rt-thread/bsp/imxrt/libraries/MIMXRT1020/MIMXRT1021/drivers/fsl_ocotp.h

212 lines
7.5 KiB
C

/*
* Copyright 2019-2020 NXP
* All rights reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
#ifndef _FSL_OCOTP_H_
#define _FSL_OCOTP_H_
#include "fsl_common.h"
/*!
* @addtogroup ocotp
* @{
*/
/*******************************************************************************
* Definitions
*******************************************************************************/
/*! @name Driver version */
/*@{*/
/*! @brief OCOTP driver version. */
#define FSL_OCOTP_DRIVER_VERSION (MAKE_VERSION(2, 1, 3))
/*@}*/
#ifndef OCOTP_READ_FUSE_DATA_COUNT
#define OCOTP_READ_FUSE_DATA_COUNT (1U)
#endif
/*! @brief _ocotp_status Error codes for the OCOTP driver. */
enum
{
kStatus_OCOTP_AccessError = MAKE_STATUS(kStatusGroup_SDK_OCOTP, 0), /*!< eFuse and shadow register access error. */
kStatus_OCOTP_CrcFail = MAKE_STATUS(kStatusGroup_SDK_OCOTP, 1), /*!< CRC check failed. */
kStatus_OCOTP_ReloadError =
MAKE_STATUS(kStatusGroup_SDK_OCOTP, 2), /*!< Error happens during reload shadow register. */
kStatus_OCOTP_ProgramFail = MAKE_STATUS(kStatusGroup_SDK_OCOTP, 3), /*!< Fuse programming failed. */
kStatus_OCOTP_Locked = MAKE_STATUS(kStatusGroup_SDK_OCOTP, 4), /*!< Fuse is locked and cannot be programmed. */
};
#if (defined(FSL_FEATURE_OCOTP_HAS_TIMING_CTRL) && FSL_FEATURE_OCOTP_HAS_TIMING_CTRL)
/*! @brief OCOTP timing structure.
* Note that, these value are used for calcalating the read/write timings.
* And the values should statisfy below rules:
*
* Tsp_rd=(WAIT+1)/ipg_clk_freq should be >= 150ns;
* Tsp_pgm=(RELAX+1)/ipg_clk_freq should be >= 100ns;
* Trd = ((STROBE_READ+1)- 2*(RELAX_READ+1)) /ipg_clk_freq,
* The Trd is required to be larger than 40 ns.
* Tpgm = ((STROBE_PROG+1)- 2*(RELAX_PROG+1)) /ipg_clk_freq;
* The Tpgm should be configured within the range of 9000 ns < Tpgm < 11000 ns;
*/
typedef struct _ocotp_timing
{
uint32_t wait; /*!< Wait time value to fill in the TIMING register. */
uint32_t relax; /*!< Relax time value to fill in the TIMING register. */
uint32_t strobe_prog; /*!< Storbe program time value to fill in the TIMING register. */
uint32_t strobe_read; /*!< Storbe read time value to fill in the TIMING register. */
} ocotp_timing_t;
#endif /* FSL_FEATURE_OCOTP_HAS_TIMING_CTRL */
/*******************************************************************************
* API
*******************************************************************************/
#if defined(__cplusplus)
extern "C" {
#endif
/*!
* @brief Initializes OCOTP controller.
*
* @param base OCOTP peripheral base address.
* @param srcClock_Hz source clock frequency in unit of Hz. When the macro
* FSL_FEATURE_OCOTP_HAS_TIMING_CTRL is defined as 0, this parameter is not used,
* application could pass in 0 in this case.
*/
void OCOTP_Init(OCOTP_Type *base, uint32_t srcClock_Hz);
/*!
* @brief De-initializes OCOTP controller.
*
* @retval kStatus_Success upon successful execution, error status otherwise.
*/
void OCOTP_Deinit(OCOTP_Type *base);
/*!
* @brief Checking the BUSY bit in CTRL register.
* Checking this BUSY bit will help confirm if the OCOTP controller is ready for access.
*
* @param base OCOTP peripheral base address.
* @retval true for bit set and false for cleared.
*/
static inline bool OCOTP_CheckBusyStatus(OCOTP_Type *base)
{
return ((OCOTP_CTRL_BUSY_MASK == (base->CTRL & OCOTP_CTRL_BUSY_MASK)) ? (true) : (false));
}
/*!
