/************************************************************************* * * * YAP Prolog * * * * Yap Prolog was developed at NCCUP - Universidade do Porto * * * * Copyright L.Damas, V.S.Costa and Universidade do Porto 2015- * * * ************************************************************************** * * * File: flags.c * * Last rev: * * mods: * * comments: abstract machine definitions * * * *************************************************************************/ /** @file C/flags.c @addtogroup Flags @ingroup core @{ */ // this is where we define flags #define INIT_FLAGS 1 #include "Yap.h" #include "iopreds.h" #if HAVE_UNISTD_H #include #endif static Term ro(Term inp); static Term nat(Term inp); static Term isatom(Term inp); static Term booleanFlag(Term inp); // static bool string( Term inp ); // static bool list_atom( Term inp ); static Term list_option(Term inp); static Term argv(Term inp); static Term os_argv(Term inp); static bool agc_threshold(Term inp); static bool gc_margin(Term inp); static Term executable(Term inp); static Term sys_thread_id(Term inp); static Term sys_pid(Term inp); static bool mkprompt(Term inp); static Term synerr(Term inp); static Term indexer(Term inp); static Term stream(Term inp); static bool getenc(Term inp); static bool typein(Term inp); static bool dqs(Term t2); static bool bqs(Term t2); static bool sqf(Term t2); static bool set_error_stream(Term inp); static bool set_input_stream(Term inp); static bool set_output_stream(Term inp); static void newFlag(Term fl, Term val); static Int current_prolog_flag(USES_REGS1); static Int set_prolog_flag(USES_REGS1); #include "Yatom.h" #include "YapEval.h" #include "yapio.h" #define YAP_FLAG(ID, NAME, WRITABLE, DEF, INIT, HELPER) \ { NAME, WRITABLE, DEF, INIT, HELPER } #define GZERO_FLAG \ { NULL, false, NULL, NULL, NULL } #define LZERO_FLAG \ { NULL, false, NULL, NULL, NULL } static flag_info global_flags_setup[] = { #include "YapGFlagInfo.h" GZERO_FLAG}; static flag_info local_flags_setup[] = { #include "YapLFlagInfo.h" LZERO_FLAG}; static Term indexer(Term inp) { if (inp == TermOff || inp == TermSingle || inp == TermCompact || inp == TermMulti || inp == TermOn || inp == TermMax) return inp; if (IsAtomTerm(inp)) { Yap_Error(DOMAIN_ERROR_OUT_OF_RANGE, inp, "set_prolog_flag index in {off,single,compact,multi,on,max}"); return TermZERO; } Yap_Error(TYPE_ERROR_ATOM, inp, "set_prolog_flag in {dec10,error,fail,quiet}"); return TermZERO; } static bool dqf1(ModEntry *new, Term t2 USES_REGS) { new->flags &= ~(DBLQ_CHARS | DBLQ_CODES | DBLQ_ATOM | DBLQ_STRING); if (IsAtomTerm(t2)) { if (t2 == TermString) { new->flags |= DBLQ_STRING; return true; } else if (t2 == TermAtom) { new->flags |= DBLQ_ATOM; return true; } else if (t2 == TermCodes) { new->flags |= DBLQ_CODES; return true; } else if (t2 == TermChars) { new->flags |= DBLQ_CHARS; return true; } /* bad argument, but still an atom */ Yap_Error(DOMAIN_ERROR_OUT_OF_RANGE, t2, "bad option %s for backquoted " "string flag, use one string, " "atom, codes or chars", RepAtom(AtomOfTerm(t2))->StrOfAE); return false; } else { Yap_Error(TYPE_ERROR_ATOM, t2, "set_prolog_flag(double_quotes, %s), should " "be {string,atom,codes,chars}", RepAtom(AtomOfTerm(t2))->StrOfAE); return false; } } static bool dqs(Term t2) { CACHE_REGS ModEntry *new = Yap_GetModuleEntry(CurrentModule); return dqf1(new, t2 PASS_REGS); } static bool bqf1(ModEntry *new, Term t2 USES_REGS) { new->flags &= ~(BCKQ_CHARS | BCKQ_CODES | BCKQ_ATOM | BCKQ_STRING); if (IsAtomTerm(t2)) { if (t2 == TermString) { new->flags |= BCKQ_STRING; return true; } else if (t2 == TermAtom) { new->flags |= BCKQ_ATOM; return true; } else if (t2 == TermCodes) { new->flags |= BCKQ_CODES; return true; } else if (t2 == TermChars) { new->flags |= BCKQ_CHARS; return true; } Yap_Error(DOMAIN_ERROR_OUT_OF_RANGE, t2, "bad option %s for backquoted " "string flag, use one string, " "atom, codes or chars", RepAtom(AtomOfTerm(t2))->StrOfAE); return false; } else { Yap_Error(TYPE_ERROR_ATOM, t2, "flag %s is not module-scoped", RepAtom(AtomOfTerm(t2))->StrOfAE); return false; } } static bool bqs(Term t2) { CACHE_REGS ModEntry *new = Yap_GetModuleEntry(CurrentModule); return bqf1(new, t2 PASS_REGS); } static bool sqf1(ModEntry *new, Term t2 USES_REGS) { new->flags &= ~(SNGQ_CHARS | SNGQ_CODES | SNGQ_ATOM | SNGQ_STRING); if (IsAtomTerm(t2)) { if (t2 == TermString) { new->flags |= SNGQ_STRING; return true; } else if (t2 == TermAtom) { new->flags |= SNGQ_ATOM; return true; } else if (t2 == TermCodes) { new->flags |= SNGQ_CODES; return true; } else if (t2 == TermChars) { new->flags |= SNGQ_CHARS; return true; } Yap_Error(DOMAIN_ERROR_OUT_OF_RANGE, t2, "bad option %s for backquoted " "string flag, use one string, " "atom, codes or chars", RepAtom(AtomOfTerm(t2))->StrOfAE); return false; } else { Yap_Error(TYPE_ERROR_ATOM, t2, "flag %s is not module-scoped", RepAtom(AtomOfTerm(t2))->StrOfAE); return false; } } static bool sqf(Term t2) { CACHE_REGS ModEntry *new = Yap_GetModuleEntry(CurrentModule); return sqf1(new, t2 PASS_REGS); } static Term isaccess(Term inp) { if (inp == TermReadWrite || inp == TermReadOnly) return inp; if (IsAtomTerm(inp)) { Yap_Error(DOMAIN_ERROR_OUT_OF_RANGE, inp, "set_prolog_flag access in {read_write,read_only}"); return TermZERO; } Yap_Error(TYPE_ERROR_ATOM, inp, "set_prolog_flag access in {read_write,read_only}"); return TermZERO; } static Term stream(Term inp) { if (IsVarTerm(inp)) return inp; if (Yap_CheckStream(inp, Input_Stream_f | Output_Stream_f | Append_Stream_f | Socket_Stream_f, "yap_flag/3") >= 0) return inp; return 0; } static bool set_error_stream(Term inp) { if (IsVarTerm(inp)) return Yap_unify(inp, Yap_StreamUserName(LOCAL_c_error_stream)); return Yap_SetErrorStream( inp ); } static bool set_input_stream(Term inp) { if (IsVarTerm(inp)) return Yap_unify(inp, Yap_StreamUserName(LOCAL_c_input_stream)); return Yap_SetInputStream( inp ); } static bool set_output_stream(Term inp) { if (IsVarTerm(inp)) return Yap_unify(inp, Yap_StreamUserName(LOCAL_c_output_stream)); return Yap_SetOutputStream( inp ); } static Term isground(Term inp) { return Yap_IsGroundTerm(inp) ? inp : TermZERO; } static Term flagscope(Term inp) { if (inp == TermGlobal || inp == TermThread || inp == TermModule) return inp; if (IsAtomTerm(inp)) { Yap_Error(DOMAIN_ERROR_OUT_OF_RANGE, inp, "set_prolog_flag access in {global,module,thread}"); return TermZERO; } Yap_Error(TYPE_ERROR_ATOM, inp, "set_prolog_flag access in {global,module,thread}"); return TermZERO; } static bool mkprompt(Term inp) { CACHE_REGS if (IsVarTerm(inp)) { return Yap_unify(inp, MkAtomTerm(Yap_LookupAtom(LOCAL_Prompt))); } if (!IsAtomTerm(inp)) { Yap_Error(TYPE_ERROR_ATOM, inp, "set_prolog_flag"); return false; } strncpy(LOCAL_Prompt, (const char *)RepAtom(AtomOfTerm(inp))->StrOfAE, MAX_PROMPT); return true; } static bool getenc(Term inp) { CACHE_REGS if (!IsVarTerm(inp) && !IsAtomTerm(inp)) { Yap_Error(TYPE_ERROR_ATOM, inp, "get_encoding"); return false; } return Yap_unify(inp, MkAtomTerm(Yap_LookupAtom(enc_name(LOCAL_encoding)))); } /* static bool enablerl( Term inp ) { CACHE_REGS if (IsVarTerm(inp)) { return Yap_unify( inp, MkAtomTerm( Yap_LookupAtom( enc_name(LOCAL_encoding) )) ); } if (!IsAtomTerm(inp) ) { Yap_Error(TYPE_ERROR_ATOM, inp, "set_prolog_flag"); return false; } enc_id( RepAtom( AtomOfTerm( inp ) )->StrOfAE, ENC_OCTET ); return true; } */ static bool typein(Term inp) { CACHE_REGS if (IsVarTerm(inp)) { Term tin = CurrentModule; if (tin == PROLOG_MODULE) tin = TermProlog; return Yap_unify(inp, tin); } if (!IsAtomTerm(inp)) { Yap_Error(TYPE_ERROR_ATOM, inp, "set_prolog_flag"); return false; } CurrentModule = inp; if (inp == TermProlog) CurrentModule = PROLOG_MODULE; return true; } #if 0 static Int p_has_yap_or(USES_REGS1) { #ifdef YAPOR return (TRUE); #else return (FALSE); #endif } static Int p_has_eam(USES_REGS1) { #ifdef BEAM return (TRUE); #else return (FALSE); #endif } static Int p_has_jit(USES_REGS1) { #ifdef HAS_JIT return (TRUE); #else return (FALSE); #endif } static bool tabling( Term inp ) { if (value == 0) { /* default */ tab_ent_ptr tab_ent = GLOBAL_root_tab_ent; while (tab_ent) { TabEnt_mode(tab_ent) = TabEnt_flags(tab_ent); tab_ent = TabEnt_next(tab_ent); } yap_flags[TA BLING_MODE_FLAG] = 0; } else if (value == 1) { /* batched */ tab_ent_ptr tab_ent = GLOBAL_root_tab_ent; while (tab_ent) { SetMode_Batched(TabEnt_mode(tab_ent)); tab_ent = TabEnt_next(tab_ent); } SetMode_Batched(yap_flags[TABLING_MODE_FLAG]); } else if (value == 2) { /* local */ tab_ent_ptr tab_ent = GLOBAL_root_tab_ent; while (tab_ent) { SetMode_Local(TabEnt_mode(tab_ent)); tab_ent = TabEnt_next(tab_ent); } SetMode_Local(yap_flags[TABLING_MODE_FLAG]); } else if (value == 3) { /* exec_answers */ tab_ent_ptr tab_ent = GLOBAL_root_tab_ent; while (tab_ent) { SetMode_ExecAnswers(TabEnt_mode(tab_ent)); tab_ent = TabEnt_next(tab_ent); } SetMode_ExecAnswers(yap_flags[TABLING_MODE_FLAG]); } else if (value == 4) { /* load_answers */ tab_ent_ptr tab_ent = GLOBAL_root_tab_ent; while (tab_ent) { SetMode_LoadAnswers(TabEnt_mode(tab_ent)); tab_ent = TabEnt_next(tab_ent); } SetMode_LoadAnswers(yap_flags[TABLING_MODE_FLAG]); } else if (value == 5) { /* local_trie */ tab_ent_ptr tab_ent = GLOBAL_root_tab_ent; while (tab_ent) { SetMode_LocalTrie(TabEnt_mode(tab_ent)); tab_ent = TabEnt_next(tab_ent); } SetMode_LocalTrie(yap_flags[TABLING_MODE_FLAG]); } else if (value == 6) { /* global_trie */ tab_ent_ptr tab_ent = GLOBAL_root_tab_ent; while (tab_ent) { SetMode_GlobalTrie(TabEnt_mode(tab_ent)); tab_ent = TabEnt_next(tab_ent); } SetMode_GlobalTrie(yap_flags[TABLING_MODE_FLAG]); } else if (value == 7) { /* CoInductive */ tab_ent_ptr tab_ent = GLOBAL_root_tab_ent; while (tab_ent) { SetMode_CoInductive(TabEnt_mode(tab_ent)); tab_ent = TabEnt_next(tab_ent); } SetMode_CoInductive(yap_flags[TABLING_MODE_FLAG]); } } static bool string( Term inp ) { if (IsVarTerm(inp)) { Yap_Error(INSTANTIATION_ERROR, inp, "set_prolog_flag in \"...\""); return false; } if (IsStringTerm( inp )) return true; Term inp0 = inp; if (IsPairTerm(inp)) { Term hd = HeadOfTerm(inp); if (IsAtomTerm(hd)) { do { Term hd = HeadOfTerm(inp); if (!IsAtomTerm(hd)) { Yap_Error(TYPE_ERROR_TEXT, inp0, "set_prolog_flag in \"...