Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I found a piece of code that I was writing for interview prep few months ago.

According to the comment I had, it was trying to solve this problem:

Given some dollar value in cents (e.g. 200 = 2 dollars, 1000 = 10 dollars), find all the combinations of coins that make up the dollar value. There are only penny, nickel, dime, and quarter. (quarter = 25 cents, dime = 10 cents, nickel = 5 cents, penny = 1 cent)

For example, if 100 was given, the answer should be...
4 quarter(s) 0 dime(s) 0 nickel(s) 0 pennies
3 quarter(s) 1 dime(s) 0 nickel(s) 15 pennies
etc.

This can be solved in both iterative and recursive ways, I believe. My recursive solution is quite buggy, and I was wondering how other people would solve this problem. The difficult part of this problem was making it as efficient as possible.

UPDATE
Making this thread into a community wiki, because apparently, we have gathered many different implementations :)

share|improve this question
18  
I'm not an USA citizen, so... can you say to use what is a quarter, a dime, a nickel and a penny? –  akappa Jul 9 '09 at 23:27
5  
@akappa: penny = 1 cent; nickel = 5 cents; dime = 10 cents; quarter = 25 cents :) –  codingbear Jul 9 '09 at 23:29
2  
Can we turn this into a code golf please? This would be VERY insteresting :) –  John T Jul 9 '09 at 23:34
1  
@blee code golf refers to solving a problem in the least amount of characters possible, with the programming language of your choice. Here are some that have been done on this website: stackoverflow.com/search?q=code+golf –  John T Jul 9 '09 at 23:53
1  
code-golf => stackoverflow.com/questions/tagged/code-golf –  Brad Gilbert Jul 10 '09 at 15:37

20 Answers 20

I looked into this once a long time ago, and you can read my little write-up on it. Here’s the Mathematica source.

By using generating functions, you can get a closed-form constant-time solution to the problem. Graham, Knuth, and Patashnik’s Concrete Mathematics is the book for this, and contains a fairly extensive discussion of the problem. Essentially you define a polynomial where the *n*th coefficient is the number of ways of making change for n dollars.

Pages 4-5 of the writeup show how you can use Mathematica (or any other convenient computer algebra system) to compute the answer for 10^10^6 dollars in a couple seconds in three lines of code.

(And this was long enough ago that that’s a couple of seconds on a 75Mhz Pentium...)

share|improve this answer
    
+1: Wonderful answer :) –  akappa Jul 10 '09 at 13:39
8  
Good answer, but minor quibbles: note that (1) This gives the number of ways, while for some reason the question asks for the actual set of all ways. Of course, there can be no way of finding the set in polynomial time, since the output itself has superpolynomially many entries (2) It is debatable whether a generating function is a "closed form" (see Herbert Wilf's wonderful book Generatingfunctionology: math.upenn.edu/~wilf/DownldGF.html) and if you mean an expression like (1+√5)^n, it takes Ω(log n) time to compute, not constant time. –  ShreevatsaR Jul 10 '09 at 18:33
    
Gentle introduction to dynamic programming. Also, I encourage anyone with a sequence problem to read generatingfunctionology. –  Colonel Panic Nov 11 '12 at 18:17
    
Thanks so much Andrew ... this explanation helped me out so much ...Posting the scala function below .. should some one need it –  jayaram S Mar 29 '13 at 2:48

I would favor a recursive solution. You have some list of denominations, if the smallest one can evenly divide any remaining currency amount, this should work fine.

Basically, you move from largest to smallest denominations.
Recursively,

  1. You have a current total to fill, and a largest denomination (with more than 1 left). If there is only 1 denomination left, there is only one way to fill the total. You can use 0 to k copies of your current denomination such that k * cur denomination <= total.
  2. For 0 to k, call the function with the modified total and new largest denomination.
  3. Add up the results from 0 to k. That's how many ways you can fill your total from the current denomination on down. Return this number.

Here's my python version of your stated problem, for 200 cents. I get 1463 ways. This version prints all the combinations and the final count total.

