.\" -*- nroff -*- .\" Copyright 2001 by Theodore Ts'o. All Rights Reserved. .\" This file may be copied under the terms of the GNU Public License. .\" .TH E2IMAGE 8 "@E2FSPROGS_MONTH@ @E2FSPROGS_YEAR@" "E2fsprogs version @E2FSPROGS_VERSION@" .SH NAME e2image \- Save critical ext2/ext3/ext4 filesystem metadata to a file .SH SYNOPSIS .B e2image .RB [ \-r | \-Q " [" \-af ]] [ .B \-b .I superblock ] [ .B \-B .I blocksize ] [ .B \-cnps ] [ .B \-o .I src_offset ] [ .B \-O .I dest_offset ] .I device .I image-file .br .B e2image .B \-I .I device .I image-file .SH DESCRIPTION The .B e2image program will save critical ext2, ext3, or ext4 filesystem metadata located on .I device to a file specified by .IR image-file . The image file may be examined by .B dumpe2fs and .BR debugfs , by using the .B \-i option to those programs. This can assist an expert in recovering catastrophically corrupted filesystems. .PP It is a very good idea to create image files for all filesystems on a system and save the partition layout (which can be generated using the .B fdisk \-l command) at regular intervals --- at boot time, and/or every week or so. The image file should be stored on some filesystem other than the filesystem whose data it contains, to ensure that this data is accessible in the case where the filesystem has been badly damaged. .PP To save disk space, .B e2image creates the image file as a sparse file, or in QCOW2 format. Hence, if the sparse image file needs to be copied to another location, it should either be compressed first or copied using the .B \-\-sparse=always option to the GNU version of .BR cp (1). This does not apply to the QCOW2 image, which is not sparse. .PP The size of an ext2 image file depends primarily on the size of the filesystems and how many inodes are in use. For a typical 10 Gigabyte filesystem, with 200,000 inodes in use out of 1.2 million inodes, the image file will be approximately 35 Megabytes; a 4 Gigabyte filesystem with 15,000 inodes in use out of 550,000 inodes will result in a 3 Megabyte image file. Image files tend to be quite compressible; an image file taking up 32 Megabytes of space on disk will generally compress down to 3 or 4 Megabytes. .PP If .I image-file is .BR \- , then the output of .B e2image will be sent to standard output, so that the output can be piped to another program, such as .BR gzip (1). (Note that this is currently only supported when creating a raw image file using the .B \-r option, since the process of creating a normal image file, or QCOW2 image currently requires random access to the file, which cannot be done using a pipe. .SH OPTIONS .TP .B \-a Include file data in the image file. Normally .B e2image only includes fs metadata, not regular file data. This option will produce an image that is suitable to use to clone the entire FS or for backup purposes. Note that this option only works with the raw .RI ( \-r ) or QCOW2 .RI ( \-Q ) formats. In conjunction with the .B \-r option it is possible to clone all and only the used blocks of one filesystem to another device/image file. .TP .BI \-b " superblock" Get image from partition with broken primary superblock by using the superblock located at filesystem block number .IR superblock . The partition is copied as-is including broken primary superblock. .TP .BI \-B " blocksize" Set the filesystem blocksize in bytes. Normally, .B e2image will search for the superblock at various different block sizes in an attempt to find the appropriate blocksize. This search can be fooled in some cases. This option forces e2fsck to only try locating the superblock with a particular blocksize. If the superblock is not found, e2image will terminate with a fatal error. .TP .BI \-c Compare each block to be copied from the source .I device to the corresponding block in the target .IR image-file . If both are already the same, the write will be skipped. This is useful if the file system is being cloned to a flash-based storage device (where reads are very fast and where it is desirable to avoid unnecessary writes to reduce write wear on the device). .TP .B \-f Override the read-only requirement for the source filesystem when saving the image file using the .B \-r and .B \-Q options. Normally, if the source filesystem is in use, the resulting image file is very likely not going to be useful. In some cases where the source filesystem is in constant use this may be better than no image at all. .TP .B \-I install the metadata stored in the image file back to the device. It can be used to restore the filesystem metadata back to the device in emergency situations. .PP .B WARNING!!!! The .B \-I option should only be used as a desperation measure when other alternatives have failed. If the filesystem has changed since the image file was created, data .B will be lost. In general, you should make another full image backup of the filesystem first, in case you wish to try other recovery strategies afterward. .TP .B \-n Cause all image writes to be skipped, and instead only print the block numbers that would have been written. .TP .BI \-o " src_offset" Specify offset of the image to be read from the start of the source .I device in bytes. See .B OFFSETS for more details. .TP .BI \-O " tgt_offset" Specify offset of the image to be written from the start of the target .I image-file in bytes. See .B OFFSETS for more details. .TP .B \-p Show progress of image-file creation. .TP .B \-Q Create a QCOW2-format image file instead of a normal image file, suitable for use by virtual machine images, and other tools that can use the .B .qcow image format. See .B QCOW2 IMAGE FILES below for details. .TP .B \-r Create a raw image file instead of a normal image file. See .B RAW IMAGE FILES below for details. .TP .B \-s Scramble directory entries and zero out unused portions of the directory blocks in the written image file to avoid revealing information about the contents of the filesystem. However, this will prevent analysis of problems related to hash-tree indexed directories. .SH RAW IMAGE FILES The .B \-r option will create a raw image file, which differs from a normal image file in two ways. First, the filesystem metadata is placed in the same relative offset within .I image-file as it is in the .I device so that .BR debugfs (8), .BR dumpe2fs (8), .BR e2fsck (8), .BR losetup (8), etc. and can be run directly on the raw image file. In order to minimize the amount of disk space consumed by the raw image file, it is created as a sparse file. (Beware of copying or compressing/decompressing this file with utilities that don't understand how to create sparse files; the file will become as large as the filesystem itself!) Secondly, the raw image file also includes indirect blocks and directory blocks, which the standard image file does not have. .PP Raw image files are sometimes used when sending filesystems to the maintainer as part of bug reports to e2fsprogs. When used in this capacity, the recommended command is as follows (replace .B hda1 with the appropriate device for your system): .PP .br \fBe2image \-r /dev/hda1 \- | bzip2 > hda1.e2i.bz2\fR .PP This will only send the metadata information, without any data blocks. However, the filenames in the directory blocks can still reveal information about the contents of the filesystem that the bug reporter may wish to keep confidential. To address this concern, the .B \-s option can be specified to scramble the filenames in the image. .PP Note that this will work even if you substitute .B /dev/hda1 for another raw disk image, or QCOW2 image previously created by .BR e2image . .SH QCOW2 IMAGE FILES The .B \-Q option will create a QCOW2 image file instead of a normal, or raw image file. A QCOW2 image contains all the information the raw image does, however unlike the raw image it is not sparse. The QCOW2 image minimize the amount of space used by the image by storing it in special format which packs data closely together, hence avoiding holes while still minimizing size. .PP In order to send filesystem to the maintainer as a part of bug report to e2fsprogs, use following commands (replace .B hda1 with the appropriate device for your system): .PP .br \ \fBe2image \-Q /dev/hda1 hda1.qcow2\fR .br \ \fBbzip2 -z hda1.qcow2\fR .PP This will only send the metadata information, without any data blocks. As described for .B RAW IMAGE FILES the .B \-s option can be specified to scramble the filesystem names in the image. .PP Note that the QCOW2 image created by .B e2image is a regular QCOW2 image and can be processed by tools aware of QCOW2 format such as for example .BR qemu-img . .PP You can convert a .qcow2 image into a raw image with: .PP .br \ \fBe2image \-r hda1.qcow2 hda1.raw\fR .br .PP This can be useful to write a QCOW2 image containing all data to a sparse image file where it can be loop mounted, or to a disk partition. Note that this may not work with QCOW2 images not generated by e2image. .SH OFFSETS Normally a filesystem starts at the beginning of a partition, and .B e2image is run on the partition. When working with image files, you don't have the option of using the partition device, so you can specify the offset where the filesystem starts directly with the .B \-o option. Similarly the .B \-O option specifies the offset that should be seeked to in the destination before writing the filesystem. .PP For example, if you have a .B dd image of a whole hard drive that contains an ext2 fs in a partition starting at 1 MiB, you can clone that image to a block device with: .PP .br \ \fBe2image \-aro 1048576 img /dev/sda1\fR .br .PP Or you can clone a filesystem from a block device into an image file, leaving room in the first MiB for a partition table with: .PP .br \ \fBe2image -arO 1048576 /dev/sda1 img\fR .br .PP If you specify at least one offset, and only one file, an in-place move will be performed, allowing you to safely move the filesystem from one offset to another. .SH AUTHOR .B e2image was written by Theodore Ts'o (tytso@mit.edu). .SH AVAILABILITY .B e2image is part of the e2fsprogs package and is available from http://e2fsprogs.sourceforge.net. .SH SEE ALSO .BR dumpe2fs (8), .BR debugfs (8) .BR e2fsck (8)