I mean, I malloc a segment of memory, maybe 1k maybe 20bytes..
assume the pointer is pMem
How can I know the content pMem
refered is all Zero
or \0
. I know memcmp
but the second parameter should another memory address...
thanx




You can use calloc if you want all 0s in the memory you allocate 


As others have already suggested you probably want memset or calloc. But if you actually do want to check if a memory area is all zero, you can compare it with itself but shifted by one.
where length is the number of bytes you want to be zero. 


If you need the memory to be zero, just However, if you really want to efficiently check a region of memory to see if it's all zero, you can 


As you've noted, It sounds like you don't have another block of memory, though. You just have one, and you want to know whether it's all zero. The standard libraries don't provide such a function, but it's easy to write your own:
If you want to allocate a new block of memory and have it be all zero right away, then use 


If you're testing it, and then only going to use it if it's zero, then be aware you have a racecondition, because the method suggested by @Mark Byers doesn't have an atomic test/set operation. It'll be hard to get the logic correct in this case. If you want to zero it if it's not already zero, then just set it to zero as that will be faster. 


C++ solution:



Another C++ solution, slightly simpler than Kirill's. It is somewhat less efficient, though, as it traverses the entire sequence even when that sequence contains a nonzero element.



Since Mark's answer has provoked some controversy:
Results (cygwin, Windows XP, Core 2 Duo T7700 at 2.4 GHz):
So, the memcmp is taking approximately (2.8  0.4) / (1.2  0.4) = 3 times as long, for me. It'd be interesting to see other people's results  all my malloced memory is zeroed, so I'm getting the worstcase time for each comparison, always. With smaller blocks (and more of them) the comparison time is less significant, but memcmp is still slower:
I am slightly surprised by this. I expected memcmp to at least compete, since I expect it to be inlined and to be optimised for small sizes known at compile time. Even changing it so that it tests an int at the start and then 16 bytes of memcmp, to avoid the unaligned worst case, doesn't speed it up much. 


For large buffers:
Remarks: The code assumes the buffer is well aligned (i.e. the address is a multiple of the CPU Word size). If not, a block similar to "remainder" needs to be put in front of the block test. The additional code will of course be slower for small buffers  however, in this case one commonly assumes that these short durations don't matter. If you prefer you can of course replace the loops with std::find_if. Performance: 1: 3.9 (VS 2008, /Ox /Ot, 2,47 +/ 0,11 vs. 0,63 +/ 0,19, for 10000 repeats over 256000 bytes, statistics over 15 repeats first removed) Discussion: From my experience analyzing C/C++ to assembly, I wouldn't expect a compiler to do this optimization  because it is a pessimization for small Also, the total time is negligible for most applications, a cache miss will be far worse and affect both versions the same. [edit] for the fun of it: Overlapping memcmp clocks in at 1:1.4, which is vastly better than the single byte check (surprised me a little). Note that the misaligned read makes that strongly platform dependent. 


Poking around with Steve Jessops code for fun I found this variant
to be about 50% faster (no branches in the core loop). All bugs are mine. [Edit]: As Steve points out, this version has a good worst case and a terrible best case (since they are the same). Only use it if a completely zeroed buffer is the only case that needs to be fast. 


