#include #include #include #include #include #include #include #include "misc.h" #include "elf.h" #define cprintf(col, ...) do {color(col); printf(__VA_ARGS__); }while(0) bool g_debug = false; typedef uint8_t packed_bcd_uint8_t; typedef uint16_t packed_bcd_uint16_t; struct rknano_date_t { packed_bcd_uint16_t year; packed_bcd_uint8_t mday; packed_bcd_uint8_t month; }; struct rknano_version_t { packed_bcd_uint16_t major; packed_bcd_uint16_t minor; packed_bcd_uint16_t rev; }; struct rknano_image_t { uint16_t width; uint16_t height; uint8_t data[0]; }; struct rknano_blob_t { uint32_t offset; uint32_t size; }; #define VENDOR_NAME_SIZE 32 #define MODEL_NAME_SIZE 32 #define MAX_NR_STAGES 4 #define MAX_NR_FONTS 10 #define MAX_NR_GBK 5 #define MAX_NR_STRTBL 10 #define MAX_NR_IMAGERES 10 #define MAX_NR_UNK 10 #define MAGIC_RKNANOFW "RKnanoFW" #define MAGIC_RKNANOFW_SIZE 8 struct rknano_header_t { struct rknano_date_t date; struct rknano_version_t version; uint8_t unk6[6]; char vendor[VENDOR_NAME_SIZE]; char model[MODEL_NAME_SIZE]; uint32_t nr_stages; struct rknano_blob_t stage[MAX_NR_STAGES]; uint32_t nr_fonts; struct rknano_blob_t font[MAX_NR_FONTS]; uint32_t nr_gbk; struct rknano_blob_t gbk[MAX_NR_GBK]; uint32_t nr_strtbl; struct rknano_blob_t strtbl[MAX_NR_STRTBL]; uint32_t nr_imageres; struct rknano_blob_t imageres[MAX_NR_IMAGERES]; uint32_t nr_unk; struct rknano_blob_t unk[MAX_NR_UNK]; uint32_t pad; uint32_t size; char magic[MAGIC_RKNANOFW_SIZE]; }; char *g_out_prefix = NULL; static void encode_page(uint8_t *inpg, uint8_t *outpg, const int size) { uint8_t key[] = { 0x7C, 0x4E, 0x03, 0x04, 0x55, 0x05, 0x09, 0x07, 0x2D, 0x2C, 0x7B, 0x38, 0x17, 0x0D, 0x17, 0x11 }; int i, i3, x, val, idx; uint8_t key1[0x100]; uint8_t key2[0x100]; for (i=0; i<0x100; i++) { key1[i] = i; key2[i] = key[i&0xf]; } i3 = 0; for (i=0; i<0x100; i++) { x = key1[i]; i3 = key1[i] + i3; i3 += key2[i]; i3 &= 0xff; key1[i] = key1[i3]; key1[i3] = x; } idx = 0; for (i=0; i>= 1) { if(result & 0x80) result = (2 * result) ^ 0x1021; else result *= 2; if(*buf & bit) result ^= 0x1021; } } return result; } /* scramble mode */ enum { NO_ENC, CONTINOUS_ENC, /* scramble whole block at once */ PAGE_ENC /* nand bootloader is scrambled in 0x200 chunks */ }; static void save_blob(const struct rknano_blob_t *b, void *buf, uint32_t size, char *name, int suffix, int enc_mode) { if(g_out_prefix == NULL || b->size == 0 || b->offset + b->size > size) return; char *path = malloc(strlen(g_out_prefix) + strlen(name) + 32); if(suffix >= 0) sprintf(path, "%s%s%d.bin", g_out_prefix, name, suffix); else sprintf(path, "%s%s.bin", g_out_prefix, name); FILE *f = fopen(path, "wb"); uint8_t *ptr = buf + b->offset; if(enc_mode != NO_ENC) { ptr = malloc(b->size); int len = b->size; uint8_t *buff_ptr = buf + b->offset; uint8_t *out_ptr = ptr; if(enc_mode == PAGE_ENC) { while(len >= 0x200) { encode_page(buff_ptr, out_ptr, 0x200); buff_ptr += 0x200; out_ptr += 0x200; len -= 0x200; } } encode_page(buff_ptr, out_ptr, len); } if(f) { fwrite(ptr, b->size, 1, f); fclose(f); } if(enc_mode != NO_ENC) free(ptr); } static void print_blob_interval(const struct rknano_blob_t *b) { cprintf(YELLOW, "%#x -> %#x", b->offset, b->offset + b->size); } static int do_nanofw_image(uint8_t *buf, unsigned long size) { if(size < sizeof(struct rknano_header_t)) return 1; struct rknano_header_t *hdr = (void *)buf; if(size < hdr->size) return 1; if(strncmp(hdr->magic, MAGIC_RKNANOFW, MAGIC_RKNANOFW_SIZE)) return 1; cprintf(BLUE, "Header\n"); cprintf(GREEN, " Date: "); cprintf(YELLOW, "%x/%x/%x\n", hdr->date.mday, hdr->date.month, hdr->date.year); cprintf(GREEN, " Version: "); cprintf(YELLOW, "%x.%x.%x\n", hdr->version.major, hdr->version.minor, hdr->version.rev); cprintf(GREEN, " Vendor: "); cprintf(YELLOW, "%s\n", hdr->vendor); cprintf(GREEN, " Model: "); cprintf(YELLOW, "%s\n", hdr->model); cprintf(GREEN, " Pad: "); for(int i = 0; i < 6; i++) cprintf(YELLOW, " %02x", hdr->unk6[i]); cprintf(YELLOW, "\n"); cprintf(BLUE, "Stages\n"); for(unsigned i = 0; i < hdr->nr_stages; i++) { cprintf(GREEN, " %i: ", i); print_blob_interval(&hdr->stage[i]); cprintf(OFF, "\n"); save_blob(&hdr->stage[i], buf, size, "stage", i, NO_ENC); } cprintf(BLUE, "Fonts\n"); for(unsigned i = 0; i < hdr->nr_fonts; i++) { cprintf(GREEN, " %i: ", i); print_blob_interval(&hdr->font[i]); cprintf(OFF, "\n"); save_blob(&hdr->font[i], buf, size, "font", i, NO_ENC); } cprintf(BLUE, "GBK\n"); for(unsigned i = 0; i < hdr->nr_gbk; i++) { cprintf(GREEN, " %i: ", i); print_blob_interval(&hdr->gbk[i]); cprintf(OFF, "\n"); save_blob(&hdr->gbk[i], buf, size, "gbk", i, NO_ENC); } cprintf(BLUE, "String Tables\n"); for(unsigned i = 0; i < hdr->nr_strtbl; i++) { cprintf(GREEN, " %i: ", i); print_blob_interval(&hdr->strtbl[i]); cprintf(OFF, "\n"); save_blob(&hdr->strtbl[i], buf, size, "strtbl", i, NO_ENC); } cprintf(BLUE, "Image Resources\n"); for(unsigned i = 0; i < hdr->nr_imageres; i++) { cprintf(GREEN, " %i: ", i); print_blob_interval(&hdr->imageres[i]); cprintf(OFF, "\n"); save_blob(&hdr->imageres[i], buf, size, "imgres", i, NO_ENC); } cprintf(BLUE, "Unknown\n"); for(unsigned i = 0; i < hdr->nr_unk; i++) { cprintf(GREEN, " %i: ", i); print_blob_interval(&hdr->unk[i]); cprintf(OFF, "\n"); save_blob(&hdr->unk[i], buf, size, "unk", i, NO_ENC); } cprintf(BLUE, "Other\n"); cprintf(GREEN, " Size: "); cprintf(YELLOW, "%#x\n", hdr->size); cprintf(GREEN, " Magic: "); cprintf(YELLOW, "%." STR(MAGIC_RKNANOFW_SIZE) "s ", hdr->magic); if(strncmp(hdr->magic, MAGIC_RKNANOFW, MAGIC_RKNANOFW_SIZE) == 0) cprintf(RED, "OK\n"); else