120

I need a binary search algorithm that is compatible with the C++ STL containers, something like std::binary_search in the standard library's <algorithm> header, but I need it to return the iterator that points at the result, not a simple boolean telling me if the element exists.

(On a side note, what the hell was the standard committee thinking when they defined the API for binary_search?!)

My main concern here is that I need the speed of a binary search, so although I can find the data with other algorithms, as mentioned below, I want to take advantage of the fact that my data is sorted to get the benefits of a binary search, not a linear search.

so far lower_bound and upper_bound fail if the datum is missing:

//lousy pseudo code
vector(1,2,3,4,6,7,8,9,0) //notice no 5
iter = lower_bound_or_upper_bound(start,end,5)
iter != 5 && iter !=end //not returning end as usual, instead it'll return 4 or 6

Note: I'm also fine using an algorithm that doesn't belong to the std namespace as long as its compatible with containers. Like, say, boost::binary_search.

9
  • 2
    Regarding the edit: that's why std::equal_range is the solution. Otherwise, you'll have to test for equality (or equivalence to be more) Jan 15, 2009 at 10:56
  • You have to test for equality after using (lower/upper)_bound (see answer below). Jan 15, 2009 at 10:56
  • 1
    lower_bound and upper_bound documentation state that the range must be sorted, and because of this they can be implemented as binary search.
    – vividos
    Jan 15, 2009 at 11:02
  • @vividos, hurray! you found just the piece of documentation I needed to know about! Thanks! Jan 15, 2009 at 11:04
  • Robert, the lower/upper_bound/equal_range algorithms do not work with unsorted ranges. You're just lucky to see them working with the elements sample you took. Jan 15, 2009 at 11:04

9 Answers 9

105

There is no such functions, but you can write a simple one using std::lower_bound, std::upper_bound or std::equal_range.

A simple implementation could be

template<class Iter, class T>
Iter binary_find(Iter begin, Iter end, T val)
{
    // Finds the lower bound in at most log(last - first) + 1 comparisons
    Iter i = std::lower_bound(begin, end, val);

    if (i != end && !(val < *i))
        return i; // found
    else
        return end; // not found
}

Another solution would be to use a std::set, which guarantees the ordering of the elements and provides a method iterator find(T key) that returns an iterator to the given item. However, your requirements might not be compatible with the use of a set (for example if you need to store the same element multiple times).

14
  • yes this works, and I have a similar implementation right now, however it's a "naive" implementation, in the sense that it's not making use of the situation's context, in this case sorted data. Jan 15, 2009 at 10:59
  • 8
    I don't really understand your comment, since lower_bound can only be used on sorted data. Complexity is lower than using find (see edit). Jan 15, 2009 at 11:02
  • 4
    To complement Luc's answer, check Matt Austern's classic article Why You Shouldn't Use set, and What You Should Use Instead (C++ Report 12:4, April 2000) to understand why binary search with sorted vectors is usually preferable to std::set, which is a tree-based associative container.
    – ZunTzu
    Nov 3, 2012 at 12:46
  • 18
    Don't use *i == val! Rather use !(val < *i). The reason is that lower_bound uses <, not == (i.e. T is not even required to be equality-comparable). (See Scott Meyers' Effective STL for an explanation of the difference between equality and equivalence.)
    – gx_
    Jul 9, 2013 at 16:22
  • 2
    @CanKavaklıoğlu There is no element located at end. Ranges in the C++ standard library are represented with half-open intervals: the end iterator "points" after the last element. As such, it can be returned by algorithms to indicate that no value was found. Nov 3, 2015 at 21:22
10

You should have a look at std::equal_range. It will return a pair of iterators to the range of all results.

2
  • According to cplusplus.com/reference/algorithm/equal_range the cost of std::equal_range is approximately twice as high as std::lower_bound. It appears that it wraps a call to std::lower_bound and a call to std::upper_bound. If you know your data doesn't have duplicates then that is overkill and std::lower_bound (as demonstrated in the top answer) is the best choice. Jun 22, 2015 at 23:40
  • @BruceDawson: cplusplus.com only gives a reference implementation to specify the behavior; for an actual implementation you can check your favorite standard library. For example, in llvm.org/svn/llvm-project/libcxx/trunk/include/algorithm we can see that the calls to lower_bound and upper_bound are made on disjoint intervals (after some manual binary search). That being said, it is likely to be more expensive, especially on ranges with multiple values matching. Sep 27, 2017 at 14:58
6

There is a set of them:

http://www.sgi.com/tech/stl/table_of_contents.html

Search for:

On a separate note:

They were probably thinking that searching containers could term up more than one result. But on the odd occasion where you just need to test for existence an optimized version would also be nice.

4
  • 4
    binary_search doesn't return an iterator as I mentioned earlier, that's why I'm looking for an alternative. Jan 15, 2009 at 10:43
  • 1
    Yes, I know. But it fits in the set of binary search algorithms. So its nice for others to know about. Jan 15, 2009 at 10:44
  • 10
    binary_search is just, like so many other things in the STL, named wrong. I hate that. Testing for existence is not the same as searching for something. Jan 15, 2009 at 10:53
  • 2
    These binary search functions are not useful in case where you want to know the index of the element you are looking for. I have to write my own recursive function for this task. I hope this, template<class T> int bindary_search(const T& item), should be added to the next version of C++.
    – Kemin Zhou
    Jul 28, 2016 at 22:52
3

If std::lower_bound is too low-level for your liking, you might want to check boost::container::flat_multiset. It is a drop-in replacement for std::multiset implemented as a sorted vector using binary search.

