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Jérome Perrin
gitlab-ce
Commits
80d6e5bb
Commit
80d6e5bb
authored
Apr 06, 2017
by
http://jneen.net/
Browse files
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add a new DeclarativePolicy framework
parent
585e6aa5
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+1220
-0
lib/declarative_policy.rb
lib/declarative_policy.rb
+58
-0
lib/declarative_policy/base.rb
lib/declarative_policy/base.rb
+329
-0
lib/declarative_policy/cache.rb
lib/declarative_policy/cache.rb
+32
-0
lib/declarative_policy/condition.rb
lib/declarative_policy/condition.rb
+102
-0
lib/declarative_policy/dsl.rb
lib/declarative_policy/dsl.rb
+103
-0
lib/declarative_policy/preferred_scope.rb
lib/declarative_policy/preferred_scope.rb
+28
-0
lib/declarative_policy/rule.rb
lib/declarative_policy/rule.rb
+301
-0
lib/declarative_policy/runner.rb
lib/declarative_policy/runner.rb
+181
-0
lib/declarative_policy/step.rb
lib/declarative_policy/step.rb
+86
-0
No files found.
lib/declarative_policy.rb
0 → 100644
View file @
80d6e5bb
require_dependency
'declarative_policy/cache'
require_dependency
'declarative_policy/condition'
require_dependency
'declarative_policy/dsl'
require_dependency
'declarative_policy/preferred_scope'
require_dependency
'declarative_policy/rule'
require_dependency
'declarative_policy/runner'
require_dependency
'declarative_policy/step'
require_dependency
'declarative_policy/base'
module
DeclarativePolicy
class
<<
self
def
policy_for
(
user
,
subject
,
opts
=
{})
cache
=
opts
[
:cache
]
||
{}
key
=
Cache
.
policy_key
(
user
,
subject
)
cache
[
key
]
||=
class_for
(
subject
).
new
(
user
,
subject
,
opts
)
end
def
class_for
(
subject
)
return
GlobalPolicy
if
subject
==
:global
return
NilPolicy
if
subject
.
nil?
subject
=
find_delegate
(
subject
)
subject
.
class
.
ancestors
.
each
do
|
klass
|
next
unless
klass
.
name
begin
policy_class
=
"
#{
klass
.
name
}
Policy"
.
constantize
# NOTE: the < operator here tests whether policy_class
# inherits from Base. We can't use #is_a? because that
# tests for *instances*, not *subclasses*.
return
policy_class
if
policy_class
<
Base
rescue
NameError
nil
end
end
raise
"no policy for
#{
subject
.
class
.
name
}
"
end
private
def
find_delegate
(
subject
)
seen
=
Set
.
new
while
subject
.
respond_to?
(
:declarative_policy_delegate
)
raise
ArgumentError
,
"circular delegations"
if
seen
.
include?
(
subject
.
object_id
)
seen
<<
subject
.
object_id
subject
=
subject
.
declarative_policy_delegate
end
subject
end
end
end
lib/declarative_policy/base.rb
0 → 100644
View file @
80d6e5bb
module
DeclarativePolicy
class
Base
# A map of ability => list of rules together with :enable
# or :prevent actions. Used to look up which rules apply to
# a given ability. See Base.ability_map
class
AbilityMap
attr_reader
:map
def
initialize
(
map
=
{})
@map
=
map
end
# This merge behavior is different than regular hashes - if both
# share a key, the values at that key are concatenated, rather than
# overridden.
def
merge
(
other
)
conflict_proc
=
proc
{
|
key
,
my_val
,
other_val
|
my_val
+
other_val
}
AbilityMap
.
new
(
@map
.
merge
(
other
.
map
,
&
conflict_proc
))
end
def
actions
(
key
)
@map
[
key
]
||=
[]
end
def
enable
(
key
,
rule
)
actions
(
key
)
<<
[
:enable
,
rule
]
end
def
prevent
(
key
,
rule
)
actions
(
key
)
<<
[
:prevent
,
rule
]
end
end
class
<<
self
# The `own_ability_map` vs `ability_map` distinction is used so that
# the data structure is properly inherited - with subclasses recursively
# merging their parent class.
#
# This pattern is also used for conditions, global_actions, and delegations.
def
ability_map
if
self
==
Base
own_ability_map
else
superclass
.
ability_map
.
merge
(
own_ability_map
)
end
end
def
own_ability_map
@own_ability_map
||=
AbilityMap
.
new
end
# an inheritable map of conditions, by name
def
conditions
if
self
==
Base
own_conditions
else
superclass
.
