errorm messages for the transpiler

This commit is contained in:
Galfour 2019-06-04 08:21:13 +00:00
parent c2643f5b4c
commit 388c5e6a09
4 changed files with 227 additions and 98 deletions

View File

@ -51,7 +51,7 @@ let transpile_value
let%bind f =
let open Transpiler in
let (f , _) = functionalize e in
let%bind main = translate_main f in
let%bind main = translate_main f e.location in
ok main
in

View File

@ -5,7 +5,7 @@ let transpile_value
let%bind f =
let open Transpiler in
let (f , _) = functionalize e in
let%bind main = translate_main f in
let%bind main = translate_main f e.location in
ok main
in

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@ -79,7 +79,7 @@ let rec simpl_type_expression : Raw.type_expr -> type_expression result = fun te
in
ok @@ T_function (a , b)
)
| TApp x ->
| TApp x -> (
let (name, tuple) = x.value in
let lst = npseq_to_list tuple.value.inside in
let%bind cst =
@ -88,10 +88,11 @@ let rec simpl_type_expression : Raw.type_expr -> type_expression result = fun te
in
let%bind lst' = bind_map_list simpl_type_expression lst in
ok @@ T_constant (cst , lst')
| TProd p ->
let%bind tpl = simpl_list_type_expression
@@ npseq_to_list p.value in
)
| TProd p -> (
let%bind tpl = simpl_list_type_expression @@ npseq_to_list p.value in
ok tpl
)
| TRecord r ->
let aux = fun (x, y) -> let%bind y = simpl_type_expression y in ok (x, y) in
let%bind lst =

View File

@ -15,7 +15,78 @@ let map_of_kv_list lst =
let open AST.SMap in
List.fold_left (fun prev (k, v) -> add k v prev) empty lst
module Errors = struct
let corner_case ~loc message =
let title () = "corner case" in
let content () = "we don't have a good error message for this case. we are
striving find ways to better report them and find the use-cases that generate
them. please report this to the developers." in
let data = [
("location" , fun () -> loc) ;
("message" , fun () -> message) ;
] in
error ~data title content
let unrecognized_type_constant name =
let title () = "unrecognized type constant" in
let content () = name in
error title content
let unsupported_pattern_matching kind location =
let title () = "unsupported pattern-matching" in
let content () = Format.asprintf "%s patterns aren't supported yet" kind in
let data = [
("location" , fun () -> Format.asprintf "%a" Location.pp location) ;
] in
error ~data title content
let not_functional_main location =
let title () = "not functional main" in
let content () = "main should be a function" in
let data = [
("location" , fun () -> Format.asprintf "%a" Location.pp location) ;
] in
error ~data title content
let missing_entry_point name =
let title () = "missing entry point" in
let content () = "no entry point with the given name" in
let data = [
("name" , fun () -> name) ;
] in
error ~data title content
let wrong_mini_c_value expected_type actual =
let title () = "illed typed intermediary value" in
let content () = "type of intermediary value doesn't match what was expected" in
let data = [
("expected_type" , fun () -> expected_type) ;
("actual" , fun () -> Format.asprintf "%a" Mini_c.PP.value actual ) ;
] in
error ~data title content
let bad_untranspile bad_type value =
let title () = "untranspiling bad value" in
let content () = Format.asprintf "can not untranspile %s" bad_type in
let data = [
("bad_type" , fun () -> bad_type) ;
("value" , fun () -> Format.asprintf "%a" Mini_c.PP.value value) ;
] in
error ~data title content
let unknown_untranspile unknown_type value =
let title () = "untranspiling unknown value" in
