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Resolver.cc @ de52331

ADTast-experimentalenumforall-pointer-decayjacob/cs343-translationnew-ast-unique-exprpthread-emulationqualifiedEnum

Last change on this file since de52331 was 7583c02, checked in by Fangren Yu <f37yu@…>, 4 years ago

partially improve #226: resolver environment size reduced to O(n)

generated code still has exponential size. should cache resolved implicits
and reuse thunks to reduce generated code size.
assertion fails cannot exit early and may have a minor performance
reduction.

Property mode set to 100644

File size: 76.2 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	// 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	ast::TypeEnvironment env;
1154	ast::ptr< ast::Expr > newExpr = resolveInVoidContext( untyped, symtab, env );
1155	finishExpr( newExpr, env, untyped->env );
1156	return newExpr;
1157	}
1158
1159	namespace {
1160
1161
1162	/// resolve `untyped` to the expression whose candidate satisfies `pred` with the
1163	/// lowest cost, returning the resolved version
1164	ast::ptr< ast::Expr > findKindExpression(
1165	const ast::Expr * untyped, const ast::SymbolTable & symtab,
1166	std::function<bool(const Candidate &)> pred = anyCandidate,
1167	const std::string & kind = "", ResolvMode mode = {}
1168	) {
1169	if ( ! untyped ) return {};
1170	CandidateRef choice =
1171	findUnfinishedKindExpression( untyped, symtab, kind, pred, mode );
1172	ResolvExpr::finishExpr( choice->expr, choice->env, untyped->env );
1173	return std::move( choice->expr );
1174	}
1175
1176	/// Resolve `untyped` to the single expression whose candidate is the best match
1177	ast::ptr< ast::Expr > findSingleExpression(
1178	const ast::Expr * untyped, const ast::SymbolTable & symtab
1179	) {
1180	Stats::ResolveTime::start( untyped );
1181	auto res = findKindExpression( untyped, symtab );
1182	Stats::ResolveTime::stop();
1183	return res;
1184	}
1185	} // anonymous namespace
1186
1187	ast::ptr< ast::Expr > findSingleExpression(
1188	const ast::Expr * untyped, const ast::Type * type, const ast::SymbolTable & symtab
1189	) {
1190	assert( untyped && type );
1191	ast::ptr< ast::Expr > castExpr = new ast::CastExpr{ untyped, type };
1192	ast::ptr< ast::Expr > newExpr = findSingleExpression( castExpr, symtab );
1193	removeExtraneousCast( newExpr, symtab );
1194	return newExpr;
1195	}
1196
1197	namespace {
1198	bool structOrUnion( const Candidate & i ) {
1199	const ast::Type * t = i.expr->result->stripReferences();
1200	return dynamic_cast< const ast::StructInstType * >( t ) \|\| dynamic_cast< const ast::UnionInstType * >( t );
1201	}
1202	/// Predicate for "Candidate has integral type"
1203	bool hasIntegralType( const Candidate & i ) {
1204	const ast::Type * type = i.expr->result;
1205
1206	if ( auto bt = dynamic_cast< const ast::BasicType * >( type ) ) {
1207	return bt->isInteger();
1208	} else if (
1209	dynamic_cast< const ast::EnumInstType * >( type )
1210	\|\| dynamic_cast< const ast::ZeroType * >( type )
1211	\|\| dynamic_cast< const ast::OneType * >( type )
1212	) {
1213	return true;
1214	} else return false;
1215	}
1216
1217	/// Resolve `untyped` as an integral expression, returning the resolved version
1218	ast::ptr< ast::Expr > findIntegralExpression(
1219	const ast::Expr * untyped, const ast::SymbolTable & symtab
1220	) {
1221	return findKindExpression( untyped, symtab, hasIntegralType, "condition" );
1222	}
1223
1224	/// check if a type is a character type
1225	bool isCharType( const ast::Type * t ) {
1226	if ( auto bt = dynamic_cast< const ast::BasicType * >( t ) ) {
1227	return bt->kind == ast::BasicType::Char
1228	\|\| bt->kind == ast::BasicType::SignedChar
1229	\|\| bt->kind == ast::BasicType::UnsignedChar;
1230	}
1231	return false;
1232	}
1233
1234	/// Advance a type itertor to the next mutex parameter
1235	template<typename Iter>
1236	inline bool nextMutex( Iter & it, const Iter & end ) {
1237	while ( it != end && ! (*it)->is_mutex() ) { ++it; }
1238	return it != end;
1239	}
1240	}
1241
1242	class Resolver_new final
1243	: public ast::WithSymbolTable, public ast::WithGuards,
1244	public ast::WithVisitorRef<Resolver_new>, public ast::WithShortCircuiting,
1245	public ast::WithStmtsToAdd<> {
1246
1247	ast::ptr< ast::Type > functionReturn = nullptr;
1248	ast::CurrentObject currentObject;
1249	// for work previously in GenInit
1250	static InitTweak::ManagedTypes_new managedTypes;
1251
1252	bool inEnumDecl = false;
1253
1254	public:
1255	static size_t traceId;
1256	Resolver_new() = default;
1257	Resolver_new( const ast::SymbolTable & syms ) { symtab = syms; }
1258
1259	const ast::FunctionDecl * previsit( const ast::FunctionDecl * );
1260	const ast::FunctionDecl * postvisit( const ast::FunctionDecl * );
1261	const ast::ObjectDecl * previsit( const ast::ObjectDecl * );
1262	void previsit( const ast::AggregateDecl * );
1263	void previsit( const ast::StructDecl * );
1264	void previsit( const ast::EnumDecl * );
1265	const ast::StaticAssertDecl * previsit( const ast::StaticAssertDecl * );
1266
1267	const ast::ArrayType * previsit( const ast::ArrayType * );
