amiro-blt / Target / Source / ARMCM4_STM32 / flash.c @ 0dc9f2f9
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/************************************************************************************//** |
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* \file Source\ARMCM4_STM32\flash.c
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* \brief Bootloader flash driver source file.
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* \ingroup Target_ARMCM4_STM32
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* \internal
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*----------------------------------------------------------------------------------------
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* C O P Y R I G H T
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*----------------------------------------------------------------------------------------
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* Copyright (c) 2013 by Feaser http://www.feaser.com All rights reserved
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*
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*----------------------------------------------------------------------------------------
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* L I C E N S E
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*----------------------------------------------------------------------------------------
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* This file is part of OpenBLT. OpenBLT is free software: you can redistribute it and/or
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* modify it under the terms of the GNU General Public License as published by the Free
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* Software Foundation, either version 3 of the License, or (at your option) any later
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* version.
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*
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* OpenBLT is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY;
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* without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
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* PURPOSE. See the GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License along with OpenBLT.
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* If not, see <http://www.gnu.org/licenses/>.
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*
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* A special exception to the GPL is included to allow you to distribute a combined work
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* that includes OpenBLT without being obliged to provide the source code for any
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* proprietary components. The exception text is included at the bottom of the license
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* file <license.html>.
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*
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* \endinternal
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****************************************************************************************/
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/****************************************************************************************
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* Include files
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****************************************************************************************/
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#include "boot.h" /* bootloader generic header */ |
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#include "stm32f4xx.h" /* STM32 registers */ |
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#include "stm32f4xx_conf.h" /* STM32 peripheral drivers */ |
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/****************************************************************************************
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* Macro definitions
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****************************************************************************************/
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/** \brief Value for an invalid flash sector. */
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#define FLASH_INVALID_SECTOR (0xff) |
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/** \brief Value for an invalid flash address. */
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#define FLASH_INVALID_ADDRESS (0xffffffff) |
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/** \brief Standard size of a flash block for writing. */
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#define FLASH_WRITE_BLOCK_SIZE (512) |
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/** \brief Total numbers of sectors in array flashLayout[]. */
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#define FLASH_TOTAL_SECTORS (sizeof(flashLayout)/sizeof(flashLayout[0])) |
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/** \brief Offset into the user program's vector table where the checksum is located. */
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#define FLASH_VECTOR_TABLE_CS_OFFSET (0x1ac) |
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/****************************************************************************************
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* Type definitions
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****************************************************************************************/
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/** \brief Flash sector descriptor type. */
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typedef struct |
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{ |
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blt_addr sector_start; /**< sector start address */
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blt_int32u sector_size; /**< sector size in bytes */
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blt_int8u sector_num; /**< sector number */
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} tFlashSector; |
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/** \brief Structure type for grouping flash block information.
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* \details Programming is done per block of max FLASH_WRITE_BLOCK_SIZE. for this a
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* flash block manager is implemented in this driver. this flash block manager
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* depends on this flash block info structure. It holds the base address of
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* the flash block and the data that should be programmed into the flash
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* block. The .base_addr must be a multiple of FLASH_WRITE_BLOCK_SIZE.
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*/
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typedef struct |
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{ |
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blt_addr base_addr; |
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blt_int8u data[FLASH_WRITE_BLOCK_SIZE]; |
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} tFlashBlockInfo; |
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/****************************************************************************************
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* Function prototypes
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****************************************************************************************/
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static blt_bool FlashInitBlock(tFlashBlockInfo *block, blt_addr address);
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static tFlashBlockInfo *FlashSwitchBlock(tFlashBlockInfo *block, blt_addr base_addr);
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static blt_bool FlashAddToBlock(tFlashBlockInfo *block, blt_addr address,
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blt_int8u *data, blt_int32u len); |
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static blt_bool FlashWriteBlock(tFlashBlockInfo *block);
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static blt_bool FlashEraseSectors(blt_int8u first_sector, blt_int8u last_sector);
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static blt_int8u FlashGetSector(blt_addr address);
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/****************************************************************************************
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* Local constant declarations
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****************************************************************************************/
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/** \brief Array wit the layout of the flash memory.
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* \details Also controls what part of the flash memory is reserved for the bootloader.
