public interface CipherService
CipherService uses a cryptographic algorithm called a
Cipher to convert an original input source using a
key to an uninterpretable format. The resulting encrypted output is only able to be converted back to original form with a
key as well.
CipherServices can perform both encryption and decryption.
Ciphers, the
Key used to encrypt the source is the same as (or trivially similar to) the
Key used to decrypt it.
For
Asymmetric
Ciphers, the encryption
Key is not the same as the decryption
Key. The most common type of Asymmetric Ciphers are based on what is called public/private key pairs:
A
private key is known only to a single party, and as its name implies, is supposed be kept very private and secure. A
public key that is associated with the private key can be disseminated freely to anyone. Then data encrypted by the public key can only be decrypted by the private key and vice versa, but neither party need share their private key with anyone else. By not sharing a private key, you can guarantee no 3rd party can intercept the key and therefore use it to decrypt a message.
This asymmetric key technology was created as a more secure alternative to symmetric ciphers that sometimes suffer from man-in-the-middle attacks since, for data shared between two parties, the same Key must also be shared and may be compromised.
Note that a symmetric cipher is perfectly fine to use if you just want to encode data in a format no one else can understand and you never give away the key. Shiro uses a symmetric cipher when creating certain HTTP Cookies for example - because it is often undesirable to have user's identity stored in a plain-text cookie, that identity can be converted via a symmetric cipher. Since the the same exact Shiro application will receive the cookie, it can decrypt it via the same
Key and there is no potential for discovery since that Key is never shared with anyone.
CipherServices vs JDK CiphersCipherServices essentially do the same things as JDK
Ciphers, but in simpler and easier-to-use ways for most application developers. When thinking about encrypting and decrypting data in an application, most app developers want what a
CipherService provides, rather than having to manage the lower-level intricacies of the JDK's
Cipher API. Here are a few reasons why most people prefer
CipherServices:
CipherService method calls do not retain state between method invocations. JDK Cipher instances do retain state across invocations, requiring its end-users to manage the instance and its state themselves.CipherService instances are thread-safe inherently because no state is retained across method invocations. JDK Cipher instances retain state and cannot be used by multiple threads concurrently.CipherService method calls are single operation methods: encryption or decryption in their entirety are done as a single method call. This is ideal for the large majority of developer needs where you have something unencrypted and just want it decrypted (or vice versa) in a single method call. In contrast, JDK Cipher instances can support encrypting/decrypting data in chunks over time (because it retains state), but this often introduces API clutter and confusion for most application developers.CipherService implementations for different Cipher algorithms (AesCipherService, BlowfishCipherService, etc). There is only one JDK Cipher class to represent all cipher algorithms/instances. CipherService instances are type-safe, instantiating and using one is often as simple as calling the default constructor, for example, new AesCipherService();. The JDK Cipher class however requires using a procedural factory method with String arguments to indicate how the instance should be created. The String arguments themselves are somewhat cryptic and hard to understand unless you're a security expert. Shiro hides these details from you, but allows you to configure them if you want.BlowfishCipherService,
AesCipherService
| Modifier and Type | Method and Description |
|---|---|
ByteSource |
decrypt(byte[] encrypted, byte[] decryptionKey)
Decrypts encrypted data via the specified cipher key and returns the original (pre-encrypted) data.
|
void |
decrypt(InputStream
Receives encrypted data from the given
InputStream, decrypts it, and sends the resulting decrypted data to the given
OutputStream.
|
ByteSource |
encrypt(byte[] raw, byte[] encryptionKey)
Encrypts data via the specified cipher key.
|
void |
encrypt(InputStream
Receives the data from the given
InputStream, encrypts it, and sends the resulting encrypted data to the given
OutputStream.
|
ByteSourcedecrypt(byte[] encrypted, byte[] decryptionKey) throws CryptoException
encrypted - the previously encrypted data to decrypt
decryptionKey - the cipher key used during decryption.
CryptoException - if there is an error during decryption
void decrypt(InputStreamin, OutputStream out, byte[] decryptionKey) throws CryptoException
InputStream, decrypts it, and sends the resulting decrypted data to the given
OutputStream.
NOTE: This method
does NOT flush or close either stream prior to returning - the caller must do so when they are finished with the streams. For example:
try {
InputStream in = ...
OutputStream out = ...
cipherService.decrypt(in, out, decryptionKey);
} finally {
if (in != null) {
try {
in.close();
} catch (IOException ioe1) { ... log, trigger event, etc }
}
if (out != null) {
try {
out.close();
} catch (IOException ioe2) { ... log, trigger event, etc }
}
}
in - the stream supplying the data to decrypt
out - the stream to send the decrypted data
decryptionKey - the cipher key to use for decryption
CryptoException - if there is any problem during decryption.
ByteSourceencrypt(byte[] raw, byte[] encryptionKey) throws CryptoException
CipherService implementation.
raw - the data to encrypt
encryptionKey - the cipher key used during encryption.
CryptoException - if there is an error during encryption
void encrypt(InputStreamin, OutputStream out, byte[] encryptionKey) throws CryptoException
InputStream, encrypts it, and sends the resulting encrypted data to the given
OutputStream.
NOTE: This method
does NOT flush or close either stream prior to returning - the caller must do so when they are finished with the streams. For example:
try {
InputStream in = ...
OutputStream out = ...
cipherService.encrypt(in, out, encryptionKey);
} finally {
if (in != null) {
try {
in.close();
} catch (IOException ioe1) { ... log, trigger event, etc }
}
if (out != null) {
try {
out.close();
} catch (IOException ioe2) { ... log, trigger event, etc }
}
}
in - the stream supplying the data to encrypt
out - the stream to send the encrypted data
encryptionKey - the cipher key to use for encryption
CryptoException - if there is any problem during encryption.