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What does the volatile keyword do? In C++ what problem does it solve?

In my case, I have never knowingly needed it.

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Here is an interesting discussion about volatile with regards to the Singleton pattern: – chessguy Sep 16 '08 at 14:05
There is an intriguing technique that makes your compiler detect possible race conditions that relies heavily on the volatile keyword, you can read about it at – Neno Ganchev Sep 16 '08 at 14:44
This is a nice resource with an example on when volatile can be used effectively, put together in pretty layman terms. Link :… – Optimized Coder Nov 11 '11 at 6:48
I use it for lock free code/double checked locking – paulm Jan 27 '14 at 14:15

12 Answers 12

up vote 154 down vote accepted

volatile is needed if you are reading from a spot in memory that, say, a completely separate process/device/whatever may write to.

I used to work with dual-port ram in a multiprocessor system in straight C. We used a hardware managed 16 bit value as a semaphore to know when the other guy was done. Essentially we did this:

void waitForSemaphore()
   volatile uint16_t* semPtr = WELL_KNOWN_SEM_ADDR;/*well known address to my semaphore*/
   while ((*semPtr) != IS_OK_FOR_ME_TO_PROCEED);

Without volatile, the optimizer sees the loop as useless (The guy never sets the value! He's nuts, get rid of that code!) and my code would proceed without having acquired the semaphore, causing problems later on.

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In this case, what would happen if uint16_t* volatile semPtr was written instead? This should mark the pointer as volatile (instead of the value pointed to), so that checks to the pointer itself, e.g. semPtr == SOME_ADDR may not be optimized. This however implies a volatile pointed value again as well. No? – Zyl Aug 25 '14 at 20:54
@Zyl No, it does not. In practice, what you suggest is likely what will happen. But theoretically, one could end up with a compiler that optimizes access to values because it decided that none of those values are ever changed. And if you meant volatile to apply to the value and not the pointer, you'd be screwed. Again, unlikely, but it's better to err on doing things right, than taking advantage of behavior that happens to work today. – iheanyi Jun 23 '15 at 21:56
How would this not be a race on *semPtr? – Baum mit Augen Oct 17 '15 at 12:14
@Doug T. A better explanation is this – machineaddict Feb 18 at 7:57

volatile is needed when developing embedded systems or device drivers, where you need to read or write a memory-mapped hardware device. The contents of a particular device register could change at any time, so you need the volatile keyword to ensure that such accesses aren't optimised away by the compiler.

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This is not only valid for embedded systems but for all device drivers development. – Mladen Janković Sep 16 '08 at 14:11
Yes, that's true. – ChrisN Sep 16 '08 at 14:14
The only time I ever needed it on an 8bit ISA bus where you read the same address twice - the compiler had a bug and ignored it (early Zortech c++) – Martin Beckett Jan 13 '09 at 5:13

Most modern processors have floating point registers that have more than 64 bits of precision. That way, if you run several operations on double-precision numbers, you actually get a higher-precision answer than if you were to truncate each intermediate result to 64 bits.

This is usually great, but it means that depending on how the compiler assigned registers and did optimizations you'll have different results for the exact same operations on the exact same inputs. If you need consistency then you can force each operation to go back to memory by using the volatile keyword.

It's also useful for some algorithms that make no algebraic sense but reduce floating point error, such as Kahan summation. Algebraicly it's a nop, so it will often get incorrectly optimized out unless some intermediate variables are volatile.

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+1 for a (useful) use of volatile I don't think I've ever seen before. – Derrick Turk May 4 '10 at 15:56
When you compute numerical derivatives it is useful too, to make sure x + h - x == h you define hh = x + h - x as volatile so that a proper delta can be computed. – Alexandre C. Jun 30 '10 at 11:36
??? Where's your source for these claims? I'm skeptical. – Jason S Sep 15 '14 at 2:16
+1, indeed in my experience there was a case when floating-point computations produced different results in Debug and Release, so unit tests written for one configuration were failing for another. We solved it by means of declaring one floating-point variable as volatile double instead of just double, so to ensure that it is truncated from FPU precision to 64-bit (RAM) precision before continuing further computations. The results were substantially different because of a further exaggeration of the floating-point error. – Serge Rogatch Aug 6 '15 at 7:05

From an Embedded Systems Article by Dan Saks:

"A volatile object is one whose value might change spontaneously. That is, when you declare an object to be volatile, you're telling the compiler that the object might change state even though no statements in the program appear to change it."

