# Find the smallest regular number that is not less than N

Regular numbers are numbers that evenly divide powers of 60. As an example, 602 = 3600 = 48 × 75, so both 48 and 75 are divisors of a power of 60. Thus, they are also regular numbers.

This is an extension of rounding up to the next power of two.

I have an integer value N which may contain large prime factors and I want to round it up to a number composed of only small prime factors (2, 3 and 5)

Examples:

• `f(18) == 18 == 21 * 32`
• `f(19) == 20 == 22 * 51`
• `f(257) == 270 == 21 * 33 * 51`

What would be an efficient way to find the smallest number satisfying this requirement?

The values involved may be large, so I would like to avoid enumerating all regular numbers starting from 1 or maintaining an array of all possible values.

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What have you tried? Did you read the citations in the "Algorithms" section of the Wikipedia article you linked, or the related article on smooth numbers? –  Jordan Feb 11 '12 at 18:34
@Jordan yes, I am familiar with the lazy functional technique for generating all regular numbers (which could be used as a brute-force solution for my problem.) I also read the part about estimating the number of smooth numbers in a range. Do you think this might be useful here? If so feel free to put it in an answer! –  finnw Feb 11 '12 at 18:39
Also known as "Hamming numbers" "ugly numbers" and "5-smooth numbers". Useful for choose sizes of data to do FFTs on. –  endolith Sep 30 '13 at 19:11

Okay, hopefully third time's a charm here. A recursive, branching algorithm for an initial input of p, where N is the number being 'built' within each thread. NB 3a-c here are launched as separate threads or otherwise done (quasi-)asynchronously.

1. Calculate the next-largest power of 2 after p, call this R. N = p.

2. Is N > R? Quit this thread. Is p composed of only small prime factors? You're done. Otherwise, go to step 3.

3. After any of 3a-c, go to step 4.

a) Round p up to the nearest multiple of 2. This number can be expressed as m * 2.
b) Round p up to the nearest multiple of 3. This number can be expressed as m * 3.
c) Round p up to the nearest multiple of 5. This number can be expressed as m * 5.

4. Go to step 2, with p = m.

I've omitted the bookkeeping to do regarding keeping track of N but that's fairly straightforward I take it.

Edit: Forgot 6, thanks ypercube.

Edit 2: Had this up to 30, (5, 6, 10, 15, 30) realized that was unnecessary, took that out.

Edit 3: (The last one I promise!) Added the power-of-30 check, which helps prevent this algorithm from eating up all your RAM.

Edit 4: Changed power-of-30 to power-of-2, per finnw's observation.

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You forgot `m * 6` –  ypercube Feb 11 '12 at 18:43
In step 1, can you not use the next largest power of 2 instead of 30? –  finnw Feb 11 '12 at 19:40
@finnw Yes, you're right. Breaking my promise and editing accordingly. –  Matt Phillips Feb 11 '12 at 19:45
Have you implemented this? I have tried to follow how this algorithm will proceed when N=1025; The best solution is 1080 but I don't think it will find it. –  finnw Feb 12 '12 at 15:16
@finnw Admittedly not, but for your example the you'd get the following sequence: 1025 -> 1026 = 2 x 513 -> 514 = 2 x 257 -> 258 = 2 x 129 -> 129 = 3 x 43 -> 45 = 3 x 15 -> 15 = 3 x 5. Then N at this point = 2 x 2 x 2 x 3 x 3 x 3 x 5 = 1080. Key is that in some cases 'rounding up' is vacuous, if the factor is already present. Now there will be many paths generated and what your example makes me realize is that the first path to finish might not always have the smallest N. So I think you have to wait until all threads terminate, sort, and take the lowest. –  Matt Phillips Feb 12 '12 at 15:35

One can produce an arbitrarily thin slice of the Hamming sequence around n-th member in time `~ n^(2/3)` by direct enumeration of triples `(i,j,k)` such that `N = 2^i * 3^j * 5^k`.

