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source: src/ResolvExpr/Unify.cc @ 216597d

ADTarm-ehast-experimentalenumforall-pointer-decayjacob/cs343-translationjenkins-sandboxnew-astnew-ast-unique-exprpthread-emulationqualifiedEnum

Last change on this file since 216597d was 3315e3d, checked in by Andrew Beach <ajbeach@…>, 5 years ago
Unify uses Qualifiers::unify, which should handle lvalue better.
Property mode set to `100644`
File size: 48.3 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	// Unify.cc --
8	//
9	// Author : Richard C. Bilson
10	// Created On : Sun May 17 12:27:10 2015
11	// Last Modified By : Andrew Beach
12	// Last Modified On : Wed Sep 4 10:00:00 2019
13	// Update Count : 44
14	//
15
16	#include "Unify.h"
17
18	#include <cassert> // for assertf, assert
19	#include <iterator> // for back_insert_iterator, back_inserter
20	#include <map> // for _Rb_tree_const_iterator, _Rb_tree_i...
21	#include <memory> // for unique_ptr
22	#include <set> // for set
23	#include <string> // for string, operator==, operator!=, bas...
24	#include <utility> // for pair, move
25	#include <vector>
26
27	#include "AST/Decl.hpp"
28	#include "AST/Node.hpp"
29	#include "AST/Pass.hpp"
30	#include "AST/Type.hpp"
31	#include "AST/TypeEnvironment.hpp"
32	#include "Common/PassVisitor.h" // for PassVisitor
33	#include "FindOpenVars.h" // for findOpenVars
34	#include "Parser/LinkageSpec.h" // for C
35	#include "SynTree/Constant.h" // for Constant
36	#include "SynTree/Declaration.h" // for TypeDecl, TypeDecl::Data, Declarati...
37	#include "SynTree/Expression.h" // for TypeExpr, Expression, ConstantExpr
38	#include "SynTree/Mutator.h" // for Mutator
39	#include "SynTree/Type.h" // for Type, TypeInstType, FunctionType
40	#include "SynTree/Visitor.h" // for Visitor
41	#include "Tuples/Tuples.h" // for isTtype
42	#include "TypeEnvironment.h" // for EqvClass, AssertionSet, OpenVarSet
43	#include "typeops.h" // for flatten, occurs, commonType
44
45	namespace ast {
46	class SymbolTable;
47	}
48
49	namespace SymTab {
50	class Indexer;
51	} // namespace SymTab
52
53	// #define DEBUG
54
55	namespace ResolvExpr {
56
57	struct Unify_old : public WithShortCircuiting {
58	Unify_old( Type *type2, TypeEnvironment &env, AssertionSet &needAssertions, AssertionSet &haveAssertions, const OpenVarSet &openVars, WidenMode widen, const SymTab::Indexer &indexer );
59
60	bool get_result() const { return result; }
61
62	void previsit( BaseSyntaxNode * ) { visit_children = false; }
63
64	void postvisit( VoidType * voidType );
65	void postvisit( BasicType * basicType );
66	void postvisit( PointerType * pointerType );
67	void postvisit( ArrayType * arrayType );
68	void postvisit( ReferenceType * refType );
69	void postvisit( FunctionType * functionType );
70	void postvisit( StructInstType * aggregateUseType );
71	void postvisit( UnionInstType * aggregateUseType );
72	void postvisit( EnumInstType * aggregateUseType );
73	void postvisit( TraitInstType * aggregateUseType );
74	void postvisit( TypeInstType * aggregateUseType );
75	void postvisit( TupleType * tupleType );
76	void postvisit( VarArgsType * varArgsType );
77	void postvisit( ZeroType * zeroType );
78	void postvisit( OneType * oneType );
79
80	private:
81	template< typename RefType > void handleRefType( RefType inst, Type other );
82	template< typename RefType > void handleGenericRefType( RefType inst, Type other );
83
84	bool result;
85	Type *type2; // inherited
86	TypeEnvironment &env;
87	AssertionSet &needAssertions;
88	AssertionSet &haveAssertions;
89	const OpenVarSet &openVars;
90	WidenMode widen;
91	const SymTab::Indexer &indexer;
92	};
93
94	/// Attempts an inexact unification of type1 and type2.
95	/// Returns false if no such unification; if the types can be unified, sets common (unless they unify exactly and have identical type qualifiers)
96	bool unifyInexact( Type type1, Type type2, TypeEnvironment &env, AssertionSet &needAssertions, AssertionSet &haveAssertions, const OpenVarSet &openVars, WidenMode widen, const SymTab::Indexer &indexer, Type *&common );
97	bool unifyExact( Type type1, Type type2, TypeEnvironment &env, AssertionSet &needAssertions, AssertionSet &haveAssertions, const OpenVarSet &openVars, WidenMode widen, const SymTab::Indexer &indexer );
98
99	bool unifyExact(
100	const ast::Type * type1, const ast::Type * type2, ast::TypeEnvironment & env,
101	ast::AssertionSet & need, ast::AssertionSet & have, const ast::OpenVarSet & open,
102	WidenMode widen, const ast::SymbolTable & symtab );
103
104	bool typesCompatible( const Type * first, const Type * second, const SymTab::Indexer & indexer, const TypeEnvironment & env ) {
105	TypeEnvironment newEnv;
106	OpenVarSet openVars, closedVars; // added closedVars
107	AssertionSet needAssertions, haveAssertions;
108	Type * newFirst = first->clone(), * newSecond = second->clone();
109	env.apply( newFirst );
110	env.apply( newSecond );
111
112	// do we need to do this? Seems like we do, types should be able to be compatible if they
113	// have free variables that can unify
114	findOpenVars( newFirst, openVars, closedVars, needAssertions, haveAssertions, false );
115	findOpenVars( newSecond, openVars, closedVars, needAssertions, haveAssertions, true );
116
117	bool result = unifyExact( newFirst, newSecond, newEnv, needAssertions, haveAssertions, openVars, WidenMode( false, false ), indexer );
118	delete newFirst;
119	delete newSecond;
120	return result;
121	}
122
123	bool typesCompatible(
124	const ast::Type * first, const ast::Type * second, const ast::SymbolTable & symtab,
125	const ast::TypeEnvironment & env ) {
126	ast::TypeEnvironment newEnv;
127	ast::OpenVarSet open, closed;
128	ast::AssertionSet need, have;
129
130	ast::ptr<ast::Type> newFirst{ first }, newSecond{ second };
131	env.apply( newFirst );
132	env.apply( newSecond );
133
134	findOpenVars( newFirst, open, closed, need, have, FirstClosed );
135	findOpenVars( newSecond, open, closed, need, have, FirstOpen );
136
137	return unifyExact(
138	newFirst, newSecond, newEnv, need, have, open, noWiden(), symtab );
139	}
140
141	bool typesCompatibleIgnoreQualifiers( const Type * first, const Type * second, const SymTab::Indexer &indexer, const TypeEnvironment &env ) {
142	TypeEnvironment newEnv;
143	OpenVarSet openVars;
144	AssertionSet needAssertions, haveAssertions;
145	Type newFirst = first->clone(), newSecond = second->clone();
146	env.apply( newFirst );
147	env.apply( newSecond );
148	newFirst->get_qualifiers() = Type::Qualifiers();
149	newSecond->get_qualifiers() = Type::Qualifiers();
150	/// std::cerr << "first is ";
151	/// first->print( std::cerr );
152	/// std::cerr << std::endl << "second is ";
153	/// second->print( std::cerr );
