/**************************************************************************
**
** This file is part of Qt Creator
**
** Copyright (c) 2010 Nokia Corporation and/or its subsidiary(-ies).
**
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**
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**
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** accordance with the Qt Commercial License Agreement provided with the
** Software or, alternatively, in accordance with the terms contained in
** a written agreement between you and Nokia.
**
** GNU Lesser General Public License Usage
**
** Alternatively, this file may be used under the terms of the GNU Lesser
** General Public License version 2.1 as published by the Free Software
** Foundation and appearing in the file LICENSE.LGPL included in the
** packaging of this file. Please review the following information to
** ensure the GNU Lesser General Public License version 2.1 requirements
** will be met: http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html.
**
** If you are unsure which license is appropriate for your use, please
** contact the sales department at http://qt.nokia.com/contact.
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**************************************************************************/
#include "ResolveExpression.h"
#include "LookupContext.h"
#include "Overview.h"
#include "DeprecatedGenTemplateInstance.h"
#include "CppRewriter.h"
#include <Control.h>
#include <AST.h>
#include <Scope.h>
#include <Names.h>
#include <Symbols.h>
#include <Literals.h>
#include <CoreTypes.h>
#include <TypeVisitor.h>
#include <NameVisitor.h>
#include <QtCore/QList>
#include <QtCore/QtDebug>
using namespace CPlusPlus;
namespace {
template <typename _Tp>
static QList<_Tp> removeDuplicates(const QList<_Tp> &results)
{
QList<_Tp> uniqueList;
QSet<_Tp> processed;
foreach (const _Tp &r, results) {
if (processed.contains(r))
continue;
processed.insert(r);
uniqueList.append(r);
}
return uniqueList;
}
} // end of anonymous namespace
/////////////////////////////////////////////////////////////////////
// ResolveExpression
/////////////////////////////////////////////////////////////////////
ResolveExpression::ResolveExpression(const LookupContext &context)
: ASTVisitor(context.expressionDocument()->translationUnit()),
_scope(0),
_context(context),
bind(context.expressionDocument()->translationUnit())
{ }
ResolveExpression::~ResolveExpression()
{ }
QList<LookupItem> ResolveExpression::operator()(ExpressionAST *ast, Scope *scope)
{ return resolve(ast, scope); }
QList<LookupItem> ResolveExpression::resolve(ExpressionAST *ast, Scope *scope)
{
if (! scope)
return QList<LookupItem>();
Scope *previousVisibleSymbol = _scope;
_scope = scope;
const QList<LookupItem> result = resolve(ast);
_scope = previousVisibleSymbol;
return result;
}
QList<LookupItem> ResolveExpression::resolve(ExpressionAST *ast)
{
const QList<LookupItem> previousResults = switchResults(QList<LookupItem>());
accept(ast);
return removeDuplicates(switchResults(previousResults));
}
QList<LookupItem> ResolveExpression::switchResults(const QList<LookupItem> &results)
{
const QList<LookupItem> previousResults = _results;
_results = results;
return previousResults;
}
void ResolveExpression::addResults(const QList<Symbol *> &symbols)
{
foreach (Symbol *symbol, symbols) {
LookupItem item;
item.setType(symbol->type());
item.setScope(symbol->scope());
item.setDeclaration(symbol);
_results.append(item);
}
}
void ResolveExpression::addResults(const QList<LookupItem> &items)
{
_results += items;
}
void ResolveExpression::addResult(const FullySpecifiedType &ty, Scope *scope)
{
LookupItem item;
item.setType(ty);
item.setScope(scope);
_results.append(item);
}
bool ResolveExpression::visit(IdExpressionAST *ast)
{
accept(ast->name);
return false;
}
bool ResolveExpression::visit(BinaryExpressionAST *ast)
{
if (tokenKind(ast->binary_op_token) == T_COMMA && ast->right_expression && ast->right_expression->asQtMethod() != 0) {
if (ast->left_expression && ast->left_expression->asQtMethod() != 0)
thisObject();
else
accept(ast->left_expression);
QtMethodAST *qtMethod = ast->right_expression->asQtMethod();
if (DeclaratorAST *d = qtMethod->declarator) {
if (d->core_declarator) {
if (DeclaratorIdAST *declaratorId = d->core_declarator->asDeclaratorId()) {
if (NameAST *nameAST = declaratorId->name) {
if (ClassOrNamespace *binding = baseExpression(_results, T_ARROW)) {
_results.clear();
addResults(binding->lookup(nameAST->name));
}
}
}
}
}
return false;
}
accept(ast->left_expression);
return false;
}
bool ResolveExpression::visit(CastExpressionAST *ast)
{
Scope *dummyScope = _context.expressionDocument()->globalNamespace();
FullySpecifiedType ty = bind(ast->type_id, dummyScope);
addResult(ty, _scope);
return false;
}
bool ResolveExpression::visit(ConditionAST *)
{
// nothing to do.
