2014-03-12 04:17:51 -05:00
# define __STDC_FORMAT_MACROS
# define __STDC_LIMIT_MACROS
/***********************************************************************************[SimpSolver.cc]
Copyright ( c ) 2006 , Niklas Een , Niklas Sorensson
Copyright ( c ) 2007 - 2010 , Niklas Sorensson
Permission is hereby granted , free of charge , to any person obtaining a copy of this software and
associated documentation files ( the " Software " ) , to deal in the Software without restriction ,
including without limitation the rights to use , copy , modify , merge , publish , distribute ,
sublicense , and / or sell copies of the Software , and to permit persons to whom the Software is
furnished to do so , subject to the following conditions :
The above copyright notice and this permission notice shall be included in all copies or
substantial portions of the Software .
THE SOFTWARE IS PROVIDED " AS IS " , WITHOUT WARRANTY OF ANY KIND , EXPRESS OR IMPLIED , INCLUDING BUT
NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY , FITNESS FOR A PARTICULAR PURPOSE AND
NONINFRINGEMENT . IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM ,
DAMAGES OR OTHER LIABILITY , WHETHER IN AN ACTION OF CONTRACT , TORT OR OTHERWISE , ARISING FROM , OUT
OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE .
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
2014-07-20 18:01:26 -05:00
# include "Sort.h"
# include "SimpSolver.h"
# include "System.h"
2014-03-12 04:17:51 -05:00
using namespace Minisat ;
//=================================================================================================
// Options:
static const char * _cat = " SIMP " ;
static BoolOption opt_use_asymm ( _cat , " asymm " , " Shrink clauses by asymmetric branching. " , false ) ;
static BoolOption opt_use_rcheck ( _cat , " rcheck " , " Check if a clause is already implied. (costly) " , false) ;
static BoolOption opt_use_elim ( _cat , " elim " , " Perform variable elimination. " , true ) ;
static IntOption opt_grow ( _cat , " grow " , " Allow a variable elimination step to grow by a number of clauses. " , 0 ) ;
static IntOption opt_clause_lim ( _cat , " cl-lim " , " Variables are not eliminated if it produces a resolvent with a length above this limit. -1 means no limit " , 20 , IntRange ( - 1 , INT32_MAX ) ) ;
static IntOption opt_subsumption_lim ( _cat , " sub-lim " , " Do not check if subsumption against a clause larger than this. -1 means no limit. " , 1000 , IntRange ( - 1 , INT32_MAX ) ) ;
static DoubleOption opt_simp_garbage_frac ( _cat , " simp-gc-frac " , " The fraction of wasted memory allowed before a garbage collection is triggered during simplification. " , 0.5 , DoubleRange ( 0 , false , HUGE_VAL , false ) ) ;
//=================================================================================================
// Constructor/Destructor:
SimpSolver : : SimpSolver ( ) :
grow ( opt_grow )
, clause_lim ( opt_clause_lim )
, subsumption_lim ( opt_subsumption_lim )
, simp_garbage_frac ( opt_simp_garbage_frac )
, use_asymm ( opt_use_asymm )
, use_rcheck ( opt_use_rcheck )
, use_elim ( opt_use_elim )
, extend_model ( true )
, merges ( 0 )
, asymm_lits ( 0 )
, eliminated_vars ( 0 )
, elimorder ( 1 )
, use_simplification ( true )
, occurs ( ClauseDeleted ( ca ) )
, elim_heap ( ElimLt ( n_occ ) )
, bwdsub_assigns ( 0 )
, n_touched ( 0 )
{
vec < Lit > dummy ( 1 , lit_Undef ) ;
ca . extra_clause_field = true ; // NOTE: must happen before allocating the dummy clause below.