154	/// std::cerr << std::endl << "newFirst is ";
155	/// newFirst->print( std::cerr );
156	/// std::cerr << std::endl << "newSecond is ";
157	/// newSecond->print( std::cerr );
158	/// std::cerr << std::endl;
159	bool result = unifyExact( newFirst, newSecond, newEnv, needAssertions, haveAssertions, openVars, WidenMode( false, false ), indexer );
160	delete newFirst;
161	delete newSecond;
162	return result;
163	}
164
165	bool typesCompatibleIgnoreQualifiers(
166	const ast::Type * first, const ast::Type * second, const ast::SymbolTable & symtab,
167	const ast::TypeEnvironment & env ) {
168	ast::TypeEnvironment newEnv;
169	ast::OpenVarSet open;
170	ast::AssertionSet need, have;
171
172	ast::ptr<ast::Type> newFirst{ first }, newSecond{ second };
173	env.apply( newFirst );
174	env.apply( newSecond );
175	reset_qualifiers( newFirst );
176	reset_qualifiers( newSecond );
177
178	return unifyExact(
179	newFirst, newSecond, newEnv, need, have, open, noWiden(), symtab );
180	}
181
182	bool unify( Type type1, Type type2, TypeEnvironment &env, AssertionSet &needAssertions, AssertionSet &haveAssertions, OpenVarSet &openVars, const SymTab::Indexer &indexer ) {
183	OpenVarSet closedVars;
184	findOpenVars( type1, openVars, closedVars, needAssertions, haveAssertions, false );
185	findOpenVars( type2, openVars, closedVars, needAssertions, haveAssertions, true );
186	Type *commonType = 0;
187	if ( unifyInexact( type1, type2, env, needAssertions, haveAssertions, openVars, WidenMode( true, true ), indexer, commonType ) ) {
188	if ( commonType ) {
189	delete commonType;
190	} // if
191	return true;
192	} else {
193	return false;
194	} // if
195	}
196
197	bool unify( Type type1, Type type2, TypeEnvironment &env, AssertionSet &needAssertions, AssertionSet &haveAssertions, OpenVarSet &openVars, const SymTab::Indexer &indexer, Type *&commonType ) {
198	OpenVarSet closedVars;
199	findOpenVars( type1, openVars, closedVars, needAssertions, haveAssertions, false );
200	findOpenVars( type2, openVars, closedVars, needAssertions, haveAssertions, true );
201	return unifyInexact( type1, type2, env, needAssertions, haveAssertions, openVars, WidenMode( true, true ), indexer, commonType );
202	}
203
204	bool unifyExact( Type type1, Type type2, TypeEnvironment &env, AssertionSet &needAssertions, AssertionSet &haveAssertions, const OpenVarSet &openVars, WidenMode widen, const SymTab::Indexer &indexer ) {
205	#ifdef DEBUG
206	TypeEnvironment debugEnv( env );
207	#endif
208	if ( type1->get_qualifiers() != type2->get_qualifiers() ) {
209	return false;
210	}
211
212	bool result;
213	TypeInstType var1 = dynamic_cast< TypeInstType >( type1 );
214	TypeInstType var2 = dynamic_cast< TypeInstType >( type2 );
215	OpenVarSet::const_iterator entry1, entry2;
216	if ( var1 ) {
217	entry1 = openVars.find( var1->get_name() );
218	} // if
219	if ( var2 ) {
220	entry2 = openVars.find( var2->get_name() );
221	} // if
222	bool isopen1 = var1 && ( entry1 != openVars.end() );
223	bool isopen2 = var2 && ( entry2 != openVars.end() );
224
225	if ( isopen1 && isopen2 ) {
226	if ( entry1->second.kind != entry2->second.kind ) {
227	result = false;
228	} else {
229	result = env.bindVarToVar(
230	var1, var2, TypeDecl::Data{ entry1->second, entry2->second }, needAssertions,
231	haveAssertions, openVars, widen, indexer );
232	}
233	} else if ( isopen1 ) {
234	result = env.bindVar( var1, type2, entry1->second, needAssertions, haveAssertions, openVars, widen, indexer );
235	} else if ( isopen2 ) { // TODO: swap widen values in call, since type positions are flipped?
236	result = env.bindVar( var2, type1, entry2->second, needAssertions, haveAssertions, openVars, widen, indexer );
237	} else {
238	PassVisitor<Unify_old> comparator( type2, env, needAssertions, haveAssertions, openVars, widen, indexer );
239	type1->accept( comparator );
240	result = comparator.pass.get_result();
241	} // if
242	#ifdef DEBUG
243	std::cerr << "============ unifyExact" << std::endl;
244	std::cerr << "type1 is ";
245	type1->print( std::cerr );
246	std::cerr << std::endl << "type2 is ";
247	type2->print( std::cerr );
248	std::cerr << std::endl << "openVars are ";
249	printOpenVarSet( openVars, std::cerr, 8 );
250	std::cerr << std::endl << "input env is " << std::endl;
251	debugEnv.print( std::cerr, 8 );
252	std::cerr << std::endl << "result env is " << std::endl;
253	env.print( std::cerr, 8 );
254	std::cerr << "result is " << result << std::endl;
255	#endif
256	return result;
257	}
258
259	bool unifyExact( Type type1, Type type2, TypeEnvironment &env, AssertionSet &needAssertions, AssertionSet &haveAssertions, OpenVarSet &openVars, const SymTab::Indexer &indexer ) {
260	return unifyExact( type1, type2, env, needAssertions, haveAssertions, openVars, WidenMode( false, false ), indexer );
261	}
262
263	bool unifyInexact( Type type1, Type type2, TypeEnvironment &env, AssertionSet &needAssertions, AssertionSet &haveAssertions, const OpenVarSet &openVars, WidenMode widen, const SymTab::Indexer &indexer, Type *&common ) {
264	Type::Qualifiers tq1 = type1->get_qualifiers(), tq2 = type2->get_qualifiers();
265	type1->get_qualifiers() = Type::Qualifiers();
266	type2->get_qualifiers() = Type::Qualifiers();
267	bool result;
268	#ifdef DEBUG
269	std::cerr << "unifyInexact type 1 is ";
270	type1->print( std::cerr );
271	std::cerr << " type 2 is ";
272	type2->print( std::cerr );
273	std::cerr << std::endl;
274	#endif
275	if ( ! unifyExact( type1, type2, env, needAssertions, haveAssertions, openVars, widen, indexer ) ) {
276	#ifdef DEBUG
277	std::cerr << "unifyInexact: no exact unification found" << std::endl;
278	#endif
279	if ( ( common = commonType( type1, type2, widen.first, widen.second, indexer, env, openVars ) ) ) {
280	common->tq = tq1.unify( tq2 );
281	#ifdef DEBUG
282	std::cerr << "unifyInexact: common type is ";
283	common->print( std::cerr );
284	std::cerr << std::endl;
285	#endif
286	result = true;
287	} else {
288	#ifdef DEBUG
289	std::cerr << "unifyInexact: no common type found" << std::endl;
290	#endif
291	result = false;
292	} // if
293	} else {
294	if ( tq1 != tq2 ) {
295	if ( ( tq1 > tq2 \|\| widen.first ) && ( tq2 > tq1 \|\| widen.second ) ) {
296	common = type1->clone();
297	common->tq = tq1.unify( tq2 );
298	result = true;
299	} else {
300	result = false;
301	} // if
302	} else {
303	common = type1->clone();
304	common->tq = tq1.unify( tq2 );
305	result = true;
306	} // if
307	} // if
308	type1->get_qualifiers() = tq1;
309	type2->get_qualifiers() = tq2;
310	return result;
311	}
312
313	Unify_old::Unify_old( Type *type2, TypeEnvironment &env, AssertionSet &needAssertions, AssertionSet &haveAssertions, const OpenVarSet &openVars, WidenMode widen, const SymTab::Indexer &indexer )
