/*
libparted - a library for manipulating disk partitions
Copyright (C) 1999 - 2001, 2005, 2007-2010 Free Software Foundation, Inc.
This program 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.
This program 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 this program. If not, see .
*/
/** \file device.c */
/**
* \addtogroup PedDevice
*
* \brief Device access.
*
* When ped_device_probe_all() is called, libparted attempts to detect all
* devices. It constructs a list which can be accessed with
* ped_device_get_next().
*
* If you want to use a device that isn't on the list, use
* ped_device_get(). Also, there may be OS-specific constructors, for creating
* devices from file descriptors, stores, etc. For example,
* ped_device_new_from_store().
*
* @{
*/
#include
#include
#include
#include
#include
#include
#include
#include "architecture.h"
static PedDevice* devices; /* legal advice says: initialized to NULL,
under section 6.7.8 part 10
of ISO/EIC 9899:1999 */
static void
_device_register (PedDevice* dev)
{
PedDevice* walk;
for (walk = devices; walk && walk->next; walk = walk->next);
if (walk)
walk->next = dev;
else
devices = dev;
dev->next = NULL;
}
static void
_device_unregister (PedDevice* dev)
{
PedDevice* walk;
PedDevice* last = NULL;
for (walk = devices; walk != NULL; last = walk, walk = walk->next) {
if (walk == dev) break;
}
/* This function may be called twice for the same device if a
libparted user explictly removes the device from the cache using
ped_device_cache_remove(), we get called and it then becomes the
user's responsibility to free the PedDevice by calling
ped_device_destroy().
ped_device_destroy() will then call us a second time, so if the
device is not found in the list do nothing. */
if (walk == NULL)
return;
if (last)
last->next = dev->next;
else
devices = dev->next;
}
/**
* Returns the next device that was detected by ped_device_probe_all(), or
* calls to ped_device_get_next().
* If dev is NULL, returns the first device.
*
* \return NULL if dev is the last device.
*/
PedDevice*
ped_device_get_next (const PedDevice* dev)
{
if (dev)
return dev->next;
else
return devices;
}
void
_ped_device_probe (const char* path)
{
PedDevice* dev;
PED_ASSERT (path != NULL);
ped_exception_fetch_all ();
dev = ped_device_get (path);
if (!dev)
ped_exception_catch ();
ped_exception_leave_all ();
}
/**
* Attempts to detect all devices.
*/
void
ped_device_probe_all ()
{
ped_architecture->dev_ops->probe_all ();
}
/**
* Close/free all devices.
* Called by ped_done(), so you do not need to worry about it.
*/
void
ped_device_free_all ()
{
while (devices)
ped_device_destroy (devices);
}
/**
* Gets the device "name", where name is usually the block device, e.g.
* /dev/sdb. If the device wasn't detected with ped_device_probe_all(),
* an attempt will be made to detect it again. If it is found, it will
* be added to the list.
*/
PedDevice*
ped_device_get (const char* path)
{
PedDevice* walk;
char* normal_path = NULL;
PED_ASSERT (path != NULL);
/* Don't canonicalize /dev/mapper or /dev/md/ paths, see
tests/symlink.c
*/
if (strncmp (path, "/dev/mapper/", 12) &&
strncmp (path, "/dev/md/", 8))
normal_path = canonicalize_file_name (path);
if (!normal_path)
/* Well, maybe it is just that the file does not exist.
* Try it anyway. */
normal_path = strdup (path);
if (!normal_path)
return NULL;
for (walk = devices; walk != NULL; walk = walk->next) {
if (!strcmp (walk->path, normal_path)) {
free (normal_path);
return walk;
}
}
walk = ped_architecture->dev_ops->_new (normal_path);
free (normal_path);
if (!walk)
return NULL;
_device_register (walk);
return walk;
}
/**
* Destroys a device and removes it from the device list, and frees
* all resources associated with the device (all resources allocated
* when the device was created).
*/
void
ped_device_destroy (PedDevice* dev)
{
_device_unregister (dev);
while (dev->open_count) {
if (!ped_device_close (dev))
break;
}
ped_architecture->dev_ops->destroy (dev);
}
void
ped_device_cache_remove(PedDevice *dev)
{
_device_unregister (dev);
}
int
ped_device_is_busy (PedDevice* dev)
{
return ped_architecture->dev_ops->is_busy (dev);
}
/**
* Attempt to open a device to allow use of read, write and sync functions.
*
* The meaning of "open" is architecture-dependent. Apart from requesting
* access to the device from the operating system, it does things like flushing
* caches.
