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readings [2015/03/27 20:18] kevincha [Lecture 23 (3/27 Fri.)] |
readings [2015/04/03 21:37] albert |
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* {{tldram-lee.pdf| Lee et al., “Tiered-Latency DRAM: A Low Latency and Low Cost DRAM Architecture,” HPCA 2013. (Sections 1 and 2)}} | * {{tldram-lee.pdf| Lee et al., “Tiered-Latency DRAM: A Low Latency and Low Cost DRAM Architecture,” HPCA 2013. (Sections 1 and 2)}} | ||
* {{2012_isca_salp.pdf| Kim et al., “A Case for Subarray-Level Parallelism (SALP) in DRAM,” ISCA 2012. (Sections 1 and 2)}} | * {{2012_isca_salp.pdf| Kim et al., “A Case for Subarray-Level Parallelism (SALP) in DRAM,” ISCA 2012. (Sections 1 and 2)}} | ||
- | * {{raidr_isca12.pdf| Liu et al., “RAIDR: Retention-Aware Intelligent DRAM Refresh,” ISCA 2012. (Sections 1 and 2)}} | + | * {{http://users.ece.cmu.edu/~omutlu/pub/raidr-dram-refresh_isca12.pdf|Liu et al., “RAIDR: Retention-Aware Intelligent DRAM Refresh,” ISCA 2012.}} |
* {{main-memory-system_kiise15.pdf| Onur Mutlu, Justin Meza, and Lavanya Subramanian, "The Main Memory System: Challenges and Opportunities," Invited Article in Communications of the Korean Institute of Information Scientists and Engineers (KIISE), 2015.}} | * {{main-memory-system_kiise15.pdf| Onur Mutlu, Justin Meza, and Lavanya Subramanian, "The Main Memory System: Challenges and Opportunities," Invited Article in Communications of the Korean Institute of Information Scientists and Engineers (KIISE), 2015.}} | ||
**Mentioned During Lecture:** | **Mentioned During Lecture:** | ||
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* {{tldram-lee.pdf| Lee et al., “Tiered-Latency DRAM: A Low Latency and Low Cost DRAM Architecture,” HPCA 2013. (Sections 1 and 2)}} | * {{tldram-lee.pdf| Lee et al., “Tiered-Latency DRAM: A Low Latency and Low Cost DRAM Architecture,” HPCA 2013. (Sections 1 and 2)}} | ||
* {{2012_isca_salp.pdf| Kim et al., “A Case for Subarray-Level Parallelism (SALP) in DRAM,” ISCA 2012. (Sections 1 and 2)}} | * {{2012_isca_salp.pdf| Kim et al., “A Case for Subarray-Level Parallelism (SALP) in DRAM,” ISCA 2012. (Sections 1 and 2)}} | ||
- | * {{raidr_isca12.pdf| Liu et al., “RAIDR: Retention-Aware Intelligent DRAM Refresh,” ISCA 2012. (Sections 1 and 2)}} | + | * {{http://users.ece.cmu.edu/~omutlu/pub/raidr-dram-refresh_isca12.pdf|Liu et al., “RAIDR: Retention-Aware Intelligent DRAM Refresh,” ISCA 2012.}} |
* {{main-memory-system_kiise15.pdf| Onur Mutlu, Justin Meza, and Lavanya Subramanian, "The Main Memory System: Challenges and Opportunities," Invited Article in Communications of the Korean Institute of Information Scientists and Engineers (KIISE), 2015.}} | * {{main-memory-system_kiise15.pdf| Onur Mutlu, Justin Meza, and Lavanya Subramanian, "The Main Memory System: Challenges and Opportunities," Invited Article in Communications of the Korean Institute of Information Scientists and Engineers (KIISE), 2015.}} | ||
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* {{p60-liu.pdf|Liu et al., “An Experimental Study of Data Retention Behavior in Modern DRAM Devices,” ISCA 2013.}} | * {{p60-liu.pdf|Liu et al., “An Experimental Study of Data Retention Behavior in Modern DRAM Devices,” ISCA 2013.}} | ||
* {{http://users.ece.cmu.edu/~kevincha/papers/chang_hpca2014.pdf|Kevin Chang, Donghyuk Lee, Zeshan Chishti, Alaa Alameldeen, Chris Wilkerson, Yoongu Kim, Onur Mutlu, "Improving DRAM Performance by Parallelizing Refreshes with Accesses", In HPCA 2014, Orlando, Feb. 2014.}} | * {{http://users.ece.cmu.edu/~kevincha/papers/chang_hpca2014.pdf|Kevin Chang, Donghyuk Lee, Zeshan Chishti, Alaa Alameldeen, Chris Wilkerson, Yoongu Kim, Onur Mutlu, "Improving DRAM Performance by Parallelizing Refreshes with Accesses", In HPCA 2014, Orlando, Feb. 2014.}} | ||
