Acceleration by Inline Cache for Memory-Intensive Algorithms on FPGA via High-Level Synthesis

Using FPGA-based acceleration of high-performance computing (HPC) applications to reduce energy and power consumption is becoming an interesting option, thanks to the availability of high-level synthesis (HLS) tools that enable fast design cycles. However, obtaining good performance for memory-intensive algorithms, which often exchange large data arrays with external DRAM, still requires time-consuming optimization and good knowledge of hardware design. This article proposes a new design methodology, based on dedicated application- and data array-specific caches. These caches provide most of the benefits that can be achieved by coding optimized DMA-like transfer strategies by hand into the HPC application code, but require only limited manual tuning (basically the selection of architecture and size), are neutral to target HLS tool and technology (FPGA or ASIC), and do not require changes to application code. We show experimental results obtained on five common memory-intensive algorithms from very diverse domains, namely machine learning, data sorting, and computer vision. We test the cost and performance of our caches against both out-of-the-box code originally optimized for a GPU, and manually optimized implementations specifically targeted for FPGAs via HLS. The implementation using our caches achieved an 8X speedup and 2X energy reduction on average with respect to out-of-the-box models using only simple directive-based optimizations (e.g., pipelining). They also achieved comparable performance with much less design effort when compared with the versions that were manually optimized to achieve efficient memory transfers specifically for an FPGA

