OpenSSL
provides SSL
, TLS and general purpose cryptography. It wraps the OpenSSL library.
Examples
All examples assume you have loaded OpenSSL
with:
require 'openssl'
These examples build atop each other. For example the key created in the next is used in throughout these examples.
Keys
Creating a Key
This example creates a 2048 bit RSA keypair and writes it to the current directory.
key = OpenSSL::PKey::RSA.new 2048 open 'private_key.pem', 'w' do |io| io.write key.to_pem end open 'public_key.pem', 'w' do |io| io.write key.public_key.to_pem end
Exporting a Key
Keys saved to disk without encryption are not secure as anyone who gets ahold of the key may use it unless it is encrypted. In order to securely export a key you may export it with a pass phrase.
cipher = OpenSSL::Cipher.new 'aes-256-cbc' pass_phrase = 'my secure pass phrase goes here' key_secure = key.export cipher, pass_phrase open 'private.secure.pem', 'w' do |io| io.write key_secure end
OpenSSL::Cipher.ciphers
returns a list of available ciphers.
Loading a Key
A key can also be loaded from a file.
key2 = OpenSSL::PKey.read File.read 'private_key.pem' key2.public? # => true key2.private? # => true
or
key3 = OpenSSL::PKey.read File.read 'public_key.pem' key3.public? # => true key3.private? # => false
Loading an Encrypted Key
OpenSSL
will prompt you for your pass phrase when loading an encrypted key. If you will not be able to type in the pass phrase you may provide it when loading the key:
key4_pem = File.read 'private.secure.pem' pass_phrase = 'my secure pass phrase goes here' key4 = OpenSSL::PKey.read key4_pem, pass_phrase
RSA Encryption
RSA provides encryption and decryption using the public and private keys. You can use a variety of padding methods depending upon the intended use of encrypted data.
Encryption & Decryption
Asymmetric public/private key encryption is slow and victim to attack in cases where it is used without padding or directly to encrypt larger chunks of data. Typical use cases for RSA encryption involve “wrapping” a symmetric key with the public key of the recipient who would “unwrap” that symmetric key again using their private key. The following illustrates a simplified example of such a key transport scheme. It shouldn’t be used in practice, though, standardized protocols should always be preferred.
wrapped_key = key.public_encrypt key
A symmetric key encrypted with the public key can only be decrypted with the corresponding private key of the recipient.
original_key = key.private_decrypt wrapped_key
By default PKCS#1 padding will be used, but it is also possible to use other forms of padding, see PKey::RSA
for further details.
Signatures
Using “private_encrypt” to encrypt some data with the private key is equivalent to applying a digital signature to the data. A verifying party may validate the signature by comparing the result of decrypting the signature with “public_decrypt” to the original data. However, OpenSSL::PKey
already has methods “sign” and “verify” that handle digital signatures in a standardized way - “private_encrypt” and “public_decrypt” shouldn’t be used in practice.
To sign a document, a cryptographically secure hash of the document is computed first, which is then signed using the private key.
signature = key.sign 'SHA256', document
To validate the signature, again a hash of the document is computed and the signature is decrypted using the public key. The result is then compared to the hash just computed, if they are equal the signature was valid.
if key.verify 'SHA256', signature, document puts 'Valid' else puts 'Invalid' end
PBKDF2 Password-based Encryption
If supported by the underlying OpenSSL
version used, Password-based Encryption should use the features of PKCS5
. If not supported or if required by legacy applications, the older, less secure methods specified in RFC 2898 are also supported (see below).
PKCS5
supports PBKDF2 as it was specified in PKCS#5 v2.0. It still uses a password, a salt, and additionally a number of iterations that will slow the key derivation process down. The slower this is, the more work it requires being able to brute-force the resulting key.
