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source: src/Parser/DeclarationNode.cc @ 512d937c

ADTast-experimental

Last change on this file since 512d937c was 0d0931d, checked in by Andrew Beach <ajbeach@…>, 16 months ago
Removing some indent changes in parser. These can go in later, but hopefully this will avoid conflicts with the translation.
Property mode set to `100644`
File size: 43.6 KB

Line
1	//
2	// Cforall Version 1.0.0 Copyright (C) 2015 University of Waterloo
3	//
4	// The contents of this file are covered under the licence agreement in the
5	// file "LICENCE" distributed with Cforall.
6	//
7	// DeclarationNode.cc --
8	//
9	// Author : Rodolfo G. Esteves
10	// Created On : Sat May 16 12:34:05 2015
11	// Last Modified By : Andrew Beach
12	// Last Modified On : Tue Mar 14 11:56:00 2023
13	// Update Count : 1406
14	//
15
16	#include <cassert> // for assert, assertf, strict_dynamic_cast
17	#include <iterator> // for back_insert_iterator
18	#include <list> // for list
19	#include <memory> // for unique_ptr
20	#include <ostream> // for operator<<, ostream, basic_ostream
21	#include <string> // for string, operator+, allocator, char...
22
23	#include "Common/SemanticError.h" // for SemanticError
24	#include "Common/UniqueName.h" // for UniqueName
25	#include "Common/utility.h" // for maybeClone, maybeBuild, CodeLocation
26	#include "Parser/ParseNode.h" // for DeclarationNode, ExpressionNode
27	#include "SynTree/LinkageSpec.h" // for Spec, linkageName, Cforall
28	#include "SynTree/Attribute.h" // for Attribute
29	#include "SynTree/Declaration.h" // for TypeDecl, ObjectDecl, InlineMemberDecl, Declaration
30	#include "SynTree/Expression.h" // for Expression, ConstantExpr
31	#include "SynTree/Statement.h" // for AsmStmt
32	#include "SynTree/Type.h" // for Type, Type::StorageClasses, Type::...
33	#include "TypeData.h" // for TypeData, TypeData::Aggregate_t
34	#include "TypedefTable.h" // for TypedefTable
35
36	class Initializer;
37
38	extern TypedefTable typedefTable;
39
40	using namespace std;
41
42	// These must harmonize with the corresponding DeclarationNode enumerations.
43	const char * DeclarationNode::basicTypeNames[] = {
44	"void", "_Bool", "char", "int", "int128",
45	"float", "double", "long double", "float80", "float128",
46	"_float16", "_float32", "_float32x", "_float64", "_float64x", "_float128", "_float128x", "NoBasicTypeNames"
47	};
48	const char * DeclarationNode::complexTypeNames[] = {
49	"_Complex", "NoComplexTypeNames", "_Imaginary"
50	}; // Imaginary unsupported => parse, but make invisible and print error message
51	const char * DeclarationNode::signednessNames[] = {
52	"signed", "unsigned", "NoSignednessNames"
53	};
54	const char * DeclarationNode::lengthNames[] = {
55	"short", "long", "long long", "NoLengthNames"
56	};
57	const char * DeclarationNode::builtinTypeNames[] = {
58	"__builtin_va_list", "__auto_type", "zero_t", "one_t", "NoBuiltinTypeNames"
59	};
60
61	UniqueName DeclarationNode::anonymous( "__anonymous" );
62
63	extern LinkageSpec::Spec linkage; // defined in parser.yy
64
65	DeclarationNode::DeclarationNode() :
66	linkage( ::linkage ) {
67
68	// variable.name = nullptr;
69	variable.tyClass = TypeDecl::NUMBER_OF_KINDS;
70	variable.assertions = nullptr;
71	variable.initializer = nullptr;
72
73	assert.condition = nullptr;
74	assert.message = nullptr;
75	}
76
77	DeclarationNode::~DeclarationNode() {
78	// delete variable.name;
79	delete variable.assertions;
80	delete variable.initializer;
81
82	// delete type;
83	delete bitfieldWidth;
84
85	delete asmStmt;
86	// asmName, no delete, passed to next stage
87	delete initializer;
88
89	delete assert.condition;
90	delete assert.message;
91	}
92
93	DeclarationNode * DeclarationNode::clone() const {
94	DeclarationNode * newnode = new DeclarationNode;
95	newnode->set_next( maybeClone( get_next() ) );
96	newnode->name = name ? new string( *name ) : nullptr;
97
98	newnode->builtin = NoBuiltinType;
99	newnode->type = maybeClone( type );
100	newnode->inLine = inLine;
101	newnode->storageClasses = storageClasses;
102	newnode->funcSpecs = funcSpecs;
103	newnode->bitfieldWidth = maybeClone( bitfieldWidth );
104	newnode->enumeratorValue.reset( maybeClone( enumeratorValue.get() ) );
105	newnode->hasEllipsis = hasEllipsis;
106	newnode->linkage = linkage;
107	newnode->asmName = maybeClone( asmName );
108	cloneAll( attributes, newnode->attributes );
109	newnode->initializer = maybeClone( initializer );
110	newnode->extension = extension;
111	newnode->asmStmt = maybeClone( asmStmt );
112	newnode->error = error;
113
114	// newnode->variable.name = variable.name ? new string( *variable.name ) : nullptr;
115	newnode->variable.tyClass = variable.tyClass;
116	newnode->variable.assertions = maybeClone( variable.assertions );
117	newnode->variable.initializer = maybeClone( variable.initializer );
118
119	newnode->assert.condition = maybeClone( assert.condition );
120	newnode->assert.message = maybeClone( assert.message );
121	return newnode;
122	} // DeclarationNode::clone
123
124	void DeclarationNode::print( std::ostream & os, int indent ) const {
125	os << string( indent, ' ' );
126	if ( name ) {
127	os << *name << ": ";
128	} // if
129
130	if ( linkage != LinkageSpec::Cforall ) {
131	os << LinkageSpec::name( linkage ) << " ";
132	} // if
133
134	storageClasses.print( os );
135	funcSpecs.print( os );
136
137	if ( type ) {
138	type->print( os, indent );
139	} else {
140	os << "untyped entity ";
141	} // if
142
143	if ( bitfieldWidth ) {
144	os << endl << string( indent + 2, ' ' ) << "with bitfield width ";
145	bitfieldWidth->printOneLine( os );
146	} // if
147
148	if ( initializer ) {
149	os << endl << string( indent + 2, ' ' ) << "with initializer ";
150	initializer->printOneLine( os );
151	os << " maybe constructed? " << initializer->get_maybeConstructed();
152	} // if
153
154	if ( ! attributes.empty() ) {
155	os << string( indent + 2, ' ' ) << "with attributes " << endl;
156	for ( Attribute * attr: reverseIterate( attributes ) ) {
157	os << string( indent + 4, ' ' ) << attr->name.c_str() << endl;
158	} // for
159	} // if
160
161	os << endl;
162	}
163
164	void DeclarationNode::printList( std::ostream & os, int indent ) const {
165	ParseNode::printList( os, indent );
166	if ( hasEllipsis ) {
167	os << string( indent, ' ' ) << "and a variable number of other arguments" << endl;
168	} // if
169	}
170
171	DeclarationNode * DeclarationNode::newStorageClass( Type::StorageClasses sc ) {
