Abstract:
The invention provides, in one aspect, a server load balancer (SLB) recovery method that replicates a primary SLB&#39;s connection data after the primary SLB experiences a failure, as opposed to before it experiences a failure as is currently done in the known hot stand-by recovery method. In some embodiments, this is made possible by (1) employing a replication agent on each target processing unit (e.g., each processing unit on which a server application runs) and (2) transmitting, from the primary SLB, connection data information (i.e., information comprising a session identifier) to the replication agent running on the target processing unit to which the session is mapped, which replication agent will store the data until it is required to transmit the data to a cold stand-by SLB.

Description:
TECHNICAL FIELD 
       [0001]    The invention relates the field of server load balancing. 
       BACKGROUND 
       [0002]    A server load balancer (SLB) is device (hardware and/or software) for balancing session traffic across a set of applications (e.g., server applications), each of which runs on a processing unit (e.g., a server computer, a blade server, etc.). In many environments it is desired to have in-place a stand-by SLB in case the primary SLB fails. It is known that the stand-by SLB can either be a “hot” stand-by or a “cold” stand-by. When using a hot stand-by SLB it is required that connection data (e.g., a connection table) that is used by the primary SLB in balancing traffic across the server applications be replicated to the hot stand-by SLB prior to the failure of the primary SLB. Typically, this replication is accomplished by updating connection data accessible to the hot stand-by SLB each time the connection data maintained by the primary SLB is updated. An advantage of using a hot stand-by SLB is that, in case a failure of the primary SLB (or “active” SLB) occurs, a switchover to the stand-by SLB occurs and this stand-by SLB would have connection data that is identical to the connection data that was maintained by the primary SLB, thereby enabling the stand-by SLB to takeover as primary SLB and continue balance traffic for the already established sessions as well as new session. 
         [0003]    A problem with using the hot stand-by method is that if the hot stand-by fails, then the connection data will be lost. Moreover, the hot stand-by method requires that the hot stand-by SLB work in tandem with the primary SLB so that the primary SLB&#39;s connection data can be replicated. Another problem with the hot stand-by method occurs when some event (e.g., power failure, operating system crash, hardware fault) causes the primary SLB and a target processing unit (e.g., a processing unit on which a server application runs) to fail at more less the same time. When such a situation arises, the replicated connection data that is used by the stand-by SLB may include invalid information (e.g., information mapping a session to the failed target processing unit). This could cause the hot stand-by SLB to forward traffic to the failed target processing unit, which is undesirable because the traffic will not get processed due to the failure of the target processing unit. 
         [0004]    A problem with using a cold stand-by SLB is that there is no replication of the primary SLB&#39;s connection data, and this means that the cold stand-by SLB can not route traffic corresponding to a session that was established before the primary SLB failed. 
         [0005]    What is desired, therefore, are improved systems and methods for recovering from the failure of an SLB. 
       SUMMARY 
       [0006]    In one aspect, the invention provides an SLB recovery method that replicates the primary SLB&#39;s connection data after the primary SLB experiences a failure, as opposed to before it experiences a failure as is currently done in the known hot stand-by recovery method. In some embodiments, this is made possible by (1) employing a replication agent on each target processing unit (e.g., each processing unit on which a server application runs) and (2) transmitting, from the primary SLB, connection data information (i.e., information comprising a session identifier) to the replication agent running on the target processing unit to which the session is mapped, which replication agent will store the connection data information until it is required to transmit the data to a cold stand-by SLB. 
         [0007]    By having the primary SLB transmit connection data information to the replication agent, the replication agent can provide the connection data information to the cold stand-by SLB in the event the primary SLB experiences a failure. This provides the advantage of enabling a system design solution that can capitalize on the flexibility of cold stand-by methods yet is still able to protect established sessions because the cold stand-by SLB can receive from one or more replication agents connection data information that maps an established session to a particular target processing unit. This is particularly useful in server farms and clustered system designs. 
         [0008]    Moreover, the above described embodiment provides protection against multiple SLB failures because, in the event of a primary SLB failure and a cold stand-by failure, a second cold stand-by SLB can easily replicate the necessary connection data by merely receiving the necessary information from the replication agents. 
