/* ***************************************************************************** * 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. * ****************************************************************************/ /** * @brief */ #include "libmaple.h" #include "rcc.h" #include "nvic.h" #include "gpio.h" #include "nvic.h" #include "i2c.h" #include "string.h" static inline int32 wait_for_state_change(i2c_dev *dev, i2c_state state); static i2c_dev i2c_dev1 = { .regs = (i2c_reg_map*)I2C1_BASE, .gpio_port = GPIOB_BASE, .sda_pin = 7, .scl_pin = 6, .clk_line = RCC_I2C1, .ev_nvic_line = NVIC_I2C1_EV, .er_nvic_line = NVIC_I2C1_ER, .state = I2C_STATE_IDLE }; i2c_dev* const I2C1 = &i2c_dev1; struct crumb { uint32 event; uint32 sr1; uint32 sr2; }; #define NR_CRUMBS 128 static struct crumb crumbs[NR_CRUMBS]; static uint32 cur_crumb = 0; static inline void leave_big_crumb(uint32 event, uint32 sr1, uint32 sr2) { if (cur_crumb < NR_CRUMBS) { struct crumb *crumb = &crumbs[cur_crumb++]; crumb->event = event; crumb->sr1 = sr1; crumb->sr2 = sr2; } } enum { IRQ_ENTRY = 1, TXE_ONLY = 2, TXE_BTF = 3, STOP_SENT = 4, TEST = 5, RX_ADDR_START = 6, RX_ADDR_STOP = 7, RXNE_ONLY = 8, RXNE_SENDING = 9, RXNE_START_SENT = 10, RXNE_STOP_SENT = 11, RXNE_DONE = 12, ERROR_ENTRY = 13, }; /** * @brief IRQ handler for i2c master. Handles transmission/reception. * @param dev i2c device */ static void i2c_irq_handler(i2c_dev *dev) { i2c_msg *msg = dev->msg; uint8 read = msg->flags & I2C_MSG_READ; uint32 sr1 = dev->regs->SR1; uint32 sr2 = dev->regs->SR2; leave_big_crumb(IRQ_ENTRY, sr1, sr2); /* * EV5: Start condition sent */ if (sr1 & I2C_SR1_SB) { msg->xferred = 0; i2c_enable_irq(dev, I2C_IRQ_BUFFER); /* * Master receiver */ if (read) { i2c_enable_ack(dev); } i2c_send_slave_addr(dev, msg->addr, read); sr1 = sr2 = 0; } /* * EV6: Slave address sent */ if (sr1 & I2C_SR1_ADDR) { /* * Special case event EV6_1 for master receiver. * Generate NACK and restart/stop condition after ADDR * is cleared. */ if (read) { if (msg->length == 1) { i2c_disable_ack(dev); if (dev->msgs_left > 1) { i2c_start_condition(dev); leave_big_crumb(RX_ADDR_START, 0, 0); } else { i2c_stop_condition(dev); leave_big_crumb(RX_ADDR_STOP, 0, 0); } } } else { /* * Master transmitter: write first byte to fill shift register. * We should get another TXE interrupt immediately to fill DR again. */ i2c_write(dev, msg->data[msg->xferred++]); } sr1 = sr2 = 0; } /* * EV8: Master transmitter * Transmit buffer empty, but we haven't finished transmitting the last * byte written. */ if ((sr1 & I2C_SR1_TXE) && !(sr1 & I2C_SR1_BTF)) { leave_big_crumb(TXE_ONLY, 0, 0); if (dev->msgs_left) { i2c_write(dev, msg->data[msg->xferred++]); if (msg->xferred == msg->length) { /* * End of this message. Turn off TXE/RXNE and wait for * BTF to send repeated start or stop condition. */ i2c_disable_irq(dev, I2C_IRQ_BUFFER); dev->msgs_left--; } } else { /* * This should be impossible... */ throb(); } sr1 = sr2 = 0; } /* * EV8_2: Master transmitter * Last byte sent, program repeated start/stop */ if ((sr1 & I2C_SR1_TXE) && (sr1 & I2C_SR1_BTF)) { leave_big_crumb(TXE_BTF, 0, 0); if (dev->msgs_left) { leave_big_crumb(TEST, 0, 0); /* * Repeated start insanity: We can't disable ITEVTEN or else SB * won't interrupt, but if we don't disable ITEVTEN, BTF will * continually interrupt us. What the fuck ST? */ i2c_start_condition(dev); while (!(dev->regs->SR1 & I2C_SR1_SB)) ; dev->msg++; } else { i2c_stop_condition(dev); /* * Turn off event interrupts to keep BTF from firing until the end * of the stop condition. Why on earth they didn't have a start/stop * condition request clear BTF is beyond me. */ i2c_disable_irq(dev, I2C_IRQ_EVENT); leave_big_crumb(STOP_SENT, 0, 0); dev->state = I2C_STATE_XFER_DONE; } sr1 = sr2 = 0; } /* * EV7: Master Receiver */ if (sr1 & I2C_SR1_RXNE) { leave_big_crumb(RXNE_ONLY, 0, 0); msg->data[msg->xferred++] = dev->regs->DR; /* * EV7_1: Second to last byte in the reception? Set NACK and generate * stop/restart condition in time for the last byte. We'll get one more * RXNE interrupt before shutting things down. */ if (msg->xferred == (msg->length - 1)) { i2c_disable_ack(dev); if (dev->msgs_left > 2) { i2c_start_condition(dev); leave_big_crumb(RXNE_START_SENT, 0, 0); } else { i2c_stop_condition(dev); leave_big_crumb(RXNE_STOP_SENT, 0, 0); } } else if (msg->xferred == msg->length) { dev->msgs_left--; if (dev->msgs_left == 0) { /* * We're done. */ leave_big_crumb(RXNE_DONE, 