Encryption
The strategy is to first instantiate a Cipher
for encryption, and then to generate a random IV plus a key derived from the password using PBKDF2. PKCS #5 v2.0 recommends at least 8 bytes for the salt, the number of iterations largely depends on the hardware being used.
cipher = OpenSSL::Cipher.new 'aes-256-cbc' cipher.encrypt iv = cipher.random_iv pwd = 'some hopefully not to easily guessable password' salt = OpenSSL::Random.random_bytes 16 iter = 20000 key_len = cipher.key_len digest = OpenSSL::Digest.new('SHA256') key = OpenSSL::PKCS5.pbkdf2_hmac(pwd, salt, iter, key_len, digest) cipher.key = key Now encrypt the data: encrypted = cipher.update document encrypted << cipher.final
Decryption
Use the same steps as before to derive the symmetric AES key, this time setting the Cipher
up for decryption.
cipher = OpenSSL::Cipher.new 'aes-256-cbc' cipher.decrypt cipher.iv = iv # the one generated with #random_iv pwd = 'some hopefully not to easily guessable password' salt = ... # the one generated above iter = 20000 key_len = cipher.key_len digest = OpenSSL::Digest.new('SHA256') key = OpenSSL::PKCS5.pbkdf2_hmac(pwd, salt, iter, key_len, digest) cipher.key = key Now decrypt the data: decrypted = cipher.update encrypted decrypted << cipher.final
PKCS #5 Password-based Encryption
PKCS #5 is a password-based encryption standard documented at RFC2898. It allows a short password or passphrase to be used to create a secure encryption key. If possible, PBKDF2 as described above should be used if the circumstances allow it.
PKCS #5 uses a Cipher
, a pass phrase and a salt to generate an encryption key.
pass_phrase = 'my secure pass phrase goes here' salt = '8 octets'
Encryption
First set up the cipher for encryption
encryptor = OpenSSL::Cipher.new 'aes-256-cbc' encryptor.encrypt encryptor.pkcs5_keyivgen pass_phrase, salt
Then pass the data you want to encrypt through
encrypted = encryptor.update 'top secret document' encrypted << encryptor.final
Decryption
Use a new Cipher
instance set up for decryption
decryptor = OpenSSL::Cipher.new 'aes-256-cbc' decryptor.decrypt decryptor.pkcs5_keyivgen pass_phrase, salt
Then pass the data you want to decrypt through
plain = decryptor.update encrypted plain << decryptor.final
X509
Certificates
Creating a Certificate
This example creates a self-signed certificate using an RSA key and a SHA1 signature.
key = OpenSSL::PKey::RSA.new 2048 name = OpenSSL::X509::Name.parse '/CN=nobody/DC=example' cert = OpenSSL::X509::Certificate.new cert.version = 2 cert.serial = 0 cert.not_before = Time.now cert.not_after = Time.now + 3600 cert.public_key = key.public_key cert.subject = name
Certificate Extensions
You can add extensions to the certificate with OpenSSL::SSL::ExtensionFactory to indicate the purpose of the certificate.
extension_factory = OpenSSL::X509::ExtensionFactory.new nil, cert cert.add_extension \ extension_factory.create_extension('basicConstraints', 'CA:FALSE', true) cert.add_extension \ extension_factory.create_extension( 'keyUsage', 'keyEncipherment,dataEncipherment,digitalSignature') cert.add_extension \ extension_factory.create_extension('subjectKeyIdentifier', 'hash')
The list of supported extensions (and in some cases their possible values) can be derived from the “objects.h” file in the OpenSSL
source code.
Signing a Certificate
To sign a certificate set the issuer and use OpenSSL::X509::Certificate#sign
with a digest algorithm. This creates a self-signed cert because we’re using the same name and key to sign the certificate as was used to create the certificate.
cert.issuer = name cert.sign key, OpenSSL::Digest.new('SHA1') open 'certificate.pem', 'w' do |io| io.write cert.to_pem end
Loading a Certificate
Like a key, a cert can also be loaded from a file.
cert2 = OpenSSL::X509::Certificate.new File.read 'certificate.pem'
Verifying a Certificate
Certificate#verify will return true when a certificate was signed with the given public key.
raise 'certificate can not be verified' unless cert2.verify key
Certificate Authority
A certificate authority (CA) is a trusted third party that allows you to verify the ownership of unknown certificates. The CA issues key signatures that indicate it trusts the user of that key. A user encountering the key can verify the signature by using the CA’s public key.
