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lglib.h
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lglib.h
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/*-------------------------------------------------------------------------*/
/* Copyright 2010-2020 Armin Biere Johannes Kepler University Linz Austria */
/*-------------------------------------------------------------------------*/
#ifndef lglib_h_INCLUDED
#define lglib_h_INCLUDED
#include <stdio.h> // for 'FILE'
#include <stdlib.h> // for 'int64_t'
//--------------------------------------------------------------------------
#define LGL_UNKNOWN 0
#define LGL_SATISFIABLE 10
#define LGL_UNSATISFIABLE 20
//--------------------------------------------------------------------------
typedef struct LGL LGL;
//--------------------------------------------------------------------------
LGL * lglinit (void); // constructor
void lglrelease (LGL *); // destructor
// externally provided memory manager ...
typedef void * (*lglalloc) (void*mem, size_t);
typedef void (*lgldealloc) (void*mem, void*, size_t);
typedef void * (*lglrealloc) (void*mem, void *ptr, size_t old, size_t);
LGL * lglminit (void *mem, lglalloc, lglrealloc, lgldealloc);
// 'Cloning' produces identicaly behaving solvers.
LGL * lglclone (LGL *);
LGL * lglmclone (LGL *, void *mem, lglalloc, lglrealloc, lgldealloc);
int lglunclone (LGL * dst, LGL * src); // does not release 'src'
// 'Forking' copies only irredundant clauses and also uses internal variable
// indices of the parent as external variable indices. Thus 'parent' and
// the forked off 'child' do neither exactly work the same way, nor do they
// use from the API point of view the same set of variables. They are
// satisfiability equivalent. If the child becomes unsatisfiable the parent
// can be assumed to be unsatisfiable too and thus 'lgljoin' would just add
// the empty clause to the parent. If the child produces a satisfying
// assignment, this assignment is turned into an assignment of the parent by
// 'lgljoin'. Parents can be forked multiple times. A child has exactly
// one parent. Parents and children can be released independently. Between
// 'lglfork' and 'lgljoin' no other operations but further 'lglfork' are
// allowed. The effect ot multiple 'lgljoin' with the same parent is
// unclear at this point. The same memory manager is use for the child and
// the parent. Options, prefix, output file and the callbacks for 'getime'
// and 'onabort' are copied too (if set).
LGL * lglfork (LGL * parent);
int lgljoin (LGL * parent, LGL * child); // does not release 'child'
// Both 'Cloning' and 'Forking' can be used to implement 'Push & Pop', but
// the asymmetric forking is more similar to the classical way of
// implementing it, needs less resources since for instance eliminated
// variables do not occupy any memory in the children, but requires lifting
// back satisfying assignments explicitly (through the whole parent chain).
// If these full satisfying assignments are really needed actually cloning
// could be more space efficient too. Assume you want to split the solver
// into two instances, one with a literal set to false, the other one to
// true. Then cloning allows you to produce two independent branches, while
// for forking you need three, since the root / top solver still has to be
// kept for lifting back a potential assignment.
//--------------------------------------------------------------------------
const char * lglparsefile (LGL *, FILE *, int force,
int * lineno_ptr, int * max_var_ptr);
const char * lglparsepath (LGL *, const char * path, int force,
int * lineno_ptr, int * max_var_ptr);
//--------------------------------------------------------------------------
const char * lglversion ();
void lglbnr (const char * name,
const char * prefix,
FILE * file); // ... banner
void lglusage (LGL *); // print usage "-h"
void lglopts (LGL *, const char * prefix, int); // ... defaults "-d" | "-e"
void lglrgopts (LGL *); // ... option ranges "-r"
void lglpcs (LGL *, int mixed); // ... PCS file
void lglsizes (LGL *); // ... data structure sizes
//--------------------------------------------------------------------------
// setters and getters for options
void lglsetout (LGL *, FILE*); // output file for report
void lglsetrace (LGL *, FILE*); // set trace output file
void lglsetprefix (LGL *, const char*); // prefix for messages
FILE * lglgetout (LGL *);
const char * lglgetprefix (LGL *);
void lglsetopt (LGL *, const char *, int); // set option value
int lglreadopts (LGL *, FILE *); // read and set options
int lglgetopt (LGL *, const char *); // get option value
int lgldefopt (LGL *, const char *); // get default value
int lglhasopt (LGL *, const char *); // exists option?
int lglgetoptminmax (LGL *, const char *, int * minptr, int * maxptr);
void * lglfirstopt (LGL *); // option iterator: first
void * lglnextopt (LGL *, // option iterator: next
void * iterator,
const char ** nameptr,
int *valptr, int *minptr, int *maxptr);
// individual ids for logging and statistics:
void lglsetid (LGL *, int tid, int tids);
// Set default phase of a literal. Any decision on this literal will always
// try this phase. Note, that this function does not have any effect on
// eliminated variables. Further equivalent variables share the same forced
// phase and thus if they are set to different default phases, only the last
// set operation will be kept.
void lglsetphase (LGL *, int lit);
void lglresetphase (LGL *, int lit); // Stop forcing phase in decisions.
