예제 #1
0
void FunctionScope::init(AnalysisResultConstPtr ar) {
  m_dynamicInvoke = false;
  bool canInline = true;
  if (m_pseudoMain) {
    canInline = false;
    m_variables->forceVariants(ar, VariableTable::AnyVars);
    setReturnType(ar, Type::Variant);
  }

  if (m_refReturn) {
    m_returnType = Type::Variant;
  }

  if (!strcasecmp(m_name.c_str(), "__autoload")) {
    setVolatile();
  }

  // FileScope's flags are from parser, but VariableTable has more flags
  // coming from type inference phase. So we are tranferring these flags
  // just for better modularization between FileScope and VariableTable.
  if (m_attribute & FileScope::ContainsDynamicVariable) {
    m_variables->setAttribute(VariableTable::ContainsDynamicVariable);
  }
  if (m_attribute & FileScope::ContainsLDynamicVariable) {
    m_variables->setAttribute(VariableTable::ContainsLDynamicVariable);
  }
  if (m_attribute & FileScope::ContainsExtract) {
    m_variables->setAttribute(VariableTable::ContainsExtract);
  }
  if (m_attribute & FileScope::ContainsAssert) {
    m_variables->setAttribute(VariableTable::ContainsAssert);
  }
  if (m_attribute & FileScope::ContainsCompact) {
    m_variables->setAttribute(VariableTable::ContainsCompact);
  }
  if (m_attribute & FileScope::ContainsUnset) {
    m_variables->setAttribute(VariableTable::ContainsUnset);
  }
  if (m_attribute & FileScope::ContainsGetDefinedVars) {
    m_variables->setAttribute(VariableTable::ContainsGetDefinedVars);
  }

  if (m_stmt && Option::AllVolatile && !m_pseudoMain && !m_method) {
    m_volatile = true;
  }

  m_dynamic = Option::IsDynamicFunction(m_method, m_name) ||
    Option::EnableEval == Option::FullEval || Option::AllDynamic;
  if (!m_method && Option::DynamicInvokeFunctions.find(m_name) !=
      Option::DynamicInvokeFunctions.end()) {
    setDynamicInvoke();
  }
  if (m_modifiers) {
    m_virtual = m_modifiers->isAbstract();
  }

  if (m_stmt) {
    MethodStatementPtr stmt = dynamic_pointer_cast<MethodStatement>(m_stmt);
    StatementListPtr stmts = stmt->getStmts();
    if (stmts) {
      if (stmts->getRecursiveCount() > Option::InlineFunctionThreshold)
        canInline = false;
      for (int i = 0; i < stmts->getCount(); i++) {
        StatementPtr stmt = (*stmts)[i];
        stmt->setFileLevel();
        if (stmt->is(Statement::KindOfExpStatement)) {
          ExpStatementPtr expStmt = dynamic_pointer_cast<ExpStatement>(stmt);
          ExpressionPtr exp = expStmt->getExpression();
          exp->setTopLevel();
        }
      }
    }
  } else {
    canInline = false;
  }
  m_inlineable = canInline;
}
예제 #2
0
FunctionScope::FunctionScope(AnalysisResultPtr ar, bool method,
                             const std::string &name, StatementPtr stmt,
                             bool reference, int minParam, int maxParam,
                             ModifierExpressionPtr modifiers,
                             int attribute, const std::string &docComment,
                             FileScopePtr file,
                             bool inPseudoMain /* = false */)
    : BlockScope(name, docComment, stmt, BlockScope::FunctionScope),
    m_method(method), m_file(file), m_minParam(0), m_maxParam(0),
    m_attribute(attribute), m_refReturn(reference), m_modifiers(modifiers),
    m_virtual(false), m_overriding(false), m_redeclaring(-1),
    m_volatile(false), m_ignored(false), m_pseudoMain(inPseudoMain),
    m_magicMethod(false), m_system(false), m_inlineable(false), m_sep(false),
    m_containsThis(false), m_staticMethodAutoFixed(false),
    m_callTempCountMax(0), m_callTempCountCurrent(0) {
  bool canInline = true;
  if (inPseudoMain) {
    canInline = false;
    m_variables->forceVariants(ar);
    setReturnType(ar, Type::Variant);
  }
  setParamCounts(ar, minParam, maxParam);

