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feat: add spec for namespace configs
Co-authored-by: Kevin Goslar <[email protected]> Co-authored-by: hackerman <[email protected]>
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# The "Ory Permission Language" Specification | ||
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Enforcing fine-grained permissions is a critical building block of mature | ||
technology solutions that protect privacy and identity in the information age. | ||
Several proprietary languages to represent permission already exist, namely the | ||
[Authzed Schema Language](https://docs.authzed.com/reference/schema-lang) and | ||
[Auth0 FGA](https://docs.fga.dev/). Most permissions are defined by normal | ||
developers who typically are most familiar with Web technologies like JavaScript | ||
or Typescript. We see the need for a developer-friendly configuration language | ||
for permissions that has such a small learning curve that most developers can | ||
understand and use it with close to no effort. We therefore chose to define our | ||
permissions configuration language as a subset of the most common | ||
general-purpose programming language: JavaScript/TypeScript. | ||
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The Ory Permission Language is a syntactical subset of TypeScript. Along with | ||
type definitions for the syntax elements of the language (such as `Namespace` or | ||
`Context`), users can get context help from their IDE while writing the | ||
configuration. | ||
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## Notation | ||
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The syntax is specified using the Extended Backus-Naur Form (EBNF): | ||
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```ebnf | ||
Production = production_name "=" [ Expression ] "." . | ||
Expression = Alternative { "|" Alternative } . | ||
Alternative = Term { Term } . | ||
Term = production_name | token [ "…" token ] | Group | Option | Repetition . | ||
Group = "(" Expression ")" . | ||
Option = "[" Expression "]" . | ||
Repetition = "{" Expression "}" . | ||
``` | ||
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Productions are expressions constructed from terms and the following operators, | ||
in increasing precedence: | ||
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```ebnf | ||
| alternation | ||
() grouping | ||
[] option (0 or 1 times) | ||
{} repetition (0 to n times) | ||
``` | ||
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Lower-case production names are used to identify lexical tokens. Non-terminals | ||
are in CamelCase. Lexical tokens are enclosed in double quotes `""` or single | ||
quotes `''`. | ||
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The form `a … b` represents the set of characters from a through b as | ||
alternatives. The horizontal ellipsis `…` is also used elsewhere in the spec to | ||
informally denote various enumerations or code snippets that are not further | ||
specified. | ||
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## Configuraton text representation | ||
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The configuration is encoded in UTF-8. | ||
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## Lexical elements | ||
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### Comments | ||
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1. Line comments start with the character sequence `//` and stop at the end of | ||
the line. | ||
2. General comments start with the character sequence `/*` and stop with the | ||
first subsequent character sequence `*/`. | ||
3. Documentation comments start with the character sequence `/**` and stop with | ||
the first subsequent character sequence `*/`. | ||
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### Identifiers | ||
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Identifiers name program entities such as variables and types. An identifier is | ||
a sequence of one or more letters and digits. The first character in an | ||
identifier must be a letter. | ||
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```ebnf | ||
identifier = letter { letter | digit } . | ||
digit = "0" … "9" . | ||
letter = "A" … "Z" | "a" … "z" | "_" . | ||
``` | ||
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### String literals | ||
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String literals represent string constants as sequences of characters. | ||
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```ebnf | ||
string_lit = single_quoted | double_quoted . | ||
single_quoted = "'" identifier "'" . | ||
double_quoted = '"' identifier '"' . | ||
``` | ||
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### Keywords | ||
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The configuration language has the following keywords: | ||
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- `class` | ||
- `implements` | ||
- `related` | ||
- `permits` | ||
- `this` | ||
- `ctx` | ||
- `id` | ||
- `imports` | ||
- `exports` | ||
- `as` | ||
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### Builtin Types | ||
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The following types are built in: | ||
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- `Context` | ||
- `Namespace` | ||
- `Namespace[]` | ||
- `boolean` | ||
- `string` | ||
- `SubjectSet<T, R>` | ||
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In TypeScript, they would be defined as follows: | ||
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```typescript | ||
