[ceph.git] / ceph / src / boost / libs / python / doc / polymorphism.txt

.. Copyright David Abrahams 2006. Distributed under the Boost
.. Software License, Version 1.0. (See accompanying
.. file LICENSE_1_0.txt or copy at
.. http://www.boost.org/LICENSE_1_0.txt)

How Runtime Polymorphism is expressed in Boost.Python:
-----------------------------------------------------

   struct A { virtual std::string f(); virtual ~A(); };

   std::string call_f(A& x) { return x.f(); }

   struct B { virtual std::string f() { return "B"; } };

   struct Bcb : B
   { 
      Bcb(PyObject* self) : m_self(self) {}

      virtual std::string f() { return call_method<std::string>(m_sef, "f"); }
      static std::string f_default(B& b) { return b.B::f(); }

      PyObject* m_self;
   };

   struct C : B
   {
      virtual std::string f() { return "C"; }
   };

   >>> class D(B):
   ...     def f():
   ...         return 'D'
   ...
   >>> class E(B): pass
   ...


When we write, "invokes B::f non-virtually", we mean:

  void g(B& x) { x.B::f(); }

This will call B::f() regardless of the dynamic type of x. Any other
way of invoking B::f, including through a function pointer, is a
"virtual invocation", and will call the most-derived override of f().

Case studies

   C++\Python class
       \___A_____B_____C_____D____E___
       |
   A   |   1
       |
   B   |   2     3
       |
   Bcb |         4           5    6
       |
   C   |         7     8
       |


1. Simple case

2. Python A holds a B*. Probably won't happen once we have forced
   downcasting. 

   Requires:
         x.f() -> 'B'
         call_f(x) -> 'B'

   Implies: A.f invokes A::f() (virtually or otherwise)

3. Python B holds a B*. 

   Requires:
        x.f() -> 'B'
        call_f(x) -> 'B'
   
   Implies: B.f invokes B::f (virtually or otherwise)


4. B constructed from Python

   Requires:

        x.f() -> 'B'
        call_f(x) -> 'B'

   Implies: B.f invokes B::f non-virtually. Bcb::f invokes B::f
            non-virtually.

   Question: Does it help if we arrange for Python B construction to
   build a true B object? Then this case doesn't arise.


5. D is a Python class derived from B

   Requires:

        x.f() -> 'D'
        call_f(x) -> 'D'

   Implies: Bcb::f must invoke call_method to look up the Python
            method override, otherwise call_f wouldn't work.

6. E is like D, but doesn't override f

   Requires:

        x.f() -> 'B'
        call_f(x) -> 'B'

   Implies: B.f invokes B::f non-virtually. If it were virtual, x.f()
            would cause infinite recursion, because we've already
            determined that Bcb::f must invoke call_method to look up
            the Python method override.

7. Python B object holds a C*

   Requires:
        
        x.f() -> 'C'
        call_f(x) -> 'C'

   Implies: B.f invokes B::f virtually. 

8. C object constructed from Python

   Requires:

        x.f() -> 'C'
        call_f(x) -> 'C'

   Implies: nothing new.

------

Total implications:

2: A.f invokes A::f() (virtually or otherwise)
3: B.f invokes B::f (virtually or otherwise)
4: B.f invokes B::f non-virtually. Bcb::f invokes B::f non-virtually
6: B.f invokes B::f non-virtually. 
7: B.f invokes B::f virtually. 

5: Bcb::f invokes call_method to look up the Python method

Though (4) is avoidable, clearly 6 and 7 are not, and they
conflict. The implication is that B.f must choose its behavior
according to the type of the contained C++ object. If it is Bcb, a
non-virtual call to B::f must occur. Otherwise, a virtual call to B::f
must occur. This is essentially the same scheme we had with
Boost.Python v1.

Note: in early versions of Boost.Python v1, we solved this problem by
introducing a new Python class in the hierarchy, so that D and E
actually derive from a B', and B'.f invokes B::f non-virtually, while
B.f invokes B::f virtually. However, people complained about the
artificial class in the hierarchy, which was revealed when they tried
to do normal kinds of Python introspection.

