/************************************************************************************ * arch/arm/src/stm32/stm32_i2c.c * STM32 I2C Hardware Layer - Device Driver * * Copyright (C) 2011 Uros Platise. All rights reserved. * Author: Uros Platise * * With extensions, modifications by: * * Copyright (C) 2011-2013 Gregory Nutt. All rights reserved. * Author: Gregroy Nutt * * 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 NuttX 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 OWNER 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. * ************************************************************************************/ /* Supports: * - Master operation, 100 kHz (standard) and 400 kHz (full speed) * - Multiple instances (shared bus) * - Interrupt based operation * * Structure naming: * - Device: structure as defined by the nuttx/i2c/i2c.h * - Instance: represents each individual access to the I2C driver, obtained by * the i2c_init(); it extends the Device structure from the nuttx/i2c/i2c.h; * Instance points to OPS, to common I2C Hardware private data and contains * its own private data, as frequency, address, mode of operation (in the future) * - Private: Private data of an I2C Hardware * * TODO * - Check for all possible deadlocks (as BUSY='1' I2C needs to be reset in HW using the I2C_CR1_SWRST) * - SMBus support (hardware layer timings are already supported) and add SMBA gpio pin * - Slave support with multiple addresses (on multiple instances): * - 2 x 7-bit address or * - 1 x 10 bit adresses + 1 x 7 bit address (?) * - plus the broadcast address (general call) * - Multi-master support * - DMA (to get rid of too many CPU wake-ups and interventions) * - Be ready for IPMI */ /************************************************************************************ * Included Files ************************************************************************************/ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "up_arch.h" #include "stm32_rcc.h" #include "stm32_i2c.h" #include "stm32_waste.h" // useful when debugging // #pragma GCC optimize("O0") /* At least one I2C peripheral must be enabled */ #if defined(CONFIG_STM32_I2C1) || defined(CONFIG_STM32_I2C2) || defined(CONFIG_STM32_I2C3) /* This implementation is for the STM32 F1, F2, and F4 only */ #if defined(CONFIG_STM32_STM32F10XX) || defined(CONFIG_STM32_STM32F20XX) || \ defined(CONFIG_STM32_STM32F40XX) /************************************************************************************ * Pre-processor Definitions ************************************************************************************/ /* Configuration ********************************************************************/ /* CONFIG_I2C_POLLED may be set so that I2C interrrupts will not be used. Instead, * CPU-intensive polling will be used. */ /* Interrupt wait timeout in seconds and milliseconds */ #if !defined(CONFIG_STM32_I2CTIMEOSEC) && !defined(CONFIG_STM32_I2CTIMEOMS) # define CONFIG_STM32_I2CTIMEOSEC 0 # define CONFIG_STM32_I2CTIMEOMS 500 /* Default is 500 milliseconds */ #elif !defined(CONFIG_STM32_I2CTIMEOSEC) # define CONFIG_STM32_I2CTIMEOSEC 0 /* User provided milliseconds */ #elif !defined(CONFIG_STM32_I2CTIMEOMS) # define CONFIG_STM32_I2CTIMEOMS 0 /* User provided seconds */ #endif /* Interrupt wait time timeout in system timer ticks */ #define CONFIG_STM32_I2CTIMEOTICKS \ (SEC2TICK(CONFIG_STM32_I2CTIMEOSEC) + MSEC2TICK(CONFIG_STM32_I2CTIMEOMS)) /* On the STM32F103ZE, there is an internal conflict between I2C1 and FSMC. In that * case, it is necessary to disable FSMC before each I2C1 access and re-enable FSMC * when the I2C access completes. */ #undef I2C1_FSMC_CONFLICT #if defined(CONFIG_STM32_STM32F10XX) && defined(CONFIG_STM32_FSMC) && defined(CONFIG_STM32_I2C1) # define I2C1_FSMC_CONFLICT #endif /* Debug ****************************************************************************/ /* CONFIG_DEBUG_I2C + CONFIG_DEBUG enables general I2C debug output. */ #ifdef CONFIG_DEBUG_I2C # define i2cdbg dbg # define i2cvdbg vdbg #else # define i2cdbg(x...) # define i2cvdbg(x...) #endif /* I2C event trace logic. NOTE: trace uses the internal, non-standard, low-level * debug interface syslog() but does not require that any other debug * is enabled. */ #ifndef CONFIG_I2C_TRACE # define stm32_i2c_tracereset(p) # define stm32_i2c_tracenew(p,s) # define stm32_i2c_traceevent(p,e,a) # define stm32_i2c_tracedump(p) #endif #ifndef CONFIG_I2C_NTRACE # define CONFIG_I2C_NTRACE 32 #endif /************************************************************************************ * Private Types ************************************************************************************/ /* Interrupt state */ enum stm32_intstate_e { INTSTATE_IDLE = 0, /* No I2C activity */ INTSTATE_WAITING, /* Waiting for completion of interrupt activity */ INTSTATE_DONE, /* Interrupt activity complete */ }; /* Trace events */ enum stm32_trace_e { I2CEVENT_NONE = 0, /* No events have occurred with this status */ I2CEVENT_SENDADDR, /* Start/Master bit set and address sent, param = msgc */ I2CEVENT_SENDBYTE, /* Send byte, param = dcnt */ I2CEVENT_ITBUFEN, /* Enable buffer interrupts, param = 0 */ I2CEVENT_RCVBYTE, /* Read more dta, param = dcnt */ I2CEVENT_REITBUFEN, /* Re-enable buffer interrupts, param = 0 */ I2CEVENT_DISITBUFEN, /* Disable buffer interrupts, param = 0 */ I2CEVENT_BTFNOSTART, /* BTF on last byte with no restart, param = msgc */ I2CEVENT_BTFRESTART, /* Last byte sent, re-starting, param = msgc */ I2CEVENT_BTFSTOP, /* Last byte sten, send stop, param = 0 */ I2CEVENT_ERROR /* Error occurred, param = 0 */ }; #ifdef CONFIG_I2C_TRACE static const char *stm32_trace_names[] = { "NONE ", "SENDADDR ", "SENDBYTE ", "ITBUFEN ", "RCVBYTE ", "REITBUFEN ", "DISITBUFEN", "BTFNOSTART", "BTFRESTART", "BTFSTOP ", "ERROR " }; #endif /* Trace data */ struct stm32_trace_s { uint32_t status; /* I2C 32-bit SR2|SR1 status */ uint32_t count; /* Interrupt count when status change */ enum stm32_intstate_e event; /* Last event that occurred with this status */ uint32_t parm; /* Parameter associated with the event */ uint32_t time; /* First of event or first status */ }; /* I2C Device hardware configuration */ struct stm32_i2c_config_s { uint32_t base; /* I2C base address */ #ifndef CONFIG_I2C_POLLED int ( *isr)(int, void *); /* Interrupt handler */ #endif uint32_t clk_bit; /* Clock enable bit */ uint32_t reset_bit; /* Reset bit */ uint32_t scl_pin; /* GPIO configuration for SCL as SCL */ uint32_t scl_gpio; /* GPIO configuration for SCL as a GPIO */ uint32_t sda_pin; /* GPIO configuration for SDA as SDA */ uint32_t sda_gpio; /* GPIO configuration for SDA as a GPIO */ uint32_t ev_irq; /* Event IRQ */ uint32_t er_irq; /* Error IRQ */ }; /* I2C Device Private Data */ struct stm32_i2c_priv_s { const struct stm32_i2c_config_s *config; /* Port configuration */ int refs; /* Referernce count */ sem_t sem_excl; /* Mutual exclusion semaphore */ #ifndef CONFIG_I2C_POLLED sem_t sem_isr; /* Interrupt wait semaphore */ #endif volatile uint8_t intstate; /* Interrupt handshake (see enum stm32_intstate_e) */ uint8_t msgc; /* Message count */ struct i2c_msg_s *msgv; /* Message list */ uint8_t *ptr; /* Current message buffer */ int dcnt; /* Current message length */ uint16_t flags; /* Current message flags */ /* I2C trace support */ #ifdef CONFIG_I2C_TRACE int tndx; /* Trace array index */ uint32_t start_time; /* Time when the trace was started */ /* The actual trace data */ struct stm32_trace_s trace[CONFIG_I2C_NTRACE]; #endif uint32_t status; /* End of transfer SR2|SR1 status */ }; /* I2C Device, Instance */ struct stm32_i2c_inst_s { struct i2c_ops_s *ops; /* Standard I2C operations */ struct stm32_i2c_priv_s *priv; /* Common driver private data structure */ uint32_t frequency; /* Frequency used in this instantiation */ int address; /* Address used in this instantiation */ uint16_t flags; /* Flags used in this instantiation */ }; /************************************************************************************ * Private Function Prototypes ************************************************************************************/ static inline uint16_t stm32_i2c_getreg(FAR struct stm32_i2c_priv_s *priv, uint8_t offset); static inline void stm32_i2c_putreg(FAR struct stm32_i2c_priv_s *priv, uint8_t offset, uint16_t value); static inline void stm32_i2c_modifyreg(FAR struct stm32_i2c_priv_s *priv, uint8_t offset, uint16_t clearbits, uint16_t setbits); static inline void stm32_i2c_sem_wait(FAR struct i2c_dev_s *dev); static inline int stm32_i2c_sem_waitdone(FAR struct stm32_i2c_priv_s *priv, int timeout_us); static inline void stm32_i2c_sem_waitstop(FAR struct stm32_i2c_priv_s *priv, int timeout_us); static inline void stm32_i2c_sem_post(FAR struct i2c_dev_s *dev); static inline void stm32_i2c_sem_init(FAR struct i2c_dev_s *dev); static inline void stm32_i2c_sem_destroy(FAR struct i2c_dev_s *dev); #ifdef CONFIG_I2C_TRACE static void stm32_i2c_tracereset(FAR struct stm32_i2c_priv_s *priv); static void stm32_i2c_tracenew(FAR struct stm32_i2c_priv_s *priv, uint32_t status); static void stm32_i2c_traceevent(FAR struct stm32_i2c_priv_s *priv, enum stm32_trace_e event, uint32_t parm); static void stm32_i2c_tracedump(FAR struct stm32_i2c_priv_s *priv); #endif /* CONFIG_I2C_TRACE */ static void stm32_i2c_setclock(FAR struct stm32_i2c_priv_s *priv, uint32_t frequency); static inline void stm32_i2c_sendstart(FAR struct stm32_i2c_priv_s *priv); static inline void stm32_i2c_clrstart(FAR struct stm32_i2c_priv_s *priv); static inline void stm32_i2c_sendstop(FAR struct stm32_i2c_priv_s *priv); static inline uint32_t stm32_i2c_getstatus(FAR struct stm32_i2c_priv_s *priv); #ifdef I2C1_FSMC_CONFLICT static inline uint32_t stm32_i2c_disablefsmc(FAR struct stm32_i2c_priv_s *priv); static inline void stm32_i2c_enablefsmc(uint32_t ahbenr); #endif /* I2C1_FSMC_CONFLICT */ static int stm32_i2c_isr(struct stm32_i2c_priv_s * priv); // useful when debugging // static int stm32_i2c_isr(struct stm32_i2c_priv_s *priv) __attribute__((optimize("O0"))); #ifndef CONFIG_I2C_POLLED #ifdef CONFIG_STM32_I2C1 static int stm32_i2c1_isr(int irq, void *context); #endif #ifdef CONFIG_STM32_I2C2 static int stm32_i2c2_isr(int irq, void *context); #endif #ifdef CONFIG_STM32_I2C3 static int stm32_i2c3_isr(int irq, void *context); #endif #endif static int stm32_i2c_init(FAR struct stm32_i2c_priv_s *priv); static int stm32_i2c_deinit(FAR struct stm32_i2c_priv_s *priv); static uint32_t stm32_i2c_setfrequency(FAR struct i2c_dev_s *dev, uint32_t frequency); static int stm32_i2c_setaddress(FAR struct i2c_dev_s *dev, int addr, int nbits); static int stm32_i2c_process(FAR struct i2c_dev_s *dev, FAR struct i2c_msg_s *msgs, int count); static int stm32_i2c_write(FAR struct i2c_dev_s *dev, const uint8_t *buffer, int buflen); static int stm32_i2c_read(FAR struct i2c_dev_s *dev, uint8_t *buffer, int buflen); #ifdef CONFIG_I2C_WRITEREAD static int stm32_i2c_writeread(FAR struct i2c_dev_s *dev, const uint8_t *wbuffer, int wbuflen, uint8_t *buffer, int buflen); #endif #ifdef CONFIG_I2C_TRANSFER static int stm32_i2c_transfer(FAR struct i2c_dev_s *dev, FAR struct i2c_msg_s *msgs, int count); #endif /************************************************************************************ * Private Data ************************************************************************************/ #ifdef CONFIG_STM32_I2C1 # ifndef GPIO_I2C1_SCL_GPIO # define GPIO_I2C1_SCL_GPIO 0 # endif # ifndef GPIO_I2C1_SDA_GPIO # define GPIO_I2C1_SDA_GPIO 0 # endif static const struct stm32_i2c_config_s stm32_i2c1_config = { .base = STM32_I2C1_BASE, #ifndef CONFIG_I2C_POLLED .isr = stm32_i2c1_isr, #endif .clk_bit = RCC_APB1ENR_I2C1EN, .reset_bit = RCC_APB1RSTR_I2C1RST, .scl_pin = GPIO_I2C1_SCL, .scl_gpio = GPIO_I2C1_SCL_GPIO, .sda_pin = GPIO_I2C1_SDA, .sda_gpio = GPIO_I2C1_SDA_GPIO, .ev_irq = STM32_IRQ_I2C1EV, .er_irq = STM32_IRQ_I2C1ER }; struct stm32_i2c_priv_s stm32_i2c1_priv = { .config = &stm32_i2c1_config, .refs = 0, .intstate = INTSTATE_IDLE, .msgc = 0, .msgv = NULL, .ptr = NULL, .dcnt = 0, .flags = 0, .status = 0 }; #endif #ifdef CONFIG_STM32_I2C2 # ifndef GPIO_I2C2_SCL_GPIO # define GPIO_I2C2_SCL_GPIO 0 # endif # ifndef GPIO_I2C2_SDA_GPIO # define GPIO_I2C2_SDA_GPIO 0 # endif static const struct stm32_i2c_config_s stm32_i2c2_config = { .base = STM32_I2C2_BASE, #ifndef CONFIG_I2C_POLLED .isr = stm32_i2c2_isr, #endif .clk_bit = RCC_APB1ENR_I2C2EN, .reset_bit = RCC_APB1RSTR_I2C2RST, .scl_pin = GPIO_I2C2_SCL, .scl_gpio = GPIO_I2C2_SCL_GPIO, .sda_pin = GPIO_I2C2_SDA, .sda_gpio = GPIO_I2C2_SDA_GPIO, .ev_irq = STM32_IRQ_I2C2EV, .er_irq = STM32_IRQ_I2C2ER }; struct stm32_i2c_priv_s stm32_i2c2_priv = { .config = &stm32_i2c2_config, .refs = 0, .intstate = INTSTATE_IDLE, .msgc = 0, .msgv = NULL, .ptr = NULL, .dcnt = 0, .flags = 0, .status = 0 }; #endif #ifdef CONFIG_STM32_I2C3 # ifndef GPIO_I2C3_SCL_GPIO # define GPIO_I2C3_SCL_GPIO 0 # endif # ifndef GPIO_I2C3_SDA_GPIO # define GPIO_I2C3_SDA_GPIO 0 # endif static const struct stm32_i2c_config_s stm32_i2c3_config = { .base = STM32_I2C3_BASE, #ifndef CONFIG_I2C_POLLED .isr = stm32_i2c3_isr, #endif .clk_bit = RCC_APB1ENR_I2C3EN, .reset_bit = RCC_APB1RSTR_I2C3RST, .scl_pin = GPIO_I2C3_SCL, .scl_gpio = GPIO_I2C3_SCL_GPIO, .sda_pin = GPIO_I2C3_SDA, .sda_gpio = GPIO_I2C3_SDA_GPIO, .ev_irq = STM32_IRQ_I2C3EV, .er_irq = STM32_IRQ_I2C3ER }; struct stm32_i2c_priv_s stm32_i2c3_priv = { .config = &stm32_i2c3_config, .refs = 0, .intstate = INTSTATE_IDLE, .msgc = 0, .msgv = NULL, .ptr = NULL, .dcnt = 0, .flags = 0, .status = 0 }; #endif /* Device Structures, Instantiation */ struct i2c_ops_s stm32_i2c_ops = { .setfrequency = stm32_i2c_setfrequency, .setaddress = stm32_i2c_setaddress, .write = stm32_i2c_write, .read = stm32_i2c_read #ifdef CONFIG_I2C_WRITEREAD , .writeread = stm32_i2c_writeread #endif #ifdef CONFIG_I2C_TRANSFER , .transfer = stm32_i2c_transfer #endif #ifdef CONFIG_I2C_SLAVE , .setownaddress = stm32_i2c_setownaddress, .registercallback = stm32_i2c_registercallback #endif }; /************************************************************************************ * Private Functions ************************************************************************************/ /************************************************************************************ * Name: stm32_i2c_getreg * * Description: * Get register value by offset * ************************************************************************************/ static inline uint16_t stm32_i2c_getreg(FAR struct stm32_i2c_priv_s *priv, uint8_t offset) { return getreg16(priv->config->base + offset); } /************************************************************************************ * Name: stm32_i2c_putreg * * Description: * Put register value by offset * ************************************************************************************/ static inline void stm32_i2c_putreg(FAR struct stm32_i2c_priv_s *priv, uint8_t offset, uint16_t value) { putreg16(value, priv->config->base + offset); } /************************************************************************************ * Name: stm32_i2c_modifyreg * * Description: * Modify register value by offset * ************************************************************************************/ static inline void stm32_i2c_modifyreg(FAR struct stm32_i2c_priv_s *priv, uint8_t offset, uint16_t clearbits, uint16_t setbits) { modifyreg16(priv->config->base + offset, clearbits, setbits); } /************************************************************************************ * Name: * * Description: * * ************************************************************************************/ static inline void stm32_i2c_sem_wait(FAR struct i2c_dev_s *dev) { while (sem_wait(&((struct stm32_i2c_inst_s *)dev)->priv->sem_excl) != 0) { ASSERT(errno == EINTR); } } /************************************************************************************ * Name: stm32_i2c_sem_waitdone * * Description: * Wait for a transfer to complete * ************************************************************************************/ #ifndef CONFIG_I2C_POLLED static inline int stm32_i2c_sem_waitdone(FAR struct stm32_i2c_priv_s *priv, int timeout_us) { struct timespec abstime; irqstate_t flags; uint32_t regval; int ret; flags = irqsave(); /* Enable I2C interrupts */ regval = stm32_i2c_getreg(priv, STM32_I2C_CR2_OFFSET); regval |= (I2C_CR2_ITERREN | I2C_CR2_ITEVFEN); stm32_i2c_putreg(priv, STM32_I2C_CR2_OFFSET, regval); /* Signal the interrupt handler that we are waiting. NOTE: Interrupts * are currently disabled but will be temporarily re-enabled below when * sem_timedwait() sleeps. */ priv->intstate = INTSTATE_WAITING; do { /* Get the current time */ (void)clock_gettime(CLOCK_REALTIME, &abstime); /* Calculate a time in the future */ #if CONFIG_STM32_I2CTIMEOSEC > 0 abstime.tv_sec += CONFIG_STM32_I2CTIMEOSEC; #endif #if CONFIG_STM32_I2CTIMEOUS_PER_BYTE > 0 /* Count the number of bytes left to process */ int i; int bytecount = 0; for (i = 0; i < priv->msgc; i++) { bytecount += priv->msgv[i].length; } abstime.tv_nsec += (CONFIG_STM32_I2CTIMEOUS_PER_BYTE * bytecount) * 1000; if (abstime.tv_nsec > 1000 * 1000 * 1000) { abstime.tv_sec++; abstime.tv_nsec -= 1000 * 1000 * 1000; } #elif CONFIG_STM32_I2CTIMEOMS > 0 abstime.tv_nsec += CONFIG_STM32_I2CTIMEOMS * 1000 * 1000; if (abstime.tv_nsec > 1000 * 1000 * 1000) { abstime.tv_sec++; abstime.tv_nsec -= 1000 * 1000 * 1000; } #endif /* Wait until either the transfer is complete or the timeout expires */ ret = sem_timedwait(&priv->sem_isr, &abstime); if (ret != OK && errno != EINTR) { /* Break out of the loop on irrecoverable errors. This would * include timeouts and mystery errors reported by sem_timedwait. * NOTE that we try again if we are awakened by a signal (EINTR). */ break; } } /* Loop until the interrupt level transfer is complete. */ while (priv->intstate != INTSTATE_DONE); /* Set the interrupt state back to IDLE */ priv->intstate = INTSTATE_IDLE; /* Disable I2C interrupts */ regval = stm32_i2c_getreg(priv, STM32_I2C_CR2_OFFSET); regval &= ~I2C_CR2_ALLINTS; stm32_i2c_putreg(priv, STM32_I2C_CR2_OFFSET, regval); irqrestore(flags); return ret; } #else static inline int stm32_i2c_sem_waitdone(FAR struct stm32_i2c_priv_s *priv, int timeout_us) { uint32_t start; uint32_t elapsed; int ret; /* Signal the interrupt handler that we are waiting. NOTE: Interrupts * are currently disabled but will be temporarily re-enabled below when * sem_timedwait() sleeps. */ priv->intstate = INTSTATE_WAITING; start = clock_systimer(); do { /* Poll by simply calling the timer interrupt handler until it * reports that it is done. */ stm32_i2c_isr(priv); /* Calculate the elapsed time */ elapsed = clock_systimer() - start; } /* Loop until the transfer is complete. */ while (priv->intstate != INTSTATE_DONE && elapsed < USEC2TICK(timeout_us)); i2cvdbg("intstate: %d elapsed: %d threshold: %d status: %08x\n", priv->intstate, elapsed, USEC2TICK(timeout_us), priv->status); /* Set the interrupt state back to IDLE */ ret = priv->intstate == INTSTATE_DONE ? OK : -ETIMEDOUT; priv->intstate = INTSTATE_IDLE; return ret; } #endif /************************************************************************************ * Name: stm32_i2c_sem_waitstop * * Description: * Wait for a STOP to complete * ************************************************************************************/ static inline void stm32_i2c_sem_waitstop(FAR struct stm32_i2c_priv_s *priv, int timeout_us) { uint32_t start; uint32_t elapsed; uint32_t cr1; uint32_t sr1; /* Wait as stop might still be in progress; but stop might also * be set because of a timeout error: "The [STOP] bit is set and * cleared by software, cleared by hardware when a Stop condition is * detected, set by hardware when a timeout error is detected." */ start = clock_systimer(); do { /* Check for STOP condition */ cr1 = stm32_i2c_getreg(priv, STM32_I2C_CR1_OFFSET); if ((cr1 & I2C_CR1_STOP) == 0) { return; } /* Check for timeout error */ sr1 = stm32_i2c_getreg(priv, STM32_I2C_SR1_OFFSET); if ((sr1 & I2C_SR1_TIMEOUT) != 0) { return; } /* Calculate the elapsed time */ elapsed = clock_systimer() - start; } /* Loop until the stop is complete or a timeout occurs. */ while (elapsed < USEC2TICK(timeout_us)); /* If we get here then a timeout occurred with the STOP condition * still pending. */ i2cvdbg("Timeout with CR1: %04x SR1: %04x\n", cr1, sr1); } /************************************************************************************ * Name: stm32_i2c_sem_post * * Description: * Release the mutual exclusion semaphore * ************************************************************************************/ static inline void stm32_i2c_sem_post(FAR struct i2c_dev_s *dev) { sem_post( &((struct stm32_i2c_inst_s *)dev)->priv->sem_excl ); } /************************************************************************************ * Name: stm32_i2c_sem_init * * Description: * Initialize semaphores * ************************************************************************************/ static inline void stm32_i2c_sem_init(FAR struct i2c_dev_s *dev) { sem_init(&((struct stm32_i2c_inst_s *)dev)->priv->sem_excl, 0, 1); #ifndef CONFIG_I2C_POLLED sem_init(&((struct stm32_i2c_inst_s *)dev)->priv->sem_isr, 0, 0); #endif } /************************************************************************************ * Name: stm32_i2c_sem_destroy * * Description: * Destroy semaphores. * ************************************************************************************/ static inline void stm32_i2c_sem_destroy(FAR struct i2c_dev_s *dev) { sem_destroy(&((struct stm32_i2c_inst_s *)dev)->priv->sem_excl); #ifndef CONFIG_I2C_POLLED sem_destroy(&((struct stm32_i2c_inst_s *)dev)->priv->sem_isr); #endif } /************************************************************************************ * Name: stm32_i2c_trace* * * Description: * I2C trace instrumentation * ************************************************************************************/ #ifdef CONFIG_I2C_TRACE static void stm32_i2c_traceclear(FAR struct stm32_i2c_priv_s *priv) { struct stm32_trace_s *trace = &priv->trace[priv->tndx]; trace->status = 0; /* I2C 32-bit SR2|SR1 status */ trace->count = 0; /* Interrupt count when status change */ trace->event = I2CEVENT_NONE; /* Last event that occurred with this status */ trace->parm = 0; /* Parameter associated with the event */ trace->time = 0; /* Time of first status or event */ } static void stm32_i2c_tracereset(FAR struct stm32_i2c_priv_s *priv) { /* Reset the trace info for a new data collection */ priv->tndx = 0; priv->start_time = clock_systimer(); stm32_i2c_traceclear(priv); } static void stm32_i2c_tracenew(FAR struct stm32_i2c_priv_s *priv, uint32_t status) { struct stm32_trace_s *trace = &priv->trace[priv->tndx]; /* Is the current entry uninitialized? Has the status changed? */ if (trace->count == 0 || status != trace->status) { /* Yes.. Was it the status changed? */ if (trace->count != 0) { /* Yes.. bump up the trace index (unless we are out of trace entries) */ if (priv->tndx >= (CONFIG_I2C_NTRACE-1)) { i2cdbg("Trace table overflow\n"); return; } priv->tndx++; trace = &priv->trace[priv->tndx]; } /* Initialize the new trace entry */ stm32_i2c_traceclear(priv); trace->status = status; trace->count = 1; trace->time = clock_systimer(); } else { /* Just increment the count of times that we have seen this status */ trace->count++; } } static void stm32_i2c_traceevent(FAR struct stm32_i2c_priv_s *priv, enum stm32_trace_e event, uint32_t parm) { struct stm32_trace_s *trace; if (event != I2CEVENT_NONE) { trace = &priv->trace[priv->tndx]; /* Initialize the new trace entry */ trace->event = event; trace->parm = parm; trace->time = clock_systimer(); /* Bump up the trace index (unless we are out of trace entries) */ if (priv->tndx >= (CONFIG_I2C_NTRACE-1)) { i2cdbg("Trace table overflow\n"); return; } priv->tndx++; stm32_i2c_traceclear(priv); } } static void stm32_i2c_tracedump(FAR struct stm32_i2c_priv_s *priv) { struct stm32_trace_s *trace; int i; syslog("Elapsed time: %d\n", clock_systimer() - priv->start_time); for (i = 0; i <= priv->tndx; i++) { trace = &priv->trace[i]; syslog("%2d. STATUS: %08x COUNT: %3d EVENT: %s PARM: %08x TIME: %d\n", i+1, trace->status, trace->count, stm32_trace_names[trace->event], trace->parm, trace->time - priv->start_time); } } #endif /* CONFIG_I2C_TRACE */ /************************************************************************************ * Name: stm32_i2c_setclock * * Description: * Set the I2C clock * ************************************************************************************/ static void stm32_i2c_setclock(FAR struct stm32_i2c_priv_s *priv, uint32_t frequency) { uint16_t cr1; uint16_t ccr; uint16_t trise; uint16_t freqmhz; uint16_t speed; /* Disable the selected I2C peripheral to configure TRISE */ cr1 = stm32_i2c_getreg(priv, STM32_I2C_CR1_OFFSET); stm32_i2c_putreg(priv, STM32_I2C_CR1_OFFSET, cr1 & ~I2C_CR1_PE); /* Update timing and control registers */ freqmhz = (uint16_t)(STM32_PCLK1_FREQUENCY / 1000000); ccr = 0; /* Configure speed in standard mode */ if (frequency <= 100000) { /* Standard mode speed calculation */ speed = (uint16_t)(STM32_PCLK1_FREQUENCY / (frequency << 1)); /* The CCR fault must be >= 4 */ if (speed < 4) { /* Set the minimum allowed value */ speed = 4; } ccr |= speed; /* Set Maximum Rise Time for standard mode */ trise = freqmhz + 1; } /* Configure speed in fast mode */ else /* (frequency <= 400000) */ { /* Fast mode speed calculation with Tlow/Thigh = 16/9 */ #ifdef CONFIG_STM32_I2C_DUTY16_9 speed = (uint16_t)(STM32_PCLK1_FREQUENCY / (frequency * 25)); /* Set DUTY and fast speed bits */ ccr |= (I2C_CCR_DUTY|I2C_CCR_FS); #else /* Fast mode speed calculation with Tlow/Thigh = 2 */ speed = (uint16_t)(STM32_PCLK1_FREQUENCY / (frequency * 3)); /* Set fast speed bit */ ccr |= I2C_CCR_FS; #endif /* Verify that the CCR speed value is nonzero */ if (speed < 1) { /* Set the minimum allowed value */ speed = 1; } ccr |= speed; /* Set Maximum Rise Time for fast mode */ trise = (uint16_t)(((freqmhz * 300) / 1000) + 1); } /* Write the new values of the CCR and TRISE registers */ stm32_i2c_putreg(priv, STM32_I2C_CCR_OFFSET, ccr); stm32_i2c_putreg(priv, STM32_I2C_TRISE_OFFSET, trise); /* Bit 14 of OAR1 must be configured and kept at 1 */ stm32_i2c_putreg(priv, STM32_I2C_OAR1_OFFSET, I2C_OAR1_ONE); /* Re-enable the peripheral (or not) */ stm32_i2c_putreg(priv, STM32_I2C_CR1_OFFSET, cr1); } /************************************************************************************ * Name: stm32_i2c_sendstart * * Description: * Send the START conditions/force Master mode * ************************************************************************************/ static inline void stm32_i2c_sendstart(FAR struct stm32_i2c_priv_s *priv) { /* Disable ACK on receive by default and generate START */ stm32_i2c_modifyreg(priv, STM32_I2C_CR1_OFFSET, I2C_CR1_ACK, I2C_CR1_START); } /************************************************************************************ * Name: stm32_i2c_clrstart * * Description: * Clear the STOP, START or PEC condition on certain error recovery steps. * ************************************************************************************/ static inline void stm32_i2c_clrstart(FAR struct stm32_i2c_priv_s *priv) { /* "Note: When the STOP, START or PEC bit is