/* This file is part of solidity. solidity is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. solidity is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with solidity. If not, see . */ /** * @date 2017 * Unit tests for parsing Yul. */ #include #include #include #include #include #include #include #include #include #include #include #include #include using namespace std; using namespace dev; using namespace langutil; namespace yul { namespace test { namespace { bool parse(string const& _source, std::shared_ptr _dialect, ErrorReporter& errorReporter) { try { auto scanner = make_shared(CharStream(_source, "")); auto parserResult = yul::Parser(errorReporter, _dialect).parse(scanner, false); if (parserResult) { yul::AsmAnalysisInfo analysisInfo; return (yul::AsmAnalyzer( analysisInfo, errorReporter, dev::test::Options::get().evmVersion(), boost::none, _dialect )).analyze(*parserResult); } } catch (FatalError const&) { BOOST_FAIL("Fatal error leaked."); } return false; } boost::optional parseAndReturnFirstError(string const& _source, shared_ptr _dialect, bool _allowWarnings = true) { ErrorList errors; ErrorReporter errorReporter(errors); if (!parse(_source, _dialect, errorReporter)) { BOOST_REQUIRE(!errors.empty()); BOOST_CHECK_EQUAL(errors.size(), 1); return *errors.front(); } else { // If success is true, there might still be an error in the assembly stage. if (_allowWarnings && Error::containsOnlyWarnings(errors)) return {}; else if (!errors.empty()) { if (!_allowWarnings) BOOST_CHECK_EQUAL(errors.size(), 1); return *errors.front(); } } return {}; } bool successParse(std::string const& _source, shared_ptr _dialect = Dialect::yul(), bool _allowWarnings = true) { return !parseAndReturnFirstError(_source, _dialect, _allowWarnings); } Error expectError(std::string const& _source, shared_ptr _dialect = Dialect::yul(), bool _allowWarnings = false) { auto error = parseAndReturnFirstError(_source, _dialect, _allowWarnings); BOOST_REQUIRE(error); return *error; } } #define CHECK_ERROR_DIALECT(text, typ, substring, dialect) \ do \ { \ Error err = expectError((text), dialect, false); \ BOOST_CHECK(err.type() == (Error::Type::typ)); \ BOOST_CHECK(dev::solidity::searchErrorMessage(err, (substring))); \ } while(0) #define CHECK_ERROR(text, typ, substring) CHECK_ERROR_DIALECT(text, typ, substring, Dialect::yul()) BOOST_AUTO_TEST_SUITE(YulParser) BOOST_AUTO_TEST_CASE(smoke_test) { BOOST_CHECK(successParse("{ }")); } BOOST_AUTO_TEST_CASE(vardecl) { BOOST_CHECK(successParse("{ let x:u256 := 7:u256 }")); } BOOST_AUTO_TEST_CASE(vardecl_bool) { BOOST_CHECK(successParse("{ let x:bool := true:bool }")); BOOST_CHECK(successParse("{ let x:bool := false:bool }")); } BOOST_AUTO_TEST_CASE(vardecl_empty) { BOOST_CHECK(successParse("{ let x:u256 }")); } BOOST_AUTO_TEST_CASE(assignment) { BOOST_CHECK(successParse("{ let x:u256 := 2:u256 let y:u256 := x }")); } BOOST_AUTO_TEST_CASE(vardecl_complex) { BOOST_CHECK(successParse("{ function add(a:u256, b:u256) -> c:u256 {} let y:u256 := 2:u256 let x:u256 := add(7:u256, add(6:u256, y)) }")); } BOOST_AUTO_TEST_CASE(blocks) { BOOST_CHECK(successParse("{ let x:u256 := 7:u256 { let y:u256 := 3:u256 } { let z:u256 := 2:u256 } }")); } BOOST_AUTO_TEST_CASE(function_definitions) { BOOST_CHECK(successParse("{ function f() { } function g(a:u256) -> x:u256 { } }")); } BOOST_AUTO_TEST_CASE(function_definitions_multiple_args) { BOOST_CHECK(successParse("{ function f(a:u256, d:u256) { } function g(a:u256, d:u256) -> x:u256, y:u256 { } }")); } BOOST_AUTO_TEST_CASE(function_calls) { BOOST_CHECK(successParse("{ function f(a:u256) -> b:u256 {} function g(a:u256, b:u256, c:u256) {} function x() { g(1:u256, 2:u256, f(3:u256)) x() } }")); } BOOST_AUTO_TEST_CASE(tuple_assignment) { BOOST_CHECK(successParse("{ function f() -> a:u256, b:u256, c:u256 {} let x:u256, y:u256, z:u256 := f() }")); } BOOST_AUTO_TEST_CASE(label) { CHECK_ERROR("{ label: }", ParserError, "Labels are not supported."); } BOOST_AUTO_TEST_CASE(instructions) { CHECK_ERROR("{ pop }", ParserError, "Call or assignment expected."); } BOOST_AUTO_TEST_CASE(push) { CHECK_ERROR("{ 0x42:u256 }", ParserError, "Call or assignment expected."); } BOOST_AUTO_TEST_CASE(assign_from_stack) { CHECK_ERROR("{ =: x:u256 }", ParserError, "Literal or identifier expected."); } BOOST_AUTO_TEST_CASE(empty_call) { CHECK_ERROR("{ () }", ParserError, "Literal or identifier expected."); } BOOST_AUTO_TEST_CASE(tokens_as_identifers) { BOOST_CHECK(successParse("{ let return:u256 := 1:u256 }")); BOOST_CHECK(successParse("{ let byte:u256 := 1:u256 }")); BOOST_CHECK(successParse("{ let address:u256 := 1:u256 }")); BOOST_CHECK(successParse("{ let bool:u256 := 1:u256 }")); } BOOST_AUTO_TEST_CASE(lacking_types) { CHECK_ERROR("{ let x := 1:u256 }", ParserError, "Expected identifier but got '='"); CHECK_ERROR("{ let x:u256 := 1 }", ParserError, "Expected ':' but got '}'"); CHECK_ERROR("{ function f(a) {} }", ParserError, "Expected ':' but got ')'"); CHECK_ERROR("{ function f(a:u256) -> b {} }", ParserError, "Expected ':' but got '{'"); } BOOST_AUTO_TEST_CASE(invalid_types) { /// testing invalid literal /// NOTE: these will need to change when types are compared CHECK_ERROR("{ let x:bool := 1:invalid }", TypeError, "\"invalid\" is not a valid type (user defined types are not yet supported)."); /// testing invalid variable declaration CHECK_ERROR("{ let x:invalid := 1:bool }", TypeError, "\"invalid\" is not a valid type (user defined types are not yet supported)."); CHECK_ERROR("{ function f(a:invalid) {} }", TypeError, "\"invalid\" is not a valid type (user defined types are not yet supported)."); } BOOST_AUTO_TEST_CASE(number_literals) { BOOST_CHECK(successParse("{ let x:u256 := 1:u256 }")); CHECK_ERROR("{ let x:u256 := .1:u256 }", ParserError, "Invalid number literal."); CHECK_ERROR("{ let x:u256 := 1e5:u256 }", ParserError, "Invalid number literal."); CHECK_ERROR("{ let x:u256 := 67.235:u256 }", ParserError, "Invalid number literal."); CHECK_ERROR("{ let x:u256 := 0x1ffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff:u256 }", TypeError, "Number literal too large (> 256 bits)"); } BOOST_AUTO_TEST_CASE(builtin_types) { BOOST_CHECK(successParse("{ let x:bool := true:bool }")); BOOST_CHECK(successParse("{ let x:u8 := 1:u8 }")); BOOST_CHECK(successParse("{ let x:s8 := 1:u8 }")); BOOST_CHECK(successParse("{ let x:u32 := 1:u32 }")); BOOST_CHECK(successParse("{ let x:s32 := 1:s32 }")); BOOST_CHECK(successParse("{ let x:u64 := 1:u64 }")); BOOST_CHECK(successParse("{ let x:s64 := 1:s64 }")); BOOST_CHECK(successParse("{ let x:u128 := 1:u128 }")); BOOST_CHECK(successParse("{ let x:s128 := 1:s128 }")); BOOST_CHECK(successParse("{ let x:u256 := 1:u256 }")); BOOST_CHECK(successParse("{ let x:s256 := 1:s256 }")); } BOOST_AUTO_TEST_CASE(recursion_depth) { string input; for (size_t i = 0; i < 20000; i++) input += "{"; input += "let x:u256 := 0:u256"; for (size_t i = 0; i < 20000; i++) input += "}"; CHECK_ERROR(input, ParserError, "recursion"); } BOOST_AUTO_TEST_CASE(multiple_assignment) { CHECK_ERROR("{ let x:u256 function f() -> a:u256, b:u256 {} 123:u256, x := f() }", ParserError, "Label name / variable name must precede \",\" (multiple assignment)."); CHECK_ERROR("{ let x:u256 function f() -> a:u256, b:u256 {} x, 123:u256 := f() }", ParserError, "Variable name expected in multiple assignment."); /// NOTE: Travis hiccups if not having a variable char const* text = R"( { function f(a:u256) -> r1:u256, r2:u256 { r1 := a r2 := 7:u256 } let x:u256 := 9:u256 let y:u256 := 2:u256 x, y := f(x) } )"; BOOST_CHECK(successParse(text)); } BOOST_AUTO_TEST_CASE(if_statement) { BOOST_CHECK(successParse("{ if true:bool {} }")); BOOST_CHECK(successParse("{ if false:bool { let x:u256 := 3:u256 } }")); BOOST_CHECK(successParse("{ function f() -> x:bool {} if f() { let b:bool := f() } }")); } BOOST_AUTO_TEST_CASE(if_statement_invalid) { CHECK_ERROR("{ if let x:u256 {} }", ParserError, "Literal or identifier expected."); CHECK_ERROR("{ if true:bool let x:u256 := 3:u256 }", ParserError, "Expected '{' but got reserved keyword 'let'"); // TODO change this to an error once we check types. BOOST_CHECK(successParse("{ if 42:u256 { } }")); } BOOST_AUTO_TEST_CASE(builtins_parser) { struct SimpleDialect: public Dialect { SimpleDialect(): Dialect(AsmFlavour::Strict) {} BuiltinFunction const* builtin(YulString _name) const override { return _name == "builtin"_yulstring ? &f : nullptr; } BuiltinFunction f; }; shared_ptr dialect = make_shared(); CHECK_ERROR_DIALECT("{ let builtin := 6 }", ParserError, "Cannot use builtin function name \"builtin\" as identifier name.", dialect); CHECK_ERROR_DIALECT("{ function builtin() {} }", ParserError, "Cannot use builtin function name \"builtin\" as identifier name.", dialect); CHECK_ERROR_DIALECT("{ builtin := 6 }", ParserError, "Cannot assign to builtin function \"builtin\".", dialect); } BOOST_AUTO_TEST_CASE(builtins_analysis) { struct SimpleDialect: public Dialect { SimpleDialect(): Dialect(AsmFlavour::Strict) {} BuiltinFunction const* builtin(YulString _name) const override { return _name == "builtin"_yulstring ? &f : nullptr; } BuiltinFunction f{"builtin"_yulstring, vector(2), vector(3), false}; }; shared_ptr dialect = make_shared(); BOOST_CHECK(successParse("{ let a, b, c := builtin(1, 2) }", dialect)); CHECK_ERROR_DIALECT("{ let a, b, c := builtin(1) }", TypeError, "Function expects 2 arguments but got 1", dialect); CHECK_ERROR_DIALECT("{ let a, b := builtin(1, 2) }", DeclarationError, "Variable count mismatch: 2 variables and 3 values.", dialect); } BOOST_AUTO_TEST_SUITE_END() } } // end namespaces