C++ template library for high performance SIMD based sorting routines for
built-in integers and floats (16-bit, 32-bit and 64-bit data types) and custom
defined C++ objects. The sorting routines are accelerated using AVX-512/AVX2
when available. The library auto picks the best version depending on the
processor it is run on. If you are looking for the AVX-512 or AVX2 specific
implementations, please see
README file
under src/
directory. The following routines are currently supported:
template <typename T, typename Func>
void x86simdsort::object_qsort(T *arr, uint32_t arrsize, Func key_func)
T
is any user defined struct or class and arr
is a pointer to the first
element in the array of objects of type T
. Func
is a lambda function that
computes the key
value for each object which is the metric used to sort the
objects. Func
needs to have the following signature:
[] (T obj) -> key_t { key_t key; /* compute key for obj */ return key; }
Note that the return type of the key key_t
needs to be one of the following
: [float, uint32_t, int32_t, double, uint64_t, int64_t]
. object_qsort
has a
space complexity of O(N)
. Specifically, it requires arrsize * sizeof(key_t)
bytes to store a vector with all the keys and an additional
arrsize * sizeof(uint32_t)
bytes to store the indexes of the object array.
For performance reasons, we support object_qsort
only when the array size is
less than or equal to UINT32_MAX
. An example usage of object_qsort
is
provided in the examples
section. Refer to section to get a sense of
how fast this is relative to std::sort
.
void x86simdsort::qsort(T* arr, size_t size, bool hasnan, bool descending);
void x86simdsort::qselect(T* arr, size_t k, size_t size, bool hasnan, bool descending);
void x86simdsort::partial_qsort(T* arr, size_t k, size_t size, bool hasnan, bool descending);
Supported datatypes: T
[_Float16, uint16_t, int16_t, float, uint32_t, int32_t, double, uint64_t, int64_t]
void x86simdsort::keyvalue_qsort(T1* key, T2* val, size_t size, bool hasnan, bool descending);
void x86simdsort::keyvalue_select(T1* key, T2* val, size_t k, size_t size, bool hasnan, bool descending);
void x86simdsort::keyvalue_partial_sort(T1* key, T2* val, size_t k, size_t size, bool hasnan, bool descending);
Supported datatypes: T1
, T2
[float, uint32_t, int32_t, double, uint64_t, int64_t]
Note that keyvalue sort is not yet supported for 16-bit
data types.
std::vector<size_t> arg = x86simdsort::argsort(T* arr, size_t size, bool hasnan, bool descending);
std::vector<size_t> arg = x86simdsort::argselect(T* arr, size_t k, size_t size, bool hasnan);
Supported datatypes: T
[_Float16, uint16_t, int16_t, float, uint32_t, int32_t, double, uint64_t, int64_t]
meson is the used build system. Command to build and install the library:
meson setup --buildtype release builddir && cd builddir
meson compile
sudo meson install
Once installed, you can use pkg-config --cflags --libs x86simdsortcpp
to
populate the right cflags and ldflags to compile and link your C++ program.
This repository also contains a test suite and benchmarking suite which are
written using googletest and google
benchmark frameworks respectively. You
can configure meson to build them both by using -Dbuild_tests=true
and
-Dbuild_benchmarks=true
.
There is a risk when compile with avx512 by g++ v9 and v10,
as some MMX Technology
instructions is used by g++ v9/v10
without clearing fpu state.
Check issue 154
for more details.
Adding g++
option -mno-mmx
, which disables MMX Technology
instructions, is a possible workaround.
#include "x86simdsort.h"
int main() {
std::vector<float> arr{1000};
x86simdsort::qsort(arr.data(), 1000, true);
return 0;
}
#include "x86simdsort.h"
#include <cmath>
struct Point {
double x, y, z;
};
int main() {
std::vector<Point> arr{1000};
// Sort an array of Points by its x value:
x86simdsort::object_qsort(arr.data(), 1000, [](Point p) { return p.x; });
// Sort an array of Points by its distance from origin:
x86simdsort::object_qsort(arr.data(), 1000, [](Point p) {
return sqrt(p.x*p.x+p.y*p.y+p.z*p.z);
});
return 0;
}
x86simdsort::qsort
is equivalent toqsort
in C orstd::sort
in C++.x86simdsort::qselect
is equivalent tostd::nth_element
in C++ ornp.partition
in NumPy.x86simdsort::partial_qsort
is equivalent tostd::partial_sort
in C++.x86simdsort::argsort
is equivalent tonp.argsort
in NumPy.x86simdsort::argselect
is equivalent tonp.argpartition
in NumPy.
Supported datatypes: uint16_t, int16_t, _Float16, uint32_t, int32_t, float, uint64_t, int64_t, double
. Note that _Float16
will require building this
library with g++ >= 12.x. All the functions have an optional argument bool hasnan
set to false
by default (these are relevant to floating point data
types only). If your array has NAN's, the the behaviour of the sorting routine
is undefined. If hasnan
is set to true, NAN's are always sorted to the end of
the array. In addition to that, qsort will replace all your NAN's with
std::numeric_limits<T>::quiet_NaN
. The original bit-exact NaNs in
the input are not preserved. Also note that the arg methods (argsort and
argselect) will not use the SIMD based algorithms if they detect NAN's in the
array. You can read details of all the implementations
here.
Performance of object_qsort
can vary significantly depending on the defintion
of the custom class and we highly recommend benchmarking before using it. For
the sake of illustration, we provide a few examples in
./benchmarks/bench-objsort.hpp which measures
performance of object_qsort
relative to std::sort
when sorting an array of
3D points represented by the class: struct Point {double x, y, z;}
and
struct Point {float x, y, x;}
. We sort these points based on several
different metrics:
- sort by coordinate
x
- sort by manhanttan distance (relative to origin):
abs(x) + abx(y) + abs(z)
- sort by Euclidean distance (relative to origin):
sqrt(x*x + y*y + z*z)
- sort by Chebyshev distance (relative to origin):
max(abs(x), abs(y), abs(z))
The performance data (shown in the plot below) can be collected by building the
benchmarks suite and running ./builddir/benchexe --benchmark_filter==*obj*
.
The data plot shown below was collected on a processor with AVX-512. For the
simplest of cases where we want to sort an array of struct by one of its
members, object_qsort
can be up-to 5x faster for 32-bit data type and about
4x for 64-bit data type. It tends to do even better when the metric to sort by
gets more complicated. Sorting by Euclidean distance can be up-to 10x faster.