* \note May allocate resources. Any resources allocated here will
* be freed by a final ped_device_close(). (ped_device_open() may be
* called multiple times -- it's a ref-count-like mechanism)
*
* \return zero on failure
*/
int
ped_device_open (PedDevice* dev)
{
int status;
PED_ASSERT (dev != NULL);
PED_ASSERT (!dev->external_mode);
if (dev->open_count)
status = ped_architecture->dev_ops->refresh_open (dev);
else
status = ped_architecture->dev_ops->open (dev);
if (status)
dev->open_count++;
return status;
}
/**
* Close dev.
* If this is the final close, then resources allocated by
* ped_device_open() are freed.
*
* \return zero on failure
*/
int
ped_device_close (PedDevice* dev)
{
PED_ASSERT (dev != NULL);
PED_ASSERT (!dev->external_mode);
PED_ASSERT (dev->open_count > 0);
if (--dev->open_count)
return ped_architecture->dev_ops->refresh_close (dev);
else
return ped_architecture->dev_ops->close (dev);
}
/**
* Begins external access mode. External access mode allows you to
* safely do IO on the device. If a PedDevice is open, then you should
* not do any IO on that device, e.g. by calling an external program
* like e2fsck, unless you put it in external access mode. You should
* not use any libparted commands that do IO to a device, e.g.
* ped_file_system_{open|resize|copy}, ped_disk_{read|write}), while
* a device is in external access mode.
* Also, you should not ped_device_close() a device, while it is
* in external access mode.
* Note: ped_device_begin_external_access_mode() does things like
* tell the kernel to flush its caches.
*
* Close a device while pretending it is still open.
* This is useful for temporarily suspending libparted access to the device
* in order for an external program to access it.
* (Running external programs while the device is open can cause cache
* coherency problems.)
*
* In particular, this function keeps track of dev->open_count, so that
* reference counting isn't screwed up.
*
* \return zero on failure.
*/
int
ped_device_begin_external_access (PedDevice* dev)
{
PED_ASSERT (dev != NULL);
PED_ASSERT (!dev->external_mode);
dev->external_mode = 1;
if (dev->open_count)
return ped_architecture->dev_ops->close (dev);
else
return 1;
}
/**
* \brief Complementary function to ped_device_begin_external_access.
*
* \note does things like tell the kernel to flush the device's cache.
*
* \return zero on failure.
*/
int
ped_device_end_external_access (PedDevice* dev)
{
PED_ASSERT (dev != NULL);
PED_ASSERT (dev->external_mode);
dev->external_mode = 0;
if (dev->open_count)
return ped_architecture->dev_ops->open (dev);
else
return 1;
}
/**
* \internal Read count sectors from dev into buffer, beginning with sector
* start.
*
* \return zero on failure.
*/
int
ped_device_read (const PedDevice* dev, void* buffer, PedSector start,
PedSector count)
{
PED_ASSERT (dev != NULL);
PED_ASSERT (buffer != NULL);
PED_ASSERT (!dev->external_mode);
PED_ASSERT (dev->open_count > 0);
return (ped_architecture->dev_ops->read) (dev, buffer, start, count);
}
/**
* \internal Write count sectors from buffer to dev, starting at sector
* start.
*
* \return zero on failure.
*
* \sa PedDevice::sector_size
* \sa PedDevice::phys_sector_size
*/
int
ped_device_write (PedDevice* dev, const void* buffer, PedSector start,
PedSector count)
{
PED_ASSERT (dev != NULL);
PED_ASSERT (buffer != NULL);
PED_ASSERT (!dev->external_mode);
PED_ASSERT (dev->open_count > 0);
return (ped_architecture->dev_ops->write) (dev, buffer, start, count);
}
PedSector
ped_device_check (PedDevice* dev, void* buffer, PedSector start,
PedSector count)
{
PED_ASSERT (dev != NULL);
PED_ASSERT (!dev->external_mode);
PED_ASSERT (dev->open_count > 0);
return (ped_architecture->dev_ops->check) (dev, buffer, start, count);
}
/**
* \internal Flushes all write-behind caches that might be holding up
* writes.
* It is slow because it guarantees cache coherency among all relevant caches.
*
* \return zero on failure
*/
int
ped_device_sync (PedDevice* dev)
{
PED_ASSERT (dev != NULL);
PED_ASSERT (!dev->external_mode);
PED_ASSERT (dev->open_count > 0);
return ped_architecture->dev_ops->sync (dev);
}
/**
* \internal Flushes all write-behind caches that might be holding writes.
* \warning Does NOT ensure cache coherency with other caches.
* If you need cache coherency, use ped_device_sync() instead.
*
* \return zero on failure
*/
int
ped_device_sync_fast (PedDevice* dev)
{
PED_ASSERT (dev != NULL);
PED_ASSERT (!dev->external_mode);
PED_ASSERT (dev->open_count > 0);
return ped_architecture->dev_ops->sync_fast (dev);
}
/**
* Get a constraint that represents hardware requirements on geometry.
