4 #include <linux/coff.h>
10 /* http://www.delorie.com/djgpp/doc/coff/ */
13 unsigned short f_magic; /* magic number */
14 unsigned short f_nscns; /* number of sections */
15 unsigned int f_timdat; /* time & date stamp */
16 unsigned int f_symptr; /* file pointer to symtab */
17 unsigned int f_nsyms; /* number of symtab entries */
18 unsigned short f_opthdr; /* sizeof(optional hdr) */
19 unsigned short f_flags; /* flags */
23 unsigned short magic; /* type of file */
24 unsigned short vstamp; /* version stamp */
25 unsigned int tsize; /* text size in bytes, padded to FW bdry*/
26 unsigned int dsize; /* initialized data " " */
27 unsigned int bsize; /* uninitialized data " " */
28 unsigned int entry; /* entry pt. */
29 unsigned int text_start; /* base of text used for this file */
30 unsigned int data_start; /* base of data used for this file */
34 char s_name[8]; /* section name */
35 unsigned int s_paddr; /* physical address, aliased s_nlib */
36 unsigned int s_vaddr; /* virtual address */
37 unsigned int s_size; /* section size */
38 unsigned int s_scnptr; /* file ptr to raw data for section */
39 unsigned int s_relptr; /* file ptr to relocation */
40 unsigned int s_lnnoptr; /* file ptr to line numbers */
41 unsigned short s_nreloc; /* number of relocation entries */
42 unsigned short s_nlnno; /* number of line number entries */
43 unsigned int s_flags; /* flags */
47 unsigned int r_vaddr; /* address of relocation */
48 unsigned int r_symndx; /* symbol we're adjusting for */
49 unsigned short r_type; /* type of relocation */
50 } __attribute__((packed)) RELOC;
54 char e_name[E_SYMNMLEN];
56 unsigned int e_zeroes;
57 unsigned int e_offset;
62 unsigned short e_type;
63 unsigned char e_sclass;
64 unsigned char e_numaux;
65 } __attribute__((packed)) SYMENT;
71 unsigned int fpos; // for patching
75 static int symt_cmp(const void *p1_, const void *p2_)
77 const struct my_symtab *p1 = p1_, *p2 = p2_;
78 return p1->addr - p2->addr;
81 void parse_headers(FILE *f, unsigned int *base_out,
82 long *sect_ofs, uint8_t **sect_data, long *sect_sz,
83 RELOC **relocs, long *reloc_cnt,
84 struct my_symtab **symtab_out, long *sym_cnt)
86 struct my_symtab *symt_o = NULL;
87 char *stringtab = NULL;
88 unsigned int base = 0;
101 ret = fseek(f, 0, SEEK_END);
106 ret = fseek(f, 0, SEEK_SET);
109 ret = fread(&hdr, 1, sizeof(hdr), f);
110 my_assert(ret, sizeof(hdr));
112 if (hdr.f_magic == 0x5a4d) // MZ
114 ret = fseek(f, 0x3c, SEEK_SET);
116 ret = fread(&val, 1, sizeof(val), f);
117 my_assert(ret, sizeof(val));
119 ret = fseek(f, val, SEEK_SET);
121 ret = fread(&val, 1, sizeof(val), f);
122 my_assert(ret, sizeof(val));
123 my_assert(val, 0x4550); // PE
125 // should be COFF now
126 ret = fread(&hdr, 1, sizeof(hdr), f);
127 my_assert(ret, sizeof(hdr));
130 my_assert(hdr.f_magic, COFF_I386MAGIC);
132 if (hdr.f_opthdr != 0)
134 opthdr_pos = ftell(f);
136 if (hdr.f_opthdr < sizeof(opthdr))
139 ret = fread(&opthdr, 1, sizeof(opthdr), f);
140 my_assert(ret, sizeof(opthdr));
141 my_assert(opthdr.magic, COFF_ZMAGIC);
143 printf("text_start: %x\n", opthdr.text_start);
145 if (hdr.f_opthdr > sizeof(opthdr)) {
146 ret = fread(&base, 1, sizeof(base), f);
147 my_assert(ret, sizeof(base));
148 printf("base: %x\n", base);
150 ret = fseek(f, opthdr_pos + hdr.f_opthdr, SEEK_SET);
154 // note: assuming first non-empty one is .text ..
