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yap-6.3/H/Yatom.h
Vitor Santos Costa 45439b8b86 fix backcall
2018-10-17 16:51:29 +01:00

1549 lines
48 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: YAtom.h.m4 *
* Last rev: 19/2/88 *
* mods: *
* comments: atom properties header file for YAP *
* *
*************************************************************************/
/* This code can only be defined *after* including Regs.h!!! */
#ifndef YATOM_H
#define YATOM_H 1
INLINE_ONLY Atom AbsAtom(AtomEntry *p);
INLINE_ONLY AtomEntry *RepAtom(Atom a);
#ifdef USE_OFFSETS
INLINE_ONLY Atom AbsAtom(AtomEntry *p) { return (Atom)(Addr(p) - AtomBase); }
INLINE_ONLY AtomEntry *RepAtom(Atom a) {
return (AtomEntry *) (AtomBase + Unsigned (a);
}
#else
INLINE_ONLY Atom AbsAtom(AtomEntry *p) { return (Atom)(p); }
INLINE_ONLY AtomEntry *RepAtom(Atom a) { return (AtomEntry *)(a); }
#endif
#if USE_OFFSETS_IN_PROPS
INLINE_ONLY Prop AbsProp(PropEntry *p);
INLINE_ONLY Prop AbsProp(PropEntry *p) { return (Prop)(Addr(p) - AtomBase); }
INLINE_ONLY PropEntry *RepProp(Prop p);
INLINE_ONLY PropEntry *RepProp(Prop p) {
return (PropEntry *)(AtomBase + Unsigned(p));
}
#else
INLINE_ONLY Prop AbsProp(PropEntry *p);
INLINE_ONLY Prop AbsProp(PropEntry *p) { return (Prop)(p); }
INLINE_ONLY PropEntry *RepProp(Prop p);
INLINE_ONLY PropEntry *RepProp(Prop p) { return (PropEntry *)(p); }
#endif
#if USE_OFFSETS_IN_PROPS
INLINE_ONLY FunctorEntry *RepFunctorProp(Prop p);
INLINE_ONLY FunctorEntry *RepFunctorProp(Prop p) {
return (FunctorEntry *)(AtomBase + Unsigned(p));
}
INLINE_ONLY Prop AbsFunctorProp(FunctorEntry *p);
INLINE_ONLY Prop AbsFunctorProp(FunctorEntry *p) {
return (Prop)(Addr(p) - AtomBase);
}
#else
INLINE_ONLY FunctorEntry *RepFunctorProp(Prop p);
INLINE_ONLY FunctorEntry *RepFunctorProp(Prop p) { return (FunctorEntry *)(p); }
INLINE_ONLY Prop AbsFunctorProp(FunctorEntry *p);
INLINE_ONLY Prop AbsFunctorProp(FunctorEntry *p) { return (Prop)(p); }
#endif
INLINE_ONLY arity_t ArityOfFunctor(Functor);
INLINE_ONLY arity_t ArityOfFunctor(Functor Fun) {
return (arity_t)(((FunctorEntry *)Fun)->ArityOfFE);
}
INLINE_ONLY Atom NameOfFunctor(Functor);
INLINE_ONLY Atom NameOfFunctor(Functor Fun) {
return (Atom)(((FunctorEntry *)Fun)->NameOfFE);
}
INLINE_ONLY PropFlags IsFunctorProperty(int);
INLINE_ONLY PropFlags IsFunctorProperty(int flags) {
return (PropFlags)((flags == FunctorProperty));
}
/* summary of property codes used
00 00 predicate entry
80 00 db property
bb 00 functor entry
ff df sparse functor
ff ex arithmetic property
ff f4 translation
ff f5 blob
ff f6 hold
ff f7 array
ff f8 wide atom
ff fa module property
ff fb blackboard property
ff fc value property
ff fd global property
ff fe flag property
ff ff op property
*/
/* Global Variable property */
typedef struct global_entry {
Prop NextOfPE; /* used to chain properties */
PropFlags KindOfPE; /* kind of property */
#if defined(YAPOR) || defined(THREADS)
rwlock_t GRWLock; /* a simple lock to protect this entry */
#if THREADS
unsigned int owner_id; /* owner thread */
#endif
#endif
struct AtomEntryStruct *AtomOfGE; /* parent atom for deletion */
struct global_entry *NextGE; /* linked list of global entries */
Term global; /* index in module table */
Term AttChain; /* index in module table */
} GlobalEntry;
#if USE_OFFSETS_IN_PROPS
INLINE_ONLY GlobalEntry *RepGlobalProp(Prop p);
INLINE_ONLY GlobalEntry *RepGlobalProp(Prop p) {
return (GlobalEntry *)(AtomBase + Unsigned(p));
}
INLINE_ONLY Prop AbsGlobalProp(GlobalEntry *p);
INLINE_ONLY Prop AbsGlobalProp(GlobalEntry *p) {
return (Prop)(Addr(p) - AtomBase);
}
#else
INLINE_ONLY GlobalEntry *RepGlobalProp(Prop p);
INLINE_ONLY GlobalEntry *RepGlobalProp(Prop p) { return (GlobalEntry *)(p); }
INLINE_ONLY Prop AbsGlobalProp(GlobalEntry *p);
INLINE_ONLY Prop AbsGlobalProp(GlobalEntry *p) { return (Prop)(p); }
#endif
#define GlobalProperty ((PropFlags)0xfffd)
INLINE_ONLY PropFlags IsGlobalProperty(int);
INLINE_ONLY PropFlags IsGlobalProperty(int flags) {
return (PropFlags)((flags == GlobalProperty));
}
/** Module property: low-level data used to manage modes.
Includes lists of pedicates, operators and other well-defIned
properties.
*/
typedef struct mod_entry {
Prop NextOfPE; /** chain of atom properties */
PropFlags KindOfPE; /** kind of property */
struct pred_entry *PredForME; /** index in module table */
struct operator_entry *OpForME; /** index in operator table */
Atom AtomOfME; /** module's name */
Atom OwnerFile; /** module's owner file */
#if defined(YAPOR) || defined(THREADS)
rwlock_t ModRWLock; /** a read-write lock to protect the entry */
#endif
unsigned int flags; /** Module local flags (from SWI compat) */
struct mod_entry *NextME; /** next module */
} ModEntry;
#if USE_OFFSETS_IN_PROPS
INLINE_ONLY ModEntry *RepModProp(Prop p);
INLINE_ONLY ModEntry *RepModProp(Prop p) {
return (ModEntry *)(AtomBase + Unsigned(p));
}
INLINE_ONLY Prop AbsModProp(ModEntry *p);
INLINE_ONLY Prop AbsModProp(ModEntry *p) { return (Prop)(Addr(p) - AtomBase); }
#else
INLINE_ONLY ModEntry *RepModProp(Prop p);
INLINE_ONLY ModEntry *RepModProp(Prop p) { return (ModEntry *)(p); }
INLINE_ONLY Prop AbsModProp(ModEntry *p);
INLINE_ONLY Prop AbsModProp(ModEntry *p) { return (Prop)(p); }
#define ModToTerm(m) (m == PROLOG_MODULE ? TermProlog : m)
#endif
#define ModProperty ((PropFlags)0xfffa)
INLINE_ONLY bool IsModProperty(int);
INLINE_ONLY bool IsModProperty(int flags) { return flags == ModProperty; }
/* Flags on module. Most of these flags are copied to the read context
in pl-read.c.