#!/usr/bin/python

# find the number of ways to reach a total with the given number of combinations

cents = 200
denominations = [25, 10, 5, 1]
names = {25: "quarter(s)", 10: "dime(s)", 5 : "nickel(s)", 1 : "pennies"}

def count_combs(left, i, comb, add):
    if add: comb.append(add)
    if left == 0 or (i+1) == len(denominations):
        if (i+1) == len(denominations) and left > 0:
            comb.append( (left, denominations[i]) )
            i += 1
        while i < len(denominations):
            comb.append( (0, denominations[i]) )
            i += 1
        print " ".join("%d %s" % (n,names[c]) for (n,c) in comb)
        return 1
    cur = denominations[i]
    return sum(count_combs(left-x*cur, i+1, comb[:], (x,cur)) for x in range(0, int(left/cur)+1))

print count_combs(cents, 0, [], None)
share|improve this answer
    
Haven't ran it, but by going through your logic, it makes sense :) –  codingbear Jul 9 '09 at 23:48
    
You can replace the last two lines of the function with "return sum(count_combs(...) for ...)" - that way the list doesn't get materialized at all. :) –  Nick Johnson Jul 10 '09 at 9:24
    
Thanks for the tip. I'm always interested in ways to tighten up code. –  leif Jul 10 '09 at 13:33

Scala function :

def countChange(money: Int, coins: List[Int]): Int = {

def loop(money: Int, lcoins: List[Int], count: Int): Int = {
  // if there are no more coins or if we run out of money ... return 0 
  if ( lcoins.isEmpty || money < 0) 0
  else{
    if (money == 0 ) count + 1   
/* if the recursive subtraction leads to 0 money left - a prefect division hence return count +1 */
    else
/* keep iterating ... sum over money and the rest of the coins and money - the first item and the full set of coins left*/
      loop(money, lcoins.tail,count) + loop(money - lcoins.head,lcoins, count)
  }
}

val x = loop(money, coins, 0)
Console println x
x
}
share|improve this answer
    
Thanks! This is a great start. But, I think this fails when "money" starts out being 0 :) . –  aqn May 11 at 21:33

Clean scala function:

def countChange(money: Int, coins: List[Int]): Int =
  if (money == 0) 1
  else if (coins.isEmpty || money < 0) 0
  else countChange(money - coins.head, coins) + countChange(money, coins.tail)
share|improve this answer

Here's some absolutely straightforward C++ code to solve the problem which did ask for all the combinations to be shown.

#include <stdio.h>
#include <stdlib.h>

int main(int argc, char *argv[])
{
    if (argc != 2)
    {
    	printf("usage: change amount-in-cents\n");
    	return 1;
    }

    int total = atoi(argv[1]);

    printf("quarter\tdime\tnickle\tpenny\tto make %d\n", total);

    int combos = 0;

    for (int q = 0; q <= total / 25; q++)
    {
    	int total_less_q = total - q * 25;
    	for (int d = 0; d <= total_less_q / 10; d++)
    	{
    		int total_less_q_d = total_less_q - d * 10;
    		for (int n = 0; n <= total_less_q_d / 5; n++)
    		{
    			int p = total_less_q_d - n * 5;
    			printf("%d\t%d\t%d\t%d\n", q, d, n, p);
    			combos++;
    		}
    	}
    }

    printf("%d combinations\n", combos);

    return 0;
}

But I'm quite intrigued about the sub problem of just calculating the number of combinations. I suspect there's a closed-form equation for it.

share|improve this answer
5  
Surely this is C, not C++. –  nikhil Jul 9 '12 at 19:29
1  
@George Phillips can u explain? –  Trying Mar 24 '13 at 17:47
    
I think it's pretty straightforward. Basically, the idea is to iterate all quarters (using 0,1,2 .. max), and then iterate through all dimes based on the quarters used, etc.. –  Peter Lee Jul 29 '13 at 2:56
1  
The downside for this solution is: if there are 50-cent, 100-cent, 500-cent coins, then we have to use 6-level loops... –  Peter Lee Jul 29 '13 at 2:57

Let C(i,J) the set of combinations of making i cents using the values in the set J.

You can define C as that:

alt text

(first(J) takes in a deterministic way an element of a set)

It turns out a pretty recursive function... and reasonably efficient if you use memoization ;)

share|improve this answer
    
Yeah, this ("dynamic programming", in a sense) is going to be the optimal solution. –  ShreevatsaR Jul 9 '09 at 23:38
    
What does first() do? Sorry, I'm trying to recall my math/logic notations.... –  codingbear Jul 9 '09 at 23:51
    
you're right: take J as a list and not as a set: then first(J) brings to you the first element and J \ first(J) gives to you the rest of the list. –  akappa Jul 9 '09 at 23:52

The sub problem is a typical Dynamic Programming problem.

