Some notes about the use of unification in Coq ---------------------------------------------- There are several applications of unification and pattern-matching ** Unification of types ** - For type inference, inference of implicit arguments * this basically amounts to solve problems of the form T <= U or T = U where T and U are types coming from a given typing problem * this kind of problem has to succeed and all the power of unification is a priori expected (full beta/delta/iota/zeta/nu/mu, pattern-unification, pruning, imitation/projection heuristics, ...) - For lemma application (apply, auto, ...) * these are also problems of the form T <= U on types but with T coming from a lemma and U from the goal * it is not obvious that we always want unification and not matching * it is not clear which amounts of delta one wants to use ** Looking for subterms ** - For tactics applying on subterms: induction, destruct, rewrite - As part of unification of types in the presence of higher-order evars (e.g. when applying a lemma of conclusion "?P t") ---------------------------------------------------------------------- Here are examples of features one may want or not when looking for subterms A- REWRITING 1- Full conversion on closed terms 1a- Full conversion on closed terms in the presence of at least one evars (meta) Section A1. Variable y: nat. Hypothesis H: forall x, x+2 = 0. Goal y+(1+1) = 0. rewrite H. (* 0 = 0 *) Abort. Goal 2+(1+1) = 0. rewrite H. (* 0 = 0 *) Abort. (* This exists since the very beginning of Chet's unification for tactics *) (* But this fails for setoid rewrite *) 1b- Full conversion on closed terms without any evars in the lemma 1b.1- Fails on rewrite (because Unification.w_unify_to_subterm_list replaces unification by check for a syntactic subterm if terms has no evar/meta) Goal 0+1 = 0 -> 0+(1+0) = 0. intros H; rewrite H. (* fails *) Abort. 1b.2- Works with setoid rewrite Require Import Setoid. Goal 0+1 = 0 -> 0+(1+0) = 0. intros H; rewrite H at 1. (* 0 = 0 *) Abort. 2- Using known instances in full conversion on closed terms Section A2. Hypothesis H: forall x, x+(2+x) = 0. Goal 1+(1+2) = 0. rewrite H. Abort. End A2. (* This exists since 8.2 (HH) *) 3- Pattern-unification on Rels Section A3a. Variable F: (nat->nat->nat)->nat. Goal exists f, F (fun x y => f x y) = 0 -> F (fun x y => plus y x) = 0. eexists. intro H; rewrite H. (* 0 = 0 *) Abort. End A3a. (* Works since pattern unification on Meta applied to Rel was introduced *) (* in unification.ml (8.1, Sep 2006, HH) *) Section A3b. Variables x y: nat. Variable H: forall f, f x y = 0. Goal plus y x = 0. rewrite H. (* 0 = 0 *) Abort. End A3b. (* Works since pattern unification on all Meta was supported *) (* in unification.ml (8.4, Jun 2011, HH) *) 4- Unification with open terms Section A4. Hypothesis H: forall x, S x = 0. Goal S 0 = 0. rewrite (H _). (* 0 = 0 *) Abort. End A4. (* Works since unification on Evar was introduced so as to support rewriting *) (* with open terms (8.2, MS, r11543, Unification.w_unify_to_subterm_list ) *) 5- Unification of pre-existing evars 5a- Basic unification of pre-existing evars Section A4. Variables x y: nat. Goal exists z, S z = 0 -> S (plus y x) = 0. eexists. intro H; rewrite H. (* 0 = 0 *) Abort. End A4. (* This worked in 8.2 and 8.3 as a side-effect of support for rewriting *) (* with open terms (8.2, MS, r11543) *) 5b- Pattern-unification of pre-existing evars in rewriting lemma Goal exists f, forall x y, f x y = 0 -> plus y x = 0. eexists. intros x y H; rewrite H. (* 0 = 0 *) Abort. (* Works since pattern-unification on Evar was introduced *) (* in unification.ml (8.3, HH, r12229) *) (* currently governed by a flag: use_evars_pattern_unification *) 5c- Pattern-unification of pre-existing evars in goal Goal exists f, forall x y, plus x y = 0 -> f y x = 0. eexists. intros x y H; rewrite H. (* 0 = 0 *) Abort. (* This worked in 8.2 and 8.3 but was removed for autorewrite in 8.4 *) 5d- Mixing pattern-unification of pre-existing evars in goal and evars in lemma Goal exists f, forall x, (forall y, plus x y = 0) -> forall y:nat, f y x = 0. eexists. intros x H y. rewrite H. (* 0 = 0 *) Abort. (* This worked in 8.2 and 8.3 but was removed for autorewrite in 8.4 *) 6- Multiple non-identical but convertible occurrences Tactic rewrite only considers the first one, from left-to-right, e.g.: Section A6. Variable y: nat. Hypothesis H: forall x, x+2 = 0. Goal (y+(2+0))+(y+(1+1)) = (y+(1+1))+(y+(2+0)). rewrite H. (* 0+(y+(1+1)) = y+(1+1)+0 *) Abort. End A6. Tactic setoid rewrite first looks for syntactically equal terms and if not uses the leftmost occurrence modulo delta. Require Import Setoid. Section A6. Variable y: nat. Hypothesis H: forall x, x+2 = 0. Goal (y+(2+0))+(y+2) = (y+2)+(y+(2+0)). rewrite H at 1 2 3 4. (* (y+(2+0))+0 = 0+(y+(2+0)) *) Abort. Goal (y+(2+0))+(y+(1+1)) = (y+(1+1))+(y+(2+0)). rewrite H at 1 2 3 4. (* 0+(y+(1+1)) = y+(1+1)+0 *) Abort. End A6. 7- Conversion Section A6. Variable y: nat. Hypothesis H: forall x, S x = 0. Goal id 1 = 0. rewrite H. B- ELIMINATION (INDUCTION / CASE ANALYSIS) This is simpler because open terms are not allowed and no unification is involved (8.3).