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source: src/GenPoly/Box.cc @ e6cee92

ADTaaron-thesisarm-ehast-experimentalcleanup-dtorsdeferred_resndemanglerenumforall-pointer-decayjacob/cs343-translationjenkins-sandboxnew-astnew-ast-unique-exprnew-envno_listpersistent-indexerpthread-emulationqualifiedEnumresolv-newwith_gc

Last change on this file since e6cee92 was 0a81c3f, checked in by Rob Schluntz <rschlunt@…>, 7 years ago
Remove several missing-reference related hacks
Property mode set to `100644`
File size: 86.7 KB

Line
1	//
2	// Cforall Version 1.0.0 Copyright (C) 2015 University of Waterloo
3	//
4	// The contents of this file are covered under the licence agreement in the
5	// file "LICENCE" distributed with Cforall.
6	//
7	// Box.cc --
8	//
9	// Author : Richard C. Bilson
10	// Created On : Mon May 18 07:44:20 2015
11	// Last Modified By : Peter A. Buhr
12	// Last Modified On : Wed Jun 21 15:49:59 2017
13	// Update Count : 346
14	//
15
16	#include <algorithm>
17	#include <iterator>
18	#include <list>
19	#include <map>
20	#include <set>
21	#include <stack>
22	#include <string>
23	#include <utility>
24	#include <vector>
25	#include <cassert>
26
27	#include "Box.h"
28	#include "DeclMutator.h"
29	#include "PolyMutator.h"
30	#include "FindFunction.h"
31	#include "ScopedSet.h"
32	#include "ScrubTyVars.h"
33
34	#include "Parser/ParseNode.h"
35
36	#include "SynTree/Attribute.h"
37	#include "SynTree/Constant.h"
38	#include "SynTree/Declaration.h"
39	#include "SynTree/Expression.h"
40	#include "SynTree/Initializer.h"
41	#include "SynTree/Mutator.h"
42	#include "SynTree/Statement.h"
43	#include "SynTree/Type.h"
44	#include "SynTree/TypeSubstitution.h"
45
46	#include "ResolvExpr/TypeEnvironment.h"
47	#include "ResolvExpr/TypeMap.h"
48	#include "ResolvExpr/typeops.h"
49
50	#include "SymTab/Indexer.h"
51	#include "SymTab/Mangler.h"
52
53	#include "Common/ScopedMap.h"
54	#include "Common/SemanticError.h"
55	#include "Common/UniqueName.h"
56	#include "Common/utility.h"
57
58	#include "InitTweak/InitTweak.h"
59
60	#include <ext/functional> // temporary
61
62	namespace GenPoly {
63	namespace {
64	FunctionType makeAdapterType( FunctionType adaptee, const TyVarMap &tyVars );
65
66	/// Adds layout-generation functions to polymorphic types
67	class LayoutFunctionBuilder final : public DeclMutator {
68	unsigned int functionNesting; // current level of nested functions
69	public:
70	LayoutFunctionBuilder() : functionNesting( 0 ) {}
71
72	using DeclMutator::mutate;
73	virtual DeclarationWithType mutate( FunctionDecl functionDecl ) override;
74	virtual Declaration mutate( StructDecl structDecl ) override;
75	virtual Declaration mutate( UnionDecl unionDecl ) override;
76	};
77
78	/// Replaces polymorphic return types with out-parameters, replaces calls to polymorphic functions with adapter calls as needed, and adds appropriate type variables to the function call
79	class Pass1 final : public PolyMutator {
80	public:
81	Pass1();
82
83	using PolyMutator::mutate;
84	virtual Expression mutate( ApplicationExpr appExpr ) override;
85	virtual Expression mutate( AddressExpr addrExpr ) override;
86	virtual Expression mutate( UntypedExpr expr ) override;
87	virtual DeclarationWithType* mutate( FunctionDecl *functionDecl ) override;
88	virtual TypeDecl mutate( TypeDecl typeDecl ) override;
89	virtual Expression mutate( CommaExpr commaExpr ) override;
90	virtual Expression mutate( ConditionalExpr condExpr ) override;
91	virtual Statement * mutate( ReturnStmt *returnStmt ) override;
92	virtual Type mutate( PointerType pointerType ) override;
93	virtual Type * mutate( FunctionType *functionType ) override;
94
95	virtual void doBeginScope() override;
96	virtual void doEndScope() override;
97	private:
98	/// Pass the extra type parameters from polymorphic generic arguments or return types into a function application
99	void passArgTypeVars( ApplicationExpr appExpr, Type parmType, Type argBaseType, std::list< Expression >::iterator &arg, const TyVarMap &exprTyVars, std::set< std::string > &seenTypes );
100	/// passes extra type parameters into a polymorphic function application
101	void passTypeVars( ApplicationExpr appExpr, Type polyRetType, std::list< Expression *>::iterator &arg, const TyVarMap &exprTyVars );
102	/// wraps a function application with a new temporary for the out-parameter return value
103	Expression addRetParam( ApplicationExpr appExpr, Type retType, std::list< Expression >::iterator &arg );
104	/// Replaces all the type parameters of a generic type with their concrete equivalents under the current environment
105	void replaceParametersWithConcrete( ApplicationExpr appExpr, std::list< Expression >& params );
106	/// Replaces a polymorphic type with its concrete equivalant under the current environment (returns itself if concrete).
107	/// If `doClone` is set to false, will not clone interior types
108	Type replaceWithConcrete( ApplicationExpr appExpr, Type *type, bool doClone = true );
109	/// wraps a function application returning a polymorphic type with a new temporary for the out-parameter return value
110	Expression addDynRetParam( ApplicationExpr appExpr, Type polyType, std::list< Expression >::iterator &arg );
111	Expression applyAdapter( ApplicationExpr appExpr, FunctionType function, std::list< Expression >::iterator &arg, const TyVarMap &exprTyVars );
112	void boxParam( Type formal, Expression &arg, const TyVarMap &exprTyVars );
113	void boxParams( ApplicationExpr appExpr, FunctionType function, std::list< Expression *>::iterator &arg, const TyVarMap &exprTyVars );
114	void addInferredParams( ApplicationExpr appExpr, FunctionType functionType, std::list< Expression *>::iterator &arg, const TyVarMap &tyVars );
115	/// Stores assignment operators from assertion list in local map of assignment operations
116	void passAdapters( ApplicationExpr appExpr, FunctionType functionType, const TyVarMap &exprTyVars );
117	FunctionDecl makeAdapter( FunctionType adaptee, FunctionType *realType, const std::string &mangleName, const TyVarMap &tyVars );
118	/// Replaces intrinsic operator functions with their arithmetic desugaring
119	Expression handleIntrinsics( ApplicationExpr appExpr );
120	/// Inserts a new temporary variable into the current scope with an auto-generated name
121	ObjectDecl makeTemporary( Type type );
122
123	ScopedMap< std::string, DeclarationWithType* > adapters; ///< Set of adapter functions in the current scope
124
125	std::map< ApplicationExpr , Expression > retVals;
126
127	DeclarationWithType *retval;
128	UniqueName tempNamer;
129	};
130
131	/// * Moves polymorphic returns in function types to pointer-type parameters
132	/// * adds type size and assertion parameters to parameter lists
133	class Pass2 final : public PolyMutator {
134	public:
135	template< typename DeclClass >
136	DeclClass handleDecl( DeclClass decl );
137	template< typename AggDecl >
138	AggDecl * handleAggDecl( AggDecl * aggDecl );
139
140	typedef PolyMutator Parent;
141	using Parent::mutate;
142	virtual DeclarationWithType mutate( FunctionDecl functionDecl ) override;
143	virtual ObjectDecl mutate( ObjectDecl objectDecl ) override;
144	virtual StructDecl mutate( StructDecl structDecl ) override;
145	virtual UnionDecl mutate( UnionDecl unionDecl ) override;
146	virtual TypeDecl mutate( TypeDecl typeDecl ) override;
147	virtual TypedefDecl mutate( TypedefDecl typedefDecl ) override;
148	virtual Type mutate( PointerType pointerType ) override;
149	virtual Type mutate( FunctionType funcType ) override;
150
151	private:
152	void addAdapters( FunctionType *functionType );
153
154	std::map< UniqueId, std::string > adapterName;
155	};
156
157	/// Replaces member and size/align/offsetof expressions on polymorphic generic types with calculated expressions.
158	/// * Replaces member expressions for polymorphic types with calculated add-field-offset-and-dereference
159	/// * Calculates polymorphic offsetof expressions from offset array
160	/// * Inserts dynamic calculation of polymorphic type layouts where needed
161	class PolyGenericCalculator final : public PolyMutator {
162	public:
163	typedef PolyMutator Parent;
164	using Parent::mutate;
165
166	PolyGenericCalculator();
167
168	template< typename DeclClass >
169	DeclClass handleDecl( DeclClass decl, Type *type );
170	virtual DeclarationWithType mutate( FunctionDecl functionDecl ) override;
171	virtual ObjectDecl mutate( ObjectDecl objectDecl ) override;
172	virtual TypedefDecl mutate( TypedefDecl objectDecl ) override;
173	virtual TypeDecl mutate( TypeDecl objectDecl ) override;
174	virtual Statement mutate( DeclStmt declStmt ) override;
175	virtual Type mutate( PointerType pointerType ) override;
176	virtual Type mutate( FunctionType funcType ) override;
177	virtual Expression mutate( MemberExpr memberExpr ) override;
178	virtual Expression mutate( SizeofExpr sizeofExpr ) override;
179	virtual Expression mutate( AlignofExpr alignofExpr ) override;
180	virtual Expression mutate( OffsetofExpr offsetofExpr ) override;
181	virtual Expression mutate( OffsetPackExpr offsetPackExpr ) override;
182
183	virtual void doBeginScope() override;
184	virtual void doEndScope() override;
185
186	private:
187	/// Makes a new variable in the current scope with the given name, type & optional initializer
188	ObjectDecl makeVar( const std::string &name, Type type, Initializer *init = 0 );
189	/// returns true if the type has a dynamic layout; such a layout will be stored in appropriately-named local variables when the function returns
190	bool findGeneric( Type *ty );
191	/// adds type parameters to the layout call; will generate the appropriate parameters if needed
192	void addOtypeParamsToLayoutCall( UntypedExpr layoutCall, const std::list< Type > &otypeParams );
193
194	/// Enters a new scope for type-variables, adding the type variables from ty
195	void beginTypeScope( Type *ty );
196	/// Exits the type-variable scope
197	void endTypeScope();
198
199	ScopedSet< std::string > knownLayouts; ///< Set of generic type layouts known in the current scope, indexed by sizeofName
200	ScopedSet< std::string > knownOffsets; ///< Set of non-generic types for which the offset array exists in the current scope, indexed by offsetofName
201	UniqueName bufNamer; ///< Namer for VLA buffers
202	};
203
204	/// Replaces initialization of polymorphic values with alloca, declaration of dtype/ftype with appropriate void expression, and sizeof expressions of polymorphic types with the proper variable
205	class Pass3 final : public PolyMutator {
206	public:
207	template< typename DeclClass >
208	DeclClass handleDecl( DeclClass decl, Type *type );
209
210	using PolyMutator::mutate;
211	virtual DeclarationWithType mutate( FunctionDecl functionDecl ) override;
212	virtual ObjectDecl mutate( ObjectDecl objectDecl ) override;
213	virtual TypedefDecl mutate( TypedefDecl objectDecl ) override;
214	virtual TypeDecl mutate( TypeDecl objectDecl ) override;
215	virtual Type mutate( PointerType pointerType ) override;
216	virtual Type mutate( FunctionType funcType ) override;
217	private:
218	};
219
220	} // anonymous namespace
221
222	/// version of mutateAll with special handling for translation unit so you can check the end of the prelude when debugging
223	template< typename MutatorType >
224	inline void mutateTranslationUnit( std::list< Declaration* > &translationUnit, MutatorType &mutator ) {
225	bool seenIntrinsic = false;
226	SemanticError errors;
227	for ( typename std::list< Declaration* >::iterator i = translationUnit.begin(); i != translationUnit.end(); ++i ) {
228	try {
229	if ( *i ) {
230	if ( (*i)->get_linkage() == LinkageSpec::Intrinsic ) {
231	seenIntrinsic = true;
232	} else if ( seenIntrinsic ) {
233	seenIntrinsic = false; // break on this line when debugging for end of prelude
234	}
235
236	i = dynamic_cast< Declaration >( (*i)->acceptMutator( mutator ) );
237	assert( *i );
238	} // if
239	} catch( SemanticError &e ) {
240	e.set_location( (*i)->location );
241	errors.append( e );
242	} // try
243	} // for
244	if ( ! errors.isEmpty() ) {
245	throw errors;
246	} // if
247	}
248
249	void box( std::list< Declaration *>& translationUnit ) {
250	LayoutFunctionBuilder layoutBuilder;
251	Pass1 pass1;
252	Pass2 pass2;
253	PolyGenericCalculator polyCalculator;
254	Pass3 pass3;
255
256	layoutBuilder.mutateDeclarationList( translationUnit );
257	mutateTranslationUnit/All/( translationUnit, pass1 );
258	mutateTranslationUnit/All/( translationUnit, pass2 );
259	mutateTranslationUnit/All/( translationUnit, polyCalculator );
260	mutateTranslationUnit/All/( translationUnit, pass3 );
261	}
262
263	////////////////////////////////// LayoutFunctionBuilder ////////////////////////////////////////////
264
265	DeclarationWithType LayoutFunctionBuilder::mutate( FunctionDecl functionDecl ) {
266	functionDecl->set_functionType( maybeMutate( functionDecl->get_functionType(), *this ) );
267	++functionNesting;
268	functionDecl->set_statements( maybeMutate( functionDecl->get_statements(), *this ) );
269	--functionNesting;
270	return functionDecl;
271	}
272
273	/// Get a list of type declarations that will affect a layout function
274	std::list< TypeDecl* > takeOtypeOnly( std::list< TypeDecl* > &decls ) {
275	std::list< TypeDecl * > otypeDecls;
276
277	for ( std::list< TypeDecl* >::const_iterator decl = decls.begin(); decl != decls.end(); ++decl ) {
278	if ( (*decl)->isComplete() ) {
279	otypeDecls.push_back( *decl );
280	}
281	}
282
283	return otypeDecls;
284	}
285
286	/// Adds parameters for otype layout to a function type
287	void addOtypeParams( FunctionType layoutFnType, std::list< TypeDecl > &otypeParams ) {
288	BasicType sizeAlignType( Type::Qualifiers(), BasicType::LongUnsignedInt );
289
290	for ( std::list< TypeDecl* >::const_iterator param = otypeParams.begin(); param != otypeParams.end(); ++param ) {
291	TypeInstType paramType( Type::Qualifiers(), (param)->get_name(), param );
292	std::string paramName = mangleType( &paramType );
293	layoutFnType->get_parameters().push_back( new ObjectDecl( sizeofName( paramName ), Type::StorageClasses(), LinkageSpec::Cforall, 0, sizeAlignType.clone(), 0 ) );
294	layoutFnType->get_parameters().push_back( new ObjectDecl( alignofName( paramName ), Type::StorageClasses(), LinkageSpec::Cforall, 0, sizeAlignType.clone(), 0 ) );
295	}
296	}
297
298	/// Builds a layout function declaration
299	FunctionDecl buildLayoutFunctionDecl( AggregateDecl typeDecl, unsigned int functionNesting, FunctionType *layoutFnType ) {
300	// Routines at global scope marked "static" to prevent multiple definitions is separate translation units
301	// because each unit generates copies of the default routines for each aggregate.
