mbed library sources
Dependents: FRDM-KL46Z_LCD_Test FRDM-KL46Z_LCD_Test FRDM-KL46Z_Plantilla FRDM-KL46Z_Plantilla ... more
targets/hal/TARGET_STM/TARGET_NUCLEO_F401RE/spi_api.c
- Committer:
- ebrus
- Date:
- 2016-07-28
- Revision:
- 0:6bc4ac881c8e
File content as of revision 0:6bc4ac881c8e:
/* mbed Microcontroller Library ******************************************************************************* * Copyright (c) 2014, STMicroelectronics * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright notice, * this list of conditions and the following disclaimer in the documentation * and/or other materials provided with the distribution. * 3. Neither the name of STMicroelectronics nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER * CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ******************************************************************************* */ #include "mbed_assert.h" #include "spi_api.h" #if DEVICE_SPI #include <math.h> #include "cmsis.h" #include "pinmap.h" static const PinMap PinMap_SPI_MOSI[] = { {PA_7, SPI_1, STM_PIN_DATA(STM_MODE_AF_PP, GPIO_PULLUP, GPIO_AF5_SPI1)}, {PB_5, SPI_1, STM_PIN_DATA(STM_MODE_AF_PP, GPIO_PULLUP, GPIO_AF5_SPI1)}, // {PB_5, SPI_3, STM_PIN_DATA(STM_MODE_AF_PP, GPIO_PULLUP, GPIO_AF6_SPI3)}, {PB_15, SPI_2, STM_PIN_DATA(STM_MODE_AF_PP, GPIO_PULLUP, GPIO_AF5_SPI2)}, {PC_3, SPI_2, STM_PIN_DATA(STM_MODE_AF_PP, GPIO_PULLUP, GPIO_AF5_SPI2)}, {PC_12, SPI_3, STM_PIN_DATA(STM_MODE_AF_PP, GPIO_PULLUP, GPIO_AF6_SPI3)}, {NC, NC, 0} }; static const PinMap PinMap_SPI_MISO[] = { {PA_6, SPI_1, STM_PIN_DATA(STM_MODE_AF_PP, GPIO_PULLUP, GPIO_AF5_SPI1)}, {PB_4, SPI_1, STM_PIN_DATA(STM_MODE_AF_PP, GPIO_PULLUP, GPIO_AF5_SPI1)}, // {PB_4, SPI_3, STM_PIN_DATA(STM_MODE_AF_PP, GPIO_PULLUP, GPIO_AF6_SPI3)}, {PB_14, SPI_2, STM_PIN_DATA(STM_MODE_AF_PP, GPIO_PULLUP, GPIO_AF5_SPI2)}, {PC_2, SPI_2, STM_PIN_DATA(STM_MODE_AF_PP, GPIO_PULLUP, GPIO_AF5_SPI2)}, {PC_11, SPI_3, STM_PIN_DATA(STM_MODE_AF_PP, GPIO_PULLUP, GPIO_AF6_SPI3)}, {NC, NC, 0} }; static const PinMap PinMap_SPI_SCLK[] = { {PA_5, SPI_1, STM_PIN_DATA(STM_MODE_AF_PP, GPIO_PULLUP, GPIO_AF5_SPI1)}, {PB_3, SPI_1, STM_PIN_DATA(STM_MODE_AF_PP, GPIO_PULLUP, GPIO_AF5_SPI1)}, // {PB_3, SPI_3, STM_PIN_DATA(STM_MODE_AF_PP, GPIO_PULLUP, GPIO_AF6_SPI3)}, {PB_10, SPI_2, STM_PIN_DATA(STM_MODE_AF_PP, GPIO_PULLUP, GPIO_AF5_SPI2)}, {PB_13, SPI_2, STM_PIN_DATA(STM_MODE_AF_PP, GPIO_PULLUP, GPIO_AF5_SPI2)}, {PC_10, SPI_3, STM_PIN_DATA(STM_MODE_AF_PP, GPIO_PULLUP, GPIO_AF6_SPI3)}, {NC, NC, 0} }; static const PinMap PinMap_SPI_SSEL[] = { {PA_4, SPI_1, STM_PIN_DATA(STM_MODE_AF_PP, GPIO_NOPULL, GPIO_AF5_SPI1)}, // {PA_4, SPI_3, STM_PIN_DATA(STM_MODE_AF_PP, GPIO_NOPULL, GPIO_AF6_SPI3)}, {PA_15, SPI_1, STM_PIN_DATA(STM_MODE_AF_PP, GPIO_NOPULL, GPIO_AF5_SPI1)}, // {PA_15, SPI_3, STM_PIN_DATA(STM_MODE_AF_PP, GPIO_NOPULL, GPIO_AF6_SPI3)}, {PB_9, SPI_2, STM_PIN_DATA(STM_MODE_AF_PP, GPIO_NOPULL, GPIO_AF5_SPI2)}, {PB_12, SPI_2, STM_PIN_DATA(STM_MODE_AF_PP, GPIO_NOPULL, GPIO_AF5_SPI2)}, {NC, NC, 