Are there any examples for a recursive function that calls an other function which calls the first one too ?

Example :

function1()
{    
    //do something 
    f2();
    //do something
}

function2()
{
    //do something 
    f1();
    //do something
}
  • 4
    You just provided one :) unless you meant real life example? – Anthony Forloney Apr 27 '10 at 20:54
  • i mean a real world one :) – Hannoun Yassir Apr 27 '10 at 20:56
  • The general term is “mutual recursion”, and yeah, there are many, many cases where the calls made by a function would be likely to cause a nested call into that function. – bobince Apr 27 '10 at 21:23
up vote 22 down vote accepted

Mutual recursion is common in code that parses mathematical expressions (and other grammars). A recursive descent parser based on the grammar below will naturally contain mutual recursion: expression-terms-term-factor-primary-expression.

expression
    + terms
    - terms
    terms

terms
    term + terms
    term - terms

term
    factor
    factor * term
    factor / term

factor
    primary
    primary ^ factor

primary
    ( expression )
    number
    name
    name ( expression )
  • 1
    +1, I was thinking about this, too. In fact, using mutual tail recursion to implement automata is just a special case of a tail recursive descent parser, which in turn is a variant of a recursive descent parser. – Jörg W Mittag Apr 28 '10 at 22:39

The proper term for this is Mutual Recursion.

http://en.wikipedia.org/wiki/Mutual_recursion

There's an example on that page, I'll reproduce here in Java:

boolean even( int number )
{    
    if( number == 0 )
        return true;
    else
        return odd(abs(number)-1)
}

boolean odd( int number )
{
    if( number == 0 )
        return false;
    else
        return even(abs(number)-1);
}

Where abs( n ) means return the absolute value of a number.

Clearly this is not efficient, just to demonstrate a point.

An example might be the minmax algorithm commonly used in game programs such as chess. Starting at the top of the game tree, the goal is to find the maximum value of all the nodes at the level below, whose values are defined as the minimum of the values of the nodes below that, whose values are defines as the maximum of the values below that, whose values ...

  • Good use case.. – Geoff Apr 27 '10 at 21:48

It's a bit contrived and not very efficient, but you could do this with a function to calculate Fibbonacci numbers as in:


fib2(n) { return fib(n-2); }

fib1(n) { return fib(n-1); }

fib(n)
{
  if (n>1)
    return fib1(n) + fib2(n);
  else
    return 1;
}

In this case its efficiency can be dramatically enhanced if the language supports memoization

  • Mutual Recursion is not the same as Double Recursion, the question describes Mutual Recursion. Any mutually recursive set of functions can be unrolled into a single recursive function simply by inlining the code. – Geoff Apr 27 '10 at 21:30
  • You've fixed it now, my comment looks out of place! – Geoff Apr 27 '10 at 21:49
  • @Geoff: No problem... I got a little carried away and started writing stuff without thinking. – andand Apr 27 '10 at 23:39

In a language with proper tail calls, Mutual Tail Recursion is a very natural way of implementing automata.

I can think of two common sources of mutual recursion.

Functions dealing with mutually recursive types

Consider an Abstract Syntax Tree (AST) that keeps position information in every node. The type might look like this:

type Expr =
  | Int of int
  | Var of string
  | Add of ExprAux * ExprAux
and ExprAux = Expr of int * Expr

The easiest way to write functions that manipulate values of these types is to write mutually recursive functions. For example, a function to find the set of free variables:

let rec freeVariables = function
  | Int n -> Set.empty
  | Var x -> Set.singleton x
  | Add(f, g) -> Set.union (freeVariablesAux f) (freeVariablesAux g)
and freeVariablesAux (Expr(loc, e)) =
  freeVariables e

State machines

Consider a state machine that is either on, off or paused with instructions to start, stop, pause and resume (F# code):

type Instruction = Start | Stop | Pause | Resume

The state machine might be written as mutually recursive functions with one function for each state:

type State = State of (Instruction -> State)

let rec isOff = function
  | Start -> State isOn
  | _ -> State isOff
and isOn = function
  | Stop -> State isOff
  | Pause -> State isPaused
  | _ -> State isOn
and isPaused = function
  | Stop -> State isOff
  | Resume -> State isOn
  | _ -> State isPaused

Here is my coded solution. For a calculator app that performs *,/,- operations using mutual recursion. It also checks for brackets (()) to decide the order of precedence.

