45

Numbers whose only prime factors are 2, 3, or 5 are called ugly numbers.

Example:

1, 2, 3, 4, 5, 6, 8, 9, 10, 12, 15, ... 

1 can be considered as 2^0.

I am working on finding nth ugly number. Note that these numbers are extremely sparsely distributed as n gets large.

I wrote a trivial program that computes if a given number is ugly or not. For n > 500 - it became super slow. I tried using memoization - observation: ugly_number * 2, ugly_number * 3, ugly_number * 5 are all ugly. Even with that it is slow. I tried using some properties of log - since that will reduce this problem from multiplication to addition - but, not much luck yet. Thought of sharing this with you all. Any interesting ideas?

Using a concept similar to Sieve of Eratosthenes (thanks Anon)

    for (int i(2), uglyCount(0); ; i++) {
        if (i % 2 == 0)
            continue;
        if (i % 3 == 0)
            continue;
        if (i % 5 == 0)
            continue;
        uglyCount++;
        if (uglyCount == n - 1)
            break;
    }

i is the nth ugly number.

Even this is pretty slow. I am trying to find the 1500th ugly number.

12

13 Answers 13

42

A simple fast solution in Java. Uses approach described by Anon..
Here TreeSet is just a container capable of returning smallest element in it. (No duplicates stored.)

    int n = 20;
    SortedSet<Long> next = new TreeSet<Long>();
    next.add((long) 1);

    long cur = 0;
    for (int i = 0; i < n; ++i) {
        cur = next.first();
        System.out.println("number " + (i + 1) + ":   " + cur);

        next.add(cur * 2);
        next.add(cur * 3);
        next.add(cur * 5);
        next.remove(cur);
    }

Since 1000th ugly number is 51200000, storing them in bool[] isn't really an option.

edit
As a recreation from work (debugging stupid Hibernate), here's completely linear solution. Thanks to marcog for idea!

    int n = 1000;

    int last2 = 0;
    int last3 = 0;
    int last5 = 0;

    long[] result = new long[n];
    result[0] = 1;
    for (int i = 1; i < n; ++i) {
        long prev = result[i - 1];

        while (result[last2] * 2 <= prev) {
            ++last2;
        }
        while (result[last3] * 3 <= prev) {
            ++last3;
        }
        while (result[last5] * 5 <= prev) {
            ++last5;
        }

        long candidate1 = result[last2] * 2;
        long candidate2 = result[last3] * 3;
        long candidate3 = result[last5] * 5;

        result[i] = Math.min(candidate1, Math.min(candidate2, candidate3));
    }

    System.out.println(result[n - 1]);

The idea is that to calculate a[i], we can use a[j]*2 for some j < i. But we also need to make sure that 1) a[j]*2 > a[i - 1] and 2) j is smallest possible.
Then, a[i] = min(a[j]*2, a[k]*3, a[t]*5).

7
  • 7
    @vardhan If you don't understand something, ask. Don't just 'fix' things. Aug 22, 2011 at 9:11
  • 4
    @vardhan "The 2nd solution is not completely linear -- The 3 while loops inside the for loops cannot be described as constant time." -- Um, utterly wrong. Each lasti ranges from 0 to at most n, once total, so they're O(n) total. Put another way, per iteration of the for loop, the average number of iterations of each of the 3 inner loops is <= 1, which is indeed constant time.
    – Jim Balter
    Mar 29, 2013 at 6:39
  • 1
    Is the while loop necessary though? Won't prev be one of the three last? Like the top solution here: stackoverflow.com/questions/5505894/…
    – Kakira
    Jun 29, 2015 at 21:21
  • 1
    @Kakira if is enough ; but no, sometimes two or even all three have to be advanced at once ; in the linked solution the two ifs are sequential, not exclusive; I think Dijkstra himself wrote this algo down with the whiles, so as not to leave room for any doubt correctness-wise, I think his reasoning was.
    – Will Ness
    Dec 26, 2015 at 13:25
  • 1
    The internal while is making this a bad reading, it looks like we can move last2 last3 or last5 for more than 1, which we cannot. :( It is confused if last2 is pointer or it is a power of 2 on first reading. :( Really no reason for that. We do not loop for more than 1.
    – Alex Peter
    Jun 15, 2019 at 20:11
12

I am working on finding nth ugly number. Note that these numbers are extremely sparsely distributed as n gets large.