conditions
.
merge
(
own_conditions
)
end
end
def
own_conditions
@own_conditions
||=
{}
end
# a list of global actions, generated by `prevent_all`. these aren't
# stored in `ability_map` because they aren't indexed by a particular
# ability.
def
global_actions
if
self
==
Base
own_global_actions
else
superclass
.
global_actions
+
own_global_actions
end
end
def
own_global_actions
@own_global_actions
||=
[]
end
# an inheritable map of delegations, indexed by name (which may be
# autogenerated)
def
delegations
if
self
==
Base
own_delegations
else
superclass
.
delegations
.
merge
(
own_delegations
)
end
end
def
own_delegations
@own_delegations
||=
{}
end
# all the [rule, action] pairs that apply to a particular ability.
# we combine the specific ones looked up in ability_map with the global
# ones.
def
configuration_for
(
ability
)
ability_map
.
actions
(
ability
)
+
global_actions
end
### declaration methods ###
def
delegate
(
name
=
nil
,
&
delegation_block
)
if
name
.
nil?
@delegate_name_counter
||=
0
@delegate_name_counter
+=
1
name
=
:"anonymous_
#{
@delegate_name_counter
}
"
end
name
=
name
.
to_sym
if
delegation_block
.
nil?
delegation_block
=
proc
{
@subject
.
__send__
(
name
)
}
end
own_delegations
[
name
]
=
delegation_block
end
# Declares a rule, constructed using RuleDsl, and returns
# a PolicyDsl which is used for registering the rule with
# this class. PolicyDsl will call back into Base.enable_when,
# Base.prevent_when, and Base.prevent_all_when.
def
rule
(
&
b
)
rule
=
RuleDsl
.
new
(
self
).
instance_eval
(
&
b
)
PolicyDsl
.
new
(
self
,
rule
)
end
# A hash in which to store calls to `desc` and `with_scope`, etc.
def
last_options
@last_options
||=
{}.
with_indifferent_access
end
# retrieve and zero out the previously set options (used in .condition)
def
last_options!
last_options
.
tap
{
@last_options
=
nil
}
end
# Declare a description for the following condition. Currently unused,
# but opens the potential for explaining to users why they were or were
# not able to do something.
def
desc
(
description
)
last_options
[
:description
]
=
description
end
def
with_options
(
opts
=
{})
last_options
.
merge!
(
opts
)
end
def
with_scope
(
scope
)
with_options
scope:
scope
end
def
with_score
(
score
)
with_options
score:
score
end
# Declares a condition. It gets stored in `own_conditions`, and generates
# a query method based on the condition's name.
def
condition
(
name
,
opts
=
{},
&
value
)
name
=
name
.
to_sym
opts
=
last_options!
.
merge
(
opts
)
opts
[
:context_key
]
||=
self
.
name
condition
=
Condition
.
new
(
name
,
opts
,
&
value
)
self
.
own_conditions
[
name
]
=
condition
define_method
(
:"
#{
name
}
?"
)
{
condition
(
name
).
pass?
}
end
# These next three methods are mainly called from PolicyDsl,
# and are responsible for "inverting" the relationship between
# an ability and a rule. We store in `ability_map` a map of
# abilities to rules that affect them, together with a
# symbol indicating :prevent or :enable.
def
enable_when
(
abilities
,
rule
)
abilities
.
each
{
|
a
|
own_ability_map
.
enable
(
a
,
rule
)
}
end
def
prevent_when
(
abilities
,
rule
)
abilities
.
each
{
|
a
|
own_ability_map
.
prevent
(
a
,
rule
)
}
end
# we store global prevents (from `prevent_all`) separately,
# so that they can be combined into every decision made.
def
prevent_all_when
(
rule
)
own_global_actions
<<
[
:prevent
,
rule
]
end
end
# A policy object contains a specific user and subject on which
# to compute abilities. For this reason it's sometimes called
# "context" within the framework.
#
# It also stores a reference to the cache, so it can be used
# to cache computations by e.g. ManifestCondition.
attr_reader
:user
,
:subject
,
:cache
def
initialize
(
user
,
subject
,
opts
=
{})
@user
=
user
@subject
=
subject
@cache
=
opts
[
:cache
]
||
{}
end
# helper for checking abilities on this and other subjects
# for the current user.
def
can?
(
ability
,
new_subject
=
:_self
)
return
allowed?
(
ability
)
if
new_subject
==
:_self
policy_for
(
new_subject
).
allowed?
