// // Copyright 2015 Ettus Research LLC // // This program 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. // // This program 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 this program. If not, see . // #include "../lib/rfnoc/nocscript/function_table.hpp" #include #include #include #include #include #include #include #include "nocscript_common.hpp" // We need this global variable for one of the later tests int and_counter = 0; BOOST_AUTO_TEST_CASE(test_literals) { expression_literal literal_int("5", expression::TYPE_INT); BOOST_CHECK_EQUAL(literal_int.infer_type(), expression::TYPE_INT); BOOST_CHECK_EQUAL(literal_int.get_int(), 5); BOOST_CHECK_EQUAL(literal_int.to_bool(), true); BOOST_REQUIRE_THROW(literal_int.get_string(), uhd::type_error); BOOST_REQUIRE_THROW(literal_int.get_bool(), uhd::type_error); expression_literal literal_int0("0", expression::TYPE_INT); BOOST_CHECK_EQUAL(literal_int0.infer_type(), expression::TYPE_INT); BOOST_CHECK_EQUAL(literal_int0.to_bool(), false); expression_literal literal_double("2.3", expression::TYPE_DOUBLE); BOOST_CHECK_EQUAL(literal_double.infer_type(), expression::TYPE_DOUBLE); BOOST_CHECK_CLOSE(literal_double.get_double(), 2.3, 0.01); BOOST_CHECK_EQUAL(literal_double.to_bool(), true); BOOST_REQUIRE_THROW(literal_double.get_string(), uhd::type_error); BOOST_REQUIRE_THROW(literal_double.get_bool(), uhd::type_error); expression_literal literal_bool(true); BOOST_CHECK_EQUAL(literal_bool.infer_type(), expression::TYPE_BOOL); BOOST_CHECK_EQUAL(literal_bool.get_bool(), true); BOOST_CHECK_EQUAL(literal_bool.to_bool(), true); BOOST_CHECK_EQUAL(literal_bool.eval().get_bool(), true); BOOST_REQUIRE_THROW(literal_bool.get_string(), uhd::type_error); BOOST_REQUIRE_THROW(literal_bool.get_int(), uhd::type_error); expression_literal literal_bool_false(false); BOOST_CHECK_EQUAL(literal_bool_false.infer_type(), expression::TYPE_BOOL); BOOST_CHECK_EQUAL(literal_bool_false.get_bool(), false); BOOST_CHECK_EQUAL(literal_bool_false.to_bool(), false); BOOST_REQUIRE_EQUAL(literal_bool_false.eval().get_bool(), false); BOOST_REQUIRE_THROW(literal_bool_false.get_string(), uhd::type_error); BOOST_REQUIRE_THROW(literal_bool_false.get_int(), uhd::type_error); expression_literal literal_string("'foo bar'", expression::TYPE_STRING); BOOST_CHECK_EQUAL(literal_string.infer_type(), expression::TYPE_STRING); BOOST_CHECK_EQUAL(literal_string.get_string(), "foo bar"); BOOST_REQUIRE_THROW(literal_string.get_bool(), uhd::type_error); BOOST_REQUIRE_THROW(literal_string.get_int(), uhd::type_error); expression_literal literal_int_vec("[1, 2, 3]", expression::TYPE_INT_VECTOR); BOOST_CHECK_EQUAL(literal_int_vec.infer_type(), expression::TYPE_INT_VECTOR); std::vector test_data = boost::assign::list_of(1)(2)(3); std::vector result = literal_int_vec.get_int_vector(); BOOST_CHECK_EQUAL_COLLECTIONS(test_data.begin(), test_data.end(), result.begin(), result.end()); BOOST_REQUIRE_THROW(literal_int_vec.get_bool(), uhd::type_error); BOOST_REQUIRE_THROW(literal_int_vec.get_int(), uhd::type_error); } // Need those for the variable testing: expression::type_t variable_get_type(const std::string &var_name) { if (var_name == "spp") { std::cout << "Returning type for $spp..." << std::endl; return expression::TYPE_INT; } if (var_name == "is_true") { std::cout << "Returning type for $is_true..." << std::endl; return expression::TYPE_BOOL; } throw uhd::syntax_error("Cannot infer type (unknown variable)"); } expression_literal variable_get_value(const std::string &var_name) { if (var_name == "spp") { std::cout << "Returning value for $spp..." << std::endl; return expression_literal(5); } if (var_name == "is_true") { std::cout << "Returning value for $is_true..." << std::endl; return expression_literal(true); } throw uhd::syntax_error("Cannot read value (unknown variable)"); } BOOST_AUTO_TEST_CASE(test_variables) { BOOST_REQUIRE_THROW( expression_variable v_fail( "foo", // Invalid token boost::bind(&variable_get_type, _1), boost::bind(&variable_get_value, _1) ), uhd::assertion_error ); expression_variable v( "$spp", // The token boost::bind(&variable_get_type, _1), // type-getter boost::bind(&variable_get_value, _1) // value-getter ); BOOST_CHECK_EQUAL(v.infer_type(), expression::TYPE_INT); BOOST_CHECK_EQUAL(v.eval().get_int(), 5); } BOOST_AUTO_TEST_CASE(test_container) { // Create some sub-expressions: expression_literal::sptr l_true = E(true); expression_literal::sptr l_false = E(false); expression_literal::sptr l_int = E(5); BOOST_REQUIRE_EQUAL(l_false->get_bool(), false); BOOST_REQUIRE_EQUAL(l_false->to_bool(), false); expression_variable::sptr l_boolvar = boost::make_shared( "$is_true", boost::bind(&variable_get_type, _1), boost::bind(&variable_get_value, _1) ); // This will throw anytime it's evaluated: expression_variable::sptr l_failvar = boost::make_shared( "$does_not_exist", boost::bind(&variable_get_type, _1), boost::bind(&variable_get_value, _1) ); expression_container c; std::cout << "One true, OR: " << std::endl; c.add(l_true); c.set_combiner_safe(expression_container::COMBINE_OR); expression_literal ret_val_1 = c.eval(); BOOST_CHECK_EQUAL(ret_val_1.infer_type(), expression::TYPE_BOOL); BOOST_CHECK_EQUAL(ret_val_1.eval().get_bool(), true); std::cout << std::endl << std::endl << "Two true, one false, OR: " << std::endl; c.add(l_true); c.add(l_false); expression_literal ret_val_2 = c.eval(); BOOST_CHECK_EQUAL(ret_val_2.infer_type(), expression::TYPE_BOOL); BOOST_CHECK_EQUAL(ret_val_2.eval().get_bool(), true); expression_container c2; c2.add(l_false); c2.add(l_false); c2.set_combiner(expression_container::COMBINE_AND); std::cout << std::endl << std::endl << "Two false, AND: " << std::endl; expression_literal ret_val_3 = c2.eval(); BOOST_CHECK_EQUAL(ret_val_3.infer_type(), expression::TYPE_BOOL); BOOST_REQUIRE_EQUAL(ret_val_3.eval().get_bool(), false); c2.add(l_failvar); // Will not fail, because l_failvar never gets eval'd: expression_literal ret_val_4 = c2.eval(); BOOST_CHECK_EQUAL(ret_val_4.infer_type(), expression::TYPE_BOOL); BOOST_CHECK_EQUAL(ret_val_4.eval().get_bool(), false); // Same here: c.add(l_failvar); expression_literal ret_val_5 = c.eval(); BOOST_CHECK_EQUAL(ret_val_5.infer_type(), expression::TYPE_BOOL); BOOST_CHECK_EQUAL(ret_val_5.eval().get_bool(), true); // Now it'll throw: c.set_combiner(expression_container::COMBINE_ALL); BOOST_REQUIRE_THROW(c.eval(), uhd::syntax_error); std::cout << "Checking type inference on ',' sequences: " << std::endl; // Check types match BOOST_CHECK_EQUAL(c2.infer_type(), expression::TYPE_BOOL); expression_container c3; c3.set_combiner(expression_container::COMBINE_ALL); c3.add(l_false); c3.add(l_int); BOOST_CHECK_EQUAL(c3.infer_type(), expression::TYPE_INT); } // We'll