This is too long to fit in a comment, but I thought I'd give some constructive advice on how to format your contribution.
In your (now closed) question, you asked:
How is the GEMM routine in OpenBLAS so fast? Specifically:
What are the concepts that enable GEMM to perform at near-peak speeds? How is data managed through the many layers of modern CPU
memory? How are the matrices cached and how does one determine optimal
caching parameters for a particular microarchitecture?
How does one implement these concepts for a particular microarchitecture in a high-level language such as C (without using
assembly just yet)? What optimization "tricks" are necessary at this
level? Can you provide code snippets to illustrate how the concepts in
part 1 translate to a portable code that operates are near-peak
How does one hand-optimize assembly routines for a particular microarchitecture? How does one decide what instructions to use and
how to order them? Can you provide illustrative examples? What is the
I count 11 question marks above, 10 of which expound on a broad and vague (but very, very interesting) question. In some sense, they're questions at four different levels of abstraction---why is OpenBLAS fast, how do broad microarchitectural details inform programming, how does the cache work, and how do you write a fast MM kernel.
To my knowledge (I've never written a fast BLAS), some of these points are adequately covered in Goto and van de Geijn's "Anatomy" paper. It's OK to reference that paper (and others) in your questions and answers. It may even be beneficial to do so; people who aren't familiar with the subject matter but like casting close votes might take it as a cue that the question's a little deeper than it might at first appear.
It might be fruitful to handle point 3 like this:
Q: I wrote the following blob of assembly code:
(blob of assembly code)
My understanding is that, on my Sandy Bridge Blah Blah Blah, provided all the data is in L1d, I should be able to run the following driver loop 1234567 times per second:
(trivial driver loop that runs surprisingly slowly)
But it only runs 12345 times per second. What's going on?
A: (why the code runs slow, how to fix it so it runs faster, what it looks like when fixed, and .)
Notice that this is a self-contained question about ricing out a piece of assembly code that just about anybody with the expertise, time, and motivation can answer. The answer is also rather likely to be informative and educational to anyone willing to put in a fraction of the work the answerer put in.
You can handle some of point 2 in a similar fashion:
Q: OK, I've successfully riced out a DGEMM kernel (link to kernel-ricing question). When I try to use it in the following way on my Sandy Bridge blah blah blah, it goes too slow:
(self-contained program implementing and running a DGEMM using the fast kernel)
Here's the perf stat output on my box:
(perf stat output likely identifying the problem)
What's an L2 cache miss? How can I hide the cost of these things?
A: (Answer providing details on what's going on, why, and how to mitigate. Contains a much, much better DGEMM.)