init.c - platform/external/mtools - Git at Google

 /*  Copyright 1986-1992 Emmet P. Gray.
  *  Copyright 1996-2002,2006-2009 Alain Knaff.
  *  This file is part of mtools.
  *
  *  Mtools is free software: you can redistribute it and/or modify
  *  it under the terms of the GNU General Public License as published by
  *  the Free Software Foundation, either version 3 of the License, or
  *  (at your option) any later version.
  *
  *  Mtools is distributed in the hope that it will be useful,
  *  but WITHOUT ANY WARRANTY; without even the implied warranty of
  *  MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
  *  GNU General Public License for more details.
  *
  *  You should have received a copy of the GNU General Public License
  *  along with Mtools.  If not, see <http://www.gnu.org/licenses/>.
  *
  * Initialize an MSDOS diskette.  Read the boot sector, and switch to the
  * proper floppy disk device to match the format on the disk.  Sets a bunch
  * of global variables.  Returns 0 on success, or 1 on failure.
  */

 #include "sysincludes.h"
 #include "msdos.h"
 #include "stream.h"
 #include "mtools.h"
 #include "device.h"
 #include "old_dos.h"
 #include "fsP.h"
 #include "buffer.h"
 #include "file_name.h"
 #include "open_image.h"

 #define FULL_CYL

 mt_off_t sectorsToBytes(Fs_t *This, uint32_t off)
 {
 	return (mt_off_t) off << This->sectorShift;
 }

 /*
  * Read the boot sector.  We glean the disk parameters from this sector.
  */
 static int read_boot(Stream_t *Stream, union bootsector * boot, size_t size)
 {
 	size_t boot_sector_size; /* sector size, as stored in boot sector */

 	/* read the first sector, or part of it */
 	if(!size)
 		size = BOOTSIZE;
 	if(size > MAX_BOOT)
 		size = MAX_BOOT;

 	if (force_pread(Stream, boot->characters, 0, size) != (ssize_t) size)
 		return -1;

 	boot_sector_size = WORD(secsiz);
 	if(boot_sector_size < sizeof(boot->bytes)) {
 		/* zero rest of in-memory boot sector */
 		memset(boot->bytes+boot_sector_size, 0,
 		       sizeof(boot->bytes) - boot_sector_size);
 	}

 	return 0;
 }

 static int fs_flush(Stream_t *Stream)
 {
 	DeclareThis(Fs_t);

 	fat_write(This);
 	return 0;
 }

 static doscp_t *get_dosConvert(Stream_t *Stream)
 {
   DeclareThis(Fs_t);
   return This->cp;
 }

 Class_t FsClass = {
 	0,
 	0,
 	pread_pass_through, /* read */
 	pwrite_pass_through, /* write */
 	fs_flush,
 	fs_free, /* free */
 	0, /* set geometry */
 	get_data_pass_through,
 	0, /* pre allocate */
 	get_dosConvert, /* dosconvert */
 	0 /* discard */
 };

 /**
  * Get media type byte from boot sector (BIOS Parameter Block 2) or
  * from FAT (if media byte from BPB 2 looks fishy)
  * Return the media byte + 0x100 if found in BPB 2, or as is if found in FAT.
  */
 static int get_media_type(Stream_t *St, union bootsector *boot)
 {
 	int media;

 	media = boot->boot.descr;
 	if(media < 0xf0){
 		char temp[512];
 		/* old DOS disk. Media descriptor in the first FAT byte */
 		/* we assume 512-byte sectors here */
 		if (force_pread(St,temp,512,512) == 512)
 			media = (unsigned char) temp[0];
 		else
 			media = 0;
 	} else
 		media += 0x100;
 	return media;
 }


 Stream_t *GetFs(Stream_t *Fs)
 {
 	while(Fs && Fs->Class != &FsClass)
 		Fs = Fs->Next;
 	return Fs;
 }

 static void boot_to_geom(struct device *dev, int media,
 			 union bootsector *boot) {
 	uint32_t tot_sectors;
 	int BootP, Infp0, InfpX, InfTm;
 	int j;
 	unsigned char sum;
 	uint16_t sect_per_track;
 	struct label_blk_t *labelBlock;

 	dev->ssize = 2; /* allow for init_geom to change it */
 	dev->use_2m = 0x80; /* disable 2m mode to begin */

 	if(media == 0xf0 || media >= 0x100){
 		dev->heads = WORD(nheads);
 		dev->sectors = WORD(nsect);
 		tot_sectors = DWORD(bigsect);
 		SET_INT(tot_sectors, WORD(psect));
 		sect_per_track = dev->heads * dev->sectors;
 		if(sect_per_track == 0) {
 		    if(mtools_skip_check) {
 			/* add some fake values if sect_per_track is
 			 * zero. Indeed, some atari disks lack the
 			 * geometry values (i.e. have zeroes in their
 			 * place). In order to avoid division by zero
 			 * errors later on, plug 1 everywhere
 			 */
 			dev->heads = 1;
 			dev->sectors = 1;
 			sect_per_track = 1;
 		    } else {
 			fprintf(stderr, "The devil is in the details: zero number of heads or sectors\n");
 			exit(1);
 		    }
 		}
 		dev->tracks = tot_sectors / sect_per_track;
 		if(tot_sectors % sect_per_track)
 			/* round size up */
 			dev->tracks++;