1268	const ast::PointerType * previsit( const ast::PointerType * );
1269
1270	const ast::ExprStmt * previsit( const ast::ExprStmt * );
1271	const ast::AsmExpr * previsit( const ast::AsmExpr * );
1272	const ast::AsmStmt * previsit( const ast::AsmStmt * );
1273	const ast::IfStmt * previsit( const ast::IfStmt * );
1274	const ast::WhileStmt * previsit( const ast::WhileStmt * );
1275	const ast::ForStmt * previsit( const ast::ForStmt * );
1276	const ast::SwitchStmt * previsit( const ast::SwitchStmt * );
1277	const ast::CaseStmt * previsit( const ast::CaseStmt * );
1278	const ast::BranchStmt * previsit( const ast::BranchStmt * );
1279	const ast::ReturnStmt * previsit( const ast::ReturnStmt * );
1280	const ast::ThrowStmt * previsit( const ast::ThrowStmt * );
1281	const ast::CatchStmt * previsit( const ast::CatchStmt * );
1282	const ast::CatchStmt * postvisit( const ast::CatchStmt * );
1283	const ast::WaitForStmt * previsit( const ast::WaitForStmt * );
1284	const ast::WithStmt * previsit( const ast::WithStmt * );
1285
1286	const ast::SingleInit * previsit( const ast::SingleInit * );
1287	const ast::ListInit * previsit( const ast::ListInit * );
1288	const ast::ConstructorInit * previsit( const ast::ConstructorInit * );
1289
1290	void resolveWithExprs(std::vector<ast::ptr<ast::Expr>> & exprs, std::list<ast::ptr<ast::Stmt>> & stmtsToAdd);
1291
1292	void beginScope() { managedTypes.beginScope(); }
1293	void endScope() { managedTypes.endScope(); }
1294	bool on_error(ast::ptr<ast::Decl> & decl);
1295	};
1296	// size_t Resolver_new::traceId = Stats::Heap::new_stacktrace_id("Resolver");
1297
1298	InitTweak::ManagedTypes_new Resolver_new::managedTypes;
1299
1300	void resolve( ast::TranslationUnit& translationUnit ) {
1301	ast::Pass< Resolver_new >::run( translationUnit );
1302	}
1303
1304	ast::ptr< ast::Init > resolveCtorInit(
1305	const ast::ConstructorInit * ctorInit, const ast::SymbolTable & symtab
1306	) {
1307	assert( ctorInit );
1308	ast::Pass< Resolver_new > resolver{ symtab };
1309	return ctorInit->accept( resolver );
1310	}
1311
1312	const ast::Expr * resolveStmtExpr(
1313	const ast::StmtExpr * stmtExpr, const ast::SymbolTable & symtab
1314	) {
1315	assert( stmtExpr );
1316	ast::Pass< Resolver_new > resolver{ symtab };
1317	auto ret = mutate(stmtExpr->accept(resolver));
1318	strict_dynamic_cast< ast::StmtExpr * >( ret )->computeResult();
1319	return ret;
1320	}
1321
1322	namespace {
1323	const ast::Attribute * handleAttribute(const CodeLocation & loc, const ast::Attribute * attr, const ast::SymbolTable & symtab) {
1324	std::string name = attr->normalizedName();
1325	if (name == "constructor" \|\| name == "destructor") {
1326	if (attr->params.size() == 1) {
1327	auto arg = attr->params.front();
1328	auto resolved = ResolvExpr::findSingleExpression( arg, new ast::BasicType( ast::BasicType::LongLongSignedInt ), symtab );
1329	auto result = eval(arg);
1330
1331	auto mutAttr = mutate(attr);
1332	mutAttr->params.front() = resolved;
1333	if (! result.second) {
1334	SemanticWarning(loc, Warning::GccAttributes,
1335	toCString( name, " priorities must be integers from 0 to 65535 inclusive: ", arg ) );
1336	}
1337	else {
1338	auto priority = result.first;
1339	if (priority < 101) {
1340	SemanticWarning(loc, Warning::GccAttributes,
1341	toCString( name, " priorities from 0 to 100 are reserved for the implementation" ) );
1342	} else if (priority < 201 && ! buildingLibrary()) {
1343	SemanticWarning(loc, Warning::GccAttributes,
1344	toCString( name, " priorities from 101 to 200 are reserved for the implementation" ) );
1345	}
1346	}
1347	return mutAttr;
1348	} else if (attr->params.size() > 1) {
1349	SemanticWarning(loc, Warning::GccAttributes, toCString( "too many arguments to ", name, " attribute" ) );
1350	} else {
1351	SemanticWarning(loc, Warning::GccAttributes, toCString( "too few arguments to ", name, " attribute" ) );
1352	}
1353	}
1354	return attr;
1355	}
1356	}
1357
1358	const ast::FunctionDecl * Resolver_new::previsit( const ast::FunctionDecl * functionDecl ) {
1359	GuardValue( functionReturn );
1360
1361	assert (functionDecl->unique());
1362	if (!functionDecl->has_body() && !functionDecl->withExprs.empty()) {
1363	SemanticError(functionDecl->location, functionDecl, "Function without body has with declarations");
1364	}
1365
1366	if (!functionDecl->isTypeFixed) {
1367	auto mutDecl = mutate(functionDecl);
1368	auto mutType = mutDecl->type.get_and_mutate();
1369
1370	for (auto & attr: mutDecl->attributes) {
1371	attr = handleAttribute(mutDecl->location, attr, symtab);
1372	}
1373
1374	// handle assertions
1375
1376	symtab.enterScope();
1377	mutType->forall.clear();
1378	mutType->assertions.clear();
1379	for (auto & typeParam : mutDecl->type_params) {
1380	symtab.addType(typeParam);
1381	mutType->forall.emplace_back(new ast::TypeInstType(typeParam->name, typeParam));
1382	}
1383	for (auto & asst : mutDecl->assertions) {
1384	asst = fixObjectType(asst.strict_as<ast::ObjectDecl>(), symtab);
1385	symtab.addId(asst);
1386	mutType->assertions.emplace_back(new ast::VariableExpr(functionDecl->location, asst));
1387	}
1388
1389	// temporarily adds params to symbol table.
