Q#: Enabling scalable quantum computing and development with a high-level domain-specific language
- Krysta M. Svore ,
- Alan Geller ,
- Matthias Troyer ,
- John Azariah ,
- Chris Granade ,
- Bettina Heim ,
- Vadym Kliuchnikov ,
- Mariia Mykhailova ,
- Andres Paz ,
- Martin Roetteler
https://arxiv.org/abs/1803.00652 |
Quantum computing exploits quantum phenomena such as superposition and entanglement to realize a form of parallelism that is not available to traditional computing. It offers the potential of significant computational speed-ups in quantum chemistry, materials science, cryptography, and machine learning. The dominant approach to programming quantum computers is to provide an existing high-level language with libraries that allow for the expression of quantum programs. This approach can permit computations that are meaningless in a quantum context; prohibits succinct expression of interaction between classical and quantum logic; and does not provide important constructs that are required for quantum programming. We present Q#, a quantum-focused domain-specific language explicitly designed to correctly, clearly and completely express quantum algorithms. Q# provides a type system, a tightly constrained environment to safely interleave classical and quantum computations; specialized syntax, symbolic code manipulation to automatically generate correct transformations of quantum operations, and powerful functional constructs which aid composition.