*/
#define M_SYSTEM (0x0001) /* system module */
#define M_CHARESCAPE (0x0002) /* module */
#define DBLQ_CHARS (0x0004) /* "ab" --> ['a', 'b'] */
#define DBLQ_ATOM (0x0008) /* "ab" --> 'ab' */
#define DBLQ_STRING (0x0010) /* "ab" --> "ab" */
#define DBLQ_CODES (0x0020) /* "ab" --> [0'a, 0'b] */
#define DBLQ_MASK (DBLQ_CHARS | DBLQ_ATOM | DBLQ_STRING | DBLQ_CODES)
#define BCKQ_CHARS (0x0040) /* `ab` --> ['a', 'b'] */
#define BCKQ_ATOM (0x0080) /* `ab` --> 'ab' */
#define BCKQ_STRING (0x0100) /* `ab` --> "ab" */
#define BCKQ_CODES (0x0200) /* `ab` --> [0'a, 0'b] */
#define BCKQ_MASK (BCKQ_CHARS | BCKQ_ATOM | BCKQ_STRING | BCKQ_CODES)
#define UNKNOWN_FAIL (0x0400) /* module */
#define UNKNOWN_WARNING (0x0800) /* module */
#define UNKNOWN_ERROR (0x1000) /* module */
#define UNKNOWN_FAST_FAIL (0x2000) /* module */
#define UNKNOWN_ABORT (0x4000) /* module */
#define UNKNOWN_HALT (0x8000) /* module */
#define UNKNOWN_MASK \
(UNKNOWN_ERROR | UNKNOWN_WARNING | UNKNOWN_FAIL | UNKNOWN_FAST_FAIL | \
UNKNOWN_ABORT | UNKNOWN_HALT)
#define SNGQ_CHARS (0x10000) /* 'ab' --> [a, b] */
#define SNGQ_ATOM (0x20000) /* 'ab' --> ab */
#define SNGQ_STRING (0x40000) /* 'ab' --> "ab" */
#define SNGQ_CODES (0x80000) /* 'ab' --> [0'a, 0'b] */
#define SNGQ_MASK (BCKQ_CHARS | BCKQ_ATOM | BCKQ_STRING | BCKQ_CODES)
Term Yap_getUnknownModule(ModEntry *m);
void Yap_setModuleFlags(ModEntry *n, ModEntry *o);
/* operator property entry structure */
typedef struct operator_entry {
Prop NextOfPE; /* used to chain properties */
PropFlags KindOfPE; /* kind of property */
#if defined(YAPOR) || defined(THREADS)
rwlock_t OpRWLock; /* a read-write lock to protect the entry */
#endif
Atom OpName; /* atom name */
Term OpModule; /* module of predicate */
struct operator_entry *OpNext; /* next in list of operators */
struct operator_entry *NextForME; /* next in list of module operators */
BITS16 Prefix, Infix, Posfix; /**o precedences */
} OpEntry;
#if USE_OFFSETS_IN_PROPS
INLINE_ONLY OpEntry *RepOpProp(Prop p);
INLINE_ONLY OpEntry *RepOpProp(Prop p) {
return (OpEntry *)(AtomBase + Unsigned(p));
}
INLINE_ONLY Prop AbsOpProp(OpEntry *p);
INLINE_ONLY Prop AbsOpProp(OpEntry *p) { return (Prop)(Addr(p) - AtomBase); }
#else
INLINE_ONLY OpEntry *RepOpProp(Prop p);
INLINE_ONLY OpEntry *RepOpProp(Prop p) { return (OpEntry *)(p); }
INLINE_ONLY Prop AbsOpProp(OpEntry *p);
INLINE_ONLY Prop AbsOpProp(OpEntry *p) { return (Prop)(p); }
#endif
#define OpProperty ((PropFlags)0xffff)
INLINE_ONLY bool IsOpProperty(PropFlags);
INLINE_ONLY bool IsOpProperty(PropFlags flags) { return flags == OpProperty; }
typedef enum { INFIX_OP = 0, POSFIX_OP = 1, PREFIX_OP = 2 } op_type;
OpEntry *Yap_GetOpProp(Atom, op_type, Term CACHE_TYPE);
int Yap_IsPrefixOp(Atom, int *, int *);
int Yap_IsOp(Atom);
int Yap_IsInfixOp(Atom, int *, int *, int *);
int Yap_IsPosfixOp(Atom, int *, int *);
bool Yap_dup_op(OpEntry *op, ModEntry *she);
/* defines related to operator specifications */
#define MaskPrio 0x0fff
#define DcrlpFlag 0x1000
#define DcrrpFlag 0x2000
typedef union arith_ret *eval_ret;
/* expression property entry structure */
typedef struct {
Prop NextOfPE; /* used to chain properties */
PropFlags KindOfPE; /* kind of property */
unsigned int ArityOfEE;
BITS16 ENoOfEE;
BITS16 FlagsOfEE;
/* operations that implement the expression */
int FOfEE;
} ExpEntry;
#if USE_OFFSETS_IN_PROPS
INLINE_ONLY ExpEntry *RepExpProp(Prop p);
INLINE_ONLY ExpEntry *RepExpProp(Prop p) {
return (ExpEntry *)(AtomBase + Unsigned(p));
}
INLINE_ONLY Prop AbsExpProp(ExpEntry *p);
INLINE_ONLY Prop AbsExpProp(ExpEntry *p) { return (Prop)(Addr(p) - AtomBase); }
#else
INLINE_ONLY ExpEntry *RepExpProp(Prop p);
INLINE_ONLY ExpEntry *RepExpProp(Prop p) { return (ExpEntry *)(p); }
INLINE_ONLY Prop AbsExpProp(ExpEntry *p);
INLINE_ONLY Prop AbsExpProp(ExpEntry *p) { return (Prop)(p); }
#endif
#define ExpProperty 0xffe0
/* only unary and binary expressions are acceptable */
INLINE_ONLY PropFlags IsExpProperty(int);
INLINE_ONLY PropFlags IsExpProperty(int flags) {
return (PropFlags)((flags == ExpProperty));
}
/* value property entry structure */
typedef struct {
Prop NextOfPE; /* used to chain properties */
PropFlags KindOfPE; /* kind of property */
#if defined(YAPOR) || defined(THREADS)
rwlock_t VRWLock; /* a read-write lock to protect the entry */
#endif
Term ValueOfVE; /* (atomic) value associated with the atom */
} ValEntry;
#if USE_OFFSETS_IN_PROPS
INLINE_ONLY ValEntry *RepValProp(Prop p);
INLINE_ONLY ValEntry *RepValProp(Prop p) {
return (ValEntry *)(AtomBase + Unsigned(p));
}
INLINE_ONLY Prop AbsValProp(ValEntry *p);
INLINE_ONLY Prop AbsValProp(ValEntry *p) { return (Prop)(Addr(p) - AtomBase); }
#else
INLINE_ONLY ValEntry *RepValProp(Prop p);
INLINE_ONLY ValEntry *RepValProp(Prop p) { return (ValEntry *)(p); }
INLINE_ONLY Prop AbsValProp(ValEntry *p);
INLINE_ONLY Prop AbsValProp(ValEntry *p) { return (Prop)(p); }
#endif
#define ValProperty ((PropFlags)0xfffc)
/* predicate property entry structure */
/* AsmPreds are things like var, nonvar, atom ...which are implemented
through dedicated machine instructions. In this case the 8 lower
bits of PredFlags are used to hold the machine instruction code
for the pred.
