It is not possible to generally know the size of the node. However, you can know the size of the node at compile time, for a specific platform and set of libraries.
will tell you the size of the node. Note that it might not be the actual size of all of the members within the node combined. Occasionally, padding is necessary to have the members within the struct align on memory alignment boundaries necessary for proper operation.
In addition, pointers do not have a specific size. They are large enough to accommodate the required memory address, but that's the only requirement that they must satisfy. There are dramatic differences in pointer size between 32-bit and 64-bit environments, and even if not shifting between two supported bit-ness environments on the same hardware, different hardware platforms may have different memory requirements to store a pointer value.
Where you get the "4 bytes to store a pointer" is from the popular misconception that all computers that use C are Intel CPUs, in the Pentium family of chips, which can only run 32-bit code. It was an untrue assumption back then, and it's equally untrue to assume it now.
Even after that is taken into account, arrays of the struct might require between-array-element padding for correct memory alignment. As a result, even if you know the size of the struct, you cannot assure that an array of
X elements will fit in a memory area of
X * sizeof(struct node) bytes.
sizeof(...) to find the answer you seek, but make sure that pretty much everything you want to take the size of is in the
As far as the life of the pointer, it lives as long as the program is running; however, the value stored in
node->next might not actually reference a meaningful address.
node->next is designed to hold an address, but there are far too many ways to trick
node->next to point to addresses that do not specify the beginning of a pattern of bits which satisfy the needs of a
This "problem" with the C language was fixed to some degree in subsequent languages meant to "improve" upon C, by making pointer-type operations impossible. Instead the languages allowed the safe sub-set of pointer operations, which meant that you really didn't have a pointer (so they called it a reference). Java and C# are two such languages, but there are many that deny the truly dangerous operations on pointers.
It is not proper to call a pointer an instance of a variable, because it really is a variable that holds a memory address. There is no strict requirement that the memory address it holds contains a bit pattern that will satisfy the "type" of the pointer. It's just one of those legacy C issues, which C++ preserved in order to be compatible with C. Also, an instance variable tends to suggest object-oriented terminology, and C cannot (in its default form) provide object-oriented guarantees, so applying object-oriented-programming terminology to C is inappropriate.
Likewise, a struct is not a class, and members of the struct are subject to slightly different rules than members of a class. The biggest "slightly different" rule is that members of a struct are generally publicly accessible, unless you actually take great care to hide the declaration of the struct from the rest of the program (which will require a lot of C gymnastics to do and make your program still work).