302	FunctionDecl *layoutDecl = new FunctionDecl( layoutofName( typeDecl ),
303	functionNesting > 0 ? Type::StorageClasses() : Type::StorageClasses( Type::Static ),
304	LinkageSpec::AutoGen, layoutFnType, new CompoundStmt( noLabels ),
305	std::list< Attribute * >(), Type::FuncSpecifiers( Type::Inline ) );
306	layoutDecl->fixUniqueId();
307	return layoutDecl;
308	}
309
310	/// Makes a unary operation
311	Expression makeOp( const std::string &name, Expression arg ) {
312	UntypedExpr *expr = new UntypedExpr( new NameExpr( name ) );
313	expr->get_args().push_back( arg );
314	return expr;
315	}
316
317	/// Makes a binary operation
318	Expression makeOp( const std::string &name, Expression lhs, Expression *rhs ) {
319	UntypedExpr *expr = new UntypedExpr( new NameExpr( name ) );
320	expr->get_args().push_back( lhs );
321	expr->get_args().push_back( rhs );
322	return expr;
323	}
324
325	/// Returns the dereference of a local pointer variable
326	Expression derefVar( ObjectDecl var ) {
327	return makeOp( "*?", new VariableExpr( var ) );
328	}
329
330	/// makes an if-statement with a single-expression if-block and no then block
331	Statement makeCond( Expression cond, Expression *ifPart ) {
332	return new IfStmt( noLabels, cond, new ExprStmt( noLabels, ifPart ), 0 );
333	}
334
335	/// makes a statement that assigns rhs to lhs if lhs < rhs
336	Statement makeAssignMax( Expression lhs, Expression *rhs ) {
337	return makeCond( makeOp( "?<?", lhs, rhs ), makeOp( "?=?", lhs->clone(), rhs->clone() ) );
338	}
339
340	/// makes a statement that aligns lhs to rhs (rhs should be an integer power of two)
341	Statement makeAlignTo( Expression lhs, Expression *rhs ) {
342	// check that the lhs is zeroed out to the level of rhs
343	Expression *ifCond = makeOp( "?&?", lhs, makeOp( "?-?", rhs, new ConstantExpr( Constant::from_ulong( 1 ) ) ) );
344	// if not aligned, increment to alignment
345	Expression *ifExpr = makeOp( "?+=?", lhs->clone(), makeOp( "?-?", rhs->clone(), ifCond->clone() ) );
346	return makeCond( ifCond, ifExpr );
347	}
348
349	/// adds an expression to a compound statement
350	void addExpr( CompoundStmt stmts, Expression expr ) {
351	stmts->get_kids().push_back( new ExprStmt( noLabels, expr ) );
352	}
353
354	/// adds a statement to a compound statement
355	void addStmt( CompoundStmt stmts, Statement stmt ) {
356	stmts->get_kids().push_back( stmt );
357	}
358
359	Declaration LayoutFunctionBuilder::mutate( StructDecl structDecl ) {
360	// do not generate layout function for "empty" tag structs
361	if ( structDecl->get_members().empty() ) return structDecl;
362
363	// get parameters that can change layout, exiting early if none
364	std::list< TypeDecl* > otypeParams = takeOtypeOnly( structDecl->get_parameters() );
365	if ( otypeParams.empty() ) return structDecl;
366
367	// build layout function signature
368	FunctionType *layoutFnType = new FunctionType( Type::Qualifiers(), false );
369	BasicType *sizeAlignType = new BasicType( Type::Qualifiers(), BasicType::LongUnsignedInt );
370	PointerType *sizeAlignOutType = new PointerType( Type::Qualifiers(), sizeAlignType );
371
372	ObjectDecl *sizeParam = new ObjectDecl( sizeofName( structDecl->get_name() ), Type::StorageClasses(), LinkageSpec::Cforall, 0, sizeAlignOutType, 0 );
373	layoutFnType->get_parameters().push_back( sizeParam );
374	ObjectDecl *alignParam = new ObjectDecl( alignofName( structDecl->get_name() ), Type::StorageClasses(), LinkageSpec::Cforall, 0, sizeAlignOutType->clone(), 0 );
375	layoutFnType->get_parameters().push_back( alignParam );
376	ObjectDecl *offsetParam = new ObjectDecl( offsetofName( structDecl->get_name() ), Type::StorageClasses(), LinkageSpec::Cforall, 0, sizeAlignOutType->clone(), 0 );
377	layoutFnType->get_parameters().push_back( offsetParam );
378	addOtypeParams( layoutFnType, otypeParams );
379
380	// build function decl
381	FunctionDecl *layoutDecl = buildLayoutFunctionDecl( structDecl, functionNesting, layoutFnType );
382
383	// calculate struct layout in function body
384
385	// initialize size and alignment to 0 and 1 (will have at least one member to re-edit size)
386	addExpr( layoutDecl->get_statements(), makeOp( "?=?", derefVar( sizeParam ), new ConstantExpr( Constant::from_ulong( 0 ) ) ) );
387	addExpr( layoutDecl->get_statements(), makeOp( "?=?", derefVar( alignParam ), new ConstantExpr( Constant::from_ulong( 1 ) ) ) );
388	unsigned long n_members = 0;
389	bool firstMember = true;
390	for ( std::list< Declaration* >::const_iterator member = structDecl->get_members().begin(); member != structDecl->get_members().end(); ++member ) {
391	DeclarationWithType dwt = dynamic_cast< DeclarationWithType >( *member );
392	assert( dwt );
393	Type *memberType = dwt->get_type();
394
395	if ( firstMember ) {
396	firstMember = false;
397	} else {
398	// make sure all members after the first (automatically aligned at 0) are properly padded for alignment
399	addStmt( layoutDecl->get_statements(), makeAlignTo( derefVar( sizeParam ), new AlignofExpr( memberType->clone() ) ) );
400	}
401
402	// place current size in the current offset index
403	addExpr( layoutDecl->get_statements(), makeOp( "?=?", makeOp( "?[?]", new VariableExpr( offsetParam ), new ConstantExpr( Constant::from_ulong( n_members ) ) ),
404	derefVar( sizeParam ) ) );
405	++n_members;
406
407	// add member size to current size
408	addExpr( layoutDecl->get_statements(), makeOp( "?+=?", derefVar( sizeParam ), new SizeofExpr( memberType->clone() ) ) );
409
410	// take max of member alignment and global alignment
411	addStmt( layoutDecl->get_statements(), makeAssignMax( derefVar( alignParam ), new AlignofExpr( memberType->clone() ) ) );
412	}
413	// make sure the type is end-padded to a multiple of its alignment
414	addStmt( layoutDecl->get_statements(), makeAlignTo( derefVar( sizeParam ), derefVar( alignParam ) ) );
415
416	addDeclarationAfter( layoutDecl );
417	return structDecl;
418	}
419
420	Declaration LayoutFunctionBuilder::mutate( UnionDecl unionDecl ) {
421	// do not generate layout function for "empty" tag unions
422	if ( unionDecl->get_members().empty() ) return unionDecl;
423
424	// get parameters that can change layout, exiting early if none
425	std::list< TypeDecl* > otypeParams = takeOtypeOnly( unionDecl->get_parameters() );
426	if ( otypeParams.empty() ) return unionDecl;
427
428	// build layout function signature
429	FunctionType *layoutFnType = new FunctionType( Type::Qualifiers(), false );
430	BasicType *sizeAlignType = new BasicType( Type::Qualifiers(), BasicType::LongUnsignedInt );
431	PointerType *sizeAlignOutType = new PointerType( Type::Qualifiers(), sizeAlignType );
432
433	ObjectDecl *sizeParam = new ObjectDecl( sizeofName( unionDecl->get_name() ), Type::StorageClasses(), LinkageSpec::Cforall, 0, sizeAlignOutType, 0 );
434	layoutFnType->get_parameters().push_back( sizeParam );
435	ObjectDecl *alignParam = new ObjectDecl( alignofName( unionDecl->get_name() ), Type::StorageClasses(), LinkageSpec::Cforall, 0, sizeAlignOutType->clone(), 0 );
436	layoutFnType->get_parameters().push_back( alignParam );
437	addOtypeParams( layoutFnType, otypeParams );
438
439	// build function decl
440	FunctionDecl *layoutDecl = buildLayoutFunctionDecl( unionDecl, functionNesting, layoutFnType );
441
442	// calculate union layout in function body
443	addExpr( layoutDecl->get_statements(), makeOp( "?=?", derefVar( sizeParam ), new ConstantExpr( Constant::from_ulong( 1 ) ) ) );
444	addExpr( layoutDecl->get_statements(), makeOp( "?=?", derefVar( alignParam ), new ConstantExpr( Constant::from_ulong( 1 ) ) ) );
445	for ( std::list< Declaration* >::const_iterator member = unionDecl->get_members().begin(); member != unionDecl->get_members().end(); ++member ) {
446	DeclarationWithType dwt = dynamic_cast< DeclarationWithType >( *member );
447	assert( dwt );
448	Type *memberType = dwt->get_type();
449
450	// take max member size and global size
451	addStmt( layoutDecl->get_statements(), makeAssignMax( derefVar( sizeParam ), new SizeofExpr( memberType->clone() ) ) );
452
453	// take max of member alignment and global alignment
454	addStmt( layoutDecl->get_statements(), makeAssignMax( derefVar( alignParam ), new AlignofExpr( memberType->clone() ) ) );
455	}
456	// make sure the type is end-padded to a multiple of its alignment
457	addStmt( layoutDecl->get_statements(), makeAlignTo( derefVar( sizeParam ), derefVar( alignParam ) ) );
458
459	addDeclarationAfter( layoutDecl );
460	return unionDecl;
461	}
462
463	////////////////////////////////////////// Pass1 ////////////////////////////////////////////////////
464
465	namespace {
466	std::string makePolyMonoSuffix( FunctionType * function, const TyVarMap &tyVars ) {
467	std::stringstream name;
468
469	// NOTE: this function previously used isPolyObj, which failed to produce
470	// the correct thing in some situations. It's not clear to me why this wasn't working.
471
472	// if the return type or a parameter type involved polymorphic types, then the adapter will need
473	// to take those polymorphic types as pointers. Therefore, there can be two different functions
474	// with the same mangled name, so we need to further mangle the names.