C_Preds are things write, read, ... implemented in C. In this case
CodeOfPred holds the address of the correspondent C-function.
don't forget to also add in qly.h
*/
/// Different predicate flags
typedef uint64_t pred_flags_t;
#define UndefPredFlag \
((pred_flags_t)0x4000000000) //< Predicate not explicitely defined.
#define ProfiledPredFlag ((pred_flags_t)0x2000000000) //< pred is being profiled
#define DiscontiguousPredFlag \
((pred_flags_t)0x1000000000) //< predicates whose clauses may be all-over the
// place..
#define SysExportPredFlag \
((pred_flags_t)0x800000000) //< reuse export list to prolog module.
#define NoTracePredFlag \
((pred_flags_t)0x400000000) //< cannot trace this predicate
#define NoSpyPredFlag ((pred_flags_t)0x200000000) //< cannot spy this predicate
#define QuasiQuotationPredFlag \
((pred_flags_t)0x100000000) //< SWI-like quasi quotations
#define MegaClausePredFlag \
((pred_flags_t)0x80000000) //< predicate is implemented as a mega-clause
#define ThreadLocalPredFlag ((pred_flags_t)0x40000000) //< local to a thread
#define MultiFileFlag ((pred_flags_t)0x20000000) //< is multi-file
#define UserCPredFlag ((pred_flags_t)0x10000000) //< CPred defined by the user
#define LogUpdatePredFlag \
((pred_flags_t)0x08000000) //< dynamic predicate with log. upd. sem.
#define InUsePredFlag ((pred_flags_t)0x04000000) //< count calls to pred
#define CountPredFlag ((pred_flags_t)0x02000000) //< count calls to pred
#define HiddenPredFlag ((pred_flags_t)0x01000000) //< invisible predicate
#define CArgsPredFlag ((pred_flags_t)0x00800000) //< SWI-like C-interface pred.
#define SourcePredFlag \
((pred_flags_t)0x00400000) //< static predicate with source declaration
#define MetaPredFlag \
((pred_flags_t)0x00200000) //< predicate subject to a meta declaration
#define SyncPredFlag \
((pred_flags_t)0x00100000) //< has to synch before it can execute
#define NumberDBPredFlag ((pred_flags_t)0x00080000) //< entry for an atom key
#define AtomDBPredFlag ((pred_flags_t)0x00040000) //< entry for a number key
// #define GoalExPredFlag ((pred_flags_t)0x00020000) /// predicate that is
// called by goal_expand
#define TestPredFlag ((pred_flags_t)0x00010000) //< is a test (optim. comit)
#define AsmPredFlag ((pred_flags_t)0x00008000) //< inline
#define StandardPredFlag ((pred_flags_t)0x00004000) //< system predicate
#define DynamicPredFlag ((pred_flags_t)0x00002000) //< dynamic predicate
#define CPredFlag ((pred_flags_t)0x00001000) //< written in C
#define SafePredFlag ((pred_flags_t)0x00000800) //< does not alter arguments
#define CompiledPredFlag ((pred_flags_t)0x00000400) //< is static
#define IndexedPredFlag ((pred_flags_t)0x00000200) //< has indexing code
#define SpiedPredFlag ((pred_flags_t)0x00000100) //< is a spy point
#define BinaryPredFlag ((pred_flags_t)0x00000080) //< test predicate
#define TabledPredFlag ((pred_flags_t)0x00000040) //< is tabled
#define SequentialPredFlag \
((pred_flags_t)0x00000020) //< may not create parallel choice points!
#define BackCPredFlag ((pred_flags_t)0x00000008) //< Myddas Imported pred
#define ModuleTransparentPredFlag ((pred_flags_t)0x00000004)
#define SWIEnvPredFlag ((pred_flags_t)0x00000002) //< new SWI interface
#define UDIPredFlag ((pred_flags_t)0x00000001) //< User Defined Indexing
#define SystemPredFlags \
(AsmPredFlag | StandardPredFlag | CPredFlag | BinaryPredFlag | BackCPredFlag)
#define ForeignPredFlags \
(AsmPredFlag | SWIEnvPredFlag | CPredFlag | BinaryPredFlag | UDIPredFlag | \
CArgsPredFlag | UserCPredFlag | SafePredFlag | BackCPredFlag)
#define LivePredFlags \
(LogUpdatePredFlag | MultiFileFlag | TabledPredFlag | ForeignPredFlags)
#define StatePredFlags \
(InUsePredFlag | CountPredFlag | SpiedPredFlag | IndexedPredFlag)
#define is_system(pe) (pe->PredFlags & SystemPredFlags)
#define is_dynamic(pe) (pe->PredFlags & DynamicPredFlag)
#define is_foreign(pe) (pe->PredFlags & ForeignPredFlags)
#define is_static(pe) (pe->PredFlags & CompiledPredFlag)
#define is_logupd(pe) (pe->PredFlags & LogUpdatePredFlag)
#define is_live(pe) (pe->PredFlags & LivePredFlags)
#ifdef TABLING
#define is_tabled(pe) (pe->PredFlags & TabledPredFlag)
#endif /* TABLING */
/* profile data */
typedef struct {
UInt NOfEntries; /* nbr of times head unification succeeded */
UInt NOfHeadSuccesses; /* nbr of times head unification succeeded */
UInt NOfRetries; /* nbr of times a clause for the pred
was retried */
#if defined(YAPOR) || defined(THREADS)
lockvar lock; /* a simple lock to protect this entry */
#endif
} profile_data;
typedef enum { LUCALL_EXEC, LUCALL_ASSERT, LUCALL_RETRACT } timestamp_type;
#define TIMESTAMP_EOT ((UInt)(~0L))
#define TIMESTAMP_RESET (TIMESTAMP_EOT - 1024)
typedef struct pred_entry {
Prop NextOfPE; /* used to chain properties */
PropFlags KindOfPE; /* kind of property */
struct yami *CodeOfPred;
OPCODE OpcodeOfPred; /* undefcode, indexcode, spycode, .... */
pred_flags_t PredFlags;
UInt ArityOfPE; /* arity of property */
union {
struct {
struct yami *TrueCodeOfPred; /* code address */
struct yami *FirstClause;
struct yami *LastClause;
UInt NOfClauses;
OPCODE ExpandCode;
} p_code;
CPredicate f_code;
CmpPredicate d_code;
} cs; /* if needing to spy or to lock */
Functor FunctorOfPred; /* functor for Predicate */
union {
Atom OwnerFile; /* File where the predicate was defined */
Int IndxId; /* Index for a certain key */
} src;
#if defined(YAPOR) || defined(THREADS)
