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source: src/GenPoly/Box.cpp @ 8a4e472

Last change on this file since 8a4e472 was c4b9fa9, checked in by Andrew Beach <ajbeach@…>, 7 months ago
Just some random clean-up in Box pass while I was musing.
Property mode set to `100644`
File size: 81.4 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	// Box.cpp -- Implement polymorphic function calls and types.
8	//
9	// Author : Andrew Beach
10	// Created On : Thr Oct 6 13:39:00 2022
11	// Last Modified By : Andrew Beach
12	// Last Modified On : Mon Oct 2 17:00:00 2023
13	// Update Count : 0
14	//
15
16	#include "Box.h"
17
18	#include "AST/Decl.hpp" // for Decl, FunctionDecl, ...
19	#include "AST/Expr.hpp" // for AlignofExpr, ConstantExpr, ...
20	#include "AST/Init.hpp" // for Init, SingleInit
21	#include "AST/Inspect.hpp" // for getFunctionName
22	#include "AST/Pass.hpp" // for Pass, WithDeclsToAdd, ...
23	#include "AST/Stmt.hpp" // for CompoundStmt, ExprStmt, ...
24	#include "AST/Vector.hpp" // for vector
25	#include "AST/GenericSubstitution.hpp" // for genericSubstitution
26	#include "CodeGen/OperatorTable.h" // for isAssignment
27	#include "Common/ScopedMap.h" // for ScopedMap
28	#include "Common/UniqueName.h" // for UniqueName
29	#include "Common/utility.h" // for toCString, group_iterate
30	#include "GenPoly/FindFunction.h" // for findFunction
31	#include "GenPoly/GenPoly.h" // for getFunctionType, ...
32	#include "GenPoly/Lvalue.h" // for generalizedLvalue
33	#include "GenPoly/ScopedSet.h" // for ScopedSet
34	#include "GenPoly/ScrubTypeVars.hpp" // for scrubTypeVars, scrubAllTypeVars
35	#include "ResolvExpr/Unify.h" // for typesCompatible
36	#include "SymTab/Mangler.h" // for mangle, mangleType
37
38	namespace GenPoly {
39
40	namespace {
41
42	/// The layout type is used to represent sizes, alignments and offsets.
43	ast::BasicType * makeLayoutType() {
44	return new ast::BasicType( ast::BasicType::LongUnsignedInt );
45	}
46
47	/// Fixed version of layout type (just adding a 'C' in C++ style).
48	ast::BasicType * makeLayoutCType() {
49	return new ast::BasicType( ast::BasicType::LongUnsignedInt,
50	ast::CV::Qualifiers( ast::CV::Const ) );
51	}
52
53	// --------------------------------------------------------------------------
54	/// Adds layout-generation functions to polymorphic types.
55	struct LayoutFunctionBuilder final :
56	public ast::WithDeclsToAdd<>,
57	public ast::WithShortCircuiting,
58	public ast::WithVisitorRef<LayoutFunctionBuilder> {
59	void previsit( ast::StructDecl const * decl );
60	void previsit( ast::UnionDecl const * decl );
61	};
62
63	/// Get all sized type declarations; those that affect a layout function.
64	ast::vector<ast::TypeDecl> takeSizedParams(
65	ast::vector<ast::TypeDecl> const & decls ) {
66	ast::vector<ast::TypeDecl> sizedParams;
67	for ( ast::ptr<ast::TypeDecl> const & decl : decls ) {
68	if ( decl->isComplete() ) {
69	sizedParams.emplace_back( decl );
70	}
71	}
72	return sizedParams;
73	}
74
75	/// Adds parameters for otype size and alignment to a function type.
76	void addSTypeParams(
77	ast::vector<ast::DeclWithType> & params,
78	ast::vector<ast::TypeDecl> const & sizedParams ) {
79	for ( ast::ptr<ast::TypeDecl> const & sizedParam : sizedParams ) {
80	ast::TypeInstType inst( sizedParam );
81	std::string paramName = Mangle::mangleType( &inst );
82	params.emplace_back( new ast::ObjectDecl(
83	sizedParam->location,
84	sizeofName( paramName ),
85	makeLayoutCType()
86	) );
87	params.emplace_back( new ast::ObjectDecl(
88	sizedParam->location,
89	alignofName( paramName ),
90	makeLayoutCType()
91	) );
92	}
93	}
94
95	ast::Type * makeLayoutOutType() {
96	return new ast::PointerType( makeLayoutType() );
97	}
98
99	struct LayoutData {
100	ast::FunctionDecl * function;
101	ast::ObjectDecl * sizeofParam;
102	ast::ObjectDecl * alignofParam;
103	ast::ObjectDecl * offsetofParam;
104	};
105
106	LayoutData buildLayoutFunction(
107	CodeLocation const & location, ast::AggregateDecl const * aggr,
108	ast::vector<ast::TypeDecl> const & sizedParams,
109	bool isInFunction, bool isStruct ) {
110	ast::ObjectDecl * sizeParam = new ast::ObjectDecl(
111	location,
112	sizeofName( aggr->name ),
113	makeLayoutOutType()
114	);
115	ast::ObjectDecl * alignParam = new ast::ObjectDecl(
116	location,
117	alignofName( aggr->name ),
118	makeLayoutOutType()
119	);
120	ast::ObjectDecl * offsetParam = nullptr;
121	ast::vector<ast::DeclWithType> params = { sizeParam, alignParam };
122	if ( isStruct ) {
123	offsetParam = new ast::ObjectDecl(
124	location,
125	offsetofName( aggr->name ),
126	makeLayoutOutType()
127	);
128	params.push_back( offsetParam );
129	}
130	addSTypeParams( params, sizedParams );
131
132	// Routines at global scope marked "static" to prevent multiple
133	// definitions is separate translation units because each unit generates
134	// copies of the default routines for each aggregate.
135	ast::FunctionDecl * layoutDecl = new ast::FunctionDecl(
136	location,
137	layoutofName( aggr ),
138	{}, // forall
139	{}, // assertions
140	std::move( params ),
141	{}, // returns
142	new ast::CompoundStmt( location ),
143	isInFunction ? ast::Storage::Classes() : ast::Storage::Static,
144	ast::Linkage::AutoGen,
145	{}, // attrs
146	ast::Function::Inline,
147	ast::FixedArgs
148	);
149	layoutDecl->fixUniqueId();
150	return LayoutData{ layoutDecl, sizeParam, alignParam, offsetParam };
151	}
152
153	/// Makes a binary operation.
154	ast::Expr * makeOp( CodeLocation const & location, std::string const & name,
155	ast::Expr const * lhs, ast::Expr const * rhs ) {
156	return new ast::UntypedExpr( location,
157	new ast::NameExpr( location, name ), { lhs, rhs } );
158	}
159
160	/// Make a binary operation and wrap it in a statement.
161	ast::Stmt * makeOpStmt( CodeLocation const & location, std::string const & name,
162	ast::Expr const * lhs, ast::Expr const * rhs ) {
163	return new ast::ExprStmt( location, makeOp( location, name, lhs, rhs ) );
164	}
165
166	/// Returns the dereference of a local pointer variable.
167	ast::Expr * derefVar(
168	CodeLocation const & location, ast::ObjectDecl const * var ) {
169	return ast::UntypedExpr::createDeref( location,
170	new ast::VariableExpr( location, var ) );
171	}
172
173	/// Makes an if-statement with a single-expression then and no else.
174	ast::Stmt * makeCond( CodeLocation const & location,
175	ast::Expr const * cond, ast::Expr const * thenPart ) {
176	return new ast::IfStmt( location,
177	cond, new ast::ExprStmt( location, thenPart ), nullptr );
178	}
179
180	/// Makes a statement that aligns lhs to rhs (rhs should be an integer
181	/// power of two).
182	ast::Stmt * makeAlignTo( CodeLocation const & location,
183	ast::Expr const * lhs, ast::Expr const * rhs ) {
184	// Check that the lhs is zeroed out to the level of rhs.
185	ast::Expr * ifCond = makeOp( location, "?&?", lhs,
186	makeOp( location, "?-?", rhs,
187	ast::ConstantExpr::from_ulong( location, 1 ) ) );
188	// If not aligned, increment to alignment.
189	ast::Expr * ifExpr = makeOp( location, "?+=?", ast::deepCopy( lhs ),
190	makeOp( location, "?-?", ast::deepCopy( rhs ),
191	ast::deepCopy( ifCond ) ) );
192	return makeCond( location, ifCond, ifExpr );
193	}
194
195	/// Makes a statement that assigns rhs to lhs if lhs < rhs.
196	ast::Stmt * makeAssignMax( CodeLocation const & location,
197	ast::Expr const * lhs, ast::Expr const * rhs ) {
198	return makeCond( location,
199	makeOp( location, "?<?", ast::deepCopy( lhs ), ast::deepCopy( rhs ) ),
200	makeOp( location, "?=?", lhs, rhs ) );
201	}
202
203	void LayoutFunctionBuilder::previsit( ast::StructDecl const * decl ) {
204	// Do not generate layout function for empty tag structures.
205	visit_children = false;
206	if ( decl->members.empty() ) return;
207
208	// Get parameters that can change layout, exiting early if none.
209	ast::vector<ast::TypeDecl> sizedParams =
210	takeSizedParams( decl->params );
211	if ( sizedParams.empty() ) return;
212
213	CodeLocation const & location = decl->location;
214
215	// Build layout function signature.
216	LayoutData layout = buildLayoutFunction(
217	location, decl, sizedParams, isInFunction(), true );
218	ast::FunctionDecl * layoutDecl = layout.function;
219	// Also return these or extract them from the parameter list?
220	ast::ObjectDecl const * sizeofParam = layout.sizeofParam;
221	ast::ObjectDecl const * alignofParam = layout.alignofParam;
222	ast::ObjectDecl const * offsetofParam = layout.offsetofParam;
223	assert( nullptr != layout.offsetofParam );
224
225	// Calculate structure layout in function body.
226	// Initialize size and alignment to 0 and 1
227	// (Will have at least one member to update size).
228	auto & kids = layoutDecl->stmts.get_and_mutate()->kids;
229	kids.emplace_back( makeOpStmt( location, "?=?",
230	derefVar( location, sizeofParam ),
231	ast::ConstantExpr::from_ulong( location, 0 )
232	) );
233	kids.emplace_back( makeOpStmt( location, "?=?",
234	derefVar( location, alignofParam ),
235	ast::ConstantExpr::from_ulong( location, 1 )
236	) );
237	// TODO: Polymorphic types will be out of the struct declaration scope.
238	// Should be removed by PolyGenericCalculator.
239	for ( auto const & member : enumerate( decl->members ) ) {
240	auto dwt = member.val.strict_as<ast::DeclWithType>();
241	ast::Type const * memberType = dwt->get_type();
242
243	if ( 0 < member.idx ) {
244	// Make sure all later members have padding to align them.
245	kids.emplace_back( makeAlignTo( location,
246	derefVar( location, sizeofParam ),
247	new ast::AlignofExpr( location, ast::deepCopy( memberType ) )
248	) );
249	}
250
251	// Place current size in the current offset index.
252	kids.emplace_back( makeOpStmt( location, "?=?",
253	makeOp( location, "?[?]",
254	new ast::VariableExpr( location, offsetofParam ),
255	ast::ConstantExpr::from_ulong( location, member.idx ) ),
256	derefVar( location, sizeofParam ) ) );
257
258	// Add member size to current size.
259	kids.emplace_back( makeOpStmt( location, "?+=?",
260	derefVar( location, sizeofParam ),
261	new ast::SizeofExpr( location, ast::deepCopy( memberType ) ) ) );
262
263	// Take max of member alignment and global alignment.
264	// (As align is always 2^n, this will always be a multiple of both.)
265	kids.emplace_back( makeAssignMax( location,
266	derefVar( location, alignofParam ),
267	new ast::AlignofExpr( location, ast::deepCopy( memberType ) ) ) );
268	}
269	// Make sure the type is end-padded to a multiple of its alignment.
270	kids.emplace_back( makeAlignTo( location,
271	derefVar( location, sizeofParam ),
272	derefVar( location, alignofParam ) ) );
273
274	declsToAddAfter.emplace_back( layoutDecl );
275	}
276
277	void LayoutFunctionBuilder::previsit( ast::UnionDecl const * decl ) {
278	visit_children = false;
279	// Do not generate layout function for empty tag unions.
280	if ( decl->members.empty() ) return;
281
282	// Get parameters that can change layout, exiting early if none.
283	ast::vector<ast::TypeDecl> sizedParams =
284	takeSizedParams( decl->params );
285	if ( sizedParams.empty() ) return;
286
287	CodeLocation const & location = decl->location;
288
289	// Build layout function signature.
