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IOCTL_GETFSMAP(2) Linux Programmer's Manual IOCTL_GETFSMAP(2)

NAME

ioctl_getfsmap - retrieve the physical layout of the filesystem

SYNOPSIS

#include <sys/ioctl.h>
#include <linux/fs.h>
#include <linux/fsmap.h>

int ioctl(int fd, FS_IOC_GETFSMAP, struct fsmap_head * arg);

DESCRIPTION

This ioctl(2) operation retrieves physical extent mappings for a filesystem. This information can be used to discover which files are mapped to a physical block, examine free space, or find known bad blocks, among other things.

The sole argument to this operation should be a pointer to a single struct fsmap_head:


struct fsmap {

__u32 fmr_device; /* Device ID */
__u32 fmr_flags; /* Mapping flags */
__u64 fmr_physical; /* Device offset of segment */
__u64 fmr_owner; /* Owner ID */
__u64 fmr_offset; /* File offset of segment */
__u64 fmr_length; /* Length of segment */
__u64 fmr_reserved[3]; /* Must be zero */ }; struct fsmap_head {
__u32 fmh_iflags; /* Control flags */
__u32 fmh_oflags; /* Output flags */
__u32 fmh_count; /* # of entries in array incl. input */
__u32 fmh_entries; /* # of entries filled in (output) */
__u64 fmh_reserved[6]; /* Must be zero */
struct fsmap fmh_keys[2]; /* Low and high keys for
the mapping search */
struct fsmap fmh_recs[]; /* Returned records */ };

The two fmh_keys array elements specify the lowest and highest reverse-mapping key for which the application would like physical mapping information. A reverse mapping key consists of the tuple (device, block, owner, offset). The owner and offset fields are part of the key because some filesystems support sharing physical blocks between multiple files and therefore may return multiple mappings for a given physical block.

Filesystem mappings are copied into the fmh_recs array, which immediately follows the header data.

Fields of struct fsmap_head

The fmh_iflags field is a bit mask passed to the kernel to alter the output. No flags are currently defined, so the caller must set this value to zero.

The fmh_oflags field is a bit mask of flags set by the kernel concerning the returned mappings. If FMH_OF_DEV_T is set, then the fmr_device field represents a dev_t structure containing the major and minor numbers of the block device.

The fmh_count field contains the number of elements in the array being passed to the kernel. If this value is 0, fmh_entries will be set to the number of records that would have been returned had the array been large enough; no mapping information will be returned.

The fmh_entries field contains the number of elements in the fmh_recs array that contain useful information.

The fmh_reserved fields must be set to zero.

Keys

The two key records in fsmap_head.fmh_keys specify the lowest and highest extent records in the keyspace that the caller wants returned. A filesystem that can share blocks between files likely requires the tuple (device, physical, owner, offset, flags) to uniquely index any filesystem mapping record. Classic non-sharing filesystems might be able to identify any record with only (device, physical, flags). For example, if the low key is set to (8:0, 36864, 0, 0, 0), the filesystem will only return records for extents starting at or above 36 KiB on disk. If the high key is set to (8:0, 1048576, 0, 0, 0), only records below 1 MiB will be returned. The format of fmr_device in the keys must match the format of the same field in the output records, as defined below. By convention, the field fsmap_head.fmh_keys[0] must contain the low key and fsmap_head.fmh_keys[1] must contain the high key for the request.

For convenience, if fmr_length is set in the low key, it will be added to fmr_block or fmr_offset as appropriate. The caller can take advantage of this subtlety to set up subsequent calls by copying fsmap_head.fmh_recs[fsmap_head.fmh_entries - 1] into the low key. The function fsmap_advance (defined in linux/fsmap.h) provides this functionality.

Fields of struct fsmap

The fmr_device field uniquely identifies the underlying storage device. If the FMH_OF_DEV_T flag is set in the header's fmh_oflags field, this field contains a dev_t from which major and minor numbers can be extracted. If the flag is not set, this field contains a value that must be unique for each unique storage device.

The fmr_physical field contains the disk address of the extent in bytes.

The fmr_owner field contains the owner of the extent. This is an inode number unless FMR_OF_SPECIAL_OWNER is set in the fmr_flags field, in which case the value is determined by the filesystem. See the section below about owner values for more details.

The fmr_offset field contains the logical address in the mapping record in bytes. This field has no meaning if the FMR_OF_SPECIAL_OWNER or FMR_OF_EXTENT_MAP flags are set in fmr_flags.

The fmr_length field contains the length of the extent in bytes.

The fmr_flags field is a bit mask of extent state flags. The bits are:

The extent is allocated but not yet written.
This extent contains extended attribute data.
This extent contains extent map information for the owner.
Parts of this extent may be shared.
The fmr_owner field contains a special value instead of an inode number.
This is the last record in the data set.

The fmr_reserved field will be set to zero.

Owner values

Generally, the value of the fmr_owner field for non-metadata extents should be an inode number. However, filesystems are under no obligation to report inode numbers; they may instead report FMR_OWN_UNKNOWN if the inode number cannot easily be retrieved, if the caller lacks sufficient privilege, if the filesystem does not support stable inode numbers, or for any other reason. If a filesystem wishes to condition the reporting of inode numbers based on process capabilities, it is strongly urged that the CAP_SYS_ADMIN capability be used for this purpose.

Free space.
This extent is in use but its owner is not known or not easily retrieved.
This extent is filesystem metadata.

XFS can return the following special owner values:

Free space.
This extent is in use but its owner is not known or not easily retrieved.
Static filesystem metadata which exists at a fixed address. These are the AG superblock, the AGF, the AGFL, and the AGI headers.
The filesystem journal.
Allocation group metadata, such as the free space btrees and the reverse mapping btrees.
The inode and free inode btrees.
Inode records.
Reference count information.
This extent is being used to stage a copy-on-write.
This extent has been marked defective either by the filesystem or the underlying device.

ext4 can return the following special owner values:

Free space.
This extent is in use but its owner is not known or not easily retrieved.
Static filesystem metadata which exists at a fixed address. This is the superblock and the group descriptors.
The filesystem journal.
Inode records.
Block bit map.
Inode bit map.

RETURN VALUE

On error, -1 is returned, and errno is set to indicate the error.

ERRORS

The error placed in errno can be one of, but is not limited to, the following:

fd is not open for reading.
The filesystem has detected a checksum error in the metadata.
The pointer passed in was not mapped to a valid memory address.
The array is not long enough, the keys do not point to a valid part of the filesystem, the low key points to a higher point in the filesystem's physical storage address space than the high key, or a nonzero value was passed in one of the fields that must be zero.
Insufficient memory to process the request.
The filesystem does not support this command.
The filesystem metadata is corrupt and needs repair.

VERSIONS

The FS_IOC_GETFSMAP operation first appeared in Linux 4.12.

CONFORMING TO

This API is Linux-specific. Not all filesystems support it.

EXAMPLE

See io/fsmap.c in the xfsprogs distribution for a sample program.

SEE ALSO

ioctl(2)

COLOPHON

This page is part of release 4.15 of the Linux man-pages project. A description of the project, information about reporting bugs, and the latest version of this page, can be found at https://www.kernel.org/doc/man-pages/.

2017-09-15 Linux