dmkz's blog

By dmkz, history, 6 years ago, translation, In English

UPD: while I was translating this post from Russian to English, dacin21 wrote his post, more advanced, link. I hope that my post will help beginners, but in my post more rough estimates.

And in Russia we call rolling hashes as a polynomial hashes.

Hello, codeforces! This blogpost is written for all those who want to understand and use polynomial hashes and learn how to apply them in solving various problems. I will briefly write the theoretical material, consider the features of the implementation and consider some problems, among them:

  1. Searching all occurrences of one string of length n in another string length m in O(n + m) time

  2. Searching for the largest common substring of two strings of lengths n and m (n ≥ m) in O((n + m·log(n))·log(m)) and O(n·log(m)) time

  3. Finding the lexicographically minimal cyclic shift of a string of length n in O(n·log(n)) time

  4. Sorting of all cyclic shifts of a string of length n in lexicographic order in O(n·log(n)2) time

  5. Finding the number of sub-palindromes of a string of length n in O(n·log(n)) time

  6. The number of substrings of string of length n that are cyclic shifts of the another string length m in O((n + mlog(n)) time

  7. The number of suffixes of a string of length n, the infinite extension of which coincides with the infinite extension of the given string for O(n·log(n)) (extension is a duplicate string an infinite number of times).

  8. Largest common prefix of two strings length n with swapping two chars in one of them O(n·log(n))

Note 1. It is possible that some problems can be solved more quickly by other methods, for example, sorting the cyclic shifts — this is exactly what happens when constructing a suffix array, to search for all occurrences of one string in another will allow the Knut-Morris-Pratt algorithm, the Manaker algorithm works well with the sub-palindromes, and for own suffixes there is a prefix function.

Note 2. In the problems above, an estimate is made when a hash search is performed by sorting and binary searching. If you have your own hash table with open mixing or overflow chains, then you — lucky, boldly replace the hash search for a search in your hash table, but do not try to use std::unordered_set, as in practice the search in std::unordered_set loses sorting and binary search in connection with the fact that this piece obeys the C++ standard and has to guarantee a lot to the user, which is useful for industrial coding and, often, is useless in the competitive programming, so sorting and binary search for simple structures gain absolute primacy in C++ in speed of work , if not used additional own structures.

Note 3. In cases where comparison of elements is slow (for example, comparison by hash in O(log(n)) time), in the worst case std::random_shuffle + std::sort always loses std::stable_sort, because std::stable_sort guarantees the minimum number of comparisons among all sorts (based on comparisons) for the worst case.

The solution of the listed tasks will be given below, the source codes also.

As advantages of polynomial hashing I can notice that you often do not need to think, you can immediately take and write a naive algorithm to solve the problem and speed it up with polynomial hashing. Personally, firstly, I think about solution with a polynomial hash, perhaps that's why I'm blue.

Among the disadvantages of polynomial hashing: a) Too many operations getting remainder from the integer division, sometimes on the border with TLE for large problems, and b) on the codeforces in C++ programs are often small guarantees against hacking due to MinGW: std::random_device generates the same number every time, std::chrono::high_resolution_clock ticks in microseconds instead of nanoseconds. (The Cygwin compiler for windows wins against MinGW).

`UPD`: Solved а)
`UPD`: Solved b)

What is polynomial hashing?

Hash-function must assign to the object a certain value (hash) and possess the following properties:

  1. If two objects are equal, then their hashes are equal.

  2. If two hashes are equal, then the objects are equal with a high probability.

A collision is the very unpleasant situation of equality of two hashes for not equal objects. Ideally, when you choose a hash function, you need to ensure that probability of collision lowest of possibles. In practice — just a probability to successfully pass a set of tests to the task.

There are two approaches in choosing a function of a polynomial hash that depend on directions: from left to right and from right to left. To begin with, consider the option from left to right, and below, after describing the problems that arise in connection with the choice of the first option, consider the second.