(
ability
)
end
# This is the main entry point for permission checks. It constructs
# or looks up a Runner for the given ability and asks it if it passes.
def
allowed?
(
*
abilities
)
abilities
.
all?
{
|
a
|
runner
(
a
).
pass?
}
end
# The inverse of #allowed?, used mainly in specs.
def
disallowed?
(
*
abilities
)
abilities
.
all?
{
|
a
|
!
runner
(
a
).
pass?
}
end
# computes the given ability and prints a helpful debugging output
# showing which
def
debug
(
ability
,
*
a
)
runner
(
ability
).
debug
(
*
a
)
end
desc
"Unknown user"
condition
(
:anonymous
,
scope: :user
,
score:
0
)
{
@user
.
nil?
}
desc
"By default"
condition
(
:default
,
scope: :global
,
score:
0
)
{
true
}
def
repr
subject_repr
=
if
@subject
.
respond_to?
(
:id
)
"
#{
@subject
.
class
.
name
}
/
#{
@subject
.
id
}
"
else
@subject
.
inspect
end
user_repr
=
if
@user
@user
.
to_reference
else
"<anonymous>"
end
"(
#{
user_repr
}
:
#{
subject_repr
}
)"
end
def
inspect
"#<
#{
self
.
class
.
name
}
#{
repr
}
>"
end
# returns a Runner for the given ability, capable of computing whether
# the ability is allowed. Runners are cached on the policy (which itself
# is cached on @cache), and caches its result. This is how we perform caching
# at the ability level.
def
runner
(
ability
)
ability
=
ability
.
to_sym
@runners
||=
{}
@runners
[
ability
]
||=
begin
delegated_runners
=
delegated_policies
.
values
.
compact
.
map
{
|
p
|
p
.
runner
(
ability
)
}
own_runner
=
Runner
.
new
(
own_steps
(
ability
))
delegated_runners
.
inject
(
own_runner
,
&
:merge_runner
)
end
end
# Helpers for caching. Used by ManifestCondition in performing condition
# computation.
#
# NOTE we can't use ||= here because the value might be the
# boolean `false`
def
cache
(
key
,
&
b
)
return
@cache
[
key
]
if
cached?
(
key
)
@cache
[
key
]
=
yield
end
def
cached?
(
key
)
!
@cache
[
key
].
nil?
end
# returns a ManifestCondition capable of computing itself. The computation
# will use our own @cache.
def
condition
(
name
)
name
=
name
.
to_sym
@_conditions
||=
{}
@_conditions
[
name
]
||=
begin
raise
"invalid condition
#{
name
}
"
unless
self
.
class
.
conditions
.
key?
(
name
)
ManifestCondition
.
new
(
self
.
class
.
conditions
[
name
],
self
)
end
end
# used in specs - returns true if there is no possible way for any action
# to be allowed, determined only by the global :prevent_all rules.
def
banned?
global_steps
=
self
.
class
.
global_actions
.
map
{
|
(
action
,
rule
)
|
Step
.
new
(
self
,
rule
,
action
)
}
!
Runner
.
new
(
global_steps
).
pass?
end
# A list of other policies that we've delegated to (see `Base.delegate`)
def
delegated_policies
@delegated_policies
||=
self
.
class
.
delegations
.
transform_values
do
|
block
|
new_subject
=
instance_eval
(
&
block
)
# never delegate to nil, as that would immediately prevent_all
next
if
new_subject
.
nil?
policy_for
(
new_subject
)
end
end
def
policy_for
(
other_subject
)
DeclarativePolicy
.
policy_for
(
@user
,
other_subject
,
cache:
@cache
)
end
protected
# constructs steps that come from this policy and not from any delegations
def
own_steps
(
ability
)
rules
=
self
.
class
.
configuration_for
(
ability
)
rules
.
map
{
|
(
action
,
rule
)
|
Step
.
new
(
self
,
rule
,
action
)
}
end
end
end
lib/declarative_policy/cache.rb
0 → 100644
View file @
80d6e5bb
module
DeclarativePolicy
module
Cache
class
<<
self
def
user_key
(
user
)
return
'<anonymous>'
if
user
.
nil?
id_for
(
user
)
end
def
policy_key
(
user
,
subject
)
u
=
user_key
(
user
)
s
=
subject_key
(
subject
)
"/dp/policy/
#{
u
}
/
#{
s
}
"
end
def
subject_key
(
subject
)
return
'<nil>'
if
subject
.
nil?
return
subject
.
inspect
if
subject
.
is_a?
(
Symbol
)
"
#{
subject
.
class
.
name
}
:
#{
id_for
(
subject
)
}
"
end
private
def
id_for
(
obj
)
if
obj
.
respond_to?
