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yap-6.3/C/stdpreds.c

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/*************************************************************************
* *
* YAP Prolog *
* *
* Yap Prolog was developed at NCCUP - Universidade do Porto *
* *
* Copyright L.Damas, V.S.Costa and Universidade do Porto 1985-1997 *
* *
**************************************************************************
* *
* File: stdpreds.c *
* Last rev: *
* mods: *
* comments: General-purpose C implemented system predicates *
* *
*************************************************************************/
#ifdef SCCS
static char SccsId[] = "%W% %G%";
#endif
/*
* This file includes the definition of a miscellania of standard predicates
* for yap refering to: Consulting, Executing a C predicate from call,
* Comparisons (both general and numeric), Structure manipulation, Direct
* access to atoms and predicates, Basic support for the debugger
*
* It also includes a table where all C-predicates are initializated
*
*/
#include "Yap.h"
#include "Yatom.h"
#include "Heap.h"
#include "eval.h"
#include "yapio.h"
#include <stdio.h>
#if HAVE_STRING_H
#include <string.h>
#endif
STD_PROTO(static Int p_setval, (void));
STD_PROTO(static Int p_value, (void));
STD_PROTO(static Int p_values, (void));
STD_PROTO(static Int p_flipflop, (void));
STD_PROTO(static Int p_setflop, (void));
#ifdef undefined
STD_PROTO(static CODEADDR *FindAtom, (CODEADDR, int *));
#endif /* undefined */
STD_PROTO(static Int p_opdec, (void));
STD_PROTO(static Term get_num, (char *));
STD_PROTO(static Int p_name, (void));
STD_PROTO(static Int p_atom_chars, (void));
STD_PROTO(static Int p_atom_codes, (void));
STD_PROTO(static Int p_atom_length, (void));
STD_PROTO(static Int p_atom_split, (void));
STD_PROTO(static Int p_number_chars, (void));
STD_PROTO(static Int p_number_codes, (void));
STD_PROTO(static Int p_univ, (void));
STD_PROTO(static Int p_abort, (void));
STD_PROTO(static Int p_halt, (void));
STD_PROTO(static Int p_halt0, (void));
STD_PROTO(static Int init_current_atom, (void));
STD_PROTO(static Int cont_current_atom, (void));
STD_PROTO(static Int init_current_predicate, (void));
STD_PROTO(static Int cont_current_predicate, (void));
STD_PROTO(static OpEntry *NextOp, (OpEntry *));
STD_PROTO(static Int init_current_op, (void));
STD_PROTO(static Int cont_current_op, (void));
#ifdef DEBUG
STD_PROTO(static Int p_debug, (void));
#endif
STD_PROTO(static Int p_flags, (void));
STD_PROTO(static int AlreadyHidden, (char *));
STD_PROTO(static Int p_hide, (void));
STD_PROTO(static Int p_hidden, (void));
STD_PROTO(static Int p_unhide, (void));
STD_PROTO(static Int TrailMax, (void));
STD_PROTO(static Int GlobalMax, (void));
STD_PROTO(static Int LocalMax, (void));
STD_PROTO(static Int p_statistics_heap_max, (void));
STD_PROTO(static Int p_statistics_global_max, (void));
STD_PROTO(static Int p_statistics_local_max, (void));
STD_PROTO(static Int p_statistics_heap_info, (void));
STD_PROTO(static Int p_statistics_stacks_info, (void));
STD_PROTO(static Int p_statistics_trail_info, (void));
STD_PROTO(static Term mk_argc_list, (void));
STD_PROTO(static Int p_argv, (void));
STD_PROTO(static Int p_cputime, (void));
STD_PROTO(static Int p_runtime, (void));
STD_PROTO(static Int p_walltime, (void));
STD_PROTO(static Int p_access_yap_flags, (void));
STD_PROTO(static Int p_set_yap_flags, (void));
static Int
p_setval(void)
{ /* '$set_value'(+Atom,+Atomic) */
Term t1 = Deref(ARG1), t2 = Deref(ARG2);
if (!IsVarTerm(t1) && IsAtomTerm(t1) &&
(!IsVarTerm(t2) && (IsAtomTerm(t2) || IsNumTerm(t2)))) {
PutValue(AtomOfTerm(t1), t2);
return (TRUE);
}
return (FALSE);
}
static Int
p_value(void)
{ /* '$get_value'(+Atom,?Val) */
Term t1 = Deref(ARG1);
if (!IsAtomTerm(t1))
return (FALSE);
return (unify_constant(ARG2, GetValue(AtomOfTerm(t1))));
}
static Int
p_values(void)
{ /* '$values'(Atom,Old,New) */
Term t1 = Deref(ARG1), t3 = Deref(ARG3);
if (!IsAtomTerm(t1))
return (FALSE);
if (!unify_constant(ARG2, GetValue(AtomOfTerm(t1))))
return (FALSE);
if (!IsVarTerm(t3)) {
if (IsAtomTerm(t3) || IsNumTerm(t3)) {
PutValue(AtomOfTerm(t1), t3);
} else
return (FALSE);
}
return (TRUE);
}
static Int
p_flipflop(void)
{ /* '$flipflop' */
Atom at;
PredEntry *pred;
at = FullLookupAtom("$spy");
pred = RepPredProp(PredPropByFunc(MkFunctor(at, 1),0));
SpyCode = pred;
return ((int) (FlipFlop = (1 - FlipFlop)));
}
static Int
p_setflop(void)
{ /* '$setflop'(N) */
Term t = Deref(ARG1);
if (IsIntTerm(t)) {
FlipFlop = IntOfTerm(t) & 1;
return (TRUE);
}
return (FALSE);
}
Int
p_creep(void)
{
Atom at;
PredEntry *pred;
at = FullLookupAtom("$creep");
pred = RepPredProp(PredPropByFunc(MkFunctor(at, 1),0));
CreepCode = pred;
CreepFlag = Unsigned(LCL0)-Unsigned(H0);
creep_on = TRUE;
return (TRUE);
}
#ifdef undefined
/*
* Returns where some particular piece of code is, it may take its time but
* then you only need it while creeping, so why bother ?
*/
static CODEADDR *
FindAtom(codeToFind, arity)
CODEADDR codeToFind;
unsigned int *arityp;
{
Atom a;
int i;
for (i = 0; i < MaxHash; ++i) {
READ_LOCK(HashChain[i].AeRWLock);
a = HashChain[i].Entry;
READ_UNLOCK(HashChain[i].AeRWLock);
while (a != NIL) {
register PredEntry *pp;
AtomEntry *ae = RepAtom(a);
READ_LOCK(ae->ARWLock);
pp = RepPredProp(RepAtom(a)->PropsOfAE);
while (!EndOfPAEntr(pp) && ((pp->KindOfPE & 0x8000)
|| (pp->CodeOfPred != codeToFind)))
pp = RepPredProp(pp->NextOfPE);
if (pp != NIL) {
CODEADDR *out;
READ_LOCK(pp->PRWLock);
out = &(pp->CodeOfPred)
*arityp = pp->ArityOfPE;
READ_UNLOCK(pp->PRWLock);
READ_UNLOCK(ae->ARWLock);
return (out);
}
a = RepAtom(a)->NextOfAE;
READ_UNLOCK(ae->ARWLock);
}
}
*arityp = 0;
return (0);
}
/*
* This is called when you want to creep a C-predicate or a predicate written
* in assembly
*/
CELL
FindWhatCreep(toCreep)
CELL toCreep;
{
unsigned int arity;
Atom at;
CODEADDR *place;
if (toCreep > 64) { /* written in C */
int i;
place = FindAtom((CODEADDR) toCreep, &arity);
*--ASP = Unsigned(P);
*--ASP = N = arity;
for (i = 1; i <= arity; ++i)
*--ASP = X[i];
/* P = CellPtr(CCREEPCODE); */
return (Unsigned(place));
}
}
#endif /* undefined */
static Int
p_opdec(void)
{ /* '$op'(p,type,atom) */
/* we know the arguments are integer, atom, atom */
Term p = Deref(ARG1), t = Deref(ARG2), at = Deref(ARG3);
return (OpDec((int) IntOfTerm(p), RepAtom(AtomOfTerm(t))->StrOfAE,
AtomOfTerm(at)));
}
#ifdef NO_STRTOD
#if HAVE_CTYPE_H
#include <ctype.h>
#endif
double
strtod(s, pe)
char *s, **pe;
{
double r = atof(s);
*pe = s;
while (*s == ' ')
++s;
if (*s == '+' || *s == '-')
++s;
if (!isdigit(*s))
return (r);
while (isdigit(*s))
++s;
if (*s == '.')
