/// <summary>
        /// Verify that an action succeeds and produces a particular emulator command.
        /// </summary>
        /// <param name="session">Mock session.</param>
        /// <param name="del">Action to test.</param>
        /// <param name="expected">Expected text.</param>
        public static void VerifyCommand(this MockTaskSession session, VerifyDelegate del, string expected)
        {
            IoResult result;

            result = del();
            Assert.AreEqual(true, result.Success);
            Assert.AreEqual(expected, session.LastCommandProcessed);
        }
Beispiel #2
0
        /// <summary>
        /// Call this to End the asyncronous verification request.
        /// </summary>
        /// <param name="ar">The ar.</param>
        /// <returns></returns>
        public VerificationResult EndVerify(IAsyncResult ar)
        {
            VerifyDelegate verifyDelegate = ((AsyncResult)ar).AsyncDelegate as VerifyDelegate;

            if (verifyDelegate != null)
            {
                return(verifyDelegate.EndInvoke(ar));
            }
            else
            {
                throw new InvalidOperationException("cannot get results, asynchresult is null");
            }
        }
Beispiel #3
0
        // This constructor will be used by NET45 for signing and for RSAKeyWrap
        internal AsymmetricAdapter(SecurityKey key, string algorithm, HashAlgorithm hashAlgorithm, bool requirePrivateKey)
        {
            HashAlgorithm = hashAlgorithm;

            // RsaSecurityKey has either Rsa OR RsaParameters.
            // If we use the RsaParameters, we create a new RSA object and will need to dispose.
            if (key is RsaSecurityKey rsaKey)
            {
                InitializeUsingRsaSecurityKey(rsaKey, algorithm);
            }
            else if (key is X509SecurityKey x509Key)
            {
                InitializeUsingX509SecurityKey(x509Key, algorithm, requirePrivateKey);
            }
            else if (key is JsonWebKey jsonWebKey)
            {
                if (JsonWebKeyConverter.TryConvertToSecurityKey(jsonWebKey, out SecurityKey securityKey))
                {
                    if (securityKey is RsaSecurityKey rsaSecurityKeyFromJsonWebKey)
                    {
                        InitializeUsingRsaSecurityKey(rsaSecurityKeyFromJsonWebKey, algorithm);
                    }
                    else if (securityKey is X509SecurityKey x509SecurityKeyFromJsonWebKey)
                    {
                        InitializeUsingX509SecurityKey(x509SecurityKeyFromJsonWebKey, algorithm, requirePrivateKey);
                    }
                    else if (securityKey is ECDsaSecurityKey edcsaSecurityKeyFromJsonWebKey)
                    {
                        InitializeUsingEcdsaSecurityKey(edcsaSecurityKeyFromJsonWebKey);
                    }
                    else
                    {
                        throw LogHelper.LogExceptionMessage(new NotSupportedException(LogHelper.FormatInvariant(LogMessages.IDX10684, algorithm, key)));
                    }
                }
            }
            else if (key is ECDsaSecurityKey ecdsaKey)
            {
                ECDsaSecurityKey  = ecdsaKey;
                SignatureFunction = SignWithECDsa;
                VerifyFunction    = VerifyWithECDsa;
            }
            else
            {
                throw LogHelper.LogExceptionMessage(new NotSupportedException(LogHelper.FormatInvariant(LogMessages.IDX10684, algorithm, key)));
            }
        }
Beispiel #4
0
        public WorkflowManager()
        {
            InitializeComponent();
            this.ApproveFn = ApprovePdf;
            this.VerifyFn  = VerifyPdf;

            ShowNotifyIcon();
            logfn = Log;

            string rootDir = Path.Combine(Application.StartupPath, "Portal");

            webManager         = new WebManager(rootDir, Properties.Settings.Default.WebManagerPort, this);
            webManager.SendLog = WebManagerLog;
            webManager.Start();


            //string portal = Path.Combine(Application.StartupPath, "Portal\\index.html");
            string portal = "http://localhost:" + Properties.Settings.Default.WebManagerPort.ToString() + "/index.html";

            docDir = Path.Combine(Application.StartupPath, "Portal\\docs");