return false;
}
bool ResolveExpression::visit(ConditionalExpressionAST *ast)
{
if (ast->left_expression)
accept(ast->left_expression);
else if (ast->right_expression)
accept(ast->right_expression);
return false;
}
bool ResolveExpression::visit(CppCastExpressionAST *ast)
{
Scope *dummyScope = _context.expressionDocument()->globalNamespace();
FullySpecifiedType ty = bind(ast->type_id, dummyScope);
addResult(ty, _scope);
return false;
}
bool ResolveExpression::visit(DeleteExpressionAST *)
{
FullySpecifiedType ty(control()->voidType());
addResult(ty, _scope);
return false;
}
bool ResolveExpression::visit(ArrayInitializerAST *)
{
// nothing to do.
return false;
}
bool ResolveExpression::visit(NewExpressionAST *ast)
{
if (ast->new_type_id) {
Scope *dummyScope = _context.expressionDocument()->globalNamespace();
FullySpecifiedType ty = bind(ast->new_type_id, dummyScope);
FullySpecifiedType ptrTy(control()->pointerType(ty));
addResult(ptrTy, _scope);
}
// nothing to do.
return false;
}
bool ResolveExpression::visit(TypeidExpressionAST *)
{
const Name *stdName = control()->nameId(control()->identifier("std"));
const Name *tiName = control()->nameId(control()->identifier("type_info"));
const Name *q = control()->qualifiedNameId(control()->qualifiedNameId(/* :: */ 0, stdName), tiName);
FullySpecifiedType ty(control()->namedType(q));
addResult(ty, _scope);
return false;
}
bool ResolveExpression::visit(TypenameCallExpressionAST *)
{
// nothing to do
return false;
}
bool ResolveExpression::visit(TypeConstructorCallAST *)
{
// nothing to do.
return false;
}
bool ResolveExpression::visit(SizeofExpressionAST *)
{
FullySpecifiedType ty(control()->integerType(IntegerType::Int));
ty.setUnsigned(true);
addResult(ty, _scope);
return false;
}
bool ResolveExpression::visit(NumericLiteralAST *ast)
{
const Token &tk = tokenAt(ast->literal_token);
Type *type = 0;
bool isUnsigned = false;
if (tk.is(T_CHAR_LITERAL))
type = control()->integerType(IntegerType::Char);
else if (tk.is(T_WIDE_CHAR_LITERAL))
type = control()->integerType(IntegerType::WideChar);
else if (const NumericLiteral *literal = numericLiteral(ast->literal_token)) {
isUnsigned = literal->isUnsigned();
if (literal->isInt())
type = control()->integerType(IntegerType::Int);
else if (literal->isLong())
type = control()->integerType(IntegerType::Long);
else if (literal->isLongLong())
type = control()->integerType(IntegerType::LongLong);
else if (literal->isFloat())
type = control()->floatType(FloatType::Float);
else if (literal->isDouble())
type = control()->floatType(FloatType::Double);
else if (literal->isLongDouble())
type = control()->floatType(FloatType::LongDouble);
else
type = control()->integerType(IntegerType::Int);
}
FullySpecifiedType ty(type);
ty.setUnsigned(isUnsigned);
addResult(ty, _scope);
return false;
}
bool ResolveExpression::visit(BoolLiteralAST *)
{
FullySpecifiedType ty(control()->integerType(IntegerType::Bool));
addResult(ty, _scope);
return false;
}
bool ResolveExpression::visit(ThisExpressionAST *)
{
thisObject();
return false;
}
void ResolveExpression::thisObject()
{
Scope *scope = _scope;
for (; scope; scope = scope->scope()) {
if (Function *fun = scope->asFunction()) {
if (Class *klass = scope->enclosingClass()) {
FullySpecifiedType classTy(control()->namedType(klass->name()));
