Using a Hardware Security Module (HSM)

The cryptographic operations performed by Fabric nodes can be delegated to a Hardware Security Module (HSM). An HSM protects your private keys and handles cryptographic operations, allowing your peers and orderer nodes to sign and endorse transactions without exposing their private keys. If you require compliance with government standards such as FIPS 140-2, there are multiple certified HSMs from which to choose.

Fabric currently leverages the PKCS11 standard to communicate with an HSM.

Note: Fabric can use a HSM for peer and orderer node MSP identities as documented in this topic, however for TLS you must use file-based keys as documented in the TLS topic.

Configuring an HSM

To use an HSM with your Fabric node, you need to update the bccsp (Crypto Service Provider) section of the node configuration file such as core.yaml or orderer.yaml. In the bccsp section, you need to select PKCS11 as the provider and enter the path to the PKCS11 library that you would like to use. You also need to provide the Label and PIN of the token that you created for your cryptographic operations. You can use one token to generate and store multiple keys.

The prebuilt Hyperledger Fabric Docker images are not enabled to use PKCS11. If you are deploying Fabric using docker, you need to build your own images and enable PKCS11 using the following command:

make docker GO_TAGS=pkcs11

You also need to ensure that the PKCS11 library is available to be used by the node by installing it or mounting it inside the container.

Example

The following example demonstrates how to configure a Fabric node to use an HSM.

First, you will need to install an implementation of the PKCS11 interface. This example uses the softhsm open source implementation. After downloading and configuring softhsm, you will need to set the SOFTHSM2_CONF environment variable to point to the softhsm2 configuration file.

You can then use softhsm to create the token that will handle the cryptographic operations of your Fabric node inside an HSM slot. In this example, we create a token labelled “fabric” and set the pin to “71811222”. After you have created the token, update the configuration file to use PKCS11 and your token as the crypto service provider. You can find an example bccsp section below:

#############################################################################
# BCCSP (BlockChain Crypto Service Provider) section is used to select which
# crypto library implementation to use
#############################################################################
bccsp:
  default: PKCS11
  pkcs11:
    Library: /etc/hyperledger/fabric/libsofthsm2.so
    Pin: "71811222"
    Label: fabric
    hash: SHA2
    security: 256
    Immutable: false

By default, when private keys are generated using the HSM, the private key is mutable, meaning PKCS11 private key attributes can be changed after the key is generated. Setting Immutable to true means that the private key attributes cannot be altered after key generation. Before you configure immutability by setting Immutable: true, ensure that PKCS11 object copy is supported by the HSM.

If you are using AWS HSM there is an additional step required:

  • Add the parameter, AltID to the pkcs11 section of the bccsp block. When AWS HSM is being used, this parameter is used to assign a unique value for the Subject Key Identifier (SKI). Create a long secure string outside of Fabric and assign it to the AltID parameter. For example:

    #############################################################################
    # BCCSP (BlockChain Crypto Service Provider) section is used to select which
    # crypto library implementation to use
    #############################################################################
    bccsp:
      default: PKCS11
      pkcs11:
        Library: /etc/hyperledger/fabric/libsofthsm2.so
        Pin: 71811222
        Label: fabric
        hash: SHA2
        security: 256
        Immutable: false
        AltID: 4AMfmFMtLY6B6vN3q4SQtCkCQ6UY5f6gUF3rDRE4wqD4YDUrunuZbmZpVk8zszkt86yenPBUGE2aCQCZmQFcmnj3UaxyLzfTMjCnapAe3
    

You can also use environment variables to override the relevant fields of the configuration file. If you are connecting to softhsm2 using the Fabric CA server, you could set the following environment variables or directly set the corresponding values in the CA server config file:

FABRIC_CA_SERVER_BCCSP_DEFAULT=PKCS11
FABRIC_CA_SERVER_BCCSP_PKCS11_LIBRARY=/etc/hyperledger/fabric/libsofthsm2.so
FABRIC_CA_SERVER_BCCSP_PKCS11_PIN=71811222
FABRIC_CA_SERVER_BCCSP_PKCS11_LABEL=fabric

If you are connecting to softhsm2 using the Fabric peer, you could set the following environment variables or directly set the corresponding values in the peer config file:

CORE_PEER_BCCSP_DEFAULT=PKCS11
CORE_PEER_BCCSP_PKCS11_LIBRARY=/etc/hyperledger/fabric/libsofthsm2.so
CORE_PEER_BCCSP_PKCS11_PIN=71811222
CORE_PEER_BCCSP_PKCS11_LABEL=fabric

If you are connecting to softhsm2 using the Fabric orderer, you could set the following environment variables or directly set the corresponding values in the orderer config file:

