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# Threat Analysis for RemoteLogin propagation
See also [1] for getting an idea about the analysis.
## Technical Background
### Control Flow
```mermaid
sequenceDiagram
participant fs as foreign_repository_server
participant os as our_repository_server
fs ->> os: post /api/activitypub/repository-id/1/inbox {Like-Activity}
activate os
os ->> repository: load "1"
os ->> os: validate actor id inputs
activate os
os ->> FederationInfo: get by Host
os ->> os: if FederatonInfo not found
activate os
os ->> fs: get .well-known/nodeinfo
os ->> NodeInfoWellKnown: create & validate
os ->> fs: get api/v1/nodeinfo
os ->> NodeInfo: create & validate
os ->> FederationInfo: create
deactivate os
os ->> ForgeLike: validate
deactivate os
os ->> user: search for user with actor-id
os ->> os: create user if not found
activate os
os ->> fs: get /api/activitypub/user-id/{id from actor}
os ->> ForgePerson: validate
os ->> user: create user from ForgePerson
deactivate os
os ->> repository: execute star
os ->> FederationInfo: update latest activity
os -->> fs: 200 ok
deactivate os
```
### Data transferred
```
# NodeInfoWellKnown
{"links":[
{"href":"https://federated-repo.prod.meissa.de/api/v1/nodeinfo",
"rel":"http://nodeinfo.diaspora.software/ns/schema/2.1"}]}
# NodeInfo
{"version":"2.1",
"software":{"name":"gitea",
...}}
# LikeActivity
{"id": "https://repo.prod.meissa.de/api/v1/activitypub/user-id/1/outbox/12345",
"type": "Like",
"actor": "https://repo.prod.meissa.de/api/v1/activitypub/user-id/1",
"object": "https://codeberg.org/api/v1/activitypub/repository-id/12"
"startTime": "2014-12-31T23:00:00-08:00"
}
# Person
{"id":"https://federated-repo.prod.meissa.de/api/v1/activitypub/user-id/10",
"type":"Person",
"preferredUsername":"stargoose9",
"name": "goose going to star the repo",
"publicKey":{"id":"https://federated-repo.prod.meissa.de/api/v1/activitypub/user-id/10#main-key",
"owner":"https://federated-repo.prod.meissa.de/api/v1/activitypub/user-id/10",
"publicKeyPem":"-----BEGIN PUBLIC KEY-----\nMIIBoj...XAgMBAAE=\n-----END PUBLIC KEY-----\n"}}
```
### Data Flow
```mermaid
flowchart TD
A(User) --> |stars a federated repository| B(foreign repository server)
B --> |Like Activity| C(our repository server)
C --> |get NodeInfoWellKnown| B
C --> |get NodeInfo| B
C --> |get Person Actor| B
C --> |cache/create federated user locally| D(our database)
C --> |cache/create NodeInfo locally| D(our database)
C --> |add star to repo locally| D
```
## Analysis
### Assets
1. **Service Availability**: The availability of our or foreign servers.
2. **Instance Reputation**: We hope our project does not live on a spam instance.
3. **Project Reputation**: The reputation of an individual project.
### Actors
1. **Script Kiddies**: Boored teens, willing to do some illegal stuff without deep knowledge of tech details but broad knowledge across internet discussions. Able to do some bash / python scripting.
2. **Experienced Hacker**: Hacker with deep knowledge.
3. **Hacker**: Hacker with some knowledge.
4. **Malicious Fediverse Member**: Malicious Members of the fediverse, able to operate malicious forge instances.
5. **Malicious Forge Admin**: Admin of good reputation forge instance in the fediverse.
6. **Federated User**: Members of good reputation forge instance in the fediverse.
### Threat
1.
### Mitigations
1.
### DREAD-Score
| Threat | Damage | Reproducibility | Exploitability | Affected Users | Discoverability | Mitigations |
| :----- | :------ | :-------------- | :------------- | :------------- | :-------------- | :---------- |
| 1. | ... tbd | | | | | |
| 2. | ... tbd | | | | | |
Threat Score with values between 1 - 6
* Damage how severe would the damage be if the attack is successful? 6 is a very bad damage.
* Reproducibility how easy would the attack be reproducible? 6 is very easy to reproduce.
* Exploitability How much time, effort and experience are necessary to exploit the threat? 6 is very easy to make.
* Affected Users if a threat were exploited, how many percentage of users would be affected?