         [0009]    Additionally, some embodiments of the invention solve the above described problem that occurs when an event (e.g., power failure, operating system crash, hardware fault, etc) causes the primary SLB and a target processing unit to fail at more less the same time. As described above, in such a situation, the conventional stand-by SLB will have connection data (e.g., a connection table) that includes invalid connection data information (e.g., a records that maps a session to the failed target processing unit). However, if such a situation occurs in a system according to some embodiment of the invention, the replicated connection data used by the stand-by SLB will not contain any such invalid connection data information. This is so because, in some embodiments, the stand-by SLB receives its connection data information from the target processing unit themselves after the primary SLB fails. Thus, if a target has failed at more or less the same time as the primary SLB, then the stand-by SLB will not receive any connection data information from the failed target. Hence, the stand-by SLB will not have connection data that includes connection data information that maps a session to the failed target. 
         [0010]    One aspect of the invention provides a method, performed by a stand-by SLB. In some embodiments, this method includes: replicating, by the stand-by SLB, at least a portion of connection data maintained by the primary SLB such that the replicated connection data is accessible to the stand-by SLB, characterized in that the replicating step occurs in response to a detection of the failure of the primary SLB. After the replicating step, the stand-by SLB may: (a) receive traffic corresponding to a session; (b) access the replicated connection data to determine a target processing unit to which the session is mapped; and (c) forward the traffic to the determined target processing unit (i.e., the stand-by SLB become the primary SLB). 
         [0011]    After the replicating step, the stand-by SLB (which is now a primary SLB) may further: receive traffic corresponding to a second session and access the replicated connection data to determine whether the accessed data comprises information mapping the second session to any of a plurality of target processing units. In response to determining that the accessed data does not comprise information mapping the second session to any of the plurality of target processing units, the stand-by SLB is configured to: (a) select a particular target processing unit; (b) update the replicated connection data so that the replicated connection data will comprise information mapping the second session with the selected target processing unit; and (c) transmit to a replication agent running on the selected target processing unit a connection data update message comprising a session identifier identifying the second session. 
         [0012]    In some embodiments, the step of replicating the connection data comprises: receiving, at the stand-by SLB, a replication message transmitted from a target processing unit, wherein the replication message contains a session identifier identifying a session; and in response to receiving the replication message, storing information that maps the session with the target processing unit. In some embodiments, the replication message may contain a plurality of session identifiers, each identifying a different session, and, in response to receiving the replication message, the stand-by SLB stores information mapping each of the plurality of session identifiers with the target processing unit. 
         [0013]    In some embodiments, the method further includes: transmitting, in response to the failure of the primary SLB, a connection data synchronization message to each of a first and a second target processing unit, wherein each of the first and second target processing units is configured to transmit one or more replication messages to the stand-by SLB in response to receiving the connection data synchronization message. 
         [0014]    In some embodiments, the connection data maintained by the primary SLB comprises first information mapping a first session to the first target processing unit and second information mapping a second session to the second target processing unit, wherein the first information consists of a first record comprising a first field storing a session identifier identifying the first session and a second field storing a target processing unit identifier identifying the first target processing unit, and the second information consists of a second record comprising a second field storing a session identifier identifying the second session and a second field storing a target processing unit identifier identifying the second target processing unit. 
         [0015]    In some embodiments, the step of receiving, at the stand-by SLB, traffic corresponding to a session consists of receiving, at the stand-by SLB, a network packet comprising information identifying the session, wherein the network packet is an Internet Protocol (IP) packet that contains an IP header and a payload, wherein the payload contains a transport layer segment having a transport layer header and payload, and data from the IP header and transport layer header identifies the network packet as corresponding to the session. 
         [0016]    In some embodiments, the primary SLB may execute on one of the target processing units. In this case, the replicated connection data may not contain information that maps any session to the target processing unit on which the primary SLB was running when it failed. This, as described above, is advantageous because it is undesirable for the stand-by SLB to attempt to forward traffic to a failed target, which could happen if the connection table used by the stand-by SLB contains a record that maps a session to a failed target processing unit. 
