Software Development

This is the original Bouncy Castle 1.34 specification.

Bouncy Castle Crypto Package

1.0 Introduction

The Bouncy Castle Crypto package is a Java implementation of cryptographic algorithms. The package is organised so that it contains a light-weight API suitable for use in any environment (including the newly released J2ME) with the additional infrastructure to conform the algorithms to the JCE framework.

This software is distributed under a license based on the MIT X Consortium license. To view the license, see here

If you have the full package you will have six jar files, bcprov*.jar which contains the BC provider, jce-*.jar which contains the JCE provider, clean room API, and bcmail*.jar which contains the mail API.

Note: if you are using JDK 1.0, you will just find a class hierarchy in the classes directory.

To view examples, look at the test programs in the packages:

org.bouncycastle.crypto.test
org.bouncycastle.jce.provider.test

To verify the packages, run the following Java programs with the appropriate classpath:

java org.bouncycastle.crypto.test.RegressionTest
java org.bouncycastle.jce.provider.test.RegressionTest

2.0 Patents

Some of the algorithms in the Bouncy Castle APIs are patented in some places. It is upon the user of the library to be aware of what the legal situation is in their own situation, however we have been asked to specifically mention the patent below at the request of the patent holder.

The IDEA encryption algorithm is patented in the USA, Japan, and Europe including at least Austria, France, Germany, Italy, Netherlands, Spain, Sweden, Switzerland and the United Kingdom. Non-commercial use is free, however any commercial products that make use of IDEA are liable for royalties. Please see www.mediacrypt.com for further details.

3.0 Specifications

clean room implementation of the JCE API
light-weight cryptographic API consisting of support for
- BlockCipher
- BufferedBlockCipher
- AsymmetricBlockCipher
- BufferedAsymmetricBlockCipher
- StreamCipher
- BufferedStreamCipher
- KeyAgreement
- IESCipher
- Digest
- Mac
- PBE
- Signers
JCE compatible framework for a Bouncy Castle provider

4.0 Light-weight API

This API has been specifically developed for those circumstances where the rich API and integration requirements of the JCE are not required.

However as a result, the light-weight API requires more effort and understanding on the part of a developer to initialise and utilise the algorithms.

4.1 Example

To utilise the light-weight API in a program, the fundamentals are as follows;



 /*
  * This will use a supplied key, and encrypt the data
  * This is the equivalent of DES/CBC/PKCS5Padding
  */
 BlockCipher engine = new DESEngine();
 BufferedBlockCipher cipher = new PaddedBlockCipher(new CBCCipher(engine));

 byte[] key = keyString.getBytes();
 byte[] input = inputString.getBytes();

 cipher.init(true, new KeyParameter(key));

 byte[] cipherText = new byte[cipher.getOutputSize(input.length)];
 
 int outputLen = cipher.processBytes(input, 0, input.length, cipherText, 0);
 try
 {
  cipher.doFinal(cipherText, outputLen);
 }
 catch (CryptoException ce)
 {
  System.err.println(ce);
  System.exit(1);
 }

4.2 Algorithms

The light-weight API has built in support for the following:

Symmetric (Block)

The base interface is BlockCipher and has the following implementations which match the modes the block cipher can be operated in.

Name	Constructor	Notes
BufferedBlockCipher	BlockCipher
CBCBlockCipher	BlockCipher
CFBBlockCipher	BlockCipher, block size (in bits)
OFBBlockCipher	BlockCipher, block size (in bits)
SICBlockCipher	BlockCipher, block size (in bits)	Also known as CTR mode
OpenPGPCFBBlockCipher	BlockCipher
GOFBBlockCipher	BlockCipher	GOST OFB mode

BufferedBlockCipher has a further sub-classes

Name	Constructor	Notes
PaddedBufferedBlockCipher	BlockCipher	a buffered block cipher that can use padding - default PKCS5/7 padding
CTSBlockCipher	BlockCipher	Cipher Text Stealing

The following paddings can be used with the PaddedBufferedBlockCipher.

