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source: src/ResolvExpr/CandidateFinder.cpp@ 16ba4a6f

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ADT arm-eh ast-experimental enum forall-pointer-decay jacob/cs343-translation new-ast-unique-expr pthread-emulation qualifiedEnum

Last change on this file since 16ba4a6f was 954c954, checked in by Fangren Yu <f37yu@…>, 5 years ago
Move function argument and return variable declarations from FunctionType to FunctionDecl
Property mode set to `100644`
File size: 63.1 KB

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1	//
2	// Cforall Version 1.0.0 Copyright (C) 2015 University of Waterloo
3	//
4	// The contents of this file are covered under the licence agreement in the
5	// file "LICENCE" distributed with Cforall.
6	//
7	// CandidateFinder.cpp --
8	//
9	// Author : Aaron B. Moss
10	// Created On : Wed Jun 5 14:30:00 2019
11	// Last Modified By : Andrew Beach
12	// Last Modified On : Tue Oct 1 14:55:00 2019
13	// Update Count : 2
14	//
15
16	#include "CandidateFinder.hpp"
17
18	#include <deque>
19	#include <iterator> // for back_inserter
20	#include <sstream>
21	#include <string>
22	#include <unordered_map>
23	#include <vector>
24
25	#include "Candidate.hpp"
26	#include "CompilationState.h"
27	#include "Cost.h"
28	#include "ExplodedArg.hpp"
29	#include "RenameVars.h" // for renameTyVars
30	#include "Resolver.h"
31	#include "ResolveTypeof.h"
32	#include "SatisfyAssertions.hpp"
33	#include "typeops.h" // for adjustExprType, conversionCost, polyCost, specCost
34	#include "Unify.h"
35	#include "AST/Expr.hpp"
36	#include "AST/Node.hpp"
37	#include "AST/Pass.hpp"
38	#include "AST/Print.hpp"
39	#include "AST/SymbolTable.hpp"
40	#include "AST/Type.hpp"
41	#include "Common/utility.h" // for move, copy
42	#include "SymTab/Mangler.h"
43	#include "SymTab/Validate.h" // for validateType
44	#include "Tuples/Tuples.h" // for handleTupleAssignment
45
46	#define PRINT( text ) if ( resolvep ) { text }
47
48	namespace ResolvExpr {
49
50	const ast::Expr * referenceToRvalueConversion( const ast::Expr * expr, Cost & cost ) {
51	if ( expr->result.as< ast::ReferenceType >() ) {
52	// cast away reference from expr
53	cost.incReference();
54	return new ast::CastExpr{ expr, expr->result->stripReferences() };
55	}
56
57	return expr;
58	}
59
60	/// Unique identifier for matching expression resolutions to their requesting expression
61	UniqueId globalResnSlot = 0;
62
63	Cost computeConversionCost(
64	const ast::Type * argType, const ast::Type * paramType, bool argIsLvalue,
65	const ast::SymbolTable & symtab, const ast::TypeEnvironment & env
66	) {
67	PRINT(
68	std::cerr << std::endl << "converting ";
69	ast::print( std::cerr, argType, 2 );
70	std::cerr << std::endl << " to ";
71	ast::print( std::cerr, paramType, 2 );
72	std::cerr << std::endl << "environment is: ";
73	ast::print( std::cerr, env, 2 );
74	std::cerr << std::endl;
75	)
76	Cost convCost = conversionCost( argType, paramType, argIsLvalue, symtab, env );
77	PRINT(
78	std::cerr << std::endl << "cost is " << convCost << std::endl;
79	)
80	if ( convCost == Cost::infinity ) return convCost;
81	convCost.incPoly( polyCost( paramType, symtab, env ) + polyCost( argType, symtab, env ) );
82	PRINT(
83	std::cerr << "cost with polycost is " << convCost << std::endl;
84	)
85	return convCost;
86	}
87
88	namespace {
89	/// First index is which argument, second is which alternative, third is which exploded element
90	using ExplodedArgs_new = std::deque< std::vector< ExplodedArg > >;
91
92	/// Returns a list of alternatives with the minimum cost in the given list
93	CandidateList findMinCost( const CandidateList & candidates ) {
94	CandidateList out;
95	Cost minCost = Cost::infinity;
96	for ( const CandidateRef & r : candidates ) {
97	if ( r->cost < minCost ) {
98	minCost = r->cost;
99	out.clear();
100	out.emplace_back( r );
101	} else if ( r->cost == minCost ) {
102	out.emplace_back( r );
103	}
104	}
105	return out;
106	}
107
108	/// Computes conversion cost for a given expression to a given type
109	const ast::Expr * computeExpressionConversionCost(
110	const ast::Expr * arg, const ast::Type * paramType, const ast::SymbolTable & symtab, const ast::TypeEnvironment & env, Cost & outCost
111	) {
112	Cost convCost = computeConversionCost(
113	arg->result, paramType, arg->get_lvalue(), symtab, env );
114	outCost += convCost;
115
116	// If there is a non-zero conversion cost, ignoring poly cost, then the expression requires
117	// conversion. Ignore poly cost for now, since this requires resolution of the cast to
118	// infer parameters and this does not currently work for the reason stated below
119	Cost tmpCost = convCost;
120	tmpCost.incPoly( -tmpCost.get_polyCost() );
121	if ( tmpCost != Cost::zero ) {
122	ast::ptr< ast::Type > newType = paramType;
123	env.apply( newType );
124	return new ast::CastExpr{ arg, newType };
125
126	// xxx - should be able to resolve this cast, but at the moment pointers are not
127	// castable to zero_t, but are implicitly convertible. This is clearly inconsistent,
128	// once this is fixed it should be possible to resolve the cast.
129	// xxx - this isn't working, it appears because type1 (parameter) is seen as widenable,
130	// but it shouldn't be because this makes the conversion from DT* to DT* since
131	// commontype(zero_t, DT) is DT, rather than nothing
132
133	// CandidateFinder finder{ symtab, env };
134	// finder.find( arg, ResolvMode::withAdjustment() );
135	// assertf( finder.candidates.size() > 0,
136	// "Somehow castable expression failed to find alternatives." );
137	// assertf( finder.candidates.size() == 1,
138	// "Somehow got multiple alternatives for known cast expression." );
139	// return finder.candidates.front()->expr;
140	}
141
142	return arg;
143	}
144
145	/// Computes conversion cost for a given candidate
146	Cost computeApplicationConversionCost(
147	CandidateRef cand, const ast::SymbolTable & symtab
148	) {
149	auto appExpr = cand->expr.strict_as< ast::ApplicationExpr >();
150	auto pointer = appExpr->func->result.strict_as< ast::PointerType >();
151	auto function = pointer->base.strict_as< ast::FunctionType >();
152
153	Cost convCost = Cost::zero;
154	const auto & params = function->params;
155	auto param = params.begin();
156	auto & args = appExpr->args;
157
158	for ( unsigned i = 0; i < args.size(); ++i ) {
159	const ast::Type * argType = args[i]->result;
160	PRINT(
161	std::cerr << "arg expression:" << std::endl;
162	ast::print( std::cerr, args[i], 2 );
163	std::cerr << "--- results are" << std::endl;
164	ast::print( std::cerr, argType, 2 );
165	)
166
167	if ( param == params.end() ) {
168	if ( function->isVarArgs ) {
169	convCost.incUnsafe();
170	PRINT( std::cerr << "end of params with varargs function: inc unsafe: "
171	<< convCost << std::endl; ; )
172	// convert reference-typed expressions into value-typed expressions
173	cand->expr = ast::mutate_field_index(
174	appExpr, &ast::ApplicationExpr::args, i,
175	referenceToRvalueConversion( args[i], convCost ) );
176	continue;
177	} else return Cost::infinity;
178	}
179
180	if ( auto def = args[i].as< ast::DefaultArgExpr >() ) {
181	// Default arguments should be free - don't include conversion cost.
