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I'm programming in C++ right now, and I love using pointers. But it seems that other, newer languages like Java, C#, and Python don't allow you to explicitly declare pointers. In other words, you can't write both int x and int * y, and have x be a value while y is a pointer, in any of those languages. What is the reasoning behind this?

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most people would say that they can be dangerous, because of the ability to mess up and create seg faults and or memory leaks. –  Jim Nov 2 '10 at 4:37
What are you doing with pointers that you love? –  GManNickG Nov 2 '10 at 4:47
@GMan--I think my favorite thing is allowing a class A to contain pointers to another class B, so that if an object of B is actually a class C inherited from B, then A can call C's functions instead of B's virtual functions. I guess other languages might be implemented differently to avoid that need for pointers though. Also, you can make two classes include pointers to each other so that both can access each's functions, but you can't do that with values because it would create an infinite loop with class A containing class B containing class A... –  wrongusername Nov 2 '10 at 5:00
Umm, false premise. –  Ben Voigt Nov 2 '10 at 5:57
Hehe, I love the 2 people trying to close this... how exactly would it be too vague? –  wrongusername Nov 3 '10 at 3:21

6 Answers 6

up vote 14 down vote accepted

Pointers aren't bad, they are just easy to get wrong. In newer languages they have found ways of doing the same things, but with less risk of shooting yourself in the foot.

There is nothing wrong with pointers though. Go ahead and love them.

Toward your example, why would you want both x and y pointing to the same memory? Why not just always call it x?

One more point, pointers mean that you have to manage the memory lifetime yourself. Newer languages prefer to use garbage collection to manage the memory and allowing for pointers would make that task quite difficult.

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Of course, nothing good comes for free. C++ pointers are powerful and dangerous, and in some of the other languages, while you can't shoot yourself in the foot, you have a hard time aiming down at all. There are things to be learned from how higher level languages handle pointers that can be applied to C++. –  ssube Nov 2 '10 at 4:43
"pointers mean that you have to manage the memory lifetime yourself" This is one of the most widespread and frustrating misconceptions about C++. You can manage dynamically allocated object lifetimes manually, but you don't have to (and you definitely shouldn't, most of the time). Facilities like smart pointers and containers can be used to ensure automatic lifetime management. Considering only lifetime management, this approach is actually better than garbage collection, because the lifetimes are also deterministic. –  James McNellis Nov 2 '10 at 6:06
@Ben: weak pointers solve that problem –  FredOverflow Nov 2 '10 at 6:50
@Steve: So then when you use GC, it's still you managing memory since you are the one making sure you used a GC language? –  GManNickG Nov 2 '10 at 9:16
@GMan: even in a GC language, to get rid of an subobject, you'll have to set the pointer in the parent to null. There are plenty of frameworks (especially GUI frameworks) that are prone to leaks for exactly this reason. Somewhere with the framework, one pointer survives, and an entire set of interconnected objects is leaked. –  MSalters Nov 2 '10 at 9:37

I'll start with one of my favorite Scott Meyers quotes:

When I give talks on exception handling, I teach people two things:

  • POINTERS ARE YOUR ENEMIES, because they lead to the kinds of problems that auto_ptr is designed to eliminate.

  • POINTERS ARE YOUR FRIENDS, because operations on pointers can't throw.

Then I tell them to have a nice day :-)

The point is that pointers are extremely useful and it's certainly necessary to understand them when programming in C++. You can't understand the C++ memory model without understanding pointers. When you are implementing a resource-owning class (like a smart pointer, for example), you need to use pointers, and you can take advantage of their no-throw guarantee to write exception-safe resource owning classes.

However, in well-written C++ application code, you should never have to work with raw pointers. Never. You should always use some layer of abstraction instead of working directly with pointers:

  • Use references instead of pointers wherever possible. References cannot be null and they make code easier to understand, easier to write, and easier to code review.

  • Use smart pointers to manage any pointers that you do use. Smart pointers like shared_ptr, auto_ptr, and unique_ptr help to ensure that you don't leak resources or free resources prematurely.

  • Use containers like those found in the standard library for storing collections of objects instead of allocating arrays yourself. By using containers like vector and map, you can ensure that your code is exception safe (meaning that even when an exception is thrown, you won't leak resources).

  • Use iterators when working with containers. It's far easier to use iterators correctly than it is to use pointers correctly, and many library implementations provide debug support for helping you to find where you are using them incorrectly.

  • When you are working with legacy or third-party APIs and you absolutely must use raw pointers, write a class to encapsulate usage of that API.

C++ has automatic resource management in the form of Scope-Bound Resource Management (SBRM, also called Resource Acquisition is Initialization, or RAII). Use it. If you aren't using it, you're doing it wrong.

