mirror of
https://github.com/DCC-EX/CommandStation-EX.git
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520 lines
22 KiB
C
520 lines
22 KiB
C
/*
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* © 2022-23 Paul M Antoine
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* © 2023, Neil McKechnie
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* All rights reserved.
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*
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* This file is part of CommandStation-EX
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*
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* This is free software: you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation, either version 3 of the License, or
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* (at your option) any later version.
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*
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* It is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with CommandStation. If not, see <https://www.gnu.org/licenses/>.
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*/
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#ifndef I2CMANAGER_STM32_H
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#define I2CMANAGER_STM32_H
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#include <Arduino.h>
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#include "I2CManager.h"
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#include "I2CManager_NonBlocking.h" // to satisfy intellisense
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#include <wiring_private.h>
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#include "stm32f4xx_hal_rcc.h"
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/*****************************************************************************
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* STM32F4xx I2C native driver support
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*
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* Nucleo-64 and Nucleo-144 boards all use I2C1 as the default I2C peripheral
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* Later we may wish to support other STM32 boards, allow use of an alternate
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* I2C bus, or more than one I2C bus on the STM32 architecture
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*****************************************************************************/
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#if defined(I2C_USE_INTERRUPTS) && defined(ARDUINO_ARCH_STM32)
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#if defined(ARDUINO_NUCLEO_F401RE) || defined(ARDUINO_NUCLEO_F411RE) || defined(ARDUINO_NUCLEO_F446RE) \
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|| defined(ARDUINO_NUCLEO_F412ZG) || defined(ARDUINO_NUCLEO_F413ZH) \
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|| defined(ARDUINO_NUCLEO_F429ZI) || defined(ARDUINO_NUCLEO_F446ZE)
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// Assume I2C1 for now - default I2C bus on Nucleo-F411RE and likely all Nucleo-64
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// and Nucleo-144 variants
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I2C_TypeDef *s = I2C1;
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// In init we will ask the STM32 HAL layer for the configured APB1 clock frequency in Hz
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uint32_t APB1clk1; // Peripheral Input Clock speed in Hz.
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uint32_t i2c_MHz; // Peripheral Input Clock speed in MHz.
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// IRQ handler for I2C1, replacing the weak definition in the STM32 HAL
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extern "C" void I2C1_EV_IRQHandler(void) {
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I2CManager.handleInterrupt();
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}
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extern "C" void I2C1_ER_IRQHandler(void) {
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I2CManager.handleInterrupt();
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}
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#else
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#warning STM32 board selected is not yet supported - so I2C1 peripheral is not defined
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#endif
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#endif
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// Peripheral Input Clock speed in MHz.
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// For STM32F446RE, the speed is 45MHz. Ideally, this should be determined
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// at run-time from the APB1 clock, as it can vary from STM32 family to family.
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// #define I2C_PERIPH_CLK 45
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// I2C SR1 Status Register #1 bit definitions for convenience
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// #define I2C_SR1_SMBALERT (1<<15) // SMBus alert
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// #define I2C_SR1_TIMEOUT (1<<14) // Timeout of Tlow error
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// #define I2C_SR1_PECERR (1<<12) // PEC error in reception
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// #define I2C_SR1_OVR (1<<11) // Overrun/Underrun error
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// #define I2C_SR1_AF (1<<10) // Acknowledge failure
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// #define I2C_SR1_ARLO (1<<9) // Arbitration lost (master mode)
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// #define I2C_SR1_BERR (1<<8) // Bus error (misplaced start or stop condition)
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// #define I2C_SR1_TxE (1<<7) // Data register empty on transmit
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// #define I2C_SR1_RxNE (1<<6) // Data register not empty on receive
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// #define I2C_SR1_STOPF (1<<4) // Stop detection (slave mode)
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// #define I2C_SR1_ADD10 (1<<3) // 10 bit header sent
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// #define I2C_SR1_BTF (1<<2) // Byte transfer finished - data transfer done
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// #define I2C_SR1_ADDR (1<<1) // Address sent (master) or matched (slave)
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// #define I2C_SR1_SB (1<<0) // Start bit (master mode) 1=start condition generated
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// I2C CR1 Control Register #1 bit definitions for convenience
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// #define I2C_CR1_SWRST (1<<15) // Software reset - places peripheral under reset
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// #define I2C_CR1_ALERT (1<<13) // SMBus alert assertion