Name	Description
PKCS7Padding	PKCS7/PKCS5 padding
ISO10126d2Padding	ISO 10126-2 padding
X932Padding	X9.23 padding
ISO7816d4Padding	ISO 7816-4 padding (ISO 9797-1 scheme 2)
ZeroBytePadding	Pad with Zeros (not recommended)

The following cipher engines are implemented that can be used with the above modes.

Name	KeySizes (in bits)	Block Size	Notes
AESEngine	0 .. 256	128 bit
AESWrapEngine	0 .. 256	128 bit	Implements FIPS AES key wrapping
BlowfishEngine	0 .. 448	64 bit
CAST5Engine	0 .. 128	64 bit
CAST6Engine	0 .. 256	128 bit
DESEngine	64	64 bit
DESedeEngine	128, 192	64 bit
DESedeWrapEngine	128, 192	64 bit	Implements Draft IETF DESede key wrapping
IDEAEngine	128	64 bit
RC2Engine	0 .. 1024	64 bit
RC532Engine	0 .. 128	64 bit	Uses a 32 bit word
RC564Engine	0 .. 128	128 bit	Uses a 64 bit word
RC6Engine	0 .. 256	128 bit
RijndaelEngine	0 .. 256	128 bit, 160 bit, 192 bit, 224 bit, 256 bit
SkipjackEngine	0 .. 128	64 bit
TwofishEngine	128, 192, 256	128 bit
SerpentEngine	128, 192, 256	128 bit
GOST28147Engine	256	64 bit	Has a range of S-boxes
CamelliaEngine	128, 192, 256	128 bit

Symmetric (Stream)

The base interface is StreamCipher and has the following implementations which match the modes the stream cipher can be operated in.

Name	Constructor	Notes
BlockStreamCipher	BlockCipher

The following cipher engines are implemented that can be used with the above modes.

Name	KeySizes (in bits)	Notes
RC4Engine	40 .. 2048

Block Asymmetric

The base interface is AsymmetricBlockCipher and has the following implementations which match the modes the cipher can be operated in.

Name	Constructor	Notes
BufferedAsymmetricBlockCipher	AsymmetricBlockCipher
OAEPEncoding	AsymmetricBlockCipher
PKCS1Encoding	AsymmetricBlockCipher
ISO9796d1Encoding	AsymmetricBlockCipher	ISO9796-1

The following cipher engines are implemented that can be used with the above modes.

Name	KeySizes (in bits)	Notes
RSAEngine	any multiple of 8 large enough for the encoding.
ElGamalEngine	any multiple of 8 large enough for the encoding.

Digest

The base interface is Digest and has the following implementations

Name	Output (in bits)	Notes
MD2Digest	128
MD4Digest	128
MD5Digest	128
RipeMD128Digest	128	basic RipeMD
RipeMD160Digest	160	enhanced version of RipeMD
RipeMD256Digest	256	expanded version of RipeMD128
RipeMD320Digest	320	expanded version of RipeMD160
SHA1Digest	160
SHA224Digest	224	FIPS 180-2
SHA256Digest	256	FIPS 180-2
SHA384Digest	384	FIPS 180-2
SHA512Digest	512	FIPS 180-2
TigerDigest	192	The Tiger Digest.
GOST3411Digest	256	The GOST-3411 Digest.
WhirlpoolDigest	512	The Whirlpool Digest.

MAC

The base interface is Mac and has the following implementations

Name	Output (in bits)	Notes
CBCBlockCipherMac	blocksize/2 unless specified
CFBBlockCipherMac	blocksize/2, in CFB 8 mode, unless specified
HMac	digest length

PBE

The base class is PBEParametersGenerator and has the following sub-classes

Name	Constructor	Notes
PKCS5S1ParametersGenerator	Digest
PKCS5S2ParametersGenerator		Uses SHA1/Hmac as defined
PKCS12ParametersGenerator	Digest
OpenSSLPBEParametersGenerator		Uses MD5 as defined

Key Agreement

Two versions of Diffie-Hellman key agreement are supported, the basic version, and one for use with long term public keys. Two versions of key agreement using Elliptic Curve cryptography are also supported, standard Diffie-Hellman key agreement and standard key agreement with co-factors.