155 for (s = 0; s < hdr.f_nscns; s++) {
156 ret = fread(&scnhdr, 1, sizeof(scnhdr), f);
157 my_assert(ret, sizeof(scnhdr));
159 if (scnhdr.s_size != 0) {
165 printf("f_nsyms: %x\n", hdr.f_nsyms);
166 printf("s_name: '%s'\n", scnhdr.s_name);
167 printf("s_vaddr: %x\n", scnhdr.s_vaddr);
168 printf("s_size: %x\n", scnhdr.s_size);
169 //printf("s_scnptr: %x\n", scnhdr.s_scnptr);
170 printf("s_nreloc: %x\n", scnhdr.s_nreloc);
173 ret = fseek(f, scnhdr.s_scnptr, SEEK_SET);
176 *sect_data = malloc(scnhdr.s_size);
177 my_assert_not(*sect_data, NULL);
178 ret = fread(*sect_data, 1, scnhdr.s_size, f);
179 my_assert(ret, scnhdr.s_size);
181 *sect_ofs = scnhdr.s_scnptr;
182 *sect_sz = scnhdr.s_size;
185 ret = fseek(f, scnhdr.s_relptr, SEEK_SET);
188 reloc_size = scnhdr.s_nreloc * sizeof((*relocs)[0]);
189 *relocs = malloc(reloc_size + 1);
190 my_assert_not(*relocs, NULL);
191 ret = fread(*relocs, 1, reloc_size, f);
192 my_assert(ret, reloc_size);
194 *reloc_cnt = scnhdr.s_nreloc;
197 if (hdr.f_nsyms != 0) {
200 symt_o = malloc(hdr.f_nsyms * sizeof(symt_o[0]) + 1);
201 my_assert_not(symt_o, NULL);
203 ret = fseek(f, hdr.f_symptr
204 + hdr.f_nsyms * sizeof(syment), SEEK_SET);
206 ret = fread(&i, 1, sizeof(i), f);
207 my_assert(ret, sizeof(i));
208 my_assert((unsigned int)i < filesize, 1);
210 stringtab = malloc(i);
211 my_assert_not(stringtab, NULL);
212 memset(stringtab, 0, 4);
213 ret = fread(stringtab + 4, 1, i - 4, f);
214 my_assert(ret, i - 4);
216 ret = fseek(f, hdr.f_symptr, SEEK_SET);
220 for (i = s = 0; i < hdr.f_nsyms; i++) {
223 ret = fread(&syment, 1, sizeof(syment), f);
224 my_assert(ret, sizeof(syment));
226 strncpy(symname, syment.e.e_name, 8);
227 //printf("%3d %2d %08x '%s'\n", syment.e_sclass,
228 // syment.e_scnum, syment.e_value, symname);
230 if (syment.e_scnum != text_scnum || syment.e_sclass != C_EXT)
233 symt_o[s].addr = syment.e_value;
234 symt_o[s].fpos = pos;
235 if (syment.e.e.e_zeroes == 0)
236 symt_o[s].name = stringtab + syment.e.e.e_offset;
238 symt_o[s].name = strdup(symname);
241 if (syment.e_numaux) {
242 ret = fseek(f, syment.e_numaux * sizeof(syment),
245 i += syment.e_numaux;
250 qsort(symt_o, s, sizeof(symt_o[0]), symt_cmp);
253 *symtab_out = symt_o;
255 if (base != 0 && base_out != NULL)
256 *base_out = base + scnhdr.s_vaddr;
259 static int handle_pad(uint8_t *d_obj, uint8_t *d_exe, int maxlen)
261 static const uint8_t p7[7] = { 0x8d, 0xa4, 0x24, 0x00, 0x00, 0x00, 0x00 };
262 static const uint8_t p6[6] = { 0x8d, 0x9b, 0x00, 0x00, 0x00, 0x00 };
263 static const uint8_t p5[5] = { 0x05, 0x00, 0x00, 0x00, 0x00 };
264 static const uint8_t p4[4] = { 0x8d, 0x64, 0x24, 0x00 };
265 static const uint8_t p3[3] = { 0x8d, 0x49, 0x00 };
266 static const uint8_t p2[2] = { 0x8b, 0xff };
267 static const uint8_t p1[1] = { 0x90 };
271 for (i = 0; i < maxlen; i++)
272 if (d_exe[i] != 0xcc)
275 for (len = i; len > 0; )
283 case sizeof(p ## x): \
284 if (memcmp(d_obj, p ## x, sizeof(p ## x))) \
286 memset(d_obj, 0xcc, sizeof(p ## x)); \
296 printf("%s: unhandled len: %d\n", __func__, len);
308 struct equiv_opcode {
313 uint8_t v_masm_mask[8];
315 uint8_t v_msvc_mask[8];
319 { 0x66,0x83,0xf8,0x03 }, { 0xff,0xff,0xff,0x00 },
320 { 0x66,0x3d,0x03,0x00 }, { 0xff,0xff,0x00,0xff }, },
321 // lea -0x1(%ebx,%eax,1),%esi // op mod/rm sib offs
322 // mov, test, imm grp 1
324 { 0x8d,0x74,0x03 }, { 0xf0,0x07,0xc0 },
325 { 0x8d,0x74,0x18 }, { 0xf0,0x07,0xc0 }, },
326 // movzbl 0x58f24a(%eax,%ecx,1),%eax
328 { 0x0f,0xb6,0x84,0x08 }, { 0xff,0xff,0x07,0xc0 },
329 { 0x0f,0xb6,0x84,0x01 }, { 0xff,0xff,0x07,0xc0 }, },
332 { 0xfe,0x4c,0x03 }, { 0xfe,0xff,0xc0 },
333 { 0xfe,0x4c,0x18 }, { 0xfe,0xff,0xc0 }, },
336 { 0x38,0x0c,0x0c }, { 0xff,0xff,0xc0 },
337 { 0x38,0x0c,0x30 }, { 0xff,0xff,0xc0 }, },
340 { 0x84,0xd3 }, { 0xfe,0xc0 },
341 { 0x84,0xda }, { 0xfe,0xc0 }, },
344 { 0x3a,0xca }, { 0xff,0xc0 },
345 { 0x38,0xd1 }, { 0xff,0xc0 }, },
348 { 0xf3,0x66 }, { 0xfe,0xff },
349 { 0x66,0xf3 }, { 0xff,0xfe }, },
350 // fadd st, st(0) vs st(0), st
352 { 0xd8,0xc0 }, { 0xff,0xf7 },
353 { 0xdc,0xc0 }, { 0xff,0xf7 }, },
355 // broad filters (may take too much..)
