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source: src/SymTab/Validate.cc @ 490d17e0

ADTast-experimentalpthread-emulationqualifiedEnum

Last change on this file since 490d17e0 was 24ceace, checked in by JiadaL <j82liang@…>, 2 years ago
Merge branch 'master' of plg.uwaterloo.ca:software/cfa/cfa-cc
Property mode set to `100644`
File size: 83.4 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	// Validate.cc --
8	//
9	// Author : Richard C. Bilson
10	// Created On : Sun May 17 21:50:04 2015
11	// Last Modified By : Andrew Beach
12	// Last Modified On : Fri Apr 29 9:45:00 2022
13	// Update Count : 365
14	//
15
16	// The "validate" phase of translation is used to take a syntax tree and convert it into a standard form that aims to be
17	// as regular in structure as possible. Some assumptions can be made regarding the state of the tree after this pass is
18	// complete, including:
19	//
20	// - No nested structure or union definitions; any in the input are "hoisted" to the level of the containing struct or
21	// union.
22	//
23	// - All enumeration constants have type EnumInstType.
24	//
25	// - The type "void" never occurs in lists of function parameter or return types. A function
26	// taking no arguments has no argument types.
27	//
28	// - No context instances exist; they are all replaced by the set of declarations signified by the context, instantiated
29	// by the particular set of type arguments.
30	//
31	// - Every declaration is assigned a unique id.
32	//
33	// - No typedef declarations or instances exist; the actual type is substituted for each instance.
34	//
35	// - Each type, struct, and union definition is followed by an appropriate assignment operator.
36	//
37	// - Each use of a struct or union is connected to a complete definition of that struct or union, even if that
38	// definition occurs later in the input.
39
40	#include "Validate.h"
41
42	#include <cassert> // for assertf, assert
43	#include <cstddef> // for size_t
44	#include <list> // for list
45	#include <string> // for string
46	#include <unordered_map> // for unordered_map
47	#include <utility> // for pair
48
49	#include "AST/Chain.hpp"
50	#include "AST/Decl.hpp"
51	#include "AST/Node.hpp"
52	#include "AST/Pass.hpp"
53	#include "AST/SymbolTable.hpp"
54	#include "AST/Type.hpp"
55	#include "AST/TypeSubstitution.hpp"
56	#include "CodeGen/CodeGenerator.h" // for genName
57	#include "CodeGen/OperatorTable.h" // for isCtorDtor, isCtorDtorAssign
58	#include "ControlStruct/Mutate.h" // for ForExprMutator
59	#include "Common/CodeLocation.h" // for CodeLocation
60	#include "Common/Stats.h" // for Stats::Heap
61	#include "Common/PassVisitor.h" // for PassVisitor, WithDeclsToAdd
62	#include "Common/ScopedMap.h" // for ScopedMap
63	#include "Common/SemanticError.h" // for SemanticError
64	#include "Common/UniqueName.h" // for UniqueName
65	#include "Common/utility.h" // for operator+, cloneAll, deleteAll
66	#include "CompilationState.h" // skip some passes in new-ast build
67	#include "Concurrency/Keywords.h" // for applyKeywords
68	#include "FixFunction.h" // for FixFunction
69	#include "Indexer.h" // for Indexer
70	#include "InitTweak/GenInit.h" // for fixReturnStatements
71	#include "InitTweak/InitTweak.h" // for isCtorDtorAssign
72	#include "ResolvExpr/typeops.h" // for typesCompatible
73	#include "ResolvExpr/Resolver.h" // for findSingleExpression
74	#include "ResolvExpr/ResolveTypeof.h" // for resolveTypeof
75	#include "SymTab/Autogen.h" // for SizeType
76	#include "SynTree/LinkageSpec.h" // for C
77	#include "SynTree/Attribute.h" // for noAttributes, Attribute
78	#include "SynTree/Constant.h" // for Constant
79	#include "SynTree/Declaration.h" // for ObjectDecl, DeclarationWithType
80	#include "SynTree/Expression.h" // for CompoundLiteralExpr, Expressio...
81	#include "SynTree/Initializer.h" // for ListInit, Initializer
82	#include "SynTree/Label.h" // for operator==, Label
83	#include "SynTree/Mutator.h" // for Mutator
84	#include "SynTree/Type.h" // for Type, TypeInstType, EnumInstType
85	#include "SynTree/TypeSubstitution.h" // for TypeSubstitution
86	#include "SynTree/Visitor.h" // for Visitor
87	#include "Validate/HandleAttributes.h" // for handleAttributes
88	#include "Validate/FindSpecialDecls.h" // for FindSpecialDecls
89
90	class CompoundStmt;
91	class ReturnStmt;
92	class SwitchStmt;
93
94	#define debugPrint( x ) if ( doDebug ) x
95
96	namespace SymTab {
97	/// hoists declarations that are difficult to hoist while parsing
98	struct HoistTypeDecls final : public WithDeclsToAdd {
99	void previsit( SizeofExpr * );
100	void previsit( AlignofExpr * );
101	void previsit( UntypedOffsetofExpr * );
102	void previsit( CompoundLiteralExpr * );
103	void handleType( Type * );
104	};
105
106	struct FixQualifiedTypes final : public WithIndexer {
107	FixQualifiedTypes() : WithIndexer(false) {}
108	Type * postmutate( QualifiedType * );
109	};
110
111	struct HoistStruct final : public WithDeclsToAdd, public WithGuards {
112	/// Flattens nested struct types
113	static void hoistStruct( std::list< Declaration * > &translationUnit );
114
115	void previsit( StructDecl * aggregateDecl );
116	void previsit( UnionDecl * aggregateDecl );
117	void previsit( StaticAssertDecl * assertDecl );
118	void previsit( StructInstType * type );
119	void previsit( UnionInstType * type );
120	void previsit( EnumInstType * type );
121
122	private:
123	template< typename AggDecl > void handleAggregate( AggDecl * aggregateDecl );
124
125	AggregateDecl * parentAggr = nullptr;
126	};
127
128	/// Fix return types so that every function returns exactly one value
129	struct ReturnTypeFixer {
130	static void fix( std::list< Declaration * > &translationUnit );
131
132	void postvisit( FunctionDecl * functionDecl );
133	void postvisit( FunctionType * ftype );
134	};
135
136	/// Replaces enum types by int, and function or array types in function parameter and return lists by appropriate pointers.
137	struct EnumAndPointerDecay_old {
138	void previsit( EnumDecl * aggregateDecl );
139	void previsit( FunctionType * func );
140	};
141
142	/// Associates forward declarations of aggregates with their definitions
143	struct LinkReferenceToTypes_old final : public WithIndexer, public WithGuards, public WithVisitorRef<LinkReferenceToTypes_old>, public WithShortCircuiting {
144	LinkReferenceToTypes_old( const Indexer * indexer );
145
146	void postvisit( TypeInstType * typeInst );
147
148	void postvisit( EnumInstType * enumInst );
149	void postvisit( StructInstType * structInst );
150	void postvisit( UnionInstType * unionInst );
151	void postvisit( TraitInstType * traitInst );
152	void previsit( QualifiedType * qualType );
153	void postvisit( QualifiedType * qualType );
154
155	void postvisit( EnumDecl * enumDecl );
156	void postvisit( StructDecl * structDecl );
157	void postvisit( UnionDecl * unionDecl );
158	void postvisit( TraitDecl * traitDecl );
159
160	void previsit( StructDecl * structDecl );
161	void previsit( UnionDecl * unionDecl );
162
163	void renameGenericParams( std::list< TypeDecl * > & params );
164
165	private:
166	const Indexer * local_indexer;
167
168	typedef std::map< std::string, std::list< EnumInstType * > > ForwardEnumsType;
169	typedef std::map< std::string, std::list< StructInstType * > > ForwardStructsType;
170	typedef std::map< std::string, std::list< UnionInstType * > > ForwardUnionsType;
171	ForwardEnumsType forwardEnums;
172	ForwardStructsType forwardStructs;
173	ForwardUnionsType forwardUnions;
174	/// true if currently in a generic type body, so that type parameter instances can be renamed appropriately
175	bool inGeneric = false;
176	};
177
178	/// Does early resolution on the expressions that give enumeration constants their values
179	struct ResolveEnumInitializers final : public WithIndexer, public WithGuards, public WithVisitorRef<ResolveEnumInitializers>, public WithShortCircuiting {
180	ResolveEnumInitializers( const Indexer * indexer );
181	void postvisit( EnumDecl * enumDecl );
182
183	private:
184	const Indexer * local_indexer;
185
186	};
187
188	/// Replaces array and function types in forall lists by appropriate pointer type and assigns each Object and Function declaration a unique ID.
189	struct ForallPointerDecay_old final {
190	void previsit( ObjectDecl * object );
191	void previsit( FunctionDecl * func );
192	void previsit( FunctionType * ftype );
193	void previsit( StructDecl * aggrDecl );
194	void previsit( UnionDecl * aggrDecl );
195	};
196
197	// These structs are the sub-sub-passes of ForallPointerDecay_old.
198
199	struct TraitExpander_old final {
200	void previsit( FunctionType * );
201	void previsit( StructDecl * );
202	void previsit( UnionDecl * );
203	};
204
205	struct AssertionFixer_old final {
206	void previsit( FunctionType * );
207	void previsit( StructDecl * );
208	void previsit( UnionDecl * );
209	};
210
211	struct CheckOperatorTypes_old final {
212	void previsit( ObjectDecl * );
213	};
214
215	struct FixUniqueIds_old final {
216	void previsit( DeclarationWithType * );
217	};
218
219	struct ReturnChecker : public WithGuards {
220	/// Checks that return statements return nothing if their return type is void
221	/// and return something if the return type is non-void.
222	static void checkFunctionReturns( std::list< Declaration * > & translationUnit );
223
224	void previsit( FunctionDecl * functionDecl );
225	void previsit( ReturnStmt * returnStmt );
226
227	typedef std::list< DeclarationWithType * > ReturnVals;
228	ReturnVals returnVals;
229	};
230
231	struct ReplaceTypedef final : public WithVisitorRef<ReplaceTypedef>, public WithGuards, public WithShortCircuiting, public WithDeclsToAdd {
232	ReplaceTypedef() : scopeLevel( 0 ) {}
233	/// Replaces typedefs by forward declarations
234	static void replaceTypedef( std::list< Declaration * > &translationUnit );
235
236	void premutate( QualifiedType * );
237	Type * postmutate( QualifiedType * qualType );
238	Type * postmutate( TypeInstType * aggregateUseType );
239	Declaration * postmutate( TypedefDecl * typeDecl );
240	void premutate( TypeDecl * typeDecl );
241	void premutate( FunctionDecl * funcDecl );
242	void premutate( ObjectDecl * objDecl );
243	DeclarationWithType * postmutate( ObjectDecl * objDecl );
244
245	void premutate( CastExpr * castExpr );
246
247	void premutate( CompoundStmt * compoundStmt );
248
249	void premutate( StructDecl * structDecl );
250	void premutate( UnionDecl * unionDecl );
251	void premutate( EnumDecl * enumDecl );
252	void premutate( TraitDecl * );
253
254	void premutate( FunctionType * ftype );
255
256	private:
257	template<typename AggDecl>
258	void addImplicitTypedef( AggDecl * aggDecl );
259	template< typename AggDecl >
260	void handleAggregate( AggDecl * aggr );
261
262	typedef std::unique_ptr<TypedefDecl> TypedefDeclPtr;
263	typedef ScopedMap< std::string, std::pair< TypedefDeclPtr, int > > TypedefMap;
264	typedef ScopedMap< std::string, TypeDecl * > TypeDeclMap;
265	TypedefMap typedefNames;
266	TypeDeclMap typedeclNames;
267	int scopeLevel;
268	bool inFunctionType = false;
269	};
270
271	struct EliminateTypedef {
272	/// removes TypedefDecls from the AST
273	static void eliminateTypedef( std::list< Declaration * > &translationUnit );
274
275	template<typename AggDecl>
276	void handleAggregate( AggDecl * aggregateDecl );
277
278	void previsit( StructDecl * aggregateDecl );
279	void previsit( UnionDecl * aggregateDecl );
280	void previsit( CompoundStmt * compoundStmt );
281	};
282
283	struct VerifyCtorDtorAssign {
284	/// ensure that constructors, destructors, and assignment have at least one
285	/// parameter, the first of which must be a pointer, and that ctor/dtors have no
286	/// return values.
