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source: src/Tuples/TupleExpansion.cc @ 7fe2498

ADTaaron-thesisarm-ehast-experimentalcleanup-dtorsdeferred_resndemanglerenumforall-pointer-decayjacob/cs343-translationjenkins-sandboxnew-astnew-ast-unique-exprnew-envno_listpersistent-indexerpthread-emulationqualifiedEnumresolv-newwith_gc

Last change on this file since 7fe2498 was e6512c8, checked in by Rob Schluntz <rschlunt@…>, 7 years ago
generate tuples by arity to reduce the number of generated structs
Property mode set to `100644`
File size: 14.0 KB

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1	//
2	// Cforall Version 1.0.0 Copyright (C) 2015 University of Waterloo
3	//
4	// The contents of this file are covered under the licence agreement in the
5	// file "LICENCE" distributed with Cforall.
6	//
7	// TupleAssignment.cc --
8	//
9	// Author : Rodolfo G. Esteves
10	// Created On : Mon May 18 07:44:20 2015
11	// Last Modified By : Peter A. Buhr
12	// Last Modified On : Wed Feb 1 16:40:40 2017
13	// Update Count : 3
14	//
15
16	#include <iterator>
17	#include <iostream>
18	#include <cassert>
19	#include "Tuples.h"
20	#include "GenPoly/DeclMutator.h"
21	#include "SynTree/Mutator.h"
22	#include "SynTree/Statement.h"
23	#include "SynTree/Declaration.h"
24	#include "SynTree/Type.h"
25	#include "SynTree/Expression.h"
26	#include "SynTree/Initializer.h"
27	#include "SymTab/Mangler.h"
28	#include "Common/ScopedMap.h"
29	#include "ResolvExpr/typeops.h"
30	#include "InitTweak/GenInit.h"
31	#include "InitTweak/InitTweak.h"
32
33	namespace Tuples {
34	namespace {
35	class MemberTupleExpander final : public Mutator {
36	public:
37	typedef Mutator Parent;
38	using Parent::mutate;
39
40	virtual Expression * mutate( UntypedMemberExpr * memberExpr ) override;
41	};
42
43	class UniqueExprExpander final : public GenPoly::DeclMutator {
44	public:
45	typedef GenPoly::DeclMutator Parent;
46	using Parent::mutate;
47
48	virtual Expression * mutate( UniqueExpr * unqExpr ) override;
49
50	std::map< int, Expression * > decls; // not vector, because order added may not be increasing order
51
52	~UniqueExprExpander() {
53	for ( std::pair<const int, Expression *> & p : decls ) {
54	delete p.second;
55	}
56	}
57	};
58
59	class TupleAssignExpander : public Mutator {
60	public:
61	typedef Mutator Parent;
62	using Parent::mutate;
63
64	virtual Expression * mutate( TupleAssignExpr * tupleExpr );
65	};
66
67	class TupleTypeReplacer : public GenPoly::DeclMutator {
68	public:
69	typedef GenPoly::DeclMutator Parent;
70	using Parent::mutate;
71
72	virtual Type * mutate( TupleType * tupleType ) override;
73
74	virtual CompoundStmt * mutate( CompoundStmt * stmt ) override {
75	typeMap.beginScope();
76	stmt = Parent::mutate( stmt );
77	typeMap.endScope();
78	return stmt;
79	}
80	private:
81	ScopedMap< int, StructDecl * > typeMap;
82	};
83
84	class TupleIndexExpander final : public Mutator {
85	public:
86	typedef Mutator Parent;
87	using Parent::mutate;
88
89	virtual Expression * mutate( TupleIndexExpr * tupleExpr ) override;
90	};
91
92	class TupleExprExpander final : public Mutator {
93	public:
94	typedef Mutator Parent;
95	using Parent::mutate;
96
97	virtual Expression * mutate( TupleExpr * tupleExpr ) override;
98	};
99	}
100
101	void expandMemberTuples( std::list< Declaration * > & translationUnit ) {
102	MemberTupleExpander expander;
103	mutateAll( translationUnit, expander );
104	}
105
106	void expandUniqueExpr( std::list< Declaration * > & translationUnit ) {
107	UniqueExprExpander unqExpander;
108	unqExpander.mutateDeclarationList( translationUnit );
109	}
110
111	void expandTuples( std::list< Declaration * > & translationUnit ) {
112	TupleAssignExpander assnExpander;
113	mutateAll( translationUnit, assnExpander );
114
115	TupleTypeReplacer replacer;
116	replacer.mutateDeclarationList( translationUnit );
117
118	TupleIndexExpander idxExpander;
119	mutateAll( translationUnit, idxExpander );
120
121	TupleExprExpander exprExpander;
122	mutateAll( translationUnit, exprExpander );
123	}
124
125	namespace {
126	/// given a expression representing the member and an expression representing the aggregate,
127	/// reconstructs a flattened UntypedMemberExpr with the right precedence
128	Expression * reconstructMemberExpr( Expression * member, Expression * aggr ) {
129	if ( UntypedMemberExpr * memberExpr = dynamic_cast< UntypedMemberExpr * >( member ) ) {
130	// construct a new UntypedMemberExpr with the correct structure , and recursively
131	// expand that member expression.