            Process.Start(portal);
        }
Beispiel #5
0
        /// <summary>
        /// Begins the verification in asynchronous mode.
        /// </summary>
        /// <param name="clientAETitle">The client AE title.</param>
        /// <param name="remoteAE">The remote AE.</param>
        /// <param name="remoteHost">The remote host.</param>
        /// <param name="remotePort">The remote port.</param>
        /// <param name="callback">The callback.</param>
        /// <param name="asyncState">State of the async.</param>
        /// <returns></returns>
        public IAsyncResult BeginVerify(string clientAETitle, string remoteAE, string remoteHost, int remotePort, AsyncCallback callback, object asyncState)
        {
            VerifyDelegate verifyDelegate = new VerifyDelegate(this.Verify);

            return(verifyDelegate.BeginInvoke(clientAETitle, remoteAE, remoteHost, remotePort, callback, asyncState));
        }
Beispiel #6
0
        private void InitializeUsingRsa(RSA rsa, string algorithm)
        {
#if NET461 || NETSTANDARD2_0
            if (algorithm.Equals(SecurityAlgorithms.RsaSsaPssSha256, StringComparison.Ordinal) ||
                algorithm.Equals(SecurityAlgorithms.RsaSsaPssSha256Signature, StringComparison.Ordinal) ||
                algorithm.Equals(SecurityAlgorithms.RsaSsaPssSha384, StringComparison.Ordinal) ||
                algorithm.Equals(SecurityAlgorithms.RsaSsaPssSha384Signature, StringComparison.Ordinal) ||
                algorithm.Equals(SecurityAlgorithms.RsaSsaPssSha512, StringComparison.Ordinal) ||
                algorithm.Equals(SecurityAlgorithms.RsaSsaPssSha512Signature, StringComparison.Ordinal))
            {
                RSASignaturePadding = RSASignaturePadding.Pss;
            }
            else
            {
                // default RSASignaturePadding for other supported RSA algorithms is Pkcs1
                RSASignaturePadding = RSASignaturePadding.Pkcs1;
            }
#endif

            // This case is the result of a calling
            // X509Certificate2.GetPrivateKey OR X509Certificate2.GetPublicKey.Key
            // These calls return an AsymmetricAlgorithm which doesn't have API's to do much and need to be cast.
            // RSACryptoServiceProvider is wrapped to support SHA2
            // RSACryptoServiceProviderProxy is only supported on Windows platform
#if DESKTOP
            _useRSAOeapPadding = algorithm.Equals(SecurityAlgorithms.RsaOAEP, StringComparison.Ordinal) ||
                                 algorithm.Equals(SecurityAlgorithms.RsaOaepKeyWrap, StringComparison.Ordinal);

            if (rsa is RSACryptoServiceProvider rsaCryptoServiceProvider)
            {
                RsaCryptoServiceProviderProxy = new RSACryptoServiceProviderProxy(rsaCryptoServiceProvider);
                SignatureFunction             = SignWithRsaCryptoServiceProviderProxy;
                VerifyFunction = VerifyWithRsaCryptoServiceProviderProxy;
                // RSACryptoServiceProviderProxy will keep track of if it creates a new RSA object.
                // Only if a new RSA was creaated, RSACryptoServiceProviderProxy will call RSA.Dispose().
                _disposeCryptoOperators = true;
                return;
            }
#endif

