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source: src/Parser/TypeData.cc @ d49bfa8

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

Last change on this file since d49bfa8 was ac10576, checked in by Andrew Beach <ajbeach@…>, 7 years ago
Replaced emptyQualifiers with noQualifiers for consistancy with noLabels and noAttributes.
Property mode set to `100644`
File size: 31.9 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	// TypeData.cc --
8	//
9	// Author : Rodolfo G. Esteves
10	// Created On : Sat May 16 15:12:51 2015
11	// Last Modified By : Andrew Beach
12	// Last Modified On : Tus Jul 18 10:10:00 2017
13	// Update Count : 566
14	//
15
16	#include <cassert>
17	#include <algorithm>
18	#include <iterator>
19	#include "Common/utility.h"
20	#include "TypeData.h"
21	#include "SynTree/Type.h"
22	#include "SynTree/Declaration.h"
23	#include "SynTree/Expression.h"
24	#include "SynTree/Statement.h"
25	#include "SynTree/Initializer.h"
26	using namespace std;
27
28	TypeData::TypeData( Kind k ) : kind( k ), base( nullptr ), forall( nullptr ) /, PTR1( (void)(0xdeadbeefdeadbeef)), PTR2( (void)(0xdeadbeefdeadbeef) ) / {
29	switch ( kind ) {
30	case Unknown:
31	case Pointer:
32	case EnumConstant:
33	// nothing else to initialize
34	break;
35	case Basic:
36	// basic = new Basic_t;
37	break;
38	case Array:
39	// array = new Array_t;
40	array.dimension = nullptr;
41	array.isVarLen = false;
42	array.isStatic = false;
43	break;
44	case Function:
45	// function = new Function_t;
46	function.params = nullptr;
47	function.idList = nullptr;
48	function.oldDeclList = nullptr;
49	function.body = nullptr;
50	function.newStyle = false;
51	break;
52	// Enum is an Aggregate, so both structures are initialized together.
53	case Enum:
54	// enumeration = new Enumeration_t;
55	enumeration.name = nullptr;
56	enumeration.constants = nullptr;
57	enumeration.body = false;
58	case Aggregate:
59	// aggregate = new Aggregate_t;
60	aggregate.name = nullptr;
61	aggregate.params = nullptr;
62	aggregate.actuals = nullptr;
63	aggregate.fields = nullptr;
64	aggregate.body = false;
65	aggregate.tagged = false;
66	aggregate.parent = nullptr;
67	break;
68	case AggregateInst:
69	// aggInst = new AggInst_t;
70	aggInst.aggregate = nullptr;
71	aggInst.params = nullptr;
72	aggInst.hoistType = false;;
73	break;
74	case Symbolic:
75	case SymbolicInst:
76	// symbolic = new Symbolic_t;
77	symbolic.name = nullptr;
78	symbolic.params = nullptr;
79	symbolic.actuals = nullptr;
80	symbolic.assertions = nullptr;
81	break;
82	case Tuple:
83	// tuple = new Tuple_t;
84	tuple = nullptr;
85	break;
86	case Typeof:
87	// typeexpr = new Typeof_t;
88	typeexpr = nullptr;
89	break;
90	case Builtin:
91	// builtin = new Builtin_t;
92	break;
93	} // switch
94	} // TypeData::TypeData
95
96	TypeData::~TypeData() {
97	delete base;
98	delete forall;
99
100	switch ( kind ) {
101	case Unknown:
102	case Pointer:
103	case EnumConstant:
104	// nothing to destroy
105	break;
106	case Basic:
107	// delete basic;
108	break;
109	case Array:
110	delete array.dimension;
111	// delete array;
112	break;
113	case Function:
114	delete function.params;
115	delete function.idList;
116	delete function.oldDeclList;
117	delete function.body;
118	// delete function;
119	break;
120	case Aggregate:
121	delete aggregate.name;
122	delete aggregate.params;
123	delete aggregate.actuals;
124	delete aggregate.fields;
125	delete aggregate.parent;
126	// delete aggregate;
127	break;
128	case AggregateInst:
129	delete aggInst.aggregate;
130	delete aggInst.params;
131	// delete aggInst;
132	break;
133	case Enum:
134	delete enumeration.name;
135	delete enumeration.constants;
136	// delete enumeration;
137	break;
138	case Symbolic:
139	case SymbolicInst:
140	delete symbolic.name;
141	delete symbolic.params;
142	delete symbolic.actuals;
143	delete symbolic.assertions;
144	// delete symbolic;
145	break;
146	case Tuple:
147	// delete tuple->members;
148	delete tuple;
149	break;
150	case Typeof:
151	// delete typeexpr->expr;
152	delete typeexpr;
153	break;
154	case Builtin:
155	// delete builtin;
156	break;
157	} // switch
158	} // TypeData::~TypeData
159
160	TypeData * TypeData::clone() const {
161	TypeData * newtype = new TypeData( kind );
