static CLAUSE inf_CreateURUnitResolvent(CLAUSE Clause, int i, SUBST Subst, LIST FoundMap, FLAGSTORE Flags, PRECEDENCE Precedence) /************************************************************** INPUT: A non-unit clause, a literal index from the clause, a substitution, a list of pairs (l1, l2) of literals, where l1 is from the non-unit clause and l2 is from a unit clause, a flag store and a precedence. RETURNS: The resolvent of this UR resolution inference. The clause consists of the literal at index <i> in <Clause> after application of <Subst>. EFFECT: The flag store and the precedence are needed to create the new clause. ***************************************************************/ { CLAUSE Result, PClause; LITERAL Lit; TERM Atom; LIST Parents; NAT depth; /* Create atom for resolvent */ Atom = subst_Apply(Subst, term_Copy(clause_GetLiteralAtom(Clause, i))); /* Create clause */ Parents = list_List(Atom); if (i <= clause_LastConstraintLitIndex(Clause)) Result = clause_Create(Parents, list_Nil(), list_Nil(), Flags, Precedence); else if (i <= clause_LastAntecedentLitIndex(Clause)) Result = clause_Create(list_Nil(), Parents, list_Nil(), Flags, Precedence); else Result = clause_Create(list_Nil(), list_Nil(), Parents, Flags, Precedence); list_Delete(Parents); /* Get parent clauses and literals, calculate depth of resolvent */ Parents = list_List(Clause); depth = clause_Depth(Clause); for ( ; !list_Empty(FoundMap); FoundMap = list_Cdr(FoundMap)) { Lit = list_PairSecond(list_Car(FoundMap)); /* Literal from unit */ PClause = clause_LiteralOwningClause(Lit); Parents = list_Cons(PClause, Parents); depth = misc_Max(depth, clause_Depth(PClause)); clause_AddParentClause(Result, clause_Number(PClause)); clause_AddParentLiteral(Result, clause_LiteralGetIndex(Lit)); Lit = list_PairFirst(list_Car(FoundMap)); /* Is from <Clause> */ clause_AddParentClause(Result, clause_Number(Clause)); clause_AddParentLiteral(Result, clause_LiteralGetIndex(Lit)); } clause_SetFromURResolution(Result); clause_SetDepth(Result, depth+1); clause_SetSplitDataFromList(Result, Parents); list_Delete(Parents); return Result; }
static CLAUSE red_CreateTerminatorEmptyClause(LIST FoundMap, FLAGSTORE Flags, PRECEDENCE Precedence) /************************************************************** INPUT: A list of pairs (l1, l2), where l1 and l2 are unifiable literals with complementary sign and a flag store. More accurately, a substitution s exists, such that l1 s = l2 s for all pairs (l1,l2) in <FoundMap>. For all literals l from the involved clauses there exists one pair (l1,l2) in <FoundMap> with l1=l or l2=l. The flags store and the precedence are needed to create the new clause. RETURNS: A newly created empty clause, where the data (parents,...) is set according to <FoundMap>. ***************************************************************/ { CLAUSE Result, PClause; LITERAL Lit; LIST Parents; NAT depth; Result = clause_Create(list_Nil(), list_Nil(), list_Nil(), Flags, Precedence); Parents = list_Nil(); depth = 0; for (; !list_Empty(FoundMap); FoundMap = list_Cdr(FoundMap)) { Lit = list_PairSecond(list_Car(FoundMap)); PClause = clause_LiteralOwningClause(Lit); Parents = list_Cons(PClause, Parents); depth = misc_Max(depth, clause_Depth(PClause)); clause_AddParentClause(Result, clause_Number(PClause)); clause_AddParentLiteral(Result, clause_LiteralGetIndex(Lit)); Lit = list_PairFirst(list_Car(FoundMap)); PClause = clause_LiteralOwningClause(Lit); Parents = list_Cons(PClause, Parents); depth = misc_Max(depth, clause_Depth(PClause)); clause_AddParentClause(Result, clause_Number(PClause)); clause_AddParentLiteral(Result, clause_LiteralGetIndex(Lit)); } clause_SetFromTerminator(Result); clause_SetDepth(Result, depth+1); clause_SetSplitDataFromList(Result, Parents); list_Delete(Parents); return Result; }