type Context = { subject: never } | ||
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interface Namespace { | ||
related?: { [relation: string]: Namespace[] } | ||
permits?: { [method: string]: (ctx: Context) => boolean } | ||
} | ||
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interface Array<Namespace> { | ||
includes(element: Namespace): boolean | ||
traverse(iteratorfn: (element: Namespace) => boolean): boolean | ||
} | ||
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type SubjectSet< | ||
A extends Namespace, | ||
R extends keyof A["related"], | ||
> = A["related"][R] extends Array<infer T> ? T : never | ||
``` | ||
### Operators | ||
The following character sequences represent boolean operators: | ||
| Operator | Signature | Semantic | | ||
| -------- | -------------- | ------------------------------------ | | ||
| `&&` | _x_ `&&` _y_ | true iff. both _x_ and _y_ are true | | ||
| `\|\|` | _x_ `\|\|` _y_ | true iff. either _x_ or _y_ are true | | ||
The following character sequences represent miscellaneous operators: | ||
| Operator | Example | Semantic | | ||
| -------- | ---------------------------------------- | ----------------------------------------------------------------- | | ||
| `(`, `)` | `x()` | call function `x` | | ||
| `[]` | `T[]` | `T` is an array type | | ||
| `<`, `>` | `SubjectSet<Group, "members">` | Type reference to the "members" relation of the "Group" namespace | | ||
| `{`, `}` | `class x {}` | Scope delimiters | | ||
| `=>` | `list.transitive(el => f(el))` | Lambda definition token. | | ||
| `.` | `this.x` | Property traversal token | | ||
| `:` | `relation: type` | Relation/type separator token | | ||
| `=` | `permits = {...}` | Assignment token | | ||
| `,` | `{x: 1, y: 2}` | Property separator | | ||
| `'` | `'string'` | Single quoted string literal | | ||
| `"` | `"string"` | Double quoted string literal | | ||
| `*` | `import * from @ory/permission-language` | Import glob | | ||
| `\|` | `(User \| Group)[]` | Type union | | ||
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## Statements | ||
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### Type declaration | ||
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The top level of the configuration consists of a list of `class` declarations | ||
for each namespace. Each `class` consists of relation declarations and | ||
permission declarations. | ||
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```ebnf | ||
Config = [ ClassDecl ] . | ||
ClassDecl = "class" identifier "implements" "Namespace" "{" ClassSpec "}" . | ||
ClassSpec = [ RelationDecls ] | [ PermissionDefns] . | ||
``` | ||
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The following example declares the type _User_. | ||
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```ts | ||
class User implements Namespace {} | ||
``` | ||
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### Relation declaration | ||
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The `related` section of type declarations defines relations. Unlike regular | ||
TypeScript, `RelationName` must be a unique identifier used as the relation | ||
strings in the tuples. The `TypeName` must be the name of another `type` that is | ||
defined above or below (in TypeScript: a class that implements `Namespace`). | ||
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Type unions (`|`) can be used to denote that a relation can have subjects of | ||
multiple types, e.g., `viewers: (User | SubjectSet<Group, "members">)[]`, | ||
meaning that the subject of the "viewer" relation can be either a "User", or a | ||
subject set "Group#members". | ||
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```ebnf | ||
RelationDecls = "related" "=" "{" { RelationName ":" ArrayType } "}" . | ||
RelationName = identifier . | ||
ArrayType = RelationType | ( "(" RelationType { "|" RelationType } ")" ) "[]" . | ||
RelationType = SubjectType | SubjectSetType . | ||
SubjectType = TypeName . | ||
SubjectSetType = "SubjectSet" "<" TypeName, string_lit ">" . | ||
TypeName = identifier . | ||
``` | ||
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Note that all relations are defined as array types `T[]` because there are | ||
naturally only many-to-many relations in Keto. | ||
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The following declares a type _Document_ with three relations: _owners_ and | ||
_viewers_, both of which have _users_ as subjects. Additionally, the relation | ||
_parent_ has type _Document_. | ||
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```ts | ||
class User {} | ||
class Document { | ||
related = { | ||
parents: Document[] | ||
owners: User[] | ||
viewers: User[] | ||
} | ||
} | ||
``` | ||
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### Permission definition | ||
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Permissions are defined as functions within class declarations that take a | ||
parameter `ctx` of type `Context` and evaluate to a boolean `true` or `false`. | ||
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The type annotations for `ctx` and the return value are optional. | ||
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```ebnf | ||
PermissionDefns = "permits" "=" "{" Permission [ "," Permission ] "}" . | ||
Permission = PermissionSign "=>" PermissionBody . | ||
PermissionSign = PermissionName ":" "(" "ctx" [ ":" "Context" ] ")" [ ":" "boolean" ] . | ||
PermissionName = identifier . | ||
``` | ||
