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source: src/InitTweak/FixInitNew.cpp@ c8f5f7d

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ADT ast-experimental pthread-emulation qualifiedEnum

Last change on this file since c8f5f7d was 8060b2b, checked in by Andrew Beach <ajbeach@…>, 3 years ago
Some recent work has taken me by ResolveCopyCtors, while there I saw some clean-up to do.
Property mode set to `100644`
File size: 58.5 KB

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1	#include "FixInit.h"
2
3	#include <stddef.h> // for NULL
4	#include <algorithm> // for set_difference, copy_if
5	#include <cassert> // for assert, strict_dynamic_cast
6	#include <iostream> // for operator<<, ostream, basic_ost...
7	#include <iterator> // for insert_iterator, back_inserter
8	#include <list> // for _List_iterator, list, list<>::...
9	#include <map> // for _Rb_tree_iterator, _Rb_tree_co...
10	#include <memory> // for allocator_traits<>::value_type
11	#include <set> // for set, set<>::value_type
12	#include <unordered_map> // for unordered_map, unordered_map<>...
13	#include <unordered_set> // for unordered_set
14	#include <utility> // for pair
15
16	#include "CodeGen/GenType.h" // for genPrettyType
17	#include "CodeGen/OperatorTable.h"
18	#include "Common/CodeLocationTools.hpp"
19	#include "Common/PassVisitor.h" // for PassVisitor, WithStmtsToAdd
20	#include "Common/SemanticError.h" // for SemanticError
21	#include "Common/UniqueName.h" // for UniqueName
22	#include "Common/utility.h" // for CodeLocation, ValueGuard, toSt...
23	#include "FixGlobalInit.h" // for fixGlobalInit
24	#include "GenInit.h" // for genCtorDtor
25	#include "GenPoly/GenPoly.h" // for getFunctionType
26	#include "InitTweak.h" // for getFunctionName, getCallArg
27	#include "ResolvExpr/Resolver.h" // for findVoidExpression
28	#include "ResolvExpr/typeops.h" // for typesCompatible
29	#include "SymTab/Autogen.h" // for genImplicitCall
30	#include "SymTab/Indexer.h" // for Indexer
31	#include "SymTab/Mangler.h" // for Mangler
32	#include "SynTree/LinkageSpec.h" // for C, Spec, Cforall, isBuiltin
33	#include "SynTree/Attribute.h" // for Attribute
34	#include "SynTree/Constant.h" // for Constant
35	#include "SynTree/Declaration.h" // for ObjectDecl, FunctionDecl, Decl...
36	#include "SynTree/Expression.h" // for UniqueExpr, VariableExpr, Unty...
37	#include "SynTree/Initializer.h" // for ConstructorInit, SingleInit
38	#include "SynTree/Label.h" // for Label, operator<
39	#include "SynTree/Mutator.h" // for mutateAll, Mutator, maybeMutate
40	#include "SynTree/Statement.h" // for ExprStmt, CompoundStmt, Branch...
41	#include "SynTree/Type.h" // for Type, Type::StorageClasses
42	#include "SynTree/TypeSubstitution.h" // for TypeSubstitution, operator<<
43	#include "SynTree/DeclReplacer.h" // for DeclReplacer
44	#include "SynTree/Visitor.h" // for acceptAll, maybeAccept
45	#include "Validate/FindSpecialDecls.h" // for dtorStmt, dtorStructDestroy
46
47	#include "AST/Expr.hpp"
48	#include "AST/Node.hpp"
49	#include "AST/Pass.hpp"
50	#include "AST/Print.hpp"
51	#include "AST/SymbolTable.hpp"
52	#include "AST/Type.hpp"
53	#include "AST/DeclReplacer.hpp"
54
55	extern bool ctordtorp; // print all debug
56	extern bool ctorp; // print ctor debug
57	extern bool cpctorp; // print copy ctor debug
58	extern bool dtorp; // print dtor debug
59	#define PRINT( text ) if ( ctordtorp ) { text }
60	#define CP_CTOR_PRINT( text ) if ( ctordtorp \|\| cpctorp ) { text }
61	#define DTOR_PRINT( text ) if ( ctordtorp \|\| dtorp ) { text }
62
63	namespace InitTweak {
64	namespace {
65	struct SelfAssignChecker {
66	void previsit( const ast::ApplicationExpr * appExpr );
67	};
68
69	struct StmtExprResult {
70	const ast::StmtExpr * previsit( const ast::StmtExpr * stmtExpr );
71	};
72
73	/// wrap function application expressions as ImplicitCopyCtorExpr nodes so that it is easy to identify which
74	/// function calls need their parameters to be copy constructed
75	struct InsertImplicitCalls : public ast::WithConstTypeSubstitution, public ast::WithShortCircuiting {
76	const ast::Expr * postvisit( const ast::ApplicationExpr * appExpr );
77
78	// only handles each UniqueExpr once
79	// if order of visit does not change, this should be safe
80	void previsit (const ast::UniqueExpr *);
81
82	std::unordered_set<decltype(ast::UniqueExpr::id)> visitedIds;
83	};
84
85	/// generate temporary ObjectDecls for each argument and return value of each ImplicitCopyCtorExpr,
86	/// generate/resolve copy construction expressions for each, and generate/resolve destructors for both
87	/// arguments and return value temporaries
88	struct ResolveCopyCtors final : public ast::WithGuards, public ast::WithStmtsToAdd<>, public ast::WithSymbolTable, public ast::WithShortCircuiting, public ast::WithVisitorRef<ResolveCopyCtors>, public ast::WithConstTranslationUnit {
89	const ast::Expr * postvisit( const ast::ImplicitCopyCtorExpr * impCpCtorExpr );
90	const ast::StmtExpr * previsit( const ast::StmtExpr * stmtExpr );
91	const ast::UniqueExpr * previsit( const ast::UniqueExpr * unqExpr );
92
93	/// handles distant mutations of environment manually.
94	/// WithConstTypeSubstitution cannot remember where the environment is from
95
96	/// MUST be called at start of overload previsit
97	void previsit( const ast::Expr * expr);
98	/// MUST be called at return of overload postvisit
99	const ast::Expr * postvisit(const ast::Expr * expr);
100
101	/// create and resolve ctor/dtor expression: fname(var, [cpArg])
102	const ast::Expr * makeCtorDtor( const std::string & fname, const ast::ObjectDecl * var, const ast::Expr * cpArg = nullptr );
103	/// true if type does not need to be copy constructed to ensure correctness
104	bool skipCopyConstruct( const ast::Type * type );
105	ast::ptr< ast::Expr > copyConstructArg( const ast::Expr * arg, const ast::ImplicitCopyCtorExpr * impCpCtorExpr, const ast::Type * formal );
106	ast::Expr * destructRet( const ast::ObjectDecl * ret, const ast::Expr * arg );
107	private:
108	/// hack to implement WithTypeSubstitution while conforming to mutation safety.
109	ast::TypeSubstitution * env;
110	bool envModified;
111	};
112
113	/// collects constructed object decls - used as a base class
114	struct ObjDeclCollector : public ast::WithGuards, public ast::WithShortCircuiting {
115	// use ordered data structure to maintain ordering for set_difference and for consistent error messages
116	typedef std::list< const ast::ObjectDecl * > ObjectSet;
117	void previsit( const ast::CompoundStmt *compoundStmt );
118	void previsit( const ast::DeclStmt *stmt );
119
120	// don't go into other functions
121	void previsit( const ast::FunctionDecl * ) { visit_children = false; }
122
123	protected:
124	ObjectSet curVars;
125	};
126
127	// debug
128	template<typename ObjectSet>
129	struct PrintSet {
130	PrintSet( const ObjectSet & objs ) : objs( objs ) {}
131	const ObjectSet & objs;
132	};
133	template<typename ObjectSet>
134	PrintSet<ObjectSet> printSet( const ObjectSet & objs ) { return PrintSet<ObjectSet>( objs ); }
135	template<typename ObjectSet>
136	std::ostream & operator<<( std::ostream & out, const PrintSet<ObjectSet> & set) {
137	out << "{ ";
138	for ( auto & obj : set.objs ) {
139	out << obj->name << ", " ;
140	} // for
141	out << " }";
142	return out;
143	}
144
145	struct LabelFinder final : public ObjDeclCollector {
146	typedef std::map< std::string, ObjectSet > LabelMap;
147	// map of Label -> live variables at that label
148	LabelMap vars;
149
150	typedef ObjDeclCollector Parent;
151	using Parent::previsit;
152	void previsit( const ast::Stmt * stmt );
153
154	void previsit( const ast::CompoundStmt *compoundStmt );
155	void previsit( const ast::DeclStmt *stmt );
156	};
157
158	/// insert destructor calls at the appropriate places. must happen before CtorInit nodes are removed
159	/// (currently by FixInit)
160	struct InsertDtors final : public ObjDeclCollector, public ast::WithStmtsToAdd<> {
161	typedef std::list< ObjectDecl * > OrderedDecls;
162	typedef std::list< OrderedDecls > OrderedDeclsStack;
163
164	InsertDtors( ast::Pass<LabelFinder> & finder ) : finder( finder ), labelVars( finder.core.vars ) {}
165
166	typedef ObjDeclCollector Parent;
167	using Parent::previsit;
168
169	void previsit( const ast::FunctionDecl * funcDecl );
170
171	void previsit( const ast::BranchStmt * stmt );
172	private:
173	void handleGoto( const ast::BranchStmt * stmt );
174
175	ast::Pass<LabelFinder> & finder;
176	LabelFinder::LabelMap & labelVars;
177	OrderedDeclsStack reverseDeclOrder;
178	};
179
180	/// expand each object declaration to use its constructor after it is declared.
