UnityGame/Library/PackageCache/com.unity.collections/Unity.Collections/NativeSort.cs

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2024-10-27 10:53:47 +03:00
using System;
using System.Collections.Generic;
using System.Diagnostics;
using Unity.Burst;
using Unity.Collections.LowLevel.Unsafe;
using Unity.Jobs;
using Unity.Jobs.LowLevel.Unsafe;
using Unity.Mathematics;
namespace Unity.Collections
{
/// <summary>
/// Extension methods for sorting collections.
/// </summary>
[GenerateTestsForBurstCompatibility]
public static class NativeSortExtension
{
/// <summary>
/// A comparer that uses IComparable.CompareTo(). For primitive types, this is an ascending sort.
/// </summary>
/// <typeparam name="T">Source type of elements</typeparam>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int) })]
public struct DefaultComparer<T> : IComparer<T> where T : IComparable<T>
{
/// <summary>
/// Compares two values.
/// </summary>
/// <param name="x">First value to compare.</param>
/// <param name="y">Second value to compare.</param>
/// <returns>A signed integer that denotes the relative values of `x` and `y`:
/// 0 if they're equal, negative if `x &lt; y`, and positive if `x &gt; y`.</returns>
public int Compare(T x, T y) => x.CompareTo(y);
}
/// <summary>
/// Sorts an array in ascending order.
/// </summary>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <param name="array">The array to sort.</param>
/// <param name="length">The number of elements to sort in the array.
/// Indexes greater than or equal to `length` won't be included in the sort.</param>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int) })]
public unsafe static void Sort<T>(T* array, int length)
where T : unmanaged, IComparable<T>
{
IntroSort<T, DefaultComparer<T>>(array, length, new DefaultComparer<T>());
}
/// <summary>
/// Sorts an array using a custom comparison.
/// </summary>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <typeparam name="U">The type of the comparer.</typeparam>
/// <param name="array">The array to sort.</param>
/// <param name="length">The number of elements to sort in the array.
/// Indexes greater than or equal to `length` won't be included in the sort.</param>
/// <param name="comp">The comparison function used to determine the relative order of the elements.</param>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int), typeof(DefaultComparer<int>) })]
public unsafe static void Sort<T, U>(T* array, int length, U comp)
where T : unmanaged
where U : IComparer<T>
{
IntroSort<T, U>(array, length, comp);
}
/// <summary>
/// Returns a job which will sort an array in ascending order.
/// </summary>
/// <remarks>This method does not schedule the job. Scheduling the job is left to you.</remarks>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <param name="array">The array to sort.</param>
/// <param name="length">The number of elements to sort in the array.
/// Indexes greater than or equal to `length` won't be included in the sort.</param>
/// <returns>A job for sorting the array.</returns>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int) }, RequiredUnityDefine = "UNITY_2020_2_OR_NEWER" /* Due to job scheduling on 2020.1 using statics */)]
public unsafe static SortJob<T, DefaultComparer<T>> SortJob<T>(T* array, int length)
where T : unmanaged, IComparable<T>
{
return new SortJob<T, DefaultComparer<T>> { Data = array, Length = length, Comp = new DefaultComparer<T>() };
}
/// <summary>
/// Returns a job which will sort an array using a custom comparison.
/// </summary>
/// <remarks>This method does not schedule the job. Scheduling the job is left to you.</remarks>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <typeparam name="U">The type of the comparer.</typeparam>
/// <param name="array">The array to sort.</param>
/// <param name="length">The number of elements to sort in the array.
/// Indexes greater than or equal to `length` won't be included in the sort.</param>
/// <param name="comp">The comparison function used to determine the relative order of the elements.</param>
/// <returns>A job for sorting the array.</returns>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int), typeof(DefaultComparer<int>) }, RequiredUnityDefine = "UNITY_2020_2_OR_NEWER" /* Due to job scheduling on 2020.1 using statics */)]
public unsafe static SortJob<T, U> SortJob<T, U>(T* array, int length, U comp)
where T : unmanaged
where U : IComparer<T>
{
CheckComparer(array, length, comp);
return new SortJob<T, U>() { Data = array, Length = length, Comp = comp };
}
/// <summary>
/// Finds a value in a sorted array by binary search.
/// </summary>
/// <remarks>If the array is not sorted, the value might not be found, even if it's present in the array.</remarks>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <param name="ptr">The array to search.</param>
/// <param name="value">The value to locate.</param>
/// <param name="length">The number of elements to search. Indexes greater than or equal to `length` won't be searched.</param>
/// <returns>If found, the index of the located value. If not found, the return value is negative.</returns>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int) })]
public unsafe static int BinarySearch<T>(T* ptr, int length, T value)
where T : unmanaged, IComparable<T>
{
return BinarySearch(ptr, length, value, new DefaultComparer<T>());
}
/// <summary>
/// Finds a value in a sorted array by binary search using a custom comparison.
/// </summary>
/// <remarks>If the array is not sorted, the value might not be found, even if it's present in the array.</remarks>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <typeparam name="U">The type of the comparer.</typeparam>
/// <param name="ptr">The array to search.</param>
/// <param name="value">The value to locate.</param>
/// <param name="length">The number of elements to search. Indexes greater than or equal to `length` won't be searched.</param>
/// <param name="comp">The comparison function used to determine the relative order of the elements.</param>
/// <returns>If found, the index of the located value. If not found, the return value is negative.</returns>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int), typeof(DefaultComparer<int>) })]
public unsafe static int BinarySearch<T, U>(T* ptr, int length, T value, U comp)
where T : unmanaged
where U : IComparer<T>
{
CheckComparer(ptr, length, comp);
var offset = 0;
for (var l = length; l != 0; l >>= 1)
{
var idx = offset + (l >> 1);
var curr = ptr[idx];
var r = comp.Compare(value, curr);
if (r == 0)
{
return idx;
}
if (r > 0)
{
offset = idx + 1;
--l;
}
}
return ~offset;
}
/// <summary>
/// Sorts this array in ascending order.
