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target: return JIM_OK instead of ERROR_OK
[openocd/cortex.git] / src / target / image.c
blobf8d05292c853cf5189b5337b5fc8c3771d3a2cbd
1 /***************************************************************************
2 * Copyright (C) 2007 by Dominic Rath *
3 * Dominic.Rath@gmx.de *
4 * *
5 * Copyright (C) 2007,2008 Øyvind Harboe *
6 * oyvind.harboe@zylin.com *
7 * *
8 * Copyright (C) 2008 by Spencer Oliver *
9 * spen@spen-soft.co.uk *
10 * *
11 * Copyright (C) 2009 by Franck Hereson *
12 * franck.hereson@secad.fr *
13 * *
14 * This program is free software; you can redistribute it and/or modify *
15 * it under the terms of the GNU General Public License as published by *
16 * the Free Software Foundation; either version 2 of the License, or *
17 * (at your option) any later version. *
18 * *
19 * This program is distributed in the hope that it will be useful, *
20 * but WITHOUT ANY WARRANTY; without even the implied warranty of *
21 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
22 * GNU General Public License for more details. *
23 * *
24 * You should have received a copy of the GNU General Public License *
25 * along with this program; if not, write to the *
26 * Free Software Foundation, Inc., *
27 * 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. *
28 ***************************************************************************/
29 #ifdef HAVE_CONFIG_H
30 #include "config.h"
31 #endif
32
33 #include "image.h"
34 #include "target.h"
35 #include <helper/log.h>
36
37
38 /* convert ELF header field to host endianness */
39 #define field16(elf,field)\
40 ((elf->endianness == ELFDATA2LSB)? \
41 le_to_h_u16((uint8_t*)&field):be_to_h_u16((uint8_t*)&field))
42
43 #define field32(elf,field)\
44 ((elf->endianness == ELFDATA2LSB)? \
45 le_to_h_u32((uint8_t*)&field):be_to_h_u32((uint8_t*)&field))
46
47 static int autodetect_image_type(struct image *image, const char *url)
48 {
49 int retval;
50 struct fileio fileio;
51 size_t read_bytes;
52 uint8_t buffer[9];
53
54 /* read the first 4 bytes of image */
55 if ((retval = fileio_open(&fileio, url, FILEIO_READ, FILEIO_BINARY)) != ERROR_OK)
56 {
57 return retval;
58 }
59 retval = fileio_read(&fileio, 9, buffer, &read_bytes);
60
61 if (retval == ERROR_OK)
62 {
63 if (read_bytes != 9)
64 {
65 retval = ERROR_FILEIO_OPERATION_FAILED;
66 }
67 }
68 fileio_close(&fileio);
69
70 if (retval != ERROR_OK)
71 return retval;
72
73 /* check header against known signatures */
74 if (strncmp((char*)buffer,ELFMAG,SELFMAG) == 0)
75 {
76 LOG_DEBUG("ELF image detected.");
77 image->type = IMAGE_ELF;
78 }
79 else if ((buffer[0]==':') /* record start byte */
80 &&(isxdigit(buffer[1]))
81 &&(isxdigit(buffer[2]))
82 &&(isxdigit(buffer[3]))
83 &&(isxdigit(buffer[4]))
84 &&(isxdigit(buffer[5]))
85 &&(isxdigit(buffer[6]))
86 &&(buffer[7]=='0') /* record type : 00 -> 05 */
87 &&(buffer[8]>='0') && (buffer[8]<'6'))
88 {
89 LOG_DEBUG("IHEX image detected.");
90 image->type = IMAGE_IHEX;
91 }
92 else if ((buffer[0] == 'S') /* record start byte */
93 &&(isxdigit(buffer[1]))
94 &&(isxdigit(buffer[2]))
95 &&(isxdigit(buffer[3]))
96 &&(buffer[1] >= '0') && (buffer[1] < '9'))
97 {
98 LOG_DEBUG("S19 image detected.");
99 image->type = IMAGE_SRECORD;
100 }
101 else
102 {
103 image->type = IMAGE_BINARY;
104 }
105
106 return ERROR_OK;
107 }
108
109 static int identify_image_type(struct image *image, const char *type_string, const char *url)
110 {
111 if (type_string)
112 {
113 if (!strcmp(type_string, "bin"))
114 {
115 image->type = IMAGE_BINARY;
116 }
117 else if (!strcmp(type_string, "ihex"))
118 {
119 image->type = IMAGE_IHEX;
120 }
121 else if (!strcmp(type_string, "elf"))
122 {
123 image->type = IMAGE_ELF;
124 }
125 else if (!strcmp(type_string, "mem"))
126 {
127 image->type = IMAGE_MEMORY;
128 }
129 else if (!strcmp(type_string, "s19"))
130 {
131 image->type = IMAGE_SRECORD;
132 }
133 else if (!strcmp(type_string, "build"))
134 {
135 image->type = IMAGE_BUILDER;
136 }
137 else
138 {
139 return ERROR_IMAGE_TYPE_UNKNOWN;
140 }
141 }
142 else
143 {
144 return autodetect_image_type(image, url);
145 }
146
147 return ERROR_OK;
148 }
149
150 static int image_ihex_buffer_complete_inner(struct image *image, char *lpszLine, struct imageection *section)
