We consider logic-based argumentation in which an argument is a pair (Phi, alpha), where the support Phi is a minimal consistent set of formulae taken from a given knowledge base (usually denoted by Delta) that entails the claim alpha (a formula). We study the complexity of three central problems in argumentation: the existence of a support Phi subset of Delta, the verification of a support, and the relevance problem (given psi, is there a support Phi such that psi is an element of Phi?). When arguments are given in the frill language of propositional logic, these problems are computationally costly tasks: the verification problem is DP-complete; the others are Sigma(P)(2)-complete. We study these problems in Schaefer's famous framework where the considered propositional formulae are in generalized conjunctive normal form. This means that formulae are conjunctions of constraints built upon a fixed finite set of Boolean relations Gamma (the constraint language). We show that according to the properties of this language Gamma, deciding whether there exists a support for a claim in a given knowledge base is either polynomial, NP-complete, coNP-complete, or Sigma(P)(2)-complete. We present a dichotomous classification, P or DP-complete, for the verification problem and a trichotomous classification for the relevance problem into either polynomial, NP-complete, or Sigma(P)(2)-complete. These last two classifications are obtained by means of algebraic tools.