Consider the sequence {a0, a1, ..., an - 1}. Under the polynomial hash from left to right for this sequence, we have in mind the result of calculating the following expression:

Here p and m — point (or base) and a hash module, respectively.

The conditions that we will impose: , .

Note. If you think about interpreting the expression, then we match the sequences {a0, a1, ..., an - 1} number of length n in the number in system with base p and take the remainder from its division by the number m, or the value of the polynomial (n - 1)-th power with coefficients ai at the point p modulo m. We'll talk about the choice of p and m later.

Note. If the value of (not by modulo), is placed in an integer data type (for example, a 64-bit type), then each sequence can be associated with this number. Then the comparison by greater / less / equal can be performed in O(1) time.

Comparison by equal in O(1) time

Now let's answer the question, how to compare arbitrary segments of sequence for O(1)? We show that to compare the segments of given sequence {a0, a1, ..., an - 1}, it is sufficient to compute the polynomial hash on each prefix of the original sequence.

Define a polynomial hash on the prefix as:

Briefly denote as and keep in mind that the final value is taken modulo m. Then:

General form:

The polynomial hash on each prefix can be calculated in O(n) time, using recurrence relations:

Let's say we need to compare two substrings that begin with i and j and have the length len, for equality:

Consider the differences and . It's not difficult to see that:

We multiply the first equation by pj, and the second by pi. We get:

We see that on the right-hand side of the expressions in brackets polynomial hashes were obtained from the segments of sequence:

Thus, in order to determine whether the required segments of sequence have coincided, we need to check the following equality:

One such comparison can be performed in O(1) time, assuming the degree of p modulo precalculated. With the module m, we have:

Problem: Comparing one segment of sequence depends on the parameters of the other segment of sequence (from j).

The first solution of this problem (given by veschii_nevstrui) is based on multiplying the first equation by p - i, and the second by p - j. Then we get:

We can see that in the right-hand parts of equations we get a polynomial hash from the needed segments of sequence. Then, the equality is checked as:

To implement this, we need to find the inverse element for p modulo m. From the condition gcd(p, m) = 1, the inverse element always exists. To do this, we need calculate or just know the value of the Euler function for the selected module φ (m) and get power φ(m) - 1 for p. If we precalculate the powers of the inverse element for the selected module, then the comparison can be performed in O(1) time.

The second solution we can use if we know the maximum lengths of compared segments of sequences. Let's denote the maximum length of compared lines as . We multiply 1-th equation by power mxPow - i - len + 1 of p, and 2-nd equation by mxPow - j - len + 1 power of p. We get:

We can note that on the right-hand sides of equals a polynomial hash of segments of sequence. Then, the equality is checked as follows:

This approach allows you to compare one substring of length len with all substrings of length len by equality, including substrings of another string, since the expression for the substring of the length len starting at the position i, depends only on the parameters of the current substring i, len and constant mxPow, and not from the parameters of another substring.

Now consider another approach for choosing polynomial hash function. Define a polynomial hash on the prefix as:

Briefly denote as and keep in mind that the final value is taken modulo m. Then:

The polynomial hash on each prefix can be calculated in O(n) time, using recurrence relations:

Let's say we need to compare two substrings that begin with i and j and have the length len, for equality:

Consider the differences and . It's not difficult to see that:

We see that on the right-hand side of the expressions in brackets polynomial hashes were obtained from the segments of sequence:

Thus, in order to determine whether the required segments of sequence have coincided, we need to check the following equality:

One such comparison can be performed in O(1) time, assuming the degree of p modulo m precalculated.

