C++中volatile和mutable關(guān)鍵字用法詳解

更新時間：2020年02月01日 14:03:05 作者：fengbingchun

這篇文章主要介紹了C++中volatile和mutable關(guān)鍵字用法詳解,文中通過示例代碼介紹的非常詳細，對大家的學習或者工作具有一定的參考學習價值，需要的朋友們下面隨著小編來一起學習學習吧

C/C++中的volatile關(guān)鍵字和const對應，用來修飾變量，用于告訴編譯器該變量值是不穩(wěn)定的，可能被更改。使用volatile注意事項：

(1). 編譯器會對帶有volatile關(guān)鍵字的變量禁用優(yōu)化(A volatile specifier is a hint to a compiler that an object may change its value in ways not specified by the language so that aggressive optimizations must be avoided)。

(2). 當多個線程都要用到某一個變量且該變量的值會被改變時應該用volatile聲明，該關(guān)鍵字的作用是防止編譯器優(yōu)化把變量從內(nèi)存裝入CPU寄存器中。如果變量被裝入寄存器，那么多個線程有可能有的使用內(nèi)存中的變量，有的使用寄存器中的變量，這會造成程序的錯誤執(zhí)行。volatile的意思是讓編譯器每次操作該變量時一定要從內(nèi)存中取出，而不是使用已經(jīng)存在寄存器中的值(It cannot cache the variables in register)。

(3). 中斷服務程序中訪問到的變量最好帶上volatile。

(4). 并行設(shè)備的硬件寄存器的變量最好帶上volatile。

(5). 聲明的變量可以同時帶有const和volatile關(guān)鍵字。

(6). 多個volatile變量間的操作，是不會被編譯器交換順序的，能夠保證volatile變量間的順序性，編譯器不會進行亂序優(yōu)化(The value cannot change in order of assignment)。但volatile變量和非volatile變量之間的順序，編譯器不保證順序，可能會進行亂序優(yōu)化。

C++中的mutable關(guān)鍵字使用場景：

(1). 允許即使包含它的對象被聲明為const時仍可修改聲明為mutable的類成員(sometimes there is requirement to modify one or more data members of class/struct through const function even though you don't want the function to update other members of class/struct. This task can be easily performed by using mutable keyword)。

(2). 應用在C++11 lambda表達式來表示按值捕獲的值是可修改的，默認情況下是不可修改的，但修改僅在lambda式內(nèi)有效(since c++11 mutable can be used on a lambda to denote that things captured by value are modifiable (they aren't by default))。

詳細用法見下面的測試代碼，下面是從其他文章中copy的測試代碼，詳細內(nèi)容介紹可以參考對應的reference：

#include "volatile_mutable.hpp"
#include <iostream>
#include <stdio.h>
#include <time.h>
#include <mutex>
#include <string.h>
 
namespace volatile_mutable_ {
 
///////////////////////////////////////////////////////////
int test_volatile_1()
{
 volatile int i1 = 0; // correct
 int volatile i2 = 0; // correct
 
 return 0;
}
 
///////////////////////////////////////////////////////////
// reference: https://en.cppreference.com/w/c/language/volatile
int test_volatile_2()
{
{ // Any attempt to read or write to an object whose type is volatile-qualified through a non-volatile lvalue results in undefined behavior
 volatile int n = 1; // object of volatile-qualified type
 int* p = (int*)&n;
 int val = *p; // undefined behavior in C, Note: link does not report an error under C++
 fprintf(stdout, "val: %d\n", val);
}
 
{ // A member of a volatile-qualified structure or union type acquires the qualification of the type it belongs to
 typedef struct ss { int i; const int ci; } s;
 // the type of s.i is int, the type of s.ci is const int
 volatile s vs = { 1, 2 };
 // the types of vs.i and vs.ci are volatile int and const volatile int
}
 
{ // If an array type is declared with the volatile type qualifier (through the use of typedef), the array type is not volatile-qualified, but its element type is
 typedef int A[2][3];
 volatile A a = { {4, 5, 6}, {7, 8, 9} }; // array of array of volatile int
 //int* pi = a[0]; // Error: a[0] has type volatile int*
 volatile int* pi = a[0];
}
 
{ // A pointer to a non-volatile type can be implicitly converted to a pointer to the volatile-qualified version of the same or compatible type. The reverse conversion can be performed with a cast expression
 int* p = nullptr;
 volatile int* vp = p; // OK: adds qualifiers (int to volatile int)
 //p = vp; // Error: discards qualifiers (volatile int to int)
 p = (int*)vp; // OK: cast
}
 
