/* * Copyright (c) 2016, Freescale Semiconductor, Inc. * Copyright 2017-2022, NXP * All rights reserved. * * SPDX-License-Identifier: BSD-3-Clause */ #ifndef _FSL_SNVS_HP_H_ #define _FSL_SNVS_HP_H_ #include "fsl_common.h" /*! * @addtogroup snvs_hp * @{ */ /******************************************************************************* * Definitions ******************************************************************************/ /*! @name Driver version */ /*@{*/ #define FSL_SNVS_HP_DRIVER_VERSION (MAKE_VERSION(2, 3, 2)) /*!< Version 2.3.2 */ /*@}*/ /*! @brief List of SNVS interrupts */ typedef enum _snvs_hp_interrupts { kSNVS_RTC_AlarmInterrupt = SNVS_HPCR_HPTA_EN_MASK, /*!< RTC time alarm */ kSNVS_RTC_PeriodicInterrupt = SNVS_HPCR_PI_EN_MASK, /*!< RTC periodic interrupt */ } snvs_hp_interrupts_t; /*! @brief List of SNVS flags */ typedef enum _snvs_hp_status_flags { kSNVS_RTC_AlarmInterruptFlag = SNVS_HPSR_HPTA_MASK, /*!< RTC time alarm flag */ kSNVS_RTC_PeriodicInterruptFlag = SNVS_HPSR_PI_MASK, /*!< RTC periodic interrupt flag */ kSNVS_ZMK_ZeroFlag = (int)SNVS_HPSR_ZMK_ZERO_MASK, /*!< The ZMK is zero */ kSNVS_OTPMK_ZeroFlag = SNVS_HPSR_OTPMK_ZERO_MASK, /*!< The OTPMK is zero */ } snvs_hp_status_flags_t; /* Re-map Security Violation for RT11xx specific violation*/ #ifndef SNVS_HPSVSR_SV0_MASK #define SNVS_HPSVSR_SV0_MASK SNVS_HPSVSR_CAAM_MASK #endif #ifndef SNVS_HPSVSR_SV1_MASK #define SNVS_HPSVSR_SV1_MASK SNVS_HPSVSR_JTAGC_MASK #endif #ifndef SNVS_HPSVSR_SV2_MASK #define SNVS_HPSVSR_SV2_MASK SNVS_HPSVSR_WDOG2_MASK #endif #ifndef SNVS_HPSVSR_SV4_MASK #define SNVS_HPSVSR_SV4_MASK SNVS_HPSVSR_SRC_MASK #endif #ifndef SNVS_HPSVSR_SV5_MASK #define SNVS_HPSVSR_SV5_MASK SNVS_HPSVSR_OCOTP_MASK #endif /*! @brief List of SNVS security violation flags */ typedef enum _snvs_hp_sv_status_flags { kSNVS_LP_ViolationFlag = SNVS_HPSVSR_SW_LPSV_MASK, /*!< Low Power section Security Violation */ kSNVS_ZMK_EccFailFlag = SNVS_HPSVSR_ZMK_ECC_FAIL_MASK, /*!< Zeroizable Master Key Error Correcting Code Check Failure */ kSNVS_LP_SoftwareViolationFlag = SNVS_HPSVSR_SW_LPSV_MASK, /*!< LP Software Security Violation */ kSNVS_FatalSoftwareViolationFlag = SNVS_HPSVSR_SW_FSV_MASK, /*!< Software Fatal Security Violation */ kSNVS_SoftwareViolationFlag = SNVS_HPSVSR_SW_SV_MASK, /*!< Software Security Violation */ kSNVS_Violation0Flag = SNVS_HPSVSR_SV0_MASK, /*!< Security Violation 0 */ kSNVS_Violation1Flag = SNVS_HPSVSR_SV1_MASK, /*!< Security Violation 1 */ kSNVS_Violation2Flag = SNVS_HPSVSR_SV2_MASK, /*!< Security Violation 2 */ #if defined(SNVS_HPSVSR_SV3_MASK) kSNVS_Violation3Flag = SNVS_HPSVSR_SV3_MASK, /*!< Security Violation 3 */ #endif /* SNVS_HPSVSR_SV3_MASK */ kSNVS_Violation4Flag = SNVS_HPSVSR_SV4_MASK, /*!< Security Violation 4 */ kSNVS_Violation5Flag = SNVS_HPSVSR_SV5_MASK, /*!< Security Violation 5 */ } snvs_hp_sv_status_flags_t; /*! * @brief Macro to make security violation flag * * Macro help to make security violation flag kSNVS_Violation0Flag to kSNVS_Violation5Flag, * For example, SNVS_MAKE_HP_SV_FLAG(0) is kSNVS_Violation0Flag. */ #define SNVS_MAKE_HP_SV_FLAG(x) (1U << (SNVS_HPSVSR_SV0_SHIFT + (x))) /*! @brief Structure is used to hold the date and time */ typedef struct _snvs_hp_rtc_datetime { uint16_t year; /*!< Range from 1970 to 2099.*/ uint8_t month; /*!< Range from 1 to 12.*/ uint8_t day; /*!< Range from 1 to 31 (depending on month).*/ uint8_t hour; /*!< Range from 0 to 23.*/ uint8_t minute; /*!< Range from 0 to 59.*/ uint8_t second; /*!