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source: src/GenPoly/Box.cpp @ 917f67dd

Last change on this file since 917f67dd was b6f2e7ab, checked in by Andrew Beach <ajbeach@…>, 2 months ago
Removed SizeofExpr::expr and AlignofExpr::expr, expressions that would be stored there are wrapped in TypeofType? and stored in the type field. Some special cases to hide the typeof in code generation were added. In addition, initializer length is calculated in more cases so that the full type of more arrays is known sooner. Other than that, most of the code changes were just stripping out the conditional code and checks no longer needed. Some tests had to be updated, because the typeof is not hidden in dumps and the resolver replaces known typeof expressions with the type. The extension case caused some concern but it appears that just hides warnings in the expression which no longer exists.
Property mode set to `100644`
File size: 84.3 KB

Rev	Line
[1ee0a4da]	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	//
[83fd57d]	7	// Box.cpp -- Implement polymorphic function calls and types.
[1ee0a4da]	8	//
	9	// Author : Andrew Beach
	10	// Created On : Thr Oct 6 13:39:00 2022
[ca9d65e]	11	// Last Modified By : Peter A. Buhr
	12	// Last Modified On : Thu Dec 14 17:42:17 2023
	13	// Update Count : 7
[1ee0a4da]	14	//
	15
[c92bdcc]	16	#include "Box.hpp"
[1ee0a4da]	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
[c92bdcc]	26	#include "CodeGen/OperatorTable.hpp" // for isAssignment
[be4335b]	27	#include "Common/Iterate.hpp" // for group_iterate
[c92bdcc]	28	#include "Common/ScopedMap.hpp" // for ScopedMap
[be4335b]	29	#include "Common/ToString.hpp" // for toCString
[c92bdcc]	30	#include "Common/UniqueName.hpp" // for UniqueName
	31	#include "GenPoly/FindFunction.hpp" // for findFunction
[82d5816]	32	#include "GenPoly/GenPoly.hpp" // for getFunctionType, isPolyType, ...
[c92bdcc]	33	#include "GenPoly/Lvalue.hpp" // for generalizedLvalue
	34	#include "GenPoly/ScopedSet.hpp" // for ScopedSet
[d787828d]	35	#include "GenPoly/ScrubTypeVars.hpp" // for scrubTypeVars, scrubAllTypeVars
[c92bdcc]	36	#include "ResolvExpr/Unify.hpp" // for typesCompatible
	37	#include "SymTab/Mangler.hpp" // for mangle, mangleType
[1ee0a4da]	38
	39	namespace GenPoly {
	40
	41	namespace {
	42
[dd900b5]	43	/// The layout type is used to represent sizes, alignments and offsets.
	44	ast::BasicType * makeLayoutType() {
[7a780ad]	45	return new ast::BasicType( ast::BasicKind::LongUnsignedInt );
[dd900b5]	46	}
	47
	48	/// Fixed version of layout type (just adding a 'C' in C++ style).
	49	ast::BasicType * makeLayoutCType() {
[7a780ad]	50	return new ast::BasicType( ast::BasicKind::LongUnsignedInt,
[dd900b5]	51	ast::CV::Qualifiers( ast::CV::Const ) );
	52	}
	53
[1ee0a4da]	54	// --------------------------------------------------------------------------
	55	/// Adds layout-generation functions to polymorphic types.
	56	struct LayoutFunctionBuilder final :
	57	public ast::WithDeclsToAdd<>,
	58	public ast::WithShortCircuiting,
	59	public ast::WithVisitorRef<LayoutFunctionBuilder> {
	60	void previsit( ast::StructDecl const * decl );
	61	void previsit( ast::UnionDecl const * decl );
	62	};
	63
	64	/// Get all sized type declarations; those that affect a layout function.
	65	ast::vector<ast::TypeDecl> takeSizedParams(
	66	ast::vector<ast::TypeDecl> const & decls ) {
	67	ast::vector<ast::TypeDecl> sizedParams;
	68	for ( ast::ptr<ast::TypeDecl> const & decl : decls ) {
	69	if ( decl->isComplete() ) {
	70	sizedParams.emplace_back( decl );
	71	}
	72	}
	73	return sizedParams;
	74	}
	75
	76	/// Adds parameters for otype size and alignment to a function type.
[4604bf5]	77	void addSTypeParams(
[0bf0b97]	78	ast::vector<ast::DeclWithType> & params,
[1ee0a4da]	79	ast::vector<ast::TypeDecl> const & sizedParams ) {
	80	for ( ast::ptr<ast::TypeDecl> const & sizedParam : sizedParams ) {
	81	ast::TypeInstType inst( sizedParam );
	82	std::string paramName = Mangle::mangleType( &inst );
[0bf0b97]	83	params.emplace_back( new ast::ObjectDecl(
[1ee0a4da]	84	sizedParam->location,
	85	sizeofName( paramName ),
[dd900b5]	86	makeLayoutCType()
[1ee0a4da]	87	) );
[0bf0b97]	88	params.emplace_back( new ast::ObjectDecl(
[1ee0a4da]	89	sizedParam->location,
	90	alignofName( paramName ),
[dd900b5]	91	makeLayoutCType()
[1ee0a4da]	92	) );
	93	}
	94	}
	95
[dd900b5]	96	ast::Type * makeLayoutOutType() {
	97	return new ast::PointerType( makeLayoutType() );
[1ee0a4da]	98	}
	99
	100	struct LayoutData {
	101	ast::FunctionDecl * function;
	102	ast::ObjectDecl * sizeofParam;
	103	ast::ObjectDecl * alignofParam;
	104	ast::ObjectDecl * offsetofParam;
	105	};
	106
	107	LayoutData buildLayoutFunction(
	108	CodeLocation const & location, ast::AggregateDecl const * aggr,
[0bf0b97]	109	ast::vector<ast::TypeDecl> const & sizedParams,
[1ee0a4da]	110	bool isInFunction, bool isStruct ) {
	111	ast::ObjectDecl * sizeParam = new ast::ObjectDecl(
	112	location,
	113	sizeofName( aggr->name ),
[dd900b5]	114	makeLayoutOutType()
[1ee0a4da]	115	);
	116	ast::ObjectDecl * alignParam = new ast::ObjectDecl(
	117	location,
	118	alignofName( aggr->name ),
[dd900b5]	119	makeLayoutOutType()
[1ee0a4da]	120	);
	121	ast::ObjectDecl * offsetParam = nullptr;
	122	ast::vector<ast::DeclWithType> params = { sizeParam, alignParam };
	123	if ( isStruct ) {
	124	offsetParam = new ast::ObjectDecl(
	125	location,
	126	offsetofName( aggr->name ),
[dd900b5]	127	makeLayoutOutType()
[1ee0a4da]	128	);
	129	params.push_back( offsetParam );
	130	}
[0bf0b97]	131	addSTypeParams( params, sizedParams );
[1ee0a4da]	132
	133	// Routines at global scope marked "static" to prevent multiple
	134	// definitions is separate translation units because each unit generates
	135	// copies of the default routines for each aggregate.
	136	ast::FunctionDecl * layoutDecl = new ast::FunctionDecl(
	137	location,
	138	layoutofName( aggr ),
	139	{}, // forall
	140	{}, // assertions
	141	std::move( params ),
	142	{}, // returns
	143	new ast::CompoundStmt( location ),
	144	isInFunction ? ast::Storage::Classes() : ast::Storage::Static,
	145	ast::Linkage::AutoGen,
	146	{}, // attrs
	147	ast::Function::Inline,
	148	ast::FixedArgs
	149	);
	150	layoutDecl->fixUniqueId();
	151	return LayoutData{ layoutDecl, sizeParam, alignParam, offsetParam };
	152	}
	153
	154	/// Makes a binary operation.
	155	ast::Expr * makeOp( CodeLocation const & location, std::string const & name,
	156	ast::Expr const * lhs, ast::Expr const * rhs ) {
	157	return new ast::UntypedExpr( location,
	158	new ast::NameExpr( location, name ), { lhs, rhs } );
	159	}
	160
	161	/// Make a binary operation and wrap it in a statement.
	162	ast::Stmt * makeOpStmt( CodeLocation const & location, std::string const & name,
	163	ast::Expr const * lhs, ast::Expr const * rhs ) {
	164	return new ast::ExprStmt( location, makeOp( location, name, lhs, rhs ) );
	165	}
	166
	167	/// Returns the dereference of a local pointer variable.
	168	ast::Expr * derefVar(
	169	CodeLocation const & location, ast::ObjectDecl const * var ) {
	170	return ast::UntypedExpr::createDeref( location,
	171	new ast::VariableExpr( location, var ) );
	172	}
	173
	174	/// Makes an if-statement with a single-expression then and no else.
	175	ast::Stmt * makeCond( CodeLocation const & location,
	176	ast::Expr const * cond, ast::Expr const * thenPart ) {
	177	return new ast::IfStmt( location,
	178	cond, new ast::ExprStmt( location, thenPart ), nullptr );
	179	}
	180
	181	/// Makes a statement that aligns lhs to rhs (rhs should be an integer
	182	/// power of two).
	183	ast::Stmt * makeAlignTo( CodeLocation const & location,
	184	ast::Expr const * lhs, ast::Expr const * rhs ) {
	185	// Check that the lhs is zeroed out to the level of rhs.
	186	ast::Expr * ifCond = makeOp( location, "?&?", lhs,
	187	makeOp( location, "?-?", rhs,
	188	ast::ConstantExpr::from_ulong( location, 1 ) ) );
	189	// If not aligned, increment to alignment.
	190	ast::Expr * ifExpr = makeOp( location, "?+=?", ast::deepCopy( lhs ),
	191	makeOp( location, "?-?", ast::deepCopy( rhs ),
	192	ast::deepCopy( ifCond ) ) );
	193	return makeCond( location, ifCond, ifExpr );
	194	}
	195
	196	/// Makes a statement that assigns rhs to lhs if lhs < rhs.
	197	ast::Stmt * makeAssignMax( CodeLocation const & location,
	198	ast::Expr const * lhs, ast::Expr const * rhs ) {
	199	return makeCond( location,
	200	makeOp( location, "?<?", ast::deepCopy( lhs ), ast::deepCopy( rhs ) ),
	201	makeOp( location, "?=?", lhs, rhs ) );
	202	}
	203
	204	void LayoutFunctionBuilder::previsit( ast::StructDecl const * decl ) {
	205	// Do not generate layout function for empty tag structures.
	206	visit_children = false;
	207	if ( decl->members.empty() ) return;
	208
	209	// Get parameters that can change layout, exiting early if none.
	210	ast::vector<ast::TypeDecl> sizedParams =
	211	takeSizedParams( decl->params );
	212	if ( sizedParams.empty() ) return;
	213
	214	CodeLocation const & location = decl->location;
	215
	216	// Build layout function signature.
[0bf0b97]	217	LayoutData layout = buildLayoutFunction(
	218	location, decl, sizedParams, isInFunction(), true );
[1ee0a4da]	219	ast::FunctionDecl * layoutDecl = layout.function;
	220	// Also return these or extract them from the parameter list?
	221	ast::ObjectDecl const * sizeofParam = layout.sizeofParam;
	222	ast::ObjectDecl const * alignofParam = layout.alignofParam;
	223	ast::ObjectDecl const * offsetofParam = layout.offsetofParam;
	224	assert( nullptr != layout.offsetofParam );
	225
	226	// Calculate structure layout in function body.
	227	// Initialize size and alignment to 0 and 1
	228	// (Will have at least one member to update size).
	229	auto & kids = layoutDecl->stmts.get_and_mutate()->kids;
	230	kids.emplace_back( makeOpStmt( location, "?=?",
	231	derefVar( location, sizeofParam ),
	232	ast::ConstantExpr::from_ulong( location, 0 )
	233	) );
	234	kids.emplace_back( makeOpStmt( location, "?=?",
	235	derefVar( location, alignofParam ),
	236	ast::ConstantExpr::from_ulong( location, 1 )
	237	) );
	238	// TODO: Polymorphic types will be out of the struct declaration scope.
[be4335b]	239	// This breaks invariants until it is corrected later.
[1ee0a4da]	240	for ( auto const & member : enumerate( decl->members ) ) {
	241	auto dwt = member.val.strict_as<ast::DeclWithType>();
	242	ast::Type const * memberType = dwt->get_type();
	243
	244	if ( 0 < member.idx ) {
	245	// Make sure all later members have padding to align them.
	246	kids.emplace_back( makeAlignTo( location,
	247	derefVar( location, sizeofParam ),
	248	new ast::AlignofExpr( location, ast::deepCopy( memberType ) )
	249	) );
	250	}
	251
	252	// Place current size in the current offset index.
	253	kids.emplace_back( makeOpStmt( location, "?=?",
	254	makeOp( location, "?[?]",
	255	new ast::VariableExpr( location, offsetofParam ),
	256	ast::ConstantExpr::from_ulong( location, member.idx ) ),
	257	derefVar( location, sizeofParam ) ) );
	258
	259	// Add member size to current size.
	260	kids.emplace_back( makeOpStmt( location, "?+=?",
	261	derefVar( location, sizeofParam ),
	262	new ast::SizeofExpr( location, ast::deepCopy( memberType ) ) ) );
	263
	264	// Take max of member alignment and global alignment.
	265	// (As align is always 2^n, this will always be a multiple of both.)
	266	kids.emplace_back( makeAssignMax( location,
	267	derefVar( location, alignofParam ),
	268	new ast::AlignofExpr( location, ast::deepCopy( memberType ) ) ) );
	269	}
	270	// Make sure the type is end-padded to a multiple of its alignment.
	271	kids.emplace_back( makeAlignTo( location,
	272	derefVar( location, sizeofParam ),
	273	derefVar( location, alignofParam ) ) );
	274
	275	declsToAddAfter.emplace_back( layoutDecl );
	276	}
	277
	278	void LayoutFunctionBuilder::previsit( ast::UnionDecl const * decl ) {
	279	visit_children = false;
	280	// Do not generate layout function for empty tag unions.
	281	if ( decl->members.empty() ) return;
	282
	283	// Get parameters that can change layout, exiting early if none.