            // This case required the user to get a RSA object by calling
            // X509Certificate2.GetRSAPrivateKey() OR X509Certificate2.GetRSAPublicKey()
            // This requires 4.6+ to be installed. If a dependent library is targeting 4.5, 4.5.1, 4.5.2 or 4.6
            // they will use Net45, but the type is RSACng.
            // The 'lightup' code will bind to the correct operators.
#if NET45
            else if (rsa.GetType().ToString().Equals(_rsaCngTypeName, StringComparison.Ordinal) && IsRsaCngSupported())
            {
                _lightUpHashAlgorithmName = GetLightUpHashAlgorithmName();
                SignatureFunction         = Pkcs1SignData;
                VerifyFunction            = Pkcs1VerifyData;
                return;
            }
            else
            {
                // In NET45 we only support RSACryptoServiceProvider or "System.Security.Cryptography.RSACng"
                throw LogHelper.LogExceptionMessage(new NotSupportedException(LogHelper.FormatInvariant(LogMessages.IDX10687, typeof(RSACryptoServiceProvider).ToString(), _rsaCngTypeName, rsa.GetType().ToString())));
            }
#endif

#if NET461 || NETSTANDARD2_0
            // Here we can use RSA straight up.
            _rsaEncryptionPadding = (algorithm.Equals(SecurityAlgorithms.RsaOAEP, StringComparison.Ordinal) || algorithm.Equals(SecurityAlgorithms.RsaOaepKeyWrap, StringComparison.Ordinal))
                        ? RSAEncryptionPadding.OaepSHA1
                        : RSAEncryptionPadding.Pkcs1;
            RSA = rsa;
            SignatureFunction = SignWithRsa;
            VerifyFunction    = VerifyWithRsa;
#endif
        }
Beispiel #7
0
 private void InitializeUsingEcdsaSecurityKey(ECDsaSecurityKey ecdsaSecurityKey)
 {
     ECDsaSecurityKey  = ecdsaSecurityKey;
     SignatureFunction = SignWithECDsa;
     VerifyFunction    = VerifyWithECDsa;
 }
Beispiel #8
0
		/// <summary>
		/// Begins the verification in asynchronous mode.
		/// </summary>
		/// <param name="clientAETitle">The client AE title.</param>
		/// <param name="remoteAE">The remote AE.</param>
		/// <param name="remoteHost">The remote host.</param>
		/// <param name="remotePort">The remote port.</param>
		/// <param name="callback">The callback.</param>
		/// <param name="asyncState">State of the async.</param>
		/// <returns></returns>
		public IAsyncResult BeginVerify(string clientAETitle, string remoteAE, string remoteHost, int remotePort, AsyncCallback callback, object asyncState)
		{
			VerifyDelegate verifyDelegate = new VerifyDelegate(this.Verify);

			return verifyDelegate.BeginInvoke(clientAETitle, remoteAE, remoteHost, remotePort, callback, asyncState);
		}
Beispiel #9
0
        /// <summary>
        /// Creates a new qryptext instance. <para> </para>
        /// Make sure to create one only once and cache it as needed, since loading the DLLs into memory can negatively affect the performance.
        /// <param name="sharedLibPathOverride">[OPTIONAL] Don't look for a <c>lib/</c> folder and directly use this path as a pre-resolved, platform-specific shared lib/DLL file path. Pass this if you want to manually handle the various platform's paths yourself.</param>
        /// </summary>
        public QryptextSharpContext(string sharedLibPathOverride = null)
        {
            string os;

            if (RuntimeInformation.IsOSPlatform(OSPlatform.Windows))
            {
                os        = "windows";
                loadUtils = new SharedLibLoadUtilsWindows();
            }
            else if (RuntimeInformation.IsOSPlatform(OSPlatform.Linux))
            {
                os        = "linux";
                loadUtils = new SharedLibLoadUtilsLinux();
            }
            else if (RuntimeInformation.IsOSPlatform(OSPlatform.OSX))
            {
                os        = "mac";
                loadUtils = new SharedLibLoadUtilsMac();
            }
            else
            {
                throw new PlatformNotSupportedException("Unsupported OS");
            }

            if (string.IsNullOrEmpty(sharedLibPathOverride))
            {
                StringBuilder pathBuilder = new StringBuilder(256);
                pathBuilder.Append("lib/");

                switch (RuntimeInformation.ProcessArchitecture)
                {
                case Architecture.X64:
                    pathBuilder.Append("x64/");
                    break;

                case Architecture.X86:
                    pathBuilder.Append("x86/");
                    break;

