Patent application number | Description | Published |
20090113082 | Device, System, and Method of Speculative Packet Transmission - Device, system and method of speculative packet transmission. For example, an apparatus for speculative packet transmission includes: a credit-based flow control interconnect device to initiate speculative transmission of a Transaction Layer Packet if a number of available flow control credits is insufficient for completing the transmission. | 04-30-2009 |
20090138641 | Device, System, and Method of Handling Delayed Transactions - Device, system, and method of handling delayed transactions. For example, an apparatus to handle delayed transactions in a computing system includes: a slave unit adapted to pseudo-randomly reject a request received from a master unit. | 05-28-2009 |
20090177822 | Device, System, and Method of Handling Transactions - Some embodiments include, for example, devices, systems, and methods of handling transactions. In some demonstrative embodiments, an apparatus to handle transactions in a computing system may include a master unit to arbitrate between read and write requests to be issued over a request bus according to at least first and second arbitration schemes. A first ratio between read and write requests issued by the master unit according to the first arbitration scheme may be different from a second ratio between read and write requests issued by the master unit according to the second arbitration scheme. | 07-09-2009 |
20090185487 | AUTOMATED ADVANCE LINK ACTIVATION - Embodiments herein provide a transaction level mechanism that ensures that the links are operational right in time for the data flow, so that the data flow will not be impacted by delays associated with link recovery into the operational state. The path has links that have the ability to be in an inactive mode or an active mode. The embodiments herein transmit an “activation transmission” over the path to turn on the links within the path, before sending a data transfer (comprising packetized data) to turn on (wake up) the inactive links within the path, so that the actual data transfer does not experience any such start-up or wake-up delays. | 07-23-2009 |
20090187683 | ADAPTIVE LINK WIDTH CONTROL - A communications apparatus uses at least one logical communications link that comprises a plurality of lanes within a computerized hardware device. A data transfer monitor is connected to the logical communications link and measures the real-time data transfer bandwidth of the logical communications link. In addition, a link management unit or link width control unit (comparator) is connected to the lanes and to the data transfer monitor and continually compares the real-time data transfer bandwidth to a predetermined data transfer bandwidth standard. If the real-time data transfer bandwidth is below the predetermined data transfer bandwidth standard, the link management unit is adapted to perform up-configuring of the logical communications link by activating additional lanes up to a maximum number of lanes making up the logical communications link. Conversely, if the real-time data transfer bandwidth is above the predetermined data transfer bandwidth standard, the link management unit is adapted to perform down-configuring the logical communications link by deactivating lanes within the logical communications link. The lanes consume less power when the lanes are deactivated relative to when the lanes are activated, thus the down-configuring reduces power consumption. | 07-23-2009 |
20100226420 | Detection of Frame Marker Quality - For example, a method of detecting frame marker quality includes: detecting, in a bit-stream sent from a first component to a second component of a common hardware unit, a frame marker having a bit pattern different from an uncorrupted frame marker specified by a communication protocol; and assigning a quality level indicator to the frame marker based on a difference between said bit pattern and a bit pattern of said uncorrupted frame marker. | 09-09-2010 |
20120089979 | Performance Monitor Design for Counting Events Generated by Thread Groups - A number of hypervisor register fields are set to specify which processor cores are allowed to generate a number of performance events for a particular thread group. A plurality of threads for an application running in the computing environment to a plurality of thread groups are configured by a plurality of thread group fields in a plurality of control registers. A number of counter sets are allowed to count a number of thread group events originating from one of a shared resource and a shared cache are specified by a number of additional hypervisor register fields. | 04-12-2012 |
20120089984 | Performance Monitor Design for Instruction Profiling Using Shared Counters - Counter registers are shared among multiple threads executing on multiple processor cores. An event within the processor core is selected. A multiplexer in front of each of a number of counters is configured to route the event to a counter. A number of counters are assigned for the event to each of a plurality of threads running for a plurality of applications on a plurality of processor cores, wherein each of the counters includes a thread identifier in the interrupt thread identification field and a processor identifier in the processor identification field. The number of counters is configured to have a number of interrupt thread identification fields and a number of processor identification fields to identify a thread that will receive a number of interrupts. | 04-12-2012 |
20120089985 | Sharing Sampled Instruction Address Registers for Efficient Instruction Sampling in Massively Multithreaded Processors - Sampled instruction address registers are shared among multiple threads executing on a plurality of processor cores. Each of a plurality of sampled instruction address registers are assigned to a particular thread running for an application on the plurality of processor cores. Each of the sampled instruction address registers are configured by storing in each of the sampled instruction address registers a thread identification of the particular thread in a thread identification field and a processor identification of a particular processor on which the particular thread is running in a processor identification field. | 04-12-2012 |
20130159764 | PCI Express Error Handling and Recovery Action Controls - An apparatus and method of PCIe error handling and recovery actions taken in the event of an error. An error reporting extension defines a set of commonly used actions that are taken by a device in response to the detection of an error. This minimizes the side effects of continued device operation following the occurrence of an error. The device's error handling capabilities are advertised and the system software specifies the desired device action to take upon occurrence of a particular error. The particular error handling action is defined uniquely for each PCIe function and error type, such that different errors trigger a different type of action, thereby affecting only specific device functions or the entire device, depending on the configuration. Error handling actions and control fields are placed in the extension portion of the PCI Express Advanced Error Reporting configuration space. | 06-20-2013 |