Hi Codeforces!
Have you ever had this issue before?
If yes, then you have come to the right place! This is a blog about my super easy to use template for (reroot) DP on trees. I really believe that this template is kind of revolutionary for solving reroot DP problems. I've implemented it both in Python and in C++ (the template supports Python2
, Python3
and >= C++14
). Using this template, you will be able to easily solve > 2000 rated reroot problems in a couple of minutes, with a couple of lines of code.
A big thanks goes out to everyone that has helped me by giving feedback on blog and/or discussing reroot with me, nor, meooow, qmk, demoralizer, jeroenodb, ffao. And especially a huge thanks goes to nor for helping out making the C++ version of the template.
1. Introduction / Motivation
As an example, consider this problem: 1324F - Maximum White Subtree. The single thing that makes this problem difficult is that you need for every node $$$u$$$ find the maximum white subtree containing $$$u$$$. Had this problem only asked to find the answer for a specific node $$$u$$$, then a simple dfs solution would have worked.
But 1324F - Maximum White Subtree requires you to find the answer for every node. This forces you to use a technique called rerooting. Long story short, it is a mess to code. Maybe you could argue that for this specific problem it isn't all that bad. But it is definitely not as easy to code as the dfs solution above.
What if I told you that it is possible to take the logic from the dfs function above, put it inside of a "black box", and get the answer for all $$$u$$$ in $$$O(n \log n)$$$ time? Well it is, and that is what this blog is all about =)
In order to extract the logic from the simple dfs solution, let us first create a generic template for DP on trees and implement the simple dfs solution using its interface. Note that the following code contain the exact same logic as the simple dfs solution above. It solves the problem for a specific node $$$u$$$.
Now, all that remains to solve the full problem is to switch out the treeDP
function with the ultimate reroot template. The template returns the output of treeDP
for every node $$$u$$$, in $$$O(n \log n)$$$ time! It is just that easy. 240129139
The takeaway from this is example is that the reroot template makes it almost trivial to solve complicated reroot problems. For example, suppose we modify 1324F - Maximum White Subtree such that both nodes and edges have colors. Normally this modification would be complicated and would require an entire overhaul of the solution. However, with the ultimate reroot template, the solution is simply:
2. Collection of reroot problems and solutions
Here is a collection of reroot problems on Codeforces, together with some short and simple solutions in both Python and C++ using the rerooter
template. These are nice problems to practice on if you want to try out using this template. The difficulty rating ranges between 1700 and 2600. I've also put together a GYM contest with all of the problems: Collection of Reroot DP problems (difficulty rating 1700 to 2600).
Python 240150642, C++ 240130674, 219D - Choosing Capital for Treeland
Python 240150668, C++ 240130635, 543D - Road Improvement
Python 240150708, C++ 240130592, 627D - Preorder Test
Python 240150734, C++ 240130838, 852E - Casinos and travel
Python 240150756, C++ 240130918, 960E - Alternating Tree
Or alternatively using "edge DP": Python 240150781, C++ 240131037
Python 240150804, C++ 240131105, 1092F - Tree with Maximum Cost
Python 240150829, C++ 240131161, 1182D - Complete Mirror
Python 240150852, C++ 240131416, 1187E - Tree Painting
Python 240150867, C++ 240131453, 1324F - Maximum White Subtree
Python 240150889, C++ 240131551, 1498F - Christmas Game
Python 240150910, C++ 240131643, 1626E - Black and White Tree
Python 240150929, C++ 240131727, 1691F - K-Set Tree
Python 240150943, C++ 240131762, 1881F - Minimum Maximum Distance
3. Understanding the rerooter
black box
The following is the black box rerooter
implemented naively:
rerooter
outputs three variables.
rootDP
is a list, whererootDP[node] = dfs(node)
.forwardDP
is a list of lists, whereforwardDP[node][eind] = dfs(nei, node)
, wherenei = graph[node][eind]
.reverseDP
is a list of lists, wherereverseDP[node][eind] = dfs(node, nei)
, wherenei = graph[node][eind]
.
If you don't understand the definitions of rootDP
/forwardDP
/reverseDP
, then I recommend reading the naive $$$O(n^2)$$$ implementation of rerooter
. It should be fairly self explanatory.
The rest of this blog is about the techniques of how to make rerooter
run in $$$O(n \log n)$$$. So if you just want to use rerooter
as a black box, then you don't have to read or understand the rest of this blog.
One last remark. If you've ever done rerooting before, you might recall that rerooting usually runs in $$$O(n)$$$ time. So why does this template run in $$$O(n \log n)$$$? The reason for this is that I restrict myself to use the combine
function in a left folding procedure, e.g. combine(combine(combine(nodeDP, neiDP1), neiDP2), neiDP3)
. My template is not allowed to do for example combine(nodeDP, combine(neiDP1, combine(neiDP2, neiDP3)))
. While this limitation makes the template run slower, $$$O(n \log n)$$$ instead of $$$O(n)$$$, it also makes it a lot easier to use the template. If you still think that the $$$O(n)$$$ version is superior, then I don't think you've understood how nice and general the $$$O(n \log n)$$$ version truly is.
4. Rerooting and exclusivity
The general idea behind rerooting is that we first compute the DP as normal for some arbitrary node as the root (I use node = 0
for this). After we have done this we can "move" the root of the tree by updating the DP value of the old root and the DP value of a neighbour to the old root. That neighbour then becomes the new root.
Let $$$u$$$ denote the current root, and let $$$v$$$ denote the neighbour of $$$u$$$ that we want to move the root to. At this point, we already know the value of dfs(v, u)
since $$$u$$$ is the current root. But in order to be able to move the root from $$$u$$$ to $$$v$$$, we need to find the new DP value of $$$u$$$, i.e. dfs(u, v)
.
If we think about this in terms of forwardDP
and reverseDP
, then we currently know forwardDP[u]
, and our goal is to compute reverseDP[u]
. This can be done naively in $$$O(\text{deg}(u)^2)$$$ time with a couple of for loops by calling combine
$$$O(\text{deg}(u)^2)$$$ times, and then calling finalize
$$$O(\text{deg}(u))$$$ times.
The bottle neck here are the $$$O(\text{deg}(u)^2)$$$ calls to combine
. So for now, let us separate out the part of the code that calls combine
from the rest of the code into a function called exclusive
. The goal of the next section will then be to speed up the naively implemented exclusive
function to run in $$$O(\text{deg}(u) \text{log} (\text{deg}(u)))$$$ time.
5. The exclusive segment tree
We are almost done implementing the fast reroot template. The only operation left to speed up is the function exclusive
. Currently it runs in $$$O(\sum \text{deg}^2)$$$ time. The trick to make exclusive
run in $$$O(\sum \text{deg} \log{(\text{deg})})$$$ time is to create something similar to a segment tree.
Suppose you have a segment tree where each node in the segment tree accumulates all of the values outside of its interval. The leaves of such a segment tree can then be used as the output of exclusive
. I call this data structure the exclusive segment tree.
The exclusive segment tree is naturally built from top to bottom, taking $$$O(n \log n)$$$ time. Here is an implementation of rerooter
using the exclusive segment tree:
This algorithm runs in $$$O(\sum \text{deg} \log{(\text{deg})})$$$, so we are essentially done. However, this implementation uses recursive DFS which especially for Python is a huge drawback. Recursion in Python is both relatively slow and increadibly memory hungry. So for a far more practical version, I've also implemented this same algorithm using a BFS instead of a DFS. This gives us the final version of the ultimate rerooter
template!