< Range from 0 to 59.*/ } snvs_hp_rtc_datetime_t; /*! * @brief SNVS config structure * * This structure holds the configuration settings for the SNVS peripheral. To initialize this * structure to reasonable defaults, call the SNVS_GetDefaultConfig() function and pass a * pointer to your config structure instance. * * The config struct can be made const so it resides in flash */ typedef struct _snvs_hp_rtc_config { bool rtcCalEnable; /*!< true: RTC calibration mechanism is enabled; false:No calibration is used */ uint32_t rtcCalValue; /*!< Defines signed calibration value for nonsecure RTC; This is a 5-bit 2's complement value, range from -16 to +15 */ uint32_t periodicInterruptFreq; /*!< Defines frequency of the periodic interrupt; Range from 0 to 15 */ } snvs_hp_rtc_config_t; /*! @brief List of SNVS Security State Machine State */ typedef enum _snvs_hp_ssm_state { kSNVS_SSMInit = 0x00, /*!< Init */ kSNVS_SSMHardFail = 0x01, /*!< Hard Fail */ kSNVS_SSMSoftFail = 0x03, /*!< Soft Fail */ kSNVS_SSMInitInter = 0x08, /*!< Init Intermediate (transition state between Init and Check) */ kSNVS_SSMCheck = 0x09, /*!< Check */ kSNVS_SSMNonSecure = 0x0B, /*!< Non-Secure */ kSNVS_SSMTrusted = 0x0D, /*!< Trusted */ kSNVS_SSMSecure = 0x0F, /*!< Secure */ } snvs_hp_ssm_state_t; /******************************************************************************* * API ******************************************************************************/ #if defined(__cplusplus) extern "C" { #endif /*! * @name Initialization and deinitialization * @{ */ /*! * @brief Initialize the SNVS. * * @note This API should be called at the beginning of the application using the SNVS driver. * * @param base SNVS peripheral base address */ void SNVS_HP_Init(SNVS_Type *base); /*! * @brief Deinitialize the SNVS. * * @param base SNVS peripheral base address */ void SNVS_HP_Deinit(SNVS_Type *base); /*! * @brief Ungates the SNVS clock and configures the peripheral for basic operation. * * @note This API should be called at the beginning of the application using the SNVS driver. * * @param base SNVS peripheral base address * @param config Pointer to the user's SNVS configuration structure. */ void SNVS_HP_RTC_Init(SNVS_Type *base, const snvs_hp_rtc_config_t *config); /*! * @brief Stops the RTC and SRTC timers. * * @param base SNVS peripheral base address */ void SNVS_HP_RTC_Deinit(SNVS_Type *base); /*! * @brief Fills in the SNVS config struct with the default settings. * * The default values are as follows. * @code * config->rtccalenable = false; * config->rtccalvalue = 0U; * config->PIFreq = 0U; * @endcode * @param config Pointer to the user's SNVS configuration structure. */ void SNVS_HP_RTC_GetDefaultConfig(snvs_hp_rtc_config_t *config); /*! @}*/ /*! * @name Non secure RTC current Time & Alarm * @{ */ /*! * @brief Sets the SNVS RTC date and time according to the given time structure. * * @param base SNVS peripheral base address * @param datetime Pointer to the structure where the date and time details are stored. * * @return kStatus_Success: Success in setting the time and starting the SNVS RTC * kStatus_InvalidArgument: Error because the datetime format is incorrect */ status_t SNVS_HP_RTC_SetDatetime(SNVS_Type *base, const snvs_hp_rtc_datetime_t *datetime); /*! * @brief Gets the SNVS RTC time and stores it in the given time structure. * * @param base SNVS peripheral base address * @param datetime Pointer to the structure where the date and time details are