                case Architecture.Arm:
                    pathBuilder.Append("armeabi-v7a/");
                    break;

                case Architecture.Arm64:
                    pathBuilder.Append("arm64-v8a/");
                    break;
                }

                if (!Directory.Exists(pathBuilder.ToString()))
                {
                    throw new PlatformNotSupportedException($"Qryptext shared library not found in {pathBuilder} and/or unsupported CPU architecture. Please don't forget to copy the Qryptext shared libraries/DLL into the 'lib/{{CPU_ARCHITECTURE}}/{{OS}}/{{SHARED_LIB_FILE}}' folder of your output build directory.  https://github.com/GlitchedPolygons/qryptext/tree/master/csharp/lib/");
                }

                pathBuilder.Append(os);
                pathBuilder.Append('/');

                string[] l = Directory.GetFiles(pathBuilder.ToString());
                if (l == null || l.Length != 1)
                {
                    throw new FileLoadException("There should only be exactly one shared library file per supported platform!");
                }

                pathBuilder.Append(Path.GetFileName(l[0]));
                LoadedLibraryPath = Path.GetFullPath(pathBuilder.ToString());
                pathBuilder.Clear();
            }
            else
            {
                LoadedLibraryPath = sharedLibPathOverride;
            }

            lib = loadUtils.LoadLibrary(LoadedLibraryPath);
            if (lib == IntPtr.Zero)
            {
                goto hell;
            }


            IntPtr enableFprintf = loadUtils.GetProcAddress(lib, "qryptext_enable_fprintf");

            if (enableFprintf == IntPtr.Zero)
            {
                goto hell;
            }

            IntPtr disableFprintf = loadUtils.GetProcAddress(lib, "qryptext_disable_fprintf");

            if (disableFprintf == IntPtr.Zero)
            {
                goto hell;
            }

            IntPtr isFprintfEnabled = loadUtils.GetProcAddress(lib, "qryptext_is_fprintf_enabled");

            if (isFprintfEnabled == IntPtr.Zero)
            {
                goto hell;
            }

            IntPtr getVersionNumber = loadUtils.GetProcAddress(lib, "qryptext_get_version_number");

            if (getVersionNumber == IntPtr.Zero)
            {
                goto hell;
            }

            IntPtr getVersionNumberString = loadUtils.GetProcAddress(lib, "qryptext_get_version_number_string");

            if (getVersionNumberString == IntPtr.Zero)
            {
                goto hell;
            }

            IntPtr devUrandom = loadUtils.GetProcAddress(lib, "qryptext_dev_urandom");

            if (devUrandom == IntPtr.Zero)
            {
                goto hell;
            }

            IntPtr calcEncryptionOutputLength = loadUtils.GetProcAddress(lib, "qryptext_calc_encryption_output_length");

            if (calcEncryptionOutputLength == IntPtr.Zero)
            {
                goto hell;
            }

            IntPtr calcBase64Length = loadUtils.GetProcAddress(lib, "qryptext_calc_base64_length");

            if (calcBase64Length == IntPtr.Zero)
            {
                goto hell;
            }

            IntPtr genKyber1K = loadUtils.GetProcAddress(lib, "qryptext_kyber1024_generate_keypair");

            if (genKyber1K == IntPtr.Zero)
            {
                goto hell;
            }

            IntPtr genFalcon1K = loadUtils.GetProcAddress(lib, "qryptext_falcon1024_generate_keypair");

            if (genFalcon1K == IntPtr.Zero)
            {
                goto hell;
            }

            IntPtr encrypt = loadUtils.GetProcAddress(lib, "qryptext_encrypt");

            if (encrypt == IntPtr.Zero)
            {
                goto hell;
            }

            IntPtr decrypt = loadUtils.GetProcAddress(lib, "qryptext_decrypt");

            if (decrypt == IntPtr.Zero)
            {
                goto hell;
            }

