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windows-server-2003/sdktools/link16/newent.c

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/*
* TITLE
* newent.c
* Pete Stewart
* (C) Copyright Microsoft Corp 1984-1989
* 1 October 1984
*
* DESCRIPTION
* This file contains routines for the DOS 4.0 linker
* that manage per-segment entry point information.
*
* It also contains routines that manage per-segment
* relocation information.
*
* Modifications:
*
* 09-Feb-1989 RB Fix Insert().
*/
#include <minlit.h> /* Basic type definitions */
#include <bndtrn.h> /* Constants and compound types */
#include <bndrel.h> /* Types and constants */
#include <lnkio.h> /* I/O definitions */
#include <newexe.h> /* DOS & 286 .EXE format data structures */
#if EXE386
#include <exe386.h> /* 386 .EXE format data structures */
#endif
#include <lnkmsg.h> /* Error messages */
#include <extern.h> /* External declarations */
#include <impexp.h>
#define hashra(ra) (WORD) ((ra) % HEPLEN)
/* Function to hash offset */
#if NOT EXE386
#define hashrlc(r) (((NR_SEGNO(*r) << NR_STYPE(*r)) + NR_ENTRY(*r)) & HASH_SIZE - 1)
/* Hash relocation item */
#define EOC ((RATYPE) 0xFFFF)
/* End-of-chain marker */
#endif
#define IsInSet(x) ((pOrdinalSet[(x) >> 3] & BitMask[(x) & 0x07]) != 0)
#define NotInSet(x) ((pOrdinalSet[(x) >> 3] & BitMask[(x) & 0x07]) == 0)
#define SetBit(x) (pOrdinalSet[(x) >> 3] |= BitMask[(x) & 0x07])
#define MaxIndex 8192
#define ET_END 0xffff
/*
* FUNCTION PROTOTYPES
*/
LOCAL void NEAR NewBundle(unsigned short type);
LOCAL WORD NEAR MatchRlc(RLCPTR rlcp0,
RLCPTR rlcp1);
#if NOT QCLINK
LOCAL void NEAR NewEntry(unsigned short sa,
RATYPE ra,
unsigned char flags,
unsigned short hi,
unsigned short ord);
LOCAL void SavExp1(APROPNAMEPTR apropexp,
RBTYPE rhte,
RBTYPE rprop,
WORD fNewHte);
LOCAL void SavExp2(APROPNAMEPTR apropexp,
RBTYPE rhte,
RBTYPE rprop,
WORD fNewHte);
LOCAL WORD NEAR BuildList(WORD NewOrd, RBTYPE NewProp);
LOCAL WORD NEAR FindFreeRange(void);
LOCAL WORD NEAR Insert(RBTYPE NewProp);
#endif
/*
* LOCAL DATA
*/
#if NOT QCLINK
#pragma pack(1)
typedef struct _BUNDLE
{
BYTE count;
BYTE type;
}
BUNDLE;
#pragma pack()
LOCAL WORD ceCurBnd; /* No. of entries in current bundle */
LOCAL WORD offCurBnd; /* Offset of current bundle header */
LOCAL WORD tyCurBnd; /* Type of current bundle */
LOCAL WORD ordMac; /* Highest entry ordinal number */
LOCAL BYTE *pOrdinalSet;
#if EXE386
LOCAL APROPEXPPTR pExport; /* Pointer to export property cell */
#endif
LOCAL struct {
WORD ord; /* Current available ordinal */
WORD count; /* Number of free ordinals in range */
}
FreeRange;
LOCAL BYTE BitMask[] = { /* Bit mask used in set operations */
0x01,
0x02,
0x04,
0x08,
0x10,
0x20,
0x40,
0x80 };
LOCAL WORD MinOrd = 0; /* Min ordinal number see so far */
LOCAL WORD MaxOrd = 0; /* Max ordinal number see so far */
RBTYPE pMinOrd = NULL; /* Pointer to property cell with MinOrd */
LOCAL RBTYPE pMaxOrd = NULL; /* Pointer to property cell with MaxOrd */
LOCAL RBTYPE pStart;
#ifndef UNPOOLED_RELOCS
LOCAL void * pPoolRlc; /* memory pool for relocations */
#endif
#if NOT EXE386
LOCAL void NEAR NewBundle(type) /* Make a new bundle */
WORD type; /* Type of new bundle */
{
BUNDLE FAR *pBnd; /* Ptr to start of bundle or entry */
BUNDLE bnd;
if (EntryTable.byteMac != 0)
{
// If there is a previous bundle patch the count filed
pBnd = (BUNDLE FAR *) &(EntryTable.rgByte[offCurBnd]);
pBnd->count = (BYTE) ceCurBnd;
}
bnd.count = 0;
bnd.type = (BYTE) type;
offCurBnd = AddEntry((BYTE *) &bnd, sizeof(BUNDLE));
ceCurBnd = 0;
tyCurBnd = type;
if (type == ET_END)
EntryTable.byteMac--;
}
#endif
/****************************************************************
* *
* NAME: NewEntry *
* *
* DESCRIPTION: *
* *
* This function makes an entry in the Entry Table for a *
* given file segment number, offset, and flag set. It also *
* makes an entry in the entry address hash table on the *
* given hash chain for the new entry point. N.B.: this *
* function assumes the static variable ordMac is set to the *
* desired ordinal value for the entry being added. *
* *
* ARGUMENTS: *
* *
* SATYPE sa File segment number *
* RATYPE ra Offset *
* FTYPE flags Entry point flags *
* WORD hi Hash table index *
* WORD ord New ordinal *
* *
* RETURNS: *
* *
* WORD Offset in Entry Table *
* *
* SIDE EFFECTS: *
* *
* Maintains a hash table hashing file segment/offset pairs *
* to entry table offsets. Builds in virtual memory the *