290	LayoutData layout = buildLayoutFunction(
291	location, decl, sizedParams, isInFunction(), false );
292	ast::FunctionDecl * layoutDecl = layout.function;
293	// Also return these or extract them from the parameter list?
294	ast::ObjectDecl const * sizeofParam = layout.sizeofParam;
295	ast::ObjectDecl const * alignofParam = layout.alignofParam;
296	assert( nullptr == layout.offsetofParam );
297
298	// Calculate union layout in function body.
299	// Both are simply the maximum for union (actually align is always the
300	// LCM, but with powers of two that is also the maximum).
301	auto & kids = layoutDecl->stmts.get_and_mutate()->kids;
302	kids.emplace_back( makeOpStmt( location,
303	"?=?", derefVar( location, sizeofParam ),
304	ast::ConstantExpr::from_ulong( location, 1 )
305	) );
306	kids.emplace_back( makeOpStmt( location,
307	"?=?", derefVar( location, alignofParam ),
308	ast::ConstantExpr::from_ulong( location, 1 )
309	) );
310	// TODO: Polymorphic types will be out of the union declaration scope.
311	for ( auto const & member : decl->members ) {
312	auto dwt = member.strict_as<ast::DeclWithType>();
313	ast::Type const * memberType = dwt->get_type();
314
315	// Take max member size and global size.
316	kids.emplace_back( makeAssignMax( location,
317	derefVar( location, sizeofParam ),
318	new ast::SizeofExpr( location, ast::deepCopy( memberType ) )
319	) );
320
321	// Take max of member alignment and global alignment.
322	kids.emplace_back( makeAssignMax( location,
323	derefVar( location, alignofParam ),
324	new ast::AlignofExpr( location, ast::deepCopy( memberType ) )
325	) );
326	}
327	kids.emplace_back( makeAlignTo( location,
328	derefVar( location, sizeofParam ),
329	derefVar( location, alignofParam ) ) );
330
331	declsToAddAfter.emplace_back( layoutDecl );
332	}
333
334	// --------------------------------------------------------------------------
335	/// Application expression transformer.
336	/// * Replaces polymorphic return types with out-parameters.
337	/// * Replaces call to polymorphic functions with adapter calls which handles
338	/// dynamic arguments and return values.
339	/// * Adds appropriate type variables to the function calls.
340	struct CallAdapter final :
341	public ast::WithConstTypeSubstitution,
342	public ast::WithGuards,
343	public ast::WithShortCircuiting,
344	public ast::WithStmtsToAdd<>,
345	public ast::WithVisitorRef<CallAdapter> {
346	CallAdapter();
347
348	void previsit( ast::Decl const * decl );
349	ast::FunctionDecl const * previsit( ast::FunctionDecl const * decl );
350	void previsit( ast::TypeDecl const * decl );
351	void previsit( ast::CommaExpr const * expr );
352	ast::Expr const * postvisit( ast::ApplicationExpr const * expr );
353	ast::Expr const * postvisit( ast::UntypedExpr const * expr );
354	void previsit( ast::AddressExpr const * expr );
355	ast::Expr const * postvisit( ast::AddressExpr const * expr );
356	ast::ReturnStmt const * previsit( ast::ReturnStmt const * stmt );
357
358	void beginScope();
359	void endScope();
360	private:
361	// Many helpers here use a mutable ApplicationExpr as an in/out parameter
362	// instead of using the return value, to save on mutates and free up the
363	// return value.
364
365	/// Passes extra layout arguments for sized polymorphic type parameters.
366	ast::vector<ast::Expr>::iterator passTypeVars(
367	ast::ApplicationExpr * expr,
368	ast::FunctionType const * funcType );
369	/// Wraps a function application with a new temporary for the
370	/// out-parameter return value.
371	ast::Expr const * addRetParam(
372	ast::ApplicationExpr * expr, ast::Type const * retType );
373	/// Wraps a function application returning a polymorphic type with a new
374	/// temporary for the out-parameter return value.
375	ast::Expr const * addDynRetParam(
376	ast::ApplicationExpr * expr, ast::Type const * polyType );
377	/// Modify a call so it passes the function through the correct adapter.
378	ast::Expr const * applyAdapter(
379	ast::ApplicationExpr * expr,
380	ast::FunctionType const * function );
381	/// Convert a single argument into its boxed form to pass the parameter.
382	void boxParam( ast::ptr<ast::Expr> & arg,
383	ast::Type const * formal, TypeVarMap const & exprTyVars );
384	/// Box every argument from arg forward, matching the functionType
385	/// parameter list. arg should point into expr's argument list.
386	void boxParams(
387	ast::ApplicationExpr const * expr,
388	ast::vector<ast::Expr>::iterator arg,
389	ast::FunctionType const * function,
390	const TypeVarMap & typeVars );
391	/// Adds the inferred parameters derived from the assertions of the
392	/// expression to the call.
393	void addInferredParams(
394	ast::ApplicationExpr * expr,
395	ast::vector<ast::Expr>::iterator arg,
396	ast::FunctionType const * functionType,
397	const TypeVarMap & typeVars );
398	/// Stores assignment operators from assertion list in
399	/// local map of assignment operations.
400	void passAdapters(
401	ast::ApplicationExpr * expr,
402	ast::FunctionType const * type,
403	const TypeVarMap & typeVars );
404	/// Create an adapter function based on the type of the adaptee and the
405	/// real type with the type substitutions applied.
406	ast::FunctionDecl * makeAdapter(
407	ast::FunctionType const * adaptee,
408	ast::FunctionType const * realType,
409	std::string const & mangleName,
410	TypeVarMap const & typeVars,
411	CodeLocation const & location ) const;
412	/// Replaces intrinsic operator functions with their arithmetic desugaring.
413	ast::Expr const * handleIntrinsics( ast::ApplicationExpr const * );
414	/// Inserts a new temporary variable into the current scope with an
415	/// auto-generated name.
416	ast::ObjectDecl * makeTemporary(
417	CodeLocation const & location, ast::Type const * type );
418
419	TypeVarMap scopeTypeVars;
420	ScopedMap< std::string, ast::DeclWithType const * > adapters;
421	std::map< ast::ApplicationExpr const , ast::Expr const > retVals;
422	ast::DeclWithType const * retval;
423	UniqueName tmpNamer;
424	};
425
426	/// Replaces a polymorphic type with its concrete equivalant under the
427	/// current environment (returns itself if concrete).
428	/// If `doClone` is set to false, will not clone interior types
429	ast::Type const * replaceWithConcrete(
430	ast::Type const * type,
431	ast::TypeSubstitution const & typeSubs,
432	bool doCopy = true );
433
434	/// Replaces all the type parameters of a generic type with their
435	/// concrete equivalents under the current environment.
436	void replaceParametersWithConcrete(
437	ast::vector<ast::Expr> & params,
438	ast::TypeSubstitution const & typeSubs ) {
439	for ( ast::ptr<ast::Expr> & paramExpr : params ) {
440	ast::TypeExpr const * param = paramExpr.as<ast::TypeExpr>();
441	assertf( param, "Aggregate parameters should be type expressions." );
442	paramExpr = ast::mutate_field( param, &ast::TypeExpr::type,
443	replaceWithConcrete( param->type.get(), typeSubs, false ) );
444	}
445	}
446
447	ast::Type const * replaceWithConcrete(
448	ast::Type const * type,
449	ast::TypeSubstitution const & typeSubs,
450	bool doCopy ) {
451	if ( auto instType = dynamic_cast<ast::TypeInstType const *>( type ) ) {
452	ast::Type const * concrete = typeSubs.lookup( instType );
453	return ( nullptr != concrete ) ? concrete : instType;
454	} else if ( auto structType =
455	dynamic_cast<ast::StructInstType const *>( type ) ) {
456	ast::StructInstType * newType =
457	doCopy ? ast::deepCopy( structType ) : ast::mutate( structType );
458	replaceParametersWithConcrete( newType->params, typeSubs );
459	return newType;
460	} else if ( auto unionType =
461	dynamic_cast<ast::UnionInstType const *>( type ) ) {
462	ast::UnionInstType * newType =
463	doCopy ? ast::deepCopy( unionType ) : ast::mutate( unionType );
464	replaceParametersWithConcrete( newType->params, typeSubs );
465	return newType;
466	} else {
467	return type;
468	}
469	}
470
471	std::string makePolyMonoSuffix(
472	ast::FunctionType const * function,
473	TypeVarMap const & typeVars ) {
474	// If the return type or a parameter type involved polymorphic types,
475	// then the adapter will need to take those polymorphic types as pointers.
476	// Therefore, there can be two different functions with the same mangled
477	// name, so we need to further mangle the names.
478	std::stringstream name;
479	for ( auto ret : function->returns ) {
480	name << ( isPolyType( ret, typeVars ) ? 'P' : 'M' );
481	}
482	name << '_';
483	for ( auto arg : function->params ) {
484	name << ( isPolyType( arg, typeVars ) ? 'P' : 'M' );
485	}
486	return name.str();
487	}
488
489	std::string mangleAdapterName(
490	ast::FunctionType const * function,
491	TypeVarMap const & typeVars ) {
492	return Mangle::mangle( function, {} )
493	+ makePolyMonoSuffix( function, typeVars );
494	}
495
496	std::string makeAdapterName( std::string const & mangleName ) {
497	return "_adapter" + mangleName;
498	}
499
500	void makeRetParam( ast::FunctionType * type ) {
501	ast::ptr<ast::Type> & retParam = type->returns.front();
502
503	// Make a new parameter that is a pointer to the type of the old return value.
504	retParam = new ast::PointerType( retParam.get() );
505	type->params.emplace( type->params.begin(), retParam );
506
507	// We don't need the return value any more.
508	type->returns.clear();
509	}
510
511	ast::FunctionType * makeAdapterType(
512	ast::FunctionType const * adaptee,
513	TypeVarMap const & typeVars ) {
514	ast::FunctionType * adapter = ast::deepCopy( adaptee );
515	if ( isDynRet( adapter, typeVars ) ) {
516	makeRetParam( adapter );
517	}
518	adapter->params.emplace( adapter->params.begin(),
519	new ast::PointerType( new ast::FunctionType( ast::VariableArgs ) )
520	);
521	return adapter;
522	}
523
524	CallAdapter::CallAdapter() : tmpNamer( "_temp" ) {}
525
526	void CallAdapter::previsit( ast::Decl const * ) {
527	// Prevent type declaration information from leaking out.
528	GuardScope( scopeTypeVars );
529	}
530
531	ast::FunctionDecl const * CallAdapter::previsit( ast::FunctionDecl const * decl ) {
532	// Prevent type declaration information from leaking out.
533	GuardScope( scopeTypeVars );
534
535	if ( nullptr == decl->stmts ) {
536	return decl;
537	}
538
539	GuardValue( retval );
540
541	// Process polymorphic return value.
542	retval = nullptr;
543	ast::FunctionType const * type = decl->type;
544	if ( isDynRet( type ) && decl->linkage != ast::Linkage::C ) {
545	retval = decl->returns.front();
546
547	// Give names to unnamed return values.
548	if ( "" == retval->name ) {
549	auto mutRet = ast::mutate( retval );
550	mutRet->name = "_retparam";
551	mutRet->linkage = ast::Linkage::C;
552	retval = mutRet;
553	decl = ast::mutate_field_index( decl,
554	&ast::FunctionDecl::returns, 0, mutRet );
555	}
556	}
557
558	// The formal_usage/expr_id values may be off if we get them from the
559	// type, trying the declaration instead.
560	makeTypeVarMap( type, scopeTypeVars );
561
562	// Get all needed adapters from the call. We will forward them.
563	ast::vector<ast::FunctionType> functions;
564	for ( ast::ptr<ast::VariableExpr> const & assertion : type->assertions ) {
565	auto atype = assertion->result.get();
566	findFunction( atype, functions, scopeTypeVars, needsAdapter );
567	}
568
569	for ( ast::ptr<ast::Type> const & arg : type->params ) {
570	findFunction( arg, functions, scopeTypeVars, needsAdapter );
571	}
572
573	for ( auto funcType : functions ) {
574	std::string mangleName = mangleAdapterName( funcType, scopeTypeVars );
575	if ( adapters.contains( mangleName ) ) continue;
576	std::string adapterName = makeAdapterName( mangleName );
577	// TODO: The forwarding here is problematic because these
578	// declarations are not rooted anywhere in the translation unit.