0, 0); dev->state = I2C_STATE_XFER_DONE; } else { dev->msg++; } } } } void __irq_i2c1_ev(void) { i2c_irq_handler(&i2c_dev1); } static void i2c_irq_error_handler(i2c_dev *dev) { uint32 sr1 = dev->regs->SR1; uint32 sr2 = dev->regs->SR2; leave_big_crumb(ERROR_ENTRY, sr1, sr2); i2c_stop_condition(dev); i2c_disable_irq(dev, I2C_IRQ_BUFFER | I2C_IRQ_EVENT | I2C_IRQ_ERROR); dev->state = I2C_STATE_ERROR; } void __irq_i2c1_er(void) { i2c_irq_error_handler(&i2c_dev1); } static void i2c_bus_reset(const i2c_dev *dev) { /* Release both lines */ gpio_write_bit(dev->gpio_port, dev->scl_pin, 1); gpio_write_bit(dev->gpio_port, dev->sda_pin, 1); gpio_set_mode(dev->gpio_port, dev->scl_pin, GPIO_MODE_OUTPUT_OD); gpio_set_mode(dev->gpio_port, dev->sda_pin, GPIO_MODE_OUTPUT_OD); /* * Make sure the bus is free by clocking it until any slaves release the * bus. */ while (!gpio_read_bit(dev->gpio_port, dev->sda_pin)) { /* Wait for any clock stretching to finish */ while (!gpio_read_bit(dev->gpio_port, dev->scl_pin)) ; delay_us(10); /* Pull low */ gpio_write_bit(dev->gpio_port, dev->scl_pin, 0); delay_us(10); /* Release high again */ gpio_write_bit(dev->gpio_port, dev->scl_pin, 1); delay_us(10); } /* Generate start then stop condition */ gpio_write_bit(dev->gpio_port, dev->sda_pin, 0); delay_us(10); gpio_write_bit(dev->gpio_port, dev->scl_pin, 0); delay_us(10); gpio_write_bit(dev->gpio_port, dev->scl_pin, 1); delay_us(10); gpio_write_bit(dev->gpio_port, dev->sda_pin, 1); } /** * @brief Initialize an i2c device as bus master * @param device to enable * @param flags bitwise or of the following I2C options: * I2C_FAST_MODE: 400 khz operation * I2C_10BIT_ADDRESSING: Enable 10-bit addressing */ void i2c_master_enable(i2c_dev *dev, uint32 flags) { #define STANDARD_CCR (PCLK1/(100000*2)) #define STANDARD_TRISE 37 /* Reset the bus. Clock out any hung slaves. */ i2c_bus_reset(dev); /* Turn on clock and set GPIO modes */ rcc_reset_dev(dev->clk_line); rcc_clk_enable(dev->clk_line); gpio_set_mode(dev->gpio_port, dev->sda_pin, GPIO_MODE_AF_OUTPUT_OD); gpio_set_mode(dev->gpio_port, dev->scl_pin, GPIO_MODE_AF_OUTPUT_OD); /* I2C1 and I2C2 are fed from APB1, clocked at 36MHz */ i2c_set_input_clk(dev, 36); /* 100 khz only for now */ i2c_set_clk_control(dev, STANDARD_CCR); /* * Set scl rise time, standard mode for now. * Max rise time in standard mode: 1000 ns * Max rise time in fast mode: 300ns */ i2c_set_trise(dev, STANDARD_TRISE); /* Enable event and buffer interrupts */ nvic_irq_enable(dev->ev_nvic_line); nvic_irq_enable(dev->er_nvic_line); i2c_enable_irq(dev, I2C_IRQ_EVENT | I2C_IRQ_BUFFER | I2C_IRQ_ERROR); /* * Important STM32 Errata: * * See STM32F10xx8 and STM32F10xxB Errata sheet (Doc ID 14574 Rev 8), * Section 2.11.1, 2.11.2. * * 2.11.1: * When the EV7, EV7_1, EV6_1, EV6_3, EV2, EV8, and EV3 events are not * managed before the current byte is being transferred, problems may be * encountered such as receiving an extra byte, reading the same data twice * or missing data. * * 2.11.2: * In Master Receiver mode, when closing the communication using * method 2, the content of the last read data can be corrupted. * * If the user software is not able to read the data N-1 before the STOP * condition is generated on the bus, the content of the shift register * (data N) will be corrupted. (data N is shifted 1-bit to the left). * * ---------------------------------------------------------------------- * * In order to ensure that events are not missed, the i2c interrupt must * not be preempted. We set the i2c interrupt priority to be the highest * interrupt in the system (priority level 0). All other interrupts have * been initialized to priority level 16. See nvic_init(). */ nvic_irq_set_priority(dev->ev_nvic_line, 0); nvic_irq_set_priority(dev->er_nvic_line, 0); /* Make it go! */ i2c_peripheral_enable(dev); } int32 i2c_master_xfer(i2c_dev *dev, i2c_msg *msgs, uint16 num) { int32 rc; dev->msg = msgs; dev->msgs_left = num; while (dev->regs->SR2 & I2C_SR2_BUSY) ; dev->state = I2C_STATE_BUSY; i2c_enable_irq(dev, I2C_IRQ_EVENT); i2c_start_condition(dev); rc = wait_for_state_change(dev, I2C_STATE_XFER_DONE); if (rc < 0) { goto out; } dev->state = I2C_STATE_IDLE; rc = num; out: return rc; } static inline int32 wait_for_state_change(i2c_dev *dev, i2c_state state) { int32 rc; i2c_state tmp; while (1) { tmp = dev->state; if ((tmp == state) || (tmp == I2C_STATE_ERROR)) { return (tmp == I2C_STATE_ERROR) ? -1 : 0; } } }