182	// Unwrap them here because they are not relevant to the rest of the system
183	cand->expr = ast::mutate_field_index(
184	appExpr, &ast::ApplicationExpr::args, i, def->expr );
185	++param;
186	continue;
187	}
188
189	// mark conversion cost and also specialization cost of param type
190	// const ast::Type * paramType = (*param)->get_type();
191	cand->expr = ast::mutate_field_index(
192	appExpr, &ast::ApplicationExpr::args, i,
193	computeExpressionConversionCost(
194	args[i], *param, symtab, cand->env, convCost ) );
195	convCost.decSpec( specCost( *param ) );
196	++param; // can't be in for-loop update because of the continue
197	}
198
199	if ( param != params.end() ) return Cost::infinity;
200
201	// specialization cost of return types can't be accounted for directly, it disables
202	// otherwise-identical calls, like this example based on auto-newline in the I/O lib:
203	//
204	// forall(otype OS) {
205	// void ?\|?(OS&, int); // with newline
206	// OS& ?\|?(OS&, int); // no newline, always chosen due to more specialization
207	// }
208
209	// mark type variable and specialization cost of forall clause
210	convCost.incVar( function->forall.size() );
211	for ( const ast::TypeDecl * td : function->forall ) {
212	convCost.decSpec( td->assertions.size() );
213	}
214
215	return convCost;
216	}
217
218	void makeUnifiableVars(
219	const ast::ParameterizedType * type, ast::OpenVarSet & unifiableVars,
220	ast::AssertionSet & need
221	) {
222	for ( const ast::TypeDecl * tyvar : type->forall ) {
223	unifiableVars[ tyvar->name ] = ast::TypeDecl::Data{ tyvar };
224	for ( const ast::DeclWithType * assn : tyvar->assertions ) {
225	need[ assn ].isUsed = true;
226	}
227	}
228	}
229
230	/// Gets a default value from an initializer, nullptr if not present
231	const ast::ConstantExpr * getDefaultValue( const ast::Init * init ) {
232	if ( auto si = dynamic_cast< const ast::SingleInit * >( init ) ) {
233	if ( auto ce = si->value.as< ast::CastExpr >() ) {
234	return ce->arg.as< ast::ConstantExpr >();
235	} else {
236	return si->value.as< ast::ConstantExpr >();
237	}
238	}
239	return nullptr;
240	}
241
242	/// State to iteratively build a match of parameter expressions to arguments
243	struct ArgPack {
244	std::size_t parent; ///< Index of parent pack
245	ast::ptr< ast::Expr > expr; ///< The argument stored here
246	Cost cost; ///< The cost of this argument
247	ast::TypeEnvironment env; ///< Environment for this pack
248	ast::AssertionSet need; ///< Assertions outstanding for this pack
249	ast::AssertionSet have; ///< Assertions found for this pack
250	ast::OpenVarSet open; ///< Open variables for this pack
251	unsigned nextArg; ///< Index of next argument in arguments list
252	unsigned tupleStart; ///< Number of tuples that start at this index
253	unsigned nextExpl; ///< Index of next exploded element
254	unsigned explAlt; ///< Index of alternative for nextExpl > 0
255
256	ArgPack()
257	: parent( 0 ), expr(), cost( Cost::zero ), env(), need(), have(), open(), nextArg( 0 ),
258	tupleStart( 0 ), nextExpl( 0 ), explAlt( 0 ) {}
259
260	ArgPack(
261	const ast::TypeEnvironment & env, const ast::AssertionSet & need,
262	const ast::AssertionSet & have, const ast::OpenVarSet & open )
263	: parent( 0 ), expr(), cost( Cost::zero ), env( env ), need( need ), have( have ),
264	open( open ), nextArg( 0 ), tupleStart( 0 ), nextExpl( 0 ), explAlt( 0 ) {}
265
266	ArgPack(
267	std::size_t parent, const ast::Expr * expr, ast::TypeEnvironment && env,
268	ast::AssertionSet && need, ast::AssertionSet && have, ast::OpenVarSet && open,
269	unsigned nextArg, unsigned tupleStart = 0, Cost cost = Cost::zero,
270	unsigned nextExpl = 0, unsigned explAlt = 0 )
271	: parent(parent), expr( expr ), cost( cost ), env( move( env ) ), need( move( need ) ),
272	have( move( have ) ), open( move( open ) ), nextArg( nextArg ), tupleStart( tupleStart ),
273	nextExpl( nextExpl ), explAlt( explAlt ) {}
274
275	ArgPack(
276	const ArgPack & o, ast::TypeEnvironment && env, ast::AssertionSet && need,
277	ast::AssertionSet && have, ast::OpenVarSet && open, unsigned nextArg, Cost added )
278	: parent( o.parent ), expr( o.expr ), cost( o.cost + added ), env( move( env ) ),
279	need( move( need ) ), have( move( have ) ), open( move( open ) ), nextArg( nextArg ),
280	tupleStart( o.tupleStart ), nextExpl( 0 ), explAlt( 0 ) {}
281
282	/// true if this pack is in the middle of an exploded argument
283	bool hasExpl() const { return nextExpl > 0; }
284
285	/// Gets the list of exploded candidates for this pack
286	const ExplodedArg & getExpl( const ExplodedArgs_new & args ) const {
287	return args[ nextArg-1 ][ explAlt ];
288	}
289
290	/// Ends a tuple expression, consolidating the appropriate args
291	void endTuple( const std::vector< ArgPack > & packs ) {
292	// add all expressions in tuple to list, summing cost
293	std::deque< const ast::Expr * > exprs;
294	const ArgPack * pack = this;
295	if ( expr ) { exprs.emplace_front( expr ); }
296	while ( pack->tupleStart == 0 ) {
297	pack = &packs[pack->parent];
298	exprs.emplace_front( pack->expr );
299	cost += pack->cost;
300	}
301	// reset pack to appropriate tuple
302	std::vector< ast::ptr< ast::Expr > > exprv( exprs.begin(), exprs.end() );
303	expr = new ast::TupleExpr{ expr->location, move( exprv ) };
304	tupleStart = pack->tupleStart - 1;
305	parent = pack->parent;
306	}
307	};
308
309	/// Instantiates an argument to match a parameter, returns false if no matching results left
310	bool instantiateArgument(
311	const ast::Type * paramType, const ast::Init * init, const ExplodedArgs_new & args,
312	std::vector< ArgPack > & results, std::size_t & genStart, const ast::SymbolTable & symtab,
313	unsigned nTuples = 0
314	) {
315	if ( auto tupleType = dynamic_cast< const ast::TupleType * >( paramType ) ) {
316	// paramType is a TupleType -- group args into a TupleExpr
317	++nTuples;
318	for ( const ast::Type * type : *tupleType ) {
319	// xxx - dropping initializer changes behaviour from previous, but seems correct
320	// ^^^ need to handle the case where a tuple has a default argument
321	if ( ! instantiateArgument(
322	type, nullptr, args, results, genStart, symtab, nTuples ) ) return false;
323	nTuples = 0;
324	}
325	// re-constitute tuples for final generation
326	for ( auto i = genStart; i < results.size(); ++i ) {
327	results[i].endTuple( results );
328	}
329	return true;
330	} else if ( const ast::TypeInstType * ttype = Tuples::isTtype( paramType ) ) {
331	// paramType is a ttype, consumes all remaining arguments
332
333	// completed tuples; will be spliced to end of results to finish
334	std::vector< ArgPack > finalResults{};
335
336	// iterate until all results completed
337	std::size_t genEnd;
338	++nTuples;
339	do {
340	genEnd = results.size();
341
342	// add another argument to results
343	for ( std::size_t i = genStart; i < genEnd; ++i ) {
344	unsigned nextArg = results[i].nextArg;
345
346	// use next element of exploded tuple if present
347	if ( results[i].hasExpl() ) {
348	const ExplodedArg & expl = results[i].getExpl( args );
349
350	unsigned nextExpl = results[i].nextExpl + 1;
351	if ( nextExpl == expl.exprs.size() ) { nextExpl = 0; }
352
353	results.emplace_back(
354	i, expl.exprs[ results[i].nextExpl ], copy( results[i].env ),
355	copy( results[i].need ), copy( results[i].have ),
356	copy( results[i].open ), nextArg, nTuples, Cost::zero, nextExpl,
357	results[i].explAlt );
358
359	continue;
360	}
361
362	// finish result when out of arguments
363	if ( nextArg >= args.size() ) {
364	ArgPack newResult{
365	results[i].env, results[i].need, results[i].have, results[i].open };
366	newResult.nextArg = nextArg;
367	const ast::Type * argType = nullptr;
368
369	if ( nTuples > 0 \|\| ! results[i].expr ) {
370	// first iteration or no expression to clone,
371	// push empty tuple expression
372	newResult.parent = i;
373	newResult.expr = new ast::TupleExpr{ CodeLocation{}, {} };
374	argType = newResult.expr->result;
375	} else {
376	// clone result to collect tuple
377	newResult.parent = results[i].parent;
378	newResult.cost = results[i].cost;
379	newResult.tupleStart = results[i].tupleStart;
380	newResult.expr = results[i].expr;
381	argType = newResult.expr->result;
382
383	if ( results[i].tupleStart > 0 && Tuples::isTtype( argType ) ) {
384	// the case where a ttype value is passed directly is special,
385	// e.g. for argument forwarding purposes
386	// xxx - what if passing multiple arguments, last of which is
387	// ttype?
388	// xxx - what would happen if unify was changed so that unifying
389	// tuple
390	// types flattened both before unifying lists? then pass in
391	// TupleType (ttype) below.
