Scalable Equivalence Checking and Verification of Shallow Quantum Circuits

This paper concerns the problem of checking if two shallow (i.e., constant-depth) quantum circuits perform equivalent computations. Equivalence checking is a fundamental correctness question -- needed, e.g., for ensuring that transformations applied to a quantum circuit do not alter its behavior. For quantum circuits, the problem is challenging because a straightforward representation on a classical computer of each circuit's quantum state can require time and space that are exponential in the number of qubits $n$. The paper presents decision procedures for two variants of the equivalence-checking problem. Both can be carried out on a classical computer in time and space that, for any fixed depth, is linear in $n$. Our critical insight is that local projections are precise enough to completely characterize the output state of a shallow quantum circuit. Instead of explicitly computing the output state of a circuit, we generate a set of local projections that serve as constraints on the output state. Moreover, the circuit's output state is the unique quantum state that satisfies all the constraints. Beyond equivalence checking, we show how to use the constraint representation to check a class of assertions, both statically and at run time. Our assertion-checking methods are sound and complete for assertions expressed as conjunctions of local projections. Our experiments show that on a server equipped with 2 x Intel\textsuperscript{\textregistered} Xeon\textsuperscript{\textregistered} Gold 6338 CPUs (128 threads total) and 1.0~TiB of RAM, running Ubuntu 20.04.6 LTS, the constraint representation of a random 100-qubit circuit of depth 6 can be computed in 19.8 seconds. For fixed inputs $\ket{0}^{\otimes 100}$, equivalence checking of {random} 100-qubit circuits of depth 3 takes 4.46 seconds; for arbitrary inputs, it takes no more than 31.96 seconds.