++s;
while (isdigit(*s))
++s;
if (*s == 'e' || *s == 'E')
++s;
if (*s == '+' || *s == '-')
++s;
while (isdigit(*s))
++s;
*pe = s;
return (r);
}
#else
#include <stdlib.h>
#endif
static char *cur_char_ptr;
static int
get_char_from_string(int sno)
{
if (cur_char_ptr[0] == '\0')
return(-1);
cur_char_ptr++;
return((int)(cur_char_ptr[-1]));
}
static Term
get_num(char *t)
{
Term out;
cur_char_ptr = t;
out = scan_num(get_char_from_string);
/* not ever iso */
if (out == TermNil && yap_flags[LANGUAGE_MODE_FLAG] != 1) {
int sign = 1;
if (t[0] == '+') {
t++;
}
if (t[0] == '-') {
t++;
sign = -1;
}
if(strcmp(t,"inf") == 0) {
Term ta[1];
ta[0] = MkAtomTerm(LookupAtom("inf"));
if (sign > 0) {
return(MkApplTerm(MkFunctor(AtomPlus, 1), 1, ta));
}
return(MkApplTerm(MkFunctor(AtomMinus, 1), 1, ta));
}
if(strcmp(t,"nan") == 0) {
Term ta[1];
ta[0] = MkAtomTerm(LookupAtom("nan"));
if (sign > 0) {
return(MkApplTerm(MkFunctor(AtomPlus, 1), 1, ta));
}
return(MkApplTerm(MkFunctor(AtomMinus, 1), 1, ta));
}
}
if (cur_char_ptr[0] == '\0')
return(out);
else
return(TermNil);
}
Int
runtime(void)
{
return(cputime()-total_gc_time()-total_stack_shift_time());
}
Int last_gc_time = 0;
Int last_ss_time = 0;
/* $runtime(-SinceInterval,-SinceStart) */
static Int
p_runtime(void)
{
Int now, interval,
gc_time,
ss_time;
cputime_interval(&now, &interval);
gc_time = total_gc_time();
ss_time = total_stack_shift_time();
now -= gc_time+ss_time;
interval -= (gc_time-last_gc_time)+(ss_time-last_ss_time);
last_gc_time = gc_time;
last_ss_time = ss_time;
return( unify_constant(ARG1, MkIntegerTerm(now)) &&
unify_constant(ARG2, MkIntegerTerm(interval)) );
}
/* $cputime(-SinceInterval,-SinceStart) */
static Int
p_cputime(void)
{
Int now, interval;
cputime_interval(&now, &interval);
return( unify_constant(ARG1, MkIntegerTerm(now)) &&
unify_constant(ARG2, MkIntegerTerm(interval)) );
}
static Int
p_walltime(void)
{
Int now, interval;
walltime_interval(&now, &interval);
return( unify_constant(ARG1, MkIntegerTerm(now)) &&
unify_constant(ARG2, MkIntegerTerm(interval)) );
}
static Int
p_char_code(void)
{
Int t0 = Deref(ARG1);
if (IsVarTerm(t0)) {
Term t1 = Deref(ARG2);
if (IsVarTerm(t1)) {
Error(INSTANTIATION_ERROR,t0,"char_code/2");
return(FALSE);
} else if (!IsIntegerTerm(t1)) {
Error(TYPE_ERROR_INTEGER,t1,"char_code/2");
return(FALSE);
} else {
Int code = IntegerOfTerm(t1);
char codes[2];
Term tout;
if (code < 0 || code > 256) {
Error(REPRESENTATION_ERROR_CHARACTER_CODE,t1,"char_code/2");
return(FALSE);
}
codes[0] = code;
codes[1] = '\0';
tout = MkAtomTerm(LookupAtom(codes));
return(unify(ARG1,tout));
}
} else if (!IsAtomTerm(t0)) {
Error(TYPE_ERROR_CHARACTER,t0,"char_code/2");
return(FALSE);
} else {
char *c = RepAtom(AtomOfTerm(t0))->StrOfAE;
if (c[1] != '\0') {
Error(TYPE_ERROR_CHARACTER,t0,"char_code/2");
return(FALSE);
}
return(unify(ARG2,MkIntTerm((Int)(c[0]))));
}
}
static Int
p_name(void)
{ /* name(?Atomic,?String) */
char *String = (char *)TR, *s; /* alloc temp space on trail */
Term t, NewT, AtomNameT = Deref(ARG1);
ARG2 = Deref(ARG2);
if (!IsVarTerm(AtomNameT)) {
if (IsAtomTerm(AtomNameT)) {
s = RepAtom(AtomOfTerm(AtomNameT))->StrOfAE;
NewT = StringToList(s);
if (!IsVarTerm(ARG2) && !IsPairTerm(ARG2)) {
Error(TYPE_ERROR_LIST,ARG2,
"name/2");
return(FALSE);
}
return (unify(NewT, ARG2));
} else if (IsIntTerm(AtomNameT)) {
#if SHORT_INTS
sprintf(String, "%ld", IntOfTerm(AtomNameT));
#else
sprintf(String, "%d", IntOfTerm(AtomNameT));
#endif
NewT = StringToList(String);
if (!IsVarTerm(ARG2) && !IsPairTerm(ARG2)) {
Error(TYPE_ERROR_LIST,ARG2,"name/2");
return(FALSE);
}
return (unify(NewT, ARG2));
} else if (IsFloatTerm(AtomNameT)) {
sprintf(String, "%f", FloatOfTerm(AtomNameT));
NewT = StringToList(String);
if (!IsVarTerm(ARG2) && !IsPairTerm(ARG2)) {
Error(TYPE_ERROR_LIST,ARG2,"name/2");
return(FALSE);
}
return (unify(NewT, ARG2));
} else if (IsLongIntTerm(AtomNameT)) {
#if SHORT_INTS
sprintf(String, "%ld", LongIntOfTerm(AtomNameT));
#else
sprintf(String, "%d", LongIntOfTerm(AtomNameT));
#endif
NewT = StringToList(String);
if (!IsVarTerm(ARG2) && !IsPairTerm(ARG2)) {
Error(TYPE_ERROR_LIST,ARG2,"name/2");
return(FALSE);
}
return (unify(NewT, ARG2));
} else {
Error(TYPE_ERROR_ATOMIC,AtomNameT,"name/2");
return(FALSE);
}
}
t = ARG2;
s = String;
if (!IsVarTerm(t) && t == MkAtomTerm(AtomNil)) {
return (unify_constant(ARG1, MkAtomTerm(LookupAtom(""))));
}
while (!IsVarTerm(t) && IsPairTerm(t)) {
Term Head;
Int i;
Head = HeadOfTerm(t);
if (IsVarTerm(Head)) {
Error(INSTANTIATION_ERROR,Head,"name/2");
return(FALSE);
}
if (!IsIntTerm(Head)) {
Error(TYPE_ERROR_INTEGER,Head,"name/2");
return(FALSE);
}
i = IntOfTerm(Head);
if (i < 0 || i > 255) {
if (i<0)
Error(DOMAIN_ERROR_NOT_LESS_THAN_ZERO,Head,"name/2");
return(FALSE);
}
*s++ = i;
t = TailOfTerm(t);
}
*s = '\0';
if (IsVarTerm(t)) {
Error(INSTANTIATION_ERROR,t,"name/2");
return(FALSE);
}
if (IsAtomTerm(t) && AtomOfTerm(t) == AtomNil) {
if ((NewT = get_num(String)) == TermNil) {
NewT = MkAtomTerm(LookupAtom(String));
}
return (unify_constant(ARG1, NewT));
} else {
Error(TYPE_ERROR_LIST,t,"name/2");
return(FALSE);
}
}
static Int
p_atom_chars(void)
{
Term t1 = Deref(ARG1);
if (!IsVarTerm(t1)) {
Term NewT;
if (!IsAtomTerm(t1)) {
Error(TYPE_ERROR_ATOM, t1, "atom_chars/2");
return(FALSE);
}
if (yap_flags[YAP_TO_CHARS_FLAG] == QUINTUS_TO_CHARS) {
NewT = StringToList(RepAtom(AtomOfTerm(t1))->StrOfAE);
} else {
NewT = StringToListOfAtoms(RepAtom(AtomOfTerm(t1))->StrOfAE);
}
return (unify(NewT, ARG2));
} else {
/* ARG1 unbound */
char *String = (char *)TR; /* alloc temp space on trail */
register Term t = Deref(ARG2);
register char *s = String;
if (IsVarTerm(t)) {
Error(INSTANTIATION_ERROR, t1, "atom_chars/2");
return(FALSE);
}
if (t == TermNil) {
return (unify_constant(t1, MkAtomTerm(LookupAtom(""))));
}
if (!IsPairTerm(t)) {
Error(TYPE_ERROR_LIST, t, "atom_chars/2");
return(FALSE);
}
if (yap_flags[YAP_TO_CHARS_FLAG] == QUINTUS_TO_CHARS) {
while (t != TermNil) {
register Term Head;
register Int i;
Head = HeadOfTerm(t);
