SQL SERVER – Introduction to SQL Server Encryption and Symmetric Key Encryption Tutorial with Script
2014-03-24 17:49
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SQL SERVER – Introduction to SQL Server Encryption and Symmetric Key Encryption Tutorial with Script
转自:http://blog.sqlauthority.com/2009/04/28/sql-server-introduction-to-sql-server-encryption-and-symmetric-key-encryption-tutorial-with-script/
SQL Server 2005 and SQL Server 2008 provide encryption as a new feature to protect data against hackers’ attacks. Hackers might be able to penetrate the database or tables, but owing to encryption they would not be able to understand
the data or make use of it. Nowadays, it has become imperative to encrypt crucial security-related data while storing in the database as well as during transmission across a network between the client and the server.
Encryption hierarchy is marked by three-level security. These three levels provide different mechanisms for securing data across networks and local servers. Different levels of hierarchies allow multiple instances of services (e.g.,
SQL Server Services) to run on one physical server.
Windows Level – Highest Level – Uses Windows DP API for encryption
SQL Server Level - Moderate Level – Uses Services Master Key for encryption
Database Level – Lower Level – Uses Database Master Key for encryption
There are two kinds of keys used in encryption:
Symmetric Key – In Symmetric cryptography system, the sender and the receiver of a message share a single, common key that is used to encrypt and decrypt the message. This is relatively easy to implement, and both the sender and the receiver
can encrypt or decrypt the messages.
Asymmetric Key – Asymmetric cryptography, also known as Public-key cryptography, is a system in which the sender and the receiver of a message have a pair of cryptographic keys – a public key and a private key – to encrypt and decrypt the
message. This is a relatively complex system where the sender can use his key to encrypt the message but he cannot decrypt it. The receiver, on the other hand, can use his key to decrypt the message but he cannot encrypt it. This intricacy has turned it into
a resource-intensive process.
Yet another way to encrypt data is through certificates. A public key certificate is a digitally signed statement that binds the value of a public key to the identity of the person, device, or service that holds the corresponding
private key. A Certification Authority (CA) issues and signs certifications.
Download complete script here.
Please create a sample database that we will be use for testing Encryption. There are two different kinds of encryptions available in SQL Server:
Database Level – This level secures all the data in a database. However, every time data is written or read from database, the whole database needs to be decrypted. This is a very resource-intensive process and not a practical solution.
Column (or Row) Level – This level of encryption is the most preferred method. Here, only columns containing important data should be encrypted; this will result in lower CPU load compared with the whole database level encryption. If a
column is used as a primary key or used in comparison clauses (WHERE clauses, JOIN conditions) the database will have to decrypt the whole column to perform operations involving those columns.
Let’s go over a simple instance that demonstrates the encryption and the decryption process executed with Symmetric Key and Triple DES encryption algorithm.
First, let’s create a sample table and then populate it with sample data. We will now encrypt one of the two columns of the table.
The preceding code will return the result depicted in the subsequent figure.
Result of the SQL query
Every database can have one master key. Database master key is a symmetric key used to protect the private keys of certificates and asymmetric keys present in the database. It uses Triple DES algorithm together with user-provided
password to encrypt the keys.
Certificates are used to safeguard encryption keys, which are used to encrypt data in the database. SQL Server 2005 has the capability to generate self-signed X.509 certificates.
The symmetric key can be encrypted by using various options such as certificate, password, symmetric key, and asymmetric key. A number of different algorithms can be employed for encrypting key. The supported algorithms are DES,
TRIPLE_DES, RC2, RC4, RC4_128, DESX, AES_128, AES_192, and AES_256.
Now add a column of type varbinary to the original table, which will store the encrypted value for the SecondCol.
Before the key is used, it needs to be decrypted using the same method that was used for encrypting it. In our example, we have used a certificate for encrypting the key. Because of the same reason, we are using the same certificate
for opening the key and making it available for use. Subsequent to opening it and making it available for use, we can use the encryptkey function and store the encrypted values in the database, in the EncryptSecondCol column.
We can drop the original SecondCol column, which we have now encrypted in the EncryptSecondCol column. If you do not want to drop the column, you can keep it for future comparison of the data when we decrypt the column.
We can run a SELECT query on our database and verify if our data in the table is well protected and hackers will not be able to make use of it even if they somehow manage to reach the data.
Result of the previous SQL query
Authorized user can use the decryptbykey function to retrieve the original data from the encrypted column. If Symmetric key is not open for decryption, it has to be decrypted using the same certificate that was used to encrypt
it. An important point to bear in mind here is that the original column and the decrypted column should have the same data types. If their data types differ, incorrect values could be reproduced. In our case, we have used a VARCHAR data type for SecondCol
and EncryptSecondCol.