579	adapters.insert(
580	mangleName,
581	new ast::ObjectDecl(
582	decl->location,
583	adapterName,
584	new ast::PointerType(
585	makeAdapterType( funcType, scopeTypeVars ) ),
586	nullptr, // init
587	ast::Storage::Classes(),
588	ast::Linkage::C
589	)
590	);
591	}
592
593	return decl;
594	}
595
596	void CallAdapter::previsit( ast::TypeDecl const * decl ) {
597	addToTypeVarMap( decl, scopeTypeVars );
598	}
599
600	void CallAdapter::previsit( ast::CommaExpr const * expr ) {
601	// Attempting to find application expressions that were mutated by the
602	// copy constructor passes to use an explicit return variable, so that
603	// the variable can be reused as a parameter to the call rather than
604	// creating a new temporary variable. Previously this step was an
605	// optimization, but with the introduction of tuples and UniqueExprs,
606	// it is necessary to ensure that they use the same variable.
607	// Essentially, looking for pattern:
608	// (x=f(...), x)
609	// To compound the issue, the right side can be *x, etc.
610	// because of lvalue-returning functions
611	if ( auto assign = expr->arg1.as<ast::UntypedExpr>() ) {
612	if ( CodeGen::isAssignment( ast::getFunctionName( assign ) ) ) {
613	assert( 2 == assign->args.size() );
614	if ( auto app = assign->args.back().as<ast::ApplicationExpr>() ) {
615	// First argument is assignable, so it must be an lvalue,
616	// so it should be legal to takes its address.
617	retVals.insert_or_assign( app, assign->args.front() );
618	}
619	}
620	}
621	}
622
623	ast::Expr const * CallAdapter::postvisit( ast::ApplicationExpr const * expr ) {
624	assert( expr->func->result );
625	ast::FunctionType const * function = getFunctionType( expr->func->result );
626	assertf( function, "ApplicationExpr has non-function type %s",
627	toCString( expr->func->result ) );
628
629	if ( auto newExpr = handleIntrinsics( expr ) ) {
630	return newExpr;
631	}
632
633	ast::ApplicationExpr * mutExpr = ast::mutate( expr );
634	ast::Expr const * ret = expr;
635
636	// TODO: This entire section should probably be refactored to do less
637	// pushing to the front/middle of a vector.
638	ptrdiff_t initArgCount = mutExpr->args.size();
639
640	TypeVarMap exprTypeVars;
641	// TODO: Should this take into account the variables already bound in
642	// scopeTypeVars ([ex] remove them from exprTypeVars)?
643	makeTypeVarMap( function, exprTypeVars );
644	auto dynRetType = isDynRet( function, exprTypeVars );
645
646	// NOTE: addDynRetParam needs to know the actual (generated) return type
647	// so it can make a temporary variable, so pass the result type form the
648	// `expr` `passTypeVars` needs to know the program-text return type ([ex]
649	// the distinction between _conc_T30 and T3(int)) concRetType may not be
650	// a good name in one or both of these places.
651	if ( dynRetType ) {
652	ast::Type const * result = mutExpr->result;
653	ast::Type const * concRetType = result->isVoid() ? nullptr : result;
654	// [Comment from before translation.]
655	// Used to use dynRetType instead of concRetType.
656	ret = addDynRetParam( mutExpr, concRetType );
657	} else if ( needsAdapter( function, scopeTypeVars )
658	&& !needsAdapter( function, exprTypeVars ) ) {
659	// Change the application so it calls the adapter rather than the
660	// passed function.
661	ret = applyAdapter( mutExpr, function );
662	}
663
664	assert( typeSubs );
665	ast::vector<ast::Expr>::iterator argIt =
666	passTypeVars( mutExpr, function );
667	addInferredParams( mutExpr, argIt, function, exprTypeVars );
668
669	argIt = mutExpr->args.begin();
670	std::advance( argIt, ( mutExpr->args.size() - initArgCount ) );
671
672	boxParams( mutExpr, argIt, function, exprTypeVars );
673	passAdapters( mutExpr, function, exprTypeVars );
674
675	return ret;
676	}
677
678	bool isPolyDeref( ast::UntypedExpr const * expr,
679	TypeVarMap const & typeVars,
680	ast::TypeSubstitution const * typeSubs ) {
681	if ( expr->result && isPolyType( expr->result, typeVars, typeSubs ) ) {
682	if ( auto name = expr->func.as<ast::NameExpr>() ) {
683	if ( "*?" == name->name ) {
684	return true;
685	}
686	}
687	}
688	return false;
689	}
690
691	ast::Expr const * CallAdapter::postvisit( ast::UntypedExpr const * expr ) {
692	if ( isPolyDeref( expr, scopeTypeVars, typeSubs ) ) {
693	return expr->args.front();
694	}
695	return expr;
696	}
697
698	void CallAdapter::previsit( ast::AddressExpr const * ) {
699	visit_children = false;
700	}
701
702	ast::Expr const * CallAdapter::postvisit( ast::AddressExpr const * expr ) {
703	assert( expr->arg->result );
704	assert( !expr->arg->result->isVoid() );
705
706	bool doesNeedAdapter = false;
707	if ( auto un = expr->arg.as<ast::UntypedExpr>() ) {
708	if ( isPolyDeref( un, scopeTypeVars, typeSubs ) ) {
709	if ( auto app = un->args.front().as<ast::ApplicationExpr>() ) {
710	assert( app->func->result );
711	auto function = getFunctionType( app->func->result );
712	assert( function );
713	doesNeedAdapter = needsAdapter( function, scopeTypeVars );
714	}
715	}
716	}
717	// isPolyType check needs to happen before mutating expr arg,
718	// so pull it forward out of the if condition.
719	expr = ast::mutate_field( expr, &ast::AddressExpr::arg,
720	expr->arg->accept( *visitor ) );
721	// But must happen after mutate, since argument might change
722	// (ex. intrinsic *?, ?[?]) re-evaluate above comment.
723	bool polyType = isPolyType( expr->arg->result, scopeTypeVars, typeSubs );
724	if ( polyType \|\| doesNeedAdapter ) {
725	ast::Expr * ret = ast::mutate( expr->arg.get() );
726	ret->result = ast::deepCopy( expr->result );
727	return ret;
728	} else {
729	return expr;
730	}
731	}
732
733	ast::ReturnStmt const * CallAdapter::previsit( ast::ReturnStmt const * stmt ) {
734	// Since retval is set when the return type is dynamic, this function
735	// should have been converted to void return & out parameter.
736	if ( retval && stmt->expr ) {
737	assert( stmt->expr->result );
738	assert( !stmt->expr->result->isVoid() );
739	return ast::mutate_field( stmt, &ast::ReturnStmt::expr, nullptr );
740	}
741	return stmt;
742	}
743
744	void CallAdapter::beginScope() {
745	adapters.beginScope();
746	}
747
748	void CallAdapter::endScope() {
749	adapters.endScope();
750	}
751
752	/// Find instances of polymorphic type parameters.
753	struct PolyFinder {
754	TypeVarMap const & typeVars;
755	bool result = false;
756	PolyFinder( TypeVarMap const & tvs ) : typeVars( tvs ) {}
757
758	void previsit( ast::TypeInstType const * type ) {
759	if ( isPolyType( type, typeVars ) ) result = true;
760	}
761	};
762
763	/// True if these is an instance of a polymorphic type parameter in the type.
764	bool hasPolymorphism( ast::Type const * type, TypeVarMap const & typeVars ) {
765	return ast::Pass<PolyFinder>::read( type, typeVars );
766	}
767
768	ast::vector<ast::Expr>::iterator CallAdapter::passTypeVars(
769	ast::ApplicationExpr * expr,
770	ast::FunctionType const * function ) {
771	assert( typeSubs );
772	ast::vector<ast::Expr>::iterator arg = expr->args.begin();
773	// Pass size/align for type variables.
774	for ( ast::ptr<ast::TypeInstType> const & typeVar : function->forall ) {
775	if ( !typeVar->base->isComplete() ) continue;
776	ast::Type const * concrete = typeSubs->lookup( typeVar );
777	if ( !concrete ) {
778	// Should this be an assertion?
779	SemanticError( expr, toString( typeSubs,
780	"\nunbound type variable: ", typeVar->typeString(),
781	" in application " ) );
782	}
783	arg = expr->args.insert( arg,
784	new ast::SizeofExpr( expr->location, ast::deepCopy( concrete ) ) );
785	arg++;
786	arg = expr->args.insert( arg,
787	new ast::AlignofExpr( expr->location, ast::deepCopy( concrete ) ) );
788	arg++;
789	}
790	return arg;
791	}
792
793	ast::Expr const * CallAdapter::addRetParam(
794	ast::ApplicationExpr * expr, ast::Type const * retType ) {
795	// Create temporary to hold return value of polymorphic function and
796	// produce that temporary as a result using a comma expression.
797	assert( retType );
798
799	ast::Expr * paramExpr = nullptr;
800	// Try to use existing return value parameter if it exists,
801	// otherwise create a new temporary.
802	if ( retVals.count( expr ) ) {
803	paramExpr = ast::deepCopy( retVals[ expr ] );
804	} else {
805	auto newObj = makeTemporary( expr->location, ast::deepCopy( retType ) );
806	paramExpr = new ast::VariableExpr( expr->location, newObj );
807	}
808	ast::Expr * retExpr = ast::deepCopy( paramExpr );
809
810	// If the type of the temporary is not polpmorphic, box temporary by
811	// taking its address; otherwise the temporary is already boxed and can
812	// be used directly.
813	if ( !isPolyType( paramExpr->result, scopeTypeVars, typeSubs ) ) {
814	paramExpr = new ast::AddressExpr( paramExpr->location, paramExpr );
815	}
816	// Add argument to function call.
817	expr->args.insert( expr->args.begin(), paramExpr );
818	// Build a comma expression to call the function and return a value.
819	ast::CommaExpr * comma = new ast::CommaExpr(
820	expr->location, expr, retExpr );
821	comma->env = expr->env;
822	expr->env = nullptr;
823	return comma;
824	}
825
826	ast::Expr const * CallAdapter::addDynRetParam(
827	ast::ApplicationExpr * expr, ast::Type const * polyType ) {
828	assert( typeSubs );
829	ast::Type const * concrete = replaceWithConcrete( polyType, *typeSubs );
830	// Add out-parameter for return value.
831	return addRetParam( expr, concrete );
832	}
833
834	ast::Expr const * CallAdapter::applyAdapter(
835	ast::ApplicationExpr * expr,
836	ast::FunctionType const * function ) {
837	ast::Expr const * ret = expr;
838	if ( isDynRet( function, scopeTypeVars ) ) {
839	ret = addRetParam( expr, function->returns.front() );
840	}
841	std::string mangleName = mangleAdapterName( function, scopeTypeVars );
842	std::string adapterName = makeAdapterName( mangleName );
843
844	// Cast adaptee to `void (*)()`, since it may have any type inside a
845	// polymorphic function.
846	ast::Type const * adapteeType = new ast::PointerType(
847	new ast::FunctionType( ast::VariableArgs ) );
848	expr->args.insert( expr->args.begin(),
849	new ast::CastExpr( expr->location, expr->func, adapteeType ) );
850	// The result field is never set on NameExpr. / Now it is.
851	auto head = new ast::NameExpr( expr->location, adapterName );
852	head->result = ast::deepCopy( adapteeType );
853	expr->func = head;
854
855	return ret;
856	}
857
858	/// Cast parameters to polymorphic functions so that types are replaced with
859	/// `void *` if they are type parameters in the formal type.
860	/// This gets rid of warnings from gcc.
861	void addCast(
862	ast::ptr<ast::Expr> & actual,
863	ast::Type const * formal,
864	TypeVarMap const & typeVars ) {
865	// Type contains polymorphism, but isn't exactly a polytype, in which
866	// case it has some real actual type (ex. unsigned int) and casting to
867	// `void *` is wrong.
868	if ( hasPolymorphism( formal, typeVars )
869	&& !isPolyType( formal, typeVars ) ) {
870	ast::Type const * newType = ast::deepCopy( formal );
871	newType = scrubTypeVars( newType, typeVars );
872	actual = new ast::CastExpr( actual->location, actual, newType );
873	}
874	}
875
876	void CallAdapter::boxParam( ast::ptr<ast::Expr> & arg,
877	ast::Type const * param, TypeVarMap const & exprTypeVars ) {
878	assertf( arg->result, "arg does not have result: %s", toCString( arg ) );
879	addCast( arg, param, exprTypeVars );
880	if ( !needsBoxing( param, arg->result, exprTypeVars, typeSubs ) ) {
881	return;
882	}
883	CodeLocation const & location = arg->location;
884
885	if ( arg->get_lvalue() ) {
886	// The argument expression may be CFA lvalue, but not C lvalue,
887	// so apply generalizedLvalue transformations.
