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yap-6.3/C/qlyw.c
2014-02-18 09:44:01 +00:00

910 lines
22 KiB
C
Executable File

/*************************************************************************
* *
* YAP Prolog *
* *
* Yap Prolog was developed at NCCUP - Universidade do Porto *
* *
* Copyright L.Damas, V. Santos Costa and Universidade do Porto 1985-- *
* *
**************************************************************************
* *
* File: qlyw.c *
* comments: quick saver/loader *
* *
* Last rev: $Date: 2011-08-29$,$Author: vsc $ *
* $Log: not supported by cvs2svn $ *
* *
*************************************************************************/
#include <SWI-Stream.h>
#include "absmi.h"
#include "Foreign.h"
#include "alloc.h"
#include "yapio.h"
#include "iopreds.h"
#include "attvar.h"
#if HAVE_STRING_H
#include <string.h>
#endif
#include "qly.h"
static void RestoreEntries(PropEntry *, int USES_REGS);
static void CleanCode(PredEntry * USES_REGS);
static void
GrowAtomTable(void) {
CACHE_REGS
UInt size = LOCAL_ExportAtomHashTableSize;
export_atom_hash_entry_t *p, *newt, *oldt = LOCAL_ExportAtomHashChain;
UInt new_size = size + (size > 1024 ? size : 1024);
UInt i;
newt = (export_atom_hash_entry_t *)calloc(new_size,sizeof(export_atom_hash_entry_t));
if (!newt) {
return;
}
p = oldt;
for (i = 0 ; i < size ; p++,i++) {
Atom a = p->val;
export_atom_hash_entry_t *newp;
CELL hash;
char *apt;
if (!a) continue;
apt = RepAtom(a)->StrOfAE;
hash = HashFunction((unsigned char *)apt)/(2*sizeof(CELL)) % new_size;
newp = newt+hash;
while (newp->val) {
newp++;
if (newp == newt+new_size)
newp = newt;
}
newp->val = a;
}
LOCAL_ExportAtomHashChain = newt;
LOCAL_ExportAtomHashTableSize = new_size;
free(oldt);
}
static void
LookupAtom(Atom at)
{
CACHE_REGS
char *p = RepAtom(at)->StrOfAE;
CELL hash = HashFunction((unsigned char *)p) % LOCAL_ExportAtomHashTableSize;
export_atom_hash_entry_t *a;
a = LOCAL_ExportAtomHashChain+hash;
while (a->val) {
if (a->val == at) {
return;
}
a++;
if (a == LOCAL_ExportAtomHashChain+LOCAL_ExportAtomHashTableSize)
a = LOCAL_ExportAtomHashChain;
}
a->val = at;
LOCAL_ExportAtomHashTableNum++;
if (LOCAL_ExportAtomHashTableNum >
LOCAL_ExportAtomHashTableSize/2
) {
GrowAtomTable();
if (!LOCAL_ExportAtomHashChain) {
return;
}
}
}
static void
GrowFunctorTable(void) {
CACHE_REGS
UInt size = LOCAL_ExportFunctorHashTableSize;
export_functor_hash_entry_t *p, *newt, *oldt = LOCAL_ExportFunctorHashChain;
UInt new_size = size + (size > 1024 ? size : 1024);
UInt i;
newt = (export_functor_hash_entry_t *)calloc(new_size,sizeof(export_functor_hash_entry_t));
if (!newt) {
return;