set, the software must * not perform any write access to I2C_CR1 before this bit is * cleared by hardware. Otherwise there is a risk of setting a * second STOP, START or PEC request." * * "The [STOP] bit is set and cleared by software, cleared by hardware * when a Stop condition is detected, set by hardware when a timeout * error is detected. * * "This [START] bit is set and cleared by software and cleared by hardware * when start is sent or PE=0." The bit must be cleared by software if the * START is never sent. * * "This [PEC] bit is set and cleared by software, and cleared by hardware * when PEC is transferred or by a START or Stop condition or when PE=0." */ stm32_i2c_modifyreg(priv, STM32_I2C_CR1_OFFSET, I2C_CR1_START|I2C_CR1_STOP|I2C_CR1_PEC, 0); } /************************************************************************************ * Name: stm32_i2c_sendstop * * Description: * Send the STOP conditions * ************************************************************************************/ static inline void stm32_i2c_sendstop(FAR struct stm32_i2c_priv_s *priv) { stm32_i2c_modifyreg(priv, STM32_I2C_CR1_OFFSET, I2C_CR1_ACK, I2C_CR1_STOP); } /************************************************************************************ * Name: stm32_i2c_getstatus * * Description: * Get 32-bit status (SR1 and SR2 combined) * ************************************************************************************/ static inline uint32_t stm32_i2c_getstatus(FAR struct stm32_i2c_priv_s *priv) { uint32_t status = stm32_i2c_getreg(priv, STM32_I2C_SR1_OFFSET); status |= (stm32_i2c_getreg(priv, STM32_I2C_SR2_OFFSET) << 16); return status; } /************************************************************************************ * Name: stm32_i2c_disablefsmc * * Description: * FSMC must be disable while accessing I2C1 because it uses a common resource * (LBAR) * * NOTE: This is an issue with the STM32F103ZE, but may not be an issue with other * STM32s. You may need to experiment * ************************************************************************************/ #ifdef I2C1_FSMC_CONFLICT static inline uint32_t stm32_i2c_disablefsmc(FAR struct stm32_i2c_priv_s *priv) { uint32_t ret = 0; uint32_t regval; /* Is this I2C1 */ #if defined(CONFIG_STM32_I2C2) || defined(CONFIG_STM32_I2C3) if (priv->config->base == STM32_I2C1_BASE) #endif { /* Disable FSMC unconditionally */ ret = getreg32( STM32_RCC_AHBENR); regval = ret & ~RCC_AHBENR_FSMCEN; putreg32(regval, STM32_RCC_AHBENR); } return ret; } /************************************************************************************ * Name: stm32_i2c_enablefsmc * * Description: * Re-enabled the FSMC * ************************************************************************************/ static inline void stm32_i2c_enablefsmc(uint32_t ahbenr) { uint32_t regval; /* Enable AHB clocking to the FSMC only if it was previously enabled. */ if ((ahbenr & RCC_AHBENR_FSMCEN) != 0) { regval = getreg32( STM32_RCC_AHBENR); regval |= RCC_AHBENR_FSMCEN; putreg32(regval, STM32_RCC_AHBENR); } } #else # define stm32_i2c_disablefsmc(priv) (0) # define stm32_i2c_enablefsmc(ahbenr) #endif /* I2C1_FSMC_CONFLICT */ /************************************************************************************ * Name: stm32_i2c_isr * * Description: * Common Interrupt Service Routine * ************************************************************************************/ static int stm32_i2c_isr(struct stm32_i2c_priv_s *priv) { uint32_t status = stm32_i2c_getstatus(priv); /* Check for new trace setup */ stm32_i2c_tracenew(priv, status); /* Was start bit sent */ if ((status & I2C_SR1_SB) != 0) { stm32_i2c_traceevent(priv, I2CEVENT_SENDADDR, priv->msgc); /* we check for msgc > 0 here as an unexpected interrupt with I2C_SR1_SB set due to noise on the I2C cable can otherwise cause msgc to wrap causing memory overwrite */ if (priv->msgc > 0 && priv->msgv != NULL) { /* Get run-time data */ priv->ptr = priv->msgv->buffer; priv->dcnt = priv->msgv->length; priv->flags = priv->msgv->flags; /* Send address byte and define addressing mode */ stm32_i2c_putreg(priv, STM32_I2C_DR_OFFSET, (priv->flags & I2C_M_TEN) ? 0 : ((priv->msgv->addr << 1) | (priv->flags & I2C_M_READ))); /* Set ACK for receive mode */ if (priv->dcnt > 1 && (priv->flags & I2C_M_READ) != 0) { stm32_i2c_modifyreg(priv, STM32_I2C_CR1_OFFSET, 0, I2C_CR1_ACK); } /* Increment to next pointer and decrement message count */ priv->msgv++; priv->msgc--; } else { /* clear ISR by writing to DR register */ stm32_i2c_putreg(priv, STM32_I2C_DR_OFFSET, 0); } } /* In 10-bit addressing mode, was first byte sent */ else if ((status & I2C_SR1_ADD10) != 0) { /* TODO: Finish 10-bit mode addressing for now just clear ISR by writing to DR register. As we don't do 10 bit addressing this must be a spurious ISR */ stm32_i2c_putreg(priv, STM32_I2C_DR_OFFSET, 0); } /* Was address sent, continue with either sending or reading data */ else if ((priv->flags & I2C_M_READ) == 0 && (status & (I2C_SR1_ADDR | I2C_SR1_TXE)) != 0) { if (priv->dcnt > 0) { /* Send a byte */ stm32_i2c_traceevent(priv, I2CEVENT_SENDBYTE, priv->dcnt); stm32_i2c_putreg(priv, STM32_I2C_DR_OFFSET, *priv->ptr++); priv->dcnt--; } } else if ((priv->flags & I2C_M_READ) != 0 && (status & I2C_SR1_ADDR) != 0) { /* Enable RxNE and TxE buffers in order to receive one or multiple bytes */ #ifndef CONFIG_I2C_POLLED stm32_i2c_traceevent(priv, I2CEVENT_ITBUFEN, 0); stm32_i2c_modifyreg(priv, STM32_I2C_CR2_OFFSET, 0, I2C_CR2_ITBUFEN); #endif } /* More bytes to read */ else if ((status & I2C_SR1_RXNE) != 0) { /* Read a byte, if dcnt goes < 0, then read dummy bytes to ack ISRs */ if (priv->dcnt > 0) { stm32_i2c_traceevent(priv, I2CEVENT_RCVBYTE, priv->dcnt); /* No interrupts or context switches may occur in the following * sequence. Otherwise, additional bytes may be sent by the * device. */ #ifdef CONFIG_I2C_POLLED irqstate_t state = irqsave(); #endif /* Receive a byte */ *priv->ptr++ = stm32_i2c_getreg(priv, STM32_I2C_DR_OFFSET); /* Disable acknowledge when last byte is to be received */ priv->dcnt--; if (priv->dcnt == 1) { stm32_i2c_modifyreg(priv, STM32_I2C_CR1_OFFSET, I2C_CR1_ACK, 0); } #ifdef CONFIG_I2C_POLLED irqrestore(state); #endif } else { // throw away the unexpected byte stm32_i2c_getreg(priv, STM32_I2C_DR_OFFSET); } } else if (status & I2C_SR1_TXE) { /* this should never happen, but it does happen occasionally with lots of noise on the bus. It means the peripheral is expecting more data bytes, but we don't have any to give. This has been seen with status=0x70084, reproduced with noise generated by a Jabra wireless headset in close proximity to the I2C lines */ stm32_i2c_putreg(priv, STM32_I2C_DR_OFFSET, 0); } else if (status & I2C_SR1_BTF) { /* we should have handled all cases where this could happen above, but just to ensure it gets acked, lets clear