The agreement APIs are in the org.bouncycastle.crypto.agreement package. Classes for generating Diffie-Hellman parameters can be found in the org.bouncycastle.crypto.params and org.bouncycastle.crypto.generators packages.

IESCipher

The IES cipher is based on the one described in IEEE P1363a (draft 10), for use with either traditional Diffie-Hellman or Elliptic Curve Diffie-Hellman.

Note: At the moment this is still a draft, don't use it for anything that may be subject to long term storage, the key values produced may well change as the draft is finalised.

Signers

DSA, ECDSA, ISO-9796-2, GOST-3410-94, GOST-3410-2001, and RSA-PSS are supported by the org.bouncycastle.crypto.signers package. Note: as these are light weight classes, if you need to use SHA1 or GOST-3411 (as defined in the relevant standards) you'll also need to make use of the appropriate digest class in conjunction with these. Classes for generating DSA and ECDSA parameters can be found in the org.bouncycastle.crypto.params and org.bouncycastle.crypto.generators packages.

4.3 ASN.1 package

The light-weight API has direct interfaces into a package capable of reading and writing DER-encoded ASN.1 objects and for the generation of X.509 V3 certificate objects and PKCS12 files. BER InputStream and OutputStream classes are provided as well.

5.0 Bouncy Castle Provider

The Bouncy Castle provider is a JCE compliant provider that is a wrapper built on top of the light-weight API.

The advantage for writing application code that uses the provider interface to cryptographic algorithms is that the actual provider used can be selected at run time. This is extremely valuable for applications that may wish to make use of a provider that has underlying hardware for cryptographic computation, or where an application may have been developed in an environment with cryptographic export controls.

5.1 Example

To utilise the JCE provider in a program, the fundamentals are as follows;


 /*
  * This will generate a random key, and encrypt the data
  */
 Key  key;
 KeyGenerator keyGen;
 Cipher  encrypt;

 Security.addProvider(new BouncyCastleProvider());

 try
 {
  // "BC" is the name of the BouncyCastle provider
  keyGen = KeyGenerator.getInstance("DES", "BC");
  keyGen.init(new SecureRandom());

  key = keyGen.generateKey();

  encrypt = Cipher.getInstance("DES/CBC/PKCS5Padding", "BC");
 }
 catch (Exception e)
 {
  System.err.println(e);
  System.exit(1);
 }

 encrypt.init(Cipher.ENCRYPT_MODE, key);

 bOut = new ByteArrayOutputStream();
 cOut = new CipherOutputStream(bOut, encrypt);

 cOut.write("plaintext".getBytes());
 cOut.close();

 // bOut now contains the cipher text

The provider can also be configured as part of your environment via static registration by adding an entry to the java.security properties file (found in $JAVA_HOME/jre/lib/security/java.security, where $JAVA_HOME is the location of your JDK/JRE distribution). You'll find detailed instructions in the file but basically it comes down to adding a line:


   security.provider.<n>=org.bouncycastle.jce.provider.BouncyCastleProvider

Where <n> is the preference you want the provider at (1 being the most prefered).

Where you put the jar is up to mostly up to you, although with jdk1.3 and jdk1.4 the best (and in some cases only) place to have it is in $JAVA_HOME/jre/lib/ext. Note: under Windows there will normally be a JRE and a JDK install of Java if you think you have installed it correctly and it still doesn't work chances are you have added the provider to the installation not being used.

Note: with JDK 1.4 and later you will need to have installed the unrestricted policy files to take full advantage of the provider. If you do not install the policy files you are likely to get something like the following:


       java.lang.SecurityException: Unsupported keysize or algorithm parameters
               at javax.crypto.Cipher.init(DashoA6275)

The policy files can be found at the same place you downloaded the JDK.

5.2 Algorithms

Symmetric (Block)

Modes:

ECB
CBC
OFB(n)
CFB(n)
SIC (also known as CTR)
OpenPGPCFB
CTS (equivalent to CBC/WithCTS)
GOFB

Where (n) is a multiple of 8 that gives the blocksize in bits, eg, OFB8. Note that OFB and CFB mode can be used with plain text that is not an exact multiple of the block size if NoPadding has been specified.

