Demo application running on STM8 demonstrating a web interface with ESPTerm
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/**
******************************************************************************
* @file stm8s_i2c.h
* @author MCD Application Team
* @version V2.2.0
* @date 30-September-2014
* @brief This file contains all functions prototype and macros for the I2C peripheral.
******************************************************************************
* @attention
*
* <h2><center>&copy; COPYRIGHT 2014 STMicroelectronics</center></h2>
*
* Licensed under MCD-ST Liberty SW License Agreement V2, (the "License");
* You may not use this file except in compliance with the License.
* You may obtain a copy of the License at:
*
* http://www.st.com/software_license_agreement_liberty_v2
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*
******************************************************************************
*/
/* Define to prevent recursive inclusion -------------------------------------*/
#ifndef __STM8S_I2C_H
#define __STM8S_I2C_H
/* Includes ------------------------------------------------------------------*/
#include "stm8s.h"
/* Exported types ------------------------------------------------------------*/
/** @addtogroup I2C_Exported_Types
* @{
*/
/**
* @brief I2C duty cycle (fast mode only)
*/
typedef enum
{
I2C_DUTYCYCLE_2 = (uint8_t)0x00, /*!< Fast mode Tlow/THigh = 2 */
I2C_DUTYCYCLE_16_9 = (uint8_t)0x40 /*!< Fast mode Tlow/Thigh = 16/9 */
} I2C_DutyCycle_TypeDef;
/**
* @brief I2C Acknowledgement configuration
*/
typedef enum
{
I2C_ACK_NONE = (uint8_t)0x00, /*!< No acknowledge */
I2C_ACK_CURR = (uint8_t)0x01, /*!< Acknowledge on the current byte */
I2C_ACK_NEXT = (uint8_t)0x02 /*!< Acknowledge on the next byte */
} I2C_Ack_TypeDef;
/**
* @brief I2C Addressing Mode (slave mode only)
*/
typedef enum
{
I2C_ADDMODE_7BIT = (uint8_t)0x00, /*!< 7-bit slave address (10-bit address not acknowledged) */
I2C_ADDMODE_10BIT = (uint8_t)0x80 /*!< 10-bit slave address (7-bit address not acknowledged) */
} I2C_AddMode_TypeDef;
/**
* @brief I2C Interrupt sources
* Warning: the values correspond to the bit position in the ITR register
*/
typedef enum
{
I2C_IT_ERR = (uint8_t)0x01, /*!< Error Interruption */
I2C_IT_EVT = (uint8_t)0x02, /*!< Event Interruption */
I2C_IT_BUF = (uint8_t)0x04 /*!< Buffer Interruption */
} I2C_IT_TypeDef;
/**
* @brief I2C transfer direction
* Warning: the values correspond to the ADD0 bit position in the OARL register
*/
typedef enum
{
I2C_DIRECTION_TX = (uint8_t)0x00, /*!< Transmission direction */
I2C_DIRECTION_RX = (uint8_t)0x01 /*!< Reception direction */
} I2C_Direction_TypeDef;
/**
* @brief I2C Flags
* @brief Elements values convention: 0xXXYY
* X = SRx registers index
* X = 1 : SR1
* X = 2 : SR2
* X = 3 : SR3
* Y = Flag mask in the register
*/
typedef enum
{
/* SR1 register flags */
I2C_FLAG_TXEMPTY = (uint16_t)0x0180, /*!< Transmit Data Register Empty flag */
I2C_FLAG_RXNOTEMPTY = (uint16_t)0x0140, /*!< Read Data Register Not Empty flag */
I2C_FLAG_STOPDETECTION = (uint16_t)0x0110, /*!< Stop detected flag */
I2C_FLAG_HEADERSENT = (uint16_t)0x0108, /*!< 10-bit Header sent flag */
I2C_FLAG_TRANSFERFINISHED = (uint16_t)0x0104, /*!< Data Byte Transfer Finished flag */
I2C_FLAG_ADDRESSSENTMATCHED = (uint16_t)0x0102, /*!< Address Sent/Matched (master/slave) flag */
I2C_FLAG_STARTDETECTION = (uint16_t)0x0101, /*!< Start bit sent flag */