}
p = oldt;
for (i = 0 ; i < size ; p++,i++) {
Functor f = p->val;
export_functor_hash_entry_t *newp;
CELL hash;
if (!f) continue;
hash = ((CELL)(f))/(2*sizeof(CELL)) % new_size;
newp = newt+hash;
while (newp->val) {
newp++;
if (newp == newt+new_size)
newp = newt;
}
newp->val = p->val;
newp->arity = p->arity;
newp->name = p->name;
}
LOCAL_ExportFunctorHashChain = newt;
LOCAL_ExportFunctorHashTableSize = new_size;
free(oldt);
}
static void
LookupFunctor(Functor fun)
{
CACHE_REGS
CELL hash = ((CELL)(fun))/(2*sizeof(CELL)) % LOCAL_ExportFunctorHashTableSize;
export_functor_hash_entry_t *f;
Atom name = NameOfFunctor(fun);
UInt arity = ArityOfFunctor(fun);
f = LOCAL_ExportFunctorHashChain+hash;
while (f->val) {
if (f->val == fun) {
return;
}
f++;
if (f == LOCAL_ExportFunctorHashChain+LOCAL_ExportFunctorHashTableSize)
f = LOCAL_ExportFunctorHashChain;
}
LookupAtom(name);
f->val = fun;
f->name = name;
f->arity = arity;
LOCAL_ExportFunctorHashTableNum++;
if (LOCAL_ExportFunctorHashTableNum >
LOCAL_ExportFunctorHashTableSize/2
) {
GrowFunctorTable();
if (!LOCAL_ExportFunctorHashChain) {
return;
}
}
}
static void
GrowPredTable(void) {
CACHE_REGS
UInt size = LOCAL_ExportPredEntryHashTableSize;
export_pred_entry_hash_entry_t *p, *newt, *oldt = LOCAL_ExportPredEntryHashChain;
UInt new_size = size + (size > 1024 ? size : 1024);
UInt i;
newt = (export_pred_entry_hash_entry_t *)calloc(new_size,sizeof(export_pred_entry_hash_entry_t));
if (!newt) {
return;
}
p = oldt;
for (i = 0 ; i < size ; p++,i++) {
PredEntry *pe = p->val;
export_pred_entry_hash_entry_t *newp;
CELL hash;
if (!pe) continue;
hash = ((CELL)(pe))/(2*sizeof(CELL)) % new_size;
newp = newt+hash;
while (newp->val) {
newp++;
if (newp == newt+new_size)
newp = newt;
}
newp->val = p->val;
newp->arity = p->arity;
newp->u_af.f = p->u_af.f;
newp->module = p->module;
}
LOCAL_ExportPredEntryHashChain = newt;
LOCAL_ExportPredEntryHashTableSize = new_size;
free(oldt);
}
static void
LookupPredEntry(PredEntry *pe)
{
CACHE_REGS
CELL hash = (((CELL)(pe))/(2*sizeof(CELL))) % LOCAL_ExportPredEntryHashTableSize;
export_pred_entry_hash_entry_t *p;
UInt arity = pe->ArityOfPE;
p = LOCAL_ExportPredEntryHashChain+hash;
while (p->val) {
if (p->val == pe) {
return;
}
p++;
if (p == LOCAL_ExportPredEntryHashChain+LOCAL_ExportPredEntryHashTableSize)
p = LOCAL_ExportPredEntryHashChain;
}
p->arity = arity;
p->val = pe;
if (pe->ModuleOfPred != IDB_MODULE) {
if (arity) {
p->u_af.f = pe->FunctorOfPred;
LookupFunctor(pe->FunctorOfPred);
} else {
p->u_af.a = (Atom)(pe->FunctorOfPred);
LookupAtom((Atom)(pe->FunctorOfPred));
}
} else {
if (pe->PredFlags & AtomDBPredFlag) {