 		BootP = WORD(ext.old.BootP);
 		Infp0 = WORD(ext.old.Infp0);
 		InfpX = WORD(ext.old.InfpX);
 		InfTm = WORD(ext.old.InfTm);

 		if(WORD(fatlen)) {
 			labelBlock = &boot->boot.ext.old.labelBlock;
 		} else {
 			labelBlock = &boot->boot.ext.fat32.labelBlock;
 		}

 		if (boot->boot.descr >= 0xf0 &&
 		    has_BPB4 &&
 		    strncmp( boot->boot.banner,"2M", 2 ) == 0 &&
 		    BootP < 512 && Infp0 < 512 && InfpX < 512 && InfTm < 512 &&
 		    BootP >= InfTm + 2 && InfTm >= InfpX && InfpX >= Infp0 &&
 		    Infp0 >= 76 ){
 			for (sum=0, j=63; j < BootP; j++)
 				sum += boot->bytes[j];/* checksum */
 			dev->ssize = boot->bytes[InfTm];
 			if (!sum && dev->ssize <= 7){
 				dev->use_2m = 0xff;
 				dev->ssize |= 0x80; /* is set */
 			}
 		}
 		dev->sector_size = WORD(secsiz);
 	} else
 		if(setDeviceFromOldDos(media, dev) < 0)
 			exit(1);
 }

 /**
  * Tries out one device definition for the given drive number
  * Parameters
  *  - dev: device definition to try
  *  - mode: file open mode
  *  - out_dev: device parameters (geometry, etc.) are returned here
  *  - boot: boot sector is read from the disk into this structure
  *  - name: "name" of device definition (returned)
  *  - media: media byte is returned here (ored with 0x100 if there is a
  *    BIOS Parameter block present)
  *  - maxSize: maximal size supported by (physical) drive returned here
  *  - try_writable: whether to try opening it writable from the get-go,
  *     even if not specified as writable in mode (used for mlabel)
  *  - isRop: whether device is read-only is returned here
  * Return value:
  *  - a Stream allowing to read from this device, must be closed by caller
  *
  * If a geometry change is needed, drive is re-opened RW, as geometry
  * change ioctl needs write access. However, in such case, the lock
  * acquired is still only a read lock.
  */
 static Stream_t *try_device(struct device *dev,
 			    int mode, struct device *out_dev,
 			    union bootsector *boot,
 			    char *name, int *media, mt_off_t *maxSize,
 			    int *isRop, int try_writable,
 			    char *errmsg)
 {
 	int retry_write;
 	int have_read_bootsector=0;
 	int modeFlags = mode & ~O_ACCMODE;
 	int openMode;
 	int lockMode;

 	*out_dev = *dev;
 	expand(dev->name,name);
 #ifdef USING_NEW_VOLD
 	strcpy(name, getVoldName(dev, name));
 #endif

 	if(try_writable) {
 		/* Caller asks up to try first read-write, and only fall back
 		 * if not feasible */
 		openMode = O_RDWR | modeFlags;
 	} else {
 		openMode = mode;
 	}
 	lockMode = openMode;

 	for(retry_write=0; retry_write<2; retry_write++) {
 		Stream_t *Stream;
 		int r;
 		int geomFailure=0;

 		if(retry_write)
 			mode |= O_RDWR;

 		Stream = OpenImage(out_dev, dev, name, openMode, errmsg,
 				   0, lockMode,
 				   maxSize, &geomFailure, NULL);
 		if(Stream == NULL) {
 			if(geomFailure && (mode & O_ACCMODE) == O_RDONLY) {
 				/* Our first attempt was to open read-only,
 				   but this resulted in failure setting the
 				   geometry */
 				openMode = modeFlags | O_RDWR;
 				continue;
 			}

 			if(try_writable &&
 			   (errno == EPERM ||
 			    errno == EACCES ||
 			    errno == EROFS)) {
 				/* Our first attempt was to open
 				 * read-write, but this resulted in a
 				 * read-protection problem */
 				lockMode = openMode = modeFlags | O_RDONLY;
 				continue;
 			}
 			return NULL;
 		}
 		if(!have_read_bootsector) {
 			/* read the boot sector */
 			if ((r=read_boot(Stream, boot, out_dev->blocksize)) < 0){
 				sprintf(errmsg,
 					"init %c: could not read boot sector",
 					dev->drive);
 				FREE(&Stream);
 				return NULL;
 			}

 			if((*media= get_media_type(Stream, boot)) <= 0xf0 ){
 				if (boot->boot.jump[2]=='L')
 					sprintf(errmsg,
 						"diskette %c: is Linux LILO, not DOS",
 						dev->drive);
 				else
 					sprintf(errmsg,"init %c: non DOS media", dev->drive);
 				FREE(&Stream);
 				return NULL;
 			}
 			have_read_bootsector=1;
 		}

