1 / 16

“NVM Duet: Unified Working Memory and Persistent Store Architecture”

“NVM Duet: Unified Working Memory and Persistent Store Architecture”. Ren- Shuo Liu, De-Yu Shen, Chia-Lin Yang, Shun- Chih Yu, Cheng-Yuan Michael Wang. Sungmin Koo sm.koo1989@gmail.com. Index. Background Introduction Data Consistency vs. Bank-Level Parallelism

trente
Download Presentation

“NVM Duet: Unified Working Memory and Persistent Store Architecture”

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. “NVM Duet: Unified Working Memory and Persistent Store Architecture” Ren-Shuo Liu, De-Yu Shen, Chia-Lin Yang, Shun-Chih Yu, Cheng-Yuan Michael Wang Sungmin Koo sm.koo1989@gmail.com

  2. Index • Background • Introduction • Data Consistency vs. Bank-Level Parallelism • Data Durability vs. Write Speed • NVM Duet • Evaluation

  3. Background • Structure of PCM(Phase Chang Memory) cell • 2-states • Amorphous state(high resistance, 0) • Polycrystalline state(low resistance, 1) • Read and Write mechanisms of PCM • RESET(writing bit “0”) • Heat the phase change material • Short latency • High power consumption • SET(writing bit “1”) • Sustained low voltage pulse • Long latency • Low power consumption • To read the state of phase change material, a low enough voltage pulse is applied to the material.

  4. Background • MLC PCM • The large resistance difference between the amorphous state and the polycrystalline state makes it possible to store multiple bits per PCM cell • ‘Iterative programming’technique

  5. Background • Characteristics Comparison • PCM memory system architectures

  6. Introduction • NVM technologies have gained a lot of attention recently. • Non-volatile, byte-addressability • SCM blurs the line between working memory and persistent store. • Enable the construction of large-scale working memory • High density, scalability, MLC technique • Alternative to conventional persistent store. • can be connected to CPUs via a direct memory access path • Ordinary load, store instruction(previous study) • SCM will play the role of both working memory and persistent store at the same time. • NVM duet • Guarantee consistency and durability • not require advance partitioning of PCM resources between persistent store and working memory • All the management is transparent to applications.

  7. Data Consistency vs. Bank-Level Parallelism • Achieve consistency mechanism • Persistent update mechanisms at the software level • Journaling, shadow update • Enforcing ordering writes at the hardware level • Consistent update • Issues write requests to create N3’ and N4’ • Issuing write requests to create N1’, which points to N2, N3’, and N4’ • Issue a barrier

  8. Data Consistency vs. Bank-Level Parallelism • Figure 3(a) displays a schedule that respects the barriers. • Figure 3(b) shows if the barriers were not present. • Figure 3(c) have knowledge of the use case for each write • A, B, and G belong to working memory • The others belong to persistent store

  9. Data Durability vs. Write Speed • The write speed can be estimated based on the target band allocation • A small R is used for a narrow target band to prevent the iterative write from completely missing the target band. • Resistance drift • PCM’s limited non-volatility • The resistance of PCM cells drifts upward • Occur data losses

  10. NVM Duet • HW/SW Interface • Built on recently proposed software framework(NV-heap, Mnemosyne) • Programmers declare persistent data in the PCM main memory(keywords) • Link persistent data to a reserved virtual address space (PersistSpace) • AllocMap(one bit each PCM frame) • Convey to the memory controller the OS’s knowledge of the use case of each piece of data

  11. NVM Duet • Duet Scheduler • fully exploit the bank-level parallelism • Rule 1: Writes to working memory can be scheduled regardless of barriers. • Rule 2: Writes to persistent store are prioritized over writes to working memory if a barrier is pending in the memory controller.

  12. NVM Duet • Dual-Retention PCM Architecture • Dual-Retention PCM chips • Provide two access modes with different retention guarantees • Command interface(mode signal) • Smart Refresh • Remove unnecessary refreshing operation

  13. Evaluation

  14. Evaluation

  15. References • Haros Volos, Andres Jaan Tack, and Michael M.Swift. Mnemosyne: Lightweight Persistent Memory. • Ju-Young Jung and Sangyeun Cho. Memorage: Emerging Persistent RAM based Malleable Main Memory and Storage Architecture. • 유승훈, 이은지, 반효경.Design and Implementation of a Write Efficient Journaling File System for Phase Change Memory. • Eunji Lee, HyokyungBahn, and Sam H. Noh. Unioning of the Buffer Cache and Journaling Layers with Non-volatile Memory. • Fei Xia, JinXiong, and Ning-Hui Sun. A survey of Phase Change Memory System.

  16. Q&A

More Related