mycpp/README.md

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1	mycpp
2	=====
3
4	This is a Python-to-C++ translator based on MyPy. It only
5	handles the small subset of Python that we use in Oils.
6
7	It's inspired by both mypyc and Shed Skin. These posts give background:
8
9	- [Brief Descriptions of a Python to C++ Translator](https://www.oilshell.org/blog/2022/05/mycpp.html)
10	- [Oil Is Being Implemented "Middle Out"](https://www.oilshell.org/blog/2022/03/middle-out.html)
11
12	As of March 2024, the translation to C++ is done. So it's no longer
13	experimental!
14
15	However, it's still pretty hacky. This doc exists mainly to explain the
16	hacks. (We may want to rewrite mycpp as "yaks", although it's low priority
17	right now.)
18
19	---
20
21	Source for this doc: [mycpp/README.md]($oils-src). The code is all in
22	[mycpp/]($oils-src).
23
24
25	<div id="toc">
26	</div>
27
28	## Instructions
29
30	### Translating and Compiling `oils-cpp`
31
32	Running `mycpp` is best done on a Debian / Ubuntu-ish machine. Follow the
33	instructions at <https://github.com/oilshell/oil/wiki/Contributing> to create
34	the "dev build" first, which is DISTINCT from the C++ build. Make sure you can
35	run:
36
37	oil$ build/py.sh all
38
39	This will give you a working shell:
40
41	oil$ bin/osh -c 'echo hi' # running interpreted Python
42	hi
43
44	To run mycpp, we will build Python 3.10, clone MyPy, and install MyPy's
45	dependencies. First install packages:
46
47	# We need libssl-dev, libffi-dev, zlib1g-dev to bootstrap Python
48	oil$ build/deps.sh install-ubuntu-packages
49
50	Then fetch data, like the Python 3.10 tarball and MyPy repo:
51
52	oil$ build/deps.sh fetch
53
54	Then build from source:
55
56	oil$ build/deps.sh install-wedges
57
58	To build oil-native, use:
59
60	oil$ ./NINJA-config.sh
61	oil$ ninja # translate and compile, may take 30 seconds
62
63	oil$ _bin/cxx-asan/osh -c 'echo hi' # running compiled C++ !
64	hi
65
66	To run the tests and benchmarks:
67
68	oil$ mycpp/TEST.sh test-translator
69	... 200+ tasks run ...
70
71	If you have problems, post a message on `#oil-dev` at
72	`https://oilshell.zulipchat.com`. Not many people have contributed to `mycpp`,
73	so I can use your feedback!
74
75	Related:
76
77	- [Oil Native Quick
78	Start](https://github.com/oilshell/oil/wiki/Oil-Native-Quick-Start) on the
79	wiki.
80	- [Oil Dev Cheat Sheet](https://github.com/oilshell/oil/wiki/Oil-Native-Quick-Start)
81
82	## Notes on the Algorithm / Architecture
83
84	There are four passes over the MyPy AST.
85
86	(1) `const_pass.py`: Collect string constants
87
88	Turn turn the constant in `myfunc("foo")` into top-level `GLOBAL_STR(str1,
89	"foo")`.
90
91	(2) Three passes in `cppgen_pass.py`.
92
93	(a) Forward Declaration Pass.
94
95	class Foo;
96	class Bar;
97
98	This pass also determines which methods should be declared `virtual` in their
99	declarations. The `virtual` keyword is written in the next pass.
100
101	(b) Declaration Pass.
102
103	class Foo {
104	void method();
105	};
106	class Bar {
107	void method();
108	};
109
110	More work in this pass:
111
112	- Collect member variables and write them at the end of the definition
113	- Collect locals for "hoisting". Written in the next pass.
114
115	(c) Definition Pass.
116
117	void Foo:method() {
118	...
119	}
120
121	void Bar:method() {
122	...
123	}
124
125	Note: I really wish we were not using visitors, but that's inherited from MyPy.
126
127	## mycpp Idioms / "Creative Hacks"
128
129	Oils is written in typed Python 2. It will run under a stock Python 2
130	interpreter, and it will typecheck with stock MyPy.
