//***************************************************************************** // // am_hal_i2c_bit_bang.c //! @file //! //! @brief I2C bit bang module. //! //! These functions implement the I2C bit bang utility //! It implements an I2C interface at close to 400 kHz // //***************************************************************************** //***************************************************************************** // // Copyright (c) 2020, Ambiq Micro // 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 the copyright holder nor the names of its // contributors may be used to endorse or promote products derived from this // software without specific prior written permission. // // Third party software included in this distribution is subject to the // additional license terms as defined in the /docs/licenses directory. // // 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. // // This is part of revision 2.4.2 of the AmbiqSuite Development Package. // //***************************************************************************** #include #include #include "am_mcu_apollo.h" #include "am_hal_i2c_bit_bang.h" // Max number of clock cycles to wait for clock stretch #define I2C_BB_MAX_CLOCK_STRETCH_WAIT 100 #define I2C_BB_DESIRED_FREQ_HZ 400000 #define I2C_BB_CYCLES_PER_DELAY_COUNT 3 #define I2C_BB_ONE_BIT_TIME_IN_CYCLES (AM_HAL_CLKGEN_FREQ_MAX_HZ/I2C_BB_DESIRED_FREQ_HZ) #define I2C_BB_ONE_BIT_TIME_IN_DELAY_COUNT (I2C_BB_ONE_BIT_TIME_IN_CYCLES/I2C_BB_CYCLES_PER_DELAY_COUNT) // Number of loops (each worth 3 cycles) needed to delay for defined time // This is imprecise, as there is a setup time as well which is not accounted // for // One Bit time = 120 Cycles (400 kHz @ 48 MHz) #define HALF_BIT_TIME (I2C_BB_ONE_BIT_TIME_IN_DELAY_COUNT/2) #define QUARTER_BIT_TIME (I2C_BB_ONE_BIT_TIME_IN_DELAY_COUNT/4) #define ASM_DELAY am_hal_flash_delay // Empirically determined adjustments to account for the fact that there is a // variable time spent in actual processing as well, and hence we need not delay // for the full time. This processing time is variable based on exact processing // needed at various times, and will also vary based on compiler type and // optimization levels #define I2C_BB_TIMER_ADJUST 6 // Can not be more than QUARTER_BIT_TIME - 1 #define I2C_BB_TIMER_HI_ADJUST 15 // Can not be more than HALF_BIT_TIME - 1 #define I2C_BB_TIMER_LO_ADJUST 13 // Can not be more than HALF_BIT_TIME - 1 // Wait till it is time to end the SCL Hi Period #define WAIT_I2C_CLOCK_HI_PERIOD() ASM_DELAY(HALF_BIT_TIME - I2C_BB_TIMER_HI_ADJUST) // Wait till it is time to end the SCL Lo Period #define WAIT_I2C_CLOCK_LOW_PERIOD() ASM_DELAY(HALF_BIT_TIME - I2C_BB_TIMER_LO_ADJUST) // Delay for Quarter Clock #define WAIT_FOR_QUARTER_I2C_CLOCK() ASM_DELAY(QUARTER_BIT_TIME - I2C_BB_TIMER_ADJUST) #define WRITE_SCL_LO() \ do { \ AM_REGVAL(am_hal_i2c_bit_bang_priv.sck_reg_clr_addr) = (am_hal_i2c_bit_bang_priv.sck_reg_val); \ } while(0) #define PULL_SCL_HI() \ do { \ AM_REGVAL(am_hal_i2c_bit_bang_priv.sck_reg_set_addr) = (am_hal_i2c_bit_bang_priv.sck_reg_val); \ } while(0) #define GET_SCL() (AM_REGVAL(am_hal_i2c_bit_bang_priv.sck_reg_read_addr) & (am_hal_i2c_bit_bang_priv.sck_reg_val)) #define GET_SDA() (AM_REGVAL(am_hal_i2c_bit_bang_priv.sda_reg_read_addr) & (am_hal_i2c_bit_bang_priv.sda_reg_val)) #define WRITE_SDA_LO() \ do { \ AM_REGVAL(am_hal_i2c_bit_bang_priv.sda_reg_clr_addr) = (am_hal_i2c_bit_bang_priv.sda_reg_val); \ } while(0) #define PULL_SDA_HI() \ do { \ AM_REGVAL(am_hal_i2c_bit_bang_priv.sda_reg_set_addr) = (am_hal_i2c_bit_bang_priv.sda_reg_val); \ } while(0) //***************************************************************************** // // I2C Bit Bang Private Data Structure // //***************************************************************************** typedef struct am_util_bit_bang_priv { bool start_flag; uint32_t sck_gpio_number; uint32_t sda_gpio_number; uint32_t sck_reg_set_addr; uint32_t sck_reg_clr_addr; uint32_t sck_reg_read_addr; uint32_t sck_reg_val; uint32_t sda_reg_set_addr; uint32_t sda_reg_clr_addr; uint32_t sda_reg_read_addr; uint32_t sda_reg_val; } am_hal_i2c_bit_bang_priv_t; static am_hal_i2c_bit_bang_priv_t am_hal_i2c_bit_bang_priv; // // Wait for any stretched clock to go high // If it times out - return failure // static inline bool i2c_pull_and_wait_scl_hi(void) { // Maximum time to wait for clock stretching uint32_t maxLoop = 4*I2C_BB_MAX_CLOCK_STRETCH_WAIT + 1; // Pull SCL High PULL_SCL_HI(); // Poll for SCL to check for clock stretching while (!GET_SCL()) { if (--maxLoop == 0) { // timeout! return true; } WAIT_FOR_QUARTER_I2C_CLOCK(); } return false; } //***************************************************************************** // //! @brief Initialize i2c bit bang private data structure //! //! @param sck_gpio_number is the GPIO # for the I2C SCK clock pin //! @param sda_gpio_number is the GPIO # for the I2C SDA data pin //! //! This function initializes the I2C bit bang utility's internal data struct. //! //! returns None. // //***************************************************************************** am_hal_i2c_bit_bang_enum_e am_hal_i2c_bit_bang_init(uint32_t sck_gpio_number, uint32_t sda_gpio_number) { int i; // // remember GPIO pin assignments for I2C bus signals // am_hal_i2c_bit_bang_priv.sck_gpio_number = sck_gpio_number; am_hal_i2c_bit_bang_priv.sda_gpio_number = sda_gpio_number; am_hal_i2c_bit_bang_priv.sck_reg_set_addr = AM_HAL_GPIO_WTS_REG(sck_gpio_number); am_hal_i2c_bit_bang_priv.sck_reg_clr_addr = AM_HAL_GPIO_WTC_REG(sck_gpio_number); am_hal_i2c_bit_bang_priv.sck_reg_read_addr = AM_HAL_GPIO_RD_REG(sck_gpio_number); am_hal_i2c_bit_bang_priv.sck_reg_val = AM_HAL_GPIO_WTC_M(sck_gpio_number); am_hal_i2c_bit_bang_priv.sda_reg_set_addr = AM_HAL_GPIO_WTS_REG(sda_gpio_number); am_hal_i2c_bit_bang_priv.sda_reg_clr_addr = AM_HAL_GPIO_WTC_REG(sda_gpio_number); am_hal_i2c_bit_bang_priv.sda_reg_read_addr = AM_HAL_GPIO_RD_REG(sda_gpio_number); am_hal_i2c_bit_bang_priv.sda_reg_val = AM_HAL_GPIO_WTC_M(sda_gpio_number); // // Set SCK GPIO data bit high so we aren't pulling down the clock // am_hal_gpio_out_bit_set(sck_gpio_number); // // Set up SCK GPIO configuration bi-direction, input // am_hal_gpio_pin_config(sck_gpio_number, AM_HAL_PIN_OPENDRAIN | AM_HAL_GPIO_INPEN); // // Set SDA GPIO data bit high so we aren't pulling down the data line // am_hal_gpio_out_bit_set(sda_gpio_number); // // Set up SDA GPIO configuration bi-direction, input // am_hal_gpio_pin_config(sda_gpio_number, AM_HAL_PIN_OPENDRAIN | AM_HAL_GPIO_INPEN); // Now make sure we have control of the clock line // // Wait for any stretched clock to go high. Return if still not high // if (i2c_pull_and_wait_scl_hi()) { return AM_HAL_I2C_BIT_BANG_CLOCK_TIMEOUT; } if (!GET_SDA()) { // If previous transaction did not finish - SDA may be pulled low for a Read. // If so - need to flush out the data (max 8 bits) & NACK for (i = 0; i < 9; i++) { // // Pull down on clock line // WRITE_SCL_LO(); // // Delay for 1/2 bit cell time to start the clock and let peer write on SDA // WAIT_I2C_CLOCK_LOW_PERIOD(); if (i2c_pull_and_wait_scl_hi()) { return AM_HAL_I2C_BIT_BANG_CLOCK_TIMEOUT; } if (GET_SDA()) { // Send START/STOP to clear the bus // // Delay for 1/4 bit cell time // WAIT_FOR_QUARTER_I2C_CLOCK(); WRITE_SDA_LO(); // // Delay for 1/4 bit cell time // WAIT_FOR_QUARTER_I2C_CLOCK(); // // Pull down on clock line // WRITE_SCL_LO(); // // Delay for 1/2 bit cell time to start the clock and let peer write on SDA // WAIT_I2C_CLOCK_LOW_PERIOD(); // // Release the clock line // PULL_SCL_HI(); // // Delay for 1/4 bit cell time // WAIT_FOR_QUARTER_I2C_CLOCK(); PULL_SDA_HI(); // // Delay for 1/4 bit cell time // WAIT_FOR_QUARTER_I2C_CLOCK(); break; } } if (i == 9) { // It is it still stuck after 9 clocks - something is wrong. Need to bail out return AM_HAL_I2C_BIT_BANG_DATA_TIMEOUT; } } return AM_HAL_I2C_BIT_BANG_SUCCESS; } //***************************************************************************** // //! @brief Receive one data byte from an I2C device //! //! This function handles sending one byte to a slave device //! bNack defines if we should send an ACK or NACK //! //! returns the byte received // //***************************************************************************** static inline am_hal_i2c_bit_bang_enum_e i2c_receive_byte(uint8_t *pRxByte, bool bNack) { int i; uint8_t data_byte = 0; // // Loop through receiving 8 bits // for (i = 0; i < 8; i++) { // // Pull down on clock line // WRITE_SCL_LO(); // // release the data line from from the previous ACK // PULL_SDA_HI(); // // Delay for 1/2 bit cell time to start the clock and let peer write on SDA // WAIT_I2C_CLOCK_LOW_PERIOD(); if (i2c_pull_and_wait_scl_hi()) { return AM_HAL_I2C_BIT_BANG_CLOCK_TIMEOUT; } // // grab the data bit here // if ( GET_SDA() ) { // // set the bit in the data byte to be returned // data_byte |= (0x80 >> i); } // // Delay for 1/2 bit cell time while clock is high // WAIT_I2C_CLOCK_HI_PERIOD(); } *pRxByte = data_byte; // // Pull down on clock line // WRITE_SCL_LO(); // // pull the data line down so we can ACK/NAK the byte we just received // if (bNack) { // // Pull up on data line with clock low to indicate NAK // PULL_SDA_HI(); } else { // // Pull down on data line with clock low to indicate ACK // WRITE_SDA_LO(); } // // Delay for 1/2 bit cell time before sending ACK to device // WAIT_I2C_CLOCK_LOW_PERIOD(); if (i2c_pull_and_wait_scl_hi()) { return AM_HAL_I2C_BIT_BANG_CLOCK_TIMEOUT; } // // Delay for 1/2 bit cell time while clock is high to le peer sample the ACK/NAK // WAIT_I2C_CLOCK_HI_PERIOD(); // // Give the received data byte back to them // return AM_HAL_I2C_BIT_BANG_SUCCESS; } //***************************************************************************** // //! @brief Send one data bytes to an I2C device //! //! @param one_byte the byte to send, could be address could be data //! //! This function handles sending one byte to a slave device //! Starts with 0 clock and runs till full cycle //! //! returns I2C