I wrote a trivial program that computes if a given number is ugly or not.

This looks like the wrong approach for the problem you're trying to solve - it's a bit of a shlemiel algorithm.

Are you familiar with the Sieve of Eratosthenes algorithm for finding primes? Something similar (exploiting the knowledge that every ugly number is 2, 3 or 5 times another ugly number) would probably work better for solving this.

With the comparison to the Sieve I don't mean "keep an array of bools and eliminate possibilities as you go up". I am more referring to the general method of generating solutions based on previous results. Where the Sieve gets a number and then removes all multiples of it from the candidate set, a good algorithm for this problem would start with an empty set and then add the correct multiples of each ugly number to that.

4
  • 3
    +1 This solves the problem of finding the nth number fast. You should also add that going through the multiples of 2,3,5 in parallel will remove the need for a bool array.
    – moinudin
    Jan 5, 2011 at 1:27
  • I was familiar with Sieve of Eratosthenes.. First I started thinking about generating a sorted list of all the ugly number - which was not quite clean. Then I ventures into the trivial solution (which was damn slow obviously). Sieve of Eratosthenes should help me solve the problem in O(U(n)) where U(n) is the nth ugly number.
    – Anil Katti
    Jan 5, 2011 at 1:37
  • @Anil You don't have to store elements in array, you can use any other type of container, like heap. This can give you O(n*logn) easily. There's also an approach described by marcog: it'll give O(n), but it's a bit trickier. Jan 5, 2011 at 1:39
  • 1
    @Anil: When I made the comparison to the Sieve, I didn't really mean "keep an array of bools and eliminate possibilities as you go up" - I was more referring to the general method of generating solutions based on previous results. Where the Sieve gets a result and the removes all multiples of it from the candidate set, a good algorithm for this problem would start with an empty set and then add the correct multiples of each ugly number to that.
    – Anon.
    Jan 5, 2011 at 1:50
9

My answer refers to the correct answer given by Nikita Rybak. So that one could see a transition from the idea of the first approach to that of the second.

from collections import deque
def hamming():
    h=1;next2,next3,next5=deque([]),deque([]),deque([])
    while True:
        yield h
        next2.append(2*h)
        next3.append(3*h)
        next5.append(5*h)
        h=min(next2[0],next3[0],next5[0])
        if h == next2[0]: next2.popleft()
        if h == next3[0]: next3.popleft()
        if h == next5[0]: next5.popleft()

What's changed from Nikita Rybak's 1st approach is that, instead of adding next candidates into single data structure, i.e. Tree set, one can add each of them separately into 3 FIFO lists. This way, each list will be kept sorted all the time, and the next least candidate must always be at the head of one ore more of these lists.

If we eliminate the use of the three lists above, we arrive at the second implementation in Nikita Rybak' answer. This is done by evaluating those candidates (to be contained in three lists) only when needed, so that there is no need to store them.

Simply put:

In the first approach, we put every new candidate into single data structure, and that's bad because too many things get mixed up unwisely. This poor strategy inevitably entails O(log(tree size)) time complexity every time we make a query to the structure. By putting them into separate queues, however, you will see that each query takes only O(1) and that's why the overall performance reduces to O(n)!!! This is because each of the three lists is already sorted, by itself.

0
6

I believe you can solve this problem in sub-linear time, probably O(n^{2/3}).

