// // Copyright 2015 Ettus Research LLC // Copyright 2018 Ettus Research, a National Instruments Company // // SPDX-License-Identifier: GPL-3.0-or-later // #include "../lib/rfnoc/nocscript/function_table.hpp" #include "nocscript_common.hpp" #include #include #include #include #include #include BOOST_AUTO_TEST_CASE(test_basic_funcs) { function_table::sptr ft = function_table::make(); BOOST_CHECK(ft->function_exists("ADD")); BOOST_CHECK(ft->function_exists("ADD", two_int_args)); BOOST_CHECK(ft->function_exists("LE", two_int_args)); BOOST_CHECK(ft->function_exists("GE")); BOOST_CHECK(ft->function_exists("GE", two_int_args)); BOOST_CHECK(ft->function_exists("TRUE")); BOOST_CHECK(ft->function_exists("FALSE")); // Math expression_container::expr_list_type two_int_values{E(2), E(3)}; expression_container::expr_list_type two_int_values2{E(3), E(2)}; expression_container::expr_list_type two_double_values{E(2.0), E(3.0)}; BOOST_REQUIRE_EQUAL(ft->get_type("ADD", two_int_args), expression::TYPE_INT); expression_literal e_add = ft->eval("ADD", two_int_args, two_int_values); BOOST_REQUIRE_EQUAL(e_add.infer_type(), expression::TYPE_INT); BOOST_CHECK_EQUAL(e_add.get_int(), 5); BOOST_REQUIRE_EQUAL(ft->get_type("MULT", two_int_args), expression::TYPE_INT); expression_literal e_mult_i = ft->eval("MULT", two_int_args, two_int_values); BOOST_REQUIRE_EQUAL(e_mult_i.infer_type(), expression::TYPE_INT); BOOST_CHECK_EQUAL(e_mult_i.get_int(), 6); BOOST_REQUIRE_EQUAL(ft->get_type("MULT", two_double_args), expression::TYPE_DOUBLE); expression_literal e_mult_d = ft->eval("MULT", two_double_args, two_double_values); BOOST_REQUIRE_EQUAL(e_mult_d.infer_type(), expression::TYPE_DOUBLE); BOOST_CHECK_CLOSE(e_mult_d.get_double(), 6.0, 0.01); BOOST_REQUIRE_EQUAL(ft->get_type("DIV", two_double_args), expression::TYPE_DOUBLE); expression_literal e_div_d = ft->eval("DIV", two_double_args, two_double_values); BOOST_REQUIRE_EQUAL(e_div_d.infer_type(), expression::TYPE_DOUBLE); BOOST_CHECK_CLOSE(e_div_d.get_double(), 2.0 / 3.0, 0.01); BOOST_REQUIRE_EQUAL(ft->get_type("MODULO", two_int_args), expression::TYPE_INT); expression_literal e_modulo_i = ft->eval("MODULO", two_int_args, two_int_values); BOOST_REQUIRE_EQUAL(e_modulo_i.infer_type(), expression::TYPE_INT); BOOST_CHECK_EQUAL(e_modulo_i.get_int(), 2 % 3); BOOST_REQUIRE_EQUAL(ft->get_type("LE", two_int_args), expression::TYPE_BOOL); expression_literal e_le = ft->eval("LE", two_int_args, two_int_values); BOOST_REQUIRE_EQUAL(e_le.infer_type(), expression::TYPE_BOOL); BOOST_CHECK_EQUAL(e_le.get_bool(), true); BOOST_CHECK_EQUAL(ft->eval("LE", two_int_args, two_int_values2).get_bool(), false); expression_literal e_ge = ft->eval("GE", two_int_args, two_int_values); BOOST_REQUIRE_EQUAL(ft->get_type("GE", two_int_args), expression::TYPE_BOOL); BOOST_REQUIRE_EQUAL(e_ge.infer_type(), expression::TYPE_BOOL); BOOST_CHECK_EQUAL(e_ge.get_bool(), false); expression_container::expr_list_type sixty_four{E(64)}; expression_literal e_pwr2 = ft->eval("IS_PWR_OF_2", one_int_arg, sixty_four); BOOST_REQUIRE_EQUAL(e_pwr2.infer_type(), expression::TYPE_BOOL); BOOST_CHECK_EQUAL(e_pwr2.get_bool(), true); expression_literal e_log2 = ft->eval("LOG2", one_int_arg, sixty_four); BOOST_REQUIRE_EQUAL(e_log2.infer_type(), expression::TYPE_INT); BOOST_CHECK_EQUAL(e_log2.get_int(), 6); // Boolean Logic expression_container::expr_list_type