bwdsub_tmpunit = ca . alloc ( dummy ) ;
remove_satisfied = false ;
}
SimpSolver : : ~ SimpSolver ( )
{
}
Var SimpSolver : : newVar ( lbool upol , bool dvar ) {
Var v = Solver : : newVar ( upol , dvar ) ;
frozen . insert ( v , ( char ) false ) ;
eliminated . insert ( v , ( char ) false ) ;
if ( use_simplification ) {
n_occ . insert ( mkLit ( v ) , 0 ) ;
n_occ . insert ( ~ mkLit ( v ) , 0 ) ;
occurs . init ( v ) ;
touched . insert ( v , 0 ) ;
elim_heap . insert ( v ) ;
}
return v ; }
void SimpSolver : : releaseVar ( Lit l )
{
assert ( ! isEliminated ( var ( l ) ) ) ;
if ( ! use_simplification & & var ( l ) > = max_simp_var )
// Note: Guarantees that no references to this variable is
// left in model extension datastructure. Could be improved!
Solver : : releaseVar ( l ) ;
else
// Otherwise, don't allow variable to be reused.
Solver : : addClause ( l ) ;
}
lbool SimpSolver : : solve_ ( bool do_simp , bool turn_off_simp )
{
vec < Var > extra_frozen ;
lbool result = l_True ;
do_simp & = use_simplification ;
if ( do_simp ) {
// Assumptions must be temporarily frozen to run variable elimination:
for ( int i = 0 ; i < assumptions . size ( ) ; i + + ) {
Var v = var ( assumptions [ i ] ) ;
// If an assumption has been eliminated, remember it.
assert ( ! isEliminated ( v ) ) ;
if ( ! frozen [ v ] ) {
// Freeze and store.
setFrozen ( v , true ) ;
extra_frozen . push ( v ) ;
} }
result = lbool ( eliminate ( turn_off_simp ) ) ;
}
if ( result = = l_True )
result = Solver : : solve_ ( ) ;
else if ( verbosity > = 1 )
printf ( " =============================================================================== \n " ) ;
if ( result = = l_True & & extend_model )
extendModel ( ) ;
if ( do_simp )
// Unfreeze the assumptions that were frozen:
for ( int i = 0 ; i < extra_frozen . size ( ) ; i + + )
setFrozen ( extra_frozen [ i ] , false ) ;
return result ;
}
bool SimpSolver : : addClause_ ( vec < Lit > & ps )
{
# ifndef NDEBUG
for ( int i = 0 ; i < ps . size ( ) ; i + + )
assert ( ! isEliminated ( var ( ps [ i ] ) ) ) ;
# endif
int nclauses = clauses . size ( ) ;
if ( use_rcheck & & implied ( ps ) )
return true ;
if ( ! Solver : : addClause_ ( ps ) )
return false ;
if ( use_simplification & & clauses . size ( ) = = nclauses + 1 ) {
CRef cr = clauses . last ( ) ;
const Clause & c = ca [ cr ] ;
// NOTE: the clause is added to the queue immediately and then
// again during 'gatherTouchedClauses()'. If nothing happens
// in between, it will only be checked once. Otherwise, it may
// be checked twice unnecessarily. This is an unfortunate
// consequence of how backward subsumption is used to mimic
// forward subsumption.