* @brief Checking the ERROR bit in CTRL register.
*
* @param base OCOTP peripheral base address.
* @retval true for bit set and false for cleared.
*/
static inline bool OCOTP_CheckErrorStatus(OCOTP_Type *base)
{
return ((OCOTP_CTRL_ERROR_MASK == (base->CTRL & OCOTP_CTRL_ERROR_MASK)) ? (true) : (false));
}
/*!
* @brief Clear the error bit if this bit is set.
*
* @param base OCOTP peripheral base address.
*/
static inline void OCOTP_ClearErrorStatus(OCOTP_Type *base)
{
base->CTRL_CLR = OCOTP_CTRL_CLR_ERROR_MASK;
}
/*!
* @brief Reload the shadow register.
* This function will help reload the shadow register without reseting the OCOTP module.
* Please make sure the OCOTP has been initialized before calling this API.
*
* @param base OCOTP peripheral base addess.
* @retval kStatus_Success Reload success.
* @retval kStatus_OCOTP_ReloadError Reload failed.
*/
status_t OCOTP_ReloadShadowRegister(OCOTP_Type *base);
/*!
* @brief Read the fuse shadow register with the fuse addess.
*
* @deprecated Use @ref OCOTP_ReadFuseShadowRegisterExt instead of this function.
*
* @param base OCOTP peripheral base address.
* @param address the fuse address to be read from.
* @return The read out data.
*/
uint32_t OCOTP_ReadFuseShadowRegister(OCOTP_Type *base, uint32_t address);
/*!
* @brief Read the fuse shadow register from the fuse addess.
*
* This function reads fuse from @p address, how many words to read is specified
* by the parameter @p fuseWords. This function could read at most
* OCOTP_READ_FUSE_DATA_COUNT fuse word one time.
*
* @param base OCOTP peripheral base address.
* @param address the fuse address to be read from.
* @param data Data array to save the readout fuse value.
* @param fuseWords How many words to read.
* @retval kStatus_Success Read success.
* @retval kStatus_Fail Error occurs during read.
*/
status_t OCOTP_ReadFuseShadowRegisterExt(OCOTP_Type *base, uint32_t address, uint32_t *data, uint8_t fuseWords);
/*!
* @brief Write the fuse shadow register with the fuse addess and data.
* Please make sure the wrtie address is not locked while calling this API.
*
* @param base OCOTP peripheral base address.
* @param address the fuse address to be written.
* @param data the value will be writen to fuse address.
* @retval write status, kStatus_Success for success and kStatus_Fail for failed.
*/
status_t OCOTP_WriteFuseShadowRegister(OCOTP_Type *base, uint32_t address, uint32_t data);
/*!
* @brief Write the fuse shadow register and lock it.
*
* Please make sure the wrtie address is not locked while calling this API.
*
* Some OCOTP controller supports ECC mode and redundancy mode (see reference mananual
* for more details). OCOTP controller will auto select ECC or redundancy
* mode to program the fuse word according to fuse map definition. In ECC mode, the
* 32 fuse bits in one word can only be written once. In redundancy mode, the word can
* be written more than once as long as they are different fuse bits. Set parameter
* @p lock as true to force use ECC mode.
*
* @param base OCOTP peripheral base address.
* @param address The fuse address to be written.
* @param data The value will be writen to fuse address.
* @param lock Lock or unlock write fuse shadow register operation.
* @retval kStatus_Success Program and reload success.
* @retval kStatus_OCOTP_Locked The eFuse word is locked and cannot be programmed.
* @retval kStatus_OCOTP_ProgramFail eFuse word programming failed.
* @retval kStatus_OCOTP_ReloadError eFuse word programming success, but
* error happens during reload the values.
* @retval kStatus_OCOTP_AccessError Cannot access eFuse word.
*/
status_t OCOTP_WriteFuseShadowRegisterWithLock(OCOTP_Type *base, uint32_t address, uint32_t data, bool lock);
/*!
* @brief Get the OCOTP controller version from the register.
*
* @param base OCOTP peripheral base address.
* @retval return the version value.
*/
static inline uint32_t OCOTP_GetVersion(OCOTP_Type *base)
{
return (base->VERSION);
}
#if defined(__cplusplus)
}
#endif
/*! @}*/
#endif /* _FSL_OCOTP_H_ */