1390	// actual scoping rules for params and withexprs differ - see Pass::visit(FunctionDecl)
1391
1392	std::vector<ast::ptr<ast::Type>> paramTypes;
1393	std::vector<ast::ptr<ast::Type>> returnTypes;
1394
1395	for (auto & param : mutDecl->params) {
1396	param = fixObjectType(param.strict_as<ast::ObjectDecl>(), symtab);
1397	symtab.addId(param);
1398	paramTypes.emplace_back(param->get_type());
1399	}
1400	for (auto & ret : mutDecl->returns) {
1401	ret = fixObjectType(ret.strict_as<ast::ObjectDecl>(), symtab);
1402	returnTypes.emplace_back(ret->get_type());
1403	}
1404	// since function type in decl is just a view of param types, need to update that as well
1405	mutType->params = std::move(paramTypes);
1406	mutType->returns = std::move(returnTypes);
1407
1408	auto renamedType = strict_dynamic_cast<const ast::FunctionType *>(renameTyVars(mutType, RenameMode::GEN_EXPR_ID));
1409
1410	std::list<ast::ptr<ast::Stmt>> newStmts;
1411	resolveWithExprs (mutDecl->withExprs, newStmts);
1412
1413	if (mutDecl->stmts) {
1414	auto mutStmt = mutDecl->stmts.get_and_mutate();
1415	mutStmt->kids.splice(mutStmt->kids.begin(), std::move(newStmts));
1416	mutDecl->stmts = mutStmt;
1417	}
1418
1419	symtab.leaveScope();
1420
1421	mutDecl->type = renamedType;
1422	mutDecl->mangleName = Mangle::mangle(mutDecl);
1423	mutDecl->isTypeFixed = true;
1424	functionDecl = mutDecl;
1425	}
1426	managedTypes.handleDWT(functionDecl);
1427
1428	functionReturn = extractResultType( functionDecl->type );
1429	return functionDecl;
1430	}
1431
1432	const ast::FunctionDecl * Resolver_new::postvisit( const ast::FunctionDecl * functionDecl ) {
1433	// default value expressions have an environment which shouldn't be there and trips up
1434	// later passes.
1435	assert( functionDecl->unique() );
1436	ast::FunctionType * mutType = mutate( functionDecl->type.get() );
1437
1438	for ( unsigned i = 0 ; i < mutType->params.size() ; ++i ) {
1439	if ( const ast::ObjectDecl * obj = mutType->params[i].as< ast::ObjectDecl >() ) {
1440	if ( const ast::SingleInit * init = obj->init.as< ast::SingleInit >() ) {
1441	if ( init->value->env == nullptr ) continue;
1442	// clone initializer minus the initializer environment
1443	auto mutParam = mutate( mutType->params[i].strict_as< ast::ObjectDecl >() );
1444	auto mutInit = mutate( mutParam->init.strict_as< ast::SingleInit >() );
1445	auto mutValue = mutate( mutInit->value.get() );
1446
1447	mutValue->env = nullptr;
1448	mutInit->value = mutValue;
1449	mutParam->init = mutInit;
1450	mutType->params[i] = mutParam;
1451
1452	assert( ! mutType->params[i].strict_as< ast::ObjectDecl >()->init.strict_as< ast::SingleInit >()->value->env);
1453	}
1454	}
1455	}
1456	mutate_field(functionDecl, &ast::FunctionDecl::type, mutType);
1457	return functionDecl;
1458	}
1459
1460	const ast::ObjectDecl * Resolver_new::previsit( const ast::ObjectDecl * objectDecl ) {
1461	// To handle initialization of routine pointers [e.g. int (*fp)(int) = foo()],
1462	// class-variable `initContext` is changed multiple times because the LHS is analyzed
1463	// twice. The second analysis changes `initContext` because a function type can contain
1464	// object declarations in the return and parameter types. Therefore each value of
1465	// `initContext` is retained so the type on the first analysis is preserved and used for
1466	// selecting the RHS.
1467	GuardValue( currentObject );
1468
1469	if ( inEnumDecl && dynamic_cast< const ast::EnumInstType * >( objectDecl->get_type() ) ) {
1470	// enumerator initializers should not use the enum type to initialize, since the
1471	// enum type is still incomplete at this point. Use `int` instead.