* This function will return a constraint representing the limits imposed
* by the size of the disk, it will *not* provide any alignment constraints.
*
* Alignment constraints may be desirable when using media that have a physical
* sector size that is a multiple of the logical sector size, as in this case
* proper partition alignment can benefit disk performance signigicantly.
* When you want a constraint with alignment info, use
* ped_device_get_minimal_aligned_constraint() or
* ped_device_get_optimal_aligned_constraint().
*
* \return NULL on error, otherwise a pointer to a dynamically allocated
* constraint.
*/
PedConstraint*
ped_device_get_constraint (const PedDevice* dev)
{
PedGeometry *s, *e;
PedConstraint* c = ped_constraint_new (
ped_alignment_any, ped_alignment_any,
s = ped_geometry_new (dev, 0, dev->length),
e = ped_geometry_new (dev, 0, dev->length),
1, dev->length);
free (s);
free (e);
return c;
}
static PedConstraint*
_ped_device_get_aligned_constraint(const PedDevice *dev,
PedAlignment* start_align)
{
PedAlignment *end_align = NULL;
PedGeometry *whole_dev_geom = NULL;
PedConstraint *c = NULL;
if (start_align) {
end_align = ped_alignment_new(start_align->offset - 1,
start_align->grain_size);
if (!end_align)
goto free_start_align;
}
whole_dev_geom = ped_geometry_new (dev, 0, dev->length);
if (start_align)
c = ped_constraint_new (start_align, end_align,
whole_dev_geom, whole_dev_geom,
1, dev->length);
else
c = ped_constraint_new (ped_alignment_any, ped_alignment_any,
whole_dev_geom, whole_dev_geom,
1, dev->length);
free (whole_dev_geom);
free (end_align);
free_start_align:
free (start_align);
return c;
}
/**
* Get a constraint that represents hardware requirements on geometry and
* alignment.
*
* This function will return a constraint representing the limits imposed
* by the size of the disk and the minimal alignment requirements for proper
* performance of the disk.
*
* \return NULL on error, otherwise a pointer to a dynamically allocated
* constraint.
*/
PedConstraint*
ped_device_get_minimal_aligned_constraint(const PedDevice *dev)
{
return _ped_device_get_aligned_constraint(dev,
ped_device_get_minimum_alignment(dev));
}
/**
* Get a constraint that represents hardware requirements on geometry and
* alignment.
*
* This function will return a constraint representing the limits imposed
* by the size of the disk and the alignment requirements for optimal
* performance of the disk.
*
* \return NULL on error, otherwise a pointer to a dynamically allocated
* constraint.
*/
PedConstraint*
ped_device_get_optimal_aligned_constraint(const PedDevice *dev)
{
return _ped_device_get_aligned_constraint(dev,
ped_device_get_optimum_alignment(dev));
}
/**
* Get an alignment that represents minimum hardware requirements on alignment.
* When for example using media that has a physical sector size that is a
* multiple of the logical sector size, it is desirable to have disk accesses
* (and thus partitions) properly aligned. Having partitions not aligned to
* the minimum hardware requirements may lead to a performance penalty.
*
* The returned alignment describes the alignment for the start sector of the
* partition, the end sector should be aligned too, to get the end sector
* alignment decrease the returned alignment's offset by 1.
*
* \return the minimum alignment of partition start sectors, or NULL if this
* information is not available.
*/
PedAlignment*
ped_device_get_minimum_alignment(const PedDevice *dev)
{
PedAlignment *align = NULL;
if (ped_architecture->dev_ops->get_minimum_alignment)
align = ped_architecture->dev_ops->get_minimum_alignment(dev);
if (align == NULL)
align = ped_alignment_new(0,
dev->phys_sector_size / dev->sector_size);
return align;
}
/**
* Get an alignment that represents the hardware requirements for optimal
* performance.
*
* The returned alignment describes the alignment for the start sector of the
* partition, the end sector should be aligned too, to get the end sector
* alignment decrease the returned alignment's offset by 1.
*
* \return the optimal alignment of partition start sectors, or NULL if this
* information is not available.
*/
PedAlignment*
ped_device_get_optimum_alignment(const PedDevice *dev)
{
PedAlignment *align = NULL;
if (ped_architecture->dev_ops->get_optimum_alignment)
align = ped_architecture->dev_ops->get_optimum_alignment(dev);
/* If the arch specific code could not give as an alignment
return a default value based on the type of device. */
if (align == NULL) {
/* Align to a grain of 1MiB (like vista / win7) */
align = ped_alignment_new(0,
(PED_DEFAULT_ALIGNMENT
/ dev->sector_size));
}
return align;
}
/** @} */