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bl.c
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bl.c
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/****************************************************************************
*
* Copyright (c) 2012-2014 PX4 Development Team. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in
* the documentation and/or other materials provided with the
* distribution.
* 3. Neither the name PX4 nor the names of its contributors may be
* used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
* FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
* COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
* BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
* OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
* AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN
* ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*
****************************************************************************/
/**
* @file bl.c
*
* Common bootloader logic.
*
* Aside from the header includes below, this file should have no board-specific logic.
*/
#include "hw_config.h"
#include <inttypes.h>
#include <stdlib.h>
#include <stdbool.h>
#include <string.h>
#include "bl.h"
#include "cdcacm.h"
#ifdef SECURE_BTL_ENABLED
#include "crypto_hal/crypto.h"
#endif
#include "uart.h"
// bootloader flash update protocol.
//
// Command format:
//
// <opcode>[<command_data>]<EOC>
//
// Reply format:
//
// [<reply_data>]<INSYNC><status>
//
// The <opcode> and <status> values come from the PROTO_ defines below,
// the <*_data> fields is described only for opcodes that transfer data;
// in all other cases the field is omitted.
//
// Expected workflow (protocol 3) is:
//
// GET_SYNC verify that the board is present
// GET_DEVICE determine which board (select firmware to upload)
// CHIP_ERASE erase the program area and reset address counter
// loop:
// PROG_MULTI program bytes
// GET_CRC verify CRC of entire flashable area
// RESET finalise flash programming, reset chip and starts application
//
#define BL_PROTOCOL_VERSION 5 // The revision of the bootloader protocol
//* Next revision needs to update
// protocol bytes
#define PROTO_INSYNC 0x12 // 'in sync' byte sent before status
#define PROTO_EOC 0x20 // end of command
// Reply bytes
#define PROTO_OK 0x10 // INSYNC/OK - 'ok' response
#define PROTO_FAILED 0x11 // INSYNC/FAILED - 'fail' response
#define PROTO_INVALID 0x13 // INSYNC/INVALID - 'invalid' response for bad commands
#define PROTO_BAD_SILICON_REV 0x14 // On the F4 series there is an issue with < Rev 3 silicon
#define PROTO_RESERVED_0X15 0x15 // Reserved
// see https://pixhawk.org/help/errata
// Command bytes
#define PROTO_GET_SYNC 0x21 // NOP for re-establishing sync
#define PROTO_GET_DEVICE 0x22 // get device ID bytes
#define PROTO_CHIP_ERASE 0x23 // erase program area and reset program address
#define PROTO_PROG_MULTI 0x27 // write bytes at program address and increment
#define PROTO_GET_CRC 0x29 // compute & return a CRC
#define PROTO_GET_OTP 0x2a // read a byte from OTP at the given address
#define PROTO_GET_SN 0x2b // read a word from UDID area ( Serial) at the given address
#define PROTO_GET_CHIP 0x2c // read chip version (MCU IDCODE)
#define PROTO_SET_DELAY 0x2d // set minimum boot delay
#define PROTO_GET_CHIP_DES 0x2e // read chip version In ASCII
#define PROTO_BOOT 0x30 // boot the application
#define PROTO_DEBUG 0x31 // emit debug information - format not defined
#define PROTO_SET_BAUD 0x33 // set baud rate on uart
#define PROTO_RESERVED_0X36 0x36 // Reserved
#define PROTO_RESERVED_0X37 0x37 // Reserved
#define PROTO_RESERVED_0X38 0x38 // Reserved
#define PROTO_RESERVED_0X39 0x39 // Reserved
#define PROTO_PROG_MULTI_MAX 64 // maximum PROG_MULTI size
#define PROTO_READ_MULTI_MAX 255 // size of the size field
/* argument values for PROTO_GET_DEVICE */
#define PROTO_DEVICE_BL_REV 1 // bootloader revision
#define PROTO_DEVICE_BOARD_ID 2 // board ID
#define PROTO_DEVICE_BOARD_REV 3 // board revision
#define PROTO_DEVICE_FW_SIZE 4 // size of flashable area