888	// if ( auto var = dynamic_cast<ast::VariableExpr const *>( arg ) ) {
889	// if ( dynamic_cast<ast::ArrayType const *>( varExpr->var->get_type() ) ){
890	// // temporary hack - don't box arrays, because &arr is not the same as &arr[0]
891	// return;
892	// }
893	// }
894	arg = generalizedLvalue( new ast::AddressExpr( arg->location, arg ) );
895	if ( !ResolvExpr::typesCompatible( param, arg->result ) ) {
896	// Silence warnings by casting boxed parameters when the actually
897	// type does not match up with the formal type.
898	arg = new ast::CastExpr( location, arg, ast::deepCopy( param ) );
899	}
900	} else {
901	// Use type computed in unification to declare boxed variables.
902	ast::ptr<ast::Type> newType = ast::deepCopy( param );
903	if ( typeSubs ) typeSubs->apply( newType );
904	ast::ObjectDecl * newObj = makeTemporary( location, newType );
905	auto assign = ast::UntypedExpr::createCall( location, "?=?", {
906	new ast::VariableExpr( location, newObj ),
907	arg,
908	} );
909	stmtsToAddBefore.push_back( new ast::ExprStmt( location, assign ) );
910	arg = new ast::AddressExpr(
911	new ast::VariableExpr( location, newObj ) );
912	}
913	}
914
915	void CallAdapter::boxParams(
916	ast::ApplicationExpr const * expr,
917	ast::vector<ast::Expr>::iterator arg,
918	ast::FunctionType const * function,
919	const TypeVarMap & typeVars ) {
920	for ( auto param : function->params ) {
921	assertf( arg != expr->args.end(),
922	"boxParams: missing argument for param %s to %s in %s",
923	toCString( param ), toCString( function ), toCString( expr ) );
924	boxParam( *arg, param, typeVars );
925	++arg;
926	}
927	}
928
929	void CallAdapter::addInferredParams(
930	ast::ApplicationExpr * expr,
931	ast::vector<ast::Expr>::iterator arg,
932	ast::FunctionType const * functionType,
933	TypeVarMap const & typeVars ) {
934	ast::vector<ast::Expr>::iterator cur = arg;
935	for ( auto assertion : functionType->assertions ) {
936	auto inferParam = expr->inferred.inferParams().find(
937	assertion->var->uniqueId );
938	assertf( inferParam != expr->inferred.inferParams().end(),
939	"addInferredParams missing inferred parameter: %s in: %s",
940	toCString( assertion ), toCString( expr ) );
941	ast::ptr<ast::Expr> newExpr = ast::deepCopy( inferParam->second.expr );
942	boxParam( newExpr, assertion->result, typeVars );
943	cur = expr->args.insert( cur, newExpr.release() );
944	++cur;
945	}
946	}
947
948	/// Modifies the ApplicationExpr to accept adapter functions for its
949	/// assertion and parameters, declares the required adapters.
950	void CallAdapter::passAdapters(
951	ast::ApplicationExpr * expr,
952	ast::FunctionType const * type,
953	const TypeVarMap & exprTypeVars ) {
954	// Collect a list of function types passed as parameters or implicit
955	// parameters (assertions).
956	ast::vector<ast::Type> const & paramList = type->params;
957	ast::vector<ast::FunctionType> functions;
958
959	for ( ast::ptr<ast::VariableExpr> const & assertion : type->assertions ) {
960	findFunction( assertion->result, functions, exprTypeVars, needsAdapter );
961	}
962	for ( ast::ptr<ast::Type> const & arg : paramList ) {
963	findFunction( arg, functions, exprTypeVars, needsAdapter );
964	}
965
966	// Parameter function types for which an appropriate adapter has been
967	// generated. We cannot use the types after applying substitutions,
968	// since two different parameter types may be unified to the same type.
969	std::set<std::string> adaptersDone;
970
971	CodeLocation const & location = expr->location;
972
973	for ( ast::ptr<ast::FunctionType> const & funcType : functions ) {
974	std::string mangleName = Mangle::mangle( funcType );
975
976	// Only attempt to create an adapter or pass one as a parameter if we
977	// haven't already done so for this pre-substitution parameter
978	// function type.
979	// The second part of the result if is if the element was inserted.
980	if ( !adaptersDone.insert( mangleName ).second ) continue;
981
982	// Apply substitution to type variables to figure out what the
983	// adapter's type should look like. (Copy to make the release safe.)
984	assert( typeSubs );
985	auto result = typeSubs->apply( ast::deepCopy( funcType ) );
986	ast::FunctionType * realType = ast::mutate( result.node.release() );
987	mangleName = Mangle::mangle( realType );
988	mangleName += makePolyMonoSuffix( funcType, exprTypeVars );
989
990	// Check if the adapter has already been created, or has to be.
991	using AdapterIter = decltype(adapters)::iterator;
992	AdapterIter adapter = adapters.find( mangleName );
993	if ( adapter == adapters.end() ) {
994	ast::FunctionDecl * newAdapter = makeAdapter(
995	funcType, realType, mangleName, exprTypeVars, location );
996	std::pair<AdapterIter, bool> answer =
997	adapters.insert( mangleName, newAdapter );
998	adapter = answer.first;
999	stmtsToAddBefore.push_back(
1000	new ast::DeclStmt( location, newAdapter ) );
1001	}
1002	assert( adapter != adapters.end() );
1003
1004	// Add the approprate adapter as a parameter.
1005	expr->args.insert( expr->args.begin(),
1006	new ast::VariableExpr( location, adapter->second ) );
1007	}
1008	}
1009
1010	// Parameter and argument may be used wrong around here.
1011	ast::Expr * makeAdapterArg(
1012	ast::DeclWithType const * param,
1013	ast::Type const * arg,
1014	ast::Type const * realParam,
1015	TypeVarMap const & typeVars,
1016	CodeLocation const & location ) {
1017	assert( param );
1018	assert( arg );
1019	assert( realParam );
1020	if ( isPolyType( realParam, typeVars ) && !isPolyType( arg ) ) {
1021	ast::UntypedExpr * deref = ast::UntypedExpr::createDeref(
1022	location,
1023	new ast::CastExpr( location,
1024	new ast::VariableExpr( location, param ),
1025	new ast::PointerType( ast::deepCopy( arg ) )
1026	)
1027	);
1028	deref->result = ast::deepCopy( arg );
1029	return deref;
1030	}
1031	return new ast::VariableExpr( location, param );
1032	}
1033
1034	// This seems to be one of the problematic functions.
1035	void addAdapterParams(
1036	ast::ApplicationExpr * adaptee,
1037	ast::vector<ast::Type>::const_iterator arg,
1038	ast::vector<ast::DeclWithType>::iterator param,
1039	ast::vector<ast::DeclWithType>::iterator paramEnd,
1040	ast::vector<ast::Type>::const_iterator realParam,
1041	TypeVarMap const & typeVars,
1042	CodeLocation const & location ) {
1043	UniqueName paramNamer( "_p" );
1044	for ( ; param != paramEnd ; ++param, ++arg, ++realParam ) {
1045	if ( "" == (*param)->name ) {
1046	auto mutParam = (*param).get_and_mutate();
1047	mutParam->name = paramNamer.newName();
1048	mutParam->linkage = ast::Linkage::C;
1049	}
1050	adaptee->args.push_back(
1051	makeAdapterArg( param, arg, *realParam, typeVars, location ) );
1052	}
1053	}
1054
1055	ast::FunctionDecl * CallAdapter::makeAdapter(
1056	ast::FunctionType const * adaptee,
1057	ast::FunctionType const * realType,
1058	std::string const & mangleName,
1059	TypeVarMap const & typeVars,
1060	CodeLocation const & location ) const {
1061	ast::FunctionType * adapterType = makeAdapterType( adaptee, typeVars );
1062	adapterType = ast::mutate( scrubTypeVars( adapterType, typeVars ) );
1063
1064	// Some of these names will be overwritten, but it gives a default.
1065	UniqueName pNamer( "_param" );
1066	UniqueName rNamer( "_ret" );
1067
1068	bool first = true;
1069
1070	ast::FunctionDecl * adapterDecl = new ast::FunctionDecl( location,
1071	makeAdapterName( mangleName ),
1072	{}, // forall
1073	{}, // assertions
1074	map_range<ast::vector<ast::DeclWithType>>( adapterType->params,
1075	[&pNamer, &location, &first]( ast::ptr<ast::Type> const & param ) {
1076	// [Trying to make the generated code match exactly more often.]
1077	if ( first ) {
1078	first = false;
1079	return new ast::ObjectDecl( location, "_adaptee", param );
1080	}
1081	return new ast::ObjectDecl( location, pNamer.newName(), param );
1082	} ),
1083	map_range<ast::vector<ast::DeclWithType>>( adapterType->returns,
1084	[&rNamer, &location]( ast::ptr<ast::Type> const & retval ) {
1085	return new ast::ObjectDecl( location, rNamer.newName(), retval );
1086	} ),
1087	nullptr, // stmts
1088	{}, // storage
1089	ast::Linkage::C
1090	);
1091
1092	ast::DeclWithType * adapteeDecl =
1093	adapterDecl->params.front().get_and_mutate();
1094	adapteeDecl->name = "_adaptee";
1095
1096	// Do not carry over attributes to real type parameters/return values.
1097	auto mutRealType = ast::mutate( realType );
1098	for ( ast::ptr<ast::Type> & decl : mutRealType->params ) {
1099	if ( decl->attributes.empty() ) continue;
1100	auto mut = ast::mutate( decl.get() );
1101	mut->attributes.clear();
1102	decl = mut;
1103	}
1104	for ( ast::ptr<ast::Type> & decl : mutRealType->returns ) {
1105	if ( decl->attributes.empty() ) continue;
1106	auto mut = ast::mutate( decl.get() );
1107	mut->attributes.clear();
1108	decl = mut;
1109	}
1110	realType = mutRealType;
1111
1112	ast::ApplicationExpr * adapteeApp = new ast::ApplicationExpr( location,
1113	new ast::CastExpr( location,
1114	new ast::VariableExpr( location, adapteeDecl ),
1115	new ast::PointerType( realType )
1116	)
1117	);
1118
1119	for ( auto group : group_iterate( realType->assertions,
1120	adapterType->assertions, adaptee->assertions ) ) {
1121	auto assertArg = std::get<0>( group );
1122	auto assertParam = std::get<1>( group );
1123	auto assertReal = std::get<2>( group );
1124	adapteeApp->args.push_back( makeAdapterArg(
1125	assertParam->var, assertArg->var->get_type(),
1126	assertReal->var->get_type(), typeVars, location
1127	) );
1128	}
1129
1130	ast::vector<ast::Type>::const_iterator
1131	arg = realType->params.begin(),
1132	param = adapterType->params.begin(),
1133	realParam = adaptee->params.begin();
1134	ast::vector<ast::DeclWithType>::iterator
1135	paramDecl = adapterDecl->params.begin();
1136	// Skip adaptee parameter in the adapter type.
1137	++param;
1138	++paramDecl;
1139
1140	ast::Stmt * bodyStmt;
1141	// Returns void/nothing.
1142	if ( realType->returns.empty() ) {
1143	addAdapterParams( adapteeApp, arg, paramDecl, adapterDecl->params.end(),
1144	realParam, typeVars, location );
1145	bodyStmt = new ast::ExprStmt( location, adapteeApp );
1146	// Returns a polymorphic type.
1147	} else if ( isDynType( adaptee->returns.front(), typeVars ) ) {
1148	ast::UntypedExpr * assign = new ast::UntypedExpr( location,
1149	new ast::NameExpr( location, "?=?" ) );
1150	ast::UntypedExpr * deref = ast::UntypedExpr::createDeref( location,
1151	new ast::CastExpr( location,
1152	new ast::VariableExpr( location, *paramDecl++ ),
1153	new ast::PointerType(
1154	ast::deepCopy( realType->returns.front() ) ) ) );
1155	assign->args.push_back( deref );
1156	addAdapterParams( adapteeApp, arg, paramDecl, adapterDecl->params.end(),
1157	realParam, typeVars, location );
1158	assign->args.push_back( adapteeApp );
1159	bodyStmt = new ast::ExprStmt( location, assign );
1160	// Adapter for a function that returns a monomorphic value.