  if (m_refReturn) {
    m_returnType = Type::Variant;
  }

  // FileScope's flags are from parser, but VariableTable has more flags
  // coming from type inference phase. So we are tranferring these two
  // flags just for better modularization between FileScope and VariableTable.
  if (m_attribute & FileScope::ContainsDynamicVariable) {
    m_variables->setAttribute(VariableTable::ContainsDynamicVariable);
  }
  if (m_attribute & FileScope::ContainsLDynamicVariable) {
    m_variables->setAttribute(VariableTable::ContainsLDynamicVariable);
  }
  if (m_attribute & FileScope::ContainsExtract) {
    m_variables->setAttribute(VariableTable::ContainsExtract);
  }
  if (m_attribute & FileScope::ContainsCompact) {
    m_variables->setAttribute(VariableTable::ContainsCompact);
  }
  if (m_attribute & FileScope::ContainsUnset) {
    m_variables->setAttribute(VariableTable::ContainsUnset);
  }
  if (m_attribute & FileScope::ContainsGetDefinedVars) {
    m_variables->setAttribute(VariableTable::ContainsGetDefinedVars);
  }

  if (m_stmt && Option::AllVolatile) {
    m_volatile = true;
  }

  m_dynamic = Option::IsDynamicFunction(method, m_name) ||
    Option::EnableEval == Option::FullEval;
  if (modifiers) {
    m_virtual = modifiers->isAbstract();
  }

  if (m_stmt) {
    MethodStatementPtr stmt = dynamic_pointer_cast<MethodStatement>(m_stmt);
    StatementListPtr stmts = stmt->getStmts();
    if (stmts) {
      if (stmts->getRecursiveCount() > Option::InlineFunctionThreshold)
        canInline = false;
      for (int i = 0; i < stmts->getCount(); i++) {
        StatementPtr stmt = (*stmts)[i];
        stmt->setFileLevel();
        if (stmt->is(Statement::KindOfExpStatement)) {
          ExpStatementPtr expStmt = dynamic_pointer_cast<ExpStatement>(stmt);
          ExpressionPtr exp = expStmt->getExpression();
          exp->setTopLevel();
        }
      }
    }
  } else {
    canInline = false;
  }
  m_inlineable = canInline;
}
예제 #3
0
void StatementList::outputCPPImpl(CodeGenerator &cg, AnalysisResultPtr ar) {
  FunctionScopePtr func = ar->getFunctionScope();
  bool inPseudoMain = func && func->inPseudoMain();
  std::vector<bool> isDeclaration;

  if (inPseudoMain) {
    // We need these declarations to go first, because PHP allows top level
    // function and class declarations to appear after usage.
    for (unsigned int i = 0; i < m_stmts.size(); i++) {
      StatementPtr stmt = m_stmts[i];
      bool isDecl = false;
      if (stmt->is(Statement::KindOfFunctionStatement)) {
        isDecl = true;
      } else if (stmt->is(Statement::KindOfClassStatement) ||
                 stmt->is(Statement::KindOfInterfaceStatement)) {
        ClassScopePtr cls =
          (dynamic_pointer_cast<InterfaceStatement>(stmt))->getClassScope();
        isDecl = cls->isBaseClass() || !cls->isVolatile();
      }
      if (isDecl) stmt->outputCPP(cg,ar);
      isDeclaration.push_back(isDecl);
    }
  }