475	for ( std::list< DeclarationWithType *>::iterator retval = function->get_returnVals().begin(); retval != function->get_returnVals().end(); ++retval ) {
476	if ( isPolyType( (*retval)->get_type(), tyVars ) ) {
477	name << "P";
478	} else {
479	name << "M";
480	}
481	}
482	name << "_";
483	std::list< DeclarationWithType *> &paramList = function->get_parameters();
484	for ( std::list< DeclarationWithType *>::iterator arg = paramList.begin(); arg != paramList.end(); ++arg ) {
485	if ( isPolyType( (*arg)->get_type(), tyVars ) ) {
486	name << "P";
487	} else {
488	name << "M";
489	}
490	} // for
491	return name.str();
492	}
493
494	std::string mangleAdapterName( FunctionType * function, const TyVarMap &tyVars ) {
495	return SymTab::Mangler::mangle( function ) + makePolyMonoSuffix( function, tyVars );
496	}
497
498	std::string makeAdapterName( const std::string &mangleName ) {
499	return "_adapter" + mangleName;
500	}
501
502	Pass1::Pass1() : tempNamer( "_temp" ) {}
503
504	DeclarationWithType Pass1::mutate( FunctionDecl functionDecl ) {
505	if ( functionDecl->get_statements() ) { // empty routine body ?
506	// std::cerr << "mutating function: " << functionDecl->get_mangleName() << std::endl;
507	doBeginScope();
508	scopeTyVars.beginScope();
509
510	DeclarationWithType *oldRetval = retval;
511
512	// process polymorphic return value
513	retval = nullptr;
514	if ( isDynRet( functionDecl->get_functionType() ) && functionDecl->get_linkage() != LinkageSpec::C ) {
515	retval = functionDecl->get_functionType()->get_returnVals().front();
516
517	// give names to unnamed return values
518	if ( retval->get_name() == "" ) {
519	retval->set_name( "_retparm" );
520	retval->set_linkage( LinkageSpec::C );
521	} // if
522	} // if
523
524	FunctionType *functionType = functionDecl->get_functionType();
525	makeTyVarMap( functionDecl->get_functionType(), scopeTyVars );
526
527	std::list< DeclarationWithType *> &paramList = functionType->get_parameters();
528	std::list< FunctionType *> functions;
529	for ( Type::ForallList::iterator tyVar = functionType->get_forall().begin(); tyVar != functionType->get_forall().end(); ++tyVar ) {
530	for ( std::list< DeclarationWithType >::iterator assert = (tyVar)->get_assertions().begin(); assert != (*tyVar)->get_assertions().end(); ++assert ) {
531	findFunction( (*assert)->get_type(), functions, scopeTyVars, needsAdapter );
532	} // for
533	} // for
534	for ( std::list< DeclarationWithType *>::iterator arg = paramList.begin(); arg != paramList.end(); ++arg ) {
535	findFunction( (*arg)->get_type(), functions, scopeTyVars, needsAdapter );
536	} // for
537
538	for ( std::list< FunctionType *>::iterator funType = functions.begin(); funType != functions.end(); ++funType ) {
539	std::string mangleName = mangleAdapterName( *funType, scopeTyVars );
540	if ( adapters.find( mangleName ) == adapters.end() ) {
541	std::string adapterName = makeAdapterName( mangleName );
542	adapters.insert( std::pair< std::string, DeclarationWithType >( mangleName, new ObjectDecl( adapterName, Type::StorageClasses(), LinkageSpec::C, nullptr, new PointerType( Type::Qualifiers(), makeAdapterType( funType, scopeTyVars ) ), nullptr ) ) );
543	} // if
544	} // for
545
546	functionDecl->set_statements( functionDecl->get_statements()->acceptMutator( *this ) );
547
548	scopeTyVars.endScope();
549	retval = oldRetval;
550	doEndScope();
551	// std::cerr << "end function: " << functionDecl->get_mangleName() << std::endl;
552	} // if
553	return functionDecl;
554	}
555
556	TypeDecl Pass1::mutate( TypeDecl typeDecl ) {
557	addToTyVarMap( typeDecl, scopeTyVars );
558	return Mutator::mutate( typeDecl );
559	}
560
561	Expression Pass1::mutate( CommaExpr commaExpr ) {
562	// Attempting to find application expressions that were mutated by the copy constructor passes
563	// to use an explicit return variable, so that the variable can be reused as a parameter to the
564	// call rather than creating a new temp variable. Previously this step was an optimization, but
565	// with the introduction of tuples and UniqueExprs, it is necessary to ensure that they use the same variable.
566	// Essentially, looking for pattern: (x=f(...), x)
567	// To compound the issue, the right side can be *x, etc. because of lvalue-returning functions
568	if ( UntypedExpr * assign = dynamic_cast< UntypedExpr * >( commaExpr->get_arg1() ) ) {
569	if ( InitTweak::isAssignment( InitTweak::getFunctionName( assign ) ) ) {
570	assert( assign->get_args().size() == 2 );
571	if ( ApplicationExpr * appExpr = dynamic_cast< ApplicationExpr * > ( assign->get_args().back() ) ) {
572	// first argument is assignable, so it must be an lvalue, so it should be legal to take its address.
573	retVals[appExpr] = assign->get_args().front();
574	}
575	}
576	}
577
578	commaExpr->set_arg1( maybeMutate( commaExpr->get_arg1(), *this ) );
579	commaExpr->set_arg2( maybeMutate( commaExpr->get_arg2(), *this ) );
580	return commaExpr;
581	}
582
583	Expression Pass1::mutate( ConditionalExpr condExpr ) {
584	condExpr->set_arg1( maybeMutate( condExpr->get_arg1(), *this ) );
585	condExpr->set_arg2( maybeMutate( condExpr->get_arg2(), *this ) );
586	condExpr->set_arg3( maybeMutate( condExpr->get_arg3(), *this ) );
587	return condExpr;
588
589	}
590
591	void Pass1::passArgTypeVars( ApplicationExpr appExpr, Type parmType, Type argBaseType, std::list< Expression >::iterator &arg, const TyVarMap &exprTyVars, std::set< std::string > &seenTypes ) {
592	Type *polyType = isPolyType( parmType, exprTyVars );
593	if ( polyType && ! dynamic_cast< TypeInstType* >( polyType ) ) {
594	std::string typeName = mangleType( polyType );
595	if ( seenTypes.count( typeName ) ) return;
596
597	arg = appExpr->get_args().insert( arg, new SizeofExpr( argBaseType->clone() ) );
598	arg++;
599	arg = appExpr->get_args().insert( arg, new AlignofExpr( argBaseType->clone() ) );
600	arg++;
601	if ( dynamic_cast< StructInstType* >( polyType ) ) {
602	if ( StructInstType argBaseStructType = dynamic_cast< StructInstType >( argBaseType ) ) {
603	// zero-length arrays are forbidden by C, so don't pass offset for empty struct
604	if ( ! argBaseStructType->get_baseStruct()->get_members().empty() ) {
605	arg = appExpr->get_args().insert( arg, new OffsetPackExpr( argBaseStructType->clone() ) );
606	arg++;
607	}
608	} else {
609	throw SemanticError( "Cannot pass non-struct type for generic struct" );
610	}
611	}
612
613	seenTypes.insert( typeName );
614	}
615	}
616
617	void Pass1::passTypeVars( ApplicationExpr appExpr, Type polyRetType, std::list< Expression *>::iterator &arg, const TyVarMap &exprTyVars ) {
618	// pass size/align for type variables
619	for ( TyVarMap::const_iterator tyParm = exprTyVars.begin(); tyParm != exprTyVars.end(); ++tyParm ) {
620	ResolvExpr::EqvClass eqvClass;
621	assert( env );
622	if ( tyParm->second.isComplete ) {
623	Type *concrete = env->lookup( tyParm->first );
624	if ( concrete ) {
625	arg = appExpr->get_args().insert( arg, new SizeofExpr( concrete->clone() ) );
626	arg++;
627	arg = appExpr->get_args().insert( arg, new AlignofExpr( concrete->clone() ) );
628	arg++;
629	} else {
630	// xxx - should this be an assertion?
631	std::string x = env ? toString( *env ) : "missing env";
632	throw SemanticError( x + "\n" + "unbound type variable: " + tyParm->first + " in application ", appExpr );
633	} // if
634	} // if
635	} // for
636
637	// add size/align for generic types to parameter list
638	if ( ! appExpr->get_function()->has_result() ) return;
639	FunctionType *funcType = getFunctionType( appExpr->get_function()->get_result() );
640	assert( funcType );
641
642	std::list< DeclarationWithType* >::const_iterator fnParm = funcType->get_parameters().begin();
643	std::list< Expression* >::const_iterator fnArg = arg;
644	std::set< std::string > seenTypes; ///< names for generic types we've seen
645
646	// a polymorphic return type may need to be added to the argument list
647	if ( polyRetType ) {
648	Type *concRetType = replaceWithConcrete( appExpr, polyRetType );
649	passArgTypeVars( appExpr, polyRetType, concRetType, arg, exprTyVars, seenTypes );
650	++fnArg; // skip the return parameter in the argument list
651	}
652
653	// add type information args for presently unseen types in parameter list
654	for ( ; fnParm != funcType->get_parameters().end() && fnArg != appExpr->get_args().end(); ++fnParm, ++fnArg ) {
655	if ( ! (*fnArg)->get_result() ) continue;
656	Type * argType = (*fnArg)->get_result();
657	passArgTypeVars( appExpr, (*fnParm)->get_type(), argType, arg, exprTyVars, seenTypes );
658	}
659	}
660
661	ObjectDecl Pass1::makeTemporary( Type type ) {
662	ObjectDecl *newObj = new ObjectDecl( tempNamer.newName(), Type::StorageClasses(), LinkageSpec::C, 0, type, 0 );
663	stmtsToAdd.push_back( new DeclStmt( noLabels, newObj ) );
664	return newObj;
665	}
666
667	Expression Pass1::addRetParam( ApplicationExpr appExpr, Type retType, std::list< Expression >::iterator &arg ) {
668	// Create temporary to hold return value of polymorphic function and produce that temporary as a result
669	// using a comma expression.
670	assert( retType );
671
672	Expression * paramExpr = nullptr;
673	// try to use existing return value parameter if it exists, otherwise create a new temporary
674	if ( retVals.count( appExpr ) ) {
675	paramExpr = retVals[appExpr]->clone();
676	} else {
677	ObjectDecl *newObj = makeTemporary( retType->clone() );
678	paramExpr = new VariableExpr( newObj );
679	}
680	Expression * retExpr = paramExpr->clone();
681
682	// If the type of the temporary is not polymorphic, box temporary by taking its address;
683	// otherwise the temporary is already boxed and can be used directly.
684	if ( ! isPolyType( paramExpr->get_result(), scopeTyVars, env ) ) {
685	paramExpr = new AddressExpr( paramExpr );
686	} // if
687	arg = appExpr->get_args().insert( arg, paramExpr ); // add argument to function call
688	arg++;
689	// Build a comma expression to call the function and emulate a normal return.
690	CommaExpr *commaExpr = new CommaExpr( appExpr, retExpr );
691	commaExpr->set_env( appExpr->get_env() );
692	appExpr->set_env( 0 );
693	return commaExpr;
694	}
695
696	void Pass1::replaceParametersWithConcrete( ApplicationExpr appExpr, std::list< Expression >& params ) {
697	for ( std::list< Expression* >::iterator param = params.begin(); param != params.end(); ++param ) {
698	TypeExpr paramType = dynamic_cast< TypeExpr >( *param );
699	assertf(paramType, "Aggregate parameters should be type expressions");
700	paramType->set_type( replaceWithConcrete( appExpr, paramType->get_type(), false ) );
701	}
702	}
703
704	Type Pass1::replaceWithConcrete( ApplicationExpr appExpr, Type *type, bool doClone ) {
705	if ( TypeInstType typeInst = dynamic_cast< TypeInstType >( type ) ) {
706	Type *concrete = env->lookup( typeInst->get_name() );
707	if ( concrete == 0 ) {
708	return typeInst;
709	// xxx - should this be an assertion?
