Compilation of Quantum Applications to Hardware Primitives

We present results from compilation software that tailors the execution of quantum applications to underlying hardware primitives. Exemplar techniques employed include native gateset decomposition, echoed noise mitigation, dynamical decoupling, noise-aware mapping, and crosstalk avoidance. In each such technique, the compiler must be made aware of the underlying device physics. We present experimental results from cold atom, superconducting, and trapped ion hardware. On multiple benchmark applications, we observe 10x improvements in performance, with further enhancements possible at larger program sizes.