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The volatile keyword tells the compiler not to optimize the variable which is prefixed. The variable may change during run time by unknown source (not known by the compiler) maybe by an external interrupt etc.

Is there any other advantage of volatile? Does volatile apply to reading from files?

closed as too broad by user3386109, jim mcnamara, Micha Wiedenmann, Soner Gönül, durron597 May 27 '15 at 23:49

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    Are you sure the compiler knows all the interrupts and takes that into account when compiling the code? – M.M May 27 '15 at 3:36
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    The volatile keyword does no such thing. Seek clarification from within section 5.1.2.3p4. – autistic May 27 '15 at 3:42
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    without volatile how can you define and access memory-mapped registers? – phuclv May 27 '15 at 3:49
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    @undefinedbehaviour no, registers will be defined like #define SFR (volatile char *)0x1234. There's no OS for you to get memory-mapped files – phuclv May 27 '15 at 4:15
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    @undefined behaviour. Please, give me a code example where you avoid the use of volatile accessing a register of an AVR ATmega168? (I.E.: the TCNT1 register) ATmega168 datasheet – Sir Jo Black May 27 '15 at 12:08
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volatile keyword says to compiler do not optimize the variable which is prefixed with, the variable may change during run time by unknown source(not known to compiler) may be by an external interrupt etc.

No. The volatile keyword does not tell the compiler to disable or not optimize a variable; the volatile keyword tells the compiler that the variable (or rather the memory that the variable represents) may be modified externally to the program.

This has the effect that the compiler is no longer able to do the necessary analysis to determine if various optimizations are safe (that is functionally equivalent), so the compiler does not perform those optimizations. This is a necessary side-effect, but not the primarily purpose for the existence of the keyword.

The usage of volatile as a somewhat or slightly portable hack of acting like a pragma to disable the compiler's optimization is a fairly common pattern. Outside of embedded programming, this may be its most commonly encountered usage for application programmers.

The compiler knows all the interrupts of that controller. So in that case how the volatile keyword helps?

The volatile keyword means the memory contents can be modified outside of the program's control, either in another process, thread, or by external signals such as a hardware interrupt.

Compilers don't "know" about interrupts, there may be system header files distributed with a compiler that define symbolic names for an interrupt, but that does not mean the compiler understands them.

Is there any other advantage of volatile?

Not that I can think of, beside what's described here.

[Does] volatile appl[y] to reading from files?

Except when used as an form of inter-process communication (IPC) or as a semaphore, the contents of a file are normally controlled by a single process, so the usage of volatile is not necessary.

  • Nice explanation Mr.mctylr, thank you. Now i got clear picture of how volatile keyword acts. – Lokesh V Gowda May 27 '15 at 5:01
  • And one more question, Can i assume I/O connected ADC as example. So ADC value changes anytime from outise world, this is not known to compiler. – Lokesh V Gowda May 27 '15 at 5:05
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    Yes an memory mapped I/O connection, such as an ADC input, is a good example of a case where volatile keyword may be used. The variable's contents are controlled outside of the program's control (i.e. it is controlled by the ADC), and so may change without the compiler knowing. – mctylr May 28 '15 at 0:37
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volatile actually tells the compiler the value of the variable may be changed outside its control flow. The most popular would be an interrupt or interrupt handler or a hardware register. For the latter, the compiler does actually not know when its value changes. Nor does it for an interrupt, as that only occurs at run-time.

Note that C assumes a single threaded program flow; the compiler does not have any idea of concurrent processes. Even less does it make assumptions on the underlying hardware.

For all other variables, the compiler may (gcc for instance actually will) assume it has full knowledge about the system state.

Also accesses to volatile variables may not be reordered with respect to each other. This is important when e.g. a UART requires the status register to be read first and then a new char may be stored to the transmit data register. For most MCUs, only this sequence will clear the flags properly. Very important: non-vloatile variables may be reordered as much as the compiler wants to (as long it does not change the program logic, of course).

Note that volatile does not guarantee atomicity and correct behaviour on multicore-systems or does protect against re-ordering of accesses by the hardware (memory controller, etc.) (well, the AVR is a bit underprivileged with all these ;-). That is one reason for locks and why hardware-areas in the memory map are treated special by the hardware (ordered, non-shared).

Edit:

Here is detailed how gcc handles volatile objects. gcc is known to strictily keep to the standard for optimizations. Anything not forbidden might be exploited for optimization. Classic embedded compilers like IAR are often much more conservative.