lockvar PELock; /* a simple lock to protect expansion */
#endif
#ifdef TABLING
tab_ent_ptr TableOfPred;
#endif /* TABLING */
#ifdef BEAM
struct Predicates *beamTable;
#endif
struct yami *MetaEntryOfPred; /* allow direct access from meta-calls */
Term ModuleOfPred; /* module for this definition */
UInt TimeStampOfPred;
timestamp_type LastCallOfPred;
/* This must be at an odd number of cells, otherwise it
will not be aligned on RISC machines */
profile_data *StatisticsForPred; /* enable profiling for predicate */
struct pred_entry *NextPredOfModule; /* next pred for same module */
struct pred_entry *NextPredOfHash; /* next pred for same module */
} PredEntry;
#define PEProp ((PropFlags)(0x0000))
#if USE_OFFSETS_IN_PROPS
INLINE_ONLY PredEntry *RepPredProp(Prop p);
INLINE_ONLY PredEntry *RepPredProp(Prop p) {
return (PredEntry *)(AtomBase + Unsigned(p));
}
INLINE_ONLY Prop AbsPredProp(PredEntry *p);
INLINE_ONLY Prop AbsPredProp(PredEntry *p) {
return (Prop)(Addr(p) - AtomBase);
}
#else
INLINE_ONLY PredEntry *RepPredProp(Prop p);
INLINE_ONLY PredEntry *RepPredProp(Prop p) { return (PredEntry *)(p); }
INLINE_ONLY Prop AbsPredProp(PredEntry *p);
INLINE_ONLY Prop AbsPredProp(PredEntry *p) { return (Prop)(p); }
#endif
INLINE_ONLY PropFlags IsPredProperty(int);
INLINE_ONLY PropFlags IsPredProperty(int flags) {
return (PropFlags)((flags == PEProp));
}
INLINE_ONLY Atom NameOfPred(PredEntry *pe);
INLINE_ONLY Atom NameOfPred(PredEntry *pe) {
if (pe->ModuleOfPred == IDB_MODULE) {
return NULL;
} else if (pe->ArityOfPE == 0) {
return (Atom)pe->FunctorOfPred;
} else {
Functor f = pe->FunctorOfPred;
return NameOfFunctor(f);
}
}
extern const char *IndicatorOfPred(PredEntry *pe);
extern PredEntry *Yap_get_pred(Term t, Term tmod, const char *pname);
profile_data *Yap_initProfiler(PredEntry *p);
/* Flags for code or dbase entry */
/* There are several flags for code and data base entries */
typedef enum {
ExoMask = 0x1000000, /* is exo code */
FuncSwitchMask = 0x800000, /* is a switch of functors */
HasDBTMask = 0x400000, /* includes a pointer to a DBTerm */
MegaMask = 0x200000, /* mega clause */
FactMask = 0x100000, /* a fact */
SwitchRootMask = 0x80000, /* root for the index tree */
SwitchTableMask = 0x40000, /* switch table */
HasBlobsMask = 0x20000, /* blobs which may be in use */
ProfFoundMask = 0x10000, /* clause is being counted by profiler */
DynamicMask = 0x8000, /* dynamic predicate */
InUseMask = 0x4000, /* this block is being used */
ErasedMask = 0x2000, /* this block has been erased */
IndexMask = 0x1000, /* indexing code */
DBClMask = 0x0800, /* data base structure */
LogUpdRuleMask = 0x0400, /* code is for a log upd rule with env */
LogUpdMask = 0x0200, /* logic update index. */
StaticMask = 0x0100, /* static predicates */
DirtyMask = 0x0080, /* LUIndices */
HasCutMask = 0x0040, /* ! */
SrcMask = 0x0020, /* has a source term, only for static references */
/* other flags belong to DB */
} dbentry_flags;
/* predicate initialization */
void Yap_InitCPred(const char *name, arity_t arity, CPredicate f,
pred_flags_t flags);
void Yap_InitAsmPred(const char *name, arity_t arity, int code, CPredicate asmc,
pred_flags_t flags);
void Yap_InitCmpPred(const char *name, arity_t arity, CmpPredicate cmp,
pred_flags_t flags);
void Yap_InitCPredBack(const char *name, arity_t arity, arity_t extra,
CPredicate call, CPredicate retry, pred_flags_t flags);
void Yap_InitCPredBackCut(const char *name, arity_t arity, arity_t extra,
CPredicate call, CPredicate retry, CPredicate cut,
pred_flags_t flags);
void Yap_InitCPredBack_(const char *name, arity_t arity, arity_t extra,
CPredicate call, CPredicate retry, CPredicate cut,
pred_flags_t flags);
/* *********************** DBrefs **************************************/
typedef struct DB_TERM {
#ifdef COROUTINING
union {
CELL attachments; /* attached terms */
Int line_number;
struct DB_TERM *NextDBT;
} ag;
#endif
struct DB_STRUCT **DBRefs; /* pointer to other references */
CELL NOfCells; /* Size of Term */
CELL Entry; /* entry point */
Term Contents[MIN_ARRAY]; /* stored term */
} DBTerm;
INLINE_ONLY DBTerm *TermToDBTerm(Term);
INLINE_ONLY DBTerm *TermToDBTerm(Term X) {
if (IsPairTerm(X)) {
return (DBTerm *)((unsigned char *)RepPair(X) - (CELL) &
(((DBTerm *)NULL)->Contents));
} else {
return (DBTerm *)((unsigned char *)RepAppl(X) - (CELL) &
(((DBTerm *)NULL)->Contents));
}
}
/* The ordering of the first 3 fields should be compatible with lu_clauses */
typedef struct DB_STRUCT {
Functor id; /* allow pointers to this struct to id */
/* as dbref */
CELL Flags; /* Term Flags */
#if defined(YAPOR) || defined(THREADS)
lockvar lock; /* a simple lock to protect this entry */
#endif
#if MULTIPLE_STACKS
Int ref_count; /* how many branches are using this entry */
#endif
CELL NOfRefsTo; /* Number of references pointing here */
struct struct_dbentry *Parent; /* key of DBase reference */
struct yami *Code; /* pointer to code if this is a clause */
struct DB_STRUCT *Prev; /* Previous element in chain */
struct DB_STRUCT *Next; /* Next element in chain */
struct DB_STRUCT *p, *n; /* entry's age, negative if from recorda,
positive if it was recordz */
CELL Mask; /* parts that should be cleared */
CELL Key; /* A mask that can be used to check before
you unify */
DBTerm DBT;
} DBStruct;
#define DBStructFlagsToDBStruct(X) \