* Entry Table. Updates the following variables: *
* *
* WORD offCurBnd Offset of start of current *
* bundle of entries. *
* WORD ceCurBnd Count of entries in cur- *
* rent bundle. *
* WORD tyCurBnd Type of current bundle. *
* WORD cbEntTab Size of Entry Table in *
* bytes. *
* *
* NOTE: THIS FUNCTION CALLS THE VIRTUAL MEMORY MANAGER. *
* *
****************************************************************/
LOCAL void NEAR NewEntry(sa,ra,flags,hi,ord)
SATYPE sa; /* File segment number */
RATYPE ra; /* Segment offset */
FTYPE flags; /* Entry point flags */
WORD hi; /* Hash table index */
WORD ord; /* New ordinal */
{
EPTYPE FAR *ep; /* Entry point node */
#if NOT EXE386
WORD tyEntry; /* Entry type */
WORD cbEntry; /* Length of entry in bytes */
BYTE entry[6]; /* The entry itself - NE version */
#endif
#if EXE386
static WORD prevEntryOrd; // Previous export ordinal
DWORD eatEntry; /* The entry itself - LE version */
#endif
#if NOT EXE386
if(sa == SANIL) /* If absolute symbol */
tyEntry = BNDABS; /* use fake segment # */
else if (TargetOs == NE_OS2)
tyEntry = NonConfIOPL(mpsaflags[sa]) ? BNDMOV: sa;
else
tyEntry = (mpsaflags[sa] & NSMOVE)? BNDMOV: sa;
/* Get the entry type */
/* If not library, or realmode and not solo data, clear local data bit. */
if(!(vFlags & NENOTP) || (!(vFlags & NEPROT) && !(vFlags & NESOLO)))
flags &= ~2;
entry[0] = (BYTE) flags; /* Set the entry flags */
if(tyEntry == BNDMOV /* If entry is in movable segment */
#if O68K
&& iMacType == MAC_NONE
#endif
)
{
++cMovableEntries; /* Increment movable entries count */
cbEntry = 6; /* Entry is six bytes long */
entry[1] = 0xCD; /* INT... */
entry[2] = 0x3F; /* ...3FH */
entry[3] = (BYTE) sa; /* File segment number */
entry[4] = (BYTE) ra; /* Lo-byte of offset */
entry[5] = (BYTE)(ra >> BYTELN);/* Hi-byte of offset */
}
else /* Else if fixed entry */
{
cbEntry = 3; /* Entry is three bytes long */
entry[1] = (BYTE) ra; /* Lo-byte of offset */
entry[2] = (BYTE)(ra >> BYTELN);/* Hi-byte of offset */
}
#endif
#if EXE386
/*
* This function creates one entry in the Export Address Table.
* The EAT table is stored in linker's VM in area AREAEAT. The
* global variable cbEntTab always points to free space in the
* AREAEAT.
*/
eatEntry = 0L;
if ((prevEntryOrd != 0) && (ord > prevEntryOrd + 1))
{
// Write unused entries in the Export Address Table
for (; prevEntryOrd < ord - 1; prevEntryOrd++)
{
if (cbEntTab + sizeof(DWORD) > MEGABYTE)
Fatal(ER_eatovf, MEGABYTE);
vmmove(sizeof(DWORD), &eatEntry, (long)(AREAEAT + cbEntTab), TRUE);
cbEntTab += sizeof(DWORD);
}
}
prevEntryOrd = ord;
// FLAT address
eatEntry = mpsaBase[sa] + ra;
/* Check for Entry Table overflow */
if (cbEntTab + sizeof(DWORD) > MEGABYTE)
Fatal(ER_eatovf, MEGABYTE);
#endif
/* Insert the new entry */
#if NOT EXE386
if (tyCurBnd != tyEntry || ceCurBnd == BNDMAX)
NewBundle(tyEntry); /* Make a new bundle if needed */
++ceCurBnd; /* Increment counter */
#endif
/* Save entry in virtual memory */
#if EXE386
vmmove(sizeof(DWORD), &eatEntry, (long)(AREAEAT + cbEntTab), TRUE);
#else
AddEntry(entry, cbEntry);
#endif
ep = (EPTYPE FAR *) GetMem(sizeof(EPTYPE));
ep->ep_next = htsaraep[hi]; /* Link old chain to new node */
ep->ep_sa = sa; /* Save the file segment number */
ep->ep_ra = ra; /* Save offset */
ep->ep_ord = ord; /* Save Entry Table ordinal */
htsaraep[hi] = ep; /* Make new node head of chain */
}
/****************************************************************
* *
* NAME: MpSaRaEto *
* *
* DESCRIPTION: *
* *
* This function returns an Entry Table ordinal given a *
* file segment number (sa) for a segment and an offset in *
* that segment. *
* *
* ARGUMENTS: *
* *
* SATYPE sa File segment number *
* RATYPE ra Offset *
* *
* RETURNS: *
* *
* WORD Entry Table ordinal *
* *
* SIDE EFFECTS: *
* *
* Calls NewEntry(). Increments ordMac. *
* *
* NOTE: THIS FUNCTION CALLS THE VIRTUAL MEMORY MANAGER. *
* *
****************************************************************/
WORD NEAR MpSaRaEto(sa,ra)
SATYPE sa; /* File segment number */
RATYPE ra; /* Segment offset */
{
WORD hi; /* Hash table index */
EPTYPE FAR *ep; /* Entry point node */
hi = hashra(ra); /* Hash the offset */
for (ep = htsaraep[hi]; ep != NULL; ep = ep->ep_next)
{ /* Loop through hash chain */
if (ep->ep_sa == sa && ep->ep_ra == ra)
return(ep->ep_ord);
/* If match found, return number */
}
// At this point, we know a new entry must be created.
