void USBD_Composite_Unregister_All() {
int32_t irq = HAL_disable_irq();
s_Classes = NULL;
s_Classes_Count = 0;
memset(s_Class_Entries, 0, sizeof(s_Class_Entries));
HAL_enable_irq(irq);
}
int HAL_Set_Direct_Interrupt_Handler(IRQn_Type irqn, HAL_Direct_Interrupt_Handler handler, uint32_t flags, void* reserved)
{
if (irqn < NonMaskableInt_IRQn || irqn > HASH_RNG_IRQn) {
return 1;
}
int32_t state = HAL_disable_irq();
volatile uint32_t* isrs = (volatile uint32_t*)SCB->VTOR;
if (handler == NULL && (flags & HAL_DIRECT_INTERRUPT_FLAG_RESTORE)) {
// Restore
HAL_Core_Restore_Interrupt(irqn);
} else {
isrs[IRQN_TO_IDX(irqn)] = (uint32_t)handler;
}
if (flags & HAL_DIRECT_INTERRUPT_FLAG_DISABLE) {
// Disable
NVIC_DisableIRQ(irqn);
} else if (flags & HAL_DIRECT_INTERRUPT_FLAG_ENABLE) {
NVIC_EnableIRQ(irqn);
}
HAL_enable_irq(state);
return 0;
}
void HAL_USART_Send_Break(HAL_USART_Serial serial, void* reserved)
{
int32_t state = HAL_disable_irq();
while((usartMap[serial]->usart_peripheral->CR1 & USART_CR1_SBK) == SET);
USART_SendBreak(usartMap[serial]->usart_peripheral);
while((usartMap[serial]->usart_peripheral->CR1 & USART_CR1_SBK) == SET);
HAL_enable_irq(state);
}
void panic_(ePanicCode code, void* extraInfo, void (*HAL_Delay_Microseconds)(uint32_t))
{
HAL_disable_irq();
// Flush any serial message to help the poor bugger debug this;
flash_codes_t pcd = flash_codes[code];
LED_SetRGBColor(RGB_COLOR_RED);
LED_SetBrightness(DEFAULT_LED_RGB_BRIGHTNESS);
LED_Signaling_Stop();
uint16_t c;
int loops = 2;
log_direct_("!");
LED_Off(LED_RGB);
while(loops) {
// preamble
for (c = 3; c; c--) {
LED_SetRGBColor(pcd.led);
LED_On(LED_RGB);
HAL_Delay_Microseconds(MS2u(150));
LED_Off(LED_RGB);
HAL_Delay_Microseconds(MS2u(100));
}
HAL_Delay_Microseconds(MS2u(100));
for (c = 3; c; c--) {
LED_SetRGBColor(pcd.led);
LED_On(LED_RGB);
HAL_Delay_Microseconds(MS2u(300));
LED_Off(LED_RGB);
HAL_Delay_Microseconds(MS2u(100));
}
HAL_Delay_Microseconds(MS2u(100));
for (c = 3; c; c--) {
LED_SetRGBColor(pcd.led);
LED_On(LED_RGB);
HAL_Delay_Microseconds(MS2u(150));
LED_Off(LED_RGB);
HAL_Delay_Microseconds(MS2u(100));
}
// pause
HAL_Delay_Microseconds(MS2u(900));
// play code
for (c = code; c; c--) {
LED_SetRGBColor(pcd.led);
LED_On(LED_RGB);
HAL_Delay_Microseconds(MS2u(300));
LED_Off(LED_RGB);
HAL_Delay_Microseconds(MS2u(300));
}
// pause
HAL_Delay_Microseconds(MS2u(800));
#ifdef RELEASE_BUILD
if (--loops == 0) HAL_Core_System_Reset();
#endif
}
}
void USBD_Composite_Set_State(void* cls, bool state) {
int32_t irq = HAL_disable_irq();
for(USBD_Composite_Class_Data* c = s_Classes; c != NULL; c = c->next) {
if (cls && c == cls) {
c->active = state;
break;
}
}
HAL_enable_irq(irq);
}
int32_t HAL_USB_USART_Available_Data(HAL_USB_USART_Serial serial)
{
int32_t available = 0;
int state = HAL_disable_irq();
available = ring_data_avail(usbUsartMap[serial].data->rx_buffer_length,
usbUsartMap[serial].data->rx_buffer_head,
usbUsartMap[serial].data->rx_buffer_tail);
HAL_enable_irq(state);
return available;
}
void HAL_USB_USART_Init(HAL_USB_USART_Serial serial, const HAL_USB_USART_Config* config)
{
