# Why is my bottom-up merge sort so slow in Java?

I spent the past few hours trying to figure out why the Java version of my sorting algorithm was twice as slow as a recursive merge sort, since the C and C++ versions were 40-50% faster. I kept removing more and more code until I had stripped everything down to a simple loop and merge, but it was still twice as slow. Why is this so slow only in Java?

For reference, here's what a bottom-up merge sort might look like:

``````public static <T> void sort(T[] a, T[] aux, Comparator<T> comp) {
int N = a.length;
for (int n = 1; n < N; n = n+n)
for (int i = 0; i < N-n; i += n+n)
merge(a, aux, i, i+n-1, Math.min(i+n+n-1, N-1), comp);
}
``````

And here's the recursive version:

``````public static <T> void sort(T[] a, T[] aux, int lo, int hi, Comparator<T> comp) {
int mid = lo + (hi - lo) / 2;
sort(a, aux, lo, mid, comp);
sort(a, aux, mid + 1, hi, comp);
merge(a, aux, lo, mid, hi, comp);
}
``````

Those are basically just copied from the algorithms on this website. As a last resort I figured I'd copy and paste something from online, but it too is twice as slow as the recursive version.

Is there something "special" about Java that I'm missing?

EDIT: As requested, here's some code:

``````import java.util.*;
import java.lang.*;
import java.io.*;

class Test {
public int value;
public int index;
}

class TestComparator implements Comparator<Test> {
public int compare(Test a, Test b) {
if (a.value < b.value) return -1;
if (a.value > b.value) return 1;
return 0;
}
}

class Merge<T> {
private static <T> void Merge(T[] array, int start, int mid, int end, Comparator<T> comp, T[] buffer) {
java.lang.System.arraycopy(array, start, buffer, 0, (mid - start));
int A_count = 0, B_count = 0, insert = 0;
while (A_count < (mid - start) && B_count < (end - mid)) {
if (comp.compare(array[mid + B_count], buffer[A_count]) >= 0)
array[start + insert++] = buffer[A_count++];
else
array[start + insert++] = array[mid + B_count++];
}
java.lang.System.arraycopy(buffer, A_count, array, start + insert, (mid - start) - A_count);
}

private static <T> void SortR(T[] array, int start, int end, T[] buffer, Comparator<T> comp) {
if (end - start <= 2) {
if (end - start == 2) {
if (comp.compare(array[start], array[end - 1]) > 0) {
T swap = array[start];
array[start] = array[end - 1];
array[end - 1] = swap;
}
}

return;
}

int mid = start + (end - start)/2;
SortR(array, start, mid, buffer, comp);
SortR(array, mid, end, buffer, comp);
Merge(array, start, mid, end, comp, buffer);
}

public static <T> void Recursive(T[] array, Comparator<T> comp) {
@SuppressWarnings("unchecked")
T[] buffer = (T[]) new Object[array.length];
SortR(array, 0, array.length, buffer, comp);
}

public static <T> void BottomUp(T[] array, Comparator<T> comp) {
@SuppressWarnings("unchecked")
T[] buffer = (T[]) new Object[array.length];

int size = array.length;
for (int index = 0; index < size - 1; index += 2) {
if (comp.compare(array[index], array[index + 1]) > 0) {
T swap = array[index];
array[index] = array[index + 1];
array[index + 1] = swap;
}
}

for (int length = 2; length < size; length += length)
for (int index = 0; index < size - length; index += length + length)
Merge(array, index, index + length, Math.min(index + length + length, size), comp, buffer);
}
}

class SortRandom {
public static Random rand;
public static int nextInt(int max) {
// set the seed on the random number generator
if (rand == null) rand = new Random();
return rand.nextInt(max);
}
public static int nextInt() {
return nextInt(2147483647);
}
}

class Sorter {
public static void main (String[] args) throws java.lang.Exception {
int max_size = 1500000;
TestComparator comp = new TestComparator();

for (int total = 0; total < max_size; total += 2048 * 16) {
Test[] array1 = new Test[total];
Test[] array2 = new Test[total];

for (int index = 0; index < total; index++) {
Test item = new Test();

item.value = SortRandom.nextInt();
item.index = index;

array1[index] = item;
array2[index] = item;
}

double time1 = System.currentTimeMillis();
Merge.BottomUp(array1, comp);
time1 = System.currentTimeMillis() - time1;

double time2 = System.currentTimeMillis();
Merge.Recursive(array2, comp);
time2 = System.currentTimeMillis() - time2;

if (time1 >= time2)
System.out.format("%f%% as fast\n", time2/time1 * 100.0);
else
System.out.format("%f%% faster\n", time2/time1 * 100.0 - 100.0);

System.out.println("verifying...");
for (int index = 0; index < total; index++) {
if (comp.compare(array1[index], array2[index]) != 0) throw new Exception();
if (array2[index].index != array1[index].index) throw new Exception();
}
System.out.println("correct!");
}
}
}
``````

