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package com.sun.crypto.provider;
import java.security.*;
import java.security.spec.*;
import javax.crypto.*;
import javax.crypto.spec.*;
import javax.crypto.BadPaddingException;
import java.nio.ByteBuffer;
/**
* This class implements the AES algorithm in its various modes
* (<code>ECB</code>, <code>CFB</code>, <code>OFB</code>, <code>CBC</code>,
* <code>PCBC</code>) and padding schemes (<code>PKCS5Padding</code>,
* <code>NoPadding</code>, <code>ISO10126Padding</code>).
*
* @author Valerie Peng
*
*
* @see AESCrypt
* @see CipherBlockChaining
* @see ElectronicCodeBook
* @see CipherFeedback
* @see OutputFeedback
*/
abstract class AESCipher extends CipherSpi {
public static final class General extends AESCipher {
public General() {
super(-1);
}
}
abstract static class OidImpl extends AESCipher {
protected OidImpl(int keySize, String mode, String padding) {
super(keySize);
try {
engineSetMode(mode);
engineSetPadding(padding);
} catch (GeneralSecurityException gse) {
// internal error; re-throw as provider exception
ProviderException pe =new ProviderException("Internal Error");
pe.initCause(gse);
throw pe;
}
}
}
public static final class AES128_ECB_NoPadding extends OidImpl {
public AES128_ECB_NoPadding() {
super(16, "ECB", "NOPADDING");
}
}
public static final class AES192_ECB_NoPadding extends OidImpl {
public AES192_ECB_NoPadding() {
super(24, "ECB", "NOPADDING");
}
}
public static final class AES256_ECB_NoPadding extends OidImpl {
public AES256_ECB_NoPadding() {
super(32, "ECB", "NOPADDING");
}
}
public static final class AES128_CBC_NoPadding extends OidImpl {
public AES128_CBC_NoPadding() {
super(16, "CBC", "NOPADDING");
}
}
public static final class AES192_CBC_NoPadding extends OidImpl {
public AES192_CBC_NoPadding() {
super(24, "CBC", "NOPADDING");
}
}
public static final class AES256_CBC_NoPadding extends OidImpl {
public AES256_CBC_NoPadding() {
super(32, "CBC", "NOPADDING");
}
}
public static final class AES128_OFB_NoPadding extends OidImpl {
public AES128_OFB_NoPadding() {
super(16, "OFB", "NOPADDING");
}
}
public static final class AES192_OFB_NoPadding extends OidImpl {
public AES192_OFB_NoPadding() {
super(24, "OFB", "NOPADDING");
}
}
public static final class AES256_OFB_NoPadding extends OidImpl {
public AES256_OFB_NoPadding() {
super(32, "OFB", "NOPADDING");
}
}
public static final class AES128_CFB_NoPadding extends OidImpl {
public AES128_CFB_NoPadding() {
super(16, "CFB", "NOPADDING");
}
}
public static final class AES192_CFB_NoPadding extends OidImpl {
public AES192_CFB_NoPadding() {
super(24, "CFB", "NOPADDING");
}
}
public static final class AES256_CFB_NoPadding extends OidImpl {
public AES256_CFB_NoPadding() {
super(32, "CFB", "NOPADDING");
}
}
public static final class AES128_GCM_NoPadding extends OidImpl {
public AES128_GCM_NoPadding() {
super(16, "GCM", "NOPADDING");
}
}
public static final class AES192_GCM_NoPadding extends OidImpl {
public AES192_GCM_NoPadding() {
super(24, "GCM", "NOPADDING");
}
}
public static final class AES256_GCM_NoPadding extends OidImpl {
public AES256_GCM_NoPadding() {
super(32, "GCM", "NOPADDING");
}
}
// utility method used by AESCipher and AESWrapCipher
static final void checkKeySize(Key key, int fixedKeySize)
throws InvalidKeyException {
if (fixedKeySize != -1) {
if (key == null) {
throw new InvalidKeyException("The key must not be null");
}
byte[] value = key.getEncoded();
if (value == null) {
throw new InvalidKeyException("Key encoding must not be null");
} else if (value.length != fixedKeySize) {
throw new InvalidKeyException("The key must be " +
fixedKeySize*8 + " bits");
}
}
}
/*
* internal CipherCore object which does the real work.
*/
private CipherCore core = null;
/*
* needed to support AES oids which associates a fixed key size
* to the cipher object.
*/
private final int fixedKeySize; // in bytes, -1 if no restriction
/**
* Creates an instance of AES cipher with default ECB mode and
* PKCS5Padding.
*/
protected AESCipher(int keySize) {
core = new CipherCore(new AESCrypt(), AESConstants.AES_BLOCK_SIZE);
fixedKeySize = keySize;
}
/**
* Sets the mode of this cipher.
*
* @param mode the cipher mode
*
* @exception NoSuchAlgorithmException if the requested cipher mode does
* not exist
*/
protected void engineSetMode(String mode)
throws NoSuchAlgorithmException {
core.setMode(mode);
}
/**
* Sets the padding mechanism of this cipher.
*
* @param padding the padding mechanism
*
* @exception NoSuchPaddingException if the requested padding mechanism
* does not exist
*/
protected void engineSetPadding(String paddingScheme)
throws NoSuchPaddingException {
core.setPadding(paddingScheme);
}
/**
* Returns the block size (in bytes).
*
* @return the block size (in bytes), or 0 if the underlying algorithm is
* not a block cipher
*/
protected int engineGetBlockSize() {
return AESConstants.AES_BLOCK_SIZE;
}
/**
* Returns the length in bytes that an output buffer would need to be in
* order to hold the result of the next <code>update</code> or
* <code>doFinal</code> operation, given the input length
* <code>inputLen</code> (in bytes).
*
* <p>This call takes into account any unprocessed (buffered) data from a
* previous <code>update</code> call, and padding.
*
* <p>The actual output length of the next <code>update</code> or
* <code>doFinal</code> call may be smaller than the length returned by
* this method.
*
* @param inputLen the input length (in bytes)
*
* @return the required output buffer size (in bytes)
*/
protected int engineGetOutputSize(int inputLen) {
return core.getOutputSize(inputLen);
}
/**
* Returns the initialization vector (IV) in a new buffer.
*
* <p>This is useful in the case where a random IV has been created
* (see <a href = "#init">init</a>),
* or in the context of password-based encryption or
* decryption, where the IV is derived from a user-provided password.
*
* @return the initialization vector in a new buffer, or null if the
* underlying algorithm does not use an IV, or if the IV has not yet
* been set.
*/
protected byte[] engineGetIV() {
return core.getIV();
}
/**
* Returns the parameters used with this cipher.
*
* <p>The returned parameters may be the same that were used to initialize
* this cipher, or may contain the default set of parameters or a set of
* randomly generated parameters used by the underlying cipher
* implementation (provided that the underlying cipher implementation
* uses a default set of parameters or creates new parameters if it needs
* parameters but was not initialized with any).
*
* @return the parameters used with this cipher, or null if this cipher
* does not use any parameters.
*/
protected AlgorithmParameters engineGetParameters() {
return core.getParameters("AES");
}
/**
* Initializes this cipher with a key and a source of randomness.
*
* <p>The cipher is initialized for one of the following four operations:
* encryption, decryption, key wrapping or key unwrapping, depending on
* the value of <code>opmode</code>.
*
* <p>If this cipher requires an initialization vector (IV), it will get
* it from <code>random</code>.
* This behaviour should only be used in encryption or key wrapping
* mode, however.
* When initializing a cipher that requires an IV for decryption or
* key unwrapping, the IV
* (same IV that was used for encryption or key wrapping) must be provided
* explicitly as a
* parameter, in order to get the correct result.
*
* <p>This method also cleans existing buffer and other related state
* information.
*
* @param opmode the operation mode of this cipher (this is one of
* the following:
* <code>ENCRYPT_MODE</code>, <code>DECRYPT_MODE</code>,
* <code>WRAP_MODE</code> or <code>UNWRAP_MODE</code>)
* @param key the secret key
* @param random the source of randomness
*
* @exception InvalidKeyException if the given key is inappropriate for
* initializing this cipher
*/
protected void engineInit(int opmode, Key key, SecureRandom random)
throws InvalidKeyException {
checkKeySize(key, fixedKeySize);
core.init(opmode, key, random);
}
/**
* Initializes this cipher with a key, a set of
* algorithm parameters, and a source of randomness.