* Discoverability How easy can an attack be discovered? Does the attacker have to expect prosecution? 6 is very hard to discover / is not illegal
## Contributors
## Reference
[1]: https://owasp.org/www-community/Threat_Modeling_Process

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# Activity for federated star action
## Status
Active
## Context
While implementing the star activity we have to take several decisions which will impact all other activities. Due to this relevance we will discuss decision with as many federation contributors as possible.
## Decision
We decided to use "2. Like Activity while source information comes from NodeInfo"
## Choices
### 1. Star Activity derived from AP Like with additional source information
```edn
# edn notation
{@context [
"as": "https://www.w3.org/ns/activitystreams#",
"forge": "https://forgefed.org/ns#",],
::as/id "https://repo.prod.meissa.de/api/v1/activitypub/user-id/1/outbox/12345",
::as/type "Star",
::forge/source "forgejo",
::as/actor "https://repo.prod.meissa.de/api/v1/activitypub/user-id/1",
::as/object "https://codeberg.org/api/v1/activitypub/repository-id/12"
}
```
```json
# json notation
{"id": "https://repo.prod.meissa.de/api/v1/activitypub/user-id/1/outbox/12345",
"type": "Star",
"source": "forgejo",
"actor": "https://repo.prod.meissa.de/api/v1/activitypub/user-id/1",
"object": "https://codeberg.org/api/v1/activitypub/repository-id/1",
"startTime": "2014-12-31T23:00:00-08:00",
}
```
This way of expressing stars will have the following features:
1. Actor & object may be dereferenced by (ap-)api
2. The activity can be referenced itself (e.g. in order to express a result of the triggered action)
3. Star is a special case of a Like. Star only happens in ForgeFed context. Different things should be named different ...
4. With the `source` given it would be more easy to distinguish the uri layout for object and actor id's and make implementation more straight forward
1. The `source` field reflects the software sending an activity. Values of it may be forgejo, gitlab, ...
2. Knowing the sending system will make it easier to interact with:
1. We know exactly how the actor can be dereferenced - names may be filled & used different (see: https://codeberg.org/meissa/forgejo/src/commit/7cac9806f8247963b1cdce3f2c5f5d1bc3763fbe/routers/api/v1/activitypub/repository.go#L180)
2. We know how we can validate the given references - valid uris will be different in details (see: https://codeberg.org/meissa/forgejo/src/commit/7cac9806f8247963b1cdce3f2c5f5d1bc3763fbe/models/forgefed/actor.go#L121)
5. startTime protects against The Reply Attack discussed in [threat-analysis] [threat-analysis]
### 2. Like Activity while source information comes from NodeInfo
```json
# NodeInfo
{
"version": "2.1",
"software": {
"name": "gitea",
"version": "1.20.0+dev-2539-g5840cc6d3",
},
"protocols": [
"activitypub"
],
}
# Like Activity
{"id": "https://repo.prod.meissa.de/api/v1/activitypub/user-id/1/outbox/12345",
"type": "Like",
"actor": "https://repo.prod.meissa.de/api/v1/activitypub/user-id/1",
"object": "https://codeberg.org/api/v1/activitypub/repository-id/1",
"startTime": "2014-12-31T23:00:00-08:00"
}
```
This way of expressing stars will have the following features:
1. Actor & object may be dereferenced by (ap-)api
2. The activity can be referenced itself (e.g. in order to express a result of the triggered action)
3. With NodeInfo given it would be more easy to distinguish the uri layout for object and actor id's and make implementation more straight forward
1. The NodeInfo field reflects the software & version sending an activity. Values of may be gitea, forgejo, gitlab, ...
2. Knowing the sending system will it make easier to interact with:
1. We know exactly how the actor can be derefernced - names maybe filled & used different (see: https://codeberg.org/meissa/forgejo/src/commit/7cac9806f8247963b1cdce3f2c5f5d1bc3763fbe/routers/api/v1/activitypub/repository.go#L180)
2. We know how we can validate the given references - valid uris will be different in details (see: https://codeberg.org/meissa/forgejo/src/commit/7cac9806f8247963b1cdce3f2c5f5d1bc3763fbe/models/forgefed/actor.go#L121)
4. startTime protects against The Reply Attack discussed in [threat-analysis] [threat-analysis]
## See also
1. [spec in clojure]: https://repo.prod.meissa.de/meissa/activity-pub-poc/src/branch/forgefed_star/src/test/cljc/org/domaindrivenarchitecture/fed_poc/forgefed_test.cljc#L36-L41
2. [threat-analysis]: threat_analysis_star_activity.md

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# How to Trigger Activities
- [How to Trigger Activities](#how-to-trigger-activities)
- [Status](#status)
- [Context](#context)
- [Decision](#decision)
- [Choices](#choices)
- [1. Transient Federation without Constraints](#1-transient-federation-without-constraints)
- [Problem - Circularity And Inconsistency](#problem---circularity-and-inconsistency)
- [2. Direct Federation only](#2-direct-federation-only)
- [Discussion for option 2.](#discussion-for-option-2)
- [3. Transient Federation and Remember Processed](#3-transient-federation-and-remember-processed)
- [See also](#see-also)
## Status
Proposal
## Context
While implementing the trigger of federated stars we have to handle the distribution of corresponding Like-Activities to the federated repositories.