 		/* set new parameters, if needed */
 		errno = 0;
 		boot_to_geom(out_dev, *media, boot);
 		if(SET_GEOM(Stream, out_dev, dev)){
 			if(errno == EBADF || errno == EPERM) {
 				/* Retry with write */
 				FREE(&Stream);
 				openMode = modeFlags | O_RDWR;
 				continue;
 			}
 			if(errno)
 #ifdef HAVE_SNPRINTF
 				snprintf(errmsg, 199,
 					 "Can't set disk parameters for %c: %s",
 					 dev->drive, strerror(errno));
 #else
 			sprintf(errmsg,
 				"Can't set disk parameters for %c: %s",
 				drive, strerror(errno));
 #endif
 			else
 				sprintf(errmsg,
 					"Can't set disk parameters for %c",
 					dev->drive);
 			FREE(&Stream);
 			return NULL;
 		}
 		if(isRop) {
 			*isRop = (openMode & O_ACCMODE) == O_RDONLY;
 		}
 		return Stream;
 	}
 	return NULL;
 }

 uint32_t calc_clus_start(Fs_t *Fs) {
 	return Fs->fat_start + Fs->fat_len*Fs->num_fat + Fs->dir_len;
 }

 /* Calculates number of clusters, and fills it in into Fs->num_clus
  * Returns 0 if calculation could be performed, and -1 if less sectors than
  * clus_start
  */
 int calc_num_clus(Fs_t *Fs, uint32_t tot_sectors)
 {
 	Fs->clus_start = calc_clus_start(Fs);
 	if(tot_sectors <= Fs->clus_start)
 		return -1;
 	Fs->num_clus = (tot_sectors - Fs->clus_start) / Fs->cluster_size;
 	return 0;
 }

 /**
  * Tries out all device definitions for the given drive letter, until one
  * is found that is able to read from the device
  * Parameters
  *  - drive: drive letter to check
  *  - mode: file open mode
  *  - out_dev: device parameters (geometry, etc.) are returned here
  *  - boot: boot sector is read from the disk into this structure
  *  - name: "name" of device definition (returned)
  *  - media: media byte is returned here (ored with 0x100 if there is a
  *    BIOS Parameter block present)
  *  - maxSize: maximal size supported by (physical) drive returned here
  *  - isRop: whether device is read-only is returned here
  * Return value:
  *  - a Stream allowing to read from this device, must be closed by caller
  */
 Stream_t *find_device(char drive, int mode, struct device *out_dev,
 		      union bootsector *boot,
 		      char *name, int *media, mt_off_t *maxSize,
 		      int *isRop)
 {
 	char errmsg[200];
 	struct device *dev;

 	sprintf(errmsg, "Drive '%c:' not supported", drive);
 					/* open the device */
 	for (dev=devices; dev->name; dev++) {
 		Stream_t *Stream;
 		int isRo;
 		isRo=0;
 		if (dev->drive != drive)
 			continue;

 		Stream = try_device(dev, mode, out_dev,
 				    boot,
 				    name, media, maxSize,
 				    &isRo, isRop != NULL,
 				    errmsg);
 		if(Stream) {
 			if(isRop)
 				*isRop = isRo;
 			return Stream;
 		}
 	}

 	/* print error msg if needed */
 	fprintf(stderr,"%s\n",errmsg);
 	return NULL;
 }


 uint32_t parseFsParams(	Fs_t *This,
 			union bootsector *boot,
 			int media,
 			unsigned int cylinder_size)
 {
 	uint32_t tot_sectors;

 	if ((media & ~7) == 0xf8){
 		/* This bit of code is only entered if there is no BPB, or
 		 * else result of the AND would be 0x1xx
 		 */
 		struct OldDos_t *params=getOldDosByMedia(media);
 		if(params == NULL) {
 			fprintf(stderr, "Unknown media byte %02x\n", media);
 			return 0;
 		}
 		This->cluster_size = params->cluster_size;
 		tot_sectors = cylinder_size * params->tracks;
 		This->fat_start = 1;
 		This->fat_len = params->fat_len;
 		This->dir_len = params->dir_len;
 		This->num_fat = 2;
 		This->sector_size = 512;
 		This->sectorShift = 9;
 		This->sectorMask = 511;
 	} else {
 		struct label_blk_t *labelBlock;
 		unsigned int i;

 		This->sector_size = WORD(secsiz);
 		if(This->sector_size > MAX_SECTOR){
 			fprintf(stderr,"init: sector size too big\n");
 			return 0;
 		}

 		i = log_2(This->sector_size);

 		if(i == 24) {
 			fprintf(stderr,
 				"init: sector size (%d) not a small power of two\n",
 				This->sector_size);
 			return 0;
 		}
 		This->sectorShift = i;
 		This->sectorMask = This->sector_size - 1;