-------

Assumption: we will have a function which builds a virtual function
dispatch callable Python object.

     make_virtual_function(pvmf, default_impl, call_policies, dispatch_type)

Pseudocode:

     Get first argument from Python arg tuple
     if it contains dispatch_type
        call default_impl
     else
        call through pvmf


Open questions:

   1. What about Python multiple inheritance? Do we have the right
      check in the if clause above?
      
      A: Not quite. The correct test looks like:

      Deduce target type of pvmf, i.e. T in R(T::*)(A1...AN).
      Find holder in first argument which holds T
      if it holds dispatch_type...

   2. Can we make this more efficient?
     
     The current "returning" mechanism will look up a holder for T
     again. I don't know if we know how to avoid that.


  OK, the solution involves reworking the call mechanism. This is
  neccesary anyway in order to enable wrapping of function objects.

  It can result in a reduction in the overall amount of source code,
  because returning<> won't need to be specialized for every
  combination of function and member function... though it will still
  need a void specialization. We will still need a way to dispatch to
  member functions through a regular function interface. mem_fn is
  almost the right tool, but it only goes up to 8
  arguments. Forwarding is tricky if you don't want to incur copies.
  I think the trick is to use arg_from_python<T>::result_type for each
  argument to the forwarder.

  Another option would be to use separate function, function object,
  and member function dispatchers. Once you know you have a member
  function, you don't need cv-qualified overloads to call it.