151 {
152 struct image_ihex *ihex = image->type_private;
153 struct fileio *fileio = &ihex->fileio;
154 uint32_t full_address = 0x0;
155 uint32_t cooked_bytes;
156 int i;
157
158 /* we can't determine the number of sections that we'll have to create ahead of time,
159 * so we locally hold them until parsing is finished */
160
161 ihex->buffer = malloc(fileio->size >> 1);
162 cooked_bytes = 0x0;
163 image->num_sections = 0;
164 section[image->num_sections].private = &ihex->buffer[cooked_bytes];
165 section[image->num_sections].base_address = 0x0;
166 section[image->num_sections].size = 0x0;
167 section[image->num_sections].flags = 0;
168
169 while (fileio_fgets(fileio, 1023, lpszLine) == ERROR_OK)
170 {
171 uint32_t count;
172 uint32_t address;
173 uint32_t record_type;
174 uint32_t checksum;
175 uint8_t cal_checksum = 0;
176 size_t bytes_read = 0;
177
178 if (sscanf(&lpszLine[bytes_read], ":%2" SCNx32 "%4" SCNx32 "%2" SCNx32 , &count, &address, &record_type) != 3)
179 {
180 return ERROR_IMAGE_FORMAT_ERROR;
181 }
182 bytes_read += 9;
183
184 cal_checksum += (uint8_t)count;
185 cal_checksum += (uint8_t)(address >> 8);
186 cal_checksum += (uint8_t)address;
187 cal_checksum += (uint8_t)record_type;
188
189 if (record_type == 0) /* Data Record */
190 {
191 if ((full_address & 0xffff) != address)
192 {
193 /* we encountered a nonconsecutive location, create a new section,
194 * unless the current section has zero size, in which case this specifies
195 * the current section's base address
196 */
197 if (section[image->num_sections].size != 0)
198 {
199 image->num_sections++;
200 if (image->num_sections >= IMAGE_MAX_SECTIONS)
201 {
202 /* too many sections */
203 LOG_ERROR("Too many sections found in IHEX file");
204 return ERROR_IMAGE_FORMAT_ERROR;
205 }
206 section[image->num_sections].size = 0x0;
207 section[image->num_sections].flags = 0;
208 section[image->num_sections].private = &ihex->buffer[cooked_bytes];
209 }
210 section[image->num_sections].base_address =
211 (full_address & 0xffff0000) | address;
212 full_address = (full_address & 0xffff0000) | address;
213 }
214
215 while (count-- > 0)
216 {
217 unsigned value;
218 sscanf(&lpszLine[bytes_read], "%2x", &value);
219 ihex->buffer[cooked_bytes] = (uint8_t)value;
220 cal_checksum += (uint8_t)ihex->buffer[cooked_bytes];
221 bytes_read += 2;
222 cooked_bytes += 1;
223 section[image->num_sections].size += 1;
224 full_address++;
225 }
226 }
227 else if (record_type == 1) /* End of File Record */
228 {
229 /* finish the current section */
230 image->num_sections++;
231
232 /* copy section information */
233 image->sections = malloc(sizeof(struct imageection) * image->num_sections);
234 for (i = 0; i < image->num_sections; i++)
235 {
236 image->sections[i].private = section[i].private;
237 image->sections[i].base_address = section[i].base_address;
238 image->sections[i].size = section[i].size;
239 image->sections[i].flags = section[i].flags;
240 }
241
242 return ERROR_OK;
243 }
244 else if (record_type == 2) /* Linear Address Record */
245 {
246 uint16_t upper_address;
247
248 sscanf(&lpszLine[bytes_read], "%4hx", &upper_address);
249 cal_checksum += (uint8_t)(upper_address >> 8);
250 cal_checksum += (uint8_t)upper_address;
251 bytes_read += 4;
252
253 if ((full_address >> 4) != upper_address)
254 {
255 /* we encountered a nonconsecutive location, create a new section,
256 * unless the current section has zero size, in which case this specifies
257 * the current section's base address
258 */
259 if (section[image->num_sections].size != 0)
260 {
261 image->num_sections++;
262 if (image->num_sections >= IMAGE_MAX_SECTIONS)
263 {
264 /* too many sections */
265 LOG_ERROR("Too many sections found in IHEX file");
266 return ERROR_IMAGE_FORMAT_ERROR;
267 }
268 section[image->num_sections].size = 0x0;
269 section[image->num_sections].flags = 0;
270 section[image->num_sections].private = &ihex->buffer[cooked_bytes];
271 }
272 section[image->num_sections].base_address =
273 (full_address & 0xffff) | (upper_address << 4);
274 full_address = (full_address & 0xffff) | (upper_address << 4);
275 }
276 }
277 else if (record_type == 3) /* Start Segment Address Record */
278 {
279 uint32_t dummy;
280
281 /* "Start Segment Address Record" will not be supported */