162	newtype->qualifiers = qualifiers;
163	newtype->base = maybeClone( base );
164	newtype->forall = maybeClone( forall );
165
166	switch ( kind ) {
167	case Unknown:
168	case EnumConstant:
169	case Pointer:
170	// nothing else to copy
171	break;
172	case Basic:
173	newtype->basictype = basictype;
174	newtype->complextype = complextype;
175	newtype->signedness = signedness;
176	newtype->length = length;
177	break;
178	case Array:
179	newtype->array.dimension = maybeClone( array.dimension );
180	newtype->array.isVarLen = array.isVarLen;
181	newtype->array.isStatic = array.isStatic;
182	break;
183	case Function:
184	newtype->function.params = maybeClone( function.params );
185	newtype->function.idList = maybeClone( function.idList );
186	newtype->function.oldDeclList = maybeClone( function.oldDeclList );
187	newtype->function.body = maybeClone( function.body );
188	newtype->function.newStyle = function.newStyle;
189	break;
190	case Aggregate:
191	newtype->aggregate.name = aggregate.name ? new string( *aggregate.name ) : nullptr;
192	newtype->aggregate.params = maybeClone( aggregate.params );
193	newtype->aggregate.actuals = maybeClone( aggregate.actuals );
194	newtype->aggregate.fields = maybeClone( aggregate.fields );
195	newtype->aggregate.kind = aggregate.kind;
196	newtype->aggregate.body = aggregate.body;
197	newtype->aggregate.tagged = aggregate.tagged;
198	newtype->aggregate.parent = aggregate.parent ? new string( *aggregate.parent ) : nullptr;
199	break;
200	case AggregateInst:
201	newtype->aggInst.aggregate = maybeClone( aggInst.aggregate );
202	newtype->aggInst.params = maybeClone( aggInst.params );
203	newtype->aggInst.hoistType = aggInst.hoistType;
204	break;
205	case Enum:
206	newtype->enumeration.name = enumeration.name ? new string( *enumeration.name ) : nullptr;
207	newtype->enumeration.constants = maybeClone( enumeration.constants );
208	newtype->enumeration.body = enumeration.body;
209	break;
210	case Symbolic:
211	case SymbolicInst:
212	newtype->symbolic.name = symbolic.name ? new string( *symbolic.name ) : nullptr;
213	newtype->symbolic.params = maybeClone( symbolic.params );
214	newtype->symbolic.actuals = maybeClone( symbolic.actuals );
215	newtype->symbolic.assertions = maybeClone( symbolic.assertions );
216	newtype->symbolic.isTypedef = symbolic.isTypedef;
217	break;
218	case Tuple:
219	newtype->tuple = maybeClone( tuple );
220	break;
221	case Typeof:
222	newtype->typeexpr = maybeClone( typeexpr );
223	break;
224	case Builtin:
225	assert( builtintype == DeclarationNode::Zero \|\| builtintype == DeclarationNode::One );
226	newtype->builtintype = builtintype;
227	break;
228	} // switch
229	return newtype;
230	} // TypeData::clone
231
232	void TypeData::print( ostream &os, int indent ) const {
233	for ( int i = 0; i < Type::NumTypeQualifier; i += 1 ) {
234	if ( qualifiers[i] ) os << Type::QualifiersNames[ i ] << ' ';
235	} // for
236
237	if ( forall ) {
238	os << "forall " << endl;
239	forall->printList( os, indent + 4 );
240	} // if
241
242	switch ( kind ) {
243	case Unknown:
244	os << "entity of unknown type ";
245	break;
246	case Pointer:
247	os << "pointer ";
248	if ( base ) {
249	os << "to ";
250	base->print( os, indent );
251	} // if
252	break;
253	case EnumConstant:
254	os << "enumeration constant ";
255	break;
256	case Basic:
257	if ( signedness != DeclarationNode::NoSignedness ) os << DeclarationNode::signednessNames[ signedness ] << " ";
258	if ( length != DeclarationNode::NoLength ) os << DeclarationNode::lengthNames[ length ] << " ";
259	assert( basictype != DeclarationNode::NoBasicType );
260	os << DeclarationNode::basicTypeNames[ basictype ] << " ";
261	if ( complextype != DeclarationNode::NoComplexType ) os << DeclarationNode::complexTypeNames[ complextype ] << " ";
262	break;
263	case Array:
264	if ( array.isStatic ) {
265	os << "static ";
266	} // if
267	if ( array.dimension ) {
268	os << "array of ";
269	array.dimension->printOneLine( os, indent );
270	} else if ( array.isVarLen ) {
271	os << "variable-length array of ";
272	} else {
273	os << "open array of ";
274	} // if
275	if ( base ) {
276	base->print( os, indent );
277	} // if
278	break;
279	case Function:
