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source: src/SymTab/Validate.cc@ 1cb758f2

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Last change on this file since 1cb758f2 was 2ae171d8, checked in by Rob Schluntz <rschlunt@…>, 8 years ago
Minor clean up
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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 : Tus Aug 8 13:27:00 2017
13	// Update Count : 358
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 <utility> // for pair
47
48	#include "CodeGen/CodeGenerator.h" // for genName
49	#include "CodeGen/OperatorTable.h" // for isCtorDtor, isCtorDtorAssign
50	#include "Common/PassVisitor.h" // for PassVisitor, WithDeclsToAdd
51	#include "Common/ScopedMap.h" // for ScopedMap
52	#include "Common/SemanticError.h" // for SemanticError
53	#include "Common/UniqueName.h" // for UniqueName
54	#include "Common/utility.h" // for operator+, cloneAll, deleteAll
55	#include "Concurrency/Keywords.h" // for applyKeywords
56	#include "FixFunction.h" // for FixFunction
57	#include "Indexer.h" // for Indexer
58	#include "InitTweak/InitTweak.h" // for isCtorDtorAssign
59	#include "Parser/LinkageSpec.h" // for C
60	#include "ResolvExpr/typeops.h" // for typesCompatible
61	#include "SymTab/AddVisit.h" // for addVisit
62	#include "SymTab/Autogen.h" // for SizeType
63	#include "SynTree/Attribute.h" // for noAttributes, Attribute
64	#include "SynTree/Constant.h" // for Constant
65	#include "SynTree/Declaration.h" // for ObjectDecl, DeclarationWithType
66	#include "SynTree/Expression.h" // for CompoundLiteralExpr, Expressio...
67	#include "SynTree/Initializer.h" // for ListInit, Initializer
68	#include "SynTree/Label.h" // for operator==, Label
69	#include "SynTree/Mutator.h" // for Mutator
70	#include "SynTree/Type.h" // for Type, TypeInstType, EnumInstType
71	#include "SynTree/TypeSubstitution.h" // for TypeSubstitution
72	#include "SynTree/Visitor.h" // for Visitor
73
74	class CompoundStmt;
75	class ReturnStmt;
76	class SwitchStmt;
77
78
79	#define debugPrint( x ) if ( doDebug ) { std::cout << x; }
80
81	namespace SymTab {
82	class HoistStruct final : public Visitor {
83	template< typename Visitor >
84	friend void acceptAndAdd( std::list< Declaration * > &translationUnit, Visitor &visitor );
85	template< typename Visitor >
86	friend void addVisitStatementList( std::list< Statement* > &stmts, Visitor &visitor );
87	public:
88	/// Flattens nested struct types
89	static void hoistStruct( std::list< Declaration * > &translationUnit );
90
91	std::list< Declaration * > &get_declsToAdd() { return declsToAdd; }
92
93	virtual void visit( EnumInstType *enumInstType );
94	virtual void visit( StructInstType *structInstType );
95	virtual void visit( UnionInstType *unionInstType );
96	virtual void visit( StructDecl *aggregateDecl );
97	virtual void visit( UnionDecl *aggregateDecl );
98
99	virtual void visit( CompoundStmt *compoundStmt );
100	virtual void visit( SwitchStmt *switchStmt );
101	private:
102	HoistStruct();
103
104	template< typename AggDecl > void handleAggregate( AggDecl *aggregateDecl );
105
106	std::list< Declaration * > declsToAdd, declsToAddAfter;
107	bool inStruct;
108	};
109
110	/// Fix return types so that every function returns exactly one value
111	struct ReturnTypeFixer {
112	static void fix( std::list< Declaration * > &translationUnit );
113
114	void postvisit( FunctionDecl * functionDecl );
115	void postvisit( FunctionType * ftype );
116	};
117
118	/// Replaces enum types by int, and function or array types in function parameter and return lists by appropriate pointers.
119	struct EnumAndPointerDecay {
120	void previsit( EnumDecl *aggregateDecl );
121	void previsit( FunctionType *func );
122	};
123
124	/// Associates forward declarations of aggregates with their definitions
125	class LinkReferenceToTypes final : public Indexer {
126	typedef Indexer Parent;
127	public:
128	LinkReferenceToTypes( bool doDebug, const Indexer *indexer );
129	using Parent::visit;
130	void visit( EnumInstType *enumInst ) final;
131	void visit( StructInstType *structInst ) final;
132	void visit( UnionInstType *unionInst ) final;
133	void visit( TraitInstType *contextInst ) final;
134	void visit( EnumDecl *enumDecl ) final;
135	void visit( StructDecl *structDecl ) final;
136	void visit( UnionDecl *unionDecl ) final;
137	void visit( TypeInstType *typeInst ) final;
138	private:
139	const Indexer *indexer;
140
141	typedef std::map< std::string, std::list< EnumInstType * > > ForwardEnumsType;
142	typedef std::map< std::string, std::list< StructInstType * > > ForwardStructsType;
143	typedef std::map< std::string, std::list< UnionInstType * > > ForwardUnionsType;
144	ForwardEnumsType forwardEnums;
145	ForwardStructsType forwardStructs;
146	ForwardUnionsType forwardUnions;
147	};
148
149	/// Replaces array and function types in forall lists by appropriate pointer type and assigns each Object and Function declaration a unique ID.
