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I have a string like the following:
String str = "4*5";
Now I have to get the result of 20 by using the string.
I know in some other languages the eval() function will do this.
How can I do this in Java?
You can use the ScriptEngine class and evaluate it as a Javascript string.
ScriptEngineManager manager = new ScriptEngineManager();
ScriptEngine engine = manager.getEngineByName("js");
Object result = engine.eval("4*5");
There may be a better way, but this one works.
There is no standard Java class or method that will do what you want. Your options include:
Select and use some third-party expression evaluation library. For example JEL or any of the half dozen libraries listed here.
Wrap the expression in the Java source code for a class with an eval method, send that to the Java compiler, and then load the resulting compiled class.
Use some scripting language that can be called from Java as an expression evaluator. Possibilities include Javascript1, BeanShell, and so on. A JSR 223 compliant scripting language implementation can be called via the Scripting API.
Write your own expression evaluator from scratch.
The first approach is probably simplest. The second and third approaches are a potential security risk if you get the expression to be evaluated from an untrusted user. (Think code injection.)
1 - Javascript in Java SE is a moving target. From Java 6, a version of Mozilla's Rhino Javascript implementation was bundled with Java SE. The in Java 8, it was superseded by Nashorn. In Java 11, Nashorn was deprecated, and finally dropped from the core codebase. As of 2021, both Rhino and Nashorn are being maintained as separate (non-Oracle) products, and Oracle's GraalVM has its own Javascript implementation.
There are very few real use cases in which being able to evaluate a String as a fragment of Java code is necessary or desirable. That is, asking how to do this is really an XY problem: you actually have a different problem, which can be solved a different way.
First ask yourself, where did this String that you wish to evaluate come from? Did another part of your program generate it, or was it input provided by the user?
Another part of my program generated it: so, you want one part of your program to decide the kind of operation to perform, but not perform the operation, and a second part that performs the chosen operation. Instead of generating and then evaluating a String, use the Strategy, Command or Builder design pattern, as appropriate for your particular case.
It is user input: the user could input anything, including commands that, when executed, could cause your program to misbehave, crash, expose information that should be secret, damage persistent information (such as the content of a database), and other such nastiness. The only way to prevent that would be to parse the String yourself, check it was not malicious, and then evaluate it. But parsing it yourself is much of the work that the requested evalfunction would do, so you have saved yourself nothing. Worse still, checking that arbitrary Java was not malicious is impossible, because checking that is the halting problem.
It is user input, but the syntax and semantics of permitted text to evaluate is greatly restricted: No general purpose facility can easily implement a general purpose parser and evaluator for whatever restricted syntax and semantics you have chosen. What you need to do is implement a parser and evaluator for your chosen syntax and semantics. If the task is simple, you could write a simple recursive-descent or finite-state-machine parser by hand. If the task is difficult, you could use a compiler-compiler (such as ANTLR) to do some of the work for you.
I just want to implement a desktop calculator!: A homework assignment, eh? If you could implement the evaluation of the input expression using a provided eval function, it would not be much of a homework assignment, would it? Your program would be three lines long. Your instructor probably expects you to write the code for a simple arithmetic parser/evaluator. There is well known algorithm, shunting-yard, which you might find useful.
With Java 9, we get access to jshell, so one can write something like this:
import jdk.jshell.JShell;
import java.lang.StringBuilder;
import java.io.BufferedReader;
import java.io.InputStreamReader;
import java.io.IOException;
public class Eval {
public static void main(String[] args) throws IOException {
try(JShell js = JShell.create(); BufferedReader br = new BufferedReader(new InputStreamReader(System.in))) {
js.onSnippetEvent(snip -> {
if (snip.status() == jdk.jshell.Snippet.Status.VALID) {
System.out.println("➜ " + snip.value());
}
});
System.out.print("> ");
for (String line = br.readLine(); line != null; line = br.readLine()) {
js.eval(js.sourceCodeAnalysis().analyzeCompletion(line).source());
System.out.print("> ");
}
}
}
}
Sample run:
> 1 + 2 / 4 * 3
➜ 1
> 32 * 121
➜ 3872
> 4 * 5
➜ 20
> 121 * 51
➜ 6171
>
Slightly op, but that's what Java currently has to offer
I could advise you to use Exp4j. It is easy to understand as you can see from the following example code:
Expression e = new ExpressionBuilder("3 * sin(y) - 2 / (x - 2)")
.variables("x", "y")
.build()
.setVariable("x", 2.3)
.setVariable("y", 3.14);
double result = e.evaluate();
No, you can not have a generic "eval" in Java (or any compiled language). Unless you're willing to write a Java compiler AND a JVM to be executed inside of your Java program.
Yes, you can have some library to evaluate numeric algebraic expressions like the one above - see this thread for discussion.
As previous answers, there is no standard API in Java for this.
You can add groovy jar files to your path and groovy.util.Eval.me("4*5") gets your job done.
A fun way to solve your problem could be coding an eval() function on your own!
I've done it for you!
You can use FunctionSolver library simply by typing FunctionSolver.solveByX(function,value) inside your code. The function attribute is a String which represents the function you want to solve, the value attribute is the value of the independent variable
of your function (which MUST be x).
If you want to solve a function which contains more than one independent variable, you can use FunctionSolver.solve(function,values) where the values attribute is an HashMap(String,Double) which contains all your independent attributes (as Strings) and their respective values (as Doubles).
Another piece of information: I've coded a simple version of FunctionSolver, so its supports only Math methods which return a double value and which accepts one or two double values as fields (just use FunctionSolver.usableMathMethods() if you're curious) (These methods are: bs, sin, cos, tan, atan2, sqrt, log, log10, pow, exp, min, max, copySign, signum, IEEEremainder, acos, asin, atan, cbrt, ceil, cosh, expm1, floor, hypot, log1p, nextAfter, nextDown, nextUp, random, rint, sinh, tanh, toDegrees, toRadians, ulp). Also, that library supports the following operators: * / + - ^ (even if java normally does not support the ^ operator).
One last thing: while creating this library I had to use reflections to call Math methods. I think it's really cool, just have a look at this if you are interested in!
That's all, here it is the code (and the library):
package core;
import java.lang.reflect.InvocationTargetException;
import java.lang.reflect.Method;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.HashMap;
public abstract class FunctionSolver {
public static double solveNumericExpression (String expression) throws NoSuchMethodException, IllegalAccessException, IllegalArgumentException, InvocationTargetException {
return solve(expression, new HashMap<>());
}
public static double solveByX (String function, double value) throws NoSuchMethodException, IllegalAccessException, IllegalArgumentException, InvocationTargetException {
HashMap<String, Double> values = new HashMap<>();
values.put("x", value);
return solveComplexFunction(function, function, values);
}
public static double solve (String function, HashMap<String,Double> values) throws NoSuchMethodException, IllegalAccessException, IllegalArgumentException, InvocationTargetException {
return solveComplexFunction(function, function, values);
}
private static double solveComplexFunction (String function, String motherFunction, HashMap<String, Double> values) throws NoSuchMethodException, IllegalAccessException, IllegalArgumentException, InvocationTargetException {
int position = 0;
while(position < function.length()) {
if (alphabetic.contains(""+function.charAt(position))) {
if (position == 0 || !alphabetic.contains(""+function.charAt(position-1))) {
int endIndex = -1;
for (int j = position ; j < function.length()-1 ; j++) {
if (alphabetic.contains(""+function.charAt(j))
&& !alphabetic.contains(""+function.charAt(j+1))) {
endIndex = j;
break;
}
}
if (endIndex == -1 & alphabetic.contains(""+function.charAt(function.length()-1))) {
endIndex = function.length()-1;
}
if (endIndex != -1) {
String alphabeticElement = function.substring(position, endIndex+1);
if (Arrays.asList(usableMathMethods()).contains(alphabeticElement)) {
//Start analyzing a Math function
int closeParenthesisIndex = -1;
int openedParenthesisquantity = 0;
int commaIndex = -1;