282 /* but we must consume it, and do not create an error. */
283 while (count-- > 0)
284 {
285 sscanf(&lpszLine[bytes_read], "%2" SCNx32 , &dummy);
286 cal_checksum += (uint8_t)dummy;
287 bytes_read += 2;
288 }
289 }
290 else if (record_type == 4) /* Extended Linear Address Record */
291 {
292 uint16_t upper_address;
293
294 sscanf(&lpszLine[bytes_read], "%4hx", &upper_address);
295 cal_checksum += (uint8_t)(upper_address >> 8);
296 cal_checksum += (uint8_t)upper_address;
297 bytes_read += 4;
298
299 if ((full_address >> 16) != upper_address)
300 {
301 /* we encountered a nonconsecutive location, create a new section,
302 * unless the current section has zero size, in which case this specifies
303 * the current section's base address
304 */
305 if (section[image->num_sections].size != 0)
306 {
307 image->num_sections++;
308 if (image->num_sections >= IMAGE_MAX_SECTIONS)
309 {
310 /* too many sections */
311 LOG_ERROR("Too many sections found in IHEX file");
312 return ERROR_IMAGE_FORMAT_ERROR;
313 }
314 section[image->num_sections].size = 0x0;
315 section[image->num_sections].flags = 0;
316 section[image->num_sections].private = &ihex->buffer[cooked_bytes];
317 }
318 section[image->num_sections].base_address =
319 (full_address & 0xffff) | (upper_address << 16);
320 full_address = (full_address & 0xffff) | (upper_address << 16);
321 }
322 }
323 else if (record_type == 5) /* Start Linear Address Record */
324 {
325 uint32_t start_address;
326
327 sscanf(&lpszLine[bytes_read], "%8" SCNx32, &start_address);
328 cal_checksum += (uint8_t)(start_address >> 24);
329 cal_checksum += (uint8_t)(start_address >> 16);
330 cal_checksum += (uint8_t)(start_address >> 8);
331 cal_checksum += (uint8_t)start_address;
332 bytes_read += 8;
333
334 image->start_address_set = 1;
335 image->start_address = be_to_h_u32((uint8_t*)&start_address);
336 }
337 else
338 {
339 LOG_ERROR("unhandled IHEX record type: %i", (int)record_type);
340 return ERROR_IMAGE_FORMAT_ERROR;
341 }
342
343 sscanf(&lpszLine[bytes_read], "%2" SCNx32 , &checksum);
344 bytes_read += 2;
345
346 if ((uint8_t)checksum != (uint8_t)(~cal_checksum + 1))
347 {
348 /* checksum failed */
349 LOG_ERROR("incorrect record checksum found in IHEX file");
350 return ERROR_IMAGE_CHECKSUM;
351 }
352 }
353
354 LOG_ERROR("premature end of IHEX file, no end-of-file record found");
355 return ERROR_IMAGE_FORMAT_ERROR;
356 }
357
358 /**
359 * Allocate memory dynamically instead of on the stack. This
360 * is important w/embedded hosts.
361 */
362 static int image_ihex_buffer_complete(struct image *image)
363 {
364 char *lpszLine = malloc(1023);
365 if (lpszLine == NULL)
366 {
367 LOG_ERROR("Out of memory");
368 return ERROR_FAIL;
369 }
370 struct imageection *section = malloc(sizeof(struct imageection) * IMAGE_MAX_SECTIONS);
371 if (section == NULL)
372 {
373 free(lpszLine);
374 LOG_ERROR("Out of memory");
375 return ERROR_FAIL;
376 }
377 int retval;
378
379 retval = image_ihex_buffer_complete_inner(image, lpszLine, section);
380
381 free(section);
382 free(lpszLine);
383
384 return retval;
385 }
386
387 static int image_elf_read_headers(struct image *image)
388 {
389 struct image_elf *elf = image->type_private;
390 size_t read_bytes;
391 uint32_t i,j;
392 int retval;
393
394 elf->header = malloc(sizeof(Elf32_Ehdr));
395
396 if (elf->header == NULL)
397 {
398 LOG_ERROR("insufficient memory to perform operation ");
399 return ERROR_FILEIO_OPERATION_FAILED;
400 }
401
402 if ((retval = fileio_read(&elf->fileio, sizeof(Elf32_Ehdr), (uint8_t*)elf->header, &read_bytes)) != ERROR_OK)
403 {
404 LOG_ERROR("cannot read ELF file header, read failed");
405 return ERROR_FILEIO_OPERATION_FAILED;
406 }
407 if (read_bytes != sizeof(Elf32_Ehdr))
408 {
409 LOG_ERROR("cannot read ELF file header, only partially read");
410 return ERROR_FILEIO_OPERATION_FAILED;
411 }
412
413 if (strncmp((char*)elf->header->e_ident,ELFMAG,SELFMAG) != 0)
414 {
415 LOG_ERROR("invalid ELF file, bad magic number");
416 return ERROR_IMAGE_FORMAT_ERROR;
417 }
418 if (elf->header->e_ident[EI_CLASS]!=ELFCLASS32)
419 {
420 LOG_ERROR("invalid ELF file, only 32bits files are supported");
421 return ERROR_IMAGE_FORMAT_ERROR;
422 }
423
424 elf->endianness = elf->header->e_ident[EI_DATA];
425 if ((elf->endianness != ELFDATA2LSB)
