- Construct decision graph, add start vertex to it. Each vertex contains "trim level", i.e. the value to which should be decremented all array values to the left of current node. Start vertex's "trim level" is infinity. Each edge of the graph has a value, corresponding to the cost of decision.
- For each array element, starting from the rightmost, do steps 3 .. 5.
- For each leaf vertex, do steps 4 .. 5.
- Create up to 2 outgoing edges, (1) with the cost of deleting the array element and (2) with the cost of trimming all elements to the left (exactly, the cost of decreasing "trim level").
- Connect these edges to newly created vertexes, one vertex for each array element and each "trim level".
- Find shortest path from start vertex to one of the vertexes, corresponding to leftmost array element. Length of this path equals to the cost of the solution.
- Decrement and delete array elements according to the decision graph.

This algorithm may be treated as an optimization of brute-force approach. For brute-force search, starting from rightmost array element, construct binary decision tree. Each vertex has 2 outgoing edges, one for "delete" decision, other "trim" decision. Decision cost is associated with each edge. "Trim level" is associated with each vertex. Optimal solution is determined by shortest path in this tree.

Remove every path, that is obviously non-optimal. For example, if the largest element is the last in the array, "trim" decision has cost zero, and "delete" decision is non-optimal. Delete path, starting from this "delete" decision. After this optimization, decision tree is more sparse: some vertexes have 2 outgoing edges, some - only one.

On each depth level, decision tree may have several vertexes with the same "trim level". Subtrees, starting from these vertexes, are identical to each other. That's a good reason to join all these vertexes to one vertex. This transforms tree into graph having at most n^{2}/2 vertexes.

**Complexity**

Simplest implementation of this algorithm is O(n^{3}), because for each of the O(n^{2}) vertexes it computes trimming cost iteratively, in O(n) time.

Repeated trimming cost calculations are not necessary if there is enough memory to store all partial trimming cost results. This may require O(n^{2}) or even O(n) space.

With such optimization, this algorithm is O(n^{2}). Due to simple structure of the graph, shortest path search has O(n^{2}) complexity, not O(n^{2} * log(n)).

**C++11 implementation (both space and time complexity is O(n**^{2})):

```
//g++ -std=c++0x
#include <iostream>
#include <vector>
#include <algorithm>
typedef unsigned val_t;
typedef unsigned long long acc_t; // to avoid overflows
typedef unsigned ind_t;
typedef std::vector<val_t> arr_t;
struct Node
{
acc_t trimCost;
acc_t cost;
ind_t link;
bool used;
Node()
: trimCost(0)
, used(false)
{}
};
class Matrix
{
std::vector<Node> m;
ind_t columns;
public:
Matrix(ind_t rows, ind_t cols)
: m(rows * cols)
, columns(cols)
{}
Node& operator () (ind_t row, ind_t column)
{
return m[columns * row + column];
}
};
void fillTrimCosts(const arr_t& array, const arr_t& levels, Matrix& matrix)
{
for (ind_t row = 0; row != array.size(); ++row)
{
for (ind_t column = 0; column != levels.size(); ++column)
{
Node& node = matrix(row + 1, column);
node.trimCost = matrix(row, column).trimCost;
if (array[row] > levels[column])
{
node.trimCost += array[row] - levels[column];
}
}
}
}
void updateNode(Node& node, acc_t cost, ind_t column)
{
if (!node.used || node.cost > cost)
{
node.cost = cost;
node.link = column;
}
}
acc_t transform(arr_t& array)
{
const ind_t size = array.size();
// Sorted array of trim levels
arr_t levels = array;
std::sort(levels.begin(), levels.end());
levels.erase(
std::unique(levels.begin(), levels.end()),
levels.end());
// Initialize matrix
Matrix matrix(size + 1, levels.size());
fillTrimCosts(array, levels, matrix);
Node& startNode = matrix(size, levels.size() - 1);
startNode.used = true;
startNode.cost = 0;
// For each array element, starting from the last one
for (ind_t row = size; row != 0; --row)
{
// Determine trim level for this array element
auto iter = std::lower_bound(levels.begin(), levels.end(), array[row - 1]);
const ind_t newLevel = iter - levels.begin();
// For each trim level
for (ind_t column = 0; column != levels.size(); ++column)
{
const Node& node = matrix(row, column);
if (!node.used)
continue;
// Determine cost of trimming to current array element's level
const acc_t oldCost = node.trimCost;
const acc_t newCost = matrix(row, newLevel).trimCost;
const acc_t trimCost = (newCost > oldCost)? newCost - oldCost: 0;
// Nodes for "trim" and "delete" decisions
Node& trimNode = matrix(row - 1, newLevel);
Node& nextNode = matrix(row - 1, column);
if (trimCost)
{
// Decision needed, update both nodes
updateNode(trimNode, trimCost + node.cost, column);
updateNode(nextNode, array[row - 1] + node.cost, column);
trimNode.used = true;
}
else
{
// No decision needed, pass current state to the next row's node
updateNode(nextNode, node.cost, column);
}
nextNode.used = true;
}
}
// Find optimal cost and starting trim level for it
acc_t bestCost = size * levels.size();
ind_t bestLevel = levels.size();
for (ind_t column = 0; column != levels.size(); ++column)
{
const Node& node = matrix(0, column);
if (node.used && node.cost < bestCost)
{
bestCost = node.cost;
bestLevel = column;
}
}
// Trace the path of minimum cost
for (ind_t row = 0; row != size; ++row)
{
const Node& node = matrix(row, bestLevel);
const ind_t next = node.link;
if (next == bestLevel && node.cost != matrix(row + 1, next).cost)
{
array[row] = 0;
}
else if (array[row] > levels[bestLevel])
{
array[row] = levels[bestLevel];
}
bestLevel = next;
}
return bestCost;
}
void printArray(const arr_t& array)
{
for (val_t val: array)
if (val)
std::cout << val << ' ';
else
std::cout << "* ";
std::cout << std::endl;
}
int main()
{
arr_t array({9,8,7,6,5,4,3,2,1});
printArray(array);
acc_t cost = transform(array);
printArray(array);
std::cout << "Cost=" << cost << std::endl;
return 0;
}
```

`a[i]--`

? – soulcheck Jan 19 '12 at 14:53