132	MemberTupleExpander expander;
133	UntypedMemberExpr * newMemberExpr = new UntypedMemberExpr( memberExpr->get_member(), new UntypedMemberExpr( memberExpr->get_aggregate(), aggr->clone() ) );
134
135	memberExpr->set_member(nullptr);
136	memberExpr->set_aggregate(nullptr);
137	delete memberExpr;
138	return newMemberExpr->acceptMutator( expander );
139	} else {
140	// not a member expression, so there is nothing to do but attach and return
141	return new UntypedMemberExpr( member, aggr->clone() );
142	}
143	}
144	}
145
146	Expression * MemberTupleExpander::mutate( UntypedMemberExpr * memberExpr ) {
147	if ( UntypedTupleExpr * tupleExpr = dynamic_cast< UntypedTupleExpr * > ( memberExpr->get_member() ) ) {
148	Expression * aggr = memberExpr->get_aggregate()->clone()->acceptMutator( *this );
149	// aggregate expressions which might be impure must be wrapped in unique expressions
150	// xxx - if there's a member-tuple expression nested in the aggregate, this currently generates the wrong code if a UniqueExpr is not used, and it's purely an optimization to remove the UniqueExpr
151	// if ( Tuples::maybeImpure( memberExpr->get_aggregate() ) ) aggr = new UniqueExpr( aggr );
152	aggr = new UniqueExpr( aggr );
153	for ( Expression *& expr : tupleExpr->get_exprs() ) {
154	expr = reconstructMemberExpr( expr, aggr );
155	}
156	delete aggr;
157	return tupleExpr;
158	} else {
159	// there may be a tuple expr buried in the aggregate
160	// xxx - this is a memory leak
161	return new UntypedMemberExpr( memberExpr->get_member()->clone(), memberExpr->get_aggregate()->acceptMutator( *this ) );
162	}
163	}
164
165	Expression * UniqueExprExpander::mutate( UniqueExpr * unqExpr ) {
166	unqExpr = safe_dynamic_cast< UniqueExpr * > ( Parent::mutate( unqExpr ) );
167	const int id = unqExpr->get_id();
168
169	// on first time visiting a unique expr with a particular ID, generate the expression that replaces all UniqueExprs with that ID,
170	// and lookup on subsequent hits. This ensures that all unique exprs with the same ID reference the same variable.
171	if ( ! decls.count( id ) ) {
172	Expression * assignUnq;
173	Expression * var = unqExpr->get_var();
174	if ( unqExpr->get_object() ) {
175	// an object was generated to represent this unique expression -- it should be added to the list of declarations now
176	addDeclaration( unqExpr->get_object() );
177	unqExpr->set_object( nullptr );
178	// steal the expr from the unqExpr
179	assignUnq = UntypedExpr::createAssign( unqExpr->get_var()->clone(), unqExpr->get_expr() );
180	unqExpr->set_expr( nullptr );
181	} else {
182	// steal the already generated assignment to var from the unqExpr - this has been generated by FixInit
183	Expression * expr = unqExpr->get_expr();
184	CommaExpr * commaExpr = safe_dynamic_cast< CommaExpr * >( expr );
185	assignUnq = commaExpr->get_arg1();
186	commaExpr->set_arg1( nullptr );
187	}
188	BasicType * boolType = new BasicType( Type::Qualifiers(), BasicType::Bool );
189	ObjectDecl * finished = new ObjectDecl( toString( "_unq_expr_finished_", id ), DeclarationNode::NoStorageClass, LinkageSpec::Cforall, nullptr, new BasicType( Type::Qualifiers(), BasicType::Bool ), new SingleInit( new ConstantExpr( Constant( boolType->clone(), "0" ) ), noDesignators ) );
190	addDeclaration( finished );
191	// (finished ? _unq_expr_N : (_unq_expr_N = <unqExpr->get_expr()>, finished = 1, _unq_expr_N))
192	// This pattern ensures that each unique expression is evaluated once, regardless of evaluation order of the generated C code.