            IntPtr sign = loadUtils.GetProcAddress(lib, "qryptext_sign");

            if (sign == IntPtr.Zero)
            {
                goto hell;
            }

            IntPtr verify = loadUtils.GetProcAddress(lib, "qryptext_verify");

            if (verify == IntPtr.Zero)
            {
                goto hell;
            }

            enableFprintfDelegate              = Marshal.GetDelegateForFunctionPointer <EnableFprintfDelegate>(enableFprintf);
            disableFprintfDelegate             = Marshal.GetDelegateForFunctionPointer <DisableFprintfDelegate>(disableFprintf);
            isFprintfEnabledDelegate           = Marshal.GetDelegateForFunctionPointer <IsFprintfEnabledDelegate>(isFprintfEnabled);
            getVersionNumberDelegate           = Marshal.GetDelegateForFunctionPointer <GetVersionNumberDelegate>(getVersionNumber);
            getVersionNumberStringDelegate     = Marshal.GetDelegateForFunctionPointer <GetVersionNumberStringDelegate>(getVersionNumberString);
            devUrandomDelegate                 = Marshal.GetDelegateForFunctionPointer <DevUrandomDelegate>(devUrandom);
            calcEncryptionOutputLengthDelegate = Marshal.GetDelegateForFunctionPointer <CalcEncryptionOutputLengthDelegate>(calcEncryptionOutputLength);
            calcBase64LengthDelegate           = Marshal.GetDelegateForFunctionPointer <CalcBase64LengthDelegate>(calcBase64Length);
            generateKyber1024KeyPairDelegate   = Marshal.GetDelegateForFunctionPointer <GenerateKyber1024KeyPairDelegate>(genKyber1K);
            generateFalcon1024KeyPairDelegate  = Marshal.GetDelegateForFunctionPointer <GenerateFalcon1024KeyPairDelegate>(genFalcon1K);
            encryptDelegate = Marshal.GetDelegateForFunctionPointer <EncryptDelegate>(encrypt);
            decryptDelegate = Marshal.GetDelegateForFunctionPointer <DecryptDelegate>(decrypt);
            signDelegate    = Marshal.GetDelegateForFunctionPointer <SignDelegate>(sign);
            verifyDelegate  = Marshal.GetDelegateForFunctionPointer <VerifyDelegate>(verify);

            return;

hell:
            throw new Exception($"Failed to load one or more functions from the shared library \"{LoadedLibraryPath}\"!");
        }
Beispiel #10
0
        private void InitializeUsingRsa(RSA rsa, string algorithm)
        {
            // The return value for X509Certificate2.GetPrivateKey OR X509Certificate2.GetPublicKey.Key is a RSACryptoServiceProvider
            // These calls return an AsymmetricAlgorithm which doesn't have API's to do much and need to be cast.
            // RSACryptoServiceProvider is wrapped with RSACryptoServiceProviderProxy as some CryptoServideProviders (CSP's) do
            // not natively support SHA2.
#if DESKTOP
            if (rsa is RSACryptoServiceProvider rsaCryptoServiceProvider)
            {
                _useRSAOeapPadding = algorithm.Equals(SecurityAlgorithms.RsaOAEP) ||
                                     algorithm.Equals(SecurityAlgorithms.RsaOaepKeyWrap);

                RsaCryptoServiceProviderProxy = new RSACryptoServiceProviderProxy(rsaCryptoServiceProvider);
                DecryptFunction   = DecryptWithRsaCryptoServiceProviderProxy;
                EncryptFunction   = EncryptWithRsaCryptoServiceProviderProxy;
                SignatureFunction = SignWithRsaCryptoServiceProviderProxy;
                VerifyFunction    = VerifyWithRsaCryptoServiceProviderProxy;

                // RSACryptoServiceProviderProxy will track if a new RSA object is created and dispose appropriately.
                _disposeCryptoOperators = true;
                return;
            }
#endif

