Is there an easy way to bit-reflect a byte variable in Delphi so that the most significant bit (MSB) gets the least significant bit (LSB) and vice versa?
If speed is important, then you can use lookup table. You feel it once on program start and then you just take a value from table. Since you're only needing to map byte to byte, that would take 256x1=256 bytes of memory. And given recent Delphi versions support inline functions, that would provide for both speed, readability and reliability (incapsulating array lookup in the function you may be sure you would not change the values due to some typo)
Speed comparison of several implementations that were mentioned on this forum.
Pascal AND unrolled: 10052 Asm Shift unrolled: 4573 LUT, called: 3192 Pascal math, called: 4614
Note: LUT (lookup table) timings are probably rather optimistic here. Due to running in tight loop the whole table was sucked into L1 CPU cache. In real computations this function most probably would be called much less frequently and L1 cache would not keep the table entirely.
Pascal inlined function calls result are bogus - Delphi did not called them, detecting they had no side-effects. But funny - the timings were different.
And below the explanation:
All calls to inlined functions were eliminated. Yet about passing the parameters Delphi made three different decisions:
In code you can do it like this:
But a lookup table would be much more efficient, and only consume 256 bytes of memory.
This is more than 10 times faster than the version of the code that operates on individual bits.
Finally, I don't normally like to comment too negatively on accepted answers when I have a competing answer. In this case there are very serious problems with the answer that you accepted that I would like to state clearly for you and also for any future readers.
You accepted @Arioch's answer at the time when it contained the same Pascal code as can be seen in this answer, together with two assembler versions. It turns out that those assembler versions are much slower than the Pascal version. They are twice as slow as the Pascal code.
It is a common fallacy that converting high level code to assembler results in faster code. If you do it badly then you can easily produce code that runs more slowly than the code emitted by the compiler. There are times when it is worth writing code in assembler but you must not ever do so without proper benchmarking.
What is particularly egregious about the use of assembler here is that it is so obvious that the table based solution will be exceedingly fast. It's hard to imagine how that could be significantly improved upon.
Using brute force can be simple and effective.
This routine is NOT
Added array of byte as input and result assigned to array of byte as well. This shows better performance for the LUT solution.
Googling a little, found
This one is closer to the LUT solution, even faster in one test.
Code to benchmark:
Result of benchmark (XE3, i7 CPU 870):
I added some of the other proposals in the last part of the table (all inlined). It is probably most fair to test in a loop with an array in and an array as result.
Note: I added a new algorithm for the x64 bit part of