Marlin_Firmware/Marlin/src/HAL/STM32F1/SPI.cpp
2020-09-06 17:29:43 -05:00

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26 KiB
C++

/******************************************************************************
* The MIT License
*
* Copyright (c) 2010 Perry Hung.
*
* Permission is hereby granted, free of charge, to any person
* obtaining a copy of this software and associated documentation
* files (the "Software"), to deal in the Software without
* restriction, including without limitation the rights to use, copy,
* modify, merge, publish, distribute, sublicense, and/or sell copies
* of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be
* included in all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
* NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS
* BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN
* ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
* CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
* SOFTWARE.
*****************************************************************************/
/**
* @author Marti Bolivar <mbolivar@leaflabs.com>
* @brief Wirish SPI implementation.
*/
#ifdef __STM32F1__
#include <SPI.h>
#include <libmaple/timer.h>
#include <libmaple/util.h>
#include <libmaple/rcc.h>
#include <boards.h>
#include <wirish.h>
#include "../../inc/MarlinConfig.h"
#include "spi_pins.h"
/** Time in ms for DMA receive timeout */
#define DMA_TIMEOUT 100
#if CYCLES_PER_MICROSECOND != 72
#warning "Unexpected clock speed; SPI frequency calculation will be incorrect"
#endif
struct spi_pins { uint8_t nss, sck, miso, mosi; };
static const spi_pins* dev_to_spi_pins(spi_dev *dev);
static void configure_gpios(spi_dev *dev, bool as_master);
static spi_baud_rate determine_baud_rate(spi_dev *dev, uint32_t freq);
#if BOARD_NR_SPI >= 3 && !defined(STM32_HIGH_DENSITY)
#error "The SPI library is misconfigured: 3 SPI ports only available on high density STM32 devices"
#endif
static const spi_pins board_spi_pins[] __FLASH__ = {
#if BOARD_NR_SPI >= 1
{ BOARD_SPI1_NSS_PIN,
BOARD_SPI1_SCK_PIN,
BOARD_SPI1_MISO_PIN,
BOARD_SPI1_MOSI_PIN },
#endif
#if BOARD_NR_SPI >= 2
{ BOARD_SPI2_NSS_PIN,
BOARD_SPI2_SCK_PIN,
BOARD_SPI2_MISO_PIN,
BOARD_SPI2_MOSI_PIN },
#endif
#if BOARD_NR_SPI >= 3
{ BOARD_SPI3_NSS_PIN,
BOARD_SPI3_SCK_PIN,
BOARD_SPI3_MISO_PIN,
BOARD_SPI3_MOSI_PIN },
#endif
};
#if BOARD_NR_SPI >= 1
static void *_spi1_this;
#endif
#if BOARD_NR_SPI >= 2
static void *_spi2_this;
#endif
#if BOARD_NR_SPI >= 3
static void *_spi3_this;
#endif
/**
* Constructor
*/
SPIClass::SPIClass(uint32_t spi_num) {
_currentSetting = &_settings[spi_num - 1]; // SPI channels are called 1 2 and 3 but the array is zero indexed
switch (spi_num) {
#if BOARD_NR_SPI >= 1
case 1:
_currentSetting->spi_d = SPI1;
_spi1_this = (void*)this;
break;
#endif
#if BOARD_NR_SPI >= 2
case 2:
_currentSetting->spi_d = SPI2;
_spi2_this = (void*)this;
break;
#endif
#if BOARD_NR_SPI >= 3
case 3:
_currentSetting->spi_d = SPI3;
_spi3_this = (void*)this;
break;
#endif
default: ASSERT(0);
}
// Init things specific to each SPI device
// clock divider setup is a bit of hack, and needs to be improved at a later date.
