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8aec8807c9
A whole bunch of files in this project had DOS line endings. This is due to how I started working on it on a Windows machine with little Git experience. Now it's inconsistent so I'm fixing it.
430 lines
13 KiB
C
430 lines
13 KiB
C
/*
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* parallel_flash.c
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*
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* Created on: Nov 25, 2011
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* Author: Doug
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*
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* Copyright (C) 2011-2020 Doug Brown
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*
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* This program is free software; you can redistribute it and/or
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* modify it under the terms of the GNU General Public License
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* as published by the Free Software Foundation; either version 2
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* of the License, or (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* 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
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* along with this program; if not, write to the Free Software
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* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
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*
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*/
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#include "parallel_flash.h"
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#include "../util.h"
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/// Erasable sector size in SST39SF040
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#define SECTOR_SIZE_SST39SF040 (4*1024UL)
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/// Erasable sector size in M29F160FB5AN6E2, 8-bit mode
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#define SECTOR_SIZE_M29F160FB5AN6E2_8 (64*1024UL)
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static uint32_t ParallelFlash_MaskForChips(uint8_t chips);
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static ALWAYS_INLINE void ParallelFlash_WaitForCompletion(void);
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static ALWAYS_INLINE uint32_t ParallelFlash_UnlockAddress1(void);
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/// The type/arrangement of parallel flash chips we are talking to
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static ParallelFlashChipType curChipType = ParallelFlash_SST39SF040_x4;
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/** Sets the type/arrangement of parallel flash chips we are talking to
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*
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* @param type The type/arrangement of flash chips
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*/
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void ParallelFlash_SetChipType(ParallelFlashChipType type)
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{
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curChipType = type;
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}
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/** Gets the type/arrangement of parallel flash chips we are talking to
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*
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* @return The current type/arrangement of flash chips
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*/
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ParallelFlashChipType ParallelFlash_ChipType(void)
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{
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return curChipType;
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}
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/** Reads data from the flash chip
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*
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* @param startAddress The address for reading
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* @param buf The buffer to read to
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* @param len The number of bytes to read
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*/
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void ParallelFlash_Read(uint32_t startAddress, uint32_t *buf, uint16_t len)
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{
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// Just forward this request directly onto the parallel bus. Nothing
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// special is required for reading a chunk of data.
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ParallelBus_Read(startAddress, buf, len);
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}
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/** Unlocks the flash chips using the special write sequence
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*
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* @param chipsMask The mask of which chips to unlock
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*/
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void ParallelFlash_UnlockChips(uint8_t chipsMask)
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{
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// Use a mask so we don't unlock chips we don't want to talk with
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uint32_t mask = ParallelFlash_MaskForChips(chipsMask);
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uint32_t unlockAddress = ParallelFlash_UnlockAddress1();
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// First part of unlock sequence:
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// Write 0x55555555 to the address bus and 0xAA to the data bus
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// (Some datasheets may only say 0x555 or 0x5555, but they ignore
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// the upper bits, so writing the alternating pattern to all address lines
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// should make it compatible with larger chips).
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ParallelBus_WriteCycle(unlockAddress, 0xAAAAAAAAUL & mask);
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// Second part of unlock sequence is the same thing, but reversed.
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ParallelBus_WriteCycle(~unlockAddress, 0x55555555UL & mask);
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}
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/** Reads the ID of the chips
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*
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* @param Pointer to variable for storing ID info about each chip
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*/
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void ParallelFlash_IdentifyChips(ParallelFlashChipID *chips)
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{
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// Start by writing the unlock sequence to ALL chips
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ParallelFlash_UnlockChips(ALL_CHIPS);
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// Write 0x90 to the first unlock address for the identify command...
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ParallelBus_WriteCycle(ParallelFlash_UnlockAddress1(), 0x90909090UL);
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// Now we can read the vendor and product ID from addresses 0 and 1
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// (or 1 and 2 if we're using the M29F160FB5AN6E2 in 8-bit mode).
