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source: src/ResolvExpr/Resolver.cc @ c2409fd

ADTarm-ehast-experimentalenumforall-pointer-decayjacob/cs343-translationnew-ast-unique-exprpthread-emulationqualifiedEnum

Last change on this file since c2409fd was b107885, checked in by Fangren Yu <f37yu@…>, 3 years ago
remove warning message
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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	// Resolver.cc --
8	//
9	// Author : Aaron B. Moss
10	// Created On : Sun May 17 12:17:01 2015
11	// Last Modified By : Andrew Beach
12	// Last Modified On : Fri Mar 27 11:58:00 2020
13	// Update Count : 242
14	//
15
16	#include <cassert> // for strict_dynamic_cast, assert
17	#include <memory> // for allocator, allocator_traits<...
18	#include <tuple> // for get
19	#include <vector> // for vector
20
21	#include "Alternative.h" // for Alternative, AltList
22	#include "AlternativeFinder.h" // for AlternativeFinder, resolveIn...
23	#include "Candidate.hpp"
24	#include "CandidateFinder.hpp"
25	#include "CurrentObject.h" // for CurrentObject
26	#include "RenameVars.h" // for RenameVars, global_renamer
27	#include "Resolver.h"
28	#include "ResolveTypeof.h"
29	#include "ResolvMode.h" // for ResolvMode
30	#include "typeops.h" // for extractResultType
31	#include "Unify.h" // for unify
32	#include "CompilationState.h"
33	#include "AST/Chain.hpp"
34	#include "AST/Decl.hpp"
35	#include "AST/Init.hpp"
36	#include "AST/Pass.hpp"
37	#include "AST/Print.hpp"
38	#include "AST/SymbolTable.hpp"
39	#include "AST/Type.hpp"
40	#include "Common/PassVisitor.h" // for PassVisitor
41	#include "Common/SemanticError.h" // for SemanticError
42	#include "Common/Stats/ResolveTime.h" // for ResolveTime::start(), ResolveTime::stop()
43	#include "Common/utility.h" // for ValueGuard, group_iterate
44	#include "InitTweak/GenInit.h"
45	#include "InitTweak/InitTweak.h" // for isIntrinsicSingleArgCallStmt
46	#include "ResolvExpr/TypeEnvironment.h" // for TypeEnvironment
47	#include "SymTab/Autogen.h" // for SizeType
48	#include "SymTab/Indexer.h" // for Indexer
49	#include "SymTab/Mangler.h" // for Mangler
50	#include "SynTree/Declaration.h" // for ObjectDecl, TypeDecl, Declar...
51	#include "SynTree/Expression.h" // for Expression, CastExpr, InitExpr
52	#include "SynTree/Initializer.h" // for ConstructorInit, SingleInit
53	#include "SynTree/Statement.h" // for ForStmt, Statement, BranchStmt
54	#include "SynTree/Type.h" // for Type, BasicType, PointerType
55	#include "SynTree/TypeSubstitution.h" // for TypeSubstitution
56	#include "SynTree/Visitor.h" // for acceptAll, maybeAccept
57	#include "Tuples/Tuples.h"
58	#include "Validate/FindSpecialDecls.h" // for SizeType
59
60	using namespace std;
61
62	namespace ResolvExpr {
63	struct Resolver_old final : public WithIndexer, public WithGuards, public WithVisitorRef<Resolver_old>, public WithShortCircuiting, public WithStmtsToAdd {
64	Resolver_old() {}
65	Resolver_old( const SymTab::Indexer & other ) {
66	indexer = other;
67	}
68
69	void previsit( FunctionDecl * functionDecl );
70	void postvisit( FunctionDecl * functionDecl );
71	void previsit( ObjectDecl * objectDecll );
72	void previsit( EnumDecl * enumDecl );
73	void previsit( StaticAssertDecl * assertDecl );
74
75	void previsit( ArrayType * at );
76	void previsit( PointerType * at );
77
78	void previsit( ExprStmt * exprStmt );
79	void previsit( AsmExpr * asmExpr );
80	void previsit( AsmStmt * asmStmt );
81	void previsit( IfStmt * ifStmt );
82	void previsit( WhileStmt * whileStmt );
83	void previsit( ForStmt * forStmt );
84	void previsit( SwitchStmt * switchStmt );
85	void previsit( CaseStmt * caseStmt );
86	void previsit( BranchStmt * branchStmt );
87	void previsit( ReturnStmt * returnStmt );
88	void previsit( ThrowStmt * throwStmt );
89	void previsit( CatchStmt * catchStmt );
90	void postvisit( CatchStmt * catchStmt );
91	void previsit( WaitForStmt * stmt );
92
93	void previsit( SingleInit * singleInit );
94	void previsit( ListInit * listInit );
95	void previsit( ConstructorInit * ctorInit );
96	private:
97	typedef std::list< Initializer * >::iterator InitIterator;
98
99	template< typename PtrType >
100	void handlePtrType( PtrType * type );
101
102	void fallbackInit( ConstructorInit * ctorInit );
103
104	Type * functionReturn = nullptr;
105	CurrentObject currentObject = nullptr;
106	bool inEnumDecl = false;
107	};
108
109	struct ResolveWithExprs : public WithIndexer, public WithGuards, public WithVisitorRef<ResolveWithExprs>, public WithShortCircuiting, public WithStmtsToAdd {
110	void previsit( FunctionDecl * );
111	void previsit( WithStmt * );
112
113	void resolveWithExprs( std::list< Expression * > & withExprs, std::list< Statement * > & newStmts );
114	};
115
116	void resolve( std::list< Declaration * > translationUnit ) {
117	PassVisitor<Resolver_old> resolver;
118	acceptAll( translationUnit, resolver );
119	}
120
121	void resolveDecl( Declaration * decl, const SymTab::Indexer & indexer ) {
122	PassVisitor<Resolver_old> resolver( indexer );
123	maybeAccept( decl, resolver );
124	}
125
126	namespace {
127	struct DeleteFinder_old : public WithShortCircuiting {
128	DeletedExpr * delExpr = nullptr;
129	void previsit( DeletedExpr * expr ) {
130	if ( delExpr ) visit_children = false;
131	else delExpr = expr;
132	}
133
134	void previsit( Expression * ) {
135	if ( delExpr ) visit_children = false;
136	}
137	};
138	}
139
140	DeletedExpr * findDeletedExpr( Expression * expr ) {
141	PassVisitor<DeleteFinder_old> finder;
142	expr->accept( finder );
143	return finder.pass.delExpr;
144	}
145
146	namespace {
147	struct StripCasts_old {
148	Expression * postmutate( CastExpr * castExpr ) {
149	if ( castExpr->isGenerated && ResolvExpr::typesCompatible( castExpr->arg->result, castExpr->result, SymTab::Indexer() ) ) {
150	// generated cast is to the same type as its argument, so it's unnecessary -- remove it
151	Expression * expr = castExpr->arg;
152	castExpr->arg = nullptr;
153	std::swap( expr->env, castExpr->env );
154	return expr;
155	}
156	return castExpr;
157	}
158
159	static void strip( Expression *& expr ) {
160	PassVisitor<StripCasts_old> stripper;
161	expr = expr->acceptMutator( stripper );
162	}
163	};
164
165	void finishExpr( Expression & expr, const TypeEnvironment & env, TypeSubstitution oldenv = nullptr ) {
166	expr->env = oldenv ? oldenv->clone() : new TypeSubstitution;
167	env.makeSubstitution( *expr->env );
168	StripCasts_old::strip( expr ); // remove unnecessary casts that may be buried in an expression
169	}
170
171	void removeExtraneousCast( Expression *& expr, const SymTab::Indexer & indexer ) {
172	if ( CastExpr * castExpr = dynamic_cast< CastExpr * >( expr ) ) {
173	if ( typesCompatible( castExpr->arg->result, castExpr->result, indexer ) ) {
174	// cast is to the same type as its argument, so it's unnecessary -- remove it
175	expr = castExpr->arg;
176	castExpr->arg = nullptr;
177	std::swap( expr->env, castExpr->env );
178	delete castExpr;
179	}
180	}
181	}
182	} // namespace
183
184	namespace {
185	void findUnfinishedKindExpression(Expression * untyped, Alternative & alt, const SymTab::Indexer & indexer, const std::string & kindStr, std::function<bool(const Alternative &)> pred, ResolvMode mode = ResolvMode{} ) {
186	assertf( untyped, "expected a non-null expression." );
187
188	// xxx - this isn't thread-safe, but should work until we parallelize the resolver
189	static unsigned recursion_level = 0;
190
191	++recursion_level;
192	TypeEnvironment env;
193	AlternativeFinder finder( indexer, env );
194	finder.find( untyped, recursion_level == 1 ? mode.atTopLevel() : mode );
195	--recursion_level;
196
197	#if 0
198	if ( finder.get_alternatives().size() != 1 ) {
199	std::cerr << "untyped expr is ";
200	untyped->print( std::cerr );
201	std::cerr << std::endl << "alternatives are:";
202	for ( const Alternative & alt : finder.get_alternatives() ) {
203	alt.print( std::cerr );
204	} // for
205	} // if
206	#endif
207
208	// produce filtered list of alternatives
209	AltList candidates;
210	for ( Alternative & alt : finder.get_alternatives() ) {
211	if ( pred( alt ) ) {
212	candidates.push_back( std::move( alt ) );
213	}
214	}
215
216	// produce invalid error if no candidates
217	if ( candidates.empty() ) {
218	SemanticError( untyped, toString( "No reasonable alternatives for ", kindStr, (kindStr != "" ? " " : ""), "expression: ") );
219	}
220
221	// search for cheapest candidate
222	AltList winners;
223	bool seen_undeleted = false;
224	for ( unsigned i = 0; i < candidates.size(); ++i ) {
225	int c = winners.empty() ? -1 : candidates[i].cost.compare( winners.front().cost );
226
227	if ( c > 0 ) continue; // skip more expensive than winner
228
229	if ( c < 0 ) {
230	// reset on new cheapest
231	seen_undeleted = ! findDeletedExpr( candidates[i].expr );
232	winners.clear();
233	} else /* if ( c == 0 ) */ {
234	if ( findDeletedExpr( candidates[i].expr ) ) {
235	// skip deleted expression if already seen one equivalent-cost not
236	if ( seen_undeleted ) continue;
237	} else if ( ! seen_undeleted ) {
238	// replace list of equivalent-cost deleted expressions with one non-deleted
239	winners.clear();
240	seen_undeleted = true;
241	}
242	}
243
244	winners.emplace_back( std::move( candidates[i] ) );
245	}
246
247	// promote alternative.cvtCost to .cost
248	// xxx - I don't know why this is done, but I'm keeping the behaviour from findMinCost
249	for ( Alternative& winner : winners ) {
250	winner.cost = winner.cvtCost;
251	}
252
253	// produce ambiguous errors, if applicable
254	if ( winners.size() != 1 ) {
255	std::ostringstream stream;
256	stream << "Cannot choose between " << winners.size() << " alternatives for " << kindStr << (kindStr != "" ? " " : "") << "expression\n";
257	untyped->print( stream );
258	stream << " Alternatives are:\n";
259	printAlts( winners, stream, 1 );
260	SemanticError( untyped->location, stream.str() );
261	}
262
263	// single selected choice
264	Alternative& choice = winners.front();
265
266	// fail on only expression deleted
267	if ( ! seen_undeleted ) {
268	SemanticError( untyped->location, choice.expr, "Unique best alternative includes deleted identifier in " );
269	}
270
271	// xxx - check for ambiguous expressions
272
273	// output selected choice
274	alt = std::move( choice );
275	}
276
277	/// resolve `untyped` to the expression whose alternative satisfies `pred` with the lowest cost; kindStr is used for providing better error messages
278	void findKindExpression(Expression *& untyped, const SymTab::Indexer & indexer, const std::string & kindStr, std::function<bool(const Alternative &)> pred, ResolvMode mode = ResolvMode{}) {
279	if ( ! untyped ) return;
280	Alternative choice;
281	findUnfinishedKindExpression( untyped, choice, indexer, kindStr, pred, mode );
282	finishExpr( choice.expr, choice.env, untyped->env );
283	delete untyped;
284	untyped = choice.expr;
285	choice.expr = nullptr;
286	}
287
288	bool standardAlternativeFilter( const Alternative & ) {
289	// currently don't need to filter, under normal circumstances.
