Key Transparency provides a lookup service for generic records and a public, tamper-proof audit log of all record changes. While being publicly auditable, individual records are only revealed in response to queries for specific IDs.
Key Transparency can be used as a public key discovery service to authenticate users and provides a mechanism to keep the service accountable.
Key Transparency empowers account owners to reliably see what public keys have been associated with their account, and it can be used by senders to see how long an account has been active and stable before trusting it.
Key Transparency can add verifiable and user-friendly auditing to any scenario that involves authenticating users with public keys, including Universal Second Factor Security Keys and end-to-end encryption.
Key Transparency is a work-in-progress with the following milestones under development.
- Install Go 1.13.
GO111MODULE=on go get github.com/google/keytransparency/cmd/keytransparency-client
The Key Transparency server publishes a separate set of public keys for each directory that it hosts. By hosting multiple directories, a single domain can host directories for multiple apps or customers. A standardized pattern for discovering domains and directories is a TODO in issue #389.
Within a directory the server uses the following public keys to sign its responses:
log.public_key
signs the top-most Merkle tree root, covering the ordered list of map roots.map.public_key
signs each snapshot of the key-value database in the form of a sparse Merkle tree.vrf.der
signs outputs of the Verifiable Random Function which obscures the key values in the key-value database.
A directory's public keys can be retrieved over HTTPS/JSON with curl
or over gRPC with grpcurl.
The sandboxserver has been initialized with a domain named default
.
$ curl -s https://sandbox.keytransparency.dev/v1/directories/default | json_pp
$ grpcurl -d '{"directory_id": "default"}' sandbox.keytransparency.dev:443 google.keytransparency.v1.KeyTransparency/GetDirectory
Show output
{
"directory_id" : "default",
"log" : {
"hash_algorithm" : "SHA256",
"hash_strategy" : "RFC6962_SHA256",
"public_key" : {
"der" : "MFkwEwYHKoZIzj0CAQYIKoZIzj0DAQcDQgAEXPi4Ut3cRY3OCXWvcSnE/sk6tbDEgBeZapfEy/BIKfsMbj3hPLG+WEjzh1IP2TDirc9GpQ+r9HVGR81KqRpbjw=="
},
"signature_algorithm" : "ECDSA",
"tree_id" : "4565568921879890247",
"tree_type" : "PREORDERED_LOG"
},
"map" : {
"hash_algorithm" : "SHA256",
"hash_strategy" : "CONIKS_SHA256",
"public_key" : {
"der" : "MFkwEwYHKoZIzj0CAQYIKoZIzj0DAQcDQgAEgX6ITeFrqLmclqH+3XVhbaEeJO37vy1dZYRFxpKScERdeeu3XRirJszc5KJgaZs0LdvJqOccfNc2gJfInLGIuA=="
},
"signature_algorithm" : "ECDSA",
"tree_id" : "5601540825264769688",
"tree_type" : "MAP"
},
"max_interval" : "60s",
"min_interval" : "1s",
"vrf" : {
"der" : "MFkwEwYHKoZIzj0CAQYIKoZIzj0DAQcDQgAEvuqCkY9rM/jq/8hAoQn2PClvlNvVeV0MSUqzc67q6W+MzY/YZKmPLY5t/n/VUEqeSgwU+/sXgER3trsL6nZu+A=="
}
}
Every update to a user record in key transparency must be signed by an authorized-key
.
Update signatures are saved in the Merkle tree data structure, producing a record of who made each change to a user's account, allowing products to distinguish between changes signed by a user key, the provider's key, or a reset-provider's key.
Each account has an updatable policy that lists the current set of authorized public keys that are allowed to make updates to the user's record.
To create an initial set of update signing keys, run the authorized-keys create-keyset
command.
Keys will be saved in a .keyset
file in the current working directory.
$ PASSWORD=[[YOUR-KEYSET-PASSWORD]]
$ keytransparency-client authorized-keys create-keyset --password=${PASSWORD}
Show output
$ PASSWORD=[[YOUR-KEYSET-PASSWORD]]
$ keytransparency-client authorized-keys create-keyset --password=${PASSWORD}
$ keytransparency-client authorized-keys list-keyset --password=${PASSWORD}
My Authorized Keys:
primary_key_id:17445529 key_info:<type_url:"type.googleapis.com/google.crypto.tink.EcdsaPrivateKey" status:ENABLED key_id:17445529 output_prefix_type:TINK >
Any number of protocols may be used to prove to the server that a client owns a userID. The sandbox server supports a fake authentication string and OAuth.