if (usbUsartMap[serial].data == NULL) {
usbUsartMap[serial].data = &usbUsartInstanceData[serial];
if (serial == HAL_USB_USART_SERIAL) {
usbUsartMap[serial].data->ep_in_data = CDC0_IN_EP;
usbUsartMap[serial].data->ep_in_int = CDC0_CMD_EP;
usbUsartMap[serial].data->ep_out_data = CDC0_OUT_EP;
usbUsartMap[serial].data->name = USBD_PRODUCT_STRING " " "Serial";
} else if (serial == HAL_USB_USART_SERIAL1) {
usbUsartMap[serial].data->ep_in_data = CDC1_IN_EP;
usbUsartMap[serial].data->ep_in_int = CDC1_CMD_EP;
usbUsartMap[serial].data->ep_out_data = CDC1_OUT_EP;
usbUsartMap[serial].data->name = USBD_PRODUCT_STRING " " "USBSerial1";
}
usbUsartMap[serial].data->req_handler = HAL_USB_USART_Request_Handler;
}
if (config && (
usbUsartMap[serial].data->rx_buffer == NULL ||
usbUsartMap[serial].data->rx_buffer_size == 0 ||
usbUsartMap[serial].data->tx_buffer == NULL ||
usbUsartMap[serial].data->tx_buffer_size == 0))
{
HAL_USB_USART_Config conf;
memset(&conf, 0, sizeof(conf));
memcpy(&conf, config, (config->size>sizeof(conf) ? sizeof(conf) : config->size));
if (!conf.rx_buffer) {
conf.rx_buffer = malloc(USB_RX_BUFFER_SIZE);
conf.rx_buffer_size = USB_RX_BUFFER_SIZE;
}
if (!conf.tx_buffer) {
conf.tx_buffer = malloc(USB_TX_BUFFER_SIZE);
conf.tx_buffer_size = USB_TX_BUFFER_SIZE;
}
// Just in case disable interrupts
int32_t state = HAL_disable_irq();
usbUsartMap[serial].data->rx_buffer = conf.rx_buffer;
usbUsartMap[serial].data->rx_buffer_size = conf.rx_buffer_size;
usbUsartMap[serial].data->tx_buffer = conf.tx_buffer;
usbUsartMap[serial].data->tx_buffer_size = conf.tx_buffer_size;
HAL_enable_irq(state);
}
if (!usbUsartMap[serial].cls) {
usbUsartMap[serial].cls = USBD_Composite_Register(&USBD_MCDC_cb, usbUsartMap[serial].data, serial == HAL_USB_USART_SERIAL ? 1 : 0);
usbUsartMap[serial].data->cls = usbUsartMap[serial].cls;
USBD_Composite_Set_State(usbUsartMap[serial].cls, false);
}
}
void HAL_SPI_DMA_Transfer(HAL_SPI_Interface spi, void* tx_buffer, void* rx_buffer, uint32_t length, HAL_SPI_DMA_UserCallback userCallback)
{
int32_t state = HAL_disable_irq();
spiState[spi].SPI_DMA_UserCallback = userCallback;
/* Config and initiate DMA transfer */
HAL_SPI_DMA_Config(spi, tx_buffer, rx_buffer, length);
if (spiState[spi].mode == SPI_MODE_SLAVE && spiState[spi].SPI_SS_State == 1)
{
SPI_Cmd(spiMap[spi].SPI_Peripheral, ENABLE);
}
HAL_enable_irq(state);
}
bool USBD_Composite_Get_State(void* cls) {
bool state = false;
int32_t irq = HAL_disable_irq();
for(USBD_Composite_Class_Data* c = s_Classes; c != NULL; c = c->next) {
if (cls && c == cls) {
state = c->active;
break;
}
}
HAL_enable_irq(irq);
return state;
}
int32_t HAL_USB_USART_Available_Data_For_Write(HAL_USB_USART_Serial serial)
{
if (HAL_USB_USART_Is_Connected(serial))
{
int state = HAL_disable_irq();
int32_t available = ring_space_avail(usbUsartMap[serial].data->tx_buffer_size,
usbUsartMap[serial].data->tx_buffer_head,
usbUsartMap[serial].data->tx_buffer_tail);
HAL_enable_irq(state);
return available;
}
return -1;
}
void HAL_Core_Button_Mirror_Pin_Disable(uint8_t bootloader, uint8_t button, void* reserved) {
(void)button; // unused
