/*************************************************************************** * Copyright (C) 2007 by Dominic Rath * * Dominic.Rath@gmx.de * * * * Copyright (C) 2007,2008 Øyvind Harboe * * oyvind.harboe@zylin.com * * * * Copyright (C) 2008 by Spencer Oliver * * spen@spen-soft.co.uk * * * * This program is free software; you can redistribute it and/or modify * * it under the terms of the GNU General Public License as published by * * the Free Software Foundation; either version 2 of the License, or * * (at your option) any later version. * * * * This program is distributed in the hope that it will be useful, * * but WITHOUT ANY WARRANTY; without even the implied warranty of * * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * * GNU General Public License for more details. * * * * You should have received a copy of the GNU General Public License * * along with this program; if not, write to the * * Free Software Foundation, Inc., * * 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. * ***************************************************************************/ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include #include #ifdef HAVE_ELF_H #include #endif #include "image.h" #include "types.h" #include "replacements.h" #include "log.h" #include "fileio.h" #include "target.h" /* convert ELF header field to host endianness */ #define field16(elf,field)\ ((elf->endianness==ELFDATA2LSB)? \ le_to_h_u16((u8*)&field):be_to_h_u16((u8*)&field)) #define field32(elf,field)\ ((elf->endianness==ELFDATA2LSB)? \ le_to_h_u32((u8*)&field):be_to_h_u32((u8*)&field)) static int autodetect_image_type(image_t *image, char *url) { int retval; fileio_t fileio; u32 read_bytes; u8 buffer[9]; /* read the first 4 bytes of image */ if ((retval = fileio_open(&fileio, url, FILEIO_READ, FILEIO_BINARY)) != ERROR_OK) { return retval; } retval = fileio_read(&fileio, 9, buffer, &read_bytes); if (retval==ERROR_OK) { if (read_bytes != 9) { retval=ERROR_FILEIO_OPERATION_FAILED; } } fileio_close(&fileio); if (retval!=ERROR_OK) return retval; /* check header against known signatures */ if (strncmp((char*)buffer,ELFMAG,SELFMAG)==0) { LOG_DEBUG("ELF image detected."); image->type = IMAGE_ELF; } else if ((buffer[0]==':') /* record start byte */ &&(isxdigit(buffer[1])) &&(isxdigit(buffer[2])) &&(isxdigit(buffer[3])) &&(isxdigit(buffer[4])) &&(isxdigit(buffer[5])) &&(isxdigit(buffer[6])) &&(buffer[7]=='0') /* record type : 00 -> 05 */ &&(buffer[8]>='0')&&(buffer[8]<'6')) { LOG_DEBUG("IHEX image detected."); image->type = IMAGE_IHEX; } else if ((buffer[0] == 'S') /* record start byte */ &&(isxdigit(buffer[1])) &&(isxdigit(buffer[2])) &&(isxdigit(buffer[3])) &&(buffer[1] >= '0') && (buffer[1] < '9')) { LOG_DEBUG("S19 image detected."); image->type = IMAGE_SRECORD; } else { image->type = IMAGE_BINARY; } return ERROR_OK; } int identify_image_type(image_t *image, char *type_string, char *url) { if (type_string) { if (!strcmp(type_string, "bin")) { image->type = IMAGE_BINARY; } else if (!strcmp(type_string, "ihex")) { image->type = IMAGE_IHEX; } else if (!strcmp(type_string, "elf")) { image->type = IMAGE_ELF; } else if (!strcmp(type_string, "mem")) { image->type = IMAGE_MEMORY; } else if (!strcmp(type_string, "s19")) { image->type = IMAGE_SRECORD; } else if (!strcmp(type_string, "build")) { image->type = IMAGE_BUILDER; } else { return ERROR_IMAGE_TYPE_UNKNOWN; } } else { return autodetect_image_type(image, url); } return ERROR_OK; } int image_ihex_buffer_complete(image_t *image) { image_ihex_t *ihex = image->type_private; fileio_t *fileio = &ihex->fileio; u32 