if (IsVarTerm(Head)) {
Error(INSTANTIATION_ERROR,Head,"atom_chars/2");
return(FALSE);
} else if (!IsIntTerm(Head)) {
Error(REPRESENTATION_ERROR_CHARACTER_CODE,Head,"atom_chars/2");
return(FALSE);
}
i = IntOfTerm(Head);
if (i < 0 || i > 255) {
Error(REPRESENTATION_ERROR_CHARACTER_CODE,Head,"atom_chars/2");
return(FALSE);
}
*s++ = i;
t = TailOfTerm(t);
if (IsVarTerm(t)) {
Error(INSTANTIATION_ERROR,t,"atom_chars/2");
return(FALSE);
} else if (!IsPairTerm(t) && t != TermNil) {
Error(TYPE_ERROR_LIST, t, "atom_chars/2");
return(FALSE);
}
}
} else {
/* ISO Prolog Mode */
while (t != TermNil) {
register Term Head;
register char *is;
Head = HeadOfTerm(t);
if (IsVarTerm(Head)) {
Error(INSTANTIATION_ERROR,Head,"atom_chars/2");
return(FALSE);
} else if (!IsAtomTerm(Head)) {
Error(TYPE_ERROR_CHARACTER,Head,"atom_chars/2");
return(FALSE);
}
is = RepAtom(AtomOfTerm(Head))->StrOfAE;
if (is[1] != '\0') {
Error(TYPE_ERROR_CHARACTER,Head,"atom_chars/2");
return(FALSE);
}
*s++ = is[0];
t = TailOfTerm(t);
if (IsVarTerm(t)) {
Error(INSTANTIATION_ERROR,t,"atom_chars/2");
return(FALSE);
} else if (!IsPairTerm(t) && t != TermNil) {
Error(TYPE_ERROR_LIST, t, "atom_chars/2");
return(FALSE);
}
}
}
*s++ = '\0';
return (unify_constant(ARG1, MkAtomTerm(LookupAtom(String))));
}
}
static Int
p_atom_concat(void)
{
Term t1 = Deref(ARG1);
char *cptr = ((AtomEntry *)PreAllocCodeSpace())->StrOfAE, *cpt0;
char *top = (char *)AuxSp;
char *atom_str;
UInt sz;
restart:
cpt0 = cptr;
/* we need to have a list */
if (IsVarTerm(t1)) {
ReleasePreAllocCodeSpace((ADDR)cpt0);
Error(INSTANTIATION_ERROR, ARG1, "atom_concat/2");
return(FALSE);
}
while (IsPairTerm(t1)) {
Term thead = HeadOfTerm(t1);
if (IsVarTerm(thead)) {
ReleasePreAllocCodeSpace((ADDR)cpt0);
Error(INSTANTIATION_ERROR, ARG1, "atom_concat/2");
return(FALSE);
}
if (!IsAtomTerm(thead)) {
ReleasePreAllocCodeSpace((ADDR)cpt0);
Error(TYPE_ERROR_ATOM, ARG1, "atom_concat/2");
return(FALSE);
}
atom_str = RepAtom(AtomOfTerm(thead))->StrOfAE;
/* check for overflows */
sz = strlen(atom_str);
if (cptr+sz >= top-1024) {
ReleasePreAllocCodeSpace((ADDR)cpt0);
if (!growheap(FALSE)) {
Error(SYSTEM_ERROR, TermNil, "YAP could not grow heap in atom_concat/2 ]\n");
return(FALSE);
}
goto restart;
}
memcpy((void *)cptr, (void *)atom_str, sz);
cptr += sz;
t1 = TailOfTerm(t1);
if (IsVarTerm(t1)) {
ReleasePreAllocCodeSpace((ADDR)cpt0);
Error(INSTANTIATION_ERROR, ARG1, "atom_concat/2");
return(FALSE);
}
}
if (t1 == TermNil) {
Term tout;
cptr[0] = '\0';
tout = MkAtomTerm(LookupAtom(cpt0));
ReleasePreAllocCodeSpace((ADDR)cpt0);
return(unify(ARG2, tout));
}
ReleasePreAllocCodeSpace((ADDR)cpt0);
Error(TYPE_ERROR_LIST, ARG1, "atom_concat/2");
return(FALSE);
}
static Int
p_atom_codes(void)
{
Term t1 = Deref(ARG1);
if (!IsVarTerm(t1)) {
Term NewT;
if (!IsAtomTerm(t1)) {
Error(TYPE_ERROR_ATOM, t1, "atom_codes/2");
return(FALSE);
}
NewT = StringToList(RepAtom(AtomOfTerm(t1))->StrOfAE);
return (unify(NewT, ARG2));
} else {
/* ARG1 unbound */
char *String = (char *)TR; /* alloc temp space on trail */
register Term t = Deref(ARG2);
register char *s = String;
if (IsVarTerm(t)) {
Error(INSTANTIATION_ERROR, t1, "atom_codes/2");
return(FALSE);
}
if (t == TermNil) {
return (unify_constant(t1, MkAtomTerm(LookupAtom(""))));
}
if (!IsPairTerm(t)) {
Error(TYPE_ERROR_LIST, t, "atom_codes/2");
return(FALSE);
}
while (t != TermNil) {
register Term Head;
register Int i;
Head = HeadOfTerm(t);
if (IsVarTerm(Head)) {
Error(INSTANTIATION_ERROR,Head,"atom_codes/2");
return(FALSE);
} else if (!IsIntTerm(Head)) {
Error(REPRESENTATION_ERROR_CHARACTER_CODE,Head,"atom_codes/2");
return(FALSE);
}
i = IntOfTerm(Head);
if (i < 0 || i > 255) {
Error(REPRESENTATION_ERROR_CHARACTER_CODE,Head,"atom_codes/2");
return(FALSE);
}
*s++ = i;
t = TailOfTerm(t);
if (IsVarTerm(t)) {
Error(INSTANTIATION_ERROR,t,"atom_codes/2");
return(FALSE);
} else if (!IsPairTerm(t) && t != TermNil) {
Error(TYPE_ERROR_LIST, t, "atom_codes/2");
return(FALSE);
}
}
*s++ = '\0';
return (unify_constant(ARG1, MkAtomTerm(LookupAtom(String))));
}
}
static Int
p_atom_length(void)
{
Term t1 = Deref(ARG1);
Term t2 = Deref(ARG2);
Int len;
if (IsVarTerm(t1)) {
Error(INSTANTIATION_ERROR, t1, "atom_length/2");
return(FALSE);
}
if (!IsAtomTerm(t1)) {
Error(TYPE_ERROR_ATOM, t1, "atom_length/2");
return(FALSE);
}
if (!IsVarTerm(t2)) {
if (!IsIntTerm(t2)) {
Error(TYPE_ERROR_INTEGER, t2, "atom_length/2");
return(FALSE);
}
if ((len = IntOfTerm(t2)) < 0) {
Error(DOMAIN_ERROR_NOT_LESS_THAN_ZERO, t2, "atom_length/2");
return(FALSE);
}
return((Int)strlen(RepAtom(AtomOfTerm(t1))->StrOfAE) == len);
} else {
Term tj = MkIntTerm(strlen(RepAtom(AtomOfTerm(t1))->StrOfAE));
return(unify_constant(t2,tj));
}
}
/* split an atom into two sub-atoms */
static Int
p_atom_split(void)
{
Term t1 = Deref(ARG1);
Term t2 = Deref(ARG2);
Int len;
char *s, *s1;
int i;
Term to1, to2;
s1 = (char *)H;
if (IsVarTerm(t1)) {
Error(INSTANTIATION_ERROR, t1, "$atom_split/4");
return(FALSE);
}
if (!IsAtomTerm(t1)) {
Error(TYPE_ERROR_ATOM, t1, "$atom_split/4");
return(FALSE);
}
if (IsVarTerm(t2)) {
Error(INSTANTIATION_ERROR, t2, "$atom_split/4");
return(FALSE);
}
if (!IsIntTerm(t2)) {
Error(TYPE_ERROR_INTEGER, t2, "$atom_split/4");
return(FALSE);
}
if ((len = IntOfTerm(t2)) < 0) {
Error(DOMAIN_ERROR_NOT_LESS_THAN_ZERO, t2, "$atom_split/4");
return(FALSE);
}
s = RepAtom(AtomOfTerm(t1))->StrOfAE;
if (len > (Int)strlen(s)) return(FALSE);
for (i = 0; i< len; i++) {
if (s1 > (char *)LCL0-1024)
Error(SYSTEM_ERROR,t1,"$atom_split/4");
s1[i] = s[i];
}
s1[len] = '\0';
to1 = MkAtomTerm(LookupAtom(s1));
to2 = MkAtomTerm(LookupAtom(s+len));
return(unify_constant(ARG3,to1) && unify_constant(ARG4,to2));
}
static Int
p_number_chars(void)
{
char *String = (char *)TR; /* alloc temp space on Trail */
register Term t = Deref(ARG2), t1 = Deref(ARG1);
Term NewT;
register char *s = String;
if (IsNonVarTerm(t1)) {
Term NewT;
if (!IsNumTerm(t1)) {
Error(TYPE_ERROR_NUMBER, t1, "number_chars/2");
return(FALSE);
} else if (IsIntTerm(t1)) {
