Search Space Reduction for Efficient Quantum Compilation
Authors: 
Amisha Srivastava, Chao Lu, Navnil Choudhury, Ayush Arunachalam, Kanad BasuAuthors Info & Claims
Pages 109 - 114
Abstract
Quantum computers have demonstrated exponential speedup for certain computational tasks like integer factorization, molecular simulation, and machine learning, compared to the classical computers. One of the most challenging problems in quantum computing is quantum compilation, which involves the translation of a quantum circuit into a representation that adheres to the constraints imposed by the quantum hardware. However, this process of mapping the logical qubits to physical qubits incurs a significantly large search space, which needs to be analyzed to obtain the optimal mapping. A non-optimal mapping or compilation strategy introduces additional hardware overhead, thereby rendering inefficiency. Recently, researchers have proposed a technique to reduce the search space for efficient quantum compilation. However, this approach focuses on a generic solution involving only the physical architecture, and hence, as shown in our paper, often fails to incorporate the optimal solution in the reduced search space. To this end, we propose PERM and SGO (PAS), which, to the best of our knowledge, is the first quantum compilation strategy that facilitates a reduced search space comprising a more optimal solution in terms of additional CNOT gates compared to the existing technique. Our experimental evaluation using the MQT benchmarks demonstrates the efficacy of our approach, which furnishes up to 428x reduction compared to the unoptimized search space, and 57.1x reduction compared to existing research, while providing savings in terms of additional CNOT gates by up to 53.85%.
References
[1]
Alan Bundy et al. 1984. Breadth-first search. In Catalogue of artificial intelligence tools. Springer, 13--13.
[2]
Lukas Burgholzer et al. 2022. Limiting the Search Space in Optimal Quantum Circuit Mapping. In IEEE ASP-DAC.
[3]
Yudong Cao et al. 2019. Quantum chemistry in the age of quantum computing. Chemical reviews, Vol. 119, 19 (2019), 10856--10915.
[4]
Jerry Chow et al. 2021. IBM Quantum breaks the 100-qubit processor barrier. IBM Research Blog (2021).
[5]
Carlo Ciliberto et al. 2018. Quantum machine learning: a classical perspective. Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, Vol. 474, 2209 (2018), 20170551.
[6]
Craig Gidney et al. 2021. How to factor 2048 bit RSA integers in 8 hours using 20 million noisy qubits. Quantum, Vol. 5 (2021), 433.
[7]
Lov K Grover. 1996. A fast quantum mechanical algorithm for database search. In ACM TC. 212--219.
[8]
Murali et al. 2019. Noise-adaptive compiler mappings for noisy intermediate-scale quantum computers. In ASPLOS.
[9]
Peter W Shor. 1999. Polynomial-time algorithms for prime factorization and discrete logarithms on a quantum computer. SIAM review (1999).
[10]
Bochen Tan et al. 2020. Optimal layout synthesis for quantum computing. In IEEE/ACM ICCAD.
[11]
Jean Vuillemin. 1978. A data structure for manipulating priority queues. Commun. ACM, Vol. 21, 4 (1978), 309--315.
[12]
Robert Wille et al. 2020. JKQ: JKU tools for quantum computing. In IEEE ICCAD.
[13]
James R Wootton et al. 2021. Teaching quantum computing with an interactive textbook. In IEEE QCE. 385--391.
Index Terms
- Search Space Reduction for Efficient Quantum Compilation
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Information
Published In
June 2023
731 pages
ISBN:9798400701252
DOI:10.1145/3583781
- General Chairs:
- Himanshu Thapliyal,
- Ronald DeMara,
- Program Chairs:
- Inna Partin-Vaisband,
- Srinivas Katkoori
Copyright © 2023 Owner/Author.
This work is licensed under a Creative Commons Attribution International 4.0 License.
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Association for Computing Machinery
New York, NY, United States
Publication History
Published: 05 June 2023
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- National Science Foundation
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GLSVLSI '23
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