#if NET45
            // This case required the user to get a RSA object by calling
            // X509Certificate2.GetRSAPrivateKey() OR X509Certificate2.GetRSAPublicKey()
            // This requires 4.6+ to be installed. If a dependent library is targeting 4.5, 4.5.1, 4.5.2 or 4.6
            // they will bind to our Net45 target, but the type is RSACng.
            // The 'lightup' code will bind to the correct operators.
            else if (rsa.GetType().ToString().Equals(_rsaCngTypeName) && IsRsaCngSupported())
            {
                _useRSAOeapPadding = algorithm.Equals(SecurityAlgorithms.RsaOAEP) ||
                                     algorithm.Equals(SecurityAlgorithms.RsaOaepKeyWrap);

                _lightUpHashAlgorithmName = GetLightUpHashAlgorithmName();
                DecryptFunction           = DecryptNet45;
                EncryptFunction           = EncryptNet45;
                SignatureFunction         = Pkcs1SignData;
                VerifyFunction            = Pkcs1VerifyData;
                RSA = rsa;
                return;
            }
            else
            {
                // In NET45 we only support RSACryptoServiceProvider or "System.Security.Cryptography.RSACng"
                throw LogHelper.LogExceptionMessage(new NotSupportedException(LogHelper.FormatInvariant(LogMessages.IDX10687, LogHelper.MarkAsNonPII(typeof(RSACryptoServiceProvider).ToString()), LogHelper.MarkAsNonPII(_rsaCngTypeName), LogHelper.MarkAsNonPII(rsa.GetType().ToString()))));
            }
#endif

#if NET461 || NET472 || NETSTANDARD2_0
            if (algorithm.Equals(SecurityAlgorithms.RsaSsaPssSha256) ||
                algorithm.Equals(SecurityAlgorithms.RsaSsaPssSha256Signature) ||
                algorithm.Equals(SecurityAlgorithms.RsaSsaPssSha384) ||
                algorithm.Equals(SecurityAlgorithms.RsaSsaPssSha384Signature) ||
                algorithm.Equals(SecurityAlgorithms.RsaSsaPssSha512) ||
                algorithm.Equals(SecurityAlgorithms.RsaSsaPssSha512Signature))
            {
                RSASignaturePadding = RSASignaturePadding.Pss;
            }
            else
            {
                // default RSASignaturePadding for other supported RSA algorithms is Pkcs1
                RSASignaturePadding = RSASignaturePadding.Pkcs1;
            }

            RSAEncryptionPadding = (algorithm.Equals(SecurityAlgorithms.RsaOAEP) || algorithm.Equals(SecurityAlgorithms.RsaOaepKeyWrap))
                        ? RSAEncryptionPadding.OaepSHA1
                        : RSAEncryptionPadding.Pkcs1;
            RSA               = rsa;
            DecryptFunction   = DecryptWithRsa;
            EncryptFunction   = EncryptWithRsa;
            SignatureFunction = SignWithRsa;
            VerifyFunction    = VerifyWithRsa;
#endif
        }
Beispiel #11
0
 public VerifierAttribute(Type typeContainingMethod, string methodName)
 {
     Handler = (VerifyDelegate)Delegate.CreateDelegate(
         typeof(VerifyDelegate),
         typeContainingMethod.GetMethod(methodName));
 }
Beispiel #12
0
        public OrlpEd25519Context(string sharedLibPathOverride = null)
        {
            string os;

            if (RuntimeInformation.IsOSPlatform(OSPlatform.Windows))
            {
                os        = "windows";
                loadUtils = new SharedLibLoadUtilsWindows();
            }
            else if (RuntimeInformation.IsOSPlatform(OSPlatform.Linux))
            {
                os        = "linux";
                loadUtils = new SharedLibLoadUtilsLinux();
            }
            else if (RuntimeInformation.IsOSPlatform(OSPlatform.OSX))
            {
                os        = "mac";
                loadUtils = new SharedLibLoadUtilsMac();
            }
            else
            {
                throw new PlatformNotSupportedException("Unsupported OS");
            }