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* If the bootloader size changes, the reserved sectors for the bootloader
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* might need adjustment to make sure the bootloader doesn't get overwritten.
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*/
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static const tFlashSector flashLayout[] = |
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{ |
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/* space is reserved for a bootloader configuration with all supported communication
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* interfaces enabled. when for example only UART is needed, than the space required
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* for the bootloader can be made a lot smaller here.
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*/
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/* { 0x08000000, 0x04000, 0}, flash sector 0 - reserved for bootloader */
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/* { 0x08004000, 0x04000, 1}, flash sector 1 - reserved for bootloader */
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{ 0x08008000, 0x04000, 2}, /* flash sector 2 - 16kb */ |
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{ 0x0800c000, 0x04000, 3}, /* flash sector 3 - 16kb */ |
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{ 0x08010000, 0x10000, 4}, /* flash sector 4 - 64kb */ |
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{ 0x08020000, 0x20000, 5}, /* flash sector 5 - 128kb */ |
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{ 0x08040000, 0x20000, 6}, /* flash sector 6 - 128kb */ |
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{ 0x08060000, 0x20000, 7}, /* flash sector 7 - 128kb */ |
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#if (BOOT_NVM_SIZE_KB > 512) |
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{ 0x08080000, 0x20000, 8}, /* flash sector 8 - 128kb */ |
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{ 0x080A0000, 0x20000, 9}, /* flash sector 9 - 128kb */ |
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{ 0x080C0000, 0x20000, 10}, /* flash sector 10 - 128kb */ |
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{ 0x080E0000, 0x20000, 11}, /* flash sector 11 - 128kb */ |
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#endif
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#if (BOOT_NVM_SIZE_KB > 1024) |
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{ 0x08100000, 0x04000, 12}, /* flash sector 12 - 16kb */ |
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{ 0x08104000, 0x04000, 13}, /* flash sector 13 - 16kb */ |
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{ 0x08108000, 0x04000, 14}, /* flash sector 14 - 16kb */ |
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{ 0x0810c000, 0x04000, 15}, /* flash sector 15 - 16kb */ |
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{ 0x08110000, 0x10000, 16}, /* flash sector 16 - 64kb */ |
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{ 0x08120000, 0x20000, 17}, /* flash sector 17 - 128kb */ |
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{ 0x08140000, 0x20000, 18}, /* flash sector 18 - 128kb */ |
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{ 0x08160000, 0x20000, 19}, /* flash sector 19 - 128kb */ |
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{ 0x08180000, 0x20000, 20}, /* flash sector 20 - 128kb */ |
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{ 0x081A0000, 0x20000, 21}, /* flash sector 21 - 128kb */ |
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{ 0x081C0000, 0x20000, 22}, /* flash sector 22 - 128kb */ |
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{ 0x081E0000, 0x20000, 23}, /* flash sector 23 - 128kb */ |
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#endif
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#if (BOOT_NVM_SIZE_KB > 2048) |
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#error "BOOT_NVM_SIZE_KB > 2048 is currently not supported." |
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#endif
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}; |
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/** \brief Lookup table to quickly convert sector number to mask.
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* \details The STM32F4x Standard Peripheral Library driver needs a sector mask instead
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* of the sector number. this ROM lookup table can quickly convert the sector
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* number to its mask.