/// </summary>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <param name="array">The array to sort.</param>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int) })]
public unsafe static void Sort<T>(this NativeArray<T> array)
where T : unmanaged, IComparable<T>
{
IntroSortStruct<T, DefaultComparer<T>>(array.GetUnsafePtr(), array.Length, new DefaultComparer<T>());
}
/// <summary>
/// Sorts this array using a custom comparison.
/// </summary>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <typeparam name="U">The type of the comparer.</typeparam>
/// <param name="array">The array to sort.</param>
/// <param name="comp">The comparison function used to determine the relative order of the elements.</param>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int), typeof(DefaultComparer<int>) })]
public unsafe static void Sort<T, U>(this NativeArray<T> array, U comp)
where T : unmanaged
where U : IComparer<T>
{
var ptr = (T*)array.GetUnsafePtr();
var len = array.Length;
CheckComparer(ptr, len, comp);
IntroSortStruct<T, U>(ptr, len, comp);
}
/// <summary>
/// Returns a job which will sort this array in ascending order.
/// </summary>
/// <remarks>This method does not schedule the job. Scheduling the job is left to you.</remarks>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <param name="array">The array to sort.</param>
/// <returns>A job for sorting this array.</returns>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int) }, RequiredUnityDefine = "UNITY_2020_2_OR_NEWER" /* Due to job scheduling on 2020.1 using statics */)]
public unsafe static SortJob<T, DefaultComparer<T>> SortJob<T>(this NativeArray<T> array)
where T : unmanaged, IComparable<T>
{
return SortJob((T*)NativeArrayUnsafeUtility.GetUnsafeBufferPointerWithoutChecks(array), array.Length, new DefaultComparer<T>());
}
/// <summary>
/// Returns a job which will sort this array using a custom comparison.
/// </summary>
/// <remarks>This method does not schedule the job. Scheduling the job is left to you.</remarks>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <typeparam name="U">The type of the comparer.</typeparam>
/// <param name="array">The array to sort.</param>
/// <param name="comp">The comparison function used to determine the relative order of the elements.</param>
/// <returns>A job for sorting the array.</returns>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int), typeof(DefaultComparer<int>) }, RequiredUnityDefine = "UNITY_2020_2_OR_NEWER" /* Due to job scheduling on 2020.1 using statics */)]
public unsafe static SortJob<T, U> SortJob<T, U>(this NativeArray<T> array, U comp)
where T : unmanaged
where U : IComparer<T>
{
var ptr = (T*)NativeArrayUnsafeUtility.GetUnsafeBufferPointerWithoutChecks(array);
var len = array.Length;
CheckComparer(ptr, len, comp);
return new SortJob<T, U>
{
Data = ptr,
Length = len,
Comp = comp
};
}
/// <summary>
/// Finds a value in this sorted array by binary search.
/// </summary>
/// <remarks>If the array is not sorted, the value might not be found, even if it's present in this array.</remarks>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <param name="array">The array to search.</param>
/// <param name="value">The value to locate.</param>
/// <returns>If found, the index of the located value. If not found, the return value is negative.</returns>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int) })]
public static int BinarySearch<T>(this NativeArray<T> array, T value)
where T : unmanaged, IComparable<T>
{
return array.BinarySearch(value, new DefaultComparer<T>());
}
/// <summary>
/// Finds a value in this sorted array by binary search using a custom comparison.
/// </summary>
/// <remarks>If the array is not sorted, the value might not be found, even if it's present in this array.
/// </remarks>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <typeparam name="U">The comparer type.</typeparam>
/// <param name="array">The array to search.</param>
/// <param name="value">The value to locate.</param>
/// <param name="comp">The comparison function used to determine the relative order of the elements.</param>
/// <returns>If found, the index of the located value. If not found, the return value is negative.</returns>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int), typeof(DefaultComparer<int>) })]
public unsafe static int BinarySearch<T, U>(this NativeArray<T> array, T value, U comp)
where T : unmanaged
where U : IComparer<T>
{
return BinarySearch((T*)NativeArrayUnsafeUtility.GetUnsafeReadOnlyPtr(array), array.Length, value, comp);
}
/// <summary>
/// Finds a value in this sorted array by binary search.
/// </summary>
/// <remarks>If the array is not sorted, the value might not be found, even if it's present in this array.</remarks>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <param name="array">The array to search.</param>
/// <param name="value">The value to locate.</param>
/// <returns>If found, the index of the located value. If not found, the return value is negative.</returns>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int) })]
public static int BinarySearch<T>(this NativeArray<T>.ReadOnly array, T value)
where T : unmanaged, IComparable<T>
{
return array.BinarySearch(value, new DefaultComparer<T>());
}
/// <summary>
/// Finds a value in this sorted array by binary search using a custom comparison.
/// </summary>
/// <remarks>If the array is not sorted, the value might not be found, even if it's present in this array.
/// </remarks>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <typeparam name="U">The comparer type.</typeparam>
/// <param name="array">The array to search.</param>
/// <param name="value">The value to locate.</param>
/// <param name="comp">The comparison function used to determine the relative order of the elements.</param>
/// <returns>If found, the index of the located value. If not found, the return value is negative.</returns>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int), typeof(DefaultComparer<int>) })]
public unsafe static int BinarySearch<T, U>(this NativeArray<T>.ReadOnly array, T value, U comp)
where T : unmanaged
where U : IComparer<T>
{
return BinarySearch((T*)NativeArrayUnsafeUtility.GetUnsafeReadOnlyPtr(array), array.Length, value, comp);
}
/// <summary>
/// Sorts this list in ascending order.
