A system-on-chip (SoC) may be configured to enable a Multi-Chip Daisy Chain Topology using peripheral component interface express (PCIe). The SoC may include a processor, a local memory, a root complex operably connected to the processor and the local memory, and a multi-function endpoint controller. The root complex may obtain forwarding information to configure routing of transactions to one or more PCIe endpoint functions or to the local memory. The root complex may initialize, based on the forwarding information, access between a host and the one or more PCIe endpoint functions. The multi-function endpoint controller may obtain a descriptor and endpoint information to configure outbound portals for transactions to at least one remote host. The multi-function endpoint controller may establish a communication path between the host and a function out of a plurality of functions.

A system-on-chip (SoC) may be configured to enable a Multi-Chip Daisy Chain Topology using peripheral component interface express (PCIe). The SoC may include a processor, a local memory, a root complex operably connected to the processor and the local memory, and a multi-function endpoint controller. The root complex may obtain forwarding information to configure routing of transactions to one or more PCIe endpoint functions or to the local memory. The root complex may initialize, based on the forwarding information, access between a host and the one or more PCIe endpoint functions. The multi-function endpoint controller may obtain a descriptor and endpoint information to configure outbound portals for transactions to at least one remote host. The multi-function endpoint controller may establish a communication path between the host and a function out of a plurality of functions.

Methods and systems are disclosed to aggregate traffic from multiple server devices through a peripheral component interconnect (PCI) hosting device. In one embodiment, the PCI hosting device comprises a network interface to couple the PCI hosting device to a network, a plurality of PCI interfaces, a processing circuit to forward packets, and a power supply to supply power to the PCI interfaces independently from the plurality of server devices. Each of the PCI interfaces is designed to be coupled to one server device to the PCI hosting device, which is registered as a first PCI board of a first server device through a first PCI interface and as a second PCI board of a second server device through a second PCI interface, and the PCI hosting device is designed to forward packets between the network interface and the first server device, and the network interface and the second server device.

Systems and methods are disclosed for efficient management of bus bandwidth among multiple drivers. An example method may comprise: receiving a request from a driver to write data via a bus; reading contents of a random access memory (RAM) at a specified interval of time to determine whether the data written by the driver is accumulated in the RAM; responsive to determining that the data written by the driver is accumulated in the RAM, determining whether a bandwidth of the bus satisfies a bandwidth condition; and responsive to determining that the bandwidth satisfies the bandwidth condition, forwarding, via the bus, a portion of the data written by the driver in the RAM to a device memory of a device.

A communication system includes a camera module and a backend module. The camera module includes an image sensor, a data converter, and a first interface. The image sensor generates a digital signal according to an optical signal. The data converter converts the digital signal into a conversion signal. The first interface transmits the conversion signal. The backend module includes a second interface and a processor. The second interface receives the conversion signal. The processor processes the received conversion signal.

In example implementations, an apparatus is provided. The apparatus includes a riser card body, a first interface, a first 2×8 slot on a surface of the riser card body, and a second 2×8 slot on a same side of the surface of the riser card body as the first 2×8 slot. The first interface includes a first set of fingers and a second set of fingers at an end of the riser card body to connect to a peripheral component interconnect e×press (PC1e) slot of a motherboard. The first 2×8 slot and the second 2×8 slot are positioned perpendicular to the PCIe slot of the motherboard.

Systems, methods and computer software are disclosed for fronthaul. In one embodiment a method is disclosed, comprising: providing a virtual Radio Access Network (vRAN) having a centralized unit (CU) and a distributed unit (DU); and interconnecting the CU and DU over an Input/Output (I/O) bus using Peripheral Component Interconnect-Express (PCIe); wherein the CU and the DU include a PCI to optical converter and an optical to PCI converter.

A configurable multi-function Peripheral Component Interchange Express (PCIe) endpoint controller, integrated in a system-on-chip (SoC), that exposes multiple functions of multiple processing subsystems (e.g., peripherals) to a host. The SoC may include a centralized transaction tunneling unit and a multi-function interrupt manager. The processing subsystems output data to the host via the centralized transaction tunneling unit, which translates addresses provided by the host to a local address of the SoC. Therefore, the centralized transaction tunneling unit enables those processing subsystems to consume addresses provided by the host without the need for software intervention and software-based translation. The SoC may also provide isolation between each function provided by the processing systems. The multi-function interrupt manager enables the endpoint controller to propagate interrupt messages received from the processing subsystems to the host.

An information handling system may perform a quick boot based on a determination that a boot does not require an update to at least one of a firmware and hardware of an information handling system. The information handling system may reboot and may determine whether a boot of the system requires an update to at least one of a firmware and hardware of the information handling system. If the boot does not require an update to the at least one of a firmware and hardware of the information handling system, the information handling system may boot by bypassing one or more basic input/output system (BIOS) power-on self-test (POST) operations.

Systems and method are provided. An illustrative system includes a first compute node having a first processing unit, a first compute node port, and a first peripheral component interconnect bus configured to carry data between the first processing unit and the first compute node port. The system may further include a multi-host network interface controller having a first multi-host port, where the first multi-host port is configured to connect with the first compute node port via a first peripheral component interconnect cable, a network port, where the network port is configured to receive a network interface of a networking cable, and processing circuitry configured to translate and carry data between the first multi-host port and the network port.