581081a3df
This uses an equivalent algorithm but with a different initial value than we normally use (all bits off vs all bits on). Use the new crc_32r to replace the original MI4 crc32 implementation. This frees up some extra space on mi4 targets which gives us more room on a few very space constrained targets (sansa c200/e200, etc). Change-Id: Iaaac3ae353b30566156b1404cbf31ca32926203d
503 lines
15 KiB
C
503 lines
15 KiB
C
/***************************************************************************
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* __________ __ ___.
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* Open \______ \ ____ ____ | | _\_ |__ _______ ___
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* Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ /
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* Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < <
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* Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \
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* \/ \/ \/ \/ \/
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* $Id: fat32format.c 30351 2011-08-25 19:58:47Z thomasjfox $
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*
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*
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* FAT32 formatting functions. Based on:
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*
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* Fat32 formatter version 1.03
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* (c) Tom Thornhill 2005
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* This software is covered by the GPL.
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* By using this tool, you agree to absolve Ridgecrop of an liabilities for
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* lost data.
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* Please backup any data you value before using this tool.
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*
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*
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* Modified June 2007 by Dave Chapman for use in ipodpatcher
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* Modified September 2011 by Frank Gevaerts for use in sansa eraser
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*
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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 software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY
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* KIND, either express or implied.
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*
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****************************************************************************/
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#include <stdio.h>
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#include <stdlib.h>
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#include "common.h"
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#include "cpu.h"
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#include "file.h"
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#include "system.h"
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#include "kernel.h"
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#include "lcd.h"
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#include "font.h"
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#include "storage.h"
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#include "button.h"
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#include "disk.h"
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#include <string.h>
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#include "i2c.h"
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#include "backlight-target.h"
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#include "power.h"
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#define SECTOR_SIZE 512
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/* The following functions are not the most efficient, but are
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self-contained and don't require needing to know endianness of CPU
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at compile-time.
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Note that htole16/htole32 exist on some platforms, so for
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simplicity we use different names.
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*/
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static uint16_t rb_htole16(uint16_t x)
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{
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uint16_t test = 0x1234;
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unsigned char* p = (unsigned char*)&test;
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if (p[0]==0x12) {
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/* Big-endian */
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return swap16(x);
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} else {
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return x;
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}
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}
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static uint32_t rb_htole32(uint32_t x)
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{
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uint32_t test = 0x12345678;
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unsigned char* p = (unsigned char*)&test;
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if (p[0]==0x12) {
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/* Big-endian */
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return swap32(x);
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} else {
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return x;
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}
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}
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/* A large aligned buffer for disk I/O */
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unsigned char sectorbuf[128*SECTOR_SIZE];
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/* TODO: Pass these as parameters to the various create_ functions */
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/* can be zero for default or 1,2,4,8,16,32 or 64 */
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static int sectors_per_cluster = 0;
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/* Recommended values */
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static uint32_t ReservedSectCount = 32;
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static uint32_t NumFATs = 2;
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static uint32_t BackupBootSect = 6;
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static uint32_t VolumeId=0; /* calculated before format */
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/* Calculated later */
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static uint32_t FatSize=0;
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static uint32_t BytesPerSect=0;
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static uint32_t SectorsPerCluster=0;
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static uint32_t TotalSectors=0;
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static uint32_t SystemAreaSize=0;
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static uint32_t UserAreaSize=0;
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static uint8_t VolId[12] = "NO NAME ";
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struct FAT_BOOTSECTOR32
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{
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/* Common fields. */
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uint8_t sJmpBoot[3];
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char sOEMName[8];
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uint16_t wBytsPerSec;
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uint8_t bSecPerClus;
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uint16_t wRsvdSecCnt;
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uint8_t bNumFATs;
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uint16_t wRootEntCnt;
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uint16_t wTotSec16; /* if zero, use dTotSec32 instead */
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uint8_t bMedia;
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uint16_t wFATSz16;
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uint16_t wSecPerTrk;
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uint16_t wNumHeads;
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uint32_t dHiddSec;
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uint32_t dTotSec32;
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/* Fat 32/16 only */
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uint32_t dFATSz32;
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uint16_t wExtFlags;
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uint16_t wFSVer;
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uint32_t dRootClus;
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uint16_t wFSInfo;
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uint16_t wBkBootSec;
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uint8_t Reserved[12];
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uint8_t bDrvNum;
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uint8_t Reserved1;
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uint8_t bBootSig; /* == 0x29 if next three fields are ok */
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uint32_t dBS_VolID;
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uint8_t sVolLab[11];
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uint8_t sBS_FilSysType[8];
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} __attribute__((packed));
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struct FAT_FSINFO {
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uint32_t dLeadSig; // 0x41615252
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uint8_t sReserved1[480]; // zeros
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uint32_t dStrucSig; // 0x61417272
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uint32_t dFree_Count; // 0xFFFFFFFF
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uint32_t dNxt_Free; // 0xFFFFFFFF
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uint8_t sReserved2[12]; // zeros
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uint32_t dTrailSig; // 0xAA550000
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} __attribute__((packed));
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/* Write "count" zero sectors, starting at sector "sector" */
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static int zero_sectors(uint32_t sector, int count)
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{
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int n;
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memset(sectorbuf, 0, 128 * SECTOR_SIZE);
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/* Write 128 sectors at a time */
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while (count) {
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if (count >= 128)
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n = 128;
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else
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n = count;
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if (storage_write_sectors(sector,n,sectorbuf) < 0) {
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printf("[ERR] Write failed in zero_sectors\n");
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return -1;
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}
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sector += n;
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count -= n;
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}
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return 0;
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}
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/*
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28.2 CALCULATING THE VOLUME SERIAL NUMBER
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For example, say a disk was formatted on 26 Dec 95 at 9:55 PM and 41.94
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seconds. DOS takes the date and time just before it writes it to the
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disk.