p->u_af.a = (Atom)(pe->FunctorOfPred);
p->arity = (CELL)(-2);
LookupAtom((Atom)(pe->FunctorOfPred));
} else if (!(pe->PredFlags & NumberDBPredFlag)) {
p->u_af.f = pe->FunctorOfPred;
p->arity = (CELL)(-1);
LookupFunctor(pe->FunctorOfPred);
} else {
p->u_af.f = pe->FunctorOfPred;
}
}
if (pe->ModuleOfPred) {
p->module = AtomOfTerm(pe->ModuleOfPred);
} else {
p->module = AtomProlog;
}
LookupAtom(p->module);
LOCAL_ExportPredEntryHashTableNum++;
if (LOCAL_ExportPredEntryHashTableNum >
LOCAL_ExportPredEntryHashTableSize/2
) {
GrowPredTable();
if (!LOCAL_ExportPredEntryHashChain) {
return;
}
}
}
static void
GrowDBRefTable(void) {
CACHE_REGS
UInt size = LOCAL_ExportDBRefHashTableSize;
export_dbref_hash_entry_t *p, *newt, *oldt = LOCAL_ExportDBRefHashChain;
UInt new_size = size + (size > 1024 ? size : 1024);
UInt i;
newt = (export_dbref_hash_entry_t *)calloc(new_size,sizeof(export_dbref_hash_entry_t));
if (!newt) {
return;
}
p = oldt;
for (i = 0 ; i < size ; p++,i++) {
DBRef dbr = p->val;
export_dbref_hash_entry_t *newp;
CELL hash;
if (!dbr) continue;
hash = ((CELL)(dbr))/(2*sizeof(CELL)) % new_size;
newp = newt+hash;
while (newp->val) {
newp++;
if (newp == newt+new_size)
newp = newt;
}
newp->val = p->val;
newp->sz = p->sz;
newp->refs = p->refs;
}
LOCAL_ExportDBRefHashChain = newt;
LOCAL_ExportDBRefHashTableSize = new_size;
free(oldt);
}
static void
LookupDBRef(DBRef ref)
{
CACHE_REGS
CELL hash = ((CELL)(ref))/(2*sizeof(CELL)) % LOCAL_ExportDBRefHashTableSize;
export_dbref_hash_entry_t *a;
a = LOCAL_ExportDBRefHashChain+hash;
while (a->val) {
if (a->val == ref) {
a->refs++;
return;
}
a++;
if (a == LOCAL_ExportDBRefHashChain+LOCAL_ExportDBRefHashTableSize)
a = LOCAL_ExportDBRefHashChain;
}
a->val = ref;
a->sz = ((LogUpdClause *)ref)->ClSize;
a->refs = 1;
LOCAL_ExportDBRefHashTableNum++;
if (LOCAL_ExportDBRefHashTableNum >
LOCAL_ExportDBRefHashTableSize/2
) {
GrowDBRefTable();
if (!LOCAL_ExportDBRefHashChain) {
return;
}
}
}
static void
InitHash(void)
{
CACHE_REGS
LOCAL_ExportFunctorHashTableNum = 0;
LOCAL_ExportFunctorHashTableSize = EXPORT_FUNCTOR_TABLE_SIZE;
LOCAL_ExportFunctorHashChain = (export_functor_hash_entry_t *)calloc(LOCAL_ExportFunctorHashTableSize, sizeof(export_functor_hash_entry_t ));
LOCAL_ExportAtomHashTableNum = 0;
LOCAL_ExportAtomHashTableSize = EXPORT_ATOM_TABLE_SIZE;
LOCAL_ExportAtomHashChain = (export_atom_hash_entry_t *)calloc( LOCAL_ExportAtomHashTableSize, sizeof(export_atom_hash_entry_t *));
LOCAL_ExportPredEntryHashTableNum = 0;
LOCAL_ExportPredEntryHashTableSize = EXPORT_PRED_ENTRY_TABLE_SIZE;
