Heterogeneous chip multiprocessor architectures for big data applications

Homayoun, Houman

doi:10.1145/2903150.2908078

Cited by 6 publications

(4 citation statements)

References 30 publications

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“…In recent years, many cores are trending as a on-chip computing platform [1]- [3] that can provide massive computational power for a heterogenous computing environment for big data [4] and other compute intensive embedded artificial intelligence applications [5]. Some recent work [6]- [9] on high performance computing for big data have focused on processing framework, architecture synthesis and utilization of multiple cores.…”

Section: Introductionmentioning

confidence: 99%

An efficient multi-level cache system for geometrically interconnected many-core chip multiprocessor

Ramesh

Abed

2022

IJRES

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<p><span lang="EN-US">Many-core chip multiprocessor offers high parallel processing power for big data analytics; however, they require efficient multi-level cache and interconnection to achieve high system throughput. Using on-chip first level L1 and second level L2 per core fast private caches is expensive for large number of cores. In this paper, for moderate number of cores from 16 to 64, we present a cost and performance efficient multi-level cache system with per core L1 and last level shared bus cache on each bus line of a cost-efficient geometrically bus-based interconnection. In our approach, we extracted cache hit and miss concurrencies and applied concurrent average memory access time to more accurately determine the cache system performance. We conducted least recently used cache policy-based simulation for cache system with L1, with L1/L2, and with L1/shared bus cache. Our simulation results show that an average system throughput improvement of 2.5x can be achieved by using system with L1/shared bus cache system compared to using only first level L1 or L1/L2. Further, we show that the throughput degradation for the proposed cache system is only within 5% for a single bus fault, suggesting a good bus fault tolerance.</span></p>

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Section: Introductionmentioning

confidence: 99%

An efficient multi-level cache system for geometrically interconnected many-core chip multiprocessor

Ramesh

Abed

2022

IJRES

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Section: Introductionmentioning

confidence: 99%

“…is la er e ect is commonly referred to as the breakdown of Dennard's scaling, which forces designs to operate only a fraction of the whole system, leaving the remaining design in a dark silicon state [8,10]. To address this, heterogeneous multiprocessors (HMPs) have emerged over other designs, especially in mobile devices [17,33], where keeping within a strict energy envelope while still being able to deliver performance on demand is crucial.To be able to deliver high performance through Memory Level Parallelism (MLP) and instruction level parallelism (ILP), an Out-of-Order (OoO) core is commonly used that has large caches, does aggressive speculation (branch predictors, prefetchers) and masks memory latency at the cost of signi cantly increased design complexity, area and power requirements. On the other hand, In-Order (InO) cores aim at conserving energy through a simpler and smaller design, at the expense of performance and lower operating frequency.…”

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confidence: 99%

Nucleus

Vougioukas

Sandberg

Diestelhorst

et al. 2017

ACM Trans. Embed. Comput. Syst.

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Heterogeneous multi-processors are designed to bridge the gap between performance and energy e ciency in modern embedded systems. is is achieved by pairing Out-of-Order (OoO) cores, yielding performance through aggressive speculation and latency masking, with In-Order (InO) cores, that preserve energy through simpler design. By leveraging migrations between them, workloads can therefore select the best se ing for any given energy/delay envelope. However, migrations introduce execution overheads that can hurt performance if they happen too frequently. Finding the optimal migration frequency is critical to maximize energy savings while maintaining acceptable performance. We develop a simulation methodology that can 1) isolate the hardware e ects of migrations from the so ware, 2) directly compare the performance of di erent core types, 3) quantify the performance degradation and 4) calculate the cost of migrations for each case. To showcase our methodology we run mibench, a microbenchmark suite, and show that migrations can happen as fast as every 100k instructions with li le performance loss. We also show that, contrary to numerous recent studies, hypothetical designs do not need to share all of their internal components to be able to migrate at that frequency. Instead, we propose a feasible system that shares level 2 caches and a translation lookaside bu er that matches performance and e ciency. Our results show that there are phases comprising up to 10% that a migration to the OoO core leads to performance bene ts without any additional energy cost when running on the InO core, and up to 6% of phases where a migration to the InO core can save energy without a ecting performance. When considering a policy that focuses on improving the energy-delay product, results show that on average 66% of the phases can be migrated to deliver equal or be er system operation without having to aggressively share the entire memory system or to revert to migration periods ner than 100k instructions. Permission to make digital or hard copies of all or part of this work for personal or classroom use is granted without fee provided that copies are not made or distributed for pro t or commercial advantage and that copies bear this notice and the full citation on the rst page. Copyrights for components of this work owned by others than the author(s) must be honored. Abstracting with credit is permi ed. To copy otherwise, or republish, to post on servers or to redistribute to lists, requires prior speci c permission and/or a fee. Request permissions from permissions@acm.org. Instructions per cycle Fig. 1. An excerpt of execution of dijkstra running on two di erent core types. Sampling at a higher resolution reveals phases that can potentially be exploited to increase e iciency. INTRODUCTIONIn today's embedded devices, performance is always tied to power constraints and energy e ciency. is happens because, while process technology scaling is enabling larger transistor densities, power per area has shown to increase beyond a certain thr...

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“…The command indicates the root node; in this case, the root is P5. Therefore, all MPEs know the node number 2. The root MPE orders the local bus to distribute the value of the status register to all MPEs.…”

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confidence: 99%

Efficient Pipelined Broadcast with Monitoring Processing Node Status on a Multi-Core Processor

Park

2019

Mathematics

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This paper presents an efficient pipelined broadcasting algorithm with the inter-node transmission order change technique considering the communication status of processing nodes. The proposed method changes the transmission order for the broadcast operation based on the communication status of processing nodes. When a broadcast operation is received, a local bus checks the remaining pre-existing transmission data size of each processing node; it then transmits data according to the changed transmission order using the status information. Therefore, the synchronization time can be hidden for the remaining time, until the pre-existing data transmissions finish; as a result, the overall broadcast completion time is reduced. The simulation results indicated that the speed-up ratio of the proposed algorithm was up to 1.423, compared to that of the previous algorithm. To demonstrate physical implementation feasibility, the message passing engine (MPE) with the proposed broadcast algorithm was designed by using Verilog-HDL, which supports four processing nodes. The logic synthesis results with TSMC 0.18 µm process cell libraries show that the logic area of the proposed MPE is 2288.1 equivalent NAND gates, which is approximately 2.1% of the entire chip area. Therefore, performance improvement in multi-core processors is expected with a small hardware area overhead.

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Heterogeneous chip multiprocessor architectures for big data applications

Cited by 6 publications

References 30 publications

An efficient multi-level cache system for geometrically interconnected many-core chip multiprocessor

An efficient multi-level cache system for geometrically interconnected many-core chip multiprocessor

Nucleus

Efficient Pipelined Broadcast with Monitoring Processing Node Status on a Multi-Core Processor

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