#define PROTO_DEVICE_VEC_AREA 5 // contents of reserved vectors 7-10
// State
#define STATE_PROTO_GET_SYNC 0x1 // Have Seen NOP for re-establishing sync
#define STATE_PROTO_GET_DEVICE 0x2 // Have Seen get device ID bytes
#define STATE_PROTO_CHIP_ERASE 0x4 // Have Seen erase program area and reset program address
#define STATE_PROTO_PROG_MULTI 0x8 // Have Seen write bytes at program address and increment
#define STATE_PROTO_GET_CRC 0x10 // Have Seen compute & return a CRC
#define STATE_PROTO_GET_OTP 0x20 // Have Seen read a byte from OTP at the given address
#define STATE_PROTO_GET_SN 0x40 // Have Seen read a word from UDID area ( Serial) at the given address
#define STATE_PROTO_GET_CHIP 0x80 // Have Seen read chip version (MCU IDCODE)
#define STATE_PROTO_GET_CHIP_DES 0x100 // Have Seen read chip version In ASCII
#define STATE_PROTO_BOOT 0x200 // Have Seen boot the application
#if defined(TARGET_HW_PX4_PIO_V1) || defined(TARGET_HW_MODALAI_VOXL2_IO)
#define STATE_ALLOWS_ERASE (STATE_PROTO_GET_SYNC)
#define STATE_ALLOWS_REBOOT (STATE_PROTO_GET_SYNC)
# define SET_BL_STATE(s)
# define SET_BL_FIRST_STATE(s) bl_state |= (s)
#else
#define STATE_ALLOWS_ERASE (STATE_PROTO_GET_SYNC|STATE_PROTO_GET_DEVICE)
#define STATE_ALLOWS_REBOOT (STATE_ALLOWS_ERASE|STATE_PROTO_PROG_MULTI|STATE_PROTO_GET_CRC)
# define SET_BL_STATE(s) bl_state |= (s)
# define SET_BL_FIRST_STATE(s) bl_state |= (s)
#endif
static uint8_t bl_type;
static uint8_t last_input;
inline void cinit(void *config, uint8_t interface)
{
#if INTERFACE_USB
if (interface == USB) {
return usb_cinit(config);
}
#endif
#if INTERFACE_USART
if (interface == USART) {
return uart_cinit(config);
}
#endif
}
inline void cfini(void)
{
#if INTERFACE_USB
usb_cfini();
#endif
#if INTERFACE_USART
uart_cfini();
#endif
}
inline int cin(uint32_t devices)
{
#if INTERFACE_USB
if ((bl_type == NONE || bl_type == USB) && (devices & USB0_DEV) != 0) {
int usb_in = usb_cin();
if (usb_in >= 0) {
last_input = USB;
return usb_in;
}
}
#endif
#if INTERFACE_USART
if ((bl_type == NONE || bl_type == USART) && (devices & SERIAL0_DEV) != 0) {
int uart_in = uart_cin();
if (uart_in >= 0) {
last_input = USART;
return uart_in;
}
}
#endif
return -1;
}
inline void cout(uint8_t *buf, unsigned len)
{
#if INTERFACE_USB
if (bl_type == USB) {
usb_cout(buf, len);
}
#endif
#if INTERFACE_USART
if (bl_type == USART) {
uart_cout(buf, len);
}
#endif
}
/* The PX4IO is so low on FLASH that this abstaction is not possible as
* a called API. Therefore these macros are needed.
*/
#if defined(TARGET_HW_PX4_PIO_V1) || defined(TARGET_HW_MODALAI_VOXL2_IO)
# include <libopencm3/stm32/flash.h>
#include <libopencm3/cm3/systick.h>
#include <libopencm3/cm3/scb.h>
#define arch_systic_init(d) \
systick_set_clocksource(STK_CSR_CLKSOURCE_AHB); \
systick_set_reload(board_info.systick_mhz * 1000); \
systick_interrupt_enable(); \
systick_counter_enable();
#define arch_systic_deinit() \
systick_interrupt_disable(); \
systick_counter_disable();
#define arch_flash_lock flash_lock
#define arch_flash_unlock flash_unlock
#define arch_setvtor(address) SCB_VTOR = address;
#endif
static const uint32_t bl_proto_rev = BL_PROTOCOL_VERSION; // value returned by PROTO_DEVICE_BL_REV
static unsigned head, tail;
static uint8_t rx_buf[256] USB_DATA_ALIGN;
static enum led_state {LED_BLINK, LED_ON, LED_OFF} _led_state;
void sys_tick_handler(void);
void
buf_put(uint8_t b)
{
unsigned next = (head + 1) % sizeof(rx_buf);
if (next != tail) {
rx_buf[head] = b;
head = next;
}
}
int
buf_get(void)
{
int ret = -1;
if (tail != head) {
ret = rx_buf[tail];
tail = (tail + 1) % sizeof(rx_buf);
}
return ret;
}
static void
do_jump(uint32_t stacktop, uint32_t entrypoint)
{
asm volatile(
"msr msp, %0 \n"
"bx %1 \n"
: : "r"(stacktop), "r"(entrypoint) :);
// just to keep noreturn happy
for (;;) ;
}
void
jump_to_app()
{
const uint32_t *app_base = (const uint32_t *)APP_LOAD_ADDRESS;
const uint32_t *vec_base = (const uint32_t *)app_base;
/*
* We refuse to program the first word of the app until the upload is marked
* complete by the host. So if it's not 0xffffffff, we should try booting it.
