES) {
d->branching_point = BRANCH_NO;
d->type = (d->type == DECISION_ASSIGN) ? DECISION_EXCLUDE : DECISION_ASSIGN;
return apply_decision(ss, d);
}
if (d->no_package && !d->found_solution) {
if (ns->last_touched_decision < backup_until)
backup_until = ns->last_touched_decision;
}
ss->num_decisions--;
}
dbg_printf("-->next_branch: no more branches\n");
return SOLVERR_STOP;
}
static void apply_constraint(struct apk_solver_state *ss, struct apk_dependency *dep)
{
struct apk_name *name = dep->name;
struct apk_name_state *ns = name_to_ns(name);
int i, strength;
if (ss->num_decisions > 0) {
struct apk_name *name0 = decision_to_name(&ss->decisions[ss->num_decisions]);
struct apk_name_state *ns0 = name_to_ns(name0);
strength = ns0->requirers ?: 1;
} else {
strength = 1;
}
if (ns->locked) {
if (ns->chosen)
dbg_printf("%s: locked to " PKG_VER_FMT " already\n",
name->name, PKG_VER_PRINTF(ns->chosen));
else
dbg_printf("%s: locked to empty\n",
name->name);
if (!apk_dep_is_satisfied(dep, ns->chosen))
ss->score.conflicts += strength;
return;
}
if (name->pkgs->num == 0) {
if (!dep->optional)
ss->score.conflicts += strength;
return;
}
if (dep->repository_tag) {
dbg_printf("%s: adding pinnings %d\n",
dep->name->name, dep->repository_tag);
ns->preferred_pinning = BIT(dep->repository_tag);
ns->allowed_pinning |= BIT(dep->repository_tag);
ns->inherited_pinning[dep->repository_tag]++;
recalculate_maybe(ss, name, 0, ns->allowed_pinning);
}
if (ss->num_decisions > 0) {
struct apk_name *name0 = decision_to_name(&ss->decisions[ss->num_decisions]);
dbg_printf("%s: inheriting flags and pinning from %s\n",
name->name, name0->name);
inherit_name_state(ss->db, name, name0);
ns->last_touched_decision = ss->num_decisions;
}
for (i = 0; i < name->pkgs->num; i++) {
struct apk_package *pkg0 = name->pkgs->item[i];
struct apk_package_state *ps0 = pkg_to_ps(pkg0);
if (ps0 == NULL || ps0->locked ||
ss->topology_position < pkg0->topology_hard)
continue;
if (!apk_dep_is_satisfied(dep, pkg0)) {
ps0->conflicts++;
dbg_printf(PKG_VER_FMT ": conflicts++ -> %d\n",
PKG_VER_PRINTF(pkg0),
ps0->conflicts);
}
}
if (!dep->optional)
ns->requirers += strength;
update_name_state(ss, name);
}
static void undo_constraint(struct apk_solver_state *ss, struct apk_dependency *dep)
{
struct apk_name *name = dep->name;
struct apk_name_state *ns = name_to_ns(name);
int i, strength;
if (ss->num_decisions > 0) {
struct apk_name *name0 = decision_to_name(&ss->decisions[ss->num_decisions]);
struct apk_name_state *ns0 = name_to_ns(name0);
strength = ns0->requirers ?: 1;
} else {
strength = 1;
}
if (ns->locked) {
if (ns->chosen != NULL) {
dbg_printf(PKG_VER_FMT " selected already for %s\n",
PKG_VER_PRINTF(ns->chosen), name->name);
} else {
dbg_printf("%s selected to not be satisfied\n",
name->name);
}
if (!apk_dep_is_satisfied(dep, ns->chosen))
ss->score.conflicts -= strength;
return;
}
if (name->pkgs->num == 0) {
if (!dep->optional)
ss->score.conflicts -= strength;
return;
}
if (ss->num_decisions > 0) {
struct apk_name *name0 = decision_to_name(&ss->decisions[ss->num_decisions]);
dbg_printf("%s: uninheriting flags and pinning from %s\n",
name->name, name0->name);
uninherit_name_state(ss->db, name, name0);
/* note: for perfection, we should revert here to the
* *previous* value, but that'd require keeping track
* of it which would require dynamic memory allocations.
