/************************************************************************* * * * YAP Prolog * * * * Yap Prolog was developed at NCCUP - Universidade do Porto * * * * Copyright L.Damas, V.S.Costa and Universidade do Porto 1985-1997 * * * ************************************************************************** * * * File: exec.c * * Last rev: 8/2/88 * * mods: * * comments: Execute Prolog code * * * *************************************************************************/ #ifdef SCCS static char SccsId[] = "@(#)cdmgr.c 1.1 05/02/98"; #endif #include "absmi.h" #include "yapio.h" STATIC_PROTO(Int CallPredicate, (PredEntry *, choiceptr)); STATIC_PROTO(Int CallClause, (PredEntry *, unsigned int, Int)); STATIC_PROTO(Int p_save_cp, (void)); STATIC_PROTO(Int p_execute, (void)); STATIC_PROTO(Int p_execute0, (void)); STATIC_PROTO(Int p_at_execute, (void)); static Term current_cp_as_integer(void) { return(MkIntTerm(LCL0-(CELL *)B)); } static inline Int CallPredicate(PredEntry *pen, choiceptr cut_pt) { WRITE_LOCK(pen->PRWLock); #ifdef DEPTH_LIMIT if (DEPTH <= MkIntTerm(1)) {/* I assume Module==0 is prolog */ if (pen->ModuleOfPred) { if (DEPTH == MkIntTerm(0)) return(FALSE); else DEPTH = RESET_DEPTH(); } } else if (pen->ModuleOfPred) DEPTH -= MkIntConstant(2); #endif /* DEPTH_LIMIT */ #ifdef LOW_LEVEL_TRACER if (do_low_level_trace) low_level_trace(enter_pred,pen,XREGS+1); #endif /* LOW_LEVEL_TRACE */ CP = P; P = (yamop *)(pen->CodeOfPred); /* vsc: increment reduction counter at meta-call entry */ WRITE_UNLOCK(pen->PRWLock); if (pen->PredFlags & ProfiledPredFlag) { LOCK(pen->StatisticsForPred.lock); pen->StatisticsForPred.NOfEntries++; UNLOCK(pen->StatisticsForPred.lock); } ENV = YENV; YENV = ASP; YENV[E_CB] = (CELL) cut_pt; return (TRUE); } inline static Int CallMetaCall(SMALLUNSGN mod) { ARG2 = current_cp_as_integer(); /* p_save_cp */ ARG3 = ARG1; ARG4 = ModuleName[mod]; return (CallPredicate(PredMetaCall, B)); } Term ExecuteCallMetaCall(SMALLUNSGN mod) { Term ts[4]; ts[0] = ARG1; ts[1] = current_cp_as_integer(); /* p_save_cp */ ts[2] = ARG1; ts[3] = ModuleName[mod]; return(MkApplTerm(PredMetaCall->FunctorOfPred,4,ts)); } static Int CallError(yap_error_number err, SMALLUNSGN mod) { if (yap_flags[LANGUAGE_MODE_FLAG] == 1) { return(CallMetaCall(mod)); } else { Error(err, ARG1, "call/1"); return(FALSE); } } static Int CallClause(PredEntry *pen, unsigned int arity, Int position) { CELL flags; if (position == -1) return(CallPredicate(pen, B)); WRITE_LOCK(pen->PRWLock); flags = pen->PredFlags; if ((flags & (CompiledPredFlag | DynamicPredFlag)) || pen->OpcodeOfPred == UNDEF_OPCODE) { CODEADDR q; #ifdef DEPTH_LIMIT if (DEPTH <= MkIntTerm(1)) {/* I assume Module==0 is prolog */ if (pen->ModuleOfPred) { if (DEPTH == MkIntTerm(0)) return(FALSE); else DEPTH = RESET_DEPTH(); } } else if (pen->ModuleOfPred) DEPTH -= MkIntConstant(2); #endif /* DEPTH_LIMIT */ #ifdef LOW_LEVEL_TRACER if (do_low_level_trace) low_level_trace(enter_pred,pen,XREGS+1); #endif /* LOW_LEVEL_TRACE */ ENV = YENV; YENV = ASP; YENV[E_CB] = (CELL)(B->cp_b); CP = P; q = pen->FirstClause; if (pen->PredFlags & ProfiledPredFlag) { LOCK(pen->StatisticsForPred.lock); if (position == 1) pen->StatisticsForPred.NOfEntries++; else pen->StatisticsForPred.NOfRetries++; UNLOCK(pen->StatisticsForPred.lock); } if (flags & DynamicPredFlag) { CLAUSECODE->arity = pen->ArityOfPE; CLAUSECODE->func = pen->FunctorOfPred; while (position > 1) { while (ClauseCodeToClause(q)->ClFlags & ErasedMask) q = NextClause(q); position--; q = NextClause(q); } while (ClauseCodeToClause(q)->ClFlags & ErasedMask) q = NextClause(q); #if defined(YAPOR) || defined(THREADS) { Clause *cl = ClauseCodeToClause(q); LOCK(cl->ClLock); TRAIL_CLREF(cl); INC_DBREF_COUNT(cl); UNLOCK(cl->ClLock); } #else if (!(ClauseCodeToClause(q)->ClFlags & InUseMask)) { OPREG *opp = &(ClauseCodeToClause(q)->ClFlags); TRAIL_CLREF(ClauseCodeToClause(q)); *opp |= InUseMask; } #endif CLAUSECODE->clause = (CODEADDR)NEXTOP((yamop *)(q),ld); P = (yamop *)CLAUSECODE->clause; WRITE_UNLOCK(pen->PRWLock); return((CELL)(&(CLAUSECODE->clause))); } else { for (; position > 1; position--) q = NextClause(q); P = NEXTOP((yamop *)(q),ld); WRITE_UNLOCK(pen->PRWLock); return (Unsigned(pen)); } } else { Error(SYSTEM_ERROR,ARG1,"debugger tries to debug clause for builtin"); return (FALSE); } } static Int p_save_cp(void) { Term t = Deref(ARG1); Term td; #if SHADOW_HB register CELL *HBREG = HB; #endif if (!IsVarTerm(t)) return(FALSE); td = current_cp_as_integer(); BIND((CELL *)t,td,bind_save_cp); #ifdef COROUTINING DO_TRAIL(CellPtr(t), td); if (CellPtr(t) < H0) WakeUp((CELL *)t); bind_save_cp: #endif