131
132	However, there are a few language features that don't map cleanly from typed
133	Python to C++:
134
135	- switch statements (unfortunately we don't have the Python 3 match statement)
136	- C++ destructors - the RAII ptatern
137	- casting - MyPy has one kind of cast; C++ has `static_cast` and
138	`reinterpret_cast`. (We don't use C-style casting.)
139
140	So this describes the idioms we use. There are some hacks in
141	[mycpp/cppgen_pass.py]($oils-src) to handle these cases, and also Python
142	runtime equivalents in `mycpp/mylib.py`.
143
144	### `with {,tag,str_}switch` → Switch statement
145
146	We have three constructs that translate to a C++ switch statement. They use a
147	Python context manager `with Xswitch(obj) ...` as a little hack.
148
149	Here are examples like the ones in [mycpp/examples/test_switch.py]($oils-src).
150	(`ninja mycpp-logs-equal` translates, compiles, and tests all the examples.)
151
152	Simple switch:
153
154	myint = 99
155	with switch(myint) as case:
156	if case(42, 43):
157	print('forties')
158	else:
159	print('other')
160
161	Switch on object type, which goes well with ASDL sum types:
162
163	val = value.Str('foo) # type: value_t
164	with tagswitch(val) as case:
165	if case(value_e.Str, value_e.Int):
166	print('string or int')
167	else:
168	print('other')
169
170	We usually need to apply the `UP_val` pattern here, described in the next
171	section.
172
173	Switch on string, which generates a fast two-level dispatch -- first on
174	length, and then with `str_equals_c()`:
175
176	s = 'foo'
177	with str_switch(s) as case:
178	if case("foo")
179	print('FOO')
180	else:
181	print('other')
182
183	### `val` → `UP_val` → `val` Downcasting pattern
184
185	Summary: variable names like `UP_` are special* in our Python code.
186
187	Consider the downcasts marked BAD:
188
189	val = value.Str('foo) # type: value_t
190
191	with tagswitch(obj) as case:
192	if case(value_e.Str):
193	val = cast(value.Str, val) # BAD: conflicts with first declaration
194	print('s = %s' % val.s)
195
196	elif case(value_e.Int):
197	val = cast(value.Int, val) # BAD: conflicts with both
198	print('i = %d' % val.i)
199
200	else:
201	print('other')
202
203	MyPy allows this, but it translates to invalid C++ code. C++ can't have a
204	variable named `val`, with 2 related types `value_t` and `value::Str`.
205
206	So we use this idiom instead, which takes advantage of **local vars in case
207	blocks** in C++:
208
209	val = value.Str('foo') # type: value_t
210
211	UP_val = val # temporary variable that will be casted
212
213	with tagswitch(val) as case:
214	if case(value_e.Str):
215	val = cast(value.Str, UP_val) # this works
216	print('s = %s' % val.s)
217
218	elif case(value_e.Int):
219	val = cast(value.Int, UP_val) # also works
220	print('i = %d' % val.i)
221
222	else:
223	print('other')
224
225	This translates to something like:
226
227	value_t* val = Alloc<value::Str>(str42);
228	value_t* UP_val = val;
229
230	switch (val->tag()) {
231	case value_e::Str: {
232	// DIFFERENT local var
233	value::Str* val = static_cast<value::Str>(UP_val);
234	print(StrFormat(str43, val->s))
235	}
236	break;
237	case value_e::Int: {
238	// ANOTHER DIFFERENT local var
239	value::Int* val = static_cast<value::Int>(UP_val);
240	print(StrFormat(str44, val->i))
241	}
242	break;
243	default:
244	print(str45);
245	}
246
247	This works because there's no problem having different variables with the
248	same name within each `case { }` block.
249
250	Again, the names `UP_` are special*. If the name doesn't start with `UP_`,
251	the inner blocks will look like:
252
253	case value_e::Str: {
254	val = static_cast<value::Str>(val); // BAD: val reused
255	print(StrFormat(str43, val->s))
256	}
257
258	And they will fail to compile. It's not valid C++ because the superclass
259	`value_t` doesn't have a field `val->s`. Only the subclass `value::Str` has
260	it.