280	os << "function" << endl;
281	if ( function.params ) {
282	os << string( indent + 2, ' ' ) << "with parameters " << endl;
283	function.params->printList( os, indent + 4 );
284	} else {
285	os << string( indent + 2, ' ' ) << "with no parameters " << endl;
286	} // if
287	if ( function.idList ) {
288	os << string( indent + 2, ' ' ) << "with old-style identifier list " << endl;
289	function.idList->printList( os, indent + 4 );
290	} // if
291	if ( function.oldDeclList ) {
292	os << string( indent + 2, ' ' ) << "with old-style declaration list " << endl;
293	function.oldDeclList->printList( os, indent + 4 );
294	} // if
295	os << string( indent + 2, ' ' ) << "returning ";
296	if ( base ) {
297	base->print( os, indent + 4 );
298	} else {
299	os << "nothing ";
300	} // if
301	os << endl;
302	if ( function.body ) {
303	os << string( indent + 2, ' ' ) << "with body " << endl;
304	function.body->printList( os, indent + 2 );
305	} // if
306	break;
307	case Aggregate:
308	os << DeclarationNode::aggregateNames[ aggregate.kind ] << ' ' << *aggregate.name << endl;
309	if ( aggregate.params ) {
310	os << string( indent + 2, ' ' ) << "with type parameters " << endl;
311	aggregate.params->printList( os, indent + 4 );
312	} // if
313	if ( aggregate.actuals ) {
314	os << string( indent + 2, ' ' ) << "instantiated with actual parameters " << endl;
315	aggregate.actuals->printList( os, indent + 4 );
316	} // if
317	if ( aggregate.fields ) {
318	os << string( indent + 2, ' ' ) << "with members " << endl;
319	aggregate.fields->printList( os, indent + 4 );
320	} // if
321	if ( aggregate.body ) {
322	os << string( indent + 2, ' ' ) << " with body " << endl;
323	} // if
324	break;
325	case AggregateInst:
326	if ( aggInst.aggregate ) {
327	os << "instance of " ;
328	aggInst.aggregate->print( os, indent );
329	} else {
330	os << "instance of an unspecified aggregate ";
331	} // if
332	if ( aggInst.params ) {
333	os << string( indent + 2, ' ' ) << "with parameters " << endl;
334	aggInst.params->printList( os, indent + 2 );
335	} // if
336	break;
337	case Enum:
338	os << "enumeration ";
339	if ( enumeration.constants ) {
340	os << "with constants" << endl;
341	enumeration.constants->printList( os, indent + 2 );
342	} // if
343	if ( enumeration.body ) {
344	os << string( indent + 2, ' ' ) << " with body " << endl;
345	} // if
346	break;
347	case SymbolicInst:
348	os << "instance of type " << *symbolic.name;
349	if ( symbolic.actuals ) {
350	os << " with parameters" << endl;
351	symbolic.actuals->printList( os, indent + 2 );
352	} // if
353	break;
354	case Symbolic:
355	if ( symbolic.isTypedef ) {
356	os << "typedef definition ";
357	} else {
358	os << "type definition ";
359	} // if
360	if ( symbolic.params ) {
361	os << endl << string( indent + 2, ' ' ) << "with parameters" << endl;
362	symbolic.params->printList( os, indent + 2 );
363	} // if
364	if ( symbolic.assertions ) {
365	os << endl << string( indent + 2, ' ' ) << "with assertions" << endl;
366	symbolic.assertions->printList( os, indent + 4 );
367	os << string( indent + 2, ' ' );
368	} // if
369	if ( base ) {
370	os << "for ";
371	base->print( os, indent + 2 );
372	} // if
373	break;
374	case Tuple:
375	os << "tuple ";
376	if ( tuple ) {
377	os << "with members " << endl;
378	tuple->printList( os, indent + 2 );
379	} // if
380	break;
381	case Typeof:
382	os << "type-of expression ";
383	if ( typeexpr ) {
384	typeexpr->print( os, indent + 2 );
385	} // if
386	break;
387	case Builtin:
388	os << "gcc builtin type";
389	break;
390	default:
391	os << "internal error: TypeData::print " << kind << endl;
392	assert( false );
393	} // switch
394	} // TypeData::print
395
396	template< typename ForallList >
397	void buildForall( const DeclarationNode * firstNode, ForallList &outputList ) {
398	buildList( firstNode, outputList );
399	for ( typename ForallList::iterator i = outputList.begin(); i != outputList.end(); ++i ) {
400	TypeDecl * td = static_cast<TypeDecl >(i);
401	if ( td->get_kind() == TypeDecl::Any ) {
402	// add assertion parameters to `type' tyvars in reverse order
403	// add dtor: void ^?{}(T *)
404	FunctionType * dtorType = new FunctionType( Type::Qualifiers(), false );
