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|
(** This file implements various substitution utilities to instantiate types,
function bodies, etc.
*)
module T = Types
module TU = TypesUtils
module V = Values
module E = Expressions
module A = LlbcAst
module C = Contexts
(** Substitute types variables and regions in a type.
TODO: we can reimplement that with visitors.
*)
let rec ty_substitute (rsubst : 'r1 -> 'r2)
(tsubst : T.TypeVarId.id -> 'r2 T.ty) (ty : 'r1 T.ty) : 'r2 T.ty =
let open T in
let subst = ty_substitute rsubst tsubst in
(* helper *)
match ty with
| Adt (def_id, regions, tys) ->
Adt (def_id, List.map rsubst regions, List.map subst tys)
| Array aty -> Array (subst aty)
| Slice sty -> Slice (subst sty)
| Ref (r, ref_ty, ref_kind) -> Ref (rsubst r, subst ref_ty, ref_kind)
(* Below variants: we technically return the same value, but because
one has type ['r1 ty] and the other has type ['r2 ty], we need to
deconstruct then reconstruct *)
| Bool -> Bool
| Char -> Char
| Never -> Never
| Integer int_ty -> Integer int_ty
| Str -> Str
| TypeVar vid -> tsubst vid
(** Convert an [rty] to an [ety] by erasing the region variables *)
let erase_regions (ty : T.rty) : T.ety =
ty_substitute (fun _ -> T.Erased) (fun vid -> T.TypeVar vid) ty
(** Generate fresh regions for region variables.
Return the list of new regions and appropriate substitutions from the
original region variables to the fresh regions.
TODO: simplify? we only need the subst `T.RegionVarId.id -> T.RegionId.id`
*)
let fresh_regions_with_substs (region_vars : T.region_var list) :
T.RegionId.id list
* (T.RegionVarId.id -> T.RegionId.id)
* (T.RegionVarId.id T.region -> T.RegionId.id T.region) =
(* Generate fresh regions *)
let fresh_region_ids = List.map (fun _ -> C.fresh_region_id ()) region_vars in
(* Generate the map from region var ids to regions *)
let ls = List.combine region_vars fresh_region_ids in
let rid_map =
List.fold_left
(fun mp (k, v) -> T.RegionVarId.Map.add k.T.index v mp)
T.RegionVarId.Map.empty ls
in
(* Generate the substitution from region var id to region *)
let rid_subst id = T.RegionVarId.Map.find id rid_map in
(* Generate the substitution from region to region *)
let rsubst r =
match r with T.Static -> T.Static | T.Var id -> T.Var (rid_subst id)
in
(* Return *)
(fresh_region_ids, rid_subst, rsubst)
(** Erase the regions in a type and substitute the type variables *)
let erase_regions_substitute_types (tsubst : T.TypeVarId.id -> T.ety)
(ty : 'r T.region T.ty) : T.ety =
let rsubst (_ : 'r T.region) : T.erased_region = T.Erased in
ty_substitute rsubst tsubst ty
(** Create a region substitution from a list of region variable ids and a list of
regions (with which to substitute the region variable ids *)
let make_region_subst (var_ids : T.RegionVarId.id list)
(regions : 'r T.region list) : T.RegionVarId.id T.region -> 'r T.region =
let ls = List.combine var_ids regions in
let mp =
List.fold_left
(fun mp (k, v) -> T.RegionVarId.Map.add k v mp)
T.RegionVarId.Map.empty ls
in
fun r ->
match r with
| T.Static -> T.Static
| T.Var id -> T.RegionVarId.Map.find id mp
(** Create a type substitution from a list of type variable ids and a list of
types (with which to substitute the type variable ids) *)
let make_type_subst (var_ids : T.TypeVarId.id list) (tys : 'r T.ty list) :
T.TypeVarId.id -> 'r T.ty =
let ls = List.combine var_ids tys in
let mp =
List.fold_left
(fun mp (k, v) -> T.TypeVarId.Map.add k v mp)
T.TypeVarId.Map.empty ls
in
fun id -> T.TypeVarId.Map.find id mp
(** Instantiate the type variables in an ADT definition, and return, for
every variant, the list of the types of its fields *)
let type_decl_get_instantiated_variants_fields_rtypes (def : T.type_decl)
(regions : T.RegionId.id T.region list) (types : T.rty list) :
(T.VariantId.id option * T.rty list) list =
let r_subst =
make_region_subst
(List.map (fun x -> x.T.index) def.T.region_params)
regions
in
let ty_subst =
make_type_subst (List.map (fun x -> x.T.index) def.T.type_params) types
in
let (variants_fields : (T.VariantId.id option * T.field list) list) =
match def.T.kind with
| T.Enum variants ->
List.mapi
(fun i v -> (Some (T.VariantId.of_int i), v.T.fields))
variants
