catala/compiler/scopelang/dependency.ml

Ignoring revisions in .git-blame-ignore-revs. Click here to bypass and see the normal blame view.

356 lines
12 KiB
OCaml
Raw Normal View History

2020-11-25 20:00:34 +03:00
(* This file is part of the Catala compiler, a specification language for tax
and social benefits computation rules. Copyright (C) 2020 Inria, contributor:
Denis Merigoux <denis.merigoux@inria.fr>
Licensed under the Apache License, Version 2.0 (the "License"); you may not
use this file except in compliance with the License. You may obtain a copy of
the License at
http://www.apache.org/licenses/LICENSE-2.0
Unless required by applicable law or agreed to in writing, software
distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
License for the specific language governing permissions and limitations under
the License. *)
(** Graph representation of the dependencies between scopes in the Catala
program. Vertices are functions, x -> y if x is used in the definition of y. *)
2022-11-21 12:46:17 +03:00
open Catala_utils
open Shared_ast
type vertex = Scope of ScopeName.t | Topdef of TopdefName.t
module SVertex = struct
type t = vertex
(* While we enforce that globals don't depend on scopes, and could therefore
compute two separate dependency graphs and traverse them one after the
other, code-wise it's simpler to have a single graph including both *)
let compare v1 v2 =
match v1, v2 with
| Scope s1, Scope s2 -> ScopeName.compare s1 s2
| Topdef g1, Topdef g2 -> TopdefName.compare g1 g2
| Scope _, _ -> -1
| _, Scope _ -> 1
| Topdef _, _ | _, Topdef _ -> .
let equal v1 v2 =
match v1, v2 with
| Scope s1, Scope s2 -> ScopeName.equal s1 s2
| Topdef g1, Topdef g2 -> TopdefName.equal g1 g2
| (Scope _ | Topdef _), _ -> false
let hash = function
| Scope s -> ScopeName.hash s
| Topdef g -> TopdefName.hash g
let format ppf = function
| Scope s -> ScopeName.format ppf s
| Topdef g -> TopdefName.format ppf g
(* let to_string v = Format.asprintf "%a" format v
let info = function | Scope s -> ScopeName.get_info s | Topdef g ->
TopdefName.get_info g *)
end
module VMap = Map.Make (SVertex)
2020-11-25 20:00:34 +03:00
(** On the edges, the label is the expression responsible for the use of the
function *)
2020-12-06 14:32:36 +03:00
module SEdge = struct
2020-11-25 20:00:34 +03:00
type t = Pos.t
let compare = compare
let default = Pos.no_pos
end
2020-12-06 14:32:36 +03:00
module SDependencies =
Graph.Persistent.Digraph.ConcreteBidirectionalLabeled (SVertex) (SEdge)
2020-12-06 14:32:36 +03:00
module STopologicalTraversal = Graph.Topological.Make (SDependencies)
2020-11-25 20:00:34 +03:00
2020-12-06 14:32:36 +03:00
module SSCC = Graph.Components.Make (SDependencies)
2020-11-25 20:00:34 +03:00
(** Tarjan's stongly connected components algorithm, provided by OCamlGraph *)
let rec expr_used_defs e =
Make scopes directly callable Quite a few changes are included here, some of which have some extra implications visible in the language: - adds the `Scope of { -- input_v: value; ... }` construct in the language - handle it down the pipeline: * `ScopeCall` in the surface AST * `EScopeCall` in desugared and scopelang * expressions are now traversed to detect dependencies between scopes * transformed into a normal function call in dcalc - defining a scope now implicitely defines a structure with the same name, with the output variables of the scope defined as fields. This allows us to type the return value from a scope call and access its fields easily. * the implications are mostly in surface/name_resolution.ml code-wise * the `Scope_out` struct that was defined in scope_to_dcalc is no longer needed/used and the fields are no longer renamed (changes some outputs; the explicit suffix for variables with multiple states is ignored as well) * one benefit is that disambiguation works just like for structures when there are conflicts on field names * however, it's now a conflict if a scope and a structure have the same name (side-note: issues with conflicting enum / struct names or scope variables / subscope names were silent and are now properly reported) - you can consequently use scope names as types for variables as well. Writing literals is not allowed though, they can only be obtained by calling the scope. Remaining TODOs: - context variables are not handled properly at the moment - error handling on invalid calls - tests show a small error message regression; lots of examples will need tweaking to avoid scope/struct name or struct fields / output variable conflicts - add a `->` syntax to make struct field access distinct from scope output var access, enforced with typing. This is expected to reduce confusion of users and add a little typing precision. - document the new syntax & implications (tutorial, cheat-sheet) - a consequence of the changes is that subscope variables also can now be typed. A possible future evolution / simplification would be to rewrite subscopes as explicit scope calls early in the pipeline. That could also allow to manipulate them as expressions (bind them in let-ins, return them...)
