© 2021 PathCheck Foundation
Authors: Justin Dossey and Vitor Pamplona
Status: DRAFT
Date: Feb 26, 2021
The PathCheck Verifiable QR Specification is an extension of the W3C Verifiable Credentials Data Model expressed as a URI for the purposes of providing a standardized format of describing Verifiable Credentials within the constraints of the QR specification. This document describes the protocol to create Verifiable Credentials directly as URIs for space-limited alphanumeric-required applications, such as QR Codes, NFC tags and SMS Messages.
For the purposes of brevity, this document refers to the following terms which are defined as follows:
- HOLDER: The HOLDER is the party who is receiving the credential from the ISSUER
- ISSUER: The ISSUER is the party who delivers the credential to a HOLDER.
- VERIFIER: The VERIFIER is the party who reads and verifies the signature of credential.
All verifiable credentials follow a URI Schema that starts with CRED: and a message with:
- the type of the payload, one of the options here
- the version of the payload
- the payload itself
- the keyId, a reference to the public key
- and a cryptographic signature of the payload
The URI is simply organized in a colon-separated string as:
cred:type:version:signature:keyId:payload
The type field declares the payload type (e.g. COUPON, PASSKEY, BADGE or STATUS) and the version is a ever-incrementing NUMERIC field defining the version of the type of payload. The payload block contains the information itself in a pre-defined format. The cryptographic signature is a DER signature in Base32 form, calculated using the private key of the ISSUER.
Payload specifications define the syntax and semantic meaning of the fields as well as their order in the serialization process. All payload type specifications must be submitted as pull requests to the payload folder in this repository. The general payload encoding is described in sections below.
The example below is a valid credential
CRED:COUPON:1:GBDAEIIA42QDQ5BDUUXVMSQ4VIMMA7RETIZSXB573OL24M4L67LYB24CZYVQEIIA2EZ5W2QXLR7LUSLQW
6MLAFV3N7OTT3BDAZCNCRMYBMUYC6WMXMNQ:KEYS.PATHCHECK.ORG:1/5000/SOMERVILLE%20MA%20US/1A/%3E65
Main Benefits of this protocol are
- Extremely small QR Sizes in Alphanumeric (~140 bytes for the average payload)
- Data minimalism by requirements of the application
- Allows for the use of feature phones and low energy chips as scanners.
- It is ideal size and character set to use on SMS, SmartCards and NFC tags
- It's readable by any text file
- Freedom of payload specification
- Any new payload can be described and approved in minutes
- Business logic is part of the payload definition as opposed to hidden
- Freedom of cryptographic tools to sign for the packages.
- RSA, ECDSA, JWTs and other signature models are supported
- Protocol guarantees easily accessible Public Keys by design
- Public Key files describe the algorithms being used by the issuer
- Composability of QRs enable privacy and selective disclosure
- The hash of one QR can be used in another, building a signed chain of QRs
- Domain-based trust model
- If users trust
cdc.gov, they will also trustkeys.cdc.gov - There is no need for a centralized issuing authority
- No need to trust app developers or private lists of approved issuers
- If users trust
- Enhanced Security
- The signed payload is cryptographically protected and thus impossible to tamper
- Freedom of binding
- There's no requirement to bind the credential to a user or proxy models to a user
- Electronic binding with individual wallets is possible when the credential is loaded on an app.
- Extremely private
- The only information online is a public key.
- The protocol does not require centralized servers.
- No exposure to government, no blockchain, no private companies, no trusted lists
- There's no need to manage did's or other private issuing systems
- Easy to backup
- A simple picture or a paper copy serves as a backup of the code
- Negligible cost per user on all activities
- Generalizable:
- Any record/payload can be created and signed in the same format
- Free as in beer
- The entire specification is licensed under MIT License
Disadvantages are:
- Traceability of the QR Codes is possible by colluding verifiers
- Solutions include generating multiple salted QR Codes to be given away as opposed to one code that is read everywhere
- Chance of losing the data if the QR is lost
- The issuer might have a copy of the event record, but it is not a requirement
- Apps and pictures of the card can serve as a backup
- No realtime revocation of cards/credentials
- Issuer removes the public key from the domain, invalidating all credentials
- The verifier app needs to wait for the next issuer list (or revocation list) update
- The information in the QR itself is not encrypted by design
- Payload specifications can include password-protected fields
- Fields are case insensitive by design
- Payloads are encoraged to encode each field in Base32 if case sensitivity is required
Data to be used for signing and hashes is uppercased, percent encoded and then serialized with a slash-separated (/) string in the specified order the payload spec describes. Cryptographic signatures and hashes MUST be calculated against encoded versions of the underlying payload, as they appear in the final URI. This permits signature verification before any decoding.