e_true{E(true)}; expression_container::expr_list_type e_false{E(false)}; BOOST_CHECK(ft->eval("TRUE", no_args, empty_arg_list).to_bool()); BOOST_CHECK(ft->eval("TRUE", no_args, empty_arg_list).get_bool()); BOOST_CHECK_EQUAL(ft->eval("FALSE", no_args, empty_arg_list).to_bool(), false); BOOST_CHECK_EQUAL(ft->eval("FALSE", no_args, empty_arg_list).get_bool(), false); BOOST_CHECK(ft->eval("NOT", one_bool_arg, e_false).to_bool()); // Control std::cout << "Checking ~1s sleep until... "; expression_container::expr_list_type e_sleeptime{E(.999)}; BOOST_CHECK(ft->eval("SLEEP", one_double_arg, e_sleeptime).get_bool()); std::cout << "Now." << std::endl; } // Some bogus function to test the registry expression_literal add_plus2_int(expression_container::expr_list_type args) { return expression_literal(args[0]->eval().get_int() + args[1]->eval().get_int() + 2); } BOOST_AUTO_TEST_CASE(test_add_funcs) { function_table::sptr ft = function_table::make(); BOOST_CHECK(not ft->function_exists("ADD_PLUS_2")); expression_function::argtype_list_type add_int_args{ expression::TYPE_INT, expression::TYPE_INT}; ft->register_function("ADD_PLUS_2", boost::bind(&add_plus2_int, _1), expression::TYPE_INT, add_int_args); BOOST_CHECK(ft->function_exists("ADD_PLUS_2")); BOOST_CHECK(ft->function_exists("ADD_PLUS_2", add_int_args)); expression_container::expr_list_type add_int_values{E(2), E(3)}; expression_literal e = ft->eval("ADD_PLUS_2", two_int_args, add_int_values); BOOST_REQUIRE_EQUAL(e.infer_type(), expression::TYPE_INT); BOOST_CHECK_EQUAL(e.get_int(), 7); } int dummy_true_counter = 0; // Some bogus function to test the registry expression_literal dummy_true(expression_container::expr_list_type) { dummy_true_counter++; std::cout << "Running dummy/true statement." << std::endl; return expression_literal(true); } int dummy_false_counter = 0; // Some bogus function to test the registry expression_literal dummy_false(expression_container::expr_list_type) { dummy_false_counter++; std::cout << "Running dummy/false statement." << std::endl; return expression_literal(false); } BOOST_AUTO_TEST_CASE(test_conditionals) { function_table::sptr ft = function_table::make(); ft->register_function( "DUMMY", boost::bind(&dummy_true, _1), expression::TYPE_BOOL, no_args); ft->register_function( "DUMMY_F", boost::bind(&dummy_false, _1), expression::TYPE_BOOL, no_args); BOOST_REQUIRE(ft->function_exists("DUMMY", no_args)); BOOST_REQUIRE(ft->function_exists("DUMMY_F", no_args)); expression_function::sptr dummy_statement = boost::make_shared("DUMMY", ft); expression_function::sptr if_statement = boost::make_shared("IF", ft); if_statement->add(E(true)); if_statement->add(dummy_statement); std::cout << "Dummy statement should run once until END:" << std::endl; dummy_true_counter = 0; BOOST_CHECK(if_statement->eval().get_bool()); BOOST_CHECK_EQUAL(dummy_true_counter, 1); std::cout << "END." << std::endl; std::cout << "Dummy statement should not run until END:" << std::endl; expression_function::sptr if_statement2 = boost::make_shared("IF", ft); if_statement2->add(E(false)); if_statement2->add(dummy_statement); dummy_true_counter = 0; BOOST_CHECK(not if_statement2->eval().get_bool()); BOOST_CHECK_EQUAL(dummy_true_counter, 0); std::cout << "END." << std::endl; expression_function::sptr if_else_statement = boost::make_shared("IF_ELSE", ft); expression_function::sptr