2022-10-21 16:47:17 +03:00
let recurse_subterms e =
Expr.shallow_fold
(fun e -> VMap.union (fun _ x _ -> Some x) (expr_used_defs e))
e VMap.empty
Make scopes directly callable Quite a few changes are included here, some of which have some extra implications visible in the language: - adds the `Scope of { -- input_v: value; ... }` construct in the language - handle it down the pipeline: * `ScopeCall` in the surface AST * `EScopeCall` in desugared and scopelang * expressions are now traversed to detect dependencies between scopes * transformed into a normal function call in dcalc - defining a scope now implicitely defines a structure with the same name, with the output variables of the scope defined as fields. This allows us to type the return value from a scope call and access its fields easily. * the implications are mostly in surface/name_resolution.ml code-wise * the `Scope_out` struct that was defined in scope_to_dcalc is no longer needed/used and the fields are no longer renamed (changes some outputs; the explicit suffix for variables with multiple states is ignored as well) * one benefit is that disambiguation works just like for structures when there are conflicts on field names * however, it's now a conflict if a scope and a structure have the same name (side-note: issues with conflicting enum / struct names or scope variables / subscope names were silent and are now properly reported) - you can consequently use scope names as types for variables as well. Writing literals is not allowed though, they can only be obtained by calling the scope. Remaining TODOs: - context variables are not handled properly at the moment - error handling on invalid calls - tests show a small error message regression; lots of examples will need tweaking to avoid scope/struct name or struct fields / output variable conflicts - add a `->` syntax to make struct field access distinct from scope output var access, enforced with typing. This is expected to reduce confusion of users and add a little typing precision. - document the new syntax & implications (tutorial, cheat-sheet) - a consequence of the changes is that subscope variables also can now be typed. A possible future evolution / simplification would be to rewrite subscopes as explicit scope calls early in the pipeline. That could also allow to manipulate them as expressions (bind them in let-ins, return them...)
2022-10-21 16:47:17 +03:00
in
match e with
| ELocation (ToplevelVar { name = v, pos }), _ ->
if TopdefName.path v <> [] then VMap.empty
else VMap.singleton (Topdef v) pos
| (EScopeCall { scope; _ }, m) as e ->
if ScopeName.path scope <> [] then VMap.empty
else VMap.add (Scope scope) (Expr.mark_pos m) (recurse_subterms e)
| EAbs { binder; _ }, _ ->
Make scopes directly callable Quite a few changes are included here, some of which have some extra implications visible in the language: - adds the `Scope of { -- input_v: value; ... }` construct in the language - handle it down the pipeline: * `ScopeCall` in the surface AST * `EScopeCall` in desugared and scopelang * expressions are now traversed to detect dependencies between scopes * transformed into a normal function call in dcalc - defining a scope now implicitely defines a structure with the same name, with the output variables of the scope defined as fields. This allows us to type the return value from a scope call and access its fields easily. * the implications are mostly in surface/name_resolution.ml code-wise * the `Scope_out` struct that was defined in scope_to_dcalc is no longer needed/used and the fields are no longer renamed (changes some outputs; the explicit suffix for variables with multiple states is ignored as well) * one benefit is that disambiguation works just like for structures when there are conflicts on field names * however, it's now a conflict if a scope and a structure have the same name (side-note: issues with conflicting enum / struct names or scope variables / subscope names were silent and are now properly reported) - you can consequently use scope names as types for variables as well. Writing literals is not allowed though, they can only be obtained by calling the scope. Remaining TODOs: - context variables are not handled properly at the moment - error handling on invalid calls - tests show a small error message regression; lots of examples will need tweaking to avoid scope/struct name or struct fields / output variable conflicts - add a `->` syntax to make struct field access distinct from scope output var access, enforced with typing. This is expected to reduce confusion of users and add a little typing precision. - document the new syntax & implications (tutorial, cheat-sheet) - a consequence of the changes is that subscope variables also can now be typed. A possible future evolution / simplification would be to rewrite subscopes as explicit scope calls early in the pipeline. That could also allow to manipulate them as expressions (bind them in let-ins, return them...)