 		/*
 		 * all numbers are in sectors, except num_clus
 		 * (which is in clusters)
 		 */
 		tot_sectors = WORD(psect);
 		if(!tot_sectors)
 			tot_sectors = DWORD(bigsect);

 		This->cluster_size = boot->boot.clsiz;
 		This->fat_start = WORD(nrsvsect);
 		This->fat_len = WORD(fatlen);
 		This->dir_len = WORD(dirents) * MDIR_SIZE / This->sector_size;
 		This->num_fat = boot->boot.nfat;

 		if (This->fat_len) {
 			labelBlock = &boot->boot.ext.old.labelBlock;
 		} else {
 			labelBlock = &boot->boot.ext.fat32.labelBlock;
 			This->fat_len = DWORD(ext.fat32.bigFat);
 			This->backupBoot = WORD(ext.fat32.backupBoot);
 		}

 		if(has_BPB4) {
 			This->serialized = 1;
 			This->serial_number = _DWORD(labelBlock->serial);
 		}
 	}

 	if(calc_num_clus(This, tot_sectors) < 0)
 		/* Too few sectors */
 		return 0;
 	set_fat(This);

 	return tot_sectors;
 }


 Stream_t *fs_init(char drive, int mode, int *isRop)
 {
 	uint32_t blocksize;
 	int media;
 	size_t disk_size = 0;	/* In case we don't happen to set this below */
 	uint32_t tot_sectors;
 	char name[EXPAND_BUF];
 	unsigned int cylinder_size;
 	struct device dev;
 	mt_off_t maxSize;
 	char errmsg[81];

 	union bootsector boot;

 	Fs_t *This;

 	This = New(Fs_t);
 	if (!This)
 		return NULL;

 	init_head(&This->head, &FsClass, NULL);
 	This->preallocatedClusters = 0;
 	This->lastFatSectorNr = 0;
 	This->lastFatAccessMode = 0;
 	This->lastFatSectorData = 0;
 	This->drive = drive;
 	This->last = 0;

 	This->head.Next = find_device(drive, mode, &dev, &boot, name, &media,
 				      &maxSize, isRop);
 	if(!This->head.Next)
 		return NULL;

 	cylinder_size = dev.heads * dev.sectors;
 	This->serialized = 0;

 	tot_sectors = parseFsParams(This, &boot, media, cylinder_size);
 	if(tot_sectors == 0) {
 		/* Error raised by parseFsParams */
 		return NULL;
 	}

 	if (check_if_sectors_fit(tot_sectors, maxSize,
 				 This->sector_size, errmsg) < 0) {
 		fprintf(stderr, "%s", errmsg);
 		return NULL;
 	}

 	/* full cylinder buffering */
 #ifdef FULL_CYL
 	disk_size = (dev.tracks) ? cylinder_size : 512;
 #else /* FULL_CYL */
 	disk_size = (dev.tracks) ? dev.sectors : 512;
 #endif /* FULL_CYL */

 #if (defined OS_sysv4 && !defined OS_solaris)
 	/*
 	 * The driver in Dell's SVR4 v2.01 is unreliable with large writes.
 	 */
         disk_size = 0;
 #endif /* (defined sysv4 && !defined(solaris)) */

 #ifdef OS_linux
 	disk_size = cylinder_size;
 #endif

 #if 1
 	if(disk_size > 256) {
 		disk_size = dev.sectors;
 		if(dev.sectors % 2)
 			disk_size <<= 1;
 	}
 #endif
 	if (disk_size % 2)
 		disk_size *= 2;

 	if(!dev.blocksize || dev.blocksize < This->sector_size)
 		blocksize = This->sector_size;
 	else
 		blocksize = dev.blocksize;
 	if (disk_size) {
 		Stream_t *Buffer = buf_init(This->head.Next,
 					    8 * disk_size * blocksize,
 					    disk_size * blocksize,
 					    This->sector_size);

 		if (Buffer != NULL)
 			This->head.Next = Buffer;
 		else
 			perror("init: allocate buffer");
 	}

 	/* read the FAT sectors */
 	if(fat_read(This, &boot, dev.use_2m&0x7f)){
 		fprintf(stderr, "Error reading FAT\n");
 		This->num_fat = 1;
 		FREE(&This->head.Next);
 		Free(This->head.Next);
 		return NULL;
 	}

 	/* Set the codepage */
 	This->cp = cp_open(dev.codepage);
 	if(This->cp == NULL) {
 		fprintf(stderr, "Error setting code page\n");
 		fs_free((Stream_t *)This);
 		FREE(&This->head.Next);
 		Free(This->head.Next);
 		return NULL;
 	}

 	return (Stream_t *) This;
 }

 char getDrive(Stream_t *Stream)
 {
 	DeclareThis(Fs_t);

 	if(This->head.Class != &FsClass)
 		return getDrive(GetFs(Stream));
 	else
 		return This->drive;
 }

 /*
  * Upper layer asks to pre-allocated more additional clusters
  * Parameters:
  *   size: new additional clusters to pre-allocate
  * Return:
  *   0  if pre-allocation was granted
  *  -1  if not enough clusters could be found
  */
 int fsPreallocateClusters(Fs_t *Fs, uint32_t size)
 {
 	if(size > 0 && getfreeMinClusters((Stream_t *)Fs, size) != 1)
 		return -1;