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*/
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static const blt_int16u flashSectorNumToMask[] = |
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{ |
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FLASH_Sector_0, /* idx 0 - mask for sector 0 */
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FLASH_Sector_1, /* idx 1 - mask for sector 1 */
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FLASH_Sector_2, /* idx 2 - mask for sector 2 */
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FLASH_Sector_3, /* idx 3 - mask for sector 3 */
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FLASH_Sector_4, /* idx 4 - mask for sector 4 */
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FLASH_Sector_5, /* idx 5 - mask for sector 5 */
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FLASH_Sector_6, /* idx 6 - mask for sector 6 */
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FLASH_Sector_7, /* idx 7 - mask for sector 7 */
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FLASH_Sector_8, /* idx 8 - mask for sector 8 */
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FLASH_Sector_9, /* idx 9 - mask for sector 9 */
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FLASH_Sector_10, /* idx 10 - mask for sector 10 */
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FLASH_Sector_11, /* idx 11 - mask for sector 11 */
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FLASH_Sector_12, /* idx 12 - mask for sector 12 */
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FLASH_Sector_13, /* idx 13 - mask for sector 13 */
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FLASH_Sector_14, /* idx 14 - mask for sector 14 */
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FLASH_Sector_15, /* idx 15 - mask for sector 15 */
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FLASH_Sector_16, /* idx 16 - mask for sector 16 */
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FLASH_Sector_17, /* idx 17 - mask for sector 17 */
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FLASH_Sector_18, /* idx 18 - mask for sector 18 */
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FLASH_Sector_19, /* idx 19 - mask for sector 19 */
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FLASH_Sector_20, /* idx 20 - mask for sector 20 */
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FLASH_Sector_21, /* idx 21 - mask for sector 21 */
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FLASH_Sector_22, /* idx 22 - mask for sector 22 */
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FLASH_Sector_23 /* idx 23 - mask for sector 23 */
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}; |
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/****************************************************************************************
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* Local data declarations
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****************************************************************************************/
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/** \brief Local variable with information about the flash block that is currently
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* being operated on.
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* \details The smallest amount of flash that can be programmed is
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* FLASH_WRITE_BLOCK_SIZE. A flash block manager is implemented in this driver
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* and stores info in this variable. Whenever new data should be flashed, it
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* is first added to a RAM buffer, which is part of this variable. Whenever
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* the RAM buffer, which has the size of a flash block, is full or data needs
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* to be written to a different block, the contents of the RAM buffer are
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* programmed to flash. The flash block manager requires some software
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* overhead, yet results is faster flash programming because data is first
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* harvested, ideally until there is enough to program an entire flash block,
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* before the flash device is actually operated on.
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*/
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static tFlashBlockInfo blockInfo;
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/** \brief Local variable with information about the flash boot block.
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* \details The first block of the user program holds the vector table, which on the
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* STM32 is also the where the checksum is written to. Is it likely that
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* the vector table is first flashed and then, at the end of the programming
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* sequence, the checksum. This means that this flash block need to be written
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* to twice. Normally this is not a problem with flash memory, as long as you
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* write the same values to those bytes that are not supposed to be changed
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* and the locations where you do write to are still in the erased 0xFF state.
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* Unfortunately, writing twice to flash this way, does not work reliably on
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* all micros. This is why we need to have an extra block, the bootblock,
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* placed under the management of the block manager. This way is it possible
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* to implement functionality so that the bootblock is only written to once
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* at the end of the programming sequence.
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*/
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static tFlashBlockInfo bootBlockInfo;
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/************************************************************************************//** |
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** \brief Initializes the flash driver.
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** \return none.
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**
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****************************************************************************************/
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void FlashInit(void) |
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{ |
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/* init the flash block info structs by setting the address to an invalid address */
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blockInfo.base_addr = FLASH_INVALID_ADDRESS; |
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bootBlockInfo.base_addr = FLASH_INVALID_ADDRESS; |
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} /*** end of FlashInit ***/
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/************************************************************************************//** |
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** \brief Writes the data to flash through a flash block manager. Note that this
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** function also checks that no data is programmed outside the flash
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** memory region, so the bootloader can never be overwritten.
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** \param addr Start address.
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** \param len Length in bytes.
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** \param data Pointer to the data buffer.
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** \return BLT_TRUE if successful, BLT_FALSE otherwise.
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**
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****************************************************************************************/
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blt_bool FlashWrite(blt_addr addr, blt_int32u len, blt_int8u *data) |
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{ |
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blt_addr base_addr; |
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/* make sure the addresses are within the flash device */
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if ( (FlashGetSector(addr) == FLASH_INVALID_SECTOR) || \
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(FlashGetSector(addr+len-1) == FLASH_INVALID_SECTOR) )
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{ |
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return BLT_FALSE;
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} |
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/* if this is the bootblock, then let the boot block manager handle it */
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base_addr = (addr/FLASH_WRITE_BLOCK_SIZE)*FLASH_WRITE_BLOCK_SIZE; |
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if (base_addr == flashLayout[0].sector_start) |
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{ |
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/* let the boot block manager handle it */
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return FlashAddToBlock(&bootBlockInfo, addr, data, len);
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} |
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/* let the block manager handle it */
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return FlashAddToBlock(&blockInfo, addr, data, len);
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} /*** end of FlashWrite ***/
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/************************************************************************************//** |
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** \brief Erases the flash memory. Note that this function also checks that no
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** data is erased outside the flash memory region, so the bootloader can
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** never be erased.