2022-10-21 16:47:17 +03:00
let _, body = Bindlib.unmbind binder in
expr_used_defs body
Make scopes directly callable Quite a few changes are included here, some of which have some extra implications visible in the language: - adds the `Scope of { -- input_v: value; ... }` construct in the language - handle it down the pipeline: * `ScopeCall` in the surface AST * `EScopeCall` in desugared and scopelang * expressions are now traversed to detect dependencies between scopes * transformed into a normal function call in dcalc - defining a scope now implicitely defines a structure with the same name, with the output variables of the scope defined as fields. This allows us to type the return value from a scope call and access its fields easily. * the implications are mostly in surface/name_resolution.ml code-wise * the `Scope_out` struct that was defined in scope_to_dcalc is no longer needed/used and the fields are no longer renamed (changes some outputs; the explicit suffix for variables with multiple states is ignored as well) * one benefit is that disambiguation works just like for structures when there are conflicts on field names * however, it's now a conflict if a scope and a structure have the same name (side-note: issues with conflicting enum / struct names or scope variables / subscope names were silent and are now properly reported) - you can consequently use scope names as types for variables as well. Writing literals is not allowed though, they can only be obtained by calling the scope. Remaining TODOs: - context variables are not handled properly at the moment - error handling on invalid calls - tests show a small error message regression; lots of examples will need tweaking to avoid scope/struct name or struct fields / output variable conflicts - add a `->` syntax to make struct field access distinct from scope output var access, enforced with typing. This is expected to reduce confusion of users and add a little typing precision. - document the new syntax & implications (tutorial, cheat-sheet) - a consequence of the changes is that subscope variables also can now be typed. A possible future evolution / simplification would be to rewrite subscopes as explicit scope calls early in the pipeline. That could also allow to manipulate them as expressions (bind them in let-ins, return them...)
2022-10-21 16:47:17 +03:00
| e -> recurse_subterms e
let rule_used_defs = function
Make scopes directly callable Quite a few changes are included here, some of which have some extra implications visible in the language: - adds the `Scope of { -- input_v: value; ... }` construct in the language - handle it down the pipeline: * `ScopeCall` in the surface AST * `EScopeCall` in desugared and scopelang * expressions are now traversed to detect dependencies between scopes * transformed into a normal function call in dcalc - defining a scope now implicitely defines a structure with the same name, with the output variables of the scope defined as fields. This allows us to type the return value from a scope call and access its fields easily. * the implications are mostly in surface/name_resolution.ml code-wise * the `Scope_out` struct that was defined in scope_to_dcalc is no longer needed/used and the fields are no longer renamed (changes some outputs; the explicit suffix for variables with multiple states is ignored as well) * one benefit is that disambiguation works just like for structures when there are conflicts on field names * however, it's now a conflict if a scope and a structure have the same name (side-note: issues with conflicting enum / struct names or scope variables / subscope names were silent and are now properly reported) - you can consequently use scope names as types for variables as well. Writing literals is not allowed though, they can only be obtained by calling the scope. Remaining TODOs: - context variables are not handled properly at the moment - error handling on invalid calls - tests show a small error message regression; lots of examples will need tweaking to avoid scope/struct name or struct fields / output variable conflicts - add a `->` syntax to make struct field access distinct from scope output var access, enforced with typing. This is expected to reduce confusion of users and add a little typing precision. - document the new syntax & implications (tutorial, cheat-sheet) - a consequence of the changes is that subscope variables also can now be typed. A possible future evolution / simplification would be to rewrite subscopes as explicit scope calls early in the pipeline. That could also allow to manipulate them as expressions (bind them in let-ins, return them...)