/* Q: Given some dollar value in cents (e.g. 200 = 2 dollars, 1000 = 10 dollars),
      find the number of combinations of coins that make up the dollar value.
      There are only penny, nickel, dime, and quarter.
      (quarter = 25 cents, dime = 10 cents, nickel = 5 cents, penny = 1 cent) */
/* A:
Reference: http://andrew.neitsch.ca/publications/m496pres1.nb.pdf
f(n, k): number of ways of making change for n cents, using only the first
         k+1 types of coins.

          +- 0,                        n < 0 || k < 0
f(n, k) = |- 1,                        n == 0
          +- f(n, k-1) + f(n-C[k], k), else
 */

#include <iostream>
#include <vector>
using namespace std;

int C[] = {1, 5, 10, 25};

// Recursive: very slow, O(2^n)
int f(int n, int k)
{
    if (n < 0 || k < 0)
        return 0;

    if (n == 0)
        return 1;

    return f(n, k-1) + f(n-C[k], k); 
}

// Non-recursive: fast, but still O(nk)
int f_NonRec(int n, int k)
{
    vector<vector<int> > table(n+1, vector<int>(k+1, 1));

    for (int i = 0; i <= n; ++i)
    {
        for (int j = 0; j <= k; ++j)
        {
            if (i < 0 || j < 0) // Impossible, for illustration purpose
            {
                table[i][j] = 0;
            }
            else if (i == 0 || j == 0) // Very Important
            {
                table[i][j] = 1;
            }
            else
            {
                // The recursion. Be careful with the vector boundary
                table[i][j] = table[i][j-1] + 
                    (i < C[j] ? 0 : table[i-C[j]][j]);
            }
        }
    }

    return table[n][k];
}

int main()
{
    cout << f(100, 3) << ", " << f_NonRec(100, 3) << endl;
    cout << f(200, 3) << ", " << f_NonRec(200, 3) << endl;
    cout << f(1000, 3) << ", " << f_NonRec(1000, 3) << endl;

    return 0;
}
share|improve this answer

If the currency system allows it, a simple greedy algorithm that takes as many of each coin as possible, starting with the highest value currency.

Otherwise, dynamic programming is required to find an optimal solution quickly since this problem is essentially the knapsack problem.

For example, if a currency system has the coins: {13, 8, 1}, the greedy solution would make change for 24 as {13, 8, 1, 1, 1}, but the true optimal solution is {8, 8, 8}

Edit: I thought we were making change optimally, not listing all the ways to make change for a dollar. My recent interview asked how to make change so I jumped ahead before finishing to read the question.

share|improve this answer
    
the problem is not necessarily for one dollar -- it could 2 or 23, so your solution is still the only correct one. –  Neil G Jul 10 '09 at 4:20
    
(for the general case) –  Neil G Jul 10 '09 at 4:21

semi-hack to get around the unique combination problem - force descending order:

$denoms = [1,5,10,25]
def all_combs(sum,last) 
  return 1 if sum == 0
  return $denoms.select{|d| d &le sum && d &le last}.inject(0) {|total,denom|
           total+all_combs(sum-denom,denom)}
end

This will run slow since it won't be memoized, but you get the idea.

share|improve this answer

This is a really old question, but I came up with a recursive solution that seemed smaller than all the others, so here goes -

 public static void printAll(int ind, int[] denom,int N,int[] vals){
    if(N==0){
        System.out.println(Arrays.toString(vals));
        return;
    }
    if(ind == (denom.length))return;             
    int currdenom = denom[ind];
    for(int i=0;i<=(N/currdenom);i++){
        vals[ind] = i;
        printAll(ind+1,denom,N-i*currdenom,vals);
    }
 }
share|improve this answer

