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He is example of atomic_read implementation:

#define atomic_read(v) (*(volatile int *)&(v)->counter)                                  

Also, should we explicitly use memory barriers for atomic operations on arm?

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    Obviously to prevent compiler time optimization based on assumtions that value won't change.
    – 0andriy
    Oct 24, 2019 at 7:52
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    the atomic operations applies to memory cell, if the value will be cached in a register this will make no sense. Regarding barriers - in general, no, but in particular context this might be needed. Oct 24, 2019 at 9:25
  • volatile indicates the compiler not to optimize read and writes. The expression also force address generation (so it force the thing to be in memory, so no register). Note volatile sig_atomic_t is in standard C, and so it has also some meaning for all compilers (unlike register that can be ignored). Oct 25, 2019 at 8:57
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    The definition above does not use the atomic builtins of GCC. I also think it is confusing to call it atomic_read(). Compiling that does not automatically add any barriers. Perhaps the question should be why that is fine, since it is how the kernel implements it.
    – danyhow
    Oct 25, 2019 at 14:06
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    This document explains it: github.com/torvalds/linux/blob/master/Documentation/… There must be an atomic_read_acquire() and atomic_set_release() defined, which provide memory ordering.
    – danyhow
    Oct 25, 2019 at 14:17

2 Answers 2

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He is example of atomic_read implementation:

A problematic one actually, which assumes that a cast is not a nop, which isn't guaranteed.

Also, should we explicitly use memory barriers for atomic operations on arm?

Probably. It depends on what you are doing and what you are expecting.

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    The code is from an earlier Linux ARM kernel were it is mandated to use GCC. The above answer is correct that this is generically wrong, but the OP has posted with little context and there is nothing wrong with the macro IF you are using GCC (which honours the cast) and you are not on an SMP system (no need for barriers). More recent kernels (say 2014+) have been update to address these issues. See: LKML 2014 The change was for all arches, not just ARM. Also, barriers aren't IF you know it is accessed by a single CPU. Oct 26, 2019 at 17:52
  • @artlessnoise "there is nothing wrong with the macro IF you are using GCC" What is your source on that one?
    – curiousguy
    Oct 26, 2019 at 17:58
  • The versions of gcc are pegged by the header files when you compile the kernel; if not, it throws an error and the approved GCC versions (when this was active) was treating volatile as a reload. Oct 26, 2019 at 22:07
  • @artlessnoise Does any GCC version promises to treat the result of cast to volatile as referring to a volatile obj? Or it is an happy accident?
    – curiousguy
    Oct 26, 2019 at 22:10
  • counter itself is an atomic_t; it can be cached after a read. The important part is to read the entire value and not just a part of it and to do it at the sequence point. I think the accepted answer is wrong and was only adding a comment that your answer was more correct. Oct 26, 2019 at 22:12
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Yes, the casting to volatile is to prevent the compiler from assuming the value of v cannot change. As for using memory barriers, the GCC builtins already allow you to specify the memory ordering you desire, no need to do it manually: https://gcc.gnu.org/onlinedocs/gcc-9.2.0/gcc/_005f_005fatomic-Builtins.html#g_t_005f_005fatomic-Builtins

The default behavior on GCC is to use __ATOMIC_SEQ_CST which will emit the barriers necessary on Arm to make sure your atomics execute in the order you place them in the code. To optimize performance on Arm, you will want to consider using weaker semantics to allow the compiler to elide barriers and let the hardware execute faster. For more information on the types of memory barriers the Arm architecture has, see https://developer.arm.com/docs/den0024/latest/memory-ordering/barriers.

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