yap-6.3/C/save.c

/*************************************************************************
*									 *
*	 YAP Prolog 							 *
*									 *
*	Yap Prolog was developed at NCCUP - Universidade do Porto	 *
*									 *
* Copyright L.Damas, V.S.Costa and Universidade do Porto 1985-1997	 *
*									 *
**************************************************************************
*									 *
* File:		save.c							 *
* Last rev:								 *
* mods:									 *
* comments:	saving and restoring a Prolog computation		 *
*									 *
*************************************************************************/
#ifdef SCCS
static char     SccsId[] = "@(#)save.c	1.3 3/15/90";
#endif

#include "absmi.h"
#include "alloc.h"
#include "yapio.h"
#include "sshift.h"
#include "Foreign.h"
#if HAVE_STRING_H
#include <string.h>
#endif
#if !HAVE_STRNCAT
#define strncat(X,Y,Z) strcat(X,Y)
#endif
#if !HAVE_STRNCPY
#define strncpy(X,Y,Z) strcpy(X,Y)
#endif

#if HAVE_FCNTL_H
#include <fcntl.h>
#endif
#ifdef HAVE_UNISTD_H
#include <unistd.h>
#endif
#ifdef HAVE_SYS_TYPES_H
#include <sys/types.h>
#endif
#ifdef HAVE_SYS_STAT_H
#include <sys/stat.h>
#endif


/*********  hack for accesing several kinds of terms. Should be cleaned **/

#define AbsTerm(V) ((Term) (V))

extern char     StartUpFile[];

static char end_msg[256] ="*** End of YAP saved state *****";

#ifdef DEBUG

/*
 * FOR DEBUGGING define DEBUG_RESTORE0 to check the file stuff,
 * define DEBUG_RESTORE1 to see if it is able to prepare the chain,
 * define DEBUG_RESTORE2 to see how things are going,
 * define DEBUG_RESTORE3 to check if the atom chain is still a working
 * chain,
 * define DEBUG_RESTORE4 if you want to set the output for some
 * particular file,
 * define DEBUG_RESTORE5 if you want to see how the stacks are being
 * cleaned up,
 * define DEBUG_RESTORE6 if you want to follow the execution in 
 *
 * Also a file is defined where you can write things, by default stderr 
 *
 * Good Luck 
 */

#endif

STATIC_PROTO(void  myread, (int, char *, Int));
STATIC_PROTO(void  mywrite, (int, char *, Int));
STATIC_PROTO(int   open_file, (char *, int));
STATIC_PROTO(void  close_file, (void));
STATIC_PROTO(void  putout, (CELL));
STATIC_PROTO(void  putcellptr, (CELL *));
STATIC_PROTO(CELL  get_cell, (void));
STATIC_PROTO(CELL  *get_cellptr, ( /* CELL * */ void));
STATIC_PROTO(void  put_info, (int, int));
STATIC_PROTO(void  save_regs, (int));
STATIC_PROTO(void  save_code_info, (void));
STATIC_PROTO(void  save_heap, (void));
STATIC_PROTO(void  save_stacks, (int));
STATIC_PROTO(void  save_crc, (void));
STATIC_PROTO(Int   do_save, (int));
STATIC_PROTO(Int   p_save, (void));
STATIC_PROTO(Int   p_save_program, (void));
STATIC_PROTO(int   check_header, (void));
STATIC_PROTO(void  get_heap_info, (void));
STATIC_PROTO(void  get_regs, (int));
STATIC_PROTO(void  get_insts, (OPCODE []));
STATIC_PROTO(void  get_hash, (void));
STATIC_PROTO(void  CopyCode, (void));
STATIC_PROTO(void  CopyStacks, (void));
STATIC_PROTO(int   get_coded, (int, OPCODE []));
STATIC_PROTO(void  restore_codes, (void));
STATIC_PROTO(void  ConvDBList, (Term, char *,CELL));
STATIC_PROTO(Term  AdjustDBTerm, (Term));
STATIC_PROTO(void  RestoreDB, (DBEntry *));
STATIC_PROTO(void  RestoreClause, (Clause *));
STATIC_PROTO(void  CleanClauses, (CODEADDR, CODEADDR));
STATIC_PROTO(void  rehash, (CELL *, int, int));
STATIC_PROTO(void  CleanCode, (PredEntry *));
STATIC_PROTO(void  RestoreEntries, (PropEntry *));
STATIC_PROTO(void  RestoreInvisibleAtoms, (void));
STATIC_PROTO(void  RestoreFreeSpace, (void));
STATIC_PROTO(void  restore_heap, (void));
#ifdef DEBUG_RESTORE3
STATIC_PROTO(void  ShowAtoms, (void));
STATIC_PROTO(void  ShowEntries, (PropEntry *));
#endif
STATIC_PROTO(int   OpenRestore, (char *));
STATIC_PROTO(void  CloseRestore, (void));
STATIC_PROTO(int  check_opcodes, (OPCODE []));
STATIC_PROTO(void  RestoreHeap, (OPCODE [], int));
STATIC_PROTO(Int  p_restore, (void));
STATIC_PROTO(void  restore_heap_regs, (void));
STATIC_PROTO(void  restore_regs, (int));
STATIC_PROTO(void  ConvDBStruct, (Term, char *, CELL));
#ifdef MACYAP
STATIC_PROTO(void NewFileInfo, (long, long));
extern int      DefVol;
#endif

#if HAVE_IO_H
#include <io.h>
#endif

#ifdef LIGHT

#include <unix.h>
#include <strings.h>

void 
LightBug(char *);

static void 
LightBug(s)
	char           *s;
{
}

#endif				/* LIGHT */

#if SHORT_INTS

#ifdef M_WILLIAMS
#include <fcntl.h>
#endif

static void 
myread(int fd, char *buff, Int len)
{
  while (len > 16000) {
    int nchars = read(fd, buff, 16000);
    if (nchars <= 0)
      Error(FATAL_ERROR,TermNil,"bad saved state, system corrupted");
    len -= 16000;
    buff += 16000;
  }
  read(fd, buff, (unsigned) len);
}

static void 
mywrite(int fd, char *buff, Int len)
{
  while (len > 16000) {
    write(fd, buff, 16000);
    len -= 16000;
    buff += 16000;
  }
  write(fd, buff, (unsigned) len);
}

#else				/* SHORT_INTS */

inline static
void myread(int fd, char *buffer, Int len) {
  int nread;

  while (len > 0) {
    nread = read(fd, buffer,  (int)len);
    if (nread < 1) {
      Error(FATAL_ERROR,TermNil,"bad saved state, system corrupted");
    }
    buffer += nread;
    len -= nread;
  }
}

inline static
void mywrite(int fd, char *buff, Int len) {
  Int nwritten;

  while (len > 0) {
    nwritten = (Int)write(fd, buff, (int)len);
    if (nwritten == -1) {
      Error(SYSTEM_ERROR,TermNil,"write error while saving");
    }
    buff += nwritten;
    len -= nwritten;
  }
}

#endif				/* SHORT_INTS */

#define FullSaved		1

#define Atomics		0
#define Funcs		1

/* Where the code was before */



typedef CELL   *CELLPOINTER;

int             splfild = 0;

#ifdef DEBUG

#ifdef DEBUG_RESTORE4
static FILE    *errout;
#else
#define errout YP_stderr
#endif

#endif				/* DEBUG */

static Int      OldHeapUsed;

static CELL     which_save;

/* Open a file to read or to write */
static int 
open_file(char *ss, int flag)
{
  int splfild;

#ifdef M_WILLIAMS
  if (flag & O_CREAT)
    splfild = creat(ss, flag);
  else
    splfild = open(ss, flag);
  if (splfild < 0) {
#else
#ifdef O_BINARY
#if _MSC_VER
    if ((splfild = _open(ss, flag | O_BINARY), _S_IREAD | _S_IWRITE) < 0)
#else
    if ((splfild = open(ss, flag | O_BINARY), 0755) < 0)
#endif
#else  /* O_BINARY */
    if ((splfild = open(ss, flag, 0755)) < 0)
#endif  /* O_BINARY */
#endif 	/* M_WILLIAMS */
      {
	splfild = 0;	/* We do not have an open file */
	return(-1);
      }
#ifdef undf0
      YP_fprintf(errout, "Opened file %s\n", ss);
#endif
      return(splfild);
}

static void 
close_file(void)
{
  close(splfild);
  splfild = 0;
}

/* stores a cell in a file */
static void 
putout(CELL l)
{
	mywrite(splfild, (char *) &l, sizeof(CELL));
}

/* stores a pointer to a cell in a file */
static void 
putcellptr(CELL *l)
{
	mywrite(splfild, (char *) &l, sizeof(CELLPOINTER));
}

/* gets a cell from a file */
static CELL 
get_cell(void)
{
	CELL            l;
	myread(splfild, (char *) &l, Unsigned(sizeof(CELL)));
	return (l);
}

/* gets a pointer to cell from a file */
static CELL    *
get_cellptr(void)
{
	CELL           *l;
	myread(splfild, (char *) &l, Unsigned(sizeof(CELLPOINTER)));
	return (l);
}

/*
 * writes the header (at the moment YAPV*), info about what kind of saved
 * set, the work size, and the space ocuppied 
 */
static void 
put_info(int info, int mode)
{
  char     msg[256];

  sprintf(msg, "#!/bin/sh\nexec_dir=${YAPBINDIR:-%s}\nexec $exec_dir/yap $0 \"$@\"\n%cYAPV%s", BIN_DIR, 1, version_number);
  mywrite(splfild, msg, strlen(msg) + 1);
  putout(Unsigned(info));
  /* say whether we just saved the heap or everything */
  putout(mode);
  /* current state of stacks, to be used by SavedInfo */
#if defined(YAPOR) || defined(TABLING)
  /* space available in heap area */
  putout(Unsigned(GlobalBase)-Unsigned(HeapBase));
  /* space available for stacks */
  putout(Unsigned(LocalBase)-Unsigned(GlobalBase)+CellSize);
#else
  /* space available in heap area */
  putout(Unsigned(GlobalBase)-Unsigned(HeapBase));
  /* space available for stacks */
  putout(Unsigned(LocalBase)-Unsigned(GlobalBase));
#endif /* YAPOR || TABLING */
  /* space available for trail */
  putout(Unsigned(TrailTop)-Unsigned(TrailBase));
  /* Space used in heap area */
  putout(Unsigned(HeapTop)-Unsigned(HeapBase));
  /* Space used for local stack */
  putout(Unsigned(LCL0)-Unsigned(ASP));
  /* Space used for global stack */
  putout(Unsigned(H) - Unsigned(GlobalBase));
  /* Space used for trail */
  putout(Unsigned(TR) - Unsigned(TrailBase));
}

static void
save_regs(int mode)
{
  /* save all registers */
  putout((CELL)compile_arrays);
  if (mode == DO_EVERYTHING) {
    putcellptr((CELL *)CP);
    putcellptr(ENV);
    putcellptr(ASP);
    /* putout((CELL)N); */
    putcellptr(H0);
    putcellptr(LCL0);
    putcellptr(H);
    putcellptr(HB);
    putcellptr((CELL *)B);
    putcellptr((CELL *)TR);
    putcellptr(YENV);
    putcellptr(S);
    putcellptr((CELL *)P);
    putcellptr((CELL *)MyTR);
    putout(CreepFlag);
    putcellptr((CELL *)TopB);
    putcellptr((CELL *)DelayedB);
    putout(FlipFlop);
    putout(CurrentModule);
#ifdef COROUTINING
    putout(DelayedVars);
#endif
  }
  putcellptr((CELL *)HeapPlus);
  if (mode == DO_EVERYTHING) {
#ifdef COROUTINING
    putout(WokenGoals);
#endif
#ifdef  DEPTH_LIMIT
    putout(DEPTH);
#endif
  }
  /* The operand base */
  putcellptr(CellPtr(XREGS));
  putout(which_save);
  /* Now start by saving the code */
  /* the heap boundaries */
  putcellptr(CellPtr(HeapBase));
  putcellptr(CellPtr(HeapTop));
  /* and the space it ocuppies */
  putout(Unsigned(HeapUsed));
  /* Then the start of the free code */
  putcellptr(CellPtr(FreeBlocks));
  if (mode == DO_EVERYTHING) {
    /* put the old trail base, just in case it moves again */
    putout(ARG1);
    if (which_save == 2) {
      putout(ARG2);
    }
    putcellptr(CellPtr(TrailBase));
  }
}

static void
save_code_info(void)
{

  /* First the instructions */
  {
    op_numbers i;

