Techniques are provided for characterizing and quantifying a sequentiality of workloads using sequentiality profiles and signatures. One exemplary method comprises obtaining telemetry data for an input/output workload; evaluating a distribution over time of sequence lengths for input/output requests in the telemetry data by the input/output workload; and generating a sequentiality profile for the input/output workload to characterize the input/output workload based at least in part on the distribution over time of the sequence lengths. Multiple sequentiality profiles for one or more input/output workloads may be clustered into a plurality of clusters. A sequentiality signature may be generated to represent one or more sequentiality profiles within a given cluster. A performance of data movement policies may be evaluated with respect to the sequentiality signature of the given cluster.

The present disclosure relates to a communication apparatus, a communication method, a program, and a communication system that enable more reliable communication. A bus IF is constituted by a master having an initiative of communication and a slave that communicates with the master under the control of the master. Additionally, the slave is provided with a detection unit that, when detecting a change in level of a signal line representing a declaration of initiation or end of communication by the master, outputs a detection signal indicating that the change in level of the signal line representing a declaration of initiation or end of communication has been detected, and a false detection avoidance unit that invalidates output of the detection signal during a specific time slot set in advance. The present technology can be applied to, for example, a bus IF that performs communication in conformity with the I3C standard.

A function processing service may receive a request to execute source code. The source code may include instructions to perform a function. The function processing service may determine whether at least one hardware acceleration condition has been satisfied for the function. If at least one hardware acceleration condition has been satisfied, the instructions in the source code may be translated into hardware-specific code corresponding to a hardware circuit. The hardware circuit may be configured based on the hardware-specific code, and the hardware circuit may perform the function. The function processing service may then provide the result obtained from the hardware circuit to the requesting entity.

A Serial Peripheral Interface (SPI) master (110) and method therein for transferring data to a peripheral device in a data communication and processing system (100) are disclosed. The SPI master (110) comprises a memory (111) comprising a list of packets, each packet comprises data associated with a time parameter indicating at which time the data is to be transferred to the peripheral device. The time parameter is configurable. The SPI master further comprises a serial transmit and receive unit (112) to transfer the data in the list at a time according to the time parameter associated with the data.

A bus system is provided. The bus system includes a master device, a bus, and a plurality of slave devices electrically connected to the master device via the bus. Each slave device has an alert handshake pin. The alert handshake pins of the slave devices are electrically connected together via an alert-handshake control line. When a first slave device communicates with the master device through the bus, in a first phase of a plurality of phases in each assignment period, the first slave device sets the alert-handshake control line to a first voltage level via the alert handshake pin, wherein the first phase corresponds to the first slave device. In the phases other than the first phase in each assignment period, the alert-handshake control line is at a second voltage level. Each of the phases includes two clock cycles.

Provided herein are systems and methods for performing dynamic adaption and correction for internal delays in devices connected to a common time-multiplexed bus. The methods allow devices to operate reliably at a higher bus frequency by correcting for inherent and unknown delays within the components and in the system by measuring the actual delays using multiple readings with the bus. Intrinsic noise and jitter are used to increase the precision of the measurements, thereby essentially using these uncertainties as self-dithering for increased measurement resolution. During adaption, delays may be adjusted in multiple step sizes to speed adaption time.

A system includes a controller for controlling communication between a first device and a second device connected by way of a communication interface. The controller that is associated with the first device is configured to receive a communication request from a processor of the first device for communicating with the second device. Based on the communication request, the controller is further configured to retrieve a set of instructions from an instruction memory that is associated with the first device. Further, the controller is configured to control the communication interface at each cycle of a clock signal by executing each instruction thus controlling the communication between the first and second devices at each cycle of the clock signal.

Provided are a synchronization control method, a chip, an electronic device and a storage medium. A master device sets a reference time for a plurality of slave devices wirelessly connected to the master device; and determines a target count value K of a connection event and an offset time of a respective slave device for each of the plurality of slave devices. The master device transmits the target count value of the connection event and the offset time to the respective slave device, so that each of the plurality of slave devices performs control based on the target count value of the connection event and the offset time of the respective slave device, so as to perform a task at the reference time.

Embodiments relate to an integrated circuit of an electronic device that coordinates activities with another integrated circuit of the electronic device. The integrated circuit includes an interface circuit and a processor circuit. The interface circuit communicates over a multi-drop bus connected to multiple electronic components. The processor circuit receives an authorization request from the integrated circuit via the interface circuit and the multi-drop bus. The received authorization request relates to authorization to perform an activity on the other integrated circuit. In response to receiving the authorization request, the processor circuit determines whether the other integrated circuit is authorized to execute the activity. In response to determining that the other integrated circuit is authorized to execute the activity, the processor circuit sends, to the other integrated circuit over a configurable direct connection, an authorization signal authorizing the other integrated circuit to execute the activity.

A data interface circuit wherein calibration adjustments for data bit capture are made without disturbing normal system operation, is described. A plurality of DLL capture and delay circuits for sampling a trained optimal sampling point as well as leading and trailing sampling points are defined. A first stream of data bits is input to the data interface circuit and using a first calibration method, a first optimal sampling point for sampling the data bits input is established. A second stream of data bits is input to the data interface circuit during normal system operation. A second calibration method is performed that is different from the first, the second calibration method being performed whereby: at least one reference data path is established for sampling transition edges of the second stream of data bits input to the data interface during normal system operation. Several fringe timing points are sampled, whereby several of the plurality of fringe timing points are associated with each of the transition edges of the second stream of data bits input to the data interface circuit. The drift amount is compared with a drift correction threshold value and the first optimal sampling point is shifted in time by the drift amount to revise the first optimal sampling point.