405	dtorType->get_parameters().push_back( new ObjectDecl( "", Type::StorageClasses(), LinkageSpec::Cforall, nullptr, new PointerType( Type::Qualifiers(), new TypeInstType( Type::Qualifiers(), td->get_name(), *i ) ), nullptr ) );
406	td->get_assertions().push_front( new FunctionDecl( "^?{}", Type::StorageClasses(), LinkageSpec::Cforall, dtorType, nullptr ) );
407
408	// add copy ctor: void ?{}(T *, T)
409	FunctionType * copyCtorType = new FunctionType( Type::Qualifiers(), false );
410	copyCtorType->get_parameters().push_back( new ObjectDecl( "", Type::StorageClasses(), LinkageSpec::Cforall, nullptr, new PointerType( Type::Qualifiers(), new TypeInstType( Type::Qualifiers(), td->get_name(), *i ) ), nullptr ) );
411	copyCtorType->get_parameters().push_back( new ObjectDecl( "", Type::StorageClasses(), LinkageSpec::Cforall, nullptr, new TypeInstType( Type::Qualifiers(), td->get_name(), *i ), nullptr ) );
412	td->get_assertions().push_front( new FunctionDecl( "?{}", Type::StorageClasses(), LinkageSpec::Cforall, copyCtorType, nullptr ) );
413
414	// add default ctor: void ?{}(T *)
415	FunctionType * ctorType = new FunctionType( Type::Qualifiers(), false );
416	ctorType->get_parameters().push_back( new ObjectDecl( "", Type::StorageClasses(), LinkageSpec::Cforall, nullptr, new PointerType( Type::Qualifiers(), new TypeInstType( Type::Qualifiers(), td->get_name(), *i ) ), nullptr ) );
417	td->get_assertions().push_front( new FunctionDecl( "?{}", Type::StorageClasses(), LinkageSpec::Cforall, ctorType, nullptr ) );
418
419	// add assignment operator: T * ?=?(T *, T)
420	FunctionType * assignType = new FunctionType( Type::Qualifiers(), false );
421	assignType->get_parameters().push_back( new ObjectDecl( "", Type::StorageClasses(), LinkageSpec::Cforall, nullptr, new PointerType( Type::Qualifiers(), new TypeInstType( Type::Qualifiers(), td->get_name(), *i ) ), nullptr ) );
422	assignType->get_parameters().push_back( new ObjectDecl( "", Type::StorageClasses(), LinkageSpec::Cforall, nullptr, new TypeInstType( Type::Qualifiers(), td->get_name(), *i ), nullptr ) );
423	assignType->get_returnVals().push_back( new ObjectDecl( "", Type::StorageClasses(), LinkageSpec::Cforall, nullptr, new TypeInstType( Type::Qualifiers(), td->get_name(), *i ), nullptr ) );
424	td->get_assertions().push_front( new FunctionDecl( "?=?", Type::StorageClasses(), LinkageSpec::Cforall, assignType, nullptr ) );
425	} // if
426	} // for
427	}
428
429	Type * typebuild( const TypeData * td ) {
430	assert( td );
431	switch ( td->kind ) {
432	case TypeData::Unknown:
433	// fill in implicit int
434	return new BasicType( buildQualifiers( td ), BasicType::SignedInt );
435	case TypeData::Basic:
436	return buildBasicType( td );
437	case TypeData::Pointer:
438	return buildPointer( td );
439	case TypeData::Array:
440	return buildArray( td );
441	case TypeData::Function:
442	return buildFunction( td );
443	case TypeData::AggregateInst:
444	return buildAggInst( td );
445	case TypeData::EnumConstant:
446	// the name gets filled in later -- by SymTab::Validate
447	return new EnumInstType( buildQualifiers( td ), "" );
448	case TypeData::SymbolicInst:
449	return buildSymbolicInst( td );;
450	case TypeData::Tuple:
451	return buildTuple( td );
452	case TypeData::Typeof:
453	return buildTypeof( td );
454	case TypeData::Builtin:
455	if(td->builtintype == DeclarationNode::Zero) {
456	return new ZeroType( noQualifiers );
457	}
458	else if(td->builtintype == DeclarationNode::One) {
459	return new OneType( noQualifiers );
460	}
461	else {
462	return new VarArgsType( buildQualifiers( td ) );
463	}
464	case TypeData::Symbolic:
465	case TypeData::Enum:
466	case TypeData::Aggregate:
467	assert( false );
468	} // switch
469	return nullptr;
470	} // typebuild
471
472	TypeData * typeextractAggregate( const TypeData * td, bool toplevel ) {
473	TypeData * ret = nullptr;
474
475	switch ( td->kind ) {
476	case TypeData::Aggregate:
477	if ( ! toplevel && td->aggregate.fields ) {
478	ret = td->clone();
479	} // if
480	break;
481	case TypeData::Enum:
482	if ( ! toplevel && td->enumeration.constants ) {
483	ret = td->clone();
484	} // if
485	break;
486	case TypeData::AggregateInst:
487	if ( td->aggInst.aggregate ) {