287	static void verify( std::list< Declaration * > &translationUnit );
288
289	void previsit( FunctionDecl * funcDecl );
290	};
291
292	/// ensure that generic types have the correct number of type arguments
293	struct ValidateGenericParameters {
294	void previsit( StructInstType * inst );
295	void previsit( UnionInstType * inst );
296	};
297
298	/// desugar declarations and uses of dimension paramaters like [N],
299	/// from type-system managed values, to tunnneling via ordinary types,
300	/// as char[-] in and sizeof(-) out
301	struct TranslateDimensionGenericParameters : public WithIndexer, public WithGuards {
302	static void translateDimensions( std::list< Declaration * > &translationUnit );
303	TranslateDimensionGenericParameters();
304
305	bool nextVisitedNodeIsChildOfSUIT = false; // SUIT = Struct or Union -Inst Type
306	bool visitingChildOfSUIT = false;
307	void changeState_ChildOfSUIT( bool newVal );
308	void premutate( StructInstType * sit );
309	void premutate( UnionInstType * uit );
310	void premutate( BaseSyntaxNode * node );
311
312	TypeDecl * postmutate( TypeDecl * td );
313	Expression * postmutate( DimensionExpr * de );
314	Expression * postmutate( Expression * e );
315	};
316
317	struct FixObjectType : public WithIndexer {
318	/// resolves typeof type in object, function, and type declarations
319	static void fix( std::list< Declaration * > & translationUnit );
320
321	void previsit( ObjectDecl * );
322	void previsit( FunctionDecl * );
323	void previsit( TypeDecl * );
324	};
325
326	struct InitializerLength {
327	/// for array types without an explicit length, compute the length and store it so that it
328	/// is known to the rest of the phases. For example,
329	/// int x[] = { 1, 2, 3 };
330	/// int y[][2] = { { 1, 2, 3 }, { 1, 2, 3 } };
331	/// here x and y are known at compile-time to have length 3, so change this into
332	/// int x[3] = { 1, 2, 3 };
333	/// int y[3][2] = { { 1, 2, 3 }, { 1, 2, 3 } };
334	static void computeLength( std::list< Declaration * > & translationUnit );
335
336	void previsit( ObjectDecl * objDecl );
337	};
338
339	struct ArrayLength : public WithIndexer {
340	static void computeLength( std::list< Declaration * > & translationUnit );
341
342	void previsit( ArrayType * arrayType );
343	};
344
345	struct CompoundLiteral final : public WithDeclsToAdd, public WithVisitorRef<CompoundLiteral> {
346	Type::StorageClasses storageClasses;
347
348	void premutate( ObjectDecl * objectDecl );
349	Expression * postmutate( CompoundLiteralExpr * compLitExpr );
350	};
351
352	struct LabelAddressFixer final : public WithGuards {
353	std::set< Label > labels;
354
355	void premutate( FunctionDecl * funcDecl );
356	Expression * postmutate( AddressExpr * addrExpr );
357	};
358
359	void validate_A( std::list< Declaration * > & translationUnit ) {
360	PassVisitor<EnumAndPointerDecay_old> epc;
361	PassVisitor<HoistTypeDecls> hoistDecls;
362	{
363	Stats::Heap::newPass("validate-A");
364	Stats::Time::BlockGuard guard("validate-A");
365	VerifyCtorDtorAssign::verify( translationUnit ); // must happen before autogen, because autogen examines existing ctor/dtors
366	acceptAll( translationUnit, hoistDecls );
367	ReplaceTypedef::replaceTypedef( translationUnit );
368	ReturnTypeFixer::fix( translationUnit ); // must happen before autogen
369	acceptAll( translationUnit, epc ); // must happen before VerifyCtorDtorAssign, because void return objects should not exist; before LinkReferenceToTypes_old because it is an indexer and needs correct types for mangling
370	}
371	}
372
373	void linkReferenceToTypes( std::list< Declaration * > & translationUnit ) {
374	PassVisitor<LinkReferenceToTypes_old> lrt( nullptr );
375	acceptAll( translationUnit, lrt ); // must happen before autogen, because sized flag needs to propagate to generated functions
376	}
377
378	void validate_B( std::list< Declaration * > & translationUnit ) {
379	PassVisitor<FixQualifiedTypes> fixQual;
380	{
381	Stats::Heap::newPass("validate-B");
382	Stats::Time::BlockGuard guard("validate-B");
383	//linkReferenceToTypes( translationUnit );
384	mutateAll( translationUnit, fixQual ); // must happen after LinkReferenceToTypes_old, because aggregate members are accessed
385	HoistStruct::hoistStruct( translationUnit );
386	EliminateTypedef::eliminateTypedef( translationUnit );
387	}
388	}
389
390	void validate_C( std::list< Declaration * > & translationUnit ) {
391	PassVisitor<ValidateGenericParameters> genericParams;
392	PassVisitor<ResolveEnumInitializers> rei( nullptr );
393	{
394	Stats::Heap::newPass("validate-C");
395	Stats::Time::BlockGuard guard("validate-C");
396	Stats::Time::TimeBlock("Validate Generic Parameters", [&]() {
397	acceptAll( translationUnit, genericParams ); // check as early as possible - can't happen before LinkReferenceToTypes_old; observed failing when attempted before eliminateTypedef
398	});
399	Stats::Time::TimeBlock("Translate Dimensions", [&]() {
400	TranslateDimensionGenericParameters::translateDimensions( translationUnit );
401	});
402	if (!useNewAST) {
403	Stats::Time::TimeBlock("Resolve Enum Initializers", [&]() {
404	acceptAll( translationUnit, rei ); // must happen after translateDimensions because rei needs identifier lookup, which needs name mangling
405	});
406	}
407	Stats::Time::TimeBlock("Check Function Returns", [&]() {
408	ReturnChecker::checkFunctionReturns( translationUnit );
409	});
410	Stats::Time::TimeBlock("Fix Return Statements", [&]() {
411	InitTweak::fixReturnStatements( translationUnit ); // must happen before autogen
412	});
413	}
414	}
415
416	static void decayForallPointers( std::list< Declaration * > & translationUnit ) {
417	PassVisitor<TraitExpander_old> te;
418	acceptAll( translationUnit, te );
419	PassVisitor<AssertionFixer_old> af;
420	acceptAll( translationUnit, af );
421	PassVisitor<CheckOperatorTypes_old> cot;
422	acceptAll( translationUnit, cot );
423	PassVisitor<FixUniqueIds_old> fui;
424	acceptAll( translationUnit, fui );
425	}
426
427	void validate_D( std::list< Declaration * > & translationUnit ) {
428	{
429	Stats::Heap::newPass("validate-D");
430	Stats::Time::BlockGuard guard("validate-D");
431	Stats::Time::TimeBlock("Apply Concurrent Keywords", [&]() {
432	Concurrency::applyKeywords( translationUnit );
433	});
434	Stats::Time::TimeBlock("Forall Pointer Decay", [&]() {
435	decayForallPointers( translationUnit ); // must happen before autogenerateRoutines, after Concurrency::applyKeywords because uniqueIds must be set on declaration before resolution
436	});
437	Stats::Time::TimeBlock("Hoist Control Declarations", [&]() {
438	ControlStruct::hoistControlDecls( translationUnit ); // hoist initialization out of for statements; must happen before autogenerateRoutines
439	});
440	Stats::Time::TimeBlock("Generate Autogen routines", [&]() {
441	autogenerateRoutines( translationUnit ); // moved up, used to be below compoundLiteral - currently needs EnumAndPointerDecay_old
442	});
443	}
444	}
445
446	void validate_E( std::list< Declaration * > & translationUnit ) {
447	PassVisitor<CompoundLiteral> compoundliteral;
448	{
449	Stats::Heap::newPass("validate-E");
450	Stats::Time::BlockGuard guard("validate-E");
451	Stats::Time::TimeBlock("Implement Mutex Func", [&]() {
452	Concurrency::implementMutexFuncs( translationUnit );
453	});
454	Stats::Time::TimeBlock("Implement Thread Start", [&]() {
455	Concurrency::implementThreadStarter( translationUnit );
456	});
457	Stats::Time::TimeBlock("Compound Literal", [&]() {
458	mutateAll( translationUnit, compoundliteral );
459	});
460	if (!useNewAST) {
461	Stats::Time::TimeBlock("Resolve With Expressions", [&]() {
462	ResolvExpr::resolveWithExprs( translationUnit ); // must happen before FixObjectType because user-code is resolved and may contain with variables
463	});
464	}
465	}
466	}
467
468	void validate_F( std::list< Declaration * > & translationUnit ) {
469	PassVisitor<LabelAddressFixer> labelAddrFixer;
470	{
471	Stats::Heap::newPass("validate-F");
472	Stats::Time::BlockGuard guard("validate-F");
473	if (!useNewAST) {
474	Stats::Time::TimeCall("Fix Object Type",
475	FixObjectType::fix, translationUnit);
476	}
477	Stats::Time::TimeCall("Initializer Length",
478	InitializerLength::computeLength, translationUnit);
479	if (!useNewAST) {
480	Stats::Time::TimeCall("Array Length",
481	ArrayLength::computeLength, translationUnit);
482	}
483	Stats::Time::TimeCall("Find Special Declarations",
484	Validate::findSpecialDecls, translationUnit);
485	Stats::Time::TimeCall("Fix Label Address",
486	mutateAll<LabelAddressFixer>, translationUnit, labelAddrFixer);
487	if (!useNewAST) {
488	Stats::Time::TimeCall("Handle Attributes",
489	Validate::handleAttributes, translationUnit);
490	}
491	}
492	}
493
494	void validate( std::list< Declaration * > &translationUnit, __attribute__((unused)) bool doDebug ) {
495	validate_A( translationUnit );
496	validate_B( translationUnit );
497	validate_C( translationUnit );
498	validate_D( translationUnit );
499	validate_E( translationUnit );
500	validate_F( translationUnit );
501	}
502
503	void validateType( Type * type, const Indexer * indexer ) {
504	PassVisitor<EnumAndPointerDecay_old> epc;
505	PassVisitor<LinkReferenceToTypes_old> lrt( indexer );
506	PassVisitor<TraitExpander_old> te;
507	PassVisitor<AssertionFixer_old> af;
508	PassVisitor<CheckOperatorTypes_old> cot;
509	PassVisitor<FixUniqueIds_old> fui;
510	type->accept( epc );
511	type->accept( lrt );
512	type->accept( te );
513	type->accept( af );
514	type->accept( cot );
515	type->accept( fui );
516	}
517
518	void HoistTypeDecls::handleType( Type * type ) {
519	// some type declarations are buried in expressions and not easy to hoist during parsing; hoist them here
520	AggregateDecl * aggr = nullptr;
521	if ( StructInstType * inst = dynamic_cast< StructInstType * >( type ) ) {
522	aggr = inst->baseStruct;
523	} else if ( UnionInstType * inst = dynamic_cast< UnionInstType * >( type ) ) {
524	aggr = inst->baseUnion;
525	} else if ( EnumInstType * inst = dynamic_cast< EnumInstType * >( type ) ) {
526	aggr = inst->baseEnum;
527	}
528	if ( aggr && aggr->body ) {
529	declsToAddBefore.push_front( aggr );
530	}
531	}
532
533	void HoistTypeDecls::previsit( SizeofExpr * expr ) {
534	handleType( expr->type );
535	}
536
537	void HoistTypeDecls::previsit( AlignofExpr * expr ) {
538	handleType( expr->type );
539	}
540
541	void HoistTypeDecls::previsit( UntypedOffsetofExpr * expr ) {
542	handleType( expr->type );
543	}
544
545	void HoistTypeDecls::previsit( CompoundLiteralExpr * expr ) {
546	handleType( expr->result );
547	}
548
549
550	Type * FixQualifiedTypes::postmutate( QualifiedType * qualType ) {
551	Type * parent = qualType->parent;
552	Type * child = qualType->child;
553	if ( dynamic_cast< GlobalScopeType * >( qualType->parent ) ) {
554	// .T => lookup T at global scope
555	if ( TypeInstType * inst = dynamic_cast< TypeInstType * >( child ) ) {
556	auto td = indexer.globalLookupType( inst->name );
557	if ( ! td ) {
558	SemanticError( qualType->location, toString("Use of undefined global type ", inst->name) );
559	}
560	auto base = td->base;
561	assert( base );
562	Type * ret = base->clone();
563	ret->get_qualifiers() = qualType->get_qualifiers();
564	return ret;
565	} else {
566	// .T => T is not a type name
567	assertf( false, "unhandled global qualified child type: %s", toCString(child) );
568	}
569	} else {
570	// S.T => S must be an aggregate type, find the declaration for T in S.
