After estimating the factors related to performance as explained in Chapter 1, Product Concepts the Application Server. A topology is the arrangement of machines, Application Server instances, and HADB nodes, and the communication flow among them.
There are two fundamental deployment topologies. Both topologies have common building blocks: multiple Application Server instances in a cluster, a mirrored set of HADB nodes, and HADB spare nodes. Both of them require a set of common configuration settings to function properly.
This chapter discusses:
Common Requirements for both topologies.
The two topologies:
This section describes the requirements that are common to both topologies:
Both topologies must meet the following general requirements:
Machines that host HADB nodes must be in pairs. That is, there must be an even number of them.
Machines that host the HADB nodes must run the same operating system. It is best to use identical or nearly identical machines, in terms of configuration and performance.
For HTTP and SFSB session information to be persisted to the HADB, the Application Server instances must be in a cluster and satisfy all related requirements. For more information on configuring clusters, see Chapter 5, Using Application Server Clusters, in Sun Java System Application Server Enterprise Edition 8.1 2005Q2 High Availability Administration Guide.
Machines hosting the Application Server instances must be as identical as possible, in terms of configuration and performance. This is because the load balancer plug-in uses a round-robin policy for load balancing, and if machines of different classes host instances, then the load will not be balanced in the most optimum way across these machines.
Preferably have a separate uninterruptible power supply (UPS) for each DRU.
Each DRU contains a complete copy of the data in HADB and can continue servicing requests if the other DRU becomes unavailable. However, if a node in one DRU and its mirror in another DRU fail at the same time, some portion of data is lost. For this reason, it is important that the system is not set up so that both DRUs can be affected by a single failure such as a power failure or disk failure.
Follow these guidelines when setting up the HADB nodes and machines:
Set up each DRU with a number of spare nodes equal to the number of nodes running on each machine. This is because if each machine in the configuration runs n data nodes, the failure of a single machine brings down n nodes.
Run the same number of HADB nodes on all machines to balance load as evenly as possible.
Do not run nodes from different DRUs on the same machine. If you must run nodes from different DRUs on the same machine, ensure that the machine can handle any single point of failure (for failures related to disk, memory, CPU, power, operating system crashes, and so on).
Both the topologies have Application Server instances in a cluster. These instances persist session information to the HADB. Configure the load balancer to include configuration information for all the Application Server instances in the cluster.
For more information on setting up a cluster and adding Application Server instances to clusters, see Chapter 5, Using Application Server Clusters, in Sun Java System Application Server Enterprise Edition 8.1 2005Q2 High Availability Administration Guide.
In the co-located topology, the Application Server instance and the HADB nodes are on the same machine (hence the name co-located). This topology requires fewer machines than the separate tier topology. The co-located topology uses CPUs more efficiently—an Application Server instance and an HADB node share one machine and the processing is distributed evenly among them.
This topology requires a minimum of two machines. To improve throughput, add more machines in pairs.
The following figure illustrates an example configuration of the co-located topology.
Machine SYS0 hosts Application Server instance A, machine SYS1 hosts Application Server instance B, machine SYS2 hosts Application Server instance C, and machine SYS3 hosts Application Server instance D.
These four instances form a cluster that persists information to the two DRUs:
DRU0 comprises two machines, SYS0 and SYS2. HADB node active 0 is on the machine SYS0. HADB node spare 2 is on the machine SYS2.
DRU1 comprises two machines, SYS1 and SYS3. HADB node active 1 is on the machine SYS1. HADB node spare 3 is on the machine SYS3.
For better scalability and throughput, increase the number of Application Server instances and HADB nodes by adding more machines. For example, you could add two machines, each with one Application Server instance and one HADB node. Make sure to add the HADB nodes in pairs, assigning one node for each DRU. Variation of Co-located Topology illustrates this configuration.
In this variation, the machines SYS4 and SYS5 have been added to the co-located topology described in Example Configuration.
Application Server instances are hosted as follows:
Machine SYS0 hosts instance A
Machine SYS1 hosts instance B
Machine SYS2 hosts instance C
Machine SYS3 hosts instance D
Machine SYS4 hosts instance E
Machine SYS5 hosts instance F
These instances form a cluster that persists information to the two DRUs:
DRU0 comprises machines SYS0, SYS2, and SYS4. HADB node active 0 is on the machine SYS0. HADB node active 2 is on the machine SYS2. HADB node spare 4 is on the machine SYS4.
