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Let's say I have a set of integers. I want to find the longest increasing subsequence of that set using dynamic programming. This is simply out of practice, reviewing my old notes from my algorithms course, and I don't seem to understand how this works.

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5 Answers 5

up vote 117 down vote accepted

OK, I will describe first the simplest solution which is O(N^2), where N is the size of the set. There also exists a O(N log N) solution, which I will describe also. Look here for it at the section Efficient algorithms.

I will assume the indices of the array are from 0 to N-1. So let's define DP[i] to be the length of the LIS(Longest increasing subsequence) which is ending at element with index i. To compute DP[i] we look at all indices j < i and check both if DP[j] + 1 > DP[i] and array[j] < array[i](we want it to be increasing). If this is true we can update the current optimum for DP[i]. To find the global optimum for the array you can take the maximum value from DP[0..N-1].

int maxLength = 1, bestEnd = 0;
DP[0] = 1;
prev[0] = -1;

for (int i = 1; i < N; i++)
{
   DP[i] = 1;
   prev[i] = -1;

   for (int j = i - 1; j >= 0; j--)
      if (DP[j] + 1 > DP[i] && array[j] < array[i])
      {
         DP[i] = DP[j] + 1;
         prev[i] = j;
      }

   if (DP[i] > maxLength)
   {
      bestEnd = i;
      maxLength = DP[i];
   }
}

I use the array prev to be able later to find the actual sequence not only its length. Just go back recursively from bestEnd in a loop using prev[bestEnd]. The -1 value is a sign to stop.

OK, now to the more efficient O(N log N) solution:

Let S[pos] be defined as the smallest integer that ends an increasing sequence of length pos.

Now iterate through every integer X of the input set and do the following:

  1. If X > last element in S, then append X to the end of S. This essentialy means we have found a new largest LIS.

  2. Otherwise find the smallest element in S, which is >= than X, and change it to X. Because S is sorted at any time, the element can be found using binary search in log(N).

Total runtime - N integers and a binary search for each of them - N * log(N) = O(N log N)

Now let's do a real example:

Set of integers: 2 6 3 4 1 2 9 5 8

Steps:

0. S = {} - Initialize S to the empty set
1. S = {2} - New largest LIS
2. S = {2, 6} - New largest LIS
3. S = {2, 3} - Changed 6 to 3
4. S = {2, 3, 4} - New largest LIS
5. S = {1, 3, 4} - Changed 2 to 1
6. S = {1, 2, 4} - Changed 3 to 2
7. S = {1, 2, 4, 9} - New largest LIS
8. S = {1, 2, 4, 5} - Changed 9 to 5
9. S = {1, 2, 4, 5, 8} - New largest LIS

So the length of the LIS is 5 (the size of S).

To reconstruct the actual LIS we will again use a parent array. Let parent[i] be the predecessor of element with index i in the LIS ending at element with index i.

To make things simpler, we can keep in the array S, not the actual integers, but their indices(positions) in the set. We do not keep {1, 2, 4, 5, 8}, but keep {4, 5, 3, 7, 8}.

That is input[4] = 1, input[5] = 2, input[3] = 4, input[7] = 5, input[8] = 8.

If we update properly the parent array, the actual LIS is:

input[S[lastElementOfS]], 
input[parent[S[lastElementOfS]]],
input[parent[parent[S[lastElementOfS]]]],
........................................

Now to the important thing - how do we update the parent array? There are two options:

  1. If X > last element in S, then parent[indexX] = indexLastElement. This means the parent of the newest element is the last element. We just prepend X to the end of S.

  2. Otherwise find the index of the smallest element in S, which is >= than X, and change it to X. Here parent[indexX] = S[index - 1].