Comparison by greater / less in O(log(n)) time

Consider two substrings of (possibly) different strings of lengths len1 and len2, (len1 ≤ len2), starting in the positions i and j respectively. Note that the ratio greater / less is determined by the first non-equal symbol in these substrings, and before this position strings are equal. Thus, we need to find the position of the first non-equal symbol by the binary search method, and then compare the found symbols. By comparing substrings to equality in O(1) time, we can solve the problem of comparing substrings by greater / less in O(log(len1)) time:

Pseudocode

Minimizing the probability of collision

Using approximations in birthday problem, we get (perhaps a rough) estimate of the probability of collision. Suppose we compute a polynomial hash modulo m and, during the program, we need to compare n strings. Then the probability that the collision will occur:

Hence it is obvious that m needs to be taken much more than n2. Then, approximating the exponential as Taylor series, we get the probability of collision on one test:

If we look at the problem of searching of occurrences of all cyclic shifts of one row in another string of lengths to 105, then we can get 1015 comparisons of strings.

If we take a prime modulo of the order 109, then we will not go through any of the maximum tests.

If we take a module of the order 1018, then the probability of collision on one test is  ≈ 0.001. If the maximum tests are 100, the probability of collision in one of the tests is  ≈ 0.1, that is 10%.

If we take the module of the order 1027, then on the 100 maximum tests the probability of collision is  ≈ 10 - 10.

Conclusion: the higher the value of module, the more likely that we must pass the test. This probability not includes estimate probability of hack your solution.

Double polynomial hash

Of course, in real programs we can not take modules of the order 1027. How to be? To the aid comes the Chinese theorem on the remainders. If we take two mutually simple modules m1 and m2, then the ring of residues modulo m = m1·m2 is equivalent to the product of rings modulo m1 and m2, i.e. there is biection between them, based on the idempotents of the residue ring modulo m. In other words, if you calculate modulo m1 and modulo m2, and then compare two segments of sequence with and simultaneously, then this is equivalent to comparing a polynomial hash modulo m. Similarly, we can take three mutually prime modules m1, m2, m3.

Features of the implementation

So, we came to the implementation of the above. Goal — the minimum of the number of the remainder calculation from the integer division, i.e. get two multiplications in a 64-bit type and one take the remainder from division in 64-bit type for one calculation of a double polynomial hash, get a hash modulo about 10^27 and protect the code from hacking on сodeforces

Selection of modules. It is advantageous to use a double polynomial hash on the modules m1 = 1000000123 and m2 = 2^64. If you do not like this choice of m1, you can select 1000000321 or 2^31-1, the main thing is to choose such a prime number so that the difference of the two residues lies within the signed 32-bit type (int). A prime number is more convenient, since the conditions gcd(m1, m2) = 1 andgcd(m1, p) = 1 are automatically provided. The choice of m2 = 2^64 is not accidental. The C++ standard ensures that all calculations in the unsigned long long are executed modulo 2^64 automatically. Separately, the module 2^64 can not be taken, because there is an anti-hash test, which does not depend on the choice of the hash pointp. The module m1 should be specified as constant to speed up the taking the remainder (the compiler (not MinGW) optimizes, replacing by multiplication and bitwise shifting).

Sequence encoding. If given a sequence of characters, consisting, for example, of small Latin letters, then you not need to encode anything, because each character already corresponds to its code. If a sequence of integers is given that is reasonable for a representation in memory of length, then it is possible to collect all the occurring numbers into one array, sort, delete the repeats and assign to each number in the sequence its index in sorted set. Code zero is forbidden: all sequences of the form 0,0,0, .., 0 of different length will have the same polynomial hash.

Choosing of the base. As the base p it suffices to take any odd number satisfying the condition max(a[i]) < p < m1. (odd, because then gcd(p, 2 ^ 64) = 1). If you can be hacked, then it is necessary to generate p randomly with every new program start, and generation with std::srand(std::time(0)) and std::rand() is a bad idea, because std::time(0) ticks very slowly, and std::rand() does not provide enough uniformity. If the compiler is not MINGW (unfortunately, MinGW is installed on the codeforces), then you can use std::random_device, std::mt19937, std::uniform_int_distribution<int> (in cygwin on windows and gnu gcc on linux this set provides almost absolute randomness). If you were unlucky and you use only MinGW, then there is nothing left to do but replace std::random_device with std::chrono::high_resolution_clock and hope for the best (or is there a way to get some counter from the processor?). On MinGW, this timer ticks in microseconds, on cygwin and gnu gcc in nanoseconds.