181	struct FixInit : public ast::WithStmtsToAdd<> {
182	static void fixInitializers( ast::TranslationUnit &translationUnit );
183
184	const ast::DeclWithType * postvisit( const ast::ObjectDecl *objDecl );
185
186	std::list< ast::ptr< ast::Decl > > staticDtorDecls;
187	};
188
189	/// generate default/copy ctor and dtor calls for user-defined struct ctor/dtors
190	/// for any member that is missing a corresponding ctor/dtor call.
191	/// error if a member is used before constructed
192	struct GenStructMemberCalls final : public ast::WithGuards, public ast::WithShortCircuiting, public ast::WithSymbolTable, public ast::WithVisitorRef<GenStructMemberCalls>, public ast::WithConstTranslationUnit {
193	void previsit( const ast::FunctionDecl * funcDecl );
194	const ast::DeclWithType * postvisit( const ast::FunctionDecl * funcDecl );
195
196	void previsit( const ast::MemberExpr * memberExpr );
197	void previsit( const ast::ApplicationExpr * appExpr );
198
199	/// Note: this post mutate used to be in a separate visitor. If this pass breaks, one place to examine is whether it is
200	/// okay for this part of the recursion to occur alongside the rest.
201	const ast::Expr * postvisit( const ast::UntypedExpr * expr );
202
203	SemanticErrorException errors;
204	private:
205	template< typename... Params >
206	void emit( CodeLocation, const Params &... params );
207
208	ast::FunctionDecl * function = nullptr;
209	std::set< const ast::DeclWithType * > unhandled;
210	std::map< const ast::DeclWithType *, CodeLocation > usedUninit;
211	const ast::ObjectDecl * thisParam = nullptr;
212	bool isCtor = false; // true if current function is a constructor
213	const ast::StructDecl * structDecl = nullptr;
214	};
215
216	/// expands ConstructorExpr nodes into comma expressions, using a temporary for the first argument
217	struct FixCtorExprs final : public ast::WithDeclsToAdd<>, public ast::WithSymbolTable, public ast::WithShortCircuiting, public ast::WithConstTranslationUnit {
218	const ast::Expr * postvisit( const ast::ConstructorExpr * ctorExpr );
219	};
220
221	/// add CompoundStmts around top-level expressions so that temporaries are destroyed in the correct places.
222	struct SplitExpressions : public ast::WithShortCircuiting {
223	ast::Stmt * postvisit( const ast::ExprStmt * stmt );
224	void previsit( const ast::TupleAssignExpr * expr );
225	};
226	} // namespace
227
228	void fix( ast::TranslationUnit & translationUnit, bool inLibrary ) {
229	ast::Pass<SelfAssignChecker>::run( translationUnit );
230
231	// fixes StmtExpr to properly link to their resulting expression
232	ast::Pass<StmtExprResult>::run( translationUnit );
233
234	// fixes ConstructorInit for global variables. should happen before fixInitializers.
235	InitTweak::fixGlobalInit( translationUnit, inLibrary );
236
237	// must happen before ResolveCopyCtors because temporaries have to be inserted into the correct scope
238	ast::Pass<SplitExpressions>::run( translationUnit );
239
240	ast::Pass<InsertImplicitCalls>::run( translationUnit );
241
242	// Needs to happen before ResolveCopyCtors, because argument/return temporaries should not be considered in
243	// error checking branch statements
244	{
245	ast::Pass<LabelFinder> finder;
246	ast::Pass<InsertDtors>::run( translationUnit, finder );
247	}
248
249	ast::Pass<ResolveCopyCtors>::run( translationUnit );
250	FixInit::fixInitializers( translationUnit );
251	ast::Pass<GenStructMemberCalls>::run( translationUnit );
252
253	// Needs to happen after GenStructMemberCalls, since otherwise member constructors exprs
254	// don't have the correct form, and a member can be constructed more than once.
255	ast::Pass<FixCtorExprs>::run( translationUnit );
256	}
257
258	namespace {
259	/// find and return the destructor used in `input`. If `input` is not a simple destructor call, generate a thunk
260	/// that wraps the destructor, insert it into `stmtsToAdd` and return the new function declaration
261	const ast::DeclWithType * getDtorFunc( const ast::ObjectDecl * objDecl, const ast::Stmt * input, std::list< ast::ptr<ast::Stmt> > & stmtsToAdd ) {
262	const CodeLocation loc = input->location;
263	// unwrap implicit statement wrapper
264	// Statement * dtor = input;
265	assert( input );
266	// std::list< const ast::Expr * > matches;
267	auto matches = collectCtorDtorCalls( input );
268
269	if ( dynamic_cast< const ast::ExprStmt * >( input ) ) {
270	// only one destructor call in the expression
271	if ( matches.size() == 1 ) {
272	auto func = getFunction( matches.front() );
273	assertf( func, "getFunction failed to find function in %s", toString( matches.front() ).c_str() );
274
275	// cleanup argument must be a function, not an object (including function pointer)
276	if ( auto dtorFunc = dynamic_cast< const ast::FunctionDecl * > ( func ) ) {
277	if ( dtorFunc->type->forall.empty() ) {
278	// simple case where the destructor is a monomorphic function call - can simply
279	// use that function as the cleanup function.
280	return func;
281	}
282	}
283	}
284	}
285
286	// otherwise the cleanup is more complicated - need to build a single argument cleanup function that
287	// wraps the more complicated code.
288	static UniqueName dtorNamer( "__cleanup_dtor" );
289	std::string name = dtorNamer.newName();
290	ast::FunctionDecl * dtorFunc = SymTab::genDefaultFunc( loc, name, objDecl->type->stripReferences(), false );
291	stmtsToAdd.push_back( new ast::DeclStmt(loc, dtorFunc ) );
292
293	// the original code contains uses of objDecl - replace them with the newly generated 'this' parameter.
294	const ast::ObjectDecl * thisParam = getParamThis( dtorFunc );
295	const ast::Expr * replacement = new ast::VariableExpr( loc, thisParam );
296
297	auto base = replacement->result->stripReferences();
298	if ( dynamic_cast< const ast::ArrayType * >( base ) \|\| dynamic_cast< const ast::TupleType * > ( base ) ) {
299	// need to cast away reference for array types, since the destructor is generated without the reference type,
300	// and for tuple types since tuple indexing does not work directly on a reference
301	replacement = new ast::CastExpr( replacement, base );
302	}
303	auto dtor = ast::DeclReplacer::replace( input, ast::DeclReplacer::ExprMap{ std::make_pair( objDecl, replacement ) } );
304	auto mutStmts = dtorFunc->stmts.get_and_mutate();
305	mutStmts->push_back(strict_dynamic_cast<const ast::Stmt *>( dtor ));
306	dtorFunc->stmts = mutStmts;
307
308	return dtorFunc;
309	}
310
311	void FixInit::fixInitializers( ast::TranslationUnit & translationUnit ) {
312	ast::Pass<FixInit> fixer;
313
314	// can't use mutateAll, because need to insert declarations at top-level
315	// can't use DeclMutator, because sometimes need to insert IfStmt, etc.