This must be done consistently and without circularity, such that a repository starring by a user leads to exactly one added star in every federated repository.
```mermaid
flowchart TD
U(User) -->|Press Star on UI| A(A: repository - follow C by incident)
A ~~~ B(B: follow A)
B ~~~ C(C: follow B)
C ~~~ A
```
## Decision
## Choices
### 1. Transient Federation without Constraints
In this case the star federation process would look like:
1. Repo on an instance receives a star (regardless of whether via UI or federation)
2. Instance federates star to all repos that are set as federated repositories.
#### Problem - Circularity And Inconsistency
Circular federation would lead to a infinite circular distribution of Like-Activities:
```mermaid
flowchart TD
U(User) -->|Press Star on UI| A(A: repository - follow C by incident)
A -->|federate Like Activity| B(B: follow A)
B -->|federate Like Activity| C(C: follow B)
C -->|federate Like Activity| A
```
1. Given a repo on the 3 instances A, B, C.
Repo on instance A has set repo on instance B as federation repo.
Repo on instance B has set repo on instance C as federation repo.
Repo on instance C has set repo on instance A as federation repo.
2. User stars repo on instance A via UI.
3. Instance A sends Like-Activity to repo on instance B.
4. Instance B creates local FederatedUser, stars the repo and sends Like-Activity to repo on instance C.
5. Instance C creates local FederatedUser, stars the repo and sends Like-Activity to repo on instance A.
6. Instance A creates local FederatedUser, since the Actor of the Like-Activity is the local FederatedUser created on instance C.
Thus, the repo on instance A gets another star by this user and sends Like-Activity to the repo on instance C.
7. The circular distribution of Like-Activities continues, since the actor is always the local FederatedUser of the sending instance.
### 2. Direct Federation only
```mermaid
flowchart TD
U(User) -->|Press Star on UI| A(A: repository - follow C not allowed)
A -->|federate Like Activity| B(B: follow A)
A -->|federate Like Activity| C(C: follow B not allowed, has to follow A)
```
In this case the star federation process would look like:
1. Case: Repo on an instance receives a star by an authenticated user via UI/API:
1. Repository gets starred by the authenticated User.
2. Instance federates star to all repos that are set as federated repositories.
2. Case: Repo on an instance receives a star via a Like-Activity:
1. Instance creates FederatedUser and stars the repository.
2. No further star federation to federated repos is triggered.
#### Discussion for option 2.
1. pro
1. Prevent circular communication
2. Clear semantic also in case of "Who should authorize a digital signature"
### 3. Transient Federation and Remember Processed
In this case the star federation process would look like:
1. Repo on an instance receives a star (regardless of whether via UI or federation)
2. If this activity was not operated already in this instance, federate star to all repos that are set as federated repositories.
## See also

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# Activity for federated star action
- [Activity for federated star action](#activity-for-federated-star-action)
- [Status](#status)
- [Context](#context)
- [Decision](#decision)
- [Choices](#choices)
- [1. Map to plain forgejo User](#1-map-to-plain-forgejo-user)
- [1. Pro](#1-pro)
- [1. Con](#1-con)
- [2. Map to User-\&-ExternalLoginUser](#2-map-to-user--externalloginuser)
- [2. Pro](#2-pro)
- [2. Con](#2-con)
- [3. Map to User-\&-FederatedUser](#3-map-to-user--federateduser)
- [3. Pro](#3-pro)
- [3. Con](#3-con)
- [4. Map to new FederatedPerson and introduce a common User interface](#4-map-to-new-federatedperson-and-introduce-a-common-user-interface)
- [4. Pro](#4-pro)
- [4. Con](#4-con)
## Status
Active
## Context
While implementing federation we have to represent federated persons on a local instance.
A federated person should be able to execute local actions (as if he was a local user), ideally without too many code changes.
For being able to map the federated person reliable, the local representation has to carry a clear mapping to the original federated person.
