我已经实现了mergesort和quicksort来将它们与本机JavaScript排序进行比较。对于快速排序,我尝试使用此算法:在youtube上查看算法。两种算法都使用尽可能少的内存,对于合并排序,将为每个递归调用传递辅助数组(以避免开销),对于快速排序,将传递起始位置和结束位置。我正在使用排序来管理NodeJs应用程序中的大量数据。
在下面有mergesort,quicksort和本机JavaScript排序,您可以测试性能
问题是:为什么本机JavaScript的执行速度较慢?
就我而言:
Chrome-合并排序:度量:1997.920ms;快速排序:测量:1755.740ms; native:度量:4988.105ms 节点:合并排序:度量:2233.413ms; 快速排序:测量:1876.055ms; 母语:措施:6317.118ms
合并排序
var length = 10000000; // ten millions; var arr = []; for (let i = length; i > 0; i--) { // random array arr.push(parseInt(Math.random() * 1000000000)); } var mergeSort = function(array) { function merge(arr, aux, lo, mid, hi) { for (var k = lo; k <= hi; k++) { aux[k] = arr[k]; } var i = lo; var j = mid + 1; for (var k = lo; k <= hi; k++) { if (i > mid) { arr[k] = aux[j++]; } else if (j > hi) { arr[k] = aux[i++]; } else if (aux[i] < aux[j]) { arr[k] = aux[i++]; } else { arr[k] = aux[j++]; } } } function sort(array, aux, lo, hi) { if (hi <= lo) return; var mid = Math.floor(lo + (hi - lo) / 2); sort(array, aux, lo, mid); sort(array, aux, mid + 1, hi); merge(array, aux, lo, mid, hi); } function merge_sort(array) { var aux = array.slice(0); sort(array, aux, 0, array.length - 1); return array; } return merge_sort(array); } console.time('measure'); mergeSort(arr); console.timeEnd('measure'); console.log(arr[0], arr[1]);
快速排序
var length = 10000000; // ten millions; var arr = []; for (let i = length; i > 0; i--) { // random array arr.push(parseInt(Math.random() * 1000000000)); } function quickSort(arr, leftPos, rightPos, arrLength) { let initialLeftPos = leftPos; let initialRightPos = rightPos; let direction = true; let pivot = rightPos; while ((leftPos - rightPos) < 0) { if (direction) { if (arr[pivot] < arr[leftPos]) { quickSort.swap(arr, pivot, leftPos); pivot = leftPos; rightPos--; direction = !direction; } else leftPos++; } else { if (arr[pivot] <= arr[rightPos]) { rightPos--; } else { quickSort.swap(arr, pivot, rightPos); leftPos++; pivot = rightPos; direction = !direction; } } } if (pivot - 1 > initialLeftPos) { quickSort(arr, initialLeftPos, pivot - 1, arrLength); } if (pivot + 1 < initialRightPos) { quickSort(arr, pivot + 1, initialRightPos, arrLength); } } quickSort.swap = (arr, el1, el2) => { let swapedElem = arr[el1]; arr[el1] = arr[el2]; arr[el2] = swapedElem; } arrLength = arr.length; console.time('measure'); quickSort(arr, 0, arrLength - 1, arrLength); console.log(arr[0], arr[1]); console.timeEnd('measure');
本机Javascript排序
var length = 10000000; // ten millions; var arr = []; for (let i = length; i > 0; i--) { // random array arr.push(parseInt(Math.random() * 100000000)); } console.time('measure'); arr.sort(function compareNumbers(a, b) { return a - b; }); console.timeEnd('measure'); console.log(arr[0], arr[1]);
那么,为什么本机排序较慢?在看代码
https://github.com/v8/v8/blob/0c76b0ae850027006d5ec0d92449e449d996d3bb/src/js/array.js#L744
问题似乎是GetThirdIndex()。当分区大小> 1000时会调用该方法,并且我假设它用于防止快速排序的最坏情况下的性能,但是开销很大,因为它会创建对的内部数组并对它们进行排序,而这些对的排序会导致进一步的递归调用GetThirdIndex()。这与与分区原始数组和分区内部对数组有关的递归调用结合在一起。
由于这些示例的测试数据是随机数据,因此Relu的quicksort不需要GetThirdIndex()之类的东西。数组中也有“空洞”的检查,但我认为这并不重要。
GetThirdIndex()的替代方法是就地中位数:
http://en.wikipedia.org/wiki/Median_of_medians
使用这些方法来防止最坏情况的合并排序比快速排序更快,但是合并排序需要的辅助数组的大小与原始数组的大小相同或一半。
Introsort是quicksort和heapsort的混合体,如果递归级别太深,则切换到heapsort是一种替代方法:
http://en.wikipedia.org/wiki/Introsort
下面的第二个合并排序示例使用一个compare函数进行公平的比较。它比本机版本快得多。对于Chrome,比较功能对整体时间的影响不大。对于Firefox,比较功能具有更大的作用。对于Firefox,本机版本因内存不足而失败,因此我无法进行比较。
这些是原始海报“好奇”的自上而下合并排序的较快版本,使用相互递归函数来避免复制并优化了merge()(每个比较有两个条件)。
使用Firefox的结果(时间略有不同)
native sort - failed for out of memory. Relu's merge sort - 1.8 seconds Relu's quick sort - 1.3 seconds optimized merge sort - 1.4 seconds optimized merge sort with compare - 1.8 seconds
使用Chrome的结果(时间略有不同)