 	Fs->preallocatedClusters += size;
 	return 0;
 }

 /*
  * Upper layer wants to release some clusters that it had
  * pre-allocated before Usually done because they have now been really
  * allocated, and thus pre-allocation needs to be released to prevent
  * counting them twice.
  * Parameters:
  *   size: new additional clusters to pre-allocate
  */
 void fsReleasePreallocateClusters(Fs_t *Fs, uint32_t size)
 {
 	Fs->preallocatedClusters -= size;
 }
	/* Copyright 1986-1992 Emmet P. Gray.
	* Copyright 1996-2002,2006-2009 Alain Knaff.
	* This file is part of mtools.
	*
	* Mtools is free software: you can redistribute it and/or modify
	* it under the terms of the GNU General Public License as published by
	* the Free Software Foundation, either version 3 of the License, or
	* (at your option) any later version.
	*
	* Mtools is distributed in the hope that it will be useful,
	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	* GNU General Public License for more details.
	*
	* You should have received a copy of the GNU General Public License
	* along with Mtools. If not, see <http://www.gnu.org/licenses/>.
	*
	* Initialize an MSDOS diskette. Read the boot sector, and switch to the
	* proper floppy disk device to match the format on the disk. Sets a bunch
	* of global variables. Returns 0 on success, or 1 on failure.
	*/

	#include "sysincludes.h"
	#include "msdos.h"
	#include "stream.h"
	#include "mtools.h"
	#include "device.h"
	#include "old_dos.h"
	#include "fsP.h"
	#include "buffer.h"
	#include "file_name.h"
	#include "open_image.h"

	#define FULL_CYL

	mt_off_t sectorsToBytes(Fs_t *This, uint32_t off)
	{
	return (mt_off_t) off << This->sectorShift;
	}

	/*
	* Read the boot sector. We glean the disk parameters from this sector.
	*/
	static int read_boot(Stream_t Stream, union bootsector boot, size_t size)
	{
	size_t boot_sector_size; /* sector size, as stored in boot sector */

	/* read the first sector, or part of it */
	if(!size)
	size = BOOTSIZE;
	if(size > MAX_BOOT)
	size = MAX_BOOT;

	if (force_pread(Stream, boot->characters, 0, size) != (ssize_t) size)
	return -1;

	boot_sector_size = WORD(secsiz);
	if(boot_sector_size < sizeof(boot->bytes)) {
	/* zero rest of in-memory boot sector */
	memset(boot->bytes+boot_sector_size, 0,
	sizeof(boot->bytes) - boot_sector_size);
	}

	return 0;
	}

	static int fs_flush(Stream_t *Stream)
	{
	DeclareThis(Fs_t);

	fat_write(This);
	return 0;
	}

	static doscp_t get_dosConvert(Stream_t Stream)
	{
	DeclareThis(Fs_t);
	return This->cp;
	}

	Class_t FsClass = {
	0,
	0,
	pread_pass_through, /* read */
	pwrite_pass_through, /* write */
	fs_flush,
	fs_free, /* free */
	0, /* set geometry */
	get_data_pass_through,
	0, /* pre allocate */
	get_dosConvert, /* dosconvert */
	0 /* discard */
	};

	/**
	* Get media type byte from boot sector (BIOS Parameter Block 2) or
	* from FAT (if media byte from BPB 2 looks fishy)
	* Return the media byte + 0x100 if found in BPB 2, or as is if found in FAT.
	*/
	static int get_media_type(Stream_t St, union bootsector boot)
	{
	int media;

	media = boot->boot.descr;
	if(media < 0xf0){
	char temp[512];
	/* old DOS disk. Media descriptor in the first FAT byte */
	/* we assume 512-byte sectors here */
	if (force_pread(St,temp,512,512) == 512)
	media = (unsigned char) temp[0];
	else
	media = 0;
	} else
	media += 0x100;
	return media;
	}


	Stream_t GetFs(Stream_t Fs)
	{
	while(Fs && Fs->Class != &FsClass)
	Fs = Fs->Next;
	return Fs;
	}

	static void boot_to_geom(struct device *dev, int media,
	union bootsector *boot) {
	uint32_t tot_sectors;
	int BootP, Infp0, InfpX, InfTm;
	int j;
	unsigned char sum;
	uint16_t sect_per_track;
	struct label_blk_t *labelBlock;

	dev->ssize = 2; /* allow for init_geom to change it */
	dev->use_2m = 0x80; /* disable 2m mode to begin */

	if(media == 0xf0 \|\| media >= 0x100){
	dev->heads = WORD(nheads);
	dev->sectors = WORD(nsect);
	tot_sectors = DWORD(bigsect);
	SET_INT(tot_sectors, WORD(psect));
	sect_per_track = dev->heads * dev->sectors;
	if(sect_per_track == 0) {
	if(mtools_skip_check) {
	/* add some fake values if sect_per_track is
	* zero. Indeed, some atari disks lack the
	* geometry values (i.e. have zeroes in their
	* place). In order to avoid division by zero
	* errors later on, plug 1 everywhere
	*/
	dev->heads = 1;
	dev->sectors = 1;
	sect_per_track = 1;
	} else {
	fprintf(stderr, "The devil is in the details: zero number of heads or sectors\n");
	exit(1);
	}
	}
	dev->tracks = tot_sectors / sect_per_track;
	if(tot_sectors % sect_per_track)
	/* round size up */
	dev->tracks++;

