cppcheck/lib/symboldatabase.h

/*
 * Cppcheck - A tool for static C/C++ code analysis
 * Copyright (C) 2007-2016 Cppcheck team.
 *
 * This program is free software: you can redistribute it and/or modify
 * it under the terms of the GNU General Public License as published by
 * the Free Software Foundation, either version 3 of the License, or
 * (at your option) any later version.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */

//---------------------------------------------------------------------------
#ifndef symboldatabaseH
#define symboldatabaseH
//---------------------------------------------------------------------------

#include <string>
#include <list>
#include <vector>
#include <set>
#include <algorithm>
#include <map>

#include "config.h"
#include "token.h"
#include "mathlib.h"

class Tokenizer;
class Settings;
class ErrorLogger;
class Library;

class Scope;
class SymbolDatabase;

/**
 * @brief Access control enumerations.
 */
enum AccessControl { Public, Protected, Private, Global, Namespace, Argument, Local, Throw };

/**
 * @brief Array dimension information.
 */
struct Dimension {
    Dimension() : start(nullptr), end(nullptr), num(0), known(true) { }

    const Token *start;  // size start token
    const Token *end;    // size end token
    MathLib::bigint num; // (assumed) dimension length when size is a number, 0 if not known
    bool known;          // Known size
};

/** @brief Information about a class type. */
class CPPCHECKLIB Type {
public:
    const Token* classDef; // Points to "class" token
    const Scope* classScope;
    const Scope* enclosingScope;
    enum NeedInitialization {
        Unknown, True, False
    } needInitialization;

    class BaseInfo {
    public:
        BaseInfo() :
            type(nullptr), nameTok(nullptr), access(Public), isVirtual(false) {
        }

        std::string name;
        const Type* type;
        const Token* nameTok;
        AccessControl access;  // public/protected/private
        bool isVirtual;
        // allow ordering within containers
        bool operator<(const BaseInfo& rhs) const {
            return this->type < rhs.type;
        }
    };

    struct FriendInfo {
        FriendInfo() :
            nameStart(nullptr), nameEnd(nullptr), type(nullptr) {
        }

        const Token* nameStart;
        const Token* nameEnd;
        std::string name;
        const Type* type;
    };

    std::vector<BaseInfo> derivedFrom;
    std::list<FriendInfo> friendList;

    Type(const Token* classDef_ = 0, const Scope* classScope_ = 0, const Scope* enclosingScope_ = 0) :
        classDef(classDef_),
        classScope(classScope_),
        enclosingScope(enclosingScope_),
        needInitialization(Unknown) {
        if (classDef_ && classDef_->str() == "enum")
            needInitialization = True;
    }

    const std::string& name() const;

    bool isEnumType() const {
        return classDef && classDef->str() == "enum";
    }

    const Token *initBaseInfo(const Token *tok, const Token *tok1);

    const Function* getFunction(const std::string& funcName) const;

    /**
    * Check for circulare dependencies, i.e. loops within the class hierarchie
    * @param ancestors list of ancestors. For internal usage only, clients should not supply this argument.
    * @return true if there is a circular dependency
    */
    bool hasCircularDependencies(std::set<BaseInfo>* ancestors = nullptr) const;

    /**
    * Check for dependency
    * @param ancestor potential ancestor
    * @return true if there is a dependency
    */
    bool findDependency(const Type* ancestor) const;
};

class CPPCHECKLIB Enumerator {
public:
    explicit Enumerator(const Scope * scope_) : scope(scope_), name(nullptr), value(0), start(nullptr), end(nullptr), value_known(false) { }
    const Scope * scope;
    const Token * name;
    MathLib::bigint value;
    const Token * start;
    const Token * end;
    bool value_known;
};