#if BOARD_NR_SPI >= 1
_settings[0].spi_d = SPI1;
_settings[0].clockDivider = determine_baud_rate(_settings[0].spi_d, _settings[0].clock);
_settings[0].spiDmaDev = DMA1;
_settings[0].spiTxDmaChannel = DMA_CH3;
_settings[0].spiRxDmaChannel = DMA_CH2;
#endif
#if BOARD_NR_SPI >= 2
_settings[1].spi_d = SPI2;
_settings[1].clockDivider = determine_baud_rate(_settings[1].spi_d, _settings[1].clock);
_settings[1].spiDmaDev = DMA1;
_settings[1].spiTxDmaChannel = DMA_CH5;
_settings[1].spiRxDmaChannel = DMA_CH4;
#endif
#if BOARD_NR_SPI >= 3
_settings[2].spi_d = SPI3;
_settings[2].clockDivider = determine_baud_rate(_settings[2].spi_d, _settings[2].clock);
_settings[2].spiDmaDev = DMA2;
_settings[2].spiTxDmaChannel = DMA_CH2;
_settings[2].spiRxDmaChannel = DMA_CH1;
#endif
// added for DMA callbacks.
_currentSetting->state = SPI_STATE_IDLE;
}
/**
* Set up/tear down
*/
void SPIClass::updateSettings() {
uint32_t flags = ((_currentSetting->bitOrder == MSBFIRST ? SPI_FRAME_MSB : SPI_FRAME_LSB) | _currentSetting->dataSize | SPI_SW_SLAVE | SPI_SOFT_SS);
spi_master_enable(_currentSetting->spi_d, (spi_baud_rate)_currentSetting->clockDivider, (spi_mode)_currentSetting->dataMode, flags);
}
void SPIClass::begin() {
spi_init(_currentSetting->spi_d);
configure_gpios(_currentSetting->spi_d, 1);
updateSettings();
// added for DMA callbacks.
_currentSetting->state = SPI_STATE_READY;
}
void SPIClass::beginSlave() {
spi_init(_currentSetting->spi_d);
configure_gpios(_currentSetting->spi_d, 0);
uint32_t flags = ((_currentSetting->bitOrder == MSBFIRST ? SPI_FRAME_MSB : SPI_FRAME_LSB) | _currentSetting->dataSize);
spi_slave_enable(_currentSetting->spi_d, (spi_mode)_currentSetting->dataMode, flags);
// added for DMA callbacks.
_currentSetting->state = SPI_STATE_READY;
}
void SPIClass::end() {
if (!spi_is_enabled(_currentSetting->spi_d)) return;
// Follows RM0008's sequence for disabling a SPI in master/slave
// full duplex mode.
while (spi_is_rx_nonempty(_currentSetting->spi_d)) {
// FIXME [0.1.0] remove this once you have an interrupt based driver
volatile uint16_t rx __attribute__((unused)) = spi_rx_reg(_currentSetting->spi_d);
}
waitSpiTxEnd(_currentSetting->spi_d);
spi_peripheral_disable(_currentSetting->spi_d);
// added for DMA callbacks.
// Need to add unsetting the callbacks for the DMA channels.
_currentSetting->state = SPI_STATE_IDLE;
}
/* Roger Clark added 3 functions */
void SPIClass::setClockDivider(uint32_t clockDivider) {
_currentSetting->clockDivider = clockDivider;
uint32_t cr1 = _currentSetting->spi_d->regs->CR1 & ~(SPI_CR1_BR);
_currentSetting->spi_d->regs->CR1 = cr1 | (clockDivider & SPI_CR1_BR);
}
void SPIClass::setBitOrder(BitOrder bitOrder) {
_currentSetting->bitOrder = bitOrder;
uint32_t cr1 = _currentSetting->spi_d->regs->CR1 & ~(SPI_CR1_LSBFIRST);
if (bitOrder == LSBFIRST) cr1 |= SPI_CR1_LSBFIRST;
_currentSetting->spi_d->regs->CR1 = cr1;
}
/**
* Victor Perez. Added to test changing datasize from 8 to 16 bit modes on the fly.
* Input parameter should be SPI_CR1_DFF set to 0 or 1 on a 32bit word.
*/
void SPIClass::setDataSize(uint32_t datasize) {
_currentSetting->dataSize = datasize;
uint32_t cr1 = _currentSetting->spi_d->regs->CR1 & ~(SPI_CR1_DFF);
uint8_t en = spi_is_enabled(_currentSetting->spi_d);
spi_peripheral_disable(_currentSetting->spi_d);
_currentSetting->spi_d->regs->CR1 = cr1 | (datasize & SPI_CR1_DFF) | en;
}
void SPIClass::setDataMode(uint8_t dataMode) {
/**
* Notes:
* As far as we know the AVR numbers for dataMode match the numbers required by the STM32.
