Question

Another question I thought for sure would have been asked before, but I don't see it in the "Related Questions" list.

Could you C++ developers please give us a good description of what RAII is, why it is important, and whether or not it might have any relevance to other languages?

I do know a little bit. I believe it stands for "Resource Acquisition is Initialization". However, that name doesn't jive with my (possibly incorrect) understanding of what RAII is: I get the impression that RAII is a way of initializing objects on the stack such that, when those variables go out of scope, the destructors will automatically be called causing the resources to be cleaned up.

So why isn't that called "using the stack to trigger cleanup" (UTSTTC:)? How do you get from there to "RAII"?

And how can you make something on the stack that will cause the cleanup of something that lives on the heap? Also, are there cases where you can't use RAII? Do you ever find yourself wishing for garbage collection? At least a garbage collector you could use for some objects while letting others be managed?

Thanks.

Answer 1

So why isn't that called "using the stack to trigger cleanup" (UTSTTC:)?

Because it is much more than that. Besides, RAII is telling you what to do to solve many problems (Acquire your ressources in a constructor!) UTSTTC is just one application of that.

Ressource Management sucks. Here, ressource is anything that needs cleanup after use. Studies of projects across many platforms show the majority of bugs are related to ressource management - and it's particularly bad on Windows (due to the many types of objects and allocators).

In C++, ressource management is particluary complicated dues to the combination of exceptions and (C++ - style) templates. For a peek under the hood, see GOTW8).

---

C++ guarantees that the destructor is called IF AND ONLY IF the constructor succeeded. Relying on that, RAII can solve many nasty problems the average programmer might not even be aware of. Here are a few examples beyond the "my local variables will be destroyed when ever I return".

Lets start with an simplistic FileHandle class employing RAII:

// an overly simplistic file handle, employing RAII:
class FileHandle
{
 public:
   FileHandle(char * name)
   {
      h = fileopen(name);
      if (!h) 
        throw "MAYDAY! MAYDAY"; 
   }
   ~FileHandle() { fileclose(h); }

   // ...   
}

If construction fails (with an exception), no other member function - not even the destructor - gets called.

RAII avoids using objects in an invalid state. it already makes life easier before we even use the object.

Now, have a look at temporary objects:

void CopyFileData(FileHandle source, FileHandle dest);
// ...
void Foo()
{
   CopyFileData(FileHandle("C:\source"), FileHandle("C:\dest"));
}

There are three error cases to handled: no file can be opened, only one file can be opened, both files can be opened but copying the files failed. In a non-RAII implementation, Foo() would have to handle all three cases explicitely.

RAII releases ressources that were acquired, even when multiple ressources are aquired within one statement.

Now, lets aggregate some objects:

class Logger
{
   FileHandle h, hDuplex; // this logger can write to two files at once!
 public:
   Logger(char const * file, const char * duplex) : h(file), hDuplex(duplex)
   {
      if (!filewrite_duplex(h, hDuplex, "New Session"))
        throw "Ugh damn!";
   }
}

The constructor of Logger will fail if h can't be opened, hDuplex can't be opened, or writing to the files fails. In any of these cases, Logger's destructor will not be called - so we can't rely on Loggers destructor to release the files). But if h was opened, its destructor will be called during cleanup of the constructor call.

RAII simplifies cleanup after partial construction.

---

Negative points:

Negative points? All problems can be solved with RAII and smart pointers ;-)

RAII is sometimes unwieldy when you need delayed acquisition, pushing aggregated objects onto the heap.
Imagine the Logger needs a SetTargetFile(char * target). In that case, the handle, that still needs to be a member of Logger, needs to reside on the heap (e.g. in a smart pointer, to trigger the handles destruction appropriately.)

I've never wished for garbage collection really. When I do C# I sometimes feel a moment of bliss that I just don't need to care, but much more I miss all the cool toys that can be created through deterministic destruction. (using/IDisposable just doesn't cut it.)

I've had one particulary complex structure that might have benefitted from GC, where "simple" smart pointers would cause circular references over multiple classes. We muddled through by carefully balancing strong and weak pointers, but anytime we want to change something, we have to study a big relationship chart. GC might have been better, but some of the components held ressources that should be release ASAP.

Answer 2

And how can you make something on the stack that will cause the cleanup of something that lives on the heap?

class int_buffer
{
   size_t m_size;
   int *  m_buf;

   public:
   int_buffer( size_t size )
     : m_size( size ), m_buf( 0 )
   {
       if( m_size > 0 )
           m_buf = new int[m_size]; // will throw on failure by default
   }
   ~int_buffer()
   {
       delete m_buf;
   }
   /* ...rest of class implementation...*/

};


void foo() 
{
    int_buffer ib(20); // creates a buffer of 20 bytes
    std::cout << ib.size() << std::endl;
} // here the destructor is called automatically even if an exception is thrown and the memory ib held is freed.

When an instance of int_buffer comes into existence it must have a size, and it will allocate the necessary memory. When it goes out of scope, it's destructor is called. This is very useful for things like synchronization objects. Consider

class mutex
{
   // ...
   take();
   release();

   class mutex::sentry
   {
      mutex & mm;
      public:
      sentry( mutex & m ) : mm(m) 
      {
          mm.take();
      }
      ~sentry()
      {
          mm.release();
      }
   }; // mutex::sentry;
};
mutex m;

int getSomeValue()
{
    mutex::sentry ms( m ); // blocks here until the mutex is taken
    return 0;  
} // the mutex is released in the destructor call here.