NewEntry(sa, ra, 0, hi, ++ordMac); /* Add a new entry */
return(ordMac); /* Return Entry Table ordinal */
}
/****************************************************************
* *
* NAME: BuildList *
* *
* DESCRIPTION: *
* *
* This function links the property cells of exports with *
* preassigned ordinals into list. Global pointers pMinOrd *
* and pMaxOrd points to the begin and end of this list. The *
* preassigned ordinals are stored in the set pointed by the *
* global pointer pOrdinalSet. *
* *
* ARGUMENTS: *
* *
* WORD NewOrd New preassigned ordinal *
* RBTYPE NewProp Addr of property cell *
* *
* RETURNS: *
* *
* TRUE if ordinal seen for the first time, otherwise FALSE. *
* *
* SIDE EFFECTS: *
* *
* Changes pMinOrd and pMaxOrd pointers, sets bits in ordinal *
* set and sets MinOrd, MaxOrd seen so far. *
* *
****************************************************************/
LOCAL WORD NEAR BuildList(WORD NewOrd, RBTYPE NewProp)
{
RBTYPE pTemp; /* Temporary pointer to property cell */
APROPEXPPTR pExpCurr; /* Export record pointer */
APROPEXPPTR pExpPrev; /* Export record pointer */
if (!MinOrd && !MaxOrd)
{ /* First time call */
MinOrd = MaxOrd = NewOrd;
pMinOrd = pMaxOrd = NewProp;
SetBit(NewOrd);
return TRUE;
}
if (IsInSet(NewOrd))
return FALSE; /* Ordinal all ready used */
SetBit(NewOrd); /* Set bit in ordinal set */
if (NewOrd > MaxOrd)
{ /* Add new at the list end */
pExpCurr = (APROPEXPPTR ) FetchSym(pMaxOrd,TRUE);
pExpCurr->ax_NextOrd = NewProp;
MARKVP();
pMaxOrd = NewProp;
MaxOrd = NewOrd;
pExpCurr = (APROPEXPPTR ) FetchSym(NewProp,TRUE);
pExpCurr->ax_NextOrd = NULL;
MARKVP();
}
else if (NewOrd < MinOrd)
{ /* Add new at list begin */
pExpCurr = (APROPEXPPTR ) FetchSym(NewProp,TRUE);
pExpCurr->ax_NextOrd = pMinOrd;
MARKVP();
pMinOrd = NewProp;
MinOrd = NewOrd;
}
else
{ /* Add new in the middle of list */
pTemp = pMinOrd;
do
{
pExpPrev = (APROPEXPPTR ) FetchSym(pTemp,TRUE);
pExpCurr = (APROPEXPPTR ) FetchSym(pExpPrev->ax_NextOrd,TRUE);
if (NewOrd < pExpCurr->ax_ord)
{
pTemp = pExpPrev->ax_NextOrd;
pExpPrev->ax_NextOrd = NewProp;
MARKVP();
pExpCurr = (APROPEXPPTR ) FetchSym(NewProp,TRUE);
pExpCurr->ax_NextOrd = pTemp;
MARKVP();
break;
}
pTemp = pExpPrev->ax_NextOrd;
} while (pTemp);
}
if(NewOrd > ordMac) ordMac = NewOrd; /* Remember largest ordinal */
return TRUE;
}
/****************************************************************
* *
* NAME: FindFreeRange *
* *
* DESCRIPTION: *
* *
* This function finds in the ordinal set first available *
* free range of ordinals. *
* *
* ARGUMENTS: *
* *
* Nothing. *
* *
* RETURNS: *
* *
* TRUE if free range found, otherwise FALSE. *
* *
* SIDE EFFECTS: *
* *
* Changes FreeRange descriptor by setting first free ordinal *
* and the lenght of range. *
* *
****************************************************************/
LOCAL WORD NEAR FindFreeRange(void)
{
int ByteIndex;
int BitIndex;
ByteIndex = FreeRange.ord >> 3;
BitIndex = FreeRange.ord & 0x07;
while ((pOrdinalSet[ByteIndex] & BitMask[BitIndex]) &&
ByteIndex < MaxIndex)
{ /* Skip all used ordinals */
FreeRange.ord++;
BitIndex = (BitIndex + 1) & 0x07;
if (!BitIndex)
ByteIndex++;
}
if (ByteIndex < MaxIndex)
{
if (FreeRange.ord > MaxOrd)
{
FreeRange.count = 0xffff - MaxOrd;
return TRUE;
}
do
{ /* Count all unused ordinals */
FreeRange.count++;
BitIndex = (BitIndex + 1) & 0x07;
if (!BitIndex)
ByteIndex++;
} while (!(pOrdinalSet[ByteIndex] & BitMask[BitIndex]) &&
ByteIndex < MaxIndex);
return TRUE;
}
return FALSE;
}
/****************************************************************
* *
* NAME: Insert *
* *
* DESCRIPTION: *
* *
* This function inserts into the exports list new property *
* cell without preassigned ordinal. It assigns new ordinal. *
* *
* ARGUMENTS: *
* *
* RBTYPE NewProp New property cell to insert *
* *
* RETURNS: *
* *
* New assigned ordinal. *
* *
* SIDE EFFECTS: *
* *
* Changes FreeRange descriptor and MaxOrd assigned so far. *
* *
****************************************************************/
LOCAL WORD NEAR Insert(RBTYPE NewProp)
{
APROPEXPPTR pExpCurr; /* Export record pointer */
APROPEXPPTR pExpPrev; /* Export record pointer */
WORD NewOrd;
RBTYPE pTemp, rbPrev, rbCur;
/*
* On entry, pStart points to the place in the export list where
* NewProp should be inserted. If NULL, the list is empty.
*/
if (!FreeRange.count)
{
/* No more space left in current free range; find the next one. */
if (!FindFreeRange())
Fatal(ER_expmax);
/*
* Update pStart (the insertion point) by walking down the list and
* finding the first element whose ordinal is greater than the new
* ordinal, or the end of the list if none is found.
*/
rbPrev = RHTENIL;
for (rbCur = pStart; rbCur != RHTENIL; rbCur = pExpCurr->ax_NextOrd)
{
pExpCurr = (APROPEXPPTR) FetchSym(rbCur, FALSE);
if (pExpCurr->ax_ord > FreeRange.ord)
break;
rbPrev = rbCur;
}
/* Set pStart to the insertion point. */
pStart = rbPrev;
}
/* Insert new property cell */
NewOrd = FreeRange.ord++;
FreeRange.count--;
SetBit(NewOrd);
pExpCurr = (APROPEXPPTR ) FetchSym(NewProp,TRUE);
pExpCurr->ax_ord = NewOrd;
MARKVP();
if (pStart != NULL)
{
// We're not inserting at head of list. Append new cell to previous
// cell.
pExpPrev = (APROPEXPPTR ) FetchSym(pStart,TRUE);
pTemp = pExpPrev->ax_NextOrd;
pExpPrev->ax_NextOrd = NewProp;
MARKVP();
}
else
{
// We're inserting at head of list. Set head list pointer to new
// cell.
pTemp = pMinOrd;
pMinOrd = NewProp;
}
/*
* Set the next pointer to the following element in the list.
*/
pExpCurr = (APROPEXPPTR ) FetchSym(NewProp,TRUE);
pExpCurr->ax_NextOrd = pTemp;
MARKVP();
/*
* Update MaxOrd and pStart.