Towards Efficient Resource Allocation for Embedded Systems

Das Hauptthema ist die dynamische Ressourcenverwaltung in eingebetteten Systemen, insbesondere die Verwaltung von Rechenzeit und Netzwerkverkehr auf einem MPSoC. Die Idee besteht darin, eine Pipeline für die Verarbeitung von Mobiler Kommunikation auf dem Chip dynamisch zu schedulen, um die Effizienz der Hardwareressourcen zu verbessern, ohne den Ressourcenverbrauch des dynamischen Schedulings dramatisch zu erhöhen. Sowohl Software- als auch Hardwaremodule werden auf Hotspots im Ressourcenverbrauch untersucht und optimiert, um diese zu entfernen. Da Applikationen im Bereich der Signalverarbeitung normalerweise mit Hilfe von SDF-Diagrammen beschrieben werden können, wird deren dynamisches Scheduling optimiert, um den Ressourcenverbrauch gegenüber dem üblicherweise verwendeten statischen Scheduling zu verbessern. Es wird ein hybrider dynamischer Scheduler vorgestellt, der die Vorteile von Processing-Networks und der Planung von Task-Graphen kombiniert. Es ermöglicht dem Scheduler, ein Gleichgewicht zwischen der Parallelisierung der Berechnung und der Zunahme des dynamischen Scheduling-Aufands optimal abzuwägen. Der resultierende dynamisch erstellte Schedule reduziert den Ressourcenverbrauch um etwa 50%, wobei die Laufzeit im Vergleich zu einem statischen Schedule nur um 20% erhöht wird. Zusätzlich wird ein verteilter dynamischer SDF-Scheduler vorgeschlagen, der das Scheduling in verschiedene Teile zerlegt, die dann zu einer Pipeline verbunden werden, um mehrere parallele Prozessoren einzubeziehen. Jeder Scheduling-Teil wird zu einem Cluster mit Load-Balancing erweitert, um die Anzahl der parallel laufenden Scheduling-Jobs weiter zu erhöhen. Auf diese Weise wird dem vorhandene Engpass bei dem dynamischen Scheduling eines zentralisierten Schedulers entgegengewirkt, sodass 7x mehr Prozessoren mit dem Pipelined-Clustered-Dynamic-Scheduler für eine typische Signalverarbeitungsanwendung verwendet werden können. Das neue dynamische Scheduling-System setzt das Vorhandensein von drei verschiedenen Kommunikationsmodi zwischen den Verarbeitungskernen voraus. Bei der Emulation auf Basis des häufig verwendeten RDMA-Protokolls treten Leistungsprobleme auf. Sehr gut kann RDMA für einmalige Punkt-zu-Punkt-Datenübertragungen verwendet werden, wie sie bei der Ausführung von Task-Graphen verwendet werden. Process-Networks verwenden normalerweise Datenströme mit hohem Volumen und hoher Bandbreite. Es wird eine FIFO-basierte Kommunikationslösung vorgestellt, die einen zyklischen Puffer sowohl im Sender als auch im Empfänger implementiert, um diesen Bedarf zu decken. Die Pufferbehandlung und die Datenübertragung zwischen ihnen erfolgen ausschließlich in Hardware, um den Software-Overhead aus der Anwendung zu entfernen. Die Implementierung verbessert die Zugriffsverwaltung mehrerer Nutzer auf flächen-effiziente Single-Port Speichermodule. Es werden 0,8 der theoretisch möglichen Bandbreite, die normalerweise nur mit flächenmäßig teureren Dual-Port-Speichern erreicht wird. Der dritte Kommunikationsmodus definiert eine einfache Message-Passing-Implementierung, die ohne einen Verbindungszustand auskommt. Dieser Modus wird für eine effiziente prozessübergreifende Kommunikation des verteilten Scheduling-Systems und der engen Ansteuerung der restlichen Prozessoren benötigt. Eine Flusskontrolle in Hardware stellt sicher, dass eine große Anzahl von Sendern Nachrichten an denselben Empfänger senden kann. Dabei wird garantiert, dass alle Nachrichten korrekt empfangen werden, ohne dass eine Verbindung hergestellt werden muss und die Nachrichtenlaufzeit gering bleibt. Die Arbeit konzentriert sich auf die Optimierung des Codesigns von Hardware und Software, um die kompromisslose Ressourceneffizienz der dynamischen SDF-Graphen-Planung zu erhöhen. Besonderes Augenmerk wird auf die Abhängigkeiten zwischen den Ebenen eines verteilten Scheduling-Systems gelegt, das auf der Verfügbarkeit spezifischer hardwarebeschleunigter Kommunikationsmethoden beruht.:1 Introduction 1.1 Motivation 1.2 The Multiprocessor System on Chip Architecture 1.3 Concrete MPSoC Architecture 1.4 Representing LTE/5G baseband processing as Static Data Flow 1.5 Compuation Stack 1.6 Performance Hotspots Addressed 1.7 State of the Art 1.8 Overview of the Work 2 Hybrid SDF Execution 2.1 Addressed Performance Hotspot 2.2 State of the Art 2.3 Static Data Flow Graphs 2.4 Runtime Environment 2.5 Overhead of Deloying Tasks to a MPSoC 2.6 Interpretation of SDF Graphs as Task Graphs 2.7 Interpreting SDF Graphs as Process Networks 2.8 Hybrid Interpretation 2.9 Graph Topology Considerations 2.10 Theoretic Impact of Hybrid Interpretation 2.11 Simulating Hybrid Execution 2.12 Pipeline SDF Graph Example 2.13 Random SDF Graphs 2.14 LTE-like SDF Graph 2.15 Key Lernings 3 Distribution of Management 3.1 Addressed Performance Hotspot 3.2 State of the Art 3.3 Revising Deployment Overhead 3.4 Distribution of Overhead 3.5 Impact of Management Distribution to Resource Utilization 3.6 Reconfigurability 3.7 Key Lernings 4 Sliced FIFO Hardware 4.1 Addressed Performance Hotspot 4.2 State of the Art 4.3 System Environment 4.4 Sliced Windowed FIFO buffer 4.5 Single FIFO Evaluation 4.6 Multiple FIFO Evalutaion 4.7 Hardware Implementation 4.8 Key Lernings 5 Message Passing