Walkthrough for the security features of SQL Server on Linux
If you are a Linux user who is new to SQL Server, the following tasks walk you through some of the security tasks. These are not unique or specific to Linux, but it helps to give you an idea of areas to investigate further. In each example, a link is provided to the in-depth documentation for that area.
The following examples use the AdventureWorks2014 sample database. For instructions on how to obtain and install this sample database, see Restore a SQL Server database from Windows to Linux.
Create a login and a database user
Grant others access to SQL Server by creating a login in the master database using the CREATE LOGIN statement. For example:
CREATE LOGIN Larry WITH PASSWORD = '************';
Always use a strong password in place of the asterisks in the previous command.
Logins can connect to SQL Server and have access (with limited permissions) to the master database. To connect to a user-database, a login needs a corresponding identity at the database level, called a database user. Users are specific to each database and must be separately created in each database to grant them access. The following example moves you into the AdventureWorks2014 database, and then uses the CREATE USER statement to create a user named Larry that is associated with the login named Larry. Though the login and the user are related (mapped to each other), they are different objects. The login is a server-level principle. The user is a database-level principal.
USE AdventureWorks2014; GO CREATE USER Larry; GO
- A SQL Server administrator account can connect to any database and can create more logins and users in any database.
- When someone creates a database they become the database owner, which can connect to that database. Database owners can create more users.
Later you can authorize other logins to create a more logins by granting them the
ALTER ANY LOGIN permission. Inside a database, you can authorize other users to create more users by granting them the
ALTER ANY USER permission. For example:
GRANT ALTER ANY LOGIN TO Larry; GO USE AdventureWorks2014; GO GRANT ALTER ANY USER TO Jerry; GO
Now the login Larry can create more logins, and the user Jerry can create more users.
Granting access with least privileges
The first people to connect to a user-database will be the administrator and database owner accounts. However these users have all the permissions available on the database. This is more permission than most users should have.
When you are just getting started, you can assign some general categories of permissions by using the built-in fixed database roles. For example, the
db_datareader fixed database role can read all tables in the database, but make no changes. Grant membership in a fixed database role by using the ALTER ROLE statement. The following example add the user
Jerry to the
db_datareader fixed database role.
USE AdventureWorks2014; GO ALTER ROLE db_datareader ADD MEMBER Jerry;
For a list of the fixed database roles, see Database-Level Roles.
Later, when you are ready to configure more precise access to your data (highly recommended), create your own user-defined database roles using CREATE ROLE statement. Then assign specific granular permissions to you custom roles.
For example, the following statements create a database role named
Sales, grants the
Sales group the ability to see, update, and delete rows from the
Orders table, and then adds the user
Jerry to the
CREATE ROLE Sales; GRANT SELECT ON Object::Sales TO Orders; GRANT UPDATE ON Object::Sales TO Orders; GRANT DELETE ON Object::Sales TO Orders; ALTER ROLE Sales ADD MEMBER Jerry; ``` For more information about the permission system, see [Getting Started with Database Engine Permissions](../relational-databases/security/authentication-access/getting-started-with-database-engine-permissions.md). ## Configure row-level security [Row-Level Security](../relational-databases/security/row-level-security.md) enables you to restrict access to rows in a database based on the user executing a query. This feature is useful for scenarios like ensuring that customers can only access their own data or that workers can only access data that is pertinent to their department. The following steps walk through setting up two Users with different row-level access to the `Sales.SalesOrderHeader` table. Create two user accounts to test the row level security: ``` USE AdventureWorks2014; GO CREATE USER Manager WITHOUT LOGIN; CREATE USER SalesPerson280 WITHOUT LOGIN; ``` Grant read access on the `Sales.SalesOrderHeader` table to both users: ``` GRANT SELECT ON Sales.SalesOrderHeader TO Manager; GRANT SELECT ON Sales.SalesOrderHeader TO SalesPerson280; ``` Create a new schema and inline table-valued function. The function returns 1 when a row in the `SalesPersonID` column matches the ID of a `SalesPerson` login or if the user executing the query is the Manager user. ``` CREATE SCHEMA Security; GO CREATE FUNCTION Security.fn_securitypredicate(@SalesPersonID AS int) RETURNS TABLE WITH SCHEMABINDING AS RETURN SELECT 1 AS fn_securitypredicate_result WHERE ('SalesPerson' + CAST(@SalesPersonId as VARCHAR(16)) = USER_NAME()) OR (USER_NAME() = 'Manager'); ``` Create a security policy adding the function as both a filter and a block predicate on the table:
CREATE SECURITY POLICY SalesFilter
ADD FILTER PREDICATE Security.fn_securitypredicate(SalesPersonID)
ADD BLOCK PREDICATE Security.fn_securitypredicate(SalesPersonID)
WITH (STATE = ON);
Execute the following to query the `SalesOrderHeader` table as each user. Verify that `SalesPerson280` only sees the 95 rows from their own sales and that the `Manager` can see all the rows in the table.