To give you the idea, if you simplify the problem to allow factors of just 2 and 3, you can achieve O(n^{1/2}) time starting by searching for the smallest power of two that is at least as large as the nth ugly number, and then generating a list of O(n^{1/2}) candidates. This code should give you an idea how to do it. It relies on the fact that the nth number containing only powers of 2 and 3 has a prime factorization whose sum of exponents is O(n^{1/2}).

def foo(n):
  p2 = 1  # current power of 2
  p3 = 1  # current power of 3
  e3 = 0  # exponent of current power of 3
  t = 1   # number less than or equal to the current power of 2
  while t < n:
    p2 *= 2
    if p3 * 3 < p2:
      p3 *= 3
      e3 += 1
    t += 1 + e3
  candidates = [p2]
  c = p2
  for i in range(e3):
    c /= 2
    c *= 3
    if c > p2: c /= 2
    candidates.append(c)
  return sorted(candidates)[n - (t - len(candidates))]

The same idea should work for three allowed factors, but the code gets more complex. The sum of the powers of the factorization drops to O(n^{1/3}), but you need to consider more candidates, O(n^{2/3}) to be more precise.

4
  • yes, the n^{2/3} is correct, though I didn't follow your arguments here. This is done by enumerating the i,j,k triples to not reach above an estimated value of n-th member of the sequence (since ln2, ln3, ln5 are known). Code and links in this answer.
    – Will Ness
    Mar 26, 2014 at 9:59
  • It's a shame that the only fast solution has so few votes. It will easily find the one millionth ugly number around 10^253 by my estimate.
    – gnasher729
    Aug 30, 2015 at 19:51
  • @gnasher729 1000000-th Hamming number is 5.19312780448E+83, actually.
    – Will Ness
    Dec 26, 2015 at 12:55
  • works for 100, 10000 (I verified that the results are correct -- the value returned is at the index n in the sequence, zero-based), but fails for 1000 with "list index out of range" error. ideone.com/6hnIxg
    – Will Ness
    Feb 11, 2019 at 18:45
6

A lot of good answers here, but I was having trouble understanding those, specifically how any of these answers, including the accepted one, maintained the axiom 2 in Dijkstra's original paper:

Axiom 2. If x is in the sequence, so is 2 * x, 3 * x, and 5 * x.

After some whiteboarding, it became clear that the axiom 2 is not an invariant at each iteration of the algorithm, but actually the goal of the algorithm itself. At each iteration, we try to restore the condition in axiom 2. If last is the last value in the result sequence S, axiom 2 can simply be rephrased as:

For some x in S, the next value in S is the minimum of 2x, 3x, and 5x, that is greater than last. Let's call this axiom 2'.

Thus, if we can find x, we can compute the minimum of 2x, 3x, and 5x in constant time, and add it to S.

But how do we find x? One approach is, we don't; instead, whenever we add a new element e to S, we compute 2e, 3e, and 5e, and add them to a minimum priority queue. Since this operations guarantees e is in S, simply extracting the top element of the PQ satisfies axiom 2'.

This approach works, but the problem is that we generate a bunch of numbers we may not end up using. See this answer for an example; if the user wants the 5th element in S (5), the PQ at that moment holds 6 6 8 9 10 10 12 15 15 20 25. Can we not waste this space?

Turns out, we can do better. Instead of storing all these numbers, we simply maintain three counters for each of the multiples, namely, 2i, 3j, and 5k. These are candidates for the next number in S. When we pick one of them, we increment only the corresponding counter, and not the other two. By doing so, we are not eagerly generating all the multiples, thus solving the space problem with the first approach.

Let's see a dry run for n = 8, i.e. the number 9. We start with 1, as stated by axiom 1 in Dijkstra's paper.

