I would guess there was an attempt to execute an instruction at the address 0xdf3251 and that location wasn't backed up by a readable and executable page of memory (perhaps, completely unmapped).
If that's the case, the exception (page fault, in fact) originates from that instruction and the exception handler has its address on the stack (the location to return to, in case the exception can be somehow resolved and the faulting instruction restarted when the handler returns). And that's the first address you're seeing.
CR2 register that the page fault handler reads, which is the second address you're seeing, also has the same address because it has to contain the address of an inaccessible memory location irrespective of whether the page fault has been caused by:
- complete absence of mapping (there's no page mapped at all)
- lack of write permission (the page is read-only)
- lack of execute permission (the page has the no-execute bit set) OR
- lack of kernel privilege (the page is marked as accessible only in the kernel)
and irrespective of whether it was during a data access or while fetching an instruction (the latter being our case).
That's how you can get the instruction and memory access addresses equal.
Most likely the code had a bug resulting in a memory corruption and some pointer (or a return address on the stack) was overwritten with a bogus value pointing to an inaccessible memory location. And then one way or the other the CPU was directed to continue execution there (most likely using one of these instructions:
ret). There's also a chance of having a race condition somewhere.