314	: result( false ), type2( type2 ), env( env ), needAssertions( needAssertions ), haveAssertions( haveAssertions ), openVars( openVars ), widen( widen ), indexer( indexer ) {
315	}
316
317	void Unify_old::postvisit( __attribute__((unused)) VoidType *voidType) {
318	result = dynamic_cast< VoidType* >( type2 );
319	}
320
321	void Unify_old::postvisit(BasicType *basicType) {
322	if ( BasicType otherBasic = dynamic_cast< BasicType >( type2 ) ) {
323	result = basicType->get_kind() == otherBasic->get_kind();
324	} // if
325	}
326
327	void markAssertionSet( AssertionSet &assertions, DeclarationWithType *assert ) {
328	/// std::cerr << "assertion set is" << std::endl;
329	/// printAssertionSet( assertions, std::cerr, 8 );
330	/// std::cerr << "looking for ";
331	/// assert->print( std::cerr );
332	/// std::cerr << std::endl;
333	AssertionSet::iterator i = assertions.find( assert );
334	if ( i != assertions.end() ) {
335	/// std::cerr << "found it!" << std::endl;
336	i->second.isUsed = true;
337	} // if
338	}
339
340	void markAssertions( AssertionSet &assertion1, AssertionSet &assertion2, Type *type ) {
341	for ( std::list< TypeDecl* >::const_iterator tyvar = type->get_forall().begin(); tyvar != type->get_forall().end(); ++tyvar ) {
342	for ( std::list< DeclarationWithType* >::const_iterator assert = (tyvar)->get_assertions().begin(); assert != (tyvar)->get_assertions().end(); ++assert ) {
343	markAssertionSet( assertion1, *assert );
344	markAssertionSet( assertion2, *assert );
345	} // for
346	} // for
347	}
348
349	void Unify_old::postvisit(PointerType *pointerType) {
350	if ( PointerType otherPointer = dynamic_cast< PointerType >( type2 ) ) {
351	result = unifyExact( pointerType->get_base(), otherPointer->get_base(), env, needAssertions, haveAssertions, openVars, WidenMode( false, false ), indexer );
352	markAssertions( haveAssertions, needAssertions, pointerType );
353	markAssertions( haveAssertions, needAssertions, otherPointer );
354	} // if
355	}
356
357	void Unify_old::postvisit(ReferenceType *refType) {
358	if ( ReferenceType otherRef = dynamic_cast< ReferenceType >( type2 ) ) {
359	result = unifyExact( refType->get_base(), otherRef->get_base(), env, needAssertions, haveAssertions, openVars, WidenMode( false, false ), indexer );
360	markAssertions( haveAssertions, needAssertions, refType );
361	markAssertions( haveAssertions, needAssertions, otherRef );
362	} // if
363	}
364
365	void Unify_old::postvisit(ArrayType *arrayType) {
366	ArrayType otherArray = dynamic_cast< ArrayType >( type2 );
367	// to unify, array types must both be VLA or both not VLA
368	// and must both have a dimension expression or not have a dimension
369	if ( otherArray && arrayType->get_isVarLen() == otherArray->get_isVarLen() ) {
370
371	if ( ! arrayType->get_isVarLen() && ! otherArray->get_isVarLen() &&
372	arrayType->get_dimension() != 0 && otherArray->get_dimension() != 0 ) {
373	ConstantExpr * ce1 = dynamic_cast< ConstantExpr * >( arrayType->get_dimension() );
374	ConstantExpr * ce2 = dynamic_cast< ConstantExpr * >( otherArray->get_dimension() );
375	// see C11 Reference Manual 6.7.6.2.6
376	// two array types with size specifiers that are integer constant expressions are
377	// compatible if both size specifiers have the same constant value
378	if ( ce1 && ce2 ) {
379	Constant * c1 = ce1->get_constant();
380	Constant * c2 = ce2->get_constant();
381
382	if ( c1->get_value() != c2->get_value() ) {
383	// does not unify if the dimension is different
384	return;
385	}
386	}
387	}
388
389	result = unifyExact( arrayType->get_base(), otherArray->get_base(), env, needAssertions, haveAssertions, openVars, WidenMode( false, false ), indexer );
390	} // if
391	}
392
393	template< typename Iterator, typename Func >
394	std::unique_ptr<Type> combineTypes( Iterator begin, Iterator end, Func & toType ) {
395	std::list< Type * > types;
396	for ( ; begin != end; ++begin ) {
397	// it's guaranteed that a ttype variable will be bound to a flat tuple, so ensure that this results in a flat tuple
398	flatten( toType( *begin ), back_inserter( types ) );
399	}
400	return std::unique_ptr<Type>( new TupleType( Type::Qualifiers(), types ) );
401	}
402
403	template< typename Iterator1, typename Iterator2 >
404	bool unifyDeclList( Iterator1 list1Begin, Iterator1 list1End, Iterator2 list2Begin, Iterator2 list2End, TypeEnvironment &env, AssertionSet &needAssertions, AssertionSet &haveAssertions, const OpenVarSet &openVars, const SymTab::Indexer &indexer ) {
405	auto get_type = [](DeclarationWithType * dwt){ return dwt->get_type(); };
406	for ( ; list1Begin != list1End && list2Begin != list2End; ++list1Begin, ++list2Begin ) {
407	Type * t1 = (*list1Begin)->get_type();
408	Type * t2 = (*list2Begin)->get_type();
409	bool isTtype1 = Tuples::isTtype( t1 );
410	bool isTtype2 = Tuples::isTtype( t2 );
411	// xxx - assumes ttype must be last parameter
412	// xxx - there may be a nice way to refactor this, but be careful because the argument positioning might matter in some cases.
413	if ( isTtype1 && ! isTtype2 ) {
414	// combine all of the things in list2, then unify
415	return unifyExact( t1, combineTypes( list2Begin, list2End, get_type ).get(), env, needAssertions, haveAssertions, openVars, WidenMode( false, false ), indexer );
416	} else if ( isTtype2 && ! isTtype1 ) {
417	// combine all of the things in list1, then unify
418	return unifyExact( combineTypes( list1Begin, list1End, get_type ).get(), t2, env, needAssertions, haveAssertions, openVars, WidenMode( false, false ), indexer );
419	} else if ( ! unifyExact( t1, t2, env, needAssertions, haveAssertions, openVars, WidenMode( false, false ), indexer ) ) {
420	return false;
421	} // if
422	} // for
423	// may get to the end of one argument list before the end of the other. This is only okay when the other is a ttype
424	if ( list1Begin != list1End ) {
425	// try unifying empty tuple type with ttype
426	Type * t1 = (*list1Begin)->get_type();
427	if ( Tuples::isTtype( t1 ) ) {
428	return unifyExact( t1, combineTypes( list2Begin, list2End, get_type ).get(), env, needAssertions, haveAssertions, openVars, WidenMode( false, false ), indexer );
429	} else return false;
430	} else if ( list2Begin != list2End ) {
431	// try unifying empty tuple type with ttype
432	Type * t2 = (*list2Begin)->get_type();
433	if ( Tuples::isTtype( t2 ) ) {
434	return unifyExact( combineTypes( list1Begin, list1End, get_type ).get(), t2, env, needAssertions, haveAssertions, openVars, WidenMode( false, false ), indexer );
435	} else return false;
436	} else {
437	return true;
438	} // if
439	}
440
441	/// Finds ttypes and replaces them with their expansion, if known.