316	SemanticErrorException errors;
317	for ( auto i = translationUnit.decls.begin(); i != translationUnit.decls.end(); ++i ) {
318	try {
319	// maybeAccept( *i, fixer ); translationUnit should never contain null
320	i = (i)->accept(fixer);
321	translationUnit.decls.splice( i, fixer.core.staticDtorDecls );
322	} catch( SemanticErrorException &e ) {
323	errors.append( e );
324	} // try
325	} // for
326	if ( ! errors.isEmpty() ) {
327	throw errors;
328	} // if
329	}
330
331	const ast::StmtExpr * StmtExprResult::previsit( const ast::StmtExpr * stmtExpr ) {
332	// we might loose the result expression here so add a pointer to trace back
333	assert( stmtExpr->result );
334	const ast::Type * result = stmtExpr->result;
335	if ( ! result->isVoid() ) {
336	auto mutExpr = mutate(stmtExpr);
337	const ast::CompoundStmt * body = mutExpr->stmts;
338	assert( ! body->kids.empty() );
339	mutExpr->resultExpr = body->kids.back().strict_as<ast::ExprStmt>();
340	return mutExpr;
341	}
342	return stmtExpr;
343	}
344
345	ast::Stmt * SplitExpressions::postvisit( const ast::ExprStmt * stmt ) {
346	// wrap each top-level ExprStmt in a block so that destructors for argument and return temporaries are destroyed
347	// in the correct places
348	ast::CompoundStmt * ret = new ast::CompoundStmt( stmt->location, { stmt } );
349	return ret;
350	}
351
352	void SplitExpressions::previsit( const ast::TupleAssignExpr * ) {
353	// don't do this within TupleAssignExpr, since it is already broken up into multiple expressions
354	visit_children = false;
355	}
356
357	// Relatively simple structural comparison for expressions, needed to determine
358	// if two expressions are "the same" (used to determine if self assignment occurs)
359	struct StructuralChecker {
360	// Strip all casts and then dynamic_cast.
361	template<typename T>
362	static const T * cast( const ast::Expr * expr ) {
363	// this might be too permissive. It's possible that only particular casts are relevant.
364	while ( auto cast = dynamic_cast< const ast::CastExpr * >( expr ) ) {
365	expr = cast->arg;
366	}
367	return dynamic_cast< const T * >( expr );
368	}
369
370	void previsit( const ast::Expr * ) {
371	// anything else does not qualify
372	result = false;
373	}
374
375	// ignore casts
376	void previsit( const ast::CastExpr * ) {}
377
378	void previsit( const ast::MemberExpr * memExpr ) {
379	if ( auto otherMember = cast< ast::MemberExpr >( other ) ) {
380	if ( otherMember->member == memExpr->member ) {
381	other = otherMember->aggregate;
382	return;
383	}
384	}
385	result = false;
386	}
387
388	void previsit( const ast::VariableExpr * varExpr ) {
389	if ( auto otherVar = cast< ast::VariableExpr >( other ) ) {
390	if ( otherVar->var == varExpr->var ) {
391	return;
392	}
393	}
394	result = false;
395	}
396
397	void previsit( const ast::AddressExpr * ) {
398	if ( auto addrExpr = cast< ast::AddressExpr >( other ) ) {
399	other = addrExpr->arg;
400	return;
401	}
402	result = false;
403	}
404
405	const ast::Expr * other;
406	bool result = true;
407	StructuralChecker( const ast::Expr * other ) : other(other) {}
408	};
409
410	bool structurallySimilar( const ast::Expr * e1, const ast::Expr * e2 ) {
411	return ast::Pass<StructuralChecker>::read( e1, e2 );
412	}
413
414	void SelfAssignChecker::previsit( const ast::ApplicationExpr * appExpr ) {
415	auto function = getFunction( appExpr );
416	// Doesn't use isAssignment, because ?+=?, etc. should not count as self-assignment.
417	if ( function->name == "?=?" && appExpr->args.size() == 2
418	// Check for structural similarity (same variable use, ignore casts, etc.
419	// (but does not look too deeply, anything looking like a function is off limits).
420	&& structurallySimilar( appExpr->args.front(), appExpr->args.back() ) ) {
421	SemanticWarning( appExpr->location, Warning::SelfAssignment, toCString( appExpr->args.front() ) );
422	}
423	}
424
425	const ast::Expr * InsertImplicitCalls::postvisit( const ast::ApplicationExpr * appExpr ) {
426	if ( auto function = appExpr->func.as<ast::VariableExpr>() ) {
427	if ( function->var->linkage.is_builtin ) {
428	// optimization: don't need to copy construct in order to call intrinsic functions
429	return appExpr;
430	} else if ( auto funcDecl = function->var.as<ast::DeclWithType>() ) {
431	auto ftype = dynamic_cast< const ast::FunctionType * >( GenPoly::getFunctionType( funcDecl->get_type() ) );
432	assertf( ftype, "Function call without function type: %s", toString( funcDecl ).c_str() );
433	if ( CodeGen::isConstructor( funcDecl->name ) && ftype->params.size() == 2 ) {
434	auto t1 = getPointerBase( ftype->params.front() );
435	auto t2 = ftype->params.back();
436	assert( t1 );
437
438	if ( ResolvExpr::typesCompatible( t1, t2 ) ) {
439	// optimization: don't need to copy construct in order to call a copy constructor
440	return appExpr;
441	} // if
442	} else if ( CodeGen::isDestructor( funcDecl->name ) ) {
443	// correctness: never copy construct arguments to a destructor
444	return appExpr;
445	} // if
446	} // if
447	} // if
448	CP_CTOR_PRINT( std::cerr << "InsertImplicitCalls: adding a wrapper " << appExpr << std::endl; )
449
450	// wrap each function call so that it is easy to identify nodes that have to be copy constructed
451	ast::ptr<ast::TypeSubstitution> tmp = appExpr->env;
452	auto mutExpr = mutate(appExpr);
453	mutExpr->env = nullptr;
454
455	auto expr = new ast::ImplicitCopyCtorExpr( appExpr->location, mutExpr );
456	// Move the type substitution to the new top-level. The substitution
457	// is needed to obtain the type of temporary variables so that copy
458	// constructor calls can be resolved.
459	assert( typeSubs );
460	expr->env = tmp;
461	return expr;
462	}
463
464	void ResolveCopyCtors::previsit(const ast::Expr * expr) {
465	if ( nullptr == expr->env ) {
466	return;
467	}
468	GuardValue( env ) = expr->env->clone();
469	GuardValue( envModified ) = false;
470	}
471
472	const ast::Expr * ResolveCopyCtors::postvisit(const ast::Expr * expr) {
473	// No local environment, skip.
474	if ( nullptr == expr->env ) {
475	return expr;
476	// Environment was modified, mutate and replace.
477	} else if ( envModified ) {
478	auto mutExpr = mutate(expr);
479	mutExpr->env = env;
480	return mutExpr;
481	// Environment was not mutated, delete the shallow copy before guard.
482	} else {
483	delete env;
484	return expr;
485	}
486	}
487
488	bool ResolveCopyCtors::skipCopyConstruct( const ast::Type * type ) { return ! isConstructable( type ); }
489
490	const ast::Expr * ResolveCopyCtors::makeCtorDtor( const std::string & fname, const ast::ObjectDecl * var, const ast::Expr * cpArg ) {
491	assert( var );
492	assert( var->isManaged() );
493	assert( !cpArg \|\| cpArg->isManaged() );
494	// arrays are not copy constructed, so this should always be an ExprStmt
495	ast::ptr< ast::Stmt > stmt = genCtorDtor(var->location, fname, var, cpArg );
496	assertf( stmt, "ResolveCopyCtors: genCtorDtor returned nullptr: %s / %s / %s", fname.c_str(), toString( var ).c_str(), toString( cpArg ).c_str() );
497	auto exprStmt = stmt.strict_as<ast::ImplicitCtorDtorStmt>()->callStmt.strict_as<ast::ExprStmt>();
498	ast::ptr<ast::Expr> untyped = exprStmt->expr; // take ownership of expr
499
500	// resolve copy constructor
501	// should only be one alternative for copy ctor and dtor expressions, since all arguments are fixed
502	// (VariableExpr and already resolved expression)
503	CP_CTOR_PRINT( std::cerr << "ResolvingCtorDtor " << untyped << std::endl; )
504	ast::ptr<ast::Expr> resolved = ResolvExpr::findVoidExpression(untyped, { symtab, transUnit().global } );
505	assert( resolved );
506	if ( resolved->env ) {
507	// Extract useful information and discard new environments. Keeping them causes problems in PolyMutator passes.
508	env->add( *resolved->env );
509	envModified = true;
510	auto mut = mutate(resolved.get());
511	assertf(mut == resolved.get(), "newly resolved expression must be unique");
512	mut->env = nullptr;
513	} // if
514	if ( auto assign = resolved.as<ast::TupleAssignExpr>() ) {
515	// fix newly generated StmtExpr
516	previsit( assign->stmtExpr );
517	}
518	return resolved.release();
519	}
520
521	ast::ptr<ast::Expr> ResolveCopyCtors::copyConstructArg(
522	const ast::Expr * arg, const ast::ImplicitCopyCtorExpr * impCpCtorExpr, const ast::Type * formal )
523	{
524	static UniqueName tempNamer("_tmp_cp");
525	assert( env );
526	const CodeLocation loc = impCpCtorExpr->location;
527	// CP_CTOR_PRINT( std::cerr << "Type Substitution: " << *env << std::endl; )
528	assert( arg->result );
529	ast::ptr<ast::Type> result = arg->result;
530	if ( skipCopyConstruct( result ) ) return arg; // skip certain non-copyable types
531
532	// type may involve type variables, so apply type substitution to get temporary variable's actual type,
533	// since result type may not be substituted (e.g., if the type does not appear in the parameter list)
534	// Use applyFree so that types bound in function pointers are not substituted, e.g. in forall(dtype T) void (*)(T).
