Understand how Azure IoT Edge uses certificates

Applies to: IoT Edge 1.5 checkmark IoT Edge 1.5 IoT Edge 1.4 checkmark IoT Edge 1.4

Important

IoT Edge 1.5 LTS and IoT Edge 1.4 LTS are supported releases. IoT Edge 1.4 LTS is end of life on November 12, 2024. If you are on an earlier release, see Update IoT Edge.

IoT Edge uses different types of certificates for different purposes. This article walks you through the different ways that IoT Edge uses certificates with Azure IoT Hub and IoT Edge gateway scenarios.

Important

For brevity, this article applies to IoT Edge version 1.2 or later. The certificate concepts for version 1.1 are similar, but there are some differences:

  • The device CA certificate in version 1.1 was renamed to Edge CA certificate.
  • The workload CA certificate in version 1.1 was retired. In version 1.2 or later, the IoT Edge module runtime generates all server certificates directly from the Edge CA certificate, without the intermediate workload CA certificate between them in the certificate chain.

Summary

These core scenarios are where IoT Edge uses certificates. Use the links to learn more about each scenario.

Actor Purpose Certificate
IoT Edge Ensures it's communicating to the right IoT Hub IoT Hub server certificate
IoT Hub Ensures the request came from a legitimate IoT Edge device IoT Edge identity certificate
Downstream IoT device Ensures it's communicating to the right IoT Edge gateway IoT Edge Hub edgeHub module server certificate, issued by Edge CA
IoT Edge Signs new module server certificates. For example, edgeHub Edge CA certificate
IoT Edge Ensures the request came from a legitimate downstream device IoT device identity certificate

Prerequisites

Single device scenario

To help understand IoT Edge certificate concepts, imagine a scenario where an IoT Edge device named EdgeGateway connects to an Azure IoT Hub named ContosoIotHub. In this example, all authentication is done with X.509 certificate authentication rather than symmetric keys. To establish trust in this scenario, we need to guarantee the IoT Hub and IoT Edge device are authentic: "Is this device genuine and valid?" and "Is the identity of the IoT Hub correct?". The scenario can be illustrated as follows:

Trust scenario state diagram showing connection between IoT Edge device and IoT Hub.

We'll explain the answers to each question and then expand the example in later sections of the article.

Device verifies IoT Hub identity

How does EdgeGateway verify it's communicating with the genuine ContosoIotHub? When EdgeGateway wants to talk to the cloud, it connects to the endpoint ContosoIoTHub.Azure-devices.NET. To make sure the endpoint is authentic, IoT Edge needs ContosoIoTHub to show identification (ID). The ID must be issued by an authority that EdgeGateway trusts. To verify IoT Hub identity, IoT Edge and IoT Hub use the TLS handshake protocol to verify IoT Hub's server identity. A TLS handshake is illustrated in the following diagram. To keep the example simple, some details have been omitted. To learn more about the TLS handshake protocol, see TLS handshake on Wikipedia.

Note

In this example, ContosoIoTHub represents the IoT Hub hostname ContosoIotHub.Azure-devices.NET.

Sequence diagram showing certificate exchange from IoT Hub to IoT Edge device with certificate verification with the trusted root store on the IoT Edge device.

In this context, you don't need to know the exact details of the cryptographic algorithm. It's important to understand that the algorithm ensures the server possesses the private key that is paired with its public key. It verifies that the presenter of the certificate didn't copy or steal it. If we use a photo ID as an example, your face matches the photo on the ID. If someone steals your ID, they can't use it for identification because your face is unique and difficult to reproduce. For cryptographic keys, the key pair is related and unique. Instead of the matching a face to a photo ID, the cryptographic algorithm uses the key pair to verify identity.

In our scenario, ContosoIotHub shows the following certificate chain:

Flow diagram showing intermediate and root certificate authority chain for IoT Hub.

The root certificate authority (CA) is the Baltimore CyberTrust Root certificate. This root certificate is signed by DigiCert, and is widely trusted and stored in many operating systems. For example, both Ubuntu and Windows include it in the default certificate store.

Windows certificate store:

Screenshot showing Baltimore CyberTrust Root certificate listed in the Windows certificate store.

Ubuntu certificate store:

Screenshot showing Baltimore CyberTrust Root certificate listed in the Ubuntu certificate store.