*
* <p>The cipher is initialized for one of the following four operations:
* encryption, decryption, key wrapping or key unwrapping, depending on
* the value of <code>opmode</code>.
*
* <p>If this cipher (including its underlying feedback or padding scheme)
* requires any random bytes, it will get them from <code>random</code>.
*
* @param opmode the operation mode of this cipher (this is one of
* the following:
* <code>ENCRYPT_MODE</code>, <code>DECRYPT_MODE</code>,
* <code>WRAP_MODE</code> or <code>UNWRAP_MODE</code>)
* @param key the encryption key
* @param params the algorithm parameters
* @param random the source of randomness
*
* @exception InvalidKeyException if the given key is inappropriate for
* initializing this cipher
* @exception InvalidAlgorithmParameterException if the given algorithm
* parameters are inappropriate for this cipher
*/
protected void engineInit(int opmode, Key key,
AlgorithmParameterSpec params,
SecureRandom random)
throws InvalidKeyException, InvalidAlgorithmParameterException {
checkKeySize(key, fixedKeySize);
core.init(opmode, key, params, random);
}
protected void engineInit(int opmode, Key key,
AlgorithmParameters params,
SecureRandom random)
throws InvalidKeyException, InvalidAlgorithmParameterException {
checkKeySize(key, fixedKeySize);
core.init(opmode, key, params, random);
}
/**
* Continues a multiple-part encryption or decryption operation
* (depending on how this cipher was initialized), processing another data
* part.
*
* <p>The first <code>inputLen</code> bytes in the <code>input</code>
* buffer, starting at <code>inputOffset</code>, are processed, and the
* result is stored in a new buffer.
*
* @param input the input buffer
* @param inputOffset the offset in <code>input</code> where the input
* starts
* @param inputLen the input length
*
* @return the new buffer with the result
*
* @exception IllegalStateException if this cipher is in a wrong state
* (e.g., has not been initialized)
*/
protected byte[] engineUpdate(byte[] input, int inputOffset,
int inputLen) {
return core.update(input, inputOffset, inputLen);
}
/**
* Continues a multiple-part encryption or decryption operation
* (depending on how this cipher was initialized), processing another data
* part.
*
* <p>The first <code>inputLen</code> bytes in the <code>input</code>
* buffer, starting at <code>inputOffset</code>, are processed, and the
* result is stored in the <code>output</code> buffer, starting at
* <code>outputOffset</code>.
*
* @param input the input buffer
* @param inputOffset the offset in <code>input</code> where the input
* starts
* @param inputLen the input length
* @param output the buffer for the result
* @param outputOffset the offset in <code>output</code> where the result
* is stored
*
* @return the number of bytes stored in <code>output</code>
*
* @exception ShortBufferException if the given output buffer is too small
* to hold the result
*/
protected int engineUpdate(byte[] input, int inputOffset, int inputLen,
byte[] output, int outputOffset)
throws ShortBufferException {
return core.update(input, inputOffset, inputLen, output,
outputOffset);
}
/**
* Encrypts or decrypts data in a single-part operation,
* or finishes a multiple-part operation.
* The data is encrypted or decrypted, depending on how this cipher was
* initialized.
*
* <p>The first <code>inputLen</code> bytes in the <code>input</code>
* buffer, starting at <code>inputOffset</code>, and any input bytes that
* may have been buffered during a previous <code>update</code> operation,
* are processed, with padding (if requested) being applied.
* The result is stored in a new buffer.
*
* <p>The cipher is reset to its initial state (uninitialized) after this
* call.
*
* @param input the input buffer
* @param inputOffset the offset in <code>input</code> where the input
* starts
* @param inputLen the input length
*
* @return the new buffer with the result
*
* @exception IllegalBlockSizeException if this cipher is a block cipher,
* no padding has been requested (only in encryption mode), and the total
* input length of the data processed by this cipher is not a multiple of
* block size
* @exception BadPaddingException if this cipher is in decryption mode,
* and (un)padding has been requested, but the decrypted data is not
* bounded by the appropriate padding bytes
*/
protected byte[] engineDoFinal(byte[] input, int inputOffset, int inputLen)
throws IllegalBlockSizeException, BadPaddingException {
return core.doFinal(input, inputOffset, inputLen);
}
/**
* Encrypts or decrypts data in a single-part operation,
* or finishes a multiple-part operation.
