| blob | b90a01a458373aa50733150de95ac7f3b5a38cce |
1 /*
2 * KERNEL32 thunks and other undocumented stuff
3 *
4 * Copyright 1997-1998 Marcus Meissner
5 * Copyright 1998 Ulrich Weigand
6 */
27 /***********************************************************************
28 * *
29 * Win95 internal thunks *
30 * *
31 ***********************************************************************/
33 /***********************************************************************
34 * Generates a FT_Prolog call.
35 *
36 * 0FB6D1 movzbl edx,cl
37 * 8B1495xxxxxxxx mov edx,[4*edx + targetTable]
38 * 68xxxxxxxx push FT_Prolog
39 * C3 lret
40 */
42 LPBYTE x;
51 /* fill rest with 0xCC / int 3 */
52 }
54 /***********************************************************************
55 * _write_qtthunk (internal)
56 * Generates a QT_Thunk style call.
57 *
58 * 33C9 xor ecx, ecx
59 * 8A4DFC mov cl , [ebp-04]
60 * 8B148Dxxxxxxxx mov edx, [4*ecx + targetTable]
61 * B8yyyyyyyy mov eax, QT_Thunk
62 * FFE0 jmp eax
63 */
67 ) {
68 LPBYTE x;
78 /* should fill the rest of the 32 bytes with 0xCC */
79 }
81 /***********************************************************************
82 * _loadthunk
83 */
86 {
88 HMODULE32 hmod;
92 {
96 }
100 {
104 }
107 {
113 }
116 {
120 }
123 {
127 }
130 }
132 /***********************************************************************
133 * GetThunkStuff (KERNEL32.53)
134 */
136 {
138 }
140 /***********************************************************************
141 * GetThunkBuff (KERNEL32.52)
142 * Returns a pointer to ThkBuf in the 16bit library SYSTHUNK.DLL.
143 */
145 {
147 }
149 /***********************************************************************
150 * ThunkConnect32 (KERNEL32)
151 * Connects a 32bit and a 16bit thunkbuffer.
152 */
159 DWORD dwReason /* [in] initialisation argument */
160 ) {
161 BOOL32 directionSL;
164 {
169 }
171 {
176 }
177 else
178 {
182 }
185 {
187 {
193 {
199 {
202 }
215 }
216 else
217 {
223 /* write QT_Thunk and FT_Prolog stubs */
226 }
228 }
231 /* FIXME: cleanup */
233 }
236 }
238 /**********************************************************************
239 * QT_Thunk (KERNEL32)
240 *
241 * The target address is in EDX.
242 * The 16 bit arguments start at ESP+4.
243 * The number of 16bit argumentbytes is EBP-ESP-0x44 (68 Byte thunksetup).
244 * [ok]
245 */
247 {
248 CONTEXT context16;
249 DWORD argsize;
267 }
270 /**********************************************************************
271 * FT_Prolog (KERNEL32.233)
272 *
273 * The set of FT_... thunk routines is used instead of QT_Thunk,
274 * if structures have to be converted from 32-bit to 16-bit
275 * (change of member alignment, conversion of members).
276 *
277 * The thunk function (as created by the thunk compiler) calls
278 * FT_Prolog at the beginning, to set up a stack frame and
279 * allocate a 64 byte buffer on the stack.
280 * The input parameters (target address and some flags) are
281 * saved for later use by FT_Thunk.
282 *
283 * Input: EDX 16-bit target address (SEGPTR)
284 * CX bits 0..7 target number (in target table)
285 * bits 8..9 some flags (unclear???)
286 * bits 10..15 number of DWORD arguments
287 *
288 * Output: A new stackframe is created, and a 64 byte buffer
289 * allocated on the stack. The layout of the stack
290 * on return is as follows:
291 *
292 * (ebp+4) return address to caller of thunk function
293 * (ebp) old EBP
294 * (ebp-4) saved EBX register of caller
295 * (ebp-8) saved ESI register of caller
296 * (ebp-12) saved EDI register of caller
297 * (ebp-16) saved ECX register, containing flags
298 * (ebp-20) bitmap containing parameters that are to be converted
299 * by FT_Thunk; it is initialized to 0 by FT_Prolog and
300 * filled in by the thunk code before calling FT_Thunk
301 * (ebp-24)
302 * ... (unclear)
303 * (ebp-44)
304 * (ebp-48) saved EAX register of caller (unclear, never restored???)