When a device checks for the Baltimore CyberTrust Root certificate, it's preinstalled in the OS. From EdgeGateway perspective, since the certificate chain presented by ContosoIotHub is signed by a root CA that the OS trusts, the certificate is considered trustworthy. The certificate is known as IoT Hub server certificate. To learn more about the IoT Hub server certificate, see Transport Layer Security (TLS) support in IoT Hub.

In summary, EdgeGateway can verify and trust ContosoIotHub's identity because:

  • ContosoIotHub presents its IoT Hub server certificate
  • The server certificate is trusted in the OS certificate store
  • Data encrypted with ContosoIotHub's public key can be decrypted by ContosoIotHub, proving its possession of the private key

IoT Hub verifies IoT Edge device identity

How does ContosoIotHub verify it's communicating with EdgeGateway? Since IoT Hub supports mutual TLS (mTLS), it checks EdgeGateway's certificate during client-authenticated TLS handshake. For simplicity, we'll skip some steps in the following diagram.

Sequence diagram showing certificate exchange from IoT Edge device to IoT Hub with certificate thumbprint check verification on IoT Hub.

In this case, EdgeGateway provides its IoT Edge device identity certificate. From ContosoIotHub perspective, it checks both that the thumbprint of the provided certificate matches its record and EdgeGateway has the private key paired with the certificate it presented. When you provision an IoT Edge device in IoT Hub, you provide a thumbprint. The thumbprint is what IoT Hub uses to verify the certificate.

Tip

IoT Hub requires two thumbprints when registering an IoT Edge device. A best practice is to prepare two different device identity certificates with different expiration dates. This way, if one certificate expires, the other is still valid and gives you time to rotate the expired certificate. However, it's also possible to use only one certificate for registration. Use a single certificate by setting the same certificate thumbprint for both the primary and secondary thumbprints when registering the device.

For example, we can use the following command to get the identity certificate's thumbprint on EdgeGateway:

sudo openssl x509 -in /var/lib/aziot/certd/certs/deviceid-random.cer -noout -nocert -fingerprint -sha256

The command outputs the certificate SHA256 thumbprint:

SHA256 Fingerprint=1E:F3:1F:88:24:74:2C:4A:C1:A7:FA:EC:5D:16:C4:11:CD:85:52:D0:88:3E:39:CB:7F:17:53:40:9C:02:95:C3

If we view the SHA256 thumbprint value for the EdgeGateway device registered in IoT Hub, we can see it matches the thumbprint on EdgeGateway:

Screenshot from Azure portal of EdgeGateway device's thumbprint in ContosoIotHub.

In summary, ContosoIotHub can trust EdgeGateway because EdgeGateway presents a valid IoT Edge device identity certificate whose thumbprint matches the one registered in IoT Hub.

For more information about the certificate building process, see Create and provision an IoT Edge device on Linux using X.509 certificates.

Note

This example doesn't address Azure IoT Hub Device Provisioning Service (DPS), which has support for X.509 CA authentication with IoT Edge when provisioned with an enrollment group. Using DPS, you upload the CA certificate or an intermediate certificate, the certificate chain is verified, then the device is provisioned. To learn more, see DPS X.509 certificate attestation.

In the Azure Portal, DPS displays the SHA1 thumbprint for the certificate rather than the SHA256 thumbprint.

DPS registers or updates the SHA256 thumbprint to IoT Hub. You can verify the thumbprint using the command openssl x509 -in /var/lib/aziot/certd/certs/deviceid-long-random-string.cer -noout -fingerprint -sha256. Once registered, Iot Edge uses thumbprint authentication with IoT Hub. If the device is reprovisioned and a new certificate is issued, DPS updates IoT Hub with the new thumbprint.

IoT Hub currently doesn't support X.509 CA authentication directly with IoT Edge.

Certificate use for module identity operations

In the certificate verification diagrams, it may appear IoT Edge only uses the certificate to talk to IoT Hub. IoT Edge consists of several modules. As a result, IoT Edge uses the certificate to manage module identities for modules that send messages. The modules don't use the certificate to authenticate to IoT Hub, but rather use SAS keys derived from the private key that are generated by IoT Edge module runtime. These SAS keys don't change even if the device identity certificate expires. If the certificate expires, edgeHub for example continues to run, and only the module identity operations fail.

