# Shortest sequence of unfold operations

I was proposed to solve this problem a while ago, and still keeps me woken up at unusual times:

Two integer variables L and R are given. Their initial content is 0 and 1, respectively, and it can be manipulated using the following unfold operations:

• operation 'L' is the assignment of value 2*L−R to variable L;

• operation 'R' is the assignment of value 2*R−L to variable R.

An integer N is given. An unfold sequence for N is a sequence of unfold operations such that, after performing these operations, either L = N or R = N.

For example, consider N = 21 and the following sequence of unfold operations: `['L', 'L', 'R', 'L', 'R']`. This is an unfold sequence for N, because:

after the first operation L becomes −1 (R remains 1); after the second operation L becomes −3 (R remains 1); after the third operation R becomes 5 (L remains −3); after the fourth operation L becomes −11 (R remains 5); after the fifth operation R becomes 21 (L remains −11). After the last operation, R = N. The sequence consists of five operations, and no shorter unfold sequence for N exists.

Write a function

`int interval_unfold_count(int N);`

that, given an integer N, returns the length of the shortest unfold sequence for N. The function should return −1 if no unfold sequence for N exists.

For example, given N = 21, the function should return 5, as explained above.

Assume that:

N is an integer within the range `[−2,147,483,648..2,147,483,647]`.

Complexity:

expected worst-case time complexity is O(log(N)); expected worst-case space complexity is O(1).

My possible solution would be to create a binary tree, and assign left nodes to L operations, where each node will contain L and R, and assign right nodes to R. After the tree is created to a certain point then I'd perform best-first search, but I feel this is not the solution.

This might be misleading but I noticed that for the example given, 21, 10101, the result (5) is the number of shifts to the right that the number requires to become 0.

I also believe this has to deal with dynamic programming, but I am not sure about this. Does this have anything to do with functional-programming folding? Because I was asked to do this in Java, or C. So please if you can come up with a solution try to do it in either one of these languages.

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LOL. I never got such an assignment ;) this was a problem for an online job interview. –  user1254458 Mar 7 '12 at 11:11
If it says the expected worst-case time complexity is O(log(N)), I'm skeptical about it being a DP problem. –  Luiz Rodrigo Mar 7 '12 at 11:13
A job interview? Wow. I was irritated because you asked for a solution in Java or C instead of a general algorithm or hint... (and you're absolutely positive that they really want to hire someone? The question is quite a challenge ;) ) –  Andreas_D Mar 7 '12 at 11:20
Lol... Andreas_D I had this assignment in a certain online code interview as well, this is not homework at all. Didn't finished it on time tho :/. I think he asks for a solution in Java or C to prove it can be done without functional programming. –  eLobato Mar 7 '12 at 11:20
I'm still tempted to retag this as homework, since you are asking for an algorithm an the PL doesn't matter. –  Mister Smith Mar 7 '12 at 12:50

If you build the tree you described a few levels, you'll notice the pattern. The tree would be something like -

``````0                           (0,1)
/       \
1                      (-1,1)     (0,2)
/   \       /    \
2                  (-3,1) (-1,3) (-2,2)  (0,4)
``````

Continuing in this fashion, you'll note that `i-th level` in the tree contains all the numbers in the range `[-2^i+1, 2^i]`.

So, for a given number `N`, you'll just need to check on which level this number appears first. Sample code -

``````int interval_unfold_count(int N) {
for(i = 0; ; i++) {
if( (-(1<<i) + 1) <= N && N <= (1<<i) ) return i;
}
}
``````

UPDATE

Full Working Code -

``````#include <stdio.h>
#include <string>
using namespace std;

int interval_unfold_count(int N) {
for(int i = 0; ; i++) {
if( (-(1LL<<i) + 1) <= N && N <= (1LL<<i) ) return i;
}
}

string findPath(int N) {
if(N == 0 || N == 1) return "";
if(N&1) return "L" + findPath((N+1LL)/2); //N odd
else return "R" + findPath(N/2); //N even
}

int main() {
int i, x;
string s;
for(i = -10; i <= 10; i++) {
x = interval_unfold_count(i);
s = findPath(i);
printf("Input Number = %d, Min steps = %d, Path = %s\n",i, x, s.c_str());
}
return 0;
}
``````