* in practice this is good enough. */
if (ns->last_touched_decision > ss->num_decisions)
ns->last_touched_decision = ss->num_decisions;
}
for (i = 0; i < name->pkgs->num; i++) {
struct apk_package *pkg0 = name->pkgs->item[i];
struct apk_package_state *ps0 = pkg_to_ps(pkg0);
if (ps0 == NULL || ps0->locked ||
ss->topology_position < pkg0->topology_hard)
continue;
if (!apk_dep_is_satisfied(dep, pkg0)) {
ps0->conflicts--;
dbg_printf(PKG_VER_FMT ": conflicts-- -> %d\n",
PKG_VER_PRINTF(pkg0),
ps0->conflicts);
}
}
if (!dep->optional)
ns->requirers -= strength;
update_name_state(ss, name);
}
static int expand_branch(struct apk_solver_state *ss)
{
struct apk_name *name;
struct apk_name_state *ns;
struct apk_package *pkg0 = NULL;
unsigned int i, topology0 = 0;
unsigned short allowed_pinning, preferred_pinning;
unsigned int allowed_repos;
int primary_decision, branching_point;
/* FIXME: change unsolved_list to a priority queue */
list_for_each_entry(ns, &ss->unsolved_list_head, unsolved_list) {
struct apk_score score;
struct apk_score pkgscore;
name = ns->name;
/* no options left */
if (ns->chosen == NULL) {
if (ns->none_excluded)
return SOLVERR_PRUNED;
return push_decision(ss, name, NULL, DECISION_ASSIGN, BRANCH_NO, FALSE);
}
if (pkg_to_ps(ns->chosen)->topology_soft < ss->topology_position &&
pkg_to_ps(ns->chosen)->topology_soft > topology0)
pkg0 = ns->chosen, topology0 = pkg_to_ps(pkg0)->topology_soft;
else if (ns->chosen->topology_hard > topology0)
pkg0 = ns->chosen, topology0 = pkg0->topology_hard;
if (!ns->name_touched)
continue;
ns->name_touched = 0;
score = ss->score;
addscore(&score, &ss->minimum_penalty);
subscore(&score, &ns->minimum_penalty);
if (!ns->none_excluded) {
get_unassigned_score(name, &pkgscore);
if (cmpscore2(&score, &pkgscore, &ss->best_score) >= 0) {
dbg_printf("%s: pruning none, score too high "SCORE_FMT"+"SCORE_FMT">="SCORE_FMT"\n",
name->name,
SCORE_PRINTF(&score),
SCORE_PRINTF(&pkgscore),
SCORE_PRINTF(&ss->best_score));
return push_decision(ss, name, NULL, DECISION_EXCLUDE, BRANCH_NO, FALSE);
}
}
for (i = 0; i < name->pkgs->num; i++) {
struct apk_package *pkg0 = name->pkgs->item[i];
struct apk_package_state *ps0 = pkg_to_ps(pkg0);
if (ps0 == NULL || ps0->locked ||
ss->topology_position < pkg0->topology_hard)
continue;
get_topology_score(ss, ns, pkg0, &pkgscore);
if (cmpscore2(&score, &pkgscore, &ss->best_score) >= 0 ||
!pkg_available(ss, pkg0))
return push_decision(ss, name, pkg0, DECISION_EXCLUDE, BRANCH_NO, FALSE);
}
}
if (pkg0 == NULL) {
dbg_printf("expand_branch: solution with score "SCORE_FMT"\n",
SCORE_PRINTF(&ss->score));
return SOLVERR_SOLUTION;
}
/* someone needs to provide this name -- find next eligible
* provider candidate */
name = pkg0->name;
ns = name_to_ns(name);
if (!ns->none_excluded) {
struct apk_package_state *ps0 = pkg_to_ps(pkg0);
if (ps0->conflicts > ns->requirers)
primary_decision = DECISION_ASSIGN;
else
primary_decision = DECISION_EXCLUDE;
return push_decision(ss, name, NULL, primary_decision, BRANCH_YES, FALSE);