571	AggregateDecl * aggr = nullptr;
572	if ( StructInstType * inst = dynamic_cast< StructInstType * >( parent ) ) {
573	aggr = inst->baseStruct;
574	} else if ( UnionInstType * inst = dynamic_cast< UnionInstType * > ( parent ) ) {
575	aggr = inst->baseUnion;
576	} else {
577	SemanticError( qualType->location, toString("Qualified type requires an aggregate on the left, but has: ", parent) );
578	}
579	assert( aggr ); // TODO: need to handle forward declarations
580	for ( Declaration * member : aggr->members ) {
581	if ( TypeInstType * inst = dynamic_cast< TypeInstType * >( child ) ) {
582	// name on the right is a typedef
583	if ( NamedTypeDecl * aggr = dynamic_cast< NamedTypeDecl * > ( member ) ) {
584	if ( aggr->name == inst->name ) {
585	assert( aggr->base );
586	Type * ret = aggr->base->clone();
587	ret->get_qualifiers() = qualType->get_qualifiers();
588	TypeSubstitution sub = parent->genericSubstitution();
589	sub.apply(ret);
590	return ret;
591	}
592	}
593	} else {
594	// S.T - S is not an aggregate => error
595	assertf( false, "unhandled qualified child type: %s", toCString(qualType) );
596	}
597	}
598	// failed to find a satisfying definition of type
599	SemanticError( qualType->location, toString("Undefined type in qualified type: ", qualType) );
600	}
601
602	// ... may want to link canonical SUE definition to each forward decl so that it becomes easier to lookup?
603	}
604
605
606	void HoistStruct::hoistStruct( std::list< Declaration * > &translationUnit ) {
607	PassVisitor<HoistStruct> hoister;
608	acceptAll( translationUnit, hoister );
609	}
610
611	bool shouldHoist( Declaration * decl ) {
612	return dynamic_cast< StructDecl * >( decl ) \|\| dynamic_cast< UnionDecl * >( decl ) \|\| dynamic_cast< StaticAssertDecl * >( decl );
613	}
614
615	namespace {
616	void qualifiedName( AggregateDecl * aggr, std::ostringstream & ss ) {
617	if ( aggr->parent ) qualifiedName( aggr->parent, ss );
618	ss << "__" << aggr->name;
619	}
620
621	// mangle nested type names using entire parent chain
622	std::string qualifiedName( AggregateDecl * aggr ) {
623	std::ostringstream ss;
624	qualifiedName( aggr, ss );
625	return ss.str();
626	}
627	}
628
629	template< typename AggDecl >
630	void HoistStruct::handleAggregate( AggDecl * aggregateDecl ) {
631	if ( parentAggr ) {
632	aggregateDecl->parent = parentAggr;
633	aggregateDecl->name = qualifiedName( aggregateDecl );
634	// Add elements in stack order corresponding to nesting structure.
635	declsToAddBefore.push_front( aggregateDecl );
636	} else {
637	GuardValue( parentAggr );
638	parentAggr = aggregateDecl;
639	} // if
640	// Always remove the hoisted aggregate from the inner structure.
641	GuardAction( [aggregateDecl]() { filter( aggregateDecl->members, shouldHoist, false ); } );
642	}
643
644	void HoistStruct::previsit( StaticAssertDecl * assertDecl ) {
645	if ( parentAggr ) {
646	declsToAddBefore.push_back( assertDecl );
647	}
648	}
649
650	void HoistStruct::previsit( StructDecl * aggregateDecl ) {
651	handleAggregate( aggregateDecl );
652	}
653
654	void HoistStruct::previsit( UnionDecl * aggregateDecl ) {
655	handleAggregate( aggregateDecl );
656	}
657
658	void HoistStruct::previsit( StructInstType * type ) {
659	// need to reset type name after expanding to qualified name
660	assert( type->baseStruct );
661	type->name = type->baseStruct->name;
662	}
663
664	void HoistStruct::previsit( UnionInstType * type ) {
665	assert( type->baseUnion );
666	type->name = type->baseUnion->name;
667	}
668
669	void HoistStruct::previsit( EnumInstType * type ) {
670	assert( type->baseEnum );
671	type->name = type->baseEnum->name;
672	}
673
674
675	bool isTypedef( Declaration * decl ) {
676	return dynamic_cast< TypedefDecl * >( decl );
677	}
678
679	void EliminateTypedef::eliminateTypedef( std::list< Declaration * > &translationUnit ) {
680	PassVisitor<EliminateTypedef> eliminator;
681	acceptAll( translationUnit, eliminator );
682	filter( translationUnit, isTypedef, true );
683	}
684
685	template< typename AggDecl >
686	void EliminateTypedef::handleAggregate( AggDecl * aggregateDecl ) {
687	filter( aggregateDecl->members, isTypedef, true );
688	}
689
690	void EliminateTypedef::previsit( StructDecl * aggregateDecl ) {
691	handleAggregate( aggregateDecl );
692	}
693
694	void EliminateTypedef::previsit( UnionDecl * aggregateDecl ) {
695	handleAggregate( aggregateDecl );
696	}
697
698	void EliminateTypedef::previsit( CompoundStmt * compoundStmt ) {
699	// remove and delete decl stmts
700	filter( compoundStmt->kids, [](Statement * stmt) {
701	if ( DeclStmt * declStmt = dynamic_cast< DeclStmt * >( stmt ) ) {
702	if ( dynamic_cast< TypedefDecl * >( declStmt->decl ) ) {
703	return true;
704	} // if
705	} // if
706	return false;
707	}, true);
708	}
709
710	void EnumAndPointerDecay_old::previsit( EnumDecl * enumDecl ) {
711	// Set the type of each member of the enumeration to be EnumConstant
712	for ( std::list< Declaration * >::iterator i = enumDecl->members.begin(); i != enumDecl->members.end(); ++i ) {
713	ObjectDecl * obj = dynamic_cast< ObjectDecl * >( * i );
714	assert( obj );
715	obj->set_type( new EnumInstType( Type::Qualifiers( Type::Const ), enumDecl->name ) );
716	} // for
717	}
718
719	namespace {
720	template< typename DWTList >
721	void fixFunctionList( DWTList & dwts, bool isVarArgs, FunctionType * func ) {
722	auto nvals = dwts.size();
723	bool containsVoid = false;
724	for ( auto & dwt : dwts ) {
725	// fix each DWT and record whether a void was found
726	containsVoid \|= fixFunction( dwt );
727	}
728
729	// the only case in which "void" is valid is where it is the only one in the list
730	if ( containsVoid && ( nvals > 1 \|\| isVarArgs ) ) {
731	SemanticError( func, "invalid type void in function type " );
732	}
733
734	// one void is the only thing in the list; remove it.
735	if ( containsVoid ) {
736	delete dwts.front();
737	dwts.clear();
738	}
739	}
740	}
741
742	void EnumAndPointerDecay_old::previsit( FunctionType * func ) {
743	// Fix up parameters and return types
744	fixFunctionList( func->parameters, func->isVarArgs, func );
745	fixFunctionList( func->returnVals, false, func );
746	}
747
748	LinkReferenceToTypes_old::LinkReferenceToTypes_old( const Indexer * other_indexer ) : WithIndexer( false ) {
749	if ( other_indexer ) {
750	local_indexer = other_indexer;
751	} else {
752	local_indexer = &indexer;
753	} // if
754	}
755
756	void LinkReferenceToTypes_old::postvisit( EnumInstType * enumInst ) {
757	const EnumDecl * st = local_indexer->lookupEnum( enumInst->name );
758	// it's not a semantic error if the enum is not found, just an implicit forward declaration
759	if ( st ) {
760	enumInst->baseEnum = const_cast<EnumDecl *>(st); // Just linking in the node
761	} // if
762	if ( ! st \|\| ! st->body ) {
763	// use of forward declaration
764	forwardEnums[ enumInst->name ].push_back( enumInst );
765	} // if
766	}
767	void LinkReferenceToTypes_old::postvisit( StructInstType * structInst ) {
768	const StructDecl * st = local_indexer->lookupStruct( structInst->name );
769	// it's not a semantic error if the struct is not found, just an implicit forward declaration
770	if ( st ) {
771	structInst->baseStruct = const_cast<StructDecl *>(st); // Just linking in the node
772	} // if
773	if ( ! st \|\| ! st->body ) {
774	// use of forward declaration
775	forwardStructs[ structInst->name ].push_back( structInst );
776	} // if
777	}
778
779	void LinkReferenceToTypes_old::postvisit( UnionInstType * unionInst ) {
780	const UnionDecl * un = local_indexer->lookupUnion( unionInst->name );
781	// it's not a semantic error if the union is not found, just an implicit forward declaration
782	if ( un ) {
783	unionInst->baseUnion = const_cast<UnionDecl *>(un); // Just linking in the node
784	} // if
785	if ( ! un \|\| ! un->body ) {
786	// use of forward declaration
787	forwardUnions[ unionInst->name ].push_back( unionInst );
788	} // if
789	}
790
791	void LinkReferenceToTypes_old::previsit( QualifiedType * ) {
792	visit_children = false;
793	}
794
795	void LinkReferenceToTypes_old::postvisit( QualifiedType * qualType ) {
796	// linking only makes sense for the 'oldest ancestor' of the qualified type
797	qualType->parent->accept( * visitor );
798	}
799
800	template< typename Decl >
801	void normalizeAssertions( std::list< Decl * > & assertions ) {
802	// ensure no duplicate trait members after the clone
803	auto pred = [](Decl * d1, Decl * d2) {
804	// only care if they're equal
805	DeclarationWithType * dwt1 = dynamic_cast<DeclarationWithType *>( d1 );
806	DeclarationWithType * dwt2 = dynamic_cast<DeclarationWithType *>( d2 );
807	if ( dwt1 && dwt2 ) {
808	if ( dwt1->name == dwt2->name && ResolvExpr::typesCompatible( dwt1->get_type(), dwt2->get_type(), SymTab::Indexer() ) ) {
809	// std::cerr << "=========== equal:" << std::endl;
810	// std::cerr << "d1: " << d1 << std::endl;
811	// std::cerr << "d2: " << d2 << std::endl;
812	return false;
813	}
814	}
815	return d1 < d2;
816	};
817	std::set<Decl *, decltype(pred)> unique_members( assertions.begin(), assertions.end(), pred );
818	// if ( unique_members.size() != assertions.size() ) {
819	// std::cerr << "============different" << std::endl;
820	// std::cerr << unique_members.size() << " " << assertions.size() << std::endl;
821	// }
822
823	std::list< Decl * > order;
824	order.splice( order.end(), assertions );
825	std::copy_if( order.begin(), order.end(), back_inserter( assertions ), [&]( Decl * decl ) {
826	return unique_members.count( decl );
827	});
828	}
829
830	// expand assertions from trait instance, performing the appropriate type variable substitutions
831	template< typename Iterator >
832	void expandAssertions( TraitInstType * inst, Iterator out ) {
833	assertf( inst->baseTrait, "Trait instance not linked to base trait: %s", toCString( inst ) );
834	std::list< DeclarationWithType * > asserts;
835	for ( Declaration * decl : inst->baseTrait->members ) {
836	asserts.push_back( strict_dynamic_cast<DeclarationWithType *>( decl->clone() ) );
837	}
838	// substitute trait decl parameters for instance parameters
839	applySubstitution( inst->baseTrait->parameters.begin(), inst->baseTrait->parameters.end(), inst->parameters.begin(), asserts.begin(), asserts.end(), out );
840	}
841
842	void LinkReferenceToTypes_old::postvisit( TraitDecl * traitDecl ) {
843	if ( traitDecl->name == "sized" ) {
844	// "sized" is a special trait - flick the sized status on for the type variable
845	assertf( traitDecl->parameters.size() == 1, "Built-in trait 'sized' has incorrect number of parameters: %zd", traitDecl->parameters.size() );
846	TypeDecl * td = traitDecl->parameters.front();
847	td->set_sized( true );
848	}
849
850	// move assertions from type parameters into the body of the trait
851	for ( TypeDecl * td : traitDecl->parameters ) {
852	for ( DeclarationWithType * assert : td->assertions ) {
853	if ( TraitInstType * inst = dynamic_cast< TraitInstType * >( assert->get_type() ) ) {
854	expandAssertions( inst, back_inserter( traitDecl->members ) );
855	} else {
856	traitDecl->members.push_back( assert->clone() );
857	}
858	}
859	deleteAll( td->assertions );
860	td->assertions.clear();
861	} // for
862	}
863
864	void LinkReferenceToTypes_old::postvisit( TraitInstType * traitInst ) {
865	// handle other traits
866	const TraitDecl * traitDecl = local_indexer->lookupTrait( traitInst->name );
867	if ( ! traitDecl ) {
868	SemanticError( traitInst->location, "use of undeclared trait " + traitInst->name );
869	} // if
870	if ( traitDecl->parameters.size() != traitInst->parameters.size() ) {
871	SemanticError( traitInst, "incorrect number of trait parameters: " );
872	} // if
873	traitInst->baseTrait = const_cast<TraitDecl *>(traitDecl); // Just linking in the node
874
875	// need to carry over the 'sized' status of each decl in the instance
876	for ( auto p : group_iterate( traitDecl->parameters, traitInst->parameters ) ) {
877	TypeExpr * expr = dynamic_cast< TypeExpr * >( std::get<1>(p) );
878	if ( ! expr ) {
879	SemanticError( std::get<1>(p), "Expression parameters for trait instances are currently unsupported: " );
880	}
881	if ( TypeInstType * inst = dynamic_cast< TypeInstType * >( expr->get_type() ) ) {
882	TypeDecl * formalDecl = std::get<0>(p);
883	TypeDecl * instDecl = inst->baseType;
884	if ( formalDecl->get_sized() ) instDecl->set_sized( true );
885	}
886	}
887	// normalizeAssertions( traitInst->members );
888	}
889
890	void LinkReferenceToTypes_old::postvisit( EnumDecl * enumDecl ) {
891	// visit enum members first so that the types of self-referencing members are updated properly
892	// Replace the enum base; right now it works only for StructEnum
893	if ( enumDecl->base && dynamic_cast<TypeInstType*>(enumDecl->base) ) {
894	std::string baseName = static_cast<TypeInstType*>(enumDecl->base)->name;
895	const StructDecl * st = local_indexer->lookupStruct( baseName );
896	if ( st ) {
897	enumDecl->base = new StructInstType(Type::Qualifiers(),const_cast<StructDecl *>(st)); // Just linking in the node
898	}
899	}
900	if ( enumDecl->body ) {
901	ForwardEnumsType::iterator fwds = forwardEnums.find( enumDecl->name );
902	if ( fwds != forwardEnums.end() ) {
903	for ( std::list< EnumInstType * >::iterator inst = fwds->second.begin(); inst != fwds->second.end(); ++inst ) {
904	(* inst)->baseEnum = enumDecl;
905	} // for
906	forwardEnums.erase( fwds );
907	} // if
908	} // if
909	}
910
911	void LinkReferenceToTypes_old::renameGenericParams( std::list< TypeDecl * > & params ) {
912	// rename generic type parameters uniquely so that they do not conflict with user-defined function forall parameters, e.g.
