/* * Copyright 2013-2016 Freescale Semiconductor, Inc. * Copyright 2016-2020 NXP * All rights reserved. * * SPDX-License-Identifier: BSD-3-Clause * */ #include "fsl_ftfx_flash.h" /******************************************************************************* * Definitions ******************************************************************************/ /* Component ID definition, used by tools. */ #ifndef FSL_COMPONENT_ID #define FSL_COMPONENT_ID "platform.drivers.flash" #endif /*! * @brief Enumeration for special memory property. */ enum _ftfx_special_mem_property { kFTFx_AccessSegmentUnitSize = 256UL, kFTFx_MinProtectBlockSize = 1024UL, }; #if defined(FSL_FEATURE_FLASH_HAS_SWAP_CONTROL_CMD) && FSL_FEATURE_FLASH_HAS_SWAP_CONTROL_CMD /*! * @brief Enumeration for the index of read/program once record */ enum _k3_flash_read_once_index { kFLASH_RecordIndexSwapAddr = 0xA1U, /*!< Index of Swap indicator address.*/ kFLASH_RecordIndexSwapEnable = 0xA2U, /*!< Index of Swap system enable.*/ kFLASH_RecordIndexSwapDisable = 0xA3U, /*!< Index of Swap system disable.*/ }; #endif /* FSL_FEATURE_FLASH_HAS_SWAP_CONTROL_CMD */ /******************************************************************************* * Prototypes ******************************************************************************/ /*! @brief init flash features */ static void flash_init_features(ftfx_config_t *config); /*! @brief init protection feature */ static void flash_protection_init(flash_config_t *config, uint8_t flashIndex); /*! @brief init access segment feature */ #if defined(FSL_FEATURE_FLASH_HAS_ACCESS_CONTROL) && FSL_FEATURE_FLASH_HAS_ACCESS_CONTROL static void flash_access_init(flash_config_t *config, uint8_t flashIndex); #endif /*! @brief init flash operation config */ static void flash_opsonfig_Init(flash_config_t *config, uint8_t flashIndex); /*! @brief Calculate flash memory size based on given parameter */ static uint32_t flash_calculate_mem_size(uint32_t pflashBlockCount, uint32_t pflashBlockSize, uint32_t pfsizeMask, uint32_t pfsizeShift); static uint32_t flash_calculate_prot_segment_size(uint32_t flashSize, uint32_t segmentCount); /*! @brief Validates the given address to get current flash index */ static status_t flash_check_range_to_get_index(flash_config_t *config, uint32_t start, uint32_t lengthInBytes, uint8_t *flashIndex); /*! @brief Decide whether to convert the start address from primary flash to secondary flash based on the current start * address*/ static void flash_convert_start_address(ftfx_config_t *config, uint32_t start); #if defined(FSL_FEATURE_FLASH_HAS_PFLASH_BLOCK_SWAP) && FSL_FEATURE_FLASH_HAS_PFLASH_BLOCK_SWAP /*! @brief Validates the given address to see if it is equal to swap indicator address in pflash swap IFR.*/ static status_t flash_validate_swap_indicator_address(ftfx_config_t *config, uint32_t address); #endif /* FSL_FEATURE_FLASH_HAS_PFLASH_BLOCK_SWAP */ /******************************************************************************* * Variables ******************************************************************************/ static volatile uint32_t *const kFPROTL = (volatile uint32_t *)(uint32_t)&FTFx_FPROT_LOW_REG; #if defined(FTFx_FLASH0_HAS_HIGH_PROT_REG) && FTFx_FLASH0_HAS_HIGH_PROT_REG static volatile uint32_t *const kFPROTH = (volatile uint32_t *)(uint32_t)&FTFx_FPROT_HIGH_REG; #endif /* FTFx_FLASH0_HAS_HIGH_PROT_REG */ #if defined(FTFx_FLASH1_HAS_INT_PROT_REG) && FTFx_FLASH1_HAS_INT_PROT_REG volatile uint8_t *const kFPROTSL = (volatile uint8_t *)(uint32_t)&FTFx_FPROTSL_REG; volatile uint8_t *const kFPROTSH = (volatile uint8_t *)(uint32_t)&FTFx_FPROTSH_REG; #endif /* FTFx_FLASH1_HAS_INT_PROT_REG */ /*! * @brief Table of pflash sizes. * * The index into this table is the value of the SIM_FCFG1.PFSIZE bitfield. * * The values in this table have been right shifted 10 bits so that they will all fit within * an 16-bit integer. To get the actual flash density, you must left shift the looked up value * by 10 bits. * * Elements of this table have a value of 0 in cases where the PFSIZE bitfield value is * reserved. * * Code to use the table: * @code * uint8_t pfsize = (SIM->FCFG1 & SIM_FCFG1_PFSIZE_MASK) >> SIM_FCFG1_PFSIZE_SHIFT; * flashDensity = ((uint32_t)kPFlashDensities[pfsize]) << 10; * @endcode */ #if defined(FSL_FEATURE_FLASH_SIZE_ENCODING_RULE_VERSION) && (FSL_FEATURE_FLASH_SIZE_ENCODING_RULE_VERSION == 1) static const uint16_t kPFlashDensities[] = { 0u, /* 0x0 - undefined */ 0u, /* 0x1 - undefined */ 0u, /* 0x2 - undefined */ 0u, /* 0x3 - undefined */ 0u, /* 0x4 - undefined */ 0u, /* 0x5 - undefined */ 0u, /* 0x6 - undefined */ 0u, /* 0x7 - undefined */ 0u, /* 0x8 - undefined */ 0u, /* 0x9 - undefined */ 256u, /* 0xa - 262144, 256KB */ 0u, /* 0xb - undefined */ 1024u, /* 0xc - 1048576, 1MB */ 0u, /* 0xd - undefined */ 0u, /* 0xe - undefined */ 0u, /* 0xf - undefined */ }; #else static const uint16_t kPFlashDensities[] = { 8u, /* 0x0 - 8192, 8KB */ 16u, /* 0x1 - 16384, 16KB */ 24u, /* 0x2 - 24576, 24KB */ 32u, /* 0x3 - 32768, 32KB */ 48u, /* 0x4 - 49152, 48KB */ 64u, /* 0x5 - 65536, 64KB */ 96u, /* 0x6 - 98304, 96KB */ 128u, /* 0x7 - 131072, 128KB */ 192u, /* 0x8 - 196608, 192KB */ 256u, /* 0x9 - 262144, 256KB */ 384u, /* 0xa - 393216, 384KB */ 512u, /* 0xb - 524288, 512KB */ 768u, /* 0xc - 786432, 768KB */ 1024u, /* 0xd - 1048576, 1MB */ 1536u, /* 0xe - 1572864, 1.5MB */ /* 2048u, 0xf - 2097152, 2MB */ }; #endif /******************************************************************************* * Code ******************************************************************************/ /*! * @brief Initializes the global flash properties structure members. * * This function checks and initializes the Flash module for the other Flash APIs. * * @param config Pointer to the storage for the driver runtime state. * * @retval #kStatus_FTFx_Success API was executed successfully. * @retval #kStatus_FTFx_InvalidArgument An invalid argument is provided. * @retval #kStatus_FTFx_ExecuteInRamFunctionNotReady Execute-in-RAM function is not available. * @retval #kStatus_FTFx_PartitionStatusUpdateFailure Failed to update the partition status. */ status_t FLASH_Init(flash_config_t *config) { if (config == NULL) { return kStatus_FTFx_InvalidArgument; } for (uint8_t flashIndex = 0U; flashIndex < FTFx_FLASH_COUNT; flashIndex++) { /* init flash type, kinetis has Pflash and flxnvm, pflash is often used to store executable code * and flexnvm can be used as date flash to store user data, and can also be configured