}
dbg_printf("expand_branch: "PKG_VER_FMT" score: "SCORE_FMT"\tminpenalty: "SCORE_FMT"\tbest: "SCORE_FMT"\n",
PKG_VER_PRINTF(pkg0),
SCORE_PRINTF(&ss->score),
SCORE_PRINTF(&ss->minimum_penalty),
SCORE_PRINTF(&ss->best_score));
preferred_pinning = ns->preferred_pinning ?: APK_DEFAULT_PINNING_MASK;
allowed_pinning = ns->allowed_pinning | preferred_pinning | APK_DEFAULT_PINNING_MASK;
allowed_repos = get_pinning_mask_repos(ss->db, allowed_pinning);
if ((pkg0->repos != 0) && !(pkg0->repos & allowed_repos)) {
/* pinning has not enabled the package */
primary_decision = DECISION_EXCLUDE;
/* but if it is installed, we might consider it */
if ((pkg0->ipkg == NULL) && (pkg0->filename == NULL))
branching_point = BRANCH_NO;
else
branching_point = BRANCH_YES;
} else if (ns->requirers == 0 && ns->install_ifs != 0 &&
install_if_missing(ss, pkg0)) {
/* not directly required, and package specific
* install_if never triggered */
primary_decision = DECISION_EXCLUDE;
branching_point = BRANCH_NO;
} else if (is_topology_optimum(ss, pkg0)) {
primary_decision = DECISION_ASSIGN;
branching_point = BRANCH_YES;
} else {
primary_decision = DECISION_EXCLUDE;
branching_point = BRANCH_YES;
}
return push_decision(ss, pkg0->name, pkg0,
primary_decision, branching_point, TRUE);
}
static int get_tag(struct apk_database *db, unsigned short pinning_mask, unsigned int repos)
{
int i;
for (i = 0; i < db->num_repo_tags; i++) {
if (!(BIT(i) & pinning_mask))
continue;
if (db->repo_tags[i].allowed_repos & repos)
return i;
}
return APK_DEFAULT_REPOSITORY_TAG;
}
static void record_solution(struct apk_solver_state *ss)
{
struct apk_database *db = ss->db;
struct apk_name_state *ns;
int i, n;
apk_solution_array_resize(&ss->best_solution, ss->assigned_names);
n = 0;
for (i = ss->num_decisions; i > 0; i--) {
struct apk_decision *d = &ss->decisions[i];
struct apk_package *pkg = decision_to_pkg(d);
unsigned short pinning;
unsigned int repos;
d->found_solution = 1;
if (pkg == NULL) {
dbg_printf("record_solution: %s: NOTHING\n",
decision_to_name(d)->name);
continue;
}
dbg_printf("record_solution: " PKG_VER_FMT ": %s\n",
PKG_VER_PRINTF(pkg),
d->type == DECISION_ASSIGN ? "INSTALL" : "no install");
if (d->type != DECISION_ASSIGN)
continue;
ns = name_to_ns(pkg->name);
pinning = ns->allowed_pinning | ns->preferred_pinning | APK_DEFAULT_PINNING_MASK;
repos = pkg->repos | (pkg->ipkg ? db->repo_tags[pkg->ipkg->repository_tag].allowed_repos : 0);
ASSERT(n < ss->assigned_names, "Name assignment overflow\n");
ss->best_solution->item[n++] = (struct apk_solution_entry){
.pkg = pkg,
.reinstall = ns->inherited_reinstall ||
((ns->solver_flags_local | ss->solver_flags) & APK_SOLVERF_REINSTALL),
.repository_tag = get_tag(db, pinning, repos),
};
}
apk_solution_array_resize(&ss->best_solution, n);
}
static int compare_solution_entry(const void *p1, const void *p2)
{
const struct apk_solution_entry *c1 = (const struct apk_solution_entry *) p1;
const struct apk_solution_entry *c2 = (const struct apk_solution_entry *) p2;
