Coin change problem with infinite number of coins of each denomination

I want to know the idea of algorithm for the coin change problem where each denomination has infinte number of coins. Means how to apply DP (like the standard coin change problem) For e.g in set 1,10,15, change for 35 gives--2 coins of 10 and one coin of 15

Also give me an idea of brute forcing algorithm for this. I know to iterate over all the sets. But how to vary the number of each coin while brute forcing

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The "coin change" problem that you're talking about might be called the "knapsack problem": en.wikipedia.org/wiki/Knapsack_problem –  ChrisW Oct 5 '09 at 5:04
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5 Answers

I would think about building the solution one step at a time, inductively:

Coins available are 1c, 5c, 10c, 25c (you can tweak them according to your needs)

1. Minimun coins for 1c = 1 X 1c. Upto 4 cents, we need 1c coins, as that is the least denomination.
2. For 5 cents, we have one 5c coin. Combining that with 4c above, we can generate any number between 1 and 9.
3. For 10 cents, we need 1 X 10c. Combining the above three, we can generate any number between 1 and 19.
4. For 20c, we need 2 x 10c, as 20 is divisible by 10.

If you can formulate the problem inductively, it might be easier to tackle it.

EDIT:
Alright, here's another attempt to explain the dynamic programming solution:

Think of a table with `x` rows (`x` is number of distinct denominations) and `n` columns (`n` is the amount you have to build using least denominations). Every cell in this table represents a distinct sub-problem and will eventually contain the solution to it. Assume:

row 1 represents the set `{1c}` i.e. in row 1 you are allowed to use infinite `1c`
row 2 represents the set `{1c, 10c}` i.e in row 2 you are allowed to infinite `1c` and `10c`
row 3 represents the set `{1c, 10c, 15c}` and so on...
Each column represents the amount you want to construct.

Thus, every cell corresponds to one small sub-problem. For example (the indexes are starting from 1 for the sake of simplicity),
`cell(1, 5)` ==> construct `5c` using only `{1c}`
`cell(2, 9)` ==> construct `9c` using `{1c, 10c}`
`cell(3, 27)` ==> construct `27c` using `{1c, 10c, 15c}`
Now your aim is to get the answer to `cell(x, n)`

`Solution:`
Start solving the table from the simplest problem. Solving the first row is trivial, since in the first row the only denomination available is `{1c}`. Every cell in row 1 has a trivial solution, leading to `cell(1, n)` = `{nx1c}` (`n` coins of `1c`).

Now proceed to the next row. Generalizing for the 2nd row, lets see how to solve for (say) `cell(2, 28)` i.e. construct `28c` using `{1c, 10c}`. Here, you need to make a decision, whether to include `10c` in the solution or not, and how many coins. You have 3 choices (3 = 28/10 + 1)

`Choice 1`:
Take `{1x10c}` and the rest from the previous row (which is stored in `cell(1, 18)`). This gives you `{1x10c, 18x1c}` = `19 coins`

`Choice 2`:
Take `{2x10c}` and the rest from previous row (which is stored in `cell(1, 8)`). This gives you `{2x10c, 8x1c}` = `10 coins`

`Choice 3`:
Take no `10c` and the rest from the previous row (which is stored in `cell(1, 28)`). This gives you `{28x1c}` = `28 coins`

Clearly, choice 2 is the best as it takes less coins. Write it down in the table and proceed ahead. The table is to be filled one row at a time, and within a row, in the order of increasing amounts.

Going by above rules, you will reach `cell(x, n)`, the solution to which will be a choice between `n/p + 1` alternatives, where `p` = newest denomination in row `x`. The best choice is your answer.

The table actually memoizes the solutions to smaller problems, so that you don't need to solve them again and again.

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I understood the first part of ur answer (by induction). But the code that u have given gives answer as 7. But optimal is 3 –  avd Oct 5 '09 at 10:15
I think I made a mistake. Removing the code part of the answer to avoid confusion. –  Ashwin Oct 5 '09 at 10:41
Phew! Pretty long post for 4:30 am. –  Ashwin Oct 5 '09 at 11:28
I hope my post clarified your doubts. –  Ashwin Oct 5 '09 at 17:52
For [1,10,20,25], if you want to give 30cents, how would induction work ? At 25cent, we have optimal soln 25cent coin, at 29 we have 25+1+1+1+1, what would trigger at 30 cents, we should drop 25cent coin and start using 20cent coin ? –  Ajeet Feb 18 '13 at 7:08
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about the brute force part:

``````int i,j,k;
for(i=0;i<35;i++){
for(j=0;j<4;j++){
for(k=0;k<3;k++){
if(1*i+10*j+15*k == 35){
//is this what you need?
//minimum=min(minimum,(i+j+k));
}
}
}
}
``````
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This is how to translate a number from one numbering system to another. For example:

``````35 = 1*2^5 + 0*2^4 + 0*2^3 + 0*2^2 + 0*2^1 + 1*2^0
``````

That is:

``````var cash = 35;
var coins = [15, 10, 5, 1];
var change = {};
for(var i=0; i<coins.length; i++){
change[coins[i]]  = Math.floor(cash/coins[i]);
cash %= coins[i];
}
//change now contains:
//15:2, 10:0, 5:1, 1:0
``````
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This is not always optimal. For example, if coins is [1, 3, 4], and cash = 6, the your program will output 4, 1, 1 instead of 3, 3. –  Olexiy Oct 5 '09 at 19:39
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Regarding the brute force.

It is called "greedy algorithm" - you always take the biggest coin which is not greater than the value you need to represent.

pseudo code, returns the number of coins needed to represent value, if we can use each one infinite number of times

``````int[] greedy(int value, int[] coins) {
int[] ans = ...;
int v = coins.length - 1;
int left = value;
while (left > 0 && v >= 0) {
if (coins[v] <= left) {
ans.push(coins[v]);
} else {
v--;
}
}
return left == 0 ? ans : //representation impossible,
//so you better do something;
}
``````

pseudo code, returns the number of coins needed to represent value, if we can use each one infinite number of times

``````int f(int value, int[] coins) {
int[] memo = new int[value + 1];
Arrays.fill(memo, 1234567);
memo[0] = 0;
for (int coin : coins)
for (int i = 0; i + coin <= value; i++)
memo[i + coin] = min(memo[i + coin], memo[i] + 1);
return memo[value];
}
``````

to know which coins to take, start from the end: `if memo[value] = 3`, then you check all coins and find such coin that `memo[value - coin] == 2`, continue from `(value - coin)` until you reach `0`.

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! Brute force is NOT greedy. Brute force is what it is. Brute force. In brute force you simulate every possible combination and pick the one which optimizes certain function. Greedy, will try to make decision one at a time, and you dont backtrack resulting into one single combination at the end.. –  Ajeet Feb 18 '13 at 7:16
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You can run it here http://www.exorithm.com/algorithm/view/coin_change

``````function coin_change (\$amount, \$coins)
{
\$change = array();
rsort(\$coins);
for(\$i=0; \$i<count(\$coins); \$i++) {
\$change[\$coins[\$i]] = floor(\$amount/\$coins[\$i]);
\$amount = \$amount % \$coins[\$i];
}
return \$change;
}
``````
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for change 30, and coins [1,10,20,25] this would give wrong/suboptimal result as coins = 6 –  Ajeet Feb 18 '13 at 7:12
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