193	Expression * assignFinished = UntypedExpr::createAssign( new VariableExpr(finished), new ConstantExpr( Constant( boolType->clone(), "1" ) ) );
194	ConditionalExpr * condExpr = new ConditionalExpr( new VariableExpr( finished ), var->clone(),
195	new CommaExpr( new CommaExpr( assignUnq, assignFinished ), var->clone() ) );
196	condExpr->set_result( var->get_result()->clone() );
197	condExpr->set_env( maybeClone( unqExpr->get_env() ) );
198	decls[id] = condExpr;
199	}
200	delete unqExpr;
201	return decls[id]->clone();
202	}
203
204	Expression * TupleAssignExpander::mutate( TupleAssignExpr * assnExpr ) {
205	assnExpr = safe_dynamic_cast< TupleAssignExpr * >( Parent::mutate( assnExpr ) );
206	StmtExpr * ret = assnExpr->get_stmtExpr();
207	assnExpr->set_stmtExpr( nullptr );
208	// move env to StmtExpr
209	ret->set_env( assnExpr->get_env() );
210	assnExpr->set_env( nullptr );
211	delete assnExpr;
212	return ret;
213	}
214
215	Type * TupleTypeReplacer::mutate( TupleType * tupleType ) {
216	tupleType = safe_dynamic_cast< TupleType * > ( Parent::mutate( tupleType ) );
217	unsigned tupleSize = tupleType->size();
218	if ( ! typeMap.count( tupleSize ) ) {
219	// generate struct type to replace tuple type based on the number of components in the tuple
220	StructDecl * decl = new StructDecl( toString( "_tuple_type_", tupleSize ) );
221	decl->set_body( true );
222	for ( size_t i = 0; i < tupleSize; ++i ) {
223	TypeDecl * tyParam = new TypeDecl( toString("tuple_param_", i), DeclarationNode::NoStorageClass, nullptr, TypeDecl::Any );
224	decl->get_members().push_back( new ObjectDecl( toString("field_", i), DeclarationNode::NoStorageClass, LinkageSpec::C, nullptr, new TypeInstType( Type::Qualifiers(), tyParam->get_name(), tyParam ), nullptr ) );
225	decl->get_parameters().push_back( tyParam );
226	}
227	if ( tupleSize == 0 ) {
228	// empty structs are not standard C. Add a dummy field to empty tuples to silence warnings when a compound literal Tuple0 is created.
229	decl->get_members().push_back( new ObjectDecl( "dummy", DeclarationNode::NoStorageClass, LinkageSpec::C, nullptr, new BasicType( Type::Qualifiers(), BasicType::SignedInt ), nullptr ) );
230	}
231	typeMap[tupleSize] = decl;
232	addDeclaration( decl );
233	}
234	Type::Qualifiers qualifiers = tupleType->get_qualifiers();
235
236	StructDecl * decl = typeMap[tupleSize];
237	StructInstType * newType = new StructInstType( qualifiers, decl );
238	for ( Type * t : *tupleType ) {
239	newType->get_parameters().push_back( new TypeExpr( t->clone() ) );
240	}
241	delete tupleType;
242	return newType;
243	}
244
245	Expression * TupleIndexExpander::mutate( TupleIndexExpr * tupleExpr ) {
246	Expression * tuple = maybeMutate( tupleExpr->get_tuple(), *this );
247	assert( tuple );
248	tupleExpr->set_tuple( nullptr );
249	unsigned int idx = tupleExpr->get_index();
250	TypeSubstitution * env = tupleExpr->get_env();
251	tupleExpr->set_env( nullptr );
252	delete tupleExpr;
253
254	StructInstType * type = safe_dynamic_cast< StructInstType * >( tuple->get_result() );
255	StructDecl * structDecl = type->get_baseStruct();
256	assert( structDecl->get_members().size() > idx );
257	Declaration * member = *std::next(structDecl->get_members().begin(), idx);
258	MemberExpr * memExpr = new MemberExpr( safe_dynamic_cast< DeclarationWithType * >( member ), tuple );
259	memExpr->set_env( env );
260	return memExpr;
261	}
262
263	Expression * replaceTupleExpr( Type * result, const std::list< Expression * > & exprs, TypeSubstitution * env ) {
264	if ( result->isVoid() ) {
265	// void result - don't need to produce a value for cascading - just output a chain of comma exprs
266	assert( ! exprs.empty() );
267	std::list< Expression * >::const_iterator iter = exprs.begin();