((DBRef)((unsigned char *)(X) - (CELL) & (((DBRef)NULL)->Flags)))
#if MULTIPLE_STACKS
#define INIT_DBREF_COUNT(X) (X)->ref_count = 0
#define INC_DBREF_COUNT(X) (X)->ref_count++
#define DEC_DBREF_COUNT(X) (X)->ref_count--
#define DBREF_IN_USE(X) ((X)->ref_count != 0)
#else
#define INIT_DBREF_COUNT(X)
#define INC_DBREF_COUNT(X)
#define DEC_DBREF_COUNT(X)
#define DBREF_IN_USE(X) ((X)->Flags & InUseMask)
#endif
typedef DBStruct *DBRef;
/* extern Functor FunctorDBRef; */
INLINE_ONLY int IsDBRefTerm(Term);
INLINE_ONLY int IsDBRefTerm(Term t) {
return (int)(IsApplTerm(t) && FunctorOfTerm(t) == FunctorDBRef);
}
INLINE_ONLY Term MkDBRefTerm(DBRef);
INLINE_ONLY Term MkDBRefTerm(DBRef p) {
return (Term)((AbsAppl(((CELL *)(p)))));
}
INLINE_ONLY DBRef DBRefOfTerm(Term t);
INLINE_ONLY DBRef DBRefOfTerm(Term t) { return (DBRef)(((DBRef)(RepAppl(t)))); }
INLINE_ONLY int IsRefTerm(Term);
INLINE_ONLY int IsRefTerm(Term t) {
return (int)(IsApplTerm(t) && FunctorOfTerm(t) == FunctorDBRef);
}
INLINE_ONLY CODEADDR RefOfTerm(Term t);
INLINE_ONLY CODEADDR RefOfTerm(Term t) { return (CODEADDR)(DBRefOfTerm(t)); }
typedef struct struct_dbentry {
Prop NextOfPE; /* used to chain properties */
PropFlags KindOfPE; /* kind of property */
unsigned int ArityOfDB; /* kind of property */
Functor FunctorOfDB; /* functor for this property */
#if defined(YAPOR) || defined(THREADS)
rwlock_t DBRWLock; /* a simple lock to protect this entry */
#endif
DBRef First; /* first DBase entry */
DBRef Last; /* last DBase entry */
Term ModuleOfDB; /* module for this definition */
DBRef F0, L0; /* everyone */
} DBEntry;
typedef DBEntry *DBProp;
#define DBProperty ((PropFlags)0x8000)
typedef struct {
Prop NextOfPE; /* used to chain properties */
PropFlags KindOfPE; /* kind of property */
unsigned int ArityOfDB; /* kind of property */
Functor FunctorOfDB; /* functor for this property */
#if defined(YAPOR) || defined(THREADS)
rwlock_t DBRWLock; /* a simple lock to protect this entry */
#endif
DBRef First; /* first DBase entry */
DBRef Last; /* last DBase entry */
Term ModuleOfDB; /* module for this definition */
Int NOfEntries; /* age counter */
DBRef Index; /* age counter */
} LogUpdDBEntry;
typedef LogUpdDBEntry *LogUpdDBProp;
#define CodeDBBit 0x2
#define CodeDBProperty (DBProperty | CodeDBBit)
INLINE_ONLY PropFlags IsDBProperty(int);
INLINE_ONLY PropFlags IsDBProperty(int flags) {
return (PropFlags)((flags & ~CodeDBBit) == DBProperty);
}
#if USE_OFFSETS_IN_PROPS
INLINE_ONLY DBProp RepDBProp(Prop p);
INLINE_ONLY DBProp RepDBProp(Prop p) {
return (DBProp)(AtomBase + Unsigned(p));
}
INLINE_ONLY Prop AbsDBProp(DBProp p);
INLINE_ONLY Prop AbsDBProp(DBProp p) { return (Prop)(Addr(p) - AtomBase); }
#else
INLINE_ONLY DBProp RepDBProp(Prop p);
INLINE_ONLY DBProp RepDBProp(Prop p) { return (DBProp)(p); }
INLINE_ONLY Prop AbsDBProp(DBProp p);
INLINE_ONLY Prop AbsDBProp(DBProp p) { return (Prop)(p); }
#endif
/* These are the actual flags for DataBase terms */
typedef enum {
DBAtomic = 0x1,
DBVar = 0x2,
DBNoVars = 0x4,
DBComplex = 0x8,
DBCode = 0x10,
DBNoCode = 0x20,
DBWithRefs = 0x40
} db_term_flags;
typedef struct {
Prop NextOfPE; /* used to chain properties */
PropFlags KindOfPE; /* kind of property */
Atom KeyOfBB; /* functor for this property */
Term Element; /* blackboard element */
#if defined(YAPOR) || defined(THREADS)
rwlock_t BBRWLock; /* a read-write lock to protect the entry */
#endif
Term ModuleOfBB; /* module for this definition */
} BlackBoardEntry;
typedef BlackBoardEntry *BBProp;
#if USE_OFFSETS_IN_PROPS
INLINE_ONLY BlackBoardEntry *RepBBProp(Prop p);
INLINE_ONLY BlackBoardEntry *RepBBProp(Prop p) {
return (BlackBoardEntry *)(AtomBase + Unsigned(p));
}
INLINE_ONLY Prop AbsBBProp(BlackBoardEntry *p);
INLINE_ONLY Prop AbsBBProp(BlackBoardEntry *p) {
return (Prop)(Addr(p) - AtomBase);
}
#else
INLINE_ONLY BlackBoardEntry *RepBBProp(Prop p);
INLINE_ONLY BlackBoardEntry *RepBBProp(Prop p) {
return (BlackBoardEntry *)(p);
}
INLINE_ONLY Prop AbsBBProp(BlackBoardEntry *p);
INLINE_ONLY Prop AbsBBProp(BlackBoardEntry *p) { return (Prop)(p); }
#endif
#define BBProperty ((PropFlags)0xfffb)
INLINE_ONLY PropFlags IsBBProperty(int);
INLINE_ONLY PropFlags IsBBProperty(int flags) {
return (PropFlags)((flags == BBProperty));
}
/* hold property entry structure */
typedef struct hold_entry {
Prop NextOfPE; /* used to chain properties */
PropFlags KindOfPE; /* kind of property */
UInt RefsOfPE; /* used to count the number of holds */
} HoldEntry;
#if USE_OFFSETS_IN_PROPS
INLINE_ONLY HoldEntry *RepHoldProp(Prop p);
INLINE_ONLY HoldEntry *RepHoldProp(Prop p) {
return (HoldEntry *)(AtomBase + Unsigned(p));
}
INLINE_ONLY Prop AbsHoldProp(HoldEntry *p);
INLINE_ONLY Prop AbsHoldProp(HoldEntry *p) {
return (Prop)(Addr(p) - AtomBase);
}
#else
INLINE_ONLY HoldEntry *RepHoldProp(Prop p);
INLINE_ONLY HoldEntry *RepHoldProp(Prop p) { return (HoldEntry *)(p); }
INLINE_ONLY Prop AbsHoldProp(HoldEntry *p);
INLINE_ONLY Prop AbsHoldProp(HoldEntry *p) { return (Prop)(p); }
#endif
#define HoldProperty 0xfff6
/* translation property entry structure */
typedef struct translation_entry {
Prop NextOfPE; /* used to chain properties */
PropFlags KindOfPE; /* kind of property */
arity_t arity; /* refers to atom (0) or functor(N > 0) */
Int Translation; /* used to hash the atom as an integer; */
} TranslationEntry;
#if USE_OFFSETS_IN_PROPS
INLINE_ONLY TranslationEntry *RepTranslationProp(Prop p);