And here's a C++ version:

``````#include <iostream>
#include <cassert>
#include <cstring>
#include <ctime>

class Test {
public:
size_t value, index;
};

bool TestCompare(Test item1, Test item2) {
return (item1.value < item2.value);
}

namespace Merge {
template <typename T, typename Comparison>
void Merge(T array[], int start, int mid, int end, Comparison compare, T buffer[]) {
std::copy(&array[start], &array[mid], &buffer[0]);
int A_count = 0, B_count = 0, insert = 0;
while (A_count < (mid - start) && B_count < (end - mid)) {
if (!compare(array[mid + B_count], buffer[A_count]))
array[start + insert++] = buffer[A_count++];
else
array[start + insert++] = array[mid + B_count++];
}
std::copy(&buffer[A_count], &buffer[mid - start], &array[start + insert]);
}

template <typename T, typename Comparison>
void SortR(T array[], int start, int end, T buffer[], Comparison compare) {
if (end - start <= 2) {
if (end - start == 2)
if (compare(array[end - 1], array[start]))
std::swap(array[start], array[end - 1]);
return;
}

int mid = start + (end - start)/2;
SortR(array, start, mid, buffer, compare);
SortR(array, mid, end, buffer, compare);
Merge(array, start, mid, end, compare, buffer);
}

template <typename T, typename Comparison>
void Recursive(T array[], int size, Comparison compare) {
T *buffer = new T[size];
SortR(array, 0, size, buffer, compare);
delete[] buffer;
}

template <typename T, typename Comparison>
void BottomUp(T array[], int size, Comparison compare) {
T *buffer = new T[size];

for (int index = 0; index < size - 1; index += 2) {
if (compare(array[index + 1], array[index]))
std::swap(array[index], array[index + 1]);
}

for (int length = 2; length < size; length += length)
for (int index = 0; index < size - length; index += length + length)
Merge(array, index, index + length, std::min(index + length + length, size), compare, buffer);

delete[] buffer;
}
}

int main() {
srand(time(NULL));
int max_size = 1500000;
for (int total = 0; total < max_size; total += 2048 * 16) {
Test *array1 = new Test[total];
Test *array2 = new Test[total];

for (int index = 0; index < total; index++) {
Test item;
item.value = rand();
item.index = index;

array1[index] = item;
array2[index] = item;
}

double time1 = clock() * 1.0/CLOCKS_PER_SEC;
Merge::BottomUp(array1, total, TestCompare);
time1 = clock() * 1.0/CLOCKS_PER_SEC;

double time2 = clock() * 1.0/CLOCKS_PER_SEC;
Merge::Recursive(array2, total, TestCompare);
time2 = clock() * 1.0/CLOCKS_PER_SEC;

if (time1 >= time2)
std::cout << time2/time1 * 100.0 << "% as fast" << std::endl;
else
std::cout << time2/time1 * 100.0 - 100.0 << "% faster" << std::endl;

std::cout << "verifying... ";
for (int index = 0; index < total; index++) {
assert(array1[index].value == array2[index].value);
assert(array2[index].index == array1[index].index);
}
std::cout << "correct!" << std::endl;

delete[] array1;
delete[] array2;
}
return 0;
}
``````

The differences aren't as drastic as the original versions, but the C++ iterative version is faster while the Java iterative version is slower.

