# How to get the target number with +3 or *5 operations without recursion?

This is an interview problem I came across yesterday, I can think of a recursive solution but I wanna know if there's a non-recursive solution.

Given a number N, starting with number 1, you can only multiply the result by 5 or add 3 to the result. If there's no way to get N through this method, return "Can't generate it".

Ex:

``````Input: 23
Output: (1+3)*5+3
Input: 215
Output: ((1*5+3)*5+3)*5
Input: 12
Output: Can't generate it.
``````

The recursive method can be obvious and intuitive, but are there any non-recursive methods?

I think the quickest, non recursive solution is (for N > 2):

• if `N mod 3 == 1`, it can be generated as `1 + 3*k`.
• if `N mod 3 == 2`, it can be generated as `1*5 + 3*k`
• if `N mod 3 == 0`, it cannot be generated

The last statement comes from the fact that starting with 1 (= 1 mod 3) you can only reach numbers which are equals to 1 or 2 mod 3:

• when you add 3, you don't change the value mod 3
• a number equals to 1 mod 3 multiplied by 5 gives a number equals to 2 mod 3
• a number equals to 2 mod 3 multiplied by 5 gives a number equals to 1 mod 3
• This solves the decision problem quite brilliantly, but it does not solve the construction problem the way the OP has intended: `215` would be generated as `1*5+3+3+3...+3` with `+3` repeated 70 times, not as `((1*5+3)*5+3)*5`. Jul 15, 2013 at 11:16
• The method is cool, pure mathematical analysis. But as @dasblinkenlight says, the result format is not what I want. Is there any way to print it exactly like what it requires? Jul 15, 2013 at 11:58
• You're right, it doesn't produce the best solution (unless N can't be generated!). But getting the shortest solution is a much more difficult problem. And the recursive solution really seems the easiest way to go. Jul 15, 2013 at 13:34
• @obourgain In my opinion you solved the more subtle problem of efficiently deciding whether or not number can be reached. Finding the shortest solution to `N` is an "off-the-shelf" application of Dijkstra's algorithm. Jul 15, 2013 at 15:02
• The shortest solution is not that difficult of a problem, and my solution is about O(N) (where N is number of digits, so O(log(N)) for size of number) Jul 15, 2013 at 23:46

The key here is to work backwards. Start with the number you want to reach and if it's divisible by 5 then divide by 5 because multiplication by 5 results in a shorter solution than addition by 3. The only exceptions are if the value equals 10, because dividing by 5 would yield 2 which is insolvable. If the number is not divisible by 5 or is equal to 10, subtract 3. This produces the shortest string

Repeat until you reach 1

Here is python code:

``````def f(x):
if x%3 == 0 or x==2:
return "Can't generate it"
l = []
while x!=1:
if x%5 != 0 or x==10:
l.append(3)
x -= 3
else:
l.append(5)
x /=5
l.reverse()
s = '1'
for v in l:
if v == 3:
s += ' + 3'
else:
s = '(' + s + ')*5'
return s
``````

Credit to the previous solutions for determining whether a given number is possible

• yes, it is a better idea to search backwards from the target number `N` rather than forwards from `1` as I suggested. The idea of preferring `/5` to `-3` is particularly astute, and I think could be justified mathematically, e.g. using proof by contradiction (it ought to be possible to show that if you have the choice of subtracting 3 from `N` or dividing by 5, subtracting 3 will take more steps). Jul 18, 2013 at 16:10
• It's a fairly simple proof, although it's not in strict mathematical language: If there is the opportunity to divide by 5, and you instead subtract 3, you would have to subtract 5 times in order to get another chance to divide by 5. If you then divide by 5 it takes a total of 6 steps. If however, you divide by 5 first and then subtract 3, it takes 2 steps. The only scenario in which you would not want to divide by 5, is at 10, because if you do you will be left with 2 which is impossible to generate. Jul 18, 2013 at 19:52
• Sounds too simple to me, and the fact that for 10 it's clearly wrong stands as more evidence. I'll see if I can think of other counterexamples. Nov 18, 2014 at 23:55
• I have proven to myself that the reasoning is solid down to 15. Nov 19, 2014 at 0:05

Model the problem as a graph:

• Nodes are numbers
• Your root node is 1
• Links between nodes are `*5` or `+3`.

Then run Dijkstra's algorithm to get the shortest path. If you exhaust all links from nodes `<N` without getting to `N` then you can't generate `N`. (Alternatively, use @obourgain's answer to decide in advance whether the problem can be solved, and only attempt to work out how to solve the problem if it can be solved.)

So essentially, you enqueue the node (1, null path). You need a dictionary storing {node(i.e. number) => best path found so far for that node}. Then, so long as the queue isn't empty, in each pass of the loop you

• Dequeue the head (node,path) from the queue.
• If the number of this node is `>N`, or you've already seen this node before with fewer steps in the path, then don't do any more on this pass.
• Add (node => path) to the dictionary.
• Enqueue nodes reachable from this node with `*5` and `+3` (together with the paths that get you to those nodes)

When the loop terminates, look up `N` in the dictionary to get the path, or output "Can't generate it".

Edit: note, this is really Breadth-first search rather than Dijkstra's algorithm, as the cost of traversing a link is fixed at 1.

You can use the following recursion (which is indeed intuitive):

``````f(input) = f(input/5) OR f(input -3)
base:
f(1) = true
f(x) = false    x is not natural positive number
``````

Note that it can be done using Dynamic Programming as well:

``````f[-2] = f[-1] = f[0] = false
f[1] = true
for i from 2 to n:
f[i] = f[i-3] or (i%5 == 0? f[i/5] : false)
``````

To get the score, you need to get on the table after building it from `f[n]` and follow the valid `true` moves.

Time and space complexity of the DP solution is `O(n)` [pseudo-polynomial]

All recursive algorithms can also be implemented using a stack. So, something like this:

``````bool canProduce(int target){
Stack<int> numStack;
int current;

numStack.push(1);

while(!numStack.empty){
current=numStack.top();
numStack.pop();
if(current==target)
return true;
if(current+3 < target)
numStack.push(current+3);
if(current*5 < target)
numStack.push(current*5);
}

return false;
}
``````

In Python:

The smart solution:

``````def f(n):
if n % 3 == 1:
print '1' + '+3' * (n // 3)
elif n % 3 == 2:
print '1*5' + '+3' * ((n - 5) // 3)
else:
print "Can't generate it."
``````

A naive but still O(n) version:

``````def f(n):
d={1:'1'}
for i in range(n):
if i in d:
d[i*5] = '(' + d[i] + ')*5'
d[i+3] = d[i] + '+3'

if n in d:
print d[n]
else:
print "Can't generate it."
``````

And of course, you could also use a stack to reproduce the behavior of the recursive calls.

Which gives:

``````>>> f(23)
(1)*5+3+3+3+3+3+3
>>> f(215)
(1)*5+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3+3
>>> f(12)
Can't generate it.
``````