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** \param addr Start address.
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** \param len Length in bytes.
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** \return BLT_TRUE if successful, BLT_FALSE otherwise.
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**
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****************************************************************************************/
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blt_bool FlashErase(blt_addr addr, blt_int32u len) |
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{ |
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blt_int8u first_sector; |
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blt_int8u last_sector; |
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/* obtain the first and last sector number */
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first_sector = FlashGetSector(addr); |
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last_sector = FlashGetSector(addr+len-1);
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/* check them */
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if ( (first_sector == FLASH_INVALID_SECTOR) || (last_sector == FLASH_INVALID_SECTOR) )
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{ |
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return BLT_FALSE;
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} |
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/* erase the sectors */
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return FlashEraseSectors(first_sector, last_sector);
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} /*** end of FlashErase ***/
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/************************************************************************************//** |
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** \brief Writes a checksum of the user program to non-volatile memory. This is
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** performed once the entire user program has been programmed. Through
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** the checksum, the bootloader can check if the programming session
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** was completed, which indicates that a valid user programming is
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** present and can be started.
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** \return BLT_TRUE if successful, BLT_FALSE otherwise.
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**
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****************************************************************************************/
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blt_bool FlashWriteChecksum(void)
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{ |
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blt_int32u signature_checksum = 0;
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/* for the STM32 target we defined the checksum as the Two's complement value of the
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* sum of the first 7 exception addresses.
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*
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* Layout of the vector table:
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* 0x08000000 Initial stack pointer
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* 0x08000004 Reset Handler
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* 0x08000008 NMI Handler
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* 0x0800000C Hard Fault Handler
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* 0x08000010 MPU Fault Handler
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* 0x08000014 Bus Fault Handler
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* 0x08000018 Usage Fault Handler
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*
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* signature_checksum = Two's complement of (SUM(exception address values))
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*
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* the bootloader writes this 32-bit checksum value right after the vector table
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* of the user program. note that this means one extra dummy entry must be added
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* at the end of the user program's vector table to reserve storage space for the
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* checksum.
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*/
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/* first check that the bootblock contains valid data. if not, this means the
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* bootblock is not part of the reprogramming this time and therefore no
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* new checksum needs to be written
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*/
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if (bootBlockInfo.base_addr == FLASH_INVALID_ADDRESS)
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{ |
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return BLT_TRUE;
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} |
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/* compute the checksum. note that the user program's vectors are not yet written
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* to flash but are present in the bootblock data structure at this point.
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*/
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signature_checksum += *((blt_int32u*)(&bootBlockInfo.data[0+0x00])); |
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signature_checksum += *((blt_int32u*)(&bootBlockInfo.data[0+0x04])); |
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signature_checksum += *((blt_int32u*)(&bootBlockInfo.data[0+0x08])); |
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signature_checksum += *((blt_int32u*)(&bootBlockInfo.data[0+0x0C])); |
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signature_checksum += *((blt_int32u*)(&bootBlockInfo.data[0+0x10])); |
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signature_checksum += *((blt_int32u*)(&bootBlockInfo.data[0+0x14])); |
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signature_checksum += *((blt_int32u*)(&bootBlockInfo.data[0+0x18])); |
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signature_checksum = ~signature_checksum; /* one's complement */
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signature_checksum += 1; /* two's complement */ |
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/* write the checksum */
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return FlashWrite(flashLayout[0].sector_start+FLASH_VECTOR_TABLE_CS_OFFSET, |
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sizeof(blt_addr), (blt_int8u*)&signature_checksum);
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} /*** end of FlashWriteChecksum ***/
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/************************************************************************************//** |
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** \brief Verifies the checksum, which indicates that a valid user program is
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** present and can be started.
