# Calculating vs. lookup tables for sine value performance?

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Let's say you had to calculate the sine (cosine or tangent - whatever) where the domain is between 0.01 and 360.01. (using C#)

What would be more performant?

1. Using Math.Sin
2. Using a lookup array with precalculated values

I would anticpate that given the domain, option 2 would be much faster. At what point in the precision of the domain (0.0000n) does the performance of the calculation exceed the lookup.

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To calculate 360000 different sinus values here takes about 35 milliseconds... on a single thread. (AMD Quadcore 3 Ghz.) Are you calculating that much that this is a performace issue? Could you spread the work over multiple threads (and CPU cores)? – Jeroen Landheer Sep 5 '09 at 3:34
the application is non-trivial math... we need to implement fourier transorm of spectral signals - e.g. nuclear magnetic resonance. there could be 10^5-10^8 measurements... it seemed to be wasteful to recalculate the same value multiple times... – mson Sep 5 '09 at 7:08
There is a similar question here with some more choices: stackoverflow.com/questions/1164492/sine-table-interpolation – Nosredna Sep 5 '09 at 14:17
@mson: I'm glad you asked this question. I have a Windows Mobile app that does FFT on WAV files in order to render a particular type of visualization, and it looks like using an array-based approximation for the Sin function will speed this operation up by a huge factor (see my comment about testing this on a WinMo device). Approximating like this for audio purposes wouldn't work (it would generate too much noise), but for visualization purposes it's perfect. – MusiGenesis Sep 5 '09 at 16:56
@MusiGenesis, my sine approximation does not use a LUT, can be done inline, is usually fast enough, and the highest noise peak is 70dB below the signal. It was design for audio. Not promising it will work, of course. :-) musicdsp.org/showArchiveComment.php?ArchiveID=241 – Nosredna Sep 5 '09 at 18:19

Update: read through to the end. It looks like the lookup table is faster than Math.Sin after all.

I would guess that the lookup approach would be faster than Math.Sin. I would also say that it would be a lot faster, but Robert's answer made me think that I would still want to benchmark this to be sure. I do a lot of audio buffer processing, and I've noticed that a method like this:

``````for (int i = 0; i < audiodata.Length; i++)
{
audiodata[i] *= 0.5;
}
``````

will execute significantly faster than

``````for (int i = 0; i < audiodata.Length; i++)
{
audiodata[i] = Math.Sin(audiodata[i]);
}
``````

If the difference between Math.Sin and a simple multiplication is substantial, I would guess that the difference between Math.Sin and a lookup would also be substantial.

I dunno, though, and my computer with Visual Studio is in the basement, and I'm too tired to take the 2 minutes it would take to determine this.

Update: OK, it took more than 2 minutes (more like 20) to test this, but it looks like Math.Sin is at least twice as fast as a lookup table (using a Dictionary). Here's the class that does Sin using Math.Sin or a lookup table:

``````public class SinBuddy
{
private Dictionary<double, double> _cachedSins
= new Dictionary<double, double>();
private const double _cacheStep = 0.01;
private double _factor = Math.PI / 180.0;

public SinBuddy()
{
for (double angleDegrees = 0; angleDegrees <= 360.0;
angleDegrees += _cacheStep)
{
double angleRadians = angleDegrees * _factor;
}
}

public double CacheStep
{
get
{
return _cacheStep;
}
}

public double SinLookup(double angleDegrees)
{
double value;
if (_cachedSins.TryGetValue(angleDegrees, out value))
{
return value;
}
else
{
throw new ArgumentException(
String.Format("No cached Sin value for {0} degrees",
angleDegrees));
}
}

public double Sin(double angleDegrees)
{
double angleRadians = angleDegrees * _factor;
}
}
``````

