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# Find the row representing the smallest integer in row wise sorted matrix

I was asked this question on in a recent Java telephonic interview:

You are given an NxN binary (0-1) matrix with following properties:

• Each row is sorted (sequence of 0's followed by sequence of 1's)
• Every row represents an unsigned integer (by reading the bits)
• Each row is unique

Example:

``````0 1 1
1 1 1
0 0 1
``````

The bit values in each row is sorted and the rows represent the integers 3, 7 and 1.

Find the row representing the smallest integer. In the example above, the answer is row 3, which represents the integer 1.

I started with brute force of quadratic complexity. The interviewer replied saying I was not exploiting the sorted property.

After thinking a lot I used binary search on each row and it came to O(nlogn). He asked if I could improve any further. I thought a lot but failed to improve.

I would appreciate if anyone can give any pointers on imporoving it.

Another example:

``````0 1 1 1
0 0 0 1
0 0 0 0
1 1 1 1
``````

The answer will be row 3, which represents the integer 0.

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Each row is sorted? or represents a number? not clear.... – Itay Karo Nov 29 '10 at 12:47
Finding the min/max of a sequence is at worst a linear operation. How did you come up with something quadratic? – Ignacio Vazquez-Abrams Nov 29 '10 at 12:51
sorted means that no `0` appears after `1` in a row. – khachik Nov 29 '10 at 12:53
I still don't get the "each row is sorted"... – pgras Nov 29 '10 at 12:56
@pgras: it means that each number consists of a sequence of zeroes followed by a sequence of ones. The only numbers you can have in the list are those in the form of 2^n-1. e.g. 0, 1, 3, 7, 15 etc. – JeremyP Nov 29 '10 at 13:40

Start with row 1. Go right until you hit the first `1`. Then go down to row 2, but remain in the same column and repeat the process of going right until you hit a `1`. Do this repeatedly. The row in which you last stepped right is your answer.

This is an O(N+M) solution (for an NxM matrix, or O(N) for a square NxN matrix as given in the question).

``````0 1 1 1
0 0 0 1
0 0 0 0
1 1 1 1
``````

The `.`'s here represent the path traversed:

``````. . 1 1
0 . . .
0 0 0 . . Last right step, therefore this is our answer
1 1 1 1 .
``````

This solution works on non-square matrixes, retaining a worst case O(N+M) efficiency for an NxM matrix.

Why does this work? The guarantee that the numbers will be sorted means every row will be a series of 0's followed by a series of 1's. So the magnitude of a row is equivalent to how far right you can go before hitting a 1. So if a row can ever take you further by just following the 0's, then it must be longer than anything we've processed before.

Python code:

``````li = [[0, 1, 1, 1],
[0, 0, 0, 1],
[0, 0, 0, 0],
[1, 1, 1, 1]]

ans, j = 0, 0
for i, row in enumerate(li):
while j < len(row) and row[j] == 0:
j += 1
ans = i

print "Row", ans+1, "".join(map(str, li[ans]))
``````

There is also a simpler solution, because of the constraints of always having a square NxN matrix and distinct rows together. Together they mean that the row with the lowest value will be either `0 0 ... 0 1` or `0 0 ... 0 0`. This is because there are N of N+1 possible numbers represented in the matrix, so the "missing" number is either 0 (in which case the smallest value represented is 1) or it's something else (smallest value is 0).

With this knowledge, we check the column second from the right for a 0. When we find one, we look to its right and if that contains another 0 we have our answer (there can only be one row ending in a `0`). Otherwise, we continue to search the column for another 0. If we don't find another 0, the first one we found was the row we're looking for (there can only be one row ending in `01` and since there was none ending in `00`, this is the smallest).

Python code:

``````li = [[0, 1, 1, 1],
[0, 0, 0, 1],
[0, 0, 0, 0],
[1, 1, 1, 1]]

for i, row in enumerate(li):
if row[-2] == 0:
ans = i
if row[-1] == 0:
break

print "Row", ans+1, "".join(map(str, li[ans]))
``````

That solution answers the question with least difficulty in O(N), but generalising it to handle non-square NxM matrixes or non-distinct numbers will make its worst-case efficiency O(N^2). I personally prefer the first solution.

