Windows2000/private/windbg64/debugger/ee/debfmt.c

3525 lines
101 KiB
C
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2001-01-01 00:00:00 +01:00
/*** debfmt.c - expression evaluator formatting routines
* GLOBAL
* LOCAL
* DESCRIPTION
* Expression evaluator formatting routines
*/
#include "debexpr.h"
#include "ldouble.h"
#ifndef _SBCS
#include <mbctype.h>
#endif
#include "locale.h"
#define _CRTBLD // work around bug in headers
#include "undname.h"
#undef _CRTBLD
#ifdef USE_CUSTVIEW
#include "custview.h"
HRESULT WINAPI ExportViewHwnd( DWORD dwAddress, DEBUGHELPER *pHelper, int nBase, BOOL bUniStrings, char *pResult, size_t max, DWORD reserved );
HRESULT WINAPI ExportViewGuid( DWORD dwAddress, DEBUGHELPER *pHelper, int nBase, BOOL bUniStrings, char *pResult, size_t max, DWORD reserved );
HRESULT WINAPI ExportViewVariant( DWORD dwAddress, DEBUGHELPER *pHelper, int nBase, BOOL bUniStrings, char *pResult, size_t max, DWORD reserved );
HRESULT WINAPI ExportViewHresult( DWORD dwAddress, DEBUGHELPER *pHelper, int nBase, BOOL bUniStrings, char *pResult, size_t max, DWORD reserved );
extern DEBUGHELPER StaticHelper;
#endif // USE_CUSTVIEW
void InsertCache (CV_typ_t, HEXE);
typedef enum FMT_ret {
FMT_error,
FMT_none,
FMT_ok
} FMT_ret;
typedef struct FMT_state {
pexstate_t pExState;
char *pExStr;
PCXT pCxt;
} FMT_state;
// definitions used for caching auto-expansion rules
// The cache is implemented as a table. Each entry maps a pair
// (type, hExe) to the corresponding auto expansion rule string
// (that string may be NULL if no rule exists for the particular type)
typedef struct aecache_t {
CV_typ_t typ;
HEXE hExe;
EEHSTR hStr;
} aecache_t;
#define AECACHE_MAX 64 // max number of entries in the cache
static aecache_t AECache [AECACHE_MAX] = {0}; // cache for auto-exp. rules
static int cAECache = 0; // current number of entries
void AppendCVQualifier (peval_t, char * *, uint *);
int ConvertWCToMB (char *, wchar_t);
EESTATUS Format (peval_t, uint, char * *, int *, bool_t);
void EvalString (peval_t, char * *, int *, bool_t);
void EvalMem (peval_t, char *FAR *, int *, char);
void FormatAutoExpand (peval_t, uint, char * *, int *);
void FormatAEChildTM (uint, peval_t, uint, char * *, int *);
void FormatAEDownCastType (peval_t, uint, char * *, int *);
void FormatAEError (peval_t, uint, char * * , int *);
BOOL GetRawAddr( peval_t pv, ADDR *paddr );
void FormatExpand (peval_t, char * *, uint *, char * *, ulong, PHDR_TYPE);
void FormatClass (peval_t, uint, char * * , int *);
EESTATUS FormatEnum (peval_t, char * , int );
void FormatProc (peval_t, char * *, uint *, char * *, CV_typ_t, CV_typ_t, CV_call_e, ulong , CV_typ_t, ulong, PHDR_TYPE);
char * FormatUndecorate( char*, char*);
char * FormatVirtual (char *, peval_t, PEEHSTR);
FMT_ret VerifyFormat (peval_t, PEEFORMAT, char * *, int *, bool_t *);
INLINE bool_t IsPrint (int ch);
void FASTCALL DoAutoExpand (PHTM);
void FASTCALL DoBindAutoExpand (PHTM);
void FASTCALL DoEvalAutoExpand (PHTM);
bool_t FASTCALL FindAERule (peval_t, LSZ, uint);
bool_t FASTCALL UpdateEEHSTR(EEHSTR *, LSZ);
void FASTCALL SaveFmtState (FMT_state *);
void FASTCALL RestoreFmtState (FMT_state *);
bool_t FASTCALL LookupAECache (CV_typ_t, HEXE, char *);
void FASTCALL ReorderAECache (int);
void FASTCALL InsertAECache (CV_typ_t, HEXE, char far *);
static char accessstr[4][4] = {" ", "PV ", "PR ", "PB "};
struct typestr {
uchar type; // type and subtype
uchar len;
char SEGBASED (_segname("_CODE")) * name;
};
struct modestr {
uchar mode;
uchar len;
char SEGBASED (_segname("_CODE")) * name;
};
#pragma warning ( disable:4120 ) // "based/unbased mismatch"
// define all the strings in the code segment
#define TYPENAME(name, type, len, str) static char SEGBASED(_segname("_CODE")) S##name[] = str;
#define MODENAME(name, mode, len, str) static char SEGBASED(_segname("_CODE")) S##name[] = str;
#define PTRNAME(name, str) static char SEGBASED(_segname("_CODE")) S##name[] = str;
#include "fmtstr.h"
#undef TYPENAME
#undef MODENAME
#undef PTRNAME
// load all the type names into a table
static struct typestr SEGBASED(_segname("_CODE")) nametype[] = {
#define TYPENAME(name, type, len, str) {type, len, S##name},
#define MODENAME(name, mode, len, str)
#define PTRNAME(name, str)
#include "fmtstr.h"
#undef TYPENAME
#undef MODENAME
#undef PTRNAME
};
// load all the mode names into a table
static struct modestr SEGBASED(_segname("_CODE")) namemode[] = {
#define TYPENAME(name, type, len, str)
#define MODENAME(name, mode, len, str) {mode, len, S##name},
#define PTRNAME(name, str)
#include "fmtstr.h"
#undef TYPENAME
#undef MODENAME
#undef PTRNAME
};
// load all the pointer type names into an array
static char SEGBASED(_segname("_CODE")) *SEGBASED(_segname("_CODE")) ptrname[] = {
#define TYPENAME(name, type, len, str)
#define MODENAME(name, mode, len, str)
#define PTRNAME(name, str) S##name,
#include "fmtstr.h"
#undef TYPENAME
#undef MODENAME
#undef PTRNAME
};
#pragma warning ( default:4120 ) // "based/unbased mismatch"
#define typecount (sizeof (nametype) / sizeof (nametype[0]))
#define modecount (sizeof (namemode) / sizeof (namemode[0]))
char *fmt_char_nz[] = {
"0%03.03o '%c'",
"%d '%c'",
"0x%02.02x '%c'",
"0x%02.02X '%c'",
};
// The IDE wants to show a null character as '\x00', but CV wants to show
// it as ''
#ifdef WINQCXX
#define szNullChar "\\x00"
#else
#define szNullChar ""
#endif
char *fmt_char_zr[] = {
"0%03.03o '" szNullChar "'",
"%d '" szNullChar "'",
"0x%02.02x '" szNullChar "'",
"0x%02.02X '" szNullChar "'",
};
char *fmt_char[] = {
"0%03.03o",
"%d",
"0x%02.02x",
"0x%02.02X",
};
char *fmt_short[] = {
"0%06.06ho",
"%hd",
"0x%04.04hx",
"0x%04.04hX",
};
char *fmt_ushort[] = {
"0%06.06ho",
"%hu",
"0x%04.04hx",
"0x%04.04hX",
};
char *fmt_long[] = {
"0%011.011lo",
"%ld",
"0x%08.08lx",
"0x%08.08lX",
};
char *fmt_ulong[] = {
"0%011.011lo",
"%lu",
"0x%08.08lx",
"0x%08.08lX",
};
char *fmt_quad[] = {
"0%022.022I64o",
"%I64d",
"0x%016.016I64x",
"0x%016.016I64X",
};
char *fmt_uquad[] = {
"0%022.022I64o",
"%I64u",
"0x%016.016I64x",
"0x%016.016I64X",
};
char *fmt_ptr_16_16[] = {
"0x%04hx:0x%04hx",
"0x%04hX:0x%04hX",
};
char *fmt_ptr_16_32[] = {
"0x%04hx:0x%08lx",
"0x%04hX:0x%08lX",
};
char *fmt_ptr_0_16[] = {
"0x%04hx",
"0x%04hX",
};
char *fmt_ptr_0_32[] = {
"0x%08lx",
"0x%08lX",
};
char *fmt_ptr_64[] = {
"0x%016I64x",
"0x%016I64X",
};
char *bailout = "\x006""??? * ";
// on some locales (eg German) use commas instead of periods in floats.
// This confuses the EE greatly as it thinks the commas are part of the format specifier
int sprintf_english( char *buffer, const char *fmtStr, ... )
{
int cResult;
va_list marker;
va_start( marker, fmtStr );
setlocale( LC_NUMERIC, "C" );
cResult = vsprintf( buffer, fmtStr, marker );
setlocale( LC_NUMERIC, "" );
va_end( marker );
return cResult;
}
/** FormatCXT - format context packet
* status = FormatCXT (pCXT, phStr, dwFlags);
* Entry pCXT = pointer to context
* phStr = return location for string
* dwFlags = control flags for formatting
* Exit context formatted into buffer as a context operator
* Returns EENONE if no error
* EEGENERAL if error
*/
ulong FormatCXT (PCXT pCXT, PEEHSTR phStr, DWORD dwFlags)
{
HMOD hMod;
HPROC hProc;
HSF hsf;
HEXE hExe;
SYMPTR pProc;
char *pFile;
char *pExe;
char *pStr;
uint len = 6;
eval_t eval;
peval_t pv = &eval;
char buf[FCNSTRMAX + sizeof(HDR_TYPE)];
char *pName = buf;
char procName[NAMESTRMAX];
char *pFName;
char *pc = 0;
uint lenP;
CV_typ_t typ;
PHDR_TYPE pHdr;
hMod = SHHMODFrompCXT (pCXT);
hProc = SHHPROCFrompCXT (pCXT);
if ((hMod == 0) && (hProc == 0)) {
if ((*phStr = MemAllocate (10)) != 0) {
pStr = (char *) MemLock (*phStr);
*pStr = 0;
MemUnLock (*phStr);
return (EENOERROR);
}
}
hsf = SLHsfFromPcxt (pCXT);
hExe = SHHexeFromHmod (hMod);
if (dwFlags & HCXTFMT_Short) {
pExe = SHGetModNameFromHexe( hExe );
}
else {
pExe = SHGetExeName( hExe );
}
if ( pExe == NULL) {
// we can't generate a CXT if we can't get the exe name
return (EECATASTROPHIC);
}
pFile = SLNameFromHsf (hsf) ;
// it is possible to get the exe name, but not source
// file/line information (ex. a public) In this case we will use
// pExe instead of pFile (ie. {,,foob.exe} )
if (hProc != 0) {
switch ((pProc = (SYMPTR)MHOmfLock ((HSYM)hProc))->rectyp) {
case S_LPROC16:
case S_GPROC16:
lenP = ((PROCPTR16)pProc)->name[0];
pFName = (char *) &((PROCPTR16)pProc)->name[1];
typ = ((PROCPTR16)pProc)->typind;
break;
case S_LPROC32:
case S_GPROC32:
lenP = ((PROCPTR32)pProc)->name[0];
pFName = (char *) &((PROCPTR32)pProc)->name[1];
typ = ((PROCPTR32)pProc)->typind;
break;
case S_LPROCMIPS:
case S_GPROCMIPS:
lenP = ((PROCPTRMIPS)pProc)->name[0];
pFName = (char *) &((PROCPTRMIPS)pProc)->name[1];
typ = ((PROCPTRMIPS)pProc)->typind;
break;
case S_LPROCIA64:
case S_GPROCIA64:
lenP = ((PROCPTRIA64)pProc)->name[0];
pFName = (char *) &((PROCPTRIA64)pProc)->name[1];
typ = ((PROCPTRIA64)pProc)->typind;
break;
default:
DASSERT (FALSE);
// Perhaps this should be handled differently. The situation is that
// a thunk has MOD and PROC context, but no typind.