return(TRUE); } static Int EnterCreepMode(SMALLUNSGN mod) { PredEntry *PredSpy = RepPredProp(PredPropByFunc(FunctorSpy,0)); Term tn = MkApplTerm(MkFunctor(AtomMetaCall,1),1,&ARG1); ARG1 = MkPairTerm(ModuleName[mod],tn); CreepFlag = CalculateStackGap(); P_before_spy = P; return (CallPredicate(PredSpy, B)); } /* push module inside so that it will visible to the next calls */ static Term PushModule(Term t,SMALLUNSGN mod) { Functor f = FunctorOfTerm(t); Term tmod = ModuleName[mod]; if (ArityOfFunctor(f) == 2) { Term ti[2], tf[2]; ti[0] = tmod; ti[1] = ArgOfTerm(1,t); tf[0] = MkApplTerm(FunctorModule,2,ti); ti[0] = tmod; ti[1] = ArgOfTerm(2,t); tf[1] = MkApplTerm(FunctorModule,2,ti); return(MkApplTerm(f,2,tf)); } else { Term ti[2], tf[1]; ti[0] = tmod; ti[1] = ArgOfTerm(1,t); tf[0] = MkApplTerm(FunctorModule,2,ti); return(MkApplTerm(f,1,tf)); } } inline static Int do_execute(Term t, SMALLUNSGN mod) { if (yap_flags[SPY_CREEP_FLAG]) { return(EnterCreepMode(mod)); } else if (PredGoalExpansion->OpcodeOfPred != UNDEF_OPCODE) { return(CallMetaCall(mod)); } restart_exec: if (IsVarTerm(t)) { return CallError(INSTANTIATION_ERROR, mod); } else if (IsApplTerm(t)) { register Functor f = FunctorOfTerm(t); register CELL *pt; PredEntry *pen; unsigned int i, arity; f = FunctorOfTerm(t); if (IsExtensionFunctor(f)) { return CallError(TYPE_ERROR_CALLABLE, mod); } arity = ArityOfFunctor(f); pen = RepPredProp(PredPropByFunc(f, mod)); /* You thought we would be over by now */ /* but no meta calls require special preprocessing */ if (pen->PredFlags & MetaPredFlag) { if (f == FunctorModule) { Term tmod = ArgOfTerm(1,t); if (!IsVarTerm(tmod) && IsAtomTerm(tmod)) { mod = LookupModule(tmod); t = ArgOfTerm(2,t); goto restart_exec; } } if (pen->PredFlags & PushModPredFlag) { t = PushModule(t,mod); } return(CallMetaCall(mod)); } /* now let us do what we wanted to do from the beginning !! */ /* I cannot use the standard macro here because otherwise I would dereference the argument and might skip a svar */ pt = RepAppl(t)+1; for (i = 1; i <= arity; i++) { #if SBA Term d0 = *pt++; if (d0 == 0) XREGS[i] = (CELL)(pt-1); else XREGS[i] = d0; #else XREGS[i] = *pt++; #endif } return (CallPredicate(pen, B)); } else if (IsAtomTerm(t)) { PredEntry *pe; Atom a = AtomOfTerm(t); if (a == AtomTrue || a == AtomOtherwise || a == AtomCut) return(TRUE); else if (a == AtomFail || a == AtomFalse) return(FALSE); /* call may not define new system predicates!! */ pe = RepPredProp(PredPropByAtom(a, mod)); return (CallPredicate(pe, B)); } else if (IsIntTerm(t)) { return CallError(TYPE_ERROR_CALLABLE, mod); } else { /* Is Pair Term */ return(CallMetaCall(mod)); } } static Int p_execute(void) { /* '$execute'(Goal) */ Term t = Deref(ARG1); return(do_execute(t, CurrentModule)); } static Int p_execute_in_mod(void) { /* '$execute'(Goal) */ return(do_execute(Deref(ARG1), IntOfTerm(Deref(ARG2)))); } inline static Int CallMetaCallWithin(void) { return (CallPredicate(PredMetaCall, B)); } /* '$execute_within'(Goal,CutPt,OrigGoal,Mod) */ static Int p_execute_within(void) { Term t = Deref(ARG1); Term tmod = Deref(ARG4); unsigned int arity; Prop pe; Atom a; SMALLUNSGN mod = LookupModule(tmod); #ifdef SBA choiceptr cut_pt = (choiceptr)IntegerOfTerm(Deref(ARG2)); #else choiceptr cut_pt = (choiceptr)(LCL0-IntegerOfTerm(Deref(ARG2))); #endif restart_exec: if (yap_flags[SPY_CREEP_FLAG]) { return(EnterCreepMode(mod)); } else if (PredGoalExpansion->OpcodeOfPred != UNDEF_OPCODE) { return(CallMetaCallWithin()); /* at this point check if we should enter creep mode */ } else if (IsVarTerm(t)) { return CallError(INSTANTIATION_ERROR, mod); } else if (IsApplTerm(t)) { register Functor f = FunctorOfTerm(t); register unsigned int i; register CELL *pt; if (IsExtensionFunctor(f)) { return CallError(TYPE_ERROR_CALLABLE, mod); } { PredEntry *pen; arity = ArityOfFunctor(f); a = NameOfFunctor(f); pe = PredPropByFunc(f, mod); pen = RepPredProp(pe); /* You thought we would be over by now */ /* but no meta calls require special preprocessing */ if (pen->PredFlags & MetaPredFlag) { if (f == FunctorModule) { Term tmod = ArgOfTerm(1,t); if (!IsVarTerm(tmod) && IsAtomTerm(tmod)) { mod = LookupModule(tmod); t = ArgOfTerm(2,t); goto restart_exec; } } return(CallMetaCallWithin()); } /* now let us do what we wanted to do from the beginning !! */ /* I cannot use the standard macro here because otherwise I would dereference the argument and might skip a svar */ pt = RepAppl(t)+1; for (i = 1; i <= arity; ++i) { #if SBA Term d0 = *pt++; if (d0 == 0) XREGS[i] = (CELL)(pt-1); else XREGS[i] = d0; #else XREGS[i] = *pt++; #endif } return (CallPredicate(pen, cut_pt)); } } else