290	// in the future, this may be useful for removing deleted expressions
291	return true;
292	}
293	} // namespace
294
295	// used in resolveTypeof
296	Expression * resolveInVoidContext( Expression * expr, const SymTab::Indexer & indexer ) {
297	TypeEnvironment env;
298	return resolveInVoidContext( expr, indexer, env );
299	}
300
301	Expression * resolveInVoidContext( Expression * expr, const SymTab::Indexer & indexer, TypeEnvironment & env ) {
302	// it's a property of the language that a cast expression has either 1 or 0 interpretations; if it has 0
303	// interpretations, an exception has already been thrown.
304	assertf( expr, "expected a non-null expression." );
305
306	CastExpr * untyped = new CastExpr( expr ); // cast to void
307	untyped->location = expr->location;
308
309	// set up and resolve expression cast to void
310	Alternative choice;
311	findUnfinishedKindExpression( untyped, choice, indexer, "", standardAlternativeFilter, ResolvMode::withAdjustment() );
312	CastExpr * castExpr = strict_dynamic_cast< CastExpr * >( choice.expr );
313	assert( castExpr );
314	env = std::move( choice.env );
315
316	// clean up resolved expression
317	Expression * ret = castExpr->arg;
318	castExpr->arg = nullptr;
319
320	// unlink the arg so that it isn't deleted twice at the end of the program
321	untyped->arg = nullptr;
322	return ret;
323	}
324
325	void findVoidExpression( Expression *& untyped, const SymTab::Indexer & indexer ) {
326	resetTyVarRenaming();
327	TypeEnvironment env;
328	Expression * newExpr = resolveInVoidContext( untyped, indexer, env );
329	finishExpr( newExpr, env, untyped->env );
330	delete untyped;
331	untyped = newExpr;
332	}
333
334	void findSingleExpression( Expression *& untyped, const SymTab::Indexer & indexer ) {
335	findKindExpression( untyped, indexer, "", standardAlternativeFilter );
336	}
337
338	void findSingleExpression( Expression & untyped, Type type, const SymTab::Indexer & indexer ) {
339	assert( untyped && type );
340	// transfer location to generated cast for error purposes
341	CodeLocation location = untyped->location;
342	untyped = new CastExpr( untyped, type );
343	untyped->location = location;
344	findSingleExpression( untyped, indexer );
345	removeExtraneousCast( untyped, indexer );
346	}
347
348	namespace {
349	bool isIntegralType( const Alternative & alt ) {
350	Type * type = alt.expr->result;
351	if ( dynamic_cast< EnumInstType * >( type ) ) {
352	return true;
353	} else if ( BasicType * bt = dynamic_cast< BasicType * >( type ) ) {
354	return bt->isInteger();
355	} else if ( dynamic_cast< ZeroType* >( type ) != nullptr \|\| dynamic_cast< OneType* >( type ) != nullptr ) {
356	return true;
357	} else {
358	return false;
359	} // if
360	}
361
362	void findIntegralExpression( Expression *& untyped, const SymTab::Indexer & indexer ) {
363	findKindExpression( untyped, indexer, "condition", isIntegralType );
364	}
365	}
366
367
368	bool isStructOrUnion( const Alternative & alt ) {
369	Type * t = alt.expr->result->stripReferences();
370	return dynamic_cast< StructInstType * >( t ) \|\| dynamic_cast< UnionInstType * >( t );
371	}
372
373	void resolveWithExprs( std::list< Declaration * > & translationUnit ) {
374	PassVisitor<ResolveWithExprs> resolver;
375	acceptAll( translationUnit, resolver );
376	}
377
378	void ResolveWithExprs::resolveWithExprs( std::list< Expression * > & withExprs, std::list< Statement * > & newStmts ) {
379	for ( Expression *& expr : withExprs ) {
380	// only struct- and union-typed expressions are viable candidates
381	findKindExpression( expr, indexer, "with statement", isStructOrUnion );
382
383	// if with expression might be impure, create a temporary so that it is evaluated once
384	if ( Tuples::maybeImpure( expr ) ) {
385	static UniqueName tmpNamer( "_with_tmp_" );
386	ObjectDecl * tmp = ObjectDecl::newObject( tmpNamer.newName(), expr->result->clone(), new SingleInit( expr ) );
387	expr = new VariableExpr( tmp );
388	newStmts.push_back( new DeclStmt( tmp ) );
389	if ( InitTweak::isConstructable( tmp->type ) ) {
390	// generate ctor/dtor and resolve them
391	tmp->init = InitTweak::genCtorInit( tmp );
392	tmp->accept( *visitor );
393	}
394	}
395	}
396	}
397
398	void ResolveWithExprs::previsit( WithStmt * withStmt ) {
399	resolveWithExprs( withStmt->exprs, stmtsToAddBefore );
400	}
401
402	void ResolveWithExprs::previsit( FunctionDecl * functionDecl ) {
403	{
404	// resolve with-exprs with parameters in scope and add any newly generated declarations to the
405	// front of the function body.
406	auto guard = makeFuncGuard( [this]() { indexer.enterScope(); }, [this](){ indexer.leaveScope(); } );
407	indexer.addFunctionType( functionDecl->type );
408	std::list< Statement * > newStmts;
409	resolveWithExprs( functionDecl->withExprs, newStmts );
410	if ( functionDecl->statements ) {
411	functionDecl->statements->kids.splice( functionDecl->statements->kids.begin(), newStmts );
412	} else {
413	assertf( functionDecl->withExprs.empty() && newStmts.empty(), "Function %s without a body has with-clause and/or generated with declarations.", functionDecl->name.c_str() );
414	}
415	}
416	}
417
418	void Resolver_old::previsit( ObjectDecl * objectDecl ) {
419	// To handle initialization of routine pointers, e.g., int (*fp)(int) = foo(), means that
420	// class-variable initContext is changed multiple time because the LHS is analysed twice.
421	// The second analysis changes initContext because of a function type can contain object
422	// declarations in the return and parameter types. So each value of initContext is
423	// retained, so the type on the first analysis is preserved and used for selecting the RHS.
424	GuardValue( currentObject );
425	currentObject = CurrentObject( objectDecl->get_type() );
426	if ( inEnumDecl && dynamic_cast< EnumInstType * >( objectDecl->get_type() ) ) {
427	// enumerator initializers should not use the enum type to initialize, since
428	// the enum type is still incomplete at this point. Use signed int instead.
429	currentObject = CurrentObject( new BasicType( Type::Qualifiers(), BasicType::SignedInt ) );
430	}
431	}
432
433	template< typename PtrType >
434	void Resolver_old::handlePtrType( PtrType * type ) {
435	if ( type->get_dimension() ) {
436	findSingleExpression( type->dimension, Validate::SizeType->clone(), indexer );
437	}
438	}
439
440	void Resolver_old::previsit( ArrayType * at ) {
441	handlePtrType( at );
442	}
443
444	void Resolver_old::previsit( PointerType * pt ) {
445	handlePtrType( pt );
446	}
447
448	void Resolver_old::previsit( FunctionDecl * functionDecl ) {
449	#if 0
450	std::cerr << "resolver visiting functiondecl ";
451	functionDecl->print( std::cerr );
452	std::cerr << std::endl;
453	#endif
454	GuardValue( functionReturn );
455	functionReturn = ResolvExpr::extractResultType( functionDecl->type );
456	}
457
458	void Resolver_old::postvisit( FunctionDecl * functionDecl ) {
459	// default value expressions have an environment which shouldn't be there and trips up
460	// later passes.
461	// xxx - it might be necessary to somehow keep the information from this environment, but I
462	// can't currently see how it's useful.
463	for ( Declaration * d : functionDecl->type->parameters ) {
464	if ( ObjectDecl * obj = dynamic_cast< ObjectDecl * >( d ) ) {
465	if ( SingleInit * init = dynamic_cast< SingleInit * >( obj->init ) ) {
466	delete init->value->env;
467	init->value->env = nullptr;
468	}
469	}
470	}
471	}
472
473	void Resolver_old::previsit( EnumDecl * ) {
474	// in case we decide to allow nested enums
475	GuardValue( inEnumDecl );
476	inEnumDecl = true;
477	}
478
479	void Resolver_old::previsit( StaticAssertDecl * assertDecl ) {
480	findIntegralExpression( assertDecl->condition, indexer );
481	}
482
483	void Resolver_old::previsit( ExprStmt * exprStmt ) {
484	visit_children = false;
485	assertf( exprStmt->expr, "ExprStmt has null Expression in resolver" );
486	findVoidExpression( exprStmt->expr, indexer );
487	}
488
489	void Resolver_old::previsit( AsmExpr * asmExpr ) {
490	visit_children = false;
491	findVoidExpression( asmExpr->operand, indexer );
492	}
493
494	void Resolver_old::previsit( AsmStmt * asmStmt ) {
495	visit_children = false;
496	acceptAll( asmStmt->get_input(), *visitor );
497	acceptAll( asmStmt->get_output(), *visitor );
498	}
499
500	void Resolver_old::previsit( IfStmt * ifStmt ) {
501	findIntegralExpression( ifStmt->condition, indexer );
502	}
503
504	void Resolver_old::previsit( WhileStmt * whileStmt ) {
505	findIntegralExpression( whileStmt->condition, indexer );
506	}
507
508	void Resolver_old::previsit( ForStmt * forStmt ) {
509	if ( forStmt->condition ) {
510	findIntegralExpression( forStmt->condition, indexer );
511	} // if
512
513	if ( forStmt->increment ) {
514	findVoidExpression( forStmt->increment, indexer );
515	} // if
516	}
517
518	void Resolver_old::previsit( SwitchStmt * switchStmt ) {
519	GuardValue( currentObject );
520	findIntegralExpression( switchStmt->condition, indexer );
521
522	currentObject = CurrentObject( switchStmt->condition->result );
523	}
524
525	void Resolver_old::previsit( CaseStmt * caseStmt ) {
526	if ( caseStmt->condition ) {
527	std::list< InitAlternative > initAlts = currentObject.getOptions();
528	assertf( initAlts.size() == 1, "SwitchStmt did not correctly resolve an integral expression." );
529	// must remove cast from case statement because RangeExpr cannot be cast.
530	Expression * newExpr = new CastExpr( caseStmt->condition, initAlts.front().type->clone() );
531	findSingleExpression( newExpr, indexer );
532	// case condition cannot have a cast in C, so it must be removed, regardless of whether it performs a conversion.