392	--newResult.tupleStart;
393	} else {
394	// collapse leftover arguments into tuple
395	newResult.endTuple( results );
396	argType = newResult.expr->result;
397	}
398	}
399
400	// check unification for ttype before adding to final
401	if (
402	unify(
403	ttype, argType, newResult.env, newResult.need, newResult.have,
404	newResult.open, symtab )
405	) {
406	finalResults.emplace_back( move( newResult ) );
407	}
408
409	continue;
410	}
411
412	// add each possible next argument
413	for ( std::size_t j = 0; j < args[nextArg].size(); ++j ) {
414	const ExplodedArg & expl = args[nextArg][j];
415
416	// fresh copies of parent parameters for this iteration
417	ast::TypeEnvironment env = results[i].env;
418	ast::OpenVarSet open = results[i].open;
419
420	env.addActual( expl.env, open );
421
422	// skip empty tuple arguments by (nearly) cloning parent into next gen
423	if ( expl.exprs.empty() ) {
424	results.emplace_back(
425	results[i], move( env ), copy( results[i].need ),
426	copy( results[i].have ), move( open ), nextArg + 1, expl.cost );
427
428	continue;
429	}
430
431	// add new result
432	results.emplace_back(
433	i, expl.exprs.front(), move( env ), copy( results[i].need ),
434	copy( results[i].have ), move( open ), nextArg + 1, nTuples,
435	expl.cost, expl.exprs.size() == 1 ? 0 : 1, j );
436	}
437	}
438
439	// reset for next round
440	genStart = genEnd;
441	nTuples = 0;
442	} while ( genEnd != results.size() );
443
444	// splice final results onto results
445	for ( std::size_t i = 0; i < finalResults.size(); ++i ) {
446	results.emplace_back( move( finalResults[i] ) );
447	}
448	return ! finalResults.empty();
449	}
450
451	// iterate each current subresult
452	std::size_t genEnd = results.size();
453	for ( std::size_t i = genStart; i < genEnd; ++i ) {
454	unsigned nextArg = results[i].nextArg;
455
456	// use remainder of exploded tuple if present
457	if ( results[i].hasExpl() ) {
458	const ExplodedArg & expl = results[i].getExpl( args );
459	const ast::Expr * expr = expl.exprs[ results[i].nextExpl ];
460
461	ast::TypeEnvironment env = results[i].env;
462	ast::AssertionSet need = results[i].need, have = results[i].have;
463	ast::OpenVarSet open = results[i].open;
464
465	const ast::Type * argType = expr->result;
466
467	PRINT(
468	std::cerr << "param type is ";
469	ast::print( std::cerr, paramType );
470	std::cerr << std::endl << "arg type is ";
471	ast::print( std::cerr, argType );
472	std::cerr << std::endl;
473	)
474
475	if ( unify( paramType, argType, env, need, have, open, symtab ) ) {
476	unsigned nextExpl = results[i].nextExpl + 1;
477	if ( nextExpl == expl.exprs.size() ) { nextExpl = 0; }
478
479	results.emplace_back(
480	i, expr, move( env ), move( need ), move( have ), move( open ), nextArg,
481	nTuples, Cost::zero, nextExpl, results[i].explAlt );
482	}
483
484	continue;
485	}
486
487	// use default initializers if out of arguments
488	if ( nextArg >= args.size() ) {
489	if ( const ast::ConstantExpr * cnst = getDefaultValue( init ) ) {
490	ast::TypeEnvironment env = results[i].env;
491	ast::AssertionSet need = results[i].need, have = results[i].have;
492	ast::OpenVarSet open = results[i].open;
493
494	if ( unify( paramType, cnst->result, env, need, have, open, symtab ) ) {
495	results.emplace_back(
496	i, new ast::DefaultArgExpr{ cnst->location, cnst }, move( env ),
497	move( need ), move( have ), move( open ), nextArg, nTuples );
498	}
499	}
500
501	continue;
502	}
503
504	// Check each possible next argument
505	for ( std::size_t j = 0; j < args[nextArg].size(); ++j ) {
506	const ExplodedArg & expl = args[nextArg][j];
507
508	// fresh copies of parent parameters for this iteration
509	ast::TypeEnvironment env = results[i].env;
510	ast::AssertionSet need = results[i].need, have = results[i].have;
511	ast::OpenVarSet open = results[i].open;
512
513	env.addActual( expl.env, open );
514
515	// skip empty tuple arguments by (nearly) cloning parent into next gen
516	if ( expl.exprs.empty() ) {
517	results.emplace_back(
518	results[i], move( env ), move( need ), move( have ), move( open ),
519	nextArg + 1, expl.cost );
520
521	continue;
522	}
523
524	// consider only first exploded arg
525	const ast::Expr * expr = expl.exprs.front();
526	const ast::Type * argType = expr->result;
527
528	PRINT(
529	std::cerr << "param type is ";
530	ast::print( std::cerr, paramType );
531	std::cerr << std::endl << "arg type is ";
532	ast::print( std::cerr, argType );
533	std::cerr << std::endl;
534	)
535
536	// attempt to unify types
537	if ( unify( paramType, argType, env, need, have, open, symtab ) ) {
538	// add new result
539	results.emplace_back(
540	i, expr, move( env ), move( need ), move( have ), move( open ),
541	nextArg + 1, nTuples, expl.cost, expl.exprs.size() == 1 ? 0 : 1, j );
542	}
543	}
544	}
545
546	// reset for next parameter
547	genStart = genEnd;
548
549	return genEnd != results.size(); // were any new results added?
550	}
551
552	/// Generate a cast expression from `arg` to `toType`
553	const ast::Expr * restructureCast(
554	ast::ptr< ast::Expr > & arg, const ast::Type * toType, ast::GeneratedFlag isGenerated = ast::GeneratedCast
555	) {
556	if (
557	arg->result->size() > 1
558	&& ! toType->isVoid()
559	&& ! dynamic_cast< const ast::ReferenceType * >( toType )
560	) {
561	// Argument is a tuple and the target type is neither void nor a reference. Cast each
562	// member of the tuple to its corresponding target type, producing the tuple of those
563	// cast expressions. If there are more components of the tuple than components in the
564	// target type, then excess components do not come out in the result expression (but
565	// UniqueExpr ensures that the side effects will still be produced)
566	if ( Tuples::maybeImpureIgnoreUnique( arg ) ) {
567	// expressions which may contain side effects require a single unique instance of
568	// the expression
569	arg = new ast::UniqueExpr{ arg->location, arg };
570	}
571	std::vector< ast::ptr< ast::Expr > > components;
572	for ( unsigned i = 0; i < toType->size(); ++i ) {
573	// cast each component
574	ast::ptr< ast::Expr > idx = new ast::TupleIndexExpr{ arg->location, arg, i };
575	components.emplace_back(
576	restructureCast( idx, toType->getComponent( i ), isGenerated ) );
577	}
578	return new ast::TupleExpr{ arg->location, move( components ) };
579	} else {
580	// handle normally
581	return new ast::CastExpr{ arg->location, arg, toType, isGenerated };
582	}
583	}
584
585	/// Gets the name from an untyped member expression (must be NameExpr)
586	const std::string & getMemberName( const ast::UntypedMemberExpr * memberExpr ) {
587	if ( memberExpr->member.as< ast::ConstantExpr >() ) {
588	SemanticError( memberExpr, "Indexed access to struct fields unsupported: " );
589	}
590
591	return memberExpr->member.strict_as< ast::NameExpr >()->name;
592	}
593
594	/// Actually visits expressions to find their candidate interpretations
595	class Finder final : public ast::WithShortCircuiting {
596	const ast::SymbolTable & symtab;
597	public:
598	static size_t traceId;
599	CandidateFinder & selfFinder;
600	CandidateList & candidates;
601	const ast::TypeEnvironment & tenv;
602	ast::ptr< ast::Type > & targetType;
603
604	enum Errors {
605	NotFound,
606	NoMatch,
607	ArgsToFew,
608	ArgsToMany,
609	RetsToFew,
610	RetsToMany,
611	NoReason
612	};
613
614	struct {
615	Errors code = NotFound;
616	} reason;
617
618	Finder( CandidateFinder & f )
619	: symtab( f.localSyms ), selfFinder( f ), candidates( f.candidates ), tenv( f.env ),
620	targetType( f.targetType ) {}
621
622	void previsit( const ast::Node * ) { visit_children = false; }
623
624	/// Convenience to add candidate to list
625	template<typename... Args>
626	void addCandidate( Args &&... args ) {
627	candidates.emplace_back( new Candidate{ std::forward<Args>( args )... } );
628	reason.code = NoReason;
629	}
630
631	void postvisit( const ast::ApplicationExpr * applicationExpr ) {
632	addCandidate( applicationExpr, tenv );
633	}
634
635	/// Set up candidate assertions for inference
636	void inferParameters( CandidateRef & newCand, CandidateList & out ) {
637	// Set need bindings for any unbound assertions
638	UniqueId crntResnSlot = 0; // matching ID for this expression's assertions
639	for ( auto & assn : newCand->need ) {
640	// skip already-matched assertions
641	if ( assn.second.resnSlot != 0 ) continue;
642	// assign slot for expression if needed
643	if ( crntResnSlot == 0 ) { crntResnSlot = ++globalResnSlot; }
644	// fix slot to assertion
645	assn.second.resnSlot = crntResnSlot;
646	}
647	// pair slot to expression
648	if ( crntResnSlot != 0 ) {
649	newCand->expr.get_and_mutate()->inferred.resnSlots().emplace_back( crntResnSlot );
650	}
651
652	// add to output list; assertion satisfaction will occur later
653	out.emplace_back( newCand );
654	}
655
656	/// Completes a function candidate with arguments located
657	void validateFunctionCandidate(
658	const CandidateRef & func, ArgPack & result, const std::vector< ArgPack > & results,
659	CandidateList & out
660	) {
661	ast::ApplicationExpr * appExpr =
662	new ast::ApplicationExpr{ func->expr->location, func->expr };
663	// sum cost and accumulate arguments
664	std::deque< const ast::Expr * > args;
665	Cost cost = func->cost;
666	const ArgPack * pack = &result;
667	while ( pack->expr ) {
668	args.emplace_front( pack->expr );
669	cost += pack->cost;
670	pack = &results[pack->parent];
671	}
672	std::vector< ast::ptr< ast::Expr > > vargs( args.begin(), args.end() );
673	appExpr->args = move( vargs );
674	// build and validate new candidate
675	auto newCand =
676	std::make_shared<Candidate>( appExpr, result.env, result.open, result.need, cost );
677	PRINT(
678	std::cerr << "instantiate function success: " << appExpr << std::endl;
679	std::cerr << "need assertions:" << std::endl;
680	ast::print( std::cerr, result.need, 2 );
681	)
682	inferParameters( newCand, out );
683	}
684
685	/// Builds a list of candidates for a function, storing them in out
686	void makeFunctionCandidates(
687	const CandidateRef & func, const ast::FunctionType * funcType,
688	const ExplodedArgs_new & args, CandidateList & out
689	) {
690	ast::OpenVarSet funcOpen;
691	ast::AssertionSet funcNeed, funcHave;
692	ast::TypeEnvironment funcEnv{ func->env };
693	makeUnifiableVars( funcType, funcOpen, funcNeed );
694	// add all type variables as open variables now so that those not used in the
695	// parameter list are still considered open
696	funcEnv.add( funcType->forall );
697
698	if ( targetType && ! targetType->isVoid() && ! funcType->returns.empty() ) {
699	// attempt to narrow based on expected target type
700	const ast::Type * returnType = funcType->returns.front();
701	if ( ! unify(
702	returnType, targetType, funcEnv, funcNeed, funcHave, funcOpen, symtab )
703	) {
704	// unification failed, do not pursue this candidate
705	return;
706	}
707	}
708
709	// iteratively build matches, one parameter at a time
710	std::vector< ArgPack > results;
711	results.emplace_back( funcEnv, funcNeed, funcHave, funcOpen );
712	std::size_t genStart = 0;
713
714	// xxx - how to handle default arg after change to ftype representation?