Instead of just the average, this test shows the 1st quartile and 3rd quartile of time taken, but it seems the system was fairly consistent (runs varying within ±2%). $ make time cc m32 g O3 W Wall Wextra o test32 test.c repe.S lrt ./test32  bit_or  use_memcmp  check_bytes  check_aligned  repe_scasb  repe_scas ++++++ 0x7+4  zero 1.09e07/1.09e072.09e07/2.11e071.66e07/1.68e071.35e07/1.74e071.83e07/1.86e072.00e07/2.06e07 last 1.09e07/1.09e072.09e07/2.12e071.00e07/1.00e071.18e07/1.18e071.83e07/1.85e071.83e07/1.85e07 half 1.09e07/1.09e071.79e07/1.84e077.42e08/7.42e086.98e08/6.98e081.57e07/1.59e071.39e07/1.40e07 first1.09e07/1.09e076.11e08/6.11e084.81e08/4.81e086.98e08/6.99e081.22e07/1.27e071.39e07/1.42e07 0x7+2  zero 1.09e07/1.09e072.09e07/2.11e071.66e07/1.71e071.31e07/1.57e071.83e07/1.85e072.00e07/2.06e07 last 1.09e07/1.09e072.09e07/2.14e071.00e07/1.00e071.22e07/1.24e071.83e07/1.88e071.83e07/1.83e07 half 1.09e07/1.09e071.79e07/1.80e077.42e08/7.42e088.72e08/8.72e081.57e07/1.59e071.61e07/1.66e07 first1.09e07/1.09e076.11e08/6.11e084.81e08/4.81e086.55e08/6.55e081.22e07/1.22e075.82e08/5.82e08 0x7+1  zero 1.09e07/1.09e072.09e07/2.14e071.66e07/1.66e071.09e07/1.42e071.83e07/1.88e072.05e07/2.07e07 last 1.09e07/1.09e072.09e07/2.14e071.00e07/1.00e071.00e07/1.00e071.83e07/1.87e071.92e07/1.97e07 half 1.09e07/1.09e071.79e07/1.81e077.42e08/7.42e087.85e08/7.86e081.57e07/1.61e071.92e07/1.97e07 first1.09e07/1.09e076.11e08/6.11e084.81e08/4.81e085.24e08/5.24e081.22e07/1.22e076.55e08/6.55e08 0x7  zero 1.09e07/1.09e072.09e07/2.14e071.66e07/1.71e071.52e07/1.79e071.83e07/1.88e072.00e07/2.06e07 last 1.09e07/1.09e072.09e07/2.14e071.00e07/1.00e071.44e07/1.70e071.83e07/1.88e071.83e07/1.85e07 half 1.09e07/1.09e071.79e07/1.79e077.42e08/7.42e087.85e08/7.85e081.57e07/1.57e071.39e07/1.39e07 first1.09e07/1.09e076.11e08/6.11e084.81e08/4.81e087.85e08/7.85e081.22e07/1.22e071.39e07/1.39e07 0x400  zero 9.06e06/9.06e069.97e06/9.97e061.79e05/1.81e052.93e06/2.93e069.06e06/9.07e062.41e06/2.41e06 last 9.06e06/9.06e069.97e06/9.97e061.80e05/1.80e052.39e06/2.39e069.06e06/9.07e062.40e06/2.40e06 half 9.06e06/9.06e065.08e06/5.08e069.06e06/9.06e061.29e06/1.29e064.62e06/4.62e061.30e06/1.30e06 first9.06e06/9.06e069.25e08/9.67e088.34e08/9.67e081.05e07/1.06e071.58e07/1.58e071.75e07/1.75e07 0x1000  zero 3.59e05/3.59e053.95e05/3.95e057.15e05/7.15e051.14e05/1.14e053.59e05/3.59e059.20e06/9.20e06 last 3.59e05/3.59e053.95e05/3.95e053.59e05/3.59e059.18e06/9.18e063.59e05/3.59e059.19e06/9.19e06 half 3.59e05/3.59e051.99e05/1.99e051.81e05/1.81e054.74e06/4.74e061.81e05/1.81e054.74e06/4.75e06 first3.59e05/3.59e052.04e07/2.04e072.04e07/2.04e072.13e07/2.13e072.65e07/2.66e072.82e07/2.82e07 0x10000 zero 9.52e03/1.07e021.14e02/1.17e021.94e02/2.04e023.43e03/3.52e039.59e03/1.07e023.10e03/3.17e03 last 9.57e03/1.07e021.14e02/1.17e029.73e03/1.08e023.04e03/3.13e039.57e03/1.05e023.11e03/3.22e03 half 9.54e03/1.06e025.06e03/5.13e034.69e03/4.76e031.17e03/1.17e034.60e03/4.65e031.18e03/1.18e03 first9.55e03/1.07e022.28e06/2.29e062.26e06/2.27e062.28e06/2.29e062.34e06/2.35e062.36e06/2.36e06 cc m64 g O3 W Wall Wextra o test64 test.c repe.S lrt ./test64  bit_or  use_memcmp  check_bytes  check_aligned  repe_scasb  repe_scas ++++++ 0x7+4  zero 9.14e08/9.14e081.65e07/1.65e071.17e07/1.17e071.26e07/1.26e071.52e07/1.52e072.57e07/2.67e07 last 9.14e08/9.14e081.65e07/1.65e071.04e07/1.17e071.09e07/1.09e071.52e07/1.52e071.70e07/1.70e07 half 9.14e08/9.14e081.35e07/1.35e077.83e08/7.83e085.66e08/5.66e081.26e07/1.26e077.83e08/7.83e08 first9.14e08/9.14e084.79e08/4.79e085.23e08/5.23e085.66e08/5.66e081.00e07/1.00e077.83e08/7.83e08 0x7+2  zero 