This is my answer in Python. It does not use recursion:

def crossprod (list1, list2):
    output = 0
    for i in range(0,len(list1)):
        output += list1[i]*list2[i]

    return output

def breakit(target, coins):
    coinslimit = [(target / coins[i]) for i in range(0,len(coins))]
    count = 0
    temp = []
    for i in range(0,len(coins)):
        temp.append([j for j in range(0,coinslimit[i]+1)])


    r=[[]]
    for x in temp:
        t = []
        for y in x:
            for i in r:
                t.append(i+[y])
        r = t

    for targets in r:
        if crossprod(targets, coins) == target:
            print targets
            count +=1
    return count




if __name__ == "__main__":
    coins = [25,10,5,1]
    target = 78
    print breakit(target, coins)

Example output

    ...
    1 ( 10 cents)  2 ( 5 cents)  58 ( 1 cents)  
    4 ( 5 cents)  58 ( 1 cents)  
    1 ( 10 cents)  1 ( 5 cents)  63 ( 1 cents)  
    3 ( 5 cents)  63 ( 1 cents)  
    1 ( 10 cents)  68 ( 1 cents)  
    2 ( 5 cents)  68 ( 1 cents)  
    1 ( 5 cents)  73 ( 1 cents)  
    78 ( 1 cents)  
    Number of solutions =  121
share|improve this answer
public class RepresentCents {
public static int sum(int n){
int count = 0;
for (int i = 0; i <= n / 25; i++)
    for (int j = 0; j <= n / 10; j++)
        for (int k = 0; k <= n / 5; k++)
            for (int l = 0; l <= n; l++){   
                int v = i * 25 + j * 10 + k * 5 + l;
                if (v == n)
                    count ++;
                else if (v > n)
                    break;
            }
return count;
}

public static void main(String[] args){
    System.out.println(sum(100));
}
}

The code is using java to solve this problem and it also works... This method may not be a good idea because of too many loops, but it's really a straight forward way.

share|improve this answer

This blog entry of mine solves this knapsack like problem for the figures from an XKCD comic. A simple change to the items dict and the exactcost value will yield all solutions for your problem too.

If the problem were to find the change that used the least cost, then a naive greedy algorithm that used as much of the highest value coin might well fail for some combinations of coins and target amount. For example if there are coins with values 1, 3, and 4; and the target amount is 6 then the greedy algorithm might suggest three coins of value 4, 1, and 1 when it is easy to see that you could use two coins each of value 3.

  • Paddy.
share|improve this answer

I used a really simple loop to solve this in a BlackJack game I'm writing in HTML5 using the Isogenic Game Engine. You can see a video of the BlackJack game which shows the chips that were used to make up a bet from the bet value on the BlackJack table above the cards: http://bit.ly/yUF6iw

In this example, betValue equals the total value that you wish to divide into "coins" or "chips" or whatever.

You can set the chipValues array items to whatever your coins or chips are worth. Make sure that the items are ordered from lowest value to highest value (penny, nickel, dime, quarter).

Here is the JavaScript:

// Set the total that we want to divide into chips
var betValue = 191;

// Set the chip values
var chipValues = [
    1,
    5,
    10,
    25
];

// Work out how many of each chip is required to make up the bet value
var tempBet = betValue;
var tempChips = [];
for (var i = chipValues.length - 1; i >= 0; i--) {
    var chipValue = chipValues[i];
    var divided = Math.floor(tempBet / chipValue);

    if (divided >= 1) {
        tempChips[i] = divided;
        tempBet -= divided * chipValues[i];
    }

    if (tempBet == 0) { break; }
}

// Display the chips and how many of each make up the betValue
for (var i in tempChips) {
    console.log(tempChips[i] + ' of ' + chipValues[i]);
}

You obviously don't need to do the last loop and it is only there to console.log the final array values.

share|improve this answer

I know this is a very old question. I was searching through the proper answer and couldn't find anything that is simple and satisfactory. Took me some time but was able to jot down something.

function denomination(coins, original_amount){
    var original_amount = original_amount;
    var original_best = [ ];

    for(var i=0;i<coins.length; i++){
      var amount = original_amount;
      var best = [ ];
      var tempBest = [ ]
      while(coins[i]<=amount){
        amount = amount - coins[i];
        best.push(coins[i]);
      }
      if(amount>0 && coins.length>1){
        tempBest = denomination(coins.slice(0,i).concat(coins.slice(i+1,coins.length)), amount);
        //best = best.concat(denomination(coins.splice(i,1), amount));
      }
      if(tempBest.length!=0 || (best.length!=0 && amount==0)){
        best = best.concat(tempBest);
        if(original_best.length==0 ){
          original_best = best
        }else if(original_best.length > best.length ){
          original_best = best;
        }  
      }
    }
    return original_best;  
  }
  denomination( [1,10,3,9] , 19 );