LIST split_Backtrack(PROOFSEARCH PS, CLAUSE EmptyClause, CLAUSE* SplitClause) /************************************************************** INPUT: A proofsearch object, an empty clause and a pointer to a clause used as return value. RETURNS: A list of clauses deleted in the backtracked split levels. <*SplitClause> is set to the split clause for the right branch of the splitting step, or NULL, if the tableau is finished. EFFECT: Backtracks the top of the split stack wrt the empty clause's level ***************************************************************/ { SPLIT ActBacktrackSplit; LIST RecoverList, Scan; int Backtracklevel; ActBacktrackSplit = (SPLIT)NULL; RecoverList = split_RemoveUnnecessarySplits(PS, EmptyClause); Backtracklevel = clause_SplitLevel(EmptyClause); *SplitClause = NULL; /* Backtrack all split levels bigger than the level of the empty clause */ while (!prfs_SplitStackEmpty(PS) && (prfs_ValidLevel(PS) > Backtracklevel)) { ActBacktrackSplit = prfs_SplitStackTop(PS); prfs_SplitStackPop(PS); if (prfs_SplitFatherClause(ActBacktrackSplit) != (CLAUSE)NULL) { RecoverList = list_Cons(prfs_SplitFatherClause(ActBacktrackSplit), RecoverList); prfs_SplitSetFatherClause(ActBacktrackSplit, NULL); } RecoverList = list_Nconc(prfs_SplitDeletedClauses(ActBacktrackSplit), RecoverList); clause_DeleteClauseList(prfs_SplitBlockedClauses(ActBacktrackSplit)); prfs_SplitFree(ActBacktrackSplit); prfs_DecValidLevel(PS); } /* Backtrack further for all right branches on top of the stack */ while (!prfs_SplitStackEmpty(PS) && list_Empty(prfs_SplitBlockedClauses(prfs_SplitStackTop(PS)))) { ActBacktrackSplit = prfs_SplitStackTop(PS); prfs_SplitStackPop(PS); if (prfs_SplitFatherClause(ActBacktrackSplit) != (CLAUSE)NULL) RecoverList = list_Cons(prfs_SplitFatherClause(ActBacktrackSplit), RecoverList); RecoverList = list_Nconc(prfs_SplitDeletedClauses(ActBacktrackSplit), RecoverList); prfs_SplitFree(ActBacktrackSplit); prfs_DecValidLevel(PS); } if (!prfs_SplitStackEmpty(PS)) { /* Enter the right branch of the splitting step */ int SplitMinus1; LIST RightClauses; SplitMinus1 = prfs_ValidLevel(PS) - 1; ActBacktrackSplit = prfs_SplitStackTop(PS); RecoverList = list_Nconc(prfs_SplitDeletedClauses(ActBacktrackSplit), RecoverList); prfs_SplitSetDeletedClauses(ActBacktrackSplit, list_Nil()); RecoverList = split_DeleteInvalidClausesFromList(PS, SplitMinus1, RecoverList); RightClauses = prfs_SplitBlockedClauses(ActBacktrackSplit); prfs_SplitSetBlockedClauses(ActBacktrackSplit, list_Nil()); for (Scan = RightClauses; !list_Empty(Scan); Scan = list_Cdr(Scan)) { if (clause_Number(list_Car(Scan)) == 0) { /* Found the right clause, the negation clauses have number -1. */ #ifdef CHECK if (*SplitClause != NULL) { misc_StartErrorReport(); misc_ErrorReport("\n In split_Backtrack:"); misc_ErrorReport(" Found two blocked clauses "); misc_ErrorReport("\n with clause number 0 (this marks the clause "); misc_ErrorReport("\n for the right branch of the tableau)."); misc_FinishErrorReport(); } #endif *SplitClause = list_Car(Scan); } clause_NewNumber((CLAUSE) list_Car(Scan)); clause_AddParentClause((CLAUSE) list_Car(Scan), clause_Number(EmptyClause)); clause_AddParentLiteral((CLAUSE) list_Car(Scan), 0); /* dummy literal */ } #ifdef CHECK if (*SplitClause == NULL) { misc_StartErrorReport(); misc_ErrorReport("\n In split_Backtrack: DidnĀ“t find a blocked clause"); misc_ErrorReport("\n with clause number 0. (this marks the clause "); misc_ErrorReport("\n for the right branch of the tableau)."); misc_FinishErrorReport(); } #endif RecoverList = list_Nconc(RightClauses, RecoverList); /* Then, delete clauses from current level (Hack) */ prfs_DecValidLevel(PS); prfs_MoveInvalidClausesDocProof(PS); split_DeleteInvalidClausesFromStack(PS); prfs_IncValidLevel(PS); } else { /* Don't delete clauses from current level (split is top level) */ prfs_MoveInvalidClausesDocProof(PS); for (Scan = RecoverList; !list_Empty(Scan); Scan = list_Cdr(Scan)) prfs_InsertDocProofClause(PS, list_Car(Scan)); list_Delete(RecoverList); RecoverList = list_Nil(); } prfs_SetLastBacktrackLevel(PS, prfs_ValidLevel(PS)); return RecoverList; }