#include <cfg/macros.h> // BV()
#include <cfg/module.h>
+#include <cpu/power.h>
#include <drv/gpio_stm32.h>
#include <drv/irq_cm3.h>
#include <drv/clock_stm32.h>
#include <io/stm32.h>
-struct stm32_i2c *i2c = (struct stm32_i2c *)I2C1_BASE;
-
-#define WAIT_BTF(base) while( !(base->SR1 & BV(SR1_BTF)) )
-#define WAIT_RXE(base) while( !(base->SR1 & BV(SR1_RXE)) )
+struct I2cHardware
+{
+ struct stm32_i2c *base;
+ uint32_t clk_i2c_en;
+ uint32_t pin_mask;
+ uint8_t cache[2];
+ bool cached;
+};
+
+#define WAIT_BTF(base) \
+ do { \
+ while (!(base->SR1 & BV(SR1_BTF))) \
+ cpu_relax(); \
+ } while (0)
+
+#define WAIT_RXNE(base) \
+ do { \
+ while (!(base->SR1 & BV(SR1_RXNE))) \
+ cpu_relax(); \
+ } while (0)
INLINE uint32_t get_status(struct stm32_i2c *base)
{
return ((base->SR1 | (base->SR2 << 16)) & 0x00FFFFFF);
}
-
-INLINE bool check_i2cStatus(uint32_t event)
+/*
+ * This fuction read the status registers of the i2c device
+ * and waint until the selec event happen. If occur one error
+ * the funtions return false.
+ */
+INLINE bool wait_event(I2c *i2c, uint32_t event)
{
while (true)
{
- uint32_t stat = get_status(i2c);
+ uint32_t stat = get_status(i2c->hw->base);
if (stat == event)
break;
if (stat & SR1_ERR_MASK)
{
- LOG_ERR("[%08lx]\n", stat & SR1_ERR_MASK);
- i2c->SR1 &= ~SR1_ERR_MASK;
-
- i2c->CR1 |= CR1_START_SET;
+ i2c->hw->base->SR1 &= ~SR1_ERR_MASK;
return false;
}
-
+ cpu_relax();
}
-
return true;
}
-/**
- * Send START condition on the bus.
- *
- * \return true on success, false otherwise.
- */
-static bool i2c_builtin_start(void)
-{
-
- i2c->CR1 |= (CR1_ACK_SET | BV(CR1_POS) | CR1_PE_SET);
- i2c->CR1 |= CR1_START_SET;
-
- if(check_i2cStatus(I2C_EVENT_MASTER_MODE_SELECT))
- return true;
-
- return false;
-}
-
-
-/**
- * Send START condition and select slave for write.
- * \c id is the device id comprehensive of address left shifted by 1.
- * The LSB of \c id is ignored and reset to 0 for write operation.
- *
- * \return true on success, false otherwise.
- */
-bool i2c_builtin_start_w(uint8_t id)
+INLINE void start_w(struct I2c *i2c, uint16_t slave_addr)
{
-
/*
* Loop on the select write sequence: when the eeprom is busy
* writing previously sent data it will reply to the SLA_W
* keep trying until the eeprom responds with an ACK.
*/
ticks_t start = timer_clock();
- while (i2c_builtin_start())
+ while (true)
{
- i2c->DR = id & OAR1_ADD0_RESET;
+ i2c->hw->base->CR1 |= CR1_ACK_SET | CR1_START_SET;
+
+ if(!wait_event(i2c, I2C_EVENT_MASTER_MODE_SELECT))
+ {
+ LOG_ERR("ARBIT lost\n");
+ i2c->errors |= I2C_ARB_LOST;
+ break;
+ }
- if(check_i2cStatus(I2C_EVENT_MASTER_TRANSMITTER_MODE_SELECTED))
- return true;
+ i2c->hw->base->DR = slave_addr & OAR1_ADD0_RESET;
+
+ if(wait_event(i2c, I2C_EVENT_MASTER_TRANSMITTER_MODE_SELECTED))
+ break;
if (timer_clock() - start > ms_to_ticks(CONFIG_I2C_START_TIMEOUT))
{
- LOG_ERR("Timeout on I2C_START\n");
+ LOG_ERR("Timeout on I2C START\n");
+ i2c->errors |= I2C_START_TIMEOUT;
+ i2c->hw->base->CR1 |= CR1_STOP_SET;
break;
}
}
-
- return false;
}
-
-/**
- * Send START condition and select slave for read.