INLINE_ONLY TranslationEntry *RepTranslationProp(Prop p) {
return (TranslationEntry *)(AtomBase + Unsigned(p));
}
INLINE_ONLY Prop AbsTranslationProp(TranslationEntry *p);
INLINE_ONLY Prop AbsTranslationProp(TranslationEntry *p) {
return (Prop)(Addr(p) - AtomBase);
}
#else
INLINE_ONLY TranslationEntry *RepTranslationProp(Prop p);
INLINE_ONLY TranslationEntry *RepTranslationProp(Prop p) {
return (TranslationEntry *)(p);
}
INLINE_ONLY Prop AbsTranslationProp(TranslationEntry *p);
INLINE_ONLY Prop AbsTranslationProp(TranslationEntry *p) { return (Prop)(p); }
#endif
#define TranslationProperty 0xfff4
bool Yap_PutAtomTranslation(Atom a, arity_t arity, Int i);
/* get translation prop for atom; */
static inline TranslationEntry *Yap_GetTranslationProp(Atom at, arity_t arity) {
Prop p0;
AtomEntry *ae = RepAtom(at);
TranslationEntry *p;
READ_LOCK(ae->ARWLock);
p = RepTranslationProp(p0 = ae->PropsOfAE);
while (p0 && (p->KindOfPE != TranslationProperty || p->arity != arity))
p = RepTranslationProp(p0 = p->NextOfPE);
READ_UNLOCK(ae->ARWLock);
if (p0 == NIL)
return (TranslationEntry *)NULL;
p->arity = arity;
return p;
}
INLINE_ONLY bool IsTranslationProperty(PropFlags);
INLINE_ONLY bool IsTranslationProperty(PropFlags flags) {
return flags == TranslationProperty;
}
/*** handle named mutexes */
/* named mutex property entry structure */
typedef struct mutex_entry {
Prop NextOfPE; /* used to chain properties */
PropFlags KindOfPE; /* kind of property */
void *Mutex; /* used to hash the atom as an integer; */
} MutexEntry;
#if USE_OFFSETS_IN_PROPS
INLINE_ONLY MutexEntry *RepMutexProp(Prop p);
INLINE_ONLY MutexEntry *RepMutexProp(Prop p) {
return (MutexEntry *)(AtomBase + Unsigned(p));
}
INLINE_ONLY Prop AbsMutexProp(MutexEntry *p);
INLINE_ONLY Prop AbsMutexProp(MutexEntry *p) {
return (Prop)(Addr(p) - AtomBase);
}
#else
INLINE_ONLY MutexEntry *RepMutexProp(Prop p);
INLINE_ONLY MutexEntry *RepMutexProp(Prop p) { return (MutexEntry *)(p); }
INLINE_ONLY Prop AbsMutexProp(MutexEntry *p);
INLINE_ONLY Prop AbsMutexProp(MutexEntry *p) { return (Prop)(p); }
#endif
#define MutexProperty 0xfff5
bool Yap_PutAtomMutex(Atom a, void *ptr);
/* get mutex prop for atom; */
static inline void *Yap_GetMutexFromProp(Atom at) {
Prop p0;
AtomEntry *ae = RepAtom(at);
MutexEntry *p;
READ_LOCK(ae->ARWLock);
p = RepMutexProp(p0 = ae->PropsOfAE);
while (p0 && p->KindOfPE != MutexProperty)
p = RepMutexProp(p0 = p->NextOfPE);
READ_UNLOCK(ae->ARWLock);
if (p0 == NIL)
return NULL;
return p->Mutex;
}
INLINE_ONLY bool IsMutexProperty(PropFlags);
INLINE_ONLY bool IsMutexProperty(PropFlags flags) {
return (PropFlags)((flags == MutexProperty));
}
/* end of code for named mutexes */
typedef enum {
STATIC_ARRAY = 1,
DYNAMIC_ARRAY = 2,
MMAP_ARRAY = 4,
FIXED_ARRAY = 8
} array_type;
/* array property entry structure */
/* first case is for dynamic arrays */
typedef struct array_entry {
Prop NextOfPE; /* used to chain properties */
PropFlags KindOfPE; /* kind of property */
Int ArrayEArity; /* Arity of Array (positive) */
array_type TypeOfAE;
#if defined(YAPOR) || defined(THREADS)
rwlock_t ArRWLock; /* a read-write lock to protect the entry */
#if THREADS
unsigned int owner_id;
#endif
#endif
struct array_entry *NextAE;
Term ValueOfVE; /* Pointer to the actual array */
} ArrayEntry;
/* second case is for static arrays */
typedef struct {
Term tlive;
Term tstore;
} live_term;
typedef union {
Int *ints;
char *chars;
unsigned char *uchars;
Float *floats;
AtomEntry **ptrs;
Term *atoms;
Term *dbrefs;
DBTerm **terms;
live_term *lterms;
} statarray_elements;
/* next, the actual data structure */
typedef struct static_array_entry {
Prop NextOfPE; /* used to chain properties */
PropFlags KindOfPE; /* kind of property */
Int ArrayEArity; /* Arity of Array (negative) */
array_type TypeOfAE;
#if defined(YAPOR) || defined(THREADS)
rwlock_t ArRWLock; /* a read-write lock to protect the entry */
#endif
struct static_array_entry *NextAE;
static_array_types ArrayType; /* Type of Array Elements. */
statarray_elements ValueOfVE; /* Pointer to the Array itself */
} StaticArrayEntry;
#if USE_OFFSETS_IN_PROPS
INLINE_ONLY ArrayEntry *RepArrayProp(Prop p);
INLINE_ONLY ArrayEntry *RepArrayProp(Prop p) {
return (ArrayEntry *)(AtomBase + Unsigned(p));
}
INLINE_ONLY Prop AbsArrayProp(ArrayEntry *p);
INLINE_ONLY Prop AbsArrayProp(ArrayEntry *p) {
return (Prop)(Addr(p) - AtomBase);
}
INLINE_ONLY StaticArrayEntry *RepStaticArrayProp(Prop p);
INLINE_ONLY StaticArrayEntry *RepStaticArrayProp(Prop p) {
return (StaticArrayEntry *)(AtomBase + Unsigned(p));
}
INLINE_ONLY Prop AbsStaticArrayProp(StaticArrayEntry *p);
INLINE_ONLY Prop AbsStaticArrayProp(StaticArrayEntry *p) {
return (Prop)(Addr(p) - AtomBase);
}
#else
INLINE_ONLY ArrayEntry *RepArrayProp(Prop p);
INLINE_ONLY ArrayEntry *RepArrayProp(Prop p) { return (ArrayEntry *)(p); }
INLINE_ONLY Prop AbsArrayProp(ArrayEntry *p);
INLINE_ONLY Prop AbsArrayProp(ArrayEntry *p) { return (Prop)(p); }
INLINE_ONLY StaticArrayEntry *RepStaticArrayProp(Prop p);
INLINE_ONLY StaticArrayEntry *RepStaticArrayProp(Prop p) {
return (StaticArrayEntry *)(p);
}
INLINE_ONLY Prop AbsStaticArrayProp(StaticArrayEntry *p);
INLINE_ONLY Prop AbsStaticArrayProp(StaticArrayEntry *p) { return (Prop)(p); }
#endif
#define ArrayProperty ((PropFlags)0xfff7)
INLINE_ONLY bool ArrayIsDynamic(ArrayEntry *);
INLINE_ONLY bool ArrayIsDynamic(ArrayEntry *are) {