533	// Ideally we would perform the conversion internally here.
534	if ( CastExpr * castExpr = dynamic_cast< CastExpr * >( newExpr ) ) {
535	newExpr = castExpr->arg;
536	castExpr->arg = nullptr;
537	std::swap( newExpr->env, castExpr->env );
538	delete castExpr;
539	}
540	caseStmt->condition = newExpr;
541	}
542	}
543
544	void Resolver_old::previsit( BranchStmt * branchStmt ) {
545	visit_children = false;
546	// must resolve the argument for a computed goto
547	if ( branchStmt->get_type() == BranchStmt::Goto ) { // check for computed goto statement
548	if ( branchStmt->computedTarget ) {
549	// computed goto argument is void *
550	findSingleExpression( branchStmt->computedTarget, new PointerType( Type::Qualifiers(), new VoidType( Type::Qualifiers() ) ), indexer );
551	} // if
552	} // if
553	}
554
555	void Resolver_old::previsit( ReturnStmt * returnStmt ) {
556	visit_children = false;
557	if ( returnStmt->expr ) {
558	findSingleExpression( returnStmt->expr, functionReturn->clone(), indexer );
559	} // if
560	}
561
562	void Resolver_old::previsit( ThrowStmt * throwStmt ) {
563	visit_children = false;
564	// TODO: Replace *exception type with &exception type.
565	if ( throwStmt->get_expr() ) {
566	const StructDecl * exception_decl = indexer.lookupStruct( "__cfaehm_base_exception_t" );
567	assert( exception_decl );
568	Type * exceptType = new PointerType( noQualifiers, new StructInstType( noQualifiers, const_cast<StructDecl *>(exception_decl) ) );
569	findSingleExpression( throwStmt->expr, exceptType, indexer );
570	}
571	}
572
573	void Resolver_old::previsit( CatchStmt * catchStmt ) {
574	// Until we are very sure this invarent (ifs that move between passes have thenPart)
575	// holds, check it. This allows a check for when to decode the mangling.
576	if ( IfStmt * ifStmt = dynamic_cast<IfStmt *>( catchStmt->body ) ) {
577	assert( ifStmt->thenPart );
578	}
579	// Encode the catchStmt so the condition can see the declaration.
580	if ( catchStmt->cond ) {
581	IfStmt * ifStmt = new IfStmt( catchStmt->cond, nullptr, catchStmt->body );
582	catchStmt->cond = nullptr;
583	catchStmt->body = ifStmt;
584	}
585	}
586
587	void Resolver_old::postvisit( CatchStmt * catchStmt ) {
588	// Decode the catchStmt so everything is stored properly.
589	IfStmt * ifStmt = dynamic_cast<IfStmt *>( catchStmt->body );
590	if ( nullptr != ifStmt && nullptr == ifStmt->thenPart ) {
591	assert( ifStmt->condition );
592	assert( ifStmt->elsePart );
593	catchStmt->cond = ifStmt->condition;
594	catchStmt->body = ifStmt->elsePart;
595	ifStmt->condition = nullptr;
596	ifStmt->elsePart = nullptr;
597	delete ifStmt;
598	}
599	}
600
601	template< typename iterator_t >
602	inline bool advance_to_mutex( iterator_t & it, const iterator_t & end ) {
603	while( it != end && !(*it)->get_type()->get_mutex() ) {
604	it++;
605	}
606
607	return it != end;
608	}
609
610	void Resolver_old::previsit( WaitForStmt * stmt ) {
611	visit_children = false;
612
613	// Resolve all clauses first
614	for( auto& clause : stmt->clauses ) {
615
616	TypeEnvironment env;
617	AlternativeFinder funcFinder( indexer, env );
618
619	// Find all alternatives for a function in canonical form
620	funcFinder.findWithAdjustment( clause.target.function );
621
622	if ( funcFinder.get_alternatives().empty() ) {
623	stringstream ss;
624	ss << "Use of undeclared indentifier '";
625	ss << strict_dynamic_cast<NameExpr*>( clause.target.function )->name;
626	ss << "' in call to waitfor";
627	SemanticError( stmt->location, ss.str() );
628	}
629
630	if(clause.target.arguments.empty()) {
631	SemanticError( stmt->location, "Waitfor clause must have at least one mutex parameter");
632	}
633
634	// Find all alternatives for all arguments in canonical form
635	std::vector< AlternativeFinder > argAlternatives;
636	funcFinder.findSubExprs( clause.target.arguments.begin(), clause.target.arguments.end(), back_inserter( argAlternatives ) );
637
638	// List all combinations of arguments
639	std::vector< AltList > possibilities;
640	combos( argAlternatives.begin(), argAlternatives.end(), back_inserter( possibilities ) );
641
642	AltList func_candidates;
643	std::vector< AltList > args_candidates;
644
645	// For every possible function :
646	// try matching the arguments to the parameters
647	// not the other way around because we have more arguments than parameters
648	SemanticErrorException errors;
649	for ( Alternative & func : funcFinder.get_alternatives() ) {
650	try {
651	PointerType * pointer = dynamic_cast< PointerType* >( func.expr->get_result()->stripReferences() );
652	if( !pointer ) {
653	SemanticError( func.expr->get_result(), "candidate not viable: not a pointer type\n" );
654	}
655
656	FunctionType * function = dynamic_cast< FunctionType* >( pointer->get_base() );
657	if( !function ) {
658	SemanticError( pointer->get_base(), "candidate not viable: not a function type\n" );
659	}
660
661
662	{
663	auto param = function->parameters.begin();
664	auto param_end = function->parameters.end();
665
666	if( !advance_to_mutex( param, param_end ) ) {
667	SemanticError(function, "candidate function not viable: no mutex parameters\n");
668	}
669	}
670
671	Alternative newFunc( func );
672	// Strip reference from function
673	referenceToRvalueConversion( newFunc.expr, newFunc.cost );
674
675	// For all the set of arguments we have try to match it with the parameter of the current function alternative
676	for ( auto & argsList : possibilities ) {
677
678	try {
679	// Declare data structures need for resolution
680	OpenVarSet openVars;
681	AssertionSet resultNeed, resultHave;
682	TypeEnvironment resultEnv( func.env );
683	makeUnifiableVars( function, openVars, resultNeed );
684	// add all type variables as open variables now so that those not used in the parameter
685	// list are still considered open.
686	resultEnv.add( function->forall );
687
688	// Load type variables from arguemnts into one shared space
689	simpleCombineEnvironments( argsList.begin(), argsList.end(), resultEnv );
690
691	// Make sure we don't widen any existing bindings
692	resultEnv.forbidWidening();
693
694	// Find any unbound type variables
695	resultEnv.extractOpenVars( openVars );
696
697	auto param = function->parameters.begin();
698	auto param_end = function->parameters.end();
699
700	int n_mutex_param = 0;
701
702	// For every arguments of its set, check if it matches one of the parameter
703	// The order is important
704	for( auto & arg : argsList ) {
705
706	// Ignore non-mutex arguments
707	if( !advance_to_mutex( param, param_end ) ) {
708	// We ran out of parameters but still have arguments
709	// this function doesn't match
710	SemanticError( function, toString("candidate function not viable: too many mutex arguments, expected ", n_mutex_param, "\n" ));
711	}
712
713	n_mutex_param++;
714
715	// Check if the argument matches the parameter type in the current scope
716	if( ! unify( arg.expr->get_result(), (*param)->get_type(), resultEnv, resultNeed, resultHave, openVars, this->indexer ) ) {
717	// Type doesn't match
718	stringstream ss;
719	ss << "candidate function not viable: no known convertion from '";
720	(*param)->get_type()->print( ss );
721	ss << "' to '";
722	arg.expr->get_result()->print( ss );
723	ss << "' with env '";
724	resultEnv.print(ss);
725	ss << "'\n";
726	SemanticError( function, ss.str() );
727	}
728
729	param++;
730	}
731
732	// All arguments match !
733
734	// Check if parameters are missing
735	if( advance_to_mutex( param, param_end ) ) {
736	do {
737	n_mutex_param++;
738	param++;
739	} while( advance_to_mutex( param, param_end ) );
740
741	// We ran out of arguments but still have parameters left
742	// this function doesn't match
743	SemanticError( function, toString("candidate function not viable: too few mutex arguments, expected ", n_mutex_param, "\n" ));
744	}
745
746	// All parameters match !
747
748	// Finish the expressions to tie in the proper environments
749	finishExpr( newFunc.expr, resultEnv );
750	for( Alternative & alt : argsList ) {
751	finishExpr( alt.expr, resultEnv );
752	}
753
754	// This is a match store it and save it for later
755	func_candidates.push_back( newFunc );
756	args_candidates.push_back( argsList );
757
758	}
759	catch( SemanticErrorException & e ) {
760	errors.append( e );
761	}
762	}
763	}
764	catch( SemanticErrorException & e ) {
765	errors.append( e );
766	}
767	}
768
769	// Make sure we got the right number of arguments
770	if( func_candidates.empty() ) { SemanticErrorException top( stmt->location, "No alternatives for function in call to waitfor" ); top.append( errors ); throw top; }
771	if( args_candidates.empty() ) { SemanticErrorException top( stmt->location, "No alternatives for arguments in call to waitfor" ); top.append( errors ); throw top; }
772	if( func_candidates.size() > 1 ) { SemanticErrorException top( stmt->location, "Ambiguous function in call to waitfor" ); top.append( errors ); throw top; }
773	if( args_candidates.size() > 1 ) { SemanticErrorException top( stmt->location, "Ambiguous arguments in call to waitfor" ); top.append( errors ); throw top; }
774	// TODO: need to use findDeletedExpr to ensure no deleted identifiers are used.
775
776	// Swap the results from the alternative with the unresolved values.
777	// Alternatives will handle deletion on destruction
778	std::swap( clause.target.function, func_candidates.front().expr );
779	for( auto arg_pair : group_iterate( clause.target.arguments, args_candidates.front() ) ) {
780	std::swap ( std::get<0>( arg_pair), std::get<1>( arg_pair).expr );
781	}
782
783	// Resolve the conditions as if it were an IfStmt
784	// Resolve the statments normally
785	findSingleExpression( clause.condition, this->indexer );
786	clause.statement->accept( *visitor );
787	}
788
789
790	if( stmt->timeout.statement ) {
791	// Resolve the timeout as an size_t for now
792	// Resolve the conditions as if it were an IfStmt
793	// Resolve the statments normally
794	findSingleExpression( stmt->timeout.time, new BasicType( noQualifiers, BasicType::LongLongUnsignedInt ), this->indexer );
795	findSingleExpression( stmt->timeout.condition, this->indexer );
796	stmt->timeout.statement->accept( *visitor );
797	}
798
799	if( stmt->orelse.statement ) {
800	// Resolve the conditions as if it were an IfStmt
801	// Resolve the statments normally
802	findSingleExpression( stmt->orelse.condition, this->indexer );
803	stmt->orelse.statement->accept( *visitor );
804	}
805	}
806
807	bool isCharType( Type * t ) {
808	if ( BasicType * bt = dynamic_cast< BasicType * >( t ) ) {
809	return bt->get_kind() == BasicType::Char \|\| bt->get_kind() == BasicType::SignedChar \|\|
810	bt->get_kind() == BasicType::UnsignedChar;
811	}
812	return false;
813	}
814
815	void Resolver_old::previsit( SingleInit * singleInit ) {
816	visit_children = false;
817	// resolve initialization using the possibilities as determined by the currentObject cursor
818	Expression * newExpr = new UntypedInitExpr( singleInit->value, currentObject.getOptions() );
819	findSingleExpression( newExpr, indexer );
820	InitExpr * initExpr = strict_dynamic_cast< InitExpr * >( newExpr );
821
822	// move cursor to the object that is actually initialized
823	currentObject.setNext( initExpr->get_designation() );
824
825	// discard InitExpr wrapper and retain relevant pieces
826	newExpr = initExpr->expr;
827	initExpr->expr = nullptr;
828	std::swap( initExpr->env, newExpr->env );
829	// InitExpr may have inferParams in the case where the expression specializes a function
830	// pointer, and newExpr may already have inferParams of its own, so a simple swap is not
831	// sufficient.