LOCAL_ExportPredEntryHashChain = (export_pred_entry_hash_entry_t *)calloc(LOCAL_ExportPredEntryHashTableSize, sizeof(export_pred_entry_hash_entry_t));
LOCAL_ExportDBRefHashTableNum = 0;
LOCAL_ExportDBRefHashTableSize = EXPORT_DBREF_TABLE_SIZE;
LOCAL_ExportDBRefHashChain = (export_dbref_hash_entry_t *)calloc(EXPORT_DBREF_TABLE_SIZE, sizeof(export_dbref_hash_entry_t));
}
static void
CloseHash(void)
{
CACHE_REGS
LOCAL_ExportFunctorHashTableNum = 0;
LOCAL_ExportFunctorHashTableSize = 0L;
free(LOCAL_ExportFunctorHashChain);
LOCAL_ExportAtomHashTableNum = 0;
LOCAL_ExportAtomHashTableSize = 0L;
free(LOCAL_ExportAtomHashChain);
LOCAL_ExportPredEntryHashTableNum = 0;
LOCAL_ExportPredEntryHashTableSize = 0L;
free(LOCAL_ExportPredEntryHashChain);
LOCAL_ExportDBRefHashTableNum = 0;
LOCAL_ExportDBRefHashTableSize = 0L;
free(LOCAL_ExportDBRefHashChain);
}
static inline Atom
AtomAdjust(Atom a)
{
LookupAtom(a);
return a;
}
static inline Functor
FuncAdjust(Functor f)
{
LookupFunctor(f);
return f;
}
static inline Term
AtomTermAdjust(Term t)
{
LookupAtom(AtomOfTerm(t));
return t;
}
static inline Term
TermToGlobalOrAtomAdjust(Term t)
{
if (t && IsAtomTerm(t))
return AtomTermAdjust(t);
return t;
}
#define IsOldCode(P) FALSE
#define IsOldCodeCellPtr(P) FALSE
#define IsOldDelay(P) FALSE
#define IsOldDelayPtr(P) FALSE
#define IsOldLocalInTR(P) FALSE
#define IsOldLocalInTRPtr(P) FALSE
#define IsOldGlobal(P) FALSE
#define IsOldGlobalPtr(P) FALSE
#define IsOldTrail(P) FALSE
#define IsOldTrailPtr(P) FALSE
#define CharP(X) ((char *)(X))
#define REINIT_LOCK(P)
#define REINIT_RWLOCK(P)
#define BlobTypeAdjust(P) (P)
#define NoAGCAtomAdjust(P) (P)
#define OrArgAdjust(P)
#define TabEntryAdjust(P)
#define IntegerAdjust(D) (D)
#define AddrAdjust(P) (P)
#define MFileAdjust(P) (P)
#define CodeVarAdjust(P) (P)
#define ConstantAdjust(P) (P)
#define ArityAdjust(P) (P)
#define DoubleInCodeAdjust(P)
#define IntegerInCodeAdjust(P)
#define OpcodeAdjust(P) (P)
static inline Term
ModuleAdjust(Term t)
{
if (!t) return t;
return AtomTermAdjust(t);
}
static inline PredEntry *
PredEntryAdjust(PredEntry *pe)
{
LookupPredEntry(pe);
return pe;
}
static inline PredEntry *
PtoPredAdjust(PredEntry *pe)
{
LookupPredEntry(pe);
return pe;
}
#define ExternalFunctionAdjust(P) (P)
#define DBRecordAdjust(P) (P)
#define ModEntryPtrAdjust(P) (P)
#define AtomEntryAdjust(P) (P)
#define GlobalEntryAdjust(P) (P)
#define BlobTermInCodeAdjust(P) (P)
#define CellPtoHeapAdjust(P) (P)
#define PtoAtomHashEntryAdjust(P) (P)
#define CellPtoHeapCellAdjust(P) (P)
#define CellPtoTRAdjust(P) (P)
#define CodeAddrAdjust(P) (P)
#define ConsultObjAdjust(P) (P)
#define DelayAddrAdjust(P) (P)
#define DelayAdjust(P) (P)