* The data is encrypted or decrypted, depending on how this cipher was
* initialized.
*
* <p>The first <code>inputLen</code> bytes in the <code>input</code>
* buffer, starting at <code>inputOffset</code>, and any input bytes that
* may have been buffered during a previous <code>update</code> operation,
* are processed, with padding (if requested) being applied.
* The result is stored in the <code>output</code> buffer, starting at
* <code>outputOffset</code>.
*
* <p>The cipher is reset to its initial state (uninitialized) after this
* call.
*
* @param input the input buffer
* @param inputOffset the offset in <code>input</code> where the input
* starts
* @param inputLen the input length
* @param output the buffer for the result
* @param outputOffset the offset in <code>output</code> where the result
* is stored
*
* @return the number of bytes stored in <code>output</code>
*
* @exception IllegalBlockSizeException if this cipher is a block cipher,
* no padding has been requested (only in encryption mode), and the total
* input length of the data processed by this cipher is not a multiple of
* block size
* @exception ShortBufferException if the given output buffer is too small
* to hold the result
* @exception BadPaddingException if this cipher is in decryption mode,
* and (un)padding has been requested, but the decrypted data is not
* bounded by the appropriate padding bytes
*/
protected int engineDoFinal(byte[] input, int inputOffset, int inputLen,
byte[] output, int outputOffset)
throws IllegalBlockSizeException, ShortBufferException,
BadPaddingException {
return core.doFinal(input, inputOffset, inputLen, output,
outputOffset);
}
/**
* Returns the key size of the given key object.
*
* @param key the key object.
*
* @return the key size of the given key object.
*
* @exception InvalidKeyException if <code>key</code> is invalid.
*/
protected int engineGetKeySize(Key key) throws InvalidKeyException {
byte[] encoded = key.getEncoded();
if (!AESCrypt.isKeySizeValid(encoded.length)) {
throw new InvalidKeyException("Invalid AES key length: " +
encoded.length + " bytes");
}
return encoded.length * 8;
}
/**
* Wrap a key.
*
* @param key the key to be wrapped.
*
* @return the wrapped key.
*
* @exception IllegalBlockSizeException if this cipher is a block
* cipher, no padding has been requested, and the length of the
* encoding of the key to be wrapped is not a
* multiple of the block size.
*
* @exception InvalidKeyException if it is impossible or unsafe to
* wrap the key with this cipher (e.g., a hardware protected key is
* being passed to a software only cipher).
*/
protected byte[] engineWrap(Key key)
throws IllegalBlockSizeException, InvalidKeyException {
return core.wrap(key);
}
/**
* Unwrap a previously wrapped key.
*
* @param wrappedKey the key to be unwrapped.
*
* @param wrappedKeyAlgorithm the algorithm the wrapped key is for.
*
* @param wrappedKeyType the type of the wrapped key.
* This is one of <code>Cipher.SECRET_KEY</code>,
* <code>Cipher.PRIVATE_KEY</code>, or <code>Cipher.PUBLIC_KEY</code>.
*
* @return the unwrapped key.
*
* @exception NoSuchAlgorithmException if no installed providers
* can create keys of type <code>wrappedKeyType</code> for the
* <code>wrappedKeyAlgorithm</code>.
*
* @exception InvalidKeyException if <code>wrappedKey</code> does not
* represent a wrapped key of type <code>wrappedKeyType</code> for
* the <code>wrappedKeyAlgorithm</code>.
*/
protected Key engineUnwrap(byte[] wrappedKey,
String wrappedKeyAlgorithm,
int wrappedKeyType)
throws InvalidKeyException, NoSuchAlgorithmException {
return core.unwrap(wrappedKey, wrappedKeyAlgorithm,
wrappedKeyType);
}
/**
* Continues a multi-part update of the Additional Authentication
* Data (AAD), using a subset of the provided buffer.
* <p>
* Calls to this method provide AAD to the cipher when operating in
* modes such as AEAD (GCM/CCM). If this cipher is operating in
* either GCM or CCM mode, all AAD must be supplied before beginning
* operations on the ciphertext (via the {@code update} and {@code
* doFinal} methods).
*
* @param src the buffer containing the AAD
* @param offset the offset in {@code src} where the AAD input starts
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