// Prefer decisions on 'important' variables.
void lglsetimportant (LGL *, int lit);
// Assume the solver is in the SATISFIABLE state (after 'lglsat' or
// 'lglsimp'), then calling 'lglsetphases' will copy the current assignment
// as default phases.
void lglsetphases (LGL *);
//--------------------------------------------------------------------------
// call back for abort
void lglonabort (LGL *, void * state, void (*callback)(void* state));
//--------------------------------------------------------------------------
// write and read API trace
void lglwtrapi (LGL *, FILE *);
void lglrtrapi (LGL *, FILE *);
//--------------------------------------------------------------------------
// traverse units, equivalences, remaining clauses, or all clauses:
void lglutrav (LGL *, void * state, void (*trav)(void *, int unit));
void lgletrav (LGL *, void * state, void (*trav)(void *, int lit, int repr));
void lglctrav (LGL *, void * state, void (*trav)(void *, int lit));
void lgltravall (LGL *, void * state, void (*trav)(void *state, int lit));
//--------------------------------------------------------------------------
void lglprint (LGL *, FILE *); // remaining in DIMACS format
void lglprintall (LGL *, FILE *); // including units & equivs
//--------------------------------------------------------------------------
// main interface as in PicoSAT (see 'picosat.h' for more information)
int lglmaxvar (LGL *);
int lglincvar (LGL *);
void lgladd (LGL *, int lit);
void lglassume (LGL *, int lit); // assume single units
void lglcassume (LGL *, int lit); // assume clause
// (at most one)
void lglfixate (LGL *); // add assumptions as units
int lglsat (LGL *);
int lglsimp (LGL *, int iterations);
int lglderef (LGL *, int lit); // neg=false, pos=true
int lglfixed (LGL *, int lit); // ditto but toplevel
int lglfailed (LGL *, int lit); // ditto for assumptions
int lglinconsistent (LGL *); // contains empty clause?
int lglchanged (LGL *); // model changed
void lglreducecache (LGL *); // reset cache size
void lglflushcache (LGL *); // flush all learned clauses
/*------------------------------------------------------------------------*/
/* Return representative from equivalence class if literal is not top-level
* assigned nor eliminated.
*/
int lglrepr (LGL *, int lit);
/* Set 'startptr' and 'toptr' to the 'start' and 'top' of the reconstruction
* stack, which is used in BCE, BVE and CCE for reconstructing a solution
* after eliminating variables or clauses. These pointers are only valid
* until the next 'lglsat/lglsimp' call.
*/
void lglreconstk (LGL * lgl, int ** startptr, int ** toptr);
//--------------------------------------------------------------------------
// Incremental interface provides reference counting for indices, i.e.
// unfrozen indices become invalid after next 'lglsat' (or 'lglsimp').
// This is actually a reference counter for variable indices still in use
// after the next 'lglsat' or 'lglsimp' call. It is actually variable based
// and only applies to literals in new clauses or used as assumptions,
// e.g. in calls to 'lgladd' and 'lglassume'.
//
// The following example is actually compilable and used for explaining
// all the details of this rather complicated incremental API contract:
/***** start of incremental example ***************************************
#include "lglib.h"
#ifdef NDEBUG
#undef NDEBUG
#endif
#include <assert.h>
int main () {
LGL * lgl = lglinit ();
int res;
lgladd (lgl, -14); lgladd (lgl, 2); lgladd (lgl, 0); // binary clause
lgladd (lgl, 14); lgladd (lgl, -1); lgladd (lgl, 0); // binary clause
lglassume (lgl, 1); // assume '1'
lglfreeze (lgl, 1); // will use '1' below
lglfreeze (lgl, 14); // will use '14 too
assert (lglfrozen (lgl, 1));
assert (lglfrozen (lgl, 14));
res = lglsat (lgl);
assert (res == 10);
(void) lglderef (lgl, 1); // fine
(void) lglderef (lgl, 2); // fine
(void) lglderef (lgl, 3); // fine !