832	newExpr->spliceInferParams( initExpr );
833	delete initExpr;
834
835	// get the actual object's type (may not exactly match what comes back from the resolver
836	// due to conversions)
837	Type * initContext = currentObject.getCurrentType();
838
839	removeExtraneousCast( newExpr, indexer );
840
841	// check if actual object's type is char[]
842	if ( ArrayType * at = dynamic_cast< ArrayType * >( initContext ) ) {
843	if ( isCharType( at->get_base() ) ) {
844	// check if the resolved type is char *
845	if ( PointerType * pt = dynamic_cast< PointerType *>( newExpr->get_result() ) ) {
846	if ( isCharType( pt->get_base() ) ) {
847	if ( CastExpr * ce = dynamic_cast< CastExpr * >( newExpr ) ) {
848	// strip cast if we're initializing a char[] with a char *,
849	// e.g. char x[] = "hello";
850	newExpr = ce->get_arg();
851	ce->set_arg( nullptr );
852	std::swap( ce->env, newExpr->env );
853	delete ce;
854	}
855	}
856	}
857	}
858	}
859
860	// set initializer expr to resolved express
861	singleInit->value = newExpr;
862
863	// move cursor to next object in preparation for next initializer
864	currentObject.increment();
865	}
866
867	void Resolver_old::previsit( ListInit * listInit ) {
868	visit_children = false;
869	// move cursor into brace-enclosed initializer-list
870	currentObject.enterListInit();
871	// xxx - fix this so that the list isn't copied, iterator should be used to change current
872	// element
873	std::list<Designation *> newDesignations;
874	for ( auto p : group_iterate(listInit->get_designations(), listInit->get_initializers()) ) {
875	// iterate designations and initializers in pairs, moving the cursor to the current
876	// designated object and resolving the initializer against that object.
877	Designation * des = std::get<0>(p);
878	Initializer * init = std::get<1>(p);
879	newDesignations.push_back( currentObject.findNext( des ) );
880	init->accept( *visitor );
881	}
882	// set the set of 'resolved' designations and leave the brace-enclosed initializer-list
883	listInit->get_designations() = newDesignations; // xxx - memory management
884	currentObject.exitListInit();
885
886	// xxx - this part has not be folded into CurrentObject yet
887	// } else if ( TypeInstType * tt = dynamic_cast< TypeInstType * >( initContext ) ) {
888	// Type * base = tt->get_baseType()->get_base();
889	// if ( base ) {
890	// // know the implementation type, so try using that as the initContext
891	// ObjectDecl tmpObj( "", Type::StorageClasses(), LinkageSpec::Cforall, nullptr, base->clone(), nullptr );
892	// currentObject = &tmpObj;
893	// visit( listInit );
894	// } else {
895	// // missing implementation type -- might be an unknown type variable, so try proceeding with the current init context
896	// Parent::visit( listInit );
897	// }
898	// } else {
899	}
900
901	// ConstructorInit - fall back on C-style initializer
902	void Resolver_old::fallbackInit( ConstructorInit * ctorInit ) {
903	// could not find valid constructor, or found an intrinsic constructor
904	// fall back on C-style initializer
905	delete ctorInit->get_ctor();
906	ctorInit->set_ctor( nullptr );
907	delete ctorInit->get_dtor();
908	ctorInit->set_dtor( nullptr );
909	maybeAccept( ctorInit->get_init(), *visitor );
910	}
911
912	// needs to be callable from outside the resolver, so this is a standalone function
913	void resolveCtorInit( ConstructorInit * ctorInit, const SymTab::Indexer & indexer ) {
914	assert( ctorInit );
915	PassVisitor<Resolver_old> resolver( indexer );
916	ctorInit->accept( resolver );
917	}
918
919	void resolveStmtExpr( StmtExpr * stmtExpr, const SymTab::Indexer & indexer ) {
920	assert( stmtExpr );
921	PassVisitor<Resolver_old> resolver( indexer );
922	stmtExpr->accept( resolver );
923	stmtExpr->computeResult();
924	// xxx - aggregate the environments from all statements? Possibly in AlternativeFinder instead?
925	}
926
927	void Resolver_old::previsit( ConstructorInit * ctorInit ) {
928	visit_children = false;
929	// xxx - fallback init has been removed => remove fallbackInit function and remove complexity from FixInit and remove C-init from ConstructorInit
930	maybeAccept( ctorInit->ctor, *visitor );
931	maybeAccept( ctorInit->dtor, *visitor );
932
933	// found a constructor - can get rid of C-style initializer
934	delete ctorInit->init;
935	ctorInit->init = nullptr;
936
937	// intrinsic single parameter constructors and destructors do nothing. Since this was
938	// implicitly generated, there's no way for it to have side effects, so get rid of it
939	// to clean up generated code.
940	if ( InitTweak::isIntrinsicSingleArgCallStmt( ctorInit->ctor ) ) {
941	delete ctorInit->ctor;
942	ctorInit->ctor = nullptr;
943	}
944
945	if ( InitTweak::isIntrinsicSingleArgCallStmt( ctorInit->dtor ) ) {
946	delete ctorInit->dtor;
947	ctorInit->dtor = nullptr;
948	}
949
950	// xxx - todo -- what about arrays?
951	// if ( dtor == nullptr && InitTweak::isIntrinsicCallStmt( ctorInit->get_ctor() ) ) {
952	// // can reduce the constructor down to a SingleInit using the
953	// // second argument from the ctor call, since
954	// delete ctorInit->get_ctor();
955	// ctorInit->set_ctor( nullptr );
956
957	// Expression * arg =
958	// ctorInit->set_init( new SingleInit( arg ) );
959	// }
960	}
961
962	///////////////////////////////////////////////////////////////////////////
963	//
964	// * NEW RESOLVER *
965	//
966	///////////////////////////////////////////////////////////////////////////
967
968	namespace {
969	/// Finds deleted expressions in an expression tree
970	struct DeleteFinder_new final : public ast::WithShortCircuiting, public ast::WithVisitorRef<DeleteFinder_new> {
971	const ast::DeletedExpr * result = nullptr;
972
973	void previsit( const ast::DeletedExpr * expr ) {
974	if ( result ) { visit_children = false; }
975	else { result = expr; }
976	}
977
978	void previsit( const ast::Expr * expr ) {
979	if ( result ) { visit_children = false; }
980	if (expr->inferred.hasParams()) {
981	for (auto & imp : expr->inferred.inferParams() ) {
982	imp.second.expr->accept(*visitor);
983	}
984	}
985	}
986	};
987	} // anonymous namespace
988	/// Check if this expression is or includes a deleted expression
989	const ast::DeletedExpr * findDeletedExpr( const ast::Expr * expr ) {
990	return ast::Pass<DeleteFinder_new>::read( expr );
991	}
992
993	namespace {
994	/// always-accept candidate filter
995	bool anyCandidate( const Candidate & ) { return true; }
996
997	/// Calls the CandidateFinder and finds the single best candidate
998	CandidateRef findUnfinishedKindExpression(
999	const ast::Expr * untyped, const ast::SymbolTable & symtab, const std::string & kind,
1000	std::function<bool(const Candidate &)> pred = anyCandidate, ResolvMode mode = {}
1001	) {
1002	if ( ! untyped ) return nullptr;
1003
1004	// xxx - this isn't thread-safe, but should work until we parallelize the resolver
1005	static unsigned recursion_level = 0;
1006
1007	++recursion_level;
1008	ast::TypeEnvironment env;
1009	CandidateFinder finder{ symtab, env };
1010	finder.find( untyped, recursion_level == 1 ? mode.atTopLevel() : mode );
1011	--recursion_level;
1012
1013	// produce a filtered list of candidates
1014	CandidateList candidates;
1015	for ( auto & cand : finder.candidates ) {
1016	if ( pred( *cand ) ) { candidates.emplace_back( cand ); }
1017	}
1018
1019	// produce invalid error if no candidates
1020	if ( candidates.empty() ) {
1021	SemanticError( untyped,
1022	toString( "No reasonable alternatives for ", kind, (kind != "" ? " " : ""),
1023	"expression: ") );
1024	}
1025
1026	// search for cheapest candidate
1027	CandidateList winners;
1028	bool seen_undeleted = false;
1029	for ( CandidateRef & cand : candidates ) {
1030	int c = winners.empty() ? -1 : cand->cost.compare( winners.front()->cost );
1031
1032	if ( c > 0 ) continue; // skip more expensive than winner
1033
1034	if ( c < 0 ) {
1035	// reset on new cheapest
1036	seen_undeleted = ! findDeletedExpr( cand->expr );
1037	winners.clear();
1038	} else /* if ( c == 0 ) */ {
1039	if ( findDeletedExpr( cand->expr ) ) {
1040	// skip deleted expression if already seen one equivalent-cost not
1041	if ( seen_undeleted ) continue;
1042	} else if ( ! seen_undeleted ) {
1043	// replace list of equivalent-cost deleted expressions with one non-deleted
1044	winners.clear();
1045	seen_undeleted = true;
1046	}
1047	}
1048
1049	winners.emplace_back( std::move( cand ) );
1050	}
1051
1052	// promote candidate.cvtCost to .cost
1053	promoteCvtCost( winners );
1054
1055	// produce ambiguous errors, if applicable
1056	if ( winners.size() != 1 ) {
1057	std::ostringstream stream;
1058	stream << "Cannot choose between " << winners.size() << " alternatives for "
1059	<< kind << (kind != "" ? " " : "") << "expression\n";
1060	ast::print( stream, untyped );
1061	stream << " Alternatives are:\n";
1062	print( stream, winners, 1 );
1063	SemanticError( untyped->location, stream.str() );
1064	}
1065
1066	// single selected choice
1067	CandidateRef & choice = winners.front();
1068
1069	// fail on only expression deleted
1070	if ( ! seen_undeleted ) {
1071	SemanticError( untyped->location, choice->expr.get(), "Unique best alternative "
1072	"includes deleted identifier in " );
1073	}
1074
1075	return std::move( choice );
1076	}
1077
1078	/// Strips extraneous casts out of an expression
1079	struct StripCasts_new final {
1080	const ast::Expr * postvisit( const ast::CastExpr * castExpr ) {
1081	if (
1082	castExpr->isGenerated == ast::GeneratedCast
1083	&& typesCompatible( castExpr->arg->result, castExpr->result )
1084	) {
1085	// generated cast is the same type as its argument, remove it after keeping env
1086	return ast::mutate_field(
1087	castExpr->arg.get(), &ast::Expr::env, castExpr->env );
1088	}
1089	return castExpr;
1090	}
1091
1092	static void strip( ast::ptr< ast::Expr > & expr ) {
1093	ast::Pass< StripCasts_new > stripper;
1094	expr = expr->accept( stripper );
1095	}
1096	};
1097
1098	/// Swaps argument into expression pointer, saving original environment
1099	void swap_and_save_env( ast::ptr< ast::Expr > & expr, const ast::Expr * newExpr ) {
1100	ast::ptr< ast::TypeSubstitution > env = expr->env;
1101	expr.set_and_mutate( newExpr )->env = env;
1102	}
1103
1104	/// Removes cast to type of argument (unlike StripCasts, also handles non-generated casts)
1105	void removeExtraneousCast( ast::ptr<ast::Expr> & expr, const ast::SymbolTable & symtab ) {
1106	if ( const ast::CastExpr * castExpr = expr.as< ast::CastExpr >() ) {
1107	if ( typesCompatible( castExpr->arg->result, castExpr->result, symtab ) ) {
1108	// cast is to the same type as its argument, remove it
1109	swap_and_save_env( expr, castExpr->arg );
1110	}
1111	}
1112	}
1113
1114
1115	} // anonymous namespace
1116	/// Establish post-resolver invariants for expressions
1117	void finishExpr(
1118	ast::ptr< ast::Expr > & expr, const ast::TypeEnvironment & env,
1119	const ast::TypeSubstitution * oldenv = nullptr
1120	) {
1121	// set up new type substitution for expression
1122	ast::ptr< ast::TypeSubstitution > newenv =
1123	oldenv ? oldenv : new ast::TypeSubstitution{};
1124	env.writeToSubstitution( *newenv.get_and_mutate() );
1125	expr.get_and_mutate()->env = std::move( newenv );
1126	// remove unncecessary casts
1127	StripCasts_new::strip( expr );
1128	}
1129
1130	ast::ptr< ast::Expr > resolveInVoidContext(
1131	const ast::Expr * expr, const ast::SymbolTable & symtab, ast::TypeEnvironment & env
1132	) {
1133	assertf( expr, "expected a non-null expression" );
1134
1135	// set up and resolve expression cast to void
1136	ast::ptr< ast::CastExpr > untyped = new ast::CastExpr{ expr };
1137	CandidateRef choice = findUnfinishedKindExpression(
1138	untyped, symtab, "", anyCandidate, ResolvMode::withAdjustment() );
1139
1140	// a cast expression has either 0 or 1 interpretations (by language rules);
1141	// if 0, an exception has already been thrown, and this code will not run
1142	const ast::CastExpr * castExpr = choice->expr.strict_as< ast::CastExpr >();
1143	env = std::move( choice->env );
1144
1145	return castExpr->arg;
1146	}
1147
1148	/// Resolve `untyped` to the expression whose candidate is the best match for a `void`
1149	/// context.