+---------+---+---+---+----+----+----+-------------------+
| #       | i | j | k | 2i | 3j | 5k | S                 |
+---------+---+---+---+----+----+----+-------------------+
| initial | 1 | 1 | 1 | 2  | 3  | 5  | {1}               |
+---------+---+---+---+----+----+----+-------------------+
| 1       | 1 | 1 | 1 | 2  | 3  | 5  | {1,2}             |
+---------+---+---+---+----+----+----+-------------------+
| 2       | 2 | 1 | 1 | 4  | 3  | 5  | {1,2,3}           |
+---------+---+---+---+----+----+----+-------------------+
| 3       | 2 | 2 | 1 | 4  | 6  | 5  | {1,2,3,4}         |
+---------+---+---+---+----+----+----+-------------------+
| 4       | 3 | 2 | 1 | 6  | 6  | 5  | {1,2,3,4,5}       |
+---------+---+---+---+----+----+----+-------------------+
| 5       | 3 | 2 | 2 | 6  | 6  | 10 | {1,2,3,4,5,6}     |
+---------+---+---+---+----+----+----+-------------------+
| 6       | 4 | 2 | 2 | 8  | 6  | 10 | {1,2,3,4,5,6}     |
+---------+---+---+---+----+----+----+-------------------+
| 7       | 4 | 3 | 2 | 8  | 9  | 10 | {1,2,3,4,5,6,8}   |
+---------+---+---+---+----+----+----+-------------------+
| 8       | 5 | 3 | 2 | 10 | 9  | 10 | {1,2,3,4,5,6,8,9} |
+---------+---+---+---+----+----+----+-------------------+

Notice that S didn't grow at iteration 6, because the minimum candidate 6 had already been added previously. To avoid this problem of having to remember all of the previous elements, we amend our algorithm to increment all the counters whenever the corresponding multiples are equal to the minimum candidate. That brings us to the following Scala implementation.

def hamming(n: Int): Seq[BigInt] = {
  @tailrec
  def next(x: Int, factor: Int, xs: IndexedSeq[BigInt]): Int = {
    val leq = factor * xs(x) <= xs.last
    if (leq) next(x + 1, factor, xs)
    else x
  }

  @tailrec
  def loop(i: Int, j: Int, k: Int, xs: IndexedSeq[BigInt]): IndexedSeq[BigInt] = {
    if (xs.size < n) {
      val a = next(i, 2, xs)
      val b = next(j, 3, xs)
      val c = next(k, 5, xs)
      val m = Seq(2 * xs(a), 3 * xs(b), 5 * xs(c)).min

      val x = a + (if (2 * xs(a) == m) 1 else 0)
      val y = b + (if (3 * xs(b) == m) 1 else 0)
      val z = c + (if (5 * xs(c) == m) 1 else 0)

      loop(x, y, z, xs :+ m)
    } else xs
  }

  loop(0, 0, 0, IndexedSeq(BigInt(1)))
}
3
  • what is the value of Iterator.from(6).drop(1).next()? isn't it 7? if so, it would mean this code is wrong. as a test, what is the 1000th hamming number produced by this code, please? is it 51200000?
    – Will Ness
    Feb 11, 2019 at 11:52
  • this code is wrong. it produces e.g. 14=7*2, 21 = 7*3, 22 = 11*2...
    – Will Ness
    Feb 11, 2019 at 17:11
  • @WillNess fixed, thanks for finding the bug. I didn't try to generate the 1000 number, but I tested up to 15. Also, if I was going to use this code for generating a large sequence, I'd probably use a mutable sequence, and also try not to repeat BigInt multiplications. Feb 12, 2019 at 3:57
4

Basicly the search could be made O(n):

Consider that you keep a partial history of ugly numbers. Now, at each step you have to find the next one. It should be equal to a number from the history multiplied by 2, 3 or 5. Chose the smallest of them, add it to history, and drop some numbers from it so that the smallest from the list multiplied by 5 would be larger than the largest.

It will be fast, because the search of the next number will be simple:
min(largest * 2, smallest * 5, one from the middle * 3),
that is larger than the largest number in the list. If they are scarse, the list will always contain few numbers, so the search of the number that have to be multiplied by 3 will be fast.

