Data transformation with code examples
Note
Transform secrets engine requires Vault Enterprise Advanced Data Protection (ADP) license.
The Transform Secrets Engine tutorial introduced the basic working of the Transform secrets engine using Vault CLI, API, and UI. This tutorial takes it to the next step and go through code examples to show how an application may leverage the Transform secrets engine.
Prerequisites
This lab was tested on macOS using an x86_64 based processor. If you are running macOS on an Apple silicon-based processor, use a x86_64 based Linux virtual machine in your preferred cloud provider.
Before You Proceed
If you are new to the Transform secrets engine, be sure to go through the Transform Secrets Engine tutorial first. This tutorial assumes that you have a basic knowledge of configuring the Transform secrets engine.
Scenario introduction
The example application is a simple RESTful payment service that receives and stores payment data for later processing. The API has a single route that accepts an HTTP POST request, and it uses PostgreSQL for data storage.
Security requirements
The security requirements for the API are:
- Credit card details must be stored in the database in an encrypted format at rest
- It must be possible to infer the bank and type of a card number without decrypting it
The first requirement is relatively trivial to solve using Vault and the Transit Secrets Engine. Transit secrets can be used as encryption as service to encrypt the credit card details before they are written to the database.
To satisfy the second requirement, you need to be able to query the type of the
card and the bank which issued it. You can get this data from the card number as
not all the data in a credit card number is unique. A credit card number is
composed of three parts: the Issuer Number,
the Account Number
and the
Checksum.
Issuer Number
relates to the type of the card (first digit), and the issuer's
code is the information that you would like to query to satisfy the second
requirement.
Account Number
is the unique identifier assigned to the holder of the card.
Checksum
is not a secret part of the card number; instead, it is designed for
quick error checking. The checksum is generated from the card number; before
processing the checksum is regenerated using the Luhn algorithm, if the given
and the computed checksums differ, then the card number has been entered
incorrectly.
To be able to query the card issuer you realistically have two options:
- Partially encrypt the card number in the database
- Store metadata for the card along with the encrypted values
To implement this requirement in code, the developers have the responsibility for managing the complexity of partially encrypting the credit card data, and the information security needs to worry about the correct implementation.
Integrate with Transform secrets engine
Vault's Transform Secrets Engine can simplify the process while still satisfying the second requirement. Transform secrets engine allows you to encrypt data while preserving formatting or to partially encrypt data based on a user-configurable formula. The benefits of this are that the information security team can centrally manage the definition for the encryption process, and the developers don't need to worry about the implementation, they can use the Transform API to encrypt the card numbers.
There are three options to interact with the Vault API:
- Use one of the Client libraries
- Generate your client from the OpenAPI v3 specifications
- Manually interact with the HTTP API
This tutorial follows the third option as this demonstrates the simplicity of interacting with Vault's API. In our scenario, the application only needs to encode data and not manage the configuration for Transform; to do this, it only needs to interact with the Encode API endpoint.
Clone the code example repository
Clone the demo assets from the demo-vault GitHub repository to perform the steps described in this tutorial.
$ git clone https://github.com/nicholasjackson/demo-vault
Change the working directory to
demo-vault/transform
.$ cd demo-vault/transform
Review the code
The transform-engine-go
directory contains the code example written in Go, and
the transform-engine-java
directory contains a Java code example.
$ tree -d
.
├── blueprint
│  ├── docs
│  │  └── images
│  ├── files
│  └── secrets
├── transform-engine-go
│  ├── bin
│  ├── data
│  ├── handlers
│  └── vault
└── transform-engine-java
├── gradle
│  └── wrapper
└── src
└── main
├── java
│  └── payments
│  ├── model
│  ├── repository
│  └── vault
└── resources
21 directories
To send a credit card number to Vault for encryption through the Transform secrets engine, the application must:
- Create a request payload
- Invoke the Vault API
- Parse the response
Create a request payload
The first thing that needs to be done is to construct a byte array with a JSON formatted string for the payload. In both Go and Java common libraries easily handle this function.
- Go: See line 56-57 of
transform-engine-go/vault/vault.go
. - Java: See line 43-48 of
transform-engine-java/src/main/java/payments/vault/VaultClient.java
.
Invoke the Vault API
Once the request body is set to the JSON data payload, you can make the request and retrieve the response from the Vault server.
- Go: See line 60-72 of
transform-engine-go/vault/vault.go
. - Java: See line 51-62 of
transform-engine-java/src/main/java/payments/vault/VaultClient.java
.
Parse the response
To read the JSON response from the Vault API, you can parse the body from the HTTP client into a simple structure. The encoded data can now be passed to another function which will store it in the database.
- Go: See line 75-79 of
transform-engine-go/vault/vault.go
. - Java: See line 65-67 of
transform-engine-java/src/main/java/payments/vault/VaultClient.java
.
