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This question already has an answer here:

I have a mass of data, maybe 4MB. Now want to check if all bits in it are 0.

Eg: Here is the data:

void* data = malloc(4*1024*1024);
memset(data, 0, 4*1024*1024);

Check if all bits in it are 0. Here is my solution which is not fast enough:

int dataisnull(char* data, int length)
{
    int i = 0;
    while(i<length){
        if (data[i]) return 0;
        i++;
    }
    return 1;
}

This code might have some things to improve in performance. For example, in 32/64 bits machine, checking 4/8 bytes at a time may be faster.

So I wonder what is the fastest way to do it?

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marked as duplicate by Peter Cordes, Vatine, HaveNoDisplayName, Martin James, rightfold Feb 17 at 15:21

This question has been asked before and already has an answer. If those answers do not fully address your question, please ask a new question.

8  
Don't you need to increment data in the loop too? – Andy Turner Feb 17 at 7:20
1  
Use something like SIMD to process the data faster. – Dai Feb 17 at 7:22
2  
Also, don't you need to do if(data[i]) return 0; ? – Magisch Feb 17 at 7:24
10  
if you want to zero data at allocation time then calloc is much faster than malloc then zero – Lưu Vĩnh Phúc Feb 17 at 7:53
4  
Possible duplicate of Faster approach to checking for an all-zero buffer in C?, although that question doesn't have any great answers :/ Also found Using C/Intel assembly, what is the fastest way to test if a 128-byte memory block contains all zeros? – Peter Cordes Feb 17 at 11:48
up vote 13 down vote accepted

You can handle multiple bytes at a time and unroll the loop:

int dataisnull(const void *data, size_t length) {
    /* assuming data was returned by malloc, thus is properly aligned */
    size_t i = 0, n = length / sizeof(size_t);
    const size_t *pw = data;
    const unsigned char *pb = data;
    size_t val;
#define UNROLL_FACTOR  8
#if UNROLL_FACTOR == 8
    size_t n1 = n - n % UNROLL_FACTOR;
    for (; i < n1; i += UNROLL_FACTOR) {
        val = pw[i + 0] | pw[i + 1] | pw[i + 2] | pw[i + 3] |
              pw[i + 4] | pw[i + 5] | pw[i + 6] | pw[i + 7];
        if (val)
            return 0;
    }
#endif
    val = 0;
    for (; i < n; i++) {
        val |= pw[i];
    }
    for (i = n * sizeof(size_t); i < length; i++) {
        val |= pb[i];
    }
    return val == 0;
}

Depending on your specific problem, it might be more efficient to detect non zero values early or late:

  • If the all zero case is the most common, you should compute cumulate all bits into the val accumulator and test only at the end.
  • If the all zero case is rare, you should check for non zero values more often.

The unrolled version above is a compromise that tests for non zero values every 64 or 128 bytes depending on the size of size_t.

Depending on your compiler and processor, you might get better performance by unrolling less or more. You could also use intrinsic functions available for your particular architecture to take advantage of vector types, but it would be less portable.

Note that the code does not verify proper alignment for the data pointer:

  • it cannot be done portably.
  • it assumes the data was allocated via malloc or similar, hence properly aligned for any type.

As always, benchmark different solutions to see if it makes a real difference. This function might not be a bottleneck at all, writing a complex function to optimize a rare case is counterproductive, it makes the code less readable, more likely to contain bugs and much less maintainable. For example, the assumption on data alignment may not hold if you change memory allocation scheme or if you use static arrays, the function may invoke undefined behavior then.

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3  
That code will invoke Undefined Behavior in C99, C11, or C14 if the data in question has an effective type which is something other than a size_t or a signed equivalent. Note that for purpose of C99's aliasing rules, int and long are different types; even if both are the same size as size_t, at most one of them will be an equivalent type for purpose of aliasing rules. Your approach would be a good one in most sensible dialects of C, but not in C99, C11, or C14 as defined by the Standards. – supercat Feb 17 at 8:22
1  
Compilers are quite complex and unpredictable. I'm concerned that because the compiler can't verify the alignment of the incoming pointer at compile-time, it will produce expensive instructions (a lot of fast instructions only work on aligned addresses). Also, peeking into the assembler at different levels of optimizations may reveal the compiler is already attempting to unroll the loops and group the branches (speculative execution). – orion Feb 17 at 8:31
4  
Is the loop unrolling actually providing a speed up? It looks like something the compiler should be quite good at. GCC has -funroll-loops to do this automatically. – Davidmh Feb 17 at 8:59
1  
@2501: thanks for the correction. Classic cut+paste bug. – chqrlie Feb 17 at 10:26
1  
@Ringo_D: it should be faster because there are fewer test and branches. fewer comparisons with 0, fewer bound tests because of reading multiple bytes at a time and unrolling the loop. – chqrlie Feb 17 at 10:40