    OPCODE my_ops[_std_top+1];
    for (i = _Ystop; i <= _std_top; ++i)
      my_ops[i] = opcode(i);
    mywrite(splfild, (char *)my_ops, sizeof(OPCODE)*(_std_top+1));
  }
  /* Then the c-functions */
  putout(NUMBER_OF_CPREDS);
  {
    UInt i;
    for (i = 0; i < NUMBER_OF_CPREDS; ++i)
      putcellptr(CellPtr(c_predicates[i]));
  }
  /* Then the cmp-functions */
  putout(NUMBER_OF_CMPFUNCS);
  {
    UInt i;
    for (i = 0; i < NUMBER_OF_CMPFUNCS; ++i) {
      putcellptr(CellPtr(cmp_funcs[i].p));
      putcellptr(CellPtr(cmp_funcs[i].f));
    }
  }
  /* and the current character codes */
  mywrite(splfild, chtype, NUMBER_OF_CHARS);
}

static void
save_heap(void)
{
  int j;
  /* Then save the whole heap */
#if defined(YAPOR) || defined(TABLING)
  /* skip the local and global data structures */
  j = Unsigned(&GLOBAL) - Unsigned(HeapBase);
  putout(j);
  mywrite(splfild, (char *) HeapBase, j);
#ifdef USE_HEAP
  j = Unsigned(HeapTop) - Unsigned(&HashChain);
  putout(j);
  mywrite(splfild, (char *) &HashChain, j);
#else
  j = Unsigned(BaseAllocArea) - Unsigned(&HashChain);
  putout(j);
  mywrite(splfild, (char *) &HashChain, j);
  j = Unsigned(HeapTop) - Unsigned(TopAllocBlockArea);
  putout(j);
  mywrite(splfild, (char *) TopAllocBlockArea, j);
#endif
#else
  j = Unsigned(HeapTop) - Unsigned(HeapBase);
  /* store 10 more cells because of the memory manager */
  mywrite(splfild, (char *) HeapBase, j);
#endif
}

static void
save_stacks(int mode)
{
  int j;
  
  switch (mode) {
  case DO_EVERYTHING:
    /* Now, go and save the state */
    /* Save the local stack */
    j = Unsigned(LCL0) - Unsigned(ASP);
    mywrite(splfild, (char *) ASP, j);
    /* Save the global stack */
    j = Unsigned(H) - Unsigned(GlobalBase);
    mywrite(splfild, (char *) GlobalBase, j);
    /* Save the trail */
    j = Unsigned(TR) - Unsigned(TrailBase);
    mywrite(splfild, (char *) TrailBase, j);
    break;
  case DO_ONLY_CODE:
    {
      tr_fr_ptr tr_ptr = TR; 
      while (tr_ptr != (tr_fr_ptr)TrailBase) {
	CELL val = TrailTerm(tr_ptr-1);
	if (IsVarTerm(val)) {
	  CELL *d1 = VarOfTerm(val);
	  if (d1 < (CELL *)HeapTop)
	    putout(val);
	} else if (IsPairTerm(val)) {
	  CELL *d1 = RepPair(val);
	  if (d1 < (CELL *)HeapTop)
	    putout(val);
	}
	tr_ptr--;
      }
    }
    putcellptr(NULL);
    break;
  }
}

static void
save_crc(void)
{
  /* Save a CRC */
  mywrite(splfild, end_msg, 256);
#ifdef MACYAP
  NewFileInfo('TEXT', 'MYap');
  if (DefVol)
    SetVol(0l, DefVol);
  DefVol = 0;
#endif
}

static Int
do_save(int mode) {
#ifdef MACYAP
  NewFileInfo('YAPS', 'MYap');
#endif
  Term t1 = Deref(ARG1);
  if (!GetName(FileNameBuf, YAP_FILENAME_MAX, t1)) {
    Error(TYPE_ERROR_LIST,t1,"save/1");
    return(FALSE);
  }
  CloseStreams(TRUE);
  if ((splfild = open_file(FileNameBuf, O_WRONLY | O_CREAT)) < 0) {
    Error(SYSTEM_ERROR,MkAtomTerm(LookupAtom(FileNameBuf)),
	  "restore/1, open(%s)", strerror(errno));
    return(FALSE);
  }
  put_info(FullSaved, mode);
  save_regs(mode);
  save_code_info();
  save_heap();
  save_stacks(mode);
  save_crc();
  close_file();
  return (TRUE);
}

/* Saves a complete prolog environment */
static Int 
p_save(void)
{
  which_save = 1;
  return(do_save(DO_EVERYTHING));
}

/* Saves a complete prolog environment */
static Int 
p_save2(void)
{
  which_save = 2;
  return(do_save(DO_EVERYTHING) && unify(ARG2,MkIntTerm(1)));
}

/* Just save the program, not the stacks */
static Int 
p_save_program(void)
{
  which_save = 0;
  return(do_save(DO_ONLY_CODE));
}

/* Now, to restore the saved code */

/* First check out if we are dealing with a valid file */
static int 
check_header(void)
{
  char            pp[80];
  char msg[256];
  CELL hp_size, gb_size, lc_size, tr_size, mode;

  /* skip the first line */
  do {
    myread(splfild, pp, 1);
  } while (pp[0] != 1);
  /* now check the version */
  sprintf(msg, "YAPV%s", version_number);
  myread(splfild, pp, Unsigned(strlen(msg) + 1));
  if (strcmp(pp, msg) != 0) {
    Error(SYSTEM_ERROR,TermNil,"not a saved Prolog state");
    return(FAIL_RESTORE);
  }
  /* check info on header */
  /* ignore info on saved state */
  get_cell();
  /* check the restore mode */
  if ((mode = get_cell()) != DO_EVERYTHING && mode != DO_ONLY_CODE) {
    Error(SYSTEM_ERROR,TermNil,"corrupted saved state");
    return(FAIL_RESTORE);
  }
  /* ignore info on stacks size */
  get_cell();
  get_cell();
  get_cell();
  /* now, check whether we got enough enough space to load the
     saved space */
  if ((hp_size = get_cell()) > Unsigned(AuxTop) - Unsigned(HeapBase)) {
    Error(SYSTEM_ERROR,TermNil,"out of heap space, Yap needs %d", hp_size);
    return(FAIL_RESTORE);
  }
  if (mode == DO_EVERYTHING) {
    if ((lc_size = get_cell())+(gb_size=get_cell()) > Unsigned(LocalBase) - Unsigned(GlobalBase)) {
      Error(SYSTEM_ERROR,TermNil,"out of stack space, Yap needs %d", lc_size+gb_size);
      return(FALSE);
    }
    if ((tr_size = get_cell()) > Unsigned(TrailTop) - Unsigned(TrailBase)) {
      Error(SYSTEM_ERROR,TermNil,"out of trail space, Yap needs %d", tr_size);
      return(FAIL_RESTORE);
    }
  } else {
    /* skip cell size */
    get_cell();
    get_cell();
    get_cell();
  }
  return(mode);
}

/* Gets the state of the heap, and evaluates the related variables */
static void 
get_heap_info(void)
{
  OldHeapBase = (ADDR) get_cellptr();
  OldHeapTop = (ADDR) get_cellptr();
  OldHeapUsed = (Int) get_cell();
  FreeBlocks = (BlockHeader *) get_cellptr();
  HDiff = Unsigned(HeapBase) - Unsigned(OldHeapBase);
}

/* Gets the register array */
/* Saves the old bases for the work areas */
/* and evaluates the difference from the old areas to the new ones */
static void 
get_regs(int flag)
{
  CELL           *NewGlobalBase = (CELL *)GlobalBase;
  CELL           *NewLCL0 = LCL0;
  CELL           *OldXREGS;

  /* Get regs */
  compile_arrays = (int)get_cell();
  if (flag == DO_EVERYTHING) {
    CP = (yamop *)get_cellptr();
    ENV = get_cellptr();
    ASP = get_cellptr();
    /* N = get_cell(); */
    H0 = get_cellptr();
    LCL0 = get_cellptr();
    H = get_cellptr();
    HB = get_cellptr();
    B = (choiceptr)get_cellptr();
    TR = (tr_fr_ptr)get_cellptr();
    YENV = get_cellptr();
    S = get_cellptr();
    P = (yamop *)get_cellptr();
    MyTR = (tr_fr_ptr)get_cellptr();
    CreepFlag = get_cell();
    TopB = (choiceptr)get_cellptr();
    DelayedB = (choiceptr)get_cellptr();
    FlipFlop = get_cell();
    CurrentModule = get_cell();
#ifdef COROUTINING
    DelayedVars = get_cell();
#endif
  }
  HeapPlus = (ADDR)get_cellptr();
  if (flag == DO_EVERYTHING) {
#ifdef COROUTINING
    WokenGoals = get_cell();
#endif
#ifdef  DEPTH_LIMIT
    DEPTH = get_cell();
#endif
  }
  /* Get the old bases */
  OldXREGS = get_cellptr();
  which_save = get_cell();
  XDiff =  (CELL)XREGS - (CELL)OldXREGS;
  get_heap_info();
  if (flag == DO_EVERYTHING) {
    ARG1 = get_cell();
    if (which_save == 2) {
      ARG2 = get_cell();
    }
    /* get old trail base */
    OldTrailBase = (ADDR)get_cellptr();
    /* Save the old register where we can easily access them */
    OldASP = ASP;
    OldLCL0 = LCL0;
    OldGlobalBase = (CELL *)GlobalBase;
    OldH = H;
    OldTR = TR;
    GDiff = Unsigned(NewGlobalBase) - Unsigned(GlobalBase);
    LDiff = Unsigned(NewLCL0) - Unsigned(LCL0);
    TrDiff = LDiff;
    GlobalBase = (ADDR)NewGlobalBase;
    LCL0 = NewLCL0;
  }
}

/* Get the old opcodes and place them in a hash table */
static void 
get_insts(OPCODE old_ops[])
{
  myread(splfild, (char *)old_ops, sizeof(OPCODE)*(_std_top+1));
}

/* check if the old functions are the same as the new ones, or if they
   have moved around. Note that we don't need these functions afterwards */
static int 
check_funcs(void)
{
  UInt old_NUMBER_OF_CPREDS, old_NUMBER_OF_CMPFUNCS;
  int out = FALSE;

  if ((old_NUMBER_OF_CPREDS = get_cell()) != NUMBER_OF_CPREDS) {
    Error(SYSTEM_ERROR,TermNil,"bad saved state, different number of functions (%d vs %d), system corrupted, old_NUMBER_OF_CPREDS, NUMBER_OF_CPREDS");
  }
  {
    unsigned int i;
    for (i = 0; i < old_NUMBER_OF_CPREDS; ++i) {
      CELL *old_pred = get_cellptr();
      out = (out || old_pred != CellPtr(c_predicates[i]));
    }
  }
  if ((old_NUMBER_OF_CMPFUNCS = get_cell()) != NUMBER_OF_CMPFUNCS) {
    Error(SYSTEM_ERROR,TermNil,"bad saved state, different number of comparison functions (%d vs %d), system corrupted", old_NUMBER_OF_CMPFUNCS, NUMBER_OF_CMPFUNCS);
  }
  {
    unsigned int i;
    for (i = 0; i < old_NUMBER_OF_CMPFUNCS; ++i) {
      CELL *old_p = get_cellptr();
      CELL *old_f = get_cellptr();
      /*      if (AddrAdjust((ADDR)old_p) != cmp_funcs[i].p) {
	
	Error(SYSTEM_ERROR,TermNil,"bad saved state, comparison function is in wrong place (%p vs %p), system corrupted", AddrAdjust((ADDR)old_p), cmp_funcs[i].p);
	} */
      cmp_funcs[i].p = (PredEntry *)AddrAdjust((ADDR)old_p);
      out = (out ||
	     old_f != CellPtr(cmp_funcs[i].f));
    }
  }
  return(out);
}

/* Get the old atoms hash table */
static void 
get_hash(void)
{
  myread(splfild, chtype , NUMBER_OF_CHARS);
}

/* Copy all of the old code to the new Heap */
static void 
CopyCode(void)
{
#if defined(YAPOR) || defined(TABLING)
  /* skip the local and global data structures */
  CELL j = get_cell();
  if (j != Unsigned(&GLOBAL) - Unsigned(HeapBase)) {
    Error(FATAL_ERROR,TermNil,"bad saved state, system corrupted");
  }
  myread(splfild, (char *) HeapBase, j);
#ifdef USE_HEAP
  j = get_cell();
  myread(splfild, (char *) &HashChain, j);
#else
  j = get_cell();
  if (j != Unsigned(BaseAllocArea) - Unsigned(&HashChain)) {
    Error(FATAL_ERROR,TermNil,"bad saved state, system corrupted");
  }
  myread(splfild, (char *) &HashChain, j);
  j = get_cell();
  myread(splfild, (char *) TopAllocBlockArea, j);
#endif
#else
  myread(splfild, (char *) HeapBase,
	 (Unsigned(OldHeapTop) - Unsigned(OldHeapBase)));
#endif
}

/* Copy the local and global stack and also the trail to their new home */
/* In REGS we still have nonadjusted values !! */
static void 
CopyStacks(void)
{
  Int             j;
  char           *NewASP;

  j = Unsigned(OldLCL0) - Unsigned(ASP);
  NewASP = (char *) (Unsigned(ASP) + (Unsigned(LCL0) - Unsigned(OldLCL0)));
  myread(splfild, (char *) NewASP, j);
  j = Unsigned(H) - Unsigned(OldGlobalBase);
  myread(splfild, (char *) GlobalBase, j);
  j = Unsigned(TR) - Unsigned(OldTrailBase);
  myread(splfild, TrailBase, j);
}

/* Copy the local and global stack and also the trail to their new home */
/* In REGS we still have nonadjusted values !! */
static void 
CopyTrailEntries(void)
{
  CELL           entry, *Entries;

  Entries = (CELL *)TrailBase;
  do {
    *Entries++ = entry = get_cell();
  } while ((CODEADDR)entry != NULL);
}

/* get things which are saved in the file */
static int 
get_coded(int flag, OPCODE old_ops[])
{
  char my_end_msg[256];
  int funcs_moved = FALSE;

  get_regs(flag);
  get_insts(old_ops);
  funcs_moved = check_funcs();
  get_hash();
  CopyCode();
  switch (flag) {
  case DO_EVERYTHING:
    CopyStacks();
    break;
  case DO_ONLY_CODE:
    CopyTrailEntries();
    break;
  }
  /* Check CRC */
  myread(splfild, my_end_msg, 256);
  if (strcmp(end_msg,my_end_msg) != 0)
    Error(FATAL_ERROR,TermNil,"bad saved state, system corrupted");
  return(funcs_moved);
}