/// </summary>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <param name="list">The list to sort.</param>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int) })]
public unsafe static void Sort<T>(this NativeList<T> list)
where T : unmanaged, IComparable<T>
{
list.Sort(new DefaultComparer<T>());
}
/// <summary>
/// Sorts this list using a custom comparison.
/// </summary>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <typeparam name="U">The type of the comparer.</typeparam>
/// <param name="list">The list to sort.</param>
/// <param name="comp">The comparison function used to determine the relative order of the elements.</param>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int), typeof(DefaultComparer<int>) })]
public unsafe static void Sort<T, U>(this NativeList<T> list, U comp)
where T : unmanaged
where U : IComparer<T>
{
IntroSort<T, U>(list.GetUnsafePtr(), list.Length, comp);
}
/// <summary>
/// Returns a job which will sort this list in ascending order.
/// </summary>
/// <remarks>When `NativeList.Length` is not known at scheduling time use `SortJobDefer` instead.
/// This method does not schedule the job. Scheduling the job is left to you.</remarks>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <param name="list">The list to sort.</param>
/// <returns>A job for sorting this list.</returns>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int) }, RequiredUnityDefine = "UNITY_2020_2_OR_NEWER" /* Due to job scheduling on 2020.1 using statics */)]
public unsafe static SortJob<T, DefaultComparer<T>> SortJob<T>(this NativeList<T> list)
where T : unmanaged, IComparable<T>
{
return SortJob(list, new DefaultComparer<T>());
}
/// <summary>
/// Returns a job which will sort this list using a custom comparison.
/// </summary>
/// <remarks>When `NativeList.Length` is not known at scheduling time use `SortJobDefer` instead.
/// This method does not schedule the job. Scheduling the job is left to you.</remarks>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <typeparam name="U">The type of the comparer.</typeparam>
/// <param name="list">The list to sort.</param>
/// <param name="comp">The comparison function used to determine the relative order of the elements.</param>
/// <returns>A job for sorting this list.</returns>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int), typeof(DefaultComparer<int>) }, RequiredUnityDefine = "UNITY_2020_2_OR_NEWER" /* Due to job scheduling on 2020.1 using statics */)]
public unsafe static SortJob<T, U> SortJob<T, U>(this NativeList<T> list, U comp)
where T : unmanaged
where U : IComparer<T>
{
return SortJob(list.GetUnsafePtr(), list.Length, comp);
}
/// <summary>
/// Returns a job which will sort this list in ascending order.
/// </summary>
/// <remarks>`SortJobDefer` is intended for use when `NativeList.Length` is not known at scheduling time,
/// and it depends on completion of previosly scheduled job(s).
/// This method does not schedule the job. Scheduling the job is left to you.</remarks>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <param name="list">The list to sort.</param>
/// <returns>A job for sorting this list.</returns>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int) }, RequiredUnityDefine = "UNITY_2020_2_OR_NEWER" /* Due to job scheduling on 2020.1 using statics */)]
public unsafe static SortJobDefer<T, DefaultComparer<T>> SortJobDefer<T>(this NativeList<T> list)
where T : unmanaged, IComparable<T>
{
return SortJobDefer(list, new DefaultComparer<T>());
}
/// <summary>
/// Returns a job which will sort this list using a custom comparison.
/// </summary>
/// <remarks>`SortJobDefer` is intended for use when `NativeList.Length` is not known at scheduling time,
/// and it depends on completion of previosly scheduled job(s).
/// This method does not schedule the job. Scheduling the job is left to you.</remarks>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <typeparam name="U">The type of the comparer.</typeparam>
/// <param name="list">The list to sort.</param>
/// <param name="comp">The comparison function used to determine the relative order of the elements.</param>
/// <returns>A job for sorting this list.</returns>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int), typeof(DefaultComparer<int>) }, RequiredUnityDefine = "UNITY_2020_2_OR_NEWER" /* Due to job scheduling on 2020.1 using statics */)]
public unsafe static SortJobDefer<T, U> SortJobDefer<T, U>(this NativeList<T> list, U comp)
where T : unmanaged
where U : IComparer<T>
{
return new SortJobDefer<T, U> { Data = list, Comp = comp };
}
/// <summary>
/// Finds a value in this sorted list by binary search.
/// </summary>
/// <remarks>If this list is not sorted, the value might not be found, even if it's present in this list.</remarks>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <param name="list">The list to search.</param>
/// <param name="value">The value to locate.</param>
/// <returns>If found, the index of the located value. If not found, the return value is negative.</returns>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int) })]
public static int BinarySearch<T>(this NativeList<T> list, T value)
where T : unmanaged, IComparable<T>
{
return list.AsReadOnly().BinarySearch(value, new DefaultComparer<T>());
}
/// <summary>
/// Finds a value in this sorted list by binary search using a custom comparison.
/// </summary>
/// <remarks>If this list is not sorted, the value may not be found, even if it's present in this list.</remarks>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <typeparam name="U">The type of the comparer.</typeparam>
/// <param name="list">The list to search.</param>
/// <param name="value">The value to locate.</param>
/// <param name="comp">The comparison function used to determine the relative order of the elements.</param>
/// <returns>If found, the index of the located value. If not found, the return value is negative.</returns>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int), typeof(DefaultComparer<int>) })]
public unsafe static int BinarySearch<T, U>(this NativeList<T> list, T value, U comp)
where T : unmanaged
where U : IComparer<T>
{
return list.AsReadOnly().BinarySearch(value, comp);
}
/// <summary>
/// Sorts this list in ascending order.
/// </summary>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <param name="list">The list to sort.</param>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int) })]
public unsafe static void Sort<T>(this UnsafeList<T> list) where T : unmanaged, IComparable<T>
{
list.Sort(new DefaultComparer<T>());
}
/// <summary>
/// Sorts the list using a custom comparison.
