Oh, man, where to begin?

First, I'm amazed that this is news. Second, the problem is not that profilers are bad, it is that *some* profilers are bad.
The authors built one that, they feel, is good, just by avoiding some of the mistakes they found in the ones they evaluated.
Mistakes are common because of some persistent myths about performance profiling.

But let's be positive.
If one wants to find opportunities for speedup, it is really very simple:

Sampling should be *uncorrelated* with the state of the program.

That means happening at a truly random time, regardless of whether the program is in I/O (except for user input), or in GC, or in a tight CPU loop, or whatever.

Sampling should *read the function call stack*,

so as to determine which statements were "active" at the time of the sample.
The reason is that every call site (point at which a function is called) has a percentage cost equal to the fraction of time it is on the stack.
(Note: the paper is concerned entirely with self-time, ignoring the massive impact of avoidable function calls in large software. In fact, the reason behind the original `gprof`

was to help find those calls.)

Reporting should show *percent by line* (not by function).

If a "hot" function is identified, one still has to hunt inside it for the "hot" lines of code accounting for the time. That information is *in the samples*! Why hide it?

An almost universal mistake (that the paper shares) is to be concerned too much with accuracy of *measurement*, and not enough with accuracy of *location*.
For example, here is an example of performance tuning
in which a series of performance problems were identified and fixed, resulting in a compounded speedup of 43 times.
It was not essential to know precisely the size of each problem before fixing it, but to know its location.
A phenomenon of performance tuning is that fixing one problem, by reducing the time, magnifies the percentages of remaining problems, so they are easier to find.
As long as *any* problem is found and fixed, progress is made toward the goal of finding and fixing all the problems.
It is not essential to fix them in decreasing size order, but it is essential to pinpoint them.

On the subject of statistical accuracy of measurement, if a call point is on the stack some percent of time F (like 20%), and N (like 100) random-time samples are taken, then the number of samples that show the call point is a binomial distribution, with mean = NF = 20, standard deviation = sqrt(NF(1-F)) = sqrt(16) = 4. So the percent of samples that show it will be 20% +/- 4%.
So is that accurate? Not really, but has the problem been found? Precisely.

In fact, the larger a problem is, in terms of percent, the fewer samples are needed to locate it. For example, if 3 samples are taken, and a call point shows up on 2 of them, it is highly likely to be very costly.
(Specifically, it follows a beta distribution. If you generate 4 uniform 0,1 random numbers, and sort them, the distribution of the 3rd one is the distribution of cost for that call point.
It's mean is (2+1)/(3+2) = 0.6, so that is the expected savings, given those samples.)
INSERTED: And the speedup factor you get is governed by another distribution, *BetaPrime*, and *its* average is 4. So if you take 3 samples, see a problem on 2 of them, and eliminate that problem, on average you will make the program four times faster.

It's high time we programmers blew the cobwebs out of our heads on the subject of profiling.

Disclaimer - the paper failed to reference my article: Dunlavey, “Performance tuning with instruction-level cost derived from call-stack sampling”, ACM SIGPLAN Notices 42, 8 (August, 2007), pp. 4-8.