2022-10-21 16:47:17 +03:00
| Ast.Assertion e | Ast.Definition (_, _, _, e) ->
(* TODO: maybe this info could be passed on from previous passes without
walking through all exprs again *)
expr_used_defs e
| Ast.Call (subscope, subindex, _) ->
if ScopeName.path subscope = [] then
VMap.singleton (Scope subscope)
(Mark.get (SubScopeName.get_info subindex))
else VMap.empty
Make scopes directly callable Quite a few changes are included here, some of which have some extra implications visible in the language: - adds the `Scope of { -- input_v: value; ... }` construct in the language - handle it down the pipeline: * `ScopeCall` in the surface AST * `EScopeCall` in desugared and scopelang * expressions are now traversed to detect dependencies between scopes * transformed into a normal function call in dcalc - defining a scope now implicitely defines a structure with the same name, with the output variables of the scope defined as fields. This allows us to type the return value from a scope call and access its fields easily. * the implications are mostly in surface/name_resolution.ml code-wise * the `Scope_out` struct that was defined in scope_to_dcalc is no longer needed/used and the fields are no longer renamed (changes some outputs; the explicit suffix for variables with multiple states is ignored as well) * one benefit is that disambiguation works just like for structures when there are conflicts on field names * however, it's now a conflict if a scope and a structure have the same name (side-note: issues with conflicting enum / struct names or scope variables / subscope names were silent and are now properly reported) - you can consequently use scope names as types for variables as well. Writing literals is not allowed though, they can only be obtained by calling the scope. Remaining TODOs: - context variables are not handled properly at the moment - error handling on invalid calls - tests show a small error message regression; lots of examples will need tweaking to avoid scope/struct name or struct fields / output variable conflicts - add a `->` syntax to make struct field access distinct from scope output var access, enforced with typing. This is expected to reduce confusion of users and add a little typing precision. - document the new syntax & implications (tutorial, cheat-sheet) - a consequence of the changes is that subscope variables also can now be typed. A possible future evolution / simplification would be to rewrite subscopes as explicit scope calls early in the pipeline. That could also allow to manipulate them as expressions (bind them in let-ins, return them...)