1150	ast::ptr< ast::Expr > findVoidExpression(
1151	const ast::Expr * untyped, const ast::SymbolTable & symtab
1152	) {
1153	resetTyVarRenaming();
1154	ast::TypeEnvironment env;
1155	ast::ptr< ast::Expr > newExpr = resolveInVoidContext( untyped, symtab, env );
1156	finishExpr( newExpr, env, untyped->env );
1157	return newExpr;
1158	}
1159
1160	namespace {
1161
1162
1163	/// resolve `untyped` to the expression whose candidate satisfies `pred` with the
1164	/// lowest cost, returning the resolved version
1165	ast::ptr< ast::Expr > findKindExpression(
1166	const ast::Expr * untyped, const ast::SymbolTable & symtab,
1167	std::function<bool(const Candidate &)> pred = anyCandidate,
1168	const std::string & kind = "", ResolvMode mode = {}
1169	) {
1170	if ( ! untyped ) return {};
1171	CandidateRef choice =
1172	findUnfinishedKindExpression( untyped, symtab, kind, pred, mode );
1173	ResolvExpr::finishExpr( choice->expr, choice->env, untyped->env );
1174	return std::move( choice->expr );
1175	}
1176
1177	/// Resolve `untyped` to the single expression whose candidate is the best match
1178	ast::ptr< ast::Expr > findSingleExpression(
1179	const ast::Expr * untyped, const ast::SymbolTable & symtab
1180	) {
1181	Stats::ResolveTime::start( untyped );
1182	auto res = findKindExpression( untyped, symtab );
1183	Stats::ResolveTime::stop();
1184	return res;
1185	}
1186	} // anonymous namespace
1187
1188	ast::ptr< ast::Expr > findSingleExpression(
1189	const ast::Expr * untyped, const ast::Type * type, const ast::SymbolTable & symtab
1190	) {
1191	assert( untyped && type );
1192	ast::ptr< ast::Expr > castExpr = new ast::CastExpr{ untyped, type };
1193	ast::ptr< ast::Expr > newExpr = findSingleExpression( castExpr, symtab );
1194	removeExtraneousCast( newExpr, symtab );
1195	return newExpr;
1196	}
1197
1198	namespace {
1199	bool structOrUnion( const Candidate & i ) {
1200	const ast::Type * t = i.expr->result->stripReferences();
1201	return dynamic_cast< const ast::StructInstType * >( t ) \|\| dynamic_cast< const ast::UnionInstType * >( t );
1202	}
1203	/// Predicate for "Candidate has integral type"
1204	bool hasIntegralType( const Candidate & i ) {
1205	const ast::Type * type = i.expr->result;
1206
1207	if ( auto bt = dynamic_cast< const ast::BasicType * >( type ) ) {
1208	return bt->isInteger();
1209	} else if (
1210	dynamic_cast< const ast::EnumInstType * >( type )
1211	\|\| dynamic_cast< const ast::ZeroType * >( type )
1212	\|\| dynamic_cast< const ast::OneType * >( type )
1213	) {
1214	return true;
1215	} else return false;
1216	}
1217
1218	/// Resolve `untyped` as an integral expression, returning the resolved version
1219	ast::ptr< ast::Expr > findIntegralExpression(
1220	const ast::Expr * untyped, const ast::SymbolTable & symtab
1221	) {
1222	return findKindExpression( untyped, symtab, hasIntegralType, "condition" );
1223	}
1224
1225	/// check if a type is a character type
1226	bool isCharType( const ast::Type * t ) {
1227	if ( auto bt = dynamic_cast< const ast::BasicType * >( t ) ) {
1228	return bt->kind == ast::BasicType::Char
1229	\|\| bt->kind == ast::BasicType::SignedChar
1230	\|\| bt->kind == ast::BasicType::UnsignedChar;
1231	}
1232	return false;
1233	}
1234
1235	/// Advance a type itertor to the next mutex parameter
1236	template<typename Iter>
1237	inline bool nextMutex( Iter & it, const Iter & end ) {
1238	while ( it != end && ! (*it)->is_mutex() ) { ++it; }
1239	return it != end;
1240	}
1241	}
1242
1243	class Resolver_new final
1244	: public ast::WithSymbolTable, public ast::WithGuards,
1245	public ast::WithVisitorRef<Resolver_new>, public ast::WithShortCircuiting,
1246	public ast::WithStmtsToAdd<> {
1247
1248	ast::ptr< ast::Type > functionReturn = nullptr;
1249	ast::CurrentObject currentObject;
1250	// for work previously in GenInit
1251	static InitTweak::ManagedTypes_new managedTypes;
1252
1253	bool inEnumDecl = false;
1254
1255	public:
1256	static size_t traceId;
1257	Resolver_new() = default;
1258	Resolver_new( const ast::SymbolTable & syms ) { symtab = syms; }
1259
1260	const ast::FunctionDecl * previsit( const ast::FunctionDecl * );
1261	const ast::FunctionDecl * postvisit( const ast::FunctionDecl * );
1262	const ast::ObjectDecl * previsit( const ast::ObjectDecl * );
1263	void previsit( const ast::AggregateDecl * );
1264	void previsit( const ast::StructDecl * );
1265	void previsit( const ast::EnumDecl * );
1266	const ast::StaticAssertDecl * previsit( const ast::StaticAssertDecl * );
1267
1268	const ast::ArrayType * previsit( const ast::ArrayType * );
1269	const ast::PointerType * previsit( const ast::PointerType * );
1270
1271	const ast::ExprStmt * previsit( const ast::ExprStmt * );
1272	const ast::AsmExpr * previsit( const ast::AsmExpr * );
1273	const ast::AsmStmt * previsit( const ast::AsmStmt * );
1274	const ast::IfStmt * previsit( const ast::IfStmt * );
1275	const ast::WhileStmt * previsit( const ast::WhileStmt * );
1276	const ast::ForStmt * previsit( const ast::ForStmt * );
1277	const ast::SwitchStmt * previsit( const ast::SwitchStmt * );
1278	const ast::CaseStmt * previsit( const ast::CaseStmt * );
1279	const ast::BranchStmt * previsit( const ast::BranchStmt * );
1280	const ast::ReturnStmt * previsit( const ast::ReturnStmt * );
1281	const ast::ThrowStmt * previsit( const ast::ThrowStmt * );
1282	const ast::CatchStmt * previsit( const ast::CatchStmt * );
1283	const ast::CatchStmt * postvisit( const ast::CatchStmt * );
1284	const ast::WaitForStmt * previsit( const ast::WaitForStmt * );
1285	const ast::WithStmt * previsit( const ast::WithStmt * );
1286
1287	const ast::SingleInit * previsit( const ast::SingleInit * );
1288	const ast::ListInit * previsit( const ast::ListInit * );
1289	const ast::ConstructorInit * previsit( const ast::ConstructorInit * );
1290
1291	void resolveWithExprs(std::vector<ast::ptr<ast::Expr>> & exprs, std::list<ast::ptr<ast::Stmt>> & stmtsToAdd);
1292
1293	void beginScope() { managedTypes.beginScope(); }
1294	void endScope() { managedTypes.endScope(); }
1295	bool on_error(ast::ptr<ast::Decl> & decl);
1296	};
1297	// size_t Resolver_new::traceId = Stats::Heap::new_stacktrace_id("Resolver");
1298
1299	InitTweak::ManagedTypes_new Resolver_new::managedTypes;
1300
1301	void resolve( ast::TranslationUnit& translationUnit ) {
1302	ast::Pass< Resolver_new >::run( translationUnit );
1303	}
1304
1305	ast::ptr< ast::Init > resolveCtorInit(
1306	const ast::ConstructorInit * ctorInit, const ast::SymbolTable & symtab
1307	) {
1308	assert( ctorInit );
1309	ast::Pass< Resolver_new > resolver{ symtab };
1310	return ctorInit->accept( resolver );
1311	}
1312
1313	ast::ptr< ast::Expr > resolveStmtExpr(
1314	const ast::StmtExpr * stmtExpr, const ast::SymbolTable & symtab
1315	) {
1316	assert( stmtExpr );
1317	ast::Pass< Resolver_new > resolver{ symtab };
1318	ast::ptr< ast::Expr > ret = stmtExpr;
1319	ret = ret->accept( resolver );
1320	strict_dynamic_cast< ast::StmtExpr * >( ret.get_and_mutate() )->computeResult();
1321	return ret;
1322	}
1323
1324	namespace {
1325	const ast::Attribute * handleAttribute(const CodeLocation & loc, const ast::Attribute * attr, const ast::SymbolTable & symtab) {
1326	std::string name = attr->normalizedName();
1327	if (name == "constructor" \|\| name == "destructor") {
1328	if (attr->params.size() == 1) {
1329	auto arg = attr->params.front();
1330	auto resolved = ResolvExpr::findSingleExpression( arg, new ast::BasicType( ast::BasicType::LongLongSignedInt ), symtab );
1331	auto result = eval(arg);
1332
1333	auto mutAttr = mutate(attr);
1334	mutAttr->params.front() = resolved;
1335	if (! result.second) {
1336	SemanticWarning(loc, Warning::GccAttributes,
1337	toCString( name, " priorities must be integers from 0 to 65535 inclusive: ", arg ) );
1338	}
1339	else {
1340	auto priority = result.first;
1341	if (priority < 101) {
1342	SemanticWarning(loc, Warning::GccAttributes,
1343	toCString( name, " priorities from 0 to 100 are reserved for the implementation" ) );
1344	} else if (priority < 201 && ! buildingLibrary()) {
1345	SemanticWarning(loc, Warning::GccAttributes,
1346	toCString( name, " priorities from 101 to 200 are reserved for the implementation" ) );
1347	}
1348	}
1349	return mutAttr;
1350	} else if (attr->params.size() > 1) {
1351	SemanticWarning(loc, Warning::GccAttributes, toCString( "too many arguments to ", name, " attribute" ) );
1352	} else {
1353	SemanticWarning(loc, Warning::GccAttributes, toCString( "too few arguments to ", name, " attribute" ) );
1354	}
1355	}
1356	return attr;
1357	}
1358	}
1359
1360	const ast::FunctionDecl * Resolver_new::previsit( const ast::FunctionDecl * functionDecl ) {
1361	GuardValue( functionReturn );
1362
1363	assert (functionDecl->unique());
1364	if (!functionDecl->has_body() && !functionDecl->withExprs.empty()) {
1365	SemanticError(functionDecl->location, functionDecl, "Function without body has with declarations");
1366	}
1367
1368	if (!functionDecl->isTypeFixed) {
1369	auto mutDecl = mutate(functionDecl);
1370	auto mutType = mutDecl->type.get_and_mutate();
1371
1372	for (auto & attr: mutDecl->attributes) {
1373	attr = handleAttribute(mutDecl->location, attr, symtab);
1374	}
1375
1376	// handle assertions
1377
1378	symtab.enterScope();
1379	mutType->forall.clear();
1380	mutType->assertions.clear();
1381	for (auto & typeParam : mutDecl->type_params) {
1382	symtab.addType(typeParam);
1383	mutType->forall.emplace_back(new ast::TypeInstType(typeParam->name, typeParam));
1384	}
1385	for (auto & asst : mutDecl->assertions) {
1386	asst = fixObjectType(asst.strict_as<ast::ObjectDecl>(), symtab);
1387	symtab.addId(asst);
1388	mutType->assertions.emplace_back(new ast::VariableExpr(functionDecl->location, asst));
1389	}
1390
1391	// temporarily adds params to symbol table.
