The free bifibration on a functor

Abstract

We consider the problem of constructing the free bifibration generated by a functor of categories p : D C. This problem was previously considered by Lamarche, and is closely related to the problem, considered by Dawson, Par\'e, and Pronk, of ``freely adjoining adjoints'' to a category. We develop a proof-theoretic approach to the problem, beginning with a construction of the free bifibration p : Bifib(p) C in which objects of Bifib(p) are formulas of a primitive ``bifibrational logic'', and arrows are derivations in a cut-free sequent calculus modulo a notion of permutation equivalence. We show that instantiating the construction to the identity functor generates a zigzag double category Z(C), which is also the free double category with companions and conjoints (or fibrant double category) on C. The approach adapts smoothly to the more general task of building (P,N)-fibrations, where one only asks for pushforwards along arrows in P and pullbacks along arrows in N for some subsets of arrows; this encompasses Kock and Joyal's notion of ambifibration when (P,N) form a factorization system. We establish a series of progressively stronger normal forms, guided by ideas of focusing from proof theory, and obtain a canonicity result under assumption that the base category is factorization preordered relative to P and N. This canonicity result allows us to decide the word problem and to enumerate relative homsets without duplicates. Finally, we describe several examples of a combinatorial nature, including a category of plane trees generated as a free bifibration over ω, and a category of increasing forests generated as a free ambifibration over , which contains the lattices of noncrossing partitions as quotients of its fibers by the Beck-Chevalley condition for bicartesian squares.

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