Some Sample Input / Output -

``````Input Number = -10, Min steps = 4, Path = RLRL
Input Number = -9, Min steps = 4, Path = LRRL
Input Number = -8, Min steps = 4, Path = RRRL
Input Number = -7, Min steps = 3, Path = LLL
Input Number = -6, Min steps = 3, Path = RLL
Input Number = -5, Min steps = 3, Path = LRL
Input Number = -4, Min steps = 3, Path = RRL
Input Number = -3, Min steps = 2, Path = LL
Input Number = -2, Min steps = 2, Path = RL
Input Number = -1, Min steps = 1, Path = L
Input Number = 0, Min steps = 0, Path =
Input Number = 1, Min steps = 0, Path =
Input Number = 2, Min steps = 1, Path = R
Input Number = 3, Min steps = 2, Path = LR
Input Number = 4, Min steps = 2, Path = RR
Input Number = 5, Min steps = 3, Path = LLR
Input Number = 6, Min steps = 3, Path = RLR
Input Number = 7, Min steps = 3, Path = LRR
Input Number = 8, Min steps = 3, Path = RRR
Input Number = 9, Min steps = 4, Path = LLLR
Input Number = 10, Min steps = 4, Path = RLLR
``````
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Question, why are you shifting 1<<i –  eLobato Mar 7 '12 at 11:49
`1<<i` means `2^i` –  Sabbir Yousuf Sanny Mar 7 '12 at 11:50
The function should return −1 if no unfold sequence for N exists. In that case your function would be O(N) right? Checking for 1<<i going off the boundaries of an integer might help avoiding to run the algorithm for O(n).? –  eLobato Mar 7 '12 at 11:55
I added checking for negative numbers which is a requirement –  eLobato Mar 7 '12 at 12:20
The complexity is a bit more complex to proof. The basic idea is to perform a breadth-first search in a tree (which has a well known complexity of O(2^DEEP)). However, you must proof that, because of the nature of both functions, the BFS is always going to hit a certain level in the tree... –  Mister Smith Mar 7 '12 at 12:48

Mathematical proof that the above solutions work:

Consider the following tree, which I stole from Sabbir's answer:

``````0                           (0,1)
/       \
1                      (-1,1)     (0,2)
/   \       /    \
2                  (-3,1) (-1,3) (-2,2)  (0,4)
``````

We'll show that each level contains exactly the numbers from 1 - 2 ^ N to 2 ^ N.

Step 1: Assume that level N contains the pairs (i, i + 2 ^ N) for i in [1 - 2 ^ N, 2 - 2 ^ N, ..., 0]. It follows that in this case

(*) level N contains all the numbers from 1 - 2 ^ N to 2 ^ N.

Step 2: From each pair (i, i + 2 ^ N) of level N we get 2 pairs of level N + 1:

(2 * i - i - 2 ^ N, i + 2 ^ N) and (i, 2 * i + 2 ^ (N + 1) - i), which are equivalent to

(i - 2 ^ N, i - 2 ^ N + 2 ^ (N + 1)) and (i, i + 2 ^ (N + 1)), which have the form assumed in Step 1, but for level N + 1.

As i ranges from 1 - 2 ^ N to 0, the first kind of pairs give pairs with first component in the range from 1 - 2 ^ (N + 1) to -2 ^ N, and the second kind of pairs give pairs with first component from 1 - 2 ^ N to 0. The second component of any pair is 2 ^ (N + 1) larger than the firs component. Thus we get all pairs from the assumption.

Step 3: It remains to show that the assumptions holds for N = 0, which is trivial:

i takes exactly one value (i.e. 0), and 2 ^ N = 1, thus (i, i + 2 ^ N) = (0, 1), which is the starting value of (L, R).

Thus the assumption and (*) hold for all N >= 0. q.e.d.

-

This was a very good one. I wonder who comes up with these questions. Anyway, I run the following code on a few instances and it works. Just copy, paste, and run the code:

``````public class Unfolding {

public static int unfolding_count(Integer[] seed, int N){
if(null == seed) return -1;
Integer[] LR;
int lvl=-1;//so as not to count the root as an unfolding, don't start at zero
while(!queue.isEmpty()){
int size = queue.size();
lvl++;
while(size>0){
LR = queue.remove();
if(N == LR[0].intValue() || N == LR[1].intValue())
return lvl;
int L=LR[0], R = LR[1];
size--;
}
}
return lvl;//return -1 on failure
}//

public static void main(String... args){
Integer[] seed = {0,1};
int N=21;
System.out.print(unfolding_count(seed,N));
}//

}
``````
-

If all you want is to print the steps here is a very short solution:

``````public class Unfolding {
public static void unfolding_count(int N){
int L=0, R=1;
N-=1;
while(N>0){
if(N%2==0)
System.out.print("L; ");
else
System.out.print("R; ");
N/=2;
}
System.out.println();
}//

public static void main(String... args){
int N=21;
unfolding_count(N);
}//

}
``````

