What you're currently doing is an exhaustive search (i.e. checking every element once), thus O(n*m). You aren't taking advantage of the sorted nature of the matrix.
Given a sorted list, Binary Search lets you search in O(lg n). Basically, you check the middle element of your list. If it's greater than your target then you know you can ignore the second half of the list. Repeat this process, halfing your search space each time, until you find the element or your search space equals 1 item. In Python code:
def binSearch(value, data):
bottom = 0 #first entry
top = len(data) -1 #last entry
while bottom <= top: #if bottom ever becomes greater than top then the object is not in the list
i = int(bottom + math.floor((top - bottom)/2)) #find the mid-point
if data[i] == value: #we found it
elif data[i] > value:
top = i - 1 #value must be before i
bottom = i + 1 #value must be after i
return None #not found
Now, think about what information you can gather from the matrix structure. You know that given a n x m matrix
mat sorted as you desribed, for any row
mat[i] is the lowest items in the row and
mat[i][n] is the highest. Similarly, for any column j,
mat[j] is the lowest value fo that column and
mat[m][j] is the highest. That means that if
mat[i] <= value <= mat[i][n] is not true then value cannot be in row i. Similarly, if
mat[j] <= value <= mat[m][j] is not true then value cannot be in column j.
So the obvious improvement is, for each row that could possibly contain the value, do a binary search.
for row in mat:
if (row <= value) AND (row[len(row) - 1] >= value): #if the value could possibly be in the row
result = binSearch(value, row)
if result: #if we found it
binSearch() is O(lg m). Worst case scenario is performing
binSearch() on every row, thus O(n * lg m).
I was trying to implement a O(lg n * lg m) solution but I can't figure it out. The problem is that I can only eliminate the top left and bottom right corners of the matrix. I can't eliminate the bottom left or top right.