1392	// actual scoping rules for params and withexprs differ - see Pass::visit(FunctionDecl)
1393
1394	std::vector<ast::ptr<ast::Type>> paramTypes;
1395	std::vector<ast::ptr<ast::Type>> returnTypes;
1396
1397	for (auto & param : mutDecl->params) {
1398	param = fixObjectType(param.strict_as<ast::ObjectDecl>(), symtab);
1399	symtab.addId(param);
1400	paramTypes.emplace_back(param->get_type());
1401	}
1402	for (auto & ret : mutDecl->returns) {
1403	ret = fixObjectType(ret.strict_as<ast::ObjectDecl>(), symtab);
1404	returnTypes.emplace_back(ret->get_type());
1405	}
1406	// since function type in decl is just a view of param types, need to update that as well
1407	mutType->params = std::move(paramTypes);
1408	mutType->returns = std::move(returnTypes);
1409
1410	auto renamedType = strict_dynamic_cast<const ast::FunctionType *>(renameTyVars(mutType, RenameMode::GEN_EXPR_ID));
1411
1412	std::list<ast::ptr<ast::Stmt>> newStmts;
1413	resolveWithExprs (mutDecl->withExprs, newStmts);
1414
1415	if (mutDecl->stmts) {
1416	auto mutStmt = mutDecl->stmts.get_and_mutate();
1417	mutStmt->kids.splice(mutStmt->kids.begin(), std::move(newStmts));
1418	mutDecl->stmts = mutStmt;
1419	}
1420
1421	symtab.leaveScope();
1422
1423	mutDecl->type = renamedType;
1424	mutDecl->mangleName = Mangle::mangle(mutDecl);
1425	mutDecl->isTypeFixed = true;
1426	functionDecl = mutDecl;
1427	}
1428	managedTypes.handleDWT(functionDecl);
1429
1430	functionReturn = extractResultType( functionDecl->type );
1431	return functionDecl;
1432	}
1433
1434	const ast::FunctionDecl * Resolver_new::postvisit( const ast::FunctionDecl * functionDecl ) {
1435	// default value expressions have an environment which shouldn't be there and trips up
1436	// later passes.
1437	assert( functionDecl->unique() );
1438	ast::FunctionType * mutType = mutate( functionDecl->type.get() );
1439
1440	for ( unsigned i = 0 ; i < mutType->params.size() ; ++i ) {
1441	if ( const ast::ObjectDecl * obj = mutType->params[i].as< ast::ObjectDecl >() ) {
1442	if ( const ast::SingleInit * init = obj->init.as< ast::SingleInit >() ) {
1443	if ( init->value->env == nullptr ) continue;
1444	// clone initializer minus the initializer environment
1445	auto mutParam = mutate( mutType->params[i].strict_as< ast::ObjectDecl >() );
1446	auto mutInit = mutate( mutParam->init.strict_as< ast::SingleInit >() );
1447	auto mutValue = mutate( mutInit->value.get() );
1448
1449	mutValue->env = nullptr;
1450	mutInit->value = mutValue;
1451	mutParam->init = mutInit;
1452	mutType->params[i] = mutParam;
1453
1454	assert( ! mutType->params[i].strict_as< ast::ObjectDecl >()->init.strict_as< ast::SingleInit >()->value->env);
1455	}
1456	}
1457	}
1458	mutate_field(functionDecl, &ast::FunctionDecl::type, mutType);
1459	return functionDecl;
1460	}
1461
1462	const ast::ObjectDecl * Resolver_new::previsit( const ast::ObjectDecl * objectDecl ) {
1463	// To handle initialization of routine pointers [e.g. int (*fp)(int) = foo()],
1464	// class-variable `initContext` is changed multiple times because the LHS is analyzed
1465	// twice. The second analysis changes `initContext` because a function type can contain
1466	// object declarations in the return and parameter types. Therefore each value of
1467	// `initContext` is retained so the type on the first analysis is preserved and used for
1468	// selecting the RHS.
1469	GuardValue( currentObject );
1470
1471	if ( inEnumDecl && dynamic_cast< const ast::EnumInstType * >( objectDecl->get_type() ) ) {
1472	// enumerator initializers should not use the enum type to initialize, since the
1473	// enum type is still incomplete at this point. Use `int` instead.
1474	objectDecl = fixObjectType(objectDecl, symtab);
1475	currentObject = ast::CurrentObject{
1476	objectDecl->location, new ast::BasicType{ ast::BasicType::SignedInt } };
1477	}
1478	else {
1479	if (!objectDecl->isTypeFixed) {
1480	auto newDecl = fixObjectType(objectDecl, symtab);
1481	auto mutDecl = mutate(newDecl);
1482
1483	// generate CtorInit wrapper when necessary.
1484	// in certain cases, fixObjectType is called before reaching
1485	// this object in visitor pass, thus disabling CtorInit codegen.
1486	// this happens on aggregate members and function parameters.
1487	if ( InitTweak::tryConstruct( mutDecl ) && ( managedTypes.isManaged( mutDecl ) \|\| ((! isInFunction() \|\| mutDecl->storage.is_static ) && ! InitTweak::isConstExpr( mutDecl->init ) ) ) ) {
1488	// constructed objects cannot be designated
1489	if ( InitTweak::isDesignated( mutDecl->init ) ) SemanticError( mutDecl, "Cannot include designations in the initializer for a managed Object. If this is really what you want, then initialize with @=.\n" );
1490	// constructed objects should not have initializers nested too deeply
1491	if ( ! InitTweak::checkInitDepth( mutDecl ) ) SemanticError( mutDecl, "Managed object's initializer is too deep " );
1492
1493	mutDecl->init = InitTweak::genCtorInit( mutDecl->location, mutDecl );
1494	}
1495
1496	objectDecl = mutDecl;
1497	}
1498	currentObject = ast::CurrentObject{ objectDecl->location, objectDecl->get_type() };
1499	}
1500
1501	return objectDecl;
1502	}
1503
1504	void Resolver_new::previsit( const ast::AggregateDecl * _aggDecl ) {
1505	auto aggDecl = mutate(_aggDecl);
1506	assertf(aggDecl == _aggDecl, "type declarations must be unique");
1507
1508	for (auto & member: aggDecl->members) {
1509	// nested type decls are hoisted already. no need to do anything
1510	if (auto obj = member.as<ast::ObjectDecl>()) {
1511	member = fixObjectType(obj, symtab);
1512	}
1513	}
1514	}
1515
1516	void Resolver_new::previsit( const ast::StructDecl * structDecl ) {
1517	previsit(static_cast<const ast::AggregateDecl *>(structDecl));
1518	managedTypes.handleStruct(structDecl);
1519	}
1520
1521	void Resolver_new::previsit( const ast::EnumDecl * ) {
1522	// in case we decide to allow nested enums
1523	GuardValue( inEnumDecl );
1524	inEnumDecl = true;
1525	// don't need to fix types for enum fields
1526	}
1527
1528
1529	const ast::StaticAssertDecl * Resolver_new::previsit(
1530	const ast::StaticAssertDecl * assertDecl
1531	) {
1532	return ast::mutate_field(
1533	assertDecl, &ast::StaticAssertDecl::cond,
1534	findIntegralExpression( assertDecl->cond, symtab ) );
1535	}
1536
1537	template< typename PtrType >
1538	const PtrType * handlePtrType( const PtrType * type, const ast::SymbolTable & symtab ) {
1539	if ( type->dimension ) {
1540	ast::ptr< ast::Type > sizeType = ast::sizeType;
1541	ast::mutate_field(
1542	type, &PtrType::dimension,
1543	findSingleExpression( type->dimension, sizeType, symtab ) );
1544	}
1545	return type;
1546	}
1547
1548	const ast::ArrayType * Resolver_new::previsit( const ast::ArrayType * at ) {
1549	return handlePtrType( at, symtab );
1550	}
1551
1552	const ast::PointerType * Resolver_new::previsit( const ast::PointerType * pt ) {
1553	return handlePtrType( pt, symtab );
1554	}
1555
1556	const ast::ExprStmt * Resolver_new::previsit( const ast::ExprStmt * exprStmt ) {
1557	visit_children = false;
1558	assertf( exprStmt->expr, "ExprStmt has null expression in resolver" );
1559
1560	return ast::mutate_field(
1561	exprStmt, &ast::ExprStmt::expr, findVoidExpression( exprStmt->expr, symtab ) );
1562	}
1563
1564	const ast::AsmExpr * Resolver_new::previsit( const ast::AsmExpr * asmExpr ) {
1565	visit_children = false;
1566
1567	asmExpr = ast::mutate_field(
1568	asmExpr, &ast::AsmExpr::operand, findVoidExpression( asmExpr->operand, symtab ) );
1569
1570	return asmExpr;
1571	}
1572
1573	const ast::AsmStmt * Resolver_new::previsit( const ast::AsmStmt * asmStmt ) {
1574	visitor->maybe_accept( asmStmt, &ast::AsmStmt::input );
1575	visitor->maybe_accept( asmStmt, &ast::AsmStmt::output );
1576	visit_children = false;
1577	return asmStmt;
1578	}
1579
1580	const ast::IfStmt * Resolver_new::previsit( const ast::IfStmt * ifStmt ) {
1581	return ast::mutate_field(
1582	ifStmt, &ast::IfStmt::cond, findIntegralExpression( ifStmt->cond, symtab ) );
1583	}
1584
1585	const ast::WhileStmt * Resolver_new::previsit( const ast::WhileStmt * whileStmt ) {
1586	return ast::mutate_field(
1587	whileStmt, &ast::WhileStmt::cond, findIntegralExpression( whileStmt->cond, symtab ) );
1588	}
1589
1590	const ast::ForStmt * Resolver_new::previsit( const ast::ForStmt * forStmt ) {
1591	if ( forStmt->cond ) {
1592	forStmt = ast::mutate_field(
1593	forStmt, &ast::ForStmt::cond, findIntegralExpression( forStmt->cond, symtab ) );
1594	}
1595
1596	if ( forStmt->inc ) {
1597	forStmt = ast::mutate_field(
1598	forStmt, &ast::ForStmt::inc, findVoidExpression( forStmt->inc, symtab ) );
1599	}
1600
1601	return forStmt;
1602	}
1603
1604	const ast::SwitchStmt * Resolver_new::previsit( const ast::SwitchStmt * switchStmt ) {
1605	GuardValue( currentObject );
1606	switchStmt = ast::mutate_field(
1607	switchStmt, &ast::SwitchStmt::cond,
1608	findIntegralExpression( switchStmt->cond, symtab ) );
1609	currentObject = ast::CurrentObject{ switchStmt->location, switchStmt->cond->result };
1610	return switchStmt;
1611	}
1612
1613	const ast::CaseStmt * Resolver_new::previsit( const ast::CaseStmt * caseStmt ) {
1614	if ( caseStmt->cond ) {
1615	std::deque< ast::InitAlternative > initAlts = currentObject.getOptions();
1616	assertf( initAlts.size() == 1, "SwitchStmt did not correctly resolve an integral "
1617	"expression." );
1618
1619	ast::ptr< ast::Expr > untyped =
1620	new ast::CastExpr{ caseStmt->location, caseStmt->cond, initAlts.front().type };
1621	ast::ptr< ast::Expr > newExpr = findSingleExpression( untyped, symtab );
1622
1623	// case condition cannot have a cast in C, so it must be removed here, regardless of
1624	// whether it would perform a conversion.
