--- a/doc/book/en/03-sect-definition-schema.en.txt Fri Nov 21 17:36:42 2008 +0100
+++ /dev/null Thu Jan 01 00:00:00 1970 +0000
@@ -1,344 +0,0 @@
-.. -*- coding: utf-8 -*-
-
-Entity type definition
-----------------------
-
-An entity type is defined by a Python class which inherits `EntityType`. The
-class name correponds to the type name. Then the content of the class contains
-the description of attributes and relations for the defined entity type,
-by example ::
-
- class Personne(EntityType):
- """A person with the properties and the relations necessarry for my
- application"""
-
- last_name = String(required=True, fulltextindexed=True)
- first_name = String(required=True, fulltextindexed=True)
- title = String(vocabulary=('M', 'Mme', 'Mlle'))
- date_of_birth = Date()
- works_for = SubjectRelation('Company', cardinality='?*')
-
-* the name of the Python attribute corresponds to the name of the attribute
- or the relation in `LAX` application.
-
-* all built-in types are available: `String`, `Int`, `Float`,
- `Boolean`, `Date`, `Datetime`, `Time`, `Byte`.
-
-* each entity has at least the following meta-relations:
-
- - `eid` (`Int`)
-
- - `creation_date` (`Datetime`)
-
- - `modification_date` (`Datetime`)
-
- - `created_by` (`EUser`) (which user created the entity)
-
- - `owned_by` (`EUser`) (who does the entity belongs to, by default the
- creator but not necessarry and it could have multiple owners)
-
- - `is` (`EEType`)
-
-
-* it is also possible to define relations of type object by using `ObjectRelation`
- instead of `SubjectRelation`
-
-* the first argument of `SubjectRelation` and `ObjectRelation` gives respectively
- the object/subject entity type of the relation. This could be:
-
- * a string corresponding to an entity type
-
- * a tuple of string correponding to multiple entities types
-
- * special string such as follows:
-
- - "**" : all types of entities
- - "*" : all types of entities non meta
- - "@" : all types of meta entities but not system entities (e.g. used for
- the basis schema description)
-
-* it is possible to use the attribute `meta` to flag an entity type as a `meta`
- (e.g. used to describe/categorize other entities)
-
-* optional properties for attributes and relations:
-
- - `description` : string describing an attribute or a relation. By default
- this string will be used in the editing form of the entity, which means
- that it is supposed to help the end-user and should be flagged by the
- function `_` to be properly internationalized.
-
- - `constraints` : list of conditions/constraints that the relation needs to
- satisfy (c.f. `Contraints`_)
-
- - `cardinality` : two characters string which specify the cardinality of the
- relation. The first character defines the cardinality of the relation on
- the subject, the second on the object of the relation. When a relation
- has multiple possible subjects or objects, the cardinality applies to all
- and not on a one to one basis (so it must be consistent...). The possible
- values are inspired from regular expressions syntax:
-
- * `1`: 1..1
- * `?`: 0..1
- * `+`: 1..n
- * `*`: 0..n
-
- - `meta` : boolean indicating that the relation is a meta-relation (false by
- default)
-
-* optionnal properties for attributes:
-
- - `required` : boolean indicating if the attribute is required (false by default)
-
- - `unique` : boolean indicating if the value of the attribute has to be unique
- or not within all entities of the same type (false by default)
-
- - `indexed` : boolean indicating if an index needs to be created for this
- attribute in the database (false by default). This is usefull only if
- you know that you will have to run numerous searches on the value of this
- attribute.
-
- - `default` : default value of the attribute. In case of date types, the values
- which could be used correpond to the RQL keywords `TODAY` and `NOW`.
-
- - `vocabulary` : specify static possible values of an attribute
-
-* optionnal properties of type `String`:
-
- - `fulltextindexed` : boolean indicating if the attribute is part of
- the full text index (false by default) (*applicable on the type `Byte`
- as well*)
-
- - `internationalizable` : boolean indicating if the value of the attribute
- is internationalizable (false by default)
-
- - `maxsize` : integer providing the maximum size of the string (no limit by default)
-
-* optionnal properties for relations:
-
- - `composite` : string indicating that the subject (composite == 'subject')
- is composed of the objects of the relations. For the opposite case (when
- the object is composed of the subjects of the relation), we just need
- to set 'object' as the value. The composition implies that when the relation
- is deleted (so when the composite is deleted), the composed are also deleted.