for (int j = endIndex+1 ; j < function.length() ; j++) {
if (function.substring(j,j+1).equals("(")) {
openedParenthesisquantity++;
}else if (function.substring(j,j+1).equals(")")) {
openedParenthesisquantity--;
if (openedParenthesisquantity == 0) {
closeParenthesisIndex = j;
break;
}
}else if (function.substring(j,j+1).equals(",") & openedParenthesisquantity == 0) {
if (commaIndex == -1) {
commaIndex = j;
}else{
throw new IllegalArgumentException("The argument of math function (which is "+alphabeticElement+") has too many commas");
}
}
}
if (closeParenthesisIndex == -1) {
throw new IllegalArgumentException("The argument of a Math function (which is "+alphabeticElement+") hasn't got the closing bracket )");
}
String functionArgument = function.substring(endIndex+2,closeParenthesisIndex);
if (commaIndex != -1) {
double firstParameter = solveComplexFunction(functionArgument.substring(0,commaIndex),motherFunction,values);
double secondParameter = solveComplexFunction(functionArgument.substring(commaIndex+1),motherFunction,values);
Method mathMethod = Math.class.getDeclaredMethod(alphabeticElement, new Class<?>[] {double.class, double.class});
mathMethod.setAccessible(true);
String newKey = getNewKey(values);
values.put(newKey, (Double) mathMethod.invoke(null, firstParameter, secondParameter));
function = function.substring(0, position)+newKey
+((closeParenthesisIndex == function.length()-1)?(""):(function.substring(closeParenthesisIndex+1)));
}else {
double firstParameter = solveComplexFunction(functionArgument, motherFunction, values);
Method mathMethod = Math.class.getDeclaredMethod(alphabeticElement, new Class<?>[] {double.class});
mathMethod.setAccessible(true);
String newKey = getNewKey(values);
values.put(newKey, (Double) mathMethod.invoke(null, firstParameter));
function = function.substring(0, position)+newKey
+((closeParenthesisIndex == function.length()-1)?(""):(function.substring(closeParenthesisIndex+1)));
}
}else if (!values.containsKey(alphabeticElement)) {
throw new IllegalArgumentException("Found a group of letters ("+alphabeticElement+") which is neither a variable nor a Math function: ");
}
}
}
}
position++;
}
return solveBracketsFunction(function,motherFunction,values);
}
private static double solveBracketsFunction (String function,String motherFunction,HashMap<String, Double> values) throws IllegalArgumentException{
function = function.replace(" ", "");
String openingBrackets = "([{";
String closingBrackets = ")]}";
int parenthesisIndex = 0;
do {
int position = 0;
int openParenthesisBlockIndex = -1;
String currentOpeningBracket = openingBrackets.charAt(parenthesisIndex)+"";
String currentClosingBracket = closingBrackets.charAt(parenthesisIndex)+"";
if (contOccouranceIn(currentOpeningBracket,function) != contOccouranceIn(currentClosingBracket,function)) {
throw new IllegalArgumentException("Error: brackets are misused in the function "+function);
}
while (position < function.length()) {
if (function.substring(position,position+1).equals(currentOpeningBracket)) {
if (position != 0 && !operators.contains(function.substring(position-1,position))) {
throw new IllegalArgumentException("Error in function: there must be an operator following a "+currentClosingBracket+" breacket");
}
openParenthesisBlockIndex = position;
}else if (function.substring(position,position+1).equals(currentClosingBracket)) {
if (position != function.length()-1 && !operators.contains(function.substring(position+1,position+2))) {
throw new IllegalArgumentException("Error in function: there must be an operator before a "+currentClosingBracket+" breacket");
}
String newKey = getNewKey(values);
values.put(newKey, solveBracketsFunction(function.substring(openParenthesisBlockIndex+1,position),motherFunction, values));
function = function.substring(0,openParenthesisBlockIndex)+newKey
+((position == function.length()-1)?(""):(function.substring(position+1)));
position = -1;
}
position++;
}
parenthesisIndex++;
}while (parenthesisIndex < openingBrackets.length());
return solveBasicFunction(function,motherFunction, values);
}
private static double solveBasicFunction (String function, String motherFunction, HashMap<String, Double> values) throws IllegalArgumentException{
if (!firstContainsOnlySecond(function, alphanumeric+operators)) {
throw new IllegalArgumentException("The function "+function+" is not a basic function");
}
if (function.contains("**") |
function.contains("//") |
function.contains("--") |
function.contains("+*") |
function.contains("+/") |
function.contains("-*") |
function.contains("-/")) {
/*
* ( -+ , +- , *- , *+ , /- , /+ )> Those values are admitted
*/
throw new IllegalArgumentException("Operators are misused in the function");
}
function = function.replace(" ", "");
int position;
int operatorIndex = 0;
String currentOperator;
do {
currentOperator = operators.substring(operatorIndex,operatorIndex+1);
if (currentOperator.equals("*")) {
currentOperator+="/";
operatorIndex++;
}else if (currentOperator.equals("+")) {
currentOperator+="-";
operatorIndex++;
}
operatorIndex++;
position = 0;
while (position < function.length()) {
if ((position == 0 && !(""+function.charAt(position)).equals("-") && !(""+function.charAt(position)).equals("+") && operators.contains(""+function.charAt(position))) ||
(position == function.length()-1 && operators.contains(""+function.charAt(position)))){
throw new IllegalArgumentException("Operators are misused in the function");
}
if (currentOperator.contains(function.substring(position, position+1)) & position != 0) {
int firstTermBeginIndex = position;
while (firstTermBeginIndex > 0) {
if ((alphanumeric.contains(""+function.charAt(firstTermBeginIndex))) & (operators.contains(""+function.charAt(firstTermBeginIndex-1)))){
break;
}
firstTermBeginIndex--;
}
if (firstTermBeginIndex != 0 && (function.charAt(firstTermBeginIndex-1) == '-' | function.charAt(firstTermBeginIndex-1) == '+')) {
if (firstTermBeginIndex == 1) {
firstTermBeginIndex--;
}else if (operators.contains(""+(function.charAt(firstTermBeginIndex-2)))){
firstTermBeginIndex--;
}
}
String firstTerm = function.substring(firstTermBeginIndex,position);
int secondTermLastIndex = position;
while (secondTermLastIndex < function.length()-1) {
if ((alphanumeric.contains(""+function.charAt(secondTermLastIndex))) & (operators.contains(""+function.charAt(secondTermLastIndex+1)))) {
break;
}
secondTermLastIndex++;
}
String secondTerm = function.substring(position+1,secondTermLastIndex+1);
double result;
switch (function.substring(position,position+1)) {
case "*": result = solveSingleValue(firstTerm,values)*solveSingleValue(secondTerm,values); break;
case "/": result = solveSingleValue(firstTerm,values)/solveSingleValue(secondTerm,values); break;
case "+": result = solveSingleValue(firstTerm,values)+solveSingleValue(secondTerm,values); break;
case "-": result = solveSingleValue(firstTerm,values)-solveSingleValue(secondTerm,values); break;
case "^": result = Math.pow(solveSingleValue(firstTerm,values),solveSingleValue(secondTerm,values)); break;
default: throw new IllegalArgumentException("Unknown operator: "+currentOperator);
}
String newAttribute = getNewKey(values);
values.put(newAttribute, result);
function = function.substring(0,firstTermBeginIndex)+newAttribute+function.substring(secondTermLastIndex+1,function.length());
deleteValueIfPossible(firstTerm, values, motherFunction);
deleteValueIfPossible(secondTerm, values, motherFunction);
position = -1;
}
position++;
}
}while (operatorIndex < operators.length());
return solveSingleValue(function, values);
}
private static double solveSingleValue (String singleValue, HashMap<String, Double> values) throws IllegalArgumentException{
if (isDouble(singleValue)) {
return Double.parseDouble(singleValue);
}else if (firstContainsOnlySecond(singleValue, alphabetic)){
return getValueFromVariable(singleValue, values);
}else if (firstContainsOnlySecond(singleValue, alphanumeric+"-+")) {
String[] composition = splitByLettersAndNumbers(singleValue);
if (composition.length != 2) {
throw new IllegalArgumentException("Wrong expression: "+singleValue);
}else {
if (composition[0].equals("-")) {
composition[0] = "-1";
}else if (composition[1].equals("-")) {
composition[1] = "-1";
}else if (composition[0].equals("+")) {
composition[0] = "+1";
}else if (composition[1].equals("+")) {
composition[1] = "+1";
}
if (isDouble(composition[0])) {
return Double.parseDouble(composition[0])*getValueFromVariable(composition[1], values);
}else if (isDouble(composition[1])){
return Double.parseDouble(composition[1])*getValueFromVariable(composition[0], values);
}else {
throw new IllegalArgumentException("Wrong expression: "+singleValue);
}
}
}else {
throw new IllegalArgumentException("Wrong expression: "+singleValue);
}
}
private static double getValueFromVariable (String variable, HashMap<String, Double> values) throws IllegalArgumentException{
Double val = values.get(variable);
if (val == null) {
throw new IllegalArgumentException("Unknown variable: "+variable);
}else {
return val;
}
}
/*
* FunctionSolver help tools:
*
*/
private static final String alphabetic = "abcdefghilmnopqrstuvzwykxy";
private static final String numeric = "0123456789.";
private static final String alphanumeric = alphabetic+numeric;
private static final String operators = "^*/+-"; //--> Operators order in important!