WP says that `n ~ (log N)^3`, i.e. run time `~ (log N)^2`. Here we don't care for the exact position of the found triple in the sequence, so all the count calculations from the original code can be thrown away:

``````slice hi w = sortBy (compare `on` fst) b where       -- hi>log2(N) is a top value
lb5=logBase 2 5 ; lb3=logBase 2 3                  -- w<1 (NB!) is log2(width)
b  = concat                                        -- the slice
[ [ (r,(i,j,k)) | frac < w ]                   -- store it, if inside width
| k <- [ 0 .. floor ( hi   /lb5) ],  let p = fromIntegral k*lb5,
j <- [ 0 .. floor ((hi-p)/lb3) ],  let q = fromIntegral j*lb3 + p,
let (i,frac)=properFraction(hi-q) ;    r = hi - frac ]   -- r = i + q
``````

Having enumerated the triples in the slice, it is a simple matter of sorting and searching, taking practically `O(1)` time (for arbitrarily thin a slice) to find the first triple above `N`. Well, actually, for constant width (logarithmic), the amount of numbers in the slice (members of the "upper crust" in the `(i,j,k)`-space below the `log(N)` plane) is again `m ~ n^2/3 ~ (log N)^2` and sorting takes `m log m` time (so that searching, even linear, takes `~ m` run time then). But the width can be made smaller for bigger `N`s, following some empirical observations; and constant factors for the enumeration of triples are much higher than for the subsequent sorting anyway.

Even with constant width (logarthmic) it runs very fast, calculating the 1,000,000-th value in the Hamming sequence in a few hundredths of a second.

The original idea of "top band of triples" is due Louis Klauder, from DDJ discussion some years back.

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I wish I understood Haskell. :/ This looks superficially like the best answer. –  endolith Oct 3 '13 at 20:26
@endolith this here is very basic stuff. `f x y` is a function application, `f(x,y)`. the list comprehension `[x | p x]` is a list containing one `x` if `p(x)` is true; empty otherwise. list comprehension `[x | k <- [0..10], j<- [k..10], let x=k+j*42]` pulls each `k` from a range from 0 to 10, and for each k it pulls each `j` from a range from `k` to 10 (as if there were two nested loops there). `properFraction` is a built-in, for e.g. 3.14 it returns a pair `(3,0.14)`. `fst(a,b) == a` is another built-in. `concat` concatenates lists in a given list, to form one list: `[[1],[],[3]] --> [1,3]`. –  Will Ness Oct 3 '13 at 22:28
@endolith lastly, `fromIntegral i*x` is `fromIntegral(i) * x` is just `i*x`, where `i` is a value of some integer-like type, and `x` some floating type. `fromIntegral` is like a type cast; we aren't allowed to multiply an int and a double directly, in Haskell. so the algo goes from `log2(N) = i+j*log2(3)+k*log2(5)`; enumerates all possible `k`s and for each, all possible `j`s, finds the top `i` and thus the triple `(k,j,i)` and keeps it if inside the given "width" below the given `high` logarithmic top value (when `width < 1` there can be only one such `i`) then sorts them by their logvals. –  Will Ness Oct 3 '13 at 22:48
Does this produce the right output for n=11? I tried to do it on ideone and it outputs (0,1,1), which I think means 3*5=15, but the next regular number is 12 which would be (2,1,0) = 2^2*3. Also it's supposed to be the next regular number >= to n, but this seems to calculate the next regular number > n? –  endolith May 11 at 5:20
@endolith running that ideone entry with 11 as its input produces the 11-th number in the Hamming sequence, 1-based. Running it with a character 'a' as input produces first 20 elements in the sequence: [1,2,3,4,5,6,8,9,10,12,15,16,18,20,24,25,27,30,32,36]. As you can see, the 11-th number there is 15. –  Will Ness May 11 at 7:10

You want to find the smallest number `m` that is `m >= N` and `m = 2^i * 3^j * 5^k` where all `i,j,k >= 0`.