2022-10-21 16:47:17 +03:00
let build_program_dep_graph (prgm : 'm Ast.program) : SDependencies.t =
2020-12-06 14:32:36 +03:00
let g = SDependencies.empty in
let g =
TopdefName.Map.fold
(fun v _ g -> SDependencies.add_vertex g (Topdef v))
prgm.program_topdefs g
in
2020-12-06 14:32:36 +03:00
let g =
ScopeName.Map.fold
(fun v _ g -> SDependencies.add_vertex g (Scope v))
2020-12-06 14:32:36 +03:00
prgm.program_scopes g
in
let g =
TopdefName.Map.fold
(fun glo_name (expr, _) g ->
let used_defs = expr_used_defs expr in
if VMap.mem (Topdef glo_name) used_defs then
Message.raise_spanned_error
(Mark.get (TopdefName.get_info glo_name))
"The Topdef %a has a definition that refers to itself, which is \
forbidden since Catala does not provide recursion"
TopdefName.format glo_name;
VMap.fold
(fun def pos g ->
let edge = SDependencies.E.create def pos (Topdef glo_name) in
SDependencies.add_edge_e g edge)
used_defs g)
prgm.program_topdefs g
in
ScopeName.Map.fold
(fun scope_name (scope, _) g ->
Make scopes directly callable Quite a few changes are included here, some of which have some extra implications visible in the language: - adds the `Scope of { -- input_v: value; ... }` construct in the language - handle it down the pipeline: * `ScopeCall` in the surface AST * `EScopeCall` in desugared and scopelang * expressions are now traversed to detect dependencies between scopes * transformed into a normal function call in dcalc - defining a scope now implicitely defines a structure with the same name, with the output variables of the scope defined as fields. This allows us to type the return value from a scope call and access its fields easily. * the implications are mostly in surface/name_resolution.ml code-wise * the `Scope_out` struct that was defined in scope_to_dcalc is no longer needed/used and the fields are no longer renamed (changes some outputs; the explicit suffix for variables with multiple states is ignored as well) * one benefit is that disambiguation works just like for structures when there are conflicts on field names * however, it's now a conflict if a scope and a structure have the same name (side-note: issues with conflicting enum / struct names or scope variables / subscope names were silent and are now properly reported) - you can consequently use scope names as types for variables as well. Writing literals is not allowed though, they can only be obtained by calling the scope. Remaining TODOs: - context variables are not handled properly at the moment - error handling on invalid calls - tests show a small error message regression; lots of examples will need tweaking to avoid scope/struct name or struct fields / output variable conflicts - add a `->` syntax to make struct field access distinct from scope output var access, enforced with typing. This is expected to reduce confusion of users and add a little typing precision. - document the new syntax & implications (tutorial, cheat-sheet) - a consequence of the changes is that subscope variables also can now be typed. A possible future evolution / simplification would be to rewrite subscopes as explicit scope calls early in the pipeline. That could also allow to manipulate them as expressions (bind them in let-ins, return them...)
2022-10-21 16:47:17 +03:00
List.fold_left
(fun g rule ->
let used_defs = rule_used_defs rule in
if VMap.mem (Scope scope_name) used_defs then
Message.raise_spanned_error
(Mark.get (ScopeName.get_info scope.Ast.scope_decl_name))
Make scopes directly callable Quite a few changes are included here, some of which have some extra implications visible in the language: - adds the `Scope of { -- input_v: value; ... }` construct in the language - handle it down the pipeline: * `ScopeCall` in the surface AST * `EScopeCall` in desugared and scopelang * expressions are now traversed to detect dependencies between scopes * transformed into a normal function call in dcalc - defining a scope now implicitely defines a structure with the same name, with the output variables of the scope defined as fields. This allows us to type the return value from a scope call and access its fields easily. * the implications are mostly in surface/name_resolution.ml code-wise * the `Scope_out` struct that was defined in scope_to_dcalc is no longer needed/used and the fields are no longer renamed (changes some outputs; the explicit suffix for variables with multiple states is ignored as well) * one benefit is that disambiguation works just like for structures when there are conflicts on field names * however, it's now a conflict if a scope and a structure have the same name (side-note: issues with conflicting enum / struct names or scope variables / subscope names were silent and are now properly reported) - you can consequently use scope names as types for variables as well. Writing literals is not allowed though, they can only be obtained by calling the scope. Remaining TODOs: - context variables are not handled properly at the moment - error handling on invalid calls - tests show a small error message regression; lots of examples will need tweaking to avoid scope/struct name or struct fields / output variable conflicts - add a `->` syntax to make struct field access distinct from scope output var access, enforced with typing. This is expected to reduce confusion of users and add a little typing precision. - document the new syntax & implications (tutorial, cheat-sheet) - a consequence of the changes is that subscope variables also can now be typed. A possible future evolution / simplification would be to rewrite subscopes as explicit scope calls early in the pipeline. That could also allow to manipulate them as expressions (bind them in let-ins, return them...)