535
536	// xxx - this originally mutates arg->result in place. is it correct?
537	result = env->applyFree( result.get() ).node;
538	auto mutResult = result.get_and_mutate();
539	mutResult->set_const(false);
540
541	auto mutArg = mutate(arg);
542	mutArg->result = mutResult;
543
544	ast::ptr<ast::Expr> guard = mutArg;
545
546	ast::ptr<ast::ObjectDecl> tmp = new ast::ObjectDecl(loc, "__tmp", mutResult, nullptr );
547
548	// create and resolve copy constructor
549	CP_CTOR_PRINT( std::cerr << "makeCtorDtor for an argument" << std::endl; )
550	auto cpCtor = makeCtorDtor( "?{}", tmp, mutArg );
551
552	if ( auto appExpr = dynamic_cast< const ast::ApplicationExpr * >( cpCtor ) ) {
553	// if the chosen constructor is intrinsic, the copy is unnecessary, so
554	// don't create the temporary and don't call the copy constructor
555	auto function = appExpr->func.strict_as<ast::VariableExpr>();
556	if ( function->var->linkage == ast::Linkage::Intrinsic ) {
557	// arguments that need to be boxed need a temporary regardless of whether the copy constructor is intrinsic,
558	// so that the object isn't changed inside of the polymorphic function
559	if ( ! GenPoly::needsBoxing( formal, result, impCpCtorExpr->callExpr, env ) ) {
560	// xxx - should arg->result be mutated? see comment above.
561	return guard;
562	}
563	}
564	}
565
566	// set a unique name for the temporary once it's certain the call is necessary
567	auto mut = tmp.get_and_mutate();
568	assertf (mut == tmp, "newly created ObjectDecl must be unique");
569	mut->name = tempNamer.newName();
570
571	// replace argument to function call with temporary
572	stmtsToAddBefore.push_back( new ast::DeclStmt(loc, tmp ) );
573	arg = cpCtor;
574	return destructRet( tmp, arg );
575
576	// impCpCtorExpr->dtors.push_front( makeCtorDtor( "^?{}", tmp ) );
577	}
578
579	ast::Expr * ResolveCopyCtors::destructRet( const ast::ObjectDecl * ret, const ast::Expr * arg ) {
580	auto global = transUnit().global;
581	// TODO: refactor code for generating cleanup attribute, since it's common and reused in ~3-4 places
582	// check for existing cleanup attribute before adding another(?)
583	// need to add __Destructor for _tmp_cp variables as well
584
585	assertf( global.dtorStruct, "Destructor generation requires __Destructor definition." );
586	assertf( global.dtorStruct->members.size() == 2, "__Destructor definition does not have expected fields." );
587	assertf( global.dtorDestroy, "Destructor generation requires __destroy_Destructor." );
588
589	const CodeLocation loc = ret->location;
590
591	// generate a __Destructor for ret that calls the destructor
592	auto res = makeCtorDtor( "^?{}", ret );
593	auto dtor = mutate(res);
594
595	// if the chosen destructor is intrinsic, elide the generated dtor handler
596	if ( arg && isIntrinsicCallExpr( dtor ) ) {
597	return new ast::CommaExpr(loc, arg, new ast::VariableExpr(loc, ret ) );
598	// return;
599	}
600
601	if ( ! dtor->env ) dtor->env = maybeClone( env );
602	auto dtorFunc = getDtorFunc( ret, new ast::ExprStmt(loc, dtor ), stmtsToAddBefore );
603
604	auto dtorStructType = new ast::StructInstType( global.dtorStruct );
605
606	// what does this do???
607	dtorStructType->params.push_back( new ast::TypeExpr(loc, new ast::VoidType() ) );
608
609	// cast destructor pointer to void ()(void ), to silence GCC incompatible pointer warnings
610	auto dtorFtype = new ast::FunctionType();
611	dtorFtype->params.push_back( new ast::PointerType(new ast::VoidType( ) ) );
612	auto dtorType = new ast::PointerType( dtorFtype );
613
614	static UniqueName namer( "_ret_dtor" );
615	auto retDtor = new ast::ObjectDecl(loc, namer.newName(), dtorStructType, new ast::ListInit(loc, { new ast::SingleInit(loc, ast::ConstantExpr::null(loc) ), new ast::SingleInit(loc, new ast::CastExpr( new ast::VariableExpr(loc, dtorFunc ), dtorType ) ) } ) );
616	retDtor->attributes.push_back( new ast::Attribute( "cleanup", { new ast::VariableExpr(loc, global.dtorDestroy ) } ) );
617	stmtsToAddBefore.push_back( new ast::DeclStmt(loc, retDtor ) );
618
619	if ( arg ) {
620	auto member = new ast::MemberExpr(loc, global.dtorStruct->members.front().strict_as<ast::DeclWithType>(), new ast::VariableExpr(loc, retDtor ) );
621	auto object = new ast::CastExpr( new ast::AddressExpr( new ast::VariableExpr(loc, ret ) ), new ast::PointerType(new ast::VoidType() ) );
622	ast::Expr * assign = createBitwiseAssignment( member, object );
623	return new ast::CommaExpr(loc, new ast::CommaExpr(loc, arg, assign ), new ast::VariableExpr(loc, ret ) );
624	}
625	return nullptr;
626	// impCpCtorExpr->get_dtors().push_front( makeCtorDtor( "^?{}", ret ) );
627	}
628
629	const ast::Expr * ResolveCopyCtors::postvisit( const ast::ImplicitCopyCtorExpr *impCpCtorExpr ) {
630	CP_CTOR_PRINT( std::cerr << "ResolveCopyCtors: " << impCpCtorExpr << std::endl; )
631
632	ast::ApplicationExpr * appExpr = mutate(impCpCtorExpr->callExpr.get());
633	const ast::ObjectDecl * returnDecl = nullptr;
634	const CodeLocation loc = appExpr->location;
635
636	// take each argument and attempt to copy construct it.
637	auto ftype = GenPoly::getFunctionType( appExpr->func->result );
638	assert( ftype );
639	auto & params = ftype->params;
640	auto iter = params.begin();
641	for ( auto & arg : appExpr->args ) {
642	const ast::Type * formal = nullptr;
643	if ( iter != params.end() ) { // does not copy construct C-style variadic arguments
644	// DeclarationWithType * param = *iter++;
645	formal = *iter++;
646	}
647
648	arg = copyConstructArg( arg, impCpCtorExpr, formal );
649	} // for
650
651	// each return value from the call needs to be connected with an ObjectDecl at the call site, which is
652	// initialized with the return value and is destructed later
653	// xxx - handle named return values?
654	const ast::Type * result = appExpr->result;
655	if ( ! result->isVoid() ) {
656	static UniqueName retNamer("_tmp_cp_ret");
657	// result = result->clone();
658	auto subResult = env->apply( result ).node;
659	auto ret = new ast::ObjectDecl(loc, retNamer.newName(), subResult, nullptr );
660	auto mutType = mutate(ret->type.get());
661	mutType->set_const( false );
662	ret->type = mutType;
663	returnDecl = ret;
664	stmtsToAddBefore.push_back( new ast::DeclStmt(loc, ret ) );
665	CP_CTOR_PRINT( std::cerr << "makeCtorDtor for a return" << std::endl; )
666	} // for
667	CP_CTOR_PRINT( std::cerr << "after Resolving: " << impCpCtorExpr << std::endl; )
668	// ------------------------------------------------------
669
670	CP_CTOR_PRINT( std::cerr << "Coming out the back..." << impCpCtorExpr << std::endl; )
671
672	// detach fields from wrapper node so that it can be deleted without deleting too much
673
674	// xxx - actual env might be somewhere else, need to keep invariant
675
676	// deletion of wrapper should be handled by pass template now
677
678	// impCpCtorExpr->callExpr = nullptr;
679	assert (appExpr->env == nullptr);
680	appExpr->env = impCpCtorExpr->env;
681	// std::swap( impCpCtorExpr->env, appExpr->env );
682	// assert( impCpCtorExpr->env == nullptr );
683	// delete impCpCtorExpr;
684
685	if ( returnDecl ) {
686	ast::Expr * assign = createBitwiseAssignment( new ast::VariableExpr(loc, returnDecl ), appExpr );
687	if ( ! dynamic_cast< const ast::ReferenceType * >( result ) ) {
688	// destructing reference returns is bad because it can cause multiple destructor calls to the same object - the returned object is not a temporary
689	assign = destructRet( returnDecl, assign );
690	assert(assign);
691	} else {
692	assign = new ast::CommaExpr(loc, assign, new ast::VariableExpr(loc, returnDecl ) );
693	}
694	// move env from appExpr to retExpr
695	// std::swap( assign->env, appExpr->env );
696	assign->env = appExpr->env;
697	// actual env is handled by common routine that replaces WithTypeSubstitution
698	return postvisit((const ast::Expr *)assign);
699	} else {
700	return postvisit((const ast::Expr *)appExpr);
701	} // if
702	}
703
704	const ast::StmtExpr * ResolveCopyCtors::previsit( const ast::StmtExpr * _stmtExpr ) {
705	// function call temporaries should be placed at statement-level, rather than nested inside of a new statement expression,
706	// since temporaries can be shared across sub-expressions, e.g.