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// #define I2C_CR1_PEC (1<<12) // Packet Error Checking transfer in progress
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// #define I2C_CR1_POS (1<<11) // Acknowledge/PEC Postion (for data reception in PEC mode)
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// #define I2C_CR1_ACK (1<<10) // Acknowledge enable - ACK returned after byte is received (address or data)
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// #define I2C_CR1_STOP (1<<9) // STOP generated
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// #define I2C_CR1_START (1<<8) // START generated
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// #define I2C_CR1_NOSTRETCH (1<<7) // Clock stretching disable (slave mode)
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// #define I2C_CR1_ENGC (1<<6) // General call (broadcast) enable (address 00h is ACKed)
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// #define I2C_CR1_ENPEC (1<<5) // PEC Enable
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// #define I2C_CR1_ENARP (1<<4) // ARP enable (SMBus)
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// #define I2C_CR1_SMBTYPE (1<<3) // SMBus type, 1=host, 0=device
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// #define I2C_CR1_SMBUS (1<<1) // SMBus mode, 1=SMBus, 0=I2C
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// #define I2C_CR1_PE (1<<0) // I2C Peripheral enable
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// States of the STM32 I2C driver state machine
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enum {TS_IDLE,TS_START,TS_W_ADDR,TS_W_DATA,TS_W_STOP,TS_R_ADDR,TS_R_DATA,TS_R_STOP};
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/***************************************************************************
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* Set I2C clock speed register. This should only be called outside of
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* a transmission. The I2CManagerClass::_setClock() function ensures
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* that it is only called at the beginning of an I2C transaction.
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***************************************************************************/
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void I2CManagerClass::I2C_setClock(uint32_t i2cClockSpeed) {
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// Calculate a rise time appropriate to the requested bus speed
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// Use 10x the rise time spec to enable integer divide of 50ns clock period
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uint16_t t_rise;
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while (s->CR1 & I2C_CR1_STOP); // Prevents lockup by guarding further
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// writes to CR1 while STOP is being executed!
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// Disable the I2C device, as TRISE can only be programmed whilst disabled
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s->CR1 &= ~(I2C_CR1_PE); // Disable I2C
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s->CR1 |= I2C_CR1_SWRST; // reset the I2C
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asm("nop"); // wait a bit... suggestion from online!
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s->CR1 &= ~(I2C_CR1_SWRST); // Normal operation
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if (i2cClockSpeed > 100000UL)
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{
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// if (i2cClockSpeed > 400000L)
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// i2cClockSpeed = 400000L;
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t_rise = 300; // nanoseconds
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}
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else
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{
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// i2cClockSpeed = 100000L;
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t_rise = 1000; // nanoseconds
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}
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// Configure the rise time register - max allowed tRISE is 1000ns,
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// so value = 1000ns * I2C_PERIPH_CLK MHz / 1000 + 1.
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s->TRISE = (t_rise * i2c_MHz / 1000) + 1;
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// Bit 15: I2C Master mode, 0=standard, 1=Fast Mode
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// Bit 14: Duty, fast mode duty cycle (use 2:1)
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// Bit 11-0: FREQR
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// if (i2cClockSpeed > 400000UL) {
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// // In fast mode plus, I2C period is 3 * CCR * TPCLK1.
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// // s->CCR &= ~(0x3000); // Clear all bits except 12 and 13 which must remain per reset value
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// s->CCR = APB1clk1 / 3 / i2cClockSpeed; // Set I2C clockspeed to start!
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// s->CCR |= 0xC000; // We need Fast Mode AND DUTY bits set
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// } else {
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// In standard and fast mode, I2C period is 2 * CCR * TPCLK1
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s->CCR &= ~(0x3000); // Clear all bits except 12 and 13 which must remain per reset value
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s->CCR |= (APB1clk1 / 2 / i2cClockSpeed); // Set I2C clockspeed to start!
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// s->CCR |= (i2c_MHz * 500 / (i2cClockSpeed / 1000)); // Set I2C clockspeed to start!
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// if (i2cClockSpeed > 100000UL)
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// s->CCR |= 0xC000; // We need Fast Mode bits set as well
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// }
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// DIAG(F("I2C_init() peripheral clock is now: %d, full reg is %x"), (s->CR2 & 0xFF), s->CR2);
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// DIAG(F("I2C_init() peripheral CCR is now: %d"), s->CCR);
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// DIAG(F("I2C_init() peripheral TRISE is now: %d"), s->TRISE);
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// Enable the I2C master mode
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s->CR1 |= I2C_CR1_PE; // Enable I2C
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}
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/***************************************************************************
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* Initialise I2C registers.
