OpenSSL Hacks

Anthony J. Stieber

Issue #147, July 2006

OpenSSL contains a command-line tool to do nearly everything possible within the OpenSSL library. Even better, it's probably already installed on your system.

OpenSSL is a powerful Secure Sockets Layer cryptographic library. Apache uses it for HTTPS encryption, and OpenSSH uses it for SSH encryption. But, you don't have to use it as a library. It's also a multipurpose, cross-platform crypto tool.

Here's a little background on OpenSSL. Before OpenSSL, there was ssleay, an SSL implementation written by Eric A. Young. It was successively improved and eventually became OpenSSL, similar to how NCSA HTTPd became the Apache Web server. Today, OpenSSL supports dozens of cryptographic algorithms and protocols with hundreds of options.

OpenSSL has a lot of features. In addition to the SSL client and server features, OpenSSL also has:

  • US federal government NIST FIPS 140-2 Level 1 validation.

  • TLS, the next generation of SSL.

  • X.509 key and certificate generation.

  • X.509 certificate authority.

  • S/MIME encryption.

  • File encryption and hashing.

  • UNIX password hashes.

  • Nine different commercial cryptographic hardware devices.

  • Cryptographic performance testing.

  • Thirty-six commands.

  • Six message digest algorithms.

  • Nine cipher algorithms with four block modes (where applicable).

  • Multiple crypto protocols.

Although OpenSSL is complex, a lot of that complexity can be avoided. The remainder of this article concentrates on features that are easy to use, and in only a few lines of shell code.

This article uses the same section titles as in my earlier GnuPG article (“GnuPG Hacks”, Linux Journal, March 2006, page 52) to make it easier to compare OpenSSL and GnuPG.

Getting Started

First, let's confirm that OpenSSL is installed and in your path. Many Linux distributions, even some small distributions, include OpenSSL. Usually OpenSSL is located in /usr/bin/, like most bundled packages.

In all of the examples, the shell prompt is set to $.

First, type:

$ openssl version

Note that there are no leading dashes for the version option.

You should get something like this:

OpenSSL 0.9.7d 17 Mar 2004

The exact version number, date and other details may vary. At the time of this writing, the current version is OpenSSL 0.9.8a. The examples we're using should work for most versions of OpenSSL.

If you typed openssl with no command-line option, you'll get this:

OpenSSL>

If this happens, simply type quit or press Ctrl-C to exit safely. It's only the OpenSSL internal command-line prompt. It doesn't have command-line editing and has no explicit help function. But, it will type a list of commands if you type a command it doesn't know. It's better to avoid it for now.

Binary File Shields

Binary files typically are sent in e-mail using MIME. However, if your e-mail software doesn't support MIME, like most command-line e-mail, you're stuck with uuencode, or you can use OpenSSL's base64 encoding. Base64 is the same encoding used by the much more complicated MIME protocol, but it's not directly MIME-compatible.

To wrap a file in base64 text encoding, type:


$ openssl base64 < filename.bin > filename.txt

To unwrap a base64-encoded file, type:


$ openssl base64 -d < filename.txt > filename.bin

Note that OpenSSL doesn't care about the filename extension.

OpenSSL, unlike GnuPG or MIME, also can encode short strings, as follows:

$ echo "The Linux Journal" | openssl base64
VGhlIExpbnV4IEpvdXJuYWwK

Decoding is similar:

$ echo "VGhlIExpbnV4IEpvdXJuYWwK" | openssl base64 -d
The Linux Journal

Note the -d option, which specifies decoding.

Better Checksums

sum and cksum are the traditional UNIX checksum programs. They work fine, as long as as you don't need cross-platform compatibility or security, and you don't mind that occasionally two completely different files will have the same checksum value.

Although Linux systems often have md5sum installed, the MD5 algorithm suffers from a relatively new vulnerability and shouldn't be used anymore.