426 &&(elf->endianness != ELFDATA2MSB))
427 {
428 LOG_ERROR("invalid ELF file, unknown endianess setting");
429 return ERROR_IMAGE_FORMAT_ERROR;
430 }
431
432 elf->segment_count = field16(elf,elf->header->e_phnum);
433 if (elf->segment_count == 0)
434 {
435 LOG_ERROR("invalid ELF file, no program headers");
436 return ERROR_IMAGE_FORMAT_ERROR;
437 }
438
439 if ((retval = fileio_seek(&elf->fileio, field32(elf,elf->header->e_phoff))) != ERROR_OK)
440 {
441 LOG_ERROR("cannot seek to ELF program header table, read failed");
442 return retval;
443 }
444
445 elf->segments = malloc(elf->segment_count*sizeof(Elf32_Phdr));
446 if (elf->segments == NULL)
447 {
448 LOG_ERROR("insufficient memory to perform operation ");
449 return ERROR_FILEIO_OPERATION_FAILED;
450 }
451
452 if ((retval = fileio_read(&elf->fileio, elf->segment_count*sizeof(Elf32_Phdr), (uint8_t*)elf->segments, &read_bytes)) != ERROR_OK)
453 {
454 LOG_ERROR("cannot read ELF segment headers, read failed");
455 return retval;
456 }
457 if (read_bytes != elf->segment_count*sizeof(Elf32_Phdr))
458 {
459 LOG_ERROR("cannot read ELF segment headers, only partially read");
460 return ERROR_FILEIO_OPERATION_FAILED;
461 }
462
463 /* count useful segments (loadable), ignore BSS section */
464 image->num_sections = 0;
465 for (i = 0;i < elf->segment_count;i++)
466 if ((field32(elf, elf->segments[i].p_type) == PT_LOAD) && (field32(elf, elf->segments[i].p_filesz) != 0))
467 image->num_sections++;
468 /* alloc and fill sections array with loadable segments */
469 image->sections = malloc(image->num_sections * sizeof(struct imageection));
470 for (i = 0,j = 0;i < elf->segment_count;i++)
471 {
472 if ((field32(elf, elf->segments[i].p_type) == PT_LOAD) && (field32(elf, elf->segments[i].p_filesz) != 0))
473 {
474 image->sections[j].size = field32(elf,elf->segments[i].p_filesz);
475 image->sections[j].base_address = field32(elf,elf->segments[i].p_paddr);
476 image->sections[j].private = &elf->segments[i];
477 image->sections[j].flags = field32(elf,elf->segments[i].p_flags);
478 j++;
479 }
480 }
481
482 image->start_address_set = 1;
483 image->start_address = field32(elf,elf->header->e_entry);
484
485 return ERROR_OK;
486 }
487
488 static int image_elf_read_section(struct image *image, int section, uint32_t offset, uint32_t size, uint8_t *buffer, size_t *size_read)
489 {
490 struct image_elf *elf = image->type_private;
491 Elf32_Phdr *segment = (Elf32_Phdr *)image->sections[section].private;
492 size_t read_size,really_read;
493 int retval;
494
495 *size_read = 0;
496
497 LOG_DEBUG("load segment %d at 0x%" PRIx32 " (sz = 0x%" PRIx32 ")",section,offset,size);
498
499 /* read initialized data in current segment if any */
500 if (offset < field32(elf,segment->p_filesz))
501 {
502 /* maximal size present in file for the current segment */
503 read_size = MIN(size, field32(elf,segment->p_filesz)-offset);
504 LOG_DEBUG("read elf: size = 0x%zu at 0x%" PRIx32 "", read_size,
505 field32(elf,segment->p_offset) + offset);
506 /* read initialized area of the segment */
507 if ((retval = fileio_seek(&elf->fileio, field32(elf,segment->p_offset) + offset)) != ERROR_OK)
508 {
509 LOG_ERROR("cannot find ELF segment content, seek failed");
510 return retval;
511 }
512 if ((retval = fileio_read(&elf->fileio, read_size, buffer, &really_read)) != ERROR_OK)
513 {
514 LOG_ERROR("cannot read ELF segment content, read failed");
515 return retval;
516 }
517 buffer += read_size;
518 size -= read_size;
519 offset += read_size;
520 *size_read += read_size;
521 /* need more data ? */
522 if (!size)
523 return ERROR_OK;
524 }
525
526 return ERROR_OK;
527 }
528
529 static int image_mot_buffer_complete_inner(struct image *image, char *lpszLine, struct imageection *section)
530 {
531 struct image_mot *mot = image->type_private;
532 struct fileio *fileio = &mot->fileio;
533 uint32_t full_address = 0x0;
534 uint32_t cooked_bytes;
535 int i;
536
537 /* we can't determine the number of sections that we'll have to create ahead of time,
538 * so we locally hold them until parsing is finished */
539
540 mot->buffer = malloc(fileio->size >> 1);
541 cooked_bytes = 0x0;
542 image->num_sections = 0;
543 section[image->num_sections].private = &mot->buffer[cooked_bytes];
544 section[image->num_sections].base_address = 0x0;
