My apologies, a better readme will follow.

Intellect

Info: Intellect is a Domain-specific language and Rules Engine for Python. Author: Michael Joseph Walsh

1. What is Intellect Intellect is a DSL (“Domain-Specific Language”) and Rule Engine for Python I authored for expressing policies to orchestrate and control a dynamic network defense cyber-security platform being researched in The MITRE Corporation’s Innovation Program. The rules engine provides an intellect, a form of artificial intelligence, a faculty of reasoning and understanding objectively over a working memory. The memory retains knowledge relevant to the system, and a set of rules authored in the DSL that describe a necessary behavior to achieve some goal. Each rule has an optional condition, and a suite of one or more actions. These actions either further direct the behavior of the system, and/or further inform the system. The engine starts with some facts, truths known about past or present circumstances, and uses rules to infer more facts. These facts fire more rules, that infer more facts and so on. For the platform in the Innovation Program, the network defender uses the DSL to confer policy, how the platform is to respond to network events mounted over covert network channels, but there are no direct ties written into the language nor the rule engine to cyber security and thus the system in its entirety can be more broadly used in other domains.

2. Installation To install via setuptools use easy_install -U Intellect

To install via pip use pip install Intellect

To install via pypm use pypm install intellect

Or download the latest source from Master or the most recent tagged release Tagged Releases, unpack, and run python setup.py install

3. Dependencies ANTLR3 Python Runtime 3.1.3

Python itself, if you don’t already have it. I tested the code on Python 2.7.1 and 2.7.2.

4. Contribution The source code is available under the BSD 4-clause license. If you have ideas, code, bug reports, or fixes you would like to contribute please do so. Bugs and feature requests can be filed at Github.

5. Background Many production rule system implementations have been open-sourced, such as JBoss Drools, Rools, Jess, Lisa, et cetera. If you’re familiar with the Drools syntax, Intellect’s syntax should look familiar. (I’m not saying it is based on it, because it is not entirely, but I found as I was working the syntax I would check with Drools and if made sense to push in the direction of Drools, this is what I did.) The aforementioned implementations are available for other languages for expressing production rules, but it is my belief that Python is under-represented, and as such it was my thought the language and rule engine could benefit from being open sourced, and so I put a request in. The MITRE Corporation granted release August 4, 2011. Thus, releasing the domain-specific language (DSL) and Rule Engine to Open Source in the hopes doing so will extend its use and increase its chances for possible adoption, while at the same time mature the project with more interested eyeballs being placed on it. Starting out, it was initially assumed the aforementioned platform would be integrated with the best Open Source rules engine available for Python as there are countless implementation for Ruby, Java, and Perl, but surprisingly I found none fitting the project’s needs. This led to the thought of inventing one; simply typing the keywords “python rules engine” into Google though will return to you the advice “to not invent yet another rules language”, but instead you are advised to “just write your rules in Python, import them, and execute them.” The basis for this advice can be coalesced down to doing so otherwise does not fit with the “Python Philosophy.” At the time, I did not believe this to be true, nor fully contextualized, and yet admittedly, I had not yet authored a line of Python code (Yes, you’re looking at my first Python program. So, please give me a break.) nor used ANTLR3 prior to this effort. Looking back, I firmly believe the act of inventing a rules engine and abstracting it behind a nomenclature that describes and illuminates a specific domain is the best way for in case of aforementioned platform the network defender to think about the problem. Like I said though the DSL and rules engine could be used for anything needing a “production rule system”. As there were no rules engines available for Python fitting the platforms needs, a policy language and naive forward chaining rules engine were built from scratch. The policy language’s grammar is based on a subset of Python language syntax. The policy DSL is parsed and lexed with the help of the ANTLR3 Parse Generator and Runtime for Python.

6. Facts (Data being reasoned over) The interpreter, the rules engine, and the remainder of the code such as objects for conferring discrete network conditions, referred to as “facts”, are also authored in Python. Python’s approach to the object-oriented programming paradigm, where objects consist of data fields and methods, did not easily lend itself to describing “facts”. Because the data fields of a Python object referred to syntactically as “attributes” can and often are set on an instance of a class, they will not exist prior to a class’s instantiation. In order for a rules engine to work, it must be able to fully introspect an object instance representing a condition. This proves to be very difficult unless the property decorator with its two attributes, “getter” and “setter”, introduced in Python 2.6, are adopted and formally used for authoring these objects. Coincidentally, the use of the “Getter/Setter Pattern” used frequently in Java is singularly frowned upon in the Python developer community with the cheer of “Python is not Java”. So, you will need to author your facts as Python object’s who attributes are formally denoted as properties like so for the attributes you would like to reason over: class ClassA(object): ''' An example fact ''' def __init__(self, property0 = None, property1 = None): ''' ClassA initializer ''' self._property0 = property0 @property def property0(self): return self._property0 @property0.setter def property0(self, value): self._property0 = value