stored. */ void SNVS_HP_RTC_GetDatetime(SNVS_Type *base, snvs_hp_rtc_datetime_t *datetime); /*! * @brief Sets the SNVS RTC alarm time. * * The function sets the RTC alarm. It also checks whether the specified alarm time * is greater than the present time. If not, the function does not set the alarm * and returns an error. * * @param base SNVS peripheral base address * @param alarmTime Pointer to the structure where the alarm time is stored. * * @return kStatus_Success: success in setting the SNVS RTC alarm * kStatus_InvalidArgument: Error because the alarm datetime format is incorrect * kStatus_Fail: Error because the alarm time has already passed */ status_t SNVS_HP_RTC_SetAlarm(SNVS_Type *base, const snvs_hp_rtc_datetime_t *alarmTime); /*! * @brief Returns the SNVS RTC alarm time. * * @param base SNVS peripheral base address * @param datetime Pointer to the structure where the alarm date and time details are stored. */ void SNVS_HP_RTC_GetAlarm(SNVS_Type *base, snvs_hp_rtc_datetime_t *datetime); #if (defined(FSL_FEATURE_SNVS_HAS_SRTC) && (FSL_FEATURE_SNVS_HAS_SRTC > 0)) /*! * @brief The function synchronizes RTC counter value with SRTC. * * @param base SNVS peripheral base address */ void SNVS_HP_RTC_TimeSynchronize(SNVS_Type *base); #endif /* FSL_FEATURE_SNVS_HAS_SRTC */ /*! @}*/ /*! * @name Interrupt Interface * @{ */ /*! * @brief Enables the selected SNVS interrupts. * * @param base SNVS peripheral base address * @param mask The interrupts to enable. This is a logical OR of members of the * enumeration :: _snvs_hp_interrupts_t */ static inline void SNVS_HP_RTC_EnableInterrupts(SNVS_Type *base, uint32_t mask) { base->HPCR |= mask; } /*! * @brief Disables the selected SNVS interrupts. * * @param base SNVS peripheral base address * @param mask The interrupts to disable. This is a logical OR of members of the * enumeration :: _snvs_hp_interrupts_t */ static inline void SNVS_HP_RTC_DisableInterrupts(SNVS_Type *base, uint32_t mask) { base->HPCR &= ~mask; } /*! * @brief Gets the enabled SNVS interrupts. * * @param base SNVS peripheral base address * * @return The enabled interrupts. This is the logical OR of members of the * enumeration :: _snvs_hp_interrupts_t */ uint32_t SNVS_HP_RTC_GetEnabledInterrupts(SNVS_Type *base); /*! @}*/ /*! * @name Status Interface * @{ */ /*! * @brief Gets the SNVS status flags. * * @param base SNVS peripheral base address * * @return The status flags. This is the logical OR of members of the * enumeration :: _snvs_hp_status_flags_t */ uint32_t SNVS_HP_RTC_GetStatusFlags(SNVS_Type *base); /*! * @brief Clears the SNVS status flags. * * @param base SNVS peripheral base address * @param mask The status flags to clear. This is a logical OR of members of the * enumeration :: _snvs_hp_status_flags_t */ static inline void SNVS_HP_RTC_ClearStatusFlags(SNVS_Type *base, uint32_t mask) { base->HPSR |= mask; } /*! @}*/ /*! * @name Timer Start and Stop * @{ */ /*! * @brief Starts the SNVS RTC time counter. * * @param base SNVS peripheral base address */ static inline void SNVS_HP_RTC_StartTimer(SNVS_Type *base) { base->HPCR |= SNVS_HPCR_RTC_EN_MASK; while (0U == (base->HPCR & SNVS_HPCR_RTC_EN_MASK)) { } } /*! * @brief Stops the SNVS RTC time counter. * * @param base SNVS peripheral base address */ static inline void SNVS_HP_RTC_StopTimer(SNVS_Type *base) { base->HPCR &= ~SNVS_HPCR_RTC_EN_MASK; while ((base->HPCR & SNVS_HPCR_RTC_EN_MASK) != 0U) { } } /*! @}*/ /*! * @brief Enable or disable master key