And here's the test/timing code:

``````SinBuddy buddy = new SinBuddy();

System.Diagnostics.Stopwatch timer = new System.Diagnostics.Stopwatch();
int loops = 200;

// Math.Sin
timer.Start();
for (int i = 0; i < loops; i++)
{
for (double angleDegrees = 0; angleDegrees <= 360.0;
angleDegrees += buddy.CacheStep)
{
double d = buddy.Sin(angleDegrees);
}
}
timer.Stop();
MessageBox.Show(timer.ElapsedMilliseconds.ToString());

// lookup
timer.Start();
for (int i = 0; i < loops; i++)
{
for (double angleDegrees = 0; angleDegrees <= 360.0;
angleDegrees += buddy.CacheStep)
{
double d = buddy.SinLookup(angleDegrees);
}
}
timer.Stop();
MessageBox.Show(timer.ElapsedMilliseconds.ToString());
``````

Using a step value of 0.01 degrees and looping through the full range of values 200 times (as in this code) takes about 1.4 seconds using Math.Sin, and about 3.2 seconds using a Dictionary lookup table. Lowering the step value to 0.001 or 0.0001 makes the lookup perform even worse against Math.Sin. Also, this result is even more in favor of using Math.Sin, since SinBuddy.Sin does a multiplication to turn the angle in degrees into the angle in radians on every call, while SinBuddy.SinLookup just does a straight lookup.

This is on a cheap laptop (no dual cores or anything fancy). Robert, you da man! (But I still think I should get the check, coz I did the work).

Update 2: OK, I am thoroughly retarded. It turns out stopping and restarting the Stopwatch doesn't reset the elapsed milliseconds, so the lookup only seemed half as fast because it's time was including the time for the Math.Sin calls. Also, I reread the question and realized you were talking about caching the values in a simple array, rather than using a Dictionary. Here is my modified code (I'm leaving the old code up as a warning to future generations):

``````public class SinBuddy
{
private Dictionary<double, double> _cachedSins
= new Dictionary<double, double>();
private const double _cacheStep = 0.01;
private double _factor = Math.PI / 180.0;

private double[] _arrayedSins;

public SinBuddy()
{
// set up dictionary
for (double angleDegrees = 0; angleDegrees <= 360.0;
angleDegrees += _cacheStep)
{
double angleRadians = angleDegrees * _factor;
}

// set up array
int elements = (int)(360.0 / _cacheStep) + 1;
_arrayedSins = new double[elements];
int i = 0;
for (double angleDegrees = 0; angleDegrees <= 360.0;
angleDegrees += _cacheStep)
{
double angleRadians = angleDegrees * _factor;
i++;
}
}

public double CacheStep
{
get
{
return _cacheStep;
}
}

public double SinArrayed(double angleDegrees)
{
int index = (int)(angleDegrees / _cacheStep);
return _arrayedSins[index];
}

public double SinLookup(double angleDegrees)
{
double value;
if (_cachedSins.TryGetValue(angleDegrees, out value))
{
return value;
}
else
{
throw new ArgumentException(
String.Format("No cached Sin value for {0} degrees",
angleDegrees));
}
}

public double Sin(double angleDegrees)
{
double angleRadians = angleDegrees * _factor;
}
}
``````

And the test/timing code:

``````SinBuddy buddy = new SinBuddy();

System.Diagnostics.Stopwatch timer = new System.Diagnostics.Stopwatch();
int loops = 200;

// Math.Sin
timer.Start();
for (int i = 0; i < loops; i++)
{
for (double angleDegrees = 0; angleDegrees <= 360.0;
angleDegrees += buddy.CacheStep)
{
double d = buddy.Sin(angleDegrees);
}
}
timer.Stop();
MessageBox.Show(timer.ElapsedMilliseconds.ToString());

// lookup
timer = new System.Diagnostics.Stopwatch();
timer.Start();
for (int i = 0; i < loops; i++)
{
for (double angleDegrees = 0; angleDegrees <= 360.0;
angleDegrees += buddy.CacheStep)
{
double d = buddy.SinLookup(angleDegrees);
}
}
timer.Stop();
MessageBox.Show(timer.ElapsedMilliseconds.ToString());

// arrayed
timer = new System.Diagnostics.Stopwatch();
timer.Start();
for (int i = 0; i < loops; i++)
{
for (double angleDegrees = 0; angleDegrees <= 360.0;
angleDegrees += buddy.CacheStep)
{
double d = buddy.SinArrayed(angleDegrees);
}
}
timer.Stop();
MessageBox.Show(timer.ElapsedMilliseconds.ToString());
``````

These results are quite different. Using Math.Sin takes about 850 milliseconds, the Dictionary lookup table takes about 1300 milliseconds, and the array-based lookup table takes about 600 milliseconds. So it appears that a (properly-written [gulp]) lookup table is actually a bit faster than using Math.Sin, but not by much.