ORDERER_GENERAL_BCCSP_DEFAULT=PKCS11
ORDERER_GENERAL_BCCSP_PKCS11_LIBRARY=/etc/hyperledger/fabric/libsofthsm2.so
ORDERER_GENERAL_BCCSP_PKCS11_PIN=71811222
ORDERER_GENERAL_BCCSP_PKCS11_LABEL=fabric

If you are deploying your nodes using docker compose, after building your own images, you can update your docker compose files to mount the softhsm library and configuration file inside the container using volumes. As an example, you would add the following environment and volumes variables to your docker compose file:

  environment:
     - SOFTHSM2_CONF=/etc/hyperledger/fabric/config.file
  volumes:
     - /home/softhsm/config.file:/etc/hyperledger/fabric/config.file
     - /usr/local/Cellar/softhsm/2.1.0/lib/softhsm/libsofthsm2.so:/etc/hyperledger/fabric/libsofthsm2.so

Setting up a network using HSM

If you are deploying Fabric nodes using an HSM, your private keys need to be generated and stored inside the HSM rather than inside the keystore folder of the node’s local MSP folder. The keystore folder of the MSP will remain empty. Instead, the Fabric node will use the subject key identifier of the signing certificate in the signcerts folder to retrieve the private key from inside the HSM. The process for creating the node MSP folder differs depending on whether you are using a Fabric Certificate Authority (CA) your own CA.

Before you begin

Before configuring a Fabric node to use an HSM, you should have completed the following steps:

  1. Created a partition on your HSM Server and recorded the Label and PIN of the partition.

  2. Followed instructions in the documentation from your HSM provider to configure an HSM Client that communicates with your HSM server.

Using an HSM with a Fabric CA

You can set up a Fabric CA to use an HSM by making the same edits to the CA server configuration file as you would make to a peer or ordering node. Because you can use the Fabric CA to generate keys inside an HSM, the process of creating the local MSP folders is straightforward. Use the following steps:

  1. Modify the bccsp section of the Fabric CA server configuration file and point to the Label and PIN that you created for your HSM. When the Fabric CA server starts, the private key is generated and stored in the HSM. If you are not concerned about exposing your CA signing certificate, you can skip this step and only configure an HSM for your peer or ordering nodes, described in the next steps.

  2. Use the Fabric CA client to register the peer or ordering node identities with your CA.

  3. Before you deploy a peer or ordering node with HSM support, you need to enroll the node identity by storing its private key in the HSM. Edit the bccsp section of the Fabric CA client config file or use the associated environment variables to point to the HSM configuration for your peer or ordering node. In the Fabric CA Client configuration file, replace the default SW configuration with the PKCS11 configuration and provide the values for your own HSM:

bccsp:
  default: PKCS11
  pkcs11:
    Library: /etc/hyperledger/fabric/libsofthsm2.so
    Pin: "71811222"
    Label: fabric
    hash: SHA2
    security: 256
    Immutable: false

Then for each node, use the Fabric CA client to generate the peer or ordering node’s MSP folder by enrolling against the node identity that you registered in step 2. Instead of storing the private key in the keystore folder of the associated MSP, the enroll command uses the node’s HSM to generate and store the private key for the peer or ordering node. The keystore folder remains empty.

  1. To configure a peer or ordering node to use the HSM, similarly update the bccsp section of the peer or orderer configuration file to use PKCS11 and provide the Label and PIN. Also, edit the value of the mspConfigPath (for a peer node) or the LocalMSPDir (for an ordering node) to point to the MSP folder that was generated in the previous step using the Fabric CA client. Now that the peer or ordering node is configured to use HSM, when you start the node it will be able sign and endorse transactions with the private key protected by the HSM.

Using an HSM with your own CA

If you are using your own Certificate Authority to deploy Fabric components, you can use an HSM using the following steps:

  1. Configure your CA to communicate with an HSM using PKCS11 and create a Label and PIN. Then use your CA to generate the private key and signing certificate for each node, with the private key generated inside the HSM.

  2. Use your CA to build the peer or ordering node MSP folder. Place the signing certificate that you generated in step 1 inside the signcerts folder. You can leave the keystore folder empty.

  3. To configure a peer or ordering node to use the HSM, similarly update the bccsp section of the peer or orderer configuration file to use PKCS11 andand provide the Label and PIN. Edit the value of the mspConfigPath (for a peer node) or the LocalMSPDir (for an ordering node) to point to the MSP folder that was generated in the previous step using the Fabric CA client. Now that the peer or ordering node is configured to use HSM, when you start the node it will be able sign and endorse transactions with the private key protected by the HSM.