707	// [A, A] f(); // decl
708	// g([A] x, [A] y); // decl
709	// g(f()); // call
710	// f is executed once, so the return temporary is shared across the tuple constructors for x and y.
711	// Explicitly mutating children instead of mutating the inner compound statement forces the temporaries to be added
712	// to the outer context, rather than inside of the statement expression.
713
714	// call the common routine that replaces WithTypeSubstitution
715	previsit((const ast::Expr *) _stmtExpr);
716
717	visit_children = false;
718	const CodeLocation loc = _stmtExpr->location;
719
720	assert( env );
721
722	symtab.enterScope();
723	// visit all statements
724	auto stmtExpr = mutate(_stmtExpr);
725	auto mutStmts = mutate(stmtExpr->stmts.get());
726
727	auto & stmts = mutStmts->kids;
728	for ( auto & stmt : stmts ) {
729	stmt = stmt->accept( *visitor );
730	} // for
731	stmtExpr->stmts = mutStmts;
732	symtab.leaveScope();
733
734	assert( stmtExpr->result );
735	// const ast::Type * result = stmtExpr->result;
736	if ( ! stmtExpr->result->isVoid() ) {
737	static UniqueName retNamer("_tmp_stmtexpr_ret");
738
739	// result = result->clone();
740	auto result = env->apply( stmtExpr->result.get() ).node;
741	if ( ! InitTweak::isConstructable( result ) ) {
742	// delete result;
743	return stmtExpr;
744	}
745	auto mutResult = result.get_and_mutate();
746	mutResult->set_const(false);
747
748	// create variable that will hold the result of the stmt expr
749	auto ret = new ast::ObjectDecl(loc, retNamer.newName(), mutResult, nullptr );
750	stmtsToAddBefore.push_back( new ast::DeclStmt(loc, ret ) );
751
752	assertf(
753	stmtExpr->resultExpr,
754	"Statement-Expression should have a resulting expression at %s:%d",
755	stmtExpr->location.filename.c_str(),
756	stmtExpr->location.first_line
757	);
758
759	const ast::ExprStmt * last = stmtExpr->resultExpr;
760	// xxx - if this is non-unique, need to copy while making resultExpr ref
761	assertf(last->unique(), "attempt to modify weakly shared statement");
762	auto mutLast = mutate(last);
763	// above assertion means in-place mutation is OK
764	try {
765	mutLast->expr = makeCtorDtor( "?{}", ret, mutLast->expr );
766	} catch(...) {
767	std::cerr << "*CFA internal error: ";
768	std::cerr << "can't resolve implicit constructor";
769	std::cerr << " at " << stmtExpr->location.filename;
770	std::cerr << ":" << stmtExpr->location.first_line << std::endl;
771
772	abort();
773	}
774
775	// add destructors after current statement
776	stmtsToAddAfter.push_back( new ast::ExprStmt(loc, makeCtorDtor( "^?{}", ret ) ) );
777
778	// must have a non-empty body, otherwise it wouldn't have a result
779	assert( ! stmts.empty() );
780
781	// if there is a return decl, add a use as the last statement; will not have return decl on non-constructable returns
782	stmts.push_back( new ast::ExprStmt(loc, new ast::VariableExpr(loc, ret ) ) );
783	} // if
784
785	assert( stmtExpr->returnDecls.empty() );
786	assert( stmtExpr->dtors.empty() );
787
788	return stmtExpr;
789	}
790
791	// to prevent warnings ('_unq0' may be used uninitialized in this function),
792	// insert an appropriate zero initializer for UniqueExpr temporaries.
793	ast::Init * makeInit( const ast::Type * t, CodeLocation const & loc ) {
794	if ( auto inst = dynamic_cast< const ast::StructInstType * >( t ) ) {
795	// initizer for empty struct must be empty
796	if ( inst->base->members.empty() ) {
797	return new ast::ListInit( loc, {} );
798	}
799	} else if ( auto inst = dynamic_cast< const ast::UnionInstType * >( t ) ) {
800	// initizer for empty union must be empty
801	if ( inst->base->members.empty() ) {
802	return new ast::ListInit( loc, {} );
803	}
804	}
805
806	return new ast::ListInit( loc, {
807	new ast::SingleInit( loc, ast::ConstantExpr::from_int( loc, 0 ) )
808	} );
809	}
810
811	const ast::UniqueExpr * ResolveCopyCtors::previsit( const ast::UniqueExpr * unqExpr ) {
812	visit_children = false;
813	// xxx - hack to prevent double-handling of unique exprs, otherwise too many temporary variables and destructors are generated
814	static std::unordered_map< int, const ast::UniqueExpr * > unqMap;
815	auto mutExpr = mutate(unqExpr);
816	if ( ! unqMap.count( unqExpr->id ) ) {
817	// resolve expr and find its
818
819	auto impCpCtorExpr = mutExpr->expr.as<ast::ImplicitCopyCtorExpr>();
820	// PassVisitor<ResolveCopyCtors> fixer;
821
822	mutExpr->expr = mutExpr->expr->accept( *visitor );
823	// it should never be necessary to wrap a void-returning expression in a UniqueExpr - if this assumption changes, this needs to be rethought
824	assert( unqExpr->result );
825	if ( impCpCtorExpr ) {
826	auto comma = unqExpr->expr.strict_as<ast::CommaExpr>();
827	auto var = comma->arg2.strict_as<ast::VariableExpr>();
828	// note the variable used as the result from the call
829	mutExpr->var = var;
830	} else {
831	// expr isn't a call expr, so create a new temporary variable to use to hold the value of the unique expression
832	mutExpr->object = new ast::ObjectDecl( mutExpr->location, toString("_unq", mutExpr->id), mutExpr->result, makeInit( mutExpr->result, mutExpr->location ) );
833	mutExpr->var = new ast::VariableExpr( mutExpr->location, mutExpr->object );
834	}
835
836	// stmtsToAddBefore.splice( stmtsToAddBefore.end(), fixer.pass.stmtsToAddBefore );
837	// stmtsToAddAfter.splice( stmtsToAddAfter.end(), fixer.pass.stmtsToAddAfter );
838	unqMap[mutExpr->id] = mutExpr;
839	} else {
840	// take data from other UniqueExpr to ensure consistency
841	// delete unqExpr->get_expr();
842	mutExpr->expr = unqMap[mutExpr->id]->expr;
843	// delete unqExpr->result;
844	mutExpr->result = mutExpr->expr->result;
845	}
846	return mutExpr;
847	}
848
849	const ast::DeclWithType * FixInit::postvisit( const ast::ObjectDecl *_objDecl ) {
850	const CodeLocation loc = _objDecl->location;
851
852	// since this removes the init field from objDecl, it must occur after children are mutated (i.e. postvisit)
853	if ( ast::ptr<ast::ConstructorInit> ctorInit = _objDecl->init.as<ast::ConstructorInit>() ) {
854	auto objDecl = mutate(_objDecl);
855
856	// could this be non-unique?
857	if (objDecl != _objDecl) {
858	std::cerr << "FixInit: non-unique object decl " << objDecl->location << objDecl->name << std::endl;
859	}
860	// a decision should have been made by the resolver, so ctor and init are not both non-NULL
861	assert( ! ctorInit->ctor \|\| ! ctorInit->init );
862	if ( const ast::Stmt * ctor = ctorInit->ctor ) {
863	if ( objDecl->storage.is_static ) {
864	addDataSectionAttribute(objDecl);
865	// originally wanted to take advantage of gcc nested functions, but
866	// we get memory errors with this approach. To remedy this, the static
867	// variable is hoisted when the destructor needs to be called.