  • More specifically, in an Arduino, the volatile keyword directs the compiler to [produce code that] loads the variable from RAM and not from a storage register. See arduino.cc/en/reference/volatile – Robert Harvey May 27 '15 at 3:41
  • @RobertHarvey: Ehm.. I was sure we're talking about C and AVR, not arduino. (btw: thanks for the edit). – too honest for this site May 27 '15 at 3:44
  • You had me doubting so I went back and double-checked. Sure enough, I was right the first time; Arduino uses AtMega processors, and the AtMega128 is cited in the question. – Robert Harvey May 27 '15 at 3:49
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    @RobertHarvey: Well, yes (could have told you, too)! But ATMega does not use arduino necessarily ;-). – too honest for this site May 27 '15 at 3:51
  • I don't know what the processor cross-pollination is. But it seems pretty clear that the motivation is to ask the processor to go get the value from its source, rather than relying on a (possibly stale) cached value in a register. – Robert Harvey May 27 '15 at 3:52
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The C / C++ standard for volatile means that reads and writes to a volatile variable will be a read or write to that location in memory, and that the order of operations to a volatile variable will be maintained. Since reads from a volatile variable are actually reads of the variable in memory, then if the variable is updated by an outside source such as another thread, process, or hardware, the value read will reflect any writes that occurred before the read. It's meant to be used for memory mapped hardware interfaces such as I/O memory mapped ports. It doesn't prevent out of order operations on other variables. I assume that the order of operations on multiple volatile variables is maintained, since this would be needed for hardware / software handshake.

Microsoft compilers optionally extend the meaning of volatile so that read / write operations to volatile variables are effectively done as a memory barrier and can be use for communication between threads. MSDN volatile .

  • Note that the order is only maintained for a single process. And even that is not guaranteed as any instance in-between might reorder accesses. That's the reason atomics have been introduced in C11. – too honest for this site May 27 '15 at 3:41
  • Well, yes - and no - Yes: for simple atomic operations, but this is often enough (just think of a very wide counter (larger than CPU-word width) which is incremented by one thread and read by multiple others - for example). However, have a look at atomic_compare_exchange(). This is the basis for many non-blocking & lock-less algorithms (e.g. lists). Just search for this. – too honest for this site May 27 '15 at 4:09
  • Then you might re-read and concentrate on the memory_order constraints. There you will find the barriers. stdatomic.h however also provides an explicit fence (aka barrier, actually two) instruction. In general, atomicity is a system-wide concept. However, DMA and peripheral registers are not included, I'd say it is all components which implicitly execute the current program (that composed of the compilation units discussed). – too honest for this site May 27 '15 at 12:29
  • MSDN is definitively not the relevant standard and a very bad reference for C - most will not accept this as such. They deliberately do not even support C99. You really should first understand before confronting. If in doubt, read the standard (the last draft n1570 is available for free download). – too honest for this site May 27 '15 at 20:02
  • @Olaf - Then I don't understand the point of your first comment. In my answer, I clearly state that the standard volatile does not act as a memory barrier, but that Microsoft compilers (Visual Studio) optionally (the default for X86) cause volatile to act as a memory barrier. – rcgldr May 27 '15 at 20:09
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volatile, as you mentioned, is a guarantee that the compiler will perform no optimizations regarding the variable. If a variable's value isn't changed in a scope as determined by the compiler, it may cache the value to a register and refer to that cached value for efficiency so it doesn't waste cycles fetching the actual value from main memory.

I'd imagine in a microcontroller with such limited amounts of registers, you wouldn't want to cache variables constantly.

  • What would be an "optimized variable"? I just can think of proper alignment. And: that is not just a matter of scope, but system state. – too honest for this site May 27 '15 at 3:37
  • THe problem with volatile in general is, while the compiler does gurantee that, the hardware might actually not. – too honest for this site May 27 '15 at 3:42
  • Right, interrupts and waking from sleep/brownouts are examples. I guess this is what you mean by system state. – erip May 27 '15 at 3:45
  • System state is the whole "state of the system". Just think of all storage cells (variables, constants, CPU registers, peripheral registers, bus-interface registers, ... - everything) as a veeerrrry wide state-variable of a FSM - finite state machine, read about that). Interrupts are actually not part of that, but the interrupt flag bit would be, as much as the interrupt enable bit, etc. – too honest for this site May 27 '15 at 12:43

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