#define GlobalAdjust(P) (P)
#define DBRefAdjust(P,DoRef) DBRefAdjust__(P PASS_REGS)
static inline DBRef
DBRefAdjust__ (DBRef dbt USES_REGS)
{
LookupDBRef(dbt);
return dbt;
}
#define DBRefPAdjust(P) (P)
#define DBTermAdjust(P) (P)
#define LUIndexAdjust(P) (P)
#define SIndexAdjust(P) (P)
#define LocalAddrAdjust(P) (P)
#define GlobalAddrAdjust(P) (P)
#define OpListAdjust(P) (P)
#define PtoLUCAdjust(P) (P)
#define PtoStCAdjust(P) (P)
#define PtoArrayEAdjust(P) (P)
#define PtoArraySAdjust(P) (P)
#define PtoGlobalEAdjust(P) (P)
#define PtoDelayAdjust(P) (P)
#define PtoGloAdjust(P) (P)
#define PtoLocAdjust(P) (P)
#define PtoHeapCellAdjust(P) (P)
#define TermToGlobalAdjust(P) (P)
#define PtoOpAdjust(P) (P)
#define PtoLUClauseAdjust(P) (P)
#define PtoLUIndexAdjust(P) (P)
#define PtoDBTLAdjust(P) (P)
#define PtoPtoPredAdjust(P) (P)
#define OpRTableAdjust(P) (P)
#define OpEntryAdjust(P) (P)
#define PropAdjust(P) (P)
#define TrailAddrAdjust(P) (P)
#define XAdjust(P) (P)
#define YAdjust(P) (P)
#define HoldEntryAdjust(P) (P)
#define CodeCharPAdjust(P) (P)
#define CodeVoidPAdjust(P) (P)
#define HaltHookAdjust(P) (P)
#define recompute_mask(dbr)
#define rehash(oldcode, NOfE, KindOfEntries)
#define RestoreSWIHash()
#include "rheap.h"
static void
RestoreHashPreds( USES_REGS1 )
{
}
static void
RestoreAtomList(Atom atm USES_REGS)
{
}
static size_t save_bytes(IOSTREAM *stream, void *ptr, size_t sz)
{
return Sfwrite(ptr, sz, 1, stream);
}
static size_t save_byte(IOSTREAM *stream, int byte)
{
Sputc(byte, stream);
return 1;
}
static size_t save_bits16(IOSTREAM *stream, BITS16 val)
{
BITS16 v = val;
return save_bytes(stream, &v, sizeof(BITS16));
}
static size_t save_uint(IOSTREAM *stream, UInt val)
{
UInt v = val;
return save_bytes(stream, &v, sizeof(UInt));
}
static size_t save_int(IOSTREAM *stream, int val)
{
UInt v = val;
return save_bytes(stream, &v, sizeof(int));
}
static size_t save_tag(IOSTREAM *stream, qlf_tag_t tag)
{
return save_byte(stream, tag);
}
static int
SaveHash(IOSTREAM *stream)
{
CACHE_REGS
UInt i;
/* first, current opcodes */
CHECK(save_tag(stream, QLY_START_X));
save_uint(stream, (UInt)&ARG1);
CHECK(save_tag(stream, QLY_START_OPCODES));
save_int(stream, _std_top);
for (i= 0; i <= _std_top; i++) {
save_uint(stream, (UInt)Yap_opcode(i));
}
CHECK(save_tag(stream, QLY_START_ATOMS));
CHECK(save_uint(stream, LOCAL_ExportAtomHashTableNum));
for (i = 0; i < LOCAL_ExportAtomHashTableSize; i++) {
export_atom_hash_entry_t *a = LOCAL_ExportAtomHashChain+i;
if (a->val) {
Atom at = a->val;
CHECK(save_uint(stream, (UInt)at));
if (IsWideAtom(at)) {
CHECK(save_tag(stream, QLY_ATOM_WIDE));