	284	ast::vector<ast::TypeDecl> sizedParams =
	285	takeSizedParams( decl->params );
	286	if ( sizedParams.empty() ) return;
	287
	288	CodeLocation const & location = decl->location;
	289
	290	// Build layout function signature.
[0bf0b97]	291	LayoutData layout = buildLayoutFunction(
	292	location, decl, sizedParams, isInFunction(), false );
[1ee0a4da]	293	ast::FunctionDecl * layoutDecl = layout.function;
	294	// Also return these or extract them from the parameter list?
	295	ast::ObjectDecl const * sizeofParam = layout.sizeofParam;
	296	ast::ObjectDecl const * alignofParam = layout.alignofParam;
	297	assert( nullptr == layout.offsetofParam );
	298
	299	// Calculate union layout in function body.
	300	// Both are simply the maximum for union (actually align is always the
	301	// LCM, but with powers of two that is also the maximum).
	302	auto & kids = layoutDecl->stmts.get_and_mutate()->kids;
	303	kids.emplace_back( makeOpStmt( location,
	304	"?=?", derefVar( location, sizeofParam ),
	305	ast::ConstantExpr::from_ulong( location, 1 )
	306	) );
	307	kids.emplace_back( makeOpStmt( location,
	308	"?=?", derefVar( location, alignofParam ),
	309	ast::ConstantExpr::from_ulong( location, 1 )
	310	) );
	311	// TODO: Polymorphic types will be out of the union declaration scope.
[be4335b]	312	// This breaks invariants until it is corrected later.
[1ee0a4da]	313	for ( auto const & member : decl->members ) {
	314	auto dwt = member.strict_as<ast::DeclWithType>();
	315	ast::Type const * memberType = dwt->get_type();
	316
	317	// Take max member size and global size.
	318	kids.emplace_back( makeAssignMax( location,
	319	derefVar( location, sizeofParam ),
	320	new ast::SizeofExpr( location, ast::deepCopy( memberType ) )
	321	) );
	322
	323	// Take max of member alignment and global alignment.
	324	kids.emplace_back( makeAssignMax( location,
	325	derefVar( location, alignofParam ),
	326	new ast::AlignofExpr( location, ast::deepCopy( memberType ) )
	327	) );
	328	}
	329	kids.emplace_back( makeAlignTo( location,
	330	derefVar( location, sizeofParam ),
	331	derefVar( location, alignofParam ) ) );
	332
	333	declsToAddAfter.emplace_back( layoutDecl );
	334	}
	335
	336	// --------------------------------------------------------------------------
	337	/// Application expression transformer.
	338	/// * Replaces polymorphic return types with out-parameters.
	339	/// * Replaces call to polymorphic functions with adapter calls which handles
	340	/// dynamic arguments and return values.
	341	/// * Adds appropriate type variables to the function calls.
	342	struct CallAdapter final :
	343	public ast::WithConstTypeSubstitution,
	344	public ast::WithGuards,
	345	public ast::WithShortCircuiting,
	346	public ast::WithStmtsToAdd<>,
	347	public ast::WithVisitorRef<CallAdapter> {
	348	CallAdapter();
	349
	350	void previsit( ast::Decl const * decl );
	351	ast::FunctionDecl const * previsit( ast::FunctionDecl const * decl );
	352	void previsit( ast::TypeDecl const * decl );
	353	void previsit( ast::CommaExpr const * expr );
	354	ast::Expr const * postvisit( ast::ApplicationExpr const * expr );
	355	ast::Expr const * postvisit( ast::UntypedExpr const * expr );
	356	void previsit( ast::AddressExpr const * expr );
	357	ast::Expr const * postvisit( ast::AddressExpr const * expr );
	358	ast::ReturnStmt const * previsit( ast::ReturnStmt const * stmt );
	359
	360	void beginScope();
	361	void endScope();
	362	private:
	363	// Many helpers here use a mutable ApplicationExpr as an in/out parameter
	364	// instead of using the return value, to save on mutates and free up the
	365	// return value.
	366
[61e5d99]	367	/// Passes extra layout arguments for sized polymorphic type parameters.
[23a0e576]	368	void passTypeVars(
[1ee0a4da]	369	ast::ApplicationExpr * expr,
[23a0e576]	370	ast::vector<ast::Expr> & extraArgs,
[61e5d99]	371	ast::FunctionType const * funcType );
[1ee0a4da]	372	/// Wraps a function application with a new temporary for the
	373	/// out-parameter return value.
	374	ast::Expr const * addRetParam(
	375	ast::ApplicationExpr * expr, ast::Type const * retType );
	376	/// Wraps a function application returning a polymorphic type with a new
	377	/// temporary for the out-parameter return value.
	378	ast::Expr const * addDynRetParam(
	379	ast::ApplicationExpr * expr, ast::Type const * polyType );
	380	/// Modify a call so it passes the function through the correct adapter.
	381	ast::Expr const * applyAdapter(
	382	ast::ApplicationExpr * expr,
	383	ast::FunctionType const * function );
	384	/// Convert a single argument into its boxed form to pass the parameter.
	385	void boxParam( ast::ptr<ast::Expr> & arg,
	386	ast::Type const * formal, TypeVarMap const & exprTyVars );
	387	/// Box every argument from arg forward, matching the functionType
	388	/// parameter list. arg should point into expr's argument list.
	389	void boxParams(
[23a0e576]	390	ast::ApplicationExpr * expr,
	391	ast::Type const * polyRetType,
[1ee0a4da]	392	ast::FunctionType const * function,
	393	const TypeVarMap & typeVars );
	394	/// Adds the inferred parameters derived from the assertions of the
	395	/// expression to the call.
	396	void addInferredParams(
	397	ast::ApplicationExpr * expr,
[23a0e576]	398	ast::vector<ast::Expr> & extraArgs,
[1ee0a4da]	399	ast::FunctionType const * functionType,
	400	const TypeVarMap & typeVars );
	401	/// Stores assignment operators from assertion list in
	402	/// local map of assignment operations.
	403	void passAdapters(
	404	ast::ApplicationExpr * expr,
	405	ast::FunctionType const * type,
	406	const TypeVarMap & typeVars );
	407	/// Create an adapter function based on the type of the adaptee and the
	408	/// real type with the type substitutions applied.
	409	ast::FunctionDecl * makeAdapter(
	410	ast::FunctionType const * adaptee,
	411	ast::FunctionType const * realType,
	412	std::string const & mangleName,
	413	TypeVarMap const & typeVars,
	414	CodeLocation const & location ) const;
	415	/// Replaces intrinsic operator functions with their arithmetic desugaring.
	416	ast::Expr const * handleIntrinsics( ast::ApplicationExpr const * );
	417	/// Inserts a new temporary variable into the current scope with an
	418	/// auto-generated name.
	419	ast::ObjectDecl * makeTemporary(
	420	CodeLocation const & location, ast::Type const * type );
	421
[52a5262e]	422	TypeVarMap scopeTypeVars;
[1ee0a4da]	423	ScopedMap< std::string, ast::DeclWithType const * > adapters;
	424	std::map< ast::ApplicationExpr const , ast::Expr const > retVals;
	425	ast::DeclWithType const * retval;
	426	UniqueName tmpNamer;
	427	};
	428
	429	/// Replaces a polymorphic type with its concrete equivalant under the
	430	/// current environment (returns itself if concrete).
	431	/// If `doClone` is set to false, will not clone interior types
	432	ast::Type const * replaceWithConcrete(
	433	ast::Type const * type,
	434	ast::TypeSubstitution const & typeSubs,
	435	bool doCopy = true );
	436
	437	/// Replaces all the type parameters of a generic type with their
	438	/// concrete equivalents under the current environment.
	439	void replaceParametersWithConcrete(
	440	ast::vector<ast::Expr> & params,
	441	ast::TypeSubstitution const & typeSubs ) {
	442	for ( ast::ptr<ast::Expr> & paramExpr : params ) {
	443	ast::TypeExpr const * param = paramExpr.as<ast::TypeExpr>();
	444	assertf( param, "Aggregate parameters should be type expressions." );
	445	paramExpr = ast::mutate_field( param, &ast::TypeExpr::type,
	446	replaceWithConcrete( param->type.get(), typeSubs, false ) );
	447	}
	448	}
	449
	450	ast::Type const * replaceWithConcrete(
	451	ast::Type const * type,
	452	ast::TypeSubstitution const & typeSubs,
	453	bool doCopy ) {
	454	if ( auto instType = dynamic_cast<ast::TypeInstType const *>( type ) ) {
	455	ast::Type const * concrete = typeSubs.lookup( instType );
	456	return ( nullptr != concrete ) ? concrete : instType;
	457	} else if ( auto structType =
	458	dynamic_cast<ast::StructInstType const *>( type ) ) {
	459	ast::StructInstType * newType =
	460	doCopy ? ast::deepCopy( structType ) : ast::mutate( structType );
	461	replaceParametersWithConcrete( newType->params, typeSubs );
	462	return newType;
	463	} else if ( auto unionType =
	464	dynamic_cast<ast::UnionInstType const *>( type ) ) {
	465	ast::UnionInstType * newType =
	466	doCopy ? ast::deepCopy( unionType ) : ast::mutate( unionType );
	467	replaceParametersWithConcrete( newType->params, typeSubs );
	468	return newType;
	469	} else {
	470	return type;
	471	}
	472	}
	473
	474	std::string makePolyMonoSuffix(
	475	ast::FunctionType const * function,
	476	TypeVarMap const & typeVars ) {
	477	// If the return type or a parameter type involved polymorphic types,
	478	// then the adapter will need to take those polymorphic types as pointers.
	479	// Therefore, there can be two different functions with the same mangled
	480	// name, so we need to further mangle the names.
	481	std::stringstream name;
	482	for ( auto ret : function->returns ) {
	483	name << ( isPolyType( ret, typeVars ) ? 'P' : 'M' );
	484	}
	485	name << '_';
	486	for ( auto arg : function->params ) {
	487	name << ( isPolyType( arg, typeVars ) ? 'P' : 'M' );
	488	}
	489	return name.str();
	490	}
	491
	492	std::string mangleAdapterName(
	493	ast::FunctionType const * function,
	494	TypeVarMap const & typeVars ) {
	495	return Mangle::mangle( function, {} )
	496	+ makePolyMonoSuffix( function, typeVars );
	497	}
	498
	499	std::string makeAdapterName( std::string const & mangleName ) {
	500	return "_adapter" + mangleName;
	501	}
	502
	503	void makeRetParam( ast::FunctionType * type ) {
	504	ast::ptr<ast::Type> & retParam = type->returns.front();
	505
	506	// Make a new parameter that is a pointer to the type of the old return value.
	507	retParam = new ast::PointerType( retParam.get() );
	508	type->params.emplace( type->params.begin(), retParam );
	509
	510	// We don't need the return value any more.
	511	type->returns.clear();
	512	}
	513
	514	ast::FunctionType * makeAdapterType(
	515	ast::FunctionType const * adaptee,
	516	TypeVarMap const & typeVars ) {
[82a5ea2]	517	assertf( ast::FixedArgs == adaptee->isVarArgs,
	518	"Cannot adapt a varadic function, should have been checked." );
[1ee0a4da]	519	ast::FunctionType * adapter = ast::deepCopy( adaptee );
	520	if ( isDynRet( adapter, typeVars ) ) {
	521	makeRetParam( adapter );
	522	}
	523	adapter->params.emplace( adapter->params.begin(),
	524	new ast::PointerType( new ast::FunctionType( ast::VariableArgs ) )
	525	);
	526	return adapter;
	527	}
	528
	529	CallAdapter::CallAdapter() : tmpNamer( "_temp" ) {}
	530
	531	void CallAdapter::previsit( ast::Decl const * ) {
	532	// Prevent type declaration information from leaking out.
	533	GuardScope( scopeTypeVars );
	534	}
	535
	536	ast::FunctionDecl const * CallAdapter::previsit( ast::FunctionDecl const * decl ) {
[e14d169]	537	// Prevent type declaration information from leaking out.
	538	GuardScope( scopeTypeVars );
	539
[1ee0a4da]	540	if ( nullptr == decl->stmts ) {
	541	return decl;
	542	}
	543
	544	GuardValue( retval );
	545
	546	// Process polymorphic return value.
	547	retval = nullptr;
	548	ast::FunctionType const * type = decl->type;
	549	if ( isDynRet( type ) && decl->linkage != ast::Linkage::C ) {
	550	retval = decl->returns.front();
	551
	552	// Give names to unnamed return values.
	553	if ( "" == retval->name ) {
	554	auto mutRet = ast::mutate( retval );
	555	mutRet->name = "_retparam";
	556	mutRet->linkage = ast::Linkage::C;
	557	retval = mutRet;
	558	decl = ast::mutate_field_index( decl,
	559	&ast::FunctionDecl::returns, 0, mutRet );
	560	}
	561	}
	562
	563	// The formal_usage/expr_id values may be off if we get them from the
	564	// type, trying the declaration instead.
	565	makeTypeVarMap( type, scopeTypeVars );
	566
	567	// Get all needed adapters from the call. We will forward them.
	568	ast::vector<ast::FunctionType> functions;
	569	for ( ast::ptr<ast::VariableExpr> const & assertion : type->assertions ) {
	570	auto atype = assertion->result.get();
	571	findFunction( atype, functions, scopeTypeVars, needsAdapter );
	572	}
	573
	574	for ( ast::ptr<ast::Type> const & arg : type->params ) {
	575	findFunction( arg, functions, scopeTypeVars, needsAdapter );
	576	}
	577
	578	for ( auto funcType : functions ) {
	579	std::string mangleName = mangleAdapterName( funcType, scopeTypeVars );
	580	if ( adapters.contains( mangleName ) ) continue;
	581	std::string adapterName = makeAdapterName( mangleName );
[be4335b]	582	// NODE: This creates floating nodes, breaking invariants.
	583	// This is corrected in the RewireAdapters sub-pass.
