# Optimization: why is < more expensive than multiple !=

I have a 2d array of chars that I need to do some operations on. In some cases, I need to check if character is a-h. I used to accomplish this by checking if the character was not equal to any of the other characters (there are only 5 other characters). However, I recently had the idea that I could instead check if the character was < 'j' to get the same result with hopefully fewer assembly instructions.

In some places I put it, it did result in a small speed-up, but in others it resulted in a rather large slowdown. Any ideas why this is? What is the relative expense of != as opposed to < in if statements?

Here is an example code snippet:

``````if( arr[r][c] == arr[r][c+1] && arr[r][c] == arr[r][c+2]
&& arr[r][c] != 'q' && arr[r][c] != 'r' && arr[r][c] != 's' && arr[r][c] != 't')
``````

vs

``````if( arr[r][c] == arr[r][c+1] && arr[r][c] == arr[r][c+2]
&& arr[r][c] < 'j')
``````
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Can you show us the results of your performance tests? –  0x499602D2 Aug 1 '13 at 1:44
Can you provide an SSCCE? –  Mysticial Aug 1 '13 at 2:27
Well, the two expressions are not equivalent -- they will pass different patterns through. What happens in the body of the if and else legs presumably would affect overall cost. –  Hot Licks Aug 1 '13 at 3:21
@seaotternerd - Not a chance! –  Hot Licks Aug 1 '13 at 3:23
@user2503981 if you can provide an SSCCE as Mystical says, we might be able to get faster runtimes for you ;) –  Eiyrioü von Kauyf Aug 1 '13 at 4:16

If I understand your question correctly, it seems that you wish to check if all elements of an array column are between the characters 'a' and 'h' and are identical, and you want to optimize this process.

Should you happen to know some assembly language, I strongly recommend using a disassembler to find out what exactly is occurring in your function during execution. All compilers and optimization levels are slightly different. However, a bare minimum of operations for a comparison of two values in memory would consist of:

. loading the two variables in memory to the processor registers (several clock cycles)

. performing an equality test on the values in the two registers (1 clock cycle)

. executing a jump command based on the flags register (intel processors)(another clock cycle)

Now this is about as simple of an operation as you can get for a processor, but since you have stacked comparison operations, the time required for these checks accumulate (particularly the clock cycles needed for memory access.

Therefore, to reduce the time needed for these comparisons, one needs to reduce the number of comparisons. Remember that characters 'a' through 'h' have ascii values between 0x61 and 0x68 (decimal 97 to 104). You can ascertain if a character is between 'a' through 'h' in about three comparison operations by:

``````if(arr[r][c] >= 97 && arr[r][c] <= 104)
``````

Check only one value of the column and use this bit-twiddling trick to determine if all elements in the column are the same:

``````if(((arr[r][c] ^ arr[r][c+1]) + (arr[r][c] ^ arr[r][c+2]) + ...*etc*) == 0)
``````

The "xor"('^') comparison takes a single clock cycle, as does addition, and if there are any dissimilarities between any two column entities, the operation will result in a nonzero result. This method should increase in linear time with number of column elements, and as an added bonus an optimizing compiler might be able to keep 'arr[r][c]' in one of the registers during the operation.

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Have you actually measured those premature optimisations with full optimisations enabled during compilation? –  undefined behaviour Aug 1 '13 at 4:05
No, and if the questioner and myself were to use different compilers or different optimization levels, it may have been a moot point to do so. However, in my own experience, I have found that excessive variable comparisons cause a execution delay that becomes nontrivial even for moderately-sized inputs (consider a string-search algorithm). I simply offered a means by which these comparisons could be minimized for the task at hand. As for portability, ascii or ebcdic encoding was not specified in the question, and I really cannot imagine any processor without xor and addition operations. –  J. Alfred Prufrock Aug 1 '13 at 5:18
Using if( !((mboard[r][c] ^ mboard[r][c+1]) + (mboard[r][c] ^ mboard[r][c+2])) && mboard[r][c]<'j') I got the same speed as my second example in the main question, which ran slower than the first example. –  user2503981 Aug 1 '13 at 6:59
@J.AlfredPrufrock Your suggestion might make sense if it's to remove redundant operations. However, it seems like you're recommending the introduction of more comparisons or using different operations. Given that most compilers are intelligent enough to remove unused variables and code, don't you think it could replace comparisons with xor operations quite easily? Is removing the lazy evaluation of `&&` really an optimisation? –  undefined behaviour Aug 1 '13 at 7:40
@user2503981 - I have dissassembled compilations the two `if` conditions that you had previously posted using gcc 4.4.3 (i486 target, default optimization), and have found that it takes about 7-8 processor instructions to clear the registers, move memory variables to registers, and effect a comparison. Each != comparison adds to the total number of instructions needed, and is much longer than a single < comparison. My only guess is that the particular syntax you used affects something else in the program, or that somehow the compiler bypasses making all of the != comparisons sequentially. –  J. Alfred Prufrock Aug 1 '13 at 17:32