return ((are)->TypeOfAE & DYNAMIC_ARRAY) != 0;
}
INLINE_ONLY bool IsArrayProperty(PropFlags);
INLINE_ONLY bool IsArrayProperty(PropFlags flags) {
return flags == ArrayProperty;
}
/* SWI Blob property */
typedef struct YAP_blob_prop_entry {
Prop NextOfPE; /* used to chain properties */
PropFlags KindOfPE; /* kind of property */
struct _PL_blob_t *blob_type; /* type of blob */
} YAP_BlobPropEntry;
#if USE_OFFSETS_IN_PROPS
INLINE_ONLY YAP_BlobPropEntry *RepBlobProp(Prop p);
INLINE_ONLY YAP_BlobPropEntry *RepBlobProp(Prop p) {
return (YAP_BlobPropEntry *)(AtomBase + Unsigned(p));
}
INLINE_ONLY AtomEntry *AbsBlobProp(BlobPropEntry *p);
INLINE_ONLY Prop AbsBlobProp(YAP_BlobPropEntry *p) {
return (Prop)(Addr(p) - AtomBase);
}
#else
INLINE_ONLY YAP_BlobPropEntry *RepBlobProp(Prop p);
INLINE_ONLY YAP_BlobPropEntry *RepBlobProp(Prop p) {
return (YAP_BlobPropEntry *)(p);
}
INLINE_ONLY Prop AbsBlobProp(YAP_BlobPropEntry *p);
INLINE_ONLY Prop AbsBlobProp(YAP_BlobPropEntry *p) { return (Prop)(p); }
#endif
#define BlobProperty ((PropFlags)0xfffe)
INLINE_ONLY bool IsBlobProperty(PropFlags);
INLINE_ONLY bool IsBlobProperty(PropFlags flags) {
return flags == BlobProperty;
}
INLINE_ONLY bool IsBlob(Atom);
INLINE_ONLY bool IsBlob(Atom at) {
return RepAtom(at)->PropsOfAE != NIL &&
IsBlobProperty(RepBlobProp(RepAtom(at)->PropsOfAE)->KindOfPE);
}
INLINE_ONLY bool IsValProperty(PropFlags);
INLINE_ONLY bool IsValProperty(PropFlags flags) { return flags == ValProperty; }
/* flag property entry structure */
typedef Term (*flag_func)(Term);
typedef bool (*flag_helper_func)(Term);
typedef struct {
Prop NextOfPE; /* used to chain properties */
PropFlags KindOfPE; /* kind of property */
#if defined(YAPOR) || defined(THREADS)
rwlock_t VRWLock; /* a read-write lock to protect the entry */
#endif
int FlagOfVE; /* (atomic) value associated with the atom */
bool global, atomic, rw;
flag_func type;
flag_helper_func helper;
} FlagEntry;
#if USE_OFFSETS_IN_PROPS
INLINE_ONLY FlagEntry *RepFlagProp(Prop p);
INLINE_ONLY FlagEntry *RepFlagProp(Prop p) {
return (FlagEntry *)(AtomBase + Unsigned(p));
}
INLINE_ONLY Prop AbsFlagProp(FlagEntry *p);
INLINE_ONLY Prop AbsValProp(FlagEntry *p) { return (Prop)(Addr(p) - AtomBase); }
#else
INLINE_ONLY FlagEntry *RepFlagProp(Prop p);
INLINE_ONLY FlagEntry *RepFlagProp(Prop p) { return (FlagEntry *)(p); }
INLINE_ONLY Prop AbsFlagProp(FlagEntry *p);
INLINE_ONLY Prop AbsFlagProp(FlagEntry *p) { return (Prop)(p); }
#endif
#define FlagProperty ((PropFlags)0xfff9)
INLINE_ONLY bool IsFlagProperty(PropFlags);
INLINE_ONLY bool IsFlagProperty(PropFlags flags) {
return flags == FlagProperty;
}
/* Proto types */
extern char *Yap_TermToBuffer(Term t, int flags);
extern Term Yap_BufferToTerm(const char *s, Term opts);
/* cdmgr.c */
extern int Yap_RemoveIndexation(PredEntry *);
extern void Yap_UpdateTimestamps(PredEntry *);
/* dbase.c */
extern void Yap_ErDBE(DBRef);
extern DBTerm *Yap_StoreTermInDB(Term, int);
DBTerm *Yap_StoreTermInDBPlusExtraSpace(Term, UInt, UInt *);
Term Yap_FetchTermFromDB(const void *);
Term Yap_FetchClauseTermFromDB(const void *);
Term Yap_PopTermFromDB(const void *);
void Yap_ReleaseTermFromDB(const void *);
/* init.c */
Atom Yap_GetOp(OpEntry *, int *, int);
/* vsc: redefined to GetAProp to avoid conflicts with Windows header files */
Prop Yap_GetAProp(Atom, PropFlags);
Prop Yap_GetAPropHavingLock(AtomEntry *, PropFlags);
#define PROLOG_MODULE 0
#include "YapHeap.h"
#define PredHashInitialSize ((UInt)1039)
#define PredHashIncrement ((UInt)7919)
/*************************************************************************************************
flag support
*************************************************************************************************/
#include "YapFlags.h"
INLINE_ONLY UInt PRED_HASH(FunctorEntry *, Term, UInt);
INLINE_ONLY UInt PRED_HASH(FunctorEntry *fe, Term cur_mod, UInt size) {
return (((CELL)fe + cur_mod) >> 2) % size;
}
INLINE_ONLY Prop GetPredPropByFuncAndModHavingLock(FunctorEntry *, Term);
INLINE_ONLY Prop PredPropByFuncAndMod(FunctorEntry *, Term);
INLINE_ONLY Prop PredPropByAtomAndMod(Atom, Term);
INLINE_ONLY Prop GetPredPropByFuncHavingLock(FunctorEntry *, Term);
INLINE_ONLY Prop PredPropByFunc(Functor fe, Term cur_mod);
INLINE_ONLY Prop PredPropByAtom(Atom at, Term cur_mod);
#ifdef THREADS
Prop Yap_NewThreadPred(struct pred_entry *CACHE_TYPE);
Prop Yap_NewPredPropByFunctor(Functor, Term);
INLINE_ONLY struct pred_entry *Yap_GetThreadPred(struct pred_entry *CACHE_TYPE);
INLINE_ONLY struct pred_entry *
Yap_GetThreadPred(struct pred_entry *ap USES_REGS) {
Functor f = ap->FunctorOfPred;
Term mod = ap->ModuleOfPred;
Prop p0 = AbsPredProp(LOCAL_ThreadHandle.local_preds);
while (p0) {
PredEntry *ap = RepPredProp(p0);
if (ap->FunctorOfPred == f && ap->ModuleOfPred == mod)
return ap;
p0 = ap->NextOfPE;
}
return RepPredProp(Yap_NewThreadPred(ap PASS_REGS));
}
#endif
INLINE_ONLY Prop GetPredPropByFuncHavingLock(FunctorEntry *fe, Term cur_mod) {
PredEntry *p;
if (!(p = RepPredProp(fe->PropsOfFE))) {
return NIL;
}
if ((p->ModuleOfPred == cur_mod || !(p->ModuleOfPred))) {
#ifdef THREADS
/* Thread Local Predicates */
if (p->PredFlags & ThreadLocalPredFlag) {
return AbsPredProp(Yap_GetThreadPred(p INIT_REGS));
}
#endif
return AbsPredProp(p);
}
if (p->NextOfPE) {
UInt hash = PRED_HASH(fe, cur_mod, PredHashTableSize);
READ_LOCK(PredHashRWLock);
