# Binary search algorithm in python

I am trying to implement the binary search in python and have written it as follows. However, I can't make it stop whenever needle_element is larger than the largest element in the array.

Can you help? Thanks.

``````def binary_search(array, needle_element):
mid = (len(array)) / 2
if not len(array):
raise "Error"
if needle_element == array[mid]:
return mid
elif needle_element > array[mid]:
return mid + binary_search(array[mid:],needle_element)
elif needle_element < array[mid]:
return binary_search(array[:mid],needle_element)
else:
raise "Error"
``````
• I would try to avoid creating lots of partial copies of the array, and pass in a lower and upper index instead. Then you simply stop if lower>upper. – Lasse V. Karlsen Feb 29 '12 at 14:58
• May want to see binary-search-in-python – nawfal Jun 15 '14 at 19:22
• If the purpose of this is academic understanding of binsearch, I can't really help, but if the purpose of this code is to actualy be used: never roll your own binsearch. Always use widly adopted, and prefereably old, library implementation, and even then be very careful, binseach is notoriously difficult to get right in all edgecases. – RBF06 Feb 22 '19 at 23:11

## 14 Answers

In the case that `needle_element > array[mid]`, you currently pass `array[mid:]` to the recursive call. But you know that `array[mid]` is too small, so you can pass `array[mid+1:]` instead (and adjust the returned index accordingly).

If the needle is larger than all the elements in the array, doing it this way will eventually give you an empty array, and an error will be raised as expected.

Note: Creating a sub-array each time will result in bad performance for large arrays. It's better to pass in the bounds of the array instead.

• Good performance note; it is important for the OP to consider that – PALEN Sep 29 '17 at 0:23

It would be much better to work with a `lower` and `upper` indexes as Lasse V. Karlsen was suggesting in a comment to the question.

This would be the code:

``````def binary_search(array, target):
lower = 0
upper = len(array)
while lower < upper:   # use < instead of <=
x = lower + (upper - lower) // 2
val = array[x]
if target == val:
return x
elif target > val:
if lower == x:   # these two are the actual lines
break        # you're looking for
lower = x
elif target < val:
upper = x
``````
• `lower < upper` will stop once you have reached the smaller number (from the left side)
• `if lower == x: break` will stop once you've reached the higher number (from the right side)

Example:

``````>>> binary_search([1,5,8,10], 5)   # return 1
1
>>> binary_search([1,5,8,10], 0)   # return None
>>> binary_search([1,5,8,10], 15)  # return None
``````
• This doesn't work. Try a list: [7,9,2,4,8,6,5,1,8,5,3]. – user1342336 Jan 17 '17 at 20:13
• You could do `x = (lower + upper) // 2` – prgDevelop Sep 19 '17 at 8:11
• @user1342336 Binary search is only expected to work on lists that are already in sorted order. – Arthur Tacca Jul 16 '20 at 21:44

Why not use the bisect module? It should do the job you need---less code for you to maintain and test.

• bisect.bisect_right( a, b) -> gonna be hard to do better speed wise – D Adams Mar 5 '17 at 1:48

array[mid:] creates a new sub-copy everytime you call it = slow. Also you use recursion, which in Python is slow, too.

Try this:

``````def binarysearch(sequence, value):
lo, hi = 0, len(sequence) - 1
while lo <= hi:
mid = (lo + hi) // 2
if sequence[mid] < value:
lo = mid + 1
elif value < sequence[mid]:
hi = mid - 1
else:
return mid
return None
``````
• Not only recursion is slow - it will actually blow up in your face if the array is long enough, because Python has no tail recursion optimization and will run out of stack frames given a large enough input array. – Shnatsel Mar 25 '16 at 15:42
• @Shnatsel ad "large enough input array" - given we are talking about "binary" search and CPython has by default recursion limit set to 1000 (can be set to more by `sys.setrecursionlimit`) we are talking about arrays of sizes up to 2**1000, also know as ~10^300... – Ecir Hana Mar 26 '16 at 0:53

You can improve your algorithm as the others suggested, but let's first look at why it doesn't work:

You're getting stuck in a loop because if `needle_element > array[mid]`, you're including element `mid` in the bisected array you search next. So if needle is not in the array, you'll eventually be searching an array of length one forever. Pass `array[mid+1:]` instead (it's legal even if `mid+1` is not a valid index), and you'll eventually call your function with an array of length zero. So `len(array) == 0` means "not found", not an error. Handle it appropriately.