913	// forall(otype T)
914	// struct Box {
915	// T x;
916	// };
917	// forall(otype T)
918	// void f(Box(T) b) {
919	// ...
920	// }
921	// The T in Box and the T in f are different, so internally the naming must reflect that.
922	GuardValue( inGeneric );
923	inGeneric = ! params.empty();
924	for ( TypeDecl * td : params ) {
925	td->name = "__" + td->name + "_generic_";
926	}
927	}
928
929	void LinkReferenceToTypes_old::previsit( StructDecl * structDecl ) {
930	renameGenericParams( structDecl->parameters );
931	}
932
933	void LinkReferenceToTypes_old::previsit( UnionDecl * unionDecl ) {
934	renameGenericParams( unionDecl->parameters );
935	}
936
937	void LinkReferenceToTypes_old::postvisit( StructDecl * structDecl ) {
938	// visit struct members first so that the types of self-referencing members are updated properly
939	// xxx - need to ensure that type parameters match up between forward declarations and definition (most importantly, number of type parameters and their defaults)
940	if ( structDecl->body ) {
941	ForwardStructsType::iterator fwds = forwardStructs.find( structDecl->name );
942	if ( fwds != forwardStructs.end() ) {
943	for ( std::list< StructInstType * >::iterator inst = fwds->second.begin(); inst != fwds->second.end(); ++inst ) {
944	(* inst)->baseStruct = structDecl;
945	} // for
946	forwardStructs.erase( fwds );
947	} // if
948	} // if
949	}
950
951	void LinkReferenceToTypes_old::postvisit( UnionDecl * unionDecl ) {
952	if ( unionDecl->body ) {
953	ForwardUnionsType::iterator fwds = forwardUnions.find( unionDecl->name );
954	if ( fwds != forwardUnions.end() ) {
955	for ( std::list< UnionInstType * >::iterator inst = fwds->second.begin(); inst != fwds->second.end(); ++inst ) {
956	(* inst)->baseUnion = unionDecl;
957	} // for
958	forwardUnions.erase( fwds );
959	} // if
960	} // if
961	}
962
963	void LinkReferenceToTypes_old::postvisit( TypeInstType * typeInst ) {
964	// ensure generic parameter instances are renamed like the base type
965	if ( inGeneric && typeInst->baseType ) typeInst->name = typeInst->baseType->name;
966	if ( const NamedTypeDecl * namedTypeDecl = local_indexer->lookupType( typeInst->name ) ) {
967	if ( const TypeDecl * typeDecl = dynamic_cast< const TypeDecl * >( namedTypeDecl ) ) {
968	typeInst->set_isFtype( typeDecl->kind == TypeDecl::Ftype );
969	} // if
970	} // if
971	}
972
973	ResolveEnumInitializers::ResolveEnumInitializers( const Indexer * other_indexer ) : WithIndexer( true ) {
974	if ( other_indexer ) {
975	local_indexer = other_indexer;
976	} else {
977	local_indexer = &indexer;
978	} // if
979	}
980
981	void ResolveEnumInitializers::postvisit( EnumDecl * enumDecl ) {
982	if ( enumDecl->body ) {
983	for ( Declaration * member : enumDecl->members ) {
984	ObjectDecl * field = strict_dynamic_cast<ObjectDecl *>( member );
985	if ( field->init ) {
986	// need to resolve enumerator initializers early so that other passes that determine if an expression is constexpr have the appropriate information.
987	SingleInit * init = strict_dynamic_cast<SingleInit *>( field->init );
988	if ( !enumDecl->base \|\| dynamic_cast<BasicType *>(enumDecl->base))
989	ResolvExpr::findSingleExpression( init->value, new BasicType( Type::Qualifiers(), BasicType::SignedInt ), indexer );
990	else {
991	if (dynamic_cast<PointerType *>(enumDecl->base)) {
992	auto typePtr = dynamic_cast<PointerType *>(enumDecl->base);
993	ResolvExpr::findSingleExpression( init->value,
994	new PointerType( Type::Qualifiers(), typePtr->base ), indexer );
995	} else {
996	ResolvExpr::findSingleExpression( init->value, new BasicType( Type::Qualifiers(), BasicType::SignedInt ), indexer );
997	}
998	}
999
1000	}
1001	}
1002
1003	} // if
1004	}
1005
1006	/// Fix up assertions - flattens assertion lists, removing all trait instances
1007	void forallFixer( std::list< TypeDecl * > & forall, BaseSyntaxNode * node ) {
1008	for ( TypeDecl * type : forall ) {
1009	std::list< DeclarationWithType * > asserts;
1010	asserts.splice( asserts.end(), type->assertions );
1011	// expand trait instances into their members
1012	for ( DeclarationWithType * assertion : asserts ) {
1013	if ( TraitInstType * traitInst = dynamic_cast< TraitInstType * >( assertion->get_type() ) ) {
1014	// expand trait instance into all of its members
1015	expandAssertions( traitInst, back_inserter( type->assertions ) );
1016	delete traitInst;
1017	} else {
1018	// pass other assertions through
1019	type->assertions.push_back( assertion );
1020	} // if
1021	} // for
1022	// apply FixFunction to every assertion to check for invalid void type
1023	for ( DeclarationWithType *& assertion : type->assertions ) {
1024	bool isVoid = fixFunction( assertion );
1025	if ( isVoid ) {
1026	SemanticError( node, "invalid type void in assertion of function " );
1027	} // if
1028	} // for
1029	// normalizeAssertions( type->assertions );
1030	} // for
1031	}
1032
1033	/// Replace all traits in assertion lists with their assertions.
1034	void expandTraits( std::list< TypeDecl * > & forall ) {
1035	for ( TypeDecl * type : forall ) {
1036	std::list< DeclarationWithType * > asserts;
1037	asserts.splice( asserts.end(), type->assertions );
1038	// expand trait instances into their members
1039	for ( DeclarationWithType * assertion : asserts ) {
1040	if ( TraitInstType * traitInst = dynamic_cast< TraitInstType * >( assertion->get_type() ) ) {
1041	// expand trait instance into all of its members
1042	expandAssertions( traitInst, back_inserter( type->assertions ) );
1043	delete traitInst;
1044	} else {
1045	// pass other assertions through
1046	type->assertions.push_back( assertion );
1047	} // if
1048	} // for
1049	}
1050	}
1051
1052	/// Fix each function in the assertion list and check for invalid void type.
1053	void fixAssertions(
1054	std::list< TypeDecl * > & forall, BaseSyntaxNode * node ) {
1055	for ( TypeDecl * type : forall ) {
1056	for ( DeclarationWithType *& assertion : type->assertions ) {
1057	bool isVoid = fixFunction( assertion );
1058	if ( isVoid ) {
1059	SemanticError( node, "invalid type void in assertion of function " );
1060	} // if
1061	} // for
1062	}
1063	}
1064
1065	void ForallPointerDecay_old::previsit( ObjectDecl * object ) {
1066	// ensure that operator names only apply to functions or function pointers
1067	if ( CodeGen::isOperator( object->name ) && ! dynamic_cast< FunctionType * >( object->type->stripDeclarator() ) ) {
1068	SemanticError( object->location, toCString( "operator ", object->name.c_str(), " is not a function or function pointer." ) );
1069	}
1070	object->fixUniqueId();
1071	}
1072
1073	void ForallPointerDecay_old::previsit( FunctionDecl * func ) {
1074	func->fixUniqueId();
1075	}
1076
1077	void ForallPointerDecay_old::previsit( FunctionType * ftype ) {
1078	forallFixer( ftype->forall, ftype );
1079	}
1080
1081	void ForallPointerDecay_old::previsit( StructDecl * aggrDecl ) {
1082	forallFixer( aggrDecl->parameters, aggrDecl );
1083	}
1084
1085	void ForallPointerDecay_old::previsit( UnionDecl * aggrDecl ) {
1086	forallFixer( aggrDecl->parameters, aggrDecl );
1087	}
1088
1089	void TraitExpander_old::previsit( FunctionType * ftype ) {
1090	expandTraits( ftype->forall );
1091	}
1092
1093	void TraitExpander_old::previsit( StructDecl * aggrDecl ) {
1094	expandTraits( aggrDecl->parameters );
1095	}
1096
1097	void TraitExpander_old::previsit( UnionDecl * aggrDecl ) {
1098	expandTraits( aggrDecl->parameters );
1099	}
1100
1101	void AssertionFixer_old::previsit( FunctionType * ftype ) {
1102	fixAssertions( ftype->forall, ftype );
1103	}
1104
1105	void AssertionFixer_old::previsit( StructDecl * aggrDecl ) {
1106	fixAssertions( aggrDecl->parameters, aggrDecl );
1107	}
1108
1109	void AssertionFixer_old::previsit( UnionDecl * aggrDecl ) {
1110	fixAssertions( aggrDecl->parameters, aggrDecl );
1111	}
1112
1113	void CheckOperatorTypes_old::previsit( ObjectDecl * object ) {
1114	// ensure that operator names only apply to functions or function pointers
1115	if ( CodeGen::isOperator( object->name ) && ! dynamic_cast< FunctionType * >( object->type->stripDeclarator() ) ) {
1116	SemanticError( object->location, toCString( "operator ", object->name.c_str(), " is not a function or function pointer." ) );
1117	}
1118	}
1119
1120	void FixUniqueIds_old::previsit( DeclarationWithType * decl ) {
1121	decl->fixUniqueId();
1122	}
1123
1124	void ReturnChecker::checkFunctionReturns( std::list< Declaration * > & translationUnit ) {
1125	PassVisitor<ReturnChecker> checker;
1126	acceptAll( translationUnit, checker );
1127	}
1128
1129	void ReturnChecker::previsit( FunctionDecl * functionDecl ) {
1130	GuardValue( returnVals );
1131	returnVals = functionDecl->get_functionType()->get_returnVals();
1132	}
1133
1134	void ReturnChecker::previsit( ReturnStmt * returnStmt ) {
1135	// Previously this also checked for the existence of an expr paired with no return values on
1136	// the function return type. This is incorrect, since you can have an expression attached to
1137	// a return statement in a void-returning function in C. The expression is treated as if it
1138	// were cast to void.
