cryptopp561

Crypto++: a C++ Class Library of Cryptographic Schemes Version 5.6.1 (8/9/2010, SVN r520) Crypto++ Library is a free C++ class library of cryptographic schemes. Currently the library contains the following algorithms: algorithm type name authenticated encryption schemes GCM, CCM, EAX high speed stream ciphers Panama, Sosemanuk, Salsa20, XSalsa20 AES and AES candidates AES (Rijndael), RC6, MARS, Twofish, Serpent, CAST-256 IDEA, Triple-DES (DES-EDE2 and DES-EDE3), other block ciphers Camellia, SEED, RC5, Blowfish, TEA, XTEA, Skipjack, SHACAL-2 block cipher modes of operation ECB, CBC, CBC ciphertext stealing (CTS), CFB, OFB, counter mode (CTR) message authentication codes VMAC, HMAC, GMAC, CMAC, CBC-MAC, DMAC, Two-Track-MAC SHA-1, SHA-2 (SHA-224, SHA-256, SHA-384, and hash functions SHA-512), Tiger, WHIRLPOOL, RIPEMD-128, RIPEMD-256, RIPEMD-160, RIPEMD-320 RSA, DSA, ElGamal, Nyberg-Rueppel (NR), public-key cryptography Rabin-Williams (RW), LUC, LUCELG, DLIES (variants of DHAES), ESIGN padding schemes for public-key PKCS#1 v2.0, OAEP, PSS, PSSR, IEEE P1363 systems EMSA2 and EMSA5 Diffie-Hellman (DH), Unified Diffie-Hellman key agreement schemes (DH2), Menezes-Qu-Vanstone (MQV), LUCDIF, XTR-DH elliptic curve cryptography ECDSA, ECNR, ECIES, ECDH, ECMQV insecure or obsolescent MD2, MD4, MD5, Panama Hash, DES, ARC4, SEAL algorithms retained for backwards 3.0, WAKE, WAKE-OFB, DESX (DES-XEX3), RC2, compatibility and historical SAFER, 3-WAY, GOST, SHARK, CAST-128, Square value Other features include: * pseudo random number generators (PRNG): ANSI X9.17 appendix C, RandomPool * password based key derivation functions: PBKDF1 and PBKDF2 from PKCS #5, PBKDF from PKCS #12 appendix B * Shamir's secret sharing scheme and Rabin's information dispersal algorithm (IDA) * fast multi-precision integer (bignum) and polynomial operations * finite field arithmetics, including GF(p) and GF(2^n) * prime number generation and verification * useful non-cryptographic algorithms + DEFLATE (RFC 1951) compression/decompression with gzip (RFC 1952) and zlib (RFC 1950) format support + hex, base-32, and base-64 coding/decoding + 32-bit CRC and Adler32 checksum * class wrappers for these operating system features (optional): + high resolution timers on Windows, Unix, and Mac OS + Berkeley and Windows style sockets + Windows named pipes + /dev/random, /dev/urandom, /dev/srandom + Microsoft's CryptGenRandom on Windows * A high level interface for most of the above, using a filter/pipeline metaphor * benchmarks and validation testing * x86, x86-64 (x64), MMX, and SSE2 assembly code for the most commonly used algorithms, with run-time CPU feature detection and code selection * some versions are available in FIPS 140-2 validated form You are welcome to use it for any purpose without paying me, but see License.txt for the fine print. The following compilers are supported for this release. Please visit http://www.cryptopp.com the most up to date build instructions and porting notes. * MSVC 6.0 - 2010 * GCC 3.3 - 4.5 * C++Builder 2010 * Intel C++ Compiler 9 - 11.1 * Sun Studio 12u1, Express 11/08, Express 06/10 *** Important Usage Notes *** 1. If a constructor for A takes a pointer to an object B (except primitive types such as int and char), then A owns B and will delete B at A's destruction. If a constructor for A takes a reference to an object B, then the caller retains ownership of B and should not destroy it until A no longer needs it. 2. Crypto++ is thread safe at the class level. This means you can use Crypto++ safely in a multithreaded application, but you must provide synchronization when multiple threads access a common Crypto++ object. *** MSVC-Specific Information *** On Windows, Crypto++ can be compiled into 3 forms: a static library including all algorithms, a DLL with only FIPS Approved algorithms, and a static library with only algorithms not in the DLL. (FIPS Approved means Approved according to the FIPS 140-2 standard.) The DLL may be used by itself, or it may be used together with the second form of the static library. MSVC project files are included to build all three forms, and sample applications using each of the three forms are also included. To compile Crypto++ with MSVC, open the "cryptest.dsw" (for MSVC 6 and MSVC .NET 2003) or "cryptest.sln" (for MSVC 2005 - 2010) workspace file and build one or more of the following projects: cryptopp - This builds the DLL. Please note that if you wish to use Crypto++ as a FIPS validated module, you must use a pre-built DLL that has undergone the FIPS validation process instead of building your own. dlltest - This builds a sample application that only uses the DLL. cryptest Non-DLL-Import Configuration - This builds the full static library along with a full test driver. cryptest DLL-Import Configuration - This builds a static library containing only algorithms not in the DLL, along with a full test driver that uses both the DLL and the static library. To use the Crypto++ DLL in your application, #include "dll.h" before including any other Crypto++ header files, and place the DLL in the same directory as your .exe file. dll.h includes the line #pragma comment(lib, "cryptopp") so you don't have to explicitly list the import library in your project settings. To use a static library form of Crypto++, make the "cryptlib" project a dependency of your application project, or specify it as an additional library to link with in your project settings. In either case you should check the compiler options to make sure that the library and your application are using the same C++ run-time libraries and calling conventions. *** DLL Memory Management *** Because it's possible for the Crypto++ DLL to delete objects allocated by the calling application, they must use the same C++ memory heap. Three methods are provided to achieve this. 1. The calling application can tell Crypto++ what heap to use. This method is required when the calling application uses a non-standard heap. 2. Crypto++ can tell the calling application what heap to use. This method is required when the calling application uses a statically linked C++ Run Time Library. (Method 1 does not work in this case because the Crypto++ DLL is initialized before the calling application's heap is initialized.) 3. Crypto++ can automatically use the heap provided by the calling application's dynamically linked C++ Run Time Library. The calling application must make sure that the dynamically linked C++ Run Time Library is initialized before Crypto++ is loaded. (At this time it is not clear if it is possible to control the order in which DLLs are initialized on Windows 9x machines, so it might be best to avoid using this method.) When Crypto++ attaches to a new process, it searches all modules loaded into the process space for exported functions "GetNewAndDeleteForCryptoPP" and "SetNewAndDeleteFromCryptoPP". If one of these functions is found, Crypto++ uses methods 1 or 2, respectively, by calling the function. Otherwise, method 3 is used. *** GCC-Specific Information *** A makefile is included for you to compile Crypto++ with GCC. Make sure you are using GNU Make and GNU ld. The make process will produce two files, libcryptop