What are the barriers to understanding pointers and what can be done to overcome them? [closed]
Why are pointers such a leading factor of confusion for many new, and even old, college level students in C or C++? Are there any tools or thought processes that helped you understand how pointers work at the variable, function, and beyond level?
What are some good practice things that can be done to bring somebody to the level of, "Ah-hah, I got it," without getting them bogged down in the overall concept? Basically, drill like scenarios.
Solution 1:
Pointers is a concept that for many can be confusing at first, in particular when it comes to copying pointer values around and still referencing the same memory block.
I've found that the best analogy is to consider the pointer as a piece of paper with a house address on it, and the memory block it references as the actual house. All sorts of operations can thus be easily explained.
I've added some Delphi code down below, and some comments where appropriate. I chose Delphi since my other main programming language, C#, does not exhibit things like memory leaks in the same way.
If you only wish to learn the high-level concept of pointers, then you should ignore the parts labelled "Memory layout" in the explanation below. They are intended to give examples of what memory could look like after operations, but they are more low-level in nature. However, in order to accurately explain how buffer overruns really work, it was important that I added these diagrams.
Disclaimer: For all intents and purposes, this explanation and the example memory layouts are vastly simplified. There's more overhead and a lot more details you would need to know if you need to deal with memory on a low-level basis. However, for the intents of explaining memory and pointers, it is accurate enough.
Let's assume the THouse class used below looks like this:
type
THouse = class
private
FName : array[0..9] of Char;
public
constructor Create(name: PChar);
end;
When you initialize the house object, the name given to the constructor is copied into the private field FName. There is a reason it is defined as a fixed-size array.
In memory, there will be some overhead associated with the house allocation, I'll illustrate this below like this:
---[ttttNNNNNNNNNN]--- ^ ^ | | | +- the FName array | +- overhead
The "tttt" area is overhead, there will typically be more of this for various types of runtimes and languages, like 8 or 12 bytes. It is imperative that whatever values are stored in this area never gets changed by anything other than the memory allocator or the core system routines, or you risk crashing the program.
Allocate memory
Get an entrepreneur to build your house, and give you the address to the house. In contrast to the real world, memory allocation cannot be told where to allocate, but will find a suitable spot with enough room, and report back the address to the allocated memory.
In other words, the entrepreneur will choose the spot.
THouse.Create('My house');
Memory layout:
---[ttttNNNNNNNNNN]--- 1234My house
Keep a variable with the address
Write the address to your new house down on a piece of paper. This paper will serve as your reference to your house. Without this piece of paper, you're lost, and cannot find the house, unless you're already in it.
var
h: THouse;
begin
h := THouse.Create('My house');
...
Memory layout:
h v ---[ttttNNNNNNNNNN]--- 1234My house
Copy pointer value
Just write the address on a new piece of paper. You now have two pieces of paper that will get you to the same house, not two separate houses. Any attempts to follow the address from one paper and rearrange the furniture at that house will make it seem that the other house has been modified in the same manner, unless you can explicitly detect that it's actually just one house.
Note This is usually the concept that I have the most problem explaining to people, two pointers does not mean two objects or memory blocks.
var
h1, h2: THouse;
begin
h1 := THouse.Create('My house');
h2 := h1; // copies the address, not the house
...
h1 v ---[ttttNNNNNNNNNN]--- 1234My house ^ h2
Freeing the memory
Demolish the house. You can then later on reuse the paper for a new address if you so wish, or clear it to forget the address to the house that no longer exists.
var
h: THouse;
begin
h := THouse.Create('My house');
...
h.Free;
h := nil;
Here I first construct the house, and get hold of its address. Then I do something to the house (use it, the ... code, left as an exercise for the reader), and then I free it. Lastly I clear the address from my variable.
Memory layout:
h <--+ v +- before free ---[ttttNNNNNNNNNN]--- | 1234My house <--+ h (now points nowhere) <--+ +- after free ---------------------- | (note, memory might still xx34My house <--+ contain some data)
Dangling pointers
You tell your entrepreneur to destroy the house, but you forget to erase the address from your piece of paper. When later on you look at the piece of paper, you've forgotten that the house is no longer there, and goes to visit it, with failed results (see also the part about an invalid reference below).
var
h: THouse;
begin
h := THouse.Create('My house');
...
h.Free;
... // forgot to clear h here
h.OpenFrontDoor; // will most likely fail
Using h
after the call to .Free
might work, but that is just pure luck. Most likely it will fail, at a customers place, in the middle of a critical operation.
h <--+ v +- before free ---[ttttNNNNNNNNNN]--- | 1234My house <--+ h <--+ v +- after free ---------------------- | xx34My house <--+
As you can see, h still points to the remnants of the data in memory, but since it might not be complete, using it as before might fail.