172	DeclarationNode * newnode = new DeclarationNode;
173	newnode->storageClasses = sc;
174	return newnode;
175	} // DeclarationNode::newStorageClass
176
177	DeclarationNode * DeclarationNode::newFuncSpecifier( Type::FuncSpecifiers fs ) {
178	DeclarationNode * newnode = new DeclarationNode;
179	newnode->funcSpecs = fs;
180	return newnode;
181	} // DeclarationNode::newFuncSpecifier
182
183	DeclarationNode * DeclarationNode::newTypeQualifier( Type::Qualifiers tq ) {
184	DeclarationNode * newnode = new DeclarationNode;
185	newnode->type = new TypeData();
186	newnode->type->qualifiers = tq;
187	return newnode;
188	} // DeclarationNode::newQualifier
189
190	DeclarationNode * DeclarationNode::newBasicType( BasicType bt ) {
191	DeclarationNode * newnode = new DeclarationNode;
192	newnode->type = new TypeData( TypeData::Basic );
193	newnode->type->basictype = bt;
194	return newnode;
195	} // DeclarationNode::newBasicType
196
197	DeclarationNode * DeclarationNode::newComplexType( ComplexType ct ) {
198	DeclarationNode * newnode = new DeclarationNode;
199	newnode->type = new TypeData( TypeData::Basic );
200	newnode->type->complextype = ct;
201	return newnode;
202	} // DeclarationNode::newComplexType
203
204	DeclarationNode * DeclarationNode::newSignedNess( Signedness sn ) {
205	DeclarationNode * newnode = new DeclarationNode;
206	newnode->type = new TypeData( TypeData::Basic );
207	newnode->type->signedness = sn;
208	return newnode;
209	} // DeclarationNode::newSignedNess
210
211	DeclarationNode * DeclarationNode::newLength( Length lnth ) {
212	DeclarationNode * newnode = new DeclarationNode;
213	newnode->type = new TypeData( TypeData::Basic );
214	newnode->type->length = lnth;
215	return newnode;
216	} // DeclarationNode::newLength
217
218	DeclarationNode * DeclarationNode::newForall( DeclarationNode * forall ) {
219	DeclarationNode * newnode = new DeclarationNode;
220	newnode->type = new TypeData( TypeData::Unknown );
221	newnode->type->forall = forall;
222	return newnode;
223	} // DeclarationNode::newForall
224
225	DeclarationNode * DeclarationNode::newFromGlobalScope() {
226	DeclarationNode * newnode = new DeclarationNode;
227	newnode->type = new TypeData( TypeData::GlobalScope );
228	return newnode;
229	}
230
231	DeclarationNode * DeclarationNode::newQualifiedType( DeclarationNode * parent, DeclarationNode * child) {
232	DeclarationNode * newnode = new DeclarationNode;
233	newnode->type = new TypeData( TypeData::Qualified );
234	newnode->type->qualified.parent = parent->type;
235	newnode->type->qualified.child = child->type;
236	parent->type = nullptr;
237	child->type = nullptr;
238	delete parent;
239	delete child;
240	return newnode;
241	}
242
243	DeclarationNode * DeclarationNode::newAggregate( AggregateDecl::Aggregate kind, const string * name, ExpressionNode * actuals, DeclarationNode * fields, bool body ) {
244	DeclarationNode * newnode = new DeclarationNode;
245	newnode->type = new TypeData( TypeData::Aggregate );
246	newnode->type->aggregate.kind = kind;
247	newnode->type->aggregate.anon = name == nullptr;
248	newnode->type->aggregate.name = newnode->type->aggregate.anon ? new string( DeclarationNode::anonymous.newName() ) : name;
249	newnode->type->aggregate.actuals = actuals;
250	newnode->type->aggregate.fields = fields;
251	newnode->type->aggregate.body = body;
252	newnode->type->aggregate.tagged = false;
253	newnode->type->aggregate.parent = nullptr;
254	return newnode;
255	} // DeclarationNode::newAggregate
256
257	DeclarationNode * DeclarationNode::newEnum( const string * name, DeclarationNode * constants, bool body, bool typed, DeclarationNode * base, EnumHiding hiding ) {
258	DeclarationNode * newnode = new DeclarationNode;
259	newnode->type = new TypeData( TypeData::Enum );
260	newnode->type->enumeration.anon = name == nullptr;
261	newnode->type->enumeration.name = newnode->type->enumeration.anon ? new string( DeclarationNode::anonymous.newName() ) : name;
262	newnode->type->enumeration.constants = constants;
263	newnode->type->enumeration.body = body;
264	newnode->type->enumeration.typed = typed;
265	newnode->type->enumeration.hiding = hiding;
266	if ( base && base->type ) {
267	newnode->type->base = base->type;
268	} // if
269
270	return newnode;
271	} // DeclarationNode::newEnum
272
273
274
275	DeclarationNode * DeclarationNode::newName( const string * name ) {
276	DeclarationNode * newnode = new DeclarationNode;
277	assert( ! newnode->name );
278	newnode->name = name;
279	return newnode;
280	} // DeclarationNode::newName
281
282	DeclarationNode * DeclarationNode::newEnumConstant( const string * name, ExpressionNode * constant ) {
283	DeclarationNode * newnode = newName( name );
284	newnode->enumeratorValue.reset( constant );
285	return newnode;
286	} // DeclarationNode::newEnumConstant
287
288	DeclarationNode * DeclarationNode::newEnumValueGeneric( const string * name, InitializerNode * init ) {
289	if ( init ) {
290	if ( init->get_expression() ) {
291	return newEnumConstant( name, init->get_expression() );
292	} else {
293	DeclarationNode * newnode = newName( name );
294	newnode->initializer = init;
295	return newnode;
296	} // if
297	} else {
298	return newName( name );
299	} // if
300	} // DeclarationNode::newEnumValueGeneric
301
302	DeclarationNode * DeclarationNode::newEnumInLine( const string name ) {
303	DeclarationNode * newnode = newName( new std::string(name) );
304	newnode->enumInLine = true;
305	return newnode;
306	}
307
308	DeclarationNode * DeclarationNode::newFromTypedef( const string * name ) {
309	DeclarationNode * newnode = new DeclarationNode;
310	newnode->type = new TypeData( TypeData::SymbolicInst );
311	newnode->type->symbolic.name = name;
312	newnode->type->symbolic.isTypedef = true;
313	newnode->type->symbolic.params = nullptr;
314	return newnode;
315	} // DeclarationNode::newFromTypedef
316
317	DeclarationNode * DeclarationNode::newFromTypeGen( const string * name, ExpressionNode * params ) {
318	DeclarationNode * newnode = new DeclarationNode;
319	newnode->type = new TypeData( TypeData::SymbolicInst );
320	newnode->type->symbolic.name = name;
321	newnode->type->symbolic.isTypedef = false;
322	newnode->type->symbolic.actuals = params;
323	return newnode;
324	} // DeclarationNode::newFromTypeGen
325
326	DeclarationNode * DeclarationNode::newTypeParam( TypeDecl::Kind tc, const string * name ) {
327	DeclarationNode * newnode = newName( name );
328	newnode->type = nullptr;
329	newnode->variable.tyClass = tc;
