/**
* @params {Array} coins
* @params {Number} amount
*/
export const change = (coins, amount) => {
// Create and initialize the storage
const combinations = new Array(amount 1).fill(0)
combinations[0] = 1
// Determine the direction of smallest sub-problem
for (let i = 0; i < coins.length; i ) {
// Travel and fill the combinations array
for (let j = coins[i]; j < combinations.length; j ) {
combinations[j] = combinations[j - coins[i]]
}
}
return combinations[amount]
}
/**
* @params {Array} coins
* @params {Number} amount
*/
export const coinChangeMin = (coins, amount) => {
const map = { 0: 1 }
for (let i = 1; i <= amount; i ) {
let min = Infinity
for (const coin of coins) {
if (i < coin) continue
min = Math.min(min, 1 map[i - coin])
}
map[i] = min
}
return map[amount] === Infinity ? -1 : map[amount] - 1
}
Given a value N
, if we want to make change for N
cents, and we have infinite supply of each of S = {S1, S2, .. , Sm}
valued coins, how many ways can we make the change? The order of coins doesn’t matter.
Let the dp[i]
be the length of the coin change of prefix N[1..i]
. Our answer is dp[N]
.
We fill dp[0]
as 1 because there is only one way to get 0 coins (We pick no coins).
Now let's try calculate dp[i]
for any i
. dp[0..i]
will store each sub problems from 0
to N
. That's why the answer will be dp[N]
. First, we need to iterate each coin types to pick them one-by-one. Then we iterate the sub problems from current coin that we pick before to N
cents. That's why we must make dp table with N
columns.
This is the codes for the Coin Change algorithm:
for coin_val in S:
for i in range(coin_val, n 1):
dp[i] = dp[i - coin_val]
In the second iteration, for every cent that can be exchanged, we take it by subtracting the i-th column by the value of the coin we take and adding it into the current column. So dp[i]
will store the current sub problem.
O(N * S)
in any case
O(N)
- simple implementation. We only need 1D array to store the answer.
Let's say we have 3 coin types [1,2,3]
and we want to change for 7
cents. So we will define our table like this.
[1, 0, 0, 0, 0, 0, 0, 0]
0th column will store 1 since there is only one way to get 0 cents.
{1,1,1,1,1,1,1}
. On the final iteration, our table be like:[1, 1, 1, 1, 1, 1, 1, 1]
dp[2] = dp[0]
. We know that dp[0]
stored a value of 1. Thus, dp[2] will store the value of 1 1 = 2
. From here we know that for 2 cents, there are 2 ways {1,1}
and {2}
. And this operation will continue. Now our table be like:[1, 1, 2, 2, 3, 3, 4, 4]
4 ways to make 7 cents using value of 1 and 2. {{1,1,1,1,1,1,1}, {1,1,1,1,1,2}, {1,1,1,2,2}, {1,2,2,2}}
[1, 1, 2, 3, 4, 5, 7, 8]
So the final answer is 8. 8 ways to make change of 7 cents using all coin types. {{1,1,1,1,1,1,1}, {1,1,1,1,1,2}, {1,1,1,2,2}, {1,2,2,2}, {1,1,1,1,3}, {1,3,3}, {2,2,3}, {1,1,2,3}}