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References can be 'null', for example when you make a reference to a dereferenced invalid pointer. See: codepad.org/JEPQpv2v –  Paul Nov 2 '10 at 5:58
@Paul: The behavior of your code snippet is undefined. "A null reference cannot exist in a well-defined program, because the only way to create such a reference would be to bind it to the “object” obtained by dereferencing a null pointer, which causes undefined behavior" (C++03 8.3.2/4). –  James McNellis Nov 2 '10 at 6:00
@James McNellis: Accessing a null pointer is also undefined behavior, but that's beside the point. The point was, is that it is completely possible to have an 'invalid' reference (i.e. 'null'/black hole of undefined behavior/etc). It may be reaching a little bit, but it is definitely fun to debug when encountered... –  Paul Nov 2 '10 at 6:10
@Paul: Well, there are a lot of things that result in undefined behavior. When you write a function that takes a reference (like f() in your example), you can rightly assume that the reference will be valid because if it isn't, your caller has already screwed up the program. Yes, you can have bugs with respect to this issue, but usually they are far and few between (and in my experience, they are often obvious enough that they get caught in code reviews). –  James McNellis Nov 2 '10 at 6:35
@Paul: Wrong. How can you, within the C++, conclude that a reference is invalid? You cannot, because in a well-defined program you can never have a bad reference. You defeat yourself when you say it's possible, because you can no longer reliably observe the state of your program, which is required to conclude a reference is invalid. (In other words, the problem lies with the guy who invoked UB, not with references. References cannot be null; UB can be entered.) –  GManNickG Nov 2 '10 at 8:04

Pointers can be abused, and managed languages prefer to protect you from potential pitfalls. However, pointers are certainly not bad - they're an integral feature of the C and C++ languages, and writing C/C++ code without them is both tricky and cumbersome.

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A true "pointer" has two characteristics.

  • It holds the address of another object (or primitive)
    • and exposes the numeric nature of that address so you can do arithmetic.

Typically the arithmetic operations defined for pointers are:

  1. Adding an integer to a pointer into an array, which returns the address of another element.
  2. Subtracting two pointers into the same array, which returns the number of elements in-between (inclusive of one end).
  3. Comparing two pointers into the same array, which indicates which element is closer to the head of the array.

Managed languages generally lead you down the road of "references" instead of pointers. A reference also holds the address of another object (or primitive), but arithmetic is disallowed.

Among other things, this means you can't use pointer arithmetic to walk off the end of an array and treat some other data using the wrong type. The other way of forming an invalid pointer is taken care of in such environments by using garbage collection.

Together this ensures type-safety, but at a terrible loss of generality.

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I don't see how you lose generality. Not having pointers just forces you to call a spade a spade: if you want an array of items, you declare it as an array of items and use integer indices, which can be numerically manipulated. (Note that in C and C++, pointer arithmetic is formally allowed ONLY between pointers that point into the same memory block, i.e., array). –  zvrba Nov 2 '10 at 10:09
@zvrba: The fact that managed languages don't let you form a reference to a subobject is a HUGE loss of generality. Not being able to type-pun to char* is a HUGE loss of generality. Also, my answer stresses that both pointers need to be into the same block. Nonetheless, pointers to different objects have an undefined but stable ordering, in managed environments this guarantee is no longer made, the garbage collector is permitted not only to move objects but to change their order. –  Ben Voigt Nov 2 '10 at 13:11
What do you mean by "loss of generality"? And unsafe casts (e.g., to char*) are not an inherent property of pointers, it's just a C feature. –  zvrba Nov 2 '10 at 13:39
@zvrba: As I said, pointers expose the numeric nature of the underlying address. The ability to turn a pointer into an integer and an integer into a pointer is quite sufficient to setup type-punning (what you called an unsafe cast, but many uses of type-punning are actually perfectly safe). –  Ben Voigt Nov 2 '10 at 15:10
Uh, C runs also on machines with non-linear memory models. There, casting to integer and back doesn't have much sense. Pointer is an object that can be used to reach another object. That is common across all languages having the pointer datatype (e.g. Pascal, Ada). All other properties you assign to pointers come from your own personal, arbitrary definition. –  zvrba Nov 2 '10 at 17:14

I try to answer OP's question directly:

In other words, you can't write both int x and int * y, and have x be a value while y is a pointer, in any of those languages. What is the reasoning behind this?

The reason behind this is the managed memory model in these languages. In C# (or Python, or Java,...) the lifetime of resources and thus usage of memory is managed automatically by the underlying runtime, or by it's garbage collector, to be precise. Briefly: The application has no control over the location of a resource in memory. It is not specified - and is even not guaranteed to stay constant during the lifetime of a resource. Hence, the notion of pointer as 'a location of something in virtual or physical memory' is completely irrelevant.

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As someone already mentioned, pointers can, and actually, will go wrong if you have a massive application. This is one of the reasons we sometimes see Windows having problems due to NULL pointers created! I personally don't like pointers because it causes terrible memory leak and no matter how good you manage your memory, it will eventually hunt you down in some ways. I experienced this a lot with OpenCV when working around image processing applications. Having lots of pointers floating around, putting them in a list and then retrieving them later caused problems for me. But again, there are good sides of using pointers and it is often a good way to tune up your code. It all depends on what you are doing, what specs you have to meet, etc.

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