Client code example
transform-engine-go/vault/vault.go
package vault
import (
"bytes"
"encoding/json"
"fmt"
"net/http"
)
type Client struct {
token string
uri string
}
type TokenRequest struct {
Value string `json:"value"`
}
type TokenResponse struct {
Data TokenReponseData `json:"data"`
}
type TokenReponseData struct {
EncodedValue string `json:"encoded_value"`
}
// NewClient creates a new Vault client
func NewClient(token, serverURI string) *Client {
return &Client{token, serverURI}
}
// IsOK returns true if Vault is unsealed and can accept requests
func (c *Client) IsOK() bool {
url := fmt.Sprintf("%s/v1/sys/health", c.uri)
r, _ := http.NewRequest(http.MethodGet, url, nil)
r.Header.Add("X-Vault-Token", c.token)
resp, err := http.DefaultClient.Do(r)
if err != nil {
return false
}
defer resp.Body.Close()
if resp.StatusCode != http.StatusOK {
return false
}
return true
}
// TokenizeCCNumber uses the Vault API to tokenize the given string
func (c *Client) TokenizeCCNumber(cc string) (string, error) {
// create the JSON request as a byte array
req := TokenRequest{Value: cc}
data, _ := json.Marshal(req)
// call the api
url := fmt.Sprintf("%s/v1/transform/encode/payments", c.uri)
r, _ := http.NewRequest(http.MethodPost, url, bytes.NewReader(data))
r.Header.Add("X-Vault-Token", c.token)
resp, err := http.DefaultClient.Do(r)
if err != nil {
return "", err
}
defer resp.Body.Close()
if resp.StatusCode != http.StatusOK {
return "", fmt.Errorf("Vault returned reponse code %d, expected status code 200", resp.StatusCode)
}
// process the response
tr := &TokenResponse{}
err = json.NewDecoder(resp.Body).Decode(tr)
if err != nil {
return "", err
}
return tr.Data.EncodedValue, nil
}
Start the sample application
The demo uses Shipyard to start a Vault server and example application in Docker on your local machine.
Run the demo.
$ shipyard run ./blueprint
The output may look like:
Running configuration from: ./blueprint
[INFO] Creating Network: ref=local
[INFO] Creating Documentation: ref=docs
[INFO] Creating Container: ref=payments_java
[INFO] Creating Container: ref=payments_go
[INFO] Creating Container: ref=vault
[INFO] Creating Container: ref=postgres
The Vault server, Postgres server, and example applications are also accessible from your terminal at the following locations:
Component | Address |
---|---|
Vault | localhost:8200 |
PostgreSQL | localhost:5432 - Database: payments - User: root - Password: password |
Java example application | localhost:9092 |
Go example application | localhost:9091 |
Validation
You can verify that the Docker containers are running.
$ docker ps -a CONTAINER ID IMAGE ...snip... NAMES c60a35ee6601 registry.shipyard.run/terminal-server:v0.1.0 ...snip... terminal.docs.shipyard.run b210301ddb17 postgres:11.6 ...snip... postgres.container.shipyard.run 44cc6051c6ac nicholasjackson/transform-demo:java ...snip... payments-java.container.shipyard.run cc92ad0c2d26 registry.shipyard.run/docs:v0.1.0 ...snip... docs.docs.shipyard.run 2e37ff75de45 hashicorp/vault-enterprise:1.4.0-rc1_ent ...snip... vault.container.shipyard.run 5af3a69ca41b nicholasjackson/transform-demo:go ...snip... payments-go.container.shipyard.run
Set the
VAULT_ADDR
environment variable value tohttp://localhost:8200
.$ export VAULT_ADDR="http://localhost:8200"
Check and see if the Transform secrets engine is configured.
$ vault secrets list
If the output does NOT list
transform/
, execute the/blueprint/files/setup_transform.sh
script.$ ./blueprint/files/setup_transform.sh Success! Enabled the transform secrets engine at: transform/ Success! Data written to: transform/role/payments Success! Data written to: transform/transformation/ccn-fpe Success! Data written to: transform/template/ccn Success! Data written to: transform/alphabet/numerics
This sets up the Transform secrets engine to take the credit card number and encrypt it based on the transformation rule defined by the
cnn
template.
Test the application
Both the Java and the Go code are running, so you can use curl
to test either
application.
Send a credit card number to the Go application at localhost:9091
.
$ curl --header "content-type: application/json" \
--data '{"card_number": "1234-1234-1234-1234"}' \
localhost:9091
Output:
{"transaction_id": 1}
You can send multiple requests.
To see the encrypted value for this transaction you can query the orders table on the database.
$ PGPASSWORD=password psql -h localhost -p 5432 -U root -d payments -c 'SELECT * from orders;'
id | card_number | created_at | updated_at | deleted_at
----+---------------------+----------------------------+----------------------------+------------
1 | 1234-1219-2537-6134 | 2021-12-22 00:18:28.566104 | 2021-12-22 00:18:28.566155 |
(1 rows)
The database contains the encrypted card number.
Real-world impact of partially encrypting data
You may wonder how it reduces the security of the encrypted card number by only encrypting the account number and CV2 data. In real terms, it probably does not make a difference.
A number containing 16 digits has a possibility of 16^16 combinations, including the CV2 number. This roughly equates to 10 quintillion different permutations.
If you only store 10 digits of the card number plus the CV2, this is 10^13, or about 10 trillion combinations. Since the first 6 digits of a card number are the issuer and card type, there are not 1 million different issuers. Let's say there are 10,000, storing the full 16 digits would give you roughly 100 quadrillion combinations. In both cases, we need to remove the checksum, so we get 10 quadrillion combinations if you encrypt the account number and 1 trillion if you do not.
Not encrypting the issuer means someone can make fewer guesses to determine the number; however, the attacker still need to make 1 trillion guesses. Assuming someone managed to obtain your database containing partially encrypted card numbers. If you had an average API request time of 100 milliseconds to accept or reject a payment, it would take about 190258 years for someone to brute force a payment. Even if the attacker was running parallel attacks, the odds are stacked heavily against them.
Clean up
When you are done exploring, stop and remove the Docker containers.
$ shipyard destroy
Unset the
VAULT_ADDR
environment variable.$ unset VAULT_ADDR
Summary
In this tutorial, you have learned how the Transform secrets engine can partially encrypt credit card numbers at rest while preserving the formatting and ability to query the card issuer. This example only covers one of the possibilities for the Transform secrets engine.