If you drop the database after the entire processing is complete, you do not have to worry about cleaning up the database. However, in real world on production servers, the database is not dropped. It is a good practice for developers
to close the key after using it. If keys and certificates are used only once or their use is over, they can be dropped as well. Dropping a database will drop everything it contains – table, keys, certificates, all the data, to name a few.
Summary
Encryption is a very important security feature of SQL Server 2005. Long keys and asymmetric keys create unassailable, stronger encryption and stronger encryption uses lots of CPU to encrypt data. Stronger encryption is slower
to process. When there is a huge amount of data to encrypt, it is suggested to encrypt it using a symmetric key. The same symmetric key can be encrypted further with an asymmetric key for additional protection, thereby adding the advantage of a stronger encryption.
It is also recommended to compress data before encryption, as encrypted data cannot be compressed.
转自:http://blog.sqlauthority.com/2009/04/28/sql-server-introduction-to-sql-server-encryption-and-symmetric-key-encryption-tutorial-with-script/
SQL Server 2005 and SQL Server 2008 provide encryption as a new feature to protect data against hackers’ attacks. Hackers might be able to penetrate the database or tables, but owing to encryption they would not be able to understand
the data or make use of it. Nowadays, it has become imperative to encrypt crucial security-related data while storing in the database as well as during transmission across a network between the client and the server.
Encryption hierarchy is marked by three-level security. These three levels provide different mechanisms for securing data across networks and local servers. Different levels of hierarchies allow multiple instances of services (e.g.,
SQL Server Services) to run on one physical server.
Windows Level – Highest Level – Uses Windows DP API for encryption
SQL Server Level - Moderate Level – Uses Services Master Key for encryption
Database Level – Lower Level – Uses Database Master Key for encryption
There are two kinds of keys used in encryption:
Symmetric Key – In Symmetric cryptography system, the sender and the receiver of a message share a single, common key that is used to encrypt and decrypt the message. This is relatively easy to implement, and both the sender and the receiver
can encrypt or decrypt the messages.
Asymmetric Key – Asymmetric cryptography, also known as Public-key cryptography, is a system in which the sender and the receiver of a message have a pair of cryptographic keys – a public key and a private key – to encrypt and decrypt the
message. This is a relatively complex system where the sender can use his key to encrypt the message but he cannot decrypt it. The receiver, on the other hand, can use his key to decrypt the message but he cannot encrypt it. This intricacy has turned it into
a resource-intensive process.
Yet another way to encrypt data is through certificates. A public key certificate is a digitally signed statement that binds the value of a public key to the identity of the person, device, or service that holds the corresponding
private key. A Certification Authority (CA) issues and signs certifications.
Download complete script here.
Please create a sample database that we will be use for testing Encryption. There are two different kinds of encryptions available in SQL Server:
Database Level – This level secures all the data in a database. However, every time data is written or read from database, the whole database needs to be decrypted. This is a very resource-intensive process and not a practical solution.
Column (or Row) Level – This level of encryption is the most preferred method. Here, only columns containing important data should be encrypted; this will result in lower CPU load compared with the whole database level encryption. If a
column is used as a primary key or used in comparison clauses (WHERE clauses, JOIN conditions) the database will have to decrypt the whole column to perform operations involving those columns.
Let’s go over a simple instance that demonstrates the encryption and the decryption process executed with Symmetric Key and Triple DES encryption algorithm.
/* Create Database */ USE master GO CREATE DATABASE EncryptTest ON PRIMARY ( NAME = N'EncryptTest', FILENAME = N'C:\EncryptTest.mdf') LOG ON ( NAME = N'EncryptTest_log', FILENAME = N'C:\EncryptTest_log.ldf') GO
First, let’s create a sample table and then populate it with sample data. We will now encrypt one of the two columns of the table.
/* Create table and insert data in the table */ USE EncryptTest GO CREATE TABLE TestTable (FirstCol INT, SecondCol VARCHAR(50)) GO INSERT INTO TestTable (FirstCol, SecondCol) SELECT 1,'First' UNION ALL SELECT 2,'Second' UNION ALL SELECT 3,'Third' UNION ALL SELECT 4,'Fourth' UNION ALL SELECT 5,'Fifth' GO /* Check the content of the TestTable */ USE EncryptTest GO SELECT * FROM TestTable GO
The preceding code will return the result depicted in the subsequent figure.