(
:id
)
&&
obj
.
id
obj
.
id
.
to_s
else
"#
#{
obj
.
object_id
}
"
end
end
end
end
end
lib/declarative_policy/condition.rb
0 → 100644
View file @
80d6e5bb
module
DeclarativePolicy
# A Condition is the data structure that is created by the
# `condition` declaration on DeclarativePolicy::Base. It is
# more or less just a struct of the data passed to that
# declaration. It holds on to the block to be instance_eval'd
# on a context (instance of Base) later, via #compute.
class
Condition
attr_reader
:name
,
:description
,
:scope
attr_reader
:manual_score
attr_reader
:context_key
def
initialize
(
name
,
opts
=
{},
&
compute
)
@name
=
name
@compute
=
compute
@scope
=
opts
.
fetch
(
:scope
,
:normal
)
@description
=
opts
.
delete
(
:description
)
@context_key
=
opts
[
:context_key
]
@manual_score
=
opts
.
fetch
(
:score
,
nil
)
end
def
compute
(
context
)
!!
context
.
instance_eval
(
&
@compute
)
end
def
key
"
#{
@context_key
}
/
#{
@name
}
"
end
end
# In contrast to a Condition, a ManifestCondition contains
# a Condition and a context object, and is capable of calculating
# a result itself. This is the return value of Base#condition.
class
ManifestCondition
def
initialize
(
condition
,
context
)
@condition
=
condition
@context
=
context
end
# The main entry point - does this condition pass? We reach into
# the context's cache here so that we can share in the global
# cache (often RequestStore or similar).
def
pass?
@context
.
cache
(
cache_key
)
{
@condition
.
compute
(
@context
)
}
end
# Whether we've already computed this condition.
def
cached?
@context
.
cached?
(
cache_key
)
end
# This is used to score Rule::Condition. See Rule::Condition#score
# and Runner#steps_by_score for how scores are used.
#
# The number here is intended to represent, abstractly, how
# expensive it would be to calculate this condition.
#
# See #cache_key for info about @condition.scope.
def
score
# If we've been cached, no computation is necessary.
return
0
if
cached?
# Use the override from condition(score: ...) if present
return
@condition
.
manual_score
if
@condition
.
manual_score
# Global scope rules are cheap due to max cache sharing
return
2
if
@condition
.
scope
==
:global
# "Normal" rules can't share caches with any other policies
return
16
if
@condition
.
scope
==
:normal
# otherwise, we're :user or :subject scope, so it's 4 if
# the caller has declared a preference
return
4
if
@condition
.
scope
==
DeclarativePolicy
.
preferred_scope
# and 8 for all other :user or :subject scope conditions.
8
end
private
# This method controls the caching for the condition. This is where
# the condition(scope: ...) option comes into play. Notice that
# depending on the scope, we may cache only by the user or only by
# the subject, resulting in sharing across different policy objects.
def
cache_key
case
@condition
.
scope
when
:normal
then
"/dp/condition/
#{
@condition
.
key
}
/
#{
user_key
}
,
#{
subject_key
}
"
when
:user
then
"/dp/condition/
#{
@condition
.
key
}
/
#{
user_key
}
"
when
:subject
then
"/dp/condition/
#{
@condition
.
key
}
/
#{
subject_key
}
"
when
:global
then
"/dp/condition/
#{
@condition
.
key
}
"
else
raise
'invalid scope'
end
end
def
user_key
Cache
.
user_key
(
@context
.
user
)
end
def
subject_key
Cache
.
subject_key
(
@context
.
subject
)
end
end
end
lib/declarative_policy/dsl.rb
0 → 100644
View file @
80d6e5bb
module
DeclarativePolicy
# The DSL evaluation context inside rule { ... } blocks.
# Responsible for creating and combining Rule objects.
#
# See Base.rule
class
RuleDsl
def
initialize
(
context_class
)
@context_class
=
context_class
end
def
can?
(
ability
)
Rule
::
Ability
.
new
(
ability
)
end
def
all?
(
*
rules
)
Rule
::
And
.
make
(
rules
)
end
def
any?
(
*
rules
)
Rule
::
Or
.
make
(
rules
)
end
def
none?
(
*
rules
)
~
Rule
::
Or
.
new
(
rules
)
end
def
cond
(
condition
)
Rule
::
Condition
.
new
(
condition
)
end
def
delegate
(
delegate_name
,
condition
)
Rule
::
DelegatedCondition
.
new
(
delegate_name
,
condition
)
end
def
method_missing
(
m
,
*
a
,
&
b
)
return
super
unless
a
.
size
==
0
&&
!
block_given?
if
@context_class
.
delegations
.
key?
