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DSA Signature Create and VerifyShows how to create a DSA (DSS) signature for the contents of a file. The first step is to create an SHA-1 hash of the file contents. The hash is signed using the Digital Signature Algorithm and the signature bytes are retrieved as a hex-encoded string. The 2nd part of the example loads the signature and verifies it against the hash. Downloads: MS Windows Visual C/C++ Libraries Linux/CentOS C/C++ Libraries MAC OS X C/C++ Libraries Solaris C/C++ Libraries C++ Builder Libraries #include <CkCrypt2.h> #include <CkDsa.h> void ChilkatSample(void) { bool success; // Use Chilkat Crypt to hash the contents of a file. CkCrypt2 crypt; success = crypt.UnlockComponent("Anything for 30-day trial."); if (success != true) { printf("%s\n",crypt.lastErrorText()); return; } crypt.put_EncodingMode("hex"); crypt.put_HashAlgorithm("sha-1"); const char * hashStr; // Return the SHA-1 hash of a file. The file may be any size. // The Chilkat Crypt component will stream the file when // computing the hash, keeping the memory usage constant // and reasonable. // The 20-byte SHA-1 hash is returned as a hex-encoded string. hashStr = crypt.hashFileENC("hamlet.xml"); CkDsa dsa; // The Chilkat Crypt and Chilkat DSA components are separate // products. To license both, it's least expensive to purchase // the "Chilkat Bundle" which provides licenses to all the // Chilkat components. success = dsa.UnlockComponent("Anything for 30-day trial"); if (success != true) { printf("%s\n",dsa.lastErrorText()); return; } // Load a DSA private key from a PEM file. Chilkat DSA // provides the ability to load and save DSA public and private // keys from encrypted or non-encrypted PEM or DER. // The LoadText method is for convenience only. You may // use any means to load the contents of a PEM file into // a string. const char * pemPrivateKey; pemPrivateKey = dsa.loadText("dsa_priv.pem"); success = dsa.FromPem(pemPrivateKey); if (success != true) { printf("%s\n",dsa.lastErrorText()); return; } // You may optionally verify the key to ensure that it is a valid // DSA key. success = dsa.VerifyKey(); if (success != true) { printf("%s\n",dsa.lastErrorText()); return; } // Load the hash to be signed into the DSA object: success = dsa.SetEncodedHash("hex",hashStr); if (success != true) { printf("%s\n",dsa.lastErrorText()); return; } // Now that the DSA object contains both the private key and hash, // it is ready to create the signature: success = dsa.SignHash(); if (success != true) { printf("%s\n",dsa.lastErrorText()); return; } // If SignHash is successful, the DSA object contains the // signature. It may be accessed as a hex or base64 encoded // string. (It is also possible to access directly in byte array form via // the "Signature" property.) const char * hexSig; hexSig = dsa.getEncodedSignature("hex"); printf("Signature:\n"); printf("%s\n",hexSig); // ----------------------------------------------------------- // Step 2: Verify the DSA Signature // ----------------------------------------------------------- CkDsa dsa2; // Load the DSA public key to be used for verification: const char * pemPublicKey; pemPublicKey = dsa2.loadText("dsa_pub.pem"); success = dsa2.FromPublicPem(pemPublicKey); if (success != true) { printf("%s\n",dsa2.lastErrorText()); return; } // Load the hash to be verified against the signature. success = dsa2.SetEncodedHash("hex",hashStr); if (success != true) { printf("%s\n",dsa2.lastErrorText()); return; } // Load the signature: success = dsa2.SetEncodedSignature("hex",hexSig); if (success != true) { printf("%s\n",dsa2.lastErrorText()); return; } // Verify: success = dsa2.Verify(); if (success != true) { printf("%s\n",dsa2.lastErrorText()); } else { printf("DSA Signature Verified!\n"); } } |
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