// This file is part of BOINC. // http://boinc.berkeley.edu // Copyright (C) 2008 University of California // // BOINC is free software; you can redistribute it and/or modify it // under the terms of the GNU Lesser General Public License // as published by the Free Software Foundation, // either version 3 of the License, or (at your option) any later version. // // BOINC 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 Lesser General Public License for more details. // // You should have received a copy of the GNU Lesser General Public License // along with BOINC. If not, see . #ifndef H_CRYPT #define H_CRYPT // We're set up to use either RSAEuro or the OpenSSL crypto library. // We use our own data structures (R_RSA_PUBLIC_KEY and R_RSA_PRIVATE_KEY) // to store keys in either case. #include #include #if (OPENSSL_VERSION_NUMBER >= 0x10100000L) /* OpenSSL 1.1.0+ */ #define HAVE_OPAQUE_EVP_PKEY 1 /* since 1.1.0 -pre3 */ #define HAVE_OPAQUE_RSA_DSA_DH 1 /* since 1.1.0 -pre5 */ #endif #define MAX_RSA_MODULUS_BITS 1024 #define MAX_RSA_MODULUS_LEN ((MAX_RSA_MODULUS_BITS + 7) / 8) #define MAX_RSA_PRIME_BITS ((MAX_RSA_MODULUS_BITS + 1) / 2) #define MAX_RSA_PRIME_LEN ((MAX_RSA_PRIME_BITS + 7) / 8) typedef struct { unsigned short int bits; /* length in bits of modulus */ unsigned char modulus[MAX_RSA_MODULUS_LEN]; /* modulus */ unsigned char exponent[MAX_RSA_MODULUS_LEN]; /* public exponent */ } R_RSA_PUBLIC_KEY; typedef struct { unsigned short int bits; /* length in bits of modulus */ unsigned char modulus[MAX_RSA_MODULUS_LEN]; /* modulus */ unsigned char publicExponent[MAX_RSA_MODULUS_LEN]; /* public exponent */ unsigned char exponent[MAX_RSA_MODULUS_LEN]; /* private exponent */ unsigned char prime[2][MAX_RSA_PRIME_LEN]; /* prime factors */ unsigned char primeExponent[2][MAX_RSA_PRIME_LEN]; /* exponents for CRT */ unsigned char coefficient[MAX_RSA_PRIME_LEN]; /* CRT coefficient */ } R_RSA_PRIVATE_KEY; // functions to convert between OpenSSL's keys (using BIGNUMs) // and our binary format extern void openssl_to_keys( RSA* rp, int nbits, R_RSA_PRIVATE_KEY& priv, R_RSA_PUBLIC_KEY& pub ); extern void private_to_openssl(R_RSA_PRIVATE_KEY& priv, RSA* rp); extern void public_to_openssl(R_RSA_PUBLIC_KEY& pub, RSA* rp); extern int openssl_to_private(RSA *from, R_RSA_PRIVATE_KEY *to); struct KEY { unsigned short int bits; unsigned char data[1]; }; struct DATA_BLOCK { unsigned char* data; unsigned int len; }; #define MIN_OUT_BUFFER_SIZE MAX_RSA_MODULUS_LEN+1 // the size of a binary signature (encrypted MD5) // #define SIGNATURE_SIZE_BINARY MIN_OUT_BUFFER_SIZE // size of text-encoded signature #define SIGNATURE_SIZE_TEXT (SIGNATURE_SIZE_BINARY*2+20) extern int sprint_hex_data(char* p, DATA_BLOCK&); #ifdef _USING_FCGI_ #undef FILE #endif extern int print_hex_data(FILE* f, DATA_BLOCK&); extern int scan_hex_data(FILE* f, DATA_BLOCK&); extern int print_key_hex(FILE*, KEY* key, int len); extern int scan_key_hex(FILE*, KEY* key, int len); #ifdef _USING_FCGI_ #define FILE FCGI_FILE #endif extern int sscan_key_hex(const char*, KEY* key, int len); extern int encrypt_private( R_RSA_PRIVATE_KEY& key, DATA_BLOCK& in, DATA_BLOCK& out ); extern int decrypt_public( R_RSA_PUBLIC_KEY& key, DATA_BLOCK& in, DATA_BLOCK& out ); extern int sign_file( const char* path, R_RSA_PRIVATE_KEY&, DATA_BLOCK& signature ); extern int sign_block( DATA_BLOCK& data, R_RSA_PRIVATE_KEY&, DATA_BLOCK& signature ); extern int check_file_signature( const char* md5, R_RSA_PUBLIC_KEY&, DATA_BLOCK& signature, bool& ); extern int check_file_signature2( const char* md5, const char* signature, const char* key, bool& ); extern int check_string_signature( const char* text, const char* signature, R_RSA_PUBLIC_KEY&, bool& ); extern int check_string_signature2( const char* text, const char* signature, const char* key, bool& ); extern int print_raw_data(FILE* f, DATA_BLOCK& x); extern int scan_raw_data(FILE *f, DATA_BLOCK& x); extern int read_key_file(const char* keyfile, R_RSA_PRIVATE_KEY& key); extern int generate_signature( char* text_to_sign, char* signature_hex, R_RSA_PRIVATE_KEY& key ); // Check if sfileMsg (of length sfsize) has been created from sha1_md using the // private key beloning to the public key file cFile // Return: // 1: YES // 0: NO or error extern int check_validity_of_cert( const char *cFile, const unsigned char *sha1_md, unsigned char *sfileMsg, const int sfsize, const char* caPath ); extern char *check_validity(const char *certPath, const char *origFile, unsigned char *signature, char* caPath ); struct CERT_SIGS; int cert_verify_file( CERT_SIGS* signatures, const char* origFile, const char* trustLocation ); #endif