545 section[image->num_sections].size = 0x0;
546 section[image->num_sections].flags = 0;
547
548 while (fileio_fgets(fileio, 1023, lpszLine) == ERROR_OK)
549 {
550 uint32_t count;
551 uint32_t address;
552 uint32_t record_type;
553 uint32_t checksum;
554 uint8_t cal_checksum = 0;
555 uint32_t bytes_read = 0;
556
557 /* get record type and record length */
558 if (sscanf(&lpszLine[bytes_read], "S%1" SCNx32 "%2" SCNx32 , &record_type, &count) != 2)
559 {
560 return ERROR_IMAGE_FORMAT_ERROR;
561 }
562
563 bytes_read += 4;
564 cal_checksum += (uint8_t)count;
565
566 /* skip checksum byte */
567 count -=1;
568
569 if (record_type == 0)
570 {
571 /* S0 - starting record (optional) */
572 int iValue;
573
574 while (count-- > 0) {
575 sscanf(&lpszLine[bytes_read], "%2x", &iValue);
576 cal_checksum += (uint8_t)iValue;
577 bytes_read += 2;
578 }
579 }
580 else if (record_type >= 1 && record_type <= 3)
581 {
582 switch (record_type)
583 {
584 case 1:
585 /* S1 - 16 bit address data record */
586 sscanf(&lpszLine[bytes_read], "%4" SCNx32, &address);
587 cal_checksum += (uint8_t)(address >> 8);
588 cal_checksum += (uint8_t)address;
589 bytes_read += 4;
590 count -=2;
591 break;
592
593 case 2:
594 /* S2 - 24 bit address data record */
595 sscanf(&lpszLine[bytes_read], "%6" SCNx32 , &address);
596 cal_checksum += (uint8_t)(address >> 16);
597 cal_checksum += (uint8_t)(address >> 8);
598 cal_checksum += (uint8_t)address;
599 bytes_read += 6;
600 count -=3;
601 break;
602
603 case 3:
604 /* S3 - 32 bit address data record */
605 sscanf(&lpszLine[bytes_read], "%8" SCNx32 , &address);
606 cal_checksum += (uint8_t)(address >> 24);
607 cal_checksum += (uint8_t)(address >> 16);
608 cal_checksum += (uint8_t)(address >> 8);
609 cal_checksum += (uint8_t)address;
610 bytes_read += 8;
611 count -=4;
612 break;
613
614 }
615
616 if (full_address != address)
617 {
618 /* we encountered a nonconsecutive location, create a new section,
619 * unless the current section has zero size, in which case this specifies
620 * the current section's base address
621 */
622 if (section[image->num_sections].size != 0)
623 {
624 image->num_sections++;
625 section[image->num_sections].size = 0x0;
626 section[image->num_sections].flags = 0;
627 section[image->num_sections].private = &mot->buffer[cooked_bytes];
628 }
629 section[image->num_sections].base_address = address;
630 full_address = address;
631 }
632
633 while (count-- > 0)
634 {
635 unsigned value;
636 sscanf(&lpszLine[bytes_read], "%2x", &value);
637 mot->buffer[cooked_bytes] = (uint8_t)value;
638 cal_checksum += (uint8_t)mot->buffer[cooked_bytes];
639 bytes_read += 2;
640 cooked_bytes += 1;
641 section[image->num_sections].size += 1;
642 full_address++;
643 }
644 }
645 else if (record_type == 5)
646 {
647 /* S5 is the data count record, we ignore it */
648 uint32_t dummy;
649
650 while (count-- > 0)
651 {
652 sscanf(&lpszLine[bytes_read], "%2" SCNx32 , &dummy);
653 cal_checksum += (uint8_t)dummy;
654 bytes_read += 2;
655 }
656 }
657 else if (record_type >= 7 && record_type <= 9)
658 {
659 /* S7, S8, S9 - ending records for 32, 24 and 16bit */
660 image->num_sections++;
661
662 /* copy section information */
663 image->sections = malloc(sizeof(struct imageection) * image->num_sections);
664 for (i = 0; i < image->num_sections; i++)
665 {
666 image->sections[i].private = section[i].private;
667 image->sections[i].base_address = section[i].base_address;
668 image->sections[i].size = section[i].size;
669 image->sections[i].flags = section[i].flags;
670 }
671
672 return ERROR_OK;
673 }
674 else
675 {
676 LOG_ERROR("unhandled S19 record type: %i", (int)(record_type));
677 return ERROR_IMAGE_FORMAT_ERROR;
678 }
679
680 /* account for checksum, will always be 0xFF */
681 sscanf(&lpszLine[bytes_read], "%2" SCNx32 , &checksum);
682 cal_checksum += (uint8_t)checksum;
683 bytes_read += 2;
684
685 if (cal_checksum != 0xFF)
686 {
687 /* checksum failed */
688 LOG_ERROR("incorrect record checksum found in S19 file");
689 return ERROR_IMAGE_CHECKSUM;
690 }
691 }
692
693 LOG_ERROR("premature end of S19 file, no end-of-file record found");
694 return ERROR_IMAGE_FORMAT_ERROR;
695 }
696
697 /**
698 * Allocate memory dynamically instead of on the stack. This
699 * is important w/embedded hosts.
