Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

Let's say I'm using a map that uses three strings as a key. Here's a quick example struct:

struct ExampleMapKey
{
 std::string key0;
 std::string key1;
 std::string key2;

 bool operator<(const ExampleMapKey& other) const
 {
  if (key0 < other.key0) return true;
  else if (key0 > other.key0) return false;

  if (key1 < other.key1) return true;
  else if (key1 > other.key1) return false;

  return key2 < other.key2;
 }
}

Now, this works fine until I decide I want to use lower_bound and upper_bound. If I want to find the range of values formed by any key0, any key1 starting with "ab", and any key2 starting with "cd", using those 2 functions with ExampleMapKey("", "ab", "cd") and ExampleMapKey("", "ac", "ce") respectively will have me iterating through keys that don't fulfill my requirements. Or will I miss keys that do? Either way, it's wrong.

It seems what I need is a data structure that explicitly indexes by each key, and will also allow me to perform potentially complicated lower_bound and upper_bound iterations. Is there such a thing? I'm not necessarily using strings, nor am I limited to only 3 keys, so it needs to be STL-style or similarly generic.

share|improve this question
    
Boost::MultiIndex? –  Mooing Duck Sep 24 '12 at 17:51

2 Answers 2

up vote 2 down vote accepted
  1. Boost Multi-index Containers Library can be of help.

    Update: After rereading your question, I think you may have to do what is taught in db classes; you would have to use one of the indices to create a temporary result, and prune that result, based on your second constraint (alternatively, you can run each constraint on each index, joining the results). Boost Multi-index Containers will only allow lookup on one index at a time AFAIK.

  2. For the particular type of query that you asked, you might be able to come up with a very specialized data structure that can help, by adding indices on partitions of indices. That is for example, you take the 2nd index, split it in half, rewrite a 3rd index for the first half, and for the 2nd half. Then you split each half and repeat. This way, you can select a section of the 2nd index, and then subsequently select a part of the 3rd index that is within (approximately) that part of the 2nd index. But I don't know of any library that does this.

  3. Another approach might be some sort of multi-dimensional data structure, though I am not familiar with using such a structure with non-numeric keys. For example, imagine your keys were integers, you could use a 3D kd-tree or other spatial index, and query for a cubic range. For example: (using libssrckdtree, seems it might work with strings too):

Codes for (3):

#include <ssrc/spatial/kd_tree.h>

#include <cstdlib>
#include <ctime>
#include <iostream>
#include <algorithm>
#include <cassert>

#include <string>

typedef std::array<std::string, 3> Point;

typedef ssrc::spatial::kd_tree<Point, Point> Tree;

int main()
{
  Tree tree;

  Point point = {{"any1","aa1","cc1"}};
  tree[point] = point;

  point = {{"any2","ab1","cc1"}};
  tree[point] = point;

  point = {{"any3","ab1","cd1"}};
  tree[point] = point;
  point = {{"any4","ab1","cd2"}};
  tree[point] = point;
  point = {{"any5","ab1","cd3"}};
  tree[point] = point;


  point = {{"any22","ac1","cc1"}};
  tree[point] = point;

  point = {{"any33","ac1","cd1"}};
  tree[point] = point;
  point = {{"any44","ac1","cd2"}};
  tree[point] = point;
  point = {{"any55","ac1","cd3"}};
  tree[point] = point;


  point = {{"any6","aa1","cd2"}};
  tree[point] = point;
  point = {{"any7","aa1","cd3"}};
  tree[point] = point;

  Point lower{ { "any0", "ab", "cd" } }, upper{ { "any9", "ac", "cd2" } };

  for(Tree::const_iterator it = tree.begin(lower, upper), end = tree.end();
      it != end; ++it)
  {
    Point point = it->first;
    Point value = it->second;
    std::cout << point[0] << ", " << point[1] << ", " << point[2] << std::endl;
  }


  return 0;
}

Output:

any3, ab1, cd1
any4, ab1, cd2
share|improve this answer
    
Hey, that's pretty clever. –  user173342 Sep 24 '12 at 21:37

In such std::map there wouldn't be a single range, it would be set of ranges.

Consider such keys (sorted as defined by your comparator object):

#0 {"aa", "aa", "cb" },
#1 {"aa", "ab", "cd" },
#2 {"aa", "abb", "cdd" },
#3 {"ab", "aa", "cb" },
#4 {"ab", "ab", "cd" },
#5 {"ab", "abb", "cdd" },

Ranges matching your constraints are: {1.2} and {4,5}.

With std::map<> you have to find range for every key0, then within given key0 - do lower/upper_bound for key1, Then do the same for key2. But to do so - redefine your map from:

std::map<ExampleKey, T> 

to

std::map<std::string, std::map<std::string, std::map<std::string, T> > >:

And to find all matching ranges do:

for (auto it0 = theMap.begin(); it0 != theMap.end(); ++it0)
{
    auto it1lower = it0->second.lower_bound("ab");
    auto it1upper = it0->second.upper_bound("ac");
    for (auto it1 = it1lower; it1 != it1upper; ++it)
    {
       auto it2lower = it1->second.lower_bound("cd");
       auto it2upper = it1->second.upper_bound("ce");
       // and now we have on of matching ranges:
    }
}
share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.