native sort - 5.3 seconds Relu's merge sort - 2.1 seconds Relu's quick sort - 1.8 seconds optimized merge sort - 1.6 seconds optimized merge sort with compare - 1.7 seconds
var length = 10000000; // ten millions; var arr = []; for (let i = length; i > 0; i--) { // random array arr.push(parseInt(Math.random() * 1000000000)); } var mergeSort = function(array) { function merge(arr, aux, lo, mid, hi) { var i = lo; var j = mid + 1; var k = lo; while(true){ if(arr[i] <= arr[j]){ aux[k++] = arr[i++]; if(i > mid){ do aux[k++] = arr[j++]; while(j <= hi); break; } } else { aux[k++] = arr[j++]; if(j > hi){ do aux[k++] = arr[i++]; while(i <= mid); break; } } } } function sortarrtoaux(arr, aux, lo, hi) { if (hi < lo) return; if (hi == lo){ aux[lo] = arr[lo]; return; } var mid = Math.floor(lo + (hi - lo) / 2); sortarrtoarr(arr, aux, lo, mid); sortarrtoarr(arr, aux, mid + 1, hi); merge(arr, aux, lo, mid, hi); } function sortarrtoarr(arr, aux, lo, hi) { if (hi <= lo) return; var mid = Math.floor(lo + (hi - lo) / 2); sortarrtoaux(arr, aux, lo, mid); sortarrtoaux(arr, aux, mid + 1, hi); merge(aux, arr, lo, mid, hi); } function merge_sort(arr) { var aux = arr.slice(0); sortarrtoarr(arr, aux, 0, arr.length - 1); return arr; } return merge_sort(array); } console.time('measure'); mergeSort(arr); console.timeEnd('measure'); console.log(arr[0], arr[1]);
合并排序与比较功能
var length = 10000000; // ten millions; var arr = []; for (let i = length; i > 0; i--) { // random array arr.push(parseInt(Math.random() * 1000000000)); } var mergeSort = function(array, comparefn) { function merge(arr, aux, lo, mid, hi, comparefn) { var i = lo; var j = mid + 1; var k = lo; while(true){ var cmp = comparefn(arr[i], arr[j]); if(cmp <= 0){ aux[k++] = arr[i++]; if(i > mid){ do aux[k++] = arr[j++]; while(j <= hi); break; } } else { aux[k++] = arr[j++]; if(j > hi){ do aux[k++] = arr[i++]; while(i <= mid); break; } } } } function sortarrtoaux(arr, aux, lo, hi, comparefn) { if (hi < lo) return; if (hi == lo){ aux[lo] = arr[lo]; return; } var mid = Math.floor(lo + (hi - lo) / 2); sortarrtoarr(arr, aux, lo, mid, comparefn); sortarrtoarr(arr, aux, mid + 1, hi, comparefn); merge(arr, aux, lo, mid, hi, comparefn); } function sortarrtoarr(arr, aux, lo, hi, comparefn) { if (hi <= lo) return; var mid = Math.floor(lo + (hi - lo) / 2); sortarrtoaux(arr, aux, lo, mid, comparefn); sortarrtoaux(arr, aux, mid + 1, hi, comparefn); merge(aux, arr, lo, mid, hi, comparefn); } function merge_sort(arr, comparefn) { var aux = arr.slice(0); sortarrtoarr(arr, aux, 0, arr.length - 1, comparefn); return arr; } return merge_sort(array, comparefn); } console.time('measure'); mergeSort(arr, function compareNumbers(a, b) { return a - b; }); console.timeEnd('measure'); // check result for (let i = 1; i < length; i++) { if(arr[i] < arr[i-1]){ console.log('error'); break; } } console.log(arr[0], arr[1]);
旁注:本机排序不稳定:
本机Javascript排序-测试稳定性
var length = 100000; var arr = []; var j; for (let i = 0; i < length; i++) { j = parseInt(Math.random() * 100); arr[i] = [j, i]; } console.time('measure'); arr.sort(function compareNumbers(a, b) { return a[0] - b[0]; }); console.timeEnd('measure'); for (let i = 1; i < length; i++) { if( (arr[i][0] == arr[i-1][0]) && (arr[i][1] < arr[i-1][1]) ){ console.log('not stable'); console.log(arr[i-1][0], arr[i-1][1]); console.log(arr[i ][0], arr[i ][1]); break; } }
本机Javascript排序-更改比较以使其稳定
var length = 100000; var arr = []; var j; for (let i = 0; i < length; i++) { j = parseInt(Math.random() * 100); arr[i] = [j, i]; } console.time('measure'); arr.sort(function compareNumbers(a, b) { if(a[0] == b[0]) return a[1] - b[1]; return a[0] - b[0]; }); console.timeEnd('measure'); for (let i = 1; i < length; i++) { if( (arr[i][0] == arr[i-1][0]) && (arr[i][1] < arr[i-1][1]) ){ console.log('not stable'); console.log(arr[i-1][0], arr[i-1][1]); console.log(arr[i ][0], arr[i ][1]); break; } }
