A data processing method and apparatus are provided, which relate to the communications field and can reduce a delay and energy consumption for data processing in a data exchange process of an optical network. A specific solution is: obtaining a to-be-processed optical data packet; obtaining an optical label from the to-be-processed optical data packet; determining, according to the optical label, whether an optical signal data frame is a data frame of a preset type; if the optical signal data frame is the data frame of the preset type, obtaining a port corresponding to a label destination address according to an optical label destination address and generating an optical switching instruction; and outputting the to-be-processed optical data packet through a target port according to the optical switching instruction. The data processing method and apparatus are used for data processing.

A data center network includes a plurality of packet-optical switches each at a location in the data center network and each including a switch fabric comprising both a Layer 1 fabric and a packet fabric communicatively coupled to one or more line ports; wherein the plurality of packet-optical switches are communicatively coupled to one another in a topology to form data connectivity in the data center network, and wherein each of the plurality of packet-optical switches is configured to provide the data connectivity through the Layer 1 switch bypassing the packet fabric when the location does not require Layer 2 forwarding in the topology, and provide the data connectivity through the Layer 1 switch and using the packet fabric to provide the data service with multi-point connectivity when the location requires Layer 2 forwarding in the topology.

Systems and methods for efficient prioritized restoration of services implemented in a node in a network utilizing a control plane include, responsive to detecting a fault on a link adjacent to the node, releasing higher priority services affected by the fault immediately via control plane signaling such that the higher priority services mesh restore; maintaining a list of the released higher priority services; tracking mesh restoration of the released higher priority services; and releasing lower priority services based on the tracking, subsequent to the immediate mesh restoration of the higher priority services.

Methodologies and systems that pass signals between control planes of nodes within a FlexE Network also conforming to the Generalized Multiprotocol Label Switching (GMPLS) protocol are described. The signals passed between the control planes conform to the GMPLS protocol and comprise a FlexE Ethernet Group Number and identify at least one Ethernet PHY conforming to the requirements of IEEE 802.3-2015. The Flexible Ethernet Group Number and the at least one Ethernet PHY are stored in non-transitory memory accessible by a node within the FlexE Network. Then, the node configures a FlexE Group based upon the Flexible Ethernet Group Number and the at least one Ethernet PHY.

Embodiments of the present invention relate to the field of information technologies and disclose a link determining method, apparatus, and system for an optical packet switching system, which can reduce optical packet switching costs. The method includes: first, a control manager generates reference optical label information and an enabling signal, and sends the reference optical label information and the enabling signal to a link determining device; then, when the enabling signal is active, the link determining device determines, according to parsed-out actual optical label information and the received reference optical label information, whether an alarm signal is generated, and if it is determined that the alarm signal is generated, sends the alarm signal to the control manager; and finally, the control manager further determines, according to the received alarm signal, whether a link corresponding to the alarm signal is abnormal.

The present invention discloses a method for assigning and processing a label in an optical network. The method includes: learning that a label switched path is required to be established in an optical network; generating a label, in which the label is used for indicating that a first optical channel data unit is multiplexed to a second optical channel data unit; the label includes a tributary slot type indication field that is used for indicating a tributary slot type of the second optical channel data unit, and the label further includes a tributary slot assignment indication field that is used for indicating a tributary slot occupied in the second optical channel data unit into which the first optical channel data unit is multiplexed; and sending the label to a node on the label switched path by a signaling message of GMPLS.

A packet optical network may include a packet optical gateway node that is configured to advertise a segment label to other nodes in the network where the segment label is used by a source node in place of a conventional segment routing label when the source node generates the list of labels included in the header of a data packet while establishing a path through a network. The segment label differs from a conventional segment routing label in that the segment label indicates the L0/L1 device or path as opposed to the L2/L3 device indicated by a conventional segment routing label.

For optical routing, a processor detects an optical data packet communicated over at least one optical subcarrier of a plurality of optical subcarriers. The processor further detects each of the plurality of optical subcarriers over which the optical data packet is carried. The processor generates a label including one or more asserted optical subcarrier values corresponding to each of the plurality of optical subcarriers over which the optical data packet is carried. In addition, the processor routes the optical data packet from the optical switch based on a routing action associated with the label.

In one embodiment, a network server layer provides disjoint channels in response to client-layer disjoint path requests. For example, the network layer can be an optical network, and the client layer may be a packet switching layer (e.g., label switching, Internet Protocol). In one embodiment, a server-layer node receives a client-layer disjoint path request to provide a server-layer channel through a server-layer network. The client-layer disjoint path request includes an identifier corresponding to an existing client-layer path that traverses a current channel through the server-layer network that does not include the server-layer node. The server-layer network determines a particular channel through the server-layer network that is disjoint to the current channel based on route information of the current channel, and then signaling is performed within the server-layer network to establish the particular channel.

Systems and methods for determining minimal spectrum occupancy in routing and wavelength/spectrum assignment (RWA/RSA) in an optical network include performing, for a new demand request, a set of binary operations using a binary representation for each wavelength or portion of spectrum over all links in the optical network; and selecting, based on the set of binary operations, i) a route and ii) one of a) a wavelength and b) one or more portions of spectrum for the new demand request.