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** \return BLT_TRUE if successful, BLT_FALSE otherwise.
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**
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****************************************************************************************/
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blt_bool FlashVerifyChecksum(void)
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{ |
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blt_int32u signature_checksum = 0;
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/* verify the checksum based on how it was written by CpuWriteChecksum() */
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signature_checksum += *((blt_int32u*)(flashLayout[0].sector_start));
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signature_checksum += *((blt_int32u*)(flashLayout[0].sector_start+0x04)); |
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signature_checksum += *((blt_int32u*)(flashLayout[0].sector_start+0x08)); |
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signature_checksum += *((blt_int32u*)(flashLayout[0].sector_start+0x0C)); |
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signature_checksum += *((blt_int32u*)(flashLayout[0].sector_start+0x10)); |
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signature_checksum += *((blt_int32u*)(flashLayout[0].sector_start+0x14)); |
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signature_checksum += *((blt_int32u*)(flashLayout[0].sector_start+0x18)); |
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signature_checksum += *((blt_int32u*)(flashLayout[0].sector_start+FLASH_VECTOR_TABLE_CS_OFFSET));
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/* sum should add up to an unsigned 32-bit value of 0 */
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if (signature_checksum == 0) |
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{ |
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/* checksum okay */
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return BLT_TRUE;
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} |
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/* checksum incorrect */
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return BLT_FALSE;
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} /*** end of FlashVerifyChecksum ***/
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/************************************************************************************//** |
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** \brief Finalizes the flash driver operations. There could still be data in
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** the currently active block that needs to be flashed.
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** \return BLT_TRUE if successful, BLT_FALSE otherwise.
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**
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****************************************************************************************/
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blt_bool FlashDone(void)
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{ |
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/* check if there is still data waiting to be programmed in the boot block */
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if (bootBlockInfo.base_addr != FLASH_INVALID_ADDRESS)
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{ |
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if (FlashWriteBlock(&bootBlockInfo) == BLT_FALSE)
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{ |
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return BLT_FALSE;
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} |
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} |
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/* check if there is still data waiting to be programmed */
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if (blockInfo.base_addr != FLASH_INVALID_ADDRESS)
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{ |
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if (FlashWriteBlock(&blockInfo) == BLT_FALSE)
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{ |
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return BLT_FALSE;
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} |
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} |
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/* still here so all is okay */
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return BLT_TRUE;
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} /*** end of FlashDone ***/
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/************************************************************************************//** |
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** \brief Obtains the base address of the flash memory available to the user program.
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** This is basically the first address in the flashLayout table.
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** \return Base address.
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**
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****************************************************************************************/
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blt_addr FlashGetUserProgBaseAddress(void)
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{ |
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return flashLayout[0].sector_start; |
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} /*** end of FlashGetUserProgBaseAddress ***/
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/************************************************************************************//** |
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** \brief Copies data currently in flash to the block->data and sets the
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** base address.
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** \param block Pointer to flash block info structure to operate on.
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** \param address Base address of the block data.
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** \return BLT_TRUE if successful, BLT_FALSE otherwise.
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**
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****************************************************************************************/
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static blt_bool FlashInitBlock(tFlashBlockInfo *block, blt_addr address)
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{ |
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/* check address alignment */
|
427 |
if ((address % FLASH_WRITE_BLOCK_SIZE) != 0) |
428 |
{ |
429 |
return BLT_FALSE;
|
430 |
} |
431 |
/* make sure that we are initializing a new block and not the same one */
|
432 |
if (block->base_addr == address)
|
433 |
{ |
434 |
/* block already initialized, so nothing to do */
|
435 |
return BLT_TRUE;
|
436 |
} |
437 |
/* set the base address and copies the current data from flash */
|
438 |
block->base_addr = address; |
439 |
CpuMemCopy((blt_addr)block->data, address, FLASH_WRITE_BLOCK_SIZE); |
440 |
return BLT_TRUE;
|
441 |
} /*** end of FlashInitBlock ***/
|
442 |
|
443 |
|
444 |
/************************************************************************************//** |
445 |
** \brief Switches blocks by programming the current one and initializing the
|
446 |
** next.
|
447 |
** \param block Pointer to flash block info structure to operate on.
|
448 |
** \param base_addr Base address of the next block.
|
449 |
** \return The pointer of the block info struct that is no being used, or a NULL
|
450 |
** pointer in case of error.
|
451 |
**
|
452 |
****************************************************************************************/
|
453 |
static tFlashBlockInfo *FlashSwitchBlock(tFlashBlockInfo *block, blt_addr base_addr)
|
454 |
{ |
455 |
/* check if a switch needs to be made away from the boot block. in this case the boot
|
456 |
* block shouldn't be written yet, because this is done at the end of the programming
|
457 |
* session by FlashDone(), this is right after the checksum was written.
