Disclosed embodiments are directed at systems, methods, and architecture for operating a control plane of a microservice architecture application. The control plane may links a plurality of APIs for the microservice architecture application. The communication between the APIs and the control plane enables the control plane to assess the settings of the APIs compared to stored versions of the settings. The settings and stored versions may each be hashed with a hashing algorithm. The control plane may instruct APIS to update their settings responsive to determining that the settings do not match the stored versions.

Disclosed embodiments are directed at systems, methods, and architecture for operating a control plane of a microservice architecture application. The control plane may links a plurality of APIs for the microservice architecture application. The communication between the APIs and the control plane enables the control plane to assess the settings of the APIs compared to stored versions of the settings. The settings and stored versions may each be hashed with a hashing algorithm. The control plane may instruct APIS to update their settings responsive to determining that the settings do not match the stored versions.

System on a chip, comprising several master pieces of equipment, several slave resources, an interconnection circuit capable of routing transactions between master pieces of equipment and slave resources, and a processing unit at least configured to allow a user of the system on a chip to implement within the system on a chip at least one configuration diagram of this system defined by a set of configuration pieces of information including at least one piece of identification information assigned to each master piece of equipment, The identification pieces of information are intended to be attached to all the transactions emitted by the corresponding master pieces of equipment, the set of configuration pieces of information not being used for addressing the slave resources receiving the transactions and being used to define an assignment of at least one piece of master equipment to at least some of the slave resources.

System on a chip, comprising several master pieces of equipment, several slave resources, an interconnection circuit capable of routing transactions between master pieces of equipment and slave resources, and a processing unit at least configured to allow a user of the system on a chip to implement within the system on a chip at least one configuration diagram of this system defined by a set of configuration pieces of information including at least one piece of identification information assigned to each master piece of equipment, The identification pieces of information are intended to be attached to all the transactions emitted by the corresponding master pieces of equipment, the set of configuration pieces of information not being used for addressing the slave resources receiving the transactions and being used to define an assignment of at least one piece of master equipment to at least some of the slave resources.

Methods, systems, and devices for wireless communications are described. A user equipment (UE) may establish a cellular connection with a base station associated with a cellular radio network. The UE may receive an access policy of the cellular radio network identifying an access preference rule for the UE to adopt for connections to a core network function of the cellular radio network, the access preference rule indicating for the UE to preferentially connect to the core network function via a non-cellular radio network. The UE may determine that a gateway between the non-cellular radio network and the core network function of the cellular radio network is not configured. The UE may determine that a gateway selection policy of the cellular radio network is not configured. The UE may establish a connection to a legacy core network function of a legacy cellular radio network via a legacy gateway.

Methods, systems, and devices for wireless communications are described. A user equipment (UE) may establish a cellular connection with a base station associated with a cellular radio network. The UE may receive an access policy of the cellular radio network identifying an access preference rule for the UE to adopt for connections to a core network function of the cellular radio network, the access preference rule indicating for the UE to preferentially connect to the core network function via a non-cellular radio network. The UE may determine that a gateway between the non-cellular radio network and the core network function of the cellular radio network is not configured. The UE may determine that a gateway selection policy of the cellular radio network is not configured. The UE may establish a connection to a legacy core network function of a legacy cellular radio network via a legacy gateway.

The techniques disclosed herein improve existing systems by receiving, by a packet processor from a control node of the communications network, a request to program operations for processing data packets, the request received with opaque data comprising a state of the control node. The packet processor stores the operations and the opaque data in a data store of the packet processor. The packet processor receives from the control node a subsequent request to retrieve the opaque data. The packet processor sends to the control node the operations and the opaque data that were stored in the data store of the packet processor. The opaque data is not stored in the control node.

The techniques disclosed herein improve existing systems by receiving, by a packet processor from a control node of the communications network, a request to program operations for processing data packets, the request received with opaque data comprising a state of the control node. The packet processor stores the operations and the opaque data in a data store of the packet processor. The packet processor receives from the control node a subsequent request to retrieve the opaque data. The packet processor sends to the control node the operations and the opaque data that were stored in the data store of the packet processor. The opaque data is not stored in the control node.

The present disclosure relates to a baseboard management controller (BMC)-based switch monitoring method, a system, a computer device, and a readable medium thereof. The BMC-based switch monitoring method includes: virtualizing a multi-core BMC into a plurality of logical computers such that each core operates separately; in response to start of a switch, migrating functions of the switch into a first core of the multi-core BMC for start, and monitoring other cores of the multi-core BMC based on a second core of the multi-core BMC; determining, in response to that a new service is received by the switch is detected, whether the new service is a firmware upgrade service; and allocating the new service to the second core in the multi-core BMC for operation, in response to that the new service is the firmware upgrade service.

The present disclosure relates to a baseboard management controller (BMC)-based switch monitoring method, a system, a computer device, and a readable medium thereof. The BMC-based switch monitoring method includes: virtualizing a multi-core BMC into a plurality of logical computers such that each core operates separately; in response to start of a switch, migrating functions of the switch into a first core of the multi-core BMC for start, and monitoring other cores of the multi-core BMC based on a second core of the multi-core BMC; determining, in response to that a new service is received by the switch is detected, whether the new service is a firmware upgrade service; and allocating the new service to the second core in the multi-core BMC for operation, in response to that the new service is the firmware upgrade service.