/** @brief Information about a member variable. */
class CPPCHECKLIB Variable {
    /** @brief flags mask used to access specific bit. */
    enum {
        fIsMutable   = (1 << 0), /** @brief mutable variable */
        fIsStatic    = (1 << 1), /** @brief static variable */
        fIsConst     = (1 << 2), /** @brief const variable */
        fIsExtern    = (1 << 3), /** @brief extern variable */
        fIsClass     = (1 << 4), /** @brief user defined type */
        fIsArray     = (1 << 5), /** @brief array variable */
        fIsPointer   = (1 << 6), /** @brief pointer variable */
        fIsReference = (1 << 7), /** @brief reference variable */
        fIsRValueRef = (1 << 8), /** @brief rvalue reference variable */
        fHasDefault  = (1 << 9), /** @brief function argument with default value */
        fIsStlType   = (1 << 10), /** @brief STL type ('std::') */
        fIsStlString = (1 << 11), /** @brief std::string|wstring|basic_string&lt;T&gt;|u16string|u32string */
        fIsFloatType = (1 << 12)  /** @brief Floating point type */
    };

    /**
     * Get specified flag state.
     * @param flag_ flag to get state of
     * @return true if flag set or false in flag not set
     */
    bool getFlag(unsigned int flag_) const {
        return bool((_flags & flag_) != 0);
    }

    /**
     * Set specified flag state.
     * @param flag_ flag to set state
     * @param state_ new state of flag
     */
    void setFlag(unsigned int flag_, bool state_) {
        _flags = state_ ? _flags | flag_ : _flags & ~flag_;
    }

    /**
     * @brief parse and save array dimension information
     * @param lib Library instance
     * @return true if array, false if not
     */
    bool arrayDimensions(const Library* lib);

public:
    Variable(const Token *name_, const Token *start_, const Token *end_,
             std::size_t index_, AccessControl access_, const Type *type_,
             const Scope *scope_, const Library* lib)
        : _name(name_),
          _start(start_),
          _end(end_),
          _index(index_),
          _access(access_),
          _flags(0),
          _type(type_),
          _scope(scope_) {
        evaluate(lib);
    }

    /**
     * Get name token.
     * @return name token
     */
    const Token *nameToken() const {
        return _name;
    }

    /**
     * Get type start token.
     * The type start token doesn't account 'static' and 'const' qualifiers
     * E.g.:
     *     static const int * const p = ...;
     * type start token ^
     * @return type start token
     */
    const Token *typeStartToken() const {
        return _start;
    }

    /**
     * Get type end token.
     * The type end token doesn't account the forward 'const' qualifier
     * E.g.:
     *     static const int * const p = ...;
     *       type end token ^
     * @return type end token
     */
    const Token *typeEndToken() const {
        return _end;
    }

    /**
     * Get end token of variable declaration
     * E.g.
     * int i[2][3] = ...
     *   end token ^
     * @return variable declaration end token
     */
    const Token *declEndToken() const;

    /**
     * Get name string.
     * @return name string
     */
    const std::string &name() const {
        // name may not exist for function arguments
        if (_name)
            return _name->str();

        return emptyString;
    }

    /**
     * Get declaration ID (varId used for variable in its declaration).
     * @return declaration ID
     */
    unsigned int declarationId() const {
        // name may not exist for function arguments
        if (_name)
            return _name->varId();

        return 0;
    }

    /**
     * Get index of variable in declared order.
     * @return variable index
     */
    std::size_t index() const {
        return _index;
    }

    /**
     * Is variable public.
     * @return true if public, false if not
     */
    bool isPublic() const {
        return _access == Public;
    }

    /**
     * Is variable protected.
     * @return true if protected, false if not
     */
    bool isProtected() const {
        return _access == Protected;
    }

    /**
     * Is variable private.
     * @return true if private, false if not
     */
    bool isPrivate() const {
        return _access == Private;
    }

    /**
     * Is variable global.
     * @return true if global, false if not
     */
    bool isGlobal() const {
        return _access == Global;
    }

    /**
     * Is variable in a namespace.
     * @return true if in a namespace, false if not
     */
    bool isNamespace() const {
        return _access == Namespace;
    }

    /**
     * Is variable a function argument.
     * @return true if a function argument, false if not
     */
    bool isArgument() const {
        return _access == Argument;
    }

