Patent Document

BACKGROUND OF THE INVENTION  
       [0001]     The invention relates generally to computer systems, and deals more particularly with load balancing of servers in a cluster.  
         [0002]     Servers perform various tasks for clients such as furnishing web pages, hosting content, storing data and hosting applications. It was known to arrange two or more similar servers in a cluster for redundancy; in case one server failed, there would still be one server to handle the work requests of the clients. It was also known to arrange similar servers in a cluster to increase the overall computing resources available to the clients. In both cases, a load balancing computer, separate from the servers in the cluster, determined which server to route each new client request. The load balancing computer was located between the clients and the cluster of servers. Different load balancing algorithms are currently known. These include a simple round robin algorithm where the different servers in the cluster are sequentially assigned work requests as they are received by the load balancer. Other load balancing algorithms are more sophisticated and consider the length of the current work queue of each server and/or the current response time of each server. In these more sophisticated algorithms, new client requests are routed to the server with the shortest current work queue or shortest current response time. In those clusters where the servers are not all identical, a known load balancer may consider the type of client request and the server with the best configuration or resources to handle the type of client request.  
         [0003]     It was also known for the servers in the cluster to periodically send to the load balancer a “hello” message or “heartbeat” to indicate that the server is still running and not severely overloaded. If the load balancer does not receive the hello message within a predetermined time interval (or “time-out”) of the previous hello message, then the load balancer may assume that the server is “down” and then remove the server from the cluster. In such a case, the load balancer will not assign any new client requests to this server until the server reestablishes its viability with the load balancer.  
         [0004]     It was also known for the load balancer to monitor the work load of the cluster and of individual servers in the cluster. The work load was measured by the number of message packets received in the client requests, over a time interval. The length of the message packets in the client requests is loosely correlated to the work required to handle the request. If the work load exceeded a threshold for the cluster or any server in the cluster, then the load balancer may request help from additional resources on the network by sending the request to servers that are configured to lend available resources. Upon a successful request for additional resources, this would start the process as defined in the Join-Request Process.  
         [0005]     Currently, the parameters defining the clustering, i.e. which servers are in the cluster to receive and handle client requests, what load balancing algorithm to use for the cluster, what hello message interval to use for each server, and what time-out to use for each server, are specified in the configuration of the load balancer. Some of these parameters are default parameters of the load balancing program, and others are input by an administrator of the load balancer. (Although as noted above, if a load balancer was initially configured to include a certain server as part of the cluster, and this server goes down, then the load balancer will remove this server from the cluster, until such time as the server reestablishes its viability to the load balancer.) While the foregoing technique to define the parameters was effective, it relied too heavily on the knowledge and foresight of the administrator of the load balancer. Also, it some cases, it was not sufficiently dynamic enough to account for change of circumstances.  
         [0006]     Therefore, an object of the present invention is to improve the process of defining parameters of a cluster of servers.  
       SUMMARY OF THE INVENTION  
       [0007]     The invention resides in a system, method and program product for operating a cluster of servers. A load balancer, separate from the servers, selects servers to handle respective work requests assigned to the cluster based on a load balancing algorithm, and sends the work requests to the selected servers. The load balancer receives a request from another server not currently a member of the cluster. The request requests that the other server become a member of the cluster to handle work requests. In response to the request, the load balancer joins the other server as a member of the cluster to handle some work requests subsequently assigned to the cluster.  
         [0008]     In accordance with one feature of the invention, the other server specifies to the load balancer a preferred load balancing algorithm to be used for assigning work requests to servers in the cluster.  
         [0009]     In accordance with another feature of the invention, the other server specifies to the load balancer a load threshold for the other server.  
         [0010]     In accordance with another feature of the invention, the other server specifies to the load balancer a time-out to be used for the other server. The time-out indicates a time allotted for the other server to send a hello message since sending a previous hello message.  
     
    
     BRIEF DESCRIPTION OF THE FIGURES  
       [0011]      FIG. 1  is a block diagram of a computer system including a load balancing program within a firewall and a cluster of servers, according to one embodiment of the present invention.  
         [0012]      FIG. 2  is a flow chart illustrating a join function, initiated by a server, within the load balancing program of  FIG. 1 .  
         [0013]      FIG. 3  is a flow chart illustrating a causal removal function initiated by and within the load balancing program of  FIG. 1 .  
