Notes on FFT / NTT, and the "ultimate" NTT with modulus >= 9 * 10^18

Revision en9, by Spheniscine, 2020-03-29 11:07:23

Prerequisites: you need to be familiar with both modular arithmetic and Fast Fourier Transform / number theoretic transform. The latter can be a rather advanced topic, but I personally found this article helpful. Note that there are some relatively easy optimizations/improvements that can be done, like precalculating the modular inverse of $$$n$$$, the "bit-reversed-indices" (can be done in $$$O(n)$$$ with DP), as well as the powers of $$$\omega_n$$$. Also useful is modifying it so that the input array length can be any power of two $$$\leq n$$$; some problems require multiplying polynomials of many different lengths, and you'd rather the runtime be $$$O(n \log n)$$$ over the sums of lengths, rather than (number of polynomials * maximum capacity).

Also helpful is knowing how to use NTT to solve problems modulo $$$998244353$$$, like 1096G - Lucky Tickets and 1251F - Red-White Fence. Note that for some problems it's easier to think of FFT not as multiplying polynomials, but of finding multiset $$$C$$$ as the pairwise sums of multisets $$$A$$$ and $$$B$$$, in the form of arrays $$$A[i] =$$$ number of instances of $$$i$$$ in multiset $$$A$$$. This is equivalent to multiplying polynomials of the form $$$\sum _{i=0} ^n A[i]x^i$$$.

Note that $$$\omega_n$$$ can be easily found via the formula $$$g ^ {(m-1) / n} \ \text{ mod } m$$$, provided that:

  1. $$$m$$$ is prime
  2. $$$g$$$ is any primitive root modulo $$$m$$$. It is easiest to find this before hand and then hardcode it in the submission. You can either implement the algorithm yourself or use Wolfram Alpha to find it via the query PrimitiveRoot[m]. (Spoiler alert, $$$g = 3$$$ works well for $$$998244353$$$)
  3. $$$n$$$ divides $$$m-1$$$ evenly. As $$$n$$$ is typically rounded up to the nearest power of 2 for basic NTT implementations, this is easiest when $$$m$$$ is of the form $$${a \cdot 2^{k} + 1}$$$ where $$$2^k \geq n$$$. This is why $$$998244353$$$ is a commonly-appearing modulus; it's $$$119 \cdot 2^{23} + 1$$$. Note that this modulus also appears in many problems that don't require FFT/NTT; this is a deliberate "crying-wolf" strategy employed by puzzle writers, so that you can't recognize immediately that a problem requires FFT/NTT via the given modulus.

Now onto the main topic, the "ultimate" NTT.

Rationale: There are a few problems like 993E - Nikita and Order Statistics that require FFT, however the results aren't output with any modulus, and indeed may exceed the range of a 32-bit integer type. There are several usual solutions for solving this:

  1. Do NTT with two moduli and restoring the result via Chinese Remainder Theorem. This has several prominent disadvantages:
    1. Slow, as the NTT routine has to be done twice.
    2. Complicated setup, as several suitable moduli has to be found, and their primitive roots calculated
    3. Restoring the result with CRT requires either brute force or multiplications modulo $$$pq$$$, which may overflow even 64-bit integer types.
  2. Do FFT with complex numbers and floating point types. Disadvantages are:
    1. Could be slow due to heavy floating-point arithmetic. Additionally, JVM-based languages (Java, Kotlin, Scala) suffer complications here, as representing complex numbers with object-based tuples adds a significant overhead.
    2. Limited precision due to rounding error. Typically the problems are constructed such that it won't be a problem if care is taken in the implementation, but won't it be nice to just not to have to worry about it?

To solve these problems, I propose the "ultimate" NTT solution — just use one huge modulus. The one I use is $$$m = 9223372036737335297 = 54975513881 \cdot 2^{24} + 1, g = 3$$$. This is just over a hundred million less than $$$2^{63} - 1$$$, the maximum value of a signed 64-bit integer.

However, this obviously raises the issue of how to safely do modular arithmetic with such huge integers. Addition is complicated by possible overflow into the sign bit, thus the usual if(x >= m) x -= m won't work. Instead, first normalize $$$x$$$ into the range $$$[-m, m)$$$; this is easily done with subtracting $$$m$$$ after any addition operation. Then do x += (x >> 63) & m. This has the effect of adding $$$m$$$ to $$$x$$$ if and only if $$$x$$$ is negative.

The elephant in the room however is multiplication. The usual method requires computing a 126-bit product, then doing a modulo operation over a 63-bit integer; this could be slow and error-prone to implement. C++ users could rejoice, as Codeforces recently implemented support for 128-bit integers via this update. However, before you celebrate too early, there are still issues: this may not be available on other platforms, and I can't imagine that straight 128-bit modulo 64-bit is exactly the fastest operation in the world, so the following might still be helpful even to C++ users.

