Anyone who can come up with solutions like this, on the fly, without having first studied the problem, is a genius and I salute them. Also thank you Neetcode for this video

I dealt with a slightly different problem in the 1980s. I was to find the "moving median" of N points in a data sequence that keeps on coming. But I wasn't going to do this with programming, but with dedicated hardware, like gate arrays. At any instant, there were N saved points. The oldest was discarded, the sample just arrived was inserted, and the median of the N points in the list was reported. I used a min-heap and a max heap. The exciting thing was that all the comparisons and data movements in working with a heap can be done in parallel, so the O(log N) time per sample reduces to O(1).

This is just incredible... for some reason I either never learned, or don't remember learning, Heaps in my computer science education at university. Throughout the years I have always heard the word Heap but never really drilled down into what it did or where it is useful. This really inspired me to fill the gap!!

Thanks for making this clear!!!

10:18 But two, that's "two" big of a difference 😁 Thank you NeetCode, your videos have helped me understand hard problems a bunch!

thanks neetcode for amazing explanation !!!!..... you are doing a great job man.....there are a few youtube channels which implement problem code in python...YOU ARE THE BEST OF THEM 👑

Excellent work on explaining this! I was wondering if you can do a follow up video expounding upon the other approaches to the problem? IMHO, the primary reason this a leetcode hard problem is because of the myriad of approaches to solving it especially given different constraints (i.e. memory bound - how can do we do it with Reservoir Sampling, Segment Trees, etc.) I saw the Leetcode solution to this problem mentions these different approaches but I think you will do a much better job of explaining it :)

a fantastic explanation as always, Thanks!

Man you're actually so goated. These explanations legitimely make me understand the structures and concepts and I can code out the solution from understanding the logic before you go through writing the code. While I'm sure Google was great, I'm glad you're focusing full time on this because you're the absolute best resource I've come across

I'm a bit confused on why to add the new numbers directly to small heap by default. Couldn't this be optimized by comparing the incoming number to both of the root nodes and adding the new one to the small/large heap depending on if the new value is less than or greater than the root nodes? Like let's take 3547: First add 3 to the small heap - O(1) Next 5 comes in, is greater than 3, add to large heap - O(1) Next 4 comes in, is between the values, add to small heap - O (log n) Next 7 comes in, is larger than 4 and larger than 5, add to large heap - O (log n) if that last number was a 1, its smaller than 4 and 5, add to small heap. Now the heaps are unbalanced so pop 4 from small heap, push to large heap - O (log n) + O (log n) This way whenever your trees are imbalanced you can just pop the root of the larger one and push it to the smaller one to keep them always balanced and at most you have to push and pop once rather than twice with the "swap" method in the video. I may be missing something, but it seems inefficient at first glance. Other than that, great video, you always explain these so concisely 👍

Best explanation. Thank you

Very nicely presented, thanks!

Thank You for the amazing explanation Neetcode

amazing explanation, thank you very much sir !

best explanation ever! thank you so much for this.

Thank you so much for made this amazing video!

whenever i came to see your approch i just had to watch 1/3 of the video cuz your explanation is soo good

Awesome explanation... thank you!!

very well explained !!!

awesome explanation.. thanks a lot!

Very nice visual explanation. I would suggest, that instead of saying size is approximately equal, can we say size difference must be at MOST 1 ?

Best Explanation!

Nice explanation!

