I want to use vector<char> as a buffer. The interface is perfect for my needs, but there's a performance penalty when resizing it beyond its current size, since the memory is initialized. I don't need the initialization, since the data will be overwritten in any case by some third-party C functions. Is there a way or a specific allocator to avoid the initialization step? Note that I do want to use resize(), not other tricks like reserve() and capacity(), because I need size() to always represent the significative size of my "buffer" at any moment, while capacity() might be greater than its size after a resize(), so, again, I cannot rely on capacity() as a significative information for my application. Furthemore, the (new) size of the vector is never known in advance, so I cannot use std::array. If vector cannot be configured that way, I'd like to know what kind of container or allocator I could use instead of vector<char, std::alloc>. The only requirement is that the alternative to vector must at most be based on STL or Boost. I have access to C++11.

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    reserve/capacity? Or std::array , or an appropriate constructor..Not very clear what you want to do/avoid.. – Karthik T Mar 5 '13 at 9:22
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    which performance penalty? How did you measure it? – UmNyobe Mar 5 '13 at 9:22
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    @UmNyobe no need to measure. It's clear that resizing from 0 to 10^9 as a worst case costs in terms of performance, even if the allocator is smart enough to use memset (which cannot be guaranteed). – Martin Mar 5 '13 at 9:28
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    @us2012 there is not guarantee that capacity() will be the same as size. – Martin Mar 5 '13 at 9:35
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    @us2012: Using a vector's reserved storage is not a good idea. If the size of the vector's internal storage changes, the value of the 'fake' elements won't get copied, vector implementations with checked iterators/operator[] will assert if you use that funcationality to access the 'fake' elements etc. – JoeG Mar 5 '13 at 9:39

There's nothing in the standard library that meets your requirements, and nothing I know of in boost either.

There are three reasonable options I can think of:

  • Stick with std::vector for now, leave a comment in the code and come back to it if this ever causes a bottleneck in your application.
  • Use a custom allocator with empty construct/destroy methods - and hope your optimiser will be smart enough to remove any calls to them.
  • Create a wrapper around a a dynamically allocated array, implementing only the minimal functionality that you require.
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    +1 The second item is a big hope, but it will probably see the light if the optimizer is reasonably intelligent. The third obviously grants the most control, but at the price of more code to maintain (but would it really be worse than a custom allocator derivation?, probably not.) – WhozCraig Mar 5 '13 at 9:57
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    @WhozCraig: I would throw away any compiler that would failed to remove calls to empty functions, this is a really straight-forward optimization. I think the custom allocator is the cleanest and simplest way to go. – Luc Touraille Mar 5 '13 at 10:01
  • I think I can derive the standard allocator privately and export all the member functions from that allocator (via using) except construct() and destroy(), which I will redefine as empty. The g++/clang++ compilers should be smart enough to optimize the calls out. – Martin Mar 5 '13 at 10:06
  • @Martin it will be interesting to see what comes of it. Don't forget to provide a rebind. If you've never written a std::allocator compliant allocator before, you'll eventually get to that. – WhozCraig Mar 5 '13 at 10:09
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    @MaximYegorushkin, for trivial types it uses _Construct if std::allocator is used, because the result is "as if" each element had been initialized by std::allocator<T>::construct, but for a custom allocator that optimization is not used. See <bits/stl_uninitialized.h> and the __uninitialized_fill_n_a function which is overloaded on the allocator type and either dispatches to __uninitialized_fill_n or allocator_traits<A>::construct – Jonathan Wakely Mar 5 '13 at 14:15

It is a known issue that initialization can not be turned off even explicitly for std::vector.

People normally implement their own pod_vector<> that does not do any initialization of the elements.

Another way is to create a type which is layout-compatible with char, whose constructor does nothing:

struct NoInitChar
    char value;
    NoInitChar() noexcept {
        // do nothing
        static_assert(sizeof *this == sizeof value, "invalid size");
        static_assert(__alignof *this == __alignof value, "invalid alignment");

int main() {
    std::vector<NoInitChar> v;
    v.resize(10); // calls NoInitChar() which does not initialize

    // Look ma, no reinterpret_cast<>!
    char* beg = &v.front().value;
    char* end = beg + v.size();
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    @Martin the standard requires that a) the alignment of an aggregate is a multiple of the alignment of one of its members with the largest alignment requirement, b) the size of a structure is a multiple of its alignment. In other words, the standard guarantees that NoInitChar has the same size and alignment as char. Those static asserts are primarily compilable documentation. – Maxim Egorushkin Mar 5 '13 at 10:30
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    @MaximYegorushkin Really? Sounds rather that it just guarantees that its size and alignment are mutliples of the char size and alignment (whatever a compiler could gain from adding unneccessary padding, but well, the standard at least allows it). So those asserts are not true by standard, even if probably true on any reasonable platform. But interesting answer +1. – Chris says Reinstate Monica Mar 5 '13 at 15:27
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    @MaximYegorushkin Yes, "neccessary" or "allowed"? That's the question (however theoretical that may be). – Chris says Reinstate Monica Mar 5 '13 at 16:39
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    @user2328447 NoInitChar constructor must be inline, otherwise you get poor performance, as you observed. – Maxim Egorushkin Dec 28 '17 at 12:18
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    @KeithM en.cppreference.com/w/cpp/language/inline: A function defined entirely inside a class/struct/union definition, whether it's a member function or a non-member friend function, is implicitly an inline function.. People should benchmark optimised versions – Maxim Egorushkin Mar 11 '19 at 17:22

Encapsulate it.

Initialise it to the maximum size (not reserve).

Keep a reference to the iterator representing the end of the real size, as you put it.

Use begin and real end, instead of end, for your algorithms.


As an alternative solution that works with vectors of different pod types:

template<typename V>
void resize(V& v, size_t newSize)
    struct vt { typename V::value_type v; vt() {}};
    static_assert(sizeof(vt[10]) == sizeof(typename V::value_type[10]), "alignment error");
    typedef std::vector<vt, typename std::allocator_traits<typename V::allocator_type>::template rebind_alloc<vt>> V2;

And then you can:

std::vector<char> v;
resize(v, 1000); // instead of v.resize(1000);

This is most likely UB, even though it works properly for me for cases where I care more about performance. Difference in generated assembly as produced by clang:

        push    rbx
        mov     edi, 1000
        call    operator new(unsigned long)
        mov     rbx, rax
        mov     edx, 1000
        mov     rdi, rax
        xor     esi, esi
        call    memset
        mov     rdi, rbx
        pop     rbx
        jmp     operator delete(void*)

        push    rax
        mov     edi, 1000
        call    operator new(unsigned long)
        mov     rdi, rax
        pop     rax
        jmp     operator delete(void*)

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