         [0017]    In another aspect, the invention provides an improved stand-by server load balancer (SLB). The improved stand-by SLB is configured to recover from the failure of a primary SLB, which is operable to use stored connection data to balance traffic across a plurality of target processing units using. The stored connection data comprises information mapping sessions with target processing units. Advantageously, in one embodiment, the stand-by SLB is configured such that, in response to a detection of the failure of the primary SLB, the stand-by SLB replicates the connection data (or most of the connection data) to create replicated connection data. The replicated connection data is accessible to the stand-by SLB so that the stand-by SLB can use the replicated connection data to balance traffic across the plurality of target processing units. 
         [0018]    In some embodiments, the stand-by SLB is configured to replicate the connection data by receiving one or more replication messages from one or more of the target processing units, each of the one or more replication message comprising a session identifier and a target processing unit identifier. In some embodiments, the stand-by SLB is further configured such that, in response to the failure of the primary SLB, the stand-by SLB transmits a connection data synchronization message to at least one of the plurality of target processing units. 
         [0019]    In some embodiments, the connection data comprises a record comprising a first field storing a session identifier identifying a session and a second field storing a target processing unit identifier identifying a target processing unit, and the replicated connection data comprises a record comprising a first field storing the session identifier identifying the session and a second field storing the target processing unit identifier identifying the target processing unit. 
         [0020]    The stand-by SLB may be further operable to: receive a network packet corresponding to a session; use the replicated connection data to determine the target processing unit to which the session is mapped; and forward the network packet to the determined target processing unit. The network packet may be an Internet Protocol (IP) packet that contains an IP header and a payload, wherein the payload contains a transport layer segment having a transport layer header and payload, and data from the IP header and transport layer header identifies the network packet as corresponding to the session. 
         [0021]    In another aspect, the invention provides an improved primary server load balance (SLB) for balancing traffic across a plurality of target processing units. The primary SLB is operable to receive traffic corresponding to a session and access connection data to determine whether the connection data comprises information mapping the session to any of the plurality of target processing units. Advantageously, in response to determining that the connection data does not comprise information mapping the session to any of the plurality of target processing units, the primary SLB selects a particular target processing unit from the plurality of target processing units, updates the connection data so that the connection data will comprise information mapping the session with the selected target processing unit, and transmits to a replication agent running on the selected target processing unit a connection data update message comprising a session identifier identifying the session. The connection update message may comprise a target processing unit identifier for identifying the selected target processing unit. 
         [0022]    In another aspect, the invention provides a computer program product comprising a computer usable medium having a computer readable program code embodied therein, said computer readable program code adapted to be executed to implement a method comprising: accessing connection data, in response to receiving traffic corresponding to a session, to determine whether the connection data comprises information mapping the session to any of the plurality of target processing units; and in response to determining that the connection data does not comprise information mapping the session to any of the plurality of target processing units: (a) selecting a particular target processing unit from the plurality of target processing units and (b) updating the connection data so that the connection data will comprise information mapping the session with the selected target processing unit. Characterized in that the method further comprises, in further response to determining that the connection data does not comprise information mapping the session to any of the plurality of target processing units, transmitting to a replication agent running on the selected target processing unit a connection data update message comprising a session identifier identifying the session. 
         [0023]    In another aspect, the invention provides a computer program product comprising a computer usable medium having a computer readable program code embodied therein, said computer readable program code adapted to be executed to implement a method comprising: replicating connection data used by a primary server load balancer (SLB) immediately in response to a detection that the primary SLB has failed; and using the replicated connection data to balance traffic across a plurality of target processing units. 
         [0024]    In another aspect, the invention provides, a target processing unit, wherein the target processing includes a replication agent. Advantageously, the replication agent is operable to: receive from a primary server load balancer (SLB) a connection data update message comprising a session identifier identifying a session; and store the session identifier in response to receiving the connection data update message, characterized in that: the replication agent is configured to transmit the session identifier to a stand-by SLB in response to receiving a synchronization message. 