305 * (ebp-52) saved EDX register, containing 16-bit thunk target
306 * (ebp-56)
307 * ... (unclear)
308 * (ebp-64)
309 *
310 * ESP is EBP-68 on return.
311 *
312 */
315 {
316 /* Pop return address to thunk code */
319 /* Build stack frame */
323 /* Allocate 64-byte Thunk Buffer */
327 /* Store Flags (ECX) and Target Address (EDX) */
328 /* Save other registers to be restored later */
337 /* Push return address back onto stack */
339 }
341 /**********************************************************************
342 * FT_Thunk (KERNEL32.234)
343 *
344 * This routine performs the actual call to 16-bit code,
345 * similar to QT_Thunk. The differences are:
346 * - The call target is taken from the buffer created by FT_Prolog
347 * - Those arguments requested by the thunk code (by setting the
348 * corresponding bit in the bitmap at EBP-20) are converted
349 * from 32-bit pointers to segmented pointers (those pointers
350 * are guaranteed to point to structures copied to the stack
351 * by the thunk code, so we always use the 16-bit stack selector
352 * for those addresses).
353 *
354 * The bit #i of EBP-20 corresponds here to the DWORD starting at
355 * ESP+4 + 2*i.
356 *
357 * FIXME: It is unclear what happens if there are more than 32 WORDs
358 * of arguments, so that the single DWORD bitmap is no longer
359 * sufficient ...
360 */
363 {
367 CONTEXT context16;
387 {
392 }
397 }
399 /**********************************************************************
400 * FT_ExitNN (KERNEL32.218 - 232)
401 *
402 * One of the FT_ExitNN functions is called at the end of the thunk code.
403 * It removes the stack frame created by FT_Prolog, moves the function
404 * return from EBX to EAX (yes, FT_Thunk did use EAX for the return
405 * value, but the thunk code has moved it from EAX to EBX in the
406 * meantime ... :-), restores the caller's EBX, ESI, and EDI registers,
407 * and perform a return to the CALLER of the thunk code (while removing
408 * the given number of arguments from the caller's stack).
409 */
412 {
413 /* Return value is in EBX */
416 /* Restore EBX, ESI, and EDI registers */
421 /* Clean up stack frame */
425 /* Pop return address to CALLER of thunk code */
427 /* Remove arguments */
429 /* Push return address back onto stack */
431 }
450 /**********************************************************************
451 * WOWCallback16 (KERNEL32.62)(WOW32.2)
452 * Calls a win16 function with a single DWORD argument.
453 * RETURNS
454 * the return value
455 */
458 DWORD arg /* [in] single DWORD argument to function */
459 ) {
460 DWORD ret;
465 }
467 /**********************************************************************
468 * WOWCallback16Ex (KERNEL32.55)(WOW32.3)
469 * Calls a function in 16bit code.
470 * RETURNS
471 * TRUE for success
472 */
478 LPDWORD pdwRetCode /* [out] return value of win16 function */
479 ) {
481 }
483 /***********************************************************************
484 * ThunkInitLS (KERNEL32.43)
485 * A thunkbuffer link routine
486 * The thunkbuf looks like:
487 *
488 * 00: DWORD length ? don't know exactly
489 * 04: SEGPTR ptr ? where does it point to?
490 * The pointer ptr is written into the first DWORD of 'thunk'.
491 * (probably correct implemented)
492 * [ok probably]
493 * RETURNS
494 * segmented pointer to thunk?
495 */
501 LPCSTR dll32 /* [in] name of win32 dll (FIXME: not used?) */
502 ) {
503 LPDWORD addr;
513 }
515 /***********************************************************************
516 * Common32ThkLS (KERNEL32.45)
517 *
518 * This is another 32->16 thunk, independent of the QT_Thunk/FT_Thunk
519 * style thunks. The basic difference is that the parameter conversion
520 * is done completely on the *16-bit* side here. Thus we do not call
521 * the 16-bit target directly, but call a common entry point instead.
