src/libdisk/disk.c - plan9 - Git at Google

 #include <u.h>
 #include <libc.h>
 #include <bio.h>
 #include <ctype.h>
 #include <disk.h>

 static Disk*
 mkwidth(Disk *disk)
 {
 	char buf[40];

 	sprint(buf, "%lld", disk->size);
 	disk->width = strlen(buf);
 	return disk;
 }

 /*
  * Discover the disk geometry by various sleazeful means.
  *
  * First, if there is a partition table in sector 0,
  * see if all the partitions have the same end head
  * and sector; if so, we'll assume that that's the
  * right count.
  *
  * If that fails, we'll try looking at the geometry that the ATA
  * driver supplied, if any, and translate that as a
  * BIOS might.
  *
  * If that too fails, which should only happen on a SCSI
  * disk with no currently defined partitions, we'll try
  * various common (h, s) pairs used by BIOSes when faking
  * the geometries.
  */
 typedef struct Table  Table;
 typedef struct Tentry Tentry;
 struct Tentry {
 	uchar	active;			/* active flag */
 	uchar	starth;			/* starting head */
 	uchar	starts;			/* starting sector */
 	uchar	startc;			/* starting cylinder */
 	uchar	type;			/* partition type */
 	uchar	endh;			/* ending head */
 	uchar	ends;			/* ending sector */
 	uchar	endc;			/* ending cylinder */
 	uchar	xlba[4];			/* starting LBA from beginning of disc */
 	uchar	xsize[4];		/* size in sectors */
 };
 enum {
 	Toffset		= 446,		/* offset of partition table in sector */
 	Magic0		= 0x55,
 	Magic1		= 0xAA,
 	NTentry		= 4
 };
 struct Table {
 	Tentry	entry[NTentry];
 	uchar	magic[2];
 };
 static int
 partitiongeometry(Disk *disk)
 {
 	char *rawname;
 	int i, h, rawfd, s;
 	uchar buf[512];
 	Table *t;

 	t = (Table*)(buf + Toffset);

 	/*
 	 * look for an MBR first in the /dev/sdXX/data partition, otherwise
 	 * attempt to fall back on the current partition.
 	 */
 	rawname = malloc(strlen(disk->prefix) + 5);	/* prefix + "data" + nul */
 	if(rawname == nil)
 		return -1;

 	strcpy(rawname, disk->prefix);
 	strcat(rawname, "data");
 	rawfd = open(rawname, OREAD);
 	free(rawname);
 	if(rawfd >= 0
 	&& seek(rawfd, 0, 0) >= 0
 	&& readn(rawfd, buf, 512) == 512
 	&& t->magic[0] == Magic0
 	&& t->magic[1] == Magic1) {
 		close(rawfd);
 	} else {
 		if(rawfd >= 0)
 			close(rawfd);
 		if(seek(disk->fd, 0, 0) < 0
 		|| readn(disk->fd, buf, 512) != 512
 		|| t->magic[0] != Magic0
 		|| t->magic[1] != Magic1) {
 			return -1;
 		}
 	}

 	h = s = -1;
 	for(i=0; i<NTentry; i++) {
 		if(t->entry[i].type == 0)
 			continue;

 		t->entry[i].ends &= 63;
 		if(h == -1) {
 			h = t->entry[i].endh;
 			s = t->entry[i].ends;
 		} else {
 			/*
 			 * Only accept the partition info if every
 			 * partition is consistent.
 			 */
 			if(h != t->entry[i].endh || s != t->entry[i].ends)
 				return -1;
 		}
 	}

 	if(h == -1)
 		return -1;

 	disk->h = h+1;	/* heads count from 0 */
 	disk->s = s;	/* sectors count from 1 */
 	disk->c = disk->secs / (disk->h*disk->s);
 	disk->chssrc = Gpart;
 	return 0;
 }

 /*
  * If there is ATA geometry, use it, perhaps massaged.
  */
 static int
 drivergeometry(Disk *disk)
 {
 	int m;

 	if(disk->c == 0 || disk->h == 0 || disk->s == 0)
 		return -1;

 	disk->chssrc = Gdisk;
 	if(disk->c < 1024)
 		return 0;

 	switch(disk->h) {
 	case 15:
 		disk->h = 255;
 		disk->c /= 17;
 		return 0;
 	}

 	for(m = 2; m*disk->h < 256; m *= 2) {
 		if(disk->c/m < 1024) {
 			disk->c /= m;
 			disk->h *= m;
 			return 0;
 		}
 	}

 	/* set to 255, 63 and be done with it */
 	disk->h = 255;
 	disk->s = 63;
 	disk->c = disk->secs / (disk->h * disk->s);
 	return 0;
 }