	BootP = WORD(ext.old.BootP);
	Infp0 = WORD(ext.old.Infp0);
	InfpX = WORD(ext.old.InfpX);
	InfTm = WORD(ext.old.InfTm);

	if(WORD(fatlen)) {
	labelBlock = &boot->boot.ext.old.labelBlock;
	} else {
	labelBlock = &boot->boot.ext.fat32.labelBlock;
	}

	if (boot->boot.descr >= 0xf0 &&
	has_BPB4 &&
	strncmp( boot->boot.banner,"2M", 2 ) == 0 &&
	BootP < 512 && Infp0 < 512 && InfpX < 512 && InfTm < 512 &&
	BootP >= InfTm + 2 && InfTm >= InfpX && InfpX >= Infp0 &&
	Infp0 >= 76 ){
	for (sum=0, j=63; j < BootP; j++)
	sum += boot->bytes[j];/* checksum */
	dev->ssize = boot->bytes[InfTm];
	if (!sum && dev->ssize <= 7){
	dev->use_2m = 0xff;
	dev->ssize \|= 0x80; /* is set */
	}
	}
	dev->sector_size = WORD(secsiz);
	} else
	if(setDeviceFromOldDos(media, dev) < 0)
	exit(1);
	}

	/**
	* Tries out one device definition for the given drive number
	* Parameters
	* - dev: device definition to try
	* - mode: file open mode
	* - out_dev: device parameters (geometry, etc.) are returned here
	* - boot: boot sector is read from the disk into this structure
	* - name: "name" of device definition (returned)
	* - media: media byte is returned here (ored with 0x100 if there is a
	* BIOS Parameter block present)
	* - maxSize: maximal size supported by (physical) drive returned here
	* - try_writable: whether to try opening it writable from the get-go,
	* even if not specified as writable in mode (used for mlabel)
	* - isRop: whether device is read-only is returned here
	* Return value:
	* - a Stream allowing to read from this device, must be closed by caller
	*
	* If a geometry change is needed, drive is re-opened RW, as geometry
	* change ioctl needs write access. However, in such case, the lock
	* acquired is still only a read lock.
	*/
	static Stream_t try_device(struct device dev,
	int mode, struct device *out_dev,
	union bootsector *boot,
	char name, int media, mt_off_t *maxSize,
	int *isRop, int try_writable,
	char *errmsg)
	{
	int retry_write;
	int have_read_bootsector=0;
	int modeFlags = mode & ~O_ACCMODE;
	int openMode;
	int lockMode;

	out_dev = dev;
	expand(dev->name,name);
	#ifdef USING_NEW_VOLD
	strcpy(name, getVoldName(dev, name));
	#endif

	if(try_writable) {
	/* Caller asks up to try first read-write, and only fall back
	* if not feasible */
	openMode = O_RDWR \| modeFlags;
	} else {
	openMode = mode;
	}
	lockMode = openMode;

	for(retry_write=0; retry_write<2; retry_write++) {
	Stream_t *Stream;
	int r;
	int geomFailure=0;

	if(retry_write)
	mode \|= O_RDWR;

	Stream = OpenImage(out_dev, dev, name, openMode, errmsg,
	0, lockMode,
	maxSize, &geomFailure, NULL);
	if(Stream == NULL) {
	if(geomFailure && (mode & O_ACCMODE) == O_RDONLY) {
	/* Our first attempt was to open read-only,
	but this resulted in failure setting the
	geometry */
	openMode = modeFlags \| O_RDWR;
	continue;
	}

	if(try_writable &&
	(errno == EPERM \|\|
	errno == EACCES \|\|
	errno == EROFS)) {
	/* Our first attempt was to open
	* read-write, but this resulted in a
	* read-protection problem */
	lockMode = openMode = modeFlags \| O_RDONLY;
	continue;
	}
	return NULL;
	}
	if(!have_read_bootsector) {
	/* read the boot sector */
	if ((r=read_boot(Stream, boot, out_dev->blocksize)) < 0){
	sprintf(errmsg,
	"init %c: could not read boot sector",
	dev->drive);
	FREE(&Stream);
	return NULL;
	}

	if((*media= get_media_type(Stream, boot)) <= 0xf0 ){
	if (boot->boot.jump[2]=='L')
	sprintf(errmsg,
	"diskette %c: is Linux LILO, not DOS",
	dev->drive);
	else
	sprintf(errmsg,"init %c: non DOS media", dev->drive);
	FREE(&Stream);
	return NULL;
	}
	have_read_bootsector=1;
	}