- * \c id is the device id comprehensive of address left shifted by 1.
- * The LSB of \c id is ignored and set to 1 for read operation.
- *
- * \return true on success, false otherwise.
- */
-bool i2c_builtin_start_r(uint8_t id)
+INLINE bool start_and_addr(struct I2c *i2c, uint16_t slave_addr)
{
- i2c_builtin_start();
+ i2c->hw->base->CR1 |= CR1_START_SET;
+ if(!wait_event(i2c, I2C_EVENT_MASTER_MODE_SELECT))
+ {
+ LOG_ERR("ARBIT lost\n");
+ i2c->errors |= I2C_ARB_LOST;
+ i2c->hw->base->CR1 |= CR1_STOP_SET;
+ return false;
+ }
- i2c->DR = (id | OAR1_ADD0_SET);
+ i2c->hw->base->DR = (slave_addr | OAR1_ADD0_SET);
- if(check_i2cStatus(I2C_EVENT_MASTER_RECEIVER_MODE_SELECTED))
- return true;
+ if (i2c->xfer_size == 2)
+ i2c->hw->base->CR1 |= CR1_ACK_SET | CR1_POS_SET;
- return false;
-}
+ if(!wait_event(i2c, I2C_EVENT_MASTER_RECEIVER_MODE_SELECTED))
+ {
+ LOG_ERR("SLAR NACK:%08lx\n", get_status(i2c->hw->base));
+ i2c->errors |= I2C_NO_ACK;
+ i2c->hw->base->CR1 |= CR1_STOP_SET;
+ return false;
+ }
+ return true;
+}
-/**
- * Send STOP condition.
- */
-void i2c_builtin_stop(void)
+INLINE void start_r(struct I2c *i2c, uint16_t slave_addr)
{
- i2c->CR1 |= CR1_STOP_SET;
- i2c->CR1 &= CR1_PE_RESET;
-}
+ if (!start_and_addr(i2c, slave_addr))
+ return;
+ /*
+ * Due to the hardware receive bytes from slave in automatically mode
+ * we should manage contextually all cases that we want to read one, two or more
+ * than two bytes. To comply this behaviour to our api we shoul bufferd some byte
+ * to hide all special case that needs to use this device.
+ */
+ if (i2c->xfer_size == 1)
+ {
+ i2c->hw->base->CR1 &= CR1_ACK_RESET;
+ cpu_flags_t irq;
+ IRQ_SAVE_DISABLE(irq);
+ (void)i2c->hw->base->SR2;
+ if (I2C_TEST_STOP(i2c->flags) == I2C_STOP)
+ i2c->hw->base->CR1 |= CR1_STOP_SET;
+ IRQ_RESTORE(irq);
-bool i2c_builtin_put(const uint8_t data)
-{
- return true;
+ WAIT_RXNE(i2c->hw->base);
+
+ i2c->hw->cache[0] = i2c->hw->base->DR;
+ i2c->hw->cached = true;
+
+ if (I2C_TEST_STOP(i2c->flags) == I2C_STOP)
+ while (i2c->hw->base->CR1 & CR1_STOP_SET);
+
+ i2c->hw->base->CR1 |= CR1_ACK_SET;
+ }
+ else if (i2c->xfer_size == 2)
+ {
+ cpu_flags_t irq;
+
+ IRQ_SAVE_DISABLE(irq);
+ (void)i2c->hw->base->SR2;
+ i2c->hw->base->CR1 &= CR1_ACK_RESET;
+ IRQ_RESTORE(irq);
+
+ WAIT_BTF(i2c->hw->base);
+
+ IRQ_SAVE_DISABLE(irq);
+ if (I2C_TEST_STOP(i2c->flags) == I2C_STOP)
+ i2c->hw->base->CR1 |= CR1_STOP_SET;
+ /*
+ * We store read bytes like a fifo..
