A programmable circuit that is configured to control a target memory is used to detect a number and types of a plurality of target events in real time. In the event a trigger condition associated with a triggered preset state in a plurality of preset states is satisfied by the detected number and types of the plurality of target events, an action execution circuit module corresponding to the triggered preset state is selected to run, where the trigger condition is based on at least one of the plurality of target events. Using the action execution circuit module corresponding to the triggered preset state, one or more actions corresponding to the triggered preset state are executed, where at least one of the one or more actions corresponding to the triggered preset state is associated with controlling the target memory.

In an embodiment a method for operating a processing system includes programming, by a microprocessor during a CAN FD Light data transmission phase, a control register of a Serial Peripheral Interface (SPI) communication interface of the processing system in order to activate a master mode; generating, by the microprocessor during the CAN FD Light data transmission phase, a transmission CAN FD Light frame; storing, by the microprocessor during the CAN FD Light data transmission phase, the transmission CAN FD Light frame to a memory; and activating, by the microprocessor during the CAN FD Light data transmission phase a first DMA channel so that the first DMA channel sequentially transfers the transmission CAN FD Light frame from the memory to a transmission shift register in the SPI communication interface.

A technique includes holding a bus interface of a removable device that is inserted into a connector of a computer system in a state to prevent the device from communicating with a communication link. The communication link is coupled to the connector and is associated with operating system access to the device. The method includes a baseboard management controller communicating with the device using a channel other than the communication link while the bus interface of the device is held in the state; the baseboard management controller performing a security operation corresponding to the device based on the communication with the device using the channel; and the baseboard management controller releasing the bus interface of the device from the state to allow the device to communicate with the communication link in response to the baseboard management controller completing the security operation.

A method for managing communications involving a lockstep processing comprising at least a first processor and a second processor can include receiving, at a data synchronizer, a first signal from a first device. The method can also include receiving, at the data synchronizer, a second signal from a second device. In addition, the method can include determining, by the data synchronizer, whether the first signal is equal to the second signal. When the first signal is equal to the second signal, the method can include transmitting, by the data synchronizer, the first signal to the first processor and the second signal to the second processor. Specifically, in example embodiments, transmitting the first signal to the first processor can occur synchronously with transmitting the second signal to the second processor.

Embodiments herein describe techniques for separating data transmitted between I/O functions in an integrated component and a host into separate data paths. In one embodiment, data packets are transmitted using a direct data path that bypasses a switch in the integrated component. In contrast, configuration packets (e.g., hot-swap, hot-add, hot-remove data, some types of descriptors, etc.) are transmitted to the switch which then forwards the configuration packets to their destination. The direct path for the data packets does not rely on switch connectivity (and its accompanying latency) to transport bandwidth sensitive traffic between the host and the I/O functions, and instead avoids (e.g., bypasses) the bandwidth, resource, store/forward, and latency properties of the switch. Meanwhile, the software compatibility attributes, such as hot plug attributes (which are not latency or bandwidth sensitive), continue to be supported by using the switch to provide a configuration data path.

An apparatus and method for controlling an interface between a plurality of processors in an electronic device are disclosed. The electronic device may include: a first integrated circuit; a second integrated circuit; and a Peripheral Component Interconnect Express (PCIe) interface interconnecting the first integrated circuit and the second integrated circuit, wherein the first integrated circuit may be configured to identify the required latency level associated with a service provided by the electronic device, and restrict the use of at least one power mode among a plurality of power modes supported by the PCIe interface, based on the required latency level associated with the service. Additional embodiments are possible.

A chiplet system can include a Serial Peripheral Interface (SPI) bus for communication. A controller or primary device coupled to the SPI bus can generate a message with read or write instructions for one or more secondary devices. In an example, the primary device can be configured to use information on a data input port or data input bus to determine a communication status of one or multiple secondary devices on the bus.

A chiplet system can include a Serial Peripheral Interface (SPI) bus for communication. A controller or primary device coupled to the SPI bus can generate a message with read or write instructions for one or more secondary devices. In an example, the primary device can be configured to use information on a data input port or data input bus to determine a communication status of one or multiple secondary devices on the bus.

A device comprising: a data interface comprising: a data input for receiving a data signal; a clock input for receiving a clock signal for clocking the data signal; and a timing input for receiving a first timing signal having a first frequency; and a timing signal generator configured to generate, based on the first timing signal and the data signal, a second timing signal having a second frequency, the first frequency being a integer multiple of the second frequency, a phase of the second timing signal being aligned with an event in the data signal.

A system comprises an interposer including interconnect and multiple chiplets arranged on the interposer. Each chiplet includes multiple chiplet input-output (I/O) channels interconnected to I/O channels of other chiplets by the interposer; a chiplet I/O interface for the chiplet I/O channels that includes multiple interface layers; and initialization logic circuitry configured to advance initialization of the chiplet interface sequentially through the interface layers starting with a lowest interface layer.