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The `ctx` object is a fixed parameter that contains the `subject` for which the | ||
permission check should be conducted: | ||
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```ts | ||
ctx = { subject: "some_user_id" } | ||
``` | ||
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The context will contain more fields in the future, e.g., the IP range or | ||
geolocation, the time of day, or the security level of the device making the | ||
request. | ||
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```ebnf | ||
PermissionBody = ( "(" PermissionBody ")" ) | ( PermissionCheck | { Operator PermissionBody } ) . | ||
Operator = "||" | "&&" . | ||
PermissionCheck = TransitiveCheck | IncludesCheck . | ||
``` | ||
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The body of a permission check is either one of: | ||
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- a `IncludesCheck`, a check that something is in a set, e.g., | ||
`this.related.viewers.includes(ctx.subject)`: | ||
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```ebnf | ||
IncludesCheck = Var "." "related" "." RelationName "." "includes" "(" "ctx" "." "subject" ")" . | ||
Var = identifier . | ||
``` | ||
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- a `TranstitiveCheck`, a call to a permission on a relation, e.g., | ||
`this.related.parents.transitive(p => p.permits.view(ctx))`: | ||
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```ebnf | ||
TransitiveCheck = "this" "." "related" "." RelationName "." "transitive" "(" Var "=>" ( PermissionCall | IncludesCheck ) ")" . | ||
PermissionCall = Var "." "permits" "." PermissionName "(" "ctx" ")" . | ||
``` | ||
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## Implementation notes | ||
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`IncludeCheck` and `TransitiveCheck` translate to Zanzibar concepts as follows: | ||
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| Keto Config | Zanzibar AST | | ||
| --------------------------------------------------------- | ------------------------------------------------------------------------------------ | | ||
| `this.related.R.includes(ctx.subject)` | `computed_userset { relation: "R" } }` | | ||
| `this.related.R.transitive(x = x.permits.P(ctx.subject))` | `tuple_to_userset { tupleset { relation: "R" } computed_userset { relation: "P" } }` | | ||
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## Type checking | ||
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The following type checks are performed once the config is fully parsed: | ||
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- Given a `TypeName` as `X` (e.g., in `RelationDecls`), we check that there | ||
exists a class declaration for `X`. | ||
- Given a `SubjectSetType` as `SubjectSet<T, R>`, we check that `R` is a | ||
relation defined for `T`. | ||
- Given an `IncludesCheck` as `this.related.R.includes(ctx.subject)`, we check | ||
that | ||
- `R` is a relation defined for the current namespace. | ||
- Given a `TransitiveCheck` as | ||
`this.related.R.transitive(x = x.permits.P(ctx.subject))`, we check that | ||
- `R` is a relation defined for the current namespace and that | ||
- `P` is a permission defined for all types referenced by `R`. | ||
- Given a `TransitiveCheck` as | ||
`this.related.R.transitive(x = x.related.S.includes(ctx.subject))`, we check | ||
that | ||
- `R` is a relation defined for the current namespace and that | ||
- `S` is a relation defined for all types referenced by `R`. | ||
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## Examples | ||
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The config can be type-checked in `strict` mode by TypeScript with the | ||
[noLib](https://www.typescriptlang.org/tsconfig#noLib) option (preventing the | ||
standard globals), and the | ||
[strictPropertyInitialization](https://www.typescriptlang.org/tsconfig#strictPropertyInitialization) | ||
option (allowing uninitialized properties). | ||
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```ts | ||
class User implements Namespace { | ||
related: { | ||
manager: User[] | ||
} | ||
} | ||
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class Group implements Namespace { | ||
related: { | ||
members: (User | Group)[] | ||
} | ||
} | ||
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class Folder implements Namespace { | ||
related: { | ||
parents: File[] | ||
viewers: (User | SubjectSet<Group, "members">)[] | ||
} | ||
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permits = { | ||
view: (ctx: Context): boolean => this.related.viewers.includes(ctx.subject), | ||
} | ||
} | ||
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class File implements Namespace { | ||
related: { | ||
parents: (File | Folder)[] | ||
viewers: (User | SubjectSet<Group, "members">)[] | ||
owners: (User | SubjectSet<Group, "members">)[] | ||
siblings: File[] | ||
} | ||
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permits = { | ||
view: (ctx: Context): boolean => | ||
this.related.parents.traverse((p) => | ||
p.related.viewers.includes(ctx.subject), | ||
) || | ||
this.related.parents.traverse((p) => p.permits.view(ctx)) || | ||
this.related.viewers.includes(ctx.subject) || | ||
this.related.owners.includes(ctx.subject), | ||
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edit: (ctx: Context) => this.related.owners.includes(ctx.subject), | ||
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rename: (ctx: Context) => | ||
this.related.siblings.traverse((s) => s.permits.edit(ctx)), | ||
} | ||
} | ||
``` |