/****************************************************************************** * 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 * @brief Wirish SPI implementation. */ #include #include #include #include #include #include struct spi_pins { uint8 nss; uint8 sck; uint8 miso; uint8 mosi; }; static const spi_pins* dev_to_spi_pins(spi_dev *dev); static void enable_device(spi_dev *dev, bool as_master, SPIFrequency frequency, spi_cfg_flag endianness, spi_mode mode); static const spi_pins board_spi_pins[] __FLASH__ = { {BOARD_SPI1_NSS_PIN, BOARD_SPI1_SCK_PIN, BOARD_SPI1_MISO_PIN, BOARD_SPI1_MOSI_PIN}, {BOARD_SPI2_NSS_PIN, BOARD_SPI2_SCK_PIN, BOARD_SPI2_MISO_PIN, BOARD_SPI2_MOSI_PIN}, #ifdef STM32_HIGH_DENSITY {BOARD_SPI3_NSS_PIN, BOARD_SPI3_SCK_PIN, BOARD_SPI3_MISO_PIN, BOARD_SPI3_MOSI_PIN}, #endif }; /* * Constructor */ HardwareSPI::HardwareSPI(uint32 spi_num) { switch (spi_num) { case 1: this->spi_d = SPI1; break; case 2: this->spi_d = SPI2; break; #ifdef STM32_HIGH_DENSITY case 3: this->spi_d = SPI3; break; #endif default: ASSERT(0); } } /* * Set up/tear down */ void HardwareSPI::begin(SPIFrequency frequency, uint32 bitOrder, uint32 mode) { if (mode >= 4) { ASSERT(0); return; } spi_cfg_flag end = bitOrder == MSBFIRST ? SPI_FRAME_MSB : SPI_FRAME_LSB; spi_mode m = (spi_mode)mode; enable_device(this->spi_d, true, frequency, end, m); } void HardwareSPI::begin(void) { this->begin(SPI_1_125MHZ, MSBFIRST, 0); } void HardwareSPI::beginSlave(uint32 bitOrder, uint32 mode) { if (mode >= 4) { ASSERT(0); return; } spi_cfg_flag end = bitOrder == MSBFIRST ? SPI_FRAME_MSB : SPI_FRAME_LSB; spi_mode m = (spi_mode)mode; enable_device(this->spi_d, false, (SPIFrequency)0, end, m); } void HardwareSPI::beginSlave(void) { this->beginSlave(MSBFIRST, 0); } void HardwareSPI::end(void) { if (!spi_is_enabled(this->spi_d)) { return; } // Follows RM0008's sequence for disabling a SPI in master/slave // full duplex mode. while (spi_is_rx_nonempty(this->spi_d)) { // FIXME [0.1.0] remove this once you have an interrupt based driver volatile uint16 rx __attribute__((unused)) = spi_rx_reg(this->spi_d); } while (!spi_is_tx_empty(this->spi_d)) ; while (spi_is_busy(this->spi_d)) ; spi_peripheral_disable(this->spi_d); } /* * I/O */ uint8 HardwareSPI::read(void) { uint8 buf[1]; this->read(buf, 1); return buf[0]; } void HardwareSPI::read(uint8 *buf, uint32 len) { uint32 rxed = 0; while (rxed < len) { while (!spi_is_rx_nonempty(this->spi_d)) ; buf[rxed++] = (uint8)spi_rx_reg(this->spi_d); } } void HardwareSPI::write(uint8 byte) { this->write(&byte, 1); } void HardwareSPI::write(const uint8 *data, uint32 length) { uint32 txed = 0; while (txed < length) { txed += spi_tx(this->spi_d, data + txed, length - txed); } } uint8 HardwareSPI::transfer(uint8 byte) { this->write(byte); return this->read(); } /* * Pin accessors */ uint8 HardwareSPI::misoPin(void) { return dev_to_spi_pins(this->spi_d)->miso; } uint8 HardwareSPI::mosiPin(void) { return dev_to_spi_pins(this->spi_d)->mosi; } uint8 HardwareSPI::sckPin(void) { return dev_to_spi_pins(this->spi_d)->sck; } uint8 HardwareSPI::nssPin(void) { return dev_to_spi_pins(this->spi_d)->nss; } /* * Deprecated functions */ uint8 HardwareSPI::send(uint8 data) { uint8 buf[] = {data}; return this->send(buf, 1); } uint8 HardwareSPI::send(uint8 *buf, uint32 len) { uint32 txed = 0; uint8 ret = 0; while (txed < len) { this->write(buf[txed++]); ret = this->read(); } return ret; } uint8 HardwareSPI::recv(void) { return this->read(); } /* * Auxiliary functions */ static void configure_gpios(spi_dev *dev, bool as_master); static spi_baud_rate determine_baud_rate(spi_dev *dev, SPIFrequency freq); static const spi_pins* dev_to_spi_pins(spi_dev *dev) { switch (dev->clk_id) { case RCC_SPI1: return board_spi_pins; case RCC_SPI2: return board_spi_pins + 1; #ifdef STM32_HIGH_DENSITY case RCC_SPI3: return board_spi_pins + 2; #endif default: return NULL; } } /* Enables the device in master or slave full duplex mode. If you * change this code, you must ensure that appropriate changes are made * to HardwareSPI::end(). */ static void enable_device(spi_dev *dev, bool as_master, SPIFrequency freq, spi_cfg_flag endianness, spi_mode mode) { spi_baud_rate baud = determine_baud_rate(dev, freq); uint32 cfg_flags = (endianness | SPI_DFF_8_BIT | SPI_SW_SLAVE | (as_master ? SPI_SOFT_SS : 0)); spi_init(dev); configure_gpios(dev, as_master); if (as_master) { spi_master_enable(dev, baud, mode, cfg_flags); } else { spi_slave_enable(dev, mode, cfg_flags); } } 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]; const stm32_pin_info *scki = &PIN_MAP[pins->sck]; const stm32_pin_info *misoi = &PIN_MAP[pins->miso]; const stm32_pin_info *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[MAX_SPI_FREQS] __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, SPIFrequency freq) { if (rcc_dev_clk(dev->clk_id) == RCC_APB2 && freq == SPI_140_625KHZ) { /* APB2 peripherals are too fast for 140.625 KHz */ ASSERT(0); return (spi_baud_rate)~0; } return (rcc_dev_clk(dev->clk_id) == RCC_APB2 ? baud_rates[freq + 1] : baud_rates[freq]); }