Find nearest points in a vector

Given a sorted vector with a number of values, as in the following example:

``````std::vector<double> f;
f.pushback(10);
f.pushback(100);
f.pushback(1000);
f.pushback(10000);
``````

I'm looking for the most elegant way to retrieve for any double d the two values that are immediately adjacent to it. For example, given the value "45", I'd like this to return "10" and "100".

I was looking at lower_bound and upper_bound, but they don't do what I want. Can you help?

EDIT: I've decided to post my own anser, as it is somewhat a composite of all the helpful answers that I got in this thread. I've voted up those answers which I thought were most helpful.

Thanks everyone,

Dave

-
There are edge cases where your question is not clear. What would you expect if you used the value "45" on the vector {44, 45, 46}? What about {44, 45, 45, 46}? – Drew Dormann Jan 22 '09 at 16:29
You're right, I should clarify. The values in the vector are unique, for starters. Second, I'm actually looking for the following two values: the one that is the largest that is smaller than the given, and the one that is the smallest that is larger or equal. – Dave Van den Eynde Jan 22 '09 at 19:45
Oh, and by elegant I don't mean the most efficient. I mean elegant as in use of the STL to write readable code (if there's such a thing). – Dave Van den Eynde Jan 22 '09 at 19:48

You can grab both values (if they exist) in one call with equal_range(). It returns a std::pair of iterators, with first being the first location and second being the last location in which you could insert the value passed without violating ordering. To strictly meet your criteria, you'd have to decrement the iterator in first, after verifying that it wasn't equal to the vector's begin().

-

You can use STL's lower_bound to get want you want in a few lines of code. lower_bound uses binary search under the hood, so your runtime is O(log n).

``````double val = 45;
double lower, upper;
std::vector<double>::iterator it;
it = lower_bound(f.begin(), f.end(), val);
if (it == f.begin()) upper = *it; // no smaller value  than val in vector
else if (it == f.end()) lower = *(it-1); // no bigger value than val in vector
else {
lower = *(it-1);
upper = *it;
}
``````
-
This will fail if there are multiple entries with the same value - just as upper_bound will fail (but for the other side of the comparison). – Harper Shelby Jan 22 '09 at 16:41
Shouldn't. If you look for 45 in {10, 10, 10, 100, 100, 100, ...} it will correctly find 10 and 100. – Martin Jan 22 '09 at 18:25
Thanks this snippet helped me to solve a similar problem. – Adamski Jun 13 '14 at 23:23

You could simply use a binary search, which will run in O(log(n)).

Here is a Lua snippet (I don't have time to do it in C++, sorry) which does what you want, except for limit conditions (that you did not define anyway) :

``````function search(value, list, first, last)
if not first then first = 1; last = #list end

if last - first < 2 then
return list[first], list[last]
end

local median = math.ceil(first + (last - first)/2)

if list[median] > value then
return search(value, list, first, median)
else
return search(value, list, median, last)
end
end

local list = {1,10,100,1000}

print(search(arg[1] + 0, list))
``````

It takes the value to search from the command line :

``````\$ lua search.lua 10 # didn't know what to do in this case
10  100
\$ lua search.lua 101
100 1000
\$ lua search.lua 99
10  100
``````
-
Since you have an already sorted list, a binary search is the way to go. – Ates Goral Jan 22 '09 at 16:47
True, but lower_bound, upper_bound, equal_range and some others are forms of a binary search. That still wouldn't get me the answers that I'm looking for per se, unless I do some postprocessing. – Dave Van den Eynde Jan 23 '09 at 9:09
I added a snippet to my answer to show you how you could do it. I did it in lua because my c++ is a bit rusty (and I don't have much time) but it should be easily translatable. – Wookai Jan 23 '09 at 14:54

I'm going to post my own anser, and vote anyone up that helped me to reach it, since this is what I'll use in the end, and you've all helped me reach this conclusion. Comments are welcome.

``````std::pair<value_type, value_type> GetDivisions(const value_type& from) const
{
if (m_divisions.empty())

std::vector<value_type>::const_iterator it =
std::lower_bound(m_divisions.begin(), m_divisions.end(), from);

if (it == m_divisions.end())
return std::make_pair(m_divisions.back(), m_divisions.back());
else if (it == m_divisions.begin())
return std::make_pair(m_divisions.front(), m_divisions.front());
else
return std::make_pair(*(it - 1), *(it));
}
``````
-
I didn't see this until after I'd written my second answer - not too shocking to see the structure of your function was very similar. – Harper Shelby Jan 23 '09 at 16:59
One question - won't this break down if 'from' is in the vector? In your initial problem, you had values 10,100,1000,10000. If 'from' is 100, you'll get <10,100> back, but shouldn't you get <10,1000>? – Harper Shelby Jan 23 '09 at 17:04

What if (in your case) d is less than the first element or more than the last? And how to deal with negative values? By the way: guaranteeing that your "d" lives between the first and the last value of your vector you can do like that:

``````// Your initializations
std::vector<double>::const_iterator sit = f.begin();
double upper, lower;
``````