715	if (const ast::VariableExpr * varExpr = func->expr.as<ast::VariableExpr>()) {
716	if (const ast::FunctionDecl * funcDecl = varExpr->var.as<ast::FunctionDecl>()) {
717	// function may have default args only if directly calling by name
718	// must use types on candidate however, due to RenameVars substitution
719	auto nParams = funcType->params.size();
720
721	for (size_t i=0; i<nParams; ++i) {
722	auto obj = funcDecl->params[i].strict_as<ast::ObjectDecl>();
723	if (!instantiateArgument(
724	funcType->params[i], obj->init, args, results, genStart, symtab)) return;
725	}
726	goto endMatch;
727	}
728	}
729	for ( const auto & param : funcType->params ) {
730	// Try adding the arguments corresponding to the current parameter to the existing
731	// matches
732	// no default args for indirect calls
733	if ( ! instantiateArgument(
734	param, nullptr, args, results, genStart, symtab ) ) return;
735	}
736
737	endMatch:
738	if ( funcType->isVarArgs ) {
739	// append any unused arguments to vararg pack
740	std::size_t genEnd;
741	do {
742	genEnd = results.size();
743
744	// iterate results
745	for ( std::size_t i = genStart; i < genEnd; ++i ) {
746	unsigned nextArg = results[i].nextArg;
747
748	// use remainder of exploded tuple if present
749	if ( results[i].hasExpl() ) {
750	const ExplodedArg & expl = results[i].getExpl( args );
751
752	unsigned nextExpl = results[i].nextExpl + 1;
753	if ( nextExpl == expl.exprs.size() ) { nextExpl = 0; }
754
755	results.emplace_back(
756	i, expl.exprs[ results[i].nextExpl ], copy( results[i].env ),
757	copy( results[i].need ), copy( results[i].have ),
758	copy( results[i].open ), nextArg, 0, Cost::zero, nextExpl,
759	results[i].explAlt );
760
761	continue;
762	}
763
764	// finish result when out of arguments
765	if ( nextArg >= args.size() ) {
766	validateFunctionCandidate( func, results[i], results, out );
767
768	continue;
769	}
770
771	// add each possible next argument
772	for ( std::size_t j = 0; j < args[nextArg].size(); ++j ) {
773	const ExplodedArg & expl = args[nextArg][j];
774
775	// fresh copies of parent parameters for this iteration
776	ast::TypeEnvironment env = results[i].env;
777	ast::OpenVarSet open = results[i].open;
778
779	env.addActual( expl.env, open );
780
781	// skip empty tuple arguments by (nearly) cloning parent into next gen
782	if ( expl.exprs.empty() ) {
783	results.emplace_back(
784	results[i], move( env ), copy( results[i].need ),
785	copy( results[i].have ), move( open ), nextArg + 1,
786	expl.cost );
787
788	continue;
789	}
790
791	// add new result
792	results.emplace_back(
793	i, expl.exprs.front(), move( env ), copy( results[i].need ),
794	copy( results[i].have ), move( open ), nextArg + 1, 0, expl.cost,
795	expl.exprs.size() == 1 ? 0 : 1, j );
796	}
797	}
798
799	genStart = genEnd;
800	} while( genEnd != results.size() );
801	} else {
802	// filter out the results that don't use all the arguments
803	for ( std::size_t i = genStart; i < results.size(); ++i ) {
804	ArgPack & result = results[i];
805	if ( ! result.hasExpl() && result.nextArg >= args.size() ) {
806	validateFunctionCandidate( func, result, results, out );
807	}
808	}
809	}
810	}
811
812	/// Adds implicit struct-conversions to the alternative list
813	void addAnonConversions( const CandidateRef & cand ) {
814	// adds anonymous member interpretations whenever an aggregate value type is seen.
815	// it's okay for the aggregate expression to have reference type -- cast it to the
816	// base type to treat the aggregate as the referenced value
817	ast::ptr< ast::Expr > aggrExpr( cand->expr );
818	ast::ptr< ast::Type > & aggrType = aggrExpr.get_and_mutate()->result;
819	cand->env.apply( aggrType );
820
821	if ( aggrType.as< ast::ReferenceType >() ) {
822	aggrExpr = new ast::CastExpr{ aggrExpr, aggrType->stripReferences() };
823	}
824
825	if ( auto structInst = aggrExpr->result.as< ast::StructInstType >() ) {
826	addAggMembers( structInst, aggrExpr, *cand, Cost::safe, "" );
827	} else if ( auto unionInst = aggrExpr->result.as< ast::UnionInstType >() ) {
828	addAggMembers( unionInst, aggrExpr, *cand, Cost::safe, "" );
829	}
830	}
831
832	/// Adds aggregate member interpretations
833	void addAggMembers(
834	const ast::BaseInstType * aggrInst, const ast::Expr * expr,
835	const Candidate & cand, const Cost & addedCost, const std::string & name
836	) {
837	for ( const ast::Decl * decl : aggrInst->lookup( name ) ) {
838	auto dwt = strict_dynamic_cast< const ast::DeclWithType * >( decl );
839	CandidateRef newCand = std::make_shared<Candidate>(
840	cand, new ast::MemberExpr{ expr->location, dwt, expr }, addedCost );
841	// add anonymous member interpretations whenever an aggregate value type is seen
842	// as a member expression
843	addAnonConversions( newCand );
844	candidates.emplace_back( move( newCand ) );
845	}
846	}
847
848	/// Adds tuple member interpretations
849	void addTupleMembers(
850	const ast::TupleType * tupleType, const ast::Expr * expr, const Candidate & cand,
851	const Cost & addedCost, const ast::Expr * member
852	) {
853	if ( auto constantExpr = dynamic_cast< const ast::ConstantExpr * >( member ) ) {
854	// get the value of the constant expression as an int, must be between 0 and the
855	// length of the tuple to have meaning
856	long long val = constantExpr->intValue();
857	if ( val >= 0 && (unsigned long long)val < tupleType->size() ) {
858	addCandidate(
859	cand, new ast::TupleIndexExpr{ expr->location, expr, (unsigned)val },
860	addedCost );
861	}
862	}
863	}
864
865	void postvisit( const ast::UntypedExpr * untypedExpr ) {
866	CandidateFinder funcFinder{ symtab, tenv };
867	funcFinder.find( untypedExpr->func, ResolvMode::withAdjustment() );
868	// short-circuit if no candidates
869	if ( funcFinder.candidates.empty() ) return;
870
871	reason.code = NoMatch;
872
873	std::vector< CandidateFinder > argCandidates =
874	selfFinder.findSubExprs( untypedExpr->args );
875
876	// take care of possible tuple assignments
877	// if not tuple assignment, handled as normal function call
878	Tuples::handleTupleAssignment( selfFinder, untypedExpr, argCandidates );
879
880	// find function operators
881	ast::ptr< ast::Expr > opExpr = new ast::NameExpr{ untypedExpr->location, "?()" };
882	CandidateFinder opFinder{ symtab, tenv };
883	// okay if there aren't any function operations
884	opFinder.find( opExpr, ResolvMode::withoutFailFast() );
885	PRINT(
886	std::cerr << "known function ops:" << std::endl;
887	print( std::cerr, opFinder.candidates, 1 );
888	)
889
890	// pre-explode arguments
891	ExplodedArgs_new argExpansions;
892	for ( const CandidateFinder & args : argCandidates ) {
893	argExpansions.emplace_back();