private static boolean firstContainsOnlySecond(String firstString, String secondString) {
for (int j = 0 ; j < firstString.length() ; j++) {
if (!secondString.contains(firstString.substring(j, j+1))) {
return false;
}
}
return true;
}
private static String getNewKey (HashMap<String, Double> hashMap) {
String alpha = "abcdefghilmnopqrstuvzyjkx";
for (int j = 0 ; j < alpha.length() ; j++) {
String k = alpha.substring(j,j+1);
if (!hashMap.containsKey(k) & !Arrays.asList(usableMathMethods()).contains(k)) {
return k;
}
}
for (int j = 0 ; j < alpha.length() ; j++) {
for (int i = 0 ; i < alpha.length() ; i++) {
String k = alpha.substring(j,j+1)+alpha.substring(i,i+1);
if (!hashMap.containsKey(k) & !Arrays.asList(usableMathMethods()).contains(k)) {
return k;
}
}
}
throw new NullPointerException();
}
public static String[] usableMathMethods () {
/*
* Only methods that:
* return a double type
* present one or two parameters (which are double type)
*/
Method[] mathMethods = Math.class.getDeclaredMethods();
ArrayList<String> usableMethodsNames = new ArrayList<>();
for (Method method : mathMethods) {
boolean usable = true;
int argumentsCounter = 0;
Class<?>[] methodParametersTypes = method.getParameterTypes();
for (Class<?> parameter : methodParametersTypes) {
if (!parameter.getSimpleName().equalsIgnoreCase("double")) {
usable = false;
break;
}else {
argumentsCounter++;
}
}
if (!method.getReturnType().getSimpleName().toLowerCase().equals("double")) {
usable = false;
}
if (usable & argumentsCounter<=2) {
usableMethodsNames.add(method.getName());
}
}
return usableMethodsNames.toArray(new String[usableMethodsNames.size()]);
}
private static boolean isDouble (String number) {
try {
Double.parseDouble(number);
return true;
}catch (Exception ex) {
return false;
}
}
private static String[] splitByLettersAndNumbers (String val) {
if (!firstContainsOnlySecond(val, alphanumeric+"+-")) {
throw new IllegalArgumentException("Wrong passed value: <<"+val+">>");
}
ArrayList<String> response = new ArrayList<>();
String searchingFor;
int lastIndex = 0;
if (firstContainsOnlySecond(""+val.charAt(0), numeric+"+-")) {
searchingFor = alphabetic;
}else {
searchingFor = numeric+"+-";
}
for (int j = 0 ; j < val.length() ; j++) {
if (searchingFor.contains(val.charAt(j)+"")) {
response.add(val.substring(lastIndex, j));
lastIndex = j;
if (searchingFor.equals(numeric+"+-")) {
searchingFor = alphabetic;
}else {
searchingFor = numeric+"+-";
}
}
}
response.add(val.substring(lastIndex,val.length()));
return response.toArray(new String[response.size()]);
}
private static void deleteValueIfPossible (String val, HashMap<String, Double> values, String function) {
if (values.get(val) != null & function != null) {
if (!function.contains(val)) {
values.remove(val);
}
}
}
private static int contOccouranceIn (String howManyOfThatString, String inThatString) {
return inThatString.length() - inThatString.replace(howManyOfThatString, "").length();
}
}
Writing your own library is not that hard as u might thing. Here is link for Shunting-yard algorithm with step by step algorithm explenation. Although, you will have to parse the input for tokens first.
There are 2 other questions wich can give you some information too:
Turn a String into a Math Expression?
What's a good library for parsing mathematical expressions in java?
As there are many answers, I'm adding my implementation on top of eval() method with some additional features like support for factorial, evaluating complex expressions etc.
package evaluation;
import java.math.BigInteger;
import java.util.EmptyStackException;
import java.util.Scanner;
import java.util.Stack;
import javax.script.ScriptEngine;
import javax.script.ScriptEngineManager;
import javax.script.ScriptException;
public class EvalPlus {
private static Scanner scanner = new Scanner(System.in);
public static void main(String[] args) {
System.out.println("This Evaluation is based on BODMAS rule\n");
evaluate();
}
private static void evaluate() {
StringBuilder finalStr = new StringBuilder();
System.out.println("Enter an expression to evaluate:");
String expr = scanner.nextLine();
if(isProperExpression(expr)) {
expr = replaceBefore(expr);
char[] temp = expr.toCharArray();
String operators = "(+-*/%)";
for(int i = 0; i < temp.length; i++) {
if((i == 0 && temp[i] != '*') || (i == temp.length-1 && temp[i] != '*' && temp[i] != '!')) {
finalStr.append(temp[i]);
} else if((i > 0 && i < temp.length -1) || (i==temp.length-1 && temp[i] == '!')) {
if(temp[i] == '!') {
StringBuilder str = new StringBuilder();
for(int k = i-1; k >= 0; k--) {
if(Character.isDigit(temp[k])) {
str.insert(0, temp[k] );
} else {
break;
}
}
Long prev = Long.valueOf(str.toString());
BigInteger val = new BigInteger("1");
for(Long j = prev; j > 1; j--) {
val = val.multiply(BigInteger.valueOf(j));
}
finalStr.setLength(finalStr.length() - str.length());
finalStr.append("(" + val + ")");
if(temp.length > i+1) {
char next = temp[i+1];
if(operators.indexOf(next) == -1) {
finalStr.append("*");
}
}
} else {
finalStr.append(temp[i]);
}
}
}
expr = finalStr.toString();
if(expr != null && !expr.isEmpty()) {
ScriptEngineManager mgr = new ScriptEngineManager();
ScriptEngine engine = mgr.getEngineByName("JavaScript");
try {
System.out.println("Result: " + engine.eval(expr));
evaluate();
} catch (ScriptException e) {
System.out.println(e.getMessage());
}
} else {
System.out.println("Please give an expression");
evaluate();
}
} else {
System.out.println("Not a valid expression");
evaluate();
}
}
private static String replaceBefore(String expr) {
expr = expr.replace("(", "*(");
expr = expr.replace("+*", "+").replace("-*", "-").replace("**", "*").replace("/*", "/").replace("%*", "%");
return expr;
}
private static boolean isProperExpression(String expr) {
expr = expr.replaceAll("[^()]", "");
char[] arr = expr.toCharArray();
Stack<Character> stack = new Stack<Character>();
int i =0;
while(i < arr.length) {
try {
if(arr[i] == '(') {
stack.push(arr[i]);
} else {
stack.pop();
}
} catch (EmptyStackException e) {
stack.push(arr[i]);
}
i++;
}
return stack.isEmpty();
}
}
Please find the updated gist anytime here. Also comment if any issues are there. Thanks.
There are some perfectly capable answers here. However for non-trivial script it may be desirable to retain the code in a cache, or for debugging purposes, or even to have dynamically self-updating code.
To that end, sometimes it's simpler or more robust to interact with Java via command line. Create a temporary directory, output your script and any assets, create the jar. Finally import your new code.
It's a bit beyond the scope of normal eval() use in most languages, though you could certainly implement eval by returning the result from some function in your jar.
Still, thought I'd mention this method as it does fully encapsulate everything Java can do without 3rd party tools, in case of desperation. This method allows me to turn HTML templates into objects and save them, avoiding the need to parse a template at runtime.
import java.util.ArrayList;
import java.util.List;
import java.util.ListIterator;
class Calculate {
public static void main(String[] args) {
String strng = "8*-2*3*-1*10/2+6-2";
String[] oparator = {"+","-","*","/"};
List<String> op1 = new ArrayList<>();
String[] x = strng.split("");
int sayac=0;
for (String i : x) {
sayac ++;
for (String c : oparator) {
if (i.equals(c)) {
try {
int j = Integer.parseInt(strng.substring(0, sayac - 1));
op1.add(strng.substring(0, sayac - 1));
op1.add(c);
strng = strng.substring(sayac);
sayac = 0;
}catch (Exception e)
{
continue;
}
}
}
}
op1.add(strng);
ListIterator<String> it = op1.listIterator();
List<List> newlist = new ArrayList<>() ;
while (it.hasNext()) {
List<String> p= new ArrayList<>();
p.add(String.valueOf(it.nextIndex()));
p.add(it.next());
newlist.add(p);
}
int sayac2=0;
String oparatorvalue = "*";
calculate(sayac2,newlist,oparatorvalue);
String oparatorvalue2 = "/";
calculate(sayac2,newlist,oparatorvalue2);
String oparatorvalue3 = "+";
calculate(sayac2,newlist,oparatorvalue3);
String oparatorvalue4 = "-";
calculate(sayac2,newlist,oparatorvalue4);
System.out.println("Result:"+newlist.get(0).get(1));
}
private static void calculate(int sayac2, List<List> newlist, String oparatorvalue) {
while (sayac2<4){
try{
for (List j : newlist) {
if (j.get(1) == oparatorvalue) {
Integer opindex = newlist.indexOf(j);
Object sayi1 = newlist.get(opindex - 1).get(1);
Object sayi2 = newlist.get(opindex + 1).get(1);
int sonuc=0;
if (oparatorvalue.equals("*")){
sonuc = Integer.parseInt(sayi1.toString()) * Integer.parseInt(sayi2.toString());
}
if (oparatorvalue.equals("/")){
sonuc = Integer.parseInt(sayi1.toString()) / Integer.parseInt(sayi2.toString());
}
if (oparatorvalue.equals("+")){
sonuc = Integer.parseInt(sayi1.toString()) + Integer.parseInt(sayi2.toString());
}
if (oparatorvalue.equals("-")){
sonuc = Integer.parseInt(sayi1.toString()) - Integer.parseInt(sayi2.toString());
}
newlist.remove(opindex - 1);
newlist.remove(opindex - 1);
newlist.remove(opindex - 1);
List<String> sonuclist = new ArrayList<>();
sonuclist.add(String.valueOf(opindex - 1));
sonuclist.add(String.valueOf(sonuc));
newlist.add(opindex - 1, sonuclist);
}}}
catch (Exception e){
continue;
}
sayac2++;}
}
}
If you do not want to import heavy scripting library, you can use SimpleExpressionEvaluator directly into your code
Usage:
Expression.eval("1+2").asString(); // returns "3.0"
Expression.eval("1+2").asInt(); // returns 3
Expression.eval("2>3").asString(); // returns "false"
Expression.eval("2>3").asBoolean(); // returns false
Expression.eval("(3>2)||((2<4)&&(2>1))").asString(); // returns "true"
With variables:
HashMap<String, Object> st = new HashMap<String, Object>();
st.put("a",1);
st.put("b",2);
st.put("c",3);
st.put("d",4);
Expression.eval("a+b", st).asInt(); // or simply asString()
Expression.eval("a>b",st).asBoolean(); // or simply asString()
Expression.eval("(c>b)||((b<d)&&(b>a))",st).asBoolean(); // or simply asString()
Expression.eval("(c>2)||((2<d)&&(b>1))",st).asBoolean(); // or simply asString()
Using ExpressionBuilder:
Expression.expressionBuilder().putSymbol("a",2).putSymbol("b",3).build("(b>a)").evaluate()
The following resolved the issue:
ScriptEngineManager mgr = new ScriptEngineManager();
ScriptEngine engine = mgr.getEngineByName("JavaScript");
String str = "4*5";
System.out.println(engine.eval(str));
Beginners question: how do I print a readable version of the parse tree to stdout?