150	class ForallPointerDecay final : public Indexer {
151	typedef Indexer Parent;
152	public:
153	using Parent::visit;
154	ForallPointerDecay( const Indexer *indexer );
155
156	virtual void visit( ObjectDecl *object ) override;
157	virtual void visit( FunctionDecl *func ) override;
158
159	const Indexer *indexer;
160	};
161
162	struct ReturnChecker : public WithGuards {
163	/// Checks that return statements return nothing if their return type is void
164	/// and return something if the return type is non-void.
165	static void checkFunctionReturns( std::list< Declaration * > & translationUnit );
166
167	void previsit( FunctionDecl * functionDecl );
168	void previsit( ReturnStmt * returnStmt );
169
170	typedef std::list< DeclarationWithType * > ReturnVals;
171	ReturnVals returnVals;
172	};
173
174	class EliminateTypedef : public Mutator {
175	public:
176	EliminateTypedef() : scopeLevel( 0 ) {}
177	/// Replaces typedefs by forward declarations
178	static void eliminateTypedef( std::list< Declaration * > &translationUnit );
179	private:
180	virtual Declaration mutate( TypedefDecl typeDecl );
181	virtual TypeDecl mutate( TypeDecl typeDecl );
182	virtual DeclarationWithType mutate( FunctionDecl funcDecl );
183	virtual DeclarationWithType mutate( ObjectDecl objDecl );
184	virtual CompoundStmt mutate( CompoundStmt compoundStmt );
185	virtual Type mutate( TypeInstType aggregateUseType );
186	virtual Expression mutate( CastExpr castExpr );
187
188	virtual Declaration mutate( StructDecl structDecl );
189	virtual Declaration mutate( UnionDecl unionDecl );
190	virtual Declaration mutate( EnumDecl enumDecl );
191	virtual Declaration mutate( TraitDecl contextDecl );
192
193	template<typename AggDecl>
194	AggDecl handleAggregate( AggDecl aggDecl );
195
196	template<typename AggDecl>
197	void addImplicitTypedef( AggDecl * aggDecl );
198
199	typedef std::unique_ptr<TypedefDecl> TypedefDeclPtr;
200	typedef ScopedMap< std::string, std::pair< TypedefDeclPtr, int > > TypedefMap;
201	typedef std::map< std::string, TypeDecl * > TypeDeclMap;
202	TypedefMap typedefNames;
203	TypeDeclMap typedeclNames;
204	int scopeLevel;
205	};
206
207	struct VerifyCtorDtorAssign {
208	/// ensure that constructors, destructors, and assignment have at least one
209	/// parameter, the first of which must be a pointer, and that ctor/dtors have no
210	/// return values.
211	static void verify( std::list< Declaration * > &translationUnit );
212
213	void previsit( FunctionDecl *funcDecl );
214	};
215
216	/// ensure that generic types have the correct number of type arguments
217	struct ValidateGenericParameters {
218	void previsit( StructInstType * inst );
219	void previsit( UnionInstType * inst );
220	};
221
222	struct ArrayLength {
223	/// for array types without an explicit length, compute the length and store it so that it
224	/// is known to the rest of the phases. For example,
225	/// int x[] = { 1, 2, 3 };
226	/// int y[][2] = { { 1, 2, 3 }, { 1, 2, 3 } };
227	/// here x and y are known at compile-time to have length 3, so change this into
228	/// int x[3] = { 1, 2, 3 };
229	/// int y[3][2] = { { 1, 2, 3 }, { 1, 2, 3 } };
230	static void computeLength( std::list< Declaration * > & translationUnit );
231
232	void previsit( ObjectDecl * objDecl );
233	};
234
235	struct CompoundLiteral final : public WithDeclsToAdd, public WithVisitorRef<CompoundLiteral> {
236	Type::StorageClasses storageClasses;
237
238	void premutate( ObjectDecl *objectDecl );
239	Expression * postmutate( CompoundLiteralExpr *compLitExpr );
240	};
241
242
243	FunctionDecl * dereferenceOperator = nullptr;
244	struct FindSpecialDeclarations final {
245	void previsit( FunctionDecl * funcDecl );
246	};
247
248	void validate( std::list< Declaration * > &translationUnit, bool doDebug ) {
249	PassVisitor<EnumAndPointerDecay> epc;
250	LinkReferenceToTypes lrt( doDebug, 0 );
251	ForallPointerDecay fpd( 0 );
252	PassVisitor<CompoundLiteral> compoundliteral;
253	PassVisitor<ValidateGenericParameters> genericParams;
254	PassVisitor<FindSpecialDeclarations> finder;
255
256	EliminateTypedef::eliminateTypedef( translationUnit );
257	HoistStruct::hoistStruct( translationUnit ); // must happen after EliminateTypedef, so that aggregate typedefs occur in the correct order
258	ReturnTypeFixer::fix( translationUnit ); // must happen before autogen
259	acceptAll( translationUnit, lrt ); // must happen before autogen, because sized flag needs to propagate to generated functions
260	acceptAll( translationUnit, genericParams ); // check as early as possible - can't happen before LinkReferenceToTypes
261	acceptAll( translationUnit, epc ); // must happen before VerifyCtorDtorAssign, because void return objects should not exist
262	VerifyCtorDtorAssign::verify( translationUnit ); // must happen before autogen, because autogen examines existing ctor/dtors
263	Concurrency::applyKeywords( translationUnit );
264	autogenerateRoutines( translationUnit ); // moved up, used to be below compoundLiteral - currently needs EnumAndPointerDecay