Flow:: expression -> term -> factor -> expression 

    Calculator.h
    #ifndef CALCULATOR_H_
    #define CALCULATOR_H_

    #include <string>
    using namespace std;

    /****** A Calculator Class holding expression, term, factor ********/
    class Calculator
    {
    public:
        /**Default Constructor*/
        Calculator();

        /** Parameterized Constructor common for all exception
         * @aparam e exception value
         * */
        Calculator(char e);

        /**
         * Function to start computation
         * @param input - input expression*/
        void start(string input);

        /**
         * Evaluates Term*
         * @param input string for term*/
        double term(string& input);

         /* Evaluates factor*
         * @param input string for factor*/
        double factor(string& input);

         /* Evaluates Expression*
          * @param input string for expression*/
        double expression(string& input);


         /* Evaluates number*
          * @param input string for number*/
        string number(string n);

        /**
         * Prints calculates value of the expression
         * */
        void print();

        /**
         * Converts char to double
         * @param c input char
         * */
        double charTONum(const char* c);

        /**
         * Get error
         */
        char get_value() const;
        /** Reset all values*/
        void reset();
    private:
        int lock;//set lock to check extra parenthesis
        double result;// result
        char error_msg;// error message
    };

    /**Error for unexpected string operation*/
    class Unexpected_error:public Calculator
    {
    public:
        Unexpected_error(char e):Calculator(e){};
    };

    /**Error for missing parenthesis*/
    class Missing_parenthesis:public Calculator
    {
    public:
        Missing_parenthesis(char e):Calculator(e){};
    };

    /**Error if divide by zeros*/
    class DivideByZero:public Calculator{
    public:
        DivideByZero():Calculator(){};
    };
    #endif
    ===============================================================================

    Calculator.cpp

    //============================================================================
    // Name        : Calculator.cpp
    // Author      : Anurag
    // Version     :
    // Copyright   : Your copyright notice
    // Description : Calculator using mutual recursion in C++, Ansi-style
    //============================================================================

    #include "Calculator.h"
    #include <iostream>
    #include <string>
    #include <math.h>
    #include <exception>
    using namespace std;


    Calculator::Calculator():lock(0),result(0),error_msg(' '){

    }

    Calculator::Calculator(char e):result(0), error_msg(e) {

    }

    char Calculator::get_value() const {
        return this->error_msg;
    }

    void Calculator::start(string input) {
        try{
        result = expression(input);
        print();
        }catch (Unexpected_error e) {
            cout<<result<<endl;
            cout<<"***** Unexpected "<<e.get_value()<<endl;
        }catch (Missing_parenthesis e) {
            cout<<"***** Missing "<<e.get_value()<<endl;
        }catch (DivideByZero e) {
            cout<<"***** Division By Zero" << endl;
        }
    }

    double Calculator::expression(string& input) {
        double expression=0;
        if(input.size()==0)
            return 0;
        expression = term(input);
        if(input[0] == ' ')
            input = input.substr(1);
        if(input[0] == '+') {
            input = input.substr(1);
            expression += term(input);
        }
        else if(input[0] == '-') {
            input = input.substr(1);
            expression -= term(input);
        }
        if(input[0] == '%'){
            result = expression;
            throw Unexpected_error(input[0]);
        }
        if(input[0]==')' && lock<=0 )
            throw Missing_parenthesis(')');
        return expression;
    }

    double Calculator::term(string& input) {
        if(input.size()==0)
            return 1;
        double term=1;
        term = factor(input);
        if(input[0] == ' ')
            input = input.substr(1);
        if(input[0] == '*') {
            input = input.substr(1);
            term = term * factor(input);
        }
        else if(input[0] == '/') {
            input = input.substr(1);
            double den = factor(input);
            if(den==0) {
                throw DivideByZero();
            }
            term = term / den;
        }
        return term;
    }

    double Calculator::factor(string& input) {
        double factor=0;
        if(input[0] == ' ') {
            input = input.substr(1);
        }
        if(input[0] == '(') {
            lock++;
            input = input.substr(1);
            factor = expression(input);
            if(input[0]==')') {
                lock--;
                input = input.substr(1);
                return factor;
            }else{
                throw Missing_parenthesis(')');
            }
        }
        else if (input[0]>='0' && input[0]<='9'){
            string nums = input.substr(0,1) + number(input.substr(1));
            input = input.substr(nums.size());
            return stod(nums);
        }
        else {
            result = factor;
            throw Unexpected_error(input[0]);
        }
        return factor;
    }

    string Calculator::number(string input) {
        if(input.substr(0,2)=="E+" || input.substr(0,2)=="E-" || input.substr(0,2)=="e-" || input.substr(0,2)=="e-")
            return input.substr(0,2) + number(input.substr(2));
        else if((input[0]>='0' && input[0]<='9') || (input[0]=='.'))
            return input.substr(0,1) + number(input.substr(1));
        else
            return "";
    }

    void Calculator::print() {
        cout << result << endl;
    }

    void Calculator::reset(){
        this->lock=0;
        this->result=0;
    }
    int main() {

        Calculator* cal = new Calculator;
        string input;
        cout<<"Expression? ";
        getline(cin,input);
        while(input!="."){
            cal->start(input.substr(0,input.size()-2));
            cout<<"Expression? ";
            cal->reset();
            getline(cin,input);
        }
        cout << "Done!" << endl;
        return 0;
    }
    ==============================================================
    Sample input-> Expression? (42+8)*10 =
    Output-> 500

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