7. The Policy DSL Example with policy files can be found at the path Intellect/src/intellect/examples. Policy files must follow the Policy grammar as define in Intellect/src/intellect/grammar/Policy.g. The rest of this section documents the grammar of policy domain-specific language.

7.1 Import Statements ( ImportStmts ) Import statements basically follow Python’s with a few limitations. For example, The wild card form of import is not supported for the reasons elaborated here and follow the Python 2.7.2 grammar. ImportStmt statements exist only at the same level of ruleStmt statements as per the grammar, and are typically at the top of a policy file, but are not limited to. In fact, if you break up your policy across several files the last imported as class or module wins as the one being named.

7.2 Attribute Statements ( attribute ) The syntax diagram for a attributeStmt . attributeStmt statements are expressions used to create policy attributes, a form of globals, that are accessible from rules. For example, a policy could be written: import logging first_sum = 0 second_sum = 0 rule "set both first_sum and second_sum to 1": agenda-group "test_d" then: attribute (first_sum, second_sum) = (1,1) log("first_sum is {0}".format(first_sum), "example", logging.DEBUG) log("second_sum is {0}".format(second_sum), "example", logging.DEBUG) rule "add 2": agenda-group "test_d" then: attribute first_sum += 2 attribute second_sum += 2 log("first_sum is {0}".format(first_sum), "example", logging.DEBUG) log("second_sum is {0}".format(second_sum), "example", logging.DEBUG) rule "add 3": agenda-group "test_d" then: attribute first_sum += 3 attribute second_sum += 3 log("first_sum is {0}".format(first_sum), "example", logging.DEBUG) log("second_sum is {0}".format(second_sum), "example", logging.DEBUG) rule "add 4": agenda-group "test_d" then: attribute first_sum += 4 attribute second_sum += 4 log("first_sum is {0}".format(first_sum), "example", logging.DEBUG) log("second_sum is {0}".format(second_sum), "example", logging.DEBUG) halt rule "should never get here": agenda-group "test_d" then: log("Then how did I get here?", "example", logging.DEBUG) containing the two atributeStmt statements: first_sum = 0 second_sum = 0 The following rules will increment these two attributes using attributeAction statements. Code to exercise this policy would look like so: class MyIntellect(Intellect): pass if __name__ == "__main__": # set up logging for the example logger = logging.getLogger('example') logger.setLevel(logging.DEBUG) consoleHandler = logging.StreamHandler(stream=sys.stdout) consoleHandler.setFormatter(logging.Formatter('%(asctime)s %(name)-12s %(levelname)-8s%(message)s')) logger.addHandler(consoleHandler) myIntellect = MyIntellect() policy_d = myIntellect.learn("./rulesets/test_d.policy") myIntellect.reason(["test_d"]) and the logging output from the execution of the above would be: 2011-10-04 23:56:51,681 example DEBUG __main__.MyIntellect :: first_sum is 1 2011-10-04 23:56:51,682 example DEBUG __main__.MyIntellect :: second_sum is 1 2011-10-04 23:56:51,683 example DEBUG __main__.MyIntellect :: first_sum is 3 2011-10-04 23:56:51,683 example DEBUG __main__.MyIntellect :: second_sum is 3 2011-10-04 23:56:51,685 example DEBUG __main__.MyIntellect :: first_sum is 6 2011-10-04 23:56:51,685 example DEBUG __main__.MyIntellect :: second_sum is 6 2011-10-04 23:56:51,687 example DEBUG __main__.MyIntellect :: first_sum is 10 2011-10-04 23:56:51,687 example DEBUG __main__.MyIntellect :: second_sum is 10 See section 7.3.3.1.2 attributeAction for another example.

