OPENSSL-ENC(1ssl) OpenSSL OPENSSL-ENC(1ssl)

openssl-enc - symmetric cipher routines

openssl enc|cipher [-cipher] [-help] [-list] [-ciphers] [-in filename] [-out filename] [-pass arg] [-e] [-d] [-a] [-base64] [-A] [-k password] [-kfile filename] [-K key] [-iv IV] [-S salt] [-salt] [-nosalt] [-z] [-md digest] [-iter count] [-pbkdf2] [-saltlen size] [-p] [-P] [-bufsize number] [-nopad] [-v] [-debug] [-none] [-engine id] [-rand files] [-writerand file] [-provider name] [-provider-path path] [-propquery propq]

openssl cipher [...]

The symmetric cipher commands allow data to be encrypted or decrypted using various block and stream ciphers using keys based on passwords or explicitly provided. Base64 encoding or decoding can also be performed either by itself or in addition to the encryption or decryption.

The cipher to use.
Print out a usage message.
List all supported ciphers.
Alias of -list to display all supported ciphers.
The input filename, standard input by default.
The output filename, standard output by default.
The password source. For more information about the format of arg see openssl-passphrase-options(1).
Encrypt the input data: this is the default.
Decrypt the input data.
Base64 process the data. This means that if encryption is taking place the data is base64 encoded after encryption. If decryption is set then the input data is base64 decoded before being decrypted.

When the -A option not given, on encoding a newline is inserted after each 64 characters, and on decoding a newline is expected among the first 1024 bytes of input.

Same as -a
If the -a option is set then base64 encoding produces output without any newline character, and base64 decoding does not require any newlines. Therefore it can be helpful to use the -A option when decoding unknown input.
The password to derive the key from. This is for compatibility with previous versions of OpenSSL. Superseded by the -pass argument.
Read the password to derive the key from the first line of filename. This is for compatibility with previous versions of OpenSSL. Superseded by the -pass argument.
Use the specified digest to create the key from the passphrase. The default algorithm is sha-256.
Use a given number of iterations on the password in deriving the encryption key. High values increase the time required to brute-force the resulting file. This option enables the use of PBKDF2 algorithm to derive the key.
Use PBKDF2 algorithm with a default iteration count of 10000 unless otherwise specified by the -iter command line option.
Set the salt length to use when using the -pbkdf2 option. For compatibility reasons, the default is 8 bytes. The maximum value is currently 16 bytes. If the -pbkdf2 option is not used, then this option is ignored and a fixed salt length of 8 is used. The salt length used when encrypting must also be used when decrypting.
Don't use a salt in the key derivation routines. This option SHOULD NOT be used except for test purposes or compatibility with ancient versions of OpenSSL.
Use salt (randomly generated or provide with -S option) when encrypting, this is the default.
The actual salt to use: this must be represented as a string of hex digits. If this option is used while encrypting, the same exact value will be needed again during decryption. This salt may be truncated or zero padded to match the salt length (See -saltlen).
The actual key to use: this must be represented as a string comprised only of hex digits. If only the key is specified, the IV must additionally specified using the -iv option. When both a key and a password are specified, the key given with the -K option will be used and the IV generated from the password will be taken. It does not make much sense to specify both key and password.
The actual IV to use: this must be represented as a string comprised only of hex digits. When only the key is specified using the -K option, the IV must explicitly be defined. When a password is being specified using one of the other options, the IV is generated from this password.
Print out the key and IV used.
Print out the key and IV used then immediately exit: don't do any encryption or decryption.
Set the buffer size for I/O.
Disable standard block padding.
Verbose print; display some statistics about I/O and buffer sizes.
Debug the BIOs used for I/O.
Compress or decompress encrypted data using zlib after encryption or before decryption. This option exists only if OpenSSL was compiled with the zlib or zlib-dynamic option.
Use NULL cipher (no encryption or decryption of input).
See "Random State Options" in openssl(1) for details.
See "Provider Options" in openssl(1), provider(7), and property(7).
See "Engine Options" in openssl(1). This option is deprecated.

The program can be called either as "openssl cipher" or "openssl enc -cipher". The first form doesn't work with engine-provided ciphers, because this form is processed before the configuration file is read and any ENGINEs loaded. Use the openssl-list(1) command to get a list of supported ciphers.

Engines which provide entirely new encryption algorithms (such as the ccgost engine which provides gost89 algorithm) should be configured in the configuration file. Engines specified on the command line using -engine option can only be used for hardware-assisted implementations of ciphers which are supported by the OpenSSL core or another engine specified in the configuration file.

When the enc command lists supported ciphers, ciphers provided by engines, specified in the configuration files are listed too.

A password will be prompted for to derive the key and IV if necessary.

The -salt option should ALWAYS be used if the key is being derived from a password unless you want compatibility with previous versions of OpenSSL.

Without the -salt option it is possible to perform efficient dictionary attacks on the password and to attack stream cipher encrypted data. The reason for this is that without the salt the same password always generates the same encryption key.

When the salt is generated at random (that means when encrypting using a passphrase without explicit salt given using -S option), the first bytes of the encrypted data are reserved to store the salt for later decrypting.

