CertificateManager 1.0.9

dotnet add package CertificateManager --version 1.0.9                
NuGet\Install-Package CertificateManager -Version 1.0.9                
This command is intended to be used within the Package Manager Console in Visual Studio, as it uses the NuGet module's version of Install-Package.
<PackageReference Include="CertificateManager" Version="1.0.9" />                
For projects that support PackageReference, copy this XML node into the project file to reference the package.
paket add CertificateManager --version 1.0.9                
#r "nuget: CertificateManager, 1.0.9"                
#r directive can be used in F# Interactive and Polyglot Notebooks. Copy this into the interactive tool or source code of the script to reference the package.
// Install CertificateManager as a Cake Addin
#addin nuget:?package=CertificateManager&version=1.0.9

// Install CertificateManager as a Cake Tool
#tool nuget:?package=CertificateManager&version=1.0.9                

Certificate Manager Documentation

Certificate Manager is a package which makes it easy to create certificates (chained and self signed) which can be used to in client server authentication and IoT Devices like Azure IoT Hub

Basic usage ASP.NET Core, .NET Core

Add the NuGet package to the your project file

<PackageReference Include="CertificateManager" Version="1.0.9" />

The NuGet packages uses dependency injection to setup. In a console application initialize the package as follows:

var serviceProvider = new ServiceCollection()
    .AddCertificateManager()
    .BuildServiceProvider();

Or in an ASP.NET Core application use the Startup ConfigureServices method to initialize the package.

public void ConfigureServices(IServiceCollection services)
{
    // ...

    services.AddCertificateManager();
}

Certificate Configuration

Distinguished Name

The distinguished name will be saved to the Issuer and the Subject properties of the certificate.

var distinguishedName = new DistinguishedName
{
    CommonName = "localhost",
    Country = "CH",
    Locality = "CH",
    Organisation = "damienbod",
    OrganisationUnit = "development"
};

The CommonName property is required.

example in certificate:

C=CH, C=CH, O=damienbod, OU=development, CN=localhost

definitions:

  • C= Country
  • ST= State or province
  • L= Locality
  • O= organisation
  • OU=Organisation Unit
  • CN= Common name

// CN is REQUIRED

Validity Period

The Validity Period defines when the certificate is valid from and how long.

var validityPeriod = new ValidityPeriod
{
    ValidFrom = DateTime.UtcNow,
    ValidTo = DateTime.UtcNow.AddYears(10)
};

If creating a child certificate from a root or an intermediate certification, the values cannot be outside the range of the parent. If the certificate values are outside the range, the parent values will be used.

The ValidFrom and the ValidTo values can then be used to validate the certificate. It is recommended the keep this period short. This depends on how you use and deploy the certificates.

Creating Self Signed Certificates for Client Server Authentication

The CreateCertificatesClientServerAuth service is used to create these certificates.

var dnsName = "localhost";
var serviceProvider = new ServiceCollection()
    .AddCertificateManager()
    .BuildServiceProvider();

var createClientServerAuthCerts = serviceProvider.GetService<CreateCertificatesClientServerAuth>();

The NewServerSelfSignedCertificate method can be used to create a self signed certificate for a certificate which is to be used on the server. The dnsName must match your server deployment. Only the correct enhanced Key usages is set.

Oid("1.3.6.1.5.5.7.3.1"), // TLS Server auth

This can then be validated.

// Server self signed certificate
var server = createClientServerAuthCerts.NewServerSelfSignedCertificate(
    new DistinguishedName { CommonName = "server", Country = "CH" },
    new ValidityPeriod { ValidFrom = DateTime.UtcNow, ValidTo = DateTime.UtcNow.AddYears(10) },
    dnsName);
server.FriendlyName = "azure server certificate";

The NewClientSelfSignedCertificate method can be used to create a self signed certificate for a certificate which is to be used on the server. The dnsName must match your server deployment. Only the correct enhanced Key usages is set.

Oid("1.3.6.1.5.5.7.3.2"), // TLS Client auth

This can then be validated.