/* Now, everything on its place so you must adjust the pointers */

/* restore the failcodes */
static void 
restore_codes(void)
{
  heap_regs->heap_top = AddrAdjust(OldHeapTop);
#ifdef YAPOR
  heap_regs->getworkfirsttimecode.opc = opcode(_getwork_first_time);
  heap_regs->getworkcode.opc = opcode(_getwork);
  INIT_YAMOP_LTT(&(heap_regs->getworkcode), 0);
  heap_regs->getworkcode_seq.opc = opcode(_getwork_seq);
  INIT_YAMOP_LTT(&(heap_regs->getworkcode_seq), 0);
#endif /* YAPOR */
#ifdef TABLING
  heap_regs->tablecompletioncode.opc = opcode(_table_completion);
  heap_regs->tableanswerresolutioncode.opc = opcode(_table_answer_resolution);
#ifdef YAPOR
  INIT_YAMOP_LTT(&(heap_regs->tablecompletioncode), 0);
  INIT_YAMOP_LTT(&(heap_regs->tableanswerresolutioncode), 0);
#endif /* YAPOR */
#endif /* TABLING */
  heap_regs->failcode = opcode(_op_fail);
  heap_regs->failcode_1 = opcode(_op_fail);
  heap_regs->failcode_2 = opcode(_op_fail);
  heap_regs->failcode_3 = opcode(_op_fail);
  heap_regs->failcode_4 = opcode(_op_fail);
  heap_regs->failcode_5 = opcode(_op_fail);
  heap_regs->failcode_6 = opcode(_op_fail);
  heap_regs->trustfailcode = opcode(_trust_fail);
  heap_regs->yescode = opcode(_Ystop);
#ifdef YAPOR
  heap_regs->nocode.opc = opcode(_Nstop);
  INIT_YAMOP_LTT(&(heap_regs->nocode), 1);
#else
  heap_regs->nocode = opcode(_Nstop);
#endif  /* YAPOR */

#ifdef YAPOR
  INIT_YAMOP_LTT(&(heap_regs->rtrycode), 1);
#endif /* YAPOR */
  ((yamop *)(&heap_regs->rtrycode))->opc = opcode(_retry_and_mark);
  if (((yamop *)(&heap_regs->rtrycode))->u.ld.d != NIL)
    ((yamop *)(&heap_regs->rtrycode))->u.ld.d =
      CodeAddrAdjust(((yamop *)(&heap_regs->rtrycode))->u.ld.d);
  {
    int             arity;
    arity = heap_regs->clausecode.arity;
    if (heap_regs->clausecode.clause != NIL)
      heap_regs->clausecode.clause =
	CodeAddrAdjust(heap_regs->clausecode.clause);
    if (arity) {
      heap_regs->clausecode.func =
	FuncAdjust(heap_regs->clausecode.func); 
    } else {
      /* an atom */
      heap_regs->clausecode.func =
	(Functor)AtomAdjust((Atom)(heap_regs->clausecode.func));
    }
  }
  /* restore consult stack. It consists of heap pointers, so it
     is easy to fix.
  */
  heap_regs->consultlow  = 
    ConsultObjAdjust(heap_regs->consultlow);
  heap_regs->consultbase =
    ConsultObjAdjust(heap_regs->consultbase);
  heap_regs->consultsp   =
    ConsultObjAdjust(heap_regs->consultsp);
  {
    /* we assume all pointers have the same size */
    register consult_obj *pt = heap_regs->consultsp;
    while (pt <
	   heap_regs->consultlow+heap_regs->consultcapacity) {
      pt->p = PropAdjust(pt->p);
      pt ++;
    }
  }
#if USE_THREADED_CODE
  heap_regs->op_rtable = (opentry *)
    CodeAddrAdjust((CODEADDR)(heap_regs->op_rtable));
#endif
  if (heap_regs->atprompt != NIL) {
    heap_regs->atprompt =
      AtomAdjust(heap_regs->atprompt);
  }
  heap_regs->undef_op = opcode(_undef_p);
  heap_regs->index_op = opcode(_index_pred);
  if (heap_regs->char_conversion_table != NULL) {
    heap_regs->char_conversion_table = (char *)
      AddrAdjust((ADDR)heap_regs->char_conversion_table);
  }
  if (heap_regs->char_conversion_table2 != NULL) {
    heap_regs->char_conversion_table2 = (char *)
      AddrAdjust((ADDR)heap_regs->char_conversion_table2);
  }
  if (heap_regs->dead_clauses != NULL) {
    heap_regs->dead_clauses = (Clause *)
      AddrAdjust((ADDR)(heap_regs->dead_clauses));
  }
  /* vsc: FIXME !!!!! */
  if (heap_regs->db_queues != NULL) {
    heap_regs->db_queues = (struct idb_queue *)
      AddrAdjust((ADDR)(heap_regs->db_queues));
  }
  if (heap_regs->db_queues_cache != NULL) {
    heap_regs->db_queues_cache = (struct idb_queue *)
      AddrAdjust((ADDR)(heap_regs->db_queues_cache));
  }
  heap_regs->retry_recorded_code = 
    PtoOpAdjust(heap_regs->retry_recorded_code);
  heap_regs->retry_recorded_k_code =
    PtoOpAdjust(heap_regs->retry_recorded_k_code);
  heap_regs->retry_drecorded_code =
    PtoOpAdjust(heap_regs->retry_drecorded_code);
  heap_regs->retry_c_recordedp_code =
    PtoOpAdjust(heap_regs->retry_c_recordedp_code);
  if (heap_regs->IntKeys != NULL) {
    heap_regs->IntKeys = (Prop *)AddrAdjust((ADDR)(heap_regs->IntKeys));
    {
      UInt i;
      for (i = 0; i < heap_regs->int_keys_size; i++) {
	if (heap_regs->IntKeys[i] != NIL) {
	  Prop p0 = heap_regs->IntKeys[i] = PropAdjust(heap_regs->IntKeys[i]);
	  RestoreEntries(RepProp(p0));
	}
      }
    }
  }
  if (heap_regs->IntBBKeys != NULL) {
    heap_regs->IntBBKeys = (Prop *)AddrAdjust((ADDR)(heap_regs->IntBBKeys));
    {
      UInt i;
      for (i = 0; i < heap_regs->int_bb_keys_size; i++) {
	if (heap_regs->IntBBKeys[i] != NIL) {
	  Prop p0 = heap_regs->IntBBKeys[i] = PropAdjust(heap_regs->IntBBKeys[i]);
	  RestoreEntries(RepProp(p0));
	}
      }
    }
  }
  {
    /* adjust atoms in atom table */
    unsigned int i = 0;

    for (i = 0; i < heap_regs->no_of_modules; i++) {
      heap_regs->module_name[i] = AtomTermAdjust(heap_regs->module_name[i]);
    }
  }
  heap_regs->atom_abol = AtomAdjust(heap_regs->atom_abol);
  heap_regs->atom_append = AtomAdjust(heap_regs->atom_append);
  heap_regs->atom_array = AtomAdjust(heap_regs->atom_array);
  heap_regs->atom_assert = AtomAdjust(heap_regs->atom_assert);
  heap_regs->atom_alarm = AtomAdjust(heap_regs->atom_alarm);
  heap_regs->atom_b = AtomAdjust(heap_regs->atom_b);
  heap_regs->atom_break = AtomAdjust(heap_regs->atom_break);
  heap_regs->atom_call = AtomAdjust(heap_regs->atom_call);
  heap_regs->atom_catch = AtomAdjust(heap_regs->atom_catch);
  heap_regs->atom_comma = AtomAdjust(heap_regs->atom_comma);
  heap_regs->atom_cpu_time = AtomAdjust(heap_regs->atom_cpu_time);
  heap_regs->atom_csult = AtomAdjust(heap_regs->atom_csult);
  heap_regs->atom_cut = AtomAdjust(heap_regs->atom_cut);
  heap_regs->atom_cut_by = AtomAdjust(heap_regs->atom_cut_by);
#ifdef EUROTRA
#ifdef SFUNC
  heap_regs->atom_dollar_undef = AtomAdjust(heap_regs->atom_dollar_undef);
#endif
#endif
  heap_regs->atom_e = AtomAdjust(heap_regs->atom_e);
  heap_regs->atom_e_q = AtomAdjust(heap_regs->atom_e_q);
  heap_regs->atom_eof = AtomAdjust(heap_regs->atom_eof);
#ifdef EUROTRA
  heap_regs->atom_f_b = AtomAdjust(heap_regs->atom_f_b);
#endif
  heap_regs->atom_fail = AtomAdjust(heap_regs->atom_fail);
  heap_regs->atom_false = AtomAdjust(heap_regs->atom_false);
  heap_regs->atom_fast = AtomAdjust(heap_regs->atom_fast);
  heap_regs->atom_g_t = AtomAdjust(heap_regs->atom_g_t);
  heap_regs->atom_gc = AtomAdjust(heap_regs->atom_gc);
  heap_regs->atom_gc_margin = AtomAdjust(heap_regs->atom_gc_margin);
  heap_regs->atom_gc_trace = AtomAdjust(heap_regs->atom_gc_trace);
  heap_regs->atom_gc_verbose = AtomAdjust(heap_regs->atom_gc_verbose);
  heap_regs->atom_global = AtomAdjust(heap_regs->atom_global);
  heap_regs->atom_heap_used = AtomAdjust(heap_regs->atom_heap_used);
  heap_regs->atom_index = AtomAdjust(heap_regs->atom_index);
  heap_regs->atom_inf = AtomAdjust(heap_regs->atom_inf);
  heap_regs->atom_l_t = AtomAdjust(heap_regs->atom_l_t);
  heap_regs->atom_local = AtomAdjust(heap_regs->atom_local);
  heap_regs->atom_meta_call = AtomAdjust(heap_regs->atom_meta_call);
  heap_regs->atom_minus = AtomAdjust(heap_regs->atom_minus);
  heap_regs->atom_nan = AtomAdjust(heap_regs->atom_nan);
  heap_regs->atom_otherwise = AtomAdjust(heap_regs->atom_otherwise);
  heap_regs->atom_pi = AtomAdjust(heap_regs->atom_pi);
  heap_regs->atom_plus = AtomAdjust(heap_regs->atom_plus);
  heap_regs->atom_portray = AtomAdjust(heap_regs->atom_portray);
  heap_regs->atom_profile = AtomAdjust(heap_regs->atom_profile);
  heap_regs->atom_random = AtomAdjust(heap_regs->atom_random);
  heap_regs->atom_read = AtomAdjust(heap_regs->atom_read);
  heap_regs->atom_repeat = AtomAdjust(heap_regs->atom_repeat);
  heap_regs->atom_restore_regs = AtomAdjust(heap_regs->atom_restore_regs);
#if HAVE_SIGACTION
  heap_regs->atom_sig_pending = AtomAdjust(heap_regs->atom_sig_pending);
#endif
  heap_regs->atom_stack_free = AtomAdjust(heap_regs->atom_stack_free);
  heap_regs->atom_true = AtomAdjust(heap_regs->atom_true);
  heap_regs->atom_user = AtomAdjust(heap_regs->atom_user);
  heap_regs->atom_usr_err = AtomAdjust(heap_regs->atom_usr_err);
  heap_regs->atom_usr_in = AtomAdjust(heap_regs->atom_usr_in);
  heap_regs->atom_usr_out = AtomAdjust(heap_regs->atom_usr_out);
  heap_regs->atom_version_number = AtomAdjust(heap_regs->atom_version_number);
  heap_regs->atom_write = AtomAdjust(heap_regs->atom_write);
#ifdef   USE_SOCKET
  heap_regs->functor_af_inet = FuncAdjust(heap_regs->functor_af_inet);
  heap_regs->functor_af_local = FuncAdjust(heap_regs->functor_af_local);
  heap_regs->functor_af_unix = FuncAdjust(heap_regs->functor_af_unix);
#endif
  heap_regs->functor_alt_not = FuncAdjust(heap_regs->functor_alt_not);
  heap_regs->functor_arrow = FuncAdjust(heap_regs->functor_arrow);
  heap_regs->functor_assert = FuncAdjust(heap_regs->functor_assert);
#ifdef COROUTINING
  heap_regs->functor_att_goal = FuncAdjust(heap_regs->functor_att_goal);
#endif
  heap_regs->functor_braces = FuncAdjust(heap_regs->functor_braces);
  heap_regs->functor_call = FuncAdjust(heap_regs->functor_call);
  heap_regs->functor_cut_by = FuncAdjust(heap_regs->functor_cut_by);
  heap_regs->functor_comma = FuncAdjust(heap_regs->functor_comma);
  heap_regs->functor_csult = FuncAdjust(heap_regs->functor_csult);
  heap_regs->functor_eq = FuncAdjust(heap_regs->functor_eq);
  heap_regs->functor_execute_in_mod = FuncAdjust(heap_regs->functor_execute_in_mod);
  heap_regs->functor_execute_within = FuncAdjust(heap_regs->functor_execute_within);
  heap_regs->functor_g_atom = FuncAdjust(heap_regs->functor_g_atom);
  heap_regs->functor_g_atomic = FuncAdjust(heap_regs->functor_g_atomic);
  heap_regs->functor_g_compound = FuncAdjust(heap_regs->functor_g_compound);
  heap_regs->functor_g_float = FuncAdjust(heap_regs->functor_g_float);
  heap_regs->functor_g_integer = FuncAdjust(heap_regs->functor_g_integer);
  heap_regs->functor_g_number = FuncAdjust(heap_regs->functor_g_number);
  heap_regs->functor_g_primitive = FuncAdjust(heap_regs->functor_g_primitive);
  heap_regs->functor_g_var = FuncAdjust(heap_regs->functor_g_var);
  heap_regs->functor_last_execute_within = FuncAdjust(heap_regs->functor_last_execute_within);
  heap_regs->functor_list = FuncAdjust(heap_regs->functor_list);
  heap_regs->functor_module = FuncAdjust(heap_regs->functor_module);
#ifdef MULTI_ASSIGNMENT_VARIABLES
  heap_regs->functor_mutable = FuncAdjust(heap_regs->functor_mutable);
#endif
  heap_regs->functor_not = FuncAdjust(heap_regs->functor_not);
  heap_regs->functor_or = FuncAdjust(heap_regs->functor_or);
  heap_regs->functor_portray = FuncAdjust(heap_regs->functor_portray);
  heap_regs->functor_query = FuncAdjust(heap_regs->functor_query);
  heap_regs->functor_spy = FuncAdjust(heap_regs->functor_spy);
  heap_regs->functor_stream = FuncAdjust(heap_regs->functor_stream);
  heap_regs->functor_stream_pos = FuncAdjust(heap_regs->functor_stream_pos);
  heap_regs->functor_stream_eOS = FuncAdjust(heap_regs->functor_stream_eOS);
  heap_regs->functor_change_module = FuncAdjust(heap_regs->functor_change_module);
  heap_regs->functor_current_module = FuncAdjust(heap_regs->functor_current_module);
  heap_regs->functor_u_minus = FuncAdjust(heap_regs->functor_u_minus);
  heap_regs->functor_u_plus = FuncAdjust(heap_regs->functor_u_plus);
  heap_regs->functor_v_bar = FuncAdjust(heap_regs->functor_v_bar);
  heap_regs->functor_var = FuncAdjust(heap_regs->functor_var);
#ifdef EUROTRA
  heap_regs->term_dollar_u = AtomTermAdjust(heap_regs->term_dollar_u);
#endif
  heap_regs->term_prolog = AtomTermAdjust(heap_regs->term_prolog);
  heap_regs->term_refound_var = AtomTermAdjust(heap_regs->term_refound_var);
  heap_regs->file_aliases =
    (struct AliasDescS *)AddrAdjust((ADDR)heap_regs->file_aliases);
  heap_regs->yap_lib_dir =
    (char *)AddrAdjust((ADDR)heap_regs->yap_lib_dir);
  heap_regs->pred_goal_expansion =
    (PredEntry *)AddrAdjust((ADDR)heap_regs->pred_goal_expansion);
  heap_regs->pred_meta_call =
    (PredEntry *)AddrAdjust((ADDR)heap_regs->pred_meta_call);
  heap_regs->pred_catch =
    (PredEntry *)AddrAdjust((ADDR)heap_regs->pred_catch);
  heap_regs->pred_throw =
    (PredEntry *)AddrAdjust((ADDR)heap_regs->pred_throw);
  heap_regs->pred_handle_throw =
    (PredEntry *)AddrAdjust((ADDR)heap_regs->pred_handle_throw);
  if (heap_regs->undef_code != NULL)
    heap_regs->undef_code = (PredEntry *)PtoHeapCellAdjust((CELL *)(heap_regs->undef_code));
  if (heap_regs->creep_code != NULL)
    heap_regs->creep_code = (PredEntry *)PtoHeapCellAdjust((CELL *)(heap_regs->creep_code));
  if (heap_regs->spy_code != NULL)
    heap_regs->spy_code = (PredEntry *)PtoHeapCellAdjust((CELL *)(heap_regs->spy_code));
#ifdef COROUTINING
#ifdef MULTI_ASSIGNMENT_VARIABLES
    if (heap_regs->wake_up_code != NULL)
      heap_regs->wake_up_code = (PredEntry *)PtoHeapCellAdjust((CELL *)(heap_regs->wake_up_code));
    heap_regs->mutable_list =
      AbsAppl(PtoGloAdjust(RepAppl(heap_regs->mutable_list)));
    heap_regs->atts_mutable_list =
      AbsAppl(PtoGloAdjust(RepAppl(heap_regs->atts_mutable_list)));
#endif
#endif
  if (heap_regs->last_wtime != NULL)
    heap_regs->last_wtime = (void *)PtoHeapCellAdjust((CELL *)(heap_regs->last_wtime));
}