Padding Schemes:

No padding
PKCS5/7
ISO10126/ISO10126-2
ISO7816-4/ISO9797-1
X9.23/X923
TBC
ZeroByte
withCTS (if used with ECB mode)

When placed together this gives a specification for an algorithm as;

DES/CBC/X9.23Padding
DES/OFB8/NoPadding
IDEA/CBC/ISO10126Padding
IDEA/CBC/ISO7816-4Padding
SKIPJACK/ECB/PKCS7Padding
DES/ECB/WithCTS

Note: default key sizes are in bold.

Name	KeySizes (in bits)	Block Size	Notes
AES	0 .. 256 (192)	128 bit
AESWrap	0 .. 256 (192)	128 bit	A FIPS AES key wrapper
Blowfish	0 .. 448 (448)	64 bit
CAST5	0 .. 128(128)	64 bit
CAST6	0 .. 256(256)	128 bit
DES	64	64 bit
DESede	128, 192	64 bit
DESedeWrap	128, 192	128 bit	A Draft IETF DESede key wrapper
IDEA	128 (128)	64 bit
RC2	0 .. 1024 (128)	64 bit
RC5	0 .. 128 (128)	64 bit	Uses a 32 bit word
RC5-64	0 .. 256 (256)	128 bit	Uses a 64 bit word
RC6	0 .. 256 (128)	128 bit
Rijndael	0 .. 256 (192)	128 bit
Skipjack	0 .. 128 (128)	64 bit
Twofish	128, 192, 256 (256)	128 bit
Serpent	128, 192, 256 (256)	128 bit
GOST28147	256	64 bit
Camellia	128, 192, 256	128 bit

Symmetric (Stream)

Note: default key sizes are in bold.

Name	KeySizes (in bits)	Notes
RC4	40 .. 2048 bits (128)

Block Asymmetric

Encoding:

OAEP - Optimal Asymmetric Encryption Padding
PCKS1 - PKCS v1.5 Padding
ISO9796-1 - ISO9796-1 edition 1 Padding

Note: except as indicated in PKCS 1v2 we recommend you use OAEP, as mandated in X9.44.

When placed together with RSA this gives a specification for an algorithm as;

RSA/NONE/NoPadding
RSA/NONE/PKCS1Padding
RSA/NONE/OAEPWithMD5AndMGF1Padding
RSA/NONE/OAEPWithSHA1AndMGF1Padding
RSA/NONE/OAEPWithSHA224AndMGF1Padding
RSA/NONE/OAEPWithSHA256AndMGF1Padding
RSA/NONE/OAEPWithSHA384AndMGF1Padding
RSA/NONE/OAEPWithSHA512AndMGF1Padding
RSA/NONE/ISO9796-1Padding

Name	KeySizes (in bits)	Notes
RSA	any multiple of 8 bits large enough for the encryption(2048)
ElGamal	any multiple of 8 bits large enough for the encryption(1024)

Key Agreement

Diffie-Hellman key agreement is supported using the "DH", "ECDH", and "ECDHC" (ECDH with cofactors) key agreement instances.

Note: with basic "DH" only the basic algorithm fits in with the JCE API, if you're using long-term public keys you may want to look at the light-weight API.

ECIES

An implementation of ECIES (stream mode) as described in IEEE P 1363a.

Note: At the moment this is still a draft, don't use it for anything that may be subject to long term storage, the key values produced may well change as the draft is finalised.