as eeprom backup space * with flexram. */ config->ftfxConfig[flashIndex].flashDesc.type = (uint8_t)kFTFx_MemTypePflash; /* init the current flash index */ config->ftfxConfig[flashIndex].flashDesc.index = flashIndex; /* init flash features */ flash_init_features(&config->ftfxConfig[flashIndex]); /* init flash Operation Config */ flash_opsonfig_Init(config, flashIndex); #if defined(FSL_FEATURE_FLASH_HAS_ACCESS_CONTROL) && FSL_FEATURE_FLASH_HAS_ACCESS_CONTROL if (0U != (config->ftfxConfig[flashIndex].flashDesc.feature.hasXaccControl)) { /* init access segment feature */ flash_access_init(config, flashIndex); } #endif /* FSL_FEATURE_FLASH_HAS_ACCESS_CONTROL */ #if (FTFx_FLASH_COUNT > 1U) if (0U != (config->ftfxConfig[flashIndex].flashDesc.feature.hasProtControl)) #endif { /* init protection feature */ flash_protection_init(config, flashIndex); } /* Init FTFx Kernel */ FTFx_API_Init(&config->ftfxConfig[flashIndex]); } return kStatus_FTFx_Success; } /*! * @brief Erases the Dflash sectors encompassed by parameters passed into function. * * This function erases the appropriate number of flash sectors based on the * desired start address and length. * * @param config The pointer to the storage for the driver runtime state. * @param start The start address of the desired flash memory to be erased. * The start address does not need to be sector-aligned but must be word-aligned. * @param lengthInBytes The length, given in bytes (not words or long-words) * to be erased. Must be word-aligned. * @param key The value used to validate all flash erase APIs. * * @retval #kStatus_FTFx_Success API was executed successfully; the appropriate number of flash sectors based on the * desired start address and length was erased successfully. * * @retval #kStatus_FTFx_InvalidArgument An invalid argument is provided. * @retval #kStatus_FTFx_AlignmentError The parameter is not aligned with the specified baseline. * @retval #kStatus_FTFx_AddressError The address is out of range. * @retval #kStatus_FTFx_EraseKeyError The API erase key is invalid. * @retval #kStatus_FTFx_ExecuteInRamFunctionNotReady Execute-in-RAM function is not available. * @retval #kStatus_FTFx_AccessError Invalid instruction codes and out-of bounds addresses. * @retval #kStatus_FTFx_ProtectionViolation The program/erase operation is requested to execute on protected areas. * @retval #kStatus_FTFx_CommandFailure Run-time error during the command execution. */ status_t FLASH_Erase(flash_config_t *config, uint32_t start, uint32_t lengthInBytes, uint32_t key) { status_t returnCode; uint8_t flashIndex; /* check the supplied address range to get flash index */ returnCode = flash_check_range_to_get_index(config, start, lengthInBytes, &flashIndex); if (returnCode != kStatus_FTFx_Success) { return returnCode; } /* Decide whether to convert the start address from primary flash to secondary flash based on the current address */ flash_convert_start_address(&config->ftfxConfig[flashIndex], start); return FTFx_CMD_Erase(&config->ftfxConfig[flashIndex], start, lengthInBytes, key); } /*! * @brief Erases the Dflash sectors encompassed by parameters passed into function. * * This function erases one flash sector size based on the start address, and it is * executed asynchronously. */ status_t FLASH_EraseSectorNonBlocking(flash_config_t *config, uint32_t start, uint32_t key) { status_t returnCode; uint8_t flashIndex; uint32_t lengthInBytes = FSL_FEATURE_FLASH_PFLASH_BLOCK_SECTOR_SIZE; /* check the supplied address range to get flash index */ returnCode = flash_check_range_to_get_index(config, start, lengthInBytes, &flashIndex); if (returnCode != kStatus_FTFx_Success) { return returnCode; } /* Decide whether to convert the start address from primary flash to secondary flash based on the current address */ flash_convert_start_address(&config->ftfxConfig[flashIndex], start); return FTFx_CMD_EraseSectorNonBlocking(&config->ftfxConfig[flashIndex], start, key); } /*! * @brief Erases entire flexnvm */ status_t FLASH_EraseAll(flash_config_t *config, uint32_t key) { return FTFx_CMD_EraseAll(&config->ftfxConfig[0], key); } #if defined(FSL_FEATURE_FLASH_HAS_ERASE_ALL_BLOCKS_UNSECURE_CMD) && FSL_FEATURE_FLASH_HAS_ERASE_ALL_BLOCKS_UNSECURE_CMD /*! * @brief Erases the entire flexnvm, including protected sectors. */ status_t FLASH_EraseAllUnsecure(flash_config_t *config, uint32_t key) { return FTFx_CMD_EraseAllUnsecure(&config->ftfxConfig[0], key); } #endif /*! * @brief Programs flash with data at locations passed in through parameters. * * This function programs the flash memory with the desired data for a given * flash area as determined by the start address and the length. */ status_t FLASH_Program(flash_config_t *config, uint32_t start, uint8_t *src, uint32_t lengthInBytes) { status_t returnCode; uint8_t flashIndex; /* check range to get flash index */ returnCode = flash_check_range_to_get_index(config, start, lengthInBytes, &flashIndex); if (returnCode != kStatus_FTFx_Success) { return returnCode; } /* convert the start address from primary flash to secondary flash based on the current address */ flash_convert_start_address(&config->ftfxConfig[flashIndex], start); /* Programs flash */ return FTFx_CMD_Program(&config->ftfxConfig[flashIndex], start, src, lengthInBytes); } /*! * @brief Reads the Program Once Field through parameters. */ status_t FLASH_ProgramOnce(flash_config_t *config, uint32_t index, uint8_t *src, uint32_t lengthInBytes) { return FTFx_CMD_ProgramOnce(&config->ftfxConfig[0], index, src, lengthInBytes); } #if defined(FSL_FEATURE_FLASH_HAS_PROGRAM_SECTION_CMD) && FSL_FEATURE_FLASH_HAS_PROGRAM_SECTION_CMD /*! * @brief Programs flash with data at locations passed in through parameters via the Program Section command. * * This function programs the flash memory with the desired data for a given * flash area as determined by the start address and length. * */ status_t FLASH_ProgramSection(flash_config_t *config, uint32_t start, uint8_t *src, uint32_t lengthInBytes) { status_t returnCode; uint8_t flashIndex; /* Validates the range of the given address range and get flash index */ returnCode = flash_check_range_to_get_index(config, start, lengthInBytes, &flashIndex); if (returnCode != kStatus_FTFx_Success) { return returnCode; } /* convert the start address from primary flash to secondary flash based on the current address */ flash_convert_start_address(&config->ftfxConfig[flashIndex], start); return FTFx_CMD_ProgramSection(&config->ftfxConfig[flashIndex], start, src, lengthInBytes); } #endif #if defined(FSL_FEATURE_FLASH_HAS_READ_RESOURCE_CMD) && FSL_FEATURE_FLASH_HAS_READ_RESOURCE_CMD /*! * @brief Reads the resource with data at locations passed in through parameters. */ status_t FLASH_ReadResource( flash_config_t *config, uint32_t start, uint8_t *dst, uint32_t lengthInBytes, ftfx_read_resource_opt_t option) { return FTFx_CMD_ReadResource(&config->ftfxConfig[0], start, dst, lengthInBytes, option); } #endif /*! * @brief Reads the Program Once Field through parameters. */ status_t FLASH_ReadOnce(flash_config_t *config, uint32_t index, uint8_t *dst, uint32_t lengthInBytes) { return FTFx_CMD_ReadOnce(&config->ftfxConfig[0], index, dst, lengthInBytes); } /*! * @brief Verifies an erasure of the desired flash area at a specified margin level. * * This function checks the appropriate number of flash sectors based on * the desired start address and length to check whether the flash is erased * to the specified read margin level. */ status_t FLASH_VerifyErase(flash_config_t *config, uint32_t start, uint32_t lengthInBytes, ftfx_margin_value_t margin) { status_t returnCode; uint8_t flashIndex; /* check range to get flash index */ returnCode = flash_check_range_to_get_index(config, start, lengthInBytes, &flashIndex); if (returnCode != kStatus_FTFx_Success) { return returnCode; } /* convert the start address from primary flash to secondary flash based on the current start address*/ flash_convert_start_address(&config->ftfxConfig[flashIndex], start); return FTFx_CMD_VerifyErase(&config->ftfxConfig[flashIndex], start, lengthInBytes, margin); } /*! * @brief Verifies erasure of the entire flash at a specified margin level. */ status_t FLASH_VerifyEraseAll(flash_config_t *config, ftfx_margin_value_t margin) { return FTFx_CMD_VerifyEraseAll(&config->ftfxConfig[0], margin); } /*! * @brief Verifies programming of the desired flash area at a specified margin level. * * This function verifies the data programmed in the flash memory using the * Flash Program Check Command and compares it to the expected data for a given * flash area as determined by the start address and length. */ status_t FLASH_VerifyProgram(flash_config_t *config, uint32_t start, uint32_t lengthInBytes, const uint8_t *expectedData, ftfx_margin_value_t margin, uint32_t *failedAddress, uint32_t *failedData) { status_t returnCode; uint8_t flashIndex; /* Validates the given address to get current flash index */ returnCode = flash_check_range_to_get_index(config, start, lengthInBytes, &flashIndex); if (returnCode != kStatus_FTFx_Success) { return returnCode; } /* convert the start address from primary flash to secondary flash based on the current start address */ flash_convert_start_address(&config->ftfxConfig[flashIndex], start); return FTFx_CMD_VerifyProgram(&config->ftfxConfig[flashIndex], start, lengthInBytes, expectedData, margin, failedAddress, failedData); } /*! * @brief Returns the security state via the pointer passed into the function. */ status_t FLASH_GetSecurityState(flash_config_t *config, ftfx_security_state_t *state) { return FTFx_REG_GetSecurityState(&config->ftfxConfig[0], state); } /*! * @brief Allows users to bypass security with a backdoor key. */ status_t FLASH_SecurityBypass(flash_config_t *config, const uint8_t *backdoorKey) { return FTFx_CMD_SecurityBypass(&config->ftfxConfig[0], backdoorKey); } #if defined(FSL_FEATURE_FLASH_HAS_SET_FLEXRAM_FUNCTION_CMD) && FSL_FEATURE_FLASH_HAS_SET_FLEXRAM_FUNCTION_CMD /*! * @brief Sets the FlexRAM function command. */ status_t FLASH_SetFlexramFunction(flash_config_t *config, ftfx_flexram_func_opt_t option) { return FTFx_CMD_SetFlexramFunction(&config->ftfxConfig[0], option); } #endif #if defined(FSL_FEATURE_FLASH_HAS_PFLASH_BLOCK_SWAP) && FSL_FEATURE_FLASH_HAS_PFLASH_BLOCK_SWAP /*! * @brief Swaps the lower half flash with the higher half flash. */ status_t FLASH_Swap(flash_config_t *config, uint32_t address, bool isSetEnable) { status_t returnCode; ftfx_swap_state_config_t returnInfo; ftfx_config_t *ftfxConfig; uint8_t flashIndex; returnCode = flash_check_range_to_get_index(config, address, 1U, &flashIndex); if (returnCode != kStatus_FTFx_Success) { return returnCode; } ftfxConfig = &config->ftfxConfig[flashIndex]; (void)memset(&returnInfo, 0xFF, sizeof(returnInfo)); do { returnCode = FTFx_CMD_SwapControl(ftfxConfig, address, kFTFx_SwapControlOptionReportStatus, &returnInfo); if (returnCode != kStatus_FTFx_Success) { return returnCode; } if (!isSetEnable) { if (returnInfo.flashSwapState == kFTFx_SwapStateDisabled) { return kStatus_FTFx_Success; } else if (returnInfo.flashSwapState == kFTFx_SwapStateUninitialized) { /* The swap system changed to the DISABLED state with Program flash block 0 * located at relative flash address 0x0_0000 */ returnCode = FTFx_CMD_SwapControl(ftfxConfig, address, kFTFx_SwapControlOptionDisableSystem, &returnInfo); } else { /* Swap disable should be requested only when swap system is in the uninitialized state */ return kStatus_FTFx_SwapSystemNotInUninitialized; } } else { /* When first swap: the initial swap state is Uninitialized, flash swap indicator address is unset, * the swap procedure should be Uninitialized -> Update-Erased -> Complete. * After the first swap has been completed, the flash swap inidicator address cannot be modified * unless EraseAllBlocks command is issued, the swap procedure is changed to Update -> Update-Erased -> * Complete. */ switch (returnInfo.flashSwapState) { case kFTFx_SwapStateUninitialized: /* If current swap mode is Uninitialized, Initialize Swap to Initialized/READY state. */ returnCode = FTFx_CMD_SwapControl(ftfxConfig, address, kFTFx_SwapControlOptionIntializeSystem, &returnInfo); break; case kFTFx_SwapStateReady: /* Validate whether the address provided to the swap system is matched to * swap indicator address in the IFR */ returnCode = flash_validate_swap_indicator_address(ftfxConfig, address); if (returnCode == kStatus_FTFx_Success) { /* If current swap mode is Initialized/Ready, Initialize Swap to UPDATE state. */ returnCode = FTFx_CMD_SwapControl(ftfxConfig, address, kFTFx_SwapControlOptionSetInUpdateState, &returnInfo); } break; case kFTFx_SwapStateUpdate: /* If current swap mode is Update, Erase indicator sector in non active block * to proceed swap system to update-erased state */ returnCode = FLASH_Erase(config, address + (ftfxConfig->flashDesc.totalSize >> 1u), ftfxConfig->opsConfig.addrAligment.sectorCmd, (uint32_t)kFTFx_ApiEraseKey); break; case kFTFx_SwapStateUpdateErased: /* If current swap mode is Update or Update-Erased, progress Swap to COMPLETE State */ returnCode = FTFx_CMD_SwapControl(ftfxConfig, address, kFTFx_SwapControlOptionSetInCompleteState, &returnInfo); break; case kFTFx_SwapStateComplete: break; case kFTFx_SwapStateDisabled: /* When swap system is in disabled state, We need to clear swap system back to uninitialized * by issuing EraseAllBlocks command */ returnCode = kStatus_FTFx_SwapSystemNotInUninitialized; break; default: returnCode = kStatus_FTFx_InvalidArgument; break; } } if (returnCode != kStatus_FTFx_Success) { break; } } while (!