(
m
)
DelegateDsl
.
new
(
self
,
m
)
else
cond
(
m
.
to_sym
)
end
end
end
# Used when the name of a delegate is mentioned in
# the rule DSL.
class
DelegateDsl
def
initialize
(
rule_dsl
,
delegate_name
)
@rule_dsl
=
rule_dsl
@delegate_name
=
delegate_name
end
def
method_missing
(
m
,
*
a
,
&
b
)
return
super
unless
a
.
size
==
0
&&
!
block_given?
@rule_dsl
.
delegate
(
@delegate_name
,
m
)
end
end
# The return value of a rule { ... } declaration.
# Can call back to register rules with the containing
# Policy class (context_class here). See Base.rule
#
# Note that the #policy method just performs an #instance_eval,
# which is useful for multiple #enable or #prevent callse.
#
# Also provides a #method_missing proxy to the context
# class's class methods, so that helper methods can be
# defined and used in a #policy { ... } block.
class
PolicyDsl
def
initialize
(
context_class
,
rule
)
@context_class
=
context_class
@rule
=
rule
end
def
policy
(
&
b
)
instance_eval
(
&
b
)
end
def
enable
(
*
abilities
)
@context_class
.
enable_when
(
abilities
,
@rule
)
end
def
prevent
(
*
abilities
)
@context_class
.
prevent_when
(
abilities
,
@rule
)
end
def
prevent_all
@context_class
.
prevent_all_when
(
@rule
)
end
def
method_missing
(
m
,
*
a
,
&
b
)
return
super
unless
@context_class
.
respond_to?
(
m
)
@context_class
.
__send__
(
m
,
*
a
,
&
b
)
end
def
respond_to_missing?
(
m
)
@context_class
.
respond_to?
(
m
)
||
super
end
end
end
lib/declarative_policy/preferred_scope.rb
0 → 100644
View file @
80d6e5bb
module
DeclarativePolicy
PREFERRED_SCOPE_KEY
=
:"DeclarativePolicy.preferred_scope"
class
<<
self
def
with_preferred_scope
(
scope
,
&
b
)
Thread
.
current
[
PREFERRED_SCOPE_KEY
],
old_scope
=
scope
,
Thread
.
current
[
PREFERRED_SCOPE_KEY
]
yield
ensure
Thread
.
current
[
PREFERRED_SCOPE_KEY
]
=
old_scope
end
def
preferred_scope
Thread
.
current
[
PREFERRED_SCOPE_KEY
]
end
def
user_scope
(
&
b
)
with_preferred_scope
(
:user
,
&
b
)
end
def
subject_scope
(
&
b
)
with_preferred_scope
(
:subject
,
&
b
)
end
def
preferred_scope
=
(
scope
)
Thread
.
current
[
PREFERRED_SCOPE_KEY
]
=
scope
end
end
end
lib/declarative_policy/rule.rb
0 → 100644
View file @
80d6e5bb
module
DeclarativePolicy
module
Rule
# A Rule is the object that results from the `rule` declaration,
# usually built using the DSL in `RuleDsl`. It is a basic logical
# combination of building blocks, and is capable of deciding,
# given a context (instance of DeclarativePolicy::Base) whether it
# passes or not. Note that this decision doesn't by itself know
# how that affects the actual ability decision - for that, a
# `Step` is used.
class
Base
def
self
.
make
(
*
a
)
new
(
*
a
).
simplify
end
# true or false whether this rule passes.
# `context` is a policy - an instance of
# DeclarativePolicy::Base.
def
pass?
(
context
)
raise
'abstract'
end
# same as #pass? except refuses to do any I/O,
# returning nil if the result is not yet cached.
# used for accurately scoring And/Or
def
cached_pass?
(
context
)
raise
'abstract'
end
# abstractly, how long would it take to compute
# this rule? lower-scored rules are tried first.
def
score
(
context
)
raise
'abstract'
end
# unwrap double negatives and nested and/or
def
simplify
self
end
# convenience combination methods
def
or
(
other
)
Or
.
make
([
self
,
other
])
end
def
and
(
other
)
And
.
make
([
self
,
other
])
end
def
negate
Not
.
make
(
self
)
end
alias_method
:|
,
:or
alias_method
:&
,
:and
alias_method
:~
@
,
:negate
def
inspect
"#<Rule
#{
repr
}
>"
end
end
# A rule that checks a condition. This is the
# type of rule that results from a basic bareword
# in the rule dsl (see RuleDsl#method_missing).
class
Condition
<
Base
def
initialize
(
name
)
@name
=
name
end
# we delegate scoring to the condition. See
# ManifestCondition#score.
def
score
(
context
)
context
.
condition
(
@name
).
score
end
# Let the ManifestCondition from the context
# decide whether we pass.
def
pass?