/// </summary>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <typeparam name="U">The type of the comparer.</typeparam>
/// <param name="list">The list to sort.</param>
/// <param name="comp">The comparison function used to determine the relative order of the elements.</param>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int), typeof(DefaultComparer<int>) })]
public unsafe static void Sort<T, U>(this UnsafeList<T> list, U comp)
where T : unmanaged
where U : IComparer<T>
{
IntroSort<T, U>(list.Ptr, list.Length, comp);
}
/// <summary>
/// Returns a job which will sort this list in ascending order.
/// </summary>
/// <remarks>This method does not schedule the job. Scheduling the job is left to you.</remarks>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <param name="list">The list to sort.</param>
/// <returns>A job for sorting this list.</returns>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int) }, RequiredUnityDefine = "UNITY_2020_2_OR_NEWER" /* Due to job scheduling on 2020.1 using statics */)]
public unsafe static SortJob<T, DefaultComparer<T>> SortJob<T>(this UnsafeList<T> list)
where T : unmanaged, IComparable<T>
{
return SortJob(list.Ptr, list.Length, new DefaultComparer<T>());
}
/// <summary>
/// Returns a job which will sort this list using a custom comparison.
/// </summary>
/// <remarks>This method does not schedule the job. Scheduling the job is left to you.</remarks>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <typeparam name="U">The type of the comparer.</typeparam>
/// <param name="list">The list to sort.</param>
/// <param name="comp">The comparison function used to determine the relative order of the elements.</param>
/// <returns>A job for sorting this list.</returns>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int), typeof(DefaultComparer<int>) }, RequiredUnityDefine = "UNITY_2020_2_OR_NEWER" /* Due to job scheduling on 2020.1 using statics */)]
public unsafe static SortJob<T, U> SortJob<T, U>(this UnsafeList<T> list, U comp)
where T : unmanaged
where U : IComparer<T>
{
return SortJob(list.Ptr, list.Length, comp);
}
/// <summary>
/// Finds a value in this sorted list by binary search.
/// </summary>
/// <remarks>If this list is not sorted, the value might not be found, even if it's present in this list.</remarks>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <param name="list">The list to search.</param>
/// <param name="value">The value to locate.</param>
/// <returns>If found, the index of the located value. If not found, the return value is negative.</returns>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int) })]
public static int BinarySearch<T>(this UnsafeList<T> list, T value)
where T : unmanaged, IComparable<T>
{
return list.BinarySearch(value, new DefaultComparer<T>());
}
/// <summary>
/// Finds a value in this sorted list by binary search using a custom comparison.
/// </summary>
/// <remarks>If this list is not sorted, the value might not be found, even if it's present in this list.</remarks>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <typeparam name="U">The type of the comparer.</typeparam>
/// <param name="list">The list to search.</param>
/// <param name="value">The value to locate.</param>
/// <param name="comp">The comparison function used to determine the relative order of the elements.</param>
/// <returns>If found, the index of the located value. If not found, the return value is negative.</returns>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int), typeof(DefaultComparer<int>) })]
public unsafe static int BinarySearch<T, U>(this UnsafeList<T> list, T value, U comp)
where T : unmanaged
where U : IComparer<T>
{
return BinarySearch(list.Ptr, list.Length, value, comp);
}
/// <summary>
/// Sorts this slice in ascending order.
/// </summary>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <param name="slice">The slice to sort.</param>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int) })]
public unsafe static void Sort<T>(this NativeSlice<T> slice)
where T : unmanaged, IComparable<T>
{
slice.Sort(new DefaultComparer<T>());
}
/// <summary>
/// Sorts this slice using a custom comparison.
/// </summary>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <typeparam name="U">The type of the comparer.</typeparam>
/// <param name="slice">The slice to sort.</param>
/// <param name="comp">The comparison function used to determine the relative order of the elements.</param>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int), typeof(DefaultComparer<int>) })]
public unsafe static void Sort<T, U>(this NativeSlice<T> slice, U comp)
where T : unmanaged
where U : IComparer<T>
{
var ptr = (T*)slice.GetUnsafePtr();
var len = slice.Length;
CheckComparer(ptr, len, comp);
CheckStrideMatchesSize<T>(slice.Stride);
IntroSortStruct<T, U>(ptr, len, comp);
}
/// <summary>
/// Returns a job which will sort this slice in ascending order.
/// </summary>
/// <remarks>This method does not schedule the job. Scheduling the job is left to you.</remarks>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <param name="slice">The slice to sort.</param>
/// <returns>A job for sorting this slice.</returns>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int) }, RequiredUnityDefine = "UNITY_2020_2_OR_NEWER" /* Due to job scheduling on 2020.1 using statics */)]
public unsafe static SortJob<T, DefaultComparer<T>> SortJob<T>(this NativeSlice<T> slice)
where T : unmanaged, IComparable<T>
{
CheckStrideMatchesSize<T>(slice.Stride);
return SortJob((T*)slice.GetUnsafePtr(), slice.Length, new DefaultComparer<T>());
}
/// <summary>
/// Returns a job which will sort this slice using a custom comparison.
/// </summary>
/// <remarks>This method does not schedule the job. Scheduling the job is left to you.</remarks>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <typeparam name="U">The type of the comparer.</typeparam>
/// <param name="slice">The slice to sort.</param>
/// <param name="comp">The comparison function used to determine the relative order of the elements.</param>
/// <returns>A job for sorting this slice.</returns>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int), typeof(DefaultComparer<int>) }, RequiredUnityDefine = "UNITY_2020_2_OR_NEWER" /* Due to job scheduling on 2020.1 using statics */)]
public unsafe static SortJob<T, U> SortJob<T, U>(this NativeSlice<T> slice, U comp)
where T : unmanaged
where U : IComparer<T>
{
CheckStrideMatchesSize<T>(slice.Stride);
return SortJob((T*)slice.GetUnsafePtr(), slice.Length, comp);
}
/// <summary>
/// Finds a value in this sorted slice by binary search.