488	ret = typeextractAggregate( td->aggInst.aggregate, false );
489	} // if
490	break;
491	default:
492	if ( td->base ) {
493	ret = typeextractAggregate( td->base, false );
494	} // if
495	} // switch
496	return ret;
497	} // typeextractAggregate
498
499	Type::Qualifiers buildQualifiers( const TypeData * td ) {
500	return td->qualifiers;
501	} // buildQualifiers
502
503	Type * buildBasicType( const TypeData * td ) {
504	BasicType::Kind ret;
505
506	switch ( td->basictype ) {
507	case DeclarationNode::Void:
508	if ( td->signedness != DeclarationNode::NoSignedness && td->length != DeclarationNode::NoLength ) {
509	throw SemanticError( "invalid type specifier \"void\" in type: ", td );
510	} // if
511
512	return new VoidType( buildQualifiers( td ) );
513	break;
514
515	case DeclarationNode::Bool:
516	if ( td->signedness != DeclarationNode::NoSignedness ) {
517	throw SemanticError( string( "invalid type specifier " ) + DeclarationNode::signednessNames[ td->signedness ] + " in type: ", td );
518	} // if
519	if ( td->length != DeclarationNode::NoLength ) {
520	throw SemanticError( string( "invalid type specifier " ) + DeclarationNode::lengthNames[ td->length ] + " in type: ", td );
521	} // if
522
523	ret = BasicType::Bool;
524	break;
525
526	case DeclarationNode::Char:
527	// C11 Standard 6.2.5.15: The three types char, signed char, and unsigned char are collectively called the
528	// character types. The implementation shall define char to have the same range, representation, and behavior as
529	// either signed char or unsigned char.
530	static BasicType::Kind chartype[] = { BasicType::SignedChar, BasicType::UnsignedChar, BasicType::Char };
531
532	if ( td->length != DeclarationNode::NoLength ) {
533	throw SemanticError( string( "invalid type specifier " ) + DeclarationNode::lengthNames[ td->length ] + " in type: ", td );
534	} // if
535
536	ret = chartype[ td->signedness ];
537	break;
538
539	case DeclarationNode::Int:
540	static BasicType::Kind inttype[2][4] = {
541	{ BasicType::ShortSignedInt, BasicType::LongSignedInt, BasicType::LongLongSignedInt, BasicType::SignedInt },
542	{ BasicType::ShortUnsignedInt, BasicType::LongUnsignedInt, BasicType::LongLongUnsignedInt, BasicType::UnsignedInt },
543	};
544
545	Integral: ;
546	if ( td->signedness == DeclarationNode::NoSignedness ) {
547	const_cast<TypeData *>(td)->signedness = DeclarationNode::Signed;
548	} // if
549	ret = inttype[ td->signedness ][ td->length ];
550	break;
551
552	case DeclarationNode::Float:
553	case DeclarationNode::Double:
554	case DeclarationNode::LongDouble: // not set until below
555	static BasicType::Kind floattype[3][3] = {
556	{ BasicType::FloatComplex, BasicType::DoubleComplex, BasicType::LongDoubleComplex },
557	{ BasicType::FloatImaginary, BasicType::DoubleImaginary, BasicType::LongDoubleImaginary },
558	{ BasicType::Float, BasicType::Double, BasicType::LongDouble },
559	};
560
561	FloatingPoint: ;
562	if ( td->signedness != DeclarationNode::NoSignedness ) {
563	throw SemanticError( string( "invalid type specifier " ) + DeclarationNode::signednessNames[ td->signedness ] + " in type: ", td );
564	} // if
565	if ( td->length == DeclarationNode::Short \|\| td->length == DeclarationNode::LongLong ) {
566	throw SemanticError( string( "invalid type specifier " ) + DeclarationNode::lengthNames[ td->length ] + " in type: ", td );
567	} // if
568	if ( td->basictype == DeclarationNode::Float && td->length == DeclarationNode::Long ) {
569	throw SemanticError( "invalid type specifier \"long\" in type: ", td );
570	} // if
571	if ( td->length == DeclarationNode::Long ) {
572	const_cast<TypeData *>(td)->basictype = DeclarationNode::LongDouble;
573	} // if
574
575	ret = floattype[ td->complextype ][ td->basictype - DeclarationNode::Float ];
576	break;
577
578	case DeclarationNode::NoBasicType:
579	// No basic type in declaration => default double for Complex/Imaginary and int type for integral types
580	if ( td->complextype == DeclarationNode::Complex \|\| td->complextype == DeclarationNode::Imaginary ) {
581	const_cast<TypeData *>(td)->basictype = DeclarationNode::Double;
582	goto FloatingPoint;
583	} // if
584
585	const_cast<TypeData *>(td)->basictype = DeclarationNode::Int;