	/* set new parameters, if needed */
	errno = 0;
	boot_to_geom(out_dev, *media, boot);
	if(SET_GEOM(Stream, out_dev, dev)){
	if(errno == EBADF \|\| errno == EPERM) {
	/* Retry with write */
	FREE(&Stream);
	openMode = modeFlags \| O_RDWR;
	continue;
	}
	if(errno)
	#ifdef HAVE_SNPRINTF
	snprintf(errmsg, 199,
	"Can't set disk parameters for %c: %s",
	dev->drive, strerror(errno));
	#else
	sprintf(errmsg,
	"Can't set disk parameters for %c: %s",
	drive, strerror(errno));
	#endif
	else
	sprintf(errmsg,
	"Can't set disk parameters for %c",
	dev->drive);
	FREE(&Stream);
	return NULL;
	}
	if(isRop) {
	*isRop = (openMode & O_ACCMODE) == O_RDONLY;
	}
	return Stream;
	}
	return NULL;
	}

	uint32_t calc_clus_start(Fs_t *Fs) {
	return Fs->fat_start + Fs->fat_len*Fs->num_fat + Fs->dir_len;
	}

	/* Calculates number of clusters, and fills it in into Fs->num_clus
	* Returns 0 if calculation could be performed, and -1 if less sectors than
	* clus_start
	*/
	int calc_num_clus(Fs_t *Fs, uint32_t tot_sectors)
	{
	Fs->clus_start = calc_clus_start(Fs);
	if(tot_sectors <= Fs->clus_start)
	return -1;
	Fs->num_clus = (tot_sectors - Fs->clus_start) / Fs->cluster_size;
	return 0;
	}

	/**
	* Tries out all device definitions for the given drive letter, until one
	* is found that is able to read from the device
	* Parameters
	* - drive: drive letter to check
	* - mode: file open mode
	* - out_dev: device parameters (geometry, etc.) are returned here
	* - boot: boot sector is read from the disk into this structure
	* - name: "name" of device definition (returned)
	* - media: media byte is returned here (ored with 0x100 if there is a
	* BIOS Parameter block present)
	* - maxSize: maximal size supported by (physical) drive returned here
	* - isRop: whether device is read-only is returned here
	* Return value:
	* - a Stream allowing to read from this device, must be closed by caller
	*/
	Stream_t find_device(char drive, int mode, struct device out_dev,
	union bootsector *boot,
	char name, int media, mt_off_t *maxSize,
	int *isRop)
	{
	char errmsg[200];
	struct device *dev;

	sprintf(errmsg, "Drive '%c:' not supported", drive);
	/* open the device */
	for (dev=devices; dev->name; dev++) {
	Stream_t *Stream;
	int isRo;
	isRo=0;
	if (dev->drive != drive)
	continue;

	Stream = try_device(dev, mode, out_dev,
	boot,
	name, media, maxSize,
	&isRo, isRop != NULL,
	errmsg);
	if(Stream) {
	if(isRop)
	*isRop = isRo;
	return Stream;
	}
	}

	/* print error msg if needed */
	fprintf(stderr,"%s\n",errmsg);
	return NULL;
	}


	uint32_t parseFsParams( Fs_t *This,
	union bootsector *boot,
	int media,
	unsigned int cylinder_size)
	{
	uint32_t tot_sectors;

	if ((media & ~7) == 0xf8){
	/* This bit of code is only entered if there is no BPB, or
	* else result of the AND would be 0x1xx
	*/
	struct OldDos_t *params=getOldDosByMedia(media);
	if(params == NULL) {
	fprintf(stderr, "Unknown media byte %02x\n", media);
	return 0;
	}
	This->cluster_size = params->cluster_size;
	tot_sectors = cylinder_size * params->tracks;
	This->fat_start = 1;
	This->fat_len = params->fat_len;
	This->dir_len = params->dir_len;
	This->num_fat = 2;
	This->sector_size = 512;
	This->sectorShift = 9;
	This->sectorMask = 511;
	} else {
	struct label_blk_t *labelBlock;
	unsigned int i;

	This->sector_size = WORD(secsiz);
	if(This->sector_size > MAX_SECTOR){
	fprintf(stderr,"init: sector size too big\n");
	return 0;
	}

	i = log_2(This->sector_size);

	if(i == 24) {
	fprintf(stderr,
	"init: sector size (%d) not a small power of two\n",
	This->sector_size);
	return 0;
	}
	This->sectorShift = i;
	This->sectorMask = This->sector_size - 1;

	/*
	* all numbers are in sectors, except num_clus
	* (which is in clusters)
	*/
	tot_sectors = WORD(psect);
	if(!tot_sectors)
	tot_sectors = DWORD(bigsect);

