void mew_bluetooth_transmit(uint8_t* data, uint16_t size, uint8_t sync_mode) {
mew_check_dma_memory((void*)data, "mew_bluetooth_transmit");
mew_wait_for_state(&_mew_dma_tx_state, 0);
_mew_dma_tx_state = 1;
dma_stream_reset(MEW_BLUETOOTH_DMA, MEW_BLUETOOTH_DMA_STREAM_TX);
dma_set_transfer_mode(MEW_BLUETOOTH_DMA, MEW_BLUETOOTH_DMA_STREAM_TX, DMA_SxCR_DIR_MEM_TO_PERIPHERAL);
dma_set_priority(MEW_BLUETOOTH_DMA, MEW_BLUETOOTH_DMA_STREAM_TX, DMA_SxCR_PL_HIGH);
dma_set_memory_size(MEW_BLUETOOTH_DMA, MEW_BLUETOOTH_DMA_STREAM_TX, DMA_SxCR_MSIZE_8BIT);
dma_set_peripheral_size(MEW_BLUETOOTH_DMA, MEW_BLUETOOTH_DMA_STREAM_TX, DMA_SxCR_PSIZE_8BIT);
dma_enable_memory_increment_mode(MEW_BLUETOOTH_DMA, MEW_BLUETOOTH_DMA_STREAM_TX);
dma_set_peripheral_address(MEW_BLUETOOTH_DMA, MEW_BLUETOOTH_DMA_STREAM_TX, (uint32_t) &MEW_BLUETOOTH_DMA_DR);
dma_channel_select(MEW_BLUETOOTH_DMA, MEW_BLUETOOTH_DMA_STREAM_TX, MEW_BLUETOOTH_DMA_CHANNEL_TX);
dma_set_memory_address(MEW_BLUETOOTH_DMA, MEW_BLUETOOTH_DMA_STREAM_TX, (uint32_t) data);
dma_set_number_of_data(MEW_BLUETOOTH_DMA, MEW_BLUETOOTH_DMA_STREAM_TX, size);
dma_disable_fifo_error_interrupt(MEW_BLUETOOTH_DMA, MEW_BLUETOOTH_DMA_STREAM_TX);
dma_disable_half_transfer_interrupt(MEW_BLUETOOTH_DMA, MEW_BLUETOOTH_DMA_STREAM_TX);
dma_enable_transfer_complete_interrupt(MEW_BLUETOOTH_DMA, MEW_BLUETOOTH_DMA_STREAM_TX);
dma_enable_transfer_error_interrupt(MEW_BLUETOOTH_DMA, MEW_BLUETOOTH_DMA_STREAM_TX);
dma_enable_transfer_complete_interrupt(MEW_BLUETOOTH_DMA, MEW_BLUETOOTH_DMA_STREAM_TX);
__mew_bluetooth_clear_buf();
dma_enable_stream(MEW_BLUETOOTH_DMA, MEW_BLUETOOTH_DMA_STREAM_TX);
if (sync_mode == 1) {
mew_wait_for_state(&_mew_dma_tx_state, 0);
}
}
static void __spi_dma_start(uint32_t stream)
{
/* XXX: Possible spurious interrupts on good transfers on FEIF? */
dma_disable_fifo_error_interrupt(DMA1, stream);
dma_disable_half_transfer_interrupt(DMA1, stream);
dma_enable_transfer_complete_interrupt(DMA1, stream);
dma_enable_transfer_error_interrupt(DMA1, stream);
dma_enable_transfer_complete_interrupt(DMA1, stream);
dma_enable_stream(DMA1, stream);
}
static void setup_i2c_port(enum I2C_FREQ I2C_speed)
{
// Disable I2C if it happens to be enabled
i2c_peripheral_disable(I2C_PORT);
dma_channel_reset(I2C_TX_DMA, I2C_TX_DMA_CHANNEL);
i2c_disable_interrupt(I2C_PORT, (I2C_CR2_ITEVTEN | I2C_CR2_ITERREN));
DISABLE_I2C_INTERRUPT();
reset_i2c_pins();
// set: Source, Destination, and Amount (DMA channel must be disabled)
dma_set_peripheral_address(I2C_TX_DMA, I2C_TX_DMA_CHANNEL, (uint32_t)&I2C_DR(I2C_PORT));
dma_set_memory_address(I2C_TX_DMA, I2C_TX_DMA_CHANNEL, 0);
dma_set_number_of_data(I2C_TX_DMA, I2C_TX_DMA_CHANNEL, 0);
// set the DMA Configuration (DMA_CCRx)
// (BIT 14) mem2mem_mode disabled
dma_set_priority(I2C_TX_DMA, I2C_TX_DMA_CHANNEL, DMA_CCR_PL_HIGH); // (BIT 12:13)
dma_set_memory_size(I2C_TX_DMA, I2C_TX_DMA_CHANNEL, DMA_CCR_MSIZE_8BIT); // (BIT 10:11)
dma_set_peripheral_size(I2C_TX_DMA, I2C_TX_DMA_CHANNEL, DMA_CCR_PSIZE_8BIT); // (BIT 8:9)
