Patent application number | Description | Published |
20100284404 | SYSTEMS AND METHODS FOR PACKET STEERING IN A MULTI-CORE ARCHITECTURE - Described herein is a method and system for distributing whole and fragmented requests and responses across a multi-core system. Each core executes a packet engine that further processes data packets and data packet fragments allocated to that core. A flow distributor executing within the multi-core system forwards client requests to a packet engine on a core that is selected based on a value generated when a hash is applied to a tuple comprising a client IP address, a client port, a server IP address and a server port identified in the request. The packet engine maintains each element of the tuple and forwards the request to the selected core. The packet engine can also process data packet fragments by assembling the fragments prior to transmitting them to the selected core, or by transmitting the data packet fragments to the selected core. | 11-11-2010 |
20100325391 | SYSTEMS AND METHODS FOR INITIALIZATION AND LINK MANAGEMENT OF NICS IN A MULTI-CORE ENVIRONMENT - The present application is directed towards systems and methods for coordination and management of a shared resource in a multi-core system. In a multi-core system, multiple cores may be utilizing a shared resource. However, internal resources common to the shared resource may need to be initialized by only one core, and independent and uncoordinated initialization by multiple cores may cause errors. The present invention provides systems and methods for coordinating such initialization and use through a handshaking protocol. | 12-23-2010 |
20100325495 | SYSTEMS AND METHOD FOR TRANSACTION STALL DETECTION AND PROPAGATING THE RESULT IN A MULTI-CORE ARCHITECTURE - The present invention is directed towards systems and methods for determining failure in and controlling access to a shared resource in a multi-core system. In some embodiments of a multi-core system, individual cores may share the same resource. Additionally, the resource may occasionally fail or need to be reset, and the period during which the resource is being reset may be non-instantaneous. In an embodiment without coordination between the cores, one core experiencing a failure may reset the resource. During the period in which the resource is resetting, another core may interpret the reset as a failure and reset the resource. As more cores interpret the resets as failures, they will trigger resets, quickly resulting in the resource being constantly reset and unavailable. Thus, in some embodiments, a coordination system may be utilized to determine failure of a shared resource and control resets and access to the shared resource. | 12-23-2010 |
20110280244 | SYSTEMS AND METHODS FOR PACKET STEERING IN A MULTI-CORE ARCHITECTURE - Described herein is a method and system for distributing whole and fragmented requests and responses across a multi-core system. Each core executes a packet engine that further processes data packets and data packet fragments allocated to that core. A flow distributor executing within the multi-core system forwards client requests to a packet engine on a core that is selected based on a value generated when a hash is applied to a tuple comprising a client IP address, a client port, a server IP address and a server port identified in the request. The packet engine maintains each element of the tuple and forwards the request to the selected core. The packet engine can also process data packet fragments by assembling the fragments prior to transmitting them to the selected core, or by transmitting the data packet fragments to the selected core. | 11-17-2011 |
20130304907 | Dynamically Determining How Many Network Packets to Process - A packet quota value, which indicates a maximum number of network packets that a network appliance processes before switching to a different task, is modified. Log data, which includes multiple log entries spanning a time interval, is accessed. Each log entry includes a processing time that indicates how much time the network appliance spent performing network traffic tasks before switching to the different task. The log data is analyzed. Responsive to the analysis indicating that a current state of network traffic is heavier than a maximum state of network traffic that was observed during the time interval, the packet quota value is increased. Responsive to the analysis indicating that the current state of network traffic is lighter than a minimum state of network traffic that was observed during the time interval, the packet quota value is decreased. | 11-14-2013 |
20130336104 | SYSTEMS AND METHODS FOR PROPAGATING HEALTH OF A CLUSTER NODE - The present disclosure describes systems and methods for propagating port state to intermediary devices of a cluster in a static link aggregation environment. The methods and systems include a cluster comprising a plurality of intermediary devices in communication with a network device via a static link aggregation comprising aggregated ports from different intermediary devices of the cluster. A first device of the static link aggregation is configured to detect that a health of the first device is below a predetermined threshold and, responsive to the detection, identify one or more ports in the aggregated ports as down. A second device of the link aggregation is configured to, responsive to the identification, remove the ports from a distribution list for the static link aggregation. Upon detection that a health of a device is above a predetermined threshold, the first device may identify the ports as up. | 12-19-2013 |
20130336337 | SYSTEMS AND METHODS FOR SHARING L2 INFORMATION & MAC BASED FORWARDING - The present application is directed towards sharing data link layer information of network traffic distributed across a cluster of intermediary devices. A method for sharing data link layer information across a cluster includes receiving a request packet at a first intermediary device. The first intermediary device identifies a first set of data link layer information from a data link layer of the request packet. The first intermediary device modifies the request packet for transmission on a common data backplane of the cluster to include the first set of data link layer information in the request packet. The modified request packet includes a second set of data link layer information that differs from the first set of data link layer information at the data link layer. The first intermediary device transmits the modified request packet on the common data backplane of the cluster to other devices of the cluster. | 12-19-2013 |
20150067212 | SYSTEMS AND METHODS FOR INITIALIZATION AND LINK MANAGEMENT OF NICS IN A MULTI-CORE ENVIRONMENT - The present application is directed towards systems and methods for coordination and management of a shared resource in a multi-core system. In a multi-core system, multiple cores may be utilizing a shared resource. However, internal resources common to the shared resource may need to be initialized by only one core, and independent and uncoordinated initialization by multiple cores may cause errors. The present invention provides systems and methods for coordinating such initialization and use through a handshaking protocol. | 03-05-2015 |