* From the AVR doc https://www.atmel.com/images/doc2585.pdf section 2.4
*
* SPI Mode CPOL CPHA Shift SCK-edge Capture SCK-edge
* 0 0 0 Falling Rising
* 1 0 1 Rising Falling
* 2 1 0 Rising Falling
* 3 1 1 Falling Rising
*
* On the STM32 it appears to be
*
* bit 1 - CPOL : Clock polarity
* (This bit should not be changed when communication is ongoing)
* 0 : CLK to 0 when idle
* 1 : CLK to 1 when idle
*
* bit 0 - CPHA : Clock phase
* (This bit should not be changed when communication is ongoing)
* 0 : The first clock transition is the first data capture edge
* 1 : The second clock transition is the first data capture edge
*
* If someone finds this is not the case or sees a logic error with this let me know ;-)
*/
_currentSetting->dataMode = dataMode;
uint32_t cr1 = _currentSetting->spi_d->regs->CR1 & ~(SPI_CR1_CPOL|SPI_CR1_CPHA);
_currentSetting->spi_d->regs->CR1 = cr1 | (dataMode & (SPI_CR1_CPOL|SPI_CR1_CPHA));
}
void SPIClass::beginTransaction(uint8_t pin, const SPISettings &settings) {
setBitOrder(settings.bitOrder);
setDataMode(settings.dataMode);
setDataSize(settings.dataSize);
setClockDivider(determine_baud_rate(_currentSetting->spi_d, settings.clock));
begin();
}
void SPIClass::beginTransactionSlave(const SPISettings &settings) {
setBitOrder(settings.bitOrder);
setDataMode(settings.dataMode);
setDataSize(settings.dataSize);
beginSlave();
}
void SPIClass::endTransaction() { }
/**
* I/O
*/
uint16_t SPIClass::read() {
while (!spi_is_rx_nonempty(_currentSetting->spi_d)) { /* nada */ }
return (uint16_t)spi_rx_reg(_currentSetting->spi_d);
}
void SPIClass::read(uint8_t *buf, uint32_t len) {
if (len == 0) return;
spi_rx_reg(_currentSetting->spi_d); // clear the RX buffer in case a byte is waiting on it.
spi_reg_map * regs = _currentSetting->spi_d->regs;
// start sequence: write byte 0
regs->DR = 0x00FF; // write the first byte
// main loop
while (--len) {
while (!(regs->SR & SPI_SR_TXE)) { /* nada */ } // wait for TXE flag
noInterrupts(); // go atomic level - avoid interrupts to surely get the previously received data
regs->DR = 0x00FF; // write the next data item to be transmitted into the SPI_DR register. This clears the TXE flag.
while (!(regs->SR & SPI_SR_RXNE)) { /* nada */ } // wait till data is available in the DR register
*buf++ = (uint8)(regs->DR); // read and store the received byte. This clears the RXNE flag.
interrupts(); // let systick do its job
}
// read remaining last byte
while (!(regs->SR & SPI_SR_RXNE)) { /* nada */ } // wait till data is available in the Rx register
*buf++ = (uint8)(regs->DR); // read and store the received byte
}
void SPIClass::write(uint16_t data) {
/* Added for 16bit data Victor Perez. Roger Clark
* Improved speed by just directly writing the single byte to the SPI data reg and wait for completion,
* by taking the Tx code from transfer(byte)
* This almost doubles the speed of this function.