710	// std::string x = env ? toString( *env ) : "missing env";
711	// throw SemanticError( x + "\n" + "Unbound type variable " + typeInst->get_name() + " in ", appExpr );
712	} // if
713	return concrete;
714	} else if ( StructInstType structType = dynamic_cast< StructInstType >( type ) ) {
715	if ( doClone ) {
716	structType = structType->clone();
717	}
718	replaceParametersWithConcrete( appExpr, structType->get_parameters() );
719	return structType;
720	} else if ( UnionInstType unionType = dynamic_cast< UnionInstType >( type ) ) {
721	if ( doClone ) {
722	unionType = unionType->clone();
723	}
724	replaceParametersWithConcrete( appExpr, unionType->get_parameters() );
725	return unionType;
726	}
727	return type;
728	}
729
730	Expression Pass1::addDynRetParam( ApplicationExpr appExpr, Type dynType, std::list< Expression >::iterator &arg ) {
731	assert( env );
732	Type *concrete = replaceWithConcrete( appExpr, dynType );
733	// add out-parameter for return value
734	return addRetParam( appExpr, concrete, arg );
735	}
736
737	Expression Pass1::applyAdapter( ApplicationExpr appExpr, FunctionType function, std::list< Expression >::iterator &arg, const TyVarMap &tyVars ) {
738	Expression *ret = appExpr;
739	// if ( ! function->get_returnVals().empty() && isPolyType( function->get_returnVals().front()->get_type(), tyVars ) ) {
740	if ( isDynRet( function, tyVars ) ) {
741	ret = addRetParam( appExpr, function->get_returnVals().front()->get_type(), arg );
742	} // if
743	std::string mangleName = mangleAdapterName( function, tyVars );
744	std::string adapterName = makeAdapterName( mangleName );
745
746	// cast adaptee to void (*)(), since it may have any type inside a polymorphic function
747	Type * adapteeType = new PointerType( Type::Qualifiers(), new FunctionType( Type::Qualifiers(), true ) );
748	appExpr->get_args().push_front( new CastExpr( appExpr->get_function(), adapteeType ) );
749	appExpr->set_function( new NameExpr( adapterName ) ); // xxx - result is never set on NameExpr
750
751	return ret;
752	}
753
754	void Pass1::boxParam( Type param, Expression &arg, const TyVarMap &exprTyVars ) {
755	assert( arg->has_result() );
756	if ( isPolyType( param, exprTyVars ) ) {
757	if ( isPolyType( arg->get_result() ) ) {
758	// if the argument's type is polymorphic, we don't need to box again!
759	return;
760	} else if ( arg->get_result()->get_lvalue() ) { // xxx - is this still right??
761	// xxx - dynamic_cast<ReferenceType *>( arg->get_result() )??
762	// VariableExpr and MemberExpr are lvalues; need to check this isn't coming from the second arg of a comma expression though (not an lvalue)
763	// xxx - need to test that this code is still reachable
764	if ( CommaExpr commaArg = dynamic_cast< CommaExpr >( arg ) ) {
765	commaArg->set_arg2( new AddressExpr( commaArg->get_arg2() ) );
766	} else {
767	arg = new AddressExpr( arg );
768	}
769	if ( ! ResolvExpr::typesCompatible( param, arg->get_result(), SymTab::Indexer() ) ) {
770	// silence warnings by casting boxed parameters when the actual type does not match up with the formal type.
771	arg = new CastExpr( arg, param->clone() );
772	}
773	} else {
774	// use type computed in unification to declare boxed variables
775	Type * newType = param->clone();
776	if ( env ) env->apply( newType );
777	ObjectDecl *newObj = new ObjectDecl( tempNamer.newName(), Type::StorageClasses(), LinkageSpec::C, 0, newType, 0 );
778	newObj->get_type()->get_qualifiers() = Type::Qualifiers(); // TODO: is this right???
779	stmtsToAdd.push_back( new DeclStmt( noLabels, newObj ) );
780	UntypedExpr *assign = new UntypedExpr( new NameExpr( "?=?" ) );
781	assign->get_args().push_back( new VariableExpr( newObj ) );
782	assign->get_args().push_back( arg );
783	stmtsToAdd.push_back( new ExprStmt( noLabels, assign ) );
784	arg = new AddressExpr( new VariableExpr( newObj ) );
785	} // if
786	} // if
787	}
788
789	/// cast parameters to polymorphic functions so that types are replaced with
790	/// void * if they are type parameters in the formal type.
791	/// this gets rid of warnings from gcc.
792	void addCast( Expression &actual, Type formal, const TyVarMap &tyVars ) {
793	if ( getFunctionType( formal ) ) {
794	Type * newType = formal->clone();
795	newType = ScrubTyVars::scrub( newType, tyVars );
796	actual = new CastExpr( actual, newType );
797	} // if
798	}
799
800	void Pass1::boxParams( ApplicationExpr appExpr, FunctionType function, std::list< Expression *>::iterator &arg, const TyVarMap &exprTyVars ) {
801	for ( std::list< DeclarationWithType *>::const_iterator param = function->get_parameters().begin(); param != function->get_parameters().end(); ++param, ++arg ) {
802	assertf( arg != appExpr->get_args().end(), "boxParams: missing argument for param %s to %s in %s", toString( *param ).c_str(), toString( function ).c_str(), toString( appExpr ).c_str() );
803	addCast( arg, (param)->get_type(), exprTyVars );
804	boxParam( (param)->get_type(), arg, exprTyVars );
805	} // for
806	}
807
808	void Pass1::addInferredParams( ApplicationExpr appExpr, FunctionType functionType, std::list< Expression *>::iterator &arg, const TyVarMap &tyVars ) {
809	std::list< Expression *>::iterator cur = arg;
810	for ( Type::ForallList::iterator tyVar = functionType->get_forall().begin(); tyVar != functionType->get_forall().end(); ++tyVar ) {
811	for ( std::list< DeclarationWithType >::iterator assert = (tyVar)->get_assertions().begin(); assert != (*tyVar)->get_assertions().end(); ++assert ) {
812	InferredParams::const_iterator inferParam = appExpr->get_inferParams().find( (*assert)->get_uniqueId() );
813	if ( inferParam == appExpr->get_inferParams().end() ) {
814	std::cerr << "looking for assertion: " << (*assert) << std::endl << appExpr << std::endl;
815	}
816	assertf( inferParam != appExpr->get_inferParams().end(), "NOTE: Explicit casts of polymorphic functions to compatible monomorphic functions are currently unsupported" );
817	Expression *newExpr = inferParam->second.expr->clone();
818	addCast( newExpr, (*assert)->get_type(), tyVars );
819	boxParam( (*assert)->get_type(), newExpr, tyVars );
820	appExpr->get_args().insert( cur, newExpr );
821	} // for
822	} // for
823	}
824
825	void makeRetParm( FunctionType *funcType ) {
826	DeclarationWithType *retParm = funcType->get_returnVals().front();
827
828	// make a new parameter that is a pointer to the type of the old return value
829	retParm->set_type( new PointerType( Type::Qualifiers(), retParm->get_type() ) );
830	funcType->get_parameters().push_front( retParm );
831
832	// we don't need the return value any more
833	funcType->get_returnVals().clear();
834	}
835
836	FunctionType makeAdapterType( FunctionType adaptee, const TyVarMap &tyVars ) {
837	// actually make the adapter type
838	FunctionType *adapter = adaptee->clone();
839	// if ( ! adapter->get_returnVals().empty() && isPolyType( adapter->get_returnVals().front()->get_type(), tyVars ) ) {
840	if ( isDynRet( adapter, tyVars ) ) {
841	makeRetParm( adapter );
842	} // if
843	adapter->get_parameters().push_front( new ObjectDecl( "", Type::StorageClasses(), LinkageSpec::C, 0, new PointerType( Type::Qualifiers(), new FunctionType( Type::Qualifiers(), true ) ), 0 ) );
844	return adapter;
845	}
846
847	Expression makeAdapterArg( DeclarationWithType param, DeclarationWithType arg, DeclarationWithType realParam, const TyVarMap &tyVars ) {
848	assert( param );
849	assert( arg );
850	if ( isPolyType( realParam->get_type(), tyVars ) ) {
851	if ( ! isPolyType( arg->get_type() ) ) {
852	UntypedExpr deref = new UntypedExpr( new NameExpr( "?" ) );
853	deref->get_args().push_back( new CastExpr( new VariableExpr( param ), new PointerType( Type::Qualifiers(), arg->get_type()->clone() ) ) );
854	deref->set_result( arg->get_type()->clone() );
855	return deref;
856	} // if
857	} // if
858	return new VariableExpr( param );
859	}
860
861	void addAdapterParams( ApplicationExpr adapteeApp, std::list< DeclarationWithType >::iterator arg, std::list< DeclarationWithType >::iterator param, std::list< DeclarationWithType >::iterator paramEnd, std::list< DeclarationWithType *>::iterator realParam, const TyVarMap &tyVars ) {
862	UniqueName paramNamer( "_p" );
863	for ( ; param != paramEnd; ++param, ++arg, ++realParam ) {
864	if ( (*param)->get_name() == "" ) {
865	(*param)->set_name( paramNamer.newName() );
866	(*param)->set_linkage( LinkageSpec::C );
867	} // if
868	adapteeApp->get_args().push_back( makeAdapterArg( param, arg, *realParam, tyVars ) );
869	} // for
870	}
871
872	FunctionDecl Pass1::makeAdapter( FunctionType adaptee, FunctionType *realType, const std::string &mangleName, const TyVarMap &tyVars ) {
873	FunctionType *adapterType = makeAdapterType( adaptee, tyVars );
874	adapterType = ScrubTyVars::scrub( adapterType, tyVars );
875	DeclarationWithType *adapteeDecl = adapterType->get_parameters().front();
876	adapteeDecl->set_name( "_adaptee" );
877	ApplicationExpr *adapteeApp = new ApplicationExpr( new CastExpr( new VariableExpr( adapteeDecl ), new PointerType( Type::Qualifiers(), realType ) ) );
878	Statement *bodyStmt;
879
880	Type::ForallList::iterator tyArg = realType->get_forall().begin();
881	Type::ForallList::iterator tyParam = adapterType->get_forall().begin();
882	Type::ForallList::iterator realTyParam = adaptee->get_forall().begin();
883	for ( ; tyParam != adapterType->get_forall().end(); ++tyArg, ++tyParam, ++realTyParam ) {
884	assert( tyArg != realType->get_forall().end() );
885	std::list< DeclarationWithType >::iterator assertArg = (tyArg)->get_assertions().begin();
886	std::list< DeclarationWithType >::iterator assertParam = (tyParam)->get_assertions().begin();
887	std::list< DeclarationWithType >::iterator realAssertParam = (realTyParam)->get_assertions().begin();
888	for ( ; assertParam != (*tyParam)->get_assertions().end(); ++assertArg, ++assertParam, ++realAssertParam ) {
889	assert( assertArg != (*tyArg)->get_assertions().end() );
890	adapteeApp->get_args().push_back( makeAdapterArg( assertParam, assertArg, *realAssertParam, tyVars ) );
891	} // for
892	} // for
893
894	std::list< DeclarationWithType *>::iterator arg = realType->get_parameters().begin();
895	std::list< DeclarationWithType *>::iterator param = adapterType->get_parameters().begin();
896	std::list< DeclarationWithType *>::iterator realParam = adaptee->get_parameters().begin();
897	param++; // skip adaptee parameter in the adapter type
898	if ( realType->get_returnVals().empty() ) {
899	// void return
900	addAdapterParams( adapteeApp, arg, param, adapterType->get_parameters().end(), realParam, tyVars );
901	bodyStmt = new ExprStmt( noLabels, adapteeApp );
902	// } else if ( isPolyType( adaptee->get_returnVals().front()->get_type(), tyVars ) ) {
903	} else if ( isDynType( adaptee->get_returnVals().front()->get_type(), tyVars ) ) {
904	// return type T
905	if ( (*param)->get_name() == "" ) {
906	(*param)->set_name( "_ret" );
907	(*param)->set_linkage( LinkageSpec::C );
908	} // if
909	UntypedExpr *assign = new UntypedExpr( new NameExpr( "?=?" ) );
910	UntypedExpr deref = UntypedExpr::createDeref( new CastExpr( new VariableExpr( param++ ), new PointerType( Type::Qualifiers(), realType->get_returnVals().front()->get_type()->clone() ) ) );
911	assign->get_args().push_back( deref );
912	addAdapterParams( adapteeApp, arg, param, adapterType->get_parameters().end(), realParam, tyVars );
913	assign->get_args().push_back( adapteeApp );
914	bodyStmt = new ExprStmt( noLabels, assign );
915	} else {
916	// adapter for a function that returns a monomorphic value
917	addAdapterParams( adapteeApp, arg, param, adapterType->get_parameters().end(), realParam, tyVars );
918	bodyStmt = new ReturnStmt( noLabels, adapteeApp );
919	} // if
920	CompoundStmt *adapterBody = new CompoundStmt( noLabels );
921	adapterBody->get_kids().push_back( bodyStmt );
922	std::string adapterName = makeAdapterName( mangleName );
923	return new FunctionDecl( adapterName, Type::StorageClasses(), LinkageSpec::C, adapterType, adapterBody );
924	}
925
926	void Pass1::passAdapters( ApplicationExpr * appExpr, FunctionType * functionType, const TyVarMap & exprTyVars ) {
927	// collect a list of function types passed as parameters or implicit parameters (assertions)
928	std::list< DeclarationWithType *> &paramList = functionType->get_parameters();
929	std::list< FunctionType *> functions;
930	for ( Type::ForallList::iterator tyVar = functionType->get_forall().begin(); tyVar != functionType->get_forall().end(); ++tyVar ) {
931	for ( std::list< DeclarationWithType >::iterator assert = (tyVar)->get_assertions().begin(); assert != (*tyVar)->get_assertions().end(); ++assert ) {
932	findFunction( (*assert)->get_type(), functions, exprTyVars, needsAdapter );
933	} // for
934	} // for
935	for ( std::list< DeclarationWithType *>::iterator arg = paramList.begin(); arg != paramList.end(); ++arg ) {
936	findFunction( (*arg)->get_type(), functions, exprTyVars, needsAdapter );
937	} // for
938
939	// parameter function types for which an appropriate adapter has been generated. we cannot use the types
940	// after applying substitutions, since two different parameter types may be unified to the same type
941	std::set< std::string > adaptersDone;
942
943	for ( std::list< FunctionType *>::iterator funType = functions.begin(); funType != functions.end(); ++funType ) {
944	FunctionType originalFunction = (funType)->clone();
945	FunctionType realFunction = (funType)->clone();
946	std::string mangleName = SymTab::Mangler::mangle( realFunction );
947
948	// only attempt to create an adapter or pass one as a parameter if we haven't already done so for this
949	// pre-substitution parameter function type.
