Has anyone here ever used C++'s "placement new"? If so, what for? It looks to me like it would only be useful on memory-mapped hardware.

  • 13
    This is just the information I've been looking for, to call object constructors on boost allocated memory pools. (Hoping these keywords will make it easier for someone to find in future). – Sideshow Bob Sep 14 '11 at 10:19
  • 2
    It is used in the C++11 Wikipedia article in the constructor of a union. – HelloGoodbye Nov 5 '15 at 10:15
  • @HelloGoodbye, interesting! In the article you linked, why can't you just do p = pt and use assignment operator of Point instead of doing new(&p) Point(pt) ? I wonder of the differences between the two. Would the former call operator= on Point, while the latter calls copy constructor of Point ? but I'm still not very clear why one is better than the other. – Andrei-Niculae Petre Nov 28 at 20:29
  • @Andrei-NiculaePetre I haven't used placement new myself, but I guess you should use it—together with the copy constructor—if you don't currently have an object of that class, otherwise you should use the copy assignment operator. Unless the class is trivial; then it doesn't matter which of them you use. The same thing goes for destruction of the object. Failing to handle this properly for non-trivial classes may very likely lead to strange behavior, and might even cause undefined behavior in some situations. – HelloGoodbye Nov 28 at 23:30
  • @Andrei-NiculaePetre Actually, I find the example in the Wikipedia article quite bad, as it just assumes that no prior object exists and that they need to construct one. This is not the case if U::operator= has just been called. – HelloGoodbye Nov 28 at 23:44

22 Answers 22

up vote 330 down vote accepted

Placement new allows you to construct an object in memory that's already allocated.

You may want to do this for optimization when you need to construct multiple instances of an object, and it is faster not to re-allocate memory each time you need a new instance. Instead, it might be more efficient to perform a single allocation for a chunk of memory that can hold multiple objects, even though you don't want to use all of it at once.

DevX gives a good example:

Standard C++ also supports placement new operator, which constructs an object on a pre-allocated buffer. This is useful when building a memory pool, a garbage collector or simply when performance and exception safety are paramount (there's no danger of allocation failure since the memory has already been allocated, and constructing an object on a pre-allocated buffer takes less time):

char *buf  = new char[sizeof(string)]; // pre-allocated buffer
string *p = new (buf) string("hi");    // placement new
string *q = new string("hi");          // ordinary heap allocation

You may also want to be sure there can be no allocation failure at a certain part of critical code (for instance, in code executed by a pacemaker). In that case you would want to allocate memory earlier, then use placement new within the critical section.

Deallocation in placement new

You should not deallocate every object that is using the memory buffer. Instead you should delete[] only the original buffer. You would have to then call the destructors of your classes manually. For a good suggestion on this, please see Stroustrup's FAQ on: Is there a "placement delete"?

  • 46
    It's not deprecated as you need this feature to effeciently implement container objects (like vector). If you are not building your own container you don't need to use this feature though. – Martin York Oct 21 '08 at 21:19
  • 24
    It is also very important to remember to #include <memory>, otherwise you might run into some terrible headaches in some platforms that do not automatically recognize placement new – Ramon Zarazua B. Sep 24 '09 at 18:28
  • 18
    Strictly, it's undefined behaviour to call delete[] on the original char buffer. Using placement new has ended the lifetime of the original char objects by re-using their storage. If you now call delete[] buf the dynamic type of the object(s) pointed to no longer matches their static type so you have undefined behaviour. It is more consistent to use operator new/operator delete to allocate raw memory inteded for use by placement new. – CB Bailey Mar 21 '10 at 15:10
  • 25
    I would definitely skip on using the heap in a pacemaker :-) – Eli Bendersky Jan 9 '11 at 8:42
  • 10
    @RamonZarazua Wrong header, it's #include <new>. – bit2shift Apr 26 '16 at 3:46