case S_THUNK32:
MHOmfUnLock (hProc);
return (EECATASTROPHIC);
}
_tcsncpy(procName, pFName, lenP);
procName[lenP] = '\0';
EVAL_MOD(pv) = hMod;
pv->CXTT = *pCXT;
SetNodeType(pv, typ);
pHdr = (PHDR_TYPE)pName;
memset (pName, 0, FCNSTRMAX + sizeof (HDR_TYPE));
pName = pName + sizeof (HDR_TYPE);
pc = pName;
lenP = FCNSTRMAX - 1;
pFName = procName;
// set selection mask in order to supress formatting
// of the proc return type
FormatType (pv, &pName, &lenP, &pFName, 0x1L, pHdr);
lenP = FCNSTRMAX - lenP;
// ignore buffer header from FormatType
memmove ((char *)pHdr, pc, lenP);
pc = (char *)pHdr;
len += lenP;
}
if ( pFile ) {
len += (UINT)(BYTE)*pFile + (int)_tcslen (pExe) ;
}
else {
len += (int)_tcslen (pExe) ;
}
if ((*phStr = MemAllocate (len)) != 0) {
pStr = (char *) MemLock (*phStr);
if (dwFlags & HCXTFMT_Short) {
_tcscpy(pStr, pExe);
_tcsupr(pStr);
_tcscat(pStr, "!");
}
else {
_tcscpy (pStr, "{");
if (hProc != 0 && !(dwFlags & HCXTFMT_No_Procedure)) {
_tcscat (pStr, pc);
}
_tcscat (pStr, ",");
if ( pFile ) {
_tcsncat (pStr, pFile + 1, (UINT)(BYTE)*pFile);
}
_tcscat (pStr, ",");
_tcscat (pStr, pExe);
_tcscat (pStr, "}");
}
MemUnLock (*phStr);
}
else {
MHOmfUnLock (hProc);
return (EECATASTROPHIC);
}
MHOmfUnLock (hProc);
return (EENOERROR);
}
/** AppendCVQualifier - append "const"/"volatile" qualifier
* AppendCVQualifier (pv, buf, buflen);
* Entry pv = pointer to value node
* buf = pointer pointer to buffer
* buflen = pointer to buffer length
* Exit type qualifier (const / volatile) appended to buffer
* *buflen = space remaining in buffer
* Returns none
*/
void AppendCVQualifier (peval_t pv, char * *buf, uint *buflen)
{
uint len;
if (EVAL_IS_CONST (pv)) {
len = min (*buflen, 6);
_tcsncpy (*buf, "const ", len);
*buf += len;
*buflen -= len;
}
else if (EVAL_IS_VOLATILE (pv)) {
len = min (*buflen, 9);
_tcsncpy (*buf, "volatile ", len);
*buf += len;
*buflen -= len;
}
}
/** FormatType - format type string
* FormatType (pv, ppbuf, pcount, ppName, select, pHdr);
* Entry pv = pointer to value node
* ppbuf = pointer pointer to buffer
* pcount = pointer to buffer length
* ppName = pointer to name if not null
* select = selection mask
* pHdr = pointer to structure describing formatting
* Exit type formatted into buffer
* *pcount = space remaining in buffer
* *pHdr updated
* Returns none
*/
void FormatType (peval_t pv, char * *buf, uint *buflen,
char * *ppName, ulong select, PHDR_TYPE pHdr)
{
eval_t evalT;
peval_t pvT = &evalT;
uint skip = 1;
uint len;
int itype, imode;
char *tname;
CV_typ_t type;
#if defined (NEVR)
if (EVAL_ACCESS (pv) != 0) {
len = min (*buflen, 3);
_tcsncpy (*buf, accessstr[EVAL_ACCESS (pv)], len);
*buf += len;
*buflen -= len;
}
#endif
if (!EVAL_IS_PTR (pv)) {
AppendCVQualifier(pv, buf, buflen);
}
if (CV_IS_PRIMITIVE (EVAL_TYP (pv))) {
switch (EVAL_TYP (pv)) {
default:
// determine type
for (itype = 0; itype < typecount; itype++) {
if (nametype[itype].type == (EVAL_TYP (pv) & (CV_TMASK|CV_SMASK)))
break;
}
// determine mode (e.g. direct, near ptr, etc.)
for (imode = 0; imode < modecount; imode++) {
if (namemode[imode].mode == CV_MODE (EVAL_TYP (pv)))
break;
}
// if the whole type consists of the matched type & mode,
// then we have a match
if (EVAL_TYP (pv) ==
(CV_typ_t) ((nametype[itype].type) |
(namemode[imode].mode << CV_MSHIFT))) {
// copy type string
len = min (*buflen, nametype[itype].len);
_tcsncpy (*buf, nametype[itype].name, len);
*buf += len;
*buflen -= len;
// copy mode string
len = min (*buflen, namemode[imode].len);
_tcsncpy (*buf, namemode[imode].name, len);
*buf += len;
*buflen -= len;
}
else {
// no match
len = min (*buflen, (sizeof("??? ") - 1));
_tcsncpy (*buf, "??? ", len);
*buf += len;
*buflen -= len;
}
break;
case T_NCVPTR:
tname = "\x007""near * ";
goto formatmode;
case T_HCVPTR:
tname = "\x007""huge * ";
goto formatmode;
case T_FCVPTR:
tname = "\x006""far * ";
goto formatmode;
case T_32NCVPTR:
case T_32FCVPTR:
case T_64NCVPTR:
tname = "\x002""* ";
formatmode:
AppendCVQualifier(pv, buf, buflen);
*pvT = *pv;
SetNodeType (pvT, PTR_UTYPE (pv));
type = EVAL_TYP (pvT);
if (CV_IS_INTERNAL_PTR (type)) {
// we are in a bind here. The type generator messed
// up and generated a created type pointing to a created
// type. we are going to bail out here.
len = min (*buflen, (uint)*bailout);
_tcsncpy (*buf, bailout + 1, len);
*buflen -= len;
*buf += len;
}
else {
FormatType (pvT, buf, buflen, 0, select, pHdr);
}
len = min (*buflen, (uint)*tname);
_tcsncpy (*buf, tname + 1, len);
*buflen -= len;
*buf += len;
break;
}
}
else {
#ifdef NEVER
if (FormatUDT (pv, buf, buflen) == FALSE)
#endif
FormatExpand (pv, buf, buflen, ppName, select, pHdr);
}
if (ppName != NULL && *ppName != NULL) {
len = (int)_tcslen (*ppName);
len = min (len, *buflen);
pHdr->offname = (ulong)(*buf - (char *)pHdr - sizeof (HDR_TYPE));
pHdr->lenname = len;
_tcsncpy (*buf, *ppName, len);
*buflen -= len;
*buf += len;
*ppName = NULL;
}
}
/** FormatExpand - format expanded type definition
* FormatExpand (pv, ppbuf, pbuflen, ppName, select)
* Entry pv = pointer to value node
* ppbuf = pointer to pointer to buffer
* pbuflen = pointer to space remaining in buffer
* ppName = pointer to name to insert after type if not null
* select = selection mask
* pHdr = pointer to type formatting header
* Exit buffer contains formatted type
* ppbuf = end of formatted string
* pbuflen = space remaining in buffer
* Returns none
*/
void
FormatExpand (
peval_t pv,
char * *buf,
uint *buflen,
char * *ppName,
ulong select,
PHDR_TYPE pHdr
)
{
eval_t evalT;
peval_t pvT = &evalT;
uint skip = 1;
uint len;
HTYPE hType;
plfEasy pType;
unsigned model;
ulong count;
char tempbuf[33];
CV_typ_t rvtype;
CV_typ_t mclass;
CV_call_e call;
ulong cparam;
CV_typ_t parmtype;
CV_typ_t thistype;
char *movestart;
uint movelen;
uint movedist;
HEXE hExe;
long nTypeSize;
if ((hType = THGetTypeFromIndex (EVAL_MOD (pv), EVAL_TYP (pv))) == 0) {
return;
}
pType = (plfEasy)(&((TYPPTR)(MHOmfLock (hType)))->leaf);
switch (pType->leaf) {
case LF_STRUCTURE:
case LF_CLASS:
skip = offsetof (lfClass, data);
RNumLeaf (((char *)(&pType->leaf)) + skip, &skip);
len = *(((char *)&(pType->leaf)) + skip);
len = min (len, *buflen);
_tcsncpy (*buf, ((char *)pType) + skip + 1, len);
*buflen -= len;
*buf += len;
if (*buflen > 1) {
**buf = ' ';
(*buf)++;
(*buflen)--;
}
MHOmfUnLock (hType);
break;
case LF_UNION:
skip = offsetof (lfUnion, data);
RNumLeaf (((char *)(&pType->leaf)) + skip, &skip);
len = *(((char *)&(pType->leaf)) + skip);
len = min (len, *buflen);
_tcsncpy (*buf, ((char *)pType) + skip + 1, len);
*buflen -= len;
*buf += len;
if (*buflen > 1) {
**buf = ' ';
(*buf)++;
(*buflen)--;
}
MHOmfUnLock (hType);
break;
case LF_ENUM:
skip = offsetof (lfEnum, Name);
len = ((plfEnum)pType)->Name[0];
len = min (len, *buflen);
_tcsncpy (*buf, (char *) &((plfEnum)pType)->Name[1], len);
*buflen -= len;
*buf += len;
if (*buflen > 1) {
**buf = ' ';
(*buf)++;
(*buflen)--;
}
MHOmfUnLock (hType);
break;
case LF_POINTER:
// we're going to be looking for this real soon
// put it in the cache now...
hExe = SHHexeFromHmod (EVAL_MOD (pv));
InsertCache(EVAL_TYP(pv), hExe);
// set up a node to evaluate this field
model = ((plfPointer)pType)->attr.ptrtype;
// format the underlying type
*pvT = *pv;
EVAL_TYP (pvT) = ((plfPointer)pType)->utype;
MHOmfUnLock (hType);
SetNodeType (pvT, EVAL_TYP (pvT));
FormatType (pvT, buf, buflen, 0, select, pHdr);
len = min (*buflen, (uint)*ptrname[model]);
_tcsncpy (*buf, ptrname[model] + 1, len);
*buflen -= len;
*buf += len;
if (((plfPointer)pType)->attr.ptrmode == CV_PTR_MODE_REF) {
// this is a reference type -- we must fix the string
// that we just formatted so that it looks like a reference
// and not a pointer [rm]
DASSERT((*buf)[-1] == ' ');
DASSERT((*buf)[-2] == '*');
(*buf)[-2] = '&';
}
// const/volatile qualifier for the pointer type
// should be appended after the '*'
AppendCVQualifier (pv, buf, buflen);
break;
case LF_ARRAY:
*pvT = *pv;
EVAL_TYP (pvT) = ((plfArray)(&pType->leaf))->elemtype;
skip = offsetof (lfArray, data);
count = (ulong) RNumLeaf (((char *)(&pType->leaf)) + skip, &skip);
MHOmfUnLock (hType);
SetNodeType (pvT, EVAL_TYP (pvT));
// continue down until the underlying type is reached
FormatType (pvT, buf, buflen, ppName, select, pHdr);
if ((ppName != NULL) && (*ppName != NULL)) {
len = _tcslen (*ppName);
len = min (len, *buflen);
pHdr->offname = (ulong)(*buf - (char *)pHdr - sizeof (HDR_TYPE));
pHdr->lenname = len;
_tcsncpy (*buf, *ppName, len);
*buflen -= len;
*buf += len;
*ppName = NULL;
}
// display size of array or * if size unknown. We have to
// move the trailing part of the string down if it already
// set so that the array dimensions come out in the proper
// order
nTypeSize = TypeSize (pvT);
if (count != 0 && nTypeSize != 0) {
ultoa (count / nTypeSize, tempbuf, 10);
len = _tcslen (tempbuf);
}
else {
*tempbuf = '?';
*(tempbuf + 1) = 0;
len = 1;
}
if (*buflen >= 2) {
if (pHdr->offtrail == 0) {
pHdr->offtrail = (ulong)(*buf - (char *)pHdr - sizeof (HDR_TYPE));
movestart = (char *)pHdr + sizeof (HDR_TYPE) + pHdr->offtrail;
movelen = 0;
movedist = 0;
}
else {
movestart = (char *)pHdr + sizeof (HDR_TYPE) + pHdr->offtrail;
movelen = _tcslen (movestart);
movedist = _tcslen (tempbuf) + 2;
movelen = min (*buflen, movelen);
memmove (movestart + movedist, movestart, movelen);
}
*movestart++ = '[';
memmove (movestart, tempbuf, len);
movestart += len;
*movestart++ = ']';
*buf += len + 2;
*buflen -= len + 2;
}
break;
case LF_PROCEDURE:
mclass = 0;
rvtype = ((plfProc)pType)->rvtype;
call = (CV_call_e) ((plfProc)pType)->calltype;
cparam = ((plfProc)pType)->parmcount;
parmtype = ((plfProc)pType)->arglist;
MHOmfUnLock (hType);
FormatProc (pv, buf, buflen, ppName, rvtype, mclass, call,
cparam, parmtype, select, pHdr);
break;
case LF_MFUNCTION:
rvtype = ((plfMFunc)pType)->rvtype;
mclass = ((plfMFunc)pType)->classtype;
call = (CV_call_e) ((plfMFunc)pType)->calltype;
thistype = ((plfMFunc)pType)->thistype;
cparam = ((plfMFunc)pType)->parmcount;
parmtype = ((plfMFunc)pType)->arglist;
MHOmfUnLock (hType);
FormatProc (pv, buf, buflen, ppName, rvtype, mclass, call,
cparam, parmtype, select, pHdr);
break;
case LF_MODIFIER:
#ifdef NEVER
// Disabled. We emitted const in the wrong order if the following
// node was a pointer. Let FormatType handle this [dolphin #5043]
if (*buflen >= 6) {
if (((plfModifier)pType)->attr.MOD_const == TRUE) {
_tcsncpy (*buf, "const ", 6);
*buf += 6;
*buflen -= 6;
}
}
if (*buflen >= 9) {
if (((plfModifier)pType)->attr.MOD_volatile == TRUE) {
_tcsncpy (*buf, "volatile ", 9);
*buf += 9;
*buflen -= 9;
}
}
EVAL_TYP (pv) = ((plfModifier)pType)->type;
#endif
MHOmfUnLock (hType);
SetNodeType (pv, EVAL_TYP (pv));
FormatType (pv, buf, buflen, ppName, select, pHdr);
break;
case LF_LABEL:
MHOmfUnLock (hType);
break;
default:
MHOmfUnLock (hType);
break;
}
}
#ifdef NEVER
bool_t FormatUDT (peval_t pv, char * *buf,
uint *buflen)
{
// Slow ineffective search disabled jsg 2/1/92
// This code would search all symbols for typedefs to the current type index.