\""); return false; } } while (IsPairTerm( inp ) ); } else if (IsIntTerm(hd)) { do { Term hd = HeadOfTerm(inp); if (!IsIntTerm(hd)) { Yap_Error(TYPE_ERROR_TEXT, inp0, "set_prolog_flag in \"...\""); return false; } if (IntOfTerm(hd) < 0) { Yap_Error(DOMAIN_ERROR_NOT_LESS_THAN_ZERO, inp0, "set_prolog_flag in 0..."); return false; } } while (IsPairTerm( inp ) ); } else { Yap_Error(TYPE_ERROR_TEXT, inp0, "set_prolog_flag in \"...\""); return false; } } if ( inp != TermNil ) { Yap_Error(TYPE_ERROR_TEXT, inp0, "set_prolog_flag in \"...\""); return false; } return true; } static bool list_atom( Term inp ) { if (IsVarTerm(inp)) { Yap_Error(INSTANTIATION_ERROR, inp, "set_prolog_flag in \"...\""); return false; } Term inp0 = inp; if (IsPairTerm(inp)) { Term hd = HeadOfTerm(inp); do { if (!IsAtomTerm(hd)) { Yap_Error(TYPE_ERROR_ATOM, inp0, "set_prolog_flag in \"...\""); return false; } } while (IsPairTerm( inp ) ); } if ( inp != TermNil ) { Yap_Error(TYPE_ERROR_LIST, inp0, "set_prolog_flag in [...]"); return false; } return true; } #endif static Term list_option(Term inp) { if (IsVarTerm(inp)) { Yap_Error(INSTANTIATION_ERROR, inp, "set_prolog_flag in \"...\""); return inp; } Term inp0 = inp; if (IsPairTerm(inp)) { do { Term hd = HeadOfTerm(inp); inp = TailOfTerm(inp); if (IsAtomTerm(hd)) { continue; } if (IsApplTerm(hd)) { Functor f = FunctorOfTerm(hd); if (!IsExtensionFunctor(f) && ArityOfFunctor(f) == 1 && Yap_IsGroundTerm(hd)) { continue; } if (!Yap_IsGroundTerm(hd)) Yap_Error(INSTANTIATION_ERROR, hd, "set_prolog_flag in \"...\""); return TermZERO; } } while (IsPairTerm(inp)); if (inp == TermNil) { return inp0; } Yap_Error(TYPE_ERROR_LIST, inp0, "set_prolog_flag in [...]"); return TermZERO; } else /* lone option */ { if (IsAtomTerm(inp)) { return inp; } else if (IsApplTerm(inp)) { Functor f = FunctorOfTerm(inp); if (!IsExtensionFunctor(f) && ArityOfFunctor(f) == 1 && Yap_IsGroundTerm(ArgOfTerm(1, inp))) { return inp; } } } return TermZERO; } static bool agc_threshold(Term t) { t = Deref(t); if (IsVarTerm(t)) { CACHE_REGS return Yap_unify(t, MkIntegerTerm(GLOBAL_AGcThreshold)); } else if (!IsIntegerTerm(t)) { Yap_Error(TYPE_ERROR_INTEGER, t, "prolog_flag/2 agc_margin"); return FALSE; } else { Int i = IntegerOfTerm(t); if (i < 0) { Yap_Error(DOMAIN_ERROR_NOT_LESS_THAN_ZERO, t, "prolog_flag/2 agc_margin"); return FALSE; } else { GLOBAL_AGcThreshold = i; return TRUE; } } } static bool gc_margin(Term t) { t = Deref(t); if (IsVarTerm(t)) { return Yap_unify(t, Yap_GetValue(AtomGcMargin)); } else if (!IsIntegerTerm(t)) { Yap_Error(TYPE_ERROR_INTEGER, t, "prolog_flag/2 agc_margin"); return FALSE; } else { Int i = IntegerOfTerm(t); if (i < 0) { Yap_Error(DOMAIN_ERROR_NOT_LESS_THAN_ZERO, t, "prolog_flag/2 gc_margin"); return FALSE; } else { CACHE_REGS Yap_PutValue(AtomGcMargin, MkIntegerTerm(i)); return true; } } } static Term mk_argc_list(USES_REGS1) { int i = 1; Term t = TermNil; while (i < GLOBAL_argc) { char *arg = GLOBAL_argv[i]; /* check for -L -- */ if (arg[0] == '-' && arg[1] == 'L') { arg += 2; while (*arg != '\0' && (*arg == ' ' || *arg == '\t')) arg++; if (*arg == '-' && arg[1] == '-' && arg[2] == '\0') { /* we found the separator */ int j; for (j = GLOBAL_argc - 1; j > i + 1; --j) { t = MkPairTerm(MkAtomTerm(Yap_LookupAtom(GLOBAL_argv[j])), t); } return t; } else if (GLOBAL_argv[i + 1] && GLOBAL_argv[i + 1][0] == '-' && GLOBAL_argv[i + 1][1] == '-' && GLOBAL_argv[i + 1][2] == '\0') { /* we found the separator */ int j; for (j = GLOBAL_argc - 1; j > i + 2; --j) { t = MkPairTerm(MkAtomTerm(Yap_LookupAtom(GLOBAL_argv[j])), t); } return t; } } if (arg[0] == '-' && arg[1] == '-' && arg[2] == '\0') { /* we found the separator */ int j; for (j = GLOBAL_argc - 1; j > i; --j) { t = MkPairTerm(MkAtomTerm(Yap_LookupAtom(GLOBAL_argv[j])), t); } return (t); } i++; } return (t); } static Term mk_os_argc_list(USES_REGS1) { int i = 0; Term t = TermNil; for (i = 0; i < GLOBAL_argc; i++) { char *arg = GLOBAL_argv[i]; t = MkPairTerm(MkAtomTerm(Yap_LookupAtom(arg)), t); } return (t); } static Term argv(Term inp) { CACHE_REGS return mk_argc_list(PASS_REGS1); } static Term os_argv(Term inp) { CACHE_REGS return mk_os_argc_list(PASS_REGS1); } static FlagEntry * GetFlagProp(Atom a) { /* look property list of atom a for kind */ AtomEntry *ae = RepAtom(a); FlagEntry *pp; READ_LOCK(ae->ARWLock); pp = RepFlagProp(ae->PropsOfAE); while (!EndOfPAEntr(pp) && pp->KindOfPE != FlagProperty) pp = RepFlagProp(pp->NextOfPE); READ_UNLOCK(ae->ARWLock); return pp; } static void initFlag(flag_info *f, int fnum, bool global) { Atom name = Yap_LookupAtom(f->name); AtomEntry *ae = RepAtom(name); WRITE_LOCK(ae->ARWLock); FlagEntry *fprop = RepFlagProp(Yap_GetAPropHavingLock(name, FlagProperty)); if (fprop == NULL) { fprop = (FlagEntry *)Yap_AllocAtomSpace(sizeof(FlagEntry)); if (fprop == NULL) { WRITE_UNLOCK(ae->ARWLock); Yap_Error(RESOURCE_ERROR_HEAP, TermNil, "not enough space for new Flag %s", ae->StrOfAE); return; } fprop->KindOfPE = FlagProperty; fprop->FlagOfVE = fnum; fprop->rw = f->writable; fprop->global = global; fprop->type = f->def; fprop->helper = f->helper; AddPropToAtom(ae, AbsFlagProp(fprop)); } WRITE_UNLOCK(ae->ARWLock); } static Term executable(Term inp) { return MkAtomTerm(Yap_LookupAtom(Yap_FindExecutable())); } static Term sys_thread_id(Term inp) { CACHE_REGS int pid; #ifdef HAVE_GETTID_SYSCALL pid = syscall(__NR_gettid); #elif defined(HAVE_GETTID_MACRO) pid = gettid(); #elif defined(__WINDOWS__) pid = GetCurrentThreadId(); #else pid = 0; #endif return MkIntegerTerm(pid); } static Term sys_pid(Term inp) { CACHE_REGS int pid; #if defined(__MINGW32__) || _MSC_VER pid = _getpid(); #else pid = getpid(); #endif return MkIntegerTerm(pid); } static bool setYapFlagInModule(Term tflag, Term t2, Term mod) { CACHE_REGS FlagEntry *fv; ModEntry *me = Yap_GetModuleEntry(mod); if (!me) return false; fv = GetFlagProp(AtomOfTerm(tflag)); if (!fv && !fv->global) { Yap_Error(DOMAIN_ERROR_PROLOG_FLAG, tflag, "trying to set unknown module flag"); return false; } if (mod == USER_MODULE) { flag_term *tarr = GLOBAL_Flags; if (!(fv->type(t2))) return false; if (fv->helper && !(fv->helper(t2))) return false; Term tout = tarr[fv->FlagOfVE].at; if (IsVarTerm(tout)) { Term t; while ((t = Yap_PopTermFromDB(tarr[fv->FlagOfVE].DBT)) == 0) { if (!Yap_gc(2, ENV, gc_P(P, CP))) { Yap_Error(RESOURCE_ERROR_STACK, TermNil, LOCAL_ErrorMessage); return false; } } } else if (IsAtomOrIntTerm(t2)) tarr[fv->FlagOfVE].at = t2; else { tarr[fv->FlagOfVE].DBT = Yap_StoreTermInDB(t2, 2); } } // module specific stuff now if (fv->FlagOfVE == UNKNOWN_FLAG) { me->flags &= ~(UNKNOWN_MASK); if (t2 == TermError) { me->flags |= (UNKNOWN_ERROR); return true; } else if (t2 == TermFail) { me->flags |= (UNKNOWN_FAIL); return true; } else if (t2 == TermWarning) { me->flags |= (UNKNOWN_WARNING); return true; } else if (t2 == TermFastFail) { me->flags |= (UNKNOWN_FAST_FAIL); return true; } Yap_Error( DOMAIN_ERROR_OUT_OF_RANGE, t2, "bad option %s for unknown flag, use one of error, fail or warning.", RepAtom(AtomOfTerm(tflag))->StrOfAE); return false; } else if (fv->FlagOfVE == DOUBLE_QUOTES_FLAG) { return dqf1(me, t2 PASS_REGS); } else if (fv->FlagOfVE == CHARACTER_ESCAPES_FLAG) { if (t2 == TermTrue) { me->flags |= M_CHARESCAPE; return true; } else if (t2 == TermFalse) { me->flags &= ~(M_CHARESCAPE); return true; } Yap_Error(DOMAIN_ERROR_OUT_OF_RANGE, t2, "bad option %s for character_escapes flag, use true or false", RepAtom(AtomOfTerm(tflag))->StrOfAE); return false; } else if (fv->FlagOfVE == BACK_QUOTES_FLAG) { return bqf1(me, t2 PASS_REGS); } else if (fv->FlagOfVE == SINGLE_QUOTES_FLAG) { return sqf1(me, t2 PASS_REGS); } // bad key? return false; } static Term getYapFlagInModule(Term tflag, Term mod) { FlagEntry *fv; ModEntry *me = Yap_GetModuleEntry(mod); if (!mod) return false; fv = GetFlagProp(AtomOfTerm(tflag)); if (!fv && !fv->global) { Yap_Error(DOMAIN_ERROR_OUT_OF_RANGE, tflag, "trying to set unknown flag"); return 0L; } // module specific stuff now if (fv->FlagOfVE == UNKNOWN_FLAG) { if (me->flags & UNKNOWN_ERROR) return TermError; if (me->flags & UNKNOWN_WARNING) return TermWarning; return TermFail; } else if (fv->FlagOfVE == CHARACTER_ESCAPES_FLAG) { if (me->flags & M_CHARESCAPE) return TermTrue; } else if (fv->FlagOfVE == BACK_QUOTES_FLAG) { if (me->flags & BCKQ_CHARS) return TermChars; if (me->flags & BCKQ_CODES) return TermCodes; if (me->flags & BCKQ_ATOM) return TermAtom; return TermString; } else if (fv->FlagOfVE == SINGLE_QUOTES_FLAG) { if (me->flags & SNGQ_CHARS) return TermChars; if (me->flags & SNGQ_CODES) return TermCodes; if (me->flags & SNGQ_ATOM) return TermAtom; return TermString; } else if (fv->FlagOfVE == DOUBLE_QUOTES_FLAG) { if (me->flags & DBLQ_CHARS) return TermChars; if (me->flags & DBLQ_CODES) return TermCodes; if (me->flags & DBLQ_ATOM) return TermAtom; return TermString; } Yap_Error(DOMAIN_ERROR_OUT_OF_RANGE, tflag, "flag %s is not module-scoped", RepAtom(AtomOfTerm(tflag))->StrOfAE); return 0L; } static Int cont_yap_flag(USES_REGS1) { int i = IntOfTerm(EXTRA_CBACK_ARG(2, 1)); int gmax = GLOBAL_flagCount; int lmax = LOCAL_flagCount; Term tflag = Deref(ARG1); EXTRA_CBACK_ARG(2, 1) = MkIntTerm(i + 1); if (IsApplTerm(tflag) && FunctorOfTerm(tflag) == FunctorModule) { Term modt = CurrentModule; tflag = Yap_StripModule(tflag, &modt); while (i != gmax && i != UNKNOWN_FLAG && i != CHARACTER_ESCAPES_FLAG && i != BACK_QUOTES_FLAG && i != SINGLE_QUOTES_FLAG && i != DOUBLE_QUOTES_FLAG) i++; if (i == gmax) cut_fail(); EXTRA_CBACK_ARG(2, 1) = MkIntTerm(i + 1); { Term lab = MkAtomTerm(Yap_LookupAtom(global_flags_setup[i].name)); Term val = Deref(ARG2); if (!Yap_unify(tflag, lab)) return false; if (IsVarTerm(val)) { Term oval = getYapFlagInModule(lab, modt); if (oval == 0) return false; return Yap_unify(oval, val); } else { return setYapFlagInModule(tflag, val, modt); } } return false; } if (i >= gmax) { Yap_unify(ARG1, MkAtomTerm(Yap_LookupAtom(local_flags_setup[i - gmax].name))); if (i == gmax + lmax - 1) do_cut(0); } else { Yap_unify(ARG1, MkAtomTerm(Yap_LookupAtom(global_flags_setup[i].name))); } Term flag = getYapFlag(Deref(ARG1)); return Yap_unify(flag, ARG2); } static Int yap_flag(USES_REGS1) { Term tflag = Deref(ARG1); if (IsVarTerm(tflag)) { EXTRA_CBACK_ARG(2, 1) = MkIntTerm(0); return cont_yap_flag(PASS_REGS1); } if (IsApplTerm(tflag) && FunctorOfTerm(tflag) == FunctorModule) { Term modt; tflag = Yap_StripModule(tflag, &modt); if (IsVarTerm(tflag)) { EXTRA_CBACK_ARG(2, 1) = MkIntTerm(0); return cont_yap_flag(PASS_REGS1); } do_cut(0); if (!isatom(tflag)) return false; if (!isatom(modt)) return false; if (IsVarTerm(Deref(ARG2))) { Term flag = getYapFlagInModule(tflag, modt); if (flag == 0) return false; return Yap_unify(flag, ARG2); } else { return setYapFlagInModule(tflag, Deref(ARG2), modt); } } do_cut(0); if (IsVarTerm(Deref(ARG2))) { Term flag = getYapFlag(Deref(ARG1)); if (flag == 0) return false; return Yap_unify(flag, ARG2); } return set_prolog_flag(PASS_REGS1); } static Int cont_prolog_flag(USES_REGS1) { int i = IntOfTerm(EXTRA_CBACK_ARG(3, 1)); while (i < GLOBAL_flagCount + LOCAL_flagCount) { int gmax = GLOBAL_flagCount; int lmax = LOCAL_flagCount; Term flag, f; if (i >= gmax + lmax) { cut_fail(); } else if (i >= gmax) { Yap_unify(ARG1, (f = MkAtomTerm( Yap_LookupAtom(local_flags_setup[i - gmax].name)))); } else { Yap_unify(ARG1, (f = MkAtomTerm(Yap_LookupAtom(global_flags_setup[i].name)))); } EXTRA_CBACK_ARG(3, 1) = MkIntTerm(++i); flag = getYapFlag(f); if (!Yap_unify(flag, ARG2)) return false; return setYapFlag(f, Deref(ARG3)); } cut_fail(); } /** @pred prolog_flag(? _Flag_,- _OldValue_,+ _NewValue_) Obtain the value for a YAP Prolog flag and then set it to a new value. Equivalent to first calling current_prolog_flag/2 with the second argument _OldValue_ unbound and then calling set_prolog_flag/2 with the third argument _NewValue_. */ static Int prolog_flag(USES_REGS1) { if (IsVarTerm(Deref(ARG1))) { EXTRA_CBACK_ARG(3, 1) = MkIntTerm(0); return cont_prolog_flag(PASS_REGS1); } do_cut(0); if (IsVarTerm(Deref(ARG3))) { Term flag = getYapFlag(Deref(ARG1)); if (flag == 0) return false; return Yap_unify(flag, ARG2); } return setYapFlag(Deref(ARG1), Deref(ARG3)); } static Int cont_current_prolog_flag(USES_REGS1) { int i = IntOfTerm(EXTRA_CBACK_ARG(2, 1)); while (i < GLOBAL_flagCount + LOCAL_flagCount) { int gmax = GLOBAL_flagCount; int lmax = LOCAL_flagCount; Term flag, f; if (i >= gmax + lmax) { cut_fail(); } else if (i >= gmax) { Yap_unify(ARG1, (f = MkAtomTerm( Yap_LookupAtom(local_flags_setup[i - gmax].name)))); } else { Yap_unify(ARG1, (f = MkAtomTerm(Yap_LookupAtom(global_flags_setup[i].name)))); } EXTRA_CBACK_ARG(2, 1) = MkIntTerm(++i); flag = getYapFlag(f); return Yap_unify(flag, ARG2); } cut_fail(); } static Int current_prolog_flag(USES_REGS1) { if (IsVarTerm(Deref(ARG1))) { EXTRA_CBACK_ARG(3, 1) = MkIntTerm(0); return cont_current_prolog_flag(PASS_REGS1); } do_cut(0); Term flag = getYapFlag(Deref(ARG1)); if (flag == 0) return false; return Yap_unify(flag, ARG2); } /** @pred current_prolog_flag(? _Flag_,- _Value_) is iso Obtain the value for a YAP Prolog flag. Equivalent to calling yap_flag/2 with the second argument unbound, and unifying the returned second argument with _Value_. */ static Int current_prolog_flag2(USES_REGS1) { Term tflag = Deref(ARG1); Term tout = 0; FlagEntry *fv; flag_term *tarr; if (IsVarTerm(tflag)) { EXTRA_CBACK_ARG(2, 1) = MkIntTerm(0); return cont_yap_flag(PASS_REGS1); } do_cut(0); if (!IsAtomTerm(tflag)) { Yap_Error(TYPE_ERROR_ATOM, tflag, "current_prolog_flag/3"); return (FALSE); } fv = GetFlagProp(AtomOfTerm(tflag)); if (!fv) { // should itself depend on a flag return FALSE; } if (fv->global) tarr = GLOBAL_Flags; else tarr = LOCAL_Flags; tout = tarr[fv->FlagOfVE].at; if (tout == TermZERO) { // Yap_DebugPlWriteln(tflag); return false; } if (IsVarTerm(tout)) tout = Yap_FetchTermFromDB(tarr[fv->FlagOfVE].DBT); return (Yap_unify(ARG2, tout)); } void Yap_setModuleFlags(ModEntry *new, ModEntry *cme) { CACHE_REGS Atom at = new->AtomOfME; if (at == AtomProlog || CurrentModule == PROLOG_MODULE) { new->flags = M_SYSTEM | UNKNOWN_ERROR | M_CHARESCAPE | DBLQ_CODES | BCKQ_STRING |SNGQ_ATOM; if (at == AtomUser) new->flags = UNKNOWN_ERROR | M_CHARESCAPE | DBLQ_CODES | BCKQ_STRING |SNGQ_ATOM; } else if (cme && cme->flags && cme != new) { new->flags = cme->flags; } else { new->flags = (UNKNOWN_ERROR | M_CHARESCAPE | DBLQ_CODES | BCKQ_STRING |SNGQ_ATOM); } // printf("cme=%s new=%s flags=%x\n",cme,at->StrOfAE,new->flags); } bool setYapFlag(Term tflag, Term t2) { FlagEntry *fv; flag_term *tarr; if (IsVarTerm(tflag)) { Yap_Error(INSTANTIATION_ERROR, tflag, "yap_flag/2"); return (FALSE); } if (IsApplTerm(tflag) && FunctorOfTerm(tflag) == FunctorModule) { Term modt; tflag = Yap_StripModule(tflag, &modt); if (!isatom(tflag)) return false; if (!isatom(modt)) return false; return setYapFlagInModule(tflag, t2, modt); } if (!IsAtomTerm(tflag)) { Yap_Error(TYPE_ERROR_ATOM, tflag, "yap_flag/2"); return (FALSE); } fv = GetFlagProp(AtomOfTerm(tflag)); if (!fv) { Term fl = GLOBAL_Flags[USER_FLAGS_FLAG].at; if (fl == TermSilent) { CACHE_REGS Term t2 = Deref(ARG2); newFlag(tflag, t2); } else if (fl == TermWarning) { Yap_Warning("Flag %s does not exist", RepAtom(AtomOfTerm(fl))->StrOfAE); } else { Yap_Error(DOMAIN_ERROR_PROLOG_FLAG, tflag, "trying to set unknown flag \"%s\"", AtomName(AtomOfTerm(tflag))); } return false; } if (fv->global) { CACHE_REGS switch (fv->FlagOfVE) { case UNKNOWN_FLAG: case CHARACTER_ESCAPES_FLAG: case BACK_QUOTES_FLAG: case DOUBLE_QUOTES_FLAG: case SINGLE_QUOTES_FLAG: return setYapFlagInModule(tflag, t2, CurrentModule); default: tarr = GLOBAL_Flags; } } else { CACHE_REGS tarr = LOCAL_Flags; } if (!