Improving multithreading performance for clustered VLIW architectures.

Very Long Instruction Word (VLIW) processors are very popular in embedded and mobile computing domain. Use of VLIW processors range from Digital Signal Processors (DSPs) found in a plethora of communication and multimedia devices to Graphics Processing Units (GPUs) used in gaming and high performance computing devices. The advantage of VLIWs is their low complexity and low power design which enable high performance at a low cost. Scalability of VLIWs is limited by the scalability of register file ports. It is not viable to have a VLIW processor with a single large register file because of area and power consumption implications of the register file. Clustered VLIW solve the register file scalability issue by partitioning the register file into multiple clusters and a set of functional units that are attached to register file of that cluster. Using a clustered approach, higher issue width can be achieved while keeping the cost of register file within reasonable limits. Several commercial VLIW processors have been designed using the clustered VLIW model. VLIW processors can be used to run a larger set of applications. Many of these applications have a good Lnstruction Level Parallelism (ILP) which can be efficiently utilized. However, several applications, specially the ones that are control code dominated do not exibit good ILP and the processor is underutilized. Cache misses is another major source of resource underutiliztion. Multithreading is a popular technique to improve processor utilization. Interleaved MultiThreading (IMT) hides cache miss latencies by scheduling a different thread each cycle but cannot hide unused instructions slots. Simultaneous MultiThread (SMT) can also remove ILP under-utilization by issuing multiple threads to fill the empty instruction slots. However, SMT has a higher implementation cost than IMT. The thesis presents Cluster-level Simultaneous MultiThreading (CSMT) that supports a limited form of SMT where VLIW instructions from different threads are merged at a cluster-level granularity. This lowers the hardware implementation cost to a level comparable to the cheap IMT technique. The more complex SMT combines VLIW instructions at the individual operation-level granularity which is quite expensive especially in for a mobile solution. We refer to SMT at operation-level as OpSMT to reduce ambiguity. While previous studies restricted OpSMT on a VLIW to 2 threads, CSMT has a better scalability and upto 8 threads can be supported at a reasonable cost. The thesis proposes several other techniques to further improve CSMT performance. In particular, Cluster renaming remaps the clusters used by instructions of different threads to reduce resource conflicts. Cluster renaming is quite effective in reducing the issue-slots under-utilization and significantly improves CSMT performance.The thesis also proposes: a hybrid between IMT and CSMT which increases the number of supported threads, heterogeneous instruction merging where some instructions are combined using SMT and CSMT rest, and finally, split-issue, a technique that allows to launch partially an instruction making it easier to be combined with others

A configurable vector processor for accelerating speech coding algorithms

The growing demand for voice-over-packer (VoIP) services and multimedia-rich applications has made increasingly important the efficient, real-time implementation of low-bit rates speech coders on embedded VLSI platforms. Such speech coders are designed to substantially reduce the bandwidth requirements thus enabling dense multichannel gateways in small form factor. This however comes at a high computational cost which mandates the use of very high performance embedded processors. This thesis investigates the potential acceleration of two major ITU-T speech coding algorithms, namely G.729A and G.723.1, through their efficient implementation on a configurable extensible vector embedded CPU architecture. New scalar and vector ISAs were introduced which resulted in up to 80% reduction in the dynamic instruction count of both workloads. These instructions were subsequently encapsulated into a parametric, hybrid SISD (scalar processor)–SIMD (vector) processor. This work presents the research and implementation of the vector datapath of this vector coprocessor which is tightly-coupled to a Sparc-V8 compliant CPU, the optimization and simulation methodologies employed and the use of Electronic System Level (ESL) techniques to rapidly design SIMD datapaths

ACOTES project: Advanced compiler technologies for embedded streaming

Streaming applications are built of data-driven, computational components, consuming and producing unbounded data streams. Streaming oriented systems have become dominant in a wide range of domains, including embedded applications and DSPs. However, programming efficiently for streaming architectures is a challenging task, having to carefully partition the computation and map it to processes in a way that best matches the underlying streaming architecture, taking into account the distributed resources (memory, processing, real-time requirements) and communication overheads (processing and delay). These challenges have led to a number of suggested solutions, whose goal is to improve the programmer’s productivity in developing applications that process massive streams of data on programmable, parallel embedded architectures. StreamIt is one such example. Another more recent approach is that developed by the ACOTES project (Advanced Compiler Technologies for Embedded Streaming). The ACOTES approach for streaming applications consists of compiler-assisted mapping of streaming tasks to highly parallel systems in order to maximize cost-effectiveness, both in terms of energy and in terms of design effort. The analysis and transformation techniques automate large parts of the partitioning and mapping process, based on the properties of the application domain, on the quantitative information about the target systems, and on programmer directives. This paper presents the outcomes of the ACOTES project, a 3-year collaborative work of industrial (NXP, ST, IBM, Silicon Hive, NOKIA) and academic (UPC, INRIA, MINES ParisTech) partners, and advocates the use of Advanced Compiler Technologies that we developed to support Embedded Streaming.Peer ReviewedPostprint (published version

Reducing soft errors through operand width aware policies

Soft errors are an important challenge in contemporary microprocessors. Particle hits on the components of a processor are expected to create an increasing number of transient errors with each new microprocessor generation. In this paper, we propose simple mechanisms that effectively reduce the vulnerability to soft errors in a processor. Our designs are generally motivated by the fact that many of the produced and consumed values in the processors are narrow and their upper order bits are meaningless. Soft errors caused by any particle strike to these higher order bits can be avoided by simply identifying these narrow values. Alternatively, soft errors can be detected or corrected on the narrow values by replicating the vulnerable portion of the value inside the storage space provided for the upper order bits of these operands. As a faster but less fault tolerant alternative to ECC and parity, we offer a variety of schemes that make use of narrow values and analyze their efficiency in reducing soft error vulnerability of different data-holding components of a processor. On average, techniques that make use of the narrowness of the values can provide 49 percent error detection, 45 percent error correction, or 27 percent error avoidance coverage for single bit upsets in the first level data cache across all Spec2K. In other structures such as the immediate field of the issue queue, an average error detection rate of 64 percent is achieved.Peer ReviewedPostprint (published version

State of the art baseband DSP platforms for Software Defined Radio: A survey

Software Defined Radio (SDR) is an innovative approach which is becoming a more and more promising technology for future mobile handsets. Several proposals in the field of embedded systems have been introduced by different universities and industries to support SDR applications. This article presents an overview of current platforms and analyzes the related architectural choices, the current issues in SDR, as well as potential future trends.Peer reviewe