2022-10-21 16:47:17 +03:00
"The scope %a is calling into itself as a subscope, which is \
forbidden since Catala does not provide recursion"
ScopeName.format scope.Ast.scope_decl_name;
VMap.fold
(fun used_def pos g ->
let edge =
SDependencies.E.create used_def pos (Scope scope_name)
in
Make scopes directly callable Quite a few changes are included here, some of which have some extra implications visible in the language: - adds the `Scope of { -- input_v: value; ... }` construct in the language - handle it down the pipeline: * `ScopeCall` in the surface AST * `EScopeCall` in desugared and scopelang * expressions are now traversed to detect dependencies between scopes * transformed into a normal function call in dcalc - defining a scope now implicitely defines a structure with the same name, with the output variables of the scope defined as fields. This allows us to type the return value from a scope call and access its fields easily. * the implications are mostly in surface/name_resolution.ml code-wise * the `Scope_out` struct that was defined in scope_to_dcalc is no longer needed/used and the fields are no longer renamed (changes some outputs; the explicit suffix for variables with multiple states is ignored as well) * one benefit is that disambiguation works just like for structures when there are conflicts on field names * however, it's now a conflict if a scope and a structure have the same name (side-note: issues with conflicting enum / struct names or scope variables / subscope names were silent and are now properly reported) - you can consequently use scope names as types for variables as well. Writing literals is not allowed though, they can only be obtained by calling the scope. Remaining TODOs: - context variables are not handled properly at the moment - error handling on invalid calls - tests show a small error message regression; lots of examples will need tweaking to avoid scope/struct name or struct fields / output variable conflicts - add a `->` syntax to make struct field access distinct from scope output var access, enforced with typing. This is expected to reduce confusion of users and add a little typing precision. - document the new syntax & implications (tutorial, cheat-sheet) - a consequence of the changes is that subscope variables also can now be typed. A possible future evolution / simplification would be to rewrite subscopes as explicit scope calls early in the pipeline. That could also allow to manipulate them as expressions (bind them in let-ins, return them...)
2022-10-21 16:47:17 +03:00
SDependencies.add_edge_e g edge)
used_defs g)
Make scopes directly callable Quite a few changes are included here, some of which have some extra implications visible in the language: - adds the `Scope of { -- input_v: value; ... }` construct in the language - handle it down the pipeline: * `ScopeCall` in the surface AST * `EScopeCall` in desugared and scopelang * expressions are now traversed to detect dependencies between scopes * transformed into a normal function call in dcalc - defining a scope now implicitely defines a structure with the same name, with the output variables of the scope defined as fields. This allows us to type the return value from a scope call and access its fields easily. * the implications are mostly in surface/name_resolution.ml code-wise * the `Scope_out` struct that was defined in scope_to_dcalc is no longer needed/used and the fields are no longer renamed (changes some outputs; the explicit suffix for variables with multiple states is ignored as well) * one benefit is that disambiguation works just like for structures when there are conflicts on field names * however, it's now a conflict if a scope and a structure have the same name (side-note: issues with conflicting enum / struct names or scope variables / subscope names were silent and are now properly reported) - you can consequently use scope names as types for variables as well. Writing literals is not allowed though, they can only be obtained by calling the scope. Remaining TODOs: - context variables are not handled properly at the moment - error handling on invalid calls - tests show a small error message regression; lots of examples will need tweaking to avoid scope/struct name or struct fields / output variable conflicts - add a `->` syntax to make struct field access distinct from scope output var access, enforced with typing. This is expected to reduce confusion of users and add a little typing precision. - document the new syntax & implications (tutorial, cheat-sheet) - a consequence of the changes is that subscope variables also can now be typed. A possible future evolution / simplification would be to rewrite subscopes as explicit scope calls early in the pipeline. That could also allow to manipulate them as expressions (bind them in let-ins, return them...)