*/
if (app_base[0] == 0xffffffff) {
return;
}
#ifdef SECURE_BTL_ENABLED
const image_toc_entry_t *toc_entries;
uint8_t len;
uint8_t i = 0;
/* When secure btl is used, the address comes from the TOC */
app_base = (const uint32_t *)0;
vec_base = (const uint32_t *)0;
/* TOC not found or empty, stay in btl */
if (!find_toc(&toc_entries, &len)) {
return;
}
/* Verify the first entry, containing the TOC itself */
if (!verify_app(0, toc_entries)) {
/* Image verification failed, stay in btl */
return;
}
/* TOC is verified, loop through all the apps and perform crypto ops */
for (i = 0; i < len; i++) {
/* Verify app, if needed. i == 0 is already verified */
if (i != 0 &&
toc_entries[i].flags1 & TOC_FLAG1_CHECK_SIGNATURE &&
!verify_app(i, toc_entries)) {
/* Signature check failed, don't process this app */
continue;
}
/* Check if this app needs decryption */
if (toc_entries[i].flags1 & TOC_FLAG1_DECRYPT &&
!decrypt_app(i, toc_entries)) {
/* Decryption / authenticated decryption failed, skip this app */
continue;
}
/* Check if this app needs to be copied to RAM */
if (toc_entries[i].flags1 & TOC_FLAG1_COPY) {
/* TOC is verified, so we assume that the addresses are good */
memcpy(toc_entries[i].target, toc_entries[i].start,
(uintptr_t)toc_entries[i].end - (uintptr_t)toc_entries[i].start);
}
/* Check if this app is bootable, if so set the app_base */
if (toc_entries[i].flags1 & TOC_FLAG1_BOOT) {
app_base = get_base_addr(&toc_entries[i]);
}
/* Check if this app has vectors, if so set the vec_base */
if (toc_entries[i].flags1 & TOC_FLAG1_VTORS) {
vec_base = get_base_addr(&toc_entries[i]);
}
}
if (app_base == 0) {
/* No bootable app found in TOC, bail out */
return;
}
if (vec_base == 0) {
/* No separate vectors block, vectors come along with the app */
vec_base = app_base;
}
#endif
/*
* The second word of the app is the entrypoint; it must point within the
* flash area (or we have a bad flash).