Create or fetch the public key for your specific application.
openssl genpkey -algorithm X25519 -out xkey.pem
openssl pkey -in xkey.pem -pubout
-----BEGIN PUBLIC KEY-----
MCowBQYDK2VuAyEAtCAsIMDyVUUooA5yhgRefcEr7edVOmyNCUaN1LCYl3s=
-----END PUBLIC KEY-----
keytransparency-client post [email protected] \
--kt-url sandbox.keytransparency.dev:443 \
--fake-auth-userid [email protected] \
--password=${PASSWORD} \
--verbose \
--logtostderr \
--data='MCowBQYDK2VuAyEAtCAsIMDyVUUooA5yhgRefcEr7edVOmyNCUaN1LCYl3s=' #Your public key in base64
keytransparency-client get <email> --kt-url sandbox.keytransparency.dev:443 --verbose
β Commitment verified.
β VRF verified.
β Sparse tree proof verified.
β Signed Map Head signature verified.
CT β STH signature verified.
CT β Consistency proof verified.
CT New trusted STH: 2016-09-12 15:31:19.547 -0700 PDT
CT β SCT signature verified. Saving SCT for future inclusion proof verification.
β Signed Map Head CT inclusion proof verified.
keys:<key:"app1" value:"test" >
keytransparency-client history [email protected] --kt-url sandbox.keytransparency.dev:443
Revision |Timestamp |Profile
4 |Mon Sep 12 22:23:54 UTC 2016 |keys:<key:"app1" value:"test" >
Prerequisites
- GoLang
- OpenSSL
- Docker
- Docker Engine 1.17.6+
docker version -f '{{.Server.APIVersion}}'
- Docker Compose 1.11.0+
docker-compose --version
- Docker Engine 1.17.6+
-
Run the deployment script
# Download the latest version of keytransparency git clone https://github.com/google/keytransparency.git cd keytransparency # Run the deployment script for local environment ./scripts/deploy_local.sh deploy
-
Check Docker's running containers
docker container ls
You should see 8 new running containers:
- gcr.io/key-transparency/keytransparency-monitor
- gcr.io/key-transparency/keytransparency-sequencer
- gcr.io/trillian-opensource-ci/map_server
- gcr.io/trillian-opensource-ci/log_signer
- gcr.io/trillian-opensource-ci/log_server
- gcr.io/key-transparency/keytransparency-server
- gcr.io/trillian-opensource-ci/db_server
- prom/prometheus
-
Watch it Run
The script will remove all the containers and their networks.
# Run the script to undeploy
./scripts/deploy_local.sh undeploy
Key Transparency and its Trillian backend use a MySQL database, which must be setup in order for the Key Transparency tests to work.
docker-compose up -d db
will launch the database in the background.
The directory structure of Key Transparency is as follows:
- cmd: binaries
- keytransparency-client: Key Transparency CLI client.
- keytransparency-sequencer: Key Transparency backend.
- keytransparency-server: Key Transparency frontend.
- core: main library source code. Core libraries do not import impl.
- adminserver: private API for creating new directories.
- api: gRPC API definitions.
- crypto: verifiable random function and commitment implementations.
- directory: interface for retrieving directory info from storage.
- keyserver: keyserver implementation.
- mutator: "smart contract" implementation.
- sequencer: mutation executor.
- deploy: deployment configs:
- docker: init helper.
- kubernetes: kube deploy configs.
- prometheus: monitoring docker module.
- docs: documentation.
- impl: environment specific modules:
- authentication: authentication policy grpc interceptor.
- authorization: OAuth and fake auth grpc interceptor.
- integration: environment specific integration tests.
- mysql: mysql implementations of storage modules.
- scripts: scripts
- deploy: deploy to Google Compute Engine.
Key Transparency would not have been possible without a whole host of collaborators including researchers, interns, and open source contributors.
Key Transparency was inspired by CONIKS and Certificate Transparency.
- Google Security Blog Post
- CONIKS Project
- Why Making Johnny's Key Management Transparent is So Challenging
- Google Launches Key Transparency While a Trade-Off in WhatsApp Is Called a Backdoor
- On Ghost Users and Messaging Backdoors
- Verifiable Random Functions
- Message Layer Security
- OpenPGP Email Summit 2019