Abstract: Systems, methods, and apparatuses for range protection. In some embodiments, an apparatus comprises at least one monitoring circuit to monitor for memory accesses to an address space and take action upon a violation to the address space, wherein the action is one of generating a notification to a node that requested the monitor, generating the wrong request, generate a notification in a specific context of the home node, and generating a notification in a node that has ownership of the address space; at least one a protection table to store an identifier of the address space; and at least one hardware core to execute an instruction to enable the monitoring circuit.

Abstract: Embodiments of the invention describe a system main memory comprising two levels of memory that include cached subsets of system disk level storage. This main memory includes “near memory” comprising memory made of volatile memory, and “far memory” comprising volatile or nonvolatile memory storage that is larger and slower than the near memory. The far memory is presented as “main memory” to the host OS while the near memory is a cache for the far memory that is transparent to the OS, thus appearing to the OS the same as prior art main memory solutions. The management of the two-level memory may be done by a combination of logic and modules executed via the host CPU. Near memory may be coupled to the host system CPU via high bandwidth, low latency means for efficient processing. Far memory may be coupled to the CPU via low bandwidth, high latency means.

Abstract: Described herein are devices and techniques for distributing application data. A device can communicate with one or more hardware switches. The device can receive, from a software stack, a multicast message including a constraint that indicates how application data is to be distributed. The constraint including a listing of the set of nodes and a number of nodes to which the application data is to be distributed. The device may receive, from the software stack, the application data for distribution to a plurality of nodes. The plurality of nodes being a subset of the set of nodes equaling the number of nodes. The device may select the plurality of nodes from the set of nodes. The device also may distribute a copy of the application data to the plurality of nodes based on the constraint. Also described are other embodiments.

Abstract: An apparatus is described that includes a memory card. The memory card also includes volatile memory devices. The memory card also includes non volatile memory devices. The memory card is configurable to implement a first portion of the storage space of the non volatile memory devices as system memory. The memory card also includes a controller to manage, upon a power down event, the transfer of information from the volatile memory devices into a second portion of the storage space of the non volatile memory devices.

Abstract: A physical layer (PHY) is coupled to a serial, differential link that is to include a number of lanes. The PHY includes a transmitter and a receiver to be coupled to each lane of the number of lanes. The transmitter coupled to each lane is configured to embed a clock with data to be transmitted over the lane, and the PHY periodically issues a blocking link state (BLS) request to cause an agent to enter a BLS to hold off link layer flit transmission for a duration. The PHY utilizes the serial, differential link during the duration for a PHY associated task selected from a group including an in-band reset, an entry into low power state, and an entry into partial width state.

Abstract: A physical layer (PHY) is coupled to a serial, differential link that is to include a number of lanes. The PHY includes a transmitter and a receiver to be coupled to each lane of the number of lanes. The transmitter coupled to each lane is configured to embed a clock with data to be transmitted over the lane, and the PHY periodically issues a blocking link state (BLS) request to cause an agent to enter a BLS to hold off link layer flit transmission for a duration.

Abstract: Examples are disclosed for probabilistic dynamic random access memory (DRAM) row repair. In some examples, using a row hammer limit for DRAM and a maximum activation rate for the DRAM a probabilistic row hammer detection value may be determined. The probabilistic row hammer detection value may then be used such that a probability is acceptably low that a given activation to an aggressor row of the DRAM causes the row hammer limit to be exceeded before a scheduled row refresh is performed on one or more victim rows associated with the aggressor row. Other examples are described and claimed.

Abstract: A semiconductor chip comprising memory controller circuitry having interface circuitry to couple to a memory channel. The memory controller includes first logic circuitry to implement a first memory channel protocol on the memory channel. The first memory channel protocol is specific to a first volatile system memory technology. The interface also includes second logic circuitry to implement a second memory channel protocol on the memory channel. The second memory channel protocol is specific to a second non volatile system memory technology. The second memory channel protocol is a transactional protocol.

Abstract: Methods, apparatus, and systems for reliable replication mechanisms based on active-passive HFI protocols build on top of non-reliable multicast fabric implementations. Under a first hardware-based scheme, a reliable replication mechanism is (primarily) implemented via Host Fabric Interfaces (HFIs) coupled to (or integrated in) nodes coupled to a non-reliable fabric. Under this approach, the HFIs take an active role in ensuring reliable delivery of multicast messages to each of multiple target nodes. Under a second hybrid software/hardware scheme, software running on nodes is responsible for determining whether target nodes have confirmed delivery of multicast messages and sending retry messages for cases in which delivery is not acknowledged within a timeout period. At the same time, the HFIs on the target nodes are responsible for generating reply messages containing acknowledgements rather than software running on the target nodes.