| T.Struct fields -> [ (None, fields) ]
| T.Opaque ->
raise
(Failure
("Can't retrieve the variants of an opaque type: "
^ Names.name_to_string def.name))
in
List.map
(fun (id, fields) ->
( id,
List.map (fun f -> ty_substitute r_subst ty_subst f.T.field_ty) fields
))
variants_fields
(** Instantiate the type variables in an ADT definition, and return the list
of types of the fields for the chosen variant *)
let type_decl_get_instantiated_field_rtypes (def : T.type_decl)
(opt_variant_id : T.VariantId.id option)
(regions : T.RegionId.id T.region list) (types : T.rty list) : T.rty list =
let r_subst =
make_region_subst
(List.map (fun x -> x.T.index) def.T.region_params)
regions
in
let ty_subst =
make_type_subst (List.map (fun x -> x.T.index) def.T.type_params) types
in
let fields = TU.type_decl_get_fields def opt_variant_id in
List.map (fun f -> ty_substitute r_subst ty_subst f.T.field_ty) fields
(** Return the types of the properly instantiated ADT's variant, provided a
context *)
let ctx_adt_get_instantiated_field_rtypes (ctx : C.eval_ctx)
(def_id : T.TypeDeclId.id) (opt_variant_id : T.VariantId.id option)
(regions : T.RegionId.id T.region list) (types : T.rty list) : T.rty list =
let def = C.ctx_lookup_type_decl ctx def_id in
type_decl_get_instantiated_field_rtypes def opt_variant_id regions types
(** Return the types of the properly instantiated ADT value (note that
here, ADT is understood in its broad meaning: ADT, assumed value or tuple) *)
let ctx_adt_value_get_instantiated_field_rtypes (ctx : C.eval_ctx)
(adt : V.adt_value) (id : T.type_id)
(region_params : T.RegionId.id T.region list) (type_params : T.rty list) :
T.rty list =
match id with
| T.AdtId id ->
(* Retrieve the types of the fields *)
ctx_adt_get_instantiated_field_rtypes ctx id adt.V.variant_id
region_params type_params
| T.Tuple ->
assert (List.length region_params = 0);
type_params
| T.Assumed aty -> (
match aty with
| T.Box | T.Vec ->
assert (List.length region_params = 0);
assert (List.length type_params = 1);
type_params
| T.Option ->
assert (List.length region_params = 0);
assert (List.length type_params = 1);
if adt.V.variant_id = Some T.option_some_id then type_params
else if adt.V.variant_id = Some T.option_none_id then []
else failwith "Unrechable")
(** Instantiate the type variables in an ADT definition, and return the list
of types of the fields for the chosen variant *)
let type_decl_get_instantiated_field_etypes (def : T.type_decl)
(opt_variant_id : T.VariantId.id option) (types : T.ety list) : T.ety list =
let ty_subst =
make_type_subst (List.map (fun x -> x.T.index) def.T.type_params) types
in
let fields = TU.type_decl_get_fields def opt_variant_id in
List.map
(fun f -> erase_regions_substitute_types ty_subst f.T.field_ty)
fields
(** Return the types of the properly instantiated ADT's variant, provided a
context *)
let ctx_adt_get_instantiated_field_etypes (ctx : C.eval_ctx)
(def_id : T.TypeDeclId.id) (opt_variant_id : T.VariantId.id option)
(types : T.ety list) : T.ety list =
let def = C.ctx_lookup_type_decl ctx def_id in
type_decl_get_instantiated_field_etypes def opt_variant_id types
(** Apply a type substitution to a place *)
let place_substitute (_tsubst : T.TypeVarId.id -> T.ety) (p : E.place) : E.place
=
(* There is nothing to do *)
p
(** Apply a type substitution to an operand constant value *)
let operand_constant_value_substitute (_tsubst : T.TypeVarId.id -> T.ety)
(op : E.operand_constant_value) : E.operand_constant_value =
(* There is nothing to do *)
op
(** Apply a type substitution to an operand *)
let operand_substitute (tsubst : T.TypeVarId.id -> T.ety) (op : E.operand) :
E.operand =
let p_subst = place_substitute tsubst in
match op with
| E.Copy p -> E.Copy (p_subst p)
| E.Move p -> E.Move (p_subst p)
| E.Constant (ety, cv) ->
let rsubst x = x in
E.Constant
( ty_substitute rsubst tsubst ety,
operand_constant_value_substitute tsubst cv )
(** Apply a type substitution to an rvalue *)
let rvalue_substitute (tsubst : T.TypeVarId.id -> T.ety) (rv : E.rvalue) :
E.rvalue =
let op_subst = operand_substitute tsubst in
let p_subst = place_substitute tsubst in
match rv with
| E.Use op -> E.Use (op_subst op)
| E.Ref (p, bkind) -> E.Ref (p_subst p, bkind)