full_address = 0x0; u32 cooked_bytes; int i; char lpszLine[1023]; /* we can't determine the number of sections that we'll have to create ahead of time, * so we locally hold them until parsing is finished */ image_section_t section[IMAGE_MAX_SECTIONS]; ihex->buffer = malloc(fileio->size >> 1); cooked_bytes = 0x0; image->num_sections = 0; section[image->num_sections].private = &ihex->buffer[cooked_bytes]; section[image->num_sections].base_address = 0x0; section[image->num_sections].size = 0x0; section[image->num_sections].flags = 0; while (fileio_fgets(fileio, 1023, lpszLine) == ERROR_OK) { u32 count; u32 address; u32 record_type; u32 checksum; u8 cal_checksum = 0; u32 bytes_read = 0; if (sscanf(&lpszLine[bytes_read], ":%2x%4x%2x", &count, &address, &record_type) != 3) { return ERROR_IMAGE_FORMAT_ERROR; } bytes_read += 9; cal_checksum += (u8)count; cal_checksum += (u8)(address >> 8); cal_checksum += (u8)address; cal_checksum += (u8)record_type; if (record_type == 0) /* Data Record */ { if ((full_address & 0xffff) != address) { /* we encountered a nonconsecutive location, create a new section, * unless the current section has zero size, in which case this specifies * the current section's base address */ if (section[image->num_sections].size != 0) { image->num_sections++; section[image->num_sections].size = 0x0; section[image->num_sections].flags = 0; section[image->num_sections].private = &ihex->buffer[cooked_bytes]; } section[image->num_sections].base_address = (full_address & 0xffff0000) | address; full_address = (full_address & 0xffff0000) | address; } while (count-- > 0) { sscanf(&lpszLine[bytes_read], "%2x", (u32*)&ihex->buffer[cooked_bytes]); cal_checksum += (u8)ihex->buffer[cooked_bytes]; bytes_read += 2; cooked_bytes += 1; section[image->num_sections].size += 1; full_address++; } } else if (record_type == 1) /* End of File Record */ { /* finish the current section */ image->num_sections++; /* copy section information */ image->sections = malloc(sizeof(image_section_t) * image->num_sections); for (i = 0; i < image->num_sections; i++) { image->sections[i].private = section[i].private; image->sections[i].base_address = section[i].base_address; image->sections[i].size = section[i].size; image->sections[i].flags = section[i].flags; } return ERROR_OK; } else if (record_type == 2) /* Linear Address Record */ { u16 upper_address; sscanf(&lpszLine[bytes_read], "%4hx", &upper_address); cal_checksum += (u8)(upper_address >> 8); cal_checksum += (u8)upper_address; bytes_read += 4; if ((full_address >> 4) != upper_address) { /* we encountered a nonconsecutive location, create a new section, * unless the current section has zero size, in which case this specifies * the current section's base address */ if (section[image->num_sections].size != 0) { image->num_sections++; section[image->num_sections].size = 0x0; section[image->num_sections].flags = 0; section[image->num_sections].private = &ihex->buffer[cooked_bytes]; } section[image->num_sections].base_address = (full_address & 0xffff) | (upper_address << 4); full_address = (full_address & 0xffff) | (upper_address << 4); } } else if (record_type == 3) /* Start Segment Address Record */ { u32 dummy; /* "Start Segment Address Record" will not be supported */ /* but we must consume it, and do not create an error. */ while (count-- > 0) { sscanf(&lpszLine[bytes_read], "%2x", &dummy); cal_checksum += (u8)dummy; bytes_read += 2; } } else if (record_type == 4) /* Extended Linear Address Record */ { u16 upper_address; sscanf(&lpszLine[bytes_read], "%4hx", &upper_address); cal_checksum += (u8)(upper_address >> 8); cal_checksum += (u8)upper_address; bytes_read += 4; if ((full_address >> 16) != upper_address) { /* we encountered a nonconsecutive location, create a new section, * unless the current section has zero size, in which case this specifies * the current section's base address */ if (section[image->num_sections].size != 0) { image->num_sections++; section[image->num_sections].size = 0x0; section[image->num_sections].flags = 0; section[image->num_sections].private = &ihex->buffer[cooked_bytes]; } section[image->num_sections].base_address = (full_address & 0xffff) | (upper_address << 16); full_address = (full_address & 0xffff) | (upper_address << 16); } } else if (record_type == 5) /* Start Linear Address Record */ { u32 start_address; sscanf(&lpszLine[bytes_read], "%8x", &start_address); cal_checksum += (u8)(start_address >> 24); cal_checksum += (u8)(start_address >> 16); cal_checksum += (u8)(start_address >> 8); cal_checksum += (u8)start_address; bytes_read += 8; image->start_address_set = 1; image->start_address = be_to_h_u32((u8*)&start_address); } else { LOG_ERROR("unhandled IHEX record type: %i", record_type); return ERROR_IMAGE_FORMAT_ERROR; } sscanf(&lpszLine[bytes_read], "%2x", &checksum); bytes_read += 2; if ((u8)checksum != (u8)(~cal_checksum + 1)) { /* checksum failed */ LOG_ERROR("incorrect record checksum found in IHEX file"); return ERROR_IMAGE_CHECKSUM; } } LOG_ERROR("premature end of IHEX file, no end-of-file record found"); return ERROR_IMAGE_FORMAT_ERROR; } int image_elf_read_headers(image_t *image) { image_elf_t *elf = image->type_private; u32 read_bytes; u32 i,j; int retval; elf->header = malloc(sizeof(Elf32_Ehdr)); if(elf->header == NULL) { LOG_ERROR("insufficient memory to perform operation "); return ERROR_FILEIO_OPERATION_FAILED; } if ((retval = fileio_read(&elf->fileio, sizeof(Elf32_Ehdr), (u8*)elf->header, &read_bytes)) != ERROR_OK) { LOG_ERROR("cannot read ELF file header, read failed"); return ERROR_FILEIO_OPERATION_FAILED; } if (read_bytes != sizeof(Elf32_Ehdr)) { LOG_ERROR("cannot read ELF file header, only partially read"); return ERROR_FILEIO_OPERATION_FAILED; } if (strncmp((char*)elf->header->e_ident,ELFMAG,SELFMAG)!=0) { LOG_ERROR("invalid ELF file, bad magic number"); return ERROR_IMAGE_FORMAT_ERROR; } if (elf->header->e_ident[EI_CLASS]!=ELFCLASS32) { LOG_ERROR("invalid ELF file, only 32bits files are supported"); return ERROR_IMAGE_FORMAT_ERROR; } elf->endianness = elf->header->e_ident[EI_DATA]; if ((elf->endianness!=ELFDATA2LSB) &&(elf->endianness!=ELFDATA2MSB)) { LOG_ERROR("invalid ELF file, unknown endianess setting"); return ERROR_IMAGE_FORMAT_ERROR; } elf->segment_count = field16(elf,elf->header->e_phnum); if (elf->segment_count==0) { LOG_ERROR("invalid ELF file, no program headers"); return ERROR_IMAGE_FORMAT_ERROR; } if ((retval = fileio_seek(&elf->fileio, field32(elf,elf->header->e_phoff))) != ERROR_OK) { LOG_ERROR("cannot seek to ELF program header table, read failed"); return retval; } elf->segments = malloc(elf->segment_count*sizeof(Elf32_Phdr)); if(elf->segments == NULL) { LOG_ERROR("insufficient memory to perform operation "); return ERROR_FILEIO_OPERATION_FAILED; } if ((retval = fileio_read(&elf->fileio, elf->segment_count*sizeof(Elf32_Phdr), (u8*)elf->segments, &read_bytes)) != ERROR_OK) { LOG_ERROR("cannot read ELF segment headers, read failed"); return retval; } if (read_bytes != elf->segment_count*sizeof(Elf32_Phdr)) { LOG_ERROR("cannot read ELF segment headers, only partially read"); return ERROR_FILEIO_OPERATION_FAILED; } /* count