/* SR2 register flags */
I2C_FLAG_WAKEUPFROMHALT = (uint16_t)0x0220, /*!< Wake Up From Halt Flag */
I2C_FLAG_OVERRUNUNDERRUN = (uint16_t)0x0208, /*!< Overrun/Underrun flag */
I2C_FLAG_ACKNOWLEDGEFAILURE = (uint16_t)0x0204, /*!< Acknowledge Failure Flag */
I2C_FLAG_ARBITRATIONLOSS = (uint16_t)0x0202, /*!< Arbitration Loss Flag */
I2C_FLAG_BUSERROR = (uint16_t)0x0201, /*!< Misplaced Start or Stop condition */
/* SR3 register flags */
I2C_FLAG_GENERALCALL = (uint16_t)0x0310, /*!< General Call header received Flag */
I2C_FLAG_TRANSMITTERRECEIVER = (uint16_t)0x0304, /*!< Transmitter Receiver Flag */
I2C_FLAG_BUSBUSY = (uint16_t)0x0302, /*!< Bus Busy Flag */
I2C_FLAG_MASTERSLAVE = (uint16_t)0x0301 /*!< Master Slave Flag */
} I2C_Flag_TypeDef;
/**
* @brief I2C Pending bits
* Elements values convention: 0xXYZZ
* X = SRx registers index
* X = 1 : SR1
* X = 2 : SR2
* Y = Position of the corresponding Interrupt
* ZZ = flag mask in the dedicated register(X register)
*/
typedef enum
{
/* SR1 register flags */
I2C_ITPENDINGBIT_TXEMPTY = (uint16_t)0x1680, /*!< Transmit Data Register Empty */
I2C_ITPENDINGBIT_RXNOTEMPTY = (uint16_t)0x1640, /*!< Read Data Register Not Empty */
I2C_ITPENDINGBIT_STOPDETECTION = (uint16_t)0x1210, /*!< Stop detected */
I2C_ITPENDINGBIT_HEADERSENT = (uint16_t)0x1208, /*!< 10-bit Header sent */
I2C_ITPENDINGBIT_TRANSFERFINISHED = (uint16_t)0x1204, /*!< Data Byte Transfer Finished */
I2C_ITPENDINGBIT_ADDRESSSENTMATCHED = (uint16_t)0x1202, /*!< Address Sent/Matched (master/slave) */
I2C_ITPENDINGBIT_STARTDETECTION = (uint16_t)0x1201, /*!< Start bit sent */
/* SR2 register flags */
I2C_ITPENDINGBIT_WAKEUPFROMHALT = (uint16_t)0x2220, /*!< Wake Up From Halt */
I2C_ITPENDINGBIT_OVERRUNUNDERRUN = (uint16_t)0x2108, /*!< Overrun/Underrun */
I2C_ITPENDINGBIT_ACKNOWLEDGEFAILURE = (uint16_t)0x2104, /*!< Acknowledge Failure */
I2C_ITPENDINGBIT_ARBITRATIONLOSS = (uint16_t)0x2102, /*!< Arbitration Loss */
I2C_ITPENDINGBIT_BUSERROR = (uint16_t)0x2101 /*!< Misplaced Start or Stop condition */
} I2C_ITPendingBit_TypeDef;
/**
* @brief I2C possible events
* Values convention: 0xXXYY
* XX = Event SR3 corresponding value
* YY = Event SR1 corresponding value
* @note if Event = EV3_2 the rule above does not apply
* YY = Event SR2 corresponding value
*/
typedef enum
{
/*========================================
I2C Master Events (Events grouped in order of communication)
==========================================*/
/**
* @brief Communication start
*
* After sending the START condition (I2C_GenerateSTART() function) the master
* has to wait for this event. It means that the Start condition has been correctly
* released on the I2C bus (the bus is free, no other devices is communicating).
*
*/
/* --EV5 */
I2C_EVENT_MASTER_MODE_SELECT = (uint16_t)0x0301, /*!< BUSY, MSL and SB flag */
/**
* @brief Address Acknowledge
*
* After checking on EV5 (start condition correctly released on the bus), the
* master sends the address of the slave(s) with which it will communicate
* (I2C_Send7bitAddress() function, it also determines the direction of the communication:
* Master transmitter or Receiver).
* Then the master has to wait that a slave acknowledges his address.
* If an acknowledge is sent on the bus, one of the following events will
* be set:
*
* 1) In case of Master Receiver (7-bit addressing):
* the I2C_EVENT_MASTER_RECEIVER_MODE_SELECTED event is set.
