# Efficiently converting array of 24-bit ints to floats or doubles in C#

I have an array of interleaved signed 24-bit ints (complex numbers) in little endian order that I would like to convert to a complex array of floats or doubles. By interleaved, I mean:

R1 R2 R3 I1 I2 I3 R4 R5 R6 I4 I5 I6 . . .

Where each item is an 8-bit byte, and each three together are a 24-bit int, with R = real and I = imaginary.

What's the most efficient way to do this in C#? The code has to run many times, so I'm trying to squeeze every last cycle out of it I can. I'm hoping for something more efficient than a brute force shift, or and cast.

I wouldn't mind using unsafe code in this case, if it would help.

Here's the baseline, brute-force approach with the second number of the pair commented out, and with sign handling ignored for the moment, to simplify the IDL:

class Program
{
const int Size = 10000000;
static void Main(string[] args)
{
//
// Array of little-endian 24-bit complex ints
// (least significant byte first)
//
byte[] buf = new byte[3 * 2 * Size];
float[] real = new float[Size];
//float[] imag = new float[Size];

//
// The brute-force way
//
int j = 0;
Stopwatch timer = new Stopwatch();
timer.Start();
for (int i = 0; i < Size; i++)
{
real[i] = (float)(buf[j] | (buf[j + 1] << 8) | (buf[j + 2] << 16));
j += 3;
// imag[i] = (float)(buf[j] | (buf[j + 1] << 8) | (buf[j + 2] << 16));
j += 3;
}
timer.Stop();
Console.WriteLine("result = " +
(float)(timer.ElapsedMilliseconds * 1000.0f / Size) +
" microseconds per complex number");
}
}

and the associated IDL:

IL_0024:  ldc.i4.0
IL_0025:  stloc.s    i
IL_0027:  br.s       IL_0050
IL_0029:  ldloc.1
IL_002a:  ldloc.s    i
IL_002c:  ldloc.0
IL_002d:  ldloc.2
IL_002e:  ldelem.u1
IL_002f:  ldloc.0
IL_0030:  ldloc.2
IL_0031:  ldc.i4.1
IL_0033:  ldelem.u1
IL_0034:  ldc.i4.8
IL_0035:  shl
IL_0036:  or
IL_0037:  ldloc.0
IL_0038:  ldloc.2
IL_0039:  ldc.i4.2
IL_003b:  ldelem.u1
IL_003c:  ldc.i4.s   16
IL_003e:  shl
IL_003f:  or
IL_0040:  conv.r4
IL_0041:  stelem.r4
IL_0042:  ldloc.2
IL_0043:  ldc.i4.3
IL_0045:  stloc.2
IL_0046:  ldloc.2
IL_0047:  ldc.i4.3
IL_0049:  stloc.2
IL_004a:  ldloc.s    i
IL_004c:  ldc.i4.1
IL_004e:  stloc.s    i
IL_0050:  ldloc.s    i
IL_0052:  ldc.i4     0x989680
IL_0057:  blt.s      IL_0029
-
As long as the bytes live in memory you'll be forced to perform the shifts anyway (whether you do it in your code or the framework works some magic). There are very few constructs in .NET (or even C++) to help you perform this any more quickly than doing the bit shifting manually. – M.Babcock Jul 18 '13 at 4:17
In C or C++, I could use pointers, and copy the three bytes into the lower 32-bits of a union of a float and an int or array of 4 bytes (leaving the mantissa zero) -- or maybe copy all 4 at once as an int, if the alignment is right. That would avoid the multiplies that come with array indexing, the shifts, and the cast. – RickNZ Jul 18 '13 at 4:52
The only random suggestion is to try unpack 12 bytes in iteration so you can just deal with int32 value all the way... – Alexei Levenkov Jul 18 '13 at 4:52
@RickNZ - I'm not sure all of those byte copies would be more efficient than a processor-optimized bit shift (IO is IO after all). If you're looking for a less code intensive solution - that will for sure work. Otherwise, I'd recommend some profiling. It almost sounds like premature optimization to me. – M.Babcock Jul 18 '13 at 4:56
@RickNZ - On second thought, depending the quantities you're talking about, the memory copies have the potential to become a detrimental bottleneck in your application (assuming this is a detrimental part of the system). If you're looking for throughput then you're absolutely better off reading the bytes as they lay rather than wasting conversion space and time. I'm still 99% sure this is premature optimization for a .NET app but I'm sure this will produce more scalable results. – M.Babcock Jul 18 '13 at 5:09

No solution can be faster than shifting. Using memcpy would cost you a function call which is much slower because of many other consequences such as stack push/pop, jump... And it won't save you from multiplying to get the index. Ofcourse you can increase the pointer by 3 and don't need the multiply but using the solution @Alexei Levenkov said it only need to increase the pointer after each loop by 12 bytes and no multiply is needed at all.

unsigned int *data;
unsigned int i = 0;
unsigned int real[SIZE], imag[SIZE];

for (data = dataIn; data != dataIn + size; data += 3)
{
// D1--------- D2--------- D3---------
// R1 R2 R3 I1 I2 I3 R4 R5 R6 I4 I5 I6
real[i] = data[0] >> 8;
imag[i] = ((data[0] & 0xff) << 16) | (data[1] >> 16);
real[i + 1] = ((data[1] & 0xffff) << 8) | (data[2] >> 24);
imag[i + 1] = data[2] & 0xffffff;
i++;
}

if the size is not a multiple of 12 then the remaining bytes will be extracted at the end, outside the loop.

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