BB ENUM //! { //! AM_HAL_I2C_BIT_BANG_SUCCESS, //! AM_HAL_I2C_BIT_BANG_ADDRESS_NAKED //! } // //***************************************************************************** static inline am_hal_i2c_bit_bang_enum_e i2c_send_byte(uint8_t one_byte) { int i; bool data_naked = false; // // Loop through sending 8 bits // for (i = 0; i < 8; i++) { // // Pull down on clock line // WRITE_SCL_LO(); // // output the next data bit // if ( one_byte & (0x80 >> i) ) { PULL_SDA_HI(); } else { WRITE_SDA_LO(); } // // Delay for 1/2 bit cell time to start the clock // WAIT_I2C_CLOCK_LOW_PERIOD(); if (i2c_pull_and_wait_scl_hi()) { return AM_HAL_I2C_BIT_BANG_CLOCK_TIMEOUT; } // // Delay for 1/2 bit cell time while clock is high // WAIT_I2C_CLOCK_HI_PERIOD(); } // // Pull down on clock line // WRITE_SCL_LO(); // // Delay for 1/2 bit cell time to start the clock // WAIT_I2C_CLOCK_LOW_PERIOD(); if (i2c_pull_and_wait_scl_hi()) { return AM_HAL_I2C_BIT_BANG_CLOCK_TIMEOUT; } // // Grab the state of the ACK bit and return it // data_naked = GET_SDA(); // // Delay for 1/2 bit cell time to complete the high period // WAIT_I2C_CLOCK_HI_PERIOD(); if ( data_naked ) { return AM_HAL_I2C_BIT_BANG_DATA_NAKED; } else { return AM_HAL_I2C_BIT_BANG_SUCCESS; } } //***************************************************************************** // //! @brief Receive a string of data bytes from an I2C device //! //! @param address (only 8 bit I2C addresses are supported) //! LSB is I2C R/W //! @param number_of_bytes to transfer (# payload bytes) //! @param pData pointer to data buffer to receive payload //! //! This function handles receiving a payload from a slave device //! //! returns ENUM{AM_HAL_I2C_BIT_BANG_SUCCESS,AM_HAL_I2C_BIT_BANG_ADDRESS_NAKED} // //***************************************************************************** am_hal_i2c_bit_bang_enum_e am_hal_i2c_bit_bang_receive(uint8_t address, uint32_t number_of_bytes, uint8_t *pData, uint8_t ui8Offset, bool bUseOffset, bool bNoStop) { uint32_t ui32I; am_hal_i2c_bit_bang_enum_e status = AM_HAL_I2C_BIT_BANG_SUCCESS; if (i2c_pull_and_wait_scl_hi()) { return AM_HAL_I2C_BIT_BANG_CLOCK_TIMEOUT; } // // Pull down on data line with clock high --> START CONDITION // WRITE_SDA_LO(); // // Delay for 1/2 bit cell time to start the clock // WAIT_I2C_CLOCK_HI_PERIOD(); // // send the address byte and wait for the ACK/NAK // status = i2c_send_byte(address); if ( status != AM_HAL_I2C_BIT_BANG_SUCCESS ) { if ( status == AM_HAL_I2C_BIT_BANG_DATA_NAKED) { return AM_HAL_I2C_BIT_BANG_ADDRESS_NAKED; } return status; } if ( bUseOffset ) { status = i2c_send_byte(ui8Offset); if ( status != AM_HAL_I2C_BIT_BANG_SUCCESS ) { return status; } } // // receive the requested number of data bytes // for (ui32I = 0; ui32I < number_of_bytes - 1; ui32I++) { // // receive the data bytes and send ACK for each one // status = i2c_receive_byte(pData, false); if (status != AM_HAL_I2C_BIT_BANG_SUCCESS) { return status; } pData++; } // Send NAK for the last byte status = i2c_receive_byte(pData, true); if (status != AM_HAL_I2C_BIT_BANG_SUCCESS) { return status; } //******************** // Send stop condition //******************** // // Pull down on clock line // WRITE_SCL_LO(); // // Delay for 1/4 bit cell time // WAIT_FOR_QUARTER_I2C_CLOCK(); if (!bNoStop) { // // Pull down on data line with clock low // WRITE_SDA_LO(); } else { // // Release data line with clock low itself, as we are not sending STOP // PULL_SDA_HI(); } // // // Delay for 1/4 bit cell time // WAIT_FOR_QUARTER_I2C_CLOCK(); if (i2c_pull_and_wait_scl_hi()) { return AM_HAL_I2C_BIT_BANG_CLOCK_TIMEOUT; } // // Delay for 1/2 bit cell time while clock is high // WAIT_I2C_CLOCK_HI_PERIOD(); if (!bNoStop) { // // release data line with clock high --> STOP CONDITION // PULL_SDA_HI(); } // // message successfully received (how could we fail???) // return AM_HAL_I2C_BIT_BANG_SUCCESS; } //***************************************************************************** // //! @brief Send a string of data bytes to an I2C device //! //! @param address (only 8 bit I2C addresses are supported) //! LSB is I2C R/W //! @param number_of_bytes to transfer (# payload bytes) //! @param pData pointer to data buffer containing payload //! //! This function handles sending a payload to a slave device //! //! returns ENUM {AM_HAL_I2C_BIT_BANG_SUCCESS, AM_HAL_I2C_BIT_BANG_DATA_NAKED, //! AM_HAL_I2C_BIT_BANG_ADDRESS_NAKED} // //***************************************************************************** am_hal_i2c_bit_bang_enum_e am_hal_i2c_bit_bang_send(uint8_t address, uint32_t number_of_bytes, uint8_t *pData, uint8_t ui8Offset, bool bUseOffset, bool bNoStop) { uint32_t ui32I; am_hal_i2c_bit_bang_enum_e status; bool data_naked = false; if (i2c_pull_and_wait_scl_hi()) { return AM_HAL_I2C_BIT_BANG_CLOCK_TIMEOUT; } // // Pull down on data line with clock high --> START CONDITION // WRITE_SDA_LO(); // // Delay for 1/2 bit cell time to start the clock // WAIT_I2C_CLOCK_HI_PERIOD(); // // send the address byte and wait for the ACK/NAK // status = i2c_send_byte(address); if ( status != AM_HAL_I2C_BIT_BANG_SUCCESS ) { if ( status == AM_HAL_I2C_BIT_BANG_DATA_NAKED) { return AM_HAL_I2C_BIT_BANG_ADDRESS_NAKED; } return status; } if ( bUseOffset ) { status = i2c_send_byte(ui8Offset); if ( status != AM_HAL_I2C_BIT_BANG_SUCCESS ) { return status; } } // // send the requested number of data bytes // for (ui32I = 0; ui32I < number_of_bytes; ui32I++) { // // send out the data bytes while watching for premature NAK // status = i2c_send_byte(*pData++); if (status != AM_HAL_I2C_BIT_BANG_SUCCESS) { if (status == AM_HAL_I2C_BIT_BANG_DATA_NAKED) { if (ui32I != (number_of_bytes-1)) { data_naked = true; // TODO - should we be sending the STOP bit in this case regardless of bNoStop? break; } else { status = AM_HAL_I2C_BIT_BANG_SUCCESS; } } else { return status; } } } //******************** // Send stop condition //******************** // // Pull down on clock line // WRITE_SCL_LO(); // // Delay for 1/4 bit cell time // WAIT_FOR_QUARTER_I2C_CLOCK(); if (!bNoStop) { // // Pull down on data line with clock low // WRITE_SDA_LO(); } else { // // Release data line with clock low itself, as we are not sending STOP // PULL_SDA_HI(); } // // Delay for 1/4 bit cell time // WAIT_FOR_QUARTER_I2C_CLOCK(); if (i2c_pull_and_wait_scl_hi()) { return AM_HAL_I2C_BIT_BANG_CLOCK_TIMEOUT; } if (!bNoStop) { // // release data line with clock high --> STOP CONDITION // PULL_SDA_HI(); } // // Delay for 1/2 bit cell time while clock is high // WAIT_I2C_CLOCK_HI_PERIOD(); if ( data_naked ) { return AM_HAL_I2C_BIT_BANG_DATA_NAKED; // if it happens early } // // message successfully sent // return AM_HAL_I2C_BIT_BANG_SUCCESS; }