The interaction between modules and IoT Hub is secure because the SAS key is derived from a secret and IoT Edge manages the key without the risk of human intervention.

Nested device hierarchy scenario with IoT Edge as gateway

You now have a good understanding of a simple interaction IoT Edge between and IoT Hub. But, IoT Edge can also act as a gateway for downstream devices or other IoT Edge devices. These communication channels must also be encrypted and trusted. Because of the added complexity, we have to expand our example scenario to include a downstream device.

We add a regular IoT device named TempSensor, which connects to its parent IoT Edge device EdgeGateway that connects to IoT Hub ContosoIotHub. Similar to before, all authentication is done with X.509 certificate authentication. Our new scenario raises two new questions: "Is the TempSensor device legitimate?" and "Is the identity of the EdgeGateway correct?". The scenario can be illustrated as follows:

Trust scenario state diagram showing connection between IoT Edge device, an IoT Edge gateway, and IoT Hub.

Tip

TempSensor is an IoT device in the scenario. The certificate concept is the same if TempSensor is a downstream IoT Edge device of parent EdgeGateway.

Device verifies gateway identity

How does TempSensor verify it's communicating with the genuine EdgeGateway? When TempSensor wants to talk to the EdgeGateway, TempSensor needs EdgeGateway to show an ID. The ID must be issued by an authority that TempSensor trusts.

Sequence diagram showing certificate exchange from gateway device to IoT Edge device with certificate verification using the private root certificate authority.

The flow is the same as when EdgeGateway talks to ContosoIotHub. TempSensor and EdgeGateway use the TLS handshake protocol to verify EdgeGateway's identity. There are two important details:

  • Hostname specificity: The certificate presented by EdgeGateway must be issued to the same hostname (domain or IP address) that TempSensor uses to connect to EdgeGateway.
  • Self-signed root CA specificity: The certificate chain presented by EdgeGateway is likely not in the OS default trusted root store.

To understand the details, let's first examine the certificate chain presented by EdgeGateway.

Flow diagram showing certificate authority chain for an IoT Edge gateway.

Hostname specificity

The certificate common name CN = edgegateway.local is listed at the top of the chain. edgegateway.local is edgeHub's server certificate common name. edgegateway.local is also the hostname for EdgeGateway on the local network (LAN or VNet) where TempSensor and EdgeGateway are connected. It could be a private IP address such as 192.168.1.23 or a fully qualified domain name (FQDN) like the diagram. The edgeHub server certificate is generated using the hostname parameter defined in the IoT Edge config.toml file. Don't confuse the edgeHub server certificate with Edge CA certificate. For more information about managing the Edge CA certificate, see Manage IoT Edge certificates.

When TempSensor connects to EdgeGateway, TempSensor uses the hostname edgegateway.local to connect to EdgeGateway. TempSensor checks the certificate presented by EdgeGateway and verifies that the certificate common name is edgegateway.local. If the certificate common name is different, TempSensor rejects the connection.

Note

For simplicity, the example shows subject certificate common name (CN) as property that is validated. In practice, if a certificate has a subject alternative name (SAN), SAN is validated instead of CN. Generally, because SAN can contain multiple values, it has both the main domain/hostname for the certificate holder as well as any alternate domains.

Why does EdgeGateway need to be told about its own hostname?

EdgeGateway doesn't have a reliable way to know how other clients on the network can connect to it. For example, on a private network, there could be DHCP servers or mDNS services that list EdgeGateway as 10.0.0.2 or example-mdns-hostname.local. But, some networks could have DNS servers that map edgegateway.local to EdgeGateway's IP address 10.0.0.2.

To solve the issue, IoT Edge uses the configured hostname value in config.toml and creates a server certificate for it. When a request comes to edgeHub module, it presents the certificate with the right certificate common name (CN).

Why does IoT Edge create certificates?

In the example, notice there's an iotedged workload ca edgegateway in the certificate chain. It's the certificate authority (CA) that exists on the IoT Edge device known as Edge CA (formerly known as Device CA in version 1.1). Like the Baltimore CyberTrust root CA in the earlier example, the Edge CA can issue other certificates. Most importantly, and also in this example, it issues the server certificate to edgeHub module. But, it can also issue certificates to other modules running on the IoT Edge device.