*
* 2) In case of Master Transmitter (7-bit addressing):
* the I2C_EVENT_MASTER_TRANSMITTER_MODE_SELECTED is set
*
* 3) In case of 10-Bit addressing mode, the master (just after generating the START
* and checking on EV5) has to send the header of 10-bit addressing mode (I2C_SendData()
* function).
* Then master should wait on EV9. It means that the 10-bit addressing
* header has been correctly sent on the bus.
* Then master should send the second part of the 10-bit address (LSB) using
* the function I2C_Send7bitAddress(). Then master should wait for event EV6.
*
*/
/* --EV6 */
I2C_EVENT_MASTER_TRANSMITTER_MODE_SELECTED = (uint16_t)0x0782, /*!< BUSY, MSL, ADDR, TXE and TRA flags */
I2C_EVENT_MASTER_RECEIVER_MODE_SELECTED = (uint16_t)0x0302, /*!< BUSY, MSL and ADDR flags */
/* --EV9 */
I2C_EVENT_MASTER_MODE_ADDRESS10 = (uint16_t)0x0308, /*!< BUSY, MSL and ADD10 flags */
/**
* @brief Communication events
*
* If a communication is established (START condition generated and slave address
* acknowledged) then the master has to check on one of the following events for
* communication procedures:
*
* 1) Master Receiver mode: The master has to wait on the event EV7 then to read
* the data received from the slave (I2C_ReceiveData() function).
*
* 2) Master Transmitter mode: The master has to send data (I2C_SendData()
* function) then to wait on event EV8 or EV8_2.
* These two events are similar:
* - EV8 means that the data has been written in the data register and is
* being shifted out.
* - EV8_2 means that the data has been physically shifted out and output
* on the bus.
* In most cases, using EV8 is sufficient for the application.
* Using EV8_2 leads to a slower communication but ensures more reliable test.
* EV8_2 is also more suitable than EV8 for testing on the last data transmission
* (before Stop condition generation).
*
* @note In case the user software does not guarantee that this event EV7 is
* managed before the current byte end of transfer, then user may check on EV7
* and BTF flag at the same time (ie. (I2C_EVENT_MASTER_BYTE_RECEIVED | I2C_FLAG_BTF)).
* In this case the communication may be slower.
*
*/
/* Master RECEIVER mode -----------------------------*/
/* --EV7 */
I2C_EVENT_MASTER_BYTE_RECEIVED = (uint16_t)0x0340, /*!< BUSY, MSL and RXNE flags */
/* Master TRANSMITTER mode --------------------------*/
/* --EV8 */
I2C_EVENT_MASTER_BYTE_TRANSMITTING = (uint16_t)0x0780, /*!< TRA, BUSY, MSL, TXE flags */
/* --EV8_2 */
I2C_EVENT_MASTER_BYTE_TRANSMITTED = (uint16_t)0x0784, /*!< EV8_2: TRA, BUSY, MSL, TXE and BTF flags */
/*========================================
I2C Slave Events (Events grouped in order of communication)
==========================================*/
/**
* @brief Communication start events
*
* Wait on one of these events at the start of the communication. It means that
* the I2C peripheral detected a Start condition on the bus (generated by master
* device) followed by the peripheral address.
* The peripheral generates an ACK condition on the bus (if the acknowledge
* feature is enabled through function I2C_AcknowledgeConfig()) and the events
* listed above are set :
*
* 1) In normal case (only one address managed by the slave), when the address
* sent by the master matches the own address of the peripheral (configured by
* I2C_OwnAddress1 field) the I2C_EVENT_SLAVE_XXX_ADDRESS_MATCHED event is set
* (where XXX could be TRANSMITTER or RECEIVER).
*
* 2) In case the address sent by the master is General Call (address 0x00) and
* if the General Call is enabled for the peripheral (using function I2C_GeneralCallCmd())
* the following event is set I2C_EVENT_SLAVE_GENERALCALLADDRESS_MATCHED.