265	Concurrency::implementMutexFuncs( translationUnit );
266	Concurrency::implementThreadStarter( translationUnit );
267	ReturnChecker::checkFunctionReturns( translationUnit );
268	mutateAll( translationUnit, compoundliteral );
269	acceptAll( translationUnit, fpd );
270	ArrayLength::computeLength( translationUnit );
271	acceptAll( translationUnit, finder );
272	}
273
274	void validateType( Type type, const Indexer indexer ) {
275	PassVisitor<EnumAndPointerDecay> epc;
276	LinkReferenceToTypes lrt( false, indexer );
277	ForallPointerDecay fpd( indexer );
278	type->accept( epc );
279	type->accept( lrt );
280	type->accept( fpd );
281	}
282
283	void HoistStruct::hoistStruct( std::list< Declaration * > &translationUnit ) {
284	HoistStruct hoister;
285	acceptAndAdd( translationUnit, hoister );
286	}
287
288	HoistStruct::HoistStruct() : inStruct( false ) {
289	}
290
291	void filter( std::list< Declaration * > &declList, bool (pred)( Declaration ), bool doDelete ) {
292	std::list< Declaration * >::iterator i = declList.begin();
293	while ( i != declList.end() ) {
294	std::list< Declaration * >::iterator next = i;
295	++next;
296	if ( pred( *i ) ) {
297	if ( doDelete ) {
298	delete *i;
299	} // if
300	declList.erase( i );
301	} // if
302	i = next;
303	} // while
304	}
305
306	bool isStructOrUnion( Declaration *decl ) {
307	return dynamic_cast< StructDecl * >( decl ) \|\| dynamic_cast< UnionDecl * >( decl );
308	}
309
310	template< typename AggDecl >
311	void HoistStruct::handleAggregate( AggDecl *aggregateDecl ) {
312	if ( inStruct ) {
313	// Add elements in stack order corresponding to nesting structure.
314	declsToAdd.push_front( aggregateDecl );
315	Visitor::visit( aggregateDecl );
316	} else {
317	inStruct = true;
318	Visitor::visit( aggregateDecl );
319	inStruct = false;
320	} // if
321	// Always remove the hoisted aggregate from the inner structure.
322	filter( aggregateDecl->get_members(), isStructOrUnion, false );
323	}
324
325	void HoistStruct::visit( EnumInstType *structInstType ) {
326	if ( structInstType->get_baseEnum() ) {
327	declsToAdd.push_front( structInstType->get_baseEnum() );
328	}
329	}
330
331	void HoistStruct::visit( StructInstType *structInstType ) {
332	if ( structInstType->get_baseStruct() ) {
333	declsToAdd.push_front( structInstType->get_baseStruct() );
334	}
335	}
336
337	void HoistStruct::visit( UnionInstType *structInstType ) {
338	if ( structInstType->get_baseUnion() ) {
339	declsToAdd.push_front( structInstType->get_baseUnion() );
340	}
341	}
342
343	void HoistStruct::visit( StructDecl *aggregateDecl ) {
344	handleAggregate( aggregateDecl );
345	}
346
347	void HoistStruct::visit( UnionDecl *aggregateDecl ) {
348	handleAggregate( aggregateDecl );
349	}
350
351	void HoistStruct::visit( CompoundStmt *compoundStmt ) {
352	addVisit( compoundStmt, *this );
353	}
354
355	void HoistStruct::visit( SwitchStmt *switchStmt ) {
356	addVisit( switchStmt, *this );
357	}
358
359	void EnumAndPointerDecay::previsit( EnumDecl *enumDecl ) {
360	// Set the type of each member of the enumeration to be EnumConstant
361	for ( std::list< Declaration * >::iterator i = enumDecl->get_members().begin(); i != enumDecl->get_members().end(); ++i ) {
362	ObjectDecl * obj = dynamic_cast< ObjectDecl * >( *i );
363	assert( obj );
364	obj->set_type( new EnumInstType( Type::Qualifiers( Type::Const ), enumDecl->get_name() ) );
365	} // for
366	}
367
368	namespace {
369	template< typename DWTList >
370	void fixFunctionList( DWTList & dwts, FunctionType * func ) {
371	// the only case in which "void" is valid is where it is the only one in the list; then it should be removed
372	// entirely. other fix ups are handled by the FixFunction class
373	typedef typename DWTList::iterator DWTIterator;
374	DWTIterator begin( dwts.begin() ), end( dwts.end() );
375	if ( begin == end ) return;
376	FixFunction fixer;
377	DWTIterator i = begin;
378	i = (i)->acceptMutator( fixer );
379	if ( fixer.get_isVoid() ) {
380	DWTIterator j = i;
381	++i;
382	delete *j;
383	dwts.erase( j );
384	if ( i != end ) {
385	throw SemanticError( "invalid type void in function type ", func );
386	} // if
387	} else {
388	++i;
389	for ( ; i != end; ++i ) {
390	FixFunction fixer;
391	i = (i)->acceptMutator( fixer );
392	if ( fixer.get_isVoid() ) {
393	throw SemanticError( "invalid type void in function type ", func );
394	} // if
395	} // for
396	} // if
397	}
398	}
399
400	void EnumAndPointerDecay::previsit( FunctionType *func ) {
401	// Fix up parameters and return types
402	fixFunctionList( func->get_parameters(), func );
403	fixFunctionList( func->get_returnVals(), func );
404	}
405
406	LinkReferenceToTypes::LinkReferenceToTypes( bool doDebug, const Indexer *other_indexer ) : Indexer( doDebug ) {
407	if ( other_indexer ) {
408	indexer = other_indexer;
409	} else {
410	indexer = this;
411	} // if
412	}
413
414	void LinkReferenceToTypes::visit( EnumInstType *enumInst ) {