Great stuff, thanks mate! I've been thinking off migrating to Python for interviews but the edge case with max heap again made me stop doing that :)

perfect solution and illustration, thanks so much

A bit shorter and easier: import heapq class MedianFinder: def __init__(self): self.min_heap = [] # To store the larger half of numbers self.max_heap = [] # To store the smaller half of numbers def addNum(self, num: int) -> None: # Push the number to the max-heap (negated) to simulate a min-heap heapq.heappush(self.max_heap, -num) # Pop the smallest number from the max-heap and push it to the min-heap heapq.heappush(self.min_heap, -heapq.heappop(self.max_heap)) # If the min-heap has more elements than the max-heap, balance the heaps if len(self.min_heap) > len(self.max_heap): heapq.heappush(self.max_heap, -heapq.heappop(self.min_heap)) def findMedian(self) -> float: # If the total count of numbers is odd, the median is the top of the max-heap if len(self.max_heap) > len(self.min_heap): return -self.max_heap[0] # If the total count of numbers is even, the median is the average of the tops of both heaps return (-self.max_heap[0] + self.min_heap[0]) / 2

we can also do with sortedlist from sorted containers

I had this in an interview and was asked: - "If all integer numbers from the stream are in the range [0, 100], how would you optimize your solution?" - "If 99% of all integer numbers from the stream are in the range [0, 100], how would you optimize your solution?" How would you go about this? :) Thanks!

An alternative solution could be to use self-balancing trees (AVL, Red-Black, etc.) where all the operations are log_n. However, we don't need find and instead just need to maintain a separate pointer to the median, then after each insert, depending on whether the inserted number is greater or less the current median, we move the median pointer to the element adjacent to the previous median.

For some interesting reason it runs a bit slower, if we add incoming num into the big heap instead of small, and make the necessary amendment to the code to pop from big instead of small.

question: if you're doing a bunch of logn operations for every add, isn't this a nlogn algorithm? if you're adding n elements, and each time you'll do logn operations, this becomes nlogn. you may as well have just sorted it.

The solution is understandable, but it would take weeks of full time work for me, to find it by myself. As every test, mock code verifies your knowledge of patterns.

Thank you so much🥰🥰🥰

the addNum function should be SO MUCH simpler. You don't need to check anything if you keep everything on track. if "small" is larger, push element to there and pop from there and push it to "bigger", VICE VERSA. The heaps themselves will make the work of whos bigger/smaller.

Why can't I think of such amazing solutions 😢

Even tho this is a hard problem and I have trouble with mediums and even some easy problems, I was able to get this one pr easily. So I guess everyone has a type of problem that just clicks. No point beating yourself up over not getting all of the patterns immediately.

Thank you for this great explanation! I was wondering why can't we use a self-balancing BST like AVL or Red Black Tree ?

Does using heapq._heapify_max a standard for implementing a max heap or we need to use -1 with min heap?

many thanks

Why do you do this thing where you first add to the left by default, and then check & rebalance between the two heaps? Can't you peek at the min/max in either tree and decide where it should go based on that, and based on the current sizes of each tree without having to actually go through an `add` operation?

I have 0 knowledge of dsa or oop yet i think this is the easiest leetcode problem there ever exists. I can do this only using C !

Thanks for the explanation! I found the below solution a bit cleaner yet still intuitive. The idea is that for every new number, 1. we first push it to the small heap 2. then pop from small heap and push to big heap 3. check if the small heap is too small(not balanced) the code can be reduced largely in this case: class MedianFinder: def __init__(self): self.maxHeap = [] self.minHeap = [] def addNum(self, num: int) -> None: heapq.heappush(self.maxHeap, num * -1) heapq.heappush(self.minHeap, heapq.heappop(self.maxHeap) * -1) if len(self.minHeap) > len(self.maxHeap): heapq.heappush(self.maxHeap, heapq.heappop(self.minHeap) * -1) def findMedian(self) -> float: if len(self.maxHeap) == len(self.minHeap): return (self.minHeap[0] + self.maxHeap[0] * -1) /2 else: return self.maxHeap[0] * -1

Great video

Got asked this during a 20 minute technical interview for a FAANG internship. Got the brute force solution but didn't get anywhere close to optimal. Safe to say I didn't do well 😔

not too bad! I thought I had to implement my own heap

You are amazing!!!!!

this is amazing

Thank you

Hi, I have a question about this question. Can I use binary search to do insertion sort when adding a new number? This will also be a O(logn) algorithm

Thanks!

