cloog-0.17.0/isl/interface/python.cc - toolchain/cloog - Git at Google

 /*
  * Copyright 2011 Sven Verdoolaege. All rights reserved.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions
  * are met:
  *
  *    1. Redistributions of source code must retain the above copyright
  *       notice, this list of conditions and the following disclaimer.
  *
  *    2. Redistributions in binary form must reproduce the above
  *       copyright notice, this list of conditions and the following
  *       disclaimer in the documentation and/or other materials provided
  *       with the distribution.
  *
  * THIS SOFTWARE IS PROVIDED BY SVEN VERDOOLAEGE ''AS IS'' AND ANY
  * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
  * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL SVEN VERDOOLAEGE OR
  * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
  * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
  * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA,
  * OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
  * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
  * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  *
  * The views and conclusions contained in the software and documentation
  * are those of the authors and should not be interpreted as
  * representing official policies, either expressed or implied, of
  * Sven Verdoolaege.
  */

 #include <stdio.h>
 #include <iostream>
 #include <map>
 #include "extract_interface.h"
 #include "python.h"

 /* Is the given type declaration marked as being a subtype of some other
  * type?  If so, return that other type in "super".
  */
 static bool is_subclass(RecordDecl *decl, string &super)
 {
 	if (!decl->hasAttrs())
 		return false;

 	string sub = "isl_subclass";
 	size_t len = sub.length();
 	AttrVec attrs = decl->getAttrs();
 	for (AttrVec::const_iterator i = attrs.begin() ; i != attrs.end(); ++i) {
 		const AnnotateAttr *ann = dyn_cast<AnnotateAttr>(*i);
 		if (!ann)
 			continue;
 		string s = ann->getAnnotation().str();
 		if (s.substr(0, len) == sub) {
 			super = s.substr(len + 1, s.length() - len  - 2);
 			return true;
 		}
 	}

 	return false;
 }

 /* Is decl marked as a constructor?
  */
 static bool is_constructor(Decl *decl)
 {
 	return has_annotation(decl, "isl_constructor");
 }

 /* Is decl marked as consuming a reference?
  */
 static bool takes(Decl *decl)
 {
 	return has_annotation(decl, "isl_take");
 }

 /* isl_class collects all constructors and methods for an isl "class".
  * "name" is the name of the class.
  * "type" is the declaration that introduces the type.
  */
 struct isl_class {
 	string name;
 	RecordDecl *type;
 	set<FunctionDecl *> constructors;
 	set<FunctionDecl *> methods;

 	void print(map<string, isl_class> &classes, set<string> &done);
 	void print_constructor(FunctionDecl *method);
 	void print_method(FunctionDecl *method, bool subclass, string super);
 };

 /* Return the class that has a name that matches the initial part
  * of the namd of function "fd".
  */
 static isl_class &method2class(map<string, isl_class> &classes,
 	FunctionDecl *fd)
 {
 	string best;
 	map<string, isl_class>::iterator ci;
 	string name = fd->getNameAsString();

 	for (ci = classes.begin(); ci != classes.end(); ++ci) {
 		if (name.substr(0, ci->first.length()) == ci->first)
 			best = ci->first;
 	}

 	return classes[best];
 }

 /* Is "type" the type "isl_ctx *"?
  */
 static bool is_isl_ctx(QualType type)
 {
 	if (!type->isPointerType())
 		return 0;
 	type = type->getPointeeType();
 	if (type.getAsString() != "isl_ctx")
 		return false;

 	return true;
 }

 /* Is the first argument of "fd" of type "isl_ctx *"?
  */
 static bool first_arg_is_isl_ctx(FunctionDecl *fd)
 {
 	ParmVarDecl *param;

 	if (fd->getNumParams() < 1)
 		return false;

 	param = fd->getParamDecl(0);
 	return is_isl_ctx(param->getOriginalType());
 }

 /* Is "type" that of a pointer to an isl_* structure?
  */
 static bool is_isl_type(QualType type)
 {
 	if (type->isPointerType()) {
 		string s = type->getPointeeType().getAsString();
 		return s.substr(0, 4) == "isl_";
 	}

 	return false;
 }

 /* Is "type" that of a pointer to a function?
  */
 static bool is_callback(QualType type)
 {
 	if (!type->isPointerType())
 		return false;
 	type = type->getPointeeType();
 	return type->isFunctionType();
 }