Hardware 5.1 Addressed Performance Hotspot 5.2 State of the Art 5.3 Message Passing Regarded as Queueing 5.4 A Remote Direct Memory Access Based Implementation 5.5 Hardware Implementation Concept 5.6 Evalutation of Performance 5.7 Key Lernings 6 SummaryThe main topic is the dynamic resource allocation in embedded systems, especially the allocation of computing time and network traffic on an multi processor system on chip (MPSoC). The idea is to dynamically schedule a mobile communication signal processing pipeline on the chip to improve hardware resource efficiency while not dramatically improve resource consumption because of dynamic scheduling overhead. Both software and hardware modules are examined for resource consumption hotspots and optimized to remove them. Since signal processing can usually be described with the help of static data flow (SDF) graphs, the dynamic handling of those is optimized to improve resource consumption over the commonly used static scheduling approach. A hybrid dynamic scheduler is presented that combines benefits from both processing networks and task graph scheduling. It allows the scheduler to optimally balance parallelization of computation and addition of dynamic scheduling overhead. The resulting dynamically created schedule reduces resource consumption by about 50%, with a runtime increase of only 20% compared to a static schedule. Additionally, a distributed dynamic SDF scheduler is proposed that splits the scheduling into different parts, which are then connected to a scheduling pipeli ne to incorporate multiple parallel working processors. Each scheduling stage is reworked into a load-balanced cluster to increase the number of parallel scheduling jobs further. This way, the still existing dynamic scheduling bottleneck of a centralized scheduler is widened, allowing handling 7x more processors with the pipelined, clustered dynamic scheduler for a typical signal processing application. The presented dynamic scheduling system assumes the presence of three different communication modes between the processing cores. When emulated on top of the commonly used remote direct memory access (RDMA) protocol, performance issues are encountered. Firstly, RDMA can neatly be used for single-shot point-to-point data transfers, like used in task graph scheduling. Process networks usually make use of high-volume and high-bandwidth data streams. A first in first out (FIFO) communication solution is presented that implements a cyclic buffer on both sender and receiver to serve this need. The buffer handling and data transfer between them are done purely in hardware to remove software overhead from the application. The implementation improves the multi-user access to area-efficient single port on-chip memory modules. It achieves 0.8 of the theoretically possible bandwidth, usually only achieved with area expensive dual-port memories. The third communication mode defines a lightweight message passing (MP) implementation that is truly connectionless. It is needed for efficient inter-process communication of the distributed and clustered scheduling system and the worker processing units’ tight coupling. A hardware flow control assures that an arbitrary number of senders can spontaneously start sending messages to the same receiver. Yet, all messages are guaranteed to be correctly received while eliminating the need for connection establishment and keeping a low message delay. The work focuses on the hardware-software codesign optimization to increase the uncompromised resource efficiency of dynamic SDF graph scheduling. Special attention is paid to the inter-level dependencies in developing a distributed scheduling system, which relies on the availability of specific hardwareaccelerated communication methods.:1 Introduction 1.1 Motivation 1.2 The Multiprocessor System on Chip Architecture 1.3 Concrete MPSoC Architecture 1.4 Representing LTE/5G baseband processing as Static Data Flow 1.5 Compuation Stack 1.6 Performance Hotspots Addressed 1.7 State of the Art 1.8 Overview of the Work 2 Hybrid SDF Execution 2.1 Addressed Performance Hotspot 2.2 State of the Art 2.3 Static Data Flow Graphs 2.4 Runtime Environment 2.5 Overhead of Deloying Tasks to a MPSoC 2.6 Interpretation of SDF Graphs as Task Graphs 2.7 Interpreting SDF Graphs as Process Networks 2.8 Hybrid Interpretation 2.9 Graph Topology Considerations 2.10 Theoretic Impact of Hybrid Interpretation 2.11 Simulating Hybrid Execution 2.12 Pipeline SDF Graph Example 2.13 Random SDF Graphs 2.14 LTE-like SDF Graph 2.15 Key Lernings 3 Distribution of Management 3.1 Addressed Performance Hotspot 3.2 State of the Art 3.3 Revising Deployment Overhead 3.4 Distribution of Overhead 3.5 Impact of Management Distribution to Resource Utilization 3.6 Reconfigurability 3.7 Key Lernings 4 Sliced FIFO Hardware 4.1 Addressed Performance Hotspot 4.2 State of the Art 4.3 System Environment 4.4 Sliced Windowed FIFO buffer 4.5 Single FIFO Evaluation 4.6 Multiple FIFO Evalutaion 4.7 Hardware Implementation 4.8 Key Lernings 5 Message Passing Hardware 5.1 Addressed Performance Hotspot 5.2 State of the Art 5.3 Message Passing Regarded as Queueing 5.4 A Remote Direct Memory Access Based Implementation 5.5 Hardware Implementation Concept 5.6 Evalutation of Performance 5.7 Key Lernings 6 Summar