0
2

Here is a correct solution in ML. The function ugly() will return a stream (lazy list) of hamming numbers. The function nth can be used on this stream.

This uses the Sieve method, the next elements are only calculated when needed.

datatype stream = Item of int * (unit->stream);
fun cons (x,xs) = Item(x, xs);
fun head (Item(i,xf)) = i;
fun tail (Item(i,xf)) = xf();
fun maps f xs = cons(f (head xs), fn()=> maps f (tail xs));

fun nth(s,1)=head(s)
  | nth(s,n)=nth(tail(s),n-1);

fun merge(xs,ys)=if (head xs=head ys) then
                   cons(head xs,fn()=>merge(tail xs,tail ys))
                 else if (head xs<head ys) then
                   cons(head xs,fn()=>merge(tail xs,ys))
                 else
                   cons(head ys,fn()=>merge(xs,tail ys));

fun double n=n*2;
fun triple n=n*3;

fun ij()=
    cons(1,fn()=>
      merge(maps double (ij()),maps triple (ij())));

fun quint n=n*5;

fun ugly()=
    cons(1,fn()=>
      merge((tail (ij())),maps quint (ugly())));

This was first year CS work :-)

2

To find the n-th ugly number in O (n^(2/3)), jonderry's algorithm will work just fine. Note that the numbers involved are huge so any algorithm trying to check whether a number is ugly or not has no chance.

Finding all of the n smallest ugly numbers in ascending order is done easily by using a priority queue in O (n log n) time and O (n) space: Create a priority queue of numbers with the smallest numbers first, initially including just the number 1. Then repeat n times: Remove the smallest number x from the priority queue. If x hasn't been removed before, then x is the next larger ugly number, and we add 2x, 3x and 5x to the priority queue. (If anyone doesn't know the term priority queue, it's like the heap in the heapsort algorithm). Here's the start of the algorithm:

1 -> 2 3 5
1 2 -> 3 4 5 6 10
1 2 3 -> 4 5 6 6 9 10 15
1 2 3 4 -> 5 6 6 8 9 10 12 15 20
1 2 3 4 5 -> 6 6 8 9 10 10 12 15 15 20 25
1 2 3 4 5 6 -> 6 8 9 10 10 12 12 15 15 18 20 25 30
1 2 3 4 5 6 -> 8 9 10 10 12 12 15 15 18 20 25 30
1 2 3 4 5 6 8 -> 9 10 10 12 12 15 15 16 18 20 24 25 30 40

Proof of execution time: We extract an ugly number from the queue n times. We initially have one element in the queue, and after extracting an ugly number we add three elements, increasing the number by 2. So after n ugly numbers are found we have at most 2n + 1 elements in the queue. Extracting an element can be done in logarithmic time. We extract more numbers than just the ugly numbers but at most n ugly numbers plus 2n - 1 other numbers (those that could have been in the sieve after n-1 steps). So the total time is less than 3n item removals in logarithmic time = O (n log n), and the total space is at most 2n + 1 elements = O (n).

1
  • finding n first members of Hamming sequence is an O(n) time calculation. n log n is totally unnecessary. the accepted answer's second version (under "edit") is O(n). (it is also what Dijkstra wrote, down to the whiles -- ifs are enough really, but he wrote that using while leaves no room for doubt, correctness-wise).
    – Will Ness
    Dec 25, 2015 at 12:31
1

I guess we can use Dynamic Programming (DP) and compute nth Ugly Number. Complete explanation can be found at http://www.geeksforgeeks.org/ugly-numbers/

#include <iostream>
#define MAX 1000

using namespace std;

// Find Minimum among three numbers
long int min(long int x, long int y, long int z) {

    if(x<=y) {
        if(x<=z) {
            return x;
        } else {
            return z;
        }
    } else {
        if(y<=z) {
            return y;
        } else {
            return z;
        }
    }   
}


