Memory virtualization

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In computer science, memory virtualization decouples volatile random access memory (RAM) resources from individual systems in the data centre, and then aggregates those resources into a virtualized memory pool available to any computer in the cluster.[citation needed] The memory pool is accessed by the operating system or applications running on top of the operating system. The distributed memory pool can then be utilized as a high-speed cache, a messaging layer, or a large, shared memory resource for a CPU or a GPU application.

Description[]

Memory virtualization allows networked, and therefore distributed, servers to share a pool of memory to overcome physical memory limitations, a common bottleneck in software performance.[citation needed] With this capability integrated into the network, applications can take advantage of a very large amount of memory to improve overall performance, system utilization, increase memory usage efficiency, and enable new use cases. Software on the memory pool nodes (servers) allows nodes to connect to the memory pool to contribute memory, and store and retrieve data. Management software and the technologies of memory overcommitment manage shared memory, data insertion, eviction and provisioning policies, data assignment to contributing nodes, and handles requests from client nodes. The memory pool may be accessed at the application level or operating system level. At the application level, the pool is accessed through an API or as a networked file system to create a high-speed shared memory cache. At the operating system level, a page cache can utilize the pool as a very large memory resource that is much faster than local or networked storage.

Memory virtualization implementations are distinguished from shared memory systems. Shared memory systems do not permit abstraction of memory resources, thus requiring implementation with a single operating system instance (i.e. not within a clustered application environment).

Memory virtualization is also different from storage based on flash memory such as solid-state drives (SSDs) - SSDs and other similar technologies replace hard-drives (networked or otherwise), while memory virtualization replaces or complements traditional RAM.

Benefits[]

Remove physical-memory limits

Run multiple application at once

Products[]

Implementations[]

Application level integration[]

In this case, applications running on connected computers connect to the memory pool directly through an API or the file system.

Cluster implementing memory virtualization at the application level. Contributors 1...n contribute memory to the pool. Applications read and write data to the pool using Java or C APIs, or a file system API.

Operating System Level Integration[]

In this case, the operating system connects to the memory pool, and makes pooled memory available to applications.

Cluster implementing memory virtualization. Contributors 1...n contribute memory to the pool. The operating system connects to the memory pool through the page cache system. Applications consume pooled memory via the operating system.

Background[]

Memory virtualization technology follows from memory management architectures and virtual memory techniques. In both fields, the path of innovation has moved from tightly coupled relationships between logical and physical resources to more flexible, abstracted relationships where physical resources are allocated as needed.

Virtual memory systems abstract between physical RAM and virtual addresses, assigning virtual memory addresses both to physical RAM and to disk-based storage, expanding addressable memory, but at the cost of speed. NUMA and SMP architectures optimize memory allocation within multi-processor systems. While these technologies dynamically manage memory within individual computers, memory virtualization manages the aggregated memory of multiple networked computers as a single memory pool.

In tandem with memory management innovations, a number of virtualization techniques have arisen to make the best use of available hardware resources. Application virtualization was demonstrated in mainframe systems first. The next wave was storage virtualization, as servers connected to storage systems such as NAS or SAN in addition to, or instead of, on-board hard disk drives. Server virtualization, or Full virtualization, partitions a single physical server into multiple virtual machines, consolidating multiple instances of operating systems onto the same machine for the purpose of efficiency and flexibility. In both storage and server virtualization, the applications are unaware that the resources they are using are virtual rather than physical, so efficiency and flexibility are achieved without application changes. In the same way, memory virtualization allocates the memory of an entire networked cluster of servers among the computers in that cluster.

See also[]

References[]

  • Oleg Goldshmidt, Virtualization: Advanced Operating Systems
  • "Startup RNA Networks Virtualizes Memory Across Multiple Servers". InformationWeek. February 13, 2009. Retrieved March 24, 2009.
  • "Five Virtualization Trends to Watch". ComputerWorld. February 3, 2009. Archived from the original on March 16, 2009. Retrieved March 24, 2009.
  • "RNA networks and Memory Virtualization". ZDNet. February 2, 2009. Retrieved March 24, 2009.
  • Kusnetzky, Dan (January 28, 2007). "Sorting out the different layers of virtualization". ZDNet. Retrieved March 24, 2009.
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