1139	if ( ! returnStmt->get_expr() && returnVals.size() != 0 ) {
1140	SemanticError( returnStmt, "Non-void function returns no values: " );
1141	}
1142	}
1143
1144
1145	void ReplaceTypedef::replaceTypedef( std::list< Declaration * > &translationUnit ) {
1146	PassVisitor<ReplaceTypedef> eliminator;
1147	mutateAll( translationUnit, eliminator );
1148	if ( eliminator.pass.typedefNames.count( "size_t" ) ) {
1149	// grab and remember declaration of size_t
1150	Validate::SizeType = eliminator.pass.typedefNames["size_t"].first->base->clone();
1151	} else {
1152	// xxx - missing global typedef for size_t - default to long unsigned int, even though that may be wrong
1153	// eventually should have a warning for this case.
1154	Validate::SizeType = new BasicType( Type::Qualifiers(), BasicType::LongUnsignedInt );
1155	}
1156	}
1157
1158	void ReplaceTypedef::premutate( QualifiedType * ) {
1159	visit_children = false;
1160	}
1161
1162	Type * ReplaceTypedef::postmutate( QualifiedType * qualType ) {
1163	// replacing typedefs only makes sense for the 'oldest ancestor' of the qualified type
1164	qualType->parent = qualType->parent->acceptMutator( * visitor );
1165	return qualType;
1166	}
1167
1168	static bool isNonParameterAttribute( Attribute * attr ) {
1169	static const std::vector<std::string> bad_names = {
1170	"aligned", "__aligned__",
1171	};
1172	for ( auto name : bad_names ) {
1173	if ( name == attr->name ) {
1174	return true;
1175	}
1176	}
1177	return false;
1178	}
1179
1180	Type * ReplaceTypedef::postmutate( TypeInstType * typeInst ) {
1181	// instances of typedef types will come here. If it is an instance
1182	// of a typdef type, link the instance to its actual type.
1183	TypedefMap::const_iterator def = typedefNames.find( typeInst->name );
1184	if ( def != typedefNames.end() ) {
1185	Type * ret = def->second.first->base->clone();
1186	ret->location = typeInst->location;
1187	ret->get_qualifiers() \|= typeInst->get_qualifiers();
1188	// GCC ignores certain attributes if they arrive by typedef, this mimics that.
1189	if ( inFunctionType ) {
1190	ret->attributes.remove_if( isNonParameterAttribute );
1191	}
1192	ret->attributes.splice( ret->attributes.end(), typeInst->attributes );
1193	// place instance parameters on the typedef'd type
1194	if ( ! typeInst->parameters.empty() ) {
1195	ReferenceToType * rtt = dynamic_cast<ReferenceToType *>(ret);
1196	if ( ! rtt ) {
1197	SemanticError( typeInst->location, "Cannot apply type parameters to base type of " + typeInst->name );
1198	}
1199	rtt->parameters.clear();
1200	cloneAll( typeInst->parameters, rtt->parameters );
1201	mutateAll( rtt->parameters, * visitor ); // recursively fix typedefs on parameters
1202	} // if
1203	delete typeInst;
1204	return ret;
1205	} else {
1206	TypeDeclMap::const_iterator base = typedeclNames.find( typeInst->name );
1207	if ( base == typedeclNames.end() ) {
1208	SemanticError( typeInst->location, toString("Use of undefined type ", typeInst->name) );
1209	}
1210	typeInst->set_baseType( base->second );
1211	return typeInst;
1212	} // if
1213	assert( false );
1214	}
1215
1216	struct VarLenChecker : WithShortCircuiting {
1217	void previsit( FunctionType * ) { visit_children = false; }
1218	void previsit( ArrayType * at ) {
1219	isVarLen \|= at->isVarLen;
1220	}
1221	bool isVarLen = false;
1222	};
1223
1224	bool isVariableLength( Type * t ) {
1225	PassVisitor<VarLenChecker> varLenChecker;
1226	maybeAccept( t, varLenChecker );
1227	return varLenChecker.pass.isVarLen;
1228	}
1229
1230	Declaration * ReplaceTypedef::postmutate( TypedefDecl * tyDecl ) {
1231	if ( typedefNames.count( tyDecl->name ) == 1 && typedefNames[ tyDecl->name ].second == scopeLevel ) {
1232	// typedef to the same name from the same scope
1233	// must be from the same type
1234
1235	Type * t1 = tyDecl->base;
1236	Type * t2 = typedefNames[ tyDecl->name ].first->base;
1237	if ( ! ResolvExpr::typesCompatible( t1, t2, Indexer() ) ) {
1238	SemanticError( tyDecl->location, "Cannot redefine typedef: " + tyDecl->name );
1239	}
1240	// Cannot redefine VLA typedefs. Note: this is slightly incorrect, because our notion of VLAs
1241	// at this point in the translator is imprecise. In particular, this will disallow redefining typedefs
1242	// with arrays whose dimension is an enumerator or a cast of a constant/enumerator. The effort required
1243	// to fix this corner case likely outweighs the utility of allowing it.
1244	if ( isVariableLength( t1 ) \|\| isVariableLength( t2 ) ) {
1245	SemanticError( tyDecl->location, "Cannot redefine typedef: " + tyDecl->name );
1246	}
1247	} else {
1248	typedefNames[ tyDecl->name ] = std::make_pair( TypedefDeclPtr( tyDecl ), scopeLevel );
1249	} // if
1250
1251	// When a typedef is a forward declaration:
1252	// typedef struct screen SCREEN;
1253	// the declaration portion must be retained:
1254	// struct screen;
1255	// because the expansion of the typedef is:
1256	// void rtn( SCREEN * p ) => void rtn( struct screen * p )
1257	// hence the type-name "screen" must be defined.
1258	// Note, qualifiers on the typedef are superfluous for the forward declaration.
1259
1260	Type * designatorType = tyDecl->base->stripDeclarator();
1261	if ( StructInstType * aggDecl = dynamic_cast< StructInstType * >( designatorType ) ) {
1262	declsToAddBefore.push_back( new StructDecl( aggDecl->name, AggregateDecl::Struct, noAttributes, tyDecl->linkage ) );
1263	} else if ( UnionInstType * aggDecl = dynamic_cast< UnionInstType * >( designatorType ) ) {
1264	declsToAddBefore.push_back( new UnionDecl( aggDecl->name, noAttributes, tyDecl->linkage ) );
1265	} else if ( EnumInstType * enumDecl = dynamic_cast< EnumInstType * >( designatorType ) ) {
1266	// declsToAddBefore.push_back( new EnumDecl( enumDecl->name, noAttributes, tyDecl->linkage, enumDecl->baseEnum->base ) );
1267	if (enumDecl->baseEnum) {
1268	declsToAddBefore.push_back( new EnumDecl( enumDecl->name, noAttributes, tyDecl->linkage, enumDecl->baseEnum->base ) );
1269	} else {
1270	declsToAddBefore.push_back( new EnumDecl( enumDecl->name, noAttributes, tyDecl->linkage ) );
1271	}
1272	} // if
1273	return tyDecl->clone();
1274	}
1275
1276	void ReplaceTypedef::premutate( TypeDecl * typeDecl ) {
1277	TypedefMap::iterator i = typedefNames.find( typeDecl->name );
1278	if ( i != typedefNames.end() ) {
1279	typedefNames.erase( i ) ;
1280	} // if
1281
1282	typedeclNames.insert( typeDecl->name, typeDecl );
1283	}
1284
1285	void ReplaceTypedef::premutate( FunctionDecl * ) {
1286	GuardScope( typedefNames );
1287	GuardScope( typedeclNames );
1288	}
1289
1290	void ReplaceTypedef::premutate( ObjectDecl * ) {
1291	GuardScope( typedefNames );
1292	GuardScope( typedeclNames );
1293	}
1294
1295	DeclarationWithType * ReplaceTypedef::postmutate( ObjectDecl * objDecl ) {
1296	if ( FunctionType * funtype = dynamic_cast<FunctionType *>( objDecl->type ) ) { // function type?
1297	// replace the current object declaration with a function declaration
1298	FunctionDecl * newDecl = new FunctionDecl( objDecl->name, objDecl->get_storageClasses(), objDecl->linkage, funtype, 0, objDecl->attributes, objDecl->get_funcSpec() );
1299	objDecl->attributes.clear();
1300	objDecl->set_type( nullptr );
1301	delete objDecl;
1302	return newDecl;
1303	} // if
1304	return objDecl;
1305	}
1306
1307	void ReplaceTypedef::premutate( CastExpr * ) {
1308	GuardScope( typedefNames );
1309	GuardScope( typedeclNames );
1310	}
1311
1312	void ReplaceTypedef::premutate( CompoundStmt * ) {
1313	GuardScope( typedefNames );
1314	GuardScope( typedeclNames );
1315	scopeLevel += 1;
1316	GuardAction( [this](){ scopeLevel -= 1; } );
1317	}
1318
1319	template<typename AggDecl>
1320	void ReplaceTypedef::addImplicitTypedef( AggDecl * aggDecl ) {
1321	if ( typedefNames.count( aggDecl->get_name() ) == 0 ) {
1322	Type * type = nullptr;
1323	if ( StructDecl * newDeclStructDecl = dynamic_cast< StructDecl * >( aggDecl ) ) {
1324	type = new StructInstType( Type::Qualifiers(), newDeclStructDecl->get_name() );
1325	} else if ( UnionDecl * newDeclUnionDecl = dynamic_cast< UnionDecl * >( aggDecl ) ) {
1326	type = new UnionInstType( Type::Qualifiers(), newDeclUnionDecl->get_name() );
1327	} else if ( EnumDecl * newDeclEnumDecl = dynamic_cast< EnumDecl * >( aggDecl ) ) {
1328	type = new EnumInstType( Type::Qualifiers(), newDeclEnumDecl->get_name() );
1329	} // if
1330	TypedefDeclPtr tyDecl( new TypedefDecl( aggDecl->get_name(), aggDecl->location, Type::StorageClasses(), type, aggDecl->get_linkage() ) );
1331	typedefNames[ aggDecl->get_name() ] = std::make_pair( std::move( tyDecl ), scopeLevel );
1332	// add the implicit typedef to the AST
1333	declsToAddBefore.push_back( new TypedefDecl( aggDecl->get_name(), aggDecl->location, Type::StorageClasses(), type->clone(), aggDecl->get_linkage() ) );
1334	} // if
1335	}
1336
1337	template< typename AggDecl >
1338	void ReplaceTypedef::handleAggregate( AggDecl * aggr ) {
1339	SemanticErrorException errors;
1340
1341	ValueGuard< std::list<Declaration * > > oldBeforeDecls( declsToAddBefore );
1342	ValueGuard< std::list<Declaration * > > oldAfterDecls ( declsToAddAfter );
1343	declsToAddBefore.clear();
1344	declsToAddAfter.clear();
1345
1346	GuardScope( typedefNames );
1347	GuardScope( typedeclNames );
1348	mutateAll( aggr->parameters, * visitor );
1349	mutateAll( aggr->attributes, * visitor );
1350
1351	// unroll mutateAll for aggr->members so that implicit typedefs for nested types are added to the aggregate body.
1352	for ( std::list< Declaration * >::iterator i = aggr->members.begin(); i != aggr->members.end(); ++i ) {
1353	if ( !declsToAddAfter.empty() ) { aggr->members.splice( i, declsToAddAfter ); }
1354
1355	try {
1356	* i = maybeMutate( * i, * visitor );
1357	} catch ( SemanticErrorException &e ) {
1358	errors.append( e );
1359	}
1360
1361	if ( !declsToAddBefore.empty() ) { aggr->members.splice( i, declsToAddBefore ); }
1362	}
1363
1364	if ( !declsToAddAfter.empty() ) { aggr->members.splice( aggr->members.end(), declsToAddAfter ); }
1365	if ( !errors.isEmpty() ) { throw errors; }
1366	}
1367
1368	void ReplaceTypedef::premutate( StructDecl * structDecl ) {
1369	visit_children = false;
1370	addImplicitTypedef( structDecl );
1371	handleAggregate( structDecl );
1372	}
1373
1374	void ReplaceTypedef::premutate( UnionDecl * unionDecl ) {
1375	visit_children = false;
1376	addImplicitTypedef( unionDecl );
1377	handleAggregate( unionDecl );
1378	}
1379
1380	void ReplaceTypedef::premutate( EnumDecl * enumDecl ) {
1381	addImplicitTypedef( enumDecl );
1382	}
1383
1384	void ReplaceTypedef::premutate( FunctionType * ) {
1385	GuardValue( inFunctionType );
1386	inFunctionType = true;
1387	}
1388
1389	void ReplaceTypedef::premutate( TraitDecl * ) {
1390	GuardScope( typedefNames );
1391	GuardScope( typedeclNames);
1392	}
1393
1394	void VerifyCtorDtorAssign::verify( std::list< Declaration * > & translationUnit ) {
1395	PassVisitor<VerifyCtorDtorAssign> verifier;
1396	acceptAll( translationUnit, verifier );
1397	}
1398
1399	void VerifyCtorDtorAssign::previsit( FunctionDecl * funcDecl ) {
1400	FunctionType * funcType = funcDecl->get_functionType();
1401	std::list< DeclarationWithType * > &returnVals = funcType->get_returnVals();
1402	std::list< DeclarationWithType * > &params = funcType->get_parameters();
1403
1404	if ( CodeGen::isCtorDtorAssign( funcDecl->get_name() ) ) { // TODO: also check /=, etc.
