Question

What are some general tips to make sure I don't leak memory in C++ programs ? How do I figure out who should free memory that has been dynamically allocated ?

Answer 1

Instead of managing memory manually, try to use smart pointers where applicable.
Take a look at the Boost lib[1] and TR1[2] pointers[3].

[1] http://www.boost.org/
[2] http://en.wikipedia.org/wiki/Technical_Report_1
[3] http://www.boost.org/doc/libs/1_36_0/libs/smart_ptr/smart_ptr.htm

Answer 2

User smart pointers everywhere you can! Whole classes of memory leaks just go away.

Answer 3

You'll want to look at smart pointers, such as boost's smart pointers.

Instead of

int main()
{ 
    Object* obj = new Object();
    //...
    delete obj;
}

boost::shared_ptr will automatically delete once the reference count is zero:

int main()
{
    boost::shared_ptr<Object> obj(new Object());
    //...
    // destructor destroys when reference count is zero
}

Note my last note, "when reference count is zero, which is the coolest part. So If you have multiple users of your object, you won't have to keep track of whether the object is still in use. Once nobody refers to your shared pointer, it gets destroyed.

This is not a panacea, however. Though you can access the base pointer, you wouldn't want to pass it to a 3rd party API unless you were confident with what it was doing. Lots of times, your "posting" stuff to some other thread for work to be done AFTER the creating scope is finished. This is common with PostThreadMessage in Win32:

void foo()
{
   boost::shared_ptr<Object> obj(new Object()); 

   // Simplified here
   PostThreadMessage(...., (LPARAM)ob.get());
   // Destructor destroys! pointer sent to PostThreadMessage is invalid! Zohnoes!
}

As always, use your thinking cap with any tool...

Answer 4

Share and know memory ownership rules across your project. Using the COM rules makes for the best consistency ([in] parameters are owned by the caller, callee must copy; [out] params are owned by the caller, callee must make a copy if keeping a reference; etc.)

Answer 5

Read up on RAII and make sure you understand it.

Answer 6

If you can, use boost shared_ptr and standard C++ auto_ptr. Those convey ownership semantics.

When you return an auto_ptr, you are telling the caller that you are giving them ownership of the memory.

When you return a shared_ptr, you are telling the caller that you have a reference to it and they take part of the ownership, but it isn't solely their responsibility.

These semantics also apply to parameters. If the caller passes you an auto_ptr, they are giving you ownership.

Answer 7

valgrind is a good tool to check your program, too.

Answer 8

One technique that has become popular with memory management in C++ is RAII. Basically you use constructors/destructors to handle resource allocation. Of course there are some other obnoxious details in C++ due to exception safety, but the basic idea is pretty simple.

The issue generally comes down to one of ownership. I highly recommend reading the Effective C++ series by Scott Meyers and Modern C++ Design by Andrei Alexandrescu.

Answer 9

If you can't/don't use a smart pointer for something (although that should be a huge red flag), type in your code with:

allocate
if allocation succeeded:
{ //scope)
     deallocate()
}

That's obvious, but make sure you type it before you type any code in the scope

Answer 10

Also, don't use manually allocated memory if there's a std library class (e.g. vector). Make sure if you violate that rule that you have a virtual destructor.

Answer 11

Exactly one return from any function. That way you can do deallocation there and never miss it.

It's too easy to make a mistake otherwise:

new a()
if (Bad()) {delete a; return;}
new b()
if (Bad()) {delete a; delete b; return;}
... // etc.

Answer 12

If you are going to manage your memory manually, you have two cases:

1. I created the object (perhaps indirectly, by calling a function that allocates a new object), I use it (or a function I call uses it), then I free it.
2. Somebody gave me the reference, so I should not free it.

If you need to break any of these rules, please document it.

It is all about pointer ownership.

Answer 13

You can intercept the memory allocation functions and see if there are some memory zones not freed upon program exit (though it is not suitable for all the applications).

It can also be done at compile time by replacing operators new and delete and other memory allocation functions.

For example check in this site [Debugging memory allocation in C++] Note: There is a trick for delete operator also something like this:

#define DEBUG_DELETE PrepareDelete(__LINE__,__FILE__); delete
#define delete DEBUG_DELETE

You can store in some variables the name of the file and when the overloaded delete operator will know which was the place it was called from. This way you can have the trace of every delete and malloc from your program. At the end of the memory checking sequence you should be able to report what allocated block of memory was not 'deleted' identifying it by filename and line number which is I guess what you want.

You could also try something like BoundsChecker under Visual Studio which is pretty interesting and easy to use.

Answer 14

@Joseph

can you explain your answer with more detail please?

Answer 15

Bah, you young kids and your new-fangled garbage collectors...