Taking logarithms the equations can be rewritten as:

`````` log m >= log N
log m = i*log2 + j*log3 + k*log5
``````

You can calculate `log2`, `log3`, `log5` and `logN` to (enough high, depending on the size of `N`) accuracy. Then this problem looks like a Integer Linear programming problem and you could try to solve it using one of the known algorithms for this NP-hard problem.

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NP-hard? Oh dear –  finnw Feb 11 '12 at 19:24
The transformated problem is (in general) NP-hard. This particular instance of the general Integer Programming problem may have nicer solutions. Or the original (non-tranformated) number theory problem may have nicer algorithm. –  ypercube Feb 11 '12 at 19:27
one can directly calculate a slice of the Hamming sequence near n-th member in n^(2/3) time with very low constant factor. WP gives correlation formula for n vs N as `log N ~ n^(1/3)`. This gives `n ~ (log N)^3` and time `~ (log N)^2`. –  Will Ness Aug 20 '12 at 16:41
I've added an answer to that effect. –  Will Ness Aug 20 '12 at 16:57

Here's another possibility I just thought of:

If N is X bits long, then the smallest regular number RN will be in the range
`[2X-1, 2X]`

e.g. if N = 257 (binary `100000001`) then we know R is `1xxxxxxxx` unless R is exactly equal to the next power of 2 (512)

To generate all the regular numbers in this range, we can generate the odd regular numbers (i.e. multiples of powers of 3 and 5) first, then take each value and multiply by 2 (by bit-shifting) as many times as necessary to bring it into this range.

In Python:

``````from itertools import ifilter, takewhile
from Queue import PriorityQueue

def nextPowerOf2(n):
p = max(1, n)
while p != (p & -p):
p += p & -p
return p

# Generate multiples of powers of 3, 5
def oddRegulars():
q = PriorityQueue()
q.put(1)
prev = None
while not q.empty():
n = q.get()
if n != prev:
prev = n
yield n
if n % 3 == 0:
q.put(n // 3 * 5)
q.put(n * 3)

# Generate regular numbers with the same number of bits as n
def regularsCloseTo(n):
p = nextPowerOf2(n)
numBits = len(bin(n))
for i in takewhile(lambda x: x <= p, oddRegulars()):
yield i << max(0, numBits - len(bin(i)))

def nextRegular(n):
bigEnough = ifilter(lambda x: x >= n, regularsCloseTo(n))
return min(bigEnough)
``````
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hi, I've added a new answer here that shows how to directly enumerate (i,j,k) triples in the narrow vicinity of log(N), which is very fast. –  Will Ness Aug 20 '12 at 17:19
actually, this is pretty close in its intention to what I posted, just differs in implementation. :) –  Will Ness Aug 22 '12 at 0:21
This fails for nextRegular(7), nextRegular(31), nextRegular(61), etc. with `ValueError: min() arg is an empty sequence` –  endolith Oct 6 '13 at 2:11

Here's a solution in Python, based on Will Ness answer but taking some shortcuts and using pure integer math to avoid running into log space numerical accuracy errors:

``````import math

def next_regular(target):
"""
Find the next regular number greater than or equal to target.
"""
# Check if it's already a power of 2 (or a non-integer)
try:
if not (target & (target-1)):
return target
except TypeError:
# Convert floats/decimals for further processing
target = int(math.ceil(target))

if target <= 6:
return target

match = float('inf') # Anything found will be smaller
p5 = 1
while p5 < target:
p35 = p5
while p35 < target:
# Ceiling integer division, avoiding conversion to float
# (quotient = ceil(target / p35))
# From http://stackoverflow.com/a/17511341/125507
quotient = -(-target // p35)

# Quickly find next power of 2 >= quotient
# See http://stackoverflow.com/a/19164783/125507
try:
p2 = 2**((quotient - 1).bit_length())
except AttributeError:
# Fallback for Python <2.7
p2 = 2**(len(bin(quotient - 1)) - 2)

N = p2 * p35
if N == target:
return N
elif N < match:
match = N
p35 *= 3
if p35 == target:
return p35
if p35 < match:
match = p35
p5 *= 5
if p5 == target:
return p5
if p5 < match:
match = p5
return match
``````

In English: iterate through every combination of 5s and 3s, quickly finding the next power of 2 >= target for each pair and keeping the smallest result. (It's a waste of time to iterate through every possible multiple of 2 if only one of them can be correct). It also returns early if it ever finds that the target is already a regular number, though this is not strictly necessary.