894	auto & argE = argExpansions.back();
895	for ( const CandidateRef & arg : args ) { argE.emplace_back( *arg, symtab ); }
896	}
897
898	// Find function matches
899	CandidateList found;
900	SemanticErrorException errors;
901	for ( CandidateRef & func : funcFinder ) {
902	try {
903	PRINT(
904	std::cerr << "working on alternative:" << std::endl;
905	print( std::cerr, *func, 2 );
906	)
907
908	// check if the type is a pointer to function
909	const ast::Type * funcResult = func->expr->result->stripReferences();
910	if ( auto pointer = dynamic_cast< const ast::PointerType * >( funcResult ) ) {
911	if ( auto function = pointer->base.as< ast::FunctionType >() ) {
912	CandidateRef newFunc{ new Candidate{ *func } };
913	newFunc->expr =
914	referenceToRvalueConversion( newFunc->expr, newFunc->cost );
915	makeFunctionCandidates( newFunc, function, argExpansions, found );
916	}
917	} else if (
918	auto inst = dynamic_cast< const ast::TypeInstType * >( funcResult )
919	) {
920	if ( const ast::EqvClass * clz = func->env.lookup( inst->name ) ) {
921	if ( auto function = clz->bound.as< ast::FunctionType >() ) {
922	CandidateRef newFunc{ new Candidate{ *func } };
923	newFunc->expr =
924	referenceToRvalueConversion( newFunc->expr, newFunc->cost );
925	makeFunctionCandidates( newFunc, function, argExpansions, found );
926	}
927	}
928	}
929	} catch ( SemanticErrorException & e ) { errors.append( e ); }
930	}
931
932	// Find matches on function operators `?()`
933	if ( ! opFinder.candidates.empty() ) {
934	// add exploded function alternatives to front of argument list
935	std::vector< ExplodedArg > funcE;
936	funcE.reserve( funcFinder.candidates.size() );
937	for ( const CandidateRef & func : funcFinder ) {
938	funcE.emplace_back( *func, symtab );
939	}
940	argExpansions.emplace_front( move( funcE ) );
941
942	for ( const CandidateRef & op : opFinder ) {
943	try {
944	// check if type is pointer-to-function
945	const ast::Type * opResult = op->expr->result->stripReferences();
946	if ( auto pointer = dynamic_cast< const ast::PointerType * >( opResult ) ) {
947	if ( auto function = pointer->base.as< ast::FunctionType >() ) {
948	CandidateRef newOp{ new Candidate{ *op} };
949	newOp->expr =
950	referenceToRvalueConversion( newOp->expr, newOp->cost );
951	makeFunctionCandidates( newOp, function, argExpansions, found );
952	}
953	}
954	} catch ( SemanticErrorException & e ) { errors.append( e ); }
955	}
956	}
957
958	// Implement SFINAE; resolution errors are only errors if there aren't any non-error
959	// candidates
960	if ( found.empty() && ! errors.isEmpty() ) { throw errors; }
961
962	// Compute conversion costs
963	for ( CandidateRef & withFunc : found ) {
964	Cost cvtCost = computeApplicationConversionCost( withFunc, symtab );
965
966	PRINT(
967	auto appExpr = withFunc->expr.strict_as< ast::ApplicationExpr >();
968	auto pointer = appExpr->func->result.strict_as< ast::PointerType >();
969	auto function = pointer->base.strict_as< ast::FunctionType >();
970
971	std::cerr << "Case +++++++++++++ " << appExpr->func << std::endl;
972	std::cerr << "parameters are:" << std::endl;
973	ast::printAll( std::cerr, function->params, 2 );
974	std::cerr << "arguments are:" << std::endl;
975	ast::printAll( std::cerr, appExpr->args, 2 );
976	std::cerr << "bindings are:" << std::endl;
977	ast::print( std::cerr, withFunc->env, 2 );
978	std::cerr << "cost is: " << withFunc->cost << std::endl;
979	std::cerr << "cost of conversion is:" << cvtCost << std::endl;
980	)
981
982	if ( cvtCost != Cost::infinity ) {
983	withFunc->cvtCost = cvtCost;
984	candidates.emplace_back( move( withFunc ) );
985	}
986	}
987	found = move( candidates );
988
989	// use a new list so that candidates are not examined by addAnonConversions twice
990	CandidateList winners = findMinCost( found );
991	promoteCvtCost( winners );
992
993	// function may return a struct/union value, in which case we need to add candidates
994	// for implicit conversions to each of the anonymous members, which must happen after
995	// `findMinCost`, since anon conversions are never the cheapest
996	for ( const CandidateRef & c : winners ) {
997	addAnonConversions( c );
998	}
999	spliceBegin( candidates, winners );
1000
1001	if ( candidates.empty() && targetType && ! targetType->isVoid() ) {
1002	// If resolution is unsuccessful with a target type, try again without, since it
1003	// will sometimes succeed when it wouldn't with a target type binding.
1004	// For example:
1005	// forall( otype T ) T & ?[]( T *, ptrdiff_t );
1006	// const char * x = "hello world";
1007	// unsigned char ch = x[0];
1008	// Fails with simple return type binding (xxx -- check this!) as follows:
1009	// * T is bound to unsigned char
1010	// * (x: const char ) is unified with unsigned char , which fails
1011	// xxx -- fix this better
1012	targetType = nullptr;
1013	postvisit( untypedExpr );
1014	}
1015	}
1016
1017	/// true if expression is an lvalue
1018	static bool isLvalue( const ast::Expr * x ) {
1019	return x->result && ( x->get_lvalue() \|\| x->result.as< ast::ReferenceType >() );
1020	}
1021
1022	void postvisit( const ast::AddressExpr * addressExpr ) {
1023	CandidateFinder finder{ symtab, tenv };
1024	finder.find( addressExpr->arg );
1025
1026	if( finder.candidates.empty() ) return;
1027
1028	reason.code = NoMatch;
1029
1030	for ( CandidateRef & r : finder.candidates ) {
1031	if ( ! isLvalue( r->expr ) ) continue;
1032	addCandidate( *r, new ast::AddressExpr{ addressExpr->location, r->expr } );
1033	}
1034	}
1035
1036	void postvisit( const ast::LabelAddressExpr * labelExpr ) {
1037	addCandidate( labelExpr, tenv );
1038	}
1039
1040	void postvisit( const ast::CastExpr * castExpr ) {
1041	ast::ptr< ast::Type > toType = castExpr->result;
1042	assert( toType );
1043	toType = resolveTypeof( toType, symtab );
1044	toType = SymTab::validateType( castExpr->location, toType, symtab );
1045	toType = adjustExprType( toType, tenv, symtab );
1046
1047	CandidateFinder finder{ symtab, tenv, toType };
1048	finder.find( castExpr->arg, ResolvMode::withAdjustment() );
1049
1050	if( !finder.candidates.empty() ) reason.code = NoMatch;
1051
1052	CandidateList matches;
1053	for ( CandidateRef & cand : finder.candidates ) {
1054	ast::AssertionSet need( cand->need.begin(), cand->need.end() ), have;
1055	ast::OpenVarSet open( cand->open );
1056
1057	cand->env.extractOpenVars( open );
1058
1059	// It is possible that a cast can throw away some values in a multiply-valued
1060	// expression, e.g. cast-to-void, one value to zero. Figure out the prefix of the
1061	// subexpression results that are cast directly. The candidate is invalid if it
1062	// has fewer results than there are types to cast to.