*/
if (NewOrd > MaxOrd)
MaxOrd++;
pStart = NewProp;
return NewOrd;
}
/****************************************************************
* *
* NAME: SavExp1 *
* *
* DESCRIPTION: *
* *
* This function places the virtual addresses of property *
* cells for exports with preassigned ordinals into a table *
* which will later be used to create the first part of the *
* entry table. It also verifies the validity of the ex- *
* ports. *
* *
* ARGUMENTS: *
* *
* APROPEXPPTR apropexp Export record pointer *
* RBTYPE rhte Addr of hash table entry *
* RBTYPE rprop Address of export record *
* FTYPE fNewHte New hash table entry flag *
* *
* RETURNS: *
* *
* Nothing. *
* *
* SIDE EFFECTS: *
* *
* Entries are made in a table on the stack to which the *
* local static variable prb points. The global variable *
* ordMac is set to the highest ordinal value found. Pro- *
* perty cells for exports are updated to contain the file *
* segment number and offset of the entry point. *
* *
* NOTE: THIS FUNCTION CALLS THE VIRTUAL MEMORY MANAGER. *
* *
****************************************************************/
LOCAL void SavExp1(APROPNAMEPTR apropexp,
RBTYPE rhte,
RBTYPE rprop,
WORD fNewHte)
{
AHTEPTR ahte; /* Pointer to hash table entry */
LOCAL APROPNAMEPTR apropnam; /* Public definition record pointer */
LOCAL APROPPTR aprop; /* temp. pointer */
WORD ord; /* Entry ordinal */
SATYPE sa; /* File segment number */
RATYPE ra; /* Offset in segment */
WORD fStartSeen=0; /* Have we seen the start of the list */
APROPEXPPTR pExport;
char *p;
ASSERT(fNewHte); /* Only once per customer */
pExport = (APROPEXPPTR ) apropexp;
if((ord = pExport->ax_ord) >= EXPMAX)
{ /* If ordinal too big */
pExport->ax_ord = 0; /* Treat as unspecified */
ord = 0;
MARKVP(); /* Page has changed */
/* Issue error message */
ahte = (AHTEPTR ) FetchSym(rhte,FALSE);
OutError(ER_ordmax,1 + GetFarSb(ahte->cch));
}
apropnam = (APROPNAMEPTR ) FetchSym(pExport->ax_symdef,FALSE);
/* Fetch the public symbol def. */
for (aprop = (APROPPTR) apropnam; aprop->a_attr != ATTRPNM;)
{
if(aprop->a_attr == ATTRALIAS) /* If an alias */
{
aprop = (APROPPTR) FetchSym(
((APROPALIASPTR)aprop)->al_sym, FALSE );
if (aprop->a_attr == ATTRPNM) /* The substitute is a public-OK */
break;
}
aprop = (APROPPTR) FetchSym (aprop->a_next, FALSE);
if (aprop->a_next == NULL && aprop->a_attr == ATTRNIL) /* Beginning of list */
{
aprop = (APROPPTR) FetchSym ( ((AHTEPTR)aprop)->rprop, FALSE);
fStartSeen ++;
}
if ((aprop != (APROPPTR) apropnam) && (fStartSeen<2))
continue; /* Find an ALIAS or the starting point */
/* Issue error message */
if(SbCompare(GetPropName(FetchSym(rhte,FALSE)), GetPropName(FetchSym(pExport->ax_symdef,FALSE)), 0))
{
/* skip the (alias %s) part */
OutError(ER_expund,1 + GetPropName(FetchSym(rhte,FALSE)), " ");
}
else
{
if(p = GetMem(SBLEN + 20))
sprintf(p, " (alias %s) ", 1 + GetPropName(FetchSym(pExport->ax_symdef,FALSE)));
OutError(ER_expund,1 + GetPropName(FetchSym(rhte,FALSE)),p);
if(p) FreeMem(p);
}
/* Flag export as undefined */
pExport = (APROPEXPPTR ) FetchSym(rprop,TRUE);
pExport->ax_symdef = RHTENIL;
return;
}
apropnam = (APROPNAMEPTR) aprop;
sa = mpsegsa[mpgsnseg[apropnam->an_gsn]];
/* Get the file segment number */
ra = apropnam->an_ra; /* Get the offset in the segment */
#if NOT EXE386
if(apropnam->an_flags & FIMPORT) /* If public is an import */
{
/* Issue error message */
OutError(ER_expimp,1 + GetPropName(FetchSym(rhte,FALSE)),
1 + GetPropName(FetchSym(pExport->ax_symdef,FALSE)));