415	Parent::visit( enumInst );
416	EnumDecl *st = indexer->lookupEnum( enumInst->get_name() );
417	// it's not a semantic error if the enum is not found, just an implicit forward declaration
418	if ( st ) {
419	//assert( ! enumInst->get_baseEnum() \|\| enumInst->get_baseEnum()->get_members().empty() \|\| ! st->get_members().empty() );
420	enumInst->set_baseEnum( st );
421	} // if
422	if ( ! st \|\| st->get_members().empty() ) {
423	// use of forward declaration
424	forwardEnums[ enumInst->get_name() ].push_back( enumInst );
425	} // if
426	}
427
428	void LinkReferenceToTypes::visit( StructInstType *structInst ) {
429	Parent::visit( structInst );
430	StructDecl *st = indexer->lookupStruct( structInst->get_name() );
431	// it's not a semantic error if the struct is not found, just an implicit forward declaration
432	if ( st ) {
433	//assert( ! structInst->get_baseStruct() \|\| structInst->get_baseStruct()->get_members().empty() \|\| ! st->get_members().empty() );
434	structInst->set_baseStruct( st );
435	} // if
436	if ( ! st \|\| st->get_members().empty() ) {
437	// use of forward declaration
438	forwardStructs[ structInst->get_name() ].push_back( structInst );
439	} // if
440	}
441
442	void LinkReferenceToTypes::visit( UnionInstType *unionInst ) {
443	Parent::visit( unionInst );
444	UnionDecl *un = indexer->lookupUnion( unionInst->get_name() );
445	// it's not a semantic error if the union is not found, just an implicit forward declaration
446	if ( un ) {
447	unionInst->set_baseUnion( un );
448	} // if
449	if ( ! un \|\| un->get_members().empty() ) {
450	// use of forward declaration
451	forwardUnions[ unionInst->get_name() ].push_back( unionInst );
452	} // if
453	}
454
455	void LinkReferenceToTypes::visit( TraitInstType *traitInst ) {
456	Parent::visit( traitInst );
457	if ( traitInst->get_name() == "sized" ) {
458	// "sized" is a special trait with no members - just flick the sized status on for the type variable
459	if ( traitInst->get_parameters().size() != 1 ) {
460	throw SemanticError( "incorrect number of trait parameters: ", traitInst );
461	}
462	TypeExpr * param = safe_dynamic_cast< TypeExpr * > ( traitInst->get_parameters().front() );
463	TypeInstType * inst = safe_dynamic_cast< TypeInstType * > ( param->get_type() );
464	TypeDecl * decl = inst->get_baseType();
465	decl->set_sized( true );
466	// since "sized" is special, the next few steps don't apply
467	return;
468	}
469
470	// handle other traits
471	TraitDecl *traitDecl = indexer->lookupTrait( traitInst->get_name() );
472	if ( ! traitDecl ) {
473	throw SemanticError( "use of undeclared trait " + traitInst->get_name() );
474	} // if
475	if ( traitDecl->get_parameters().size() != traitInst->get_parameters().size() ) {
476	throw SemanticError( "incorrect number of trait parameters: ", traitInst );
477	} // if
478
479	for ( TypeDecl * td : traitDecl->get_parameters() ) {
480	for ( DeclarationWithType * assert : td->get_assertions() ) {
481	traitInst->get_members().push_back( assert->clone() );
482	} // for
483	} // for
484
485	// need to clone members of the trait for ownership purposes
486	std::list< Declaration * > members;
487	std::transform( traitDecl->get_members().begin(), traitDecl->get_members().end(), back_inserter( members ), [](Declaration * dwt) { return dwt->clone(); } );
488
489	applySubstitution( traitDecl->get_parameters().begin(), traitDecl->get_parameters().end(), traitInst->get_parameters().begin(), members.begin(), members.end(), back_inserter( traitInst->get_members() ) );
490
491	// need to carry over the 'sized' status of each decl in the instance
492	for ( auto p : group_iterate( traitDecl->get_parameters(), traitInst->get_parameters() ) ) {
493	TypeExpr * expr = safe_dynamic_cast< TypeExpr * >( std::get<1>(p) );
494	if ( TypeInstType * inst = dynamic_cast< TypeInstType * >( expr->get_type() ) ) {
495	TypeDecl * formalDecl = std::get<0>(p);
496	TypeDecl * instDecl = inst->get_baseType();
497	if ( formalDecl->get_sized() ) instDecl->set_sized( true );
498	}
499	}
500	}
501
502	void LinkReferenceToTypes::visit( EnumDecl *enumDecl ) {
503	// visit enum members first so that the types of self-referencing members are updated properly
504	Parent::visit( enumDecl );
505	if ( ! enumDecl->get_members().empty() ) {
506	ForwardEnumsType::iterator fwds = forwardEnums.find( enumDecl->get_name() );
507	if ( fwds != forwardEnums.end() ) {
508	for ( std::list< EnumInstType * >::iterator inst = fwds->second.begin(); inst != fwds->second.end(); ++inst ) {
509	(*inst )->set_baseEnum( enumDecl );
510	} // for
511	forwardEnums.erase( fwds );
512	} // if
513	} // if
514	}
515
516	void LinkReferenceToTypes::visit( StructDecl *structDecl ) {
517	// visit struct members first so that the types of self-referencing members are updated properly
518	// xxx - need to ensure that type parameters match up between forward declarations and definition (most importantly, number of type parameters and and their defaults)
519	Parent::visit( structDecl );