int32_t state = HAL_disable_irq();
if (HAL_Buttons[BUTTON1_MIRROR].pin != PIN_INVALID) {
HAL_Interrupts_Detach_Ext(HAL_Buttons[BUTTON1_MIRROR].pin, 1, NULL);
HAL_Buttons[BUTTON1_MIRROR].active = 0;
HAL_Buttons[BUTTON1_MIRROR].pin = PIN_INVALID;
}
HAL_enable_irq(state);
if (bootloader) {
BUTTON_Mirror_Persist(NULL);
}
}
uint8_t USBD_Composite_Registered_Count(bool onlyActive) {
uint8_t registered = (uint8_t)s_Classes_Count;
if (onlyActive) {
registered = 0;
int32_t irq = HAL_disable_irq();
for(USBD_Composite_Class_Data* c = s_Classes; c != NULL; c = c->next) {
if (c->active)
registered++;
}
HAL_enable_irq(irq);
}
return registered;
}
int32_t HAL_USB_USART_Receive_Data(HAL_USB_USART_Serial serial, uint8_t peek)
{
if (HAL_USB_USART_Available_Data(serial) > 0)
{
int state = HAL_disable_irq();
uint8_t data = usbUsartMap[serial].data->rx_buffer[usbUsartMap[serial].data->rx_buffer_tail];
if (!peek) {
usbUsartMap[serial].data->rx_buffer_tail = ring_wrap(usbUsartMap[serial].data->rx_buffer_length,
usbUsartMap[serial].data->rx_buffer_tail + 1);
}
HAL_enable_irq(state);
return data;
}
return -1;
}
void USBD_Composite_Unregister(void* cls, void* priv) {
int32_t irq = HAL_disable_irq();
USBD_Composite_Class_Data* prev = NULL;
for(USBD_Composite_Class_Data* c = s_Classes; c != NULL; prev = c, c = c->next) {
if ((cls && c == cls) || (priv && c->priv == priv)) {
c->inuse = 0;
if (prev) {
prev->next = c->next;
} else {
s_Classes = c->next;
}
s_Classes_Count--;
break;
}
}
HAL_enable_irq(irq);
}
void* USBD_Composite_Register(USBD_Multi_Instance_cb_Typedef* cb, void* priv, uint8_t front) {
if (s_Classes_Count >= USBD_COMPOSITE_MAX_CLASSES || cb == NULL)
return NULL;
int32_t irq = HAL_disable_irq();
USBD_Composite_Class_Data* cls = NULL;
for (int i = 0; i < USBD_COMPOSITE_MAX_CLASSES; i++) {
if (s_Class_Entries[i].inuse == 0) {
cls = s_Class_Entries + i;
break;
}
}
if (cls) {
cls->inuse = 1;
cls->active = 1;
cls->cb = cb;
cls->priv = priv;
cls->epMask = 0xffffffff;
cls->interfaces = 0;
cls->firstInterface = 0;
cls->next = NULL;
cls->cfg = NULL;
if (s_Classes == NULL) {
s_Classes = cls;
} else {
USBD_Composite_Class_Data* c = s_Classes;
if (!front) {
while(c->next) {
c = c->next;
}
c->next = cls;
} else {
s_Classes = cls;
cls->next = c;
}
}
s_Classes_Count++;
}
HAL_enable_irq(irq);
return (void*)cls;
}
int32_t HAL_USB_USART_Send_Data(HAL_USB_USART_Serial serial, uint8_t data)
{
int32_t ret = -1;
int32_t available = 0;
do {
available = HAL_USB_USART_Available_Data_For_Write(serial);
}
while (available < 1 && available != -1 && HAL_USB_WillPreempt());
// Confirm once again that the Host is connected
int32_t state = HAL_disable_irq();
if (HAL_USB_USART_Is_Connected(serial) && available > 0)
{
usbUsartMap[serial].data->tx_buffer[usbUsartMap[serial].data->tx_buffer_head] = data;
usbUsartMap[serial].data->tx_buffer_head = ring_wrap(usbUsartMap[serial].data->tx_buffer_size,
usbUsartMap[serial].data->tx_buffer_head + 1);
ret = 1;
}
HAL_enable_irq(state);
return ret;
}
void HAL_Core_Execute_Stop_Mode(void)
{
int32_t state = HAL_disable_irq();
if((BKP_ReadBackupRegister(BKP_DR9) >> 12) == 0xA)