DRU1 comprises the machines SYS1, SYS3, and SYS5. HADB node active 1 is on the machine SYS1. HADB node active 3 is on the machine SYS3. HADB node spare 5 is on the machine SYS5.
This topology requires more hardware than the co-located topology. It might be a good fit if you have different types of machines—you can allocate one set of machines to host Application Server instances and another to host HADB nodes. For example, you could use more powerful machines for the Application Server instances and less powerful machines for HADB.
The following figure illustrates the separate tier topology.
In this topology, machine SYS0 hosts Application Server instance A and machine SYS1 hosts Application Server instance B. These two instances form a cluster that persists session information to the two DRUs:
DRU0 comprises two machines, SYS2 and SYS4. HADB node active 0 is on machine SYS2 and the HADB node spare 2 is on machine SYS4.
DRU1 comprises two machines, SYS3 and SYS5. HADB node active 1 is on machine SYS3 and the HADB node spare 3 on machine SYS5.
All the nodes on a DRU are on different machines, so that even if one machine fails, the complete data for any DRU continues to be available on other machines.
A variation of the separate tier topology is to increase the number of Application Server instances by adding more machines horizontally to the configuration. For example, add another machine to the example configuration by creating a new Application Server instance. Similarly, increase the number of HADB nodes by adding more machines to host HADB nodes. Recall you must add the HADB nodes in pairs with one node for each DRU.
Variation of Separate Tier Topology illustrates this configuration.
In this configuration, each machine hosting Application Server instances has two instances. There are thus a total of six Application Server instances in the cluster.
HADB nodes are on machines SYS3, SYS4, SYS5, and SYS6.
DRU0 comprises two machines:
SYS3, which hosts HADB node active 0 and HADB node active 2.
SYS5, with HADB node spare 4 and HADB node spare 6.
DRU1 comprises two machines:
SYS4, which hosts HADB node active 1 and HADB node active 3.
SYS6, which hosts HADB node spare 5 and HADB node spare 7.
Each machine hosting HADB nodes hosts two nodes. Thus, there are a total of eight HADB nodes: four active nodes and four spare nodes.
Determine what trade-offs are required to meet your goals. For example, if ease of maintenance is critical, the separate tier topology is more suitable. The trade-off is that this topology requires more machines than the co-located topology.
An important factor in the choice of topology is the type of machines available. If the system contains large, Symmetric Multiprocessing (SMP) machines, the co-located topology is attractive because you can take full advantage of the processing power of these machines. If the system contains various types of machines, the separate tier topology can be more useful because you can allocate a different set of machines to the Application Server tier and to the HADB tier. For example, you might want to use the most powerful machines for the Application Server tier and less powerful machines for the HADB tier.
The following table compares the co-located topology and the separate tier topology. The left column lists the name of the topology, the middle column lists the advantages of the topology, and the right column lists the disadvantages of the topologyTable 3–1 Comparison of Topologies
Requires fewer machines. Because the HADB nodes and the Application Server instances are on the same tier, you are able to create an Application Server instance on each spare node to handle additional load.
Improved CPU utilization. Processing is distributed evenly between an Application Server instance and an HADB node sharing one machine.
Useful for large, Symmetric Multiprocessing (SMP) machines since it takes full advantage of their processing power.
Increased complexity of maintenance. For example, when you have to shut down machines hosting HADB nodes to perform maintenance, application server instances on the machine also become unavailable.
Separate Tier Topology
Easier maintenance. For example, you are able to perform maintenance on the machines that host Application Server instances without having to bring down HADB nodes.
Useful with different types of machines. You are able to allocate a different set of machines to the Application Server tier and the HADB tier. For example, you are able to use more powerful machines for the Application Server tier and the less powerful machines for the HADB tier.
Requires more machines than the co-located topology. Because application server instances and HADB nodes are located on separate tiers, application server instances cannot be located on the machines that host the HADB spare nodes.
Reduced CPU utilization. The application server tier and the HADB tier will likely have uneven loads. This is more significant with a small number of machines (four to six).