 /* Is "type" that of "char *" of "const char *"?
  */
 static bool is_string(QualType type)
 {
 	if (type->isPointerType()) {
 		string s = type->getPointeeType().getAsString();
 		return s == "const char" || s == "char";
 	}

 	return false;
 }

 /* Return the name of the type that "type" points to.
  * The input "type" is assumed to be a pointer type.
  */
 static string extract_type(QualType type)
 {
 	if (type->isPointerType())
 		return type->getPointeeType().getAsString();
 	assert(0);
 }

 /* Drop the "isl_" initial part of the type name "name".
  */
 static string type2python(string name)
 {
 	return name.substr(4);
 }

 /* Construct a wrapper for a callback argument (at position "arg").
  * Assign the wrapper to "cb".  We assume here that a function call
  * has at most one callback argument.
  *
  * The wrapper converts the arguments of the callback to python types.
  * If any exception is thrown, the wrapper keeps track of it in exc_info[0]
  * and returns -1.  Otherwise the wrapper returns 0.
  */
 static void print_callback(QualType type, int arg)
 {
 	const FunctionProtoType *fn = type->getAs<FunctionProtoType>();
 	unsigned n_arg = fn->getNumArgs();

 	printf("        exc_info = [None]\n");
 	printf("        fn = CFUNCTYPE(c_int");
 	for (int i = 0; i < n_arg - 1; ++i) {
 		QualType arg_type = fn->getArgType(i);
 		assert(is_isl_type(arg_type));
 		printf(", c_void_p");
 	}
 	printf(", c_void_p)\n");
 	printf("        def cb_func(");
 	for (int i = 0; i < n_arg; ++i) {
 		if (i)
 			printf(", ");
 		printf("cb_arg%d", i);
 	}
 	printf("):\n");
 	for (int i = 0; i < n_arg - 1; ++i) {
 		string arg_type;
 		arg_type = type2python(extract_type(fn->getArgType(i)));
 		printf("            cb_arg%d = %s(ctx=self.ctx, ptr=cb_arg%d)\n",
 			i, arg_type.c_str(), i);
 	}
 	printf("            try:\n");
 	printf("                arg%d(", arg);
 	for (int i = 0; i < n_arg - 1; ++i) {
 		if (i)
 			printf(", ");
 		printf("cb_arg%d", i);
 	}
 	printf(")\n");
 	printf("            except:\n");
 	printf("                import sys\n");
 	printf("                exc_info[0] = sys.exc_info()\n");
 	printf("                return -1\n");
 	printf("            return 0\n");
 	printf("        cb = fn(cb_func)\n");
 }

 /* Print a python method corresponding to the C function "method".
  * "subclass" is set if the method belongs to a class that is a subclass
  * of some other class ("super").
  *
  * If the function has a callback argument, then it also has a "user"
  * argument.  Since Python has closures, there is no need for such
  * a user argument in the Python interface, so we simply drop it.
  * We also create a wrapper ("cb") for the callback.
  *
  * If the function has additional arguments that refer to isl structures,
  * then we check if the actual arguments are of the right type.
  * If not, we try to convert it to the right type.
  * It that doesn't work and if subclass is set, we try to convert self
  * to the type of the superclass and call the corresponding method.
  *
  * If the function consumes a reference, then we pass it a copy of
  * the actual argument.
  */
 void isl_class::print_method(FunctionDecl *method, bool subclass, string super)
 {
 	string fullname = method->getName();
 	string cname = fullname.substr(name.length() + 1);
 	int num_params = method->getNumParams();
 	int drop_user = 0;

 	for (int i = 1; i < num_params; ++i) {
 		ParmVarDecl *param = method->getParamDecl(i);
 		QualType type = param->getOriginalType();
 		if (is_callback(type))
 			drop_user = 1;
 	}

 	printf("    def %s(self", cname.c_str());
 	for (int i = 1; i < num_params - drop_user; ++i)
 		printf(", arg%d", i);
 	printf("):\n");

