/* ************************************************************** * C++ Mathematical Expression Toolkit Library * * * * Simple Example 09 * * Author: Arash Partow (1999-2024) * * URL: https://www.partow.net/programming/exprtk/index.html * * * * Copyright notice: * * Free use of the Mathematical Expression Toolkit Library is * * permitted under the guidelines and in accordance with the * * most current version of the MIT License. * * https://www.opensource.org/licenses/MIT * * SPDX-License-Identifier: MIT * * * ************************************************************** */ #include #include #include "exprtk.hpp" template void primes() { typedef exprtk::symbol_table symbol_table_t; typedef exprtk::expression expression_t; typedef exprtk::parser parser_t; typedef exprtk::function_compositor compositor_t; typedef typename compositor_t::function function_t; T x = T(0); symbol_table_t symbol_table; symbol_table.add_constants(); symbol_table.add_variable("x",x); compositor_t compositor(symbol_table); //Mode 1 - if statement based compositor.add( function_t("is_prime_impl1") .vars("x", "y") .expression ( " if (y == 1,true, " " if (0 == (x % y),false, " " is_prime_impl1(x,y - 1))) " )); compositor.add( function_t("is_prime1") .var("x") .expression ( " if (frac(x) != 0) " " return [false]; " " else if (x <= 0) " " return [false]; " " else " " is_prime_impl1(x,min(x - 1,trunc(sqrt(x)) + 1)); " )); //Mode 2 - switch statement based compositor.add( function_t("is_prime_impl2") .vars("x", "y") .expression ( " switch " " { " " case y == 1 : true; " " case (x % y) == 0 : false; " " default : is_prime_impl2(x,y - 1); " " } " )); compositor.add( function_t("is_prime2") .var("x") .expression ( " switch " " { " " case x <= 0 : false; " " case frac(x) != 0 : false; " " default : is_prime_impl2(x,min(x - 1,trunc(sqrt(x)) + 1)); " " } " )); //Mode 3 - switch statement and for-loop based compositor.add( function_t("is_prime3") .var("x") .expression ( " switch " " { " " case x <= 1 : return [false]; " " case frac(x) != 0 : return [false]; " " case x == 2 : return [true ]; " " }; " " " " var prime_lut[27] := " " { " " 2, 3, 5, 7, 11, 13, 17, 19, 23, " " 29, 31, 37, 41, 43, 47, 53, 59, 61, " " 67, 71, 73, 79, 83, 89, 97, 101, 103 " " }; " " " " var upper_bound := min(x - 1, trunc(sqrt(x)) + 1); " " " " for (var i := 0; i < prime_lut[]; i += 1) " " { " " if (prime_lut[i] >= upper_bound) " " return [true]; " " else if ((x % prime_lut[i]) == 0) " " return [false]; " " }; " " " " var lower_bound := prime_lut[prime_lut[] - 1] + 2; " " " " for (var i := lower_bound; i < upper_bound; i += 2) " " { " " if ((x % i) == 0) " " { " " return [false]; " " } " " }; " " " " return [true]; " )); std::string expression_str1 = "is_prime1(x)"; std::string expression_str2 = "is_prime2(x)"; std::string expression_str3 = "is_prime3(x)"; expression_t expression1; expression_t expression2; expression_t expression3; expression1.register_symbol_table(symbol_table); expression2.register_symbol_table(symbol_table); expression3.register_symbol_table(symbol_table); parser_t parser; parser.compile(expression_str1, expression1); parser.compile(expression_str2, expression2); parser.compile(expression_str3, expression3); for (std::size_t i = 0; i < 15000; ++i) { x = static_cast(i); const T result1 = expression1.value(); const T result2 = expression2.value(); const T result3 = expression3.value(); const bool results_concur = (result1 == result2) && (result1 == result3) ; printf("%03d Result1: %c Result2: %c Result3: %c " "Results Concur: %c\n", static_cast(i), (result1 == T(1)) ? 'T' : 'F', (result2 == T(1)) ? 'T' : 'F', (result3 == T(1)) ? 'T' : 'F', (results_concur) ? 'T' : 'F'); } } int main() { primes(); return 0; }