1472	objectDecl = fixObjectType(objectDecl, symtab);
1473	currentObject = ast::CurrentObject{
1474	objectDecl->location, new ast::BasicType{ ast::BasicType::SignedInt } };
1475	}
1476	else {
1477	if (!objectDecl->isTypeFixed) {
1478	auto newDecl = fixObjectType(objectDecl, symtab);
1479	auto mutDecl = mutate(newDecl);
1480
1481	// generate CtorInit wrapper when necessary.
1482	// in certain cases, fixObjectType is called before reaching
1483	// this object in visitor pass, thus disabling CtorInit codegen.
1484	// this happens on aggregate members and function parameters.
1485	if ( InitTweak::tryConstruct( mutDecl ) && ( managedTypes.isManaged( mutDecl ) \|\| ((! isInFunction() \|\| mutDecl->storage.is_static ) && ! InitTweak::isConstExpr( mutDecl->init ) ) ) ) {
1486	// constructed objects cannot be designated
1487	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" );
1488	// constructed objects should not have initializers nested too deeply
1489	if ( ! InitTweak::checkInitDepth( mutDecl ) ) SemanticError( mutDecl, "Managed object's initializer is too deep " );
1490
1491	mutDecl->init = InitTweak::genCtorInit( mutDecl->location, mutDecl );
1492	}
1493
1494	objectDecl = mutDecl;
1495	}
1496	currentObject = ast::CurrentObject{ objectDecl->location, objectDecl->get_type() };
1497	}
1498
1499	return objectDecl;
1500	}
1501
1502	void Resolver_new::previsit( const ast::AggregateDecl * _aggDecl ) {
1503	auto aggDecl = mutate(_aggDecl);
1504	assertf(aggDecl == _aggDecl, "type declarations must be unique");
1505
1506	for (auto & member: aggDecl->members) {
1507	// nested type decls are hoisted already. no need to do anything
1508	if (auto obj = member.as<ast::ObjectDecl>()) {
1509	member = fixObjectType(obj, symtab);
1510	}
1511	}
1512	}
1513
1514	void Resolver_new::previsit( const ast::StructDecl * structDecl ) {
1515	previsit(static_cast<const ast::AggregateDecl *>(structDecl));
1516	managedTypes.handleStruct(structDecl);
1517	}
1518
1519	void Resolver_new::previsit( const ast::EnumDecl * ) {
1520	// in case we decide to allow nested enums
1521	GuardValue( inEnumDecl );
1522	inEnumDecl = true;
1523	// don't need to fix types for enum fields
1524	}
1525
1526
1527	const ast::StaticAssertDecl * Resolver_new::previsit(
1528	const ast::StaticAssertDecl * assertDecl
1529	) {
1530	return ast::mutate_field(
1531	assertDecl, &ast::StaticAssertDecl::cond,
1532	findIntegralExpression( assertDecl->cond, symtab ) );
1533	}
1534
1535	template< typename PtrType >
1536	const PtrType * handlePtrType( const PtrType * type, const ast::SymbolTable & symtab ) {
1537	if ( type->dimension ) {
1538	ast::ptr< ast::Type > sizeType = ast::sizeType;
1539	ast::mutate_field(
1540	type, &PtrType::dimension,
1541	findSingleExpression( type->dimension, sizeType, symtab ) );
1542	}
1543	return type;
1544	}
1545
1546	const ast::ArrayType * Resolver_new::previsit( const ast::ArrayType * at ) {
1547	return handlePtrType( at, symtab );
1548	}
1549
1550	const ast::PointerType * Resolver_new::previsit( const ast::PointerType * pt ) {
1551	return handlePtrType( pt, symtab );
1552	}
1553
1554	const ast::ExprStmt * Resolver_new::previsit( const ast::ExprStmt * exprStmt ) {
1555	visit_children = false;
1556	assertf( exprStmt->expr, "ExprStmt has null expression in resolver" );
1557
1558	return ast::mutate_field(
1559	exprStmt, &ast::ExprStmt::expr, findVoidExpression( exprStmt->expr, symtab ) );
1560	}
1561
1562	const ast::AsmExpr * Resolver_new::previsit( const ast::AsmExpr * asmExpr ) {
1563	visit_children = false;
1564
1565	asmExpr = ast::mutate_field(
1566	asmExpr, &ast::AsmExpr::operand, findVoidExpression( asmExpr->operand, symtab ) );
1567
1568	return asmExpr;
1569	}
1570
1571	const ast::AsmStmt * Resolver_new::previsit( const ast::AsmStmt * asmStmt ) {
1572	visitor->maybe_accept( asmStmt, &ast::AsmStmt::input );
1573	visitor->maybe_accept( asmStmt, &ast::AsmStmt::output );
1574	visit_children = false;
1575	return asmStmt;
1576	}
1577
1578	const ast::IfStmt * Resolver_new::previsit( const ast::IfStmt * ifStmt ) {
1579	return ast::mutate_field(
1580	ifStmt, &ast::IfStmt::cond, findIntegralExpression( ifStmt->cond, symtab ) );
1581	}
1582
1583	const ast::WhileStmt * Resolver_new::previsit( const ast::WhileStmt * whileStmt ) {
1584	return ast::mutate_field(
1585	whileStmt, &ast::WhileStmt::cond, findIntegralExpression( whileStmt->cond, symtab ) );
1586	}
1587
1588	const ast::ForStmt * Resolver_new::previsit( const ast::ForStmt * forStmt ) {
1589	if ( forStmt->cond ) {
1590	forStmt = ast::mutate_field(
1591	forStmt, &ast::ForStmt::cond, findIntegralExpression( forStmt->cond, symtab ) );
1592	}
1593
1594	if ( forStmt->inc ) {
1595	forStmt = ast::mutate_field(
1596	forStmt, &ast::ForStmt::inc, findVoidExpression( forStmt->inc, symtab ) );
1597	}
1598
1599	return forStmt;
1600	}
1601
1602	const ast::SwitchStmt * Resolver_new::previsit( const ast::SwitchStmt * switchStmt ) {
1603	GuardValue( currentObject );
1604	switchStmt = ast::mutate_field(
1605	switchStmt, &ast::SwitchStmt::cond,
1606	findIntegralExpression( switchStmt->cond, symtab ) );
1607	currentObject = ast::CurrentObject{ switchStmt->location, switchStmt->cond->result };
1608	return switchStmt;
1609	}
1610
1611	const ast::CaseStmt * Resolver_new::previsit( const ast::CaseStmt * caseStmt ) {
1612	if ( caseStmt->cond ) {
1613	std::deque< ast::InitAlternative > initAlts = currentObject.getOptions();
1614	assertf( initAlts.size() == 1, "SwitchStmt did not correctly resolve an integral "
1615	"expression." );
1616
1617	ast::ptr< ast::Expr > untyped =
1618	new ast::CastExpr{ caseStmt->location, caseStmt->cond, initAlts.front().type };
1619	ast::ptr< ast::Expr > newExpr = findSingleExpression( untyped, symtab );
1620
1621	// case condition cannot have a cast in C, so it must be removed here, regardless of
1622	// whether it would perform a conversion.
