Embodiments of systems and methods for platform framework arbitration are described. In some embodiments, an Information Handling System (IHS) may include a processor and a memory coupled to the processor, the memory having program instructions stored thereon that, upon execution, cause the IHS to: provide, from a platform framework to an arbitration object via an Application Programming Interface (API), a plurality of runtime objects; receive, by the platform framework from the arbitration object via the API, an indication of an arbitration result with respect to the plurality of objects; and convey, from the platform framework to a participant via the API, the indication of the arbitration result.

A queuing requester for access to a memory system is provided. Transaction requests are received from two or more requestors for access to the memory system. Each transaction request includes an associated priority value. A request queue of the received transaction requests is formed in the queuing requester. Each transaction request includes an associated priority value. A highest priority value of all pending transaction requests within the request queue is determined. An elevated priority value is selected when the highest priority value is higher than the priority value of an oldest transaction request in the request queue; otherwise the priority value of the oldest transaction request is selected. The oldest transaction request in the request queue with the selected priority value is then provided to the memory system. An arbitration contest with other requesters for access to the memory system is performed using the selected priority value.

An example method of image signal processing, comprising at least one of, receiving a set of high priority signals, receiving a set of low priority signals, reconfiguring a first portion of a pipeline to route the high priority signals through an in-line mode process and reconfiguring a second portion of the pipeline to route the low priority signals through an offline mode process.

In an embodiment, a method includes: receiving, with a first buffer of a first error compactor unit (ECU), a first error packet associated with a first circuit; receiving, with the first buffer, a second error packet associated with a second circuit; transmitting a first reading request for reading the first error packet; receiving the first reading request with an arbiter of an error aggregator unit (EAU) of a central error management circuit; in response to receiving the first reading request, reading the first error packet from the first buffer, transmitting the first error packet to a controller of the central error management circuit, and transmitting a first acknowledgement to the first ECU; receiving the first acknowledgement with the first ECU; and in response to receiving the first acknowledgement, transmitting a second reading request for reading the second error packet.

A dual-model memory interface of a computing system is provided, configurable to present memory interfaces having differently-graded bandwidth capacity to different processors of the computing system. A mode switch controller of the memory interface controller, based on at least an arbitration rule written to a configuration register, switches the memory interface controller between a narrow-band mode and a wide-band mode. In each mode, the memory interface controller disables either a plurality of narrow-band memory interfaces of the memory interface controller according to a first bus standard, or a wide-band memory interface of the memory interface controller according to a second bus standard. The memory interface controller virtualizes a plurality of system memory units of the computing system as a virtual wide-band memory unit according to the second bus standard, or virtualizes a system memory unit of the computing system as a virtual narrow-band memory unit according to the first bus standard.

Devices and techniques for programmable atomic operator resource locking are described herein. A request for a programmable atomic operator (PAO) can be received at a memory controller that includes a programmable atomic unit (PAU). Here, the request includes an identifier for the PAO and a memory address. The memory addressed is processed to identify a lock value. A verification can be performed to determine that the lock value indicates that there is no lock corresponding to the memory address. Then, the lock value is set to indicate that there is now a lock corresponding to the memory address and the PAO is invoked based on the identifier for the PAO. In response to completion of the PAO, the lock value is set to indicate that there is no longer a lock corresponding to the memory address.

Devices and techniques for asynchronous pipeline merging are described herein. An apparatus, includes a memory controller, which includes merge circuitry; where the memory controller chiplet is configured to perform operations including those to: perform a bitwise logical operation on a first logging bit vector and a second logging bit vector to obtain a result vector, wherein the first logging bit vector is associated with a first pipeline and the second logging bit vector is associated with a second pipeline, and wherein bits in respective index positions of the first and second logging bit vectors represent transactions; select a completed transaction from the result vector using a round-robin technique; and forward the completed transaction from the set of completed transactions to an output pipeline.

A method includes detecting in a communication bus a write command to a first circuit and comparing a write address of the write command with a set of safe addresses. When the write address matches a safe address of the set of safe addresses, an error correction code (ECC) is generated based at least on write data of the write command, and the ECC is stored in a memory of a parameter safe storage circuit. A read command to the first circuit is detected in the communication bus, a read address of the read command is compared with the set of safe addresses, and, when the read address matches a safe address of the set of safe addresses, it is determined whether read data of the read command is corrupted based on the stored ECC, and an error notification is provided when the read data is determined to be corrupted.

NUMA-aware reader-writer locks may leverage lock cohorting techniques that introduce a synthetic level into the lock hierarchy (e.g., one whose nodes do not correspond to the system topology). The synthetic level may include a global reader lock and a global writer lock. A writer thread may acquire a node-level writer lock, then the global writer lock, and then the top-level lock, after which it may access a critical section protected by the lock. The writer may release the lock (if an upper bound on consecutive writers has been met), or may pass the lock to another writer (on the same node or a different node, according to a fairness policy). A reader may acquire the global reader lock (whether or not node-level reader locks are present), and then the top-level lock. However, readers may only hold these locks long enough to increment reader counts associated with them.

A user station for a bus system and a method for transmitting a message at different bit rates in a bus system. The user station includes a communication control unit for creating a message for a further user station of the bus system. The communication control unit provides, in the message, a first phase, which is to be transmitted at a first bit rate, and to provide a second phase, which is to be transmitted at a second bit rate, which is faster than the first bit rate. The communication control unit is designed to provide in the message a first predetermined bit pattern for a bit rate switching between the first and second bit rate and to provide a second predetermined bit pattern for a bit rate switching between the second and first bit rate. The second predetermined pattern differs from all other bit patterns in a valid message.