    /**
     * Is variable local.
     * @return true if local, false if not
     */
    bool isLocal() const {
        return (_access == Local) && !isExtern();
    }

    /**
     * Is variable mutable.
     * @return true if mutable, false if not
     */
    bool isMutable() const {
        return getFlag(fIsMutable);
    }

    /**
     * Is variable static.
     * @return true if static, false if not
     */
    bool isStatic() const {
        return getFlag(fIsStatic);
    }

    /**
     * Is variable extern.
     * @return true if extern, false if not
     */
    bool isExtern() const {
        return getFlag(fIsExtern);
    }

    /**
     * Is variable const.
     * @return true if const, false if not
     */
    bool isConst() const {
        return getFlag(fIsConst);
    }

    /**
     * Is variable a throw type.
     * @return true if throw type, false if not
     */
    bool isThrow() const {
        return _access == Throw;
    }

    /**
     * Is variable a user defined (or unknown) type.
     * @return true if user defined type, false if not
     */
    bool isClass() const {
        return getFlag(fIsClass);
    }

    /**
     * Is variable an array.
     * @return true if array, false if not
     */
    bool isArray() const {
        return getFlag(fIsArray) && !getFlag(fIsPointer);
    }

    /**
     * Is pointer variable.
     * @return true if pointer, false otherwise
     */
    bool isPointer() const {
        return getFlag(fIsPointer);
    }

    /**
     * Is variable a pointer to an array
     * @return true if pointer to array, false otherwise
     */
    bool isPointerToArray() const {
        return isPointer() && getFlag(fIsArray);
    }

    /**
     * Is variable an array of pointers
     * @return true if array or pointers, false otherwise
     */
    bool isPointerArray() const;

    /**
     * Is array or pointer variable.
     * @return true if pointer or array, false otherwise
     */
    bool isArrayOrPointer() const {
        return getFlag(fIsArray) || getFlag(fIsPointer);
    }

    /**
     * Is reference variable.
     * @return true if reference, false otherwise
     */
    bool isReference() const {
        return getFlag(fIsReference);
    }

    /**
     * Is reference variable.
     * @return true if reference, false otherwise
     */
    bool isRValueReference() const {
        return getFlag(fIsRValueRef);
    }

    /**
     * Does variable have a default value.
     * @return true if has a default falue, false if not
     */
    bool hasDefault() const {
        return getFlag(fHasDefault);
    }

    /**
     * Get Type pointer of known type.
     * @return pointer to type if known, NULL if not known
     */
    const Type *type() const {
        return _type;
    }

    /**
     * Get Scope pointer of known type.
     * @return pointer to type scope if known, NULL if not known
     */
    const Scope *typeScope() const {
        return _type ? _type->classScope : 0;
    }

    /**
     * Get Scope pointer of enclosing scope.
     * @return pointer to enclosing scope
     */
    const Scope *scope() const {
        return _scope;
    }

    /**
     * Get array dimensions.
     * @return array dimensions vector
     */
    const std::vector<Dimension> &dimensions() const {
        return _dimensions;
    }

    /**
     * Get array dimension length.
     * @return length of dimension
     */
    MathLib::bigint dimension(std::size_t index_) const {
        return _dimensions[index_].num;
    }

    /**
     * Get array dimension known.
     * @return length of dimension known
     */
    bool dimensionKnown(std::size_t index_) const {
        return _dimensions[index_].known;
    }

    /**
    * Checks if the variable is an STL type ('std::')
    * E.g.:
    *   std::string s;
    *   ...
    *   sVar->isStlType() == true
    * @return true if it is an stl type and its type matches any of the types in 'stlTypes'
    */
    bool isStlType() const {
        return getFlag(fIsStlType);
    }

    /**
     * Checks if the variable is an STL type ('std::')
     * E.g.:
     *   std::string s;
     *   ...
     *   sVar->isStlType() == true
     * @return true if it is an stl type and its type matches any of the types in 'stlTypes'
     */
    bool isStlStringType() const {
        return getFlag(fIsStlString);
    }