Wouldn't you get an index out of range if the first action was to find median? before adding at least two elements? Line 34 would run but there wouldn't be anything to return from the heaps. line 34: return ( -1 * self.small[0] + self.large[0]) / 2

thank you

i like the way you think ,its impressive

Binary search actually works for this problem.

Great Explanation! - Question: Why can't we find the index to insert the element to array list using Binary Search and add it to that index as we go? Is it because insertion to a particular index in ArrayList is O(n) operation?

Great explanation. Couldn't heaps be avoided in this case? We can insert the values from our stream into our list in log time by using binary search (by definition empty and lists of size 1 are always sorted) and then find the median that way. Am I missing something?

heya! im not sure why the solution works for you, but i had to divide by 2.0 instead of 2 because of some floating error - took very long to debug this :/ had to read through the discuss section in leetcode to find some answers - but thanks for doing this!

anyone can tell me that , at 23:16, is there any case where the input will enter into line no 24? if so what could be that sample input?

Awesome!

i inow it's silly, but inserting into an empty heap is O(1). Getting the max or min is O(1) if it doesn't involve removing it. I think you covered that though. Awesome video. I liked and subscribed!

why you dun use sortedcontainers? is it we are not allowed to use this library?

What is the time complexity of this solution ?

instead of using heap or priority queues. You can use segment tree . Let me explain , each node from l to r represents the position where each value in the segment l , r lies in the sorted array . Then you can use lazy update to update the position and binary search in segment tree to find the median :"D have fun.

U a God

The brute force solution is actually O(n^2). The reason is because it takes n time to search the array to know where to insert the current number, and then the actual insertion takes another n because you have to shift over all the elements after it.

If in interviews this is how we have to explain but in any OA or CP we can use this bisect.insort(nums,num) this will do all the minheap stuff

Definitely the best videos. Los mejores vídeos sin duda.

What is time complexity for this solution?

I Don't understand when we are chcking if every num in small is

I don't understand why line 16 doesn't output "IndexError: list index out of range" when he tries to get the first index of the empty large heap. What am I missing?

I believe in C++, we cant delete arbitrary elements from heap, so we would have to modifications in this approach.

Thanks for making this look easy and Isn't that O(n) as we are finding lengths of small and large?

Jesus, on an interview I have no idea how they expect us to come up with this if we never saw this heap solution before. I'm just gonna give them the in-order sorting solution and talk to them about the 2 heap solution if I ever get this, cause this is tough to remember.

@NeetCode , What do you think is the problem with using re-balancing BST directly which keeps root as the median (in odd case)? I mean ,it seems like you are trying to do the exactly same thing indirectly

Can we use library function of heaps in interview?

I think it would be way easier to solve with if len(self.small) == len(self.large) instead

Great... Although you code in python, which is above my head, thanks for the intuition though;

Your explaining is good as f

cant u use an order statistic tree for this?

Cant we do it in set in which insert in sorted order and will be less painful than using two heaps. max insert complexity is still log(n) and median will also be O(1)

which board you are using?

isn't heappop() an O(logn) operation, since the heap has to be rearranged later, instead of O(1) ?

How can we create a heap in Js.

Is this not the same as using a single heap?

so maximum time complexity for add operation will be : 3 log N , correct ?

Speed will be a little be faster if we check item is large or equal to self.large[0], then decide which heap to add import heapq class MedianFinder: def __init__(self): self.small = [] # maxheap self.large = [] # minheap heapq.heapify(self.small) heapq.heapify(self.large) def addNum(self, num: int) -> None: if (self.large and (self.large[0]) 1: temp = -1 * heapq.heappop(self.small) heapq.heappush(self.large, temp) if len(self.small) - len(self.large) < -1: temp = -1 * heapq.heappop(self.large) heapq.heappush(self.small, temp) def findMedian(self) -> float: if len(self.small) > len(self.large): return -1 * self.small[0] if len(self.large) > len(self.small): return self.large[0] return (-1 * self.small[0] + self.large[0])/2

i enjoyed

Instead of a heap can't we maintain a simple list. For every insert we add the element in the sorted order using binary search.