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Low order word is calculated: Volume Serial Number is:
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Month & Day 12/26 0c1ah
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Sec & Hundrenths 41:94 295eh 3578:1d02
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-----
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3578h
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High order word is calculated:
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Hours & Minutes 21:55 1537h
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Year 1995 07cbh
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-----
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1d02h
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*/
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static uint32_t get_volume_id ( void )
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{
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/* TODO */
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#if 0
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SYSTEMTIME s;
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uint32_t d;
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uint16_t lo,hi,tmp;
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GetLocalTime( &s );
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lo = s.wDay + ( s.wMonth << 8 );
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tmp = (s.wMilliseconds/10) + (s.wSecond << 8 );
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lo += tmp;
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hi = s.wMinute + ( s.wHour << 8 );
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hi += s.wYear;
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d = lo + (hi << 16);
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return(d);
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#endif
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return(0);
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}
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/*
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This is the Microsoft calculation from FATGEN
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uint32_t RootDirSectors = 0;
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uint32_t TmpVal1, TmpVal2, FATSz;
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TmpVal1 = DskSize - ( ReservedSecCnt + RootDirSectors);
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TmpVal2 = (256 * SecPerClus) + NumFATs;
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TmpVal2 = TmpVal2 / 2;
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FATSz = (TmpVal1 + (TmpVal2 - 1)) / TmpVal2;
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return( FatSz );
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*/
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static uint32_t get_fat_size_sectors(uint32_t DskSize, uint32_t ReservedSecCnt,
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uint32_t SecPerClus, uint32_t NumFATs,
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uint32_t BytesPerSect)
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{
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uint32_t Numerator, Denominator;
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uint32_t FatElementSize = 4;
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uint32_t FatSz;
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/* This is based on
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http://hjem.get2net.dk/rune_moeller_barnkob/filesystems/fat.html
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I've made the obvious changes for FAT32
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*/
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Numerator = FatElementSize * ( DskSize - ReservedSecCnt );
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Denominator = ( SecPerClus * BytesPerSect ) + ( FatElementSize * NumFATs );
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FatSz = Numerator / Denominator;
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/* round up */
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FatSz += 1;
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return((uint32_t)FatSz);
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}
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static uint8_t get_spc(uint32_t ClusterSizeKB, uint32_t BytesPerSect)
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{
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uint32_t spc = ( ClusterSizeKB * 1024 ) / BytesPerSect;
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return( (uint8_t) spc );
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}
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static uint8_t get_sectors_per_cluster(uint32_t DiskSizeSectors,
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uint32_t BytesPerSect)
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{
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uint8_t ret = 0x01; /* 1 sector per cluster */
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int32_t DiskSizeMB = DiskSizeSectors / ( 1024*1024 / SECTOR_SIZE);
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/* 512 MB to 8,191 MB 4 KB */
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if ( DiskSizeMB > 512 )
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ret = get_spc( 4, BytesPerSect ); /* ret = 0x8; */
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/* 8,192 MB to 16,383 MB 8 KB */
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if ( DiskSizeMB > 8192 )
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ret = get_spc( 8, BytesPerSect ); /* ret = 0x10; */
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/* 16,384 MB to 32,767 MB 16 KB */
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if ( DiskSizeMB > 16384 )
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ret = get_spc( 16, BytesPerSect ); /* ret = 0x20; */
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/* Larger than 32,768 MB 32 KB */
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if ( DiskSizeMB > 32768 )
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ret = get_spc( 32, BytesPerSect ); /* ret = 0x40; */
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return( ret );
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}
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static void create_boot_sector(unsigned char* buf)
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{
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struct FAT_BOOTSECTOR32* pFAT32BootSect = (struct FAT_BOOTSECTOR32*)buf;
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/* fill out the boot sector and fs info */
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pFAT32BootSect->sJmpBoot[0]=0xEB;
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pFAT32BootSect->sJmpBoot[1]=0x5A;