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***************************************************************************/
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void I2CManagerClass::I2C_init()
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{
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// Query the clockspeed from the STM32 HAL layer
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APB1clk1 = HAL_RCC_GetPCLK1Freq();
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i2c_MHz = APB1clk1 / 1000000UL;
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// DIAG(F("I2C_init() peripheral clock speed is: %d"), i2c_MHz);
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// Enable clocks
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RCC->APB1ENR |= RCC_APB1ENR_I2C1EN;//(1 << 21); // Enable I2C CLOCK
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// Reset the I2C1 peripheral to initial state
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RCC->APB1RSTR |= RCC_APB1RSTR_I2C1RST;
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RCC->APB1RSTR &= ~RCC_APB1RSTR_I2C1RST;
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// Standard I2C pins are SCL on PB8 and SDA on PB9
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RCC->AHB1ENR |= (1<<1); // Enable GPIOB CLOCK for PB8/PB9
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// Bits (17:16)= 1:0 --> Alternate Function for Pin PB8;
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// Bits (19:18)= 1:0 --> Alternate Function for Pin PB9
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GPIOB->MODER &= ~((3<<(8*2)) | (3<<(9*2))); // Clear all MODER bits for PB8 and PB9
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GPIOB->MODER |= (2<<(8*2)) | (2<<(9*2)); // PB8 and PB9 set to ALT function
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GPIOB->OTYPER |= (1<<8) | (1<<9); // PB8 and PB9 set to open drain output capability
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GPIOB->OSPEEDR |= (3<<(8*2)) | (3<<(9*2)); // PB8 and PB9 set to High Speed mode
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GPIOB->PUPDR &= ~((3<<(8*2)) | (3<<(9*2))); // Clear all PUPDR bits for PB8 and PB9
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GPIOB->PUPDR |= (1<<(8*2)) | (1<<(9*2)); // PB8 and PB9 set to pull-up capability
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// Alt Function High register routing pins PB8 and PB9 for I2C1:
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// Bits (3:2:1:0) = 0:1:0:0 --> AF4 for pin PB8
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// Bits (7:6:5:4) = 0:1:0:0 --> AF4 for pin PB9
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GPIOB->AFR[1] &= ~((15<<0) | (15<<4)); // Clear all AFR bits for PB8 on low nibble, PB9 on next nibble up
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GPIOB->AFR[1] |= (4<<0) | (4<<4); // PB8 on low nibble, PB9 on next nibble up
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// Software reset the I2C peripheral
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I2C1->CR1 &= ~I2C_CR1_PE; // Disable I2C1 peripheral
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s->CR1 |= I2C_CR1_SWRST; // reset the I2C
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asm("nop"); // wait a bit... suggestion from online!
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s->CR1 &= ~(I2C_CR1_SWRST); // Normal operation
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// Clear all bits in I2C CR2 register except reserved bits
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s->CR2 &= 0xE000;
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// Set I2C peripheral clock frequency
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// s->CR2 |= I2C_PERIPH_CLK;
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s->CR2 |= i2c_MHz;
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// DIAG(F("I2C_init() peripheral clock is now: %d"), s->CR2);
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// set own address to 00 - not used in master mode
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I2C1->OAR1 = (1 << 14); // bit 14 should be kept at 1 according to the datasheet
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#if defined(I2C_USE_INTERRUPTS)
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// Setting NVIC
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NVIC_SetPriority(I2C1_EV_IRQn, 1); // Match default priorities
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NVIC_EnableIRQ(I2C1_EV_IRQn);
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NVIC_SetPriority(I2C1_ER_IRQn, 1); // Match default priorities
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NVIC_EnableIRQ(I2C1_ER_IRQn);
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// CR2 Interrupt Settings
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// Bit 15-13: reserved
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// Bit 12: LAST - DMA last transfer
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// Bit 11: DMAEN - DMA enable
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// Bit 10: ITBUFEN - Buffer interrupt enable
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// Bit 9: ITEVTEN - Event interrupt enable
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// Bit 8: ITERREN - Error interrupt enable
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// Bit 7-6: reserved
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// Bit 5-0: FREQ - Peripheral clock frequency (max 50MHz)
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s->CR2 |= (I2C_CR2_ITBUFEN | I2C_CR2_ITEVTEN | I2C_CR2_ITERREN); // Enable Buffer, Event and Error interrupts
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#endif
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// DIAG(F("I2C_init() setting initial I2C clock to 100KHz"));
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// Calculate baudrate and set default rate for now
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// Configure the Clock Control Register for 100KHz SCL frequency
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// Bit 15: I2C Master mode, 0=standard, 1=Fast Mode
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// Bit 14: Duty, fast mode duty cycle
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// Bit 11-0: so CCR divisor would be clk / 2 / 100000 (where clk is in Hz)
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// s->CCR = I2C_PERIPH_CLK * 5;
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s->CCR &= ~(0x3000); // Clear all bits except 12 and 13 which must remain per reset value
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s->CCR |= (APB1clk1 / 2 / 100000UL); // Set a default of 100KHz I2C clockspeed to start!
