A communications interface for interfacing between a host system and a state machine includes an event slot, the event slot comprising a plurality of registers including: a write register for writing by the host system, and a read register for reading by the host system, wherein the event slot is addressed from the host system by a single address location permitting the host system to write data to the write register and/or read data from the read register; and wherein the write register and the read register are individually addressable by the state machine.

An interconnect controller for a data processing platform includes a data link layer controller for selectively receiving data packets from and sending data packets to a higher protocol layer, and a physical layer controller coupled to the data link layer controller and adapted to be coupled to a communication link. The physical layer controller operates according to a predetermined protocol selectively at one of a plurality of enhanced speeds that are not specified by any published standard and are separated from each other by the same predetermined amount. In response to performing a link initialization, the interconnect controller performs at least one setup operation to select a speed, and subsequently operates the communication link using a selected speed.

A memory mapping method for coupling a plurality of servers with a PCI express bus is disclosed. The method comprises: configuring an extended memory address on a management host having a memory address; mapping the extended memory address of the management host corresponding to each of the servers to memory addresses of each of the servers respectively by a plurality of non-transparent bridges of the PCI express bus; configuring an extended memory address on each of the servers; and mapping the extended memory address of each of the servers to the memory address and the extended memory address of the management host by the non-transparent bridges, the extended memory address of each of the servers corresponding to the servers and the management host.

The present disclosure relates to embodiments of bus interface systems capable of dealing with the tougher half clock cycle of SREAD commands in the new mobile industry processor interface (MIPI) radio frequency front end (RFFE) version 2.0 standard. With regard to the slave bus controllers of the bus interface systems disclosed herein, the slave bus controller is configured to operate the slave bus driver such that the data bus line is driven towards a minimum voltage level in response to a final clock edge of the clock signal during the bus park subframe. To ensure compliance with the MIPI RFFE version 2.0 standard, the slave bus controller is configured to detect when the data bus line has been driven within a first voltage range after the final clock edge and continue driving the data bus line 16 even after the bus park half clock period is finished.

Disclosed herein are systems and techniques for general purpose input/output (GPIO)-to-GPIO communication in a multi-node, daisy-chained network. In some embodiments, a transceiver may support GPIO between multiple nodes, without host intervention after initial programming. In some such embodiments, the host may be required only for initial setup of the virtual ports. In some embodiments, GPIO pins can be inputs (which may change virtual ports) or outputs (which may reflect virtual ports). In some embodiments, multiple virtual ports may be mapped to one GPIO output pin (with the values OR'ed together, for example). In some embodiments, multiple GPIO input pins may be mapped to one virtual port. For example, multiple GPIO input pin values may be OR'ed together, even if they come from multiple nodes.

Approaches for bridging communication between first and second buses are disclosed. Address translation information and associated security indicators are stored in a memory. Each access request from the first bus includes a first requester security indicator and a requested address. Each access request from the first bus and directed to the second bus is either rejected, or translated and communicated to the second bus, based on the requester security indicator and the security indicator associated with the address translation information for the requested address. Each access request from the second bus to the first bus includes the requested address, and the access request is translated and communicated to the first bus along with the security indicator that is associated with the address translation information for the requested address.

A communications system includes a single wire communications bus and a plurality of slave devices, each of the slave devices associated with a common slave identifier. The single wire communications bus is configured to receive a message comprising data, a slave identifier, and a register map address. A respective one of the plurality of slave devices selectively responds to the message if the slave identifier in the message is the same as the common slave identifier associated with the respective one of the plurality of slave devices and the register map address in the message is the same as the register map address associated with the respective one of the plurality of slave devices.

In accordance with an embodiment, a method of operating a bus interface circuit includes detecting a start sequence on a plurality of input terminals, determining whether a first input terminal and a second input terminal is a data terminal and a clock terminal, respectively, or whether the first input terminal and the second terminal is a clock terminal and a data terminal, respectively. The method also includes routing the first input terminal to a data terminal and the second input terminal to a clock terminal if first input terminal and the second input terminal are determined to be a data terminal and a clock terminal, respectively, and routing the first input terminal to the clock terminal and the second input terminal to the data terminal if first input terminal and the second input terminal are determined to be a clock terminal and a data terminal, respectively.

A method, system and computer program product are provided for implementing coherent accelerator function isolation for virtualization in an input/output (IO) adapter in a computer system. A coherent accelerator provides accelerator function units (AFUs), each AFU is adapted to operate independently of the other AFUs to perform a computing task that can be implemented within application software on a processor. The AFU has access to system memory bound to the application software and is adapted to make copies of that memory within AFU memory-cache in the AFU. As part of this memory coherency domain, each of the AFU memory-cache and processor memory-cache is adapted to be aware of changes to data commonly in either cache as well as data changed in memory of which the respective cache contains a copy.

A universal serial bus device receives a data packet from a host. The universal serial bus device includes a first virtual device, a second virtual device and a data-assigning device. The data-assigning device performs a determination operation, including: transmitting data corresponding to the a first logical address to the first virtual device, when the first logical address is the same as an address of the first virtual device wherein the data corresponding to the first logical address and the first logical address are recorded in the data packet; transmitting data corresponding to the a second logical address to the first virtual device, when the first logical address is the same as an address of the first virtual device wherein the data corresponding to the second logical address and the second logical address are recorded in the data packet.