std::unique_ptr twice as big as underlying object

Question

I'm having an issue with (specifically the MSFT VS 10.0 implementation of) std::unique_ptrs. When I create a std::list of them, I use twice as much memory as when I create a std::list of just the underlying object (note: this is a big object -- ~200 bytes, so it's not just an extra reference counter lying around).

In other words, if I run:

std::list<MyObj> X;
X.resize( 1000, MyObj());

my application will require half as much memory as when I run:

std::list<std::unique_ptr<MyObj>> X;
for ( int i=0; i<1000; i++ ) X.push_back(std::unique_ptr<MyObj>(new MyObj()));

I've checked out the MSFT implementation and I don't see anything obvious -- any one encountered this and have any ideas?

EDIT: Ok, to be a bit more clear/specific. This is clearly a Windows memory usage issue and I am obviously missing something. I have now tried the following:

1. Create a std::list of 100000 MyObj
2. Create a std::list of 100000 MyObj*
3. Create a std::list of 100000 int*
4. Create a std::list of 50000 int*

In each case, each add'l member of the list, whether a pointer or otherwise, is bloating my application by 4400(!) bytes. This is in a release, 64-bit build, without any debugging information included (Linker > Debugging > Generate Debug Info set to No).

I obviously need to research this a bit more to narrow it down to a smaller test case.

For those interested, I am determining application size using Process Explorer.

Turns out it was entirely heap fragmentation. How ridiculous. 4400 bytes per 8 byte object! I switched to pre-allocating and the problem went away entirely -- I am used to some inefficiency in relying on per-object allocation, but this was just ridiculous.

MyObj implementation below:

class   MyObj
{
public:
    MyObj() { memset(this,0,sizeof(MyObj)); }

    double              m_1;
    double              m_2;
    double              m_3;
    double              m_4;
    double              m_5;
    double              m_6;
    double              m_7;
    double              m_8;
    double              m_9;
    double              m_10;
    double              m_11;           
    double              m_12;           
    double              m_13;
    double              m_14;
    double              m_15;
    double              m_16;
    double              m_17;
    double              m_18;
    double              m_19;
    double              m_20;
    double              m_21;
    double              m_22;
    double              m_23;
    CUnit*              m_UnitPtr;
    CUnitPos*           m_UnitPosPtr;
};

Answer 1

The added memory is likely from heap inefficiencies - you have to pay extra for each block you allocate due to internal fragmentation and malloc data. You're performing twice the amount of allocations which is going to incur a penalty hit.

For instance, this:

for(int i = 0; i < 100; ++i) {
  new int;
}

will use more memory than this:

new int[100];

Even though the amount allocated is the same.

---

Edit:

I'm getting around 13% more memory used using unique_ptr using GCC on Linux.

Answer 2

std::list<MyObj> contains N copies of your object (+ the information needed for the pointers of the list).

std::unique_ptr<MyObj> contains a pointer to a instance of your object. (It should only contain a MyObj*).

So a std::list<std::unique_ptr<MyObj>> is not directly equivalent to your first list. std::list<MyObj*> should give the same size as the std::unque_ptr list.

After verifying the implementation, the only thing that could be embedded next to the pointer of the object itself, could be the 'deleter', which in the default case is a empty object that calls operator delete.

Do you have a Debug or a Release build?

Answer 3

This isn't an answer, but it doesn't fit in a comment and it might be illustrative.

I cannot reproduce the claim (GCC 4.6.2). Take this code:

#include <memory>
#include <list>

struct Foo { char p[200]; };

int main()
{
  //std::list<Foo> l1(100);

  std::list<std::unique_ptr<Foo>> l2;
  for (unsigned int i = 0; i != 100; ++i) l2.emplace_back(new Foo);
}

Enabling only l1 produces (in Valgrind):

total heap usage: 100 allocs, 100 frees, 20,800 bytes allocated

Enabling only l2 and the loop gives:

total heap usage: 200 allocs, 200 frees, 21,200 bytes allocated

The smart pointers take up exactly 4 × 100 bytes.

In both cases, /usr/bin/time -v gives:

Maximum resident set size (kbytes): 3136

Further more, pmap shows in both cases: total 2996K. To confirm, I changed the object size to 20000 and the number of elements to 10000. Now the numbers are 198404K vs 198484K: Exactly 80000B difference, 8B per unique pointer (presumably there's some 8B alignment going on in the allocator of the list). Under the same changes, the "maximum resident set size"s reported by time -v are now 162768 vs 164304.