868	//
869	// generate:
870	// static T __objName_static_varN;
871	// void __objName_dtor_atexitN() {
872	// __dtor__...;
873	// }
874	// int f(...) {
875	// ...
876	// static bool __objName_uninitialized = true;
877	// if (__objName_uninitialized) {
878	// __ctor(__objName);
879	// __objName_uninitialized = false;
880	// atexit(__objName_dtor_atexitN);
881	// }
882	// ...
883	// }
884
885	static UniqueName dtorCallerNamer( "_dtor_atexit" );
886
887	// static bool __objName_uninitialized = true
888	auto boolType = new ast::BasicType( ast::BasicType::Kind::Bool );
889	auto boolInitExpr = new ast::SingleInit(loc, ast::ConstantExpr::from_int(loc, 1 ) );
890	auto isUninitializedVar = new ast::ObjectDecl(loc, objDecl->mangleName + "_uninitialized", boolType, boolInitExpr, ast::Storage::Static, ast::Linkage::Cforall);
891	isUninitializedVar->fixUniqueId();
892
893	// __objName_uninitialized = false;
894	auto setTrue = new ast::UntypedExpr(loc, new ast::NameExpr(loc, "?=?" ) );
895	setTrue->args.push_back( new ast::VariableExpr(loc, isUninitializedVar ) );
896	setTrue->args.push_back( ast::ConstantExpr::from_int(loc, 0 ) );
897
898	// generate body of if
899	auto initStmts = new ast::CompoundStmt(loc);
900	auto & body = initStmts->kids;
901	body.push_back( ctor );
902	body.push_back( new ast::ExprStmt(loc, setTrue ) );
903
904	// put it all together
905	auto ifStmt = new ast::IfStmt(loc, new ast::VariableExpr(loc, isUninitializedVar ), initStmts, 0 );
906	stmtsToAddAfter.push_back( new ast::DeclStmt(loc, isUninitializedVar ) );
907	stmtsToAddAfter.push_back( ifStmt );
908
909	const ast::Stmt * dtor = ctorInit->dtor;
910
911	// these should be automatically managed once reassigned
912	// objDecl->set_init( nullptr );
913	// ctorInit->set_ctor( nullptr );
914	// ctorInit->set_dtor( nullptr );
915	if ( dtor ) {
916	// if the object has a non-trivial destructor, have to
917	// hoist it and the object into the global space and
918	// call the destructor function with atexit.
919
920	// Statement * dtorStmt = dtor->clone();
921
922	// void __objName_dtor_atexitN(...) {...}
923	ast::FunctionDecl * dtorCaller = new ast::FunctionDecl(loc, objDecl->mangleName + dtorCallerNamer.newName(), {}, {}, {}, new ast::CompoundStmt(loc, {dtor}), ast::Storage::Static, ast::Linkage::C );
924	dtorCaller->fixUniqueId();
925	// dtorCaller->stmts->push_back( dtor );
926
927	// atexit(dtor_atexit);
928	auto callAtexit = new ast::UntypedExpr(loc, new ast::NameExpr(loc, "atexit" ) );
929	callAtexit->args.push_back( new ast::VariableExpr(loc, dtorCaller ) );
930
931	body.push_back( new ast::ExprStmt(loc, callAtexit ) );
932
933	// hoist variable and dtor caller decls to list of decls that will be added into global scope
934	staticDtorDecls.push_back( objDecl );
935	staticDtorDecls.push_back( dtorCaller );
936
937	// need to rename object uniquely since it now appears
938	// at global scope and there could be multiple function-scoped
939	// static variables with the same name in different functions.
940	// Note: it isn't sufficient to modify only the mangleName, because
941	// then subsequent Indexer passes can choke on seeing the object's name
942	// if another object has the same name and type. An unfortunate side-effect
943	// of renaming the object is that subsequent NameExprs may fail to resolve,
944	// but there shouldn't be any remaining past this point.
945	static UniqueName staticNamer( "_static_var" );
946	objDecl->name = objDecl->name + staticNamer.newName();
947	objDecl->mangleName = Mangle::mangle( objDecl );
948	objDecl->init = nullptr;
949
950	// xxx - temporary hack: need to return a declaration, but want to hoist the current object out of this scope
951	// create a new object which is never used
952	static UniqueName dummyNamer( "_dummy" );
953	auto dummy = new ast::ObjectDecl(loc, dummyNamer.newName(), new ast::PointerType(new ast::VoidType()), nullptr, ast::Storage::Static, ast::Linkage::Cforall, 0, { new ast::Attribute("unused") } );
954	// delete ctorInit;
955	return dummy;
956	} else {
957	objDecl->init = nullptr;
958	return objDecl;
959	}
960	} else {
961	auto implicit = strict_dynamic_cast< const ast::ImplicitCtorDtorStmt * > ( ctor );
962	auto ctorStmt = implicit->callStmt.as<ast::ExprStmt>();
963	const ast::ApplicationExpr * ctorCall = nullptr;
964	if ( ctorStmt && (ctorCall = isIntrinsicCallExpr( ctorStmt->expr )) && ctorCall->args.size() == 2 ) {
965	// clean up intrinsic copy constructor calls by making them into SingleInits
966	const ast::Expr * ctorArg = ctorCall->args.back();
967	// ctorCall should be gone afterwards
968	auto mutArg = mutate(ctorArg);
969	mutArg->env = ctorCall->env;
970	// std::swap( ctorArg->env, ctorCall->env );
971	objDecl->init = new ast::SingleInit(loc, mutArg );
972
973	// ctorCall->args.pop_back();
974	} else {
975	stmtsToAddAfter.push_back( ctor );
976	objDecl->init = nullptr;
977	// ctorInit->ctor = nullptr;
978	}
979
980	const ast::Stmt * dtor = ctorInit->dtor;
981	if ( dtor ) {
982	auto implicit = strict_dynamic_cast< const ast::ImplicitCtorDtorStmt * >( dtor );
983	const ast::Stmt * dtorStmt = implicit->callStmt;
984
985	// don't need to call intrinsic dtor, because it does nothing, but
986	// non-intrinsic dtors must be called
987	if ( ! isIntrinsicSingleArgCallStmt( dtorStmt ) ) {
988	// set dtor location to the object's location for error messages
989	auto dtorFunc = getDtorFunc( objDecl, dtorStmt, stmtsToAddBefore );
990	objDecl->attributes.push_back( new ast::Attribute( "cleanup", { new ast::VariableExpr(loc, dtorFunc ) } ) );
991	// ctorInit->dtor = nullptr;
992	} // if
993	}
994	} // if
995	} else if ( const ast::Init * init = ctorInit->init ) {
996	objDecl->init = init;
997	// ctorInit->init = nullptr;
998	} else {
999	// no constructor and no initializer, which is okay
1000	objDecl->init = nullptr;
1001	} // if
1002	// delete ctorInit;
1003	return objDecl;
1004	} // if
1005	return _objDecl;
1006	}
1007
1008	void ObjDeclCollector::previsit( const ast::CompoundStmt * ) {
1009	GuardValue( curVars );
1010	}
1011
1012	void ObjDeclCollector::previsit( const ast::DeclStmt * stmt ) {
1013	// keep track of all variables currently in scope
1014	if ( auto objDecl = stmt->decl.as<ast::ObjectDecl>() ) {
1015	curVars.push_back( objDecl );
1016	} // if
1017	}
1018
1019	void LabelFinder::previsit( const ast::Stmt * stmt ) {
1020	// for each label, remember the variables in scope at that label.
1021	for ( auto l : stmt->labels ) {
1022	vars[l] = curVars;
1023	} // for
1024	}
1025
1026	void LabelFinder::previsit( const ast::CompoundStmt * stmt ) {
1027	previsit( (const ast::Stmt *) stmt );
1028	Parent::previsit( stmt );
1029	}
1030
1031	void LabelFinder::previsit( const ast::DeclStmt * stmt ) {
1032	previsit( (const ast::Stmt *)stmt );
1033	Parent::previsit( stmt );
1034	}
1035
1036
1037	void InsertDtors::previsit( const ast::FunctionDecl * funcDecl ) {
1038	// each function needs to have its own set of labels
1039	GuardValue( labelVars );
1040	labelVars.clear();
1041	// LabelFinder does not recurse into FunctionDecl, so need to visit
1042	// its children manually.
1043	if (funcDecl->type) funcDecl->type->accept(finder);
1044	// maybeAccept( funcDecl->type, finder );
1045	if (funcDecl->stmts) funcDecl->stmts->accept(finder) ;
1046
1047	// all labels for this function have been collected, insert destructors as appropriate via implicit recursion.
