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source: src/GenPoly/Box.cc @ 029e330

ADTarm-ehast-experimentalcleanup-dtorsenumforall-pointer-decayjacob/cs343-translationjenkins-sandboxnew-astnew-ast-unique-exprpthread-emulationqualifiedEnum

Last change on this file since 029e330 was 029e330, checked in by Rob Schluntz <rschlunt@…>, 6 years ago
Minor code cleanup
Property mode set to `100644`
File size: 88.6 KB

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

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