         [0014]      FIG. 4  is a flow chart illustrating a discretionary removal function, initiated by a server, within the load balancing program of  FIG. 1 .  
         [0015]      FIG. 5  is a flow chart illustrating a join invitation function initiated by and within the load balancing program of  FIG. 1 , when an additional server is needed for the cluster.  
         [0016]      FIG. 6  is a flow chart illustrating a release function, initiated by and within the load balancing program of  FIG. 1 , when the additional server is no longer needed for the cluster.  
     
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS  
       [0017]     Referring now to the drawings in detail wherein like reference numbers indicate like elements,  FIG. 1  illustrates a computer system generally designated  10  according to one embodiment of the present invention. System  10  comprises a firewall  12  for a cluster  14  of servers  20   a,b,c,d . . . n . (As shown in  FIG. 1 , server  20   a  is initially outside of cluster  14 , but later joins the cluster  14  pursuant to the steps of  FIG. 2 .) Servers  20   a - n  reside on a network such as ethernet, token ring or fddi. However, the present invention works at layer three of the OSI Reference Model, so layer two media such as token ring, ethernet, fddi are transparent. Firewall  12  comprises a computer and a known filtering program  22  which filters incoming messages from Internet  24 , for security reasons. The known filtering program may base its filtering decisions on the IP protocol, protocol port, source IP address, destination IP address and known state of the message.  
         [0018]     Firewall  12  also includes a load balancing program  30  according to the present invention. A storage device  34  includes a configuration file  36  for load balancing program  30 . Storage device  34  includes a variety of different load balancing program routines for servers  20   a - n.  By way of example, one load balancing routine is a simple “round robin” algorithm where incoming work requests are assigned sequentially to the servers in the cluster. Another load balancing routine assigns new work requests to the server with the shortest current work queue. Another load balancing routine assigns new work requests to the server with the fastest current response time. Configuration file  36  includes load balancing parameters for servers  20   a - n,  as described in more detail below.  
         [0019]     Load balancing program  30  is initially configured with default parameters and/or by an administrator of the firewall  12  who can override the default parameters and supply other parameters. The following is an example of parameters of an initial configuration for cluster  14  of servers: 
        identity of a load balancing routine for the cluster. The load balancing routine is configured by an administrator at start up to use a specific load balancing algorithm. The initial setup of a device that wants to be load balanced can request the use of a different load balancing algorithm during the Join-Request process.     identity (IP address) of each server in the cluster     load threshold for each server, i.e. the number of message packets over a certain time interval that represent work requests and can be handled by the respective server. This incoming message packet rate loosely correlates to the amount of work required of the respective server to respond to the request. Different servers in the cluster can have different load thresholds.     hello interval, i.e. each server in the cluster is expected to send to the load balancing program a “hello” message periodically, for example, every ten seconds, to prove that the server is still “up” and available to handle work requests from the load balancing program.     time-out, i.e. how long the load balancing program will wait after receipt of each hello message for the next hello message before assuming that the server is down or severely overloaded. When a hello message is received, the load balancing program initiates a time-out clock, for example, thirty seconds. If the next hello message is not received before expiration of the time-out clock, then the load balancing program will assume that the server is down or severely overloaded, and remove the server from the cluster. Once removed, the load balancing program will not assign any subsequent work requests to this server, unless it rejoins the cluster. Any work requests previously assigned to this server that are not completed (as indicated by an acknowledgment by the server at the TCP/IP layer) will be reassigned by the load balancing program to another server in the cluster.     authentication, i.e. the shared password used to authenticate members of the cluster who wish to participate.        
 
         [0026]      FIG. 2  illustrates a join function  40  within load balancing program  30 . The join function is invoked by a join request initiated by (a) programming within a server not currently in a cluster or (b) an administrator of the server, to join the server into a specific cluster. When the decision is made by programming within the server, the decision can be based on under utilization of the server as measured by CPU monitoring hardware or software. When the decision is made by an administrator of the server, the decision can be based on under utilization of the server or installation/building of a new server that is looking for a cluster to join. In the case of the server programming making the decision, the server programming creates a request, including the requisite cluster parameters, to join a named cluster. In the case of the administrator making the decision, the administrator enters into server  20   a  a command to join a named cluster and other cluster parameters (as described below), and programming within server  20   a  generates the join request. (The load balancing program  30  can periodically broadcast to the available servers the identities of the existing clusters, or the administrator can learn the identities of the existing clusters by manually checking the configuration of the load balancer  30 .) After the join request is created, it is sent to the join function  40  within load balancing program  30  within firewall  22  (step  50 ). The join request includes a pass phrase (i.e. a sophisticated pass word) of the server, an identity (for example, a group identity) of a cluster that the server wants to join, a load threshold for the server, a time-out for the server, a “hello interval” for the server, a desired load balancing algorithm for the cluster and optionally, other user definable parameters for the server or cluster. The load balancing algorithm is the algorithm that server  20   a  requests to be used for the cluster, such as round robin, shortest work queue, fastest response time, etc.  