*/
if (app_base[1] < APP_LOAD_ADDRESS) {
return;
}
if (app_base[1] >= (APP_LOAD_ADDRESS + board_info.fw_size)) {
return;
}
/* just for paranoia's sake */
arch_flash_lock();
/* kill the systick interrupt */
arch_systic_deinit();
/* deinitialise the interface */
cfini();
/* reset the clock */
clock_deinit();
/* deinitialise the board */
board_deinit();
/* switch exception handlers to the application */
arch_setvtor((uint32_t)vec_base);
/* extract the stack and entrypoint from the app vector table and go */
do_jump(app_base[0], app_base[1]);
}
volatile unsigned timer[NTIMERS];
void
sys_tick_handler(void)
{
unsigned i;
for (i = 0; i < NTIMERS; i++)
if (timer[i] > 0) {
timer[i]--;
}
if ((_led_state == LED_BLINK) && (timer[TIMER_LED] == 0)) {
led_toggle(LED_BOOTLOADER);
timer[TIMER_LED] = 50;
}
}
void
delay(unsigned msec)
{
timer[TIMER_DELAY] = msec;
while (timer[TIMER_DELAY] > 0)
;
}
static void
led_set(enum led_state state)
{
_led_state = state;
switch (state) {
case LED_OFF:
led_off(LED_BOOTLOADER);
break;
case LED_ON:
led_on(LED_BOOTLOADER);
break;
case LED_BLINK:
/* restart the blink state machine ASAP */
timer[TIMER_LED] = 0;
break;
}
}
static void
sync_response(void)
{
uint8_t data[] = {
PROTO_INSYNC, // "in sync"
PROTO_OK // "OK"
};
cout(data, sizeof(data));
}
#if defined(TARGET_HW_PX4_FMU_V4) || defined(TARGET_HW_UVIFY_CORE)
static void
bad_silicon_response(void)
{
uint8_t data[] = {
PROTO_INSYNC, // "in sync"
PROTO_BAD_SILICON_REV // "issue with < Rev 3 silicon"
};
cout(data, sizeof(data));
}
#endif
static void
invalid_response(void)
{
uint8_t data[] = {
PROTO_INSYNC, // "in sync"
PROTO_INVALID // "invalid command"
};
cout(data, sizeof(data));
}
static void
failure_response(void)
{
uint8_t data[] = {
PROTO_INSYNC, // "in sync"
PROTO_FAILED // "command failed"
};
cout(data, sizeof(data));
}
static int
cin_wait(unsigned timeout)
{
int c = -1;
/* start the timeout */
timer[TIMER_CIN] = timeout;
do {
c = cin(board_get_devices());
if (c >= 0) {
break;
}
} while (timer[TIMER_CIN] > 0);
return c;
}
/**
* Function to wait for EOC
*
* @param timeout length of time in ms to wait for the EOC to be received
* @return true if the EOC is returned within the timeout perio, else false
*/
inline static bool
wait_for_eoc(unsigned timeout)
{
return cin_wait(timeout) == PROTO_EOC;
}
static void
cout_word(uint32_t val)
{
cout((uint8_t *)&val, 4);
}
#ifndef NO_OTP_SN_CHIP
static int
cin_word(uint32_t *wp, unsigned timeout)
{
union {
uint32_t w;
uint8_t b[4];
} u;
for (unsigned i = 0; i < 4; i++) {
int c = cin_wait(timeout);
if (c < 0) {
return c;
}
u.b[i] = c & 0xff;
}
*wp = u.w;
return 0;
}
#endif
static uint32_t
crc32(const uint8_t *src, unsigned len, unsigned state)
{
static uint32_t crctab[256];
/* check whether we have generated the CRC table yet */
/* this is much smaller than a static table */
if (crctab[1] == 0) {
for (unsigned i = 0; i < 256; i++) {
uint32_t c = i;
for (unsigned j = 0; j < 8; j++) {
if (c & 1) {
c = 0xedb88320U ^ (c >> 1);
} else {
c = c >> 1;
}
}
crctab[i] = c;
}
}
for (unsigned i = 0; i < len; i++) {
state = crctab[(state ^ src[i]) & 0xff] ^ (state >> 8);
}
return state;
}
void
bootloader(unsigned timeout)
{
bl_type = NONE; // The type of the bootloader, whether loading from USB or USART, will be determined by on what port the bootloader recevies its first valid command.