268	Expression * expr = new CastExpr( *iter++ );
269	for ( ; iter != exprs.end(); ++iter ) {
270	expr = new CommaExpr( expr, new CastExpr( *iter ) );
271	}
272	expr->set_env( env );
273	return expr;
274	} else {
275	// typed tuple expression - produce a compound literal which performs each of the expressions
276	// as a distinct part of its initializer - the produced compound literal may be used as part of
277	// another expression
278	std::list< Initializer * > inits;
279	for ( Expression * expr : exprs ) {
280	inits.push_back( new SingleInit( expr ) );
281	}
282	Expression * expr = new CompoundLiteralExpr( result, new ListInit( inits ) );
283	expr->set_env( env );
284	return expr;
285	}
286	}
287
288	Expression * TupleExprExpander::mutate( TupleExpr * tupleExpr ) {
289	// recursively expand sub-tuple-expressions
290	tupleExpr = safe_dynamic_cast<TupleExpr *>(Parent::mutate(tupleExpr));
291	Type * result = tupleExpr->get_result();
292	std::list< Expression * > exprs = tupleExpr->get_exprs();
293	assert( result );
294	TypeSubstitution * env = tupleExpr->get_env();
295
296	// remove data from shell and delete it
297	tupleExpr->set_result( nullptr );
298	tupleExpr->get_exprs().clear();
299	tupleExpr->set_env( nullptr );
300	delete tupleExpr;
301
302	return replaceTupleExpr( result, exprs, env );
303	}
304
305	Type * makeTupleType( const std::list< Expression * > & exprs ) {
306	// produce the TupleType which aggregates the types of the exprs
307	TupleType *tupleType = new TupleType( Type::Qualifiers(true, true, true, true, true) );
308	Type::Qualifiers &qualifiers = tupleType->get_qualifiers();
309	for ( Expression * expr : exprs ) {
310	assert( expr->get_result() );
311	if ( expr->get_result()->isVoid() ) {
312	// if the type of any expr is void, the type of the entire tuple is void
313	delete tupleType;
314	return new VoidType( Type::Qualifiers() );
315	}
316	Type * type = expr->get_result()->clone();
317	tupleType->get_types().push_back( type );
318	// the qualifiers on the tuple type are the qualifiers that exist on all component types
319	qualifiers &= type->get_qualifiers();
320	} // for
321	if ( exprs.empty() ) qualifiers = Type::Qualifiers();
322	return tupleType;
323	}
324
325	TypeInstType * isTtype( Type * type ) {
326	if ( TypeInstType * inst = dynamic_cast< TypeInstType * >( type ) ) {
327	if ( inst->get_baseType()->get_kind() == TypeDecl::Ttype ) {
328	return inst;
329	}
330	}
331	return nullptr;
332	}
333
334	namespace {
335	/// determines if impurity (read: side-effects) may exist in a piece of code. Currently gives a very crude approximation, wherein any function call expression means the code may be impure
336	class ImpurityDetector : public Visitor {
337	public:
338	typedef Visitor Parent;
339	virtual void visit( ApplicationExpr * appExpr ) {
340	if ( DeclarationWithType * function = InitTweak::getFunction( appExpr ) ) {
341	if ( function->get_linkage() == LinkageSpec::Intrinsic ) {
342	if ( function->get_name() == "*?" \|\| function->get_name() == "?[?]" ) {
343	// intrinsic dereference, subscript are pure, but need to recursively look for impurity
344	Parent::visit( appExpr );
345	return;
346	}
347	}
348	}
349	maybeImpure = true;
350	}
351	virtual void visit( UntypedExpr * untypedExpr ) { maybeImpure = true; }
352	bool maybeImpure = false;
353	};
354	} // namespace
355
356	bool maybeImpure( Expression * expr ) {
357	ImpurityDetector detector;
358	expr->accept( detector );
359	return detector.maybeImpure;
360	}
361	} // namespace Tuples
362
363	// Local Variables: //
364	// tab-width: 4 //
365	// mode: c++ //
366	// compile-command: "make install" //
367	// End: //

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