(and yeah, I realize these versions kinda suck and allocate more memory than is used)

Update 2: When I switched the bottom-up merge sort over to a postorder traversal, which closely matches the order of array accesses in the recursive version, it finally started running about 10% faster than the recursive version. So it looks like it has to do with cache misses and not micro-benchmarks or an unpredictable JVM.

The reason it only affects the Java version may be because Java lacks the custom value types used in the C++ version. I'll allocate all of the Test classes separately in the C++ version and see what happens to the performance. The sorting algorithm I'm working on can't be easily adapted to this type of traversal, but if the performance tanks in the C++ version too I might not have much of a choice.

Update 3: Nope, switching the C++ version over to allocated classes did not seem to have any appreciable effect on its performance. It sure seems like it's caused by something with Java specifically.

• c and c++ will generally run faster tham Java because they aren't running on top of the JVM. Commented Apr 16, 2014 at 23:15
• The C++ version of a bottom-up sort is 50% faster than the C++ version of a recursive sort, and the Java version of the bottom-up sort is twice as slow as the Java version of a recursive sort. Commented Apr 16, 2014 at 23:17
• It depends on your machine architecture and your JVM. There might be few other factors as well Commented Apr 16, 2014 at 23:18
• How many times do you invoke `sort()` for measurement? If you do it only once, I guess it's JIT: in recursive version `sort()` gets compiled by JIT because it's invoked multiple times, whereas in bottom-up version it doesn't. Commented Apr 16, 2014 at 23:57
• About 25 times or so, although the number of iterations doesn't seem to matter. Commented Apr 17, 2014 at 0:02

Interesting question. I couldn't figure out why bottomUp version is slower than recursive, while with array size of power of two they work identicaly.

At least bottomUp is slower just a bit, not twice.

``````Benchmark                             Mode          Mean   Mean error    Units
RecursiveVsBottomUpSort.bottomUp      avgt        64.436        0.376    us/op
RecursiveVsBottomUpSort.recursive     avgt        58.902        0.552    us/op
``````

Code:

``````@OutputTimeUnit(TimeUnit.MICROSECONDS)
@BenchmarkMode(Mode.AverageTime)
@Warmup(iterations = 5, time = 1)
@Measurement(iterations = 10, time = 1)
@Fork(1)
public class RecursiveVsBottomUpSort {

static final int N = 1024;
int[] a = new int[N];
int[] aux = new int[N];

@Setup(Level.Invocation)
public void fill() {
Random r = ThreadLocalRandom.current();
for (int i = 0; i < N; i++) {
a[i] = r.nextInt();
}
}

@GenerateMicroBenchmark
public static int bottomUp(RecursiveVsBottomUpSort st) {
int[] a = st.a, aux = st.aux;
int N = a.length;
for (int n = 1; n < N; n = n + n) {
for (int i = 0; i < N - n; i += n + n) {
merge(a, aux, i, i + n - 1, Math.min(i + n + n - 1, N - 1));
}
}
return a[N - 1];
}

@GenerateMicroBenchmark
public static int recursive(RecursiveVsBottomUpSort st) {
sort(st.a, st.aux, 0, N - 1);
return st.a[N - 1];
}

static void sort(int[] a, int[] aux, int lo, int hi) {
if (lo == hi)
return;
int mid = lo + (hi - lo) / 2;
sort(a, aux, lo, mid);
sort(a, aux, mid + 1, hi);
merge(a, aux, lo, mid, hi);
}

static void merge(int[] a, int[] aux, int lo, int mid, int hi) {
System.arraycopy(a, lo, aux, lo, mid + 1 - lo);

for (int j = mid+1; j <= hi; j++)
aux[j] = a[hi-j+mid+1];

int i = lo, j = hi;
for (int k = lo; k <= hi; k++)
if (aux[j] < aux[i]) a[k] = aux[j--];
else                      a[k] = aux[i++];
}
}
``````