return strcmp(c1->pkg->name->name, c2->pkg->name->name);
}
static int compare_change(const void *p1, const void *p2)
{
const struct apk_change *c1 = (const struct apk_change *) p1;
const struct apk_change *c2 = (const struct apk_change *) p2;
if (c1->newpkg == NULL) {
if (c2->newpkg == NULL) {
/* both deleted - reverse topology order */
return c2->oldpkg->topology_hard -
c1->oldpkg->topology_hard;
}
/* c1 deleted, c2 installed -> c2 first*/
return 1;
}
if (c2->newpkg == NULL)
/* c1 installed, c2 deleted -> c1 first*/
return -1;
return c1->newpkg->topology_hard -
c2->newpkg->topology_hard;
}
static int generate_changeset(struct apk_database *db,
struct apk_solution_array *solution,
struct apk_changeset *changeset,
unsigned short solver_flags)
{
struct apk_name *name;
struct apk_name_state *ns;
struct apk_package *pkg, *pkg0;
struct apk_installed_package *ipkg;
int i, j, num_installs = 0, num_removed = 0, ci = 0;
/* calculate change set size */
for (i = 0; i < solution->num; i++) {
pkg = solution->item[i].pkg;
ns = name_to_ns(pkg->name);
ns->chosen = pkg;
ns->in_changeset = 1;
if ((pkg->ipkg == NULL) ||
solution->item[i].reinstall ||
solution->item[i].repository_tag != pkg->ipkg->repository_tag)
num_installs++;
}
list_for_each_entry(ipkg, &db->installed.packages, installed_pkgs_list) {
name = ipkg->pkg->name;
ns = name_to_ns(name);
if ((ns->chosen == NULL) || !ns->in_changeset)
num_removed++;
}
/* construct changeset */
apk_change_array_resize(&changeset->changes, num_installs + num_removed);
list_for_each_entry(ipkg, &db->installed.packages, installed_pkgs_list) {
name = ipkg->pkg->name;
ns = name_to_ns(name);
if ((ns->chosen == NULL) || !ns->in_changeset) {
changeset->changes->item[ci].oldpkg = ipkg->pkg;
ci++;
}
}
for (i = 0; i < solution->num; i++) {
pkg = solution->item[i].pkg;
name = pkg->name;
ns = name_to_ns(name);
if ((pkg->ipkg == NULL) ||
solution->item[i].reinstall ||
solution->item[i].repository_tag != pkg->ipkg->repository_tag){
for (j = 0; j < name->pkgs->num; j++) {
pkg0 = name->pkgs->item[j];
if (pkg0->ipkg == NULL)
continue;
changeset->changes->item[ci].oldpkg = pkg0;
break;
}
changeset->changes->item[ci].newpkg = pkg;
changeset->changes->item[ci].repository_tag = solution->item[i].repository_tag;
changeset->changes->item[ci].reinstall = solution->item[i].reinstall;
ci++;
}
}
/* sort changeset to topology order */
qsort(changeset->changes->item, changeset->changes->num,
sizeof(struct apk_change), compare_change);
return 0;
}
static int free_state(apk_hash_item item, void *ctx)
{
struct apk_name *name = (struct apk_name *) item;
struct apk_name_state *ns = (struct apk_name_state *) name->state_ptr;
if (ns != NULL) {
#ifdef DEBUG_CHECKS
ASSERT(ns->requirers == 0, "Requirers is not zero after cleanup\n");
#endif
free(ns);
name->state_ptr = NULL;
}
return 0;
}
static int free_package(apk_hash_item item, void *ctx)
{
struct apk_package *pkg = (struct apk_package *) item;
if (pkg->state_ptr != NULL) {
free(pkg->state_ptr);
pkg->state_ptr = NULL;