 /*
  * There's no ATA geometry and no partitions.
  * Our guess is as good as anyone's.
  */
 static struct {
 	int h;
 	int s;
 } guess[] = {
 	64, 32,
 	64, 63,
 	128, 63,
 	255, 63,
 };
 static int
 guessgeometry(Disk *disk)
 {
 	int i;
 	long c;

 	disk->chssrc = Gguess;
 	c = 1024;
 	for(i=0; i<nelem(guess); i++)
 		if(c*guess[i].h*guess[i].s >= disk->secs) {
 			disk->h = guess[i].h;
 			disk->s = guess[i].s;
 			disk->c = disk->secs / (disk->h * disk->s);
 			return 0;
 		}

 	/* use maximum values */
 	disk->h = 255;
 	disk->s = 63;
 	disk->c = disk->secs / (disk->h * disk->s);
 	return 0;
 }

 static void
 findgeometry(Disk *disk)
 {
 	if(partitiongeometry(disk) < 0
 	&& drivergeometry(disk) < 0
 	&& guessgeometry(disk) < 0) {	/* can't happen */
 		print("we're completely confused about your disk; sorry\n");
 		assert(0);
 	}
 }

 static Disk*
 openfile(Disk *disk)
 {
 	Dir *d;

 	if((d = dirfstat(disk->fd)) == nil){
 		free(disk);
 		return nil;
 	}

 	disk->secsize = 512;
 	disk->size = d->length;
 	disk->secs = disk->size / disk->secsize;
 	disk->offset = 0;
 	free(d);

 	findgeometry(disk);
 	return mkwidth(disk);
 }

 static Disk*
 opensd(Disk *disk)
 {
 	Biobuf b;
 	char *p, *f[10];
 	int nf;

 	Binit(&b, disk->ctlfd, OREAD);
 	while(p = Brdline(&b, '\n')) {
 		p[Blinelen(&b)-1] = '\0';
 		nf = tokenize(p, f, nelem(f));
 		if(nf >= 3 && strcmp(f[0], "geometry") == 0) {
 			disk->secsize = strtoll(f[2], 0, 0);
 			if(nf >= 6) {
 				disk->c = strtol(f[3], 0, 0);
 				disk->h = strtol(f[4], 0, 0);
 				disk->s = strtol(f[5], 0, 0);
 			}
 		}
 		if(nf >= 4 && strcmp(f[0], "part") == 0 && strcmp(f[1], disk->part) == 0) {
 			disk->offset = strtoll(f[2], 0, 0);
 			disk->secs = strtoll(f[3], 0, 0) - disk->offset;
 		}
 	}


 	disk->size = disk->secs * disk->secsize;
 	if(disk->size <= 0) {
 		strcpy(disk->part, "");
 		disk->type = Tfile;
 		return openfile(disk);
 	}

 	findgeometry(disk);
 	return mkwidth(disk);
 }

 Disk*
 opendisk(char *disk, int rdonly, int noctl)
 {
 	char *p, *q;
 	Disk *d;

 	d = malloc(sizeof(*d));
 	if(d == nil)
 		return nil;

 	d->fd = d->wfd = d->ctlfd = -1;
 	d->rdonly = rdonly;

 	d->fd = open(disk, OREAD);
 	if(d->fd < 0) {
 		werrstr("cannot open disk file");
 		free(d);
 		return nil;
 	}

 	if(rdonly == 0) {
 		d->wfd = open(disk, OWRITE);
 		if(d->wfd < 0)
 			d->rdonly = 1;
 	}

 	if(noctl)
 		return openfile(d);

 	p = malloc(strlen(disk) + 4);	/* 4: slop for "ctl\0" */
 	if(p == nil) {
 		close(d->wfd);
 		close(d->fd);
 		free(d);
 		return nil;
 	}
 	strcpy(p, disk);

 	/* check for floppy(3) disk */
 	if(strlen(p) >= 7) {
 		q = p+strlen(p)-7;
 		if(q[0] == 'f' && q[1] == 'd' && isdigit((uchar)q[2]) && strcmp(q+3, "disk") == 0) {
 			strcpy(q+3, "ctl");
 			if((d->ctlfd = open(p, ORDWR)) >= 0) {
 				*q = '\0';
 				d->prefix = p;
 				d->type = Tfloppy;
 				return openfile(d);
 			}
 		}
 	}

 	/* attempt to find sd(3) disk or partition */
 	if(q = strrchr(p, '/'))
 		q++;
 	else
 		q = p;

 	strcpy(q, "ctl");
 	if((d->ctlfd = open(p, ORDWR)) >= 0) {
 		*q = '\0';
 		d->prefix = p;
 		d->type = Tsd;
 		d->part = strdup(disk+(q-p));
 		if(d->part == nil){
 			close(d->ctlfd);
 			close(d->wfd);
 			close(d->fd);
 			free(p);
 			free(d);
 			return nil;
 		}
 		return opensd(d);
 	}

