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yap-6.3/H/TermExt.h
2012-06-07 10:28:30 -05:00

710 lines
13 KiB
C
Executable File

/*************************************************************************
* *
* YAP Prolog %W% %G% *
* Yap Prolog was developed at NCCUP - Universidade do Porto *
* *
* Copyright L.Damas, V.S.Costa and Universidade do Porto 1985-1997 *
* *
**************************************************************************
* *
* File: TermExt.h *
* mods: *
* comments: Extensions to standard terms for YAP *
* version: $Id: TermExt.h,v 1.15 2008-03-25 22:03:13 vsc Exp $ *
*************************************************************************/
#ifdef USE_SYSTEM_MALLOC
#define SF_STORE (&(Yap_heap_regs->funcs))
#else
#define SF_STORE ((special_functors *)HEAP_INIT_BASE)
#endif
#ifdef USE_OFFSETS
#define AtomFoundVar ((Atom)(&(((special_functors *)(NULL))->AtFoundVar)))
#define AtomFreeTerm ((Atom)(&(((special_functors *)(NULL))->AtFreeTerm)))
#define AtomNil ((Atom)(&(((special_functors *)(NULL))->AtNil)))
#define AtomDot ((Atom)(&(((special_functors *)(NULL))->AtDot)))
#elif defined(THREADS)
#define AtomFoundVar AbsAtom(SF_STORE->AtFoundVar)
#define AtomFreeTerm AbsAtom(SF_STORE->AtFreeTerm)
#define AtomNil AbsAtom(SF_STORE->AtNil)
#define AtomDot AbsAtom(SF_STORE->AtDot)
#else
#define AtomFoundVar AbsAtom(&(SF_STORE->AtFoundVar))
#define AtomFreeTerm AbsAtom(&(SF_STORE->AtFreeTerm))
#define AtomNil AbsAtom(&(SF_STORE->AtNil))
#define AtomDot AbsAtom(&(SF_STORE->AtDot))
#endif
#define TermFoundVar MkAtomTerm(AtomFoundVar)
#define TermFreeTerm MkAtomTerm(AtomFreeTerm)
#define TermNil MkAtomTerm(AtomNil)
#define TermDot MkAtomTerm(AtomDot)
typedef enum
{
db_ref_e = sizeof (Functor *),
attvar_e = 2*sizeof (Functor *),
long_int_e = 3 * sizeof (Functor *),
big_int_e = 4 * sizeof (Functor *),
double_e = 5 * sizeof (Functor *)
}
blob_type;
#define FunctorDBRef ((Functor)(db_ref_e))
#define FunctorAttVar ((Functor)(attvar_e))
#define FunctorLongInt ((Functor)(long_int_e))
#define FunctorBigInt ((Functor)(big_int_e))
#define FunctorDouble ((Functor)(double_e))
#define EndSpecials (double_e+sizeof(Functor *))
inline EXTERN int IsAttVar (CELL *pt);
inline EXTERN int
IsAttVar (CELL *pt)
{
#ifdef YAP_H
CACHE_REGS
return (pt)[-1] == (CELL)attvar_e
&& pt < H;
#else
return (pt)[-1] == (CELL)attvar_e;
#endif
}
inline EXTERN int GlobalIsAttVar (CELL *pt);
inline EXTERN int
GlobalIsAttVar (CELL *pt)
{
return (pt)[-1] == (CELL)attvar_e;
}
typedef enum
{
BIG_INT = 0x01,
BIG_RATIONAL = 0x02,
BIG_FLOAT = 0x04,
EMPTY_ARENA = 0x10,
ARRAY_INT = 0x21,
ARRAY_FLOAT = 0x22,
CLAUSE_LIST = 0x40,
BLOB_STRING = 0x80, /* SWI style strings */
BLOB_WIDE_STRING = 0x81, /* SWI style strings */
EXTERNAL_BLOB = 0x100, /* generic data */
USER_BLOB_START = 0x1000, /* user defined blob */
USER_BLOB_END = 0x1100 /* end of user defined blob */
}
big_blob_type;
inline EXTERN blob_type BlobOfFunctor (Functor f);
inline EXTERN blob_type
BlobOfFunctor (Functor f)
{
return (blob_type) ((CELL)f);
}
typedef struct cp_frame {
CELL *start_cp;
CELL *end_cp;
CELL *to;
#ifdef RATIONAL_TREES
CELL oldv;
int ground;
#endif
} copy_frame;
#ifdef COROUTINING
typedef struct
