/*
* Copyright (c) 2017, SUSE Inc.
*
* This program is licensed under the BSD license, read LICENSE.BSD
* for further information
*/
/*
* cleandeps.c
*
* code to find and erase unneeded packages
*/
#include <stdio.h>
#include <stdlib.h>
#include <unistd.h>
#include <string.h>
#include "solver.h"
#include "solverdebug.h"
#include "solver_private.h"
#include "bitmap.h"
#include "pool.h"
#include "util.h"
#include "policy.h"
#include "cplxdeps.h"
#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 void
dep_pkgcheck_slow(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_slow(solv, rd->name, m, q);
dep_pkgcheck_slow(solv, rd->evr, m, q);
return;
}
if (rd->flags == REL_COND || rd->flags == REL_UNLESS)
{
dep_pkgcheck_slow(solv, rd->name, m, q);
if (ISRELDEP(rd->evr))
{
Reldep *rd2 = GETRELDEP(pool, rd->evr);
if (rd2->flags == REL_ELSE)
dep_pkgcheck_slow(solv, rd2->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 inline void
dep_pkgcheck(Solver *solv, Id dep, Map *m, Queue *q)
{
Pool *pool = solv->pool;
Id p, pp;
if (!ISSIMPLEDEP(pool, dep))
{
dep_pkgcheck_slow(solv, dep, m, q);
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)
return 0;
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;
}
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_filter_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
static void
filter_unneeded(Solver *solv, Queue *unneededq, Map *unneededmap, int justone)
{
Pool *pool = solv->pool;
Repo *installed = solv->installed;
Queue edges;
Id *nrequires;
Map m, installedm;
int i, j, pass, count = unneededq->count;
Id *low;
if (unneededq->count < 2)
return;
map_init(&m, 0);
if (!unneededmap)
{
unneededmap = &m;
map_grow(unneededmap, installed->end - installed->start);
for (i = 0; i < count; i++)
MAPSET(unneededmap, unneededq->elements[i] - installed->start);
}
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_filter_unneeded(pool, s - pool->solvables, dep, &edges, unneededmap, unneededq);
continue;
}
#endif
if (justone)
{
int count = 0;
FOR_PROVIDES(p, pp, dep)
{
Solvable *sp = pool->solvables + p;
if (s == sp || sp->repo != installed)
continue;
count++;
}
if (count != 1)
continue;
}
FOR_PROVIDES(p, pp, dep)
{
Solvable *sp = pool->solvables + p;
if (s == sp || sp->repo != installed || !MAPTST(unneededmap, 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 (solver_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);
if (justone && iq.count != 1)
{
queue_free(&iq);
continue;
}
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(unneededmap, 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(&m);
}
#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;
}
else if (p == ip)
break;
}
if (!p)
{
for (i = blk; (p = dq.elements[i]) != 0; i++)
{
if (p < 0)
continue;
if (MAPTST(im, p))
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
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;
}
static void
find_update_seeds(Solver *solv, Queue *updatepkgs_filtered, Map *userinstalled)
{
Pool *pool = solv->pool;
Repo *installed = solv->installed;
Queue *cleandeps_updatepkgs = solv->cleandeps_updatepkgs;
int i, j;
Id p;
queue_prealloc(updatepkgs_filtered, cleandeps_updatepkgs->count);
for (i = 0; i < cleandeps_updatepkgs->count; i++)
{
p = cleandeps_updatepkgs->elements[i];
if (pool->solvables[p].repo == installed)
{
#ifdef ENABLE_LINKED_PKGS
const char *name = pool_id2str(pool, pool->solvables[p].name);
if (strncmp(name, "pattern:", 8) == 0 || strncmp(name, "application:", 12) == 0)
continue;
#endif
queue_push(updatepkgs_filtered, p);
}
}
#ifdef CLEANDEPSDEBUG
printf("SEEDS IN (%d)\n", updatepkgs_filtered->count);