(void) lglderef (lgl, 14); // fine
assert (!lglusable (lgl, 2));
// lgladd (lgl, 2); // ILLEGAL
// lglassume (lgl, 2); // ILLEGAL
assert (lglusable (lgl, 15)); // '15' not used yet!
lgladd (lgl, -14); lgladd (lgl, 1); lgladd (lgl, 0); // binary clause
lgladd (lgl, 15); lgladd (lgl, 0); // fine!
lglmelt (lgl, 14); // '1' discarded
res = lglsat (lgl);
assert (res == 10);
assert (lglfrozen (lgl, 1));
(void) lglderef (lgl, 1); // fine
(void) lglderef (lgl, 2); // fine
(void) lglderef (lgl, 3); // fine
(void) lglderef (lgl, 14); // fine
(void) lglderef (lgl, 15); // fine
assert (!lglusable (lgl, 2));
assert (!lglusable (lgl, 14));
// lglassume (lgl, 2); // ILLEGAL
// lglassume (lgl, 14); // ILLEGAL
lgladd (lgl, 1); // still frozen
lglmelt (lgl, 1);
lgladd (lgl, 0);
res = lglsat (lgl);
assert (res == 10); // TODO right?
// none frozen
assert (!lglusable (lgl, 1));
// lgladd(lgl, 1); // ILLEGAL
lglsetopt (lgl, "plain", 1); // disable BCE ...
lgladd (lgl, 8); lgladd (lgl, -9); lgladd (lgl, 0);
res = lglsat (lgl);
assert (res == 10);
assert (!lglusable (lgl, 8));
assert (!lglusable (lgl, -9));
assert (lglreusable (lgl, 8));
assert (lglreusable (lgl, -9));
lglreuse (lgl, 8);
lgladd (lgl, -8); lgladd (lgl, 0);
lglsetopt (lgl, "plain", 0); // enable BCE ...
res = lglsat (lgl);
assert (res);
return res;
}
****** end of incremental example ****************************************/
void lglfreeze (LGL *, int lit);
int lglfrozen (LGL *, int lit);
void lglmelt (LGL *, int lit);
void lglmeltall (LGL *); // melt all literals
// If a literal was not frozen at the last call to 'lglsat' (or 'lglsimp')
// it becomes 'unusable' after the next call even though it might not
// have been used as blocking literal etc. This
int lglusable (LGL *, int lit);
int lglreusable (LGL *, int lit);
void lglreuse (LGL *, int lit);
//--------------------------------------------------------------------------
// Returns a good look ahead literal or zero if all potential literals have
// been eliminated or have been used as blocking literals in blocked clause
// elimination. Zero is also returned if the formula is already
// inconsistent. The lookahead literal is made usable again, for instance
// if it was not frozen during a previous SAT call and thus implicitly
// became melted. Therefore it can be added in a unit clause.
int lglookahead (LGL *);
//--------------------------------------------------------------------------
// stats:
void lglflushtimers (LGL *lgl); // after interrupt etc.
void lglstats (LGL *);
int64_t lglgetconfs (LGL *);
int64_t lglgetdecs (LGL *);
int64_t lglgetprops (LGL *);
size_t lglbytes (LGL *);
int lglnvars (LGL *);
int lglnclauses (LGL *);
double lglmb (LGL *);
double lglmaxmb (LGL *);
double lglsec (LGL *);
double lglprocesstime (void);
//--------------------------------------------------------------------------
// low-level parallel support through call backs
void lglseterm (LGL *, int (*term)(void*), void*);
void lglsetproduceunit (LGL *, void (*produce)(void*, int), void*);
void lglsetconsumeunits (LGL *, void (*consume)(void*,int**,int**), void*);
void lglsetconsumedunits (LGL *, void (*consumed)(void*,int), void*);
void lglsetproducecls (LGL*, void(*produce)(void*,int*,int glue),void*);
void lglsetconsumecls (LGL*,void(*consume)(void*,int**,int *glueptr),void*);
void lglsetconsumedcls (LGL *, void (*consumed)(void*,int), void*);
void lglsetlockeq (LGL *, int * (*lock)(void*), void *);
void lglsetunlockeq (LGL *, void (*unlock)(void*,int cons,int prod), void *);
void lglsetmsglock (LGL *, void (*lock)(void*), void (*unlock)(void*), void*);
void lglsetime (LGL *, double (*time)(void));
#endif