We use it with custom memory pools. Just a sketch:

class Pool {
public:
    Pool() { /* implementation details irrelevant */ };
    virtual ~Pool() { /* ditto */ };

    virtual void *allocate(size_t);
    virtual void deallocate(void *);

    static Pool::misc_pool() { return misc_pool_p; /* global MiscPool for general use */ }
};

class ClusterPool : public Pool { /* ... */ };
class FastPool : public Pool { /* ... */ };
class MapPool : public Pool { /* ... */ };
class MiscPool : public Pool { /* ... */ };

// elsewhere...

void *pnew_new(size_t size)
{
   return Pool::misc_pool()->allocate(size);
}

void *pnew_new(size_t size, Pool *pool_p)
{
   if (!pool_p) {
      return Pool::misc_pool()->allocate(size);
   }
   else {
      return pool_p->allocate(size);
   }
}

void pnew_delete(void *p)
{
   Pool *hp = Pool::find_pool(p);
   // note: if p == 0, then Pool::find_pool(p) will return 0.
   if (hp) {
      hp->deallocate(p);
   }
}

// elsewhere...

class Obj {
public:
   // misc ctors, dtors, etc.

   // just a sampling of new/del operators
   void *operator new(size_t s)             { return pnew_new(s); }
   void *operator new(size_t s, Pool *hp)   { return pnew_new(s, hp); }
   void operator delete(void *dp)           { pnew_delete(dp); }
   void operator delete(void *dp, Pool*)    { pnew_delete(dp); }

   void *operator new[](size_t s)           { return pnew_new(s); }
   void *operator new[](size_t s, Pool* hp) { return pnew_new(s, hp); }
   void operator delete[](void *dp)         { pnew_delete(dp); }
   void operator delete[](void *dp, Pool*)  { pnew_delete(dp); }
};

// elsewhere...

ClusterPool *cp = new ClusterPool(arg1, arg2, ...);

Obj *new_obj = new (cp) Obj(arg_a, arg_b, ...);

Now you can cluster objects together in a single memory arena, select an allocator which is very fast but does no deallocation, use memory mapping, and any other semantic you wish to impose by choosing the pool and passing it as an argument to an object's placement new operator.

  • 1
    Nice, but the problem is to define Pool::find_pool(void *) efficiently... – jdkoftinoff Jan 28 '11 at 16:53
  • Yep. We get fairly clever about that, but it's off-topic for this question. – Don Wakefield Jan 28 '11 at 20:28
  • 1
    @jdkoftinoff do you have any link to an actual code sample? seems pretty interesting for me! – Victor Jan 14 '17 at 10:26
  • @DonWakefield How do you handle alignment in this pool? Shouldn't you pass alignment as an argument to allocate() somewhere? – Mikhail Vasilyev Jun 13 at 17:16
  • @MikhailVasilyev, in a real implementation, you would of course handle that. Example code only. – Don Wakefield Jun 13 at 17:36

It's useful if you want to separate allocation from initialization. STL uses placement new to create container elements.

I've used it in real-time programming. We typically don't want to perform any dynamic allocation (or deallocation) after the system starts up, because there's no guarantee how long that is going to take.

What I can do is preallocate a large chunk of memory (large enough to hold any amount of whatever that the class may require). Then, once I figure out at runtime how to construct the things, placement new can be used to construct objects right where I want them. One situation I know I used it in was to help create a heterogeneous circular buffer.

It's certainly not for the faint of heart, but that's why they make the syntax for it kinda gnarly.

  • Hi TED, could you please share more about the solution you have. I'm thinking on a pre-allocated solution but have not got much progress. Thank you in advance! – Viet Mar 22 '10 at 12:38
  • Well, the actual hetrogenious circular buffer code was really the tricky part to get right. The palcement new looks a little grisly, but by comparison it was no trouble at all. – T.E.D. Mar 23 '10 at 13:40

I've used it to construct objects allocated on the stack via alloca().

shameless plug: I blogged about it here.