700 */
701 static int image_mot_buffer_complete(struct image *image)
702 {
703 char *lpszLine = malloc(1023);
704 if (lpszLine == NULL)
705 {
706 LOG_ERROR("Out of memory");
707 return ERROR_FAIL;
708 }
709 struct imageection *section = malloc(sizeof(struct imageection) * IMAGE_MAX_SECTIONS);
710 if (section == NULL)
711 {
712 free(lpszLine);
713 LOG_ERROR("Out of memory");
714 return ERROR_FAIL;
715 }
716 int retval;
717
718 retval = image_mot_buffer_complete_inner(image, lpszLine, section);
719
720 free(section);
721 free(lpszLine);
722
723 return retval;
724 }
725
726
727 int image_open(struct image *image, const char *url, const char *type_string)
728 {
729 int retval = ERROR_OK;
730
731 if ((retval = identify_image_type(image, type_string, url)) != ERROR_OK)
732 {
733 return retval;
734 }
735
736 if (image->type == IMAGE_BINARY)
737 {
738 struct image_binary *image_binary;
739
740 image_binary = image->type_private = malloc(sizeof(struct image_binary));
741
742 if ((retval = fileio_open(&image_binary->fileio, url, FILEIO_READ, FILEIO_BINARY)) != ERROR_OK)
743 {
744 return retval;
745 }
746
747 image->num_sections = 1;
748 image->sections = malloc(sizeof(struct imageection));
749 image->sections[0].base_address = 0x0;
750 image->sections[0].size = image_binary->fileio.size;
751 image->sections[0].flags = 0;
752 }
753 else if (image->type == IMAGE_IHEX)
754 {
755 struct image_ihex *image_ihex;
756
757 image_ihex = image->type_private = malloc(sizeof(struct image_ihex));
758
759 if ((retval = fileio_open(&image_ihex->fileio, url, FILEIO_READ, FILEIO_TEXT)) != ERROR_OK)
760 {
761 return retval;
762 }
763
764 if ((retval = image_ihex_buffer_complete(image)) != ERROR_OK)
765 {
766 LOG_ERROR("failed buffering IHEX image, check daemon output for additional information");
767 fileio_close(&image_ihex->fileio);
768 return retval;
769 }
770 }
771 else if (image->type == IMAGE_ELF)
772 {
773 struct image_elf *image_elf;
774
775 image_elf = image->type_private = malloc(sizeof(struct image_elf));
776
777 if ((retval = fileio_open(&image_elf->fileio, url, FILEIO_READ, FILEIO_BINARY)) != ERROR_OK)
778 {
779 return retval;
780 }
781
782 if ((retval = image_elf_read_headers(image)) != ERROR_OK)
783 {
784 fileio_close(&image_elf->fileio);
785 return retval;
786 }
787 }
788 else if (image->type == IMAGE_MEMORY)
789 {
790 struct target *target = get_target(url);
791
792 if (target == NULL)
793 {
794 LOG_ERROR("target '%s' not defined", url);
795 return ERROR_FAIL;
796 }
797
798 struct image_memory *image_memory;
799
800 image->num_sections = 1;
801 image->sections = malloc(sizeof(struct imageection));
802 image->sections[0].base_address = 0x0;
803 image->sections[0].size = 0xffffffff;
804 image->sections[0].flags = 0;
805
806 image_memory = image->type_private = malloc(sizeof(struct image_memory));
807
808 image_memory->target = target;
809 image_memory->cache = NULL;
810 image_memory->cache_address = 0x0;
811 }
812 else if (image->type == IMAGE_SRECORD)
813 {
814 struct image_mot *image_mot;
815
816 image_mot = image->type_private = malloc(sizeof(struct image_mot));
817
818 if ((retval = fileio_open(&image_mot->fileio, url, FILEIO_READ, FILEIO_TEXT)) != ERROR_OK)
819 {
820 return retval;
821 }
822
823 if ((retval = image_mot_buffer_complete(image)) != ERROR_OK)
824 {
825 LOG_ERROR("failed buffering S19 image, check daemon output for additional information");
826 fileio_close(&image_mot->fileio);
827 return retval;
828 }
829 }
830 else if (image->type == IMAGE_BUILDER)
831 {
832 image->num_sections = 0;
833 image->sections = NULL;
834 image->type_private = NULL;
835 }
836
837 if (image->base_address_set)
838 {
839 /* relocate */
840 int section;
841 for (section = 0; section < image->num_sections; section++)