(t2 = fv->type(t2))) return false; if (fv->helper && !(fv->helper(t2))) return false; Term tout = tarr[fv->FlagOfVE].at; if (IsVarTerm(tout)) Yap_PopTermFromDB(tarr[fv->FlagOfVE].DBT); if (IsAtomOrIntTerm(t2)) tarr[fv->FlagOfVE].at = t2; else { tarr[fv->FlagOfVE].DBT = Yap_StoreTermInDB(t2, 2); } return true; } Term Yap_UnknownFlag(Term mod) { if (mod == PROLOG_MODULE) mod = TermProlog; ModEntry *fv = Yap_GetModuleEntry(mod); if (fv == NULL) fv = Yap_GetModuleEntry(TermUser); if (fv->flags & UNKNOWN_ERROR) return TermError; if (fv->flags & UNKNOWN_WARNING) return TermWarning; return TermFail; } Term getYapFlag(Term tflag) { FlagEntry *fv; flag_term *tarr; if (IsVarTerm(tflag)) { Yap_Error(INSTANTIATION_ERROR, tflag, "yap_flag/2"); return (FALSE); } if (IsApplTerm(tflag) && FunctorOfTerm(tflag) == FunctorModule) { Term modt; tflag = Yap_StripModule(tflag, &modt); if (!isatom(tflag)) return false; if (!isatom(modt)) return false; return getYapFlagInModule(tflag, modt); } if (!IsAtomTerm(tflag)) { Yap_Error(TYPE_ERROR_ATOM, tflag, "yap_flag/2"); return (FALSE); } fv = GetFlagProp(AtomOfTerm(tflag)); if (!fv) { Term fl = GLOBAL_Flags[USER_FLAGS_FLAG].at; if (fl == TermSilent) { return false; } else if (fl == TermWarning) { Yap_Warning("Flag ~s does not exist", RepAtom(AtomOfTerm(tflag))->StrOfAE); } else { Yap_Error(DOMAIN_ERROR_PROLOG_FLAG, tflag, "trying to use unknown flag %s", RepAtom(AtomOfTerm(tflag))->StrOfAE); } return false; } if (fv->global) tarr = GLOBAL_Flags; else { CACHE_REGS tarr = LOCAL_Flags; } Term tout = tarr[fv->FlagOfVE].at; if (IsVarTerm(tout)) return Yap_FetchTermFromDB(tarr[fv->FlagOfVE].DBT); else return tout; } /** @pred set_prolog_flag(+ _Flag_,+ _Value_) is iso Set the value for YAP Prolog flag `Flag`. Equivalent to calling yap_flag/2 with both arguments bound. */ static Int set_prolog_flag(USES_REGS1) { Term tflag = Deref(ARG1), t2 = Deref(ARG2); return setYapFlag(tflag, t2); } /** @pred source After executing this goal, YAP keeps information on the source of the predicates that will be consulted. This enables the use of [listing/0](@ref listing), `listing/1` and [clause/2](@ref clause) for those clauses. The same as `source_mode(_,on)` or as declaring all newly defined static procedures as `public`. */ static Int source(USES_REGS1) { setBooleanGlobalPrologFlag(SOURCE_FLAG, true); return true; } /** @pred no_source The opposite to `source`. The same as `source_mode(_,off)`. */ static Int no_source(USES_REGS1) { setBooleanGlobalPrologFlag(SOURCE_FLAG, false); return true; } /** @pred source_mode(- _O_,+ _N_) The state of source mode can either be on or off. When the source mode is on, all clauses are kept both as compiled code and in a "hidden" database. _O_ is unified with the previous state and the mode is set according to _N_. */ static Int source_mode(USES_REGS1) { Term targ; bool current = trueGlobalPrologFlag(SOURCE_FLAG); if (current && !Yap_unify_constant(ARG1, TermTrue)) return false; if (!current && !Yap_unify_constant(ARG1, TermFalse)) return false; targ = Deref(ARG2); setYapFlag(TermSource, targ); return true; } static bool setInitialValue(bool bootstrap, flag_func f, const char *s, flag_term *tarr) { errno = 0; const char *ss = (const char *)s; if (f == booleanFlag) { if (!bootstrap) { return 0; } const char *ss = (const char *)s; if (!strcmp(ss, "true")) { tarr->at = TermTrue; return true; } if (!strcmp(ss, "false")) { tarr->at = TermFalse; return true; } if (!strcmp(ss, "on")) { tarr->at = TermTrue; return true; } if (!strcmp(ss, "off")) { tarr->at = TermFalse; return true; } Yap_Error(DOMAIN_ERROR_OUT_OF_RANGE, TermNil, "~s should be either true (on) or false (off)", s); return false; } else if (f == nat) { if (!bootstrap) { return 0; } UInt r = strtoul(ss, NULL, 10); Term t; if (errno) { Yap_Error(DOMAIN_ERROR_OUT_OF_RANGE, TermNil, "~s should be a positive integer)", s); return false; } CACHE_REGS t = MkIntegerTerm(r); if (IsIntTerm(t)) tarr->at = t; else { tarr->DBT = Yap_StoreTermInDB(t, 2); } return true; } else if (f == at2n) { if (!bootstrap) { return false; } if (!strcmp(ss, "INT_MAX")) { tarr->at = MkIntTerm(Int_MAX); return true; } if (!strcmp(ss, "MAX_THREADS")) { tarr->at = MkIntTerm(MAX_THREADS); return true; } if (!strcmp(ss, "MAX_WORKERS")) { tarr->at = MkIntTerm(MAX_WORKERS); return true; } if (!strcmp(ss, "INT_MIN")) { tarr->at = MkIntTerm(Int_MIN); return true; } if (!strcmp(ss, "YAP_NUMERIC_VERSION")) { tarr->at = MkIntTerm(atol(YAP_NUMERIC_VERSION)); return true; } if (!strcmp(ss, "YAP_NUMERIC_VERSION")) { tarr->at = MkIntTerm(atol(YAP_NUMERIC_VERSION)); return true; } Yap_Error(DOMAIN_ERROR_OUT_OF_RANGE, TermNil, "~s should be either true (on) or false (off)", s); return false; } else if (f == isatom) { if (!bootstrap) { return false; } Atom r = Yap_LookupAtom(s); if (errno) { Yap_Error(DOMAIN_ERROR_OUT_OF_RANGE, TermNil, "~s should be a positive integer)", s); tarr->at = TermNil; } tarr->at = MkAtomTerm(r); return true; } else if (f == options) { CACHE_REGS char tmp[512]; Term t0; if (bootstrap) { return true; } t0 = AbsPair(HR); while (true) { int i = 0, ch = s[0]; while (ch != '\0' && ch != ';') { if (ch != ' ') tmp[i++] = ch; s++; ch = *s; } tmp[i] = '\0'; HR += 2; HR[-2] = MkAtomTerm(Yap_LookupAtom(tmp)); if (ch) { HR[-1] = AbsPair(HR); s++; continue; } else { HR[-1] = TermNil; tarr->DBT = Yap_StoreTermInDB(t0, 2); return true; } } } else if (strcmp(ss, "@boot") == 0) { if (bootstrap) { return true; } Term t = f(TermZERO); if (t == TermZERO) return false; if (IsAtomOrIntTerm(t)) { tarr->at = t; } else { tarr->DBT = Yap_StoreTermInDB(t, 2); } } else { Term t0; if (bootstrap) { return false; } CACHE_REGS const char *us = (const char *)s; t0 = Yap_BufferToTermWithPrioBindings(us, TermNil, 0L, strlen(s) + 1, GLOBAL_MaxPriority); if (!t0) return false; if (IsAtomTerm(t0) || IsIntTerm(t0)) { // do yourself flags if (t0 == MkAtomTerm(AtomQuery)) { f(TermNil); } else { tarr->at = t0; } } else { tarr->DBT = Yap_StoreTermInDB(t0, 2); } return true; } return false; } #define PROLOG_FLAG_PROPERTY_DEFS() \ PAR("access", isaccess, PROLOG_FLAG_PROPERTY_ACCESS, "read_write") \ , PAR("type", isground, PROLOG_FLAG_PROPERTY_TYPE, "term"), \ PAR("scope", flagscope, PROLOG_FLAG_PROPERTY_SCOPE, "global"), \ PAR("keep", booleanFlag, PROLOG_FLAG_PROPERTY_KEEP, "false"), \ PAR(NULL, ok, PROLOG_FLAG_PROPERTY_END, 0) #define PAR(x, y, z, w) z typedef enum prolog_flag_property_enum_choices { PROLOG_FLAG_PROPERTY_DEFS() } prolog_flag_property_choices_t; #undef PAR #define PAR(x, y, z, w) \ { x, y, z, w } static const param2_t prolog_flag_property_defs[] = { PROLOG_FLAG_PROPERTY_DEFS()}; #undef PAR static Int do_prolog_flag_property(Term tflag, Term opts USES_REGS) { /* Init current_prolog_flag */ FlagEntry *fv; xarg *args; prolog_flag_property_choices_t i; bool rc = true; args = Yap_ArgList2ToVector(opts, prolog_flag_property_defs, PROLOG_FLAG_PROPERTY_END); if (args == NULL) { Yap_Error(LOCAL_Error_TYPE, opts, NULL); return false; } if (!IsAtomTerm(tflag)) { if (IsApplTerm(tflag) && FunctorOfTerm(tflag) == FunctorModule) { Term modt = CurrentModule; tflag = Yap_YapStripModule(tflag, &modt); } else { free(args); Yap_Error(TYPE_ERROR_ATOM, tflag, "yap_flag/2"); return (FALSE); } } fv = GetFlagProp(AtomOfTerm(tflag)); for (i = 0; i < PROLOG_FLAG_PROPERTY_END; i++) { if (args[i].used) { switch (i) { case PROLOG_FLAG_PROPERTY_ACCESS: if (fv->rw) rc = rc && Yap_unify(TermReadWrite, args[PROLOG_FLAG_PROPERTY_ACCESS].tvalue); else rc = rc && Yap_unify(TermReadOnly, args[PROLOG_FLAG_PROPERTY_ACCESS].tvalue); break; case PROLOG_FLAG_PROPERTY_TYPE: if (fv->type == booleanFlag) rc = rc && Yap_unify(TermBoolean, args[PROLOG_FLAG_PROPERTY_TYPE].tvalue); else if (fv->type == isatom) rc = rc && Yap_unify(TermAtom, args[PROLOG_FLAG_PROPERTY_TYPE].tvalue); else if (fv->type == nat) rc = rc && Yap_unify(TermInteger, args[PROLOG_FLAG_PROPERTY_TYPE].tvalue); else if (fv->type == isfloat) rc = rc && Yap_unify(TermFloat, args[PROLOG_FLAG_PROPERTY_TYPE].tvalue); else rc = rc && Yap_unify(TermTerm, args[PROLOG_FLAG_PROPERTY_TYPE].tvalue); break; case PROLOG_FLAG_PROPERTY_KEEP: rc = rc && false; break; case PROLOG_FLAG_PROPERTY_SCOPE: if (fv->global) { if (fv->FlagOfVE == UNKNOWN_FLAG || fv->FlagOfVE == CHARACTER_ESCAPES_FLAG || fv->FlagOfVE == SINGLE_QUOTES_FLAG || fv->FlagOfVE == DOUBLE_QUOTES_FLAG || fv->FlagOfVE == BACK_QUOTES_FLAG) Yap_unify(TermModule, args[PROLOG_FLAG_PROPERTY_SCOPE].tvalue); rc = rc && Yap_unify(TermGlobal, args[PROLOG_FLAG_PROPERTY_SCOPE].tvalue); } else rc = rc && Yap_unify(TermThread, args[PROLOG_FLAG_PROPERTY_SCOPE].tvalue); break; case PROLOG_FLAG_PROPERTY_END: /* break; */ Yap_Error(DOMAIN_ERROR_PROLOG_FLAG, opts, "Flag not supported by YAP"); } } } // UNLOCK(GLOBAL_Prolog_Flag[sno].prolog_flaglock); free(args); return rc; } static Int cont_prolog_flag_property(USES_REGS1) { /* current_prolog_flag */ int i = IntOfTerm(EXTRA_CBACK_ARG(2, 1)); while (i < GLOBAL_flagCount + LOCAL_flagCount) { int gmax = GLOBAL_flagCount; int lmax = LOCAL_flagCount; Term lab; if (i >= gmax + lmax) { cut_fail(); } else if (i >= gmax) { lab = MkAtomTerm(Yap_LookupAtom(local_flags_setup[i - gmax].name)); } else { if (i == UNKNOWN_FLAG || i == CHARACTER_ESCAPES_FLAG || i == SINGLE_QUOTES_FLAG || i == DOUBLE_QUOTES_FLAG || i == BACK_QUOTES_FLAG) { Term labs[2]; labs[0] = MkVarTerm(); labs[1] = MkAtomTerm(Yap_LookupAtom(global_flags_setup[i].name)); lab = Yap_MkApplTerm(FunctorModule, 2, labs); } else { lab = MkAtomTerm(Yap_LookupAtom(global_flags_setup[i].name)); } } EXTRA_CBACK_ARG(2, 1) = MkIntTerm(++i); Yap_unify(ARG1, lab); return do_prolog_flag_property(lab, Deref(ARG2) PASS_REGS); } cut_fail(); } /** @pred prolog_flag_property(+ _Flag_,+ _Prooperties_) Report a property for a YAP Prolog flag. _Properties_ include * `type(+_Type_)` with _Type_ one of `boolean`, `integer`, `float`, `atom` and `term` (that is, any ground term) * `access(+_Access_)` with _Access_ one of `read_only` or `read_write` * `scope(+_Scope_) the flag aplies to a `thread`, to a `module`, or is `global` to the system. */ static Int prolog_flag_property(USES_REGS1) { /* Init current_prolog_flag */ Term t1 = Deref(ARG1); /* make valgrind happy by always filling in memory */ EXTRA_CBACK_ARG(2, 1) = MkIntTerm(0); if (IsVarTerm(t1)) { return (cont_prolog_flag_property(PASS_REGS1)); } else { if (IsApplTerm(t1) && FunctorOfTerm(t1) == FunctorModule) { Term modt; t1 = Yap_StripModule(t1, &modt); if (IsAtomTerm(modt)) { Int rc; rc = cont_prolog_flag_property(PASS_REGS1); return rc; } } else if (IsAtomTerm(t1)) { do_cut(0); return do_prolog_flag_property(t1, Deref(ARG2) PASS_REGS); } else { Yap_Error(TYPE_ERROR_ATOM, t1, "prolog_flag_property/2"); } } return false; } static void newFlag(Term fl, Term val) { flag_info f; int i = GLOBAL_flagCount; GLOBAL_flagCount++; f.name = (char *)RepAtom(AtomOfTerm(fl))->StrOfAE; f.writable = true; f.helper = NULL; f.def = ok; initFlag(&f, i, true); if (IsAtomOrIntTerm(val)) { GLOBAL_Flags[i].at = val; } else { GLOBAL_Flags[i].DBT = Yap_StoreTermInDB(val, 2); } } static Int do_create_prolog_flag(USES_REGS1) { FlagEntry *fv; xarg *args; prolog_flag_property_choices_t i; Term tflag = Deref(ARG1), tval = Deref(ARG2), opts = Deref(ARG3); args = Yap_ArgList2ToVector(opts, prolog_flag_property_defs, PROLOG_FLAG_PROPERTY_END); if (args == NULL) { Yap_Error(LOCAL_Error_TYPE, opts, NULL); return false; } fv = GetFlagProp(AtomOfTerm(tflag)); if (fv) { if (args[PROLOG_FLAG_PROPERTY_KEEP].used && args[PROLOG_FLAG_PROPERTY_KEEP].tvalue == TermTrue) { free(args); return true; } } else { newFlag(tflag, tval); fv = GetFlagProp(AtomOfTerm(tflag)); } for (i = 0; i < PROLOG_FLAG_PROPERTY_END; i++) { if (args[i].used) { switch (i) { case PROLOG_FLAG_PROPERTY_KEEP: break; case PROLOG_FLAG_PROPERTY_ACCESS: if (args[PROLOG_FLAG_PROPERTY_ACCESS].tvalue == TermReadWrite) fv->rw = true; else fv->rw = false; break; case PROLOG_FLAG_PROPERTY_TYPE: { Term ttype = args[PROLOG_FLAG_PROPERTY_TYPE].tvalue; if (ttype == TermBoolean) fv->type = booleanFlag; else if (ttype == TermInteger) fv->type = isatom; else if (ttype == TermFloat) fv->type = isfloat; else fv->type = isground; } break; case PROLOG_FLAG_PROPERTY_SCOPE: free(args); return false; case PROLOG_FLAG_PROPERTY_END: break; } } } // UNLOCK(GLOBAL_Prolog_Flag[sno].prolog_flaglock); free(args); return true; } /** * Init System Prolog flags. This is done in two phases: * early on, it takes care of the atomic flags that are required by other *modules; * later, it looks at flags that are structured terms * * @param bootstrap: wether this is done before stack initialization, or *afterwards. * Complex terms can only be built in the second step. */ void Yap_InitFlags(bool bootstrap) { CACHE_REGS tr_fr_ptr tr0 = TR; flag_info *f = global_flags_setup; GLOBAL_flagCount = 0; if (bootstrap) { GLOBAL_Flags = (union flagTerm *)Yap_AllocCodeSpace( sizeof(union flagTerm) * (2 * sizeof(global_flags_setup) / sizeof(flag_info))); } while (f->name != NULL) { bool itf = setInitialValue(bootstrap, f->def, f->init, GLOBAL_Flags + GLOBAL_flagCount); if (itf) { initFlag(f, GLOBAL_flagCount, true); } GLOBAL_flagCount++; f++; } LOCAL_flagCount = 0; int nflags = sizeof(local_flags_setup) / sizeof(flag_info); if (bootstrap) LOCAL_Flags = (union flagTerm *)Yap_AllocCodeSpace(sizeof(union flagTerm) * nflags); f = local_flags_setup; while (f->name != NULL) { bool itf = setInitialValue(bootstrap, f->def, f->init, LOCAL_Flags + LOCAL_flagCount); // Term itf = Yap_BufferToTermWithPrioBindings(f->init, // strlen(f->init)+1, // LOBAL_MaxPriority, &tp); if (itf) { initFlag(f, LOCAL_flagCount, false); } LOCAL_flagCount++; f++; } // fix readline gettong set so early if (GLOBAL_Stream[StdInStream].status & Readline_Stream_f) { setBooleanGlobalPrologFlag(READLINE_FLAG, true); } if (!bootstrap) { Yap_InitCPredBack("current_prolog_flag", 2, 1, current_prolog_flag, cont_yap_flag, 0); TR = tr0; /** @pred prolog_flag(? _Flag_,- _Value__) Obtain the value for a YAP Prolog flag, same as current_prolog_flag/2_. */ Yap_InitCPredBack("prolog_flag", 3, 1, current_prolog_flag, cont_yap_flag, 0); Yap_InitCPredBack("yap_flag", 3, 1, prolog_flag, cont_yap_flag, 0); Yap_InitCPredBack("prolog_flag", 2, 1, current_prolog_flag2, cont_current_prolog_flag, 0); Yap_InitCPredBack("current_prolog_flag", 2, 1, current_prolog_flag2, cont_current_prolog_flag, 0); Yap_InitCPred("set_prolog_flag", 2, set_prolog_flag, SyncPredFlag); Yap_InitCPred("$create_prolog_flag", 3, do_create_prolog_flag, SyncPredFlag); Yap_InitCPredBack("yap_flag", 2, 1, yap_flag, cont_yap_flag, 0); Yap_InitCPredBack("prolog_flag_property", 2, 1, prolog_flag_property, cont_prolog_flag_property, 0); Yap_InitCPred("source", 0, source, SyncPredFlag); Yap_InitCPred("no_source", 0, no_source, SyncPredFlag); Yap_InitCPred("source_mode", 2, source_mode, SyncPredFlag); } } /* Accessing and changing the flags for a predicate */