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Mac Intrusion Detection Analysis System

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MIDAS

MIDAS is a framework for developing a Mac Intrusion Detection Analysis System, based on work and collaborative discussions between the Etsy and Facebook security teams. This repository provides a modular framework and a number of helper utilities, as well as an example module for detecting modifications to common OS X persistence mechanisms.

The MIDAS project is based off concepts presented in [Homebrew Defensive Security] (http://www.slideshare.net/mimeframe/ruxcon-2012-15195589) and [Attack-Driven Defense] (http://www.slideshare.net/zanelackey/attackdriven-defense), as well as lessons learned during the development of the Tripyarn and BigMac products.

Our mutual goal in releasing this framework is to foster more discussion in this area and provide organizations with a starting point in instrumenting OS X endpoints to detect common patterns of compromise and persistence.

Overview

The midas subdirectory is where the core MIDAS code lives. The entry point is launcher.py. From there, each module in midas/modules is executed and the stdout of the module is written to a log file. When deploying MIDAS, this is the code that's put on user's systems.

The develop subdirectory is where development resources (like a .pylintrc) live.

The templates resource is where template and base resources live. These can be used as a starting point when adding modules.

Architecture

MIDAS allows you to define a set of "modules" that implement host-based checks, verifications, analysis, etc.

Launcher

The launcher.py file exists at the top level of the midas directory. It gathers some simple information about the host it's executing on (such as time, hostname, etc) and defines the ways that it should handle modules of certain languages. To add a supported language, create a new instance of TyLanguage in launcher.py and add it to the SUPPORTED_LANGUAGES list. If you'd like to change the way a certain language is supported (perhaps you'd like all python modules to be executed with a custom version of python), you can change the attributes (such as execution_string) of the language.

Once key definitions are made, the launcher will iterate through all files (note that directories are explicitly skipped) in the modules subdirectory. For each file in the directory, if a language entry is found that indicates how to deal with that filetype, the file is executed and the stdout of the module are appended to a log file in the log subdirectory. Note that a module modules/example.py will generate a log file logs/example.log.

Module language

Modules can be written in any language, so long as a named tuple for that language is defined in midas/launcher.py. These named tuples (which already exist for python, ruby and shell) exist so that MIDAS knows how to handle certain filetypes when it sees them.

As long as your code can be executed and prints something to stdout, it can be a module.

Components

Example module

The file midas/modules/example.py is an example MIDAS module created to illustrate what a MIDAS module might look like. This module performs analysis of LaunchAgents and LaunchDaemons on the host and logs any modifications that it identifies. The rest of the checks and verifications analyze the host firewall configurations and log any additions or differences that are identified. This is not meant to be a complete intrusion detection mechanism alone, instead it is meant as a reference example of what a MIDAS module may look like.

Helpers

There are several helper files in midas/lib/helpers that are generally grouped by category. Functions in these helpers can be imported by modules to assist in general tasks. Some functionality exposed by helpers include:

  • list all weak SSH keys on a host
  • find all files in a given directory with given permissions
  • list all startup items
  • list all LaunchAgents, LaunchDaemons, etc.
  • list and hash all kernel extensions
  • return the SSID of the currently connected WiFi network
  • return the IP and MAC address of the current network gateway
  • return DNS configuration information
  • and much, much more

Config system

The config file, which can be found at midas/lib/config.py is a way to group together information that can be abstracted away from modules. Usually there are things like strings that should be checked in a certain module validation, directories to search during a given check, etc. By abstracting the data away from the individual module/code, it makes it easier for people who might not maintain the code to contribute to it.

Since the config dictionary is operated on via a static method, it does not need to instantiate the Config object in order to use it. To add a new value to the config dictionary, simply add an entry in the class.

ORM and table definitions

MIDAS relies on a local datastore to do some simple host-based analytics with the data gathered by modules. For this reason, MIDAS comes with a simple, custom ORM.

