|
|
Sponsored Content
Special Forums
UNIX and Linux Applications
High Performance Computing
Memory Barriers for (Ubuntu) Linux (i686)
Post 302430141 by gorga on Wednesday 16th of June 2010 06:01:30 PM
06-16-2010
Hi Corona, (small world 
)
I hadn't heard of futexes until you mentioned them, but I did some reading and it seems they still use atomic instructions to update shared variables. In that case I could just use one of GCC's built-in atomic operations like "__sync_fetch_ and_ add" or "__sync_bool_compare_and_swap" as described here...
Atomic Builtins - Using the GNU Compiler Collection (GCC)
The thing with these is they use the asm op-code "lock", which issues a hardware lock on the data-bus effectively locking every other process out of memory. Because I'm writing an application that should be scalable for a system with many cores, I'm discouraged by this.
Could be a possibility, I believe they have made advances into highly parrallel architectures recently, but the project is at a research stage right now so if I can get it to work well on x86 that's good enough for now. I like the sound of this idea though...
This could be a good solution, but I'm not sure how to do it. Do you have any examples of similar code as a guide?
prefix and instance are both uint32_t while state is an enum (guess that means its a uint32_t also?).
)Quote:
Atomic Builtins - Using the GNU Compiler Collection (GCC)
The thing with these is they use the asm op-code "lock", which issues a hardware lock on the data-bus effectively locking every other process out of memory. Because I'm writing an application that should be scalable for a system with many cores, I'm discouraged by this.
Quote:
Besides, what if you need to move it to MIPS or something?
Quote:
Could you perhaps reorder it to put prefix, instance, and state in order in memory? You could assemble the data in an MMX or SSE register, then overwrite several structure members in one assembly op.
Quote:
One thought does occur to me. How large are these structures?
|
|
4 More Discussions You Might Find Interesting
1. UNIX for Dummies Questions & Answers
I have 512 mem on this laptop, though 'top' tells me I only have 380. However, Ubuntu is using 288 mb of memory, when I only have 3 terminals, running lynx, vim(for this file) and (of course) top. Considering it I have lynx running a 600 page txt file, which of course would eat some memory but 300?... (0 Replies)
Discussion started by: riwa
0 Replies
2. Linux
Hi, i am quite new to linux. I am interested in fedora linux distro. Fedora Project
I dont know which one to choose, either i686, x86 64 or ppc. I prefer a live cd, coz its easy to use.
And what is the difference between "Fedora Desktop Live Media" and "Fedora KDE Live Media". (3 Replies)
Discussion started by: superblacksmith
3 Replies
3. Programming
Hi guys , i need to get the total virtual memory in ubuntu but i need to write a C++ code for that, any idea on how to go about doing it? any references? or website that i can refer to ? (6 Replies)
Discussion started by: xiaojesus
6 Replies
4. Ubuntu
My PC (Esprimo, 3 yeas old) has one hard drive having 2 partitions C: (80 GB NTFS, XP) and D: (120 GB NTFS, empty) and and a 200 MB area that yet is not-partitioned.
I would like to try Ubuntu and to install Ubuntu on the not-partitioned area . The idea is to have the possibility to run... (7 Replies)
Discussion started by: C.Weidemann
7 Replies
LEARN ABOUT SUNOS
atomic_ops
atomic_ops(9F) atomic_ops(9F) NAME
atomic_ops - atomic operations SYNOPSIS
#include <sys/atomic.h> This collection of functions provides atomic memory operations. There are 8 different classes of atomic operations: atomic_add(9F) These functions provide an atomic addition of a signed value to a variable. atomic_and(9F) These functions provide an atomic logical 'and' of a value to a variable. atomic_bits(9F) These functions provide atomic bit setting and clearing within a variable. atomic_cas(9F) These functions provide an atomic comparison of a value with a variable. If the comparison is equal, then swap in a new value for the variable, returning the old value of the variable in either case. atomic_dec(9F) These functions provide an atomic decrement on a variable. atomic_inc(9F) These functions provide an atomic increment on a variable. atomic_or(9F) These functions provide an atomic logical 'or' of a value to a variable. atomic_swap(9F) These functions provide an atomic swap of a value with a variable, returning the old value of the variable. See attributes(5) for descriptions of the following attributes: +-----------------------------+-----------------------------+ | ATTRIBUTE TYPE | ATTRIBUTE VALUE | +-----------------------------+-----------------------------+ |Interface Stability |Evolving | +-----------------------------+-----------------------------+ atomic_add(9F), atomic_and(9F), atomic_bits(9F), atomic_cas(9F), atomic_dec(9F), atomic_inc(9F), atomic_or(9F), atomic_swap(9F), mem- bar_ops(9F), attributes(5) Atomic instructions ensure global visibility of atomically-modified variables on completion. In a relaxed store order system, this does not guarantee that the visibility of other variables will be synchronized with the completion of the atomic instruction. If such synchro- nization is required, memory barrier instructions must be used. See membar_ops(9F). Atomic instructions can be expensive. since they require synchronization to occur at a hardware level. This means they should be used with care to ensure that forcing hardware level synchronization occurs a minimum number of times. For example, if you have several variables that need to be incremented as a group, and each needs to be done atomically, then do so with a mutex lock protecting all of them being incremented rather than using the atomic_inc(9F) operation on each of them. 28 Mar 2005 atomic_ops(9F)