Cryptographic tools must sign and verify a SHA256 hash of the UTF-8 byte array of the uppercased, percent-encoded, slash-separated payload. The resulting signature in Distinguished Encoding Rules (DER - as per ASN.1 encoding rules defined in the ITU-T X.690, 2002, specification) format must be then encoded in Base32URL, a Base32 (RFC4648) without added padding (=). The removal of the padding is due to the fact that = is not a supported character on both URI and alphanumeric QR codes.
Public Keys can be generated using any cryptographic method. Verifiers must implement the cryptographic protocol included in the Public Key PEM File. Any verifier must be able to download a public key of the signer and maintain an indexed local key-value store of approved public keys in PEM format.
The keyID of the public key can be:
- a FQDN to a DNS TXT Record containing the key for download.
- a database and key ID to facilitate trusted lists of issuers.
- a URL address to download keys from.
Before validating a signature, verifiers must compute the SHA256 of the payload (as is from the URI) and decode the Base32URL signature.
When the key is placed into DNS TXT records, issuers need to convert their PEM files to remove:
- -----BEGIN PUBLIC KEY-----
- -----END PUBLIC KEY-----
- new line chars or
\n, as new line is not a valid character for TXT Records.
Issuers should replace \n with \\n. Verifiers must convert back from \\n to \n
Make sure the remaining PEM includes an Object Identifier (OID) in the base64 format.
For example, the keyId keys.pathcheck.org needs a DNS Lookup and has: ($ dig -t txt keys.pathcheck.org):
MFYwEAYHKoZIzj0CAQYFK4EEAAoDQgAE6DeIun4EgMBLUmbtjQw7DilMJ82YIvOR\\n2jz/IK0R/F7/zXY1z+gqvFXfDcJqR5clbAYlO9lHmvb4lsPLZHjugQ==
Verifiers must then return the content to it's original format by replacing \\n by the new line character.
The PathCheck Foundation will keep a list of trusted issuers on this repository. References to this list use the period character (.) to separate the id of the public key from the name of the database/folder in this order: id.folder
As an example, the keyId 1a9.pcf refers to the database at the PCF folder and the file name in that database is 1a9.pem. Each ID must contain the raw PEM file of the issuer.
This keyId is a direct URL reference with the raw PEM file of the public key inside the issuer's website, but without the URL Schema component (https://). Host must result the link in uppercase format. Verifiers must add https:// to the URL, download and parse the key.
For example, the keyId www.pathcheck.org/hubfs/pub downloads a file that contains the public key of a ECDSA keypair.
The payload should be represented as a series of uppercased, percent-encoded values delimited by the slash (/) character. The serialization order is defined in each type of payload specification and key names are omitted. Percent encoding of the upcased payload is used to address QR code character set limitations, while supporting the URI spec.
This document will use the following terms to define data types.
- NUMERIC: The NUMERIC data type is a sequence of integers between 0 and 99999999, inclusive.
- STRING: The STRING data type is a sequence of UTF-8, NFC Normalized characters, up to 255 bytes after encoding.
- HASH: The HASH data type is a sequence of 52 alphanumeric characters containing a base32-encoded hash.
- SIGNATUREBASE32: The SIGNATUREBASE32 data type is a sequence of up-to-102 alphanumeric characters containing a base32url-encoded digest.
- DATE: a date, in ISO 8601 (YYYYMMDD) Basic Notation. Example:
20200201is 1 February, 2020. - TIMESTAMP: a date time, in seconds from Epoch. Example:
1607745600is2020-12-12T12:00:00+08:00. - SHORTSTRING: a sequence of US-ASCII characters which is limited to 8 bytes in length.
