rockbox/bootloader/main-pp.c

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/***************************************************************************
* __________ __ ___.
* 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 <stdio.h>
#include <stdlib.h>
#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 <string.h>
#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_LEFT
#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 } },
};
/*
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();
Add working dual-boot bootloaders for H10 and Sansa, which allow booting the OF and Rockbox. Rolo also works. Changes made: Combine bootloader/h10.c and bootloader/e200.c into a common bootloader file (bootloader/main-pp.c) to be used by all mi4 based PortalPlayer targets. The file bootloader/main-pp.c is based off the old bootloader/h10.c with some minor changes to allow it to work on the Sansa too. This effectively adds a Sansa bootloader. Define MODEL_NAME string in config-*.h for use in bootloader. Split crt0-pp.S into separate files for bootloader and normal builds. Bootloader code is now in crt0-pp-bl.S while normal build code stays in crt0-pp.S. Improvements to crt0-pp.S and crt0-pp-bl.S (mostly to make it more multiprocessor safe): * Leave space in bootloader at 0xe0-0xeb since scramble writes over there when it creates the mi4 file (don't leave space for iPods since it's not needed and all code in crt0-pp-bl.S needs to fit before the boot_table at 0x100). * Remove unused DEBUG and STUB code from crt0-pp.S. * Make CPU wait for COP to be sleeping when we put the COP to sleep. * Invalidate COP cache when COP wakes * Flush CPU cache before waking COP * Make sure only the CPU clears the BSS (not the COP) * Make sure only the CPU sets up its own stack (not the COP) Rolo works on H10, so enable it. Make Sansa e200 use rockbox.e200 rather than PP5022.mi4 for 'Normal' builds. This makes updating rockbox simpler as we don't need to go through the firmware update procedure, but rather just put a new rockbox.e200 on the device. rockbox.e200 uses a simple 'add' checksum. git-svn-id: svn://svn.rockbox.org/rockbox/trunk@11815 a1c6a512-1295-4272-9138-f99709370657
2006-12-19 11:33:53 +00:00
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();
#if defined(SANSA_E200) || defined(SANSA_C200)
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
/* Enable bootloader messages if any button is pressed */
if (btn)
verbose = true;
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; i<NUM_PARTITIONS; i++)
{
pinfo = disk_partinfo(i);
printf("Partition %d: 0x%02x %ld MB",
i, pinfo->type, 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