package coq-lsp
Language Server Protocol native server for Coq
Install
Dune Dependency
Authors
Maintainers
Sources
coq-lsp-0.2.0.8.17.tbz
sha256=36340f464107ac60bb4033fad249984690cdcce3a6bef4ca439ffb2a4458dbf9
sha512=4866f4c2f0acda0c114e27b32cd60fa054333e1c7249227b8c3b23a316d7f306676203bd317f135a40368a292b7b49b76f0bdacff21d7e9bfb5a422d1c8d6ad8
doc/src/coq-lsp.coq/state.ml.html
Source file state.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 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 154 155 156 157 158 159 160 161 162 163 164 165 166 167 168 169 170 171 172 173 174 175 176 177 178 179 180 181 182 183 184 185 186 187 188 189 190 191 192 193 194 195 196 197 198 199 200 201 202 203 204 205 206 207 208 209 210 211 212 213 214 215 216 217 218 219 220 221 222 223 224 225 226 227 228 229 230 231 232 233 234 235 236 237 238 239 240 241 242 243 244 245 246 247 248 249 250 251 252 253 254 255 256 257 258 259 260 261 262 263 264 265type t = Vernacstate.t (* EJGA: This requires patches to Coq, they are in the lsp_debug branch let any_out oc (a : Summary.Frozen.any) = (* let (Summary.Frozen.Any (tag, _value)) = a in *) (* let name = Summary.Dyn.repr tag in *) (* Lsp.Io.log_error "marshall" name; *) Marshal.to_channel oc a [] let _frozen_out oc (s : Summary.Frozen.t) = Summary.Frozen.iter (any_out oc) s let summary_out oc (s : Summary.frozen) = let { Summary.summaries; ml_module } = s in (* frozen_out oc summaries; *) Marshal.to_channel oc summaries []; Marshal.to_channel oc ml_module []; () let summary_in ic : Summary.frozen = let summaries = Marshal.from_channel ic in let ml_module = Marshal.from_channel ic in { Summary.summaries; ml_module } let system_out oc ((l : Lib.frozen), (s : Summary.frozen)) = (* Both parts of system have functional values !! Likely due to Lib.frozen having a Summary.frozen inside? *) Marshal.to_channel oc l [ Closures ]; summary_out oc s; () let system_in ic : Vernacstate.System.t = let l : Lib.frozen = Marshal.from_channel ic in let s : Summary.frozen = summary_in ic in (l, s) let _marshal_out oc st = let { Vernacstate.parsing; system; lemmas; program; opaques; shallow } = st in Marshal.to_channel oc parsing []; system_out oc system; (* lemmas doesn't !! *) Marshal.to_channel oc lemmas []; Marshal.to_channel oc program []; Marshal.to_channel oc opaques []; Marshal.to_channel oc shallow []; () let _marshal_in ic = let parsing = Marshal.from_channel ic in let system = system_in ic in let lemmas = Marshal.from_channel ic in let program = Marshal.from_channel ic in let opaques = Marshal.from_channel ic in let shallow = Marshal.from_channel ic in { Vernacstate.parsing; system; lemmas; program; opaques; shallow } *) let marshal_in ic : t = Marshal.from_channel ic let marshal_out oc st = Marshal.to_channel oc st [] let of_coq x = x let to_coq x = x (* let compare x y = compare x y *) let compare (x : t) (y : t) = let open Vernacstate in let { parsing = ps1 ; system = is1 ; lemmas = l1 ; program = g1 ; opaques = o1 ; shallow = h1 } = x in let { parsing = ps2 ; system = is2 ; lemmas = l2 ; program = g2 ; opaques = o2 ; shallow = h2 } = y in if ps1 == ps2 && is1 == is2 && l1 == l2 && g1 == g2 && o1 == o2 && h1 == h2 then 0 else 1 let equal x y = compare x y = 0 let hash x = (* OCaml's defaults are 10, 100, but not so good for us, much improved settings are below (best try so far) *) let meaningful, total = (64, 256) in Hashtbl.hash_param meaningful total x let mode ~st = Option.map (fun _ -> Vernacinterp.get_default_proof_mode ()) st.Vernacstate.lemmas let parsing ~st = st.Vernacstate.parsing module Proof_ = Proof module Proof = struct type t = Vernacstate.LemmaStack.t let to_coq x = x let equal x y = x == y (* OCaml's defaults are 10, 100, we use this as to give best precision for petanque-like users *) let hash x = let meaningful, total = (128, 256) in Hashtbl.hash_param meaningful total x end let lemmas ~st = st.Vernacstate.lemmas module Declare_ = Declare module Declare = struct open Names open Constr [@@@ocaml.warning "-34"] [@@@ocaml.warning "-37"] type 'a obligation_body = | DefinedObl of 'a | TermObl of constr type fixpoint_kind = | IsFixpoint of lident option list | IsCoFixpoint module Obligation = struct type t = { obl_name : Id.t ; obl_type : types ; obl_location : Evar_kinds.t Loc.located ; obl_body : pconstant obligation_body option ; obl_status : bool * Evar_kinds.obligation_definition_status ; obl_deps : Int.Set.t ; obl_tac : unit Proofview.tactic option } end module ProgramDecl = struct type obligations = { obls : Obligation.t array ; remaining : int } type 'a t = { prg_cinfo : constr Declare.CInfo.t ; prg_info : Declare.Info.t ; prg_opaque : bool ; prg_hook : 'a option ; prg_body : Constr.constr ; prg_uctx : UState.t ; prg_obligations : obligations ; prg_deps : Id.t list ; prg_fixkind : fixpoint_kind option ; prg_notations : Metasyntax.where_decl_notation list ; prg_reduce : constr -> constr } end module ProgMap = Id.Map module OblState = struct type t = prg_hook ProgramDecl.t CEphemeron.key ProgMap.t and prg_hook = PrgHook of t Declare.Hook.g module View = struct module Obl = struct type t = { name : Names.Id.t ; loc : Loc.t option ; status : bool * Evar_kinds.obligation_definition_status ; solved : bool } let make (o : Obligation.t) = let { Obligation.obl_name; obl_location; obl_status; obl_body; _ } = o in { name = obl_name ; loc = fst obl_location ; status = obl_status ; solved = Option.has_some obl_body } end type t = { opaque : bool ; remaining : int ; obligations : Obl.t array } let make { ProgramDecl.prg_opaque; prg_obligations; _ } = { opaque = prg_opaque ; remaining = prg_obligations.remaining ; obligations = Array.map Obl.make prg_obligations.obls } let make eph = CEphemeron.get eph |> make end let view s = Names.Id.Map.map View.make (Obj.magic s) end end let program ~st = NeList.head st.Vernacstate.program |> Declare.OblState.view let drop_proof ~st = let open Vernacstate in { st with lemmas = Option.cata (fun s -> snd @@ Vernacstate.LemmaStack.pop s) None st.lemmas } let drop_all_proofs ~st = let open Vernacstate in { st with lemmas = None } let in_state ~token ~st ~f a = let f a = Vernacstate.unfreeze_interp_state st; f a in Protect.eval ~token ~f a let in_stateM ~token ~st ~f a = let open Protect.E.O in let* () = Protect.eval ~token ~f:Vernacstate.unfreeze_interp_state st in f a let admit ~st () = let () = Vernacstate.unfreeze_interp_state st in match st.Vernacstate.lemmas with | None -> st | Some lemmas -> let pm = NeList.head st.Vernacstate.program in let proof, lemmas = Vernacstate.(LemmaStack.pop lemmas) in let pm = Declare_.Proof.save_admitted ~pm ~proof in let program = NeList.map_head (fun _ -> pm) st.Vernacstate.program in let st = Vernacstate.freeze_interp_state ~marshallable:false in { st with lemmas; program } let admit ~token ~st = Protect.eval ~token ~f:(admit ~st) () let admit_goal ~st () = let () = Vernacstate.unfreeze_interp_state st in match st.Vernacstate.lemmas with | None -> st | Some lemmas -> let f pf = Declare_.Proof.by Proofview.give_up pf |> fst in let lemmas = Some (Vernacstate.LemmaStack.map_top ~f lemmas) in { st with lemmas } let admit_goal ~token ~st = Protect.eval ~token ~f:(admit_goal ~st) () let count_edges univ = let univ = UGraph.repr univ in Univ.Level.Map.fold (fun _ node acc -> acc + match node with | UGraph.Alias _ -> 1 | Node m -> Univ.Level.Map.cardinal m) univ (Univ.Level.Map.cardinal univ) let info_universes ~token ~st = let open Protect.E.O in let+ univ = in_state ~token ~st ~f:Global.universes () in let univs = UGraph.domain univ in let nuniv = Univ.Level.Set.cardinal univs in let nconst = count_edges univ in (nuniv, nconst)