CHECK(save_uint(stream, wcslen(RepAtom(at)->WStrOfAE)));
CHECK(save_bytes(stream, at->WStrOfAE, (wcslen(at->WStrOfAE)+1)*sizeof(wchar_t)));
} else {
CHECK(save_tag(stream, QLY_ATOM));
CHECK(save_uint(stream, strlen(RepAtom(at)->StrOfAE)));
CHECK(save_bytes(stream, at->StrOfAE, (strlen(at->StrOfAE)+1)*sizeof(char)));
}
}
}
save_tag(stream, QLY_START_FUNCTORS);
save_uint(stream, LOCAL_ExportFunctorHashTableNum);
for (i = 0; i < LOCAL_ExportFunctorHashTableSize; i++) {
export_functor_hash_entry_t *f = LOCAL_ExportFunctorHashChain+i;
if (!(f->val))
continue;
CHECK(save_uint(stream, (UInt)(f->val)));
CHECK(save_uint(stream, f->arity));
CHECK(save_uint(stream, (CELL)(f->name)));
}
save_tag(stream, QLY_START_PRED_ENTRIES);
save_uint(stream, LOCAL_ExportPredEntryHashTableNum);
for (i = 0; i < LOCAL_ExportPredEntryHashTableSize; i++) {
export_pred_entry_hash_entry_t *p = LOCAL_ExportPredEntryHashChain+i;
if (!(p->val))
continue;
CHECK(save_uint(stream, (UInt)(p->val)));
CHECK(save_uint(stream, p->arity));
CHECK(save_uint(stream, (UInt)p->module));
CHECK(save_uint(stream, (UInt)p->u_af.f));
}
save_tag(stream, QLY_START_DBREFS);
save_uint(stream, LOCAL_ExportDBRefHashTableNum);
for (i = 0; i < LOCAL_ExportDBRefHashTableSize; i++) {
export_dbref_hash_entry_t *p = LOCAL_ExportDBRefHashChain+i;
if (p->val) {
CHECK(save_uint(stream, (UInt)(p->val)));
CHECK(save_uint(stream, p->sz));
CHECK(save_uint(stream, p->refs));
}
}
save_tag(stream, QLY_FAILCODE);
save_uint(stream, (UInt)FAILCODE);
return 1;
}
static size_t
save_clauses(IOSTREAM *stream, PredEntry *pp) {
yamop *FirstC, *LastC;
FirstC = pp->cs.p_code.FirstClause;
LastC = pp->cs.p_code.LastClause;
if (FirstC == NULL && LastC == NULL) {
return 1;
}
if (pp->PredFlags & LogUpdatePredFlag) {
LogUpdClause *cl = ClauseCodeToLogUpdClause(FirstC);
while (cl != NULL) {
if (IN_BETWEEN(cl->ClTimeStart, pp->TimeStampOfPred, cl->ClTimeEnd)) {
UInt size = cl->ClSize;
CHECK(save_tag(stream, QLY_START_LU_CLAUSE));
CHECK(save_uint(stream, (UInt)cl));
CHECK(save_uint(stream, size));
CHECK(save_bytes(stream, cl, size));
}
cl = cl->ClNext;
}
CHECK(save_tag(stream, QLY_END_LU_CLAUSES));
} else if (pp->PredFlags & MegaClausePredFlag) {
MegaClause *cl = ClauseCodeToMegaClause(FirstC);
UInt size = cl->ClSize;
CHECK(save_uint(stream, (UInt)cl));
CHECK(save_uint(stream, (UInt)(cl->ClFlags)));
CHECK(save_uint(stream, size));
CHECK(save_bytes(stream, cl, size));
} else if (pp->PredFlags & DynamicPredFlag) {
yamop *cl = FirstC;
do {
DynamicClause *dcl = ClauseCodeToDynamicClause(cl);
UInt size = dcl->ClSize;
CHECK(save_uint(stream, (UInt)cl));
CHECK(save_uint(stream, size));
