Let $M \in \{0,1\}^{m\times n}$, where $n\gg 1$. A procedure formed by the following three steps is repeated $t\gg 1$ times:

1) We receive a row $\boldsymbol{r}$ of $M$ picked in an adversarial (hidden) way, viz. we do not know the row index of $\boldsymbol{r}$ and a copy of the row vector $\boldsymbol{r}$ is provided to us.  

2) We receive a set $S$ formed by sampling uniformly at random $\sqrt{n}$ indices from $[n]$.

3) We need to find at least one row $\boldsymbol{r}'$ of $M$ such that, for all column indices $j \in S$, we have $\boldsymbol{r}'_j=\boldsymbol{r}_j$.

It is easy to see that the simplest method to accomplish this task requires in the worst case a total number of elementary operations (e.g., verifying if two binary digits are equal) that is order of $t\,m\,\sqrt{n}$, as both $k$ and $n$ approach infinity. 

Question: Is there a (perhaps randomized) method to accomplish this task such that, by suitably pre-processing the matrix $M$ in a preliminary phase if necessary, the (expected) number of elementary operations is equal in the worst case to $o(t\,m\,\sqrt{n})$? 

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For example, consider we pre-process the matrix $M$ by permutating its rows such that, if $N_i$ is the integer corresponding to the binary digit representation of the $i$-th row of $M$, they are sorted in such a way $N_i\le N_j$ whenever $i \le j$. Is there any method able to take advantage of this row (sorting) permutation?