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Nov
6
comment Is there any legitimate use for Intel's RDRAND?
I thought of that, but those snippets relies both on compiler specific intrinsics and on a hardware feature. In a real scenario, you would want to use a library anyways, both to support any hardware and to encapsulate the non-portable assembly/intrinsics code.
Nov
6
comment Generating random numbers: CPU vs GPU, which currently wins?
On my tests, std::mt19937 is about 100 times faster than RDRAND on a tight loop.
Oct
20
comment How to correctly represent 3D rotation in games
So, the "state" of any object of your game in space is described by a vector (displacement from origin) and a quaternion (orientation around its center)?
Oct
20
comment How to correctly represent 3D rotation in games
This is too fuzzy. I probably know what you want, but don't know how to start...
Oct
13
comment How to synchronize the value of a variable among all threads?
Hi, I just added an MVCE. Your code seems to work properly, but mine deadlocks (the exit condition depends on all threads, not only one).
Oct
10
comment How to synchronize the value of a variable among all threads?
And how to keep my private variables created before the loop? The reason I am doing this way is that inside the loop there is another parallel loop (nested parallel) that works on the private variables of each thread organized previously.
Oct
10
comment How to synchronize the value of a variable among all threads?
Yes, that is the precisely the point, because they have inconsistent views of the cond_var, some threads will never reach the barrier again, deadlocking. But I did try to load the variable with #pragma atomic read, and it didn't work. Apparently, atomic read guarantee that I will not have an inconsistent value, but does not guarantee it is the most recent one.
Oct
8
comment Why doesn't this code scale linearly?
Made a huge difference the numactl thing. I will take a time later to use libnuma to split the work properly between NUMA sockets and set the threads affinity accordingly.
Oct
8
comment Why doesn't this code scale linearly?
Thanks for the tip. I am just leraning OpenMP and had trouble understanding the reduction thing.
Oct
8
comment Why doesn't this code scale linearly?
I take this answer. The memory bandwidth is the limit. My attempt to improve shared cache reuse, by making the threads to work closer together makes the problem worse, probably because of individual cache invalidation by other threads writings (other tests also shows that bigger work_line is much better for solver convergence). I suppose the code can be made better by coding for NUMA (spliting the jobs and memory access by processor socket), but I won't tackle this problem for now.
Oct
7
comment Why doesn't this code scale linearly?
I won't be able to run it on the same Xeon machine, but on my desktop machine L3 cache miss is 32%, and memory read rate is 15.41 GBytes/ 3111 Mticks. How Mticks translates to seconds? Are those CPU clock ticks?
Oct
7
comment Why doesn't this code scale linearly?
Isn't the work_line thing a kind of loop tiling?
Oct
7
comment Why doesn't this code scale linearly?
I am convincing the sysadmin to allow me to have r/w permission on /dev/cpu/*/msr...
Oct
7
comment Why doesn't this code scale linearly?
That would explain the high times on low work_line runs.
Oct
7
comment Why doesn't this code scale linearly?
I've heard they also offer parallelism on the superscalar pipelines, so if both threads has low instruction level parallelism, they can run simultaneously on different instruction pipelines.
Oct
6
comment Why doesn't this code scale linearly?
About the cache locality, the matrix came from a uniform finite difference discretization of a 3D partial differential equation. In the middle loop, the thread has to access 5 different "places" of the array sol. 1st: sol[i-1], sol[i] and sol[i+1]; 2nd: sol[i-128]; 3rd: sol[i+128]; 4th: sol[i-1024]; 5th: sol[i+1024]. So, it is not a mess of scatter-gather memory access.
Oct
6
comment Why doesn't this code scale linearly?
This specific case: O(N*7*10000) = O(N), where N is the side of the square matrix. This is so because the matrix is sparse.
Oct
6
comment Why doesn't this code scale linearly?
I don't think there is a real software lock there. I haven't looked at the assembly, but they are most likely atomic read/write available on instruction level. Anyway, I'll rerun a sparser version of case 3 without atomic read/write. For bigger work_line, it makes no difference (I ran a test on a different machine with 4 threads) and it makes sense because a clash is very unlikely. For smaller work_line, it may be relevant. See this: gcc.gnu.org/onlinedocs/gcc-4.1.2/gcc/Atomic-Builtins.html
Sep
25
comment Is there any way to write “mod 31” without modulus/division operators?
Missing return.
Sep
25
comment Is there any way to write “mod 31” without modulus/division operators?
There is no definitive convetion for modulus of negative number. Modular arithmetics is defined for natural numbers. Op asked for (mod 31), not to simulate C % behavior in all ranges.