IQP circuits for 2-Forrelation

Abstract

The 2-Forrelation problem provides an optimal separation between classical and quantum query complexity and is also the problem used for separating BQP and PH relative to an oracle. A natural question is therefore to ask what are the minimal quantum resources needed to solve this problem. We show that 2-Forrelation can be solved using Instantaneous Quantum Polynomial-time (IQP) circuits, a restricted model of quantum computation in which all gates commute. Concretely, two IQP circuits with two quantum queries and efficient classical processing suffice. For the signed variant of 2-Forrelation, even a single IQP circuit and query suffices. This answers a recent open question of Girish (arXiv:2510.06385) on the power of commuting quantum computations. We use this to show that (BPPIQP)O ⊂eq PHO relative to an oracle O, strengthening the result of Raz and Tal (STOC 2019). Our results show that IQP circuits can be used for classically hard decision problems, thus providing a new route for showing quantum advantage with IQP circuits, avoiding the verification difficulties associated with sampling tasks. We also prove Fourier growth bounds for IQP circuits in terms of the size of their accepting set. The key ingredient is an algebraic identity of the quadratic function Q(x) = Σi < j xixj that allows extracting inner-product phases within an IQP circuit.