/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Copyright (C) 2006 by Barry Wardell * * Based on Rockbox iriver bootloader by Linus Nielsen Feltzing * and the ipodlinux bootloader by Daniel Palffy and Bernard Leach * * All files in this archive are subject to the GNU General Public License. * See the file COPYING in the source tree root for full license agreement. * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY * KIND, either express or implied. * ****************************************************************************/ #include #include #include "common.h" #include "cpu.h" #include "file.h" #include "system.h" #include "kernel.h" #include "lcd.h" #include "font.h" #include "ata.h" #include "button.h" #include "disk.h" #include "crc32-mi4.h" #include #include "power.h" #if defined(SANSA_E200) #include "i2c.h" #include "backlight-target.h" #endif #if defined(SANSA_E200) || defined(SANSA_C200) #include "usb.h" #include "usb_drv.h" #endif /* Button definitions */ #if CONFIG_KEYPAD == IRIVER_H10_PAD #define BOOTLOADER_BOOT_OF BUTTON_LEFT #elif CONFIG_KEYPAD == SANSA_E200_PAD #define BOOTLOADER_BOOT_OF BUTTON_LEFT #elif CONFIG_KEYPAD == SANSA_C200_PAD #define BOOTLOADER_BOOT_OF BUTTON_LEFT #elif CONFIG_KEYPAD == MROBE100_PAD #define BOOTLOADER_BOOT_OF BUTTON_POWER #endif /* Maximum allowed firmware image size. 10MB is more than enough */ #define MAX_LOADSIZE (10*1024*1024) /* A buffer to load the original firmware or Rockbox into */ unsigned char *loadbuffer = (unsigned char *)DRAM_START; /* Bootloader version */ char version[] = APPSVERSION; /* Locations and sizes in hidden partition on Sansa */ #if defined(SANSA_E200) || defined(SANSA_C200) #define PPMI_SECTOR_OFFSET 1024 #define PPMI_SECTORS 1 #define MI4_HEADER_SECTORS 1 #define NUM_PARTITIONS 2 #else #define NUM_PARTITIONS 1 #endif #define MI4_HEADER_SIZE 0x200 /* mi4 header structure */ struct mi4header_t { unsigned char magic[4]; uint32_t version; uint32_t length; uint32_t crc32; uint32_t enctype; uint32_t mi4size; uint32_t plaintext; uint32_t dsa_key[10]; uint32_t pad[109]; unsigned char type[4]; unsigned char model[4]; }; /* PPMI header structure */ struct ppmi_header_t { unsigned char magic[4]; uint32_t length; uint32_t pad[126]; }; inline unsigned int le2int(unsigned char* buf) { int32_t res = (buf[3] << 24) | (buf[2] << 16) | (buf[1] << 8) | buf[0]; return res; } inline void int2le(unsigned int val, unsigned char* addr) { addr[0] = val & 0xFF; addr[1] = (val >> 8) & 0xff; addr[2] = (val >> 16) & 0xff; addr[3] = (val >> 24) & 0xff; } struct tea_key { const char * name; uint32_t key[4]; }; #define NUM_KEYS (sizeof(tea_keytable)/sizeof(tea_keytable[0])) struct tea_key tea_keytable[] = { { "default" , { 0x20d36cc0, 0x10e8c07d, 0xc0e7dcaa, 0x107eb080 } }, { "sansa", { 0xe494e96e, 0x3ee32966, 0x6f48512b, 0xa93fbb42 } }, { "sansa_gh", { 0xd7b10538, 0xc662945b, 0x1b3fce68, 0xf389c0e6 } }, { "sansa_103", { 0x1d29ddc0, 0x2579c2cd, 0xce339e1a, 0x75465dfe } }, { "rhapsody", { 0x7aa9c8dc, 0xbed0a82a, 0x16204cc7, 0x5904ef38 } }, { "p610", { 0x950e83dc, 0xec4907f9, 0x023734b9, 0x10cfb7c7 } }, { "p640", { 0x220c5f23, 0xd04df68e, 0x431b5e25, 0x4dcc1fa1 } }, { "virgin", { 0xe83c29a1, 0x04862973, 0xa9b3f0d4, 0x38be2a9c } }, { "20gc_eng", { 0x0240772c, 0x6f3329b5, 0x3ec9a6c5, 0xb0c9e493 } }, { "20gc_fre", { 0xbede8817, 0xb23bfe4f, 0x80aa682d, 0xd13f598c } }, { "elio_p722", { 0x6af3b9f8, 0x777483f5, 0xae8181cc, 0xfa6d8a84 } }, { "c200", { 0xbf2d06fa, 0xf0e23d59, 0x29738132, 0xe2d04ca7 } }, { "c200_103", { 0x2a7968de, 0x15127979, 0x142e60a7, 