1161	} else {
1162	addAdapterParams( adapteeApp, arg, paramDecl, adapterDecl->params.end(),
1163	realParam, typeVars, location );
1164	bodyStmt = new ast::ReturnStmt( location, adapteeApp );
1165	}
1166
1167	adapterDecl->stmts = new ast::CompoundStmt( location, { bodyStmt } );
1168	return adapterDecl;
1169	}
1170
1171	ast::Expr const * makeIncrDecrExpr(
1172	CodeLocation const & location,
1173	ast::ApplicationExpr const * expr,
1174	ast::Type const * polyType,
1175	bool isIncr ) {
1176	ast::NameExpr * opExpr =
1177	new ast::NameExpr( location, isIncr ? "?+=?" : "?-=?" );
1178	ast::UntypedExpr * addAssign = new ast::UntypedExpr( location, opExpr );
1179	if ( auto address = expr->args.front().as<ast::AddressExpr>() ) {
1180	addAssign->args.push_back( address->arg );
1181	} else {
1182	addAssign->args.push_back( expr->args.front() );
1183	}
1184	addAssign->args.push_back( new ast::NameExpr( location,
1185	sizeofName( Mangle::mangleType( polyType ) ) ) );
1186	addAssign->result = ast::deepCopy( expr->result );
1187	addAssign->env = expr->env ? expr->env : addAssign->env;
1188	return addAssign;
1189	}
1190
1191	/// Handles intrinsic functions for postvisit ApplicationExpr.
1192	ast::Expr const * CallAdapter::handleIntrinsics(
1193	ast::ApplicationExpr const * expr ) {
1194	auto varExpr = expr->func.as<ast::VariableExpr>();
1195	if ( !varExpr \|\| varExpr->var->linkage != ast::Linkage::Intrinsic ) {
1196	return nullptr;
1197	}
1198	std::string const & varName = varExpr->var->name;
1199
1200	// Index Intrinsic:
1201	if ( "?[?]" == varName ) {
1202	assert( expr->result );
1203	assert( 2 == expr->args.size() );
1204
1205	ast::Type const * baseType1 =
1206	isPolyPtr( expr->args.front()->result, scopeTypeVars, typeSubs );
1207	ast::Type const * baseType2 =
1208	isPolyPtr( expr->args.back()->result, scopeTypeVars, typeSubs );
1209	// If neither argument is a polymorphic pointer, do nothing.
1210	if ( !baseType1 && !baseType2 ) {
1211	return expr;
1212	}
1213	// The arguments cannot both be polymorphic pointers.
1214	assert( !baseType1 \|\| !baseType2 );
1215	// (So exactly one of the arguments is a polymorphic pointer.)
1216
1217	CodeLocation const & location = expr->location;
1218	CodeLocation const & location1 = expr->args.front()->location;
1219	CodeLocation const & location2 = expr->args.back()->location;
1220
1221	ast::UntypedExpr * ret = new ast::UntypedExpr( location,
1222	new ast::NameExpr( location, "?+?" ) );
1223	if ( baseType1 ) {
1224	auto multiply = ast::UntypedExpr::createCall( location2, "?*?", {
1225	expr->args.back(),
1226	new ast::SizeofExpr( location1, deepCopy( baseType1 ) ),
1227	} );
1228	ret->args.push_back( expr->args.front() );
1229	ret->args.push_back( multiply );
1230	} else {
1231	assert( baseType2 );
1232	auto multiply = ast::UntypedExpr::createCall( location1, "?*?", {
1233	expr->args.front(),
1234	new ast::SizeofExpr( location2, deepCopy( baseType2 ) ),
1235	} );
1236	ret->args.push_back( multiply );
1237	ret->args.push_back( expr->args.back() );
1238	}
1239	ret->result = ast::deepCopy( expr->result );
1240	ret->env = expr->env ? expr->env : ret->env;
1241	return ret;
1242	// Dereference Intrinsic:
1243	} else if ( "*?" == varName ) {
1244	assert( expr->result );
1245	assert( 1 == expr->args.size() );
1246
1247	// If this isn't for a poly type, then do nothing.
1248	if ( !isPolyType( expr->result, scopeTypeVars, typeSubs ) ) {
1249	return expr;
1250	}
1251
1252	// Remove dereference from polymorphic types since they are boxed.
1253	ast::Expr * ret = ast::deepCopy( expr->args.front() );
1254	// Fix expression type to remove pointer.
1255	ret->result = expr->result;
1256	ret->env = expr->env ? expr->env : ret->env;
1257	return ret;
1258	// Post-Increment/Decrement Intrinsics:
1259	} else if ( "?++" == varName \|\| "?--" == varName ) {
1260	assert( expr->result );
1261	assert( 1 == expr->args.size() );
1262
1263	ast::Type const * baseType =
1264	isPolyType( expr->result, scopeTypeVars, typeSubs );
1265	if ( nullptr == baseType ) {
1266	return expr;
1267	}
1268	ast::Type * tempType = ast::deepCopy( expr->result );
1269	if ( typeSubs ) {
1270	auto result = typeSubs->apply( tempType );
1271	tempType = ast::mutate( result.node.release() );
1272	}
1273	CodeLocation const & location = expr->location;
1274	ast::ObjectDecl * newObj = makeTemporary( location, tempType );
1275	ast::VariableExpr * tempExpr =
1276	new ast::VariableExpr( location, newObj );
1277	ast::UntypedExpr * assignExpr = new ast::UntypedExpr( location,
1278	new ast::NameExpr( location, "?=?" ) );
1279	assignExpr->args.push_back( ast::deepCopy( tempExpr ) );
1280	if ( auto address = expr->args.front().as<ast::AddressExpr>() ) {
1281	assignExpr->args.push_back( ast::deepCopy( address->arg ) );
1282	} else {
1283	assignExpr->args.push_back( ast::deepCopy( expr->args.front() ) );
1284	}
1285	return new ast::CommaExpr( location,
1286	new ast::CommaExpr( location,
1287	assignExpr,
1288	makeIncrDecrExpr( location, expr, baseType, "?++" == varName )
1289	),
1290	tempExpr
1291	);
1292	// Pre-Increment/Decrement Intrinsics:
1293	} else if ( "++?" == varName \|\| "--?" == varName ) {
1294	assert( expr->result );
1295	assert( 1 == expr->args.size() );
1296
1297	ast::Type const * baseType =
1298	isPolyType( expr->result, scopeTypeVars, typeSubs );
1299	if ( nullptr == baseType ) {
1300	return expr;
1301	}
1302	return makeIncrDecrExpr(
1303	expr->location, expr, baseType, "++?" == varName );
1304	// Addition and Subtration Intrinsics:
1305	} else if ( "?+?" == varName \|\| "?-?" == varName ) {
1306	assert( expr->result );
1307	assert( 2 == expr->args.size() );
1308
1309	auto baseType1 =
1310	isPolyPtr( expr->args.front()->result, scopeTypeVars, typeSubs );
1311	auto baseType2 =
1312	isPolyPtr( expr->args.back()->result, scopeTypeVars, typeSubs );
1313
1314	CodeLocation const & location = expr->location;
1315	CodeLocation const & location1 = expr->args.front()->location;
1316	CodeLocation const & location2 = expr->args.back()->location;
1317	// LHS op RHS -> (LHS op RHS) / sizeof(LHS)
1318	if ( baseType1 && baseType2 ) {
1319	auto divide = ast::UntypedExpr::createCall( location, "?/?", {
1320	expr,
1321	new ast::SizeofExpr( location, deepCopy( baseType1 ) ),
1322	} );
1323	if ( expr->env ) divide->env = expr->env;
1324	return divide;
1325	// LHS op RHS -> LHS op (RHS * sizeof(LHS))
1326	} else if ( baseType1 ) {
1327	auto multiply = ast::UntypedExpr::createCall( location2, "?*?", {
1328	expr->args.back(),
1329	new ast::SizeofExpr( location1, deepCopy( baseType1 ) ),
1330	} );
1331	return ast::mutate_field_index(
1332	expr, &ast::ApplicationExpr::args, 1, multiply );
1333	// LHS op RHS -> (LHS * sizeof(RHS)) op RHS
1334	} else if ( baseType2 ) {
1335	auto multiply = ast::UntypedExpr::createCall( location1, "?*?", {
1336	expr->args.front(),
1337	new ast::SizeofExpr( location2, deepCopy( baseType2 ) ),
1338	} );
1339	return ast::mutate_field_index(
1340	expr, &ast::ApplicationExpr::args, 0, multiply );
1341	}
1342	// Addition and Subtration Relative Assignment Intrinsics:
1343	} else if ( "?+=?" == varName \|\| "?-=?" == varName ) {
1344	assert( expr->result );
1345	assert( 2 == expr->args.size() );
1346
1347	CodeLocation const & location1 = expr->args.front()->location;
1348	CodeLocation const & location2 = expr->args.back()->location;
1349	auto baseType = isPolyPtr( expr->result, scopeTypeVars, typeSubs );
1350	// LHS op RHS -> LHS op (RHS * sizeof(LHS))
1351	if ( baseType ) {
1352	auto multiply = ast::UntypedExpr::createCall( location2, "?*?", {
1353	expr->args.back(),
1354	new ast::SizeofExpr( location1, deepCopy( baseType ) ),
1355	} );
1356	return ast::mutate_field_index(
1357	expr, &ast::ApplicationExpr::args, 1, multiply );
1358	}
1359	}
1360	return expr;
1361	}
1362
1363	ast::ObjectDecl * CallAdapter::makeTemporary(
1364	CodeLocation const & location, ast::Type const * type ) {
1365	auto newObj = new ast::ObjectDecl( location, tmpNamer.newName(), type );
1366	stmtsToAddBefore.push_back( new ast::DeclStmt( location, newObj ) );
1367	return newObj;
1368	}
1369
1370	// --------------------------------------------------------------------------
1371	/// Modifies declarations to accept implicit parameters.
1372	/// * Move polymorphic returns in function types to pointer-type parameters.
1373	/// * Adds type size and assertion parameters to parameter lists.
1374	struct DeclAdapter final {
1375	ast::FunctionDecl const * previsit( ast::FunctionDecl const * decl );
1376	ast::FunctionDecl const * postvisit( ast::FunctionDecl const * decl );
1377	private:
1378	void addAdapters( ast::FunctionDecl * decl, TypeVarMap & localTypeVars );
1379	};
1380
1381	ast::ObjectDecl * makeObj(
1382	CodeLocation const & location, std::string const & name ) {
1383	// The size/align parameters may be unused, so add the unused attribute.
1384	return new ast::ObjectDecl( location, name,
1385	makeLayoutCType(),
1386	nullptr, ast::Storage::Classes(), ast::Linkage::C, nullptr,
1387	{ new ast::Attribute( "unused" ) } );
1388	}
1389
1390	/// A modified and specialized version of ast::add_qualifiers.
1391	ast::Type const * addConst( ast::Type const * type ) {
1392	ast::CV::Qualifiers cvq = { ast::CV::Const };
1393	if ( ( type->qualifiers & cvq ) != 0 ) return type;
1394	auto mutType = ast::mutate( type );
1395	mutType->qualifiers \|= cvq;
1396	return mutType;
1397	}
1398
1399	ast::FunctionDecl const * DeclAdapter::previsit( ast::FunctionDecl const * decl ) {
1400	TypeVarMap localTypeVars;
1401	makeTypeVarMap( decl, localTypeVars );
1402
1403	auto mutDecl = mutate( decl );
1404
1405	// Move polymorphic return type to parameter list.
1406	if ( isDynRet( mutDecl->type ) ) {
1407	auto ret = strict_dynamic_cast<ast::ObjectDecl *>(
1408	mutDecl->returns.front().get_and_mutate() );
1409	ret->set_type( new ast::PointerType( ret->type ) );
1410	mutDecl->params.insert( mutDecl->params.begin(), ret );
1411	mutDecl->returns.erase( mutDecl->returns.begin() );
1412	ret->init = nullptr;
1413	}
1414
1415	// Add size/align and assertions for type parameters to parameter list.
1416	ast::vector<ast::DeclWithType> inferredParams;
1417	ast::vector<ast::DeclWithType> layoutParams;
1418	for ( ast::ptr<ast::TypeDecl> & typeParam : mutDecl->type_params ) {
1419	auto mutParam = mutate( typeParam.get() );
1420	// Add all size and alignment parameters to parameter list.
1421	if ( mutParam->isComplete() ) {
1422	ast::TypeInstType paramType( mutParam );
1423	std::string paramName = Mangle::mangleType( &paramType );
1424
1425	auto sizeParam = makeObj( typeParam->location, sizeofName( paramName ) );
1426	layoutParams.emplace_back( sizeParam );
1427
1428	auto alignParam = makeObj( typeParam->location, alignofName( paramName ) );
1429	layoutParams.emplace_back( alignParam );
1430	}
1431	// Assertions should be stored in the main list.
1432	assert( mutParam->assertions.empty() );
1433	typeParam = mutParam;
1434	}
1435	for ( ast::ptr<ast::DeclWithType> & assert : mutDecl->assertions ) {
1436	ast::DeclWithType * mutAssert = ast::mutate( assert.get() );
1437	// Assertion parameters may not be used in body,
1438	// pass along with unused attribute.