if (IsAtomOrIntTerm(t)) { if (IsIntTerm(t)) { return CallError(TYPE_ERROR_CALLABLE, mod); } a = AtomOfTerm(t); if (a == AtomTrue || a == AtomOtherwise) return(TRUE); else if (a == AtomCut) { /* find where to cut to */ if (SHOULD_CUT_UP_TO(B,cut_pt)) { #ifdef YAPOR /* Wow, we're gonna cut!!! */ CUT_prune_to(cut_pt); #else /* Wow, we're gonna cut!!! */ B = cut_pt; #endif /* YAPOR */ #ifdef TABLING abolish_incomplete_subgoals(B); #endif /* TABLING */ HB = PROTECT_FROZEN_H(B); } return(TRUE); } else if (a == AtomFail || a == AtomFalse) { return(FALSE); } else { /* call may not define new system predicates!! */ pe = PredPropByAtom(a, mod); return (CallPredicate(RepPredProp(pe), cut_pt)); } } else { /* Is Pair Term */ return(CallMetaCallWithin()); } } /* '$execute_within2'(Goal) */ static Int p_execute_within2(void) { Term t = Deref(ARG1); Prop pe; SMALLUNSGN mod = CurrentModule; restart_exec: if (yap_flags[SPY_CREEP_FLAG]) { return(EnterCreepMode(CurrentModule)); } else if (PredGoalExpansion->OpcodeOfPred != UNDEF_OPCODE) { return(CallMetaCallWithin()); } else if (IsVarTerm(t)) { return CallError(INSTANTIATION_ERROR, CurrentModule); } else if (IsApplTerm(t)) { register Functor f = FunctorOfTerm(t); if (IsExtensionFunctor(f)) { return CallError(TYPE_ERROR_CALLABLE, mod); } if (f == FunctorModule) { Term tmod = ArgOfTerm(1,t); if (!IsVarTerm(tmod) && IsAtomTerm(tmod)) { mod = LookupModule(tmod); t = ArgOfTerm(2,t); goto restart_exec; } } { PredEntry *pen; CELL *dest; register CELL *pt; register unsigned int i; unsigned int arity = ArityOfFunctor(f); pe = PredPropByFunc(f, mod); pen = RepPredProp(pe); /* You thought we would be over by now */ /* but no meta calls require special preprocessing */ if (pen->PredFlags & MetaPredFlag) { return(CallMetaCallWithin()); } /* at this point check if we should enter creep mode */ /* now let us do what we wanted to do from the beginning !! */ /* I cannot use the standard macro here because otherwise I would dereference the argument and might skip a svar */ pt = RepAppl(t)+1; dest = XREGS+1; for (i = 0; i < arity; ++i) { #if SBA Term d0 = *pt++; if (d0 == 0) *dest++ = (CELL)(pt-1); else *dest++ = d0; #else *dest++ = *pt++; #endif } if (pen->PredFlags & CutTransparentPredFlag) return (CallPredicate(pen, (choiceptr)(ENV[E_CB]))); else return (CallPredicate(pen, B)); } } else if (IsAtomTerm(t)) { Atom a = AtomOfTerm(t); if (a == AtomTrue || a == AtomOtherwise) return(TRUE); else if (a == AtomCut) { choiceptr pt0; pt0 = (choiceptr)(ENV[E_CB]); /* find where to cut to */ if (SHOULD_CUT_UP_TO(B,pt0)) { #ifdef YAPOR /* Wow, we're gonna cut!!! */ CUT_prune_to(pt0); #else /* Wow, we're gonna cut!!! */ B = pt0; #endif /* YAPOR */ #ifdef TABLING abolish_incomplete_subgoals(B); #endif /* TABLING */ HB = PROTECT_FROZEN_H(B); } return(TRUE); } else if (a == AtomFail || a == AtomFalse) { return(FALSE); } /* call may not define new system predicates!! */ pe = PredPropByAtom(a, CurrentModule); return (CallPredicate(RepPredProp(pe), B)); } else if (IsIntTerm(t)) { return CallError(TYPE_ERROR_CALLABLE, mod); } else { /* Is Pair Term */ return(CallMetaCallWithin()); } } static Int p_execute0(void) { /* '$execute0'(Goal,Mod) */ Term t = Deref(ARG1); Term tmod = Deref(ARG2); unsigned int arity; Prop pe; SMALLUNSGN mod = LookupModule(tmod); restart_exec: if (IsVarTerm(t)) { Error(INSTANTIATION_ERROR,ARG3,"call/1"); return(FALSE); } else if (IsAtomTerm(t)) { Atom a = AtomOfTerm(t); pe = PredPropByAtom(a, mod); } else if (IsApplTerm(t)) { register Functor f = FunctorOfTerm(t); register unsigned int i; register CELL *pt; if (IsExtensionFunctor(f)) return(FALSE); if (f == FunctorModule) { Term tmod = ArgOfTerm(1,t); if (!IsVarTerm(tmod) && IsAtomTerm(tmod)) { mod = LookupModule(tmod); t = ArgOfTerm(2,t); goto restart_exec; } } arity = ArityOfFunctor(f); /* I cannot use the standard macro here because otherwise I would dereference the argument and might skip a svar */ pt = RepAppl(t)+1; for (i = 1; i <= arity; ++i) { #if SBA Term d0 = *pt++; if (d0 == 0) XREGS[i] = (CELL)(pt-1); else XREGS[i] = d0; #else XREGS[i] = *pt++; #endif } pe = PredPropByFunc(f, mod); } else { Error(TYPE_ERROR_CALLABLE,ARG3,"call/1"); return(FALSE); } /* N = arity; */ /* call may not define new system predicates!! */ return (CallPredicate(RepPredProp(pe), B)); } static Int p_execute_0(void) { /* '$execute_0'(Goal) */ Term t = Deref(ARG1); SMALLUNSGN mod = LookupModule(Deref(ARG2)); Prop pe; if (IsAtomTerm(t)) { Atom a; a = AtomOfTerm(t); pe = PredPropByAtom(a, mod); } else if (IsApplTerm(t)) { Functor f = FunctorOfTerm(t); Int Arity, i; CELL *ptr; if (IsExtensionFunctor(f)) { Error(TYPE_ERROR_CALLABLE, t, "call_with_args/1"); return(FALSE); } pe = PredPropByFunc(f, mod); Arity = ArityOfFunctor(f); ptr = RepAppl(t)+1; for (i=1;i<=Arity;i++) { XREGS[i] = *ptr++; } } else { CELL *ptr; pe = PredPropByFunc(MkFunctor(AtomDot,2), mod); ptr = RepPair(t); XREGS[1] = ptr[0]; XREGS[2] = ptr[1]; } return (CallPredicate(RepPredProp(pe), B)); } static Int p_execute_1(void) { /* '$execute_0'(Goal) */ Term t = Deref(ARG1); SMALLUNSGN mod = LookupModule(Deref(ARG3)); Prop pe; if (!IsAtomTerm(t)) { Error(TYPE_ERROR_ATOM,ARG1,"call_with_args/2"); return(FALSE); } if (IsAtomTerm(t)) { Atom a; a = AtomOfTerm(t); ARG1 = ARG2; pe = PredPropByFunc(MkFunctor(a,1),mod); } else if (IsApplTerm(t)) { Functor f = FunctorOfTerm(t); Int Arity, i; Atom a; CELL *ptr; if (IsExtensionFunctor(f)) { Error(TYPE_ERROR_CALLABLE, t, "call_with_args/2"); return(FALSE); } Arity = ArityOfFunctor(f); a = NameOfFunctor(f); pe = PredPropByFunc(MkFunctor(a,Arity+1), mod); XREGS[Arity+1] = ARG2; ptr = RepAppl(t)+1; for (i=1;i<=Arity;i++) { XREGS[i] = *ptr++; } } else { CELL *ptr; pe = PredPropByFunc(MkFunctor(AtomDot,3), mod); ptr = RepPair(t); XREGS[3] = ARG2; XREGS[1] = ptr[0]; XREGS[2] = ptr[1]; } return (CallPredicate(RepPredProp(pe), B)); } static Int p_execute_2(void) { /* '$execute_2'(Goal) */ Term t = Deref(ARG1); SMALLUNSGN mod = LookupModule(Deref(ARG4)); Prop pe; if (IsAtomTerm(t)) { Atom a; a = AtomOfTerm(t); ARG1 = ARG2; ARG2 = ARG3; pe = PredPropByFunc(MkFunctor(a,2),mod); } else if (IsApplTerm(t)) { Functor f = FunctorOfTerm(t); Int Arity, i; Atom a; CELL *ptr; if (IsExtensionFunctor(f)) { Error(TYPE_ERROR_CALLABLE, t, "call_with_args/3"); return(FALSE); } Arity = ArityOfFunctor(f); a = NameOfFunctor(f); pe = PredPropByFunc(MkFunctor(a,Arity+2), mod); XREGS[Arity+2] = ARG3; XREGS[Arity+1] = ARG2; ptr = RepAppl(t)+1; for (i=1;i<=Arity;i++) { XREGS[i] = *ptr++; } } else { CELL *ptr; pe = PredPropByFunc(MkFunctor(AtomDot,4), mod); ptr = RepPair(t); XREGS[4] = ARG3; XREGS[3] = ARG2; XREGS[1] = ptr[0]; XREGS[2] = ptr[1]; } return (CallPredicate(RepPredProp(pe), B)); } static Int p_execute_3(void) { /* '$execute_3'(Goal) */ Term t = Deref(ARG1); SMALLUNSGN mod = LookupModule(Deref(ARG5)); Prop pe; if (!IsAtomTerm(t)) { Error(TYPE_ERROR_ATOM,ARG1,"call_with_args/4"); return(FALSE); } if (IsAtomTerm(t)) { Atom a; a = AtomOfTerm(t); ARG1 = ARG2; ARG2 = ARG3; ARG3 = ARG4; pe = PredPropByFunc(MkFunctor(a,3),mod); } else if (IsApplTerm(t)) { Functor f = FunctorOfTerm(t); Int Arity, i; Atom a; CELL *ptr; if (IsExtensionFunctor(f)) { Error(TYPE_ERROR_CALLABLE, t, "call_with_args/2"); return(FALSE); } Arity = ArityOfFunctor(f); a = NameOfFunctor(f); pe = PredPropByFunc(MkFunctor(a,Arity+3), mod); XREGS[Arity+3] = ARG4; XREGS[Arity+2] = ARG3; XREGS[Arity+1] = ARG2; ptr = RepAppl(t)+1; for (i=1;i<=Arity;i++) { XREGS[i] = *ptr++; } } else { CELL *ptr; pe = PredPropByFunc(MkFunctor(AtomDot,5), mod); ptr = RepPair(t); XREGS[5] = ARG4; XREGS[4] = ARG3; XREGS[3] = ARG2; XREGS[1] = ptr[0]; XREGS[2] = ptr[1]; } return (CallPredicate(RepPredProp(pe), B)); } static Int p_execute_4(void) { /* '$execute_4'(Goal) */ Term t = Deref(ARG1); SMALLUNSGN mod = LookupModule(Deref(ARG6)); Prop pe; if (IsAtomTerm(t)) { Atom a; a = AtomOfTerm(t); ARG1 = ARG2; ARG2 = ARG3; ARG3 = ARG4; ARG4 = ARG5; pe = PredPropByFunc(MkFunctor(a,4),mod); } else if (IsApplTerm(t)) { Functor f = FunctorOfTerm(t); Int Arity, i; Atom a; CELL *ptr; if (IsExtensionFunctor(f)) { Error(TYPE_ERROR_CALLABLE, t, "call_with_args/5"); return(FALSE); } Arity = ArityOfFunctor(f); a = NameOfFunctor(f); pe = PredPropByFunc(MkFunctor(a,Arity+4), mod); XREGS[Arity+4] = ARG5; XREGS[Arity+3] = ARG4; XREGS[Arity+2] = ARG3; XREGS[Arity+1] = ARG2; ptr = RepAppl(t)+1; for (i=1;i<=Arity;i++) { XREGS[i] = *ptr++; } } else { CELL *ptr; pe = PredPropByFunc(MkFunctor(AtomDot,6), mod); ptr = RepPair(t); XREGS[6] = ARG5; XREGS[5] = ARG4; XREGS[4] = ARG3; XREGS[3] = ARG2; XREGS[1] = ptr[0]; XREGS[2] = ptr[1]; } return (CallPredicate(RepPredProp(pe), B)); } static Int p_execute_5(void) { /* '$execute_5'(Goal) */ Term t = Deref(ARG1); SMALLUNSGN mod = LookupModule(Deref(ARG7)); Prop pe; if (IsAtomTerm(t)) { Atom a; a = AtomOfTerm(t); ARG1 = ARG2; ARG2 = ARG3; ARG3 = ARG4; ARG4 = ARG5; ARG5 = ARG6; pe = PredPropByFunc(MkFunctor(a,5),mod); } else if (IsApplTerm(t)) { Functor f = FunctorOfTerm(t); Int Arity, i; Atom a; CELL *ptr; if (IsExtensionFunctor(f)) { Error(TYPE_ERROR_CALLABLE, t, "call_with_args/6"); return(FALSE); } Arity = ArityOfFunctor(f); a = NameOfFunctor(f); pe = PredPropByFunc(MkFunctor(a,Arity+5), mod); XREGS[Arity+5] = ARG6; XREGS[Arity+4] = ARG5; XREGS[Arity+3] = ARG4; XREGS[Arity+2] = ARG3; XREGS[Arity+1] = ARG2; ptr = RepAppl(t)+1; for (i=1;i<=Arity;i++) { XREGS[i] = *ptr++; } } else { CELL *ptr; pe = PredPropByFunc(MkFunctor(AtomDot,7), mod); ptr = RepPair(t); XREGS[7] = ARG6; XREGS[6] = ARG5; XREGS[5] = ARG4; XREGS[4] = ARG3; XREGS[3] = ARG2; XREGS[1] = ptr[0]; XREGS[2] = ptr[1]; } return (CallPredicate(RepPredProp(pe), B)); } static Int p_execute_6(void) { /* '$execute_6'(Goal) */ Term t = Deref(ARG1); SMALLUNSGN mod = LookupModule(Deref(ARG8)); Prop pe; if (IsAtomTerm(t)) { Atom a; a = AtomOfTerm(t); ARG1 = ARG2; ARG2 = ARG3; ARG3 = ARG4; ARG4 = ARG5; ARG5 = ARG6; ARG6 = ARG7; pe = PredPropByFunc(MkFunctor(a,6),mod); } else if (IsApplTerm(t)) { Functor f = FunctorOfTerm(t); Int Arity, i; Atom a; CELL *ptr; if (IsExtensionFunctor(f)) { Error(TYPE_ERROR_CALLABLE, t, "call_with_args/7"); return(FALSE); } Arity = ArityOfFunctor(f); a = NameOfFunctor(f); pe = PredPropByFunc(MkFunctor(a,Arity+6), mod); XREGS[Arity+6] = ARG7; XREGS[Arity+5] = ARG6; XREGS[Arity+4] = ARG5; XREGS[Arity+3] = ARG4; XREGS[Arity+2] = ARG3; XREGS[Arity+1] = ARG2; ptr = RepAppl(t)+1; for (i=1;i<=Arity;i++) { XREGS[i] = *ptr++; } } else { CELL *ptr; pe = PredPropByFunc(MkFunctor(AtomDot,8), mod); ptr = RepPair(t); XREGS[8] = ARG7; XREGS[7] = ARG6; XREGS[6] = ARG5; XREGS[5] = ARG4; XREGS[4] = ARG3; XREGS[3] = ARG2; XREGS[1] = ptr[0]; XREGS[2] = ptr[1]; } return (CallPredicate(RepPredProp(pe), B)); } static Int p_execute_7(void) { /* '$execute_7'(Goal) */ Term t = Deref(ARG1); SMALLUNSGN mod = LookupModule(Deref(ARG9)); Prop pe; if (IsAtomTerm(t)) { Atom a; a = AtomOfTerm(t); ARG1 = ARG2; ARG2 = ARG3; ARG3 = ARG4; ARG4 = ARG5; ARG5 = ARG6; ARG6 = ARG7; ARG7 = ARG8; pe = PredPropByFunc(MkFunctor(a,7),mod); } else if (IsApplTerm(t)) { Functor f = FunctorOfTerm(t); Int Arity, i; Atom a; CELL *ptr; if (IsExtensionFunctor(f)) { Error(TYPE_ERROR_CALLABLE, t, "call_with_args/8"); return(FALSE); } Arity = ArityOfFunctor(f); a = NameOfFunctor(f); pe = PredPropByFunc(MkFunctor(a,Arity+7), mod); XREGS[Arity+7] = ARG8; XREGS[Arity+6] = ARG7; XREGS[Arity+5] = ARG6; XREGS[Arity+4] = ARG5; XREGS[Arity+3] = ARG4; XREGS[Arity+2] = ARG3; XREGS[Arity+1] = ARG2; ptr = RepAppl(t)+1; for (i=1;i<=Arity;i++) { XREGS[i] = *ptr++; } } else { CELL *ptr; pe = PredPropByFunc(MkFunctor(AtomDot,9), mod); ptr = RepPair(t); XREGS[9] = ARG8; XREGS[8] = ARG7; XREGS[7] = ARG6; XREGS[6] = ARG5; XREGS[5] = ARG4; XREGS[4] = ARG3; XREGS[3] = ARG2; XREGS[1] = ptr[0]; XREGS[2] = ptr[1]; } return (CallPredicate(RepPredProp(pe), B)); } static Int p_execute_8(void) { /* '$execute_8'(Goal) */ Term t = Deref(ARG1); SMALLUNSGN mod = LookupModule(Deref(ARG10)); Prop pe; if (IsAtomTerm(t)) { Atom a; a = AtomOfTerm(t); ARG1 = ARG2; ARG2 = ARG3; ARG3 = ARG4; ARG4 = ARG5; ARG5 = ARG6; ARG6 = ARG7; ARG7 = ARG8; ARG8 = ARG9; pe = PredPropByFunc(MkFunctor(a,8),mod); } else if (IsApplTerm(t)) { Functor f = FunctorOfTerm(t); Int Arity, i; Atom a; CELL *ptr; if (IsExtensionFunctor(f)) { Error(TYPE_ERROR_CALLABLE, t, "call_with_args/9"); return(FALSE); } Arity = ArityOfFunctor(f); a = NameOfFunctor(f); pe = PredPropByFunc(MkFunctor(a,Arity+8), mod); XREGS[Arity+8] = ARG9; XREGS[Arity+7] = ARG8; XREGS[Arity+6] = ARG7; XREGS[Arity+5] = ARG6; XREGS[Arity+4] = ARG5; XREGS[Arity+3] = ARG4; XREGS[Arity+2] = ARG3; XREGS[Arity+1] = ARG2; ptr = RepAppl(t)+1; for (i=1;i<=Arity;i++) { XREGS[i] = *ptr++; } } else { CELL *ptr; pe = PredPropByFunc(MkFunctor(AtomDot,10), mod); ptr = RepPair(t); XREGS[10] = ARG9; XREGS[9] = ARG8; XREGS[8] = ARG7; XREGS[7] = ARG6; XREGS[6] = ARG5; XREGS[5] = ARG4; XREGS[4] = ARG3; XREGS[3] = ARG2; XREGS[1] = ptr[0]; XREGS[2] = ptr[1]; } return (CallPredicate(RepPredProp(pe), B)); } static Int p_execute_9(void) { /* '$execute_9'(Goal) */ Term t = Deref(ARG1); SMALLUNSGN mod = LookupModule(Deref(ARG11)); Prop pe; if (IsAtomTerm(t)) { Atom a; a = AtomOfTerm(t); ARG1 = ARG2; ARG2 = ARG3; ARG3 = ARG4; ARG4 = ARG5; ARG5 = ARG6; ARG6 = ARG7; ARG7 = ARG8; ARG8 = ARG9; ARG9 = ARG10; pe = PredPropByFunc(MkFunctor(a,9),mod); } else if (IsApplTerm(t)) { Functor f = FunctorOfTerm(t); Int Arity, i; Atom a; CELL *ptr; if (IsExtensionFunctor(f)) { Error(TYPE_ERROR_CALLABLE, t, "call_with_args/10"); return(FALSE); } Arity = ArityOfFunctor(f); a = NameOfFunctor(f); pe = PredPropByFunc(MkFunctor(a,Arity+9), mod); XREGS[Arity+9] = ARG10; XREGS[Arity+8] = ARG9; XREGS[Arity+7] = ARG8; XREGS[Arity+6] = ARG7; XREGS[Arity+5] = ARG6; XREGS[Arity+4] = ARG5; XREGS[Arity+3] = ARG4; XREGS[Arity+2] = ARG3; XREGS[Arity+1] = ARG2; ptr = RepAppl(t)+1; for (i=1;i<=Arity;i++) { XREGS[i] = *ptr++; } } else { CELL *ptr; pe = PredPropByFunc(MkFunctor(AtomDot,11), mod); ptr = RepPair(t); XREGS[11] = ARG10; XREGS[10] = ARG9; XREGS[9] = ARG8; XREGS[8] = ARG7; XREGS[7] = ARG6; XREGS[6] = ARG5; XREGS[5] = ARG4; XREGS[4] = ARG3; XREGS[3] = ARG2; XREGS[1] = ptr[0]; XREGS[2] = ptr[1]; } return (CallPredicate(RepPredProp(pe), B)); } static Int p_execute_10(void) { /* '$execute_10'(Goal) */ Term t = Deref(ARG1); SMALLUNSGN mod = LookupModule(Deref(ARG12)); Prop pe; if (IsAtomTerm(t)) { Atom a; a = AtomOfTerm(t); ARG1 = ARG2; ARG2 = ARG3; ARG3 = ARG4; ARG4 = ARG5; ARG5 = ARG6; ARG6 = ARG7; ARG7 = ARG8; ARG8 = ARG9; ARG9 = ARG10; ARG10 = ARG11; pe = PredPropByFunc(MkFunctor(a,10),mod); } else if (IsApplTerm(t)) { Functor f = FunctorOfTerm(t); Int Arity, i; Atom a; CELL *ptr; if (IsExtensionFunctor(f)) { Error(TYPE_ERROR_CALLABLE, t, "call_with_args/11"); return(FALSE); } Arity = ArityOfFunctor(f); a = NameOfFunctor(f); pe = PredPropByFunc(MkFunctor(a,Arity+10), mod); XREGS[Arity+10] = ARG11; XREGS[Arity+9] = ARG10; XREGS[Arity+8] = ARG9; XREGS[Arity+7] = ARG8; XREGS[Arity+6] = ARG7; XREGS[Arity+5] = ARG6; XREGS[Arity+4] = ARG5; XREGS[Arity+3] = ARG4; XREGS[Arity+2] = ARG3; XREGS[Arity+1] = ARG2; ptr = RepAppl(t)+1; for (i=1;i<=Arity;i++) { XREGS[i] = *ptr++; } } else { CELL *ptr; pe = PredPropByFunc(MkFunctor(AtomDot,12), mod); ptr = RepPair(t); XREGS[12] = ARG11; XREGS[11] = ARG10; XREGS[10] = ARG9; XREGS[9] = ARG8; XREGS[8] = ARG7; XREGS[7] = ARG6; XREGS[6] = ARG5; XREGS[5] = ARG4; XREGS[4] = ARG3; XREGS[3] = ARG2; XREGS[1] = ptr[0]; XREGS[2] = ptr[1]; } return (CallPredicate(RepPredProp(pe), B)); } #ifdef DEPTH_LIMIT static Int p_execute_depth_limit(void) { Term d = Deref(ARG2); if (IsVarTerm(d)) { Error(INSTANTIATION_ERROR,d,"depth_bound_call/2"); } else if (!IsIntTerm(d)) { Error(TYPE_ERROR_INTEGER, d, "depth_bound_call/2"); return(FALSE); } DEPTH = MkIntTerm(IntOfTerm(d)*2); return(p_execute()); } #endif static Int p_pred_goal_expansion_on(void) { /* a goal needs expansion if we have goal_expansion defined or if the goal is a meta-call */ return (PredGoalExpansion->OpcodeOfPred != UNDEF_OPCODE); } static Int p_at_execute(void) { /* '$execute'(Goal,ClauseNumber) */ Term t = Deref(ARG1), tmod = Deref(ARG2), t2 = Deref(ARG3); unsigned int arity; Prop pe; Atom a; SMALLUNSGN mod = LookupModule(tmod); restart_exec: if (IsAtomTerm(t)) { a = AtomOfTerm(t); pe = PredPropByAtom(a, mod); arity = 0; } else if (IsApplTerm(t)) { register Functor f = FunctorOfTerm(t); register unsigned int i; register CELL *pt; if (IsBlobFunctor(f)) return(FALSE); if (f == FunctorModule) { Term tmod = ArgOfTerm(1,t); if (!IsVarTerm(tmod) && IsAtomTerm(tmod)) { mod = LookupModule(tmod); t = ArgOfTerm(2,t); goto restart_exec; } if (IsVarTerm(tmod)) { Error(INSTANTIATION_ERROR, ARG1, "calling clause in debugger"); } Error(TYPE_ERROR_ATOM, ARG1, "calling clause in debugger"); } arity = ArityOfFunctor(f); a = NameOfFunctor(f); /* I cannot use the standard macro here because otherwise I would dereference the argument and might skip a svar */ pt = RepAppl(t)+1; for (i = 1; i <= arity; ++i) #if SBA { Term d0 = *pt++; if (d0 == 0) XREGS[i] = (CELL)(pt-1); else XREGS[i] = d0; } #else XREGS[i] = *pt++; #endif pe = PredPropByFunc(f,mod); } else return (FALSE); /* for the moment */ if (IsVarTerm(t2) || !IsIntTerm(t2)) return (FALSE); /* N = arity; */ /* call may not define new system predicates!! */ return (CallClause(RepPredProp(pe), arity, IntOfTerm(t2))); } int exec_absmi(int top) { int lval; if (top && (lval = sigsetjmp (RestartEnv, 1)) != 0) { switch(lval) { case 1: { /* restart */ /* otherwise, SetDBForThrow will fail entering critical mode */ PrologMode = UserMode; /* find out where to cut to */ #if defined(__GNUC__) #if defined(hppa) || defined(__alpha) /* siglongjmp resets the TR hardware register */ restore_TR(); #endif #if defined(__alpha) /* siglongjmp resets the H hardware register */ restore_H(); #endif #endif yap_flags[SPY_CREEP_FLAG] = 0; CreepFlag = CalculateStackGap(); P = (yamop *)FAILCODE; PrologMode = UserMode; } break; case 2: { /* arithmetic exception */ /* must be done here, otherwise siglongjmp will clobber all the registers */ Error(YAP_matherror,TermNil,NULL); /* reset the registers so that we don't have trash in abstract machine */ set_fpu_exceptions(yap_flags[LANGUAGE_MODE_FLAG] == 1); P = (yamop *)FAILCODE; PrologMode = UserMode; } break; case 3: { /* saved state */ return(FALSE); } default: /* do nothing */ PrologMode = UserMode; } } else { PrologMode = UserMode; } return(absmi(0)); } static int do_goal(CODEADDR CodeAdr, int arity, CELL *pt, int