An embodiment processing system comprises a queued SPI circuit, which comprises a hardware SPI communication interface, an arbiter and a plurality of interface circuits. Each interface circuit comprises a transmission FIFO memory, a reception FIFO memory and an interface control circuit. The interface control circuit is configured to receive first data packets and store them to the transmission FIFO memory. The interface control circuit sequentially reads the first data packets from the transmission FIFO memory, extracts at least one transmission data word, and provides the extracted word to the arbiter. The interface control circuit receives from the arbiter a reception data word and stores second data packets comprising the received reception data word to the reception FIFO memory. The interface control circuit sequentially reads the second data packets from the reception FIFO memory and transmits them to the digital processing circuit.

Some examples relate to a method. In the method, a write transaction is routed from a master device to a slave device through a communication path. The communication path includes a first bridge and a second bridge downstream of the first bridge. The first bridge and the second bridge are coupled to one another via an interface structure. The first bridge sets a write busy signal on the communication path when the write transaction is processed by the first bridge; and in response to the first bridge setting the write busy signal, the second bridge holds the write busy signal until the write transaction has been received by the slave device. Upon the slave device receiving the write transaction, the second bridge resets the write busy signal to propagate the reset write busy signal back to the master device through the first bridge.

The systems and methods for bus ownership in a system power management interface (SPMI) bus may include two or more masters on the SPMI bus, and bus ownership may be passed between masters. The current owner of the bus is responsible for providing a clock signal on the clock line of the SPMI bus. To avoid problems caused by ringing of the clock signal being sent on a conductor that exceeds the SPMI specification, the original master (from whom bus ownership is being transferred) holds the clock line of the SPMI bus at a logical low for a clock delay value that is based on conductor length.

Disclosed are a module assembly and a multi-master communication method thereof, and more particularly, a module assembly including a plurality of modules capable of transmitting/receiving data by forming an open drain based one-wire communication bus upon mutual combination, in which at least one module requiring the data transmission among the plurality of modules performs first declaration for a transmission intention by outputting a low signal within a predetermined first arbitration time when at least one module is in an on state by sensing the one-wire communication bus state, at least one module performing the first declaration for the transmission intention performs second declaration for the transmission intention by outputting a high signal within a second arbitration time, and a module which outputs the high signal last within the second arbitration time secures final bus occupation.

A method of transferring data from a first bus to a second bus across an asynchronous interface using an asynchronous bridge. The bridge comprises a bus slave module, connected to the first bus, comprising a forward-channel initiator in a first power and/or clock domain; and a bus master module, connected to the second bus, comprising a forward-channel terminator in a second power and/or clock domain. The forward-channel initiator and terminator are in communication to form a forward lockable mutex for arbitrating access to signals used to transfer data from the first domain to the second domain. If the mutex is locked, a forward data channel is used to transfer data between the domains. Otherwise if the mutex is unlocked, the forward channel initiator toggles a status request signal and the forward channel terminator toggles a status acknowledge signal in response, the mutex thereby becoming locked.

A system and method for executing instructions in a constrained order. In some embodiments, the method includes: sending by a host, a first instruction, followed by an order-constrained instruction, followed by a second instruction; receiving, by a target, the first instructions, the order-constrained instruction, and the second instruction; and executing, by the target, the first instruction; the order-constrained instruction, after executing the first instruction; and the second instruction, after executing the order-constrained instruction.

Channel availability information associated with data traffic between a Master and a Slave within an interconnection network (“ICN”) in a System-on-Chip (“SoC”) is monitored by a channel performance monitor in order to improve the performance of the ICN. The channel availability information is fed back to certain Masters to control their data traffic into the ICN. The channel performance monitor monitors and evaluates the data traffic handled by switches within the ICN that can potentially interfere with communication paths between particular Masters and Slaves, and control the initiation of data traffic from predetermined Masters.

A system and method for efficiently arbitrating traffic on a bus. A computing system includes a fabric for routing traffic among one or more agents and one or more endpoints. The fabric includes multiple arbiters in an arbitration hierarchy. Arbiters store traffic in buffers with each buffer associated with a particular traffic type and a source of the traffic. Arbiters maintain a respective urgency counter for keeping track of a period of time traffic of a particular type is blocked by upstream arbiters. When the block is removed, the traffic of the particular type has priority for selection based on the urgency counter. When arbiters receive feedback from downstream arbiters or sources, the arbiters adjust selection priority accordingly. For example, changes in bandwidth requirement, low latency tolerance and active status cause adjustments in selection priority of stored requests.

A semiconductor device is configured so that two or more master devices access a slave device via a bus. The semiconductor device includes: a priority generation circuit that generates a priority based on a transfer amount between a specific master device and a specific slave device; and an arbitration circuit that performs an arbitration based on the priority when competition of the accesses occurs.

Embodiments of systems and methods for high-availability (HA) management networks for High Performance Computing (HPC) platforms are described. In some embodiments, an HPC platform may include a first Baseboard Management Controller (BMC) having a first network port; and a hardware accelerator comprising a second BMC having a second network port, where at least one of: (a) the first BMC is configured to share the first network port with the second BMC in response to a determination that the second network port has failed or has insufficient bandwidth, or (b) the second BMC is configured to share the second network port with the first BMC in response to a determination that the first network port has failed or has insufficient bandwidth.