Aspects of a storage device including a memory and a controller are provided. The controller may receive a prefetch request to retrieve data for a host having a promoted stream. The controller may access a frozen time table indicating hosts for which data has been prefetched and frozen times associated with the host and other hosts. The controller can determine whether the host has a higher priority over other hosts included in the frozen time table based on corresponding frozen times and data access parameters associated with the host. The controller may determine to prefetch the data for the host in response to the prefetch request when the host has a higher priority than the other hosts. The controller can receive a host read command associated with the promoted stream from the host and provide the prefetched data to the host in response to the host read command.

A cache and memory coherent system includes multiple processing chips each hosting a different subset of a shared memory space and one or more routing tables defining access routes between logical addresses of the shared memory space and endpoints that each correspond to a select one of the multiple processing chips. The system further includes a coherent mesh fabric that physically couples together each pair of the multiple processing chips, the coherent mesh fabric being configured to execute routing logic for updating the one or more routing tables responsive to identification of a first processing chip of the multiple processing chips hosting a defective hardware component, the update to the routing tables being effective to remove all access routes having endpoints corresponding to the first processing chip.

A cache and memory coherent system includes multiple processing chips each hosting a different subset of a shared memory space and one or more routing tables defining access routes between logical addresses of the shared memory space and endpoints that each correspond to a select one of the multiple processing chips. The system further includes a coherent mesh fabric that physically couples together each pair of the multiple processing chips, the coherent mesh fabric being configured to execute routing logic for updating the one or more routing tables responsive to identification of a first processing chip of the multiple processing chips hosting a defective hardware component, the update to the routing tables being effective to remove all access routes having endpoints corresponding to the first processing chip.

Systems and methods are disclosed including a processing device operatively coupled to a first and a second memory device. The processing device can receive a set of data access requests, from a host system, in a first order and execute the set of data access requests in a second order. The processing device can further identify a late data access request of the set of data access requests and determine whether a data structure in a local memory associated with the processing device includes a previous outstanding data access request corresponding to an address associated with the late data access request. Responsive to determining that the data structure includes an indication of a previous outstanding data access request corresponding to the address associated with the late data access request, identifying a type of data dependency associated with the previous outstanding data access request and performing one or more operations associated with the type of data dependency.

Systems and methods are disclosed including a processing device operatively coupled to a first and a second memory device. The processing device can receive a set of data access requests, from a host system, in a first order and execute the set of data access requests in a second order. The processing device can further identify a late data access request of the set of data access requests and determine whether a data structure in a local memory associated with the processing device includes a previous outstanding data access request corresponding to an address associated with the late data access request. Responsive to determining that the data structure includes an indication of a previous outstanding data access request corresponding to the address associated with the late data access request, identifying a type of data dependency associated with the previous outstanding data access request and performing one or more operations associated with the type of data dependency.

Technologies for cross-device shared web resource caching include a client device and a shared cache device. The client device scans for a shared cache device in local proximity to the client device and, in response to the scan, registers with the shared cache device. After registering, the client device requests a cached web resource from the shared cache device. The shared cache device determines whether a cached web resource that matches the request is installed in a shared cache. The shared cache device may determine whether an origin of the request matches the mi gin of the cached web resource. If installed, the shared cache device sends a found response and the cached web resource to the client device. If not installed, the shared cache device sends a not-found response and the client device may request the web resource from a remote web server. Other embodiments are described and claimed.

Technologies for cross-device shared web resource caching include a client device and a shared cache device. The client device scans for a shared cache device in local proximity to the client device and, in response to the scan, registers with the shared cache device. After registering, the client device requests a cached web resource from the shared cache device. The shared cache device determines whether a cached web resource that matches the request is installed in a shared cache. The shared cache device may determine whether an origin of the request matches the mi gin of the cached web resource. If installed, the shared cache device sends a found response and the cached web resource to the client device. If not installed, the shared cache device sends a not-found response and the client device may request the web resource from a remote web server. Other embodiments are described and claimed.

Apparatuses, systems, and methods for controlling cache allocations in a configurable combined private and shared cache in a processor-based system. The processor-based system is configured to receive a cache allocation request to allocate a line in a share cache structure, which may further include a client identification (ID). The cache allocation request and the client ID can be compared to a sub-non-uniform memory access (NUMA) (sub-NUMA) bit mask and a client allocation bit mask to generate a cache allocation vector. The sub-NUMA bit mask may have been programmed to indicate that processing cores associated with a sub-NUMA region are available, whereas processing cores associated with other sub-NUMA regions are not available, and the client allocation bit mask may have been programmed to indicate that processing cores are available. The sub-NUMA bit mask and the client allocation bit mask can be combined to create a cache allocation vector that a cache allocation request to allocate a line serviced by one of processing cores.

Aspects disclosed in the detailed description include configuring a configurable combined private and shared cache in a processor. Related processor-based systems and methods are also disclosed. A combined private and shared cache structure is configurable to select a private cache portion and a shared cache portion.

Aspects disclosed in the detailed description include configuring a configurable combined private and shared cache in a processor. Related processor-based systems and methods are also disclosed. A combined private and shared cache structure is configurable to select a private cache portion and a shared cache portion.