cprintf(RED, "Mismatch\n"); return 0; } struct rknano_stage_header_t { uint32_t addr; uint32_t count; } __attribute__((packed)); /* * The [code_pa,code_pa+code_sz[ and [data_pa,data_pa+data_sz[ ranges * are consitent: they never overlap and have no gaps and fill the * entire space. Furthermore they match the code sequences so it's * reasonable to assume these fields are correct. * The other fields are still quite unsure. */ struct rknano_stage_section_t { uint32_t code_pa; uint32_t code_va; uint32_t code_sz; uint32_t data_pa; uint32_t data_va; uint32_t data_sz; uint32_t bss_va; uint32_t bss_sz; } __attribute__((packed)); static void elf_printf(void *user, bool error, const char *fmt, ...) { if(!g_debug && !error) return; (void) user; va_list args; va_start(args, fmt); vprintf(fmt, args); va_end(args); } static void elf_write(void *user, uint32_t addr, const void *buf, size_t count) { FILE *f = user; fseek(f, addr, SEEK_SET); fwrite(buf, count, 1, f); } static void extract_elf_section(struct elf_params_t *elf, int count) { if(g_out_prefix == NULL) return; char *filename = xmalloc(strlen(g_out_prefix) + 32); sprintf(filename, "%s%d.elf", g_out_prefix, count); if(g_debug) printf("Write entry %d to %s\n", count, filename); FILE *fd = fopen(filename, "wb"); free(filename); if(fd == NULL) return ; elf_write_file(elf, elf_write, elf_printf, fd); fclose(fd); } static int do_nanostage_image(uint8_t *buf, unsigned long size) { if(size < sizeof(struct rknano_stage_section_t)) return 1; struct rknano_stage_header_t *hdr = (void *)buf; cprintf(BLUE, "Header\n"); cprintf(GREEN, " Base Address: "); cprintf(YELLOW, "%#08x\n", hdr->addr); cprintf(GREEN, " Load count: "); cprintf(YELLOW, "%d\n", hdr->count); struct rknano_stage_section_t *sec = (void *)(hdr + 1); for(unsigned i = 0; i < hdr->count; i++, sec++) { cprintf(BLUE, "Section %d\n", i); cprintf(GREEN, " Code: "); cprintf(YELLOW, "0x%08x", sec->code_pa); cprintf(RED, "-(txt)-"); cprintf(YELLOW, "0x%08x", sec->code_pa + sec->code_sz); cprintf(BLUE, " |--> "); cprintf(YELLOW, "0x%08x", sec->code_va); cprintf(RED, "-(txt)-"); cprintf(YELLOW, "0x%08x\n", sec->code_va + sec->code_sz); cprintf(GREEN, " Data: "); cprintf(YELLOW, "0x%08x", sec->data_pa); cprintf(RED, "-(dat)-"); cprintf(YELLOW, "0x%08x", sec->data_pa + sec->data_sz); cprintf(BLUE, " |--> "); cprintf(YELLOW, "0x%08x", sec->data_va); cprintf(RED, "-(dat)-"); cprintf(YELLOW, "0x%08x\n", sec->data_va + sec->data_sz); cprintf(GREEN, " Data: "); cprintf(RED, " "); cprintf(BLUE, " |--> "); cprintf(YELLOW, "0x%08x", sec->bss_va); cprintf(RED, "-(bss)-"); cprintf(YELLOW, "0x%08x\n", sec->bss_va + sec->bss_sz); #if 0 struct rknano_blob_t blob; blob.offset = sec->code_pa - hdr->addr; blob.size = sec->code_sz; save_blob(&blob, buf, size, "entry.", i, NO_ENC); #else