*
*/
/* --EV1 (all the events below are variants of EV1) */
/* 1) Case of One Single Address managed by the slave */
I2C_EVENT_SLAVE_RECEIVER_ADDRESS_MATCHED = (uint16_t)0x0202, /*!< BUSY and ADDR flags */
I2C_EVENT_SLAVE_TRANSMITTER_ADDRESS_MATCHED = (uint16_t)0x0682, /*!< TRA, BUSY, TXE and ADDR flags */
/* 2) Case of General Call enabled for the slave */
I2C_EVENT_SLAVE_GENERALCALLADDRESS_MATCHED = (uint16_t)0x1200, /*!< EV2: GENCALL and BUSY flags */
/**
* @brief Communication events
*
* Wait on one of these events when EV1 has already been checked :
*
* - Slave RECEIVER mode:
* - EV2: When the application is expecting a data byte to be received.
* - EV4: When the application is expecting the end of the communication:
* master sends a stop condition and data transmission is stopped.
*
* - Slave Transmitter mode:
* - EV3: When a byte has been transmitted by the slave and the application
* is expecting the end of the byte transmission.
* The two events I2C_EVENT_SLAVE_BYTE_TRANSMITTED and I2C_EVENT_SLAVE_BYTE_TRANSMITTING
* are similar. The second one can optionally be used when the user software
* doesn't guarantee the EV3 is managed before the current byte end of transfer.
* - EV3_2: When the master sends a NACK in order to tell slave that data transmission
* shall end (before sending the STOP condition).
* In this case slave has to stop sending data bytes and expect a Stop
* condition on the bus.
*
* @note In case the user software does not guarantee that the event EV2 is
* managed before the current byte end of transfer, then user may check on EV2
* and BTF flag at the same time (ie. (I2C_EVENT_SLAVE_BYTE_RECEIVED | I2C_FLAG_BTF)).
* In this case the communication may be slower.
*
*/
/* Slave RECEIVER mode --------------------------*/
/* --EV2 */
I2C_EVENT_SLAVE_BYTE_RECEIVED = (uint16_t)0x0240, /*!< BUSY and RXNE flags */
/* --EV4 */
I2C_EVENT_SLAVE_STOP_DETECTED = (uint16_t)0x0010, /*!< STOPF flag */
/* Slave TRANSMITTER mode -----------------------*/
/* --EV3 */
I2C_EVENT_SLAVE_BYTE_TRANSMITTED = (uint16_t)0x0684, /*!< TRA, BUSY, TXE and BTF flags */
I2C_EVENT_SLAVE_BYTE_TRANSMITTING = (uint16_t)0x0680, /*!< TRA, BUSY and TXE flags */
/* --EV3_2 */
I2C_EVENT_SLAVE_ACK_FAILURE = (uint16_t)0x0004 /*!< AF flag */
} I2C_Event_TypeDef;
/**
* @}
*/
/* Exported constants --------------------------------------------------------*/
/** @addtogroup I2C_Exported_Constants
* @{
*/
#define I2C_MAX_STANDARD_FREQ ((uint32_t)100000)
#define I2C_MAX_FAST_FREQ ((uint32_t)400000)
#if defined(STM8S208) || defined(STM8S207) || defined(STM8S007)
#define I2C_MAX_INPUT_FREQ ((uint8_t)24)
#else
#define I2C_MAX_INPUT_FREQ ((uint8_t)16)
#endif
/**
*@}
*/
/* Exported macros -----------------------------------------------------------*/
/* Private macros ------------------------------------------------------------*/
/** @addtogroup I2C_Private_Macros
* @{
*/
/**
* @brief Macro used by the assert function to check the different functions parameters.
*/
/**
* @brief Macro used by the assert function to check the different I2C duty cycles.
*/
#define IS_I2C_DUTYCYCLE_OK(DUTY) \
(((DUTY) == I2C_DUTYCYCLE_2) || \
((DUTY) == I2C_DUTYCYCLE_16_9))
/**
* @brief Macro used by the assert function to check the different acknowledgement configuration
*/
#define IS_I2C_ACK_OK(ACK) \
(((ACK) == I2C_ACK_NONE) || \
((ACK) == I2C_ACK_CURR) || \
((ACK) == I2C_ACK_NEXT))
/**
* @brief Macro used by the assert function to check the different I2C addressing modes.
*/
#define IS_I2C_ADDMODE_OK(ADDMODE) \
(((ADDMODE) == I2C_ADDMODE_7BIT) || \
((ADDMODE) == I2C_ADDMODE_10BIT))
/**
* @brief Macro used by the assert function to check the different I2C interrupt types.