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// Note: The Micron datasheet says it requires 12V to be applied to A9
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// in order for the identification command to work properly, but in
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// practice the identification process works fine without it.
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uint32_t vendorAddress = curChipType != ParallelFlash_M29F160FB5AN6E2_x4 ?
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0 : 1;
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uint32_t manufacturers = ParallelBus_ReadCycle(vendorAddress);
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uint32_t devices = ParallelBus_ReadCycle(vendorAddress + 1);
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for (int8_t i = 0; i < PARALLEL_FLASH_NUM_CHIPS; i++)
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{
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uint8_t manufacturer = (uint8_t)(manufacturers >> (8 * i));
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uint8_t device = (uint8_t)(devices >> (8 * i));
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chips[PARALLEL_FLASH_NUM_CHIPS - i - 1].manufacturer = manufacturer;
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chips[PARALLEL_FLASH_NUM_CHIPS - i - 1].device = device;
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}
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// Exit software ID mode
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ParallelBus_WriteCycle(0, 0xF0F0F0F0UL);
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}
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/** Erases the specified chips
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*
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* @param chipsMask The mask of which chips to erase
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*/
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void ParallelFlash_EraseChips(uint8_t chipsMask)
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{
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uint32_t unlockAddress = ParallelFlash_UnlockAddress1();
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ParallelFlash_UnlockChips(chipsMask);
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ParallelBus_WriteCycle(unlockAddress, 0x80808080UL);
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ParallelFlash_UnlockChips(chipsMask);
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ParallelBus_WriteCycle(unlockAddress, 0x10101010UL);
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ParallelFlash_WaitForCompletion();
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}
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/** Erases only the range of sectors specified in the specified chips
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*
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* @param address The start address to erase (must be aligned to a sector boundary)
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* @param length The number of bytes to erase (must be aligned to a sector boundary)
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* @param chipsMask The mask of which chips to erase
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* @return True on success, false on failure
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*/
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bool ParallelFlash_EraseSectors(uint32_t address, uint32_t length, uint8_t chipsMask)
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{
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bool result = false;
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// Figure out our sector size
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uint32_t sectorSize;
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switch (curChipType)
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{
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case ParallelFlash_SST39SF040_x4:
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default:
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sectorSize = SECTOR_SIZE_SST39SF040;
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break;
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case ParallelFlash_M29F160FB5AN6E2_x4:
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sectorSize = SECTOR_SIZE_M29F160FB5AN6E2_8;
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break;
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}
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// Make sure the area requested to be erased is on good boundaries
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if ((address % sectorSize) ||
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(length % sectorSize))
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{
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return false;
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}
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// We're good to go. Let's do it. The process varies based on the chip type
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if (curChipType == ParallelFlash_SST39SF040_x4)
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{
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// This chip sucks because you have to erase each sector with its own
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// complete erase unlock command, which can take a while. At least
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// individual erase operations are much faster on this chip...
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while (length)
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{
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// Start the erase command
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ParallelFlash_UnlockChips(chipsMask);
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ParallelBus_WriteCycle(ParallelFlash_UnlockAddress1(), 0x80808080UL);
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ParallelFlash_UnlockChips(chipsMask);
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// Now provide a sector address, but only one. Then the whole
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// unlock sequence has to be done again after this sector is done.
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ParallelBus_WriteCycle(address, 0x30303030UL);
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address += sectorSize;
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length -= sectorSize;
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// Wait for completion of this individual erase operation before
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// we can start a new erase operation.
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ParallelFlash_WaitForCompletion();
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}
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result = true;
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}
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else if (curChipType == ParallelFlash_M29F160FB5AN6E2_x4)
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{
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// This chip is nicer because it can take all the sector addresses at
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// once and then do the final erase operation in one fell swoop.
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// Start the erase command
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ParallelFlash_UnlockChips(chipsMask);
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ParallelBus_WriteCycle(ParallelFlash_UnlockAddress1(), 0x80808080UL);
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ParallelFlash_UnlockChips(chipsMask);
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// Now provide as many sector addresses as needed to erase.