#if SHORT_INTS
sprintf(String, "%ld", IntOfTerm(t1));
#else
sprintf(String, "%d", IntOfTerm(t1));
#endif
if (yap_flags[YAP_TO_CHARS_FLAG] == QUINTUS_TO_CHARS) {
NewT = StringToList(String);
} else {
NewT = StringToListOfAtoms(String);
}
return (unify(NewT, ARG2));
} else if (IsFloatTerm(t1)) {
sprintf(String, "%f", FloatOfTerm(t1));
if (yap_flags[YAP_TO_CHARS_FLAG] == QUINTUS_TO_CHARS) {
NewT = StringToList(String);
} else {
NewT = StringToListOfAtoms(String);
}
return (unify(NewT, ARG2));
} else if (IsLongIntTerm(t1)) {
#if SHORT_INTS
sprintf(String, "%ld", LongIntOfTerm(t1));
#else
sprintf(String, "%d", LongIntOfTerm(t1));
#endif
if (yap_flags[YAP_TO_CHARS_FLAG] == QUINTUS_TO_CHARS) {
NewT = StringToList(String);
} else {
NewT = StringToListOfAtoms(String);
}
return (unify(NewT, ARG2));
#if USE_GMP
} else if (IsBigIntTerm(t1)) {
mpz_get_str(String, 10, BigIntOfTerm(t1));
if (yap_flags[YAP_TO_CHARS_FLAG] == QUINTUS_TO_CHARS) {
NewT = StringToList(String);
} else {
NewT = StringToListOfAtoms(String);
}
return (unify(NewT, ARG2));
#endif
}
}
if (IsVarTerm(t)) {
Error(INSTANTIATION_ERROR, t1, "number_chars/2");
return(FALSE);
}
if (t == TermNil) {
return (FALSE);
}
if (!IsPairTerm(t)) {
Error(TYPE_ERROR_LIST, t, "number_chars/2");
return(FALSE);
}
if (yap_flags[YAP_TO_CHARS_FLAG] == QUINTUS_TO_CHARS) {
while (t != TermNil) {
register Term Head;
register Int i;
Head = HeadOfTerm(t);
if (IsVarTerm(Head)) {
Error(INSTANTIATION_ERROR,Head,"number_chars/2");
return(FALSE);
} else if (!IsIntTerm(Head)) {
Error(REPRESENTATION_ERROR_CHARACTER_CODE,Head,"number_chars/2");
return(FALSE);
}
i = IntOfTerm(Head);
if (i < 0 || i > 255) {
Error(REPRESENTATION_ERROR_CHARACTER_CODE,Head,"number_chars/2");
return(FALSE);
}
*s++ = i;
t = TailOfTerm(t);
if (IsVarTerm(t)) {
Error(INSTANTIATION_ERROR,t,"number_chars/2");
return(FALSE);
} else if (!IsPairTerm(t) && t != TermNil) {
Error(TYPE_ERROR_LIST, t, "number_chars/2");
return(FALSE);
}
}
} else {
/* ISO code */
while (t != TermNil) {
register Term Head;
register char *is;
Head = HeadOfTerm(t);
if (IsVarTerm(Head)) {
Error(INSTANTIATION_ERROR,Head,"number_chars/2");
return(FALSE);
} else if (!IsAtomTerm(Head)) {
Error(TYPE_ERROR_CHARACTER,Head,"number_chars/2");
return(FALSE);
}
is = RepAtom(AtomOfTerm(Head))->StrOfAE;
if (is[1] != '\0') {
Error(TYPE_ERROR_CHARACTER,Head,"number_chars/2");
return(FALSE);
}
*s++ = is[0];
t = TailOfTerm(t);
if (IsVarTerm(t)) {
Error(INSTANTIATION_ERROR,t,"number_chars/2");
return(FALSE);
} else if (!IsPairTerm(t) && t != TermNil) {
Error(TYPE_ERROR_LIST, t, "number_chars/2");
return(FALSE);
}
}
}
*s++ = '\0';
if ((NewT = get_num(String)) == TermNil) {
Error(SYNTAX_ERROR, Deref(ARG2), "number_chars/2", String);
return (FALSE);
}
return (unify(ARG1, NewT));
}
static Int
p_number_atom(void)
{
char *String = (char *)TR; /* alloc temp space on Trail */
register Term t = Deref(ARG2), t1 = Deref(ARG1);
Term NewT;
register char *s = String;
if (IsNonVarTerm(t1)) {
if (IsIntTerm(t1)) {
Term NewT;
#if SHORT_INTS
sprintf(String, "%ld", IntOfTerm(t1));
#else
sprintf(String, "%d", IntOfTerm(t1));
#endif
NewT = MkAtomTerm(LookupAtom(String));
return (unify(NewT, ARG2));
} else if (IsFloatTerm(t1)) {
Term NewT;
sprintf(String, "%f", FloatOfTerm(t1));
NewT = MkAtomTerm(LookupAtom(String));
return (unify(NewT, ARG2));
} else if (IsLongIntTerm(t1)) {
Term NewT;
#if SHORT_INTS
sprintf(String, "%ld", LongIntOfTerm(t1));
#else
sprintf(String, "%d", LongIntOfTerm(t1));
#endif
NewT = MkAtomTerm(LookupAtom(String));
return (unify(NewT, ARG2));
#if USE_GMP
} else if (IsBigIntTerm(t1)) {
Term NewT;
mpz_get_str(String, 10, BigIntOfTerm(t1));
NewT = MkAtomTerm(LookupAtom(String));
return (unify(NewT, ARG2));
#endif
} else {
Error(TYPE_ERROR_NUMBER, t1, "number_atom/2");
return(FALSE);
}
}
if (IsVarTerm(t)) {
Error(INSTANTIATION_ERROR, t, "number_chars/2");
return(FALSE);
}
if (t == TermNil) {
return (FALSE);
}
if (!IsAtomTerm(t)) {
Error(TYPE_ERROR_LIST, t, "number_atom/2");
return(FALSE);
}
s = RepAtom(AtomOfTerm(t))->StrOfAE;
if ((NewT = get_num(s)) == TermNil) {
Error(SYNTAX_ERROR, Deref(ARG2), "number_atom/2", String);
return (FALSE);
}
return (unify(ARG1, NewT));
}
static Int
p_number_codes(void)
{
char *String = (char *)TR; /* alloc temp space on Trail */
register Term t = Deref(ARG2), t1 = Deref(ARG1);
Term NewT;
register char *s = String;
if (IsNonVarTerm(t1)) {
if (IsIntTerm(t1)) {
#if SHORT_INTS
sprintf(String, "%ld", IntOfTerm(t1));
#else
sprintf(String, "%d", IntOfTerm(t1));
#endif
NewT = StringToList(String);
return (unify(NewT, ARG2));
} else if (IsFloatTerm(t1)) {
sprintf(String, "%f", FloatOfTerm(t1));
NewT = StringToList(String);
return (unify(NewT, ARG2));
} else if (IsLongIntTerm(t1)) {
#if SHORT_INTS
sprintf(String, "%ld", LongIntOfTerm(t1));
#else
sprintf(String, "%d", LongIntOfTerm(t1));
#endif
NewT = StringToList(String);
return (unify(NewT, ARG2));
#if USE_GMP
} else if (IsBigIntTerm(t1)) {
mpz_get_str(String, 10, BigIntOfTerm(t1));
NewT = StringToList(String);
return (unify(NewT, ARG2));
#endif
} else {
Error(TYPE_ERROR_NUMBER, t1, "number_codes/2");
return(FALSE);
}
}
if (IsVarTerm(t)) {
Error(INSTANTIATION_ERROR, t, "number_codes/2");
}
if (t == TermNil) {
return (FALSE);
}
if (!IsPairTerm(t)) {
Error(TYPE_ERROR_LIST, t, "number_codes/2");
return(FALSE);
}
while (t != TermNil) {
register Term Head;
register Int i;
Head = HeadOfTerm(t);
if (IsVarTerm(Head)) {
Error(INSTANTIATION_ERROR,Head,"number_codes/2");
return(FALSE);
} else if (!IsIntTerm(Head)) {
Error(REPRESENTATION_ERROR_CHARACTER_CODE,Head,"number_codes/2");
return(FALSE);
}
i = IntOfTerm(Head);
if (i < 0 || i > 255) {
Error(REPRESENTATION_ERROR_CHARACTER_CODE,Head,"number_codes/2");
return(FALSE);
}
*s++ = i;
t = TailOfTerm(t);
if (IsVarTerm(t)) {
Error(INSTANTIATION_ERROR,t,"number_codes/2");
return(FALSE);
} else if (!IsPairTerm(t) && t != TermNil) {
Error(TYPE_ERROR_LIST, t, "number_codes/2");
return(FALSE);
}
}
*s++ = '\0';
if ((NewT = get_num(String)) == TermNil) {