*/
#define IS_I2C_INTERRUPT_OK(IT) \
(((IT) == I2C_IT_ERR) || \
((IT) == I2C_IT_EVT) || \
((IT) == I2C_IT_BUF) || \
((IT) == (I2C_IT_ERR | I2C_IT_EVT)) || \
((IT) == (I2C_IT_ERR | I2C_IT_BUF)) || \
((IT) == (I2C_IT_EVT | I2C_IT_BUF)) || \
((IT) == (I2C_IT_EVT | I2C_IT_BUF | I2C_IT_ERR)))
/**
* @brief Macro used by the assert function to check the different I2C communcation direction.
*/
#define IS_I2C_DIRECTION_OK(DIR) \
(((DIR) == I2C_DIRECTION_TX) || \
((DIR) == I2C_DIRECTION_RX))
/**
* @brief Macro used by the assert function to check the different I2C flags.
*/
#define IS_I2C_FLAG_OK(FLAG) \
(((FLAG) == I2C_FLAG_TXEMPTY) || \
((FLAG) == I2C_FLAG_RXNOTEMPTY) || \
((FLAG) == I2C_FLAG_STOPDETECTION) || \
((FLAG) == I2C_FLAG_HEADERSENT) || \
((FLAG) == I2C_FLAG_TRANSFERFINISHED) || \
((FLAG) == I2C_FLAG_ADDRESSSENTMATCHED) || \
((FLAG) == I2C_FLAG_STARTDETECTION) || \
((FLAG) == I2C_FLAG_WAKEUPFROMHALT) || \
((FLAG) == I2C_FLAG_OVERRUNUNDERRUN) || \
((FLAG) == I2C_FLAG_ACKNOWLEDGEFAILURE) || \
((FLAG) == I2C_FLAG_ARBITRATIONLOSS) || \
((FLAG) == I2C_FLAG_BUSERROR) || \
((FLAG) == I2C_FLAG_GENERALCALL) || \
((FLAG) == I2C_FLAG_TRANSMITTERRECEIVER) || \
((FLAG) == I2C_FLAG_BUSBUSY) || \
((FLAG) == I2C_FLAG_MASTERSLAVE))
/**
* @brief Macro used by the assert function to check the I2C flags to clear.
*/
#define IS_I2C_CLEAR_FLAG_OK(FLAG) ((((uint16_t)(FLAG) & (uint16_t)0xFD00) == 0x00) \
&& ((uint16_t)(FLAG) != 0x00))
/**
* @brief Macro used by the assert function to check the different I2C possible pending bits.
*/
#define IS_I2C_ITPENDINGBIT_OK(ITPENDINGBIT) \
(((ITPENDINGBIT) == I2C_ITPENDINGBIT_TXEMPTY) || \
((ITPENDINGBIT) == I2C_ITPENDINGBIT_RXNOTEMPTY) || \
((ITPENDINGBIT) == I2C_ITPENDINGBIT_STOPDETECTION) || \
((ITPENDINGBIT) == I2C_ITPENDINGBIT_HEADERSENT) || \
((ITPENDINGBIT) == I2C_ITPENDINGBIT_TRANSFERFINISHED) || \
((ITPENDINGBIT) == I2C_ITPENDINGBIT_ADDRESSSENTMATCHED) || \
((ITPENDINGBIT) == I2C_ITPENDINGBIT_STARTDETECTION) || \
((ITPENDINGBIT) == I2C_ITPENDINGBIT_WAKEUPFROMHALT) || \
((ITPENDINGBIT) == I2C_ITPENDINGBIT_OVERRUNUNDERRUN) || \
((ITPENDINGBIT) == I2C_ITPENDINGBIT_ACKNOWLEDGEFAILURE) || \
((ITPENDINGBIT) == I2C_ITPENDINGBIT_ARBITRATIONLOSS) || \
((ITPENDINGBIT) == I2C_ITPENDINGBIT_BUSERROR))
/**
* @brief Macro used by the assert function to check the different I2C possible
* pending bits to clear by writing 0.