I've tested it pretty thoroughly, testing every integer from 0 to 51200000 and comparing to the list on OEIS http://oeis.org/A051037, as well as many large numbers that are ±1 from regular numbers, etc. It's now being used in SciPy to find optimal sizes for FFTs.

I'm not sure if the log method is faster because I couldn't get it to work reliably enough to test it. I think it has a similar number of operations, though? I'm not sure, but this is reasonably fast. Takes <3 seconds (or 0.7 second with gmpy) to calculate that 2142 × 380 × 5444 is the next regular number above 22 × 3454 × 5249+1 (the 100,000,000th regular number, which has 392 digits)

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I wrote a small c# program to solve this problem. It's not very optimised but it's a start. This solution is pretty fast for numbers as big as 11 digits.

``````private long GetRegularNumber(long n)
{
long result = n - 1;
long quotient = result;

while (quotient > 1)
{
result++;
quotient = result;

quotient = RemoveFactor(quotient, 2);
quotient = RemoveFactor(quotient, 3);
quotient = RemoveFactor(quotient, 5);
}

return result;
}

private static long RemoveFactor(long dividend, long divisor)
{
long remainder = 0;
long quotient = dividend;
while (remainder == 0)
{
dividend = quotient;
quotient = Math.DivRem(dividend, divisor, out remainder);
}
return dividend;
}
``````
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Is C# the right language for this? Won't it be slower, particularly in iterations, than C or C++? –  Matt Phillips Feb 11 '12 at 19:48
I'm pretty sure any programmer can rewrite this in c/c++ fairly easy. C# was the quickest way for me to test my idea. –  david.s Feb 11 '12 at 19:52
`N_i ~ exp( i^(1/3) )` i.e. gaps between Hamming numbers grow exponentially. So your approach will experience a very pronounced slowdown as the numbers grow in magnitude, so it seems. 11 digits is not very big. –  Will Ness Aug 21 '12 at 6:44

You know what? I'll put money on the proposition that actually, the 'dumb' algorithm is fastest. This is based on the observation that the next regular number does not, in general, seem to be much larger than the given input. So simply start counting up, and after each increment, refactor and see if you've found a regular number. But create one processing thread for each available core you have, and for N cores have each thread examine every Nth number. When each thread has found a number or crossed the power-of-2 threshold, compare the results (keep a running best number) and there you are.

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Yes it would be interesting to benchmark it. I expect you are right if we are talking about small numbers (< 10000 or so.) But as the numbers get larger so do the distances between regular numbers. An extreme example is 48000001 (the next regular number is 48600000, and it will take 2.8M divisions to find it.) –  finnw Feb 12 '12 at 16:32
hi, I've added a new answer here that shows how to directly enumerate (i,j,k) triples in the narrow vicinity of log(N), which is very fast. –  Will Ness Aug 20 '12 at 17:19
"This is based on the observation that the next regular number does not, in general, seem to be much larger than the given input." I don't think that's a good assumption. They get farther and father apart as you go up. The next regular number above 50000001 is 50331648, and that's only the 995th number. I suspect generating the list of regular numbers until you get one above your target is faster. –  endolith Sep 30 '13 at 19:28
I tested an "iterate and factor" algorithm vs a "generate list until you go over" algorithm. The factoring algorithm is faster for small numbers, but gets far slower for large numbers. 854296876 → 859963392 takes 26 ms vs 18 seconds with the factoring method. –  endolith Oct 1 '13 at 1:24