522 * This entry function then calls the target according to the target
523 * number passed in the DI register.
524 *
525 * Input: EAX SEGPTR to the common 16-bit entry point
526 * CX offset in thunk table (target number * 4)
527 * DX error return value if execution fails (unclear???)
528 * EDX.HI number of DWORD parameters
529 *
530 * (Note that we need to move the thunk table offset from CX to DI !)
531 *
532 * The called 16-bit stub expects its stack to look like this:
533 * ...
534 * (esp+40) 32-bit arguments
535 * ...
536 * (esp+8) 32 byte of stack space available as buffer
537 * (esp) 8 byte return address for use with 0x66 lret
538 *
539 * The called 16-bit stub uses a 0x66 lret to return to 32-bit code,
540 * and uses the EAX register to return a DWORD return value.
541 * Thus we need to use a special assembly glue routine
542 * (CallRegisterLongProc instead of CallRegisterShortProc).
543 *
544 * Finally, we return to the caller, popping the arguments off
545 * the stack.
546 *
547 * FIXME: The called function uses EBX to return the number of
548 * arguments that are to be popped off the caller's stack.
549 * This is clobbered by the assembly glue, so we simply use
550 * the original EDX.HI to get the number of arguments.
551 * (Those two values should be equal anyway ...?)
552 *
553 */
555 {
556 CONTEXT context16;
557 DWORD argsize;
570 /* FIXME: hack for stupid USER32 CallbackGlueLS routine */
579 /* Clean up caller's stack frame */
584 }
586 /***********************************************************************
587 * OT_32ThkLSF (KERNEL32.40)
588 *
589 * YET Another 32->16 thunk. The difference to Common32ThkLS is that
590 * argument processing is done on both the 32-bit and the 16-bit side:
591 * The 32-bit side prepares arguments, copying them onto the stack.
592 *
593 * When this routine is called, the first word on the stack is the
594 * number of argument bytes prepared by the 32-bit code, and EDX
595 * contains the 16-bit target address.
596 *
597 * The called 16-bit routine is another relaycode, doing further
598 * argument processing and then calling the real 16-bit target
599 * whose address is stored at [bp-04].
600 *
601 * The call proceeds using a normal CallRegisterShortProc.
602 * After return from the 16-bit relaycode, the arguments need
603 * to be copied *back* to the 32-bit stack, since the 32-bit
604 * relaycode processes output parameters.
605 *
606 * Note that we copy twice the number of arguments, since some of the
607 * 16-bit relaycodes in SYSTHUNK.DLL directly access the original
608 * arguments of the caller!
609 *
610 * (Note that this function seems only to be used for
611 * OLECLI32 -> OLECLI and OLESVR32 -> OLESVR thunking.)
612 */
614 {
615 CONTEXT context16;
616 DWORD argsize;
635 }
637 /***********************************************************************
638 * ThunkInitLSF (KERNEL32.41)
639 * A thunk setup routine.
640 * Expects a pointer to a preinitialized thunkbuffer in the first argument
641 * looking like:
642 * 00..03: unknown (pointer, check _41, _43, _46)
643 * 04: EB1E jmp +0x20
644 *
645 * 06..23: unknown (space for replacement code, check .90)
646 *
647 * 24:>E800000000 call offset 29
648 * 29:>58 pop eax ( target of call )
649 * 2A: 2D25000000 sub eax,0x00000025 ( now points to offset 4 )
650 * 2F: BAxxxxxxxx mov edx,xxxxxxxx
651 * 34: 68yyyyyyyy push KERNEL32.90
652 * 39: C3 ret
653 *
654 * 3A: EB1E jmp +0x20
655 * 3E ... 59: unknown (space for replacement code?)
656 * 5A: E8xxxxxxxx call <32bitoffset xxxxxxxx>
657 * 5F: 5A pop edx
658 * 60: 81EA25xxxxxx sub edx, 0x25xxxxxx
659 * 66: 52 push edx
660 * 67: 68xxxxxxxx push xxxxxxxx
661 * 6C: 68yyyyyyyy push KERNEL32.89
662 * 71: C3 ret
663 * 72: end?
