PPQSort
PPQSort (Parallel Pattern QuickSort)
Parallel Pattern Quicksort (PPQSort) is a efficient implementation of parallel quicksort algorithm, written by using only the C++20 features without using third party libraries (such as Intel TBB). PPQSort draws inspiration from pdqsort, BlockQuicksort and cpp11sort and adds some further optimizations.
- Focus on ease of use: Using only C++20 features, header only implementation, user-friendly API.
- Comprehensive test suite: Ensures correctness and robustness through extensive testing.
- Benchmarks shows great performance: Achieves impressive sorting times on various machines.
Integration
PPQSort is header only implementation. All the files needed are in include directory.
Add to existing CMake project using CPM.cmake:
include(cmake/CPM.cmake) CPMAddPackage( NAME PPQSort GITHUB_REPOSITORY GabTux/PPQSort VERSION 1.0.3 # change this to latest commit or release tag ) target_link_libraries(YOUR_TARGET PPQSort::PPQSort)
Alternatively use FetchContent or just checkout the repository and add the include directory to the linker flags.
Usage
PPQSort has similiar API as std::sort, you can use ppqsort:: policies to specify how the sort should run.
// run parallel ppqsort::sort(ppqsort::execution::par, input.begin(), input.end()); // Specify number of threads ppqsort::sort(ppqsort::execution::par, input.begin(), input.end(), 16); // provide custom comparator ppqsort::sort(ppqsort::execution::par, input.begin(), input.end(), cmp); // force branchless variant ppqsort::sort(ppqsort::execution::par_force_branchless, input_str.begin(), input_str.end(), cmp);
PPQSort will by default use C++ threads, but if you prefer, you can link it with OpenMP and it will use OpenMP as a parallel backend. However you can still enforce C++ threads parallel backend even if linked with OpenMP:
#define FORCE_CPP #include <ppqsort.h> // ... rest of the code ...
Benchmark
We compared PPQSort with various parallel sorts. Benchmarks shows, that the PPQSort is one of the fastest parallel sorting algorithms across various input data and different machines.
| Name | Algorithm | Memory usage | External dependencies | Highlight |
|---|---|---|---|---|
| PPQSort | Quicksort | in-place | None | parallel pattern quicksort algorithm |
| GCC BQS | Quicksort | in-place | OpenMP | allocating threads proportionally to subtask sizes |
| cpp11sort | Quicksort | in-place | None | Header-only, C++11 compliant |
| oneTBB parallel_ | quicksort | out-place | oneTBB | Splits input to small tasks |
| poolSTL sort | Quicksort | in-place | None | Header-only, C++17 compliant |
| Boost block_ | merging algorithm | out-place | Boost | Upper bounded small memory usage |
| AQsort | Quicksort | in-place | OpenMP | Allows the sorting of multiple datasets at once |
| MPQsort | Quicksort | in-place | OpenMP | Multiway Parallel Quicksort |
| IPS4o | Samplesort | in-place | oneTBB | Divides data into buckets and sort them recursively |
Running on ARM cluster
- Fujitsu A64FX CPU
- NUMA architecture, 48 cores (4CPUs x 12cores)
Results for INT, input size was 2e9 (2 billions):
| Algorithm | Random | Ascending | Descending | Rotated | OrganPipe | Heap | Total | Rank |
|---|---|---|---|---|---|---|---|---|
| PPQSort C++ | 5.84s | 1.84s | 4.55s | 1.38s | 2.96s | 5.58s | 22.15s | 1 |
| GCC BQS | 13.72s | 4.18s | 19.11s | 49.89s | 8.24s | 13.78s | 108.92s | 6 |
| oneTBB | 43.66s | 0.09s | 8.62s | 13.84s | 8.12s | 43.9s | 118.23s | 9 |
| poolSTL | 34.63s | 5.61s | 7.23s | 14.78s | 7.81s | 46.88s | 116.94s | 7 |
| MPQsort | 13.35s | 5.74s | 5.77s | 4.67s | 7.71s | 12.87s | 50.11s | 5 |
| cpp11sort | 9.58s | 2.47s | 2.66s | 5.47s | 3.42s | 9.9s | 33.5s | 3 |
| AQsort | 24.72s | 3.66s | 23.14s | 21.83s | 22.6s | 25.31s | 121.26s | 8 |
| Boost | 8.2s | 3.0s | 4.26s | 13.96s | 6.97s | 7.92s | 44.31s | 4 |
| IPS$^4$o | 4.8s | 0.19s | 5.97s | 5.21s | 5.59s | 4.91s | 26.67s | 2 |
Summary
Extended benchmarks (detailed in forthcoming paper) shows that IPS4o (https:/
- Competitive Speed: Delivers performance comparable to IPS4o on most machines.
- Hardware Agnostic: Maintains strong performance across various hardware, potentially surpassing IPS4o on specific systems, especially ARM platforms.
- Dependency-Free: No external libraries are required, simplifying integration. For applications demanding a fast, dependency-free parallel sorting solution, PPQSort is an excellent choice.
Running Tests and Benchmarks
Bash script for running or building specific components:
$ scripts/build.sh all ... $ scripts/run.sh standalone ...
Note that the benchmark's CMake file will by default download sparse matrices (around 26GB).
Implementation
A detailed research paper exploring PPQSort's design, implementation, and performance evaluation will be available soon.