First we need to go back to what it means to pass by value and by reference.
For languages like Java and SML, pass by value is straightforward (and there is no pass by reference), just as copying a variable value is, as all variables are just scalars and have builtin copy semantic: they are either what who count as arithmetic type in C++, or "references" (pointers with different name and syntax).
In C we have scalar and user defined types:
- Scalars have a numeric or abstract value (pointers are not numbers, they have an abstract value) that is copied.
- Aggregate types have all their possibly initialized members copied:
- for product types (arrays and structures): recursively, all members of structures and elements of arrays are copied (the C function syntax doesn't make it possible to pass arrays by value directly, only arrays members of a struct, but that's a detail).
- for sum types (unions): the value of the "active member" is preserved; obviously, member by member copy isn't in order as not all members can be initialized.
In C++ user defined types can have user defined copy semantic, which enable truly "object oriented" programming with objects with ownership of their resources and "deep copy" operations. In such case, a copy operation is really a call to a function that can almost do arbitrary operations.
For C structs compiled as C++, "copying" is still defined as calling the user defined copy operation (either constructor or assignment operator), which are implicitly generated by the compiler. It means that the semantic of a C/C++ common subset program is different in C and C++: in C a whole aggregate type is copied, in C++ an implicitly generated copy function is called to copy each member; the end result being that in either case each member is copied.
(There is an exception, I think, when a struct inside a union is copied.)
So for a class type, the only way (outside union copies) to make a new instance is via a constructor (even for those with trivial compiler generated constructors).
You can't take the address of an rvalue via unary operator &
but that doesn't mean that there is no rvalue object; and an object, by definition, has an address; and that address is even represented by a syntax construct: an object of class type can only be created by a constructor, and it has a this
pointer; but for trivial types, there is no user written constructor so there no place to put this
until after the copy is constructed, and named.
For scalar type, the value of an object is the rvalue of the object, the pure mathematical value stored into the object.
For a class type, the only notion of a value of the object is another copy of the object, which can only be made by a copy constructor, a real function (although for trivial types that function is so specially trivial, these can sometimes be created without calling the constructor). That means that the value of object is the result of change of global program state by an execution. It doesn't access mathematically.
So pass by value really isn't a thing: it's pass by copy constructor call, which is less pretty. The copy constructor is expected to perform a sensible "copy" operation according to the proper semantic of the object type, respecting its internal invariants (which are abstract user properties, not intrinsic C++ properties).
Pass by value of a class object means:
- create another instance
- then make the called function act on that instance.
Note that the issue has nothing to do with whether the copy itself is an object with an address: all function parameters are objects and have an address (at the language semantic level).
The issue is whether:
- the copy is a new object initialized with the pure mathematical value (true pure rvalue) of original object, as with scalars;
- or the copy is the value of original object, as with classes.
In the case of a trivial class type, you can still define the member of member copy of the original, so you get to define the pure rvalue of the original because of triviality of the copy operations (copy constructor and assignment). Not so with arbitrary special user functions: a value of the original has to be a constructed copy.
Class objects must be constructed by the caller; a constructor formally has a this
pointer but formalism isn't relevant here: all objects formally have an address but only those that actually get their address used in non purely local ways (unlike *&i = 1;
which is purely local use of address) need to have a well defined address.
An object must absolutely by passed by address if it must appear to have an address in both these two separately compiled functions:
void callee(int &i) {
something(&i);
}
void caller() {
int i;
callee(i);
something(&i);
}
Here even if something(address)
is a pure function or macro or whatever (like printf("%p",arg)
) that can't store the address or communicate to another entity, we have the requirement to pass by address because the address must be well defined for a unique object int
that has an unique identity.
We don't know if an external function will be "pure" in term of addresses passed to it.
Here the potential for a real use of the address in either a non trivial constructor or destructor on the caller side is probably the reason for taking the safe, simplistic route and give the object an identity in the caller and pass its address, as it makes sure that any non trivial use of its address in the constructor, after construction and in the destructor is consistent: this
must appear to be the same over the object existence.
A non trivial constructor or destructor like any other function can use the this
pointer in a way that requires consistency over its value even though some object with non trivial stuff might not:
struct file_handler { // don't use that class!
file_handler () { this->fileno = -1; }
file_handler (int f) { this->fileno = f; }
file_handler (const file_handler& rhs) {
if (this->fileno != -1)
this->fileno = dup(rhs.fileno);
else
this->fileno = -1;
}
~file_handler () {
if (this->fileno != -1)
close(this->fileno);
}
file_handler &operator= (const file_handler& rhs);
};
Note that in that case, despite explicit use of a pointer (explicit syntax this->
), the object identity is irrelevant: the compiler could well use bitwise copy the object around to move it and to do "copy elision". This is based on the level of "purity" of the use of this
in special member functions (address doesn't escape).
But purity isn't an attribute available at the standard declaration level (compiler extensions exist that add purity description on non inline function declaration), so you can't define an ABI based on purity of code that may not be available (code may or may not be inline and available for analysis).
Purity is measured as "certainly pure" or "impure or unknown". The common ground, or upper bound of semantics (actually maximum), or LCM (Least Common Multiple) is "unknown". So the ABI settles on unknown.
Summary:
- Some constructs require the compiler to define the object identity.
- The ABI is defined in term of classes of programs and not specific cases that might be optimized.
Possible future work:
Is purity annotation useful enough to be generalized and standardized?
this
pointer that points at a valid location.unique_ptr
has those. Spilling the register for that purpose would kinda negate the whole "pass in a register" optimization.