1048	}
1049
1050	// Handle break/continue/goto in the same manner as C++. Basic idea: any objects that are in scope at the
1051	// BranchStmt but not at the labelled (target) statement must be destructed. If there are any objects in scope
1052	// at the target location but not at the BranchStmt then those objects would be uninitialized so notify the user
1053	// of the error. See C++ Reference 6.6 Jump Statements for details.
1054	void InsertDtors::handleGoto( const ast::BranchStmt * stmt ) {
1055	// can't do anything for computed goto
1056	if ( stmt->computedTarget ) return;
1057
1058	assertf( stmt->target.name != "", "BranchStmt missing a label: %s", toString( stmt ).c_str() );
1059	// S_L = lvars = set of objects in scope at label definition
1060	// S_G = curVars = set of objects in scope at goto statement
1061	ObjectSet & lvars = labelVars[ stmt->target ];
1062
1063	DTOR_PRINT(
1064	std::cerr << "at goto label: " << stmt->target.name << std::endl;
1065	std::cerr << "S_G = " << printSet( curVars ) << std::endl;
1066	std::cerr << "S_L = " << printSet( lvars ) << std::endl;
1067	)
1068
1069
1070	// std::set_difference requires that the inputs be sorted.
1071	lvars.sort();
1072	curVars.sort();
1073
1074	ObjectSet diff;
1075	// S_L-S_G results in set of objects whose construction is skipped - it's an error if this set is non-empty
1076	std::set_difference( lvars.begin(), lvars.end(), curVars.begin(), curVars.end(), std::inserter( diff, diff.begin() ) );
1077	DTOR_PRINT(
1078	std::cerr << "S_L-S_G = " << printSet( diff ) << std::endl;
1079	)
1080	if ( ! diff.empty() ) {
1081	SemanticError( stmt, std::string("jump to label '") + stmt->target.name + "' crosses initialization of " + (*diff.begin())->name + " " );
1082	} // if
1083	}
1084
1085	void InsertDtors::previsit( const ast::BranchStmt * stmt ) {
1086	switch( stmt->kind ) {
1087	case ast::BranchStmt::Continue:
1088	case ast::BranchStmt::Break:
1089	// could optimize the break/continue case, because the S_L-S_G check is unnecessary (this set should
1090	// always be empty), but it serves as a small sanity check.
1091	case ast::BranchStmt::Goto:
1092	handleGoto( stmt );
1093	break;
1094	default:
1095	assert( false );
1096	} // switch
1097	}
1098
1099	bool checkWarnings( const ast::FunctionDecl * funcDecl ) {
1100	// only check for warnings if the current function is a user-defined
1101	// constructor or destructor
1102	if ( ! funcDecl ) return false;
1103	if ( ! funcDecl->stmts ) return false;
1104	return CodeGen::isCtorDtor( funcDecl->name ) && ! funcDecl->linkage.is_overrideable;
1105	}
1106
1107	void GenStructMemberCalls::previsit( const ast::FunctionDecl * funcDecl ) {
1108	GuardValue( function );
1109	GuardValue( unhandled );
1110	GuardValue( usedUninit );
1111	GuardValue( thisParam );
1112	GuardValue( isCtor );
1113	GuardValue( structDecl );
1114	errors = SemanticErrorException(); // clear previous errors
1115
1116	// need to start with fresh sets
1117	unhandled.clear();
1118	usedUninit.clear();
1119
1120	function = mutate(funcDecl);
1121	// could this be non-unique?
1122	if (function != funcDecl) {
1123	std::cerr << "GenStructMemberCalls: non-unique FunctionDecl " << funcDecl->location << funcDecl->name << std::endl;
1124	}
1125
1126	isCtor = CodeGen::isConstructor( function->name );
1127	if ( checkWarnings( function ) ) {
1128	// const ast::FunctionType * type = function->type;
1129	// assert( ! type->params.empty() );
1130	thisParam = function->params.front().strict_as<ast::ObjectDecl>();
1131	auto thisType = getPointerBase( thisParam->get_type() );
1132	auto structType = dynamic_cast< const ast::StructInstType * >( thisType );
1133	if ( structType ) {
1134	structDecl = structType->base;
1135	for ( auto & member : structDecl->members ) {
1136	if ( auto field = member.as<ast::ObjectDecl>() ) {
1137	// record all of the struct type's members that need to be constructed or
1138	// destructed by the end of the function
1139	unhandled.insert( field );
1140	}
1141	}
1142	}
1143	}
1144	}
1145
1146	const ast::DeclWithType * GenStructMemberCalls::postvisit( const ast::FunctionDecl * funcDecl ) {
1147	// remove the unhandled objects from usedUninit, because a call is inserted
1148	// to handle them - only objects that are later constructed are used uninitialized.
1149	std::map< const ast::DeclWithType *, CodeLocation > diff;
1150	// need the comparator since usedUninit and unhandled have different types
1151	struct comp_t {
1152	typedef decltype(usedUninit)::value_type usedUninit_t;
1153	typedef decltype(unhandled)::value_type unhandled_t;
1154	bool operator()(usedUninit_t x, unhandled_t y) { return x.first < y; }
1155	bool operator()(unhandled_t x, usedUninit_t y) { return x < y.first; }
1156	} comp;
1157	std::set_difference( usedUninit.begin(), usedUninit.end(), unhandled.begin(), unhandled.end(), std::inserter( diff, diff.begin() ), comp );
1158	for ( auto p : diff ) {
1159	auto member = p.first;
1160	auto loc = p.second;
1161	// xxx - make error message better by also tracking the location that the object is constructed at?
1162	emit( loc, "in ", function->name, ", field ", member->name, " used before being constructed" );
1163	}
1164
1165	const CodeLocation loc = funcDecl->location;
1166
1167	if ( ! unhandled.empty() ) {
1168	auto mutStmts = function->stmts.get_and_mutate();
1169	// need to explicitly re-add function parameters to the indexer in order to resolve copy constructors
1170	auto guard = makeFuncGuard( [this]() { symtab.enterScope(); }, [this]() { symtab.leaveScope(); } );
1171	symtab.addFunction( function );
1172	auto global = transUnit().global;
1173
1174	// need to iterate through members in reverse in order for
1175	// ctor/dtor statements to come out in the right order
1176	for ( auto & member : reverseIterate( structDecl->members ) ) {
1177	auto field = member.as<ast::ObjectDecl>();
1178	// skip non-DWT members
1179	if ( ! field ) continue;
1180	// skip non-constructable members
1181	if ( ! tryConstruct( field ) ) continue;
1182	// skip handled members
1183	if ( ! unhandled.count( field ) ) continue;
1184
1185	// insert and resolve default/copy constructor call for each field that's unhandled
1186	// std::list< const ast::Stmt * > stmt;
1187	ast::Expr * arg2 = nullptr;
1188	if ( function->name == "?{}" && isCopyFunction( function ) ) {
1189	// if copy ctor, need to pass second-param-of-this-function.field
1190	// std::list< DeclarationWithType * > & params = function->get_functionType()->get_parameters();
1191	assert( function->params.size() == 2 );
1192	arg2 = new ast::MemberExpr(funcDecl->location, field, new ast::VariableExpr(funcDecl->location, function->params.back() ) );
1193	}
1194	InitExpander_new srcParam( arg2 );
1195	// cast away reference type and construct field.