args_to_save, int top) { choiceptr saved_b = B; /* create an initial pseudo environment so that when garbage collection is going up in the environment chain it doesn't get confused */ EX = 0L; YENV = ASP; YENV[E_CP] = (CELL)P; YENV[E_CB] = (CELL)B; YENV[E_E] = (CELL)ENV; #ifdef DEPTH_LIMIT YENV[E_DEPTH] = DEPTH; #endif ENV = YENV; ASP -= EnvSizeInCells; /* and now create a pseudo choicepoint for much the same reasons */ /* CP = YESCODE; */ /* keep a place where you can inform you had an exception */ { int i; for (i = 0; i < arity; i++) { XREGS[i+1] = *pt++; } } B = (choiceptr)ASP; B--; #ifdef TABLING if (top) { DepFr_cons_cp(GLOBAL_root_dep_fr) = B; } #endif /* TABLING */ B->cp_h = H; B->cp_tr = TR; B->cp_cp = CP; B->cp_ap = NOCODE; B->cp_env = ENV; B->cp_b = saved_b; #ifdef DEPTH_LIMIT B->cp_depth = DEPTH; #endif /* DEPTH_LIMIT */ YENV = ASP = (CELL *)B; HB = H; YENV[E_CB] = Unsigned (B); P = (yamop *) CodeAdr; CP = YESCODE; S = CellPtr (RepPredProp (PredPropByFunc (MkFunctor(AtomCall, 1),0))); /* A1 mishaps */ return(exec_absmi(top)); } Int execute_goal(Term t, int nargs, SMALLUNSGN mod) { Int out; CODEADDR CodeAdr; yamop *saved_p, *saved_cp; Prop pe; PredEntry *ppe; CELL *pt; /* preserve the current restart environment */ /* visualc*/ /* just keep the difference because of possible garbage collections */ saved_p = P; saved_cp = CP; if (IsAtomTerm(t)) { Atom a = AtomOfTerm(t); pt = NULL; pe = PredPropByAtom(a, mod); } else if (IsApplTerm(t)) { Functor f = FunctorOfTerm(t); if (IsBlobFunctor(f)) { Error(TYPE_ERROR_CALLABLE,t,"call/1"); return(FALSE); } /* I cannot use the standard macro here because otherwise I would dereference the argument and might skip a svar */ pt = RepAppl(t)+1; pe = PredPropByFunc(f, mod); } else { Error(TYPE_ERROR_CALLABLE,t,"call/1"); return(FALSE); } ppe = RepPredProp(pe); if (pe == NIL) { return(CallMetaCall(mod)); } READ_LOCK(ppe->PRWLock); if (IsAtomTerm(t)) { CodeAdr = RepPredProp (pe)->CodeOfPred; READ_UNLOCK(ppe->PRWLock); out = do_goal(CodeAdr, 0, pt, nargs, FALSE); } else { Functor f = FunctorOfTerm(t); CodeAdr = RepPredProp (pe)->CodeOfPred; READ_UNLOCK(ppe->PRWLock); out = do_goal(CodeAdr, ArityOfFunctor(f), pt, nargs, FALSE); } if (out == 1) { choiceptr old_B; /* we succeeded, let's prune */ /* restore the old environment */ /* get to previous environment */ #ifdef YAPOR CUT_prune_to((choiceptr)(ENV[E_CB])); #else B = (choiceptr)(ENV[E_CB]); #endif /* YAPOR */ #ifdef TABLING abolish_incomplete_subgoals(B); #endif /* TABLING */ /* find out where we have the old arguments */ old_B = ((choiceptr)(ENV-(EnvSizeInCells+nargs+1)))-1; CP = saved_cp; P = saved_p; ASP = ENV; *--ASP = MkIntTerm(0); #ifdef DEPTH_LIMIT DEPTH= ENV[E_DEPTH]; #endif ENV = (CELL *)(ENV[E_E]); /* we have failed, and usually we would backtrack to this B, trouble is, we may also have a delayed cut to do */ if (B != NULL) HB = B->cp_h; YENV = ENV; return(TRUE); } else if (out == 0) { ASP = B->cp_env; P = saved_p; CP = saved_cp; H = B->cp_h; #ifdef DEPTH_LIMIT DEPTH= B->cp_depth; #endif /* ASP should be set to the top of the local stack when we did the call */ ASP = B->cp_env; /* YENV should be set to the current environment */ YENV = ENV = (CELL *)((B->cp_env)[E_E]); B = B->cp_b; SET_BB(B); HB = PROTECT_FROZEN_H(B); return(FALSE); } else { Error(SYSTEM_ERROR,TermNil,"emulator crashed"); return(FALSE); } } void trust_last(void) { ASP = B->cp_env; P = (yamop *)(B->cp_env[E_CP]); CP = B->cp_cp; H = B->cp_h; #ifdef DEPTH_LIMIT DEPTH= B->cp_depth; #endif YENV= ASP = B->cp_env; ENV = (CELL *)((B->cp_env)[E_E]); B = B->cp_b; if (B) { SET_BB(B); HB = PROTECT_FROZEN_H(B); } } int RunTopGoal(Term t) { CODEADDR CodeAdr; Prop pe; PredEntry *ppe; CELL *pt; UInt arity; SMALLUNSGN mod = CurrentModule; int goal_out = 0; restart_runtopgoal: if (IsAtomTerm(t)) { Atom a = AtomOfTerm(t); pt = NULL; pe = PredPropByAtom(a, CurrentModule); arity = 0; } else if (IsApplTerm(t)) { Functor f = FunctorOfTerm(t); if (IsBlobFunctor(f)) { Error(TYPE_ERROR_CALLABLE,t,"call/1"); return(FALSE); } if (f == FunctorModule) { Term tmod = ArgOfTerm(1,t); if (!IsVarTerm(tmod) && IsAtomTerm(tmod)) { mod = LookupModule(tmod); t = ArgOfTerm(2,t); goto restart_runtopgoal; } } /* I cannot use the standard macro here because otherwise I would dereference the argument and might skip a svar */ pe = GetPredPropByFunc(f, CurrentModule); pt = RepAppl(t)+1; arity = ArityOfFunctor(f); } else { Error(TYPE_ERROR_CALLABLE,t,"call/1"); return(FALSE); } ppe = RepPredProp(pe); if (pe != NIL) { READ_LOCK(ppe->PRWLock); } if (pe == NIL) { if (pe != NIL) { READ_UNLOCK(ppe->PRWLock); } /* we must always start the emulator