*/
spi_tx_reg(_currentSetting->spi_d, data); // write the data to be transmitted into the SPI_DR register (this clears the TXE flag)
waitSpiTxEnd(_currentSetting->spi_d);
}
void SPIClass::write16(uint16_t data) {
// Added by stevestrong: write two consecutive bytes in 8 bit mode (DFF=0)
spi_tx_reg(_currentSetting->spi_d, data>>8); // write high byte
while (!spi_is_tx_empty(_currentSetting->spi_d)) { /* nada */ } // Wait until TXE=1
spi_tx_reg(_currentSetting->spi_d, data); // write low byte
waitSpiTxEnd(_currentSetting->spi_d);
}
void SPIClass::write(uint16_t data, uint32_t n) {
// Added by stevstrong: Repeatedly send same data by the specified number of times
spi_reg_map * regs = _currentSetting->spi_d->regs;
while (n--) {
regs->DR = data; // write the data to be transmitted into the SPI_DR register (this clears the TXE flag)
while (!(regs->SR & SPI_SR_TXE)) { /* nada */ } // wait till Tx empty
}
while (regs->SR & SPI_SR_BSY) { /* nada */ } // wait until BSY=0 before returning
}
void SPIClass::write(const void *data, uint32_t length) {
spi_dev * spi_d = _currentSetting->spi_d;
spi_tx(spi_d, data, length); // data can be array of bytes or words
waitSpiTxEnd(spi_d);
}
uint8_t SPIClass::transfer(uint8_t byte) const {
spi_dev * spi_d = _currentSetting->spi_d;
spi_rx_reg(spi_d); // read any previous data
spi_tx_reg(spi_d, byte); // Write the data item to be transmitted into the SPI_DR register
waitSpiTxEnd(spi_d);
return (uint8)spi_rx_reg(spi_d); // "... and read the last received data."
}
uint16_t SPIClass::transfer16(uint16_t data) const {
// Modified by stevestrong: write & read two consecutive bytes in 8 bit mode (DFF=0)
// This is more effective than two distinct byte transfers
spi_dev * spi_d = _currentSetting->spi_d;
spi_rx_reg(spi_d); // read any previous data
spi_tx_reg(spi_d, data>>8); // write high byte
waitSpiTxEnd(spi_d); // wait until TXE=1 and then wait until BSY=0
uint16_t ret = spi_rx_reg(spi_d)<<8; // read and shift high byte
spi_tx_reg(spi_d, data); // write low byte
waitSpiTxEnd(spi_d); // wait until TXE=1 and then wait until BSY=0
ret += spi_rx_reg(spi_d); // read low byte
return ret;
}
/**
* Roger Clark and Victor Perez, 2015
* Performs a DMA SPI transfer with at least a receive buffer.
* If a TX buffer is not provided, FF is sent over and over for the lenght of the transfer.
* On exit TX buffer is not modified, and RX buffer cotains the received data.
* Still in progress.
*/
void SPIClass::dmaTransferSet(const void *transmitBuf, void *receiveBuf) {
dma_init(_currentSetting->spiDmaDev);
//spi_rx_dma_enable(_currentSetting->spi_d);
//spi_tx_dma_enable(_currentSetting->spi_d);
dma_xfer_size dma_bit_size = (_currentSetting->dataSize==DATA_SIZE_16BIT) ? DMA_SIZE_16BITS : DMA_SIZE_8BITS;
dma_setup_transfer(_currentSetting->spiDmaDev, _currentSetting->spiRxDmaChannel, &_currentSetting->spi_d->regs->DR,
dma_bit_size, receiveBuf, dma_bit_size, (DMA_MINC_MODE | DMA_TRNS_CMPLT ));// receive buffer DMA
if (!transmitBuf) {
transmitBuf = &ff;
dma_setup_transfer(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel, &_currentSetting->spi_d->regs->DR,
dma_bit_size, (volatile void*)transmitBuf, dma_bit_size, (DMA_FROM_MEM));// Transmit FF repeatedly
}
else {
dma_setup_transfer(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel, &_currentSetting->spi_d->regs->DR,
dma_bit_size, (volatile void*)transmitBuf, dma_bit_size, (DMA_MINC_MODE | DMA_FROM_MEM ));// Transmit buffer DMA
}
dma_set_priority(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel, DMA_PRIORITY_LOW);
dma_set_priority(_currentSetting->spiDmaDev, _currentSetting->spiRxDmaChannel, DMA_PRIORITY_VERY_HIGH);
}
uint8_t SPIClass::dmaTransferRepeat(uint16_t length) {
if (length == 0) return 0;
if (spi_is_rx_nonempty(_currentSetting->spi_d) == 1) spi_rx_reg(_currentSetting->spi_d);
_currentSetting->state = SPI_STATE_TRANSFER;
dma_set_num_transfers(_currentSetting->spiDmaDev, _currentSetting->spiRxDmaChannel, length);
dma_set_num_transfers(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel, length);
dma_enable(_currentSetting->spiDmaDev, _currentSetting->spiRxDmaChannel);// enable receive
dma_enable(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel);// enable transmit
spi_rx_dma_enable(_currentSetting->spi_d);
spi_tx_dma_enable(_currentSetting->spi_d);
if (_currentSetting->receiveCallback)
return 0;
//uint32_t m = millis();
uint8_t b = 0;
uint32_t m = millis();
while (!(dma_get_isr_bits(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel) & DMA_ISR_TCIF1)) {
// Avoid interrupts and just loop waiting for the flag to be set.