[1ee0a4da]	584	adapters.insert(
	585	mangleName,
	586	new ast::ObjectDecl(
	587	decl->location,
	588	adapterName,
	589	new ast::PointerType(
	590	makeAdapterType( funcType, scopeTypeVars ) ),
	591	nullptr, // init
	592	ast::Storage::Classes(),
	593	ast::Linkage::C
	594	)
	595	);
	596	}
	597
	598	return decl;
	599	}
	600
	601	void CallAdapter::previsit( ast::TypeDecl const * decl ) {
	602	addToTypeVarMap( decl, scopeTypeVars );
	603	}
	604
	605	void CallAdapter::previsit( ast::CommaExpr const * expr ) {
	606	// Attempting to find application expressions that were mutated by the
	607	// copy constructor passes to use an explicit return variable, so that
	608	// the variable can be reused as a parameter to the call rather than
	609	// creating a new temporary variable. Previously this step was an
[4604bf5]	610	// optimization, but with the introduction of tuples and UniqueExprs,
	611	// it is necessary to ensure that they use the same variable.
[1ee0a4da]	612	// Essentially, looking for pattern:
	613	// (x=f(...), x)
	614	// To compound the issue, the right side can be *x, etc.
	615	// because of lvalue-returning functions
	616	if ( auto assign = expr->arg1.as<ast::UntypedExpr>() ) {
	617	if ( CodeGen::isAssignment( ast::getFunctionName( assign ) ) ) {
	618	assert( 2 == assign->args.size() );
	619	if ( auto app = assign->args.back().as<ast::ApplicationExpr>() ) {
	620	// First argument is assignable, so it must be an lvalue,
	621	// so it should be legal to takes its address.
	622	retVals.insert_or_assign( app, assign->args.front() );
	623	}
	624	}
	625	}
	626	}
	627
	628	ast::Expr const * CallAdapter::postvisit( ast::ApplicationExpr const * expr ) {
	629	assert( expr->func->result );
	630	ast::FunctionType const * function = getFunctionType( expr->func->result );
	631	assertf( function, "ApplicationExpr has non-function type %s",
	632	toCString( expr->func->result ) );
	633
	634	if ( auto newExpr = handleIntrinsics( expr ) ) {
	635	return newExpr;
	636	}
	637
	638	ast::ApplicationExpr * mutExpr = ast::mutate( expr );
	639	ast::Expr const * ret = expr;
	640
[52a5262e]	641	TypeVarMap exprTypeVars;
[1ee0a4da]	642	makeTypeVarMap( function, exprTypeVars );
	643	auto dynRetType = isDynRet( function, exprTypeVars );
	644
	645	// NOTE: addDynRetParam needs to know the actual (generated) return type
	646	// so it can make a temporary variable, so pass the result type form the
	647	// `expr` `passTypeVars` needs to know the program-text return type ([ex]
	648	// the distinction between _conc_T30 and T3(int)) concRetType may not be
	649	// a good name in one or both of these places.
	650	if ( dynRetType ) {
	651	ast::Type const * result = mutExpr->result;
	652	ast::Type const * concRetType = result->isVoid() ? nullptr : result;
	653	// [Comment from before translation.]
	654	// Used to use dynRetType instead of concRetType.
	655	ret = addDynRetParam( mutExpr, concRetType );
	656	} else if ( needsAdapter( function, scopeTypeVars )
	657	&& !needsAdapter( function, exprTypeVars ) ) {
	658	// Change the application so it calls the adapter rather than the
	659	// passed function.
	660	ret = applyAdapter( mutExpr, function );
	661	}
	662
[23a0e576]	663	ast::vector<ast::Expr> prependArgs;
	664	passTypeVars( mutExpr, prependArgs, function );
	665	addInferredParams( mutExpr, prependArgs, function, exprTypeVars );
[1ee0a4da]	666
[23a0e576]	667	boxParams( mutExpr, dynRetType, function, exprTypeVars );
	668	spliceBegin( mutExpr->args, prependArgs );
[1ee0a4da]	669	passAdapters( mutExpr, function, exprTypeVars );
	670
	671	return ret;
	672	}
	673
[82d5816]	674	// Get the referent (base type of pointer). Must succeed.
	675	ast::Type const * getReferentType( ast::ptr<ast::Type> const & type ) {
	676	auto pointerType = type.strict_as<ast::PointerType>();
	677	assertf( pointerType->base, "getReferentType: pointer base is nullptr." );
	678	return pointerType->base.get();
	679	}
	680
[1ee0a4da]	681	bool isPolyDeref( ast::UntypedExpr const * expr,
	682	TypeVarMap const & typeVars,
	683	ast::TypeSubstitution const * typeSubs ) {
[82d5816]	684	auto name = expr->func.as<ast::NameExpr>();
	685	if ( name && "*?" == name->name ) {
	686	// It's a deref.
	687	// Must look under the * (and strip its ptr-ty) because expr's
	688	// result could be ar/ptr-decayed. If expr.inner:T(*)[n], then
	689	// expr is a poly deref, even though expr:T*, which is not poly.
	690	auto referentType = getReferentType( expr->args.front()->result );
	691	return isPolyType( referentType, typeVars, typeSubs );
[1ee0a4da]	692	}
	693	return false;
	694	}
	695
	696	ast::Expr const * CallAdapter::postvisit( ast::UntypedExpr const * expr ) {
	697	if ( isPolyDeref( expr, scopeTypeVars, typeSubs ) ) {
	698	return expr->args.front();
	699	}
	700	return expr;
	701	}
	702
	703	void CallAdapter::previsit( ast::AddressExpr const * ) {
	704	visit_children = false;
	705	}
	706
	707	ast::Expr const * CallAdapter::postvisit( ast::AddressExpr const * expr ) {
	708	assert( expr->arg->result );
	709	assert( !expr->arg->result->isVoid() );
	710
	711	bool doesNeedAdapter = false;
	712	if ( auto un = expr->arg.as<ast::UntypedExpr>() ) {
	713	if ( isPolyDeref( un, scopeTypeVars, typeSubs ) ) {
	714	if ( auto app = un->args.front().as<ast::ApplicationExpr>() ) {
	715	assert( app->func->result );
	716	auto function = getFunctionType( app->func->result );
	717	assert( function );
	718	doesNeedAdapter = needsAdapter( function, scopeTypeVars );
	719	}
	720	}
	721	}
	722	// isPolyType check needs to happen before mutating expr arg,
	723	// so pull it forward out of the if condition.
	724	expr = ast::mutate_field( expr, &ast::AddressExpr::arg,
	725	expr->arg->accept( *visitor ) );
	726	// But must happen after mutate, since argument might change
	727	// (ex. intrinsic *?, ?[?]) re-evaluate above comment.
	728	bool polyType = isPolyType( expr->arg->result, scopeTypeVars, typeSubs );
	729	if ( polyType \|\| doesNeedAdapter ) {
	730	ast::Expr * ret = ast::mutate( expr->arg.get() );
	731	ret->result = ast::deepCopy( expr->result );
	732	return ret;
	733	} else {
	734	return expr;
	735	}
	736	}
	737
	738	ast::ReturnStmt const * CallAdapter::previsit( ast::ReturnStmt const * stmt ) {
	739	// Since retval is set when the return type is dynamic, this function
	740	// should have been converted to void return & out parameter.
	741	if ( retval && stmt->expr ) {
	742	assert( stmt->expr->result );
	743	assert( !stmt->expr->result->isVoid() );
	744	return ast::mutate_field( stmt, &ast::ReturnStmt::expr, nullptr );
	745	}
	746	return stmt;
	747	}
	748
	749	void CallAdapter::beginScope() {
	750	adapters.beginScope();
	751	}
	752
	753	void CallAdapter::endScope() {
	754	adapters.endScope();
	755	}
	756
	757	/// Find instances of polymorphic type parameters.
	758	struct PolyFinder {
	759	TypeVarMap const & typeVars;
	760	bool result = false;
	761	PolyFinder( TypeVarMap const & tvs ) : typeVars( tvs ) {}
	762
	763	void previsit( ast::TypeInstType const * type ) {
	764	if ( isPolyType( type, typeVars ) ) result = true;
	765	}
	766	};
	767
	768	/// True if these is an instance of a polymorphic type parameter in the type.
	769	bool hasPolymorphism( ast::Type const * type, TypeVarMap const & typeVars ) {
	770	return ast::Pass<PolyFinder>::read( type, typeVars );
	771	}
	772
[23a0e576]	773	void CallAdapter::passTypeVars(
[1ee0a4da]	774	ast::ApplicationExpr * expr,
[23a0e576]	775	ast::vector<ast::Expr> & extraArgs,
[61e5d99]	776	ast::FunctionType const * function ) {
[1ee0a4da]	777	assert( typeSubs );
	778	// Pass size/align for type variables.
	779	for ( ast::ptr<ast::TypeInstType> const & typeVar : function->forall ) {
	780	if ( !typeVar->base->isComplete() ) continue;
	781	ast::Type const * concrete = typeSubs->lookup( typeVar );
	782	if ( !concrete ) {
	783	// Should this be an assertion?
[ca9d65e]	784	SemanticError( expr->location, "\nunbound type variable %s in application %s",
	785	toString( typeSubs ).c_str(), typeVar->typeString().c_str() );
[1ee0a4da]	786	}
[23a0e576]	787	extraArgs.emplace_back(
[1ee0a4da]	788	new ast::SizeofExpr( expr->location, ast::deepCopy( concrete ) ) );
[23a0e576]	789	extraArgs.emplace_back(
[1ee0a4da]	790	new ast::AlignofExpr( expr->location, ast::deepCopy( concrete ) ) );
	791	}
	792	}
	793
	794	ast::Expr const * CallAdapter::addRetParam(
	795	ast::ApplicationExpr * expr, ast::Type const * retType ) {
	796	// Create temporary to hold return value of polymorphic function and
	797	// produce that temporary as a result using a comma expression.
	798	assert( retType );
	799
	800	ast::Expr * paramExpr = nullptr;
	801	// Try to use existing return value parameter if it exists,
	802	// otherwise create a new temporary.
	803	if ( retVals.count( expr ) ) {
	804	paramExpr = ast::deepCopy( retVals[ expr ] );
	805	} else {
	806	auto newObj = makeTemporary( expr->location, ast::deepCopy( retType ) );
	807	paramExpr = new ast::VariableExpr( expr->location, newObj );
	808	}
	809	ast::Expr * retExpr = ast::deepCopy( paramExpr );
	810
	811	// If the type of the temporary is not polpmorphic, box temporary by
	812	// taking its address; otherwise the temporary is already boxed and can
	813	// be used directly.
	814	if ( !isPolyType( paramExpr->result, scopeTypeVars, typeSubs ) ) {
	815	paramExpr = new ast::AddressExpr( paramExpr->location, paramExpr );
	816	}
	817	// Add argument to function call.
	818	expr->args.insert( expr->args.begin(), paramExpr );
	819	// Build a comma expression to call the function and return a value.
	820	ast::CommaExpr * comma = new ast::CommaExpr(
	821	expr->location, expr, retExpr );
	822	comma->env = expr->env;
	823	expr->env = nullptr;
	824	return comma;
	825	}
	826
	827	ast::Expr const * CallAdapter::addDynRetParam(
	828	ast::ApplicationExpr * expr, ast::Type const * polyType ) {
	829	assert( typeSubs );
	830	ast::Type const * concrete = replaceWithConcrete( polyType, *typeSubs );
	831	// Add out-parameter for return value.
	832	return addRetParam( expr, concrete );
	833	}
	834
	835	ast::Expr const * CallAdapter::applyAdapter(
	836	ast::ApplicationExpr * expr,
	837	ast::FunctionType const * function ) {
	838	ast::Expr const * ret = expr;
	839	if ( isDynRet( function, scopeTypeVars ) ) {
	840	ret = addRetParam( expr, function->returns.front() );
	841	}
	842	std::string mangleName = mangleAdapterName( function, scopeTypeVars );
	843	std::string adapterName = makeAdapterName( mangleName );
	844
	845	// Cast adaptee to `void (*)()`, since it may have any type inside a
	846	// polymorphic function.
	847	ast::Type const * adapteeType = new ast::PointerType(
	848	new ast::FunctionType( ast::VariableArgs ) );
	849	expr->args.insert( expr->args.begin(),
	850	new ast::CastExpr( expr->location, expr->func, adapteeType ) );
	851	// The result field is never set on NameExpr. / Now it is.
	852	auto head = new ast::NameExpr( expr->location, adapterName );
	853	head->result = ast::deepCopy( adapteeType );
	854	expr->func = head;
	855
	856	return ret;
	857	}
	858
	859	/// Cast parameters to polymorphic functions so that types are replaced with
	860	/// `void *` if they are type parameters in the formal type.
	861	/// This gets rid of warnings from gcc.
	862	void addCast(
	863	ast::ptr<ast::Expr> & actual,
	864	ast::Type const * formal,
	865	TypeVarMap const & typeVars ) {
	866	// Type contains polymorphism, but isn't exactly a polytype, in which
	867	// case it has some real actual type (ex. unsigned int) and casting to
	868	// `void *` is wrong.
	869	if ( hasPolymorphism( formal, typeVars )
	870	&& !isPolyType( formal, typeVars ) ) {
	871	ast::Type const * newType = ast::deepCopy( formal );
	872	newType = scrubTypeVars( newType, typeVars );
	873	actual = new ast::CastExpr( actual->location, actual, newType );
	874	}
	875	}
	876
	877	void CallAdapter::boxParam( ast::ptr<ast::Expr> & arg,
	878	ast::Type const * param, TypeVarMap const & exprTypeVars ) {
	879	assertf( arg->result, "arg does not have result: %s", toCString( arg ) );
	880	addCast( arg, param, exprTypeVars );
	881	if ( !needsBoxing( param, arg->result, exprTypeVars, typeSubs ) ) {
	882	return;
	883	}
	884	CodeLocation const & location = arg->location;
	885
	886	if ( arg->get_lvalue() ) {
	887	// The argument expression may be CFA lvalue, but not C lvalue,
	888	// so apply generalizedLvalue transformations.