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// Configure the rise time register - max allowed is 1000ns, so value = 1000ns * I2C_PERIPH_CLK MHz / 1000 + 1.
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s->TRISE = (1000 * i2c_MHz / 1000) + 1;
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// DIAG(F("I2C_init() peripheral clock is now: %d, full reg is %x"), (s->CR2 & 0xFF), s->CR2);
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// DIAG(F("I2C_init() peripheral CCR is now: %d"), s->CCR);
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// DIAG(F("I2C_init() peripheral TRISE is now: %d"), s->TRISE);
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// Enable the I2C master mode
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s->CR1 |= I2C_CR1_PE; // Enable I2C
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}
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/***************************************************************************
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* Initiate a start bit for transmission.
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***************************************************************************/
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void I2CManagerClass::I2C_sendStart() {
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// Set counters here in case this is a retry.
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rxCount = txCount = 0;
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// On a single-master I2C bus, the start bit won't be sent until the bus
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// state goes to IDLE so we can request it without waiting. On a
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// multi-master bus, the bus may be BUSY under control of another master,
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// in which case we can avoid some arbitration failures by waiting until
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// the bus state is IDLE. We don't do that here.
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//while (s->SR2 & I2C_SR2_BUSY) {}
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// Check there's no STOP still in progress. If we OR the START bit into CR1
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// and the STOP bit is already set, we could output multiple STOP conditions.
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while (s->CR1 & I2C_CR1_STOP) {} // Wait for STOP bit to reset
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s->CR2 |= (I2C_CR2_ITEVTEN | I2C_CR2_ITERREN); // Enable interrupts
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s->CR2 &= ~I2C_CR2_ITBUFEN; // Don't enable buffer interupts yet.
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s->CR1 &= ~I2C_CR1_POS; // Clear the POS bit
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s->CR1 |= (I2C_CR1_ACK | I2C_CR1_START); // Enable the ACK and generate START
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transactionState = TS_START;
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}
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/***************************************************************************
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* Initiate a stop bit for transmission (does not interrupt)
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***************************************************************************/
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void I2CManagerClass::I2C_sendStop() {
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s->CR1 |= I2C_CR1_STOP; // Stop I2C
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}
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/***************************************************************************
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* Close I2C down
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***************************************************************************/
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void I2CManagerClass::I2C_close() {
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I2C_sendStop();
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// Disable the I2C master mode and wait for sync
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s->CR1 &= ~I2C_CR1_PE; // Disable I2C peripheral
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// Should never happen, but wait for up to 500us only.
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unsigned long startTime = micros();
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while ((s->CR1 & I2C_CR1_PE) != 0) {
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if ((int32_t)(micros() - startTime) >= 500) break;
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}
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NVIC_DisableIRQ(I2C1_EV_IRQn);
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NVIC_DisableIRQ(I2C1_ER_IRQn);
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}
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/***************************************************************************
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* Main state machine for I2C, called from interrupt handler or,
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* if I2C_USE_INTERRUPTS isn't defined, from the I2CManagerClass::loop() function
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* (and therefore, indirectly, from I2CRB::wait() and I2CRB::isBusy()).
