A method for dynamically allocating upload bandwidth to consumer nodes by a resource node that are communicatively connected by a channel-swarm in a peer-to-peer network. The method comprises periodically computing a dynamic quota value to determine a number of acceptable connections between the resource node and one or more of the consumer nodes connected by the channel-swarm; and allocating an available upload bandwidth to the one or more of the consumer nodes in the channel-swarm based on the computed dynamic quota value.

A system and method that enables editing capabilities of content accessed from a content management server using any type of locally-installed application is provided. In some embodiments, a content management server stores documents in a cache on the user's computer. Documents can thus be accessed and edited using the document in the local file system of the user. For example, users may open, reserve or lock, download, and edit documents with a single user action such as a click. Advantageously, the teachings of embodiments as described can be used in conjunction with content management systems for improving the user experiences involved in editing documents by providing an ‘instant’ and ‘seamless’ editing experience substantially equivalent to editing files on a local hard disk.

A system and method for seamless access to remotely manage documents using synchronization of locally stored documents are provided. In some embodiments, a content management server stores documents in a cache on the user's computer. Documents can thus be accessed and edited using the document in the local file system of the user and synchronized with the content management server asynchronously to access the documents on the local files system. Advantageously, the teachings of embodiments as described can be used in conjunction with content management systems for providing faster access to documents in conjunction with editing and for enabling offline work on such documents.

Techniques for dynamic resource movement in heterogeneous computing environments including provider substrate extensions are described. A dynamic resource movement service of a provider network monitor conditions of heterogeneous computing environments, including provider substrate extensions of the cloud provider network, to evaluate customer-provided movement policy conditions governing when to move customer application resources from these environments, where to move the resource to, and/or how to move the customer application resources. The customer-provided movement policy conditions may be based on a variety of factors, such as a latency between end-users of the customer application and the application itself.

A multi-access edge computing (MEC) node of a MEC network may receive, from a user device a first request to communicate via a peer-to-peer connection routed through a MEC network. The MEC node may identify one or more candidate devices that are available to communicate with the user device via the peer-to-peer connection. The MEC node may provide, to a particular candidate device of the one or more candidate devices, a second request to communicate via the peer-to-peer connection. The MEC node may receive, from the particular candidate device, an acceptance to communicate via the peer-to-peer connection. The MEC node may route data between the user device and the particular candidate device via the peer-to-peer connection.

A multi-access edge computing (MEC) node of a MEC network may receive, from a user device a first request to communicate via a peer-to-peer connection routed through a MEC network. The MEC node may identify one or more candidate devices that are available to communicate with the user device via the peer-to-peer connection. The MEC node may provide, to a particular candidate device of the one or more candidate devices, a second request to communicate via the peer-to-peer connection. The MEC node may receive, from the particular candidate device, an acceptance to communicate via the peer-to-peer connection. The MEC node may route data between the user device and the particular candidate device via the peer-to-peer connection.

A system and method that enables editing capabilities of content accessed from a content management server using any type of locally-installed application is provided. In some embodiments, a content management server stores documents in a cache on the user's computer. Documents can thus be accessed and edited using the document in the local file system of the user. For example, users may open, reserve or lock, download, and edit documents with a single user action such as a click. Advantageously, the teachings of embodiments as described can be used in conjunction with content management systems for improving the user experiences involved in editing documents by providing an instant and seamless editing experience substantially equivalent to editing files on a local hard disk.

The present invention relates to system and methods for segmented data transmission. One example comprises steps of: connecting a plurality of computerized devices to each other; designating at least one master device from the plurality of computerized devices; designating remainder of devices as slave devices; producing a content originated from said at least one master device; segmenting the content into a plurality of data-streams; transmitting at least one data-stream of said plurality of data-streams to slave devices; uploading said plurality of data-streams to a server-computer; assembling said plurality of data-streams into said content.

Some embodiments of the present application disclose a method, system, device, and server for determining transmission quality of a node, wherein the method comprises: acquiring data transmission information of a preset number of data slices transmitted from a first peer node to a second peer node and before a first slice in the data slices (S11); determining, according to the data transmission information, a data transmission success rate factor corresponding to the first slice (S12); determining, according to the data transmission information, a transmission speed factor corresponding to the first slice (S13); and determining, according to the transmission success rate factor and the transmission speed factor, transmission quality of data transmission from the first peer node to the second peer node (S14). The technical solutions provided by embodiments of the present application can timely judge the transmission quality of the node and improve the transmission efficiency of P2P.

A controller (16) for controlling a player (14), the player (14) being configured to: play back segments of a data stream stored in a buffer (12), and request at least one segment of the data stream to be transferred from a peer-to-peer cache (10) to the buffer (12) whenever an amount of data pending for playback in the buffer (12) is less than a data threshold, wherein the peer-to-peer cache (10) stores segments of a data stream in a format adapted for transfers in a peer-to-peer network; wherein the controller (16) is configured to: be set into a dynamic mode wherein the controller (16) alternately sets the data threshold to first value and to a second value greater than the first value, and into be set into a static mode wherein the controller (16) maintains the data threshold at the second value; and switch between the dynamic mode and the static mode whenever predefined conditions are met.