We get actor information as `{"actor": "https://repo.prod.meissa.de/api/v1/activitypub/user-id/1",}`. To find out whether this user is available locally without dereferencing the federated person every time is important for performance & system resilience.
## Decision
We decided to use option 3 "Map to User & FederatedUser".
Discussion can be found here: https://codeberg.org/forgejo/discussions/issues/101
## Choices
### 1. Map to plain forgejo User
1. We map PersonId AsLoginName() (e.g. 13-some.instan.ce) to User.LoginName. Due to limitations of User.LoginName validation mapping may be affected by invalid characters.
2. Created User is limited:
1. non functional email is generated, email notification is false. At the moment we have problems with email whitelists at this point.
2. strong password is generated silently
3. User.Type is UserTypeRemoteUser
4. User is not Admin
5. User is not Active
#### 1. Pro
1. We can use forgejo code (like star / unstar fkt.) without changes.
2. No new model & persistence is introduced, architectural change is small.
#### 1. Con
1. But we use fields against their semantic and see some problems / limitations for mapping arise.
1. generating email having the source fqdn is impacted by email whitelists.
1. loginName is used for mapping, but e.g. @ is not allowed.
1. password is generated headless.
2. Maybe the large User table gets even larger (see https://git.exozy.me/a/gitea/issues/2)
3. Occasional contributors may not understand the difference in level of trust implied by federated user. This may promote errors with security impact.
4. Understanding federated users entries being kind of cache would conflict with user table entries.
5. LoginNames may be occupied by federated users. This may leak information and increase attack surface.
```mermaid
classDiagram
namespace activitypub {
class Like {
ID ID
Type ActivityVocabularyType // Like
Actor Item
Object Item
}
class Actor {
ID
URL Item
Type ActivityVocabularyType // Person
Name NaturalLanguageValues
PreferredUsername NaturalLanguageValues
Inbox Item
Outbox Item
PublicKey PublicKey
}
}
namespace forgfed {
class ForgePerson {
}
class ForgeLike {
Actor PersonID
}
class ActorID {
ID string
Schema string
Path string
Host string
Port string
UnvalidatedInput string
}
class PersonID {
AsLoginName() string // "ID-Host"
}
}
namespace forgejo {
class User {
<<Aggregate Root>>
ID int64
LowerName string
Name string
Email string
Passwd string
LoginName string
Type UserType
IsActive bool
IsAdmin bool
}
}
Actor <|-- ForgePerson
Like <|-- ForgeLike
ActorID <|-- PersonID
ForgeLike *-- PersonID: Actor
PersonID -- User: mapped by AsLoginName() == LoginName
PersonID -- ForgePerson: links to
```
### 2. Map to User-&-ExternalLoginUser
1. We map PersonId.AsWebfinger() (e.g. 13@some.instan.ce) to ExternalLoginUser.ExternalID. LoginSourceID may be left Empty.
2. Created User is limited:
1. non functional email is generated, email notification is false.
2. strong password is generated silently
3. User.Type is UserTypeRemoteUser
4. User is not Admin
5. User is not Active
3. Created ExternalLoginUser is limited
1. Login via fediverse is not intended and will not work. This is distinct to the F3 usecase.
#### 2. Pro
1. We can use forgejo code (like star / unstar fkt.) without changes.
2. No new model & persistence is introduced, architectural change is small. Comparable to option 1.
3. This option was taken by the F3-Export/Import-Feature
4. Mapping may be more reliable compared to option 1.
#### 2. Con
1. We use fields against their semantic (User.EMail, User.Password, User.LoginSource, ExternalLoginUser.Login*) and see some problems / limitations for login functionality arise. Situation is worse than option 1.
1. generating email having the source fqdn is impacted by email whitelists.
2. password is generated headless.
3. TODO: How would we map/generate User.LoginName ?
4. TODO: How would we generate ExternalLoginUser.Login* fields?
2. Getting a larger User table applies to this solution comparable to option 1.
3. Occasional contributors may not understand the difference in level of trust implied by federated user, this may promote errors with security impact.
