New portable consumer embedded devices must execute multimedia and wireless network applications that demand extensive memory footprint. Moreover, they must heavily rely on Dynamic Memory (DM) due to the unpredictability of the input data (e.g., 3D streams features) and system behavior (e.g., number of applications running concurrently defined by the user). Within this context, consistent design methodologies that can tackle efficiently the complex DM behavior of these multimedia and network applications are in great need. In this article, we present a new methodology that allows to design custom DM management mechanisms with a reduced memory footprint for such kind of dynamic applications. First, our methodology describes the large design space of DM management decisions for multimedia and wireless network applications. Then, we propose a suitable way to traverse the aforementioned design space and construct custom DM managers that minimize the DM used by these highly dynamic applications. As a result, our methodology achieves improvements of memory footprint by 60% on average in real case studies over the current state-of-the-art DM managers used for these types of dynamic applications.
In the near future, portable embedded devices must run multimedia and wireless network applications with enormous computational performance (1-40GOPS) requirements at a low energy consumption (0.1-2 W). In these applications, the dynamic memory subsystem is currently one of the main sources of power consumption and its inappropriate management can severely affect the performance of the whole system. Within this context, the construction and power evaluation of custom memory managers is one of the most difficult parts for an efficient mapping of such dynamic applications on low-power embedded systems. In this paper, we present a new system-level approach to model complex dynamic memory managers integrating detailed power profiling information. This approach allows to obtain power consumption estimates, memory footprint and memory access values to refine the dynamic memory ARTICLE IN PRESS www.elsevier.com/locate/vlsi 0167-9260/$ -see front matter r
Embedded consumer devices are increasing their capabilities and can now implement new multimedia applications reserved only for powerful desktops a few years ago. These applications share complex and intensive dynamic memory use. Thus, dynamic memory optimizations are a requirement when porting these applications. Within these optimizations, the refinement of the Dynamically (de)allocated Data Type (or DDT) implementations is one of the most important and difficult parts for an efficient mapping onto low-power embedded devices.In this paper, we describe a new automatic optimization approach for the DDTs of object-oriented multimedia applications. It is based on an analytical pre-characterization of the possible elementary DDT blocks, and a multi-objective genetic algorithm to explore the design space and to select the best implementation according to different optimization criteria (i.e., memory accesses, memory footprint and energy consumption). Our results in real-life multimedia applications show that the best implementations of DDTs can be obtained in an automated way in few hours, while typically designers would require days to find a suitable implementation, achieving important savings in exploration time with respect to other state-of-the-art heuristics-based optimization methods for this task.
The next generation of embedded systems will be dominated by mobile devices, which are able to deliver communications and rich multimedia content anytime, anywhere. The major themes in these ubiquitous computing systems are applications with increased user control and interactivity with the environment. Therefore, the storage of dynamic data increases, thus making the dynamic memory allocation of heap data at run time a very important component with heavy energy consumption. In this paper, we propose a novel script, which heavily customizes the dynamic memory allocator according to the target application domain and the underlying memory hierarchy of the embedded system. The dynamic memory allocator resides in the middleware level or in the Operating System level (whenever it is available). The result of our script and automated tools is the reduction of energy consumption by 72% on average and the reduction of the execution time by 40% on average, which is demonstrated with the use of 1 real life wireless network application and 1 multimedia application.
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