950	if ( adaptersDone.find( mangleName ) == adaptersDone.end() ) {
951	adaptersDone.insert( adaptersDone.begin(), mangleName );
952
953	// apply substitution to type variables to figure out what the adapter's type should look like
954	assert( env );
955	env->apply( realFunction );
956	mangleName = SymTab::Mangler::mangle( realFunction );
957	mangleName += makePolyMonoSuffix( originalFunction, exprTyVars );
958
959	typedef ScopedMap< std::string, DeclarationWithType* >::iterator AdapterIter;
960	AdapterIter adapter = adapters.find( mangleName );
961	if ( adapter == adapters.end() ) {
962	// adapter has not been created yet in the current scope, so define it
963	FunctionDecl newAdapter = makeAdapter( funType, realFunction, mangleName, exprTyVars );
964	std::pair< AdapterIter, bool > answer = adapters.insert( std::pair< std::string, DeclarationWithType *>( mangleName, newAdapter ) );
965	adapter = answer.first;
966	stmtsToAdd.push_back( new DeclStmt( noLabels, newAdapter ) );
967	} // if
968	assert( adapter != adapters.end() );
969
970	// add the appropriate adapter as a parameter
971	appExpr->get_args().push_front( new VariableExpr( adapter->second ) );
972	} // if
973	} // for
974	} // passAdapters
975
976	Expression makeIncrDecrExpr( ApplicationExpr appExpr, Type *polyType, bool isIncr ) {
977	NameExpr *opExpr;
978	if ( isIncr ) {
979	opExpr = new NameExpr( "?+=?" );
980	} else {
981	opExpr = new NameExpr( "?-=?" );
982	} // if
983	UntypedExpr *addAssign = new UntypedExpr( opExpr );
984	if ( AddressExpr address = dynamic_cast< AddressExpr >( appExpr->get_args().front() ) ) {
985	addAssign->get_args().push_back( address->get_arg() );
986	} else {
987	addAssign->get_args().push_back( appExpr->get_args().front() );
988	} // if
989	addAssign->get_args().push_back( new NameExpr( sizeofName( mangleType( polyType ) ) ) );
990	addAssign->set_result( appExpr->get_result()->clone() );
991	if ( appExpr->get_env() ) {
992	addAssign->set_env( appExpr->get_env() );
993	appExpr->set_env( 0 );
994	} // if
995	appExpr->get_args().clear();
996	delete appExpr;
997	return addAssign;
998	}
999
1000	Expression Pass1::handleIntrinsics( ApplicationExpr appExpr ) {
1001	if ( VariableExpr varExpr = dynamic_cast< VariableExpr >( appExpr->get_function() ) ) {
1002	if ( varExpr->get_var()->get_linkage() == LinkageSpec::Intrinsic ) {
1003	if ( varExpr->get_var()->get_name() == "?[?]" ) {
1004	assert( appExpr->has_result() );
1005	assert( appExpr->get_args().size() == 2 );
1006	Type *baseType1 = isPolyPtr( appExpr->get_args().front()->get_result(), scopeTyVars, env );
1007	Type *baseType2 = isPolyPtr( appExpr->get_args().back()->get_result(), scopeTyVars, env );
1008	assert( ! baseType1 \|\| ! baseType2 ); // the arguments cannot both be polymorphic pointers
1009	UntypedExpr *ret = 0;
1010	if ( baseType1 \|\| baseType2 ) { // one of the arguments is a polymorphic pointer
1011	ret = new UntypedExpr( new NameExpr( "?+?" ) );
1012	} // if
1013	if ( baseType1 ) {
1014	UntypedExpr multiply = new UntypedExpr( new NameExpr( "??" ) );
1015	multiply->get_args().push_back( appExpr->get_args().back() );
1016	multiply->get_args().push_back( new SizeofExpr( baseType1->clone() ) );
1017	ret->get_args().push_back( appExpr->get_args().front() );
1018	ret->get_args().push_back( multiply );
1019	} else if ( baseType2 ) {
1020	UntypedExpr multiply = new UntypedExpr( new NameExpr( "??" ) );
1021	multiply->get_args().push_back( appExpr->get_args().front() );
1022	multiply->get_args().push_back( new SizeofExpr( baseType2->clone() ) );
1023	ret->get_args().push_back( multiply );
1024	ret->get_args().push_back( appExpr->get_args().back() );
1025	} // if
1026	if ( baseType1 \|\| baseType2 ) {
1027	ret->set_result( appExpr->get_result()->clone() );
1028	if ( appExpr->get_env() ) {
1029	ret->set_env( appExpr->get_env() );
1030	appExpr->set_env( 0 );
1031	} // if
1032	appExpr->get_args().clear();
1033	delete appExpr;
1034	return ret;
1035	} // if
1036	} else if ( varExpr->get_var()->get_name() == "*?" ) {
1037	assert( appExpr->has_result() );
1038	assert( ! appExpr->get_args().empty() );
1039	if ( isPolyPtr( appExpr->get_result(), scopeTyVars, env ) ) { // dereference returns a reference type
1040	// remove dereference from polymorphic types since they are boxed.
1041	Expression *ret = appExpr->get_args().front();
1042	delete ret->get_result();
1043	ret->set_result( appExpr->get_result()->clone() );
1044	if ( appExpr->get_env() ) {
1045	ret->set_env( appExpr->get_env() );
1046	appExpr->set_env( 0 );
1047	} // if
1048	appExpr->get_args().clear();
1049	delete appExpr;
1050	return ret;
1051	} // if
1052	} else if ( varExpr->get_var()->get_name() == "?++" \|\| varExpr->get_var()->get_name() == "?--" ) {
1053	assert( appExpr->has_result() );
1054	assert( appExpr->get_args().size() == 1 );
1055	if ( Type *baseType = isPolyPtr( appExpr->get_result(), scopeTyVars, env ) ) {
1056	Type *tempType = appExpr->get_result()->clone();
1057	if ( env ) {
1058	env->apply( tempType );
1059	} // if
1060	ObjectDecl *newObj = makeTemporary( tempType );
1061	VariableExpr *tempExpr = new VariableExpr( newObj );
1062	UntypedExpr *assignExpr = new UntypedExpr( new NameExpr( "?=?" ) );
1063	assignExpr->get_args().push_back( tempExpr->clone() );
1064	if ( AddressExpr address = dynamic_cast< AddressExpr >( appExpr->get_args().front() ) ) {
1065	assignExpr->get_args().push_back( address->get_arg()->clone() );
1066	} else {
1067	assignExpr->get_args().push_back( appExpr->get_args().front()->clone() );
1068	} // if
1069	CommaExpr *firstComma = new CommaExpr( assignExpr, makeIncrDecrExpr( appExpr, baseType, varExpr->get_var()->get_name() == "?++" ) );
1070	return new CommaExpr( firstComma, tempExpr );
1071	} // if
1072	} else if ( varExpr->get_var()->get_name() == "++?" \|\| varExpr->get_var()->get_name() == "--?" ) {
1073	assert( appExpr->has_result() );
1074	assert( appExpr->get_args().size() == 1 );
1075	if ( Type *baseType = isPolyPtr( appExpr->get_result(), scopeTyVars, env ) ) {
1076	return makeIncrDecrExpr( appExpr, baseType, varExpr->get_var()->get_name() == "++?" );
1077	} // if
1078	} else if ( varExpr->get_var()->get_name() == "?+?" \|\| varExpr->get_var()->get_name() == "?-?" ) {
1079	assert( appExpr->has_result() );
1080	assert( appExpr->get_args().size() == 2 );
1081	Type *baseType1 = isPolyPtr( appExpr->get_args().front()->get_result(), scopeTyVars, env );
1082	Type *baseType2 = isPolyPtr( appExpr->get_args().back()->get_result(), scopeTyVars, env );
1083	if ( baseType1 && baseType2 ) {
1084	UntypedExpr *divide = new UntypedExpr( new NameExpr( "?/?" ) );
1085	divide->get_args().push_back( appExpr );
1086	divide->get_args().push_back( new SizeofExpr( baseType1->clone() ) );
1087	divide->set_result( appExpr->get_result()->clone() );
1088	if ( appExpr->get_env() ) {
1089	divide->set_env( appExpr->get_env() );
1090	appExpr->set_env( 0 );
1091	} // if
1092	return divide;
1093	} else if ( baseType1 ) {
1094	UntypedExpr multiply = new UntypedExpr( new NameExpr( "??" ) );
1095	multiply->get_args().push_back( appExpr->get_args().back() );
1096	multiply->get_args().push_back( new SizeofExpr( baseType1->clone() ) );
1097	appExpr->get_args().back() = multiply;
1098	} else if ( baseType2 ) {
1099	UntypedExpr multiply = new UntypedExpr( new NameExpr( "??" ) );
1100	multiply->get_args().push_back( appExpr->get_args().front() );
1101	multiply->get_args().push_back( new SizeofExpr( baseType2->clone() ) );
1102	appExpr->get_args().front() = multiply;
1103	} // if
1104	} else if ( varExpr->get_var()->get_name() == "?+=?" \|\| varExpr->get_var()->get_name() == "?-=?" ) {
1105	assert( appExpr->has_result() );
1106	assert( appExpr->get_args().size() == 2 );
1107	Type *baseType = isPolyPtr( appExpr->get_result(), scopeTyVars, env );
1108	if ( baseType ) {
1109	UntypedExpr multiply = new UntypedExpr( new NameExpr( "??" ) );
1110	multiply->get_args().push_back( appExpr->get_args().back() );
1111	multiply->get_args().push_back( new SizeofExpr( baseType->clone() ) );
1112	appExpr->get_args().back() = multiply;
1113	} // if
1114	} // if
1115	return appExpr;
1116	} // if
1117	} // if
1118	return 0;
1119	}
1120
1121	Expression Pass1::mutate( ApplicationExpr appExpr ) {
1122	// std::cerr << "mutate appExpr: " << InitTweak::getFunctionName( appExpr ) << std::endl;
1123	// for ( TyVarMap::iterator i = scopeTyVars.begin(); i != scopeTyVars.end(); ++i ) {
1124	// std::cerr << i->first << " ";
1125	// }
1126	// std::cerr << "\n";
1127	appExpr->get_function()->acceptMutator( *this );
1128	mutateAll( appExpr->get_args(), *this );
1129
1130	assert( appExpr->get_function()->has_result() );
1131	PointerType pointer = safe_dynamic_cast< PointerType >( appExpr->get_function()->get_result() );
1132	FunctionType function = safe_dynamic_cast< FunctionType >( pointer->get_base() );
1133
1134	if ( Expression *newExpr = handleIntrinsics( appExpr ) ) {
1135	return newExpr;
1136	} // if
1137
1138	Expression *ret = appExpr;
1139
1140	std::list< Expression *>::iterator arg = appExpr->get_args().begin();
1141	std::list< Expression *>::iterator paramBegin = appExpr->get_args().begin();
1142
1143	TyVarMap exprTyVars( TypeDecl::Data{} );
1144	makeTyVarMap( function, exprTyVars ); // xxx - should this take into account the variables already bound in scopeTyVars (i.e. remove them from exprTyVars?)