4. Understanding federated users entries being kind of cache would conflict with user table entries.
5. LoginNames may be occupied by federated users. This may leak information and increase attack surface.
```mermaid
classDiagram
namespace activitypub {
class Like {
ID ID
Type ActivityVocabularyType // Like
Actor Item
Object Item
}
class Actor {
ID
URL Item
Type ActivityVocabularyType // Person
Name NaturalLanguageValues
PreferredUsername NaturalLanguageValues
Inbox Item
Outbox Item
PublicKey PublicKey
}
}
namespace forgfed {
class ForgePerson {
}
class ForgeLike {
Actor PersonID
}
class ActorID {
ID string
Schema string
Path string
Host string
Port string
UnvalidatedInput string
}
class PersonID {
AsWebfinger() string // "ID@Host"
}
}
namespace user {
class User {
<<Aggregate Root>>
ID int64
LoginSource int64
LowerName string
Name string
Email string
Passwd string
LoginName string
Type UserType
IsActive bool
IsAdmin bool
}
class ExternalLoginUser {
ExternalID string
LoginSourceID int64
RawData map[string]any
Provider string
}
}
namespace auth {
class Source {
<<Aggregate Root>>
ID int64
Type Type
Name string
IsActive bool
IsSyncEnabled bool
}
}
Actor <|-- ForgePerson
Like <|-- ForgeLike
ActorID <|-- PersonID
ForgeLike *-- PersonID: Actor
PersonID -- ForgePerson: links to
PersonID -- ExternalLoginUser: mapped by AsLoginName() == ExternalID
User *-- ExternalLoginUser: ExternalLoginUser.UserID
User -- Source
ExternalLoginUser -- Source
```
### 3. Map to User-&-FederatedUser
1. We map PersonId.asWbfinger() to FederatedPerson.ExternalID (e.g. 13@some.instan.ce).
2. Created User is limited:
1. non functional email is generated, email notification is false.
2. strong password is generated silently
3. User.Type is UserTypeRemoteUser
4. User is not Admin
5. User is not Active
#### 3. Pro
1. We can use forgejo code (like star / unstar fkt.) without changes.
2. Introduce FederatedUser as new model & persistence, architectural change is medium.
3. We will be able to have a reliable mapping. Better than option 1 & 2.
#### 3. Con
1. But we use fields (User.EMail, User.Password) against their semantic, but we probably can handle the problems arising. Situation is comparable to option 1.
1. generating email having the source fqdn is impacted by email whitelists.
2. password is generated headless.
3. TODO: How would we map/generate User.LoginName ?
2. Getting a larger User table applies to this solution comparable to option 1.
3. Occasional contributors may not understand the difference in level of trust implied by federated user, this may promote errors with security impact, comparable to option 1.
4. Getting a larger User table applies to this solution comparable to option 1.
5. Understanding federated users entries being kind of cache would conflict with user table entries.
6. LoginNames may be occupied by federated users. This may leak information and increase attack surface.
```mermaid
classDiagram
namespace activitypub {
class Like {
ID ID
Type ActivityVocabularyType // Like
Actor Item
Object Item
}
class Actor {
ID
Type ActivityVocabularyType // Person
Name NaturalLanguageValues
PreferredUsername NaturalLanguageValues
Inbox Item
Outbox Item
PublicKey PublicKey
}
}
namespace forgfed {
class ForgePerson {
}
class ForgeLike {
Actor PersonID
}
class ActorID {
ID string
Schema string
Path string
Host string
Port string
UnvalidatedInput string
}
class PersonID {
AsLoginName() string // "ID-Host"
AsWebfinger() string // "@ID@Host"
}
class FederationHost {
<<Aggregate Root>>
ID int64
HostFqdn string
}
class NodeInfo {
Source string
}
}
namespace user {
class User {
<<Aggregate Root>>
ID int64
LowerName string
Name string
Email string
Passwd string
LoginName string
Type UserType
IsActive bool
IsAdmin bool
}
class FederatedUser {
ID int64
UserID int64
ExternalID string
FederationHost int64
}
}
Actor <|-- ForgePerson
Like <|-- ForgeLike
ActorID <|-- PersonID
ForgeLike *-- PersonID: Actor
ForgePerson -- PersonID: links to
FederationHost *-- NodeInfo
User *-- FederatedUser: FederatedUser.UserID
PersonID -- FederatedUser : mapped by PersonID.asWebfinger() == FederatedUser.externalID
FederatedUser -- FederationHost
```
### 4. Map to new FederatedPerson and introduce a common User interface
1. We map PersonId.asWbfinger() to FederatedPerson.ExternalID (e.g. 13@some.instan.ce).
2. We will have no semantic mismatch.
#### 4. Pro
1. We will be able to have a reliable mapping.
2. We will not use fields against their semantics.
3. We do not enhance user table with "cache entries". Forgejo stays scalable, no additional DOS surface.
4. Occasional contributors may understand a clear difference between user and federated user.
5. No LoginNames where occupied
6. Caching aspects of federated users (like refresh, evict) may be easier to implement.
#### 4. Con
1. We can use forgejo code (like star / unstar fkt.) after refactorings only.
2. At every place of interaction we have to enhance persistence (e.g. a find may have to query two tables now) & introduce a common User interface.
