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@ -21,7 +21,7 @@ thinks Alice's key is. When Alice scans the QR code, she will ensure that the
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keys match what is expected, in which case, she relays this information to Bob,
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keys match what is expected, in which case, she relays this information to Bob,
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who can then tell his device that the keys match.
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who can then tell his device that the keys match.
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Example flow:
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### Example flow
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1. Alice and Bob meet in person, and want to verify each other's keys.
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1. Alice and Bob meet in person, and want to verify each other's keys.
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2. Alice requests a key verification through her device by sending an
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2. Alice requests a key verification through her device by sending an
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@ -99,6 +99,64 @@ for her, as this is done over a trusted medium. Bob verifies Alice's key
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because Alice can trust the QR code that Bob displays, and Bob can trust Alice
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because Alice can trust the QR code that Bob displays, and Bob can trust Alice
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to tell him the result of the verification.
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to tell him the result of the verification.
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#### Self-verification
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QR codes can also be used by a user to verify their own devices. These examples
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shows Alice verifying two devices, one of them (Osborne2) having cross-signing
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already set up, and the other one (Dynabook) having just logged in.
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In the first example, Osborne2 scans Dynabook:
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1. Alice logs into her new Dynabook and wants other users to be able to trust
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it via cross-signing, and to trust other devices via cross-signing.
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2. Dynabook retrieves Alice's public cross-signing key from the server, and
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displays a QR code that encodes:
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- Alice's user ID,
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- Dynabook's device key,
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- what it thinks Alice's master key is, as the `other_user_key` parameter, and
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- a random shared secret.
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Note that in this case, the QR code does not include Alice's master key in a
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`key_<key_id>` parameter, since Dynabook does not know whether it is trusted
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or not.
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3. Osborne2 scans the QR code displayed by Dynabook. At this point, Osborne2
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knows Dynabook's device key and can sign it with the self-signing key and
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upload the signature, and can trust Dynabook for sending secrets via SSSS.
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It also knows that Dynabook has the correct cross-signing key.
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4. Osborne2 tells Alice that the scan was successful, and sends the
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`reciprocate` message containing the shared secret.
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5. Upon receipt of the `reciprocate` message, Dynabook (after checking the
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shared secret) confirms with Alice that she successfully scanned the QR
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code.
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6. Alice confirms.
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7. Dynabook now knows that it can trust Alice's cross-signing keys that it
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fetched from the server.
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In the second example, Dynabook scans Osborne2:
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1. Alice logs into her new Dynabook and wants other users to be able to trust
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it via cross-signing, and to trust other devices via cross-signing.
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2. Osborne2 notices that Dynabook is a new device. Osborne2 fetches Dynabook's
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identity key and displays a QR code that encodes:
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- Alice's user ID,
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- Osborne2's device key (optional),
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- what it thinks Dynabook's key is, as `other_device_key`,
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- Alice's master key, both as `key_<key_id>` and `other_user_key`
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parameters, and
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- a random shared secret.
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3. Dynabook scans the QR code shown by Osborne2. At this point, Dynabook knows
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Alice's cross-signing key, and so it can trust it to sign other devices. It
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also knows that Osborne2 as the correct key for it.
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4. Dynabook tells Alice that the scan is successful, and sends the
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`reciprocate` message containing the shared secret.
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5. Upon receipt of the `reciprocate` message, Osborne2 (after checking the
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shared secret) confirms with Alice that she successfully scanned the QR
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code.
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6. Alice confirms.
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7. Osborne2 now knows that it has the correct device key for Dynabook, and can
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sign it with the self-signing key and upload the signature. Osborne2 can
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also trust Dynabook for sending secrets via SSSS.
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### Verification methods
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### Verification methods
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This proposal defines three verification methods that can be used in
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This proposal defines three verification methods that can be used in
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@ -129,12 +187,18 @@ the form:
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- `request`: is the event ID of the associated verification request event.
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- `request`: is the event ID of the associated verification request event.
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- `key_<key_id>`: each key that the user wants verified will have an entry of
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- `key_<key_id>`: each key that the user wants verified will have an entry of
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this form, where the value is the key in unpadded base64. The QR code should
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this form, where the value is the key in unpadded base64. The QR code should
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contain at least the user's master cross-signing key.
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contain at least the user's master cross-signing key. In the case where a
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device does not have a cross-signing key (as in the case where a user logs in
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to a new device, and is verifying against another device), thin the QR code
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should contain at least the device's key.
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- `secret`: is a random single-use shared secret in unpadded base64. It must be
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- `secret`: is a random single-use shared secret in unpadded base64. It must be
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at least 256-bits long (43 characters when base64-encoded).
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at least 256-bits long (43 characters when base64-encoded).
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- `other_user_key`: the other user's master cross-signing key, in unpadded
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- `other_user_key`: the other user's master cross-signing key, in unpadded
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base64. In other words, if Alice is displaying the QR code, this would be
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base64. In other words, if Alice is displaying the QR code, this would be
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the copy of Bob's master cross-signing key that Alice has.
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the copy of Bob's master cross-signing key that Alice has.
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- `other_device_key`: the other device's key, in unpadded base64. This is only
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needed when a user is verifying their own devices, where the other device has
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not yet been signed with the cross-signing key.
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The QR codes to be displayed and scanned, which are not a part of an in-person
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The QR codes to be displayed and scanned, which are not a part of an in-person
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verification (for example, for printing on business cards), will encode URLs of
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verification (for example, for printing on business cards), will encode URLs of
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Hubert Chathi
5 years ago