// Client self signed certificate
var client = createClientServerAuthCerts.NewClientSelfSignedCertificate(
    new DistinguishedName { CommonName = "client", Country = "CH" },
    new ValidityPeriod { ValidFrom = DateTime.UtcNow, ValidTo = DateTime.UtcNow.AddYears(10) },
    dnsName);

client.FriendlyName = "azure client certificate";

Creating Chained Certificates for Client Server Authentication

The CreateCertificatesClientServerAuth service is used to create these certificates.

var serviceProvider = new ServiceCollection()
    .AddCertificateManager()
    .BuildServiceProvider();

var createClientServerAuthCerts = serviceProvider.GetService<CreateCertificatesClientServerAuth>();

The NewRootCertificate method creates a new root certificate which can be used for chained structures. If you use your own root certificate, it needs to be added to the trusted certificate store on deployment host.

This is not needed if creting certificates from a public CA certificate. The root certificatge is a self signed certificate.

var rootCaL1 = createClientServerAuthCerts.NewRootCertificate(
    new DistinguishedName { CommonName = "root dev", Country = "IT" },
    new ValidityPeriod { ValidFrom = DateTime.UtcNow, ValidTo = DateTime.UtcNow.AddYears(10) },
    3, "localhost");
rootCaL1.FriendlyName = "developement root L1 certificate";

The NewIntermediateChainedCertificate creates an intermediate certificate from a parent root or another intermediate certificate.

// Intermediate L2 chained from root L1
var intermediateCaL2 = createClientServerAuthCerts.NewIntermediateChainedCertificate(
    new DistinguishedName { CommonName = "intermediate dev", Country = "FR" },
    new ValidityPeriod { ValidFrom = DateTime.UtcNow, ValidTo = DateTime.UtcNow.AddYears(10) },
    2,  "localhost", rootCaL1);
intermediateCaL2.FriendlyName = "developement Intermediate L2 certificate";

The NewServerChainedCertificate method can be used to create a self signed certificate for a certificate which is to be used on the server. The dnsName must match your server deployment. Only the correct enhanced Key usages is set.

Oid("1.3.6.1.5.5.7.3.1"), // TLS Server auth

This can then be validated.

// Server, Client L3 chained from Intermediate L2
var serverL3 = createClientServerAuthCerts.NewServerChainedCertificate(
    new DistinguishedName { CommonName = "server", Country = "DE" },
    new ValidityPeriod { ValidFrom = DateTime.UtcNow, ValidTo = DateTime.UtcNow.AddYears(10) },
    "localhost", intermediateCaL2);
serverL3.FriendlyName = "developement server L3 certificate";

The NewClientChainedCertificate method can be used to create a chained certificate for a certificate which is to be used on the server. The dnsName must match your server deployment. Only the correct enhanced Key usages is set.

Oid("1.3.6.1.5.5.7.3.2"), // TLS Client auth

This can then be validated.

var clientL3 = createClientServerAuthCerts.NewClientChainedCertificate(
    new DistinguishedName { CommonName = "client", Country = "IE" },
    new ValidityPeriod { ValidFrom = DateTime.UtcNow, ValidTo = DateTime.UtcNow.AddYears(10) },
    "localhost", intermediateCaL2);
clientL3.FriendlyName = "developement client L3 certificate";
            

Creating Chained Certificates for Azure IoT Hub

var serviceProvider = new ServiceCollection()
	.AddCertificateManager()
	.BuildServiceProvider();

var createClientServerAuthCerts = serviceProvider.GetService<CreateCertificatesClientServerAuth>();

var root = createClientServerAuthCerts.NewRootCertificate(
	new DistinguishedName { CommonName = "root dev", Country = "IT" },
	new ValidityPeriod { ValidFrom = DateTime.UtcNow, ValidTo = DateTime.UtcNow.AddYears(10) },
	3, "localhost");
root.FriendlyName = "developement root certificate";

// Intermediate L2 chained from root L1
var intermediate = createClientServerAuthCerts.NewIntermediateChainedCertificate(
	new DistinguishedName { CommonName = "intermediate dev", Country = "FR" },
	new ValidityPeriod { ValidFrom = DateTime.UtcNow, ValidTo = DateTime.UtcNow.AddYears(10) },
	2, "localhost", root);
intermediate.FriendlyName = "developement Intermediate certificate";

string password = "1234";
var importExportCertificate = serviceProvider.GetService<ImportExportCertificate>();

var rootCertInPfxBtyes = importExportCertificate.ExportRootPfx(password, root);
File.WriteAllBytes("root.pfx", rootCertInPfxBtyes);