If it's installed, the more secure sha1sum should be used. Several different programs go by this name, however. Some versions can hash only one file at a time, some can't handle stdin or have some other deficiency. If you run into any of these problems or simply want consistent, known, good cross-platform software, consider OpenSSL.

The OpenSSL hash output format is a bit different from GnuPG, but numerically identical. OpenSSL format always identifies the algorithm used and also outputs a lowercase hexadecimal string with no whitespace. Some find this format easier to use.

Here are some examples:

$ openssl sha1 filename
SHA1(filename)= e83a42b9bc8431a6645099be50b6341a35d3dceb

$ openssl md5 filename
MD5(filename)= 26e9855f8ad6a5906fea121283c729c4

As in my previous “GnuPG Hacks” article, the above examples use a file that contains the string: “The Linux Journal”. Note that there is no period in the string.

If you have a problem replicating these results, here is the ASCII-annotated hexadecimal representation of the file. Note the newline at the end automatically added by vi:

T  h  e     L  i  n  u  x     J  o  u  r  n  a  l  \n
54 68 65 20 4c 69 6e 75 78 20 4a 6f 75 72 6e 61 6c 0a

OpenSSL, unlike GnuPG, doesn't have SHA-512, but OpenSSL does have MD2, MD4 and MDC2. These are older algorithms that are provided for backward compatibility. Like MD5, they shouldn't be used anymore.

Quick and Clean Encryption

Although not OpenSSL's strength, it also can encrypt files. The flexibility of OpenSSL makes it a bit more complicated than GnuPG.

OpenSSL has very few defaults, so more options have to be used. There are also many algorithms from which to choose. Some algorithms, like DES and RC4-40, are kept only for backward compatibility and shouldn't be used anymore. Strong algorithms you should use include bf, which is the Blowfish algorithm, and -aes-128-cbc, which is the US NIST Advanced Encryption Standard (AES) with 128-bit keys running in Cipher Block Chaining (CBC) mode.

Here is an example:


$ openssl enc -aes-128-cbc < filename > filename.aes-128-cbc
enter aes-128-cbc encryption password:
Verifying - enter aes-128-cbc encryption password:

As with GnuPG, OpenSSL asks for a passphrase twice, which will not echo to the screen.

Decryption is also a bit more complicated:

$ openssl enc -d -aes-128-cbc -in filename.aes-128-cbc > filename
enter aes-128-cbc decryption password:

Note the -d in this example, which specifies decryption.

OpenSSL, unlike GnuPG, does not automatically detect the file type or even what algorithm, key length and mode were used to encrypt a file. You need to keep track of that yourself. In my example, I've put that information in the filename extension. OpenSSL won't manage the files and file extensions for you, you have to specify where you want the outgoing data written.

If you don't specify the correct algorithm, OpenSSL either may spew garbage or complain about a bad magic number. Either way, without the correct options, your data won't decrypt properly. To be fair, this is simply not something OpenSSL was designed to do, but it does work.

Passphrases

Before we go much further, we should discuss the importance of passphrases. In most cryptosystems, the passphrase is the secret that keeps the other secrets. It's usually the weakest point. So, creating strong passphrases is important, but it's also difficult, unless you have the right tools. Using OpenSSL, you can create a strong passphrase quickly.

A simple guide to passphrases is that longer is usually better, and eight characters is not long enough (Table 1). The goal is to make a secret that you can remember but that someone else won't know, can't guess or won't eventually stumble upon.

Table 1. Password and passphrase strengths compared with estimated time to crack. Note: time to crack is very rough. Your crackage may vary.

TypeBytesCharactersBits/CharacterTotal BitsTime to Crack
Base64 [A-Za-z0-9+/=]68648Minutes to hours
Base64 [A-Za-z0-9+/=]912672Years
Base64 [A-Za-z0-9+/=]1216696Decades
Base64 [A-Za-z0-9+/=]15206120Uncrackable?
Diceware Passphrase 8 words12.9 per word120Uncrackable?

