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I'm making a C++ wrapper for a piece of C code that returns a large array, and so I've tried to return the data in a vector<unsigned char>.

Now the problem is, the data is on the order of megabytes, and vector unnecessarily initializes its storage, which essentially turns out to cut down my speed by half.

How do I prevent this?

Or, if it's not possible -- is there some other STL container that would avoid such needless work? Or must I end up making my own container?



I'm passing the vector as my output buffer. I'm not copying the data from elsewhere.
It's something like:

vector<unsigned char> buf(size);   // Why initialize??
GetMyDataFromC(&buf[0], buf.size());
share|improve this question
@chris: I can't -- I'm passing &my_vector[0] to the C code as my output buffer! – Mehrdad Jun 22 '12 at 3:07
@templatetypedef: Yeah, me too. :-) I just hope it's not "don't use C++"... – Mehrdad Jun 22 '12 at 3:10
I know you said pre-C++11, but in C++11 a std::unique_ptr<unsigned char[]> would fit the bill here nicely, so maybe boost::scoped_array<unsigned char> could suffice for now? – ildjarn Jun 22 '12 at 3:16
@Mehrdad : No, allocated without value-initialization (i.e. new unsigned char[N] rather than new unsigned char[N]()) -- you do realize new[] doesn't need to initialize anything for scalars, right?. – ildjarn Jun 22 '12 at 3:22
@Mehrdad : Here's an online demo that has exactly the semantics you desire (and again, boost::scoped_array<> for C++03). Here's a link to an answer with the standardese describing default-initialization (no ()) vs. value-initialization (with ()). – ildjarn Jun 22 '12 at 3:28

5 Answers 5

up vote 46 down vote accepted

For default and value initialization of structs with user-provided default constructors which don't explicitly initialize anything, no initialization is performed on unsigned char members:

struct uninitialized_char {
    unsigned char m;
    uninitialized_char() {}

// just to be safe
static_assert(1 == sizeof(uninitialized_char), "");

std::vector<uninitialized_char> v(4 * (1<<20));

GetMyDataFromC(reinterpret_cast<unsigned char*>(&v[0]), v.size());

I think this is even legal under the strict aliasing rules.

When I compared the construction time for v vs. a vector<unsigned char> I got ~8 µs vs ~12 ms. More than 1000x faster. Compiler was clang 3.2 with libc++ and flags: -std=c++11 -Os -fcatch-undefined-behavior -ftrapv -pedantic -Weverything -Wno-c++98-compat -Wno-c++98-compat-pedantic -Wno-missing-prototypes

C++11 has a helper for uninitialized storage, std::aligned_storage. Though it requires a compile time size.

Here's an added example, to compare total usage (times in nanoseconds):

VERSION=1 (vector<unsigned char>):

clang++ -std=c++14 -stdlib=libc++ main.cpp -DVERSION=1 -ftrapv -Weverything -Wno-c++98-compat -Wno-sign-conversion -Wno-sign-compare -Os && ./a.out

initialization+first use: 16,425,554
array initialization: 12,228,039
first use: 4,197,515
second use: 4,404,043

VERSION=2 (vector<uninitialized_char>):

clang++ -std=c++14 -stdlib=libc++ main.cpp -DVERSION=2 -ftrapv -Weverything -Wno-c++98-compat -Wno-sign-conversion -Wno-sign-compare -Os && ./a.out

initialization+first use: 7,523,216
array initialization: 12,782
first use: 7,510,434
second use: 4,155,241

#include <iostream>
#include <chrono>
#include <vector>

struct uninitialized_char {
  unsigned char c;
  uninitialized_char() {}

void foo(unsigned char *c, int size) {
  for (int i = 0; i < size; ++i) {
    c[i] = '\0';

int main() {
  auto start = std::chrono::steady_clock::now();

#if VERSION==1
  using element_type = unsigned char;
#elif VERSION==2
  using element_type = uninitialized_char;

  std::vector<element_type> v(4 * (1<<20));

  auto end = std::chrono::steady_clock::now();

  foo(reinterpret_cast<unsigned char*>(, v.size());

  auto end2 = std::chrono::steady_clock::now();

  foo(reinterpret_cast<unsigned char*>(, v.size());

  auto end3 = std::chrono::steady_clock::now();

  std::cout << "initialization+first use: " << std::chrono::nanoseconds(end2-start).count() << '\n';
  std::cout << "array initialization: " << std::chrono::nanoseconds(end-start).count() << '\n';
  std::cout << "first use: " << std::chrono::nanoseconds(end2-end).count() << '\n';
  std::cout << "second use: " << std::chrono::nanoseconds(end3-end2).count() << '\n';