p = PredHash[hash];
while (p) {
if (p->FunctorOfPred == fe && p->ModuleOfPred == cur_mod) {
#ifdef THREADS
/* Thread Local Predicates */
if (p->PredFlags & ThreadLocalPredFlag) {
READ_UNLOCK(PredHashRWLock);
return AbsPredProp(Yap_GetThreadPred(p INIT_REGS));
}
#endif
READ_UNLOCK(PredHashRWLock);
return AbsPredProp(p);
}
p = p->NextPredOfHash;
}
READ_UNLOCK(PredHashRWLock);
}
return NIL;
}
INLINE_ONLY Prop PredPropByFunc(Functor fe, Term cur_mod)
/* get predicate entry for ap/arity; create it if neccessary. */
{
Prop p0;
FUNC_WRITE_LOCK(fe);
p0 = GetPredPropByFuncHavingLock(fe, cur_mod);
if (p0) {
FUNC_WRITE_UNLOCK(fe);
return p0;
}
return Yap_NewPredPropByFunctor(fe, cur_mod);
}
INLINE_ONLY Prop GetPredPropByFuncAndModHavingLock(FunctorEntry *fe,
Term cur_mod) {
PredEntry *p;
if (!(p = RepPredProp(fe->PropsOfFE))) {
return NIL;
}
if (p->ModuleOfPred == cur_mod || p->ModuleOfPred == 0) {
#ifdef THREADS
/* Thread Local Predicates */
if (p->PredFlags & ThreadLocalPredFlag) {
return AbsPredProp(Yap_GetThreadPred(p INIT_REGS));
}
#endif
return AbsPredProp(p);
}
if (p->NextOfPE) {
UInt hash = PRED_HASH(fe, cur_mod, PredHashTableSize);
READ_LOCK(PredHashRWLock);
p = PredHash[hash];
while (p) {
if (p->FunctorOfPred == fe && p->ModuleOfPred == cur_mod) {
#ifdef THREADS
/* Thread Local Predicates */
if (p->PredFlags & ThreadLocalPredFlag) {
READ_UNLOCK(PredHashRWLock);
return AbsPredProp(Yap_GetThreadPred(p INIT_REGS));
}
#endif
READ_UNLOCK(PredHashRWLock);
return AbsPredProp(p);
}
p = p->NextPredOfHash;
}
READ_UNLOCK(PredHashRWLock);
}
return NIL;
}
INLINE_ONLY Prop PredPropByFuncAndMod(Functor fe, Term cur_mod)
/* get predicate entry for ap/arity; create it if neccessary. */
{
Prop p0;
FUNC_WRITE_LOCK(fe);
p0 = GetPredPropByFuncAndModHavingLock(fe, cur_mod);
if (p0) {
FUNC_WRITE_UNLOCK(fe);
return p0;
}
return Yap_NewPredPropByFunctor(fe, cur_mod);
}
INLINE_ONLY Prop PredPropByAtom(Atom at, Term cur_mod)
/* get predicate entry for ap/arity; create it if neccessary. */
{
Prop p0;
AtomEntry *ae = RepAtom(at);
WRITE_LOCK(ae->ARWLock);
p0 = ae->PropsOfAE;
while (p0) {
PredEntry *pe = RepPredProp(p0);
if (pe->KindOfPE == PEProp &&
(pe->ModuleOfPred == cur_mod || !pe->ModuleOfPred)) {
#ifdef THREADS
/* Thread Local Predicates */
if (pe->PredFlags & ThreadLocalPredFlag) {
WRITE_UNLOCK(ae->ARWLock);
return AbsPredProp(Yap_GetThreadPred(pe INIT_REGS));
}
#endif
WRITE_UNLOCK(ae->ARWLock);
return (p0);
}
p0 = pe->NextOfPE;
}
return Yap_NewPredPropByAtom(ae, cur_mod);
}
INLINE_ONLY Prop PredPropByAtomAndMod(Atom at, Term cur_mod)
/* get predicate entry for ap/arity; create it if neccessary. */
{
Prop p0;
AtomEntry *ae = RepAtom(at);
WRITE_LOCK(ae->ARWLock);
p0 = ae->PropsOfAE;
while (p0) {
PredEntry *pe = RepPredProp(p0);
if (pe->KindOfPE == PEProp &&
(pe->ModuleOfPred == cur_mod || pe->ModuleOfPred == 0)) {
#ifdef THREADS
/* Thread Local Predicates */
if (pe->PredFlags & ThreadLocalPredFlag) {
WRITE_UNLOCK(ae->ARWLock);
return AbsPredProp(Yap_GetThreadPred(pe INIT_REGS));
}
#endif
WRITE_UNLOCK(ae->ARWLock);
return (p0);
}
p0 = pe->NextOfPE;
}
return Yap_NewPredPropByAtom(ae, cur_mod);
}
#if DEBUG_PELOCKING
#define PELOCK(I, Z) \
{ \
LOCK((Z)->PELock); \
(Z)->StatisticsForPred->NOfEntries = (I); \
(Z)->StatisticsForPred->NOfHeadSuccesses = pthread_self(); \
}
#define UNLOCKPE(I, Z) \
((Z)->StatisticsForPred->NOfRetries = (I), UNLOCK((Z)->PELock))
#elif YAPOR || THREADS
#define PELOCK(I, Z) (LOCK((Z)->PELock))
#define UNLOCKPE(I, Z) (UNLOCK((Z)->PELock))
#else
#define PELOCK(I, Z)
#define UNLOCKPE(I, Z)
#endif
INLINE_ONLY void AddPropToAtom(AtomEntry *, PropEntry *p);
INLINE_ONLY void AddPropToAtom(AtomEntry *ae, PropEntry *p) {
/* old properties should be always last, and wide atom properties
should always be first */
p->NextOfPE = ae->PropsOfAE;
ae->PropsOfAE = AbsProp(p);
}
// auxiliary functions
INLINE_ONLY const char *AtomName(Atom at);
/**
* AtomName(Atom at): get a string with the name of an Atom. Assumes 8 bit
*representation.
*
* @param at the atom
*
* @return a ponter to an immutable sequence of characters.
*/
INLINE_ONLY const char *AtomName(Atom at) { return RepAtom(at)->rep.uStrOfAE; }
INLINE_ONLY const char *AtomTermName(Term t);
/**
* AtomTermName(Term t): get a string with the name of a term storing an Atom.
*Assumes 8
*bit representation.
*
* @param t the atom term
*
* @return a ponter to an immutable sequence of characters.
*
* @note: this routine does not support wide chars.
*/
INLINE_ONLY const char *AtomTermName(Term t) {
return RepAtom(AtomOfTerm(t))->rep.uStrOfAE;
}
extern Term MkErrorTerm(yap_error_descriptor_t *t);
extern bool Yap_ResetException(yap_error_descriptor_t *i);
extern bool Yap_HasException(void);
extern yap_error_descriptor_t *Yap_GetException();
extern void Yap_PrintException(yap_error_descriptor_t *i);
INLINE_ONLY bool Yap_HasException(void) {
extern yap_error_number Yap_MathException__(USES_REGS1);
yap_error_number me;
if ((me = Yap_MathException__(PASS_REGS1)) && LOCAL_ActiveError->errorNo != YAP_NO_ERROR) {
LOCAL_ActiveError->errorNo = me;
}
return LOCAL_ActiveError->errorNo != YAP_NO_ERROR;
}
INLINE_ONLY Term MkSysError(yap_error_descriptor_t *i) {
Term et = MkAddressTerm(i);
return Yap_MkApplTerm(FunctorException, 1, &et);
}
yap_error_descriptor_t *Yap_UserError(Term t, yap_error_descriptor_t *i);
extern bool Yap_RaiseException(void);
#endif