java实现四则混合运算 Java实现四则混合运算代码示例
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使用栈来实现,可以处理运算优先级。
使用自然四则运算表达式即可,如:4+(3*(3-1)+2)/2。无需把表达式先转换为逆波兰等形式。
package com.joshua.cal; import java.util.Collections; import java.util.HashMap; import java.util.HashSet; import java.util.LinkedList; import java.util.List; import java.util.Map; import java.util.Set; import java.util.Stack; public class Calculator { private final Stack<Double> numStack = new Stack<Double>(); private final Stack<Character> opStack = new Stack<Character>(); private char currentOperator; private char opStackTop; private int i; private String expression; @SuppressWarnings("rawtypes") public void exec(String expression) { try { clean(); if (expression == null || expression.isEmpty()) { throw new IllegalArgumentException("Blank Expression!"); } this.expression = expression; opStack.push(TERMINATE_TOKENS.START_END_MARK); List tokens = TOKENIZER.exec(expression + TERMINATE_TOKENS.START_END_MARK); for (; i < tokens.size(); i++) { final Object token = tokens.get(i); if (token instanceof Double) { processOperand((double) token); } else { processOperator((char) token); } } } catch (Throwable e) { System.err.println(String.format( "Incorret Expression: %s\nError: %s", expression, e.getMessage())); } } private void processOperand(final double operand) { numStack.push(operand); } private void processOperator(final char currentOperator) { this.currentOperator = currentOperator; this.opStackTop = opStack.peek(); char calMode = CALCULATE_MODE.getRule(currentOperator, opStackTop); switch (calMode) { case '>': processStackHigerPriorityOperator(); break; case '<': processStackLowerPriorityOperator(); break; case '=': processStackEqualPriorityOperator(); break; default: break; } } private void processStackLowerPriorityOperator() { opStack.push(currentOperator); } private void processStackHigerPriorityOperator() { numStack.push(CALCULATE.exec(opStack.pop(), numStack.pop(), numStack.pop())); --i; // pointer back to the previous operator. } private void processStackEqualPriorityOperator() { if (TERMINATE_TOKENS.START_END_MARK == currentOperator) { System.out.println(expression + " = " + numStack.peek()); } else if (')' == currentOperator) { opStack.pop(); } } public void clean() { numStack.clear(); opStack.clear(); i = 0; } public static void main(String[] args) { Calculator cal = new Calculator(); cal.exec("4+(3*(3-1)+2)/2"); // = 8 cal.exec("4 + (-3 * ( 3 - 1 ) + 2)"); // = 0 cal.exec("4 +-/ (-3 * ( 3 - 1 ) + 2)"); // incorrect expression! cal.exec("4.5+(3.2+3)/2"); // = 7.6 cal.exec("4.5+(3.2:3)/2"); // incorrect expression! cal.exec("-4.5+(3.2-3)/2"); // = -4.4 } } enum CALCULATE { INSTANCE; public static double exec(final char operator, final double right, final double left) { switch (operator) { case '+': return left + right; case '-': return left - right; case '*': return left * right; case '/': return left / right; default: throw new IllegalArgumentException("Unsupported operator: " + operator); } } } enum TERMINATE_TOKENS { INSTANCE; public static final char START_END_MARK = '#'; private static final Map<Character, Integer> TOKENs = new HashMap<Character, Integer>(); static { // token, token id TOKENs.put('+', 0); TOKENs.put('-', 1); TOKENs.put('*', 2); TOKENs.put('/', 3); TOKENs.put('(', 4); TOKENs.put(')', 5); TOKENs.put(START_END_MARK, 6); } private static Set<Character> NEGATIVE_NUM_SENSITIVE = new HashSet<Character>(); public static synchronized Set<Character> getNegativeNumSensitiveToken() { if (NEGATIVE_NUM_SENSITIVE.size() == 0) { NEGATIVE_NUM_SENSITIVE.addAll(TOKENs.keySet()); NEGATIVE_NUM_SENSITIVE.remove(')'); } return NEGATIVE_NUM_SENSITIVE; } public static boolean isTerminateToken(final char token) { Set<Character> keys = TOKENs.keySet(); return keys.contains(token); } public static int getTokenId(final char token) { return TOKENs.get(token) == null ? -1 : TOKENs.get(token); } public static int getTokenSize() { return TOKENs.size(); } } enum CALCULATE_MODE { INSTANCE; private static char[][] RULES = { // + - * / ( ) # { '>', '>', '<', '<', '<', '>', '>' }, // + { '>', '>', '<', '<', '<', '>', '>' }, // - { '>', '>', '>', '>', '<', '>', '>' }, // * { '>', '>', '>', '>', '<', '>', '>' }, // / { '<', '<', '<', '<', '<', '=', 'o' }, // ( { '>', '>', '>', '>', 'o', '>', '>' }, // ) { '<', '<', '<', '<', '<', 'o', '=' }, // # }; static { if (RULES.length != TERMINATE_TOKENS.getTokenSize() || RULES.length < 1 || RULES[0].length != TERMINATE_TOKENS.getTokenSize()) { throw new IllegalArgumentException("Rules matrix is incorrect!"); } } public static char getRule(final char currentOperator, final char opStackTop) { try { return RULES[TERMINATE_TOKENS.getTokenId(opStackTop)][TERMINATE_TOKENS .getTokenId(currentOperator)]; } catch (Throwable e) { throw new RuntimeException("No rules were defined for some token!"); } } } enum TOKENIZER { INSTANCE; private static final StringBuilder BUFFER = new StringBuilder(); private static String clearExpression(String expression) { return expression.replaceAll(" ", ""); } private static Character PREVIOUS_CHAR; private static void clean() { BUFFER.delete(0, BUFFER.length()); PREVIOUS_CHAR = null; } private static boolean processNegativeNumbers(final String exp, final int index) { char c = exp.charAt(index); if (('+' == c || '-' == c) && (PREVIOUS_CHAR == null || TERMINATE_TOKENS .getNegativeNumSensitiveToken().contains(PREVIOUS_CHAR)) && !TERMINATE_TOKENS.isTerminateToken(exp.charAt(index + 1))) { BUFFER.append(c); return true; } return false; } @SuppressWarnings({ "unchecked", "rawtypes" }) public static List<?> exec(final String expression) { clean(); String exp = clearExpression(expression); List result = new LinkedList(); for (int i = 0; i < exp.length(); i++) { char c = exp.charAt(i); if (TERMINATE_TOKENS.isTerminateToken(c)) { if (processNegativeNumbers(exp, i)) continue; if (BUFFER.length() > 0) { result.add(Double.valueOf(BUFFER.toString())); BUFFER.delete(0, BUFFER.length()); } result.add(c); } else { BUFFER.append(c); } PREVIOUS_CHAR = c; } return Collections.unmodifiableList(result); } }
输出
4+(3*(3-1)+2)/2 = 8.0 4 + (-3 * ( 3 - 1 ) + 2) = 0.0 4.5+(3.2+3)/2 = 7.6 -4.5+(3.2-3)/2 = -4.4 Incorret Expression: 4 +-/ (-3 * ( 3 - 1 ) + 2) Error: null Incorret Expression: 4.5+(3.2:3)/2 Error: For input string: "3.2:3"
总结
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