define two functions here: ADD and XOR. The former shall // be defined for INT and DOUBLE class functable_mockup_impl : public function_table { public: functable_mockup_impl(void) {}; bool function_exists(const std::string &name) const { return name == "ADD" or name == "XOR" or name == "AND"; } bool function_exists( const std::string &name, const expression_function::argtype_list_type &arg_types ) const { if (name == "ADD") { if (arg_types.size() == 2 and arg_types[0] == expression::TYPE_DOUBLE and arg_types[1] == expression::TYPE_DOUBLE ) { return true; } if (arg_types.size() == 2 and arg_types[0] == expression::TYPE_INT and arg_types[1] == expression::TYPE_INT ) { return true; } return false; } if (name == "XOR" or name == "AND") { if (arg_types.size() == 2 and arg_types[0] == expression::TYPE_BOOL and arg_types[1] == expression::TYPE_BOOL ) { return true; } return false; } return false; } expression::type_t get_type( const std::string &name, const expression_function::argtype_list_type &arg_types ) const { if (not function_exists(name, arg_types)) { throw uhd::syntax_error(str( boost::format("[EXPR_TEXT] get_type(): Unknown function: %s, %d arguments") % name % arg_types.size() )); } if (name == "XOR" or name == "AND") { return expression::TYPE_BOOL; } if (name == "ADD") { return arg_types[0]; } UHD_THROW_INVALID_CODE_PATH(); } expression_literal eval( const std::string &name, const expression_function::argtype_list_type &arg_types, expression_container::expr_list_type &args ) { if (name == "XOR") { if (arg_types.size() != 2 or args.size() != 2 or arg_types[0] != expression::TYPE_BOOL or arg_types[1] != expression::TYPE_BOOL or args[0]->infer_type() != expression::TYPE_BOOL or args[1]->infer_type() != expression::TYPE_BOOL ) { throw uhd::syntax_error("eval(): XOR type mismatch"); } return expression_literal(bool( args[0]->eval().get_bool() xor args[1]->eval().get_bool() )); } if (name == "AND") { if (arg_types.size() != 2 or args.size() != 2 or arg_types[0] != expression::TYPE_BOOL or arg_types[1] != expression::TYPE_BOOL or args[0]->infer_type() != expression::TYPE_BOOL or args[1]->infer_type() != expression::TYPE_BOOL ) { throw uhd::syntax_error("eval(): AND type mismatch"); } std::cout << "Calling AND" << std::endl; and_counter++; return expression_literal(bool( args[0]->eval().get_bool() and args[1]->eval().get_bool() )); } if (name == "ADD") { if (args.size() != 2) { throw uhd::syntax_error("eval(): ADD type mismatch"); } if ((args[0]->infer_type() == expression::TYPE_INT) and (args[1]->infer_type() == expression::TYPE_INT)) { return expression_literal(int( args[0]->eval().get_int() + args[1]->eval().get_int() )); } else if ((args[0]->infer_type() == expression::TYPE_DOUBLE) and (args[1]->infer_type() == expression::TYPE_DOUBLE)) { return expression_literal(double( args[0]->eval().get_double() + args[1]->eval().get_double() )); } throw uhd::syntax_error("eval(): ADD type mismatch"); } throw uhd::syntax_error("eval(): unknown function"); } // We don't actually need this void register_function( const std::string &, const function_table::function_ptr &, const expression::type_t, const expression_function::argtype_list_type & ) {}; }; // The annoying part: Testing the test fixtures BOOST_AUTO_TEST_CASE(test_functable_mockup) { functable_mockup_impl