|
458 |
*/
|
459 |
if (block == &bootBlockInfo)
|
460 |
{ |
461 |
/* switch from the boot block to the generic block info structure */
|
462 |
block = &blockInfo; |
463 |
} |
464 |
/* check if a switch back into the bootblock is needed. in this case the generic block
|
465 |
* doesn't need to be written here yet.
|
466 |
*/
|
467 |
else if (base_addr == flashLayout[0].sector_start) |
468 |
{ |
469 |
/* switch from the generic block to the boot block info structure */
|
470 |
block = &bootBlockInfo; |
471 |
base_addr = flashLayout[0].sector_start;
|
472 |
} |
473 |
else
|
474 |
{ |
475 |
/* need to switch to a new block, so program the current one and init the next */
|
476 |
if (FlashWriteBlock(block) == BLT_FALSE)
|
477 |
{ |
478 |
return BLT_NULL;
|
479 |
} |
480 |
} |
481 |
|
482 |
/* initialize tne new block when necessary */
|
483 |
if (FlashInitBlock(block, base_addr) == BLT_FALSE)
|
484 |
{ |
485 |
return BLT_NULL;
|
486 |
} |
487 |
|
488 |
/* still here to all is okay */
|
489 |
return block;
|
490 |
} /*** end of FlashSwitchBlock ***/
|
491 |
|
492 |
|
493 |
/************************************************************************************//** |
494 |
** \brief Programming is done per block. This function adds data to the block
|
495 |
** that is currently collecting data to be written to flash. If the
|
496 |
** address is outside of the current block, the current block is written
|
497 |
** to flash an a new block is initialized.
|
498 |
** \param block Pointer to flash block info structure to operate on.
|
499 |
** \param address Flash destination address.
|
500 |
** \param data Pointer to the byte array with data.
|
501 |
** \param len Number of bytes to add to the block.
|
502 |
** \return BLT_TRUE if successful, BLT_FALSE otherwise.
|
503 |
**
|
504 |
****************************************************************************************/
|
505 |
static blt_bool FlashAddToBlock(tFlashBlockInfo *block, blt_addr address,
|
506 |
blt_int8u *data, blt_int32u len) |
507 |
{ |
508 |
blt_addr current_base_addr; |
509 |
blt_int8u *dst; |
510 |
blt_int8u *src; |
511 |
|
512 |
/* determine the current base address */
|
513 |
current_base_addr = (address/FLASH_WRITE_BLOCK_SIZE)*FLASH_WRITE_BLOCK_SIZE; |
514 |
|
515 |
/* make sure the blockInfo is not uninitialized */
|
516 |
if (block->base_addr == FLASH_INVALID_ADDRESS)
|
517 |
{ |
518 |
/* initialize the blockInfo struct for the current block */
|
519 |
if (FlashInitBlock(block, current_base_addr) == BLT_FALSE)
|
520 |
{ |
521 |
return BLT_FALSE;
|
522 |
} |
523 |
} |
524 |
|
525 |
/* check if the new data fits in the current block */
|
526 |
if (block->base_addr != current_base_addr)
|
527 |
{ |
528 |
/* need to switch to a new block, so program the current one and init the next */
|
529 |
block = FlashSwitchBlock(block, current_base_addr); |
530 |
if (block == BLT_NULL)
|
531 |
{ |
532 |
return BLT_FALSE;
|
533 |
} |
534 |
} |
535 |
|
536 |
/* add the data to the current block, but check for block overflow */
|
537 |
dst = &(block->data[address - block->base_addr]); |
538 |
src = data; |
539 |
do
|
540 |
{ |
541 |
/* keep the watchdog happy */
|
542 |
CopService(); |
543 |