    /**
     * Checks if the variable is of any of the STL types passed as arguments ('std::')
     * E.g.:
     *   std::string s;
     *   ...
     *   const char *str[] = {"string", "wstring"};
     *   sVar->isStlType(str) == true
     * @param stlType stl type
     * @return true if it is an stl type and its type matches any of the types in 'stlTypes'
     */
    bool isStlType(const std::string& stlType) const {
        return isStlType() && stlType==_start->strAt(2);
    }

    /**
     * Checks if the variable is of any of the STL types passed as arguments ('std::')
     * E.g.:
     *   std::string s;
     *   ...
     *   const std::set<std::string> str = make_container< std::set<std::string> >() << "string" << "wstring";
     *   sVar->isStlType(str) == true
     * @param stlTypes set of stl types
     * @return true if it is an stl type and its type matches any of the types in 'stlTypes'
     */
    bool isStlType(const std::set<std::string>& stlTypes) const {
        return isStlType() && stlTypes.find(_start->strAt(2))!=stlTypes.end();
    }

    /**
    * Determine whether it's a floating number type
    * @return true if the type is known and it's a floating type (float, double and long double) or a pointer/array to it
    */
    bool isFloatingType() const {
        return getFlag(fIsFloatType);
    }

    /**
    * Determine whether it's an enumeration type
    * @return true if the type is known and it's an enumeration type
    */
    bool isEnumType() const {
        return type() && type()->isEnumType();
    }

private:
    // only symbol database can change the type
    friend class SymbolDatabase;

    /**
     * Set Type pointer to known type.
     * @param t type
     */
    void type(const Type * t) {
        _type = t;
    }

    /** @brief variable name token */
    const Token *_name;

    /** @brief variable type start token */
    const Token *_start;

    /** @brief variable type end token */
    const Token *_end;

    /** @brief order declared */
    std::size_t _index;

    /** @brief what section is this variable declared in? */
    AccessControl _access;  // public/protected/private

    /** @brief flags */
    unsigned int _flags;

    /** @brief pointer to user defined type info (for known types) */
    const Type *_type;

    /** @brief pointer to scope this variable is in */
    const Scope *_scope;

    /** @brief array dimensions */
    std::vector<Dimension> _dimensions;

    /** @brief fill in information, depending on Tokens given at instantiation */
    void evaluate(const Library* lib);
};

class CPPCHECKLIB Function {
    /** @brief flags mask used to access specific bit. */
    enum {
        fHasBody        = (1 << 0),  /** @brief has implementation */
        fIsInline       = (1 << 1),  /** @brief implementation in class definition */
        fIsConst        = (1 << 2),  /** @brief is const */
        fIsVirtual      = (1 << 3),  /** @brief is virtual */
        fIsPure         = (1 << 4),  /** @brief is pure virtual */
        fIsStatic       = (1 << 5),  /** @brief is static */
        fIsStaticLocal  = (1 << 6),  /** @brief is static local */
        fIsExtern       = (1 << 7),  /** @brief is extern */
        fIsFriend       = (1 << 8),  /** @brief is friend */
        fIsExplicit     = (1 << 9),  /** @brief is explicit */
        fIsDefault      = (1 << 10), /** @brief is default */
        fIsDelete       = (1 << 11), /** @brief is delete */
        fIsNoExcept     = (1 << 12), /** @brief is noexcept */
        fIsThrow        = (1 << 13), /** @brief is throw */
        fIsOperator     = (1 << 14), /** @brief is operator */
        fHasLvalRefQual = (1 << 15), /** @brief has & lvalue ref-qualifier */
        fHasRvalRefQual = (1 << 16)  /** @brief has && rvalue ref-qualifier */
    };

    /**
     * Get specified flag state.
     * @param flag flag to get state of
     * @return true if flag set or false in flag not set
     */
    bool getFlag(unsigned int flag) const {
        return bool((flags & flag) != 0);
    }