volatile uint32_t bl_state = 0; // Must see correct command sequence to erase and reboot (commit first word)
uint32_t address = board_info.fw_size; /* force erase before upload will work */
uint32_t first_word = 0xffffffff;
/* (re)start the timer system */
arch_systic_init();
/* if we are working with a timeout, start it running */
if (timeout) {
timer[TIMER_BL_WAIT] = timeout;
}
/* make the LED blink while we are idle */
led_set(LED_BLINK);
while (true) {
volatile int c;
int arg;
static union {
uint8_t c[256];
uint32_t w[64];
} flash_buffer;
// Wait for a command byte
led_off(LED_ACTIVITY);
do {
/* if we have a timeout and the timer has expired, return now */
if (timeout && !timer[TIMER_BL_WAIT]) {
return;
}
/* try to get a byte from the host */
c = cin_wait(0);
} while (c < 0);
led_on(LED_ACTIVITY);
// handle the command byte
switch (c) {
// sync
//
// command: GET_SYNC/EOC
// reply: INSYNC/OK
//
case PROTO_GET_SYNC:
/* expect EOC */
if (!wait_for_eoc(2)) {
goto cmd_bad;
}
SET_BL_FIRST_STATE(STATE_PROTO_GET_SYNC);
break;
// get device info
//
// command: GET_DEVICE/<arg:1>/EOC
// BL_REV reply: <revision:4>/INSYNC/EOC
// BOARD_ID reply: <board type:4>/INSYNC/EOC
// BOARD_REV reply: <board rev:4>/INSYNC/EOC
// FW_SIZE reply: <firmware size:4>/INSYNC/EOC
// VEC_AREA reply <vectors 7-10:16>/INSYNC/EOC
// bad arg reply: INSYNC/INVALID
//
case PROTO_GET_DEVICE:
/* expect arg then EOC */
arg = cin_wait(1000);
if (arg < 0) {
goto cmd_bad;
}
if (!wait_for_eoc(2)) {
goto cmd_bad;
}
switch (arg) {
case PROTO_DEVICE_BL_REV:
cout((uint8_t *)&bl_proto_rev, sizeof(bl_proto_rev));
break;
case PROTO_DEVICE_BOARD_ID:
cout((uint8_t *)&board_info.board_type, sizeof(board_info.board_type));
break;
case PROTO_DEVICE_BOARD_REV:
cout((uint8_t *)&board_info.board_rev, sizeof(board_info.board_rev));
break;
case PROTO_DEVICE_FW_SIZE:
cout((uint8_t *)&board_info.fw_size, sizeof(board_info.fw_size));
break;
case PROTO_DEVICE_VEC_AREA:
for (unsigned p = 7; p <= 10; p++) {
uint32_t bytes = flash_func_read_word(p * 4);
cout((uint8_t *)&bytes, sizeof(bytes));
}
break;
default:
goto cmd_bad;
}
SET_BL_STATE(STATE_PROTO_GET_DEVICE);
break;
// erase and prepare for programming
//
// command: ERASE/EOC
// success reply: INSYNC/OK
// erase failure: INSYNC/FAILURE
//
case PROTO_CHIP_ERASE:
/* expect EOC */
if (!wait_for_eoc(2)) {
goto cmd_bad;
}
#if defined(TARGET_HW_PX4_FMU_V4) || defined(TARGET_HW_UVIFY_CORE)
if (check_silicon()) {
goto bad_silicon;
}
#endif
if ((bl_state & STATE_ALLOWS_ERASE) != STATE_ALLOWS_ERASE) {
goto cmd_bad;
}
// clear the bootloader LED while erasing - it stops blinking at random
// and that's confusing
led_set(LED_ON);
// erase all sectors
arch_flash_unlock();
for (int i = 0; flash_func_sector_size(i) != 0; i++) {
flash_func_erase_sector(i);
}
// disable the LED while verifying the erase
led_set(LED_OFF);
// verify the erase
for (address = 0; address < board_info.fw_size; address += 4)
if (flash_func_read_word(address) != 0xffffffff) {
goto cmd_fail;
}
address = 0;
SET_BL_STATE(STATE_PROTO_CHIP_ERASE);
// resume blinking
led_set(LED_BLINK);
break;
// program bytes at current address
//
// command: PROG_MULTI/<len:1>/<data:len>/EOC
// success reply: INSYNC/OK
// invalid reply: INSYNC/INVALID
// readback failure: INSYNC/FAILURE
//
case PROTO_PROG_MULTI: // program bytes
// expect count
arg = cin_wait(50);
if (arg < 0) {
goto cmd_bad;
}
// sanity-check arguments
