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When implementing a copy operator, do not mutate any externally observable members of the source object operand or globally accessible information. Externally observable members include, but are not limited to, members that participate in comparison or equality operations, members whose values are exposed via public APIs, and global variables.

Before C++11, a copy operation that mutated the source operand was the only way to provide move-like semantics. However, the language did not provide a way to enforce that this operation only occurred when the source operand was at the end of its lifetime, which led to fragile APIs like std::auto_ptr. In C++11 and later, such a situation is a good candidate for a move operation instead of a copy operation.

auto_ptr

For example, in C++03, std::auto_ptr had the following copy operation signatures (note: std::auto_ptr was deprecated in C++11) [ISO/IEC 14882-2003]:

Copy constructorauto_ptr(auto_ptr &A);
Copy assignmentauto_ptr& operator=(auto_ptr &A);

Both copy construction and copy assignment would mutate the source argument, A, by effectively calling this->reset(A.release()). However, this invalidated assumptions made by standard library algorithms such as std::sort(), which may need to make a copy of an object for later comparisons [Hinnant 05]. Consider an implementation the following implementation of std::sort() that implements the quick sort algorithm:.

Code Block
// ...
value_type pivot_element = *mid_point;
// ...

At this point, the sorting algorithm assumes that pivot_element and *mid_point have equivalent value representations and will compare equal. However, for std::auto_ptr, this is not the case because *mid_point has been mutated, and mutated and results in unexpected behavior.

Before In C++11, a copy operation that mutated the source operand was the only way to provide move-like semantics. However, the language did not provide a way to enforce that this operation only occurred when the source operand was at the end of its lifetime, which led to fragile APIs like the std::unique_ptr smart pointer class was introduced as a replacement for std::auto_ptr to better specify the ownership semantics of pointer objects. Rather than mutate the source argument in a copy operation, std::unique_ptr explicitly deletes the copy constructor and copy assignment operator, and instead uses a move constructor and move assignment operator. Subsequently, std::auto_ptr. In  was deprecated in C++11 and later, such a situation is a good candidate for a move operation instead of a copy operation.

Noncompliant Code Example

In this noncompliant code example, the copy operations for A mutate the source operand by resetting its member variable m to 0. When std::fill() is called, the first element copied will have the original value of obj.m12, at which point obj.m is set to 0. The subsequent nine copies will all retain the value 0.

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In this compliant solution, the copy operations for A no longer mutate the source operand, ensuring that the vector contains equivalent copies of obj. Instead, A has been given move operations that perform the mutation when it is safe to do so.

Code Block
bgColor#ccccff
langcpp
#include <algorithm>
#include <vector>

class A {
  int m;
  
public:
  A() : m(0) {}
  explicit A(int m) : m(m) {}
  
  A(const A &other) : m(other.m) {}
  A(A &&other) : m(other.m) { other.m = 0; }
  
  A& operator=(const A &other) {
    if (&other != this) {
      m = other.m;
    }
    return *this;
  }
 
  A& operator=(A &&other) {
    m = other.m;
    other.m = 0;
    return *this;
  }
  
  int get_m() const { return m; }
};

void f() {
  std::vector<A> v{10};
  A obj(12);
  std::fill(v.begin(), v.end(), obj);
}

Exceptions

OOP58-CPP-EX0: Reference counting, and implementations such as std::shared_ptr<> constitute an exception to this rule. Any copy or assignment operation of a reference-counted object requires the reference count to be incremented. The semantics of reference counting are well-understood, and it can be argued that the reference count is not a salient part of the shared_pointer object.

Risk Assessment

Copy operations that mutate the source operand or global state can lead to unexpected program behavior. In the case of using Using such a type in a Standard Template Library container or algorithm , this can also lead to undefined behavior.

Rule

Severity

Likelihood

Remediation Cost

Priority

Level

OOP58-CPP

Low

Likely

Low

P9

L2

Automated Detection

Tool

Version

Checker

Description

   

CodeSonar
Include Page
CodeSonar_V
CodeSonar_V

LANG.FUNCS.COPINC

Copy Operation Parameter Is Not const

Helix QAC

Include Page
Helix QAC_V
Helix QAC_V

C++4075
Klocwork
Include Page
Klocwork_V
Klocwork_V

CERT.OOP.COPY_MUTATES 


Parasoft C/C++test

Include Page
Parasoft_V
Parasoft_V

CERT_CPP-OOP58-a

Copy operations must not mutate the source object
Polyspace Bug Finder

Include Page
Polyspace Bug Finder_V
Polyspace Bug Finder_V

CERT C++: OOP58-CPPChecks for copy operation modifying source operand (rule partially covered)
 

Related Vulnerabilities

Search for vulnerabilities resulting from the violation of this rule on the CERT website.

Related Guidelines

Bibliography

[ISO/IEC 14882-2014]Subclause 12.8, "Copying and Moving Class Objects"
Table 21, "CopyConstructible Requirements"
Table 23, "CopyAssignable Requirements" 
[ISO/IEC 14882-2003]
 

[Hinnant
05
2005]"Rvalue Reference Recommendations for Chapter 20"

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