    /**
     * Set specified flag state.
     * @param flag flag to set state
     * @param state new state of flag
     */
    void setFlag(unsigned int flag, bool state) {
        flags = state ? flags | flag : flags & ~flag;
    }

public:
    enum Type { eConstructor, eCopyConstructor, eMoveConstructor, eOperatorEqual, eDestructor, eFunction };

    Function()
        : tokenDef(nullptr),
          argDef(nullptr),
          token(nullptr),
          arg(nullptr),
          retDef(nullptr),
          retType(nullptr),
          functionScope(nullptr),
          nestedIn(nullptr),
          initArgCount(0),
          type(eFunction),
          access(Public),
          noexceptArg(nullptr),
          throwArg(nullptr),
          flags(0) {
    }

    const std::string &name() const {
        return tokenDef->str();
    }

    std::size_t argCount() const {
        return argumentList.size();
    }
    std::size_t minArgCount() const {
        return argumentList.size() - initArgCount;
    }
    const Variable* getArgumentVar(std::size_t num) const;
    unsigned int initializedArgCount() const {
        return initArgCount;
    }
    void addArguments(const SymbolDatabase *symbolDatabase, const Scope *scope);
    /** @brief check if this function is virtual in the base classes */
    bool isImplicitlyVirtual(bool defaultVal = false) const;

    bool isConstructor() const {
        return type==eConstructor ||
               type==eCopyConstructor ||
               type==eMoveConstructor;
    }

    bool isDestructor() const {
        return type==eDestructor;
    }
    bool isAttributeConstructor() const {
        return tokenDef->isAttributeConstructor();
    }
    bool isAttributeDestructor() const {
        return tokenDef->isAttributeDestructor();
    }
    bool isAttributePure() const {
        return tokenDef->isAttributePure();
    }
    bool isAttributeConst() const {
        return tokenDef->isAttributeConst();
    }
    bool isAttributeNoreturn() const {
        return tokenDef->isAttributeNoreturn();
    }
    bool isAttributeNothrow() const {
        return tokenDef->isAttributeNothrow();
    }

    bool hasBody() const {
        return getFlag(fHasBody);
    }
    bool isInline() const {
        return getFlag(fIsInline);
    }
    bool isConst() const {
        return getFlag(fIsConst);
    }
    bool isVirtual() const {
        return getFlag(fIsVirtual);
    }
    bool isPure() const {
        return getFlag(fIsPure);
    }
    bool isStatic() const {
        return getFlag(fIsStatic);
    }
    bool isStaticLocal() const {
        return getFlag(fIsStaticLocal);
    }
    bool isExtern() const {
        return getFlag(fIsExtern);
    }
    bool isFriend() const {
        return getFlag(fIsFriend);
    }
    bool isExplicit() const {
        return getFlag(fIsExplicit);
    }
    bool isDefault() const {
        return getFlag(fIsDefault);
    }
    bool isDelete() const {
        return getFlag(fIsDelete);
    }
    bool isNoExcept() const {
        return getFlag(fIsNoExcept);
    }
    bool isThrow() const {
        return getFlag(fIsThrow);
    }
    bool isOperator() const {
        return getFlag(fIsOperator);
    }
    bool hasLvalRefQualifier() const {
        return getFlag(fHasLvalRefQual);
    }
    bool hasRvalRefQualifier() const {
        return getFlag(fHasRvalRefQual);
    }