/* restore some heap registers */
static void 
restore_heap_regs(void)
{
  HeapPlus = AddrAdjust(HeapPlus);
  *((YAP_SEG_SIZE *) HeapTop) = InUseFlag;
  HeapMax = HeapUsed = OldHeapUsed;
  restore_codes();
}

/* adjust abstract machine registers */
static void 
restore_regs(int flag)
{
  restore_heap_regs();
  if (flag == DO_EVERYTHING) {
    CP = PtoOpAdjust(CP);
    ENV = PtoLocAdjust(ENV);
    ASP = PtoLocAdjust(ASP);
    H = PtoGloAdjust(H);
    B = (choiceptr)PtoLocAdjust(CellPtr(B));
    TR = PtoTRAdjust(TR);
    P = PtoOpAdjust(P);
    HB = PtoLocAdjust(HB);
    YENV = PtoLocAdjust(YENV);
    S = PtoGloAdjust(S);
    HeapPlus = AddrAdjust(HeapPlus);
    if (MyTR)
      MyTR = PtoTRAdjust(MyTR);
#ifdef COROUTINING
    DelayedVars = AbsAppl(PtoGloAdjust(RepAppl(DelayedVars)));
#ifdef MULTI_ASSIGNMENT_VARIABLES
    WokenGoals = AbsAppl(PtoGloAdjust(RepAppl(WokenGoals)));
#endif
#endif
  }
}

/* Restoring the heap */

/* Converts a structure of the DB, as it was saved in the heap */
/* uses a variable base */
static void 
ConvDBStruct(Term Struct, char *tbase, CELL size)
{
  CELL            *TermP;
  Functor         f;
  int             Arity, i;

  TermP = (CELL *)(tbase + (CELL)RepAppl(Struct));
  f = FuncAdjust((Functor)(*TermP));
  *(Functor *)TermP = f;
  Arity = ArityOfFunctor(f);
  TermP++;
  for (i = 0; i < Arity; i++) {
    register Term   t = *TermP;
    if (IsVarTerm(t)) {
      /* do nothing */
    } else if (IsAtomTerm(t)) {
      /* these are the only ones that may actually need to be changed */
      *TermP = AtomTermAdjust(t);
    } else if (IsApplTerm(t)) {
      CELL offset = (CELL)RepAppl(Struct);
      if (offset > size) {
	*TermP = AbsAppl(CellPtoHeapAdjust(RepAppl(t)));
      }
      ConvDBStruct(t, tbase, size);
    } else if (IsPairTerm(t)) {
      ConvDBList(t, tbase, size);
    }
    TermP++;
  }
}

/* Converts a list of the DB, as it was saved in the heap */
/* uses a variable base */
static void 
ConvDBList(Term List, char *tbase, CELL size)
{
  CELL            *TermP;
  int             i;
  TermP = (CELL *)(tbase + (CELL) RepPair(List));
  for (i = 0; i < 2; i++) {
    register Term   t = *TermP;
    if (IsVarTerm(t)) {
      /* do nothing */
    } else if (IsAtomTerm(t))
      *TermP = AtomTermAdjust(t);
    else if (IsApplTerm(t))
      ConvDBStruct(t, tbase, size);
    else if (IsPairTerm(t))
      ConvDBList(t, tbase, size);
    TermP++;
  }
}

/* adjusts terms stored in the data base, when they have no variables */
static Term 
AdjustDBTerm(Term trm)
{
  Term           *p;
  
  if (IsAtomTerm(trm))
    return (AtomTermAdjust(trm));
  if (IsPairTerm(trm)) {
    p = PtoHeapCellAdjust(RepPair(trm));
    *p = AdjustDBTerm(*p);
    ++p;
    *p = AdjustDBTerm(*p);
    return (AbsPair(p-1));
  }
  if (IsApplTerm(trm)) {
    int             Arity, i;
    Functor f;
    Term *p0 = p = PtoHeapCellAdjust(RepAppl(trm));
    f = FuncAdjust((Functor)(*p));
    *p = (Term)f ;
    Arity = ArityOfFunctor(f);
    p++;
    for (i = 0; i < Arity; ++i) {
      *p = AdjustDBTerm(*p);
      p++;
    }
    return (AbsAppl(p0));
  }
  return (trm);
}

static void
recompute_mask(DBRef dbr)
{
  CELL *x = (CELL *)HeapTop, *tp;
  unsigned int Arity, i;
  Term out;
  char *tbase = CharP(dbr->Contents-1);

  if (IsPairTerm(dbr->Entry)) {

    out = AbsPair(x);
    Arity = 2;
    tp = (CELL *)(tbase + (CELL) RepPair(dbr->Entry));
  } else {
    Functor f;
    
    tp = (CELL *)(tbase + (CELL) RepAppl(dbr->Entry));
    f = (Functor)(*tp++);
    out = AbsAppl(x);
    Arity = ArityOfFunctor(f);
    *x++ = (CELL)f;
    if (Arity > 3) Arity = 3;
  }
  for (i = 0; i < Arity; i++) {
    register Term   tw = *tp++;
    if (IsVarTerm(tw)) {
      RESET_VARIABLE(x);
    } else if (IsApplTerm(tw)) {
      /* just fetch the functor from where it is in the data-base.
	 This guarantees we have access to references and friends. */
      CELL offset = (CELL)RepAppl(tw);
      if (offset > dbr->NOfCells*sizeof(CELL))
	*x = tw;
      else
	*x = AbsAppl((CELL *)(tbase + offset));
    } else if (IsAtomicTerm(tw)) {
      *x = tw;
    } else if (IsPairTerm(tw)) {
      *x = AbsPair(x);
    }
    x++;
  }
  dbr->Mask = EvalMasks(out, &(dbr->Key));
}

static void
RestoreDBEntry(DBRef dbr)
{
#ifdef DEBUG_RESTORE
  YP_fprintf(errout, "Restoring at %x", dbr);
  if (dbr->Flags & DBAtomic)
    YP_fprintf(errout, " an atomic term\n");
  else if (dbr->Flags & DBNoVars)
    YP_fprintf(errout, " with no vars\n");
  else if (dbr->Flags & DBComplex)
    YP_fprintf(errout, " complex term\n");
  else if (dbr->Flags & DBIsRef)
    YP_fprintf(errout, " a ref\n");
  else
    YP_fprintf(errout, " a var\n");
#endif
  dbr->Parent = (DBProp)AddrAdjust((ADDR)(dbr->Parent));
  if (dbr->Code != NIL)
    dbr->Code = CodeAddrAdjust(dbr->Code);
  if (dbr->Flags & DBAtomic) {
    if (IsAtomTerm(dbr->Entry))
      dbr->Entry = AtomTermAdjust(dbr->Entry);
  } else if (dbr->Flags & DBNoVars)
    dbr->Entry = (CELL) AdjustDBTerm((Term) dbr->Entry);
  else if (dbr->Flags & DBComplex) {
    if (IsApplTerm((Term) dbr->Entry))
      ConvDBStruct((Term) dbr->Entry, CharP(dbr->Contents-1), dbr->NOfCells*sizeof(CELL));
    else
      ConvDBList((Term) dbr->Entry, CharP(dbr->Contents-1), dbr->NOfCells*sizeof(CELL));
  }
  if (dbr->Prev != NULL)
    dbr->Prev = DBRefAdjust(dbr->Prev);
  if (dbr->Next != NULL)
    dbr->Next = DBRefAdjust(dbr->Next);
  if (dbr->Flags & DBWithRefs) {
    DBRef          *cp;
    DBRef            tm;
    cp = (DBRef *) ((CODEADDR) dbr + SizeOfBlock(CodePtr(dbr)));
    while ((tm = *--cp) != 0)
      *cp = DBRefAdjust(tm);
  }
#ifdef DEBUG_RESTORE2
  YP_fprintf(errout, "Recomputing masks\n");
#endif
  if (dbr->Flags & DBNoVars) {
    dbr->Mask = EvalMasks((Term) dbr->Entry, &(dbr->Key));
  } else if (dbr->Flags & DBComplex) {
    /* This is quite nasty, we want to recalculate the mask but
       we don't want to rebuild the whole term. We'll just build whatever we
       need to recompute the mask.
    */
    recompute_mask(dbr);
  }
}

/* Restores a DB structure, as it was saved in the heap */
static void 
RestoreDB(DBEntry *pp)
{
  register DBRef  dbr;

  if (pp->First != NULL)
    pp->First = DBRefAdjust(pp->First);
  if (pp->Last != NULL)
    pp->Last = DBRefAdjust(pp->Last);
#ifndef KEEP_ENTRY_AGE
  if (pp->FirstNEr != NULL)
    pp->FirstNEr = DBRefAdjust(pp->FirstNEr);
#endif
  if (pp->ArityOfDB)
    pp->FunctorOfDB = FuncAdjust(pp->FunctorOfDB);
  else
    pp->FunctorOfDB = (Functor) AtomAdjust((Atom)(pp->FunctorOfDB));
  dbr = pp->First;
  /* While we have something in the data base, restore it */
  while (dbr) {
    RestoreDBEntry(dbr);
    dbr = dbr->Next;
  }
}

/* Restores a DB structure, as it was saved in the heap */
static void 
RestoreBB(BlackBoardEntry *pp)
{
  if (pp->Element) {
    register DBRef  dbr;

    pp->Element = DBRefAdjust(pp->Element);
#ifdef DEBUG_RESTORE
    YP_fprintf(errout, "Restoring at %x", dbr);
    if (dbr->Flags & DBAtomic)
      YP_fprintf(errout, " an atomic term\n");
    else if (dbr->Flags & DBNoVars)
      YP_fprintf(errout, " with no vars\n");
    else if (dbr->Flags & DBComplex)
      YP_fprintf(errout, " complex term\n");
    else if (dbr->Flags & DBIsRef)
      YP_fprintf(errout, " a ref\n");
    else
      YP_fprintf(errout, " a var\n");
#endif
    dbr = pp->Element;
    RestoreDBEntry(dbr);
  }
  pp->KeyOfBB = AtomAdjust(pp->KeyOfBB);
}

