Abstract: According to one general aspect, an apparatus may include a plurality of performance and debug monitoring circuits (PDMCs). Each performance and debug monitoring circuit (PDMC) may include an input stage, a combinatorial stage, and a counter. The input stage may be configured to receive a plurality of input signals, wherein the input signals include: signals from other performance and debug monitoring circuits, signals from combinatorial logic circuits, and configuration values. The combinatorial stage may be configured to perform one or more logical operations on a selected sub-set of the input signals. The counter may be configured to increment based, at least in part, upon a result of the combinatorial stage.

Abstract: According to one general aspect, an apparatus may include an interconnect bus, an interconnect-to-debug bus interface, and a debug bus. The interconnect bus may be configured to connect and manage combinatorial logical blocks during normal operation of a processor and operate synchronous to a core clock. The interconnect-to-debug bus interface may be configured to translate communications between the interconnect bus and the debug bus. The debug bus may include a plurality of debug wrapper circuits arranged in a daisy chain for unidirectional communication, and configured to operate synchronous to the core clock. Each of the plurality of debug wrapper circuits may be configured to: identify if the respective debug wrapper circuit is activated by the debug bus, receive a non-invasive input from a respective combinatorial logic block, and place the non-invasive input from the respective combinatorial logic block on the debug bus.

Abstract: According to one general aspect, an apparatus may include an interconnect bus, an interconnect-to-debug bus interface, and a debug bus. The interconnect bus may be configured to connect and manage combinatorial logical blocks during normal operation of a processor and operate synchronous to a core clock. The interconnect-to-debug bus interface may be configured to translate communications between the interconnect bus and the debug bus. The debug bus may include a plurality of debug wrapper circuits arranged in a daisy chain for unidirectional communication, and configured to operate synchronous to the core clock. Each of the plurality of debug wrapper circuits may be configured to: identify if the respective debug wrapper circuit is activated by the debug bus, receive a non-invasive input from a respective combinatorial logic block, and place the non-invasive input from the respective combinatorial logic block on the debug bus.

Abstract: According to one general aspect, an apparatus may include a plurality of performance and debug monitoring circuits (PDMCs). Each performance and debug monitoring circuit (PDMC) may include an input stage, a combinatorial stage, and a counter. The input stage may be configured to receive a plurality of input signals, wherein the input signals include: signals from other performance and debug monitoring circuits, signals from combinatorial logic circuits, and configuration values. The combinatorial stage may be configured to perform one or more logical operations on a selected sub-set of the input signals. The counter may be configured to increment based, at least in part, upon a result of the combinatorial stage.

Abstract: A transaction switch and integrated circuit incorporating said for switching data through a shared memory between a plurality of data interfaces that support different data protocols, namely packetized interfaces like InfiniBand and addressed data interfaces like PCI. The transaction switch also switches transactions commanding data transfers between the disparate protocol data interfaces and between those of the data interfaces having like protocols. For example, the transaction switch enables a hybrid InfiniBand channel adapter/switch to perform both InfiniBand packet to local bus protocol data transfers through the shared memory as well as InfiniBand packet switching between the multiple InfiniBand interfaces. The transactions are tailored for each interface type to include information needed by the particular interface type to perform a data transfer.

Abstract: An Infiniband channel adapter for performing direct data transfers between a PCI bus and an Infiniband link without double-buffering the data in system memory. A local processor programs the channel adapter to decode addresses in a range of the PCI bus address space dedicated to direct transfers. When an I/O controller attached to the PCI bus transfers data from an I/O device to an address in the dedicated range, the channel adapter receives the data into an internal buffer and creates an Infiniband RDMA Write packet for transmission to virtual address within a remote Infiniband node. When the channel adapter receives an Infiniband RDMA Read Response packet, the channel adapter provides the packet payload data to the I/O controller at a PCI address in the dedicated range. A plurality of programmable address range registers facilitates multiple of the direct transfers concurrently by dividing the dedicated address range into multiple sub-ranges.

Abstract: A transaction switch and integrated circuit incorporating said for switching data through a shared memory between a plurality of data interfaces that support different data protocols, namely packetized interfaces like InfiniBand and addressed data interfaces like PCI. The transaction switch also switches transactions commanding data transfers between the disparate protocol data interfaces and between those of the data interfaces having like protocols. For example, the transaction switch enables a hybrid InfiniBand channel adapter/switch to perform both InfiniBand packet to local bus protocol data transfers through the shared memory as well as InfiniBand packet switching between the multiple InfiniBand interfaces. The transactions are tailored for each interface type to include information needed by the particular interface type to perform a data transfer.

Abstract: A method and apparatus for efficiently performing a cache operation in a processor (70) for both flushing and non-flushing. One embodiment uses a cache flush control bit (100) in a data cache (90) to determine whether or not to ignore valid bits (130) during a pseudo least recently used (LRU) replacement algorithm. When the replacement algorithm is being used for flushing the data cache (90), the valid bits (130) are not used in order to make the algorithm more efficient. If the valid bits (130) are ignored, then the least recently used bits (120) are used to select the cache line that will be replaced. However, when the replacement algorithm is being used for a non-flushing replacement purpose, the valid bits (130) are used first, followed by the plurality of least recently used bits (120), to select the cache line that will be replaced.