0xe49c1893 } }, { "c200_106", { 0xa913d139, 0xf842f398, 0x3e03f1a6, 0x060ee012 } }, { "view", { 0x70e19bda, 0x0c69ea7d, 0x2b8b1ad1, 0xe9767ced } }, { "sa9200", { 0x33ea0236, 0x9247bdc5, 0xdfaedf9f, 0xd67c9d30 } }, }; /* tea_decrypt() from http://en.wikipedia.org/wiki/Tiny_Encryption_Algorithm "Following is an adaptation of the reference encryption and decryption routines in C, released into the public domain by David Wheeler and Roger Needham:" */ /* NOTE: The mi4 version of TEA uses a different initial value to sum compared to the reference implementation and the main loop is 8 iterations, not 32. */ static void tea_decrypt(uint32_t* v0, uint32_t* v1, uint32_t* k) { uint32_t sum=0xF1BBCDC8, i; /* set up */ uint32_t delta=0x9E3779B9; /* a key schedule constant */ uint32_t k0=k[0], k1=k[1], k2=k[2], k3=k[3]; /* cache key */ for(i=0; i<8; i++) { /* basic cycle start */ *v1 -= ((*v0<<4) + k2) ^ (*v0 + sum) ^ ((*v0>>5) + k3); *v0 -= ((*v1<<4) + k0) ^ (*v1 + sum) ^ ((*v1>>5) + k1); sum -= delta; /* end cycle */ } } /* mi4 files are encrypted in 64-bit blocks (two little-endian 32-bit integers) and the key is incremented after each block */ static void tea_decrypt_buf(unsigned char* src, unsigned char* dest, size_t n, uint32_t * key) { uint32_t v0, v1; unsigned int i; for (i = 0; i < (n / 8); i++) { v0 = le2int(src); v1 = le2int(src+4); tea_decrypt(&v0, &v1, key); int2le(v0, dest); int2le(v1, dest+4); src += 8; dest += 8; /* Now increment the key */ key[0]++; if (key[0]==0) { key[1]++; if (key[1]==0) { key[2]++; if (key[2]==0) { key[3]++; } } } } } static inline bool tea_test_key(unsigned char magic_enc[8], uint32_t * key, int unaligned) { unsigned char magic_dec[8]; tea_decrypt_buf(magic_enc, magic_dec, 8, key); return (le2int(&magic_dec[4*unaligned]) == 0xaa55aa55); } static int tea_find_key(struct mi4header_t *mi4header, int fd) { unsigned int i; int rc; unsigned int j; uint32_t key[4]; unsigned char magic_enc[8]; int key_found = -1; unsigned int magic_location = mi4header->length-4; int unaligned = 0; if ( (magic_location % 8) != 0 ) { unaligned = 1; magic_location -= 4; } /* Load encrypted magic 0xaa55aa55 to check key */ lseek(fd, MI4_HEADER_SIZE + magic_location, SEEK_SET); rc = read(fd, magic_enc, 8); if(rc < 8 ) return EREAD_IMAGE_FAILED; printf("Searching for key:"); for (i=0; i < NUM_KEYS && (key_found<0) ; i++) { key[0] = tea_keytable[i].key[0]; key[1] = tea_keytable[i].key[1]; key[2] = tea_keytable[i].key[2]; key[3] = tea_keytable[i].key[3]; /* Now increment the key */ for(j=0; j<((magic_location-mi4header->plaintext)/8); j++){ key[0]++; if (key[0]==0) { key[1]++; if (key[1]==0) { key[2]++; if (key[2]==0) { key[3]++; } } } } if (tea_test_key(magic_enc,key,unaligned)) { key_found = i; printf("%s...found", tea_keytable[i].name); } else { /* printf("%s...failed", tea_keytable[i].name); */ } } return key_found; } /* Load mi4 format firmware image */ int load_mi4(unsigned char* buf, char* firmware, unsigned int buffer_size) { int fd; struct mi4header_t mi4header; int rc; unsigned long sum; char filename[MAX_PATH]; snprintf(filename,sizeof(filename),"/.rockbox/%s",firmware); fd = open(filename, O_RDONLY); if(fd < 0) { snprintf(filename,sizeof(filename),"/%s",firmware); fd = open(filename, O_RDONLY); if(fd < 0) return EFILE_NOT_FOUND; } read(fd, &mi4header, MI4_HEADER_SIZE); /* MI4 file size */ printf("mi4 size: %x", mi4header.mi4size); if ((mi4header.mi4size-MI4_HEADER_SIZE) > buffer_size) return EFILE_TOO_BIG; /* CRC32 */ printf("CRC32: %x", mi4header.crc32); /* Rockbox model id */ printf("Model id: %.4s", mi4header.model); /* Read binary type (RBOS, RBBL) */ printf("Binary type: %.4s", mi4header.type); /* Load firmware file */ lseek(fd, MI4_HEADER_SIZE, SEEK_SET); rc = read(fd, buf, mi4header.mi4size-MI4_HEADER_SIZE); if(rc < (int)mi4header.mi4size-MI4_HEADER_SIZE) return EREAD_IMAGE_FAILED; /* Check CRC32 to see if we have a valid file */ sum = chksum_crc32 (buf, mi4header.mi4size - MI4_HEADER_SIZE); printf("Calculated CRC32: %x", sum); if(sum != mi4header.crc32) return EBAD_CHKSUM; if( (mi4header.plaintext + MI4_HEADER_SIZE) != mi4header.mi4size) { /* Load encrypted firmware */ int key_index = tea_find_key(&mi4header, fd); if (key_index < 0) return EINVALID_FORMAT; /* Plaintext part is already loaded */ buf += mi4header.plaintext; /* Decrypt in-place */ tea_decrypt_buf(buf, buf, mi4header.mi4size-(mi4header.plaintext+MI4_HEADER_SIZE), tea_keytable[key_index].key); printf("%s key used", tea_keytable[key_index].name); /* Check decryption was successfull */ if(le2int(&buf[mi4header.length-mi4header.plaintext-4]) != 0xaa55aa55) { return EREAD_IMAGE_FAILED; } } return EOK; } #if defined(SANSA_E200) || defined(SANSA_C200) /* Load mi4 firmware from a hidden disk partition */ int load_mi4_part(unsigned char* buf, struct partinfo* pinfo, unsigned int buffer_size, bool disable_rebuild) { struct mi4header_t mi4header; struct ppmi_header_t ppmi_header; unsigned long sum; /* Read header to find out how long the mi4 file is. */ ata_read_sectors(IF_MV2(0,) pinfo->start + PPMI_SECTOR_OFFSET, PPMI_SECTORS, &ppmi_header); /* The first four characters at 0x80000 (sector 1024) should be PPMI*/ if( memcmp(ppmi_header.magic, "PPMI", 4) ) return EFILE_NOT_FOUND; /* printf("BL mi4 size: %x", ppmi_header.length); */ /* Read mi4 header of the OF */ ata_read_sectors(IF_MV2(0,) pinfo->start + PPMI_SECTOR_OFFSET /* + PPMI_SECTORS */ /* + (ppmi_header.length/512) */, MI4_HEADER_SECTORS, &mi4header); /* We don't support encrypted mi4 files yet */ if( (mi4header.plaintext) != (mi4header.mi4size-MI4_HEADER_SIZE)) return EINVALID_FORMAT; /* MI4 file size */ printf("OF mi4 size: %x", mi4header.mi4size); if ((mi4header.mi4size-MI4_HEADER_SIZE) > buffer_size) return EFILE_TOO_BIG; /* CRC32 */ printf("CRC32: %x", mi4header.crc32); /* Rockbox model id */ printf("Model id: %.4s", mi4header.model); /* Read binary type (RBOS, RBBL) */ printf("Binary type: %.4s", mi4header.type); /* Load firmware */ ata_read_sectors(IF_MV2(0,) pinfo->start + PPMI_SECTOR_OFFSET /* + PPMI_SECTORS */ /* + (ppmi_header.length/512) */ + MI4_HEADER_SECTORS, (mi4header.mi4size-MI4_HEADER_SIZE)/512, buf); /* Check CRC32 to see if we have a valid file */ sum = chksum_crc32 (buf,mi4header.mi4size-MI4_HEADER_SIZE); printf("Calculated CRC32: %x", sum); if(sum != mi4header.crc32) return EBAD_CHKSUM; #ifdef SANSA_E200 if (disable_rebuild) { char block[512]; printf("Disabling database rebuild"); ata_read_sectors(IF_MV2(0,) pinfo->start + 0x3c08, 1, block); block[0xe1] = 0; ata_write_sectors(IF_MV2(0,) pinfo->start + 0x3c08, 1, block); } #else (void) disable_rebuild; #endif return EOK; } #endif void* main(void) { int i; int btn; int rc; int num_partitions; struct partinfo* pinfo; #if defined(SANSA_E200) || defined(SANSA_C200) int usb_retry = 0; bool usb = false; #else char buf[256]; unsigned short* identify_info; #endif chksum_crc32gentab (); system_init(); kernel_init(); lcd_init(); font_init(); button_init(); #if defined(SANSA_E200) i2c_init(); _backlight_on(); #endif #if LCD_DEPTH > 1 lcd_set_foreground(LCD_WHITE); lcd_set_background(LCD_BLACK); #endif