Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I've recently been looking into how BitConverter works and from reading other SO questions I've read that it takes a 'shortcut' when the start index is divisible by the size of the type being converted to where it can just cast a pointer the byte at the index into a pointer to the type being converted to and de-reference it.

Source for ToInt16 as an example:

public static unsafe short ToInt16(byte[] value, int startIndex) {
     if( value == null)  {
          ThrowHelper.ThrowArgumentNullException(ExceptionArgument.value);
     }

     if ((uint) startIndex >= value.Length) {
          ThrowHelper.ThrowArgumentOutOfRangeException(ExceptionArgument.startIndex, ExceptionResource.ArgumentOutOfRange_Index);
     }

     if (startIndex > value.Length -2) {
          ThrowHelper.ThrowArgumentException(ExceptionResource.Arg_ArrayPlusOffTooSmall);
     }
     Contract.EndContractBlock();

     fixed( byte * pbyte = &value[startIndex]) {
          if( startIndex % 2 == 0) { // data is aligned 
              return *((short *) pbyte);
          }
          else {
              if( IsLittleEndian) { 
                   return (short)((*pbyte) | (*(pbyte + 1) << 8)) ;
              }
              else {
                   return (short)((*pbyte << 8) | (*(pbyte + 1)));                        
              }
          }
     }
}

My question is why does this work regardless of the endianness of the machine, and why doesn't it use the same mechanism when the data is not aligned?

An example to clarify:

I have some bytes in buffer that I know are in Big endian format, and I want to read a short value from the array at say, index 5. I also assume that my machine, since it is Windows, uses little endian.

I would use BitConverter like so, by switching the order of my bytes to little endian:

BitConverter.ToInt16(new byte[] { buffer[6], buffer[5] })

assuming the code takes the shortcut it would do what I want: just cast the bytes as they are in the order provided and return the value. But if it didn't have that shortcut code, wouldn't it then reverse the byte order again and give me the wrong value? Or if I instead did:

BitConverter.ToInt16(new byte[] { 0, buffer[6], buffer[5] }, 1)

wouldn't it give me the wrong value since the index is not divisible by 2?

Another situation:

Say I had an array of bytes that contained an short somewhere I want to extract already in little endian format, but starting at an odd offset. Woulnd't the call to BitConverter reverse the order of the bytes since BitConverter.IsLittleEndian is true and the index is not aligned, thus giving me an incorrect value?

share|improve this question
    
It does use the same mechanism when the machine is big endian. It only uses an alternative mechanism when the data isn't aligned. –  Damien_The_Unbeliever Mar 12 '14 at 15:37
    
But why does it matter whether the data is 'aligned' or not? Aren't I just asking BitConverter to convert the bytes starting at the index regardless of the contents? –  mclaassen Mar 12 '14 at 15:45
    
Thanks, that's actually what I meant. Isn't it the responsibility of the caller to have the bytes in the proper order for the endianness of the machine before passing them to BitConverter? –  mclaassen Mar 12 '14 at 15:53

3 Answers 3

up vote 2 down vote accepted

The code avoids a hardware exception on processors that don't allow misaligned data access, a bus error. Which is very expensive, it is usually resolved by kernel code that splits up the bus accesses and glues the bytes together. Such processors were still pretty common around the time that this code was written, the tail-end of the popularity of RISC designs like MIPS. Older ARM cores and Itanium are other examples, .NET versions have been released for all of them.

It makes little difference on processors that don't have a problem with it, like Intel/AMD cores. Memory is slow.

The code uses IsLittleEndian simply because it is indexing the individual bytes. Which of course makes the byte order matter.

share|improve this answer
    
Ok, I get the reason for the misaligned data access, but doesn't BitConverter expect the input array of bytes to be the same endianness as the machine? i.e. shouldn't the code when the index is misaligned just be the case where IsLittleEndian is false? Otherwise if you are passing in an array where everything is already little endian (but your int or whatever is on a misaligned address) and the machine is little endian, it will reverse the bytes giving you the wrong value. –  mclaassen Mar 12 '14 at 16:20
    
Yes, BitConverter requires the bytes to be in the processor's order. *((short *) pbyte) uses a single machine code instruction, like LDRH in the ARM link I provided. Which of course always reads the bytes in the processor order so there is never a "reversal". The only possible mistake is having the bytes in the byte[] you pass in the wrong order. –  Hans Passant Mar 12 '14 at 16:36
    
Ok, I finally get it.. I was thinking that *((short *) pbyte) was different than (short)((*pbyte) | (*(pbyte + 1) << 8)), and that say (short)0x0100 would actually be 1 (since little endian) but actually o get 1 you just cast the bits in big endian format like (short)0x0001 –  mclaassen Mar 12 '14 at 16:51

On most architecutre there is a performance hit in accessing data that isn't aligned at the proper boundary. On x86 the CPU will allow you to read from an unaligned address, but there will be a performance hit. On some architecture you'll get a CPU fault that the operating system will trap.

I'd guess that the cost of letting the CPU fix up the reading of unaligned data is greater than the cost of reading the individual bytes and doing the shift/or operations. Also, the code is now portable to platforms where an unaligned read will cause a fault.

share|improve this answer
    
Ok, but what if my array of data does in fact have ints/shorts etc. which are not on aligned offsets. It would seem that if I tried to grab an int from some odd offset in my byte array that it would not do what I want. –  mclaassen Mar 12 '14 at 16:12
    
If you look at ToInt32 and ToInt64 versions you'll see that they do a check to make sure the data is aligned on a 4 or 8 byte boundary. –  Sean Mar 12 '14 at 16:27
    
But how is *((short *)pbyte the same as (short)((*pbyte) | (*(pbyte + 1) << 8))? Doesn't the second reverse the order of the bytes? –  mclaassen Mar 12 '14 at 16:42
    
Not on little endian architectures. The first byte goes in the lower 8 bits, the second byte goes in the upper 8 bits. –  Sean Mar 12 '14 at 16:45

Why does this work regardless of the endianness of the machine?

The method does a re-interpretation of bytes assuming that they were produced in the environment with the same endianness. In other words, endianness influences both the the order the input bytes are arranged in the array, and the order the bytes need to be arranged in the output short in the same way.

Why doesn't it use the same mechanism when the machine is Big Endian?

This is an excellent observation, and it is not immediately obvious why the authors didn't do the cast. I think the reason behind it is that if you cast a pbyte with an odd value to short*, the subsequent access to short would be unaligned. This requires a special opcode to prevent a hard exception, which some platforms generate on unaligned access.

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.