	889	// if ( auto var = dynamic_cast<ast::VariableExpr const *>( arg ) ) {
	890	// if ( dynamic_cast<ast::ArrayType const *>( varExpr->var->get_type() ) ){
	891	// // temporary hack - don't box arrays, because &arr is not the same as &arr[0]
	892	// return;
	893	// }
	894	// }
	895	arg = generalizedLvalue( new ast::AddressExpr( arg->location, arg ) );
	896	if ( !ResolvExpr::typesCompatible( param, arg->result ) ) {
	897	// Silence warnings by casting boxed parameters when the actually
	898	// type does not match up with the formal type.
	899	arg = new ast::CastExpr( location, arg, ast::deepCopy( param ) );
	900	}
	901	} else {
	902	// Use type computed in unification to declare boxed variables.
	903	ast::ptr<ast::Type> newType = ast::deepCopy( param );
	904	if ( typeSubs ) typeSubs->apply( newType );
	905	ast::ObjectDecl * newObj = makeTemporary( location, newType );
	906	auto assign = ast::UntypedExpr::createCall( location, "?=?", {
	907	new ast::VariableExpr( location, newObj ),
	908	arg,
	909	} );
	910	stmtsToAddBefore.push_back( new ast::ExprStmt( location, assign ) );
	911	arg = new ast::AddressExpr(
	912	new ast::VariableExpr( location, newObj ) );
	913	}
	914	}
	915
	916	void CallAdapter::boxParams(
[23a0e576]	917	ast::ApplicationExpr * expr,
	918	ast::Type const * polyRetType,
[1ee0a4da]	919	ast::FunctionType const * function,
	920	const TypeVarMap & typeVars ) {
[23a0e576]	921	// Start at the beginning, but the return argument may have been added.
	922	auto arg = expr->args.begin();
	923	if ( polyRetType ) ++arg;
	924
[1ee0a4da]	925	for ( auto param : function->params ) {
	926	assertf( arg != expr->args.end(),
	927	"boxParams: missing argument for param %s to %s in %s",
	928	toCString( param ), toCString( function ), toCString( expr ) );
	929	boxParam( *arg, param, typeVars );
	930	++arg;
	931	}
	932	}
	933
	934	void CallAdapter::addInferredParams(
	935	ast::ApplicationExpr * expr,
[23a0e576]	936	ast::vector<ast::Expr> & extraArgs,
[1ee0a4da]	937	ast::FunctionType const * functionType,
	938	TypeVarMap const & typeVars ) {
	939	for ( auto assertion : functionType->assertions ) {
	940	auto inferParam = expr->inferred.inferParams().find(
	941	assertion->var->uniqueId );
	942	assertf( inferParam != expr->inferred.inferParams().end(),
	943	"addInferredParams missing inferred parameter: %s in: %s",
	944	toCString( assertion ), toCString( expr ) );
	945	ast::ptr<ast::Expr> newExpr = ast::deepCopy( inferParam->second.expr );
	946	boxParam( newExpr, assertion->result, typeVars );
[23a0e576]	947	extraArgs.emplace_back( newExpr.release() );
[1ee0a4da]	948	}
	949	}
	950
	951	/// Modifies the ApplicationExpr to accept adapter functions for its
	952	/// assertion and parameters, declares the required adapters.
	953	void CallAdapter::passAdapters(
	954	ast::ApplicationExpr * expr,
	955	ast::FunctionType const * type,
	956	const TypeVarMap & exprTypeVars ) {
	957	// Collect a list of function types passed as parameters or implicit
	958	// parameters (assertions).
	959	ast::vector<ast::Type> const & paramList = type->params;
	960	ast::vector<ast::FunctionType> functions;
	961
	962	for ( ast::ptr<ast::VariableExpr> const & assertion : type->assertions ) {
	963	findFunction( assertion->result, functions, exprTypeVars, needsAdapter );
	964	}
	965	for ( ast::ptr<ast::Type> const & arg : paramList ) {
	966	findFunction( arg, functions, exprTypeVars, needsAdapter );
	967	}
	968
	969	// Parameter function types for which an appropriate adapter has been
	970	// generated. We cannot use the types after applying substitutions,
	971	// since two different parameter types may be unified to the same type.
	972	std::set<std::string> adaptersDone;
	973
	974	CodeLocation const & location = expr->location;
	975
	976	for ( ast::ptr<ast::FunctionType> const & funcType : functions ) {
	977	std::string mangleName = Mangle::mangle( funcType );
	978
	979	// Only attempt to create an adapter or pass one as a parameter if we
	980	// haven't already done so for this pre-substitution parameter
	981	// function type.
	982	// The second part of the result if is if the element was inserted.
	983	if ( !adaptersDone.insert( mangleName ).second ) continue;
	984
	985	// Apply substitution to type variables to figure out what the
	986	// adapter's type should look like. (Copy to make the release safe.)
	987	assert( typeSubs );
	988	auto result = typeSubs->apply( ast::deepCopy( funcType ) );
	989	ast::FunctionType * realType = ast::mutate( result.node.release() );
	990	mangleName = Mangle::mangle( realType );
	991	mangleName += makePolyMonoSuffix( funcType, exprTypeVars );
	992
	993	// Check if the adapter has already been created, or has to be.
	994	using AdapterIter = decltype(adapters)::iterator;
	995	AdapterIter adapter = adapters.find( mangleName );
	996	if ( adapter == adapters.end() ) {
	997	ast::FunctionDecl * newAdapter = makeAdapter(
	998	funcType, realType, mangleName, exprTypeVars, location );
	999	std::pair<AdapterIter, bool> answer =
	1000	adapters.insert( mangleName, newAdapter );
	1001	adapter = answer.first;
	1002	stmtsToAddBefore.push_back(
	1003	new ast::DeclStmt( location, newAdapter ) );
	1004	}
	1005	assert( adapter != adapters.end() );
	1006
	1007	// Add the approprate adapter as a parameter.
	1008	expr->args.insert( expr->args.begin(),
	1009	new ast::VariableExpr( location, adapter->second ) );
	1010	}
	1011	}
	1012
	1013	// Parameter and argument may be used wrong around here.
	1014	ast::Expr * makeAdapterArg(
	1015	ast::DeclWithType const * param,
	1016	ast::Type const * arg,
	1017	ast::Type const * realParam,
	1018	TypeVarMap const & typeVars,
	1019	CodeLocation const & location ) {
	1020	assert( param );
	1021	assert( arg );
	1022	assert( realParam );
	1023	if ( isPolyType( realParam, typeVars ) && !isPolyType( arg ) ) {
	1024	ast::UntypedExpr * deref = ast::UntypedExpr::createDeref(
	1025	location,
	1026	new ast::CastExpr( location,
	1027	new ast::VariableExpr( location, param ),
	1028	new ast::PointerType( ast::deepCopy( arg ) )
	1029	)
	1030	);
	1031	deref->result = ast::deepCopy( arg );
	1032	return deref;
	1033	}
	1034	return new ast::VariableExpr( location, param );
	1035	}
	1036
	1037	// This seems to be one of the problematic functions.
	1038	void addAdapterParams(
	1039	ast::ApplicationExpr * adaptee,
	1040	ast::vector<ast::Type>::const_iterator arg,
	1041	ast::vector<ast::DeclWithType>::iterator param,
	1042	ast::vector<ast::DeclWithType>::iterator paramEnd,
	1043	ast::vector<ast::Type>::const_iterator realParam,
	1044	TypeVarMap const & typeVars,
	1045	CodeLocation const & location ) {
	1046	UniqueName paramNamer( "_p" );
	1047	for ( ; param != paramEnd ; ++param, ++arg, ++realParam ) {
	1048	if ( "" == (*param)->name ) {
	1049	auto mutParam = (*param).get_and_mutate();
	1050	mutParam->name = paramNamer.newName();
	1051	mutParam->linkage = ast::Linkage::C;
	1052	}
	1053	adaptee->args.push_back(
	1054	makeAdapterArg( param, arg, *realParam, typeVars, location ) );
	1055	}
	1056	}
	1057
	1058	ast::FunctionDecl * CallAdapter::makeAdapter(
	1059	ast::FunctionType const * adaptee,
	1060	ast::FunctionType const * realType,
	1061	std::string const & mangleName,
	1062	TypeVarMap const & typeVars,
	1063	CodeLocation const & location ) const {
	1064	ast::FunctionType * adapterType = makeAdapterType( adaptee, typeVars );
	1065	adapterType = ast::mutate( scrubTypeVars( adapterType, typeVars ) );
	1066
	1067	// Some of these names will be overwritten, but it gives a default.
	1068	UniqueName pNamer( "_param" );
	1069	UniqueName rNamer( "_ret" );
	1070
	1071	bool first = true;
	1072
	1073	ast::FunctionDecl * adapterDecl = new ast::FunctionDecl( location,
	1074	makeAdapterName( mangleName ),
	1075	{}, // forall
	1076	{}, // assertions
	1077	map_range<ast::vector<ast::DeclWithType>>( adapterType->params,
	1078	[&pNamer, &location, &first]( ast::ptr<ast::Type> const & param ) {
	1079	// [Trying to make the generated code match exactly more often.]
	1080	if ( first ) {
	1081	first = false;
	1082	return new ast::ObjectDecl( location, "_adaptee", param );
	1083	}
	1084	return new ast::ObjectDecl( location, pNamer.newName(), param );
[045cda3]	1085	} ),
[1ee0a4da]	1086	map_range<ast::vector<ast::DeclWithType>>( adapterType->returns,
	1087	[&rNamer, &location]( ast::ptr<ast::Type> const & retval ) {
	1088	return new ast::ObjectDecl( location, rNamer.newName(), retval );
[045cda3]	1089	} ),
[1ee0a4da]	1090	nullptr, // stmts
[045cda3]	1091	{}, // storage
	1092	ast::Linkage::C
[1ee0a4da]	1093	);
	1094
	1095	ast::DeclWithType * adapteeDecl =
	1096	adapterDecl->params.front().get_and_mutate();
	1097	adapteeDecl->name = "_adaptee";
	1098
	1099	// Do not carry over attributes to real type parameters/return values.
	1100	auto mutRealType = ast::mutate( realType );
	1101	for ( ast::ptr<ast::Type> & decl : mutRealType->params ) {
	1102	if ( decl->attributes.empty() ) continue;
	1103	auto mut = ast::mutate( decl.get() );
	1104	mut->attributes.clear();
	1105	decl = mut;
	1106	}
	1107	for ( ast::ptr<ast::Type> & decl : mutRealType->returns ) {
	1108	if ( decl->attributes.empty() ) continue;
	1109	auto mut = ast::mutate( decl.get() );
	1110	mut->attributes.clear();
	1111	decl = mut;
	1112	}
	1113	realType = mutRealType;
	1114
	1115	ast::ApplicationExpr * adapteeApp = new ast::ApplicationExpr( location,
	1116	new ast::CastExpr( location,
	1117	new ast::VariableExpr( location, adapteeDecl ),
	1118	new ast::PointerType( realType )
	1119	)
	1120	);
	1121
[d06273c]	1122	for ( auto const & [assertArg, assertParam, assertReal] : group_iterate(
	1123	realType->assertions, adapterType->assertions, adaptee->assertions ) ) {
[1ee0a4da]	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
[82d5816]	1205	ast::ptr<ast::Type> const & argType1 = expr->args.front()->result;
	1206	ast::ptr<ast::Type> const & argType2 = expr->args.back()->result;
[fd4df379]	1207
[82d5816]	1208	// Two Cases: a[i] with first arg poly ptr, i[a] with second arg poly ptr
	1209	bool isPoly1 = isPolyPtr( argType1, scopeTypeVars, typeSubs ) != nullptr;
	1210	bool isPoly2 = isPolyPtr( argType2, scopeTypeVars, typeSubs ) != nullptr;
[fd4df379]	1211
[1ee0a4da]	1212	// If neither argument is a polymorphic pointer, do nothing.
[fd4df379]	1213	if ( !isPoly1 && !isPoly2 ) {
[1ee0a4da]	1214	return expr;
	1215	}
	1216	// The arguments cannot both be polymorphic pointers.
[fd4df379]	1217	assert( !isPoly1 \|\| !isPoly2 );
[1ee0a4da]	1218	// (So exactly one of the arguments is a polymorphic pointer.)
	1219
	1220	CodeLocation const & location = expr->location;
	1221	CodeLocation const & location1 = expr->args.front()->location;
	1222	CodeLocation const & location2 = expr->args.back()->location;
	1223
	1224	ast::UntypedExpr * ret = new ast::UntypedExpr( location,
	1225	new ast::NameExpr( location, "?+?" ) );
[fd4df379]	1226	if ( isPoly1 ) {
[82d5816]	1227	auto referentType = getReferentType( argType1 );
[1ee0a4da]	1228	auto multiply = ast::UntypedExpr::createCall( location2, "?*?", {
	1229	expr->args.back(),
[82d5816]	1230	new ast::SizeofExpr( location1, deepCopy( referentType ) ),
[1ee0a4da]	1231	} );
	1232	ret->args.push_back( expr->args.front() );
	1233	ret->args.push_back( multiply );
	1234	} else {
[fd4df379]	1235	assert( isPoly2 );
[82d5816]	1236	auto referentType = getReferentType( argType2 );
[1ee0a4da]	1237	auto multiply = ast::UntypedExpr::createCall( location1, "?*?", {
	1238	expr->args.front(),
[82d5816]	1239	new ast::SizeofExpr( location2, deepCopy( referentType ) ),
[1ee0a4da]	1240	} );
	1241	ret->args.push_back( multiply );
	1242	ret->args.push_back( expr->args.back() );
	1243	}
	1244	ret->result = ast::deepCopy( expr->result );
	1245	ret->env = expr->env ? expr->env : ret->env;
	1246	return ret;
	1247	// Dereference Intrinsic:
	1248	} else if ( "*?" == varName ) {
	1249	assert( expr->result );
	1250	assert( 1 == expr->args.size() );
	1251
	1252	// If this isn't for a poly type, then do nothing.
[82d5816]	1253	auto referentType = getReferentType( expr->args.front()->result );
	1254	if ( !isPolyType( referentType, scopeTypeVars, typeSubs ) ) {
[1ee0a4da]	1255	return expr;
	1256	}
	1257
	1258	// Remove dereference from polymorphic types since they are boxed.
