Search for **x** in matrix **M**[m*n] (m rows,n columns).

I think that the best option is incorrect row skipping.

- if x is out of range of row(r) then skip searching in it

And on top of that simply apply binary (or index bit approximation) search

```
const int n=...;
const int m=...;
double x=...,A[m][n]={...};
int r,i,j,j0;
double *p;
// init bit mask for index approximation
for (j=1;j<n;j<<=1); j>>=1; if (!j) j=1; j0=j;
// search
for (r=0;r<m;r++) // all rows
if (x>=A[r][0]) // skip if x is too low
if (x<=A[r][n-1]) // skip if x is too high
{
// index approximation search in row r
for (p=A[r],i=0,j=j0;j;j>>=1)
{
i|=j;
if ((i>=n)||(x<p[i])) i^=j;
if (x==p[i]) return "x found in A[r][i]";
}
}
return "x not found";
```

On complexity your N is m*n and the algorithm is:

```
Omin(m+ log2(n))
Omax(m+m*log2(n))
```

if (m==n) then we can rewrite it in N=n*n order more simply:

```
Omin(sqrt(N)+ log2(sqrt(N)) )
Omax(sqrt(N)*(1+log2(sqrt(N))))
```

if not then n->N/m and m->N/n so:

```
Omin((N/n)+ log2(sqrt(N/m)) )
Omax((N/n)*(1+log2(sqrt(N/m))))
```

As you can see complexity depends strongly on matrix values and goes from Omin to Omax. Program should be changed to meet your interface and enviroment and also return values are just to show what happend and should be changed to meet your needs.

`O(n)`

is certainly possible. Scanning every element in an array is a canonical example of an`O(n)`

operation. Assertions to the contrary are based on the misunderstanding that`n`

represents the size of one dimension of the array; for complexity analysis it most certainly does not, it represents the number of elements in the array. If you doubt this, and think that scanning every element in an array is`O(n^2)`

then just reshape the array to a vector (`O(1)`

because it is just twiddling with indices) and scan the vector ... magically turning an`O(n^2)`

operation into an`O(n)`

one. Pshaw. – High Performance Mark Oct 17 '13 at 13:01