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***************************************************************************/
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void I2CManagerClass::I2C_handleInterrupt() {
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volatile uint16_t temp_sr1, temp_sr2;
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temp_sr1 = s->SR1;
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// Check for errors first
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if (temp_sr1 & (I2C_SR1_AF | I2C_SR1_ARLO | I2C_SR1_BERR)) {
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// Check which error flag is set
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if (temp_sr1 & I2C_SR1_AF)
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{
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s->SR1 &= ~(I2C_SR1_AF); // Clear AF
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I2C_sendStop(); // Clear the bus
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transactionState = TS_IDLE;
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completionStatus = I2C_STATUS_NEGATIVE_ACKNOWLEDGE;
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state = I2C_STATE_COMPLETED;
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}
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else if (temp_sr1 & I2C_SR1_ARLO)
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{
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// Arbitration lost, restart
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s->SR1 &= ~(I2C_SR1_ARLO); // Clear ARLO
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I2C_sendStart(); // Reinitiate request
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transactionState = TS_START;
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}
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else if (temp_sr1 & I2C_SR1_BERR)
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{
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// Bus error
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s->SR1 &= ~(I2C_SR1_BERR); // Clear BERR
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I2C_sendStop(); // Clear the bus
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transactionState = TS_IDLE;
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completionStatus = I2C_STATUS_BUS_ERROR;
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state = I2C_STATE_COMPLETED;
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}
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}
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else {
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// No error flags, so process event according to current state.
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switch (transactionState) {
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case TS_START:
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if (temp_sr1 & I2C_SR1_SB) {
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// Event EV5
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// Start bit has been sent successfully and we have the bus.
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// If anything to send, initiate write. Otherwise initiate read.
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if (operation == OPERATION_READ || ((operation == OPERATION_REQUEST) && !bytesToSend)) {
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// Send address with read flag (1) or'd in
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s->DR = (deviceAddress << 1) | 1; // send the address
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transactionState = TS_R_ADDR;
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} else {
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// Send address with write flag (0) or'd in
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s->DR = (deviceAddress << 1) | 0; // send the address
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transactionState = TS_W_ADDR;
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}
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}
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// SB bit is cleared by writing to DR (already done).
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break;
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case TS_W_ADDR:
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if (temp_sr1 & I2C_SR1_ADDR) {
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temp_sr2 = s->SR2; // read SR2 to complete clearing the ADDR bit
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// Event EV6
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// Address sent successfully, device has ack'd in response.
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if (!bytesToSend) {
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I2C_sendStop();
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transactionState = TS_IDLE;
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completionStatus = I2C_STATUS_OK;
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state = I2C_STATE_COMPLETED;
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} else {
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// Put one byte into DR to load shift register.
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s->DR = sendBuffer[txCount++];
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bytesToSend--;
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if (bytesToSend) {
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// Put another byte to load DR
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s->DR = sendBuffer[txCount++];
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bytesToSend--;
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}
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if (!bytesToSend) {
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// No more bytes to send.
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// The TXE interrupt occurs when the DR is empty, and the BTF interrupt
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// occurs when the shift register is also empty (one character later).
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// To avoid repeated TXE interrupts during this time, we disable TXE interrupt.
|
|
s->CR2 &= ~I2C_CR2_ITBUFEN; // Wait for BTF interrupt, disable TXE interrupt
|
|
transactionState = TS_W_STOP;
|
|
} else {
|
|
// More data remaining to send after this interrupt, enable TXE interrupt.
|
|
s->CR2 |= I2C_CR2_ITBUFEN;
|
|
transactionState = TS_W_DATA;
|
|
}
|
|
}
|
|
}
|
|
break;
|
|
|
|
case TS_W_DATA:
|
|
if (temp_sr1 & I2C_SR1_TXE) {
|
|
// Event EV8_1/EV8
|
|
// Transmitter empty, write a byte to it.
|
|
if (bytesToSend) {
|
|
s->DR = sendBuffer[txCount++];
|
|
bytesToSend--;
|
|
if (!bytesToSend) {
|
|
s->CR2 &= ~I2C_CR2_ITBUFEN; // Disable TXE interrupt
|
|
transactionState = TS_W_STOP;
|
|
}
|
|
}
|
|
}
|
|
break;
|
|
|
|
case TS_W_STOP:
|
|
if (temp_sr1 & I2C_SR1_BTF) {
|
|
// Event EV8_2
|
|
// Done, last character sent. Anything to receive?
|
|
if (bytesToReceive) {
|
|
I2C_sendStart();
|
|
// NOTE: Three redundant BTF interrupts take place between the
|
|
// first BTF interrupt and the START interrupt. I've tried all sorts
|
|
// of ways to eliminate them, and the only thing that worked for
|
|
// me was to loop until the BTF bit becomes reset. Either way,
|
|
// it's a waste of processor time. Anyone got a solution?
