# faster implementation of sum ( for Codility test )

How can the following simple implementation of `sum` be faster?

``````private long sum( int [] a, int begin, int end ) {
if( a == null   ) {
return 0;
}
long r = 0;
for( int i =  begin ; i < end ; i++ ) {
r+= a[i];
}
return r;
}
``````

EDIT

Background is in order.

Reading latest entry on coding horror, I came to this site: http://codility.com which has this interesting programming test.

Anyway, I got 60 out of 100 in my submission, and basically ( I think ) is because this implementation of sum, because those parts where I failed are the performance parts. I'm getting TIME_OUT_ERROR's

So, I was wondering if an optimization in the algorithm is possible.

So, no built in functions or assembly would be allowed. This my be done in C, C++, C#, Java or pretty much in any other.

EDIT

As usual, mmyers was right. I did profile the code and I saw most of the time was spent on that function, but I didn't understand why. So what I did was to throw away my implementation and start with a new one.

This time I've got an optimal solution [ according to San Jacinto O(n) -see comments to MSN below - ]

This time I've got 81% on Codility which I think is good enough. The problem is that I didn't take the 30 mins. but around 2 hrs. but I guess that leaves me still as a good programmer, for I could work on the problem until I found an optimal solution:

Here's my result.

I never understood what is those "combinations of..." nor how to test "extreme_first"

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Do you allow inline assembly in C++? – Michael Myers Feb 25 '10 at 23:24
No one can comment on speed unless you explain what language and platform you are using. Like mmyers says, if this is c++ you could inline some assembly. If it's C# the inbuilt Enumerable.Sum() method might be faster, who knows. I'm sure Java has it's own tricks too. – Simon P Stevens Feb 25 '10 at 23:29
@mmyers: Not that much. Most likely in the optimization is on the algorithm part rather than in the implementation part :-/ ( if that even makes sense ) – OscarRyz Feb 25 '10 at 23:29
@Oscar: If assembly is allowed, depending on the target platform, SSE vector instructions could be used to parallelize it. – Michael Myers Feb 25 '10 at 23:30
By the way, when you say "basically ( I think ) is because this implementation of sum", you really mean "I profiled it and found that it's spending 40% of its time in this implementation of sum", right? Because otherwise, this is a fairly pointless exercise. :) – Michael Myers Feb 25 '10 at 23:37

I don't think your problem is with the function that's summing the array, it's probably that you're summing the array WAY to frequently. If you simply sum the WHOLE array once, and then step through the array until you find the first equilibrium point you should decrease the execution time sufficiently.

``````int equi ( int[] A ) {
int equi = -1;

long lower = 0;
long upper = 0;
foreach (int i in A)
upper += i;

for (int i = 0; i < A.Length; i++)
{
upper -= A[i];
if (upper == lower)
{
equi = i;
break;
}
else
lower += A[i];
}

return equi;
}
``````
-
Yeap, that's exactly what I did. Initially I've had was: `if(sum(0,i) == sum(i,end)) return i` but that invoked too many time to `sum` so I change it for: `total = sum(a)` and inside the for: `if( current == total-current ) { return i } ` – OscarRyz Feb 26 '10 at 1:54
changes to int equi = -1; instead of 0 and you'll get a 100/100 with this solution. – Mark Feb 27 '10 at 0:33
D'oh, thanks. Stupid transcription errors. – Guildencrantz Feb 27 '10 at 3:27

If this is based on the actual sample problem, your issue isn't the sum. Your issue is how you calculate the equilibrium index. A naive implementation is O(n^2). An optimal solution is much much better.