Here is the rest:

``````while ( *sit < d )         // if the element is still less than your d

upper = *sit;              // here you get the upper value
lower = *(--sit);          // and here your lower
``````

Elegant enough? :/

-
Even though I'd still use lower_bound, which does what your code does, but using a binary search, the second part of your function made me reach my conclusion. – Dave Van den Eynde Jan 23 '09 at 9:30
Ok, glad to be useful to someone :) – tunnuz Jan 23 '09 at 13:58

You could do a search in your vector for your value (which would tell you where your value would be if it were in the vector) and then return the value before and after that location. So searching for 45 would tell you it should be at index=1 and then you would return 0 and 1 (depending on your implementation of the search, you'll either get the index of the smaller value or the index of the larger value, but this is easy to check with a couple boundary conditions). This should be able to run in O(log n) where n is the number of elements in your vector.

-
This looks to me like a linear search, which would be O(n). – Wookai Jan 22 '09 at 15:34
Since the vector is as in the example you can use binary search (O(logn)). – tunnuz Jan 22 '09 at 15:36
The STL linear search fails (value not present), lower_bound/upper_bound would work on sorted containers but are O(log N). – MSalters Jan 22 '09 at 15:39

I would write something like this, didn't test if this compiles, but you get the idea:

``````template <typename Iterator>
std::pair<Iterator, Iterator> find_best_pair(Iterator first, Iterator last, const typename Iterator::value_type & val)
{
std::pair<Iterator, Iterator> result(last, last);

typename Iterator::difference_type size = std::distance(first, last);

if (size == 2)
{
// if the container is of size 2, the answer is the two elements
result.first = first;
result.first = first;
++result.first;
}
else
{

// must be of at lease size 3
if (size > 2)
{
Iterator second = first;
++second;
Iterator prev_last = last;
--prev_last;
Iterator it(std::lower_bound(second, last, val));

if (it != last)
{

result.first = it;
result.second = it;

if (it != prev_last)
{
// if this is not the previous last
// then the answer is (it, it + 1)
++result.second;
}
else
{
// if this the previous last
// then the answer is (it - 1, it)
--result.first;
}

}

}

}

return result;

}
``````
-

I wrote up this little function, which seems to fit the more general case you wanted. I haven't tested it totally, but I did write a little test code (included).

``````#include <algorithm>
#include <iostream>
#include <vector>

template <class RandomAccessIt, class Container, class T>
std::pair<RandomAccessIt, RandomAccessIt> bracket_range(RandomAccessIt begin, RandomAccessIt end, Container& c, T val)
{
typename Container::iterator first;
typename Container::iterator second;

first = std::find(begin, end, val);
//Find the first value after this by iteration
second = first;
if (first == begin){ // Found the first element, so set this to end to indicate no lower values
first = end;
}
else if (first != end && first != begin) --first; //Set this to the first value before the found one, if the value was found
while (second != end && *second == val) ++second;
return std::make_pair(first,second);
}

int main(int argc, _TCHAR* argv[])
{
std::vector<int> values;
std::pair<std::vector<int>::iterator, std::vector<int>::iterator> vals;

for (int i = 1; i < 9; ++i) values.push_back(i);

for (int i = 0; i < 10; ++i){
vals = bracket_range(values.begin(), values.end(),values, i);
if (vals.first == values.end() && vals.second == values.end()){ // Not found at all
std::cout << i << " is not in the container." << std::endl;
}
else if (vals.first == values.end()){ // No value lower
std::cout << i << ": " << "None Lower," << *(vals.second) << std::endl;
}
else if (vals.second == values.end()) { // No value higher
std::cout << i << ": " << *(vals.first) << ", None Higher" << std::endl;
}
else{
std::cout << i << ": " << *(vals.first) << "," << *(vals.second) << std::endl;
}
}
return 0;
}
``````
-

Based on the code that tunnuz posted, here you have some improvements regarding bound checking:

``````template<typename T>
void find_enclosing_values(const std::vector<T> &vec, const T &value, T &lower, T &upper, const T &invalid_value)
{
std::vector<T>::const_iterator it = vec.begin();

while (it != vec.end() && *it < value)
++it;

if(it != vec.end())
upper = *it;
else
upper = invalid_value;

if(it == vec.begin())
lower = invalid_value;
else
lower = *(--it);

}
``````

Example of usage:

``````std::vector<int> v;

v.push_back(3);
v.push_back(7);
v.push_back(10);

int lower, upper;

find_enclosing_values(v, 4, lower, upper, -1);

std::cout<<"lower "<<lower<<" upper "<<upper<<std::endl;
``````
-
I'm sorry, but I haven't done C++ in a while now, and I'm not even working on that job anymore, so I can't verify if this is right. – Dave Van den Eynde Oct 3 '12 at 19:30

If you have the ability to use some other data structure (not a vector), I'd suggest a B-tree. If you data is unchanging, I believe you can retrieve the result in constant time (logarithmic time at the worst).

-