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I saw this question on Reddit, and there were no positive solutions presented, and I thought it would be a perfect question to ask here. This was in a thread about interview questions:

Write a method that takes an int array of size m, and returns (True/False) if the array consists of the numbers n...n+m-1, all numbers in that range and only numbers in that range. The array is not guaranteed to be sorted. (For instance, {2,3,4} would return true. {1,3,1} would return false, {1,2,4} would return false.

The problem I had with this one is that my interviewer kept asking me to optimize (faster O(n), less memory, etc), to the point where he claimed you could do it in one pass of the array using a constant amount of memory. Never figured that one out.

Along with your solutions please indicate if they assume that the array contains unique items. Also indicate if your solution assumes the sequence starts at 1. (I've modified the question slightly to allow cases where it goes 2, 3, 4...)

edit: I am now of the opinion that there does not exist a linear in time and constant in space algorithm that handles duplicates. Can anyone verify this?

The duplicate problem boils down to testing to see if the array contains duplicates in O(n) time, O(1) space. If this can be done you can simply test first and if there are no duplicates run the algorithms posted. So can you test for dupes in O(n) time O(1) space?

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1  
heres a problem array for the challengers: [1,1,4,4,5]. should = false. summation thinks its fine. –  Kent Fredric Oct 7 '08 at 3:56
1  
Um, you say that {1,3,1} should return false, but m here is 3, n = 1, all the numbers in the array are in the range 1..3, so I argue that this should return true according to the description of the problem. –  paxos1977 Oct 10 '08 at 0:42
1  
@Marcin: factorial counter-example: [1, 2, 4, 4, 4, 5, 7, 9, 9]. Product (9! = 362880) and sum (45) are the same with [1, 2, 3, 4, 5, 6, 7, 8, 9]. –  J.F. Sebastian Oct 19 '08 at 19:22

38 Answers 38

If that was a typo and the question is about all numbers being in range 1...n instead, then:

def try_arr(arr):
    n = len(arr)
    return (not any(x<1 or x>n for x in arr)) and sum(arr)==n*(n+1)/2

$ print try_arr([1,2,3])
True

$ print try_arr([1,3,1])
False

$ print try_arr([1,2,4])
False

Notes:

  • I am using the definition from the original version that numbers start from 1. Sure code can be modified to account for starting from another number.

  • If the size of the array (n) was known, you could modify this to stream data from e.g., input file, and use almost no memory (1 temp variable inside sum() and 1 variable for the current item taken from the stream)

  • any() is new in python 2.5 (but you have alternative ways to express the same thing in earlier versions of python)

  • it uses O(n) time O(1) space. (update: i wrote it does account for duplicates, but apparently that is not true as demonstrated by a comment to another answer here).

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Fail := False; Sum1 := 0; Sum2 := 0; TSum1 := 0; TSum2 := 0;

For i := 1 to m do
  Begin
    TSum1 := TSum1 + i;
    TSum2 := TSum2 + i * i;
    Item := Array[i] - n;
    If (Item < 0) or (Item >= m) then 
      Fail := True
    Else 
      Begin
        Sum1 := Sum1 + Item;
        Sum2 := Sum2 + Item * Item;
      End;
  End;
Fail := Fail Or (Sum1 <> TSum1) or (Sum2 <> TSum2);

Tired and no compiler but I think this gives O(m) runtime and can't be fooled.

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It seems like we could check for duplicates by multiplying all the numbers n...n+m together, and then comparing that value to the expected product of a sequence with no duplicates m!/(n-1)! (note that this assumes it is impossible for a sequence to pass both the expected sum test and the expected product test).

So adding to hazzen's pseudo-code, we have:

is_range(int[] nums, int n, int m) {
  sum_to_m := (m * (m + 1)) / 2
  expected_sum := sum_to_m - (n * (n - 1)) / 2
  real_sum := sum(nums)
  expected_product := m! / (n - 1)!
  real_product := product(nums)
  return ((real_sum == expected_sum) && (expected_product == real_product))


EDIT: Here's my solution in Java using the Sum of Squares to check for duplicates. It also handles any range (including negative numbers) by shifting the sequence to start at 1.

// low must be less than high
public boolean isSequence(int[] nums, int low, int high) {
    int shift = 1 - low;
    low += shift;
    high += shift;

    int sum = 0;
    int sumSquares = 0;
    for (int i = 0; i < nums.length; i++) {
        int num = nums[i] + shift;

        if (num < low)
            return false;
        else if (num > high)
            return false;

        sum += num;
        sumSquares += num * num;
    }

    int expectedSum = (high * (high + 1)) / 2;

    if (sum != expectedSum)
        return false;

    int expectedSumSquares = high * (high + 1) * (2 * high + 1) / 6;

    if (sumSquares != expectedSumSquares)
        return false;

    return true;
}
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How about using XOR with even and odd numbers separately. Think about bit level not integer value itself.

bool is_same(const int* a, const int* b, int len)
{
    int even_xor = 0; 
    int odd_xor = 0;

    for(int i=0;i<len;++i)
    {
        if(a[i] & 0x01) odd_xor ^= a[i];
        else even_xor ^= a[i];

        if(b[i] & 0x01) odd_xor ^= b[i];
        else even_xor ^= b[i];
    }

    return (even_xor == 0) && (odd_xor == 0);
}
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I don't think I explained myself in my original post well (below the solid line). For an input of [1 2 3 4 5], for example, the algorithm computes the sum:

-1 + 2 - 3 + 4 - 5

which should be equal to

-1^5 * ceil(5/2)

The pseudo-code below shows how vectors that do not begin at 1 are checked. The algorithm handles cases where the input vector is not sorted and/or it contains duplicates.


