I executed a linear search on an array containing all unique elements in range [1, 10000], sorted in increasing order with all search values i.e., from 1 to 10000 and plotted the runtime vs search value graph as follows:

enter image description here

Upon closely analysing the zoomed in version of the plot as follows:

enter image description here

I found that the runtime for some larger search values is smaller than the lower search values and vice versa

My best guess for this phenomenon is that it is related to how data is processed by CPU using primary memory and cache, but don't have a firm quantifiable reason to explain this.

Any hint would be greatly appreciated.

PS: The code was written in C++ and executed on linux platform hosted on virtual machine with 4 VCPUs on Google Cloud. The runtime was measured using the C++ Chrono library.

  • 2
    What's the precision of your timer? A simple explanation is that the discretization is a direct result of the resolution of your timer (and expected minor perturbations of runtimes based on environment variables such as system load.) – ldog Oct 19 '20 at 23:34
  • I used Chrono in C++ to measure the runtime @ldog – Deepak Tatyaji Ahire Oct 20 '20 at 16:32

CPU cache size depends on the CPU model, there are several cache levels, so your experiment should take all those factors into account. L1 cache is usually 8 KiB, which is about 4 times smaller than your 10000 array. But I don't think this is cache misses. L2 latency is about 100ns, which is much smaller than the difference between lowest and second line, which is about 5 usec. I suppose this (second line-cloud) is contributed from the context switching. The longer the task, the more probable the context switching to occur. This is why the cloud on the right side is thicker.

Now for the zoomed in figure. As Linux is not a real time OS, it's time measuring is not very reliable. IIRC it's minimal reporting unit is microsecond. Now, if a certain task takes exactly 15.45 microseconds, then its ending time depends on when it started. If the task started at exact zero time clock, the time reported would be 15 microseconds. If it started when the internal clock was at 0.1 microsecond in, than you will get 16 microsecond. What you see on the graph is a linear approximation of the analogue straight line to the discrete-valued axis. So the tasks duration you get is not actual task duration, but the real value plus task start time into microsecond (which is uniformly distributed ~U[0,1]) and all that rounded to the closest integer value.

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