Please verify these results yourself, since I have already demonstrated my incompetence.

-
c'mon quit being lazy... i'm trying to be lazy here... – mson Sep 5 '09 at 3:40
It's not just laziness - the cat's litter box down there is full, too. Although I guess that's just more laziness on my part. – MusiGenesis Sep 5 '09 at 3:52
this should be the selected answer. – San Jacinto Sep 5 '09 at 16:19
Ok, I did run your benchmarks, but without all the chaff: no separate class to encapsulate the lookup table, not method calls, no conversion from double to int etc. The benchmark with table lookups then takes 15ms and the benchmark computing sines takes 415ms (on a 3.0 Ghz Pentium III). So the problem with your benchmark is that it measures a lot of overhead. The problem with my benchmark (as others already pointed out) is that during the whole benchmark the lookup table sits nicely in the cache. Both benchmarks are too simple. – Accipitridae Sep 5 '09 at 18:04
@Accipitridae, good work. That's exactly why if you need the speed, you write the code twice and test it in situ. Benchmarks can only give a hint. My experience in real-world dsp apps (where my code is a dll running in a host that reports the %time I'm using up) is library sin() is not usable, but it's always worth testing to be sure. – Nosredna Sep 5 '09 at 18:11

It used to be that an array lookup was a good optimization to perform fast trig calculations.

But with cache hits, built-in math coprocessors (which use table lookups) and other performance improvements, it might be best to time your specific code yourself to determine which will perform better.

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i would guess that a lookup takes much less processing than actually calculating a sin value. are you certain that calculating the sin(90.00001) is faster than reading sin(90.0) as 0 from a small array? a priori - it seems like baloney... – mson Sep 5 '09 at 3:15
I used to use memoization (tabling) all the time to speed up graphic routines (lots of sines/cosines). When they added math co-processors to the CPU (which use table look-ups) the calculations could all be done in hardware and became less of an issue. Now, with on board-caches, smaller code blocks can give you a significant performance boost. If the of memory used to store the table causes cache misses, the performance loss can be significant. It's not a clear-cut issue anymore. You almost have to test your specific code to find out. – Robert Cartaino Sep 5 '09 at 3:24
mson, read this answers main point: Measure. – Henk Holterman Sep 5 '09 at 11:40
+1 to Robert for suggesting you write it both ways and test. – Nosredna Sep 5 '09 at 15:26
For my DSP uses, the built in sin is only my choice in initialization code, never during run-time. Instead, I use LUTs and various approximations. I have to decide for each application which is the better choice. – Nosredna Sep 5 '09 at 15:28

For performance questions, the only right answer is the one you reach after testing. But, before you test, you need to determine whether the effort of the test is worth your time - meaning that you've identified a performance issue.

If you're just curious, you can easily write a test to compare the speeds. However, you'll need to remember that using memory for the lookup table can affect paging in larger apps. So, even if paging is faster in your small test, it could slow things down in a larger app that uses more memory.

-

The answer to this depends entirely on how many values are in your lookup table. You say "the domain is between 0.01 and 360.01", but you don't say how many values in that range might be used, or how accurate you need the answers to be. Forgive me for not expecting to see significant digits used to convey implicit meaning in a non-scientific context.

More information is still needed to answer this question. What is the expected distribution of values between 0.01 and 360.01? Are you processing a lot of data other than the simple sin( ) computation?

36000 double precision values takes over 256k in memory; the lookup table is too large to fit in L1 cache on most machines; if you're running straight through the table, you'll miss L1 once per sizeof(cacheline)/sizeof(double) accesses, and probably hit L2. If, on the other hand, your table accesses are more or less random, you will be missing L1 almost every time you do a lookup.

It also depends a lot on the math library of the platform that you're on. Common i386 implementations of the sin function, for example, range from ~40 cycles up to 400 cycles or even more, depending on your exact microarchitecture and library vendor. I haven't timed the Microsoft library, so I don't know exactly where the C# Math.sin implementation would fall.