Abstract: A system and method are described for integrating a memory and storage hierarchy including a non-volatile memory tier within a computer system. In one embodiment, PCMS memory devices are used as one tier in the hierarchy, sometimes referred to as “far memory.” Higher performance memory devices such as DRAM placed in front of the far memory and are used to mask some of the performance limitations of the far memory. These higher performance memory devices are referred to as “near memory.

Abstract: Systems and methods may provide for detecting that a read operation is directed to a memory region while the memory region is in a poisoned state and clearing the poisoned state if volatile data stored in the memory region does not correspond to a known data pattern. Additionally, the memory region may be maintained in the poisoned state if the volatile data stored in the memory region corresponds to the known data pattern. In one example, an error may be detected, wherein the error is associated with a write operation directed to the memory region. In such a case, the poisoned state may be set for the volatile data in response to the error and the known data pattern may be written to the memory region.

Abstract: A system and method are described for integrating a memory and storage hierarchy including a non-volatile memory tier within a computer system. In one embodiment, PCMS memory devices are used as one tier in the hierarchy, sometimes referred to as “far memory.” Higher performance memory devices such as DRAM placed in front of the far memory and are used to mask some of the performance limitations of the far memory. These higher performance memory devices are referred to as “near memory.” In one embodiment, the “near memory” is configured to operate in a plurality of different modes of operation including (but not limited to) a first mode in which the near memory operates as a memory cache for the far memory and a second mode in which the near memory is allocated a first address range of a system address space with the far memory being allocated a second address range of the system address space, wherein the first range and second range represent the entire system address space.

Abstract: Provided are a method, system, computer readable storage medium, and switch for configuring a switch to assign partitions in storage devices to compute nodes. A management controller configures the switch to dynamically allocate partitions of at least one of the storage devices to the compute nodes based on a workload at the compute node.

Abstract: Embodiments are generally directed to accelerated address indirection table lookup for wear-leveled non-volatile memory. A embodiment of a memory device includes nonvolatile memory; a memory controller; and address indirection logic to provide address indirection for the nonvolatile memory, of the address indirection logic to maintain an address indirection table (AIT) in the nonvolatile memory, the AIT including a plurality of levels, and copy at least a portion of the AIT to a second memory, the second memory having less latency than the first memory.

Abstract: Methods and apparatus related to Rack Scale Architecture (RSA) and/or Shared Memory Controller (SMC) techniques of fast zeroing are described. In one embodiment, a storage device stores meta data corresponding to a portion of a non-volatile memory. Logic, coupled to the non-volatile memory, causes an update to the stored meta data in response to a request for initialization of the portion of the non-volatile memory. The logic causes initialization of the portion of the non-volatile memory prior to a reboot or power cycle of the non-volatile memory. Other embodiments are also disclosed and claimed.

Abstract: Methods and apparatus to accelerate boot time zeroing of memory based on Non-Volatile Memory (NVM) technology are described. In an embodiment, a storage device stores a boot version number corresponding to a portion of a non-volatile memory. A memory controller logic causes an update of the stored boot version number in response to each subsequent boot event. The memory controller logic returns a zero in response to a read operation directed at the portion of the non-volatile memory and a mismatch between the stored boot version number and a current boot version number. Other embodiments are also disclosed and claimed.

Abstract: An apparatus and method are described for performing a cache line write back operation. For example, one embodiment of a method comprises: initiating a cache line write back operation directed to a particular linear address; determining if a dirty cache line identified by the linear address exists at any cache of a cache hierarchy comprised of a plurality of cache levels; writing back the dirty cache line to memory if the dirty cache line exists in one of the caches; and responsively maintaining or placing the dirty cache line in an exclusive state in at least a first cache of the hierarchy.

Abstract: Examples are disclosed for probabilistic dynamic random access memory (DRAM) row repair. In some examples, using a row hammer limit for DRAM and a maximum activation rate for the DRAM a probabilistic row hammer detection value may be determined. The probabilistic row hammer detection value may then be used such that a probability is acceptably low that a given activation to an aggressor row of the DRAM causes the row hammer limit to be exceeded before a scheduled row refresh is performed on one or more victim rows associated with the aggressor row. Other examples are described and claimed.

Abstract: An apparatus and method are described for store durability and ordering in a persistent memory architecture. For example, one embodiment of a method comprises: performing at least one store operation to one or more addresses identifying at least one persistent memory device, the store operations causing one or more memory controllers to store data in the at least one persistent memory device; sending a request message to the one or more memory controllers instructing the memory controllers to confirm that the store operations are successfully committed to the at least one persistent memory device; ensuring at the one or more memory controllers that at least all pending store operations received at the time of the request message will be committed to the persistent memory device; and sending a response message from the one or more memory controllers indicating that the store operations are successfully committed to the persistent memory device.

Abstract: A system includes a non-volatile random access memory (NVRAM) device and controller logic that detects a bad block within the device, retires the bad block and replaces the bad block with a replacement block by assigning the address of the bad block to the replacement block.