-
+1 nice visual representation of the algorithm. – JeremyP Nov 29 '10 at 13:43
Being capable of working on NxM just adds complexity to the original problem. See stackoverflow.com/questions/4303813/… – Trinidad Nov 29 '10 at 19:00
-1. This is an excellent explanation and a good algorithm for solving a different problem, and an inefficient algorithm for solving the problem stated. I would normally just vote the better answers up, but all of the answers with the O(N) solution are much lower voted and there's no other effective way to move them up as quickly as voting this answer down. – Sparr Nov 30 '10 at 0:20
@marcog: nevermind the naysayers :) I immediately thought of the diagonal too (missed the 1 or 0 bit...) and I still think it's an extremely elegant answer, since it solves the problem stated for any dimensions with the same complexity as the "clever" solution (and about as much reads too). – Matthieu M. Nov 30 '10 at 9:34
I feel like I learned something cool today, thanks. – Liam Dec 4 '10 at 17:09

the lowest number must be 0 or 1. (because there are no duplications and the rows are sorted). all you have to do is go over the last column, if ti contains 0 lowest number is 0 else lowest number is 1.

EDIT - explanation
In `N` rows with the constraint you sated there can be a maximum of `N+1` unique values.
so for sure at least 0 or 1 must be in the matrix....

Edit 2 - algorithm

``````//assuming the matrix is 0 indexed base
for i = 0...N-1
if M[i][N-1] == 0
return "Value is 0 in row i";
for i = 0...N-1
if M[i][N-2] == 0
return "Value is 1 in row i";
//because of the explanation above the flow will never reach here.
``````
-
The smallest number cannot be very large (because there are no duplications in data - no two rows are the same) - The smallest number will always be 0 or 1. – Itay Karo Nov 29 '10 at 13:01
I see this works because you're given an NxN matrix with N distinct numbers. But what if you're given a non-square matrix and the smallest number is really large? – marcog Nov 29 '10 at 13:02
@macrog: I answered the question, the requirement was NxN, For a non-square matrix (NxM) your solution will work but the complexity will be O(N+M) and not O(N) as you stated. – Itay Karo Nov 29 '10 at 13:05
I know you did, your answer is correct - I'm not saying otherwise. I'm just noting that it cannot be efficiently extended to NxM. – marcog Nov 29 '10 at 13:07
@macrog You're adding unnecessary complexity. – Trinidad Nov 29 '10 at 18:59

Since the numbers are unique and since the digits are sorted, it is quite clear that for any value of N, the smallest number can be either of the form [0(N-1 times) followed by 1] or 0(N times).

For example, for N=4, the smallest number can either be 0001 or 0000.

In other words, second last digit of the number we wish to find HAS to be 0. And the last digit can either be 0 or 1

This problem then reduces to just finding these patterns in the array, which can be done using a simple for loop

``````int rowNum = -1;

for(int i=0;i<N;i++)
{
if(arr[i][N-2]==0) //Second last digit is 0. Hence the number could be min.
{
rowNum = i;

if(arr[i][N-1]==1) // If number of the form 0001 was found, keep looking for 0000
{
continue;
}
else
//If number of the form 0000 was found, exit.
//No other number can be lesser than 0000
{
break;
}
}
}
return rowNum;
``````

This algorithm would have complexity O(n)

-
Best solution given the constraints, IMO. =) – Trinidad Nov 29 '10 at 19:27
"best" solutions with a low score make me sad. +1 – Sparr Nov 29 '10 at 22:18
+1 for relating for the unique constraint – shevski Dec 19 '10 at 0:40

You want to find a rows with maximum number of zeros.

• Start at `arr[0][0]`
• If it is `0`, check the element towards right of it, `arr[0][1]`.
• If it's not `0` then skip that row and start checking at the element in the next row below the current element.

Keep doing till you go past the last row/last column or you find a row with all zeros.

Algorithm:

``````i = 0
j = 0

# continue till i is a valid index.
while(i<N)

# continue till j is valid index and ele is 0.
while(j < N AND arr[i][j] == 0)

# move towards right.
j++

# found a row with all zeros.
if(j == N)
break all loops.
end-if

end-while

# skip current row..continue on next row.
i++

end-while

``````

The complexity of this is `O(N+N)` which is `O(N)`, that is linear.

Java implementation

Related question Which makes use of exact same trick

How to efficiently search in an ordered matrix?

-
I believe this solution is slower than the other O(N) solutions. – Sparr Nov 30 '10 at 0:24
``````Start at the top-left.

The first row is the best row so far.

Repeat until you reach the bottom:
If you're not already over a 1:
Go right until you find a 1.
This row is the best row so far.
Go down one row.

Report the best row that was found.
``````

You never go up or left - you only go down (n-1) times and right no more than (n-1) times, making this O(n). This exploits the sortedness by realizing that you never have to go left to check for a 1 - if there is a 1 somewhere to the left, then there is also a 1 in the current spot (and thus the number in this row is at least as big as the one in the previous row).