dma_enable_memory_increment_mode(I2C_TX_DMA, I2C_TX_DMA_CHANNEL); // (BIT 7)
dma_disable_peripheral_increment_mode(I2C_TX_DMA, I2C_TX_DMA_CHANNEL); // (BIT 6)
// (BIT 5) Circular mode is disabled
dma_set_read_from_memory(I2C_TX_DMA, I2C_TX_DMA_CHANNEL); // (BIT 4)
dma_enable_transfer_error_interrupt(I2C_TX_DMA, I2C_TX_DMA_CHANNEL); // (BIT 3)
dma_disable_half_transfer_interrupt(I2C_TX_DMA, I2C_TX_DMA_CHANNEL); // (BIT 2)
dma_enable_transfer_complete_interrupt(I2C_TX_DMA, I2C_TX_DMA_CHANNEL); // (BIT 1)
// This is the slave address when not transmitting data
i2c_set_own_7bit_slave_address(I2C_PORT, 0x32);
// do not respond to the specified slave address
i2c_disable_ack(I2C_PORT);
// Use DMA to send I2C data
i2c_enable_dma(I2C_PORT);
// set which interrupts I2C uses
i2c_enable_interrupt(I2C_PORT, (I2C_CR2_ITEVTEN | I2C_CR2_ITERREN));
// APB1 is running at 36MHz = T(PCLK1) = 1/36000000 sec.
i2c_set_clock_frequency(I2C_PORT, I2C_CR2_FREQ_36MHZ);
// Set up the hardware for the particular speed
switch (I2C_speed) {
// Values found on Internet for the I2C standard
// STANDARD : SCL max rise time = 1000ns = 1000/1000000000 sec
// FAST : SCL max rise time = 300ns = 300/1000000000 sec
//
// DATASHEET Function:
// TRISE = (T(MAX_SCL_RISE) / T(PCLK1)) + 1
//
// DATASHEET Functions:
// STANDARD :
// T(high) = CCR * T(PCLK1)
// T(low) = CCR * T(PCLK1)
// FAST (DUTY=I2C_CCR_DUTY_DIV2)
// T(high) = CCR * T(PCLK1)
// T(low) = 2 * CCR * T(PCLK1)
// FAST (DUTY=I2C_CCR_DUTY_16_DIV_9) [To reach 400KHz]
// T(high) = 9 * CCR * T(PCLK1)
// T(low) = 16 * CCR * T(PCLK1)
//
// I2C PERIOD:
// STANDARD
// PERIOD = T(high) + T(low) = (2 * CCR * T(PCLK1))
// FAST (DUTY=I2C_CCR_DUTY_DIV2)
// PERIOD = T(high) + T(low) = (3 * CCR * T(PCLK1))
// FAST (DUTY=I2C_CCR_DUTY_16_DIV_9)
// PERIOD = T(high) + T(low) = (25 * CCR * T(PCLK1))
case I2C_400KHz:
// I2C PERIOD: 400KHz = 400000Hz = 1/400000 sec.
i2c_set_fast_mode(I2C_PORT);
// I2C_CCR_DUTY_DIV2 or I2C_CCR_DUTY_16_DIV_9
i2c_set_dutycycle(I2C_PORT, I2C_CCR_DUTY_16_DIV_9);
// CCR = PERIOD / (25 * T(PCLK1))
// CCR = (1/400000) / (25/36000000) = 18/5 = 3.6
// CCR = 4 => I2C PERIOD = 360kHz
// CCR = 3 => I2C PERIOD = 480kHz
i2c_set_ccr(I2C_PORT, 4); // Only fast mode can have a value less than 0x04
// TRISE = ( (300/1000000000) / (1/36000000) ) + 1 = 59/5 = 11.8
// TRISE = 12 => SCL max rise time ~= 305.555ns
// TRISE = 11 => SCL max rise time ~= 277.777ns
i2c_set_trise(I2C_PORT, 11);
break;
case I2C_100KHz:
// I2C PERIOD: 100KHz = 100000Hz = 1/100000 sec.
i2c_set_standard_mode(I2C_PORT);
// I2C_CCR_DUTY_DIV2 or I2C_CCR_DUTY_16_DIV_9
i2c_set_dutycycle(I2C_PORT, I2C_CCR_DUTY_DIV2);
// CCR = PERIOD / (2 * T(PCLK1))
// CCR = (1/100000) / (2/36000000) = 180
i2c_set_ccr(I2C_PORT, 180);
// TRISE = ( (1000/1000000000) / (1/36000000) ) + 1 = 37
i2c_set_trise(I2C_PORT, 37);
break;
case I2C_53KHz:
// ~= 52.91kHz is the slowest I could get to work
// CCR value of 341 works but not 342 or higher
case I2C_50KHz:
default:
// I2C PERIOD: 50KHz = 50000Hz = 1/50000 sec.