	1259	ast::Expr * ret = ast::deepCopy( expr->args.front() );
	1260	// Fix expression type to remove pointer.
	1261	ret->result = expr->result;
[fd4df379]	1262	// apply pointer decay
	1263	if (auto retArTy = ret->result.as<ast::ArrayType>()) {
	1264	ret->result = new ast::PointerType( retArTy->base );
	1265	}
[1ee0a4da]	1266	ret->env = expr->env ? expr->env : ret->env;
	1267	return ret;
	1268	// Post-Increment/Decrement Intrinsics:
	1269	} else if ( "?++" == varName \|\| "?--" == varName ) {
	1270	assert( expr->result );
	1271	assert( 1 == expr->args.size() );
	1272
	1273	ast::Type const * baseType =
	1274	isPolyType( expr->result, scopeTypeVars, typeSubs );
	1275	if ( nullptr == baseType ) {
	1276	return expr;
	1277	}
	1278	ast::Type * tempType = ast::deepCopy( expr->result );
	1279	if ( typeSubs ) {
	1280	auto result = typeSubs->apply( tempType );
	1281	tempType = ast::mutate( result.node.release() );
	1282	}
	1283	CodeLocation const & location = expr->location;
	1284	ast::ObjectDecl * newObj = makeTemporary( location, tempType );
	1285	ast::VariableExpr * tempExpr =
	1286	new ast::VariableExpr( location, newObj );
	1287	ast::UntypedExpr * assignExpr = new ast::UntypedExpr( location,
	1288	new ast::NameExpr( location, "?=?" ) );
	1289	assignExpr->args.push_back( ast::deepCopy( tempExpr ) );
	1290	if ( auto address = expr->args.front().as<ast::AddressExpr>() ) {
	1291	assignExpr->args.push_back( ast::deepCopy( address->arg ) );
	1292	} else {
	1293	assignExpr->args.push_back( ast::deepCopy( expr->args.front() ) );
	1294	}
	1295	return new ast::CommaExpr( location,
	1296	new ast::CommaExpr( location,
	1297	assignExpr,
	1298	makeIncrDecrExpr( location, expr, baseType, "?++" == varName )
	1299	),
	1300	tempExpr
	1301	);
	1302	// Pre-Increment/Decrement Intrinsics:
	1303	} else if ( "++?" == varName \|\| "--?" == varName ) {
	1304	assert( expr->result );
	1305	assert( 1 == expr->args.size() );
	1306
	1307	ast::Type const * baseType =
	1308	isPolyType( expr->result, scopeTypeVars, typeSubs );
	1309	if ( nullptr == baseType ) {
	1310	return expr;
	1311	}
	1312	return makeIncrDecrExpr(
	1313	expr->location, expr, baseType, "++?" == varName );
[fd4df379]	1314	// Addition and Subtraction Intrinsics:
[1ee0a4da]	1315	} else if ( "?+?" == varName \|\| "?-?" == varName ) {
	1316	assert( expr->result );
	1317	assert( 2 == expr->args.size() );
	1318
[82d5816]	1319	ast::ptr<ast::Type> const & argType1 = expr->args.front()->result;
	1320	ast::ptr<ast::Type> const & argType2 = expr->args.back()->result;
[fd4df379]	1321
[82d5816]	1322	bool isPoly1 = isPolyPtr( argType1, scopeTypeVars, typeSubs ) != nullptr;
	1323	bool isPoly2 = isPolyPtr( argType2, scopeTypeVars, typeSubs ) != nullptr;
[1ee0a4da]	1324
	1325	CodeLocation const & location = expr->location;
	1326	CodeLocation const & location1 = expr->args.front()->location;
	1327	CodeLocation const & location2 = expr->args.back()->location;
[82d5816]	1328	// LHS - RHS -> (LHS - RHS) / sizeof(LHS)
[fd4df379]	1329	if ( isPoly1 && isPoly2 ) {
[82d5816]	1330	// There are only subtraction intrinsics for this pattern.
[fd4df379]	1331	assert( "?-?" == varName );
[82d5816]	1332	auto referentType = getReferentType( argType1 );
[1ee0a4da]	1333	auto divide = ast::UntypedExpr::createCall( location, "?/?", {
	1334	expr,
[82d5816]	1335	new ast::SizeofExpr( location, deepCopy( referentType ) ),
[1ee0a4da]	1336	} );
	1337	if ( expr->env ) divide->env = expr->env;
	1338	return divide;
	1339	// LHS op RHS -> LHS op (RHS * sizeof(LHS))
[fd4df379]	1340	} else if ( isPoly1 ) {
[82d5816]	1341	auto referentType = getReferentType( argType1 );
[1ee0a4da]	1342	auto multiply = ast::UntypedExpr::createCall( location2, "?*?", {
	1343	expr->args.back(),
[82d5816]	1344	new ast::SizeofExpr( location1, deepCopy( referentType ) ),
[1ee0a4da]	1345	} );
	1346	return ast::mutate_field_index(
	1347	expr, &ast::ApplicationExpr::args, 1, multiply );
	1348	// LHS op RHS -> (LHS * sizeof(RHS)) op RHS
[fd4df379]	1349	} else if ( isPoly2 ) {
[82d5816]	1350	auto referentType = getReferentType( argType2 );
[1ee0a4da]	1351	auto multiply = ast::UntypedExpr::createCall( location1, "?*?", {
	1352	expr->args.front(),
[82d5816]	1353	new ast::SizeofExpr( location2, deepCopy( referentType ) ),
[1ee0a4da]	1354	} );
	1355	return ast::mutate_field_index(
	1356	expr, &ast::ApplicationExpr::args, 0, multiply );
	1357	}
[82d5816]	1358	// Addition and Subtraction Relative Assignment Intrinsics:
[1ee0a4da]	1359	} else if ( "?+=?" == varName \|\| "?-=?" == varName ) {
	1360	assert( expr->result );
	1361	assert( 2 == expr->args.size() );
	1362
	1363	CodeLocation const & location1 = expr->args.front()->location;
	1364	CodeLocation const & location2 = expr->args.back()->location;
	1365	auto baseType = isPolyPtr( expr->result, scopeTypeVars, typeSubs );
	1366	// LHS op RHS -> LHS op (RHS * sizeof(LHS))
	1367	if ( baseType ) {
	1368	auto multiply = ast::UntypedExpr::createCall( location2, "?*?", {
	1369	expr->args.back(),
	1370	new ast::SizeofExpr( location1, deepCopy( baseType ) ),
	1371	} );
	1372	return ast::mutate_field_index(
	1373	expr, &ast::ApplicationExpr::args, 1, multiply );
	1374	}
	1375	}
	1376	return expr;
	1377	}
	1378
	1379	ast::ObjectDecl * CallAdapter::makeTemporary(
	1380	CodeLocation const & location, ast::Type const * type ) {
	1381	auto newObj = new ast::ObjectDecl( location, tmpNamer.newName(), type );
	1382	stmtsToAddBefore.push_back( new ast::DeclStmt( location, newObj ) );
	1383	return newObj;
	1384	}
	1385
	1386	// --------------------------------------------------------------------------
[045cda3]	1387	/// Modifies declarations to accept implicit parameters.
[1ee0a4da]	1388	/// * Move polymorphic returns in function types to pointer-type parameters.
	1389	/// * Adds type size and assertion parameters to parameter lists.
[097c8d0]	1390	struct DeclAdapter final {
[1ee0a4da]	1391	ast::FunctionDecl const * previsit( ast::FunctionDecl const * decl );
[045cda3]	1392	ast::FunctionDecl const * postvisit( ast::FunctionDecl const * decl );
[1ee0a4da]	1393	private:
[097c8d0]	1394	void addAdapters( ast::FunctionDecl * decl, TypeVarMap & localTypeVars );
[1ee0a4da]	1395	};
	1396
[045cda3]	1397	ast::ObjectDecl * makeObj(
	1398	CodeLocation const & location, std::string const & name ) {
[dd900b5]	1399	// The size/align parameters may be unused, so add the unused attribute.
[045cda3]	1400	return new ast::ObjectDecl( location, name,
[dd900b5]	1401	makeLayoutCType(),
[045cda3]	1402	nullptr, ast::Storage::Classes(), ast::Linkage::C, nullptr,
	1403	{ new ast::Attribute( "unused" ) } );
	1404	}
	1405
[dd900b5]	1406	/// A modified and specialized version of ast::add_qualifiers.
	1407	ast::Type const * addConst( ast::Type const * type ) {
	1408	ast::CV::Qualifiers cvq = { ast::CV::Const };
	1409	if ( ( type->qualifiers & cvq ) != 0 ) return type;
	1410	auto mutType = ast::mutate( type );
	1411	mutType->qualifiers \|= cvq;
	1412	return mutType;
	1413	}
	1414
[1ee0a4da]	1415	ast::FunctionDecl const * DeclAdapter::previsit( ast::FunctionDecl const * decl ) {
[52a5262e]	1416	TypeVarMap localTypeVars;
[097c8d0]	1417	makeTypeVarMap( decl, localTypeVars );
[1ee0a4da]	1418
	1419	auto mutDecl = mutate( decl );
	1420
	1421	// Move polymorphic return type to parameter list.
	1422	if ( isDynRet( mutDecl->type ) ) {
	1423	auto ret = strict_dynamic_cast<ast::ObjectDecl *>(
	1424	mutDecl->returns.front().get_and_mutate() );
	1425	ret->set_type( new ast::PointerType( ret->type ) );
	1426	mutDecl->params.insert( mutDecl->params.begin(), ret );
	1427	mutDecl->returns.erase( mutDecl->returns.begin() );
	1428	ret->init = nullptr;
	1429	}
	1430
	1431	// Add size/align and assertions for type parameters to parameter list.
[045cda3]	1432	ast::vector<ast::DeclWithType> inferredParams;
[097c8d0]	1433	ast::vector<ast::DeclWithType> layoutParams;
[1ee0a4da]	1434	for ( ast::ptr<ast::TypeDecl> & typeParam : mutDecl->type_params ) {
	1435	auto mutParam = mutate( typeParam.get() );
	1436	// Add all size and alignment parameters to parameter list.
	1437	if ( mutParam->isComplete() ) {
	1438	ast::TypeInstType paramType( mutParam );
	1439	std::string paramName = Mangle::mangleType( &paramType );
	1440
[045cda3]	1441	auto sizeParam = makeObj( typeParam->location, sizeofName( paramName ) );
[097c8d0]	1442	layoutParams.emplace_back( sizeParam );
[1ee0a4da]	1443
[045cda3]	1444	auto alignParam = makeObj( typeParam->location, alignofName( paramName ) );
[097c8d0]	1445	layoutParams.emplace_back( alignParam );
[1ee0a4da]	1446	}
[5e0bba5]	1447	// Assertions should be stored in the main list.
	1448	assert( mutParam->assertions.empty() );
[1ee0a4da]	1449	typeParam = mutParam;
	1450	}
	1451	for ( ast::ptr<ast::DeclWithType> & assert : mutDecl->assertions ) {
[dd900b5]	1452	ast::DeclWithType * mutAssert = ast::mutate( assert.get() );
[1ee0a4da]	1453	// Assertion parameters may not be used in body,
	1454	// pass along with unused attribute.
[dd900b5]	1455	mutAssert->attributes.push_back( new ast::Attribute( "unused" ) );
	1456	mutAssert->set_type( addConst( mutAssert->get_type() ) );
	1457	inferredParams.emplace_back( mutAssert );
[1ee0a4da]	1458	}
	1459	mutDecl->assertions.clear();
	1460
[097c8d0]	1461	// Prepend each argument group. From last group to first. addAdapters
	1462	// does do the same, it just does it itself and see all other parameters.
	1463	spliceBegin( mutDecl->params, inferredParams );
	1464	spliceBegin( mutDecl->params, layoutParams );
	1465	addAdapters( mutDecl, localTypeVars );
[1ee0a4da]	1466
[5e0bba5]	1467	// Now have to update the type to match the declaration.
	1468	ast::FunctionType * type = new ast::FunctionType(
	1469	mutDecl->type->isVarArgs, mutDecl->type->qualifiers );
[f48dfcd]	1470	// The forall clauses don't match until Eraser. The assertions are empty.
[5e0bba5]	1471	for ( auto param : mutDecl->params ) {
	1472	type->params.emplace_back( param->get_type() );
	1473	}
	1474	for ( auto retval : mutDecl->returns ) {
	1475	type->returns.emplace_back( retval->get_type() );
	1476	}
	1477	mutDecl->type = type;
	1478
[1ee0a4da]	1479	return mutDecl;
	1480	}
	1481
[045cda3]	1482	ast::FunctionDecl const * DeclAdapter::postvisit(
[1ee0a4da]	1483	ast::FunctionDecl const * decl ) {
	1484	ast::FunctionDecl * mutDecl = mutate( decl );
	1485	if ( !mutDecl->returns.empty() && mutDecl->stmts
	1486	// Intrinsic functions won't be using the _retval so no need to
	1487	// generate it.
	1488	&& mutDecl->linkage != ast::Linkage::Intrinsic
	1489	// Remove check for prefix once thunks properly use ctor/dtors.
	1490	&& !isPrefix( mutDecl->name, "_thunk" )
	1491	&& !isPrefix( mutDecl->name, "_adapter" ) ) {
	1492	assert( 1 == mutDecl->returns.size() );
	1493	ast::DeclWithType const * retval = mutDecl->returns.front();
	1494	if ( "" == retval->name ) {
	1495	retval = ast::mutate_field(
	1496	retval, &ast::DeclWithType::name, "_retval" );
	1497	mutDecl->returns.front() = retval;
	1498	}
	1499	auto stmts = mutDecl->stmts.get_and_mutate();
	1500	stmts->kids.push_front( new ast::DeclStmt( retval->location, retval ) );
	1501	ast::DeclWithType * newRet = ast::deepCopy( retval );
	1502	mutDecl->returns.front() = newRet;
	1503	}
	1504	// Errors should have been caught by this point, remove initializers from
	1505	// parameters to allow correct codegen of default arguments.