}
return 0;
}
void apk_solver_set_name_flags(struct apk_name *name,
unsigned short solver_flags,
unsigned short solver_flags_inheritable)
{
struct apk_name_state *ns = name_to_ns_alloc(name);
ns->solver_flags_local = solver_flags;
ns->solver_flags_local_mask = solver_flags_inheritable;
}
static void apk_solver_free(struct apk_database *db)
{
apk_hash_foreach(&db->available.names, free_state, NULL);
apk_hash_foreach(&db->available.packages, free_package, NULL);
}
int apk_solver_solve(struct apk_database *db,
unsigned short solver_flags,
struct apk_dependency_array *world,
struct apk_solution_array **solution,
struct apk_changeset *changeset)
{
struct apk_solver_state *ss;
struct apk_installed_package *ipkg;
solver_result_t r = SOLVERR_STOP;
int i;
ss = calloc(1, sizeof(struct apk_solver_state));
ss->db = db;
ss->solver_flags = solver_flags;
ss->topology_position = -1;
ss->best_score = (struct apk_score){ .conflicts = -1 };
list_init(&ss->unsolved_list_head);
for (i = 0; i < world->num; i++) {
sort_name(ss, world->item[i].name);
name_to_ns(world->item[i].name)->in_world_dependency = 1;
}
list_for_each_entry(ipkg, &db->installed.packages, installed_pkgs_list) {
sort_name(ss, ipkg->pkg->name);
name_to_ns(ipkg->pkg->name)->originally_installed = 1;
}
#if 0
for (i = 0; i < world->num; i++)
prepare_name(ss, world->item[i].name);
list_for_each_entry(ipkg, &db->installed.packages, installed_pkgs_list)
prepare_name(ss, ipkg->pkg->name);
#endif
ss->max_decisions ++;
ss->decisions = calloc(1, sizeof(struct apk_decision[ss->max_decisions]));
foreach_dependency(ss, world, apply_constraint);
do {
/* need EXPAND if here, can return SOLUTION|PRUNED|EXPAND */
r = expand_branch(ss);
if (r == SOLVERR_SOLUTION) {
struct apk_score score;
score = ss->score;
addscore(&score, &ss->minimum_penalty);
if (cmpscore(&score, &ss->best_score) < 0) {
dbg_printf("updating best score "SCORE_FMT" (was: "SCORE_FMT")\n",
SCORE_PRINTF(&score),
SCORE_PRINTF(&ss->best_score));
record_solution(ss);
ss->best_score = score;
}
r = SOLVERR_PRUNED;
}
/* next_branch() returns PRUNED, STOP or EXPAND */
while (r == SOLVERR_PRUNED)
r = next_branch(ss);
/* STOP or EXPAND */
} while (r != SOLVERR_STOP);
#ifdef DEBUG_CHECKS
foreach_dependency(ss, world, undo_constraint);
#endif
/* collect packages */
dbg_printf("finished. best score "SCORE_FMT". solution has %d packages.\n",
SCORE_PRINTF(&ss->best_score),
ss->best_solution->num);
if (changeset != NULL) {
generate_changeset(db, ss->best_solution, changeset,
ss->solver_flags);
}
if (solution != NULL) {
qsort(ss->best_solution->item, ss->best_solution->num,
sizeof(struct apk_solution_entry), compare_solution_entry);
*solution = ss->best_solution;
} else {
apk_solution_array_free(&ss->best_solution);
}
i = ss->best_score.conflicts;
apk_solver_free(db);
free(ss->decisions);
free(ss);
return i;
}
static void print_change(struct apk_database *db,
struct apk_change *change,
int cur, int total)
{
struct apk_name *name;
struct apk_package *oldpkg = change->oldpkg;