useful segments (loadable), ignore BSS section */ image->num_sections = 0; for (i=0;isegment_count;i++) if ((field32(elf, elf->segments[i].p_type) == PT_LOAD) && (field32(elf, elf->segments[i].p_filesz) != 0)) image->num_sections++; /* alloc and fill sections array with loadable segments */ image->sections = malloc(image->num_sections * sizeof(image_section_t)); for (i=0,j=0;isegment_count;i++) { if ((field32(elf, elf->segments[i].p_type) == PT_LOAD) && (field32(elf, elf->segments[i].p_filesz) != 0)) { image->sections[j].size = field32(elf,elf->segments[i].p_filesz); image->sections[j].base_address = field32(elf,elf->segments[i].p_paddr); image->sections[j].private = &elf->segments[i]; image->sections[j].flags = field32(elf,elf->segments[i].p_flags); j++; } } image->start_address_set = 1; image->start_address = field32(elf,elf->header->e_entry); return ERROR_OK; } int image_elf_read_section(image_t *image, int section, u32 offset, u32 size, u8 *buffer, u32 *size_read) { image_elf_t *elf = image->type_private; Elf32_Phdr *segment = (Elf32_Phdr *)image->sections[section].private; u32 read_size,really_read; int retval; *size_read = 0; LOG_DEBUG("load segment %d at 0x%x (sz=0x%x)",section,offset,size); /* read initialized data in current segment if any */ if (offsetp_filesz)) { /* maximal size present in file for the current segment */ read_size = MIN(size, field32(elf,segment->p_filesz)-offset); LOG_DEBUG("read elf: size = 0x%x at 0x%x",read_size, field32(elf,segment->p_offset)+offset); /* read initialized area of the segment */ if ((retval = fileio_seek(&elf->fileio, field32(elf,segment->p_offset)+offset)) != ERROR_OK) { LOG_ERROR("cannot find ELF segment content, seek failed"); return retval; } if ((retval = fileio_read(&elf->fileio, read_size, buffer, &really_read)) != ERROR_OK) { LOG_ERROR("cannot read ELF segment content, read failed"); return retval; } buffer += read_size; size -= read_size; offset += read_size; *size_read += read_size; /* need more data ? */ if (!size) return ERROR_OK; } return ERROR_OK; } int image_mot_buffer_complete(image_t *image) { image_mot_t *mot = image->type_private; fileio_t *fileio = &mot->fileio; u32 full_address = 0x0; u32 cooked_bytes; int i; char lpszLine[1023]; /* we can't determine the number of sections that we'll have to create ahead of time, * so we locally hold them until parsing is finished */ image_section_t section[IMAGE_MAX_SECTIONS]; mot->buffer = malloc(fileio->size >> 1); cooked_bytes = 0x0; image->num_sections = 0; section[image->num_sections].private = &mot->buffer[cooked_bytes]; section[image->num_sections].base_address = 0x0; section[image->num_sections].size = 0x0; section[image->num_sections].flags = 0; while (fileio_fgets(fileio, 1023, lpszLine) == ERROR_OK) { u32 count; u32 address; u32 record_type; u32 checksum; u8 cal_checksum = 0; u32 bytes_read = 0; /* get record type and record length */ if (sscanf(&lpszLine[bytes_read], "S%1x%2x", &record_type, &count) != 2) { return ERROR_IMAGE_FORMAT_ERROR; } bytes_read += 4; cal_checksum += (u8)count; /* skip checksum byte */ count -=1; if (record_type == 0) { /* S0 - starting record (optional) */ int iValue; while (count-- > 0) { sscanf(&lpszLine[bytes_read], "%2x", &iValue); cal_checksum += (u8)iValue; bytes_read += 2; } } else if (record_type >= 1 && record_type <= 3) { switch( record_type ) { case 1: /* S1 - 16 bit address data record */ sscanf(&lpszLine[bytes_read], "%4x", &address); cal_checksum += (u8)(address >> 8); cal_checksum += (u8)address; bytes_read += 4; count -=2; break; case 2: /* S2 - 24 bit address