// https://docs.microsoft.com/en-us/azure/iot-hub/iot-hub-security-x509-get-started

var rootPublicKey = importExportCertificate.ExportCertificatePublicKey(root);
var rootPublicKeyBytes = rootPublicKey.Export(X509ContentType.Cert);
File.WriteAllBytes($"root.cer", rootPublicKeyBytes);

var intermediateCertInPfxBtyes = importExportCertificate.ExportChainedCertificatePfx(password, intermediate, root);
File.WriteAllBytes("intermediate.pfx", intermediateCertInPfxBtyes);

Creating Verify Certificate for Azure IoT Hub

var serviceProvider = new ServiceCollection()
	.AddCertificateManager()
	.BuildServiceProvider();

var createClientServerAuthCerts = serviceProvider.GetService<CreateCertificatesClientServerAuth>();

var importExportCertificate = serviceProvider.GetService<ImportExportCertificate>();

var root = new X509Certificate2("root.pfx", "1234");

var deviceVerify = createClientServerAuthCerts.NewDeviceVerificationCertificate(
"<veification code from Azure IoT Hub>", root);
deviceVerify.FriendlyName = "device verify";

var deviceVerifyPEM = importExportCertificate.PemExportPublicKeyCertificate(deviceVerify);
File.WriteAllText("deviceVerify.pem", deviceVerifyPEM);

var deviceVerifyPublicKey = importExportCertificate.ExportCertificatePublicKey(deviceVerify);
var deviceVerifyPublicKeyBytes = deviceVerifyPublicKey.Export(X509ContentType.Cert);
File.WriteAllBytes($"deviceVerify.cer", deviceVerifyPublicKeyBytes);

Creating Device (Leaf) Certificates for Azure IoT Hub

var serviceProvider = new ServiceCollection()
	.AddCertificateManager()
	.BuildServiceProvider();

var createClientServerAuthCerts = serviceProvider.GetService<CreateCertificatesClientServerAuth>();

var intermediate = new X509Certificate2("intermediate.pfx", "1234");

var testDevice01 = createClientServerAuthCerts.NewDeviceChainedCertificate(
	new DistinguishedName { CommonName = "<Device ID>" },
	new ValidityPeriod { ValidFrom = DateTime.UtcNow, ValidTo = DateTime.UtcNow.AddYears(10) },
	"localhost", intermediate);
testDevice01.FriendlyName = "IoT device testDevice01";

string password = "1234";
var importExportCertificate = serviceProvider.GetService<ImportExportCertificate>();

var deviceInPfxBytes = importExportCertificate.ExportChainedCertificatePfx(password, testDevice01, intermediate);
File.WriteAllBytes("testDevice01.pfx", deviceInPfxBytes);

Creating certificates for application development Angular, VUE.js

var serviceProvider = new ServiceCollection()
    .AddCertificateManager()
    .BuildServiceProvider();

var _createCertificatesRsa = serviceProvider.GetService<CreateCertificatesRsa>();

// Create development certificate for localhost
var devCertificate = _createCertificatesRsa
    .CreateDevelopmentCertificate("localhost", 10);

devCertificate.FriendlyName = "localhost development";

string password = "1234";
var importExportCertificate = serviceProvider.GetService<ImportExportCertificate>();

// full pfx with password
var rootCertInPfxBtyes = importExportCertificate.ExportRootPfx(password, devCertificate);
File.WriteAllBytes("dev_localhost.pfx", rootCertInPfxBtyes);

// private key
var exportRsaPrivateKeyPem = importExportCertificate.PemExportRsaPrivateKey(devCertificate);
File.WriteAllText($"dev_localhost.key", exportRsaPrivateKeyPem);

// public key certificate as pem
var exportPublicKeyCertificatePem = importExportCertificate.PemExportPublicKeyCertificate(devCertificate);
File.WriteAllText($"dev_localhost.pem", exportPublicKeyCertificatePem);

Creating Chained Certificates from a trusted CA Certificate

Exporting Certificates

Exporting self signed certificates

var serverCertInPfxBtyes = 
    importExportCertificate.ExportSelfSignedCertificatePfx(password, server);
File.WriteAllBytes("server.pfx", serverCertInPfxBtyes);

var clientCertInPfxBtyes = 
    importExportCertificate.ExportSelfSignedCertificatePfx(password, client);
File.WriteAllBytes("client.pfx", clientCertInPfxBtyes);