| E.UnaryOp (unop, op) -> E.UnaryOp (unop, op_subst op)
| E.BinaryOp (binop, op1, op2) ->
E.BinaryOp (binop, op_subst op1, op_subst op2)
| E.Discriminant p -> E.Discriminant (p_subst p)
| E.Aggregate (kind, ops) ->
let ops = List.map op_subst ops in
let kind =
match kind with
| E.AggregatedTuple -> E.AggregatedTuple
| E.AggregatedOption (variant_id, ty) ->
let rsubst r = r in
E.AggregatedOption (variant_id, ty_substitute rsubst tsubst ty)
| E.AggregatedAdt (def_id, variant_id, regions, tys) ->
let rsubst r = r in
E.AggregatedAdt
( def_id,
variant_id,
regions,
List.map (ty_substitute rsubst tsubst) tys )
in
E.Aggregate (kind, ops)
(** Apply a type substitution to an assertion *)
let assertion_substitute (tsubst : T.TypeVarId.id -> T.ety) (a : A.assertion) :
A.assertion =
{ A.cond = operand_substitute tsubst a.A.cond; A.expected = a.A.expected }
(** Apply a type substitution to a call *)
let call_substitute (tsubst : T.TypeVarId.id -> T.ety) (call : A.call) : A.call
=
let rsubst x = x in
let type_args = List.map (ty_substitute rsubst tsubst) call.A.type_args in
let args = List.map (operand_substitute tsubst) call.A.args in
let dest = place_substitute tsubst call.A.dest in
(* Putting all the paramters on purpose: we want to get a compiler error if
something moves - we may add a field on which we need to apply a substitution *)
{
func = call.A.func;
region_args = call.A.region_args;
A.type_args;
args;
dest;
}
(** Apply a type substitution to a statement *)
let rec statement_substitute (tsubst : T.TypeVarId.id -> T.ety)
(st : A.statement) : A.statement =
match st with
| A.Assign (p, rvalue) ->
let p = place_substitute tsubst p in
let rvalue = rvalue_substitute tsubst rvalue in
A.Assign (p, rvalue)
| A.FakeRead p ->
let p = place_substitute tsubst p in
A.FakeRead p
| A.SetDiscriminant (p, vid) ->
let p = place_substitute tsubst p in
A.SetDiscriminant (p, vid)
| A.Drop p ->
let p = place_substitute tsubst p in
A.Drop p
| A.Assert assertion ->
let assertion = assertion_substitute tsubst assertion in
A.Assert assertion
| A.Call call ->
let call = call_substitute tsubst call in
A.Call call
| A.Panic | A.Return | A.Break _ | A.Continue _ | A.Nop -> st
| A.Sequence (st1, st2) ->
A.Sequence
(statement_substitute tsubst st1, statement_substitute tsubst st2)
| A.Switch (op, tgts) ->
A.Switch
(operand_substitute tsubst op, switch_targets_substitute tsubst tgts)
| A.Loop le -> A.Loop (statement_substitute tsubst le)
(** Apply a type substitution to switch targets *)
and switch_targets_substitute (tsubst : T.TypeVarId.id -> T.ety)
(tgts : A.switch_targets) : A.switch_targets =
match tgts with
| A.If (st1, st2) ->
A.If (statement_substitute tsubst st1, statement_substitute tsubst st2)
| A.SwitchInt (int_ty, tgts, otherwise) ->
let tgts =
List.map (fun (sv, st) -> (sv, statement_substitute tsubst st)) tgts
in
let otherwise = statement_substitute tsubst otherwise in
A.SwitchInt (int_ty, tgts, otherwise)
(** Apply a type substitution to a function body. Return the local variables
and the body. *)
let fun_body_substitute_in_body (tsubst : T.TypeVarId.id -> T.ety)
(body : A.fun_body) : A.var list * A.statement =
let rsubst r = r in
let locals =
List.map
(fun v -> { v with A.var_ty = ty_substitute rsubst tsubst v.A.var_ty })
body.A.locals
in
let body = statement_substitute tsubst body.body in
(locals, body)
(** Substitute a function signature *)
let substitute_signature (asubst : T.RegionGroupId.id -> V.AbstractionId.id)
(rsubst : T.RegionVarId.id -> T.RegionId.id)
(tsubst : T.TypeVarId.id -> T.rty) (sg : A.fun_sig) : A.inst_fun_sig =
let rsubst' (r : T.RegionVarId.id T.region) : T.RegionId.id T.region =
match r with T.Static -> T.Static | T.Var rid -> T.Var (rsubst rid)
in
let inputs = List.map (ty_substitute rsubst' tsubst) sg.A.inputs in
let output = ty_substitute rsubst' tsubst sg.A.output in
let subst_region_group (rg : T.region_var_group) : A.abs_region_group =
let id = asubst rg.id in
let regions = List.map rsubst rg.regions in
let parents = List.map asubst rg.parents in
{ id; regions; parents }
in
let regions_hierarchy = List.map subst_region_group sg.A.regions_hierarchy in
{ A.regions_hierarchy; inputs; output }
|