1439	mutAssert->attributes.push_back( new ast::Attribute( "unused" ) );
1440	mutAssert->set_type( addConst( mutAssert->get_type() ) );
1441	inferredParams.emplace_back( mutAssert );
1442	}
1443	mutDecl->assertions.clear();
1444
1445	// Prepend each argument group. From last group to first. addAdapters
1446	// does do the same, it just does it itself and see all other parameters.
1447	spliceBegin( mutDecl->params, inferredParams );
1448	spliceBegin( mutDecl->params, layoutParams );
1449	addAdapters( mutDecl, localTypeVars );
1450
1451	// Now have to update the type to match the declaration.
1452	ast::FunctionType * type = new ast::FunctionType(
1453	mutDecl->type->isVarArgs, mutDecl->type->qualifiers );
1454	// The forall clauses don't match until Eraser. The assertions are empty.
1455	for ( auto param : mutDecl->params ) {
1456	type->params.emplace_back( param->get_type() );
1457	}
1458	for ( auto retval : mutDecl->returns ) {
1459	type->returns.emplace_back( retval->get_type() );
1460	}
1461	mutDecl->type = type;
1462
1463	return mutDecl;
1464	}
1465
1466	ast::FunctionDecl const * DeclAdapter::postvisit(
1467	ast::FunctionDecl const * decl ) {
1468	ast::FunctionDecl * mutDecl = mutate( decl );
1469	if ( !mutDecl->returns.empty() && mutDecl->stmts
1470	// Intrinsic functions won't be using the _retval so no need to
1471	// generate it.
1472	&& mutDecl->linkage != ast::Linkage::Intrinsic
1473	// Remove check for prefix once thunks properly use ctor/dtors.
1474	&& !isPrefix( mutDecl->name, "_thunk" )
1475	&& !isPrefix( mutDecl->name, "_adapter" ) ) {
1476	assert( 1 == mutDecl->returns.size() );
1477	ast::DeclWithType const * retval = mutDecl->returns.front();
1478	if ( "" == retval->name ) {
1479	retval = ast::mutate_field(
1480	retval, &ast::DeclWithType::name, "_retval" );
1481	mutDecl->returns.front() = retval;
1482	}
1483	auto stmts = mutDecl->stmts.get_and_mutate();
1484	stmts->kids.push_front( new ast::DeclStmt( retval->location, retval ) );
1485	ast::DeclWithType * newRet = ast::deepCopy( retval );
1486	mutDecl->returns.front() = newRet;
1487	}
1488	// Errors should have been caught by this point, remove initializers from
1489	// parameters to allow correct codegen of default arguments.
1490	for ( ast::ptr<ast::DeclWithType> & param : mutDecl->params ) {
1491	if ( auto obj = param.as<ast::ObjectDecl>() ) {
1492	param = ast::mutate_field( obj, &ast::ObjectDecl::init, nullptr );
1493	}
1494	}
1495	return mutDecl;
1496	}
1497
1498	void DeclAdapter::addAdapters(
1499	ast::FunctionDecl * mutDecl, TypeVarMap & localTypeVars ) {
1500	ast::vector<ast::FunctionType> functions;
1501	for ( ast::ptr<ast::DeclWithType> & arg : mutDecl->params ) {
1502	ast::Type const * type = arg->get_type();
1503	type = findAndReplaceFunction( type, functions, localTypeVars, needsAdapter );
1504	arg.get_and_mutate()->set_type( type );
1505	}
1506	std::set<std::string> adaptersDone;
1507	for ( ast::ptr<ast::FunctionType> const & func : functions ) {
1508	std::string mangleName = mangleAdapterName( func, localTypeVars );
1509	if ( adaptersDone.find( mangleName ) != adaptersDone.end() ) {
1510	continue;
1511	}
1512	std::string adapterName = makeAdapterName( mangleName );
1513	// The adapter may not actually be used, so make sure it has unused.
1514	mutDecl->params.insert( mutDecl->params.begin(), new ast::ObjectDecl(
1515	mutDecl->location, adapterName,
1516	new ast::PointerType( makeAdapterType( func, localTypeVars ) ),
1517	nullptr, {}, {}, nullptr,
1518	{ new ast::Attribute( "unused" ) } ) );
1519	adaptersDone.insert( adaptersDone.begin(), mangleName );
1520	}
1521	}
1522
1523	// --------------------------------------------------------------------------
1524	// TODO: Ideally, there would be no floating nodes at all.
1525	/// Corrects the floating nodes created in CallAdapter.
1526	struct RewireAdapters final : public ast::WithGuards {
1527	ScopedMap<std::string, ast::ObjectDecl const *> adapters;
1528	void beginScope() { adapters.beginScope(); }
1529	void endScope() { adapters.endScope(); }
1530	void previsit( ast::FunctionDecl const * decl );
1531	ast::VariableExpr const * previsit( ast::VariableExpr const * expr );
1532	};
1533
1534	void RewireAdapters::previsit( ast::FunctionDecl const * decl ) {
1535	GuardScope( adapters );
1536	for ( ast::ptr<ast::DeclWithType> const & param : decl->params ) {
1537	if ( auto objectParam = param.as<ast::ObjectDecl>() ) {
1538	adapters.insert( objectParam->name, objectParam );
1539	}
1540	}
1541	}
1542
1543	ast::VariableExpr const * RewireAdapters::previsit(
1544	ast::VariableExpr const * expr ) {
1545	// If the node is not floating, we can skip.
1546	if ( expr->var->isManaged() ) return expr;
1547	auto it = adapters.find( expr->var->name );
1548	assertf( it != adapters.end(), "Could not correct floating node." );
1549	return ast::mutate_field( expr, &ast::VariableExpr::var, it->second );
1550	}
1551
1552	// --------------------------------------------------------------------------
1553	/// Inserts code to access polymorphic layout inforation.
1554	/// * Replaces member and size/alignment/offsetof expressions on polymorphic
1555	/// generic types with calculated expressions.
1556	/// * Replaces member expressions for polymorphic types with calculated
1557	/// add-field-offset-and-dereference.
1558	/// * Calculates polymorphic offsetof expressions from offset array.
1559	/// * Inserts dynamic calculation of polymorphic type layouts where needed.
1560	struct PolyGenericCalculator final :
1561	public ast::WithConstTypeSubstitution,
1562	public ast::WithDeclsToAdd<>,
1563	public ast::WithGuards,
1564	public ast::WithStmtsToAdd<>,
1565	public ast::WithVisitorRef<PolyGenericCalculator> {
1566	PolyGenericCalculator();
1567
1568	void previsit( ast::FunctionDecl const * decl );
1569	void previsit( ast::TypedefDecl const * decl );
1570	void previsit( ast::TypeDecl const * decl );
1571	ast::Decl const * postvisit( ast::TypeDecl const * decl );
1572	ast::StructDecl const * previsit( ast::StructDecl const * decl );
1573	ast::UnionDecl const * previsit( ast::UnionDecl const * decl );
1574	ast::DeclStmt const * previsit( ast::DeclStmt const * stmt );
1575	ast::Expr const * postvisit( ast::MemberExpr const * expr );
1576	void previsit( ast::AddressExpr const * expr );
1577	ast::Expr const * postvisit( ast::AddressExpr const * expr );
1578	ast::Expr const * postvisit( ast::SizeofExpr const * expr );
1579	ast::Expr const * postvisit( ast::AlignofExpr const * expr );
1580	ast::Expr const * postvisit( ast::OffsetofExpr const * expr );
1581	ast::Expr const * postvisit( ast::OffsetPackExpr const * expr );
1582
1583	void beginScope();
1584	void endScope();
1585	private:
1586	/// Makes a new variable in the current scope with the given name,
1587	/// type and optional initializer.
1588	ast::ObjectDecl * makeVar(
1589	CodeLocation const & location, std::string const & name,
1590	ast::Type const * type, ast::Init const * init = nullptr );
1591	/// Returns true if the type has a dynamic layout;
1592	/// such a layout will be stored in appropriately-named local variables
1593	/// when the function returns.
1594	bool findGeneric( CodeLocation const & location, ast::Type const * );
1595	/// Adds type parameters to the layout call; will generate the
1596	/// appropriate parameters if needed.
1597	void addSTypeParamsToLayoutCall(
1598	ast::UntypedExpr * layoutCall,
1599	const ast::vector<ast::Type> & otypeParams );
1600	/// Change the type of generic aggregate members to char[].
1601	void mutateMembers( ast::AggregateDecl * aggr );
1602	/// Returns the calculated sizeof expression for type, or nullptr for use
1603	/// C sizeof().
1604	ast::Expr const * genSizeof( CodeLocation const &, ast::Type const * );
1605	/// Enters a new scope for type-variables,
1606	/// adding the type variables from the provided type.
1607	void beginTypeScope( ast::Type const * );
1608
1609	/// The type variables and polymorphic parameters currently in scope.
1610	TypeVarMap scopeTypeVars;
1611	/// Set of generic type layouts known in the current scope,
1612	/// indexed by sizeofName.
1613	ScopedSet<std::string> knownLayouts;
1614	/// Set of non-generic types for which the offset array exists in the
1615	/// current scope, indexed by offsetofName.
1616	ScopedSet<std::string> knownOffsets;
1617	/// Namer for VLA (variable length array) buffers.
1618	UniqueName bufNamer;
1619	/// If the argument of an AddressExpr is MemberExpr, it is stored here.
1620	ast::MemberExpr const * addrMember = nullptr;
1621	};
1622
1623	PolyGenericCalculator::PolyGenericCalculator() :
1624	knownLayouts(), knownOffsets(), bufNamer( "_buf" )
1625	{}
1626
1627	/// Converts polymorphic type into a suitable monomorphic representation.
1628	/// Currently: __attribute__(( aligned(8) )) char[size_T];
1629	ast::Type * polyToMonoType( CodeLocation const & location,
1630	ast::Type const * declType ) {
1631	auto charType = new ast::BasicType( ast::BasicType::Char );
1632	auto size = new ast::NameExpr( location,
1633	sizeofName( Mangle::mangleType( declType ) ) );
1634	auto ret = new ast::ArrayType( charType, size,
1635	ast::VariableLen, ast::DynamicDim, ast::CV::Qualifiers() );
1636	ret->attributes.emplace_back( new ast::Attribute( "aligned",
1637	{ ast::ConstantExpr::from_int( location, 8 ) } ) );
1638	return ret;
1639	}
1640
1641	void PolyGenericCalculator::previsit( ast::FunctionDecl const * decl ) {
1642	GuardScope( *this );
1643	beginTypeScope( decl->type );
1644	}
1645
1646	void PolyGenericCalculator::previsit( ast::TypedefDecl const * decl ) {
1647	assertf( false, "All typedef declarations should be removed." );
1648	beginTypeScope( decl->base );
1649	}
1650
1651	void PolyGenericCalculator::previsit( ast::TypeDecl const * decl ) {
1652	addToTypeVarMap( decl, scopeTypeVars );
1653	}
1654
1655	ast::Decl const * PolyGenericCalculator::postvisit(
1656	ast::TypeDecl const * decl ) {
1657	ast::Type const * base = decl->base;
1658	if ( nullptr == base ) return decl;
1659
1660	// Add size/align variables for opaque type declarations.
1661	ast::TypeInstType inst( decl->name, decl );
1662	std::string typeName = Mangle::mangleType( &inst );
1663
1664	ast::ObjectDecl * sizeDecl = new ast::ObjectDecl( decl->location,
1665	sizeofName( typeName ), makeLayoutCType(),
1666	new ast::SingleInit( decl->location,
1667	new ast::SizeofExpr( decl->location, deepCopy( base ) )
1668	)
1669	);
1670	ast::ObjectDecl * alignDecl = new ast::ObjectDecl( decl->location,
1671	alignofName( typeName ), makeLayoutCType(),
1672	new ast::SingleInit( decl->location,
1673	new ast::AlignofExpr( decl->location, deepCopy( base ) )
1674	)
1675	);
1676
1677	// Ensure that the initializing sizeof/alignof exprs are properly mutated.
1678	sizeDecl->accept( *visitor );
1679	alignDecl->accept( *visitor );
1680
1681	// A little trick to replace this with two declarations.
1682	// Adding after makes sure that there is no conflict with adding stmts.
1683	declsToAddAfter.push_back( alignDecl );
1684	return sizeDecl;
1685	}
1686
1687	ast::StructDecl const * PolyGenericCalculator::previsit(
1688	ast::StructDecl const * decl ) {
1689	auto mutDecl = mutate( decl );
1690	mutateMembers( mutDecl );
1691	return mutDecl;
1692	}
1693
1694	ast::UnionDecl const * PolyGenericCalculator::previsit(
1695	ast::UnionDecl const * decl ) {
1696	auto mutDecl = mutate( decl );
1697	mutateMembers( mutDecl );
1698	return mutDecl;
1699	}
1700
1701	ast::DeclStmt const * PolyGenericCalculator::previsit( ast::DeclStmt const * stmt ) {
1702	ast::ObjectDecl const * decl = stmt->decl.as<ast::ObjectDecl>();
1703	if ( !decl \|\| !findGeneric( decl->location, decl->type ) ) {
1704	return stmt;
1705	}
1706
1707	// Change initialization of a polymorphic value object to allocate via a
1708	// variable-length-array (alloca cannot be safely used in loops).