{
/* what to do when someone tries to bind our term to someone else
in some predefined context */
void (*bind_op) (Term *, Term CACHE_TYPE);
/* what to do if someone wants to copy our constraint */
int (*copy_term_op) (CELL *, struct cp_frame **, CELL * CACHE_TYPE);
/* copy the constraint into a term and back */
Term (*to_term_op) (CELL *);
int (*term_to_op) (Term, Term CACHE_TYPE);
/* op called to do marking in GC */
void (*mark_op) (CELL *);
} ext_op;
/* known delays */
typedef enum
{
empty_ext = 0 * sizeof (ext_op), /* default op, this should never be called */
attvars_ext = 1 * sizeof (ext_op) /* support for attributed variables */
/* add your own extensions here */
/* keep this one */
}
exts;
#endif
#ifdef YAP_H
/* make sure that these data structures are the first thing to be allocated
in the heap when we start the system */
#ifdef THREADS
typedef struct special_functors_struct
{
AtomEntry *AtFoundVar;
AtomEntry *AtFreeTerm;
AtomEntry *AtNil;
AtomEntry *AtDot;
} special_functors;
#else
typedef struct special_functors_struct
{
AtomEntry AtFoundVar;
char AtFoundVarChars[8];
AtomEntry AtFreeTerm;
char AtFreeTermChars[8];
AtomEntry AtNil;
char AtNilChars[8];
AtomEntry AtDot;
char AtDotChars[8];
}
special_functors;
#endif
#endif /* YAP_H */
inline extern Float CpFloatUnaligned(CELL *ptr);
#if SIZEOF_DOUBLE == SIZEOF_LONG_INT
inline EXTERN Term MkFloatTerm (Float);
inline EXTERN Term
MkFloatTerm (Float dbl)
{
CACHE_REGS
return (Term) ((H[0] = (CELL) FunctorDouble, *(Float *) (H + 1) =
dbl, H[2] = EndSpecials, H +=
3, AbsAppl (H - 3)));
}
inline EXTERN Float FloatOfTerm (Term t);
inline EXTERN Float
FloatOfTerm (Term t)
{
return (Float) (*(Float *) (RepAppl (t) + 1));
}
#define InitUnalignedFloat()
inline extern Float
CpFloatUnaligned(CELL *ptr)
{
return *((Float *)ptr);
}
#else
#if SIZEOF_DOUBLE == 2*SIZEOF_LONG_INT
inline extern void AlignGlobalForDouble( USES_REGS1 );
#define DOUBLE_ALIGNED(ADDR) ((CELL)(ADDR) & 0x4)
#ifdef i386
inline EXTERN Float
CpFloatUnaligned (CELL * ptr)
{
return *((Float *) (ptr + 1));
}
#else
/* first, need to address the alignment problem */
inline EXTERN Float
CpFloatUnaligned (CELL * ptr)
{
union
{
Float f;
CELL d[2];
} u;
u.d[0] = ptr[1];
u.d[1] = ptr[2];
return (u.f);
}
#endif
inline EXTERN Term MkFloatTerm (Float);
inline EXTERN Term
MkFloatTerm (Float dbl)
{
CACHE_REGS
return (Term) ((AlignGlobalForDouble ( PASS_REGS1 ), H[0] =
(CELL) FunctorDouble, *(Float *) (H + 1) = dbl, H[3] =
EndSpecials, H +=
4, AbsAppl (H - 4)));
}
inline EXTERN Float FloatOfTerm (Term t);
inline EXTERN Float
FloatOfTerm (Term t)
{
return (Float) ((DOUBLE_ALIGNED (RepAppl (t)) ? *(Float *) (RepAppl (t) + 1)
: CpFloatUnaligned (RepAppl (t))));
}
/* no alignment problems for 64 bit machines */
#else
/* OOPS, YAP only understands Floats that are as large as cells or that
take two cells!!! */
OOPS
#endif
#endif
#ifndef YAP_H
#include <stddef.h>
#endif
Term Yap_MkBlobStringTerm(const char *, size_t len);
Term Yap_MkBlobWideStringTerm(const wchar_t *, size_t len);
char *Yap_BlobStringOfTerm(Term);
wchar_t *Yap_BlobWideStringOfTerm(Term);
char *Yap_BlobStringOfTermAndLength(Term, size_t *);
inline EXTERN int IsFloatTerm (Term);