    void hasBody(bool state) {
        setFlag(fHasBody, state);
    }
    void isInline(bool state) {
        setFlag(fIsInline, state);
    }
    void isConst(bool state) {
        setFlag(fIsConst, state);
    }
    void isVirtual(bool state) {
        setFlag(fIsVirtual, state);
    }
    void isPure(bool state) {
        setFlag(fIsPure, state);
    }
    void isStatic(bool state) {
        setFlag(fIsStatic, state);
    }
    void isStaticLocal(bool state) {
        setFlag(fIsStaticLocal, state);
    }
    void isExtern(bool state) {
        setFlag(fIsExtern, state);
    }
    void isFriend(bool state) {
        setFlag(fIsFriend, state);
    }
    void isExplicit(bool state) {
        setFlag(fIsExplicit, state);
    }
    void isDefault(bool state) {
        setFlag(fIsDefault, state);
    }
    void isDelete(bool state) {
        setFlag(fIsDelete, state);
    }
    void isNoExcept(bool state) {
        setFlag(fIsNoExcept, state);
    }
    void isThrow(bool state) {
        setFlag(fIsThrow, state);
    }
    void isOperator(bool state) {
        setFlag(fIsOperator, state);
    }
    void hasLvalRefQualifier(bool state) {
        setFlag(fHasLvalRefQual, state);
    }
    void hasRvalRefQualifier(bool state) {
        setFlag(fHasRvalRefQual, state);
    }

    const Token *tokenDef; // function name token in class definition
    const Token *argDef;   // function argument start '(' in class definition
    const Token *token;    // function name token in implementation
    const Token *arg;      // function argument start '('
    const Token *retDef;   // function return type token
    const ::Type *retType; // function return type
    const Scope *functionScope; // scope of function body
    const Scope* nestedIn; // Scope the function is declared in
    std::list<Variable> argumentList; // argument list
    unsigned int initArgCount; // number of args with default values
    Type type;             // constructor, destructor, ...
    AccessControl access;  // public/protected/private
    const Token *noexceptArg;
    const Token *throwArg;

    static bool argsMatch(const Scope *info, const Token *first, const Token *second, const std::string &path, unsigned int depth);

private:
    bool isImplicitlyVirtual_rec(const ::Type* baseType, bool& safe) const;

    unsigned int flags;
};

class CPPCHECKLIB Scope {
    // let tests access private function for testing
    friend class TestSymbolDatabase;

public:
    struct UsingInfo {
        const Token *start;
        const Scope *scope;
    };

    enum ScopeType { eGlobal, eClass, eStruct, eUnion, eNamespace, eFunction, eIf, eElse, eFor, eWhile, eDo, eSwitch, eUnconditional, eTry, eCatch, eLambda, eEnum };

    Scope(const SymbolDatabase *check_, const Token *classDef_, const Scope *nestedIn_);
    Scope(const SymbolDatabase *check_, const Token *classDef_, const Scope *nestedIn_, ScopeType type_, const Token *start_);

    const SymbolDatabase *check;
    std::string className;
    const Token *classDef;   // class/struct/union/namespace token
    const Token *classStart; // '{' token
    const Token *classEnd;   // '}' token
    std::list<Function> functionList;
    std::multimap<std::string, const Function *> functionMap;
    std::list<Variable> varlist;
    const Scope *nestedIn;
    std::list<Scope *> nestedList;
    unsigned int numConstructors;
    unsigned int numCopyOrMoveConstructors;
    std::list<UsingInfo> usingList;
    ScopeType type;
    Type* definedType;
    std::list<Type*> definedTypes;

    // function specific fields
    const Scope *functionOf; // scope this function belongs to
    Function *function; // function info for this function

    // enum specific fields
    const Token * enumType;
    bool enumClass;

    std::vector<Enumerator> enumeratorList;

    const Enumerator * findEnumerator(const std::string & name) const {
        for (std::size_t i = 0, end = enumeratorList.size(); i < end; ++i) {
            if (enumeratorList[i].name->str() == name)
                return &enumeratorList[i];
        }
        return nullptr;
    }

    bool isClassOrStruct() const {
        return (type == eClass || type == eStruct);
    }

    bool isExecutable() const {
        return type != eClass && type != eStruct && type != eUnion && type != eGlobal && type != eNamespace && type != eEnum;
    }

    bool isLocal() const {
        return (type == eIf || type == eElse ||
                type == eFor || type == eWhile || type == eDo ||
                type == eSwitch || type == eUnconditional ||
                type == eTry || type == eCatch);
    }

    // Is there lambda/inline function(s) in this scope?
    bool hasInlineOrLambdaFunction() const;