261
262	(Note that Python has a single flat scope per function, while C++ has nested
263	scopes.)
264
265	### Python context manager → C++ constructor and destructor (RAII)
266
267	This Python code:
268
269	with ctx_Foo(42):
270	f()
271
272	translates to this C++ code:
273
274	{
275	ctx_Foo tmp(42);
276	f()
277
278	// destructor ~ctx_Foo implicitly called
279	}
280
281	## MyPy "Shimming" Technique
282
283	We have an interesting way of "writing Python and C++ at the same time":
284
285	1. First, all Python code must pass the MyPy type checker, and run with a stock
286	Python 2 interpreter.
287	- This is the source of truth — the source of our semantics.
288	1. We translate most `.py` files to C++, except some files, in particular
289	[mycpp/mylib.py]($oils-src) and files starting with `py` like
290	`core/{pyos.pyutil}.py`.
291	1. In C++, we can substitute custom implementations with the properties we
292	want, like `Dict<K, V>` being ordered, `BigInt` being distinct from C `int`,
293	`BufWriter` being efficient, etc.
294
295	The MyPy type system is very powerful! It lets us do all this.
296
297	### NewDict() for ordered dicts
298
299	Dicts in Python 2 aren't ordered, but we make them ordered at runtime by
300	using `mylib.NewDict()`, which returns `collections_.OrderedDict`.
301
302	The static type is still `Dict[K, V]`, but change the "spec" to be an
303	ordered dict.
304
305	In C++, `Dict<K, V>` is implemented as an ordered dict. (Note: we don't
306	implement preserving order on deletion, which seems OK.)
307
308	- TODO: `iteritems()` could go away
309
310	### StackArray[T]
311
312	TODO: describe this when it works.
313
314	### BigInt
315
316	- In Python, it's simply defined a a class with an integer, in
317	[mylib/mops.py]($oils-src).
318	- In C++, it's currently `typedef int64_t BigInt`, but we want to make it a big
319	integer.
320
321	### ByteAt(), ByteEquals(), ...
322
323	Hand optimization to reduce 1-byte strings. For IFS algorithm,
324	`LooksLikeGlob()`, `GlobUnescape()`.
325
326	### File / LineReader / BufWriter
327
328	TODO: describe how this works.
329
330	Can it be more type safe? I think we can cast `File` to both `LineReader` and
331	`BufWriter`.
332
333	Or can we invert the relationship, so `File` derives from both LineReader
334	and BufWriter?
335
336	### Fast JSON - avoid intermediate allocations
337
338	- `pyj8.WriteString()` is shimmed so we don't create encoded J8 string objects,
339	only to throw them away and write to `mylib.BufWriter`. Instead, we append
340	an encoded strings directly to the `BufWriter`.
341	- Likewise, we have `BufWriter::write_spaces` to avoid temporary allocations
342	when writing indents.
343	- This could be generalized to `BufWriter::write_repeated(' ', 42)`.
344	- We may also want `BufWriter::write_slice()`
345
346	## Limitations Requiring Source Rewrites
347
348	mycpp itself may cause limitations on expressiveness, or the C++ language may
349	be able express what we want.
350
351	- C++ doesn't have `try / except / else`, or `finally`
352	- Use the `with ctx_Foo` pattern instead.
353	- `if mylist` tests if the pointer is non-NULL; use `if len(mylist)` for
354	non-empty test
355	- Functions can have at most one keyword / optional argument.
356	- We generate two methods: `f(x)` which calls `f(x, y)` with the default
357	value of `y`
358	- If there are two or more optional arguments:
359	- For classes, you can use the "builder pattern", i.e. add an
360	`Init_MyMember()` method
361	- If the arguments are booleans, translate it to a single bitfield argument
362	- C++ has nested scope and Python has flat function scope. This can cause name
363	collisions.
364	- Could enforce this if it becomes a problem
365
366	Also see `mycpp/examples/invalid_*` for Python code that fails to translate.
367
368	## WARNING: Assumptions Not Checked
369
370	### Global Constants Can't Be Mutated
371
372	We translate top level constants to statically initialized C data structures
373	(zero startup cost):
374
375	gStr = 'foo'
376	gList = [1, 2] # type: List[int]
377	gDict = {'bar': 42} # type: Dict[str, int]
378
379	Even though `List` and `Dict` are mutable in general, you should NOT mutate
380	these global instances! The C++ code will break at runtime.
381
382	### Gotcha about Returning Variants (Subclasses) of a Type
383
384	MyPy will accept this code:
385
386	```
387	if cond:
388	sig = proc_sig.Open # type: proc_sig_t
389	# bad because mycpp HOISTS this
390	else:
391	sig = proc_sig.Closed.CreateNull()
392	sig.words = words # assignment fails
393	return sig
394	```
395
396	It will translate to C++, but fail to compile. Instead, rewrite it like this:
397
398	```
399	sig = None # type: proc_sig_t
400	if cond:
401	sig = proc_sig.Open # type: proc_sig_t
402	# bad because mycpp HOISTS this
403	else:
404	closed = proc_sig.Closed.CreateNull()
405	closed.words = words # assignment fails
406	sig = closed
407	return sig
408	```
409
410	### Exceptions Can't Leave Destructors / Python `__exit__`
411
412	Context managers like `with ctx_Foo():` translate to C++ constructors and
413	destructors.
414
415	In C++, a destructor can't "leave" an exception. It results in a runtime error.
416
417	You can throw and CATCH an exception WITHIN a destructor, but you can't let it
418	propagate outside.
419
420	This means you must be careful when coding the `__exit__` method. For example,
421	in `vm::ctx_Redirect`, we had this bug due to `IOError` being thrown and not
422	caught when restoring/popping redirects.
423
424	To fix the bug, we rewrote the code to use an out param
425	`List[IOError_OSError]`.
426
427	Related:
428
429	- <https://akrzemi1.wordpress.com/2011/09/21/destructors-that-throw/>
430
431	## More Translation Notes
432
433	### Hacky Heuristics
434
435	- `callable(arg)` to either:
436	- function call `f(arg)`
437	- instantiation `Alloc<T>(arg)`
438	- `name.attr` to either:
439	- `obj->member`
440	- `module::Func`
441	- `cast(MyType, obj)` to either
442	- `static_cast<MyType*>(obj)`
443	- `reinterpret_cast<MyType*>(obj)`
444
445	### Hacky Hard-Coded Names
446
447	These are signs of coupling between mycpp and Oils, which ideally shouldn't
448	exist.
449
450	- `mycpp_main.py`
451	- `ModulesToCompile()` -- some files have to be ordered first, like the ASDL
452	runtime.
453	- TODO: Pea can respect parameter order? So we do that outside the project?
454	- Another ordering constraint comes from inheritance. The forward
455	declaration is NOT sufficient in that case.
456	- `cppgen_pass.py`
457	- `_GetCastKind()` has some hard-coded names
458	- `AsdlType::Create()` is special cased to `::`, not `->`
459	- Default arguments e.g. `scope_e::Local` need a repeated `using`.
460
461	Issue on mycpp improvements: <https://github.com/oilshell/oil/issues/568>
462
463	### Major Features
464
465	- Python `int` and `bool` → C++ `int` and `bool`
466	- `None` → `nullptr`
467	- Statically Typed Python Collections
468	- `str` → `Str*`
469	- `List[T]` → `List<T>*`
470	- `Dict[K, V]` → `Dict<K, V>*`
471	- tuples → `Tuple2<A, B>`, `Tuple3<A, B, C>`, etc.
472	- Collection literals turn into initializer lists
473	- And there is a C++ type inference issue which requires an explicit
474	`std::initializer_list<int>{1, 2, 3}`, not just `{1, 2, 3}`
475	- Python's polymorphic iteration → `StrIter`, `ListIter<T>`, `DictIter<K,
476	V`
477	- `d.iteritems()` is rewritten `mylib.iteritems()` → `DictIter`
478	- TODO: can we be smarter about this?