1623	if ( const ast::CastExpr * castExpr = newExpr.as< ast::CastExpr >() ) {
1624	swap_and_save_env( newExpr, castExpr->arg );
1625	}
1626
1627	caseStmt = ast::mutate_field( caseStmt, &ast::CaseStmt::cond, newExpr );
1628	}
1629	return caseStmt;
1630	}
1631
1632	const ast::BranchStmt * Resolver_new::previsit( const ast::BranchStmt * branchStmt ) {
1633	visit_children = false;
1634	// must resolve the argument of a computed goto
1635	if ( branchStmt->kind == ast::BranchStmt::Goto && branchStmt->computedTarget ) {
1636	// computed goto argument is void*
1637	ast::ptr< ast::Type > target = new ast::PointerType{ new ast::VoidType{} };
1638	branchStmt = ast::mutate_field(
1639	branchStmt, &ast::BranchStmt::computedTarget,
1640	findSingleExpression( branchStmt->computedTarget, target, symtab ) );
1641	}
1642	return branchStmt;
1643	}
1644
1645	const ast::ReturnStmt * Resolver_new::previsit( const ast::ReturnStmt * returnStmt ) {
1646	visit_children = false;
1647	if ( returnStmt->expr ) {
1648	returnStmt = ast::mutate_field(
1649	returnStmt, &ast::ReturnStmt::expr,
1650	findSingleExpression( returnStmt->expr, functionReturn, symtab ) );
1651	}
1652	return returnStmt;
1653	}
1654
1655	const ast::ThrowStmt * Resolver_new::previsit( const ast::ThrowStmt * throwStmt ) {
1656	visit_children = false;
1657	if ( throwStmt->expr ) {
1658	const ast::StructDecl * exceptionDecl =
1659	symtab.lookupStruct( "__cfaehm_base_exception_t" );
1660	assert( exceptionDecl );
1661	ast::ptr< ast::Type > exceptType =
1662	new ast::PointerType{ new ast::StructInstType{ exceptionDecl } };
1663	throwStmt = ast::mutate_field(
1664	throwStmt, &ast::ThrowStmt::expr,
1665	findSingleExpression( throwStmt->expr, exceptType, symtab ) );
1666	}
1667	return throwStmt;
1668	}
1669
1670	const ast::CatchStmt * Resolver_new::previsit( const ast::CatchStmt * catchStmt ) {
1671	// Until we are very sure this invarent (ifs that move between passes have thenPart)
1672	// holds, check it. This allows a check for when to decode the mangling.
1673	if ( auto ifStmt = catchStmt->body.as<ast::IfStmt>() ) {
1674	assert( ifStmt->thenPart );
1675	}
1676	// Encode the catchStmt so the condition can see the declaration.
1677	if ( catchStmt->cond ) {
1678	ast::CatchStmt * stmt = mutate( catchStmt );
1679	stmt->body = new ast::IfStmt( stmt->location, stmt->cond, nullptr, stmt->body );
1680	stmt->cond = nullptr;
1681	return stmt;
1682	}
1683	return catchStmt;
1684	}
1685
1686	const ast::CatchStmt * Resolver_new::postvisit( const ast::CatchStmt * catchStmt ) {
1687	// Decode the catchStmt so everything is stored properly.
1688	const ast::IfStmt * ifStmt = catchStmt->body.as<ast::IfStmt>();
1689	if ( nullptr != ifStmt && nullptr == ifStmt->thenPart ) {
1690	assert( ifStmt->cond );
1691	assert( ifStmt->elsePart );
1692	ast::CatchStmt * stmt = ast::mutate( catchStmt );
1693	stmt->cond = ifStmt->cond;
1694	stmt->body = ifStmt->elsePart;
1695	// ifStmt should be implicately deleted here.
