| blob | 6fe7d3252964b31b1922a9a555f2afa49603e8f9 |
1 /* Pre-process emacs.exe for profiling by MSVC.
2 Copyright (C) 1999, 2001-2012 Free Software Foundation, Inc.
4 This file is part of GNU Emacs.
6 GNU Emacs is free software: you can redistribute it and/or modify
7 it under the terms of the GNU General Public License as published by
8 the Free Software Foundation, either version 3 of the License, or
9 (at your option) any later version.
11 GNU Emacs is distributed in the hope that it will be useful,
12 but WITHOUT ANY WARRANTY; without even the implied warranty of
13 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
14 GNU General Public License for more details.
16 You should have received a copy of the GNU General Public License
17 along with GNU Emacs. If not, see <http://www.gnu.org/licenses/>.
20 Andrew Innes <andrewi@harlequin.co.uk> 16-Jan-1999
21 based on code from addsection.c
22 */
24 #include <stdlib.h>
25 #include <stdio.h>
26 #include <fcntl.h>
27 #include <time.h>
28 #ifdef __GNUC__
29 #define _ANONYMOUS_UNION
30 #define _ANONYMOUS_STRUCT
31 #endif
32 #include <windows.h>
34 /* Include relevant definitions from IMAGEHLP.H, which can be found
35 in \\win32sdk\mstools\samples\image\include\imagehlp.h. */
37 PIMAGE_NT_HEADERS
39 DWORD FileLength,
40 LPDWORD HeaderSum,
41 LPDWORD CheckSum);
43 #undef min
44 #undef max
45 #define min(x, y) (((x) < (y)) ? (x) : (y))
46 #define max(x, y) (((x) > (y)) ? (x) : (y))
49 /* File handling. */
54 HANDLE file;
55 HANDLE file_mapping;
59 int
61 {
62 HANDLE file;
63 HANDLE file_mapping;
89 }
91 int
93 {
94 HANDLE file;
95 HANDLE file_mapping;
119 }
121 int
123 {
124 HANDLE file;
125 HANDLE file_mapping;
151 }
153 /* Close the system structures associated with the given file. */
154 void
156 {
159 /* For the case of output files, set final size. */
163 }
166 /* Routines to manipulate NT executable file sections. */
168 unsigned long
170 {
171 /* The true section size, before rounding, for an initialized data or
172 code section. (Supposedly some linkers swap the meaning of these
173 two values.) */
176 }
178 /* Return pointer to section header for named section. */
179 IMAGE_SECTION_HEADER *
181 {
182 PIMAGE_SECTION_HEADER section;
188 {
191 section++;
192 }
194 }
196 /* Return pointer to section header for section containing the given
197 relative virtual address. */
198 IMAGE_SECTION_HEADER *
200 {
201 PIMAGE_SECTION_HEADER section;
207 {
208 /* Some linkers (eg. the NT SDK linker I believe) swapped the
209 meaning of these two values - or rather, they ignored
210 VirtualSize entirely and always set it to zero. This affects
211 some very old exes (eg. gzip dated Dec 1993). Since
212 w32_executable_type relies on this function to work reliably,
213 we need to cope with this. */
219 section++;
220 }
222 }
224 /* Return pointer to section header for section containing the given
225 offset in its raw data area. */
226 IMAGE_SECTION_HEADER *
228 {
229 PIMAGE_SECTION_HEADER section;
235 {
239 section++;
240 }
242 }
244 /* Return offset to an object in dst, given offset in src. We assume
245 there is at least one section in both src and dst images, and that
246 the some sections may have been added to dst (after sections in src). */
247 static DWORD
251 {
257 {
260 i++;
262 {
263 /* Handle offsets after the last section. */
267 dst_section--;
269 src_section--;
270 return offset
273 }
274 src_section++;
275 dst_section++;
276 }
279 }
281 #define OFFSET_TO_RVA(offset, section) \
282 (section->VirtualAddress + ((DWORD)(offset) - section->PointerToRawData))
284 #define RVA_TO_OFFSET(rva, section) \
285 (section->PointerToRawData + ((DWORD)(rva) - section->VirtualAddress))
287 #define RVA_TO_SECTION_OFFSET(rva, section) \
288 ((DWORD)(rva) - section->VirtualAddress)
290 #define RVA_TO_PTR(var,section,filedata) \
291 ((void *)(RVA_TO_OFFSET(var,section) + (filedata)->file_base))
293 /* Convert address in executing image to RVA. */
294 #define PTR_TO_RVA(ptr) ((DWORD)(ptr) - (DWORD) GetModuleHandle (NULL))
296 #define PTR_TO_OFFSET(ptr, pfile_data) \
297 ((unsigned const char *)(ptr) - (pfile_data)->file_base)
299 #define OFFSET_TO_PTR(offset, pfile_data) \
300 ((pfile_data)->file_base + (DWORD)(offset))
302 #define ROUND_UP(p, align) (((DWORD)(p) + (align)-1) & ~((align)-1))
303 #define ROUND_DOWN(p, align) ((DWORD)(p) & ~((align)-1))
306 /* The MSVC prep program generates a ._xe file from .exe, where relevant
307 function calls etc have been patched to go through thunks (generated
308 by prep) that record timing/call information. Because the thunks
309 need to make references to functions imported from profile.dll, the
310 import table must be expanded; the end result is that all the
311 sections following .rdata are relocated to higher RVAs (add a final
312 code section is added holding all the thunks). The .reloc section is
313 also expanded, so that the thunks themselves are relocatable.