1145	ReferenceToType *dynRetType = isDynRet( function, exprTyVars );
1146
1147	// std::cerr << function << std::endl;
1148	// std::cerr << "scopeTyVars: ";
1149	// printTyVarMap( std::cerr, scopeTyVars );
1150	// std::cerr << "exprTyVars: ";
1151	// printTyVarMap( std::cerr, exprTyVars );
1152	// std::cerr << "env: " << *env << std::endl;
1153	// std::cerr << needsAdapter( function, scopeTyVars ) << ! needsAdapter( function, exprTyVars) << std::endl;
1154
1155	// NOTE: addDynRetParam needs to know the actual (generated) return type so it can make a temp variable, so pass the result type from the appExpr
1156	// passTypeVars needs to know the program-text return type (i.e. the distinction between _conc_T30 and T3(int))
1157	// concRetType may not be a good name in one or both of these places. A more appropriate name change is welcome.
1158	if ( dynRetType ) {
1159	// std::cerr << "dynRetType: " << dynRetType << std::endl;
1160	Type *concRetType = appExpr->get_result()->isVoid() ? nullptr : appExpr->get_result();
1161	ret = addDynRetParam( appExpr, concRetType, arg ); // xxx - used to use dynRetType instead of concRetType
1162	} else if ( needsAdapter( function, scopeTyVars ) && ! needsAdapter( function, exprTyVars) ) { // xxx - exprTyVars is used above...?
1163	// xxx - the ! needsAdapter check may be incorrect. It seems there is some situation where an adapter is applied where it shouldn't be, and this fixes it for some cases. More investigation is needed.
1164
1165	// std::cerr << "needs adapter: ";
1166	// printTyVarMap( std::cerr, scopeTyVars );
1167	// std::cerr << *env << std::endl;
1168	// change the application so it calls the adapter rather than the passed function
1169	ret = applyAdapter( appExpr, function, arg, scopeTyVars );
1170	} // if
1171	arg = appExpr->get_args().begin();
1172
1173	Type *concRetType = replaceWithConcrete( appExpr, dynRetType );
1174	passTypeVars( appExpr, concRetType, arg, exprTyVars ); // xxx - used to use dynRetType instead of concRetType; this changed so that the correct type paramaters are passed for return types (it should be the concrete type's parameters, not the formal type's)
1175	addInferredParams( appExpr, function, arg, exprTyVars );
1176
1177	arg = paramBegin;
1178
1179	boxParams( appExpr, function, arg, exprTyVars );
1180	passAdapters( appExpr, function, exprTyVars );
1181
1182	return ret;
1183	}
1184
1185	Expression Pass1::mutate( UntypedExpr expr ) {
1186	if ( expr->has_result() && isPolyType( expr->get_result(), scopeTyVars, env ) ) {
1187	if ( NameExpr name = dynamic_cast< NameExpr >( expr->get_function() ) ) {
1188	if ( name->get_name() == "*?" ) {
1189	Expression *ret = expr->get_args().front();
1190	expr->get_args().clear();
1191	delete expr;
1192	return ret->acceptMutator( *this );
1193	} // if
1194	} // if
1195	} // if
1196	return PolyMutator::mutate( expr );
1197	}
1198
1199	Expression Pass1::mutate( AddressExpr addrExpr ) {
1200	assert( addrExpr->get_arg()->has_result() && ! addrExpr->get_arg()->get_result()->isVoid() );
1201
1202	bool needs = false;
1203	if ( UntypedExpr expr = dynamic_cast< UntypedExpr >( addrExpr->get_arg() ) ) {
1204	if ( expr->has_result() && isPolyType( expr->get_result(), scopeTyVars, env ) ) {
1205	if ( NameExpr name = dynamic_cast< NameExpr >( expr->get_function() ) ) {
1206	if ( name->get_name() == "*?" ) {
1207	if ( ApplicationExpr * appExpr = dynamic_cast< ApplicationExpr * >( expr->get_args().front() ) ) {
1208	assert( appExpr->get_function()->has_result() );
1209	PointerType pointer = safe_dynamic_cast< PointerType >( appExpr->get_function()->get_result() );
1210	FunctionType function = safe_dynamic_cast< FunctionType >( pointer->get_base() );
1211	needs = needsAdapter( function, scopeTyVars );
1212	} // if
1213	} // if
1214	} // if
1215	} // if
1216	} // if
1217	// isPolyType check needs to happen before mutating addrExpr arg, so pull it forward
1218	// out of the if condition.
1219	bool polytype = isPolyType( addrExpr->get_arg()->get_result(), scopeTyVars, env );
1220	addrExpr->set_arg( mutateExpression( addrExpr->get_arg() ) );
1221	if ( polytype \|\| needs ) {
1222	Expression *ret = addrExpr->get_arg();
1223	delete ret->get_result();
1224	ret->set_result( addrExpr->get_result()->clone() );
1225	addrExpr->set_arg( 0 );
1226	delete addrExpr;
1227	return ret;
1228	} else {
1229	return addrExpr;
1230	} // if
1231	}
1232
1233	Statement * Pass1::mutate( ReturnStmt *returnStmt ) {
1234	if ( retval && returnStmt->get_expr() ) {
1235	assert( returnStmt->get_expr()->has_result() && ! returnStmt->get_expr()->get_result()->isVoid() );
1236	delete returnStmt->get_expr();
1237	returnStmt->set_expr( 0 );
1238	} else {
1239	returnStmt->set_expr( mutateExpression( returnStmt->get_expr() ) );
1240	} // if
1241	return returnStmt;
1242	}
1243
1244	Type * Pass1::mutate( PointerType *pointerType ) {
1245	scopeTyVars.beginScope();
1246	makeTyVarMap( pointerType, scopeTyVars );
1247
1248	Type *ret = Mutator::mutate( pointerType );
1249
1250	scopeTyVars.endScope();
1251	return ret;
1252	}
1253
1254	Type * Pass1::mutate( FunctionType *functionType ) {
1255	scopeTyVars.beginScope();
1256	makeTyVarMap( functionType, scopeTyVars );
1257
1258	Type *ret = Mutator::mutate( functionType );
1259
1260	scopeTyVars.endScope();
1261	return ret;
1262	}
1263
1264	void Pass1::doBeginScope() {
1265	adapters.beginScope();
1266	}
1267
1268	void Pass1::doEndScope() {
1269	adapters.endScope();
1270	}
1271
1272	////////////////////////////////////////// Pass2 ////////////////////////////////////////////////////
1273
1274	void Pass2::addAdapters( FunctionType *functionType ) {
1275	std::list< DeclarationWithType *> &paramList = functionType->get_parameters();
1276	std::list< FunctionType *> functions;
1277	for ( std::list< DeclarationWithType *>::iterator arg = paramList.begin(); arg != paramList.end(); ++arg ) {
1278	Type orig = (arg)->get_type();
1279	findAndReplaceFunction( orig, functions, scopeTyVars, needsAdapter );
1280	(*arg)->set_type( orig );
1281	}
1282	std::set< std::string > adaptersDone;
1283	for ( std::list< FunctionType *>::iterator funType = functions.begin(); funType != functions.end(); ++funType ) {
1284	std::string mangleName = mangleAdapterName( *funType, scopeTyVars );
1285	if ( adaptersDone.find( mangleName ) == adaptersDone.end() ) {
1286	std::string adapterName = makeAdapterName( mangleName );
1287	paramList.push_front( new ObjectDecl( adapterName, Type::StorageClasses(), LinkageSpec::C, 0, new PointerType( Type::Qualifiers(), makeAdapterType( *funType, scopeTyVars ) ), 0 ) );
1288	adaptersDone.insert( adaptersDone.begin(), mangleName );
1289	}
1290	}
1291	// deleteAll( functions );
1292	}
1293
1294	template< typename DeclClass >
1295	DeclClass * Pass2::handleDecl( DeclClass *decl ) {
1296	DeclClass ret = static_cast< DeclClass >( Parent::mutate( decl ) );
1297
1298	return ret;
1299	}
1300
1301	/// determines if `pref` is a prefix of `str`
1302	bool isPrefix( const std::string & str, const std::string & pref ) {
1303	if ( pref.size() > str.size() ) return false;
1304	auto its = std::mismatch( pref.begin(), pref.end(), str.begin() );
1305	return its.first == pref.end();
1306	}
1307
1308	DeclarationWithType * Pass2::mutate( FunctionDecl *functionDecl ) {
1309	functionDecl = safe_dynamic_cast< FunctionDecl * > ( handleDecl( functionDecl ) );
1310	FunctionType * ftype = functionDecl->get_functionType();
1311	if ( ! ftype->get_returnVals().empty() && functionDecl->get_statements() ) {
1312	if ( ! isPrefix( functionDecl->get_name(), "_thunk" ) && ! isPrefix( functionDecl->get_name(), "_adapter" ) ) { // xxx - remove check for prefix once thunks properly use ctor/dtors
1313	assert( ftype->get_returnVals().size() == 1 );
1314	DeclarationWithType * retval = ftype->get_returnVals().front();
1315	if ( retval->get_name() == "" ) {
1316	retval->set_name( "_retval" );
1317	}
1318	functionDecl->get_statements()->get_kids().push_front( new DeclStmt( noLabels, retval ) );
1319	DeclarationWithType * newRet = retval->clone(); // for ownership purposes
1320	ftype->get_returnVals().front() = newRet;
1321	}
1322	}
1323	// errors should have been caught by this point, remove initializers from parameters to allow correct codegen of default arguments
1324	for ( Declaration * param : functionDecl->get_functionType()->get_parameters() ) {
1325	if ( ObjectDecl * obj = dynamic_cast< ObjectDecl * >( param ) ) {
1326	delete obj->get_init();
1327	obj->set_init( nullptr );
1328	}
1329	}
1330	return functionDecl;
1331	}
1332
1333	ObjectDecl * Pass2::mutate( ObjectDecl *objectDecl ) {
1334	return handleDecl( objectDecl );
1335	}
1336
1337	template< typename AggDecl >
1338	AggDecl * Pass2::handleAggDecl( AggDecl * aggDecl ) {
1339	// prevent tyVars from leaking into containing scope
1340	scopeTyVars.beginScope();
1341	Parent::mutate( aggDecl );
1342	scopeTyVars.endScope();
1343	return aggDecl;
1344	}
1345
1346	StructDecl * Pass2::mutate( StructDecl *aggDecl ) {
1347	return handleAggDecl( aggDecl );
1348	}
1349
1350	UnionDecl * Pass2::mutate( UnionDecl *aggDecl ) {
1351	return handleAggDecl( aggDecl );
1352	}
1353
1354	TypeDecl * Pass2::mutate( TypeDecl *typeDecl ) {
1355	addToTyVarMap( typeDecl, scopeTyVars );
1356	if ( typeDecl->get_base() ) {
1357	return handleDecl( typeDecl );
1358	} else {
1359	return Parent::mutate( typeDecl );
1360	}
1361	}
1362
1363	TypedefDecl * Pass2::mutate( TypedefDecl *typedefDecl ) {
1364	return handleDecl( typedefDecl );
1365	}
1366
1367	Type * Pass2::mutate( PointerType *pointerType ) {
1368	scopeTyVars.beginScope();
1369	makeTyVarMap( pointerType, scopeTyVars );
1370
1371	Type *ret = Parent::mutate( pointerType );
1372
1373	scopeTyVars.endScope();
1374	return ret;
1375	}
1376
1377	Type Pass2::mutate( FunctionType funcType ) {
1378	scopeTyVars.beginScope();
1379	makeTyVarMap( funcType, scopeTyVars );
1380
1381	// move polymorphic return type to parameter list
1382	if ( isDynRet( funcType ) ) {
1383	ObjectDecl ret = safe_dynamic_cast< ObjectDecl >( funcType->get_returnVals().front() );
1384	ret->set_type( new PointerType( Type::Qualifiers(), ret->get_type() ) );
1385	funcType->get_parameters().push_front( ret );
1386	funcType->get_returnVals().pop_front();
1387	ret->set_init( nullptr ); // xxx - memory leak?