struct apk_package *newpkg = change->newpkg;
const char *msg = NULL;
char status[32], n[512], *nameptr;
int r;
snprintf(status, sizeof(status), "(%i/%i)", cur+1, total);
status[sizeof(status) - 1] = 0;
name = newpkg ? newpkg->name : oldpkg->name;
if (change->repository_tag > 0) {
snprintf(n, sizeof(n), "%s@" BLOB_FMT,
name->name,
BLOB_PRINTF(*db->repo_tags[change->repository_tag].name));
n[sizeof(n) - 1] = 0;
nameptr = n;
} else {
nameptr = name->name;
}
if (oldpkg == NULL) {
apk_message("%s Installing %s (" BLOB_FMT ")",
status, nameptr,
BLOB_PRINTF(*newpkg->version));
} else if (newpkg == NULL) {
apk_message("%s Purging %s (" BLOB_FMT ")",
status, nameptr,
BLOB_PRINTF(*oldpkg->version));
} else if (newpkg == oldpkg && !change->reinstall) {
apk_message("%s Updating pinning %s (" BLOB_FMT ")",
status, nameptr,
BLOB_PRINTF(*oldpkg->version));
} else {
r = apk_pkg_version_compare(newpkg, oldpkg);
switch (r) {
case APK_VERSION_LESS:
msg = "Downgrading";
break;
case APK_VERSION_EQUAL:
if (newpkg == oldpkg)
msg = "Re-installing";
else
msg = "Replacing";
break;
case APK_VERSION_GREATER:
msg = "Upgrading";
break;
}
apk_message("%s %s %s (" BLOB_FMT " -> " BLOB_FMT ")",
status, msg, nameptr,
BLOB_PRINTF(*oldpkg->version),
BLOB_PRINTF(*newpkg->version));
}
}
struct apk_stats {
unsigned int bytes;
unsigned int packages;
};
static void count_change(struct apk_change *change, struct apk_stats *stats)
{
if (change->newpkg != NULL) {
stats->bytes += change->newpkg->installed_size;
stats->packages ++;
}
if (change->oldpkg != NULL)
stats->packages ++;
}
static void draw_progress(int percent)
{
const int bar_width = apk_get_screen_width() - 7;
int i;
fprintf(stderr, "\e7%3i%% [", percent);
for (i = 0; i < bar_width * percent / 100; i++)
fputc('#', stderr);
for (; i < bar_width; i++)
fputc(' ', stderr);
fputc(']', stderr);
fflush(stderr);
fputs("\e8\e[0K", stderr);
}
struct progress {
struct apk_stats done;
struct apk_stats total;
struct apk_package *pkg;
size_t count;
};
static void progress_cb(void *ctx, size_t progress)
{
struct progress *prog = (struct progress *) ctx;
size_t partial = 0, count;
if (prog->pkg != NULL)
partial = muldiv(progress, prog->pkg->installed_size, APK_PROGRESS_SCALE);
count = muldiv(100, prog->done.bytes + prog->done.packages + partial,
prog->total.bytes + prog->total.packages);
if (prog->count != count)
draw_progress(count);
prog->count = count;
}
static int dump_packages(struct apk_changeset *changeset,
int (*cmp)(struct apk_change *change),
const char *msg)
{
struct apk_change *change;
struct apk_name *name;
struct apk_indent indent = { .indent = 2 };
int match = 0, i;
for (i = 0; i < changeset->changes->num; i++) {
change = &changeset->changes->item[i];
if (!cmp(change))
continue;
if (match == 0)
printf("%s:\n", msg);
if (change->newpkg != NULL)
name = change->newpkg->name;
else
name = change->oldpkg->name;
apk_print_indented(&indent, APK_BLOB_STR(name->name));
match++;
}
if (match)
printf("\n");
return match;
}