inline EXTERN int
IsFloatTerm (Term t)
{
return (int) (IsApplTerm (t) && FunctorOfTerm (t) == FunctorDouble);
}
/* extern Functor FunctorLongInt; */
inline EXTERN Term MkLongIntTerm (Int);
inline EXTERN Term
MkLongIntTerm (Int i)
{
CACHE_REGS
H[0] = (CELL) FunctorLongInt;
H[1] = (CELL) (i);
H[2] = EndSpecials;
H += 3;
return AbsAppl(H - 3);
}
inline EXTERN Int LongIntOfTerm (Term t);
inline EXTERN Int
LongIntOfTerm (Term t)
{
return (Int) (RepAppl (t)[1]);
}
inline EXTERN int IsLongIntTerm (Term);
inline EXTERN int
IsLongIntTerm (Term t)
{
return (int) (IsApplTerm (t) && FunctorOfTerm (t) == FunctorLongInt);
}
#ifdef USE_GMP
#include <stdio.h>
#include <gmp.h>
#else
typedef UInt mp_limb_t;
typedef struct {
Int _mp_size, _mp_alloc;
mp_limb_t *_mp_d;
} MP_INT;
typedef struct {
MP_INT _mp_num;
MP_INT _mp_den;
} MP_RAT;
#endif
inline EXTERN int IsBigIntTerm (Term);
inline EXTERN int
IsBigIntTerm (Term t)
{
return (int) (IsApplTerm (t) && FunctorOfTerm (t) == FunctorBigInt);
}
#ifdef USE_GMP
Term STD_PROTO (Yap_MkBigIntTerm, (MP_INT *));
MP_INT *STD_PROTO (Yap_BigIntOfTerm, (Term));
Term STD_PROTO (Yap_MkBigRatTerm, (MP_RAT *));
MP_RAT *STD_PROTO (Yap_BigRatOfTerm, (Term));
inline EXTERN void MPZ_SET (mpz_t, MP_INT *);
inline EXTERN void
MPZ_SET (mpz_t dest, MP_INT *src)
{
dest->_mp_size = src->_mp_size;
dest->_mp_alloc = src->_mp_alloc;
dest->_mp_d = src->_mp_d;
}
inline EXTERN int IsLargeIntTerm (Term);
inline EXTERN int
IsLargeIntTerm (Term t)
{
return (int) (IsApplTerm (t)
&& ((FunctorOfTerm (t) <= FunctorBigInt)
&& (FunctorOfTerm (t) >= FunctorLongInt)));
}
inline EXTERN UInt Yap_SizeOfBigInt (Term);
inline EXTERN UInt
Yap_SizeOfBigInt (Term t)
{
CELL *pt = RepAppl(t)+1;
return 2+(sizeof(MP_INT)+
(((MP_INT *)pt)->_mp_alloc*sizeof(mp_limb_t)))/sizeof(CELL);
}
#else
inline EXTERN int IsLargeIntTerm (Term);
inline EXTERN int
IsLargeIntTerm (Term t)
{
return (int) (IsApplTerm (t) && FunctorOfTerm (t) == FunctorLongInt);
}
#endif
typedef struct string_struct {
UInt len;
} blob_string_t;
inline EXTERN int IsBlobStringTerm (Term);
inline EXTERN int
IsBlobStringTerm (Term t)
{
return (int) (IsApplTerm (t) &&
FunctorOfTerm (t) == FunctorBigInt &&
(RepAppl(t)[1] & BLOB_STRING) == BLOB_STRING);
}
inline EXTERN int IsWideBlobStringTerm (Term);
inline EXTERN int
IsWideBlobStringTerm (Term t)
{
return (int) (IsApplTerm (t) &&
FunctorOfTerm (t) == FunctorBigInt &&
RepAppl(t)[1] == BLOB_WIDE_STRING);
}
/* extern Functor FunctorLongInt; */
inline EXTERN int IsLargeNumTerm (Term);
inline EXTERN int
IsLargeNumTerm (Term t)
{
return (int) (IsApplTerm (t)
&& ((FunctorOfTerm (t) <= FunctorDouble)
&& (FunctorOfTerm (t) >= FunctorLongInt)));
}
inline EXTERN int IsExternalBlobTerm (Term, CELL);
inline EXTERN int
IsExternalBlobTerm (Term t, CELL tag)
{
return (int) (IsApplTerm (t) &&
FunctorOfTerm (t) == FunctorBigInt &&
RepAppl(t)[1] == tag);
}
inline EXTERN void *ExternalBlobFromTerm (Term);
inline EXTERN void *
ExternalBlobFromTerm (Term t)
{
MP_INT *base = (MP_INT *)(RepAppl(t)+2);
return (void *) (base+1);
}
inline EXTERN int IsNumTerm (Term);
inline EXTERN int
IsNumTerm (Term t)
{
return (int) ((IsIntTerm (t) || IsLargeNumTerm (t)));
}