CharStream input = CharStreams.fromFileName("testdata/test.txt");
MyLexer lexer = new MyLexer(input);
CommonTokenStream tokens = new CommonTokenStream(lexer);
MyParser parser = new MyParser(tokens);
parser.setBuildParseTree(true);
RuleContext tree = parser.record();
System.out.println(tree.toStringTree(parser));
this prints the whole tree on a single line delimited by brackets '()'.
(record (husband <4601> (name KOHAI Nikolaus) \n (birth * um.1872 (place Ploschitz)) \n\n) (wife (marriage oo) \n (name SCHLOTTHAUER Maria) \n (birth * um.1877
...
I would like to have something like this
record
husband
<id>
name
<name>
...
wife
Extracted from SnippetsTest as a standalone utility class:
import java.util.List;
import org.antlr.v4.runtime.misc.Utils;
import org.antlr.v4.runtime.tree.Tree;
import org.antlr.v4.runtime.tree.Trees;
public class TreeUtils {
/** Platform dependent end-of-line marker */
public static final String Eol = System.lineSeparator();
/** The literal indent char(s) used for pretty-printing */
public static final String Indents = " ";
private static int level;
private TreeUtils() {}
/**
* Pretty print out a whole tree. {#link #getNodeText} is used on the node payloads to get the text
* for the nodes. (Derived from Trees.toStringTree(....))
*/
public static String toPrettyTree(final Tree t, final List<String> ruleNames) {
level = 0;
return process(t, ruleNames).replaceAll("(?m)^\\s+$", "").replaceAll("\\r?\\n\\r?\\n", Eol);
}
private static String process(final Tree t, final List<String> ruleNames) {
if (t.getChildCount() == 0) return Utils.escapeWhitespace(Trees.getNodeText(t, ruleNames), false);
StringBuilder sb = new StringBuilder();
sb.append(lead(level));
level++;
String s = Utils.escapeWhitespace(Trees.getNodeText(t, ruleNames), false);
sb.append(s + ' ');
for (int i = 0; i < t.getChildCount(); i++) {
sb.append(process(t.getChild(i), ruleNames));
}
level--;
sb.append(lead(level));
return sb.toString();
}
private static String lead(int level) {
StringBuilder sb = new StringBuilder();
if (level > 0) {
sb.append(Eol);
for (int cnt = 0; cnt < level; cnt++) {
sb.append(Indents);
}
}
return sb.toString();
}
}
Call the method as follows:
List<String> ruleNamesList = Arrays.asList(parser.getRuleNames());
String prettyTree = TreeUtils.toPrettyTree(tree, ruleNamesList);
Besides a graphical parse tree my ANTLR4 extension for Visual Studio Code also produces a formatted text parse tree:
If you like to use regex only for what it's really for, you can always print a tree by yourself:
import org.antlr.v4.runtime.Parser;
import org.antlr.v4.runtime.ParserRuleContext;
import org.antlr.v4.runtime.tree.ParseTree;
import org.antlr.v4.runtime.tree.Trees;
public static String printSyntaxTree(Parser parser, ParseTree root) {
StringBuilder buf = new StringBuilder();
recursive(root, buf, 0, Arrays.asList(parser.getRuleNames()));
return buf.toString();
}
private static void recursive(ParseTree aRoot, StringBuilder buf, int offset, List<String> ruleNames) {
for (int i = 0; i < offset; i++) {
buf.append(" ");
}
buf.append(Trees.getNodeText(aRoot, ruleNames)).append("\n");
if (aRoot instanceof ParserRuleContext) {
ParserRuleContext prc = (ParserRuleContext) aRoot;
if (prc.children != null) {
for (ParseTree child : prc.children) {
recursive(child, buf, offset + 1, ruleNames);
}
}
}
}
Usage:
ParseTree root = parser.yourOwnRule();
System.out.println(printSyntaxTree(parser, root));
I wanted to put in my own spin on this, taking advantage of the fact that I already use StringTemplate in my project. This means I don't have to manually deal with levels like the other answers. It also makes the output format easier to customize.
On top of that, the main reason I'm posting this is because I decided to skip printing rules that I'm only 'passing through', i.e. when using chain rules
a : b | something_else ;
b : c | another ;
c : d | yet_more ;
d : rule that matters ;
since they cluttered my output when checking trees from small inputs without adding any usefull information. This is also easy to change, at the //pass-through rules comment location.
I also copied in the definition of Trees.getNodeText and modified it to use a plain array to get rid of the unnecessary wrapping, and even let me customize it if I feel like it.
Finally, I made it take the parser and tree and just straight dump to System.out, since that's the only situation I need it in.
import org.antlr.v4.runtime.Parser;
import org.antlr.v4.runtime.RuleContext;
import org.antlr.v4.runtime.Token;
import org.antlr.v4.runtime.tree.ErrorNode;
import org.antlr.v4.runtime.tree.TerminalNode;
import org.antlr.v4.runtime.tree.Tree;
import org.stringtemplate.v4.ST;
//for pretty-dumping trees in short form
public class TreeUtils {
private static final ST template() {
return new ST("<rule_text>\n\t<child; separator=\"\n\">");
}
private static final ST literal(String text) {
return new ST("<text>").add("text", text);
}
public static void dump(Parser parser, Tree tree) {
System.out.println(process(parser.getRuleNames(),tree).render());
}
private static String getNodeText(Tree t, String[] ruleNames) {
if ( t instanceof RuleContext ) {
int ruleIndex = ((RuleContext)t).getRuleContext().getRuleIndex();
String ruleName = ruleNames[ruleIndex];
return ruleName;
}
else if ( t instanceof ErrorNode) {
return t.toString();
}
else if ( t instanceof TerminalNode) {
Token symbol = ((TerminalNode)t).getSymbol();
if (symbol != null) {
String s = symbol.getText();
return s;
}
}
Object payload = t.getPayload();
if ( payload instanceof Token ) {
return ((Token)payload).getText();
}
return t.getPayload().toString();
}
private static ST process(String[] ruleNames, Tree t) {
if(t.getChildCount()==0) {
return literal(getNodeText(t, ruleNames));
} else if(t.getChildCount()==1) {
//pass-through rules
return process(ruleNames,t.getChild(0));
} else {
ST out=template();
out.add("rule_text", getNodeText(t, ruleNames));
for(int i=0;i<t.getChildCount();i++) {
out.add("child", process(ruleNames,t.getChild(i)));
}
return out;
}
}
}
For Kotlin, you can use this extension function
fun Tree.format(parser: Parser, indent: Int = 0): String = buildString {
val tree = this#format
val prefix = " ".repeat(indent)
append(prefix)
append(Trees.getNodeText(tree, parser))
if (tree.childCount != 0) {
append(" (\n")
for (i in 0 until tree.childCount) {
append(tree.getChild(i).format(parser, indent + 1))
append("\n")
}
append(prefix).append(")")
}
}
I have a string like the following:
String str = "4*5";
Now I have to get the result of 20 by using the string.
I know in some other languages the eval() function will do this.
How can I do this in Java?
You can use the ScriptEngine class and evaluate it as a Javascript string.
ScriptEngineManager manager = new ScriptEngineManager();
ScriptEngine engine = manager.getEngineByName("js");
Object result = engine.eval("4*5");
There may be a better way, but this one works.
There is no standard Java class or method that will do what you want. Your options include:
Select and use some third-party expression evaluation library. For example JEL or any of the half dozen libraries listed here.
Wrap the expression in the Java source code for a class with an eval method, send that to the Java compiler, and then load the resulting compiled class.
Use some scripting language that can be called from Java as an expression evaluator. Possibilities include Javascript1, BeanShell, and so on. A JSR 223 compliant scripting language implementation can be called via the Scripting API.
Write your own expression evaluator from scratch.
The first approach is probably simplest. The second and third approaches are a potential security risk if you get the expression to be evaluated from an untrusted user. (Think code injection.)
1 - Javascript in Java SE is a moving target. From Java 6, a version of Mozilla's Rhino Javascript implementation was bundled with Java SE. The in Java 8, it was superseded by Nashorn. In Java 11, Nashorn was deprecated, and finally dropped from the core codebase. As of 2021, both Rhino and Nashorn are being maintained as separate (non-Oracle) products, and Oracle's GraalVM has its own Javascript implementation.
There are very few real use cases in which being able to evaluate a String as a fragment of Java code is necessary or desirable. That is, asking how to do this is really an XY problem: you actually have a different problem, which can be solved a different way.
First ask yourself, where did this String that you wish to evaluate come from? Did another part of your program generate it, or was it input provided by the user?
Another part of my program generated it: so, you want one part of your program to decide the kind of operation to perform, but not perform the operation, and a second part that performs the chosen operation. Instead of generating and then evaluating a String, use the Strategy, Command or Builder design pattern, as appropriate for your particular case.