+ */
+ i2c->hw->cache[1] = i2c->hw->base->DR;
+ i2c->hw->cache[0] = i2c->hw->base->DR;
+ i2c->hw->cached = true;
+ IRQ_RESTORE(irq);
+
+ i2c->hw->base->CR1 &= CR1_POS_RESET;
+ i2c->hw->base->CR1 |= CR1_ACK_SET;
+ }
}
-int i2c_builtin_get(bool ack)
+static void i2c_stm32_start(struct I2c *i2c, uint16_t slave_addr)
{
+ i2c->hw->cached = false;
- return 0;
+ if (I2C_TEST_START(i2c->flags) == I2C_START_W)
+ start_w(i2c, slave_addr);
+ else /* (I2C_TEST_START(i2c->flags) == I2C_START_R) */
+ start_r(i2c, slave_addr);
}
-bool i2c_send(const void *_buf, size_t count)
+static void i2c_stm32_putc(I2c *i2c, const uint8_t data)
{
- const uint8_t *buf = (const uint8_t *)_buf;
-
- i2c->DR = *buf++;
- count--;
+ i2c->hw->base->DR = data;
+ WAIT_BTF(i2c->hw->base);
- while (count)
+ /* Generate the stop if we finish to send all programmed bytes */
+ if ((i2c->xfer_size == 1) && (I2C_TEST_STOP(i2c->flags) == I2C_STOP))
{
- ASSERT(buf);
- WAIT_BTF(i2c);
-
- i2c->DR = *buf++;
- count--;
-
- }
-
- if(check_i2cStatus(I2C_EVENT_MASTER_BYTE_TRANSMITTED))
- return true;
-
- return false;
+ wait_event(i2c, I2C_EVENT_MASTER_BYTE_TRANSMITTED);
+ i2c->hw->base->CR1 |= CR1_STOP_SET;
+ }
}
-/**
- * In order to read bytes from the i2c we should make some tricks.
- * This because the silicon manage automatically the NACK on last byte, so to read
- * one, two or three byte we should manage separately these cases.
- */
-bool i2c_recv(void *_buf, size_t count)
+static uint8_t i2c_stm32_getc(I2c *i2c)
{
- uint8_t *buf = (uint8_t *)_buf;
-
- while (count)
+ if (i2c->hw->cached)
{
- if (count == 1)
- {
- i2c->CR1 &= ~BV(CR1_POS);
-
- if(!check_i2cStatus(I2C_EVENT_MASTER_BYTE_RECEIVED))
- return false;
-
- i2c->CR1 &= CR1_ACK_RESET;
+ ASSERT(i2c->xfer_size <= 2);
+ return i2c->hw->cache[i2c->xfer_size - 1];
+ }
+ else
+ {
+ WAIT_BTF(i2c->hw->base);
- *buf++ = i2c->DR;
- count = 0;
- }
- else if (count == 2)
+ if (i2c->xfer_size == 3)
{
- i2c->CR1 &= CR1_ACK_RESET;
+ i2c->hw->base->CR1 &= CR1_ACK_RESET;
- WAIT_BTF(i2c);
+ cpu_flags_t irq;
+ IRQ_SAVE_DISABLE(irq);
- i2c->CR1 |= CR1_STOP_SET;
+ uint8_t data = i2c->hw->base->DR;
- *buf++ = i2c->DR;
- *buf++ = i2c->DR;
+ if (I2C_TEST_STOP(i2c->flags) == I2C_STOP)
+ i2c->hw->base->CR1 |= CR1_STOP_SET;
- count = 0;
+ i2c->hw->cache[1] = i2c->hw->base->DR;
- i2c->CR1 &= ~BV(CR1_POS);
+ IRQ_RESTORE(irq);
- }
- else if (count == 3)
- {
- i2c->CR1 &= ~BV(CR1_POS);
-
- WAIT_BTF(i2c);
-
- i2c->CR1 &= CR1_ACK_RESET;
-
- *buf++ = i2c->DR;
-
