Securely wipe disk

Wiping a disk is done by writing new data over every single bit.

Tip: References to "disks" in this article also apply to loopback devices.

Common use cases

Wipe all data left on the device

The most common usecase for completely and irrevocably wiping a device is when the device is going to be given away or sold. There may be (unencrypted) data left on the device and you want to protect against simple forensic investigation that is mere child's play with for example File recovery software.

If you want to quickly wipe everything from the disk, /dev/zero or simple patterns allow maximum performance while adequate randomness can be advantageous in some cases that should be covered up in #Data remanence.

Every overwritten bit means to provide a level of data erasure not allowing recovery with normal system functions (like standard ATA/SCSI commands) and hardware interfaces. Any file recovery software mentioned above then would need to be specialized on proprietary storage-hardware features.

In case of a HDD, data recreation will not be possible without at least undocumented drive commands or tinkering with the device's controller or firmware to make them read out for example reallocated sectors (bad blocks that S.M.A.R.T. retired from use).

There are different wiping issues with different physical storage technologies. Most notably, all Flash memory based devices and older magnetic storage (old HDDs, floppy disks, tape).

Preparations for block device encryption

To prepare a drive for block device encryption inside the wiped area afterwards, it is recommended to use #Random data generated by a cryptographically strong random number generator (referred to as RNG in this article from now on).

See also Wikipedia:Random number generation.

Warning: If block device encryption is mapped on a partition that contains non-random or unencrypted data, the encryption is weakened and becomes comparable to filesystem-level encryption: disclosure of usage patterns on the encrypted drive becomes possible. Therefore, do not fill space with zeros, simple patterns (like badblocks) or other non-random data before setting up block device encryption if you are serious about it.

Data remanence

See also Wikipedia:Data remanence. The representation of data may remain even after attempts have been made to remove or erase the data.

Operating system, programs and filesystem

The operating system, executed programs or journaling file systems may copy your unencrypted data throughout the block device. When writing to plain disks, this should only be relevant in conjunction with one of the above.

If the data can be exactly located on the disk and was never copied anywhere else, wiping with random data can be thoroughgoing and impressively quick as long there is enough entropy in the pool.

A good example is cryptsetup using /dev/urandom for wiping the LUKS keyslots.

Flash memory

Write amplification and other characteristics make Flash memory, including SSDs, a stubborn target for reliable wiping. As there is a lot of transparent abstraction in between data as seen by a device's controller chip and the operating system, sight data is never overwritten in place and wiping particular blocks or files is not reliable.

Other "features" like transparent compression (all SandForce SSDs) can compress your zeros or repetitive patterns, so if wiping is fast beyond belief this might be the cause.

Disassembling Flash memory devices, unsoldering the chips and analyzing data content without the controller in between is feasible without difficulty using simple hardware. Data recovery companies do it for cheap money.

For more information see:

Marked Bad Sectors

If a hard drive marks a sector as bad, it cordons it off, and the section becomes impossible to write to via software. Thus a full overwrite would not reach it. However because of block sizes, these sections would only amount to a few theoretically recoverable KiB.

Residual magnetism

A single, full overwrite with zeros or random data does not lead to any recoverable data on a modern high-density storage device. Note that repeating the operation should not be necessary nowadays. Indications otherwise refer to single residual bits; reconstruction of byte patterns is generally not feasible. See also , and .

Select a target

Use fdisk to locate all read/write devices the user has read access to.

Check the output for lines that start with devices such as .

This is an example for a HDD formatted to boot a linux system:

Or another example with the Arch Linux image written to a 4GB USB thumb drive:

# fdisk -l
Disk /dev/sdb: 4075 MB, 4075290624 bytes, 7959552 sectors
Units = sectors of 1 * 512 = 512 bytes
Sector size (logical/physical): 512 bytes / 512 bytes
I/O size (minimum/optimal): 512 bytes / 512 bytes
Disk identifier: 0x526e236e

   Device Boot      Start         End      Blocks   Id  System
/dev/sdb1   *           0      802815      401408   17  Hidden HPFS/NTFS

If you are worried about unintentional damage of important data on the primary computer, consider using an isolated environment such as a virtual environment (VirtualBox, VMWare, QEMU, etc...) with direct connected disk drives to it or a single computer only with a storage disk(s) that need to be wiped booted from a Live Media (USB, CD, PXE, etc...) or use a script to prevent wiping mounted partitions by typo.

Select a data source

To wipe sensitive data, one can use any data pattern matching the needs.


Overwriting with /dev/zero or simple patterns is considered secure in most situations. With today's HDDs, it is deemed appropriate and fast for disk wiping.

However, a drive that is abnormally fast in writing patterns or zeroing could be doing transparent compression. It is obviously presumable not all blocks get wiped this way. Some #Flash memory devices do "feature" that.

To setup block device encryption afterwards, one should wipe the area with random data (see next section) to avoid weakening the encryption.

Random data

True random data source using /dev/random is impractical for wiping large capacities as it will take too long to wait for the entropy generation. /dev/urandom can be used as a reasonable source of pseudorandom data. For differences between random and pseudorandom data as source, please see Random number generation.

Another alternative for pseudorandom data generation is to use an encrypted datastream. For example, if one wants to prepare a device for block encryption and will use AES for the encrypted partition, it is appropriate to wipe it with a similar cipher prior to creating the filesystem to make the empty space not distinguishable from the used space.