Digest

Name	Output (in bits)	Notes
GOST3411	256
MD2	128
MD4	128
MD5	128
RipeMD128	128	basic RipeMD
RipeMD160	160	enhanced version of RipeMD
RipeMD256Digest	256	expanded version of RipeMD128
RipeMD320Digest	320	expanded version of RipeMD160
SHA1	160
SHA-224	224	FIPS 180-2
SHA-256	256	FIPS 180-2
SHA-384	384	FIPS 180-2
SHA-512	512	FIPS 180-2
Tiger	192
Whirlpool	512

MAC

Name	Output (in bits)	Notes
Any MAC based on a block cipher, CBC (the default) and CFB modes.	half the cipher's block size (usually 32 bits)
HMac-MD2	128
HMac-MD4	128
HMac-MD5	128
HMac-RipeMD128	128
HMac-RipeMD160	160
HMac-SHA1	160
HMac-SHA224	224
HMac-SHA256	256
HMac-SHA384	384
HMac-SHA512	512
HMac-Tiger	192

Examples:

DESMac
DESMac/CFB8
DESedeMac
DESedeMac/CFB8
DESedeMac64
SKIPJACKMac
SKIPJACKMac/CFB8
IDEAMac
IDEAMac/CFB8
RC2Mac
RC2Mac/CFB8
RC5Mac
RC5Mac/CFB8
ISO9797ALG3Mac

Signature Algorithms

Schemes:

GOST3411withGOST3410 (GOST3411withGOST3410-94)
GOST3411withECGOST3410 (GOST3411withGOST3410-2001)
MD2withRSA
MD5withRSA
SHA1withRSA
RIPEMD128withRSA
RIPEMD160withRSA
RIPEMD256withRSA
SHA1withDSA
SHA1withECDSA
SHA224withECDSA
SHA256withECDSA
SHA384withECDSA
SHA512withECDSA
SHA224withRSA
SHA256withRSA
SHA384withRSA
SHA512withRSA
SHA1withRSAandMGF1
SHA256withRSAandMGF1
SHA384withRSAandMGF1
SHA512withRSAandMGF1

PBE

Schemes:

PKCS5S1, any Digest, any symmetric Cipher, ASCII
PKCS5S2, SHA1/HMac, any symmetric Cipher, ASCII
PKCS12, any Digest, any symmetric Cipher, Unicode

Defined in Bouncy Castle JCE Provider

Name	Key Generation Scheme	Key Length (in bits)
PBEWithMD5AndDES	PKCS5 Scheme 1	64
PBEWithMD5AndRC2	PKCS5 Scheme 1	128
PBEWithSHA1AndDES	PKCS5 Scheme 1	64
PBEWithSHA1AndRC2	PKCS5 Scheme 1	128
PBEWithSHAAnd2-KeyTripleDES-CBC	PKCS12	128
PBEWithSHAAnd3-KeyTripleDES-CBC	PKCS12	192
PBEWithSHAAnd128BitRC2-CBC	PKCS12	128
PBEWithSHAAnd40BitRC2-CBC	PKCS12	40
PBEWithSHAAnd128BitRC4	PKCS12	128
PBEWithSHAAnd40BitRC4	PKCS12	40
PBEWithSHAAndTwofish-CBC	PKCS12	256
PBEWithSHAAndIDEA-CBC	PKCS12	128

5.3 Certificates

The Bouncy Castle provider will read X.509 certficates (v2 or v3) as per the examples in the java.security.cert.CertificateFactory class. They can be provided either in the normal PEM encoded format, or as DER binaries.

The CertificiateFactory will also read X.509 CRLs (v2) from either PEM or DER encodings.

In addition to the classes in the org.bouncycastle.ans1.x509 package for certificate generation a more JCE "friendly" class is provided in the package org.bouncycastle.jce. The JCE "friendly" class supports RSA, DSA, and EC-DSA.

5.4 Keystore

The Bouncy Castle package has three implementation of a keystore.

The first "BKS" is a keystore that will work with the keytool in the same fashion as the Sun "JKS" keystore. The keystore is resistent to tampering but not inspection.

The second, Keystore.BouncyCastle, or Keystore.UBER will only work with the keytool if the password is provided on the command line, as the entire keystore is encrypted with a PBE based on SHA1 and Twofish. PBEWithSHAAndTwofish-CBC. This makes the entire keystore resistant to tampering and inspection, and forces verification. The Sun JDK provided keytool will attempt to load a keystore even if no password is given, this is impossible for this version. (One might wonder about going to all this trouble and then having the password on the command line! New keytool anyone?).