1696	return stmt;
1697	}
1698	return catchStmt;
1699	}
1700
1701	const ast::WaitForStmt * Resolver_new::previsit( const ast::WaitForStmt * stmt ) {
1702	visit_children = false;
1703
1704	// Resolve all clauses first
1705	for ( unsigned i = 0; i < stmt->clauses.size(); ++i ) {
1706	const ast::WaitForStmt::Clause & clause = stmt->clauses[i];
1707
1708	ast::TypeEnvironment env;
1709	CandidateFinder funcFinder{ symtab, env };
1710
1711	// Find all candidates for a function in canonical form
1712	funcFinder.find( clause.target.func, ResolvMode::withAdjustment() );
1713
1714	if ( funcFinder.candidates.empty() ) {
1715	stringstream ss;
1716	ss << "Use of undeclared indentifier '";
1717	ss << clause.target.func.strict_as< ast::NameExpr >()->name;
1718	ss << "' in call to waitfor";
1719	SemanticError( stmt->location, ss.str() );
1720	}
1721
1722	if ( clause.target.args.empty() ) {
1723	SemanticError( stmt->location,
1724	"Waitfor clause must have at least one mutex parameter");
1725	}
1726
1727	// Find all alternatives for all arguments in canonical form
1728	std::vector< CandidateFinder > argFinders =
1729	funcFinder.findSubExprs( clause.target.args );
1730
1731	// List all combinations of arguments
1732	std::vector< CandidateList > possibilities;
1733	combos( argFinders.begin(), argFinders.end(), back_inserter( possibilities ) );
1734
1735	// For every possible function:
1736	// * try matching the arguments to the parameters, not the other way around because
1737	// more arguments than parameters
1738	CandidateList funcCandidates;
1739	std::vector< CandidateList > argsCandidates;
1740	SemanticErrorException errors;
1741	for ( CandidateRef & func : funcFinder.candidates ) {
1742	try {
1743	auto pointerType = dynamic_cast< const ast::PointerType * >(
1744	func->expr->result->stripReferences() );
1745	if ( ! pointerType ) {
1746	SemanticError( stmt->location, func->expr->result.get(),
1747	"candidate not viable: not a pointer type\n" );
1748	}
1749
1750	auto funcType = pointerType->base.as< ast::FunctionType >();
1751	if ( ! funcType ) {
1752	SemanticError( stmt->location, func->expr->result.get(),
1753	"candidate not viable: not a function type\n" );
1754	}
1755
1756	{
1757	auto param = funcType->params.begin();
1758	auto paramEnd = funcType->params.end();
1759
1760	if( ! nextMutex( param, paramEnd ) ) {
1761	SemanticError( stmt->location, funcType,
1762	"candidate function not viable: no mutex parameters\n");
1763	}
1764	}
1765
1766	CandidateRef func2{ new Candidate{ *func } };
1767	// strip reference from function
1768	func2->expr = referenceToRvalueConversion( func->expr, func2->cost );
1769
1770	// Each argument must be matched with a parameter of the current candidate
1771	for ( auto & argsList : possibilities ) {
1772	try {
1773	// Declare data structures needed for resolution
1774	ast::OpenVarSet open;
1775	ast::AssertionSet need, have;
1776	ast::TypeEnvironment resultEnv{ func->env };
1777	// Add all type variables as open so that those not used in the
1778	// parameter list are still considered open
1779	resultEnv.add( funcType->forall );
1780
1781	// load type variables from arguments into one shared space
1782	for ( auto & arg : argsList ) {
1783	resultEnv.simpleCombine( arg->env );
1784	}
1785
1786	// Make sure we don't widen any existing bindings
1787	resultEnv.forbidWidening();
1788
1789	// Find any unbound type variables
1790	resultEnv.extractOpenVars( open );
1791
1792	auto param = funcType->params.begin();
1793	auto paramEnd = funcType->params.end();
1794
1795	unsigned n_mutex_param = 0;
1796
1797	// For every argument of its set, check if it matches one of the
1798	// parameters. The order is important
1799	for ( auto & arg : argsList ) {
1800	// Ignore non-mutex arguments
1801	if ( ! nextMutex( param, paramEnd ) ) {
1802	// We ran out of parameters but still have arguments.
1803	// This function doesn't match
1804	SemanticError( stmt->location, funcType,
1805	toString("candidate function not viable: too many mutex "
1806	"arguments, expected ", n_mutex_param, "\n" ) );
1807	}
1808
1809	++n_mutex_param;
1810
1811	// Check if the argument matches the parameter type in the current
1812	// scope
1813	// ast::ptr< ast::Type > paramType = (*param)->get_type();
1814	if (
1815	! unify(
1816	arg->expr->result, *param, resultEnv, need, have, open,
1817	symtab )
1818	) {
1819	// Type doesn't match
1820	stringstream ss;
1821	ss << "candidate function not viable: no known conversion "
1822	"from '";
1823	ast::print( ss, *param );
1824	ss << "' to '";
1825	ast::print( ss, arg->expr->result );
1826	ss << "' with env '";
1827	ast::print( ss, resultEnv );
1828	ss << "'\n";
1829	SemanticError( stmt->location, funcType, ss.str() );
1830	}
1831
1832	++param;
1833	}
1834
1835	// All arguments match!
1836
1837	// Check if parameters are missing
1838	if ( nextMutex( param, paramEnd ) ) {
1839	do {
1840	++n_mutex_param;
1841	++param;
1842	} while ( nextMutex( param, paramEnd ) );
1843
1844	// We ran out of arguments but still have parameters left; this
1845	// function doesn't match
1846	SemanticError( stmt->location, funcType,
1847	toString( "candidate function not viable: too few mutex "
1848	"arguments, expected ", n_mutex_param, "\n" ) );
1849	}
1850
1851	// All parameters match!