((kFTFx_SwapStateComplete == returnInfo.flashSwapState) && isSetEnable)); return returnCode; } #endif /* FSL_FEATURE_FLASH_HAS_PFLASH_BLOCK_SWAP */ /*! * @brief Returns the protection state of the desired flash area via the pointer passed into the function. */ status_t FLASH_IsProtected(flash_config_t *config, uint32_t start, uint32_t lengthInBytes, flash_prot_state_t *protection_state) { status_t returnCode; ftfx_config_t *ftfxConfig; uint8_t flashIndex; if (protection_state == NULL) { return kStatus_FTFx_InvalidArgument; } returnCode = flash_check_range_to_get_index(config, start, lengthInBytes, &flashIndex); if (returnCode != kStatus_FTFx_Success) { return returnCode; } ftfxConfig = &config->ftfxConfig[flashIndex]; #if (FTFx_FLASH_COUNT > 1U) if (0U != (ftfxConfig->flashDesc.feature.hasProtControl)) #endif { uint32_t endAddress; /* end address for protection check */ uint32_t regionCheckedCounter; /* increments each time the flash address was checked for * protection status */ uint32_t regionCounter; /* incrementing variable used to increment through the flash * protection regions */ uint32_t protectStatusCounter; /* increments each time a flash region was detected as protected */ uint8_t flashRegionProtectStatus[MAX_FLASH_PROT_REGION_COUNT]; /* array of the protection * status for each * protection region */ for (uint32_t i = 0U; i < (uint32_t)MAX_FLASH_PROT_REGION_COUNT; i++) /* The protection register is initialized to the */ { /* unprotected state by default. */ flashRegionProtectStatus[i] = (uint8_t)0xFF; /* The array is initialized to all 1 */ } uint32_t flashRegionAddress[MAX_FLASH_PROT_REGION_COUNT + 1U]; /* array of the start addresses for each flash * protection region. Note this is REGION_COUNT+1 * due to requiring the next start address after * the end of flash for loop-check purposes below */ bool isBreakNeeded = false; /* Calculate Flash end address */ endAddress = start + lengthInBytes; /* populate the flashRegionAddress array with the start address of each flash region */ regionCounter = 0U; /* make sure regionCounter is initialized to 0 first */ /* populate up to 33rd element of array, this is the next address after end of flash array */ while (regionCounter <= ftfxConfig->flashDesc.protectRegionMem.count) { flashRegionAddress[regionCounter] = ftfxConfig->flashDesc.protectRegionMem.base + ftfxConfig->flashDesc.protectRegionMem.size * regionCounter; regionCounter++; } /* populate flashRegionProtectStatus array with status information * Protection status for each region is stored in the FPROT[3:0] registers * Each bit represents one region of flash * 4 registers * 8-bits-per-register = 32-bits (32-regions) * The convention is: * FPROT3[bit 0] is the first protection region (start of flash memory) * FPROT0[bit 7] is the last protection region (end of flash memory) * regionCounter is used to determine which FPROT[3:0] register to check for protection status * Note: FPROT=1 means NOT protected, FPROT=0 means protected */ regionCounter = 0U; /* make sure regionCounter is initialized to 0 first */ static volatile uint32_t *const kFPROTLx = (volatile uint32_t *)(uint32_t)&FTFx_FPROTL3_REG; #if defined(FTFx_FLASH0_HAS_HIGH_PROT_REG) && FTFx_FLASH0_HAS_HIGH_PROT_REG static volatile uint32_t *const kFPROTHx = (volatile uint32_t *)(uint32_t)&FTFx_FPROTH3_REG; #endif #if defined(FTFx_FLASH1_HAS_INT_PROT_REG) && FTFx_FLASH1_HAS_INT_PROT_REG static volatile uint16_t *const kFPROTSx = (volatile uint16_t *)(uint32_t)&FTFx_FPROTSL_REG; #endif while (regionCounter < ftfxConfig->flashDesc.protectRegionMem.count) { #if (FTFx_FLASH_COUNT > 1U) if ((0U == ftfxConfig->flashDesc.index) || (0U != ftfxConfig->flashDesc.feature.hasIndProtReg)) #endif { #if defined(MAX_FLASH_PROT_REGION_COUNT) && (MAX_FLASH_PROT_REGION_COUNT <= 32U) if (regionCounter < (uint32_t)MAX_FLASH_PROT_REGION_COUNT) { flashRegionProtectStatus[regionCounter] = (uint8_t)(((kFPROTLx[0]) >> regionCounter) & 0x1U); } #else if (regionCounter < 32u) { flashRegionProtectStatus[regionCounter] = (uint8_t)(((kFPROTLx[0]) >> regionCounter) & 0x1U); } #endif #if defined(MAX_FLASH_PROT_REGION_COUNT) && (MAX_FLASH_PROT_REGION_COUNT == 64u) else if (regionCounter < 64U) { flashRegionProtectStatus[regionCounter] = (uint8_t)(((kFPROTHx[0]) >> (regionCounter - 32U)) & 0x1U); } #endif else { isBreakNeeded = true; } regionCounter++; } #if defined(FTFx_FLASH1_HAS_INT_PROT_REG) && FTFx_FLASH1_HAS_INT_PROT_REG else if ((1U == ftfxConfig->flashDesc.index) && (0U != ftfxConfig->flashDesc.feature.hasIndProtReg)) { /* Note: So far protection region count may be 8/16 */ if (regionCounter < 16U) { flashRegionProtectStatus[regionCounter] = (uint8_t)((kFPROTSx[0] >> regionCounter) & (0x01u)); } else { isBreakNeeded = true; } regionCounter++; } #endif /* FTFx_FLASH1_HAS_INT_PROT_REG */ #if (FTFx_FLASH_COUNT > 1U) else { return kStatus_FTFx_InvalidArgument; } #endif if (isBreakNeeded) { break; } } /* loop through the flash regions and check * desired flash address range for protection status * loop stops when it is detected that start has exceeded the endAddress */ regionCounter = 0U; /* make sure regionCounter is initialized to 0 first */ regionCheckedCounter = 0U; protectStatusCounter = 0U; /* make sure protectStatusCounter is initialized to 0 first */ while (start < endAddress) { /* check to see if the address falls within this protection region * Note that if the entire flash is to be checked, the last protection * region checked would consist of the last protection start address and * the start address following the end of flash */ if ((start >= flashRegionAddress[regionCounter]) && (start < flashRegionAddress[regionCounter + 1U])) { /* increment regionCheckedCounter to indicate this region was checked */ regionCheckedCounter++; /* check the protection status of this region * Note: FPROT=1 means NOT protected, FPROT=0 means protected */ if (0U == flashRegionProtectStatus[regionCounter]) { /* increment