First of all, any fast solution must use vectorization to compare many elements at once.
However, all the vectorized implementations posted so far suffer from a common problem: they have branches. As a result, they have to introduce blockwise processing of the array (to reduce overhead of branching), which leads to low performance for small arrays. For large arrays linear search is worse than a well-optimized binary search, so there is no point in optimizing it.
However, linear search can be implemented without branches at all. The idea is very simple: the index you want is precisely the number of elements in the array that are less than the key you search for. So you can compare each element of the array to the key value and sum all the flags:
static int linear_stgatilov_scalar (const int *arr, int n, int key) {
int cnt = 0;
for (int i = 0; i < n; i++)
cnt += (arr[i] < key);
return cnt;
}
A fun thing about this solution is that it would return the same answer even if you shuffle the array =) Although this solution seems to be rather slow, it can be vectorized elegantly. The implementation provided below requires array to be 16-byte aligned. Also, the array must be padded with INT_MAX elements because it consumes 16 elements at once.
static int linear_stgatilov_vec (const int *arr, int n, int key) {
assert(size_t(arr) % 16 == 0);
__m128i vkey = _mm_set1_epi32(key);
__m128i cnt = _mm_setzero_si128();
for (int i = 0; i < n; i += 16) {
__m128i mask0 = _mm_cmplt_epi32(_mm_load_si128((__m128i *)&arr[i+0]), vkey);
__m128i mask1 = _mm_cmplt_epi32(_mm_load_si128((__m128i *)&arr[i+4]), vkey);
__m128i mask2 = _mm_cmplt_epi32(_mm_load_si128((__m128i *)&arr[i+8]), vkey);
__m128i mask3 = _mm_cmplt_epi32(_mm_load_si128((__m128i *)&arr[i+12]), vkey);
__m128i sum = _mm_add_epi32(_mm_add_epi32(mask0, mask1), _mm_add_epi32(mask2, mask3));
cnt = _mm_sub_epi32(cnt, sum);
}
cnt = _mm_hadd_epi32(cnt, cnt);
cnt = _mm_hadd_epi32(cnt, cnt);
// int ans = _mm_extract_epi32(cnt, 0); //SSE4.1
int ans = _mm_extract_epi16(cnt, 0); //correct only for n < 32K
return ans;
}
The final reduction of a single SSE2 register can be implemented with SSE2 only if necessary, it should not really affect the overall performance.
I have tested it with Visual C++ 2013 x64 compiler on Intel Core2 Duo E4700 (quite old, yeah). The array of size 197 is generated with elements provided by rand(). The full code with all the testing is here. Here is the time to perform 32M searches:
[OP]
Time = 3.155 (-896368640) //the original OP's code
[Paul R]
Time = 2.933 (-896368640)
[stgatilov]
Time = 1.139 (-896368640) //the code suggested
The OP's original code processes 10.6 millions of array per second (2.1 billion elements per second). The suggested code processes 29.5 millions of arrays per second (5.8 billion elements per second).
Also, the suggested code works well for smaller arrays: even for arrays of 15 elements, it is still almost three times faster than OP's original code.
Here is the generated assembly:
$LL56@main:
movdqa xmm2, xmm4
movdqa xmm0, xmm4
movdqa xmm1, xmm4
lea rcx, QWORD PTR [rcx+64]
pcmpgtd xmm0, XMMWORD PTR [rcx-80]
pcmpgtd xmm2, XMMWORD PTR [rcx-96]
pcmpgtd xmm1, XMMWORD PTR [rcx-48]
paddd xmm2, xmm0
movdqa xmm0, xmm4
pcmpgtd xmm0, XMMWORD PTR [rcx-64]
paddd xmm1, xmm0
paddd xmm2, xmm1
psubd xmm3, xmm2
dec r8
jne SHORT $LL56@main
$LN54@main:
phaddd xmm3, xmm3
inc rdx
phaddd xmm3, xmm3
pextrw eax, xmm3, 0
Finally, I'd like to note that a well-optimized binary search can be made faster by switching to the described vectorized linear search as soon as the interval becomes small.
UPDATE: More information can be found in my blog post on the matter.