#define HASH_SHIFT 6

/*
 * This is used to make an hash table correct, after displacing its elements,
 * HCEnd should point to an area of free space, usually in the heap. The
 * routine is very dependent on the hash function used, and it destroys the
 * previous "hit" order 
 */
static void 
rehash(CELL *oldcode, int NOfE, int KindOfEntries)
{
  register CELL  *savep, *basep;
  CELL           *oldp = oldcode;
  int             TableSize = NOfE - 1, NOfEntries;
  register int    i;
  int             hash;
  CELL            WorkTerm, failplace = 0;
  CELL           *Base = oldcode;

  if (HDiff == 0)
      return;
  basep = H;
  if (H + (NOfE*2) > ASP) {
    basep = (CELL *)TR;
    if (basep + (NOfE*2) > (CELL *)TrailTop) {
      if (!growtrail((ADDR)(basep + (NOfE*2))-TrailTop)) {
	Error(SYSTEM_ERROR, TermNil,
	      "not enough space to restore hash tables for indexing");
	exit_yap(1, "");
      }
    }
  }
  for (i = 0; i < NOfE; ++i) {
    if (*oldp == 0) {
      failplace = oldp[1];
      break;
    }
    oldp += 2;
  }
  savep = basep;
  oldp = oldcode;
  for (i = 0; i < NOfE; ++i) {
    if (*oldp != 0) {
      savep[0] = oldp[0];
      savep[1] = oldp[1];
      oldp[0] = 0;
      oldp[1] = failplace;
      savep += 2;
    }
    oldp += 2;
  }
  NOfEntries = (savep - basep)/2;
  savep = basep;
  for (i = 0; i < NOfEntries; ++i) {
    register Int    d;
    CELL *hentry;

    WorkTerm = savep[i*2];
    hash = (Unsigned(WorkTerm) >> HASH_SHIFT) & TableSize;
    hentry = Base + hash * 2;
    d = TableSize & (Unsigned(WorkTerm) | 1);
    while (*hentry) {
#ifdef DEBUG
#ifdef CLASHES
      ++clashes;
#endif /* CLASHES */
#endif /* DEBUG */
      hash = (hash + d) & TableSize;
      hentry = Base + hash * 2;
    }
    hentry[0] = WorkTerm;
    hentry[1] = savep[i*2+1];
  }
}

static CODEADDR
CCodeAdjust(PredEntry *pe)
{
  /* add this code to a list of ccalls that must be adjusted */
  
  return ((CODEADDR)(c_predicates[pe->StateOfPred]));
}

static CODEADDR
NextCCodeAdjust(PredEntry *pe)
{
  /* add this code to a list of ccalls that must be adjusted */
  
  return ((CODEADDR)(c_predicates[pe->StateOfPred+1]));
}


static CODEADDR
DirectCCodeAdjust(PredEntry *pe)
{
  /* add this code to a list of ccalls that must be adjusted */
  unsigned int i;
  
  for (i = 0; i < NUMBER_OF_CMPFUNCS; i++) {
    if (cmp_funcs[i].p == pe) {
      return((CODEADDR)(cmp_funcs[i].f));
    }
  }
  Error(FATAL_ERROR,TermNil,"bad saved state, system corrupted");
  return(NULL);
}


/* Restores a prolog clause, in its compiled form */
static void 
RestoreClause(Clause *Cl)
/*
 * Cl points to the start of the code, IsolFlag tells if we have a single
 * clause for this predicate or not 
 */
	                   
{
  yamop           *pc;
  OPREG           cl_type = Cl->ClFlags;

  if (cl_type == ApplCl ||
      (cl_type == ListCl && HeadOfClType(cl_type) == ApplCl))
    Cl->u.ClValue = (CELL)FuncAdjust((Functor)(Cl->u.ClValue));
  else if ((cl_type == AtCl ||
	    (cl_type == ListCl && HeadOfClType(cl_type) == AtCl)) &&
	   IsAtomTerm(Cl->u.ClValue))
    Cl->u.ClValue = AtomTermAdjust(Cl->u.ClValue);
  /* TO DO: log update semantics */
  /* Get the stored operator */
  pc = Cl->ClCode;
  do {
    op_numbers op = op_from_opcode(pc->opc);
    pc->opc = opcode(op);
#ifdef DEBUG_RESTORE2
    YP_fprintf(errout, "%d ", op);
#endif
    switch (op) {
    case _Ystop:
    case _Nstop:
#ifdef DEBUG_RESTORE2
      YP_fprintf(errout, "left OK\n");
#endif
      return;
      /* instructions type ld */
    case _try_me:
    case _retry_me:
    case _trust_me:
    case _profiled_retry_me:
    case _profiled_trust_me:
    case _try_me0:
    case _retry_me0:
    case _trust_me0:
    case _try_me1:
    case _retry_me1:
    case _trust_me1:
    case _try_me2:
    case _retry_me2:
    case _trust_me2:
    case _try_me3:
    case _retry_me3:
    case _trust_me3:
    case _try_me4:
    case _retry_me4:
    case _trust_me4:
    case _spy_or_trymark:
    case _try_and_mark:
    case _profiled_retry_and_mark:
    case _retry_and_mark:
    case _try_clause:
    case _retry:
    case _trust:
    case _retry_first:
    case _trust_first:
    case _retry_tail:
    case _trust_tail:
    case _retry_head:
    case _trust_head:
#ifdef YAPOR
    case _getwork:
    case _getwork_seq:
    case _sync:
#endif
#ifdef TABLING
    case _table_try_me_single:
    case _table_try_me:
    case _table_retry_me:
    case _table_trust_me:
    case _table_answer_resolution:
    case _table_completion:
#endif
      pc->u.ld.p = CodeAddrAdjust(pc->u.ld.p);
      pc->u.ld.d = CodeAddrAdjust(pc->u.ld.d);
      pc = NEXTOP(pc,ld);
      break;
      /* instructions type l */
    case _enter_profiling:
    case _retry_profiled:
    case _try_logical_pred:
    case _trust_logical_pred:
    case _dealloc_for_logical_pred:
    case _execute:
    case _dexecute:
    case _jump:
    case _move_back:
    case _skip:
    case _try_in:
    case _jump_if_var:
      pc->u.l.l = CodeAddrAdjust(pc->u.l.l);
      pc = NEXTOP(pc,l);
      break;
      /* instructions type EC */
    case _alloc_for_logical_pred:
      pc->u.EC.ClBase = CodeAddrAdjust(pc->u.EC.ClBase);
      pc = NEXTOP(pc,EC);
      break;
      /* instructions type e */
    case _trust_fail:
    case _op_fail:
    case _cut:
    case _cut_t:
    case _cut_e:
    case _procceed:
    case _allocate:
    case _deallocate:
    case _write_void:
    case _write_list:
    case _write_l_list:
#if !defined(YAPOR)
    case _or_last:
#endif
    case _pop:
    case _index_pred:
    case _undef_p:
    case _spy_pred:
    case _p_equal:
    case _p_dif:
    case _p_eq:
    case _p_functor:
#ifdef YAPOR
    case _getwork_first_time:
#endif
#ifdef TABLING
    case _trie_do_var:
    case _trie_trust_var:
    case _trie_try_var:
    case _trie_retry_var:
    case _trie_do_val:
    case _trie_trust_val:
    case _trie_try_val:
    case _trie_retry_val:
    case _trie_do_atom:
    case _trie_trust_atom:
    case _trie_try_atom:
    case _trie_retry_atom:
    case _trie_do_list:
    case _trie_trust_list:
    case _trie_try_list:
    case _trie_retry_list:
    case _trie_do_struct:
    case _trie_trust_struct:
    case _trie_try_struct:
    case _trie_retry_struct:
#endif
      pc = NEXTOP(pc,e);
      break;
      /* instructions type x */
    case _save_b_x:
    case _comit_b_x:
    case _get_list:
    case _put_list:
    case _write_x_var:
    case _write_x_val:
    case _write_x_loc:
    case _p_atom_x:
    case _p_atomic_x:
    case _p_integer_x:
    case _p_nonvar_x:
    case _p_number_x:
    case _p_var_x:
    case _p_db_ref_x:
    case _p_primitive_x:
    case _p_compound_x:
    case _p_float_x:
    case _p_cut_by_x:
      pc->u.x.x = XAdjust(pc->u.x.x);
      pc = NEXTOP(pc,x);
      break;
      /* instructions type y */
    case _save_b_y:
    case _comit_b_y:
    case _write_y_var:
    case _write_y_val: 
    case _write_y_loc:
    case _p_atom_y:
    case _p_atomic_y:
    case _p_integer_y:
    case _p_nonvar_y:
    case _p_number_y:
    case _p_var_y:
    case _p_db_ref_y:
    case _p_primitive_y:
    case _p_compound_y:
    case _p_float_y:
    case _p_cut_by_y:
      pc->u.y.y = YAdjust(pc->u.y.y);
      pc = NEXTOP(pc,y);
      break;
      /* instructions type sla */
    case _fcall:
    case _call:
    case _either:
    case _or_else:
    case _p_execute:
    case _p_execute_within:
    case _p_last_execute_within:
#ifdef YAPOR
    case _or_last:
#endif
      pc->u.sla.l = CodeAddrAdjust(pc->u.sla.l);
      if (pc->u.sla.l2 != NIL) {
	CELL *p;
	p = (CELL *)(pc->u.sla.l2 = CodeAddrAdjust(pc->u.sla.l2));
	/* restore entry to predicate from bitmap */
	p[0] = (CELL)PtoPredAdjust((PredEntry *)(p[0]));
      }
      pc->u.sla.p = CodeAddrAdjust(pc->u.sla.p);
      pc = NEXTOP(pc,sla);
      break;
      /* instructions type sla, but for functions */
    case _call_cpred:
    case _call_usercpred:
      pc->u.sla.p = CodeAddrAdjust(pc->u.sla.p);
      pc->u.sla.l = CCodeAdjust((PredEntry *)(pc->u.sla.p));
      if (pc->u.sla.l2 != NIL) {
	CELL *p;
	p = (CELL *)(pc->u.sla.l2 = CodeAddrAdjust(pc->u.sla.l2));
	/* restore entry to predicate from bitmap */
	p[0] = (CELL)PtoPredAdjust((PredEntry *)(p[0]));
      }
      pc = NEXTOP(pc,sla);
      break;
      /* instructions type xx */
    case _get_x_var:
    case _get_x_val:
    case _glist_valx:
    case _gl_void_varx:
    case _gl_void_valx:
    case _put_x_var:
    case _put_x_val:
      pc->u.xx.xr = XAdjust(pc->u.xx.xr);
      pc->u.xx.xl = XAdjust(pc->u.xx.xl);
      pc = NEXTOP(pc,xx);
      break;
      /* instructions type yx */
    case _get_y_var:
    case _get_y_val:
    case _put_y_var:
    case _put_y_val:
    case _put_unsafe:
      pc->u.yx.x = XAdjust(pc->u.yx.x);
      pc->u.yx.y = YAdjust(pc->u.yx.y);
      pc = NEXTOP(pc,yx);
      break;
      /* instructions type xc */
    case _get_atom:
    case _put_atom:
    case _get_float:
    case _get_longint:
    case _get_bigint:
      pc->u.xc.x = XAdjust(pc->u.xc.x);
      {
	Term t = pc->u.xc.c;
	if (IsAtomTerm(t))
	  pc->u.xc.c = AtomTermAdjust(t);
	else if (IsApplTerm(t))
	  pc->u.xc.c = BlobTermAdjust(t);
      }
      pc = NEXTOP(pc,xc);
      break;
      /* instructions type xf */
    case _get_struct:
    case _put_struct:
      pc->u.xf.x = XAdjust(pc->u.xf.x);
      pc->u.xf.f = FuncAdjust(pc->u.xf.f);
      pc = NEXTOP(pc,xf);
      break;
      /* instructions type xy */
    case _glist_valy:
    case _gl_void_vary:
    case _gl_void_valy:
      pc->u.xy.x = XAdjust(pc->u.xy.x);
      pc->u.xy.y = YAdjust(pc->u.xy.y);
      pc = NEXTOP(pc,xy);
      break;
      /* instructions type ox */
    case _unify_x_var:
    case _unify_x_var_write:
    case _unify_l_x_var:
    case _unify_l_x_var_write:
    case _unify_x_val_write:
    case _unify_x_val:
    case _unify_l_x_val_write:
    case _unify_l_x_val:
    case _unify_x_loc_write:
    case _unify_x_loc:
    case _unify_l_x_loc_write:
    case _unify_l_x_loc:
    case _save_pair_x_write:
    case _save_pair_x:
    case _save_appl_x_write:
    case _save_appl_x:
      pc->u.ox.opcw = opcode(op_from_opcode(pc->u.ox.opcw));
      pc->u.ox.x = XAdjust(pc->u.ox.x);
      pc = NEXTOP(pc,ox);
      break;
      /* instructions type oxx */
    case _unify_x_var2:
    case _unify_x_var2_write:
    case _unify_l_x_var2:
    case _unify_l_x_var2_write:
      pc->u.oxx.opcw = opcode(op_from_opcode(pc->u.oxx.opcw));
      pc->u.oxx.xl = XAdjust(pc->u.oxx.xl);
      pc->u.oxx.xr = XAdjust(pc->u.oxx.xr);
      pc = NEXTOP(pc,oxx);
      break;
      /* instructions type oy */
    case _unify_y_var:
    case _unify_y_var_write:
    case _unify_l_y_var:
    case _unify_l_y_var_write:
    case _unify_y_val_write:
    case _unify_y_val:
    case _unify_l_y_val_write:
    case _unify_l_y_val:
    case _unify_y_loc_write:
    case _unify_y_loc:
    case _unify_l_y_loc_write:
    case _unify_l_y_loc:
    case _save_pair_y_write:
    case _save_pair_y:
    case _save_appl_y_write:
    case _save_appl_y:
      pc->u.oy.opcw = opcode(op_from_opcode(pc->u.oy.opcw));
      pc->u.oy.y = YAdjust(pc->u.oy.y);
      pc = NEXTOP(pc,oy);
      break;
      /* instructions type o */
    case _unify_void_write:
    case _unify_void:
    case _unify_l_void_write:
    case _unify_l_void:
    case _unify_list_write:
    case _unify_list:
    case _unify_l_list_write:
    case _unify_l_list:
      pc->u.o.opcw = opcode(op_from_opcode(pc->u.o.opcw));
      pc = NEXTOP(pc,o);
      break;
      /* instructions type os */
    case _unify_n_voids_write:
    case _unify_n_voids:
    case _unify_l_n_voids_write:
    case _unify_l_n_voids:
      pc->u.os.opcw = opcode(op_from_opcode(pc->u.os.opcw));
      pc = NEXTOP(pc,os);
      break;
      /* instructions type oc */
    case _unify_atom_write:
    case _unify_atom:
    case _unify_l_atom_write:
    case _unify_l_atom:
    case _unify_float:
    case _unify_l_float:
    case _unify_longint:
    case _unify_l_longint:
    case _unify_bigint:
    case _unify_l_bigint:
      pc->u.oc.opcw = opcode(op_from_opcode(pc->u.oc.opcw));
      {
	Term t = pc->u.oc.c;
	if (IsAtomTerm(t))
	    pc->u.oc.c = AtomTermAdjust(t);
	else if (IsApplTerm(t))
	  pc->u.oc.c = BlobTermAdjust(t);
      }
      pc = NEXTOP(pc,oc);
      break;
      /* instructions type osc */
    case _unify_n_atoms_write:
    case _unify_n_atoms:
      pc->u.osc.opcw = opcode(op_from_opcode(pc->u.osc.opcw));
      {
	Term t = pc->u.osc.c;
	if (IsAtomTerm(t))
	    pc->u.osc.c = AtomTermAdjust(t);
      }
      pc = NEXTOP(pc,osc);
      break;
      /* instructions type of */
    case _unify_struct_write:
    case _unify_struct:
    case _unify_l_struc_write:
    case _unify_l_struc:
      pc->u.of.opcw = opcode(op_from_opcode(pc->u.of.opcw));
      pc->u.of.f = FuncAdjust(pc->u.of.f);
      pc = NEXTOP(pc,of);
      break;
      /* instructions type s */
    case _write_n_voids:
    case _pop_n:
#ifdef TABLING
    case _table_new_answer:
#endif
      pc = NEXTOP(pc,s);
      break;
      /* instructions type c */
   case _write_atom:
      {
	Term t = pc->u.c.c;
	if (IsAtomTerm(t))
	    pc->u.c.c = AtomTermAdjust(t);
	else if (IsApplTerm(t))
	  pc->u.c.c = BlobTermAdjust(t);
      }
      pc = NEXTOP(pc,c);
      break;
      /* instructions type sc */
   case _write_n_atoms:
      {
	Term t = pc->u.sc.c;
	if (IsAtomTerm(t))
	    pc->u.sc.c = AtomTermAdjust(t);
      }
      pc = NEXTOP(pc,sc);
      break;
      /* instructions type f */
   case _write_struct:
   case _write_l_struc:
      pc->u.f.f = FuncAdjust(pc->u.f.f);
      pc = NEXTOP(pc,f);
      break;
      /* instructions type sdl */
    case _call_c_wfail:
      pc->u.sdl.p = CodeAddrAdjust(pc->u.sdl.p);
      pc->u.sdl.l = CodeAddrAdjust(pc->u.sdl.l);
      pc->u.sdl.d = CCodeAdjust((PredEntry *)(pc->u.sdl.p));
      pc = NEXTOP(pc,sdl);
      break;
      /* instructions type lds */
    case _try_c:
    case _try_userc:
      /* don't need to do no nothing here, initstaff will do it for us
	  */
      pc->u.lds.p = CodeAddrAdjust(pc->u.lds.p);
      pc->u.lds.d = CCodeAdjust((PredEntry *)(pc->u.lds.p));
      pc = NEXTOP(pc,lds);
      break;
    case _retry_c:
    case _retry_userc:
      /* don't need to do no nothing here, initstaff will do it for us
	 pc->u.lds.d = CCodeAdjust(pc->u.lds.d); */
      pc->u.lds.p = CodeAddrAdjust(pc->u.lds.p);
      pc->u.lds.d = NextCCodeAdjust((PredEntry *)(pc->u.lds.p));
      pc = NEXTOP(pc,lds);
      break;
      /* instructions type ldl */
    case _trust_in:
    case _trust_first_in:
    case _trust_tail_in:
    case _trust_head_in:
      pc->u.ldl.p = CodeAddrAdjust(pc->u.ldl.p);
      pc->u.ldl.d = CodeAddrAdjust(pc->u.ldl.d);
      pc->u.ldl.bl = CodeAddrAdjust(pc->u.ldl.bl);
      pc = NEXTOP(pc,ldl);
      break;
      /* instructions type llll */
    case _switch_on_type:
    case _switch_list_nl:
    case _switch_on_head:
      pc->u.llll.l1 = CodeAddrAdjust(pc->u.llll.l1);
      pc->u.llll.l2 = CodeAddrAdjust(pc->u.llll.l2);
      pc->u.llll.l3 = CodeAddrAdjust(pc->u.llll.l3);
      pc->u.llll.l4 = CodeAddrAdjust(pc->u.llll.l4);
      pc = NEXTOP(pc,llll);
      break;
      /* instructions type lll */
    case _switch_on_nonv:
    case _switch_nv_list:
      pc->u.lll.l1 = CodeAddrAdjust(pc->u.lll.l1);
      pc->u.lll.l2 = CodeAddrAdjust(pc->u.lll.l2);
      pc->u.lll.l3 = CodeAddrAdjust(pc->u.lll.l3);
      pc = NEXTOP(pc,lll);
      break;
      /* instructions type cll */
    case _if_not_then:
      {
	Term t = pc->u.cll.c;
	if (IsAtomTerm(t))
	    pc->u.cll.c = AtomTermAdjust(t);
      }
      pc->u.cll.l1 = CodeAddrAdjust(pc->u.cll.l1);
      pc->u.cll.l2 = CodeAddrAdjust(pc->u.cll.l2);
      pc = NEXTOP(pc,cll);
      break;
      /* instructions type ollll */
    case _switch_list_nl_prefetch:
      pc->u.ollll.pop = opcode(op_from_opcode(pc->u.ollll.pop));
      pc->u.ollll.l1 = CodeAddrAdjust(pc->u.ollll.l1);
      pc->u.ollll.l2 = CodeAddrAdjust(pc->u.ollll.l2);
      pc->u.ollll.l3 = CodeAddrAdjust(pc->u.ollll.l3);
      pc->u.ollll.l4 = CodeAddrAdjust(pc->u.ollll.l4);
      pc = NEXTOP(pc,ollll);
      break;
      /* switch_on_func */
    case _switch_on_func:
      {
	int             i, j;
	CELL            *oldcode, *startcode;

