|Oracle® Transparent Gateway for DRDA Installation and User's Guide
10g Release 2 (10.2) for UNIX
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The gateway architecture involves multiple computer setups that have distinct security capabilities and limitations. This chapter provides information for planning and implementing your security system.
The chapter provides information that is specific to the 10.2 release of the Oracle Transparent Gateway for DRDA. It contains the following sections:
gateway security involves two groups:
Users and applications that are permitted access to a given gateway instance and DRDA database server
Server database objects that users and applications are able to query and update
You can control access in the gateway architecture at several points. Control over database object access is provided by each DRDA database server with
GRANTs and related native authorization mechanisms based on user ID.
When the gateway is involved in a SQL request, security mechanisms are in effect for each DRDA system component encountered by the gateway. The first system component encountered is the application tool or 3GL program. The last system component encountered is the DRDA database.
An application must connect to an Oracle integrating server before using the gateway. The type of logon authentication that you use determines the resulting Oracle user ID and can affect gateway operation. There are two basic types of authentication:
Oracle authentication: With Oracle authentication, each Oracle user ID has a password known to Oracle Database. When an application connects to the server, it supplies a user ID and password. Oracle Database confirms that the user ID exists and that the password matches the one kept in the database.
Operating system authentication: With operating system authentication, the servers underlying operating system is responsible for authentication. An Oracle user ID that is created with the
IDENTIFIED EXTERNALLY attribute, instead of a password, is accessed with operating system authentication. To log into such a user ID, the application supplies a forward slash ( / ) for a user ID and does not supply a password.
To perform operating system authentication, the server determines the requester's operating system user ID, optionally adds a fixed prefix to it, and uses the result as the Oracle user ID. The server confirms that the user ID exists and is
IDENTIFIED EXTERNALLY, but no password checking is done. The underlying assumption is that users were authenticated when they logged into the operating system.
Operating system authentication is not available on all platforms and is not available in some
Oracle Net (client-server) and multi-threaded server configurations. Refer to the Oracle Database Installation Guide 10g for UNIX Systems and Oracle Net documentation to determine the availability of this feature.
For more information about authenticating application logons, refer to the Oracle Database Reference.
The information here is specific to the gateway. For additional information on database links, refer to the Oracle Database Reference.
The database link should be accessible to a given user. A public database link can be used by any user ID. A private database link can be used only by the user who created it. The server makes no distinction regarding the type of use (such as read-only versus update or write) or accessibility of remote objects. The DRDA database, which is accessed, is responsible for these distinctions.
CONNECT clause is another security-related attribute of a database link. You can use the
CONNECT clause to specify an explicit user ID and password, which can differ from the user's Oracle Database user ID and password. This
CONNECT user ID and password combination is sent to the gateway when the database link connection is first opened. Depending on gateway options, the gateway might send that user ID and password to the DRDA Server for validation.
If a database link is created without a
CONNECT clause, then the user's Oracle Database user ID and password are sent to the gateway when the connection is opened. If the user logs into the Oracle integrating server with operating system authentication, then the gateway does not receive any user ID or password from the Oracle Integrating Server. In this case, user ID mapping facilities at the DRDA Server can be used to make such a connection possible if all users on the same host can use the same DRDA database user ID.
TCP/IP does not have any additional configurable security mechanism. The gateway supports a validation mechanism which requires a user ID and a valid password. The security information is passed to the
DRDA Server for validation. This type of validation is equivalent to the "
SNA Security Option SECURITY=PROGRAM". Refer to the discussion of this option in Chapter 6, Chapter 7, or Chapter 8. The difference between the two methods is that in the SNA configuration, the security validation is performed by the SNA network facilities, and in the TCP/IP configuration, the
DRDA Server manually performs the validation.
Current DRDA Servers provide options for manipulating the security conduct of an inbound (client) DRDA session request. Refer to "Documentation Requirements", for a list of IBM documentation.
The most useful DRDA Server security capability is user ID mapping. User ID mapping refers to changing the user ID associated with an incoming DRDA request to some other user ID known to that server. This is a useful feature if your Oracle Transparent Gateway installation does not have a uniform user ID structure across all systems and databases.