static int cmp_remove(struct apk_change *change)
{
return change->newpkg == NULL;
}
static int cmp_new(struct apk_change *change)
{
return change->oldpkg == NULL;
}
static int cmp_downgrade(struct apk_change *change)
{
if (change->newpkg == NULL || change->oldpkg == NULL)
return 0;
if (apk_pkg_version_compare(change->newpkg, change->oldpkg)
& APK_VERSION_LESS)
return 1;
return 0;
}
static int cmp_upgrade(struct apk_change *change)
{
if (change->newpkg == NULL || change->oldpkg == NULL)
return 0;
/* Count swapping package as upgrade too - this can happen if
* same package version is used after it was rebuilt against
* newer libraries. Basically, different (and probably newer)
* package, but equal version number. */
if ((apk_pkg_version_compare(change->newpkg, change->oldpkg) &
(APK_VERSION_GREATER | APK_VERSION_EQUAL)) &&
(change->newpkg != change->oldpkg))
return 1;
return 0;
}
static int compare_package_topology(const void *p1, const void *p2)
{
struct apk_package *pkg1 = *(struct apk_package **) p1;
struct apk_package *pkg2 = *(struct apk_package **) p2;
return pkg1->topology_hard - pkg2->topology_hard;
}
static void run_triggers(struct apk_database *db)
{
struct apk_package_array *pkgs;
int i;
pkgs = apk_db_get_pending_triggers(db);
if (pkgs == NULL || pkgs->num == 0)
return;
qsort(pkgs->item, pkgs->num, sizeof(struct apk_package *),
compare_package_topology);
for (i = 0; i < pkgs->num; i++) {
struct apk_package *pkg = pkgs->item[i];
struct apk_installed_package *ipkg = pkg->ipkg;
*apk_string_array_add(&ipkg->pending_triggers) = NULL;
apk_ipkg_run_script(ipkg, db, APK_SCRIPT_TRIGGER,
ipkg->pending_triggers->item);
apk_string_array_free(&ipkg->pending_triggers);
}
apk_package_array_free(&pkgs);
}
int apk_solver_commit_changeset(struct apk_database *db,
struct apk_changeset *changeset,
struct apk_dependency_array *world)
{
struct progress prog;
struct apk_change *change;
int i, r = 0, size_diff = 0;
if (apk_db_check_world(db, world) != 0) {
apk_error("Not committing changes due to missing repository tags. Use --force to override.");
return -1;
}
if (changeset->changes == NULL)
goto all_done;
/* Count what needs to be done */
memset(&prog, 0, sizeof(prog));
for (i = 0; i < changeset->changes->num; i++) {
change = &changeset->changes->item[i];
count_change(change, &prog.total);
if (change->newpkg)
size_diff += change->newpkg->installed_size;
if (change->oldpkg)
size_diff -= change->oldpkg->installed_size;
}
size_diff /= 1024;
if (apk_verbosity > 1 || (apk_flags & APK_INTERACTIVE)) {
r = dump_packages(changeset, cmp_remove,
"The following packages will be REMOVED");
r += dump_packages(changeset, cmp_downgrade,
"The following packages will be DOWNGRADED");
if (r || (apk_flags & APK_INTERACTIVE) || apk_verbosity > 2) {
dump_packages(changeset, cmp_new,
"The following NEW packages will be installed");
dump_packages(changeset, cmp_upgrade,
"The following packages will be upgraded");
printf("After this operation, %d kB of %s\n", abs(size_diff),
(size_diff < 0) ?