0} }; static SPI_HandleTypeDef SpiHandle; static void init_spi(spi_t *obj) { SpiHandle.Instance = (SPI_TypeDef *)(obj->spi); __HAL_SPI_DISABLE(&SpiHandle); SpiHandle.Init.Mode = obj->mode; SpiHandle.Init.BaudRatePrescaler = obj->br_presc; SpiHandle.Init.Direction = SPI_DIRECTION_2LINES; SpiHandle.Init.CLKPhase = obj->cpha; SpiHandle.Init.CLKPolarity = obj->cpol; SpiHandle.Init.CRCCalculation = SPI_CRCCALCULATION_DISABLED; SpiHandle.Init.CRCPolynomial = 7; SpiHandle.Init.DataSize = obj->bits; SpiHandle.Init.FirstBit = SPI_FIRSTBIT_MSB; SpiHandle.Init.NSS = obj->nss; SpiHandle.Init.TIMode = SPI_TIMODE_DISABLED; HAL_SPI_Init(&SpiHandle); __HAL_SPI_ENABLE(&SpiHandle); } void spi_init(spi_t *obj, PinName mosi, PinName miso, PinName sclk, PinName ssel) { // Determine the SPI to use SPIName spi_mosi = (SPIName)pinmap_peripheral(mosi, PinMap_SPI_MOSI); SPIName spi_miso = (SPIName)pinmap_peripheral(miso, PinMap_SPI_MISO); SPIName spi_sclk = (SPIName)pinmap_peripheral(sclk, PinMap_SPI_SCLK); SPIName spi_ssel = (SPIName)pinmap_peripheral(ssel, PinMap_SPI_SSEL); SPIName spi_data = (SPIName)pinmap_merge(spi_mosi, spi_miso); SPIName spi_cntl = (SPIName)pinmap_merge(spi_sclk, spi_ssel); obj->spi = (SPIName)pinmap_merge(spi_data, spi_cntl); MBED_ASSERT(obj->spi != (SPIName)NC); // Enable SPI clock if (obj->spi == SPI_1) { __SPI1_CLK_ENABLE(); } if (obj->spi == SPI_2) { __SPI2_CLK_ENABLE(); } if (obj->spi == SPI_3) { __SPI3_CLK_ENABLE(); } // Configure the SPI pins pinmap_pinout(mosi, PinMap_SPI_MOSI); pinmap_pinout(miso, PinMap_SPI_MISO); pinmap_pinout(sclk, PinMap_SPI_SCLK); // Save new values obj->bits = SPI_DATASIZE_8BIT; obj->cpol = SPI_POLARITY_LOW; obj->cpha = SPI_PHASE_1EDGE; obj->br_presc = SPI_BAUDRATEPRESCALER_256; obj->pin_miso = miso; obj->pin_mosi = mosi; obj->pin_sclk = sclk; obj->pin_ssel = ssel; if (ssel == NC) { // SW NSS Master mode obj->mode = SPI_MODE_MASTER; obj->nss = SPI_NSS_SOFT; } else { // Slave pinmap_pinout(ssel, PinMap_SPI_SSEL); obj->mode = SPI_MODE_SLAVE; obj->nss = SPI_NSS_HARD_INPUT; } init_spi(obj); } void spi_free(spi_t *obj) { // Reset SPI and disable clock if (obj->spi == SPI_1) { __SPI1_FORCE_RESET(); __SPI1_RELEASE_RESET(); __SPI1_CLK_DISABLE(); } if (obj->spi == SPI_2) { __SPI2_FORCE_RESET(); __SPI2_RELEASE_RESET(); __SPI2_CLK_DISABLE(); } if (obj->spi == SPI_3) { __SPI3_FORCE_RESET(); __SPI3_RELEASE_RESET(); __SPI3_CLK_DISABLE(); } // Configure GPIOs pin_function(obj->pin_miso, STM_PIN_DATA(STM_MODE_INPUT, GPIO_NOPULL, 0)); pin_function(obj->pin_mosi, STM_PIN_DATA(STM_MODE_INPUT, GPIO_NOPULL, 0)); pin_function(obj->pin_sclk, STM_PIN_DATA(STM_MODE_INPUT, GPIO_NOPULL, 0)); pin_function(obj->pin_ssel, STM_PIN_DATA(STM_MODE_INPUT, GPIO_NOPULL, 0)); } void spi_format(spi_t *obj, int bits, int mode, int slave) { // Save new values if (bits == 16) { obj->bits = SPI_DATASIZE_16BIT; } else { obj->bits = SPI_DATASIZE_8BIT; } switch (mode) { case 0: obj->cpol = SPI_POLARITY_LOW; obj->cpha = SPI_PHASE_1EDGE; break; case 1: obj->cpol = SPI_POLARITY_LOW; obj->cpha = SPI_PHASE_2EDGE; break; case 2: obj->cpol = SPI_POLARITY_HIGH; obj->cpha = SPI_PHASE_1EDGE; break; default: obj->cpol = SPI_POLARITY_HIGH; obj->cpha = SPI_PHASE_2EDGE; break; } if (slave == 0) { obj->mode = SPI_MODE_MASTER; obj->nss = SPI_NSS_SOFT; } else { obj->mode = SPI_MODE_SLAVE; obj->nss = SPI_NSS_HARD_INPUT; } init_spi(obj); } void spi_frequency(spi_t *obj, int hz) { // Note: The frequencies are obtained with SPI1 clock = 84 MHz (APB2 clock) if (hz < 600000) { obj->br_presc = SPI_BAUDRATEPRESCALER_256; // 330 kHz } else if ((hz >= 600000) && (hz < 1000000)) { obj->br_presc = SPI_BAUDRATEPRESCALER_128; // 656 kHz } else if ((hz >= 1000000) && (hz < 2000000)) { obj->br_presc = SPI_BAUDRATEPRESCALER_64; // 1.3 MHz } else if ((hz >= 2000000) && (hz < 5000000)) { obj->br_presc = SPI_BAUDRATEPRESCALER_32; // 2.6 MHz } else if ((hz >= 5000000) && (hz < 10000000)) { obj->br_presc = SPI_BAUDRATEPRESCALER_16; // 5.25 MHz } else if ((hz >= 10000000) && (hz < 21000000)) { obj->br_presc = SPI_BAUDRATEPRESCALER_8; // 10.5 MHz } else if ((hz >= 21000000) && (hz < 42000000)) { obj->br_presc = SPI_BAUDRATEPRESCALER_4; // 21 MHz } else { // >= 42000000 obj->br_presc = SPI_BAUDRATEPRESCALER_2; // 42 MHz } init_spi(obj); } static inline int ssp_readable(spi_t *obj) { int status; SpiHandle.Instance = (SPI_TypeDef *)(obj->spi); // Check if data is received status = ((__HAL_SPI_GET_FLAG(&SpiHandle, SPI_FLAG_RXNE) != RESET) ? 1 : 0); return status; } static inline int ssp_writeable(spi_t *obj) { int status; SpiHandle.Instance = (SPI_TypeDef *)(obj->spi); // Check if data is transmitted status = ((__HAL_SPI_GET_FLAG(&SpiHandle, SPI_FLAG_TXE) != RESET) ? 1 : 0); return status; } static inline void ssp_write(spi_t *obj, int value) { SPI_TypeDef *spi = (SPI_TypeDef *)(obj->spi); while (!ssp_writeable(obj)); spi->DR = (uint16_t)value; } static inline int ssp_read(spi_t *obj) { SPI_TypeDef *spi = (SPI_TypeDef *)(obj->spi); while (!ssp_readable(obj)); return (int)spi->DR; } static inline int ssp_busy(spi_t *obj) { int status; SpiHandle.Instance = (SPI_TypeDef *)(obj->spi); status = ((__HAL_SPI_GET_FLAG(&SpiHandle, SPI_FLAG_BSY) != RESET) ? 1 : 0); return status; } int spi_master_write(spi_t *obj, int value) { ssp_write(obj, value); return ssp_read(obj); } int spi_slave_receive(spi_t *obj) { return ((ssp_readable(obj) && !ssp_busy(obj)) ? 1 : 0); }; int spi_slave_read(spi_t *obj) { SPI_TypeDef *spi = (SPI_TypeDef *)(obj->spi); while (!ssp_readable(obj)); return (int)spi->DR; } void spi_slave_write(spi_t *obj, int value) { SPI_TypeDef *spi = (SPI_TypeDef *)(obj->spi); while (!ssp_writeable(obj)); spi->DR = (uint16_t)value; } int spi_busy(spi_t *obj) { return ssp_busy(obj); } #endif