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Great explanation, thanks so much –  Tony Apr 13 '10 at 17:44
    
You are welcome:) –  Petar Minchev Apr 13 '10 at 17:46
2  
@Cupidvogel - The answer is [2,3,4,5,8]. Read carefully - the S array DOES NOT represent an actual sequence. Let S[pos] be defined as the smallest integer that ends an increasing sequence of length pos. –  Petar Minchev Nov 22 '12 at 8:26
1  
@PetarMinchev Thanks for the great description. Just one question, this algorithm wont find ALL the subsequences right? It will return just one Subsequence? –  Kraken Jan 19 at 14:54
1  
I don't often see such clear explanations. Not only it's very easy to understand, because the doubts are cleared within the explanation, but also it addresses any implementation problem that might arise. Awesome. –  Charles W. Apr 16 at 12:46
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Petar Minchev's explanation helped clear things up for me, but it was hard for me to parse what everything was, so I made a Python implementation with overly-descriptive variable names and lots of comments. I did a naive recursive solution, the O(n^2) solution, and the O(n log n) solution.

I hope it helps clear up the algorithms!

The Recursive Solution

def recursive_solution(remaining_sequence, bigger_than=None):                    
  """Finds the longest increasing subsequence of remaining_sequence that is      
  bigger than bigger_than and returns it.  This solution is O(2^n)."""           
  # Base case: nothing is remaining.                                             
  if len(remaining_sequence) == 0:                                               
    return remaining_sequence                                                    
  # Recursive case 1: exclude the current element and process the remaining.     
  best_sequence = recursive_solution(remaining_sequence[1:], bigger_than)        
  # Recursive case 2: include the current element if it's big enough.            
  first = remaining_sequence[0]                                                  
  if (first > bigger_than) or (bigger_than is None):                             
    sequence_with = [first] + recursive_solution(remaining_sequence[1:], first)  
    # Choose whichever of case 1 and case 2 were longer.                         
    if len(sequence_with) >= len(best_sequence):                                 
      best_sequence = sequence_with                                              
  return best_sequence                                                           

The O(n^2) Dynamic Programming Solution

def dynamic_programming_solution(sequence):                                      
  """Finds the longest increasing subsequence in sequence using dynamic          
  programming.  This solution is O(n^2)."""                                      
  longest_subsequence_ending_with = []                                           
  backreference_for_subsequence_ending_with = []                                 
  current_best_end = 0                                                           
  for curr_elem in range(len(sequence)):                                         
    # It's always possible to have a subsequence of length 1.                    
    longest_subsequence_ending_with.append(1)                                    
    # If a subsequence is length 1, it doesn't have a backreference.             
    backreference_for_subsequence_ending_with.append(None)                       
    for prev_elem in range(curr_elem):                                           
      subsequence_length_through_prev = (                                        
          longest_subsequence_ending_with[prev_elem] + 1)                        
      # If the prev_elem is smaller than the current elem (so it's increasing)   
      # And if the longest subsequence from prev_elem would yield a better       
      # subsequence for curr_elem.                                               
      if ((sequence[prev_elem] < sequence[curr_elem]) and                        
          (subsequence_length_through_prev >                                     
           longest_subsequence_ending_with[curr_elem])):                         
        # Set the candidate best subsequence at curr_elem to go through prev.    
        longest_subsequence_ending_with[curr_elem] = (                           
            subsequence_length_through_prev)                                     
        backreference_for_subsequence_ending_with[curr_elem] = prev_elem         
    # If the new end is the best, update the best.                               
    if (longest_subsequence_ending_with[curr_elem] >                             
        longest_subsequence_ending_with[current_best_end]):                      
      current_best_end = curr_elem                                               
  # Output the overall best by following the backreferences.                     
  best_subsequence = []                                                          
  current_backreference = current_best_end                                       
  while current_backreference is not None:                                       
    best_subsequence.append(sequence[current_backreference])                     
    current_backreference = (                                                    
        backreference_for_subsequence_ending_with[current_backreference])        
  best_subsequence.reverse()                                                     
  return best_subsequence                                                        