Warranties against hacking. Odd numbers up to a module of the order of 10^9 are also of the order of 10^9. The cracker will need to generate an anti-hash test for each odd number so that there is a collision in the space to 10^27, compile all the tests into one big test and hack you! This is if you do not use MinGW on Windows. On MinGW, the timer is ticking, as already mentioned, in microseconds. Knowing when solution was started on the server with an accuracy of seconds, it is possible for each of the 10^6 microseconds to calculate what random p was generated, and then the number of variants in the 1000 times less. If 10^9 is some cosmic number, then 10^6 already seems not so safe. If you use std::time (0) only 10^3 number of variants (milliseconds) — can be hacked! In the comments I saw that grandmasters know how to break a polynomial hash modulo ot order of 10^36.

Ease of use. It is convenient to write a universal object for a polynomial hash and copy it to the task where it might be needed. It is better to write independently for your needs and goals in the style in which you write to understand the source code if necessary. All problems in this post are solved by copying the one class object. It is possible that there are specific tasks in which this does not work.

UPD: To speed up programs, you can quickly calculate the remainder of the divisions by modules 231 - 1 and 261 - 1. The main difficulty is multiplication. To understand the principle, look at this post by dacin21 in Larger modulo and his comment.

Mult mod `2^61-1`
Problem 1. Searching all occurrences of one string of length n in another string length m in O(n + m) time
Problem 1 statement in English

Link on problen on acmp.ru.

Solution and code
Problem 2. Searching for the largest common substring of two strings of lengths n and m (n ≥ m) in O((n + m·log(n))·log(m)) and O(n·log(m)) time

Link on problem on acm.timus.ru with length 10^5.

Link on problem on spoj.com with length 10^6.

Solution and code
Problem 3. Finding the lexicographically minimal cyclic shift of a string of length n in O(n·log(n)) time
Problem 3 statement in English

Link on problem 3

Solution and code
Problem 4. Sorting of all cyclic shifts of a string of length n in lexicographic order in O(n·log(n)2) time
Problem 4 statement in English

Link on problem 4

Note
Solution and code
Problem 5. Finding the number of sub-palindromes of a string of length n in O(n·log(n)) time
Problem 5 statement in English

Link on problem 5 with length 10^5

Link on problem 5 with length 10^6

Solution and code
Problem 6. The number of substrings of string of length n that are cyclic shifts of the another string length m in O((n + mlog(n)) time
Problem 6 statement in English

Link on problem 6

Solution and code
Problem 7. The number of suffixes of a string of length n, the infinite extension of which coincides with the infinite extension of the given string for O(n·log(n)) (extension is a duplicate string an infinite number of times).
Problem 7 statement in English

Link on problem 7

Solution and code
Problem 8. Largest common prefix of two strings length n with swapping two chars in one of them in O(n·log(n)) time

Link on problem

You can check the editorial written by a_kk and smokescreen on this site for getting solution without hashes in O(n) time.

Solution and code

That's all. I hope this post will help you to apply hashing and solve more difficult problems. I will be glad to any comments, corrections and suggestions from you. Share other problem and, possibly, your solutions, solutions without hashes. Thank you for reading this tutorial! There are many useful comments in russian under this blogpost, if you want, you can check them with google translate.

Links:

Rolling Hash (Rabin-Karp Algorithm)

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6 years ago, # |
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Awsome blog :D

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    6 years ago, # ^ |
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    Thanks, I not added problem from your contest, I'm sorry, I will add this

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    6 years ago, # ^ |
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    Added your problem and my solution as a Problem 8

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      6 years ago, # ^ |
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      feeling honoured(:p) after u mentioned our problem XD!!

      Although while making the problem I was sure a solution with binary search exits for this problem but the closest we can get to a binary search solution was this : solution which is surely wrong (:p).

      Now after learning rolling hash, will try to implement your solution :).