1709	ast::ObjectDecl * newBuf = new ast::ObjectDecl( decl->location,
1710	bufNamer.newName(),
1711	polyToMonoType( decl->location, decl->type ),
1712	nullptr, {}, ast::Linkage::C
1713	);
1714	stmtsToAddBefore.push_back( new ast::DeclStmt( stmt->location, newBuf ) );
1715
1716	// If the object has a cleanup attribute, the clean-up should be on the
1717	// buffer, not the pointer. [Perhaps this should be lifted?]
1718	auto matchAndMove = [newBuf]( ast::ptr<ast::Attribute> & attr ) {
1719	if ( "cleanup" == attr->name ) {
1720	newBuf->attributes.push_back( attr );
1721	return true;
1722	}
1723	return false;
1724	};
1725
1726	auto mutDecl = mutate( decl );
1727
1728	// Forally, side effects are not safe in this function. But it works.
1729	erase_if( mutDecl->attributes, matchAndMove );
1730
1731	mutDecl->init = new ast::SingleInit( decl->location,
1732	new ast::VariableExpr( decl->location, newBuf ) );
1733
1734	return ast::mutate_field( stmt, &ast::DeclStmt::decl, mutDecl );
1735	}
1736
1737	/// Checks if memberDecl matches the decl from an aggregate.
1738	bool isMember( ast::DeclWithType const * memberDecl, ast::Decl const * decl ) {
1739	// No matter the field, if the name is different it is not the same.
1740	if ( memberDecl->name != decl->name ) {
1741	return false;
1742	}
1743
1744	if ( memberDecl->name.empty() ) {
1745	// Plan-9 Field: Match on unique_id.
1746	return ( memberDecl->uniqueId == decl->uniqueId );
1747	}
1748
1749	ast::DeclWithType const * declWithType =
1750	strict_dynamic_cast<ast::DeclWithType const *>( decl );
1751
1752	if ( memberDecl->mangleName.empty() \|\| declWithType->mangleName.empty() ) {
1753	// Tuple-Element Field: Expect neither had mangled name;
1754	// accept match on simple name (like field_2) only.
1755	assert( memberDecl->mangleName.empty() );
1756	assert( declWithType->mangleName.empty() );
1757	return true;
1758	}
1759
1760	// Ordinary Field: Use full name to accommodate overloading.
1761	return ( memberDecl->mangleName == declWithType->mangleName );
1762	}
1763
1764	/// Finds the member in the base list that matches the given declaration;
1765	/// returns its index, or -1 if not present.
1766	long findMember( ast::DeclWithType const * memberDecl,
1767	const ast::vector<ast::Decl> & baseDecls ) {
1768	for ( auto const & [index, value] : enumerate( baseDecls ) ) {
1769	if ( isMember( memberDecl, value.get() ) ) {
1770	return index;
1771	}
1772	}
1773	return -1;
1774	}
1775
1776	/// Returns an index expression into the offset array for a type.
1777	ast::Expr * makeOffsetIndex( CodeLocation const & location,
1778	ast::Type const * objectType, long i ) {
1779	std::string name = offsetofName( Mangle::mangleType( objectType ) );
1780	return ast::UntypedExpr::createCall( location, "?[?]", {
1781	new ast::NameExpr( location, name ),
1782	ast::ConstantExpr::from_ulong( location, i ),
1783	} );
1784	}
1785
1786	ast::Expr const * PolyGenericCalculator::postvisit(
1787	ast::MemberExpr const * expr ) {
1788	// Only mutate member expressions for polymorphic types.
1789	ast::Type const * objectType = hasPolyBase(
1790	expr->aggregate->result, scopeTypeVars
1791	);
1792	if ( !objectType ) return expr;
1793	// Ensure layout for this type is available.
1794	// The boolean result is ignored.
1795	findGeneric( expr->location, objectType );
1796
1797	// Replace member expression with dynamically-computed layout expression.
1798	ast::Expr * newMemberExpr = nullptr;
1799	if ( auto structType = dynamic_cast<ast::StructInstType const *>( objectType ) ) {
1800	long offsetIndex = findMember( expr->member, structType->base->members );
1801	if ( -1 == offsetIndex ) return expr;
1802
1803	// Replace member expression with pointer to struct plus offset.
1804	ast::UntypedExpr * fieldLoc = new ast::UntypedExpr( expr->location,
1805	new ast::NameExpr( expr->location, "?+?" ) );
1806	ast::Expr * aggr = deepCopy( expr->aggregate );
1807	aggr->env = nullptr;
1808	fieldLoc->args.push_back( aggr );
1809	fieldLoc->args.push_back(
1810	makeOffsetIndex( expr->location, objectType, offsetIndex ) );
1811	fieldLoc->result = deepCopy( expr->result );
1812	newMemberExpr = fieldLoc;
1813	// Union members are all at offset zero, so just use the aggregate expr.
1814	} else if ( dynamic_cast<ast::UnionInstType const *>( objectType ) ) {
1815	ast::Expr * aggr = deepCopy( expr->aggregate );
1816	aggr->env = nullptr;
1817	aggr->result = deepCopy( expr->result );
1818	newMemberExpr = aggr;
1819	} else {
1820	return expr;
1821	}
1822	assert( newMemberExpr );
1823
1824	// Must apply the generic substitution to the member type to handle cases
1825	// where the member is a generic parameter subsituted by a known concrete
1826	// type. [ex]
1827	// forall( T ) struct Box { T x; }
1828	// forall( T ) void f() {
1829	// Box( T * ) b; b.x;
1830	// }
1831	// TODO: expr->result should be exactly expr->member->get_type() after
1832	// substitution, so it doesn't seem like it should be necessary to apply
1833	// the substitution manually. For some reason this is not currently the
1834	// case. This requires more investigation.
1835	ast::ptr<ast::Type> memberType = deepCopy( expr->member->get_type() );
1836	ast::TypeSubstitution sub = genericSubstitution( objectType );
1837	sub.apply( memberType );
1838
1839	// Not all members of a polymorphic type are themselves of a polymorphic
1840	// type; in this cas the member expression should be wrapped and
1841	// dereferenced to form an lvalue.
1842	if ( !isPolyType( memberType, scopeTypeVars ) ) {
1843	auto ptrCastExpr = new ast::CastExpr( expr->location, newMemberExpr,
1844	new ast::PointerType( memberType ) );
1845	auto derefExpr = ast::UntypedExpr::createDeref( expr->location,
1846	ptrCastExpr );
1847	newMemberExpr = derefExpr;
1848	}
1849
1850	return newMemberExpr;
1851	}
1852
1853	void PolyGenericCalculator::previsit( ast::AddressExpr const * expr ) {
1854	GuardValue( addrMember ) = expr->arg.as<ast::MemberExpr>();
1855	}
1856
1857	ast::Expr const * PolyGenericCalculator::postvisit(
1858	ast::AddressExpr const * expr ) {
1859	// arg has to have been a MemberExpr and has been mutated.
1860	if ( nullptr == addrMember \|\| expr->arg == addrMember ) {
1861	return expr;
1862	}
1863	ast::UntypedExpr const * untyped = expr->arg.as<ast::UntypedExpr>();
1864	if ( !untyped \|\| getFunctionName( untyped ) != "?+?" ) {
1865	return expr;
1866	}
1867	// MemberExpr was converted to pointer + offset; and it is not valid C to
1868	// take the address of an addition, so strip away the address-of.
1869	// It also preserves the env value.
1870	return ast::mutate_field( expr->arg.get(), &ast::Expr::env, expr->env );
1871	}
1872
1873	ast::Expr const * PolyGenericCalculator::postvisit(
1874	ast::SizeofExpr const * expr ) {
1875	ast::Type const * type = expr->type ? expr->type : expr->expr->result;
1876	ast::Expr const * gen = genSizeof( expr->location, type );
1877	return ( gen ) ? gen : expr;
1878	}
1879
1880	ast::Expr const * PolyGenericCalculator::postvisit(
1881	ast::AlignofExpr const * expr ) {
1882	ast::Type const * type = expr->type ? expr->type : expr->expr->result;
1883	if ( findGeneric( expr->location, type ) ) {
1884	return new ast::NameExpr( expr->location,
1885	alignofName( Mangle::mangleType( type ) ) );
1886	} else {
1887	return expr;
1888	}
1889	}
1890
1891	ast::Expr const * PolyGenericCalculator::postvisit(
1892	ast::OffsetofExpr const * expr ) {
1893	ast::Type const * type = expr->type;
1894	if ( !findGeneric( expr->location, type ) ) return expr;
1895
1896	// Structures replace offsetof expression with an index into offset array.
1897	if ( auto structType = dynamic_cast<ast::StructInstType const *>( type ) ) {
1898	long offsetIndex = findMember( expr->member, structType->base->members );
1899	if ( -1 == offsetIndex ) return expr;
1900
1901	return makeOffsetIndex( expr->location, type, offsetIndex );
1902	// All union members are at offset zero.
1903	} else if ( dynamic_cast<ast::UnionInstType const *>( type ) ) {
1904	return ast::ConstantExpr::from_ulong( expr->location, 0 );
1905	} else {
1906	return expr;
1907	}
1908	}
1909
1910	ast::Expr const * PolyGenericCalculator::postvisit(
1911	ast::OffsetPackExpr const * expr ) {
1912	ast::StructInstType const * type = expr->type;
1913
1914	// Pull offset back from generated type information.
1915	if ( findGeneric( expr->location, type ) ) {
1916	return new ast::NameExpr( expr->location,
1917	offsetofName( Mangle::mangleType( type ) ) );
1918	}
1919
1920	std::string offsetName = offsetofName( Mangle::mangleType( type ) );
1921	// Use the already generated offsets for this type.
1922	if ( knownOffsets.contains( offsetName ) ) {
1923	return new ast::NameExpr( expr->location, offsetName );
1924	}
1925
1926	knownOffsets.insert( offsetName );
1927
1928	// Build initializer list for offset array.
1929	ast::vector<ast::Init> inits;
1930	for ( ast::ptr<ast::Decl> const & member : type->base->members ) {
1931	auto memberDecl = member.as<ast::DeclWithType>();
1932	assertf( memberDecl, "Requesting offset of non-DWT member: %s",
1933	toCString( member ) );
1934	inits.push_back( new ast::SingleInit( expr->location,
1935	new ast::OffsetofExpr( expr->location,
1936	deepCopy( type ),
1937	memberDecl
1938	)
1939	) );
1940	}
1941
1942	auto offsetArray = makeVar( expr->location, offsetName,
1943	new ast::ArrayType(
1944	makeLayoutType(),
1945	ast::ConstantExpr::from_ulong( expr->location, inits.size() ),
1946	ast::FixedLen,
1947	ast::DynamicDim
1948	),
1949	new ast::ListInit( expr->location, std::move( inits ) )
1950	);
1951
1952	return new ast::VariableExpr( expr->location, offsetArray );
1953	}
1954
1955	void PolyGenericCalculator::beginScope() {
1956	knownLayouts.beginScope();
1957	knownOffsets.beginScope();
1958	}
1959
1960	void PolyGenericCalculator::endScope() {
1961	knownOffsets.endScope();
1962	knownLayouts.endScope();
1963	}
1964
1965	ast::ObjectDecl * PolyGenericCalculator::makeVar(
1966	CodeLocation const & location, std::string const & name,
1967	ast::Type const * type, ast::Init const * init ) {
1968	ast::ObjectDecl * ret = new ast::ObjectDecl( location, name, type, init );
1969	stmtsToAddBefore.push_back( new ast::DeclStmt( location, ret ) );
1970	return ret;
1971	}
1972
1973	/// Returns true if any of the otype parameters have a dynamic layout; and
1974	/// puts all otype parameters in the output list.