520	if ( ! structDecl->get_members().empty() ) {
521	ForwardStructsType::iterator fwds = forwardStructs.find( structDecl->get_name() );
522	if ( fwds != forwardStructs.end() ) {
523	for ( std::list< StructInstType * >::iterator inst = fwds->second.begin(); inst != fwds->second.end(); ++inst ) {
524	(*inst )->set_baseStruct( structDecl );
525	} // for
526	forwardStructs.erase( fwds );
527	} // if
528	} // if
529	}
530
531	void LinkReferenceToTypes::visit( UnionDecl *unionDecl ) {
532	Parent::visit( unionDecl );
533	if ( ! unionDecl->get_members().empty() ) {
534	ForwardUnionsType::iterator fwds = forwardUnions.find( unionDecl->get_name() );
535	if ( fwds != forwardUnions.end() ) {
536	for ( std::list< UnionInstType * >::iterator inst = fwds->second.begin(); inst != fwds->second.end(); ++inst ) {
537	(*inst )->set_baseUnion( unionDecl );
538	} // for
539	forwardUnions.erase( fwds );
540	} // if
541	} // if
542	}
543
544	void LinkReferenceToTypes::visit( TypeInstType *typeInst ) {
545	if ( NamedTypeDecl *namedTypeDecl = lookupType( typeInst->get_name() ) ) {
546	if ( TypeDecl typeDecl = dynamic_cast< TypeDecl >( namedTypeDecl ) ) {
547	typeInst->set_isFtype( typeDecl->get_kind() == TypeDecl::Ftype );
548	} // if
549	} // if
550	}
551
552	ForallPointerDecay::ForallPointerDecay( const Indexer *other_indexer ) : Indexer( false ) {
553	if ( other_indexer ) {
554	indexer = other_indexer;
555	} else {
556	indexer = this;
557	} // if
558	}
559
560	/// Fix up assertions - flattens assertion lists, removing all trait instances
561	void forallFixer( Type * func ) {
562	for ( TypeDecl * type : func->get_forall() ) {
563	std::list< DeclarationWithType * > toBeDone, nextRound;
564	toBeDone.splice( toBeDone.end(), type->get_assertions() );
565	while ( ! toBeDone.empty() ) {
566	for ( DeclarationWithType * assertion : toBeDone ) {
567	if ( TraitInstType traitInst = dynamic_cast< TraitInstType >( assertion->get_type() ) ) {
568	// expand trait instance into all of its members
569	for ( Declaration * member : traitInst->get_members() ) {
570	DeclarationWithType dwt = safe_dynamic_cast< DeclarationWithType >( member );
571	nextRound.push_back( dwt->clone() );
572	}
573	delete traitInst;
574	} else {
575	// pass assertion through
576	FixFunction fixer;
577	assertion = assertion->acceptMutator( fixer );
578	if ( fixer.get_isVoid() ) {
579	throw SemanticError( "invalid type void in assertion of function ", func );
580	}
581	type->get_assertions().push_back( assertion );
582	} // if
583	} // for
584	toBeDone.clear();
585	toBeDone.splice( toBeDone.end(), nextRound );
586	} // while
587	} // for
588	}
589
590	void ForallPointerDecay::visit( ObjectDecl *object ) {
591	forallFixer( object->get_type() );
592	if ( PointerType pointer = dynamic_cast< PointerType >( object->get_type() ) ) {
593	forallFixer( pointer->get_base() );
594	} // if
595	Parent::visit( object );
596	object->fixUniqueId();
597	}
598
599	void ForallPointerDecay::visit( FunctionDecl *func ) {
600	forallFixer( func->get_type() );
601	Parent::visit( func );
602	func->fixUniqueId();
603	}
604
605	void ReturnChecker::checkFunctionReturns( std::list< Declaration * > & translationUnit ) {
606	PassVisitor<ReturnChecker> checker;
607	acceptAll( translationUnit, checker );
608	}
609
610	void ReturnChecker::previsit( FunctionDecl * functionDecl ) {
611	GuardValue( returnVals );
612	returnVals = functionDecl->get_functionType()->get_returnVals();
613	}
614
615	void ReturnChecker::previsit( ReturnStmt * returnStmt ) {
616	// Previously this also checked for the existence of an expr paired with no return values on
617	// the function return type. This is incorrect, since you can have an expression attached to
618	// a return statement in a void-returning function in C. The expression is treated as if it
619	// were cast to void.
620	if ( ! returnStmt->get_expr() && returnVals.size() != 0 ) {
621	throw SemanticError( "Non-void function returns no values: " , returnStmt );
622	}
623	}
624
625
626	bool isTypedef( Declaration *decl ) {
627	return dynamic_cast< TypedefDecl * >( decl );
628	}
629
630	void EliminateTypedef::eliminateTypedef( std::list< Declaration * > &translationUnit ) {
631	EliminateTypedef eliminator;
632	mutateAll( translationUnit, eliminator );
633	if ( eliminator.typedefNames.count( "size_t" ) ) {
634	// grab and remember declaration of size_t
635	SizeType = eliminator.typedefNames["size_t"].first->get_base()->clone();
636	} else {
637	// xxx - missing global typedef for size_t - default to long unsigned int, even though that may be wrong
638	// eventually should have a warning for this case.
639	SizeType = new BasicType( Type::Qualifiers(), BasicType::LongUnsignedInt );
640	}
641	filter( translationUnit, isTypedef, true );
642
643	}
644
645	Type EliminateTypedef::mutate( TypeInstType typeInst ) {
646	// instances of typedef types will come here. If it is an instance
647	// of a typdef type, link the instance to its actual type.