let content () = Format.asprintf "can not untranspile %s" unknown_type in
let data = [
("unknown_type" , fun () -> unknown_type) ;
("value" , fun () -> Format.asprintf "%a" Mini_c.PP.value value) ;
] in
error ~data title content
end
open Errors
let rec translate_type (t:AST.type_value) : type_value result =
trace (simple_info "") @@
match t.type_value' with
| T_constant ("bool", []) -> ok (T_base Base_bool)
| T_constant ("int", []) -> ok (T_base Base_int)
@ -37,12 +108,7 @@ let rec translate_type (t:AST.type_value) : type_value result =
| T_constant ("option", [o]) ->
let%bind o' = translate_type o in
ok (T_option o')
| T_constant (name , lst) ->
let error =
let title () = "unrecognized type constant" in
let content () = Format.asprintf "%s (%d)" name (List.length lst) in
error title content in
fail error
| T_constant (name , _lst) -> fail @@ unrecognized_type_constant name
| T_sum m ->
let node = Append_tree.of_list @@ list_of_map m in
let aux a b : type_value result =
@ -163,8 +229,12 @@ and translate_annotated_expression (ae:AST.annotated_expression) : expression re
let%bind tv = translate_type ae.type_annotation in
let return ?(tv = tv) expr = ok @@ Combinators.Expression.make_tpl (expr, tv) in
let f = translate_annotated_expression in
let info =
let title () = "translating expression" in
let content () = Format.asprintf "%a" Location.pp ae.location in
info title content in
trace info @@
match ae.expression with
(* Optimise immediate application as a let-in *)
| E_let_in {binder; rhs; result} ->
let%bind rhs' = translate_annotated_expression rhs in
let%bind result' = translate_annotated_expression result in
@ -185,14 +255,16 @@ and translate_annotated_expression (ae:AST.annotated_expression) : expression re
let%bind a = translate_annotated_expression a in
let%bind b = translate_annotated_expression b in
return @@ E_application (a, b)
| E_constructor (m, param) ->
| E_constructor (m, param) -> (
let%bind param' = translate_annotated_expression param in
let (param'_expr , param'_tv) = Combinators.Expression.(get_content param' , get_type param') in
let%bind node_tv = tree_of_sum ae.type_annotation in
let%bind node_tv =
trace_strong (corner_case ~loc:__LOC__ "getting lr tree") @@
tree_of_sum ae.type_annotation in
let leaf (k, tv) : (expression' option * type_value) result =
if k = m then (
let%bind _ =
trace (simple_error "constructor parameter doesn't have expected type (shouldn't happen here)")
trace_strong (corner_case ~loc:__LOC__ "wrong type for constructor parameter")
@@ AST.assert_type_value_eq (tv, param.type_annotation) in
ok (Some (param'_expr), param'_tv)
) else (
@ -204,16 +276,17 @@ and translate_annotated_expression (ae:AST.annotated_expression) : expression re
let%bind b = b in
match (a, b) with
| (None, a), (None, b) -> ok (None, T_or (a, b))
| (Some _, _), (Some _, _) -> simple_fail "several identical constructors in the same variant (shouldn't happen here)"
| (Some _, _), (Some _, _) -> fail @@ corner_case ~loc:__LOC__ "multiple identical constructors in the same variant"
| (Some v, a), (None, b) -> ok (Some (E_constant ("LEFT", [Combinators.Expression.make_tpl (v, a)])), T_or (a, b))
| (None, a), (Some v, b) -> ok (Some (E_constant ("RIGHT", [Combinators.Expression.make_tpl (v, b)])), T_or (a, b))
in
let%bind (ae_opt, tv) = Append_tree.fold_ne leaf node node_tv in
let%bind ae =
trace_option (simple_error "constructor doesn't exist in claimed type (shouldn't happen here)")
trace_option (corner_case ~loc:__LOC__ "inexistant constructor")
ae_opt in
return ~tv ae
| E_tuple lst ->
)
| E_tuple lst -> (