It is user input: the user could input anything, including commands that, when executed, could cause your program to misbehave, crash, expose information that should be secret, damage persistent information (such as the content of a database), and other such nastiness. The only way to prevent that would be to parse the String yourself, check it was not malicious, and then evaluate it. But parsing it yourself is much of the work that the requested evalfunction would do, so you have saved yourself nothing. Worse still, checking that arbitrary Java was not malicious is impossible, because checking that is the halting problem.
It is user input, but the syntax and semantics of permitted text to evaluate is greatly restricted: No general purpose facility can easily implement a general purpose parser and evaluator for whatever restricted syntax and semantics you have chosen. What you need to do is implement a parser and evaluator for your chosen syntax and semantics. If the task is simple, you could write a simple recursive-descent or finite-state-machine parser by hand. If the task is difficult, you could use a compiler-compiler (such as ANTLR) to do some of the work for you.
I just want to implement a desktop calculator!: A homework assignment, eh? If you could implement the evaluation of the input expression using a provided eval function, it would not be much of a homework assignment, would it? Your program would be three lines long. Your instructor probably expects you to write the code for a simple arithmetic parser/evaluator. There is well known algorithm, shunting-yard, which you might find useful.
With Java 9, we get access to jshell, so one can write something like this:
import jdk.jshell.JShell;
import java.lang.StringBuilder;
import java.io.BufferedReader;
import java.io.InputStreamReader;
import java.io.IOException;
public class Eval {
public static void main(String[] args) throws IOException {
try(JShell js = JShell.create(); BufferedReader br = new BufferedReader(new InputStreamReader(System.in))) {
js.onSnippetEvent(snip -> {
if (snip.status() == jdk.jshell.Snippet.Status.VALID) {
System.out.println("➜ " + snip.value());
}
});
System.out.print("> ");
for (String line = br.readLine(); line != null; line = br.readLine()) {
js.eval(js.sourceCodeAnalysis().analyzeCompletion(line).source());
System.out.print("> ");
}
}
}
}
Sample run:
> 1 + 2 / 4 * 3
➜ 1
> 32 * 121
➜ 3872
> 4 * 5
➜ 20
> 121 * 51
➜ 6171
>
Slightly op, but that's what Java currently has to offer
I could advise you to use Exp4j. It is easy to understand as you can see from the following example code:
Expression e = new ExpressionBuilder("3 * sin(y) - 2 / (x - 2)")
.variables("x", "y")
.build()
.setVariable("x", 2.3)
.setVariable("y", 3.14);
double result = e.evaluate();
No, you can not have a generic "eval" in Java (or any compiled language). Unless you're willing to write a Java compiler AND a JVM to be executed inside of your Java program.
Yes, you can have some library to evaluate numeric algebraic expressions like the one above - see this thread for discussion.
As previous answers, there is no standard API in Java for this.
You can add groovy jar files to your path and groovy.util.Eval.me("4*5") gets your job done.
A fun way to solve your problem could be coding an eval() function on your own!
I've done it for you!
You can use FunctionSolver library simply by typing FunctionSolver.solveByX(function,value) inside your code. The function attribute is a String which represents the function you want to solve, the value attribute is the value of the independent variable
of your function (which MUST be x).
If you want to solve a function which contains more than one independent variable, you can use FunctionSolver.solve(function,values) where the values attribute is an HashMap(String,Double) which contains all your independent attributes (as Strings) and their respective values (as Doubles).
Another piece of information: I've coded a simple version of FunctionSolver, so its supports only Math methods which return a double value and which accepts one or two double values as fields (just use FunctionSolver.usableMathMethods() if you're curious) (These methods are: bs, sin, cos, tan, atan2, sqrt, log, log10, pow, exp, min, max, copySign, signum, IEEEremainder, acos, asin, atan, cbrt, ceil, cosh, expm1, floor, hypot, log1p, nextAfter, nextDown, nextUp, random, rint, sinh, tanh, toDegrees, toRadians, ulp). Also, that library supports the following operators: * / + - ^ (even if java normally does not support the ^ operator).
One last thing: while creating this library I had to use reflections to call Math methods. I think it's really cool, just have a look at this if you are interested in!
That's all, here it is the code (and the library):
package core;
import java.lang.reflect.InvocationTargetException;
import java.lang.reflect.Method;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.HashMap;
public abstract class FunctionSolver {
public static double solveNumericExpression (String expression) throws NoSuchMethodException, IllegalAccessException, IllegalArgumentException, InvocationTargetException {
return solve(expression, new HashMap<>());
}
public static double solveByX (String function, double value) throws NoSuchMethodException, IllegalAccessException, IllegalArgumentException, InvocationTargetException {
HashMap<String, Double> values = new HashMap<>();
values.put("x", value);
return solveComplexFunction(function, function, values);
}
public static double solve (String function, HashMap<String,Double> values) throws NoSuchMethodException, IllegalAccessException, IllegalArgumentException, InvocationTargetException {
return solveComplexFunction(function, function, values);
}
private static double solveComplexFunction (String function, String motherFunction, HashMap<String, Double> values) throws NoSuchMethodException, IllegalAccessException, IllegalArgumentException, InvocationTargetException {
int position = 0;
while(position < function.length()) {
if (alphabetic.contains(""+function.charAt(position))) {
if (position == 0 || !alphabetic.contains(""+function.charAt(position-1))) {
int endIndex = -1;
for (int j = position ; j < function.length()-1 ; j++) {
if (alphabetic.contains(""+function.charAt(j))
&& !alphabetic.contains(""+function.charAt(j+1))) {
endIndex = j;
break;
}
}
if (endIndex == -1 & alphabetic.contains(""+function.charAt(function.length()-1))) {
endIndex = function.length()-1;
}
if (endIndex != -1) {
String alphabeticElement = function.substring(position, endIndex+1);
if (Arrays.asList(usableMathMethods()).contains(alphabeticElement)) {
//Start analyzing a Math function
int closeParenthesisIndex = -1;
int openedParenthesisquantity = 0;
int commaIndex = -1;
for (int j = endIndex+1 ; j < function.length() ; j++) {
if (function.substring(j,j+1).equals("(")) {
openedParenthesisquantity++;
}else if (function.substring(j,j+1).equals(")")) {
openedParenthesisquantity--;
if (openedParenthesisquantity == 0) {
closeParenthesisIndex = j;
break;
}
}else if (function.substring(j,j+1).equals(",") & openedParenthesisquantity == 0) {
if (commaIndex == -1) {
commaIndex = j;
}else{
throw new IllegalArgumentException("The argument of math function (which is "+alphabeticElement+") has too many commas");
}
}
}
if (closeParenthesisIndex == -1) {
throw new IllegalArgumentException("The argument of a Math function (which is "+alphabeticElement+") hasn't got the closing bracket )");
}
String functionArgument = function.substring(endIndex+2,closeParenthesisIndex);
if (commaIndex != -1) {
double firstParameter = solveComplexFunction(functionArgument.substring(0,commaIndex),motherFunction,values);
double secondParameter = solveComplexFunction(functionArgument.substring(commaIndex+1),motherFunction,values);
Method mathMethod = Math.class.getDeclaredMethod(alphabeticElement, new Class<?>[] {double.class, double.class});
mathMethod.setAccessible(true);
String newKey = getNewKey(values);
values.put(newKey, (Double) mathMethod.invoke(null, firstParameter, secondParameter));
function = function.substring(0, position)+newKey
+((closeParenthesisIndex == function.length()-1)?(""):(function.substring(closeParenthesisIndex+1)));
}else {
double firstParameter = solveComplexFunction(functionArgument, motherFunction, values);
Method mathMethod = Math.class.getDeclaredMethod(alphabeticElement, new Class<?>[] {double.class});
mathMethod.setAccessible(true);
String newKey = getNewKey(values);
values.put(newKey, (Double) mathMethod.invoke(null, firstParameter));
function = function.substring(0, position)+newKey
+((closeParenthesisIndex == function.length()-1)?(""):(function.substring(closeParenthesisIndex+1)));
}
}else if (!values.containsKey(alphabeticElement)) {
throw new IllegalArgumentException("Found a group of letters ("+alphabeticElement+") which is neither a variable nor a Math function: ");
}
}
}
}
position++;
}
return solveBracketsFunction(function,motherFunction,values);
}
private static double solveBracketsFunction (String function,String motherFunction,HashMap<String, Double> values) throws IllegalArgumentException{
function = function.replace(" ", "");
String openingBrackets = "([{";
String closingBrackets = ")]}";
int parenthesisIndex = 0;
do {
int position = 0;
int openParenthesisBlockIndex = -1;
String currentOpeningBracket = openingBrackets.charAt(parenthesisIndex)+"";
String currentClosingBracket = closingBrackets.charAt(parenthesisIndex)+"";
if (contOccouranceIn(currentOpeningBracket,function) != contOccouranceIn(currentClosingBracket,function)) {
throw new IllegalArgumentException("Error: brackets are misused in the function "+function);
}
while (position < function.length()) {