 	*q = '\0';
 	d->prefix = p;
 	/* assume we just have a normal file */
 	d->type = Tfile;
 	return openfile(d);
 }
	#include <u.h>
	#include <libc.h>
	#include <bio.h>
	#include <ctype.h>
	#include <disk.h>

	static Disk*
	mkwidth(Disk *disk)
	{
	char buf[40];

	sprint(buf, "%lld", disk->size);
	disk->width = strlen(buf);
	return disk;
	}

	/*
	* Discover the disk geometry by various sleazeful means.
	*
	* First, if there is a partition table in sector 0,
	* see if all the partitions have the same end head
	* and sector; if so, we'll assume that that's the
	* right count.
	*
	* If that fails, we'll try looking at the geometry that the ATA
	* driver supplied, if any, and translate that as a
	* BIOS might.
	*
	* If that too fails, which should only happen on a SCSI
	* disk with no currently defined partitions, we'll try
	* various common (h, s) pairs used by BIOSes when faking
	* the geometries.
	*/
	typedef struct Table Table;
	typedef struct Tentry Tentry;
	struct Tentry {
	uchar active; /* active flag */
	uchar starth; /* starting head */
	uchar starts; /* starting sector */
	uchar startc; /* starting cylinder */
	uchar type; /* partition type */
	uchar endh; /* ending head */
	uchar ends; /* ending sector */
	uchar endc; /* ending cylinder */
	uchar xlba[4]; /* starting LBA from beginning of disc */
	uchar xsize[4]; /* size in sectors */
	};
	enum {
	Toffset = 446, /* offset of partition table in sector */
	Magic0 = 0x55,
	Magic1 = 0xAA,
	NTentry = 4
	};
	struct Table {
	Tentry entry[NTentry];
	uchar magic[2];
	};
	static int
	partitiongeometry(Disk *disk)
	{
	char *rawname;
	int i, h, rawfd, s;
	uchar buf[512];
	Table *t;

	t = (Table*)(buf + Toffset);

	/*
	* look for an MBR first in the /dev/sdXX/data partition, otherwise
	* attempt to fall back on the current partition.
	*/
	rawname = malloc(strlen(disk->prefix) + 5); /* prefix + "data" + nul */
	if(rawname == nil)
	return -1;

	strcpy(rawname, disk->prefix);
	strcat(rawname, "data");
	rawfd = open(rawname, OREAD);
	free(rawname);
	if(rawfd >= 0
	&& seek(rawfd, 0, 0) >= 0
	&& readn(rawfd, buf, 512) == 512
	&& t->magic[0] == Magic0
	&& t->magic[1] == Magic1) {
	close(rawfd);
	} else {
	if(rawfd >= 0)
	close(rawfd);
	if(seek(disk->fd, 0, 0) < 0
	\|\| readn(disk->fd, buf, 512) != 512
	\|\| t->magic[0] != Magic0
	\|\| t->magic[1] != Magic1) {
	return -1;
	}
	}

	h = s = -1;
	for(i=0; i<NTentry; i++) {
	if(t->entry[i].type == 0)
	continue;

	t->entry[i].ends &= 63;
	if(h == -1) {
	h = t->entry[i].endh;
	s = t->entry[i].ends;
	} else {
	/*
	* Only accept the partition info if every
	* partition is consistent.
	*/
	if(h != t->entry[i].endh \|\| s != t->entry[i].ends)
	return -1;
	}
	}

	if(h == -1)
	return -1;

	disk->h = h+1; /* heads count from 0 */
	disk->s = s; /* sectors count from 1 */
	disk->c = disk->secs / (disk->h*disk->s);
	disk->chssrc = Gpart;
	return 0;
	}

	/*
	* If there is ATA geometry, use it, perhaps massaged.
	*/
	static int
	drivergeometry(Disk *disk)
	{
	int m;

	if(disk->c == 0 \|\| disk->h == 0 \|\| disk->s == 0)
	return -1;

	disk->chssrc = Gdisk;
	if(disk->c < 1024)
	return 0;

	switch(disk->h) {
	case 15:
	disk->h = 255;
	disk->c /= 17;
	return 0;
	}

	for(m = 2; mdisk->h < 256; m = 2) {
	if(disk->c/m < 1024) {
	disk->c /= m;
	disk->h *= m;
	return 0;
	}
	}

	/* set to 255, 63 and be done with it */
	disk->h = 255;
	disk->s = 63;
	disk->c = disk->secs / (disk->h * disk->s);
	return 0;
	}