330	newnode->variable.assertions = nullptr;
331	return newnode;
332	} // DeclarationNode::newTypeParam
333
334	DeclarationNode * DeclarationNode::newTrait( const string * name, DeclarationNode * params, DeclarationNode * asserts ) {
335	DeclarationNode * newnode = new DeclarationNode;
336	newnode->type = new TypeData( TypeData::Aggregate );
337	newnode->type->aggregate.name = name;
338	newnode->type->aggregate.kind = AggregateDecl::Trait;
339	newnode->type->aggregate.params = params;
340	newnode->type->aggregate.fields = asserts;
341	return newnode;
342	} // DeclarationNode::newTrait
343
344	DeclarationNode * DeclarationNode::newTraitUse( const string * name, ExpressionNode * params ) {
345	DeclarationNode * newnode = new DeclarationNode;
346	newnode->type = new TypeData( TypeData::AggregateInst );
347	newnode->type->aggInst.aggregate = new TypeData( TypeData::Aggregate );
348	newnode->type->aggInst.aggregate->aggregate.kind = AggregateDecl::Trait;
349	newnode->type->aggInst.aggregate->aggregate.name = name;
350	newnode->type->aggInst.params = params;
351	return newnode;
352	} // DeclarationNode::newTraitUse
353
354	DeclarationNode * DeclarationNode::newTypeDecl( const string * name, DeclarationNode * typeParams ) {
355	DeclarationNode * newnode = newName( name );
356	newnode->type = new TypeData( TypeData::Symbolic );
357	newnode->type->symbolic.isTypedef = false;
358	newnode->type->symbolic.params = typeParams;
359	return newnode;
360	} // DeclarationNode::newTypeDecl
361
362	DeclarationNode * DeclarationNode::newPointer( DeclarationNode * qualifiers, OperKinds kind ) {
363	DeclarationNode * newnode = new DeclarationNode;
364	newnode->type = new TypeData( kind == OperKinds::PointTo ? TypeData::Pointer : TypeData::Reference );
365	if ( kind == OperKinds::And ) {
366	// T && is parsed as 'And' operator rather than two references => add a second reference type
367	TypeData * td = new TypeData( TypeData::Reference );
368	td->base = newnode->type;
369	newnode->type = td;
370	}
371	if ( qualifiers ) {
372	return newnode->addQualifiers( qualifiers );
373	} else {
374	return newnode;
375	} // if
376	} // DeclarationNode::newPointer
377
378	DeclarationNode * DeclarationNode::newArray( ExpressionNode * size, DeclarationNode * qualifiers, bool isStatic ) {
379	DeclarationNode * newnode = new DeclarationNode;
380	newnode->type = new TypeData( TypeData::Array );
381	newnode->type->array.dimension = size;
382	newnode->type->array.isStatic = isStatic;
383	if ( newnode->type->array.dimension == nullptr \|\| newnode->type->array.dimension->isExpressionType<ConstantExpr * >() ) {
384	newnode->type->array.isVarLen = false;
385	} else {
386	newnode->type->array.isVarLen = true;
387	} // if
388	return newnode->addQualifiers( qualifiers );
389	} // DeclarationNode::newArray
390
391	DeclarationNode * DeclarationNode::newVarArray( DeclarationNode * qualifiers ) {
392	DeclarationNode * newnode = new DeclarationNode;
393	newnode->type = new TypeData( TypeData::Array );
394	newnode->type->array.dimension = nullptr;
395	newnode->type->array.isStatic = false;
396	newnode->type->array.isVarLen = true;
397	return newnode->addQualifiers( qualifiers );
398	}
399
400	DeclarationNode * DeclarationNode::newBitfield( ExpressionNode * size ) {
401	DeclarationNode * newnode = new DeclarationNode;
402	newnode->bitfieldWidth = size;
403	return newnode;
404	}
405
406	DeclarationNode * DeclarationNode::newTuple( DeclarationNode * members ) {
407	DeclarationNode * newnode = new DeclarationNode;
408	newnode->type = new TypeData( TypeData::Tuple );
409	newnode->type->tuple = members;
410	return newnode;
411	}
412
413	DeclarationNode * DeclarationNode::newTypeof( ExpressionNode * expr, bool basetypeof ) {
414	DeclarationNode * newnode = new DeclarationNode;
415	newnode->type = new TypeData( basetypeof ? TypeData::Basetypeof : TypeData::Typeof );
416	newnode->type->typeexpr = expr;
417	return newnode;
418	}
419
420	DeclarationNode * DeclarationNode::newVtableType( DeclarationNode * decl ) {
421	DeclarationNode * newnode = new DeclarationNode;
422	newnode->type = new TypeData( TypeData::Vtable );
423	newnode->setBase( decl->type );
424	return newnode;
425	}
426
427	DeclarationNode * DeclarationNode::newBuiltinType( BuiltinType bt ) {
428	DeclarationNode * newnode = new DeclarationNode;
429	newnode->type = new TypeData( TypeData::Builtin );
430	newnode->builtin = bt;
431	newnode->type->builtintype = newnode->builtin;
432	return newnode;
433	} // DeclarationNode::newBuiltinType
434
435	DeclarationNode * DeclarationNode::newFunction( const string * name, DeclarationNode * ret, DeclarationNode * param, StatementNode * body ) {
436	DeclarationNode * newnode = newName( name );
437	newnode->type = new TypeData( TypeData::Function );
438	newnode->type->function.params = param;
439	newnode->type->function.body = body;
440
441	if ( ret ) {
442	newnode->type->base = ret->type;
443	ret->type = nullptr;
444	delete ret;
445	} // if
446
447	return newnode;
448	} // DeclarationNode::newFunction
449
450	DeclarationNode * DeclarationNode::newAttribute( const string * name, ExpressionNode * expr ) {
451	DeclarationNode * newnode = new DeclarationNode;
452	newnode->type = nullptr;
453	std::list< Expression * > exprs;
454	buildList( expr, exprs );
455	newnode->attributes.push_back( new Attribute( *name, exprs ) );
456	delete name;
457	return newnode;
458	}
459
460	DeclarationNode * DeclarationNode::newDirectiveStmt( StatementNode * stmt ) {
461	DeclarationNode * newnode = new DeclarationNode;
462	newnode->directiveStmt = stmt;
463	return newnode;
464	}
465
466	DeclarationNode * DeclarationNode::newAsmStmt( StatementNode * stmt ) {
467	DeclarationNode * newnode = new DeclarationNode;
468	newnode->asmStmt = stmt;
469	return newnode;
470	}
471
472	DeclarationNode * DeclarationNode::newStaticAssert( ExpressionNode * condition, Expression * message ) {
473	DeclarationNode * newnode = new DeclarationNode;
474	newnode->assert.condition = condition;
475	newnode->assert.message = message;
476	return newnode;
477	}
478
479
480	void appendError( string & dst, const string & src ) {
481	if ( src.empty() ) return;
482	if ( dst.empty() ) { dst = src; return; }
483	dst += ", " + src;
484	} // appendError
485
486	void DeclarationNode::checkQualifiers( const TypeData * src, const TypeData * dst ) {
487	const Type::Qualifiers qsrc = src->qualifiers, qdst = dst->qualifiers; // optimization
488
489	if ( (qsrc & qdst).any() ) { // duplicates ?