	1506	for ( ast::ptr<ast::DeclWithType> & param : mutDecl->params ) {
	1507	if ( auto obj = param.as<ast::ObjectDecl>() ) {
	1508	param = ast::mutate_field( obj, &ast::ObjectDecl::init, nullptr );
	1509	}
	1510	}
	1511	return mutDecl;
	1512	}
	1513
[097c8d0]	1514	void DeclAdapter::addAdapters(
	1515	ast::FunctionDecl * mutDecl, TypeVarMap & localTypeVars ) {
[045cda3]	1516	ast::vector<ast::FunctionType> functions;
[1ee0a4da]	1517	for ( ast::ptr<ast::DeclWithType> & arg : mutDecl->params ) {
	1518	ast::Type const * type = arg->get_type();
[097c8d0]	1519	type = findAndReplaceFunction( type, functions, localTypeVars, needsAdapter );
[1ee0a4da]	1520	arg.get_and_mutate()->set_type( type );
	1521	}
	1522	std::set<std::string> adaptersDone;
	1523	for ( ast::ptr<ast::FunctionType> const & func : functions ) {
[097c8d0]	1524	std::string mangleName = mangleAdapterName( func, localTypeVars );
[1ee0a4da]	1525	if ( adaptersDone.find( mangleName ) != adaptersDone.end() ) {
	1526	continue;
	1527	}
	1528	std::string adapterName = makeAdapterName( mangleName );
	1529	// The adapter may not actually be used, so make sure it has unused.
	1530	mutDecl->params.insert( mutDecl->params.begin(), new ast::ObjectDecl(
	1531	mutDecl->location, adapterName,
[097c8d0]	1532	new ast::PointerType( makeAdapterType( func, localTypeVars ) ),
[1ee0a4da]	1533	nullptr, {}, {}, nullptr,
	1534	{ new ast::Attribute( "unused" ) } ) );
	1535	adaptersDone.insert( adaptersDone.begin(), mangleName );
	1536	}
	1537	}
	1538
	1539	// --------------------------------------------------------------------------
	1540	/// Corrects the floating nodes created in CallAdapter.
	1541	struct RewireAdapters final : public ast::WithGuards {
	1542	ScopedMap<std::string, ast::ObjectDecl const *> adapters;
	1543	void beginScope() { adapters.beginScope(); }
	1544	void endScope() { adapters.endScope(); }
	1545	void previsit( ast::FunctionDecl const * decl );
	1546	ast::VariableExpr const * previsit( ast::VariableExpr const * expr );
	1547	};
	1548
	1549	void RewireAdapters::previsit( ast::FunctionDecl const * decl ) {
	1550	GuardScope( adapters );
	1551	for ( ast::ptr<ast::DeclWithType> const & param : decl->params ) {
	1552	if ( auto objectParam = param.as<ast::ObjectDecl>() ) {
	1553	adapters.insert( objectParam->name, objectParam );
	1554	}
	1555	}
	1556	}
	1557
	1558	ast::VariableExpr const * RewireAdapters::previsit(
	1559	ast::VariableExpr const * expr ) {
	1560	// If the node is not floating, we can skip.
	1561	if ( expr->var->isManaged() ) return expr;
	1562	auto it = adapters.find( expr->var->name );
	1563	assertf( it != adapters.end(), "Could not correct floating node." );
	1564	return ast::mutate_field( expr, &ast::VariableExpr::var, it->second );
	1565	}
	1566
	1567	// --------------------------------------------------------------------------
	1568	/// Inserts code to access polymorphic layout inforation.
	1569	/// * Replaces member and size/alignment/offsetof expressions on polymorphic
	1570	/// generic types with calculated expressions.
	1571	/// * Replaces member expressions for polymorphic types with calculated
	1572	/// add-field-offset-and-dereference.
	1573	/// * Calculates polymorphic offsetof expressions from offset array.
	1574	/// * Inserts dynamic calculation of polymorphic type layouts where needed.
	1575	struct PolyGenericCalculator final :
	1576	public ast::WithConstTypeSubstitution,
	1577	public ast::WithDeclsToAdd<>,
	1578	public ast::WithGuards,
	1579	public ast::WithStmtsToAdd<>,
	1580	public ast::WithVisitorRef<PolyGenericCalculator> {
	1581	PolyGenericCalculator();
	1582
	1583	void previsit( ast::FunctionDecl const * decl );
	1584	void previsit( ast::TypedefDecl const * decl );
	1585	void previsit( ast::TypeDecl const * decl );
	1586	ast::Decl const * postvisit( ast::TypeDecl const * decl );
	1587	ast::StructDecl const * previsit( ast::StructDecl const * decl );
	1588	ast::UnionDecl const * previsit( ast::UnionDecl const * decl );
	1589	ast::DeclStmt const * previsit( ast::DeclStmt const * stmt );
	1590	ast::Expr const * postvisit( ast::MemberExpr const * expr );
	1591	void previsit( ast::AddressExpr const * expr );
	1592	ast::Expr const * postvisit( ast::AddressExpr const * expr );
	1593	ast::Expr const * postvisit( ast::SizeofExpr const * expr );
	1594	ast::Expr const * postvisit( ast::AlignofExpr const * expr );
	1595	ast::Expr const * postvisit( ast::OffsetofExpr const * expr );
	1596	ast::Expr const * postvisit( ast::OffsetPackExpr const * expr );
	1597
	1598	void beginScope();
	1599	void endScope();
	1600	private:
	1601	/// Makes a new variable in the current scope with the given name,
	1602	/// type and optional initializer.
	1603	ast::ObjectDecl * makeVar(
	1604	CodeLocation const & location, std::string const & name,
	1605	ast::Type const * type, ast::Init const * init = nullptr );
	1606	/// Returns true if the type has a dynamic layout;
	1607	/// such a layout will be stored in appropriately-named local variables
	1608	/// when the function returns.
	1609	bool findGeneric( CodeLocation const & location, ast::Type const * );
	1610	/// Adds type parameters to the layout call; will generate the
	1611	/// appropriate parameters if needed.
[4604bf5]	1612	void addSTypeParamsToLayoutCall(
[1ee0a4da]	1613	ast::UntypedExpr * layoutCall,
	1614	const ast::vector<ast::Type> & otypeParams );
	1615	/// Change the type of generic aggregate members to char[].
	1616	void mutateMembers( ast::AggregateDecl * aggr );
[fd4df379]	1617	/// Returns the calculated sizeof/alignof expressions for type, or
	1618	/// nullptr for use C size/alignof().
[1ee0a4da]	1619	ast::Expr const * genSizeof( CodeLocation const &, ast::Type const * );
[fd4df379]	1620	ast::Expr const * genAlignof( CodeLocation const &, ast::Type const * );
[1ee0a4da]	1621	/// Enters a new scope for type-variables,
	1622	/// adding the type variables from the provided type.
	1623	void beginTypeScope( ast::Type const * );
	1624
[52a5262e]	1625	/// The type variables and polymorphic parameters currently in scope.
	1626	TypeVarMap scopeTypeVars;
[1ee0a4da]	1627	/// Set of generic type layouts known in the current scope,
	1628	/// indexed by sizeofName.
	1629	ScopedSet<std::string> knownLayouts;
	1630	/// Set of non-generic types for which the offset array exists in the
	1631	/// current scope, indexed by offsetofName.
	1632	ScopedSet<std::string> knownOffsets;
	1633	/// Namer for VLA (variable length array) buffers.
	1634	UniqueName bufNamer;
[045cda3]	1635	/// If the argument of an AddressExpr is MemberExpr, it is stored here.
	1636	ast::MemberExpr const * addrMember = nullptr;
[1ee0a4da]	1637	};
	1638
	1639	PolyGenericCalculator::PolyGenericCalculator() :
	1640	knownLayouts(), knownOffsets(), bufNamer( "_buf" )
	1641	{}
	1642
[fd4df379]	1643	static ast::Type * polyToMonoTypeRec( CodeLocation const & loc,
	1644	ast::Type const * ty ) {
	1645	ast::Type * ret;
	1646	if ( auto aTy = dynamic_cast<ast::ArrayType const *>( ty ) ) {
	1647	// recursive case
	1648	auto monoBase = polyToMonoTypeRec( loc, aTy->base );
	1649	ret = new ast::ArrayType( monoBase, aTy->dimension,
	1650	aTy->isVarLen, aTy->isStatic, aTy->qualifiers );
	1651	} else {
	1652	// base case
	1653	auto charType = new ast::BasicType( ast::BasicKind::Char );
	1654	auto size = new ast::NameExpr( loc,
	1655	sizeofName( Mangle::mangleType( ty ) ) );
	1656	ret = new ast::ArrayType( charType, size,
	1657	ast::VariableLen, ast::DynamicDim, ast::CV::Qualifiers() );
	1658	}
	1659	return ret;
	1660	}
	1661
[1ee0a4da]	1662	/// Converts polymorphic type into a suitable monomorphic representation.
[fd4df379]	1663	/// Simple cases: T -> __attribute__(( aligned(8) )) char[sizeof_T];
	1664	/// Array cases: T[eOut][eIn] -> __attribute__(( aligned(8) )) char[eOut][eIn][sizeof_T];
	1665	ast::Type * polyToMonoType( CodeLocation const & loc, ast::Type const * ty ) {
	1666	auto ret = polyToMonoTypeRec( loc, ty );
[c4b9fa9]	1667	ret->attributes.emplace_back( new ast::Attribute( "aligned",
[fd4df379]	1668	{ ast::ConstantExpr::from_int( loc, 8 ) } ) );
[1ee0a4da]	1669	return ret;
	1670	}
	1671
	1672	void PolyGenericCalculator::previsit( ast::FunctionDecl const * decl ) {
[e14d169]	1673	GuardScope( *this );
[1ee0a4da]	1674	beginTypeScope( decl->type );
	1675	}
	1676
	1677	void PolyGenericCalculator::previsit( ast::TypedefDecl const * decl ) {
	1678	assertf( false, "All typedef declarations should be removed." );
	1679	beginTypeScope( decl->base );
	1680	}
	1681
	1682	void PolyGenericCalculator::previsit( ast::TypeDecl const * decl ) {
	1683	addToTypeVarMap( decl, scopeTypeVars );
	1684	}
	1685
	1686	ast::Decl const * PolyGenericCalculator::postvisit(
	1687	ast::TypeDecl const * decl ) {
	1688	ast::Type const * base = decl->base;
[52a5262e]	1689	if ( nullptr == base ) return decl;
[1ee0a4da]	1690
	1691	// Add size/align variables for opaque type declarations.
	1692	ast::TypeInstType inst( decl->name, decl );
	1693	std::string typeName = Mangle::mangleType( &inst );
	1694
	1695	ast::ObjectDecl * sizeDecl = new ast::ObjectDecl( decl->location,
[dd900b5]	1696	sizeofName( typeName ), makeLayoutCType(),
[1ee0a4da]	1697	new ast::SingleInit( decl->location,
	1698	new ast::SizeofExpr( decl->location, deepCopy( base ) )
	1699	)
	1700	);
	1701	ast::ObjectDecl * alignDecl = new ast::ObjectDecl( decl->location,
[dd900b5]	1702	alignofName( typeName ), makeLayoutCType(),
[1ee0a4da]	1703	new ast::SingleInit( decl->location,
	1704	new ast::AlignofExpr( decl->location, deepCopy( base ) )
	1705	)
	1706	);
	1707
	1708	// Ensure that the initializing sizeof/alignof exprs are properly mutated.
	1709	sizeDecl->accept( *visitor );
	1710	alignDecl->accept( *visitor );
	1711
[52a5262e]	1712	// A little trick to replace this with two declarations.
	1713	// Adding after makes sure that there is no conflict with adding stmts.
[1ee0a4da]	1714	declsToAddAfter.push_back( alignDecl );
	1715	return sizeDecl;
	1716	}
	1717
	1718	ast::StructDecl const * PolyGenericCalculator::previsit(
	1719	ast::StructDecl const * decl ) {
	1720	auto mutDecl = mutate( decl );
	1721	mutateMembers( mutDecl );
	1722	return mutDecl;
	1723	}
	1724
	1725	ast::UnionDecl const * PolyGenericCalculator::previsit(
	1726	ast::UnionDecl const * decl ) {
	1727	auto mutDecl = mutate( decl );
	1728	mutateMembers( mutDecl );
	1729	return mutDecl;
	1730	}
	1731
	1732	ast::DeclStmt const * PolyGenericCalculator::previsit( ast::DeclStmt const * stmt ) {
	1733	ast::ObjectDecl const * decl = stmt->decl.as<ast::ObjectDecl>();
	1734	if ( !decl \|\| !findGeneric( decl->location, decl->type ) ) {
	1735	return stmt;
	1736	}
	1737
	1738	// Change initialization of a polymorphic value object to allocate via a
[52a5262e]	1739	// variable-length-array (alloca cannot be safely used in loops).
[1ee0a4da]	1740	ast::ObjectDecl * newBuf = new ast::ObjectDecl( decl->location,
	1741	bufNamer.newName(),
	1742	polyToMonoType( decl->location, decl->type ),
	1743	nullptr, {}, ast::Linkage::C
	1744	);
	1745	stmtsToAddBefore.push_back( new ast::DeclStmt( stmt->location, newBuf ) );
	1746
	1747	// If the object has a cleanup attribute, the clean-up should be on the
	1748	// buffer, not the pointer. [Perhaps this should be lifted?]
	1749	auto matchAndMove = [newBuf]( ast::ptr<ast::Attribute> & attr ) {
	1750	if ( "cleanup" == attr->name ) {
	1751	newBuf->attributes.push_back( attr );
	1752	return true;
	1753	}
	1754	return false;
	1755	};
	1756
	1757	auto mutDecl = mutate( decl );
	1758
[045cda3]	1759	// Forally, side effects are not safe in this function. But it works.
[1ee0a4da]	1760	erase_if( mutDecl->attributes, matchAndMove );
	1761
[fd4df379]	1762	// Change the decl's type.
	1763	// Upon finishing the box pass, it shall be void*.
	1764	// At this middle-of-box-pass point, that type is T.