Performance Optimization of Memory Intensive Applications on FPGA Accelerator

L'abstract è presente nell'allegato / the abstract is in the attachmen

Computing SpMV on FPGAs

There are hundreds of papers on accelerating sparse matrix vector multiplication (SpMV), however, only a handful target FPGAs. Some claim that FPGAs inherently perform inferiorly to CPUs and GPUs. FPGAs do perform inferiorly for some applications like matrix-matrix multiplication and matrix-vector multiplication. CPUs and GPUs have too much memory bandwidth and too much floating point computation power for FPGAs to compete. However, the low computations to memory operations ratio and irregular memory access of SpMV trips up both CPUs and GPUs. We see this as a leveling of the playing field for FPGAs. Our implementation focuses on three pillars: matrix traversal, multiply-accumulator design, and matrix compression. First, most SpMV implementations traverse the matrix in row-major order, but we mix column and row traversal. Second, To accommodate the new traversal the multiply accumulator stores many intermediate y values. Third, we compress the matrix to increase the transfer rate of the matrix from RAM to the FPGA. Together these pillars enable our SpMV implementation to perform competitively with CPUs and GPUs

An Efficient NoC-based Framework To Improve Dataflow Thread Management At Runtime

This doctoral thesis focuses on how the application threads that are based on dataflow execution model can be managed at Network-on-Chip (NoC) level. The roots of the dataflow execution model date back to the early 1970’s. Applications adhering to such program execution model follow a simple producer-consumer communication scheme for synchronising parallel thread related activities. In dataflow execution environment, a thread can run if and only if all its required inputs are available. Applications running on a large and complex computing environment can significantly benefit from the adoption of dataflow model. In the first part of the thesis, the work is focused on the thread distribution mechanism. It has been shown that how a scalable hash-based thread distribution mechanism can be implemented at the router level with low overheads. To enhance the support further, a tool to monitor the dataflow threads’ status and a simple, functional model is also incorporated into the design. Next, a software defined NoC has been proposed to manage the distribution of dataflow threads by exploiting its reconfigurability. The second part of this work is focused more on NoC microarchitecture level. Traditional 2D-mesh topology is combined with a standard ring, to understand how such hybrid network topology can outperform the traditional topology (such as 2D-mesh). Finally, a mixed-integer linear programming based analytical model has been proposed to verify if the application threads mapped on to the free cores is optimal or not. The proposed mathematical model can be used as a yardstick to verify the solution quality of the newly developed mapping policy. It is not trivial to provide a complete low-level framework for dataflow thread execution for better resource and power management. However, this work could be considered as a primary framework to which improvements could be carried out