648	TypedefMap::const_iterator def = typedefNames.find( typeInst->get_name() );
649	if ( def != typedefNames.end() ) {
650	Type *ret = def->second.first->get_base()->clone();
651	ret->get_qualifiers() \|= typeInst->get_qualifiers();
652	// place instance parameters on the typedef'd type
653	if ( ! typeInst->get_parameters().empty() ) {
654	ReferenceToType rtt = dynamic_cast<ReferenceToType>(ret);
655	if ( ! rtt ) {
656	throw SemanticError("cannot apply type parameters to base type of " + typeInst->get_name());
657	}
658	rtt->get_parameters().clear();
659	cloneAll( typeInst->get_parameters(), rtt->get_parameters() );
660	mutateAll( rtt->get_parameters(), *this ); // recursively fix typedefs on parameters
661	} // if
662	delete typeInst;
663	return ret;
664	} else {
665	TypeDeclMap::const_iterator base = typedeclNames.find( typeInst->get_name() );
666	assertf( base != typedeclNames.end(), "Can't find typedecl name %s", typeInst->get_name().c_str() );
667	typeInst->set_baseType( base->second );
668	} // if
669	return typeInst;
670	}
671
672	Declaration EliminateTypedef::mutate( TypedefDecl tyDecl ) {
673	Declaration *ret = Mutator::mutate( tyDecl );
674
675	if ( typedefNames.count( tyDecl->get_name() ) == 1 && typedefNames[ tyDecl->get_name() ].second == scopeLevel ) {
676	// typedef to the same name from the same scope
677	// must be from the same type
678
679	Type * t1 = tyDecl->get_base();
680	Type * t2 = typedefNames[ tyDecl->get_name() ].first->get_base();
681	if ( ! ResolvExpr::typesCompatible( t1, t2, Indexer() ) ) {
682	throw SemanticError( "cannot redefine typedef: " + tyDecl->get_name() );
683	}
684	} else {
685	typedefNames[ tyDecl->get_name() ] = std::make_pair( TypedefDeclPtr( tyDecl ), scopeLevel );
686	} // if
687
688	// When a typedef is a forward declaration:
689	// typedef struct screen SCREEN;
690	// the declaration portion must be retained:
691	// struct screen;
692	// because the expansion of the typedef is:
693	// void rtn( SCREEN p ) => void rtn( struct screen p )
694	// hence the type-name "screen" must be defined.
695	// Note, qualifiers on the typedef are superfluous for the forward declaration.
696
697	Type *designatorType = tyDecl->get_base()->stripDeclarator();
698	if ( StructInstType aggDecl = dynamic_cast< StructInstType >( designatorType ) ) {
699	return new StructDecl( aggDecl->get_name(), DeclarationNode::Struct, noAttributes, tyDecl->get_linkage() );
700	} else if ( UnionInstType aggDecl = dynamic_cast< UnionInstType >( designatorType ) ) {
701	return new UnionDecl( aggDecl->get_name(), noAttributes, tyDecl->get_linkage() );
702	} else if ( EnumInstType enumDecl = dynamic_cast< EnumInstType >( designatorType ) ) {
703	return new EnumDecl( enumDecl->get_name(), noAttributes, tyDecl->get_linkage() );
704	} else {
705	return ret->clone();
706	} // if
707	}
708
709	TypeDecl EliminateTypedef::mutate( TypeDecl typeDecl ) {
710	TypedefMap::iterator i = typedefNames.find( typeDecl->get_name() );
711	if ( i != typedefNames.end() ) {
712	typedefNames.erase( i ) ;
713	} // if
714
715	typedeclNames[ typeDecl->get_name() ] = typeDecl;
716	return Mutator::mutate( typeDecl );
717	}
718
719	DeclarationWithType EliminateTypedef::mutate( FunctionDecl funcDecl ) {
720	typedefNames.beginScope();
721	DeclarationWithType *ret = Mutator::mutate( funcDecl );
722	typedefNames.endScope();
723	return ret;
724	}
725
726	DeclarationWithType EliminateTypedef::mutate( ObjectDecl objDecl ) {
727	typedefNames.beginScope();
728	DeclarationWithType *ret = Mutator::mutate( objDecl );
729	typedefNames.endScope();
730
731	if ( FunctionType funtype = dynamic_cast<FunctionType >( ret->get_type() ) ) { // function type?