let node = Append_tree.of_list lst in
let aux (a:expression result) (b:expression result) : expression result =
let%bind a = a in
@ -224,11 +297,16 @@ and translate_annotated_expression (ae:AST.annotated_expression) : expression re
return ~tv @@ E_constant ("PAIR", [a; b])
in
Append_tree.fold_ne (translate_annotated_expression) aux node
| E_tuple_accessor (tpl, ind) ->
)
| E_tuple_accessor (tpl, ind) -> (
let%bind ty' = translate_type tpl.type_annotation in
let%bind ty_lst = get_t_tuple tpl.type_annotation in
let%bind ty_lst =
trace_strong (corner_case ~loc:__LOC__ "not a tuple") @@
get_t_tuple tpl.type_annotation in
let%bind ty'_lst = bind_map_list translate_type ty_lst in
let%bind path = tuple_access_to_lr ty' ty'_lst ind in
let%bind path =
trace_strong (corner_case ~loc:__LOC__ "tuple access") @@
tuple_access_to_lr ty' ty'_lst ind in
let aux = fun pred (ty, lr) ->
let c = match lr with
| `Left -> "CAR"
@ -237,7 +315,8 @@ and translate_annotated_expression (ae:AST.annotated_expression) : expression re
let%bind tpl' = translate_annotated_expression tpl in
let expr = List.fold_left aux tpl' path in
ok expr
| E_record m ->
)
| E_record m -> (
let node = Append_tree.of_list @@ list_of_map m in
let aux a b : expression result =
let%bind a = a in
@ -247,12 +326,18 @@ and translate_annotated_expression (ae:AST.annotated_expression) : expression re
let tv = T_pair (a_ty , b_ty) in
return ~tv @@ E_constant ("PAIR", [a; b])
in
trace_strong (corner_case ~loc:__LOC__ "record build") @@
Append_tree.fold_ne (translate_annotated_expression) aux node
)
| E_record_accessor (record, property) ->
let%bind ty' = translate_type (get_type_annotation record) in
let%bind ty_smap = get_t_record (get_type_annotation record) in
let%bind ty_smap =
trace_strong (corner_case ~loc:__LOC__ "not a record") @@
get_t_record (get_type_annotation record) in
let%bind ty'_smap = bind_map_smap translate_type ty_smap in
let%bind path = record_access_to_lr ty' ty'_smap property in
let%bind path =
trace_strong (corner_case ~loc:__LOC__ "record access") @@
record_access_to_lr ty' ty'_smap property in
let aux = fun pred (ty, lr) ->
let c = match lr with
| `Left -> "CAR"
@ -261,38 +346,49 @@ and translate_annotated_expression (ae:AST.annotated_expression) : expression re
let%bind record' = translate_annotated_expression record in
let expr = List.fold_left aux record' path in
ok expr
| E_constant (name, lst) ->
let%bind lst' = bind_list @@ List.map (translate_annotated_expression) lst in (
| E_constant (name, lst) -> (
let%bind lst' = bind_map_list (translate_annotated_expression) lst in
match name, lst with
| "NONE", [] ->
let%bind o = Mini_c.Combinators.get_t_option tv in
let%bind o =
trace_strong (corner_case ~loc:__LOC__ "not an option") @@
Mini_c.Combinators.get_t_option tv in
return @@ E_make_none o
| _ -> return @@ E_constant (name, lst')
)
| E_lambda l ->
let%bind env = transpile_environment ae.environment in
let%bind env =
trace_strong (corner_case ~loc:__LOC__ "environment") @@
transpile_environment ae.environment in
translate_lambda env l
| E_list lst ->
let%bind t = Mini_c.Combinators.get_t_list tv in
| E_list lst -> (
let%bind t =
trace_strong (corner_case ~loc:__LOC__ "not a list") @@
Mini_c.Combinators.get_t_list tv in
let%bind lst' = bind_map_list (translate_annotated_expression) lst in
let aux : expression -> expression -> expression result = fun prev cur ->
return @@ E_constant ("CONS", [cur ; prev]) in
let%bind (init : expression) = return @@ E_make_empty_list t in
bind_fold_list aux init lst'
