1

I have a trivial function that copies a byte block to std::vector:

std::vector<uint8_t> v;

void Write(const uint8_t * buffer, size_t count)
{
    //std::copy(buffer, buffer + count, std::back_inserter(v));

    v.insert(v.end(), buffer, buffer + count);
}

v.reserve(<buffer size>);
v.resize(0);

Write(<some buffer>, <buffer size>);

if I use std::vector<uint8_t>::insert it works 5 times faster than if I use std::copy.

I tried to compile this code with MSVC 2015 with enabled and disabled optimization and got the same result.

Looks like something is strange with std::copy or std::back_inserter implementation.

  • What if you use v.reserve? – tkausl Aug 20 '18 at 11:45
  • 2
    To be clear: Your question is why one is slower than the other if you disable all optimizations? Because in that case the answer is "that's neither unreasonable nor unexpected"... Step through with your debugger to find out why exactly it happens if you are really curious. – Max Langhof Aug 20 '18 at 11:46
  • 2
    Consider providing minimal reproducible example, so we could reproduce the issue you are facing, instead of trying to implement the test cases on our own. – Algirdas Preidžius Aug 20 '18 at 11:48
  • 1
    I'm not sure if it is relevant but std::vector::push_back (via std::back_inserter) has to at least check if it needs to re-allocate every time, even if you have called reserve first. std::vector::insert only has to check if it needs to re-allocate once. – Chris Drew Aug 20 '18 at 11:52
  • 1
    The effect seems to be even more severe on clang and gcc. – Max Langhof Aug 20 '18 at 13:35
1

With a good implementation of std::vector, v.insert(v.end(), buffer, buffer + count); might be implemented as:

size_t count = last-first;
resize(size() + count);
memcpy(data+offset, first, count);

std::copy(buffer, buffer + count, std::back_inserter(v)) on the other hand will be implemented as:

while ( first != last )
{
   *output++ = *first++;
}

which is equivalent to:

while ( first != last )
{
   v.push_back( *first++ );
}

or (roughly):

while ( first != last )
{
   // push_back should be slightly more efficient than this
   v.resize(v.size() + 1);
   v.back() = *first++;
}

Whilst in theory the compiler could optimise the above into a memcpy its unlikely to, at best you'll probably get the methods inlined so that you don't have a function call overhead, it'll still be writing one byte at a time whereas a memcpy will normally use vector instructions to copy multiple bytes at once.

| improve this answer | |
  • is v.push_back really 5 time slower than memcpy? – Alexey Starinsky Aug 20 '18 at 12:51
  • @AlexeyStarinsky I wouldn't be surprised if it is, there's probably a huge amount of code hidden behind a simple push_back – Alan Birtles Aug 20 '18 at 13:00
  • Please reconsider your explanation in light of this. Note in particular how neither implementation calls any functions (other than memmove and new etc., which are used by both). – Max Langhof Aug 20 '18 at 13:28
  • @MaxLanghof he isn't using clang though, he's using MSVC – Alan Birtles Aug 20 '18 at 13:51
  • Trawling through the godbolt source insert eventually calls std::_Copy_memmove with visual studio – Alan Birtles Aug 20 '18 at 13:59
5

Standard library implementation is written with performance in mind, but performance is achieved only when optimization is ON.

//This reduces the performance dramatically if the optimization is switched off.

Trying to measure a function performance with optimization OFF is as pointless as asking ourselves if the law of gravitation would still be true if there were no mass left in the Universe.

| improve this answer | |
  • cannot see the book you are linking :/ – idclev 463035818 Aug 20 '18 at 12:38
  • I tried to compile this code with MSVC 2015 with enabled and disabled optimization and got the same result. – Alexey Starinsky Aug 20 '18 at 12:46
  • @user463035818 Its just an off-topic joke: It's a book on logic from german philosopher Husserl where he actually asks that question (answered positively) and then conclude that, since there exist similar laws for the human psyche, those laws must be as eternal, invariable and fundamental as the laws of science and physics. – YSC Aug 20 '18 at 13:39
3

The call to v.insert is calling a member function of the container. The member function knows how the container is implemented, so it can do things that a more generic algorithm can't do. In particular, when inserting a range of values designated by random-access iterators into a vector, the implementation knows how many elements are being added, so it can resize the internal storage once and then just copy the elements.

The call to std::copy with an insert-iterator, on the other hand, has to call insert for each element. It can't preallocate, because std::copy works with sequences, not containers; it doesn't know how to adjust the size of the container. So for large insertions into a vector the internal storage gets resized each time the vector is full and a new insertion is needed. The overhead of that reallocation is amortized constant time, but the constant is much larger than the constant when only one resizing is done.

With the call to reserve (which I overlooked, thanks, @ChrisDrew), the overhead of reallocating is not as significant. But the implementation of insert knows how many values are being copied, and it knows that those values are contiguous in memory (because the iterator is a pointer), and it knows that the values are trivially copyable, so it will use std::memcpy to blast the bits in all at once. With std::copy, none of that applies; the back inserter has to check whether a reallocation is necessary, and that code can't be optimized out, so you end up with a loop that copies an element at a time, checking for the end of the allocated space for each element. That's much more expensive than a plain std::memcpy.

In general, the more the algorithm knows about the internals of the data structure that it's accessing, the faster it can be. STL algorithms are generic, and the cost of that genericity can be more overhead than a that of a container-specific algorithm.

| improve this answer | |
  • reserve is not called, because the vector initial capacity is large enough. – Alexey Starinsky Aug 20 '18 at 12:52
  • I sort of disagree with the "copy can't know the things insert can". In latest clang, neither version relies on memcpy 1 2 for the actual copying (both use several memmove), but one of them is more aggressive on the unrolling (or so I think). Note the structural similarity of the assembly. This is all templated code, so with proper inlining and optimization, both functions should theoretically be able to achieve the same performance regardless of being a member or free/generic function. – Max Langhof Aug 20 '18 at 13:27
  • 1
    @MaxLanghof -- I look forward to seeing your explanation for the reported performance discrepancy. – Pete Becker Aug 20 '18 at 15:49

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