490	for ( unsigned int i = 0; i < Type::NumTypeQualifier; i += 1 ) { // find duplicates
491	if ( qsrc[i] && qdst[i] ) {
492	appendError( error, string( "duplicate " ) + Type::QualifiersNames[i] );
493	} // if
494	} // for
495	} // for
496	} // DeclarationNode::checkQualifiers
497
498	void DeclarationNode::checkSpecifiers( DeclarationNode * src ) {
499	if ( (funcSpecs & src->funcSpecs).any() ) { // duplicates ?
500	for ( unsigned int i = 0; i < Type::NumFuncSpecifier; i += 1 ) { // find duplicates
501	if ( funcSpecs[i] && src->funcSpecs[i] ) {
502	appendError( error, string( "duplicate " ) + Type::FuncSpecifiersNames[i] );
503	} // if
504	} // for
505	} // if
506
507	if ( storageClasses.any() && src->storageClasses.any() ) { // any reason to check ?
508	if ( (storageClasses & src->storageClasses ).any() ) { // duplicates ?
509	for ( unsigned int i = 0; i < Type::NumStorageClass; i += 1 ) { // find duplicates
510	if ( storageClasses[i] && src->storageClasses[i] ) {
511	appendError( error, string( "duplicate " ) + Type::StorageClassesNames[i] );
512	} // if
513	} // for
514	// src is the new item being added and has a single bit
515	} else if ( ! src->storageClasses.is_threadlocal_any() ) { // conflict ?
516	appendError( error, string( "conflicting " )
517	+ Type::StorageClassesNames[storageClasses.ffs()]
518	+ " & " + Type::StorageClassesNames[src->storageClasses.ffs()] );
519	src->storageClasses.reset(); // FIX to preserve invariant of one basic storage specifier
520	} // if
521	} // if
522
523	appendError( error, src->error );
524	} // DeclarationNode::checkSpecifiers
525
526	DeclarationNode * DeclarationNode::copySpecifiers( DeclarationNode * q ) {
527	funcSpecs \|= q->funcSpecs;
528	storageClasses \|= q->storageClasses;
529
530	for ( Attribute * attr: reverseIterate( q->attributes ) ) {
531	attributes.push_front( attr->clone() );
532	} // for
533	return this;
534	} // DeclarationNode::copySpecifiers
535
536	static void addQualifiersToType( TypeData & src, TypeData dst ) {
537	if ( dst->base ) {
538	addQualifiersToType( src, dst->base );
539	} else if ( dst->kind == TypeData::Function ) {
540	dst->base = src;
541	src = nullptr;
542	} else {
543	dst->qualifiers \|= src->qualifiers;
544	} // if
545	} // addQualifiersToType
546
547	DeclarationNode * DeclarationNode::addQualifiers( DeclarationNode * q ) {
548	if ( ! q ) { return this; } // empty qualifier
549
550	checkSpecifiers( q );
551	copySpecifiers( q );
552
553	if ( ! q->type ) { delete q; return this; }
554
555	if ( ! type ) {
556	type = q->type; // reuse structure
557	q->type = nullptr;
558	delete q;
559	return this;
560	} // if
561
562	if ( q->type->forall ) { // forall qualifier ?
563	if ( type->forall ) { // polymorphic routine ?
564	type->forall->appendList( q->type->forall ); // augment forall qualifier
565	} else {
566	if ( type->kind == TypeData::Aggregate ) { // struct/union ?
567	if ( type->aggregate.params ) { // polymorphic ?