protectStatusCounter to indicate this region is protected */ protectStatusCounter++; } start += ftfxConfig->flashDesc.protectRegionMem.size; /* increment to an address within the next region */ } regionCounter++; /* increment regionCounter to check for the next flash protection region */ } /* if protectStatusCounter == 0, then no region of the desired flash region is protected */ if (protectStatusCounter == 0U) { *protection_state = kFLASH_ProtectionStateUnprotected; } /* if protectStatusCounter == regionCheckedCounter, then each region checked was protected */ else if (protectStatusCounter == regionCheckedCounter) { *protection_state = kFLASH_ProtectionStateProtected; } /* if protectStatusCounter != regionCheckedCounter, then protection status is mixed * In other words, some regions are protected while others are unprotected */ else { *protection_state = kFLASH_ProtectionStateMixed; } } #if (FTFx_FLASH_COUNT > 1U) else { *protection_state = kFLASH_ProtectionStateUnprotected; } #endif return kStatus_FTFx_Success; } #if defined(FSL_FEATURE_FLASH_HAS_ACCESS_CONTROL) && FSL_FEATURE_FLASH_HAS_ACCESS_CONTROL /*! * @brief Returns the access state of the desired flash area via the pointer passed into the function. * * This function retrieves the current flash access status for a given * flash area as determined by the start address and length. */ status_t FLASH_IsExecuteOnly(flash_config_t *config, uint32_t start, uint32_t lengthInBytes, flash_xacc_state_t *access_state) { status_t returnCode; ftfx_config_t *ftfxConfig; uint8_t flashIndex; if (access_state == NULL) { return kStatus_FTFx_InvalidArgument; } returnCode = flash_check_range_to_get_index(config, start, lengthInBytes, &flashIndex); if (returnCode != kStatus_FTFx_Success) { return returnCode; } ftfxConfig = &config->ftfxConfig[flashIndex]; /* store the execute only segment count */ uint32_t executeOnlySegmentCounter = 0U; /* Calculate end address */ uint32_t endAddress = start + lengthInBytes; /* Aligning start address and end address */ uint32_t alignedStartAddress = ALIGN_DOWN(start, ftfxConfig->flashDesc.accessSegmentMem.size); uint32_t alignedEndAddress = ALIGN_UP(endAddress, ftfxConfig->flashDesc.accessSegmentMem.size); uint32_t u32flag = 1U; uint32_t segmentIndex = 0U; /* Calculate the execute only segment Count */ uint32_t maxSupportedExecuteOnlySegmentCount = (alignedEndAddress - alignedStartAddress) / ftfxConfig->flashDesc.accessSegmentMem.size; while (start < endAddress) { uint32_t xacc = 0U; bool isInvalidSegmentIndex = false; /* Calculate which segmentIndex the address is in */ segmentIndex = (start - ftfxConfig->flashDesc.accessSegmentMem.base) / ftfxConfig->flashDesc.accessSegmentMem.size; if ((0U == ftfxConfig->flashDesc.index) || (0U != ftfxConfig->flashDesc.feature.hasIndXaccReg)) { /* For primary flash, The eight XACC registers allow up to 64 restricted segments of equal memory size. */ if (segmentIndex < 32U) { xacc = *(const volatile uint32_t *)(uint32_t)&FTFx_XACCL3_REG; } else if (segmentIndex < ftfxConfig->flashDesc.accessSegmentMem.count) { xacc = *(const volatile uint32_t *)(uint32_t)&FTFx_XACCH3_REG; segmentIndex -= 32U; } else { isInvalidSegmentIndex = true; } } #if defined(FTFx_FLASH1_HAS_INT_XACC_REG) && FTFx_FLASH1_HAS_INT_XACC_REG else if ((ftfxConfig->flashDesc.index == 1U) && (0u != ftfxConfig->flashDesc.feature.hasIndXaccReg)) { /* For secondary flash, The two XACCS registers allow up to 16 restricted segments of equal memory size. */ if (segmentIndex < 8U) { xacc = *(const volatile uint8_t *)&FTFx_XACCSL_REG; } else if (segmentIndex < ftfxConfig->flashDesc.accessSegmentMem.count) { xacc = *(const volatile uint8_t *)&FTFx_XACCSH_REG; segmentIndex -= 8U; } else { isInvalidSegmentIndex = true; } } #endif else { return kStatus_FTFx_InvalidArgument; } if (isInvalidSegmentIndex) { break; } /* Determine if this address range is in a execute-only protection flash segment. */ if (0U != ((~xacc) & (u32flag << segmentIndex))) { executeOnlySegmentCounter++; } /* Calculate tne next start address */ start += ftfxConfig->flashDesc.accessSegmentMem.size; } if (executeOnlySegmentCounter < 1u) { *access_state = kFLASH_AccessStateUnLimited; } else if (executeOnlySegmentCounter < maxSupportedExecuteOnlySegmentCount) { *access_state = kFLASH_AccessStateMixed; } else { *access_state = kFLASH_AccessStateExecuteOnly; } return kStatus_FTFx_Success; } #endif /* FSL_FEATURE_FLASH_HAS_ACCESS_CONTROL */ /*! * @brief Sets the PFlash Protection to the intended protection status. * * @param config A pointer to storage for the driver runtime state. * @param protectStatus The expected protect status to set to the PFlash protection register. Each bit is * corresponding to protection of 1/32(64) of the total PFlash. The least significant bit is corresponding to the lowest * address area of PFlash. The most significant bit is corresponding to the highest address area of PFlash. There are * two possible cases as shown below: * 0: this area is protected. * 1: this area is unprotected. * * @retval #kStatus_FTFx_Success API was executed successfully. * @retval #kStatus_FTFx_InvalidArgument An invalid argument is provided. * @retval #kStatus_FTFx_CommandFailure Run-time error during command execution. */ status_t FLASH_PflashSetProtection(flash_config_t *config, pflash_prot_status_t *protectStatus) { if ((config == NULL) || (protectStatus == NULL)) { return kStatus_FTFx_InvalidArgument; } /* Most boards support program flash protect feature, The FPROT registers * define which program flash regions are protected from program and erase operations. * Protected flash regions cannot have their content changed; * that is, these regions cannot be programmed and cannot be erased by any flash command */ #if (FTFx_FLASH_COUNT > 1U) if (0U != (config->ftfxConfig[0].flashDesc.feature.hasProtControl)) #endif { if (config->ftfxConfig[0].flashDesc.feature.ProtRegBits >= 32U) { /* set PFlash protection register, unprotected regions are marked with a 1 and * setting PFlash protection register, unprotected regions are marked with a 1 and * protected regions use a 0; each bit of FPROT register can only be changed from 1s to 0s * while all bits with 0s to 1s transitions are ignored. */ *kFPROTL = protectStatus->protl; if (protectStatus->protl != *kFPROTL) { return kStatus_FTFx_CommandFailure; } } #if defined(FTFx_FLASH0_HAS_HIGH_PROT_REG) && FTFx_FLASH0_HAS_HIGH_PROT_REG /* For primary flash with eight PROT registers allow up to 64 protected