1405	if ( params.size() == 0 ) {
1406	SemanticError( funcDecl->location, "Constructors, destructors, and assignment functions require at least one parameter." );
1407	}
1408	ReferenceType * refType = dynamic_cast< ReferenceType * >( params.front()->get_type() );
1409	if ( ! refType ) {
1410	SemanticError( funcDecl->location, "First parameter of a constructor, destructor, or assignment function must be a reference." );
1411	}
1412	if ( CodeGen::isCtorDtor( funcDecl->get_name() ) && returnVals.size() != 0 ) {
1413	if(!returnVals.front()->get_type()->isVoid()) {
1414	SemanticError( funcDecl->location, "Constructors and destructors cannot have explicit return values." );
1415	}
1416	}
1417	}
1418	}
1419
1420	// Test for special name on a generic parameter. Special treatment for the
1421	// special name is a bootstrapping hack. In most cases, the worlds of T's
1422	// and of N's don't overlap (normal treamtemt). The foundations in
1423	// array.hfa use tagging for both types and dimensions. Tagging treats
1424	// its subject parameter even more opaquely than T&, which assumes it is
1425	// possible to have a pointer/reference to such an object. Tagging only
1426	// seeks to identify the type-system resident at compile time. Both N's
1427	// and T's can make tags. The tag definition uses the special name, which
1428	// is treated as "an N or a T." This feature is not inteded to be used
1429	// outside of the definition and immediate uses of a tag.
1430	static inline bool isReservedTysysIdOnlyName( const std::string & name ) {
1431	// name's prefix was __CFA_tysys_id_only, before it got wrapped in __..._generic
1432	int foundAt = name.find("__CFA_tysys_id_only");
1433	if (foundAt == 0) return true;
1434	if (foundAt == 2 && name[0] == '_' && name[1] == '_') return true;
1435	return false;
1436	}
1437
1438	template< typename Aggr >
1439	void validateGeneric( Aggr * inst ) {
1440	std::list< TypeDecl * > * params = inst->get_baseParameters();
1441	if ( params ) {
1442	std::list< Expression * > & args = inst->get_parameters();
1443
1444	// insert defaults arguments when a type argument is missing (currently only supports missing arguments at the end of the list).
1445	// A substitution is used to ensure that defaults are replaced correctly, e.g.,
1446	// forall(otype T, otype alloc = heap_allocator(T)) struct vector;
1447	// vector(int) v;
1448	// after insertion of default values becomes
1449	// vector(int, heap_allocator(T))
1450	// and the substitution is built with T=int so that after substitution, the result is
1451	// vector(int, heap_allocator(int))
1452	TypeSubstitution sub;
1453	auto paramIter = params->begin();
1454	auto argIter = args.begin();
1455	for ( ; paramIter != params->end(); ++paramIter, ++argIter ) {
1456	if ( argIter != args.end() ) {
1457	TypeExpr * expr = dynamic_cast< TypeExpr * >( * argIter );
1458	if ( expr ) {
1459	sub.add( (* paramIter)->get_name(), expr->get_type()->clone() );
1460	}
1461	} else {
1462	Type * defaultType = (* paramIter)->get_init();
1463	if ( defaultType ) {
1464	args.push_back( new TypeExpr( defaultType->clone() ) );
1465	sub.add( (* paramIter)->get_name(), defaultType->clone() );
1466	argIter = std::prev(args.end());
1467	} else {
1468	SemanticError( inst, "Too few type arguments in generic type " );
1469	}
1470	}
1471	assert( argIter != args.end() );
1472	bool typeParamDeclared = (*paramIter)->kind != TypeDecl::Kind::Dimension;
1473	bool typeArgGiven;
1474	if ( isReservedTysysIdOnlyName( (*paramIter)->name ) ) {
1475	// coerce a match when declaration is reserved name, which means "either"
1476	typeArgGiven = typeParamDeclared;
1477	} else {
1478	typeArgGiven = dynamic_cast< TypeExpr * >( * argIter );
1479	}
1480	if ( ! typeParamDeclared && typeArgGiven ) SemanticError( inst, "Type argument given for value parameter: " );
1481	if ( typeParamDeclared && ! typeArgGiven ) SemanticError( inst, "Expression argument given for type parameter: " );
1482	}
1483
1484	sub.apply( inst );
1485	if ( args.size() > params->size() ) SemanticError( inst, "Too many type arguments in generic type " );
1486	}
1487	}
1488
1489	void ValidateGenericParameters::previsit( StructInstType * inst ) {
1490	validateGeneric( inst );
1491	}
1492
1493	void ValidateGenericParameters::previsit( UnionInstType * inst ) {
1494	validateGeneric( inst );
1495	}
1496
1497	void TranslateDimensionGenericParameters::translateDimensions( std::list< Declaration * > &translationUnit ) {
1498	PassVisitor<TranslateDimensionGenericParameters> translator;
1499	mutateAll( translationUnit, translator );
1500	}
1501
1502	TranslateDimensionGenericParameters::TranslateDimensionGenericParameters() : WithIndexer( false ) {}
1503
1504	// Declaration of type variable: forall( [N] ) -> forall( N & \| sized( N ) )
1505	TypeDecl * TranslateDimensionGenericParameters::postmutate( TypeDecl * td ) {
1506	if ( td->kind == TypeDecl::Dimension ) {
1507	td->kind = TypeDecl::Dtype;
1508	if ( ! isReservedTysysIdOnlyName( td->name ) ) {
1509	td->sized = true;
1510	}
1511	}
1512	return td;
1513	}
1514
1515	// Situational awareness:
1516	// array( float, [[currentExpr]] ) has visitingChildOfSUIT == true
1517	// array( float, [[currentExpr]] - 1 ) has visitingChildOfSUIT == false
1518	// size_t x = [[currentExpr]] has visitingChildOfSUIT == false
1519	void TranslateDimensionGenericParameters::changeState_ChildOfSUIT( bool newVal ) {
1520	GuardValue( nextVisitedNodeIsChildOfSUIT );
1521	GuardValue( visitingChildOfSUIT );
1522	visitingChildOfSUIT = nextVisitedNodeIsChildOfSUIT;
1523	nextVisitedNodeIsChildOfSUIT = newVal;
1524	}
1525	void TranslateDimensionGenericParameters::premutate( StructInstType * sit ) {
1526	(void) sit;
1527	changeState_ChildOfSUIT(true);
1528	}
1529	void TranslateDimensionGenericParameters::premutate( UnionInstType * uit ) {
1530	(void) uit;
1531	changeState_ChildOfSUIT(true);
1532	}
1533	void TranslateDimensionGenericParameters::premutate( BaseSyntaxNode * node ) {
1534	(void) node;
1535	changeState_ChildOfSUIT(false);
1536	}
1537
1538	// Passing values as dimension arguments: array( float, 7 ) -> array( float, char[ 7 ] )
1539	// Consuming dimension parameters: size_t x = N - 1 ; -> size_t x = sizeof(N) - 1 ;
1540	// Intertwined reality: array( float, N ) -> array( float, N )
1541	// array( float, N - 1 ) -> array( float, char[ sizeof(N) - 1 ] )
1542	// Intertwined case 1 is not just an optimization.
1543	// Avoiding char[sizeof(-)] is necessary to enable the call of f to bind the value of N, in:
1544	// forall([N]) void f( array(float, N) & );
1545	// array(float, 7) a;
1546	// f(a);
1547
1548	Expression * TranslateDimensionGenericParameters::postmutate( DimensionExpr * de ) {
1549	// Expression de is an occurrence of N in LHS of above examples.
1550	// Look up the name that de references.
1551	// If we are in a struct body, then this reference can be to an entry of the stuct's forall list.
1552	// Whether or not we are in a struct body, this reference can be to an entry of a containing function's forall list.
1553	// If we are in a struct body, then the stuct's forall declarations are innermost (functions don't occur in structs).
1554	// Thus, a potential struct's declaration is highest priority.
1555	// A struct's forall declarations are already renamed with _generic_ suffix. Try that name variant first.
1556
1557	std::string useName = "__" + de->name + "_generic_";
1558	TypeDecl * namedParamDecl = const_cast<TypeDecl >( strict_dynamic_cast<const TypeDecl , nullptr >( indexer.lookupType( useName ) ) );
1559
1560	if ( ! namedParamDecl ) {
1561	useName = de->name;
1562	namedParamDecl = const_cast<TypeDecl >( strict_dynamic_cast<const TypeDecl , nullptr >( indexer.lookupType( useName ) ) );
1563	}
1564
1565	// Expect to find it always. A misspelled name would have been parsed as an identifier.
1566	assert( namedParamDecl && "Type-system-managed value name not found in symbol table" );
1567
1568	delete de;
1569
1570	TypeInstType * refToDecl = new TypeInstType( 0, useName, namedParamDecl );
1571
1572	if ( visitingChildOfSUIT ) {
1573	// As in postmutate( Expression * ), topmost expression needs a TypeExpr wrapper
1574	// But avoid ArrayType-Sizeof
1575	return new TypeExpr( refToDecl );
1576	} else {
1577	// the N occurrence is being used directly as a runtime value,
1578	// if we are in a type instantiation, then the N is within a bigger value computation
1579	return new SizeofExpr( refToDecl );
1580	}
1581	}
1582
1583	Expression * TranslateDimensionGenericParameters::postmutate( Expression * e ) {
1584	if ( visitingChildOfSUIT ) {
1585	// e is an expression used as an argument to instantiate a type
1586	if (! dynamic_cast< TypeExpr * >( e ) ) {
1587	// e is a value expression
1588	// but not a DimensionExpr, which has a distinct postmutate
1589	Type * typeExprContent = new ArrayType( 0, new BasicType( 0, BasicType::Char ), e, true, false );
1590	TypeExpr * result = new TypeExpr( typeExprContent );
1591	return result;
1592	}
1593	}
1594	return e;
1595	}
1596
1597	void CompoundLiteral::premutate( ObjectDecl * objectDecl ) {
1598	storageClasses = objectDecl->get_storageClasses();
1599	}
1600
1601	Expression * CompoundLiteral::postmutate( CompoundLiteralExpr * compLitExpr ) {
1602	// transform [storage_class] ... (struct S){ 3, ... };
1603	// into [storage_class] struct S temp = { 3, ... };
1604	static UniqueName indexName( "_compLit" );
1605
1606	ObjectDecl * tempvar = new ObjectDecl( indexName.newName(), storageClasses, LinkageSpec::C, nullptr, compLitExpr->get_result(), compLitExpr->get_initializer() );
1607	compLitExpr->set_result( nullptr );
1608	compLitExpr->set_initializer( nullptr );
1609	delete compLitExpr;
1610	declsToAddBefore.push_back( tempvar ); // add modified temporary to current block
1611	return new VariableExpr( tempvar );
1612	}
1613
1614	void ReturnTypeFixer::fix( std::list< Declaration * > &translationUnit ) {
1615	PassVisitor<ReturnTypeFixer> fixer;
1616	acceptAll( translationUnit, fixer );
1617	}
1618
1619	void ReturnTypeFixer::postvisit( FunctionDecl * functionDecl ) {
1620	FunctionType * ftype = functionDecl->get_functionType();
1621	std::list< DeclarationWithType * > & retVals = ftype->get_returnVals();
1622	assertf( retVals.size() == 0 \|\| retVals.size() == 1, "Function %s has too many return values: %zu", functionDecl->get_name().c_str(), retVals.size() );
1623	if ( retVals.size() == 1 ) {
1624	// ensure all function return values have a name - use the name of the function to disambiguate (this also provides a nice bit of help for debugging).