	1765
	1766	// example 1
	1767	// before box: T t ;
	1768	// before here: char _bufxx [_sizeof_Y1T]; T t = _bufxx;
	1769	// after here: char _bufxx [_sizeof_Y1T]; T t = _bufxx; (no change here - non array case)
	1770	// after box: char _bufxx [_sizeof_Y1T]; void *t = _bufxx;
	1771
	1772	// example 2
	1773	// before box: T t[42] ;
	1774	// before here: char _bufxx[42][_sizeof_Y1T]; T t[42] = _bufxx;
	1775	// after here: char _bufxx[42][_sizeof_Y1T]; T t = _bufxx;
	1776	// after box: char _bufxx[42][_sizeof_Y1T]; void *t = _bufxx;
	1777
	1778	// Strip all "array of" wrappers
	1779	while ( auto arrayType = dynamic_cast<ast::ArrayType const *>( mutDecl->type.get() ) ) {
	1780	mutDecl->type = arrayType->base;
	1781	}
	1782
[1ee0a4da]	1783	mutDecl->init = new ast::SingleInit( decl->location,
	1784	new ast::VariableExpr( decl->location, newBuf ) );
	1785
	1786	return ast::mutate_field( stmt, &ast::DeclStmt::decl, mutDecl );
	1787	}
	1788
	1789	/// Checks if memberDecl matches the decl from an aggregate.
	1790	bool isMember( ast::DeclWithType const * memberDecl, ast::Decl const * decl ) {
	1791	// No matter the field, if the name is different it is not the same.
	1792	if ( memberDecl->name != decl->name ) {
	1793	return false;
	1794	}
	1795
	1796	if ( memberDecl->name.empty() ) {
	1797	// Plan-9 Field: Match on unique_id.
	1798	return ( memberDecl->uniqueId == decl->uniqueId );
	1799	}
	1800
	1801	ast::DeclWithType const * declWithType =
	1802	strict_dynamic_cast<ast::DeclWithType const *>( decl );
	1803
	1804	if ( memberDecl->mangleName.empty() \|\| declWithType->mangleName.empty() ) {
	1805	// Tuple-Element Field: Expect neither had mangled name;
	1806	// accept match on simple name (like field_2) only.
	1807	assert( memberDecl->mangleName.empty() );
	1808	assert( declWithType->mangleName.empty() );
	1809	return true;
	1810	}
	1811
	1812	// Ordinary Field: Use full name to accommodate overloading.
	1813	return ( memberDecl->mangleName == declWithType->mangleName );
	1814	}
	1815
	1816	/// Finds the member in the base list that matches the given declaration;
	1817	/// returns its index, or -1 if not present.
	1818	long findMember( ast::DeclWithType const * memberDecl,
	1819	const ast::vector<ast::Decl> & baseDecls ) {
[c4b9fa9]	1820	for ( auto const & [index, value] : enumerate( baseDecls ) ) {
	1821	if ( isMember( memberDecl, value.get() ) ) {
	1822	return index;
[1ee0a4da]	1823	}
	1824	}
	1825	return -1;
	1826	}
	1827
	1828	/// Returns an index expression into the offset array for a type.
	1829	ast::Expr * makeOffsetIndex( CodeLocation const & location,
	1830	ast::Type const * objectType, long i ) {
	1831	std::string name = offsetofName( Mangle::mangleType( objectType ) );
	1832	return ast::UntypedExpr::createCall( location, "?[?]", {
	1833	new ast::NameExpr( location, name ),
	1834	ast::ConstantExpr::from_ulong( location, i ),
	1835	} );
	1836	}
	1837
	1838	ast::Expr const * PolyGenericCalculator::postvisit(
	1839	ast::MemberExpr const * expr ) {
	1840	// Only mutate member expressions for polymorphic types.
	1841	ast::Type const * objectType = hasPolyBase(
[4604bf5]	1842	expr->aggregate->result, scopeTypeVars
[1ee0a4da]	1843	);
	1844	if ( !objectType ) return expr;
	1845	// Ensure layout for this type is available.
	1846	// The boolean result is ignored.
	1847	findGeneric( expr->location, objectType );
	1848
	1849	// Replace member expression with dynamically-computed layout expression.
	1850	ast::Expr * newMemberExpr = nullptr;
	1851	if ( auto structType = dynamic_cast<ast::StructInstType const *>( objectType ) ) {
	1852	long offsetIndex = findMember( expr->member, structType->base->members );
	1853	if ( -1 == offsetIndex ) return expr;
	1854
	1855	// Replace member expression with pointer to struct plus offset.
	1856	ast::UntypedExpr * fieldLoc = new ast::UntypedExpr( expr->location,
	1857	new ast::NameExpr( expr->location, "?+?" ) );
	1858	ast::Expr * aggr = deepCopy( expr->aggregate );
	1859	aggr->env = nullptr;
	1860	fieldLoc->args.push_back( aggr );
	1861	fieldLoc->args.push_back(
	1862	makeOffsetIndex( expr->location, objectType, offsetIndex ) );
	1863	fieldLoc->result = deepCopy( expr->result );
	1864	newMemberExpr = fieldLoc;
	1865	// Union members are all at offset zero, so just use the aggregate expr.
	1866	} else if ( dynamic_cast<ast::UnionInstType const *>( objectType ) ) {
	1867	ast::Expr * aggr = deepCopy( expr->aggregate );
	1868	aggr->env = nullptr;
	1869	aggr->result = deepCopy( expr->result );
	1870	newMemberExpr = aggr;
	1871	} else {
	1872	return expr;
	1873	}
	1874	assert( newMemberExpr );
	1875
	1876	// Must apply the generic substitution to the member type to handle cases
	1877	// where the member is a generic parameter subsituted by a known concrete
	1878	// type. [ex]
	1879	// forall( T ) struct Box { T x; }
	1880	// forall( T ) void f() {
	1881	// Box( T * ) b; b.x;
	1882	// }
	1883	// TODO: expr->result should be exactly expr->member->get_type() after
	1884	// substitution, so it doesn't seem like it should be necessary to apply
	1885	// the substitution manually. For some reason this is not currently the
	1886	// case. This requires more investigation.
[045cda3]	1887	ast::ptr<ast::Type> memberType = deepCopy( expr->member->get_type() );
[1ee0a4da]	1888	ast::TypeSubstitution sub = genericSubstitution( objectType );
[045cda3]	1889	sub.apply( memberType );
	1890
[1ee0a4da]	1891	// Not all members of a polymorphic type are themselves of a polymorphic
[be4335b]	1892	// type; in this case the member expression should be wrapped and
[1ee0a4da]	1893	// dereferenced to form an lvalue.
	1894	if ( !isPolyType( memberType, scopeTypeVars ) ) {
	1895	auto ptrCastExpr = new ast::CastExpr( expr->location, newMemberExpr,
	1896	new ast::PointerType( memberType ) );
	1897	auto derefExpr = ast::UntypedExpr::createDeref( expr->location,
	1898	ptrCastExpr );
	1899	newMemberExpr = derefExpr;
	1900	}
	1901
	1902	return newMemberExpr;
	1903	}
	1904
	1905	void PolyGenericCalculator::previsit( ast::AddressExpr const * expr ) {
	1906	GuardValue( addrMember ) = expr->arg.as<ast::MemberExpr>();
	1907	}
	1908
	1909	ast::Expr const * PolyGenericCalculator::postvisit(
	1910	ast::AddressExpr const * expr ) {
	1911	// arg has to have been a MemberExpr and has been mutated.
	1912	if ( nullptr == addrMember \|\| expr->arg == addrMember ) {
	1913	return expr;
	1914	}
	1915	ast::UntypedExpr const * untyped = expr->arg.as<ast::UntypedExpr>();
	1916	if ( !untyped \|\| getFunctionName( untyped ) != "?+?" ) {
	1917	return expr;
	1918	}
	1919	// MemberExpr was converted to pointer + offset; and it is not valid C to
[4604bf5]	1920	// take the address of an addition, so strip away the address-of.
[045cda3]	1921	// It also preserves the env value.
	1922	return ast::mutate_field( expr->arg.get(), &ast::Expr::env, expr->env );
[1ee0a4da]	1923	}
	1924
	1925	ast::Expr const * PolyGenericCalculator::postvisit(
	1926	ast::SizeofExpr const * expr ) {
[b6f2e7ab]	1927	ast::Expr const * gen = genSizeof( expr->location, expr->type );
[1ee0a4da]	1928	return ( gen ) ? gen : expr;
	1929	}
	1930
	1931	ast::Expr const * PolyGenericCalculator::postvisit(
	1932	ast::AlignofExpr const * expr ) {
[b6f2e7ab]	1933	ast::Expr const * gen = genAlignof( expr->location, expr->type );
[fd4df379]	1934	return ( gen ) ? gen : expr;
[1ee0a4da]	1935	}
	1936
	1937	ast::Expr const * PolyGenericCalculator::postvisit(
	1938	ast::OffsetofExpr const * expr ) {
	1939	ast::Type const * type = expr->type;
	1940	if ( !findGeneric( expr->location, type ) ) return expr;
	1941
	1942	// Structures replace offsetof expression with an index into offset array.
	1943	if ( auto structType = dynamic_cast<ast::StructInstType const *>( type ) ) {
	1944	long offsetIndex = findMember( expr->member, structType->base->members );
	1945	if ( -1 == offsetIndex ) return expr;
	1946
	1947	return makeOffsetIndex( expr->location, type, offsetIndex );
	1948	// All union members are at offset zero.
	1949	} else if ( dynamic_cast<ast::UnionInstType const *>( type ) ) {
	1950	return ast::ConstantExpr::from_ulong( expr->location, 0 );
	1951	} else {
	1952	return expr;
	1953	}
	1954	}
	1955
	1956	ast::Expr const * PolyGenericCalculator::postvisit(
	1957	ast::OffsetPackExpr const * expr ) {
	1958	ast::StructInstType const * type = expr->type;
	1959
	1960	// Pull offset back from generated type information.
	1961	if ( findGeneric( expr->location, type ) ) {
	1962	return new ast::NameExpr( expr->location,
	1963	offsetofName( Mangle::mangleType( type ) ) );
	1964	}
	1965
	1966	std::string offsetName = offsetofName( Mangle::mangleType( type ) );
	1967	// Use the already generated offsets for this type.
	1968	if ( knownOffsets.contains( offsetName ) ) {
	1969	return new ast::NameExpr( expr->location, offsetName );
	1970	}
	1971
	1972	knownOffsets.insert( offsetName );
	1973
	1974	// Build initializer list for offset array.
	1975	ast::vector<ast::Init> inits;
[dd900b5]	1976	for ( ast::ptr<ast::Decl> const & member : type->base->members ) {
[1ee0a4da]	1977	auto memberDecl = member.as<ast::DeclWithType>();
	1978	assertf( memberDecl, "Requesting offset of non-DWT member: %s",
	1979	toCString( member ) );
	1980	inits.push_back( new ast::SingleInit( expr->location,
	1981	new ast::OffsetofExpr( expr->location,
	1982	deepCopy( type ),
	1983	memberDecl
	1984	)
	1985	) );
	1986	}
	1987
	1988	auto offsetArray = makeVar( expr->location, offsetName,
	1989	new ast::ArrayType(
[dd900b5]	1990	makeLayoutType(),
	1991	ast::ConstantExpr::from_ulong( expr->location, inits.size() ),
[1ee0a4da]	1992	ast::FixedLen,
	1993	ast::DynamicDim
	1994	),
	1995	new ast::ListInit( expr->location, std::move( inits ) )
	1996	);
	1997
	1998	return new ast::VariableExpr( expr->location, offsetArray );
	1999	}
	2000
	2001	void PolyGenericCalculator::beginScope() {
	2002	knownLayouts.beginScope();
	2003	knownOffsets.beginScope();
	2004	}
	2005
	2006	void PolyGenericCalculator::endScope() {
	2007	knownOffsets.endScope();
	2008	knownLayouts.endScope();
	2009	}
	2010
	2011	ast::ObjectDecl * PolyGenericCalculator::makeVar(
	2012	CodeLocation const & location, std::string const & name,
	2013	ast::Type const * type, ast::Init const * init ) {
	2014	ast::ObjectDecl * ret = new ast::ObjectDecl( location, name, type, init );
	2015	stmtsToAddBefore.push_back( new ast::DeclStmt( location, ret ) );
	2016	return ret;
	2017	}
	2018
	2019	/// Returns true if any of the otype parameters have a dynamic layout; and
	2020	/// puts all otype parameters in the output list.
	2021	bool findGenericParams(
	2022	ast::vector<ast::Type> & out,
	2023	ast::vector<ast::TypeDecl> const & baseParams,
	2024	ast::vector<ast::Expr> const & typeParams ) {
	2025	bool hasDynamicLayout = false;
	2026
[d06273c]	2027	for ( auto const & [baseParam, typeParam] : group_iterate(
	2028	baseParams, typeParams ) ) {
[1ee0a4da]	2029	if ( !baseParam->isComplete() ) continue;
	2030	ast::TypeExpr const * typeExpr = typeParam.as<ast::TypeExpr>();
	2031	assertf( typeExpr, "All type parameters should be type expressions." );
	2032
	2033	ast::Type const * type = typeExpr->type.get();
	2034	out.push_back( type );
	2035	if ( isPolyType( type ) ) hasDynamicLayout = true;
	2036	}
	2037
	2038	return hasDynamicLayout;
	2039	}
	2040
	2041	bool PolyGenericCalculator::findGeneric(
	2042	CodeLocation const & location, ast::Type const * type ) {
	2043	type = replaceTypeInst( type, typeSubs );
	2044
	2045	if ( auto inst = dynamic_cast<ast::TypeInstType const *>( type ) ) {
	2046	// Assumes that getting put in the scopeTypeVars includes having the
	2047	// layout variables set.
	2048	if ( scopeTypeVars.contains( *inst ) ) {
	2049	return true;
	2050	}
	2051	} else if ( auto inst = dynamic_cast<ast::StructInstType const *>( type ) ) {
	2052	// Check if this type already has a layout generated for it.