  for (unsigned int i = 0; i < m_stmts.size(); i++) {
    StatementPtr stmt = m_stmts[i];
    if (stmt->is(Statement::KindOfClassStatement)) {
      if (!inPseudoMain || !isDeclaration[i]) stmt->outputCPP(cg, ar);
    } else if (!(stmt->is(Statement::KindOfFunctionStatement) ||
                 stmt->is(Statement::KindOfInterfaceStatement)) ||
               (!inPseudoMain || !isDeclaration[i])) {
      stmt->outputCPP(cg, ar);
      if (stmt->is(Statement::KindOfMethodStatement)) {
        MethodStatementPtr methodStmt =
          dynamic_pointer_cast<MethodStatement>(stmt);
        std::string methodName = methodStmt->getName();
        if (methodName == "__get") {
          FunctionScopePtr funcScope = methodStmt->getFunctionScope();
          std::string name = funcScope->getName();
          funcScope->setName("__lval");
          methodStmt->setName("__lval");
          methodStmt->outputCPP(cg, ar);
          funcScope->setName(name);
          methodStmt->setName("__get");
        } else if (methodName == "offsetget") {
          ClassScopePtr cls = ar->getClassScope();
          std::string arrayAccess("arrayaccess");
          if (cls->derivesFrom(ar, arrayAccess, false, false)) {
            FunctionScopePtr funcScope = methodStmt->getFunctionScope();
            std::string name = funcScope->getName();
            funcScope->setName("__offsetget_lval");
            methodStmt->setName("__offsetget_lval");
            methodStmt->outputCPP(cg, ar);
            funcScope->setName(name);
            methodStmt->setName("offsetget");
          }
        }
      }
    }
  }
}
예제 #4
0
bool StatementList::mergeConcatAssign(AnalysisResultPtr ar) {
  if (Option::LocalCopyProp) {
    return false;
  } else {
    // check for vector string concat assignment such as
    //   $space = " ";
    //   $a .= "hello";
    //   $a .= $space;
    //   $a .= "world!";
    // turn into (for constant folding and concat sequence)
    //   $a .= " " . "hello " . $space . "world!";
    unsigned int i = 0;
    bool merged = false;
    do {
      std::string lhsName;
      int length = 0;
      for (; i < m_stmts.size(); i++) {
        StatementPtr stmt = m_stmts[i];
        if (!stmt->is(Statement::KindOfExpStatement)) break;
        ExpStatementPtr expStmt = dynamic_pointer_cast<ExpStatement>(stmt);
        ExpressionPtr exp = expStmt->getExpression();

        // check the first assignment
        if (exp->is(Expression::KindOfAssignmentExpression)) {
          AssignmentExpressionPtr assignment_exp =
            dynamic_pointer_cast<AssignmentExpression>(exp);
          ExpressionPtr variable = assignment_exp->getVariable();
          ExpressionPtr value = assignment_exp->getValue();
          std::string variableName = variable->getText();
          if (variableName.find("->") != std::string::npos) break;
          if (value->hasEffect()) break;
          // cannot turn $a .= $b; a .= $a into $a .= $b . $a;
          if (value->getText().find(variableName) != std::string::npos) break;
          if (lhsName.empty()) {
            lhsName = variable->getText();
            length++;
            continue;
          } else {
            break;
          }
        } else if (!exp->is(Expression::KindOfBinaryOpExpression)) {
          break;
        }
        BinaryOpExpressionPtr binaryOpExp =
          dynamic_pointer_cast<BinaryOpExpression>(exp);
        if (binaryOpExp->getOp() != T_CONCAT_EQUAL) break;
        ExpressionPtr exp1 = binaryOpExp->getExp1();
        std::string exp1Text = exp1->getText();
        if (exp1Text.find("->") != std::string::npos) break;
        ExpressionPtr exp2 = binaryOpExp->getExp2();
        if (exp2->hasEffect()) break;
        if (exp2->getText().find(exp1Text) != std::string::npos) break;
        if (lhsName.empty()) {
          lhsName = exp1Text;
          length++;
        } else if (lhsName == exp1Text) {
          length++;
        } else {
          break;
        }
      }
      if (length > 1) {
        // replace m_stmts[j] to m_stmts[i - 1] with a new statement
        unsigned j = i - length;
        ExpStatementPtr expStmt;
        ExpressionPtr exp;
        BinaryOpExpressionPtr binaryOpExp;
        ExpressionPtr var;
        ExpressionPtr exp1;
        ExpressionPtr exp2;
        bool isAssignment = false;
        expStmt = dynamic_pointer_cast<ExpStatement>(m_stmts[j++]);
        exp = expStmt->getExpression();
        if (exp->is(Expression::KindOfAssignmentExpression)) {
          isAssignment = true;
          AssignmentExpressionPtr assignment_exp =
            dynamic_pointer_cast<AssignmentExpression>(exp);
          var = assignment_exp->getVariable();
          exp1 = assignment_exp->getValue();
        } else {
          binaryOpExp = dynamic_pointer_cast<BinaryOpExpression>(exp);
          var = binaryOpExp->getExp1();
          exp1 = binaryOpExp->getExp2();
        }