Shouldn't the return self.small[0] should be -1* self.small[0] in the findMedian method. As we are artificially adding them for our purposes.

Why didn't you use -1* in find median def while calculating median ?

How to come up that we require 2 priority queue one of min and one of max pls give intuition also

I believe for the brute force solution the time complexity goona be O(n^2) coz in the worst case we have to move almost n elements for at least n elements in our array

I wonder why not use a binary search instead? Since we can build the list sorted, we can binary search to find the position to insert new num in O(logn)? Then retrieve is just the same as in-order insertion which is O(1). Is it because inserting an item into an array itself takes O(n) due to copy operation in the underlying data structure?

Hello sir could you please explain why sometimes it's self.small but sometimes it's just small?? I'm really confused, thank you!

Had to make it a 2.0 instead of 2 because of some bullshit rounding error at the end

Another solution: Implement a BST. When you invoke addNum() insert into the BST (which is lgN) operation (assuming it is balanced). Then findMedian is similar to implementKthSmallest element in BST. const medianUsingBST = () => { let root = undefined; let size = 0; // Ensures sort during insertion const insertIntoBST = (num) => { if (!root) { root = new TreeNode(num); size++; return; } const helper = (curr, parent) => { if (!curr) { if (num < parent.val) { parent.left = new TreeNode(num); } else { parent.right = new TreeNode(num); } size++; return; } if (num > curr.val) { helper(curr.right, curr); } else { helper(curr.left, curr); } } helper(root, undefined); } const findKthSmallestElementInBst = (k) => { let counter = 0; let result = undefined; const inOrder = (curr) => { inOrder(curr.left); counter++; if (counter === k) { result = curr.val; } inOrder(curr.right); } inOrder(root); } const addNum = (num) => { insertIntoBST(num); } const findMedian = () => { if (size % 2 === 1) { return findKthSmallestElementInBst(Math.ceil(size / 2)); } return (findKthSmallestElementInBst(size / 2) + findKthSmallestElementInBst(size / 2) + 1) / 2; } return { addNum, findMedian} }

Came up with this solution without watching the coded solution - class MedianFinder: def __init__(self): self.maxHeap = [] # lower half of the sorted array self.minHeap = [] # upper half of the sorted array def addNum(self, num: int) -> None: heappush(self.maxHeap, -num) # if all elements in maxHeap are not smaller than all elements in meanHeap if self.minHeap and self.maxHeap and (-self.maxHeap[0]) > self.minHeap[0]: heappush(self.minHeap, -heappop(self.maxHeap)) # check if difference in size of min heap and max heap is within allowable limit sizeDiff = len(self.maxHeap) - len(self.minHeap) if sizeDiff>1: # maxHeap has 1+ extra elements heappush(self.minHeap, -heappop(self.maxHeap)) elif sizeDiff < 0: # minHeap has extra elements heappush(self.maxHeap, -heappop(self.minHeap)) def findMedian(self) -> float: if (len(self.minHeap) + len(self.maxHeap))%2==0: # even size return (self.minHeap[0] - self.maxHeap[0])/2 else: return -self.maxHeap[0]

Heaps are implemented using lists? That's misleading, at best. Still a great vid :)

Does anyone know how to answer the follow-up questions? 1. If all integer numbers from the stream are in the range [0, 100], how would you optimize your solution? I think we can replace 2 Heaps with 2 TreeMaps. The key is the number, value is the count. We need to keep the sum of values of 2 TreeMaps and update each time we balance size of the 2 TreeMaps. Because the we have 100 keys => time is O(1) and space is also O(1) 2. If 99% of all integer numbers from the stream are in the range [0, 100], how would you optimize your solution? I think 2 TreeMaps still work without changing in this case. But time and space complexity is the same as the original problem. What do you think?

that's fucking beautiful