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An optimal solution is O(n), as you say. Since the sample is written/tested online, i seriously doubt that it is testing the minutia of pipelining and loop unrolling. – San Jacinto Feb 26 '10 at 0:58
@San, even then this would be dominated by memory accesses as you scale up. :) – MSN Feb 26 '10 at 1:25
MSN, any ideas on an implmentation which is not O(n^2) – SolutionYogi Feb 26 '10 at 1:36
@Solution Yogi: I did it :P ( not knowing exactly how, but I did :P ) I did what I do for work, if I have a working solution and is taking too long, I tweak the solution to yield the same result with different steps and it worked! :) – OscarRyz Feb 26 '10 at 1:48
Oscar, I was so bugged that I could not solve it in O(n). Thinking more about it, finally I also found a way to solve it in O(n). It is satisfying to come up with a solution! :) – SolutionYogi Feb 26 '10 at 1:54

This code is simple enough that unless `a` is quite small, it's probably going to be limited primarily by memory bandwidth. As such, you probably can't hope for any significant gain by working on the summing part itself (e.g., unrolling the loop, counting down instead of up, executing sums in parallel -- unless they're on separate CPUs, each with its own access to memory). The biggest gain will probably come from issuing some preload instructions so most of the data will already be in the cache by the time you need it. The rest will just (at best) get the CPU to hurry up more, so it waits longer.

Edit: It appears that most of what's above has little to do with the real question. It's kind of small, so it may be difficult to read, but, I tried just using `std::accumulate()` for the initial addition, and it seemed to think that was all right:

-
Probably true as the integer units on most processors are so fast now that even SIMD instructions don't do much unless you're crunching a lot of numbers. I suspect the possible pipeline stalls from poorly ordered SSE instructions would slow down the SIMD version enough that it wouldn't offer much speed over the naive solution. – Ron Warholic Feb 25 '10 at 23:45
+1. In D they have vectorized array ops that use SSE instructions. They're nice syntactic sugar, but not any faster than using a plain old loop except for very small arrays. – dsimcha Feb 26 '10 at 0:02

I don't believe the problem is in the code you provided, but somehow the bigger solution must be suboptimal. This code looks good for calculating the sum of one slice of the array, but maybe it's not what you need to solve the whole problem.

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+1 And it wasn't :) – OscarRyz Feb 26 '10 at 1:49

Some tips:

• Use a profiler to identify where you're spending a lot of time.

• Write good performance tests so that you can tell the exact effect of every single change you make. Keep careful notes.

• If it turns out that the bottleneck is the checks to ensure that you're dereferencing a legal address inside the array, and you can guarantee that begin and end are in fact both inside the array, then consider fixing the array, making a pointer to the array, and doing the algorithm in pointers rather than arrays. Pointers are unsafe; they do not spend any time checking to make sure you're still inside the array, so therefore they can be somewhat faster. But you take responsibility then for ensuring that you do not corrupt every byte of memory in the address space.

-

Probably the fastest you could get would be to have your int array 16-byte aligned, stream 32 bytes into two `__m128i` variables (VC++) and call `_mm_add_epi32` (again, a VC++ intrinsic) on the chunks. Reuse one of the chunks to keep adding into it and on the final chunk extract your four ints and add them the old fashioned way.

The bigger question is why simple addition is a worthy candidate for optimization.

Edit: I see it's mostly an academic exercise. Perhaps I'll give it a go tomorrow and post some results...

-

Here is my solution and I scored 100%

`````` public static int solution(int[] A)
{
double sum = A.Sum(d => (double)d);
double leftSum=0;
for (int i = 0; i < A.Length; i++){
if (leftSum == (sum-leftSum-A[i])) {
return i;
}
else {
leftSum = leftSum + A[i];
}
}
return -1;
}
``````
-

In C# 3.0, my computer and my OS this is faster as long as you can guarantee that 4 consecutive numbers won't overflow the range of an int, probably because most additions are done using 32-bit math. However using a better algorithm usually provides higher speed up than any micro-optimization.

Time for a 100 millon elements array:

4999912596452418 -> 233ms (sum)

4999912596452418 -> 126ms (sum2)

``````    private static long sum2(int[] a, int begin, int end)
{
if (a == null) { return 0; }
long r = 0;
int i = begin;
for (; i < end - 3; i+=4)
{
//int t = ;
r += a[i] + a[i + 1] + a[i + 2] + a[i + 3];
}
for (; i < end; i++) { r += a[i]; }
return r;
}
``````
-