Generating a Passphrase

OpenSSL can create very strong random passphrases like this:

$ openssl rand 15 -base64
wGcwstkb8Er0g6w1+Dm+

If you run this example, your output will be different from the example, because the passphrase is randomly generated.

The first argument of 15 is the number of binary bytes to generate, and the second argument of -base64 specifies that those binary bytes should be encoded in base64 characters. For 15 bytes, the output always will be 20 characters, plus a newline character.

The base64 character set consists only of uppercase and lowercase letters A–Z, the numbers 1–9 and the three punctuation characters: plus, slash and equals. This is intentionally a limited character set, but more complexity in the character set is not necessarily better. Adding only one additional character makes up for the difference in security. For example, an eight-character fully printable ASCII password is about a strong as a nine-character base64 password.

Although not as quick as using OpenSSL rand, the Diceware passphrase generator produces strong and often easy-to-memorize passphrases. I highly recommend it.

Encrypted Passwords

Here's something that GnuPG can't do. OpenSSL has a built-in command for creating encrypted Linux passwords exactly like those made by /bin/passwd.

Skip this paragraph to avoid pedantic cryptography. Although commonly called encrypted, Linux passwords are actually hashed using either MD5 or the old UNIX password hash (based on the DES encryption algorithm). This allows Linux not to know your password even though it knows when you provide the correct password. When you set your password, Linux hashes your password and stores it in /etc/shadow. When you log in, Linux takes the password you provide and hashes it again, and then compares that hash to what's stored in /etc/shadow for your account. If they match, you provided the correct password and can log in. If they don't match, you don't know your password, and because only the hash was stored, the computer still doesn't know your password either.

Here's why making your own password hash is useful. Let's say you need a new password on another computer. Perhaps it's a new account or you forgot the old password and asked the system administrator to reset it for you. If you can talk to the sysadmin in person, this works well, but what if the sysadmin is somewhere else? Perhaps you've never even met your sysadmin. How do you communicate your new password? E-mail is not secure at all, and telephones are scarcely better. Postal mail takes days (and has other security problems). Fax machines, text messaging and most pagers aren't secure either.

It gets worse. Maybe you don't even trust that sysadmin. Sure, the sysadmin usually has root, but someone else knowing your password bypasses even root accountability. Maybe you want to use the same password on other computers, and you don't trust those sysadmins either.

So, do this instead:

$ openssl passwd -1
Password:
Verifying - Password:
$1$zmUy5lry$aG45DkcaJwM/GNlpBLTDy0

Enter your new password twice; it won't echo. If you have multiple accounts, run the above example multiple times. The output is the cryptographic hash of your password. The hash is randomly salted so that every time it's run, the output will be different, even if the password is the same.

In my example, the password hash is:

$1$zmUy5lry$aG45DkcaJwM/GNlpBLTDy0

Your password hash probably will be completely different, except for the initial $1$.

This password hash can now be e-mailed, faxed, text messaged or even spoken over the phone to a sysadmin to set as your password hash.

After the sysadmin receives your password hash, it can be entered into /etc/shadow manually or with chpasswd. The latter requires a temporary new file, call it newpassword, with your loginid and password hash like this:

LoginidHere:$1$ywrU2ttf$yjm9OXTIBnoKJLQK2Fw5c/

The file can contain multiple lines for other accounts too.

Then, the sysadmin runs this as root:


chpasswd --encrypted < newpassword

Now, the new password is set. It's a good idea to change your password once you log in, unless you use a really strong passphrase. This is because the password hash, once exposed, is subject to off-line brute-force attacks, unless the password is really long.

This method of resetting passwords can be quite secure. For example, using this technique, someone could take the password hash published above, create an account, then tell the person the loginid and hostname and that the password hash above was used. Only the person who originally created the password hash could know the password, even though the password hash was published in a magazine.

