A data transmission method, and a related apparatus, are provided. The method include: determining, by a first controller in available transit switches in a data center network, available transit switches respectively transiting m groups of data, where one available transit switch is configured to transit at least one group of the data, and a difference between quantities of groups of the data transited by any two available transit switches does not exceed a second threshold; and instructing, by the first controller, a destination network node to send routing information to the source network node, where the routing information includes an identifier of an available transit switch configured to transit a data group transmitted by the source network node to the destination network node. The foregoing solution can balance load of each transit switch in the data center network, improve a bandwidth resource utilization rate, and reduce a transmission delay.

A source access network device multicasts copies of a packet to multiple core switches, for switching to a same target access network device. The core switches are selected for the multicast based on a load balancing algorithm managed by a central controller. The target access network device receives at least one of the copies of the packet and generates at least metric indicative of a level of traffic congestion at the core switches and feeds back information regarding the recorded at least one metric to the controller. The controller adjusts the load balancing algorithm based on the fed back information for selection of core switches for a subsequent data flow.

A switching fabric loop prevention system includes first slave switch devices in a switching fabric that each automatically determine a first slave switch device role for themselves based on first directly connected device identification information received from a first directly connected device, and second slave switch devices in the switching fabric that each automatically determine a second slave switch device role for themselves based on second directly connected device identification information received from a second directly connected device. A master switch device in the switching fabric then configures each of the first slave switch devices having the first slave switch device role to prevent first type communications that have been received from one of the second slave switch devices having the second slave switch device role from being forwarded to another of the second slave switch devices having the second slave switch device role.

In one embodiment, a method comprises identifying within a network topology, by an apparatus, a plurality of network devices; and establishing by the apparatus, a multiple tree topology comprising a first multicast tree and a second multicast tree, the first and second multicast trees operable as redundant trees for multicast traffic in the network topology, the establishing including: allocating a first of the network devices as a corresponding root of the first multicast tree, allocating a first group of intermediate devices from the network devices as first forwarding devices in the first multicast tree, allocating a second group of intermediate devices as belonging to first leaf devices in the first multicast tree, and allocating terminal devices of the network devices as belonging to the first leaf devices, and allocating a second of the network devices as the corresponding root of the second multicast tree, allocating the second group of intermediate devices as second forwarding devices in the second multicast tree, allocating the first group of intermediate devices as belonging to second leaf devices in the second multicast tree, and allocating the terminal devices as belonging to the second leaf devices.

In one embodiment, a method comprises identifying a fat tree network topology comprising top-of-fabric (ToF) switching devices, an intermediate layer of intermediate switching devices connected to each of the ToF switching devices, and a layer of leaf network devices; and causing a first leaf network device to initiate establishment of first and second redundant multicast trees for multicasting of data packets, including: causing first and second ToF switching devices to operate as roots of the first and second multicast trees according to first and second attribute types, respectively, causing the first leaf network device to select first and second of the intermediate switching devices as first and second flooding relays belonging to the first and second attribute types, respectively, and causing the first and second flooding relays to limit propagation of registration messages generated by the first leaf network device to the first and second ToF switching devices, respectively.

In one embodiment, a method comprises causing, by an apparatus, establishment of first and second multicast trees within one or more underlay switching fabrics of one or more fat tree topologies, the first and second multicast trees comprising first and second multicast roots for multicast transmission to leaf network devices in the respective first and second multicast trees; causing, by the apparatus, establishment of an overlay tunnel between the first and second multicast roots, the overlay tunnel independent and distinct from the first and second multicast trees; causing the first multicast root to multicast transmit, via the first multicast tree, a data packet having been transmitted to the first multicast root; and causing the first multicast root to unicast transmit the data packet to the second multicast root via the overlay tunnel, for multicast transmission of the data packet by the second multicast root via the second multicast tree.

A switching fabric loop prevention system includes first slave switch devices in a switching fabric that each automatically determine a first slave switch device role for themselves based on first directly connected device identification information received from a first directly connected device, and second slave switch devices in the switching fabric that each automatically determine a second slave switch device role for themselves based on second directly connected device identification information received from a second directly connected device. A master switch device in the switching fabric then configures each of the first slave switch devices having the first slave switch device role to prevent first type communications that have been received from one of the second slave switch devices having the second slave switch device role from being forwarded to another of the second slave switch devices having the second slave switch device role.

Apparatuses and methods include receiving, by a switch, a packet; creating, by the switch, one or more copies of the packet; selecting, by the switch, a plurality of servers; and separately forwarding, by the switch, the packet and the one or more copies to the plurality of servers.

A network box accepts packets from a network in ingress ports of a first tier of leaf switches, adaptively routes the packets from the leaf switches to a second tier of spine switches within the network box, statically routes the packets from the spine switches to designated egress ports of the leaf switches, and transmits the packets from the designated egress ports into the network.

Techniques for providing a non-blocking fabric in a network are described. A network controller determines the network requirement for various network traffic types on the network and determines the allocation of resources across the network needed to establish a midlay, including midlay components on the network. The network controller then establishes the midlay on the network according to the determined allocation. At least one of the midlay components is a virtually non-blocking fabric for high-priority traffic or fully non-blocking fabric for deterministic traffic.