My favored technique for this problem is called Barrett reduction. The explanation is (adapted from this website)

  • Choose integer $$$k$$$ such that $$$2^k > n$$$. $$$k = 63$$$ works for our modulus.
  • Precompute $$$\displaystyle r = \left\lfloor \frac {4^k} n \right\rfloor$$$. For our modulus this is $$$9223372036972216319$$$, which just overflows a signed 64-bit integer. You can either store it as unsigned, or the as the signed 64-bit representation $$$-9223372036737335297$$$ (yes, this just happens to be $$$-m$$$, which is quite a neat coincidence)
  • Multiply the two integers. Note that we need all 126 bits of this product. The low bits can be easily obtained via straight multiplication, however the high bits need some bit-shifting arithmetic tricks to obtain. Adapt the following Java code, taken from here for your preferred language:
multiplyHighUnsigned code
  • Let the product be $$$x$$$. Then calculate $$$\displaystyle t = x - \left\lfloor \frac{xr}{4^k} \right\rfloor m - m$$$. This requires some adaptation of grade-school arithmetic; pseudocode in spoiler below. $$$t$$$ is guaranteed to be in the range $$$[-m, m)$$$, so the t += (t >> 63) & m trick should work to normalize it. In the following pseudocode, BARR_R $$$= r$$$ and MOD $$$= m$$$. Also, ^ represents bitwise xor, not exponentiation.
mulMod pseudocode

And that's it for this blogpost. This should be sufficient to solve most/all integer-based FFT problems in competitive programming. Note that if you need negative numbers in your polynomials, you can input them modulo $$$m$$$, then assume any integer in the output that exceeds $$$m/2$$$ is negative; this works as long as no number in the output has an absolute value greater than $$$m/2$$$, yet another advantage of using such a huge modulus.

Samples:

Tags fft, ntt, modular arithmetic

History

 
 
 
 
Revisions
 
 
  Rev. Lang. By When Δ Comment
en29 English Spheniscine 2022-10-02 02:28:33 1 Tiny change: '7 = 54975513881 \cdo' -> '7 = 549755813881 \cdo'
en28 English Spheniscine 2021-12-24 05:54:46 36
en27 English Spheniscine 2021-12-24 05:52:05 2 Tiny change: 'se (I use ($2^{16}$) in these ' -> 'se (I use $2^{16}$ in these '
en26 English Spheniscine 2021-12-24 05:51:30 2420 Tiny change: ' is a $192$nd root of u' -> ' is a $192\text{nd}$ root of u'
en25 English Spheniscine 2020-05-27 11:41:09 77
en24 English Spheniscine 2020-03-31 10:16:10 4 Tiny change: 'oiler>\n\nUpdate: I have fu' -> 'oiler>\n\n**Update:** I have fu'
en23 English Spheniscine 2020-03-31 09:25:52 254
en22 English Spheniscine 2020-03-29 17:07:51 1 Tiny change: 'at $2^k > m$. $k = 63' -> 'at $2^k > n$. $k = 63'
en21 English Spheniscine 2020-03-29 17:05:27 4
en20 English Spheniscine 2020-03-29 13:29:25 4 Tiny change: 'for basic NTT implemen' -> 'for basic FFT implemen'
en19 English Spheniscine 2020-03-29 12:55:03 74
en18 English Spheniscine 2020-03-29 12:50:51 615 Tiny change: 'deforces?) $a^2n$ in' -> 'deforces?). $a^2n$ in'
en17 English Spheniscine 2020-03-29 12:28:13 237
en16 English Spheniscine 2020-03-29 11:43:47 4 Tiny change: 'and restoring the resul' -> 'and restore the resul'
en15 English Spheniscine 2020-03-29 11:42:44 27 Tiny change: 'tions for solving this:\n\n1. D' -> 'tions for these types of problems:\n\n1. D'
en14 English Spheniscine 2020-03-29 11:39:56 1
en13 English Spheniscine 2020-03-29 11:25:24 1 Tiny change: 'm >>> 62))) * MOD -' -> 'm >>> 62)) * MOD -'
en12 English Spheniscine 2020-03-29 11:23:06 6 Tiny change: ', b: Long) {\n xh' -> ', b: Long): Long {\n xh'
en11 English Spheniscine 2020-03-29 11:19:34 6 Tiny change: 'le moduli has to be found,' -> 'le moduli must be found,'
en10 English Spheniscine 2020-03-29 11:17:17 586 Tiny change: 'em:993E]\n[submiss' -> 'em:993E]\n\n[submiss' (published)
en9 English Spheniscine 2020-03-29 11:07:23 1751 Tiny change: 'rac{xr}{4^63} \right' -> 'rac{xr}{4^{63} \right'
en8 English Spheniscine 2020-03-29 10:40:31 1482 Tiny change: 'age:\n public' -> 'age:\n public'
en7 English Spheniscine 2020-03-29 10:17:38 962
en6 English Spheniscine 2020-03-29 10:02:51 351 Tiny change: '2^{24} + 1$. This is' -> '2^{24} + 1, g = 3$. This is'
en5 English Spheniscine 2020-03-29 09:55:25 382 Tiny change: 'e problems I propose' -> 'e problems, I propose'
en4 English Spheniscine 2020-03-29 09:48:48 795 Tiny change: 'he result requires ' -> 'he result with CRT requires '
en3 English Spheniscine 2020-03-29 09:38:21 493 Tiny change: 'ating the "bit-' -> 'ating the modular inverse of $n$, the "bit-'
en2 English Spheniscine 2020-03-29 09:27:37 17 Tiny change: '(m-1) / n}$, provide' -> '(m-1) / n} \text{ mod } m$, provide'
en1 English Spheniscine 2020-03-29 09:26:30 2329 Initial revision (saved to drafts)