/* buffer overflow? */
|
544 |
if ((blt_addr)(dst-&(block->data[0])) >= FLASH_WRITE_BLOCK_SIZE) |
545 |
{ |
546 |
/* need to switch to a new block, so program the current one and init the next */
|
547 |
block = FlashSwitchBlock(block, current_base_addr+FLASH_WRITE_BLOCK_SIZE); |
548 |
if (block == BLT_NULL)
|
549 |
{ |
550 |
return BLT_FALSE;
|
551 |
} |
552 |
/* reset destination pointer */
|
553 |
dst = &(block->data[0]);
|
554 |
} |
555 |
/* write the data to the buffer */
|
556 |
*dst = *src; |
557 |
/* update pointers */
|
558 |
dst++; |
559 |
src++; |
560 |
/* decrement byte counter */
|
561 |
len--; |
562 |
} |
563 |
while (len > 0); |
564 |
/* still here so all is good */
|
565 |
return BLT_TRUE;
|
566 |
} /*** end of FlashAddToBlock ***/
|
567 |
|
568 |
|
569 |
/************************************************************************************//** |
570 |
** \brief Programs FLASH_WRITE_BLOCK_SIZE bytes to flash from the block->data
|
571 |
** array.
|
572 |
** \param block Pointer to flash block info structure to operate on.
|
573 |
** \return BLT_TRUE if successful, BLT_FALSE otherwise.
|
574 |
**
|
575 |
****************************************************************************************/
|
576 |
static blt_bool FlashWriteBlock(tFlashBlockInfo *block)
|
577 |
{ |
578 |
blt_int8u sector_num; |
579 |
blt_bool result = BLT_TRUE; |
580 |
blt_addr prog_addr; |
581 |
blt_int32u prog_data; |
582 |
blt_int32u word_cnt; |
583 |
|
584 |
/* check that address is actually within flash */
|
585 |
sector_num = FlashGetSector(block->base_addr); |
586 |
if (sector_num == FLASH_INVALID_SECTOR)
|
587 |
{ |
588 |
return BLT_FALSE;
|
589 |
} |
590 |
/* unlock the flash array */
|
591 |
FLASH_Unlock(); |
592 |
/* clear pending flags (if any) */
|
593 |
FLASH_ClearFlag(FLASH_FLAG_EOP | FLASH_FLAG_OPERR | FLASH_FLAG_WRPERR | |
594 |
FLASH_FLAG_PGAERR | FLASH_FLAG_PGPERR|FLASH_FLAG_PGSERR); |
595 |
/* check that the flash peripheral is not busy */
|
596 |
if (FLASH_GetStatus() == FLASH_BUSY)
|
597 |
{ |
598 |
/* lock the flash array again */
|
599 |
FLASH_Lock(); |
600 |
/* could not perform erase operation */
|
601 |
return BLT_FALSE;
|
602 |
} |
603 |
/* program all words in the block one by one */
|
604 |
for (word_cnt=0; word_cnt<(FLASH_WRITE_BLOCK_SIZE/sizeof(blt_int32u)); word_cnt++) |
605 |
{ |
606 |
prog_addr = block->base_addr + (word_cnt * sizeof(blt_int32u));
|
607 |
prog_data = *(volatile blt_int32u*)(&block->data[word_cnt * sizeof(blt_int32u)]); |
608 |
/* keep the watchdog happy */
|
609 |
CopService(); |
610 |
/* program the word */
|
611 |
if (FLASH_ProgramWord(prog_addr, prog_data) != FLASH_COMPLETE)
|
612 |
{ |
613 |
result = BLT_FALSE; |
614 |
break;
|
615 |
} |
616 |
/* verify that the written data is actually there */
|
617 |
if (*(volatile blt_int32u*)prog_addr != prog_data) |
618 |
{ |
619 |
result = BLT_FALSE; |
620 |
break;
|
621 |
} |
622 |
} |
623 |
/* lock the flash array again */
|
624 |
FLASH_Lock(); |
625 |
/* still here so all is okay */
|
626 |
return result;
|
627 |
} /*** end of FlashWriteBlock ***/
|
628 |
|
629 |
|
630 |
/************************************************************************************//** |