664 * This function checks if the code is there, and replaces the yyyyyyyy entries
665 * by the functionpointers.
666 * The thunkbuf looks like:
667 *
668 * 00: DWORD length ? don't know exactly
669 * 04: SEGPTR ptr ? where does it point to?
670 * The segpointer ptr is written into the first DWORD of 'thunk'.
671 * [ok probably]
672 * RETURNS
673 * unclear, pointer to win16 thkbuffer?
674 */
680 LPCSTR dll32 /* [in] name of win32 dll */
681 ) {
685 /* FIXME: add checks for valid code ... */
686 /* write pointers to kernel32.89 and kernel32.90 (+ordinal base of 1) */
699 }
701 /***********************************************************************
702 * FT_PrologPrime (KERNEL32.89)
703 *
704 * This function is called from the relay code installed by
705 * ThunkInitLSF. It replaces the location from where it was
706 * called by a standard FT_Prolog call stub (which is 'primed'
707 * by inserting the correct target table pointer).
708 * Finally, it calls that stub.
709 *
710 * Input: ECX target number + flags (passed through to FT_Prolog)
711 * (ESP) offset of location where target table pointer
712 * is stored, relative to the start of the relay code
713 * (ESP+4) pointer to start of relay code
714 * (this is where the FT_Prolog call stub gets written to)
715 *
716 * Note: The two DWORD arguments get popped from the stack.
717 *
718 */
720 {
728 /* We should actually call the relay code now, */
729 /* but we skip it and go directly to FT_Prolog */
732 }
734 /***********************************************************************
735 * QT_ThunkPrime (KERNEL32.90)
736 *
737 * This function corresponds to FT_PrologPrime, but installs a
738 * call stub for QT_Thunk instead.
739 *
740 * Input: (EBP-4) target number (passed through to QT_Thunk)
741 * EDX target table pointer location offset
742 * EAX start of relay code
743 *
744 */
746 {
754 /* We should actually call the relay code now, */
755 /* but we skip it and go directly to QT_Thunk */
758 }
760 /***********************************************************************
761 * (KERNEL32.46)
762 * Another thunkbuf link routine.
763 * The start of the thunkbuf looks like this:
764 * 00: DWORD length
765 * 04: SEGPTR address for thunkbuffer pointer
766 * [ok probably]
767 */
773 LPCSTR dll32 /* [in] win32 dll. FIXME: strange, unused */
774 ) {
775 LPDWORD addr;
781 }
783 /**********************************************************************
784 * SSInit KERNEL.700
785 * RETURNS
786 * TRUE for success.
787 */
789 {
791 }
793 /**********************************************************************
794 * SSOnBigStack KERNEL32.87
795 * Check if thunking is initialized (ss selector set up etc.)
796 * We do that differently, so just return TRUE.
797 * [ok]
798 * RETURNS
799 * TRUE for success.
800 */
802 {
805 }
807 /**********************************************************************
808 * SSCall
809 * One of the real thunking functions. This one seems to be for 32<->32
810 * thunks. It should probably be capable of crossing processboundaries.
811 *
812 * And YES, I've seen nr=48 (somewhere in the Win95 32<->16 OLE coupling)
813 * [ok]
814 */
820 ) {
830 }
852 case 40: ret = fun(args[0],args[1],args[2],args[3],args[4],args[5],args[6],args[7],args[8],args[9]);
854 case 44: ret = fun(args[0],args[1],args[2],args[3],args[4],args[5],args[6],args[7],args[8],args[9],args[10]);
856 case 48: ret = fun(args[0],args[1],args[2],args[3],args[4],args[5],args[6],args[7],args[8],args[9],args[10],args[11]);
863 }
866 }
868 /**********************************************************************
869 * W32S_BackTo32 (KERNEL32.51)
870 */
872 {
880 }
882 /**********************************************************************
883 * AllocSLCallback (KERNEL32)
884 *
885 * Win95 uses some structchains for callbacks. It allocates them
886 * in blocks of 100 entries, size 32 bytes each, layout:
887 * blockstart:
888 * 0: PTR nextblockstart
889 * 4: entry *first;
890 * 8: WORD sel ( start points to blockstart)
891 * A: WORD unknown
892 * 100xentry:
893 * 00..17: Code
894 * 18: PDB *owning_process;
895 * 1C: PTR blockstart
896 *
897 * We ignore this for now. (Just a note for further developers)
898 * FIXME: use this method, so we don't waste selectors...
