# binary search efficiency vs. linear search efficiency in fortran

This question is about the efficiency of a linear search vs. the efficiency of a binary search for a pre-sorted array in contiguous storage...

I have an application written in fortran (77!). One frequent operation for my part of the code is to find the index in an array such that `gx(i) <= xin < gx(i+1)`. I've currently implemented this as a `binary search` -- sorry for the statement labels and `goto` -- I've commented what the equivalent statments would be using fortran 90...

``````        i=1
ih=nx/2
201     continue  !do while (.true.)
if((xin.le.gx(i)).and.(xin.gt.gx(i+1)))then  !found what we want
ilow=i+1; ihigh=i
s1=(gx(ihigh)-xin)/(gx(ihigh)-gx(ilow))
s2=1.0-s1
return
endif
if(i.ge.ih)then
goto 202 !exit
endif
if(xin.le.(gx(ih))then !xin is in second half of array
i=ih
ih=nx-(nx-ih)/2
else !xin is in first half of array
i=i+1
ih=i+(ih-i)/2
endif
goto 201  !enddo
``````

However, today, I was reading on Wikipedia about binary search and I came across this:

``````Binary search can interact poorly with the memory hierarchy
(i.e. caching), because of its random-access nature. For
in-memory searching, if the span to be searched is small, a
linear search may have superior performance simply because
it exhibits better locality of reference.
``````

I don't completely understand this statement -- my impression was that cache fetches were gathered in large(ish) chunks at a time, so if we start at the beginning of the array, I thought that most of the array would be in cache already (at least as much as it would be for a linear search), so I didn't think that would matter.

So my question is, is there any way to tell which algorithm will perform better (linear or binary search?) Is there an array size boundary? I'm currently using arrays of size around 100 elements...

-

For small arrays, the problem is not cache. You are right: A small array is likely to be cached quickly.

The problem is that branch prediction is likely to fail for binary search because branches are taken or skipped at random in a data-dependent way. Branch prediction misses stall the CPU pipeline.

This effect can be severe. You can easily search 3 to 8 elements linearly in the same time it takes to do a single binary search branch (and you need to do multiple binary search branches). The exact break even point needs to be measured.

Stalling the CPU pipeline is extremely expensive. A Core i7 can retire up to 4 instructions per clock cycle (12 giga-instructions per second at 3 GHz!). But only, if you are not stalling.

There are branch-free algorithms doing binary search by using conditional-move CPU instructions. These algorithms basically unroll 32 search steps and use a `CMOV` in each step (32 steps are the theoretical maximum). They are branch-free but not stall free: Each next step depends 100% on the previous one so the CPU cannot charge ahead in the instruction stream. It has to wait all the time. So they don't solve this problem, only improve it slightly.

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Thanks for this. It's very informative. I take it from "the exact break even point needs to be measured" that there's no rule of thumb for how to deal with these things (when to search linearly vs. with a binary search)? –  mgilson May 10 '12 at 0:29
Exactly. It even depends on the CPU. For big lists (or many small lists!), it depends on the cache size of course. I'd just setup a micro-benchmark and measure binary search vs. linear search over N elements. –  usr May 10 '12 at 9:04
Also modern MMUs will tend to prefetch data in from RAM if they see you accessing the n, n+1, n+2th element in sequence, but can't tell what you're doing if you access in a seemingly random pattern like binary search outputs. –  SecurityMatt May 10 '12 at 9:10
"branch prediction is impossible" - it's not impossible - it's just wrong 50% of the time :) –  SecurityMatt May 10 '12 at 9:11
@SecurityMatt, true :) I improved the text a bit. –  usr May 10 '12 at 10:05