i2c_set_standard_mode(I2C_PORT);
// I2C_CCR_DUTY_DIV2 or I2C_CCR_DUTY_16_DIV_9
i2c_set_dutycycle(I2C_PORT, I2C_CCR_DUTY_DIV2);
// CCR = PERIOD / (2 * T(PCLK1))
// CCR = (1/50000) / (2/36000000) = 360
// (341 works but not 342 or higher)
i2c_set_ccr(I2C_PORT, 341);
// TRISE = ( (1000/1000000000) / (1/36000000) ) + 1 = 37
i2c_set_trise(I2C_PORT, 37);
break;
}
i2c_peripheral_enable(I2C_PORT);
// set the priorities for the interrupts
nvic_set_priority(I2C_EV_IRQ, IRQ_PRI_I2C);
nvic_set_priority(I2C_ER_IRQ, IRQ_PRI_ER_I2C);
nvic_set_priority(I2C_DMA_IRQ, IRQ_PRI_DMA_I2C);
}
/**
* Initialize analog to digital converter
*/
void adc_init(adc_callback_t half_transfer_callback,
adc_callback_t transfer_complete_callback)
{
/* Reset adc_state. */
adc_state.dma_transfer_error_counter = 0;
adc_state.half_transfer_callback = half_transfer_callback;
adc_state.transfer_complete_callback = transfer_complete_callback;
/* Initialize peripheral clocks. */
rcc_peripheral_enable_clock(&RCC_AHBENR, RCC_AHBENR_DMA1EN);
rcc_peripheral_enable_clock(&RCC_APB2ENR, RCC_APB2ENR_IOPAEN);
rcc_peripheral_enable_clock(&RCC_APB2ENR, RCC_APB2ENR_ADC1EN);
rcc_peripheral_enable_clock(&RCC_APB2ENR, RCC_APB2ENR_ADC2EN);
/* Initialize the ADC input GPIO. */
/* WARNING: this code is written to work with strip. On the strip
* hardware we are lucky and all the ADC channels are on the same bank
* so we can initialize all of them in one go. This code will need to be
* changed/improved if we ever have to support hardware that has the
* ADC's spread over more then one bank.
*/
gpio_set_mode(ADC_BANK, GPIO_MODE_INPUT,
GPIO_CNF_INPUT_ANALOG, ADC_PORT_U_VOLTAGE |
ADC_PORT_V_VOLTAGE |
ADC_PORT_W_VOLTAGE |
ADC_PORT_V_BATT |
ADC_PORT_CURRENT);
/* Configure DMA for data aquisition. */
/* Channel 1 reacts to: ADC1, TIM2_CH3 and TIM4_CH1 */
dma_channel_reset(DMA1, DMA_CHANNEL1);
dma_set_peripheral_address(DMA1, DMA_CHANNEL1, (uint32_t)&ADC1_DR);
dma_set_memory_address(DMA1, DMA_CHANNEL1,
(uint32_t)adc_state.raw_data);
dma_set_number_of_data(DMA1, DMA_CHANNEL1, ADC_RAW_SAMPLE_COUNT/2);
dma_set_read_from_peripheral(DMA1, DMA_CHANNEL1);
dma_enable_memory_increment_mode(DMA1, DMA_CHANNEL1);
dma_enable_circular_mode(DMA1, DMA_CHANNEL1);
dma_set_peripheral_size(DMA1, DMA_CHANNEL1, DMA_CCR_PSIZE_32BIT);
dma_set_memory_size(DMA1, DMA_CHANNEL1, DMA_CCR_MSIZE_32BIT);
dma_set_priority(DMA1, DMA_CHANNEL1, DMA_CCR_PL_VERY_HIGH);
dma_enable_half_transfer_interrupt(DMA1, DMA_CHANNEL1);
dma_enable_transfer_complete_interrupt(DMA1, DMA_CHANNEL1);
dma_enable_transfer_error_interrupt(DMA1, DMA_CHANNEL1);
dma_enable_channel(DMA1, DMA_CHANNEL1);
/* Configure interrupts in NVIC. */
nvic_set_priority(NVIC_DMA1_CHANNEL1_IRQ, 0);
nvic_enable_irq(NVIC_DMA1_CHANNEL1_IRQ);
/* Disable ADC's. */
adc_off(ADC1);
adc_off(ADC2);
/* Enable dualmode. */
adc_set_dual_mode(ADC_CR1_DUALMOD_RSM); /* Dualmode regular only. */
/* Configure the adc channels. */
adc_config(ADC1, adc1_channel_array);
adc_config(ADC2, adc2_channel_array);
/* Start converting. */
adc_start_conversion_regular(ADC1);
}