Error(SYNTAX_ERROR, Deref(ARG2), "number_chars/2", String);
return (FALSE);
}
return (unify(ARG1, NewT));
}
static Int
p_univ(void)
{ /* A =.. L */
unsigned int arity;
register Term tin;
Term twork, t2;
Atom at;
tin = Deref(ARG1);
t2 = Deref(ARG2);
if (IsVarTerm(tin)) {
/* we need to have a list */
Term *Ar;
if (IsVarTerm(t2)) {
Error(INSTANTIATION_ERROR, t2, "(=..)/2");
return(FALSE);
}
if (!IsPairTerm(t2)) {
if (t2 == TermNil)
Error(DOMAIN_ERROR_NON_EMPTY_LIST, t2, "(=..)/2");
else
Error(TYPE_ERROR_LIST, ARG2, "(=..)/2");
return (FALSE);
}
twork = HeadOfTerm(t2);
if (IsVarTerm(twork)) {
Error(INSTANTIATION_ERROR, twork, "(=..)/2");
return(FALSE);
}
if (IsNumTerm(twork)) {
Term tt = TailOfTerm(t2);
if (IsVarTerm(tt) || tt != MkAtomTerm(AtomNil)) {
Error(TYPE_ERROR_ATOM, twork, "(=..)/2");
return (FALSE);
}
return (unify_constant(ARG1, twork));
}
if (!IsAtomTerm(twork)) {
Error(TYPE_ERROR_ATOM, twork, "(=..)/2");
return (FALSE);
}
at = AtomOfTerm(twork);
twork = TailOfTerm(t2);
if (IsVarTerm(twork)) {
Error(INSTANTIATION_ERROR, twork, "(=..)/2");
return(FALSE);
} else if (!IsPairTerm(twork)) {
if (twork != TermNil) {
Error(TYPE_ERROR_LIST, ARG2, "(=..)/2");
return(FALSE);
}
return (unify_constant(ARG1, MkAtomTerm(at)));
}
/* build the term directly on the heap */
Ar = H;
H++;
while (!IsVarTerm(twork) && IsPairTerm(twork)) {
*H++ = HeadOfTerm(twork);
twork = TailOfTerm(twork);
}
if (IsVarTerm(twork)) {
Error(INSTANTIATION_ERROR, twork, "(=..)/2");
return(FALSE);
}
if (twork != TermNil) {
Error(TYPE_ERROR_LIST, ARG2, "(=..)/2");
return (FALSE);
}
#ifdef SFUNC
DOES_NOT_WORK();
{
SFEntry *pe = (SFEntry *) GetAProp(at, SFProperty);
if (pe)
twork = MkSFTerm(MkFunctor(at, SFArity),
arity, CellPtr(TR), pe->NilValue);
else
twork = MkApplTerm(MkFunctor(at, arity),
arity, CellPtr(TR));
}
#else
arity = H-Ar-1;
if (at == AtomDot && arity == 2) {
Ar[0] = Ar[1];
Ar[1] = Ar[2];
H --;
twork = AbsPair(Ar);
} else {
*Ar = (CELL)(MkFunctor(at, arity));
twork = AbsAppl(Ar);
}
#endif
return (unify(ARG1, twork));
}
if (IsAtomicTerm(tin)) {
twork = MkPairTerm(tin, MkAtomTerm(AtomNil));
return (unify(twork, ARG2));
}
if (IsRefTerm(tin))
return (FALSE);
if (IsApplTerm(tin)) {
Functor fun = FunctorOfTerm(tin);
arity = ArityOfFunctor(fun);
at = NameOfFunctor(fun);
#ifdef SFUNC
if (arity == SFArity) {
CELL *p = CellPtr(TR);
CELL *q = ArgsOfSFTerm(tin);
int argno = 1;
while (*q) {
while (*q > argno++)
*p++ = MkVarTerm();
++q;
*p++ = Deref(*q++);
}
twork = ArrayToList(CellPtr(TR), argno - 1);
} else
#endif
twork = ArrayToList(RepAppl(tin) + 1, arity);
} else {
/* We found a list */
at = AtomDot;
twork = ArrayToList(RepPair(tin), 2);
}
twork = MkPairTerm(MkAtomTerm(at), twork);
return (unify(ARG2, twork));
}
static Int
p_abort(void)
{ /* abort */
/* make sure we won't go creeping around */
Error(PURE_ABORT, TermNil, "");
return(FALSE);
}
static Int
p_halt(void)
{ /* halt */
Term t = Deref(ARG1);
Int out;
if (IsVarTerm(t)) {
Error(INSTANTIATION_ERROR,t,"halt/1");
return(FALSE);
}
if (!IsIntegerTerm(t)) {
Error(TYPE_ERROR_INTEGER,t,"halt/1");
return(FALSE);
}
out = IntegerOfTerm(t);
if (yap_flags[HALT_AFTER_CONSULT_FLAG]) {
exit_yap(out);
} else {
YP_fprintf(YP_stderr, "\n\n[ Prolog execution halted ]\n");
exit_yap(out);
}
return (TRUE);
}
static Int
p_halt0(void)
{ /* halt */
if (yap_flags[HALT_AFTER_CONSULT_FLAG]) {
exit_yap(0);
} else {
YP_fprintf(YP_stderr, "\n\n[ Prolog execution halted ]\n");
exit_yap(0);
}
return (TRUE);
}
static Int
cont_current_atom(void)
{
Atom catom;
Int i = IntOfTerm(EXTRA_CBACK_ARG(1,2));
AtomEntry *ap; /* nasty hack for gcc on hpux */
/* protect current hash table line */
if (IsAtomTerm(EXTRA_CBACK_ARG(1,1)))
catom = AtomOfTerm(EXTRA_CBACK_ARG(1,1));
else
catom = NIL;
if (catom == NIL){
i++;
/* move away from current hash table line */
while (i < MaxHash) {
READ_LOCK(HashChain[i].AERWLock);
catom = HashChain[i].Entry;
if (catom != NIL) {
break;
}
READ_UNLOCK(HashChain[i].AERWLock);
i++;
}
if (i == MaxHash) {
cut_fail();
} else {
READ_UNLOCK(HashChain[i].AERWLock);
}
}
ap = RepAtom(catom);
if (unify_constant(ARG1, MkAtomTerm(catom))) {
if (ap->NextOfAE == NIL) {
i++;
while (i < MaxHash) {
READ_LOCK(HashChain[i].AERWLock);
catom = HashChain[i].Entry;
READ_UNLOCK(HashChain[i].AERWLock);
if (catom != NIL) {
break;
}
i++;
}
if (i == MaxHash) {
cut_succeed();
} else {
EXTRA_CBACK_ARG(1,1) = MkAtomTerm(catom);
}
} else {
READ_LOCK(ap->ARWLock);
EXTRA_CBACK_ARG(1,1) = MkAtomTerm(ap->NextOfAE);
READ_UNLOCK(ap->ARWLock);
}
EXTRA_CBACK_ARG(1,2) = MkIntTerm(i);
return(TRUE);
} else {
return(FALSE);
}
}
static Int
init_current_atom(void)
{ /* current_atom(?Atom) */
Term t1 = Deref(ARG1);
if (!IsVarTerm(t1)) {
if (IsAtomTerm(t1))
cut_succeed();
else
cut_fail();
}
READ_LOCK(HashChain[0].AERWLock);
if (HashChain[0].Entry != NIL) {
EXTRA_CBACK_ARG(1,1) = MkAtomTerm(HashChain[0].Entry);
} else {
EXTRA_CBACK_ARG(1,1) = MkIntTerm(0);
}
READ_UNLOCK(HashChain[0].AERWLock);
EXTRA_CBACK_ARG(1,2) = MkIntTerm(0);
return (cont_current_atom());
}
static Int
cont_current_predicate(void)
{
PredEntry *pp = (PredEntry *)IntegerOfTerm(EXTRA_CBACK_ARG(3,1));
UInt Arity;
Atom name;
if (pp == NULL)
cut_fail();
EXTRA_CBACK_ARG(3,1) = (CELL)MkIntegerTerm((Int)(pp->NextPredOfModule));
Arity = pp->ArityOfPE;
if (Arity)
name = NameOfFunctor(pp->FunctorOfPred);
else
name = (Atom)pp->FunctorOfPred;
return (unify(ARG2,MkAtomTerm(name)) &&
unify(ARG3, MkIntegerTerm((Int)Arity)));
}
static Int
init_current_predicate(void)
{
Term t1 = Deref(ARG1);
if (IsVarTerm(t1) || !IsAtomTerm(t1)) cut_fail();
EXTRA_CBACK_ARG(3,1) = (CELL)MkIntegerTerm((Int)ModulePred[LookupModule(t1)]);
return (cont_current_predicate());
}
static OpEntry *
NextOp(OpEntry *pp)
{
while (!EndOfPAEntr(pp) && pp->KindOfPE != OpProperty)
pp = RepOpProp(pp->NextOfPE);
return (pp);
}
static Int
cont_current_op(void)
{
int prio;
Atom a = AtomOfTerm(EXTRA_CBACK_ARG(3,1));
Int i = IntOfTerm(EXTRA_CBACK_ARG(3,2));
Int fix = IntOfTerm(EXTRA_CBACK_ARG(3,3));
Term TType;