1975	bool findGenericParams(
1976	ast::vector<ast::Type> & out,
1977	ast::vector<ast::TypeDecl> const & baseParams,
1978	ast::vector<ast::Expr> const & typeParams ) {
1979	bool hasDynamicLayout = false;
1980
1981	for ( auto pair : group_iterate( baseParams, typeParams ) ) {
1982	auto baseParam = std::get<0>( pair );
1983	auto typeParam = std::get<1>( pair );
1984	if ( !baseParam->isComplete() ) continue;
1985	ast::TypeExpr const * typeExpr = typeParam.as<ast::TypeExpr>();
1986	assertf( typeExpr, "All type parameters should be type expressions." );
1987
1988	ast::Type const * type = typeExpr->type.get();
1989	out.push_back( type );
1990	if ( isPolyType( type ) ) hasDynamicLayout = true;
1991	}
1992
1993	return hasDynamicLayout;
1994	}
1995
1996	bool PolyGenericCalculator::findGeneric(
1997	CodeLocation const & location, ast::Type const * type ) {
1998	type = replaceTypeInst( type, typeSubs );
1999
2000	if ( auto inst = dynamic_cast<ast::TypeInstType const *>( type ) ) {
2001	// Assumes that getting put in the scopeTypeVars includes having the
2002	// layout variables set.
2003	if ( scopeTypeVars.contains( *inst ) ) {
2004	return true;
2005	}
2006	} else if ( auto inst = dynamic_cast<ast::StructInstType const *>( type ) ) {
2007	// Check if this type already has a layout generated for it.
2008	std::string typeName = Mangle::mangleType( type );
2009	if ( knownLayouts.contains( typeName ) ) return true;
2010
2011	// Check if any type parameters have dynamic layout;
2012	// If none do, this type is (or will be) monomorphized.
2013	ast::vector<ast::Type> sizedParams;
2014	if ( !findGenericParams( sizedParams,
2015	inst->base->params, inst->params ) ) {
2016	return false;
2017	}
2018
2019	// Insert local variables for layout and generate call to layout
2020	// function.
2021	// Done early so as not to interfere with the later addition of
2022	// parameters to the layout call.
2023	knownLayouts.insert( typeName );
2024
2025	int memberCount = inst->base->members.size();
2026	if ( 0 == memberCount ) {
2027	// All empty structures have the same layout (size 1, align 1).
2028	makeVar( location,
2029	sizeofName( typeName ), makeLayoutType(),
2030	new ast::SingleInit( location,
2031	ast::ConstantExpr::from_ulong( location, 1 ) ) );
2032	makeVar( location,
2033	alignofName( typeName ), makeLayoutType(),
2034	new ast::SingleInit( location,
2035	ast::ConstantExpr::from_ulong( location, 1 ) ) );
2036	// Since 0-length arrays are forbidden in C, skip the offset array.
2037	} else {
2038	ast::ObjectDecl const * sizeofVar = makeVar( location,
2039	sizeofName( typeName ), makeLayoutType(), nullptr );
2040	ast::ObjectDecl const * alignofVar = makeVar( location,
2041	alignofName( typeName ), makeLayoutType(), nullptr );
2042	ast::ObjectDecl const * offsetofVar = makeVar( location,
2043	offsetofName( typeName ),
2044	new ast::ArrayType(
2045	makeLayoutType(),
2046	ast::ConstantExpr::from_int( location, memberCount ),
2047	ast::FixedLen,
2048	ast::DynamicDim
2049	),
2050	nullptr
2051	);
2052
2053	// Generate call to layout function.
2054	ast::UntypedExpr * layoutCall = new ast::UntypedExpr( location,
2055	new ast::NameExpr( location, layoutofName( inst->base ) ),
2056	{
2057	new ast::AddressExpr(
2058	new ast::VariableExpr( location, sizeofVar ) ),
2059	new ast::AddressExpr(
2060	new ast::VariableExpr( location, alignofVar ) ),
2061	new ast::VariableExpr( location, offsetofVar ),
2062	} );
2063
2064	addSTypeParamsToLayoutCall( layoutCall, sizedParams );
2065
2066	stmtsToAddBefore.emplace_back(
2067	new ast::ExprStmt( location, layoutCall ) );
2068	}
2069
2070	return true;
2071	} else if ( auto inst = dynamic_cast<ast::UnionInstType const *>( type ) ) {
2072	// Check if this type already has a layout generated for it.
2073	std::string typeName = Mangle::mangleType( type );
2074	if ( knownLayouts.contains( typeName ) ) return true;
2075
2076	// Check if any type parameters have dynamic layout;
2077	// If none do, this type is (or will be) monomorphized.
2078	ast::vector<ast::Type> sizedParams;
2079	if ( !findGenericParams( sizedParams,
2080	inst->base->params, inst->params ) ) {
2081	return false;
2082	}
2083
2084	// Insert local variables for layout and generate call to layout
2085	// function.
2086	// Done early so as not to interfere with the later addition of
2087	// parameters to the layout call.
2088	knownLayouts.insert( typeName );
2089
2090	ast::ObjectDecl * sizeofVar = makeVar( location,
2091	sizeofName( typeName ), makeLayoutType() );
2092	ast::ObjectDecl * alignofVar = makeVar( location,
2093	alignofName( typeName ), makeLayoutType() );
2094
2095	ast::UntypedExpr * layoutCall = new ast::UntypedExpr( location,
2096	new ast::NameExpr( location, layoutofName( inst->base ) ),
2097	{
2098	new ast::AddressExpr(
2099	new ast::VariableExpr( location, sizeofVar ) ),
2100	new ast::AddressExpr(
2101	new ast::VariableExpr( location, alignofVar ) ),
2102	} );
2103
2104	addSTypeParamsToLayoutCall( layoutCall, sizedParams );
2105
2106	stmtsToAddBefore.emplace_back(
2107	new ast::ExprStmt( location, layoutCall ) );
2108
2109	return true;
2110	}
2111	return false;
2112	}
2113
2114	void PolyGenericCalculator::addSTypeParamsToLayoutCall(
2115	ast::UntypedExpr * layoutCall,
2116	const ast::vector<ast::Type> & otypeParams ) {
2117	CodeLocation const & location = layoutCall->location;
2118	ast::vector<ast::Expr> & args = layoutCall->args;
2119	for ( ast::ptr<ast::Type> const & param : otypeParams ) {
2120	if ( findGeneric( location, param ) ) {
2121	// Push size/align vars for a generic parameter back.
2122	std::string paramName = Mangle::mangleType( param );
2123	args.emplace_back(
2124	new ast::NameExpr( location, sizeofName( paramName ) ) );
2125	args.emplace_back(
2126	new ast::NameExpr( location, alignofName( paramName ) ) );
2127	} else {
2128	args.emplace_back(
2129	new ast::SizeofExpr( location, ast::deepCopy( param ) ) );
2130	args.emplace_back(
2131	new ast::AlignofExpr( location, ast::deepCopy( param ) ) );
2132	}
2133	}
2134	}
2135
2136	void PolyGenericCalculator::mutateMembers( ast::AggregateDecl * aggr ) {
2137	std::set<std::string> genericParams;
2138	for ( ast::ptr<ast::TypeDecl> const & decl : aggr->params ) {
2139	genericParams.insert( decl->name );
2140	}
2141	for ( ast::ptr<ast::Decl> & decl : aggr->members ) {
2142	auto field = decl.as<ast::ObjectDecl>();
2143	if ( nullptr == field ) continue;
2144
2145	ast::Type const * type = replaceTypeInst( field->type, typeSubs );
2146	auto typeInst = dynamic_cast<ast::TypeInstType const *>( type );
2147	if ( nullptr == typeInst ) continue;
2148
2149	// Do not try to monoporphize generic parameters.
2150	if ( scopeTypeVars.contains( ast::TypeEnvKey( *typeInst ) ) &&
2151	!genericParams.count( typeInst->name ) ) {
2152	// Polymorphic aggregate members should be converted into
2153	// monomorphic members. Using char[size_T] here respects
2154	// the expected sizing rules of an aggregate type.
2155	decl = ast::mutate_field( field, &ast::ObjectDecl::type,
2156	polyToMonoType( field->location, field->type ) );
2157	}
2158	}
2159	}
2160
2161	ast::Expr const * PolyGenericCalculator::genSizeof(
2162	CodeLocation const & location, ast::Type const * type ) {
2163	if ( auto * array = dynamic_cast<ast::ArrayType const *>( type ) ) {
2164	// Generate calculated size for possibly generic array.
2165	ast::Expr const * sizeofBase = genSizeof( location, array->base );
2166	if ( nullptr == sizeofBase ) return nullptr;
2167	ast::Expr const * dim = array->dimension;
2168	return makeOp( location, "?*?", sizeofBase, dim );
2169	} else if ( findGeneric( location, type ) ) {
2170	// Generate calculated size for generic type.
2171	return new ast::NameExpr( location, sizeofName(
2172	Mangle::mangleType( type ) ) );
2173	} else {
2174	return nullptr;
2175	}
2176	}
2177
2178	void PolyGenericCalculator::beginTypeScope( ast::Type const * type ) {
2179	GuardScope( scopeTypeVars );
2180	makeTypeVarMap( type, scopeTypeVars );
2181	}
2182
2183	// --------------------------------------------------------------------------
2184	/// Removes unneeded or incorrect type information.
2185	/// * Replaces initialization of polymorphic values with alloca.
2186	/// * Replaces declaration of dtype/ftype with appropriate void expression.
2187	/// * Replaces sizeof expressions of polymorphic types with a variable.
2188	/// * Strips fields from generic structure declarations.
2189	struct Eraser final :
2190	public ast::WithGuards {
2191	void guardTypeVarMap( ast::Type const * type ) {
2192	GuardScope( scopeTypeVars );
2193	makeTypeVarMap( type, scopeTypeVars );
2194	}
2195
2196	ast::ObjectDecl const * previsit( ast::ObjectDecl const * decl );
2197	ast::FunctionDecl const * previsit( ast::FunctionDecl const * decl );
2198	ast::FunctionDecl const * postvisit( ast::FunctionDecl const * decl );
2199	ast::TypedefDecl const * previsit( ast::TypedefDecl const * decl );
2200	ast::StructDecl const * previsit( ast::StructDecl const * decl );
2201	ast::UnionDecl const * previsit( ast::UnionDecl const * decl );
2202	void previsit( ast::TypeDecl const * decl );
2203	void previsit( ast::PointerType const * type );
2204	void previsit( ast::FunctionType const * type );
2205	public:
2206	TypeVarMap scopeTypeVars;
2207	};
2208
2209	ast::ObjectDecl const * Eraser::previsit( ast::ObjectDecl const * decl ) {
2210	guardTypeVarMap( decl->type );
2211	return scrubAllTypeVars( decl );
2212	}
2213
2214	ast::FunctionDecl const * Eraser::previsit( ast::FunctionDecl const * decl ) {
2215	guardTypeVarMap( decl->type );
2216	return scrubAllTypeVars( decl );
2217	}
2218
2219	ast::FunctionDecl const * Eraser::postvisit( ast::FunctionDecl const * decl ) {
2220	if ( decl->type_params.empty() ) return decl;
2221	auto mutDecl = mutate( decl );
2222	mutDecl->type_params.clear();
2223	return mutDecl;
2224	}
2225
2226	ast::TypedefDecl const * Eraser::previsit( ast::TypedefDecl const * decl ) {
2227	guardTypeVarMap( decl->base );
2228	return scrubAllTypeVars( decl );
2229	}
2230
2231	/// Strips the members from a generic aggregate.
2232	template<typename node_t>
2233	node_t const * stripGenericMembers( node_t const * decl ) {
2234	if ( decl->params.empty() ) return decl;
2235	auto mutDecl = ast::mutate( decl );
2236	mutDecl->members.clear();
2237	return mutDecl;
2238	}
2239
2240	ast::StructDecl const * Eraser::previsit( ast::StructDecl const * decl ) {
2241	return stripGenericMembers( decl );
2242	}
2243
2244	ast::UnionDecl const * Eraser::previsit( ast::UnionDecl const * decl ) {
2245	return stripGenericMembers( decl );
2246	}
2247
2248	void Eraser::previsit( ast::TypeDecl const * decl ) {
2249	addToTypeVarMap( decl, scopeTypeVars );
2250	}
2251
2252	void Eraser::previsit( ast::PointerType const * type ) {
2253	guardTypeVarMap( type );
2254	}
2255
2256	void Eraser::previsit( ast::FunctionType const * type ) {
2257	guardTypeVarMap( type );
2258	}
2259
2260	} // namespace
2261
2262	// --------------------------------------------------------------------------
2263	void box( ast::TranslationUnit & translationUnit ) {
2264	ast::Pass<LayoutFunctionBuilder>::run( translationUnit );
2265	ast::Pass<CallAdapter>::run( translationUnit );
2266	ast::Pass<DeclAdapter>::run( translationUnit );
2267	ast::Pass<RewireAdapters>::run( translationUnit );
2268	ast::Pass<PolyGenericCalculator>::run( translationUnit );
2269	ast::Pass<Eraser>::run( translationUnit );
2270	}
2271
2272	} // namespace GenPoly
2273
2274	// Local Variables: //
2275	// tab-width: 4 //
2276	// mode: c++ //
2277	// compile-command: "make install" //
2278	// End: //

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