 	for (int i = 1; i < num_params; ++i) {
 		ParmVarDecl *param = method->getParamDecl(i);
 		string type;
 		if (!is_isl_type(param->getOriginalType()))
 			continue;
 		type = type2python(extract_type(param->getOriginalType()));
 		printf("        try:\n");
 		printf("            if not arg%d.__class__ is %s:\n",
 			i, type.c_str());
 		printf("                arg%d = %s(arg%d)\n",
 			i, type.c_str(), i);
 		printf("        except:\n");
 		if (subclass) {
 			printf("            return %s(self).%s(",
 				type2python(super).c_str(), cname.c_str());
 			for (int i = 1; i < num_params - drop_user; ++i) {
 				if (i != 1)
 					printf(", ");
 				printf("arg%d", i);
 			}
 			printf(")\n");
 		} else
 			printf("            raise\n");
 	}
 	for (int i = 1; i < num_params; ++i) {
 		ParmVarDecl *param = method->getParamDecl(i);
 		QualType type = param->getOriginalType();
 		if (!is_callback(type))
 			continue;
 		print_callback(type->getPointeeType(), i);
 	}
 	printf("        res = isl.%s(", fullname.c_str());
 	if (takes(method->getParamDecl(0)))
 		printf("isl.%s_copy(self.ptr)", name.c_str());
 	else
 		printf("self.ptr");
 	for (int i = 1; i < num_params - drop_user; ++i) {
 		ParmVarDecl *param = method->getParamDecl(i);
 		QualType type = param->getOriginalType();
 		if (is_callback(type))
 			printf(", cb");
 		else if (takes(param)) {
 			string type_s = extract_type(type);
 			printf(", isl.%s_copy(arg%d.ptr)", type_s.c_str(), i);
 		} else
 			printf(", arg%d.ptr", i);
 	}
 	if (drop_user)
 		printf(", None");
 	printf(")\n");

 	if (is_isl_type(method->getResultType())) {
 		string type;
 		type = type2python(extract_type(method->getResultType()));
 		printf("        return %s(ctx=self.ctx, ptr=res)\n",
 			type.c_str());
 	} else {
 		if (drop_user) {
 			printf("        if exc_info[0] != None:\n");
 			printf("            raise exc_info[0][0], "
 				"exc_info[0][1], exc_info[0][2]\n");
 		}
 		printf("        return res\n");
 	}
 }

 /* Print part of the constructor for this isl_class.
  *
  * In particular, check if the actual arguments correspond to the
  * formal arguments of "cons" and if so call "cons" and put the
  * result in self.ptr and a reference to the default context in self.ctx.
  *
  * If the function consumes a reference, then we pass it a copy of
  * the actual argument.
  */
 void isl_class::print_constructor(FunctionDecl *cons)
 {
 	string fullname = cons->getName();
 	string cname = fullname.substr(name.length() + 1);
 	int num_params = cons->getNumParams();
 	int drop_ctx = first_arg_is_isl_ctx(cons);

 	printf("        if len(args) == %d", num_params - drop_ctx);
 	for (int i = drop_ctx; i < num_params; ++i) {
 		ParmVarDecl *param = cons->getParamDecl(i);
 		if (is_isl_type(param->getOriginalType())) {
 			string type;
 			type = extract_type(param->getOriginalType());
 			type = type2python(type);
 			printf(" and args[%d].__class__ is %s",
 				i - drop_ctx, type.c_str());
 		} else
 			printf(" and type(args[%d]) == str", i - drop_ctx);
 	}
 	printf(":\n");
 	printf("            self.ctx = Context.getDefaultInstance()\n");
 	printf("            self.ptr = isl.%s(", fullname.c_str());
 	if (drop_ctx)
 		printf("self.ctx");
 	for (int i = drop_ctx; i < num_params; ++i) {
 		ParmVarDecl *param = cons->getParamDecl(i);
 		if (i)
 			printf(", ");
 		if (is_isl_type(param->getOriginalType())) {
 			if (takes(param)) {
 				string type;
 				type = extract_type(param->getOriginalType());
 				printf("isl.%s_copy(args[%d].ptr)",
 					type.c_str(), i - drop_ctx);
 			} else
 				printf("args[%d].ptr", i - drop_ctx);
 		} else
 			printf("args[%d]", i - drop_ctx);
 	}
 	printf(")\n");
 	printf("            return\n");
 }