/* Flag export as undefined */
pExport = (APROPEXPPTR ) FetchSym(rprop,TRUE);
pExport->ax_symdef = RHTENIL;
return;
}
if (!IsIOPL(mpsaflags[sa])) /* If not I/O privileg segment */
pExport->ax_flags &= 0x07; /* force parameter words to 0 */
#endif
pExport = (APROPEXPPTR ) FetchSym(rprop,TRUE);
/* Fetch the export property cell */
pExport->ax_sa = sa; /* Set the file segment number */
pExport->ax_ra = ra; /* Set the offset in the segment */
MARKVP();
if(ord == 0) return; /* Skip unspecified ordinals for now */
if(!BuildList(ord, rprop)) /* If ordinal conflict found */
{
/*
* Issue error message for ordinal conflict
*/
OutError(ER_ordmul,ord,1 + GetPropName(FetchSym(rhte,FALSE)));
return;
}
}
/****************************************************************
* *
* NAME: SavExp2 *
* *
* DESCRIPTION: *
* *
* This function enters those exports without preassigned *
* ordinal numbers into the table to which prb refers. It *
* also builds the resident and non-resident name tables. *
* *
* ARGUMENTS: *
* *
* APROPEXPPTR apropexp Export record pointer *
* RBTYPE rhte Addr of hash table entry *
* RBTYPE rprop Address of export record *
* FTYPE fNewHte New hash table entry flag *
* *
* RETURNS: *
* *
* Nothing. *
* *
* SIDE EFFECTS: *
* *
* Entries are made in a table in virtual memory. A global *
* variable is set to contain the highest ordinal value seen. *
* *
* NOTE: THIS FUNCTION CALLS THE VIRTUAL MEMORY MANAGER. *
* *
****************************************************************/
LOCAL void SavExp2(APROPNAMEPTR apropexp,
RBTYPE rhte,
RBTYPE rprop,
WORD fNewHte)
{
AHTEPTR ahte; /* Pointer to hash table entry */
APROPNAMEPTR apropnam; /* Public definition record pointer */
WORD ord; /* Ordinal number */
WORD cb; /* # of bytes in name table entry */
SATYPE sa; /* File segment number */
FTYPE fResNam; /* True if name is resident */
FTYPE fNoName; /* True if discard name */
APROPEXPPTR pExport;
SBTYPE sbName;
pExport = (APROPEXPPTR ) apropexp;
if (pExport->ax_symdef == RHTENIL) return;
/* Skip undefined exports */
apropnam = (APROPNAMEPTR ) FetchSym(pExport->ax_symdef,FALSE);
/* Fetch the public symbol def. */
sa = mpsegsa[mpgsnseg[apropnam->an_gsn]];
/* Get the file segment number */
#if NOT EXE386
if (!IsIOPL(mpsaflags[sa])) /* If not I/O privileg segment */
pExport->ax_flags &= 0x07; /* force parameter words to 0 */
#endif
if ((ord = pExport->ax_ord) == 0) /* If unassigned export found */
{
ord = Insert(rprop); /* Add new export to the list */
fResNam = (FTYPE) TRUE; /* Name is resident */
}
else
fResNam = (FTYPE) ((pExport->ax_nameflags & RES_NAME) != 0);
/* Else set resident name flag */
fNoName = (FTYPE) ((pExport->ax_nameflags & NO_NAME) != 0);
ahte = (AHTEPTR ) FetchSym(rhte,FALSE);
/* Get external name */
cb = B2W(ahte->cch[0]) + 1; /* Number of bytes incl. length byte */
#if EXE386
/*
* For linear-executable build the Export Name Pointers Table and
* Export Name Table. For linear-executable all exported names
* are put in one Exported Name Table; there is no distiction
* between resident and non-resident tables. We still support
* the NONAME keyword by removing the exported name
* from the Export Name Table.
*/
if (!fNoName)
{
if (cb > sizeof(sbName) - sizeof(BYTE))
cb = sizeof(sbName) - sizeof(BYTE);
memcpy(sbName, GetFarSb(ahte->cch), cb + 1);
/* Copy the name to local buffer */
if (fIgnoreCase)
SbUcase(sbName); /* Make upper case if ignoring case */
// Store the pointer to the name; for now it is an offset from