// This was making the local window repaint too sluggish, since 'FormatUDT'
// can be called many times per line.
#if NEVER
search_t Name;
UDTPTR pUDT;
uint len;
// Format typedef string
InitSearchtDef (&Name, pv, SCP_module | SCP_global);
if (SearchSym (&Name) == HR_found) {
pUDT = (UDTPTR)MHOmfLock (Name.hSym);
len = pUDT->name[0];
len = min (len, *buflen);
_tcsncpy (*buf, &pUDT->name[1], len);
*buflen -= len;
*buf += len;
if (*buflen > 1) {
**buf = ' ';
(*buf)++;
(*buflen)--;
}
MHOmfUnLock (Name.hSym);
return (TRUE);
}
#endif
if (pExState != NULL)
pExState->err_num = ERR_NONE;
return (FALSE);
}
#endif
/** FormatProc - format proc or member function
* FormatProc (pv. buf, buflen, ppName, rvtype, mclass, call, cparam, paramtype, select)
*/
void
FormatProc (
peval_t pv,
char * *buf,
uint *buflen,
char * *ppName,
CV_typ_t rvtype,
CV_typ_t mclass,
CV_call_e call,
ulong cparam,
CV_typ_t paramtype,
ulong select,
PHDR_TYPE pHdr
)
{
eval_t evalT;
peval_t pvT;
HTYPE hArg;
plfArgList pArg;
ulong noffset = 1;
int len;
bool_t farcall;
ulong argCnt;
ulong saveOfftrail = pHdr->offtrail;
Unreferenced( mclass );
pvT = &evalT;
*pvT = *pv;
if (GettingChild == FALSE && (select & 0x00000001) == FALSE ) {
// output function return type if we are not getting a child TM.
// If we are getting a child tm and the function type is included,
// the subsequent parse of the generated expression will fail
// because the parse cannot handle
// type fcn (..........
// OR...
// if select == 0x1 then this is a request to format procs
// without the return type (for BPs etc)
EVAL_TYP (pvT) = (rvtype == 0)? T_VOID: rvtype;
FormatType (pvT, buf, buflen, NULL, select, pHdr);
//M00KLUDGE - need to output call and model here
switch (call) {
case CV_CALL_NEAR_C:
//near C call - caller pops stack
call = (CV_call_e) FCN_C;
farcall = FALSE;
break;
case CV_CALL_FAR_C:
// far C call - caller pops stack
call = (CV_call_e) FCN_C;
farcall = TRUE;
break;
case CV_CALL_NEAR_PASCAL:
// near pascal call - callee pops stack
call = (CV_call_e) FCN_PASCAL;
farcall = FALSE;
break;
case CV_CALL_FAR_PASCAL:
// far pascal call - callee pops stack
call = (CV_call_e) FCN_PASCAL;
farcall = TRUE;
break;
case CV_CALL_NEAR_FAST:
// near fast call - callee pops stack
call = (CV_call_e) FCN_FAST;
farcall = FALSE;
break;
case CV_CALL_FAR_FAST:
// far fast call - callee pops stack
call = (CV_call_e) FCN_FAST;
farcall = TRUE;
break;
case CV_CALL_NEAR_STD:
// near fast call - callee pops stack
call = (CV_call_e) FCN_STD;
farcall = FALSE;
break;
case CV_CALL_FAR_STD:
// far fast call - callee pops stack
call = (CV_call_e) FCN_STD;
farcall = TRUE;
break;
case CV_CALL_THISCALL:
// this goes in a reg - callee pops stack
call = (CV_call_e) FCN_THISCALL;
farcall = TRUE;
break;
case CV_CALL_MIPSCALL:
call = (CV_call_e) FCN_MIPS;
farcall = TRUE;
break;
case CV_CALL_ALPHACALL:
call = (CV_call_e) FCN_ALPHA;
farcall = TRUE;
break;
case CV_CALL_PPCCALL:
call = (CV_call_e) FCN_PPC;
farcall = TRUE;
break;
case CV_CALL_IA64CALL:
call = (CV_call_e) FCN_IA64;
farcall = TRUE;
break;
default:
DASSERT (FALSE);
call = (CV_call_e) 0;
farcall = FALSE;
break;
}
}
// output function name
if ((ppName != NULL) && (*ppName != NULL)) {
len = (int)_tcslen (*ppName);
len = __min (len, (int ) *buflen);
pHdr->offname = (ulong)(*buf - (char *)pHdr - sizeof (HDR_TYPE));
pHdr->lenname = len;
_tcsncpy (*buf, *ppName, len);
*buflen -= len;
*buf += len;
*ppName = NULL;
}
if (*buflen > 1) {
saveOfftrail = (ulong)(*buf - (char *)pHdr - sizeof (HDR_TYPE));
**buf = '(';
(*buf)++;
(*buflen)--;
}
if (cparam == 0) {
EVAL_TYP (pvT) = T_VOID;
FormatType (pvT, buf, buflen, NULL, select, pHdr);
}
else {
if ((hArg = THGetTypeFromIndex (EVAL_MOD (pv), paramtype)) == 0) {
return;
}
argCnt = 0;
while (argCnt < cparam) {
pArg = (plfArgList)((&((TYPPTR)MHOmfLock (hArg))->leaf));
EVAL_TYP (pvT) = pArg->arg[argCnt];
MHOmfUnLock (hArg);
FormatType (pvT, buf, buflen, NULL, select, pHdr);
argCnt++;
if ((argCnt < cparam) && (*buflen > 1)) {
// strip trailing blanks after the arg we just formatted
while (*((*buf)-1) == ' ') {
(*buf)--;
(*buflen)++;
}
// insert a comma and space if there are further arguments
**buf = ',';
(*buf)++;
(*buflen)--;
**buf = ' ';
(*buf)++;
(*buflen)--;
}
}
}
if (*buflen > 1) {
// strip trailing blanks
while (*((*buf)-1) == ' ') {
(*buf)--;
(*buflen)++;
}
// insert a closing parenthesis
**buf = ')';
(*buf)++;
(*buflen)--;
}
pHdr->offtrail = saveOfftrail;
}
/** FormatNode - format node according to format string
* retval = FormatNode (phTM, radix, pFormat, phValue);
* Entry phTM = pointer to handle to TM
* radix = default radix for formatting
* pFormat = pointer to format string
* phValue = pointer to handle for display string
* fAutoExpand = flag that enables auto-expanding
* Exit evaluation result formatted
* Returns EENOERROR if no error in formatting
* error number if error
*/
EESTATUS
FormatNode (
PHTM phTM,
uint Radix,
PEEFORMAT pFormat,
PEEHSTR phszValue,
SHFLAG fAutoExpand
)
{
char islong = FALSE;
char fc = 0;
char *buf;
int buflen = FMTSTRMAX - 1;
eval_t evalT;
peval_t pv = &evalT;
ulong retval = EECATASTROPHIC;
bool_t fPtrAndString;
DASSERT (*phTM != 0);
if (*phTM == 0) {
return (retval);
}
if (fAutoExpand) {
// Prepare auto-expanded child TM List
// We have to build the list here since the relevant
// code needs a handle to the TM, not just a pointer
// to the locked TM state
DoAutoExpand( phTM );
}
if ((*phszValue = MemAllocate (FMTSTRMAX)) == 0) {
// unable to allocate memory for formatting
return (retval);
}
buf = (char *)MemLock (*phszValue);
memset (buf, 0, FMTSTRMAX);
pExState = (pexstate_t) MemLock (*phTM);
pCxt = &pExState->cxt;
// Get expression string
pExStr = (char *)MemLock (pExState->hExStr);
if (pExState->state.eval_ok == TRUE) {
*pv = pExState->result;
if ((EVAL_STATE (pv) == EV_lvalue) ||
(EVAL_STATE (pv) == EV_type) ||
(EVAL_STATE (pv) == EV_rvalue && EVAL_IS_PTR (pv))) {
// do nothing
}
else {
// this handles the case were the return result is a large
// structure.
pv = &pExState->result;
}
if (EVAL_IS_REF (pv)) {
if (!LoadSymVal (pv)) {
// unable to load value
goto formatexit;
}
EVAL_IS_REF (pv) = FALSE;
EVAL_STATE (pv) = EV_lvalue;
EVAL_SYM (pv) = EVAL_PTR (pv);
SetNodeType (pv, PTR_UTYPE (pv));
}
if (EVAL_IS_CLASS (pv)) {
// For structures and classes ignore format string and format
// according to element data types
EVAL_STATE (pv) = EV_rvalue;
goto format;
}
// load value and format according to format string
if ((EVAL_STATE (pv) == EV_type) || !LoadSymVal (pv)) {
// unable to load value
retval = EEGENERAL;
if (pExState->err_num == ERR_NONE) {
pExState->err_num = ERR_NOTEVALUATABLE;
}
goto formatexit;
}
else {
switch (VerifyFormat (pv, pFormat, &buf, &buflen, &fPtrAndString)) {
case FMT_error:
retval = EEGENERAL;
pExState->err_num = ERR_FORMAT;
goto formatexit;
case FMT_none:
goto format;
case FMT_ok:
retval = EENOERROR;
goto formatexit;
}
}
}
else {
// not evaluated, fail
retval = EEGENERAL;
pExState->err_num = ERR_NOTEVALUATABLE;
goto formatexit;
}
format:
retval = Format (pv, Radix, &buf, &buflen, fPtrAndString);
if ( ( retval == EENOERROR ) && fAutoExpand && EVAL_IS_PTR (pv)) {
FormatAutoExpand (pv, Radix, &buf, &buflen);
}
formatexit:
MemUnLock (pExState->hExStr);
MemUnLock (*phszValue);
MemUnLock (*phTM);
return (retval);
}
/** ExtendToQuad - convert a scalar to a quad
* If the input node is of a scalar type, convert it to type T_QUAD,
* for display purposes.