732	// replace the current object declaration with a function declaration
733	FunctionDecl * newDecl = new FunctionDecl( ret->get_name(), ret->get_storageClasses(), ret->get_linkage(), funtype, 0, objDecl->get_attributes(), ret->get_funcSpec() );
734	objDecl->get_attributes().clear();
735	objDecl->set_type( nullptr );
736	delete objDecl;
737	return newDecl;
738	} // if
739	return ret;
740	}
741
742	Expression EliminateTypedef::mutate( CastExpr castExpr ) {
743	typedefNames.beginScope();
744	Expression *ret = Mutator::mutate( castExpr );
745	typedefNames.endScope();
746	return ret;
747	}
748
749	CompoundStmt EliminateTypedef::mutate( CompoundStmt compoundStmt ) {
750	typedefNames.beginScope();
751	scopeLevel += 1;
752	CompoundStmt *ret = Mutator::mutate( compoundStmt );
753	scopeLevel -= 1;
754	std::list< Statement * >::iterator i = compoundStmt->get_kids().begin();
755	while ( i != compoundStmt->get_kids().end() ) {
756	std::list< Statement * >::iterator next = i+1;
757	if ( DeclStmt declStmt = dynamic_cast< DeclStmt >( *i ) ) {
758	if ( dynamic_cast< TypedefDecl * >( declStmt->get_decl() ) ) {
759	delete *i;
760	compoundStmt->get_kids().erase( i );
761	} // if
762	} // if
763	i = next;
764	} // while
765	typedefNames.endScope();
766	return ret;
767	}
768
769	// there may be typedefs nested within aggregates. in order for everything to work properly, these should be removed
770	// as well
771	template<typename AggDecl>
772	AggDecl EliminateTypedef::handleAggregate( AggDecl aggDecl ) {
773	std::list<Declaration *>::iterator it = aggDecl->get_members().begin();
774	for ( ; it != aggDecl->get_members().end(); ) {
775	std::list< Declaration * >::iterator next = it+1;
776	if ( dynamic_cast< TypedefDecl * >( *it ) ) {
777	delete *it;
778	aggDecl->get_members().erase( it );
779	} // if
780	it = next;
781	}
782	return aggDecl;
783	}
784
785	template<typename AggDecl>
786	void EliminateTypedef::addImplicitTypedef( AggDecl * aggDecl ) {
787	if ( typedefNames.count( aggDecl->get_name() ) == 0 ) {
788	Type *type = nullptr;
789	if ( StructDecl * newDeclStructDecl = dynamic_cast< StructDecl * >( aggDecl ) ) {
790	type = new StructInstType( Type::Qualifiers(), newDeclStructDecl->get_name() );
791	} else if ( UnionDecl * newDeclUnionDecl = dynamic_cast< UnionDecl * >( aggDecl ) ) {
792	type = new UnionInstType( Type::Qualifiers(), newDeclUnionDecl->get_name() );
793	} else if ( EnumDecl * newDeclEnumDecl = dynamic_cast< EnumDecl * >( aggDecl ) ) {
794	type = new EnumInstType( Type::Qualifiers(), newDeclEnumDecl->get_name() );
795	} // if
796	TypedefDeclPtr tyDecl( new TypedefDecl( aggDecl->get_name(), Type::StorageClasses(), type, aggDecl->get_linkage() ) );
797	typedefNames[ aggDecl->get_name() ] = std::make_pair( std::move( tyDecl ), scopeLevel );
798	} // if
799	}
800
801	Declaration EliminateTypedef::mutate( StructDecl structDecl ) {
802	addImplicitTypedef( structDecl );
803	Mutator::mutate( structDecl );
804	return handleAggregate( structDecl );
805	}
806
807	Declaration EliminateTypedef::mutate( UnionDecl unionDecl ) {
808	addImplicitTypedef( unionDecl );
809	Mutator::mutate( unionDecl );
810	return handleAggregate( unionDecl );
811	}
812
813	Declaration EliminateTypedef::mutate( EnumDecl enumDecl ) {
814	addImplicitTypedef( enumDecl );
815	Mutator::mutate( enumDecl );
816	return handleAggregate( enumDecl );
817	}
818
819	Declaration EliminateTypedef::mutate( TraitDecl contextDecl ) {
820	Mutator::mutate( contextDecl );
821	return handleAggregate( contextDecl );
822	}
823
824	void VerifyCtorDtorAssign::verify( std::list< Declaration * > & translationUnit ) {
825	PassVisitor<VerifyCtorDtorAssign> verifier;
826	acceptAll( translationUnit, verifier );
827	}
828
829	void VerifyCtorDtorAssign::previsit( FunctionDecl * funcDecl ) {
830	FunctionType * funcType = funcDecl->get_functionType();
831	std::list< DeclarationWithType * > &returnVals = funcType->get_returnVals();
832	std::list< DeclarationWithType * > &params = funcType->get_parameters();
833
834	if ( CodeGen::isCtorDtorAssign( funcDecl->get_name() ) ) { // TODO: also check /=, etc.
835	if ( params.size() == 0 ) {
836	throw SemanticError( "Constructors, destructors, and assignment functions require at least one parameter ", funcDecl );
837	}
838	ReferenceType * refType = dynamic_cast< ReferenceType * >( params.front()->get_type() );
839	if ( ! refType ) {
840	throw SemanticError( "First parameter of a constructor, destructor, or assignment function must be a reference ", funcDecl );
841	}
842	if ( CodeGen::isCtorDtor( funcDecl->get_name() ) && returnVals.size() != 0 ) {
843	throw SemanticError( "Constructors and destructors cannot have explicit return values ", funcDecl );
844	}
845	}
846	}
847
848	template< typename Aggr >
849	void validateGeneric( Aggr * inst ) {
850	std::list< TypeDecl * > * params = inst->get_baseParameters();
851	if ( params ) {
852	std::list< Expression * > & args = inst->get_parameters();
853
854	// insert defaults arguments when a type argument is missing (currently only supports missing arguments at the end of the list).
