Constraint based command invocations are dynamically queued in a cloud queue such that aspects of remote user devices may be remotely controlled with reduced exposure to inconvenient remotely issued commands. By monitoring conditions that may trigger command invocations, verifying rules of associated constraints prior to queuing command invocations, evaluating parameters to prioritize command invocations in a dynamic issuing order within cloud queue, examining factors and reverifying previously verified rules when determining whether to transmit a command from an command invocation located at a transmission position of the cloud queue, systems and methods herein provide a constrained environment within which user devices may be remotely controlled relatively free from unexpected cloud caused encumbrances during inopportune moments.

Disclosed are a method for submitting data in sequence, a network device, a terminal device and a computer storage medium. The method comprises: when a bearer of data streams is transferred from a first network device to a second network device, the first network device sends first instruction information to the second network device, wherein the first instruction information is used for instructing the second network to transmit the transferred data streams on a new bearer in sequence.

A method and apparatus are disclosed to manage the enhanced medium access control-e (MAC-e) and enhanced MAC-es resources and respective variables for the enhanced dedicated channel (E-DCH) in the enhanced Cell_FACH state. Due to the nature of the E-DCH transmission in the uplink (UL) in the Cell_FACH state and the fact that a wireless transmit/receive unit (WTRU) might set up and release the E-DCH resources more frequently, methods to deal with the TSN numbering are described.

Constraint based command invocations are dynamically queued in a cloud queue such that aspects of remote user devices may be remotely controlled with reduced exposure to inconvenient remotely issued commands. By monitoring conditions that may trigger command invocations, verifying rules of associated constraints prior to queuing command invocations, evaluating parameters to prioritize command invocations in a dynamic issuing order within cloud queue, examining factors and reverifying previously verified rules when determining whether to transmit a command from an command invocation located at a transmission position of the cloud queue, systems and methods herein provide a constrained environment within which user devices may be remotely controlled relatively free from unexpected cloud caused encumbrances during inopportune moments.

A plurality of packets are received by a packet processing device, and the packets are distributed among two or more packet processing node elements for processing of the packets. The packets are assigned to respective packet classes, each class corresponding to a group of packets for which an order in which the packets were received is to be preserved. The packets are queued in respective queues corresponding to the assigned packet classes and according to an order in which the packets were received by the packet processing device. The packet processing node elements issue respective instructions indicative of processing actions to be performed with respect to the packets, and indications of at least some of the processing actions are stored. A processing action with respect to a packet is performed when the packet has reached a head of a queue corresponding to the class associated with the packet.

A network overlay system can include a data transport module having a network interface and a translation module configured to generate offload processing addresses for the network packet data; a system bus; at least one host processor connected to the system bus; and at least one offload processor module coupled to the system bus and configured to receive network packet data associated. Offload processor modules include processing circuits associated with at least one of the offload processing addresses that are configured to encapsulate the network packet data for transport on a logical network or decapsulate the network packet data received from the logical network. The offload processing circuits encapsulate or decapsulate network packet data independent of any host processor.

Aspects of the disclosure provide a method for reordering. The method includes receiving, by a terminal device, a stream of data units from a wireless network. The data units have respective sequence numbers. Further, the method includes reordering at a protocol layer in a protocol stack, the data units for a next process according to the sequence numbers, determining a dependency relationship of a data unit to one or more missing data units that have sequence numbers prior to the data unit, and advancing, out of order of the sequence numbers, the data unit to the next process when the data unit is independent of the one or more missing data units.

Techniques and architectures to provide trace functionality. Trace record data is received from a plurality of client threads executed by one or more processors. The trace record data is stored in a plurality of chunks maintained in an in-use list. The in-use list has a chunk for individual use by the corresponding client threads. Chunks in the in-use list are moved to a completed queue when a chunk in the in-use list is substantially full. A chunk from a free list is placed in the in-use list to replace removed chunks. The chunks from the completed queue are stored in at least one memory device.

Seamless path switching is made possible in a multi-hop network based upon stream marker packets and additional path distinguishing operations. A device receiving out-of-order packets on the same ingress interface is capable of determining a proper order for the incoming packets having different upstream paths. Packets may be reordered at a relay device or a destination device based upon where a path update is initiated. Reordering packets from the various upstream paths may be dependent upon a type of service associated with the packet.

A transmitting device comprising: a transmitter for transmitting data to a receiving device; and a controller for formatting the data to be transmitted from the transmitter, by dividing the data amongst a plurality of packets. The controller is configured to package each respective one of the packets with only a respective portion of an index sequence as an identifier field for distinguishing between the packets within the sequence, wherein at least one of the portions is alone insufficient to identify its respective packet. The controller is further configured to control the transmitter to transmit the packets including the respective portions of the index sequence, ordered such that the index sequence repeats cyclically over the transmission of the packets; thereby enabling the receiving device to determine a respective position in the index sequence for each of the packets by referencing a plurality of the portions together, and to thereby identify the packets.