CA Key
CA keys are valuable, so we encrypt and save it to disk and make sure it is not readable by other users.
ca_key = OpenSSL::PKey::RSA.new 2048 pass_phrase = 'my secure pass phrase goes here' cipher = OpenSSL::Cipher.new 'aes-256-cbc' open 'ca_key.pem', 'w', 0400 do |io| io.write ca_key.export(cipher, pass_phrase) end
CA Certificate
A CA certificate is created the same way we created a certificate above, but with different extensions.
ca_name = OpenSSL::X509::Name.parse '/CN=ca/DC=example' ca_cert = OpenSSL::X509::Certificate.new ca_cert.serial = 0 ca_cert.version = 2 ca_cert.not_before = Time.now ca_cert.not_after = Time.now + 86400 ca_cert.public_key = ca_key.public_key ca_cert.subject = ca_name ca_cert.issuer = ca_name extension_factory = OpenSSL::X509::ExtensionFactory.new extension_factory.subject_certificate = ca_cert extension_factory.issuer_certificate = ca_cert ca_cert.add_extension \ extension_factory.create_extension('subjectKeyIdentifier', 'hash')
This extension indicates the CA’s key may be used as a CA.
ca_cert.add_extension \ extension_factory.create_extension('basicConstraints', 'CA:TRUE', true)
This extension indicates the CA’s key may be used to verify signatures on both certificates and certificate revocations.
ca_cert.add_extension \ extension_factory.create_extension( 'keyUsage', 'cRLSign,keyCertSign', true)
Root CA certificates are self-signed.
ca_cert.sign ca_key, OpenSSL::Digest.new('SHA1')
The CA certificate is saved to disk so it may be distributed to all the users of the keys this CA will sign.
open 'ca_cert.pem', 'w' do |io| io.write ca_cert.to_pem end
Certificate Signing Request
The CA signs keys through a Certificate Signing Request (CSR). The CSR contains the information necessary to identify the key.
csr = OpenSSL::X509::Request.new csr.version = 0 csr.subject = name csr.public_key = key.public_key csr.sign key, OpenSSL::Digest.new('SHA1')
A CSR is saved to disk and sent to the CA for signing.
open 'csr.pem', 'w' do |io| io.write csr.to_pem end
Creating a Certificate from a CSR
Upon receiving a CSR the CA will verify it before signing it. A minimal verification would be to check the CSR’s signature.
csr = OpenSSL::X509::Request.new File.read 'csr.pem' raise 'CSR can not be verified' unless csr.verify csr.public_key
After verification a certificate is created, marked for various usages, signed with the CA key and returned to the requester.
csr_cert = OpenSSL::X509::Certificate.new csr_cert.serial = 0 csr_cert.version = 2 csr_cert.not_before = Time.now csr_cert.not_after = Time.now + 600 csr_cert.subject = csr.subject csr_cert.public_key = csr.public_key csr_cert.issuer = ca_cert.subject extension_factory = OpenSSL::X509::ExtensionFactory.new extension_factory.subject_certificate = csr_cert extension_factory.issuer_certificate = ca_cert csr_cert.add_extension \ extension_factory.create_extension('basicConstraints', 'CA:FALSE') csr_cert.add_extension \ extension_factory.create_extension( 'keyUsage', 'keyEncipherment,dataEncipherment,digitalSignature') csr_cert.add_extension \ extension_factory.create_extension('subjectKeyIdentifier', 'hash') csr_cert.sign ca_key, OpenSSL::Digest.new('SHA1') open 'csr_cert.pem', 'w' do |io| io.write csr_cert.to_pem end
SSL
and TLS Connections
Using our created key and certificate we can create an SSL
or TLS connection. An SSLContext is used to set up an SSL
session.