  • Very cool, you don't treat alloca failing though. – Motti Nov 3 '08 at 8:11
  • interesting article, but I'm not sure I understand the advantage of using this over boost::array. Can you expand on that a bit? – GrahamS Feb 10 '11 at 11:52
  • boost::array requires the size of the array to be a compile-time constant. This does not have that limitation. – Ferruccio Feb 10 '11 at 12:26
  • 2
    @Ferruccio This is pretty cool, I did notice that your macro is slightly unsafe though, namely size could be an exepression. If x+1 is passed in for example you would expand it to sizeof(type) * x + 1 which would be incorrect. You need to bracket up your macro to make it safer. – Benj Mar 15 '12 at 11:22
  • Using with alloca looks dangerous to me if an exception is thrown as you have to call the destructors on all your objects. – CashCow Apr 12 '13 at 11:13

Head Geek: BINGO! You got it totally - that's exactly what it's perfect for. In many embedded environments, external constraints and/or the overall use scenario forces the programmer to separate the allocation of an object from its initialization. Lumped together, C++ calls this "instantiation"; but whenever the constructor's action must be explicitly invoked WITHOUT dynamic or automatic allocation, placement new is the way to do it. It's also the perfect way to locate a global C++ object that is pinned to the address of a hardware component (memory-mapped I/O), or for any static object that, for whatever reason, must reside at a fixed address.

I've used it to create a Variant class (i.e. an object that can represent a single value that can be one of a number of different types).

If all of the value-types supported by the Variant class are POD types (e.g. int, float, double, bool) then a tagged C-style union is sufficient, but if you want some of the value-types to be C++ objects (e.g. std::string), the C union feature won't do, as non-POD datatypes may not be declared as part of a union.

So instead I allocate a byte array that is big enough (e.g. sizeof(the_largest_data_type_I_support)) and use placement new to initialize the appropriate C++ object in that area when the Variant is set to hold a value of that type. (And placement delete beforehand when switching away from a different non-POD data type, of course)

  • Erm, non-POD datatypes can be declared within a union, so long as you provide a union ctor - and hey - that ctor would probably use placement new to initialise its non-POD subclass. Ref: stackoverflow.com/a/33289972/2757035 Reinventing this wheel using an arbitrarily large byte array is an impressive piece of acrobatics but seems wholly unnecessary, So, what have I missed? :) – underscore_d Nov 20 '15 at 0:50
  • 4
    You missed all the versions of C++ before C++11, that in many cases still need to be supported. :) – Jeremy Friesner Nov 23 '15 at 2:33

It's also useful when you want to re-initialize global or statically allocated structures.

The old C way was using memset() to set all elements to 0. You cannot do that in C++ due to vtables and custom object constructors.

So I sometimes use the following

 static Mystruct m;

 for(...)  {
     // re-initialize the structure. Note the use of placement new
     // and the extra parenthesis after Mystruct to force initialization.
     new (&m) Mystruct();

     // do-some work that modifies m's content.
 }
  • 1
    Wouldn't you need to do a corresponding destruction before re-initializing it that way? – Head Geek Apr 5 '13 at 3:17
  • [Edited for spelling] Usually - you do. But sometimes, when you know the class does not allocate memory or other resources (or you deallocated them externally - for example when you use memory pools), you can use this technique. It does guarantee that the v-table pointers are not overwritten. – nimrodm 16 hours ago – nimrodm Apr 6 '13 at 18:54
  • 1
    Even in C, using setting all bits to 0 is only guarantied to produce a representation of 0 for integral types, not other types (null pointer can have a non zero representation). – curiousguy Aug 16 '15 at 14:20
  • @curiousguy - for primitive types you are correct (it will make the program predictable which is an advantage when it comes to debugging). However, C++ datatypes will have their constructor ran (in-place) and will be properly initialized. – nimrodm Aug 16 '15 at 14:27

It is useful if you are building a kernel - where do you place the kernel code you read from disk or the pagetable? You need to know where to jump to.

Or in other, very rare circumstances such as when you have loads of allocated room and want to place a few structures behind each other. They can be packed this way without the need for the offsetof() operator. There are other tricks for that too, though.