         [0025]    The replication agent, in some embodiments, is further operable to: receive from the primary SLB a second connection data update message comprising a second session identifier identifying a second session; and store the second session identifier in response to receiving the second connection data update message, characterized in that: the replication agent is configured such that, in response to receiving the synchronization message, the replication agent transmits to the stand-by SLB a replication message containing the first and second session identifiers. The replication message may further contain an identifier identifying the target processing unit. 
         [0026]    The above and other aspects and embodiments are described below with reference to the accompanying drawings. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0027]    The accompanying drawings, which are incorporated herein and form part of the specification, illustrate various embodiments of the present invention and, together with the description, further serve to explain the principles of the invention and to enable a person skilled in the pertinent art to make and use the invention. In the drawings, like reference numbers indicate identical or functionally similar elements. 
           [0028]      FIG. 1  illustrates a system according to an embodiment of the invention. 
           [0029]      FIG. 2  is a flow chart illustrating a processes according an embodiment of the invention. 
           [0030]      FIG. 3  is a flow chart illustrating a processes according an embodiment of the invention. 
           [0031]      FIG. 4  is a functional block diagram of an SLB apparatus according to some embodiments. 
       
    
    
     DETAILED DESCRIPTION 
       [0032]    Referring now to  FIG. 1 ,  FIG. 1  illustrates a system  100  according to an embodiment of the invention. System  100  includes a primary SLB  114  that is operable to balance session traffic across, among other things, a set of server applications  104 , each of which runs on a processing unit  102 . Also running on each processing unit  102   a  to  102   n , is a replication agent  106 . 
         [0033]      FIG. 2  is a flow chart illustrating a process  200 , according to some embodiments, that is performed by primary SLB  114 . Process  200  may begin in step  202 , where primary SLB  114  receives session traffic (e.g., a packet), via network  120 , transmitted from some device (not shown) connected to network  120 , which may be an Internet Protocol (IP) network, such as the Internet, other network. Thus, in some embodiments, the received traffic is an IP packet, which, as is well known in the art, includes a header and payload. For the sake of simplicity, we shall assume that in step  202  SLB  114  received an IP packet. 
         [0034]    In step  204 , SLB  114  extracts data from the received packet to generate a session identifier (e.g., a data structure, such as a string of bits or other structure, containing data from certain fields of the packet that together identify a session). For example, in step  204 , assuming the IP packet encapsulates a Transmission Control Protocol (TCP) packet or a User Datagram Protocol (UDP) packet, SLB  114  may form a data structure containing: (a) the following items from the IP header of the packet: source address, destination address, version (e.g. IPv4 or IPv6), and protocol (e.g., TCP or UDP) and (b) the following items from the TCP/UDP header: source port and destination port. 
         [0035]    In step  206 , SLB  114  determines whether the packet corresponds to a new session. In the case where the packet is a TCP/IP packet, in some embodiments, SLB  114  determines whether the packet corresponds to a new session by determining if the packet contains a TCP packet that indicates that the TCP packet is a TCP connection request (i.e., the SYN bit of the TCP packet is set). 
         [0036]    In the case where the packet is a UDP/IP packet, in some embodiments, SLB  114  determines whether the packet corresponds to a new session by determining whether the generated session identifier matches a session identifier stored in a connection table  117  stored in storage unit  115 , which may be a volatile (e.g., RAM) or non-volatile storage unit. In some embodiments, connection table  117  stores connection data that includes information mapping sessions to target processing units  102 . For example, the connection data may include a plurality of records, where each record comprises a first field for storing a session identifier identifying a session and a second field for storing a processing unit identifier (e.g., an IP address) associated with a target processing unit  102 . In some embodiments, the records may include additional fields. 
         [0037]    If the traffic corresponds to a new session, then the process proceeds to step  212 , otherwise it proceeds to step  222 . 
         [0038]    In step  212 , SLB  114  selects a target processing unit. For example, a table  121  of targeting processing unit identifiers may be stored in storage unit  115 , and SLB  114  selects a target processing unit in step  212  by, for example, randomly selecting from the table  121  an identifier that identifies a target processing unit. 
         [0039]    In step  214 , SLB  114  forwards the packet received in step  202  to the selected target processing unit  102 . The packet is then received and processed by protocol stack  108  and, if the packet contains application data, then the application data contained in the packet is provided to server application  104 . 
