I'm investigating ways to speed up a large section of C++ code, which has automatic derivatives for computing jacobians. This involves doing some amount of work in the actual residuals, but the majority of the work (based on profiled execution time) is in calculating the jacobians.

This surprised me, since most of the jacobians are propagated forward from 0s and 1s, so the amount of work should be 2-4x the function, not 10-12x. In order to model what a large amount of the jacobian work is like, I made a super minimal example with just a dot product (instead of sin, cos, sqrt and more that would be in a real situation) that the compiler should be able to optimize to a single return value:

#include <Eigen/Core>
#include <Eigen/Geometry>

using Array12d = Eigen::Matrix<double,12,1>;

double testReturnFirstDot(const Array12d& b)
    Array12d a;
    a.array() = 0.;
    a(0) = 1.;
    return a.dot(b);

Which should be the same as

double testReturnFirst(const Array12d& b)
    return b(0);

I was disappointed to find that, without fast-math enabled, neither GCC 8.2, Clang 6 or MSVC 19 were able to make any optimizations at all over the naive dot-product with a matrix full of 0s. Even with fast-math (https://godbolt.org/z/GvPXFy) the optimizations are very poor in GCC and Clang (still involve multiplications and additions), and MSVC doesn't do any optimizations at all.

I don't have a background in compilers, but is there a reason for this? I'm fairly sure that in a large proportion of scientific computations being able to do better constant propagation/folding would make more optimizations apparent, even if the constant-fold itself didn't result in a speedup.

While I'm interested in explanations for why this isn't done on the compiler side, I'm also interested for what I can do on a practical side to make my own code faster when facing these kinds of patterns.

  • 20
    Floating point numbers are not real numbers, they have rigorous correctness requirements which are violated by obvious optimisations. E.g. (1.0 / 3.0) * 3.0 != (1.0 * 3.0)/3.0 because rounding behaviour is fully specified, so you cannot simply cancel the 3. – Ben Aug 31 '18 at 10:37
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    The answer depends on the implementation of dot. Probably, it is not just a for loop with accumulation, but involves rescaling. No wonder that compilers can't optimize it. – Evg Aug 31 '18 at 10:37
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    The point of -ffast-math is to say "it's not necessary to comply with the standard". MSVC equivalent of fast-math is /fp:fast you may find that it does some optimisation if you specify that. – Ben Aug 31 '18 at 10:44
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    Once you added -ffast-math the remaining "problem" is explicit vectorization, see my answer. – ggael Aug 31 '18 at 11:41
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    You can see the options in the godbolt. -O3 for gcc/clang, /Ox for MSVC. – jkflying Aug 31 '18 at 13:19

This is because Eigen explicitly vectorize your code as 3 vmulpd, 2 vaddpd and 1 horizontal reduction within the remaining 4 component registers (this assumes AVX, with SSE only you'll get 6 mulpd and 5 addpd). With -ffast-math GCC and clang are allowed to remove the last 2 vmulpd and vaddpd (and this is what they do) but they cannot really replace the remaining vmulpd and horizontal reduction that have been explicitly generated by Eigen.

So what if you disable Eigen's explicit vectorization by defining EIGEN_DONT_VECTORIZE? Then you get what you expected (https://godbolt.org/z/UQsoeH) but other pieces of code might become much slower.

If you want to locally disable explicit vectorization and are not afraid of messing with Eigen's internal, you can introduce a DontVectorize option to Matrix and disable vectorization by specializing traits<> for this Matrix type:

static const int DontVectorize = 0x80000000;

namespace Eigen {
namespace internal {

template<typename _Scalar, int _Rows, int _Cols, int _MaxRows, int _MaxCols>
struct traits<Matrix<_Scalar, _Rows, _Cols, DontVectorize, _MaxRows, _MaxCols> >
: traits<Matrix<_Scalar, _Rows, _Cols> >
  typedef traits<Matrix<_Scalar, _Rows, _Cols> > Base;
  enum {
    EvaluatorFlags = Base::EvaluatorFlags & ~PacketAccessBit


using ArrayS12d = Eigen::Matrix<double,12,1,DontVectorize>;