I also believe some STL implementations make use of placement new, like std::vector. They allocate room for 2^n elements that way and don't need to always realloc.

  • Reducing memory allocations is one primary reason to use it, as well as "tricks" like loading objects off of disk – lefticus Oct 21 '08 at 16:40
  • I don't know of any kernels written in C++; most kernels are written in straight C. – Adam Rosenfield Oct 21 '08 at 16:50
  • 6
    The operating system with which I learned OS basics is written in C++: sweb.sourceforge.net – mstrobl Oct 21 '08 at 19:13

Placement new is also very useful when serialising (say with boost::serialization). In 10 years of c++ this is only the second case I've needed placement new for (third if you include interviews :) ).

I think this has not been highlighted by any answer, but another good example and usage for the new placement is to reduce the memory fragmentation (by using memory pools). This is specially useful in embedded and high availability systems. In this last case it's specially important because for a system that has to run 24/365 days it's very important to have no fragmentation. This problem has nothing to do with memory leakage.

Even when a very good malloc implementation is used (or similar memory management function) it's very difficult to deal with fragmentation for a long time. At some point if you don't manage cleverly the memory reservation/release calls you could end up with a lot of small gaps that are difficult to reuse (assign to new reservations). So, one of the solutions that are used in this case is to use a memory pool to allocate before hand the memory for the application objects. After-wards each time you need memory for some object you just use the new placement to create a new object on the already reserved memory.

This way, once your application starts you already have all the needed memory reserved. All the new memory reservation/release goes to the allocated pools (you may have several pools, one for each different object class). No memory fragmentation happens in this case since there will no gaps and your system can run for very long periods (years) without suffering from fragmentation.

I saw this in practice specially for the VxWorks RTOS since its default memory allocation system suffers a lot from fragmentation. So allocating memory through the standard new/malloc method was basically prohibited in the project. All the memory reservations should go to a dedicated memory pool.

It's used by std::vector<> because std::vector<> typically allocates more memory than there are objects in the vector<>.

I've used it for storing objects with memory mapped files.
The specific example was an image database which processed vey large numbers of large images (more than could fit in memory).

I've used it to create objects based on memory containing messages received from the network.

I've seen it used as a slight performance hack for a "dynamic type" pointer (in the section "Under the Hood"):

But here is the tricky trick I used to get fast performance for small types: if the value being held can fit inside of a void*, I don't actually bother allocating a new object, I force it into the pointer itself using placement new.

  • What does if the value being held can fit inside of a void* mean? Its always possible to assign any pointer type to void*. Can you please show us some example? – anurag86 Oct 20 '15 at 14:06
  • @anurag86: On my 64 bit machine, a void* takes 8 bytes. It's a little silly to point an eight-byte void* at a one-byte bool. But it's entirely possible to actually overlay the bool on the void*, much like a union { bool b; void* v }. You need some way to know that the thing you called a void* is actually a bool (or a short, or a float, etc.). The article I linked to describes how to do that. And, to answer the original question, placement new is the feature used to create a bool (or other type) where a void* is expected, (casts are used to later get/modify the value). – Max Lybbert Oct 20 '15 at 16:12
  • @anurag86: It's not the same thing, but you may be interested in tagged pointers ( en.wikipedia.org/wiki/Tagged_pointer ). – Max Lybbert Oct 20 '15 at 16:13

It's actually kind of required to implement any kind of data structure that allocates more memory than minimally required for the number of elements inserted (i.e., anything other than a linked structure which allocates one node at a time).

Take containers like unordered_map, vector, or deque. These all allocate more memory than is minimally required for the elements you've inserted so far to avoid requiring a heap allocation for every single insertion. Let's use vector as the simplest example.

When you do:

vector<Foo> vec;

// Allocate memory for a thousand Foos:
vec.reserve(1000);

... that doesn't actually construct a thousand Foos. It simply allocates/reserves memory for them. If vector did not use placement new here, it would be default-constructing Foos all over the place as well as having to invoke their destructors even for elements you never even inserted in the first place.