selection. * * @param base SNVS peripheral base address * @param enable Pass true to enable, false to disable. */ static inline void SNVS_HP_EnableMasterKeySelection(SNVS_Type *base, bool enable) { if (enable) { base->HPCOMR |= SNVS_HPCOMR_MKS_EN_MASK; } else { base->HPCOMR &= (~SNVS_HPCOMR_MKS_EN_MASK); } } /*! * @brief Trigger to program Zeroizable Master Key. * * @param base SNVS peripheral base address */ static inline void SNVS_HP_ProgramZeroizableMasterKey(SNVS_Type *base) { base->HPCOMR |= SNVS_HPCOMR_PROG_ZMK_MASK; } /*! * @brief Trigger SSM State Transition * * Trigger state transition of the system security monitor (SSM). It results only * the following transitions of the SSM: * - Check State -> Non-Secure (when Non-Secure Boot and not in Fab Configuration) * - Check State --> Trusted (when Secure Boot or in Fab Configuration ) * - Trusted State --> Secure * - Secure State --> Trusted * - Soft Fail --> Non-Secure * * @param base SNVS peripheral base address */ static inline void SNVS_HP_ChangeSSMState(SNVS_Type *base) { base->HPCOMR |= SNVS_HPCOMR_SSM_ST_MASK; } /*! * @brief Trigger Software Fatal Security Violation * * The result SSM state transition is: * - Check State -> Soft Fail * - Non-Secure State -> Soft Fail * - Trusted State -> Soft Fail * - Secure State -> Soft Fail * * @param base SNVS peripheral base address */ static inline void SNVS_HP_SetSoftwareFatalSecurityViolation(SNVS_Type *base) { base->HPCOMR |= SNVS_HPCOMR_SW_FSV_MASK; } /*! * @brief Trigger Software Security Violation * * The result SSM state transition is: * - Check -> Non-Secure * - Trusted -> Soft Fail * - Secure -> Soft Fail * * @param base SNVS peripheral base address */ static inline void SNVS_HP_SetSoftwareSecurityViolation(SNVS_Type *base) { base->HPCOMR |= SNVS_HPCOMR_SW_SV_MASK; } /*! * @brief Get current SSM State * * @param base SNVS peripheral base address * @return Current SSM state */ static inline snvs_hp_ssm_state_t SNVS_HP_GetSSMState(SNVS_Type *base) { return (snvs_hp_ssm_state_t)((uint32_t)((base->HPSR & SNVS_HPSR_SSM_STATE_MASK) >> SNVS_HPSR_SSM_STATE_SHIFT)); } /*! * @brief Reset the SNVS LP section. * * Reset the LP section except SRTC and Time alarm. * * @param base SNVS peripheral base address */ static inline void SNVS_HP_ResetLP(SNVS_Type *base) { base->HPCOMR |= SNVS_HPCOMR_LP_SWR_MASK; } /*! * @name High Assurance Counter (HAC) * @{ */ /*! * @brief Enable or disable the High Assurance Counter (HAC) * * @param base SNVS peripheral base address * @param enable Pass true to enable, false to disable. */ static inline void SNVS_HP_EnableHighAssuranceCounter(SNVS_Type *base, bool enable) { if (enable) { base->HPCOMR |= SNVS_HPCOMR_HAC_EN_MASK; } else { base->HPCOMR &= (~SNVS_HPCOMR_HAC_EN_MASK); } } /*! * @brief Start or stop the High Assurance Counter (HAC) * * @param base SNVS peripheral base address * @param start Pass true to start, false to stop. */ static inline void SNVS_HP_StartHighAssuranceCounter(SNVS_Type *base, bool start) { if (start) { base->HPCOMR &= (~SNVS_HPCOMR_HAC_STOP_MASK); } else { base->HPCOMR |= SNVS_HPCOMR_HAC_STOP_MASK; } } /*! * @brief Set the High Assurance Counter (HAC) initialize value. * * @param base SNVS peripheral base address * @param value The initial value to set. */ static inline void SNVS_HP_SetHighAssuranceCounterInitialValue(SNVS_Type *base, uint32_t value) { base->HPHACIVR = value; } /*! * @brief Load the High Assurance Counter (HAC) * * This function loads the HAC initialize