Very strong rules on "ownership" - what object or part of the software has the right to delete the object. Clear comments and wise variable names to make it obvious if a pointer "owns" or is "just look, don't touch". To help decide who owns what, follow as much as possible the "sandwich" pattern within every subroutine or method.

create a thing
use that thing
destroy that thing

Sometimes it's necessary to create and destroy in widely different places; i think hard to avoid that.

In any program requiring complex data structures, i create a strict clear-cut tree of objects containing other objects - using "owner" pointers. This tree models the basic hierarchy of application domain concepts. Example a 3D scene owns objects, lights, textures. At the end of the rendering when the program quits, there's a clear way to destroy everything.

Many other pointers are defined as needed whenever one entity needs access another, to scan over arays or whatever; these are the "just looking". For the 3D scene example - an object uses a texture but does not own; other objects may use that same texture. The destruction of an object does not invoke destruction of any textures.

Yes it's time consuming but that's what i do. I rarely have memory leaks or other problems. But then i work in the limited arena of high-performance scientific, data acquisition and graphics software. I don't often deal transactions like in banking and ecommerce, event-driven GUIs or high networked asynchronous chaos. Maybe the new-fangled ways have an advantage there!

Answer 16

We wrap all our allocation functions with a layer that appends a brief string at the front and a sentinel flag at the end. So for example you'd have a call to "myalloc( pszSomeString, iSize, iAlignment ); or new( "description", iSize ) MyObject(); which internally allocates the specified size plus enough space for your header and sentinel. Of course, don't forget to comment this out for non-debug builds! It takes a little more memory to do this but the benefits far outweigh the costs.

This has three benefits - first it allows you to easily and quickly track what code is leaking, by doing quick searches for code allocated in certain 'zones' but not cleaned up when those zones should have freed. It can also be useful to detect when a boundary has been overwritten by checking to ensure all sentinels are intact. This has saved us numerous times when trying to find those well-hidden crashes or array missteps. The third benefit is in tracking the use of memory to see who the big players are - a collation of certain descriptions in a MemDump tells you when 'sound' is taking up way more space than you anticipated, for example.

Answer 17

There's already a lot about how to not leak, but if you need a tool to help you track leaks take a look at:

• BoundsChecker under VS
• MMGR C/C++ lib from FluidStudio http://www.paulnettle.com/pub/FluidStudios/MemoryManagers/Fluid_Studios_Memory_Manager.zip (its overrides the allocation methods and creates a report of the allocations, leaks, etc)

Answer 18

C++ is designed RAII in mind. There is really no better way to manage memory in C++ I think. But be careful not to allocate very big chunks (like buffer objects) on local scope. It can cause stack overflows and, if there is a flaw in bounds checking while using that chunk, you can overwrite other variables or return addresses, which leads to all kinds security holes.

Answer 19

Others have mentioned ways of avoiding memory leaks in the first place (like smart pointers). But a profiling and memory-analysis tool is often the only way to track down memory problems once you have them.

Valgrind memcheck is an excellent free one.

Answer 20

I totally agree with the comments on RAII. RAII is the key to effective memory management, not only in C++ but also in C#.

Answer 21

Use RAII.

• Forget Garbage Collection (Use RAII instead, or try C# or Java). Note that GB can leak, too (if you forget to "null" some references), and that GB won't help you to dispose of ressources (if you have an object which acquired a handle to a file, the file won't be freed automatically when the object will go out of scope if you don't do it manually i n Java, or use the "dispose" pattern in C#).
• Forget the "one return per function" rule. This is a good C advice to avoid leaks, but it is outdated in C++ because of its use of exceptions (use RAII instead).
• And while the "Sandwich Pattern" is a good C advice, it is outdated in C++ because of its use of exceptions (use RAII instead).

This post seem to be repetitive, but in C++, the most basic pattern to know is RAII. Learn to use smart pointers, both from boost, TR1 or even the lowly (but ofter efficient enough) auto_ptr (but you must know its limitations).

RAII is the basis of both exception safety and ressource disposal in C++, and no other pattern (sandwich, etc.) will give you both (and most of the time, it won't give you any).

See below a comparison of RAII and non RAII code:

---

void doSandwich()
{
   T * p = new T() ;
   // process p
   delete p ; // leak if the p processing throws or return
}

void doRAIIDynamic()
{
   std::auto_ptr<T> p(new T()) ; // you can use other smart pointers, too
   // process p
   // WON'T EVER LEAK, even in case of exceptions, returns, breaks, etc.
}

void doRAIIStatic()
{
   T p ;
   // process p
   // WON'T EVER LEAK, even in case of exceptions, returns, breaks, etc.
}

---

Answer 22

I thoroughly endorse all the advice about RAII and smart pointers, but I'd also like to add a slightly higher-level tip: the easiest memory to manage is the memory you never allocated. Unlike languages like C# and Java, where pretty much everything is a reference, in C++ you should put objects on the stack whenever you can. As I've see several people (including Dr Stroustrup) point out, the main reason why garbage collection has never been popular in C++ is that well-written C++ doesn't produce much garbage in the first place.