if ((millis() - m) > DMA_TIMEOUT) { b = 2; break; }
}
waitSpiTxEnd(_currentSetting->spi_d); // until TXE=1 and BSY=0
spi_tx_dma_disable(_currentSetting->spi_d);
spi_rx_dma_disable(_currentSetting->spi_d);
dma_disable(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel);
dma_disable(_currentSetting->spiDmaDev, _currentSetting->spiRxDmaChannel);
dma_clear_isr_bits(_currentSetting->spiDmaDev, _currentSetting->spiRxDmaChannel);
dma_clear_isr_bits(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel);
_currentSetting->state = SPI_STATE_READY;
return b;
}
/**
* Roger Clark and Victor Perez, 2015
* Performs a DMA SPI transfer with at least a receive buffer.
* If a TX buffer is not provided, FF is sent over and over for the length of the transfer.
* On exit TX buffer is not modified, and RX buffer contains the received data.
* Still in progress.
*/
uint8_t SPIClass::dmaTransfer(const void *transmitBuf, void *receiveBuf, uint16_t length) {
dmaTransferSet(transmitBuf, receiveBuf);
return dmaTransferRepeat(length);
}
/**
* Roger Clark and Victor Perez, 2015
* Performs a DMA SPI send using a TX buffer.
* On exit TX buffer is not modified.
* Still in progress.
* 2016 - stevstrong - reworked to automatically detect bit size from SPI setting
*/
void SPIClass::dmaSendSet(const void * transmitBuf, bool minc) {
uint32_t flags = ( (DMA_MINC_MODE*minc) | DMA_FROM_MEM | DMA_TRNS_CMPLT);
dma_init(_currentSetting->spiDmaDev);
dma_xfer_size dma_bit_size = (_currentSetting->dataSize==DATA_SIZE_16BIT) ? DMA_SIZE_16BITS : DMA_SIZE_8BITS;
dma_setup_transfer(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel, &_currentSetting->spi_d->regs->DR, dma_bit_size,
(volatile void*)transmitBuf, dma_bit_size, flags);// Transmit buffer DMA
dma_set_priority(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel, DMA_PRIORITY_LOW);
}
uint8_t SPIClass::dmaSendRepeat(uint16_t length) {
if (length == 0) return 0;
dma_clear_isr_bits(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel);
dma_set_num_transfers(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel, length);
_currentSetting->state = SPI_STATE_TRANSMIT;
dma_enable(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel); // enable transmit
spi_tx_dma_enable(_currentSetting->spi_d);
if (_currentSetting->transmitCallback) return 0;
uint32_t m = millis();
uint8_t b = 0;
while (!(dma_get_isr_bits(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel) & DMA_ISR_TCIF1)) {
// Avoid interrupts and just loop waiting for the flag to be set.
if ((millis() - m) > DMA_TIMEOUT) { b = 2; break; }
}
waitSpiTxEnd(_currentSetting->spi_d); // until TXE=1 and BSY=0
spi_tx_dma_disable(_currentSetting->spi_d);
dma_disable(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel);
dma_clear_isr_bits(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel);
_currentSetting->state = SPI_STATE_READY;
return b;
}
uint8_t SPIClass::dmaSend(const void * transmitBuf, uint16_t length, bool minc) {
dmaSendSet(transmitBuf, minc);
return dmaSendRepeat(length);
}
uint8_t SPIClass::dmaSendAsync(const void * transmitBuf, uint16_t length, bool minc) {
uint8_t b = 0;
if (_currentSetting->state != SPI_STATE_READY) {
uint32_t m = millis();
while (!(dma_get_isr_bits(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel) & DMA_ISR_TCIF1)) {
//Avoid interrupts and just loop waiting for the flag to be set.