By the way, the password for that hash is 28 completely random base64 characters long, so it should be extremely difficult to crack. But please, don't create any accounts with that hash because the password is also published, it's:

HXzNnCTo8k44k8v7iz4ZkR/QWkM2

That password and hash were created like this:

$ openssl rand 21 -base64
HXzNnCTo8k44k8v7iz4ZkR/QWkM2
$ openssl passwd -1 HXzNnCTo8k44k8v7iz4ZkR/QWkM2

These examples use the MD5 password hashes now common on Linux systems. If you need to use the old UNIX password hash, simply leave off the -1. For example:

$ openssl passwd
Password:
Verifying - Password:
xcx7DofWC0LpQ

The password for this last password hash example is: TheLinux.

Crypto Benchmarking

The many algorithms that OpenSSL supports makes it well suited for cryptographic benchmarking. This is useful for comparing the relative performance of different cryptographic algorithms and different hardware architectures using a consistent code base. And, it has a built-in benchmarking command.

The openssl speed command, by default, runs through every single algorithm in every single supported mode and option, with several different sizes of data. The different sizes are important because of algorithm start-up overhead.

A complete speed run takes about six minutes, regardless of hardware performance, and produces 124 lines of performance data with 29 lines of summary.

However, note that cryptographic algorithm performance is extremely dependent on the specific implementation. For higher performance, OpenSSL has x86 assembly code for several algorithms. Other architectures, such as ia64, SPARC and x86-64, have much less assembly code, and most others have none. The assembly code is located in these OpenSSL source code directories: crypto/*/asm. Excerpts of the speed report for three different systems are shown in Tables 2 and 3.

Table 2. Hash and Block Cipher Performance (The numbers are in 1,000s of bytes per second using 1,024-byte blocks.)

 AMD K6-2 300MHz, Linux 2.6.12, OpenSSL 0.9.7gAMD Athlon 1.333GHz, Linux 2.4.27, OpenSSL 0.9.7dPowerMac G5 1.6GHz, Darwin Kernel Version 8.0.0, OpenSSL 0.9.7b
md526,733.93k169,207.13k76,921.71k
sha112,665.41k113,973.25k76,187.82k
blowfish cbc9,663.40k56,940.54k44,433.14k
aes-128 cbc5,134.78k31,355.90k54,987.78k

Table 3. Public Key Crypto Performance

 sign/sverify/s 
rsa 1024 bits30.8563.1AMD K6-2 300MHz, Linux 2.6.12, OpenSSL 0.9.7g
dsa 1024 bits61.650.7AMD K6-2 300MHz, Linux 2.6.12, OpenSSL 0.9.7g
rsa 1024 bits239.94,514.6AMD Athlon 1.333 GHz, Linux 2.4.27, OpenSSL 0.9.7d
dsa 1024 bits498.2410.6AMD Athlon 1.333 GHz, Linux 2.4.27, OpenSSL 0.9.7d
rsa 1024 bits148.82,739.1PowerMac G5 1.6 GHz, Darwin Kernel Version 8.0.0, OpenSSL 0.9.7b
dsa 1024 bits289.5234.6PowerMac G5 1.6 GHz, Darwin Kernel Version 8.0.0, OpenSSL 0.9.7b

Learning More

This is only a sample of what OpenSSL offers at the command line.

Some documentation is available at the OpenSSL Web site under the Documents and Related sections. There are also several mailing lists available under the Support section.

OpenSSL is written in and for C/C++, but it has been adapted to other programming languages, including Ruby. In addition, the FIPS 140-2 Level 1 validation in March 2006 makes OpenSSL a new contender in the enterprise and government cryptography markets.

Resources for this article: /article/9020.

Anthony J. Stieber is an information security professional geek who obsesses over UNIX systems, cryptology, physical security and things he can't tell you. He is currently thawing out in Minneapolis, Minnesota, USA. This is his second published article.