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        6 years ago, # ^ |
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        Please add a anti-hash test against single modulo 264 for your problem. Special generator for your problem. My old accepted solution with single hash gets wrong answer on this test.

        Single hash answer = 130048 - WRONG ANSWER
        Double hash answer = 2      - OK
        

        UPD: added, now solution with 264 gets wrong answer

        And in this problem it is necessary to generate more (maybe random) tests with length 200000 and not-zero LCP, because single integer mod ~109 accepted. For example, in problem 6 46 tests, so solution with random single hash ~10^9 to this problem gets wrong answer.

        UPD: I generated 100000 random tests with length 200000 and no one collision for single modulo with random point.

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6 years ago, # |
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Can you please explain the method used in problem 3 with some examples and pseudo-code? I'm not able to understand the method of Comparison by greater / less in O(log(n)) time.

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    6 years ago, # ^ |
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    Example for string `aaaaab`

    I write substring as pair of position of start i and length of substring len because we can compare this pairs by equal in O(1) with polynomial hashes. I hope that this example can helpful for you to understand this technique

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6 years ago, # |
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This question : QQ is same as problem 2. But here i'm getting TLE. Submission. Any suggestions?

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    6 years ago, # ^ |
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    Solution has 10^6*log2(10^6)^2 ~=~ 4*10^8 operaions in worst case, no way gets accepted with std::map.

    `std::map` is slowest way in C++ to find something in `O(log(n))`

    You need to write your own hashtable to getting O(n*log(n)) solution with O(1) time per search

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      6 years ago, # ^ |
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      Actually it will depend on the range of elements of the array.

      (Assuming the number are uniformly distributed in the array).

      Let say size of array is N = 1e6 and range of elements is 1 to 1e9, then surely sort + binary_search is a better option.

      But if N = 1e6 and range of elements is 1 to 1e4 than std::map will beat sort + binary_search.

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        6 years ago, # ^ |
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        I still think that sort + unique + binary search will beat std::map. Do you have any experiment?

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    6 years ago, # ^ |
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    Note that we are very close in time. We can solve this problem if we introduce new symbols of fixed width. Note that each character can take four different values. We can combine adjacent characters and encode them as one. For example, if we combine four characters, we will make 4 * 4 * 4 * 4 = 256 different combinations. We will convert the string in this way and find the maximum length in this case. Let this be max1. Then we convert back and look for 4 * max1 to 4 * max1 + 7.

    UPD: This improvement led to a solution in O(n log(n)^2) with smaller constant. Accepted on SPOJ, code. On ideone.com 0.83s time (just uncomment gen in line 148 for getting it)

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6 years ago, # |
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Can you help me with this problem ?

Given a string s of length <= 10^5 and Q <= 10^5 queries , In each query you have to consider a sub-string from index L to R and print number of palindromic sub-strings of the query string .

I know the hash based approach for finding the number of palindromic sub-strings of a given string but I am not able to extend the logic for handling queries .

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    6 years ago, # ^ |
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    I think that it can be solved with palindromic tree. Maybe with hashes too, but I don't know how.

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      6 years ago, # ^ |
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      Yes It can be solved using that also but I think there exist a solution which is hash based and make use of bit/ segment tree for handling range queries.It will be a great help if you can tell me that solution

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    6 years ago, # ^ |
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    I have an offline solution in O(n * log(n) + q * log(n)).

    Pass i in decreasing order. Let k be the longest odd palindrome with center on i computed as problem 5. On a segment tree add 1 on every position on range [i-k+1, i]. Do the same for even length palindromes(center on i and i+1). Then we can answer a query [L, R] such that L = i by doing range sum query on the segment tree on range [L, R].

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      6 years ago, # ^ |
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      Please tell in more detail how you will answer on query?

      index: 0123456789
      array: aabbababba - input string
        odd: 1111252111 - max len of odd palindrome with center i
       even: 1020000200 - max len of even palindrome with center {i, i+1}
      -----------------
      total: 2333232111 - after applying all queries of increment on segments
      
      Query: [l = 2, r = 3] - how we can get answer 3 with segment tree? Sum on range is 6.
      