442	/// This needs to be done so that satisfying ttype assertions is easier.
443	/// If this isn't done then argument lists can have wildly different
444	/// size and structure, when they should be compatible.
445	struct TtypeExpander_old : public WithShortCircuiting {
446	TypeEnvironment & tenv;
447	TtypeExpander_old( TypeEnvironment & tenv ) : tenv( tenv ) {}
448	void premutate( TypeInstType * ) { visit_children = false; }
449	Type * postmutate( TypeInstType * typeInst ) {
450	if ( const EqvClass *eqvClass = tenv.lookup( typeInst->get_name() ) ) {
451	// expand ttype parameter into its actual type
452	if ( eqvClass->data.kind == TypeDecl::Ttype && eqvClass->type ) {
453	delete typeInst;
454	return eqvClass->type->clone();
455	}
456	}
457	return typeInst;
458	}
459	};
460
461	/// flattens a list of declarations, so that each tuple type has a single declaration.
462	/// makes use of TtypeExpander to ensure ttypes are flat as well.
463	void flattenList( std::list< DeclarationWithType * > src, std::list< DeclarationWithType * > & dst, TypeEnvironment & env ) {
464	dst.clear();
465	for ( DeclarationWithType * dcl : src ) {
466	PassVisitor<TtypeExpander_old> expander( env );
467	dcl->acceptMutator( expander );
468	std::list< Type * > types;
469	flatten( dcl->get_type(), back_inserter( types ) );
470	for ( Type * t : types ) {
471	// outermost const, volatile, _Atomic qualifiers in parameters should not play a role in the unification of function types, since they do not determine whether a function is callable.
472	// Note: MUST consider at least mutex qualifier, since functions can be overloaded on outermost mutex and a mutex function has different requirements than a non-mutex function.
473	t->get_qualifiers() -= Type::Qualifiers(Type::Const \| Type::Volatile \| Type::Atomic);
474
475	dst.push_back( new ObjectDecl( "", Type::StorageClasses(), LinkageSpec::C, nullptr, t, nullptr ) );
476	}
477	delete dcl;
478	}
479	}
480
481	void Unify_old::postvisit(FunctionType *functionType) {
482	FunctionType otherFunction = dynamic_cast< FunctionType >( type2 );
483	if ( otherFunction && functionType->get_isVarArgs() == otherFunction->get_isVarArgs() ) {
484	// flatten the parameter lists for both functions so that tuple structure
485	// doesn't affect unification. Must be a clone so that the types don't change.
486	std::unique_ptr<FunctionType> flatFunc( functionType->clone() );
487	std::unique_ptr<FunctionType> flatOther( otherFunction->clone() );
488	flattenList( flatFunc->get_parameters(), flatFunc->get_parameters(), env );
489	flattenList( flatOther->get_parameters(), flatOther->get_parameters(), env );
490
491	// sizes don't have to match if ttypes are involved; need to be more precise wrt where the ttype is to prevent errors
492	if (
493	(flatFunc->parameters.size() == flatOther->parameters.size() &&
494	flatFunc->returnVals.size() == flatOther->returnVals.size())
495	\|\| flatFunc->isTtype()
496	\|\| flatOther->isTtype()
497	) {
498	if ( unifyDeclList( flatFunc->parameters.begin(), flatFunc->parameters.end(), flatOther->parameters.begin(), flatOther->parameters.end(), env, needAssertions, haveAssertions, openVars, indexer ) ) {
499	if ( unifyDeclList( flatFunc->returnVals.begin(), flatFunc->returnVals.end(), flatOther->returnVals.begin(), flatOther->returnVals.end(), env, needAssertions, haveAssertions, openVars, indexer ) ) {
500
501	// the original types must be used in mark assertions, since pointer comparisons are used
502	markAssertions( haveAssertions, needAssertions, functionType );
503	markAssertions( haveAssertions, needAssertions, otherFunction );
504
505	result = true;
506	} // if
507	} // if
508	} // if
509	} // if
510	}
511
512	template< typename RefType >
513	void Unify_old::handleRefType( RefType inst, Type other ) {
514	// check that other type is compatible and named the same
515	RefType otherStruct = dynamic_cast< RefType >( other );
516	result = otherStruct && inst->name == otherStruct->name;
517	}
518
519	template< typename RefType >
520	void Unify_old::handleGenericRefType( RefType inst, Type other ) {
521	// Check that other type is compatible and named the same
522	handleRefType( inst, other );
523	if ( ! result ) return;
524	// Check that parameters of types unify, if any
525	std::list< Expression* > params = inst->parameters;
526	std::list< Expression* > otherParams = ((RefType*)other)->parameters;
527
528	std::list< Expression* >::const_iterator it = params.begin(), jt = otherParams.begin();
529	for ( ; it != params.end() && jt != otherParams.end(); ++it, ++jt ) {
530	TypeExpr param = dynamic_cast< TypeExpr >(*it);
531	assertf(param, "Aggregate parameters should be type expressions");
532	TypeExpr otherParam = dynamic_cast< TypeExpr >(*jt);
533	assertf(otherParam, "Aggregate parameters should be type expressions");
534
535	Type* paramTy = param->get_type();
536	Type* otherParamTy = otherParam->get_type();
537
538	bool tupleParam = Tuples::isTtype( paramTy );
539	bool otherTupleParam = Tuples::isTtype( otherParamTy );
540
541	if ( tupleParam && otherTupleParam ) {
542	++it; ++jt; // skip ttype parameters for break
543	} else if ( tupleParam ) {
544	// bundle other parameters into tuple to match
545	std::list< Type * > binderTypes;
546
547	do {
548	binderTypes.push_back( otherParam->get_type()->clone() );
549	++jt;
550
551	if ( jt == otherParams.end() ) break;
552
553	otherParam = dynamic_cast< TypeExpr* >(*jt);
554	assertf(otherParam, "Aggregate parameters should be type expressions");
555	} while (true);
556
557	otherParamTy = new TupleType{ paramTy->get_qualifiers(), binderTypes };
558	++it; // skip ttype parameter for break
559	} else if ( otherTupleParam ) {
560	// bundle parameters into tuple to match other
561	std::list< Type * > binderTypes;
562
563	do {
564	binderTypes.push_back( param->get_type()->clone() );
565	++it;
566
567	if ( it == params.end() ) break;
568
569	param = dynamic_cast< TypeExpr* >(*it);
570	assertf(param, "Aggregate parameters should be type expressions");
571	} while (true);
572
573	paramTy = new TupleType{ otherParamTy->get_qualifiers(), binderTypes };
574	++jt; // skip ttype parameter for break
575	}
576
577	if ( ! unifyExact( paramTy, otherParamTy, env, needAssertions, haveAssertions, openVars, WidenMode(false, false), indexer ) ) {
578	result = false;
579	return;
580	}
581
582	// ttype parameter should be last
583	if ( tupleParam \|\| otherTupleParam ) break;
584	}
585	result = ( it == params.end() && jt == otherParams.end() );
586	}
587
588	void Unify_old::postvisit(StructInstType *structInst) {
589	handleGenericRefType( structInst, type2 );
590	}
591
592	void Unify_old::postvisit(UnionInstType *unionInst) {
593	handleGenericRefType( unionInst, type2 );
594	}
595
596	void Unify_old::postvisit(EnumInstType *enumInst) {
597	handleRefType( enumInst, type2 );
598	}
599
600	void Unify_old::postvisit(TraitInstType *contextInst) {
601	handleRefType( contextInst, type2 );
602	}
603
604	void Unify_old::postvisit(TypeInstType *typeInst) {
