ligo/src/passes/operators/helpers.ml
2019-09-23 23:33:25 +02:00

157 lines
4.9 KiB
OCaml

module Typer = struct
open Trace
open Ast_typed
module Errors = struct
let wrong_param_number = fun name expected got ->
let title () = "wrong number of params" in
let full () = Format.asprintf "constant name: %s\nexpected: %d\ngot: %d\n"
name expected (List.length got) in
error title full
let error_uncomparable_types a b () =
let title () = "these types are not comparable" in
let message () = "" in
let data = [
("a" , fun () -> Format.asprintf "%a" PP.type_value a) ;
("b" , fun () -> Format.asprintf "%a" PP.type_value b )
] in
error ~data title message ()
end
open Errors
type type_result = string * type_value
type typer' = type_value list -> type_value option -> type_result result
type typer = string * typer'
let typer'_0 : name -> (type_value option -> type_value result) -> typer' = fun s f lst tv_opt ->
match lst with
| [] -> (
let%bind tv' = f tv_opt in
ok (s , tv')
)
| _ -> fail @@ wrong_param_number s 0 lst
let typer_0 name f : typer = (name , typer'_0 name f)
let typer'_1 : name -> (type_value -> type_value result) -> typer' = fun s f lst _ ->
match lst with
| [ a ] -> (
let%bind tv' = f a in
ok (s , tv')
)
| _ -> fail @@ wrong_param_number s 1 lst
let typer_1 name f : typer = (name , typer'_1 name f)
let typer'_1_opt : name -> (type_value -> type_value option -> type_value result) -> typer' = fun s f lst tv_opt ->
match lst with
| [ a ] -> (
let%bind tv' = f a tv_opt in
ok (s , tv')
)
| _ -> fail @@ wrong_param_number s 1 lst
let typer_1_opt name f : typer = (name , typer'_1_opt name f)
let typer'_2 : name -> (type_value -> type_value -> type_value result) -> typer' = fun s f lst _ ->
match lst with
| [ a ; b ] -> (
let%bind tv' = f a b in
ok (s , tv')
)
| _ -> fail @@ wrong_param_number s 2 lst
let typer_2 name f : typer = (name , typer'_2 name f)
let typer'_3 : name -> (type_value -> type_value -> type_value -> type_value result) -> typer' = fun s f lst _ ->
match lst with
| [ a ; b ; c ] -> (
let%bind tv' = f a b c in
ok (s , tv')
)
| _ -> fail @@ wrong_param_number s 3 lst
let typer_3 name f : typer = (name , typer'_3 name f)
let typer'_4 : name -> (type_value -> type_value -> type_value -> type_value -> type_value result) -> typer' = fun s f lst _ ->
match lst with
| [ a ; b ; c ; d ] -> (
let%bind tv' = f a b c d in
ok (s , tv')
)
| _ -> fail @@ wrong_param_number s 4 lst
let typer_4 name f : typer = (name , typer'_4 name f)
let typer'_5 : name -> (type_value -> type_value -> type_value -> type_value -> type_value -> type_value result) -> typer' = fun s f lst _ ->
match lst with
| [ a ; b ; c ; d ; e ] -> (
let%bind tv' = f a b c d e in
ok (s , tv')
)
| _ -> fail @@ wrong_param_number s 5 lst
let typer_5 name f : typer = (name , typer'_5 name f)
let typer'_6 : name -> (type_value -> type_value -> type_value -> type_value -> type_value -> type_value -> type_value result) -> typer' = fun s f lst _ ->
match lst with
| [ a ; b ; c ; d ; e ; f_ ] -> (
let%bind tv' = f a b c d e f_ in
ok (s , tv')
)
| _ -> fail @@ wrong_param_number s 6 lst
let typer_6 name f : typer = (name , typer'_6 name f)
let constant name cst = typer_0 name (fun _ -> ok cst)
open Combinators
let eq_1 a cst = type_value_eq (a , cst)
let eq_2 (a , b) cst = type_value_eq (a , cst) && type_value_eq (b , cst)
let assert_eq_1 ?msg a b = Assert.assert_true ?msg (eq_1 a b)
let comparator : string -> typer = fun s -> typer_2 s @@ fun a b ->
let%bind () =
trace_strong (error_uncomparable_types a b) @@
Assert.assert_true @@
List.exists (eq_2 (a , b)) [
t_int () ;
t_nat () ;
t_tez () ;
t_string () ;
t_bytes () ;
t_address () ;
t_timestamp () ;
] in
ok @@ t_bool ()
let boolean_operator_2 : string -> typer = fun s -> typer_2 s @@ fun a b ->
let%bind () =
trace_strong (simple_error "A isn't of type bool") @@
Assert.assert_true @@
type_value_eq (t_bool () , a) in
let%bind () =
trace_strong (simple_error "B isn't of type bool") @@
Assert.assert_true @@
type_value_eq (t_bool () , b) in
ok @@ t_bool ()
end
module Compiler = struct
open Tezos_utils.Michelson
type predicate =
| Constant of michelson
| Unary of michelson
| Binary of michelson
| Ternary of michelson
| Tetrary of michelson
| Pentary of michelson
| Hexary of michelson
let simple_constant c = Constant c
let simple_unary c = Unary c
let simple_binary c = Binary c
let simple_ternary c = Ternary c
let simple_tetrary c = Tetrary c
let simple_pentary c = Pentary c
let simple_hexary c = Hexary c
end