	2053	std::string typeName = Mangle::mangleType( type );
	2054	if ( knownLayouts.contains( typeName ) ) return true;
	2055
	2056	// Check if any type parameters have dynamic layout;
	2057	// If none do, this type is (or will be) monomorphized.
	2058	ast::vector<ast::Type> sizedParams;
	2059	if ( !findGenericParams( sizedParams,
	2060	inst->base->params, inst->params ) ) {
	2061	return false;
	2062	}
	2063
	2064	// Insert local variables for layout and generate call to layout
	2065	// function.
	2066	// Done early so as not to interfere with the later addition of
	2067	// parameters to the layout call.
	2068	knownLayouts.insert( typeName );
	2069
	2070	int memberCount = inst->base->members.size();
	2071	if ( 0 == memberCount ) {
	2072	// All empty structures have the same layout (size 1, align 1).
	2073	makeVar( location,
[dd900b5]	2074	sizeofName( typeName ), makeLayoutType(),
[1ee0a4da]	2075	new ast::SingleInit( location,
	2076	ast::ConstantExpr::from_ulong( location, 1 ) ) );
	2077	makeVar( location,
[dd900b5]	2078	alignofName( typeName ), makeLayoutType(),
[1ee0a4da]	2079	new ast::SingleInit( location,
	2080	ast::ConstantExpr::from_ulong( location, 1 ) ) );
	2081	// Since 0-length arrays are forbidden in C, skip the offset array.
	2082	} else {
	2083	ast::ObjectDecl const * sizeofVar = makeVar( location,
[dd900b5]	2084	sizeofName( typeName ), makeLayoutType(), nullptr );
[1ee0a4da]	2085	ast::ObjectDecl const * alignofVar = makeVar( location,
[dd900b5]	2086	alignofName( typeName ), makeLayoutType(), nullptr );
[1ee0a4da]	2087	ast::ObjectDecl const * offsetofVar = makeVar( location,
	2088	offsetofName( typeName ),
	2089	new ast::ArrayType(
[dd900b5]	2090	makeLayoutType(),
[1ee0a4da]	2091	ast::ConstantExpr::from_int( location, memberCount ),
	2092	ast::FixedLen,
	2093	ast::DynamicDim
	2094	),
	2095	nullptr
	2096	);
	2097
	2098	// Generate call to layout function.
	2099	ast::UntypedExpr * layoutCall = new ast::UntypedExpr( location,
	2100	new ast::NameExpr( location, layoutofName( inst->base ) ),
	2101	{
	2102	new ast::AddressExpr(
	2103	new ast::VariableExpr( location, sizeofVar ) ),
	2104	new ast::AddressExpr(
	2105	new ast::VariableExpr( location, alignofVar ) ),
	2106	new ast::VariableExpr( location, offsetofVar ),
	2107	} );
	2108
[4604bf5]	2109	addSTypeParamsToLayoutCall( layoutCall, sizedParams );
[1ee0a4da]	2110
	2111	stmtsToAddBefore.emplace_back(
	2112	new ast::ExprStmt( location, layoutCall ) );
	2113	}
	2114
	2115	return true;
	2116	} else if ( auto inst = dynamic_cast<ast::UnionInstType const *>( type ) ) {
	2117	// Check if this type already has a layout generated for it.
	2118	std::string typeName = Mangle::mangleType( type );
	2119	if ( knownLayouts.contains( typeName ) ) return true;
	2120
	2121	// Check if any type parameters have dynamic layout;
	2122	// If none do, this type is (or will be) monomorphized.
	2123	ast::vector<ast::Type> sizedParams;
	2124	if ( !findGenericParams( sizedParams,
	2125	inst->base->params, inst->params ) ) {
	2126	return false;
	2127	}
	2128
	2129	// Insert local variables for layout and generate call to layout
	2130	// function.
	2131	// Done early so as not to interfere with the later addition of
	2132	// parameters to the layout call.
	2133	knownLayouts.insert( typeName );
	2134
	2135	ast::ObjectDecl * sizeofVar = makeVar( location,
[dd900b5]	2136	sizeofName( typeName ), makeLayoutType() );
[1ee0a4da]	2137	ast::ObjectDecl * alignofVar = makeVar( location,
[dd900b5]	2138	alignofName( typeName ), makeLayoutType() );
[1ee0a4da]	2139
	2140	ast::UntypedExpr * layoutCall = new ast::UntypedExpr( location,
	2141	new ast::NameExpr( location, layoutofName( inst->base ) ),
	2142	{
	2143	new ast::AddressExpr(
	2144	new ast::VariableExpr( location, sizeofVar ) ),
	2145	new ast::AddressExpr(
	2146	new ast::VariableExpr( location, alignofVar ) ),
	2147	} );
	2148
[4604bf5]	2149	addSTypeParamsToLayoutCall( layoutCall, sizedParams );
[1ee0a4da]	2150
	2151	stmtsToAddBefore.emplace_back(
	2152	new ast::ExprStmt( location, layoutCall ) );
	2153
	2154	return true;
[fd4df379]	2155
	2156	} else if ( auto inst = dynamic_cast<ast::ArrayType const *>( type ) ) {
	2157	return findGeneric( location, inst->base );
[1ee0a4da]	2158	}
	2159	return false;
	2160	}
	2161
[4604bf5]	2162	void PolyGenericCalculator::addSTypeParamsToLayoutCall(
[1ee0a4da]	2163	ast::UntypedExpr * layoutCall,
	2164	const ast::vector<ast::Type> & otypeParams ) {
	2165	CodeLocation const & location = layoutCall->location;
	2166	ast::vector<ast::Expr> & args = layoutCall->args;
	2167	for ( ast::ptr<ast::Type> const & param : otypeParams ) {
	2168	if ( findGeneric( location, param ) ) {
	2169	// Push size/align vars for a generic parameter back.
	2170	std::string paramName = Mangle::mangleType( param );
	2171	args.emplace_back(
	2172	new ast::NameExpr( location, sizeofName( paramName ) ) );
	2173	args.emplace_back(
	2174	new ast::NameExpr( location, alignofName( paramName ) ) );
	2175	} else {
	2176	args.emplace_back(
	2177	new ast::SizeofExpr( location, ast::deepCopy( param ) ) );
	2178	args.emplace_back(
	2179	new ast::AlignofExpr( location, ast::deepCopy( param ) ) );
	2180	}
	2181	}
	2182	}
	2183
	2184	void PolyGenericCalculator::mutateMembers( ast::AggregateDecl * aggr ) {
	2185	std::set<std::string> genericParams;
	2186	for ( ast::ptr<ast::TypeDecl> const & decl : aggr->params ) {
	2187	genericParams.insert( decl->name );
	2188	}
	2189	for ( ast::ptr<ast::Decl> & decl : aggr->members ) {
	2190	auto field = decl.as<ast::ObjectDecl>();
	2191	if ( nullptr == field ) continue;
	2192
	2193	ast::Type const * type = replaceTypeInst( field->type, typeSubs );
	2194	auto typeInst = dynamic_cast<ast::TypeInstType const *>( type );
	2195	if ( nullptr == typeInst ) continue;
	2196
	2197	// Do not try to monoporphize generic parameters.
	2198	if ( scopeTypeVars.contains( ast::TypeEnvKey( *typeInst ) ) &&
	2199	!genericParams.count( typeInst->name ) ) {
	2200	// Polymorphic aggregate members should be converted into
	2201	// monomorphic members. Using char[size_T] here respects
	2202	// the expected sizing rules of an aggregate type.
	2203	decl = ast::mutate_field( field, &ast::ObjectDecl::type,
	2204	polyToMonoType( field->location, field->type ) );
	2205	}
	2206	}
	2207	}
	2208
	2209	ast::Expr const * PolyGenericCalculator::genSizeof(
	2210	CodeLocation const & location, ast::Type const * type ) {
	2211	if ( auto * array = dynamic_cast<ast::ArrayType const *>( type ) ) {
	2212	// Generate calculated size for possibly generic array.
	2213	ast::Expr const * sizeofBase = genSizeof( location, array->base );
	2214	if ( nullptr == sizeofBase ) return nullptr;
	2215	ast::Expr const * dim = array->dimension;
	2216	return makeOp( location, "?*?", sizeofBase, dim );
	2217	} else if ( findGeneric( location, type ) ) {
[fd4df379]	2218	// Generate reference to _sizeof parameter
[1ee0a4da]	2219	return new ast::NameExpr( location, sizeofName(
	2220	Mangle::mangleType( type ) ) );
	2221	} else {
	2222	return nullptr;
	2223	}
	2224	}
	2225
[fd4df379]	2226	ast::Expr const * PolyGenericCalculator::genAlignof(
	2227	CodeLocation const & location, ast::Type const * type ) {
	2228	if ( auto * array = dynamic_cast<ast::ArrayType const *>( type ) ) {
	2229	// alignof array is alignof element
	2230	return genAlignof( location, array->base );
	2231	} else if ( findGeneric( location, type ) ) {
	2232	// Generate reference to _alignof parameter
	2233	return new ast::NameExpr( location, alignofName(
	2234	Mangle::mangleType( type ) ) );
	2235	} else {
	2236	return nullptr;
	2237	}
	2238	}
	2239
[1ee0a4da]	2240	void PolyGenericCalculator::beginTypeScope( ast::Type const * type ) {
	2241	GuardScope( scopeTypeVars );
	2242	makeTypeVarMap( type, scopeTypeVars );
	2243	}
	2244
	2245	// --------------------------------------------------------------------------
[e14d169]	2246	/// Removes unneeded or incorrect type information.
[1ee0a4da]	2247	/// * Replaces initialization of polymorphic values with alloca.
	2248	/// * Replaces declaration of dtype/ftype with appropriate void expression.
	2249	/// * Replaces sizeof expressions of polymorphic types with a variable.
	2250	/// * Strips fields from generic structure declarations.
	2251	struct Eraser final :
	2252	public ast::WithGuards {
[045cda3]	2253	void guardTypeVarMap( ast::Type const * type ) {
	2254	GuardScope( scopeTypeVars );
	2255	makeTypeVarMap( type, scopeTypeVars );
	2256	}
[1ee0a4da]	2257
	2258	ast::ObjectDecl const * previsit( ast::ObjectDecl const * decl );
	2259	ast::FunctionDecl const * previsit( ast::FunctionDecl const * decl );
[3c4003b9]	2260	ast::FunctionDecl const * postvisit( ast::FunctionDecl const * decl );
[1ee0a4da]	2261	ast::TypedefDecl const * previsit( ast::TypedefDecl const * decl );
	2262	ast::StructDecl const * previsit( ast::StructDecl const * decl );
	2263	ast::UnionDecl const * previsit( ast::UnionDecl const * decl );
	2264	void previsit( ast::TypeDecl const * decl );
	2265	void previsit( ast::PointerType const * type );
	2266	void previsit( ast::FunctionType const * type );
[52a5262e]	2267	public:
	2268	TypeVarMap scopeTypeVars;
[1ee0a4da]	2269	};
	2270
	2271	ast::ObjectDecl const * Eraser::previsit( ast::ObjectDecl const * decl ) {
[045cda3]	2272	guardTypeVarMap( decl->type );
	2273	return scrubAllTypeVars( decl );
[1ee0a4da]	2274	}
	2275
	2276	ast::FunctionDecl const * Eraser::previsit( ast::FunctionDecl const * decl ) {
[045cda3]	2277	guardTypeVarMap( decl->type );
	2278	return scrubAllTypeVars( decl );
[1ee0a4da]	2279	}
	2280
[3c4003b9]	2281	ast::FunctionDecl const * Eraser::postvisit( ast::FunctionDecl const * decl ) {
	2282	if ( decl->type_params.empty() ) return decl;
	2283	auto mutDecl = mutate( decl );
	2284	mutDecl->type_params.clear();
	2285	return mutDecl;
	2286	}
	2287
[1ee0a4da]	2288	ast::TypedefDecl const * Eraser::previsit( ast::TypedefDecl const * decl ) {
[045cda3]	2289	guardTypeVarMap( decl->base );
	2290	return scrubAllTypeVars( decl );
[1ee0a4da]	2291	}
	2292
	2293	/// Strips the members from a generic aggregate.
	2294	template<typename node_t>
	2295	node_t const * stripGenericMembers( node_t const * decl ) {
[045cda3]	2296	if ( decl->params.empty() ) return decl;
	2297	auto mutDecl = ast::mutate( decl );
	2298	mutDecl->members.clear();
	2299	return mutDecl;
[1ee0a4da]	2300	}
	2301
	2302	ast::StructDecl const * Eraser::previsit( ast::StructDecl const * decl ) {
	2303	return stripGenericMembers( decl );
	2304	}
	2305
	2306	ast::UnionDecl const * Eraser::previsit( ast::UnionDecl const * decl ) {
	2307	return stripGenericMembers( decl );
	2308	}
	2309
	2310	void Eraser::previsit( ast::TypeDecl const * decl ) {
	2311	addToTypeVarMap( decl, scopeTypeVars );
	2312	}
	2313
	2314	void Eraser::previsit( ast::PointerType const * type ) {
[045cda3]	2315	guardTypeVarMap( type );
[1ee0a4da]	2316	}
	2317
	2318	void Eraser::previsit( ast::FunctionType const * type ) {
[045cda3]	2319	guardTypeVarMap( type );
[1ee0a4da]	2320	}
	2321
	2322	} // namespace
	2323
	2324	// --------------------------------------------------------------------------
	2325	void box( ast::TranslationUnit & translationUnit ) {
	2326	ast::Pass<LayoutFunctionBuilder>::run( translationUnit );
	2327	ast::Pass<CallAdapter>::run( translationUnit );
	2328	ast::Pass<DeclAdapter>::run( translationUnit );
	2329	ast::Pass<RewireAdapters>::run( translationUnit );
	2330	ast::Pass<PolyGenericCalculator>::run( translationUnit );
	2331	ast::Pass<Eraser>::run( translationUnit );
	2332	}
	2333
	2334	} // namespace GenPoly
	2335
	2336	// Local Variables: //
	2337	// tab-width: 4 //
	2338	// mode: c++ //
	2339	// compile-command: "make install" //
	2340	// End: //

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