9.14e08/9.14e081.65e07/1.65e071.17e07/1.17e071.26e07/1.26e071.52e07/1.52e072.30e07/2.57e07 last 9.14e08/9.14e081.65e07/1.65e071.04e07/1.04e071.09e07/1.09e071.52e07/1.52e072.22e07/2.22e07 half 9.14e08/9.14e081.35e07/1.35e077.83e08/7.83e087.83e08/7.83e081.26e07/1.26e071.09e07/1.09e07 first9.14e08/9.14e084.79e08/4.79e085.23e08/5.23e085.66e08/5.66e081.00e07/1.00e077.40e08/7.40e08 0x7+1  zero 9.14e08/9.14e081.65e07/1.65e071.17e07/1.17e071.17e07/1.17e071.52e07/1.52e072.30e07/2.32e07 last 9.14e08/9.14e081.65e07/1.65e071.04e07/1.04e071.04e07/1.13e071.52e07/1.52e071.52e07/1.52e07 half 9.14e08/9.14e081.35e07/1.35e077.83e08/7.83e087.40e08/7.40e081.26e07/1.26e071.52e07/1.52e07 first9.14e08/9.14e083.92e08/3.92e084.36e08/4.36e084.79e08/4.79e081.00e07/1.00e077.83e08/7.83e08 0x7  zero 9.14e08/9.14e081.65e07/1.65e071.17e07/1.17e071.52e07/1.52e071.52e07/1.52e072.39e07/2.65e07 last 9.14e08/9.14e081.65e07/1.65e071.04e07/1.04e071.26e07/1.26e071.52e07/1.52e071.70e07/1.70e07 half 9.14e08/9.14e081.35e07/1.35e077.83e08/7.83e086.53e08/6.53e081.26e07/1.26e078.70e08/8.70e08 first9.14e08/9.14e084.79e08/4.79e085.23e08/5.23e086.53e08/6.53e081.00e07/1.00e078.70e08/8.70e08 0x400  zero 9.04e06/9.04e069.90e06/9.90e069.03e06/9.05e062.36e06/2.36e069.01e06/9.01e061.25e06/1.25e06 last 9.04e06/9.04e069.90e06/9.90e069.03e06/9.03e062.35e06/2.35e069.01e06/9.01e061.23e06/1.23e06 half 9.04e06/9.04e065.02e06/5.02e064.59e06/4.59e061.25e06/1.25e064.57e06/4.57e066.84e07/6.84e07 first9.04e06/9.04e066.19e08/7.47e087.91e08/7.92e087.03e08/7.05e081.14e07/1.15e071.27e07/1.28e07 0x1000  zero 3.61e05/3.61e053.93e05/3.93e053.58e05/3.58e059.08e06/9.08e063.58e05/3.58e054.64e06/4.64e06 last 3.61e05/3.61e053.93e05/3.93e053.58e05/3.58e059.07e06/9.07e063.58e05/3.58e054.61e06/4.61e06 half 3.61e05/3.61e051.97e05/1.97e051.80e05/1.80e054.63e06/4.63e061.80e05/1.80e052.40e06/2.40e06 first3.61e05/3.61e051.04e07/1.17e071.21e07/1.21e071.26e07/1.26e071.58e07/1.58e071.71e07/1.71e07 0x10000 zero 1.08e02/1.09e021.03e02/1.04e029.38e03/9.50e032.41e03/2.49e039.33e03/9.50e031.67e03/1.73e03 last 1.08e02/1.09e021.03e02/1.04e029.38e03/9.49e032.44e03/2.55e039.33e03/9.47e031.62e03/1.67e03 half 1.08e02/1.10e025.05e03/5.12e034.61e03/4.69e031.16e03/1.16e034.59e03/4.66e036.63e04/6.65e04 first1.08e02/1.09e028.70e07/8.80e078.70e07/8.80e078.90e07/9.00e079.60e07/9.60e079.70e07/9.80e07 $ uname srvmp Linux 2.6.32gentoo #1 SMP Sun Dec 6 16:24:50 EST 2009 x86_64 AMD Phenom(tm) 9600 QuadCore Processor As you can see,



More benchmarks: Roughly based on Steve Jessop's sample. I've tested the following:
None of these make any assumptions about the array, and simply accept and work on an array of chars. Finally, I made a fifth version, which casts the array to ints, and compares those. (This one obviously assumes that the size of the array is divisible by Oh, and note that I just slapped this test together quickly, and I used one of Windows' timers because I'm lazy. :)
My results are: (in milliseconds, for a million runs)
I think the takeaway point is pretty clear: Anything that does a bytewise comparison is slow. Really slow. Memcmp does more or less ok, but it's far from perfect. It is too general to be optimal. The most efficient way to solve this problem is to process as much data at a time as possible. 


Another C++ solution:
search_n returns the first occurrence of a sequence of "len" consecutive occurrences of the value (here 0) or it returns "end". In this particular application it obviously either returns the start of the sequence or the end. The advantage of this is I can also apply it to an array of ints, doubles, etc. which will be able to check wordbyword. (Obviously make all_zero a template to do that). 