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// The first address is a bit of a special case because the boot sector
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// actually has finer granularity for sector sizes.
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if (address == 0)
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{
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ParallelBus_WriteCycle(0x00000000UL, 0x30303030UL);
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ParallelBus_WriteCycle(0x00004000UL, 0x30303030UL);
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ParallelBus_WriteCycle(0x00006000UL, 0x30303030UL);
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ParallelBus_WriteCycle(0x00008000UL, 0x30303030UL);
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address += sectorSize;
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length -= sectorSize;
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}
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// The remaining sectors can use a more generic algorithm
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while (length)
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{
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ParallelBus_WriteCycle(address, 0x30303030UL);
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address += sectorSize;
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length -= sectorSize;
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}
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// Wait for completion of the entire erase operation
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ParallelFlash_WaitForCompletion();
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result = true;
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}
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return result;
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}
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/** Writes a buffer of data to all 4 chips simultaneously
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*
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* @param startAddress The starting address to write in flash
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* @param buf The buffer to write
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* @param len The length of data to write
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*
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* The API may look silly to have broken into different functions like this, but
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* it's a performance optimization. It means we don't have to check during every
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* byte write to see the chip unlock mask. It saves a bunch of time.
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*/
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void ParallelFlash_WriteAllChips(uint32_t startAddress, uint32_t const *buf, uint16_t len)
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{
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uint32_t unlockAddress = ParallelFlash_UnlockAddress1();
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// Normal write process used by most parallel flashes
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if (curChipType != ParallelFlash_M29F160FB5AN6E2_x4)
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{
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while (len--)
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{
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// Write this byte.
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// Unlock...and don't use the unlock function because this one
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// is more efficient knowing the mask is 0xFFFFFFFF
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ParallelBus_WriteCycle(unlockAddress, 0xAAAAAAAAUL);
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ParallelBus_WriteCycle(~unlockAddress, 0x55555555UL);
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ParallelBus_WriteCycle(unlockAddress, 0xA0A0A0A0UL);
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ParallelBus_WriteCycle(startAddress, *buf);
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ParallelFlash_WaitForCompletion();
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startAddress++;
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buf++;
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}
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}
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// Optimized write process available on the M29F160FB5AN6E2, requires
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// fewer write cycles per byte if you know you're writing multiple bytes.
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else
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{
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// Do an unlock bypass command so that we can write bytes faster.
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// Writes will only require 2 write cycles instead of 4
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ParallelBus_WriteCycle(unlockAddress, 0xAAAAAAAAUL);
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ParallelBus_WriteCycle(~unlockAddress, 0x55555555UL);
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ParallelBus_WriteCycle(unlockAddress, 0x20202020UL);
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while (len--)
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{
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// Write this byte.
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ParallelBus_WriteCycle(0, 0xA0A0A0A0UL);
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ParallelBus_WriteCycle(startAddress, *buf);
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ParallelFlash_WaitForCompletion();
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startAddress++;
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buf++;
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}
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// When we're all done, do "unlock bypass reset" to exit from
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// programming mode
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ParallelBus_WriteCycle(0, 0x90909090UL);
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ParallelBus_WriteCycle(0, 0x00000000UL);
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}
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}
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/** Writes a buffer of data to the specified chips simultaneously
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*
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* @param startAddress The starting address to write in flash
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* @param buf The buffer to write
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* @param len The length of data to write
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* @param chipsMask The mask of which chips to write
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*/
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void ParallelFlash_WriteSomeChips(uint32_t startAddress, uint32_t const *buf, uint16_t len, uint8_t chipsMask)
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{
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uint32_t unlockAddress = ParallelFlash_UnlockAddress1();
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// Normal write process used by most parallel flashes
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if (curChipType != ParallelFlash_M29F160FB5AN6E2_x4)
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{
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while (len--)
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{
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// Write this byte.