//delayMicroseconds(10);
if ((millis() - m) > DMA_TIMEOUT) { b = 2; break; }
}
waitSpiTxEnd(_currentSetting->spi_d); // until TXE=1 and BSY=0
spi_tx_dma_disable(_currentSetting->spi_d);
dma_disable(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel);
_currentSetting->state = SPI_STATE_READY;
}
if (length == 0) return 0;
uint32_t flags = ( (DMA_MINC_MODE*minc) | DMA_FROM_MEM | DMA_TRNS_CMPLT);
dma_init(_currentSetting->spiDmaDev);
// TX
dma_xfer_size dma_bit_size = (_currentSetting->dataSize==DATA_SIZE_16BIT) ? DMA_SIZE_16BITS : DMA_SIZE_8BITS;
dma_setup_transfer(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel, &_currentSetting->spi_d->regs->DR,
dma_bit_size, (volatile void*)transmitBuf, dma_bit_size, flags);// Transmit buffer DMA
dma_set_num_transfers(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel, length);
dma_clear_isr_bits(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel);
dma_enable(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel);// enable transmit
spi_tx_dma_enable(_currentSetting->spi_d);
_currentSetting->state = SPI_STATE_TRANSMIT;
return b;
}
/**
* New functions added to manage callbacks.
* Victor Perez 2017
*/
void SPIClass::onReceive(void(*callback)()) {
_currentSetting->receiveCallback = callback;
if (callback) {
switch (_currentSetting->spi_d->clk_id) {
#if BOARD_NR_SPI >= 1
case RCC_SPI1:
dma_attach_interrupt(_currentSetting->spiDmaDev, _currentSetting->spiRxDmaChannel, &SPIClass::_spi1EventCallback);
break;
#endif
#if BOARD_NR_SPI >= 2
case RCC_SPI2:
dma_attach_interrupt(_currentSetting->spiDmaDev, _currentSetting->spiRxDmaChannel, &SPIClass::_spi2EventCallback);
break;
#endif
#if BOARD_NR_SPI >= 3
case RCC_SPI3:
dma_attach_interrupt(_currentSetting->spiDmaDev, _currentSetting->spiRxDmaChannel, &SPIClass::_spi3EventCallback);
break;
#endif
default:
ASSERT(0);
}
}
else {
dma_detach_interrupt(_currentSetting->spiDmaDev, _currentSetting->spiRxDmaChannel);
}
}
void SPIClass::onTransmit(void(*callback)()) {
_currentSetting->transmitCallback = callback;
if (callback) {
switch (_currentSetting->spi_d->clk_id) {
#if BOARD_NR_SPI >= 1
case RCC_SPI1:
dma_attach_interrupt(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel, &SPIClass::_spi1EventCallback);
break;
#endif
#if BOARD_NR_SPI >= 2
case RCC_SPI2:
dma_attach_interrupt(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel, &SPIClass::_spi2EventCallback);
break;
#endif
#if BOARD_NR_SPI >= 3
case RCC_SPI3:
dma_attach_interrupt(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel, &SPIClass::_spi3EventCallback);
break;
#endif
default:
ASSERT(0);
}
}
else {
dma_detach_interrupt(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel);
}
}
/**
* TODO: check if better to first call the customer code, next disable the DMA requests.
* Also see if we need to check whether callbacks are set or not, may be better to be checked
* during the initial setup and only set the callback to EventCallback if they are set.
*/
void SPIClass::EventCallback() {
waitSpiTxEnd(_currentSetting->spi_d);
switch (_currentSetting->state) {
case SPI_STATE_TRANSFER:
while (spi_is_rx_nonempty(_currentSetting->spi_d)) { /* nada */ }
_currentSetting->state = SPI_STATE_READY;
spi_tx_dma_disable(_currentSetting->spi_d);
spi_rx_dma_disable(_currentSetting->spi_d);
//dma_disable(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel);
//dma_disable(_currentSetting->spiDmaDev, _currentSetting->spiRxDmaChannel);
if (_currentSetting->receiveCallback)
_currentSetting->receiveCallback();
break;
case SPI_STATE_TRANSMIT:
_currentSetting->state = SPI_STATE_READY;
spi_tx_dma_disable(_currentSetting->spi_d);
//dma_disable(_currentSetting->spiDmaDev, _currentSetting->spiTxDmaChannel);
if (_currentSetting->transmitCallback)
_currentSetting->transmitCallback();
break;
default:
break;
}
}
void SPIClass::attachInterrupt() {
// Should be enableInterrupt()
}
void SPIClass::detachInterrupt() {
// Should be disableInterrupt()
}
/**
* Pin accessors
*/
uint8_t SPIClass::misoPin() {
return dev_to_spi_pins(_currentSetting->spi_d)->miso;
}
uint8_t SPIClass::mosiPin() {
return dev_to_spi_pins(_currentSetting->spi_d)->mosi;
}
uint8_t SPIClass::sckPin() {
return dev_to_spi_pins(_currentSetting->spi_d)->sck;
}
uint8_t SPIClass::nssPin() {
return dev_to_spi_pins(_currentSetting->spi_d)->nss;
}
/**
* Deprecated functions
*/
uint8_t SPIClass::send(uint8_t data) { write(data); return 1; }
uint8_t SPIClass::send(uint8_t *buf, uint32_t len) { write(buf, len); return len; }
uint8_t SPIClass::recv() { return read(); }
/**
* DMA call back functions, one per port.