if (function.substring(position,position+1).equals(currentOpeningBracket)) {
if (position != 0 && !operators.contains(function.substring(position-1,position))) {
throw new IllegalArgumentException("Error in function: there must be an operator following a "+currentClosingBracket+" breacket");
}
openParenthesisBlockIndex = position;
}else if (function.substring(position,position+1).equals(currentClosingBracket)) {
if (position != function.length()-1 && !operators.contains(function.substring(position+1,position+2))) {
throw new IllegalArgumentException("Error in function: there must be an operator before a "+currentClosingBracket+" breacket");
}
String newKey = getNewKey(values);
values.put(newKey, solveBracketsFunction(function.substring(openParenthesisBlockIndex+1,position),motherFunction, values));
function = function.substring(0,openParenthesisBlockIndex)+newKey
+((position == function.length()-1)?(""):(function.substring(position+1)));
position = -1;
}
position++;
}
parenthesisIndex++;
}while (parenthesisIndex < openingBrackets.length());
return solveBasicFunction(function,motherFunction, values);
}
private static double solveBasicFunction (String function, String motherFunction, HashMap<String, Double> values) throws IllegalArgumentException{
if (!firstContainsOnlySecond(function, alphanumeric+operators)) {
throw new IllegalArgumentException("The function "+function+" is not a basic function");
}
if (function.contains("**") |
function.contains("//") |
function.contains("--") |
function.contains("+*") |
function.contains("+/") |
function.contains("-*") |
function.contains("-/")) {
/*
* ( -+ , +- , *- , *+ , /- , /+ )> Those values are admitted
*/
throw new IllegalArgumentException("Operators are misused in the function");
}
function = function.replace(" ", "");
int position;
int operatorIndex = 0;
String currentOperator;
do {
currentOperator = operators.substring(operatorIndex,operatorIndex+1);
if (currentOperator.equals("*")) {
currentOperator+="/";
operatorIndex++;
}else if (currentOperator.equals("+")) {
currentOperator+="-";
operatorIndex++;
}
operatorIndex++;
position = 0;
while (position < function.length()) {
if ((position == 0 && !(""+function.charAt(position)).equals("-") && !(""+function.charAt(position)).equals("+") && operators.contains(""+function.charAt(position))) ||
(position == function.length()-1 && operators.contains(""+function.charAt(position)))){
throw new IllegalArgumentException("Operators are misused in the function");
}
if (currentOperator.contains(function.substring(position, position+1)) & position != 0) {
int firstTermBeginIndex = position;
while (firstTermBeginIndex > 0) {
if ((alphanumeric.contains(""+function.charAt(firstTermBeginIndex))) & (operators.contains(""+function.charAt(firstTermBeginIndex-1)))){
break;
}
firstTermBeginIndex--;
}
if (firstTermBeginIndex != 0 && (function.charAt(firstTermBeginIndex-1) == '-' | function.charAt(firstTermBeginIndex-1) == '+')) {
if (firstTermBeginIndex == 1) {
firstTermBeginIndex--;
}else if (operators.contains(""+(function.charAt(firstTermBeginIndex-2)))){
firstTermBeginIndex--;
}
}
String firstTerm = function.substring(firstTermBeginIndex,position);
int secondTermLastIndex = position;
while (secondTermLastIndex < function.length()-1) {
if ((alphanumeric.contains(""+function.charAt(secondTermLastIndex))) & (operators.contains(""+function.charAt(secondTermLastIndex+1)))) {
break;
}
secondTermLastIndex++;
}
String secondTerm = function.substring(position+1,secondTermLastIndex+1);
double result;
switch (function.substring(position,position+1)) {
case "*": result = solveSingleValue(firstTerm,values)*solveSingleValue(secondTerm,values); break;
case "/": result = solveSingleValue(firstTerm,values)/solveSingleValue(secondTerm,values); break;
case "+": result = solveSingleValue(firstTerm,values)+solveSingleValue(secondTerm,values); break;
case "-": result = solveSingleValue(firstTerm,values)-solveSingleValue(secondTerm,values); break;
case "^": result = Math.pow(solveSingleValue(firstTerm,values),solveSingleValue(secondTerm,values)); break;
default: throw new IllegalArgumentException("Unknown operator: "+currentOperator);
}
String newAttribute = getNewKey(values);
values.put(newAttribute, result);
function = function.substring(0,firstTermBeginIndex)+newAttribute+function.substring(secondTermLastIndex+1,function.length());
deleteValueIfPossible(firstTerm, values, motherFunction);
deleteValueIfPossible(secondTerm, values, motherFunction);
position = -1;
}
position++;
}
}while (operatorIndex < operators.length());
return solveSingleValue(function, values);
}
private static double solveSingleValue (String singleValue, HashMap<String, Double> values) throws IllegalArgumentException{
if (isDouble(singleValue)) {
return Double.parseDouble(singleValue);
}else if (firstContainsOnlySecond(singleValue, alphabetic)){
return getValueFromVariable(singleValue, values);
}else if (firstContainsOnlySecond(singleValue, alphanumeric+"-+")) {
String[] composition = splitByLettersAndNumbers(singleValue);
if (composition.length != 2) {
throw new IllegalArgumentException("Wrong expression: "+singleValue);
}else {
if (composition[0].equals("-")) {
composition[0] = "-1";
}else if (composition[1].equals("-")) {
composition[1] = "-1";
}else if (composition[0].equals("+")) {
composition[0] = "+1";
}else if (composition[1].equals("+")) {
composition[1] = "+1";
}
if (isDouble(composition[0])) {
return Double.parseDouble(composition[0])*getValueFromVariable(composition[1], values);
}else if (isDouble(composition[1])){
return Double.parseDouble(composition[1])*getValueFromVariable(composition[0], values);
}else {
throw new IllegalArgumentException("Wrong expression: "+singleValue);
}
}
}else {
throw new IllegalArgumentException("Wrong expression: "+singleValue);
}
}
private static double getValueFromVariable (String variable, HashMap<String, Double> values) throws IllegalArgumentException{
Double val = values.get(variable);
if (val == null) {
throw new IllegalArgumentException("Unknown variable: "+variable);
}else {
return val;
}
}
/*
* FunctionSolver help tools:
*
*/
private static final String alphabetic = "abcdefghilmnopqrstuvzwykxy";
private static final String numeric = "0123456789.";
private static final String alphanumeric = alphabetic+numeric;
private static final String operators = "^*/+-"; //--> Operators order in important!
private static boolean firstContainsOnlySecond(String firstString, String secondString) {
for (int j = 0 ; j < firstString.length() ; j++) {
if (!secondString.contains(firstString.substring(j, j+1))) {
return false;
}
}
return true;
}
private static String getNewKey (HashMap<String, Double> hashMap) {
String alpha = "abcdefghilmnopqrstuvzyjkx";
for (int j = 0 ; j < alpha.length() ; j++) {
String k = alpha.substring(j,j+1);
if (!hashMap.containsKey(k) & !Arrays.asList(usableMathMethods()).contains(k)) {
return k;
}
}
for (int j = 0 ; j < alpha.length() ; j++) {
for (int i = 0 ; i < alpha.length() ; i++) {
String k = alpha.substring(j,j+1)+alpha.substring(i,i+1);
if (!hashMap.containsKey(k) & !Arrays.asList(usableMathMethods()).contains(k)) {
return k;
}
}
}
throw new NullPointerException();
}
public static String[] usableMathMethods () {
/*
* Only methods that:
* return a double type
* present one or two parameters (which are double type)
*/
Method[] mathMethods = Math.class.getDeclaredMethods();
ArrayList<String> usableMethodsNames = new ArrayList<>();
for (Method method : mathMethods) {
boolean usable = true;
int argumentsCounter = 0;
Class<?>[] methodParametersTypes = method.getParameterTypes();
for (Class<?> parameter : methodParametersTypes) {
if (!parameter.getSimpleName().equalsIgnoreCase("double")) {
usable = false;
break;
}else {
argumentsCounter++;
}
}
if (!method.getReturnType().getSimpleName().toLowerCase().equals("double")) {
usable = false;
}
if (usable & argumentsCounter<=2) {
usableMethodsNames.add(method.getName());
}
}
return usableMethodsNames.toArray(new String[usableMethodsNames.size()]);
}
private static boolean isDouble (String number) {
try {
Double.parseDouble(number);
return true;
}catch (Exception ex) {
return false;
}
}
private static String[] splitByLettersAndNumbers (String val) {
if (!firstContainsOnlySecond(val, alphanumeric+"+-")) {
throw new IllegalArgumentException("Wrong passed value: <<"+val+">>");
}
ArrayList<String> response = new ArrayList<>();
String searchingFor;
int lastIndex = 0;
if (firstContainsOnlySecond(""+val.charAt(0), numeric+"+-")) {
searchingFor = alphabetic;
}else {
searchingFor = numeric+"+-";
}
for (int j = 0 ; j < val.length() ; j++) {
if (searchingFor.contains(val.charAt(j)+"")) {
response.add(val.substring(lastIndex, j));
lastIndex = j;
if (searchingFor.equals(numeric+"+-")) {
searchingFor = alphabetic;
}else {
searchingFor = numeric+"+-";
}
}
}
response.add(val.substring(lastIndex,val.length()));
return response.toArray(new String[response.size()]);
}
private static void deleteValueIfPossible (String val, HashMap<String, Double> values, String function) {
if (values.get(val) != null & function != null) {
if (!function.contains(val)) {
values.remove(val);
}
}
}
private static int contOccouranceIn (String howManyOfThatString, String inThatString) {
return inThatString.length() - inThatString.replace(howManyOfThatString, "").length();
}
}
Writing your own library is not that hard as u might thing. Here is link for Shunting-yard algorithm with step by step algorithm explenation. Although, you will have to parse the input for tokens first.
There are 2 other questions wich can give you some information too:
Turn a String into a Math Expression?
What's a good library for parsing mathematical expressions in java?