FullySpecifiedType ptrTy(control()->pointerType(classTy));
addResult(ptrTy, fun->scope());
break;
} else if (const QualifiedNameId *q = fun->name()->asQualifiedNameId()) {
if (q->base()) {
FullySpecifiedType classTy(control()->namedType(q->base()));
FullySpecifiedType ptrTy(control()->pointerType(classTy));
addResult(ptrTy, fun->scope());
}
break;
}
}
}
}
bool ResolveExpression::visit(CompoundExpressionAST *ast)
{
CompoundStatementAST *cStmt = ast->statement;
if (cStmt && cStmt->statement_list) {
accept(cStmt->statement_list->lastValue());
}
return false;
}
bool ResolveExpression::visit(NestedExpressionAST *ast)
{
accept(ast->expression);
return false;
}
bool ResolveExpression::visit(StringLiteralAST *)
{
FullySpecifiedType charTy = control()->integerType(IntegerType::Char);
charTy.setConst(true);
FullySpecifiedType ty(control()->pointerType(charTy));
addResult(ty, _scope);
return false;
}
bool ResolveExpression::visit(ThrowExpressionAST *)
{
return false;
}
bool ResolveExpression::visit(TypeIdAST *)
{
return false;
}
bool ResolveExpression::visit(UnaryExpressionAST *ast)
{
accept(ast->expression);
unsigned unaryOp = tokenKind(ast->unary_op_token);
if (unaryOp == T_AMPER) {
QMutableListIterator<LookupItem > it(_results);
while (it.hasNext()) {
LookupItem p = it.next();
FullySpecifiedType ty = p.type();
ty.setType(control()->pointerType(ty));
p.setType(ty);
it.setValue(p);
}
} else if (unaryOp == T_STAR) {
QMutableListIterator<LookupItem > it(_results);
while (it.hasNext()) {
LookupItem p = it.next();
if (PointerType *ptrTy = p.type()->asPointerType()) {
p.setType(ptrTy->elementType());
it.setValue(p);
} else {
it.remove();
}
}
}
return false;
}
bool ResolveExpression::visit(CompoundLiteralAST *ast)
{
accept(ast->type_id);
return false;
}
bool ResolveExpression::visit(QualifiedNameAST *ast)
{
if (const Name *name = ast->name) {
const QList<LookupItem> candidates = _context.lookup(name, _scope);
addResults(candidates);
}
return false;
}
bool ResolveExpression::visit(SimpleNameAST *ast)
{
const QList<LookupItem> candidates = _context.lookup(ast->name, _scope);
addResults(candidates);
return false;
}
bool ResolveExpression::visit(TemplateIdAST *ast)
{
const QList<LookupItem> candidates = _context.lookup(ast->name, _scope);
addResults(candidates);
return false;
}
bool ResolveExpression::visit(DestructorNameAST *)
{
FullySpecifiedType ty(control()->voidType());
addResult(ty, _scope);
return false;
}
bool ResolveExpression::visit(OperatorFunctionIdAST *)
{
return false;
}
bool ResolveExpression::visit(ConversionFunctionIdAST *)
{
return false;
}
bool ResolveExpression::maybeValidPrototype(Function *funTy, unsigned actualArgumentCount) const
{
unsigned minNumberArguments = 0;
for (; minNumberArguments < funTy->argumentCount(); ++minNumberArguments) {
Argument *arg = funTy->argumentAt(minNumberArguments)->asArgument();
if (arg->hasInitializer())
break;
}
if (actualArgumentCount < minNumberArguments) {
// not enough arguments.
return false;
} else if (! funTy->isVariadic() && actualArgumentCount > funTy->argumentCount()) {
// too many arguments.
return false;
}
return true;
}
bool ResolveExpression::visit(CallAST *ast)
{
const QList<LookupItem> baseResults = resolve(ast->base_expression, _scope);
// Compute the types of the actual arguments.