1625	if ( const ast::CastExpr * castExpr = newExpr.as< ast::CastExpr >() ) {
1626	swap_and_save_env( newExpr, castExpr->arg );
1627	}
1628
1629	caseStmt = ast::mutate_field( caseStmt, &ast::CaseStmt::cond, newExpr );
1630	}
1631	return caseStmt;
1632	}
1633
1634	const ast::BranchStmt * Resolver_new::previsit( const ast::BranchStmt * branchStmt ) {
1635	visit_children = false;
1636	// must resolve the argument of a computed goto
1637	if ( branchStmt->kind == ast::BranchStmt::Goto && branchStmt->computedTarget ) {
1638	// computed goto argument is void*
1639	ast::ptr< ast::Type > target = new ast::PointerType{ new ast::VoidType{} };
1640	branchStmt = ast::mutate_field(
1641	branchStmt, &ast::BranchStmt::computedTarget,
1642	findSingleExpression( branchStmt->computedTarget, target, symtab ) );
1643	}
1644	return branchStmt;
1645	}
1646
1647	const ast::ReturnStmt * Resolver_new::previsit( const ast::ReturnStmt * returnStmt ) {
1648	visit_children = false;
1649	if ( returnStmt->expr ) {
1650	returnStmt = ast::mutate_field(
1651	returnStmt, &ast::ReturnStmt::expr,
1652	findSingleExpression( returnStmt->expr, functionReturn, symtab ) );
1653	}
1654	return returnStmt;
1655	}
1656
1657	const ast::ThrowStmt * Resolver_new::previsit( const ast::ThrowStmt * throwStmt ) {
1658	visit_children = false;
1659	if ( throwStmt->expr ) {
1660	const ast::StructDecl * exceptionDecl =
1661	symtab.lookupStruct( "__cfaehm_base_exception_t" );
1662	assert( exceptionDecl );
1663	ast::ptr< ast::Type > exceptType =
1664	new ast::PointerType{ new ast::StructInstType{ exceptionDecl } };
1665	throwStmt = ast::mutate_field(
1666	throwStmt, &ast::ThrowStmt::expr,
1667	findSingleExpression( throwStmt->expr, exceptType, symtab ) );
1668	}
1669	return throwStmt;
1670	}
1671
1672	const ast::CatchStmt * Resolver_new::previsit( const ast::CatchStmt * catchStmt ) {
1673	// Until we are very sure this invarent (ifs that move between passes have thenPart)
1674	// holds, check it. This allows a check for when to decode the mangling.
1675	if ( auto ifStmt = catchStmt->body.as<ast::IfStmt>() ) {
1676	assert( ifStmt->thenPart );
1677	}
1678	// Encode the catchStmt so the condition can see the declaration.
1679	if ( catchStmt->cond ) {
1680	ast::CatchStmt * stmt = mutate( catchStmt );
1681	stmt->body = new ast::IfStmt( stmt->location, stmt->cond, nullptr, stmt->body );
1682	stmt->cond = nullptr;
1683	return stmt;
1684	}
1685	return catchStmt;
1686	}
1687
1688	const ast::CatchStmt * Resolver_new::postvisit( const ast::CatchStmt * catchStmt ) {
1689	// Decode the catchStmt so everything is stored properly.
1690	const ast::IfStmt * ifStmt = catchStmt->body.as<ast::IfStmt>();
1691	if ( nullptr != ifStmt && nullptr == ifStmt->thenPart ) {
1692	assert( ifStmt->cond );
1693	assert( ifStmt->elsePart );
1694	ast::CatchStmt * stmt = ast::mutate( catchStmt );
1695	stmt->cond = ifStmt->cond;
1696	stmt->body = ifStmt->elsePart;
1697	// ifStmt should be implicately deleted here.
1698	return stmt;
1699	}
1700	return catchStmt;
1701	}
1702
1703	const ast::WaitForStmt * Resolver_new::previsit( const ast::WaitForStmt * stmt ) {
1704	visit_children = false;
1705
1706	// Resolve all clauses first
1707	for ( unsigned i = 0; i < stmt->clauses.size(); ++i ) {
1708	const ast::WaitForStmt::Clause & clause = stmt->clauses[i];
1709
1710	ast::TypeEnvironment env;
1711	CandidateFinder funcFinder{ symtab, env };
1712
1713	// Find all candidates for a function in canonical form
1714	funcFinder.find( clause.target.func, ResolvMode::withAdjustment() );
1715
1716	if ( funcFinder.candidates.empty() ) {
1717	stringstream ss;
1718	ss << "Use of undeclared indentifier '";
1719	ss << clause.target.func.strict_as< ast::NameExpr >()->name;
1720	ss << "' in call to waitfor";
1721	SemanticError( stmt->location, ss.str() );
1722	}
1723
1724	if ( clause.target.args.empty() ) {
1725	SemanticError( stmt->location,
1726	"Waitfor clause must have at least one mutex parameter");
1727	}
1728
1729	// Find all alternatives for all arguments in canonical form
1730	std::vector< CandidateFinder > argFinders =
1731	funcFinder.findSubExprs( clause.target.args );
1732
1733	// List all combinations of arguments
1734	std::vector< CandidateList > possibilities;
1735	combos( argFinders.begin(), argFinders.end(), back_inserter( possibilities ) );
1736
1737	// For every possible function:
1738	// * try matching the arguments to the parameters, not the other way around because
1739	// more arguments than parameters
1740	CandidateList funcCandidates;
1741	std::vector< CandidateList > argsCandidates;
1742	SemanticErrorException errors;
1743	for ( CandidateRef & func : funcFinder.candidates ) {
1744	try {
1745	auto pointerType = dynamic_cast< const ast::PointerType * >(
1746	func->expr->result->stripReferences() );
1747	if ( ! pointerType ) {
1748	SemanticError( stmt->location, func->expr->result.get(),
1749	"candidate not viable: not a pointer type\n" );
1750	}
1751
1752	auto funcType = pointerType->base.as< ast::FunctionType >();
1753	if ( ! funcType ) {
1754	SemanticError( stmt->location, func->expr->result.get(),
1755	"candidate not viable: not a function type\n" );
1756	}
1757
1758	{
1759	auto param = funcType->params.begin();
1760	auto paramEnd = funcType->params.end();
1761
1762	if( ! nextMutex( param, paramEnd ) ) {
1763	SemanticError( stmt->location, funcType,
1764	"candidate function not viable: no mutex parameters\n");
1765	}
1766	}
1767
1768	CandidateRef func2{ new Candidate{ *func } };
1769	// strip reference from function
1770	func2->expr = referenceToRvalueConversion( func->expr, func2->cost );
1771
1772	// Each argument must be matched with a parameter of the current candidate
1773	for ( auto & argsList : possibilities ) {
1774	try {
1775	// Declare data structures needed for resolution
1776	ast::OpenVarSet open;
1777	ast::AssertionSet need, have;
1778	ast::TypeEnvironment resultEnv{ func->env };
1779	// Add all type variables as open so that those not used in the
1780	// parameter list are still considered open
1781	resultEnv.add( funcType->forall );
1782
1783	// load type variables from arguments into one shared space
1784	for ( auto & arg : argsList ) {
1785	resultEnv.simpleCombine( arg->env );
1786	}
1787
1788	// Make sure we don't widen any existing bindings
1789	resultEnv.forbidWidening();
1790
1791	// Find any unbound type variables
1792	resultEnv.extractOpenVars( open );
1793
1794	auto param = funcType->params.begin();
1795	auto paramEnd = funcType->params.end();
1796
1797	unsigned n_mutex_param = 0;
1798
1799	// For every argument of its set, check if it matches one of the
1800	// parameters. The order is important
1801	for ( auto & arg : argsList ) {
1802	// Ignore non-mutex arguments
1803	if ( ! nextMutex( param, paramEnd ) ) {
1804	// We ran out of parameters but still have arguments.
1805	// This function doesn't match
1806	SemanticError( stmt->location, funcType,
1807	toString("candidate function not viable: too many mutex "
1808	"arguments, expected ", n_mutex_param, "\n" ) );
1809	}
1810
1811	++n_mutex_param;
1812
1813	// Check if the argument matches the parameter type in the current
1814	// scope
1815	// ast::ptr< ast::Type > paramType = (*param)->get_type();
1816	if (
1817	! unify(
1818	arg->expr->result, *param, resultEnv, need, have, open,
1819	symtab )
1820	) {
1821	// Type doesn't match
1822	stringstream ss;
1823	ss << "candidate function not viable: no known conversion "
1824	"from '";
1825	ast::print( ss, *param );
1826	ss << "' to '";
1827	ast::print( ss, arg->expr->result );
1828	ss << "' with env '";
1829	ast::print( ss, resultEnv );
1830	ss << "'\n";
1831	SemanticError( stmt->location, funcType, ss.str() );
1832	}
1833
1834	++param;
1835	}
1836
1837	// All arguments match!