| E_map m ->
let%bind (src, dst) = Mini_c.Combinators.get_t_map tv in
)
| E_map m -> (
let%bind (src, dst) =
trace_strong (corner_case ~loc:__LOC__ "not a map") @@
Mini_c.Combinators.get_t_map tv in
let aux : expression result -> (AST.ae * AST.ae) -> expression result = fun prev (k, v) ->
let%bind prev' = prev in
let%bind (k', v') =
let v' = e_a_some v ae.environment in
bind_map_pair (translate_annotated_expression) (k, v') in
bind_map_pair (translate_annotated_expression) (k , v') in
return @@ E_constant ("UPDATE", [k' ; v' ; prev'])
in
let init = return @@ E_make_empty_map (src, dst) in
List.fold_left aux init m
| E_look_up dsi ->
)
| E_look_up dsi -> (
let%bind (ds', i') = bind_map_pair f dsi in
return @@ E_constant ("MAP_GET", [i' ; ds'])
)
| E_sequence (a , b) -> (
let%bind a' = translate_annotated_expression a in
let%bind b' = translate_annotated_expression b in
@ -309,27 +405,25 @@ and translate_annotated_expression (ae:AST.annotated_expression) : expression re
fun (prev, acc) cur ->
let%bind ty' = translate_type prev in
match cur with
| Access_tuple ind ->
let%bind ty_lst = AST.Combinators.get_t_tuple prev in
| Access_tuple ind -> (
let%bind ty_lst =
trace_strong (corner_case ~loc:__LOC__ "not a tuple") @@
AST.Combinators.get_t_tuple prev in
let%bind ty'_lst = bind_map_list translate_type ty_lst in
let%bind path = tuple_access_to_lr ty' ty'_lst ind in
let path' = List.map snd path in
ok (List.nth ty_lst ind, acc @ path')
| Access_record prop ->
)
| Access_record prop -> (
let%bind ty_map =
let error =
let title () = "accessing property on not a record" in
let content () = Format.asprintf "%s on %a in %a"
prop Ast_typed.PP.type_value prev Ast_typed.PP.annotated_expression expr in
error title content
in
trace error @@
trace_strong (corner_case ~loc:__LOC__ "not a record") @@
AST.Combinators.get_t_record prev in
let%bind ty'_map = bind_map_smap translate_type ty_map in
let%bind path = record_access_to_lr ty' ty'_map prop in
let path' = List.map snd path in
ok (Map.String.find prop ty_map, acc @ path')
| Access_map _k -> simple_fail "no patch for map yet"
)
| Access_map _k -> fail (corner_case ~loc:__LOC__ "no patch for map yet")
in
let%bind (_, path) = bind_fold_right_list aux (ty, []) path in
let%bind expr' = translate_annotated_expression expr in
@ -349,9 +443,11 @@ and translate_annotated_expression (ae:AST.annotated_expression) : expression re
ok (tv' , s') in
return @@ E_if_none (expr' , n , ((name , tv') , s'))
| Match_variant (lst , variant) -> (
let%bind tree = tree_of_sum variant in
let%bind tree =
trace_strong (corner_case ~loc:__LOC__ "getting lr tree") @@
tree_of_sum variant in
let%bind tree' = match tree with
| Empty -> simple_fail "match empty variant"
| Empty -> fail (corner_case ~loc:__LOC__ "match empty variant")
| Full x -> ok x in
let%bind tree'' =
let rec aux t =
@ -371,7 +467,7 @@ and translate_annotated_expression (ae:AST.annotated_expression) : expression re
match t with
| ((`Leaf constructor_name) , tv) -> (
let%bind ((_ , name) , body) =
trace_option (simple_error "not supposed to happen here: missing match clause") @@
trace_option (corner_case ~loc:__LOC__ "missing match clause") @@
List.find_opt (fun ((constructor_name' , _) , _) -> constructor_name' = constructor_name) lst in
let%bind body' = translate_annotated_expression body in
return @@ E_let_in ((name , tv) , top , body')
@ -391,10 +487,11 @@ and translate_annotated_expression (ae:AST.annotated_expression) : expression re
in
return @@ E_if_left (top , a' , b')
in