 /* Print out the definition of this isl_class.
  *
  * We first check if this isl_class is a subclass of some other class.
  * If it is, we make sure the superclass is printed out first.
  *
  * Then we print a constructor with several cases, one for constructing
  * a Python object from a return value and one for each function that
  * was marked as a constructor.
  *
  * Next, we print out some common methods and the methods corresponding
  * to functions that are not marked as constructors.
  *
  * Finally, we tell ctypes about the types of the arguments of the
  * constructor functions and the return types of those function returning
  * an isl object.
  */
 void isl_class::print(map<string, isl_class> &classes, set<string> &done)
 {
 	string super;
 	string p_name = type2python(name);
 	set<FunctionDecl *>::iterator in;
 	bool subclass = is_subclass(type, super);

 	if (subclass && done.find(super) == done.end())
 		classes[super].print(classes, done);
 	done.insert(name);

 	printf("\n");
 	printf("class %s", p_name.c_str());
 	if (subclass)
 		printf("(%s)", type2python(super).c_str());
 	printf(":\n");
 	printf("    def __init__(self, *args, **keywords):\n");

 	printf("        if \"ptr\" in keywords:\n");
 	printf("            self.ctx = keywords[\"ctx\"]\n");
 	printf("            self.ptr = keywords[\"ptr\"]\n");
 	printf("            return\n");

 	for (in = constructors.begin(); in != constructors.end(); ++in)
 		print_constructor(*in);
 	printf("        raise Error\n");
 	printf("    def __del__(self):\n");
 	printf("        if hasattr(self, 'ptr'):\n");
 	printf("            isl.%s_free(self.ptr)\n", name.c_str());
 	printf("    def __str__(self):\n");
 	printf("        ptr = isl.%s_to_str(self.ptr)\n", name.c_str());
 	printf("        res = str(cast(ptr, c_char_p).value)\n");
 	printf("        libc.free(ptr)\n");
 	printf("        return res\n");
 	printf("    def __repr__(self):\n");
 	printf("        return 'isl.%s(\"%%s\")' %% str(self)\n", p_name.c_str());

 	for (in = methods.begin(); in != methods.end(); ++in)
 		print_method(*in, subclass, super);

 	printf("\n");
 	for (in = constructors.begin(); in != constructors.end(); ++in) {
 		string fullname = (*in)->getName();
 		printf("isl.%s.restype = c_void_p\n", fullname.c_str());
 		printf("isl.%s.argtypes = [", fullname.c_str());
 		for (int i = 0; i < (*in)->getNumParams(); ++i) {
 			ParmVarDecl *param = (*in)->getParamDecl(i);
 			QualType type = param->getOriginalType();
 			if (i)
 				printf(", ");
 			if (is_isl_ctx(type))
 				printf("Context");
 			else if (is_isl_type(type))
 				printf("c_void_p");
 			else if (is_string(type))
 				printf("c_char_p");
 			else
 				printf("c_int");
 		}
 		printf("]\n");
 	}
 	for (in = methods.begin(); in != methods.end(); ++in) {
 		string fullname = (*in)->getName();
 		if (is_isl_type((*in)->getResultType()))
 			printf("isl.%s.restype = c_void_p\n", fullname.c_str());
 	}
 	printf("isl.%s_free.argtypes = [c_void_p]\n", name.c_str());
 	printf("isl.%s_to_str.argtypes = [c_void_p]\n", name.c_str());
 	printf("isl.%s_to_str.restype = POINTER(c_char)\n", name.c_str());
 }

 /* Generate a python interface based on the extracted types and functions.
  * We first collect all functions that belong to a certain type,
  * separating constructors from regular methods.
  *
  * Then we print out each class in turn.  If one of these is a subclass
  * of some other class, it will make sure the superclass is printed out first.
  */
 void generate_python(set<RecordDecl *> &types, set<FunctionDecl *> functions)
 {
 	map<string, isl_class> classes;
 	map<string, isl_class>::iterator ci;
 	set<string> done;

 	set<RecordDecl *>::iterator it;
 	for (it = types.begin(); it != types.end(); ++it) {
 		RecordDecl *decl = *it;
 		string name = decl->getName();
 		classes[name].name = name;
 		classes[name].type = decl;
 	}