855	// A substitution is used to ensure that defaults are replaced correctly, e.g.,
856	// forall(otype T, otype alloc = heap_allocator(T)) struct vector;
857	// vector(int) v;
858	// after insertion of default values becomes
859	// vector(int, heap_allocator(T))
860	// and the substitution is built with T=int so that after substitution, the result is
861	// vector(int, heap_allocator(int))
862	TypeSubstitution sub;
863	auto paramIter = params->begin();
864	for ( size_t i = 0; paramIter != params->end(); ++paramIter, ++i ) {
865	if ( i < args.size() ) {
866	TypeExpr * expr = safe_dynamic_cast< TypeExpr * >( *std::next( args.begin(), i ) );
867	sub.add( (*paramIter)->get_name(), expr->get_type()->clone() );
868	} else if ( i == args.size() ) {
869	Type * defaultType = (*paramIter)->get_init();
870	if ( defaultType ) {
871	args.push_back( new TypeExpr( defaultType->clone() ) );
872	sub.add( (*paramIter)->get_name(), defaultType->clone() );
873	}
874	}
875	}
876
877	sub.apply( inst );
878	if ( args.size() < params->size() ) throw SemanticError( "Too few type arguments in generic type ", inst );
879	if ( args.size() > params->size() ) throw SemanticError( "Too many type arguments in generic type ", inst );
880	}
881	}
882
883	void ValidateGenericParameters::previsit( StructInstType * inst ) {
884	validateGeneric( inst );
885	}
886
887	void ValidateGenericParameters::previsit( UnionInstType * inst ) {
888	validateGeneric( inst );
889	}
890
891	void CompoundLiteral::premutate( ObjectDecl *objectDecl ) {
892	storageClasses = objectDecl->get_storageClasses();
893	}
894
895	Expression CompoundLiteral::postmutate( CompoundLiteralExpr compLitExpr ) {
896	// transform [storage_class] ... (struct S){ 3, ... };
897	// into [storage_class] struct S temp = { 3, ... };
898	static UniqueName indexName( "_compLit" );
899
900	ObjectDecl *tempvar = new ObjectDecl( indexName.newName(), storageClasses, LinkageSpec::C, nullptr, compLitExpr->get_result(), compLitExpr->get_initializer() );
901	compLitExpr->set_result( nullptr );
902	compLitExpr->set_initializer( nullptr );
903	delete compLitExpr;
904	declsToAddBefore.push_back( tempvar ); // add modified temporary to current block
905	return new VariableExpr( tempvar );
906	}
907
908	void ReturnTypeFixer::fix( std::list< Declaration * > &translationUnit ) {
909	PassVisitor<ReturnTypeFixer> fixer;
910	acceptAll( translationUnit, fixer );
911	}
912
913	void ReturnTypeFixer::postvisit( FunctionDecl * functionDecl ) {
914	FunctionType * ftype = functionDecl->get_functionType();
915	std::list< DeclarationWithType * > & retVals = ftype->get_returnVals();
916	assertf( retVals.size() == 0 \|\| retVals.size() == 1, "Function %s has too many return values: %zu", functionDecl->get_name().c_str(), retVals.size() );
917	if ( retVals.size() == 1 ) {
918	// 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).
919	// ensure other return values have a name.
920	DeclarationWithType * ret = retVals.front();
921	if ( ret->get_name() == "" ) {
922	ret->set_name( toString( "_retval_", CodeGen::genName( functionDecl ) ) );
923	}
924	ret->get_attributes().push_back( new Attribute( "unused" ) );
925	}
926	}
927
928	void ReturnTypeFixer::postvisit( FunctionType * ftype ) {
929	// xxx - need to handle named return values - this information needs to be saved somehow
930	// so that resolution has access to the names.
931	// Note that this pass needs to happen early so that other passes which look for tuple types
932	// find them in all of the right places, including function return types.
933	std::list< DeclarationWithType * > & retVals = ftype->get_returnVals();
934	if ( retVals.size() > 1 ) {
935	// generate a single return parameter which is the tuple of all of the return values
936	TupleType * tupleType = safe_dynamic_cast< TupleType * >( ResolvExpr::extractResultType( ftype ) );
937	// ensure return value is not destructed by explicitly creating an empty ListInit node wherein maybeConstruct is false.
938	ObjectDecl * newRet = new ObjectDecl( "", Type::StorageClasses(), LinkageSpec::Cforall, 0, tupleType, new ListInit( std::list<Initializer*>(), noDesignators, false ) );
939	deleteAll( retVals );
940	retVals.clear();
941	retVals.push_back( newRet );
942	}
943	}
944
945	void ArrayLength::computeLength( std::list< Declaration * > & translationUnit ) {
946	PassVisitor<ArrayLength> len;
947	acceptAll( translationUnit, len );
948	}
949
950	void ArrayLength::previsit( ObjectDecl * objDecl ) {
951	if ( ArrayType * at = dynamic_cast< ArrayType * >( objDecl->get_type() ) ) {
952	if ( at->get_dimension() ) return;
953	if ( ListInit * init = dynamic_cast< ListInit * >( objDecl->get_init() ) ) {
954	at->set_dimension( new ConstantExpr( Constant::from_ulong( init->get_initializers().size() ) ) );
955	}
956	}
957	}
958
959	void FindSpecialDeclarations::previsit( FunctionDecl * funcDecl ) {
960	if ( ! dereferenceOperator ) {
961	if ( funcDecl->get_name() == "*?" && funcDecl->get_linkage() == LinkageSpec::Intrinsic ) {
962	FunctionType * ftype = funcDecl->get_functionType();
963	if ( ftype->get_parameters().size() == 1 && ftype->get_parameters().front()->get_type()->get_qualifiers() == Type::Qualifiers() ) {
964	dereferenceOperator = funcDecl;
965	}
966	}
967	}
968	}
969	} // namespace SymTab
970
971	// Local Variables: //
972	// tab-width: 4 //
973	// mode: c++ //
974	// compile-command: "make install" //
975	// End: //

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