	i = pc->u.s.s;
	startcode = oldcode = (CELL *)NEXTOP(pc,s);
	for (j = 0; j < i; ++j) {
	  Functor oldfunc = (Functor)(oldcode[0]);
	  CODEADDR oldjmp = (CODEADDR)(oldcode[1]);
	  if (oldfunc != NULL) {
	    oldcode[0] = (CELL)FuncAdjust(oldfunc);
	  }
	  oldcode[1] = (CELL)CodeAddrAdjust(oldjmp);
	  oldcode += 2;
	}
	rehash(startcode, i, Funcs);
	pc = (yamop *)oldcode;
      }
      break;
      /* switch_on_cons */
    case _switch_on_cons:
      {
	int             i, j;
	CELL            *oldcode;
#if !USE_OFFSETS
	CELL            *startcode;
#endif

	i = pc->u.s.s;
#if !USE_OFFSETS
	startcode =
#endif
	  oldcode = (CELL *)NEXTOP(pc,s);
	for (j = 0; j < i; ++j) {
#if !USE_OFFSETS
	  Term oldatom = oldcode[0];
#endif
	  CODEADDR oldjmp = (CODEADDR)(oldcode[1]);
#if !USE_OFFSETS
	  if (oldatom != 0x0) {
	    oldcode[0] = AtomTermAdjust(oldatom);
	  }
#endif
	  oldcode[1] = (CELL)CodeAddrAdjust(oldjmp);
	  oldcode += 2;
	}
#if !USE_OFFSETS
	rehash(startcode, i, Atomics);
#endif
	pc = (yamop *)oldcode;
      }
      break;
      /* instructions type fll */
    case _go_on_func:
      pc->u.fll.f = FuncAdjust(pc->u.fll.f);
      pc->u.fll.l1 = CodeAddrAdjust(pc->u.fll.l1);
      pc->u.fll.l2 = CodeAddrAdjust(pc->u.fll.l2);
      pc = NEXTOP(pc,fll);
      break;
      /* instructions type cll */
    case _go_on_cons:
      if (IsAtomTerm(pc->u.cll.c))
	pc->u.cll.c = AtomTermAdjust(pc->u.cll.c);
      pc->u.cll.l1 = CodeAddrAdjust(pc->u.cll.l1);
      pc->u.cll.l2 = CodeAddrAdjust(pc->u.cll.l2);
      pc = NEXTOP(pc,cll);
      break;
      /* instructions type sl */
    case _if_func:
      {
	int             i, j;
	CELL            *oldcode;

	i = pc->u.s.s;
	pc->u.sl.l = CodeAddrAdjust(pc->u.sl.l);
	oldcode = (CELL *)NEXTOP(pc,sl);
	for (j = 0; j < i; ++j) {
	  Functor oldfunc = (Functor)(oldcode[0]);
	  CODEADDR oldjmp = (CODEADDR)(oldcode[1]);
	  if (oldfunc != NULL) {
	    oldcode[0] = (CELL)FuncAdjust(oldfunc);
	  }
	  oldcode[1] = (CELL)CodeAddrAdjust(oldjmp);
	  oldcode += 2;
	  pc = (yamop *)oldcode;
	}
      }
      break;
    case _if_cons:
      {
	int             i, j;
	CELL            *oldcode;