7.3 Rule Statements ( ruleStmt ) The syntax diagram for a ruleStmt . A rule statement at its simplest looks like so: rule "print": then: print("hello world!!!!") The rule "print" will always activate and output hello world!!!! to the sys.stdout . A rule will always have an identifier ( id ) in either a NAME or STRING token form following Python’s naming and String conventions. Generally, a rule will have both a when portion containing the condition of the rule, as of now a ruleCondition , and an action described by the then portion. The action can be thought of in Python-terms as having more specifically a suite of one ore more actions. Depending on the evaluation of condition , facts in knowledge will be matched and then operated over in the action of the rule. Such as in the rule "delete those that don't match" , all facts in knowledge of type ClassD who’s property1 value is either a 1 or 2 or 3 will be deleted in action of the rule. from intellect.testing.ClassCandD import ClassD rule "delete those that don't match": when: not $bar := ClassD(property1 in [1,2,3]) then: delete $bar

7.3.1 agenda-group rule property The syntax diagram for a agendaGroup . Optionally, a rule may have an agenda-group property that allows it to be grouped in to agenda groups, and fired on an agenda. See sections 7.2 attribute and 7.3.3.1.2 attributeAction for examples of the use of this property.

7.3.2 When The syntax diagram for a when . If present in rule, it defines the condition on which the rule will be activated.

7.3.2.1 Rule Condition ( condition ) The syntax diagram for a condition . A rule may have an optional condition, a boolean evaluation, on the state of objects in knowledge defined by a Class Constraint ( classConstraint ), and may be optionally prepended with exists as follows: rule rule_c: when: exists $classB := ClassB(property1.startswith("apple") and property2>5 and test.greaterThanTen(property2) and aMethod() == "a") then: print( "matches" + " exist" ) a = 1 b = 2 c = a + b print(c) test.helloworld() # call MyIntellect's bar method as it is decorated as callable bar() and thus the action will be called once if there are any object in memory matching the condition. The action statements modify and delete may not be used in the action if exists prepends the classContraint . Currently, the DSL only supports a single classConstraint , but work is ongoing to support more than one.

7.3.2.1.1 A Class Constraint ( classConstraint ) The syntax diagram for a classConsraint . A classContraint defines how an objects in knowledge will be matched. It defines an OBJECTBINDING , the Python name of the object’s class and the optional constraint by which objects will be matched in knowledge. The OBJECTBINDING is a NAME token following Python’s naming convention prepended with a dollar-sign ( $ ). As in the case of the Rule Condition example: exists $classB := ClassB(property1.startswith("apple") and property2>5 and test.greaterThanTen(property2) and aMethod() == "a") $classB is the OBJECTBINDING that binds the matches of facts of type ClassB in knowledge matching the constraint . An OBJECTBINDING can be further used in the action of the rule, but not in the case where the condition is prepended with exists as in the example.

7.3.2.1.2 A Constraint A constraint follows the same basic and , or , and not grammar that Python follows. As in the case of the Rule Condition example: exists $classB := ClassB(property1.startswith("apple") and property2>5 and test.greaterThanTen(property2) and aMethod() == "a") All ClassB type facts are matched in knowledge that have property1 attributes that startwith apple , and property2 attributes greater than 5 before evaluated in hand with exist statement. More on the rest of the constraint follows in the sections below.

7.3.2.1.2.1 Using Regular Expressions You can also use regular expressions in constraint by simply importing the regular expression library straight from Python and then using like so as in the case of the Rule Condition example: $classB := ClassB( re.search(r"\bapple\b", property1)!=None and property2>5 and test.greaterThanTen(property2) and aMethod() == "a") The regular expression r"\bapple\b" search is performed on property1 of objects of type ClassB in knowledge.

7.3.2.1.2.2 Using Methods To rewrite a complicated constraint : If you are writing a very complicated constraint consider moving the evaluation necessary for the constraint into a method of fact being reasoned over to increase readability. As in the case of the Rule Condition example, it could be rewritten to: $classB := ClassB(property1ContainsTheStrApple() and property2>5 and test.greaterThanTen(property2) and aMethod() == "a") If you were to add the method to ClassB: def property1ContainsTheStrApple() return re.search(r"\bapple\b", property1) != None Of a class and/or instance: This example, also demonstrates how the test module function greaterThanTen can be messaged the instance’s property2 attribute and the function’s return evaluated, and a call to the instance’s aMethod method can be evaluated for a return of "a" .

7.3.3 Then The syntax diagram for a then . Is used to define the suite of one-or-more action statements to be called firing the rule, when the rule is said to be activated.

7.3.3.1 Rule Action (Suite of Actions) The syntax diagram for an action . Rules may have a suite of one or more actions used in process of doing something, typically to achieve an aim.