As there are many answers, I'm adding my implementation on top of eval() method with some additional features like support for factorial, evaluating complex expressions etc.
package evaluation;
import java.math.BigInteger;
import java.util.EmptyStackException;
import java.util.Scanner;
import java.util.Stack;
import javax.script.ScriptEngine;
import javax.script.ScriptEngineManager;
import javax.script.ScriptException;
public class EvalPlus {
private static Scanner scanner = new Scanner(System.in);
public static void main(String[] args) {
System.out.println("This Evaluation is based on BODMAS rule\n");
evaluate();
}
private static void evaluate() {
StringBuilder finalStr = new StringBuilder();
System.out.println("Enter an expression to evaluate:");
String expr = scanner.nextLine();
if(isProperExpression(expr)) {
expr = replaceBefore(expr);
char[] temp = expr.toCharArray();
String operators = "(+-*/%)";
for(int i = 0; i < temp.length; i++) {
if((i == 0 && temp[i] != '*') || (i == temp.length-1 && temp[i] != '*' && temp[i] != '!')) {
finalStr.append(temp[i]);
} else if((i > 0 && i < temp.length -1) || (i==temp.length-1 && temp[i] == '!')) {
if(temp[i] == '!') {
StringBuilder str = new StringBuilder();
for(int k = i-1; k >= 0; k--) {
if(Character.isDigit(temp[k])) {
str.insert(0, temp[k] );
} else {
break;
}
}
Long prev = Long.valueOf(str.toString());
BigInteger val = new BigInteger("1");
for(Long j = prev; j > 1; j--) {
val = val.multiply(BigInteger.valueOf(j));
}
finalStr.setLength(finalStr.length() - str.length());
finalStr.append("(" + val + ")");
if(temp.length > i+1) {
char next = temp[i+1];
if(operators.indexOf(next) == -1) {
finalStr.append("*");
}
}
} else {
finalStr.append(temp[i]);
}
}
}
expr = finalStr.toString();
if(expr != null && !expr.isEmpty()) {
ScriptEngineManager mgr = new ScriptEngineManager();
ScriptEngine engine = mgr.getEngineByName("JavaScript");
try {
System.out.println("Result: " + engine.eval(expr));
evaluate();
} catch (ScriptException e) {
System.out.println(e.getMessage());
}
} else {
System.out.println("Please give an expression");
evaluate();
}
} else {
System.out.println("Not a valid expression");
evaluate();
}
}
private static String replaceBefore(String expr) {
expr = expr.replace("(", "*(");
expr = expr.replace("+*", "+").replace("-*", "-").replace("**", "*").replace("/*", "/").replace("%*", "%");
return expr;
}
private static boolean isProperExpression(String expr) {
expr = expr.replaceAll("[^()]", "");
char[] arr = expr.toCharArray();
Stack<Character> stack = new Stack<Character>();
int i =0;
while(i < arr.length) {
try {
if(arr[i] == '(') {
stack.push(arr[i]);
} else {
stack.pop();
}
} catch (EmptyStackException e) {
stack.push(arr[i]);
}
i++;
}
return stack.isEmpty();
}
}
Please find the updated gist anytime here. Also comment if any issues are there. Thanks.
There are some perfectly capable answers here. However for non-trivial script it may be desirable to retain the code in a cache, or for debugging purposes, or even to have dynamically self-updating code.
To that end, sometimes it's simpler or more robust to interact with Java via command line. Create a temporary directory, output your script and any assets, create the jar. Finally import your new code.
It's a bit beyond the scope of normal eval() use in most languages, though you could certainly implement eval by returning the result from some function in your jar.
Still, thought I'd mention this method as it does fully encapsulate everything Java can do without 3rd party tools, in case of desperation. This method allows me to turn HTML templates into objects and save them, avoiding the need to parse a template at runtime.
import java.util.ArrayList;
import java.util.List;
import java.util.ListIterator;
class Calculate {
public static void main(String[] args) {
String strng = "8*-2*3*-1*10/2+6-2";
String[] oparator = {"+","-","*","/"};
List<String> op1 = new ArrayList<>();
String[] x = strng.split("");
int sayac=0;
for (String i : x) {
sayac ++;
for (String c : oparator) {
if (i.equals(c)) {
try {
int j = Integer.parseInt(strng.substring(0, sayac - 1));
op1.add(strng.substring(0, sayac - 1));
op1.add(c);
strng = strng.substring(sayac);
sayac = 0;
}catch (Exception e)
{
continue;
}
}
}
}
op1.add(strng);
ListIterator<String> it = op1.listIterator();
List<List> newlist = new ArrayList<>() ;
while (it.hasNext()) {
List<String> p= new ArrayList<>();
p.add(String.valueOf(it.nextIndex()));
p.add(it.next());
newlist.add(p);
}
int sayac2=0;
String oparatorvalue = "*";
calculate(sayac2,newlist,oparatorvalue);
String oparatorvalue2 = "/";
calculate(sayac2,newlist,oparatorvalue2);
String oparatorvalue3 = "+";
calculate(sayac2,newlist,oparatorvalue3);
String oparatorvalue4 = "-";
calculate(sayac2,newlist,oparatorvalue4);
System.out.println("Result:"+newlist.get(0).get(1));
}
private static void calculate(int sayac2, List<List> newlist, String oparatorvalue) {
while (sayac2<4){
try{
for (List j : newlist) {
if (j.get(1) == oparatorvalue) {
Integer opindex = newlist.indexOf(j);
Object sayi1 = newlist.get(opindex - 1).get(1);
Object sayi2 = newlist.get(opindex + 1).get(1);
int sonuc=0;
if (oparatorvalue.equals("*")){
sonuc = Integer.parseInt(sayi1.toString()) * Integer.parseInt(sayi2.toString());
}
if (oparatorvalue.equals("/")){
sonuc = Integer.parseInt(sayi1.toString()) / Integer.parseInt(sayi2.toString());
}
if (oparatorvalue.equals("+")){
sonuc = Integer.parseInt(sayi1.toString()) + Integer.parseInt(sayi2.toString());
}
if (oparatorvalue.equals("-")){
sonuc = Integer.parseInt(sayi1.toString()) - Integer.parseInt(sayi2.toString());
}
newlist.remove(opindex - 1);
newlist.remove(opindex - 1);
newlist.remove(opindex - 1);
List<String> sonuclist = new ArrayList<>();
sonuclist.add(String.valueOf(opindex - 1));
sonuclist.add(String.valueOf(sonuc));
newlist.add(opindex - 1, sonuclist);
}}}
catch (Exception e){
continue;
}
sayac2++;}
}
}
If you do not want to import heavy scripting library, you can use SimpleExpressionEvaluator directly into your code
Usage:
Expression.eval("1+2").asString(); // returns "3.0"
Expression.eval("1+2").asInt(); // returns 3
Expression.eval("2>3").asString(); // returns "false"
Expression.eval("2>3").asBoolean(); // returns false
Expression.eval("(3>2)||((2<4)&&(2>1))").asString(); // returns "true"
With variables:
HashMap<String, Object> st = new HashMap<String, Object>();
st.put("a",1);
st.put("b",2);
st.put("c",3);
st.put("d",4);
Expression.eval("a+b", st).asInt(); // or simply asString()
Expression.eval("a>b",st).asBoolean(); // or simply asString()
Expression.eval("(c>b)||((b<d)&&(b>a))",st).asBoolean(); // or simply asString()
Expression.eval("(c>2)||((2<d)&&(b>1))",st).asBoolean(); // or simply asString()
Using ExpressionBuilder:
Expression.expressionBuilder().putSymbol("a",2).putSymbol("b",3).build("(b>a)").evaluate()
The following resolved the issue:
ScriptEngineManager mgr = new ScriptEngineManager();
ScriptEngine engine = mgr.getEngineByName("JavaScript");
String str = "4*5";
System.out.println(engine.eval(str));
How can I get a class reference/TypeElement of a specific identifier at compile time in Java?
Say I have the following source file, and I want to get a reference to the Pixel class so I can get a list of its member fields.
package com.foo.bar;
class Test {
class Pixel {
int x,y,r,g,b;
}
Pixel saturate(Pixel p, int value) {...}
}
The Pixel class definition could be nested inside the Test class, or included from a different package where the source is not available.
I am using the javax.tools API to compile the source files, and I define visitor methods so I can view the arguments to each function. The arguments of a function can be iterated using VariableTree var : node.getParameters(), but the type information from var.getType() only triggers visitIdentifier for class names. This identifier is only the simple name Pixel, not the fully-qualified com.foo.bar.Pixel.
I need a way to reverse this identifier into either Pixel.class or into the TypeElement for the definition of the Pixel class, or into the fully-qualified com.foo.bar.Pixel string so I can then use a ClassLoader on it.
A crude way would be to record all class definitions and then try to do compile-time type lookup, but this wouldn't work for externally-defined classes.
As far as I remember var.getType().toString() returns you the fully qualified class name. Unfortunately I cannot check it right now, but try it yourself.
Yes, I know, it is a very bad style to use toString() for something except logging but it seems they have not given us other choice.
I ended up creating my own class lookup tool. For those that are interested, I'll include it here.
