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376 lines
12 KiB
C
376 lines
12 KiB
C
/*
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cache.c
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The cache is not visible to the user. It should be flushed
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when any file is closed or changes are made to the filesystem.
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This cache implements a least-used-page replacement policy. This will
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distribute sectors evenly over the pages, so if less than the maximum
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pages are used at once, they should all eventually remain in the cache.
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This also has the benefit of throwing out old sectors, so as not to keep
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too many stale pages around.
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Copyright (c) 2006 Michael "Chishm" Chisholm
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Redistribution and use in source and binary forms, with or without modification,
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are permitted provided that the following conditions are met:
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1. Redistributions of source code must retain the above copyright notice,
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this list of conditions and the following disclaimer.
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2. Redistributions in binary form must reproduce the above copyright notice,
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this list of conditions and the following disclaimer in the documentation and/or
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other materials provided with the distribution.
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3. The name of the author may not be used to endorse or promote products derived
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from this software without specific prior written permission.
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THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR IMPLIED
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WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY
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AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR BE
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LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
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DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
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LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
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THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
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(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE,
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EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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*/
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#include <string.h>
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#include <limits.h>
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#include "common.h"
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#include "cache.h"
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#include "disc.h"
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#include "mem_allocate.h"
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#include "bit_ops.h"
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#include "file_allocation_table.h"
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#define CACHE_FREE UINT_MAX
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CACHE* _FAT_cache_constructor (unsigned int numberOfPages, unsigned int sectorsPerPage, const DISC_INTERFACE* discInterface) {
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CACHE* cache;
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unsigned int i;
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CACHE_ENTRY* cacheEntries;
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if (numberOfPages < 2) {
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numberOfPages = 2;
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}
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if (sectorsPerPage < 8) {
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sectorsPerPage = 8;
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}
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cache = (CACHE*) _FAT_mem_allocate (sizeof(CACHE));
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if (cache == NULL) {
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return NULL;
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}
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cache->disc = discInterface;
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cache->numberOfPages = numberOfPages;
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cache->sectorsPerPage = sectorsPerPage;
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cacheEntries = (CACHE_ENTRY*) _FAT_mem_allocate ( sizeof(CACHE_ENTRY) * numberOfPages);
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if (cacheEntries == NULL) {
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_FAT_mem_free (cache);
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return NULL;
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}
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for (i = 0; i < numberOfPages; i++) {
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cacheEntries[i].sector = CACHE_FREE;
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cacheEntries[i].count = 0;
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cacheEntries[i].last_access = 0;
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cacheEntries[i].dirty = false;
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cacheEntries[i].cache = (uint8_t*) _FAT_mem_align ( sectorsPerPage * BYTES_PER_READ );
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}
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cache->cacheEntries = cacheEntries;
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return cache;
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}
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void _FAT_cache_destructor (CACHE* cache) {
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unsigned int i;
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// Clear out cache before destroying it
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_FAT_cache_flush(cache);
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// Free memory in reverse allocation order
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for (i = 0; i < cache->numberOfPages; i++) {
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_FAT_mem_free (cache->cacheEntries[i].cache);
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}
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_FAT_mem_free (cache->cacheEntries);
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_FAT_mem_free (cache);
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}
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static u32 accessCounter = 0;
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static u32 accessTime(){
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return accessCounter;
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}
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/*
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Retrieve a sector's page from the cache. If it is not found in the cache,
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load it into the cache and return the page it was loaded to.
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Return CACHE_FREE on error.