* (This routine replaced "ExtendToLong" in order to support __int64)
*/
void ExtendToQuad (peval_t pv, bool_t fUnsigned)
{
CV_typ_t type = EVAL_TYP(pv);
if (CV_IS_PRIMITIVE (type) &&
CV_TYP_IS_DIRECT (type) &&
!CV_TYP_IS_REAL (type) &&
!CV_TYP_IS_COMPLEX (type)) {
int size = TypeSizePrim (type);
// CUDA #4028 [rm]
// if the incoming type is unsigned, we don't want to sign extend
// all the way to long even if the user asked us to display a signed
// integer. Perserving the unsigned-ness of the base type prevents
// us from display (unsigned char)255,d as -1. We would display
// correctly display 0xffffffff,d as -1 however
fUnsigned |= CV_TYP_IS_UNSIGNED(type);
if (fUnsigned) {
switch (size) {
case 1:
EVAL_QUAD(pv) = EVAL_UCHAR (pv);
break;
case 2:
EVAL_QUAD (pv) = EVAL_USHORT (pv);
break;
case 4:
EVAL_QUAD (pv) = EVAL_ULONG (pv);
break;
}
}
else {
switch (size) {
case 1:
EVAL_QUAD (pv) = EVAL_CHAR (pv);
break;
case 2:
EVAL_QUAD (pv) = EVAL_SHORT (pv);
break;
case 4:
EVAL_QUAD (pv) = EVAL_LONG (pv);
break;
}
}
}
}
/** VerifyFormat -
*/
static char stPrefixQuad[] = "\x003" "I64";
FMT_ret
VerifyFormat (
peval_t pv,
PEEFORMAT pFmtIn,
char * *buf,
int *buflen,
bool_t * pfPtrAndString
)
{
static const double MAXFP = 1e40; //max value printed in %f format
char tempbuf[128]; //large enough to hold a nice big HRESULT string but not bigger than *buflen
char prefix = 0;
char postfix = 0;
char fmtchar = 0;
int nfmtcnt = 0;
ulong size = 0;
char *pf;
char fmtstr[10];
ADDR addr;
ulong cnt;
uint fHexUpper;
CV_typ_t PtrToCharType = pExState->state.f32bit ? T_32PCHAR : T_PFCHAR;
bool_t fUnicode = FALSE;
DASSERT (*buflen >= sizeof(tempbuf));
if (EVAL_TYP (pv) == T_VOID) {
// if the value is void, ignore all formatting
_tcscpy (*buf, "<void>");
*buflen -= 6;
*buf += 6;
return (FMT_ok);
}
if (pFmtIn) {
pf = pFmtIn;
} else {
pf = &pExStr[pExState->strIndex];
}
if (*pf == ',') {
pf++;
}
while ((*pf != 0) && ((*pf == ' ') || (*pf == '\t'))) {
pf++;
}
//BUGBUG: is this really 68k specific -- if so delete it.
#if defined(TARGMAC68K)
if ((pFmtIn != NULL) && (*pf == 'p') && (EVAL_IS_ADDR(pv))) {
if (ADDR_IS_LI (EVAL_PTR(pv))) {
SHFixupAddr (&(EVAL_PTR(pv)));
}
}
#endif
if (*pf != '\0') {
// use the format from the command
*pfPtrAndString = FALSE;
}
else if ((pFmtIn != NULL) && (*pf == 'p')) {
// do not add string to pointer display
*pfPtrAndString = FALSE;
return (FMT_none);
}
else {
// add string to pointer display
*pfPtrAndString = TRUE;
return (FMT_none);
}
size = (ulong )TypeSize (pv);
if (*pf != 0) {
// extract the prefix character if it exists
switch (*pf) {
case 'h':
case 'l':
case 'L':
prefix = *pf++;
break;
case 'I':
if (!_tcsncmp(pf, &stPrefixQuad[1], stPrefixQuad[0])) {
prefix = *pf;
pf += stPrefixQuad[0];
}
break;
}
// extract the format character
switch (*pf) {
case 'd':
case 'i':
case 'u':
case 'o':
if (prefix == 0) {
prefix = 'I';
}
fmtchar = *pf++;
break;
case 'f':
case 'e':
case 'E':
case 'g':
case 'G':
if (prefix == 'h') {
return (FMT_error);
}
// force suitable prefix according to the type of data
switch (EVAL_TYP (pv)) {
case T_REAL32:
prefix = 0;
break;
case T_REAL64:
prefix = 'l';
break;
case T_REAL80:
prefix = 'L';
break;
default:
return (FMT_error);
}
fmtchar = *pf++;
break;
case 'c':
if (prefix != 0) {
return (FMT_error);
}
fmtchar = *pf++;
break;
case 'm':
if (prefix != 0) {
return (FMT_error);
}
fmtchar = *pf++;
if (*pf == 0) {
// assume byte display
postfix = (char) 'b';
}
else {
switch (postfix = *pf++) {
case 'b':
case 'w':
case 'd':
case 'a':
case 'u':
case 'q':
break;
default:
if (_istspace((_TUCHAR)postfix))
break;
else
return (FMT_error);
}
}
break;
case 's':
if (prefix != 0 && prefix != 'l' && prefix != 'L') {
return (FMT_error);
}
fmtchar = *pf++;
if (prefix == 'l' || prefix =='L') {
fUnicode = TRUE;
} else
if (*pf == 'u') {
fUnicode = TRUE;
pf ++;
} else
if (*pf == 't') {
fUnicode = GetUnicodeStrings();
pf ++;
} else
if (T_USHORT == (EVAL_TYP(pv) & (CV_TMASK | CV_SMASK) ) ) {
// If we are pointing to an unisgned short
// this is a unicode string.
fUnicode = TRUE;
}
break;
case 'x':
case 'X':
if (prefix == 0) {
prefix = 'I';
// two hex digits for each byte of the value; since we're
// formatting with %lx, there's no point in having a size
// greater than 4
// __int64 support: we're now formatting with %I64x
// and the max size can be 8 bytes
nfmtcnt = min(size,8) * 2;
}
if (nfmtcnt == 0) {
if (prefix == 'h')
nfmtcnt = 4;
else if (prefix == 'I')
nfmtcnt = 16;
else
nfmtcnt = 8;
}
fmtchar = *pf++;
fHexUpper = (fmtchar == 'X');
break;
case 'r':
if (prefix != 'h') {
return FMT_error;
}
fmtchar = *pf++;
break;
case 'p':
fmtchar = *pf++;
break;
default:
return (FMT_error);
}
while (_istspace((_TUCHAR)*pf))
pf++;
if (*pf != 0) {
return (FMT_error);
}
if (EVAL_IS_ENUM (pv)) {
SetNodeType (pv, ENUM_UTYPE (pv));
}
pf = fmtstr;
*pf++ = '%';
if (nfmtcnt != 0) {
pf += sprintf (pf, "%d", nfmtcnt);
}
if (prefix == 'I') {
_tcsncpy (pf, &stPrefixQuad[1], stPrefixQuad[0]);
pf += stPrefixQuad[0];
}
else if (prefix != 0) {
*pf++ = prefix;
}
*pf++ = fmtchar;
*pf = 0;
switch (fmtchar) {
case 'd':
case 'i':
case 'u':
ExtendToQuad (pv, (fmtchar == 'u'));
cnt = sprintf (tempbuf, fmtstr, EVAL_QUAD (pv));
break;
case 'o':
ExtendToQuad (pv, TRUE);
pf = fmtstr;
*pf++ = '0';
*pf++ = '%';
if (nfmtcnt != 0) {
pf += sprintf (fmtstr, "%d", nfmtcnt);
}
if (prefix == 'I') {
_tcsncpy (pf, &stPrefixQuad[1], stPrefixQuad[0]);
pf += stPrefixQuad[0];
}
else if (prefix != 0) {
*pf++ = prefix;
}
*pf++ = fmtchar;
*pf = 0;
cnt = sprintf (tempbuf, fmtstr, EVAL_QUAD (pv));
break;
case 'f':
// prevent internal buffer overflow
if (prefix == 'l' && EVAL_DOUBLE(pv) > MAXFP ||
prefix == 'L' && !Float10LessThanEqual (EVAL_LDOUBLE(pv), Float10FromDouble (MAXFP))) {
_tcscpy (fmtstr, prefix == 'l' ? "%le" : "%Le");
}
// fall through
case 'e':
case 'E':
case 'g':
case 'G':
if (TargetMachine != mptmppc) {
switch (prefix) {
case 'l':
cnt = sprintf_english (tempbuf, fmtstr, EVAL_DOUBLE(pv));
break;
case 'L':
//BUGBUG: this seems suspect
#if defined(WIN32) && !defined(_MIPS_) && !defined(_ALPHA_) && !defined(_PPC_) && !defined(_IA64_)
#pragma message("WARNING: Only one format for 10-byte reals")
cnt = _tcslen ( SzFromLd ( tempbuf, sizeof(tempbuf), EVAL_LDOUBLE(pv) ) );
#else
cnt = sprintf_english (tempbuf, fmtstr, EVAL_LDOUBLE(pv));
#endif
break;
default:
cnt = sprintf_english (tempbuf, fmtstr, EVAL_FLOAT(pv));
break;
}
} else {
switch (CV_SUBT (EVAL_TYP (pv))) {
case CV_RC_REAL32:
cnt = sprintf (tempbuf, fmtstr, EVAL_FLOAT (pv));
break;
case CV_RC_REAL64:
cnt = sprintf (tempbuf, fmtstr, EVAL_DOUBLE (pv));
break;
default:
cnt = sprintf (tempbuf, fmtstr, EVAL_LDOUBLE (pv));
break;
}
}
break;
case 'm':
// Need to set Evaluating to 1 to force Normalization
// of based ptrs in CastNode (and reset to 0 immediately
// afterwards)
Evaluating = TRUE;
// CUDA #4044 : make sure we can do the cast... [rm]
if (!CastNode (pv, PtrToCharType, PtrToCharType)) {
Evaluating = FALSE;
return (FMT_error);
}
EvalMem (pv, buf, buflen, postfix);
Evaluating = FALSE;
return (FMT_ok);
case 's':
if (EVAL_IS_ADDR (pv)) {
// Need to set Evaluating to 1 to force Normalization
// of based ptrs in CastNode (and reset to 0 immediately
// afterwards)
Evaluating = TRUE;
// CUDA #4044 : make sure we can do the cast... [rm]
if (!CastNode (pv, PtrToCharType, PtrToCharType)) {
Evaluating = FALSE;
return (FMT_error);
}
EvalString (pv, buf, buflen, fUnicode);
Evaluating = FALSE;
return (FMT_ok);
}
// if not an addr then just fall thru and display as
// individual chars
// sps - 9/14/92
fmtchar = 'c';
case 'c':
pf = fmtstr;
*pf++ = '\'';
if (EVAL_CHAR (pv) != 0) {
// if the value is not zero, then display it.
// otherwise, display '' (CodeView) or '\x00' (IDE)
*pf++ = '%';
*pf++ = fmtchar;
}
else {
pf += sprintf(pf, szNullChar);
}
*pf++ = '\'';
*pf = 0;
cnt = sprintf (tempbuf, fmtstr, EVAL_CHAR (pv));
break;
#ifdef USE_CUSTVIEW
case 'r':
{
DWORD dwValue = EVAL_ULONG(pv);
HRESULT hr = ExportViewHresult( dwValue,
&StaticHelper,
16 /* AMPHACK a lie */,
GetUnicodeStrings(),
tempbuf,
sizeof(tempbuf),
0 );
if (hr!=S_OK) {
sprintf( tempbuf, "0x%08lx", dwValue );
}
cnt = _tcslen( tempbuf );
}
break;
#endif
case 'x':
case 'X':
case 'p':
if (EVAL_IS_PTR (pv)) {
addr = EVAL_PTR (pv);
if (ADDR_IS_LI (addr)) {
SHFixupAddr (&addr);
}
fHexUpper = !!fHexUpper; // canonicalize
#if defined(TARGMAC68K)
if(GetAddrSeg(addr) != 0)
{
cnt = sprintf (tempbuf, fmt_ptr_16_32[fHexUpper],
GetAddrSeg (addr), (CV_uoff32_t)GetAddrOff (addr));
}
else
{
cnt = sprintf (tempbuf, fmt_ptr_0_32[fHexUpper],
(CV_uoff32_t)GetAddrOff (addr));
}
#else // !TARGMAC68K
// [cuda#4793 5/25/93 mikemo] Don't use EVAL_IS_NPTR32
// and EVAL_IS_FPTR32 here, because they fail on arrays
if (EVAL_PTRTYPE (pv) == CV_PTR_NEAR32 ||
EVAL_PTRTYPE (pv) == CV_PTR_FAR32) {
cnt = sprintf (tempbuf, fmt_ptr_0_32[fHexUpper],
(CV_uoff32_t)GetAddrOff (addr));
} else if (EVAL_PTRTYPE (pv) == CV_PTR_64) {
cnt = sprintf (tempbuf, fmt_ptr_64[fHexUpper],
GetAddrOff (addr));
}
else {
// if it is a near ptr we will treat is as a ptr
// since we always carry around the seg & offset
// even if it is near.