In the first case, the keys are encrypted with 3-Key-TripleDES.

The third is a PKCS12 compatabile keystore. PKCS12 provides a slightly different situation from the regular key store, the keystore password is currently the only password used for storing keys. Otherwise it supports all the functionality required for it to be used with the keytool. In some situations other libraries always expect to be dealing with Sun certificates, if this is the case use PKCS12-DEF, and the certificates produced by the key store will be made using the default provider.

There is an example program that produces PKCS12 files suitable for loading into browsers. It is in the package org.bouncycastle.jce.examples.

5.5 Additional support classes for Elliptic Curve.

There are no classes for supporting EC in the JDK prior to JDK 1.5. If you are using an earlier JDK you can find classes for using EC in the following packages:

org.bouncycastle.jce.spec
org.bouncycastle.jce.interfaces
org.bouncycastle.jce

6.0 BouncyCastle S/MIME

To be able to fully compile and utilise the BouncyCastle S/MIME package (including the test classes) you need the jar files for the following APIs.

Junit - http://www.junit.org
JavaMail - http://java.sun.com/products/javamail/index.html
The Java Activation Framework - http://java.sun.com/products/javabeans/glasgow/jaf.html

6.1 Setting up BouncyCastle S/MIME in JavaMail

The BouncyCastle S/MIME handlers may be set in JavaMail two ways.

STATICALLY Add the following entries to the mailcap file:

   application/pkcs7-signature;; x-java-content-handler=org.bouncycastle.mail.smime.handlers.pkcs7_signature
   application/pkcs7-mime;; x-java-content-handler=org.bouncycastle.mail.smime.handlers.pkcs7_mime
   application/x-pkcs7-signature;; x-java-content-handler=org.bouncycastle.mail.smime.handlers.x_pkcs7_signature
   application/x-pkcs7-mime;; x-java-content-handler=org.bouncycastle.mail.smime.handlers.x_pkcs7_mime
   multipart/signed;; x-java-content-handler=org.bouncycastle.mail.smime.handlers.multipart_signed

DYNAMICALLY The following code will add the BouncyCastle S/MIME handlers dynamically:

   import javax.activation.MailcapCommandMap;
   import javax.activation.CommandMap;

   public static void setDefaultMailcap()
   {
       MailcapCommandMap _mailcap =
           (MailcapCommandMap)CommandMap.getDefaultCommandMap();

       _mailcap.addMailcap("application/pkcs7-signature;; x-java-content-handler=org.bouncycastle.mail.smime.handlers.pkcs7_signature");
       _mailcap.addMailcap("application/pkcs7-mime;; x-java-content-handler=org.bouncycastle.mail.smime.handlers.pkcs7_mime");
       _mailcap.addMailcap("application/x-pkcs7-signature;; x-java-content-handler=org.bouncycastle.mail.smime.handlers.x_pkcs7_signature");
       _mailcap.addMailcap("application/x-pkcs7-mime;; x-java-content-handler=org.bouncycastle.mail.smime.handlers.x_pkcs7_mime");
       _mailcap.addMailcap("multipart/signed;; x-java-content-handler=org.bouncycastle.mail.smime.handlers.multipart_signed");

       CommandMap.setDefaultCommandMap(_mailcap);
   }

Software Development

Sunday, January 29, 2012

Bouncy Castle Crypto Package

1.0 Introduction

2.0 Patents

3.0 Specifications

4.0 Light-weight API

4.1 Example

4.2 Algorithms

Symmetric (Block)

Symmetric (Stream)

Block Asymmetric

Digest

MAC

PBE

Key Agreement

IESCipher

Signers

4.3 ASN.1 package

5.0 Bouncy Castle Provider

5.1 Example

5.2 Algorithms

Symmetric (Block)

Symmetric (Stream)

Block Asymmetric

Key Agreement

ECIES

Digest

MAC

Signature Algorithms

PBE

5.3 Certificates

5.4 Keystore

5.5 Additional support classes for Elliptic Curve.

6.0 BouncyCastle S/MIME

6.1 Setting up BouncyCastle S/MIME in JavaMail

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