- SHORTNUMERIC: a NUMERIC with a maximum value of 9.
- PHONE: a E.164 formatted phone number as string. US-ASCII, maximum 15 characters.
Payload Values are encoded per the standard using Percent Encoding. Note that all characters not present in the Alphanumeric QR scheme must be percent encoded. The Alphanumeric QR Code type imposes significant limitations on the data which can be represented, but allows for the generation of a lower-resolution QR code. Smaller QR codes will be scannable with older hardware and lower-resolution scanners, and smaller data sets allow for more aggressive error correction. This promotes usability and equity.
All fields (keys as well as values) are case-insensitive in both JSON and URI format. When performing operations such as hash comparison, a case-insensitive comparison function MUST be used. Additionally, the Alphanumeric QR Code character set does not include lowercase characters, so implementations MUST encode output in uppercase only.
For clarity and ease of reading, examples in this document are given in mixed case.
Unfilled fields MUST be submitted as empty between slash (/) characters. Only add empty delimiters if there is data after. Given fields A (required), B (optional), C (optional) the implementation MUST follow the following example:
| A | B | C | Output |
|---|---|---|---|
1 |
1 |
||
1 |
2 |
1/2 |
|
1 |
2 |
3 |
1/2/3 |
1 |
3 |
1//3 |
All characters not present in the Alphanumeric QR scheme must be percent encoded when presented in data fields. RFC 2936 requires percent encoding a number of characters, but some of the characters not required to be encoded are not included in the Alphanumeric QR character set. As a result, those characters MUST also be percent encoded.
Show me which characters need encoding
The columns in the table below indicate encoding requirements for each representable character. Any non-listed characters MUST be percent-encoded. The "URI Requires" column indicates whether the URI format rules (RFC 2396) requires encoding the character. The "Alphanumeric QR Requires" column indicates whether the character is missing from the Alphanumeric QR character set (thus, requiring encoding). The "Must Encode?" column indicates whether this specification requires percent-encoding of the character. The "Output Value" column indicates the expected output from processing the listed character.
| Character | URI Requires | Alphanumeric QR Requires | Must Encode? | Output Value |
|---|---|---|---|---|
|
YES | NO | YES | %20 |
! |
YES | YES | YES | %21 |
" |
YES | YES | YES | %22 |
# |
YES | YES | YES | %23 |
$ |
YES | NO | YES | %24 |
% |
YES | NO | YES | %25 |
& |
YES | YES | YES | %26 |
' |
YES | YES | YES | %27 |
( |
YES | YES | YES | %28 |
) |
YES | YES | YES | %29 |
* |
YES | NO | YES | %2A |
+ |
YES | NO | YES | %2B |
, |
YES | YES | YES | %2C |
- |
YES | NO | YES | %2D |
. |
YES | NO | YES | %2E |
/ |
YES | NO | YES | %2F |
0 |
NO | NO | NO | 0 |
1 |
NO | NO | NO | 1 |
2 |
NO | NO | NO | 2 |
3 |
NO | NO | NO | 3 |
4 |
NO | NO | NO | 4 |
5 |
NO | NO | NO | 5 |
6 |
NO | NO | NO | 6 |
7 |
NO | NO | NO | 7 |
8 |
NO | NO | NO | 8 |
9 |
NO | NO | NO | 9 |
: |
YES | NO | YES | %3A |
; |
YES | YES | YES | %3B |
< |
YES | YES | YES | %3C |
= |
YES | YES | YES | %3D |
> |
YES | YES | YES | %3E |
? |
YES | YES | YES | %3F |
@ |
YES | YES | YES | %40 |
A |
NO | NO | NO | A |
B |
NO | NO | NO | B |