842 {
843 image->sections[section].base_address += image->base_address;
844 }
845 /* we're done relocating. The two statements below are mainly
846 * for documenation purposes: stop anyone from empirically
847 * thinking they should use these values henceforth. */
848 image->base_address = 0;
849 image->base_address_set = 0;
850 }
851
852 return retval;
853 };
854
855 int image_read_section(struct image *image, int section, uint32_t offset, uint32_t size, uint8_t *buffer, size_t *size_read)
856 {
857 int retval;
858
859 /* don't read past the end of a section */
860 if (offset + size > image->sections[section].size)
861 {
862 LOG_DEBUG("read past end of section: 0x%8.8" PRIx32 " + 0x%8.8" PRIx32 " > 0x%8.8" PRIx32 "",
863 offset, size, image->sections[section].size);
864 return ERROR_INVALID_ARGUMENTS;
865 }
866
867 if (image->type == IMAGE_BINARY)
868 {
869 struct image_binary *image_binary = image->type_private;
870
871 /* only one section in a plain binary */
872 if (section != 0)
873 return ERROR_INVALID_ARGUMENTS;
874
875 /* seek to offset */
876 if ((retval = fileio_seek(&image_binary->fileio, offset)) != ERROR_OK)
877 {
878 return retval;
879 }
880
881 /* return requested bytes */
882 if ((retval = fileio_read(&image_binary->fileio, size, buffer, size_read)) != ERROR_OK)
883 {
884 return retval;
885 }
886 }
887 else if (image->type == IMAGE_IHEX)
888 {
889 memcpy(buffer, (uint8_t*)image->sections[section].private + offset, size);
890 *size_read = size;
891
892 return ERROR_OK;
893 }
894 else if (image->type == IMAGE_ELF)
895 {
896 return image_elf_read_section(image, section, offset, size, buffer, size_read);
897 }
898 else if (image->type == IMAGE_MEMORY)
899 {
900 struct image_memory *image_memory = image->type_private;
901 uint32_t address = image->sections[section].base_address + offset;
902
903 *size_read = 0;
904
905 while ((size - *size_read) > 0)
906 {
907 uint32_t size_in_cache;
908
909 if (!image_memory->cache
910 || (address < image_memory->cache_address)
911 || (address >= (image_memory->cache_address + IMAGE_MEMORY_CACHE_SIZE)))
912 {
913 if (!image_memory->cache)
914 image_memory->cache = malloc(IMAGE_MEMORY_CACHE_SIZE);
915
916 if (target_read_buffer(image_memory->target, address & ~(IMAGE_MEMORY_CACHE_SIZE - 1),
917 IMAGE_MEMORY_CACHE_SIZE, image_memory->cache) != ERROR_OK)
918 {
919 free(image_memory->cache);
920 image_memory->cache = NULL;
921 return ERROR_IMAGE_TEMPORARILY_UNAVAILABLE;
922 }
923 image_memory->cache_address = address & ~(IMAGE_MEMORY_CACHE_SIZE - 1);
924 }
925
926 size_in_cache = (image_memory->cache_address + IMAGE_MEMORY_CACHE_SIZE) - address;
927
928 memcpy(buffer + *size_read,
929 image_memory->cache + (address - image_memory->cache_address),
930 (size_in_cache > size) ? size : size_in_cache
931 );
932
933 *size_read += (size_in_cache > size) ? size : size_in_cache;
934 address += (size_in_cache > size) ? size : size_in_cache;
935 }
936 }
937 else if (image->type == IMAGE_SRECORD)
938 {
939 memcpy(buffer, (uint8_t*)image->sections[section].private + offset, size);
940 *size_read = size;
941
942 return ERROR_OK;
943 }
944 else if (image->type == IMAGE_BUILDER)
945 {
946 memcpy(buffer, (uint8_t*)image->sections[section].private + offset, size);
947 *size_read = size;
948
949 return ERROR_OK;
950 }
951
952 return ERROR_OK;
953 }
954
955 int image_add_section(struct image *image, uint32_t base, uint32_t size, int flags, uint8_t *data)
956 {
957 struct imageection *section;
958
959 /* only image builder supports adding sections */
960 if (image->type != IMAGE_BUILDER)
961 return ERROR_INVALID_ARGUMENTS;
962
963 /* see if there's a previous section */
964 if (image->num_sections)
965 {