Exporting chained certificates

string password = "1234";
var importExportCertificate = serviceProvider.GetService<ImportExportCertificate>();

var rootCertInPfxBtyes = importExportCertificate.ExportRootPfx(password, rootCaL1);
File.WriteAllBytes("localhost_root_l1.pfx", rootCertInPfxBtyes);

var rootPublicKey = importExportCertificate.ExportCertificatePublicKey(rootCaL1);
var rootPublicKeyBytes = rootPublicKey.Export(X509ContentType.Cert);
File.WriteAllBytes($"localhost_root_l1.cer", rootPublicKeyBytes);

var intermediateCertInPfxBtyes = importExportCertificate.ExportChainedCertificatePfx(password, intermediateCaL2, rootCaL1);
File.WriteAllBytes("localhost_intermediate_l2.pfx", intermediateCertInPfxBtyes);

var serverCertL3InPfxBtyes = importExportCertificate.ExportChainedCertificatePfx(password, serverL3, intermediateCaL2);
File.WriteAllBytes("serverl3.pfx", serverCertL3InPfxBtyes);

var clientCertL3InPfxBtyes = importExportCertificate.ExportChainedCertificatePfx(password, clientL3, intermediateCaL2);
File.WriteAllBytes("clientl3.pfx", clientCertL3InPfxBtyes);

Exporting verify certificates

var serviceProvider = new ServiceCollection()
    .AddCertificateManager()
    .BuildServiceProvider();

var createClientServerAuthCerts = serviceProvider.GetService<CreateCertificatesClientServerAuth>();

var importExportCertificate = serviceProvider.GetService<ImportExportCertificate>();

var root = new X509Certificate2("root.pfx", "1234");

var deviceVerify = createClientServerAuthCerts.NewDeviceVerificationCertificate(
"4C8C754C6DA4280DBAB7FC7BB320E7FFFB7F411CBB7EAA7D", root);
deviceVerify.FriendlyName = "device verify";

var deviceVerifyPEM = importExportCertificate.PemExportPublicKeyCertificate(deviceVerify);
File.WriteAllText("deviceVerify.pem", deviceVerifyPEM);

var deviceVerifyPublicKey = importExportCertificate.ExportCertificatePublicKey(deviceVerify);
var deviceVerifyPublicKeyBytes = deviceVerifyPublicKey.Export(X509ContentType.Cert);
File.WriteAllBytes($"deviceVerify.cer", deviceVerifyPublicKeyBytes);

Exporting Importing PEM

RSA

var sp = new ServiceCollection()
    .AddCertificateManager()
    .BuildServiceProvider();

var ccRsa = sp.GetService<CreateCertificatesRsa>();
var iec = sp.GetService<ImportExportCertificate>();

var rsaCert = ccRsa.CreateDevelopmentCertificate("localhost", 2, 2048);

// export
var publicKeyPem = iec.PemExportPublicKeyCertificate(rsaCert);
var rsaPrivateKeyPem = iec.PemExportRsaPrivateKey(rsaCert);

// import
var roundTripPublicKeyPem = iec.PemImportCertificate(publicKeyPem);
var roundTripRsaPrivateKeyPem = iec.PemImportPrivateKey(rsaPrivateKeyPem);

var roundTripFullCert = 
    iec.CreateCertificateWithPrivateKey(
        roundTripPublicKeyPem, 
        roundTripRsaPrivateKeyPem, 
        "1234");

ECDsa

var sp = new ServiceCollection()
    .AddCertificateManager()
    .BuildServiceProvider();

var cc = serviceProvider.GetService<CreateCertificatesClientServerAuth>();

var root = cc.NewRootCertificate(
    new DistinguishedName { CommonName = "root dev", Country = "IT" },
    new ValidityPeriod { ValidFrom = DateTime.UtcNow, ValidTo = DateTime.UtcNow.AddYears(10) },
    3, "localhost");
root.FriendlyName = "developement root L1 certificate";

var iec = sp.GetService<ImportExportCertificate>();

// export
var publicKeyPem = iec.PemExportPublicKeyCertificate(root);
var eCDsaPrivateKeyPem = iec.PemExportECPrivateKey(root);

// import
var roundTripPublicKeyPem = iec.PemImportCertificate(publicKeyPem);
var roundTripECPrivateKeyPem = iec.PemImportPrivateKey(eCDsaPrivateKeyPem);

var roundTripFullCert = 
    iec.CreateCertificateWithPrivateKey(
        roundTripPublicKeyPem, 
        roundTripECPrivateKeyPem, 
        "1234");