subsumption_queue . insert ( cr ) ;
for ( int i = 0 ; i < c . size ( ) ; i + + ) {
occurs [ var ( c [ i ] ) ] . push ( cr ) ;
n_occ [ c [ i ] ] + + ;
touched [ var ( c [ i ] ) ] = 1 ;
n_touched + + ;
if ( elim_heap . inHeap ( var ( c [ i ] ) ) )
elim_heap . increase ( var ( c [ i ] ) ) ;
}
}
return true ;
}
void SimpSolver : : removeClause ( CRef cr )
{
const Clause & c = ca [ cr ] ;
if ( use_simplification )
for ( int i = 0 ; i < c . size ( ) ; i + + ) {
n_occ [ c [ i ] ] - - ;
updateElimHeap ( var ( c [ i ] ) ) ;
occurs . smudge ( var ( c [ i ] ) ) ;
}
Solver : : removeClause ( cr ) ;
}
bool SimpSolver : : strengthenClause ( CRef cr , Lit l )
{
Clause & c = ca [ cr ] ;
assert ( decisionLevel ( ) = = 0 ) ;
assert ( use_simplification ) ;
// FIX: this is too inefficient but would be nice to have (properly implemented)
// if (!find(subsumption_queue, &c))
subsumption_queue . insert ( cr ) ;
if ( c . size ( ) = = 2 ) {
removeClause ( cr ) ;
c . strengthen ( l ) ;
} else {
detachClause ( cr , true ) ;
c . strengthen ( l ) ;
attachClause ( cr ) ;
remove ( occurs [ var ( l ) ] , cr ) ;
n_occ [ l ] - - ;
updateElimHeap ( var ( l ) ) ;
}
return c . size ( ) = = 1 ? enqueue ( c [ 0 ] ) & & propagate ( ) = = CRef_Undef : true ;
}
// Returns FALSE if clause is always satisfied ('out_clause' should not be used).
bool SimpSolver : : merge ( const Clause & _ps , const Clause & _qs , Var v , vec < Lit > & out_clause )
{
merges + + ;
out_clause . clear ( ) ;
bool ps_smallest = _ps . size ( ) < _qs . size ( ) ;
const Clause & ps = ps_smallest ? _qs : _ps ;
const Clause & qs = ps_smallest ? _ps : _qs ;
for ( int i = 0 ; i < qs . size ( ) ; i + + ) {
if ( var ( qs [ i ] ) ! = v ) {
for ( int j = 0 ; j < ps . size ( ) ; j + + )
if ( var ( ps [ j ] ) = = var ( qs [ i ] ) ) {
if ( ps [ j ] = = ~ qs [ i ] )
return false ;
else
goto next ;
}
out_clause . push ( qs [ i ] ) ;
}
next : ;
}
for ( int i = 0 ; i < ps . size ( ) ; i + + )
if ( var ( ps [ i ] ) ! = v )
out_clause . push ( ps [ i ] ) ;
return true ;
}
// Returns FALSE if clause is always satisfied.
bool SimpSolver : : merge ( const Clause & _ps , const Clause & _qs , Var v , int & size )
{
merges + + ;
bool ps_smallest = _ps . size ( ) < _qs . size ( ) ;
const Clause & ps = ps_smallest ? _qs : _ps ;
const Clause & qs = ps_smallest ? _ps : _qs ;
const Lit * __ps = ( const Lit * ) ps ;
const Lit * __qs = ( const Lit * ) qs ;
size = ps . size ( ) - 1 ;
for ( int i = 0 ; i < qs . size ( ) ; i + + ) {
if ( var ( __qs [ i ] ) ! = v ) {
for ( int j = 0 ; j < ps . size ( ) ; j + + )
if ( var ( __ps [ j ] ) = = var ( __qs [ i ] ) ) {
if ( __ps [ j ] = = ~ __qs [ i ] )
return false ;
else
goto next ;
}
size + + ;
}
next : ;
}
return true ;
}
void SimpSolver : : gatherTouchedClauses ( )
{
if ( n_touched = = 0 ) return ;
int i , j ;
for ( i = j = 0 ; i < subsumption_queue . size ( ) ; i + + )
if ( ca [ subsumption_queue [ i ] ] . mark ( ) = = 0 )
ca [ subsumption_queue [ i ] ] . mark ( 2 ) ;