 	set<FunctionDecl *>::iterator in;
 	for (in = functions.begin(); in != functions.end(); ++in) {
 		isl_class &c = method2class(classes, *in);
 		if (is_constructor(*in))
 			c.constructors.insert(*in);
 		else
 			c.methods.insert(*in);
 	}

 	for (ci = classes.begin(); ci != classes.end(); ++ci) {
 		if (done.find(ci->first) == done.end())
 			ci->second.print(classes, done);
 	}
 }
	/*
	* Copyright 2011 Sven Verdoolaege. All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions
	* are met:
	*
	* 1. Redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer.
	*
	* 2. Redistributions in binary form must reproduce the above
	* copyright notice, this list of conditions and the following
	* disclaimer in the documentation and/or other materials provided
	* with the distribution.
	*
	* THIS SOFTWARE IS PROVIDED BY SVEN VERDOOLAEGE ''AS IS'' AND ANY
	* EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
	* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
	* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL SVEN VERDOOLAEGE OR
	* CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
	* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
	* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA,
	* OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*
	* The views and conclusions contained in the software and documentation
	* are those of the authors and should not be interpreted as
	* representing official policies, either expressed or implied, of
	* Sven Verdoolaege.
	*/

	#include <stdio.h>
	#include <iostream>
	#include <map>
	#include "extract_interface.h"
	#include "python.h"

	/* Is the given type declaration marked as being a subtype of some other
	* type? If so, return that other type in "super".
	*/
	static bool is_subclass(RecordDecl *decl, string &super)
	{
	if (!decl->hasAttrs())
	return false;

	string sub = "isl_subclass";
	size_t len = sub.length();
	AttrVec attrs = decl->getAttrs();
	for (AttrVec::const_iterator i = attrs.begin() ; i != attrs.end(); ++i) {
	const AnnotateAttr ann = dyn_cast<AnnotateAttr>(i);
	if (!ann)
	continue;
	string s = ann->getAnnotation().str();
	if (s.substr(0, len) == sub) {
	super = s.substr(len + 1, s.length() - len - 2);
	return true;
	}
	}

	return false;
	}

	/* Is decl marked as a constructor?
	*/
	static bool is_constructor(Decl *decl)
	{
	return has_annotation(decl, "isl_constructor");
	}

	/* Is decl marked as consuming a reference?
	*/
	static bool takes(Decl *decl)
	{
	return has_annotation(decl, "isl_take");
	}

	/* isl_class collects all constructors and methods for an isl "class".
	* "name" is the name of the class.
	* "type" is the declaration that introduces the type.
	*/
	struct isl_class {
	string name;
	RecordDecl *type;
	set<FunctionDecl *> constructors;
	set<FunctionDecl *> methods;

	void print(map<string, isl_class> &classes, set<string> &done);
	void print_constructor(FunctionDecl *method);
	void print_method(FunctionDecl *method, bool subclass, string super);
	};

	/* Return the class that has a name that matches the initial part
	* of the namd of function "fd".
	*/
	static isl_class &method2class(map<string, isl_class> &classes,
	FunctionDecl *fd)
	{
	string best;
	map<string, isl_class>::iterator ci;
	string name = fd->getNameAsString();

	for (ci = classes.begin(); ci != classes.end(); ++ci) {
	if (name.substr(0, ci->first.length()) == ci->first)
	best = ci->first;
	}

	return classes[best];
	}

	/* Is "type" the type "isl_ctx *"?
	*/
	static bool is_isl_ctx(QualType type)
	{
	if (!type->isPointerType())
	return 0;
	type = type->getPointeeType();
	if (type.getAsString() != "isl_ctx")
	return false;

	return true;
	}

	/* Is the first argument of "fd" of type "isl_ctx *"?
	*/
	static bool first_arg_is_isl_ctx(FunctionDecl *fd)
	{
	ParmVarDecl *param;

	if (fd->getNumParams() < 1)
	return false;

	param = fd->getParamDecl(0);
	return is_isl_ctx(param->getOriginalType());
	}

	/* Is "type" that of a pointer to an isl_* structure?
	*/
	static bool is_isl_type(QualType type)
	{
	if (type->isPointerType()) {
	string s = type->getPointeeType().getAsString();
	return s.substr(0, 4) == "isl_";
	}

	return false;
	}

	/* Is "type" that of a pointer to a function?
	*/
	static bool is_callback(QualType type)
	{
	if (!type->isPointerType())
	return false;
	type = type->getPointeeType();
	return type->isFunctionType();
	}