1063	int discardedValues = cand->expr->result->size() - toType->size();
1064	if ( discardedValues < 0 ) continue;
1065
1066	// unification run for side-effects
1067	unify( toType, cand->expr->result, cand->env, need, have, open, symtab );
1068	Cost thisCost = castCost( cand->expr->result, toType, cand->expr->get_lvalue(),
1069	symtab, cand->env );
1070	PRINT(
1071	std::cerr << "working on cast with result: " << toType << std::endl;
1072	std::cerr << "and expr type: " << cand->expr->result << std::endl;
1073	std::cerr << "env: " << cand->env << std::endl;
1074	)
1075	if ( thisCost != Cost::infinity ) {
1076	PRINT(
1077	std::cerr << "has finite cost." << std::endl;
1078	)
1079	// count one safe conversion for each value that is thrown away
1080	thisCost.incSafe( discardedValues );
1081	CandidateRef newCand = std::make_shared<Candidate>(
1082	restructureCast( cand->expr, toType, castExpr->isGenerated ),
1083	copy( cand->env ), move( open ), move( need ), cand->cost,
1084	cand->cost + thisCost );
1085	inferParameters( newCand, matches );
1086	}
1087	}
1088
1089	// select first on argument cost, then conversion cost
1090	CandidateList minArgCost = findMinCost( matches );
1091	promoteCvtCost( minArgCost );
1092	candidates = findMinCost( minArgCost );
1093	}
1094
1095	void postvisit( const ast::VirtualCastExpr * castExpr ) {
1096	assertf( castExpr->result, "Implicit virtual cast targets not yet supported." );
1097	CandidateFinder finder{ symtab, tenv };
1098	// don't prune here, all alternatives guaranteed to have same type
1099	finder.find( castExpr->arg, ResolvMode::withoutPrune() );
1100	for ( CandidateRef & r : finder.candidates ) {
1101	addCandidate(
1102	*r,
1103	new ast::VirtualCastExpr{ castExpr->location, r->expr, castExpr->result } );
1104	}
1105	}
1106
1107	void postvisit( const ast::KeywordCastExpr * castExpr ) {
1108	const auto & loc = castExpr->location;
1109	assertf( castExpr->result, "Cast target should have been set in Validate." );
1110	auto ref = castExpr->result.strict_as<ast::ReferenceType>();
1111	auto inst = ref->base.strict_as<ast::StructInstType>();
1112	auto target = inst->base.get();
1113
1114	CandidateFinder finder{ symtab, tenv };
1115
1116	auto pick_alternatives = [target, this](CandidateList & found, bool expect_ref) {
1117	for(auto & cand : found) {
1118	const ast::Type * expr = cand->expr->result.get();
1119	if(expect_ref) {
1120	auto res = dynamic_cast<const ast::ReferenceType*>(expr);
1121	if(!res) { continue; }
1122	expr = res->base.get();
1123	}
1124
1125	if(auto insttype = dynamic_cast<const ast::TypeInstType*>(expr)) {
1126	auto td = cand->env.lookup(insttype->name);
1127	if(!td) { continue; }
1128	expr = td->bound.get();
1129	}
1130
1131	if(auto base = dynamic_cast<const ast::StructInstType*>(expr)) {
1132	if(base->base == target) {
1133	candidates.push_back( std::move(cand) );
1134	reason.code = NoReason;
1135	}
1136	}
1137	}
1138	};
1139
1140	try {
1141	// Attempt 1 : turn (thread&)X into ($thread&)X.__thrd
1142	// Clone is purely for memory management
1143	std::unique_ptr<const ast::Expr> tech1 { new ast::UntypedMemberExpr(loc, new ast::NameExpr(loc, castExpr->concrete_target.field), castExpr->arg) };
1144
1145	// don't prune here, since it's guaranteed all alternatives will have the same type
1146	finder.find( tech1.get(), ResolvMode::withoutPrune() );
1147	pick_alternatives(finder.candidates, false);
1148
1149	return;
1150	} catch(SemanticErrorException & ) {}
1151
1152	// Fallback : turn (thread&)X into ($thread&)get_thread(X)
1153	std::unique_ptr<const ast::Expr> fallback { ast::UntypedExpr::createDeref(loc, new ast::UntypedExpr(loc, new ast::NameExpr(loc, castExpr->concrete_target.getter), { castExpr->arg })) };
1154	// don't prune here, since it's guaranteed all alternatives will have the same type
1155	finder.find( fallback.get(), ResolvMode::withoutPrune() );
1156
1157	pick_alternatives(finder.candidates, true);
1158
1159	// Whatever happens here, we have no more fallbacks
1160	}
1161
1162	void postvisit( const ast::UntypedMemberExpr * memberExpr ) {
1163	CandidateFinder aggFinder{ symtab, tenv };
1164	aggFinder.find( memberExpr->aggregate, ResolvMode::withAdjustment() );
1165	for ( CandidateRef & agg : aggFinder.candidates ) {
1166	// it's okay for the aggregate expression to have reference type -- cast it to the
1167	// base type to treat the aggregate as the referenced value
1168	Cost addedCost = Cost::zero;
1169	agg->expr = referenceToRvalueConversion( agg->expr, addedCost );
1170
1171	// find member of the given type
1172	if ( auto structInst = agg->expr->result.as< ast::StructInstType >() ) {
1173	addAggMembers(
1174	structInst, agg->expr, *agg, addedCost, getMemberName( memberExpr ) );
1175	} else if ( auto unionInst = agg->expr->result.as< ast::UnionInstType >() ) {
1176	addAggMembers(
1177	unionInst, agg->expr, *agg, addedCost, getMemberName( memberExpr ) );
1178	} else if ( auto tupleType = agg->expr->result.as< ast::TupleType >() ) {
1179	addTupleMembers( tupleType, agg->expr, *agg, addedCost, memberExpr->member );
1180	}
1181	}
1182	}
1183
1184	void postvisit( const ast::MemberExpr * memberExpr ) {
1185	addCandidate( memberExpr, tenv );
1186	}
1187
1188	void postvisit( const ast::NameExpr * nameExpr ) {
1189	std::vector< ast::SymbolTable::IdData > declList = symtab.lookupId( nameExpr->name );
1190	PRINT( std::cerr << "nameExpr is " << nameExpr->name << std::endl; )
1191	if( declList.empty() ) return;
1192
1193	reason.code = NoMatch;
1194
1195	for ( auto & data : declList ) {
1196	Cost cost = Cost::zero;
1197	ast::Expr * newExpr = data.combine( nameExpr->location, cost );
1198
1199	CandidateRef newCand = std::make_shared<Candidate>(
1200	newExpr, copy( tenv ), ast::OpenVarSet{}, ast::AssertionSet{}, Cost::zero,
1201	cost );
1202	PRINT(
1203	std::cerr << "decl is ";
1204	ast::print( std::cerr, data.id );
1205	std::cerr << std::endl;
1206	std::cerr << "newExpr is ";
1207	ast::print( std::cerr, newExpr );
1208	std::cerr << std::endl;
1209	)
1210	newCand->expr = ast::mutate_field(
1211	newCand->expr.get(), &ast::Expr::result,
1212	renameTyVars( newCand->expr->result ) );
1213	// add anonymous member interpretations whenever an aggregate value type is seen
1214	// as a name expression
1215	addAnonConversions( newCand );
1216	candidates.emplace_back( move( newCand ) );
1217	}
1218	}
1219
1220	void postvisit( const ast::VariableExpr * variableExpr ) {
1221	// not sufficient to just pass `variableExpr` here, type might have changed since
1222	// creation
1223	addCandidate(
1224	new ast::VariableExpr{ variableExpr->location, variableExpr->var }, tenv );
1225	}
1226
1227	void postvisit( const ast::ConstantExpr * constantExpr ) {
1228	addCandidate( constantExpr, tenv );
1229	}
1230
1231	void postvisit( const ast::SizeofExpr * sizeofExpr ) {
1232	if ( sizeofExpr->type ) {
1233	addCandidate(
1234	new ast::SizeofExpr{
1235	sizeofExpr->location, resolveTypeof( sizeofExpr->type, symtab ) },
1236	tenv );
1237	} else {
1238	// find all candidates for the argument to sizeof
1239	CandidateFinder finder{ symtab, tenv };
1240	finder.find( sizeofExpr->expr );
1241	// find the lowest-cost candidate, otherwise ambiguous
1242	CandidateList winners = findMinCost( finder.candidates );
1243	if ( winners.size() != 1 ) {
1244	SemanticError(
1245	sizeofExpr->expr.get(), "Ambiguous expression in sizeof operand: " );
1246	}
1247	// return the lowest-cost candidate
1248	CandidateRef & choice = winners.front();
1249	choice->expr = referenceToRvalueConversion( choice->expr, choice->cost );
1250	choice->cost = Cost::zero;
1251	addCandidate( *choice, new ast::SizeofExpr{ sizeofExpr->location, choice->expr } );
1252	}
1253	}
1254
1255	void postvisit( const ast::AlignofExpr * alignofExpr ) {
1256	if ( alignofExpr->type ) {
1257	addCandidate(
1258	new ast::AlignofExpr{
1259	alignofExpr->location, resolveTypeof( alignofExpr->type, symtab ) },
1260	tenv );
1261	} else {
1262	// find all candidates for the argument to alignof
1263	CandidateFinder finder{ symtab, tenv };
1264	finder.find( alignofExpr->expr );
1265	// find the lowest-cost candidate, otherwise ambiguous
1266	CandidateList winners = findMinCost( finder.candidates );
1267	if ( winners.size() != 1 ) {
1268	SemanticError(
1269	alignofExpr->expr.get(), "Ambiguous expression in alignof operand: " );
1270	}
1271	// return the lowest-cost candidate
1272	CandidateRef & choice = winners.front();
1273	choice->expr = referenceToRvalueConversion( choice->expr, choice->cost );
1274	choice->cost = Cost::zero;
1275	addCandidate(
1276	*choice, new ast::AlignofExpr{ alignofExpr->location, choice->expr } );
1277	}
1278	}
1279
1280	void postvisit( const ast::UntypedOffsetofExpr * offsetofExpr ) {
1281	const ast::BaseInstType * aggInst;
1282	if (( aggInst = offsetofExpr->type.as< ast::StructInstType >() )) ;
1283	else if (( aggInst = offsetofExpr->type.as< ast::UnionInstType >() )) ;
1284	else return;
1285