it here */ stm32_i2c_getreg(priv, STM32_I2C_DR_OFFSET); } else if (status & I2C_SR1_STOPF) { /* we should never get this, as we are a master not a slave. Write CR1 with its current value to clear the error */ stm32_i2c_modifyreg(priv, STM32_I2C_CR1_OFFSET, 0, 0); } /* Do we have more bytes to send, enable/disable buffer interrupts * (these ISRs could be replaced by DMAs) */ #ifndef CONFIG_I2C_POLLED if (priv->dcnt > 0) { stm32_i2c_traceevent(priv, I2CEVENT_REITBUFEN, 0); stm32_i2c_modifyreg(priv, STM32_I2C_CR2_OFFSET, 0, I2C_CR2_ITBUFEN); } else if (priv->dcnt == 0) { stm32_i2c_traceevent(priv, I2CEVENT_DISITBUFEN, 0); stm32_i2c_modifyreg(priv, STM32_I2C_CR2_OFFSET, I2C_CR2_ITBUFEN, 0); } #endif /* Was last byte received or sent? Hmmm... the F2 and F4 seems to differ from * the F1 in that BTF is not set after data is received (only RXNE). */ #if defined(CONFIG_STM32_STM32F20XX) || defined(CONFIG_STM32_STM32F40XX) if (priv->dcnt <= 0 && (status & (I2C_SR1_BTF|I2C_SR1_RXNE)) != 0) #else if (priv->dcnt <= 0 && (status & I2C_SR1_BTF) != 0) #endif { stm32_i2c_getreg(priv, STM32_I2C_DR_OFFSET); /* ACK ISR */ /* Do we need to terminate or restart after this byte? * If there are more messages to send, then we may: * * - continue with repeated start * - or just continue sending writeable part * - or we close down by sending the stop bit */ if (priv->msgc > 0) { if (priv->msgv->flags & I2C_M_NORESTART) { stm32_i2c_traceevent(priv, I2CEVENT_BTFNOSTART, priv->msgc); priv->ptr = priv->msgv->buffer; priv->dcnt = priv->msgv->length; priv->flags = priv->msgv->flags; priv->msgv++; priv->msgc--; /* Restart this ISR! */ #ifndef CONFIG_I2C_POLLED stm32_i2c_modifyreg(priv, STM32_I2C_CR2_OFFSET, 0, I2C_CR2_ITBUFEN); #endif } else { stm32_i2c_traceevent(priv, I2CEVENT_BTFRESTART, priv->msgc); stm32_i2c_sendstart(priv); } } else if (priv->msgv) { stm32_i2c_traceevent(priv, I2CEVENT_BTFSTOP, 0); stm32_i2c_sendstop(priv); /* Is there a thread waiting for this event (there should be) */ #ifndef CONFIG_I2C_POLLED if (priv->intstate == INTSTATE_WAITING) { /* Yes.. inform the thread that the transfer is complete * and wake it up. */ sem_post( &priv->sem_isr ); priv->intstate = INTSTATE_DONE; } #else priv->intstate = INTSTATE_DONE; #endif /* Mark that we have stopped with this transaction */ priv->msgv = NULL; } } /* Check for errors, in which case, stop the transfer and return * Note that in master reception mode AF becomes set on last byte * since ACK is not returned. We should ignore this error. */ if ((status & I2C_SR1_ERRORMASK) != 0) { stm32_i2c_traceevent(priv, I2CEVENT_ERROR, 0); /* Clear interrupt flags */ stm32_i2c_putreg(priv, STM32_I2C_SR1_OFFSET, 0); /* Is there a thread waiting for this event (there should be) */ #ifndef CONFIG_I2C_POLLED if (priv->intstate == INTSTATE_WAITING) { /* Yes.. inform the thread that the transfer is complete * and wake it up. */ sem_post( &priv->sem_isr ); priv->intstate = INTSTATE_DONE; } #else priv->intstate = INTSTATE_DONE; #endif } priv->status = status; return OK; } /************************************************************************************ * Name: stm32_i2c1_isr * * Description: * I2C1 interrupt service routine * ************************************************************************************/ #ifndef CONFIG_I2C_POLLED #ifdef CONFIG_STM32_I2C1 static int stm32_i2c1_isr(int irq, void *context) { return stm32_i2c_isr(&stm32_i2c1_priv); } #endif /************************************************************************************ * Name: stm32_i2c2_isr * * Description: * I2C2 interrupt service routine * ************************************************************************************/ #ifdef CONFIG_STM32_I2C2 static int stm32_i2c2_isr(int irq, void *context) { return stm32_i2c_isr(&stm32_i2c2_priv); } #endif /************************************************************************************ * Name: stm32_i2c3_isr * * Description: * I2C2 interrupt service routine * ************************************************************************************/ #ifdef CONFIG_STM32_I2C3 static int stm32_i2c3_isr(int irq, void *context) { return stm32_i2c_isr(&stm32_i2c3_priv); } #endif #endif /************************************************************************************ * Private Initialization and Deinitialization ************************************************************************************/ /************************************************************************************ * Name: stm32_i2c_init * * Description: * Setup the I2C hardware, ready for operation with defaults * ************************************************************************************/ static int stm32_i2c_init(FAR struct stm32_i2c_priv_s *priv) { /* Power-up and configure GPIOs */ /* Enable power and reset the peripheral */ modifyreg32(STM32_RCC_APB1ENR, 0, priv->config->clk_bit); modifyreg32(STM32_RCC_APB1RSTR, 0, priv->config->reset_bit); modifyreg32(STM32_RCC_APB1RSTR, priv->config->reset_bit, 0); /* Configure pins */ if (stm32_configgpio(priv->config->scl_pin) < 0) { return ERROR; } if (stm32_configgpio(priv->config->sda_pin) < 0) { stm32_unconfiggpio(priv->config->scl_pin); return ERROR; } /* Attach ISRs */ #ifndef CONFIG_I2C_POLLED irq_attach(priv->config->ev_irq, priv->config->isr); irq_attach(priv->config->er_irq, priv->config->isr); up_enable_irq(priv->config->ev_irq); up_enable_irq(priv->config->er_irq); #endif /* Set peripheral frequency, where it must be at least 2 MHz for 100 kHz * or 4 MHz for 400 kHz. This also disables all I2C interrupts. */ stm32_i2c_putreg(priv, STM32_I2C_CR2_OFFSET, (STM32_PCLK1_FREQUENCY / 1000000)); stm32_i2c_setclock(priv, 100000); /* Enable I2C */ stm32_i2c_putreg(priv, STM32_I2C_CR1_OFFSET, I2C_CR1_PE); return OK; } /************************************************************************************ * Name: stm32_i2c_deinit * * Description: * Shutdown the I2C hardware * ************************************************************************************/ static int stm32_i2c_deinit(FAR struct stm32_i2c_priv_s *priv) { /* Disable I2C */ stm32_i2c_putreg(priv, STM32_I2C_CR1_OFFSET, 0); /* Unconfigure GPIO pins */ stm32_unconfiggpio(priv->config->scl_pin); stm32_unconfiggpio(priv->config->sda_pin); /* Disable and detach interrupts */ #ifndef CONFIG_I2C_POLLED up_disable_irq(priv->config->ev_irq); up_disable_irq(priv->config->er_irq); irq_detach(priv->config->ev_irq); irq_detach(priv->config->er_irq); #endif /* Disable clocking */ modifyreg32(STM32_RCC_APB1ENR, priv->config->clk_bit, 0); return OK; } /************************************************************************************ * Device Driver Operations ************************************************************************************/ /************************************************************************************ * Name: stm32_i2c_setfrequency * * Description: * Set the I2C frequency * ************************************************************************************/ static uint32_t stm32_i2c_setfrequency(FAR struct i2c_dev_s *dev, uint32_t frequency) { stm32_i2c_sem_wait(dev); #if STM32_PCLK1_FREQUENCY < 4000000 ((struct stm32_i2c_inst_s *)dev)->frequency = 100000; #else ((struct stm32_i2c_inst_s *)dev)->frequency = frequency; #endif stm32_i2c_sem_post(dev); return ((struct stm32_i2c_inst_s *)dev)->frequency; } /************************************************************************************ * Name: stm32_i2c_setaddress * * Description: * Set the I2C slave address * ************************************************************************************/ static int stm32_i2c_setaddress(FAR struct i2c_dev_s *dev, int addr, int nbits) { stm32_i2c_sem_wait(dev); ((struct stm32_i2c_inst_s *)dev)->address = addr; ((struct stm32_i2c_inst_s *)dev)->flags = (nbits == 10) ? I2C_M_TEN : 0; stm32_i2c_sem_post(dev); return OK; } /************************************************************************************ * Name: stm32_i2c_process * * Description: * Common I2C transfer logic * ************************************************************************************/ static int stm32_i2c_process(FAR struct i2c_dev_s *dev, FAR struct i2c_msg_s *msgs, int count) { struct stm32_i2c_inst_s *inst = (struct stm32_i2c_inst_s *)dev; FAR struct stm32_i2c_priv_s *priv = inst->priv; uint32_t status = 0; //uint32_t ahbenr; int errval = 0; ASSERT(count); /* Disable FSMC that shares a pin with I2C1 (LBAR) */ (void)stm32_i2c_disablefsmc(priv); /* Wait for any STOP in progress. NOTE: If we have to disable the FSMC * then we cannot do this at the top of the loop, unfortunately. The STOP * will not complete normally if the FSMC is enabled. */ #ifndef I2C1_FSMC_CONFLICT #if CONFIG_STM32_I2CTIMEOUS_START_STOP > 0 stm32_i2c_sem_waitstop(priv, CONFIG_STM32_I2CTIMEOUS_START_STOP); #else stm32_i2c_sem_waitstop(priv, CONFIG_STM32_I2CTIMEOMS * 1000UL + CONFIG_STM32_I2CTIMEOSEC * 1000000UL); #endif #endif /* Clear any pending error interrupts */ stm32_i2c_putreg(priv, STM32_I2C_SR1_OFFSET, 0); /* "Note: When the STOP, START or PEC bit is set, the software must * not perform any write access to I2C_CR1 before this bit is * cleared by hardware. Otherwise there is a risk of setting a * second STOP, START or PEC request." However, if the bits are * not cleared by hardware, then we will have to do that from hardware. */ stm32_i2c_clrstart(priv); /* Old transfers are done */ /* reset ptr and dcnt to ensure an unexpected data interrupt doesn't overwrite stale data */ priv->dcnt = 0; priv->ptr = NULL; priv->msgv = msgs; priv->msgc = count; /* Calculate timeout values */ int timeout_us = 0; #if CONFIG_STM32_I2CTIMEOUS_PER_BYTE > 0 /* Count the number of bytes left to process */ int i; int bytecount = 10; for (i = 0; i < count; i++) { bytecount += msgs[i].length; } timeout_us = CONFIG_STM32_I2CTIMEOUS_PER_BYTE * bytecount; //i2cvdbg("i2c wait: %d\n", timeout_us); #else timeout_us = CONFIG_STM32_I2CTIMEOMS * 1000UL + CONFIG_STM32_I2CTIMEOSEC * 1000000UL; #endif /* Reset I2C trace logic */ stm32_i2c_tracereset(priv); /* Set I2C clock frequency (on change it toggles I2C_CR1_PE !) */ stm32_i2c_setclock(priv, inst->frequency); /* Trigger start condition, then the process moves into the ISR. I2C * interrupts will be enabled within stm32_i2c_waitdone(). */ priv->status = 0; stm32_i2c_sendstart(priv); /* Wait for an ISR, if there was a timeout, fetch latest status to get * the BUSY flag. */ if (stm32_i2c_sem_waitdone(priv, timeout_us) < 0) { status = stm32_i2c_getstatus(priv); errval = ETIMEDOUT; i2cdbg("Timed out: CR1: %04x status: %08x after %d\n", stm32_i2c_getreg(priv, STM32_I2C_CR1_OFFSET), status, timeout_us); /* "Note: When the STOP, START or PEC bit is set, the software must * not perform any write access to I2C_CR1 before this bit is * cleared by hardware. Otherwise there is a risk of setting a * second STOP, START or PEC request." */ stm32_i2c_clrstart(priv); /* Clear busy flag in case of timeout */ status = priv->status & 0xffff; } else { /* clear SR2 (BUSY flag) as we've done successfully */ status = priv->status & 0xffff; } /* Check for error status conditions */ if ((status & I2C_SR1_ERRORMASK) != 0) { /* I2C_SR1_ERRORMASK is the 'OR' of the following individual bits: */ if (status & I2C_SR1_BERR) { /* Bus Error */ errval = EIO; } else if (status & I2C_SR1_ARLO) { /* Arbitration Lost (master mode) */ errval = EAGAIN; } else if (status & I2C_SR1_AF) { /* Acknowledge Failure */ errval = ENXIO; } else if (status & I2C_SR1_OVR) { /* Overrun/Underrun */ errval = EIO; } else if (status & I2C_SR1_PECERR) { /* PEC Error in reception */ errval = EPROTO; } else if (status & I2C_SR1_TIMEOUT) { /* Timeout or Tlow Error */ errval = ETIME; } /* This is not an error and should never happen since SMBus is not enabled */ else /* if (status & I2C_SR1_SMBALERT) */ { /* SMBus alert is an optional signal with an interrupt line for devices * that want to trade their ability to master for a pin. */ errval = EINTR; } } /* This is not an error, but should not happen. The BUSY signal can hang, * however, if there are unhealthy devices on the bus that need to be reset. * NOTE: We will only see this buy indication if stm32_i2c_sem_waitdone() * fails above; Otherwise it is cleared. */ else if ((status & (I2C_SR2_BUSY << 16)) != 0) { /* I2C Bus is for some reason busy */ errval = EBUSY; } /* Dump the trace result */ stm32_i2c_tracedump(priv); /* Wait for any STOP in progress. NOTE: If we have to disable the FSMC * then we cannot do this at the top of the loop, unfortunately. The STOP * will not complete normally if the FSMC is enabled. */ #ifdef I2C1_FSMC_CONFLICT stm32_i2c_sem_waitstop(priv); #endif /* Re-enable the FSMC */ stm32_i2c_enablefsmc(ahbenr); /* ensure that any ISR happening after we finish can't overwrite any user data */ priv->dcnt = 0; priv->ptr = NULL; stm32_i2c_sem_post(dev); return -errval; } /************************************************************************************ * Name: stm32_i2c_write * * Description: * Write I2C data * ************************************************************************************/ static int stm32_i2c_write(FAR struct i2c_dev_s *dev, const uint8_t *buffer, int buflen) { stm32_i2c_sem_wait(dev); /* ensure that address or flags don't change meanwhile */ struct i2c_msg_s msgv = { .addr = ((struct stm32_i2c_inst_s *)dev)->address, .flags = ((struct stm32_i2c_inst_s *)dev)->flags, .buffer = (uint8_t *)buffer, .length = buflen }; return stm32_i2c_process(dev, &msgv, 1); } /************************************************************************************ * Name: stm32_i2c_read * * Description: * Read I2C data * ************************************************************************************/ int stm32_i2c_read(FAR struct i2c_dev_s *dev, uint8_t *buffer, int buflen) { stm32_i2c_sem_wait(dev); /* ensure that address or flags don't change meanwhile */ struct i2c_msg_s msgv = { .addr = ((struct stm32_i2c_inst_s *)dev)->address, .flags = ((struct stm32_i2c_inst_s *)dev)->flags | I2C_M_READ, .buffer = buffer, .length = buflen }; return stm32_i2c_process(dev, &msgv, 1); } /************************************************************************************ * Name: stm32_i2c_writeread * * Description: * Read then write I2C data * ************************************************************************************/ #ifdef CONFIG_I2C_WRITEREAD static int stm32_i2c_writeread(FAR struct i2c_dev_s *dev, const uint8_t *wbuffer, int wbuflen, uint8_t *buffer, int buflen) { stm32_i2c_sem_wait(dev); /* ensure that address or flags don't change meanwhile */ struct i2c_msg_s msgv[2] = { { .addr = ((struct stm32_i2c_inst_s *)dev)->address, .flags = ((struct stm32_i2c_inst_s *)dev)->flags, .buffer = (uint8_t *)wbuffer, /* this is really ugly, sorry const ... */ .length = wbuflen }, { .addr = ((struct stm32_i2c_inst_s *)dev)->address, .flags = ((struct stm32_i2c_inst_s *)dev)->flags | ((buflen>0) ? I2C_M_READ : I2C_M_NORESTART), .buffer = buffer, .length = (buflen>0) ? buflen : -buflen } }; return stm32_i2c_process(dev, msgv, 2); } #endif /************************************************************************************ * Name: stm32_i2c_transfer * * Description: * Generic I2C transfer function * ************************************************************************************/ #ifdef CONFIG_I2C_TRANSFER static int stm32_i2c_transfer(FAR struct i2c_dev_s *dev, FAR struct i2c_msg_s *msgs, int count) { stm32_i2c_sem_wait(dev); /* ensure that address or flags don't change meanwhile */ return stm32_i2c_process(dev, msgs, count); } #endif /************************************************************************************ * Public Functions ************************************************************************************/ /************************************************************************************ * Name: up_i2cinitialize * * Description: * Initialize one I2C bus * ************************************************************************************/ FAR struct i2c_dev_s *up_i2cinitialize(int port) { struct stm32_i2c_priv_s * priv = NULL; /* private data of device with multiple instances */ struct stm32_i2c_inst_s * inst = NULL; /* device, single instance */ int irqs; #if STM32_PCLK1_FREQUENCY < 4000000 # warning STM32_I2C_INIT: Peripheral clock must be at least 4 MHz to support 400 kHz operation. #endif #if STM32_PCLK1_FREQUENCY < 2000000 # warning STM32_I2C_INIT: Peripheral clock must be at least 2 MHz to support 100 kHz operation. return NULL; #endif /* Get I2C private structure */ switch (port) { #ifdef CONFIG_STM32_I2C1 case 1: priv = (struct stm32_i2c_priv_s *)&stm32_i2c1_priv; break; #endif #ifdef CONFIG_STM32_I2C2 case 2: priv = (struct stm32_i2c_priv_s *)&stm32_i2c2_priv; break; #endif #ifdef CONFIG_STM32_I2C3 case 3: priv = (struct stm32_i2c_priv_s *)&stm32_i2c3_priv; break; #endif default: return NULL; } /* Allocate instance */ if (!(inst = kmalloc( sizeof(struct stm32_i2c_inst_s)))) { return NULL; } /* Initialize instance */ inst->ops = &stm32_i2c_ops; inst->priv = priv; inst->frequency = 100000; inst->address = 0; inst->flags = 0; /* Init private data for the first time, increment refs count, * power-up hardware and configure GPIOs. */ irqs = irqsave(); if ((volatile int)priv->refs++ == 0) { stm32_i2c_sem_init( (struct i2c_dev_s *)inst ); stm32_i2c_init( priv ); } irqrestore(irqs); return (struct i2c_dev_s *)inst; } /************************************************************************************ * Name: up_i2cuninitialize * * Description: * Uninitialize an I2C bus * ************************************************************************************/ int up_i2cuninitialize(FAR struct i2c_dev_s * dev) { int irqs; ASSERT(dev); /* Decrement refs and check for underflow */ if (((struct stm32_i2c_inst_s *)dev)->priv->refs == 0) { return ERROR; } irqs = irqsave(); if (--((struct stm32_i2c_inst_s *)dev)->priv->refs) { irqrestore(irqs); kfree(dev); return OK; } irqrestore(irqs); /* Disable power and other HW resource (GPIO's) */ stm32_i2c_deinit( ((struct stm32_i2c_inst_s *)dev)->priv ); /* Release unused resources */ stm32_i2c_sem_destroy( (struct i2c_dev_s *)dev ); kfree(dev); return OK; } /************************************************************************************ * Name: up_i2creset * * Description: * Reset an I2C bus * ************************************************************************************/ int up_i2creset(FAR struct i2c_dev_s * dev) { struct stm32_i2c_priv_s * priv; unsigned clock_count; unsigned stretch_count; int ret = ERROR; irqstate_t state; ASSERT(dev); /* Get I2C private structure */ priv = ((struct stm32_i2c_inst_s *)dev)->priv; /* Our caller must own a ref */ ASSERT(priv->refs > 0); /* Lock out other clients */ stm32_i2c_sem_wait(dev); /* De-init the port */ stm32_i2c_deinit(priv); /* If possible, use GPIO configuration to un-wedge the bus */ if ((priv->config->scl_gpio != 0) && (priv->config->sda_gpio != 0)) { stm32_configgpio(priv->config->scl_gpio); stm32_configgpio(priv->config->sda_gpio); /* * Clock the bus until any slaves currently driving it let it go. */ clock_count = 0; while (!stm32_gpioread(priv->config->sda_gpio)) { /* Give up if we have tried too hard */ if (clock_count++ > CONFIG_STM32_I2CTIMEOTICKS) { goto out; } /* * Sniff to make sure that clock stretching has finished. * * If the bus never relaxes, the reset has failed. */ stretch_count = 0; while (!stm32_gpioread(priv->config->scl_gpio)) { /* Give up if we have tried too hard */ if (stretch_count++ > 1000) { goto out; } up_udelay(10); } /* Drive SCL low */ stm32_gpiowrite(priv->config->scl_gpio, 0); up_udelay(10); /* Drive SCL high again */ stm32_gpiowrite(priv->config->scl_gpio, 1); up_udelay(10); } /* * Generate a start followed by a stop to reset slave * state machines. */ stm32_gpiowrite(priv->config->sda_gpio, 0); up_udelay(10); stm32_gpiowrite(priv->config->scl_gpio, 0); up_udelay(10); stm32_gpiowrite(priv->config->scl_gpio, 1); up_udelay(10); stm32_gpiowrite(priv->config->sda_gpio, 1); up_udelay(10); /* * Revert the GPIO configuration. */ stm32_unconfiggpio(priv->config->sda_gpio); stm32_unconfiggpio(priv->config->scl_gpio); } /* Re-init the port */ stm32_i2c_init(priv); ret = OK; out: /* release the port for re-use by other clients */ stm32_i2c_sem_post(dev); return ret; } #endif /* CONFIG_STM32_STM32F10XX || CONFIG_STM32_STM32F20XX || CONFIG_STM32_STM32F40XX */ #endif /* CONFIG_STM32_I2C1 || CONFIG_STM32_I2C2 || CONFIG_STM32_I2C3 */