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I'm writing a module that accepts some data from a spectrometer via a serial port and needs to decode it. The spectral data is encoded as 512-bytes in repeating unsigned MSB and LSB 8-bit words according to the manual. How would I decode this in C/C++?

23 – 534 encoded as 512-bytes in repeating unsigned MSB and LSB 8-bit words [MSB]*256 + [LSB].

That's a snippet from the manual.

Okay, I'd like to add in another portion to this question. According to a comment below, this is in big-endian. Now, what I'm confused about it is that if it indeed is in big-endian, wouldn't conversion to little-endian be as simple as reversing the order of all the bytes? And if that is the case, then the output to that would essentially be something like... LSB5, MSB5, LSB4, MSB4, LSB3, MSB3, LSB2, MSB2, LSB1, MSB1 and so on, which could then be converted to 16-bit words. What is it that I'm going wrong with here?

Also, if this is indeed big-endian, aren't there any native (even platform-specific if necessary, but faster) methods to handle the conversion?

share|improve this question
Isn't this format precisely 16-bit unsigned big-endian? – Iwillnotexist Idonotexist Dec 14 '13 at 2:48
I don't quite understand the format of the data as you explained it. Am I right in saying that from bytes 23 to 534 of a frame there are 256 sixteen-bit-wide ( = 2 byte) samples? If so, then there are only two ways the two bytes of each sample could be arranged in. Either the LSB comes first in the byte stream, or the MSB does. The former case is little-endian and the latter case is big-endian. So far I've understood the MSB comes first, so that would make the samples big-endian. To decode them on little-endian x86 machines, you would have to byteswap individually all 256 samples. – Iwillnotexist Idonotexist Dec 22 '13 at 22:21
As for "native" functions, if you're on GCC you may use the built-in function uint16_t __builtin_bswap16 (uint16_t x), for which no includes are needed, and if you're using Visual Studio you may use unsigned short _byteswap_ushort(unsigned short val), provided you #include <stdlib.h>. – Iwillnotexist Idonotexist Dec 22 '13 at 22:29
For something so simple as byteswapping any decent compiler can probably detect shifts-and-OR implementations and substitute in the BSWAP instruction. Using those builtins merely makes it clearer to the reader and compiler, which might optimize better as a result. – Iwillnotexist Idonotexist Dec 25 '13 at 18:36
Endianness controls only the order of the bytes within a sample, not the order of the samples within the frame. Thus a little-endian 16-bit stream resembles [LSB0][MSB0] [LSB1][MSB1] [LSB2][MSB2] [LSB3][MSB3] [LSB4][MSB4]... while a big-endian 16-bit stream resembles [MSB0][LSB0] [MSB1][LSB1] [MSB2][LSB2] [MSB3][LSB3] [MSB4][LSB4]... – Iwillnotexist Idonotexist Dec 25 '13 at 19:09
up vote 5 down vote accepted

I'm an over-optimizer sometimes, so even though Fiddling Bits has provided a perfectly adequate solution, it has unneeded divides and unneeded branches. So I'll serve up a redundant answer here.

uint8_t byteArray[512];
uint16_t wordArray[256], word, byteIdx, wordIdx;

for (byteIdx=0, wordIdx=0; byteIdx < 511; )
    word = byteArray[byteIdx++] << 8;
    wordArray[wordIdx++] = word | byteArray[byteIdx++]

The key concept is to shift the MSB byte up 8 bits (x<<8 is equivalent to x*256) then or/add it to the LSB to form the 16-bit word. The rest is all index management.

share|improve this answer
Well played! I always appreciate optimization. – Fiddling Bits Dec 14 '13 at 14:30
Thank you so much! – Siddharth Dec 15 '13 at 9:56

You'd need to store the MSB and LSB into a single word. For example:

uint8_t msb, lsb;
uint16_t word;

word = (msb << 8) | lsb;

A loop of this would look something like this:

uint8_t byteArray[512];
uint16_t wordArray[256], byteArrIdx;

for(byteArrIdx = 0; byteArrIdx < 512; byteArrIdx++)
    if((byte % 2) == 0)
        wordArray[(byteArrIdx / 2)] = byteArray[byteArrIdx] << 8;
        wordArray[(byteArrIdx / 2)] |= byteArray[byteArrIdx];


The output of msb << 8 and msb * 256 is identical. I prefer using bit shifting because your intentions are more clear to the reader.

share|improve this answer
You've earned your name for today. But why didn't you use byte & 1 instead of byte % 2? P.S. byte needs to be something bigger than uint8_t in your code sample. – Mark Ransom Dec 13 '13 at 19:41
@MarkRansom Are you sure a bigger type is necessary? The OP describes the data as unsigned MSB and LSB 8-bit words. – Fiddling Bits Dec 13 '13 at 19:42
512 is much greater than 255, the for loop will never terminate. – Casey Dec 13 '13 at 19:43
@MarkRansom Why would he use the bitwise and when he wants to test for every n-th byte? The modulo operator is better conceptually. – user529758 Dec 13 '13 at 19:44
You're using byte as an index into an array. Perhaps it would have been better to choose a different name. – Mark Ransom Dec 13 '13 at 19:44

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