void SimpleFunctionCall::analyzeProgram(AnalysisResultPtr ar) { if (m_className.empty()) { addUserFunction(ar, m_name); } else if (m_className != "parent") { addUserClass(ar, m_className); } else { m_parentClass = true; } if (ar->getPhase() == AnalysisResult::AnalyzeInclude) { CHECK_HOOK(onSimpleFunctionCallAnalyzeInclude); ConstructPtr self = shared_from_this(); // We need to know the name of the constant so that we can associate it // with this file before we do type inference. if (m_className.empty() && m_type == DefineFunction) { ScalarExpressionPtr name = dynamic_pointer_cast<ScalarExpression>((*m_params)[0]); string varName; if (name) { varName = name->getIdentifier(); if (!varName.empty()) { ar->getFileScope()->declareConstant(ar, varName); } } // handling define("CONSTANT", ...); if (m_params && m_params->getCount() >= 2) { ScalarExpressionPtr name = dynamic_pointer_cast<ScalarExpression>((*m_params)[0]); string varName; if (name) { varName = name->getIdentifier(); if (!varName.empty()) { ExpressionPtr value = (*m_params)[1]; ConstantTablePtr constants = ar->findConstantDeclarer(varName)->getConstants(); if (constants != ar->getConstants()) { constants->add(varName, NEW_TYPE(Some), value, ar, self); if (name->hasHphpNote("Dynamic")) { constants->setDynamic(ar, varName); } } } } } } if (m_type == UnserializeFunction) { ar->forceClassVariants(); } } if (ar->getPhase() == AnalysisResult::AnalyzeAll) { // Look up the corresponding FunctionScope and ClassScope // for this function call { FunctionScopePtr func; ClassScopePtr cls; if (m_className.empty()) { func = ar->findFunction(m_name); } else { cls = ar->resolveClass(m_className); if (cls) { if (m_name == "__construct") { func = cls->findConstructor(ar, true); } else { func = cls->findFunction(ar, m_name, true, true); } } } if (func && !func->isRedeclaring()) { if (m_funcScope != func) { m_funcScope = func; Construct::recomputeEffects(); } } if (cls && !cls->isRedeclaring()) m_classScope = cls; } // check for dynamic constant and volatile function/class if (m_className.empty() && (m_type == DefinedFunction || m_type == FunctionExistsFunction || m_type == ClassExistsFunction || m_type == InterfaceExistsFunction) && m_params && m_params->getCount() >= 1) { ExpressionPtr value = (*m_params)[0]; if (value->isScalar()) { ScalarExpressionPtr name = dynamic_pointer_cast<ScalarExpression>(value); if (name && name->isLiteralString()) { string symbol = name->getLiteralString(); switch (m_type) { case DefinedFunction: { ConstantTablePtr constants = ar->getConstants(); if (!constants->isPresent(symbol)) { // user constant BlockScopePtr block = ar->findConstantDeclarer(symbol); if (block) { // found the constant constants = block->getConstants(); // set to be dynamic constants->setDynamic(ar, symbol); } } break; } case FunctionExistsFunction: { FunctionScopePtr func = ar->findFunction(Util::toLower(symbol)); if (func && func->isUserFunction()) { func->setVolatile(); } break; } case InterfaceExistsFunction: case ClassExistsFunction: { ClassScopePtr cls = ar->findClass(Util::toLower(symbol)); if (cls && cls->isUserClass()) { cls->setVolatile(); } break; } default: ASSERT(false); } } } } } if (m_params) { if (ar->getPhase() == AnalysisResult::AnalyzeAll) { if (m_funcScope) { ExpressionList ¶ms = *m_params; int mpc = m_funcScope->getMaxParamCount(); for (int i = params.getCount(); i--; ) { ExpressionPtr p = params[i]; if (i < mpc ? m_funcScope->isRefParam(i) : m_funcScope->isReferenceVariableArgument()) { p->setContext(Expression::RefValue); } else if (!(p->getContext() & Expression::RefParameter)) { p->clearContext(Expression::RefValue); } } } else { FunctionScopePtr func = ar->findFunction(m_name); if (func && func->isRedeclaring()) { FunctionScope::RefParamInfoPtr info = FunctionScope::GetRefParamInfo(m_name); if (info) { for (int i = m_params->getCount(); i--; ) { if (info->isRefParam(i)) { m_params->markParam(i, canInvokeFewArgs()); } } } } else { m_params->markParams(false); } } } m_params->analyzeProgram(ar); } }