cnt = sprintf (tempbuf, fmt_ptr_16_16[fHexUpper],
GetAddrSeg (addr), (CV_uoff16_t)GetAddrOff (addr));
}
#endif // TARGMAC68K
}
else {
ExtendToQuad(pv, TRUE);
pf = fmtstr;
*pf++ = '0';
*pf++ = 'x';
*pf++ = '%';
*pf++ = '.';
if (nfmtcnt != 0) {
pf += sprintf(pf, "%d", nfmtcnt);
}
if (prefix == 'I') {
_tcsncpy (pf, &stPrefixQuad[1], stPrefixQuad[0]);
pf += stPrefixQuad[0];
}
else if (prefix != 0) {
*pf++ = prefix;
}
*pf++ = fmtchar;
*pf = 0;
cnt = sprintf (tempbuf, fmtstr, EVAL_UQUAD (pv));
}
break;
}
_tcsncpy (*buf, tempbuf, cnt + 1);
*buf += cnt;
*buflen -= cnt;
}
return(FMT_ok);
}
/* Format - format data
*/
EESTATUS
Format (
peval_t pv,
uint radix,
char * *buf,
int *plen,
bool_t fPtrAndString
)
{
char tempbuf[FMTSTRMAX];
char *pTempBuf = tempbuf;
uint cnt;
ulong isfloat = FALSE;
HSYM hProc = 0;
// M00FLAT32
SYMPTR pProc;
char *pc = NULL;
ulong cbTempBuf;
ulong *pcbTempBuf = &cbTempBuf;
ulong iRadix;
ADDR addr;
CV_typ_t type;
EEHSTR hStr = 0;
uint fHexUpper = 0;
if (*plen < 5 ) {
return (EENOERROR);
}
fHexUpper = !!fHexUpper; // canonicalize
if (EVAL_IS_BITF (pv)) {
// for a bitfield, change the type to the underlying type
SetNodeType (pv, BITF_UTYPE (pv));
}
if (EVAL_IS_CLASS (pv)) {
FormatClass (pv, radix, buf, plen);
return (EENOERROR);
}
else if (EVAL_IS_ENUM (pv)) {
if (EVAL_STATE(pv) == EV_constant) {
SetNodeType(pv, ENUM_UTYPE(pv));
}
else {
return (FormatEnum(pv, *buf, *plen));
}
}
if (CV_IS_PRIMITIVE (EVAL_TYP (pv)) && !EVAL_IS_PTR (pv)) {
if (EVAL_TYP (pv) == T_VOID) {
_tcscpy (tempbuf, "<void>");
}
else {
// establish format string index
switch (radix) {
case 8:
iRadix = 0;
break;
case 10:
iRadix = 1;
break;
default:
DASSERT (FALSE);
// note fall through
case 16:
if (fHexUpper) {
iRadix = 3;
}
else {
iRadix = 2;
}
break;
}
switch (EVAL_TYP (pv)) {
case T_CHAR:
case T_RCHAR:
case T_INT1:
if (fPtrAndString) {
if (EVAL_CHAR (pv) != 0) {
sprintf (tempbuf, fmt_char_nz[iRadix],
(radix==10) ? EVAL_CHAR (pv) : EVAL_UCHAR (pv),
EVAL_CHAR (pv));
}
else {
// don't stick a 0 in the string
sprintf (tempbuf, fmt_char_zr[iRadix],
EVAL_CHAR (pv), EVAL_CHAR (pv));
}
}
else {
sprintf (tempbuf, fmt_char[iRadix],
(radix==10) ? EVAL_CHAR (pv) : EVAL_UCHAR (pv));
}
break;
case T_UCHAR:
case T_UINT1:
if (fPtrAndString) {
if (EVAL_UCHAR (pv) != 0) {
sprintf (tempbuf, fmt_char_nz[iRadix],
EVAL_UCHAR (pv), EVAL_UCHAR (pv));
}
else {
// don't stick a 0 in the string
sprintf (tempbuf, fmt_char_zr[iRadix],
EVAL_UCHAR (pv), EVAL_UCHAR (pv));
}
}
else {
sprintf (tempbuf, fmt_char[iRadix], EVAL_UCHAR (pv));
}
break;
case T_SHORT:
case T_INT2:
sprintf (tempbuf, fmt_short[iRadix], EVAL_SHORT (pv));
break;
case T_SEGMENT:
case T_USHORT:
case T_UINT2:
sprintf (tempbuf, fmt_ushort[iRadix], EVAL_USHORT (pv));
break;
case T_LONG:
case T_INT4:
sprintf (tempbuf, fmt_long[iRadix], EVAL_LONG (pv));
break;
case T_ULONG:
case T_UINT4:
sprintf (tempbuf, fmt_ulong[iRadix], EVAL_ULONG (pv));
break;
case T_QUAD:
case T_INT8:
sprintf (tempbuf, fmt_quad[iRadix], EVAL_QUAD (pv));
break;
case T_UQUAD:
case T_UINT8:
sprintf (tempbuf, fmt_uquad[iRadix], EVAL_UQUAD (pv));
break;
case T_REAL32:
sprintf_english (tempbuf, "%#g", EVAL_FLOAT (pv));
isfloat = TRUE;
break;
case T_REAL64:
sprintf_english (tempbuf, "%#.14g", EVAL_DOUBLE (pv));
isfloat = TRUE;
break;
case T_REAL80:
#if defined(WIN32) && !defined(_MIPS_) && !defined(_ALPHA_) && !defined(_IA64_)
#pragma message("WARNING: Only one format for 10-byte reals.")
SzFromLd ( tempbuf, sizeof(tempbuf), EVAL_LDOUBLE ( pv ) );
#else
sprintf_english (tempbuf, "%#.20Lg", EVAL_LDOUBLE (pv));
#endif
isfloat = TRUE;
break;
case T_NOTYPE:
default:
if ( ADDR_IS_OFF32(pv->addr) ) {
sprintf (tempbuf, fmt_ulong[iRadix], EVAL_ULONG (pv) );
}
else {
sprintf (tempbuf, fmt_ushort[iRadix], EVAL_USHORT (pv));
}
break;
}
}
}
else if (EVAL_IS_ADDR (pv)) {
addr = EVAL_PTR (pv);
if (EVAL_IS_BASED (pv)) {
#if defined(TARGMAC68K)
cbTempBuf = sprintf (tempbuf, fmt_ptr_0_32[fHexUpper],
(ulong)EVAL_PTR_OFF (pv));
#else
if (pExState->state.f32bit) {
// a based pointer in a 32bit context is
// treated as a 32bit based pointer -- dolphin #979
cbTempBuf = sprintf (tempbuf, fmt_ptr_0_32[fHexUpper],
(ulong)EVAL_PTR_OFF (pv));
}
else
cbTempBuf = sprintf (tempbuf, fmt_ptr_0_16[fHexUpper],
(ushort)EVAL_PTR_OFF (pv));
#endif
}
#if defined(TARGMAC68K)
else {
if (ADDR_IS_LI (addr)) {
SHFixupAddr (&addr);
}
if(GetAddrSeg(addr) != 0) {
cbTempBuf = sprintf (tempbuf,
fmt_ptr_16_32[fHexUpper],
GetAddrSeg (addr), (CV_uoff32_t)GetAddrOff (addr));
}
else {
cbTempBuf = sprintf (tempbuf,
fmt_ptr_0_32[fHexUpper],
(CV_uoff32_t)GetAddrOff (addr));
}
}
#else // !TARGMAC68K
else if (EVAL_IS_PTR (pv) && EVAL_IS_REG (pv)) {
if (EVAL_IS_NPTR (pv)) {
cbTempBuf = sprintf (tempbuf, fmt_ptr_16_16[fHexUpper],
GetSegmentRegister(pExState->hframe, REG_DS), (CV_uoff16_t)EVAL_PTR_OFF (pv));
}
else if (EVAL_IS_NPTR32 (pv)) {
cbTempBuf = sprintf (tempbuf, fmt_ptr_0_32[fHexUpper],
(CV_uoff32_t)EVAL_PTR_OFF (pv));
}
else {
if (ADDR_IS_LI (addr)) {
SHFixupAddr (&addr);
}
if (EVAL_IS_FPTR32 (pv)) {
cbTempBuf = sprintf (tempbuf, fmt_ptr_0_32[fHexUpper],
(CV_uoff32_t)GetAddrOff (addr));
}
else {
cbTempBuf = sprintf (tempbuf, fmt_ptr_16_16[fHexUpper],
GetAddrSeg (addr), (CV_uoff16_t)GetAddrOff (addr));
}
}
}
else if (EVAL_IS_PTR (pv) && EVAL_IS_NPTR (pv)) {
// if it is a near ptr we will treat is as a far ptr
// since we always carry around the seg & offset
// even if it is near.
// DASSERT( EVAL_PTR_SEG (pv) != 0);
if (ADDR_IS_LI (addr)) {
SHFixupAddr (&addr);
}
cbTempBuf = sprintf (tempbuf, fmt_ptr_16_16[fHexUpper],
GetAddrSeg (addr), (CV_uoff16_t)GetAddrOff (addr));
}
else if (EVAL_IS_PTR (pv) && EVAL_IS_NPTR32 (pv)) {
// if it is a near ptr we will treat is as a far ptr
// since we always carry around the seg & offset
// even if it is near.