586	goto Integral;
587	default:
588	assert(false);
589	return nullptr;
590	} // switch
591
592	BasicType * bt = new BasicType( buildQualifiers( td ), ret );
593	buildForall( td->forall, bt->get_forall() );
594	return bt;
595	} // buildBasicType
596
597	PointerType * buildPointer( const TypeData * td ) {
598	PointerType * pt;
599	if ( td->base ) {
600	pt = new PointerType( buildQualifiers( td ), typebuild( td->base ) );
601	} else {
602	pt = new PointerType( buildQualifiers( td ), new BasicType( Type::Qualifiers(), BasicType::SignedInt ) );
603	} // if
604	buildForall( td->forall, pt->get_forall() );
605	return pt;
606	} // buildPointer
607
608	ArrayType * buildArray( const TypeData * td ) {
609	ArrayType * at;
610	if ( td->base ) {
611	at = new ArrayType( buildQualifiers( td ), typebuild( td->base ), maybeBuild< Expression >( td->array.dimension ),
612	td->array.isVarLen, td->array.isStatic );
613	} else {
614	at = new ArrayType( buildQualifiers( td ), new BasicType( Type::Qualifiers(), BasicType::SignedInt ),
615	maybeBuild< Expression >( td->array.dimension ), td->array.isVarLen, td->array.isStatic );
616	} // if
617	buildForall( td->forall, at->get_forall() );
618	return at;
619	} // buildPointer
620
621	AggregateDecl * buildAggregate( const TypeData * td, std::list< Attribute * > attributes, LinkageSpec::Spec linkage ) {
622	assert( td->kind == TypeData::Aggregate );
623	AggregateDecl * at;
624	switch ( td->aggregate.kind ) {
625	case DeclarationNode::Struct:
626	if ( td->aggregate.tagged ) {
627	at = new StructDecl( *td->aggregate.name, td->aggregate.parent, attributes, linkage );
628	buildForall( td->aggregate.params, at->get_parameters() );
629	break;
630	}
631	case DeclarationNode::Coroutine:
632	case DeclarationNode::Monitor:
633	case DeclarationNode::Thread:
634	at = new StructDecl( *td->aggregate.name, td->aggregate.kind, attributes, linkage );
635	buildForall( td->aggregate.params, at->get_parameters() );
636	break;
637	case DeclarationNode::Union:
638	at = new UnionDecl( *td->aggregate.name, attributes );
639	buildForall( td->aggregate.params, at->get_parameters() );
640	break;
641	case DeclarationNode::Trait:
642	at = new TraitDecl( *td->aggregate.name, attributes );
643	buildList( td->aggregate.params, at->get_parameters() );
644	break;
645	default:
646	assert( false );
647	} // switch
648
649	buildList( td->aggregate.fields, at->get_members() );
650	at->set_body( td->aggregate.body );
651
652	return at;
653	} // buildAggregate
654
655	ReferenceToType * buildComAggInst( const TypeData * type, std::list< Attribute * > attributes, LinkageSpec::Spec linkage ) {
656	switch ( type->kind ) {
657	case TypeData::Enum: {
658	if ( type->enumeration.body ) {
659	EnumDecl * typedecl = buildEnum( type, attributes );
660	return new EnumInstType( buildQualifiers( type ), typedecl );
661	} else {
662	return new EnumInstType( buildQualifiers( type ), *type->enumeration.name );
663	} // if
664	}
665	case TypeData::Aggregate: {
666	ReferenceToType * ret;
667	if ( type->aggregate.body ) {
668	AggregateDecl * typedecl = buildAggregate( type, attributes, linkage );
669	switch ( type->aggregate.kind ) {
670	case DeclarationNode::Struct:
671	case DeclarationNode::Coroutine:
672	case DeclarationNode::Monitor:
673	case DeclarationNode::Thread:
674	ret = new StructInstType( buildQualifiers( type ), (StructDecl *)typedecl );
675	break;
676	case DeclarationNode::Union:
677	ret = new UnionInstType( buildQualifiers( type ), (UnionDecl *)typedecl );
678	break;
679	case DeclarationNode::Trait:
680	assert( false );
681	//ret = new TraitInstType( buildQualifiers( type ), (TraitDecl *)typedecl );
682	break;
683	default:
684	assert( false );
685	} // switch
686	} else {
687	switch ( type->aggregate.kind ) {
688	case DeclarationNode::Struct:
689	case DeclarationNode::Coroutine:
690	case DeclarationNode::Monitor:
691	case DeclarationNode::Thread:
692	ret = new StructInstType( buildQualifiers( type ), *type->aggregate.name );
693	break;
694	case DeclarationNode::Union:
695	ret = new UnionInstType( buildQualifiers( type ), *type->aggregate.name );
696	break;
697	case DeclarationNode::Trait:
698	ret = new TraitInstType( buildQualifiers( type ), *type->aggregate.name );