// Actual Method that computes all Ugly Numbers till the required range
long int uglyNumber(int count) {

    long int arr[MAX], val;

    // index of last multiple of 2 --> i2
    // index of last multiple of 3 --> i3
    // index of last multiple of 5 --> i5
    int i2, i3, i5, lastIndex;

    arr[0] = 1;
    i2 = i3 = i5 = 0;
    lastIndex = 1;


    while(lastIndex<=count-1) {

        val = min(2*arr[i2], 3*arr[i3], 5*arr[i5]);

        arr[lastIndex] = val;
        lastIndex++;

        if(val == 2*arr[i2]) {
            i2++;
        }
        if(val == 3*arr[i3]) {
            i3++;
        }
        if(val == 5*arr[i5]) {
            i5++;
        }       
    }

    return arr[lastIndex-1];

}

// Starting point of program
int main() {

    long int num;
    int count;

    cout<<"Which Ugly Number : ";
    cin>>count;

    num = uglyNumber(count);

    cout<<endl<<num;    

    return 0;
}

We can see that its quite fast, just change the value of MAX to compute higher Ugly Number

0
1

Using 3 generators in parallel and selecting the smallest at each iteration, here is a C program to compute all ugly numbers below 2128 in less than 1 second:

#include <limits.h>
#include <stdio.h>

#if 0
typedef unsigned long long ugly_t;
#define UGLY_MAX  (~(ugly_t)0)
#else
typedef __uint128_t ugly_t;
#define UGLY_MAX  (~(ugly_t)0)
#endif

int print_ugly(int i, ugly_t u) {
    char buf[64], *p = buf + sizeof(buf);

    *--p = '\0';
    do { *--p = '0' + u % 10; } while ((u /= 10) != 0);
    return printf("%d: %s\n", i, p);
}

int main() {
    int i = 0, n2 = 0, n3 = 0, n5 = 0;
    ugly_t u, ug2 = 1, ug3 = 1, ug5 = 1;
#define UGLY_COUNT  110000
    ugly_t ugly[UGLY_COUNT];

    while (i < UGLY_COUNT) {
        u = ug2;
        if (u > ug3) u = ug3;
        if (u > ug5) u = ug5;
        if (u == UGLY_MAX)
            break;
        ugly[i++] = u;
        print_ugly(i, u);
        if (u == ug2) {
            if (ugly[n2] <= UGLY_MAX / 2)
                ug2 = 2 * ugly[n2++];
            else
                ug2 = UGLY_MAX;
        }
        if (u == ug3) {
            if (ugly[n3] <= UGLY_MAX / 3)
                ug3 = 3 * ugly[n3++];
            else
                ug3 = UGLY_MAX;
        }
        if (u == ug5) {
            if (ugly[n5] <= UGLY_MAX / 5)
                ug5 = 5 * ugly[n5++];
            else
                ug5 = UGLY_MAX;
        }
    }
    return 0;
}

Here are the last 10 lines of output:

100517: 338915443777200000000000000000000000000
100518: 339129266201729628114355465608000000000
100519: 339186548067800934969350553600000000000
100520: 339298130282929870605468750000000000000
100521: 339467078447341918945312500000000000000
100522: 339569540691046437734055936000000000000
100523: 339738624000000000000000000000000000000
100524: 339952965770562084651663360000000000000
100525: 340010386766614455386112000000000000000
100526: 340122240000000000000000000000000000000