3. We introduce new model & persistence.
```mermaid
classDiagram
namespace activitypub {
class Like {
ID ID
Type ActivityVocabularyType // Like
Actor Item
Object Item
}
class Actor {
ID
URL Item
Type ActivityVocabularyType // Person
Name NaturalLanguageValues
PreferredUsername NaturalLanguageValues
Inbox Item
Outbox Item
PublicKey PublicKey
}
}
namespace forgfed {
class ForgePerson {
}
class ForgeLike {
Actor PersonID
}
class ActorID {
ID string
Schema string
Path string
Host string
Port string
UnvalidatedInput string
}
class PersonID {
AsLoginName() string // "ID-Host"
AsWebfinger() string // "@ID@Host"
}
class FederatedPerson {
<<Aggregate Root>>
ID int64
UserID int64
RawData map[string]any
ExternalID string
FederationHost int64
}
class FederationHost {
<<Aggregate Root>>
ID int64
HostFqdn string
}
class NodeInfo {
Source string
}
}
namespace user {
class CommonUser {
<<Interface>>
}
class User {
}
}
User ..<| CommonUser
Actor <|-- ForgePerson
Like <|-- ForgeLike
ActorID <|-- PersonID
ForgeLike *-- PersonID: Actor
PersonID -- ForgePerson: links to
PersonID -- FederatedPerson : mapped by PersonID.asWebfinger() == FederatedPerson.externalID
FederationHost *-- NodeInfo
FederatedPerson -- FederationHost
FederatedPerson ..<| CommonUser
```

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# Federation Architecture Principles
While implementing federation in forgejo we introduced some conncepts from DomainDrivenDesign:
1. **Aggregate**: Aggregates are clusters of objects (entities or values) which are handled atomic when it comes to persistence.
2. **Validation**: Every object should express it's own validity, whenever someone is interested in
1. we collect as many invalidity information as possible in one shoot - so we return a list of validation issues if there are some.
2. Objects entering the lifetime are checked for validity on the borders (after loaded from and before stored to DB, after being newly created (New* functions) or after loaded via web / REST).
Objects in forgefed package reflect Objects from ap or f3 lib but add some Forgejo specific enhancements like more specific validation.
## Federation Model
```mermaid
classDiagram
namespace activitypub {
class Activity {
ID ID
Type ActivityVocabularyType // Like
Actor Item
Object Item
}
class Actor {
ID
Type ActivityVocabularyType // Person
Name NaturalLanguageValues
PreferredUsername NaturalLanguageValues
Inbox Item
Outbox Item
PublicKey PublicKey
}
}
namespace forgfed {
class ForgePerson {
Validate() []string
}
class ForgeLike {
Actor PersonID
Validate() []string
}
class ActorID {
ID string
Schema string
Path string
Host string
Port string
Source string
UnvalidatedInput string
Validate() []string
}
class PersonID {
AsLoginName() string // "ID-Host"
AsWebfinger() string // "@ID@Host"
Validate() []string
}
class RepositoryID {
Validate() []string
}
class FederationHost {
<<Aggregate Root>>
ID int64
HostFqdn string
Validate() []string
}
class NodeInfo {
Source string
Validate() []string
}
}
Actor <|-- ForgePerson
Activity <|-- ForgeLike
ActorID <|-- PersonID
ActorID <|-- RepositoryID
ForgeLike *-- PersonID: Actor
ForgePerson -- PersonID: links to
FederationHost *-- NodeInfo
namespace user {
class User {
<<Aggregate Root>>
ID int64
LowerName string
Name string
Email string
Passwd string
LoginName string
Type UserType
IsActive bool
IsAdmin bool
NormalizedFederatedURI string
Validate() []string
}
class FederatedUser {
ID int64
UserID int64
ExternalID string
FederationHost int64
Validate() []string
}
}
namespace repository {
class Repository {
<<Aggregate Root>>
ID int64
}
class FollowingRepository {
ID int64
RepositoryID int64
ExternalID string
FederationHost int64
Validate() []string
}
}
User "1" *-- "1" FederatedUser: FederatedUser.UserID
PersonID -- FederatedUser : mapped by PersonID.ID == FederatedUser.externalID & FederationHost.ID
PersonID -- FederationHost : mapped by PersonID.Host == FederationHost.HostFqdn
FederatedUser -- FederationHost
Repository "1" *-- "n" FollowingRepository: FollowingRepository.RepositoryID
FollowingRepository -- FederationHost
```
## Normalized URI used as ID
In order to use URIs as ID we've to normalize URIs.
