(************************************************************************) (* v * The Coq Proof Assistant / The Coq Development Team *) (* let c' = try default_conv CUMUL env t1 t2 with NotConvertible -> raise (NotConvertibleVect i) in Constraint.union c c') Constraint.empty v1 v2 (* This should be a type (a priori without intension to be an assumption) *) let type_judgment env j = match kind_of_term(whd_betadeltaiota env j.uj_type) with | Sort s -> {utj_val = j.uj_val; utj_type = s } | _ -> error_not_type env j (* This should be a type intended to be assumed. The error message is *) (* not as useful as for [type_judgment]. *) let assumption_of_judgment env j = try (type_judgment env j).utj_val with TypeError _ -> error_assumption env j let sort_judgment env j = (type_judgment env j).utj_type (************************************************) (* Incremental typing rules: builds a typing judgement given the *) (* judgements for the subterms. *) (*s Type of sorts *) (* Prop and Set *) let judge_of_prop = { uj_val = mkProp; uj_type = mkSort type1_sort } let judge_of_set = { uj_val = mkSet; uj_type = mkSort type1_sort } let judge_of_prop_contents = function | Null -> judge_of_prop | Pos -> judge_of_set (* Type of Type(i). *) let judge_of_type u = let uu = super u in { uj_val = mkType u; uj_type = mkType uu } (*s Type of a de Bruijn index. *) let judge_of_relative env n = try let (_,_,typ) = lookup_rel n env in { uj_val = mkRel n; uj_type = lift n typ } with Not_found -> error_unbound_rel env n (* Type of variables *) let judge_of_variable env id = try let ty = named_type id env in make_judge (mkVar id) ty with Not_found -> error_unbound_var env id (* Management of context of variables. *) (* Checks if a context of variable can be instantiated by the variables of the current env *) (* TODO: check order? *) let rec check_hyps_inclusion env sign = Sign.fold_named_context (fun (id,_,ty1) () -> let ty2 = named_type id env in if not (eq_constr ty2 ty1) then error "types do not match") sign ~init:() let check_args env c hyps = try check_hyps_inclusion env hyps with UserError _ | Not_found -> error_reference_variables env c (* Checks if the given context of variables [hyps] is included in the current context of [env]. *) (* let check_hyps id env hyps = let hyps' = named_context env in if not (hyps_inclusion env hyps hyps') then error_reference_variables env id *) (* Instantiation of terms on real arguments. *) (* Make a type polymorphic if an arity *) let extract_level env p = let _,c = dest_prod_assum env p in match kind_of_term c with Sort (Type u) -> Some u | _ -> None let extract_context_levels env = List.fold_left (fun l (_,b,p) -> if b=None then extract_level env p::l else l) [] let make_polymorphic_if_constant_for_ind env {uj_val = c; uj_type = t} = let params, ccl = dest_prod_assum env t in match kind_of_term ccl with | Sort (Type u) when isInd (fst (decompose_app (whd_betadeltaiota env c))) -> let param_ccls = extract_context_levels env params in let s = { poly_param_levels = param_ccls; poly_level = u} in PolymorphicArity (params,s) | _ -> NonPolymorphicType t (* Type of constants *) let type_of_constant_knowing_parameters env t paramtyps = match t with | NonPolymorphicType t -> t | PolymorphicArity (sign,ar) -> let ctx = List.rev sign in let ctx,s = instantiate_universes env ctx ar paramtyps in mkArity (List.rev ctx,s) let type_of_constant_type env t = type_of_constant_knowing_parameters env t [||] let type_of_constant env cst = type_of_constant_type env (constant_type env cst) let judge_of_constant_knowing_parameters