Here is a version in Javascript usable with QuickJS:

import * as std from "std";

function main() {
    var i = 0, n2 = 0, n3 = 0, n5 = 0;
    var u, ug2 = 1n, ug3 = 1n, ug5 = 1n;
    var ugly = [];

    for (;;) {
        u = ug2;
        if (u > ug3) u = ug3;
        if (u > ug5) u = ug5;
        ugly[i++] = u;
        std.printf("%d: %s\n", i, String(u));
        if (u >= 0x100000000000000000000000000000000n)
            break;
        if (u == ug2)
            ug2 = 2n * ugly[n2++];
        if (u == ug3)
            ug3 = 3n * ugly[n3++];
        if (u == ug5)
            ug5 = 5n * ugly[n5++];
    }
    return 0;
}
main();
9
  • 1
    are you aware of this? the linked answer's code calculates 1 billionth H.N. in 0.02s and 1 trillionth in about 2s on Ideone.
    – Will Ness
    Apr 10, 2020 at 19:26
  • 1
    @WillNess: Amazing contribution! but Haskell is so alien to non-afficionados. Do your published timings include the computation of the exact values, and the conversion to base 10?
    – chqrlie
    Apr 10, 2020 at 19:40
  • the code calculates (2,3,5) exponents triples; exact values is a matter of simple BIGNUM arithmetic. it shows also its decimal approximation, e.g. 1B --> (1334,335,404) --> "6.216075755562335E+843". there's nothing especially haskelly about the algorithm.
    – Will Ness
    Apr 10, 2020 at 19:45
  • I mean, the triples are exact, of course. exponentiation and printing (in decimal) is already provided by Haskell, so I haven't bothered reimplementing it. the interpreter responds to 2^1334*3^335*5^404 printing the result without delay (it says 0.02s after printing). It is easy to add this to the code on Ideone, I just didn't want to clutter up the output.
    – Will Ness
    Apr 10, 2020 at 20:00
  • I've added the full exact number printout to the Ideone entry; the run time didn't change for the 1Bth number. for the 1Tth though the time grew by almost a second on top the previous 2 seconds.
    – Will Ness
    Apr 11, 2020 at 8:53
0

here is my code , the idea is to divide the number by 2 (till it gives remainder 0) then 3 and 5 . If at last the number becomes one it's a ugly number. you can count and even print all ugly numbers till n.

int count = 0;
for (int i = 2; i <= n; i++) {
    int temp = i;
    while (temp % 2 == 0) temp=temp / 2;
    while (temp % 3 == 0) temp=temp / 3;
    while (temp % 5 == 0) temp=temp / 5;
    if (temp == 1) {
        cout << i << endl;
        count++;
    }

}
1
  • this code is exponential in the (qubic root of the) number k of ugly numbers it produces: n ~ exp (k ^ (1/3)). Dijkstra's algo is linear in k. It is shown in several answers here, e.g. this.
    – Will Ness
    Feb 11, 2019 at 9:37
-3

This problem can be done in O(1).

If we remove 1 and look at numbers between 2 through 30, we will notice that there are 22 numbers.

Now, for any number x in the 22 numbers above, there will be a number x + 30 in between 31 and 60 that is also ugly. Thus, we can find at least 22 numbers between 31 and 60. Now for every ugly number between 31 and 60, we can write it as s + 30. So s will be ugly too, since s + 30 is divisible by 2, 3, or 5. Thus, there will be exactly 22 numbers between 31 and 60. This logic can be repeated for every block of 30 numbers after that.

Thus, there will be 23 numbers in the first 30 numbers, and 22 for every 30 after that. That is, first 23 uglies will occur between 1 and 30, 45 uglies will occur between 1 and 60, 67 uglies will occur between 1 and 30 etc.

Now, if I am given n, say 137, I can see that 137/22 = 6.22. The answer will lie between 6*30 and 7*30 or between 180 and 210. By 180, I will have 6*22 + 1 = 133rd ugly number at 180. I will have 154th ugly number at 210. So I am looking for 4th ugly number (since 137 = 133 + 4)in the interval [2, 30], which is 5. The 137th ugly number is then 180 + 5 = 185.