*/
#define IS_I2C_CLEAR_ITPENDINGBIT_OK(ITPENDINGBIT) \
(((ITPENDINGBIT) == I2C_ITPENDINGBIT_WAKEUPFROMHALT) || \
((ITPENDINGBIT) == I2C_ITPENDINGBIT_OVERRUNUNDERRUN) || \
((ITPENDINGBIT) == I2C_ITPENDINGBIT_ACKNOWLEDGEFAILURE) || \
((ITPENDINGBIT) == I2C_ITPENDINGBIT_ARBITRATIONLOSS) || \
((ITPENDINGBIT) == I2C_ITPENDINGBIT_BUSERROR))
/**
* @brief Macro used by the assert function to check the different I2C possible events.
*/
#define IS_I2C_EVENT_OK(EVENT) (((EVENT) == I2C_EVENT_SLAVE_TRANSMITTER_ADDRESS_MATCHED) || \
((EVENT) == I2C_EVENT_SLAVE_RECEIVER_ADDRESS_MATCHED) || \
((EVENT) == I2C_EVENT_SLAVE_GENERALCALLADDRESS_MATCHED) || \
((EVENT) == I2C_EVENT_SLAVE_BYTE_RECEIVED) || \
((EVENT) == (I2C_EVENT_SLAVE_BYTE_RECEIVED | (uint16_t)I2C_FLAG_GENERALCALL)) || \
((EVENT) == I2C_EVENT_SLAVE_BYTE_TRANSMITTED) || \
((EVENT) == (I2C_EVENT_SLAVE_BYTE_TRANSMITTED | (uint16_t)I2C_FLAG_GENERALCALL)) || \
((EVENT) == I2C_EVENT_SLAVE_ACK_FAILURE) || \
((EVENT) == I2C_EVENT_SLAVE_STOP_DETECTED) || \
((EVENT) == I2C_EVENT_MASTER_MODE_SELECT) || \
((EVENT) == I2C_EVENT_MASTER_TRANSMITTER_MODE_SELECTED) || \
((EVENT) == I2C_EVENT_MASTER_RECEIVER_MODE_SELECTED) || \
((EVENT) == I2C_EVENT_MASTER_BYTE_RECEIVED) || \
((EVENT) == I2C_EVENT_MASTER_BYTE_TRANSMITTED) || \
((EVENT) == I2C_EVENT_MASTER_BYTE_TRANSMITTING) || \
((EVENT) == I2C_EVENT_MASTER_MODE_ADDRESS10))
/**
* @brief Macro used by the assert function to check the different I2C possible own address.
*/
#define IS_I2C_OWN_ADDRESS_OK(ADDRESS) \
((ADDRESS) <= (uint16_t)0x03FF)
/* The address must be even */
#define IS_I2C_ADDRESS_OK(ADD) \
(((ADD) & (uint8_t)0x01) == (uint8_t)0x00)
/**
* @brief Macro used by the assert function to check that I2C Input clock frequency must be between 1MHz and 50MHz.
*/
#define IS_I2C_INPUT_CLOCK_FREQ_OK(FREQ) \
(((FREQ) >= (uint8_t)1) && ((FREQ) <= I2C_MAX_INPUT_FREQ))
/**
* @brief Macro used by the assert function to check that I2C Output clock frequency must be between 1Hz and 400kHz.
*/
#define IS_I2C_OUTPUT_CLOCK_FREQ_OK(FREQ) \
(((FREQ) >= (uint8_t)1) && ((FREQ) <= I2C_MAX_FAST_FREQ))
/**
* @}
*/
/* Exported functions ------------------------------------------------------- */
/** @addtogroup I2C_Exported_Functions
* @{
*/
void I2C_DeInit(void);
void I2C_Init(uint32_t OutputClockFrequencyHz, uint16_t OwnAddress,
I2C_DutyCycle_TypeDef I2C_DutyCycle, I2C_Ack_TypeDef Ack,
I2C_AddMode_TypeDef AddMode, uint8_t InputClockFrequencyMHz );
void I2C_Cmd(FunctionalState NewState);
void I2C_GeneralCallCmd(FunctionalState NewState);
void I2C_GenerateSTART(FunctionalState NewState);
void I2C_GenerateSTOP(FunctionalState NewState);
void I2C_SoftwareResetCmd(FunctionalState NewState);
void I2C_StretchClockCmd(FunctionalState NewState);
void I2C_AcknowledgeConfig(I2C_Ack_TypeDef Ack);
void I2C_FastModeDutyCycleConfig(I2C_DutyCycle_TypeDef I2C_DutyCycle);
void I2C_ITConfig(I2C_IT_TypeDef I2C_IT, FunctionalState NewState);
uint8_t I2C_ReceiveData(void);
void I2C_Send7bitAddress(uint8_t Address, I2C_Direction_TypeDef Direction);
void I2C_SendData(uint8_t Data);
/**
* @brief
****************************************************************************************
*
* I2C State Monitoring Functions
*
****************************************************************************************
* This I2C driver provides three different ways for I2C state monitoring
* depending on the application requirements and constraints:
*
*
* 1) Basic state monitoring:
* Using I2C_CheckEvent() function:
* It compares the status registers (SR1, SR2 and SR3) content to a given event
* (can be the combination of one or more flags).
