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I have an NSArray of 100 numbers. I would like to create an NSArray of 5 numbers. The first number in the second array is the average of the first 20 numbers in the first array. The second number is the average of the second set of 20 numbers in the first array. And so on.

I'm curious to hear people's ideas for an efficient algorithm.

One idea I had was to do a for-loop on each set of 20 numbers, creating a temp NSArray of 20 numbers. Then perform a KVO average operation and add to the final NSArray.

Note: I always award THE answer to someone, and I'm not shy to up vote your answers. I encourage many answers. Thanks!

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3  
I entirely miss the point of using KVO here.... –  Till Feb 17 '13 at 21:07
3  
It's simple -- write code. Any "fancy" scheme you might come up with using KVO or whatever is guaranteed to be slower and more obscure. Unless this is an entry into an obscure code contest or some such, just write the code! –  Hot Licks Feb 17 '13 at 21:09
    
@Till, maddy just explained to me that KVO is not the same as key-value coding. Now I understand your comment. Thanks for your comment. –  Edward Chin Feb 18 '13 at 1:07

3 Answers 3

up vote 1 down vote accepted

The following is simple and efficient:

NSArray *numbers = ... // array of 100 numbers
NSMutableArray *averages = [NSMutableArray array];

for (int = 0; i < 5; i++) {
    float total = 0.0;
    int base = i * 20;
    for (int j = 0; j < 20; j++) {
        float num = [numbers[base + j] floatValue];
        total += num;
    }

    float avg = total / 20.0f;
    [averages addObject:@(avg)];
}

NSLog(@"Averages = %@", averages);
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1  
When it comes to efficiency, one may gain a little by omitting the multiplication by 20 within the inner loop. Not hard to figure how to do that... –  Till Feb 17 '13 at 21:20
1  
Another point, you are using a double value to divide, change the notation to 20.0f to spare another implicit typecast. –  Till Feb 17 '13 at 21:22
1  
@Zaph The @(avg) is shorthand for [NSNumber numberWithFloat:avg]. –  rmaddy Feb 17 '13 at 21:23
1  
Will it make sense to move primitive vars declaration out of the loop as well ? –  A-Live Feb 17 '13 at 21:24
1  
@Zaph Huh? Yes, I calculate the average and store it in a variable. Then I need to store the variable (avg) in the array. Since you can't store a float in an array, you need to wrap the float primitive in an NSNumber. That's what @(avg) does - it wraps the variable avg in an NSNumber object. It's not some magic for calculating an average. –  rmaddy Feb 17 '13 at 21:27

Just add the values in each 20 number section, divide by 20 and put in the appropriate output array location. It is one pass through the array, Big O(n), what more could you ask for? The time to compute this is minuscule.

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you could try something like this...

NSArray *_array = // with the 100 numbers... (I used NSNumber object for each number)

NSMutableArray *_averages = [NSMutableArray array];
for (int i = 0; i < 5; i++) [_averages addObject:@([[[_array subarrayWithRange:NSMakeRange(i * 20, 20)] valueForKeyPath:@"@avg.floatValue"] floatValue])];

the _averages will contain 5 values with the averages of the five different sections of the 100 numbers.

UPDATED:

this part is just for eyes with extra curiosity.

if you tries to avoid the NSObjects and the double for loops, you could achieve a really fast algorithm, and of course when you go lower levels, you can improve the current speed as well, the question is: does it really need?

NSInteger _segments = 1000; // it means 20.000 numbers;
Float64 _numbers[(_segments * 20)]; // fill this array as you'd like.

Float64 _averages[_segments];

for (int i = 0; i < _segments; i++) {
    NSInteger _offset = (_segments<<4)+4;
    _averages[i] = (_numbers[_offset] + _numbers[_offset+1] + _numbers[_offset+2] + _numbers[_offset+3] + _numbers[_offset+4] + _numbers[_offset+5] + _numbers[_offset+6] + _numbers[_offset+7] + _numbers[_offset+8] + _numbers[_offset+9] + _numbers[_offset+10] + _numbers[_offset+11] + _numbers[_offset+12] + _numbers[_offset+13] + _numbers[_offset+14] + _numbers[_offset+15] + _numbers[_offset+16] + _numbers[_offset+17] + _numbers[_offset+18] + _numbers[_offset+19]) / 20.f;
}

it is 10 times faster than the solution with double for loops and NSObject classes.

(un)fortunately, it is not even the ugliest solution, but there is no question it is fast as hell, I won't recommend it except the speed really matter because that kind of solutions can provide really good efficiency.

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1  
@eddieios That isn't KVO (key-value observing), it's key-value coding. –  rmaddy Feb 18 '13 at 0:47
1  
FYI - I profiled this solution against the one in my answer. This code on average took 50 times longer to execute as my solution! Of course this solution was plenty fast enough if you only have 100 numbers and you aren't doing the calculation more than a few times. –  rmaddy Feb 18 '13 at 0:58
    
@maddy, you just taught me 3 things that make me a better programmer. thanks. I also appreciate you taking the time to profile the code. I really like your answers. Pls continue to follow and answer my questions, and I'll be sure to vote up your answers. Thanks again. –  Edward Chin Feb 18 '13 at 1:05
1  
@rmaddy, and if you go lower level, you could get much faster algorithm. there is no pure miracle here. –  holex Feb 18 '13 at 9:15
    
Awesome holex, This is really cool. –  Edward Chin Feb 18 '13 at 16:04

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