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pFAT32BootSect->sJmpBoot[2]=0x90;
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memcpy(pFAT32BootSect->sOEMName, "MSWIN4.1", 8 );
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pFAT32BootSect->wBytsPerSec = rb_htole16(BytesPerSect);
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pFAT32BootSect->bSecPerClus = SectorsPerCluster ;
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pFAT32BootSect->wRsvdSecCnt = rb_htole16(ReservedSectCount);
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pFAT32BootSect->bNumFATs = NumFATs;
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pFAT32BootSect->wRootEntCnt = rb_htole16(0);
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pFAT32BootSect->wTotSec16 = rb_htole16(0);
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pFAT32BootSect->bMedia = 0xF8;
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pFAT32BootSect->wFATSz16 = rb_htole16(0);
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pFAT32BootSect->wSecPerTrk = 63;
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pFAT32BootSect->wNumHeads = 255;
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pFAT32BootSect->dHiddSec = 0;
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pFAT32BootSect->dTotSec32 = rb_htole32(TotalSectors);
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pFAT32BootSect->dFATSz32 = rb_htole32(FatSize);
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pFAT32BootSect->wExtFlags = rb_htole16(0);
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pFAT32BootSect->wFSVer = rb_htole16(0);
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pFAT32BootSect->dRootClus = rb_htole32(2);
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pFAT32BootSect->wFSInfo = rb_htole16(1);
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pFAT32BootSect->wBkBootSec = rb_htole16(BackupBootSect);
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pFAT32BootSect->bDrvNum = 0x80;
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pFAT32BootSect->Reserved1 = 0;
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pFAT32BootSect->bBootSig = 0x29;
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pFAT32BootSect->dBS_VolID = rb_htole32(VolumeId);
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memcpy(pFAT32BootSect->sVolLab, VolId, 11);
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memcpy(pFAT32BootSect->sBS_FilSysType, "FAT32 ", 8 );
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buf[510] = 0x55;
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buf[511] = 0xaa;
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}
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static void create_fsinfo(unsigned char* buf)
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{
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struct FAT_FSINFO* pFAT32FsInfo = (struct FAT_FSINFO*)buf;
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/* FSInfo sect */
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pFAT32FsInfo->dLeadSig = rb_htole32(0x41615252);
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pFAT32FsInfo->dStrucSig = rb_htole32(0x61417272);
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pFAT32FsInfo->dFree_Count = rb_htole32((uint32_t) -1);
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pFAT32FsInfo->dNxt_Free = rb_htole32((uint32_t) -1);
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pFAT32FsInfo->dTrailSig = rb_htole32(0xaa550000);
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pFAT32FsInfo->dFree_Count = rb_htole32((UserAreaSize/SectorsPerCluster)-1);
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/* clusters 0-1 reserved, we used cluster 2 for the root dir */
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pFAT32FsInfo->dNxt_Free = rb_htole32(3);
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}
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static void create_firstfatsector(unsigned char* buf)
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{
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uint32_t* p = (uint32_t*)buf; /* We know the buffer is aligned */
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/* First FAT Sector */
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p[0] = rb_htole32(0x0ffffff8); /* Reserved cluster 1 media id in low byte */
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p[1] = rb_htole32(0x0fffffff); /* Reserved cluster 2 EOC */
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p[2] = rb_htole32(0x0fffffff); /* end of cluster chain for root dir */
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}
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int format_partition(int start, int size)
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{
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uint32_t i;
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uint32_t qTotalSectors=0;
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uint32_t FatNeeded;
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VolumeId = get_volume_id( );
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/* Only support hard disks at the moment */
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if ( SECTOR_SIZE != 512 )
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{
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printf("[ERR] Only disks with 512 bytes per sector are supported.\n");
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return -1;
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}
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BytesPerSect = SECTOR_SIZE;
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/* Checks on Disk Size */
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qTotalSectors = size;
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/* low end limit - 65536 sectors */
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if ( qTotalSectors < 65536 )
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{
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/* I suspect that most FAT32 implementations would mount this
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volume just fine, but the spec says that we shouldn't do
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this, so we won't */
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printf("[ERR] This drive is too small for FAT32 - there must be at least 64K clusters\n" );
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return -1;
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}
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if ( qTotalSectors >= 0xffffffff )
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{
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/* This is a more fundamental limitation on FAT32 - the total
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sector count in the root dir is 32bit. With a bit of
