The use Referring to objects of incomplete class declarations (type, also known as "forward " declarations) , is a common . While it is possible to declare pointers and references to incomplete classes, because the class definition is not available it's not possible to access a member of the class, determine the size of the class object, and so on. However, it is possible to cast and delete a pointer to an incomplete class, but this is never a good idea.
Non-Compliant Code Example
practice. One such common usage is with the "pimpl idiom" [Sutter 00] whereby an opaque pointer is used to hide implementation details from a public-facing API. However, attempting to delete a pointer to an object of incomplete class type can lead to undefined behavior. The C++ Standard, [expr.delete], paragraph 5 [ISO/IEC 14882-2014], states the following:
If the object being deleted has incomplete class type at the point of deletion and the complete class has a non-trivial destructor or a deallocation function, the behavior is undefined.
Do not attempt to delete a pointer to an object of incomplete type. Although it is well-formed if the class has no nontrivial destructor and no associated deallocation function, it would become undefined behavior were a nontrivial destructor or deallocation function added later. It would be possible to check for a nontrivial destructor at compile time using a static_assert
and the std::is_trivially_destructible
type trait, but no such type trait exists to test for the presence of a deallocation function.
Pointer downcasting to a pointer of incomplete class type has similar caveats. Pointer upcasting (casting from a more derived type to a less derived type) is a standard implicit conversion operation. C++ allows static_cast
to perform the inverse operation, pointer downcasting, via [expr.static.cast], paragraph 7. However, when the pointed-to type is incomplete, the compiler is unable to make any class offset adjustments that may be required in the presence of multiple inheritance, resulting in a pointer that cannot be validly dereferenced.
reinterpret_cast
of a pointer type is defined by [expr.reinterpret.cast], paragraph 7, as being static_cast<cv T *>(static_cast<cv void *>(PtrValue))
, meaning that reinterpret_cast
is simply a sequence of static_cast
operations. C-style casts of a pointer to an incomplete object type are defined as using either static_cast
or reinterpret_cast
(it is unspecified which is picked) in [expr.cast], paragraph 5.
Do not attempt to cast through a pointer to an object of incomplete type. The cast operation itself is well-formed, but dereferencing the resulting pointer may result in undefined behavior if the downcast is unable to adjust for multiple inheritance.
Noncompliant Code Example
In this noncompliant code example, a class attempts to implement the pimpl idiom but deletes a pointer to an incomplete class type, resulting in undefined behavior if Body
has a nontrivial destructorConsider a common application of a handle/body idiom that implements an abstract data type by a handle that contains a pointer to an implementation class.
Code Block | ||||
---|---|---|---|---|
| ||||
class Handle { class Body *impl; // Declaration incompleteof class declaration class Handle { public: Handle(); a pointer to an incomplete class public: ~Handle() { delete impl_; } // deletionDeletion of pointer to an incomplete class // ... private: Body *impl_; }; |
Because impl_
is a pointer to an undefined class, its deletion in Handle
's destructor results in undefined behavior if Body
has a non-trivial destructor. Even in the case where Body
does have a non-trivial destructor, this practice should be avoided. During maintenance a non-trivial destructor could be added to Body
, resulting in undefined behavior in the destructor for Handle
.
Compliant Solution 1
Compliant Solution (delete
)
In this compliant solution, the deletion of impl
is The deletion of impl_
should be moved to a part of the code where where Body
is defined.
Code Block | ||||
---|---|---|---|---|
| ||||
class Handle { class Body { *impl; // Declaration of a pointer to an incomplete class public: ~Handle(); // ... }; // Elsewhere class Body { /* ... */ }; Handle::~Handle() { delete impl_; } // correct. } |
Compliant Solution
...
(std::shared_ptr
)
In this compliant solution, a std::shared_ptr
is used to own the memory to impl
. A std::shared_ptr
is capable of referring to an incomplete type, but a std::unique_ptr
is notAlternatively, an appropriate smart pointer may be used in place of a raw pointer.
Code Block | ||||
---|---|---|---|---|
| ||||
#include <memory> class Handle { std::shared_ptr<class Body> impl; public: Handle(); ~Handle() {} // correct. // ... private: std::tr1::shared_ptr<Body> impl_; }; |
Note that we used a shared_ptr
to refer to the Body
. Other common smart pointers, including std::auto_ptr
, will still produce undefined behavior.
