I'm a few years behind here, but:
In 'Edit 4/5/6' of the original post, you are using the construction:
$ /usr/bin/time cat big_file | program_to_benchmark
This is wrong in a couple of different ways:
You're actually timing the execution of `cat`, not your benchmark. The 'user' and 'sys' CPU usage displayed by `time` are those of `cat`, not your benchmarked program. Even worse, the 'real' time is also not necessarily accurate. Depending on the implementation of `cat` and of pipelines in your local OS, it is possible that `cat` writes a final giant buffer and exits long before the reader process finishes its work.
Use of `cat` is unnecessary and in fact counterproductive; you're adding moving parts. If you were on a sufficiently old system (i.e. with a single CPU and -- in certain generations of computers -- I/O faster than CPU) -- the mere fact that `cat` was running could substantially color the results. You are also subject to whatever input and output buffering and other processing `cat` may do. (This would likely earn you a 'Useless Use Of Cat' award if I were Randal Schwartz.
A better construction would be:
$ /usr/bin/time program_to_benchmark < big_file
In this statement it is the shell which opens big_file, passing it to your program (well, actually to `time` which then executes your program as a subprocess) as an already-open file descriptor. 100% of the file reading is strictly the responsibility of the program you're trying to benchmark. This gets you a real reading of its performance without spurious complications.
I will mention two possible, but actually wrong, 'fixes' which could also be considered (but I 'number' them differently as these are not things which were wrong in the original post):
A. You could 'fix' this by timing only your program:
$ cat big_file | /usr/bin/time program_to_benchmark
B. or by timing the entire pipeline:
$ /usr/bin/time sh -c 'cat big_file | program_to_benchmark'
These are wrong for the same reasons as #2: they're still using `cat` unnecessarily. I mention them for a few reasons:
they're more 'natural' for people who aren't entirely comfortable with the I/O redirection facilities of the POSIX shell
there may be cases where `cat` is needed (e.g.: the file to be read requires some sort of privilege to access, and you do not want to grant that privilege to the program to be benchmarked: `sudo cat /dev/sda | /usr/bin/time my_compression_test --no-output`)
in practice, on modern machines, the added `cat` in the pipeline is probably of no real consequence
But I say that last thing with some hesitation. If we examine the last result in 'Edit 5' --
$ /usr/bin/time cat temp_big_file | wc -l
0.01user 1.34system 0:01.83elapsed 74%CPU ...
-- this claims that `cat` consumed 74% of the CPU during the test; and indeed 1.34/1.83 is approximately 74%. Perhaps a run of:
$ /usr/bin/time wc -l < temp_big_file
would have taken only the remaining .49 seconds! Probably not: `cat` here had to pay for the read() system calls (or equivalent) which transferred the file from 'disk' (actually buffer cache), as well as the pipe writes to deliver them to `wc`. The correct test would still have had to do those read() calls; only the write-to-pipe and read-from-pipe calls would have been saved, and those should be pretty cheap.
Still, I predict you would be able to measure the difference between `cat file | wc -l` and `wc -l < file` and find a noticeable (2-digit percentage) difference. Each of the slower tests will have paid a similar penalty in absolute time; which would however amount to a smaller fraction of its larger total time.
In fact I did some quick tests with a 1.5 gigabyte file of garbage, on a Linux 3.13 (Ubuntu 14.04) system, obtaining these results (these are actually 'best of 3' results; after priming the cache, of course):
$ time wc -l < /tmp/junk
real 0.280s user 0.156s sys 0.124s (total cpu 0.280s)
$ time cat /tmp/junk | wc -l
real 0.407s user 0.157s sys 0.618s (total cpu 0.775s)
$ time sh -c 'cat /tmp/junk | wc -l'
real 0.411s user 0.118s sys 0.660s (total cpu 0.778s)
Notice that the two pipeline results claim to have taken more CPU time (user+sys) than realtime. This is because I'm using the shell (Bash)'s built-in 'time' command, which is cognizant of the pipeline; and I'm on a multi-core machine where separate processes in a pipeline can use separate cores, accumulating CPU time faster than realtime. Using /usr/bin/time I see smaller CPU time than realtime -- showing that it can only time the single pipeline element passed to it on its command line. Also, the shell's output gives milliseconds while /usr/bin/time only gives hundreths of a second.
So at the efficiency level of `wc -l`, the `cat` makes a huge difference: 409 / 283 = 1.453 or 45.3% more realtime, and 775 / 280 = 2.768, or a whopping 177% more CPU used! On my random it-was-there-at-the-time test box.
I should add that there is at least one other significant difference between these styles of testing, and I can't say whether it is a benefit or fault; you have to decide this yourself:
When you run `cat big_file | /usr/bin/time my_program`, your program is receiving input from a pipe, at precisely the pace sent by `cat`, and in chunks no larger than written by `cat`.
When you run `/usr/bin/time my_program < big_file`, your program receives an open file descriptor to the actual file. Your program -- or in many cases the I/O libraries of the language in which it was written -- may take different actions when presented with a file descriptor referencing a regular file. It may use mmap(2) to map the input file into its address space, instead of using explicit read(2) system calls. These differences could have a far larger effect on your benchmark results than the small cost of running the `cat` binary.
Of course it is an interesting benchmark result if the same program performs significantly differently between the two cases. It shows that, indeed, the program or its I/O libraries are doing something interesting, like using mmap(). So in practice it might be good to run the benchmarks both ways; perhaps discounting the `cat` result by some small factor to "forgive" the cost of running `cat` itself.