Result of the SQL query
Every database can have one master key. Database master key is a symmetric key used to protect the private keys of certificates and asymmetric keys present in the database. It uses Triple DES algorithm together with user-provided
password to encrypt the keys.
/* Create Database Master Key */ USE EncryptTest GO CREATE MASTER KEY ENCRYPTION BY PASSWORD = 'SQLAuthority' GO
Certificates are used to safeguard encryption keys, which are used to encrypt data in the database. SQL Server 2005 has the capability to generate self-signed X.509 certificates.
/* Create Encryption Certificate */ USE EncryptTest GO CREATE CERTIFICATE EncryptTestCert WITH SUBJECT = 'SQLAuthority' GO
The symmetric key can be encrypted by using various options such as certificate, password, symmetric key, and asymmetric key. A number of different algorithms can be employed for encrypting key. The supported algorithms are DES,
TRIPLE_DES, RC2, RC4, RC4_128, DESX, AES_128, AES_192, and AES_256.
/* Create Symmetric Key */ USE EncryptTest GO CREATE SYMMETRIC KEY TestTableKey WITH ALGORITHM = TRIPLE_DES ENCRYPTION BY CERTIFICATE EncryptTestCert GO
Now add a column of type varbinary to the original table, which will store the encrypted value for the SecondCol.
/* Encrypt Data using Key and Certificate Add Columns which will hold the encrypted data in binary */ USE EncryptTest GO ALTER TABLE TestTable ADD EncryptSecondCol VARBINARY(256) GO
Before the key is used, it needs to be decrypted using the same method that was used for encrypting it. In our example, we have used a certificate for encrypting the key. Because of the same reason, we are using the same certificate
for opening the key and making it available for use. Subsequent to opening it and making it available for use, we can use the encryptkey function and store the encrypted values in the database, in the EncryptSecondCol column.
/* Update binary column with encrypted data created by certificate and key */
USE EncryptTest
GO
OPEN SYMMETRIC
KEY TestTableKey DECRYPTION
BY CERTIFICATE EncryptTestCert
UPDATE TestTable
SET EncryptSecondCol
= ENCRYPTBYKEY(KEY_GUID('TestTableKey'),SecondCol)
GOWe can drop the original SecondCol column, which we have now encrypted in the EncryptSecondCol column. If you do not want to drop the column, you can keep it for future comparison of the data when we decrypt the column.
/* DROP original column which was encrypted for protect the data */ USE EncryptTest GO ALTER TABLE TestTable DROP COLUMN SecondCol GO
We can run a SELECT query on our database and verify if our data in the table is well protected and hackers will not be able to make use of it even if they somehow manage to reach the data.
/* Check the content of the TestTable */ USE EncryptTest GO SELECT * FROM TestTable GO
Result of the previous SQL query
Authorized user can use the decryptbykey function to retrieve the original data from the encrypted column. If Symmetric key is not open for decryption, it has to be decrypted using the same certificate that was used to encrypt
it. An important point to bear in mind here is that the original column and the decrypted column should have the same data types. If their data types differ, incorrect values could be reproduced. In our case, we have used a VARCHAR data type for SecondCol
and EncryptSecondCol.
/* Decrypt the data of the SecondCol */ USE EncryptTest GO OPEN SYMMETRIC KEY TestTableKey DECRYPTION BY CERTIFICATE EncryptTestCert SELECT CONVERT(VARCHAR(50),DECRYPTBYKEY(EncryptSecondCol)) AS DecryptSecondCol FROM TestTable GO
If you drop the database after the entire processing is complete, you do not have to worry about cleaning up the database. However, in real world on production servers, the database is not dropped. It is a good practice for developers
to close the key after using it. If keys and certificates are used only once or their use is over, they can be dropped as well. Dropping a database will drop everything it contains – table, keys, certificates, all the data, to name a few.
/* Clean up database */ USE EncryptTest GO CLOSE SYMMETRIC KEY TestTableKey GO DROP SYMMETRIC KEY TestTableKey GO DROP CERTIFICATE EncryptTestCert GO DROP MASTER KEY GO USE [master] GO DROP DATABASE [EncryptTest] GO
Summary
Encryption is a very important security feature of SQL Server 2005. Long keys and asymmetric keys create unassailable, stronger encryption and stronger encryption uses lots of CPU to encrypt data. Stronger encryption is slower
to process. When there is a huge amount of data to encrypt, it is suggested to encrypt it using a symmetric key. The same symmetric key can be encrypted further with an asymmetric key for additional protection, thereby adding the advantage of a stronger encryption.
It is also recommended to compress data before encryption, as encrypted data cannot be compressed.
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