2022-10-21 16:47:17 +03:00
g scope.Ast.scope_decl_rules)
prgm.program_scopes g
2020-11-25 20:00:34 +03:00
let check_for_cycle_in_defs (g : SDependencies.t) : unit =
2020-11-25 20:00:34 +03:00
(* if there is a cycle, there will be an strongly connected component of
cardinality > 1 *)
2020-12-06 14:32:36 +03:00
let sccs = SSCC.scc_list g in
match List.find_opt (function [] | [_] -> false | _ -> true) sccs with
| None -> ()
| Some [] -> assert false
| Some (v0 :: _ as scc) ->
let module VSet = Set.Make (SVertex) in
let scc = VSet.of_list scc in
let rec get_cycle cycle cycle_set v =
let cycle = v :: cycle in
let cycle_set = VSet.add v cycle_set in
let succ = SDependencies.succ g v in
if List.exists (fun v -> VSet.mem v cycle_set) succ then
(* a cycle may be smaller than the scc, in that case we just return the
first one found *)
let rec cut_after acc = function
| [] -> acc
| v :: vs ->
if List.mem v succ then v :: acc else cut_after (v :: acc) vs
in
cut_after [] cycle
else
get_cycle cycle cycle_set
(List.find (fun succ -> VSet.mem succ scc) succ)
in
let cycle = get_cycle [] VSet.empty v0 in
let spans =
List.map2
(fun v1 v2 ->
let msg =
Format.asprintf "%a is used here in the definition of %a:"
SVertex.format v1 SVertex.format v2
in
let _, edge_pos, _ = SDependencies.find_edge g v1 v2 in
Some msg, edge_pos)
cycle
(List.tl cycle @ [List.hd cycle])
in
Message.raise_multispanned_error spans
"@[<hov 2>Cyclic dependency detected between the following scopes:@ \
@[<hv>%a@]@]"
(Format.pp_print_list
~pp_sep:(fun ppf () -> Format.fprintf ppf " →@ ")
SVertex.format)
(cycle @ [List.hd cycle])
2020-11-25 20:00:34 +03:00
let get_defs_ordering (g : SDependencies.t) : SVertex.t list =
2020-12-06 14:32:36 +03:00
List.rev (STopologicalTraversal.fold (fun sd acc -> sd :: acc) g [])
module TVertex = struct
type t = Struct of StructName.t | Enum of EnumName.t
2020-12-06 14:32:36 +03:00
let hash x =
match x with Struct x -> StructName.hash x | Enum x -> EnumName.hash x
2020-12-06 14:32:36 +03:00
let compare x y =
match x, y with
| Struct x, Struct y -> StructName.compare x y
| Enum x, Enum y -> EnumName.compare x y
2020-12-06 14:32:36 +03:00
| Struct _, Enum _ -> 1
| Enum _, Struct _ -> -1
let equal x y =
match x, y with
| Struct x, Struct y -> StructName.compare x y = 0
| Enum x, Enum y -> EnumName.compare x y = 0
2020-12-06 14:32:36 +03:00
| _ -> false
let format (fmt : Format.formatter) (x : t) : unit =
2020-12-06 14:32:36 +03:00
match x with
| Struct x -> StructName.format fmt x
| Enum x -> EnumName.format fmt x
2020-12-06 14:32:36 +03:00
let get_info (x : t) =
match x with
| Struct x -> StructName.get_info x
| Enum x -> EnumName.get_info x
2020-12-06 14:32:36 +03:00
end
module TVertexSet = Set.Make (TVertex)
(** On the edges, the label is the expression responsible for the use of the
function *)
module TEdge = struct
type t = Pos.t
let compare = compare
let default = Pos.no_pos
end
module TDependencies =
Graph.Persistent.Digraph.ConcreteBidirectionalLabeled (TVertex) (TEdge)
2020-12-06 14:32:36 +03:00
module TTopologicalTraversal = Graph.Topological.Make (TDependencies)
module TSCC = Graph.Components.Make (TDependencies)
(** Tarjan's stongly connected components algorithm, provided by OCamlGraph *)