1852
1853	// Finish the expressions to tie in proper environments
1854	finishExpr( func2->expr, resultEnv );
1855	for ( CandidateRef & arg : argsList ) {
1856	finishExpr( arg->expr, resultEnv );
1857	}
1858
1859	// This is a match, store it and save it for later
1860	funcCandidates.emplace_back( std::move( func2 ) );
1861	argsCandidates.emplace_back( std::move( argsList ) );
1862
1863	} catch ( SemanticErrorException & e ) {
1864	errors.append( e );
1865	}
1866	}
1867	} catch ( SemanticErrorException & e ) {
1868	errors.append( e );
1869	}
1870	}
1871
1872	// Make sure correct number of arguments
1873	if( funcCandidates.empty() ) {
1874	SemanticErrorException top( stmt->location,
1875	"No alternatives for function in call to waitfor" );
1876	top.append( errors );
1877	throw top;
1878	}
1879
1880	if( argsCandidates.empty() ) {
1881	SemanticErrorException top( stmt->location,
1882	"No alternatives for arguments in call to waitfor" );
1883	top.append( errors );
1884	throw top;
1885	}
1886
1887	if( funcCandidates.size() > 1 ) {
1888	SemanticErrorException top( stmt->location,
1889	"Ambiguous function in call to waitfor" );
1890	top.append( errors );
1891	throw top;
1892	}
1893	if( argsCandidates.size() > 1 ) {
1894	SemanticErrorException top( stmt->location,
1895	"Ambiguous arguments in call to waitfor" );
1896	top.append( errors );
1897	throw top;
1898	}
1899	// TODO: need to use findDeletedExpr to ensure no deleted identifiers are used.
1900
1901	// build new clause
1902	ast::WaitForStmt::Clause clause2;
1903
1904	clause2.target.func = funcCandidates.front()->expr;
1905
1906	clause2.target.args.reserve( clause.target.args.size() );
1907	for ( auto arg : argsCandidates.front() ) {
1908	clause2.target.args.emplace_back( std::move( arg->expr ) );
1909	}
1910
1911	// Resolve the conditions as if it were an IfStmt, statements normally
1912	clause2.cond = findSingleExpression( clause.cond, symtab );
1913	clause2.stmt = clause.stmt->accept( *visitor );
1914
1915	// set results into stmt
1916	auto n = mutate( stmt );
1917	n->clauses[i] = std::move( clause2 );
1918	stmt = n;
1919	}
1920
1921	if ( stmt->timeout.stmt ) {
1922	// resolve the timeout as a size_t, the conditions like IfStmt, and stmts normally
1923	ast::WaitForStmt::Timeout timeout2;
1924
1925	ast::ptr< ast::Type > target =
1926	new ast::BasicType{ ast::BasicType::LongLongUnsignedInt };
1927	timeout2.time = findSingleExpression( stmt->timeout.time, target, symtab );
1928	timeout2.cond = findSingleExpression( stmt->timeout.cond, symtab );
1929	timeout2.stmt = stmt->timeout.stmt->accept( *visitor );
1930
1931	// set results into stmt
1932	auto n = mutate( stmt );
1933	n->timeout = std::move( timeout2 );
1934	stmt = n;
1935	}
1936
1937	if ( stmt->orElse.stmt ) {
1938	// resolve the condition like IfStmt, stmts normally
1939	ast::WaitForStmt::OrElse orElse2;
1940
1941	orElse2.cond = findSingleExpression( stmt->orElse.cond, symtab );
1942	orElse2.stmt = stmt->orElse.stmt->accept( *visitor );
1943
1944	// set results into stmt
1945	auto n = mutate( stmt );
1946	n->orElse = std::move( orElse2 );
1947	stmt = n;
1948	}
1949
1950	return stmt;
1951	}
1952
1953	const ast::WithStmt * Resolver_new::previsit( const ast::WithStmt * withStmt ) {
1954	auto mutStmt = mutate(withStmt);
1955	resolveWithExprs(mutStmt->exprs, stmtsToAddBefore);
1956	return mutStmt;
1957	}
1958
1959	void Resolver_new::resolveWithExprs(std::vector<ast::ptr<ast::Expr>> & exprs, std::list<ast::ptr<ast::Stmt>> & stmtsToAdd) {
1960	for (auto & expr : exprs) {
1961	// only struct- and union-typed expressions are viable candidates
1962	expr = findKindExpression( expr, symtab, structOrUnion, "with expression" );
1963
1964	// if with expression might be impure, create a temporary so that it is evaluated once
1965	if ( Tuples::maybeImpure( expr ) ) {
1966	static UniqueName tmpNamer( "_with_tmp_" );
1967	const CodeLocation loc = expr->location;
1968	auto tmp = new ast::ObjectDecl(loc, tmpNamer.newName(), expr->result, new ast::SingleInit(loc, expr ) );
1969	expr = new ast::VariableExpr( loc, tmp );
1970	stmtsToAdd.push_back( new ast::DeclStmt(loc, tmp ) );
1971	if ( InitTweak::isConstructable( tmp->type ) ) {
1972	// generate ctor/dtor and resolve them
1973	tmp->init = InitTweak::genCtorInit( loc, tmp );
1974	}
1975	// since tmp is freshly created, this should modify tmp in-place
1976	tmp->accept( *visitor );
1977	}
1978	}
1979	}
1980
1981
1982	const ast::SingleInit * Resolver_new::previsit( const ast::SingleInit * singleInit ) {
1983	visit_children = false;
1984	// resolve initialization using the possibilities as determined by the `currentObject`
1985	// cursor.