{
uint16_t wakeUpPin = BKP_ReadBackupRegister(BKP_DR9) & 0xFF;
InterruptMode edgeTriggerMode = (InterruptMode)((BKP_ReadBackupRegister(BKP_DR9) >> 8) & 0x0F);
/* Clear Stop mode system flag */
BKP_WriteBackupRegister(BKP_DR9, 0xFFFF);
if ((wakeUpPin < TOTAL_PINS) && (edgeTriggerMode <= FALLING))
{
PinMode wakeUpPinMode = INPUT;
/* Set required pinMode based on edgeTriggerMode */
switch(edgeTriggerMode)
{
case CHANGE:
wakeUpPinMode = INPUT;
break;
case RISING:
wakeUpPinMode = INPUT_PULLDOWN;
break;
case FALLING:
wakeUpPinMode = INPUT_PULLUP;
break;
}
HAL_Pin_Mode(wakeUpPin, wakeUpPinMode);
/* Configure EXTI Interrupt : wake-up from stop mode using pin interrupt */
HAL_Interrupts_Attach(wakeUpPin, NULL, NULL, edgeTriggerMode, NULL);
/* Request to enter STOP mode with regulator in low power mode */
PWR_EnterSTOPMode(PWR_Regulator_LowPower, PWR_STOPEntry_WFI);
/* Detach the Interrupt pin */
HAL_Interrupts_Detach(wakeUpPin);
/* Disable RTC Alarm */
HAL_RTC_Cancel_UnixAlarm();
/* At this stage the system has resumed from STOP mode */
/* Enable HSE, PLL and select PLL as system clock source after wake-up from STOP */
/* Enable HSE */
RCC_HSEConfig(RCC_HSE_ON);
/* Wait till HSE is ready */
if(RCC_WaitForHSEStartUp() != SUCCESS)
{
/* If HSE startup fails try to recover by system reset */
NVIC_SystemReset();
}
/* Enable PLL */
RCC_PLLCmd(ENABLE);
/* Wait till PLL is ready */
while(RCC_GetFlagStatus(RCC_FLAG_PLLRDY) == RESET);
/* Select PLL as system clock source */
RCC_SYSCLKConfig(RCC_SYSCLKSource_PLLCLK);
/* Wait till PLL is used as system clock source */
while(RCC_GetSYSCLKSource() != 0x08);
}
}
HAL_enable_irq(state);
}
void panic_(ePanicCode code, void* extraInfo, void (*HAL_Delay_Microseconds)(uint32_t))
{
#if HAL_PLATFORM_CORE_ENTER_PANIC_MODE
HAL_Core_Enter_Panic_Mode(NULL);
#else
HAL_disable_irq();
#endif // HAL_PLATFORM_CORE_ENTER_PANIC_MODE
// Flush any serial message to help the poor bugger debug this;
flash_codes_t pcd = flash_codes[code];
LED_SetRGBColor(RGB_COLOR_RED);
LED_SetBrightness(DEFAULT_LED_RGB_BRIGHTNESS);
LED_Signaling_Stop();
uint16_t c;
int loops = 2;
LOG_PRINT(TRACE, "!");
LED_Off(LED_RGB);
while(loops) {
// preamble
for (c = 3; c; c--) {
LED_SetRGBColor(pcd.led);
LED_On(LED_RGB);
HAL_Delay_Microseconds(MS2u(150));
LED_Off(LED_RGB);
HAL_Delay_Microseconds(MS2u(100));
}
HAL_Delay_Microseconds(MS2u(100));
for (c = 3; c; c--) {
LED_SetRGBColor(pcd.led);
LED_On(LED_RGB);
HAL_Delay_Microseconds(MS2u(300));
LED_Off(LED_RGB);
HAL_Delay_Microseconds(MS2u(100));
}
HAL_Delay_Microseconds(MS2u(100));
for (c = 3; c; c--) {
LED_SetRGBColor(pcd.led);
LED_On(LED_RGB);
HAL_Delay_Microseconds(MS2u(150));
LED_Off(LED_RGB);
HAL_Delay_Microseconds(MS2u(100));
}
// pause
HAL_Delay_Microseconds(MS2u(900));
// play code
for (c = code; c; c--) {
LED_SetRGBColor(pcd.led);
LED_On(LED_RGB);
HAL_Delay_Microseconds(MS2u(300));
LED_Off(LED_RGB);
HAL_Delay_Microseconds(MS2u(300));
}
// pause
HAL_Delay_Microseconds(MS2u(800));
#if defined(RELEASE_BUILD) || PANIC_BUT_KEEP_CALM == 1
if (--loops == 0) HAL_Core_System_Reset_Ex(RESET_REASON_PANIC, code, NULL);
#endif
}
}