         [0027]     In response to the join request, join function  40  first determines if the server is authentic by looking up the pass phrase in a list of authentic ones maintained in storage device  34  (decision  52 ). If not, join function  40  returns a failure message to the server  20   a  (step  54 ). If so, join function  40  checks its database  36  to determine if the cluster identity in the request exists (step  56  and decision  58 ). If not, join function  40  returns a failure message to the server  20   a  (step  60 ). If so, join function  40  compares the load threshold, time-out, hello interval, load balancing algorithm and other user definable parameters specified in the join request to those in the existing cluster configuration file  36  (step  70 ). If any of the server specific parameters, i.e. load threshold, time-out or hello interval are not the same as those in the existing configuration file  36  (decision  80 , no branch), then join function  40  determines which server specific parameter should apply to server  20   a  when part of the named cluster (step  82 ). In the case of a difference in the load threshold, time-out or hello interval, the join function will select the lower of the thresholds specified by the existing configuration file  36  and the join request. The load threshold is specified for each server, such that different servers in the same cluster can have different load thresholds. So, if the existing configuration file  36  specifies a default value of six hundred packets per second and the server  20   a  join request specifies five hundred packets per second, then the configuration file  36  will be updated with a load threshold of five hundred packets per second for server  20   a.  For example, if the existing configuration file  36  specifies a default time-out of thirty seconds, and the join request specifies a time-out of twenty seconds, then the configuration file  36  will be updated with a time-out of twenty seconds. However, if the existing configuration file specifies a default hello interval of ten seconds, and the join request specifies a hello interval of fifteen seconds, then the configuration file  36  will remain with ten seconds for the hello interval.  
         [0028]     Next, join function  40  determines if the load balancing algorithm specified in the join request is the same as that listed in the existing configuration file  36  (decision  85 ). If so, then join function  40  adds server  20   a  to the named cluster, i.e. will add the IP address of server  20  to a list of servers in the named cluster (step  86 ). Then, join function  40  returns a message to server  20   a  indicating that server  20   a  has been added to the named cluster (step  88 ). Thereafter, load balancing program  30  will send server  20   a  work requests along with the other servers in the cluster according to the load balancing algorithm.  
         [0029]     Referring again to decision  85 , in the case of a difference in the load balancing algorithm specified in the join request compared to that in the existing configuration file  36 , join function  40  will notify the server  20   a  of this difference (step  90 ). Join function  40  will use the load balancing algorithm listed in the existing configuration file for the cluster when there are other servers in the cluster. The only time a server requesting to join a cluster can select the load balancing algorithm for the cluster, is if the server is the first server in the cluster. If server  20   a  returns with an agreement message (decision  92 , yes branch), then join function  40  will add server  20  to the named cluster, as described above (step  86 ). If server  20   a  does not return an agreement message (decision  92 , no branch), then join function  40  sends a failure message to server  20   a.    
         [0030]      FIG. 3  is a flow chart illustrating a causal remove function  150  initiated by load balancing program  30  to remove a server from a cluster for security reasons of if the server is down. If the time-out expires without receipt of the expected hello message (decision  152 , no branch), then causal remove function  150  deletes the server from the cluster (step  154 ). Thereafter, load balancing program  30  will not send any work requests to this server. If the hello message is received before the time-out (decision  152 , yes branch), then causal remove function  150  will check the pass phrase which accompanies or is included in the hello message (step  158 ). If the sender is not authentic (decision  160 , no branch), then causal remove function  150  will send a failure message to the sender (step  162 ). Then, the sender will have the remainder of the time-out period to submit another hello message with a proper pass phrase. Referring again to decision  160 , yes branch, where the hello message includes an authentic pass phrase, then causal remove function will reset the timer (step  164 ) and leave the server in the cluster (step  166 ).  