356 // testb $0x4,0x1d(%esi,%eax,1)
359 { 0xf6,0x44,0x06 }, { 0x00,0x07,0xc0 },
360 { 0xf6,0x44,0x30 }, { 0x00,0x07,0xc0 }, },
363 static int cmp_mask(uint8_t *d, uint8_t *expect, uint8_t *mask, int len)
367 for (i = 0; i < len; i++)
368 if ((d[i] & mask[i]) != (expect[i] & mask[i]))
374 static int check_equiv(uint8_t *d_obj, uint8_t *d_exe, int maxlen)
376 uint8_t vo, ve, vo2, ve2;
380 for (i = 0; i < sizeof(equiv_ops) / sizeof(equiv_ops[0]); i++)
382 struct equiv_opcode *op = &equiv_ops[i];
389 if (cmp_mask(d_obj + ofs, op->v_masm,
390 op->v_masm_mask, len))
392 if (cmp_mask(d_exe + ofs, op->v_msvc,
393 op->v_msvc_mask, len))
401 for (; jo < len; jo++)
402 if (op->v_masm_mask[jo] != 0xff)
404 for (; je < len; je++)
405 if (op->v_msvc_mask[je] != 0xff)
408 if ((jo == len && je != len) || (jo != len && je == len)) {
409 printf("invalid equiv_ops\n");
413 return len + ofs - 1; // matched
416 vo = d_obj[jo] & ~op->v_masm_mask[jo];
417 ve = d_exe[je] & ~op->v_msvc_mask[je];
418 if (op->cmp_rm && op->v_masm_mask[jo] == 0xc0) {
423 if (vo != ve || vo2 != ve2)
439 int main(int argc, char *argv[])
442 long text_ofs_obj, text_ofs_exe;
443 long sztext_obj, sztext_exe, sztext_cmn;
444 RELOC *relocs_obj, *relocs_exe;
445 long reloc_cnt_obj, reloc_cnt_exe;
446 struct my_symtab *syms_obj, *syms_exe;
447 long sym_cnt_obj, sym_cnt_exe;
448 uint8_t *d_obj, *d_exe;
449 unsigned int base = 0;
456 printf("usage:\n%s <a_obj> <exe>\n", argv[0]);
460 f_obj = fopen(argv[1], "r+b");
462 fprintf(stderr, "%s", argv[1]);
467 f_exe = fopen(argv[2], "r");
469 fprintf(stderr, "%s", argv[2]);
474 parse_headers(f_obj, NULL, &text_ofs_obj, &d_obj, &sztext_obj,
475 &relocs_obj, &reloc_cnt_obj, &syms_obj, &sym_cnt_obj);
476 parse_headers(f_exe, &base, &text_ofs_exe, &d_exe, &sztext_exe,
477 &relocs_exe, &reloc_cnt_exe, &syms_exe, &sym_cnt_exe);
479 sztext_cmn = sztext_obj;
480 if (sztext_cmn > sztext_exe)
481 sztext_cmn = sztext_exe;
483 if (sztext_cmn == 0) {
484 printf("bad .text size(s): %ld, %ld\n",
485 sztext_obj, sztext_exe);
489 for (i = 0; i < reloc_cnt_obj; i++)
491 unsigned int a = relocs_obj[i].r_vaddr;
492 //printf("%04x %08x\n", relocs_obj[i].r_type, a);
494 switch (relocs_obj[i].r_type) {
496 memset(d_obj + a, 0, 4);
497 memset(d_exe + a, 0, 4);
500 printf("unknown reloc %x @%08x\n",
501 relocs_obj[i].r_type, base + a);
506 for (i = 0; i < sztext_cmn; i++)
508 if (d_obj[i] == d_exe[i])
511 left = sztext_cmn - i;
513 if (d_exe[i] == 0xcc) { // padding
514 if (handle_pad(d_obj + i, d_exe + i, left))
518 ret = check_equiv(d_obj + i, d_exe + i, left);
524 printf("%x: %02x vs %02x\n", base + i, d_obj[i], d_exe[i]);