- [PAS CLAIR]
-
-Contraints
-``````````
-By default, the available constraints types are:
-
-* `SizeConstraint` : allows to specify a minimum and/or maximum size on
- string (generic case of `maxsize`)
-
-* `BoundConstraint` : allows to specify a minimum and/or maximum value on
- numeric types
-
-* `UniqueConstraint` : identical to "unique=True"
-
-* `StaticVocabularyConstraint` : identical to "vocabulary=(...)"
-
-* `RQLConstraint` : allows to specify a RQL query that needs to be satisfied
- by the subject and/or the object of the relation. In this query the variables
- `S` and `O` are reserved for the entities subject and object of the
- relation.
-
-* `RQLVocabularyConstraint` : similar to the previous type of constraint except
- that it does not express a "strong" constraint, which means it is only used to
- restrict the values listed in the drop-down menu of editing form, but it does
- not prevent another entity to be selected
- [PAS CLAIR]
-
-
-Relation type definition
-------------------------
-
-A relation is defined by a Python class heriting `RelationType`. The name
-of the class corresponds to the name of the type. The class then contains
-a description of the properties of this type of relation, as well as a
-string for the subject and a string for the object. This allows to create
-new definition of associated relations, (so that the class can have the
-definition properties from the relation)[PAS CLAIR] by example ::
-
- class locked_by(RelationType):
- """relation on all entities indicating that they are locked"""
- inlined = True
- cardinality = '?*'
- subject = '*'
- object = 'EUser'
-
-In addition to the permissions, the own properties of the relation types
-(shared also by all definition of relation of this type) are:
-
-
-* `inlined` : boolean handling the physical optimization for archiving
- the relation in the subject entity table, instead of creating a specific
- table for the relation. This applies to the relation when the cardinality
- of subject->relation->object is 0..1 ('?') or 1..1 ('1')
-
-* `symetric` : boolean indication that the relation is symetrical, which
- means `X relation Y` implies `Y relation X`
-
-In the case of simultaneous relations definitions, `subject` and `object`
-can both be equal to the value of the first argument of `SubjectRelation`
-and `ObjectRelation`.
-
-When a relation is not inlined and not symetrical, and it does not require
-specific permissions, its definition (by using `SubjectRelation` and
-`ObjectRelation`) is all we need.
-
-Permissions definition
-----------------------
-
-Define permissions is set through to the attribute `permissions` of entities and
-relations types. It defines a dictionnary where the keys are the access types
-(action), and the values are the authorized groups or expressions.
-
-For an entity type, the possible actions are `read`, `add`, `update` and
-`delete`.
-
-For a relation type, the possible actions are `read`, `add`, and `delete`.
-
-For each access type, a tuple indicates the name of the authorized groups and/or
-one or multiple RQL expressions to satisfy to grant access. The access is
-provided once the user is in the listed groups or one of the RQL condition is
-satisfied.
-
-The standard groups are:
-
-* `guests`
-
-* `users`
-
-* `managers`
-
-* `owners` : virtual group corresponding to the entity's owner.
- This can only be used for the actions `update` and `delete` of an entity
- type.
-
-It is also possible to use specific groups if they are define in the precreate
-of the application (``migration/precreate.py``).
-
-Use of RQL expression for writing rights
-````````````````````````````````````````
-It is possible to define RQL expression to provide update permission
-(`add`, `delete` and `update`) on relation and entity types.