1388	}
1389
1390	// add size/align and assertions for type parameters to parameter list
1391	std::list< DeclarationWithType *>::iterator last = funcType->get_parameters().begin();
1392	std::list< DeclarationWithType *> inferredParams;
1393	ObjectDecl newObj( "", Type::StorageClasses(), LinkageSpec::C, 0, new BasicType( Type::Qualifiers(), BasicType::LongUnsignedInt ), 0 );
1394	ObjectDecl newPtr( "", Type::StorageClasses(), LinkageSpec::C, 0,
1395	new PointerType( Type::Qualifiers(), new BasicType( Type::Qualifiers(), BasicType::LongUnsignedInt ) ), 0 );
1396	for ( Type::ForallList::const_iterator tyParm = funcType->get_forall().begin(); tyParm != funcType->get_forall().end(); ++tyParm ) {
1397	ObjectDecl sizeParm, alignParm;
1398	// add all size and alignment parameters to parameter list
1399	if ( (*tyParm)->isComplete() ) {
1400	TypeInstType parmType( Type::Qualifiers(), (tyParm)->get_name(), tyParm );
1401	std::string parmName = mangleType( &parmType );
1402
1403	sizeParm = newObj.clone();
1404	sizeParm->set_name( sizeofName( parmName ) );
1405	last = funcType->get_parameters().insert( last, sizeParm );
1406	++last;
1407
1408	alignParm = newObj.clone();
1409	alignParm->set_name( alignofName( parmName ) );
1410	last = funcType->get_parameters().insert( last, alignParm );
1411	++last;
1412	}
1413	// move all assertions into parameter list
1414	for ( std::list< DeclarationWithType >::iterator assert = (tyParm)->get_assertions().begin(); assert != (*tyParm)->get_assertions().end(); ++assert ) {
1415	// assert = (assert)->acceptMutator( *this );
1416	inferredParams.push_back( *assert );
1417	}
1418	(*tyParm)->get_assertions().clear();
1419	}
1420
1421	// add size/align for generic parameter types to parameter list
1422	std::set< std::string > seenTypes; // sizeofName for generic types we've seen
1423	for ( std::list< DeclarationWithType* >::const_iterator fnParm = last; fnParm != funcType->get_parameters().end(); ++fnParm ) {
1424	Type polyType = isPolyType( (fnParm)->get_type(), scopeTyVars );
1425	if ( polyType && ! dynamic_cast< TypeInstType* >( polyType ) ) {
1426	std::string typeName = mangleType( polyType );
1427	if ( seenTypes.count( typeName ) ) continue;
1428
1429	ObjectDecl sizeParm, alignParm, *offsetParm;
1430	sizeParm = newObj.clone();
1431	sizeParm->set_name( sizeofName( typeName ) );
1432	last = funcType->get_parameters().insert( last, sizeParm );
1433	++last;
1434
1435	alignParm = newObj.clone();
1436	alignParm->set_name( alignofName( typeName ) );
1437	last = funcType->get_parameters().insert( last, alignParm );
1438	++last;
1439
1440	if ( StructInstType polyBaseStruct = dynamic_cast< StructInstType >( polyType ) ) {
1441	// NOTE zero-length arrays are illegal in C, so empty structs have no offset array
1442	if ( ! polyBaseStruct->get_baseStruct()->get_members().empty() ) {
1443	offsetParm = newPtr.clone();
1444	offsetParm->set_name( offsetofName( typeName ) );
1445	last = funcType->get_parameters().insert( last, offsetParm );
1446	++last;
1447	}
1448	}
1449
1450	seenTypes.insert( typeName );
1451	}
1452	}
1453
1454	// splice assertion parameters into parameter list
1455	funcType->get_parameters().splice( last, inferredParams );
1456	addAdapters( funcType );
1457	mutateAll( funcType->get_returnVals(), *this );
1458	mutateAll( funcType->get_parameters(), *this );
1459
1460	scopeTyVars.endScope();
1461	return funcType;
1462	}
1463
1464	////////////////////////////////////////// PolyGenericCalculator ////////////////////////////////////////////////////
1465
1466	PolyGenericCalculator::PolyGenericCalculator()
1467	: Parent(), knownLayouts(), knownOffsets(), bufNamer( "_buf" ) {}
1468
1469	void PolyGenericCalculator::beginTypeScope( Type *ty ) {
1470	scopeTyVars.beginScope();
1471	makeTyVarMap( ty, scopeTyVars );
1472	}
1473
1474	void PolyGenericCalculator::endTypeScope() {
1475	scopeTyVars.endScope();
1476	}
1477
1478	template< typename DeclClass >
1479	DeclClass * PolyGenericCalculator::handleDecl( DeclClass decl, Type type ) {
1480	beginTypeScope( type );
1481	// knownLayouts.beginScope();
1482	// knownOffsets.beginScope();
1483
1484	DeclClass ret = static_cast< DeclClass >( Parent::mutate( decl ) );
1485
1486	// knownOffsets.endScope();
1487	// knownLayouts.endScope();
1488	endTypeScope();
1489	return ret;
1490	}
1491
1492	ObjectDecl * PolyGenericCalculator::mutate( ObjectDecl *objectDecl ) {
1493	return handleDecl( objectDecl, objectDecl->get_type() );
1494	}
1495
1496	DeclarationWithType * PolyGenericCalculator::mutate( FunctionDecl *functionDecl ) {
1497	knownLayouts.beginScope();
1498	knownOffsets.beginScope();
1499
1500	DeclarationWithType * decl = handleDecl( functionDecl, functionDecl->get_functionType() );
1501	knownOffsets.endScope();
1502	knownLayouts.endScope();
1503	return decl;
1504	}
1505
1506	TypedefDecl * PolyGenericCalculator::mutate( TypedefDecl *typedefDecl ) {
1507	return handleDecl( typedefDecl, typedefDecl->get_base() );
1508	}
1509
1510	TypeDecl * PolyGenericCalculator::mutate( TypeDecl *typeDecl ) {
1511	addToTyVarMap( typeDecl, scopeTyVars );
1512	return Parent::mutate( typeDecl );
1513	}
1514
1515	Type * PolyGenericCalculator::mutate( PointerType *pointerType ) {
1516	beginTypeScope( pointerType );
1517
1518	Type *ret = Parent::mutate( pointerType );
1519
1520	endTypeScope();
1521	return ret;
1522	}
1523
1524	Type * PolyGenericCalculator::mutate( FunctionType *funcType ) {
1525	beginTypeScope( funcType );
1526
1527	// make sure that any type information passed into the function is accounted for
1528	for ( std::list< DeclarationWithType* >::const_iterator fnParm = funcType->get_parameters().begin(); fnParm != funcType->get_parameters().end(); ++fnParm ) {
1529	// condition here duplicates that in Pass2::mutate( FunctionType* )
1530	Type polyType = isPolyType( (fnParm)->get_type(), scopeTyVars );
1531	if ( polyType && ! dynamic_cast< TypeInstType* >( polyType ) ) {
1532	knownLayouts.insert( mangleType( polyType ) );
1533	}
1534	}
1535
1536	Type *ret = Parent::mutate( funcType );
1537
1538	endTypeScope();
1539	return ret;
1540	}
1541
1542	Statement PolyGenericCalculator::mutate( DeclStmt declStmt ) {
1543	if ( ObjectDecl objectDecl = dynamic_cast< ObjectDecl >( declStmt->get_decl() ) ) {
1544	if ( findGeneric( objectDecl->get_type() ) ) {
1545	// change initialization of a polymorphic value object to allocate via a VLA
1546	// (alloca was previously used, but can't be safely used in loops)
1547	Type *declType = objectDecl->get_type();
1548	std::string bufName = bufNamer.newName();
1549	ObjectDecl *newBuf = new ObjectDecl( bufName, Type::StorageClasses(), LinkageSpec::C, 0,
1550	new ArrayType( Type::Qualifiers(), new BasicType( Type::Qualifiers(), BasicType::Kind::Char), new NameExpr( sizeofName( mangleType(declType) ) ),
1551	true, false, std::list<Attribute>{ new Attribute( std::string{"aligned"}, std::list<Expression>{ new ConstantExpr( Constant::from_int(8) ) } ) } ), 0 );
1552	stmtsToAdd.push_back( new DeclStmt( noLabels, newBuf ) );
1553
1554	delete objectDecl->get_init();
1555
1556	objectDecl->set_init( new SingleInit( new NameExpr( bufName ) ) );
1557	}
1558	}
1559	return Parent::mutate( declStmt );
1560	}
1561
1562	/// Finds the member in the base list that matches the given declaration; returns its index, or -1 if not present
1563	long findMember( DeclarationWithType memberDecl, std::list< Declaration > &baseDecls ) {
1564	long i = 0;
1565	for(std::list< Declaration* >::const_iterator decl = baseDecls.begin(); decl != baseDecls.end(); ++decl, ++i ) {
1566	if ( memberDecl->get_name() != (*decl)->get_name() ) continue;
1567
1568	if ( DeclarationWithType declWithType = dynamic_cast< DeclarationWithType >( *decl ) ) {
1569	if ( memberDecl->get_mangleName().empty() \|\| declWithType->get_mangleName().empty()
1570	\|\| memberDecl->get_mangleName() == declWithType->get_mangleName() ) return i;
1571	else continue;
1572	} else return i;
1573	}
1574	return -1;
1575	}
1576
1577	/// Returns an index expression into the offset array for a type
1578	Expression makeOffsetIndex( Type objectType, long i ) {
1579	ConstantExpr *fieldIndex = new ConstantExpr( Constant::from_ulong( i ) );
1580	UntypedExpr *fieldOffset = new UntypedExpr( new NameExpr( "?[?]" ) );
1581	fieldOffset->get_args().push_back( new NameExpr( offsetofName( mangleType( objectType ) ) ) );
1582	fieldOffset->get_args().push_back( fieldIndex );
1583	return fieldOffset;
1584	}
1585
1586	Expression PolyGenericCalculator::mutate( MemberExpr memberExpr ) {
1587	// mutate, exiting early if no longer MemberExpr
1588	Expression *expr = Parent::mutate( memberExpr );
1589	memberExpr = dynamic_cast< MemberExpr* >( expr );
1590	if ( ! memberExpr ) return expr;
1591
1592	// only mutate member expressions for polymorphic types
1593	int tyDepth;
1594	Type *objectType = hasPolyBase( memberExpr->get_aggregate()->get_result(), scopeTyVars, &tyDepth );
1595	if ( ! objectType ) return memberExpr;
1596	findGeneric( objectType ); // ensure layout for this type is available
1597
1598	// replace member expression with dynamically-computed layout expression
1599	Expression *newMemberExpr = 0;
1600	if ( StructInstType structType = dynamic_cast< StructInstType >( objectType ) ) {
1601	// look up offset index
1602	long i = findMember( memberExpr->get_member(), structType->get_baseStruct()->get_members() );
1603	if ( i == -1 ) return memberExpr;
1604
1605	// replace member expression with pointer to base plus offset
1606	UntypedExpr *fieldLoc = new UntypedExpr( new NameExpr( "?+?" ) );
1607	Expression * aggr = memberExpr->get_aggregate()->clone();
1608	delete aggr->get_env(); // xxx - there's a problem with keeping the env for some reason, so for now just get rid of it
1609	aggr->set_env( nullptr );
1610	fieldLoc->get_args().push_back( aggr );
1611	fieldLoc->get_args().push_back( makeOffsetIndex( objectType, i ) );
1612	fieldLoc->set_result( memberExpr->get_result()->clone() );
1613	newMemberExpr = fieldLoc;
1614	} else if ( dynamic_cast< UnionInstType* >( objectType ) ) {
1615	// union members are all at offset zero, so just use the aggregate expr
1616	Expression * aggr = memberExpr->get_aggregate()->clone();
1617	delete aggr->get_env(); // xxx - there's a problem with keeping the env for some reason, so for now just get rid of it
1618	aggr->set_env( nullptr );
1619	newMemberExpr = aggr;
1620	newMemberExpr->set_result( memberExpr->get_result()->clone() );
1621	} else return memberExpr;
1622	assert( newMemberExpr );
1623
1624	Type *memberType = memberExpr->get_member()->get_type();
1625	if ( ! isPolyType( memberType, scopeTyVars ) ) {
1626	// Not all members of a polymorphic type are themselves of polymorphic type; in this case the member expression should be wrapped and dereferenced to form an lvalue
1627	CastExpr *ptrCastExpr = new CastExpr( newMemberExpr, new PointerType( Type::Qualifiers(), memberType->clone() ) );
1628	UntypedExpr *derefExpr = UntypedExpr::createDeref( ptrCastExpr );
1629	newMemberExpr = derefExpr;
1630	}
1631
1632	delete memberExpr;
1633	return newMemberExpr;
1634	}
1635
1636	ObjectDecl PolyGenericCalculator::makeVar( const std::string &name, Type type, Initializer *init ) {
1637	ObjectDecl *newObj = new ObjectDecl( name, Type::StorageClasses(), LinkageSpec::C, 0, type, init );
1638	stmtsToAdd.push_back( new DeclStmt( noLabels, newObj ) );
1639	return newObj;
1640	}
1641
1642	void PolyGenericCalculator::addOtypeParamsToLayoutCall( UntypedExpr layoutCall, const std::list< Type > &otypeParams ) {
1643	for ( std::list< Type* >::const_iterator param = otypeParams.begin(); param != otypeParams.end(); ++param ) {
1644	if ( findGeneric( *param ) ) {
1645	// push size/align vars for a generic parameter back