I'm using clang svn-3.6.0 r218006

share|improve this answer
+1 because this is awesome. The only trouble is that it would require some hacking around with reinterpret_cast to get the interface to be standard (and to hope for the best :P), but I think it's otherwise pretty great! :D – Mehrdad Jun 22 '12 at 4:15
@MatthieuM. Should be practically equivalent. Though I wonder if that would be technically undefined behavior (since m works as a single element array and we'll be accessing outside that range) whiled reinterpret cast is technically implementation defined? – bames53 Jun 22 '12 at 6:38
@Mehrdad Undefined behavior means more than that though. UB means the standard places no requirements on any part of the program, before or after the UB. Programs can't avoid being in part implementation defined, but that doesn't release them from being constrained by the standard the way UB does. – bames53 Jun 22 '12 at 17:19
@Mehrdad: I hope you understand the issue correctly, but it's quite misleading how you say it: dereferencing an invalid pointer is undefined, and whether a char is signed or unsigned is implementation-defined; how can you say those two are synonymous? – musiphil Jun 22 '12 at 23:28
"Implementation-defined" refers to a particular construct; "Undefined" refers to the entire program. They are not even close to synonymous, even when you do not specify an implementation. (This is a massively under-appreciated point about UB, even by people who think they know about UB.) – Nemo Jul 23 '12 at 5:15

Sorry, there's no way to avoid it.

C++11 adds a constructor that takes only a size, but even that will value-initialize the data.

Your best bet is to just allocate an array on the heap, stick it in a unique_ptr (where available), and use it from there.

If you're willing to, as you say, "hacking into STL," you could always grab a copy of EASTL to work from. It's a variation of certain STL containers that allows for more restricted memory conditions. A proper implementation of what you're trying to do would be to give its constructor a special value that means "default initialize the members," which for POD types means to do nothing to initialize the memory. This requires using some template metaprogramming to detect if it is a POD type, of course.

share|improve this answer
@chris: Yes, but move from... what? – Mehrdad Jun 22 '12 at 3:15
@chris: I wouldn't know the array's size at compile-time though. Or perhaps I don't understand what you mean? – Mehrdad Jun 22 '12 at 3:16
@chris: You can only move things that are compatible with each other. In general, you can only move one class instance into another instance of the same class, as moving requires poking at the guts of the object. And you certainly can't just move a Type[] into a std::vector. – Nicol Bolas Jun 22 '12 at 3:18
@chris : One could use std::move_iterator<> and call the begin/end constructor, but that would still only do element-wise moving, which wouldn't be useful for unsigned char. – ildjarn Jun 22 '12 at 3:24
@Mehrdad: If your code is simple enough and the array's lifetime is short just dynamically allocate one and move on. Arrays are not inherently unsafe, it's just that it gets hard to properly manage deallocation of dynamically allocated objects in large projects and in the face of possible exceptions. – Ed S. Jun 22 '12 at 4:11

1 It seems that using std::vector is neither necessary not sensible in your situation. You only want some object to manage some raw memory for you. This can be easily achieved by

std::unique_ptr<void, void(*)(void*)> p(std::malloc(n), std::free);

2 If you really want to use std::vector<> you could use the trick described here.

share|improve this answer
The question asked for a pre-C++11 solution, so you probably should use tr1::unique_ptr. – Adrian McCarthy Sep 18 '14 at 23:05

How about using vector.reserve() to only allocate the storage but not initialize it?

share|improve this answer
Presumably because the C function requires a properly sized buffer, and writing to reserved (but not resized) data is undefined behaviour. – Konrad Rudolph Jun 10 '13 at 15:23

The optimal solution is to simply change the allocator to do nothing for a zero-arguments construct. This means that the underlying type is the same, which dodges any kind of nasty reinterpret_casting and potential aliasing violations and can non-intrusively uninitialize any type.

template<typename T> struct no_initialize : std::allocator<T> {
    void construct(T* p) {}
    template<typename... Args> void construct(T* p, Args&&... args) {
        new (p) T(std::forward<Args>(args)...);
share|improve this answer
And then when the de-allocator is invoked...? – Lightness Races in Orbit Sep 18 '14 at 21:41
If you want uninitialized objects, then dealing with the consequences of having them is your problem. It's a dumb idea to apply it to non-trivially-destructible types in the first place. – Puppy Sep 18 '14 at 21:45
Still, I don't see how you can call this "the optimal solution" in a teaching context when you don't even address the obvious flaw. – Lightness Races in Orbit Sep 18 '14 at 22:22
The obvious flaw of destructing a type which essentially has to be trivially constructible and destructible to even want to do this in the first place? – Puppy Sep 18 '14 at 23:00
Yes, exactly. Your answer doesn't even mention that. I find that to be distressingly irresponsible coming from a high-rep user. – Lightness Races in Orbit Sep 18 '14 at 23:07

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