(
context
)
context
.
condition
(
@name
).
pass?
end
# returns nil unless it's already cached
def
cached_pass?
(
context
)
condition
=
context
.
condition
(
@name
)
return
nil
unless
condition
.
cached?
condition
.
pass?
end
def
description
(
context
)
context
.
class
.
conditions
[
@name
].
description
end
def
repr
@name
.
to_s
end
end
# A rule constructed from DelegateDsl - using a condition from a
# delegated policy.
class
DelegatedCondition
<
Base
# Internal use only - this is rescued each time it's raised.
MissingDelegate
=
Class
.
new
(
StandardError
)
def
initialize
(
delegate_name
,
name
)
@delegate_name
=
delegate_name
@name
=
name
end
def
delegated_context
(
context
)
policy
=
context
.
delegated_policies
[
@delegate_name
]
raise
MissingDelegate
if
policy
.
nil?
policy
end
def
score
(
context
)
delegated_context
(
context
).
condition
(
@name
).
score
rescue
MissingDelegate
0
end
def
cached_pass?
(
context
)
condition
=
delegated_context
(
context
).
condition
(
@name
)
return
nil
unless
condition
.
cached?
condition
.
pass?
rescue
MissingDelegate
false
end
def
pass?
(
context
)
delegated_context
(
context
).
condition
(
@name
).
pass?
rescue
MissingDelegate
false
end
def
repr
"
#{
@delegate_name
}
.
#{
@name
}
"
end
end
# A rule constructed from RuleDsl#can?. Computes a different ability
# on the same subject.
class
Ability
<
Base
attr_reader
:ability
def
initialize
(
ability
)
@ability
=
ability
end
# We ask the ability's runner for a score
def
score
(
context
)
context
.
runner
(
@ability
).
score
end
def
pass?
(
context
)
context
.
allowed?
(
@ability
)
end
def
cached_pass?
(
context
)
runner
=
context
.
runner
(
@ability
)
return
nil
unless
runner
.
cached?
runner
.
pass?
end
def
description
(
context
)
"User can
#{
@ability
.
inspect
}
"
end
def
repr
"can?(
#{
@ability
.
inspect
}
)"
end
end
# Logical `and`, containing a list of rules. Only passes
# if all of them do.
class
And
<
Base
attr_reader
:rules
def
initialize
(
rules
)
@rules
=
rules
end
def
simplify
simplified_rules
=
@rules
.
flat_map
do
|
rule
|
simplified
=
rule
.
simplify
case
simplified
when
And
then
simplified
.
rules
else
[
simplified
]
end
end
And
.
new
(
simplified_rules
)
end
def
score
(
context
)
return
0
unless
cached_pass?
(
context
).
nil?
# note that cached rules will have score 0 anyways.
@rules
.
map
{
|
r
|
r
.
score
(
context
)
}.
inject
(
0
,
:
+
)
end
def
pass?
(
context
)
# try to find a cached answer before
# checking in order
cached
=
cached_pass?
(
context
)
return
cached
unless
cached
.
nil?
@rules
.
all?
{
|
r
|
r
.
pass?
(
context
)
}
end
def
cached_pass?
(
context
)
passes
=
@rules
.
map
{
|
r
|
r
.
cached_pass?
(
context
)
}
return
false
if
passes
.
any?
{
|
p
|
p
==
false
}
return
true
if
passes
.
all?
{
|
p
|
p
==
true
}
nil
end
def
repr
"all?(
#{
rules
.
map
(
&
:repr
).
join
(
', '
)
}
)"
end
end
# Logical `or`. Mirrors And.
class
Or
<
Base
attr_reader
:rules
def
initialize
(
rules
)
@rules
=
rules
end
def
pass?
(
context
)
cached
=
cached_pass?
(
context
)
return
cached
unless
cached
.
nil?
@rules
.
any?
{
|
r
|
r
.
pass?
(
context
)
}
end
def
simplify
simplified_rules
=
@rules
.
flat_map
do
|
rule
|
simplified
=
rule
.
simplify
case
simplified
when
Or
then
simplified
.
rules
else
[
simplified
]
end
end
Or
.
new
(
simplified_rules
)
end
def
cached_pass?