Important

By default without configuration, Edge CA is automatically generated by IoT Edge module runtime when it starts for the first time, known as quickstart Edge CA, and then it issues a certificate to edgeHub module. This process speeds downstream device connection by allowing edgeHub to present a valid certificate that is signed. Without this feature, you'd have to get your CA to issue a certificate for edgeHub module. Using an automatically generated quickstart Edge CA isn't supported for use in production. For more information on quickstart Edge CA, see Quickstart Edge CA.

Isn't it dangerous to have an issuer certificate on the device?

Edge CA is designed to enable solutions with limited, unreliable, expensive, or absent connectivity but at the same time have strict regulations or policies on certificate renewals. Without Edge CA, IoT Edge - and in particular edgeHub - cannot function.

To secure Edge CA in production:

  • Put the EdgeCA private key in a trusted platform module (TPM), preferably in a fashion where the private key is ephemerally generated and never leaves the TPM.
  • Use a Public Key Infrastructure (PKI) to which Edge CA rolls up. This provides the ability to disable or refuse renewal of compromised certificates. The PKI can be managed by customer IT if they have the know how (lower cost) or through a commercial PKI provider.

Self-signed root CA specificity

The edgeHub module is an important component that makes up IoT Edge by handling all incoming traffic. In this example, it uses a certificate issued by Edge CA, which is in turn issued by a self-signed root CA. Because the root CA isn't trusted by the OS, the only way TempSensor would trust it is to install the CA certificate onto the device. This is also known as the trust bundle scenario, where you need to distribute the root to clients that need to trust the chain. The trust bundle scenario can be troublesome because you need access the device and install the certificate. Installing the certificate requires planning. It can be done with scripts, added during manufacturing, or pre-installed in the OS image.

Note

Some clients and SDKs don't use the OS trusted root store and you need to pass the root CA file directly.

Applying all of these concepts, TempSensor can verify it's communicating with the genuine EdgeGateway because it presented a certificate that matched the address and the certificate is signed by a trusted root.

To verify the certificate chain, you could use openssl on the TempSensor device. In this example, notice that the hostname for connection matches the CN of the depth 0 certificate, and that the root CA match.

openssl s_client -connect edgegateway.local:8883 --CAfile my_private_root_CA.pem

depth=3 CN = my_private_root_CA
verify return:1
depth=2 CN = my_optional_intermediate_CA
verify return:1
depth=1 CN = iotedged workload ca edgegateway
verify return:1
depth=0 CN = edgegateway.local
verify return: 1
CONNECTED(00000003)
---
Certificate chain
0 s:/CN=edgegateway.local
  i:/CN=iotedged workload ca edgegateway
1 s:/CN=iotedged workload ca edgegateway
  i:/CN=my_optional_intermediate_CA
2 s:/CN=my_optional_intermediate_CA
  i:/CN=my_private_root_CA

To learn more about openssl command, see OpenSSL documentation.

You could also inspect the certificates where they're stored by default in /var/lib/aziot/certd/certs. You can find Edge CA certificates, device identity certificates, and module certificates in the directory. You can use openssl x509 commands to inspect the certificates. For example:

sudo ls -l /var/lib/aziot/certd/certs
total 24
-rw-r--r-- 1 aziotcs aziotcs 1090 Jul 27 21:27 aziotedgedca-86f154be7ff14480027f0d00c59c223db6d9e4ab0b559fc523cca36a7c973d6d.cer
-rw-r--r-- 1 aziotcs aziotcs 2589 Jun 22 18:25 aziotedgedmoduleIoTEdgeAPIProxy637913460334654299server-c7066944a8d35ca97f1e7380ab2afea5068f39a8112476ffc89ea2c46ca81d10.cer
-rw-r--r-- 1 aziotcs aziotcs 2576 Jun 22 18:25 aziotedgedmoduleedgeHub637911101449272999server-a0407493b6b50ee07b3fedbbb9d181e7bb5f6f52c1d071114c361aca628daa92.cer
-rw-r--r-- 1 aziotcs aziotcs 1450 Jul 27 21:27 deviceid-bd732105ef89cf8edd2606a5309c8a26b7b5599a4e124a0fe6199b6b2f60e655.cer

In summary, TempSensor can trust EdgeGateway because:

  • The edgeHub module showed a valid IoT Edge module server certificate for edgegateway.local
  • The certificate is issued by Edge CA which is issued by my_private_root_CA
  • This private root CA is also stored in the TempSensor as trusted root CA earlier
  • Cryptographic algorithms verify that the ownership and issuance chain can be trusted

Certificates for other modules

Other modules can get server certificates issued by Edge CA. For example, a Grafana module that has a web interface. It can also get a certificate from Edge CA. Modules are treated as downstream devices hosted in the container. However, being able to get a certificate from the IoT Edge module runtime is a special privilege. Modules call the workload API to receive the server certificate chained to the configured Edge CA.