segments of equal memory size. */ if (config->ftfxConfig[0].flashDesc.feature.ProtRegBits == 64U) { *kFPROTH = protectStatus->proth; if (protectStatus->proth != *kFPROTH) { return kStatus_FTFx_CommandFailure; } } #endif } #if defined(FTFx_FLASH1_HAS_INT_PROT_REG) && FTFx_FLASH1_HAS_INT_PROT_REG else if ((0U != config->ftfxConfig[1].flashDesc.feature.hasProtControl) && (0U != config->ftfxConfig[1].flashDesc.feature.hasIndProtReg)) { /* For secondary flash with two FPROT registers allow up to 16 protected segments of equal memory size. */ if (config->ftfxConfig[1].flashDesc.feature.ProtRegBits == 16U) { *kFPROTSL = protectStatus->protsl; if (protectStatus->protsl != *kFPROTSL) { return kStatus_FTFx_CommandFailure; } *kFPROTSH = protectStatus->protsh; if (protectStatus->protsh != *kFPROTSH) { return kStatus_FTFx_CommandFailure; } } } #endif #if (FTFx_FLASH_COUNT > 1U) else { /*do nothing*/ } #endif return kStatus_FTFx_Success; } /*! * @brief Gets the PFlash protection status. * * @param config A pointer to the storage for the driver runtime state. * @param protectStatus Protect status returned by the PFlash IP. Each bit is corresponding to the protection of * 1/32(64) * of the total PFlash. The least significant bit corresponds to the lowest address area of the PFlash. * The most significant bit corresponds to the highest address area of PFlash. There are two possible cases as shown * below: 0: this area is protected. 1: this area is unprotected. * * @retval #kStatus_FTFx_Success API was executed successfully. * @retval #kStatus_FTFx_InvalidArgument An invalid argument is provided. */ status_t FLASH_PflashGetProtection(flash_config_t *config, pflash_prot_status_t *protectStatus) { if ((config == NULL) || (protectStatus == NULL)) { return kStatus_FTFx_InvalidArgument; } #if (FTFx_FLASH_COUNT > 1U) if (0U != (config->ftfxConfig[0].flashDesc.feature.hasProtControl)) #endif { /* get the flash protect status */ if (config->ftfxConfig[0].flashDesc.feature.ProtRegBits >= 32U) { protectStatus->protl = *kFPROTL; } #if defined(FTFx_FLASH0_HAS_HIGH_PROT_REG) && FTFx_FLASH0_HAS_HIGH_PROT_REG /* For primary flash with eight PROT registers allow up to 64 protected segments of equal memory size. */ if (config->ftfxConfig[0].flashDesc.feature.ProtRegBits == 64U) { protectStatus->proth = *kFPROTH; } #endif } #if defined(FTFx_FLASH1_HAS_INT_PROT_REG) && FTFx_FLASH1_HAS_INT_PROT_REG /* For secondary flash with two FPROT registers allow up to 16 protected segments of equal memory size. */ else if ((0U != config->ftfxConfig[1].flashDesc.feature.hasProtControl) && (0U != config->ftfxConfig[1].flashDesc.feature.hasIndProtReg)) { if (config->ftfxConfig[0].flashDesc.feature.ProtRegBits == 16U) { protectStatus->protsl = *kFPROTSL; protectStatus->protsh = *kFPROTSH; } } #endif #if (FTFx_FLASH_COUNT > 1U) else { /*do nothing*/ } #endif return kStatus_FTFx_Success; } /*! * @brief Returns the desired flash property. * * @param config A pointer to the storage for the driver runtime state. * @param whichProperty The desired property from the list of properties in * enum flash_property_tag_t * @param value A pointer to the value returned for the desired flash property. * * @retval #kStatus_FTFx_Success API was executed successfully. * @retval #kStatus_FTFx_InvalidArgument An invalid argument is provided. * @retval #kStatus_FTFx_UnknownProperty An unknown property tag. */ status_t FLASH_GetProperty(flash_config_t *config, flash_property_tag_t whichProperty, uint32_t *value) { if ((config == NULL) || (value == NULL)) { return kStatus_FTFx_InvalidArgument; } status_t status = kStatus_FTFx_Success; switch (whichProperty) { /* gat Pflash0 sector size */ case kFLASH_PropertyPflash0SectorSize: *value = config->ftfxConfig[0].flashDesc.sectorSize; break; /* gat Pflash0 total size */ case kFLASH_PropertyPflash0TotalSize: *value = config->ftfxConfig[0].flashDesc.totalSize; break; /* gat Pflash0 block size */ case kFLASH_PropertyPflash0BlockSize: *value = config->ftfxConfig[0].flashDesc.totalSize / config->ftfxConfig[0].flashDesc.blockCount; break; /* gat Pflash0 block cont */ case kFLASH_PropertyPflash0BlockCount: *value = config->ftfxConfig[0].flashDesc.blockCount; break; /* gat Pflash0 block base address */ case kFLASH_PropertyPflash0BlockBaseAddr: *value = config->ftfxConfig[0].flashDesc.blockBase; break; /* gat Pflash0 fac support feature */ case kFLASH_PropertyPflash0FacSupport: *value = (uint32_t)config->ftfxConfig[0].flashDesc.feature.hasXaccControl; break; /* gat Pflash0 access segment size feature */ case kFLASH_PropertyPflash0AccessSegmentSize: *value = config->ftfxConfig[0].flashDesc.accessSegmentMem.size; break; /* gat Pflash0 access segment count feature */ case kFLASH_PropertyPflash0AccessSegmentCount: *value = config->ftfxConfig[0].flashDesc.accessSegmentMem.count; break; #if defined(FTFx_DRIVER_HAS_FLASH1_SUPPORT) && FTFx_DRIVER_HAS_FLASH1_SUPPORT case kFLASH_PropertyPflash1SectorSize: *value = config->ftfxConfig[1].flashDesc.sectorSize; break; case kFLASH_PropertyPflash1TotalSize: *value = config->ftfxConfig[1].flashDesc.totalSize; break; case kFLASH_PropertyPflash1BlockSize: *value = config->ftfxConfig[1].flashDesc.totalSize / config->ftfxConfig[1].flashDesc.blockCount; break; case kFLASH_PropertyPflash1BlockCount: *value = config->ftfxConfig[1].flashDesc.blockCount; break; case kFLASH_PropertyPflash1BlockBaseAddr: *value = config->ftfxConfig[1].flashDesc.blockBase; break; case kFLASH_PropertyPflash1FacSupport: *value = (uint32_t)config->ftfxConfig[1].flashDesc.feature.hasXaccControl; break; case kFLASH_PropertyPflash1AccessSegmentSize: *value = config->ftfxConfig[1].flashDesc.accessSegmentMem.size; break; case kFLASH_PropertyPflash1AccessSegmentCount: *value = config->ftfxConfig[1].flashDesc.accessSegmentMem.count; break; #endif /* gat FlexRam block base addrese */ case kFLASH_PropertyFlexRamBlockBaseAddr: *value = config->ftfxConfig[0].flexramBlockBase; break; /* gat FlexRam total size */ case kFLASH_PropertyFlexRamTotalSize: *value = config->ftfxConfig[0].flexramTotalSize; break; default: /* catch inputs that are not recognized */ status = kStatus_FTFx_UnknownProperty; break; } return status; } /*! * @brief init flash FPROT, XACC registers and Independent flash block */ static void flash_init_features(ftfx_config_t *config) { /* Initialize whether flash0 has independent block, protection registers and * execute only access registers */ #if (FTFx_FLASH_COUNT > 1U) if (config->flashDesc.index == 0U) #endif { config->flashDesc.feature.isIndBlock = 1U; config->flashDesc.feature.hasIndPfsizeReg = 1U; config->flashDesc.feature.hasIndProtReg = 1U; config->flashDesc.feature.hasIndXaccReg = 1U; } /* if another flash exists */ #if defined(FTFx_DRIVER_HAS_FLASH1_SUPPORT) && FTFx_DRIVER_HAS_FLASH1_SUPPORT else if (config->flashDesc.index == 1U) { config->flashDesc.feature.isIndBlock = FTFx_FLASH1_IS_INDEPENDENT_BLOCK; config->flashDesc.feature.hasIndPfsizeReg = config->flashDesc.feature.isIndBlock; config->flashDesc.feature.hasIndProtReg = FTFx_FLASH1_HAS_INT_PROT_REG; config->flashDesc.feature.hasIndXaccReg = FTFx_FLASH1_HAS_INT_XACC_REG; } #endif #if (FTFx_FLASH_COUNT > 1U) else { /*do nothing*/ } #endif /* init protection Registers feature*/ config->flashDesc.feature.hasProtControl = 1U; /* init Execute-only Access Registers feature*/ config->flashDesc.feature.hasXaccControl = FSL_FEATURE_FLASH_HAS_ACCESS_CONTROL; } /*! * @brief Initializes the flash operation config. */ static void flash_opsonfig_Init(flash_config_t *config, uint8_t flashIndex) { uint32_t pflashStartAddress; uint32_t pflashBlockSize; uint32_t pflashBlockCount; uint32_t pflashBlockSectorSize; uint32_t pfsizeMask; uint32_t pfsizeShift; uint32_t pflashBlockWriteUnitSize; /* store P-Flash write unit size */ uint32_t pflashSectorCmdAlignment; /* store P-Flash Erase sector command address alignment */ uint32_t pflashSectionCmdAlignment; /* store Rrogram/Verify section command address alignment */ #if (FTFx_FLASH_COUNT > 1U) if (flashIndex == 1U) { pflashStartAddress = FLASH1_FEATURE_PFLASH_START_ADDRESS; pflashBlockSize = FLASH1_FEATURE_PFLASH_BLOCK_SIZE; pflashBlockCount = FLASH1_FEATURE_PFLASH_BLOCK_COUNT; pflashBlockSectorSize = FLASH1_FEATURE_PFLASH_BLOCK_SECTOR_SIZE; pflashBlockWriteUnitSize = FLASH1_FEATURE_PFLASH_BLOCK_WRITE_UNIT_SIZE; pflashSectorCmdAlignment = FLASH1_FEATURE_PFLASH_SECTOR_CMD_ADDRESS_ALIGMENT; pflashSectionCmdAlignment = FLASH1_FEATURE_PFLASH_SECTION_CMD_ADDRESS_ALIGMENT; pfsizeMask = SIM_FLASH1_PFSIZE_MASK; pfsizeShift = SIM_FLASH1_PFSIZE_SHIFT; } else #endif { pflashStartAddress = FLASH0_FEATURE_PFLASH_START_ADDRESS; /* get P-Flash start address */ pflashBlockSize = FLASH0_FEATURE_PFLASH_BLOCK_SIZE; pflashBlockCount = FLASH0_FEATURE_PFLASH_BLOCK_COUNT; pflashBlockSectorSize = FLASH0_FEATURE_PFLASH_BLOCK_SECTOR_SIZE; pflashBlockWriteUnitSize = FLASH0_FEATURE_PFLASH_BLOCK_WRITE_UNIT_SIZE; pflashSectorCmdAlignment = FLASH0_FEATURE_PFLASH_SECTOR_CMD_ADDRESS_ALIGMENT; pflashSectionCmdAlignment = FLASH0_FEATURE_PFLASH_SECTION_CMD_ADDRESS_ALIGMENT; pfsizeMask = SIM_FLASH0_PFSIZE_MASK; pfsizeShift = SIM_FLASH0_PFSIZE_SHIFT; } /* init current flash start address */ config->ftfxConfig[flashIndex].flashDesc.blockBase = pflashStartAddress; /* init current flash block count */ config->ftfxConfig[flashIndex].flashDesc.blockCount = pflashBlockCount; /* init current flash block sector size */ config->ftfxConfig[flashIndex].flashDesc.sectorSize = pflashBlockSectorSize; #if (FTFx_FLASH_COUNT > 1U) if ((0U != config->ftfxConfig[flashIndex].flashDesc.feature.isIndBlock) && (0U != config->ftfxConfig[flashIndex].flashDesc.feature.hasIndPfsizeReg)) #endif { /* Calculate flash memory size based on given parameter */ config->ftfxConfig[flashIndex].flashDesc.totalSize = flash_calculate_mem_size(pflashBlockCount, pflashBlockSize, pfsizeMask, pfsizeShift); } #if (FTFx_FLASH_COUNT > 1U) else { config->ftfxConfig[flashIndex].flashDesc.totalSize = pflashBlockCount * pflashBlockSize; } #endif /* init P-Flash write unit size */ config->ftfxConfig[flashIndex].opsConfig.addrAligment.blockWriteUnitSize = (uint8_t)pflashBlockWriteUnitSize; /* init P-Flash Erase sector command address alignment */ config->ftfxConfig[flashIndex].opsConfig.addrAligment.sectorCmd = (uint8_t)pflashSectorCmdAlignment; /* init P-Flash Rrogram/Verify section command address alignment */ config->ftfxConfig[flashIndex].opsConfig.addrAligment.sectionCmd = (uint8_t)pflashSectionCmdAlignment; /* init P-Flash Read resource command address alignment. */ config->ftfxConfig[flashIndex].opsConfig.addrAligment.resourceCmd = (uint8_t)FSL_FEATURE_FLASH_PFLASH_RESOURCE_CMD_ADDRESS_ALIGMENT; /* init P-Flash Program check command address alignment. */ config->ftfxConfig[flashIndex].opsConfig.addrAligment.checkCmd = (uint8_t)FSL_FEATURE_FLASH_PFLASH_CHECK_CMD_ADDRESS_ALIGMENT; /* init P-Flash swap command address alignment */ config->ftfxConfig[flashIndex].opsConfig.addrAligment.swapCtrlCmd = (uint8_t)FSL_FEATURE_FLASH_PFLASH_SWAP_CONTROL_CMD_ADDRESS_ALIGMENT; } #if defined(FSL_FEATURE_FLASH_HAS_ACCESS_CONTROL) && FSL_FEATURE_FLASH_HAS_ACCESS_CONTROL /*! @brief init access segment feature */ static void flash_access_init(flash_config_t *config, uint8_t flashIndex) { ftfx_spec_mem_t *specMem; /* start to initialize the structure of access segment */ #if defined(FTFx_FLASH1_HAS_INT_XACC_REG) && FTFx_FLASH1_HAS_INT_XACC_REG specMem = &config->ftfxConfig[flashIndex].flashDesc.accessSegmentMem; if (flashIndex == 1U) { specMem->base = config->ftfxConfig[flashIndex].flashDesc.blockBase; specMem->size = (uint32_t)kFTFx_AccessSegmentUnitSize << FTFx_FACSSS_REG; specMem->count = FTFx_FACSNS_REG; } else #else specMem = &config->ftfxConfig[0].flashDesc.accessSegmentMem; #endif /* FTFx_FLASH1_HAS_INT_XACC_REG */ { specMem->base = config->ftfxConfig[0].flashDesc.blockBase; specMem->size = (uint32_t)kFTFx_AccessSegmentUnitSize << FTFx_FACSS_REG; specMem->count = FTFx_FACSN_REG; } } #endif /* FSL_FEATURE_FLASH_HAS_ACCESS_CONTROL */ /*! @brief init protection feature */ static void flash_protection_init(flash_config_t *config, uint8_t flashIndex) { uint32_t pflashProtectionRegionCount; #if (FTFx_FLASH_COUNT > 1U) uint8_t i; if (flashIndex == 1U) { /* store flash0 Protection region count */ pflashProtectionRegionCount = FLASH1_FEATURE_PFLASH_PROTECTION_REGION_COUNT; } else #endif // #if (FTFx_FLASH_COUNT > 1U) { /* store flash0 Protection region count */ pflashProtectionRegionCount = FLASH0_FEATURE_PFLASH_PROTECTION_REGION_COUNT; } /* Start to initialize the structure of protection features */ ftfx_spec_mem_t *specMem; specMem = &config->ftfxConfig[flashIndex].flashDesc.protectRegionMem; #if (FTFx_FLASH_COUNT > 1U) if (0U != (config->ftfxConfig[flashIndex].flashDesc.feature.hasIndProtReg)) #endif // #if (FTFx_FLASH_COUNT > 1U) { specMem->base = config->ftfxConfig[flashIndex].flashDesc.blockBase; specMem->count = pflashProtectionRegionCount; /* Calculate flash prot segment size */ specMem->size = flash_calculate_prot_segment_size(config->ftfxConfig[flashIndex].flashDesc.totalSize, specMem->count); } #if (FTFx_FLASH_COUNT > 1U) else { uint32_t pflashTotalSize = 0U; specMem->base = config->ftfxConfig[0].flashDesc.blockBase; specMem->count = FLASH0_FEATURE_PFLASH_PROTECTION_REGION_COUNT; if (flashIndex == FTFx_FLASH_COUNT - 1U) { uint32_t segmentSize; /* store the flash protection region count */ for (i = 0U; i < FTFx_FLASH_COUNT; i++) { /* get pflash total size*/ pflashTotalSize += config->ftfxConfig[flashIndex].flashDesc.totalSize; } /* get pflash port segment size based on parameters */ segmentSize = flash_calculate_prot_segment_size(pflashTotalSize, specMem->count); for (i = 0U; i < FTFx_FLASH_COUNT; i++) { /* init flash0 and flash1 port segment size */ config->ftfxConfig[i].flashDesc.protectRegionMem.size = segmentSize; } } } #endif // #if (FTFx_FLASH_COUNT > 1U) } /*! * @brief Calculate flash memory size based on given parameter */ static uint32_t flash_calculate_mem_size(uint32_t pflashBlockCount, uint32_t pflashBlockSize, uint32_t pfsizeMask, uint32_t pfsizeShift) { uint8_t pfsize; uint32_t flashDensity; /* PFSIZE=0xf means that on customer parts the IFR was not correctly programmed. * We just use the pre-defined flash size in feature file here to support pre-production parts */ pfsize = (uint8_t)((SIM_FCFG1_REG & pfsizeMask) >> pfsizeShift); if (pfsize == 0xfU) { flashDensity = pflashBlockCount * pflashBlockSize; } else { flashDensity = ((uint32_t)kPFlashDensities[pfsize]) << 10U; } return flashDensity; } /*! * @brief Calculate flash prot segment size */ static uint32_t flash_calculate_prot_segment_size(uint32_t flashSize, uint32_t segmentCount) { uint32_t segmentSize; /* Calculate the size of the flash protection region * If the flash density is > 32KB, then protection region is 1/32 of total flash density * Else if flash density is < 32KB, then flash protection region is set to 1KB */ if (flashSize > segmentCount * (uint32_t)kFTFx_MinProtectBlockSize) { segmentSize = flashSize / segmentCount; } else { segmentSize = (uint32_t)kFTFx_MinProtectBlockSize; } return segmentSize; } /*! * @brief Validates the given start address and length to get flash index */ static status_t flash_check_range_to_get_index(flash_config_t *config, uint32_t start, uint32_t lengthInBytes, uint8_t *flashIndex) { if (config == NULL) { return kStatus_FTFx_InvalidArgument; } /* Validates the range of the given address */ for (uint8_t index = 0U; index < FTFx_FLASH_COUNT; index++) { if ((start >= config->ftfxConfig[index].flashDesc.blockBase) && ((start + lengthInBytes) <= (config->ftfxConfig[index].flashDesc.blockBase + config->ftfxConfig[index].flashDesc.totalSize))) { *flashIndex = config->ftfxConfig[index].flashDesc.index; return kStatus_FTFx_Success; } } return kStatus_FTFx_AddressError; } /*! * @brief Decide whether to convert the start address from primary flash to secondary flash based on the current start * address */ static void flash_convert_start_address(ftfx_config_t *config, uint32_t start) { // The caller will guarantee that the config is valid #if (FTFx_FLASH_COUNT > 1U) if ((0U != config->flashDesc.index) && (0U != config->flashDesc.feature.isIndBlock)) { /* When required by the command, address bit 23 selects between main flash memory * (=0) and secondary flash memory (=1).*/ config->opsConfig.convertedAddress = start - config->flashDesc.blockBase + 0x800000U; } else #endif { config->opsConfig.convertedAddress = start; } } #if defined(FSL_FEATURE_FLASH_HAS_PFLASH_BLOCK_SWAP) && FSL_FEATURE_FLASH_HAS_PFLASH_BLOCK_SWAP /*! * @brief Validates the given address to see if it is equal to swap indicator address in pflash swap IFR. */ static status_t flash_validate_swap_indicator_address(ftfx_config_t *config, uint32_t address) { status_t returnCode; struct _flash_swap_ifr_field_config { uint16_t swapIndicatorAddress; /*!< A Swap indicator address field.*/ uint16_t swapEnableWord; /*!< A Swap enable word field.*/ uint8_t reserved0[4]; /*!< A reserved field.*/ uint8_t reserved1[2]; /*!< A reserved field.*/ uint16_t swapDisableWord; /*!< A Swap disable word field.*/ uint8_t reserved2[4]; /*!< A reserved field.*/ } flashSwapIfrFieldData; uint32_t swapIndicatorAddress; #if defined(FSL_FEATURE_FLASH_HAS_READ_RESOURCE_CMD) && FSL_FEATURE_FLASH_HAS_READ_RESOURCE_CMD returnCode = FTFx_CMD_ReadResource(config, config->ifrDesc.resRange.pflashSwapIfrStart, (uint8_t *)&flashSwapIfrFieldData, sizeof(flashSwapIfrFieldData), kFTFx_ResourceOptionFlashIfr); if (returnCode != kStatus_FTFx_Success) { return returnCode; } #else { /* From RM, the actual info are stored in FCCOB6,7 */ uint32_t returnValue[2]; returnCode = FTFx_CMD_ReadOnce(config, (uint32_t)kFLASH_RecordIndexSwapAddr, (uint8_t *)returnValue, 4U); if (returnCode != kStatus_FTFx_Success) { return returnCode; } flashSwapIfrFieldData.swapIndicatorAddress = (uint16_t)returnValue[0]; returnCode = FTFx_CMD_ReadOnce(config, (uint32_t)kFLASH_RecordIndexSwapEnable, (uint8_t *)returnValue, 4U); if (returnCode != kStatus_FTFx_Success) { return returnCode; } returnCode = FTFx_CMD_ReadOnce(config, (uint32_t)kFLASH_RecordIndexSwapDisable, (uint8_t *)returnValue, 4U); if (returnCode != kStatus_FTFx_Success) { return returnCode; } } #endif /* The high bits value of Swap Indicator Address is stored in Program Flash Swap IFR Field, * the low several bit value of Swap Indicator Address is always 1'b0 */ swapIndicatorAddress = (uint32_t)flashSwapIfrFieldData.swapIndicatorAddress * config->opsConfig.addrAligment.swapCtrlCmd; if (address != swapIndicatorAddress) { return kStatus_FTFx_SwapIndicatorAddressError; } return returnCode; } #endif /* FSL_FEATURE_FLASH_HAS_PFLASH_BLOCK_SWAP */ status_t FLASH_GetCommandState(void) { uint8_t registerValue; uint32_t idleFlag; /* Get flash status register value */ registerValue = FTFx->FSTAT; /* Check DONE bit of the flash status register */ idleFlag = ((uint32_t)registerValue & FTFx_FSTAT_CCIF_MASK) >> FTFx_FSTAT_CCIF_SHIFT; if (idleFlag == 0U) { return kStatus_FTFx_CommandOperationInProgress; } else { /* Check error bits */ /* checking access error */ if (0U != (registerValue & FTFx_FSTAT_ACCERR_MASK)) { return kStatus_FTFx_AccessError; } /* checking protection error */ else if (0U != (registerValue & FTFx_FSTAT_FPVIOL_MASK)) { return kStatus_FTFx_ProtectionViolation; } /* checking MGSTAT0 non-correctable error */ else if (0U != (registerValue & FTFx_FSTAT_MGSTAT0_MASK)) { return kStatus_FTFx_CommandFailure; } else { return kStatus_FTFx_Success; } } }