struct elf_params_t elf; elf_init(&elf); elf_add_load_section(&elf, sec->code_va, sec->code_sz, buf + sec->code_pa - hdr->addr); elf_add_load_section(&elf, sec->data_va, sec->data_sz, buf + sec->data_pa - hdr->addr); elf_add_fill_section(&elf, sec->bss_va, sec->bss_sz, 0); extract_elf_section(&elf, i); elf_release(&elf); #endif } return 0; } #define MAGIC_BOOT "BOOT" #define MAGIC_BOOT_SIZE 4 struct rknano_boot_desc_t { uint8_t count; uint32_t offset; uint8_t stride; } __attribute__((packed)); struct rknano_boot_header_t { char magic[MAGIC_BOOT_SIZE]; uint16_t field_4; uint32_t field_6; uint32_t field_A; uint16_t field_E; uint8_t field_10[5]; uint32_t field_15; struct rknano_boot_desc_t desc_1; struct rknano_boot_desc_t desc_2; struct rknano_boot_desc_t desc_4; uint8_t field_2B[9]; uint32_t field_34; } __attribute__((packed)); struct rknano_boot_entry_t { uint8_t entry_size; // unsure uint32_t unk; uint16_t name[20]; uint32_t offset; uint32_t size; uint32_t sthg2; } __attribute__((packed)); uint32_t boot_crc_table[256] = { 0x00000000, 0x04C10DB7, 0x09821B6E, 0x0D4316D9, 0x130436DC, 0x17C53B6B, 0x1A862DB2, 0x1E472005, 0x26086DB8, 0x22C9600F, 0x2F8A76D6, 0x2B4B7B61, 0x350C5B64, 0x31CD56D3, 0x3C8E400A, 0x384F4DBD, 0x4C10DB70, 0x48D1D6C7, 0x4592C01E, 0x4153CDA9, 0x5F14EDAC, 0x5BD5E01B, 0x5696F6C2, 0x5257FB75, 0x6A18B6C8, 0x6ED9BB7F, 0x639AADA6, 0x675BA011, 0x791C8014, 0x7DDD8DA3, 0x709E9B7A, 0x745F96CD, 0x9821B6E0, 0x9CE0BB57, 0x91A3AD8E, 0x9562A039, 0x8B25803C, 0x8FE48D8B, 0x82A79B52, 0x866696E5, 0xBE29DB58, 0xBAE8D6EF, 0xB7ABC036, 0xB36ACD81, 0xAD2DED84, 0xA9ECE033, 0xA4AFF6EA, 0xA06EFB5D, 0xD4316D90, 0xD0F06027, 0xDDB376FE, 0xD9727B49, 0xC7355B4C, 0xC3F456FB, 0xCEB74022, 0xCA764D95, 0xF2390028, 0xF6F80D9F, 0xFBBB1B46, 0xFF7A16F1, 0xE13D36F4, 0xE5FC3B43, 0xE8BF2D9A, 0xEC7E202D, 0x34826077, 0x30436DC0, 0x3D007B19, 0x39C176AE, 0x278656AB, 0x23475B1C, 0x2E044DC5, 0x2AC54072, 0x128A0DCF, 0x164B0078, 0x1B0816A1, 0x1FC91B16, 0x018E3B13, 0x054F36A4, 0x080C207D, 0x0CCD2DCA, 0x7892BB07, 0x7C53B6B0, 0x7110A069, 0x75D1ADDE, 0x6B968DDB, 0x6F57806C, 0x621496B5, 0x66D59B02, 0x5E9AD6BF, 0x5A5BDB08, 0x5718CDD1, 0x53D9C066, 0x4D9EE063, 0x495FEDD4, 0x441CFB0D, 0x40DDF6BA, 0xACA3D697, 0xA862DB20, 0xA521CDF9, 0xA1E0C04E, 0xBFA7E04B, 0xBB66EDFC, 0xB625FB25, 0xB2E4F692, 0x8AABBB2F, 0x8E6AB698, 0x8329A041, 0x87E8ADF6, 0x99AF8DF3, 0x9D6E8044, 0x902D969D, 0x94EC9B2A, 0xE0B30DE7, 0xE4720050, 0xE9311689, 0xEDF01B3E, 0xF3B73B3B, 0xF776368C, 0xFA352055, 0xFEF42DE2, 0xC6BB605F, 0xC27A6DE8, 0xCF397B31, 0xCBF87686, 0xD5BF5683, 0xD17E5B34, 0xDC3D4DED, 0xD8FC405A, 0x6904C0EE, 0x6DC5CD59, 0x6086DB80, 0x6447D637, 0x7A00F632, 0x7EC1FB85, 0x7382ED5C, 0x7743E0EB, 0x4F0CAD56, 0x4BCDA0E1, 0x468EB638, 0x424FBB8F, 0x5C089B8A, 0x58C9963D, 0x558A80E4, 0x514B8D53, 