568	type->aggregate.params->appendList( q->type->forall ); // augment forall qualifier
569	} else { // not polymorphic
570	type->aggregate.params = q->type->forall; // set forall qualifier
571	} // if
572	} else { // not polymorphic
573	type->forall = q->type->forall; // make polymorphic routine
574	} // if
575	} // if
576	q->type->forall = nullptr; // forall qualifier moved
577	} // if
578
579	checkQualifiers( type, q->type );
580	if ( (builtin == Zero \|\| builtin == One) && q->type->qualifiers.any() && error.length() == 0 ) {
581	SemanticWarning( yylloc, Warning::BadQualifiersZeroOne, builtinTypeNames[builtin] );
582	} // if
583	addQualifiersToType( q->type, type );
584
585	delete q;
586	return this;
587	} // addQualifiers
588
589	static void addTypeToType( TypeData & src, TypeData & dst ) {
590	if ( src->forall && dst->kind == TypeData::Function ) {
591	if ( dst->forall ) {
592	dst->forall->appendList( src->forall );
593	} else {
594	dst->forall = src->forall;
595	} // if
596	src->forall = nullptr;
597	} // if
598	if ( dst->base ) {
599	addTypeToType( src, dst->base );
600	} else {
601	switch ( dst->kind ) {
602	case TypeData::Unknown:
603	src->qualifiers \|= dst->qualifiers;
604	dst = src;
605	src = nullptr;
606	break;
607	case TypeData::Basic:
608	dst->qualifiers \|= src->qualifiers;
609	if ( src->kind != TypeData::Unknown ) {
610	assert( src->kind == TypeData::Basic );
611
612	if ( dst->basictype == DeclarationNode::NoBasicType ) {
613	dst->basictype = src->basictype;
614	} else if ( src->basictype != DeclarationNode::NoBasicType )
615	SemanticError( yylloc, src, string( "conflicting type specifier " ) + DeclarationNode::basicTypeNames[ src->basictype ] + " in type: " );
616
617	if ( dst->complextype == DeclarationNode::NoComplexType ) {
618	dst->complextype = src->complextype;
619	} else if ( src->complextype != DeclarationNode::NoComplexType )
620	SemanticError( yylloc, src, string( "conflicting type specifier " ) + DeclarationNode::complexTypeNames[ src->complextype ] + " in type: " );
621
622	if ( dst->signedness == DeclarationNode::NoSignedness ) {
623	dst->signedness = src->signedness;
624	} else if ( src->signedness != DeclarationNode::NoSignedness )
625	SemanticError( yylloc, src, string( "conflicting type specifier " ) + DeclarationNode::signednessNames[ src->signedness ] + " in type: " );
626
627	if ( dst->length == DeclarationNode::NoLength ) {
628	dst->length = src->length;
629	} else if ( dst->length == DeclarationNode::Long && src->length == DeclarationNode::Long ) {
630	dst->length = DeclarationNode::LongLong;
631	} else if ( src->length != DeclarationNode::NoLength )
632	SemanticError( yylloc, src, string( "conflicting type specifier " ) + DeclarationNode::lengthNames[ src->length ] + " in type: " );
633	} // if
634	break;
635	default:
636	switch ( src->kind ) {
637	case TypeData::Aggregate:
638	case TypeData::Enum:
639	dst->base = new TypeData( TypeData::AggregateInst );
640	dst->base->aggInst.aggregate = src;
641	if ( src->kind == TypeData::Aggregate ) {
642	dst->base->aggInst.params = maybeClone( src->aggregate.actuals );
643	} // if
644	dst->base->qualifiers \|= src->qualifiers;
645	src = nullptr;
646	break;
647	default:
648	if ( dst->forall ) {
649	dst->forall->appendList( src->forall );
650	} else {
651	dst->forall = src->forall;
652	} // if
653	src->forall = nullptr;
654	dst->base = src;
655	src = nullptr;
656	} // switch
657	} // switch
658	} // if
659	}
660
661	DeclarationNode * DeclarationNode::addType( DeclarationNode * o ) {
662	if ( o ) {
663	checkSpecifiers( o );
664	copySpecifiers( o );
665	if ( o->type ) {
666	if ( ! type ) {
667	if ( o->type->kind == TypeData::Aggregate \|\| o->type->kind == TypeData::Enum ) {
668	type = new TypeData( TypeData::AggregateInst );
669	type->aggInst.aggregate = o->type;
670	if ( o->type->kind == TypeData::Aggregate ) {
671	type->aggInst.hoistType = o->type->aggregate.body;
672	type->aggInst.params = maybeClone( o->type->aggregate.actuals );
673	} else {
674	type->aggInst.hoistType = o->type->enumeration.body;
675	} // if
676	type->qualifiers \|= o->type->qualifiers;
677	} else {
678	type = o->type;
679	} // if
680	o->type = nullptr;
681	} else {
682	addTypeToType( o->type, type );
683	} // if
684	} // if
685	if ( o->bitfieldWidth ) {
686	bitfieldWidth = o->bitfieldWidth;
687	} // if
688
689	// there may be typedefs chained onto the type
690	if ( o->get_next() ) {
691	set_last( o->get_next()->clone() );
692	} // if
693	} // if
694	delete o;
695
696	return this;
697	}
698
699	DeclarationNode * DeclarationNode::addEnumBase( DeclarationNode * o ) {
700	if ( o && o -> type) {
701	type->base= o->type;
702	}
703	delete o;
704	return this;
705	}
706
707	DeclarationNode * DeclarationNode::addTypedef() {
708	TypeData * newtype = new TypeData( TypeData::Symbolic );
709	newtype->symbolic.params = nullptr;
710	newtype->symbolic.isTypedef = true;
711	newtype->symbolic.name = name ? new string( *name ) : nullptr;
712	newtype->base = type;
713	type = newtype;
714	return this;
715	}
716
717	DeclarationNode * DeclarationNode::addAssertions( DeclarationNode * assertions ) {
718	if ( variable.tyClass != TypeDecl::NUMBER_OF_KINDS ) {
719	if ( variable.assertions ) {
720	variable.assertions->appendList( assertions );
721	} else {
722	variable.assertions = assertions;
723	} // if
724	return this;
725	} // if
726
727	assert( type );
728	switch ( type->kind ) {
729	case TypeData::Symbolic:
730	if ( type->symbolic.assertions ) {
731	type->symbolic.assertions->appendList( assertions );
732	} else {
733	type->symbolic.assertions = assertions;
734	} // if
735	break;
736	default:
737	assert( false );
738	} // switch
739
740	return this;
741	}
742
743	DeclarationNode * DeclarationNode::addName( string * newname ) {
744	assert( ! name );
745	name = newname;
746	return this;
747	}
748
749	DeclarationNode * DeclarationNode::addAsmName( DeclarationNode * newname ) {
750	assert( ! asmName );
751	asmName = newname ? newname->asmName : nullptr;
752	return this->addQualifiers( newname );
753	}
754
755	DeclarationNode * DeclarationNode::addBitfield( ExpressionNode * size ) {
756	bitfieldWidth = size;
757	return this;
758	}
759
760	DeclarationNode * DeclarationNode::addVarArgs() {
761	assert( type );
762	hasEllipsis = true;
763	return this;
764	}
765
766	DeclarationNode * DeclarationNode::addFunctionBody( StatementNode * body, ExpressionNode * withExprs ) {
767	assert( type );
768	assert( type->kind == TypeData::Function );
769	assert( ! type->function.body );
770	type->function.body = body;
771	type->function.withExprs = withExprs;
772	return this;
773	}
774
775	DeclarationNode * DeclarationNode::addOldDeclList( DeclarationNode * list ) {
776	assert( type );
777	assert( type->kind == TypeData::Function );
