After some time and effort I have tracked down a memory smashing bug in my code to this function. I stopped the memory smashing by replacing the two `__block vector<int>`

variables with the combination of stack-allocated arrays to provide the storage and a `{klist|dlist}Ptr`

variables to allow code inside the block to access the arrays (seen in the commended-out code below). This makes me fairly confident that it is indeed the use of `__block vector<int>`

that is problematic.

```
void
traceTree(Matrix<double> Z, double s[3], int k, unsigned int depth)
{
int m = Z.size(1) + 1;
__block vector<int> klist(m, 0);
// int klist[m]; int * klistPtr = klist;
// klist[0] = k;
__block vector<int> dlist(1, depth);
// int dlist[depth]; int * dlistPtr = dlist;
// dlist[0] = depth;
__block int topk = 0;
int currk = 0;
void (^ subtree)(int i) = ^(int i) {
if (i > m) { // If it's not a leaf...
topk += 1;
klist[topk] = i - m;
dlist[topk] = depth - 1;
}
};
while (currk <= topk) {
k = klist[currk];
depth = dlist[currk];
s[0] += Z[{2,k}]; // Sum of the edge lengths so far
s[1] += Z[{2,k}] * Z[{2,k}]; // ... and the sum of the squares
s[2] += 1; // ... and the count of the edges
if (depth > 0) {
subtree(Z[{0,k}]); // Consider left subtree
subtree(Z[{1,k}]); // Consider right subtree
}
currk += 1;
}
}
```

[I should point out, this is a purely iterative algorithm; there's no recursion. The block exists only to avoid duplicating the code needed to handle left and right subtrees.]

The obvious question is, why are the STL `vector`

objects causing memory corruption here? They are not even doing any dynamic resizing… Is it simply not supported to use a C++ object as a `__block`

variable?

`int * klistPtr = klist;`

How would that work when`klist`

is a`vector<int>`

? In your code your block is capturing`klistPtr`

and`dlistPtr`

, not a`vector`

. – newacct Apr 8 '13 at 5:47