Some of the ciphers do not have large keys and others have security implications if not used correctly. A beginner is advised to just use a strong block cipher, such as AES, in CBC mode.

All the block ciphers normally use PKCS#5 padding, also known as standard block padding. This allows a rudimentary integrity or password check to be performed. However, since the chance of random data passing the test is better than 1 in 256 it isn't a very good test.

If padding is disabled then the input data must be a multiple of the cipher block length.

All RC2 ciphers have the same key and effective key length.

Blowfish and RC5 algorithms use a 128 bit key.

Please note that OpenSSL 3.0 changed the effect of the -S option. Any explicit salt value specified via this option is no longer prepended to the ciphertext when encrypting, and must again be explicitly provided when decrypting. Conversely, when the -S option is used during decryption, the ciphertext is expected to not have a prepended salt value.

When using OpenSSL 3.0 or later to decrypt data that was encrypted with an explicit salt under OpenSSL 1.1.1 do not use the -S option, the salt will then be read from the ciphertext. To generate ciphertext that can be decrypted with OpenSSL 1.1.1 do not use the -S option, the salt will be then be generated randomly and prepended to the output.

Note that some of these ciphers can be disabled at compile time and some are available only if an appropriate engine is configured in the configuration file. The output when invoking this command with the -list option (that is "openssl enc -list") is a list of ciphers, supported by your version of OpenSSL, including ones provided by configured engines.

This command does not support authenticated encryption modes like CCM and GCM, and will not support such modes in the future. This is due to having to begin streaming output (e.g., to standard output when -out is not used) before the authentication tag could be validated. When this command is used in a pipeline, the receiving end will not be able to roll back upon authentication failure. The AEAD modes currently in common use also suffer from catastrophic failure of confidentiality and/or integrity upon reuse of key/iv/nonce, and since openssl enc places the entire burden of key/iv/nonce management upon the user, the risk of exposing AEAD modes is too great to allow. These key/iv/nonce management issues also affect other modes currently exposed in this command, but the failure modes are less extreme in these cases, and the functionality cannot be removed with a stable release branch. For bulk encryption of data, whether using authenticated encryption modes or other modes, openssl-cms(1) is recommended, as it provides a standard data format and performs the needed key/iv/nonce management.

When enc is used with key wrapping modes the input data cannot be streamed, meaning it must be processed in a single pass. Consequently, the input data size must be less than the buffer size (-bufsize arg, default to 8*1024 bytes). The '*-wrap' ciphers require the input to be a multiple of 8 bytes long, because no padding is involved. The '*-wrap-pad' ciphers allow any input length. In both cases, no IV is needed. See example below.