for ( i = 0 ; i < nVars ( ) ; i + + )
if ( touched [ i ] ) {
const vec < CRef > & cs = occurs . lookup ( i ) ;
for ( j = 0 ; j < cs . size ( ) ; j + + )
if ( ca [ cs [ j ] ] . mark ( ) = = 0 ) {
subsumption_queue . insert ( cs [ j ] ) ;
ca [ cs [ j ] ] . mark ( 2 ) ;
}
touched [ i ] = 0 ;
}
for ( i = 0 ; i < subsumption_queue . size ( ) ; i + + )
if ( ca [ subsumption_queue [ i ] ] . mark ( ) = = 2 )
ca [ subsumption_queue [ i ] ] . mark ( 0 ) ;
n_touched = 0 ;
}
bool SimpSolver : : implied ( const vec < Lit > & c )
{
assert ( decisionLevel ( ) = = 0 ) ;
trail_lim . push ( trail . size ( ) ) ;
for ( int i = 0 ; i < c . size ( ) ; i + + )
if ( value ( c [ i ] ) = = l_True ) {
cancelUntil ( 0 ) ;
return true ;
} else if ( value ( c [ i ] ) ! = l_False ) {
assert ( value ( c [ i ] ) = = l_Undef ) ;
uncheckedEnqueue ( ~ c [ i ] ) ;
}
bool result = propagate ( ) ! = CRef_Undef ;
cancelUntil ( 0 ) ;
return result ;
}
// Backward subsumption + backward subsumption resolution
bool SimpSolver : : backwardSubsumptionCheck ( bool verbose )
{
int cnt = 0 ;
int subsumed = 0 ;
int deleted_literals = 0 ;
assert ( decisionLevel ( ) = = 0 ) ;
while ( subsumption_queue . size ( ) > 0 | | bwdsub_assigns < trail . size ( ) ) {
// Empty subsumption queue and return immediately on user-interrupt:
if ( asynch_interrupt ) {
subsumption_queue . clear ( ) ;
bwdsub_assigns = trail . size ( ) ;
break ; }
// Check top-level assignments by creating a dummy clause and placing it in the queue:
if ( subsumption_queue . size ( ) = = 0 & & bwdsub_assigns < trail . size ( ) ) {
Lit l = trail [ bwdsub_assigns + + ] ;
ca [ bwdsub_tmpunit ] [ 0 ] = l ;
ca [ bwdsub_tmpunit ] . calcAbstraction ( ) ;
subsumption_queue . insert ( bwdsub_tmpunit ) ; }
CRef cr = subsumption_queue . peek ( ) ; subsumption_queue . pop ( ) ;
Clause & c = ca [ cr ] ;
if ( c . mark ( ) ) continue ;
if ( verbose & & verbosity > = 2 & & cnt + + % 1000 = = 0 )
printf ( " subsumption left: %10d (%10d subsumed, %10d deleted literals) \r " , subsumption_queue . size ( ) , subsumed , deleted_literals ) ;
assert ( c . size ( ) > 1 | | value ( c [ 0 ] ) = = l_True ) ; // Unit-clauses should have been propagated before this point.
// Find best variable to scan:
Var best = var ( c [ 0 ] ) ;
for ( int i = 1 ; i < c . size ( ) ; i + + )
if ( occurs [ var ( c [ i ] ) ] . size ( ) < occurs [ best ] . size ( ) )
best = var ( c [ i ] ) ;
// Search all candidates:
vec < CRef > & _cs = occurs . lookup ( best ) ;
CRef * cs = ( CRef * ) _cs ;
for ( int j = 0 ; j < _cs . size ( ) ; j + + )
if ( c . mark ( ) )
break ;
else if ( ! ca [ cs [ j ] ] . mark ( ) & & cs [ j ] ! = cr & & ( subsumption_lim = = - 1 | | ca [ cs [ j ] ] . size ( ) < subsumption_lim ) ) {
Lit l = c . subsumes ( ca [ cs [ j ] ] ) ;
if ( l = = lit_Undef )
subsumed + + , removeClause ( cs [ j ] ) ;
else if ( l ! = lit_Error ) {
deleted_literals + + ;
if ( ! strengthenClause ( cs [ j ] , ~ l ) )
return false ;
