I have a structure defined like this:

```
struct Edge
{
int u, v; // vertices
Edge() { }
Edge(int u, int v)
{
this->u = u;
this->v = v;
}
};
```

and a class field defined like

```
vector<Edge> solution;
```

In one of the methods I'm creating new `Edge`

s and pushing them into the vector like this (a huge simplification of my real code, but the problem still exists):

```
solution.push_back(Edge(1, 2));
solution.push_back(Edge(3, 4));
solution.push_back(Edge(5, 6));
solution.push_back(Edge(7, 8));
solution.push_back(Edge(9, 10));
solution.push_back(Edge(11, 12));
solution.push_back(Edge(13, 14)); // adding 7th element; the problem occurs here
```

When the last `push_back`

is executing, I'm getting an error window in Visual Studio's debug mode

[AppName] has triggered a breakpoint.

and the debugger goes to `malloc.c`

, to the end of `_heap_alloc`

function. Before this 7th line, the vector seems to work properly. I can see all the elements in the debugger. It seems that the vector has a problem reallocating itself (expanding its size).

What's interesting, if I put this before all the pushing back:

```
solution.reserve(7);
```

, the 7th edge is added properly. What's even more interesting, trying to reserve space for more than 22 elements also causes the mentioned error.

What am I doing wrong? How can I debug it? The rest of the application doesn't use so much memory, so I can't believe the heap is full.

More code, on request. It's a rather sloppy implementation of 2-approximation algorithm for Metric Travelling Salesman's Problem. It first creates a minimum spanning tree, then adds vertices (just indices) to the `partialSolution`

vector in the DFS order.

```
void ApproxTSPSolver::Solve()
{
// creating a incidence matrix
SquareMatrix<float> graph(noOfPoints);
for (int r=0; r<noOfPoints; r++)
{
for (int c=0; c<noOfPoints; c++)
{
if (r == c)
graph.SetValue(r, c, MAX);
else
graph.SetValue(r, c, points[r].distance(points[c]));
}
}
// finding a minimum spanning tree
spanningTree = SquareMatrix<bool>(noOfPoints);
// zeroeing the matrix
for (int r=0; r<noOfPoints; r++)
for (int c=0; c<noOfPoints; c++)
spanningTree.SetValue(r, c, false);
bool* selected = new bool[noOfPoints];
memset(selected, 0, noOfPoints*sizeof(bool));
selected[0] = true; // the first point is initially selected
float min;
int minR, minC;
for (int i=0; i<noOfPoints - 1; i++)
{
min = MAX;
for (int r=0; r<noOfPoints; r++)
{
if (selected[r] == false)
continue;
for (int c=0; c<noOfPoints; c++)
{
if (selected[c] == false && graph.GetValue(r, c) < min)
{
min = graph.GetValue(r, c);
minR = r;
minC = c;
}
}
}
selected[minC] = true;
spanningTree.SetValue(minR, minC, true);
}
delete[] selected;
// traversing the tree
DFS(0);
minSol = 0.0f;
// rewriting the solution to the solver's solution field
for (int i=0; i<noOfPoints - 1; i++)
{
solution.push_back(Edge(partialSolution[i], partialSolution[i + 1]));
minSol += points[partialSolution[i]].distance(points[partialSolution[i + 1]]);
}
solution.push_back(Edge(partialSolution[noOfPoints - 1], partialSolution[0]));
minSol += points[partialSolution[noOfPoints - 1]].distance(points[partialSolution[0]]);
cout << endl << minSol << endl;
solved = true;
}
void ApproxTSPSolver::DFS(int vertex)
{
bool isPresent = std::find(partialSolution.begin(), partialSolution.end(), vertex)
!= partialSolution.end();
if (isPresent == false)
partialSolution.push_back(vertex); // if I comment out this line, the error doesn't occur
for (int i=0; i<spanningTree.GetSize(); i++)
{
if (spanningTree.GetValue(vertex, i) == true)
DFS(i);
}
}
class ApproxTSPSolver : public TSPSolver
{
vector<int> partialSolution;
SquareMatrix<bool> spanningTree;
void DFS(int vertex);
public:
void Solve() override;
};
```

from `main.cpp`

:

```
TSPSolver* solver;
string inputFilePath, outputFilePath;
// parsing arguments
if (ArgParser::CmdOptionExists(argv, argv + argc, "/a"))
{
solver = new ApproxTSPSolver();
}
else if (ArgParser::CmdOptionExists(argv, argv + argc, "/b"))
{
solver = new BruteForceTSPSolver();
}
else
{
solver = new BranchAndBoundTSPSolver();
}
inputFilePath = ArgParser::GetCmdOption(argv, argv + argc, "/i");
outputFilePath = ArgParser::GetCmdOption(argv, argv + argc, "/s");
solver->LoadFromFile(inputFilePath);
Timer timer;
timer.start();
solver->Solve();
timer.stop();
cout << timer.getElapsedTime();
```

A part of TSPSolver.c:

```
TSPSolver::TSPSolver()
{
points = NULL;
solved = false;
}
TSPSolver::~TSPSolver()
{
if (points)
delete[] points;
}
void TSPSolver::LoadFromFile(string path)
{
ifstream input(path);
string line;
int nodeID;
float coordX, coordY;
bool coords = false;
minX = numeric_limits<float>::max();
maxX = numeric_limits<float>::min();
minY = numeric_limits<float>::max();
maxY = numeric_limits<float>::min();
while (input.good())
{
if (coords == false)
{
getline(input, line);
if (line == "NODE_COORD_SECTION")
{
coords = true;
}
else if (line.find("DIMENSION") != string::npos)
{
int colonPos = line.find_last_of(":");
noOfPoints = stoi(line.substr(colonPos + 1));
#ifdef _DEBUG
cout << noOfPoints << " points" << endl;
#endif
// allocating memory for this amount of points
points = new Point[noOfPoints];
}
}
else
{
input >> nodeID >> coordX >> coordY;
points[nodeID - 1].X = coordX;
points[nodeID - 1].Y = coordY;
minX = min(minX, coordX);
maxX = max(maxX, coordX);
minY = min(minY, coordY);
maxY = max(maxY, coordY);
if (nodeID == noOfPoints)
{
break;
}
}
}
input.close();
}
```

`Edge(int uu, int vv): u(uu), v(vv) {}`

. It's more efficient than your current constructor. – TemplateRex Jun 10 '14 at 12:16