base64             Base 64
bf-cbc             Blowfish in CBC mode
bf                 Alias for bf-cbc
blowfish           Alias for bf-cbc
bf-cfb             Blowfish in CFB mode
bf-ecb             Blowfish in ECB mode
bf-ofb             Blowfish in OFB mode
cast-cbc           CAST in CBC mode
cast               Alias for cast-cbc
cast5-cbc          CAST5 in CBC mode
cast5-cfb          CAST5 in CFB mode
cast5-ecb          CAST5 in ECB mode
cast5-ofb          CAST5 in OFB mode
chacha20           ChaCha20 algorithm
des-cbc            DES in CBC mode
des                Alias for des-cbc
des-cfb            DES in CFB mode
des-ofb            DES in OFB mode
des-ecb            DES in ECB mode
des-ede-cbc        Two key triple DES EDE in CBC mode
des-ede            Two key triple DES EDE in ECB mode
des-ede-cfb        Two key triple DES EDE in CFB mode
des-ede-ofb        Two key triple DES EDE in OFB mode
des-ede3-cbc       Three key triple DES EDE in CBC mode
des-ede3           Three key triple DES EDE in ECB mode
des3               Alias for des-ede3-cbc
des-ede3-cfb       Three key triple DES EDE CFB mode
des-ede3-ofb       Three key triple DES EDE in OFB mode
desx               DESX algorithm.
gost89             GOST 28147-89 in CFB mode (provided by ccgost engine)
gost89-cnt         GOST 28147-89 in CNT mode (provided by ccgost engine)
idea-cbc           IDEA algorithm in CBC mode
idea               same as idea-cbc
idea-cfb           IDEA in CFB mode
idea-ecb           IDEA in ECB mode
idea-ofb           IDEA in OFB mode
rc2-cbc            128 bit RC2 in CBC mode
rc2                Alias for rc2-cbc
rc2-cfb            128 bit RC2 in CFB mode
rc2-ecb            128 bit RC2 in ECB mode
rc2-ofb            128 bit RC2 in OFB mode
rc2-64-cbc         64 bit RC2 in CBC mode
rc2-40-cbc         40 bit RC2 in CBC mode
rc4                128 bit RC4
rc4-64             64 bit RC4
rc4-40             40 bit RC4
rc5-cbc            RC5 cipher in CBC mode
rc5                Alias for rc5-cbc
rc5-cfb            RC5 cipher in CFB mode
rc5-ecb            RC5 cipher in ECB mode
rc5-ofb            RC5 cipher in OFB mode
seed-cbc           SEED cipher in CBC mode
seed               Alias for seed-cbc
seed-cfb           SEED cipher in CFB mode
seed-ecb           SEED cipher in ECB mode
seed-ofb           SEED cipher in OFB mode
sm4-cbc            SM4 cipher in CBC mode
sm4                Alias for sm4-cbc
sm4-cfb            SM4 cipher in CFB mode
sm4-ctr            SM4 cipher in CTR mode
sm4-ecb            SM4 cipher in ECB mode
sm4-ofb            SM4 cipher in OFB mode
aes-[128|192|256]-cbc  128/192/256 bit AES in CBC mode
aes[128|192|256]       Alias for aes-[128|192|256]-cbc
aes-[128|192|256]-cfb  128/192/256 bit AES in 128 bit CFB mode
aes-[128|192|256]-cfb1 128/192/256 bit AES in 1 bit CFB mode
aes-[128|192|256]-cfb8 128/192/256 bit AES in 8 bit CFB mode
aes-[128|192|256]-ctr  128/192/256 bit AES in CTR mode
aes-[128|192|256]-ecb  128/192/256 bit AES in ECB mode
aes-[128|192|256]-ofb  128/192/256 bit AES in OFB mode
aes-[128|192|256]-wrap     key wrapping using 128/192/256 bit AES
aes-[128|192|256]-wrap-pad key wrapping with padding using 128/192/256 bit AES
aria-[128|192|256]-cbc  128/192/256 bit ARIA in CBC mode
aria[128|192|256]       Alias for aria-[128|192|256]-cbc
aria-[128|192|256]-cfb  128/192/256 bit ARIA in 128 bit CFB mode
aria-[128|192|256]-cfb1 128/192/256 bit ARIA in 1 bit CFB mode
aria-[128|192|256]-cfb8 128/192/256 bit ARIA in 8 bit CFB mode
aria-[128|192|256]-ctr  128/192/256 bit ARIA in CTR mode
aria-[128|192|256]-ecb  128/192/256 bit ARIA in ECB mode
aria-[128|192|256]-ofb  128/192/256 bit ARIA in OFB mode
camellia-[128|192|256]-cbc  128/192/256 bit Camellia in CBC mode
camellia[128|192|256]       Alias for camellia-[128|192|256]-cbc
camellia-[128|192|256]-cfb  128/192/256 bit Camellia in 128 bit CFB mode
camellia-[128|192|256]-cfb1 128/192/256 bit Camellia in 1 bit CFB mode
camellia-[128|192|256]-cfb8 128/192/256 bit Camellia in 8 bit CFB mode
camellia-[128|192|256]-ctr  128/192/256 bit Camellia in CTR mode
camellia-[128|192|256]-ecb  128/192/256 bit Camellia in ECB mode
camellia-[128|192|256]-ofb  128/192/256 bit Camellia in OFB mode

Just base64 encode a binary file:

openssl base64 -in file.bin -out file.b64

Decode the same file

openssl base64 -d -in file.b64 -out file.bin

Encrypt a file using AES-128 using a prompted password and PBKDF2 key derivation:

openssl enc -aes128 -pbkdf2 -in file.txt -out file.aes128

Decrypt a file using a supplied password:

openssl enc -aes128 -pbkdf2 -d -in file.aes128 -out file.txt \
   -pass pass:<password>

Encrypt a file then base64 encode it (so it can be sent via mail for example) using AES-256 in CTR mode and PBKDF2 key derivation:

openssl enc -aes-256-ctr -pbkdf2 -a -in file.txt -out file.aes256

Base64 decode a file then decrypt it using a password supplied in a file:

openssl enc -aes-256-ctr -pbkdf2 -d -a -in file.aes256 -out file.txt \
   -pass file:<passfile>

AES key wrapping:

 openssl enc -e -a -id-aes128-wrap-pad -K 000102030405060708090A0B0C0D0E0F -in file.bin
or
 openssl aes128-wrap-pad -e -a -K 000102030405060708090A0B0C0D0E0F -in file.bin

The -A option when used with large files doesn't work properly. On the other hand, when base64 decoding without the -A option, if the first 1024 bytes of input do not include a newline character the first two lines of input are ignored.

The openssl enc command only supports a fixed number of algorithms with certain parameters. So if, for example, you want to use RC2 with a 76 bit key or RC4 with an 84 bit key you can't use this program.

The default digest was changed from MD5 to SHA256 in OpenSSL 1.1.0.

The -list option was added in OpenSSL 1.1.1e.

The -ciphers and -engine options were deprecated in OpenSSL 3.0.

The -saltlen option was added in OpenSSL 3.2.

Copyright 2000-2024 The OpenSSL Project Authors. All Rights Reserved.

Licensed under the Apache License 2.0 (the "License"). You may not use this file except in compliance with the License. You can obtain a copy in the file LICENSE in the source distribution or at https://www.openssl.org/source/license.html.

2024-10-23 3.4.0