if gets converted in some fashion (the array pointer, not the contents) then I would have a problem.
Yes, that's exactly what happens.
It's often incorrectly said that arrays are just pointers. The truth of the matter is that whenever you declare a function that takes an array:
void foo(int x[10]);
The declaration is 'adjusted' so that the parameter is a pointer:
void foo(int *x); // C++ can't tell the difference between this and the first declaration
and when you call the function:
int x[10];
foo(x);
There's an implicit conversion equivalent to the following:
int x[10];
int *tmp = &x[0];
foo(tmp);
So what happens is that you have a block of memory containing your pointers to long lived objects:
my_type *rest[count] = {new my_type, new my_type, new my_type};
You pass a pointer to that block of memory to the thread:
thread(fnc, &rest[0], count);
Then when the function returns rest
goes out of scope, and that block of memory is no longer valid.
Then the thread follows the pointer to the block of memory and reads garbage. If by some chance it does read the correct array contents then it can access the long lived objects just fine. The problem is getting the pointers to the long lived objects from the corrupt block of memory where rest
used to be on the stack.
Is there a way to suppress this behavior?
In most cases the only thing that makes sense is not use raw arrays as function parameters. You can wrap a raw array in a struct and get the sensible behavior:
struct int_array {
int x[10];
};
void foo(int_array x);
int main() {
int_array x = {1,2,3,4,5,6,7,8,9,0};
foo(x); // the array is copied rather than getting strangely converted
}
This is pretty much exactly what std::array
does, so you're better off using it.
In cases where you don't want a copy of the array you can take a reference to the array:
int foo(int (&x)[10]);
This gives you essentially the same behavior as the weird 'adjustments' and implicit conversions that are done behind your back with int foo(int x[10]); foo(x);
. The benefit here is that it's explicit and that you get type checking on the size of the array. That is, due to the 'adjustment' the following does not result in a compiler error:
int foo(int x[10]);
int x[3];
foo(x);
Whereas this will:
int foo(int (&x)[10]);
int x[3];
foo(x); // the implicit conversion to &x[0] does not get happen when the function takes a reference to array
rest
a local variable, by any chance? Does it maybe go out of scope beforefnc
starts executing?std::thread
will just copy the pointer to the first element of the array - but not elements themselves. They better stay alive for as long asfnc
is running.std::array
orstd::vector
. Both have value semantics, which are much more sensible than the weirdness of raw arrays.