The following checks if the first byte is what you want, and all subsequent pairs of bytes are the same.

int check_bytes(const char * const data, size_t length, const char val)
{
    if(length == 0) return 1;
    if(*data != val) return 0;
    return memcmp(data, data+1, length-1) ? 0 : 1;
}

int check_bytes64(const char * const data, size_t length, const char val)
{
    const char * const aligned64_start = (char *)((((uintptr_t)data) + 63) / 64 * 64);
    const char * const aligned64_end = (char *)((((uintptr_t)data) + length) / 64 * 64);
    const size_t start_length = aligned64_start - data;
    const size_t aligned64_length = aligned64_end - aligned64_start;
    const size_t end_length = length - start_length - aligned64_length;

    if (!check_bytes(data, start_length, val)) return 0;
    if (!check_bytes(aligned64_end, end_length, val)) return 0;

    return memcmp(aligned64_start, aligned64_start + 64, aligned64_length-64) ? 0 : 1;
}

A more elaborate version of this function should probably pass cache-line-aligned pointers to memcmp, and manually check the remaining blocks(s) instead of just the first byte.

Of course, you will have to profile on your specific hardware to see if there is any speed benefit of this method vs others.

If anyone doubts whether this works, ideone.

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1  
A small comment: return memcmp(...) == 0 ? true : false. Otherwise it seems like a logical error. – dmi Feb 17 at 7:38
4  
This solution is not really efficient: memcmp is given unaligned pointers: it cannot use optimized code that compares multiple byte at a time efficiently. Furthermore, comparing bytes from memory is less efficient than comparing bytes to a constant value. I did not downvote, but I understand those who did. – chqrlie Feb 17 at 7:53
1  
@chqrlie not necessarily, it depends on the implementation of memcmp. Some of them check if pointers are aligned and change the algorithm accordingly. – Michael Walz Feb 17 at 7:59
5  
@MichaelWalz I think his point was that because of data, data+1, both pointers cannot be aligned. – user694733 Feb 17 at 8:06
1  
@supercat Strict aliasing rules (or any other language rules) don't apply to implementation of C standard library functions. As long as memcmp behaves as standard says, code inside can use any types it wishes. Functions don't even have to be written in C. – user694733 Feb 17 at 9:14

I once wrote the following function for my own use. It assumes that the data to check is a multiple of a constant chunk size and aligned properly for a buffer of machine words. If this is not given in your case, it is not hard to loop for the first and last few bytes individually and only check the bulk with the optimized function. (Strictly speaking, it is undefined behavior even if the array is properly aligned but the data has been written by any type that is incompatible with unsigned long. However, I believe that you can get pretty far with this careful breaking of the rules here.)

#include <assert.h>
#include <stdbool.h>
#include <stddef.h>
#include <stdint.h>

bool
is_all_zero_bulk(const void *const p, const size_t n)
{
  typedef unsigned long word_type;
  const size_t word_size = sizeof(word_type);
  const size_t chunksize = 8;
  assert(n % (chunksize * word_size) == 0);
  assert((((uintptr_t) p) & 0x0f) == 0);
  const word_type *const frst = (word_type *) p;
  const word_type *const last = frst + n / word_size;
  for (const word_type * iter = frst; iter != last; iter += chunksize)
    {
      word_type acc = 0;
      // Trust the compiler to unroll this loop at its own discretion.
      for (size_t j = 0; j < chunksize; ++j)
        acc |= iter[j];
      if (acc != 0)
        return false;
    }
  return true;
}

The function itself is not very smart. The main ideas are:

  • Use large unsigned machine words for data comparison.
  • Enable loop unrolling by factoring out an inner loop with a constant iteration count.
  • Reduce the number of branches by ORing the words into an accumulator and only comparing it every few iterations against zero.
  • This should also make it easy for the compiler to generate vectorized code using SIMD instructions which you really want for code like this.

Additional non-standard tweaks would be to annotate the function with __attribute__ ((hot)) and use __builtin_expect(acc != 0, false). Of course, the most important thing is to turn on your compiler's optimizations.

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3  
Note that in C99, C11, and C14 the function will invoke Undefined Behavior if the data was written as any type other than word_type or a signed equivalent thereof. Maybe someday the Standards Committee will acknowledge that a decent language should include a means of using types larger than "char" for purposes of manipulating "raw memory", but it hasn't yet. – supercat Feb 17 at 8:28
    
@supercat Yes, I know. It is a “fingers crossed” approach. – 5gon12eder Feb 17 at 8:30

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