UPDATE: FASTER STILL::

``````public class Unfolding {
public static void unfolding_count(int N){
int L=0, R=1;
N-=1;
while(N>0){
if((N&1)==1)
System.out.print("L; ");
else
System.out.print("R; ");
N>>=1;
}
System.out.println();
}//

public static void main(String... args){
int N=21;
unfolding_count(N);
}//
}
``````

UPDATE 2.0: FOR THOSE ASKING FOR PROOF::

This is not an arithmetic problem in the usual sense. Notice that R and L are equal:

``````L=2*L-R => L-2*L=-R => L=R
R=2*R-L => R-2*R = -L => R=L

More specifically, given some other dimension d such as time or pace, then
R[d]=L[d+1]
``````

This is a binary walk problem, where we are asked to interpret the steps as ciphers in a binary numeral system: we are told that L=0 and R=1. Therefore the point is to walk towards a final number -- not counting the starting position. Each step is of course positionally more significant than the preceding step. Hence walking L,L,R is equivalent to 100 or 4. But why is this the answer to N=5, for example? Because this is a binary system. In the combinatoric sense, we have N=2^h choices in taking h steps. But in walking we are also sketching out a binary tree where the number of steps n from our initial position is given by n=2^h-1. Therefore,

``````2^h=n+1=N.
``````

Hence the computation for folding_count subtracts 1 from N to get to 2^h.

-

This is my try with PHP:

``````function interval_unfold_count(\$N, \$debug = false) {
\$L = 0;
\$R = 1;

\$cL = function() use (&\$L , &\$R) {
return (2*\$L)-\$R;
};

\$cR = function() use (&\$L , &\$R) {
return  (2*\$R)-\$L;
};

\$length = strlen(decbin(21));
\$map = array();
for (\$i=0; \$i <= \$N; \$i++) {
}

foreach (\$map as \$key => \$val) {
\$us = array();
foreach (\$val as \$unfold) {
switch(true) {
case \$unfold:
\$R = \$cR();
\$us[] = 'R';
break;

default:
\$L = \$cL();
\$us[] = 'L';
}
}
if (\$debug) {
echo "\$key - [",implode(\$val,','),"] sequence [",implode(\$us,','),"] value of L: \$L value of R: \$R",PHP_EOL;
}
if (\$L == \$N || \$R == \$N) {
return "fold sequense count found at: \$key with unfold sequence: [". implode(\$us, ', ').']';
}
\$L = 0;
\$R = 1;
}

return -1; // no unfold sequence
}
``````

echo interval_unfold_count(21, true);

will give something like:

``````0 - [0,0,0,0,0] sequence [L,L,L,L,L] value of L: -31 value of R: 1
1 - [0,0,0,0,1] sequence [L,L,L,L,R] value of L: -15 value of R: 17
2 - [0,0,0,1,0] sequence [L,L,L,R,L] value of L: -23 value of R: 9
3 - [0,0,0,1,1] sequence [L,L,L,R,R] value of L: -7 value of R: 25
4 - [0,0,1,0,0] sequence [L,L,R,L,L] value of L: -27 value of R: 5
5 - [0,0,1,0,1] sequence [L,L,R,L,R] value of L: -11 value of R: 21
``````
-

I wrote optimised version (PHP) based on Sabbir's observations. it looks that it works.

``````function interval_unfold_count(\$N) {
return \$N?ceil(log(abs(\$N)+(\$N<0?1:0),2)):0;
}
``````
-

I found that if you follow creating the tree like Sabbir did, for a certain N, looking for its closest power of two, and getting the exponent of this power is the solution. In fact this would be even faster. I added computations for negative numbers.

``````  public int interval_unfold_count ( int N ) {
boolean negativeN = false;
if (N == 0)
return -1;
if (N < 0) {
N = -N;
negativeN = true;
}
int pow2roundDown = pow2roundDown(N);
int result = pow2roundDown == 0 ? 0 : 32 - Integer.numberOfLeadingZeros(pow2roundDown - 1) + 1;
if (result > 32)
return -1;
if (negativeN && (1<<result) == N)
return result+1;
return result;
}

public boolean isPow2(int n) {
return ((n) & (n - 1)) == 0;
}

public int pow2roundDown(int x) {
if (x < 0)
return 0;
--x;
x |= x >> 1;
x |= x >> 2;
x |= x >> 4;
x |= x >> 8;
x |= x >> 16;
return x + 1 >> 1;
}

}
``````
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"I found that..." Ok now post the mathematical proof of that being true for any level N. –  Mister Smith Mar 7 '12 at 14:15