OpEntry *pp = NIL;
/* fix hp gcc bug */
AtomEntry *at = RepAtom(a);
if (fix > 3) {
a = AtomOfTerm(Deref(ARG3));
READ_LOCK(RepAtom(a)->ARWLock);
if (EndOfPAEntr(pp = NextOp(RepOpProp(RepAtom(a)->PropsOfAE)))) {
READ_UNLOCK(RepAtom(a)->ARWLock);
cut_fail();
}
READ_LOCK(pp->OpRWLock);
READ_UNLOCK(RepAtom(a)->ARWLock);
if (fix == 4 && pp->Prefix == 0)
fix = 5;
if (fix == 5 && pp->Posfix == 0)
fix = 6;
if (fix == 6 && pp->Infix == 0)
cut_fail();
TType = MkAtomTerm(GetOp(pp, &prio, (int) (fix - 4)));
fix++;
if (fix == 5 && pp->Posfix == 0)
fix = 6;
if (fix == 6 && pp->Infix == 0)
fix = 7;
READ_UNLOCK(pp->OpRWLock);
EXTRA_CBACK_ARG(3,3) = (CELL) MkIntTerm(fix);
if (fix < 7)
return (unify_constant(ARG1, MkIntTerm(prio))
&& unify_constant(ARG2, TType));
if (unify_constant(ARG1, MkIntTerm(prio)) && unify_constant(ARG2, TType))
cut_succeed();
else
cut_fail();
}
if (fix == 3) {
do {
if ((a = at->NextOfAE) == NIL) {
i++;
while (TRUE) {
READ_LOCK(HashChain[i].AERWLock);
a = HashChain[i].Entry;
READ_UNLOCK(HashChain[i].AERWLock);
if (a != NIL) {
break;
}
i++;
}
if (i == MaxHash)
cut_fail();
EXTRA_CBACK_ARG(3,2) = (CELL) MkIntTerm(i);
}
at = RepAtom(a);
READ_LOCK(at->ARWLock);
pp = NextOp(RepOpProp(at->PropsOfAE));
READ_UNLOCK(at->ARWLock);
} while (EndOfPAEntr(pp));
fix = 0;
EXTRA_CBACK_ARG(3,1) = (CELL) MkAtomTerm(a);
} else {
pp = NextOp(RepOpProp(at->PropsOfAE));
}
READ_LOCK(pp->OpRWLock);
if (fix == 0 && pp->Prefix == 0)
fix = 1;
if (fix == 1 && pp->Posfix == 0)
fix = 2;
TType = MkAtomTerm(GetOp(pp, &prio, (int) fix));
fix++;
if (fix == 1 && pp->Posfix == 0)
fix = 2;
if (fix == 2 && pp->Infix == 0)
fix = 3;
READ_UNLOCK(pp->OpRWLock);
EXTRA_CBACK_ARG(3,3) = (CELL) MkIntTerm(fix);
return (unify_constant(ARG1, MkIntTerm(prio)) &&
unify_constant(ARG2, TType) &&
unify_constant(ARG3, MkAtomTerm(a)));
}
static Int
init_current_op(void)
{ /* current_op(-Precedence,-Type,-Atom) */
Int i = 0;
Atom a;
Term tprio = Deref(ARG1);
Term topsec = Deref(ARG2);
Term top = Deref(ARG3);
if (!IsVarTerm(tprio)) {
Int prio;
if (!IsIntTerm(tprio)) {
Error(DOMAIN_ERROR_OPERATOR_PRIORITY,tprio,"current_op/3");
return(FALSE);
}
prio = IntOfTerm(tprio);
if (prio < 1 || prio > 1200) {
Error(DOMAIN_ERROR_OPERATOR_PRIORITY,tprio,"current_op/3");
return(FALSE);
}
}
if (!IsVarTerm(topsec)) {
char *opsec;
if (!IsAtomTerm(topsec)) {
Error(DOMAIN_ERROR_OPERATOR_SPECIFIER,topsec,"current_op/3");
return(FALSE);
}
opsec = RepAtom(AtomOfTerm(topsec))->StrOfAE;
if (!IsOpType(opsec)) {
Error(DOMAIN_ERROR_OPERATOR_SPECIFIER,topsec,"current_op/3");
return(FALSE);
}
}
if (!IsVarTerm(top)) {
if (!IsAtomTerm(top)) {
Error(TYPE_ERROR_ATOM,top,"current_op/3");
return(FALSE);
}
}
while (TRUE) {
READ_LOCK(HashChain[i].AERWLock);
a = HashChain[i].Entry;
READ_UNLOCK(HashChain[i].AERWLock);
if (a != NIL) {
break;
}
i++;
}
EXTRA_CBACK_ARG(3,1) = (CELL) MkAtomTerm(a);
EXTRA_CBACK_ARG(3,2) = (CELL) MkIntTerm(i);
if (IsVarTerm(top))
EXTRA_CBACK_ARG(3,3) = (CELL) MkIntTerm(3);
else if (IsAtomTerm(top))
EXTRA_CBACK_ARG(3,3) = (CELL) MkIntTerm(4);
else
cut_fail();
return (cont_current_op());
}
#ifdef DEBUG
static Int
p_debug()
{ /* $debug(+Flag) */
int i = IntOfTerm(Deref(ARG1));
if (i >= 'a' && i <= 'z')
Option[i - 96] = !Option[i - 96];
return (1);
}
#endif
static Int
p_flags(void)
{ /* $flags(+Functor,+Mod,?OldFlags,?NewFlags) */
PredEntry *pe;
Int newFl;
Term t1 = Deref(ARG1);
Term t2 = Deref(ARG2);
int mod;
if (IsVarTerm(t1))
return (FALSE);
if (!IsAtomTerm(t2)) {
return(FALSE);
}
mod = LookupModule(t2);
if (IsVarTerm(t1))
return (FALSE);
if (IsAtomTerm(t1)) {
pe = RepPredProp(PredPropByAtom(AtomOfTerm(t1), mod));
} else if (IsApplTerm(t1)) {
Functor funt = FunctorOfTerm(t1);
pe = RepPredProp(PredPropByFunc(funt, mod));
} else
return (FALSE);
if (EndOfPAEntr(pe))
return (FALSE);
WRITE_LOCK(pe->PRWLock);
if (!unify_constant(ARG3, MkIntTerm(pe->PredFlags))) {
WRITE_UNLOCK(pe->PRWLock);
return(FALSE);
}
ARG4 = Deref(ARG4);
if (IsVarTerm(ARG4)) {
WRITE_UNLOCK(pe->PRWLock);
return (TRUE);
} else if (!IsIntTerm(ARG4)) {
union arith_ret v;
if (Eval(ARG4, &v) == long_int_e) {
newFl = v.Int;
} else {
WRITE_UNLOCK(pe->PRWLock);
Error(TYPE_ERROR_INTEGER, ARG4, "flags");
return(FALSE);
}
} else
newFl = IntOfTerm(ARG4);
pe->PredFlags = (SMALLUNSGN) newFl;
WRITE_UNLOCK(pe->PRWLock);
return (TRUE);
}
static int
AlreadyHidden(char *name)
{
AtomEntry *chain;
READ_LOCK(INVISIBLECHAIN.AERWLock);
chain = RepAtom(INVISIBLECHAIN.Entry);
READ_UNLOCK(INVISIBLECHAIN.AERWLock);
while (!EndOfPAEntr(chain) && strcmp(chain->StrOfAE, name) != 0)
chain = RepAtom(chain->NextOfAE);
if (EndOfPAEntr(chain))
return (FALSE);
return (TRUE);
}
static Int
p_hide(void)
{ /* hide(+Atom) */
Atom atomToInclude;
Term t1 = Deref(ARG1);
if (IsVarTerm(t1)) {
Error(INSTANTIATION_ERROR,t1,"hide/1");
return(FALSE);
}
if (!IsAtomTerm(t1)) {
Error(TYPE_ERROR_ATOM,t1,"hide/1");
return(FALSE);
}
atomToInclude = AtomOfTerm(t1);
if (AlreadyHidden(RepAtom(atomToInclude)->StrOfAE)) {
Error(SYSTEM_ERROR,t1,"an atom of name %s was already hidden",
RepAtom(atomToInclude)->StrOfAE);
return(FALSE);
}
ReleaseAtom(atomToInclude);
WRITE_LOCK(INVISIBLECHAIN.AERWLock);
WRITE_LOCK(RepAtom(atomToInclude)->ARWLock);
RepAtom(atomToInclude)->NextOfAE = INVISIBLECHAIN.Entry;
WRITE_UNLOCK(RepAtom(atomToInclude)->ARWLock);
INVISIBLECHAIN.Entry = atomToInclude;
WRITE_UNLOCK(INVISIBLECHAIN.AERWLock);
return (TRUE);
}
static Int
p_hidden(void)
{ /* '$hidden'(+F) */
Atom at;
AtomEntry *chain;
Term t1 = Deref(ARG1);
if (IsVarTerm(t1))
return (FALSE);
if (IsAtomTerm(t1))
at = AtomOfTerm(t1);
else if (IsApplTerm(t1))
at = NameOfFunctor(FunctorOfTerm(t1));
else
return (FALSE);
READ_LOCK(INVISIBLECHAIN.AERWLock);
chain = RepAtom(INVISIBLECHAIN.Entry);
while (!EndOfPAEntr(chain) && AbsAtom(chain) != at)
chain = RepAtom(chain->NextOfAE);
READ_UNLOCK(INVISIBLECHAIN.AERWLock);
if (EndOfPAEntr(chain))
return (FALSE);
return (TRUE);
}
static Int
p_unhide(void)
{ /* unhide(+Atom) */
AtomEntry *atom, *old, *chain;
Term t1 = Deref(ARG1);
