open Trace type test_case = unit Alcotest.test_case type test = | Test_suite of (string * test list) | Test of test_case let wrap_test name f = let result = trace (error (thunk "running test") (thunk name)) @@ f () in match result with | Ok ((), annotations) -> ignore annotations; () | Error err -> Format.printf "%a\n%!" (Ligo.Display.error_pp ~dev:true) (err ()) ; raise Alcotest.Test_error let wrap_test_raw f = match f () with | Ok ((), annotations) -> ignore annotations; () | Error err -> Format.printf "%a\n%!" (Ligo.Display.error_pp ~dev:true) (err ()) let test name f = Test ( Alcotest.test_case name `Quick @@ fun () -> wrap_test name f ) let test_suite name lst = Test_suite (name , lst) open Ast_simplified let pack_payload (program:Ast_typed.program) (payload:expression) : bytes result = let%bind code = let env = Ast_typed.program_environment program in let%bind (typed,_) = Compile.Of_simplified.compile_expression ~env ~state:(Typer.Solver.initial_state) payload in let%bind mini_c = Compile.Of_typed.compile_expression typed in Compile.Of_mini_c.compile_expression mini_c in let (Ex_ty payload_ty) = code.expr_ty in let%bind (payload: Tezos_utils.Michelson.michelson) = Ligo.Run.Of_michelson.evaluate_expression code.expr code.expr_ty in Ligo.Run.Of_michelson.pack_payload payload payload_ty let sign_message (program:Ast_typed.program) (payload : expression) sk : string result = let open Tezos_crypto in let%bind packed_payload = pack_payload program payload in let signed_data = Signature.sign sk packed_payload in let signature_str = Signature.to_b58check signed_data in ok signature_str let contract id = let open Proto_alpha_utils.Memory_proto_alpha in let id = List.nth dummy_environment.identities id in id.implicit_contract let addr id = let open Proto_alpha_utils.Memory_proto_alpha in Protocol.Alpha_context.Contract.to_b58check @@ contract id let gen_keys = fun () -> let open Tezos_crypto in let (raw_pkh,raw_pk,raw_sk) = Signature.generate_key () in (raw_pkh,raw_pk,raw_sk) let str_keys (raw_pkh, raw_pk, raw_sk) = let open Tezos_crypto in let sk_str = Signature.Secret_key.to_b58check raw_sk in let pk_str = Signature.Public_key.to_b58check raw_pk in let pkh_str = Signature.Public_key_hash.to_b58check raw_pkh in (pkh_str,pk_str,sk_str) let sha_256_hash pl = let open Proto_alpha_utils.Memory_proto_alpha.Alpha_environment in Raw_hashes.sha256 pl open Ast_simplified.Combinators let typed_program_with_simplified_input_to_michelson (program: Ast_typed.program) (entry_point: string) (input: Ast_simplified.expression) : Compiler.compiled_expression result = let env = Ast_typed.program_environment program in let state = Typer.Solver.initial_state in let%bind app = Compile.Of_simplified.apply entry_point input in let%bind (typed_app,_) = Compile.Of_simplified.compile_expression ~env ~state app in let%bind compiled_applied = Compile.Of_typed.compile_expression typed_app in let%bind mini_c_prg = Compile.Of_typed.compile program in Compile.Of_mini_c.aggregate_and_compile_expression mini_c_prg compiled_applied let run_typed_program_with_simplified_input ?options (program: Ast_typed.program) (entry_point: string) (input: Ast_simplified.expression) : Ast_simplified.expression result = let%bind michelson_program = typed_program_with_simplified_input_to_michelson program entry_point input in let%bind michelson_output = Ligo.Run.Of_michelson.run ?options michelson_program.expr michelson_program.expr_ty in Uncompile.uncompile_typed_program_entry_function_result program entry_point michelson_output let expect ?options program entry_point input expecter = let%bind result = let run_error = let title () = "expect run" in let content () = Format.asprintf "Entry_point: %s" entry_point in error title content in trace run_error @@ run_typed_program_with_simplified_input ?options program entry_point input in expecter result let expect_fail ?options program entry_point input = let run_error = let title () = "expect run" in let content () = Format.asprintf "Entry_point: %s" entry_point in error title content in trace run_error @@ Assert.assert_fail @@ run_typed_program_with_simplified_input ?options program entry_point input let expect_string_failwith ?options program entry_point input expected_failwith = let%bind michelson_program = typed_program_with_simplified_input_to_michelson program entry_point input in let%bind err = Ligo.Run.Of_michelson.run_failwith ?options michelson_program.expr michelson_program.expr_ty in match err with | Ligo.Run.Of_michelson.Failwith_string s -> Assert.assert_equal_string expected_failwith s | _ -> simple_fail "Expected to fail with a string" let expect_eq ?options program entry_point input expected = let expecter = fun result -> let expect_error = let title () = "expect result" in let content () = Format.asprintf "Expected %a, got %a" Ast_simplified.PP.expression expected Ast_simplified.PP.expression result in error title content in trace expect_error @@ Ast_simplified.Misc.assert_value_eq (expected , result) in expect ?options program entry_point input expecter let expect_evaluate program entry_point expecter = let error = let title () = "expect evaluate" in let content () = Format.asprintf "Entry_point: %s" entry_point in error title content in trace error @@ let%bind mini_c = Ligo.Compile.Of_typed.compile program in let%bind (exp,_) = Mini_c.get_entry mini_c entry_point in let%bind michelson_value = Ligo.Compile.Of_mini_c.aggregate_and_compile_expression mini_c exp in let%bind res_michelson = Ligo.Run.Of_michelson.run michelson_value.expr michelson_value.expr_ty in let%bind res_simpl = Uncompile.uncompile_typed_program_entry_expression_result program entry_point res_michelson in expecter res_simpl let expect_eq_evaluate program entry_point expected = let expecter = fun result -> Ast_simplified.Misc.assert_value_eq (expected , result) in expect_evaluate program entry_point expecter let expect_n_aux ?options lst program entry_point make_input make_expecter = let aux n = let input = make_input n in let expecter = make_expecter n in trace (simple_error ("expect_n " ^ (string_of_int n))) @@ let result = expect ?options program entry_point input expecter in result in let%bind _ = bind_map_list aux lst in ok () let expect_eq_n_trace_aux ?options lst program entry_point make_input make_expected = let aux n = let%bind input = make_input n in let%bind expected = make_expected n in trace (simple_error ("expect_eq_n " ^ (string_of_int n))) @@ let result = expect_eq ?options program entry_point input expected in result in let%bind _ = bind_map_list_seq aux lst in ok () let expect_eq_exp_trace_aux ?options explst program entry_point make_input make_expected = let aux exp = let%bind input = make_input exp in let%bind expected = make_expected exp in let pps = Format.asprintf "%a" Ast_simplified.PP.expression exp in trace (simple_error ("expect_eq_exp " ^ pps )) @@ let result = expect_eq ?options program entry_point input expected in result in let%bind _ = bind_map_list_seq aux explst in ok () let expect_failwith_exp_trace_aux ?options explst program entry_point make_input make_expected_failwith = let aux exp = let%bind input = make_input exp in let%bind expected = make_expected_failwith exp in let pps = Format.asprintf "%a" Ast_simplified.PP.expression exp in trace (simple_error ("expect_eq_exp " ^ pps )) @@ let result = expect_string_failwith ?options program entry_point input expected in result in let%bind _ = bind_map_list_seq aux explst in ok () let expect_eq_n_aux ?options lst program entry_point make_input make_expected = let aux n = let input = make_input n in let expected = make_expected n in trace (simple_error ("expect_eq_n " ^ (string_of_int n))) @@ let result = expect_eq ?options program entry_point input expected in result in let%bind _ = bind_map_list_seq aux lst in ok () let expect_eq_n ?options = expect_eq_n_aux ?options [0 ; 1 ; 2 ; 42 ; 163 ; -1] let expect_eq_n_pos ?options = expect_eq_n_aux ?options [0 ; 1 ; 2 ; 42 ; 163] let expect_eq_n_strict_pos ?options = expect_eq_n_aux ?options [2 ; 42 ; 163] let expect_eq_n_pos_small ?options = expect_eq_n_aux ?options [0 ; 1 ; 2 ; 10] let expect_eq_n_strict_pos_small ?options = expect_eq_n_aux ?options [1 ; 2 ; 10] let expect_eq_n_pos_mid = expect_eq_n_aux [0 ; 1 ; 2 ; 10 ; 33] let expect_n_pos_small ?options = expect_n_aux ?options [0 ; 2 ; 10] let expect_n_strict_pos_small ?options = expect_n_aux ?options [2 ; 10] let expect_eq_b program entry_point make_expected = let aux b = let input = e_bool b in let expected = make_expected b in expect_eq program entry_point input expected in let%bind _ = bind_map_list_seq aux [false ; true] in ok () let expect_eq_n_int a b c = expect_eq_n a b e_int (fun n -> e_int (c n)) let expect_eq_b_bool a b c = let open Ast_simplified.Combinators in expect_eq_b a b (fun bool -> e_bool (c bool)) let rec test_height : test -> int = fun t -> match t with | Test _ -> 1 | Test_suite (_ , lst) -> (List.fold_left max 1 @@ List.map test_height lst) + 1 let extract_test : test -> test_case = fun t -> match t with | Test tc -> tc | _ -> assert false let extract_param : test -> (string * (string * test_case list) list) = let extract_element = extract_test in let extract_group : test -> (string * test_case list) = fun t -> match t with | Test tc -> ("isolated" , [ tc ]) | Test_suite (name , lst) -> (name , List.map extract_element lst) in fun t -> match t with | Test tc -> ("" , [ ("isolated" , [ tc ] ) ]) | Test_suite (name , lst) -> (name , List.map extract_group lst) let x : _ -> (unit Alcotest.test) = fun x -> x (* Alcotest.run parameters: string * (string * f list) list *) let rec run_test ?(prefix = "") : test -> unit = fun t -> match t with | Test case -> Alcotest.run "isolated test" [ ("" , [ case ]) ] | Test_suite (name , lst) -> ( if (test_height t <= 3) then ( let (name , tests) = extract_param t in Alcotest.run (prefix ^ name) tests ) else ( List.iter (run_test ~prefix:(prefix ^ name ^ "_")) lst ) )