631 |
** \brief Erases the flash sectors from first_sector up until last_sector.
|
632 |
** \param first_sector First flash sector number.
|
633 |
** \param last_sector Last flash sector number.
|
634 |
** \return BLT_TRUE if successful, BLT_FALSE otherwise.
|
635 |
**
|
636 |
****************************************************************************************/
|
637 |
static blt_bool FlashEraseSectors(blt_int8u first_sector, blt_int8u last_sector)
|
638 |
{ |
639 |
blt_int8u sector_cnt; |
640 |
|
641 |
/* validate the sector numbers */
|
642 |
if (first_sector > last_sector)
|
643 |
{ |
644 |
return BLT_FALSE;
|
645 |
} |
646 |
if ( (first_sector < flashLayout[0].sector_num) || \ |
647 |
(last_sector > flashLayout[FLASH_TOTAL_SECTORS-1].sector_num) )
|
648 |
{ |
649 |
return BLT_FALSE;
|
650 |
} |
651 |
/* unlock the flash array */
|
652 |
FLASH_Unlock(); |
653 |
/* clear pending flags (if any) */
|
654 |
FLASH_ClearFlag(FLASH_FLAG_EOP | FLASH_FLAG_OPERR | FLASH_FLAG_WRPERR | |
655 |
FLASH_FLAG_PGAERR | FLASH_FLAG_PGPERR|FLASH_FLAG_PGSERR); |
656 |
/* check that the flash peripheral is not busy */
|
657 |
if (FLASH_GetStatus() == FLASH_BUSY)
|
658 |
{ |
659 |
/* lock the flash array again */
|
660 |
FLASH_Lock(); |
661 |
/* could not perform erase operation */
|
662 |
return BLT_FALSE;
|
663 |
} |
664 |
/* erase all sectors one by one */
|
665 |
for (sector_cnt=first_sector; sector_cnt<= last_sector; sector_cnt++)
|
666 |
{ |
667 |
/* keep the watchdog happy */
|
668 |
CopService(); |
669 |
/* submit the sector erase request */
|
670 |
if (FLASH_EraseSector(flashSectorNumToMask[sector_cnt], VoltageRange_3) != FLASH_COMPLETE)
|
671 |
{ |
672 |
/* lock the flash array again */
|
673 |
FLASH_Lock(); |
674 |
/* could not perform erase operation */
|
675 |
return BLT_FALSE;
|
676 |
} |
677 |
} |
678 |
/* lock the flash array again */
|
679 |
FLASH_Lock(); |
680 |
/* still here so all went okay */
|
681 |
return BLT_TRUE;
|
682 |
} /*** end of FlashEraseSectors ***/
|
683 |
|
684 |
|
685 |
/************************************************************************************//** |
686 |
** \brief Determines the flash sector the address is in.
|
687 |
** \param address Address in the flash sector.
|
688 |
** \return Flash sector number or FLASH_INVALID_SECTOR.
|
689 |
**
|
690 |
****************************************************************************************/
|
691 |
static blt_int8u FlashGetSector(blt_addr address)
|
692 |
{ |
693 |
blt_int8u sectorIdx; |
694 |
|
695 |
/* search through the sectors to find the right one */
|
696 |
for (sectorIdx = 0; sectorIdx < FLASH_TOTAL_SECTORS; sectorIdx++) |
697 |
{ |
698 |
/* keep the watchdog happy */
|
699 |
CopService(); |
700 |
/* is the address in this sector? */
|
701 |
if ( (address >= flashLayout[sectorIdx].sector_start) && \
|
702 |
(address < (flashLayout[sectorIdx].sector_start + \ |
703 |
flashLayout[sectorIdx].sector_size)) ) |
704 |
{ |
705 |
/* return the sector number */
|
706 |
return flashLayout[sectorIdx].sector_num;
|
707 |
} |
708 |
} |
709 |
/* still here so no valid sector found */
|
710 |
return FLASH_INVALID_SECTOR;
|
711 |
} /*** end of FlashGetSector ***/
|
712 |
|
713 |
|
714 |
/*********************************** end of flash.c ************************************/
|