if (IsVarTerm(t1)) {
Error(INSTANTIATION_ERROR,t1,"unhide/1");
return(FALSE);
}
if (!IsAtomTerm(t1)) {
Error(TYPE_ERROR_ATOM,t1,"unhide/1");
return(FALSE);
}
atom = RepAtom(AtomOfTerm(t1));
WRITE_LOCK(atom->ARWLock);
if (atom->PropsOfAE != NIL) {
Error(SYSTEM_ERROR,t1,"cannot unhide an atom in use");
return(FALSE);
}
WRITE_LOCK(INVISIBLECHAIN.AERWLock);
chain = RepAtom(INVISIBLECHAIN.Entry);
old = NIL;
while (!EndOfPAEntr(chain) && strcmp(chain->StrOfAE, atom->StrOfAE) != 0) {
old = chain;
chain = RepAtom(chain->NextOfAE);
}
if (EndOfPAEntr(chain))
return (FALSE);
atom->PropsOfAE = chain->PropsOfAE;
if (old == NIL)
INVISIBLECHAIN.Entry = chain->NextOfAE;
else
old->NextOfAE = chain->NextOfAE;
WRITE_UNLOCK(INVISIBLECHAIN.AERWLock);
WRITE_UNLOCK(atom->ARWLock);
return (TRUE);
}
static Int
p_statistics_heap_max(void)
{
Term tmax = MkIntegerTerm(HeapMax);
return(unify(tmax, ARG1));
}
/* The results of the next routines are not to be trusted too */
/* much. Basically, any stack shifting will seriously confuse the */
/* results */
static Int TrailTide = -1, LocalTide = -1, GlobalTide = -1;
/* maximum Trail usage */
static Int
TrailMax(void)
{
Int i;
Int TrWidth = Unsigned(TrailTop) - Unsigned(TrailBase);
CELL *pt;
if (TrailTide != TrWidth) {
pt = (CELL *)TR;
while (pt+2 < (CELL *)TrailTop) {
if (pt[0] == 0 &&
pt[1] == 0 &&
pt[2] == 0)
break;
else
pt++;
}
if (pt+2 < (CELL *)TrailTop)
i = Unsigned(pt) - Unsigned(TrailBase);
else
i = TrWidth;
} else
return(TrWidth);
if (TrailTide > i)
i = TrailTide;
else
TrailTide = i;
return(i);
}
static Int
p_statistics_trail_max(void)
{
Term tmax = MkIntegerTerm(TrailMax());
return(unify(tmax, ARG1));
}
/* maximum Global usage */
static Int
GlobalMax(void)
{
Int i;
Int StkWidth = Unsigned(LCL0) - Unsigned(H0);
CELL *pt;
if (GlobalTide != StkWidth) {
pt = H;
while (pt+2 < ASP) {
if (pt[0] == 0 &&
pt[1] == 0 &&
pt[2] == 0)
break;
else
pt++;
}
if (pt+2 < ASP)
i = Unsigned(pt) - Unsigned(H0);
else
/* so that both Local and Global have reached maximum width */
GlobalTide = LocalTide = i = StkWidth;
} else
return(StkWidth);
if (GlobalTide > i)
i = GlobalTide;
else
GlobalTide = i;
return(i);
}
static Int
p_statistics_global_max(void)
{
Term tmax = MkIntegerTerm(GlobalMax());
return(unify(tmax, ARG1));
}
static Int
LocalMax(void)
{
Int i;
Int StkWidth = Unsigned(LCL0) - Unsigned(H0);
CELL *pt;
if (LocalTide != StkWidth) {
pt = LCL0;
while (pt-3 > H) {
if (pt[-1] == 0 &&
pt[-2] == 0 &&
pt[-3] == 0)
break;
else
--pt;
}
if (pt-3 > H)
i = Unsigned(LCL0) - Unsigned(pt);
else
/* so that both Local and Global have reached maximum width */
GlobalTide = LocalTide = i = StkWidth;
} else
return(StkWidth);
if (LocalTide > i)
i = LocalTide;
else
LocalTide = i;
return(i);
}
static Int
p_statistics_local_max(void)
{
Term tmax = MkIntegerTerm(LocalMax());
return(unify(tmax, ARG1));
}
static Int
p_statistics_heap_info(void)
{
Term tmax = MkIntegerTerm(Unsigned(H0) - Unsigned(HeapBase));
Term tusage = MkIntegerTerm(HeapUsed);
return(unify(tmax, ARG1) && unify(tusage,ARG2));
}
static Int
p_statistics_stacks_info(void)
{
Term tmax = MkIntegerTerm(Unsigned(LCL0) - Unsigned(H0));
Term tgusage = MkIntegerTerm(Unsigned(H) - Unsigned(H0));
Term tlusage = MkIntegerTerm(Unsigned(LCL0) - Unsigned(ASP));
return(unify(tmax, ARG1) && unify(tgusage,ARG2) && unify(tlusage,ARG3));
}
static Int
p_statistics_trail_info(void)
{
Term tmax = MkIntegerTerm(Unsigned(TrailTop) - Unsigned(TrailBase));
Term tusage = MkIntegerTerm(Unsigned(TR) - Unsigned(TrailBase));
return(unify(tmax, ARG1) && unify(tusage,ARG2));
}
static Term
mk_argc_list(void)
{
int i =0;
Term t = TermNil;
while (i < yap_argc) {
char *arg = yap_args[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 = yap_argc-1; j > i+1; --j) {
t = MkPairTerm(MkAtomTerm(LookupAtom(yap_args[j])),t);
}
return(t);
}
}
if (arg[0] == '-' && arg[1] == '-' && arg[2] == '\0') {
/* we found the separator */
int j;
for (j = yap_argc-1; j > i; --j) {
t = MkPairTerm(MkAtomTerm(LookupAtom(yap_args[j])),t);
}
return(t);
}
i++;
}
return(t);
}
static Int
p_argv(void)
{
Term t = mk_argc_list();
return(unify(t, ARG1));
}
static Int
p_access_yap_flags(void)
{
Term tflag = Deref(ARG1);
Int flag;
Term tout;
if (IsVarTerm(tflag)) {
Error(INSTANTIATION_ERROR, tflag, "access_yap_flags/2");
return(FALSE);
}
if (!IsIntTerm(tflag)) {
Error(TYPE_ERROR_INTEGER, tflag, "access_yap_flags/2");
return(FALSE);
}
flag = IntOfTerm(tflag);
if (flag < 0 || flag > NUMBER_OF_YAP_FLAGS) {
return(FALSE);
}
tout = MkIntegerTerm(yap_flags[flag]);
return(unify(ARG2, tout));
}
static Int
p_host_type(void)
{
return(unify(ARG1,MkAtomTerm(LookupAtom(HOST_ALIAS))));
}
static Int
p_has_yap_or(void)
{
#ifdef YAPOR
return(TRUE);
#else
return(FALSE);
#endif
}
static Int
p_set_yap_flags(void)
{
Term tflag = Deref(ARG1);
Term tvalue = Deref(ARG2);
Int flag, value;
if (IsVarTerm(tflag)) {
Error(INSTANTIATION_ERROR, tflag, "set_yap_flags/2");
return(FALSE);
}
if (!IsIntTerm(tflag)) {
Error(TYPE_ERROR_INTEGER, tflag, "set_yap_flags/2");
return(FALSE);
}
flag = IntOfTerm(tflag);
if (IsVarTerm(tvalue)) {
Error(INSTANTIATION_ERROR, tvalue, "set_yap_flags/2");
return(FALSE);
}
if (!IsIntTerm(tvalue)) {
Error(TYPE_ERROR_INTEGER, tvalue, "set_yap_flags/2");
return(FALSE);
}
value = IntOfTerm(tvalue);
/* checking should have been performed */
switch(flag) {
case CHAR_CONVERSION_FLAG:
if (value != 0 && value != 1)
return(FALSE);
yap_flags[CHAR_CONVERSION_FLAG] = value;
break;
case YAP_DOUBLE_QUOTES_FLAG:
if (value < 0 || value > 2)
return(FALSE);
yap_flags[YAP_DOUBLE_QUOTES_FLAG] = value;
break;
case YAP_TO_CHARS_FLAG:
if (value != 0 && value != 1)
return(FALSE);
yap_flags[YAP_TO_CHARS_FLAG] = value;
break;
case LANGUAGE_MODE_FLAG:
if (value < 0 || value > 2)
return(FALSE);
if (value == 1) {
heap_regs->pred_meta_call = RepPredProp(PredPropByFunc(MkFunctor(AtomMetaCall,4),0));
} else {
heap_regs->pred_meta_call = RepPredProp(PredPropByFunc(MkFunctor(AtomMetaCall,4),0));
}
yap_flags[LANGUAGE_MODE_FLAG] = value;
break;