         [0031]      FIG. 4  is a flow chart illustrating a server initiated, discretionary remove function  100  within load balancing program  30 . The discretionary remove function  100  is called by programming within a server currently within a cluster or by an administrator of the server to remove the server from the cluster. When the decision is made by programming within the server, the decision can be based on over utilization of the server. When the decision is made by an administrator of the server, the decision can be based on over utilization of the server or a desire to power-off the server or use the server for other purposes. In the case of the server programming making the decision, the server programming creates a request to remove the server from the cluster. In the case of the administrator making the decision, the administrator enters into the server, for example, server  20   a , a command to remove server  20   a  from a named cluster, and programming within server  20   a  generates the remove request. After the remove request is created, it is sent to the discretionary remove function  100  within load balancing program  30  within firewall  22  (step  102 ). The remove request includes a pass phrase of the server and an identity of the cluster from which the server wants to be removed. In response to the remove request, remove function  100  checks the pass phrase of the server. If it is not authentic (decision  104 , no branch), then discretionary remove function  100  sends a failure message to server  20   a  (step  106 ). However, if server  20   a  is authenticated, then discretionary remove function  100  removes server  20   a  from the named cluster (step  110 ). Discretionary remove function  100  also notifies server  20   a  that the remove request was fulfilled (step  112 ). Thereafter, load balancing function  30  will not send any work requests to server  20   a  that are to be handled by the named cluster.  
         [0032]      FIG. 5  is a flow chart illustrating a join invitation function  200  initiated by load balancing program  30  when the load balancing program needs one or more additional servers to handle a high level of work requests for the cluster. Load balancing program  30  periodically checks its current work load for each existing cluster and the servers in each cluster (step  202 ). If the current work load for each server in a cluster is below the respective load threshold (decision  204 , no branch), then join invitation function  200  will terminate itself (step  206 ). However, if the current work load for any server in a cluster is above the respective load threshold, then join invitation function  200  sends a request to all servers that are potentially available to join the cluster, and not already in the cluster (step  208 ). It is presumed that if one server in the cluster is above the respective load threshold, that the other servers will be above or near their respective load thresholds. This is because it is presumed that the load balancing algorithm effectively balances the load amongst the servers in the cluster in proportion to their load thresholds or capabilities. The join invitation specifies the cluster that needs one or more additional servers and invites the available servers to volunteer to join the cluster. If none of the available servers that were sent the join invitation responds, then join invitation function  200  terminates itself (step  206 ). However, if one or more of the available servers that were sent the invitation respond that it/they will comply, then join invitation function  200  records that when they subsequently join the cluster, their membership will be temporary, i.e. only as long as the work load exceeds the load threshold (step  212 ). After responding that it/they will comply with the join invitation issued in step  208 , the server(s) (either the programming within the server or an administrator of the server) will send a join request to the load balancing program  30 , and this join request will be processed by join function  40  as described above with reference to  FIG. 2 .  
         [0033]      FIG. 6  is a flow chart illustrating a release function  300  initiated by load balancing program  30  for one or more servers temporarily added pursuant to the join invitation issued by join invitation function  200 . As explained in more detail below, release function  300  releases these one or more additional servers from a cluster when they are no longer needed. Load balancing program  30  periodically compares the current work load for the cluster and the servers in the cluster (step  301 ). If the current work load for any server in a cluster is above the respective load threshold (decision  302 , no branch), then server release function  300  will terminate itself (step  306 ). However, if the current work load for all servers in the cluster is below the respective load threshold for each server, then release function  300  sends a removal request to all servers that are listed as temporary members of the cluster (step  308 ). The removal request indicates that the cluster no longer needs their membership and invites these servers to volunteer to be removed from the cluster. If none of these servers responds (decision  310 , no branch), then release function  300  terminates itself (step  306 ). However, if one or more of the temporary members respond that it/they agree to be removed from the cluster (decision  310 , yes branch), then release function  300  removes the server(s) from the cluster (step  312 ). Thereafter, load balancing function  30  will not send to these server(s) any work requests that are to be handled by the cluster.  
         [0034]     Based on the foregoing, a system, method and program product for joining and removing servers from a cluster have been disclosed. However, numerous modifications and substitutions can be made without deviating from the scope of the present invention. For example, customized fields can be added to the cluster protocol to handle security management, encryption, and external authentication. Therefore, the present invention has been disclosed by way of illustration and not limitation, and reference should be made to the following claims to determine the scope of the present invention.

Technology Category: g