lcd_clear_display(); if (button_hold()) { verbose = true; printf("Hold switch on"); printf("Shutting down..."); sleep(HZ); power_off(); } btn = button_read_device(); /* Enable bootloader messages if any button is pressed */ if (btn) verbose = true; #if defined(SANSA_E200) || defined(SANSA_C200) #if !defined(USE_ROCKBOX_USB) usb_init(); while (usb_drv_powered() && usb_retry < 5 && !usb) { usb_retry++; sleep(HZ/4); usb = (usb_detect() == USB_INSERTED); } if (usb) btn |= BOOTLOADER_BOOT_OF; #endif /* USE_ROCKBOX_USB */ #endif lcd_setfont(FONT_SYSFIXED); printf("Rockbox boot loader"); printf("Version: %s", version); printf(MODEL_NAME); i=ata_init(); #if !defined(SANSA_E200) && !defined(SANSA_C200) if (i==0) { identify_info=ata_get_identify(); /* Show model */ for (i=0; i < 20; i++) { ((unsigned short*)buf)[i]=htobe16(identify_info[i+27]); } buf[40]=0; for (i=39; i && buf[i]==' '; i--) { buf[i]=0; } printf(buf); } else { error(EATA, i); } #endif disk_init(IF_MV(0)); num_partitions = disk_mount_all(); if (num_partitions<=0) { error(EDISK,num_partitions); } /* Just list the first 2 partitions since we don't have any devices yet that have more than that */ for(i=0; itype, pinfo->size / 2048); } if(btn & BOOTLOADER_BOOT_OF) { /* Load original mi4 firmware in to a memory buffer called loadbuffer. The rest of the loading is done in crt0.S. 1) First try reading from the hidden partition (on Sansa only). 2) Next try a decrypted mi4 file in /System/OF.mi4 3) Finally, try a raw firmware binary in /System/OF.mi4. It should be a mi4 firmware decrypted and header stripped using mi4code. */ printf("Loading original firmware..."); #if defined(SANSA_E200) || defined(SANSA_C200) /* First try a (hidden) firmware partition */ printf("Trying firmware partition"); pinfo = disk_partinfo(1); if(pinfo->type == PARTITION_TYPE_OS2_HIDDEN_C_DRIVE) { rc = load_mi4_part(loadbuffer, pinfo, MAX_LOADSIZE, usb); if (rc < EOK) { printf("Can't load from partition"); printf(strerror(rc)); } else { return (void*)loadbuffer; } } else { printf("No hidden partition found."); } #endif printf("Trying /System/OF.mi4"); rc=load_mi4(loadbuffer, "/System/OF.mi4", MAX_LOADSIZE); if (rc < EOK) { printf("Can't load /System/OF.mi4"); printf(strerror(rc)); } else { return (void*)loadbuffer; } printf("Trying /System/OF.bin"); rc=load_raw_firmware(loadbuffer, "/System/OF.bin", MAX_LOADSIZE); if (rc < EOK) { printf("Can't load /System/OF.bin"); printf(strerror(rc)); } else { return (void*)loadbuffer; } error(0, 0); } else { #if 0 /* e200: enable to be able to dump the hidden partition */ if(btn & BUTTON_UP) { int fd; pinfo = disk_partinfo(1); fd = open("/part.bin", O_CREAT|O_RDWR); char sector[512]; for(i=0; i<40960; i++){ if (!(i%100)) { printf("dumping sector %d", i); } ata_read_sectors(IF_MV2(0,) pinfo->start + i, 1, sector); write(fd,sector,512); } close(fd); } #endif printf("Loading Rockbox..."); rc=load_mi4(loadbuffer, BOOTFILE, MAX_LOADSIZE); if (rc < EOK) { printf("Can't load %s:", BOOTFILE); printf(strerror(rc)); #ifdef OLD_BOOTFILE /* Try loading rockbox from old rockbox.e200/rockbox.h10 format */ rc=load_firmware(loadbuffer, OLD_BOOTFILE, MAX_LOADSIZE); if (rc < EOK) { printf("Can't load %s:", OLD_BOOTFILE); error(EBOOTFILE, rc); } #endif } } return (void*)loadbuffer; } #if !defined(SANSA_E200) && !defined(SANSA_C200) /* These functions are present in the firmware library, but we reimplement them here because the originals do a lot more than we want */ void usb_acknowledge(void) { } void usb_wait_for_disconnect(void) { } #endif