case STRICT_ISO_FLAG:
if (value != 0 && value != 1)
return(FALSE);
yap_flags[STRICT_ISO_FLAG] = value;
break;
case SPY_CREEP_FLAG:
if (value != 0 && value != 1)
return(FALSE);
yap_flags[SPY_CREEP_FLAG] = value;
break;
case SOURCE_MODE_FLAG:
if (value != 0 && value != 1)
return(FALSE);
yap_flags[SOURCE_MODE_FLAG] = value;
break;
case CHARACTER_ESCAPE_FLAG:
if (value != ISO_CHARACTER_ESCAPES
&& value != CPROLOG_CHARACTER_ESCAPES
&& value != SICSTUS_CHARACTER_ESCAPES)
return(FALSE);
yap_flags[CHARACTER_ESCAPE_FLAG] = value;
break;
case WRITE_QUOTED_STRING_FLAG:
if (value != 0 && value != 1)
return(FALSE);
yap_flags[WRITE_QUOTED_STRING_FLAG] = value;
break;
case ALLOW_ASSERTING_STATIC_FLAG:
if (value != 0 && value != 1)
return(FALSE);
yap_flags[ALLOW_ASSERTING_STATIC_FLAG] = value;
break;
default:
return(FALSE);
}
return(TRUE);
}
#ifndef YAPOR
static Int
p_default_sequential(void) {
return(TRUE);
}
#endif
#ifdef DEBUG
extern void DumpActiveGoals(void);
static Int
p_dump_active_goals(void) {
DumpActiveGoals();
return(TRUE);
}
#endif
#ifdef INES
static Int
p_euc_dist(void) {
Term t1 = Deref(ARG1);
Term t2 = Deref(ARG2);
double d1 = (double)(IntegerOfTerm(ArgOfTerm(1,t1))-IntegerOfTerm(ArgOfTerm(1,t2)));
double d2 = (double)(IntegerOfTerm(ArgOfTerm(2,t1))-IntegerOfTerm(ArgOfTerm(2,t2)));
double d3 = (double)(IntegerOfTerm(ArgOfTerm(3,t1))-IntegerOfTerm(ArgOfTerm(3,t2)));
Int result = (Int)sqrt(d1*d1+d2*d2+d3*d3);
return(unify(ARG3,MkIntegerTerm(result)));
}
volatile int loop_counter = 0;
static Int
p_loop(void) {
while (loop_counter == 0);
return(TRUE);
}
#endif
void
InitBackCPreds(void)
{
InitCPredBack("$current_atom", 1, 2, init_current_atom, cont_current_atom,
SafePredFlag|SyncPredFlag);
InitCPredBack("$current_predicate", 3, 1, init_current_predicate, cont_current_predicate,
SafePredFlag|SyncPredFlag);
InitCPredBack("current_op", 3, 3, init_current_op, cont_current_op,
SafePredFlag|SyncPredFlag);
InitBackIO();
InitBackDB();
InitUserBacks();
}
typedef void (*Proc)(void);
Proc E_Modules[]= {/* init_fc,*/ (Proc) 0 };
void
InitCPreds(void)
{
/* numerical comparison */
InitCPred("$set_value", 2, p_setval, SafePredFlag|SyncPredFlag);
InitCPred("$get_value", 2, p_value, TestPredFlag|SafePredFlag|SyncPredFlag);
InitCPred("$values", 3, p_values, SafePredFlag|SyncPredFlag);
/* The flip-flop */
InitCPred("$flipflop", 0, p_flipflop, SafePredFlag|SyncPredFlag);
InitCPred("$setflop", 1, p_setflop, SafePredFlag|SyncPredFlag);
/* general purpose */
InitCPred("$opdec", 3, p_opdec, SafePredFlag|SyncPredFlag);
InitCPred("name", 2, p_name, SafePredFlag);
InitCPred("char_code", 2, p_char_code, SafePredFlag);
InitCPred("atom_chars", 2, p_atom_chars, SafePredFlag);
InitCPred("atom_codes", 2, p_atom_codes, SafePredFlag);
InitCPred("atom_length", 2, p_atom_length, SafePredFlag);
InitCPred("$atom_split", 4, p_atom_split, SafePredFlag);
InitCPred("number_chars", 2, p_number_chars, SafePredFlag);
InitCPred("number_atom", 2, p_number_atom, SafePredFlag);
InitCPred("number_codes", 2, p_number_codes, SafePredFlag);
InitCPred("atom_concat", 2, p_atom_concat, SafePredFlag);
InitCPred("=..", 2, p_univ, SafePredFlag);
InitCPred("$statistics_trail_max", 1, p_statistics_trail_max, SafePredFlag|SyncPredFlag);
InitCPred("$statistics_heap_max", 1, p_statistics_heap_max, SafePredFlag|SyncPredFlag);
InitCPred("$statistics_global_max", 1, p_statistics_global_max, SafePredFlag|SyncPredFlag);
InitCPred("$statistics_local_max", 1, p_statistics_local_max, SafePredFlag|SyncPredFlag);
InitCPred("$statistics_heap_info", 2, p_statistics_heap_info, SafePredFlag|SyncPredFlag);
InitCPred("$statistics_stacks_info", 3, p_statistics_stacks_info, SafePredFlag|SyncPredFlag);
InitCPred("$statistics_trail_info", 2, p_statistics_trail_info, SafePredFlag|SyncPredFlag);
InitCPred("$argv", 1, p_argv, SafePredFlag);
InitCPred("$runtime", 2, p_runtime, SafePredFlag|SyncPredFlag);
InitCPred("$cputime", 2, p_cputime, SafePredFlag|SyncPredFlag);
InitCPred("$walltime", 2, p_walltime, SafePredFlag|SyncPredFlag);
InitCPred("$access_yap_flags", 2, p_access_yap_flags, SafePredFlag);
InitCPred("$set_yap_flags", 2, p_set_yap_flags, SafePredFlag|SyncPredFlag);
InitCPred("abort", 0, p_abort, SyncPredFlag);
InitCPred("halt", 1, p_halt, SyncPredFlag);
InitCPred("halt", 0, p_halt0, SyncPredFlag);
InitCPred("$host_type", 1, p_host_type, SyncPredFlag);
/* basic predicates for the prolog machine tracer */
/* they are defined in analyst.c */
/* Basic predicates for the debugger */
InitCPred("$creep", 0, p_creep, SafePredFlag|SyncPredFlag);
#ifdef DEBUG
InitCPred("$debug", 1, p_debug, SafePredFlag|SyncPredFlag);
#endif
/* Accessing and changing the flags for a predicate */
InitCPred("$flags", 4, p_flags, SafePredFlag|SyncPredFlag);
/* hiding and unhiding some predicates */
InitCPred("hide", 1, p_hide, SafePredFlag|SyncPredFlag);
InitCPred("unhide", 1, p_unhide, SafePredFlag|SyncPredFlag);
InitCPred("$hidden", 1, p_hidden, SafePredFlag|SyncPredFlag);
InitCPred("$has_yap_or", 0, p_has_yap_or, SafePredFlag|SyncPredFlag);
#ifndef YAPOR
InitCPred("$default_sequential", 1, p_default_sequential, SafePredFlag|SyncPredFlag);
#endif
#ifdef INES
InitCPred("euc_dist", 3, p_euc_dist, SafePredFlag);
InitCPred("loop", 0, p_loop, SafePredFlag);
#endif
#ifdef DEBUG
InitCPred("dump_active_goals", 0, p_dump_active_goals, SafePredFlag|SyncPredFlag);
#endif
InitUnify();
InitCdMgr();
InitExecFs();
InitIOPreds();
InitCmpPreds();
InitDBPreds();
InitBBPreds();
InitBigNums();
InitSysPreds();
InitSavePreds();
InitCoroutPreds();
InitArrayPreds();
InitLoadForeign();
InitUserCPreds();
InitUtilCPreds();
InitSortPreds();
InitMaVarCPreds();
#ifdef DEPTH_LIMIT
InitItDeepenPreds();
#endif
#ifdef ANALYST
InitAnalystPreds();
#endif
#ifdef LOW_LEVEL_TRACER
InitLowLevelTrace();
#endif
InitEval();
InitGrowPreds();
#if defined(YAPOR) || defined(TABLING)
init_optyap_preds();
#endif
{
void (*(*(p))) (void) = E_Modules;
while (*p)
(*(*p++)) ();
}
#if CAMACHO
{
extern void InitForeignPreds(void);
InitForeignPreds();
}
#endif
}