    /**
     * @brief find a function
     * @param tok token of function call
     * @param requireConst if const refers to a const variable only const methods should be matched
     * @return pointer to function if found or NULL if not found
     */
    const Function *findFunction(const Token *tok, bool requireConst=false) const;

    /**
     * @brief find if name is in nested list
     * @param name name of nested scope
     */
    Scope *findInNestedList(const std::string & name);

    const Scope *findRecordInNestedList(const std::string & name) const;
    Scope *findRecordInNestedList(const std::string & name) {
        return const_cast<Scope *>(const_cast<const Scope *>(this)->findRecordInNestedList(name));
    }

    const Type* findType(const std::string& name) const;
    Type* findType(const std::string& name) {
        return const_cast<Type*>(const_cast<const Scope *>(this)->findType(name));
    }

    /**
     * @brief find if name is in nested list
     * @param name name of nested scope
     */
    Scope *findInNestedListRecursive(const std::string & name);

    void addVariable(const Token *token_, const Token *start_,
                     const Token *end_, AccessControl access_, const Type *type_,
                     const Scope *scope_, const Library* lib) {
        varlist.push_back(Variable(token_, start_, end_, varlist.size(),
                                   access_,
                                   type_, scope_, lib));
    }

    /** @brief initialize varlist */
    void getVariableList(const Library* lib);

    const Function *getDestructor() const;

    void addFunction(const Function & func) {
        functionList.push_back(func);

        const Function * back = &functionList.back();

        functionMap.insert(make_pair(back->tokenDef->str(), back));
    }

    bool hasDefaultConstructor() const;

    AccessControl defaultAccess() const;

    /**
     * @brief check if statement is variable declaration and add it if it is
     * @param tok pointer to start of statement
     * @param varaccess access control of statement
     * @param lib Library instance
     * @return pointer to last token
     */
    const Token *checkVariable(const Token *tok, AccessControl varaccess, const Library* lib);

    /**
     * @brief get variable from name
     * @param varname name of variable
     * @return pointer to variable
     */
    const Variable *getVariable(const std::string &varname) const;

    const Token * addEnum(const Token * tok, bool isCpp);

private:
    /**
     * @brief helper function for getVariableList()
     * @param tok pointer to token to check
     * @param vartok populated with pointer to the variable token, if found
     * @param typetok populated with pointer to the type token, if found
     * @return true if tok points to a variable declaration, false otherwise
     */
    bool isVariableDeclaration(const Token* const tok, const Token*& vartok, const Token*& typetok) const;

    void findFunctionInBase(const std::string & name, size_t args, std::vector<const Function *> & matches) const;
};

class CPPCHECKLIB SymbolDatabase {
public:
    SymbolDatabase(const Tokenizer *tokenizer, const Settings *settings, ErrorLogger *errorLogger);
    ~SymbolDatabase();

    /** @brief Information about all namespaces/classes/structrues */
    std::list<Scope> scopeList;

    /** @brief Fast access to function scopes */
    std::vector<const Scope *> functionScopes;

    /** @brief Fast access to class and struct scopes */
    std::vector<const Scope *> classAndStructScopes;

    /** @brief Fast access to types */
    std::list<Type> typeList;

    /**
     * @brief find a variable type if it's a user defined type
     * @param start scope to start looking in
     * @param type token containing variable type
     * @return pointer to type if found or NULL if not found
     */
    const Type *findVariableType(const Scope *start, const Token *type) const;

    /**
     * @brief find a function
     * @param tok token of function call
     * @return pointer to function if found or NULL if not found
     */
    const Function *findFunction(const Token *tok) const;

    const Scope *findScopeByName(const std::string& name) const;

    const Type* findType(const Token *tok, const Scope *startScope) const;
    Type* findType(const Token *tok, Scope *startScope) const {
        return const_cast<Type*>(this->findType(tok, const_cast<const Scope *>(startScope)));
    }

    const Scope *findScope(const Token *tok, const Scope *startScope) const;
    Scope *findScope(const Token *tok, Scope *startScope) const {
        return const_cast<Scope *>(this->findScope(tok, const_cast<const Scope *>(startScope)));
    }

    const Variable *getVariableFromVarId(std::size_t varId) const {
        return _variableList.at(varId);
    }

    std::size_t getVariableListSize() const {
        return _variableList.size();
    }