// the begin of Export Name Table (be sure that name doesn't
// cross VM page boundary). Later when the size of the
// Export Directory Table plus the size of Export Address Table
// becomes known we update the entries in the Export Name Pointer
// Table to become a relative virtual address from the Export
// Directory Table.
if ((cbExpName & (PAGLEN - 1)) + cb > PAGLEN)
cbExpName = (cbExpName + PAGLEN - 1) & ~(PAGLEN - 1);
vmmove(sizeof(DWORD), &cbExpName, AREANAMEPTR + cbNamePtr, TRUE);
cbNamePtr += sizeof(DWORD);
if (cbNamePtr > NAMEPTRSIZE)
Fatal(ER_nameptrovf, NAMEPTRSIZE);
// Store exported name
vmmove(cb, &sbName[1], AREAEXPNAME + cbExpName, TRUE);
cbExpName += cb;
if (cbExpName > EXPNAMESIZE)
Fatal(ER_expnameovf, EXPNAMESIZE);
}
#else
/* Add exported name to segmented-executable name tables */
if (fResNam || !fNoName)
{
if (cb > sizeof(sbName) - sizeof(BYTE))
cb = sizeof(sbName) - sizeof(BYTE);
memcpy(sbName, GetFarSb(ahte->cch), cb + 1);
/* Copy the name to local buffer */
if (fIgnoreCase
#if NOT OUT_EXP
|| TargetOs == NE_WINDOWS
#endif
)
SbUcase(sbName); /* Make upper case if ignoring case */
AddName(fResNam ? &ResidentName : &NonResidentName,
sbName, ord);
}
#endif
}
#pragma check_stack(on)
void NEAR InitEntTab()
{
BYTE OrdinalSet[MaxIndex];
/* Ordinal numbers set */
#if NOT EXE386
APROPEXPPTR exp; /* Pointer to export property cell */
#endif
WORD i; /* Index */
tyCurBnd = 0xFFFF; /* Won't match any legal types */
ceCurBnd = 0; /* No entries yet */
offCurBnd = 0; /* First bundle at beginning */
ordMac = 0; /* Assume no exported entries */
pOrdinalSet = OrdinalSet; /* Set global pointer */
memset(OrdinalSet,0,MaxIndex*sizeof(BYTE));
/* Initialize set to empty */
EnSyms(SavExp1,ATTREXP); /* Enumerate exports with ordinals */
FreeRange.ord = 1; /* Initialize free range of ordinals */
FreeRange.count = 0;
pStart = pMinOrd;
EnSyms(SavExp2,ATTREXP); /* Enumerate exports without ordinals */
if (MaxOrd > ordMac)
ordMac = MaxOrd;
pStart = pMinOrd;
for(i = 1; i <= ordMac && pStart != NULL; ++i)
{ /* Loop to start Entry Table */
#if EXE386
pExport = (APROPEXPPTR ) FetchSym(pStart,FALSE);
/* Fetch symbol from virtual memory */
pStart = pExport->ax_NextOrd; /* Go down on list */
NewEntry(pExport->ax_sa, pExport->ax_ra, pExport->ax_flags,
hashra(pExport->ax_ra), pExport->ax_ord);
#else
if(NotInSet(i)) /* If a hole found */
{
if (tyCurBnd != BNDNIL || ceCurBnd == BNDMAX)
NewBundle(BNDNIL);
/* Make a new bundle if needed */
++ceCurBnd; /* Increment counter */
continue; /* Next iteration */
}
exp = (APROPEXPPTR ) FetchSym(pStart,FALSE);
/* Fetch symbol from virtual memory */
pStart = exp->ax_NextOrd; /* Go down on list */
NewEntry(exp->ax_sa,exp->ax_ra,exp->ax_flags,hashra(exp->ax_ra),i);
#endif
/* Create Entry Table entry */
}
#if EXE386
SortPtrTable();
pExport = NULL;
#endif
}
#pragma check_stack(off)
#if NOT EXE386
/****************************************************************
* *
* NAME: OutEntTab *
* *
* DESCRIPTION: *
* *
* This function writes the Entry Table to the executable *
* file. First it writes an empty bundle to mark the end of *
* the table. *
* *
* ARGUMENTS: *
* *
* None *
* *
* RETURNS: *
* *
* Nothing. *
* *
* SIDE EFFECTS: *
* *
* A table is written to the file specified by the global *
* file pointer, bsRunfile. This function calls OutVm(), *
* which CALLS THE VIRTUAL MEMORY MANAGER. *
* *
****************************************************************/
void NEAR OutEntTab()
{