* It returns SUCCESS if the current status includes the given flags
* and returns ERROR if one or more flags are missing in the current status.
* - When to use:
* - This function is suitable for most applications as well as for startup
* activity since the events are fully described in the product reference manual
* (RM0016).
* - It is also suitable for users who need to define their own events.
* - Limitations:
* - If an error occurs (ie. error flags are set besides to the monitored flags),
* the I2C_CheckEvent() function may return SUCCESS despite the communication
* hold or corrupted real state.
* In this case, it is advised to use error interrupts to monitor the error
* events and handle them in the interrupt IRQ handler.
*
* @note
* For error management, it is advised to use the following functions:
* - I2C_ITConfig() to configure and enable the error interrupts (I2C_IT_ERR).
* - I2C_IRQHandler() which is called when the I2C interrupts occur.
* - I2C_GetFlagStatus() or I2C_GetITStatus() to be called into the
* I2Cx_IRQHandler() function in order to determine which error occurred.
* - I2C_ClearFlag() or I2C_ClearITPendingBit() and/or I2C_SoftwareResetCmd()
* and/or I2C_GenerateStop() in order to clear the error flag and
* source and return to correct communication status.
*
*
* 2) Advanced state monitoring:
* Using the function I2C_GetLastEvent() which returns the image of both SR1
* & SR3 status registers in a single word (uint16_t) (Status Register 3 value
* is shifted left by 8 bits and concatenated to Status Register 1).
* - When to use:
* - This function is suitable for the same applications above but it allows to
* overcome the limitations of I2C_GetFlagStatus() function (see below).
* The returned value could be compared to events already defined in the
* library (stm8s_i2c.h) or to custom values defined by user.
* - This function is suitable when multiple flags are monitored at the same time.
* - At the opposite of I2C_CheckEvent() function, this function allows user to
* choose when an event is accepted (when all events flags are set and no
* other flags are set or just when the needed flags are set like
* I2C_CheckEvent() function).
* - Limitations:
* - User may need to define his own events.
* - Same remark concerning the error management is applicable for this
* function if user decides to check only regular communication flags (and
* ignores error flags).
*
*
* 3) Flag-based state monitoring:
* Using the function I2C_GetFlagStatus() which simply returns the status of
* one single flag (ie. I2C_FLAG_RXNE ...).
* - When to use:
* - This function could be used for specific applications or in debug phase.
* - It is suitable when only one flag checking is needed (most I2C events
* are monitored through multiple flags).
* - Limitations:
* - When calling this function, the Status register is accessed. Some flags are
* cleared when the status register is accessed. So checking the status
* of one Flag, may clear other ones.
* - Function may need to be called twice or more in order to monitor one
* single event.
*
*/
/**
*
* 1) Basic state monitoring
*******************************************************************************
*/
ErrorStatus I2C_CheckEvent(I2C_Event_TypeDef I2C_Event);
/**
*
* 2) Advanced state monitoring
*******************************************************************************
*/
I2C_Event_TypeDef I2C_GetLastEvent(void);
/**
*
* 3) Flag-based state monitoring
*******************************************************************************
*/
FlagStatus I2C_GetFlagStatus(I2C_Flag_TypeDef I2C_Flag);
/**
*
*******************************************************************************
*/
void I2C_ClearFlag(I2C_Flag_TypeDef I2C_FLAG);
ITStatus I2C_GetITStatus(I2C_ITPendingBit_TypeDef I2C_ITPendingBit);
void I2C_ClearITPendingBit(I2C_ITPendingBit_TypeDef I2C_ITPendingBit);
/**
* @}
*/
#endif /* __STM8S_I2C_H */
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