|
Chilkat • HOME • .NET Core C# • Android™ • AutoIt • C • C# • C++ • Chilkat2-Python • CkPython • Classic ASP • DataFlex • Delphi ActiveX • Delphi DLL • Go • Java • Lianja • Mono C# • Node.js • Objective-C • PHP ActiveX • PHP Extension • Perl • PowerBuilder • PowerShell • PureBasic • Ruby • SQL Server • Swift 2 • Swift 3,4,5... • Tcl • Unicode C • Unicode C++ • VB.NET • VBScript • Visual Basic 6.0 • Visual FoxPro • Xojo Plugin
(C) A3/A4 Certificate to Create and Verify an Opaque PKCS7/CMS SignatureDemonstrates how to use an A3 or A4 certificate w/ private key on a smartcard or token to create a PKCS7 opaque signature, and also how to verify an opaque signature. An opaque signature is different than a detached PKCS7 signature in that it contains the original data. Verifying an opaque signature retrieves the original content.
#include <C_CkCrypt2.h> #include <C_CkCert.h> void ChilkatSample(void) { HCkCrypt2 crypt; HCkCert cert; BOOL success; const char *originalData; const char *opaqueSig; HCkCrypt2 vCrypt; const char *extractedData; // This example assumes the Chilkat API to have been previously unlocked. // See Global Unlock Sample for sample code. crypt = CkCrypt2_Create(); // A certificate and private key is needed to create a signature. // Chilkat provides many different ways to load a certificate and private key, such // as from a smartcards and hardware tokens, PFX/.p12, Java keystore, JWK, Windows registry-based certificate stores, and other sources. // This example will load the default certificate from the smartcard that is currently in // the smartcard reader. cert = CkCert_Create(); // If the smartcard or token requires a PIN, we can set it here to avoid the dialog... CkCert_putSmartCardPin(cert,"000000"); success = CkCert_LoadFromSmartcard(cert,""); if (success != TRUE) { printf("%s\n",CkCert_lastErrorText(cert)); CkCrypt2_Dispose(crypt); CkCert_Dispose(cert); return; } // Tell it to use the cert and private key we've loaded. success = CkCrypt2_SetSigningCert(crypt,cert); if (success != TRUE) { printf("%s\n",CkCrypt2_lastErrorText(crypt)); CkCrypt2_Dispose(crypt); CkCert_Dispose(cert); return; } // Indicate we want the opaque signature in base64 format: CkCrypt2_putEncodingMode(crypt,"base64"); // Sign the string using the "utf-8" byte representation: CkCrypt2_putCharset(crypt,"utf-8"); // Create the opaque signature: originalData = "This is the string to be signed."; opaqueSig = CkCrypt2_opaqueSignStringENC(crypt,originalData); if (CkCrypt2_getLastMethodSuccess(crypt) != TRUE) { printf("%s\n",CkCrypt2_lastErrorText(crypt)); CkCrypt2_Dispose(crypt); CkCert_Dispose(cert); return; } printf("%s\n",opaqueSig); // The output looks like this: // MIIPgQYJKoZIhvcNAQcCoIIPcjCCD24CAQExCzAJBgUrDgMCGgUAMC8GCSqGSIb3DQEHAaAiBCBUaGlzIGlzIHRoZSBzdHJpbmcgdG8gYmUgc... // ---------------------------------------------------------------------------------------------- // Now let's verify the signature and retrieve the original data. // We'll use a new Crypt2 object to keep things completely separate... vCrypt = CkCrypt2_Create(); // We only need the certificate to verify a signature (and extract the data from // an opaque signature). The public key is always embedded within a certificate. success = CkCrypt2_SetVerifyCert(vCrypt,cert); if (success != TRUE) { printf("%s\n",CkCrypt2_lastErrorText(vCrypt)); CkCrypt2_Dispose(crypt); CkCert_Dispose(cert); CkCrypt2_Dispose(vCrypt); return; } CkCrypt2_putEncodingMode(vCrypt,"base64"); CkCrypt2_putCharset(vCrypt,"utf-8"); extractedData = CkCrypt2_opaqueVerifyStringENC(vCrypt,opaqueSig); if (CkCrypt2_getLastMethodSuccess(vCrypt) != TRUE) { printf("%s\n",CkCrypt2_lastErrorText(vCrypt)); CkCrypt2_Dispose(crypt); CkCert_Dispose(cert); CkCrypt2_Dispose(vCrypt); return; } printf("The extracted data: %s\n",extractedData); // The output is: // The extracted data: This is the string to be signed. CkCrypt2_Dispose(crypt); CkCert_Dispose(cert); CkCrypt2_Dispose(vCrypt); } |
|||||||
© 2000-2024 Chilkat Software, Inc. All Rights Reserved.