Also, are there cases where you can't use RAII?

No, not really.

Do you ever find yourself wishing for garbage collection? At least a garbage collector you could use for some objects while letting others be managed?

Never. Garbage collection only solves a very small subset of dynamic resource management.

Answer 3

There are already a lot of good answers here, but I'd just like to add:
A simple explanation of RAII is that, in C++, an object allocated on the stack is destroyed whenever it goes out of scope. That means, an objects destructor will be called and can do all necessary cleanup.
That means, if an object is created without "new", no "delete" is required. And this is also the idea behind "smart pointers" - they reside on the stack, and essentially wraps a heap based object.

Answer 4

RAII is an acronym for Resource Acquisition Is Initialization.

This technique is very much unique to C++ because of their support for both Constructors & Destructors & almost automatically the constructors that are matching that arguments being passed in or the worst case the default constructor is called & destructors if explicity provided is called otherwise the default one that is added by the C++ compiler is called if you didn't write an destructor explicitly for a C++ class. This happens only for C++ objects that are auto-managed - meaning that are not using the free store (memory allocated/deallocated using new,new[]/delete,delete[] C++ operators).

RAII technique makes use of this auto-managed object feature to handle the objects that are created on the heap/free-store by explcitly asking for more memory using new/new[], which should be explicitly destroyed by calling delete/delete[]. The auto-managed object's class will wrap this another object that is created on the heap/free-store memory. Hence when auto-managed object's constructor is run, the wrapped object is created on the heap/free-store memory & when the auto-managed object's handle goes out of scope, destructor of that auto-managed object is called automatically in which the wrapped object is destroyed using delete. With OOP concepts, if you wrap such objects inside another class in private scope, you wouldn't have access to the wrapped classes members & methods & this is the reason why smart pointers (aka handle classes) are designed for. These smart pointers expose the wrapped object as typed object to external world & there by allowing to invoke any members/methods that the exposed memory object is made up of. Note that smart pointers have various flavors based on different needs. You should refer to Modern C++ programming by Andrei Alexandrescu or boost library's (www.boostorg) shared_ptr.hpp implementation/documentation to learn more about it. Hope this helps you to understand RAII.

Answer 5

I'd like to put it a bit more strongly then previous responses.

RAII, Resource Acquisition Is Initialization means that all acquired resources should be acquired in the context of the initialization of an object. This forbids "naked" resource acquisition. The rationale is that cleanup in C++ works on object basis, not function-call basis. Hence, all cleanup should be done by objects, not function calls. In this sense C++ is more-object oriented then e.g. Java. Java cleanup is based on function calls in finally clauses.

Answer 6

I concur with cpitis. But would like to add that the resources can be anything not just memory. The resource could be a file, a critical section, a thread or a database connection.

It is called Resource Acquisition Is Initialization because the resource is acquired when the object controlling the resource is constructed, If the constructor failed (ie due to an exception) the resource is not acquired. Then once the object goes out of scope the resource is released. c++ guarantees that all objects on the stack that have been successfully constructed will be destructed (this includes constructors of base classes and members even if the super class constructor fails).

The rational behind RAII is to make resource acquisition exception safe. That all resources acquired are properly released no matter where an exception occurs. However this does rely on the quality of the class that acquires the resource (this must be exception safe and this is hard).

Answer 7

RAII comes from Resource Allocation Is Initialization. Basically, it means that when a constructor finishes the execution, the constructed object is fully initialized and ready to use. It also implies that the destructor will release any resources (e.g. memory, OS resources) owned by the object.

Compared with garbage collected languages/technologies (e.g. Java, .NET), C++ allows full control of the life of an object. For a stack allocated object, you'll know when the destructor of the object will be called (when the execution goes out of the scope), thing that is not really controlled in case of garbage collection. Even using smart pointers in C++ (e.g. boost::shared_ptr), you'll know that when there is no reference to the pointed object, the destructor of that object will be called.

Answer 8

The problem with garbage collection is that you lose the deterministic destruction that's crucial to RAII. Once a variable goes out of scope, it's up to the garbage collector when the object will be reclaimed. The resource that's held by the object will continue to be held until the destructor gets called.

Answer 9

RAII is using C++ destructors semantics to manage resources. For example, consider a smart pointer. You have a parameterized constructor of the pointer that initializes this pointer with the adress of object. You allocate a pointer on stack:

SmartPointer pointer( new ObjectClass() );

When the smart pointer goes out of scope the destructor of the pointer class deletes the connected object. The pointer is stack-allocated and the object - heap-allocated.

There are certain cases when RAII doesn't help. For example, if you use reference-counting smart pointers (like boost::shared_ptr) and create a graph-like structure with a cycle you risk facing a memory leak because the objects in a cycle will prevent each other from being released. Garbage collection would help against this.

Answer 10

Please see:

http://stackoverflow.com/questions/165723/do-programmers-of-other-languages-besides-c-use-know-or-understand-raii

http://stackoverflow.com/questions/395123/raii-and-smart-pointers-in-c

http://stackoverflow.com/questions/161177/does-c-support-finally-blocks-and-whats-this-raii-i-keep-hearing-about

http://stackoverflow.com/questions/159240/raii-vs-exceptions

etc..