These tables, pertinent to inbound sessions, have a role in security processing:
SYSIBM.LUNAMES table controls inbound security conduct on an SNA Logical Unit basis, affecting all DRDA connections from a particular host system. This table also controls whether inbound connection user IDs are subject to translation or mapping.
When translation is used, rows in the
SYSIBM.SYSUSERNAMES table specify translated user IDs by (Logical Unit)LU name and inbound user ID. Default entries that pertain to all LUs and to all inbound user IDs can be made in both tables. The mapping table can also be used simply to indicate which inbound user IDs are permitted from a particular LU or from all LUs, whether or not they are mapped.
This implementation provides a flexible mapping structure. You can specify that all connections from a particular LU use a single DB2 user ID, or that a particular inbound user ID always be mapped to a particular DB2 user ID regardless of origin. A
SYSUSERNAMES entry with blank LU name and inbound user ID can designate a single default DB2 user ID for all connections unless a more specific entry, by LU name, user ID, or both, exists.
The CDB tables can be updated by a user with update privilege using a SQL tool such as the DB2
SPUFI utility. For example, most database administrators, systems programmers, and security officers can update CDB tables. The DB2 DDF component must be stopped and restarted for CDB changes to take effect.
The DB2 non-DRDA-specific security features are also involved in DRDA connections. User IDs are subject to normal DB2 or SAF/RACF validation in addition to connection or sign-on exit processing. Passwords are also subject to validation. After the connection is established, all normal authorizations or
GRANTs associated with the user ID are in effect. The user ID must have execute privilege on the gateway DRDA package to process any SQL statements.
Under a Virtual Machine (VM), DRDA sessions are managed by APPC VTAM Support (AVS), which runs as a disconnected GCS virtual machine. AVS receives incoming APPC connection requests (both DRDA and non-DRDA) and routes the connection to an appropriate server virtual machine.
Originating LU name
Inbound user ID
The new user ID
You can create default entries that apply to any LU name and to any inbound user ID, and an entry can indicate that the inbound user ID is to be used without mapping.
After any indicated user ID mapping has been done, inbound DRDA connection requests are forwarded to the specified DB2/VM server machine. DB2/VM confirms only that the user ID has
CONNECT authority and, if so, that the connection is complete. At this point, the applications access to DB2/VM objects is controlled by the normal authorities and
GRANTs for the connected user ID. The user ID must have execute authority on the gateway DRDA package to process any SQL statements.
DB2/400 does not provide a user ID mapping capability comparable to that in DB2/OS390 and DB2/VM. Normally, the user ID in an incoming DRDA connection request must be a valid user ID on that DB2/400.
The DB2/400 subsystem communications entry for the gateway should specify that the gateway is not a secure location and should include a default user ID of *
After the application has completed the DRDA connection to the DB2/400, it is subject to all authorities and
GRANTs associated with the user ID in use.
The user ID must have execute authority on the gateway DRDA package to execute any SQL statements.
DB2/Universal Database (DB2/UDB) does not provide a user ID mapping capability comparable to that in DB2/OS390 and DB2/VM. Normally, the user ID in an incoming DRDA connection request must be a valid user ID on the DB2/UDB host.
After the application has completed the DRDA connection to the DB2 host, it is subject to all authorities and
GRANTs associated with the user ID in use. The user ID must have execute authority on the gateway DRDA package to execute any SQL statements.
The gateway uses userids and passwords to access the information in the remote database on the DRDA Server. Some userids and passwords must be defined in the Gateway Initialization File to handle functions such as resource recovery. In the current security conscious environment, having plain-text passwords that are accessible in the Initialization File is deemed insecure. An encryption feature has been added as part of Hetergeneous Services' generic connectivity to help make this more secure. This feature is accessible by this gateway. With it Initialization parameters which contain sensitive values might be stored in an encrypted form. Refer to the manual Oracle Database Hetergeneous Connectivity Administrator's Guide, Chapter 4, "Encrypting Initialization Parameters" for information about how to use the feature.
See Also:the parameters
DRDA_RECOVERY_PASSWORDin Appendix C as examples, for more information.