for (i = 0; i < updatepkgs_filtered->count; i++)
printf(" - %s\n", pool_solvid2str(pool, updatepkgs_filtered->elements[i]));
#endif
filter_unneeded(solv, updatepkgs_filtered, 0, 1);
#ifdef CLEANDEPSDEBUG
printf("SEEDS OUT (%d)\n", updatepkgs_filtered->count);
for (i = 0; i < updatepkgs_filtered->count; i++)
printf(" - %s\n", pool_solvid2str(pool, updatepkgs_filtered->elements[i]));
#endif
/* make sure userinstalled packages are in the seeds */
for (i = j = 0; i < updatepkgs_filtered->count; i++)
{
p = updatepkgs_filtered->elements[i];
if (!MAPTST(userinstalled, p - installed->start))
updatepkgs_filtered->elements[j++] = p;
}
queue_truncate(updatepkgs_filtered, j);
for (i = 0; i < cleandeps_updatepkgs->count; i++)
{
p = cleandeps_updatepkgs->elements[i];
if (pool->solvables[p].repo == installed)
{
#ifdef ENABLE_LINKED_PKGS
const char *name = pool_id2str(pool, pool->solvables[p].name);
if (strncmp(name, "pattern:", 8) == 0 || strncmp(name, "application:", 12) == 0)
{
queue_push(updatepkgs_filtered, p);
continue;
}
#endif
if (MAPTST(userinstalled, p - installed->start))
queue_push(updatepkgs_filtered, p);
}
}
#ifdef CLEANDEPSDEBUG
printf("SEEDS FINAL\n");
for (i = 0; i < updatepkgs_filtered->count; i++)
printf(" - %s\n", pool_solvid2str(pool, updatepkgs_filtered->elements[i]));
#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.
*/
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;
Queue updatepkgs_filtered;
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;
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; /* found a multiversion package that will not obsolate anything */
}
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
solver_intersect_obsoleted(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 (pool->considered && !MAPTST(pool->considered, p))
MAPSET(&userinstalled, p - installed->start); /* we may not remove those */
if (unneeded && !MAPTST(&userinstalled, p - installed->start))
continue;
MAPSET(&im, p);
}
MAPSET(&installedm, SYSTEMSOLVABLE);
MAPSET(&im, SYSTEMSOLVABLE);
if (!unneeded && solv->cleandeps_updatepkgs)
{
/* find update "seeds" */
queue_init(&updatepkgs_filtered);
find_update_seeds(solv, &updatepkgs_filtered, &userinstalled);
}
#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 (solver_dep_possible(solv, sup, &im))
break;
if (!sup)
{
supp = s->repo->idarraydata + s->supplements;
while ((sup = *supp++) != 0)
if (solver_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 (solver_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->repo == installed && pool->implicitobsoleteusescolors)
{
unsigned int a, bestscore = 0;
FOR_PROVIDES(p, pp, s->name)
{
Solvable *ps = pool->solvables + p;
if (ps->name != s->name || ps->repo == installed)
continue;
a = pool_arch2score(pool, ps->arch);
if (a && a != 1 && (!bestscore || a < bestscore))
bestscore = a;
}
if (bestscore && pool_arch2score(pool, s->arch) != bestscore)
{
FOR_PROVIDES(p, pp, s->name)
{
Solvable *ps = pool->solvables + p;
if (ps->repo == installed && ps->name == s->name && ps->evr == s->evr && ps->arch != s->arch && pool_arch2score(pool, ps->arch) == bestscore)
if (!MAPTST(&im, p))
{
#ifdef CLEANDEPSDEBUG
printf("%s lockstep %s\n", pool_solvid2str(pool, ip), pool_solvid2str(pool, p));
#endif
MAPSET(&im, p);
queue_push(&iq, p);
}
}
}
}
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 (p == ip)
break;
if (p)
continue;
FOR_PROVIDES(p, pp, req)
{
if (MAPTST(&im, p))
continue;
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 (p == ip)
break;
if (p)
continue;
FOR_PROVIDES(p, pp, req)
{
if (MAPTST(&im, p))
