LeetCode 3130 – Find All Possible Stable Binary Arrays II
LeetCode 3130 – Find All Possible Stable Binary Arrays II
In this article, we will learn how to solve LeetCode 3130 – Find All Possible Stable Binary Arrays II using Dynamic Programming.
This is an advanced DP problem where we must carefully control how many consecutive elements appear in the array.
Problem Summary
We are given three integers:
- zero → number of zeros
- one → number of ones
- limit → maximum allowed consecutive identical numbers
We must build binary arrays such that:
- The array contains exactly zero zeros
- The array contains exactly one ones
- No more than limit consecutive identical numbers
Return the total number of valid arrays.
Example
Input:
zero = 1 one = 2 limit = 1Possible permutations:
011 101 110Validation:
011 → invalid (two consecutive ones) 101 → valid 110 → invalidAnswer:
1
Key Observation
The difficulty of this problem is controlling consecutive identical numbers.
For example if limit = 2:
00 allowed 11 allowed 000 not allowed 111 not allowed
So while constructing the array we must remember:
- how many zeros we used
- how many ones we used
- what the last element was
DP State Definition
dp[i][j][lastBit]Where:
| Variable | Meaning |
|---|---|
| i | zeros used |
| j | ones used |
| lastBit | last number placed (0 or 1) |
dp[2][1][0]means:
- 2 zeros used
- 1 one used
- array ends with 0
DP Transition
Case 1 – Array ends with 0
To place a zero we come from:dp[i-1][j][0] dp[i-1][j][1]So:
dp[i][j][0] = dp[i-1][j][0] + dp[i-1][j][1]But this might create sequences like:
000which exceed the limit. So we subtract invalid cases:
dp[i-limit-1][j][1]
Case 2 – Array ends with 1
Similarly:dp[i][j][1] = dp[i][j-1][0] + dp[i][j-1][1]And remove invalid sequences:
dp[i][j-limit-1][0]This trick avoids tracking consecutive counts directly.
Java Implementation
class Solution {
public int numberOfStableArrays(int zero, int one, int limit) {
final int MOD = 1000000007;
int[][][] dp = new int[zero + 1][one + 1][2];
for (int i = 0; i <= zero; i++) {
for (int j = 0; j <= one; j++) {
for (int lastBit = 0; lastBit <= 1; lastBit++) {
if (i == 0) {
if (lastBit == 0 || j > limit)
dp[i][j][lastBit] = 0;
else
dp[i][j][lastBit] = 1;
} else if (j == 0) {
if (lastBit == 1 || i > limit)
dp[i][j][lastBit] = 0;
else
dp[i][j][lastBit] = 1;
} else if (lastBit == 0) {
dp[i][j][0] = dp[i - 1][j][0] + dp[i - 1][j][1];
if (i > limit)
dp[i][j][0] -= dp[i - limit - 1][j][1];
} else {
dp[i][j][1] = dp[i][j - 1][0] + dp[i][j - 1][1];
if (j > limit)
dp[i][j][1] -= dp[i][j - limit - 1][0];
}
dp[i][j][lastBit] %= MOD;
if (dp[i][j][lastBit] < 0)
dp[i][j][lastBit] += MOD;
}
}
}
return (dp[zero][one][0] + dp[zero][one][1]) % MOD;
}
}
Time Complexity
O(zero × one)
Space Complexity
O(zero × one)
Video Explanation
You can watch the complete explanation here:
Key Takeaways
- This problem uses Dynamic Programming.
- We track how many zeros and ones are used.
- We track the last element placed.
- Prefix subtraction removes invalid sequences efficiently.
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