	/*
	* There's no ATA geometry and no partitions.
	* Our guess is as good as anyone's.
	*/
	static struct {
	int h;
	int s;
	} guess[] = {
	64, 32,
	64, 63,
	128, 63,
	255, 63,
	};
	static int
	guessgeometry(Disk *disk)
	{
	int i;
	long c;

	disk->chssrc = Gguess;
	c = 1024;
	for(i=0; i<nelem(guess); i++)
	if(cguess[i].hguess[i].s >= disk->secs) {
	disk->h = guess[i].h;
	disk->s = guess[i].s;
	disk->c = disk->secs / (disk->h * disk->s);
	return 0;
	}

	/* use maximum values */
	disk->h = 255;
	disk->s = 63;
	disk->c = disk->secs / (disk->h * disk->s);
	return 0;
	}

	static void
	findgeometry(Disk *disk)
	{
	if(partitiongeometry(disk) < 0
	&& drivergeometry(disk) < 0
	&& guessgeometry(disk) < 0) { /* can't happen */
	print("we're completely confused about your disk; sorry\n");
	assert(0);
	}
	}

	static Disk*
	openfile(Disk *disk)
	{
	Dir *d;

	if((d = dirfstat(disk->fd)) == nil){
	free(disk);
	return nil;
	}

	disk->secsize = 512;
	disk->size = d->length;
	disk->secs = disk->size / disk->secsize;
	disk->offset = 0;
	free(d);

	findgeometry(disk);
	return mkwidth(disk);
	}

	static Disk*
	opensd(Disk *disk)
	{
	Biobuf b;
	char p, f[10];
	int nf;

	Binit(&b, disk->ctlfd, OREAD);
	while(p = Brdline(&b, '\n')) {
	p[Blinelen(&b)-1] = '\0';
	nf = tokenize(p, f, nelem(f));
	if(nf >= 3 && strcmp(f[0], "geometry") == 0) {
	disk->secsize = strtoll(f[2], 0, 0);
	if(nf >= 6) {
	disk->c = strtol(f[3], 0, 0);
	disk->h = strtol(f[4], 0, 0);
	disk->s = strtol(f[5], 0, 0);
	}
	}
	if(nf >= 4 && strcmp(f[0], "part") == 0 && strcmp(f[1], disk->part) == 0) {
	disk->offset = strtoll(f[2], 0, 0);
	disk->secs = strtoll(f[3], 0, 0) - disk->offset;
	}
	}


	disk->size = disk->secs * disk->secsize;
	if(disk->size <= 0) {
	strcpy(disk->part, "");
	disk->type = Tfile;
	return openfile(disk);
	}

	findgeometry(disk);
	return mkwidth(disk);
	}

	Disk*
	opendisk(char *disk, int rdonly, int noctl)
	{
	char p, q;
	Disk *d;

	d = malloc(sizeof(*d));
	if(d == nil)
	return nil;

	d->fd = d->wfd = d->ctlfd = -1;
	d->rdonly = rdonly;

	d->fd = open(disk, OREAD);
	if(d->fd < 0) {
	werrstr("cannot open disk file");
	free(d);
	return nil;
	}

	if(rdonly == 0) {
	d->wfd = open(disk, OWRITE);
	if(d->wfd < 0)
	d->rdonly = 1;
	}

	if(noctl)
	return openfile(d);

	p = malloc(strlen(disk) + 4); /* 4: slop for "ctl\0" */
	if(p == nil) {
	close(d->wfd);
	close(d->fd);
	free(d);
	return nil;
	}
	strcpy(p, disk);

	/* check for floppy(3) disk */
	if(strlen(p) >= 7) {
	q = p+strlen(p)-7;
	if(q[0] == 'f' && q[1] == 'd' && isdigit((uchar)q[2]) && strcmp(q+3, "disk") == 0) {
	strcpy(q+3, "ctl");
	if((d->ctlfd = open(p, ORDWR)) >= 0) {
	*q = '\0';
	d->prefix = p;
	d->type = Tfloppy;
	return openfile(d);
	}
	}
	}

	/* attempt to find sd(3) disk or partition */
	if(q = strrchr(p, '/'))
	q++;
	else
	q = p;

	strcpy(q, "ctl");
	if((d->ctlfd = open(p, ORDWR)) >= 0) {
	*q = '\0';
	d->prefix = p;
	d->type = Tsd;
	d->part = strdup(disk+(q-p));
	if(d->part == nil){
	close(d->ctlfd);
	close(d->wfd);
	close(d->fd);
	free(p);
	free(d);
	return nil;
	}
	return opensd(d);
	}

	*q = '\0';
	d->prefix = p;
	/* assume we just have a normal file */
	d->type = Tfile;
	return openfile(d);
	}