	/* Is "type" that of "char " of "const char "?
	*/
	static bool is_string(QualType type)
	{
	if (type->isPointerType()) {
	string s = type->getPointeeType().getAsString();
	return s == "const char" \|\| s == "char";
	}

	return false;
	}

	/* Return the name of the type that "type" points to.
	* The input "type" is assumed to be a pointer type.
	*/
	static string extract_type(QualType type)
	{
	if (type->isPointerType())
	return type->getPointeeType().getAsString();
	assert(0);
	}

	/* Drop the "isl_" initial part of the type name "name".
	*/
	static string type2python(string name)
	{
	return name.substr(4);
	}

	/* Construct a wrapper for a callback argument (at position "arg").
	* Assign the wrapper to "cb". We assume here that a function call
	* has at most one callback argument.
	*
	* The wrapper converts the arguments of the callback to python types.
	* If any exception is thrown, the wrapper keeps track of it in exc_info[0]
	* and returns -1. Otherwise the wrapper returns 0.
	*/
	static void print_callback(QualType type, int arg)
	{
	const FunctionProtoType *fn = type->getAs<FunctionProtoType>();
	unsigned n_arg = fn->getNumArgs();

	printf(" exc_info = [None]\n");
	printf(" fn = CFUNCTYPE(c_int");
	for (int i = 0; i < n_arg - 1; ++i) {
	QualType arg_type = fn->getArgType(i);
	assert(is_isl_type(arg_type));
	printf(", c_void_p");
	}
	printf(", c_void_p)\n");
	printf(" def cb_func(");
	for (int i = 0; i < n_arg; ++i) {
	if (i)
	printf(", ");
	printf("cb_arg%d", i);
	}
	printf("):\n");
	for (int i = 0; i < n_arg - 1; ++i) {
	string arg_type;
	arg_type = type2python(extract_type(fn->getArgType(i)));
	printf(" cb_arg%d = %s(ctx=self.ctx, ptr=cb_arg%d)\n",
	i, arg_type.c_str(), i);
	}
	printf(" try:\n");
	printf(" arg%d(", arg);
	for (int i = 0; i < n_arg - 1; ++i) {
	if (i)
	printf(", ");
	printf("cb_arg%d", i);
	}
	printf(")\n");
	printf(" except:\n");
	printf(" import sys\n");
	printf(" exc_info[0] = sys.exc_info()\n");
	printf(" return -1\n");
	printf(" return 0\n");
	printf(" cb = fn(cb_func)\n");
	}

	/* Print a python method corresponding to the C function "method".
	* "subclass" is set if the method belongs to a class that is a subclass
	* of some other class ("super").
	*
	* If the function has a callback argument, then it also has a "user"
	* argument. Since Python has closures, there is no need for such
	* a user argument in the Python interface, so we simply drop it.
	* We also create a wrapper ("cb") for the callback.
	*
	* If the function has additional arguments that refer to isl structures,
	* then we check if the actual arguments are of the right type.
	* If not, we try to convert it to the right type.
	* It that doesn't work and if subclass is set, we try to convert self
	* to the type of the superclass and call the corresponding method.
	*
	* If the function consumes a reference, then we pass it a copy of
	* the actual argument.
	*/
	void isl_class::print_method(FunctionDecl *method, bool subclass, string super)
	{
	string fullname = method->getName();
	string cname = fullname.substr(name.length() + 1);
	int num_params = method->getNumParams();
	int drop_user = 0;

	for (int i = 1; i < num_params; ++i) {
	ParmVarDecl *param = method->getParamDecl(i);
	QualType type = param->getOriginalType();
	if (is_callback(type))
	drop_user = 1;
	}

	printf(" def %s(self", cname.c_str());
	for (int i = 1; i < num_params - drop_user; ++i)
	printf(", arg%d", i);
	printf("):\n");

