Finding corruption in a linked list

Question

I had an interview today for a developer position and was asked an interesting techincal question that i did not know the answer to. I will ask it here to see if anyone can provide me with a solution for my curiosity. It is a multi-part question:

1) You are given a singly linked list with 100 elements (integer and a pointer to next node), find a way to detect if there is a break or corruption halfway through the linked list? You may do anything with the linked list. Note that you must do this in the list as it is iterating and this is verification before you realise that the list has any issues with it.

Assuming that the break in the linked list is at the 50th element, the integer or even the pointer to the next node (51st element) may be pointing to a garbage value which is not necessarily an invalid address.

2) Note that if there is a corruption in the linked list, how would you minimize data loss?

Answer 1

To test for a "corrupted" integer, you would need to know what the range of valid values is. Otherwise, there is no way to determine that the value in any given (signed) integer is invalid. So, assuming you have a validity test for the int, you would always check that value before iterating to the next element.

Testing for a corrupted pointer is trickier - for a start, what you need to do is check the value of the pointer to the next element before you attempt to de-reference it, and ensure it is a valid heap address. That will avoid a segmentation fault. The next thing is to validate that what the pointer points at is in fact a valid linked list node element - that's a bit trickier? Perhaps de-reference the pointer into a list element class/struct, and test the validity of the int and "next" pointer, if they are also good, then can be pretty sure the previous node was good also.

On 2), having discovered a corrupted node, [if the next pointer is corrupted] what you should do is set the "next pointer" of the previous node to 'NULL' immediately, marking it as the end of the list, and log your error etc etc. if the corruption was just to the integer value, but not to the "next" element pointer, then you should remove that element from the list and link the previous and following nodes together instead - as no need to throw the rest of the list away in that case!

Answer 2

For the first part - Overload the new operator. When ever a new node is allocated allocate some additional space before and after the node and put some known values there. In traversal each node can be checked if it is in between the known values.

Answer 3

If you at design time know that corruption may become a critical issue, you could add a "magic value" as a field into the node data structure which allows you to identify whether some data is likely to be a node or not. Or even to run through memory searching for nodes.

Or double some link information, i.e. store the address of the node after the next node in each node, such that you can recover if one link is broken.

The only problem I see is that you have to avoid segmentation faults.

Answer 4

If you can do anything to the linked list, what you can do is to calculate the checksum of each element and store it on the element itself. This way you will be able to detect corruption even if it's a single bit error on the element.

To minimize data loss perhaps you can consider having storing the nextPtr in the previous element, that way if your current element is corrupted, you can always find the location of the next element from the previous.

Answer 5

Since the number of elements (100) is known, 100th node must contain a null pointer. If it does, the list with some good probability is valid (this cannot be guaranteed, if, for example, 99th node is corrupt and points to some memory location with all zeros). Otherwise, there is some problem (this can be returned as a fact).

upd: Also, it could be possible to, an every step, look at some structures delete would use if given the pointer, but since using delete itself is not safe in any sense, this is going to be implementation-specific.