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openpilot_comma
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openpilot is an open source driver assistance system. openpilot performs the functions of Automated Lane Centering and Adaptive Cruise Control for over 200 supported car makes and models.
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openpilot_comma/board/boards/white.h

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// /////////// //
// White Panda //
// /////////// //
void white_enable_can_transciever(uint8_t transciever, bool enabled) {
switch (transciever){
case 1U:
set_gpio_output(GPIOC, 1, !enabled);
break;
case 2U:
set_gpio_output(GPIOC, 13, !enabled);
break;
case 3U:
set_gpio_output(GPIOA, 0, !enabled);
break;
default:
puts("Invalid CAN transciever ("); puth(transciever); puts("): enabling failed\n");
break;
}
}
void white_enable_can_transcievers(bool enabled) {
for(uint8_t i=1; i<=3U; i++)
white_enable_can_transciever(i, enabled);
}
void white_set_led(uint8_t color, bool enabled) {
switch (color){
case LED_RED:
set_gpio_output(GPIOC, 9, !enabled);
break;
case LED_GREEN:
set_gpio_output(GPIOC, 7, !enabled);
break;
case LED_BLUE:
set_gpio_output(GPIOC, 6, !enabled);
break;
default:
break;
}
}
void white_set_usb_power_mode(uint8_t mode){
bool valid_mode = true;
switch (mode) {
case USB_POWER_CLIENT:
// B2,A13: set client mode
set_gpio_output(GPIOB, 2, 0);
set_gpio_output(GPIOA, 13, 1);
break;
case USB_POWER_CDP:
// B2,A13: set CDP mode
set_gpio_output(GPIOB, 2, 1);
set_gpio_output(GPIOA, 13, 1);
break;
case USB_POWER_DCP:
// B2,A13: set DCP mode on the charger (breaks USB!)
set_gpio_output(GPIOB, 2, 0);
set_gpio_output(GPIOA, 13, 0);
break;
default:
valid_mode = false;
puts("Invalid usb power mode\n");
break;
}
if (valid_mode) {
usb_power_mode = mode;
}
}
void white_set_esp_gps_mode(uint8_t mode) {
switch (mode) {
case ESP_GPS_DISABLED:
// ESP OFF
set_gpio_output(GPIOC, 14, 0);
set_gpio_output(GPIOC, 5, 0);
break;
case ESP_GPS_ENABLED:
// ESP ON
set_gpio_output(GPIOC, 14, 1);
set_gpio_output(GPIOC, 5, 1);
break;
case ESP_GPS_BOOTMODE:
set_gpio_output(GPIOC, 14, 1);
set_gpio_output(GPIOC, 5, 0);
break;
default:
puts("Invalid ESP/GPS mode\n");
break;
}
}
void white_set_can_mode(uint8_t mode){
switch (mode) {
case CAN_MODE_NORMAL:
// B12,B13: disable GMLAN mode
set_gpio_mode(GPIOB, 12, MODE_INPUT);
set_gpio_mode(GPIOB, 13, MODE_INPUT);
// B3,B4: disable GMLAN mode
set_gpio_mode(GPIOB, 3, MODE_INPUT);
set_gpio_mode(GPIOB, 4, MODE_INPUT);
// B5,B6: normal CAN2 mode
set_gpio_alternate(GPIOB, 5, GPIO_AF9_CAN2);
set_gpio_alternate(GPIOB, 6, GPIO_AF9_CAN2);
// A8,A15: normal CAN3 mode
set_gpio_alternate(GPIOA, 8, GPIO_AF11_CAN3);
set_gpio_alternate(GPIOA, 15, GPIO_AF11_CAN3);
break;
case CAN_MODE_GMLAN_CAN2:
// B5,B6: disable CAN2 mode
set_gpio_mode(GPIOB, 5, MODE_INPUT);
set_gpio_mode(GPIOB, 6, MODE_INPUT);
// B3,B4: disable GMLAN mode
set_gpio_mode(GPIOB, 3, MODE_INPUT);
set_gpio_mode(GPIOB, 4, MODE_INPUT);
// B12,B13: GMLAN mode
set_gpio_alternate(GPIOB, 12, GPIO_AF9_CAN2);
set_gpio_alternate(GPIOB, 13, GPIO_AF9_CAN2);
// A8,A15: normal CAN3 mode
set_gpio_alternate(GPIOA, 8, GPIO_AF11_CAN3);
set_gpio_alternate(GPIOA, 15, GPIO_AF11_CAN3);
break;
case CAN_MODE_GMLAN_CAN3:
// A8,A15: disable CAN3 mode
set_gpio_mode(GPIOA, 8, MODE_INPUT);
set_gpio_mode(GPIOA, 15, MODE_INPUT);
// B12,B13: disable GMLAN mode
set_gpio_mode(GPIOB, 12, MODE_INPUT);
set_gpio_mode(GPIOB, 13, MODE_INPUT);
// B3,B4: GMLAN mode
set_gpio_alternate(GPIOB, 3, GPIO_AF11_CAN3);
set_gpio_alternate(GPIOB, 4, GPIO_AF11_CAN3);
// B5,B6: normal CAN2 mode
set_gpio_alternate(GPIOB, 5, GPIO_AF9_CAN2);
set_gpio_alternate(GPIOB, 6, GPIO_AF9_CAN2);
break;
default:
puts("Tried to set unsupported CAN mode: "); puth(mode); puts("\n");
break;
}
}
uint64_t marker = 0;
void white_usb_power_mode_tick(uint64_t tcnt){
#ifndef BOOTSTUB
#define CURRENT_THRESHOLD 0xF00U
#define CLICKS 5U // 5 seconds to switch modes
uint32_t current = adc_get(ADCCHAN_CURRENT);
// ~0x9a = 500 ma
// puth(current); puts("\n");
switch (usb_power_mode) {
case USB_POWER_CLIENT:
if ((tcnt - marker) >= CLICKS) {
if (!is_enumerated) {
puts("USBP: didn't enumerate, switching to CDP mode\n");
// switch to CDP
white_set_usb_power_mode(USB_POWER_CDP);
marker = tcnt;
}
}
// keep resetting the timer if it's enumerated
if (is_enumerated) {
marker = tcnt;
}
break;
case USB_POWER_CDP:
// On the EON, if we get into CDP mode we stay here. No need to go to DCP.
