// secblock.h - written and placed in the public domain by Wei Dai #ifndef CRYPTOPP_SECBLOCK_H #define CRYPTOPP_SECBLOCK_H #include "config.h" #include "misc.h" #include #if defined(CRYPTOPP_MEMALIGN_AVAILABLE) || defined(CRYPTOPP_MM_MALLOC_AVAILABLE) || defined(QNX) #include #else #include #endif NAMESPACE_BEGIN(CryptoPP) // ************** secure memory allocation *************** template class AllocatorBase { public: typedef T value_type; typedef size_t size_type; #ifdef CRYPTOPP_MSVCRT6 typedef ptrdiff_t difference_type; #else typedef std::ptrdiff_t difference_type; #endif typedef T * pointer; typedef const T * const_pointer; typedef T & reference; typedef const T & const_reference; pointer address(reference r) const {return (&r);} const_pointer address(const_reference r) const {return (&r); } void construct(pointer p, const T& val) {new (p) T(val);} void destroy(pointer p) {p->~T();} size_type max_size() const {return ~size_type(0)/sizeof(T);} // switch to std::numeric_limits::max later protected: static void CheckSize(size_t n) { if (n > ~size_t(0) / sizeof(T)) throw InvalidArgument("AllocatorBase: requested size would cause integer overflow"); } }; #define CRYPTOPP_INHERIT_ALLOCATOR_TYPES \ typedef typename AllocatorBase::value_type value_type;\ typedef typename AllocatorBase::size_type size_type;\ typedef typename AllocatorBase::difference_type difference_type;\ typedef typename AllocatorBase::pointer pointer;\ typedef typename AllocatorBase::const_pointer const_pointer;\ typedef typename AllocatorBase::reference reference;\ typedef typename AllocatorBase::const_reference const_reference; #if defined(_MSC_VER) && (_MSC_VER < 1300) // this pragma causes an internal compiler error if placed immediately before std::swap(a, b) #pragma warning(push) #pragma warning(disable: 4700) // VC60 workaround: don't know how to get rid of this warning #endif template typename A::pointer StandardReallocate(A& a, T *p, typename A::size_type oldSize, typename A::size_type newSize, bool preserve) { if (oldSize == newSize) return p; if (preserve) { typename A::pointer newPointer = a.allocate(newSize, NULL); memcpy_s(newPointer, sizeof(T)*newSize, p, sizeof(T)*STDMIN(oldSize, newSize)); a.deallocate(p, oldSize); return newPointer; } else { a.deallocate(p, oldSize); return a.allocate(newSize, NULL); } } #if defined(_MSC_VER) && (_MSC_VER < 1300) #pragma warning(pop) #endif template class AllocatorWithCleanup : public AllocatorBase { public: CRYPTOPP_INHERIT_ALLOCATOR_TYPES pointer allocate(size_type n, const void * = NULL) { CheckSize(n); if (n == 0) return NULL; if (T_Align16 && n*sizeof(T) >= 16) { byte *p; #ifdef CRYPTOPP_MM_MALLOC_AVAILABLE while (!(p = (byte *)_mm_malloc(sizeof(T)*n, 16))) #elif defined(CRYPTOPP_MEMALIGN_AVAILABLE) while (!(p = (byte *)memalign(16, sizeof(T)*n))) #elif defined(CRYPTOPP_MALLOC_ALIGNMENT_IS_16) while (!(p = (byte *)malloc(sizeof(T)*n))) #else while (!(p = (byte *)malloc(sizeof(T)*n + 16))) #endif CallNewHandler(); #ifdef CRYPTOPP_NO_ALIGNED_ALLOC size_t adjustment = 16-((size_t)p%16); p += adjustment; p[-1] = (byte)adjustment; #endif assert(IsAlignedOn(p, 16)); return (pointer)p; } pointer p; while (!(p = (pointer)malloc(sizeof(T)*n))) CallNewHandler(); return p; } void deallocate(void *p, size_type n) { memset(p, 0, n*sizeof(T)); if (T_Align16 && n*sizeof(T) >= 16) { #ifdef CRYPTOPP_MM_MALLOC_AVAILABLE _mm_free(p); #elif defined(CRYPTOPP_NO_ALIGNED_ALLOC) p = (byte *)p - ((byte *)p)[-1]; free(p); #else free(p); #endif return; } free(p); } pointer reallocate(T *p, size_type oldSize, size_type newSize, bool preserve) { return StandardReallocate(*this, p, oldSize, newSize, preserve); } // VS.NET STL enforces the policy of "All STL-compliant allocators have to provide a // template class member called rebind". template struct rebind { typedef AllocatorWithCleanup other; }; #if _MSC_VER >= 1500 AllocatorWithCleanup() {} template AllocatorWithCleanup(const AllocatorWithCleanup &) {} #endif }; CRYPTOPP_DLL_TEMPLATE_CLASS AllocatorWithCleanup; CRYPTOPP_DLL_TEMPLATE_CLASS AllocatorWithCleanup; CRYPTOPP_DLL_TEMPLATE_CLASS AllocatorWithCleanup; CRYPTOPP_DLL_TEMPLATE_CLASS AllocatorWithCleanup; #if CRYPTOPP_BOOL_X86 CRYPTOPP_DLL_TEMPLATE_CLASS AllocatorWithCleanup; // for Integer #endif template class NullAllocator : public AllocatorBase { public: CRYPTOPP_INHERIT_ALLOCATOR_TYPES pointer allocate(size_type n, const void * = NULL) { assert(false); return NULL; } void deallocate(void *p, size_type n) { assert(false); } size_type max_size() const {return 0;} }; // This allocator can't be used with standard collections because // they require that all objects of the same allocator type are equivalent. // So this is for use with SecBlock only. template , bool T_Align16 = false> class FixedSizeAllocatorWithCleanup : public AllocatorBase { public: CRYPTOPP_INHERIT_ALLOCATOR_TYPES FixedSizeAllocatorWithCleanup() : m_allocated(false) {} pointer allocate(size_type n) { assert(IsAlignedOn(m_array, 8)); if (n <= S && !m_allocated) { m_allocated = true; return GetAlignedArray(); } else return m_fallbackAllocator.allocate(n); } pointer allocate(size_type n, const void *hint) { if (n <= S && !m_allocated) { m_allocated = true; return GetAlignedArray(); } else return m_fallbackAllocator.allocate(n, hint); } void deallocate(void *p, size_type n) { if (p == GetAlignedArray()) { assert(n <= S); assert(m_allocated); m_allocated = false; memset(p, 0, n*sizeof(T)); } else m_fallbackAllocator.deallocate(p, n); } pointer reallocate(pointer p, size_type oldSize, size_type newSize, bool preserve) { if (p == GetAlignedArray() && newSize <= S) { assert(oldSize <= S); if (oldSize > newSize) memset(p + newSize, 0, (oldSize-newSize)*sizeof(T)); return p; } pointer newPointer = allocate(newSize, NULL); if (preserve) memcpy(newPointer, p, sizeof(T)*STDMIN(oldSize, newSize)); deallocate(p, oldSize); return newPointer; } size_type max_size() const {return STDMAX(m_fallbackAllocator.max_size(), S);} private: #ifdef __BORLANDC__ T* GetAlignedArray() {return m_array;} T m_array[S]; #else T* GetAlignedArray() {return T_Align16 ? (T*)(((byte *)m_array) + (0-(size_t)m_array)%16) : m_array;} CRYPTOPP_ALIGN_DATA(8) T m_array[T_Align16 ? S+8/sizeof(T) : S]; #endif A m_fallbackAllocator; bool m_allocated; }; //! a block of memory allocated using A template > class SecBlock { public: typedef typename A::value_type value_type; typedef typename A::pointer iterator; typedef typename A::const_pointer const_iterator; typedef typename A::size_type size_type; explicit SecBlock(size_type size=0) : m_size(size) {m_ptr = m_alloc.allocate(size, NULL);} SecBlock(const SecBlock &t) : m_size(t.m_size) {m_ptr = m_alloc.allocate(m_size, NULL); memcpy_s(m_ptr, m_size*sizeof(T), t.m_ptr, m_size*sizeof(T));} SecBlock(const T *t, size_type len) : m_size(len) { m_ptr = m_alloc.allocate(len, NULL); if (t == NULL) memset(m_ptr, 0, len*sizeof(T)); else memcpy(m_ptr, t, len*sizeof(T)); } ~SecBlock() {m_alloc.deallocate(m_ptr, m_size);} #ifdef __BORLANDC__ operator T *() const {return (T*)m_ptr;} #else operator const void *() const {return m_ptr;} operator void *() {return m_ptr;} operator const T *() const {return m_ptr;} operator T *() {return m_ptr;} #endif // T *operator +(size_type offset) // {return m_ptr+offset;} // const T *operator +(size_type offset) const // {return m_ptr+offset;} // T& operator[](size_type index) // {assert(index >= 0 && index < m_size); return m_ptr[index];} // const T& operator[](size_type index) const // {assert(index >= 0 && index < m_size); return m_ptr[index];} iterator begin() {return m_ptr;} const_iterator begin() const {return m_ptr;} iterator end() {return m_ptr+m_size;} const_iterator end() const {return m_ptr+m_size;} typename A::pointer data() {return m_ptr;} typename A::const_pointer data() const {return m_ptr;} size_type size() const {return m_size;} bool empty() const {return m_size == 0;} byte * BytePtr() {return (byte *)m_ptr;} const byte * BytePtr() const {return (const byte *)m_ptr;} size_type SizeInBytes() const {return m_size*sizeof(T);} //! set contents and size void Assign(const T *t, size_type len) { New(len); memcpy_s(m_ptr, m_size*sizeof(T), t, len*sizeof(T)); } //! copy contents and size from another SecBlock void Assign(const SecBlock &t) { New(t.m_size); memcpy_s(m_ptr, m_size*sizeof(T), t.m_ptr, m_size*sizeof(T)); } SecBlock& operator=(const SecBlock &t) { Assign(t); return *this; } // append to this object SecBlock& operator+=(const SecBlock &t) { size_type oldSize = m_size; Grow(m_size+t.m_size); memcpy_s(m_ptr+oldSize, m_size*sizeof(T), t.m_ptr, t.m_size*sizeof(T)); return *this; } // append operator SecBlock operator+(const SecBlock &t) { SecBlock result(m_size+t.m_size); memcpy_s(result.m_ptr, result.m_size*sizeof(T), m_ptr, m_size*sizeof(T)); memcpy_s(result.m_ptr+m_size, t.m_size*sizeof(T), t.m_ptr, t.m_size*sizeof(T)); return result; } bool operator==(const SecBlock &t) const { return m_size == t.m_size && memcmp(m_ptr, t.m_ptr, m_size*sizeof(T)) == 0; } bool operator!=(const SecBlock &t) const { return !operator==(t); } //! change size, without preserving contents void New(size_type newSize) { m_ptr = m_alloc.reallocate(m_ptr, m_size, newSize, false); m_size = newSize; } //! change size and set contents to 0 void CleanNew(size_type newSize) { New(newSize); memset(m_ptr, 0, m_size*sizeof(T)); } //! change size only if newSize > current size. contents are preserved void Grow(size_type newSize) { if (newSize > m_size) { m_ptr = m_alloc.reallocate(m_ptr, m_size, newSize, true); m_size = newSize; } } //! change size only if newSize > current size. contents are preserved and additional area is set to 0 void CleanGrow(size_type newSize) { if (newSize > m_size) { m_ptr = m_alloc.reallocate(m_ptr, m_size, newSize, true); memset(m_ptr+m_size, 0, (newSize-m_size)*sizeof(T)); m_size = newSize; } } //! change size and preserve contents void resize(size_type newSize) { m_ptr = m_alloc.reallocate(m_ptr, m_size, newSize, true); m_size = newSize; } //! swap contents and size with another SecBlock void swap(SecBlock &b) { std::swap(m_alloc, b.m_alloc); std::swap(m_size, b.m_size); std::swap(m_ptr, b.m_ptr); } //private: A m_alloc; size_type m_size; T *m_ptr; }; typedef SecBlock SecByteBlock; typedef SecBlock > AlignedSecByteBlock; typedef SecBlock SecWordBlock; //! a SecBlock with fixed size, allocated statically template > class FixedSizeSecBlock : public SecBlock { public: explicit FixedSizeSecBlock() : SecBlock(S) {} }; template class FixedSizeAlignedSecBlock : public FixedSizeSecBlock, T_Align16> > { }; //! a SecBlock that preallocates size S statically, and uses the heap when this size is exceeded template > > class SecBlockWithHint : public SecBlock { public: explicit SecBlockWithHint(size_t size) : SecBlock(size) {} }; template inline bool operator==(const CryptoPP::AllocatorWithCleanup&, const CryptoPP::AllocatorWithCleanup&) {return (true);} template inline bool operator!=(const CryptoPP::AllocatorWithCleanup&, const CryptoPP::AllocatorWithCleanup&) {return (false);} NAMESPACE_END NAMESPACE_BEGIN(std) template inline void swap(CryptoPP::SecBlock &a, CryptoPP::SecBlock &b) { a.swap(b); } #if defined(_STLP_DONT_SUPPORT_REBIND_MEMBER_TEMPLATE) || (defined(_STLPORT_VERSION) && !defined(_STLP_MEMBER_TEMPLATE_CLASSES)) // working for STLport 5.1.3 and MSVC 6 SP5 template inline CryptoPP::AllocatorWithCleanup<_Tp2>& __stl_alloc_rebind(CryptoPP::AllocatorWithCleanup<_Tp1>& __a, const _Tp2*) { return (CryptoPP::AllocatorWithCleanup<_Tp2>&)(__a); } #endif NAMESPACE_END #endif