#ifndef CRYPTOPP_ALGPARAM_H #define CRYPTOPP_ALGPARAM_H #include "cryptlib.h" #include "smartptr.h" #include "secblock.h" #if GCC_DIAGNOSTIC_AWARE # pragma GCC diagnostic push # pragma GCC diagnostic ignored "-Wunused-value" # pragma GCC diagnostic ignored "-Wunused-variable" #endif NAMESPACE_BEGIN(CryptoPP) //! used to pass byte array input as part of a NameValuePairs object /*! the deepCopy option is used when the NameValuePairs object can't keep a copy of the data available */ class ConstByteArrayParameter { public: ConstByteArrayParameter(const char *data = NULL, bool deepCopy = false) { Assign((const byte *)data, data ? strlen(data) : 0, deepCopy); } ConstByteArrayParameter(const byte *data, size_t size, bool deepCopy = false) { Assign(data, size, deepCopy); } template ConstByteArrayParameter(const T &string, bool deepCopy = false) { CRYPTOPP_COMPILE_ASSERT(sizeof(CPP_TYPENAME T::value_type) == 1); Assign((const byte *)string.data(), string.size(), deepCopy); } void Assign(const byte *data, size_t size, bool deepCopy) { if (deepCopy) m_block.Assign(data, size); else { m_data = data; m_size = size; } m_deepCopy = deepCopy; } const byte *begin() const {return m_deepCopy ? m_block.begin() : m_data;} const byte *end() const {return m_deepCopy ? m_block.end() : m_data + m_size;} size_t size() const {return m_deepCopy ? m_block.size() : m_size;} private: bool m_deepCopy; const byte *m_data; size_t m_size; SecByteBlock m_block; }; class ByteArrayParameter { public: ByteArrayParameter(byte *data = NULL, unsigned int size = 0) : m_data(data), m_size(size) {} ByteArrayParameter(SecByteBlock &block) : m_data(block.begin()), m_size(block.size()) {} byte *begin() const {return m_data;} byte *end() const {return m_data + m_size;} size_t size() const {return m_size;} private: byte *m_data; size_t m_size; }; class CRYPTOPP_DLL CombinedNameValuePairs : public NameValuePairs { public: CombinedNameValuePairs(const NameValuePairs &pairs1, const NameValuePairs &pairs2) : m_pairs1(pairs1), m_pairs2(pairs2) {} bool GetVoidValue(const char *name, const std::type_info &valueType, void *pValue) const; private: const NameValuePairs &m_pairs1, &m_pairs2; }; template class GetValueHelperClass { public: GetValueHelperClass(const T *pObject, const char *name, const std::type_info &valueType, void *pValue, const NameValuePairs *searchFirst) : m_pObject(pObject), m_name(name), m_valueType(&valueType), m_pValue(pValue), m_found(false), m_getValueNames(false) { if (strcmp(m_name, "ValueNames") == 0) { m_found = m_getValueNames = true; NameValuePairs::ThrowIfTypeMismatch(m_name, typeid(std::string), *m_valueType); if (searchFirst) searchFirst->GetVoidValue(m_name, valueType, pValue); if (typeid(T) != typeid(BASE)) pObject->BASE::GetVoidValue(m_name, valueType, pValue); ((*reinterpret_cast(m_pValue) += "ThisPointer:") += typeid(T).name()) += ';'; } if (!m_found && strncmp(m_name, "ThisPointer:", 12) == 0 && strcmp(m_name+12, typeid(T).name()) == 0) { NameValuePairs::ThrowIfTypeMismatch(m_name, typeid(T *), *m_valueType); *reinterpret_cast(pValue) = pObject; m_found = true; return; } if (!m_found && searchFirst) m_found = searchFirst->GetVoidValue(m_name, valueType, pValue); if (!m_found && typeid(T) != typeid(BASE)) m_found = pObject->BASE::GetVoidValue(m_name, valueType, pValue); } operator bool() const {return m_found;} template GetValueHelperClass & operator()(const char *name, const R & (T::*pm)() const) { if (m_getValueNames) (*reinterpret_cast(m_pValue) += name) += ";"; if (!m_found && strcmp(name, m_name) == 0) { NameValuePairs::ThrowIfTypeMismatch(name, typeid(R), *m_valueType); *reinterpret_cast(m_pValue) = (m_pObject->*pm)(); m_found = true; } return *this; } GetValueHelperClass &Assignable() { #ifndef __INTEL_COMPILER // ICL 9.1 workaround: Intel compiler copies the vTable pointer for some reason if (m_getValueNames) ((*reinterpret_cast(m_pValue) += "ThisObject:") += typeid(T).name()) += ';'; if (!m_found && strncmp(m_name, "ThisObject:", 11) == 0 && strcmp(m_name+11, typeid(T).name()) == 0) { NameValuePairs::ThrowIfTypeMismatch(m_name, typeid(T), *m_valueType); *reinterpret_cast(m_pValue) = *m_pObject; m_found = true; } #endif return *this; } private: const T *m_pObject; const char *m_name; const std::type_info *m_valueType; void *m_pValue; bool m_found, m_getValueNames; }; template GetValueHelperClass GetValueHelper(const T *pObject, const char *name, const std::type_info &valueType, void *pValue, const NameValuePairs *searchFirst=NULL, BASE *dummy=NULL) { return GetValueHelperClass(pObject, name, valueType, pValue, searchFirst); } template GetValueHelperClass GetValueHelper(const T *pObject, const char *name, const std::type_info &valueType, void *pValue, const NameValuePairs *searchFirst=NULL) { return GetValueHelperClass(pObject, name, valueType, pValue, searchFirst); } // ******************************************************** template R Hack_DefaultValueFromConstReferenceType(const R &) { return R(); } template bool Hack_GetValueIntoConstReference(const NameValuePairs &source, const char *name, const R &value) { return source.GetValue(name, const_cast(value)); } template class AssignFromHelperClass { public: AssignFromHelperClass(T *pObject, const NameValuePairs &source) : m_pObject(pObject), m_source(source), m_done(false) { if (source.GetThisObject(*pObject)) m_done = true; else if (typeid(BASE) != typeid(T)) pObject->BASE::AssignFrom(source); } template AssignFromHelperClass & operator()(const char *name, void (T::*pm)(R)) // VC60 workaround: "const R &" here causes compiler error { if (!m_done) { R value = Hack_DefaultValueFromConstReferenceType(reinterpret_cast(*(int *)NULL)); if (!Hack_GetValueIntoConstReference(m_source, name, value)) throw InvalidArgument(std::string(typeid(T).name()) + ": Missing required parameter '" + name + "'"); (m_pObject->*pm)(value); } return *this; } template AssignFromHelperClass & operator()(const char *name1, const char *name2, void (T::*pm)(R, S)) // VC60 workaround: "const R &" here causes compiler error { if (!m_done) { R value1 = Hack_DefaultValueFromConstReferenceType(reinterpret_cast(*(int *)NULL)); if (!Hack_GetValueIntoConstReference(m_source, name1, value1)) throw InvalidArgument(std::string(typeid(T).name()) + ": Missing required parameter '" + name1 + "'"); S value2 = Hack_DefaultValueFromConstReferenceType(reinterpret_cast(*(int *)NULL)); if (!Hack_GetValueIntoConstReference(m_source, name2, value2)) throw InvalidArgument(std::string(typeid(T).name()) + ": Missing required parameter '" + name2 + "'"); (m_pObject->*pm)(value1, value2); } return *this; } private: T *m_pObject; const NameValuePairs &m_source; bool m_done; }; template AssignFromHelperClass AssignFromHelper(T *pObject, const NameValuePairs &source, BASE *dummy=NULL) { return AssignFromHelperClass(pObject, source); } template AssignFromHelperClass AssignFromHelper(T *pObject, const NameValuePairs &source) { return AssignFromHelperClass(pObject, source); } // ******************************************************** // to allow the linker to discard Integer code if not needed. typedef bool (CRYPTOPP_API * PAssignIntToInteger)(const std::type_info &valueType, void *pInteger, const void *pInt); CRYPTOPP_DLL extern PAssignIntToInteger g_pAssignIntToInteger; CRYPTOPP_DLL const std::type_info & CRYPTOPP_API IntegerTypeId(); class CRYPTOPP_DLL AlgorithmParametersBase { public: class ParameterNotUsed : public Exception { public: ParameterNotUsed(const char *name) : Exception(OTHER_ERROR, std::string("AlgorithmParametersBase: parameter \"") + name + "\" not used") {} }; // this is actually a move, not a copy AlgorithmParametersBase(const AlgorithmParametersBase &x) : m_name(x.m_name), m_throwIfNotUsed(x.m_throwIfNotUsed), m_used(x.m_used) { m_next.reset(const_cast(x).m_next.release()); x.m_used = true; } AlgorithmParametersBase(const char *name, bool throwIfNotUsed) : m_name(name), m_throwIfNotUsed(throwIfNotUsed), m_used(false) {} virtual ~AlgorithmParametersBase() { #ifdef CRYPTOPP_UNCAUGHT_EXCEPTION_AVAILABLE if (!std::uncaught_exception()) #else try #endif { if (m_throwIfNotUsed && !m_used) throw ParameterNotUsed(m_name); } #ifndef CRYPTOPP_UNCAUGHT_EXCEPTION_AVAILABLE catch(...) { } #endif } bool GetVoidValue(const char *name, const std::type_info &valueType, void *pValue) const; protected: friend class AlgorithmParameters; void operator=(const AlgorithmParametersBase& rhs); // assignment not allowed, declare this for VC60 virtual void AssignValue(const char *name, const std::type_info &valueType, void *pValue) const =0; virtual void MoveInto(void *p) const =0; // not really const const char *m_name; bool m_throwIfNotUsed; mutable bool m_used; member_ptr m_next; }; template class AlgorithmParametersTemplate : public AlgorithmParametersBase { public: AlgorithmParametersTemplate(const char *name, const T &value, bool throwIfNotUsed) : AlgorithmParametersBase(name, throwIfNotUsed), m_value(value) { } void AssignValue(const char *name, const std::type_info &valueType, void *pValue) const { // special case for retrieving an Integer parameter when an int was passed in if (!(g_pAssignIntToInteger != NULL && typeid(T) == typeid(int) && g_pAssignIntToInteger(valueType, pValue, &m_value))) { NameValuePairs::ThrowIfTypeMismatch(name, typeid(T), valueType); *reinterpret_cast(pValue) = m_value; } } void MoveInto(void *buffer) const { AlgorithmParametersTemplate* p = new(buffer) AlgorithmParametersTemplate(*this); CRYPTOPP_UNUSED(p); } protected: T m_value; }; CRYPTOPP_DLL_TEMPLATE_CLASS AlgorithmParametersTemplate; CRYPTOPP_DLL_TEMPLATE_CLASS AlgorithmParametersTemplate; CRYPTOPP_DLL_TEMPLATE_CLASS AlgorithmParametersTemplate; class CRYPTOPP_DLL AlgorithmParameters : public NameValuePairs { public: AlgorithmParameters(); #ifdef __BORLANDC__ template AlgorithmParameters(const char *name, const T &value, bool throwIfNotUsed=true) : m_next(new AlgorithmParametersTemplate(name, value, throwIfNotUsed)) , m_defaultThrowIfNotUsed(throwIfNotUsed) { } #endif AlgorithmParameters(const AlgorithmParameters &x); AlgorithmParameters & operator=(const AlgorithmParameters &x); template AlgorithmParameters & operator()(const char *name, const T &value, bool throwIfNotUsed) { member_ptr p(new AlgorithmParametersTemplate(name, value, throwIfNotUsed)); p->m_next.reset(m_next.release()); m_next.reset(p.release()); m_defaultThrowIfNotUsed = throwIfNotUsed; return *this; } template AlgorithmParameters & operator()(const char *name, const T &value) { return operator()(name, value, m_defaultThrowIfNotUsed); } bool GetVoidValue(const char *name, const std::type_info &valueType, void *pValue) const; protected: member_ptr m_next; bool m_defaultThrowIfNotUsed; }; //! Create an object that implements NameValuePairs for passing parameters /*! \param throwIfNotUsed if true, the object will throw an exception if the value is not accessed \note throwIfNotUsed is ignored if using a compiler that does not support std::uncaught_exception(), such as MSVC 7.0 and earlier. \note A NameValuePairs object containing an arbitrary number of name value pairs may be constructed by repeatedly using operator() on the object returned by MakeParameters, for example: AlgorithmParameters parameters = MakeParameters(name1, value1)(name2, value2)(name3, value3); */ #ifdef __BORLANDC__ typedef AlgorithmParameters MakeParameters; #else template AlgorithmParameters MakeParameters(const char *name, const T &value, bool throwIfNotUsed = true) { return AlgorithmParameters()(name, value, throwIfNotUsed); } #endif #define CRYPTOPP_GET_FUNCTION_ENTRY(name) (Name::name(), &ThisClass::Get##name) #define CRYPTOPP_SET_FUNCTION_ENTRY(name) (Name::name(), &ThisClass::Set##name) #define CRYPTOPP_SET_FUNCTION_ENTRY2(name1, name2) (Name::name1(), Name::name2(), &ThisClass::Set##name1##And##name2) NAMESPACE_END #if GCC_DIAGNOSTIC_AWARE # pragma GCC diagnostic pop #endif #endif