Call this with the path name of every source file to be included in the search:
public void populateClassDefinitions(String path) {
Iterable<? extends JavaFileObject> files = fileManager.getJavaFileObjects(path);
CompilationTask task =
compiler.getTask(null, fileManager, diagnosticsCollector, null, null, files);
final JavacTask javacTask = (JavacTask) task;
parseResult = null;
try {
parseResult = javacTask.parse();
} catch (IOException e) {
e.printStackTrace();
return;
}
for (CompilationUnitTree tree : parseResult) {
tree.accept(new TreeScanner<Void, Void>() {
#Override
public Void visitCompilationUnit(CompilationUnitTree node, Void p) {
currentPackage = "";
ExpressionTree packageName = node.getPackageName();
if (packageName != null) {
String packageNameString = String.valueOf(packageName);
if (packageNameString.length() > 0) {
currentPackage = packageNameString;
}
}
TreeScanner<Void, String> visitor = new TreeScanner<Void, String>() {
#Override
public Void visitClass(ClassTree node, String packagePrefix) {
if (classDefinitions.get(currentPackage) == null) {
classDefinitions.put(currentPackage, new HashMap<String, ClassTree>());
}
classDefinitions.get(currentPackage).put(packagePrefix + node.getSimpleName(), node);
return super.visitClass(node, packagePrefix + node.getSimpleName() + ".");
}
};
for (Tree decls : node.getTypeDecls()) {
decls.accept(visitor, "");
}
return super.visitCompilationUnit(node, p);
}
}, null);
}
}
Call this to search for classes.
/**
* Lookup the definition of a class.
*
* Lookup order: 1. Search in the current file: within the current class scope upwards to the
* root. 2. Search laterally across files with the same package value for implicitly included
* classes. 3. Check all import statements.
*
* #param pack
* Current package ex "edu.illinois.crhc"
* #param scope
* Current scope ex "Test.InnerClass"
* #param identifier
* The partial class name to search for
* #return ClassTree the definition of this class if found
*/
ClassLookup lookupClass(CompilationUnitTree packTree, String scope, String identifier) {
dumpClassTable();
String pack = packTree.getPackageName().toString();
System.out.println("Looking for class " + pack + " - " + scope + " - " + identifier);
// Search nested scope and within same package
HashMap<String, ClassTree> packClasses = classDefinitions.get(pack);
if (packClasses != null) {
String[] scopeWalk = scope.split("\\.");
for (int i = scopeWalk.length; i >= 0; i--) {
StringBuilder scopeTest = new StringBuilder();
for (int j = 0; j < i; j++) {
scopeTest.append(scopeWalk[j] + ".");
}
scopeTest.append(identifier);
System.out.println("Testing scope " + pack + " - " + scopeTest.toString());
if (packClasses.containsKey(scopeTest.toString())) {
return new ClassLookup(packClasses.get(scopeTest.toString()), pack.replace(".", "/")
+ "/" + scopeTest.toString().replace(".", "$"));
}
}
}
/*
* Check if fully-qualified identifier (foo.bar.Widget) is used. This needs to search all
* combinations of package and class nesting.
*/
StringBuilder packTest = new StringBuilder();
String[] qualifiedName = identifier.split("\\.");
for (int i = 0; i < qualifiedName.length - 1; i++) {
packTest.append(qualifiedName[i]);
if (i != qualifiedName.length - 2) {
packTest.append(".");
}
}
String clazz = qualifiedName[qualifiedName.length - 1];
System.out.println("Testing absolute identifier: " + packTest.toString() + " " + clazz);
if (classDefinitions.containsKey(packTest.toString())) {
HashMap<String, ClassTree> foundPack = classDefinitions.get(packTest.toString());
if (foundPack.containsKey(clazz)) {
return new ClassLookup(foundPack.get(clazz), packTest.toString().replace(".", "/") + "/"
+ clazz.replace(".", "$"));
}
}
/*
* Search import statements. Last identifier segment must be class name. Search all of the
* packages for the identifier by splitting off the class name. a.b.c.Tree Tree.Branch
* Tree.Branch.Leaf
*/
for (ImportTree imp : currentPackTree.getImports()) {
pack = imp.getQualifiedIdentifier().toString();
System.out.println(pack);
String[] importName = pack.split("\\.");
// Split off class name.
// TODO: (edge case) no package
StringBuilder importTest = new StringBuilder();
for (int i = 0; i < importName.length - 1; i++) {
importTest.append(importName[i]);
if (i != importName.length - 2) {
importTest.append(".");
}
}
// See if the last import segment is * or matches the first segment of the identifier.
System.out.println("Testing globally " + importTest.toString() + " - " + identifier);
if (classDefinitions.containsKey(importTest.toString())) {
HashMap<String, ClassTree> foundPack = classDefinitions.get(importTest.toString());
String[] identifierParts = identifier.split(".");
String importClass = importName[importName.length-1];
if (importClass.equals("*") || identifierParts[0].equals(importClass)) {
if (foundPack.containsKey(identifier)) {
return new ClassLookup(foundPack.get(identifier), importTest.toString().replace(".", "/")
+ "/" + identifier.replace(".", "$"));
}
}
}
}
return null;
}
I'm searching for a way to get a list of method stubs of all classes within a jar file.
I'm not sure where to start... May I use Reflection or Javassist or some other tools of which I've not heard yet!?
At least it may be possible to unpack the jar, decompile the class files and scan with a line parser for methods, but I think that is the most dirtiest way ;-)
Any ideas?
Kind Regards
Building upon aioobe's answer, you can also use ASM's tree API (as opposed to its visitor API) to parse the contents of the class files contained within your JAR file. As well, you can read the files contained within the JAR file using the JarFile class. Here is an example of how this could be done:
The printMethodStubs method accepts a JarFile and proceeds to print out descriptions of all methods contained within all class files.
public void printMethodStubs(JarFile jarFile) throws Exception {
Enumeration<JarEntry> entries = jarFile.entries();
while (entries.hasMoreElements()) {
JarEntry entry = entries.nextElement();
String entryName = entry.getName();
if (entryName.endsWith(".class")) {
ClassNode classNode = new ClassNode();
InputStream classFileInputStream = jarFile.getInputStream(entry);
try {
ClassReader classReader = new ClassReader(classFileInputStream);
classReader.accept(classNode, 0);
} finally {
classFileInputStream.close();
}
System.out.println(describeClass(classNode));
}
}
}
The describeClass method accepts a ClassNode object and proceeds to describe it and its associated methods:
public String describeClass(ClassNode classNode) {
StringBuilder classDescription = new StringBuilder();
Type classType = Type.getObjectType(classNode.name);
// The class signature (e.g. - "public class Foo")
if ((classNode.access & Opcodes.ACC_PUBLIC) != 0) {
classDescription.append("public ");
}
if ((classNode.access & Opcodes.ACC_PRIVATE) != 0) {
classDescription.append("private ");
}
if ((classNode.access & Opcodes.ACC_PROTECTED) != 0) {
classDescription.append("protected ");
}
if ((classNode.access & Opcodes.ACC_ABSTRACT) != 0) {
classDescription.append("abstract ");
}
if ((classNode.access & Opcodes.ACC_INTERFACE) != 0) {
classDescription.append("interface ");
} else {
classDescription.append("class ");
}
classDescription.append(classType.getClassName()).append("\n");
classDescription.append("{\n");
// The method signatures (e.g. - "public static void main(String[]) throws Exception")
#SuppressWarnings("unchecked")
List<MethodNode> methodNodes = classNode.methods;
for (MethodNode methodNode : methodNodes) {
String methodDescription = describeMethod(methodNode);
classDescription.append("\t").append(methodDescription).append("\n");
}
classDescription.append("}\n");
return classDescription.toString();
}
The describeMethod method accepts a MethodNode and returns a String describing the method's signature:
public String describeMethod(MethodNode methodNode) {
StringBuilder methodDescription = new StringBuilder();
Type returnType = Type.getReturnType(methodNode.desc);
Type[] argumentTypes = Type.getArgumentTypes(methodNode.desc);
#SuppressWarnings("unchecked")
List<String> thrownInternalClassNames = methodNode.exceptions;
if ((methodNode.access & Opcodes.ACC_PUBLIC) != 0) {
methodDescription.append("public ");
}
if ((methodNode.access & Opcodes.ACC_PRIVATE) != 0) {
methodDescription.append("private ");
}
if ((methodNode.access & Opcodes.ACC_PROTECTED) != 0) {
methodDescription.append("protected ");
}
if ((methodNode.access & Opcodes.ACC_STATIC) != 0) {
methodDescription.append("static ");
}
if ((methodNode.access & Opcodes.ACC_ABSTRACT) != 0) {
methodDescription.append("abstract ");
}
if ((methodNode.access & Opcodes.ACC_SYNCHRONIZED) != 0) {
methodDescription.append("synchronized ");
}
methodDescription.append(returnType.getClassName());
methodDescription.append(" ");
methodDescription.append(methodNode.name);
methodDescription.append("(");
for (int i = 0; i < argumentTypes.length; i++) {
Type argumentType = argumentTypes[i];
if (i > 0) {
methodDescription.append(", ");
}
methodDescription.append(argumentType.getClassName());
}
methodDescription.append(")");
if (!thrownInternalClassNames.isEmpty()) {
methodDescription.append(" throws ");
int i = 0;
for (String thrownInternalClassName : thrownInternalClassNames) {
if (i > 0) {
methodDescription.append(", ");
}
methodDescription.append(Type.getObjectType(thrownInternalClassName).getClassName());
i++;
}
}
return methodDescription.toString();
}
The best way I can think of is to use the ASM-bytecode framework. Then at least you wouldn't have to go through some decompilation-output with a line-parser. In fact, getting the method-stubs should be like a 20-line implementation of one of their Visitor-interfaces.
I've used it myself for bytecode rewriting and it's fairly simple and straight forward (especially if you're just reading the class-files).
http://asm.ow2.org/