Noncommutative Valiant's Classes: Structure and Complete Problems

Abstract

In this paper we explore the noncommutative analogues, VPnc and VNPnc, of Valiant's algebraic complexity classes and show some striking connections to classical formal language theory. Our main results are the following: (1) We show that Dyck polynomials (defined from the Dyck languages of formal language theory) are complete for the class VPnc under abp reductions. Likewise, it turns out that PAL (Palindrome polynomials defined from palindromes) are complete for the class VSKEWnc (defined by polynomial-size skew circuits) under abp reductions. The proof of these results is by suitably adapting the classical Chomsky-Sch\"utzenberger theorem showing that Dyck languages are the hardest CFLs. (2) Next, we consider the class VNPnc. It is known~HWY10a that, assuming the sum-of-squares conjecture, the noncommutative polynomial Σw∈\x0,x1\nww requires exponential size circuits. We unconditionally show that Σw∈\x0,x1\nww is not VNPnc-complete under the projection reducibility. As a consequence, assuming the sum-of-squares conjecture, we exhibit a strictly infinite hierarchy of p-families under projections inside VNPnc (analogous to Ladner's theorem~Ladner75). In the final section we discuss some new VNPnc-complete problems under abp-reductions. (3) Inside VPnc too we show there is a strict hierarchy of p-families (based on the nesting depth of Dyck polynomials) under the abp reducibility.