1196	ast::Expr * thisExpr = new ast::CastExpr(funcDecl->location, new ast::VariableExpr(funcDecl->location, thisParam ), thisParam->get_type()->stripReferences());
1197	ast::Expr * memberDest = new ast::MemberExpr(funcDecl->location, field, thisExpr );
1198	ast::ptr<ast::Stmt> callStmt = SymTab::genImplicitCall( srcParam, memberDest, loc, function->name, field, static_cast<SymTab::LoopDirection>(isCtor) );
1199
1200	if ( callStmt ) {
1201	// auto & callStmt = stmt.front();
1202
1203	try {
1204	callStmt = callStmt->accept( *visitor );
1205	if ( isCtor ) {
1206	mutStmts->push_front( callStmt );
1207	} else { // TODO: don't generate destructor function/object for intrinsic calls
1208	// destructor statements should be added at the end
1209	// function->get_statements()->push_back( callStmt );
1210
1211	// Optimization: do not need to call intrinsic destructors on members
1212	if ( isIntrinsicSingleArgCallStmt( callStmt ) ) continue;
1213
1214	// __Destructor _dtor0 = { (void )&b.a1, (void ()(void *)_destroy_A };
1215	std::list< ast::ptr<ast::Stmt> > stmtsToAdd;
1216
1217	static UniqueName memberDtorNamer = { "__memberDtor" };
1218	assertf( global.dtorStruct, "builtin __Destructor not found." );
1219	assertf( global.dtorDestroy, "builtin __destroy_Destructor not found." );
1220
1221	ast::Expr * thisExpr = new ast::CastExpr( new ast::AddressExpr( new ast::VariableExpr(loc, thisParam ) ), new ast::PointerType( new ast::VoidType(), ast::CV::Qualifiers() ) );
1222	ast::Expr * dtorExpr = new ast::VariableExpr(loc, getDtorFunc( thisParam, callStmt, stmtsToAdd ) );
1223
1224	// cast destructor pointer to void ()(void ), to silence GCC incompatible pointer warnings
1225	auto dtorFtype = new ast::FunctionType();
1226	dtorFtype->params.emplace_back( new ast::PointerType( new ast::VoidType() ) );
1227	auto dtorType = new ast::PointerType( dtorFtype );
1228
1229	auto destructor = new ast::ObjectDecl(loc, memberDtorNamer.newName(), new ast::StructInstType( global.dtorStruct ), new ast::ListInit(loc, { new ast::SingleInit(loc, thisExpr ), new ast::SingleInit(loc, new ast::CastExpr( dtorExpr, dtorType ) ) } ) );
1230	destructor->attributes.push_back( new ast::Attribute( "cleanup", { new ast::VariableExpr( loc, global.dtorDestroy ) } ) );
1231	mutStmts->push_front( new ast::DeclStmt(loc, destructor ) );
1232	mutStmts->kids.splice( mutStmts->kids.begin(), stmtsToAdd );
1233	}
1234	} catch ( SemanticErrorException & error ) {
1235	emit( funcDecl->location, "in ", function->name , ", field ", field->name, " not explicitly ", isCtor ? "constructed" : "destructed", " and no ", isCtor ? "default constructor" : "destructor", " found" );
1236	}
1237	}
1238	}
1239	function->stmts = mutStmts;
1240	}
1241	if (! errors.isEmpty()) {
1242	throw errors;
1243	}
1244	// return funcDecl;
1245	return function;
1246	}
1247
1248	/// true if expr is effectively just the 'this' parameter
1249	bool isThisExpression( const ast::Expr * expr, const ast::DeclWithType * thisParam ) {
1250	// TODO: there are more complicated ways to pass 'this' to a constructor, e.g. &, &, etc.
1251	if ( auto varExpr = dynamic_cast< const ast::VariableExpr * >( expr ) ) {
1252	return varExpr->var == thisParam;
1253	} else if ( auto castExpr = dynamic_cast< const ast::CastExpr * > ( expr ) ) {
1254	return isThisExpression( castExpr->arg, thisParam );
1255	}
1256	return false;
1257	}
1258
1259	/// returns a MemberExpr if expr is effectively just member access on the 'this' parameter, else nullptr
1260	const ast::MemberExpr * isThisMemberExpr( const ast::Expr * expr, const ast::DeclWithType * thisParam ) {
1261	if ( auto memberExpr = dynamic_cast< const ast::MemberExpr * >( expr ) ) {
1262	if ( isThisExpression( memberExpr->aggregate, thisParam ) ) {
1263	return memberExpr;
1264	}
1265	} else if ( auto castExpr = dynamic_cast< const ast::CastExpr * >( expr ) ) {
1266	return isThisMemberExpr( castExpr->arg, thisParam );
1267	}
1268	return nullptr;
1269	}
1270
1271	void GenStructMemberCalls::previsit( const ast::ApplicationExpr * appExpr ) {
1272	if ( ! checkWarnings( function ) ) {
1273	visit_children = false;
1274	return;
1275	}
1276
1277	std::string fname = getFunctionName( appExpr );
1278	if ( fname == function->name ) {
1279	// call to same kind of function
1280	const ast::Expr * firstParam = appExpr->args.front();
1281
1282	if ( isThisExpression( firstParam, thisParam ) ) {
1283	// if calling another constructor on thisParam, assume that function handles
1284	// all members - if it doesn't a warning will appear in that function.
1285	unhandled.clear();
1286	} else if ( auto memberExpr = isThisMemberExpr( firstParam, thisParam ) ) {
1287	// if first parameter is a member expression on the this parameter,
1288	// then remove the member from unhandled set.
1289	if ( isThisExpression( memberExpr->aggregate, thisParam ) ) {
1290	unhandled.erase( memberExpr->member );
1291	}
1292	}
1293	}
1294	}
1295
1296	void GenStructMemberCalls::previsit( const ast::MemberExpr * memberExpr ) {
1297	if ( ! checkWarnings( function ) \|\| ! isCtor ) {
1298	visit_children = false;
1299	return;
1300	}
1301
1302	if ( isThisExpression( memberExpr->aggregate, thisParam ) ) {
1303	if ( unhandled.count( memberExpr->member ) ) {
1304	// emit a warning because a member was used before it was constructed
1305	usedUninit.insert( { memberExpr->member, memberExpr->location } );
1306	}
1307	}
1308	}
1309
1310	template< typename Visitor, typename... Params >
1311	void error( Visitor & v, CodeLocation loc, const Params &... params ) {
1312	SemanticErrorException err( loc, toString( params... ) );
1313	v.errors.append( err );
1314	}
1315
1316	template< typename... Params >
1317	void GenStructMemberCalls::emit( CodeLocation loc, const Params &... params ) {
1318	// toggle warnings vs. errors here.
1319	// warn( params... );
1320	error( *this, loc, params... );
1321	}
1322
1323	const ast::Expr * GenStructMemberCalls::postvisit( const ast::UntypedExpr * untypedExpr ) {
1324	// xxx - functions returning ast::ptr seems wrong...
1325	auto res = ResolvExpr::findVoidExpression( untypedExpr, { symtab, transUnit().global } );
1326	// Fix CodeLocation (at least until resolver is fixed).
1327	auto fix = localFillCodeLocations( untypedExpr->location, res.release() );
1328	return strict_dynamic_cast<const ast::Expr *>( fix );
1329	}
1330
1331	void InsertImplicitCalls::previsit(const ast::UniqueExpr * unqExpr) {
1332	if (visitedIds.count(unqExpr->id)) visit_children = false;
1333	else visitedIds.insert(unqExpr->id);
1334	}
1335
1336	const ast::Expr * FixCtorExprs::postvisit( const ast::ConstructorExpr * ctorExpr ) {
1337	const CodeLocation loc = ctorExpr->location;
1338	static UniqueName tempNamer( "_tmp_ctor_expr" );
1339	// xxx - is the size check necessary?
1340	assert( ctorExpr->result && ctorExpr->result->size() == 1 );
1341
1342	// xxx - this can be TupleAssignExpr now. Need to properly handle this case.
1343	// take possession of expr and env
1344	ast::ptr<ast::ApplicationExpr> callExpr = ctorExpr->callExpr.strict_as<ast::ApplicationExpr>();
1345	ast::ptr<ast::TypeSubstitution> env = ctorExpr->env;
1346	// ctorExpr->set_callExpr( nullptr );
1347	// ctorExpr->set_env( nullptr );
1348
1349	// xxx - ideally we would reuse the temporary generated from the copy constructor passes from within firstArg if it exists and not generate a temporary if it's unnecessary.
1350	auto tmp = new ast::ObjectDecl(loc, tempNamer.newName(), callExpr->args.front()->result );
1351	declsToAddBefore.push_back( tmp );
1352	// delete ctorExpr;
1353
1354	// build assignment and replace constructor's first argument with new temporary
1355	auto mutCallExpr = callExpr.get_and_mutate();
1356	const ast::Expr * firstArg = callExpr->args.front();
1357	ast::Expr * assign = new ast::UntypedExpr(loc, new ast::NameExpr(loc, "?=?" ), { new ast::AddressExpr(loc, new ast::VariableExpr(loc, tmp ) ), new ast::AddressExpr( firstArg ) } );
1358	firstArg = new ast::VariableExpr(loc, tmp );
1359	mutCallExpr->args.front() = firstArg;
1360
1361	// resolve assignment and dispose of new env
1362	auto resolved = ResolvExpr::findVoidExpression( assign, { symtab, transUnit().global } );
1363	auto mut = resolved.get_and_mutate();
1364	assertf(resolved.get() == mut, "newly resolved expression must be unique");
1365	mut->env = nullptr;
1366
1367	// for constructor expr:
1368	// T x;
1369	// x{};
1370	// results in:
1371	// T x;
1372	// T & tmp;
1373	// &tmp = &x, ?{}(tmp), tmp
1374	ast::CommaExpr * commaExpr = new ast::CommaExpr(loc, resolved, new ast::CommaExpr(loc, mutCallExpr, new ast::VariableExpr(loc, tmp ) ) );
1375	commaExpr->env = env;
1376	return commaExpr;
1377	}
1378	} // namespace
1379	} // namespace InitTweak
1380
1381	// Local Variables: //
1382	// tab-width: 4 //
1383	// mode: c++ //
1384	// compile-command: "make install" //
1385	// End: //

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