NewBundle(ET_END); /* Append an empty bundle */
WriteByteArray(&EntryTable); /* Write the table */
}
#endif
#endif /* NOT QCLINK */
#if NOT EXE386
/****************************************************************
* *
* NAME: MatchRlc *
* *
* DESCRIPTION: *
* *
* This function compares two relocation records and returns *
* TRUE if they match. Two records are said to match if they *
* agree on the fixup type and the target specification. The *
* location being fixed up does not have to match. *
* *
* ARGUMENTS: *
* *
* struct new_rlc *rlcp0 Ptr to relocation record *
* struct new_rlc *rlcp1 Ptr to relocation record *
* *
* RETURNS: *
* *
* FTYPE *
* *
* SIDE EFFECTS: *
* *
* None. *
* *
****************************************************************/
LOCAL WORD NEAR MatchRlc(rlcp0,rlcp1)
RLCPTR rlcp0; /* Ptr to struct new_rlc record */
RLCPTR rlcp1; /* Ptr to struct new_rlc record */
{
if(NR_STYPE(*rlcp0) != NR_STYPE(*rlcp1) ||
NR_FLAGS(*rlcp0) != NR_FLAGS(*rlcp1)) return(FALSE);
/* Check flags and type */
if((NR_FLAGS(*rlcp0) & NRRTYP) == NRRINT)
{ /* If internal reference */
return((NR_SEGNO(*rlcp0) == NR_SEGNO(*rlcp1)) &&
(NR_ENTRY(*rlcp0) == NR_ENTRY(*rlcp1)));
/* Check internal references */
}
return((NR_MOD(*rlcp0) == NR_MOD(*rlcp1)) &&
(NR_PROC(*rlcp0) == NR_PROC(*rlcp1)));
/* Check imports */
}
/****************************************************************
* *
* NAME: SaveFixup *
* *
* DESCRIPTION: *
* *
* This function saves a fixup record for emission later. In *
* addition, if the fixup is not additive, it builds chains. *
* *
* ARGUMENTS: *
* *
* SATYPE saLoc Segment of location to fix *
* relocation *rlcp Ptr to relocation record *
* *
* RETURNS: *
* *
* RATYPE *
* Returns the previous head of the fixup chain so that it *
* can be stuffed into the location being fixed up. If the *
* fixup is additive, however, it always returns EOC. *
* *
****************************************************************/
RATYPE NEAR SaveFixup(SATYPE saLoc, RLCPTR rlcp)
{
WORD hi; // Hash index
RLCHASH FAR *pHt; // Hash table
RLCBUCKET FAR *pBucket; // Relocation bucket
WORD fi; // fixup bucket index
RLCPTR pRlc; // Pointer to relocation record
WORD tmp;
RATYPE ra;
void FAR *pTmp;
#ifndef UNPOOLED_RELOCS
if (pPoolRlc == NULL)
pPoolRlc = PInit();
#endif
if (mpsaRlc[saLoc] == NULL)
{
// Allocate hash vector for physical segment saLoc
#ifndef UNPOOLED_RELOCS
mpsaRlc[saLoc] = (RLCHASH FAR *) PAlloc(pPoolRlc, sizeof(RLCHASH));
#else
mpsaRlc[saLoc] = (RLCHASH FAR *) GetMem(sizeof(RLCHASH));
#endif
}
pHt = mpsaRlc[saLoc];
tmp = hashrlc(rlcp);
hi = (WORD) tmp;
pBucket = pHt->hash[hi];
#if FALSE
if (saLoc == 2 && hi == 8)
{
fprintf(stdout, "Storing fixup for segment: %d\r\n", saLoc);
fprintf(stdout, " Source offset: %x; type: %x\r\n", NR_SOFF(*rlcp), NR_STYPE(*rlcp));
fprintf(stdout, " Hash index: %d\r\n", hi);
}
#endif
if (pBucket && !(NR_FLAGS(*rlcp) & NRADD))
{
// For non-additive fixups search the bucket for
// matching relocation records
for(fi = 0; fi < pBucket->count; fi++)
{
pRlc = &(pBucket->rgRlc[fi]);
if (MatchRlc(pRlc, rlcp))
{
// Relocation records match - chain them
ra = (WORD) NR_SOFF(*pRlc);
// Save previous head of chain
NR_SOFF(*pRlc) = NR_SOFF(*rlcp);
// Insert new head of chain
#if FALSE
if (saLoc == 2 && hi == 8)
fprintf(stdout, " Match found with fixup @%x\r\n", ra);
#endif
return(ra); // Return previous head of chain
}
}
}
// At this point, we know we have to add a new entry
// to the bucket we are examining.