{ // volatile disable optimizations
 clock_t t = clock();
 double d = 0.0;
 for (int n = 0; n < 10000; ++n)
 for (int m = 0; m < 10000; ++m)
  d += d * n*m; // reads and writes to a non-volatile 
 fprintf(stdout, "Modified a non-volatile variable 100m times. Time used: %.2f seconds\n", (double)(clock() - t) / CLOCKS_PER_SEC);
 
 t = clock();
 volatile double vd = 0.0;
 for (int n = 0; n < 10000; ++n)
 for (int m = 0; m < 10000; ++m)
  vd += vd * n*m; // reads and writes to a volatile 
 fprintf(stdout, "Modified a volatile variable 100m times. Time used: %.2f seconds\n", (double)(clock() - t) / CLOCKS_PER_SEC);
}
 
 return 0;
}
 
///////////////////////////////////////////////////////////
// reference: https://en.cppreference.com/w/cpp/language/cv
int test_volatile_3()
{
 int n1 = 0;      // non-const object
 const int n2 = 0;   // const object
 int const n3 = 0;   // const object (same as n2)
 volatile int n4 = 0; // volatile object
 const struct {
 int n1;
 mutable int n2;
 } x = { 0, 0 };   // const object with mutable member
 
 n1 = 1; // ok, modifiable object
 //n2 = 2; // error: non-modifiable object
 n4 = 3; // ok, treated as a side-effect
 //x.n1 = 4; // error: member of a const object is const
 x.n2 = 4; // ok, mutable member of a const object isn't const
 
 const int& r1 = n1; // reference to const bound to non-const object
 //r1 = 2; // error: attempt to modify through reference to const
 const_cast<int&>(r1) = 2; // ok, modifies non-const object n1
 fprintf(stdout, "n1: %d\n", n1); // 2
 
 const int& r2 = n2; // reference to const bound to const object
 //r2 = 2; // error: attempt to modify through reference to const
 const_cast<int&>(r2) = 2; // undefined behavior: attempt to modify const object n2, Note: link does not report an error under C++
 fprintf(stdout, "n2: %d\n", n2); // 0
 
 return 0;
}
 
///////////////////////////////////////////////////////////
// reference: https://www.geeksforgeeks.org/understanding-volatile-qualifier-in-c/
int test_volatile_4()
{
{
 const int local = 10;
 int *ptr = (int*)&local;
 fprintf(stdout, "Initial value of local : %d \n", local); // 10
 
 *ptr = 100;
 fprintf(stdout, "Modified value of local: %d \n", local); // 10
}
 
{
 const volatile int local = 10;
 int *ptr = (int*)&local;
 fprintf(stdout, "Initial value of local : %d \n", local); // 10
 
 *ptr = 100;
 fprintf(stdout, "Modified value of local: %d \n", local); // 100
}
 
 return 0;
}
 
///////////////////////////////////////////////////////////
// reference: https://en.cppreference.com/w/cpp/language/cv
int test_mutable_1()
{
 // Mutable is used to specify that the member does not affect the externally visible state of the class (as often used for mutexes,
 // memo caches, lazy evaluation, and access instrumentation)
 class ThreadsafeCounter {
 public:
 int get() const {
  std::lock_guard<std::mutex> lk(m);
  return data;
 }
 void inc() {
  std::lock_guard<std::mutex> lk(m);
  ++data;
 }
 
 private:
 mutable std::mutex m; // The "M&M rule": mutable and mutex go together
 int data = 0;
 };
 
 return 0;
}
 
///////////////////////////////////////////////////////////
// reference: https://www.tutorialspoint.com/cplusplus-mutable-keyword
int test_mutable_2()
{
 class Test {
 public:
 Test(int x = 0, int y = 0) : a(x), b(y) {}
 
 void seta(int x = 0) { a = x; }
 void setb(int y = 0) { b = y; }
 void disp() { fprintf(stdout, "a: %d, b: %d\n", a, b); }
 
 public:
 int a;
 mutable int b;
 };
 
 const Test t(10, 20);
 fprintf(stdout, "t.a: %d, t.b: %d \n", t.a, t.b); // 10, 20
 
 //t.a=30; // Error occurs because a can not be changed, because object is constant.
 t.b = 100; // b still can be changed, because b is mutable.
 fprintf(stdout, "t.a: %d, t.b: %d \n", t.a, t.b); // 10, 100
 
 return 0;
}
 
///////////////////////////////////////////////////////////
// reference: https://www.geeksforgeeks.org/c-mutable-keyword/
int test_mutable_3()
{
 using std::cout;
 using std::endl;
 
 class Customer {
 public:
 Customer(char* s, char* m, int a, int p)
 {
  strcpy(name, s);
  strcpy(placedorder, m);
  tableno = a;
  bill = p;
 }
 
 void changePlacedOrder(char* p) const { strcpy(placedorder, p); }
 void changeBill(int s) const { bill = s; }
 
 void display() const
 {
  cout << "Customer name is: " << name << endl;
  cout << "Food ordered by customer is: " << placedorder << endl;
  cout << "table no is: " << tableno << endl;
  cout << "Total payable amount: " << bill << endl;
 }
 
 private:
 char name[25];
 mutable char placedorder[50];
 int tableno;
 mutable int bill;
 };
 
 const Customer c1("Pravasi Meet", "Ice Cream", 3, 100);
 c1.display();
 c1.changePlacedOrder("GulabJammuns");
 c1.changeBill(150);
 c1.display();
 
 return 0;
}
 
///////////////////////////////////////////////////////////
// reference: https://stackoverflow.com/questions/105014/does-the-mutable-keyword-have-any-purpose-other-than-allowing-the-variable-to
int test_mutable_4()
{
 int x = 0;
 auto f1 = [=]() mutable { x = 42; }; // OK
 //auto f2 = [=]() { x = 42; }; // Error: a by-value capture cannot be modified in a non-mutable lambda
 fprintf(stdout, "x: %d\n", x); // 0
 
 return 0;
}
 
} // namespace volatile_mutable_

GitHub：https://github.com/fengbingchun/Messy_Test

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