1646	std::string paramName = mangleType( *param );
1647	layoutCall->get_args().push_back( new NameExpr( sizeofName( paramName ) ) );
1648	layoutCall->get_args().push_back( new NameExpr( alignofName( paramName ) ) );
1649	} else {
1650	layoutCall->get_args().push_back( new SizeofExpr( (*param)->clone() ) );
1651	layoutCall->get_args().push_back( new AlignofExpr( (*param)->clone() ) );
1652	}
1653	}
1654	}
1655
1656	/// returns true if any of the otype parameters have a dynamic layout and puts all otype parameters in the output list
1657	bool findGenericParams( std::list< TypeDecl* > &baseParams, std::list< Expression* > &typeParams, std::list< Type* > &out ) {
1658	bool hasDynamicLayout = false;
1659
1660	std::list< TypeDecl* >::const_iterator baseParam = baseParams.begin();
1661	std::list< Expression* >::const_iterator typeParam = typeParams.begin();
1662	for ( ; baseParam != baseParams.end() && typeParam != typeParams.end(); ++baseParam, ++typeParam ) {
1663	// skip non-otype parameters
1664	if ( ! (*baseParam)->isComplete() ) continue;
1665	TypeExpr typeExpr = dynamic_cast< TypeExpr >( *typeParam );
1666	assert( typeExpr && "all otype parameters should be type expressions" );
1667
1668	Type *type = typeExpr->get_type();
1669	out.push_back( type );
1670	if ( isPolyType( type ) ) hasDynamicLayout = true;
1671	}
1672	assert( baseParam == baseParams.end() && typeParam == typeParams.end() );
1673
1674	return hasDynamicLayout;
1675	}
1676
1677	bool PolyGenericCalculator::findGeneric( Type *ty ) {
1678	ty = replaceTypeInst( ty, env );
1679
1680	if ( TypeInstType typeInst = dynamic_cast< TypeInstType >( ty ) ) {
1681	if ( scopeTyVars.find( typeInst->get_name() ) != scopeTyVars.end() ) {
1682	// NOTE assumes here that getting put in the scopeTyVars included having the layout variables set
1683	return true;
1684	}
1685	return false;
1686	} else if ( StructInstType structTy = dynamic_cast< StructInstType >( ty ) ) {
1687	// check if this type already has a layout generated for it
1688	std::string typeName = mangleType( ty );
1689	if ( knownLayouts.find( typeName ) != knownLayouts.end() ) return true;
1690
1691	// check if any of the type parameters have dynamic layout; if none do, this type is (or will be) monomorphized
1692	std::list< Type* > otypeParams;
1693	if ( ! findGenericParams( *structTy->get_baseParameters(), structTy->get_parameters(), otypeParams ) ) return false;
1694
1695	// insert local variables for layout and generate call to layout function
1696	knownLayouts.insert( typeName ); // done early so as not to interfere with the later addition of parameters to the layout call
1697	Type *layoutType = new BasicType( Type::Qualifiers(), BasicType::LongUnsignedInt );
1698
1699	int n_members = structTy->get_baseStruct()->get_members().size();
1700	if ( n_members == 0 ) {
1701	// all empty structs have the same layout - size 1, align 1
1702	makeVar( sizeofName( typeName ), layoutType, new SingleInit( new ConstantExpr( Constant::from_ulong( (unsigned long)1 ) ) ) );
1703	makeVar( alignofName( typeName ), layoutType->clone(), new SingleInit( new ConstantExpr( Constant::from_ulong( (unsigned long)1 ) ) ) );
1704	// NOTE zero-length arrays are forbidden in C, so empty structs have no offsetof array
1705	} else {
1706	ObjectDecl *sizeVar = makeVar( sizeofName( typeName ), layoutType );
1707	ObjectDecl *alignVar = makeVar( alignofName( typeName ), layoutType->clone() );
1708	ObjectDecl *offsetVar = makeVar( offsetofName( typeName ), new ArrayType( Type::Qualifiers(), layoutType->clone(), new ConstantExpr( Constant::from_int( n_members ) ), false, false ) );
1709
1710	// generate call to layout function
1711	UntypedExpr *layoutCall = new UntypedExpr( new NameExpr( layoutofName( structTy->get_baseStruct() ) ) );
1712	layoutCall->get_args().push_back( new AddressExpr( new VariableExpr( sizeVar ) ) );
1713	layoutCall->get_args().push_back( new AddressExpr( new VariableExpr( alignVar ) ) );
1714	layoutCall->get_args().push_back( new VariableExpr( offsetVar ) );
1715	addOtypeParamsToLayoutCall( layoutCall, otypeParams );
1716
1717	stmtsToAdd.push_back( new ExprStmt( noLabels, layoutCall ) );
1718	}
1719
1720	return true;
1721	} else if ( UnionInstType unionTy = dynamic_cast< UnionInstType >( ty ) ) {
1722	// check if this type already has a layout generated for it
1723	std::string typeName = mangleType( ty );
1724	if ( knownLayouts.find( typeName ) != knownLayouts.end() ) return true;
1725
1726	// check if any of the type parameters have dynamic layout; if none do, this type is (or will be) monomorphized
1727	std::list< Type* > otypeParams;
1728	if ( ! findGenericParams( *unionTy->get_baseParameters(), unionTy->get_parameters(), otypeParams ) ) return false;
1729
1730	// insert local variables for layout and generate call to layout function
1731	knownLayouts.insert( typeName ); // done early so as not to interfere with the later addition of parameters to the layout call
1732	Type *layoutType = new BasicType( Type::Qualifiers(), BasicType::LongUnsignedInt );
1733
1734	ObjectDecl *sizeVar = makeVar( sizeofName( typeName ), layoutType );
1735	ObjectDecl *alignVar = makeVar( alignofName( typeName ), layoutType->clone() );
1736
1737	// generate call to layout function
1738	UntypedExpr *layoutCall = new UntypedExpr( new NameExpr( layoutofName( unionTy->get_baseUnion() ) ) );
1739	layoutCall->get_args().push_back( new AddressExpr( new VariableExpr( sizeVar ) ) );
1740	layoutCall->get_args().push_back( new AddressExpr( new VariableExpr( alignVar ) ) );
1741	addOtypeParamsToLayoutCall( layoutCall, otypeParams );
1742
1743	stmtsToAdd.push_back( new ExprStmt( noLabels, layoutCall ) );
1744
1745	return true;
1746	}
1747
1748	return false;
1749	}
1750
1751	Expression PolyGenericCalculator::mutate( SizeofExpr sizeofExpr ) {
1752	Type *ty = sizeofExpr->get_type();
1753	if ( findGeneric( ty ) ) {
1754	Expression *ret = new NameExpr( sizeofName( mangleType( ty ) ) );
1755	delete sizeofExpr;
1756	return ret;
1757	}
1758	return sizeofExpr;
1759	}
1760
1761	Expression PolyGenericCalculator::mutate( AlignofExpr alignofExpr ) {
1762	Type *ty = alignofExpr->get_type();
1763	if ( findGeneric( ty ) ) {
1764	Expression *ret = new NameExpr( alignofName( mangleType( ty ) ) );
1765	delete alignofExpr;
1766	return ret;
1767	}
1768	return alignofExpr;
1769	}
1770
1771	Expression PolyGenericCalculator::mutate( OffsetofExpr offsetofExpr ) {
1772	// mutate, exiting early if no longer OffsetofExpr
1773	Expression *expr = Parent::mutate( offsetofExpr );
1774	offsetofExpr = dynamic_cast< OffsetofExpr* >( expr );
1775	if ( ! offsetofExpr ) return expr;
1776
1777	// only mutate expressions for polymorphic structs/unions
1778	Type *ty = offsetofExpr->get_type();
1779	if ( ! findGeneric( ty ) ) return offsetofExpr;
1780
1781	if ( StructInstType structType = dynamic_cast< StructInstType >( ty ) ) {
1782	// replace offsetof expression by index into offset array
1783	long i = findMember( offsetofExpr->get_member(), structType->get_baseStruct()->get_members() );
1784	if ( i == -1 ) return offsetofExpr;
1785
1786	Expression *offsetInd = makeOffsetIndex( ty, i );
1787	delete offsetofExpr;
1788	return offsetInd;
1789	} else if ( dynamic_cast< UnionInstType* >( ty ) ) {
1790	// all union members are at offset zero
1791	delete offsetofExpr;
1792	return new ConstantExpr( Constant::from_ulong( 0 ) );
1793	} else return offsetofExpr;
1794	}
1795
1796	Expression PolyGenericCalculator::mutate( OffsetPackExpr offsetPackExpr ) {
1797	StructInstType *ty = offsetPackExpr->get_type();
1798
1799	Expression *ret = 0;
1800	if ( findGeneric( ty ) ) {
1801	// pull offset back from generated type information
1802	ret = new NameExpr( offsetofName( mangleType( ty ) ) );
1803	} else {
1804	std::string offsetName = offsetofName( mangleType( ty ) );
1805	if ( knownOffsets.find( offsetName ) != knownOffsets.end() ) {
1806	// use the already-generated offsets for this type
1807	ret = new NameExpr( offsetName );
1808	} else {
1809	knownOffsets.insert( offsetName );
1810
1811	std::list< Declaration* > &baseMembers = ty->get_baseStruct()->get_members();
1812	Type *offsetType = new BasicType( Type::Qualifiers(), BasicType::LongUnsignedInt );
1813
1814	// build initializer list for offset array
1815	std::list< Initializer* > inits;
1816	for ( std::list< Declaration* >::const_iterator member = baseMembers.begin(); member != baseMembers.end(); ++member ) {
1817	if ( DeclarationWithType memberDecl = dynamic_cast< DeclarationWithType >( *member ) ) {
1818	inits.push_back( new SingleInit( new OffsetofExpr( ty->clone(), memberDecl ) ) );
1819	} else {
1820	assertf( false, "Requesting offset of Non-DWT member: %s", toString( *member ).c_str() );
1821	}
1822	}
1823
1824	// build the offset array and replace the pack with a reference to it
1825	ObjectDecl *offsetArray = makeVar( offsetName, new ArrayType( Type::Qualifiers(), offsetType, new ConstantExpr( Constant::from_ulong( baseMembers.size() ) ), false, false ),
1826	new ListInit( inits ) );
1827	ret = new VariableExpr( offsetArray );
1828	}
1829	}
1830
1831	delete offsetPackExpr;
1832	return ret;
1833	}
1834
1835	void PolyGenericCalculator::doBeginScope() {
1836	knownLayouts.beginScope();
1837	knownOffsets.beginScope();
1838	}
1839
1840	void PolyGenericCalculator::doEndScope() {
1841	knownLayouts.endScope();
1842	knownOffsets.endScope();
1843	}
1844
1845	////////////////////////////////////////// Pass3 ////////////////////////////////////////////////////
1846
1847	template< typename DeclClass >
1848	DeclClass * Pass3::handleDecl( DeclClass decl, Type type ) {
1849	scopeTyVars.beginScope();
1850	makeTyVarMap( type, scopeTyVars );
1851
1852	DeclClass ret = static_cast< DeclClass >( Mutator::mutate( decl ) );
1853	// ScrubTyVars::scrub( decl, scopeTyVars );
1854	ScrubTyVars::scrubAll( decl );
1855
1856	scopeTyVars.endScope();
1857	return ret;
1858	}
1859
1860	ObjectDecl * Pass3::mutate( ObjectDecl *objectDecl ) {
1861	return handleDecl( objectDecl, objectDecl->get_type() );
1862	}
1863
1864	DeclarationWithType * Pass3::mutate( FunctionDecl *functionDecl ) {
1865	return handleDecl( functionDecl, functionDecl->get_functionType() );
1866	}
1867
1868	TypedefDecl * Pass3::mutate( TypedefDecl *typedefDecl ) {
1869	return handleDecl( typedefDecl, typedefDecl->get_base() );
1870	}
1871
1872	TypeDecl * Pass3::mutate( TypeDecl *typeDecl ) {
1873	// Initializer *init = 0;
1874	// std::list< Expression *> designators;
1875	// addToTyVarMap( typeDecl, scopeTyVars );
1876	// if ( typeDecl->get_base() ) {
1877	// init = new SimpleInit( new SizeofExpr( handleDecl( typeDecl, typeDecl->get_base() ) ), designators );
1878	// }
1879	// return new ObjectDecl( typeDecl->get_name(), Declaration::Extern, LinkageSpec::C, 0, new BasicType( Type::Qualifiers(), BasicType::UnsignedInt ), init );
1880
1881	addToTyVarMap( typeDecl, scopeTyVars );
1882	return Mutator::mutate( typeDecl );
1883	}
1884
1885	Type * Pass3::mutate( PointerType *pointerType ) {
1886	scopeTyVars.beginScope();
1887	makeTyVarMap( pointerType, scopeTyVars );
1888
1889	Type *ret = Mutator::mutate( pointerType );
1890
1891	scopeTyVars.endScope();
1892	return ret;
1893	}
1894
1895	Type * Pass3::mutate( FunctionType *functionType ) {
1896	scopeTyVars.beginScope();
1897	makeTyVarMap( functionType, scopeTyVars );
1898
1899	Type *ret = Mutator::mutate( functionType );
1900
1901	scopeTyVars.endScope();
1902	return ret;
1903	}
1904	} // anonymous namespace
1905	} // namespace GenPoly
1906
1907	// Local Variables: //
1908	// tab-width: 4 //
1909	// mode: c++ //
1910	// compile-command: "make install" //
1911	// End: //

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