        for (; j < i; j++) {
          expStmt = dynamic_pointer_cast<ExpStatement>(m_stmts[j]);
          exp = expStmt->getExpression();
          binaryOpExp = dynamic_pointer_cast<BinaryOpExpression>(exp);
          exp2 = binaryOpExp->getExp2();
          exp1 = BinaryOpExpressionPtr
            (new BinaryOpExpression(getLocation(),
                                    Expression::KindOfBinaryOpExpression,
                                    exp1, exp2, '.'));
        }
        if (isAssignment) {
          exp = AssignmentExpressionPtr
            (new AssignmentExpression(exp->getLocation(),
                                      Expression::KindOfAssignmentExpression,
                                      var, exp1,
                                      false));
        } else {
          exp = BinaryOpExpressionPtr
            (new BinaryOpExpression(getLocation(),
                                    Expression::KindOfBinaryOpExpression,
                                    var, exp1, T_CONCAT_EQUAL));
        }
        expStmt = ExpStatementPtr
          (new ExpStatement(getLocation(),
                            Statement::KindOfExpStatement, exp));

        m_stmts[i - length] = expStmt;
        for (j = i - (length - 1); i > j; i--) removeElement(j);
        merged = true;
      } else if (length == 0) {
        i++;
      }
    } while (i < m_stmts.size());
    return merged;
  }
}
예제 #5
0
StatementPtr IfStatement::preOptimize(AnalysisResultConstPtr ar) {
  if (ar->getPhase() < AnalysisResult::FirstPreOptimize) {
    return StatementPtr();
  }

  // we cannot optimize away the code inside if statement, because
  // there may be a goto that goes into if statement.
  if (hasReachableLabel()) {
    return StatementPtr();
  }

  bool changed = false;
  int i;
  int j;
  Variant value;
  bool hoist = false;
  for (i = 0; i < m_stmts->getCount(); i++) {
    IfBranchStatementPtr branch =
      dynamic_pointer_cast<IfBranchStatement>((*m_stmts)[i]);
    ExpressionPtr condition = branch->getCondition();
    if (!condition) {
      StatementPtr stmt = branch->getStmt();
      if (stmt) {
        if (!i &&
            ((getFunctionScope() && !getFunctionScope()->inPseudoMain()) ||
             !stmt->hasDecl())) {
          hoist = true;
          break;
        }
        if (stmt->is(KindOfIfStatement)) {
          StatementListPtr sub_stmts =
            dynamic_pointer_cast<IfStatement>(stmt)->m_stmts;
          m_stmts->removeElement(i);
          changed = true;
          for (j = 0; j < sub_stmts->getCount(); j++) {
            m_stmts->insertElement((*sub_stmts)[j], i++);
          }
        }
      }
      break;
    } else if (condition->getEffectiveScalar(value)) {
      if (value.toBoolean()) {
        hoist = !i &&
          ((getFunctionScope() && !getFunctionScope()->inPseudoMain()) ||
           !branch->hasDecl());
        break;
      } else if (!condition->hasEffect()) {
        m_stmts->removeElement(i--);
        changed = true;
      } else if (branch->getStmt()) {
        branch->clearStmt();
        changed = true;
      }
    }
  }

  if (!changed && i && i == m_stmts->getCount()) return StatementPtr();