Modern compilers/CPUs use branch prediction to pre-fetch candidate outcomes favoring some execution paths over others. Your compilations predicted different and thus different results. Results are likely dependent on the 2d array's contents. Further, the advantage may be different on different compilers/CPUs. Search on branch prediction - there are some great answers out there.

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Indeed! He might want to try with binary logic operators such as (test) & (test) & (test) instead of using the short-circuiting && operator. Don't forget the extra parentheses. That would run all the comparisons but do no branching. It might be considerably faster. –  Zan Lynx Aug 1 '13 at 5:07
Not "AND" but "XOR", the second `if` suggestion only involves a single comparison operation, the remaining 'comparisons' are mathematical. The result of XOR between any two identical numbers is 0. Thus if all variables are identical, all XOR operations will result in 0, and thus the sum of all results will be 0. –  J. Alfred Prufrock Aug 1 '13 at 5:26

Don't focus so much upon speed. Write a program that solves an actual, meaningful task, first. Once that's done, use a profiler to determine which parts of that program are the most significant bottlenecks. Until you have a program written to solve your actual, meaningful task, you should focus on writing portably, well-defined code rather than code that is fast.

Your notion of speed is not in the C standard. In fact, there are no guarantees with regards to speed, here. There are fast compilers and slow compilers, and even fast and slow C interpreters. As a result, your question with regards to speed is invalid. If your C compiler doesn't produce roughly identical code (in terms of speed) in this case, then either learn how to enable full optimisation or get a new C compiler.

This doesn't look portable:

``````if( arr[r][c] == arr[r][c+1] && arr[r][c] == arr[r][c+2]
&& arr[r][c] < 'j')
``````

On systems where EBCDIC is used, `'j' - 'i'`, which you assume to be one is in fact `145 - 137` (twelve). Your test includes eleven additional characters that aren't alphabetical. I suggest using `strchr("abcdefghi", a[r][c])` until you're concerned about performance. If you're concerned about the speed of this (which you shouldn't be, since it's a tiny task in anything that solves an actual problem), you could try converting this to a jump table by using a switch:

``````if (arr[r][c] == arr[r][c+1] && arr[r][c] == arr[r][c+2]) {
switch (a[r][c]) {
case 'a': case 'b': case 'c':
case 'd': case 'e': case 'f':
case 'g': case 'h': case 'i':
/* XXX: Insert code that runs when a[r][c] is in "abcdefghi"... */
break;
}
}
``````

To measure this optimisation, you could use a profiler as suggested in the first paragraph.

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In general compilers can get similar runtimes for many things; A discussion of speed is not trivial. e.g. a recursive fibonacci versus an iterative fibonacci. Please don't give @user250391 the wrong idea. –  Eiyrioü von Kauyf Aug 1 '13 at 4:15
@EiyrioüvonKauyf Please show me which section of the C standard defines speed. Prove what you say with citations. You may also wish to review my edit to that section. –  undefined behaviour Aug 1 '13 at 4:36
continued in chat >> Lounge<C++> –  Eiyrioü von Kauyf Aug 1 '13 at 4:50
@user2503981 Is it a significant bottleneck? I think not. Perhaps you might need to look at more suitable algorithms, data structures, or cache locality... –  undefined behaviour Aug 1 '13 at 6:42
I was more interested in learning why using one < was more expensive than using 4 !=, especially since it was only more expensive in one location in my program. –  user2503981 Aug 1 '13 at 7:07