The O(n log n) Dynamic Programming Solution

def find_smallest_elem_as_big_as(sequence, subsequence, elem):                   
  """Returns the index of the smallest element in subsequence as big as          
  sequence[elem].  sequence[elem] must not be larger than every element in       
  subsequence.  The elements in subsequence are indices in sequence.  Uses       
  binary search."""                                                              
  low = 0                                                                        
  high = len(subsequence) - 1                                                    
  while high > low:                                                              
    mid = (high + low) / 2                                                       
    # If the current element is not as big as elem, throw out the low half of    
    # sequence.                                                                  
    if sequence[subsequence[mid]] < sequence[elem]:                              
      low = mid + 1                                                              
    # If the current element is as big as elem, throw out everything bigger, but 
    # keep the current element.                                                  
    else:                                                                        
      high = mid                                                                 
  return high    

def optimized_dynamic_programming_solution(sequence):                            
  """Finds the longest increasing subsequence in sequence using dynamic          
  programming and binary search (per                                             
  http://en.wikipedia.org/wiki/Longest_increasing_subsequence).  This solution   
  is O(n log n)."""                                                              
  # Both of these lists hold the indices of elements in sequence and not the        
  # elements themselves.                                                         
  # This list will always be sorted.                                             
  smallest_end_to_subsequence_of_length = []                                     
  # This array goes along with sequence (not                                     
  # smallest_end_to_subsequence_of_length).  Following the corresponding element 
  # in this array repeatedly will generate the desired subsequence.              
  parent = [None for _ in sequence]                                              
  for elem in range(len(sequence)):                                              
    # We're iterating through sequence in order, so if elem is bigger than the   
    # end of longest current subsequence, we have a new longest increasing          
    # subsequence.                                                               
    if (len(smallest_end_to_subsequence_of_length) == 0 or                       
        sequence[elem] > sequence[smallest_end_to_subsequence_of_length[-1]]):   
      # If we are adding the first element, it has no parent.  Otherwise, we        
      # need to update the parent to be the previous biggest element.            
      if len(smallest_end_to_subsequence_of_length) > 0:                         
        parent[elem] = smallest_end_to_subsequence_of_length[-1]                 
      smallest_end_to_subsequence_of_length.append(elem)                         
    else:                                                                        
      # If we can't make a longer subsequence, we might be able to make a        
      # subsequence of equal size to one of our earlier subsequences with a         
      # smaller ending number (which makes it easier to find a later number that 
      # is increasing).                                                          
      # Thus, we look for the smallest element in                                
      # smallest_end_to_subsequence_of_length that is at least as big as elem       
      # and replace it with elem.                                                
      # This preserves correctness because if there is a subsequence of length n 
      # that ends with a number smaller than elem, we could add elem on to the   
      # end of that subsequence to get a subsequence of length n+1.              
      location_to_replace = find_smallest_elem_as_big_as(                        
          sequence, smallest_end_to_subsequence_of_length, elem)                 
      smallest_end_to_subsequence_of_length[location_to_replace] = elem          
      # If we're replacing the first element, we don't need to update its parent 
      # because a subsequence of length 1 has no parent.  Otherwise, its parent  
      # is the subsequence one shorter, which we just added onto.                
      if location_to_replace != 0:                                               
        parent[elem] = (                                                         
            smallest_end_to_subsequence_of_length[location_to_replace - 1])         
  # Generate the longest increasing subsequence by backtracking through parent.  
  curr_parent = smallest_end_to_subsequence_of_length[-1]                        
  longest_increasing_subsequence = []                                            
  while curr_parent is not None:                                                 
    longest_increasing_subsequence.append(sequence[curr_parent])                 
    curr_parent = parent[curr_parent]                                            
  longest_increasing_subsequence.reverse()                                       
  return longest_increasing_subsequence         
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Your optimized algorithm is incorrect. Please test the case when sequence is 5, 19, 5, 81, 50, 28, 29, 1, 83, 23. Your algorithm returns 5, 19, 81, 83 when it should return 5, 19, 28, 29, 83. –  Johan S Jan 27 at 8:52
1  
Are you sure? When I run optimized_dynamic_programming_solution([5, 19, 5, 81, 50, 28, 29, 1, 83, 23]) on my computer, it returns [5, 19, 28, 29, 83]. –  Sam King Feb 24 at 7:01
    
Although I appreciate the effort here, my eyes hurt when I stare at those pseudo-codes. –  mostruash Jun 12 at 9:01
    
mostruash -- I'm not sure what you mean. My answer doesn't have pseudo code; it has Python. –  Sam King Jun 12 at 15:39
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Note: adding code that also shows how to print out the array sequence after taking some time to figure this out with help.