778	assert( ! type->function.oldDeclList );
779	type->function.oldDeclList = list;
780	return this;
781	}
782
783	DeclarationNode * DeclarationNode::setBase( TypeData * newType ) {
784	if ( type ) {
785	TypeData * prevBase = type;
786	TypeData * curBase = type->base;
787	while ( curBase != nullptr ) {
788	prevBase = curBase;
789	curBase = curBase->base;
790	} // while
791	prevBase->base = newType;
792	} else {
793	type = newType;
794	} // if
795	return this;
796	}
797
798	DeclarationNode * DeclarationNode::copyAttribute( DeclarationNode * a ) {
799	if ( a ) {
800	for ( Attribute *attr: reverseIterate( a->attributes ) ) {
801	attributes.push_front( attr );
802	} // for
803	a->attributes.clear();
804	} // if
805	return this;
806	} // copyAttribute
807
808	DeclarationNode * DeclarationNode::addPointer( DeclarationNode * p ) {
809	if ( p ) {
810	assert( p->type->kind == TypeData::Pointer \|\| p->type->kind == TypeData::Reference );
811	setBase( p->type );
812	p->type = nullptr;
813	copyAttribute( p );
814	delete p;
815	} // if
816	return this;
817	}
818
819	DeclarationNode * DeclarationNode::addArray( DeclarationNode * a ) {
820	if ( a ) {
821	assert( a->type->kind == TypeData::Array );
822	setBase( a->type );
823	a->type = nullptr;
824	copyAttribute( a );
825	delete a;
826	} // if
827	return this;
828	}
829
830	DeclarationNode * DeclarationNode::addNewPointer( DeclarationNode * p ) {
831	if ( p ) {
832	assert( p->type->kind == TypeData::Pointer \|\| p->type->kind == TypeData::Reference );
833	if ( type ) {
834	switch ( type->kind ) {
835	case TypeData::Aggregate:
836	case TypeData::Enum:
837	p->type->base = new TypeData( TypeData::AggregateInst );
838	p->type->base->aggInst.aggregate = type;
839	if ( type->kind == TypeData::Aggregate ) {
840	p->type->base->aggInst.params = maybeClone( type->aggregate.actuals );
841	} // if
842	p->type->base->qualifiers \|= type->qualifiers;
843	break;
844
845	default:
846	p->type->base = type;
847	} // switch
848	type = nullptr;
849	} // if
850	delete this;
851	return p;
852	} else {
853	return this;
854	} // if
855	}
856
857	static TypeData * findLast( TypeData * a ) {
858	assert( a );
859	TypeData * cur = a;
860	while ( cur->base ) {
861	cur = cur->base;
862	} // while
863	return cur;
864	}
865
866	DeclarationNode * DeclarationNode::addNewArray( DeclarationNode * a ) {
867	if ( ! a ) return this;
868	assert( a->type->kind == TypeData::Array );
869	TypeData * lastArray = findLast( a->type );
870	if ( type ) {
871	switch ( type->kind ) {
872	case TypeData::Aggregate:
873	case TypeData::Enum:
874	lastArray->base = new TypeData( TypeData::AggregateInst );
875	lastArray->base->aggInst.aggregate = type;
876	if ( type->kind == TypeData::Aggregate ) {
877	lastArray->base->aggInst.params = maybeClone( type->aggregate.actuals );
878	} // if
879	lastArray->base->qualifiers \|= type->qualifiers;
880	break;
881	default:
882	lastArray->base = type;
883	} // switch
884	type = nullptr;
885	} // if
886	delete this;
887	return a;
888	}
889
890	DeclarationNode * DeclarationNode::addParamList( DeclarationNode * params ) {
891	TypeData * ftype = new TypeData( TypeData::Function );
892	ftype->function.params = params;
893	setBase( ftype );
894	return this;
895	}
896
897	static TypeData * addIdListToType( TypeData * type, DeclarationNode * ids ) {
898	if ( type ) {
899	if ( type->kind != TypeData::Function ) {
900	type->base = addIdListToType( type->base, ids );
901	} else {
902	type->function.idList = ids;
903	} // if
904	return type;
905	} else {
906	TypeData * newtype = new TypeData( TypeData::Function );
907	newtype->function.idList = ids;
908	return newtype;
909	} // if
910	} // addIdListToType
911
912	DeclarationNode * DeclarationNode::addIdList( DeclarationNode * ids ) {
913	type = addIdListToType( type, ids );
914	return this;
915	}
916
917	DeclarationNode * DeclarationNode::addInitializer( InitializerNode * init ) {
918	initializer = init;
919	return this;
920	}
921
922	DeclarationNode * DeclarationNode::addTypeInitializer( DeclarationNode * init ) {
923	assertf( variable.tyClass != TypeDecl::NUMBER_OF_KINDS, "Called addTypeInitializer on something that isn't a type variable." );
924	variable.initializer = init;
925	return this;
926	}
927
928	DeclarationNode * DeclarationNode::cloneType( string * name ) {
929	DeclarationNode * newnode = newName( name );
930	newnode->type = maybeClone( type );
931	newnode->copySpecifiers( this );
932	return newnode;
933	}
934
935	DeclarationNode * DeclarationNode::cloneBaseType( DeclarationNode * o ) {
936	if ( ! o ) return nullptr;
937
938	o->copySpecifiers( this );
939	if ( type ) {
940	TypeData * srcType = type;
941
942	// search for the base type by scanning off pointers and array designators
943	while ( srcType->base ) {
944	srcType = srcType->base;
945	} // while
946
947	TypeData * newType = srcType->clone();
948	if ( newType->kind == TypeData::AggregateInst ) {
949	// don't duplicate members
950	if ( newType->aggInst.aggregate->kind == TypeData::Enum ) {
951	delete newType->aggInst.aggregate->enumeration.constants;
952	newType->aggInst.aggregate->enumeration.constants = nullptr;
953	newType->aggInst.aggregate->enumeration.body = false;
954	} else {
955	assert( newType->aggInst.aggregate->kind == TypeData::Aggregate );
956	delete newType->aggInst.aggregate->aggregate.fields;
957	newType->aggInst.aggregate->aggregate.fields = nullptr;
958	newType->aggInst.aggregate->aggregate.body = false;
959	} // if
960	// don't hoist twice
961	newType->aggInst.hoistType = false;
962	} // if
963
964	newType->forall = maybeClone( type->forall );
965	if ( ! o->type ) {
966	o->type = newType;
967	} else {
968	addTypeToType( newType, o->type );
969	delete newType;
970	} // if
971	} // if
972	return o;
973	}
974
975	DeclarationNode * DeclarationNode::extractAggregate() const {
976	if ( type ) {
977	TypeData * ret = typeextractAggregate( type );
978	if ( ret ) {
979	DeclarationNode * newnode = new DeclarationNode;
980	newnode->type = ret;
981	return newnode;
982	} // if
983	} // if
984	return nullptr;
985	}
986
987	void buildList( const DeclarationNode * firstNode, std::list< Declaration * > & outputList ) {
988	SemanticErrorException errors;
989	std::back_insert_iterator< std::list< Declaration * > > out( outputList );
990
991	for ( const DeclarationNode * cur = firstNode; cur; cur = dynamic_cast< DeclarationNode * >( cur->get_next() ) ) {
992	try {
993	bool extracted = false, anon = false;
994	AggregateDecl * unionDecl = nullptr;
995
996	if ( DeclarationNode * extr = cur->extractAggregate() ) {
997	// Handle the case where a SUE declaration is contained within an object or type declaration.
998
999	assert( cur->type );
1000	// Replace anonymous SUE name with typedef name to prevent anonymous naming problems across translation units.