context = OpenSSL::SSL::SSLContext.new
SSL
Server
An SSL
server requires the certificate and private key to communicate securely with its clients:
context.cert = cert context.key = key
Then create an SSLServer with a TCP server socket and the context. Use the SSLServer like an ordinary TCP server.
require 'socket' tcp_server = TCPServer.new 5000 ssl_server = OpenSSL::SSL::SSLServer.new tcp_server, context loop do ssl_connection = ssl_server.accept data = ssl_connection.gets response = "I got #{data.dump}" puts response ssl_connection.puts "I got #{data.dump}" ssl_connection.close end
SSL
client
An SSL
client is created with a TCP socket and the context. SSLSocket#connect must be called to initiate the SSL
handshake and start encryption. A key and certificate are not required for the client socket.
Note that SSLSocket#close doesn’t close the underlying socket by default. Set
SSLSocket#sync_close to true if you want.
require 'socket' tcp_socket = TCPSocket.new 'localhost', 5000 ssl_client = OpenSSL::SSL::SSLSocket.new tcp_socket, context ssl_client.sync_close = true ssl_client.connect ssl_client.puts "hello server!" puts ssl_client.gets ssl_client.close # shutdown the TLS connection and close tcp_socket
Peer Verification
An unverified SSL
connection does not provide much security. For enhanced security the client or server can verify the certificate of its peer.
The client can be modified to verify the server’s certificate against the certificate authority’s certificate:
context.ca_file = 'ca_cert.pem' context.verify_mode = OpenSSL::SSL::VERIFY_PEER require 'socket' tcp_socket = TCPSocket.new 'localhost', 5000 ssl_client = OpenSSL::SSL::SSLSocket.new tcp_socket, context ssl_client.connect ssl_client.puts "hello server!" puts ssl_client.gets
If the server certificate is invalid or context.ca_file
is not set when verifying peers an OpenSSL::SSL::SSLError
will be raised.
Boolean indicating whether OpenSSL
is FIPS-capable or not
# File tmp/rubies/ruby-3.1.3/ext/openssl/lib/openssl/digest.rb, line 67
def Digest(name)
OpenSSL::Digest.const_get(name)
end
Returns a Digest
subclass by name
require 'openssl' OpenSSL::Digest("MD5") # => OpenSSL::Digest::MD5 Digest("Foo") # => NameError: wrong constant name Foo
static VALUE
ossl_debug_get(VALUE self)
{
return dOSSL;
}
static VALUE
ossl_debug_set(VALUE self, VALUE val)
{
dOSSL = RTEST(val) ? Qtrue : Qfalse;
return val;
}
Turns on or off debug mode. With debug mode, all errors added to the OpenSSL
error queue will be printed to stderr.
VALUE
ossl_get_errors(VALUE _)
{
VALUE ary;
long e;
ary = rb_ary_new();
while ((e = ERR_get_error()) != 0){
rb_ary_push(ary, rb_str_new2(ERR_error_string(e, NULL)));
}
return ary;
}
See any remaining errors held in queue.
Any errors you see here are probably due to a bug in Ruby’s OpenSSL
implementation.
static VALUE
ossl_fips_mode_get(VALUE self)
{
#ifdef OPENSSL_FIPS
VALUE enabled;
enabled = FIPS_mode() ? Qtrue : Qfalse;
return enabled;
#else
return Qfalse;
#endif
}
static VALUE
ossl_fips_mode_set(VALUE self, VALUE enabled)
{
#ifdef OPENSSL_FIPS
if (RTEST(enabled)) {
int mode = FIPS_mode();
if(!mode && !FIPS_mode_set(1)) /* turning on twice leads to an error */
ossl_raise(eOSSLError, "Turning on FIPS mode failed");
} else {
if(!FIPS_mode_set(0)) /* turning off twice is OK */
ossl_raise(eOSSLError, "Turning off FIPS mode failed");
}
return enabled;
#else
if (RTEST(enabled))
ossl_raise(eOSSLError, "This version of OpenSSL does not support FIPS mode");
return enabled;
#endif
}
Turns FIPS mode on or off. Turning on FIPS mode will obviously only have an effect for FIPS-capable installations of the OpenSSL
library. Trying to do so otherwise will result in an error.
