Okay, here goes, this probably could be made more efficient, but I think this does what you need.

```
#include <vector>
#include <iostream>
#include <iterator>
#include <algorithm>
#include <set>
#include <map>
using namespace std;
typedef vector<int> v_t;
typedef set<int> s_t;
typedef map<s_t, v_t> m_t;
typedef vector<pair<s_t, v_t> > b_t;
// this inserts a new entry into the map with the provided key
// the value_type (vector) is generated by adding the entries in each vector
// NOTE: the first vector is passed by value (so we get a copy in the function)
// the second vector (passed by ref) is then added to it.
void insert_entry(m_t& dest, s_t& key, v_t vdest, v_t const& v2)
{
v_t::const_iterator it2(v2.begin());
// there is no global operator+ for vector, so you have to do something like below
for(v_t::iterator it(vdest.begin()), end(vdest.end()); it != end && (*(it++) += *(it2++)););
// this is just debug
cout << "new key: " << key.size() << " : ";
copy(key.begin(), key.end(), ostream_iterator<int>(cout, " "));
cout << endl;
cout << "vec: ";
copy(vdest.begin(), vdest.end(), ostream_iterator<int>(cout, " "));
// actual insert in to map
// for example, key may be set<1, 2> and value is vector <3, 3, 3, 3>
dest.insert(dest.end(), make_pair(key, vdest));
cout << "size of dest: " << dest.size() << endl;
}
// This function generates all unique combinations of a given size and inserts them into
// the main map
void gen_comb(size_t cmb, b_t const& base, m_t& dest)
{
typedef m_t::iterator m_it;
cout << "combination size: " << cmb << endl;
// Now calculate our starting vector key size, a "key" is imply a combination of
// vectors, e.g. v12, v23 v14 etc. in this case key size = 2 (i.e. two vectors)
// If we need to generate combinations of size 3 (cmb=3), then we start with all
// vectors of key size = 2 (v12, v23, v14 etc.) and add all the base (v1, v2 v3) to it
size_t s_ksz = cmb - 1; // search key size
cout << "search size: " << s_ksz << endl;
// now iterate through all entries in the map
for(m_it it(dest.begin()); it != dest.end(); ++it)
{
// Aha, the key size matches what we require (for example, to generate v123, we
// need v12 (key size == 2) first
if (it->first.size() == s_ksz)
{
// Now iterate through all base vectors (v1, v2, v3, v4)
for(b_t::const_iterator v_it(base.begin()), v_end(base.end()); v_it != v_end; ++v_it)
{
// new key, start with the main key from map, e.g. set<1, 2>
s_t nk(it->first.begin(), it->first.end());
// Add the base key set<3>, reason I do it this way is that, in case you
// that base vectors should be other than size 1 (else insert(*((*v_it)->first.begin())) should work just fine.
nk.insert(v_it->first.begin(), v_it->first.end());
// check if this key exists, this is the main check, this tests whether our map
// already has a key with the same vectors (for example, set<1,2,3> == set<2,3,1> - internally set is ordered)
m_it k_e = dest.find(nk);
// If the key (combination of vectors) does not exist, then insert a new entry
if (k_e == dest.end())
{
// new key
insert_entry(dest, nk, it->second, v_it->second);
}
}
}
}
}
void trim(size_t depth, m_t& dest)
{
for(m_t::iterator it(dest.begin()); it != dest.end();)
{
if (it->first.size() == depth && (rand() % 2))
{
cout << "removing key: " << depth << " : ";
copy(it->first.begin(), it->first.end(), ostream_iterator<int>(cout, " "));
cout << endl;
dest.erase(it++);
}
else
++it;
}
}
int main(void)
{
// combination map
m_t dest;
// this is the set of bases
b_t bases;
int max_i = 4;
for(int i = 1; i <= max_i; ++i)
{
v_t v(4, i);
s_t k;
k.insert(i);
bases.push_back(make_pair(k, v));
}
// for the start, push in the bases
dest.insert(bases.begin(), bases.end());
// for each combination size, generate a new set of vectors and then trim that set.
for (size_t cmb = 1; cmb <= static_cast<size_t>(max_i); ++cmb)
{
if (cmb > 1) gen_comb(cmb, bases, dest);
trim(cmb, dest); // randomly remove some entries...
}
return 0;
}
```

NOTES:

- the
`trim`

function models your black box which removes some entries from the main map with a given key size (same size as the most recently generated combinations)
- I'm not sure about the validity of iterating through the map and inserting new entries (i.e. how it impacts the iterator, it appears to work, but I think there may be something subtle that I am missing - it's far too late at night to think about that right now!)
- Performance, may not be ideal, as you need to iterate through all keys to find the search size (for combination).
- assumes that all vectors have the same size (but this can be fixed trivially)
- If you take out the debug, you'll see that the actual code is quite small..
- The order of the combination is not preserved - not sure if this is necessary for you

EDIT:
Okay now `base`

is a vector which contains a `pair`

for the key<->vector relationship - this is constant. Initially it is added to the map, and the `gen_comb`

function is skipped for the initial state, `trim`

is still called to remove some entries. Next iteration uses the same search algorithm, but the combination is with the constant set of `base`

s.

`std::valarray`

. – Rob Kennedy Jan 4 '11 at 23:53`valarray`

. This is the first time I'm hearing it. Sorry. – Sunil Jan 4 '11 at 23:56anyone. Using it would make your addition operations easier, and it might also make it easier for people to understand your question, but I don't think it ultimately affects your question at all. You just need to keep track of which values you've combined;howyou combine them (whether by addition, concatenation, or whatever) doesn't matter. – Rob Kennedy Jan 5 '11 at 0:31