EXECUTE AS USER = 'SalesPerson280';
SELECT * FROM Sales.SalesOrderHeader;
EXECUTE AS USER = 'Manager';
SELECT * FROM Sales.SalesOrderHeader;
Alter the security policy to disable the policy. Now both users can access all rows.
ALTER SECURITY POLICY SalesFilter
WITH (STATE = OFF);
## Enable dynamic data masking [Dynamic Data Masking](../relational-databases/security/dynamic-data-masking.md) enables you to limit the exposure of sensitive data to users of an application by fully or partially masking certain columns. Use an `ALTER TABLE` statement to add a masking function to the `EmailAddress` column in the `Person.EmailAddress` table:
ALTER TABLE Person.EmailAddress
ALTER COLUMN EmailAddress
ADD MASKED WITH (FUNCTION = 'email()');
Create a new user `TestUser` with `SELECT` permission on the table, then execute a query as `TestUser` to view the masked data:
CREATE USER TestUser WITHOUT LOGIN;
GRANT SELECT ON Person.EmailAddress TO TestUser;
EXECUTE AS USER = 'TestUser';
SELECT EmailAddressID, EmailAddress FROM Person.EmailAddress;
Verify that the masking function changes the email address in the first record from: |EmailAddressID |EmailAddress | |----|---- | |1 |firstname.lastname@example.org | into |EmailAddressID |EmailAddress | |----|---- | |1 |kXXX@XXXX.com | ## Enable Transparent Data Encryption One threat to your database is the risk that someone will steal the database files off of your hard-drive. This could happen with an intrusion that gets elevated access to your system, through the actions of a problem employee, or by theft of the computer containing the files (such as a laptop). Transparent Data Encryption (TDE) encrypts the data files as they are stored on the hard drive. The master database of the SQL Server database engine has the encryption key, so that the database engine can manipulate the data. The database files cannot be read without access to the key. High-level administrators can manage, backup, and recreate the key, so the database can be moved, but only by selected people. When TDE is configured, the `tempdb` database is also automatically encrypted. Since the Database Engine can read the data, Transparent Data Encryption does not protect against unauthorized access by administrators of the computer who can directly read memory, or access SQL Server through an administrator account. ### Configure TDE - Create a master key - Create or obtain a certificate protected by the master key - Create a database encryption key and protect it by the certificate - Set the database to use encryption Configuring TDE requires `CONTROL` permission on the master database and `CONTROL` permission on the user database. Typically an administrator configures TDE. The following example illustrates encrypting and decrypting the `AdventureWorks2014` database using a certificate installed on the server named `MyServerCert`.
CREATE MASTER KEY ENCRYPTION BY PASSWORD = '**********';
CREATE CERTIFICATE MyServerCert WITH SUBJECT = 'My Database Encryption Key Certificate';
USE AdventureWorks2014; GO
CREATE DATABASE ENCRYPTION KEY
WITH ALGORITHM = AES_256
ENCRYPTION BY SERVER CERTIFICATE MyServerCert;
ALTER DATABASE AdventureWorks2014
SET ENCRYPTION ON;
To remove TDE, execute `ALTER DATABASE AdventureWorks2014 SET ENCRYPTION OFF;` The encryption and decryption operations are scheduled on background threads by SQL Server. You can view the status of these operations using the catalog views and dynamic management views in the list that appears later in this topic. > [!WARNING] > Backup files of databases that have TDE enabled are also encrypted by using the database encryption key. As a result, when you restore these backups, the certificate protecting the database encryption key must be available. This means that in addition to backing up the database, you have to make sure that you maintain backups of the server certificates to prevent data loss. Data loss will result if the certificate is no longer available. For more information, see [SQL Server Certificates and Asymmetric Keys](../relational-databases/security/sql-server-certificates-and-asymmetric-keys.md). For more information about TDE, see [Transparent Data Encryption (TDE)](../relational-databases/security/encryption/transparent-data-encryption-tde.md). ## Configure backup encryption SQL Server has the ability to encrypt the data while creating a backup. By specifying the encryption algorithm and the encryptor (a certificate or asymmetric key) when creating a backup, you can create an encrypted backup file. > [!WARNING] > It is very important to back up the certificate or asymmetric key, and preferably to a different location than the backup file it was used to encrypt. Without the certificate or asymmetric key, you cannot restore the backup, rendering the backup file unusable. The following example creates a certificate, and then creates a backup protected by the certificate.
CREATE CERTIFICATE BackupEncryptCert
WITH SUBJECT = 'Database backups';
BACKUP DATABASE [AdventureWorks2014]
TO DISK = N'/var/opt/mssql/backups/AdventureWorks2014.bak'
ALGORITHM = AES_256,
SERVER CERTIFICATE = BackupEncryptCert
STATS = 10
For more information, see [Backup Encryption](../relational-databases/backup-restore/backup-encryption.md). ## Next steps For more information about the security features of SQL Server, see [Security Center for SQL Server Database Engine and Azure SQL Database](../relational-databases/security/security-center-for-sql-server-database-engine-and-azure-sql-database.md).