int actualArgumentCount = 0;
//QList< QList<Result> > arguments;
for (ExpressionListAST *exprIt = ast->expression_list; exprIt; exprIt = exprIt->next) {
//arguments.append(resolve(exprIt->expression));
++actualArgumentCount;
}
const Name *functionCallOp = control()->operatorNameId(OperatorNameId::FunctionCallOp);
foreach (const LookupItem &result, baseResults) {
FullySpecifiedType ty = result.type().simplified();
Scope *scope = result.scope();
if (NamedType *namedTy = ty->asNamedType()) {
if (ClassOrNamespace *b = _context.lookupType(namedTy->name(), scope)) {
foreach (const LookupItem &r, b->find(functionCallOp)) {
Symbol *overload = r.declaration();
if (Function *funTy = overload->type()->asFunctionType()) {
if (maybeValidPrototype(funTy, actualArgumentCount)) {
if (Function *proto = instantiate(namedTy->name(), funTy)->asFunctionType())
addResult(proto->returnType().simplified(), scope);
}
}
}
}
} else if (Function *funTy = ty->asFunctionType()) {
if (maybeValidPrototype(funTy, actualArgumentCount))
addResult(funTy->returnType().simplified(), scope);
} else if (Class *classTy = ty->asClassType()) {
// Constructor call
FullySpecifiedType ctorTy = control()->namedType(classTy->name());
addResult(ctorTy, scope);
}
}
return false;
}
bool ResolveExpression::visit(ArrayAccessAST *ast)
{
const QList<LookupItem> baseResults = resolve(ast->base_expression, _scope);
const QList<LookupItem> indexResults = resolve(ast->expression);
const Name *arrayAccessOp = control()->operatorNameId(OperatorNameId::ArrayAccessOp);
foreach (const LookupItem &result, baseResults) {
FullySpecifiedType ty = result.type().simplified();
Scope *scope = result.scope();
if (PointerType *ptrTy = ty->asPointerType()) {
addResult(ptrTy->elementType().simplified(), scope);
} else if (ArrayType *arrTy = ty->asArrayType()) {
addResult(arrTy->elementType().simplified(), scope);
} else if (NamedType *namedTy = ty->asNamedType()) {
if (ClassOrNamespace *b = _context.lookupType(namedTy->name(), scope)) {
foreach (const LookupItem &r, b->find(arrayAccessOp)) {
Symbol *overload = r.declaration();
if (Function *funTy = overload->type()->asFunctionType()) {
if (Function *proto = instantiate(namedTy->name(), funTy)->asFunctionType())
// ### TODO: check the actual arguments
addResult(proto->returnType().simplified(), scope);
}
}
}
}
}
return false;
}
QList<LookupItem> ResolveExpression::getMembers(ClassOrNamespace *binding, const Name *memberName) const
{
Q_UNUSED(binding);
Q_UNUSED(memberName);
// ### port me
QList<LookupItem> members;
#if 0
const QList<LookupItem> originalMembers = binding->find(memberName);
foreach (const LookupItem &m, originalMembers) {
if (! m.binding() || ! m.binding()->templateId()) {
members.append(m);
continue;
}
Symbol *decl = m.declaration();
if (Class *klass = decl->scope()->asClass()) {
if (klass->templateParameters() != 0) {
SubstitutionMap map;
const TemplateNameId *templateId = m.binding()->templateId();
unsigned count = qMin(klass->templateParameterCount(), templateId->templateArgumentCount());
for (unsigned i = 0; i < count; ++i) {
map.bind(klass->templateParameterAt(i)->name(), templateId->templateArgumentAt(i));
}
SubstitutionEnvironment env;
if (m.scope())
env.switchScope(m.scope());
env.setContext(_context);
env.enter(&map);
FullySpecifiedType instantiatedTy = rewriteType(decl->type(), &env, _context.control().data());
Overview oo;
oo.setShowReturnTypes(true);
oo.setShowFunctionSignatures(true);
qDebug() << "original:" << oo(decl->type(), decl->name()) << "inst:" << oo(instantiatedTy, decl->name());
LookupItem newItem;
newItem = m;
newItem.setType(instantiatedTy);
members.append(newItem);
}
}
}
#endif
return members;
}
bool ResolveExpression::visit(MemberAccessAST *ast)
{
// The candidate types for the base expression are stored in
// _results.