1625	// ensure other return values have a name.
1626	DeclarationWithType * ret = retVals.front();
1627	if ( ret->get_name() == "" ) {
1628	ret->set_name( toString( "_retval_", CodeGen::genName( functionDecl ) ) );
1629	}
1630	ret->get_attributes().push_back( new Attribute( "unused" ) );
1631	}
1632	}
1633
1634	void ReturnTypeFixer::postvisit( FunctionType * ftype ) {
1635	// xxx - need to handle named return values - this information needs to be saved somehow
1636	// so that resolution has access to the names.
1637	// Note that this pass needs to happen early so that other passes which look for tuple types
1638	// find them in all of the right places, including function return types.
1639	std::list< DeclarationWithType * > & retVals = ftype->get_returnVals();
1640	if ( retVals.size() > 1 ) {
1641	// generate a single return parameter which is the tuple of all of the return values
1642	TupleType * tupleType = strict_dynamic_cast< TupleType * >( ResolvExpr::extractResultType( ftype ) );
1643	// ensure return value is not destructed by explicitly creating an empty ListInit node wherein maybeConstruct is false.
1644	ObjectDecl * newRet = new ObjectDecl( "", Type::StorageClasses(), LinkageSpec::Cforall, 0, tupleType, new ListInit( std::list<Initializer *>(), noDesignators, false ) );
1645	deleteAll( retVals );
1646	retVals.clear();
1647	retVals.push_back( newRet );
1648	}
1649	}
1650
1651	void FixObjectType::fix( std::list< Declaration * > & translationUnit ) {
1652	PassVisitor<FixObjectType> fixer;
1653	acceptAll( translationUnit, fixer );
1654	}
1655
1656	void FixObjectType::previsit( ObjectDecl * objDecl ) {
1657	Type * new_type = ResolvExpr::resolveTypeof( objDecl->get_type(), indexer );
1658	objDecl->set_type( new_type );
1659	}
1660
1661	void FixObjectType::previsit( FunctionDecl * funcDecl ) {
1662	Type * new_type = ResolvExpr::resolveTypeof( funcDecl->type, indexer );
1663	funcDecl->set_type( new_type );
1664	}
1665
1666	void FixObjectType::previsit( TypeDecl * typeDecl ) {
1667	if ( typeDecl->get_base() ) {
1668	Type * new_type = ResolvExpr::resolveTypeof( typeDecl->get_base(), indexer );
1669	typeDecl->set_base( new_type );
1670	} // if
1671	}
1672
1673	void InitializerLength::computeLength( std::list< Declaration * > & translationUnit ) {
1674	PassVisitor<InitializerLength> len;
1675	acceptAll( translationUnit, len );
1676	}
1677
1678	void ArrayLength::computeLength( std::list< Declaration * > & translationUnit ) {
1679	PassVisitor<ArrayLength> len;
1680	acceptAll( translationUnit, len );
1681	}
1682
1683	void InitializerLength::previsit( ObjectDecl * objDecl ) {
1684	if ( ArrayType * at = dynamic_cast< ArrayType * >( objDecl->type ) ) {
1685	if ( at->dimension ) return;
1686	if ( ListInit * init = dynamic_cast< ListInit * >( objDecl->init ) ) {
1687	at->dimension = new ConstantExpr( Constant::from_ulong( init->initializers.size() ) );
1688	}
1689	}
1690	}
1691
1692	void ArrayLength::previsit( ArrayType * type ) {
1693	if ( type->dimension ) {
1694	// need to resolve array dimensions early so that constructor code can correctly determine
1695	// if a type is a VLA (and hence whether its elements need to be constructed)
1696	ResolvExpr::findSingleExpression( type->dimension, Validate::SizeType->clone(), indexer );
1697
1698	// must re-evaluate whether a type is a VLA, now that more information is available
1699	// (e.g. the dimension may have been an enumerator, which was unknown prior to this step)
1700	type->isVarLen = ! InitTweak::isConstExpr( type->dimension );
1701	}
1702	}
1703
1704	struct LabelFinder {
1705	std::set< Label > & labels;
1706	LabelFinder( std::set< Label > & labels ) : labels( labels ) {}
1707	void previsit( Statement * stmt ) {
1708	for ( Label & l : stmt->labels ) {
1709	labels.insert( l );
1710	}
1711	}
1712	};
1713
1714	void LabelAddressFixer::premutate( FunctionDecl * funcDecl ) {
1715	GuardValue( labels );
1716	PassVisitor<LabelFinder> finder( labels );
1717	funcDecl->accept( finder );
1718	}
1719
1720	Expression * LabelAddressFixer::postmutate( AddressExpr * addrExpr ) {
1721	// convert &&label into label address
1722	if ( AddressExpr * inner = dynamic_cast< AddressExpr * >( addrExpr->arg ) ) {
1723	if ( NameExpr * nameExpr = dynamic_cast< NameExpr * >( inner->arg ) ) {
1724	if ( labels.count( nameExpr->name ) ) {
1725	Label name = nameExpr->name;
1726	delete addrExpr;
1727	return new LabelAddressExpr( name );
1728	}
1729	}
1730	}
1731	return addrExpr;
1732	}
1733
1734	namespace {
1735	/// Replaces enum types by int, and function/array types in function parameter and return
1736	/// lists by appropriate pointers
1737	/*
1738	struct EnumAndPointerDecay_new {
1739	const ast::EnumDecl * previsit( const ast::EnumDecl * enumDecl ) {
1740	// set the type of each member of the enumeration to be EnumConstant
1741	for ( unsigned i = 0; i < enumDecl->members.size(); ++i ) {
1742	// build new version of object with EnumConstant
1743	ast::ptr< ast::ObjectDecl > obj =
1744	enumDecl->members[i].strict_as< ast::ObjectDecl >();
1745	obj.get_and_mutate()->type =
1746	new ast::EnumInstType{ enumDecl->name, ast::CV::Const };
1747
1748	// set into decl
1749	ast::EnumDecl * mut = mutate( enumDecl );
1750	mut->members[i] = obj.get();
1751	enumDecl = mut;
1752	}
1753	return enumDecl;
1754	}
1755
1756	static const ast::FunctionType * fixFunctionList(
1757	const ast::FunctionType * func,
1758	std::vector< ast::ptr< ast::DeclWithType > > ast::FunctionType::* field,
1759	ast::ArgumentFlag isVarArgs = ast::FixedArgs
1760	) {
1761	const auto & dwts = func->* field;
1762	unsigned nvals = dwts.size();
1763	bool hasVoid = false;
1764	for ( unsigned i = 0; i < nvals; ++i ) {
1765	func = ast::mutate_field_index( func, field, i, fixFunction( dwts[i], hasVoid ) );
1766	}
1767
1768	// the only case in which "void" is valid is where it is the only one in the list
1769	if ( hasVoid && ( nvals > 1 \|\| isVarArgs ) ) {
1770	SemanticError(
1771	dwts.front()->location, func, "invalid type void in function type" );
1772	}
1773
1774	// one void is the only thing in the list, remove it
1775	if ( hasVoid ) {
1776	func = ast::mutate_field(
1777	func, field, std::vector< ast::ptr< ast::DeclWithType > >{} );
1778	}
1779
1780	return func;
1781	}
1782
1783	const ast::FunctionType * previsit( const ast::FunctionType * func ) {
1784	func = fixFunctionList( func, &ast::FunctionType::params, func->isVarArgs );
1785	return fixFunctionList( func, &ast::FunctionType::returns );
1786	}
1787	};
1788
1789	/// expand assertions from a trait instance, performing appropriate type variable substitutions
1790	void expandAssertions(
1791	const ast::TraitInstType * inst, std::vector< ast::ptr< ast::DeclWithType > > & out
1792	) {
1793	assertf( inst->base, "Trait instance not linked to base trait: %s", toCString( inst ) );
1794
1795	// build list of trait members, substituting trait decl parameters for instance parameters
1796	ast::TypeSubstitution sub{
1797	inst->base->params.begin(), inst->base->params.end(), inst->params.begin() };
1798	// deliberately take ast::ptr by-value to ensure this does not mutate inst->base
1799	for ( ast::ptr< ast::Decl > decl : inst->base->members ) {
1800	auto member = decl.strict_as< ast::DeclWithType >();
1801	sub.apply( member );
1802	out.emplace_back( member );
1803	}
1804	}
1805
1806	/// Associates forward declarations of aggregates with their definitions
1807	class LinkReferenceToTypes_new final
1808	: public ast::WithSymbolTable, public ast::WithGuards, public
1809	ast::WithVisitorRef<LinkReferenceToTypes_new>, public ast::WithShortCircuiting {
1810
1811	// these maps of uses of forward declarations of types need to have the actual type
1812	// declaration switched in * after * they have been traversed. To enable this in the
1813	// ast::Pass framework, any node that needs to be so mutated has mutate() called on it
1814	// before it is placed in the map, properly updating its parents in the usual traversal,
1815	// then can have the actual mutation applied later
1816	using ForwardEnumsType = std::unordered_multimap< std::string, ast::EnumInstType * >;
1817	using ForwardStructsType = std::unordered_multimap< std::string, ast::StructInstType * >;
1818	using ForwardUnionsType = std::unordered_multimap< std::string, ast::UnionInstType * >;
1819
1820	const CodeLocation & location;
1821	const ast::SymbolTable * localSymtab;
1822
1823	ForwardEnumsType forwardEnums;
1824	ForwardStructsType forwardStructs;
1825	ForwardUnionsType forwardUnions;
1826
1827	/// true if currently in a generic type body, so that type parameter instances can be
1828	/// renamed appropriately
1829	bool inGeneric = false;
1830
1831	public:
1832	/// contstruct using running symbol table
1833	LinkReferenceToTypes_new( const CodeLocation & loc )
1834	: location( loc ), localSymtab( &symtab ) {}
1835
1836	/// construct using provided symbol table
1837	LinkReferenceToTypes_new( const CodeLocation & loc, const ast::SymbolTable & syms )
1838	: location( loc ), localSymtab( &syms ) {}
1839
1840	const ast::Type * postvisit( const ast::TypeInstType * typeInst ) {
1841	// ensure generic parameter instances are renamed like the base type
1842	if ( inGeneric && typeInst->base ) {
1843	typeInst = ast::mutate_field(
1844	typeInst, &ast::TypeInstType::name, typeInst->base->name );
1845	}
1846
1847	if (
1848	auto typeDecl = dynamic_cast< const ast::TypeDecl * >(
1849	localSymtab->lookupType( typeInst->name ) )
1850	) {
1851	typeInst = ast::mutate_field( typeInst, &ast::TypeInstType::kind, typeDecl->kind );
1852	}
1853
1854	return typeInst;
1855	}
1856
1857	const ast::Type * postvisit( const ast::EnumInstType * inst ) {
1858	const ast::EnumDecl * decl = localSymtab->lookupEnum( inst->name );
1859	// not a semantic error if the enum is not found, just an implicit forward declaration
1860	if ( decl ) {
1861	inst = ast::mutate_field( inst, &ast::EnumInstType::base, decl );
1862	}
1863	if ( ! decl \|\| ! decl->body ) {
1864	// forward declaration
1865	auto mut = mutate( inst );
1866	forwardEnums.emplace( inst->name, mut );
1867	inst = mut;
1868	}
1869	return inst;
1870	}
1871
1872	void checkGenericParameters( const ast::BaseInstType * inst ) {
1873	for ( const ast::Expr * param : inst->params ) {
1874	if ( ! dynamic_cast< const ast::TypeExpr * >( param ) ) {
1875	SemanticError(
1876	location, inst, "Expression parameters for generic types are currently "
1877	"unsupported: " );
1878	}
1879	}
1880	}
1881
1882	const ast::StructInstType * postvisit( const ast::StructInstType * inst ) {
1883	const ast::StructDecl * decl = localSymtab->lookupStruct( inst->name );
1884	// not a semantic error if the struct is not found, just an implicit forward declaration
1885	if ( decl ) {
1886	inst = ast::mutate_field( inst, &ast::StructInstType::base, decl );
1887	}
1888	if ( ! decl \|\| ! decl->body ) {
1889	// forward declaration
1890	auto mut = mutate( inst );
1891	forwardStructs.emplace( inst->name, mut );
1892	inst = mut;
1893	}
1894	checkGenericParameters( inst );
1895	return inst;
1896	}
1897
1898	const ast::UnionInstType * postvisit( const ast::UnionInstType * inst ) {
1899	const ast::UnionDecl * decl = localSymtab->lookupUnion( inst->name );
1900	// not a semantic error if the struct is not found, just an implicit forward declaration
1901	if ( decl ) {
1902	inst = ast::mutate_field( inst, &ast::UnionInstType::base, decl );
1903	}
1904	if ( ! decl \|\| ! decl->body ) {
1905	// forward declaration
1906	auto mut = mutate( inst );
1907	forwardUnions.emplace( inst->name, mut );
1908	inst = mut;
1909	}
1910	checkGenericParameters( inst );
1911	return inst;
1912	}
1913
1914	const ast::Type * postvisit( const ast::TraitInstType * traitInst ) {
1915	// handle other traits
1916	const ast::TraitDecl * traitDecl = localSymtab->lookupTrait( traitInst->name );
1917	if ( ! traitDecl ) {
1918	SemanticError( location, "use of undeclared trait " + traitInst->name );
1919	}
1920	if ( traitDecl->params.size() != traitInst->params.size() ) {
1921	SemanticError( location, traitInst, "incorrect number of trait parameters: " );
1922	}
1923	traitInst = ast::mutate_field( traitInst, &ast::TraitInstType::base, traitDecl );
1924
1925	// need to carry over the "sized" status of each decl in the instance
1926	for ( unsigned i = 0; i < traitDecl->params.size(); ++i ) {
1927	auto expr = traitInst->params[i].as< ast::TypeExpr >();
1928	if ( ! expr ) {
1929	SemanticError(
1930	traitInst->params[i].get(), "Expression parameters for trait instances "
1931	"are currently unsupported: " );
1932	}
1933
1934	if ( auto inst = expr->type.as< ast::TypeInstType >() ) {
1935	if ( traitDecl->params[i]->sized && ! inst->base->sized ) {
1936	// traitInst = ast::mutate_field_index(
1937	// traitInst, &ast::TraitInstType::params, i,
1938	// ...