605	assert( openVars.find( typeInst->get_name() ) == openVars.end() );
606	TypeInstType otherInst = dynamic_cast< TypeInstType >( type2 );
607	if ( otherInst && typeInst->get_name() == otherInst->get_name() ) {
608	result = true;
609	/// } else {
610	/// NamedTypeDecl *nt = indexer.lookupType( typeInst->get_name() );
611	/// if ( nt ) {
612	/// TypeDecl type = dynamic_cast< TypeDecl >( nt );
613	/// assert( type );
614	/// if ( type->get_base() ) {
615	/// result = unifyExact( type->get_base(), typeInst, env, needAssertions, haveAssertions, openVars, WidenMode( false, false ), indexer );
616	/// }
617	/// }
618	} // if
619	}
620
621	template< typename Iterator1, typename Iterator2 >
622	bool unifyList( Iterator1 list1Begin, Iterator1 list1End, Iterator2 list2Begin, Iterator2 list2End, TypeEnvironment &env, AssertionSet &needAssertions, AssertionSet &haveAssertions, const OpenVarSet &openVars, const SymTab::Indexer &indexer ) {
623	auto get_type = [](Type * t) { return t; };
624	for ( ; list1Begin != list1End && list2Begin != list2End; ++list1Begin, ++list2Begin ) {
625	Type * t1 = *list1Begin;
626	Type * t2 = *list2Begin;
627	bool isTtype1 = Tuples::isTtype( t1 );
628	bool isTtype2 = Tuples::isTtype( t2 );
629	// xxx - assumes ttype must be last parameter
630	// xxx - there may be a nice way to refactor this, but be careful because the argument positioning might matter in some cases.
631	if ( isTtype1 && ! isTtype2 ) {
632	// combine all of the things in list2, then unify
633	return unifyExact( t1, combineTypes( list2Begin, list2End, get_type ).get(), env, needAssertions, haveAssertions, openVars, WidenMode( false, false ), indexer );
634	} else if ( isTtype2 && ! isTtype1 ) {
635	// combine all of the things in list1, then unify
636	return unifyExact( combineTypes( list1Begin, list1End, get_type ).get(), t2, env, needAssertions, haveAssertions, openVars, WidenMode( false, false ), indexer );
637	} else if ( ! unifyExact( t1, t2, env, needAssertions, haveAssertions, openVars, WidenMode( false, false ), indexer ) ) {
638	return false;
639	} // if
640
641	} // for
642	if ( list1Begin != list1End ) {
643	// try unifying empty tuple type with ttype
644	Type * t1 = *list1Begin;
645	if ( Tuples::isTtype( t1 ) ) {
646	return unifyExact( t1, combineTypes( list2Begin, list2End, get_type ).get(), env, needAssertions, haveAssertions, openVars, WidenMode( false, false ), indexer );
647	} else return false;
648	} else if ( list2Begin != list2End ) {
649	// try unifying empty tuple type with ttype
650	Type * t2 = *list2Begin;
651	if ( Tuples::isTtype( t2 ) ) {
652	return unifyExact( combineTypes( list1Begin, list1End, get_type ).get(), t2, env, needAssertions, haveAssertions, openVars, WidenMode( false, false ), indexer );
653	} else return false;
654	} else {
655	return true;
656	} // if
657	}
658
659	void Unify_old::postvisit(TupleType *tupleType) {
660	if ( TupleType otherTuple = dynamic_cast< TupleType >( type2 ) ) {
661	std::unique_ptr<TupleType> flat1( tupleType->clone() );
662	std::unique_ptr<TupleType> flat2( otherTuple->clone() );
663	std::list<Type *> types1, types2;
664
665	PassVisitor<TtypeExpander_old> expander( env );
666	flat1->acceptMutator( expander );
667	flat2->acceptMutator( expander );
668
669	flatten( flat1.get(), back_inserter( types1 ) );
670	flatten( flat2.get(), back_inserter( types2 ) );
671
672	result = unifyList( types1.begin(), types1.end(), types2.begin(), types2.end(), env, needAssertions, haveAssertions, openVars, indexer );
673	} // if
674	}
675
676	void Unify_old::postvisit( __attribute__((unused)) VarArgsType *varArgsType ) {
677	result = dynamic_cast< VarArgsType* >( type2 );
678	}
679
680	void Unify_old::postvisit( __attribute__((unused)) ZeroType *zeroType ) {
681	result = dynamic_cast< ZeroType* >( type2 );
682	}
683
684	void Unify_old::postvisit( __attribute__((unused)) OneType *oneType ) {
685	result = dynamic_cast< OneType* >( type2 );
686	}
687
688	Type * extractResultType( FunctionType * function ) {
689	if ( function->get_returnVals().size() == 0 ) {
690	return new VoidType( Type::Qualifiers() );
691	} else if ( function->get_returnVals().size() == 1 ) {
692	return function->get_returnVals().front()->get_type()->clone();
693	} else {
694	std::list< Type * > types;
695	for ( DeclarationWithType * decl : function->get_returnVals() ) {
696	types.push_back( decl->get_type()->clone() );
697	} // for
698	return new TupleType( Type::Qualifiers(), types );
699	}
700	}
701
702	class Unify_new final : public ast::WithShortCircuiting {
703	const ast::Type * type2;
704	ast::TypeEnvironment & tenv;
705	ast::AssertionSet & need;
706	ast::AssertionSet & have;
707	const ast::OpenVarSet & open;
708	WidenMode widen;
709	const ast::SymbolTable & symtab;
710	public:
711	bool result;
712
713	Unify_new(
714	const ast::Type * type2, ast::TypeEnvironment & env, ast::AssertionSet & need,
715	ast::AssertionSet & have, const ast::OpenVarSet & open, WidenMode widen,
716	const ast::SymbolTable & symtab )
717	: type2(type2), tenv(env), need(need), have(have), open(open), widen(widen),
718	symtab(symtab), result(false) {}
719
720	void previsit( const ast::Node * ) { visit_children = false; }
721
722	void postvisit( const ast::VoidType * ) {
723	result = dynamic_cast< const ast::VoidType * >( type2 );
724	}
725
726	void postvisit( const ast::BasicType * basic ) {
727	if ( auto basic2 = dynamic_cast< const ast::BasicType * >( type2 ) ) {
728	result = basic->kind == basic2->kind;
729	}
730	}
731
732	void postvisit( const ast::PointerType * pointer ) {
733	if ( auto pointer2 = dynamic_cast< const ast::PointerType * >( type2 ) ) {
734	result = unifyExact(
735	pointer->base, pointer2->base, tenv, need, have, open,
736	noWiden(), symtab );
737	}
738	}
739
740	void postvisit( const ast::ArrayType * array ) {
741	auto array2 = dynamic_cast< const ast::ArrayType * >( type2 );
742	if ( ! array2 ) return;
743
744	// to unify, array types must both be VLA or both not VLA and both must have a
745	// dimension expression or not have a dimension
746	if ( array->isVarLen != array2->isVarLen ) return;
747	if ( ! array->isVarLen && ! array2->isVarLen
748	&& array->dimension && array2->dimension ) {
749	auto ce1 = array->dimension.as< ast::ConstantExpr >();
750	auto ce2 = array2->dimension.as< ast::ConstantExpr >();
751
752	// see C11 Reference Manual 6.7.6.2.6
753	// two array types with size specifiers that are integer constant expressions are
754	// compatible if both size specifiers have the same constant value
755	if ( ce1 && ce2 && ce1->intValue() != ce2->intValue() ) return;
756	}
757
758	result = unifyExact(
759	array->base, array2->base, tenv, need, have, open, noWiden(),
760	symtab );
761	}
762
763	void postvisit( const ast::ReferenceType * ref ) {
764	if ( auto ref2 = dynamic_cast< const ast::ReferenceType * >( type2 ) ) {
765	result = unifyExact(
766	ref->base, ref2->base, tenv, need, have, open, noWiden(),
767	symtab );
768	}
769	}
770
771	private:
772	/// Replaces ttype variables with their bound types.