inline EXTERN Int IsAtomicTerm (Term);
inline EXTERN Int
IsAtomicTerm (Term t)
{
return (Int) (IsAtomOrIntTerm (t) || IsLargeNumTerm (t));
}
inline EXTERN Int IsExtensionFunctor (Functor);
inline EXTERN Int
IsExtensionFunctor (Functor f)
{
return (Int) (f <= FunctorDouble);
}
inline EXTERN Int IsBlobFunctor (Functor);
inline EXTERN Int
IsBlobFunctor (Functor f)
{
return (Int) ((f <= FunctorDouble && f >= FunctorDBRef));
}
inline EXTERN Int IsPrimitiveTerm (Term);
inline EXTERN Int
IsPrimitiveTerm (Term t)
{
return (Int) ((IsAtomOrIntTerm (t)
|| (IsApplTerm (t) && IsBlobFunctor (FunctorOfTerm (t)))));
}
#ifdef TERM_EXTENSIONS
inline EXTERN Int IsAttachFunc (Functor);
inline EXTERN Int
IsAttachFunc (Functor f)
{
return (Int) (FALSE);
}
inline EXTERN Int IsAttachedTerm (Term);
inline EXTERN Int
IsAttachedTerm (Term t)
{
return (Int) ((IsVarTerm (t) && IsAttVar(VarOfTerm(t))));
}
inline EXTERN Int GlobalIsAttachedTerm (Term);
inline EXTERN Int
GlobalIsAttachedTerm (Term t)
{
return (Int) ((IsVarTerm (t) && GlobalIsAttVar(VarOfTerm(t))));
}
inline EXTERN Int SafeIsAttachedTerm (Term);
inline EXTERN Int
SafeIsAttachedTerm (Term t)
{
return (Int) (IsVarTerm (t) && IsAttVar(VarOfTerm(t)));
}
inline EXTERN exts ExtFromCell (CELL *);
inline EXTERN exts
ExtFromCell (CELL * pt)
{
return attvars_ext;
}
#else
inline EXTERN Int IsAttachFunc (Functor);
inline EXTERN Int
IsAttachFunc (Functor f)
{
return (Int) (FALSE);
}
inline EXTERN Int IsAttachedTerm (Term);
inline EXTERN Int
IsAttachedTerm (Term t)
{
return (Int) (FALSE);
}
#endif
inline EXTERN Int Yap_BlobTag(Term t);
inline EXTERN Int Yap_BlobTag(Term t)
{
CELL *pt = RepAppl(t);
return pt[1];
}
inline EXTERN void *Yap_BlobInfo(Term t);
inline EXTERN void *Yap_BlobInfo(Term t)
{
MP_INT *blobp;
CELL *pt = RepAppl(t);
blobp = (MP_INT *)(pt+2);
return (void *)(blobp+1);
}
#ifdef YAP_H
inline EXTERN int STD_PROTO (unify_extension, (Functor, CELL, CELL *, CELL));
EXTERN int STD_PROTO (unify_extension, (Functor, CELL, CELL *, CELL));
int STD_PROTO(Yap_gmp_tcmp_big_big,(Term, Term));
inline EXTERN int
unify_extension (Functor f, CELL d0, CELL * pt0, CELL d1)
{
switch (BlobOfFunctor (f))
{
case db_ref_e:
return (d0 == d1);
case attvar_e:
return (d0 == d1);
case long_int_e:
return (pt0[1] == RepAppl (d1)[1]);
case big_int_e:
#ifdef USE_GMP
return (Yap_gmp_tcmp_big_big(d0,d1) == 0);
#else
return d0 == d1;
#endif /* USE_GMP */
case double_e:
{
CELL *pt1 = RepAppl (d1);
return (pt0[1] == pt1[1]
#if SIZEOF_DOUBLE == 2*SIZEOF_LONG_INT
&& pt0[2] == pt1[2]
#endif
);
}
}
return (FALSE);
}
static inline
CELL Yap_IntP_key(CELL *pt)
{
#ifdef USE_GMP
if (((Functor)pt[-1] == FunctorBigInt)) {
MP_INT *b1 = Yap_BigIntOfTerm(AbsAppl(pt-1));
/* first cell in program */
CELL val = ((CELL *)(b1+1))[0];
return MkIntTerm(val & (MAX_ABS_INT-1));
}
#endif
return MkIntTerm(pt[0] & (MAX_ABS_INT-1));
}
static inline
CELL Yap_Int_key(Term t)
{
return Yap_IntP_key(RepAppl(t)+1);
}
static inline
CELL Yap_DoubleP_key(CELL *pt)
{
#if SIZEOF_DOUBLE == 2*SIZEOF_LONG_INT
CELL val = pt[0]^pt[1];
#else
CELL val = pt[0];
#endif
return MkIntTerm(val & (MAX_ABS_INT-1));
}
static inline
CELL Yap_Double_key(Term t)
{
return Yap_DoubleP_key(RepAppl(t)+1);
}
#endif