Mechanisms for providing multi-homing, comprising: a memory device; and at least one hardware processor coupled to the memory device and configured to: intercept a connection between a device and a server using a proxy; establish a first connection between the device and the proxy; create multiple second connections between the proxy and the server, wherein at least two of the multiple second connections use different connection types; receive a request for blocks of data from the device using the first connection; allocate the blocks of data across the multiple second connections; request the blocks of data from the server using the multiple second connections as allocated; receive the blocks of data from the server using the multiple second connections; and forward the blocks of data to the device using the first connection.

A receiving network node (210) configured to select from received packets differing by time of initial transmission from a sending network node (230), and accepting for transmission, based on initial transmission time, the selected packets to an application layer (740). An internetworked processor node configured to: (a) read a sequence number and an originator identifier of a received packet message (810); (b) compare a stored highest sequence number associated with the originator identifier with the received packet sequence number (820); (c) if the received packet sequence number is less than or equal to the stored highest sequence number associated with the originator identifier, then discard (840) the received packet; and (d) if the received packet sequence number is greater than the stored highest sequence number associated with the originator identifier, then deliver (860) the message of the received packet to an application based on an upper layer protocol.

A client and a server negotiate a version of a protocol that supports multiplexed connections using a connectionless transport layer protocol, such as a QUIC protocol that is supported for a connection between the client and the server. The connection can support one or more streams. The client embeds a first extension in a cryptographic handshake. The first extension includes a structure that indicates a set of protocols supported by the client at a set of layers. The client and the server then concurrently negotiate a subset of the protocols and a subset of the layers that are supported by the client and the server. Data is tunneled from the subset of the protocols and the subset of the layers over the connection between the client and the server. The data is tunneled using stream frames that include the data, a first field having a value indicating a layer type, and a second field having a value indicating a protocol type.

Method of transmission of data between a server and a client, said transmission using a multihoming protocol, as SCTP, over a network comprising at least one principal link and one secondary link connecting the server and the client, said method comprising the steps of: a) set-up of a connection between the server and the client; b) allocation of a bandwidth over the principal link to the transmission of data from the server to the client; c) transmission of data from the server to the client over the principal link as long as said allocated bandwidth is not fully used; and d) if the allocated bandwidth has been fully used, transmission of data from the server to the client over the secondary link.

Systems and methods for classifying network traffic to use cellular network slices based on application parameters are described. In some embodiments, an Information Handling System (IHS) may include: a processor and a memory coupled to the processor, the memory having program instructions stored thereon that, upon execution, cause the IHS to: receive a plurality of packets originated by a single application; classify each of the plurality of packets into one of a plurality of network slices based upon network parameters of the application, where each of the network slices is associated with a weight, and for each given packet among the plurality of packets, add a weight to a header portion of the given packet, where the weight corresponds to the given packet's classification.

A module has switchable operation states. A first switching unit switches the module between a first operation state and a second operation state. A first interface switches between sending signals to another module which has switchable operation states and receiving signals from the other module. The first interface sends a first signal to the other module when the module is in the first operation state, sends a second signal to the other module when the module is to be switched into the second operation state, and receives signals from the other module when the module is in the second operation state. A second interface communicates with the other module. When the second interface receives a response of the other module to the second signal, the first switching unit switches the module into the second operation state. The reliability of module switching is improved in an embodiment.

Various embodiments of methods and apparatus for load balancing requests such that target resources serve a single client are described. In at least some embodiments, a single resource, such as a compute instance, is assigned to only one client, and that single resource is used for all subsequent connections and communications from that client. Some embodiments comprise a resource selection system which provides identifying information of an available resource, in order for a connection to be established between the client and the resource. The resource selection system then removes that identifying information from its memory. In some of these embodiments, a routing layer interfaces with the resource selection system to establish the connection between the client and the available resource. When a client is assigned to a resource, other clients may be prevented from establishing connections with the resource.

A system and method for locating a mobile device is disclosed. In a first embodiment, a system of provisioning multiple-tired location services is disclosed. The system includes a plurality of ultra-wideband devices forming a first level of a wireless infrastructure network and a plurality of location capable beacon devices forming a second level of the wireless infrastructure network. In a second embodiment, a method of providing location based services using location capable beacon devices is disclosed. In other embodiments a system for generating real-time safety alerts is further disclosed.

A computer of a data processing system includes a software encryption engine and path circuitry that initially provides one or more paths for conveying data of storage I/O requests to and from a storage device, the paths including an encrypting path having a hardware encrypting component. According to a failover technique, in a first operating state, (a) the data of the storage I/O requests is conveyed via the encrypting path with encryption and decryption of the data being performed by the hardware encrypting component, and (b) monitoring is performed for occurrence of an event indicating that the hardware encrypting component has become unavailable for encrypting and decrypting the data of the storage I/O requests. Upon occurrence of the event, if the path circuitry provides a non-encrypting path for conveying the data of the storage I/O requests to and from the storage device, then operation is switched to a second operating state in which the data of the storage I/O requests is conveyed via the non-encrypting path and is encrypted and decrypted by the software encryption engine. A failback technique provides for reverting to hardware-assisted encryption under proper circumstances.

A method and a first network node for managing a Stream Control Transmission Protocol, “SCTP” is disclosed. The first network node handles a plurality of computational resources for executing procedures of SCTP at least partially simultaneously. The first network node provides a single instance procedure for managing the SCTP association and multi-instance procedures for managing the SCTP association. Furthermore, the first network node provides a control procedure, being the single instance procedure, for managing flow and acknowledgement of SCTP packets at the SCTP association. The first network node provides the following multi-instance procedures an outgoing transmission procedure for managing and transmitting the SCTP packets from the retransmission buffer, an incoming reception procedure for receiving and managing the SCTP packets, and an outgoing reception procedure for managing and transmitting Upper Layer Protocol frames to the upper layer.