This is a javascript solution and uses recursion.

share|improve this answer
# short and sweet with O(n) table memory    

#include <iostream>
#include <vector>

int count( std::vector<int> s, int n )
{
  std::vector<int> table(n+1,0);

  table[0] = 1;
  for ( auto& k : s )
    for(int j=k; j<=n; ++j)
      table[j] += table[j-k];

  return table[n];
}

int main()
{
  std::cout <<  count({25, 10, 5, 1}, 100) << std::endl;
  return 0;
}
share|improve this answer
public class Coins {

static int ac = 421;
static int bc = 311;
static int cc = 11;

static int target = 4000;

public static void main(String[] args) {


    method2();
}

  public static void method2(){
    //running time n^2

    int da = target/ac;
    int db = target/bc;     

    for(int i=0;i<=da;i++){         
        for(int j=0;j<=db;j++){             
            int rem = target-(i*ac+j*bc);               
            if(rem < 0){                    
                break;                  
            }else{                  
                if(rem%cc==0){                  
                    System.out.format("\n%d, %d, %d ---- %d + %d + %d = %d \n", i, j, rem/cc, i*ac, j*bc, (rem/cc)*cc, target);                     
                }                   
            }                   
        }           
    }       
}
 }
share|improve this answer

Both: iterate through all denominations from high to low, take one of denomination, subtract from requried total, then recurse on remainder (constraining avilable denominations to be equal or lower to current iteration value.)

share|improve this answer

Duh, I feel stupid right now. Below there is an overly complicated solution, which I'll preserve because it is a solution, after all. A simple solution would be this:

// Generate a pretty string
val coinNames = List(("quarter", "quarters"), 
                     ("dime", "dimes"), 
                     ("nickel", "nickels"), 
                     ("penny", "pennies"))
def coinsString = 
  Function.tupled((quarters: Int, dimes: Int, nickels:Int, pennies: Int) => (
    List(quarters, dimes, nickels, pennies) 
    zip coinNames // join with names
    map (t => (if (t._1 != 1) (t._1, t._2._2) else (t._1, t._2._1))) // correct for number
    map (t => t._1 + " " + t._2) // qty name
    mkString " "
  ))

def allCombinations(amount: Int) = 
 (for{quarters <- 0 to (amount / 25)
      dimes <- 0 to ((amount - 25*quarters) / 10)
      nickels <- 0 to ((amount - 25*quarters - 10*dimes) / 5)
  } yield (quarters, dimes, nickels, amount - 25*quarters - 10*dimes - 5*nickels)
 ) map coinsString mkString "\n"

Here is the other solution. This solution is based on the observation that each coin is a multiple of the others, so they can be represented in terms of them.

// Just to make things a bit more readable, as these routines will access
// arrays a lot
val coinValues = List(25, 10, 5, 1)
val coinNames = List(("quarter", "quarters"), 
                     ("dime", "dimes"), 
                     ("nickel", "nickels"), 
                     ("penny", "pennies"))
val List(quarter, dime, nickel, penny) = coinValues.indices.toList


// Find the combination that uses the least amount of coins
def leastCoins(amount: Int): Array[Int] =
  ((List(amount) /: coinValues) {(list, coinValue) =>
    val currentAmount = list.head
    val numberOfCoins = currentAmount / coinValue
    val remainingAmount = currentAmount % coinValue
    remainingAmount :: numberOfCoins :: list.tail
  }).tail.reverse.toArray

// Helper function. Adjust a certain amount of coins by
// adding or subtracting coins of each type; this could
// be made to receive a list of adjustments, but for so
// few types of coins, it's not worth it.
def adjust(base: Array[Int], 
           quarters: Int, 
           dimes: Int, 
           nickels: Int, 
           pennies: Int): Array[Int] =
  Array(base(quarter) + quarters, 
        base(dime) + dimes, 
        base(nickel) + nickels, 
        base(penny) + pennies)

// We decrease the amount of quarters by one this way
def decreaseQuarter(base: Array[Int]): Array[Int] =
  adjust(base, -1, +2, +1, 0)