899 *
900 * Following code is then generated by AllocSLCallback. The code is 16 bit, so
901 * the 0x66 prefix switches from word->long registers.
902 *
903 * 665A pop edx
904 * 6668x arg2 x pushl <arg2>
905 * 6652 push edx
906 * EAx arg1 x jmpf <arg1>
907 *
908 * returns the startaddress of this thunk.
909 *
910 * Note, that they look very similair to the ones allocates by THUNK_Alloc.
911 * RETURNS
912 * segmented pointer to the start of the thunk
913 */
914 DWORD WINAPI
917 DWORD callback /* [in] callback function */
918 ) {
920 WORD sel;
932 }
934 /**********************************************************************
935 * FreeSLCallback (KERNEL32.274)
936 * Frees the specified 16->32 callback
937 */
938 void WINAPI
940 DWORD x /* [in] 16 bit callback (segmented pointer?) */
941 ) {
943 }
946 /**********************************************************************
947 * GetTEBSelectorFS (KERNEL.475)
948 * Set the 16-bit %fs to the 32-bit %fs (current TEB selector)
949 */
951 {
953 }
955 /**********************************************************************
956 * KERNEL_431 (KERNEL.431)
957 * IsPeFormat (W32SYS.2)
958 * Checks the passed filename if it is a PE format executeable
959 * RETURNS
960 * TRUE, if it is.
961 * FALSE if not.
962 */
965 HFILE16 hf16 /* [in] open file, if filename is NULL */
966 ) {
967 IMAGE_DOS_HEADER mzh;
969 OFSTRUCT ofs;
970 DWORD xmagic;
976 }
981 }
986 }
991 }
994 }
996 /***********************************************************************
997 * WOWHandle32 (KERNEL32.57)(WOW32.16)
998 * Converts a win16 handle of type into the respective win32 handle.
999 * We currently just return this handle, since most handles are the same
1000 * for win16 and win32.
1001 * RETURNS
1002 * The new handle
1003 */
1006 WOW_HANDLE_TYPE type /* [in] handle type */
1007 ) {
1010 }
1012 /***********************************************************************
1013 * K32Thk1632Prolog (KERNEL32.492)
1014 */
1016 {
1019 /* Arrrgh! SYSTHUNK.DLL just has to re-implement another method
1020 of 16->32 thunks instead of using one of the standard methods!
1021 This means that SYSTHUNK.DLL itself switches to a 32-bit stack,
1022 and does a far call to the 32-bit code segment of OLECLI32/OLESVR32.
1023 Unfortunately, our CallTo/CallFrom mechanism is therefore completely
1024 bypassed, which means it will crash the next time the 32-bit OLE
1025 code thunks down again to 16-bit (this *will* happen!).
1027 The following hack tries to recognize this situation.
1028 This is possible since the called stubs in OLECLI32/OLESVR32 all
1029 look exactly the same:
1030 00 E8xxxxxxxx call K32Thk1632Prolog
1031 05 FF55FC call [ebp-04]
1032 08 E8xxxxxxxx call K32Thk1632Epilog
1033 0D 66CB retf
1035 If we recognize this situation, we try to simulate the actions
1036 of our CallTo/CallFrom mechanism by copying the 16-bit stack
1037 to our 32-bit stack, creating a proper STACK16FRAME and
1038 updating thdb->cur_stack. */
1042 {
1067 }
1070 }
1072 /***********************************************************************
1073 * K32Thk1632Epilog (KERNEL32.491)
1074 */
1076 {
1081 /* We undo the SYSTHUNK hack if necessary. See K32Thk1632Prolog. */
1085 {
1104 }
1105 }