Memory leak
You lose the piece of paper and cannot find the house. The house is still standing somewhere though, and when you later on want to construct a new house, you cannot reuse that spot.
var
h: THouse;
begin
h := THouse.Create('My house');
h := THouse.Create('My house'); // uh-oh, what happened to our first house?
...
h.Free;
h := nil;
Here we overwrote the contents of the h
variable with the address of a new house, but the old one is still standing... somewhere. After this code, there is no way to reach that house, and it will be left standing. In other words, the allocated memory will stay allocated until the application closes, at which point the operating system will tear it down.
Memory layout after first allocation:
h v ---[ttttNNNNNNNNNN]--- 1234My house
Memory layout after second allocation:
h v ---[ttttNNNNNNNNNN]---[ttttNNNNNNNNNN] 1234My house 5678My house
A more common way to get this method is just to forget to free something, instead of overwriting it as above. In Delphi terms, this will occur with the following method:
procedure OpenTheFrontDoorOfANewHouse;
var
h: THouse;
begin
h := THouse.Create('My house');
h.OpenFrontDoor;
// uh-oh, no .Free here, where does the address go?
end;
After this method has executed, there's no place in our variables that the address to the house exists, but the house is still out there.
Memory layout:
h <--+ v +- before losing pointer ---[ttttNNNNNNNNNN]--- | 1234My house <--+ h (now points nowhere) <--+ +- after losing pointer ---[ttttNNNNNNNNNN]--- | 1234My house <--+
As you can see, the old data is left intact in memory, and will not be reused by the memory allocator. The allocator keeps track of which areas of memory has been used, and will not reuse them unless you free it.
Freeing the memory but keeping a (now invalid) reference
Demolish the house, erase one of the pieces of paper but you also have another piece of paper with the old address on it, when you go to the address, you won't find a house, but you might find something that resembles the ruins of one.
Perhaps you will even find a house, but it is not the house you were originally given the address to, and thus any attempts to use it as though it belongs to you might fail horribly.
Sometimes you might even find that a neighbouring address has a rather big house set up on it that occupies three address (Main Street 1-3), and your address goes to the middle of the house. Any attempts to treat that part of the large 3-address house as a single small house might also fail horribly.
var
h1, h2: THouse;
begin
h1 := THouse.Create('My house');
h2 := h1; // copies the address, not the house
...
h1.Free;
h1 := nil;
h2.OpenFrontDoor; // uh-oh, what happened to our house?
Here the house was torn down, through the reference in h1
, and while h1
was cleared as well, h2
still has the old, out-of-date, address. Access to the house that is no longer standing might or might not work.
This is a variation of the dangling pointer above. See its memory layout.
Buffer overrun
You move more stuff into the house than you can possibly fit, spilling into the neighbours house or yard. When the owner of that neighbouring house later on comes home, he'll find all sorts of things he'll consider his own.
This is the reason I chose a fixed-size array. To set the stage, assume that the second house we allocate will, for some reason, be placed before the first one in memory. In other words, the second house will have a lower address than the first one. Also, they're allocated right next to each other.
Thus, this code:
var
h1, h2: THouse;
begin
h1 := THouse.Create('My house');
h2 := THouse.Create('My other house somewhere');
^-----------------------^
longer than 10 characters
0123456789 <-- 10 characters
Memory layout after first allocation:
h1 v -----------------------[ttttNNNNNNNNNN] 5678My house
Memory layout after second allocation:
h2 h1 v v ---[ttttNNNNNNNNNN]----[ttttNNNNNNNNNN] 1234My other house somewhereouse ^---+--^ | +- overwritten
The part that will most often cause crash is when you overwrite important parts of the data you stored that really should not be randomly changed. For instance it might not be a problem that parts of the name of the h1-house was changed, in terms of crashing the program, but overwriting the overhead of the object will most likely crash when you try to use the broken object, as will overwriting links that is stored to other objects in the object.
Linked lists
When you follow an address on a piece of paper, you get to a house, and at that house there is another piece of paper with a new address on it, for the next house in the chain, and so on.
var
h1, h2: THouse;
begin
h1 := THouse.Create('Home');
h2 := THouse.Create('Cabin');
h1.NextHouse := h2;
Here we create a link from our home house to our cabin. We can follow the chain until a house has no NextHouse
reference, which means it's the last one. To visit all our houses, we could use the following code:
var
h1, h2: THouse;
h: THouse;
begin
h1 := THouse.Create('Home');
h2 := THouse.Create('Cabin');
h1.NextHouse := h2;
...
h := h1;
while h <> nil do
begin
h.LockAllDoors;
h.CloseAllWindows;
h := h.NextHouse;
end;
Memory layout (added NextHouse as a link in the object, noted with the four LLLL's in the below diagram):
h1 h2 v v ---[ttttNNNNNNNNNNLLLL]----[ttttNNNNNNNNNNLLLL] 1234Home + 5678Cabin + | ^ | +--------+ * (no link)
In basic terms, what is a memory address?