continue;
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 (!unneeded && solv->cleandeps_updatepkgs)
{
for (i = 0; i < updatepkgs_filtered.count; i++)
MAPSET(&im, updatepkgs_filtered.elements[i]);
queue_free(&updatepkgs_filtered);
}
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 (pool->considered && !MAPTST(pool->considered, p))
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
}
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)
filter_unneeded(solv, unneededq, &cleandepsmap, 0);
map_free(&cleandepsmap);
}
static void
add_cleandeps_mistake(Solver *solv, Id p)
{
if (!solv->cleandeps_mistakes)
{
solv->cleandeps_mistakes = solv_calloc(1, sizeof(Queue));
queue_init(solv->cleandeps_mistakes);
}
queue_push(solv->cleandeps_mistakes, p);
MAPCLR(&solv->cleandepsmap, p - solv->installed->start);
solver_reenablepolicyrules_cleandeps(solv, p);
}
static inline int
cleandeps_rule_is_true(Solver *solv, Rule *r)
{
Pool *pool = solv->pool;
Id p, pp;
FOR_RULELITERALS(p, pp, r)
if (p > 0 && solv->decisionmap[p] > 0)
return 1;
return 0;
}
int
solver_check_cleandeps_mistakes(Solver *solv)
{
Pool *pool = solv->pool;
Repo *installed = solv->installed;
Rule *fr;
int i, j, nj;
int mademistake = 0;
if (!solv->cleandepsmap.size || !installed)
return 0;
/* check for mistakes */
policy_update_recommendsmap(solv);
for (i = installed->start; i < installed->end; i++)
{
if (pool->solvables[i].repo != installed)
continue;
if (solv->decisionmap[i] > 0)
{
Id req, *reqp;
Solvable *s = pool->solvables + i;
/* kept package, check requires. we need to do this for things like requires(pre) */
reqp = s->repo->idarraydata + s->requires;
while ((req = *reqp++) != 0)
{
Id p2, pp2;
FOR_PROVIDES(p2, pp2, req)
{
if (pool->solvables[p2].repo != installed)
continue;
if (p2 == i || solv->decisionmap[p2] > 0)
continue;
if (!MAPTST(&solv->cleandepsmap, p2 - installed->start))
continue;
POOL_DEBUG(SOLV_DEBUG_SOLVER, "cleandeps requires mistake: %s %s %s\n", pool_solvid2str(pool, i), pool_dep2str(pool, req), pool_solvid2str(pool, p2));
add_cleandeps_mistake(solv, p2);
mademistake = 1;
}
}
}
if (!MAPTST(&solv->cleandepsmap, i - installed->start))
continue;
/* a mistake is when the featurerule is true but the updaterule is false */
fr = solv->rules + solv->featurerules + (i - installed->start);
if (!fr->p)
fr = solv->rules + solv->updaterules + (i - installed->start);
if (!fr->p)
continue;
if (!cleandeps_rule_is_true(solv, fr))
{
/* feature rule is not true, thus we cleandeps erased the package */
/* check if the package is recommended/supplemented. if yes, we made a mistake. */
if (!MAPTST(&solv->recommendsmap, i) && !solver_is_supplementing(solv, pool->solvables + i))
continue; /* feature rule is not true */
POOL_DEBUG(SOLV_DEBUG_SOLVER, "cleandeps recommends mistake: ");
solver_printruleclass(solv, SOLV_DEBUG_SOLVER, fr);
}
else
{
Rule *r = solv->rules + solv->updaterules + (i - installed->start);
if (!r->p || r == fr || cleandeps_rule_is_true(solv, r))
{
/* update rule is true, check best rules */
if (!solv->bestrules_info)
continue;
nj = solv->bestrules_end - solv->bestrules;
for (j = solv->bestrules_up - solv->bestrules; j < nj; j++)
if (solv->bestrules_info[j] == i)
{
r = solv->rules + solv->bestrules + j;
if (!cleandeps_rule_is_true(solv, r))
break;
}
if (j == nj)
continue;
}
POOL_DEBUG(SOLV_DEBUG_SOLVER, "cleandeps mistake: ");
solver_printruleclass(solv, SOLV_DEBUG_SOLVER, r);
POOL_DEBUG(SOLV_DEBUG_SOLVER, "feature rule: ");
solver_printruleclass(solv, SOLV_DEBUG_SOLVER, fr);
}
add_cleandeps_mistake(solv, i);
mademistake = 1;
}
return mademistake;
}