1939	// );
1940	ast::TraitInstType * mut = ast::mutate( traitInst );
1941	ast::chain_mutate( mut->params[i] )
1942	( &ast::TypeExpr::type )
1943	( &ast::TypeInstType::base )->sized = true;
1944	traitInst = mut;
1945	}
1946	}
1947	}
1948
1949	return traitInst;
1950	}
1951
1952	void previsit( const ast::QualifiedType * ) { visit_children = false; }
1953
1954	const ast::Type * postvisit( const ast::QualifiedType * qualType ) {
1955	// linking only makes sense for the "oldest ancestor" of the qualified type
1956	return ast::mutate_field(
1957	qualType, &ast::QualifiedType::parent, qualType->parent->accept( * visitor ) );
1958	}
1959
1960	const ast::Decl * postvisit( const ast::EnumDecl * enumDecl ) {
1961	// visit enum members first so that the types of self-referencing members are updated
1962	// properly
1963	if ( ! enumDecl->body ) return enumDecl;
1964
1965	// update forward declarations to point here
1966	auto fwds = forwardEnums.equal_range( enumDecl->name );
1967	if ( fwds.first != fwds.second ) {
1968	auto inst = fwds.first;
1969	do {
1970	// forward decl is stored * mutably * in map, can thus be updated
1971	inst->second->base = enumDecl;
1972	} while ( ++inst != fwds.second );
1973	forwardEnums.erase( fwds.first, fwds.second );
1974	}
1975
1976	// ensure that enumerator initializers are properly set
1977	for ( unsigned i = 0; i < enumDecl->members.size(); ++i ) {
1978	auto field = enumDecl->members[i].strict_as< ast::ObjectDecl >();
1979	if ( field->init ) {
1980	// need to resolve enumerator initializers early so that other passes that
1981	// determine if an expression is constexpr have appropriate information
1982	auto init = field->init.strict_as< ast::SingleInit >();
1983
1984	enumDecl = ast::mutate_field_index(
1985	enumDecl, &ast::EnumDecl::members, i,
1986	ast::mutate_field( field, &ast::ObjectDecl::init,
1987	ast::mutate_field( init, &ast::SingleInit::value,
1988	ResolvExpr::findSingleExpression(
1989	init->value, new ast::BasicType{ ast::BasicType::SignedInt },
1990	symtab ) ) ) );
1991	}
1992	}
1993
1994	return enumDecl;
1995	}
1996
1997	/// rename generic type parameters uniquely so that they do not conflict with user defined
1998	/// function forall parameters, e.g. the T in Box and the T in f, below
1999	/// forall(otype T)
2000	/// struct Box {
2001	/// T x;
2002	/// };
2003	/// forall(otype T)
2004	/// void f(Box(T) b) {
2005	/// ...
2006	/// }
2007	template< typename AggrDecl >
2008	const AggrDecl * renameGenericParams( const AggrDecl * aggr ) {
2009	GuardValue( inGeneric );
2010	inGeneric = ! aggr->params.empty();
2011
2012	for ( unsigned i = 0; i < aggr->params.size(); ++i ) {
2013	const ast::TypeDecl * td = aggr->params[i];
2014
2015	aggr = ast::mutate_field_index(
2016	aggr, &AggrDecl::params, i,
2017	ast::mutate_field( td, &ast::TypeDecl::name, "__" + td->name + "_generic_" ) );
2018	}
2019	return aggr;
2020	}
2021
2022	const ast::StructDecl * previsit( const ast::StructDecl * structDecl ) {
2023	return renameGenericParams( structDecl );
2024	}
2025
2026	void postvisit( const ast::StructDecl * structDecl ) {
2027	// visit struct members first so that the types of self-referencing members are
2028	// updated properly
2029	if ( ! structDecl->body ) return;
2030
2031	// update forward declarations to point here
2032	auto fwds = forwardStructs.equal_range( structDecl->name );
2033	if ( fwds.first != fwds.second ) {
2034	auto inst = fwds.first;
2035	do {
2036	// forward decl is stored * mutably * in map, can thus be updated
2037	inst->second->base = structDecl;
2038	} while ( ++inst != fwds.second );
2039	forwardStructs.erase( fwds.first, fwds.second );
2040	}
2041	}
2042
2043	const ast::UnionDecl * previsit( const ast::UnionDecl * unionDecl ) {
2044	return renameGenericParams( unionDecl );
2045	}
2046
2047	void postvisit( const ast::UnionDecl * unionDecl ) {
2048	// visit union members first so that the types of self-referencing members are updated
2049	// properly
2050	if ( ! unionDecl->body ) return;
2051
2052	// update forward declarations to point here
2053	auto fwds = forwardUnions.equal_range( unionDecl->name );
2054	if ( fwds.first != fwds.second ) {
2055	auto inst = fwds.first;
2056	do {
2057	// forward decl is stored * mutably * in map, can thus be updated
2058	inst->second->base = unionDecl;
2059	} while ( ++inst != fwds.second );
2060	forwardUnions.erase( fwds.first, fwds.second );
2061	}
2062	}
2063
2064	const ast::Decl * postvisit( const ast::TraitDecl * traitDecl ) {
2065	// set the "sized" status for the special "sized" trait
2066	if ( traitDecl->name == "sized" ) {
2067	assertf( traitDecl->params.size() == 1, "Built-in trait 'sized' has incorrect "
2068	"number of parameters: %zd", traitDecl->params.size() );
2069
2070	traitDecl = ast::mutate_field_index(
2071	traitDecl, &ast::TraitDecl::params, 0,
2072	ast::mutate_field(
2073	traitDecl->params.front().get(), &ast::TypeDecl::sized, true ) );
2074	}
2075
2076	// move assertions from type parameters into the body of the trait
2077	std::vector< ast::ptr< ast::DeclWithType > > added;
2078	for ( const ast::TypeDecl * td : traitDecl->params ) {
2079	for ( const ast::DeclWithType * assn : td->assertions ) {
2080	auto inst = dynamic_cast< const ast::TraitInstType * >( assn->get_type() );
2081	if ( inst ) {
2082	expandAssertions( inst, added );
2083	} else {
2084	added.emplace_back( assn );
2085	}
2086	}
2087	}
2088	if ( ! added.empty() ) {
2089	auto mut = mutate( traitDecl );
2090	for ( const ast::DeclWithType * decl : added ) {
2091	mut->members.emplace_back( decl );
2092	}
2093	traitDecl = mut;
2094	}
2095
2096	return traitDecl;
2097	}
2098	};
2099
2100	/// Replaces array and function types in forall lists by appropriate pointer type and assigns
2101	/// each object and function declaration a unique ID
2102	class ForallPointerDecay_new {
2103	const CodeLocation & location;
2104	public:
2105	ForallPointerDecay_new( const CodeLocation & loc ) : location( loc ) {}
2106
2107	const ast::ObjectDecl * previsit( const ast::ObjectDecl * obj ) {
2108	// ensure that operator names only apply to functions or function pointers
2109	if (
2110	CodeGen::isOperator( obj->name )
2111	&& ! dynamic_cast< const ast::FunctionType * >( obj->type->stripDeclarator() )
2112	) {
2113	SemanticError( obj->location, toCString( "operator ", obj->name.c_str(), " is not "
2114	"a function or function pointer." ) );
2115	}
2116
2117	// ensure object has unique ID
2118	if ( obj->uniqueId ) return obj;
2119	auto mut = mutate( obj );
2120	mut->fixUniqueId();
2121	return mut;
2122	}
2123
2124	const ast::FunctionDecl * previsit( const ast::FunctionDecl * func ) {
2125	// ensure function has unique ID
2126	if ( func->uniqueId ) return func;
2127	auto mut = mutate( func );
2128	mut->fixUniqueId();
2129	return mut;
2130	}
2131
2132	/// Fix up assertions -- flattens assertion lists, removing all trait instances
2133	template< typename node_t, typename parent_t >
2134	static const node_t * forallFixer(
2135	const CodeLocation & loc, const node_t * node,
2136	ast::FunctionType::ForallList parent_t::* forallField
2137	) {
2138	for ( unsigned i = 0; i < (node->* forallField).size(); ++i ) {
2139	const ast::TypeDecl * type = (node->* forallField)[i];
2140	if ( type->assertions.empty() ) continue;
2141
2142	std::vector< ast::ptr< ast::DeclWithType > > asserts;
2143	asserts.reserve( type->assertions.size() );
2144
2145	// expand trait instances into their members
2146	for ( const ast::DeclWithType * assn : type->assertions ) {
2147	auto traitInst =
2148	dynamic_cast< const ast::TraitInstType * >( assn->get_type() );
2149	if ( traitInst ) {
2150	// expand trait instance to all its members
2151	expandAssertions( traitInst, asserts );
2152	} else {
2153	// pass other assertions through
2154	asserts.emplace_back( assn );
2155	}
2156	}
2157
2158	// apply FixFunction to every assertion to check for invalid void type
2159	for ( ast::ptr< ast::DeclWithType > & assn : asserts ) {
2160	bool isVoid = false;
2161	assn = fixFunction( assn, isVoid );
2162	if ( isVoid ) {
2163	SemanticError( loc, node, "invalid type void in assertion of function " );
2164	}
2165	}
2166
2167	// place mutated assertion list in node
2168	auto mut = mutate( type );
2169	mut->assertions = move( asserts );
2170	node = ast::mutate_field_index( node, forallField, i, mut );
2171	}
2172	return node;
2173	}
2174
2175	const ast::FunctionType * previsit( const ast::FunctionType * ftype ) {
2176	return forallFixer( location, ftype, &ast::FunctionType::forall );
2177	}
2178
2179	const ast::StructDecl * previsit( const ast::StructDecl * aggrDecl ) {
2180	return forallFixer( aggrDecl->location, aggrDecl, &ast::StructDecl::params );
2181	}
2182
2183	const ast::UnionDecl * previsit( const ast::UnionDecl * aggrDecl ) {
2184	return forallFixer( aggrDecl->location, aggrDecl, &ast::UnionDecl::params );
2185	}
2186	};
2187	*/
2188	} // anonymous namespace
2189
2190	/*
2191	const ast::Type * validateType(
2192	const CodeLocation & loc, const ast::Type * type, const ast::SymbolTable & symtab ) {
2193	// ast::Pass< EnumAndPointerDecay_new > epc;
2194	ast::Pass< LinkReferenceToTypes_new > lrt{ loc, symtab };
2195	ast::Pass< ForallPointerDecay_new > fpd{ loc };
2196
2197	return type->accept( lrt )->accept( fpd );
2198	}
2199	*/
2200
2201	} // namespace SymTab
2202
2203	// Local Variables: //
2204	// tab-width: 4 //
2205	// mode: c++ //
2206	// compile-command: "make install" //
2207	// End: //

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