7.3.3.1.1 Simple Statements ( simpleStmt ) The syntax diagram for a simpleStmt . simpleStmts are supported actions of a rule, and so one can do the following: rule rule_c: when: exists $classB := ClassB(property1.startswith("apple") and property2>5 and test.greaterThanTen(property2) and aMethod() == "a") then: print("matches" + " exist") a = 1 b = 2 c = a + b print(c) test.helloworld() bar() The simpleStmt in the action will be executed if any facts in knowledge exist matching the condition. To keep the policy files from turning into just another Python script you will want to keep as little code out of the suite of actions and thus the policy file was possible… You will want to focus on using modify , delete , insert , halt before heavily using large amounts of simple statements. This is why action supports a limited Python grammar. if , for , while etc are not supported, only Python’s expressionStmt statements are supported.

7.3.3.1.2 attributeAction The syntax diagram for a attributeStmt . attributeAction actions are used to create, delete, or modify a policy attribute. For example: i = 0 rule rule_e: agenda-group "1" then: attribute i = i + 1 print i rule rule_f: agenda-group "2" then: attribute i = i + 1 print i rule rule_g: agenda-group "3" then: attribute i = i + 1 print i rule rule_h: agenda-group "4" then: # the 'i' variable is scoped to then portion of the rule i = 0 print i rule rule_i: agenda-group "5" then: attribute i += 1 print i # the 'i' variable is scoped to then portion of the rule i = 0 rule rule_j: agenda-group "6" then: attribute i += 1 print i If the rules engine is instructed to reason seeking to activate rules on agenda in the order describe by the Python list ["1", "2", "3", "4", "5", "6"] like so: class MyIntellect(Intellect): pass if __name__ == "__main__": myIntellect = MyIntellect() policy_c = myIntellect.learn("./rulesets/test_c.policy") myIntellect.reason(["1", "2", "3", "4", "5", "6"]) The following output will result: 1 2 3 0 4 5 When firing rule_e the policy attribute i will be incremented by a value of 1 , and print 1 , same with rule_f and rule_g , but rule_h prints 0. The reason for this is the i variable is scoped to then portion of the rule. Rule_i further illustrates scoping: the policy attribute i is further incremented by 1 and is printed, and then a variable i scoped to then portion of the rule initialized to 0 , but this has no impact on the policy attribute i for when rule_j action is executed firing the rule the value of 6 is printed.

7.3.3.1.3 learn action The syntax diagram for a learnAction . A rule entitled "Time to buy new sheep?" might look like the following: rule "Time to buy new sheep?": when: $buyOrder := BuyOrder( ) then: print( "Buying a new sheep." ) modify $buyOrder: count = $buyOrder.count - 1 learn BlackSheep() The rule above illustrates the use of a learn action to learn/insert a BlackSheep fact. The same rule can also be written as the following using insert : rule "Time to buy new sheep?": when: $buyOrder := BuyOrder( ) then: print( "Buying a new sheep." ) modify $buyOrder: count = $buyOrder.count - 1 insert BlackSheep()

7.3.3.1.4 forget action The syntax diagram for a forgetAction . A rule entitled "Remove empty buy orders" might look like the following: rule "Remove empty buy orders": when: $buyOrder := BuyOrder( count == 0 ) then: forget $buyOrder The rule above illustrates the use of a forget action to forget/delete each match returned by the rule’s condition. The same rule can also be written as the following using delete : rule "Remove empty buy orders": when: $buyOrder := BuyOrder( count == 0 ) then: delete $buyOrder Note: cannot be used in conjunction with exists .

7.3.3.1.5 modify action The syntax diagram for a modifyAction . The following rule: rule "Time to buy new sheep?": when: $buyOrder := BuyOrder( ) then: print( "Buying a new sheep." ) modify $buyOrder: count = $buyOrder.count - 1 learn BlackSheep() illustrates the use of a modify action to modify each BuyOrder match returned by the rule’s condition. Cannot be used in conjunction with exists rule conditions. The modify action can also be used to chain rules, what you do is modify the fact (toggle a boolean property, set a property’s value, etc) and then use this property to evaluate in the proceeding rule.

7.3.3.1.6 halt action The syntax diagram for a haltAction . The following rule: rule "End policy": then: log("Finished reasoning over policy.", "example", logging.DEBUG) halt illustrates the use of a halt action to tell the rules engine to halt reasoning over the policy.