    /**
     * @brief output a debug message
     */
    void debugMessage(const Token *tok, const std::string &msg) const;

    void printOut(const char * title = nullptr) const;
    void printVariable(const Variable *var, const char *indent) const;
    void printXml(std::ostream &out) const;

    bool isCPP() const;

    /*
     * @brief Do a sanity check
     */
    void validate() const;

    void validateExecutableScopes() const;
    /**
     * @brief Check variable list, e.g. variables w/o scope
     */
    void validateVariables() const;

    /** Set valuetype in provided tokenlist */
    static void setValueTypeInTokenList(Token *tokens, bool cpp, char defaultSignedness, const Library* lib);

private:
    friend class Scope;
    friend class Function;

    void addClassFunction(Scope **info, const Token **tok, const Token *argStart);
    Function *addGlobalFunctionDecl(Scope*& scope, const Token* tok, const Token *argStart, const Token* funcStart);
    Function *addGlobalFunction(Scope*& scope, const Token*& tok, const Token *argStart, const Token* funcStart);
    void addNewFunction(Scope **info, const Token **tok);
    bool isFunction(const Token *tok, const Scope* outerScope, const Token **funcStart, const Token **argStart) const;
    const Type *findTypeInNested(const Token *tok, const Scope *startScope) const;
    const Scope *findNamespace(const Token * tok, const Scope * scope) const;
    Function *findFunctionInScope(const Token *func, const Scope *ns);

    /** Whether iName is a keyword as defined in http://en.cppreference.com/w/c/keyword and http://en.cppreference.com/w/cpp/keyword*/
    bool isReservedName(const std::string& iName) const;

    const Enumerator * findEnumerator(const Token * tok) const;

    const Tokenizer *_tokenizer;
    const Settings *_settings;
    ErrorLogger *_errorLogger;

    /** variable symbol table */
    std::vector<const Variable *> _variableList;

    /** list for missing types */
    std::list<Type> _blankTypes;
};

/** Value type */
class CPPCHECKLIB ValueType {
public:
    enum Sign {UNKNOWN_SIGN, SIGNED, UNSIGNED} sign;
    enum Type {UNKNOWN_TYPE, NONSTD, VOID, BOOL, CHAR, SHORT, INT, LONG, LONGLONG, UNKNOWN_INT, FLOAT, DOUBLE, LONGDOUBLE} type;
    unsigned int pointer; // 0=>not pointer, 1=>*, 2=>**, 3=>***, etc
    unsigned int constness;  // bit 0=data, bit 1=*, bit 2=**
    const Scope *typeScope;
    std::string originalTypeName;

    ValueType() : sign(UNKNOWN_SIGN), type(UNKNOWN_TYPE), pointer(0U), constness(0U), typeScope(nullptr) {}
    ValueType(const ValueType &vt) : sign(vt.sign), type(vt.type), pointer(vt.pointer), constness(vt.constness), typeScope(vt.typeScope), originalTypeName(vt.originalTypeName) {}
    ValueType(enum Sign s, enum Type t, unsigned int p) : sign(s), type(t), pointer(p), constness(0U), typeScope(nullptr) {}
    ValueType(enum Sign s, enum Type t, unsigned int p, unsigned int c) : sign(s), type(t), pointer(p), constness(c), typeScope(nullptr) {}
    ValueType(enum Sign s, enum Type t, unsigned int p, unsigned int c, const std::string &otn) : sign(s), type(t), pointer(p), constness(c), typeScope(nullptr), originalTypeName(otn) {}

    bool isIntegral() const {
        return (type >= ValueType::Type::BOOL && type <= ValueType::Type::UNKNOWN_INT);
    }

    std::string str() const;
};


//---------------------------------------------------------------------------
#endif // symboldatabaseH