TY - GEN
T1 - Compiler-directed channel allocation for savins power in on-chip networks
AU - Chen, Guangyu
AU - Li, Feihui
AU - Kandemir, Mahmut
PY - 2006
Y1 - 2006
N2 - Increasing complexity in the communication patterns of embedded applications parallelized over multiple processing units makes it difficult to continue using the traditional bus-based on-chip communication techniques. The main contribution of this paper is to demonstrate the importance of compiler technology in reducing power consumption of applications designed for emerging multi-processor, NoC (Network-on-Chip) based embedded systems. Specifically, we propose and evaluate a compiler-directed approach to NoC power management in the context of array-intensive applications, used frequently in embedded image/video processing. The unique characteristic of the compiler-based approach proposed in this paper is that it increases the idle periods of communication channels by reusing the same set of channels for as many communication messages as possible. The unused channels in this case take better advantage of the underlying power saving mechanism employed by the network architecture. However, this channel reuse optimization should be applied with care as it can hurt performance if two or more simultaneous communications are mapped onto the same set of channels. Therefore, the problem addressed in this paper is one of reducing the number of channels used to implement a set of communications without increasing the communication latency significantly. To test the effectiveness of our approach, we implemented it within an optimizing compiler and performed experiments using twelve application codes and a network simulation environment. Our experiments show that the proposed compilerbased approach is very successful in practice and works well under both hardware based and software based channel turn-off schemes.
AB - Increasing complexity in the communication patterns of embedded applications parallelized over multiple processing units makes it difficult to continue using the traditional bus-based on-chip communication techniques. The main contribution of this paper is to demonstrate the importance of compiler technology in reducing power consumption of applications designed for emerging multi-processor, NoC (Network-on-Chip) based embedded systems. Specifically, we propose and evaluate a compiler-directed approach to NoC power management in the context of array-intensive applications, used frequently in embedded image/video processing. The unique characteristic of the compiler-based approach proposed in this paper is that it increases the idle periods of communication channels by reusing the same set of channels for as many communication messages as possible. The unused channels in this case take better advantage of the underlying power saving mechanism employed by the network architecture. However, this channel reuse optimization should be applied with care as it can hurt performance if two or more simultaneous communications are mapped onto the same set of channels. Therefore, the problem addressed in this paper is one of reducing the number of channels used to implement a set of communications without increasing the communication latency significantly. To test the effectiveness of our approach, we implemented it within an optimizing compiler and performed experiments using twelve application codes and a network simulation environment. Our experiments show that the proposed compilerbased approach is very successful in practice and works well under both hardware based and software based channel turn-off schemes.
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M3 - Conference contribution
AN - SCOPUS:33745842608
SN - 1595930272
SN - 9781595930279
T3 - Conference Record of the Annual ACM Symposium on Principles of Programming Languages
SP - 194
EP - 205
BT - Conference Record of POPL 2006
ER -