1
  • 1
    Good link; and also good link in the link: lafstern.org/matt/col1.pdf, which describes how lookups implemented with a sorted vector, rather than set (though both are log(N)), have significantly better constants of proportionality and are ~twice as fast (the disadvantage being a larger INSERTION time). Apr 14, 2013 at 20:00
3

The shortest implementation, wondering why it's not included in the standard library:

template<class ForwardIt, class T, class Compare=std::less<>>
ForwardIt binary_find(ForwardIt first, ForwardIt last, const T& value, Compare comp={})
{
    // Note: BOTH type T and the type after ForwardIt is dereferenced 
    // must be implicitly convertible to BOTH Type1 and Type2, used in Compare. 
    // This is stricter than lower_bound requirement (see above)

    first = std::lower_bound(first, last, value, comp);
    return first != last && !comp(value, *first) ? first : last;
}

From https://en.cppreference.com/w/cpp/algorithm/lower_bound

1
  • I can think of two reasons this is not in the standard library: They think it is easy to implement, but the major reason is probably that it may require a reversed version of operator()() if value is not interchangeable with *first.
    – user877329
    May 6, 2020 at 19:55
2
int BinarySearch(vector<int> array,int var)
{ 
    //array should be sorted in ascending order in this case  
    int start=0;
    int end=array.size()-1;
    while(start<=end){
        int mid=(start+end)/2;
        if(array[mid]==var){
            return mid;
        }
        else if(var<array[mid]){
            end=mid-1;
        }
        else{
            start=mid+1;
        }
    }
    return 0;
}

Example: Consider an array, A=[1,2,3,4,5,6,7,8,9] Suppose you want to search the index of 3 Initially, start=0 and end=9-1=8 Now, since start<=end; mid=4; (array[mid] which is 5) !=3 Now, 3 lies to the left of mid as its smaller than 5. Therefore, we only search the left part of the array Hence, now start=0 and end=3; mid=2.Since array[mid]==3, hence we got the number we were searching for. Hence, we return its index which is equal to mid.

3
  • 1
    It's good to have code, but you could improve the answer by providing a brief explanation of how it works for people who are new to the language.
    – Taegost
    Feb 12, 2018 at 20:17
  • Somebody incorrectly flagged your post as low-quality. A code-only answer is not low-quality. Does it attempt to answer the question? If not, flag as 'not an answer' or recommend deletion (if in the review queue). b) Is it technically incorrect? Downvote or comment.
    – Wai Ha Lee
    Feb 12, 2018 at 23:13
  • Not sure about how this compares in terms of actual runtime against the std:lower_bound solution, but personally I much prefer this nice and readable solution. It is a clean and simple implementation of binary search returning an index. No idea why this is so poorly rated!! And yes, it's not a template and yes, it doesn't return an iterator - but shall we have a poll how many people do binary search on anything other than a vector of ints? Oct 29, 2020 at 22:48
1

Check this function, qBinaryFind:

RandomAccessIterator qBinaryFind ( RandomAccessIterator begin, RandomAccessIterator end, const T & value )

Performs a binary search of the range [begin, end) and returns the position of an occurrence of value. If there are no occurrences of value, returns end.

The items in the range [begin, end) must be sorted in ascending order; see qSort().

If there are many occurrences of the same value, any one of them could be returned. Use qLowerBound() or qUpperBound() if you need finer control.

Example:

QVector<int> vect;
 vect << 3 << 3 << 6 << 6 << 6 << 8;

 QVector<int>::iterator i =
         qBinaryFind(vect.begin(), vect.end(), 6);
 // i == vect.begin() + 2 (or 3 or 4)

The function is included in the <QtAlgorithms> header which is a part of the Qt library.

1
  • 1
    Unfortunately this algorithm isn't compatible with STL containers. Jul 30, 2013 at 14:48
0

std::lower_bound() :)

1
  • OP: "so far lower_bound and upper_bound fail, because..." Jul 10, 2016 at 20:07
0

A solution returning the position inside the range could be like this, using only operations on iterators (it should work even if iterator does not arithmetic):

template <class InputIterator, typename T>
size_t BinarySearchPos(InputIterator first, InputIterator last, const T& val)
{       
    const InputIterator beginIt = first;
    InputIterator element = first;
    size_t p = 0;
    size_t shift = 0;
    while((first <= last)) 
    {
        p = std::distance(beginIt, first);
        size_t u = std::distance(beginIt, last);
        size_t m = p + (u-p)/2;  // overflow safe (p+u)/2
        std::advance(element, m - shift);
        shift = m;
        if(*element == val) 
            return m; // value found at position  m
        if(val > *element)
            first = element++;
        else
            last  = element--;

    }
    // if you are here the value is not present in the list, 
    // however if there are the value should be at position u
    // (here p==u)
    return p;

}

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