// DASSERT( EVAL_PTR_SEG (pv) != 0);
if (ADDR_IS_LI (addr)) {
SHFixupAddr (&addr);
}
cbTempBuf = sprintf (tempbuf, fmt_ptr_0_32[fHexUpper],
(CV_uoff32_t)GetAddrOff (addr));
}
else {
if (ADDR_IS_LI (addr)) {
SHFixupAddr (&addr);
}
if (EVAL_IS_FPTR32 (pv)) {
cbTempBuf = sprintf (tempbuf, fmt_ptr_0_32[fHexUpper],
(CV_uoff32_t)GetAddrOff (addr));
} else if (EVAL_IS_PTR64 (pv)) {
cbTempBuf = sprintf (tempbuf, fmt_ptr_64[fHexUpper],
/*v-vadimp (CV_uoff64_t)*/GetAddrOff (addr));
}
else {
if ( ADDR_IS_FLAT ( addr ) ) {
DASSERT ( ADDR_IS_OFF32 ( addr) );
cbTempBuf = sprintf (
tempbuf,
(TargetMachine == mptia64)? fmt_ptr_64[fHexUpper] : fmt_ptr_0_32[fHexUpper],
GetAddrOff ( addr )
);
}
else {
if ( ADDR_IS_OFF32 ( addr ) ) {
cbTempBuf = sprintf (
tempbuf,
fmt_ptr_16_32[fHexUpper],
GetAddrSeg (addr),
(CV_uoff32_t) GetAddrOff (addr)
);
}
else {
cbTempBuf = sprintf (
tempbuf,
fmt_ptr_16_16[fHexUpper],
GetAddrSeg (addr),
(CV_uoff16_t) GetAddrOff (addr)
);
}
}
}
}
#endif // TARGMAC68K
if (!EVAL_IS_DPTR (pv)) {
CXT cxt;
eval_t nv = *pv;
memset(&cxt, 0, sizeof(CXT));
addr = EVAL_PTR (pv);
if (!ADDR_IS_LI (addr)) {
SHUnFixupAddr (&addr);
}
SHSetCxtMod ( &addr, &cxt );
nv.CXTT = cxt;
if (SHGetNearestHsym (&addr, SHHMODFrompCXT (&cxt), EECODE, &hProc) == 0) {
// the address exactly matches a symbol
switch ((pProc = (SYMPTR)MHOmfLock ((HSYM)hProc))->rectyp) {
case S_LPROC16:
case S_GPROC16:
EVAL_MOD(&nv) = SHHMODFrompCXT (&cxt);
SetNodeType(&nv, (CV_typ_t)((PROCPTR16)pProc)->typind);
pc = FormatVirtual ((char *) ((PROCPTR16)pProc)->name, &nv, &hStr);
break;
case S_THUNK16:
pc = (char *) ((THUNKPTR16)pProc)->name;
break;
case S_LPROC32:
case S_GPROC32:
EVAL_MOD(&nv) = SHHMODFrompCXT (&cxt);
SetNodeType(&nv, (CV_typ_t)((PROCPTR32)pProc)->typind);
pc = FormatVirtual ((char *) ((PROCPTR32)pProc)->name, &nv, &hStr);
break;
case S_LPROCMIPS:
case S_GPROCMIPS:
EVAL_MOD(&nv) = SHHMODFrompCXT (&cxt);
SetNodeType(&nv, (CV_typ_t)((PROCPTRMIPS)pProc)->typind);
pc = FormatVirtual ((char *) ((PROCPTRMIPS)pProc)->name, &nv, &hStr);
break;
case S_LPROCIA64:
case S_GPROCIA64:
EVAL_MOD(&nv) = SHHMODFrompCXT (&cxt);
SetNodeType(&nv, (CV_typ_t)((PROCPTRIA64)pProc)->typind);
pc = FormatVirtual ((char *) ((PROCPTRIA64)pProc)->name, &nv, &hStr);
break;
case S_THUNK32:
pc = (char *) ((THUNKPTR32)pProc)->name;
break;
case S_PUB32:
{
char undname[256];
pc = FormatUndecorate( (char*) ((DATASYM32*)pProc)->name, undname );
}
break;
}
MHOmfUnLock ((HSYM)hProc);
}
}
// M00KLUDGE - display strings of chars
if ((fPtrAndString) && (EVAL_IS_PTR (pv))) {
type = EVAL_TYP (pv);
if (EVAL_IS_BASED (pv) || !CV_IS_PRIMITIVE(type)) {
type = PTR_UTYPE (pv);
}
else {
type &= (CV_TMASK | CV_SMASK);
}
if ((type == T_CHAR) || (type == T_UCHAR) || (type == T_RCHAR) || (type == T_WCHAR)
|| (GetUnicodeStrings () && (type == T_USHORT))
) {
CV_typ_t PtrToCharType;
BOOL fUnicode = FALSE;
if ((type == T_USHORT) || (type == T_WCHAR))
{
PtrToCharType = pExState->state.f32bit? ((TargetMachine == mptia64)? T_64PUSHORT : T_32PUSHORT) : T_PFUSHORT;
fUnicode = TRUE;
}
else
{
PtrToCharType = pExState->state.f32bit ? ((TargetMachine == mptia64)? T_64PCHAR : T_32PCHAR) : T_PFCHAR;
}
tempbuf[cbTempBuf] = ' ';
// Need to set Evaluating to 1 to force Normalization
// of based ptrs in CastNode (and reset to 0 immediately
// afterwards)
Evaluating = TRUE;
// CUDA #4044 : make sure we can do the cast... [rm]
if (!CastNode (pv, PtrToCharType, PtrToCharType)) {
Evaluating = FALSE;
return (EEGENERAL);
}
Evaluating = FALSE;
pTempBuf += cbTempBuf + 1;
*pcbTempBuf = FMTSTRMAX - cbTempBuf - 1;
EvalString (pv, &pTempBuf, (int *) pcbTempBuf, fUnicode);
}
}
}
else {
pExState->err_num = ERR_UNKNOWNTYPE;
return (EEGENERAL);
}
cnt = _tcslen (tempbuf);
cnt = min ((uint)*plen, cnt);
_tcsncpy (*buf, tempbuf, cnt);
*plen -= cnt;
*buf += cnt;
if (pc != NULL) {
cnt = min ((uint)*plen, ((uint)*pc) + 1);
**buf = ' ';
(*buf)++;
_tcsncpy (*buf, pc + 1, cnt - 1);
*plen -= cnt;
*buf += cnt;
}
if (hStr != 0) {
MemUnLock (hStr);
MHMemFree (hStr);
}
return (EENOERROR);
}
static char *szClassDisp = "{...}";
void FormatClass (peval_t pv, uint radix, char * *buf,
int *buflen)
{
int len;
Unreferenced( radix );
Unreferenced( pv );
if (pExState->hAutoExpandRule) {
FormatAutoExpand (pv, radix, buf, buflen);
}
else {
len = _tcslen (szClassDisp);
len = min (*buflen, len);
_tcsncpy (*buf, szClassDisp, len);
*buflen -= len;
*buf += len;
}
}
#ifdef USE_CUSTVIEW
BOOL WINAPI StaticHelperReadMem ( DEBUGHELPER *pThis, DWORD dwAddr, DWORD nWant, VOID* pWhere, DWORD *nGot )
{
ADDR addr;
UINT count;
if (pThis!=&StaticHelper)
{
// check correct 'this' usage
DASSERT( !"Bad this pointer to HelperReadMem" );
return E_INVALIDARG;
}
AddrInit( &addr, 0, 0, dwAddr, TRUE, TRUE, FALSE, FALSE );
count = GetDebuggeeBytes (addr, nWant, pWhere, T_RCHAR);
*nGot = count;
if (count==0) {
return E_FAIL;
} else if (count!=nWant) {
return S_FALSE;
} else {
return S_OK;
}
DEBUGHELPER StaticHelper =
{
0x10000,
StaticHelperReadMem
};
#endif
/*
* FormatAutoExpand
* Format the auto-expanding part of a pointer or class
*/
void
FormatAutoExpand (
peval_t pv,
uint radix,
char * *buf,
int *buflen
)
{
uint cHTM = 0;
int len;
LSZ lsz;
char *pcLDelim;
char *pcRDelim;
#ifdef USE_CUSTVIEW
CUSTOMVIEWER pViewer = NULL;
#endif
if (pExState->hAutoExpandRule) {
if (EVAL_IS_PTR (pv) && *buflen > 1) {
// we're right after the ptr value string
// so leave an extra space
* ((*buf)++) = ' ';
**buf = '\0';
*buflen -= 1;
}
if (*buflen > 1) {
* ((*buf)++) = '{';
**buf = '\0';
*buflen -= 1;
}
lsz = (LSZ) MemLock (pExState->hAutoExpandRule);
#ifdef USE_CUSTVIEW
if (_tcsncmp(lsz,"$$ADDON(",8)==0)
{
CUSTOMVIEWER pViewer = NULL;
HRESULT hr;
char arg[256];
char *p = _tcschr( lsz+8, ')' );
if (p)
{
memcpy( arg, lsz+8, p-(lsz+8) );
arg[ p-(lsz+8) ] = 0;
// one day look up these names in the registry, but
// hard-coded for now
if (_tcscmp( arg, "GUID" )==0)
pViewer = ExportViewGuid;
else if (_tcscmp( arg, "HWND" )==0)
pViewer = ExportViewHwnd;
else if (_tcscmp( arg, "VARIANT" )==0)
pViewer = ExportViewVariant;
if (pViewer)
{
// call the external DLL to expand the item
ADDR addr;
GetRawAddr( pv, &addr );
**buf = 0;
hr = pViewer( GetAddrOff( addr ), &StaticHelper, radix, GetUnicodeStrings(), *buf, *buflen, 0 );
if (hr==S_OK)
{
short len = (short)_tcslen(*buf);
*buflen -= len;
*buf += len;
}
}
}
if ( (pViewer==NULL) || (hr!=S_OK) )
FormatAEError( pv, radix, buf, buflen );
// skip to end of AE string
lsz += _tcslen( lsz );
}
else
#endif
while ( (pcLDelim = _tcschr (lsz, _T ('<'))) != NULL &&
(pcRDelim = _tcschr (pcLDelim, _T('>'))) != NULL ) {
// If the '>' we found is actually a '->' skip over this
// and look for the next one.
while (pcRDelim && *(pcRDelim - 1) == '-' )
{
pcRDelim = _tcschr(pcRDelim + 1, _T('>'));
}
if (pcRDelim == NULL)
{
break;
}
// copy string that precedes '<'
len = (int) min (*buflen, pcLDelim - lsz);
_tcsncpy (*buf, lsz, len);
*buflen -= len;
*buf += len;
lsz = pcLDelim + 1;
*pcRDelim = 0;
switch (AEParseRule(lsz)) {
case AE_downcasttype:
// print downcast class name (if any)
FormatAEDownCastType (pv, radix, buf, buflen);
break;
case AE_childTM:
// display value of auto-expand child TM
FormatAEChildTM (cHTM++, pv, radix, buf, buflen);
break;
default:
FormatAEError (pv, radix, buf, buflen);
}
*pcRDelim = _T('>');
lsz = pcRDelim + 1;
}
MemUnLock (pExState->hAutoExpandRule);
// copy remainder of format string
len = _tcslen (lsz);
len = min (*buflen, len);
_tcsncpy (*buf, lsz, len);
*buflen -= len;
*buf += len;
if (*buflen > 1) {
* ((*buf)++) = '}';
**buf = '\0';
*buflen -= 1;
}
}
}
/*
* FormatAEChildTM
* Format an auto-expanding child TM
*/
void FormatAEChildTM (uint cHTM, peval_t pv, uint radix, char * *buf,
int *buflen)
{
pexstate_t pExStateSav = pExState;
EEHSTR hszValue;
LSZ szValue;
PTML pTML;
HTM * rgHTM;
int len;
bool_t fRebind = pExState->state.fAErebind;
bool_t fReeval = pExState->state.fAEreeval;
bool_t fFormatOK = FALSE;
FMT_state fmtstate;
EESTATUS error;
pTML = &pExState->TMLAutoExpand;
// Find the appropriate TM in the TMLAutoExpand list
// and display its value.
if (cHTM < pTML->cTMListAct) {
DASSERT (pTML->hTMList);
rgHTM = (HTM *)MemLock (pTML->hTMList);
if (rgHTM && rgHTM [cHTM] != NULL) {
SaveFmtState (&fmtstate);
error = FormatNode (&rgHTM[cHTM], radix, NULL, &hszValue, FALSE);
RestoreFmtState (&fmtstate);
if (EENOERROR == error) {
fFormatOK = TRUE;
szValue = (LSZ) MemLock (hszValue);
len = _tcslen (szValue);
len = min (*buflen, len);
_tcsncpy (*buf, szValue, len);
MemUnLock (hszValue);
MemFree (hszValue);
*buflen -= len;
*buf += len;
}
}
MemUnLock (pTML->hTMList);
}
pExState = pExStateSav;
if (!fFormatOK) {
FormatAEError (pv, radix, buf, buflen);
}
}
/*
* FormatAEError
* Display Error message while auto-expanding an expression
*/
static char *szErrDisp = "???";
void FormatAEError (peval_t pv, uint radix, char * *buf,
int *buflen)
{
int len;
Unreferenced( radix );
Unreferenced( pv );
len = _tcslen (szErrDisp);
len = min (*buflen, len);
_tcsncpy (*buf, szErrDisp, len);
*buflen -= len;
*buf += len;
}
/*
* FormatAEDownCastType
* Format derived-most class type name
*/
void
FormatAEDownCastType (
peval_t pv,
uint radix,
char * *buf,
int *buflen
)
{
LSZ lsz;
char *pch;
int len;
if (pExState->hDClassName)
lsz = (LSZ) MemLock (pExState->hDClassName);
else {
CV_typ_t type = EVAL_TYP (pv);
if (EVAL_IS_PTR (pv)) {
type = PTR_UTYPE (pv);
}
lsz = GetTypeName (type, EVAL_MOD (pv));
}
DASSERT (lsz);
// hDClassName may contain a context operator
// We skip this operator in order to display the class name only
if ((pch = _tcschr (lsz, '}')) != NULL )
lsz = pch + 1;
len = _tcslen (lsz);
len = min (*buflen, len);
_tcsncpy (*buf, lsz, len);
*buflen -= len;
*buf += len;
if (pExState->hDClassName)
MemUnLock (pExState->hDClassName);
}
EESTATUS
FormatEnum (
peval_t pv,
char *buf,
int buflen
)
{
HTYPE hType, hFieldType;
plfEnum pEnumType;
plfFieldList pFieldType;
char * pEnumerate;
uint i, skip;
EESTATUS retval = EENOERROR;
if ((hType = THGetTypeFromIndex (EVAL_MOD (pv), EVAL_TYP (pv))) == 0) {
goto NoDisplay;
}
pEnumType = (plfEnum)(&((TYPPTR)(MHOmfLock (hType)))->leaf);
DASSERT(pEnumType->leaf == LF_ENUM);
if ((hFieldType = THGetTypeFromIndex (EVAL_MOD (pv), pEnumType->field)) == 0) {
goto NoDisplay;
}
pFieldType = (plfFieldList)(&((TYPPTR)(MHOmfLock (hFieldType)))->leaf);
for (i = 0, pEnumerate = (char *)pFieldType + offsetof(lfFieldList, data);
i < pEnumType->count;
i++, pEnumerate += skip)
{
DASSERT(*((unsigned short *)pEnumerate) == LF_ENUMERATE);
skip = offsetof (lfEnumerate, value);
if (EVAL_UQUAD(pv) == RNumLeaf ((char *)(&(((plfEnumerate)pEnumerate)->value)), &skip)) {
_tcsncpy(buf, pEnumerate + skip + 1, min(buflen, *(pEnumerate + skip)));
goto Exit;
}
skip += *(pEnumerate + skip) + 1; //skip name field
skip += SkipPad((uchar *)pEnumerate + skip);
}
NoDisplay:
retval = EEGENERAL;
pExState->err_num = ERR_INVENUMVAL;
Exit:
MHOmfUnLock (hType);
MHOmfUnLock (hFieldType);
return(retval);
}
BOOL GetRawAddr( peval_t pv, ADDR *paddr )
{
if (EVAL_IS_ADDR(pv))
{
BOOL bCast;
Evaluating = TRUE;
bCast = CastNode (pv, T_32PCHAR, T_32PCHAR);
Evaluating = FALSE;
if (!bCast) {
return FALSE;
}
*paddr = EVAL_PTR(pv);
}
else if (EVAL_IS_PTR(pv)) {
*paddr = EVAL_PTR(pv);
}
else
{
ResolveAddr(pv);
*paddr = EVAL_SYM(pv);
}
if (ADDR_IS_LI (*paddr)) {
SHFixupAddr (paddr);
}
if (EVAL_IS_PTR (pv) && (EVAL_IS_NPTR (pv) || EVAL_IS_NPTR32 (pv))) {
paddr->addr.seg = GetSegmentRegister(pExState->hframe, REG_DS);
}
return TRUE;
}
/*
* EvalString
* Evaluate an expression whose format string contains an 's'.