699	break;
700	default:
701	assert( false );
702	} // switch
703	} // if
704	return ret;
705	}
706	default:
707	assert( false );
708	} // switch
709	} // buildAggInst
710
711	ReferenceToType * buildAggInst( const TypeData * td ) {
712	assert( td->kind == TypeData::AggregateInst );
713
714	// ReferenceToType * ret = buildComAggInst( td->aggInst.aggregate, std::list< Attribute * >() );
715	ReferenceToType * ret = nullptr;
716	TypeData * type = td->aggInst.aggregate;
717	switch ( type->kind ) {
718	case TypeData::Enum: {
719	return new EnumInstType( buildQualifiers( type ), *type->enumeration.name );
720	}
721	case TypeData::Aggregate: {
722	switch ( type->aggregate.kind ) {
723	case DeclarationNode::Struct:
724	case DeclarationNode::Coroutine:
725	case DeclarationNode::Monitor:
726	case DeclarationNode::Thread:
727	ret = new StructInstType( buildQualifiers( type ), *type->aggregate.name );
728	break;
729	case DeclarationNode::Union:
730	ret = new UnionInstType( buildQualifiers( type ), *type->aggregate.name );
731	break;
732	case DeclarationNode::Trait:
733	ret = new TraitInstType( buildQualifiers( type ), *type->aggregate.name );
734	break;
735	default:
736	assert( false );
737	} // switch
738	}
739	break;
740	default:
741	assert( false );
742	} // switch
743
744	ret->set_hoistType( td->aggInst.hoistType );
745	buildList( td->aggInst.params, ret->get_parameters() );
746	buildForall( td->forall, ret->get_forall() );
747	return ret;
748	} // buildAggInst
749
750	NamedTypeDecl * buildSymbolic( const TypeData * td, const string & name, Type::StorageClasses scs ) {
751	assert( td->kind == TypeData::Symbolic );
752	NamedTypeDecl * ret;
753	assert( td->base );
754	if ( td->symbolic.isTypedef ) {
755	ret = new TypedefDecl( name, scs, typebuild( td->base ) );
756	} else {
757	ret = new TypeDecl( name, scs, typebuild( td->base ), TypeDecl::Any );
758	} // if
759	buildList( td->symbolic.params, ret->get_parameters() );
760	buildList( td->symbolic.assertions, ret->get_assertions() );
761	return ret;
762	} // buildSymbolic
763
764	EnumDecl * buildEnum( const TypeData * td, std::list< Attribute * > attributes ) {
765	assert( td->kind == TypeData::Enum );
766	EnumDecl * ret = new EnumDecl( *td->enumeration.name, attributes );
767	buildList( td->enumeration.constants, ret->get_members() );
768	list< Declaration * >::iterator members = ret->get_members().begin();
769	for ( const DeclarationNode * cur = td->enumeration. constants; cur != nullptr; cur = dynamic_cast< DeclarationNode * >( cur->get_next() ), ++members ) {
770	if ( cur->has_enumeratorValue() ) {
771	ObjectDecl * member = dynamic_cast< ObjectDecl * >(* members);
772	member->set_init( new SingleInit( maybeMoveBuild< Expression >( cur->consume_enumeratorValue() ) ) );
773	} // if
774	} // for
775	ret->set_body( td->enumeration.body );
776	return ret;
777	} // buildEnum
778
779	TypeInstType * buildSymbolicInst( const TypeData * td ) {
780	assert( td->kind == TypeData::SymbolicInst );
781	TypeInstType * ret = new TypeInstType( buildQualifiers( td ), *td->symbolic.name, false );
782	buildList( td->symbolic.actuals, ret->get_parameters() );
783	buildForall( td->forall, ret->get_forall() );
784	return ret;
785	} // buildSymbolicInst
786
787	TupleType * buildTuple( const TypeData * td ) {
788	assert( td->kind == TypeData::Tuple );
789	std::list< Type * > types;
790	buildTypeList( td->tuple, types );
791	TupleType * ret = new TupleType( buildQualifiers( td ), types );
792	buildForall( td->forall, ret->get_forall() );
793	return ret;
794	} // buildTuple
795
796	TypeofType * buildTypeof( const TypeData * td ) {
797	assert( td->kind == TypeData::Typeof );
798	assert( td->typeexpr );
799	// assert( td->typeexpr->expr );
800	return new TypeofType( buildQualifiers( td ), td->typeexpr->build() );
801	} // buildTypeof
802
803	Declaration * buildDecl( const TypeData * td, const string &name, Type::StorageClasses scs, Expression * bitfieldWidth, Type::FuncSpecifiers funcSpec, LinkageSpec::Spec linkage, ConstantExpr asmName, Initializer init, std::list< Attribute * > attributes ) {
804	if ( td->kind == TypeData::Function ) {
805	if ( td->function.idList ) { // KR function ?