functable; BOOST_CHECK(functable.function_exists("ADD")); BOOST_CHECK(functable.function_exists("XOR")); BOOST_CHECK(not functable.function_exists("FOOBAR")); BOOST_CHECK(functable.function_exists("ADD", two_int_args)); BOOST_CHECK(functable.function_exists("ADD", two_double_args)); BOOST_CHECK(functable.function_exists("XOR", two_bool_args)); BOOST_CHECK(not functable.function_exists("ADD", two_bool_args)); BOOST_CHECK(not functable.function_exists("ADD", no_args)); BOOST_CHECK(not functable.function_exists("XOR", no_args)); BOOST_CHECK_EQUAL(functable.get_type("ADD", two_int_args), expression::TYPE_INT); BOOST_CHECK_EQUAL(functable.get_type("ADD", two_double_args), expression::TYPE_DOUBLE); BOOST_CHECK_EQUAL(functable.get_type("XOR", two_bool_args), expression::TYPE_BOOL); expression_container::expr_list_type add_args_int = boost::assign::list_of(E(2))(E(3)) ; expression_container::expr_list_type add_args_dbl = boost::assign::list_of (E(2.25)) (E(5.0)) ; expression_container::expr_list_type xor_args_bool = boost::assign::list_of (E(true)) (E(false)) ; BOOST_CHECK_EQUAL(functable.eval("ADD", two_int_args, add_args_int), expression_literal(5)); BOOST_CHECK_EQUAL(functable.eval("ADD", two_double_args, add_args_dbl), expression_literal(7.25)); BOOST_CHECK_EQUAL(functable.eval("XOR", two_bool_args, xor_args_bool), expression_literal(true)); } BOOST_AUTO_TEST_CASE(test_function_expression) { function_table::sptr ft = boost::make_shared(); // Very simple function: ADD(2, 3) expression_function func1("ADD", ft); func1.add(E(2)); func1.add(E(3)); BOOST_CHECK_EQUAL(func1.eval(), expression_literal(5)); // More elaborate: ADD(ADD(2, 3), ADD(ADD(4, 5), 6)) ?= 20 // f4 f1 f3 f2 expression_function f1("ADD", ft); f1.add(E(2)); f1.add(E(3)); expression_function f2("ADD", ft); f2.add(E(4)); f2.add(E(5)); expression_function f3("ADD", ft); f3.add(boost::make_shared(f2)); f3.add(E(6)); expression_function f4("ADD", ft); f4.add(boost::make_shared(f1)); f4.add(boost::make_shared(f3)); BOOST_CHECK_EQUAL(f4.eval().get_int(), 20); } BOOST_AUTO_TEST_CASE(test_function_expression_laziness) { function_table::sptr ft = boost::make_shared(); // We run AND(AND(false, false), AND(false, false)). // f1 f2 f3 // That makes three ANDs // in total. However, we will only see AND being evaluated twice, because // the outcome is clear after running the first AND in the argument list. expression_function::sptr f2 = boost::make_shared("AND", ft); f2->add(E(false)); f2->add(E(false)); BOOST_CHECK(not f2->eval().get_bool()); expression_function::sptr f3 = boost::make_shared("AND", ft); f3->add(E(false)); f3->add(E(false)); BOOST_CHECK(not f3->eval().get_bool()); and_counter = 0; expression_function::sptr f1 = boost::make_shared("AND", ft); f1->add(f2); f1->add(f3); BOOST_CHECK(not f1->eval().get_bool()); BOOST_CHECK_EQUAL(and_counter, 2); } BOOST_AUTO_TEST_CASE(test_sptrs) { expression_container::sptr c = expression_container::make(); BOOST_CHECK_EQUAL(c->infer_type(), expression::TYPE_BOOL); BOOST_CHECK(c->eval().get_bool()); expression_variable::sptr v = expression_variable::make( "$spp", boost::bind(&variable_get_type, _1), // type-getter boost::bind(&variable_get_value, _1) // value-getter ); c->add(v); BOOST_REQUIRE_EQUAL(c->infer_type(), expression::TYPE_INT); BOOST_CHECK_EQUAL(c->eval().get_int(), 5); }