773	/// If this isn't done when satifying ttype assertions, then argument lists can have
774	/// different size and structure when they should be compatible.
775	struct TtypeExpander_new : public ast::WithShortCircuiting {
776	ast::TypeEnvironment & tenv;
777
778	TtypeExpander_new( ast::TypeEnvironment & env ) : tenv( env ) {}
779
780	const ast::Type * postvisit( const ast::TypeInstType * typeInst ) {
781	if ( const ast::EqvClass * clz = tenv.lookup( typeInst->name ) ) {
782	// expand ttype parameter into its actual type
783	if ( clz->data.kind == ast::TypeVar::Ttype && clz->bound ) {
784	return clz->bound;
785	}
786	}
787	return typeInst;
788	}
789	};
790
791	/// returns flattened version of `src`
792	static std::vector< ast::ptr< ast::DeclWithType > > flattenList(
793	const std::vector< ast::ptr< ast::DeclWithType > > & src, ast::TypeEnvironment & env
794	) {
795	std::vector< ast::ptr< ast::DeclWithType > > dst;
796	dst.reserve( src.size() );
797	for ( const ast::DeclWithType * d : src ) {
798	ast::Pass<TtypeExpander_new> expander{ env };
799	d = d->accept( expander );
800	auto types = flatten( d->get_type() );
801	for ( ast::ptr< ast::Type > & t : types ) {
802	// outermost const, volatile, _Atomic qualifiers in parameters should not play
803	// a role in the unification of function types, since they do not determine
804	// whether a function is callable.
805	// NOTE: must consider at least mutex qualifier, since functions can be
806	// overloaded on outermost mutex and a mutex function has different
807	// requirements than a non-mutex function
808	remove_qualifiers( t, ast::CV::Const \| ast::CV::Volatile \| ast::CV::Atomic );
809	dst.emplace_back( new ast::ObjectDecl{ d->location, "", t } );
810	}
811	}
812	return dst;
813	}
814
815	/// Creates a tuple type based on a list of DeclWithType
816	template< typename Iter >
817	static ast::ptr< ast::Type > tupleFromDecls( Iter crnt, Iter end ) {
818	std::vector< ast::ptr< ast::Type > > types;
819	while ( crnt != end ) {
820	// it is guaranteed that a ttype variable will be bound to a flat tuple, so ensure
821	// that this results in a flat tuple
822	flatten( (*crnt)->get_type(), types );
823
824	++crnt;
825	}
826
827	return { new ast::TupleType{ std::move(types) } };
828	}
829
830	template< typename Iter >
831	static bool unifyDeclList(
832	Iter crnt1, Iter end1, Iter crnt2, Iter end2, ast::TypeEnvironment & env,
833	ast::AssertionSet & need, ast::AssertionSet & have, const ast::OpenVarSet & open,
834	const ast::SymbolTable & symtab
835	) {
836	while ( crnt1 != end1 && crnt2 != end2 ) {
837	const ast::Type * t1 = (*crnt1)->get_type();
838	const ast::Type * t2 = (*crnt2)->get_type();
839	bool isTuple1 = Tuples::isTtype( t1 );
840	bool isTuple2 = Tuples::isTtype( t2 );
841
842	// assumes here that ttype must be last parameter
843	if ( isTuple1 && ! isTuple2 ) {
844	// combine remainder of list2, then unify
845	return unifyExact(
846	t1, tupleFromDecls( crnt2, end2 ), env, need, have, open,
847	noWiden(), symtab );
848	} else if ( ! isTuple1 && isTuple2 ) {
849	// combine remainder of list1, then unify
850	return unifyExact(
851	tupleFromDecls( crnt1, end1 ), t2, env, need, have, open,
852	noWiden(), symtab );
853	}
854
855	if ( ! unifyExact(
856	t1, t2, env, need, have, open, noWiden(), symtab )
857	) return false;
858
859	++crnt1; ++crnt2;
860	}
861
862	// May get to the end of one argument list before the other. This is only okay if the
863	// other is a ttype
864	if ( crnt1 != end1 ) {
865	// try unifying empty tuple with ttype
866	const ast::Type * t1 = (*crnt1)->get_type();
867	if ( ! Tuples::isTtype( t1 ) ) return false;
868	return unifyExact(
869	t1, tupleFromDecls( crnt2, end2 ), env, need, have, open,
870	noWiden(), symtab );
871	} else if ( crnt2 != end2 ) {
872	// try unifying empty tuple with ttype
873	const ast::Type * t2 = (*crnt2)->get_type();
874	if ( ! Tuples::isTtype( t2 ) ) return false;
875	return unifyExact(
876	tupleFromDecls( crnt1, end1 ), t2, env, need, have, open,
877	noWiden(), symtab );
878	}
879
880	return true;
881	}
882
883	static bool unifyDeclList(
884	const std::vector< ast::ptr< ast::DeclWithType > > & list1,
885	const std::vector< ast::ptr< ast::DeclWithType > > & list2,
886	ast::TypeEnvironment & env, ast::AssertionSet & need, ast::AssertionSet & have,
887	const ast::OpenVarSet & open, const ast::SymbolTable & symtab
888	) {
889	return unifyDeclList(
890	list1.begin(), list1.end(), list2.begin(), list2.end(), env, need, have, open,
891	symtab );
892	}
893
894	static void markAssertionSet( ast::AssertionSet & assns, const ast::DeclWithType * assn ) {
895	auto i = assns.find( assn );
896	if ( i != assns.end() ) {
897	i->second.isUsed = true;
898	}
899	}
900
901	/// mark all assertions in `type` used in both `assn1` and `assn2`
902	static void markAssertions(
903	ast::AssertionSet & assn1, ast::AssertionSet & assn2,
904	const ast::ParameterizedType * type
905	) {
906	for ( const auto & tyvar : type->forall ) {
907	for ( const ast::DeclWithType * assert : tyvar->assertions ) {
908	markAssertionSet( assn1, assert );
909	markAssertionSet( assn2, assert );
910	}
911	}
912	}
913
914	public:
915	void postvisit( const ast::FunctionType * func ) {
916	auto func2 = dynamic_cast< const ast::FunctionType * >( type2 );
917	if ( ! func2 ) return;
918
919	if ( func->isVarArgs != func2->isVarArgs ) return;
920
921	// Flatten the parameter lists for both functions so that tuple structure does not
922	// affect unification. Does not actually mutate function parameters.