env cst jl = let c = mkConst cst in let cb = lookup_constant cst env in let _ = check_args env c cb.const_hyps in let paramstyp = Array.map (fun j -> j.uj_type) jl in let t = type_of_constant_knowing_parameters env cb.const_type paramstyp in make_judge c t let judge_of_constant env cst = judge_of_constant_knowing_parameters env cst [||] (* Type of a lambda-abstraction. *) (* [judge_of_abstraction env name var j] implements the rule env, name:typ |- j.uj_val:j.uj_type env, |- (name:typ)j.uj_type : s ----------------------------------------------------------------------- env |- [name:typ]j.uj_val : (name:typ)j.uj_type Since all products are defined in the Calculus of Inductive Constructions and no upper constraint exists on the sort $s$, we don't need to compute $s$ *) let judge_of_abstraction env name var j = { uj_val = mkLambda (name, var.utj_val, j.uj_val); uj_type = mkProd (name, var.utj_val, j.uj_type) } (* Type of let-in. *) let judge_of_letin env name defj typj j = { uj_val = mkLetIn (name, defj.uj_val, typj.utj_val, j.uj_val) ; uj_type = subst1 defj.uj_val j.uj_type } (* Type of an application. *) let judge_of_apply env funj argjv = let rec apply_rec n typ cst = function | [] -> { uj_val = mkApp (j_val funj, Array.map j_val argjv); uj_type = typ }, cst | hj::restjl -> (match kind_of_term (whd_betadeltaiota env typ) with | Prod (_,c1,c2) -> (try let c = conv_leq env hj.uj_type c1 in let cst' = Constraint.union cst c in apply_rec (n+1) (subst1 hj.uj_val c2) cst' restjl with NotConvertible -> error_cant_apply_bad_type env (n,c1, hj.uj_type) funj argjv) | _ -> error_cant_apply_not_functional env funj argjv) in apply_rec 1 funj.uj_type Constraint.empty (Array.to_list argjv) (* Type of product *) let sort_of_product env domsort rangsort = match (domsort, rangsort) with (* Product rule (s,Prop,Prop) *) | (_, Prop Null) -> rangsort (* Product rule (Prop/Set,Set,Set) *) | (Prop _, Prop Pos) -> rangsort (* Product rule (Type,Set,?) *) | (Type u1, Prop Pos) -> if engagement env = Some ImpredicativeSet then (* Rule is (Type,Set,Set) in the Set-impredicative calculus *) rangsort else (* Rule is (Type_i,Set,Type_i) in the Set-predicative calculus *) Type (sup u1 type0_univ) (* Product rule (Prop,Type_i,Type_i) *) | (Prop Pos, Type u2) -> Type (sup type0_univ u2) (* Product rule (Prop,Type_i,Type_i) *) | (Prop Null, Type _) -> rangsort (* Product rule (Type_i,Type_i,Type_i) *) | (Type u1, Type u2) -> Type (sup u1 u2) (* [judge_of_product env name (typ1,s1) (typ2,s2)] implements the rule env |- typ1:s1 env, name:typ1 |- typ2 : s2 ------------------------------------------------------------------------- s' >= (s1,s2), env |- (name:typ)j.uj_val : s' where j.uj_type is convertible to a sort s2 *) let judge_of_product env name t1 t2 = let s = sort_of_product env t1.utj_type t2.utj_type in { uj_val = mkProd (name, t1.utj_val, t2.utj_val); uj_type = mkSort s } (* Type of a type cast *) (* [judge_of_cast env (c,typ1) (typ2,s)] implements the rule env |- c:typ1 env |- typ2:s env |- typ1 <= typ2 --------------------------------------------------------------------- env |- c:typ2 *) let judge_of_cast env cj k tj = let expected_type = tj.utj_val in try let cst = match k with | VMcast -> vm_conv CUMUL env cj.uj_type expected_type | DEFAULTcast -> conv_leq env cj.uj_type expected_type in { uj_val = mkCast (cj.uj_val, k, expected_type); uj_type = expected_type }, cst with NotConvertible -> error_actual_type env cj expected_type (* Inductive types. *) (* The type is parametric over the uniform parameters whose conclusion is in