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@ -1,28 +1,39 @@
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# Secure Server-side Storage
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# Secure Secret Storage and Sharing
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Some features may require clients to store encrypted data on the server so that
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it can be shared securely between clients. For example, key backups (MSC-1219)
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it can be shared securely between clients. Clients may also wish to securely
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send such data directly to each other. For example, key backups (MSC-1219)
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can store the decryption key for the backups on the server, or cross-signing
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(MSC-1756) can store the signing keys. This proposal presents a standardized
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way of storing such data.
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## Proposal
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A user can have multiple keys used for encrypting data. This allows the user
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to selectively decrypt data. For example, the user could have one key that can
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Secrets are data that clients need to use and thate are sent through or stored
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on the server, but should not be visible to server operators. Secrets are
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plain strings -- if clients need to use more complicated data, it must be
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encoded as a string.
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### Storage
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If secret data is stored on the server, it must be encrypted in order to
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prevent homeserver administrators from being able to read it. A user can have
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multiple keys used for encrypting data. This allows the user to selectively
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decrypt data on clients. For example, the user could have one key that can
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decrypt everything, and another key that can only decrypt their user-signing
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key for cross-signing. Each key has an ID, and a discription of the key is
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stored in the user's `account_data` using the `type` `m.secure_storage.key.[key
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stored in the user's `account_data` using the `type` `m.secret_storage.key.[key
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ID]`. The contents of the account data for the key will include an `algorithm`
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property, which indicates the encryption algorithm used, as well as a `name`
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property, which is a human-readable name. Other properties depend on the
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encryption algorithm, and are described below.
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property, which is a human-readable name. The contents will be signed as
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signed JSON using the user's master cross-signing key. Other properties depend
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on the encryption algorithm, and are described below.
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Encrypted data can be stored using the `account_data` API. The `type` for the
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`account_data` is defined by the feature that uses the data. For example,
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decryption keys for key backups could be stored under the type
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`m.megolm_backup.v1.recovery_key`, or the self-signing key for cross-signing
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could be stored under the type `m.signing_key.self_signing`.
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could be stored under the type `m.cross_signing.self_signing`.
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Data will be stored using using the following format:
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@ -50,16 +61,18 @@ is the same as the key for decrypting the other bits. Maybe a special flag in
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the account data? Or special case backups somehow, say, have clients inspect
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the backup's `auth_data` to see of the key config is the same?
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### Encryption algorithms
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#### Encryption algorithms
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#### `m.secure_storage.v1.curve25519-aes-sha2`
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##### `m.secret_storage.v1.curve25519-aes-sha2`
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The public key is stored in the `pubkey` property of the `m.secret_storage.key.[key
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ID]` `account_data`.
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The data is encrypted and MACed as follows:
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1. Generate an ephemeral curve25519 key, and perform an ECDH with the ephemeral
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key and the backup's public key to generate a shared secret. The public
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half of the ephemeral key, encoded using base64, becomes the `ephemeral`
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property.
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key and the public key to generate a shared secret. The public half of the
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ephemeral key, encoded using base64, becomes the `ephemeral` property.
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2. Using the shared secret, generate 80 bytes by performing an HKDF using
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SHA-256 as the hash, with a salt of 32 bytes of 0, and with the empty string
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as the info. The first 32 bytes are used as the AES key, the next 32 bytes
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@ -74,11 +87,11 @@ The data is encrypted and MACed as follows:
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(The key HKDF, AES, and HMAC steps are the same as what are used for encryption
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in olm and megolm.)
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FIXME: add an example of `m.secure_storage.key.*`, and of encrypted data.
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FIXME: add an example of `m.secret_storage.key.*`, and of encrypted data.
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##### Keys
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###### Keys
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When a user is given a raw key for `m.secure_storage.v1.curve25519-aes-sha2`,
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When a user is given a raw key for `m.secret_storage.v1.curve25519-aes-sha2`,
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it will be encoded as follows (this is the same as what is proposed in MSC1703):
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* prepend the two bytes 0x8b and 0x01 to the key
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@ -92,11 +105,11 @@ it will be encoded as follows (this is the same as what is proposed in MSC1703):
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When decoding a raw key, the process should be reversed, with the exception
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that whitespace is insignificant in the user's ASCII input.
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##### Passphrase
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###### Passphrase
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A user may wish to use a chosen passphrase rather than a randomly generated
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key. In this case, information on how to generate the key from a passphrase
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will be stored in the `passphrase` property of the `m.secure_storage.key.[key
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will be stored in the `passphrase` property of the `m.secret_storage.key.[key
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ID]` account-data:
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```json
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@ -110,19 +123,58 @@ ID]` account-data:
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}
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```
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###### `m.pbkdf2`
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**`m.pbkdf2`**
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The key is generated using PBKDF2 using the salt given in the `salt`
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parameter, and the number of rounds given in the `rounds` parameter.
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## Tradeoffs
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### Sharing
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Rather than (or in addition to) storing secrets on the server encrypted by a
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shared key, devices can send secrets to each other, encrypted using olm.
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To request a secret, a client sends a `m.secret.request` event with `action`
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set to `request` to other devices, and `name` set to the name of the secret
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that it wishes to retrieve. A device that wishes to share the secret will
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reply with a `m.secret.share` event, encrypted using olm. When the original
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client obtains the secret, it sends a `m.secret.request` event with `action`
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set to `cancel_request` to all devices other than the one that it received the
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secret from.
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Clients SHOULD ensure that they only share secrets with other devices that are
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allowed to see them. For example, clients SHOULD only share secrets with devices
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that are verified and MAY prompt the user to confirm sharing the secret.
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If a feature allows secrets to be stored or shared, then for consistency it
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SHOULD use the same name for both the `account_data` `type` and the `name` in
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the `m.secret.request`.
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Rather than encrypting data on the server using a static key, clients can
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exchange data by sending to_device messages encrypted using Olm. This allows
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clients to share data securely without requiring the user to enter keys or
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passphrases. However, users who have only one device and lose it will still
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need a way to, for example, recover their key backup, so we must provide a way
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for the data to be stored on the server.
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#### Event definitions
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##### `m.secret.request`
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Sent by a client to request a secret from another device. It is sent as an
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unencrypted to-device event.
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- `name`: (string) Required if `action` is `request`. The name of the secret
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that is being requested.
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- `action`: (enum) Required. One of ["request", "cancel_request"].
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- `requesting_device_id`: (string) Required. ID of the device requesting the
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secret.
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- `request_id`: (string) Required. A random string uniquely identifying the
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request for a secret. If the secret is requested multiple times, it should be
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reused. It should also reused in order to cancel a request.
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##### `m.secret.share`
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Sent by a client to share a secret with another device, in response to an
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`m.secret.request` event. Typically it is encrypted as an `m.room.encrypted`
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event, then sent as a to-device event.
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- `request_id`: (string) Required. The ID of the request that this a response to.
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- `secret`: (string) Required. The contents of the secret.
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## Tradeoffs
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Currently, only a public/private key mechanism is defined. It may be useful to
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also define a secret key mechanism.
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Hubert Chathi
6 years ago