/// </summary>
/// <remarks>If this slice is not sorted, the value might not be found, even if it's present in this slice.</remarks>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <param name="slice">The slice to search.</param>
/// <param name="value">The value to locate.</param>
/// <returns>If found, the index of the located value. If not found, the return value is negative.</returns>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int) })]
public static int BinarySearch<T>(this NativeSlice<T> slice, T value)
where T : unmanaged, IComparable<T>
{
return slice.BinarySearch(value, new DefaultComparer<T>());
}
/// <summary>
/// Finds a value in this sorted slice by binary search using a custom comparison.
/// </summary>
/// <remarks>If this slice is not sorted, the value might not be found, even if it's present in this slice.</remarks>
/// <typeparam name="T">The type of the elements.</typeparam>
/// <typeparam name="U">The type of the comparer.</typeparam>
/// <param name="slice">The slice to search.</param>
/// <param name="value">The value to locate.</param>
/// <param name="comp">The comparison function used to determine the relative order of the elements.</param>
/// <returns>If found, the index of the located value. If not found, the return value is negative.</returns>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int), typeof(DefaultComparer<int>) })]
public unsafe static int BinarySearch<T, U>(this NativeSlice<T> slice, T value, U comp)
where T : unmanaged
where U : IComparer<T>
{
return BinarySearch((T*)slice.GetUnsafeReadOnlyPtr(), slice.Length, value, comp);
}
/// -- Internals
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int), typeof(DefaultComparer<int>) })]
unsafe internal static void IntroSort<T, U>(void* array, int length, U comp)
where T : unmanaged
where U : IComparer<T>
{
CheckComparer((T*)array, length, comp);
IntroSort_R<T, U>(array, 0, length - 1, 2 * CollectionHelper.Log2Floor(length), comp);
}
const int k_IntrosortSizeThreshold = 16;
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int), typeof(DefaultComparer<int>) })]
unsafe internal static void IntroSort_R<T, U>(void* array, int lo, int hi, int depth, U comp)
where T : unmanaged
where U : IComparer<T>
{
while (hi > lo)
{
int partitionSize = hi - lo + 1;
if (partitionSize <= k_IntrosortSizeThreshold)
{
if (partitionSize == 1)
{
return;
}
if (partitionSize == 2)
{
SwapIfGreaterWithItems<T, U>(array, lo, hi, comp);
return;
}
if (partitionSize == 3)
{
SwapIfGreaterWithItems<T, U>(array, lo, hi - 1, comp);
SwapIfGreaterWithItems<T, U>(array, lo, hi, comp);
SwapIfGreaterWithItems<T, U>(array, hi - 1, hi, comp);
return;
}
InsertionSort<T, U>(array, lo, hi, comp);
return;
}
if (depth == 0)
{
HeapSort<T, U>(array, lo, hi, comp);
return;
}
depth--;
int p = Partition<T, U>(array, lo, hi, comp);
IntroSort_R<T, U>(array, p + 1, hi, depth, comp);
hi = p - 1;
}
}
unsafe static void InsertionSort<T, U>(void* array, int lo, int hi, U comp)
where T : unmanaged
where U : IComparer<T>
{
int i, j;
T t;
for (i = lo; i < hi; i++)
{
j = i;
t = UnsafeUtility.ReadArrayElement<T>(array, i + 1);
while (j >= lo && comp.Compare(t, UnsafeUtility.ReadArrayElement<T>(array, j)) < 0)
{
UnsafeUtility.WriteArrayElement(array, j + 1, UnsafeUtility.ReadArrayElement<T>(array, j));
j--;
}
UnsafeUtility.WriteArrayElement(array, j + 1, t);
}
}
unsafe static int Partition<T, U>(void* array, int lo, int hi, U comp)
where T : unmanaged
where U : IComparer<T>
{
int mid = lo + ((hi - lo) / 2);
SwapIfGreaterWithItems<T, U>(array, lo, mid, comp);
SwapIfGreaterWithItems<T, U>(array, lo, hi, comp);
SwapIfGreaterWithItems<T, U>(array, mid, hi, comp);
T pivot = UnsafeUtility.ReadArrayElement<T>(array, mid);
Swap<T>(array, mid, hi - 1);
int left = lo, right = hi - 1;
while (left < right)
{
while (left < hi && comp.Compare(pivot, UnsafeUtility.ReadArrayElement<T>(array, ++left)) > 0)
{
}
while (right > left && comp.Compare(pivot, UnsafeUtility.ReadArrayElement<T>(array, --right)) < 0)
{
}
if (left >= right)
break;
Swap<T>(array, left, right);
}
Swap<T>(array, left, (hi - 1));
return left;
}
unsafe static void HeapSort<T, U>(void* array, int lo, int hi, U comp)
where T : unmanaged
where U : IComparer<T>
{
int n = hi - lo + 1;
for (int i = n / 2; i >= 1; i--)
{
Heapify<T, U>(array, i, n, lo, comp);
}
for (int i = n; i > 1; i--)
{
Swap<T>(array, lo, lo + i - 1);
Heapify<T, U>(array, 1, i - 1, lo, comp);
}
}
unsafe static void Heapify<T, U>(void* array, int i, int n, int lo, U comp)
where T : unmanaged
where U : IComparer<T>
{
T val = UnsafeUtility.ReadArrayElement<T>(array, lo + i - 1);