	This->cluster_size = boot->boot.clsiz;
	This->fat_start = WORD(nrsvsect);
	This->fat_len = WORD(fatlen);
	This->dir_len = WORD(dirents) * MDIR_SIZE / This->sector_size;
	This->num_fat = boot->boot.nfat;

	if (This->fat_len) {
	labelBlock = &boot->boot.ext.old.labelBlock;
	} else {
	labelBlock = &boot->boot.ext.fat32.labelBlock;
	This->fat_len = DWORD(ext.fat32.bigFat);
	This->backupBoot = WORD(ext.fat32.backupBoot);
	}

	if(has_BPB4) {
	This->serialized = 1;
	This->serial_number = _DWORD(labelBlock->serial);
	}
	}

	if(calc_num_clus(This, tot_sectors) < 0)
	/* Too few sectors */
	return 0;
	set_fat(This);

	return tot_sectors;
	}


	Stream_t fs_init(char drive, int mode, int isRop)
	{
	uint32_t blocksize;
	int media;
	size_t disk_size = 0; /* In case we don't happen to set this below */
	uint32_t tot_sectors;
	char name[EXPAND_BUF];
	unsigned int cylinder_size;
	struct device dev;
	mt_off_t maxSize;
	char errmsg[81];

	union bootsector boot;

	Fs_t *This;

	This = New(Fs_t);
	if (!This)
	return NULL;

	init_head(&This->head, &FsClass, NULL);
	This->preallocatedClusters = 0;
	This->lastFatSectorNr = 0;
	This->lastFatAccessMode = 0;
	This->lastFatSectorData = 0;
	This->drive = drive;
	This->last = 0;

	This->head.Next = find_device(drive, mode, &dev, &boot, name, &media,
	&maxSize, isRop);
	if(!This->head.Next)
	return NULL;

	cylinder_size = dev.heads * dev.sectors;
	This->serialized = 0;

	tot_sectors = parseFsParams(This, &boot, media, cylinder_size);
	if(tot_sectors == 0) {
	/* Error raised by parseFsParams */
	return NULL;
	}

	if (check_if_sectors_fit(tot_sectors, maxSize,
	This->sector_size, errmsg) < 0) {
	fprintf(stderr, "%s", errmsg);
	return NULL;
	}

	/* full cylinder buffering */
	#ifdef FULL_CYL
	disk_size = (dev.tracks) ? cylinder_size : 512;
	#else /* FULL_CYL */
	disk_size = (dev.tracks) ? dev.sectors : 512;
	#endif /* FULL_CYL */

	#if (defined OS_sysv4 && !defined OS_solaris)
	/*
	* The driver in Dell's SVR4 v2.01 is unreliable with large writes.
	*/
	disk_size = 0;
	#endif /* (defined sysv4 && !defined(solaris)) */

	#ifdef OS_linux
	disk_size = cylinder_size;
	#endif

	#if 1
	if(disk_size > 256) {
	disk_size = dev.sectors;
	if(dev.sectors % 2)
	disk_size <<= 1;
	}
	#endif
	if (disk_size % 2)
	disk_size *= 2;

	if(!dev.blocksize \|\| dev.blocksize < This->sector_size)
	blocksize = This->sector_size;
	else
	blocksize = dev.blocksize;
	if (disk_size) {
	Stream_t *Buffer = buf_init(This->head.Next,
	8 * disk_size * blocksize,
	disk_size * blocksize,
	This->sector_size);

	if (Buffer != NULL)
	This->head.Next = Buffer;
	else
	perror("init: allocate buffer");
	}

	/* read the FAT sectors */
	if(fat_read(This, &boot, dev.use_2m&0x7f)){
	fprintf(stderr, "Error reading FAT\n");
	This->num_fat = 1;
	FREE(&This->head.Next);
	Free(This->head.Next);
	return NULL;
	}

	/* Set the codepage */
	This->cp = cp_open(dev.codepage);
	if(This->cp == NULL) {
	fprintf(stderr, "Error setting code page\n");
	fs_free((Stream_t *)This);
	FREE(&This->head.Next);
	Free(This->head.Next);
	return NULL;
	}

	return (Stream_t *) This;
	}

	char getDrive(Stream_t *Stream)
	{
	DeclareThis(Fs_t);

	if(This->head.Class != &FsClass)
	return getDrive(GetFs(Stream));
	else
	return This->drive;
	}

	/*
	* Upper layer asks to pre-allocated more additional clusters
	* Parameters:
	* size: new additional clusters to pre-allocate
	* Return:
	* 0 if pre-allocation was granted
	* -1 if not enough clusters could be found
	*/
	int fsPreallocateClusters(Fs_t *Fs, uint32_t size)
	{
	if(size > 0 && getfreeMinClusters((Stream_t *)Fs, size) != 1)
	return -1;

	Fs->preallocatedClusters += size;
	return 0;
	}

	/*
	* Upper layer wants to release some clusters that it had
	* pre-allocated before Usually done because they have now been really
	* allocated, and thus pre-allocation needs to be released to prevent
	* counting them twice.
	* Parameters:
	* size: new additional clusters to pre-allocate
	*/
	void fsReleasePreallocateClusters(Fs_t *Fs, uint32_t size)
	{
	Fs->preallocatedClusters -= size;
	}