Since loads from L2 are generally faster than 40 cycles on a sane platform, one reasonably expects the lookup table to be faster considered in isolation. However, I doubt you're computing sin( ) in isolation; if your arguments to sin( ) jump all over the table, you will be blowing other data needed for other steps of your computation out of the cache; although the sin( ) computation gets faster, the slowdown to other parts of your computation may more than outweigh the speedup. Only careful measurement can really answer this question.

Am I to understand from your other comments that you're doing this as part of a FFT computation? Is there a reason that you need to roll your own FFT instead of using one of the numerous extremely high quality implementations that already exist?

-
here is a link about significant digits... en.wikipedia.org/wiki/Significant_figures – mson Sep 5 '09 at 7:03
I also do not interpret significant figures to have any significance to the question. In programming contexts, unless otherwise specified, the precision of a number is determined by its type. – recursive Sep 5 '09 at 18:17

Since you mention Fourier transforms as an application, you might also consider to compute your sines/cosines using the equations

sin(x+y) = sin(x)cos(y) + cos(x)sin(y)

cos(x+y) = cos(x)cos(y) - sin(x)sin(y)

I.e. you can compute sin(n * x), cos(n * x) for n = 0, 1, 2 ... iteratively from sin((n-1) * x), cos((n-1) * x) and the constants sin(x), cos(x) with 4 multiplications. Of course that only works if you have to evaluate sin(x), cos(x) on an arithmetic sequence.

Comparing the approaches without the actual implementation is difficult. It depends a lot on how well your tables fit into the caches.

-
 I've see this approach used in oscillators. It's a good one. – Nosredna Sep 5 '09 at 14:46 I tried this once for an FFT implementation, which is one application the OP mentions. I still used tables in the end because the result needed not to be precise and hence a small table was enough. – Accipitridae Sep 5 '09 at 16:52 Synth that uses phasor rotation: tutututututu.de/synths/dsfsynthesis/dsfsynthesis.html – Nosredna Sep 5 '09 at 17:52 Nice. Thanks a lot. – Accipitridae Sep 5 '09 at 21:46

Math.Sin is faster. The people who wrote are smart and use table lookups when they are accurate and faster and use the math when that is faster. And there's nothing about that domain that makes it particularily faster, the first thing most trig function implementations do is to map down to a favorable domain anyway.

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a domain of 36000 possible values being looked up is much different than a domain of 360000000000000 values. – mson Sep 5 '09 at 3:11
Not every situation needs the same precision. The people who wrote the functions are smart but not magical. – Nosredna Sep 5 '09 at 14:41
Ah, I see, you were talking about the precision of the Domain, not its range. – RBarryYoung Sep 6 '09 at 2:12
Hmm, that is, the Domain's precision, rather the Domain's range. – RBarryYoung Sep 6 '09 at 2:22

As you may have thousands of values in your lookup table, what you may want to do is have a dictionary, and when you calculate a value, put it in the dictionary, so you only calculate each value one time, and use the C# function to do the calculation.

But, there is no reason to recalculate the same value over and over.

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You have to be careful with that. In some cases a dictionary lookup could be slower than the sin calculation. – Nosredna Sep 5 '09 at 14:15
The only way to know is by profiling to see where it starts to be a problem. For example, if you are using WindowsCE then you may find the sin calculation to be much slower, but there is no one solution for all hardware. – James Black Sep 5 '09 at 16:08
A dictionary could, on some systems, beat a library sin(), but it's hard to imagine it beating an array unless the array is implemented as a dictionary. Agreed that you must implement and time to be sure. – Nosredna Sep 5 '09 at 16:29
@Nosrenda, in reference to your first comment on this answer: you also have to be careful because your sine calculator could be slower than a hash function... what was the point in commenting that? – San Jacinto Sep 5 '09 at 20:28
My point is that you can't make the assumption that avoiding calculation with a dictionary will speed it up. You have to try it and test it. Saying, "there's no reason to recalculate the same value over and over" is not necessarily true, because sometimes it's faster to do exactly that. – Nosredna Sep 5 '09 at 20:41