let rec get_structs_or_enums_in_type (t : typ) : TVertexSet.t =
match Mark.remove t with
| TStruct s -> TVertexSet.singleton (TVertex.Struct s)
| TEnum e -> TVertexSet.singleton (TVertex.Enum e)
| TArrow (t1, t2) ->
2020-12-06 14:32:36 +03:00
TVertexSet.union
2023-02-20 19:21:44 +03:00
(t1
|> List.map get_structs_or_enums_in_type
|> List.fold_left TVertexSet.union TVertexSet.empty)
2020-12-06 14:32:36 +03:00
(get_structs_or_enums_in_type t2)
2023-06-15 12:11:56 +03:00
| TClosureEnv | TLit _ | TAny -> TVertexSet.empty
| TOption t1 | TArray t1 -> get_structs_or_enums_in_type t1
| TTuple ts ->
List.fold_left
(fun acc t -> TVertexSet.union acc (get_structs_or_enums_in_type t))
TVertexSet.empty ts
let build_type_graph (structs : struct_ctx) (enums : enum_ctx) : TDependencies.t
=
2020-12-06 14:32:36 +03:00
let g = TDependencies.empty in
let g =
StructName.Map.fold
(fun s fields g ->
StructField.Map.fold
(fun _ typ g ->
2020-12-06 14:32:36 +03:00
let def = TVertex.Struct s in
let g = TDependencies.add_vertex g def in
let used = get_structs_or_enums_in_type typ in
TVertexSet.fold
(fun used g ->
if TVertex.equal used def then
Message.raise_spanned_error (Mark.get typ)
"The type %a is defined using itself, which is forbidden \
since Catala does not provide recursive types"
TVertex.format used
2020-12-06 14:32:36 +03:00
else
let edge = TDependencies.E.create used (Mark.get typ) def in
2020-12-06 14:32:36 +03:00
TDependencies.add_edge_e g edge)
used g)
fields g)
2020-12-06 14:32:36 +03:00
structs g
in
let g =
EnumName.Map.fold
(fun e cases g ->
EnumConstructor.Map.fold
(fun _ typ g ->
2020-12-06 14:32:36 +03:00
let def = TVertex.Enum e in
let g = TDependencies.add_vertex g def in
let used = get_structs_or_enums_in_type typ in
TVertexSet.fold
(fun used g ->
if TVertex.equal used def then
Message.raise_spanned_error (Mark.get typ)
"The type %a is defined using itself, which is forbidden \
since Catala does not provide recursive types"
TVertex.format used
2020-12-06 14:32:36 +03:00
else
let edge = TDependencies.E.create used (Mark.get typ) def in
2020-12-06 14:32:36 +03:00
TDependencies.add_edge_e g edge)
used g)
cases g)
2020-12-06 14:32:36 +03:00
enums g
in
g
let check_type_cycles (structs : struct_ctx) (enums : enum_ctx) : TVertex.t list
=
2020-12-06 14:32:36 +03:00
let g = build_type_graph structs enums in
(* if there is a cycle, there will be an strongly connected component of
cardinality > 1 *)
let sccs = TSCC.scc_list g in
(if List.length sccs < TDependencies.nb_vertex g then
2020-12-06 14:32:36 +03:00
let scc = List.find (fun scc -> List.length scc > 1) sccs in
let spans =
List.flatten
(List.map
(fun v ->
let var_str, var_info =
Format.asprintf "%a" TVertex.format v, TVertex.get_info v
in
let succs = TDependencies.succ_e g v in
let _, edge_pos, succ =
List.find (fun (_, _, succ) -> List.mem succ scc) succs
in
let succ_str = Format.asprintf "%a" TVertex.format succ in
[
Some ("Cycle type " ^ var_str ^ ", declared:"), Mark.get var_info;
( Some
("Used here in the definition of another cycle type "
^ succ_str
^ ":"),
edge_pos );
])
scc)
in
Message.raise_multispanned_error spans
"Cyclic dependency detected between types!");
List.rev (TTopologicalTraversal.fold (fun v acc -> v :: acc) g [])