# 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 Source string Schema string Path string Host string Port string UnvalidatedInput string } class PersonID { AsLoginName() string // "ID-Host" } } namespace forgejo { class User { <> 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 Source string Schema string Path string Host string Port string UnvalidatedInput string } class PersonID { AsWebfinger() string // "ID@Host" } } namespace user { class User { <> 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 { <> 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 Source string Schema string Path string Host string Port string UnvalidatedInput string } class PersonID { AsLoginName() string // "ID-Host" AsWebfinger() string // "@ID@Host" } class FederationHost { <> ID int64 HostFqdn string } class NodeInfo { Source string } } namespace user { class User { <> 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 Source string Schema string Path string Host string Port string UnvalidatedInput string } class PersonID { AsLoginName() string // "ID-Host" AsWebfinger() string // "@ID@Host" } class FederatedPerson { <> ID int64 UserID int64 RawData map[string]any ExternalID string FederationHost int64 } class FederationHost { <> ID int64 HostFqdn string } class NodeInfo { Source string } } namespace user { class CommonUser { <> } 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 ```