0x25141B9E, 0x21D51629, 0x2C9600F0, 0x28570D47, 0x36102D42, 0x32D120F5, 0x3F92362C, 0x3B533B9B, 0x031C7626, 0x07DD7B91, 0x0A9E6D48, 0x0E5F60FF, 0x101840FA, 0x14D94D4D, 0x199A5B94, 0x1D5B5623, 0xF125760E, 0xF5E47BB9, 0xF8A76D60, 0xFC6660D7, 0xE22140D2, 0xE6E04D65, 0xEBA35BBC, 0xEF62560B, 0xD72D1BB6, 0xD3EC1601, 0xDEAF00D8, 0xDA6E0D6F, 0xC4292D6A, 0xC0E820DD, 0xCDAB3604, 0xC96A3BB3, 0xBD35AD7E, 0xB9F4A0C9, 0xB4B7B610, 0xB076BBA7, 0xAE319BA2, 0xAAF09615, 0xA7B380CC, 0xA3728D7B, 0x9B3DC0C6, 0x9FFCCD71, 0x92BFDBA8, 0x967ED61F, 0x8839F61A, 0x8CF8FBAD, 0x81BBED74, 0x857AE0C3, 0x5D86A099, 0x5947AD2E, 0x5404BBF7, 0x50C5B640, 0x4E829645, 0x4A439BF2, 0x47008D2B, 0x43C1809C, 0x7B8ECD21, 0x7F4FC096, 0x720CD64F, 0x76CDDBF8, 0x688AFBFD, 0x6C4BF64A, 0x6108E093, 0x65C9ED24, 0x11967BE9, 0x1557765E, 0x18146087, 0x1CD56D30, 0x02924D35, 0x06534082, 0x0B10565B, 0x0FD15BEC, 0x379E1651, 0x335F1BE6, 0x3E1C0D3F, 0x3ADD0088, 0x249A208D, 0x205B2D3A, 0x2D183BE3, 0x29D93654, 0xC5A71679, 0xC1661BCE, 0xCC250D17, 0xC8E400A0, 0xD6A320A5, 0xD2622D12, 0xDF213BCB, 0xDBE0367C, 0xE3AF7BC1, 0xE76E7676, 0xEA2D60AF, 0xEEEC6D18, 0xF0AB4D1D, 0xF46A40AA, 0xF9295673, 0xFDE85BC4, 0x89B7CD09, 0x8D76C0BE, 0x8035D667, 0x84F4DBD0, 0x9AB3FBD5, 0x9E72F662, 0x9331E0BB, 0x97F0ED0C, 0xAFBFA0B1, 0xAB7EAD06, 0xA63DBBDF, 0xA2FCB668, 0xBCBB966D, 0xB87A9BDA, 0xB5398D03, 0xB1F880B4, }; static uint32_t boot_crc(uint8_t *buf, int size) { uint32_t crc = 0; for(int i = 0; i < size; i++) crc = boot_crc_table[buf[i] ^ (crc >> 24)] ^ (crc << 8); return crc; } wchar_t *from_uni16(uint16_t *str) { static wchar_t buffer[64]; int i = 0; while(str[i]) { buffer[i] = str[i]; i++; } return buffer; } static int do_boot_desc(uint8_t *buf, unsigned long size, struct rknano_boot_desc_t *desc, int desc_idx) { (void) buf; (void) size; cprintf(BLUE, "Desc %d\n", desc_idx); cprintf(GREEN, " Count: "); cprintf(YELLOW, "%d\n", desc->count); cprintf(GREEN, " Offset: "); cprintf(YELLOW, "%#x\n", desc->offset); cprintf(GREEN, " Stride: "); cprintf(YELLOW, "%#x ", desc->stride); if(desc->stride < sizeof(struct rknano_boot_entry_t)) cprintf(RED, "(too small <%#lx)\n", sizeof(struct rknano_boot_entry_t)); else cprintf(RED, "(OK >=%#lx)\n", sizeof(struct rknano_boot_entry_t)); for(int i = 0; i < desc->count; i++) { struct rknano_boot_entry_t *entry = (void *)(buf + desc->offset + i * desc->stride); cprintf(BLUE, " Entry %d\n", i); cprintf(GREEN, " Entry size: "); cprintf(YELLOW, "%#x ", entry->entry_size); if(desc->stride < sizeof(struct rknano_boot_entry_t)) cprintf(RED, "(too small <%#lx)\n", sizeof(struct rknano_boot_entry_t)); else cprintf(RED, "(OK >=%#lx)\n", sizeof(struct rknano_boot_entry_t)); cprintf(GREEN, " Unk: "); cprintf(YELLOW, "%#x\n", entry->unk); cprintf(GREEN, " Name: "); cprintf(YELLOW, "%S\n", from_uni16(entry->name)); cprintf(GREEN, " Offset: "); cprintf(YELLOW, "%#x\n", entry->offset); cprintf(GREEN, " Size: "); cprintf(YELLOW, "%#x\n", entry->size); cprintf(GREEN, " Sthg 2: "); cprintf(YELLOW, "%#x\n", entry->sthg2); struct rknano_blob_t blob; blob.offset = entry->offset; blob.size = entry->size; char name[128]; sprintf(name, "%d.