i++ generally isn't equivalent to
i=i+1 because the two produce different expression values.
++i is equivalent to
i=i+1 because they produce the same expression value.
In cases where the value of any of the three aforementioned expressions with
i isn't used, the three are the same. If it's a good compiler, it can optimize out the unused temporary variable produced by
This temporary variable springs to life because
i++ dictates the following 2 things:
- the original value of
i is returned by the expression
i gets incremented by 1
If you first take the original value of
i and then increment
i, well, the original (now old) value of
i has to live somewhere (memory or register, doesn't matter) because it cannot live in the now incremented variable
i. That's your temporary variable.
If, OTOH, you first increment
i by 1, then again, you have to create somewhere (in a register or memory) a value equal to
i-1 to undo the increment, so the old (pred-incremented) value can be obtained as the result of the expression
i=i+1 things are much simpler. These expressions mandates 2 things:
i gets incremented
- the new value of
i is returned
Here it's natural to just increment
i first and then take its value. You don't have to have a pair of values of
i), old and new. New is all we need here.
Now, there are old books and old people around from the times when compilers weren't very good at optimizing. It's from there one can get an idea that
i++ might be slower than
++i. The difference was observed in practice, not made up. It was real and some may think it can still be the case today.
One can also try to analyze the difference between the two(three) incrementing expressions and see that indeed there may be a need to do some extra operations and use an additional memory cell for the temporary variable in case of
i++. And at this point the person may fail to see when this temporary isn't necessary or how to detect whether or not it's necessary. That's another possibility for questions about the said difference.
And, of course, people have loved trolling in all times. :)
As for the compiler developers being lazy... I don't think they were. Here's why.
Back in the olden days, computers were much much much slower than they are today and they carried much much less RAM.
Writing a decent optimizing compiler was possible even then.
The problem was that the extra code for optimizing was making the compiler noticeably bigger and slower. If it's bigger, fewer computers can run it, fewer programmers can use it to compile their code. If it's slower than other compilers, people will prefer other compilers because people hate to be sitting and waiting.
Case in point: me. I did have access to Borland's Turbo C/C++ in mid 90s. But I didn't consider learning and using C until late 90s, early 0's. The reason? Borland's C/C++ was much much slower than their Pascal and my PC wasn't a good one. Waiting for the code to compile was painful. And that's how it was. I first mastered Pascal and only later got back to C and C++.
So, smarter, bigger and slower compilers were costing compiler users money and time. At least during active development, which is still a very important product stage, even if the final product is compiled with a different compiler.
You should not also forget that developing and managing a big piece of compiler code with the rudimentary tools of those days wasn't much fun either. It's only now that you can have a nice IDE (and not one!) with a debugger in it, syntax highlighting, auto completion and all, Source Code Management, easy file comparison, Internet/StackOverflow, etc etc... And we can now have multiple 20+" displays connected to the PC! Now we are speaking productivity! :)
Really, we've got wonderful tools and devices today. 20, 30, 40 years ago people could only imagine or predict them, but not yet use.
Things were tougher. And, while I'm not going to make a statement here, I wouldn't be surprised to find out that back then when programming wasn't as commoditized as it is now, there were more good and brilliant programmers than there are today. And that, of course, is not in absolute digits, but rather in relative.
So, I doubt the compiler guys were lazy.
Look up the web for what's called
Small C. It's a general term for a much dumbed-down and functionally reduced C compiler implementing only the most important features of the C language. You will find some implementations by
James Hendrix (early 80s) and others and derivatives from those (e.g. RatC/Lancaster implementation of the same by
Bob Berry and
If you look at the code of any of those
Small C's, you'll find that the minimum code size is about 50+ KB with 2+ KLOC, and that's only a translator from C to assembly code! Someone at some point would need to assemble that with an assembler.
I can't imagine comfortably working with such a project on something like an 8-bit home computer, e.g. a ZX-Spectrum (which I had as a child), which could have a maximum of 48KB RAM, the CPU ran at ~3MHz, all storage was on a tape recorder and the data transfer rates were like 10KB/min, and the screen was 32x24, not even 80x25.
And all that Small C code from early 80s, barely fitting into the computer's memory, didn't optimize anything!