trace_strong (corner_case ~loc:__LOC__ "building constructor") @@
aux expr' tree''
)
| AST.Match_list _ | AST.Match_tuple (_, _) ->
simple_fail "only match bool, option and variants are translated yet"
| AST.Match_list _ -> fail @@ unsupported_pattern_matching "list" ae.location
| AST.Match_tuple _ -> fail @@ unsupported_pattern_matching "tuple" ae.location
)
and translate_lambda_deep : Mini_c.Environment.t -> AST.lambda -> Mini_c.expression result = fun env l ->
@ -433,7 +530,6 @@ and translate_lambda env l =
| [] -> (
let%bind result' = translate_annotated_expression result in
let result' = ez_e_return result' in
trace (simple_error "translate quote") @@
let%bind input = translate_type input_type in
let%bind output = translate_type output_type in
let tv = Combinators.t_function input output in
@ -441,7 +537,6 @@ and translate_lambda env l =
ok @@ Combinators.Expression.make_tpl (E_literal content, tv)
)
| _ -> (
trace (simple_error "translate lambda deep") @@
translate_lambda_deep env l
) in
ok result
@ -463,11 +558,11 @@ let translate_program (lst:AST.program) : program result =
let%bind (statements, _) = List.fold_left aux (ok ([], Environment.empty)) (temp_unwrap_loc_list lst) in
ok statements
let translate_main (l:AST.lambda) : anon_function result =
let translate_main (l:AST.lambda) loc : anon_function result =
let%bind expr = translate_lambda Environment.empty l in
match Combinators.Expression.get_content expr with
| E_literal (D_function f) -> ok f
| _ -> simple_fail "main is not a function"
| _ -> fail @@ not_functional_main loc
(* From an expression [expr], build the expression [fun () -> expr] *)
let functionalize (e:AST.annotated_expression) : AST.lambda * AST.type_value =
@ -484,7 +579,7 @@ let translate_entry (lst:AST.program) (name:string) : anon_function result =
let rec aux acc (lst:AST.program) =
let%bind acc = acc in
match lst with
| [] -> simple_fail "no entry point with given name"
| [] -> fail @@ missing_entry_point name
| hd :: tl -> (
let (AST.Declaration_constant (an , (pre_env , _))) = temp_unwrap_loc hd in
match an.name = name with
@ -498,11 +593,11 @@ let translate_entry (lst:AST.program) (name:string) : anon_function result =
match an.annotated_expression.expression with
| E_lambda l ->
let l' = { l with result = acc l.result } in
translate_main l'
translate_main l' an.annotated_expression.location
| _ ->
let (l , _) = functionalize an.annotated_expression in
let l' = { l with result = acc l.result } in
translate_main l'
translate_main l' an.annotated_expression.location
)
)
in
@ -553,36 +648,62 @@ let rec untranspile (v : value) (t : AST.type_value) : AST.annotated_expression
let open! AST in
let return e = ok (make_a_e_empty e t) in
match t.type_value' with
| T_constant ("unit", []) ->
let%bind () = get_unit v in
| T_constant ("unit", []) -> (
let%bind () =
trace_strong (wrong_mini_c_value "unit" v) @@
get_unit v in
return (E_literal Literal_unit)
| T_constant ("bool", []) ->
let%bind b = get_bool v in
)
| T_constant ("bool", []) -> (
let%bind b =
trace_strong (wrong_mini_c_value "bool" v) @@
get_bool v in
return (E_literal (Literal_bool b))
| T_constant ("int", []) ->
let%bind n = get_int v in
)
| T_constant ("int", []) -> (
let%bind n =
trace_strong (wrong_mini_c_value "int" v) @@
get_int v in
return (E_literal (Literal_int n))
| T_constant ("nat", []) ->
let%bind n = get_nat v in
)
| T_constant ("nat", []) -> (
let%bind n =
trace_strong (wrong_mini_c_value "nat" v) @@
get_nat v in
return (E_literal (Literal_nat n))
| T_constant ("tez", []) ->