	i = pc->u.sl.s;
	pc->u.sl.l = CodeAddrAdjust(pc->u.sl.l);
	oldcode = (CELL *)NEXTOP(pc,sl);
	for (j = 0; j < i; ++j) {
#if !USE_OFFSETS
	  Term oldatom = oldcode[0];
#endif
	  CODEADDR oldjmp = (CODEADDR)(oldcode[1]);
#if !USE_OFFSETS
	  if (oldatom != 0x0) {
	    oldcode[0] = AtomTermAdjust(oldatom);
	  }
#endif
	  oldcode[1] = (CELL)CodeAddrAdjust(oldjmp);
	  oldcode += 2;
	}
	pc = (yamop *)oldcode;
      }
      break;
      /* instructions type slll */
    case _switch_last:
    case _switch_l_list:
      pc->u.slll.p = CodeAddrAdjust(pc->u.slll.p);
      pc->u.slll.l1 = CodeAddrAdjust(pc->u.slll.l1);
      pc->u.slll.l2 = CodeAddrAdjust(pc->u.slll.l2);
      pc->u.slll.l3 = CodeAddrAdjust(pc->u.slll.l3);
      pc = NEXTOP(pc,slll);
      break;
      /* instructions type xxx */
    case _p_plus_vv:
    case _p_minus_vv:
    case _p_times_vv:
    case _p_div_vv:
    case _p_and_vv:
    case _p_or_vv:
    case _p_sll_vv:
    case _p_slr_vv:
    case _p_arg_vv:
    case _p_func2s_vv:
    case _p_func2f_xx:
      pc->u.xxx.x  = XAdjust(pc->u.xxx.x);
      pc->u.xxx.x1 = XAdjust(pc->u.xxx.x1);
      pc->u.xxx.x2 = XAdjust(pc->u.xxx.x2);
      pc = NEXTOP(pc,xxx);
      break;
      /* instructions type xxc */
    case _p_plus_vc:
    case _p_minus_cv:
    case _p_times_vc:
    case _p_div_cv:
    case _p_and_vc:
    case _p_or_vc:
    case _p_sll_vc:
    case _p_slr_vc:
    case _p_func2s_vc:
      pc->u.xxc.x  = XAdjust(pc->u.xxc.x);
      if (IsAtomTerm(pc->u.xxc.c))
	pc->u.xxc.c = AtomTermAdjust(pc->u.xxc.c);
      pc->u.xxc.xi = XAdjust(pc->u.xxc.xi);
      pc = NEXTOP(pc,xxc);
      break;
    case _p_div_vc:
    case _p_sll_cv:
    case _p_slr_cv:
    case _p_arg_cv:
      pc->u.xcx.x  = XAdjust(pc->u.xcx.x);
      pc->u.xcx.xi = XAdjust(pc->u.xcx.xi);
      pc = NEXTOP(pc,xcx);
      break;
    case _p_func2s_cv:
      pc->u.xcx.x  = XAdjust(pc->u.xcx.x);
      if (IsAtomTerm(pc->u.xcx.c))
	pc->u.xcx.c = AtomTermAdjust(pc->u.xcx.c);
      pc->u.xcx.xi = XAdjust(pc->u.xcx.xi);
      pc = NEXTOP(pc,xcx);
      break;
      /* instructions type xyx */
    case _p_func2f_xy:
      pc->u.xyx.x = XAdjust(pc->u.xyx.x);
      pc->u.xyx.x1 = XAdjust(pc->u.xyx.x1);
      pc->u.xyx.y2  = YAdjust(pc->u.xyx.y2);
      pc = NEXTOP(pc,xyx);
      break;
      /* instructions type yxx */
    case _p_plus_y_vv:
    case _p_minus_y_vv:
    case _p_times_y_vv:
    case _p_div_y_vv:
    case _p_and_y_vv:
    case _p_or_y_vv:
    case _p_sll_y_vv:
    case _p_slr_y_vv:
    case _p_arg_y_vv:
    case _p_func2s_y_vv:
    case _p_func2f_yx:
      pc->u.yxx.y  = YAdjust(pc->u.yxx.y);
      pc->u.yxx.x1 = XAdjust(pc->u.yxx.x1);
      pc->u.yxx.x2 = XAdjust(pc->u.yxx.x2);
      pc = NEXTOP(pc,yxx);
      break;
      /* instructions type yyx */
    case _p_func2f_yy:
      pc->u.yyx.y1 = YAdjust(pc->u.yyx.y1);
      pc->u.yyx.y2 = YAdjust(pc->u.yyx.y2);
      pc->u.yyx.x = XAdjust(pc->u.yyx.x);
      pc = NEXTOP(pc,yyx);
      break;
      /* instructions type yxc */
    case _p_plus_y_vc:
    case _p_minus_y_cv:
    case _p_times_y_vc:
    case _p_div_y_vc:
    case _p_div_y_cv:
    case _p_and_y_vc:
    case _p_or_y_vc:
    case _p_sll_y_vc:
    case _p_slr_y_vc:
    case _p_func2s_y_vc:
      pc->u.yxc.y  = YAdjust(pc->u.yxc.y);
      pc->u.yxc.c  = AtomTermAdjust(pc->u.yxc.c);
      pc->u.yxc.xi = XAdjust(pc->u.yxc.xi);
      pc = NEXTOP(pc,yxc);
      break;
      /* instructions type ycx */
    case _p_sll_y_cv:
    case _p_slr_y_cv:
    case _p_arg_y_cv:
      pc->u.ycx.y  = YAdjust(pc->u.ycx.y);
      pc->u.ycx.xi = XAdjust(pc->u.ycx.xi);
      pc = NEXTOP(pc,ycx);
      break;
      /* instructions type lxx */
    case _p_func2s_y_cv:
      pc->u.ycx.y  = YAdjust(pc->u.ycx.y);
      if (IsAtomTerm(pc->u.ycx.c))
	pc->u.ycx.c  = AtomTermAdjust(pc->u.ycx.c);
      pc->u.ycx.xi = XAdjust(pc->u.ycx.xi);
      pc = NEXTOP(pc,ycx);
      break;
      /* instructions type lxx */
    case _call_bfunc_xx:
      pc->u.lxx.p  = CodeAddrAdjust(pc->u.lxx.p);
      pc->u.lxx.l  = DirectCCodeAdjust((PredEntry *)(pc->u.lxx.p));
      pc->u.lxx.x1 = XAdjust(pc->u.lxx.x1);
      pc->u.lxx.x2 = XAdjust(pc->u.lxx.x2);
      pc = NEXTOP(pc,lxx);
      break;
      /* instructions type lxy */
    case _call_bfunc_yx:
    case _call_bfunc_xy:
      pc->u.lxy.p = CodeAddrAdjust(pc->u.lxy.p);
      pc->u.lxy.l  = DirectCCodeAdjust((PredEntry *)(pc->u.lxy.p));
      pc->u.lxy.x = XAdjust(pc->u.lxy.x);
      pc->u.lxy.y = YAdjust(pc->u.lxy.y);
      pc = NEXTOP(pc,lxy);
      break;
    case _call_bfunc_yy:
      pc->u.lyy.p  = CodeAddrAdjust(pc->u.lyy.p);
      pc->u.lyy.l  = DirectCCodeAdjust((PredEntry *)(pc->u.lyy.p));
      pc->u.lyy.y1 = YAdjust(pc->u.lyy.y1);
      pc->u.lyy.y2 = YAdjust(pc->u.lyy.y2);
      pc = NEXTOP(pc,lyy);
      break;
    }
  } while (TRUE);
}

/*
 * Restores a group of clauses for the same predicate, starting with First
 * and ending with Last, First may be equal to Last 
 */
static void 
CleanClauses(CODEADDR First, CODEADDR Last)
{
  CODEADDR cl = First;
  do {
    RestoreClause(ClauseCodeToClause(cl));
    if (cl == Last) return;
    cl = NextClause(cl);
  } while (TRUE);
}


static void
restore_static_array(StaticArrayEntry *ae)
{
  Int sz = -ae->ArrayEArity;
  switch (ae->ArrayType) {
  case array_of_ints:
  case array_of_doubles:
  case array_of_chars:
  case array_of_uchars:
  return;
  case array_of_ptrs:
    {
      AtomEntry **base = (AtomEntry **)AddrAdjust((ADDR)(ae->ValueOfVE.ptrs));
      Int i;
      ae->ValueOfVE.ptrs = base;
      if (ae != NULL) {
	for (i=0; i<sz; i++) {
	  AtomEntry *reg = *base;
	  if (reg == NULL) {
	    base++;
	  } else if (IsOldCode((CELL)reg)) {
	    *base++ = AtomEntryAdjust(reg);
	  } else if (IsOldLocalInTR((CELL)reg)) {
	    *base++ = (AtomEntry *)LocalAddrAdjust((ADDR)reg);
	  } else if (IsOldGlobal((CELL)reg)) {
	    *base++ = (AtomEntry *)GlobalAddrAdjust((ADDR)reg);
	  } else if (IsOldDelay((CELL)reg)) {
	    *base++ = (AtomEntry *)DelayAddrAdjust((ADDR)reg);
	  } else if (IsOldTrail((CELL)reg)) {
	    *base++ = (AtomEntry *)TrailAddrAdjust((ADDR)reg);
	  } else {
	    /* oops */
	    base++;
	  }
	}
      }
    }
  return;
  case array_of_atoms:  
    {
      Term *base = (Term *)AddrAdjust((ADDR)(ae->ValueOfVE.atoms));
      Int i;
      ae->ValueOfVE.atoms = base;
      if (ae != 0L) {
	for (i=0; i<sz; i++) {
	  Term reg = *base;
	  if (reg == 0L) {
	    base++;
	  } else {
	    *base++ = AtomTermAdjust(reg);
	  }
	}
      }
    }
  return;
  case array_of_dbrefs:
    {
      Term *base = (Term *)AddrAdjust((ADDR)(ae->ValueOfVE.dbrefs));
      Int i;

      ae->ValueOfVE.dbrefs = base;
      if (ae != 0L) {
	for (i=0; i<sz; i++) {
	  Term reg = *base;
	  if (reg == 0L) {
	    base++;
	  } else {
	    *base++ = AbsAppl(PtoHeapCellAdjust(RepAppl(reg)));
	  }
	}
      }
    }
  return;
  case array_of_terms:
    {
      DBRef *base = (DBRef *)AddrAdjust((ADDR)(ae->ValueOfVE.terms));
      Int i;

      ae->ValueOfVE.terms = base;
      if (ae != 0L) {
	for (i=0; i<sz; i++) {
	  DBRef reg = *base;
	  if (reg == NULL) {
	    base++;
	  } else {
	    *base++ = reg = DBRefAdjust(reg);
	    RestoreDBEntry(reg);
	  }
	}
      }
    }
  return;
  }
}

/*
 * Clean all the code for a particular predicate, this can get a bit tricky,
 * because of the indexing code 
 */
static void 
CleanCode(PredEntry *pp)
{
  CELL            flag;
  CODEADDR        FirstC, LastC;

  /* Init takes care of the first 2 cases */
  if (pp->ArityOfPE)
    pp->FunctorOfPred = FuncAdjust(pp->FunctorOfPred);
  else
    pp->FunctorOfPred = (Functor)AtomAdjust((Atom)(pp->FunctorOfPred));
  if (pp->OwnerFile)
    pp->OwnerFile = AtomAdjust(pp->OwnerFile);
  pp->OpcodeOfPred = opcode(op_from_opcode(pp->OpcodeOfPred));
  if (pp->PredFlags & (CPredFlag|BasicPredFlag)) {
    if (pp->CodeOfPred != NULL) {
      if (pp->CodeOfPred == pp->TrueCodeOfPred) {
	if (pp->PredFlags & CPredFlag)
	  /* C, assembly + C */
	  pp->CodeOfPred = pp->TrueCodeOfPred = CCodeAdjust(pp);
	else
	  /* assembly */
	  pp->CodeOfPred = (CODEADDR)AddrAdjust((ADDR)(pp->CodeOfPred));
      } else {
	/* comparison */
	pp->CodeOfPred = CCodeAdjust(pp);
	pp->TrueCodeOfPred = DirectCCodeAdjust(pp);
      }
    }
  } else {
    if (pp->FirstClause)
      pp->FirstClause = CodeAddrAdjust(pp->FirstClause);
    if (pp->LastClause)
      pp->LastClause = CodeAddrAdjust(pp->LastClause);
    pp->CodeOfPred = CodeAddrAdjust(pp->CodeOfPred);
    pp->TrueCodeOfPred = CodeAddrAdjust(pp->TrueCodeOfPred);
    flag = pp->PredFlags;
    FirstC = pp->FirstClause;
    LastC = pp->LastClause;
    /* We just have a fail here */
    if (FirstC == NIL && LastC == NIL) {
      return;
    }
#ifdef	DEBUG_RESTORE2
    YP_fprintf(errout, "at %lx Correcting clauses from %lx to %lx\n", *(OPCODE *) FirstC, FirstC, LastC);
#endif
    CleanClauses(FirstC, LastC);
    if (flag & (DynamicPredFlag|IndexedPredFlag)) {
#ifdef	DEBUG_RESTORE2
      YP_fprintf(errout, "Correcting dynamic/indexed code\n");
#endif
      RestoreClause(ClauseCodeToClause(pp->TrueCodeOfPred));
    }
  }
  /* we are pointing at ourselves */
}

/*
 * Restores all of the entries, for a particular atom, we only have problems
 * if we find code or data bases 
 */
static void 
RestoreEntries(PropEntry *pp)
{
  while (!EndOfPAEntr(pp)) {
    switch(pp->KindOfPE) {
    case FunctorProperty:
      {
	FunctorEntry *fe = (FunctorEntry *)pp;
	fe->NameOfFE =
	  AtomAdjust(fe->NameOfFE);
      }
      break;
    case ValProperty:
      {
	ValEntry *ve = (ValEntry *)pp;
	Term      tv = ve->ValueOfVE;
	if (IsAtomTerm(tv))
	  ve->ValueOfVE = AtomTermAdjust(tv);
      }
      break;
    case ArrayProperty:
      {
	ArrayEntry *ae = (ArrayEntry *)pp;
	if (ae->ArrayEArity < 0) {
	  restore_static_array((StaticArrayEntry *)ae);
	} else {
	  if (IsVarTerm(ae->ValueOfVE))
	    RESET_VARIABLE(&(ae->ValueOfVE));
	  else {
	    CELL *ptr = RepAppl(ae->ValueOfVE);
	    /* in fact it should just be a pointer to the global,
	       but we'll be conservative.
	       Notice that the variable should have been reset in restore_program mode.
	    */
	    if (IsOldGlobalPtr(ptr)) {
	      ae->ValueOfVE = AbsAppl(PtoGloAdjust(ptr));
	    } else if (IsOldCodeCellPtr(ptr)) {
	      ae->ValueOfVE = AbsAppl(PtoHeapCellAdjust(ptr));
	    } else if (IsOldLocalInTRPtr(ptr)) {
	      ae->ValueOfVE = AbsAppl(PtoLocAdjust(ptr));
	    } else if (IsOldDelayPtr(ptr)) {
	      ae->ValueOfVE = AbsAppl(PtoDelayAdjust(ptr));
	    } else if (IsOldTrailPtr(ptr)) {
	      ae->ValueOfVE = AbsAppl(CellPtoTRAdjust(ptr));
	    }
	  }
	}
      }
      break;
    case PEProp:
      CleanCode((PredEntry *) pp);
      break;
    case DBProperty:
    case LogUpdDBProperty:
    case CodeLogUpdDBProperty:
    case CodeDBProperty:
#ifdef DEBUG_RESTORE2
      YP_fprintf(errout, "Correcting data base clause at %p\n", pp);
#endif
      if (HDiff)
	RestoreDB((DBEntry *) pp);
      break;
    case BBProperty:
      if (HDiff)
	RestoreBB((BlackBoardEntry *)pp);
      break;
    case ExpProperty:
    case OpProperty:
    case ModProperty:
      /* do nothing */
      break;
    default:
      /* OOPS */
      Error(SYSTEM_ERROR, TermNil,
	    "Invalid Atom Property at %p", pp);
      return;
    }
    pp = RepProp(pp->NextOfPE);
  }
}

/* restore the atom entries which are invisible for the user */
static void 
RestoreInvisibleAtoms(void)
{
  AtomEntry      *at;
  Atom            atm = INVISIBLECHAIN.Entry;

  INVISIBLECHAIN.Entry = atm = AtomAdjust(atm);
  at = RepAtom(atm);
  if (EndOfPAEntr(at))
    return;
  do {
#ifdef DEBUG_RESTORE2		/* useful during debug */
    YP_fprintf(errout, "Restoring %s\n", at->StrOfAE);
#endif
    RestoreEntries(RepProp(at->PropsOfAE));
    atm = at->NextOfAE;
    at->NextOfAE = atm = AtomAdjust(atm);
    at = RepAtom(atm);
  }
  while (!EndOfPAEntr(at));
}