         [0040]    In step  216 , SLB  114  updates connection table  117 . For example, in step  216 , SLB  114  may add a record to table  117 , which record contains in one field the session identifier generated in step  204  and in another field a target processing unit identifier that identifies the target processing unit selected in step  212 . 
         [0041]    Advantageously, in some embodiments, in step  218 , SLB  114  sends to the selected target processing unit a connection data update message that includes the generated session identifier. This message is received by a protocol stack  108  running on the target processing unit  102  and the message is then provided to the replication agent  106  running on the target processing unit  102 . Replication agent  106 , in response to receiving the message, stores in storage unit  109  the session identifier included in the connection update message (step  220 ). Accordingly, a portion of connection table  117  is duplicated in storage unit  109 . This provides the distinct advantage of enabling replication agent  106  to inform stand-by SLB  116  of the active sessions that were handled by primary SLB  114 , as well as the target processing units associated with those active sessions, in the event primary SLB  114  experiences a failure. This information regarding the active sessions enables the cold stand-by SLB  114  to take over the handling of these active sessions. 
         [0042]    While replication agent  106  is shown as being separate and apart from protocol stack  108  (i.e., replication agent  106  is a user application), this was done solely for the sake of illustration. In some other embodiments, replication agent  106  may be part of protocol stack  108  or some other part of the operating system. In the case where, replication agent  108  is a part of protocol stack  108 , step  218  may be unnecessary because (a) the replication agent  106  may obtain from the protocol stack  108  a copy of the packet (or a copy of some portion of the packet) that was forwarded in step  214  and (b) replication agent  106  can be configured to use this information to generate the session identifier in the same manner that SLB  114  generates the session identifier as described above. After replication agent  106  generates the session identifier, agent  106  can store it in storage unit  109 . 
         [0043]    In step  222 , SLB  114  determines the target processing unit that is associated with the generated session identifier. SLB  114 , in some embodiments, makes this determination by selecting the record in connection table  117  that includes a session identifier that matches the session identifier generated in step  204 . This selected record will contain a target processing unit identifier that identifies the target processing unit associated with the generated session identifier. 
         [0044]    In step  224 , SLB  114  forwards the packet received in step  202  to the determined target processing unit  102 . In step  226 , SLB  114  determines whether the packet indicates the end of the session. For example, in the case where the packet is a TCP/IP packet, SLB  114  determines that the packet indicates the end of the session when the FIN bit of the TCP packet is set. If the packet does not indicate the end of the session, the process may proceed back to step  202 , where SLB  114  receives a new packet. If the packet indicates the end of the session, then SLB  114  updates its connection table by removing the record in the table that contains a session identifier that matches the session identifier generated in step  204  (step  228 ). In step  230 , SLB  114  sends to the replication agent on the determined target processing unit a connection data update message that includes the generated session identifier (the message may also include an end-of-session indication). In response to receiving this message, the replication agent  106  removes from storage unit  109  the session identifier that matches the session identifier included in the message (step  232 ). 
         [0045]    Referring now to  FIG. 3 ,  FIG. 3  is a flow chart illustrating a process  300  that shows steps that are preformed in the event primary SLB  114  experiences a failure. Process  300  may begin in step  302 , where SLB monitor  112  determines whether SLB  114  has experienced a failure. If SLB  114  has not experienced a failure, SLB monitor  112  continues monitoring SLB  114 . In the event of a failure, process  300  proceeds to step  304 . 
         [0046]    In step  304 , a control message (a.k.a., a connection data synchronization message) is transmitted to each target processing unit  102   a  to  102   n  (or each target processing unit identified in table  121 ). Each control message may be addressed to the replication agent  106  running on the target processing unit to which the control message was sent, thus, the control message is provided to the replication agent. The control message may be sent by SLB monitor  112  in response to it determining that SLB  114  has failed. While SLB monitor  112  is shown as being separate and apart from stand-by SLB  116 , this is not a requirement as monitor  112  may be a module of SLB  116 . 