*/
#if BOARD_NR_SPI >= 1
void SPIClass::_spi1EventCallback() {
reinterpret_cast<class SPIClass*>(_spi1_this)->EventCallback();
}
#endif
#if BOARD_NR_SPI >= 2
void SPIClass::_spi2EventCallback() {
reinterpret_cast<class SPIClass*>(_spi2_this)->EventCallback();
}
#endif
#if BOARD_NR_SPI >= 3
void SPIClass::_spi3EventCallback() {
reinterpret_cast<class SPIClass*>(_spi3_this)->EventCallback();
}
#endif
/**
* Auxiliary functions
*/
static const spi_pins* dev_to_spi_pins(spi_dev *dev) {
switch (dev->clk_id) {
#if BOARD_NR_SPI >= 1
case RCC_SPI1: return board_spi_pins;
#endif
#if BOARD_NR_SPI >= 2
case RCC_SPI2: return board_spi_pins + 1;
#endif
#if BOARD_NR_SPI >= 3
case RCC_SPI3: return board_spi_pins + 2;
#endif
default: return NULL;
}
}
static void disable_pwm(const stm32_pin_info *i) {
if (i->timer_device)
timer_set_mode(i->timer_device, i->timer_channel, TIMER_DISABLED);
}
static void configure_gpios(spi_dev *dev, bool as_master) {
const spi_pins *pins = dev_to_spi_pins(dev);
if (!pins) return;
const stm32_pin_info *nssi = &PIN_MAP[pins->nss],
*scki = &PIN_MAP[pins->sck],
*misoi = &PIN_MAP[pins->miso],
*mosii = &PIN_MAP[pins->mosi];
disable_pwm(nssi);
disable_pwm(scki);
disable_pwm(misoi);
disable_pwm(mosii);
spi_config_gpios(dev, as_master, nssi->gpio_device, nssi->gpio_bit,
scki->gpio_device, scki->gpio_bit, misoi->gpio_bit,
mosii->gpio_bit);
}
static const spi_baud_rate baud_rates[8] __FLASH__ = {
SPI_BAUD_PCLK_DIV_2,
SPI_BAUD_PCLK_DIV_4,
SPI_BAUD_PCLK_DIV_8,
SPI_BAUD_PCLK_DIV_16,
SPI_BAUD_PCLK_DIV_32,
SPI_BAUD_PCLK_DIV_64,
SPI_BAUD_PCLK_DIV_128,
SPI_BAUD_PCLK_DIV_256,
};
/**
* Note: This assumes you're on a LeafLabs-style board
* (CYCLES_PER_MICROSECOND == 72, APB2 at 72MHz, APB1 at 36MHz).
*/
static spi_baud_rate determine_baud_rate(spi_dev *dev, uint32_t freq) {
uint32_t clock = 0;
switch (rcc_dev_clk(dev->clk_id)) {
case RCC_AHB:
case RCC_APB2: clock = STM32_PCLK2; break; // 72 Mhz
case RCC_APB1: clock = STM32_PCLK1; break; // 36 Mhz
}
clock >>= 1;
uint8_t i = 0;
while (i < 7 && freq < clock) { clock >>= 1; i++; }
return baud_rates[i];
}
SPIClass SPI(SPI_DEVICE);
#endif // __STM32F1__