Complexity theory of orbit closure intersection for tensors: reductions, completeness, and graph isomorphism hardness

TL;DR

This paper introduces a complexity class for orbit closure intersection problems in tensors, establishes their computational hardness, and connects them to graph isomorphism, revealing the intrinsic difficulty of these problems.

Contribution

It defines the class TOCI for tensor orbit closure intersection problems, identifies complete problems, and links them to graph isomorphism, advancing understanding of their computational complexity.

Findings

TOCI captures the complexity of tensor orbit closure intersection problems.

Graph isomorphism reduces to tensor orbit closure intersection problems, indicating high complexity.

Established the first lower bound on the complexity of these problems.

Abstract

Many natural computational problems in computer science, mathematics, physics, and other sciences amount to deciding if two objects are equivalent. Often this equivalence is defined in terms of group actions. A natural question is to ask when two objects can be distinguished by polynomial functions that are invariant under the group action. For finite groups, this is the usual notion of equivalence, but for continuous groups like the general linear groups it gives rise to a new notion, called orbit closure intersection. It captures, among others, the graph isomorphism problem, noncommutative PIT, null cone problems in invariant theory, equivalence problems for tensor networks, and the classification of multiparty quantum states. Despite recent algorithmic progress in celebrated special cases, the computational complexity of general orbit closure intersection problems is currently quite unclear. In particular, tensors seem to give rise to the most difficult problems. In this work we start a systematic study of orbit closure intersection from the complexity-theoretic viewpoint. To this end, we define a complexity class TOCI that captures the power of orbit closure intersection problems for general tensor actions, give an appropriate notion of algebraic reductions that imply polynomial-time reductions in the usual sense, but are amenable to invariant-theoretic techniques, identify natural tensor problems that are complete for TOCI, including the equivalence of 2D tensor networks with constant physical dimension, and show that the graph isomorphism problem can be reduced to these complete problems, hence GI$\subseteq$TOCI. As such, our work establishes the first lower bound on the computational complexity of orbit closure intersection problems, and it explains the difficulty of finding unconditional polynomial-time algorithms beyond special cases, as has been observed in the literature.