966 section = &image->sections[image->num_sections - 1];
967
968 /* see if it's enough to extend the last section,
969 * adding data to previous sections or merging is not supported */
970 if (((section->base_address + section->size) == base) && (section->flags == flags))
971 {
972 section->private = realloc(section->private, section->size + size);
973 memcpy((uint8_t*)section->private + section->size, data, size);
974 section->size += size;
975 return ERROR_OK;
976 }
977 }
978
979 /* allocate new section */
980 image->num_sections++;
981 image->sections = realloc(image->sections, sizeof(struct imageection) * image->num_sections);
982 section = &image->sections[image->num_sections - 1];
983 section->base_address = base;
984 section->size = size;
985 section->flags = flags;
986 section->private = malloc(sizeof(uint8_t) * size);
987 memcpy((uint8_t*)section->private, data, size);
988
989 return ERROR_OK;
990 }
991
992 void image_close(struct image *image)
993 {
994 if (image->type == IMAGE_BINARY)
995 {
996 struct image_binary *image_binary = image->type_private;
997
998 fileio_close(&image_binary->fileio);
999 }
1000 else if (image->type == IMAGE_IHEX)
1001 {
1002 struct image_ihex *image_ihex = image->type_private;
1003
1004 fileio_close(&image_ihex->fileio);
1005
1006 if (image_ihex->buffer)
1007 {
1008 free(image_ihex->buffer);
1009 image_ihex->buffer = NULL;
1010 }
1011 }
1012 else if (image->type == IMAGE_ELF)
1013 {
1014 struct image_elf *image_elf = image->type_private;
1015
1016 fileio_close(&image_elf->fileio);
1017
1018 if (image_elf->header)
1019 {
1020 free(image_elf->header);
1021 image_elf->header = NULL;
1022 }
1023
1024 if (image_elf->segments)
1025 {
1026 free(image_elf->segments);
1027 image_elf->segments = NULL;
1028 }
1029 }
1030 else if (image->type == IMAGE_MEMORY)
1031 {
1032 struct image_memory *image_memory = image->type_private;
1033
1034 if (image_memory->cache)
1035 {
1036 free(image_memory->cache);
1037 image_memory->cache = NULL;
1038 }
1039 }
1040 else if (image->type == IMAGE_SRECORD)
1041 {
1042 struct image_mot *image_mot = image->type_private;
1043
1044 fileio_close(&image_mot->fileio);
1045
1046 if (image_mot->buffer)
1047 {
1048 free(image_mot->buffer);
1049 image_mot->buffer = NULL;
1050 }
1051 }
1052 else if (image->type == IMAGE_BUILDER)
1053 {
1054 int i;
1055
1056 for (i = 0; i < image->num_sections; i++)
1057 {
1058 free(image->sections[i].private);
1059 image->sections[i].private = NULL;
1060 }
1061 }
1062
1063 if (image->type_private)
1064 {
1065 free(image->type_private);
1066 image->type_private = NULL;
1067 }
1068
1069 if (image->sections)
1070 {
1071 free(image->sections);
1072 image->sections = NULL;
1073 }
1074 }
1075
1076 int image_calculate_checksum(uint8_t* buffer, uint32_t nbytes, uint32_t* checksum)
1077 {
1078 uint32_t crc = 0xffffffff;
1079 LOG_DEBUG("Calculating checksum");
1080
1081 static uint32_t crc32_table[256];
1082
1083 static bool first_init = false;
1084 if (!first_init)
1085 {
1086 /* Initialize the CRC table and the decoding table. */
1087 int i, j;
1088 unsigned int c;
1089 for (i = 0; i < 256; i++)
1090 {
1091 /* as per gdb */
1092 for (c = i << 24, j = 8; j > 0; --j)
1093 c = c & 0x80000000 ? (c << 1) ^ 0x04c11db7 : (c << 1);
1094 crc32_table[i] = c;
1095 }
1096
1097 first_init = true;
1098 }
1099
1100 while (nbytes > 0)
1101 {
1102 int run = nbytes;
1103 if (run > 32768)
1104 {
1105 run = 32768;
1106 }
1107 nbytes -= run;
1108 while (run--)
1109 {
1110 /* as per gdb */
1111 crc = (crc << 8) ^ crc32_table[((crc >> 24) ^ *buffer++) & 255];
1112 }
1113 keep_alive();
1114 }
1115
1116 LOG_DEBUG("Calculating checksum done");
1117
1118 *checksum = crc;
1119 return ERROR_OK;
1120 }
Marex's Cortex A8 development branch