A normalized user URI looks like: `https://federated-repo.prod.meissa.de/api/v1/activitypub/user-id/1`
In order to normalize URIs we care:
1. Case (all to lower case): `https://federated-REPO.prod.meissa.de/api/v1/activitypub/user-id/1`
2. No relative path: `https://federated-repo.prod.meissa.de/api/v1/activitypub/user-id/../user-id/1`
3. No parameters: `https://federated-repo.prod.meissa.de/api/v1/activitypub/user-id/1?some-parameters=1`
4. No Webfinger: `https://user1@federated-repo.prod.meissa.de` (with following redirects)
5. No default api: `https://federated-repo.prod.meissa.de/api/activitypub/user-id/1`
6. No autorization: `https://user:password@federated-repo.prod.meissa.de/api/v1/activitypub/user-id/1`
7. No default ports: `https://federated-repo.prod.meissa.de:443/api/v1/activitypub/user-id/1`
8. Accept non default ports: `http://localhost:3000/api/v1/activitypub/user-id/1`

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# Threat analysis for the federated Like Activity
See also [1] for getting an idea about the analysis.
## Technical Background
### Control Flow
```mermaid
sequenceDiagram
participant fs as foreign_repository_server
participant os as our_repository_server
fs ->> os: post /api/activitypub/repository-id/1/inbox {Like-Activity}
activate os
os ->> repository: load "1"
os ->> os: validate actor id inputs
activate os
os ->> FederationInfo: get by Host
os ->> os: if FederatonInfo not found
activate os
os ->> fs: get .well-known/nodeinfo
os ->> NodeInfoWellKnown: create & validate
os ->> fs: get api/v1/nodeinfo
os ->> NodeInfo: create & validate
os ->> FederationInfo: create
deactivate os
os ->> ForgeLike: validate
deactivate os
os ->> user: search for user with actor-id
os ->> os: create user if not found
activate os
os ->> fs: get /api/activitypub/user-id/{id from actor}
os ->> ForgePerson: validate
os ->> user: create user from ForgePerson
deactivate os
os ->> repository: execute star
os ->> FederationInfo: update latest activity
os -->> fs: 200 ok
deactivate os
```
### Data transferred
```
# NodeInfoWellKnown
{"links":[
{"href":"https://federated-repo.prod.meissa.de/api/v1/nodeinfo",
"rel":"http://nodeinfo.diaspora.software/ns/schema/2.1"}]}
# NodeInfo
{"version":"2.1",
"software":{"name":"gitea",
...}}
# LikeActivity
{"id": "https://repo.prod.meissa.de/api/v1/activitypub/user-id/1/outbox/12345",
"type": "Like",
"actor": "https://repo.prod.meissa.de/api/v1/activitypub/user-id/1",
"object": "https://codeberg.org/api/v1/activitypub/repository-id/12"
"startTime": "2014-12-31T23:00:00-08:00"
}
# Person
{"id":"https://federated-repo.prod.meissa.de/api/v1/activitypub/user-id/10",
"type":"Person",
"preferredUsername":"stargoose9",
"name": "goose going to star the repo",
"publicKey":{"id":"https://federated-repo.prod.meissa.de/api/v1/activitypub/user-id/10#main-key",
"owner":"https://federated-repo.prod.meissa.de/api/v1/activitypub/user-id/10",
"publicKeyPem":"-----BEGIN PUBLIC KEY-----\nMIIBoj...XAgMBAAE=\n-----END PUBLIC KEY-----\n"}}
```
### Data Flow
```mermaid
flowchart TD
A(User) --> |stars a federated repository| B(foreign repository server)
B --> |Like Activity| C(our repository server)
C --> |get NodeInfoWellKnown| B
C --> |get NodeInfo| B
C --> |get Person Actor| B
C --> |cache/create federated user locally| D(our database)
C --> |cache/create NodeInfo locally| D(our database)
C --> |add star to repo locally| D
```
## Analysis
### Assets
1. **Service Availability**: The availability of our or foreign servers.
2. **Instance Reputation**: We hope our project does not live on a spam instance.
3. **Project Reputation**: The reputation of an individual project.
### Actors
1. **Script Kiddies**: Boored teens, willing to do some illegal stuff without deep knowledge of tech details but broad knowledge across internet discussions. Able to do some bash / python scripting.
2. **Experienced Hacker**: Hacker with deep knowledge.
3. **Hacker**: Hacker with some knowledge.