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*/
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static unsigned int _FAT_cache_getSector (CACHE* cache, sec_t sector, void* buffer) {
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unsigned int i;
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CACHE_ENTRY* cacheEntries = cache->cacheEntries;
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unsigned int numberOfPages = cache->numberOfPages;
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unsigned int sectorsPerPage = cache->sectorsPerPage;
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unsigned int oldUsed = 0;
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unsigned int oldAccess = cacheEntries[0].last_access;
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for (i = 0; i < numberOfPages ; i++) {
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if ( sector>=cacheEntries[i].sector && sector < cacheEntries[i].sector+cacheEntries[i].count) {
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cacheEntries[i].last_access = accessTime();
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memcpy(buffer, cacheEntries[i].cache + ((sector - cacheEntries[i].sector)*BYTES_PER_READ), BYTES_PER_READ);
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return true;
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}
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// While searching for the desired sector, also search for the least recently used page
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if ( (cacheEntries[i].sector == CACHE_FREE) || (cacheEntries[i].last_access < oldAccess) ) {
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oldUsed = i;
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oldAccess = cacheEntries[i].last_access;
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}
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}
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// If it didn't, replace the least used cache page with the desired sector
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if ((cacheEntries[oldUsed].sector != CACHE_FREE) && (cacheEntries[oldUsed].dirty == true)) {
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// Write the page back to disc if it has been written to
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if (!_FAT_disc_writeSectors (cache->disc, cacheEntries[oldUsed].sector, cacheEntries[oldUsed].count, cacheEntries[oldUsed].cache)) {
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return false;
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}
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cacheEntries[oldUsed].dirty = false;
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}
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// Load the new sector into the cache
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if (!_FAT_disc_readSectors (cache->disc, sector, sectorsPerPage, cacheEntries[oldUsed].cache)) {
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return false;
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}
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cacheEntries[oldUsed].sector = sector;
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cacheEntries[oldUsed].count = sectorsPerPage;
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// Increment the usage count, don't reset it
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// This creates a paging policy of least recently used PAGE, not sector
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cacheEntries[oldUsed].last_access = accessTime();
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memcpy(buffer, cacheEntries[oldUsed].cache, BYTES_PER_READ);
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return true;
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}
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bool _FAT_cache_getSectors (CACHE* cache, sec_t sector, sec_t numSectors, void* buffer) {
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unsigned int i;
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CACHE_ENTRY* cacheEntries = cache->cacheEntries;
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unsigned int numberOfPages = cache->numberOfPages;
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sec_t sec;
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sec_t secs_to_read;
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unsigned int oldUsed = 0;
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unsigned int oldAccess = cacheEntries[0].last_access;
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accessCounter++;
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while(numSectors>0)
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{
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i=0;
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while (i < numberOfPages ) {
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if ( sector>=cacheEntries[i].sector && sector < cacheEntries[i].sector+cacheEntries[i].count) {
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sec=sector-cacheEntries[i].sector;
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secs_to_read=cacheEntries[i].count-sec;
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if(secs_to_read>numSectors)secs_to_read=numSectors;
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memcpy(buffer,cacheEntries[i].cache + (sec*BYTES_PER_READ), secs_to_read*BYTES_PER_READ);
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cacheEntries[i].last_access = accessTime();
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numSectors=numSectors-secs_to_read;
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if(numSectors==0) return true;
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buffer+=secs_to_read*BYTES_PER_READ;
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sector+=secs_to_read;
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i=-1; // recheck all pages again
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oldUsed = 0;
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oldAccess = cacheEntries[0].last_access;
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}
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else // While searching for the desired sector, also search for the least recently used page
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if ( (cacheEntries[i].sector == CACHE_FREE) || (cacheEntries[i].last_access < oldAccess) ) {
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oldUsed = i;
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oldAccess = cacheEntries[i].last_access;
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}
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i++;
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}
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// If it didn't, replace the least recently used cache page with the desired sector
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if ((cacheEntries[oldUsed].sector != CACHE_FREE) && (cacheEntries[oldUsed].dirty == true)) {
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// Write the page back to disc if it has been written to
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if (!_FAT_disc_writeSectors (cache->disc, cacheEntries[oldUsed].sector, cacheEntries[oldUsed].count, cacheEntries[oldUsed].cache)) {
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return false;
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}
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cacheEntries[oldUsed].dirty = false;
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}
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cacheEntries[oldUsed].count = cache->sectorsPerPage;
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if (!_FAT_disc_readSectors (cache->disc, sector, cacheEntries[oldUsed].count, cacheEntries[oldUsed].cache)) {
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return false;
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}
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cacheEntries[oldUsed].sector = sector;
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// Increment the usage count, don't reset it
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// This creates a paging policy of least used PAGE, not sector
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cacheEntries[oldUsed].last_access = accessTime();
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sec=0;
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secs_to_read=cacheEntries[oldUsed].count-sec;
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if(secs_to_read>numSectors)secs_to_read=numSectors;
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memcpy(buffer,cacheEntries[oldUsed].cache + (sec*BYTES_PER_READ), secs_to_read*BYTES_PER_READ);
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numSectors=numSectors-secs_to_read;
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if(numSectors==0) return true;
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buffer+=secs_to_read*BYTES_PER_READ;
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sector+=secs_to_read;
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oldUsed = 0;
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oldAccess = cacheEntries[0].last_access;
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}
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return false;
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}
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/*
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Reads some data from a cache page, determined by the sector number
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*/
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bool _FAT_cache_readPartialSector (CACHE* cache, void* buffer, sec_t sector, unsigned int offset, size_t size) {
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void* sec;
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if (offset + size > BYTES_PER_READ) {
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return false;
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}
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sec = (void*) _FAT_mem_align ( BYTES_PER_READ );
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if(sec == NULL) return false;
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if(! _FAT_cache_getSector(cache, sector, sec) ) {
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_FAT_mem_free(sec);
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return false;
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}
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memcpy(buffer, sec + offset, size);
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_FAT_mem_free(sec);
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return true;
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}
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bool _FAT_cache_readLittleEndianValue (CACHE* cache, uint32_t *value, sec_t sector, unsigned int offset, int num_bytes) {
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uint8_t buf[4];
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if (!_FAT_cache_readPartialSector(cache, buf, sector, offset, num_bytes)) return false;
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switch(num_bytes) {
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case 1: *value = buf[0]; break;
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case 2: *value = u8array_to_u16(buf,0); break;
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case 4: *value = u8array_to_u32(buf,0); break;
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default: return false;
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}
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return true;
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}
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/*
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Writes some data to a cache page, making sure it is loaded into memory first.