  // either else branch or if (true) branch without further declarations

  i++;
  while (i < m_stmts->getCount()) {
    m_stmts->removeElement(i);
    changed = true;
  }

  // if there is only one branch left, return stmt.
  if (hoist) {
    IfBranchStatementPtr branch =
      dynamic_pointer_cast<IfBranchStatement>((*m_stmts)[0]);
    return branch->getStmt() ? branch->getStmt() : NULL_STATEMENT();
  } else if (m_stmts->getCount() == 0) {
    return NULL_STATEMENT();
  } else {
    return changed ? static_pointer_cast<Statement>(shared_from_this())
                   : StatementPtr();
  }
}
예제 #6
0
void MethodStatement::inferFunctionTypes(AnalysisResultPtr ar) {
  IMPLEMENT_INFER_AND_CHECK_ASSERT(getFunctionScope());

  FunctionScopeRawPtr funcScope = getFunctionScope();
  bool pseudoMain = funcScope->inPseudoMain();

  if (m_stmt && funcScope->isFirstPass()) {
    if (pseudoMain ||
        funcScope->getReturnType() ||
        m_stmt->hasRetExp()) {
      bool lastIsReturn = false;
      if (m_stmt->getCount()) {
        StatementPtr lastStmt = (*m_stmt)[m_stmt->getCount()-1];
        if (lastStmt->is(Statement::KindOfReturnStatement)) {
          lastIsReturn = true;
        }
      }
      if (!lastIsReturn) {
        ExpressionPtr constant =
          makeScalarExpression(ar, funcScope->inPseudoMain() ?
                               Variant(1) : Variant(Variant::nullInit));
        ReturnStatementPtr returnStmt =
          ReturnStatementPtr(
            new ReturnStatement(getScope(), getLocation(), constant));
        m_stmt->addElement(returnStmt);
      }
    }
  }

  if (m_params) {
    m_params->inferAndCheck(ar, Type::Any, false);
  }

  // must also include params and use vars if this is a generator. note: we are
  // OK reading the params from the AST nodes of the original generator
  // function, since we have the dependency links set up
  if (funcScope->isGenerator()) {
    // orig function params
    MethodStatementRawPtr m = getOrigGeneratorFunc();
    assert(m);

    VariableTablePtr variables = funcScope->getVariables();
    ExpressionListPtr params = m->getParams();
    if (params) {
      for (int i = 0; i < params->getCount(); i++) {
        ParameterExpressionPtr param =
          dynamic_pointer_cast<ParameterExpression>((*params)[i]);
        const string &name = param->getName();
        assert(!param->isRef() || param->getType()->is(Type::KindOfVariant));
        variables->addParamLike(name, param->getType(), ar, param,
                                funcScope->isFirstPass());
      }
    }

    // use vars
    ExpressionListPtr useVars = m->getFunctionScope()->getClosureVars();
    if (useVars) {
      for (int i = 0; i < useVars->getCount(); i++) {
        ParameterExpressionPtr param =
          dynamic_pointer_cast<ParameterExpression>((*useVars)[i]);
        const string &name = param->getName();
        assert(!param->isRef() || param->getType()->is(Type::KindOfVariant));
        variables->addParamLike(name, param->getType(), ar, param,
                                funcScope->isFirstPass());
      }
    }
  }

  if (m_stmt) {
    m_stmt->inferTypes(ar);
  }
}