// Did current candidate get deleted from cs? Then check candidate at index j again:
if ( var ( l ) = = best )
j - - ;
}
}
}
return true ;
}
bool SimpSolver : : asymm ( Var v , CRef cr )
{
Clause & c = ca [ cr ] ;
assert ( decisionLevel ( ) = = 0 ) ;
if ( c . mark ( ) | | satisfied ( c ) ) return true ;
trail_lim . push ( trail . size ( ) ) ;
Lit l = lit_Undef ;
for ( int i = 0 ; i < c . size ( ) ; i + + )
if ( var ( c [ i ] ) ! = v & & value ( c [ i ] ) ! = l_False )
uncheckedEnqueue ( ~ c [ i ] ) ;
else
l = c [ i ] ;
if ( propagate ( ) ! = CRef_Undef ) {
cancelUntil ( 0 ) ;
asymm_lits + + ;
if ( ! strengthenClause ( cr , l ) )
return false ;
} else
cancelUntil ( 0 ) ;
return true ;
}
bool SimpSolver : : asymmVar ( Var v )
{
assert ( use_simplification ) ;
const vec < CRef > & cls = occurs . lookup ( v ) ;
if ( value ( v ) ! = l_Undef | | cls . size ( ) = = 0 )
return true ;
for ( int i = 0 ; i < cls . size ( ) ; i + + )
if ( ! asymm ( v , cls [ i ] ) )
return false ;
return backwardSubsumptionCheck ( ) ;
}
static void mkElimClause ( vec < uint32_t > & elimclauses , Lit x )
{
elimclauses . push ( toInt ( x ) ) ;
elimclauses . push ( 1 ) ;
}
static void mkElimClause ( vec < uint32_t > & elimclauses , Var v , Clause & c )
{
int first = elimclauses . size ( ) ;
int v_pos = - 1 ;
// Copy clause to elimclauses-vector. Remember position where the
// variable 'v' occurs:
for ( int i = 0 ; i < c . size ( ) ; i + + ) {
elimclauses . push ( toInt ( c [ i ] ) ) ;
if ( var ( c [ i ] ) = = v )
v_pos = i + first ;
}
assert ( v_pos ! = - 1 ) ;
// Swap the first literal with the 'v' literal, so that the literal
// containing 'v' will occur first in the clause:
uint32_t tmp = elimclauses [ v_pos ] ;
elimclauses [ v_pos ] = elimclauses [ first ] ;
elimclauses [ first ] = tmp ;
// Store the length of the clause last:
elimclauses . push ( c . size ( ) ) ;
}
bool SimpSolver : : eliminateVar ( Var v )
{
assert ( ! frozen [ v ] ) ;
assert ( ! isEliminated ( v ) ) ;
assert ( value ( v ) = = l_Undef ) ;
// Split the occurrences into positive and negative:
//
const vec < CRef > & cls = occurs . lookup ( v ) ;
vec < CRef > pos , neg ;
for ( int i = 0 ; i < cls . size ( ) ; i + + )
( find ( ca [ cls [ i ] ] , mkLit ( v ) ) ? pos : neg ) . push ( cls [ i ] ) ;
// Check wether the increase in number of clauses stays within the allowed ('grow'). Moreover, no
// clause must exceed the limit on the maximal clause size (if it is set):
//
int cnt = 0 ;
int clause_size = 0 ;
for ( int i = 0 ; i < pos . size ( ) ; i + + )
for ( int j = 0 ; j < neg . size ( ) ; j + + )
if ( merge ( ca [ pos [ i ] ] , ca [ neg [ j ] ] , v , clause_size ) & &
( + + cnt > cls . size ( ) + grow | | ( clause_lim ! = - 1 & & clause_size > clause_lim ) ) )
return true ;
// Delete and store old clauses:
eliminated [ v ] = true ;
setDecisionVar ( v , false ) ;
eliminated_vars + + ;
if ( pos . size ( ) > neg . size ( ) ) {
for ( int i = 0 ; i < neg . size ( ) ; i + + )
mkElimClause ( elimclauses , v , ca [ neg [ i ] ] ) ;