	for (int i = 1; i < num_params; ++i) {
	ParmVarDecl *param = method->getParamDecl(i);
	string type;
	if (!is_isl_type(param->getOriginalType()))
	continue;
	type = type2python(extract_type(param->getOriginalType()));
	printf(" try:\n");
	printf(" if not arg%d.__class__ is %s:\n",
	i, type.c_str());
	printf(" arg%d = %s(arg%d)\n",
	i, type.c_str(), i);
	printf(" except:\n");
	if (subclass) {
	printf(" return %s(self).%s(",
	type2python(super).c_str(), cname.c_str());
	for (int i = 1; i < num_params - drop_user; ++i) {
	if (i != 1)
	printf(", ");
	printf("arg%d", i);
	}
	printf(")\n");
	} else
	printf(" raise\n");
	}
	for (int i = 1; i < num_params; ++i) {
	ParmVarDecl *param = method->getParamDecl(i);
	QualType type = param->getOriginalType();
	if (!is_callback(type))
	continue;
	print_callback(type->getPointeeType(), i);
	}
	printf(" res = isl.%s(", fullname.c_str());
	if (takes(method->getParamDecl(0)))
	printf("isl.%s_copy(self.ptr)", name.c_str());
	else
	printf("self.ptr");
	for (int i = 1; i < num_params - drop_user; ++i) {
	ParmVarDecl *param = method->getParamDecl(i);
	QualType type = param->getOriginalType();
	if (is_callback(type))
	printf(", cb");
	else if (takes(param)) {
	string type_s = extract_type(type);
	printf(", isl.%s_copy(arg%d.ptr)", type_s.c_str(), i);
	} else
	printf(", arg%d.ptr", i);
	}
	if (drop_user)
	printf(", None");
	printf(")\n");

	if (is_isl_type(method->getResultType())) {
	string type;
	type = type2python(extract_type(method->getResultType()));
	printf(" return %s(ctx=self.ctx, ptr=res)\n",
	type.c_str());
	} else {
	if (drop_user) {
	printf(" if exc_info[0] != None:\n");
	printf(" raise exc_info[0][0], "
	"exc_info[0][1], exc_info[0][2]\n");
	}
	printf(" return res\n");
	}
	}

	/* Print part of the constructor for this isl_class.
	*
	* In particular, check if the actual arguments correspond to the
	* formal arguments of "cons" and if so call "cons" and put the
	* result in self.ptr and a reference to the default context in self.ctx.
	*
	* If the function consumes a reference, then we pass it a copy of
	* the actual argument.
	*/
	void isl_class::print_constructor(FunctionDecl *cons)
	{
	string fullname = cons->getName();
	string cname = fullname.substr(name.length() + 1);
	int num_params = cons->getNumParams();
	int drop_ctx = first_arg_is_isl_ctx(cons);

	printf(" if len(args) == %d", num_params - drop_ctx);
	for (int i = drop_ctx; i < num_params; ++i) {
	ParmVarDecl *param = cons->getParamDecl(i);
	if (is_isl_type(param->getOriginalType())) {
	string type;
	type = extract_type(param->getOriginalType());
	type = type2python(type);
	printf(" and args[%d].__class__ is %s",
	i - drop_ctx, type.c_str());
	} else
	printf(" and type(args[%d]) == str", i - drop_ctx);
	}
	printf(":\n");
	printf(" self.ctx = Context.getDefaultInstance()\n");
	printf(" self.ptr = isl.%s(", fullname.c_str());
	if (drop_ctx)
	printf("self.ctx");
	for (int i = drop_ctx; i < num_params; ++i) {
	ParmVarDecl *param = cons->getParamDecl(i);
	if (i)
	printf(", ");
	if (is_isl_type(param->getOriginalType())) {
	if (takes(param)) {
	string type;
	type = extract_type(param->getOriginalType());
	printf("isl.%s_copy(args[%d].ptr)",
	type.c_str(), i - drop_ctx);
	} else
	printf("args[%d].ptr", i - drop_ctx);
	} else
	printf("args[%d]", i - drop_ctx);
	}
	printf(")\n");
	printf(" return\n");
	}