int child;
while (i <= n / 2)
{
child = 2 * i;
if (child < n && (comp.Compare(UnsafeUtility.ReadArrayElement<T>(array, lo + child - 1), UnsafeUtility.ReadArrayElement<T>(array, (lo + child))) < 0))
{
child++;
}
if (comp.Compare(UnsafeUtility.ReadArrayElement<T>(array, (lo + child - 1)), val) < 0)
{
break;
}
UnsafeUtility.WriteArrayElement(array, lo + i - 1, UnsafeUtility.ReadArrayElement<T>(array, lo + child - 1));
i = child;
}
UnsafeUtility.WriteArrayElement(array, lo + i - 1, val);
}
unsafe static void Swap<T>(void* array, int lhs, int rhs) where T : unmanaged
{
T val = UnsafeUtility.ReadArrayElement<T>(array, lhs);
UnsafeUtility.WriteArrayElement(array, lhs, UnsafeUtility.ReadArrayElement<T>(array, rhs));
UnsafeUtility.WriteArrayElement(array, rhs, val);
}
unsafe static void SwapIfGreaterWithItems<T, U>(void* array, int lhs, int rhs, U comp)
where T : unmanaged
where U : IComparer<T>
{
if (lhs != rhs)
{
if (comp.Compare(UnsafeUtility.ReadArrayElement<T>(array, lhs), UnsafeUtility.ReadArrayElement<T>(array, rhs)) > 0)
{
Swap<T>(array, lhs, rhs);
}
}
}
unsafe static void IntroSortStruct<T, U>(void* array, int length, U comp)
where T : unmanaged
where U : IComparer<T>
{
IntroSortStruct_R<T, U>(array, 0, length - 1, 2 * CollectionHelper.Log2Floor(length), comp);
}
unsafe static void IntroSortStruct_R<T, U>(void* array, in int lo, in int _hi, int depth, U comp)
where T : unmanaged
where U : IComparer<T>
{
var hi = _hi;
while (hi > lo)
{
int partitionSize = hi - lo + 1;
if (partitionSize <= k_IntrosortSizeThreshold)
{
if (partitionSize == 1)
{
return;
}
if (partitionSize == 2)
{
SwapIfGreaterWithItemsStruct<T, U>(array, lo, hi, comp);
return;
}
if (partitionSize == 3)
{
SwapIfGreaterWithItemsStruct<T, U>(array, lo, hi - 1, comp);
SwapIfGreaterWithItemsStruct<T, U>(array, lo, hi, comp);
SwapIfGreaterWithItemsStruct<T, U>(array, hi - 1, hi, comp);
return;
}
InsertionSortStruct<T, U>(array, lo, hi, comp);
return;
}
if (depth == 0)
{
HeapSortStruct<T, U>(array, lo, hi, comp);
return;
}
depth--;
int p = PartitionStruct<T, U>(array, lo, hi, comp);
IntroSortStruct_R<T, U>(array, p + 1, hi, depth, comp);
hi = p - 1;
}
}
unsafe static void InsertionSortStruct<T, U>(void* array, in int lo, in int hi, U comp)
where T : unmanaged
where U : IComparer<T>
{
int i, j;
T t;
for (i = lo; i < hi; i++)
{
j = i;
t = UnsafeUtility.ReadArrayElement<T>(array, i + 1);
while (j >= lo && comp.Compare(t, UnsafeUtility.ReadArrayElement<T>(array, j)) < 0)
{
UnsafeUtility.WriteArrayElement(array, j + 1, UnsafeUtility.ReadArrayElement<T>(array, j));
j--;
}
UnsafeUtility.WriteArrayElement(array, j + 1, t);
}
}
unsafe static int PartitionStruct<T, U>(void* array, in int lo, in int hi, U comp)
where T : unmanaged
where U : IComparer<T>
{
int mid = lo + ((hi - lo) / 2);
SwapIfGreaterWithItemsStruct<T, U>(array, lo, mid, comp);
SwapIfGreaterWithItemsStruct<T, U>(array, lo, hi, comp);
SwapIfGreaterWithItemsStruct<T, U>(array, mid, hi, comp);
T pivot = UnsafeUtility.ReadArrayElement<T>(array, mid);
SwapStruct<T>(array, mid, hi - 1);
int left = lo, right = hi - 1;
while (left < right)
{
while (left < hi && comp.Compare(pivot, UnsafeUtility.ReadArrayElement<T>(array, ++left)) > 0)
{
}
while (right > left && comp.Compare(pivot, UnsafeUtility.ReadArrayElement<T>(array, --right)) < 0)
{
}
if (left >= right)
break;
SwapStruct<T>(array, left, right);
}
SwapStruct<T>(array, left, (hi - 1));
return left;
}
unsafe static void HeapSortStruct<T, U>(void* array, in int lo, in int hi, U comp)
where T : unmanaged
where U : IComparer<T>
{
int n = hi - lo + 1;
for (int i = n / 2; i >= 1; i--)
{
HeapifyStruct<T, U>(array, i, n, lo, comp);
}
for (int i = n; i > 1; i--)
{
SwapStruct<T>(array, lo, lo + i - 1);
HeapifyStruct<T, U>(array, 1, i - 1, lo, comp);
}
}
unsafe static void HeapifyStruct<T, U>(void* array, int i, int n, in int lo, U comp)
where T : unmanaged
where U : IComparer<T>
{
T val = UnsafeUtility.ReadArrayElement<T>(array, lo + i - 1);
int child;
while (i <= n / 2)
{
child = 2 * i;
if (child < n && (comp.Compare(UnsafeUtility.ReadArrayElement<T>(array, lo + child - 1), UnsafeUtility.ReadArrayElement<T>(array, (lo + child))) < 0))
{
child++;
}
if (comp.Compare(UnsafeUtility.ReadArrayElement<T>(array, (lo + child - 1)), val) < 0)
{
break;
}
UnsafeUtility.WriteArrayElement(array, lo + i - 1, UnsafeUtility.ReadArrayElement<T>(array, lo + child - 1));
i = child;
}
UnsafeUtility.WriteArrayElement(array, lo + i - 1, val);
}
unsafe static void SwapStruct<T>(void* array, int lhs, int rhs)
where T : unmanaged
{
T val = UnsafeUtility.ReadArrayElement<T>(array, lhs);