General Certificates, full APIs

Self signed certificate

Creating a self signed certificate using NewECDsaSelfSignedCertificate with ECDsa

var serviceProvider = new ServiceCollection()
    .AddCertificateManager()
    .BuildServiceProvider();

var enhancedKeyUsages = new OidCollection {
    new Oid("1.3.6.1.5.5.7.3.2"), // TLS Client auth
    new Oid("1.3.6.1.5.5.7.3.1")  // TLS Server auth
};

var createCertificates = serviceProvider.GetService<CreateCertificates>();

// Create the root self signed cert
var rootCert = createCertificates.NewECDsaSelfSignedCertificate(
    RootCertConfig.DistinguishedName,
    RootCertConfig.BasicConstraints,
    RootCertConfig.ValidityPeriod,
    RootCertConfig.SubjectAlternativeName,
    enhancedKeyUsages,
    RootCertConfig.X509KeyUsageFlags,
    new ECDsaConfiguration());

rootCert.FriendlyName = "localhost root l1";

Certificate configuration for a self signed root

public static class RootCertConfig
{
    public static DistinguishedName DistinguishedName = new DistinguishedName
    {
        CommonName = "localhost",
        Country = "CH",
        Locality = "CH",
        Organisation = "damienbod",
        OrganisationUnit = "developement"
    };

    public static BasicConstraints BasicConstraints = new BasicConstraints
    {
        CertificateAuthority = true,
        HasPathLengthConstraint = true,
        PathLengthConstraint = 3,
        Critical = true
    };

    public static ValidityPeriod ValidityPeriod = new ValidityPeriod
    {
        ValidFrom = DateTime.UtcNow,
        ValidTo = DateTime.UtcNow.AddYears(10)
    };

    public static SubjectAlternativeName SubjectAlternativeName = new SubjectAlternativeName
    {
        Email = "damienbod@damienbod.ch",
        DnsName = new List<string>
        {
            "localhost",
            "test.damienbod.ch"
        }
    };

    // Only X509KeyUsageFlags.KeyCertSign required for client server auth
    public static X509KeyUsageFlags X509KeyUsageFlags = X509KeyUsageFlags.DigitalSignature
            | X509KeyUsageFlags.KeyEncipherment
            | X509KeyUsageFlags.KeyCertSign;
    }

Chained certificate

Creating a certificate using NewECDsaChainedCertificate using ECDsa

var serviceProvider = new ServiceCollection()
    .AddCertificateManager()
    .BuildServiceProvider();

var enhancedKeyUsages = new OidCollection {
    new Oid("1.3.6.1.5.5.7.3.2"), // TLS Client auth
    new Oid("1.3.6.1.5.5.7.3.1")  // TLS Server auth
};

var createCertificates = serviceProvider.GetService<CreateCertificates>();

var deviceCertificate = createCertificates.NewECDsaChainedCertificate(
    DeviceCertConfig.DistinguishedName,
    DeviceCertConfig.BasicConstraints,
    DeviceCertConfig.ValidityPeriod,
    DeviceCertConfig.SubjectAlternativeName,
    intermediateCertificateLevel3,
    enhancedKeyUsages,
    DeviceCertConfig.X509KeyUsageFlags,
    new ECDsaConfiguration());

deviceCertificate.FriendlyName = "device cert l4";

Device certificate chained

public static class DeviceCertConfig
    {
        public static DistinguishedName DistinguishedName = new DistinguishedName
        {
            CommonName = "localhost",
            Country = "CH",
            Locality = "CH",
            Organisation = "firma x",
            OrganisationUnit = "skills"
        };

        public static BasicConstraints BasicConstraints = new BasicConstraints
        {
            CertificateAuthority = false,
            HasPathLengthConstraint = false,
            PathLengthConstraint = 0,
            Critical = true
        };

        public static ValidityPeriod ValidityPeriod = new ValidityPeriod
        {
            ValidFrom = DateTime.UtcNow,
            ValidTo = DateTime.UtcNow.AddYears(10)
        };

        public static SubjectAlternativeName SubjectAlternativeName = new SubjectAlternativeName
        {
            DnsName = new List<string>
            {
                "localhost"
            }
        };

        public static X509KeyUsageFlags X509KeyUsageFlags = 
             X509KeyUsageFlags.DigitalSignature | X509KeyUsageFlags.KeyEncipherment;
    }