I did the same naive implementation and here's my O(n) solution. I did not use the IEnumerable Sum method because it was not available at Codility. My solution still doesn't check for overflow in case the input has large numbers so it's failing that particular test on Codility.

``````using System;
using System.Collections.Generic;
using System.Linq;
using System.Text;

namespace ConsoleApplication2
{
class Program
{
static void Main(string[] args)
{
var list = new[] {-7, 1, 5, 2, -4, 3, 0};
Console.WriteLine(equi(list));
}

static int equi(int[] A)
{
if (A == null || A.Length == 0)
return -1;

if (A.Length == 1)
return 0;

var upperBoundSum = GetTotal(A);
var lowerBoundSum = 0;
for (var i = 0; i < A.Length; i++)
{
lowerBoundSum += (i - 1) >= 0 ? A[i - 1] : 0;
upperBoundSum -= A[i];
if (lowerBoundSum == upperBoundSum)
return i;
}
return -1;
}

private static int GetTotal(int[] ints)
{
var sum = 0;
for(var i=0; i < ints.Length; i++)
sum += ints[i];
return sum;
}
}
}
``````

-
+1 Great!!!... What's that "combinations_of_two" all about? About the "extreme_lange_numbers" is very very easy, just use `long` in the `GetTotal` method instead of `int` and you'll have 100% ;) – OscarRyz Feb 26 '10 at 1:58
I don't know what those cases are about. But I do some initial checks e.g. If Array Length is zero or 1, the code returns equilibrium index right away. May be that's why my average timing is 0.072s where as your average timing is 0.244s. It was a fun exercise, thank you for brining it up! :) – SolutionYogi Feb 26 '10 at 2:21

Here is a thought:

``````private static ArrayList equi(int[] A)
{

//if(A == null) return -1;
{
}

long sum0 = 0, sum1 = 0;
for (int i = 0; i < A.Length; i++) sum0 += A[i];
for (int i = 0; i < A.Length; i++)
{
sum0 -= A[i];
if (i > 0) { sum1 += A[i - 1]; }
//return i;
}
//return -1;
}
``````
-

If you are using C or C++ and develop for modern desktop systems and are willing to learn some assembler or learn about GCC intrinsics, you could use SIMD instructions.

This library is an example of what is possible for `float` and `double` arrays, similar results should be possible for integer arithmetic since SSE has integer instructions as well.

-

In C++, the following:

``````int* a1 = a + begin;
for( int i = end - begin - 1; i >= 0 ; i-- )
{
r+= a1[i];
}
``````

might be faster. The advantage is that we compare against zero in the loop.

Of course, with a really good optimizer there should be no difference at all.

Another possibility would be

``````int* a2 = a + end - 1;
for( int i = -(end - begin - 1); i <= 0 ; i++ )
{
r+= a2[i];
}
``````

here we traversing the items in the same order, just not comparing to `end`.

-
Depending on the processor and cache, this might actually be slower. Fewer instructions does not always equal more speed. – Michael Myers Feb 25 '10 at 23:34
@mmyers: what actually can be slower here? we are traversing the same items, just backwards. – Vlad Feb 25 '10 at 23:36
Prefetchers often assume that memory accesses will be sequential. I don't have time (or sufficiently advanced knowledge) to elaborate, but I think it's a Googleable concept. – Michael Myers Feb 25 '10 at 23:38
@mmyers: ok, look at the second example – Vlad Feb 25 '10 at 23:39
I would be surprised if these make any difference at all – Otto Allmendinger Feb 25 '10 at 23:46

Just some thought, not sure if accessing the pointer directly be faster

``````    int* pStart = a + begin;
int* pEnd = a + end;
while (pStart != pEnd)
{
r += *pStart++;
}
``````
-

At a previous company, we had Intel come by and give us optimization tips. They had one non-obvious and somewhat cool trick. Replace:

``````long r = 0;
for( int i =  begin ; i < end ; i++ ) {
r+= a[i];
}
``````

with

``````long r1 = 0, r2 = 0, r3 = 0, r4 = 0;
for( int i =  begin ; i < end ; i+=4 ) {
r1+= a[i];
r2+= a[i + 1];
r3+= a[i + 2];
r4+= a[i + 3];
}
long r = r1 + r2 + r3 + r4;
// Note: need to be clever if array isn't divisible by 4
``````