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6 years ago, # |
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I think the complexity of problem 2 is O((n + m * log(n)) * log(m))

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    6 years ago, # ^ |
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    Changed, thanks

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      6 years ago, # ^ |
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      I think you have to change it also in a russian version.

      Actually, I believe that we could reach asymptotics with hashtable (but not STL version, it's kinda slow). As far as I remember I had something like 3-4 times boost (maybe even more) with hashtable.

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        6 years ago, # ^ |
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        Can you, please, solve this problem with hashtable? I tried, but my hash table did not win against a accepted binary search

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          6 years ago, # ^ |
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          Well, I have two different variants of hashtables (with separate chaining and open adressing). Both got AC, but actually I needed to make some fixes because of size (first, I forgot about alphabet, then I forgot about size). But after this fixing separate chaining hashtable was good. Open adressing hashtable had some troubles with time before I changed the size of table up to 4·106 + 37. Finally I have 22ms (I hope it is ms) with open adressing hashtable and up to 15.97ms (with some experiments, my first result was 17.31ms) with separate chaining one.

          I don't think that my hashtable is the fastest in the world, but here is my old-but-gold code, maybe you are interested: https://ideone.com/hxlvr0

          UPD: I also have TL with binary search, so I think I can improve my code performance by changing the algorithm of string hashing.

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            6 years ago, # ^ |
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            I passed the solution with binary search only after I reduced the hidden constant, compressing four characters into one. More in this comment

            I think that time in seconds — time of working on all test cases summary. For example, my binary search solution gets 19.19 time on SPOJ.

            Your solution takes 0.8 seconds on ideone.com on test 10^6 len, this is very fast hashtable, thanks! My solution with hashtable on this test takes 2.5 seconds, with binary search 1.6 seconds, with compressing 4 chars to 1 and binary search 0.66 seconds.

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              6 years ago, # ^ |
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              Maybe your implementation of hashtable uses something like vector<vector<...> > that can slow down solution because of memory allocations/deallocations.

              My implementation uses something like linked lists stored in continuous section of memory without changing the size so it could allocate it once and then just reuse it.

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                6 years ago, # ^ |
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                Thanks! I passed a problem with my open addressed hash table based on std::array. Code.

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                  6 years ago, # ^ |
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                  Now you can change the asymptotics of the problem 2 :)

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6 years ago, # |
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Added rolling hash right-to-left and code for fast multiplication of remainders modulo 261 - 1 with link to the author

Добавлен полиномиальный хэш справа-налево и код для быстрого вычисления остатка по модулю 261 - 1 после умножения двух остатков со ссылкой на автора

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    6 years ago, # ^ |
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    Hi @dmkozyrev

    In the second solution for rolling hash. You have mentioned that on both sides we need to multiply by MaxPow — i — len + 1. Do you think we can skip even len also, and make it MaxPow — i + 1 ? Because anyhow if both the substrings are of same len, we can check the equality without len also.

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      6 years ago, # ^ |
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      Yes, your approach — fixing least power of base in hash, and it's working

      Example
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".. we take a module of the order 10^18, then the probability of collision on one test is  ≈ 0.001. If the maximum tests are 100, the probability of collision in one of the tests is  ≈ 0.1, that is 10%."

If the probability of collision on one test is 0.001, isn't the probability of at least one collision in 100 tests = 1 — (0.999)^100 ?

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    6 years ago, # ^ |
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    I used Taylor Series. When $$$n$$$ is large, but $$$p$$$ is small, we can just multiply $$$p$$$ by $$$n$$$:

    $$$\text{}$$$
    $$$1-(1-p)^n \approx 1 - (1 - n \cdot p + O(p^2)) \approx n \cdot p + O(p^2)$$$

    Lets calculate original formula in wolfram:

    $$$1 - (1-0.001)^{100} \approx 0.095$$$

    From Taylor approximation we got:

    $$$n \cdot p +O(p^2) \approx 0.1$$$
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5 years ago, # |
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How Can I Find The the Kth Lexicographical Minimum Substring of a given string S ??