-
Thats's O(N^2). Good for the general case, but the non-uniqueness means it can be bettered – The Archetypal Paul Nov 29 '10 at 13:09
@Paul: It's O(N) actually. The longest path you can take is only 2N moves. – JeremyP Nov 29 '10 at 13:45
Yes, you're right. I deleted my commment from another solution but forgot about this one. O(N) it is. – The Archetypal Paul Nov 29 '10 at 13:47

Since the bits in each row are sorted, once you have found a 1 bit, all bits to the right must be 1 too. In other words, the array only stores values of the form 2^n-1.

So the answer is the row with the most zero entries is the smallest.

However, since only 2**m-1 entries can be present, and there are n of those, and no two are the same we can deduce more - for any N there are N+1 such values. So either 0 or 1 must be present as we know there are no duplicates.

So look for an empty row (which is hte only one with rightmost column zero). If you don't find it, the answer is 1, else it's 0.

O(N)

-
As puzzle/interview questions go, you have to pay attention to the phrase "find the row with the lowest value" versus "find the lowest value". The answer to the first is a row index. The answer to the second is (in this case) 0 or 1. Both variations have O(N) solutions, but the latter uses one less unit of memory and N less operations. – Sparr Nov 29 '10 at 22:33

How about looping each line in reverse order and checking where the 1s end and the zeroes start?

In fact it is guaranteed that in `NxN`, the worst case is that 0 won't be there. So you can just check the last 2 entries of each row. Which makes it linear.

Since my explanation was not understood, here it is in somewhat pseudo code:

``````int lowestRow = -1;
for (k = 0; k < array.length; k ++) {
byte[] row = array[k];
if (row[row.length - 1] == 0) {
lowestRow = k;
break;
}
if (row[row.length - 2] == 0) {
lowestRow = k;
//possibly look for all-zeroes, so not breaking
}
}
``````
-
@downvoter - could you share why do you think this solution is incorrect? – Bozho Nov 29 '10 at 19:18
"@downvoter" should be a feature that notifies the anonymous downvoter in the same way that @Name does – Sparr Nov 29 '10 at 22:35
@Sparr: what about multiple downvoters? notify them all? :) – Eyal Schneider Dec 11 '10 at 9:55
@Eyal maybe all, maybe only the most recent downvoter, maybe only the most recent downvoter who didn't leave their own comment, or did – Sparr Dec 11 '10 at 20:26

You have to start with the last column, and check if the sum of the element is N-1, once you have found the column with the sum = N-1 search the column containing a 0 and this is the one you are looking for...

-

``````int best = N;

for(int i=0;i<N;i++)
for(int j=0;j<best;j++)
if (arr[i][j] != 0) {
best = j;
}
``````

The inner loops stops as soon as it determines this row won't be the better than the current answer. This could cut out alot of searching down rows which are longer than the best answer so far.

-

Find which row has the first non zero value in the furthest column. If it is binary, with the MSB on the left, and the LSB on the right the answer is the row that starts with the most zeros.

-

-

The smallest number can be 0 which looks like (0000...0000) or 1 which looks like (0000...0001).

Every larger number looks like (xxxx...xx11). So you should check the next to last digit in every row. If it is 0 then check if the last digit is 0. If it is it is the smallest number. If not, then remember the row number and continue looking for row with 0 on the next to last digit. If you find it, this will be the smallest number. If not, the first found number is smallest one.

This is the solution with N+1 steps (worst case scenario) which is O(N) complexity.

-

I don't know if it's admitted, but if it's sorted don't you need just to convert each row to decimal number and choose the row with the lower one. example:

``````[0111] -> 7
[0011] -> 3
[0000] -> 0
[0001] -> 1
``````

The solution is the row with value 0. OR?

-

I have written a O(n) algorithm, similar to what has been stated above, we start from top-left corner and work downwards:

``````a = [
[0, 1, 1, 1],
[0, 0, 0, 1],
[0, 0, 0, 0],
[1, 1, 1, 1]
]
a2 = [
[0, 0, 0, 0],
[0, 1, 1, 1],
[0, 0, 0, 1],
[1, 1, 1, 1]
]

def search(a):
n = len(a)
c = 0
r = 0
best_row = 0
while c<n and r<n:
if a[r][c] == 0:
c += 1
else:
best_row = r
r += 1

if c==n : best_row = r
print( " best row: %d" % best_row )

search( a )
search( a2 )
``````
-