-
-RQL expression for entity type permission:
-
-* you have to use the class `ERQLExpression`
-
-* the used expression corresponds to the WHERE statement of an RQL query
-
-* in this expression, the variables X and U are pre-defined references
- respectively on the current entity (on which the action is verified) and
- on the user who send the request
-
-* it is possible to use, in this expression, a special relation
- "has_<ACTION>_permission" where the subject is the user and the
- object is a any variable, meaning that the user needs to have
- permission to execute the action <ACTION> on the entities related
- to this variable
-
-For RQL expressions on a relation type, the principles are the same except
-for the following:
-
-* you have to use the class `RQLExpression` in the case of a non-final relation
- [WHAT IS A NON FINALE RELATION]
-
-* in the expression, the variables S, O and U are pre-defined references
- to respectively the subject and the object of the current relation (on
- which the action is being verified) and the user who executed the query
-
-* we can also defined rights on attributes of an entity (non-final relation),
- knowing that:
-
- - to defines RQL expression, we have to use the class `ERQLExpression`
- in which X represents the entity the attribute belongs to
-
- - the permissions `add` and `delete` are equivalent. Only `add`/`read`
- are actually taken in consideration.
-
-
-
-In addition to thatm the entity type `EPermission` from the standard library
-allow to build very complex and dynamic security architecture. The schema of
-this entity type is as follow: ::
-
- class EPermission(MetaEntityType):
- """entity type that may be used to construct some advanced security configuration
- """
- name = String(required=True, indexed=True, internationalizable=True, maxsize=100)
- require_group = SubjectRelation('EGroup', cardinality='+*',
- description=_('groups to which the permission is granted'))
- require_state = SubjectRelation('State',
- description=_("entity'state in which the permission is applyable"))
- # can be used on any entity
- require_permission = ObjectRelation('**', cardinality='*1', composite='subject',
- description=_("link a permission to the entity. This "
- "permission should be used in the security "
- "definition of the entity's type to be useful."))
-
-
-Example of configuration ::
-
- ...
-
- class Version(EntityType):
- """a version is defining the content of a particular project's release"""
-
- permissions = {'read': ('managers', 'users', 'guests',),
- 'update': ('managers', 'logilab', 'owners',),
- 'delete': ('managers', ),
- 'add': ('managers', 'logilab',
- ERQLExpression('X version_of PROJ, U in_group G,'
- 'PROJ require_permission P, P name "add_version",'
- 'P require_group G'),)}
-
- ...
-
- class version_of(RelationType):
- """link a version to its project. A version is necessarily linked to one and only one project.
- """
- permissions = {'read': ('managers', 'users', 'guests',),
- 'delete': ('managers', ),
- 'add': ('managers', 'logilab',
- RRQLExpression('O require_permission P, P name "add_version",'
- 'U in_group G, P require_group G'),)
- }
- inlined = True
-
-This configuration assumes/indicates [???] that an entity `EPermission` named
-"add_version" can be associated to a project and provides rights to create
-new versions on this project to specific groups. It is important to notice that:
-
-* in such case, we have to protect both the entity type "Version" and the relation
- associating a version to a project ("version_of")
-
-* because of the genricity of the entity type `EPermission`, we have to execute
- a unification with the groups and/or the states if necessary in the expression
- ("U in_group G, P require_group G" in the above example)
-
-
-Use of RQL expression for reading rights
-````````````````````````````````````````
-
-The principles are the same but with the following restrictions:
-
-* we can not [??] `RRQLExpression` on relation types for reading
-
-* special relations "has_<ACTION>_permission" can not be used
-
-
-Note on the use of RQL expression for `add` permission
-``````````````````````````````````````````````````````
-Potentially, the use of an RQL expression to add an entity or a relation
-can cause problems for the user interface, because if the expression uses
-the entity or the relation to create, then we are not able to verify the
-permissions before we actually add the entity (please note that this is
-not a problem for the RQL server at all, because the permissions checks are
-done after the creation). In such case, the permission checks methods
-(check_perm, has_perm) can indicate that the user is not allowed to create
-this entity but can obtain the permission.
-To compensate this problem, it is usually necessary, for such case,
-to use an action that reflects the schema permissions but which enables
-to check properly the permissions so that it would show up if necessary.
-[PAS CLAIR]