data record */ sscanf(&lpszLine[bytes_read], "%6x", &address); cal_checksum += (u8)(address >> 16); cal_checksum += (u8)(address >> 8); cal_checksum += (u8)address; bytes_read += 6; count -=3; break; case 3: /* S3 - 32 bit address data record */ sscanf(&lpszLine[bytes_read], "%8x", &address); cal_checksum += (u8)(address >> 24); cal_checksum += (u8)(address >> 16); cal_checksum += (u8)(address >> 8); cal_checksum += (u8)address; bytes_read += 8; count -=4; break; } if (full_address != address) { /* we encountered a nonconsecutive location, create a new section, * unless the current section has zero size, in which case this specifies * the current section's base address */ if (section[image->num_sections].size != 0) { image->num_sections++; section[image->num_sections].size = 0x0; section[image->num_sections].flags = 0; section[image->num_sections].private = &mot->buffer[cooked_bytes]; } section[image->num_sections].base_address = address; full_address = address; } while (count-- > 0) { sscanf(&lpszLine[bytes_read], "%2x", (u32*)&mot->buffer[cooked_bytes]); cal_checksum += (u8)mot->buffer[cooked_bytes]; bytes_read += 2; cooked_bytes += 1; section[image->num_sections].size += 1; full_address++; } } else if (record_type == 5) { /* S5 is the data count record, we ignore it */ u32 dummy; while (count-- > 0) { sscanf(&lpszLine[bytes_read], "%2x", &dummy); cal_checksum += (u8)dummy; bytes_read += 2; } } else if (record_type >= 7 && record_type <= 9) { /* S7, S8, S9 - ending records for 32, 24 and 16bit */ image->num_sections++; /* copy section information */ image->sections = malloc(sizeof(image_section_t) * image->num_sections); for (i = 0; i < image->num_sections; i++) { image->sections[i].private = section[i].private; image->sections[i].base_address = section[i].base_address; image->sections[i].size = section[i].size; image->sections[i].flags = section[i].flags; } return ERROR_OK; } else { LOG_ERROR("unhandled S19 record type: %i", record_type); return ERROR_IMAGE_FORMAT_ERROR; } /* account for checksum, will always be 0xFF */ sscanf(&lpszLine[bytes_read], "%2x", &checksum); cal_checksum += (u8)checksum; bytes_read += 2; if( cal_checksum != 0xFF ) { /* checksum failed */ LOG_ERROR("incorrect record checksum found in S19 file"); return ERROR_IMAGE_CHECKSUM; } } LOG_ERROR("premature end of S19 file, no end-of-file record found"); return ERROR_IMAGE_FORMAT_ERROR; } int image_open(image_t *image, char *url, char *type_string) { int retval = ERROR_OK; if ((retval = identify_image_type(image, type_string, url)) != ERROR_OK) { return retval; } if (image->type == IMAGE_BINARY) { image_binary_t *image_binary; image_binary = image->type_private = malloc(sizeof(image_binary_t)); if ((retval = fileio_open(&image_binary->fileio, url, FILEIO_READ, FILEIO_BINARY)) != ERROR_OK) { return retval; } image->num_sections = 1; image->sections = malloc(sizeof(image_section_t)); image->sections[0].base_address = 0x0; image->sections[0].size = image_binary->fileio.size; image->sections[0].flags = 0; } else if (image->type == IMAGE_IHEX) { image_ihex_t *image_ihex; image_ihex = image->type_private = malloc(sizeof(image_ihex_t)); if ((retval = fileio_open(&image_ihex->fileio, url, FILEIO_READ, FILEIO_TEXT)) != ERROR_OK) { return retval; } if ((retval = image_ihex_buffer_complete(image)) != ERROR_OK) { LOG_ERROR("failed buffering IHEX image, check daemon output for additional information"); fileio_close(&image_ihex->fileio); return retval; } } else if (image->type == IMAGE_ELF) { image_elf_t *image_elf; image_elf = image->type_private = malloc(sizeof(image_elf_t)); if ((retval = fileio_open(&image_elf->fileio, url, FILEIO_READ, FILEIO_BINARY)) != ERROR_OK) { return retval; } if ((retval = image_elf_read_headers(image)) != ERROR_OK) { fileio_close(&image_elf->fileio); return retval; } } else if (image->type == IMAGE_MEMORY) { image_memory_t *image_memory; image->num_sections = 1; image->sections = malloc(sizeof(image_section_t)); image->sections[0].base_address = 0x0; image->sections[0].size = 0xffffffff; image->sections[0].flags = 0; image_memory = image->type_private = malloc(sizeof(image_memory_t)); image_memory->target = get_target_by_num(strtoul(url, NULL, 0));; image_memory->cache = NULL; image_memory->cache_address = 0x0; } else if (image->type == IMAGE_SRECORD) { image_mot_t *image_mot; image_mot = image->type_private = malloc(sizeof(image_mot_t)); if ((retval = fileio_open(&image_mot->fileio, url, FILEIO_READ, FILEIO_TEXT)) != ERROR_OK) { return retval; } if ((retval = image_mot_buffer_complete(image)) != ERROR_OK) { LOG_ERROR("failed buffering S19 image, check daemon output for additional information"); fileio_close(&image_mot->fileio); return retval; } } else if (image->type == IMAGE_BUILDER) { image->num_sections = 0; image->sections = NULL; image->type_private = NULL; } if (image->base_address_set) { /* relocate */ int section; for (section=0; section < image->num_sections; section++) { image->sections[section].base_address+=image->base_address; } /* we're done relocating. The two statements below are mainly * for documenation purposes: stop anyone from empirically * thinking they should use these values henceforth. */ image->base_address=0; image->base_address_set=0; } return retval; }; int image_read_section(image_t *image, int section, u32 offset, u32 size, u8 *buffer, u32 *size_read) { int retval; /* don't read past the end of a section */ if (offset + size > image->sections[section].size) { LOG_DEBUG("read past end of section: 0x%8.8x + 0x%8.8x > 0x%8.8x", offset, size, image->sections[section].size); return ERROR_INVALID_ARGUMENTS; } if (image->type == IMAGE_BINARY) { image_binary_t *image_binary = image->type_private; /* only one section in a plain binary */ if (section != 0) return ERROR_INVALID_ARGUMENTS; /* seek to offset */ if ((retval = fileio_seek(&image_binary->fileio, offset)) != ERROR_OK) { return retval; } /* return requested bytes */ if ((retval = fileio_read(&image_binary->fileio, size, buffer, size_read)) != ERROR_OK) { return retval; } } else if (image->type == IMAGE_IHEX) { memcpy(buffer, (u8*)image->sections[section].private + offset, size); *size_read = size; return ERROR_OK; } else if (image->type == IMAGE_ELF) { return image_elf_read_section(image, section, offset, size, buffer, size_read); } else if (image->type == IMAGE_MEMORY) { image_memory_t *image_memory = image->type_private; u32 address = image->sections[section].base_address + offset; *size_read = 0; while ((size - *size_read) > 0) { u32 size_in_cache; if (!image_memory->cache || (address < image_memory->cache_address) || (address >= (image_memory->cache_address + IMAGE_MEMORY_CACHE_SIZE))) { if (!image_memory->cache) image_memory->cache = malloc(IMAGE_MEMORY_CACHE_SIZE); if (target_read_buffer(image_memory->target, address & ~(IMAGE_MEMORY_CACHE_SIZE - 1), IMAGE_MEMORY_CACHE_SIZE, image_memory->cache) != ERROR_OK) { free(image_memory->cache); image_memory->cache = NULL; return ERROR_IMAGE_TEMPORARILY_UNAVAILABLE; } image_memory->cache_address = address & ~(IMAGE_MEMORY_CACHE_SIZE - 1); } size_in_cache = (image_memory->cache_address + IMAGE_MEMORY_CACHE_SIZE) - address; memcpy(buffer + *size_read, image_memory->cache + (address - image_memory->cache_address), (size_in_cache > size) ? size : size_in_cache ); *size_read += (size_in_cache > size) ? size : size_in_cache; address += (size_in_cache > size) ? size : size_in_cache; } } else if (image->type == IMAGE_SRECORD) { memcpy(buffer, (u8*)image->sections[section].private + offset, size); *size_read = size; return ERROR_OK; } else if (image->type == IMAGE_BUILDER) { memcpy(buffer, (u8*)image->sections[section].private + offset, size); *size_read = size; return ERROR_OK; } return ERROR_OK; } int image_add_section(image_t *image, u32 base, u32 size, int flags, u8 *data) { image_section_t *section; /* only image builder supports adding sections */ if (image->type != IMAGE_BUILDER) return ERROR_INVALID_ARGUMENTS; /* see if there's a previous section */ if (image->num_sections) { section = &image->sections[image->num_sections - 1]; /* see if it's enough to extend the last section, * adding data to previous sections or merging is not supported */ if (((section->base_address + section->size) == base) && (section->flags == flags)) { section->private = realloc(section->private, section->size + size); memcpy((u8*)section->private + section->size, data, size); section->size += size; return ERROR_OK; } } /* allocate new section */ image->num_sections++; image->sections = realloc(image->sections, sizeof(image_section_t) * image->num_sections); section = &image->sections[image->num_sections - 1]; section->base_address = base; section->size = size; section->flags = flags; section->private = malloc(sizeof(u8) * size); memcpy((u8*)section->private, data, size); return ERROR_OK; } int image_close(image_t *image) { if (image->type == IMAGE_BINARY) { image_binary_t *image_binary = image->type_private; fileio_close(&image_binary->fileio); } else if (image->type == IMAGE_IHEX) { image_ihex_t *image_ihex = image->type_private; fileio_close(&image_ihex->fileio); if (image_ihex->buffer) { free(image_ihex->buffer); image_ihex->buffer = NULL; } } else if (image->type == IMAGE_ELF) { image_elf_t *image_elf = image->type_private; fileio_close(&image_elf->fileio); if (image_elf->header) { free(image_elf->header); image_elf->header = NULL; } if (image_elf->segments) { free(image_elf->segments); image_elf->segments = NULL; } } else if (image->type == IMAGE_MEMORY) { image_memory_t *image_memory = image->type_private; if (image_memory->cache) { free(image_memory->cache); image_memory->cache = NULL; } } else if (image->type == IMAGE_SRECORD) { image_mot_t *image_mot = image->type_private; fileio_close(&image_mot->fileio); if (image_mot->buffer) { free(image_mot->buffer); image_mot->buffer = NULL; } } else if (image->type == IMAGE_BUILDER) { int i; for (i = 0; i < image->num_sections; i++) { free(image->sections[i].private); image->sections[i].private = NULL; } } if (image->type_private) { free(image->type_private); image->type_private = NULL; } if (image->sections) { free(image->sections); image->sections = NULL; } return ERROR_OK; } static u32 crc32_table[256] = {0, 0}; int image_calculate_checksum(u8* buffer, u32 nbytes, u32* checksum) { u32 crc = 0xffffffff; if (!crc32_table[1]) { /* Initialize the CRC table and the decoding table. */ int i, j; unsigned int c; for (i = 0; i < 256; i++) { /* as per gdb */ for (c = i << 24, j = 8; j > 0; --j) c = c & 0x80000000 ? (c << 1) ^ 0x04c11db7 : (c << 1); crc32_table[i] = c; } } while (nbytes--) { /* as per gdb */ crc = (crc << 8) ^ crc32_table[((crc >> 24) ^ *buffer++) & 255]; } *checksum = crc; return ERROR_OK; }