/* ChibiOS/HAL - Copyright (C) 2006-2014 Giovanni Di Sirio Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. */ /** * @file KINETIS/spi_lld.c * @brief KINETIS SPI subsystem low level driver source. * * @addtogroup SPI * @{ */ #include "hal.h" #if HAL_USE_SPI || defined(__DOXYGEN__) /*===========================================================================*/ /* Driver local definitions. */ /*===========================================================================*/ /*===========================================================================*/ /* Driver exported variables. */ /*===========================================================================*/ /** @brief SPI0 driver identifier.*/ #if KINETIS_SPI_USE_SPI0 || defined(__DOXYGEN__) SPIDriver SPID1; #endif /*===========================================================================*/ /* Driver local variables and types. */ /*===========================================================================*/ /*===========================================================================*/ /* Driver local functions. */ /*===========================================================================*/ static void spi_start_xfer(SPIDriver *spip, bool polling) { /* * Enable the DSPI peripheral in master mode. * On receive overflow, new data will overwrite old data. * Set slave selects to be active low. * Clear the TX and RX FIFOs. * */ spip->spi->MCR = SPIx_MCR_MSTR | SPIx_MCR_ROOE | SPIx_MCR_PCSIS(KINETIS_SPI_PCS_ALL) | SPIx_MCR_CLR_TXF | SPIx_MCR_CLR_RXF; /* If we are not polling then enable interrupts */ if (!polling) { /* Enable transmit fill, receive and end of queue interrupts */ spip->spi->RSER = SPIx_RSER_TFFF_RE | SPIx_RSER_RFDF_RE | SPIx_RSER_EOQF_RE; } } static void spi_stop_xfer(SPIDriver *spip) { /* Halt the DSPI peripheral */ spip->spi->MCR = SPIx_MCR_MSTR | SPIx_MCR_ROOE | SPIx_MCR_PCSIS(KINETIS_SPI_PCS_ALL) | SPIx_MCR_CLR_TXF | SPIx_MCR_CLR_RXF | SPIx_MCR_HALT; /* Clear all interrupt enables */ spip->spi->RSER = 0; /* Clear all the flags which are currently set. */ spip->spi->SR |= spip->spi->SR; } /*===========================================================================*/ /* Driver interrupt handlers. */ /*===========================================================================*/ OSAL_IRQ_HANDLER(Vector70) { OSAL_IRQ_PROLOGUE(); SPIDriver *spip = &SPID1; uint32_t sr = spip->spi->SR; /* Handle Receive FIFO Drain interrupt */ if (sr & SPIx_SR_RFDF) { /* Pop the data out of the fifo */ uint8_t data = spip->spi->POPR; /* If we have an rxbuf and it has space then store the data */ if (spip->rxbuf && spip->rxidx < spip->nbytes) { spip->rxbuf[spip->rxidx++] = data; } /* Clear the Receive FIFO Drain Flag */ spip->spi->SR = SPIx_SR_RFDF; } /* Handle End of Queue interrupt */ if (sr & SPIx_SR_EOQF) { spip->spi->SR = SPIx_SR_EOQF; spi_stop_xfer(spip); _spi_isr_code(spip); } /* Handle Transmit FIFO Fill interrupt */ if (sr & SPIx_SR_TFFF) { /* The data to send is either the next tx byte or a filler byte */ uint8_t data = spip->txbuf ? spip->txbuf[spip->txidx] : 0x00; /* Calculate the number of bytes remaining and increment the index */ size_t n = spip->nbytes - spip->txidx++; /* Push the data into the FIFO, CONT if more bytes, EOQ if last byte */ spip->spi->PUSHR = (n > 1 ? SPIx_PUSHR_CONT : SPIx_PUSHR_EOQ) | SPIx_PUSHR_PCS(spip->config->pcs) | SPIx_PUSHR_TXDATA(data); /* Clear the Transmit FIFO Fill Flag */ spip->spi->SR = SPIx_SR_TFFF; } OSAL_IRQ_EPILOGUE(); } /*===========================================================================*/ /* Driver exported functions. */ /*===========================================================================*/ /** * @brief Low level SPI driver initialization. * * @notapi */ void spi_lld_init(void) { nvicEnableVector(SPI0_IRQn, KINETIS_SPI_SPI0_IRQ_PRIORITY); #if KINETIS_SPI_USE_SPI0 spiObjectInit(&SPID1); #endif } /** * @brief Configures and activates the SPI peripheral. * * @param[in] spip pointer to the @p SPIDriver object * * @notapi */ void spi_lld_start(SPIDriver *spip) { /* If in stopped state then enables the SPI and DMA clocks.*/ if (spip->state == SPI_STOP) { #if KINETIS_SPI_USE_SPI0 if (&SPID1 == spip) { /* Enable the clock for SPI0 */ SIM->SCGC6 |= SIM_SCGC6_SPI0; SPID1.spi = SPI0; if (spip->config->tar0) { spip->spi->CTAR[0] = spip->config->tar0; } else { spip->spi->CTAR[0] = KINETIS_SPI_TAR0_DEFAULT; } spip->spi->CTAR[1] = KINETIS_SPI_TAR1_DEFAULT; } #endif } /* SPI setup and enable.*/ } /** * @brief Deactivates the SPI peripheral. * * @param[in] spip pointer to the @p SPIDriver object * * @notapi */ void spi_lld_stop(SPIDriver *spip) { /* If in ready state then disables the SPI clock.