            if (!string.IsNullOrEmpty(sharedLibPathOverride))
            {
                LoadedLibraryPath = sharedLibPathOverride;
            }
            else
            {
                string cpu = RuntimeInformation.ProcessArchitecture switch
                {
                    Architecture.X64 => "x64",
                    Architecture.X86 => "x86",
                    Architecture.Arm => "armeabi-v7a",
                    Architecture.Arm64 => "arm64-v8a",
                    _ => throw new PlatformNotSupportedException("CPU Architecture not supported!")
                };

                string path = Path.Combine(Path.GetFullPath(Path.GetDirectoryName(Assembly.GetCallingAssembly().Location) ?? "."), "lib", cpu, os);

                if (!Directory.Exists(path))
                {
                    throw new PlatformNotSupportedException($"Shared library not found in {path} and/or unsupported CPU architecture. Please don't forget to copy the shared libraries/DLL into the 'lib/{{CPU_ARCHITECTURE}}/{{OS}}/{{SHARED_LIB_FILE}}' folder of your output build directory. ");
                }

                bool found = false;
                foreach (string file in Directory.GetFiles(path))
                {
                    if (file.ToLower().Contains("ed25519"))
                    {
                        LoadedLibraryPath = Path.GetFullPath(Path.Combine(path, file));
                        found             = true;
                        break;
                    }
                }

                if (!found)
                {
                    throw new FileLoadException($"Shared library not found in {path} and/or unsupported CPU architecture. Please don't forget to copy the shared libraries/DLL into the 'lib/{{CPU_ARCHITECTURE}}/{{OS}}/{{SHARED_LIB_FILE}}' folder of your output build directory. ");
                }
            }

            lib = loadUtils.LoadLibrary(LoadedLibraryPath);
            if (lib == IntPtr.Zero)
            {
                goto hell; // The gates of hell opened, and out came the beginning of marshalling, DLL hell and C# interop...
            }

            IntPtr createSeed = loadUtils.GetProcAddress(lib, "ed25519_create_seed");

            if (createSeed == IntPtr.Zero)
            {
                goto hell;
            }

            IntPtr createKeypair = loadUtils.GetProcAddress(lib, "ed25519_create_keypair");

            if (createKeypair == IntPtr.Zero)
            {
                goto hell;
            }

            IntPtr sign = loadUtils.GetProcAddress(lib, "ed25519_sign");

            if (sign == IntPtr.Zero)
            {
                goto hell;
            }

            IntPtr verify = loadUtils.GetProcAddress(lib, "ed25519_verify");

            if (verify == IntPtr.Zero)
            {
                goto hell;
            }

            IntPtr addScalar = loadUtils.GetProcAddress(lib, "ed25519_add_scalar");

            if (addScalar == IntPtr.Zero)
            {
                goto hell;
            }

            IntPtr keyExchange = loadUtils.GetProcAddress(lib, "ed25519_key_exchange");

            if (keyExchange == IntPtr.Zero)
            {
                goto hell;
            }

            IntPtr keyConvert = loadUtils.GetProcAddress(lib, "ed25519_key_convert_ref10_to_orlp");

            if (keyConvert == IntPtr.Zero)
            {
                goto hell;
            }

            createSeedDelegate         = Marshal.GetDelegateForFunctionPointer <CreateSeedDelegate>(createSeed);
            createKeypairDelegate      = Marshal.GetDelegateForFunctionPointer <CreateKeypairDelegate>(createKeypair);
            signDelegate               = Marshal.GetDelegateForFunctionPointer <SignDelegate>(sign);
            verifyDelegate             = Marshal.GetDelegateForFunctionPointer <VerifyDelegate>(verify);
            addScalarDelegate          = Marshal.GetDelegateForFunctionPointer <AddScalarDelegate>(addScalar);
            keyExchangeDelegate        = Marshal.GetDelegateForFunctionPointer <KeyExchangeDelegate>(keyExchange);
            ref10KeyConversionDelegate = Marshal.GetDelegateForFunctionPointer <Ref10KeyConversionDelegate>(keyConvert);

            return;

hell:
            throw new Exception($"Failed to load one or more functions from the orlp-ed25519 shared library \"{LoadedLibraryPath}\"!");
        }