CHECK(save_bytes(stream, dcl, size));
if (cl == LastC) return 1;
cl = NextDynamicClause(cl);
} while (TRUE);
} else {
StaticClause *cl = ClauseCodeToStaticClause(FirstC);
if (pp->PredFlags & SYSTEM_PRED_FLAGS) {
return 1;
}
do {
UInt size = cl->ClSize;
CHECK(save_uint(stream, (UInt)cl));
CHECK(save_uint(stream, size));
CHECK(save_bytes(stream, cl, size));
if (cl->ClCode == LastC) return 1;
cl = cl->ClNext;
} while (TRUE);
}
return 1;
}
static size_t
save_pred(IOSTREAM *stream, PredEntry *ap) {
CHECK(save_uint(stream, (UInt)ap));
CHECK(save_uint(stream, ap->PredFlags));
#if SIZEOF_INT_P==4
CHECK(save_uint(stream, ap->ExtraPredFlags));
#endif
CHECK(save_uint(stream, ap->cs.p_code.NOfClauses));
CHECK(save_uint(stream, ap->src.IndxId));
CHECK(save_uint(stream, ap->TimeStampOfPred));
return save_clauses(stream, ap);
}
static int
clean_pred(PredEntry *pp USES_REGS) {
if (pp->PredFlags & (AsmPredFlag|CPredFlag)) {
/* assembly */
if (pp->CodeOfPred) {
CleanClauses(pp->CodeOfPred, pp->CodeOfPred, pp PASS_REGS);
}
} else {
CleanClauses(pp->cs.p_code.FirstClause, pp->cs.p_code.LastClause, pp PASS_REGS);
}
return TRUE;
}
static size_t
mark_pred(PredEntry *ap)
{
CACHE_REGS
if (ap->ModuleOfPred != IDB_MODULE) {
if (ap->ArityOfPE) {
FuncAdjust(ap->FunctorOfPred);
} else {
AtomAdjust((Atom)(ap->FunctorOfPred));
}
} else {
if (ap->PredFlags & AtomDBPredFlag) {
AtomAdjust((Atom)(ap->FunctorOfPred));
} else if (!(ap->PredFlags & NumberDBPredFlag)) {
FuncAdjust(ap->FunctorOfPred);
}
}
if (!(ap->PredFlags & (MultiFileFlag|NumberDBPredFlag)) &&
ap->src.OwnerFile) {
AtomAdjust(ap->src.OwnerFile);
}
CHECK(clean_pred(ap PASS_REGS));
return 1;
}
static size_t
mark_ops(IOSTREAM *stream, Term mod) {
OpEntry *op = OpList;
while (op) {
if (!mod || op->OpModule == mod) {
AtomAdjust(op->OpName);
if (op->OpModule)
AtomTermAdjust(op->OpModule);
}
op = op->OpNext;
}
return 1;
}
static size_t
save_ops(IOSTREAM *stream, Term mod) {
OpEntry *op = OpList;
while (op) {
if (!mod || op->OpModule == mod) {
CHECK(save_tag(stream, QLY_NEW_OP));
save_uint(stream, (UInt)op->OpName);
save_uint(stream, (UInt)op->OpModule);
save_bits16(stream, op->Prefix);
save_bits16(stream, op->Infix);
save_bits16(stream, op->Posfix);
}
op = op->OpNext;
}
CHECK(save_tag(stream, QLY_END_OPS));
return 1;
}
static size_t
save_module(IOSTREAM *stream, Term mod) {
PredEntry *ap = Yap_ModulePred(mod);
InitHash();
ModuleAdjust(mod);
while (ap) {
ap = PredEntryAdjust(ap);
CHECK(mark_pred(ap));
ap = ap->NextPredOfModule;
}
/* just to make sure */
mark_ops(stream, mod);
SaveHash(stream);
CHECK(save_tag(stream, QLY_START_MODULE));
CHECK(save_uint(stream, (UInt)mod));