/* restore the atom entries which are invisible for the user */
static void 
RestoreForeignCodeStructure(void)
{
  ForeignObj *f_code;

  if (ForeignCodeLoaded != NULL) 
    ForeignCodeLoaded = (void *)AddrAdjust((ADDR)ForeignCodeLoaded);
  f_code = ForeignCodeLoaded;
  while (f_code != NULL) {
    StringList objs, libs;
    if (f_code->objs != NULL)
      f_code->objs = (StringList)AddrAdjust((ADDR)f_code->objs);
    objs = f_code->objs;
    while (objs != NULL) {
      if (objs->next != NULL)
	objs->next = (StringList)AddrAdjust((ADDR)objs->next);
      if (objs->s != NULL)
	objs->s = (char *)AddrAdjust((ADDR)objs->s);
      objs = objs->next;
    }
    if (f_code->libs != NULL)
      f_code->libs = (StringList)AddrAdjust((ADDR)f_code->libs);
    libs = f_code->libs;
    while (libs != NULL) {
      if (libs->next != NULL)
	libs->next = (StringList)AddrAdjust((ADDR)libs->next);
      if (libs->s != NULL)
	libs->s = (char *)AddrAdjust((ADDR)libs->s);
      libs = libs->next;
    }
    if (f_code->f != NULL)
      f_code->f = (char *)AddrAdjust((ADDR)f_code->f);
    if (f_code->next != NULL)
      f_code->next = (ForeignObj *)AddrAdjust((ADDR)f_code->f);
    f_code = f_code->next;
  }
}

/* restores the list of free space, with its curious structure */
static void 
RestoreFreeSpace(void)
{
  register BlockHeader *bpt, *bsz;
  if (FreeBlocks != NULL)
    FreeBlocks = BlockAdjust(FreeBlocks);
  bpt = FreeBlocks;
  while (bpt != NULL) {
    if (bpt->b_next != NULL) {
      bsz = bpt->b_next = BlockAdjust(bpt->b_next);
      while (bsz != NULL) {
	if (bsz->b_next_size != NULL)
	  bsz->b_next_size = BlockAdjust(bsz->b_next_size);
	if (bsz->b_next != NULL)
	  bsz->b_next = BlockAdjust(bsz->b_next);
	bsz = bsz->b_next;
      }
    }
    if (bpt->b_next_size != NULL)
      bpt->b_next_size = BlockAdjust(bpt->b_next_size);
    bpt = bpt->b_next_size;
  }
  *((YAP_SEG_SIZE *) HeapTop) = InUseFlag;
}

/*
 * This is the really tough part, to restore the whole of the heap 
 */
static void 
restore_heap(void)
{
  AtomHashEntry *HashPtr = HashChain;
  register int    i;
  for (i = 0; i < MaxHash; ++i) {
    Atom atm = HashPtr->Entry;
    if (atm) {
      AtomEntry      *at;
      HashPtr->Entry = atm = AtomAdjust(atm);
      at =  RepAtom(atm);
      do {
#ifdef DEBUG_RESTORE2			/* useful during debug */
	YP_fprintf(errout, "Restoring %s\n", at->StrOfAE);
#endif
	RestoreEntries(RepProp(at->PropsOfAE));
	atm = at->NextOfAE = AtomAdjust(at->NextOfAE);
	at = RepAtom(atm);
      } while (!EndOfPAEntr(at));
    }
    HashPtr++;
  }
  RestoreInvisibleAtoms();
  RestoreForeignCodeStructure();
}


#ifdef DEBUG_RESTORE3
static void 
ShowEntries(pp)
	PropEntry      *pp;
{
  while (!EndOfPAEntr(pp)) {
    YP_fprintf(YP_stderr,"Estou a ver a prop %x em %x\n", pp->KindOfPE, pp);
    pp = RepProp(pp->NextOfPE);
  }
}

static void 
ShowAtoms()
{
  AtomHashEntry  *HashPtr = HashChain;
  register int    i;
  for (i = 0; i < MaxHash; ++i) {
    if (HashPtr->Entry != NIL) {
      AtomEntry      *at;
      at = RepAtom(HashPtr->Entry);
      do {
	YP_fprintf(YP_stderr,"Passei ao %s em %x\n", at->StrOfAE, at);
	ShowEntries(RepProp(at->PropsOfAE));
      } while (!EndOfPAEntr(at = RepAtom(at->NextOfAE)));
    }
    HashPtr++;
  }
}

#endif /* DEBUG_RESTORE3 */

#include <stdio.h>

static int 
OpenRestore(char *s)
{
  int mode;

  /*  if (strcmp(s, StartUpFile) == 0)
      YP_fprintf(YP_stderr, "[ YAP version %s ]\n\n", version_number);*/
  CloseStreams(TRUE);
  if ((splfild = open_file(s, O_RDONLY)) < 0) {
    if (!dir_separator(s[0]) && !volume_header(s)) {

      /*
	we have a relative path for the file, try to do somewhat better 
	using YAPLIBDIR or friends.
      */
      if (Yap_LibDir != NULL) {
	strncpy(FileNameBuf, Yap_LibDir, YAP_FILENAME_MAX);
#if HAVE_GETENV
      } else {
	char *yap_env = getenv("YAPLIBDIR");
	if (yap_env != NULL) {
	  strncpy(FileNameBuf, yap_env, YAP_FILENAME_MAX);
#endif
	} else {
	  strncpy(FileNameBuf, LIB_DIR, YAP_FILENAME_MAX);
	}
#if HAVE_GETENV
      }
#endif
#if _MSC_VER || defined(__MINGW32__)
      strncat(FileNameBuf,"\\", YAP_FILENAME_MAX);
#else
      strncat(FileNameBuf,"/", YAP_FILENAME_MAX);
#endif
      strncat(FileNameBuf,s, YAP_FILENAME_MAX);
      if ((splfild = open_file(FileNameBuf, O_RDONLY)) < 0) {
	if (PrologMode != BootMode) {
	  Error(SYSTEM_ERROR,MkAtomTerm(LookupAtom(s)),
		"save/1, open(%s)", strerror(errno));
	}
	return(FAIL_RESTORE);
      }
    } else {
      return(FAIL_RESTORE);
    }
  }
  PrologMode = BootMode;
  if ((mode = check_header()) == FAIL_RESTORE)
    return(FAIL_RESTORE);
  if (!yap_flags[HALT_AFTER_CONSULT_FLAG]) {
    YP_fprintf(YP_stderr, "[ Restoring file %s ]\n", s);
  }
#ifdef DEBUG_RESTORE4
  /*
   * This should be another file, like the log file 
   */
  errout = YP_stderr;
#endif
  return(mode);
}

static void 
CloseRestore(void)
{
#ifdef DEBUG_RESTORE3
  ShowAtoms();
#endif
  close_file();
  PrologMode = UserMode;
}

static int 
check_opcodes(OPCODE old_ops[])
{
#if USE_THREADED_CODE
  int have_shifted = FALSE;
  op_numbers op = _Ystop;
  for (op = _Ystop; op < _std_top; op++) {
    if (opcode(op) != old_ops[op]) {
      have_shifted = TRUE;
      break;
    }
  }
  return(have_shifted);
#else
  return(FALSE);
#endif
}

static void 
RestoreHeap(OPCODE old_ops[], int functions_moved)
{
  int heap_moved = (OldHeapBase != HeapBase), opcodes_moved;

  opcodes_moved = check_opcodes(old_ops);
  /* opcodes_moved has side-effects and should be tried first */
  if (heap_moved || opcodes_moved || functions_moved) {
    restore_heap();
  }
  /* This must be done after restore_heap */
  if (heap_moved) {
    RestoreFreeSpace();
  }
  InitAbsmi();
  if (!(ReInitConstExps() && ReInitUnaryExps() && ReInitBinaryExps()))
    Error(SYSTEM_ERROR, TermNil, "arithmetic operator not in saved state");
#ifdef DEBUG_RESTORE1
  YP_fprintf(errout, "phase 1 done\n");
#endif
}

/*
 * This function is called to know about the parameters of the last saved
 * state 
 */
int 
SavedInfo(char *FileName, int *ATrail, int *AStack, int *AHeap, char *YapLibDir)
{
  char            pp[80];
  char		  msg[256];
  char		  NameBuf[YAP_FILENAME_MAX];
  int             result, mode;

  if ((splfild = open_file(FileName, O_RDONLY)) < 0) {
    if (!dir_separator(FileName[0]) && !volume_header(FileName)) {

      /* we have a relative path for the file, try to do somewhat better */
      if  (YapLibDir != NULL) {
	strncpy(FileNameBuf, YapLibDir, YAP_FILENAME_MAX);
#if HAVE_GETENV
      } else {
	char* my_env=getenv("YAPLIBDIR");
	if (my_env != NULL) {
	  strncpy(NameBuf, my_env, YAP_FILENAME_MAX);
#endif
	} else {
	  strncpy(NameBuf, LIB_DIR, YAP_FILENAME_MAX);
	}
#if HAVE_GETENV
      }
#endif
#if _MSC_VER || defined(__MINGW32__)
      strncat(NameBuf,"\\", YAP_FILENAME_MAX);
#else
      strncat(NameBuf,"/", YAP_FILENAME_MAX);
#endif
      strncat(NameBuf,FileName, YAP_FILENAME_MAX);
      if ((splfild = open_file(NameBuf, O_RDONLY)) < 0) {
	return(FALSE);
      }
    } else {
      return(FALSE);
    }
  }
  /* skip the first line */
  do {
    myread(splfild, pp, 1);
  } while (pp[0] != 1);
  sprintf(msg, "YAPV%s", version_number);
  myread(splfild, pp, Unsigned(strlen(msg) + 1));
  if (strcmp(pp, msg) != 0) {
    if (PrologMode != BootMode)
      Error(SYSTEM_ERROR, TermNil,
	    "file %s is not a saved Prolog state", FileName);
    return(0);
  }
  result = get_cell();
  mode = get_cell();
  if (mode != DO_ONLY_CODE && mode != DO_EVERYTHING) {
    Error(SYSTEM_ERROR, TermNil,
	  "file %s is not a saved Prolog state", FileName);
    return(0);
  }
  if (*AHeap)
    get_cell();
  else
    *AHeap = get_cell() / 1024;
  if (mode == DO_ONLY_CODE || *AStack)
    get_cell();
  else
    *AStack = get_cell() / 1024;
  if (mode == DO_ONLY_CODE || *ATrail)
    get_cell();
  else
    *ATrail = get_cell() / 1024;
  close_file();
  return (result);
}

static void
UnmarkTrEntries(void)
{
  CELL           entry, *Entries;

  /* initialise a choice point */
  B = (choiceptr)LCL0;
  B--;
  B->cp_ap = (yamop *)NOCODE;
  Entries = (CELL *)TrailBase;
  while ((entry = *Entries++) != (CELL)NULL) {
    if (IsVarTerm(entry)) {
      RESET_VARIABLE((CELL *)entry);
    } else if (IsPairTerm(entry)) {
      CODEADDR ent = (CODEADDR)RepPair(entry);
      register CELL flags;

      flags = Flags(ent);
      ResetFlag(InUseMask, flags);
      Flags(ent) = flags;
      if (FlagOn(ErasedMask, flags)) {
	if (FlagOn(DBClMask, flags)) {
	  ErDBE((DBRef) (ent - (CELL) &(((DBRef) NIL)->Flags)));
	} else {
	  ErCl(ClauseFlagsToClause(ent));
	}
      }
    }
  }
  B = NULL;
}


int in_limbo = FALSE;


/*
 * This function is called when wanting only to restore the heap and
 * associated registers 
 */
int 
Restore(char *s)
{
  int restore_mode;
  int funcs_moved;

  OPCODE old_ops[_std_top+1];

  if ((restore_mode = OpenRestore(s)) == FAIL_RESTORE)
    return(FALSE);
  ShutdownLoadForeign();
  in_limbo = TRUE;
  funcs_moved = get_coded(restore_mode, old_ops);
  restore_regs(restore_mode);
  in_limbo = FALSE;
  /*#endif*/
  RestoreHeap(old_ops, funcs_moved);
  switch(restore_mode) {
  case DO_EVERYTHING:
    if (OldHeapBase != HeapBase ||
	OldLCL0 != LCL0 ||
	OldGlobalBase != (CELL *)GlobalBase ||
	OldTrailBase != TrailBase) {
      AdjustStacksAndTrail();
      if (which_save == 2) {
	AdjustRegs(2);
      } else {
	AdjustRegs(1);
      }
      break;
#ifdef DEBUG_RESTORE2
      YP_fprintf(errout, "phase 2 done\n");
#endif
    }
    break;
  case DO_ONLY_CODE:
    UnmarkTrEntries();
    break;
  }
  ReOpenLoadForeign();
  InitPlIO();
  /* reset time */
  ReInitWallTime();
  CloseRestore();
  if (which_save == 2) {
    unify(ARG2, MkIntTerm(0));
  }
  return(restore_mode);
}

static Int 
p_restore(void)
{
  int mode;

  Term t1 = Deref(ARG1);
  if (!GetName(FileNameBuf, YAP_FILENAME_MAX, t1)) {
    Error(TYPE_ERROR_LIST,t1,"restore/1");
    return(FALSE);
  }
  if ((mode = Restore(FileNameBuf)) == DO_ONLY_CODE) {
#if PUSH_REGS
    restore_absmi_regs(&standard_regs);
#endif
    /* back to the top level we go */
    siglongjmp(RestartEnv,3);
  }
  return(mode != FAIL_RESTORE);
}

void 
InitSavePreds(void)
{
  InitCPred("$save", 1, p_save, SafePredFlag|SyncPredFlag);
  InitCPred("$save", 2, p_save2, SafePredFlag|SyncPredFlag);
  InitCPred("$save_program", 1, p_save_program, SafePredFlag|SyncPredFlag);
  InitCPred("$restore", 1, p_restore, SyncPredFlag);
}