Architectural Support for Hypervisor-Level Intrusion Tolerance in MPSoCs

Increasingly, more aspects of our lives rely on the correctness and safety of computing systems, namely in the embedded and cyber-physical (CPS) domains, which directly affect the physical world. While systems have been pushed to their limits of functionality and efficiency, security threats and generic hardware quality have challenged their safety. Leveraging the enormous modular power, diversity and flexibility of these systems, often deployed in multi-processor systems-on-chip (MPSoC), requires careful orchestration of complex and heterogeneous resources, a task left to low-level software, e.g., hypervisors. In current architectures, this software forms a single point of failure (SPoF) and a worthwhile target for attacks: once compromised, adversaries can gain access to all information and full control over the platform and the environment it controls, for instance by means of privilege escalation and resource allocation. Currently, solutions to protect low-level software often rely on a simpler, underlying trusted layer which is often a SPoF itself and/or exhibits downgraded performance. Architectural hybridization allows for the introduction of trusted-trustworthy components, which combined with fault and intrusion tolerance (FIT) techniques leveraging replication, are capable of safely handling critical operations, thus eliminating SPoFs. Performing quorum-based consensus on all critical operations, in particular privilege management, ensures no compromised low-level software can single handedly manipulate privilege escalation or resource allocation to negatively affect other system resources by propagating faults or further extend an adversary’s control. However, the performance impact of traditional Byzantine fault tolerant state-machine replication (BFT-SMR) protocols is prohibitive in the context of MPSoCs due to the high costs of cryptographic operations and the quantity of messages exchanged. Furthermore, fault isolation, one of the key prerequisites in FIT, presents a complicated challenge to tackle, given the whole system resides within one chip in such platforms. There is so far no solution completely and efficiently addressing the SPoF issue in critical low-level management software. It is our aim, then, to devise such a solution that, additionally, reaps benefit of the tight-coupled nature of such manycore systems. In this thesis we present two architectures, using trusted-trustworthy mechanisms and consensus protocols, capable of protecting all software layers, specifically at low level, by performing critical operations only when a majority of correct replicas agree to their execution: iBFT and Midir. Moreover, we discuss ways in which these can be used at application level on the example of replicated applications sharing critical data structures. It then becomes possible to confine software-level faults and some hardware faults to the individual tiles of an MPSoC, converting tiles into fault containment domains, thus, enabling fault isolation and, consequently, making way to high-performance FIT at the lowest level

Architectural Support for Hypervisor-Level Intrusion Tolerance in MPSoCs

Increasingly, more aspects of our lives rely on the correctness and safety of computing systems, namely in the embedded and cyber-physical (CPS) domains, which directly affect the physical world. While systems have been pushed to their limits of functionality and efficiency, security threats and generic hardware quality have challenged their safety. Leveraging the enormous modular power, diversity and flexibility of these systems, often deployed in multi-processor systems-on-chip (MPSoC), requires careful orchestration of complex and heterogeneous resources, a task left to low-level software, e.g., hypervisors. In current architectures, this software forms a single point of failure (SPoF) and a worthwhile target for attacks: once compromised, adversaries can gain access to all information and full control over the platform and the environment it controls, for instance by means of privilege escalation and resource allocation. Currently, solutions to protect low-level software often rely on a simpler, underlying trusted layer which is often a SPoF itself and/or exhibits downgraded performance. Architectural hybridization allows for the introduction of trusted-trustworthy components, which combined with fault and intrusion tolerance (FIT) techniques leveraging replication, are capable of safely handling critical operations, thus eliminating SPoFs. Performing quorum-based consensus on all critical operations, in particular privilege management, ensures no compromised low-level software can single handedly manipulate privilege escalation or resource allocation to negatively affect other system resources by propagating faults or further extend an adversary’s control. However, the performance impact of traditional Byzantine fault tolerant state-machine replication (BFT-SMR) protocols is prohibitive in the context of MPSoCs due to the high costs of cryptographic operations and the quantity of messages exchanged. Furthermore, fault isolation, one of the key prerequisites in FIT, presents a complicated challenge to tackle, given the whole system resides within one chip in such platforms. There is so far no solution completely and efficiently addressing the SPoF issue in critical low-level management software. It is our aim, then, to devise such a solution that, additionally, reaps benefit of the tight-coupled nature of such manycore systems. In this thesis we present two architectures, using trusted-trustworthy mechanisms and consensus protocols, capable of protecting all software layers, specifically at low level, by performing critical operations only when a majority of correct replicas agree to their execution: iBFT and Midir. Moreover, we discuss ways in which these can be used at application level on the example of replicated applications sharing critical data structures. It then becomes possible to confine software-level faults and some hardware faults to the individual tiles of an MPSoC, converting tiles into fault containment domains, thus, enabling fault isolation and, consequently, making way to high-performance FIT at the lowest level