Don't write

Object* x = new Object;

or even

shared_ptr<Object> x(new Object);

when you can just write

Object x;

Answer 23

One of the only examples about allocating and destroying in different places is thread creation (the parameter you pass). But even in this case is easy. Here is the function/method creating a thread:

struct myparams {
int x;
std::vector<double> z;
}

std::auto_ptr<myparams> param(new myparams(x, ...));
// Release the ownership in case thread creation is successfull
if (0 == pthread_create(&th, NULL, th_func, param.get()) param.release();
...

Here instead the thread function

extern "C" void* th_func(void* p) {
   try {
       std::auto_ptr<myparams> param((myparams*)p);
       ...
   } catch(...) {
   }
   return 0;
}

Pretty easyn isn't it? In case the thread creation fails the resource will be free'd (deleted) by the auto_ptr, otherwise the ownership will be passed to the thread. What if the thread is so fast that after creation it releases the resource before the

param.release();

gets called in the main function/method? Nothing! Because we will 'tell' the auto_ptr to ignore the deallocation. Is C++ memory management easy isn't it? Cheers,

Ema!

Answer 24

For MSVC only, add the following to the top of each .cpp file:

#ifdef _DEBUG
#define new DEBUG_NEW
#endif

Then, when debugging with VS2003 or greater, you will be told of any leaks when your program exits (it tracks new/delete). It's basic, but it has helped me in the past.

Answer 25

Great question!

if you are using c++ and you are developing real-time CPU-and-memory boud application (like games) you need to write your own Memory Manager.

I think the better you can do is merge some interesting works of various authors, I can give you some hint:

• Fixed size allocator is heavily discussed, everywhere in the net

• Small Object Allocation was introduced by Alexandrescu in 2001 in his perfect book "Modern c++ design"

• A great advancement (with source code distributed) can be found in an amazing article in Game Programming Gem 7 (2008) named "High Performance Heap allocator" written by Dimitar Lazarov

• A great list of resources can be found in this article

Do not start writing a noob unuseful allocator by yourself... DOCUMENT YOURSELF first.

Answer 26

A frequent source of these bugs is when you have a method that accepts a reference or pointer to an object but leaves ownership unclear. Style and commenting conventions can make this less likely.

Let the case where the function takes ownership of the object be the special case. In all situations where this happens, be sure to write a comment next to the function in the header file indicating this. You should strive to make sure that in most cases the module or class which allocates an object is also responsible for deallocating it.

Using const can help a lot in some cases. If a function will not modify an object, and does not store a reference to it that persists after it returns, accept a const reference. From reading the caller's code it will be obvious that your function has not accepted ownership of the object. You could have had the same function accept a non-const pointer, and the caller may or may not have assumed that the callee accepted ownership, but with a const reference there's no question.

Do not use non-const references in argument lists. It is very unclear when reading the caller code that the callee may have kept a reference to the parameter.

I disagree with the comments recommending reference counted pointers. This usually works fine, but when you have a bug and it doesn't work, especially if your destructor does something non-trivial, such as in a multithreaded program. Definitely try to adjust your design to not need reference counting if it's not too hard.

Answer 27

Tips in order of Importance:

-Tip#1 Always remember to declare your destructors "virtual".

-Tip#2 Use RAII

-Tip#3 Use boost's smartpointers

-Tip#4 Don't write your own buggy Smartpointers, use boost (on a project I'm on right now I can't use boost, and I've suffered having to debug my own smart pointers, I would definately not take the same route again, but then again right now I can't add boost to our dependencies)

-Tip#5 If its some casual/non-performance critical (as in games with thousands of objects) work look at Thorsten Ottosen's boost pointer container

-Tip#6 Find a leak detection header for your platform of choice such as Visual Leak Detection's "vld" header

Answer 28

＠mrlinx

Thanks for the link to FluidStudios memory manager ! http://www.paulnettle.com/pub/FluidStudios/MemoryManagers/Fluid_Studios_Memory_Manager.zip

I'd been trying to find that link the other day, but all the links I found were broken

Answer 29

Manage memory the same way you manage other resources (handles, files, db connections, sockets...). GC would not help you with them either.

Answer 30

valgrind (only avail for *nix platforms) is a very nice memory checker