	/* Print out the definition of this isl_class.
	*
	* We first check if this isl_class is a subclass of some other class.
	* If it is, we make sure the superclass is printed out first.
	*
	* Then we print a constructor with several cases, one for constructing
	* a Python object from a return value and one for each function that
	* was marked as a constructor.
	*
	* Next, we print out some common methods and the methods corresponding
	* to functions that are not marked as constructors.
	*
	* Finally, we tell ctypes about the types of the arguments of the
	* constructor functions and the return types of those function returning
	* an isl object.
	*/
	void isl_class::print(map<string, isl_class> &classes, set<string> &done)
	{
	string super;
	string p_name = type2python(name);
	set<FunctionDecl *>::iterator in;
	bool subclass = is_subclass(type, super);

	if (subclass && done.find(super) == done.end())
	classes[super].print(classes, done);
	done.insert(name);

	printf("\n");
	printf("class %s", p_name.c_str());
	if (subclass)
	printf("(%s)", type2python(super).c_str());
	printf(":\n");
	printf(" def __init__(self, args, *keywords):\n");

	printf(" if \"ptr\" in keywords:\n");
	printf(" self.ctx = keywords[\"ctx\"]\n");
	printf(" self.ptr = keywords[\"ptr\"]\n");
	printf(" return\n");

	for (in = constructors.begin(); in != constructors.end(); ++in)
	print_constructor(*in);
	printf(" raise Error\n");
	printf(" def __del__(self):\n");
	printf(" if hasattr(self, 'ptr'):\n");
	printf(" isl.%s_free(self.ptr)\n", name.c_str());
	printf(" def __str__(self):\n");
	printf(" ptr = isl.%s_to_str(self.ptr)\n", name.c_str());
	printf(" res = str(cast(ptr, c_char_p).value)\n");
	printf(" libc.free(ptr)\n");
	printf(" return res\n");
	printf(" def __repr__(self):\n");
	printf(" return 'isl.%s(\"%%s\")' %% str(self)\n", p_name.c_str());

	for (in = methods.begin(); in != methods.end(); ++in)
	print_method(*in, subclass, super);

	printf("\n");
	for (in = constructors.begin(); in != constructors.end(); ++in) {
	string fullname = (*in)->getName();
	printf("isl.%s.restype = c_void_p\n", fullname.c_str());
	printf("isl.%s.argtypes = [", fullname.c_str());
	for (int i = 0; i < (*in)->getNumParams(); ++i) {
	ParmVarDecl param = (in)->getParamDecl(i);
	QualType type = param->getOriginalType();
	if (i)
	printf(", ");
	if (is_isl_ctx(type))
	printf("Context");
	else if (is_isl_type(type))
	printf("c_void_p");
	else if (is_string(type))
	printf("c_char_p");
	else
	printf("c_int");
	}
	printf("]\n");
	}
	for (in = methods.begin(); in != methods.end(); ++in) {
	string fullname = (*in)->getName();
	if (is_isl_type((*in)->getResultType()))
	printf("isl.%s.restype = c_void_p\n", fullname.c_str());
	}
	printf("isl.%s_free.argtypes = [c_void_p]\n", name.c_str());
	printf("isl.%s_to_str.argtypes = [c_void_p]\n", name.c_str());
	printf("isl.%s_to_str.restype = POINTER(c_char)\n", name.c_str());
	}

	/* Generate a python interface based on the extracted types and functions.
	* We first collect all functions that belong to a certain type,
	* separating constructors from regular methods.
	*
	* Then we print out each class in turn. If one of these is a subclass
	* of some other class, it will make sure the superclass is printed out first.
	*/
	void generate_python(set<RecordDecl > &types, set<FunctionDecl > functions)
	{
	map<string, isl_class> classes;
	map<string, isl_class>::iterator ci;
	set<string> done;

	set<RecordDecl *>::iterator it;
	for (it = types.begin(); it != types.end(); ++it) {
	RecordDecl decl = it;
	string name = decl->getName();
	classes[name].name = name;
	classes[name].type = decl;
	}

	set<FunctionDecl *>::iterator in;
	for (in = functions.begin(); in != functions.end(); ++in) {
	isl_class &c = method2class(classes, *in);
	if (is_constructor(*in))
	c.constructors.insert(*in);
	else
	c.methods.insert(*in);
	}

	for (ci = classes.begin(); ci != classes.end(); ++ci) {
	if (done.find(ci->first) == done.end())
	ci->second.print(classes, done);
	}
	}