ap = Yap_ModulePred(mod);
while (ap) {
CHECK(save_tag(stream, QLY_START_PREDICATE));
CHECK(save_pred(stream, ap));
ap = ap->NextPredOfModule;
}
CHECK(save_tag(stream, QLY_END_PREDICATES));
CHECK(save_tag(stream, QLY_END_MODULES));
save_ops(stream, mod);
CloseHash();
return 1;
}
static int
save_header(IOSTREAM *stream)
{
char msg[256];
sprintf(msg, "#!/bin/sh\nexec_dir=${YAPBINDIR:-%s}\nexec $exec_dir/yap $0 \"$@\"\n%s", YAP_BINDIR, YAP_FULL_VERSION);
return save_bytes(stream, msg, strlen(msg)+1);
}
static size_t
save_program(IOSTREAM *stream) {
ModEntry *me = CurrentModules;
InitHash();
save_header( stream );
/* should we allow the user to see hidden predicates? */
while (me) {
PredEntry *pp;
pp = me->PredForME;
AtomAdjust(me->AtomOfME);
while (pp != NULL) {
pp = PredEntryAdjust(pp);
CHECK(mark_pred(pp));
pp = pp->NextPredOfModule;
}
me = me->NextME;
}
/* just to make sure */
mark_ops(stream, 0);
SaveHash(stream);
me = CurrentModules;
while (me) {
PredEntry *pp;
pp = me->PredForME;
CHECK(save_tag(stream, QLY_START_MODULE));
CHECK(save_uint(stream, (UInt)MkAtomTerm(me->AtomOfME)));
while (pp != NULL) {
CHECK(save_tag(stream, QLY_START_PREDICATE));
CHECK(save_pred(stream, pp));
pp = pp->NextPredOfModule;
}
CHECK(save_tag(stream, QLY_END_PREDICATES));
me = me->NextME;
}
CHECK(save_tag(stream, QLY_END_MODULES));
save_ops(stream, 0);
CloseHash();
return 1;
}
static Int
p_save_module_preds( USES_REGS1 )
{
IOSTREAM *stream;
Term tmod = Deref(ARG2);
Term t1 = Deref(ARG1);
if (IsVarTerm(t1)) {
Yap_Error(INSTANTIATION_ERROR,t1,"save_module/3");
return FALSE;
}
if (!IsAtomTerm(t1)) {
Yap_Error(TYPE_ERROR_ATOM,t1,"save_module/3");
return(FALSE);
}
if (!(stream = Yap_GetOutputStream(AtomOfTerm(t1))) ) {
return FALSE;
}
if (IsVarTerm(tmod)) {
Yap_Error(INSTANTIATION_ERROR,tmod,"save_module/2");
return FALSE;
}
if (!IsAtomTerm(tmod)) {
Yap_Error(TYPE_ERROR_ATOM,tmod,"save_module/2");
return FALSE;
}
return save_module(stream, tmod) != 0;
}
static Int
p_save_program( USES_REGS1 )
{
IOSTREAM *stream;
Term t1 = Deref(ARG1);
if (IsVarTerm(t1)) {
Yap_Error(INSTANTIATION_ERROR,t1,"save_program/3");
return FALSE;
}
if (!IsAtomTerm(t1)) {
Yap_Error(TYPE_ERROR_ATOM,t1,"save_program/3");
return(FALSE);
}
if (!(stream = Yap_GetOutputStream(AtomOfTerm(t1))) ) {
return FALSE;
}
if (!(stream = Yap_GetOutputStream(AtomOfTerm(t1))) ) {
return FALSE;
}
return save_program(stream) != 0;
}
void Yap_InitQLY(void)
{
Yap_InitCPred("$qsave_module_preds", 2, p_save_module_preds, SyncPredFlag|UserCPredFlag);
Yap_InitCPred("$qsave_program", 1, p_save_program, SyncPredFlag|UserCPredFlag);
if (FALSE) {
restore_codes();
}
}