*/
void EvalString (peval_t pv, char *FAR *buf,
int *buflen, bool_t fUnicode)
{
ADDR addr;
int count;
if(*buflen < 3) return;
**buf = '\"';
(*buf)++;
(*buflen)--;
addr = EVAL_PTR (pv);
if (ADDR_IS_LI (addr)) {
SHFixupAddr (&addr);
}
if (EVAL_IS_PTR (pv) && (EVAL_IS_NPTR (pv) || EVAL_IS_NPTR32 (pv))) {
addr.addr.seg = GetSegmentRegister(pExState->hframe, REG_DS);
}
count = GetDebuggeeBytes (addr, *buflen - 2, *buf, T_RCHAR);
if (fUnicode) {
// Convert unicode characters to MBCS, so that
// we can display them using the existing non-Unicode
// formatting routines
int cb;
wchar_t UNALIGNED *pwch = (wchar_t UNALIGNED *)*buf;
while (count >= sizeof (wchar_t) && *pwch != 0 ) {
cb = ConvertWCToMB (*buf, *pwch);
(*buflen) -= cb;
*buf += cb;
pwch ++;
count -= sizeof (wchar_t);
}
}
else {
while ((**buf != 0) && (count > 0)) {
int clen = _tclen (*buf);
(*buflen) -= clen;
*buf = _tcsinc (*buf);
count -= clen;
}
}
**buf = '\"';
(*buf)++;
(*buflen)--;
**buf = 0;
(*buf)++;
(*buflen)--;
}
/*
* Use IsPrint instead of the runtime function isprint,
* since the latter is not exported to the EE
*/
INLINE bool_t IsPrint (int ch)
{
return (ch >= 0x20) && (ch <= 0x7e) ? TRUE : FALSE;
}
/*
* EvalMem
* Evaluate an expression whose format string contains an 'm'.
* The format is similar to the memory window of codeview :
* ,m or ,mb (memory -byte display)
* SSSS:OOOO xx xx xx xx ... xx aaaa...a
* ,mw (memory -word display)
* SSSS:OOOO xxxx ... xxxx
* ,md (memory -dword display)
* SSSS:OOOO xxxxxxxx ... xxxxxxxx
* ,mq (memory -qword display)
* SSSS:OOOO xxxxxxxxxxxxxxxx ... xxxxxxxxxxxxxxxx
* ,ma (memory -ascii display)
* SSSS:OOOO aaa...a
* where SSSS:OOOO is the address, xx is dump info in hex,
* and a is an ascii char. (If the address is a 32-bit
* address, we will emit "OOOOOOOO" instead of "SSSS:OOOO".)
*/
#define MCOUNT 16 /* number of bytes to read */
#define MCOUNTA 64 /* number of bytes to read for ,ma display */
#define MINLBUFSZ 64 /* minimum local buf size for byte transfer */
#define MINBUFSZ 256 /* minimum buf size for display */
void EvalMem (peval_t pv, char *FAR *buf, int *buflen, char postfix)
{
ADDR addr;
int count;
char tempbuf[MINBUFSZ];
uchar localbuf[MINLBUFSZ];
int cnt = 0;
int nItems;
int nBytes;
int i;
char *pFmt;
uint fHexUpper = 0;
bool_t fDisplayString = FALSE;
fHexUpper = !!fHexUpper; // canonicalize
addr = EVAL_PTR (pv);
if (ADDR_IS_LI (addr)) {
SHFixupAddr (&addr);
}
if (EVAL_IS_PTR (pv) && (EVAL_IS_NPTR (pv) || EVAL_IS_NPTR32 (pv))) {
addr.addr.seg = GetSegmentRegister(pExState->hframe, REG_DS);
}
if (ADDR_IS_FLAT(addr)) {
DASSERT ( ADDR_IS_OFF32 ( addr ) );
cnt = sprintf(tempbuf, fmt_ptr_0_32[fHexUpper],
(CV_uoff32_t)GetAddrOff (addr));
}
else {
if ( ADDR_IS_OFF32 ( addr ) ) {
cnt = sprintf(tempbuf, fmt_ptr_16_32[fHexUpper],
GetAddrSeg (addr), (CV_uoff32_t)GetAddrOff (addr));
}
else {
cnt = sprintf(tempbuf, fmt_ptr_16_16[fHexUpper],
GetAddrSeg (addr), (CV_uoff16_t)GetAddrOff (addr));
}
}
tempbuf[cnt++] = ' ';
tempbuf[cnt++] = ' ';
nBytes = (postfix == 'a' ? MCOUNTA : MCOUNT);
count = GetDebuggeeBytes (addr, nBytes, (char *)localbuf, T_RCHAR);
nItems = nBytes; //assume ,m ,mb or ,ma display
switch (postfix) {
case 'b':
if (fHexUpper) {
pFmt = "%02X ";
}
else {
pFmt = "%02x ";
}
for (i=0; i<nItems; i++) {
cnt += i<count
? sprintf (tempbuf+cnt, pFmt, (unsigned int)localbuf[i])
: sprintf (tempbuf+cnt, "?? ");
}
tempbuf[cnt++] = ' ';
// fall through
case 'a':
fDisplayString = TRUE;
break;
case 'w':
case 'u':
nItems = nBytes >> 1;
count >>= 1;
if (fHexUpper) {
pFmt = "%04hX ";
}
else {
pFmt = "%04hx ";
}
for (i=0; i<nItems; i++) {
cnt += i<count
? sprintf (tempbuf+cnt, pFmt, *((unsigned short UNALIGNED *)localbuf+i))
: sprintf (tempbuf+cnt, "???? ");
}
if ('u' == postfix) {
char *pch;
int i;
// Low budget unicode display: convert unicode
// string to MBCS and use existing display code
// In-place conversion should be OK, since the
// translated character is at most two bytes long
tempbuf[cnt++] = ' ';
fDisplayString = TRUE;
pch = (char *) localbuf;
for (i=0; i<nItems; i++) {
pch += ConvertWCToMB (pch, ((wchar_t *)localbuf)[i]);
}
}
break;
case 'd':
nItems = nBytes >> 2;
count >>= 2;
if (fHexUpper) {
pFmt = "%08lX ";
}
else {
pFmt = "%08lx ";
}
for (i=0; i<nItems; i++) {
cnt += i<count
? sprintf (tempbuf+cnt, pFmt, *((unsigned long UNALIGNED *)localbuf+i))
: sprintf (tempbuf+cnt, "???????? ");
}
break;
case 'q':
nItems = nBytes >> 3;
count >>= 3;
if (fHexUpper) {
pFmt = "%016I64X ";
}
else {
pFmt = "%016I64x ";
}
for (i=0; i<nItems; i++) {
cnt += i<count
? sprintf (tempbuf+cnt, pFmt, *((unsigned __int64 UNALIGNED *)localbuf+i))
: sprintf (tempbuf+cnt, "???????? ");
}
break;
}
if (fDisplayString) {
#ifndef _SBCS
for (i=0; i<nItems; i++) {
if( i<count ) {
if ( _ismbblead( localbuf[i] ) ) {
if ( i+1<count && _ismbbtrail( localbuf[ i+1 ] ) ) {
tempbuf[cnt++] = localbuf[ i++ ];
tempbuf[cnt++] = localbuf[ i ];
}
else {
tempbuf[cnt++] = '.';
i++;
}
}
else if ( _ismbbkana( localbuf[ i ] ) ||
IsPrint( localbuf[ i ] ) ) {
tempbuf[cnt++] = localbuf[ i ];
}
else {
tempbuf[cnt++] = '.';
}
}
else {
tempbuf[cnt++] = '?';
}
}
#else
for (i=0; i<nItems; i++) {
if ( i<count ) {
if ( IsPrint(localbuf[i]) ) {
tempbuf[cnt++] = localbuf[i];
}
else {
tempbuf[cnt++] = '.';
}
}
else {
tempbuf[cnt++] = '?';
}
}
#endif
}
// If the size of the buffer is less than the display string,
// clip the formatted memory string but copy what we can
if ( *buflen - 1 < cnt ) {
cnt = *buflen - 1;
}
tempbuf[cnt] = '\0';
_tcsncpy (*buf, tempbuf, cnt + 1);
*buf += cnt;
*buflen -= cnt;
}
/*
* ConvertWCToMB - convert wide char to multi-byte
*/
int ConvertWCToMB (char *pchmb, wchar_t wch)
{
int cb;
if ((cb = wctomb (pchmb, wch)) < 0) {
// no conversion was possible,
// use a default character
*pchmb = '?';
cb = 1;
}
else if (cb == 0) {
// converting L'\0'
*pchmb = '\0';
cb = 1;
}
return cb;
}
// undecorate a symbol, currently only does @ILT symbols (for vtable entries)
// turns @ILT+nnn(?mangledname) into unmangled name
// and simply mangled ones
char *
FormatUndecorate (
char *pc,
char *newstr
)
{
size_t oLen;
char *pOpen;
char *pClose;
char undname[256];
char *pResult;
newstr++; // leave room for length byte
// make null-terminated version in user buffer
oLen = *(uchar*)pc;
memcpy( newstr, pc+1, oLen );
newstr[oLen] = 0;
if (pc[1]=='?')
{
// simple mangled name starts with "?"
pResult = __unDName( undname, newstr, sizeof(undname), malloc, free, UNDNAME_NAME_ONLY );
}
else if ( (pc[0]>5) && (memcmp(pc+1, "@ILT", 4)==0))
{
// "@ILT+nnn(?mangled)"
pOpen = _tcschr(newstr, '(' );
if (!pOpen) {
return pc;
}
pClose = _tcschr(pOpen+1, ')' );
if (!pClose) {
return pc;
}
*pClose = 0;
pResult = __unDName( undname, pOpen+1, sizeof(undname), malloc, free, UNDNAME_NAME_ONLY );
}
else {
return pc;
}
if (!pResult) {
return pc; // if failed return original
}
// undecorated OK, so convert
_tcscpy( newstr, undname );
newstr--;
newstr[0] = (uchar)_tcslen(newstr+1); // set length field
return newstr;
}
char *
FormatVirtual (
char *pc,
peval_t pv,
PEEHSTR phStr
)
{
char save;
char *pEnd;
char *bufsave;
char *buf;
uint buflen;
PHDR_TYPE pHdr;
char *pName;
if ((*phStr = MemAllocate (TYPESTRMAX + sizeof (HDR_TYPE))) == 0) {
// unable to allocate memory for type string. at least print name
return (pc);
}
bufsave = (char *)MemLock (*phStr);
memset (bufsave, 0, TYPESTRMAX + sizeof (HDR_TYPE));
buflen = TYPESTRMAX - 1;
pHdr = (PHDR_TYPE)bufsave;
buf = bufsave + sizeof (HDR_TYPE);
pCxt = &pExState->cxt;
bnCxt = 0;
pEnd = pc + *pc + 1;
save = *pEnd;
*pEnd = 0;
pName = pc + 1;
FormatType (pv, &buf, &buflen, &pName, 1L, pHdr);
*pEnd = save;
*(bufsave + sizeof (HDR_TYPE) - 1) = TYPESTRMAX - 1 - buflen;
return (bufsave + sizeof (HDR_TYPE) - 1);
}
/*** DoAutoExpand - Prepare TM for auto expansion
* void DoAutoExpand (phTM)
* Entry phTM = pointer to handle of parent TM
* Exit Creates auto-expanded TM list and stores it
* in the parent TM.