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creativity, FAT32 could be extended to handle at least 2^28
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clusters There would need to be an extra field in the
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FSInfo sector, and the old sector count could be set to
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0xffffffff. This is non standard though, the Windows FAT
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driver FASTFAT.SYS won't understand this. Perhaps a future
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version of FAT32 and FASTFAT will handle this. */
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printf("[ERR] This drive is too big for FAT32 - max 2TB supported\n");
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}
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if ( sectors_per_cluster ) {
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SectorsPerCluster = sectors_per_cluster;
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} else {
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SectorsPerCluster = get_sectors_per_cluster(size,
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BytesPerSect );
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}
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TotalSectors = (uint32_t) qTotalSectors;
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FatSize = get_fat_size_sectors(TotalSectors, ReservedSectCount,
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SectorsPerCluster, NumFATs, BytesPerSect );
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UserAreaSize = TotalSectors - ReservedSectCount - (NumFATs*FatSize);
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/* First zero out ReservedSect + FatSize * NumFats + SectorsPerCluster */
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SystemAreaSize = (ReservedSectCount+(NumFATs*FatSize) + SectorsPerCluster);
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/* Work out the Cluster count */
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FatNeeded = UserAreaSize/SectorsPerCluster;
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/* check for a cluster count of >2^28, since the upper 4 bits of
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the cluster values in the FAT are reserved. */
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if (FatNeeded > 0x0FFFFFFF) {
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printf("[ERR] This drive has more than 2^28 clusters, try to specify a larger cluster size\n" );
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return -1;
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}
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/* Sanity check, make sure the fat is big enough.
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Convert the cluster count into a Fat sector count, and check
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the fat size value we calculated earlier is OK. */
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FatNeeded *=4;
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FatNeeded += (BytesPerSect-1);
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FatNeeded /= BytesPerSect;
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if ( FatNeeded > FatSize ) {
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printf("[ERR] Drive too big to format\n");
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return -1;
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}
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/*
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Write boot sector, fats
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Sector 0 Boot Sector
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Sector 1 FSInfo
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Sector 2 More boot code - we write zeros here
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Sector 3 unused
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Sector 4 unused
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Sector 5 unused
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Sector 6 Backup boot sector
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Sector 7 Backup FSInfo sector
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Sector 8 Backup 'more boot code'
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zero'd sectors upto ReservedSectCount
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FAT1 ReservedSectCount to ReservedSectCount + FatSize
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...
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FATn ReservedSectCount to ReservedSectCount + FatSize
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RootDir - allocated to cluster2
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*/
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printf("[INFO] Formatting partition:...");
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/* Once zero_sectors has run, any data on the drive is basically lost... */
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printf("[INFO] Clearing out %d sectors for Reserved sectors, fats and root cluster...\n", SystemAreaSize );
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zero_sectors(start, SystemAreaSize);
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printf("[INFO] Initialising reserved sectors and FATs...\n" );
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/* Create the boot sector structure */
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create_boot_sector(sectorbuf);
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create_fsinfo(sectorbuf + 512);
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if (storage_write_sectors(start,2,sectorbuf)) {
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printf("[ERR] Write failed (first copy of bootsect/fsinfo)\n");
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return -1;
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}
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if (storage_write_sectors(start + BackupBootSect,2,sectorbuf)) {
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printf("[ERR] Write failed (first copy of bootsect/fsinfo)\n");
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return -1;
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}
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/* Create the first FAT sector */
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create_firstfatsector(sectorbuf);
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/* Write the first fat sector in the right places */
|
|
for ( i=0; i<NumFATs; i++ ) {
|
|
int SectorStart = ReservedSectCount + (i * FatSize );
|
|
|
|
if (storage_write_sectors(start + SectorStart,1,sectorbuf)) {
|
|
printf("[ERR] Write failed (first copy of bootsect/fsinfo)\n");
|
|
return -1;
|
|
}
|
|
}
|
|
|
|
printf("[INFO] Format successful\n");
|
|
|
|
return 0;
|
|
}
|