UnsafeUtility.WriteArrayElement(array, lhs, UnsafeUtility.ReadArrayElement<T>(array, rhs));
UnsafeUtility.WriteArrayElement(array, rhs, val);
}
unsafe static void SwapIfGreaterWithItemsStruct<T, U>(void* array, int lhs, int rhs, U comp)
where T : unmanaged
where U : IComparer<T>
{
if (lhs != rhs)
{
if (comp.Compare(UnsafeUtility.ReadArrayElement<T>(array, lhs), UnsafeUtility.ReadArrayElement<T>(array, rhs)) > 0)
{
SwapStruct<T>(array, lhs, rhs);
}
}
}
[Conditional("ENABLE_UNITY_COLLECTIONS_CHECKS"), Conditional("UNITY_DOTS_DEBUG")]
static void CheckStrideMatchesSize<T>(int stride) where T : unmanaged
{
if (stride != UnsafeUtility.SizeOf<T>())
{
throw new InvalidOperationException("Sort requires that stride matches the size of the source type");
}
}
[Conditional("ENABLE_UNITY_COLLECTIONS_CHECKS"), Conditional("UNITY_DOTS_DEBUG")]
unsafe static void CheckComparer<T, U>(T* array, int length, U comp)
where T : unmanaged
where U : IComparer<T>
{
if (length > 0)
{
T a = array[0];
if (0 != comp.Compare(a, a))
{
throw new InvalidOperationException("Comparison function is incorrect. Compare(a, a) must return 0/equal.");
}
for (int i = 1, len = math.min(length, 8); i < len; ++i)
{
T b = array[i];
if (0 == comp.Compare(a, b) &&
0 == comp.Compare(b, a))
{
continue;
}
if (0 == comp.Compare(a, b))
{
throw new InvalidOperationException("Comparison function is incorrect. Compare(a, b) of two different values should not return 0/equal.");
}
if (0 == comp.Compare(b, a))
{
throw new InvalidOperationException("Comparison function is incorrect. Compare(b, a) of two different values should not return 0/equal.");
}
if (comp.Compare(a, b) == comp.Compare(b, a))
{
throw new InvalidOperationException("Comparison function is incorrect. Compare(a, b) when a and b are different values should not return the same value as Compare(b, a).");
}
break;
}
}
}
}
/// <summary>
/// Returned by the `SortJob` methods of <see cref="Unity.Collections.NativeSortExtension"/>. Call `Schedule` to schedule the sorting.
/// </summary>
/// <remarks>
/// When `RegisterGenericJobType` is used on SortJob, to complete registration you must register `SortJob&lt;T,U&gt;.SegmentSort` and `SortJob&lt;T,U&gt;.SegmentSortMerge`.
/// </remarks>
/// <typeparam name="T">The type of the elements to sort.</typeparam>
/// <typeparam name="U">The type of the comparer.</typeparam>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int), typeof(NativeSortExtension.DefaultComparer<int>) }, RequiredUnityDefine = "UNITY_2020_2_OR_NEWER" /* Due to job scheduling on 2020.1 using statics */)]
public unsafe struct SortJob<T, U>
where T : unmanaged
where U : IComparer<T>
{
/// <summary>
/// The data to sort.
/// </summary>
public T* Data;
/// <summary>
/// Comparison function.
/// </summary>
public U Comp;
/// <summary>
/// The length to sort.
/// </summary>
public int Length;
/// <summary>
/// <undoc />
/// </summary>
[BurstCompile]
public struct SegmentSort : IJobParallelFor
{
[NativeDisableUnsafePtrRestriction]
internal T* Data;
internal U Comp;
internal int Length;
internal int SegmentWidth;
/// <summary>
/// <undoc />
/// </summary>
/// <param name="index"><undoc /></param>
public void Execute(int index)
{
var startIndex = index * SegmentWidth;
var segmentLength = ((Length - startIndex) < SegmentWidth) ? (Length - startIndex) : SegmentWidth;
NativeSortExtension.Sort(Data + startIndex, segmentLength, Comp);
}
}
/// <summary>
/// <undoc />
/// </summary>
[BurstCompile]
public struct SegmentSortMerge : IJob
{
[NativeDisableUnsafePtrRestriction]
internal T* Data;
internal U Comp;
internal int Length;
internal int SegmentWidth;
/// <summary>
/// <undoc />
/// </summary>
public void Execute()
{
var segmentCount = (Length + (SegmentWidth - 1)) / SegmentWidth;
var segmentIndex = stackalloc int[segmentCount];
var resultCopy = (T*)Memory.Unmanaged.Allocate(UnsafeUtility.SizeOf<T>() * Length, 16, Allocator.Temp);
for (int sortIndex = 0; sortIndex < Length; sortIndex++)
{
// find next best
int bestSegmentIndex = -1;
T bestValue = default(T);
for (int i = 0; i < segmentCount; i++)
{
var startIndex = i * SegmentWidth;
var offset = segmentIndex[i];
var segmentLength = ((Length - startIndex) < SegmentWidth) ? (Length - startIndex) : SegmentWidth;
if (offset == segmentLength)
continue;
var nextValue = Data[startIndex + offset];
if (bestSegmentIndex != -1)
{
if (Comp.Compare(nextValue, bestValue) > 0)
continue;
}
bestValue = nextValue;
bestSegmentIndex = i;
}
segmentIndex[bestSegmentIndex]++;
resultCopy[sortIndex] = bestValue;
}
UnsafeUtility.MemCpy(Data, resultCopy, UnsafeUtility.SizeOf<T>() * Length);
}
}
/// <summary>
/// Schedules this job.