Examples
OpenSSL.fips_mode = true # turn FIPS mode on OpenSSL.fips_mode = false # and off again
static VALUE
ossl_crypto_fixed_length_secure_compare(VALUE dummy, VALUE str1, VALUE str2)
{
const unsigned char *p1 = (const unsigned char *)StringValuePtr(str1);
const unsigned char *p2 = (const unsigned char *)StringValuePtr(str2);
long len1 = RSTRING_LEN(str1);
long len2 = RSTRING_LEN(str2);
if (len1 != len2) {
ossl_raise(rb_eArgError, "inputs must be of equal length");
}
switch (CRYPTO_memcmp(p1, p2, len1)) {
case 0: return Qtrue;
default: return Qfalse;
}
}
Constant time memory comparison for fixed length strings, such as results of HMAC
calculations.
Returns true
if the strings are identical, false
if they are of the same length but not identical. If the length is different, ArgumentError
is raised.
static VALUE
mem_check_start(VALUE self)
{
CRYPTO_mem_ctrl(CRYPTO_MEM_CHECK_ON);
return Qnil;
}
Calls CRYPTO_mem_ctrl(CRYPTO_MEM_CHECK_ON). Starts tracking memory allocations. See also OpenSSL.print_mem_leaks
.
This is available only when built with a capable OpenSSL
and –enable-debug configure option.
static VALUE
print_mem_leaks(VALUE self)
{
#if OPENSSL_VERSION_NUMBER >= 0x10100000
int ret;
#endif
#ifndef HAVE_RB_EXT_RACTOR_SAFE
// for Ruby 2.x
void ossl_bn_ctx_free(void); // ossl_bn.c
ossl_bn_ctx_free();
#endif
#if OPENSSL_VERSION_NUMBER >= 0x10100000
ret = CRYPTO_mem_leaks_fp(stderr);
if (ret < 0)
ossl_raise(eOSSLError, "CRYPTO_mem_leaks_fp");
return ret ? Qfalse : Qtrue;
#else
CRYPTO_mem_leaks_fp(stderr);
return Qnil;
#endif
}
For debugging the Ruby/OpenSSL library. Calls CRYPTO_mem_leaks_fp(stderr). Prints detected memory leaks to standard error. This cleans the global state up thus you cannot use any methods of the library after calling this.
Returns true
if leaks detected, false
otherwise.
This is available only when built with a capable OpenSSL
and –enable-debug configure option.
Example
OpenSSL.mem_check_start NOT_GCED = OpenSSL::PKey::RSA.new(256) END { GC.start OpenSSL.print_mem_leaks # will print the leakage }
# File tmp/rubies/ruby-3.1.3/ext/openssl/lib/openssl.rb, line 32
def self.secure_compare(a, b)
hashed_a = OpenSSL::Digest.digest('SHA256', a)
hashed_b = OpenSSL::Digest.digest('SHA256', b)
OpenSSL.fixed_length_secure_compare(hashed_a, hashed_b) && a == b
end
Constant time memory comparison. Inputs are hashed using SHA-256 to mask the length of the secret. Returns true
if the strings are identical, false
otherwise.
# File tmp/rubies/ruby-3.1.3/ext/openssl/lib/openssl/digest.rb, line 67
def Digest(name)
OpenSSL::Digest.const_get(name)
end
Returns a Digest
subclass by name
require 'openssl' OpenSSL::Digest("MD5") # => OpenSSL::Digest::MD5 Digest("Foo") # => NameError: wrong constant name Foo