#ifndef EON
// been CLICKS clicks since we switched to CDP
if ((tcnt-marker) >= CLICKS) {
// measure current draw, if positive and no enumeration, switch to DCP
if (!is_enumerated && (current < CURRENT_THRESHOLD)) {
puts("USBP: no enumeration with current draw, switching to DCP mode\n");
white_set_usb_power_mode(USB_POWER_DCP);
marker = tcnt;
}
}
// keep resetting the timer if there's no current draw in CDP
if (current >= CURRENT_THRESHOLD) {
marker = tcnt;
}
#endif
break;
case USB_POWER_DCP:
// been at least CLICKS clicks since we switched to DCP
if ((tcnt-marker) >= CLICKS) {
// if no current draw, switch back to CDP
if (current >= CURRENT_THRESHOLD) {
puts("USBP: no current draw, switching back to CDP mode\n");
white_set_usb_power_mode(USB_POWER_CDP);
marker = tcnt;
}
}
// keep resetting the timer if there's current draw in DCP
if (current < CURRENT_THRESHOLD) {
marker = tcnt;
}
break;
default:
puts("USB power mode invalid\n"); // set_usb_power_mode prevents assigning invalid values
break;
}
#else
UNUSED(tcnt);
#endif
}
bool white_check_ignition(void){
// ignition is on PA1
return !get_gpio_input(GPIOA, 1);
}
void white_init(void) {
common_init_gpio();
// C3: current sense
set_gpio_mode(GPIOC, 3, MODE_ANALOG);
// A1: started_alt
set_gpio_pullup(GPIOA, 1, PULL_UP);
// A2, A3: USART 2 for debugging
set_gpio_alternate(GPIOA, 2, GPIO_AF7_USART2);
set_gpio_alternate(GPIOA, 3, GPIO_AF7_USART2);
// A4, A5, A6, A7: SPI
set_gpio_alternate(GPIOA, 4, GPIO_AF5_SPI1);
set_gpio_alternate(GPIOA, 5, GPIO_AF5_SPI1);
set_gpio_alternate(GPIOA, 6, GPIO_AF5_SPI1);
set_gpio_alternate(GPIOA, 7, GPIO_AF5_SPI1);
// Set USB power mode
white_set_usb_power_mode(USB_POWER_CLIENT);
// B12: GMLAN, ignition sense, pull up
set_gpio_pullup(GPIOB, 12, PULL_UP);
/* GMLAN mode pins:
M0(B15) M1(B14) mode
=======================
0 0 sleep
1 0 100kbit
0 1 high voltage wakeup
1 1 33kbit (normal)
*/
set_gpio_output(GPIOB, 14, 1);
set_gpio_output(GPIOB, 15, 1);
// B7: K-line enable
set_gpio_output(GPIOB, 7, 1);
// C12, D2: Setup K-line (UART5)
set_gpio_alternate(GPIOC, 12, GPIO_AF8_UART5);
set_gpio_alternate(GPIOD, 2, GPIO_AF8_UART5);
set_gpio_pullup(GPIOD, 2, PULL_UP);
// L-line enable
set_gpio_output(GPIOA, 14, 1);
// C10, C11: L-Line setup (USART3)
set_gpio_alternate(GPIOC, 10, GPIO_AF7_USART3);
set_gpio_alternate(GPIOC, 11, GPIO_AF7_USART3);
set_gpio_pullup(GPIOC, 11, PULL_UP);
// Enable CAN transcievers
white_enable_can_transcievers(true);
// Disable LEDs
white_set_led(LED_RED, false);
white_set_led(LED_GREEN, false);
white_set_led(LED_BLUE, false);
// Set normal CAN mode
white_set_can_mode(CAN_MODE_NORMAL);
}
const harness_configuration white_harness_config = {
.has_harness = false
};
const board board_white = {
.board_type = "White",
.harness_config = &white_harness_config,
.init = white_init,
.enable_can_transciever = white_enable_can_transciever,
.enable_can_transcievers = white_enable_can_transcievers,
.set_led = white_set_led,
.set_usb_power_mode = white_set_usb_power_mode,
.set_esp_gps_mode = white_set_esp_gps_mode,
.set_can_mode = white_set_can_mode,
.usb_power_mode_tick = white_usb_power_mode_tick,
.check_ignition = white_check_ignition
};