1986	ast::ptr< ast::Expr > untyped = new ast::UntypedInitExpr{
1987	singleInit->location, singleInit->value, currentObject.getOptions() };
1988	ast::ptr<ast::Expr> newExpr = findSingleExpression( untyped, symtab );
1989	const ast::InitExpr * initExpr = newExpr.strict_as< ast::InitExpr >();
1990
1991	// move cursor to the object that is actually initialized
1992	currentObject.setNext( initExpr->designation );
1993
1994	// discard InitExpr wrapper and retain relevant pieces.
1995	// `initExpr` may have inferred params in the case where the expression specialized a
1996	// function pointer, and newExpr may already have inferParams of its own, so a simple
1997	// swap is not sufficient
1998	ast::Expr::InferUnion inferred = initExpr->inferred;
1999	swap_and_save_env( newExpr, initExpr->expr );
2000	newExpr.get_and_mutate()->inferred.splice( std::move(inferred) );
2001
2002	// get the actual object's type (may not exactly match what comes back from the resolver
2003	// due to conversions)
2004	const ast::Type * initContext = currentObject.getCurrentType();
2005
2006	removeExtraneousCast( newExpr, symtab );
2007
2008	// check if actual object's type is char[]
2009	if ( auto at = dynamic_cast< const ast::ArrayType * >( initContext ) ) {
2010	if ( isCharType( at->base ) ) {
2011	// check if the resolved type is char*
2012	if ( auto pt = newExpr->result.as< ast::PointerType >() ) {
2013	if ( isCharType( pt->base ) ) {
2014	// strip cast if we're initializing a char[] with a char*
2015	// e.g. char x[] = "hello"
2016	if ( auto ce = newExpr.as< ast::CastExpr >() ) {
2017	swap_and_save_env( newExpr, ce->arg );
2018	}
2019	}
2020	}
2021	}
2022	}
2023
2024	// move cursor to next object in preparation for next initializer
2025	currentObject.increment();
2026
2027	// set initializer expression to resolved expression
2028	return ast::mutate_field( singleInit, &ast::SingleInit::value, std::move(newExpr) );
2029	}
2030
2031	const ast::ListInit * Resolver_new::previsit( const ast::ListInit * listInit ) {
2032	// move cursor into brace-enclosed initializer-list
2033	currentObject.enterListInit( listInit->location );
2034
2035	assert( listInit->designations.size() == listInit->initializers.size() );
2036	for ( unsigned i = 0; i < listInit->designations.size(); ++i ) {
2037	// iterate designations and initializers in pairs, moving the cursor to the current
2038	// designated object and resolving the initializer against that object
2039	listInit = ast::mutate_field_index(
2040	listInit, &ast::ListInit::designations, i,
2041	currentObject.findNext( listInit->designations[i] ) );
2042	listInit = ast::mutate_field_index(
2043	listInit, &ast::ListInit::initializers, i,
2044	listInit->initializers[i]->accept( *visitor ) );
2045	}
2046
2047	// move cursor out of brace-enclosed initializer-list
2048	currentObject.exitListInit();
2049
2050	visit_children = false;
2051	return listInit;
2052	}
2053
2054	const ast::ConstructorInit * Resolver_new::previsit( const ast::ConstructorInit * ctorInit ) {
2055	visitor->maybe_accept( ctorInit, &ast::ConstructorInit::ctor );
2056	visitor->maybe_accept( ctorInit, &ast::ConstructorInit::dtor );
2057
2058	// found a constructor - can get rid of C-style initializer
2059	// xxx - Rob suggests this field is dead code
2060	ctorInit = ast::mutate_field( ctorInit, &ast::ConstructorInit::init, nullptr );
2061
2062	// intrinsic single-parameter constructors and destructors do nothing. Since this was
2063	// implicitly generated, there's no way for it to have side effects, so get rid of it to
2064	// clean up generated code
2065	if ( InitTweak::isIntrinsicSingleArgCallStmt( ctorInit->ctor ) ) {
2066	ctorInit = ast::mutate_field( ctorInit, &ast::ConstructorInit::ctor, nullptr );
2067	}
2068	if ( InitTweak::isIntrinsicSingleArgCallStmt( ctorInit->dtor ) ) {
2069	ctorInit = ast::mutate_field( ctorInit, &ast::ConstructorInit::dtor, nullptr );
2070	}
2071
2072	return ctorInit;
2073	}
2074
2075	// suppress error on autogen functions and mark invalid autogen as deleted.
2076	bool Resolver_new::on_error(ast::ptr<ast::Decl> & decl) {
2077	if (auto functionDecl = decl.as<ast::FunctionDecl>()) {
2078	// xxx - can intrinsic gen ever fail?
2079	if (functionDecl->linkage == ast::Linkage::AutoGen) {
2080	auto mutDecl = mutate(functionDecl);
2081	mutDecl->isDeleted = true;
2082	mutDecl->stmts = nullptr;
2083	decl = mutDecl;
2084	return false;
2085	}
2086	}
2087	return true;
2088	}
2089
2090	} // namespace ResolvExpr
2091
2092	// Local Variables: //
2093	// tab-width: 4 //
2094	// mode: c++ //
2095	// compile-command: "make install" //
2096	// End: //

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source: src/ResolvExpr/Resolver.cc @ de52331

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