if (arg % 4) {
goto cmd_bad;
}
if ((address + arg) > board_info.fw_size) {
goto cmd_bad;
}
if ((unsigned int)arg > sizeof(flash_buffer.c)) {
goto cmd_bad;
}
for (int i = 0; i < arg; i++) {
c = cin_wait(1000);
if (c < 0) {
goto cmd_bad;
}
flash_buffer.c[i] = c;
}
if (!wait_for_eoc(200)) {
goto cmd_bad;
}
if (address == 0) {
#if defined(TARGET_HW_PX4_FMU_V4) || defined(TARGET_HW_UVIFY_CORE)
if (check_silicon()) {
goto bad_silicon;
}
#endif
// save the first word and don't program it until everything else is done
first_word = flash_buffer.w[0];
// replace first word with bits we can overwrite later
flash_buffer.w[0] = 0xffffffff;
}
arg /= 4;
for (int i = 0; i < arg; i++) {
// program the word
flash_func_write_word(address, flash_buffer.w[i]);
// do immediate read-back verify
if (flash_func_read_word(address) != flash_buffer.w[i]) {
goto cmd_fail;
}
address += 4;
}
SET_BL_STATE(STATE_PROTO_PROG_MULTI);
break;
// fetch CRC of the entire flash area
//
// command: GET_CRC/EOC
// reply: <crc:4>/INSYNC/OK
//
case PROTO_GET_CRC:
// expect EOC
if (!wait_for_eoc(2)) {
goto cmd_bad;
}
// compute CRC of the programmed area
uint32_t sum = 0;
for (unsigned p = 0; p < board_info.fw_size; p += 4) {
uint32_t bytes;
if ((p == 0) && (first_word != 0xffffffff)) {
bytes = first_word;
} else {
bytes = flash_func_read_word(p);
}
sum = crc32((uint8_t *)&bytes, sizeof(bytes), sum);
}
cout_word(sum);
SET_BL_STATE(STATE_PROTO_GET_CRC);
break;
#ifndef NO_OTP_SN_CHIP
// read a word from the OTP
//
// command: GET_OTP/<addr:4>/EOC
// reply: <value:4>/INSYNC/OK
case PROTO_GET_OTP:
// expect argument
{
uint32_t index = 0;
if (cin_word(&index, 100)) {
goto cmd_bad;
}
// expect EOC
if (!wait_for_eoc(2)) {
goto cmd_bad;
}
cout_word(flash_func_read_otp(index));
}
break;
// read the SN from the UDID
//
// command: GET_SN/<addr:4>/EOC
// reply: <value:4>/INSYNC/OK
case PROTO_GET_SN:
// expect argument
{
uint32_t index = 0;
if (cin_word(&index, 100)) {
goto cmd_bad;
}
// expect EOC
if (!wait_for_eoc(2)) {
goto cmd_bad;
}
// expect valid indices 0, 4 ...ARCH_SN_MAX_LENGTH-4
if (index % sizeof(uint32_t) != 0 || index > ARCH_SN_MAX_LENGTH - sizeof(uint32_t)) {
goto cmd_bad;
}
cout_word(flash_func_read_sn(index));
}
SET_BL_STATE(STATE_PROTO_GET_SN);
break;
// read the chip ID code
//
// command: GET_CHIP/EOC
// reply: <value:4>/INSYNC/OK
case PROTO_GET_CHIP: {
// expect EOC
if (!wait_for_eoc(2)) {
goto cmd_bad;
}
cout_word(get_mcu_id());
SET_BL_STATE(STATE_PROTO_GET_CHIP);
}
break;
// read the chip description
//
// command: GET_CHIP_DES/EOC
// reply: <value:4>/INSYNC/OK
case PROTO_GET_CHIP_DES: {
uint8_t buffer[MAX_DES_LENGTH];
unsigned len = MAX_DES_LENGTH;
// expect EOC
if (!wait_for_eoc(2)) {
goto cmd_bad;
}
len = get_mcu_desc(len, buffer);
cout_word(len);
cout(buffer, len);
SET_BL_STATE(STATE_PROTO_GET_CHIP_DES);
}
break;
#endif
#ifdef BOOT_DELAY_ADDRESS
case PROTO_SET_DELAY: {
/*
Allow for the bootloader to setup a
boot delay signature which tells the
board to delay for at least a
specified number of seconds on boot.
*/
int v = cin_wait(100);
if (v < 0) {
goto cmd_bad;
}
uint8_t boot_delay = v & 0xFF;
if (boot_delay > BOOT_DELAY_MAX) {
goto cmd_bad;
}
// expect EOC
if (!wait_for_eoc(2)) {
goto cmd_bad;
}
uint32_t sig1 = flash_func_read_word(BOOT_DELAY_ADDRESS);
uint32_t sig2 = flash_func_read_word(BOOT_DELAY_ADDRESS + 4);
if (sig1 != BOOT_DELAY_SIGNATURE1 ||
sig2 != BOOT_DELAY_SIGNATURE2) {