Gateway verifies device identity

How does EdgeGateway verify it's communicating with TempSensor? EdgeGateway uses TLS client authentication to authenticate TempSensor.

Sequence diagram showing certificate exchange from IoT Edge device to gateway with certificate check verification from IoT Hub certificates.

The sequence is similar to ContosoIotHub verifying a device. However, in a gateway scenario, EdgeGateway relies on ContosoIotHub as the source of truth for the record of the certificates. EdgeGateway also keeps an offline copy or cache in case there's no connection to the cloud.

Tip

Unlike IoT Edge devices, downstream IoT devices are not limited to thumbprint X.509 authentication. X.509 CA authentication is also an option. Instead of just looking for a match on the thumbprint, EdgeGateway can also check if TempSensor's certificate is rooted in a CA that has been uploaded to ContosoIotHub.

In summary, EdgeGateway can trust TempSensor because:

  • TempSensor presented a valid IoT device identity certificate for its name
  • The identity certificate's thumbprint matches the one uploaded to ContosoIotHub
  • Cryptographic algorithms verify that the ownership and issuance chain can be trusted

Where to get the certificates and management

In most cases, you can provide your own certificates or use on auto-generated certificates. For example, Edge CA and the edgeHub certificate are auto-generated.

However, the best practice is to configure your devices to use an Enrollment over Secure Transport (EST) server to manage x509 certificates. Using an EST server frees you from manually handling the certificates and installing them on devices. For more information about using an EST server, see Configure Enrollment over Secure Transport Server for Azure IoT Edge.

You can use certificates to authenticate to EST server as well. These certificates are used to authenticate with EST servers to issue other certificates. The certificate service uses a bootstrap certificate to authenticate with an EST server. The bootstrap certificate is long-lived. Upon initial authentication, the certificate service makes a request to the EST server to issue an identity certificate. This identity certificate is used in future EST requests to the same server.

If you can't use an EST server, you should request certificates from your PKI provider. You can manage the certificate files manually in IoT Hub and your IoT Edge devices. For more information, Manage certificates on an IoT Edge device.

For proof of concept development, you can create test certificates. For more information, see Create demo certificates to test IoT Edge device features.

Certificates in IoT

Certificate authority

The certificate authority (CA) is an entity that issues digital certificates. A certificate authority acts as a trusted third party between the owner and the receiver of the certificate. A digital certificate certifies the ownership of a public key by the receiver of the certificate. The certificate chain of trust works by initially issuing a root certificate, which is the basis for trust in all certificates issued by the authority. The root certificate owner can then issue additional intermediate certificates (downstream device certificates).

Root CA certificate

A root CA certificate is the root of trust of the entire process. In production scenarios, this CA certificate is purchased from a trusted commercial certificate authority like Baltimore, Verisign, or DigiCert. Should you have complete control over the devices connecting to your IoT Edge devices, it's possible to use a corporate level certificate authority. In either event, the entire certificate chain from the IoT Edge to IoT Hub uses it. The downstream IoT devices must trust the root certificate. You can store the root CA certificate either in the trusted root certificate authority store, or provide the certificate details in your application code.

Intermediate certificates

In a typical manufacturing process for creating secure devices, root CA certificates are rarely used directly, primarily because of the risk of leakage or exposure. The root CA certificate creates and digitally signs one or more intermediate CA certificates. There may be only one, or there may be a chain of these intermediate certificates. Scenarios that would require a chain of intermediate certificates include:

  • A hierarchy of departments within a manufacturer
  • Multiple companies involved serially in the production of a device
  • A customer buying a root CA and deriving a signing certificate for the manufacturer to sign the devices they make on that customer's behalf

In any case, the manufacturer uses an intermediate CA certificate at the end of this chain to sign the Edge CA certificate placed on the end device. These intermediate certificates are closely guarded at the manufacturing plant. They undergo strict processes, both physical and electronic for their usage.

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