The following algorithm solves the problem by calculating the alternating sums of the vector elements:

-1 + 2 - 3 + 4 - 5 + .... + m = (-1)^m * ceil(m/2)

where ceil rounds up to the closest integer. In other words, odd numbers are subtracted from the running total and even numbers are added to it.

function test(data, m)
    altSum = 0
    n = Inf
    mCheck = -Inf
    for ii = 1:m
    {
        if data(ii) < n
            n = data(ii)
        if data(ii) > mCheck
            mCheck = data(ii)
        altSum = altSum + (-1)^data(ii) * data(ii)
    }
    if ((mCheck-n+1!=m) || (-1)^(n+m-1) * ceil((n+m-1)/2) - ((-1)^(n-1) * ceil((n-1)/2)) != altSum
        return false
    else
        return true
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I suppose the question boils down to ensuring that

(maximum - minimum + 1) == array_size

and this can obviously be done in O(N) time and O(1) space as follows :

int check_range(int input[], int N){
    int max = -INFINITY, min = INFINITY, i;
    for(i=0; i<N; i++){
        if(input[i] < min) min=input[i];
        if(input[i] > max) max=input[i];
    }
    return (max - min + 1) == N;
}

Note that this approach takes care of possibility of duplicates. Please report any discrepancy in the solution.

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Linear in time, constant in space solution for int m

Constant space is achieved by exploiting a sign bit. It can be done for any mutable int range if m is less than INT_MAX i.e., when the input range [n, n+m) can be shifted to [1, m+1) range if n is not positive. In practice, the precondition is almost always true if input is mutable.

/** gcc -std=c99 ... */
#include <assert.h>
#include <iso646.h>  // and, or
#include <limits.h>  // INT_MIN
#include <stdbool.h> // bool
#include <stdlib.h>  // abs()

bool inrange(int m; int a[m], int m, int n)
{
  /** Whether min(a[]) == n and max(a[]) == n+(m-1)
  */
  if (m == 0) return true; // empty range is a valid range

  // check out-of-range values
  int max = INT_MIN, min = INT_MAX;
  for (int i = 0; i < m; ++i) {
    if (min > a[i]) min = a[i];
    if (max < a[i]) max = a[i];
  }
  return (min == n and max == n+(m-1));
}

bool isperm_minus2(int m; int a[m], int m, int n)
{
  /** O(m) in time, O(1) in space (for 'typeof(m) == typeof(*a) == int')

      Whether a[] is a permutation of the range [n, n+m).

      feature: It marks visited items using a sign bit.
  */
  if (not inrange(a, m, n))
    return false; // out of range

  assert((INT_MIN - (INT_MIN - 1)) == 1); // check n == INT_MIN
  for (int *p = a; p != &a[m]; ++p) {
    *p -= (n - 1); // [n, n+m) -> [1, m+1)
    assert(*p > 0);
  }

  // determine: are there duplicates
  bool has_duplicates = false;
  for (int i = 0; i < m; ++i) {
    const int j = abs(a[i]) - 1;
    assert(j >= 0);
    assert(j < m);
    if (a[j] > 0)
      a[j] *= -1; // mark
    else { // already seen
      has_duplicates = true;
      break;
    }
  }

  // restore the array
  for (int *p = a; p != &a[m]; ++p) {
    if (*p < 0) 
      *p *= -1; // unmark
    // [1, m+1) -> [n, n+m)
    *p += (n - 1);        
  }

  return not has_duplicates; // no duplicates? (+ inrange)
}
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I don't think you need to use sums at all. Just check the minimum and maximum and check for dupes. Checking for dupes is the harder part, since you don't know n in advance, so you cannot sort in one pass. To work around that, relax the condition on the (edit:destination) array. Instead of requiring it to be sorted, go for a cyclical shift of a sorted sequence, so that the array goes [k,k+1,..., n+m-2, n+m-1,n,n+1, ... ,k-2,k-1] for some k.

With the condition above, you can assume that a[0] is already in the right position, then the right position for an element d is (d-a[0]) mod m, assuming zero-based array indexing. For example with [4,?,?,?] you can expect [4,5,6,7] or [4,1,2,3] or [4,5,6,3] or [4,5,2,3].

Then just scan the array once, putting each element in its calculated position, updating the min and max and checking for clashes. If there are no clashes and max-min=m, then the condition is met, otherwise it is false.

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