dummy_statement_f = boost::make_shared("DUMMY_F", ft); if_else_statement->add(E(true)); if_else_statement->add(dummy_statement); if_else_statement->add(dummy_statement_f); dummy_true_counter = 0; dummy_false_counter = 0; std::cout << "Should execute dummy/true statement before END:" << std::endl; BOOST_CHECK(if_else_statement->eval().get_bool()); BOOST_CHECK_EQUAL(dummy_true_counter, 1); BOOST_CHECK_EQUAL(dummy_false_counter, 0); std::cout << "END." << std::endl; expression_function::sptr if_else_statement2 = boost::make_shared("IF_ELSE", ft); if_else_statement2->add(E(false)); if_else_statement2->add(dummy_statement); if_else_statement2->add(dummy_statement_f); dummy_true_counter = 0; dummy_false_counter = 0; std::cout << "Should execute dummy/false statement before END:" << std::endl; BOOST_CHECK(not if_else_statement2->eval().get_bool()); BOOST_CHECK_EQUAL(dummy_true_counter, 0); BOOST_CHECK_EQUAL(dummy_false_counter, 1); std::cout << "END." << std::endl; } BOOST_AUTO_TEST_CASE(test_bitwise_funcs) { function_table::sptr ft = function_table::make(); BOOST_CHECK(ft->function_exists("SHIFT_RIGHT")); BOOST_CHECK(ft->function_exists("SHIFT_RIGHT", two_int_args)); BOOST_CHECK(ft->function_exists("SHIFT_LEFT")); BOOST_CHECK(ft->function_exists("SHIFT_LEFT", two_int_args)); BOOST_CHECK(ft->function_exists("BITWISE_AND")); BOOST_CHECK(ft->function_exists("BITWISE_AND", two_int_args)); BOOST_CHECK(ft->function_exists("BITWISE_OR")); BOOST_CHECK(ft->function_exists("BITWISE_OR", two_int_args)); BOOST_CHECK(ft->function_exists("BITWISE_XOR")); BOOST_CHECK(ft->function_exists("BITWISE_XOR", two_int_args)); // Bitwise Math int int_value1 = 0x2; int int_value2 = 0x3; expression_container::expr_list_type two_int_values{E(int_value1), E(int_value2)}; BOOST_REQUIRE_EQUAL(ft->get_type("SHIFT_RIGHT", two_int_args), expression::TYPE_INT); expression_literal e_shift_right = ft->eval("SHIFT_RIGHT", two_int_args, two_int_values); BOOST_REQUIRE_EQUAL(e_shift_right.infer_type(), expression::TYPE_INT); BOOST_CHECK_EQUAL(e_shift_right.get_int(), int_value1 >> int_value2); BOOST_REQUIRE_EQUAL(ft->get_type("SHIFT_LEFT", two_int_args), expression::TYPE_INT); expression_literal e_shift_left = ft->eval("SHIFT_LEFT", two_int_args, two_int_values); BOOST_REQUIRE_EQUAL(e_shift_left.infer_type(), expression::TYPE_INT); BOOST_CHECK_EQUAL(e_shift_left.get_int(), int_value1 << int_value2); BOOST_REQUIRE_EQUAL(ft->get_type("BITWISE_AND", two_int_args), expression::TYPE_INT); expression_literal e_bitwise_and = ft->eval("BITWISE_AND", two_int_args, two_int_values); BOOST_REQUIRE_EQUAL(e_bitwise_and.infer_type(), expression::TYPE_INT); BOOST_CHECK_EQUAL(e_bitwise_and.get_int(), int_value1 & int_value2); BOOST_REQUIRE_EQUAL(ft->get_type("BITWISE_OR", two_int_args), expression::TYPE_INT); expression_literal e_bitwise_or = ft->eval("BITWISE_OR", two_int_args, two_int_values); BOOST_REQUIRE_EQUAL(e_bitwise_or.infer_type(), expression::TYPE_INT); BOOST_CHECK_EQUAL(e_bitwise_or.get_int(), int_value1 | int_value2); BOOST_REQUIRE_EQUAL(ft->get_type("BITWISE_XOR", two_int_args), expression::TYPE_INT); expression_literal e_bitwise_xor = ft->eval("BITWISE_XOR", two_int_args, two_int_values); BOOST_REQUIRE_EQUAL(e_bitwise_xor.infer_type(), expression::TYPE_INT); BOOST_CHECK_EQUAL(e_bitwise_xor.get_int(), int_value1 ^ int_value2); }