with Prolog code */ return(FALSE); } CodeAdr = ppe->CodeOfPred; if (TrailTop - HeapTop < 2048) { PrologMode = BootMode; Error(SYSTEM_ERROR,TermNil, "unable to boot because of too little heap space"); } goal_out = do_goal(CodeAdr, arity, pt, 0, TRUE); return(goal_out); } static void restore_regs(Term t) { if (IsApplTerm(t)) { Int i; Int max = ArityOfFunctor(FunctorOfTerm(t)); CELL *ptr = RepAppl(t)+1; for (i = 0; i < max; i += 2) { Int j = IntOfTerm(ptr[0]); XREGS[j] = ptr[1]; ptr+=2; } } } /* low level voodoo to restore temporary registers after a call */ static Int p_restore_regs(void) { Term t = Deref(ARG1); if (IsVarTerm(t)) { Error(INSTANTIATION_ERROR,t,"support for coroutining"); return(FALSE); } if (IsAtomTerm(t)) return(TRUE); restore_regs(t); return(TRUE); } /* low level voodoo to cut and then restore temporary registers after a call */ static Int p_restore_regs2(void) { Term t = Deref(ARG1), d0; choiceptr pt0; if (IsVarTerm(t)) { Error(INSTANTIATION_ERROR,t,"support for coroutining"); return(FALSE); } d0 = Deref(ARG2); if (!IsAtomTerm(t)) { restore_regs(t); } if (IsVarTerm(d0)) { Error(INSTANTIATION_ERROR,d0,"support for coroutining"); return(FALSE); } if (!IsIntegerTerm(d0)) { return(FALSE); } #if SBA pt0 = (choiceptr)IntegerOfTerm(d0); #else pt0 = (choiceptr)(LCL0-IntOfTerm(d0)); #endif /* find where to cut to */ if (pt0 > B) { /* Wow, we're gonna cut!!! */ #ifdef YAPOR CUT_prune_to(pt0); #else B = pt0; #endif /* YAPOR */ #ifdef TABLING abolish_incomplete_subgoals(B); #endif /* TABLING */ HB = B->cp_h; /* trim_trail();*/ } return(TRUE); } static Int p_clean_ifcp(void) { #if SBA choiceptr pt0 = (choiceptr)IntegerOfTerm(Deref(ARG1)); #else choiceptr pt0 = (choiceptr)(LCL0-IntOfTerm(Deref(ARG1))); #endif if (pt0 == B) { B = B->cp_b; HB = B->cp_h; } else { pt0->cp_ap = (yamop *)TRUSTFAILCODE; } return(TRUE); } Int JumpToEnv(Term t) { yamop *pos = (yamop *)(PredDollarCatch->LastClause); CELL *env; choiceptr first_func = NULL, B0 = B; do { /* find the first choicepoint that may be a catch */ while (B != NULL && B->cp_ap != pos) { /* we are already doing a catch */ if (B->cp_ap == (yamop *)(PredHandleThrow->LastClause)) { P = (yamop *)FAILCODE; if (first_func != NULL) { B = first_func; } return(FALSE); } if (B->cp_ap == NOCODE) { /* up to the C-code to deal with this! */ B->cp_h = H; EX = t; return(FALSE); } B = B->cp_b; } /* uncaught throw */ if (B == NULL) { B = B0; #if PUSH_REGS restore_absmi_regs(&standard_regs); #endif siglongjmp(RestartEnv,1); } /* is it a continuation? */ env = B->cp_env; while (env > ENV) ENV = (CELL *)ENV[E_E]; /* yes, we found it ! */ if (env == ENV) break; /* oops, try next */ B = B->cp_b; } while (TRUE); /* step one environment above */ B->cp_cp = (yamop *)env[E_CP]; B->cp_ap = (yamop *)(PredHandleThrow->LastClause); B->cp_env = (CELL *)env[E_E]; /* cannot recover Heap because of copy term :-( */ B->cp_h = H; /* I could backtrack here, but it is easier to leave the unwinding to the emulator */ B->cp_a3 = t; P = (yamop *)FAILCODE; if (first_func != NULL) { B = first_func; } #ifdef TABLING abolish_incomplete_subgoals(B); #endif /* TABLING */ return(FALSE); } /* This does very nasty stuff!!!!! */ static Int p_jump_env(void) { return(JumpToEnv(Deref(ARG1))); } void InitExecFs(void) { InitCPred("$execute", 1, p_execute, 0); InitCPred("$execute_in_mod", 2, p_execute_in_mod, 0); InitCPred("$execute_within", 4, p_execute_within, 0); InitCPred("$execute_within", 1, p_execute_within2, 0); InitCPred("$last_execute_within", 1, p_execute_within2, 0); InitCPred("$execute", 3, p_at_execute, 0); InitCPred("$call_with_args", 2, p_execute_0, 0); InitCPred("$call_with_args", 3, p_execute_1, 0); InitCPred("$call_with_args", 4, p_execute_2, 0); InitCPred("$call_with_args", 5, p_execute_3, 0); InitCPred("$call_with_args", 6, p_execute_4, 0); InitCPred("$call_with_args", 7, p_execute_5, 0); InitCPred("$call_with_args", 8, p_execute_6, 0); InitCPred("$call_with_args", 9, p_execute_7, 0); InitCPred("$call_with_args", 10, p_execute_8, 0); InitCPred("$call_with_args", 11, p_execute_9, 0); InitCPred("$call_with_args", 12, p_execute_10, 0); #ifdef DEPTH_LIMIT InitCPred("$execute_under_depth_limit", 2, p_execute_depth_limit, 0); #endif InitCPred("$execute0", 2, p_execute0, 0); InitCPred("$save_current_choice_point", 1, p_save_cp, 0); InitCPred("$pred_goal_expansion_on", 0, p_pred_goal_expansion_on, SafePredFlag); InitCPred("$restore_regs", 1, p_restore_regs, SafePredFlag); InitCPred("$restore_regs", 2, p_restore_regs2, SafePredFlag); InitCPred("$clean_ifcp", 1, p_clean_ifcp, SafePredFlag); InitCPred("$jump_env_and_store_ball", 1, p_jump_env, 0); }