Inversion of control is a value-proof technique which is used to modularize a system and decouple the components from each other.
Low coupling is always an advantage: it
class object
{
public:
object(dependency d) : dep_(d) {}
private:
dependency dep_;
};
Only works in case dependency
class is completely stateless, i.e. doesn't have any members. Practically, this rarely happens because dependency
class may store its own dependency.
class object
{
public:
object(dependency *d) : dep_(d)
{
if (d == nullptr)
throw std::exception("null dependency");
}
private:
dependency *dep_;
};
This works like true injection. We're required to check the passed pointer for nullptr
value.
object
class does not own dependency
class, thus it's the responsibility of calling code to make sure the object
is destroyed before the dependency
object.
In real application, it's sometimes very difficult to validate.
#define DISALLOW_COPY_AND_ASSIGN(Class) \
Class(const Class &) = delete; \
Class &operator=(const Class &) = delete
class object
{
public:
object(dependency &d) : dep_(d) {}
DISALLOW_COPY_AND_ASSIGN(object);
private:
dependency &dep_;
};
The reference cannot be null, so it's a bit safer in this prospective.
However this approach brings additional constraints to object
class: it has to be non-copyable since a reference cannot be copied. You have to either manually override assignment operator and copy constructor to stop from copying or inherit it from something like boost::noncopyable
.
Like with raw pointer, the ownership constraint is in place. Calling code should provide the correct destruction order for both classes, otherwise the reference becomes invalid and application crashes with access violation.
If the dependency is a const reference:
class object
{
public:
object(const dependency &d) : dep_(d) {}
private:
const dependency &dep_;
};
you should pay attention to the fact that the object
class accepts references to temporary objects:
dependency d;
object o1(d); // this is ok, but...
object o2(dependency()); // ... this is BAD.
Further details:
class object
{
public:
object(std::shared_ptr d) : dep_(d)
{
if (!d)
throw std::exception("null dependency");
}
private:
std::shared_ptr dep_;
};
Similar to raw pointer but the ownership is controlled by smart pointer mechanism.
Still need to check for nullptr
in the constructor body.
The major advantage is the dependency
object lifetime control: there is no need for the calling application to properly control the destruction order (but consider that you need to be very careful when designing your APIs with std::shared_ptr).
Once the dependency
class is no longer used it's automatically destroyed by shared_ptr
destructor.
There are cases when shared_ptr
owned objects are not destroyed (so called cyclic references). However, with constructor injection, cyclic dependencies aren't possible due to the specific well-defined order of construction.
This works of course if no other injection methods are used across the application.
A smart pointer has a small overhead but it isn't a real problem in the majority of cases.
Further details: