2 * Copyright 2011 Sven Verdoolaege. All rights reserved.
4 * Redistribution and use in source and binary forms, with or without
5 * modification, are permitted provided that the following conditions
8 * 1. Redistributions of source code must retain the above copyright
9 * notice, this list of conditions and the following disclaimer.
11 * 2. Redistributions in binary form must reproduce the above
12 * copyright notice, this list of conditions and the following
13 * disclaimer in the documentation and/or other materials provided
14 * with the distribution.
16 * THIS SOFTWARE IS PROVIDED BY SVEN VERDOOLAEGE ''AS IS'' AND ANY
17 * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
18 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
19 * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL SVEN VERDOOLAEGE OR
20 * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
21 * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
22 * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA,
23 * OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
24 * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
25 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
26 * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
28 * The views and conclusions contained in the software and documentation
29 * are those of the authors and should not be interpreted as
30 * representing official policies, either expressed or implied, of
34 #include "isl_config.h"
39 #include <clang/AST/Attr.h>
40 #include "extract_interface.h"
43 /* Is the given type declaration marked as being a subtype of some other
44 * type? If so, return that other type in "super".
46 static bool is_subclass(RecordDecl
*decl
, string
&super
)
48 if (!decl
->hasAttrs())
51 string sub
= "isl_subclass";
52 size_t len
= sub
.length();
53 AttrVec attrs
= decl
->getAttrs();
54 for (AttrVec::const_iterator i
= attrs
.begin() ; i
!= attrs
.end(); ++i
) {
55 const AnnotateAttr
*ann
= dyn_cast
<AnnotateAttr
>(*i
);
58 string s
= ann
->getAnnotation().str();
59 if (s
.substr(0, len
) == sub
) {
60 super
= s
.substr(len
+ 1, s
.length() - len
- 2);
68 /* Is decl marked as a constructor?
70 static bool is_constructor(Decl
*decl
)
72 return has_annotation(decl
, "isl_constructor");
75 /* Is decl marked as consuming a reference?
77 static bool takes(Decl
*decl
)
79 return has_annotation(decl
, "isl_take");
82 /* isl_class collects all constructors and methods for an isl "class".
83 * "name" is the name of the class.
84 * "type" is the declaration that introduces the type.
89 set
<FunctionDecl
*> constructors
;
90 set
<FunctionDecl
*> methods
;
92 void print(map
<string
, isl_class
> &classes
, set
<string
> &done
);
93 void print_constructor(FunctionDecl
*method
);
94 void print_method(FunctionDecl
*method
, bool subclass
, string super
);
97 /* Return the class that has a name that matches the initial part
98 * of the namd of function "fd".
100 static isl_class
&method2class(map
<string
, isl_class
> &classes
,
104 map
<string
, isl_class
>::iterator ci
;
105 string name
= fd
->getNameAsString();
107 for (ci
= classes
.begin(); ci
!= classes
.end(); ++ci
) {
108 if (name
.substr(0, ci
->first
.length()) == ci
->first
)
112 return classes
[best
];
115 /* Is "type" the type "isl_ctx *"?
117 static bool is_isl_ctx(QualType type
)
119 if (!type
->isPointerType())
121 type
= type
->getPointeeType();
122 if (type
.getAsString() != "isl_ctx")
128 /* Is the first argument of "fd" of type "isl_ctx *"?
130 static bool first_arg_is_isl_ctx(FunctionDecl
*fd
)
134 if (fd
->getNumParams() < 1)
137 param
= fd
->getParamDecl(0);
138 return is_isl_ctx(param
->getOriginalType());
141 /* Is "type" that of a pointer to an isl_* structure?
143 static bool is_isl_type(QualType type
)
145 if (type
->isPointerType()) {
146 string s
= type
->getPointeeType().getAsString();
147 return s
.substr(0, 4) == "isl_";
153 /* Is "type" that of a pointer to a function?
155 static bool is_callback(QualType type
)
157 if (!type
->isPointerType())
159 type
= type
->getPointeeType();
160 return type
->isFunctionType();
163 /* Is "type" that of "char *" of "const char *"?
165 static bool is_string(QualType type
)
167 if (type
->isPointerType()) {
168 string s
= type
->getPointeeType().getAsString();
169 return s
== "const char" || s
== "char";
175 /* Return the name of the type that "type" points to.
176 * The input "type" is assumed to be a pointer type.
178 static string
extract_type(QualType type
)
180 if (type
->isPointerType())
181 return type
->getPointeeType().getAsString();
185 /* Drop the "isl_" initial part of the type name "name".
187 static string
type2python(string name
)
189 return name
.substr(4);
192 /* Construct a wrapper for a callback argument (at position "arg").
193 * Assign the wrapper to "cb". We assume here that a function call
194 * has at most one callback argument.
196 * The wrapper converts the arguments of the callback to python types.
197 * If any exception is thrown, the wrapper keeps track of it in exc_info[0]
198 * and returns -1. Otherwise the wrapper returns 0.
200 static void print_callback(QualType type
, int arg
)
202 const FunctionProtoType
*fn
= type
->getAs
<FunctionProtoType
>();
203 unsigned n_arg
= fn
->getNumArgs();
205 printf(" exc_info = [None]\n");
206 printf(" fn = CFUNCTYPE(c_int");
207 for (int i
= 0; i
< n_arg
- 1; ++i
) {
208 QualType arg_type
= fn
->getArgType(i
);
209 assert(is_isl_type(arg_type
));
210 printf(", c_void_p");
212 printf(", c_void_p)\n");
213 printf(" def cb_func(");
214 for (int i
= 0; i
< n_arg
; ++i
) {
217 printf("cb_arg%d", i
);
220 for (int i
= 0; i
< n_arg
- 1; ++i
) {
222 arg_type
= type2python(extract_type(fn
->getArgType(i
)));
223 printf(" cb_arg%d = %s(ctx=arg0.ctx, ptr=cb_arg%d)\n",
224 i
, arg_type
.c_str(), i
);
227 printf(" arg%d(", arg
);
228 for (int i
= 0; i
< n_arg
- 1; ++i
) {
231 printf("cb_arg%d", i
);
234 printf(" except:\n");
235 printf(" import sys\n");
236 printf(" exc_info[0] = sys.exc_info()\n");
237 printf(" return -1\n");
238 printf(" return 0\n");
239 printf(" cb = fn(cb_func)\n");
242 /* Print a python method corresponding to the C function "method".
243 * "subclass" is set if the method belongs to a class that is a subclass
244 * of some other class ("super").
246 * If the function has a callback argument, then it also has a "user"
247 * argument. Since Python has closures, there is no need for such
248 * a user argument in the Python interface, so we simply drop it.
249 * We also create a wrapper ("cb") for the callback.
251 * For each argument of the function that refers to an isl structure,
252 * including the object on which the method is called,
253 * we check if the corresponding actual argument is of the right type.
254 * If not, we try to convert it to the right type.
255 * It that doesn't work and if subclass is set, we try to convert self
256 * to the type of the superclass and call the corresponding method.
258 * If the function consumes a reference, then we pass it a copy of
259 * the actual argument.
261 void isl_class::print_method(FunctionDecl
*method
, bool subclass
, string super
)
263 string fullname
= method
->getName();
264 string cname
= fullname
.substr(name
.length() + 1);
265 int num_params
= method
->getNumParams();
268 for (int i
= 1; i
< num_params
; ++i
) {
269 ParmVarDecl
*param
= method
->getParamDecl(i
);
270 QualType type
= param
->getOriginalType();
271 if (is_callback(type
))
275 printf(" def %s(arg0", cname
.c_str());
276 for (int i
= 1; i
< num_params
- drop_user
; ++i
)
277 printf(", arg%d", i
);
280 for (int i
= 0; i
< num_params
; ++i
) {
281 ParmVarDecl
*param
= method
->getParamDecl(i
);
283 if (!is_isl_type(param
->getOriginalType()))
285 type
= type2python(extract_type(param
->getOriginalType()));
287 printf(" if not arg%d.__class__ is %s:\n",
289 printf(" arg%d = %s(arg%d)\n",
291 printf(" except:\n");
292 if (i
> 0 && subclass
) {
293 printf(" return %s(arg0).%s(",
294 type2python(super
).c_str(), cname
.c_str());
295 for (int i
= 1; i
< num_params
- drop_user
; ++i
) {
304 for (int i
= 1; i
< num_params
; ++i
) {
305 ParmVarDecl
*param
= method
->getParamDecl(i
);
306 QualType type
= param
->getOriginalType();
307 if (!is_callback(type
))
309 print_callback(type
->getPointeeType(), i
);
311 printf(" res = isl.%s(", fullname
.c_str());
312 if (takes(method
->getParamDecl(0)))
313 printf("isl.%s_copy(arg0.ptr)", name
.c_str());
316 for (int i
= 1; i
< num_params
- drop_user
; ++i
) {
317 ParmVarDecl
*param
= method
->getParamDecl(i
);
318 QualType type
= param
->getOriginalType();
319 if (is_callback(type
))
321 else if (takes(param
)) {
322 string type_s
= extract_type(type
);
323 printf(", isl.%s_copy(arg%d.ptr)", type_s
.c_str(), i
);
325 printf(", arg%d.ptr", i
);
331 if (is_isl_type(method
->getReturnType())) {
333 type
= type2python(extract_type(method
->getReturnType()));
334 printf(" return %s(ctx=arg0.ctx, ptr=res)\n",
338 printf(" if exc_info[0] != None:\n");
339 printf(" raise exc_info[0][0], "
340 "exc_info[0][1], exc_info[0][2]\n");
342 printf(" return res\n");
346 /* Print part of the constructor for this isl_class.
348 * In particular, check if the actual arguments correspond to the
349 * formal arguments of "cons" and if so call "cons" and put the
350 * result in self.ptr and a reference to the default context in self.ctx.
352 * If the function consumes a reference, then we pass it a copy of
353 * the actual argument.
355 void isl_class::print_constructor(FunctionDecl
*cons
)
357 string fullname
= cons
->getName();
358 string cname
= fullname
.substr(name
.length() + 1);
359 int num_params
= cons
->getNumParams();
360 int drop_ctx
= first_arg_is_isl_ctx(cons
);
362 printf(" if len(args) == %d", num_params
- drop_ctx
);
363 for (int i
= drop_ctx
; i
< num_params
; ++i
) {
364 ParmVarDecl
*param
= cons
->getParamDecl(i
);
365 if (is_isl_type(param
->getOriginalType())) {
367 type
= extract_type(param
->getOriginalType());
368 type
= type2python(type
);
369 printf(" and args[%d].__class__ is %s",
370 i
- drop_ctx
, type
.c_str());
372 printf(" and type(args[%d]) == str", i
- drop_ctx
);
375 printf(" self.ctx = Context.getDefaultInstance()\n");
376 printf(" self.ptr = isl.%s(", fullname
.c_str());
379 for (int i
= drop_ctx
; i
< num_params
; ++i
) {
380 ParmVarDecl
*param
= cons
->getParamDecl(i
);
383 if (is_isl_type(param
->getOriginalType())) {
386 type
= extract_type(param
->getOriginalType());
387 printf("isl.%s_copy(args[%d].ptr)",
388 type
.c_str(), i
- drop_ctx
);
390 printf("args[%d].ptr", i
- drop_ctx
);
392 printf("args[%d]", i
- drop_ctx
);
398 /* Print out the definition of this isl_class.
400 * We first check if this isl_class is a subclass of some other class.
401 * If it is, we make sure the superclass is printed out first.
403 * Then we print a constructor with several cases, one for constructing
404 * a Python object from a return value and one for each function that
405 * was marked as a constructor.
407 * Next, we print out some common methods and the methods corresponding
408 * to functions that are not marked as constructors.
410 * Finally, we tell ctypes about the types of the arguments of the
411 * constructor functions and the return types of those function returning
414 void isl_class::print(map
<string
, isl_class
> &classes
, set
<string
> &done
)
417 string p_name
= type2python(name
);
418 set
<FunctionDecl
*>::iterator in
;
419 bool subclass
= is_subclass(type
, super
);
421 if (subclass
&& done
.find(super
) == done
.end())
422 classes
[super
].print(classes
, done
);
426 printf("class %s", p_name
.c_str());
428 printf("(%s)", type2python(super
).c_str());
430 printf(" def __init__(self, *args, **keywords):\n");
432 printf(" if \"ptr\" in keywords:\n");
433 printf(" self.ctx = keywords[\"ctx\"]\n");
434 printf(" self.ptr = keywords[\"ptr\"]\n");
437 for (in
= constructors
.begin(); in
!= constructors
.end(); ++in
)
438 print_constructor(*in
);
439 printf(" raise Error\n");
440 printf(" def __del__(self):\n");
441 printf(" if hasattr(self, 'ptr'):\n");
442 printf(" isl.%s_free(self.ptr)\n", name
.c_str());
443 printf(" def __str__(self):\n");
444 printf(" ptr = isl.%s_to_str(self.ptr)\n", name
.c_str());
445 printf(" res = str(cast(ptr, c_char_p).value)\n");
446 printf(" libc.free(ptr)\n");
447 printf(" return res\n");
448 printf(" def __repr__(self):\n");
449 printf(" return 'isl.%s(\"%%s\")' %% str(self)\n", p_name
.c_str());
451 for (in
= methods
.begin(); in
!= methods
.end(); ++in
)
452 print_method(*in
, subclass
, super
);
455 for (in
= constructors
.begin(); in
!= constructors
.end(); ++in
) {
456 string fullname
= (*in
)->getName();
457 printf("isl.%s.restype = c_void_p\n", fullname
.c_str());
458 printf("isl.%s.argtypes = [", fullname
.c_str());
459 for (int i
= 0; i
< (*in
)->getNumParams(); ++i
) {
460 ParmVarDecl
*param
= (*in
)->getParamDecl(i
);
461 QualType type
= param
->getOriginalType();
464 if (is_isl_ctx(type
))
466 else if (is_isl_type(type
))
468 else if (is_string(type
))
475 for (in
= methods
.begin(); in
!= methods
.end(); ++in
) {
476 string fullname
= (*in
)->getName();
477 if (is_isl_type((*in
)->getReturnType()))
478 printf("isl.%s.restype = c_void_p\n", fullname
.c_str());
480 printf("isl.%s_free.argtypes = [c_void_p]\n", name
.c_str());
481 printf("isl.%s_to_str.argtypes = [c_void_p]\n", name
.c_str());
482 printf("isl.%s_to_str.restype = POINTER(c_char)\n", name
.c_str());
485 /* Generate a python interface based on the extracted types and functions.
486 * We first collect all functions that belong to a certain type,
487 * separating constructors from regular methods.
489 * Then we print out each class in turn. If one of these is a subclass
490 * of some other class, it will make sure the superclass is printed out first.
492 void generate_python(set
<RecordDecl
*> &types
, set
<FunctionDecl
*> functions
)
494 map
<string
, isl_class
> classes
;
495 map
<string
, isl_class
>::iterator ci
;
498 set
<RecordDecl
*>::iterator it
;
499 for (it
= types
.begin(); it
!= types
.end(); ++it
) {
500 RecordDecl
*decl
= *it
;
501 string name
= decl
->getName();
502 classes
[name
].name
= name
;
503 classes
[name
].type
= decl
;
506 set
<FunctionDecl
*>::iterator in
;
507 for (in
= functions
.begin(); in
!= functions
.end(); ++in
) {
508 isl_class
&c
= method2class(classes
, *in
);
509 if (is_constructor(*in
))
510 c
.constructors
.insert(*in
);
512 c
.methods
.insert(*in
);
515 for (ci
= classes
.begin(); ci
!= classes
.end(); ++ci
) {
516 if (done
.find(ci
->first
) == done
.end())
517 ci
->second
.print(classes
, done
);