std::vector<int> getLIS ( const std::vector<int>& s )
{
  int bestEnd = 0;
  int sz = s.size();
  if ( !sz )
    return std::vector<int>();

  std::vector<int> prev(sz,-1);
  std::vector<int> memo(s.size(), 0);

  int maxLength = std::numeric_limits<int>::min();

  memo[0] = 1;

  for ( auto i = 1; i < sz; ++i)
  {
    for ( auto j = 0; j < i; ++j)
    {
      if ( s[j] < s[i] && memo[i] < memo[j] + 1 )
      {
        memo[i] =  memo[j] + 1;
        prev[i] =  j;
      }
    }

    if ( memo[i] > maxLength ) 
    {
      bestEnd = i;
      maxLength = memo[i];
    }
  }

  std::vector<int> results;
  results.reserve(sz);

  std::stack<int> stk;
  int current = bestEnd;
  while (current!=-1)
  {
    stk.push(s[current]);
    current = prev[current];
  }

  while (!stk.empty())
  {
    results.push_back(stk.top());
    stk.pop();
  }

  return results;
}
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Here are three steps of evaluating the problem from dynamic programming point of view:

  1. Recurrence definition: maxLength(i) == 1 + maxLength(j) where 0 < j < i and array[i] > array[j]
  2. Recurrence parameter boundary: there might be 0 to i - 1 sub-sequences passed as a paramter
  3. Evaluation order: as it is increasing sub-sequence, it has to be evaluated from 0 to n

If we take as an example sequence {0, 8, 2, 3, 7, 9}, at index:

  • [0] we'll get subsequence {0} as a base case
  • [1] we have 1 new subsequence {0, 8}
  • [2] trying to evaluate two new sequences {0, 8, 2} and {0, 2} by adding element at index 2 to existing sub-sequences - only one is valid, so adding third possible sequence {0, 2} only to parameters list ...

Here's the working C++11 code:

#include <iostream>
#include <vector>

int getLongestIncSub(const std::vector<int> &sequence, size_t index, std::vector<std::vector<int>> &sub) {
    if(index == 0) {
        sub.push_back(std::vector<int>{sequence[0]});
        return 1;
    }

    size_t longestSubSeq = getLongestIncSub(sequence, index - 1, sub);
    std::vector<std::vector<int>> tmpSubSeq;
    for(std::vector<int> &subSeq : sub) {
        if(subSeq[subSeq.size() - 1] < sequence[index]) {
            std::vector<int> newSeq(subSeq);
            newSeq.push_back(sequence[index]);
            longestSubSeq = std::max(longestSubSeq, newSeq.size());
            tmpSubSeq.push_back(newSeq);
        }
    }
    std::copy(tmpSubSeq.begin(), tmpSubSeq.end(),
              std::back_insert_iterator<std::vector<std::vector<int>>>(sub));

    return longestSubSeq;
}

int getLongestIncSub(const std::vector<int> &sequence) {
    std::vector<std::vector<int>> sub;
    return getLongestIncSub(sequence, sequence.size() - 1, sub);
}

int main()
{
    std::vector<int> seq{0, 8, 2, 3, 7, 9};
    std::cout << getLongestIncSub(seq);
    return 0;
}
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This can be solved in O(n^2) using Dynamic Programming. Python code for the same would be like:-

def LIS(numlist):
    LS = [1]
    for i in range(1, len(numlist)):
        LS.append(1)
        for j in range(0, i):
            if numlist[i] > numlist[j] and LS[i]<=LS[j]:
                LS[i] = 1 + LS[j]
    print LS
    return max(LS)

numlist = map(int, raw_input().split(' '))
print LIS(numlist)

For input:5 19 5 81 50 28 29 1 83 23

output would be:[1, 2, 1, 3, 3, 3, 4, 1, 5, 3] 5

The list_index of output list is the list_index of input list. The value at a given list_index in output list denotes the Longest increasing subsequence length for that list_index.

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protected by Community Dec 21 '11 at 14:14

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