1838
1839	// Check if parameters are missing
1840	if ( nextMutex( param, paramEnd ) ) {
1841	do {
1842	++n_mutex_param;
1843	++param;
1844	} while ( nextMutex( param, paramEnd ) );
1845
1846	// We ran out of arguments but still have parameters left; this
1847	// function doesn't match
1848	SemanticError( stmt->location, funcType,
1849	toString( "candidate function not viable: too few mutex "
1850	"arguments, expected ", n_mutex_param, "\n" ) );
1851	}
1852
1853	// All parameters match!
1854
1855	// Finish the expressions to tie in proper environments
1856	finishExpr( func2->expr, resultEnv );
1857	for ( CandidateRef & arg : argsList ) {
1858	finishExpr( arg->expr, resultEnv );
1859	}
1860
1861	// This is a match, store it and save it for later
1862	funcCandidates.emplace_back( std::move( func2 ) );
1863	argsCandidates.emplace_back( std::move( argsList ) );
1864
1865	} catch ( SemanticErrorException & e ) {
1866	errors.append( e );
1867	}
1868	}
1869	} catch ( SemanticErrorException & e ) {
1870	errors.append( e );
1871	}
1872	}
1873
1874	// Make sure correct number of arguments
1875	if( funcCandidates.empty() ) {
1876	SemanticErrorException top( stmt->location,
1877	"No alternatives for function in call to waitfor" );
1878	top.append( errors );
1879	throw top;
1880	}
1881
1882	if( argsCandidates.empty() ) {
1883	SemanticErrorException top( stmt->location,
1884	"No alternatives for arguments in call to waitfor" );
1885	top.append( errors );
1886	throw top;
1887	}
1888
1889	if( funcCandidates.size() > 1 ) {
1890	SemanticErrorException top( stmt->location,
1891	"Ambiguous function in call to waitfor" );
1892	top.append( errors );
1893	throw top;
1894	}
1895	if( argsCandidates.size() > 1 ) {
1896	SemanticErrorException top( stmt->location,
1897	"Ambiguous arguments in call to waitfor" );
1898	top.append( errors );
1899	throw top;
1900	}
1901	// TODO: need to use findDeletedExpr to ensure no deleted identifiers are used.
1902
1903	// build new clause
1904	ast::WaitForStmt::Clause clause2;
1905
1906	clause2.target.func = funcCandidates.front()->expr;
1907
1908	clause2.target.args.reserve( clause.target.args.size() );
1909	for ( auto arg : argsCandidates.front() ) {
1910	clause2.target.args.emplace_back( std::move( arg->expr ) );
1911	}
1912
1913	// Resolve the conditions as if it were an IfStmt, statements normally
1914	clause2.cond = findSingleExpression( clause.cond, symtab );
1915	clause2.stmt = clause.stmt->accept( *visitor );
1916
1917	// set results into stmt
1918	auto n = mutate( stmt );
1919	n->clauses[i] = std::move( clause2 );
1920	stmt = n;
1921	}
1922
1923	if ( stmt->timeout.stmt ) {
1924	// resolve the timeout as a size_t, the conditions like IfStmt, and stmts normally
1925	ast::WaitForStmt::Timeout timeout2;
1926
1927	ast::ptr< ast::Type > target =
1928	new ast::BasicType{ ast::BasicType::LongLongUnsignedInt };
1929	timeout2.time = findSingleExpression( stmt->timeout.time, target, symtab );
1930	timeout2.cond = findSingleExpression( stmt->timeout.cond, symtab );
1931	timeout2.stmt = stmt->timeout.stmt->accept( *visitor );
1932
1933	// set results into stmt
1934	auto n = mutate( stmt );
1935	n->timeout = std::move( timeout2 );
1936	stmt = n;
1937	}
1938
1939	if ( stmt->orElse.stmt ) {
1940	// resolve the condition like IfStmt, stmts normally
1941	ast::WaitForStmt::OrElse orElse2;
1942
1943	orElse2.cond = findSingleExpression( stmt->orElse.cond, symtab );
1944	orElse2.stmt = stmt->orElse.stmt->accept( *visitor );
1945
1946	// set results into stmt
1947	auto n = mutate( stmt );
1948	n->orElse = std::move( orElse2 );
1949	stmt = n;
1950	}
1951
1952	return stmt;
1953	}
1954
1955	const ast::WithStmt * Resolver_new::previsit( const ast::WithStmt * withStmt ) {
1956	auto mutStmt = mutate(withStmt);
1957	resolveWithExprs(mutStmt->exprs, stmtsToAddBefore);
1958	return mutStmt;
1959	}
1960
1961	void Resolver_new::resolveWithExprs(std::vector<ast::ptr<ast::Expr>> & exprs, std::list<ast::ptr<ast::Stmt>> & stmtsToAdd) {
1962	for (auto & expr : exprs) {
1963	// only struct- and union-typed expressions are viable candidates
1964	expr = findKindExpression( expr, symtab, structOrUnion, "with expression" );
1965
1966	// if with expression might be impure, create a temporary so that it is evaluated once
1967	if ( Tuples::maybeImpure( expr ) ) {
1968	static UniqueName tmpNamer( "_with_tmp_" );
1969	const CodeLocation loc = expr->location;
1970	auto tmp = new ast::ObjectDecl(loc, tmpNamer.newName(), expr->result, new ast::SingleInit(loc, expr ) );
1971	expr = new ast::VariableExpr( loc, tmp );
1972	stmtsToAdd.push_back( new ast::DeclStmt(loc, tmp ) );
1973	if ( InitTweak::isConstructable( tmp->type ) ) {
1974	// generate ctor/dtor and resolve them
1975	tmp->init = InitTweak::genCtorInit( loc, tmp );
1976	}
1977	// since tmp is freshly created, this should modify tmp in-place
1978	tmp->accept( *visitor );
1979	}
1980	}
1981	}
1982
1983
1984	const ast::SingleInit * Resolver_new::previsit( const ast::SingleInit * singleInit ) {
1985	visit_children = false;
1986	// resolve initialization using the possibilities as determined by the `currentObject`
1987	// cursor.
1988	ast::ptr< ast::Expr > untyped = new ast::UntypedInitExpr{
1989	singleInit->location, singleInit->value, currentObject.getOptions() };
1990	ast::ptr<ast::Expr> newExpr = findSingleExpression( untyped, symtab );
1991	const ast::InitExpr * initExpr = newExpr.strict_as< ast::InitExpr >();
1992
1993	// move cursor to the object that is actually initialized
1994	currentObject.setNext( initExpr->designation );
1995
1996	// discard InitExpr wrapper and retain relevant pieces.
1997	// `initExpr` may have inferred params in the case where the expression specialized a
1998	// function pointer, and newExpr may already have inferParams of its own, so a simple
1999	// swap is not sufficient
2000	ast::Expr::InferUnion inferred = initExpr->inferred;
2001	swap_and_save_env( newExpr, initExpr->expr );
2002	newExpr.get_and_mutate()->inferred.splice( std::move(inferred) );
2003
2004	// get the actual object's type (may not exactly match what comes back from the resolver
2005	// due to conversions)
2006	const ast::Type * initContext = currentObject.getCurrentType();
2007
2008	removeExtraneousCast( newExpr, symtab );
2009
2010	// check if actual object's type is char[]
2011	if ( auto at = dynamic_cast< const ast::ArrayType * >( initContext ) ) {
2012	if ( isCharType( at->base ) ) {
2013	// check if the resolved type is char*
2014	if ( auto pt = newExpr->result.as< ast::PointerType >() ) {
2015	if ( isCharType( pt->base ) ) {
2016	// strip cast if we're initializing a char[] with a char*
2017	// e.g. char x[] = "hello"
2018	if ( auto ce = newExpr.as< ast::CastExpr >() ) {
2019	swap_and_save_env( newExpr, ce->arg );
2020	}
2021	}
2022	}
2023	}
2024	}
2025
2026	// move cursor to next object in preparation for next initializer
2027	currentObject.increment();
2028
2029	// set initializer expression to resolved expression
2030	return ast::mutate_field( singleInit, &ast::SingleInit::value, std::move(newExpr) );
2031	}
2032
2033	const ast::ListInit * Resolver_new::previsit( const ast::ListInit * listInit ) {
2034	// move cursor into brace-enclosed initializer-list
2035	currentObject.enterListInit( listInit->location );
2036
2037	assert( listInit->designations.size() == listInit->initializers.size() );
2038	for ( unsigned i = 0; i < listInit->designations.size(); ++i ) {
2039	// iterate designations and initializers in pairs, moving the cursor to the current
2040	// designated object and resolving the initializer against that object
2041	listInit = ast::mutate_field_index(
2042	listInit, &ast::ListInit::designations, i,
2043	currentObject.findNext( listInit->designations[i] ) );
2044	listInit = ast::mutate_field_index(
2045	listInit, &ast::ListInit::initializers, i,
2046	listInit->initializers[i]->accept( *visitor ) );
2047	}
2048
2049	// move cursor out of brace-enclosed initializer-list
2050	currentObject.exitListInit();
2051
2052	visit_children = false;
2053	return listInit;
2054	}
2055
2056	const ast::ConstructorInit * Resolver_new::previsit( const ast::ConstructorInit * ctorInit ) {
2057	visitor->maybe_accept( ctorInit, &ast::ConstructorInit::ctor );
2058	visitor->maybe_accept( ctorInit, &ast::ConstructorInit::dtor );
2059
2060	// found a constructor - can get rid of C-style initializer
2061	// xxx - Rob suggests this field is dead code
2062	ctorInit = ast::mutate_field( ctorInit, &ast::ConstructorInit::init, nullptr );
2063
2064	// intrinsic single-parameter constructors and destructors do nothing. Since this was
2065	// implicitly generated, there's no way for it to have side effects, so get rid of it to
2066	// clean up generated code
2067	if ( InitTweak::isIntrinsicSingleArgCallStmt( ctorInit->ctor ) ) {
2068	ctorInit = ast::mutate_field( ctorInit, &ast::ConstructorInit::ctor, nullptr );
2069	}
2070	if ( InitTweak::isIntrinsicSingleArgCallStmt( ctorInit->dtor ) ) {
2071	ctorInit = ast::mutate_field( ctorInit, &ast::ConstructorInit::dtor, nullptr );
2072	}
2073
2074	return ctorInit;
2075	}
2076
2077	// suppress error on autogen functions and mark invalid autogen as deleted.
2078	bool Resolver_new::on_error(ast::ptr<ast::Decl> & decl) {
2079	if (auto functionDecl = decl.as<ast::FunctionDecl>()) {
2080	// xxx - can intrinsic gen ever fail?
2081	if (functionDecl->linkage == ast::Linkage::AutoGen) {
2082	auto mutDecl = mutate(functionDecl);
2083	mutDecl->isDeleted = true;
2084	mutDecl->stmts = nullptr;
2085	decl = mutDecl;
2086	return false;
2087	}
2088	}
2089	return true;
2090	}
2091
2092	} // namespace ResolvExpr
2093
2094	// Local Variables: //
2095	// tab-width: 4 //
2096	// mode: c++ //
2097	// compile-command: "make install" //
2098	// End: //

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