const QList<LookupItem> baseResults = resolve(ast->base_expression, _scope);
// Evaluate the expression-id that follows the access operator.
const Name *memberName = 0;
if (ast->member_name)
memberName = ast->member_name->name;
// Remember the access operator.
const int accessOp = tokenKind(ast->access_token);
if (ClassOrNamespace *binding = baseExpression(baseResults, accessOp))
addResults(binding->lookup(memberName));
return false;
}
ClassOrNamespace *ResolveExpression::findClass(const FullySpecifiedType &originalTy, Scope *scope) const
{
FullySpecifiedType ty = originalTy.simplified();
ClassOrNamespace *binding = 0;
if (Class *klass = ty->asClassType())
binding = _context.lookupType(klass);
else if (NamedType *namedTy = ty->asNamedType())
binding = _context.lookupType(namedTy->name(), scope);
else if (Function *funTy = ty->asFunctionType())
return findClass(funTy->returnType(), scope);
return binding;
}
ClassOrNamespace *ResolveExpression::baseExpression(const QList<LookupItem> &baseResults,
int accessOp,
bool *replacedDotOperator) const
{
foreach (const LookupItem &r, baseResults) {
FullySpecifiedType ty = r.type().simplified();
Scope *scope = r.scope();
if (accessOp == T_ARROW) {
if (PointerType *ptrTy = ty->asPointerType()) {
if (ClassOrNamespace *binding = findClass(ptrTy->elementType(), scope))
return binding;
} else if (ClassOrNamespace *binding = findClass(ty, scope)) {
// lookup for overloads of operator->
const OperatorNameId *arrowOp = control()->operatorNameId(OperatorNameId::ArrowOp);
foreach (const LookupItem &r, binding->find(arrowOp)) {
Symbol *overload = r.declaration();
if (! overload)
continue;
if (overload->type()->isFunctionType()) {
FullySpecifiedType overloadTy = instantiate(binding->templateId(), overload);
Function *instantiatedFunction = overloadTy->asFunctionType();
Q_ASSERT(instantiatedFunction != 0);
FullySpecifiedType retTy = instantiatedFunction->returnType().simplified();
if (PointerType *ptrTy = retTy->asPointerType()) {
if (ClassOrNamespace *retBinding = findClass(ptrTy->elementType(), overload->scope()))
return retBinding;
else if (scope != overload->scope()) {
if (ClassOrNamespace *retBinding = findClass(ptrTy->elementType(), scope))
return retBinding;
}
}
}
}
}
} else if (accessOp == T_DOT) {
if (replacedDotOperator) {
if (PointerType *ptrTy = ty->asPointerType()) {
// replace . with ->
ty = ptrTy->elementType();
*replacedDotOperator = true;
}
}
if (ClassOrNamespace *binding = findClass(ty, scope))
return binding;
}
}
return 0;
}
FullySpecifiedType ResolveExpression::instantiate(const Name *className, Symbol *candidate) const
{
return DeprecatedGenTemplateInstance::instantiate(className, candidate, _context.control());
}
bool ResolveExpression::visit(PostIncrDecrAST *ast)
{
const QList<LookupItem> baseResults = resolve(ast->base_expression, _scope);
_results = baseResults;
return false;
}
bool ResolveExpression::visit(ObjCMessageExpressionAST *ast)
{
const QList<LookupItem> receiverResults = resolve(ast->receiver_expression);
foreach (const LookupItem &result, receiverResults) {
FullySpecifiedType ty = result.type().simplified();
ClassOrNamespace *binding = 0;
if (ObjCClass *clazz = ty->asObjCClassType()) {
// static access, e.g.:
// [NSObject description];
binding = _context.lookupType(clazz);
} else if (PointerType *ptrTy = ty->asPointerType()) {
if (NamedType *namedTy = ptrTy->elementType()->asNamedType()) {
// dynamic access, e.g.:
// NSObject *obj = ...; [obj release];
binding = _context.lookupType(namedTy->name(), result.scope());
}
}
if (binding) {
foreach (const LookupItem &r, binding->lookup(ast->selector->name)) {
Symbol *s = r.declaration();
if (ObjCMethod *m = s->asObjCMethod())
addResult(m->returnType(), result.scope());
}
}
}
return false;
}