Allocation != Construction, Freeing != Destruction

Just generally speaking to implement many data structures like the above, you cannot treat allocating memory and constructing elements as one indivisible thing, and you likewise cannot treat freeing memory and destroying elements as one indivisible thing.

There has to be a separation between these ideas to avoid superfluously invoking constructors and destructors unnecessarily left and right, and that's why the standard library separates the idea of std::allocator (which doesn't construct or destroy elements when it allocates/frees memory*) away from the containers that use it which do manually construct elements using placement new and manually destroy elements using explicit invocations of destructors.

  • I hate the design of std::allocator but that's a different subject I'll avoid ranting about. :-D

So anyway, I tend to use it a lot since I've written a number of general-purpose standard-compliant C++ containers that could not be built in terms of the existing ones. Included among them is a small vector implementation I built a couple decades ago to avoid heap allocations in common cases, and a memory-efficient trie (doesn't allocate one node at a time). In both cases I couldn't really implement them using the existing containers, and so I had to use placement new to avoid superfluously invoking constructors and destructors on things unnecessary left and right.

Naturally if you ever work with custom allocators to allocate objects individually, like a free list, then you'd also generally want to use placement new, like this (basic example which doesn't bother with exception-safety or RAII):

Foo* foo = new(free_list.allocate()) Foo(...);
...
foo->~Foo();
free_list.free(foo);

Generally, placement new is used to get rid of allocation cost of a 'normal new'.

Another scenario where I used it is a place where I wanted to have access to the pointer to an object that was still to be constructed, to implement a per-document singleton.

The one place I've run across it is in containers which allocate a contiguous buffer and then fill it with objects as required. As mentioned, std::vector might do this, and I know some versions of MFC CArray and/or CList did this (because that's where I first ran across it). The buffer over-allocation method is a very useful optimization, and placement new is pretty much the only way to construct objects in that scenario. It is also used sometimes to construct objects in memory blocks allocated outside of your direct code.

I have used it in a similar capacity, although it doesn't come up often. It's a useful tool for the C++ toolbox, though.

Script engines can use it in the native interface to allocate native objects from scripts. See Angelscript (www.angelcode.com/angelscript) for examples.

See the fp.h file in the xll project at http://xll.codeplex.com It solves the "unwarranted chumminess with the compiler" issue for arrays that like to carry their dimensions around with them.

typedef struct _FP
{
    unsigned short int rows;
    unsigned short int columns;
    double array[1];        /* Actually, array[rows][columns] */
} FP;

Here is the killer use for the C++ in-place constructor: aligning to a cache line, as well as other powers of 2 boundaries. Here is my ultra-fast pointer alignment algorithm to any power of 2 boundaries with 5 or less single-cycle instructions:

/* Quickly aligns the given pointer to a power of two boundary IN BYTES.
@return An aligned pointer of typename T.
@brief Algorithm is a 2's compliment trick that works by masking off
the desired number in 2's compliment and adding them to the
pointer.
@param pointer The pointer to align.
@param boundary_byte_count The boundary byte count that must be an even
power of 2.
@warning Function does not check if the boundary is a power of 2! */
template <typename T = char>
inline T* AlignUp(void* pointer, uintptr_t boundary_byte_count) {
  uintptr_t value = reinterpret_cast<uintptr_t>(pointer);
  value += (((~value) + 1) & (boundary_byte_count - 1));
  return reinterpret_cast<T*>(value);
}

struct Foo { Foo () {} };
char buffer[sizeof (Foo) + 64];
Foo* foo = new (AlignUp<Foo> (buffer, 64)) Foo ();

Now doesn't that just put a smile on your face (:-). I ♥♥♥ C++1x

Your Answer

By clicking "Post Your Answer", you acknowledge that you have read our updated terms of service, privacy policy and cookie policy, and that your continued use of the website is subject to these policies.

Not the answer you're looking for? Browse other questions tagged or ask your own question.