1286	for ( const ast::Decl * member : aggInst->lookup( offsetofExpr->member ) ) {
1287	auto dwt = strict_dynamic_cast< const ast::DeclWithType * >( member );
1288	addCandidate(
1289	new ast::OffsetofExpr{ offsetofExpr->location, aggInst, dwt }, tenv );
1290	}
1291	}
1292
1293	void postvisit( const ast::OffsetofExpr * offsetofExpr ) {
1294	addCandidate( offsetofExpr, tenv );
1295	}
1296
1297	void postvisit( const ast::OffsetPackExpr * offsetPackExpr ) {
1298	addCandidate( offsetPackExpr, tenv );
1299	}
1300
1301	void postvisit( const ast::LogicalExpr * logicalExpr ) {
1302	CandidateFinder finder1{ symtab, tenv };
1303	finder1.find( logicalExpr->arg1, ResolvMode::withAdjustment() );
1304	if ( finder1.candidates.empty() ) return;
1305
1306	CandidateFinder finder2{ symtab, tenv };
1307	finder2.find( logicalExpr->arg2, ResolvMode::withAdjustment() );
1308	if ( finder2.candidates.empty() ) return;
1309
1310	reason.code = NoMatch;
1311
1312	for ( const CandidateRef & r1 : finder1.candidates ) {
1313	for ( const CandidateRef & r2 : finder2.candidates ) {
1314	ast::TypeEnvironment env{ r1->env };
1315	env.simpleCombine( r2->env );
1316	ast::OpenVarSet open{ r1->open };
1317	mergeOpenVars( open, r2->open );
1318	ast::AssertionSet need;
1319	mergeAssertionSet( need, r1->need );
1320	mergeAssertionSet( need, r2->need );
1321
1322	addCandidate(
1323	new ast::LogicalExpr{
1324	logicalExpr->location, r1->expr, r2->expr, logicalExpr->isAnd },
1325	move( env ), move( open ), move( need ), r1->cost + r2->cost );
1326	}
1327	}
1328	}
1329
1330	void postvisit( const ast::ConditionalExpr * conditionalExpr ) {
1331	// candidates for condition
1332	CandidateFinder finder1{ symtab, tenv };
1333	finder1.find( conditionalExpr->arg1, ResolvMode::withAdjustment() );
1334	if ( finder1.candidates.empty() ) return;
1335
1336	// candidates for true result
1337	CandidateFinder finder2{ symtab, tenv };
1338	finder2.find( conditionalExpr->arg2, ResolvMode::withAdjustment() );
1339	if ( finder2.candidates.empty() ) return;
1340
1341	// candidates for false result
1342	CandidateFinder finder3{ symtab, tenv };
1343	finder3.find( conditionalExpr->arg3, ResolvMode::withAdjustment() );
1344	if ( finder3.candidates.empty() ) return;
1345
1346	reason.code = NoMatch;
1347
1348	for ( const CandidateRef & r1 : finder1.candidates ) {
1349	for ( const CandidateRef & r2 : finder2.candidates ) {
1350	for ( const CandidateRef & r3 : finder3.candidates ) {
1351	ast::TypeEnvironment env{ r1->env };
1352	env.simpleCombine( r2->env );
1353	env.simpleCombine( r3->env );
1354	ast::OpenVarSet open{ r1->open };
1355	mergeOpenVars( open, r2->open );
1356	mergeOpenVars( open, r3->open );
1357	ast::AssertionSet need;
1358	mergeAssertionSet( need, r1->need );
1359	mergeAssertionSet( need, r2->need );
1360	mergeAssertionSet( need, r3->need );
1361	ast::AssertionSet have;
1362
1363	// unify true and false results, then infer parameters to produce new
1364	// candidates
1365	ast::ptr< ast::Type > common;
1366	if (
1367	unify(
1368	r2->expr->result, r3->expr->result, env, need, have, open, symtab,
1369	common )
1370	) {
1371	// generate typed expression
1372	ast::ConditionalExpr * newExpr = new ast::ConditionalExpr{
1373	conditionalExpr->location, r1->expr, r2->expr, r3->expr };
1374	newExpr->result = common ? common : r2->expr->result;
1375	// convert both options to result type
1376	Cost cost = r1->cost + r2->cost + r3->cost;
1377	newExpr->arg2 = computeExpressionConversionCost(
1378	newExpr->arg2, newExpr->result, symtab, env, cost );
1379	newExpr->arg3 = computeExpressionConversionCost(
1380	newExpr->arg3, newExpr->result, symtab, env, cost );
1381	// output candidate
1382	CandidateRef newCand = std::make_shared<Candidate>(
1383	newExpr, move( env ), move( open ), move( need ), cost );
1384	inferParameters( newCand, candidates );
1385	}
1386	}
1387	}
1388	}
1389	}
1390
1391	void postvisit( const ast::CommaExpr * commaExpr ) {
1392	ast::TypeEnvironment env{ tenv };
1393	ast::ptr< ast::Expr > arg1 = resolveInVoidContext( commaExpr->arg1, symtab, env );
1394
1395	CandidateFinder finder2{ symtab, env };
1396	finder2.find( commaExpr->arg2, ResolvMode::withAdjustment() );
1397
1398	for ( const CandidateRef & r2 : finder2.candidates ) {
1399	addCandidate( *r2, new ast::CommaExpr{ commaExpr->location, arg1, r2->expr } );
1400	}
1401	}
1402
1403	void postvisit( const ast::ImplicitCopyCtorExpr * ctorExpr ) {
1404	addCandidate( ctorExpr, tenv );
1405	}
1406
1407	void postvisit( const ast::ConstructorExpr * ctorExpr ) {
1408	CandidateFinder finder{ symtab, tenv };
1409	finder.find( ctorExpr->callExpr, ResolvMode::withoutPrune() );
1410	for ( CandidateRef & r : finder.candidates ) {
1411	addCandidate( *r, new ast::ConstructorExpr{ ctorExpr->location, r->expr } );
1412	}
1413	}
1414
1415	void postvisit( const ast::RangeExpr * rangeExpr ) {
1416	// resolve low and high, accept candidates where low and high types unify
1417	CandidateFinder finder1{ symtab, tenv };
1418	finder1.find( rangeExpr->low, ResolvMode::withAdjustment() );
1419	if ( finder1.candidates.empty() ) return;
1420
1421	CandidateFinder finder2{ symtab, tenv };
1422	finder2.find( rangeExpr->high, ResolvMode::withAdjustment() );
1423	if ( finder2.candidates.empty() ) return;
1424
1425	reason.code = NoMatch;
1426
1427	for ( const CandidateRef & r1 : finder1.candidates ) {
1428	for ( const CandidateRef & r2 : finder2.candidates ) {
1429	ast::TypeEnvironment env{ r1->env };
1430	env.simpleCombine( r2->env );
1431	ast::OpenVarSet open{ r1->open };
1432	mergeOpenVars( open, r2->open );
1433	ast::AssertionSet need;
1434	mergeAssertionSet( need, r1->need );
1435	mergeAssertionSet( need, r2->need );
1436	ast::AssertionSet have;
1437
1438	ast::ptr< ast::Type > common;
1439	if (
1440	unify(
1441	r1->expr->result, r2->expr->result, env, need, have, open, symtab,
1442	common )
1443	) {
1444	// generate new expression
1445	ast::RangeExpr * newExpr =
1446	new ast::RangeExpr{ rangeExpr->location, r1->expr, r2->expr };
1447	newExpr->result = common ? common : r1->expr->result;
1448	// add candidate
1449	CandidateRef newCand = std::make_shared<Candidate>(
1450	newExpr, move( env ), move( open ), move( need ),
1451	r1->cost + r2->cost );
1452	inferParameters( newCand, candidates );
1453	}
1454	}
1455	}
1456	}
1457
1458	void postvisit( const ast::UntypedTupleExpr * tupleExpr ) {
1459	std::vector< CandidateFinder > subCandidates =
1460	selfFinder.findSubExprs( tupleExpr->exprs );
1461	std::vector< CandidateList > possibilities;
1462	combos( subCandidates.begin(), subCandidates.end(), back_inserter( possibilities ) );
1463
1464	for ( const CandidateList & subs : possibilities ) {
1465	std::vector< ast::ptr< ast::Expr > > exprs;
1466	exprs.reserve( subs.size() );
1467	for ( const CandidateRef & sub : subs ) { exprs.emplace_back( sub->expr ); }
1468
1469	ast::TypeEnvironment env;
1470	ast::OpenVarSet open;
1471	ast::AssertionSet need;
1472	for ( const CandidateRef & sub : subs ) {
1473	env.simpleCombine( sub->env );
1474	mergeOpenVars( open, sub->open );
1475	mergeAssertionSet( need, sub->need );
1476	}
1477
1478	addCandidate(
1479	new ast::TupleExpr{ tupleExpr->location, move( exprs ) },
1480	move( env ), move( open ), move( need ), sumCost( subs ) );
1481	}
1482	}
1483
1484	void postvisit( const ast::TupleExpr * tupleExpr ) {
1485	addCandidate( tupleExpr, tenv );
1486	}
1487
1488	void postvisit( const ast::TupleIndexExpr * tupleExpr ) {
1489	addCandidate( tupleExpr, tenv );
1490	}
1491
1492	void postvisit( const ast::TupleAssignExpr * tupleExpr ) {
1493	addCandidate( tupleExpr, tenv );
1494	}
1495
1496	void postvisit( const ast::UniqueExpr * unqExpr ) {
1497	CandidateFinder finder{ symtab, tenv };
1498	finder.find( unqExpr->expr, ResolvMode::withAdjustment() );
1499	for ( CandidateRef & r : finder.candidates ) {
1500	// ensure that the the id is passed on so that the expressions are "linked"
1501	addCandidate( *r, new ast::UniqueExpr{ unqExpr->location, r->expr, unqExpr->id } );
1502	}
1503	}
1504
1505	void postvisit( const ast::StmtExpr * stmtExpr ) {
1506	addCandidate( resolveStmtExpr( stmtExpr, symtab ), tenv );
1507	}
1508
1509	void postvisit( const ast::UntypedInitExpr * initExpr ) {
1510	// handle each option like a cast
1511	CandidateList matches;
1512	PRINT(
1513	std::cerr << "untyped init expr: " << initExpr << std::endl;
1514	)
1515	// O(n^2) checks of d-types with e-types
1516	for ( const ast::InitAlternative & initAlt : initExpr->initAlts ) {
1517	// calculate target type
1518	const ast::Type * toType = resolveTypeof( initAlt.type, symtab );
1519	toType = SymTab::validateType( initExpr->location, toType, symtab );
1520	toType = adjustExprType( toType, tenv, symtab );
1521	// The call to find must occur inside this loop, otherwise polymorphic return
1522	// types are not bound to the initialization type, since return type variables are
1523	// only open for the duration of resolving the UntypedExpr.