pHt->count++; // Increment count of fixups per segment
#if FALSE
if (saLoc == 2 && hi == 8)
fprintf(stdout, " New entry; Count: %d\r\n", pHt->count);
#endif
// Check space in the bucket
if (pBucket == NULL)
{
// Allocate new fixup bucket
#ifndef UNPOOLED_RELOCS
pBucket = (RLCBUCKET FAR *) PAlloc(pPoolRlc, sizeof(RLCBUCKET));
pBucket->rgRlc = (RLCPTR) PAlloc(pPoolRlc, BUCKET_DEF * sizeof(RELOCATION));
#else
pBucket = (RLCBUCKET FAR *) GetMem(sizeof(RLCBUCKET));
pBucket->rgRlc = (RLCPTR) GetMem(BUCKET_DEF * sizeof(RELOCATION));
#endif
pBucket->countMax = BUCKET_DEF;
pHt->hash[hi] = pBucket;
}
else if (pBucket->count >= pBucket->countMax)
{
// Realloc fixup bucket
#ifndef UNPOOLED_RELOCS
// REVIEW: for now we just throw away the old memory, we'll free
// REVIEW: it later, we do this infrequently anyways...
pTmp = PAlloc(pPoolRlc, (pBucket->countMax << 1) * sizeof(RELOCATION));
FMEMCPY(pTmp, pBucket->rgRlc, pBucket->countMax * sizeof(RELOCATION));
// FFREE(pBucket->rgRlc); NOT MUCH MEMORY WASTED HERE
#else
pTmp = GetMem((pBucket->countMax << 1) * sizeof(RELOCATION));
FMEMCPY(pTmp, pBucket->rgRlc, pBucket->countMax * sizeof(RELOCATION));
FFREE(pBucket->rgRlc);
#endif
pBucket->rgRlc = pTmp;
pBucket->countMax <<= 1;
}
// Add new relocation record at the end of bucket
NR_RES(*rlcp) = '\0'; // Zero the reserved field
pBucket->rgRlc[pBucket->count] = *rlcp;
++pBucket->count; // Increment count of fixups
return(EOC); // Return end-of-chain marker
}
/****************************************************************
* *
* NAME: OutFixTab *
* *
* DESCRIPTION: *
* *
* This fuction writes the load-time relocation (fixup) table *
* for a given file segment to the execuatble file. *
* *
* ARGUMENTS: *
* *
* SATYPE sa File segment number *
* *
* RETURNS: *
* *
* Nothing. *
* *
* SIDE EFFECTS: *
* *
* A table is written to the file specified by the global *
* file pointer, bsRunfile. *
* *
****************************************************************/
void NEAR OutFixTab(SATYPE sa)
{
WORD hi; // Hash table index
RLCHASH FAR *pHt;
RLCBUCKET FAR *pBucket;
pHt = mpsaRlc[sa];
WriteExe(&(pHt->count), CBWORD); // Write the number of relocations
for (hi = 0; hi < HASH_SIZE; hi++)
{
pBucket = pHt->hash[hi];
if (pBucket != NULL)
{
WriteExe(pBucket->rgRlc, pBucket->count * sizeof(RELOCATION));
#ifdef UNPOOLED_RELOCS
FFREE(pBucket->rgRlc);
#endif
}
}
#ifdef UNPOOLED_RELOCS
FFREE(pHt);
#endif
}
/****************************************************************
* *
* NAME: ReleaseRlcMemory *
* *
* DESCRIPTION: *
* *
* This function releases the pool(s) of memory that held the *
* segment relocations *
* *
* RETURNS: *
* *
* Nothing. *
* *
* SIDE EFFECTS: *
* *
* pPoolRlc is set to NULL so that we will fail if we should *
* ever try to allocate more relocations after this point *
* *
****************************************************************/
void NEAR ReleaseRlcMemory()
{
#ifndef UNPOOLED_RELOCS
// free all the memory associated with the saved relocation
if (pPoolRlc) {
PFree(pPoolRlc);
pPoolRlc = NULL;
}
#endif
}
#endif /* NOT EXE386 */