Select a block size

See also Wikipedia:Dd (Unix)#Block size, blocksize io-limits.

If you have an Advanced Format hard drive it is recommended that you specify a block size larger than the default 512 bytes. To speed up the overwriting process choose a block size matching your drive's physical geometry by appending the block size option to the dd command (i.e. for 4 KiB).

fdisk prints physical and logical sector size for every disk. Alternatively sysfs does expose information:


Calculate blocks to wipe manually

Block storage devices are divided in sectors, and the size of a single sector can be used to calculate the size of the entire device in bytes. To do so, multiply the number of sectors by the drive sector size.

As an example we use the parameters with the dd command to wipe a partition:

# dd if=data_source of=/dev/sdX bs=sector_size count=sector_number seek=partitions_start_sector status=progress

Here, to illustrate with a practical example, we will show the output of the fdisk command on the partition :

  • The first line of the fdisk output shows the disk size in bytes and in logical sectors.
  • The size in bytes of the storage device or of the partition can also be obtained with the command .
  • The Units line of the fdisk output shows the size of single logical sector; the logical sector size can also be derived from the number of bytes divided by the number of logical sectors, here use: .
  • To know the physical sector size in bytes (that will make it work faster), we can use the next line.
  • To get the disk size in physical sectors, one can divide the disk size in bytes by the size of a single physical sector, here ,
  • In the examples below we will use the logical sector size.
  • You can even wipe unallocated disk space with a dd command by calculating the difference between the end of one and start of the next partition.

To wipe partition , the example parameters with logical sectors would be used like follows.

  • By using the starting address of the partition on the device using the seek= parameter:
# dd if=data_source of=/dev/sdX bs=${BytesInSector} count=${End - Start} seek=${Start} status=progress

with , and .

  • Or by using the partitions size in logical sectors:
# dd if=data_source of=/dev/sdX1 bs=${BytesInSector} count=${LogicalSectors} status=progress

with .

Or, to wipe the whole disk by using physical sectors:

# dd if=data_source of=/dev/sdX bs=${PhysicalSectorSizeBytes} count=${AllDiskPhysicalSectors} seek=0 status=progress

with and .

Overwrite the target

You can choose from several utilities to overwrite a drive. If you only want to wipe a single file, Securely wipe disk/Tips and tricks#Wipe a single file has considerations in addition to the utilities mentioned below.

By redirecting output

The redirected output can be used to create files, rewrite free space on the partition, and to wipe the whole device or a single partition on it. The examples here use /dev/zero to zero the device, but /dev/urandom may be substituted if a random wipe is desired.

The following examples show how to rewrite the partition or a block device by redirecting stdout from other utilities:

# cat /dev/zero > /dev/sd"XY"
cat: write error: No space left on device

The file copy command cp can also be used to rewrite the device, because it ignores the type of the destination:

To display progress status and metrics you can use :

# pv --progress --timer --eta --rate --bytes --stop-at-size -s "$(blockdev --getsize64 /dev/sd"XY" )" /dev/zero > /dev/sd"XY"


See also dd and Securely wipe disk/Tips and tricks#Wipe a single file.

Zero-fill the disk by writing a zero byte to every addressable location on the disk using the /dev/zero stream.

# dd if=/dev/zero of=/dev/sdX bs=4096 status=progress

Or the /dev/urandom stream:

# dd if=/dev/urandom of=/dev/sdX bs=4096 status=progress

The process is finished when dd reports and returns control back:

dd: writing to ‘/dev/sdX’: No space left on device
7959553+0 records in
7959552+0 records out
4075290624 bytes (4.1 GB, 3.8 GiB) copied, 1247.7 s, 3.3 MB/s

To speed up wiping a large drive, see also:


A program specialized on wiping files. It is available as part of the package. To make a quick wipe of a destination, you can use something like:

$ wipe -r /path/to/wipe

See also . The tool was last updated in 2009. Its SourceForge page suggests that it is currently unmaintained.


shred (from the package) is a Unix command that can be used to securely delete individual files or full devices so that they can be recovered only with great difficulty with specialised hardware, if at all. By default shred uses three passes, writing pseudo-random data to the device during each pass. This can be reduced or increased.

The following command invokes shred with its default settings and displays the progress.

# shred -v /dev/sdX

Shred can also be used on a single partition, e.g. to wipe the first partition use shred -v /dev/sdX1.

Alternatively, shred can be instructed to do only one pass, with entropy from e.g. /dev/urandom, and a final overwrite with zeros.

# shred --verbose --random-source=/dev/urandom -n1 --zero /dev/sdX


The tool badblocks from is able to perform destructive read-write test, effectively wiping the device. By default, it performs four passes and can take very long.

# badblocks -wsv /dev/device


hdparm supports ATA Secure Erase, which is functionally equivalent to zero-filling a disk. It is however handled by the hard drive firmware itself, and includes "hidden data areas". As such, it can be seen as a modern-day "low-level format" command. SSD drives reportedly achieve factory performance after issuing this command, but may not be sufficiently wiped (see #Flash memory).

Some drives support Enhanced Secure Erase, which uses distinct patterns defined by the manufacturer. If the output of for the device indicates a manifold time advantage for the Enhanced erasure, the device probably has a hardware encryption feature and the wipe will be performed to the encryption keys only.

For detailed instructions on using ATA Secure Erase, see Solid state drive/Memory cell clearing and the Linux ATA wiki.


See Solid state drive/Memory cell clearing#Common method with blkdiscard

See also

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