* Returns void
*/
void FASTCALL DoAutoExpand (PHTM phTM)
{
static char bufRule [256];
static char bufDeriv [256];
eval_t Eval;
peval_t pv = &Eval;
bool_t fNewDownCast = FALSE;
bool_t fNewRule;
bool_t fAErebind;
bool_t fAEreeval;
DASSERT (phTM && *phTM);
pExState = (pexstate_t) MemLock (*phTM);
fAErebind = pExState->state.fAErebind;
fAEreeval = pExState->state.fAEreeval;
if (fAErebind || fAEreeval) {
// Auto-expand rule and down-cast info need to be updated.
// The auto-expand list has not been bound (or evaluated)
// since the last time this TM was bound (or evaluated)
pCxt = &pExState->cxt;
*pv = pExState->result;
// if we don't have a class or a pointer to a class,
// no autoexpansion is performed
if (EVAL_IS_PTR (pv) && !SetNodeType(pv, PTR_UTYPE(pv)) ||
!EVAL_IS_CLASS (pv)) {
EEFreeTML (&pExState->TMLAutoExpand);
MemFree (pExState->hAutoExpandRule);
pExState->hAutoExpandRule = 0;
pExState->state.fAErebind = FALSE;
pExState->state.fAEreeval = FALSE;
MemUnLock (*phTM);
return;
}
// Get the expansion rule associated with the derived-most class, if any
if (EVAL_IS_PTR (&pExState->result) &&
!EVAL_IS_REF (&pExState->result)) {
*bufDeriv = 0;
GetDerivClassName (&pExState->result, TRUE, bufDeriv, sizeof(bufDeriv));
fNewDownCast = UpdateEEHSTR (&pExState->hDClassName, bufDeriv);
if (*bufDeriv) {
FMT_state fmtstate;
uint radix = pExState->radix;
SHFLAG fCase = pExState->state.fCase;
PCXT pBindCxt = &pExState->cxt;
ulong end;
HTM hTMOut;
// bufDeriv contains a derived-most class name prepended
// by a context operator.
// Parse and Bind in order to get the corresponding
// evaluation node
SaveFmtState (&fmtstate);
if (EENOERROR == Parse (bufDeriv, radix, fCase, FALSE, &hTMOut, &end) &&
EENOERROR == DoBind (&hTMOut, pBindCxt, BIND_fSupOvlOps) ) {
pExState = (pexstate_t) MemLock (hTMOut);
*pv = pExState->result;
MemUnLock (hTMOut);
}
if (hTMOut)
EEFreeTM (&hTMOut);
RestoreFmtState (&fmtstate);
}
}
// pv should now contain the class for which we need to find
// an auto expansion rule
*bufRule = 0;
FindAERule (pv, bufRule, sizeof(bufRule));
fNewRule = UpdateEEHSTR (&pExState->hAutoExpandRule, bufRule);
if (fNewDownCast || fNewRule) {
// AutoExpand TMList should be rebound
pExState->state.fAErebind = TRUE;
pExState->state.fAEreeval = TRUE;
}
}
MemUnLock (*phTM);
if (fAErebind) {
// should apply new rule, so we'll have to
// reconstruct and rebind child TMs
DoBindAutoExpand (phTM);
}
if (fAEreeval) {
DoEvalAutoExpand (phTM);
}
pExState = (pexstate_t) MemLock (*phTM);
pExState->state.fAErebind = FALSE;
pExState->state.fAEreeval = FALSE;
MemUnLock (*phTM);
}
/*** SaveFmtState - Save Format state
* Saves global variables used by Format
*/
void FASTCALL SaveFmtState (FMT_state *pfmtstate)
{
pfmtstate->pExState = pExState;
pfmtstate->pExStr = pExStr;
pfmtstate->pCxt = pCxt;
}
/*** RestoreFmtState - Restore Format state
* Restores global variables used by Format
*/
void FASTCALL RestoreFmtState (FMT_state *pfmtstate)
{
pExState = pfmtstate->pExState;
pExStr = pfmtstate->pExStr;
pCxt = pfmtstate->pCxt;
}
/*** DoBindAutoExpand - Construct and bind auto-expanded child-TMs
* error = DoBindAutoExpand (phTM)
* Entry phTM = ptr to handle of parent TM
* Exit Auto-expand TM list created and bound
* Returns void
*/
void FASTCALL DoBindAutoExpand (PHTM phTM)
{
pexstate_t pTM;
LSZ lsz;
char *pcLDelim;
char *pcRDelim;
HTM hTMChild;
pTM = (pexstate_t) MemLock (*phTM);
EEFreeTML (&pTM->TMLAutoExpand);
MemUnLock (*phTM);
if (pTM->hAutoExpandRule) {
lsz = (LSZ) MemLock (pTM->hAutoExpandRule);
while ( (pcLDelim = _tcschr (lsz, _T ('<'))) != NULL &&
(pcRDelim = _tcschr (pcLDelim, _T('>'))) != NULL ) {
// If the '>' we found is actually a '->' skip over this
// and look for the next one.
while (pcRDelim && *(pcRDelim - 1) == '-' )
{
pcRDelim = _tcschr(pcRDelim + 1, _T('>'));
}
if (pcRDelim == NULL)
{
break;
}
hTMChild = 0;
lsz = pcLDelim + 1;
*pcRDelim = '\0';
switch (AEParseRule(lsz)) {
case AE_childTM:
GetDerivedTM (*phTM, lsz, &hTMChild);
pTM = (pexstate_t) MemLock (*phTM);
// hTMchild may be NULL, but we still need to add it to
// the list in order to keep in sync with the "<>" pairs
// in the expansion rule
TMLAddHTM ( &pTM->TMLAutoExpand, hTMChild );
MemUnLock (*phTM);
break;
case AE_downcasttype:
// do nothing, we'll just print the class name
// during formatting
break;
}
*(lsz = pcRDelim) = _T('>');
}
MemUnLock (pTM->hAutoExpandRule);
}
}
/*** DoEvalAutoExpand - Evaluate auto-expanded child TM list
* error = DoEvalAutoExpand (phTM)
* Entry phTM = ptr to handle of parent TM
* Exit Auto-expand TM list is evaluated
* Returns void
*/
void FASTCALL DoEvalAutoExpand (PHTM phTM)
{
HTM *rgHTM;
pexstate_t pTM;
PTML pTML;
uint i;
// try to evaluate auto-expand child TMs
pTM = (pexstate_t) MemLock (*phTM);
pTML = &pTM->TMLAutoExpand;
rgHTM = (HTM *)MemLock (pTML->hTMList);
for (i=0; i<pTML->cTMListAct; i++) {
if (rgHTM[i])
DoEval (&rgHTM[i], pTM->hframe, (EEDSP) pTM->style);
}
MemUnLock (pTML->hTMList);
MemUnLock (*phTM);
}
/*** UpdateEEHSTR - Update EE String
* flag = UpdateEEHSTR(phStr, lszNew)
* Entry phStr = pointer to handle of EE String to be updated
* lszNew = Null-terminated string
* Exit The contents of EE string are replaced with lszNew
* Returns TRUE if the contents of the EE string have changed
* FALSE otherwise
*/
bool_t FASTCALL UpdateEEHSTR(EEHSTR *phStr, LSZ lszNew)
{
EEHSTR hNew;
uint lenNew;
LSZ lsz;
lenNew = _tcslen (lszNew) + 1;
if (*lszNew) {
if (*phStr) {
// new string is non-NULL, old string is non-NULL
lsz = (LSZ) MemLock (*phStr);
if (!_tcscmp(lsz, lszNew)) {
// strings are the same, no update necessary
MemUnLock (*phStr);
return FALSE;
}
else {
MemUnLock (*phStr);
if ((hNew = MemReAlloc (*phStr, lenNew)) == 0) {
return FALSE;
}
}
}
else if ((hNew = MemAllocate (lenNew)) == 0) {
return FALSE;
}
// copy new string over the old string
lsz = (LSZ) MemLock (hNew);
_tcscpy (lsz, lszNew);
MemUnLock (hNew);
*phStr = hNew;
return TRUE;
}
else if (*phStr) {
// new string is NULL, old string is non-NULL
// Free old string
MemFree (*phStr);
*phStr = 0;
return TRUE;
}
// both strings are NULL, no update
return FALSE;
}
/*** FindAERule - Find Auto Expansion rule
* flag = FindAERule (pvP, buf, cchbuf)
* Entry pvP = pointer to the evaluation node containing the
* result of the expression that is auto-expanded
* buf = buffer to hold the auto-expansion rule
* cchbuf = max buffer size
* Exit if an auto-expansion rule is found for pvP it is loaded
* into buf.
* Otherwise the class hierarchy is searched in order to
* locate the nearest base class for which an auto-expansion
* rule exists
* Returns TRUE if an auto-expansion rule was found
* FALSE otherwise
*/
bool_t FASTCALL FindAERule (peval_t pvP, LSZ buf, uint cchbuf)
{
search_t Name;
psearch_t pName = &Name;
eval_t Eval;
peval_t pv = &Eval;
LSZ lsz;
CV_typ_t typ = EVAL_TYP (pvP);
HMOD hMod = EVAL_MOD (pvP);
bool_t retval = FALSE;
HEXE hExe = SHHexeFromHmod(hMod);
if (LookupAECache (typ, SHHexeFromHmod(hMod), buf)) {
return TRUE;
}
// will have to search for the rule based on
// the type name
lsz = GetTypeName (typ, hMod);
if (LoadAERule (lsz, buf, cchbuf)) {
retval = TRUE;
}
else {
BOOL fSupBaseSaved = pExState->state.fSupBase;
pExState->state.fSupBase = FALSE;
InitSearchAErule (pName, pv, EVAL_TYP (pvP), EVAL_MOD (pvP));
if (HR_found == SearchSym (pName)) {
PopStack();
lsz = GetTypeName (EVAL_TYP (pv), EVAL_MOD (pv));
retval = LoadAERule (lsz, buf, cchbuf);
}
pExState->state.fSupBase = fSupBaseSaved;
}
InsertAECache (typ, hExe, buf);
return retval;
}
/*
* Interface for accessing the auto-expansion rule cache
* void InsertAECache (type, hExe, buf)
* inserts the rule containd in buf into the cache and associates
* it with type "type" defined in executable "hExe"
* void ReorderCache (i)
* brings entry i to the top (helper routine for implementing
* LRU scheme)
* flag = LookupAECache (type, hExe, buf)
* looks-up the rule associated with type "type" defined in "hExe"
* and loads it in buffer buf
* It is assumed that buf is sufficiently large to hold the string
*/
void FASTCALL InsertAECache (CV_typ_t type, HEXE hExe, char far *buf)
{
int i;
EEHSTR hStr;
LSZ lsz;
if ((hStr = MemAllocate (_tcslen (buf) + 1)) != NULL) {
lsz = (LSZ) MemLock (hStr);
_tcscpy (lsz, buf);
MemUnLock ((HDEP)lsz);
if (cAECache == AECACHE_MAX) {
if (AECache[AECACHE_MAX - 1].hStr)
MemFree (AECache[AECACHE_MAX - 1].hStr);
cAECache--;
}
for (i = cAECache; i > 0; i--) {
AECache[i] = AECache[i - 1];
}
AECache[0].typ = type;
AECache[0].hExe = hExe;
AECache[0].hStr = hStr;
cAECache++;
}
}
void FASTCALL ReorderAECache (int iAECache)
{
aecache_t temp;
int i;
if (iAECache == 0) {
return;
}
temp = AECache[iAECache];
for (i = iAECache; i > 0; i--) {
AECache[i] = AECache[i - 1];
}
AECache[0] = temp;
}
bool_t FASTCALL LookupAECache (CV_typ_t typ, HEXE hExe, char *buf)
{
int i;
LSZ lsz;
bool_t retval = FALSE;
for (i=0; i<cAECache; i++) {
if (typ == AECache[i].typ && hExe == AECache[i].hExe) {
lsz = (LSZ) MemLock (AECache[i].hStr);
_tcscpy (buf, lsz);
MemUnLock (AECache[i].hStr);
ReorderAECache (i);
retval = TRUE;
break;
}
}
#ifdef DEBUGVER
{
static int hit = 0;
static int miss = 0;
if (retval == TRUE)
hit ++;
else
miss ++;
}
#endif
return retval;
}