ladybird/AK/QuickSelect.h
Staubfinger 607441de56 AK: Implement the quick select algorithm as AK::quickselect_inplace
This adds the quick select algorithm that finds
the kth smallest element for any collection.
Whilst doing so it also partially sorts the collection.
I have also included the option to use different pivoting functions
including median of medians which makes the quick select have
a truely linear time complexity at the costs of enormous overhead,
so this that only really useful for really large datasets.
The same was chosen to reflect the fact that it modifies
the collection in place during the selection process.
2023-02-03 19:04:15 +01:00

169 lines
7.1 KiB
C++

/*
* Copyright (c) 2023, the SerenityOS developers.
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#pragma once
#include <AK/Math.h>
#include <AK/Random.h>
#include <AK/StdLibExtras.h>
namespace AK {
// FIXME: Stole and adapted these two functions from `Userland/Demos/Tubes/Tubes.cpp` we really need something like this in `AK/Random.h`
static inline double random_double()
{
return get_random<u32>() / static_cast<double>(NumericLimits<u32>::max());
}
static inline size_t random_int(size_t min, size_t max)
{
return min + round_to<size_t>(random_double() * (max - min));
}
// Implementations of common pivot functions
namespace PivotFunctions {
// Just use the first element of the range as the pivot
// Mainly used to debug the quick select algorithm
// Good with random data since it has nearly no overhead
// Attention: Turns the algorithm quadratic if used with already (partially) sorted data
template<typename Collection, typename LessThan>
size_t first_element([[maybe_unused]] Collection& collection, size_t left, [[maybe_unused]] size_t right, [[maybe_unused]] LessThan less_than)
{
return left;
}
// Just use the middle element of the range as the pivot
// This is what is used in AK::single_pivot_quick_sort in quicksort.h
// Works fairly well with random Data
// Works incredibly well with sorted data since the pivot is always a perfect split
template<typename Collection, typename LessThan>
size_t middle_element([[maybe_unused]] Collection& collection, size_t left, size_t right, [[maybe_unused]] LessThan less_than)
{
return (left + right) / 2;
}
// Pick a random Pivot
// This is the "Traditional" implementation of both quicksort and quick select
// Performs fairly well both with random and sorted data
template<typename Collection, typename LessThan>
size_t random_element([[maybe_unused]] Collection& collection, size_t left, size_t right, [[maybe_unused]] LessThan less_than)
{
return random_int(left, right);
}
// Implementation detail of median_of_medians
// Whilst this looks quadratic in runtime, it always gets called with 5 or fewer elements so can be considered constant runtime
template<typename Collection, typename LessThan>
size_t partition5(Collection& collection, size_t left, size_t right, LessThan less_than)
{
VERIFY((right - left) <= 5);
for (size_t i = left + 1; i <= right; i++) {
for (size_t j = i; j > left && less_than(collection.at(j), collection.at(j - 1)); j--) {
swap(collection.at(j), collection.at(j - 1));
}
}
return (left + right) / 2;
}
// https://en.wikipedia.org/wiki/Median_of_medians
// Use the median of medians algorithm to pick a really good pivot
// This makes quick select run in linear time but comes with a lot of overhead that only pays off with very large inputs
template<typename Collection, typename LessThan>
size_t median_of_medians(Collection& collection, size_t left, size_t right, LessThan less_than)
{
if ((right - left) < 5)
return partition5(collection, left, right, less_than);
for (size_t i = left; i <= right; i += 5) {
size_t sub_right = i + 4;
if (sub_right > right)
sub_right = right;
size_t median5 = partition5(collection, i, sub_right, less_than);
swap(collection.at(median5), collection.at(left + (i - left) / 5));
}
size_t mid = (right - left) / 10 + left + 1;
// We're using mutual recursion here, using quickselect_inplace to find the pivot for quickselect_inplace.
// Whilst this achieves True linear Runtime, it is a lot of overhead, so use only this variant with very large inputs
return quickselect_inplace(
collection, left, left + ((right - left) / 5), mid, [](auto collection, size_t left, size_t right, auto less_than) { return AK::PivotFunctions::median_of_medians(collection, left, right, less_than); }, less_than);
}
}
// This is the Lomuto Partition scheme which is simpler but less efficient than Hoare's partitioning scheme that is traditionally used with quicksort
// https://en.wikipedia.org/wiki/Quicksort#Lomuto_partition_scheme
template<typename Collection, typename PivotFn, typename LessThan>
static size_t partition(Collection& collection, size_t left, size_t right, PivotFn pivot_fn, LessThan less_than)
{
auto pivot_index = pivot_fn(collection, left, right, less_than);
auto pivot_value = collection.at(pivot_index);
swap(collection.at(pivot_index), collection.at(right));
auto store_index = left;
for (size_t i = left; i < right; i++) {
if (less_than(collection.at(i), pivot_value)) {
swap(collection.at(store_index), collection.at(i));
store_index++;
}
}
swap(collection.at(right), collection.at(store_index));
return store_index;
}
template<typename Collection, typename PivotFn, typename LessThan>
size_t quickselect_inplace(Collection& collection, size_t left, size_t right, size_t k, PivotFn pivot_fn, LessThan less_than)
{
// Bail if left is somehow bigger than right and return default constructed result
// FIXME: This can also occur when the collection is empty maybe propagate this error somehow?
// returning 0 would be a really bad thing since this returns and index and that might lead to memory errors
// returning in ErrorOr<size_t> here might be a good option but this is a very specific error that in nearly all circumstances should be considered a bug on the callers site
VERIFY(left <= right);
// If there's only one element, return that element
if (left == right)
return left;
auto pivot_index = partition(collection, left, right, pivot_fn, less_than);
// we found the thing we were searching for
if (k == pivot_index)
return k;
// Recurse on the left side
if (k < pivot_index)
return quickselect_inplace(collection, left, pivot_index - 1, k, pivot_fn, less_than);
// recurse on the right side
return quickselect_inplace(collection, pivot_index + 1, right, k, pivot_fn, less_than);
}
//
template<typename Collection, typename PivotFn, typename LessThan>
size_t quickselect_inplace(Collection& collection, size_t k, PivotFn pivot_fn, LessThan less_than)
{
return quickselect_inplace(collection, 0, collection.size() - 1, k, pivot_fn, less_than);
}
template<typename Collection, typename PivotFn>
size_t quickselect_inplace(Collection& collection, size_t k, PivotFn pivot_fn)
{
return quickselect_inplace(collection, 0, collection.size() - 1, k, pivot_fn, [](auto& a, auto& b) { return a < b; });
}
// All of these quick select implementation versions return the `index` of the resulting element, after the algorithm has run, not the element itself!
// As Part of the Algorithm, they all modify the collection in place, partially sorting it in the process.
template<typename Collection>
size_t quickselect_inplace(Collection& collection, size_t k)
{
// By default, lets use middle_element to match `quicksort`
return quickselect_inplace(
collection, 0, collection.size() - 1, k, [](auto collection, size_t left, size_t right, auto less_than) { return PivotFunctions::middle_element(collection, left, right, less_than); }, [](auto& a, auto& b) { return a < b; });
}
}