923	auto params = flattenList( func->params, tenv );
924	auto params2 = flattenList( func2->params, tenv );
925
926	// sizes don't have to match if ttypes are involved; need to be more precise w.r.t.
927	// where the ttype is to prevent errors
928	if (
929	( params.size() != params2.size() \|\| func->returns.size() != func2->returns.size() )
930	&& ! func->isTtype()
931	&& ! func2->isTtype()
932	) return;
933
934	if ( ! unifyDeclList( params, params2, tenv, need, have, open, symtab ) ) return;
935	if ( ! unifyDeclList(
936	func->returns, func2->returns, tenv, need, have, open, symtab ) ) return;
937
938	markAssertions( have, need, func );
939	markAssertions( have, need, func2 );
940
941	result = true;
942	}
943
944	private:
945	template< typename RefType >
946	const RefType * handleRefType( const RefType * inst, const ast::Type * other ) {
947	// check that the other type is compatible and named the same
948	auto otherInst = dynamic_cast< const RefType * >( other );
949	result = otherInst && inst->name == otherInst->name;
950	return otherInst;
951	}
952
953	/// Creates a tuple type based on a list of TypeExpr
954	template< typename Iter >
955	static const ast::Type * tupleFromExprs(
956	const ast::TypeExpr * param, Iter & crnt, Iter end, ast::CV::Qualifiers qs
957	) {
958	std::vector< ast::ptr< ast::Type > > types;
959	do {
960	types.emplace_back( param->type );
961
962	++crnt;
963	if ( crnt == end ) break;
964	param = strict_dynamic_cast< const ast::TypeExpr * >( crnt->get() );
965	} while(true);
966
967	return new ast::TupleType{ std::move(types), qs };
968	}
969
970	template< typename RefType >
971	void handleGenericRefType( const RefType * inst, const ast::Type * other ) {
972	// check that other type is compatible and named the same
973	const RefType * inst2 = handleRefType( inst, other );
974	if ( ! inst2 ) return;
975
976	// check that parameters of types unify, if any
977	const std::vector< ast::ptr< ast::Expr > > & params = inst->params;
978	const std::vector< ast::ptr< ast::Expr > > & params2 = inst2->params;
979
980	auto it = params.begin();
981	auto jt = params2.begin();
982	for ( ; it != params.end() && jt != params2.end(); ++it, ++jt ) {
983	auto param = strict_dynamic_cast< const ast::TypeExpr * >( it->get() );
984	auto param2 = strict_dynamic_cast< const ast::TypeExpr * >( jt->get() );
985
986	ast::ptr< ast::Type > pty = param->type;
987	ast::ptr< ast::Type > pty2 = param2->type;
988
989	bool isTuple = Tuples::isTtype( pty );
990	bool isTuple2 = Tuples::isTtype( pty2 );
991
992	if ( isTuple && isTuple2 ) {
993	++it; ++jt; // skip ttype parameters before break
994	} else if ( isTuple ) {
995	// bundle remaining params into tuple
996	pty2 = tupleFromExprs( param2, jt, params2.end(), pty->qualifiers );
997	++it; // skip ttype parameter for break
998	} else if ( isTuple2 ) {
999	// bundle remaining params into tuple
1000	pty = tupleFromExprs( param, it, params.end(), pty2->qualifiers );
1001	++jt; // skip ttype parameter for break
1002	}
1003
1004	if ( ! unifyExact(
1005	pty, pty2, tenv, need, have, open, noWiden(), symtab ) ) {
1006	result = false;
1007	return;
1008	}
1009
1010	// ttype parameter should be last
1011	if ( isTuple \|\| isTuple2 ) break;
1012	}
1013	result = it == params.end() && jt == params2.end();
1014	}
1015
1016	public:
1017	void postvisit( const ast::StructInstType * aggrType ) {
1018	handleGenericRefType( aggrType, type2 );
1019	}
1020
1021	void postvisit( const ast::UnionInstType * aggrType ) {
1022	handleGenericRefType( aggrType, type2 );
1023	}
1024
1025	void postvisit( const ast::EnumInstType * aggrType ) {
1026	handleRefType( aggrType, type2 );
1027	}
1028
1029	void postvisit( const ast::TraitInstType * aggrType ) {
1030	handleRefType( aggrType, type2 );
1031	}
1032
1033	void postvisit( const ast::TypeInstType * typeInst ) {
1034	assert( open.find( typeInst->name ) == open.end() );
1035	handleRefType( typeInst, type2 );
1036	}
1037
1038	private:
1039	/// Creates a tuple type based on a list of Type
1040	static ast::ptr< ast::Type > tupleFromTypes(
1041	const std::vector< ast::ptr< ast::Type > > & tys
1042	) {
1043	std::vector< ast::ptr< ast::Type > > out;
1044	for ( const ast::Type * ty : tys ) {
1045	// it is guaranteed that a ttype variable will be bound to a flat tuple, so ensure
1046	// that this results in a flat tuple
1047	flatten( ty, out );
1048	}
1049
1050	return { new ast::TupleType{ std::move(out) } };
1051	}
1052
1053	static bool unifyList(
1054	const std::vector< ast::ptr< ast::Type > > & list1,
1055	const std::vector< ast::ptr< ast::Type > > & list2, ast::TypeEnvironment & env,
1056	ast::AssertionSet & need, ast::AssertionSet & have, const ast::OpenVarSet & open,
1057	const ast::SymbolTable & symtab
1058	) {
1059	auto crnt1 = list1.begin();
1060	auto crnt2 = list2.begin();
1061	while ( crnt1 != list1.end() && crnt2 != list2.end() ) {
1062	const ast::Type * t1 = *crnt1;
1063	const ast::Type * t2 = *crnt2;
1064	bool isTuple1 = Tuples::isTtype( t1 );
1065	bool isTuple2 = Tuples::isTtype( t2 );
1066
1067	// assumes ttype must be last parameter
1068	if ( isTuple1 && ! isTuple2 ) {
1069	// combine entirety of list2, then unify
1070	return unifyExact(
1071	t1, tupleFromTypes( list2 ), env, need, have, open,
1072	noWiden(), symtab );
1073	} else if ( ! isTuple1 && isTuple2 ) {
1074	// combine entirety of list1, then unify
1075	return unifyExact(
1076	tupleFromTypes( list1 ), t2, env, need, have, open,
1077	noWiden(), symtab );
1078	}
1079
1080	if ( ! unifyExact(
1081	t1, t2, env, need, have, open, noWiden(), symtab )
1082	) return false;
1083
1084	++crnt1; ++crnt2;
1085	}
1086
1087	if ( crnt1 != list1.end() ) {
1088	// try unifying empty tuple type with ttype
1089	const ast::Type * t1 = *crnt1;
1090	if ( ! Tuples::isTtype( t1 ) ) return false;
1091	// xxx - this doesn't generate an empty tuple, contrary to comment; both ported
1092	// from Rob's code
1093	return unifyExact(
1094	t1, tupleFromTypes( list2 ), env, need, have, open,