/// </summary>
/// <param name="inputDeps">Handle of a job to depend upon.</param>
/// <returns>The handle of this newly scheduled job.</returns>
public JobHandle Schedule(JobHandle inputDeps = default)
{
if (Length == 0)
return inputDeps;
var segmentCount = (Length + 1023) / 1024;
#if UNITY_2022_2_14F1_OR_NEWER
int maxThreadCount = JobsUtility.ThreadIndexCount;
#else
int maxThreadCount = JobsUtility.MaxJobThreadCount;
#endif
var workerCount = math.max(1, maxThreadCount);
var workerSegmentCount = segmentCount / workerCount;
var segmentSortJob = new SegmentSort { Data = Data, Comp = Comp, Length = Length, SegmentWidth = 1024 };
var segmentSortJobHandle = segmentSortJob.Schedule(segmentCount, workerSegmentCount, inputDeps);
var segmentSortMergeJob = new SegmentSortMerge { Data = Data, Comp = Comp, Length = Length, SegmentWidth = 1024 };
var segmentSortMergeJobHandle = segmentSortMergeJob.Schedule(segmentSortJobHandle);
return segmentSortMergeJobHandle;
}
}
/// <summary>
/// Returned by the `SortJobDefer` methods of <see cref="Unity.Collections.NativeSortExtension"/>. Call `Schedule` to schedule the sorting.
/// </summary>
/// <remarks>
/// When `RegisterGenericJobType` is used on SortJobDefer, to complete registration you must register `SortJobDefer&lt;T,U&gt;.SegmentSort` and `SortJobDefer&lt;T,U&gt;.SegmentSortMerge`.
/// </remarks>
/// <typeparam name="T">The type of the elements to sort.</typeparam>
/// <typeparam name="U">The type of the comparer.</typeparam>
[GenerateTestsForBurstCompatibility(GenericTypeArguments = new[] { typeof(int), typeof(NativeSortExtension.DefaultComparer<int>) }, RequiredUnityDefine = "UNITY_2020_2_OR_NEWER" /* Due to job scheduling on 2020.1 using statics */)]
public unsafe struct SortJobDefer<T, U>
where T : unmanaged
where U : IComparer<T>
{
/// <summary>
/// The data to sort.
/// </summary>
public NativeList<T> Data;
/// <summary>
/// Comparison function.
/// </summary>
public U Comp;
/// <summary>
/// <undoc />
/// </summary>
[BurstCompile]
public struct SegmentSort : IJobParallelForDefer
{
[ReadOnly]
internal NativeList<T> DataRO;
[NativeDisableUnsafePtrRestriction]
internal UnsafeList<T>* Data;
internal U Comp;
internal int SegmentWidth;
/// <summary>
/// <undoc />
/// </summary>
/// <param name="index"><undoc /></param>
public void Execute(int index)
{
var startIndex = index * SegmentWidth;
var segmentLength = ((Data->Length - startIndex) < SegmentWidth) ? (Data->Length - startIndex) : SegmentWidth;
NativeSortExtension.Sort(Data->Ptr + startIndex, segmentLength, Comp);
}
}
/// <summary>
/// <undoc />
/// </summary>
[BurstCompile]
public struct SegmentSortMerge : IJob
{
[NativeDisableUnsafePtrRestriction]
internal NativeList<T> Data;
internal U Comp;
internal int SegmentWidth;
/// <summary>
/// <undoc />
/// </summary>
public void Execute()
{
var length = Data.Length;
var ptr = Data.GetUnsafePtr();
var segmentCount = (length + (SegmentWidth - 1)) / SegmentWidth;
var segmentIndex = stackalloc int[segmentCount];
var resultCopy = (T*)Memory.Unmanaged.Allocate(UnsafeUtility.SizeOf<T>() * length, 16, Allocator.Temp);
for (int sortIndex = 0; sortIndex < length; sortIndex++)
{
// find next best
int bestSegmentIndex = -1;
T bestValue = default;
for (int i = 0; i < segmentCount; i++)
{
var startIndex = i * SegmentWidth;
var offset = segmentIndex[i];
var segmentLength = ((length - startIndex) < SegmentWidth) ? (length - startIndex) : SegmentWidth;
if (offset == segmentLength)
continue;
var nextValue = ptr[startIndex + offset];
if (bestSegmentIndex != -1)
{
if (Comp.Compare(nextValue, bestValue) > 0)
continue;
}
bestValue = nextValue;
bestSegmentIndex = i;
}
segmentIndex[bestSegmentIndex]++;
resultCopy[sortIndex] = bestValue;
}
UnsafeUtility.MemCpy(ptr, resultCopy, UnsafeUtility.SizeOf<T>() * length);
}
}
/// <summary>
/// Schedules this job.
/// </summary>
/// <param name="inputDeps">Handle of a job to depend upon.</param>
/// <returns>The handle of this newly scheduled job.</returns>
public JobHandle Schedule(JobHandle inputDeps = default)
{
var segmentSortJob = new SegmentSort { DataRO = Data, Data = Data.m_ListData, Comp = Comp, SegmentWidth = 1024 };
var segmentSortJobHandle = segmentSortJob.ScheduleByRef(Data, 1024, inputDeps);
var segmentSortMergeJob = new SegmentSortMerge { Data = Data, Comp = Comp, SegmentWidth = 1024 };
var segmentSortMergeJobHandle = segmentSortMergeJob.Schedule(segmentSortJobHandle);
return segmentSortMergeJobHandle;
}
}
}