4. **Malicious Fediverse Member**: Malicious Members of the fediverse, able to operate malicious forge instances.
5. **Malicious Forge Admin**: Admin of good reputation forge instance in the fediverse.
6. **Federated User**: Members of good reputation forge instance in the fediverse.
### Threat
1. Script Kiddi sends a Like Activity containing an attack actor url `http://attacked.target/very/special/path` in place of actor. Our repository server sends a `get Person Actor` request to this url. The target receives a DenialdOfService attack. We loose CPU & instance reputation.
2. Experienced hacker sends a Like Activity containing an actor url pointing to an evil forgejo instance. Our repository server sends an `get Person Actor` request to this instance and gets a person having sth. like `; drop database;` in its name. If our server tries to create a new user out of this person, the db might be dropped.
3. **Malicious Activities**: Malicious Fediverse Member sends Star Activities containing non authorized Person Actors. The Actors listed as stargazer might get angry about this. The project may loose project reputation.
4. **DOS by Rate**: Experienced Hacker records activities sent and replays some of them. Without order of activities (i.e. timestamp) we can not decide wether we should execute the activity again. If the replayed activities are UnLike Activity we might loose stars.
5. **Replay**: Experienced Hacker records activities sends a massive amount of activities which leads to new user creation & storage loss. Our instance might fall out of service. See also [replay attack@wikipedia][3].
6. **Replay out of Order**: Experienced Hacker records activities sends again Unlike Activities happened but was succeeded by an Like. Our instance accept the Unlike and removes a star. Our repository gets rated unintended bad.
7. **DOS by Slowlories**: Experienced Hacker may craft their malicious server to keep connections open. Then they send a Like Activity with the actor URL pointing to that malicious server, and your background job keeps waiting for data. Then they send more such requests, until you exhaust your limit of file descriptors openable for your system and cause a DoS (by causing cascading failures all over the system, given file descriptors are used for about everything, from files, to sockets, to pipes). See also [Slowloris@wikipedia][2].
8. **Block by future StartTime**: Hacker sends an Activity having `startTime` in far future. Our Instance does no longer accept Activities till they have far far future `startTime` from the actors instance.
9. **Malicious Forge**: If a "Malicious Fediverse Member" deploys an 'federated' forge that sends the right amount of Like activities to not hit the rate limiter, an malicious user can modify the code of any 'federated' forge to ensure that if an foreign server tries to verify and activity, it will always succeed (such as creating users on demand, or simply mocking the data).
10. **Malicious Controlled Forge**: A "Malicious Forge Admin" of a good reputation instance may impersonate users on his instance and trigger federated activities.
11. **Side Chanel Malicious Activities**: A Owner of a good reputation instance may craft malicious activities with the hope not to get moderated.
### Mitigations
1. Validate object uri in order to send only requests to well defined endpoints.
2. xorm global SQL injection protection.
3. We accept only signed Activities
4. We accept only activities having an startTime & remember the last executed activity startTime.
5. We introduce (or have) rate limiting per IP.
6. We ensure, that outgoing HTTP requests have a reasonable timeout (if you didn't get that 500b JSON response after 10 seconds, you probably won't get it).
7. **Instance Level Moderation** (such as blocking other federated forges) can mitigate "Malicious Forge"
8. **User Level Moderation** (such as blocking other federated users) can mitigate "Side Chanel Malicious Activities"
### DREAD-Score
| Threat | Damage | Reproducibility | Exploitability | Affected Users | Discoverability | Mitigations |
| :----- | :------ | :-------------- | :------------- | :------------- | :-------------- | :---------- |
| 1. | ... tbd | | | | | |
| 2. | ... tbd | | | | | |
Threat Score with values between 1 - 6
* Damage how severe would the damage be if the attack is successful? 6 is a very bad damage.
* Reproducibility how easy would the attack be reproducible? 6 is very easy to reproduce.
* Exploitability How much time, effort and experience are necessary to exploit the threat? 6 is very easy to make.
* Affected Users if a threat were exploited, how many percentage of users would be affected?
* Discoverability How easy can an attack be discovered? Does the attacker have to expect prosecution? 6 is very hard to discover / is not illegal
## Contributors
In addition to direct committer our special thanks goes to the experts joining our discussions:
* [kik](https://codeberg.org/oelmekki)
## Reference
[1]: https://geballte-sicherheit.de/threat-modelling-bedrohungsanalyse-7-teil-einstufung-von-bedrohungen-ranking-of-threats/
[2]: https://en.wikipedia.org/wiki/Slowloris_(computer_security)
[3]: https://en.wikipedia.org/wiki/Replay_attack