Why this is faster: In the original implementation, your variable r is a bottleneck. Every time through the loop, you have to pull data from memory array a (which takes a couple cycles), but you can't do multiple pulls in parallel, because the value of r in the next iteration of the loop depends on the value of r in this iteration of the loop. In the second version, r1, r2, r3, and r4 are independent, so the processor can hyperthread their execution. Only at the very end do they come together.

-
``````{In Pascal + Assembly}
{\$ASMMODE INTEL}
function equi (A : Array of longint; n : longint ) : longint;
var c:Longint;
label noOverflow1;
label noOverflow2;
label ciclo;
label fine;
label Over;
label tot;
Begin
Asm
DEC n
JS over
XOR ECX, ECX   {Somma1}
XOR EDI, EDI   {Somma2}
XOR EAX, EAX
MOV c, EDI
MOV ESI, n
tot:
MOV EDX, A
MOV EDX, [EDX+ESI*4]
PUSH EDX
JNO nooverflow1
nooverflow1:
DEC ESI
JNS tot;
SUB ECX, c
SUB EDI, c
ciclo:
POP EDX
SUB ECX, EDX
CMP ECX, EDI
JE fine
JNO nooverflow2
DEC EDI
nooverflow2:
CMP EAX, n
JA over
INC EAX
JMP ciclo
over:
MOV EAX, -1
fine:
end;
End;
``````
-
+1 for asm, not idea if it sums actually :) – Rytis I Jun 18 '14 at 15:18

100% O(n) solution in C

``````int equi ( int A[], int n ) {

long long sumLeft = 0;
long long sumRight = 0;
int i;

if (n <= 0) return -1;

for (i = 1; i < n; i++)
sumRight += A[i];
i = 0;

do {
if (sumLeft == sumRight)
return i;

sumLeft += A[i];

if ((i+1) < n)
sumRight -= A[i+1];
i++;
} while (i < n);

return -1;
}
``````

Probably not perfect but it passes their tests anyway :)

Can't say I'm a big fan of Codility though - it is an interesting idea, but I found the requirements a little too vague. I think I'd be more impressed if they gave you requirements + a suite of unit tests that test those requirements and then asked you to write code. That's how most TDD happens anyway. I don't think doing it blind really gains anything other than allowing them to throw in some corner cases.

-

I have scored 100% for this one:

``````int equi (int[] A)
{
if (A == null) return -1;

long sum0 = 0, sum1 = 0;

for (int i = 0; i < A.Length; i++) sum0 += A[i];

for (int i = 0; i < A.Length; i++)
{
sum0 -= A[i];
if (i > 0)
{
sum1 += A[i - 1];
}
if (sum1 == sum0) return i;
}
return -1;
}
``````
-
``````private static int equi ( int[] A ) {
if (A == null || A.length == 0)
return -1;
long tot = 0;
int len = A.length;
for(int i=0;i<len;i++)
tot += A[i];
if(tot == 0)
return (len-1);
long partTot = 0;
for(int i=0;i<len-1;i++)
{
partTot += A[i];
if(partTot*2+A[i+1] == tot)
return i+1;
}
return -1;
``````

}

I considered the array as a bilance so if the equilibrium index exist then half of the weight is on the left. So I only compare the partTot (partial total) x 2 with the total weight of the array. the Alg takes O(n) + O(n)

-

100% correctness and performance of this code is tested

``````Private Function equi(ByVal A() As Integer) As Integer
Dim index As Integer = -1
If A.Length > 0 And Not IsDBNull(A) Then
Dim sumLeft As Long = 0
Dim sumRight As Long = ArraySum(A)
For i As Integer = 0 To A.Length - 1
Dim val As Integer = A(i)

sumRight -= val
If sumLeft = sumRight Then
index = i
End If
sumLeft += val
Next
End If

Return index
End Function
``````
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This got me 100% in Javascript:

``````function solution(A) {
if (!(A) || !(Array.isArray(A)) || A.length < 1) {
return -1;
}

if (A.length === 1) {
return 0;
}

var sum = A.reduce(function (a, b) { return a + b; }),
lower = 0,
i,
val;

for (i = 0; i < A.length; i++) {
val = A[i];
if (((sum - lower) - val) === (lower)) {
return i;
}
lower += val;
}

return -1;
}
``````

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