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*/
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bool _FAT_cache_writePartialSector (CACHE* cache, const void* buffer, sec_t sector, unsigned int offset, size_t size) {
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unsigned int i;
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void* sec;
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CACHE_ENTRY* cacheEntries = cache->cacheEntries;
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unsigned int numberOfPages = cache->numberOfPages;
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if (offset + size > BYTES_PER_READ) {
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return false;
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}
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//To be sure sector is in cache
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sec = (void*) _FAT_mem_align ( BYTES_PER_READ );
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if(sec == NULL) return false;
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if(! _FAT_cache_getSector(cache, sector, sec) ) {
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_FAT_mem_free(sec);
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return false;
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}
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_FAT_mem_free(sec);
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//Find where sector is and write
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for (i = 0; i < numberOfPages ; i++) {
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if ( sector>=cacheEntries[i].sector && sector < cacheEntries[i].sector+cacheEntries[i].count) {
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cacheEntries[i].last_access = accessTime();
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memcpy (cacheEntries[i].cache + ((sector-cacheEntries[i].sector)*BYTES_PER_READ) + offset, buffer, size);
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cache->cacheEntries[i].dirty = true;
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return true;
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}
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}
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return false;
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}
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bool _FAT_cache_writeLittleEndianValue (CACHE* cache, const uint32_t value, sec_t sector, unsigned int offset, int size) {
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uint8_t buf[4] = {0, 0, 0, 0};
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switch(size) {
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case 1: buf[0] = value; break;
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case 2: u16_to_u8array(buf, 0, value); break;
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case 4: u32_to_u8array(buf, 0, value); break;
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default: return false;
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}
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return _FAT_cache_writePartialSector(cache, buf, sector, offset, size);
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}
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/*
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Writes some data to a cache page, zeroing out the page first
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*/
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bool _FAT_cache_eraseWritePartialSector (CACHE* cache, const void* buffer, sec_t sector, unsigned int offset, size_t size) {
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unsigned int i;
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void* sec;
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CACHE_ENTRY* cacheEntries = cache->cacheEntries;
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unsigned int numberOfPages = cache->numberOfPages;
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if (offset + size > BYTES_PER_READ) {
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return false;
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}
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//To be sure sector is in cache
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sec = (void*) _FAT_mem_align ( BYTES_PER_READ );
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if(sec == NULL) return false;
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if(! _FAT_cache_getSector(cache, sector, sec) ) {
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_FAT_mem_free(sec);
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return false;
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}
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_FAT_mem_free(sec);
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//Find where sector is and write
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for (i = 0; i < numberOfPages ; i++) {
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if ( sector>=cacheEntries[i].sector && sector < cacheEntries[i].sector+cacheEntries[i].count) {
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cacheEntries[i].last_access = accessTime();
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memset (cacheEntries[i].cache + ((sector-cacheEntries[i].sector)*BYTES_PER_READ), 0, BYTES_PER_READ);
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memcpy (cacheEntries[i].cache + ((sector-cacheEntries[i].sector)*BYTES_PER_READ) + offset, buffer, size);
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cache->cacheEntries[i].dirty = true;
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return true;
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}
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}
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return false;
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}
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/*
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Flushes all dirty pages to disc, clearing the dirty flag.
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*/
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bool _FAT_cache_flush (CACHE* cache) {
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unsigned int i;
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for (i = 0; i < cache->numberOfPages; i++) {
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if (cache->cacheEntries[i].dirty) {
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if (!_FAT_disc_writeSectors (cache->disc, cache->cacheEntries[i].sector, cache->cacheEntries[i].count, cache->cacheEntries[i].cache)) {
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return false;
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}
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}
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cache->cacheEntries[i].dirty = false;
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}
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return true;
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}
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void _FAT_cache_invalidate (CACHE* cache) {
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unsigned int i;
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_FAT_cache_flush(cache);
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for (i = 0; i < cache->numberOfPages; i++) {
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cache->cacheEntries[i].sector = CACHE_FREE;
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cache->cacheEntries[i].last_access = 0;
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cache->cacheEntries[i].count = 0;
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cache->cacheEntries[i].dirty = false;
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}
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}
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