         [0047]    In response to receiving the control message, the replication agent  106  transmits to stand-by SLB  116  each of the session identifiers it stored in storage unit  109  if it hasn&#39;t earlier removed the session identifier from the storage unit (step  306 ). For example, replication agent  106  may transmit to SLB  116  a replication message comprising the set of session identifiers. Replication agent  106  may obtain the network address of stand-by SLB  116  from a configuration file stored in storage unit  109  or it may be included in the control message. 
         [0048]    In step  308 , stand-by SLB  116  uses the session identifiers it receives from each replication agent to form connection table  123 , which, at least in part, is a replication of connection table  117 . Thus, connection table  123  is replicated connection data. For example, for each session identifier that SLB  116  receives from a particular replication agent  106 , SLB  116  may add to table  123  a record comprising a first field that stores the session identifier and a second field that stores a target processing unit identifier that identifies the target processing unit on which the replication agent is running, thereby storing information that maps the session identified by the session identifier with the target processing unit identified by the target processing unit identifier. This target processing unit identifier may be included in the replication message sent by the replication agent in step  306 . 
         [0049]    In step  310 , SLB  116  receives session traffic (e.g., a packet), via network  120 , transmitted from some device (not shown) connected to network  120 , and uses the information mapping sessions to target processing units (e.g., connection table  123 ) to forward the packet to the appropriate target processing unit as described above in connection with  FIG. 2 . 
         [0050]    Referring back to  FIG. 1 , while primary SLB  114  is shown as being separate and apart from the target processing units  102 , this is not a requirement. SLB  114 , in fact, may run on one of the target processing units. In this embodiment, when such a target processing unit fails, SLB  114  will fail along with the replication agent  106  running on the failed target processing unit. Accordingly, stand-by SLB  116  will not receive any replication message from the failed replication agent  106 . Thus, connection table  123  will not be an exact duplicate of connection table  117 . However, as long as the other replication agents have not failed, then connection table  123  will contain all of the records from connection table  117  that map a session to a target processing unit other than the failed target processing unit, which means that stand-by SLB will be able to route all of the active sessions that were not mapped to the failed target processing unit  102 . 
         [0051]    Referring now to  FIG. 4 ,  FIG. 4  illustrates a block diagram of an SLB apparatus  400 , according to some embodiments, configured to perform SLB functions described above. As shown in  FIG. 4 , SLB  400  may include: a data processor  402 , which may include one or more microprocessors and/or one or more circuits, such as an application specific integrated circuit (ASIC), Field-programmable gate arrays (FPGAs), etc; a network interface  404  for interfacing with network  110 ; a network interface  405  for interfacing with network  120 ; a storage system  406 , which may include one or more non-volatile storage devices and/or one or more volatile storage devices (e.g., random access memory (RAM)). In embodiments where data processor  402  includes a microprocessor, computer instructions  408  (i.e., software) may be stored in storage system  406 . For example, the computer instructions  408  may be embodied in a computer program stored using a computer readable means, such as, but not limited, to magnetic media (e.g., a hard disk), optical media (e.g., a DVD), memory devices (e.g., random access memory), etc. In some embodiments, computer instructions  408  is configured such that when computer instructions  408  are executed, SLB  400  is operable to perform steps described above (e.g., steps describe above with reference to the flow charts shown in  FIGS. 2 and 3 ). In other embodiments, SLB  400  is configured to perform steps described above without the need for software  408 . That is, for example, data processor  402  may consist merely of one or more ASICs. Hence, the features of the present invention described above may be implemented in hardware and/or software. 
         [0052]    While various embodiments of the present invention have been described above, it should be understood that they have been presented by way of example only, and not limitation. Thus, the breadth and scope of the present invention should not be limited by any of the above-described exemplary embodiments. Moreover, any combination of the above-described elements in all possible variations thereof is encompassed by the invention unless otherwise indicated herein or otherwise clearly contradicted by context. 
         [0053]    Additionally, while the processes described above and illustrated in the drawings are shown as a sequence of steps, this was done solely for the sake of illustration. Accordingly, it is contemplated that some steps may be added, some steps may be omitted, the order of the steps may be re-arranged, and some steps may be performed in parallel.