Full example there: https://godbolt.org/z/bOEyzv

| improve this answer | |
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    Why can't the compiler optimize the remaining vector instructions? Is it a QoI issue or is there a technical reason? – Rakete1111 Aug 31 '18 at 12:23
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    @Rakete1111 Presumably because nobody sat down to write detailed enough rules/model by which the compiler would track constant propagation through vector instructions. Some rules (such as multiplying by or adding 0.0) have evidently been included already, but it's probably difficult to make them as encompassing as the scalar ones. – Max Langhof Aug 31 '18 at 13:02
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    That would be technically possible by "un-vectorizing" the code, but this would go against what the user explicitly asked, so this is debatable whether its reasonable or not. – ggael Aug 31 '18 at 13:08
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    You are asking an awful lot of the compiler...for it to do what you want would require it to really develop some machine insight into the particulars of the problem. It's not impossible, but not the kind of think compiler writers focus on. To us humans, it is obvious that a dot product in N dimensions where all but the first element of one vector is zeros is a trivial multiplication, but that is not the compiler's focus. Further, as noted above, to maintain consistency floating point must do what it does. Python, for one, uses many 30 year-old Fortran libraries for this reason. – eSurfsnake Sep 1 '18 at 5:39
  • Can you give any insights into why is MSVC not able to optimize this code ? perhaps theres a workaround ? – darune Oct 1 '18 at 13:34

I was disappointed to find that, without fast-math enabled, neither GCC 8.2, Clang 6 or MSVC 19 were able to make any optimizations at all over the naive dot-product with a matrix full of 0s.

They have no other choice unfortunately. Since IEEE floats have signed zeros, adding 0.0 is not an identity operation:

-0.0 + 0.0 = 0.0 // Not -0.0!

Similarly, multiplying by zero does not always yield zero:

0.0 * Infinity = NaN // Not 0.0!

So the compilers simply cannot perform these constant folds in the dot product while retaining IEEE float compliance - for all they know, your input might contain signed zeros and/or infinities.

You will have to use -ffast-math to get these folds, but that may have undesired consequences. You can get more fine-grained control with specific flags (from http://gcc.gnu.org/wiki/FloatingPointMath). According to the above explanation, adding the following two flags should allow the constant folding:
-ffinite-math-only, -fno-signed-zeros

Indeed, you get the same assembly as with -ffast-math this way: https://godbolt.org/z/vGULLA. You only give up the signed zeros (probably irrelevant), NaNs and the infinities. Presumably, if you were to still produce them in your code, you would get undefined behavior, so weigh your options.

As for why your example is not optimized better even with -ffast-math: That is on Eigen. Presumably they have vectorization on their matrix operations, which are much harder for compilers to see through. A simple loop is properly optimized with these options: https://godbolt.org/z/OppEhY

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    Only clang optimizes a for loop, gcc doesn't do it. – Evg Aug 31 '18 at 11:51

One way to force a compiler to optimize multiplications by 0's and 1`s is to manually unroll the loop. For simplicity let's use

#include <array>
#include <cstddef>
constexpr std::size_t n = 12;
using Array = std::array<double, n>;

Then we can implement a simple dot function using fold expressions (or recursion if they are not available):

template<std::size_t... is>
double dot(const Array& x, const Array& y, std::index_sequence<is...>)
    return ((x[is] * y[is]) + ...);

double dot(const Array& x, const Array& y)
    return dot(x, y, std::make_index_sequence<n>{});

Now let's take a look at your function

double test(const Array& b)
    const Array a{1};    // = {1, 0, ...}
    return dot(a, b);

With -ffast-math gcc 8.2 produces:

test(std::array<double, 12ul> const&):
  movsd xmm0, QWORD PTR [rdi]

clang 6.0.0 goes along the same lines:

test(std::array<double, 12ul> const&): # @test(std::array<double, 12ul> const&)
  movsd xmm0, qword ptr [rdi] # xmm0 = mem[0],zero

For example, for

double test(const Array& b)
    const Array a{1, 1};    // = {1, 1, 0...}
    return dot(a, b);

we get

test(std::array<double, 12ul> const&):
  movsd xmm0, QWORD PTR [rdi]
  addsd xmm0, QWORD PTR [rdi+8]

Addition. Clang unrolls a for (std::size_t i = 0; i < n; ++i) ... loop without all these fold expressions tricks, gcc doesn't and needs some help.

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