+ | |||
+ | ===== Lecture 24 (3/30 Mon.) ===== | ||
+ | **Required:** | ||
+ | * {{http://users.ece.cmu.edu/~omutlu/pub/mutlu_hpca03.pdf | Mutlu et al., “Runahead Execution: An Alternative to Very Large Instruction Windows for Out-of-order Processors,” HPCA 2003.}} | ||
+ | * {{http://users.ece.cmu.edu/~omutlu/pub/TR-HPS-2006-006.pdf|Srinathet al., “Feedback directed prefetching”, HPCA 2007.}} | ||
+ | |||
+ | **Mentioned During Lecture:** | ||
+ | * {{ramulator.pdf|Kim et al., “Ramulator: A Fast and Extensible DRAM Simulator,” IEEE Computer Architecture Letters 2015.}} | ||
+ | * {{http://users.ece.cmu.edu/~omutlu/pub/eaf-cache_pact12.pdf|Seshadri et al., “The Evicted-Address Filter: A Unified Mechanism to Address Both Cache Pollution and Thrashing,”PACT 2012.}} | ||
+ | * {{http://hps.ece.utexas.edu/pub/TR-HPS-2010-002.pdf|Lee et al., “DRAM-Aware Last-Level Cache Writeback: Reducing Write-Caused Interference in Memory Systems,”HPS Technical Report, April 2010.}} | ||
+ | * {{tldram-lee.pdf| Lee et al., “Tiered-Latency DRAM: A Low Latency and Low Cost DRAM Architecture,” HPCA 2013. (Sections 1 and 2)}} | ||
+ | * {{2012_isca_salp.pdf| Kim et al., “A Case for Subarray-Level Parallelism (SALP) in DRAM,” ISCA 2012. (Sections 1 and 2)}} | ||
+ | * {{http://users.ece.cmu.edu/~omutlu/pub/rlmc_isca08.pdf|Ipek et al., “Self Optimizing Memory Controllers: A Reinforcement Learning Approach,”ISCA 2008}} | ||
+ | * {{http://users.ece.cmu.edu/~omutlu/pub/mutlu_ieee_micro06.pdf|Mutlu et al., "Efficient Runahead Execution: Power-Efficient Memory Latency Tolerance," ISCA 2005, IEEE Micro Top Picks 2006.}} | ||
+ | * {{http://users.ece.cmu.edu/~omutlu/pub/mutlu_micro05.pdf|Mutlu et al., "Address-Value Delta (AVD) Prediction," MICRO 2005.}} | ||
+ | * {{http://users.ece.cmu.edu/~omutlu/pub/armstrong_micro04.pdf|Armstrong et al., "Wrong Path Events," MICRO 2004.}} | ||
+ | |||
+ | ===== Lecture 25 (4/1 Wed.) ===== | ||
+ | **Required:** | ||
+ | * {{main-memory-system_kiise15.pdf| Onur Mutlu, Justin Meza, and Lavanya Subramanian, "The Main Memory System: Challenges and Opportunities," Invited Article in Communications of the Korean Institute of Information Scientists and Engineers (KIISE), 2015.}} | ||
+ | |||
+ | **Mentioned During Lecture:** | ||
+ | * {{jouppi1990.pdf|Jouppi, “Improving Direct-Mapped Cache Performance by the Addition of a Small Fully-Associative Cache and Prefetch Buffers,” ISCA 1990.}} | ||
+ | * {{http://users.ece.cmu.edu/~omutlu/pub/TR-HPS-2006-006.pdf|Srinathet al., “Feedback directed prefetching”, HPCA 2007.}} | ||
+ | |||
+ | ===== Lecture 26 (4/3 Fri.) ===== | ||
+ | ** Required: ** | ||
+ | * {{main-memory-system_kiise15.pdf| Onur Mutlu, Justin Meza, and Lavanya Subramanian, "The Main Memory System: Challenges and Opportunities," Invited Article in Communications of the Korean Institute of Information Scientists and Engineers (KIISE), 2015.}} | ||
+ | |||
+ | ** Mentioned during lecture: ** | ||
+ | * {{raidr-isca12.pdf|Liu et al., “RAIDR: Retention-Aware Intelligent DRAM Refresh,” ISCA 2012.}} | ||
+ | * {{2012_isca_salp.pdf|Kim et al., “A Case for Exploiting Subarray-Level Parallelism in DRAM,” ISCA 2012.}} | ||
+ | * {{TLDRAM-Lee.pdf|Lee et al., “Tiered-Latency DRAM: A Low Latency and Low Cost DRAM Architecture,” HPCA 2013.}} | ||
+ | * {{p60-liu.pdf|Liu et al., “An Experimental Study of Data Retention Behavior in Modern DRAM Devices,” ISCA 2013.}} | ||
+ | * {{rowclone_micro13.pdf|Seshadri et al., “RowClone: Fast and Efficient In-DRAM Copy and Initialization of Bulk Data,” MICRO 2013.}} | ||