Certificate Configuration full APIs

Basic Constraints

basic constraints for intermediate and root certificates. Set the path length to match the chain length.

var basicConstraints = new BasicConstraints
{
    CertificateAuthority = true,
    HasPathLengthConstraint = true,
    PathLengthConstraint = pathLengthConstraint,
    Critical = true
};

Or the basic constaints for a device, client or server certificate.

var basicConstraints = new BasicConstraints
{
    CertificateAuthority = false,
    HasPathLengthConstraint = false,
    PathLengthConstraint = 0,
    Critical = true
};

Subject Alternative Name

Add the required or supported DnsName or the Email here.

var subjectAlternativeName = new SubjectAlternativeName
{
    DnsName = new List<string>
    {
        "localhost"
    }
};

Enhanced Key Usages

Defines how the certificate key can be used.

var enhancedKeyUsages = new OidCollection {
    new Oid("1.3.6.1.5.5.7.3.2"), // TLS Client auth
    new Oid("1.3.6.1.5.5.7.3.1")  // TLS Server auth
};
  • new Oid("1.3.6.1.5.5.7.3.1") // TLS Server auth
  • new Oid("1.3.6.1.5.5.7.3.2") // TLS Client auth
  • new Oid("1.3.6.1.5.5.7.3.3") // Code signing
  • new Oid("1.3.6.1.5.5.7.3.4") // Email
  • new Oid("1.3.6.1.5.5.7.3.8") // Timestamping

X509 Key Usage Flags

Defines how the certificate key can be used.

var x509KeyUsageFlags = 
             X509KeyUsageFlags.DigitalSignature | X509KeyUsageFlags.KeyEncipherment;
  • None No key usage parameters.
  • EncipherOnly The key can be used for encryption only.
  • CrlSign The key can be used to sign a certificate revocation list (CRL).
  • KeyCertSign The key can be used to sign certificates.
  • KeyAgreement The key can be used to determine key agreement, such as a key created using the Diffie-Hellman key agreement algorithm.
  • DataEncipherment The key can be used for data encryption.
  • KeyEncipherment The key can be used for key encryption.
  • NonRepudiation The key can be used for authentication.
  • DecipherOnly The key can be used for decryption only.
Product Compatible and additional computed target framework versions.
.NET net5.0 was computed.  net5.0-windows was computed.  net6.0 was computed.  net6.0-android was computed.  net6.0-ios was computed.  net6.0-maccatalyst was computed.  net6.0-macos was computed.  net6.0-tvos was computed.  net6.0-windows was computed.  net7.0 was computed.  net7.0-android was computed.  net7.0-ios was computed.  net7.0-maccatalyst was computed.  net7.0-macos was computed.  net7.0-tvos was computed.  net7.0-windows was computed.  net8.0 was computed.  net8.0-android was computed.  net8.0-browser was computed.  net8.0-ios was computed.  net8.0-maccatalyst was computed.  net8.0-macos was computed.  net8.0-tvos was computed.  net8.0-windows was computed. 
.NET Core netcoreapp3.0 was computed.  netcoreapp3.1 was computed. 
.NET Standard netstandard2.1 is compatible. 
MonoAndroid monoandroid was computed. 
MonoMac monomac was computed. 
MonoTouch monotouch was computed. 
Tizen tizen60 was computed. 
Xamarin.iOS xamarinios was computed. 
Xamarin.Mac xamarinmac was computed. 
Xamarin.TVOS xamarintvos was computed. 
Xamarin.WatchOS xamarinwatchos was computed. 
Compatible target framework(s)
Included target framework(s) (in package)
Learn more about Target Frameworks and .NET Standard.

NuGet packages (2)

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CommunAxiom.DotnetSdk.Helpers

Package Description

DMediatR

Distributed MediatR using gRPC over TLS with auto-renewed self-signed X509 client certificates

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Version Downloads Last updated
1.0.9 3,032 10/31/2024
1.0.8 259,079 1/21/2022
1.0.7 5,746 1/16/2022
1.0.6 39,277 11/21/2021
1.0.5 70,536 8/8/2020
1.0.4 55,708 2/21/2020
1.0.3 13,776 1/29/2020
1.0.2 919 1/27/2020
1.0.1 1,874 1/24/2020
1.0.0 960 1/22/2020

Update serial conversion to use big endian only