1095	noWiden(), symtab );
1096	} else if ( crnt2 != list2.end() ) {
1097	// try unifying empty tuple with ttype
1098	const ast::Type * t2 = *crnt2;
1099	if ( ! Tuples::isTtype( t2 ) ) return false;
1100	// xxx - this doesn't generate an empty tuple, contrary to comment; both ported
1101	// from Rob's code
1102	return unifyExact(
1103	tupleFromTypes( list1 ), t2, env, need, have, open,
1104	noWiden(), symtab );
1105	}
1106
1107	return true;
1108	}
1109
1110	public:
1111	void postvisit( const ast::TupleType * tuple ) {
1112	auto tuple2 = dynamic_cast< const ast::TupleType * >( type2 );
1113	if ( ! tuple2 ) return;
1114
1115	ast::Pass<TtypeExpander_new> expander{ tenv };
1116	const ast::Type * flat = tuple->accept( expander );
1117	const ast::Type * flat2 = tuple2->accept( expander );
1118
1119	auto types = flatten( flat );
1120	auto types2 = flatten( flat2 );
1121
1122	result = unifyList( types, types2, tenv, need, have, open, symtab );
1123	}
1124
1125	void postvisit( const ast::VarArgsType * ) {
1126	result = dynamic_cast< const ast::VarArgsType * >( type2 );
1127	}
1128
1129	void postvisit( const ast::ZeroType * ) {
1130	result = dynamic_cast< const ast::ZeroType * >( type2 );
1131	}
1132
1133	void postvisit( const ast::OneType * ) {
1134	result = dynamic_cast< const ast::OneType * >( type2 );
1135	}
1136
1137	private:
1138	template< typename RefType > void handleRefType( RefType inst, Type other );
1139	template< typename RefType > void handleGenericRefType( RefType inst, Type other );
1140	};
1141
1142	bool unify(
1143	const ast::ptr<ast::Type> & type1, const ast::ptr<ast::Type> & type2,
1144	ast::TypeEnvironment & env, ast::AssertionSet & need, ast::AssertionSet & have,
1145	ast::OpenVarSet & open, const ast::SymbolTable & symtab
1146	) {
1147	ast::ptr<ast::Type> common;
1148	return unify( type1, type2, env, need, have, open, symtab, common );
1149	}
1150
1151	bool unify(
1152	const ast::ptr<ast::Type> & type1, const ast::ptr<ast::Type> & type2,
1153	ast::TypeEnvironment & env, ast::AssertionSet & need, ast::AssertionSet & have,
1154	ast::OpenVarSet & open, const ast::SymbolTable & symtab, ast::ptr<ast::Type> & common
1155	) {
1156	ast::OpenVarSet closed;
1157	findOpenVars( type1, open, closed, need, have, FirstClosed );
1158	findOpenVars( type2, open, closed, need, have, FirstOpen );
1159	return unifyInexact(
1160	type1, type2, env, need, have, open, WidenMode{ true, true }, symtab, common );
1161	}
1162
1163	bool unifyExact(
1164	const ast::Type * type1, const ast::Type * type2, ast::TypeEnvironment & env,
1165	ast::AssertionSet & need, ast::AssertionSet & have, const ast::OpenVarSet & open,
1166	WidenMode widen, const ast::SymbolTable & symtab
1167	) {
1168	if ( type1->qualifiers != type2->qualifiers ) return false;
1169
1170	auto var1 = dynamic_cast< const ast::TypeInstType * >( type1 );
1171	auto var2 = dynamic_cast< const ast::TypeInstType * >( type2 );
1172	ast::OpenVarSet::const_iterator
1173	entry1 = var1 ? open.find( var1->name ) : open.end(),
1174	entry2 = var2 ? open.find( var2->name ) : open.end();
1175	bool isopen1 = entry1 != open.end();
1176	bool isopen2 = entry2 != open.end();
1177
1178	if ( isopen1 && isopen2 ) {
1179	if ( entry1->second.kind != entry2->second.kind ) return false;
1180	return env.bindVarToVar(
1181	var1, var2, ast::TypeDecl::Data{ entry1->second, entry2->second }, need, have,
1182	open, widen, symtab );
1183	} else if ( isopen1 ) {
1184	return env.bindVar( var1, type2, entry1->second, need, have, open, widen, symtab );
1185	} else if ( isopen2 ) {
1186	return env.bindVar( var2, type1, entry2->second, need, have, open, widen, symtab );
1187	} else {
1188	ast::Pass<Unify_new> comparator{ type2, env, need, have, open, widen, symtab };
1189	type1->accept( comparator );
1190	return comparator.pass.result;
1191	}
1192	}
1193
1194	bool unifyInexact(
1195	const ast::ptr<ast::Type> & type1, const ast::ptr<ast::Type> & type2,
1196	ast::TypeEnvironment & env, ast::AssertionSet & need, ast::AssertionSet & have,
1197	const ast::OpenVarSet & open, WidenMode widen, const ast::SymbolTable & symtab,
1198	ast::ptr<ast::Type> & common
1199	) {
1200	ast::CV::Qualifiers q1 = type1->qualifiers, q2 = type2->qualifiers;
1201
1202	// force t1 and t2 to be cloned if their qualifiers must be stripped, so that type1 and
1203	// type2 are left unchanged; calling convention forces type{1,2}->strong_ref >= 1
1204	ast::ptr<ast::Type> t1{ type1 }, t2{ type2 };
1205	reset_qualifiers( t1 );
1206	reset_qualifiers( t2 );
1207
1208	if ( unifyExact( t1, t2, env, need, have, open, widen, symtab ) ) {
1209	t1 = nullptr; t2 = nullptr; // release t1, t2 to avoid spurious clones
1210
1211	// if exact unification on unqualified types, try to merge qualifiers
1212	if ( q1 == q2 \|\| ( ( q1 > q2 \|\| widen.first ) && ( q2 > q1 \|\| widen.second ) ) ) {
1213	common = type1;
1214	reset_qualifiers( common, q1 \| q2 );
1215	return true;
1216	} else {
1217	return false;
1218	}
1219
1220	} else if (( common = commonType( t1, t2, widen, symtab, env, open ) )) {
1221	t1 = nullptr; t2 = nullptr; // release t1, t2 to avoid spurious clones
1222
1223	// no exact unification, but common type
1224	reset_qualifiers( common, q1 \| q2 );
1225	return true;
1226	} else {
1227	return false;
1228	}
1229	}
1230
1231	ast::ptr<ast::Type> extractResultType( const ast::FunctionType * func ) {
1232	if ( func->returns.empty() ) return new ast::VoidType{};
1233	if ( func->returns.size() == 1 ) return func->returns[0]->get_type();
1234
1235	std::vector<ast::ptr<ast::Type>> tys;
1236	for ( const ast::DeclWithType * decl : func->returns ) {
1237	tys.emplace_back( decl->get_type() );
1238	}
1239	return new ast::TupleType{ std::move(tys) };
1240	}
1241	} // namespace ResolvExpr
1242
1243	// Local Variables: //
1244	// tab-width: 4 //
1245	// mode: c++ //
1246	// compile-command: "make install" //
1247	// End: //

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