(
context
)
passes
=
@rules
.
map
{
|
r
|
r
.
cached_pass?
(
context
)
}
return
true
if
passes
.
any?
{
|
p
|
p
==
true
}
return
false
if
passes
.
all?
{
|
p
|
p
==
false
}
nil
end
def
score
(
context
)
return
0
unless
cached_pass?
(
context
).
nil?
@rules
.
map
{
|
r
|
r
.
score
(
context
)
}.
inject
(
0
,
:
+
)
end
def
repr
"any?(
#{
@rules
.
map
(
&
:repr
).
join
(
', '
)
}
)"
end
end
class
Not
<
Base
attr_reader
:rule
def
initialize
(
rule
)
@rule
=
rule
end
def
simplify
case
@rule
when
And
then
Or
.
new
(
@rule
.
rules
.
map
(
&
:negate
)).
simplify
when
Or
then
And
.
new
(
@rule
.
rules
.
map
(
&
:negate
)).
simplify
when
Not
then
@rule
.
rule
.
simplify
else
Not
.
new
(
@rule
.
simplify
)
end
end
def
pass?
(
context
)
!
@rule
.
pass?
(
context
)
end
def
cached_pass?
(
context
)
case
@rule
.
cached_pass?
(
context
)
when
nil
then
nil
when
true
then
false
when
false
then
true
end
end
def
score
(
context
)
@rule
.
score
(
context
)
end
def
repr
"~
#{
@rule
.
repr
}
"
end
end
end
end
lib/declarative_policy/runner.rb
0 → 100644
View file @
80d6e5bb
module
DeclarativePolicy
class
Runner
class
State
def
initialize
@enabled
=
false
@prevented
=
false
end
def
enable!
@enabled
=
true
end
def
enabled?
@enabled
end
def
prevent!
@prevented
=
true
end
def
prevented?
@prevented
end
def
pass?
!
prevented?
&&
enabled?
end
end
# a Runner contains a list of Steps to be run.
attr_reader
:steps
def
initialize
(
steps
)
@steps
=
steps
end
# We make sure only to run any given Runner once,
# and just continue to use the resulting @state
# that's left behind.
def
cached?
!!
@state
end
# used by Rule::Ability. See #steps_by_score
def
score
return
0
if
cached?
steps
.
map
(
&
:score
).
inject
(
0
,
:
+
)
end
def
merge_runner
(
other
)
Runner
.
new
(
@steps
+
other
.
steps
)
end
# The main entry point, called for making an ability decision.
# See #run and DeclarativePolicy::Base#can?
def
pass?
run
unless
cached?
@state
.
pass?
end
# see DeclarativePolicy::Base#debug
def
debug
(
out
=
$stderr
)
run
(
out
)
end
private
def
flatten_steps!
@steps
=
@steps
.
flat_map
{
|
s
|
s
.
flattened
(
@steps
)
}
end
# This method implements the semantic of "one enable and no prevents".
# It relies on #steps_by_score for the main loop, and updates @state
# with the result of the step.
def
run
(
debug
=
nil
)
@state
=
State
.
new
steps_by_score
do
|
step
,
score
|
passed
=
nil
case
step
.
action
when
:enable
then
# we only check :enable actions if they have a chance of
# changing the outcome - if no other rule has enabled or
# prevented.
unless
@state
.
enabled?
||
@state
.
prevented?
passed
=
step
.
pass?
@state
.
enable!
if
passed
end
debug
<<
inspect_step
(
step
,
score
,
passed
)
if
debug
when
:prevent
then
# we only check :prevent actions if the state hasn't already
# been prevented.
unless
@state
.
prevented?
passed
=
step
.
pass?
if
passed
@state
.
prevent!
return
unless
debug
end
end
debug
<<
inspect_step
(
step
,
score
,
passed
)
if
debug
else
raise
"invalid action
#{
step
.
action
.
inspect
}
"
end
end
@state
end
# This is the core spot where all those `#score` methods matter.
# It is critcal for performance to run steps in the correct order,
# so that we don't compute expensive conditions (potentially n times
# if we're called on, say, a large list of users).
#
# In order to determine the cheapest step to run next, we rely on
# Step#score, which returns a numerical rating of how expensive
# it would be to calculate - the lower the better. It would be
# easy enough to statically sort by these scores, but we can do
# a little better - the scores are cache-aware (conditions that
# are already in the cache have score 0), which means that running
# a step can actually change the scores of other steps.
#
# So! The way we sort here involves re-scoring at every step. This
# is by necessity quadratic, but most of the time the number of steps
# will be low. But just in case, if the number of steps exceeds 50,
# we print a warning and fall back to a static sort.
#
# For each step, we yield the step object along with the computed score
# for debugging purposes.
def
steps_by_score
(
&
b
)
flatten_steps!