1001	if ( cur->type->kind == TypeData::Symbolic && cur->type->symbolic.isTypedef ) {
1002	assert( extr->type );
1003	// Handle anonymous aggregates: typedef struct { int i; } foo
1004	extr->type->qualifiers.reset(); // clear any CVs associated with the aggregate
1005	if ( extr->type->kind == TypeData::Aggregate && extr->type->aggregate.anon ) {
1006	delete extr->type->aggregate.name;
1007	extr->type->aggregate.name = new string( "__anonymous_" + *cur->name );
1008	extr->type->aggregate.anon = false;
1009	assert( cur->type->base );
1010	if ( cur->type->base ) {
1011	delete cur->type->base->aggInst.aggregate->aggregate.name;
1012	cur->type->base->aggInst.aggregate->aggregate.name = new string( "__anonymous_" + *cur->name );
1013	cur->type->base->aggInst.aggregate->aggregate.anon = false;
1014	cur->type->base->aggInst.aggregate->qualifiers.reset();
1015	} // if
1016	} // if
1017	// Handle anonymous enumeration: typedef enum { A, B, C } foo
1018	if ( extr->type->kind == TypeData::Enum && extr->type->enumeration.anon ) {
1019	delete extr->type->enumeration.name;
1020	extr->type->enumeration.name = new string( "__anonymous_" + *cur->name );
1021	extr->type->enumeration.anon = false;
1022	assert( cur->type->base );
1023	if ( cur->type->base ) {
1024	delete cur->type->base->aggInst.aggregate->enumeration.name;
1025	cur->type->base->aggInst.aggregate->enumeration.name = new string( "__anonymous_" + *cur->name );
1026	cur->type->base->aggInst.aggregate->enumeration.anon = false;
1027	} // if
1028	} // if
1029	} // if
1030
1031	Declaration * decl = extr->build();
1032	if ( decl ) {
1033	// Remember the declaration if it is a union aggregate ?
1034	unionDecl = dynamic_cast<UnionDecl *>( decl );
1035
1036	decl->location = cur->location;
1037	*out++ = decl;
1038
1039	// need to remember the cases where a declaration contains an anonymous aggregate definition
1040	extracted = true;
1041	assert( extr->type );
1042	if ( extr->type->kind == TypeData::Aggregate ) {
1043	// typedef struct { int A } B is the only case?
1044	anon = extr->type->aggregate.anon;
1045	} else if ( extr->type->kind == TypeData::Enum ) {
1046	// typedef enum { A } B is the only case?
1047	anon = extr->type->enumeration.anon;
1048	}
1049	} // if
1050	delete extr;
1051	} // if
1052
1053	Declaration * decl = cur->build();
1054	if ( decl ) {
1055	if ( TypedefDecl * typedefDecl = dynamic_cast<TypedefDecl *>( decl ) ) {
1056	if ( unionDecl ) { // is the typedef alias a union aggregate ?
1057	// This code handles a special issue with the attribute transparent_union.
1058	//
1059	// typedef union U { int i; } typedef_name __attribute__(( aligned(16) )) __attribute__(( transparent_union ))
1060	//
1061	// Here the attribute aligned goes with the typedef_name, so variables declared of this type are
1062	// aligned. However, the attribute transparent_union must be moved from the typedef_name to
1063	// alias union U. Currently, this is the only know attribute that must be moved from typedef to
1064	// alias.
1065
1066	// If typedef is an alias for a union, then its alias type was hoisted above and remembered.
1067	if ( UnionInstType * unionInstType = dynamic_cast<UnionInstType *>( typedefDecl->base ) ) {
1068	// Remove all transparent_union attributes from typedef and move to alias union.
1069	list<Attribute *>::iterator attr;
1070	for ( attr = unionInstType->attributes.begin(); attr != unionInstType->attributes.end(); ) { // forward order
1071	if ( (attr)->name == "transparent_union" \|\| (attr)->name == "__transparent_union__" ) {
1072	list<Attribute *>::iterator cur = attr; // remember current node
1073	attr++; // advance iterator
1074	unionDecl->attributes.emplace_back( *cur ); // move current
1075	unionInstType->attributes.erase( cur ); // remove current
1076	} else {
1077	attr++; // advance iterator
1078	} // if
1079	} // for
1080	} // if
1081	} // if
1082	} // if
1083
1084	// don't include anonymous declaration for named aggregates, but do include them for anonymous aggregates, e.g.:
1085	// struct S {
1086	// struct T { int x; }; // no anonymous member
1087	// struct { int y; }; // anonymous member
1088	// struct T; // anonymous member
1089	// };
1090	if ( ! (extracted && decl->name == "" && ! anon && ! cur->get_inLine()) ) {
1091	if ( decl->name == "" ) {
1092	if ( DeclarationWithType * dwt = dynamic_cast<DeclarationWithType *>( decl ) ) {
1093	if ( ReferenceToType * aggr = dynamic_cast<ReferenceToType *>( dwt->get_type() ) ) {
1094	if ( aggr->name.find("anonymous") == std::string::npos ) {
1095	if ( ! cur->get_inLine() ) {
1096	// temporary: warn about anonymous member declarations of named types, since
1097	// this conflicts with the syntax for the forward declaration of an anonymous type
1098	SemanticWarning( cur->location, Warning::AggrForwardDecl, aggr->name.c_str() );
1099	} // if
1100	} // if
1101	} // if
1102	} // if
1103	} // if
1104	decl->location = cur->location;
1105	*out++ = decl;
1106	} // if
1107	} // if
1108	} catch( SemanticErrorException & e ) {
1109	errors.append( e );
1110	} // try
1111	} // for
1112
1113	if ( ! errors.isEmpty() ) {
1114	throw errors;
1115	} // if
1116	} // buildList
1117
1118	// currently only builds assertions, function parameters, and return values
1119	void buildList( const DeclarationNode * firstNode, std::list< DeclarationWithType * > & outputList ) {
1120	SemanticErrorException errors;
1121	std::back_insert_iterator< std::list< DeclarationWithType * > > out( outputList );
1122
1123	for ( const DeclarationNode * cur = firstNode; cur; cur = dynamic_cast< DeclarationNode * >( cur->get_next() ) ) {
1124	try {
1125	Declaration * decl = cur->build();
1126	assert( decl );
1127	if ( DeclarationWithType * dwt = dynamic_cast< DeclarationWithType * >( decl ) ) {
1128	dwt->location = cur->location;
1129	*out++ = dwt;
1130	} else if ( StructDecl * agg = dynamic_cast< StructDecl * >( decl ) ) {
1131	// e.g., int foo(struct S) {}