mkElimClause ( elimclauses , mkLit ( v ) ) ;
} else {
for ( int i = 0 ; i < pos . size ( ) ; i + + )
mkElimClause ( elimclauses , v , ca [ pos [ i ] ] ) ;
mkElimClause ( elimclauses , ~ mkLit ( v ) ) ;
}
for ( int i = 0 ; i < cls . size ( ) ; i + + )
removeClause ( cls [ i ] ) ;
// Produce clauses in cross product:
vec < Lit > & resolvent = add_tmp ;
for ( int i = 0 ; i < pos . size ( ) ; i + + )
for ( int j = 0 ; j < neg . size ( ) ; j + + )
if ( merge ( ca [ pos [ i ] ] , ca [ neg [ j ] ] , v , resolvent ) & & ! addClause_ ( resolvent ) )
return false ;
// Free occurs list for this variable:
occurs [ v ] . clear ( true ) ;
// Free watchers lists for this variable, if possible:
if ( watches [ mkLit ( v ) ] . size ( ) = = 0 ) watches [ mkLit ( v ) ] . clear ( true ) ;
if ( watches [ ~ mkLit ( v ) ] . size ( ) = = 0 ) watches [ ~ mkLit ( v ) ] . clear ( true ) ;
return backwardSubsumptionCheck ( ) ;
}
bool SimpSolver : : substitute ( Var v , Lit x )
{
assert ( ! frozen [ v ] ) ;
assert ( ! isEliminated ( v ) ) ;
assert ( value ( v ) = = l_Undef ) ;
if ( ! ok ) return false ;
eliminated [ v ] = true ;
setDecisionVar ( v , false ) ;
const vec < CRef > & cls = occurs . lookup ( v ) ;
vec < Lit > & subst_clause = add_tmp ;
for ( int i = 0 ; i < cls . size ( ) ; i + + ) {
Clause & c = ca [ cls [ i ] ] ;
subst_clause . clear ( ) ;
for ( int j = 0 ; j < c . size ( ) ; j + + ) {
Lit p = c [ j ] ;
subst_clause . push ( var ( p ) = = v ? x ^ sign ( p ) : p ) ;
}
removeClause ( cls [ i ] ) ;
if ( ! addClause_ ( subst_clause ) )
return ok = false ;
}
return true ;
}
void SimpSolver : : extendModel ( )
{
int i , j ;
Lit x ;
for ( i = elimclauses . size ( ) - 1 ; i > 0 ; i - = j ) {
for ( j = elimclauses [ i - - ] ; j > 1 ; j - - , i - - )
if ( modelValue ( toLit ( elimclauses [ i ] ) ) ! = l_False )
goto next ;
x = toLit ( elimclauses [ i ] ) ;
model [ var ( x ) ] = lbool ( ! sign ( x ) ) ;
next : ;
}
}
bool SimpSolver : : eliminate ( bool turn_off_elim )
{
if ( ! simplify ( ) )
return false ;
else if ( ! use_simplification )
return true ;
// Main simplification loop:
//
while ( n_touched > 0 | | bwdsub_assigns < trail . size ( ) | | elim_heap . size ( ) > 0 ) {
gatherTouchedClauses ( ) ;
// printf(" ## (time = %6.2f s) BWD-SUB: queue = %d, trail = %d\n", cpuTime(), subsumption_queue.size(), trail.size() - bwdsub_assigns);
if ( ( subsumption_queue . size ( ) > 0 | | bwdsub_assigns < trail . size ( ) ) & &
! backwardSubsumptionCheck ( true ) ) {
ok = false ; goto cleanup ; }
// Empty elim_heap and return immediately on user-interrupt:
if ( asynch_interrupt ) {
assert ( bwdsub_assigns = = trail . size ( ) ) ;
assert ( subsumption_queue . size ( ) = = 0 ) ;
assert ( n_touched = = 0 ) ;
elim_heap . clear ( ) ;
goto cleanup ; }
// printf(" ## (time = %6.2f s) ELIM: vars = %d\n", cpuTime(), elim_heap.size());
for ( int cnt = 0 ; ! elim_heap . empty ( ) ; cnt + + ) {
Var elim = elim_heap . removeMin ( ) ;
if ( asynch_interrupt ) break ;