value to counter register. * * @param base SNVS peripheral base address */ static inline void SNVS_HP_LoadHighAssuranceCounter(SNVS_Type *base) { base->HPCOMR |= SNVS_HPCOMR_HAC_LOAD_MASK; } /*! * @brief Get the current High Assurance Counter (HAC) value * * @param base SNVS peripheral base address * @return HAC currnet value. */ static inline uint32_t SNVS_HP_GetHighAssuranceCounter(SNVS_Type *base) { return base->HPHACR; } /*! * @brief Clear the High Assurance Counter (HAC) * * This function can be called in a functional or soft fail state. When the HAC * is enabled: * - If the HAC is cleared in the soft fail state, the SSM transitions to the * hard fail state immediately; * - If the HAC is cleared in functional state, the SSM will transition to * hard fail immediately after transitioning to soft fail. * * @param base SNVS peripheral base address */ static inline void SNVS_HP_ClearHighAssuranceCounter(SNVS_Type *base) { base->HPCOMR |= SNVS_HPCOMR_HAC_CLEAR_MASK; } /*! * @brief Lock the High Assurance Counter (HAC) * * Once locked, the HAC initialize value could not be changed, the HAC enable * status could not be changed. This could only be unlocked by system reset. * * @param base SNVS peripheral base address */ static inline void SNVS_HP_LockHighAssuranceCounter(SNVS_Type *base) { base->HPLR |= SNVS_HPLR_HAC_L_MASK; } /*! @}*/ /*! * @brief Get the SNVS HP status flags. * * The flags are returned as the OR'ed value f the * enumeration :: _snvs_hp_status_flags_t. * * @param base SNVS peripheral base address * @return The OR'ed value of status flags. */ static inline uint32_t SNVS_HP_GetStatusFlags(SNVS_Type *base) { return base->HPSR; } /*! * @brief Clear the SNVS HP status flags. * * The flags to clear are passed in as the OR'ed value of the * enumeration :: _snvs_hp_status_flags_t. * Only these flags could be cleared using this API. * - @ref kSNVS_RTC_PeriodicInterruptFlag * - @ref kSNVS_RTC_AlarmInterruptFlag * * @param base SNVS peripheral base address * @param mask OR'ed value of the flags to clear. */ static inline void SNVS_HP_ClearStatusFlags(SNVS_Type *base, uint32_t mask) { base->HPSR = mask; } /*! * @brief Get the SNVS HP security violation status flags. * * The flags are returned as the OR'ed value of the * enumeration :: _snvs_hp_sv_status_flags_t. * * @param base SNVS peripheral base address * @return The OR'ed value of security violation status flags. */ static inline uint32_t SNVS_HP_GetSecurityViolationStatusFlags(SNVS_Type *base) { return base->HPSVSR; } /*! * @brief Clear the SNVS HP security violation status flags. * * The flags to clear are passed in as the OR'ed value of the * enumeration :: _snvs_hp_sv_status_flags_t. * Only these flags could be cleared using this API. * * - @ref kSNVS_ZMK_EccFailFlag * - @ref kSNVS_Violation0Flag * - @ref kSNVS_Violation1Flag * - @ref kSNVS_Violation2Flag * - kSNVS_Violation3Flag * - @ref kSNVS_Violation4Flag * - @ref kSNVS_Violation5Flag * * @param base SNVS peripheral base address * @param mask OR'ed value of the flags to clear. */ static inline void SNVS_HP_ClearSecurityViolationStatusFlags(SNVS_Type *base, uint32_t mask) { base->HPSVSR = mask; } #if defined(FSL_FEATURE_SNVS_HAS_SET_LOCK) && (FSL_FEATURE_SNVS_HAS_SET_LOCK > 0) /*! * brief Set SNVS HP Set locks. * * param base SNVS peripheral base address * */ void SNVS_HP_SetLocks(SNVS_Type *base); #endif /* FSL_FEATURE_SNVS_HAS_SET_LOCK */ #if defined(__cplusplus) } #endif /*! @}*/ #endif /* _FSL_SNVS_HP_H_ */