C |
NO | NO | NO | C |
D |
NO | NO | NO | D |
E |
NO | NO | NO | E |
F |
NO | NO | NO | F |
G |
NO | NO | NO | G |
H |
NO | NO | NO | H |
I |
NO | NO | NO | I |
J |
NO | NO | NO | J |
K |
NO | NO | NO | K |
L |
NO | NO | NO | L |
M |
NO | NO | NO | M |
N |
NO | NO | NO | N |
O |
NO | NO | NO | O |
P |
NO | NO | NO | P |
Q |
NO | NO | NO | Q |
R |
NO | NO | NO | R |
S |
NO | NO | NO | S |
T |
NO | NO | NO | T |
U |
NO | NO | NO | U |
V |
NO | NO | NO | V |
W |
NO | NO | NO | W |
X |
NO | NO | NO | X |
Y |
NO | NO | NO | Y |
Z |
NO | NO | NO | Z |
[ |
YES | YES | YES | %5B |
\ |
YES | YES | YES | %5C |
] |
YES | YES | YES | %5D |
^ |
YES | YES | YES | %5E |
_ |
NO | YES | YES | %5F |
{ |
YES | YES | YES | %7C |
} |
YES | YES | YES | %7D |
~ |
NO | YES | YES | %7E |
To sign and assemble URI:
$payload = [$number, $total, $city, $phase, $indicator];
for ($i = 0; $i < length($payload); $i += 1) do
$upcasedValue = upcase($payload[$i]);
$encodedValue = percentEncode($payload[$i]);
$payload[$i] = $encodedValue;
end
$payloadString = join('/', $payload);
$payloadHash = sha256($payloadString.to('utf-8'));
$keyId = $DNS_TXT_FQDN || $URL_TO_PEM_FILE || $REF_TO_DATABASE
$signatureDER = ecdsaSign($payloadHash);
$signature = b32toB32URL(b32encode($signatureDER))
$base = join(':', ["cred", $type, $version, $signature, $keyId]);
$upcasedBase = upcase($base);
$uri = $upcasedBase + ":" + $payloadString;To parse and verify a URI:
[$schema, $type, $version, $signature, $keyId, $payloadString] = qr.split(':')
$payload = $payloadString.split('/')
$publicKeyPem = localDB($keyId) || download($keyId)
$payloadHash = sha256($payloadString.to('utf-8')))
$signatureDER = b32decode(b32URLtoB32($signature))
$valid = ecdsaVerify($signatureDER, $payloadHash, $publicKeyPem)
for ($i = 0; $i < length($payload); $i += 1) do
$payload[$i] = percentDecode($payload[$i]);
endTo remove padding from Base32-encoded strings do:
$base32URL = $base32.replaceAll("=", "");To add padding back to Base32-encoded strings do:
switch ($base32URL.length % 8) {
case 2: $base32 = $base32URL + "======"; break;
case 4: $base32 = $base32URL + "===="; break;
case 5: $base32 = $base32URL + "==="; break;
case 7: $base32 = $base32URL + "="; break;
default: $base32 = $base32URL;
}$gitHubTree = "https://api.github.com/repos/Path-Check/paper-cred/git/trees/"
$rootDir = JSON.parse(fetch($gitHubTree)).tree
$payloadsDir = $rootDir.find(element => element.path === 'payloads');
$payloadDir = JSON.parse(fetch($gitHubTree + $payloadsDir.sha)).tree
$payloadNames = $payloadDir.map(x => x.path.replaceAll(".md","").replaceAll(".",":"));[$id, $database] = $keyId.split('.')
$gitHubTree = "https://api.github.com/repos/Path-Check/paper-cred/git/trees/"
$rootDir = JSON.parse(fetch($gitHubTree + "main")).tree
$keysDir = $rootDir.find(element => element.path === 'keys')
$databasesDir = JSON.parse(fetch($gitHubTree + $keysDir.sha)).tree
$databaseDir = $databasesDir.find(element => element.path === $database)
$pemFiles = JSON.parse(fetch($gitHubTree + $databaseDir.sha)).tree
$pemFile = $pemFiles.find(element => element.path === $id+".pem")
$publicKeyPem = fetch($gitHubTree + $pemFile.sha)- Signer and Verifiers in HTML/JavaScript
- Signer and Verifier Snippet in Python
- Signer and Verifier Snippet in Ruby
- Signer and Verifier Snippet in Java
- Signer and Verifier Snippet in zSh Script
Issues and pull requests are very welcome! :)