- i2c->CR1 |= CR1_STOP_SET;
+ WAIT_RXNE(i2c->hw->base);
- *buf++ = i2c->DR;
+ i2c->hw->cache[0] = i2c->hw->base->DR;
+ i2c->hw->cached = true;
- WAIT_RXE(i2c);
+ if (I2C_TEST_STOP(i2c->flags) == I2C_STOP)
+ while (i2c->hw->base->CR1 & CR1_STOP_SET);
- *buf++ = i2c->DR;
-
- count = 0;
+ return data;
}
else
- {
- i2c->CR1 &= ~BV(CR1_POS);
-
- WAIT_BTF(i2c);
-
- *buf++ = i2c->DR;
-
- count--;
- }
+ return i2c->hw->base->DR;
}
-
- return true;
}
-MOD_DEFINE(i2c);
+
+static const I2cVT i2c_stm32_vt =
+{
+ .start = i2c_stm32_start,
+ .getc = i2c_stm32_getc,
+ .putc = i2c_stm32_putc,
+ .write = i2c_genericWrite,
+ .read = i2c_genericRead,
+};
+
+static struct I2cHardware i2c_stm32_hw[] =
+{
+ { /* I2C1 */
+ .base = (struct stm32_i2c *)I2C1_BASE,
+ .clk_i2c_en = RCC_APB1_I2C1,
+ .pin_mask = (GPIO_I2C1_SCL_PIN | GPIO_I2C1_SDA_PIN),
+ },
+ { /* I2C2 */
+ .base = (struct stm32_i2c *)I2C2_BASE,
+ .clk_i2c_en = RCC_APB1_I2C2,
+ .pin_mask = (GPIO_I2C2_SCL_PIN | GPIO_I2C2_SDA_PIN),
+ },
+};
/**
* Initialize I2C module.
*/
-void i2c_builtin_init(void)
+void i2c_hw_init(I2c *i2c, int dev, uint32_t clock)
{
- MOD_INIT(i2c);
+
+ i2c->hw = &i2c_stm32_hw[dev];
+ i2c->vt = &i2c_stm32_vt;
RCC->APB2ENR |= RCC_APB2_GPIOB;
- RCC->APB1ENR |= RCC_APB1_I2C1;
+ RCC->APB1ENR |= i2c->hw->clk_i2c_en;
/* Set gpio to use I2C driver */
- stm32_gpioPinConfig((struct stm32_gpio *)GPIOB_BASE, GPIO_I2C1_SCL_PIN,
- GPIO_MODE_AF_OD, GPIO_SPEED_50MHZ);
-
- stm32_gpioPinConfig((struct stm32_gpio *)GPIOB_BASE, GPIO_I2C1_SDA_PIN,
+ stm32_gpioPinConfig((struct stm32_gpio *)GPIOB_BASE, i2c->hw->pin_mask,
GPIO_MODE_AF_OD, GPIO_SPEED_50MHZ);
-
/* Clear all needed registers */
- i2c->CR1 = 0;
- i2c->CR2 = 0;
- i2c->CCR = 0;
- i2c->TRISE = 0;
- i2c->OAR1 = 0;
+ i2c->hw->base->CR1 = 0;
+ i2c->hw->base->CR2 = 0;
+ i2c->hw->base->CCR = 0;
+ i2c->hw->base->TRISE = 0;
+ i2c->hw->base->OAR1 = 0;
/* Set PCLK1 frequency accornding to the master clock settings. See stm32_clock.c */
- i2c->CR2 |= CR2_FREQ_36MHZ;
+ i2c->hw->base->CR2 |= CR2_FREQ_36MHZ;
/* Configure spi in standard mode */
- #if CONFIG_I2C_FREQ <= 100000
- i2c->CCR |= (uint16_t)((CR2_FREQ_36MHZ * 1000000) / (CONFIG_I2C_FREQ << 1));
- i2c->TRISE |= (CR2_FREQ_36MHZ + 1);
- #else
- #error fast mode not supported
- #endif
+ ASSERT2(clock >= 100000, "fast mode not supported");
+
+ i2c->hw->base->CCR |= (uint16_t)((CR2_FREQ_36MHZ * 1000000) / (clock << 1));
+ i2c->hw->base->TRISE |= (CR2_FREQ_36MHZ + 1);
+ i2c->hw->base->CR1 |= CR1_PE_SET;
}