Non-Compliant Code Example
Noncompliant Code Example
Pointer downcasting (casting a pointer to a base class into a pointer to a derived class) may require adjusting the address of the pointer Similarly, while it is possible to cast a pointer or reference to an incomplete class, it is never a good idea to do so. Casting a class address often involves an adjustment of the address by a fixed amount that can only be determined after only when the layout and inheritance structure of the class inheritance structure is known, and this information is not available in the case of an incomplete class. In this noncompliant code example, f()
retrieves a polymorphic pointer of complete type B
from get_d()
. That pointer is then cast to a pointer of incomplete type D
before being passed to g()
. Casting to a pointer to the derived class may fail to properly adjust the resulting pointer, causing undefined behavior when the pointer is dereferenced by calling d->do_something()
.
Code Block | ||||
---|---|---|---|---|
| ||||
// File1.h class B { protected: double d; public: B() : d(1.0) {} }; // File2.h void g(class D *); class B *get_d(); // Returns a pointer to a D object // File1.cpp #include "File1.h" #include "File2.h" void f() { B *v = get_d(); g(reinterpret_cast<class D *>(v)); } // File2.cpp #include "File2.h" #include "File1.h" #include <iostream> class Hah { protected: short s; public: Hah() : s(12) {} }; class D : public Hah, public B { float f; public: *getMeSomeSOrtOfB(); ... class D; // incomplete declaration ... B *bp = getMeSomeSortOfB(); D *dp = (D *)bp; // old-stlye cast: legal, but inadvisable dp = reinterpret_cast<D *>(bp); // new-style cast: legal, but inadvisable |
Both an old-stlye cast and a reinterpret_cast
may be used to cast the value
Risk Assessment
XXX
D() : Hah(), B(), f(1.2f) {}
void do_something() { std::cout << "f: " << f << ", d: " << d << ", s: " << s << std::endl; }
};
void g(D *d) {
d->do_something();
}
B *get_d() {
return new D;
}
|
Implementation Details
When compiled with ClangBB. Definitions#clang3.8 and the function f()
is executed, the noncompliant code example prints the following.
Code Block |
---|
f: 1.89367e-40, d: 5.27183e-315, s: 0 |
Similarly, unexpected values are printed when the example is run in Microsoft Visual Studio 2015 and GCC 6.1.0.
Compliant Solution
This compliant solution assumes that the intent is to hide implementation details by using incomplete class types. Instead of requiring a D *
to be passed to g()
, it expects a B *
type.
Code Block | ||||
---|---|---|---|---|
| ||||
// File1.h -- contents identical.
// File2.h
void g(class B *); // Accepts a B object, expects a D object
class B *get_d(); // Returns a pointer to a D object
// File1.cpp
#include "File1.h"
#include "File2.h"
void f() {
B *v = get_d();
g(v);
}
// File2.cpp
// ... all contents are identical until ...
void g(B *d) {
D *t = dynamic_cast<D *>(d);
if (t) {
t->do_something();
} else {
// Handle error
}
}
B *get_d() {
return new D;
} |
Risk Assessment
Casting pointers or references to incomplete classes can result in bad addresses. Deleting a pointer to an incomplete class results in undefined behavior if the class has a nontrivial destructor. Doing so can cause program termination, a runtime signal, or resource leaks.
Rule | Severity | Likelihood | Remediation Cost | Priority | Level |
---|
EXP57- |
1 (low)
2 (probable)
CPP | Medium | Unlikely | Medium | P4 | L3 |
References
Automated Detection
Tool | Version | Checker | Description | ||||||
---|---|---|---|---|---|---|---|---|---|
Astrée |
| delete-with-incomplete-type | |||||||
Coverity | 6.5 | DELETE_VOID | Fully implemented | ||||||
Clang |
| -Wdelete-incomplete | |||||||
CodeSonar |
| LANG.CAST.PC.INC | Conversion: pointer to incomplete | ||||||
Helix QAC |
| C++3112 | |||||||
Klocwork |
| CERT.EXPR.DELETE_PTR.INCOMPLETE_TYPE | |||||||
LDRA tool suite |
| 169 S, 554 S | Enhanced Enforcement | ||||||
Parasoft C/C++test |
| CERT_CPP-EXP57-a | Do not delete objects with incomplete class at the point of deletion | ||||||
Parasoft Insure++ | Runtime detection | ||||||||
Polyspace Bug Finder |
| CERT C++: EXP57-CPP | Checks for conversion or deletion of incomplete class pointer | ||||||
RuleChecker |
| delete-with-incomplete-type |
Related Vulnerabilities
Search for vulnerabilities resulting from the violation of this rule on the CERT website.
Bibliography
[Dewhurst 2002] | Gotcha #39, "Casting Incomplete Types" |
[ISO/IEC 14882-2014] | Subclause 4.10, "Pointer Conversions" |
[Sutter 2000] | "Compiler Firewalls and the Pimpl Idiom" |
...
\[[Dewhurst 03|AA. C++ References#Dewhurst 04]\] Gotcha 39: Casting Incomplete Types Wiki Markup