1524	CandidateFinder finder{ symtab, tenv, toType };
1525	finder.find( initExpr->expr, ResolvMode::withAdjustment() );
1526	for ( CandidateRef & cand : finder.candidates ) {
1527	if(reason.code == NotFound) reason.code = NoMatch;
1528
1529	ast::TypeEnvironment env{ cand->env };
1530	ast::AssertionSet need( cand->need.begin(), cand->need.end() ), have;
1531	ast::OpenVarSet open{ cand->open };
1532
1533	PRINT(
1534	std::cerr << " @ " << toType << " " << initAlt.designation << std::endl;
1535	)
1536
1537	// It is possible that a cast can throw away some values in a multiply-valued
1538	// expression, e.g. cast-to-void, one value to zero. Figure out the prefix of
1539	// the subexpression results that are cast directly. The candidate is invalid
1540	// if it has fewer results than there are types to cast to.
1541	int discardedValues = cand->expr->result->size() - toType->size();
1542	if ( discardedValues < 0 ) continue;
1543
1544	// unification run for side-effects
1545	unify( toType, cand->expr->result, env, need, have, open, symtab );
1546	Cost thisCost = computeConversionCost( cand->expr->result, toType, cand->expr->get_lvalue(),
1547	symtab, env );
1548
1549	if ( thisCost != Cost::infinity ) {
1550	// count one safe conversion for each value that is thrown away
1551	thisCost.incSafe( discardedValues );
1552	CandidateRef newCand = std::make_shared<Candidate>(
1553	new ast::InitExpr{
1554	initExpr->location, restructureCast( cand->expr, toType ),
1555	initAlt.designation },
1556	move(env), move( open ), move( need ), cand->cost, thisCost );
1557	inferParameters( newCand, matches );
1558	}
1559	}
1560	}
1561
1562	// select first on argument cost, then conversion cost
1563	CandidateList minArgCost = findMinCost( matches );
1564	promoteCvtCost( minArgCost );
1565	candidates = findMinCost( minArgCost );
1566	}
1567
1568	void postvisit( const ast::InitExpr * ) {
1569	assertf( false, "CandidateFinder should never see a resolved InitExpr." );
1570	}
1571
1572	void postvisit( const ast::DeletedExpr * ) {
1573	assertf( false, "CandidateFinder should never see a DeletedExpr." );
1574	}
1575
1576	void postvisit( const ast::GenericExpr * ) {
1577	assertf( false, "_Generic is not yet supported." );
1578	}
1579	};
1580
1581	// size_t Finder::traceId = Stats::Heap::new_stacktrace_id("Finder");
1582	/// Prunes a list of candidates down to those that have the minimum conversion cost for a given
1583	/// return type. Skips ambiguous candidates.
1584	CandidateList pruneCandidates( CandidateList & candidates ) {
1585	struct PruneStruct {
1586	CandidateRef candidate;
1587	bool ambiguous;
1588
1589	PruneStruct() = default;
1590	PruneStruct( const CandidateRef & c ) : candidate( c ), ambiguous( false ) {}
1591	};
1592
1593	// find lowest-cost candidate for each type
1594	std::unordered_map< std::string, PruneStruct > selected;
1595	for ( CandidateRef & candidate : candidates ) {
1596	std::string mangleName;
1597	{
1598	ast::ptr< ast::Type > newType = candidate->expr->result;
1599	assertf(candidate->expr->result, "Result of expression %p for candidate is null", candidate->expr.get());
1600	candidate->env.apply( newType );
1601	mangleName = Mangle::mangle( newType );
1602	}
1603
1604	auto found = selected.find( mangleName );
1605	if ( found != selected.end() ) {
1606	if ( candidate->cost < found->second.candidate->cost ) {
1607	PRINT(
1608	std::cerr << "cost " << candidate->cost << " beats "
1609	<< found->second.candidate->cost << std::endl;
1610	)
1611
1612	found->second = PruneStruct{ candidate };
1613	} else if ( candidate->cost == found->second.candidate->cost ) {
1614	// if one of the candidates contains a deleted identifier, can pick the other,
1615	// since deleted expressions should not be ambiguous if there is another option
1616	// that is at least as good
1617	if ( findDeletedExpr( candidate->expr ) ) {
1618	// do nothing
1619	PRINT( std::cerr << "candidate is deleted" << std::endl; )
1620	} else if ( findDeletedExpr( found->second.candidate->expr ) ) {
1621	PRINT( std::cerr << "current is deleted" << std::endl; )
1622	found->second = PruneStruct{ candidate };
1623	} else {
1624	PRINT( std::cerr << "marking ambiguous" << std::endl; )
1625	found->second.ambiguous = true;
1626	}
1627	} else {
1628	PRINT(
1629	std::cerr << "cost " << candidate->cost << " loses to "
1630	<< found->second.candidate->cost << std::endl;
1631	)
1632	}
1633	} else {
1634	selected.emplace_hint( found, mangleName, candidate );
1635	}
1636	}
1637
1638	// report unambiguous min-cost candidates
1639	CandidateList out;
1640	for ( auto & target : selected ) {
1641	if ( target.second.ambiguous ) continue;
1642
1643	CandidateRef cand = target.second.candidate;
1644
1645	ast::ptr< ast::Type > newResult = cand->expr->result;
1646	cand->env.applyFree( newResult );
1647	cand->expr = ast::mutate_field(
1648	cand->expr.get(), &ast::Expr::result, move( newResult ) );
1649
1650	out.emplace_back( cand );
1651	}
1652	return out;
1653	}
1654
1655	} // anonymous namespace
1656
1657	void CandidateFinder::find( const ast::Expr * expr, ResolvMode mode ) {
1658	// Find alternatives for expression
1659	ast::Pass<Finder> finder{ *this };
1660	expr->accept( finder );
1661
1662	if ( mode.failFast && candidates.empty() ) {
1663	switch(finder.core.reason.code) {
1664	case Finder::NotFound:
1665	{ SemanticError( expr, "No alternatives for expression " ); break; }
1666	case Finder::NoMatch:
1667	{ SemanticError( expr, "Invalid application of existing declaration(s) in expression " ); break; }
1668	case Finder::ArgsToFew:
1669	case Finder::ArgsToMany:
1670	case Finder::RetsToFew:
1671	case Finder::RetsToMany:
1672	case Finder::NoReason:
1673	default:
1674	{ SemanticError( expr->location, "No reasonable alternatives for expression : reasons unkown" ); }
1675	}
1676	}
1677
1678	if ( mode.satisfyAssns \|\| mode.prune ) {
1679	// trim candidates to just those where the assertions are satisfiable
1680	// - necessary pre-requisite to pruning
1681	CandidateList satisfied;
1682	std::vector< std::string > errors;
1683	for ( CandidateRef & candidate : candidates ) {
1684	satisfyAssertions( candidate, localSyms, satisfied, errors );
1685	}
1686
1687	// fail early if none such
1688	if ( mode.failFast && satisfied.empty() ) {
1689	std::ostringstream stream;
1690	stream << "No alternatives with satisfiable assertions for " << expr << "\n";
1691	for ( const auto& err : errors ) {
1692	stream << err;
1693	}
1694	SemanticError( expr->location, stream.str() );
1695	}
1696
1697	// reset candidates
1698	candidates = move( satisfied );
1699	}
1700
1701	if ( mode.prune ) {
1702	// trim candidates to single best one
1703	PRINT(
1704	std::cerr << "alternatives before prune:" << std::endl;
1705	print( std::cerr, candidates );
1706	)
1707
1708	CandidateList pruned = pruneCandidates( candidates );
1709
1710	if ( mode.failFast && pruned.empty() ) {
1711	std::ostringstream stream;
1712	CandidateList winners = findMinCost( candidates );
1713	stream << "Cannot choose between " << winners.size() << " alternatives for "
1714	"expression\n";
1715	ast::print( stream, expr );
1716	stream << " Alternatives are:\n";
1717	print( stream, winners, 1 );
1718	SemanticError( expr->location, stream.str() );
1719	}
1720
1721	auto oldsize = candidates.size();
1722	candidates = move( pruned );
1723
1724	PRINT(
1725	std::cerr << "there are " << oldsize << " alternatives before elimination" << std::endl;
1726	)
1727	PRINT(
1728	std::cerr << "there are " << candidates.size() << " alternatives after elimination"
1729	<< std::endl;
1730	)
1731	}
1732
1733	// adjust types after pruning so that types substituted by pruneAlternatives are correctly
1734	// adjusted
1735	if ( mode.adjust ) {
1736	for ( CandidateRef & r : candidates ) {
1737	r->expr = ast::mutate_field(
1738	r->expr.get(), &ast::Expr::result,
1739	adjustExprType( r->expr->result, r->env, localSyms ) );
1740	}
1741	}
1742
1743	// Central location to handle gcc extension keyword, etc. for all expressions
1744	for ( CandidateRef & r : candidates ) {
1745	if ( r->expr->extension != expr->extension ) {
1746	r->expr.get_and_mutate()->extension = expr->extension;
1747	}
1748	}
1749	}
1750
1751	std::vector< CandidateFinder > CandidateFinder::findSubExprs(
1752	const std::vector< ast::ptr< ast::Expr > > & xs
1753	) {
1754	std::vector< CandidateFinder > out;
1755
1756	for ( const auto & x : xs ) {
1757	out.emplace_back( localSyms, env );
1758	out.back().find( x, ResolvMode::withAdjustment() );
1759
1760	PRINT(
1761	std::cerr << "findSubExprs" << std::endl;
1762	print( std::cerr, out.back().candidates );
1763	)
1764	}
1765
1766	return out;
1767	}
1768
1769	} // namespace ResolvExpr
1770
1771	// Local Variables: //
1772	// tab-width: 4 //
1773	// mode: c++ //
1774	// compile-command: "make install" //
1775	// End: //

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