This is a tail recursive solution, I think this is cleaner than copying partial arrays and then keeping track of the indexes for returning:

``````def binarySearch(elem, arr):
# return the index at which elem lies, or return false
# if elem is not found
# pre: array must be sorted
return binarySearchHelper(elem, arr, 0, len(arr) - 1)

def binarySearchHelper(elem, arr, start, end):
if start > end:
return False
mid = (start + end)//2
if arr[mid] == elem:
return mid
elif arr[mid] > elem:
# recurse to the left of mid
return binarySearchHelper(elem, arr, start, mid - 1)
else:
# recurse to the right of mid
return binarySearchHelper(elem, arr, mid + 1, end)
``````
``````def binary_search(array, target):
low = 0
mid = len(array) / 2
upper = len(array)

if len(array) == 1:
if array == target:
print target
return array
else:
return False
if target == array[mid]:
print array[mid]
return mid
else:
if mid > low:
arrayl = array[0:mid]
binary_search(arrayl, target)

if upper > mid:
arrayu = array[mid:len(array)]
binary_search(arrayu, target)

if __name__ == "__main__":
a = [3,2,9,8,4,1,9,6,5,9,7]
binary_search(a,9)
``````

Using Recursion:

``````def binarySearch(arr,item):
c = len(arr)//2
if item > arr[c]:
ans = binarySearch(arr[c+1:],item)
if ans:
return binarySearch(arr[c+1],item)+c+1
elif item < arr[c]:
return binarySearch(arr[:c],item)
else:
return c

binarySearch([1,5,8,10,20,50,60],10)
``````
• This doesn't handle if the item doesn't exist in the list. It just throws exception. – ozn Nov 21 '19 at 4:28

All the answers above are true , but I think it would help to share my code

``````def binary_search(number):
numbers_list = range(20, 100)
i = 0
j = len(numbers_list)
while i < j:
middle = int((i + j) / 2)
if number > numbers_list[middle]:
i = middle + 1
else:
j = middle
return 'the index is '+str(i)
``````

If you're doing a binary search, I'm guessing the array is sorted. If that is true you should be able to compare the last element in the array to the `needle_element`. As octopus says, this can be done before the search begins.

You can just check to see that `needle_element` is in the bounds of the array before starting at all. This will make it more efficient also, since you won't have to do several steps to get to the end.

``````if needle_element < array or needle_element > array[-1]:
# do something, raise error perhaps?
``````

It returns the index of key in array by using recursive.

round() is a function convert float to integer and make code fast and goes to expected case[O(logn)].

``````A=[1,2,3,4,5,6,7,8,9,10]
low = 0
hi = len(A)
v=3
def BS(A,low,hi,v):
mid = round((hi+low)/2.0)
if v == mid:
print ("You have found dude!" + " " + "Index of v is ", A.index(v))
elif v < mid:
print ("Item is smaller than mid")
hi = mid-1
BS(A,low,hi,v)
else :
print ("Item is greater than mid")
low = mid + 1
BS(A,low,hi,v)
BS(A,low,hi,v)
``````

Without the lower/upper indexes this should also do:

``````def exists_element(element, array):
if not array:
yield False

mid = len(array) // 2
if element == array[mid]:
yield True
elif element < array[mid]:
yield from exists_element(element, array[:mid])
else:
yield from exists_element(element, array[mid + 1:])
``````

Returning a boolean if the value is in the list.

Capture the first and last index of the list, loop and divide the list capturing the mid value. In each loop will do the same, then compare if value input is equal to mid value.

``````def binarySearch(array, value):
array = sorted(array)
first = 0
last = len(array) - 1

while first <= last:
midIndex = (first + last) // 2
midValue = array[midIndex]

if value == midValue:
return True
if value < midValue:
last = midIndex - 1
if value > midValue:
first = midIndex + 1
return False
``````