479	- `reversed(mylist)` → `ReverseListIter`
480	- Python's `in` operator:
481	- `s in mystr` → `str_contains(mystr, s)`
482	- `x in mylist` → `list_contains(mylist, x)`
483	- Classes and inheritance
484	- `__init__` method becomes a constructor. Note: initializer lists aren't
485	used.
486	- Detect `virtual` methods
487	- TODO: could we detect `abstract` methods? (`NotImplementedError`)
488	- Python generators `Iterator[T]` → eager `List<T>` accumulators
489	- Python Exceptions → C++ exceptions
490	- Python Modules → C++ namespace (we assume a 2-level hierarchy)
491	- TODO: mycpp need real modules, because our `oils_for_unix.mycpp.cc`
492	translation unit is getting big.
493	- And `cpp/preamble.h` is a hack to work around the lack of modules.
494
495	### Minor Translations
496
497	- `s1 == s2` → `str_equals(s1, s2)`
498	- `'x' * 3` → `str_repeat(globalStr, 3)`
499	- `[None] * 3` → `list_repeat(nullptr, 3)`
500	- Omitted:
501	- If the LHS of an assignment is `_`, then the statement is omitted
502	- This is for `_ = log`, which shuts up Python lint warnings for 'unused
503	import'
504	- Code under `if __name__ == '__main__'`
505
506	### Optimizations
507
508	- Returning Tuples by value. To reduce GC pressure, we we return
509	`Tuple2<A, B>` instead of `Tuple2<A, B>*`, and likewise for `Tuple3` and `Tuple4`.
510
511	### Rooting Policy
512
513	The translated code roots local variables in every function
514
515	StackRoots _r({&var1, &var2});
516
517	We have two kinds of hand-written code:
518
519	1. Methods like `Str::strip()` in `mycpp/`
520	2. OS bindings like `stat()` in `cpp/`
521
522	Neither of them needs any rooting! This is because we use **manual collection
523	points** in the interpreter, and these functions don't call any functions that
524	can collect. They are "leaves" in the call tree.
525
526	## The mycpp Runtime
527
528	The mycpp translator targets a runtime that's written from scratch. It
529	implements garbage-collected data structures like:
530
531	- Typed records
532	- Python classes
533	- ASDL product and sum types
534	- `Str` (immutable, as in Python)
535	- `List<T>`
536	- `Dict<K, V>`
537	- `Tuple2<A, B>`, `Tuple3<A, B, C>`, ...
538
539	It also has functions based on CPython's:
540
541	- `mycpp/gc_builtins.{h,cc}` corresponds roughly to Python's `__builtin__`
542	module, e.g. `int()` and `str()`
543	- `mycpp/gc_mylib.{h,cc}` corresponds `mylib.py`
544	- `mylib.BufWriter` is a bit like `cStringIO.StringIO`
545
546	### Differences from CPython
547
548	- Integers either C `int` or `mylib.BigInt`, not Python's arbitrary size
549	integers
550	- `NUL` bytes are allowed in arguments to syscalls like `open()`, unlike in
551	CPython
552	- `s.strip()` is defined in terms of ASCII whitespace, which does not include
553	say `\v`.
554	- This is done to be consistent with JSON and J8 Notation.
555
556	## C++ Notes
557
558	### Gotchas
559
560	- C++ classes can have 2 member variables of the same name! From the base
561	class and derived class.
562	- Failing to declare methods `virtual` can involve the wrong one being called
563	at runtime
564
565	### Minor Features Used
566
567	In addition to classes, templates, exceptions, etc. mentioned above, we use:
568
569	- `static_cast` and `reinterpret_cast`
570	- `enum class` for ASDL
571	- Function overloading
572	- For equality and hashing?
573	- `offsetof` for introspection of field positions for garbage collection
574	- `std::initializer_list` for `StackRoots()`
575	- Should we get rid of this?
576
577	### Not Used
578
579	- I/O Streams, RTTI, etc.
580	- `const`
581	- Smart pointers
582