%S", desc_idx, from_uni16(entry->name)); save_blob(&blob, buf, size, name, -1, PAGE_ENC); } return 0; } static int do_boot_image(uint8_t *buf, unsigned long size) { if(sizeof(struct rknano_boot_header_t) != 0x38) printf("aie"); if(size < sizeof(struct rknano_boot_header_t)) return 1; struct rknano_boot_header_t *hdr = (void *)buf; if(strncmp(hdr->magic, MAGIC_BOOT, MAGIC_BOOT_SIZE)) return 1; cprintf(BLUE, "Header\n"); cprintf(GREEN, " Magic: "); cprintf(YELLOW, "%." STR(MAGIC_BOOT_SIZE) "s ", hdr->magic); if(strncmp(hdr->magic, MAGIC_BOOT, MAGIC_BOOT_SIZE) == 0) cprintf(RED, "OK\n"); else cprintf(RED, "Mismatch\n"); #define print(str, name) cprintf(GREEN, " "str": ");cprintf(YELLOW, "%#x\n", (unsigned)hdr->name) #define print_arr(str, name, sz) \ cprintf(GREEN, " "str":");for(int i = 0; i < sz; i++)cprintf(YELLOW, " %#x", (unsigned)hdr->name[i]);printf("\n") print("field_4", field_4); print("field_6", field_6); print("field_A", field_A); print("field_E", field_E); print_arr("field_10", field_10, 5); print("field_15", field_15); print_arr("field_2A", field_2B, 9); print("field_34", field_34); do_boot_desc(buf, size, &hdr->desc_1, 1); do_boot_desc(buf, size, &hdr->desc_2, 2); do_boot_desc(buf, size, &hdr->desc_4, 4); cprintf(BLUE, "Variable Header:\n"); cprintf(GREEN, " Value: "); cprintf(YELLOW, "%#lx\n", *(unsigned long *)((uint8_t *)hdr + hdr->field_34 - 10)); /* The last 4 bytes are a 32-bit CRC */ cprintf(BLUE, "Post Header:\n"); cprintf(GREEN, " CRC: "); uint32_t crc = *(uint32_t *)(buf + size - 4); uint32_t ccrc = boot_crc(buf, size - 4); cprintf(YELLOW, "%08x ", crc); if(crc == ccrc) cprintf(RED, "OK\n"); else cprintf(RED, "Mismatch\n"); return 0; } typedef struct rknano_blob_t rkfw_blob_t; #define MAGIC_RKFW "RKFW" #define MAGIC_RKFW_SIZE 4 struct rkfw_header_t { char magic[MAGIC_RKFW_SIZE]; uint16_t hdr_size; // UNSURE uint32_t field_6; uint32_t field_A; uint16_t field_E; uint8_t field_10[5]; uint32_t field_15; rkfw_blob_t loader; rkfw_blob_t update; uint8_t pad[60]; uint8_t field_65; } __attribute__((packed)); static int do_rkfw_image(uint8_t *buf, unsigned long size) { if(sizeof(struct rkfw_header_t) != 0x66) printf("aie"); if(size < sizeof(struct rkfw_header_t)) return 1; struct rkfw_header_t *hdr = (void *)buf; if(strncmp(hdr->magic, MAGIC_RKFW, MAGIC_RKFW_SIZE)) return 1; cprintf(BLUE, "Header\n"); cprintf(GREEN, " Magic: "); cprintf(YELLOW, "%." STR(MAGIC_RKFW_SIZE) "s ", hdr->magic); if(strncmp(hdr->magic, MAGIC_RKFW, MAGIC_RKFW_SIZE) == 0) cprintf(RED, "OK\n"); else cprintf(RED, "Mismatch\n"); cprintf(GREEN, " Loader: "); print_blob_interval(&hdr->loader); cprintf(OFF, "\n"); save_blob(&hdr->loader, buf, size, "loader", 0, NO_ENC); cprintf(GREEN, " Update: "); print_blob_interval(&hdr->update); cprintf(OFF, "\n"); save_blob(&hdr->update, buf, size, "update", 0, NO_ENC); print("hdr_size", hdr_size); print("field_6", field_6); print("field_A", field_A); print("field_E", field_E); print_arr("field_10", field_10, 5); print("field_15", field_15); print_arr("pad", pad, 60); print("field_65", field_65); return 0; } static void usage(void) { printf("Usage: rkboottool [options] rknanoboot.bin\n"); printf("Options:\n"); printf(" --rkfw\tUnpack a rkfw file\n"); printf(" --rknanofw\tUnpack a regular RknanoFW file\n"); printf(" --rkboot\tUnpack a BOOT file\n"); printf(" --rknanostage\tUnpack a RknanoFW stage file\n"); printf(" -o \tSet output prefix\n"); printf("The default is to try to guess the format.\n"); printf("If several formats are specified, all are tried.\n"); exit(1); } int main(int argc, char **argv) { bool try_nanofw = false; bool try_rkfw = false; bool try_boot = false; bool try_nanostage = false; while(1) { static struct option long_options[] = { {"help", no_argument, 0, '?'}, {"debug", no_argument, 0, 'd'}, {"rkfw", no_argument, 0, '9'}, {"rknanofw", no_argument, 0, 'n'}, {"rknanostage", no_argument, 0, 's'}, {"rkboot", no_argument, 0, 'b'}, {"no-color", no_argument, 0, 'c'}, {0, 0, 0, 0} }; int c = getopt_long(argc, argv, "?d9nscbo:", long_options, NULL); if(c == -1) break; switch(c) { case -1: break; case 'c': enable_color(false); break; case 'b': try_boot = true; break; case 'n': try_nanofw = true; break; case 'd': g_debug = true; break; case '?': usage(); break; case 'o': g_out_prefix = optarg; break; case '9': try_rkfw = true; break; case 's': try_nanostage = true; break; default: abort(); } } if(argc - optind != 1) { usage(); return 1; } if(!try_nanostage && !try_rkfw && !try_nanofw && !try_boot) try_nanostage = try_rkfw = try_nanofw = try_boot = true; FILE *fin = fopen(argv[optind], "r"); if(fin == NULL) { perror("Cannot open boot file"); return 1; } fseek(fin, 0, SEEK_END); long size = ftell(fin); fseek(fin, 0, SEEK_SET); void *buf = malloc(size); if(buf == NULL) { perror("Cannot allocate memory"); return 1; } if(fread(buf, size, 1, fin) != 1) { perror("Cannot read file"); return 1; } fclose(fin); if(try_nanofw && !do_nanofw_image(buf, size)) goto Lsuccess; if(try_rkfw && !do_rkfw_image(buf, size)) goto Lsuccess; if(try_boot && !do_boot_image(buf, size)) goto Lsuccess; if(try_nanostage && !do_nanostage_image(buf, size)) goto Lsuccess; cprintf(GREY, "No valid format found!\n"); Lsuccess: free(buf); return 0; }