if ( isEliminated ( elim ) | | value ( elim ) ! = l_Undef ) continue ;
if ( verbosity > = 2 & & cnt % 100 = = 0 )
printf ( " elimination left: %10d \r " , elim_heap . size ( ) ) ;
if ( use_asymm ) {
// Temporarily freeze variable. Otherwise, it would immediately end up on the queue again:
bool was_frozen = frozen [ elim ] ;
frozen [ elim ] = true ;
if ( ! asymmVar ( elim ) ) {
ok = false ; goto cleanup ; }
frozen [ elim ] = was_frozen ; }
// At this point, the variable may have been set by assymetric branching, so check it
// again. Also, don't eliminate frozen variables:
if ( use_elim & & value ( elim ) = = l_Undef & & ! frozen [ elim ] & & ! eliminateVar ( elim ) ) {
ok = false ; goto cleanup ; }
checkGarbage ( simp_garbage_frac ) ;
}
assert ( subsumption_queue . size ( ) = = 0 ) ;
}
cleanup :
// If no more simplification is needed, free all simplification-related data structures:
if ( turn_off_elim ) {
touched . clear ( true ) ;
occurs . clear ( true ) ;
n_occ . clear ( true ) ;
elim_heap . clear ( true ) ;
subsumption_queue . clear ( true ) ;
use_simplification = false ;
remove_satisfied = true ;
ca . extra_clause_field = false ;
max_simp_var = nVars ( ) ;
// Force full cleanup (this is safe and desirable since it only happens once):
rebuildOrderHeap ( ) ;
garbageCollect ( ) ;
} else {
// Cheaper cleanup:
checkGarbage ( ) ;
}
if ( verbosity > = 1 & & elimclauses . size ( ) > 0 )
printf ( " | Eliminated clauses: %10.2f Mb | \n " ,
double ( elimclauses . size ( ) * sizeof ( uint32_t ) ) / ( 1024 * 1024 ) ) ;
return ok ;
}
//=================================================================================================
// Garbage Collection methods:
void SimpSolver : : relocAll ( ClauseAllocator & to )
{
if ( ! use_simplification ) return ;
// All occurs lists:
//
for ( int i = 0 ; i < nVars ( ) ; i + + ) {
occurs . clean ( i ) ;
vec < CRef > & cs = occurs [ i ] ;
for ( int j = 0 ; j < cs . size ( ) ; j + + )
ca . reloc ( cs [ j ] , to ) ;
}
// Subsumption queue:
//
for ( int i = subsumption_queue . size ( ) ; i > 0 ; i - - ) {
CRef cr = subsumption_queue . peek ( ) ; subsumption_queue . pop ( ) ;
if ( ca [ cr ] . mark ( ) ) continue ;
ca . reloc ( cr , to ) ;
subsumption_queue . insert ( cr ) ;
}
// Temporary clause:
//
ca . reloc ( bwdsub_tmpunit , to ) ;
}
void SimpSolver : : garbageCollect ( )
{
// Initialize the next region to a size corresponding to the estimated utilization degree. This
// is not precise but should avoid some unnecessary reallocations for the new region:
ClauseAllocator to ( ca . size ( ) - ca . wasted ( ) ) ;
to . extra_clause_field = ca . extra_clause_field ; // NOTE: this is important to keep (or lose) the extra fields.
relocAll ( to ) ;
Solver : : relocAll ( to ) ;
if ( verbosity > = 2 )
printf ( " | Garbage collection: %12d bytes => %12d bytes | \n " ,
ca . size ( ) * ClauseAllocator : : Unit_Size , to . size ( ) * ClauseAllocator : : Unit_Size ) ;
to . moveTo ( ca ) ;
}