*/ if (spip->state == SPI_READY) { /* Disable the clock for SPI0 */ SIM->SCGC6 &= ~SIM_SCGC6_SPI0; #if KINETIS_SPI_USE_SPI0 if (&SPID1 == spip) { /* SPI halt.*/ spip->spi->MCR |= SPIx_MCR_HALT; } #endif } } /** * @brief Asserts the slave select signal and prepares for transfers. * * @param[in] spip pointer to the @p SPIDriver object * * @notapi */ void spi_lld_select(SPIDriver *spip) { /* If we are not using the DSPI managed chip select then assert the SS */ if (!spip->config->pcs) { palClearPad(spip->config->ssport, spip->config->sspad); } } /** * @brief Deasserts the slave select signal. * @details The previously selected peripheral is unselected. * This has no effect if we are using the KINETIS PCS mode to * manage slave select. * * @param[in] spip pointer to the @p SPIDriver object * * @notapi */ void spi_lld_unselect(SPIDriver *spip) { /* If we are not using the DSPI managed chip select then deassert the SS */ if (!spip->config->pcs) { palSetPad(spip->config->ssport, spip->config->sspad); } } /** * @brief Ignores data on the SPI bus. * @details This asynchronous function starts the transmission of a series of * idle words on the SPI bus and ignores the received data. * @post At the end of the operation the configured callback is invoked. * * @param[in] spip pointer to the @p SPIDriver object * @param[in] n number of words to be ignored * * @notapi */ void spi_lld_ignore(SPIDriver *spip, size_t n) { spip->nbytes = n; spip->rxbuf = NULL; spip->rxidx = 0; spip->txbuf = NULL; spip->txidx = 0; spi_start_xfer(spip, false); } /** * @brief Exchanges data on the SPI bus. * @details This asynchronous function starts a simultaneous transmit/receive * operation. * @post At the end of the operation the configured callback is invoked. * @note The buffers are organized as uint8_t arrays for data sizes below or * equal to 8 bits else it is organized as uint16_t arrays. * * @param[in] spip pointer to the @p SPIDriver object * @param[in] n number of words to be exchanged * @param[in] txbuf the pointer to the transmit buffer * @param[out] rxbuf the pointer to the receive buffer * * @notapi */ void spi_lld_exchange(SPIDriver *spip, size_t n, const void *txbuf, void *rxbuf) { spip->nbytes = n; spip->rxbuf = rxbuf; spip->rxidx = 0; spip->txbuf = txbuf; spip->txidx = 0; spi_start_xfer(spip, false); } /** * @brief Sends data over the SPI bus. * @details This asynchronous function starts a transmit operation. * @post At the end of the operation the configured callback is invoked. * @note The buffers are organized as uint8_t arrays for data sizes below or * equal to 8 bits else it is organized as uint16_t arrays. * * @param[in] spip pointer to the @p SPIDriver object * @param[in] n number of words to send * @param[in] txbuf the pointer to the transmit buffer * * @notapi */ void spi_lld_send(SPIDriver *spip, size_t n, const void *txbuf) { spip->nbytes = n; spip->rxbuf = NULL; spip->rxidx = 0; spip->txbuf = (void *)txbuf; spip->txidx = 0; spi_start_xfer(spip, false); } /** * @brief Receives data from the SPI bus. * @details This asynchronous function starts a receive operation. * @post At the end of the operation the configured callback is invoked. * @note The buffers are organized as uint8_t arrays for data sizes below or * equal to 8 bits else it is organized as uint16_t arrays. * * @param[in] spip pointer to the @p SPIDriver object * @param[in] n number of words to receive * @param[out] rxbuf the pointer to the receive buffer * * @notapi */ void spi_lld_receive(SPIDriver *spip, size_t n, void *rxbuf) { spip->nbytes = n; spip->rxbuf = rxbuf; spip->rxidx = 0; spip->txbuf = NULL; spip->txidx = 0; spi_start_xfer(spip, false); } /** * @brief Exchanges one frame using a polled wait. * @details This synchronous function exchanges one frame using a polled * synchronization method. This function is useful when exchanging * small amount of data on high speed channels, usually in this * situation is much more efficient just wait for completion using * polling than suspending the thread waiting for an interrupt. * * @param[in] spip pointer to the @p SPIDriver object * @param[in] frame the data frame to send over the SPI bus * @return The received data frame from the SPI bus. */ uint16_t spi_lld_polled_exchange(SPIDriver *spip, uint16_t frame) { spi_start_xfer(spip, true); spip->spi->PUSHR = SPIx_PUSHR_PCS(0x10) | SPIx_PUSHR_TXDATA(frame); while ((spip->spi->SR & SPIx_SR_RFDF) == 0) ; frame = spip->spi->POPR; spi_stop_xfer(spip); return frame; } #endif /* HAL_USE_SPI */ /** @} */