Here is a C++ balanced tree structure that provides the ability to query by index in the sorted list. Since it maintains all values in sorted order, this is not be quite as efficient as the two-heaps approach, but it offers some additional flexibility. For example, it could also give you a running quartile.

```
template <typename T>
class Node
{
public:
T key;
Node* left;
Node* right;
size_t size;
Node(T k) : key(k)
{
isolate();
}
~Node()
{
delete(left);
delete(right);
}
void isolate()
{
left = NULL;
right = NULL;
size = 1;
}
void recount()
{
size = 1 + (left ? left->size : 0) + (right ? right->size : 0);
}
Node<T>* rotateLeft()
{
Node<T>* c = right;
Node<T>* gc = right->left;
right = gc;
c->left = this;
recount();
c->recount();
return c;
}
Node<T>* rotateRight()
{
Node<T>* c = left;
Node<T>* gc = left->right;
left = gc;
c->right = this;
recount();
c->recount();
return c;
}
Node<T>* balance()
{
size_t lcount = left ? left->size : 0;
size_t rcount = right ? right->size : 0;
if((lcount + 1) * 2 < (rcount + 1))
{
size_t lcount2 = right->left ? right->left->size : 0;
size_t rcount2 = right->right ? right->right->size : 0;
if(lcount2 > rcount2)
right = right->rotateRight();
return rotateLeft();
}
else if((rcount + 1) * 2 <= (lcount + 1))
{
size_t lcount2 = left->left ? left->left->size : 0;
size_t rcount2 = left->right ? left->right->size : 0;
if(lcount2 < rcount2)
left = left->rotateLeft();
return rotateRight();
}
else
{
recount();
return this;
}
}
Node<T>* insert(Node<T>* newNode)
{
if(newNode->key < key)
{
if(left)
left = left->insert(newNode);
else
left = newNode;
}
else
{
if(right)
right = right->insert(newNode);
else
right = newNode;
}
return balance();
}
Node<T>* get(size_t index)
{
size_t lcount = left ? left->size : 0;
if(index < lcount)
return left->get(index);
else if(index > lcount)
return right ? right->get(index - lcount - 1) : NULL;
else
return this;
}
Node<T>* find(T k, size_t start, size_t* outIndex)
{
if(k < key)
return left ? left->find(k, start, outIndex) : NULL;
else if(k > key)
return right ? right->find(k, left ? start + left->size + 1 : start + 1, outIndex) : NULL;
else
{
if(outIndex)
*outIndex = start + (left ? left->size : 0);
return this;
}
}
Node<T>* remove_by_index(size_t index, Node<T>** outNode)
{
size_t lcount = left ? left->size : 0;
if(index < lcount)
left = left->remove_by_index(index, outNode);
else if(index > lcount)
right = right->remove_by_index(index - lcount - 1, outNode);
else
{
*outNode = this;
size_t rcount = right ? right->size : 0;
if(lcount < rcount)
return left ? right->insert(left) : right;
else
return right ? left->insert(right) : left;
}
return balance();
}
Node<T>* remove_by_value(T k, Node<T>** outNode)
{
if(k < key)
{
if(!left)
throw "not found";
left = left->remove_by_value(k, outNode);
}
else if(k > key)
{
if(!right)
throw "not found";
right = right->remove_by_value(k, outNode);
}
else
{
*outNode = this;
size_t lcount = left ? left->size : 0;
size_t rcount = right ? right->size : 0;
if(lcount < rcount)
return left ? right->insert(left) : right;
else
return right ? left->insert(right) : left;
}
return balance();
}
};
template <typename T>
class MyReasonablyEfficientRunningSortedIndexedCollection
{
private:
Node<T>* root;
Node<T>* spare;
public:
MyReasonablyEfficientRunningSortedIndexedCollection() : root(NULL), spare(NULL)
{
}
~MyReasonablyEfficientRunningSortedIndexedCollection()
{
delete(root);
delete(spare);
}
void insert(T key)
{
if(spare)
spare->key = key;
else
spare = new Node<T>(key);
if(root)
root = root->insert(spare);
else
root = spare;
spare = NULL;
}
void drop_by_index(size_t index)
{
if(!root || index >= root->size)
throw "out of range";
delete(spare);
root = root->remove_by_index(index, &spare);
spare->isolate();
}
void drop_by_value(T key)
{
if(!root)
throw "out of range";
delete(spare);
root = root->remove_by_value(key, &spare);
spare->isolate();
}
T get(size_t index)
{
if(!root || index >= root->size)
throw "out of range";
return root->get(index)->key;
}
size_t find(T key)
{
size_t outIndex;
Node<T>* node = root ? root->find(key, 0, &outIndex) : NULL;
if(node)
return outIndex;
else
throw "not found";
}
size_t size()
{
return root ? root->size : 0;
}
};
```