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ParallelFlash_UnlockChips(chipsMask);
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ParallelBus_WriteCycle(unlockAddress, 0xA0A0A0A0UL);
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ParallelBus_WriteCycle(startAddress, *buf);
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ParallelFlash_WaitForCompletion();
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startAddress++;
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buf++;
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}
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}
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// Optimized write process available on the M29F160FB5AN6E2, requires
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// fewer write cycles per byte if you know you're writing multiple bytes.
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else
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{
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// Do an unlock bypass command so that we can write bytes faster.
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// Writes will only require 2 write cycles instead of 4
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ParallelFlash_UnlockChips(chipsMask);
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ParallelBus_WriteCycle(unlockAddress, 0x20202020UL);
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while (len--)
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{
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// Write this byte.
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ParallelBus_WriteCycle(0, 0xA0A0A0A0UL);
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ParallelBus_WriteCycle(startAddress, *buf);
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ParallelFlash_WaitForCompletion();
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startAddress++;
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buf++;
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}
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// When we're all done, do "unlock bypass reset" to exit from
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// programming mode
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ParallelBus_WriteCycle(0, 0x90909090UL);
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ParallelBus_WriteCycle(0, 0x00000000UL);
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}
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}
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/** Calculates a 32-bit mask to use with the unlock process when unlocking chips
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*
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* @param chipsMask The mask of which chips to write
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* @return A 32-bit mask that can be used on the data bus to filter out the unlock sequence
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*
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* For clarity, chipsMask has 1 bit per chip. The return value has 1 byte per
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* chip. The return value masks the unlock sequence so we only supply a valid
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* unlock sequence to the chips that we want to unlock.
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*/
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static uint32_t ParallelFlash_MaskForChips(uint8_t chips)
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{
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// Calculates a mask so we can filter out chips we don't care about.
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// Optimization because we typically don't mask the chips
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if (chips == 0x0F)
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{
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return 0xFFFFFFFFUL;
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}
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// This probably looks dumb not doing this as a loop...but AVR GCC is
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// terrible. This approach results in more optimal generated instructions.
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uint32_t mask = 0;
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if (chips & (1 << 0))
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{
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mask |= 0x000000FFUL;
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}
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if (chips & (1 << 1))
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{
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mask |= 0x0000FF00UL;
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}
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if (chips & (1 << 2))
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{
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mask |= 0x00FF0000UL;
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}
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if (chips & (1 << 3))
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{
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mask |= 0xFF000000UL;
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}
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return mask;
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}
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/** Waits for an erase or write operation on the flash chip to complete.
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*
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* We know we're done when the value we read from the chip stops changing. There
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* is a "toggle" status bit that will stop toggling when the op is complete.
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*/
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static ALWAYS_INLINE void ParallelFlash_WaitForCompletion(void)
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{
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uint32_t readback = ParallelBus_ReadCycle(0);
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uint32_t next = ParallelBus_ReadCycle(0);
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while (next != readback)
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{
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readback = next;
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next = ParallelBus_ReadCycle(0);
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}
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}
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/** Gets the first unlock address to use when unlocking writes on this chip
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*
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* @return The first unlock address.
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*
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* Note: The second unlock address is the bitwise NOT of this address.
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*/
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static ALWAYS_INLINE uint32_t ParallelFlash_UnlockAddress1(void)
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{
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// Most chips use alternating bits, with A0 being a 1 bit
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if (curChipType != ParallelFlash_M29F160FB5AN6E2_x4)
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{
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return 0x55555555UL;
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}
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// The M29F160FB5AN6E2 is weird because it's an 8-/16-bit chip. In 8-bit
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// mode it has an "A-1" pin that we treat as A0, then the chip's A0 pin is
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// really our A1, and so on. The unlock sequence still starts on the chip's
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// physical pin A0, so effectively the unlock address is inverted.
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else
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{
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return 0xAAAAAAAAUL;
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}
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}
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