|
|
//while (s->SR1 && I2C_SR1_BTF) {}
|
|
transactionState = TS_START;
|
|
} else {
|
|
I2C_sendStop();
|
|
transactionState = TS_IDLE;
|
|
completionStatus = I2C_STATUS_OK;
|
|
state = I2C_STATE_COMPLETED;
|
|
}
|
|
s->SR1 &= I2C_SR1_BTF; // Clear BTF interrupt
|
|
}
|
|
break;
|
|
|
|
case TS_R_ADDR:
|
|
if (temp_sr1 & I2C_SR1_ADDR) {
|
|
// Event EV6
|
|
// Address sent for receive.
|
|
// The next bit is different depending on whether there are
|
|
// 1 byte, 2 bytes or >2 bytes to be received, in accordance with the
|
|
// Programmers Reference RM0390.
|
|
if (bytesToReceive == 1) {
|
|
// Receive 1 byte
|
|
s->CR1 &= ~I2C_CR1_ACK; // Disable ack
|
|
temp_sr2 = s->SR2; // read SR2 to complete clearing the ADDR bit
|
|
// Next step will occur after a RXNE interrupt, so enable it
|
|
s->CR2 |= I2C_CR2_ITBUFEN;
|
|
transactionState = TS_R_STOP;
|
|
} else if (bytesToReceive == 2) {
|
|
// Receive 2 bytes
|
|
s->CR1 &= ~I2C_CR1_ACK; // Disable ACK for final byte
|
|
s->CR1 |= I2C_CR1_POS; // set POS flag to delay effect of ACK flag
|
|
// Next step will occur after a BTF interrupt, so disable RXNE interrupt
|
|
s->CR2 &= ~I2C_CR2_ITBUFEN;
|
|
temp_sr2 = s->SR2; // read SR2 to complete clearing the ADDR bit
|
|
transactionState = TS_R_STOP;
|
|
} else {
|
|
// >2 bytes, just wait for bytes to come in and ack them for the time being
|
|
// (ack flag has already been set).
|
|
// Next step will occur after a BTF interrupt, so disable RXNE interrupt
|
|
s->CR2 &= ~I2C_CR2_ITBUFEN;
|
|
temp_sr2 = s->SR2; // read SR2 to complete clearing the ADDR bit
|
|
transactionState = TS_R_DATA;
|
|
}
|
|
}
|
|
break;
|
|
|
|
case TS_R_DATA:
|
|
// Event EV7/EV7_1
|
|
if (temp_sr1 & I2C_SR1_BTF) {
|
|
// Byte received in receiver - read next byte
|
|
if (bytesToReceive == 3) {
|
|
// Getting close to the last byte, so a specific sequence is recommended.
|
|
s->CR1 &= ~I2C_CR1_ACK; // Reset ack for next byte received.
|
|
transactionState = TS_R_STOP;
|
|
}
|
|
receiveBuffer[rxCount++] = s->DR; // Store received byte
|
|
bytesToReceive--;
|
|
}
|
|
break;
|
|
|
|
case TS_R_STOP:
|
|
if (temp_sr1 & I2C_SR1_BTF) {
|
|
// Event EV7 (last one)
|
|
// When we've got here, the receiver has got the last two bytes
|
|
// (or one byte, if only one byte is being received),
|
|
// and NAK has already been sent, so we need to read from the receiver.
|
|
if (bytesToReceive) {
|
|
if (bytesToReceive > 1)
|
|
I2C_sendStop();
|
|
while(bytesToReceive) {
|
|
receiveBuffer[rxCount++] = s->DR; // Store received byte(s)
|
|
bytesToReceive--;
|
|
}
|
|
// Finish.
|
|
transactionState = TS_IDLE;
|
|
completionStatus = I2C_STATUS_OK;
|
|
state = I2C_STATE_COMPLETED;
|
|
}
|
|
} else if (temp_sr1 & I2C_SR1_RXNE) {
|
|
if (bytesToReceive == 1) {
|
|
// One byte on a single-byte transfer. Ack has already been set.
|
|
I2C_sendStop();
|
|
receiveBuffer[rxCount++] = s->DR; // Store received byte
|
|
bytesToReceive--;
|
|
// Finish.
|
|
transactionState = TS_IDLE;
|
|
completionStatus = I2C_STATUS_OK;
|
|
state = I2C_STATE_COMPLETED;
|
|
} else
|
|
s->SR1 &= I2C_SR1_RXNE; // Acknowledge interrupt
|
|
}
|
|
break;
|
|
}
|
|
// If we've received an interrupt at any other time, we're not interested so clear it
|
|
// to prevent it recurring ad infinitum.
|
|
s->SR1 = 0;
|
|
}
|
|
|
|
}
|
|
|
|
#endif /* I2CMANAGER_STM32_H */
|