1132	StructInstType * inst = new StructInstType( Type::Qualifiers(), agg->name );
1133	auto obj = new ObjectDecl( "", Type::StorageClasses(), linkage, nullptr, inst, nullptr );
1134	obj->location = cur->location;
1135	*out++ = obj;
1136	delete agg;
1137	} else if ( UnionDecl * agg = dynamic_cast< UnionDecl * >( decl ) ) {
1138	// e.g., int foo(union U) {}
1139	UnionInstType * inst = new UnionInstType( Type::Qualifiers(), agg->name );
1140	auto obj = new ObjectDecl( "", Type::StorageClasses(), linkage, nullptr, inst, nullptr );
1141	obj->location = cur->location;
1142	*out++ = obj;
1143	} else if ( EnumDecl * agg = dynamic_cast< EnumDecl * >( decl ) ) {
1144	// e.g., int foo(enum E) {}
1145	EnumInstType * inst = new EnumInstType( Type::Qualifiers(), agg->name );
1146	auto obj = new ObjectDecl( "", Type::StorageClasses(), linkage, nullptr, inst, nullptr );
1147	obj->location = cur->location;
1148	*out++ = obj;
1149	} // if
1150	} catch( SemanticErrorException & e ) {
1151	errors.append( e );
1152	} // try
1153	} // for
1154
1155	if ( ! errors.isEmpty() ) {
1156	throw errors;
1157	} // if
1158	} // buildList
1159
1160	void buildTypeList( const DeclarationNode * firstNode, std::list< Type * > & outputList ) {
1161	SemanticErrorException errors;
1162	std::back_insert_iterator< std::list< Type * > > out( outputList );
1163	const DeclarationNode * cur = firstNode;
1164
1165	while ( cur ) {
1166	try {
1167	* out++ = cur->buildType();
1168	} catch( SemanticErrorException & e ) {
1169	errors.append( e );
1170	} // try
1171	cur = dynamic_cast< DeclarationNode * >( cur->get_next() );
1172	} // while
1173
1174	if ( ! errors.isEmpty() ) {
1175	throw errors;
1176	} // if
1177	} // buildTypeList
1178
1179	Declaration * DeclarationNode::build() const {
1180	if ( ! error.empty() ) SemanticError( this, error + " in declaration of " );
1181
1182	if ( asmStmt ) {
1183	return new AsmDecl( strict_dynamic_cast<AsmStmt *>( asmStmt->build() ) );
1184	} // if
1185	if ( directiveStmt ) {
1186	return new DirectiveDecl( strict_dynamic_cast<DirectiveStmt *>( directiveStmt->build() ) );
1187	} // if
1188
1189	if ( variable.tyClass != TypeDecl::NUMBER_OF_KINDS ) {
1190	// otype is internally converted to dtype + otype parameters
1191	static const TypeDecl::Kind kindMap[] = { TypeDecl::Dtype, TypeDecl::Dtype, TypeDecl::Dtype, TypeDecl::Ftype, TypeDecl::Ttype, TypeDecl::Dimension };
1192	static_assert( sizeof(kindMap) / sizeof(kindMap[0]) == TypeDecl::NUMBER_OF_KINDS, "DeclarationNode::build: kindMap is out of sync." );
1193	assertf( variable.tyClass < sizeof(kindMap)/sizeof(kindMap[0]), "Variable's tyClass is out of bounds." );
1194	TypeDecl * ret = new TypeDecl( *name, Type::StorageClasses(), nullptr, kindMap[ variable.tyClass ], variable.tyClass == TypeDecl::Otype \|\| variable.tyClass == TypeDecl::DStype, variable.initializer ? variable.initializer->buildType() : nullptr );
1195	buildList( variable.assertions, ret->get_assertions() );
1196	return ret;
1197	} // if
1198
1199	if ( type ) {
1200	// Function specifiers can only appear on a function definition/declaration.
1201	//
1202	// inline _Noreturn int f(); // allowed
1203	// inline _Noreturn int g( int i ); // allowed
1204	// inline _Noreturn int i; // disallowed
1205	if ( type->kind != TypeData::Function && funcSpecs.any() ) {
1206	SemanticError( this, "invalid function specifier for " );
1207	} // if
1208	// Forall qualifier can only appear on a function/aggregate definition/declaration.
1209	//
1210	// forall int f(); // allowed
1211	// forall int g( int i ); // allowed
1212	// forall int i; // disallowed
1213	if ( type->kind != TypeData::Function && type->forall ) {
1214	SemanticError( this, "invalid type qualifier for " );
1215	} // if
1216	bool isDelete = initializer && initializer->get_isDelete();
1217	Declaration * decl = buildDecl( type, name ? *name : string( "" ), storageClasses, maybeBuild( bitfieldWidth ), funcSpecs, linkage, asmName, isDelete ? nullptr : maybeBuild(initializer), attributes )->set_extension( extension );
1218	if ( isDelete ) {
1219	DeclarationWithType * dwt = strict_dynamic_cast<DeclarationWithType *>( decl );
1220	dwt->isDeleted = true;
1221	}
1222	return decl;
1223	} // if
1224
1225	if ( assert.condition ) {
1226	return new StaticAssertDecl( maybeBuild( assert.condition ), strict_dynamic_cast< ConstantExpr * >( maybeClone( assert.message ) ) );
1227	}
1228
1229	// SUE's cannot have function specifiers, either
1230	//
1231	// inline _Noreturn struct S { ... }; // disallowed
1232	// inline _Noreturn enum E { ... }; // disallowed
1233	if ( funcSpecs.any() ) {
1234	SemanticError( this, "invalid function specifier for " );
1235	} // if
1236	if ( enumInLine ) {
1237	return new InlineMemberDecl( *name, storageClasses, linkage, nullptr );
1238	} // if
1239	assertf( name, "ObjectDecl must a have name\n" );
1240	return (new ObjectDecl( *name, storageClasses, linkage, maybeBuild( bitfieldWidth ), nullptr, maybeBuild( initializer ) ))->set_asmName( asmName )->set_extension( extension );
1241	}
1242
1243	Type * DeclarationNode::buildType() const {
1244	assert( type );
1245
1246	switch ( type->kind ) {
1247	case TypeData::Enum:
1248	case TypeData::Aggregate: {
1249	ReferenceToType * ret = buildComAggInst( type, attributes, linkage );
1250	buildList( type->aggregate.actuals, ret->get_parameters() );
1251	return ret;
1252	}
1253	case TypeData::Symbolic: {
1254	TypeInstType * ret = new TypeInstType( buildQualifiers( type ), *type->symbolic.name, false, attributes );
1255	buildList( type->symbolic.actuals, ret->get_parameters() );
1256	return ret;
1257	}
1258	default:
1259	Type * simpletypes = typebuild( type );
1260	simpletypes->get_attributes() = attributes; // copy because member is const
1261	return simpletypes;
1262	} // switch
1263	}
1264
1265	// Local Variables: //
1266	// tab-width: 4 //
1267	// mode: c++ //
1268	// compile-command: "make install" //
1269	// End: //

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