package rocq-runtime
The Rocq Prover -- Core Binaries and Tools
Install
dune-project
Dependency
Authors
Maintainers
Sources
rocq-9.2.0.tar.gz
sha256=a45280ab4fbaac7540b136a6b073b4a6db15739ec1e149bded43fa6f4fc25f20
doc/src/rocq-runtime.engine/univSubst.ml.html
Source file univSubst.ml
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 154 155 156 157 158 159 160 161 162 163 164 165 166 167 168 169 170 171 172 173 174 175 176 177 178 179 180 181 182 183 184 185 186 187 188 189 190 191 192 193 194 195 196 197 198 199 200 201 202 203 204 205 206 207 208 209 210 211 212 213 214(************************************************************************) (* * The Rocq Prover / The Rocq Development Team *) (* v * Copyright INRIA, CNRS and contributors *) (* <O___,, * (see version control and CREDITS file for authors & dates) *) (* \VV/ **************************************************************) (* // * This file is distributed under the terms of the *) (* * GNU Lesser General Public License Version 2.1 *) (* * (see LICENSE file for the text of the license) *) (************************************************************************) open Sorts open Util open Constr open Univ open UVars type 'a universe_map = 'a Level.Map.t type universe_subst = Universe.t universe_map type universe_subst_fn = Level.t -> Universe.t option type universe_level_subst_fn = Level.t -> Level.t type quality_subst = Quality.t QVar.Map.t type quality_subst_fn = QVar.t -> Quality.t let subst_univs_universe fn ul = let addn n u = iterate Universe.super n u in let subst, nosubst = List.fold_right (fun (u, n) (subst,nosubst) -> match fn u with | Some u' -> let a' = addn n u' in (a' :: subst, nosubst) | None -> (subst, (u, n) :: nosubst)) (Universe.repr ul) ([], []) in match subst with | [] -> ul | u :: ul -> let substs = List.fold_left Universe.sup u subst in List.fold_left (fun acc (u, n) -> Universe.sup acc (addn n (Universe.make u))) substs nosubst let enforce_eq u v c = if Universe.equal u v then c else match Universe.level u, Universe.level v with | Some u, Some v -> enforce_eq_level u v c | _ -> CErrors.anomaly (Pp.str "A universe comparison can only happen between variables.") let constraint_add_leq v u c = let eq (x, n) (y, m) = Int.equal m n && Level.equal x y in (* We just discard trivial constraints like u<=u *) if eq v u then c else match v, u with | (x,n), (y,m) -> let j = m - n in if j = -1 (* n = m+1, v+1 <= u <-> v < u *) then UnivConstraints.add (x,Lt,y) c else if j <= -1 (* n = m+k, v+k <= u and k>0 *) then if Level.equal x y then (* u+k <= u with k>0 *) UnivConstraints.add (x,Lt,x) c else CErrors.user_err (Pp.str"Unable to handle arbitrary u+k <= v constraints.") else if j = 0 then UnivConstraints.add (x,Le,y) c else (* j >= 1 *) (* m = n + k, u <= v+k *) if Level.equal x y then c (* u <= u+k, trivial *) else if Level.is_set x then c (* Prop,Set <= u+S k, trivial *) else UnivConstraints.add (x,Le,y) c (* u <= v implies u <= v+k *) let check_univ_leq_one u v = let leq (u,n) (v,n') = let cmp = Level.compare u v in if Int.equal cmp 0 then n <= n' else false in Universe.exists (leq u) v let check_univ_leq u v = Universe.for_all (fun u -> check_univ_leq_one u v) u let enforce_leq u v c = List.fold_left (fun c v -> (List.fold_left (fun c u -> constraint_add_leq u v c) c u)) c v let enforce_leq u v c = if check_univ_leq u v then c else enforce_leq (Universe.repr u) (Universe.repr v) c let enforce_univ_constraint (u,d,v) = match d with | UnivConstraint.Eq -> enforce_eq u v | UnivConstraint.Le -> enforce_leq u v | UnivConstraint.Lt -> enforce_leq (Universe.super u) v let subst_univs_constraint fn (u,d,v as c) cstrs = let u' = fn u in let v' = fn v in match u', v' with | None, None -> UnivConstraints.add c cstrs | Some u, None -> enforce_univ_constraint (u,d,Universe.make v) cstrs | None, Some v -> enforce_univ_constraint (Universe.make u,d,v) cstrs | Some u, Some v -> enforce_univ_constraint (u,d,v) cstrs let subst_univs_constraints subst csts = UnivConstraints.fold (fun c cstrs -> subst_univs_constraint subst c cstrs) csts UnivConstraints.empty let level_subst_of f = fun l -> match f l with | None -> l | Some u -> match Universe.level u with | None -> assert false | Some l -> l let subst_univs_fn_puniverses f (c, u as cu) = let u' = Instance.subst_fn f u in if u' == u then cu else (c, u') let map_universes_opt_subst_with_binders next aux frel fqual funiv k c = let flevel = fqual, level_subst_of funiv in let aux_rec ((nas, tys, bds) as rc) = let nas' = Array.Smart.map (Context.map_annot_relevance frel) nas in let tys' = Array.Fun1.Smart.map aux k tys in let k' = iterate next (Array.length tys') k in let bds' = Array.Fun1.Smart.map aux k' bds in if nas' == nas && tys' == tys && bds' == bds then rc else (nas', tys', bds') in let aux_ctx ((nas, c) as p) = let nas' = Array.Smart.map (Context.map_annot_relevance frel) nas in let k' = iterate next (Array.length nas) k in let c' = aux k' c in if nas' == nas && c' == c then p else (nas', c') in match kind c with | Const pu -> let pu' = subst_univs_fn_puniverses flevel pu in if pu' == pu then c else mkConstU pu' | Ind pu -> let pu' = subst_univs_fn_puniverses flevel pu in if pu' == pu then c else mkIndU pu' | Construct pu -> let pu' = subst_univs_fn_puniverses flevel pu in if pu' == pu then c else mkConstructU pu' | Sort s -> let s' = Sorts.subst_fn (fqual, subst_univs_universe funiv) s in if s' == s then c else mkSort s' | Case (ci,u,pms,(p,rel),iv,t,br) -> let u' = Instance.subst_fn flevel u in let rel' = frel rel in let pms' = Array.Fun1.Smart.map aux k pms in let p' = aux_ctx p in let iv' = map_invert (aux k) iv in let t' = aux k t in let br' = Array.Smart.map aux_ctx br in if rel' == rel && u' == u && pms' == pms && p' == p && iv' == iv && t' == t && br' == br then c else mkCase (ci, u', pms', (p',rel'), iv', t', br') | Array (u,elems,def,ty) -> let u' = Instance.subst_fn flevel u in let elems' = CArray.Fun1.Smart.map aux k elems in let def' = aux k def in let ty' = aux k ty in if u == u' && elems == elems' && def == def' && ty == ty' then c else mkArray (u',elems',def',ty') | Prod (na, t, u) -> let na' = Context.map_annot_relevance frel na in let t' = aux k t in let u' = aux (next k) u in if na' == na && t' == t && u' == u then c else mkProd (na', t', u') | Lambda (na, t, u) -> let na' = Context.map_annot_relevance frel na in let t' = aux k t in let u' = aux (next k) u in if na' == na && t' == t && u' == u then c else mkLambda (na', t', u') | LetIn (na, b, t, u) -> let na' = Context.map_annot_relevance frel na in let b' = aux k b in let t' = aux k t in let u' = aux (next k) u in if na' == na && b' == b && t' == t && u' == u then c else mkLetIn (na', b', t', u') | Fix (i, rc) -> let rc' = aux_rec rc in if rc' == rc then c else mkFix (i, rc') | CoFix (i, rc) -> let rc' = aux_rec rc in if rc' == rc then c else mkCoFix (i, rc') | Proj (p, r, v) -> let r' = frel r in let v' = aux k v in if r' == r && v' == v then c else mkProj (p, r', v') | _ -> Constr.map_with_binders next aux k c let nf_evars_and_universes_opt_subst fevar frel fqual funiv c = let rec self () c = match Constr.kind c with | Evar (evk, args) -> let args' = SList.Smart.map (self ()) args in begin match try fevar (evk, args') with Not_found -> None with | None -> if args == args' then c else mkEvar (evk, args') | Some c -> self () c end | _ -> map_universes_opt_subst_with_binders ignore self frel fqual funiv () c in self () c let pr_universe_subst prl = let open Pp in Level.Map.pr prl (fun u -> str" := " ++ Universe.pr prl u ++ spc ())