// Dimes are decreased this way
def decreaseDime(base: Array[Int]): Array[Int] =
  adjust(base, 0, -1, +2, 0)

// And here is how we decrease Nickels
def decreaseNickel(base: Array[Int]): Array[Int] =
  adjust(base, 0, 0, -1, +5)

// This will help us find the proper decrease function
val decrease = Map(quarter -> decreaseQuarter _,
                   dime -> decreaseDime _,
                   nickel -> decreaseNickel _)

// Given a base amount of coins of each type, and the type of coin,
// we'll produce a list of coin amounts for each quantity of that particular
// coin type, up to the "base" amount
def coinSpan(base: Array[Int], whichCoin: Int) = 
  (List(base) /: (0 until base(whichCoin)).toList) { (list, _) =>
    decrease(whichCoin)(list.head) :: list
  }

// Generate a pretty string
def coinsString(base: Array[Int]) = (
  base 
  zip coinNames // join with names
  map (t => (if (t._1 != 1) (t._1, t._2._2) else (t._1, t._2._1))) // correct for number
  map (t => t._1 + " " + t._2)
  mkString " "
)

// So, get a base amount, compute a list for all quarters variations of that base,
// then, for each combination, compute all variations of dimes, and then repeat
// for all variations of nickels.
def allCombinations(amount: Int) = {
  val base = leastCoins(amount)
  val allQuarters = coinSpan(base, quarter)
  val allDimes = allQuarters flatMap (base => coinSpan(base, dime))
  val allNickels = allDimes flatMap (base => coinSpan(base, nickel))
  allNickels map coinsString mkString "\n"
}

So, for 37 coins, for example:

scala> println(allCombinations(37))
0 quarter 0 dimes 0 nickels 37 pennies
0 quarter 0 dimes 1 nickel 32 pennies
0 quarter 0 dimes 2 nickels 27 pennies
0 quarter 0 dimes 3 nickels 22 pennies
0 quarter 0 dimes 4 nickels 17 pennies
0 quarter 0 dimes 5 nickels 12 pennies
0 quarter 0 dimes 6 nickels 7 pennies
0 quarter 0 dimes 7 nickels 2 pennies
0 quarter 1 dime 0 nickels 27 pennies
0 quarter 1 dime 1 nickel 22 pennies
0 quarter 1 dime 2 nickels 17 pennies
0 quarter 1 dime 3 nickels 12 pennies
0 quarter 1 dime 4 nickels 7 pennies
0 quarter 1 dime 5 nickels 2 pennies
0 quarter 2 dimes 0 nickels 17 pennies
0 quarter 2 dimes 1 nickel 12 pennies
0 quarter 2 dimes 2 nickels 7 pennies
0 quarter 2 dimes 3 nickels 2 pennies
0 quarter 3 dimes 0 nickels 7 pennies
0 quarter 3 dimes 1 nickel 2 pennies
1 quarter 0 dimes 0 nickels 12 pennies
1 quarter 0 dimes 1 nickel 7 pennies
1 quarter 0 dimes 2 nickels 2 pennies
1 quarter 1 dime 0 nickels 2 pennies
share|improve this answer

Java solution

import java.util.Arrays;
import java.util.Scanner;


public class nCents {



public static void main(String[] args) {

    Scanner input=new Scanner(System.in);
    int cents=input.nextInt();
    int num_ways [][] =new int [5][cents+1];

    //putting in zeroes to offset
    int getCents[]={0 , 0 , 5 , 10 , 25};
    Arrays.fill(num_ways[0], 0);
    Arrays.fill(num_ways[1], 1);

    int current_cent=0;
    for(int i=2;i<num_ways.length;i++){

        current_cent=getCents[i];

        for(int j=1;j<num_ways[0].length;j++){
            if(j-current_cent>=0){
                if(j-current_cent==0){
                    num_ways[i][j]=num_ways[i-1][j]+1;
                }else{
                    num_ways[i][j]=num_ways[i][j-current_cent]+num_ways[i-1][j];
                }
            }else{
                num_ways[i][j]=num_ways[i-1][j];
            }


        }


    }



    System.out.println(num_ways[num_ways.length-1][num_ways[0].length-1]);

}

}

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.