  Hmm, while we're at this, maybe we should solve the write-back
  converter problem. Can we do it? Maybe not. Ralf doesn't want to
  write special write-back functions here, does he? He wants the
  converter to do the work automatically. We could add
  cleanup/destructor registration. That would relieve the client from
  having accessible destructors for types which are being converted by
  rvalue. I'm not sure that this will really save any code,
  however. It rather depends on the linker, doesn't it? I wonder if
  this can be done in a backwards-compatible fashion by generating the
  delete function when it's not supplied?
Commit	Line	Data
7c673cae FG	1	.. Copyright David Abrahams 2006. Distributed under the Boost
	2	.. Software License, Version 1.0. (See accompanying
	3	.. file LICENSE_1_0.txt or copy at
	4	.. http://www.boost.org/LICENSE_1_0.txt)
	5
	6	How Runtime Polymorphism is expressed in Boost.Python:
	7	-----------------------------------------------------
	8
	9	struct A { virtual std::string f(); virtual ~A(); };
	10
	11	std::string call_f(A& x) { return x.f(); }
	12
	13	struct B { virtual std::string f() { return "B"; } };
	14
	15	struct Bcb : B
	16	{
	17	Bcb(PyObject* self) : m_self(self) {}
	18
	19	virtual std::string f() { return call_method<std::string>(m_sef, "f"); }
	20	static std::string f_default(B& b) { return b.B::f(); }
	21
	22	PyObject* m_self;
	23	};
	24
	25	struct C : B
	26	{
	27	virtual std::string f() { return "C"; }
	28	};
	29
	30	>>> class D(B):
	31	... def f():
	32	... return 'D'
	33	...
	34	>>> class E(B): pass
	35	...
	36
	37
	38	When we write, "invokes B::f non-virtually", we mean:
	39
	40	void g(B& x) { x.B::f(); }
	41
	42	This will call B::f() regardless of the dynamic type of x. Any other
	43	way of invoking B::f, including through a function pointer, is a
	44	"virtual invocation", and will call the most-derived override of f().
	45
	46	Case studies
	47
	48	C++\Python class
	49	\___A_____B_____C_____D____E___
	50	\|
	51	A \| 1
	52	\|
	53	B \| 2 3
	54	\|
	55	Bcb \| 4 5 6
	56	\|
	57	C \| 7 8
	58	\|
	59
	60
	61	1. Simple case
	62
	63	2. Python A holds a B*. Probably won't happen once we have forced
	64	downcasting.
65
66	Requires:
67	x.f() -> 'B'
68	call_f(x) -> 'B'
69
70	Implies: A.f invokes A::f() (virtually or otherwise)
71
72	3. Python B holds a B*.
73
74	Requires:
75	x.f() -> 'B'
76	call_f(x) -> 'B'
77
78	Implies: B.f invokes B::f (virtually or otherwise)
79
80
81	4. B constructed from Python
82
83	Requires:
84
85	x.f() -> 'B'
86	call_f(x) -> 'B'
87
88	Implies: B.f invokes B::f non-virtually. Bcb::f invokes B::f
89	non-virtually.
90
91	Question: Does it help if we arrange for Python B construction to
92	build a true B object? Then this case doesn't arise.
93
94
95	5. D is a Python class derived from B
96
97	Requires:
98
99	x.f() -> 'D'
100	call_f(x) -> 'D'
101
102	Implies: Bcb::f must invoke call_method to look up the Python
103	method override, otherwise call_f wouldn't work.
104
105	6. E is like D, but doesn't override f
106
107	Requires:
108
109	x.f() -> 'B'
110	call_f(x) -> 'B'
111
112	Implies: B.f invokes B::f non-virtually. If it were virtual, x.f()
113	would cause infinite recursion, because we've already
114	determined that Bcb::f must invoke call_method to look up
115	the Python method override.
116
117	7. Python B object holds a C*
118
119	Requires:
120
121	x.f() -> 'C'
122	call_f(x) -> 'C'
123
124	Implies: B.f invokes B::f virtually.
125
126	8. C object constructed from Python
127
128	Requires:
129
130	x.f() -> 'C'
131	call_f(x) -> 'C'
132
133	Implies: nothing new.
134
135	------
136
137	Total implications:
138
139	2: A.f invokes A::f() (virtually or otherwise)
140	3: B.f invokes B::f (virtually or otherwise)
141	4: B.f invokes B::f non-virtually. Bcb::f invokes B::f non-virtually
142	6: B.f invokes B::f non-virtually.
143	7: B.f invokes B::f virtually.
144
145	5: Bcb::f invokes call_method to look up the Python method
146
147	Though (4) is avoidable, clearly 6 and 7 are not, and they
148	conflict. The implication is that B.f must choose its behavior
149	according to the type of the contained C++ object. If it is Bcb, a
150	non-virtual call to B::f must occur. Otherwise, a virtual call to B::f
151	must occur. This is essentially the same scheme we had with
152	Boost.Python v1.
153
154	Note: in early versions of Boost.Python v1, we solved this problem by
155	introducing a new Python class in the hierarchy, so that D and E
156	actually derive from a B', and B'.f invokes B::f non-virtually, while
157	B.f invokes B::f virtually. However, people complained about the
158	artificial class in the hierarchy, which was revealed when they tried
159	to do normal kinds of Python introspection.
160
161	-------
162
163	Assumption: we will have a function which builds a virtual function
164	dispatch callable Python object.
165
166	make_virtual_function(pvmf, default_impl, call_policies, dispatch_type)
167
168	Pseudocode:
169
170	Get first argument from Python arg tuple
171	if it contains dispatch_type
172	call default_impl
173	else
174	call through pvmf
175
176
177	Open questions:
178
179	1. What about Python multiple inheritance? Do we have the right
180	check in the if clause above?
181
182	A: Not quite. The correct test looks like:
183
184	Deduce target type of pvmf, i.e. T in R(T::*)(A1...AN).
185	Find holder in first argument which holds T
186	if it holds dispatch_type...
187
188	2. Can we make this more efficient?
189
190	The current "returning" mechanism will look up a holder for T
191	again. I don't know if we know how to avoid that.
192
193
194	OK, the solution involves reworking the call mechanism. This is
195	neccesary anyway in order to enable wrapping of function objects.
196
197	It can result in a reduction in the overall amount of source code,
198	because returning<> won't need to be specialized for every
199	combination of function and member function... though it will still
200	need a void specialization. We will still need a way to dispatch to
201	member functions through a regular function interface. mem_fn is
202	almost the right tool, but it only goes up to 8
203	arguments. Forwarding is tricky if you don't want to incur copies.
204	I think the trick is to use arg_from_python<T>::result_type for each
205	argument to the forwarder.
206
207	Another option would be to use separate function, function object,
208	and member function dispatchers. Once you know you have a member
209	function, you don't need cv-qualified overloads to call it.
210
211	Hmm, while we're at this, maybe we should solve the write-back
212	converter problem. Can we do it? Maybe not. Ralf doesn't want to
213	write special write-back functions here, does he? He wants the
214	converter to do the work automatically. We could add
215	cleanup/destructor registration. That would relieve the client from
216	having accessible destructors for types which are being converted by
217	rvalue. I'm not sure that this will really save any code,
218	however. It rather depends on the linker, doesn't it? I wonder if
219	this can be done in a backwards-compatible fashion by generating the
220	delete function when it's not supplied?
221
222