if
@steps
.
size
>
50
warn
"DeclarativePolicy: large number of steps (
#{
steps
.
size
}
), falling back to static sort"
@steps
.
map
{
|
s
|
[
s
.
score
,
s
]
}.
sort_by
{
|
(
score
,
_
)
|
score
}.
each
do
|
(
score
,
step
)
|
yield
step
,
score
end
return
end
steps
=
Set
.
new
(
@steps
)
loop
do
return
if
steps
.
empty?
# if the permission hasn't yet been enabled and we only have
# prevent steps left, we short-circuit the state here
@state
.
prevent!
if
!
@state
.
enabled?
&&
steps
.
all?
(
&
:prevent?
)
lowest_score
=
Float
::
INFINITY
next_step
=
nil
steps
.
each
do
|
step
|
score
=
step
.
score
if
score
<
lowest_score
next_step
=
step
lowest_score
=
score
end
end
steps
.
delete
(
next_step
)
yield
next_step
,
lowest_score
end
end
# Formatter for debugging output.
def
inspect_step
(
step
,
original_score
,
passed
)
symbol
=
case
passed
when
true
then
'+'
when
false
then
'-'
when
nil
then
' '
end
"
#{
symbol
}
[
#{
original_score
.
to_i
}
]
#{
step
.
repr
}
\n
"
end
end
end
lib/declarative_policy/step.rb
0 → 100644
View file @
80d6e5bb
module
DeclarativePolicy
# This object represents one step in the runtime decision of whether
# an ability is allowed. It contains a Rule and a context (instance
# of DeclarativePolicy::Base), which contains the user, the subject,
# and the cache. It also contains an "action", which is the symbol
# :prevent or :enable.
class
Step
attr_reader
:context
,
:rule
,
:action
def
initialize
(
context
,
rule
,
action
)
@context
=
context
@rule
=
rule
@action
=
action
end
# In the flattening process, duplicate steps may be generated in the
# same rule. This allows us to eliminate those (see Runner#steps_by_score
# and note its use of a Set)
def
==
(
other
)
@context
==
other
.
context
&&
@rule
==
other
.
rule
&&
@action
==
other
.
action
end
# In the runner, steps are sorted dynamically by score, so that
# we are sure to compute them in close to the optimal order.
#
# See also Rule#score, ManifestCondition#score, and Runner#steps_by_score.
def
score
# we slightly prefer the preventative actions
# since they are more likely to short-circuit
case
@action
when
:prevent
@rule
.
score
(
@context
)
*
(
7.0
/
8
)
when
:enable
@rule
.
score
(
@context
)
end
end
def
with_action
(
action
)
Step
.
new
(
@context
,
@rule
,
action
)
end
def
enable?
@action
==
:enable
end
def
prevent?
@action
==
:prevent
end
# This rather complex method allows us to split rules into parts so that
# they can be sorted independently for better optimization
def
flattened
(
roots
)
case
@rule
when
Rule
::
Or
# A single `Or` step is the same as each of its elements as separate steps
@rule
.
rules
.
flat_map
{
|
r
|
Step
.
new
(
@context
,
r
,
@action
).
flattened
(
roots
)
}
when
Rule
::
Ability
# This looks like a weird micro-optimization but it buys us quite a lot
# in some cases. If we depend on an Ability (i.e. a `can?(...)` rule),
# and that ability *only* has :enable actions (modulo some actions that
# we already have taken care of), then its rules can be safely inlined.
steps
=
@context
.
runner
(
@rule
.
ability
).
steps
.
reject
{
|
s
|
roots
.
include?
(
s
)
}
if
steps
.
all?
(
&
:enable?
)
# in the case that we are a :prevent step, each inlined step becomes
# an independent :prevent, even though it was an :enable in its initial
# context.
steps
.
map!
{
|
s
|
s
.
with_action
(
:prevent
)
}
if
prevent?
steps
.
flat_map
{
|
s
|
s
.
flattened
(
roots
)
}
else
[
self
]
end
else
[
self
]
end
end
def
pass?
@rule
.
pass?
(
@context
)
end
def
repr
"
#{
@action
}
when
#{
@rule
.
repr
}
(
#{
@context
.
repr
}
)"
end
end
end
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