Please help....

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5 years ago, # |
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Images disappear now

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    5 years ago, # ^ |
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    :( for a while, I was solving this task and the images were not loaded i thought it was my network problem but now I understand that it is something wrong with the website. Still Solved it using pen and paper ;)

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5 years ago, # |
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Thanks for the informative post. Regarding the definition of $$$hash(a,p,m)$$$, I can see why we make the assumptions:

  1. no character maps to 0: we don't want to say all of "", "a", "aa", etc., have the same polynomial value.
  2. $$$max(a_i) < p$$$: this way every string maps to a unique polynomial value, BEFORE taking the modulus
  3. $$$gcd(p,m) = 1$$$: because if $$$d|p$$$ and $$$d|m$$$, then all strings $$$a_0+a_1p + a_2 p^2+\cdots + a_{n-1}p^{n-1}$$$ starting with the letter $$$a_0$$$ are in the same residue class with respect to $$$d$$$, (hence they will be in at most $$$m/d$$$ residue classes with respect to $$$m$$$), instead of uniformly distributed.

However, what is the reason for assuming $$$p<m$$$?

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    5 years ago, # ^ |
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    If $$$p = m$$$, then hash is equal to value of $$$a_0$$$. If $$$p = m+1$$$, then hash is equal to $$$a_0 + a_1 + ... + a_{n-1}$$$. If $$$p = m + k$$$, then $$$p = k \text{ mod } m$$$. So, we can use just $$$p < m$$$ and it will be as good as $$$p = m + k > m$$$.

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5 years ago, # |
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dmkz great-great tutorial, thx :)

I don't really get the part with collision probability estimation. Can anyone suggest some literature?

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4 years ago, # |
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Thansk bro very very much, I was looking for such a hashing tutorial.

I was solving this problem using hashing but hash was not good enough, but after reading this tutorial I was finally able to solve it.

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3 years ago, # |
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I have a slightly more optimized version of the $$$2^{61}-1$$$ modulus multiplication:

constexpr uint64_t mod = (1ull<<61) - 1;
uint64_t modmul(uint64_t a, uint64_t b){
	uint64_t l1 = (uint32_t)a, h1 = a>>32, l2 = (uint32_t)b, h2 = b>>32;
	uint64_t l = l1*l2, h = h1*h2;
        uint64_t m = (l1 + h1) * (l2 + h2) - l - h; // note 1
	uint64_t ret = (l + (m << 32)) & mod; // note 2
	ret += (((l >> 32) + m) >> 29) + (h << 3) + 1; // note 3
	ret = (ret & mod) + (ret>>61); // note 4
	return ret-1;
}

note 1: Karatsuba's technique, saving one multiplication at the cost of three additive operations

note 2: get low 61 bits of product

note 3: add high 61 bits of product. Small adaptation of the classic multiplyHigh algorithm. Also add the +1 fudge factor to help reduction

note 4: only one reduction needed, as high 61 bits can't be all ones

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2 years ago, # |
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Sorry for necroposting but actually for the problem Lexicographically Minimal String Rotation, I actually found a way myself to only need $$$O(n \log \log n)$$$ complexity, I called it as Logarithm Decomposition. But for this the LMSR problem, I still think $$$O(n)$$$ Lyndon-Duval Algorithm and my $$$O(n)$$$ Subaru Trick is simple and fast to be coded.

I tried to research the problem for few days and still not know whether or not the hashing only by itself can be used to solve the LMSR problem in $$$O(n \log \log \log n)$$$ or similar. (What I mean is that if I apply Hash to any of my 3 solutions $$$O(n \log n)$$$ Subaru Trick then it will be $$$O(n)$$$ but the constant is high enough that is just not even worth it)