806	buildKRFunction( td->function ); // transform into C11 function
807	} // if
808
809	FunctionDecl * decl;
810	Statement * stmt = maybeBuild<Statement>( td->function.body );
811	CompoundStmt * body = dynamic_cast< CompoundStmt * >( stmt );
812	decl = new FunctionDecl( name, scs, linkage, buildFunction( td ), body, attributes, funcSpec );
813	return decl->set_asmName( asmName );
814	} else if ( td->kind == TypeData::Aggregate ) {
815	return buildAggregate( td, attributes, linkage );
816	} else if ( td->kind == TypeData::Enum ) {
817	return buildEnum( td, attributes );
818	} else if ( td->kind == TypeData::Symbolic ) {
819	return buildSymbolic( td, name, scs );
820	} else {
821	return (new ObjectDecl( name, scs, linkage, bitfieldWidth, typebuild( td ), init, attributes ))->set_asmName( asmName );
822	} // if
823	return nullptr;
824	} // buildDecl
825
826	FunctionType * buildFunction( const TypeData * td ) {
827	assert( td->kind == TypeData::Function );
828	bool hasEllipsis = td->function.params ? td->function.params->get_hasEllipsis() : true;
829	if ( ! td->function.params ) hasEllipsis = ! td->function.newStyle;
830	FunctionType * ft = new FunctionType( buildQualifiers( td ), hasEllipsis );
831	buildList( td->function.params, ft->get_parameters() );
832	buildForall( td->forall, ft->get_forall() );
833	if ( td->base ) {
834	switch ( td->base->kind ) {
835	case TypeData::Tuple:
836	buildList( td->base->tuple, ft->get_returnVals() );
837	break;
838	default:
839	ft->get_returnVals().push_back( dynamic_cast< DeclarationWithType * >( buildDecl( td->base, "", Type::StorageClasses(), nullptr, Type::FuncSpecifiers(), LinkageSpec::Cforall, nullptr ) ) );
840	} // switch
841	} else {
842	ft->get_returnVals().push_back( new ObjectDecl( "", Type::StorageClasses(), LinkageSpec::Cforall, nullptr, new BasicType( Type::Qualifiers(), BasicType::SignedInt ), nullptr ) );
843	} // if
844	return ft;
845	} // buildFunction
846
847	// Transform KR routine declarations into C99 routine declarations:
848	//
849	// rtn( a, b, c ) int a, c; double b {} => int rtn( int a, double c, int b ) {}
850	//
851	// The type information for each post-declaration is moved to the corresponding pre-parameter and the post-declaration
852	// is deleted. Note, the order of the parameter names may not be the same as the declaration names. Duplicate names and
853	// extra names are disallowed.
854	//
855	// Note, there is no KR routine-prototype syntax:
856	//
857	// rtn( a, b, c ) int a, c; double b; // invalid KR prototype
858	// rtn(); // valid KR prototype
859
860	void buildKRFunction( const TypeData::Function_t & function ) {
861	assert( ! function.params );
862	// loop over declaration first as it is easier to spot errors
863	for ( DeclarationNode * decl = function.oldDeclList; decl != nullptr; decl = dynamic_cast< DeclarationNode * >( decl->get_next() ) ) {
864	// scan ALL parameter names for each declaration name to check for duplicates
865	for ( DeclarationNode * param = function.idList; param != nullptr; param = dynamic_cast< DeclarationNode * >( param->get_next() ) ) {
866	if ( decl->name == param->name ) {
867	// type set => parameter name already transformed by a declaration names so there is a duplicate
868	// declaration name attempting a second transformation
869	if ( param->type ) throw SemanticError( string( "duplicate declaration name " ) + *param->name );
870	// declaration type reset => declaration already transformed by a parameter name so there is a duplicate
871	// parameter name attempting a second transformation
872	if ( ! decl->type ) throw SemanticError( string( "duplicate parameter name " ) + *param->name );
873	param->type = decl->type; // set copy declaration type to parameter type
874	decl->type = nullptr; // reset declaration type
875	param->attributes.splice( param->attributes.end(), decl->attributes ); // copy and reset attributes from declaration to parameter
876	} // if
877	} // for
878	// declaration type still set => type not moved to a matching parameter so there is a missing parameter name
879	if ( decl->type ) throw SemanticError( string( "missing name in parameter list " ) + *decl->name );
880	} // for
881
882	// Parameter names without a declaration default to type int:
883	//
884	// rtb( a, b, c ) const char * b; {} => int rtn( int a, const char * b, int c ) {}
885
886	for ( DeclarationNode * param = function.idList; param != nullptr; param = dynamic_cast< DeclarationNode * >( param->get_next() ) ) {
887	if ( ! param->type ) { // generate type int for empty parameter type
888	param->type = new TypeData( TypeData::Basic );
889	param->type->basictype = DeclarationNode::Int;
890	} // if
891	} // for
892
893	function.params = function.idList; // newly modified idList becomes parameters
894	function.idList = nullptr; // idList now empty
895	delete function.oldDeclList; // deletes entire list
896	function.oldDeclList = nullptr; // reset
897	} // buildKRFunction
898
899	// Local Variables: //
900	// tab-width: 4 //
901	// mode: c++ //
902	// compile-command: "make install" //
903	// End: //

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