+ | * {{LCP.pdf|Pekhimenko et al., “Linearly Compressed Pages: A Main Memory Compression Framework,” MICRO 2013.}} | ||
+ | * {{|Chang et al., “Improving DRAM Performance by Parallelizing Refreshes with Accesses,” HPCA 2014.}} | ||
+ | * {{error-mitigation-for-intermittent-dram-failures_sigmetrics14.pdf|Khan et al., “The Efficacy of Error Mitigation Techniques for DRAM Retention Failures: A Comparative Experimental Study,” SIGMETRICS 2014.}} | ||
+ | * {{luo_dsn14.pdf|Luo et al., “Characterizing Application Memory Error Vulnerability to Optimize Data Center Cost,” DSN 2014.}} | ||
+ | * {{yoongu2014.pdf|Kim et al., “Flipping Bits in Memory Without Accessing Them: An Experimental Study of DRAM Disturbance Errors,” ISCA 2014.}} | ||
+ | * {{meza_cal12.pdf|Meza et al., “Enabling Efficient and Scalable Hybrid Memories,” IEEE Comp. Arch. Letters 2012.}} | ||
+ | * {{rowbuffer-aware-caching_iccd12.pdf|Yoon et al., “Row Buffer Locality Aware Caching Policies for Hybrid Memories,” ICCD 2012.}} | ||
+ | * {{sttram_ispass13.pdf|Kultursay et al., “Evaluating STT-RAM as an Energy-Efficient Main Memory Alternative,” ISPASS 2013. }} | ||
+ | * {{meza_weed13.pdf|Meza et al., “A Case for Efficient Hardware-Software Cooperative Management of Storage and Memory,” WEED 2013.}} | ||
+ | * {{ISCA09.pdf|Lee et al. “Architecting Phase Change Memory as a Scalable DRAM Alternative,” ISCA 2009.}} | ||
+ | * Meza+, “Revisiting Memory Errors in Large-Scale Production Data Centers: Analysis and Modeling of New Trends from the Field,” DSN 2015. | ||
+ | * Qureshi+, “AVATAR: A Variable-Retention-Time (VRT) Aware Refresh for DRAM Systems,” DSN 2015. | ||
+ | * {{ramulator.pdf|Kim et al., “Ramulator: A Fast and Extensible DRAM Simulator,” IEEE Computer Architecture Letters 2015.}} | ||
+ | * {{dirty-block-index_isca14.pdf|Seshadri+, “The Dirty-Block Index,” ISCA 2014.}} | ||
+ | * {{bdi-compression_pact12.pdf|Pekhimenko+, “Base-Delta-Immediate Compression: Practical Data Compression for On-Chip Caches,” PACT 2012.}} | ||
+ | * {{eaf-cache_pact12.pdf|Seshadri+, “The Evicted-Address Filter: A Unified Mechanism to Address Both Cache Pollution and Thrashing,” PACT 2012.}} | ||
+ | * {{zhao-micro2014.pdf|Zhao+, “FIRM: Fair and High-Performance Memory Control for Persistent Memory Systems,” MICRO 2014.}} | ||
+ | * {{a40-yoon.pdf|Yoon, Meza+, “Efficient Data Mapping and Buffering Techniques for Multi-Level Cell Phase-Change Memories,” ACM TACO 2014.}} | ||
+ | * {{compression-aware-cache-management_hpca15.pdf|Gennady Pekhimenko, Tyler Huberty, Rui Cai, Onur Mutlu, Phillip P. Gibbons, Michael A. Kozuch, and Todd C. Mowry, Exploiting Compressed Block Size as an Indicator of Future Reuse, HPCA 2015.}} | ||
+ | * {{06974684.pdf|Lu+, “Loose Ordering Consistency for Persistent Memory,” ICCD 2014.}} | ||
+ | * {{mutlu_et_al._-_2003_-_runahead_execution_an_alternative_to_very_large_instruction_windows_for_out-of-order_processors.pdf|Mutlu, O., Stark, J., Wilkerson, C., & Patt, Y. N. (2003). Runahead Execution: An Alternative to Very Large Instruction Windows for Out-of-Order Processors. Proceedings of the 9th International Symposium on High-Performance Computer Architecture.}} | ||
+ | * {{cooksey.pdf|Cooksey et al., “A stateless, content-directed data prefetching mechanism,” ASPLOS 2002.}} | ||
+ | * {{zilles-2001.pdf|Zilles and Sohi, “Execution-based Prediction Using Speculative Slices”, ISCA 2001.}} | ||
+ | * {{zilles-2000.pdf|Zilles and Sohi, ”Understanding the backward slices of performance degrading instructions,” ISCA 2000.}} | ||
+ | * {{http://www.amazon.com/Inside-AS-400-Second-Edition/dp/1882419669|Frank Soltis,"Inside the AS/400"}} |