315 It is this relocation which kills emacs._xe, because the dumped heap
316 pointers aren't relocated, because there is no relocation data for
317 either the relevant global/static variables or the heap section
318 itself, both of which contain pointers into the heap. [Note that
319 static variables which aren't initialized during linking may become
320 initialized with heap pointers, or even pointers to other static
321 variables, because of dumping.]
323 We could potentially generate the relocation data ourselves by making
324 two versions of temacs, one with an extra dummy section before
325 EMHEAP to offset it, and then compare the dumped executables from
326 both. That is a lot of work though, and it doesn't solve the problem
327 of dumped pointers to static variables, which also can be relocated.
329 A better solution is to pre-process emacs.exe so that the .rdata and
330 .reloc sections are moved to the end of the section table, and thus
331 prep won't relocate anything else. (Of course, we leave "dead"
332 copies of these two sections in place, so that the virtual address of
333 everything else is unaffected.) Relocating the .reloc data is
334 trivial - we just update the IMAGE_BASE_RELOCATION address in the
335 header (the data itself doesn't change). Relocating the import table
336 is more complicated though, because the calls to imported functions
337 must be patched up. That requires us to selectively apply the base
338 relocations when we encounter references to imported functions (or
339 variables) in other sections, but at least the base relocations are
340 easy to parse. */
342 static void
345 {
347 PIMAGE_DOS_HEADER dos_header;
348 PIMAGE_NT_HEADERS nt_header;
349 PIMAGE_NT_HEADERS dst_nt_header;
350 PIMAGE_SECTION_HEADER section;
351 PIMAGE_SECTION_HEADER dst_section;
352 PIMAGE_SECTION_HEADER import_section;
353 PIMAGE_SECTION_HEADER reloc_section;
354 PIMAGE_DATA_DIRECTORY import_dir;
355 PIMAGE_DATA_DIRECTORY reloc_dir;
356 DWORD import_delta_rva;
357 DWORD reloc_delta_rva;
358 DWORD offset;
361 #define COPY_CHUNK(message, src, size) \
362 do { \
363 unsigned const char *s = (void *)(src); \
364 unsigned long count = (size); \
369 memcpy (dst, s, count); \
370 dst += count; \
371 } while (0)
373 #define DST_TO_OFFSET() PTR_TO_OFFSET (dst, p_outfile)
374 #define ROUND_UP_DST_AND_ZERO(align) \
375 do { \
376 unsigned char *newdst = p_outfile->file_base \
377 + ROUND_UP (DST_TO_OFFSET (), (align)); \
379 memset (dst, 0, newdst - dst); \
380 dst = newdst; \
381 } while (0)
383 /* Copy the source image sequentially, ie. section by section after
384 copying the headers and section table, to simplify the process of
385 relocating the .rdata and .reloc section table entries (which might
386 force the raw section data to be relocated).