A memory address is in basic terms just a number. If you think of memory as a big array of bytes, the very first byte has the address 0, the next one the address 1 and so on upwards. This is simplified, but good enough.
So this memory layout:
h1 h2 v v ---[ttttNNNNNNNNNN]---[ttttNNNNNNNNNN] 1234My house 5678My house
Might have these two address (the leftmost - is address 0):
- h1 = 4
- h2 = 23
Which means that our linked list above might actuall look like this:
h1 (=4) h2 (=28) v v ---[ttttNNNNNNNNNNLLLL]----[ttttNNNNNNNNNNLLLL] 1234Home 0028 5678Cabin 0000 | ^ | +--------+ * (no link)
It is typical to store an address that "points nowhere" as a zero-address.
In basic terms, what is a pointer?
A pointer is just a variable holding a memory address. You can typically ask the programming language to give you its number, but most programming languages and runtimes tries to hide the fact that there is a number beneath, just because the number itself does not really hold any meaning to you. It is best to think of a pointer as a black box, ie. you don't really know or care about how it is actually implemented, just as long as it works.
Solution 2:
In my first Comp Sci class, we did the following exercise. Granted, this was a lecture hall with roughly 200 students in it...
Professor writes on the board: int john;
John stands up
Professor writes: int *sally = &john;
Sally stands up, points at john
Professor: int *bill = sally;
Bill stands up, points at John
Professor: int sam;
Sam stands up
Professor: bill = &sam;
Bill now points to Sam.
I think you get the idea. I think we spent about an hour doing this, until we went over the basics of pointer assignment.
Solution 3:
An analogy I've found helpful for explaining pointers is hyperlinks. Most people can understand that a link on a web page 'points' to another page on the internet, and if you can copy & paste that hyperlink then they will both point to the same original web page. If you go and edit that original page, then follow either of those links (pointers) you'll get that new updated page.
Solution 4:
The reason pointers seem to confuse so many people is that they mostly come with little or no background in computer architecture. Since many don't seem to have an idea of how computers (the machine) is actually implemented - working in C/C++ seems alien.
A drill is to ask them to implement a simple bytecode based virtual machine (in any language they chose, python works great for this) with an instruction set focussed on pointer operations (load, store, direct/indirect addressing). Then ask them to write simple programs for that instruction set.
Anything requiring slightly more than simple addition is going to involve pointers and they are sure to get it.
Solution 5:
Why are pointers such a leading factor of confusion for many new, and even old, college level students in the C/C++ language?
The concept of a placeholder for a value - variables - maps onto something we're taught in school - algebra. There isn't an existing parallel you can draw without understanding how memory is physically laid out within a computer, and no one thinks about this kind of thing until they're dealing with low level things - at the C/C++/byte communications level.
Are there any tools or thought processes that helped you understand how pointers work at the variable, function, and beyond level?
Addresses boxes. I remember when I was learning to program BASIC into microcomputers, there were these pretty books with games in them, and sometimes you had to poke values into particular addresses. They had a picture of a bunch of boxes, incrementally labelled with 0, 1, 2... and it was explained that only one small thing (a byte) could fit in these boxes, and there were a lot of them - some computers had as many as 65535! They were next to each other, and they all had an address.
What are some good practice things that can be done to bring somebody to the level of, "Ah-hah, I got it," without getting them bogged down in the overall concept? Basically, drill like scenarios.
For a drill? Make a struct:
struct {
char a;
char b;
char c;
char d;
} mystruct;
mystruct.a = 'r';
mystruct.b = 's';
mystruct.c = 't';
mystruct.d = 'u';
char* my_pointer;
my_pointer = &mystruct.b;
cout << 'Start: my_pointer = ' << *my_pointer << endl;
my_pointer++;
cout << 'After: my_pointer = ' << *my_pointer << endl;
my_pointer = &mystruct.a;
cout << 'Then: my_pointer = ' << *my_pointer << endl;
my_pointer = my_pointer + 3;
cout << 'End: my_pointer = ' << *my_pointer << endl;
Same example as above, except in C:
// Same example as above, except in C:
struct {
char a;
char b;
char c;
char d;
} mystruct;
mystruct.a = 'r';
mystruct.b = 's';
mystruct.c = 't';
mystruct.d = 'u';
char* my_pointer;
my_pointer = &mystruct.b;
printf("Start: my_pointer = %c\n", *my_pointer);
my_pointer++;
printf("After: my_pointer = %c\n", *my_pointer);
my_pointer = &mystruct.a;
printf("Then: my_pointer = %c\n", *my_pointer);
my_pointer = my_pointer + 3;
printf("End: my_pointer = %c\n", *my_pointer);
Output:
Start: my_pointer = s
After: my_pointer = t
Then: my_pointer = r
End: my_pointer = u
Perhaps that explains some of the basics through example?