let%bind n = get_nat v in
)
| T_constant ("tez", []) -> (
let%bind n =
trace_strong (wrong_mini_c_value "tez" v) @@
get_nat v in
return (E_literal (Literal_tez n))
| T_constant ("string", []) ->
let%bind n = get_string v in
)
| T_constant ("string", []) -> (
let%bind n =
trace_strong (wrong_mini_c_value "string" v) @@
get_string v in
return (E_literal (Literal_string n))
| T_constant ("address", []) ->
let%bind n = get_string v in
)
| T_constant ("address", []) -> (
let%bind n =
trace_strong (wrong_mini_c_value "address" v) @@
get_string v in
return (E_literal (Literal_address n))
)
| T_constant ("option", [o]) -> (
match%bind get_option v with
let%bind opt =
trace_strong (wrong_mini_c_value "option" v) @@
get_option v in
match opt with
| None -> ok (e_a_empty_none o)
| Some s ->
let%bind s' = untranspile s o in
ok (e_a_empty_some s')
)
| T_constant ("map", [k_ty;v_ty]) -> (
let%bind lst = get_map v in
let%bind lst =
trace_strong (wrong_mini_c_value "map" v) @@
get_map v in
let%bind lst' =
let aux = fun (k, v) ->
let%bind k' = untranspile k k_ty in
@ -592,48 +713,55 @@ let rec untranspile (v : value) (t : AST.type_value) : AST.annotated_expression
return (E_map lst')
)
| T_constant ("list", [ty]) -> (
let%bind lst = get_list v in
let%bind lst =
trace_strong (wrong_mini_c_value "list" v) @@
get_list v in
let%bind lst' =
let aux = fun e -> untranspile e ty in
bind_map_list aux lst in
return (E_list lst')
)
| T_constant ("contract" , [_ty]) ->
simple_fail "can't untranspile contract"
| T_constant ("operation" , []) ->
let%bind op = get_operation v in
fail @@ bad_untranspile "contract" v
| T_constant ("operation" , []) -> (
let%bind op =
trace_strong (wrong_mini_c_value "operation" v) @@
get_operation v in
return (E_literal (Literal_operation op))
| T_constant (name , lst) ->
let error =
let title () = "unknown type_constant" in
let content () = Format.asprintf "%s (%d)" name (List.length lst) in
error title content in
fail error
)
| T_constant (name , _lst) ->
fail @@ unknown_untranspile name v
| T_sum m ->
let lst = kv_list_of_map m in
let%bind node = match Append_tree.of_list lst with
| Empty -> simple_fail "empty sum type"
| Empty -> fail @@ corner_case ~loc:__LOC__ "empty sum type"
| Full t -> ok t
in
let%bind (name, v, tv) = extract_constructor v node in
let%bind (name, v, tv) =
trace_strong (corner_case ~loc:__LOC__ "sum extract constructor") @@
extract_constructor v node in
let%bind sub = untranspile v tv in
return (E_constructor (name, sub))
| T_tuple lst ->
let%bind node = match Append_tree.of_list lst with
| Empty -> simple_fail "empty tuple"
| Empty -> fail @@ corner_case ~loc:__LOC__ "empty tuple"
| Full t -> ok t in
let%bind tpl = extract_tuple v node in
let%bind tpl =
trace_strong (corner_case ~loc:__LOC__ "tuple extract") @@
extract_tuple v node in
let%bind tpl' = bind_list
@@ List.map (fun (x, y) -> untranspile x y) tpl in
return (E_tuple tpl')
| T_record m ->
let lst = kv_list_of_map m in
let%bind node = match Append_tree.of_list lst with
| Empty -> simple_fail "empty record"
| Empty -> fail @@ corner_case ~loc:__LOC__ "empty record"
| Full t -> ok t in
let%bind lst = extract_record v node in
let%bind lst =
trace_strong (corner_case ~loc:__LOC__ "record extract") @@
extract_record v node in
let%bind lst = bind_list
@@ List.map (fun (x, (y, z)) -> let%bind yz = untranspile y z in ok (x, yz)) lst in
let m' = map_of_kv_list lst in
return (E_record m')
| T_function _ -> simple_fail "no untranspilation for functions yet"
| T_function _ -> fail @@ bad_untranspile "function" v