388 Note that dst is updated implicitly by each COPY_CHUNK. */
401 {
404 }
417 /* Leave room for extra section table entries; filled in below. */
420 /* Align the first section's raw data area, and set the header size
421 field accordingly. */
427 {
431 /* "Blank out" the two sections being relocated. */
433 {
444 }
446 /* Update the file-relative offset for this section's raw data (if
447 it has any) in case things have been relocated; we will update
448 the other offsets below once we know where everything is. */
452 /* Copy the original raw data. */
453 COPY_CHUNK
457 /* Round up the raw data size to the new alignment. */
462 /* Align the next section's raw data area. */
464 }
466 /* Add the extra section entries, copying the raw data we skipped
467 earlier. We'll patch up the data itself below. */
469 {
480 /* Remember delta applied to import section. */
482 COPY_CHUNK
487 dst_section++;
488 }
490 {
501 /* Remember delta applied to reloc section. */
503 COPY_CHUNK
510 dst_section++;
511 }
513 /* Copy remainder of source image. */
514 section--;
517 COPY_CHUNK
522 /* Final size for new image. */
525 /* Now patch up remaining file-relative offsets. */
531 #define ADJUST_OFFSET(var) \
532 do { \
533 if ((var) != 0) \
534 (var) = relocate_offset ((var), nt_header, dst_nt_header); \
535 } while (0)
537 #define ADJUST_IMPORT_RVA(var) \
538 do { \
539 if ((var) != 0) \
540 *((DWORD *)&(var)) += import_delta_rva; \
541 } while (0)
546 {
547 /* Recompute data sizes for completeness. */
556 }
560 /* Update offsets in debug directory entries. Note that the debug
561 directory may be in the same section as the import table, so its
562 RVA may need to be adjusted too. */
563 {
564 PIMAGE_DATA_DIRECTORY debug_dir =
566 PIMAGE_DEBUG_DIRECTORY debug_entry;
568 /* Update debug_dir if part of import_section. */
574 {
581 {
582 /* The debug data itself is normally not part of any
583 section, but stored after all the raw section data. So
584 let relocate_offset do the work. */
587 }
588 }
589 }
591 /* Update RVAs in import directory entries. */
592 {
593 PIMAGE_IMPORT_DESCRIPTOR imports;
594 PIMAGE_THUNK_DATA import_thunks;
603 {
610 import_thunks++)
616 import_thunks++)
619 }
623 }
625 /* Fix up references to the import section. */
628 {
632 DWORD len_import_relocs;
633 DWORD len_remaining_relocs;
642 /* Move the base relocations for the import section, if there are
643 any; the profiler needs to be able to patch RVAs in the import
644 section itself. */
648 {
650 {
653 }
655 {
659 }
660 }
662 {
672 }
674 /* Walk up the list of base relocations, checking for references
675 to the old import section location, and patching them to
676 reference the new location. */
680 {
682 DWORD page_offset;
684 WORD word;
685 DWORD dword;
690 /* Don't apply fixups to the blanked sections. */
696 fixup++)
697 {
701 /* Unless our assumption is wrong, all low word fixups
702 should immediately follow a high fixup. */
707 {
711 /* We must assume that high and low fixups occur in
712 pairs, specifically a low fixup immediately follows a
713 high fixup (normally separated by two bytes). We
714 have to process the two fixups together, to find out
715 the full pointer value and decide whether to apply
716 the fixup. */
723 {
726 }
730 /* Docs imply two words in big-endian order, so perhaps
731 this is only used on big-endian platforms, in which
732 case the obvious code will work. */
737 /* Docs don't say, but I guess this is the equivalent
738 for little-endian platforms. */
743 /* Don't know how to handle this; MIPS support has been
744 dropped from NT4 anyway. */
747 #ifdef IMAGE_REL_BASED_SECTION
750 /* Docs don't say what these values mean. */
751 #endif
754 }
755 }
756 }
757 }
758 }
761 int
763 {
764 PIMAGE_DOS_HEADER dos_header;
765 PIMAGE_NT_HEADERS nt_header;
774 /* Open the original (dumped) executable file for reference. */
776 {
780 }
782 /* Create a new image that can be prepped; we don't expect the size to
783 change because we are only adding two new section table entries,
784 which should fit in the alignment slop. */
786 {
790 }
794 /* Patch up header fields; profiler is picky about this. */
795 {
797 DWORD headersum;
798 DWORD checksum;
804 // nt_header->FileHeader.TimeDateStamp = time (NULL);
805 // dos_header->e_cp = size / 512;
806 // nt_header->OptionalHeader.SizeOfImage = size;
810 {
811 // nt_header->FileHeader.TimeDateStamp = time (NULL);
817 }
819 }
825 }
827 /* eof */