Type; to enforce the internal constraints between the parameters and the instances of Type occurring in the type of the constructors, we use the level variables _statically_ assigned to the conclusions of the parameters as mediators: e.g. if a parameter has conclusion Type(alpha), static constraints of the form alpha<=v exist between alpha and the Type's occurring in the constructor types; when the parameters is finally instantiated by a term of conclusion Type(u), then the constraints u<=alpha is computed in the App case of execute; from this constraints, the expected dynamic constraints of the form u<=v are enforced *) let judge_of_inductive_knowing_parameters env ind jl = let c = mkInd ind in let (mib,mip) = lookup_mind_specif env ind in check_args env c mib.mind_hyps; let paramstyp = Array.map (fun j -> j.uj_type) jl in let t = Inductive.type_of_inductive_knowing_parameters env mip paramstyp in make_judge c t let judge_of_inductive env ind = judge_of_inductive_knowing_parameters env ind [||] (* Constructors. *) let judge_of_constructor env c = let constr = mkConstruct c in let _ = let ((kn,_),_) = c in let mib = lookup_mind kn env in check_args env constr mib.mind_hyps in let specif = lookup_mind_specif env (inductive_of_constructor c) in make_judge constr (type_of_constructor c specif) (* Case. *) let check_branch_types env cj (lfj,explft) = try conv_leq_vecti env (Array.map j_type lfj) explft with NotConvertibleVect i -> error_ill_formed_branch env cj.uj_val i lfj.(i).uj_type explft.(i) | Invalid_argument _ -> error_number_branches env cj (Array.length explft) let judge_of_case env ci pj cj lfj = let indspec = try find_rectype env cj.uj_type with Not_found -> error_case_not_inductive env cj in let _ = check_case_info env (fst indspec) ci in let (bty,rslty,univ) = type_case_branches env indspec pj cj.uj_val in let univ' = check_branch_types env cj (lfj,bty) in ({ uj_val = mkCase (ci, (*nf_betaiota*) pj.uj_val, cj.uj_val, Array.map j_val lfj); uj_type = rslty }, Constraint.union univ univ') (* Fixpoints. *) (* Checks the type of a general (co)fixpoint, i.e. without checking *) (* the specific guard condition. *) let type_fixpoint env lna lar vdefj = let lt = Array.length vdefj in assert (Array.length lar = lt); try conv_leq_vecti env (Array.map j_type vdefj) (Array.map (fun ty -> lift lt ty) lar) with NotConvertibleVect i -> error_ill_typed_rec_body env i lna vdefj lar (************************************************************************) (************************************************************************) (* This combinator adds the universe constraints both in the local graph and in the universes of the environment. This is to ensure that the infered local graph is satisfiable. *) let univ_combinator (cst,univ) (j,c') = (j,(Constraint.union cst c', merge_constraints c' univ)) (* The typing machine. *) (* ATTENTION : faudra faire le typage du contexte des Const, Ind et Constructsi un jour cela devient des constructions arbitraires et non plus des variables *) let rec execute env cstr cu = match kind_of_term cstr with (* Atomic terms *) | Sort (Prop c) -> (judge_of_prop_contents c, cu) | Sort (Type u) -> (judge_of_type u, cu) | Rel n -> (judge_of_relative env n, cu) | Var id -> (judge_of_variable env id, cu) | Const c -> (judge_of_constant env c, cu) (* Lambda calculus operators *) | App (f,args) -> let (jl,cu1) = execute_array env args cu in let (j,cu2) = match kind_of_term f with | Ind ind -> (* Sort-polymorphism of inductive types *) judge_of_inductive_knowing_parameters env ind jl, cu1 | Const cst -> (* Sort-polymorphism of constant *) judge_of_constant_knowing_parameters env cst jl, cu1 | _ -> (* No sort-polymorphism *) execute env f cu1 in univ_combinator cu2 (judge_of_apply env j jl) | Lambda (name,c1,c2) -> let (varj,cu1) = execute_type env c1 cu in let env1 = push_rel (name,None,varj.utj_val) env in let (j',cu2) = execute env1 c2 cu1 in (judge_of_abstraction env name varj j', cu2) | Prod (name,c1,c2) -> let (varj,cu1) = execute_type env c1 cu in let env1 = push_rel (name,None,varj.utj_val) env in let (varj',cu2) = execute_type env1 c2 cu1 in (judge_of_product env name varj varj', cu2) | LetIn (name,c1,c2,c3) -> let (j1,cu1) = execute env c1 cu in let (j2,cu2) = execute_type env c2 cu1 in let (_,cu3) = univ_combinator cu2 (judge_of_cast env j1 DEFAULTcast j2) in let env1 = push_rel (name,Some j1.uj_val,j2.utj_val) env in let (j',cu4) = execute env1 c3 cu3 in (judge_of_letin env name j1 j2 j', cu4) | Cast (c,k, t) -> let (cj,cu1) = execute env c cu in let (tj,cu2) = execute_type env t cu1 in univ_combinator cu2 (judge_of_cast env cj k tj) (* Inductive types *) | Ind ind -> (judge_of_inductive env ind, cu) | Construct c -> (judge_of_constructor env c, cu) | Case (ci,p,c,lf) -> let (cj,cu1) = execute env c cu in let (pj,cu2) = execute env p cu1 in let (lfj,cu3) = execute_array env lf cu2 in univ_combinator cu3 (judge_of_case env ci pj cj lfj) | Fix ((vn,i as vni),recdef) -> let ((fix_ty,recdef'),cu1) = execute_recdef env recdef i cu in let fix = (vni,recdef') in check_fix env fix; (make_judge (mkFix fix) fix_ty, cu1) | CoFix (i,recdef) -> let ((fix_ty,recdef'),cu1) = execute_recdef env recdef i cu in let cofix = (i,recdef') in check_cofix env cofix; (make_judge (mkCoFix cofix) fix_ty, cu1) (* Partial proofs: unsupported by the kernel *) | Meta _ -> anomaly "the kernel does not support metavariables" | Evar _ -> anomaly "the kernel does not support existential variables" and execute_type env constr cu = let (j,cu1) = execute env constr cu in (type_judgment env j, cu1) and execute_recdef env (names,lar,vdef) i cu = let (larj,cu1) = execute_array env lar cu in let lara = Array.map (assumption_of_judgment env) larj in let env1 = push_rec_types (names,lara,vdef) env in let (vdefj,cu2) = execute_array env1 vdef cu1 in let vdefv = Array.map j_val vdefj in let cst = type_fixpoint env1 names lara vdefj in univ_combinator cu2 ((lara.(i),(names,lara,vdefv)),cst) and execute_array env = array_fold_map' (execute env) and execute_list env = list_fold_map' (execute env) (* Derived functions *) let infer env constr = let (j,(cst,_)) = execute env constr (Constraint.empty, universes env) in assert (j.uj_val = constr); ({ j with uj_val = constr }, cst) let infer_type env constr = let (j,(cst,_)) = execute_type env constr (Constraint.empty, universes env) in (j, cst) let infer_v env cv = let (jv,(cst,_)) = execute_array env cv (Constraint.empty, universes env) in (jv, cst) (* Typing of several terms. *) let infer_local_decl env id = function | LocalDef c -> let (j,cst) = infer env c in (Name id, Some j.uj_val, j.uj_type), cst | LocalAssum c -> let (j,cst) = infer env c in (Name id, None, assumption_of_judgment env j), cst let infer_local_decls env decls = let rec inferec env = function | (id, d) :: l -> let env, l, cst1 = inferec env l in let d, cst2 = infer_local_decl env id d in push_rel d env, add_rel_decl d l, Constraint.union cst1 cst2 | [] -> env, empty_rel_context, Constraint.empty in inferec env decls (* Exported typing functions *) let typing env c = let (j,cst) = infer env c in let _ = add_constraints cst env in j