Described are techniques including a computer-implemented method comprising appending a HyperText Transfer Protocol (HTTP) header to a HTTP request, wherein the HTTP header includes a source Internet Protocol (IP) address of a client generating the HTTP request, a universally unique identifier (UUID) of the HTTP request, a timestamp, a lifetime, a Universal Resource Locator (URL) of the HTTP request, and a signature. The method further comprises transmitting the HTTP request with the HTTP header to a web server.

An apparatus and method for detecting multiple types of data frames within a single data stream. The data stream is examined to determine if a data frame contained therein is of a first type or a second type. The data frame is processed based on its determined type. The type of data frame is selected from a predetermined set of data frame types. Additionally, the determination is made based on detection of a first portion of the data frame or a second portion of the data frame.

An apparatus and method for detecting multiple types of data frames within a single data stream. The data stream is examined to determine if a data frame contained therein is of a first type or a second type. The data frame is processed based on its determined type. The type of data frame is selected from a predetermined set of data frame types. Additionally, the determination is made based on detection of a first portion of the data frame or a second portion of the data frame.

Various embodiments are directed to techniques for coordinating at least partially parallel performance and cancellation of data access commands between nodes of a storage cluster system. An apparatus may include a processor component of a first node coupled to a first storage device storing client device data; an access component to perform replica data access commands of replica command sets on the client device data, each replica command set assigned a set ID; a communications component to analyze a set ID included in a network packet to determine whether a portion of a replica command set in the network packet is redundant, and to reassemble the replica command set from the portion based if the portion is not redundant; and an ordering component to provide the communications component with set IDs of replica command sets of which the access component has fully performed the set of replica data access commands.

Various embodiments are directed to techniques for coordinating at least partially parallel performance and cancellation of data access commands between nodes of a storage cluster system. An apparatus may include a processor component of a first node coupled to a first storage device storing client device data; an access component to perform replica data access commands of replica command sets on the client device data, each replica command set assigned a set ID; a communications component to analyze a set ID included in a network packet to determine whether a portion of a replica command set in the network packet is redundant, and to reassemble the replica command set from the portion based if the portion is not redundant; and an ordering component to provide the communications component with set IDs of replica command sets of which the access component has fully performed the set of replica data access commands.

A system with co-resident data-plane and network interface controllers embodying a method for network switching of a data packet incoming from a network at a packet input processor portion of a network interface resource comprising the packet input processor, a packet output processor, and a network interface controller, implemented on a chip, to a target entity, is disclosed. Additionally, the system embodying a method for network switching of a data packet outgoing from an internal facing interface of a network interface controller portion of the network interface resource to a network is disclosed.

A system with co-resident data-plane and network interface controllers embodying a method for network switching of a data packet incoming from a network at a packet input processor portion of a network interface resource comprising the packet input processor, a packet output processor, and a network interface controller, implemented on a chip, to a target entity, is disclosed. Additionally, the system embodying a method for network switching of a data packet outgoing from an internal facing interface of a network interface controller portion of the network interface resource to a network is disclosed.

A SOAM virtualization system for a network having at least first and second maintenance entities coupled to each other comprises a network controller coupled to at least one of the first and second maintenance entities through a tunnel for virtualizing a SOAM network function on the at least one of the first and second maintenance entities to which the network controller is coupled. The network controller may be coupled to the first and second maintenance entities through first and second tunnels, respectively. The first maintenance entity may an originator device, and the second maintenance entity may be a destination device, with the network controller virtualizing the SOAM network function on both devices. The network controller may send a packet containing a tunnel header and a SOAM frame via the first tunnel to the originator device, which then sends the packet containing the SOAM frame to the destination device.

A method is disclosed, comprising: receiving a first and a second Internet Protocol (IP) packet at a mesh network node; tagging the first and the second IP packet at the mesh network node based on a type of traffic by adding an IP options header to each of the first and the second IP packet; forwarding the first and the second IP packet toward a mesh gateway node; filtering the first and the second IP packet at the mesh gateway node based on the added IP options header by assigning each of the first and the second IP packet to one of a plurality of message queues, each of the plurality of message queues having a limited forwarding throughput; and forwarding the first and the second IP packet from the mesh gateway node toward a mobile operator core network, thereby providing packet flow filtering based on IP header and traffic type.

A method is disclosed, comprising: receiving a first and a second Internet Protocol (IP) packet at a mesh network node; tagging the first and the second IP packet at the mesh network node based on a type of traffic by adding an IP options header to each of the first and the second IP packet; forwarding the first and the second IP packet toward a mesh gateway node; filtering the first and the second IP packet at the mesh gateway node based on the added IP options header by assigning each of the first and the second IP packet to one of a plurality of message queues, each of the plurality of message queues having a limited forwarding throughput; and forwarding the first and the second IP packet from the mesh gateway node toward a mobile operator core network, thereby providing packet flow filtering based on IP header and traffic type.