An integrated circuit (IC) can include a processor system configured to execute program code, a programmable logic, and a platform management controller coupled to the processor system and the programmable logic. The platform management controller is adapted to configure and control the processor system and the programmable logic independently.

Representative apparatus, method, and system embodiments are disclosed for configurable computing. A representative system includes an interconnection network; a processor; and a plurality of configurable circuit clusters. Each configurable circuit cluster includes a plurality of configurable circuits arranged in an array; a synchronous network coupled to each configurable circuit of the array; and an asynchronous packet network coupled to each configurable circuit of the array. A representative configurable circuit includes a configurable computation circuit and a configuration memory having a first, instruction memory storing a plurality of data path configuration instructions to configure a data path of the configurable computation circuit; and a second, instruction and instruction index memory storing a plurality of spoke instructions and data path configuration instruction indices for selection of a master synchronous input, a current data path configuration instruction, and a next data path configuration instruction for a next configurable computation circuit.

A data processing apparatus is provided. The data processing apparatus includes hardware locating circuitry for locating hardware associated with processing circuitry, and for causing hardware configuration data relating to the hardware to be generated. Providing circuitry causes the hardware configuration data to be provided to an operating system executing on the processing circuitry to enable the operating system to utilise the hardware.

Examples described herein provide for an electronic circuit, such as a System-on-Chip (SoC), having a Network-on-Chip (NoC). The NoC is configurable and has capabilities to be partially reconfigured. In an example, a NoC on an integrated circuit is configured. Subsystems on the integrated circuit communicate via the NoC. The NoC is partially reconfigured. A first subset of the NoC is reconfigured during the partial reconfiguration, and a second subset of the NoC is capable of continuing to pass communications uninterruptedly during the partial reconfiguration. After the partial reconfiguration, two or more of the subsystems communicate via the first subset of the NoC.

Embodiments of a multiprocessor system are disclosed that may include a plurality of processors interspersed with a plurality of data memory routers, a plurality of bus interface units, a bus control circuit, and a processor interface circuit. The data memory routers may be coupled together to form a primary interconnection network. The bus interface units and the bus control circuit may be coupled together in a daisy-chain fashion to form a secondary interconnection network. Each of the bus interface units may be configured to read or write data or instructions to a respective one of the plurality of data memory routers and a respective processor. The bus control circuit coupled with the processor interface circuit may be configured to function as a bidirectional bridge between the primary and secondary networks. The bus control circuit may also couple to other interface circuits and arbitrate their access to the secondary network.

Provided are integrated circuit devices and methods for operating integrated circuit devices. In various examples, an integrated circuit device can include a memory for storing instructions a configuration register, and an instruction execution circuit. An instruction read from the memory can be a reconfigurable instruction. which includes a set of fields corresponding to a plurality of operations. Values in the fields can determine whether the operations are enabled or disabled. For example, a first value in a first field can enable a first operation. Whether the first operation is performed can further be determined by comparing a second value in a second field to a third value read from the configuration register. The value set in the configuration register thus can control whether the operation is performed.

A method is disclosed for maintaining a current operating state of an enclosure when a controller card of the enclosure is repaired and/or replaced. In one embodiment, such a method maintains, within a controller card of an enclosure, operating parameters used to establish an operating state of the enclosure. The method further offloads, from the controller card while the controller card is installed in the enclosure, the operating parameters to a location external to the controller card. Upon removal of the controller card from the enclosure, the method maintains the operating state of the enclosure using the operating parameters stored in the external location. Upon reinstalling the controller card in the enclosure, the method optionally retrieves the operating parameters from the external location and initializes the controller card with the operating parameters. A corresponding system and computer program product are also disclosed.

Embodiments of a multiprocessor system are disclosed that may include a plurality of processors interspersed with a plurality of data memory routers, a plurality of bus interface units, a bus control circuit, and a processor interface circuit. The data memory routers may be coupled together to form a primary interconnection network. The bus interface units and the bus control circuit may be coupled together in a daisy-chain fashion to form a secondary interconnection network. Each of the bus interface units may be configured to read or write data or instructions to a respective one of the plurality of data memory routers and a respective processor. The bus control circuit coupled with the processor interface circuit may be configured to function as a bidirectional bridge between the primary and secondary networks. The bus control circuit may also couple to other interface circuits and arbitrate their access to the secondary network.

A reconfigurable data processor comprises an array of configurable units and a bus system configurable to define virtual machines. The system can partition the array of configurable units into a plurality of sets of configurable units, and block communications via the bus system between configurable units within a particular set and configurable units outside the particular set. A memory access controller can be connected to the bus system, configurable to confine access to memory outside the array of configurable units originating from within the particular set to memory space allocated to the particular.

A reconfigurable data processor comprises an array of configurable units and a bus system configurable to define virtual machines. The system can partition the array of configurable units into a plurality of sets of configurable units, and block communications via the bus system between configurable units within a particular set and configurable units outside the particular set. A memory access controller can be connected to the bus system, configurable to confine access to memory outside the array of configurable units originating from within the particular set to memory space allocated to the particular.