"disk space will be freed." :
"additional disk space will be used.");
}
if (apk_flags & APK_INTERACTIVE) {
printf("Do you want to continue [Y/n]? ");
fflush(stdout);
r = fgetc(stdin);
if (r != 'y' && r != 'Y' && r != '\n')
return -1;
}
}
/* Go through changes */
r = 0;
for (i = 0; i < changeset->changes->num; i++) {
change = &changeset->changes->item[i];
print_change(db, change, i, changeset->changes->num);
if (apk_flags & APK_PROGRESS)
draw_progress(prog.count);
prog.pkg = change->newpkg;
if (!(apk_flags & APK_SIMULATE)) {
if (change->oldpkg != change->newpkg || change->reinstall)
r = apk_db_install_pkg(db,
change->oldpkg, change->newpkg,
(apk_flags & APK_PROGRESS) ? progress_cb : NULL,
&prog);
if (r != 0)
break;
if (change->newpkg)
change->newpkg->ipkg->repository_tag = change->repository_tag;
}
count_change(change, &prog.done);
}
if (apk_flags & APK_PROGRESS)
draw_progress(100);
run_triggers(db);
all_done:
apk_dependency_array_copy(&db->world, world);
apk_db_write_config(db);
if (r == 0 && !db->performing_self_update) {
if (apk_verbosity > 1) {
apk_message("OK: %d packages, %d dirs, %d files, %zu MiB",
db->installed.stats.packages,
db->installed.stats.dirs,
db->installed.stats.files,
db->installed.stats.bytes / (1024 * 1024));
} else {
apk_message("OK: %zu MiB in %d packages",
db->installed.stats.bytes / (1024 * 1024),
db->installed.stats.packages);
}
}
return r;
}
static void print_dep_errors(struct apk_database *db, char *label, struct apk_dependency_array *deps)
{
int i, print_label = 1;
char buf[256];
apk_blob_t p;
struct apk_indent indent;
for (i = 0; i < deps->num; i++) {
struct apk_dependency *dep = &deps->item[i];
struct apk_package *pkg = (struct apk_package*) dep->name->state_ptr;
if (pkg != NULL && apk_dep_is_satisfied(dep, pkg))
continue;
if (print_label) {
print_label = 0;
indent.x = printf(" %s:", label);
indent.indent = indent.x + 1;
}
p = APK_BLOB_BUF(buf);
apk_blob_push_dep(&p, db, dep);
p = apk_blob_pushed(APK_BLOB_BUF(buf), p);
apk_print_indented(&indent, p);
}
if (!print_label)
printf("\n");
}
void apk_solver_print_errors(struct apk_database *db,
struct apk_solution_array *solution,
struct apk_dependency_array *world,
int unsatisfiable)
{
int i;
apk_error("%d unsatisfiable dependencies:", unsatisfiable);
for (i = 0; i < solution->num; i++) {
struct apk_package *pkg = solution->item[i].pkg;
pkg->name->state_ptr = pkg;
}
print_dep_errors(db, "world", world);
for (i = 0; i < solution->num; i++) {
struct apk_package *pkg = solution->item[i].pkg;
char pkgtext[256];
snprintf(pkgtext, sizeof(pkgtext), PKG_VER_FMT, PKG_VER_PRINTF(pkg));
print_dep_errors(db, pkgtext, pkg->depends);
}
}
int apk_solver_commit(struct apk_database *db,
unsigned short solver_flags,
struct apk_dependency_array *world)
{
struct apk_changeset changeset = {};
struct apk_solution_array *solution = NULL;
int r;
if (apk_db_check_world(db, world) != 0) {
apk_error("Not committing changes due to missing repository tags. Use --force to override.");
return -1;
}
r = apk_solver_solve(db, solver_flags,
world, &solution, &changeset);
if (r < 0)
return r;
if (r == 0 || (apk_flags & APK_FORCE)) {
/* Success -- or forced installation of bad graph */
r = apk_solver_commit_changeset(db, &changeset, world);
} else {
/* Failure -- print errors */
apk_solver_print_errors(db, solution, world, r);
}
apk_solution_array_free(&solution);
apk_change_array_free(&changeset.changes);
return r;
}