Another example: if I want the 1500th ugly number, I count 1500/22 = 68 blocks. Thus, I will have 22*68 + 1 = 1497th ugly at 30*68 = 2040. The next three uglies in the [2, 30] block are 2, 3, and 4. So our required ugly is at 2040 + 4 = 2044.

The point it that I can simply build a list of ugly numbers between [2, 30] and simply find the answer by doing look ups in O(1).

3
  • There are 17 ugly numbers between 2 and 30, not 22. And adding 30 will not make another one. For example, 3 is ugly but 33 isn't.
    – interjay
    Oct 2, 2014 at 17:52
  • 1
    Oops. I should have read the question more carefully. The problem that needs to be solved should be for numbers of the form 2^a*3^b*5^c. What I solved was for numbers that are multiples of 2, 3, and 5 and these include primes such as 7, 11, etc.
    – guidothekp
    Oct 2, 2014 at 19:04
  • this answer makes absolutely no sense to me at all. you "can simply build a list of ugly numbers"?? the question is how?
    – Will Ness
    Feb 11, 2019 at 11:56
-3

Here is another O(n) approach (Python solution) based on the idea of merging three sorted lists. The challenge is to find the next ugly number in increasing order. For example, we know the first seven ugly numbers are [1,2,3,4,5,6,8]. The ugly numbers are actually from the following three lists:

  • list 1: 1*2, 2*2, 3*2, 4*2, 5*2, 6*2, 8*2 ...     ( multiply each ugly number by 2 )
  • list 2: 1*3, 2*3, 3*3, 4*3, 5*3, 6*3, 8*3 ...     ( multiply each ugly number by 3 )
  • list 3: 1*5, 2*5, 3*5, 4*5, 5*5, 6*5, 8*5 ...     ( multiply each ugly number by 5 )

So the nth ugly number is the nth number of the list merged from the three lists above:

1, 1*2, 1*3, 2*2, 1*5, 2*3 ...

def nthuglynumber(n):
    p2, p3, p5 = 0,0,0
    uglynumber = [1]
    while len(uglynumber) < n:
        ugly2, ugly3, ugly5 = uglynumber[p2]*2, uglynumber[p3]*3, uglynumber[p5]*5
        next = min(ugly2, ugly3, ugly5)
        if next == ugly2: p2 += 1        # multiply each number
        if next == ugly3: p3 += 1        # only once by each
        if next == ugly5: p5 += 1        # of the three factors
        uglynumber += [next]
    return uglynumber[-1]
  1. STEP I: computing three next possible ugly numbers from the three lists
    • ugly2, ugly3, ugly5 = uglynumber[p2]*2, uglynumber[p3]*3, uglynumber[p5]*5
  2. STEP II, find the one next ugly number as the smallest of the three above:
    • next = min(ugly2, ugly3, ugly5)
  3. STEP III: moving the pointer forward if its ugly number was the next ugly number
    • if next == ugly2: p2+=1
    • if next == ugly3: p3+=1
    • if next == ugly5: p5+=1
    • note: not using if with elif nor else
  4. STEP IV: adding the next ugly number into the merged list uglynumber
    • uglynumber += [next]
7
  • Please format your answer properly. Python is meaningless if you don't.
    – Teepeemm
    Aug 30, 2015 at 20:02
  • That's wrong. Ugly numbers include for example 60 = 2^2 * 3^1 * 5^1 which is not on any of the lists.
    – gnasher729
    Aug 31, 2015 at 15:50
  • 1
    no, i think the function covers the ugly number 60. try the the function: nthuglynumber(26) in python. it will return 60.
    – Zhan
    Aug 31, 2015 at 16:38
  • @gnasher729 no, 60 is on all three lists: 60 = 30 * 2 = 10 * 3 = 12 * 5.
    – Will Ness
    Dec 26, 2015 at 13:41
  • The explanation is wrong. Suppose we add "7*2", "7*3", "7*5" to the 3 lists.
    – derek
    Sep 4, 2017 at 21:39

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