Links to 2 great articles by Mr. Saks regarding the volatile keyword:

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I think this is the most clear answer here. – mr5 Jul 21 '15 at 1:41
indeed very simple yet instructive explanation :) – Murat Karakuş Aug 7 '15 at 15:12
Links are not working. Need to be updated. – AttitudeMonger Dec 7 '15 at 16:04

You MUST use volatile when implementing lock-free data structures. Otherwise the compiler is free to optimize access to the variable, which will change the semantics.

To put it another way, volatile tells the compiler that accesses to this variable must correspond to a physical memory read/write operation.

For example, this is how InterlockedIncrement is declared in the Win32 API:

LONG __cdecl InterlockedIncrement(
  __inout  LONG volatile *Addend
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Developing for an embedded, I have a loop that checks on a variable that can be changed in an interrupt handler. Without "volatile", the loop becomes a noop - as far as the compiler can tell, the variable never changes, so it optimizes the check away.

Same thing would apply to a variable that may be changed in a different thread in a more traditional environment, but there we often do synchronization calls, so compiler is not so free with optimization.

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  1. you must use it to implement spinlocks as well as some (all?) lock-free data structures
  2. use it with atomic operations/instructions
  3. helped me once to overcome compiler's bug (wrongly generated code during optimization)
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You are better off using a library, compiler intrinsics, or inline assembly code. Volatile is unreliable. – Zan Lynx May 3 '09 at 17:16
1 and 2 both make use of atomic operations, but volatile does not provide atomic semantics and the platform-specific implementations of atomic will supercede the need for using volatile, so for 1 and 2, I disagree, you do NOT need volatile for these. – Dan Feb 13 '11 at 16:01
Who says anything about volatile providing atomic semantics? I said you need to USE volatile WITH atomic operations and if you don't think it's true look at the declarations of interlocked operations of win32 API (this guy also explained this in his answer) – Mladen Janković Feb 17 '11 at 13:05

A large application that I used to work on in the early 1990s contained C-based exception handling using setjmp and longjmp. The volatile keyword was necessary on variables whose values needed to be preserved in the block of code that served as the "catch" clause, lest those vars be stored in registers and wiped out by the longjmp.

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In Standard C, one of the places to use volatile is with a signal handler. In fact, in Standard C, all you can safely do in a signal handler is modify a volatile sig_atomic_t variable, or exit quickly. Indeed, AFAIK, it is the only place in Standard C that the use of volatile is required to avoid undefined behaviour.

ISO/IEC 9899:2011 § The signal function

¶5 If the signal occurs other than as the result of calling the abort or raise function, the behavior is undefined if the signal handler refers to any object with static or thread storage duration that is not a lock-free atomic object other than by assigning a value to an object declared as volatile sig_atomic_t, or the signal handler calls any function in the standard library other than the abort function, the _Exit function, the quick_exit function, or the signal function with the first argument equal to the signal number corresponding to the signal that caused the invocation of the handler. Furthermore, if such a call to the signal function results in a SIG_ERR return, the value of errno is indeterminate.252)

252) If any signal is generated by an asynchronous signal handler, the behavior is undefined.

That means that in Standard C, you can write:

static volatile sig_atomic_t sig_num = 0;

static void sig_handler(int signum)
    signal(signum, sig_handler);
    sig_num = signum;

and not much else.

POSIX is a lot more lenient about what you can do in a signal handler, but there are still limitations (and one of the limitations is that the Standard I/O library — printf() et al — cannot be used safely).

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Besides using it as intended, volatile is used in (template) metaprogramming. It can be used to prevent accidental overloading, as the volatile attribute (like const) takes part in overload resolution.

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I've used it in debug builds when the compiler insists on optimizing away a variable that I want to be able to see as I step through code.

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Beside the fact that the volatile keyword is used for telling the compiler not to optimize the access to some variable (that can be modified by a thread or an interrupt routine), it can be also used to remove some compiler bugs -- YES it can be ---.

For example I worked on an embedded platform were the compiler was making some wrong assuptions regarding a value of a variable. If the code wasn't optimized the program would run ok. With optimizations (which were really needed because it was a critical routine) the code wouldn't work correctly. The only solution (though not very correct) was to declare the 'faulty' variable as volatile.

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It is a faulty assumption the idea that the compiler doesn't optimize access to volatiles. The standard knows nothing about optimizations. The compiler is required to respect what the standard dictates, but it is free to do any optimizations that don't interfere with the normal behavior. – Terminus Sep 25 '08 at 10:22
From my experience 99.9% of all optimization "bugs" in gcc arm are errors on the part of the programmer. No idea if this applies to this answer. Just a rant on the general topic – PorkyBrain Dec 31 '13 at 0:11

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