Table definitions

Table schemas are described via a simple dictionary, all of which can be found in midas/lib/tables/. The dictionary is then parsed and valid SQL is created from the dictionary. Each item in the dictionary represents a column. The column definition should be a key-value pair where the key is a strings that represents the name of the column and the value is a dictionary that describes the column. The column definition dictionary can have the following attributes:

  • default
    • If this is set, it will be the default value of the column. This is most frequently set to "NULL"
  • nullable
    • If this is set to False, then the NOT NULL attribute will be used when creating the table
  • attrs
    • Use this to add additional SQL syntax that you want added to the table creation statement that isn't supported by tyORM
  • primary_key
    • If this is set to True, then the column listed will be set to the primary key

See the following same table definition for reference:

test_table = {
    "data_field_name" : {
        "type" : "text",
        "nullable" : False,
    },
    "other_data_field" : {
        "type" : "text",
        "default" : "NULL",
    }
}

Instantiating an ORM object

When instantiating an ORM object, the class takes one parameter: the database filename. If the file doesn't exist, the ORM will create it.

See the following example code for reference:

from lib.ty_orm import TyORM
ORM = TyORM("midas_hids.db")

Transparent primary key system

Although it is possible to specify a primary key when creating a table, TyORM transparently creates an auto-incrementing id column and sets it as a primary key. Although SQLite allows you to specify several primary keys, this is not necessary. The id column is always used as the WHERE clause identifier when doing UPDATE and DELETE operations.

Creating

Use the insert method to insert data into a table. The insert method takes two arguments: the table name and the data that you'd like to insert. The table name should be a string that describes the name of the table. The data should be a dictionary such that the keys describe the columns that the value should be inserted into.

See the following example insert call for reference:

ORM = TyORM("midas_hids.db")
data = {
    "data_field_name" : "foo",
    "other_data_field" : "bar",
}
ORM.insert("test_table", data)

Reading

Use the select method to read data from the database. The select method takes one mandatory argument and three optional arguments.

The mandatory argument that all select method calls needs to have is the table name that you'd like to select from. The optional arguments are as follows:

  • columns
    • An array of columns that you would like returned
  • where
    • A string that describes the "WHERE" clause that you would like added to the SQL query
    • Note that this can be a string but if you're supplying user input, this should be an array such that the first item in the array is the where clause with '?' place holders and the second item in the array is an array with the representative values.
  • limit
    • An integer describing the LIMIT value that you would like added to the SQL query
  • order_by
    • A string dictating which column to order results by

See the following example select calls for reference:

ORM = TyORM("midas_hids.db")

# this will return all table data
ORM.select("test_table")

# this will return only the "data_field_name" column of the
# first five columns where the "data_field_name" column is "foobar", ordered by "data_field_name"
ORM.select("test_table", ["data_field_name"], "data_field_name = 'foobar'", 5, "data_field_name")

Updating

Use the update method to update data from the database. Simply select some data and change the returned dictionary to reflect the data you want the field to be updated to and, via some "hidden" values, the ORM will take care of the rest.

See the following example update call for reference:

ORM = TyORM("midas_hids.db")
data = ORM.select("test_table", "*", "data_field_name = 'foobar123'", 1)
data['data_field_name'] = 'newname123'
ORM.update(data)

Deleting

Use the delete method to delete data from the database. Simply select some data and call the delete method and the ORM will take care of the rest.

See the following example delete call for reference:

ORM = TyORM("midas_hids.db")
data = ORM.select("test_table", "*", "data_field_name = 'foobar123'", 1)
ORM.delete(data)

Initializing tables and dynamic ALTERs

One of the strengths of tyORM is it's ability to dynamically ALTER a table if the table's schema doesn't match the table definition dictionary.

Simply call the initialize_table table method before operating on the table. The initialize_table method takes two arguments: the table name and the table definition. The initialize_table method will create the table if it doesn't exist and it will alter the table if any new columns have been added.

See the following example code for reference:

test_table_data = {
    "data_field_name" : "foo",
    "other_data_field" : "bar",
}

ORM = TyORM("midas_hids.db")
ORM.initialize_table("test_table", test_table_data)

# operate on the ORM here

Due to limitations of SQLite, this only support new columns that are added, not columns that are removed.

Host based analytics

The file lib/data_science.py is used for simple host based data aggregation. The DataScience class is used to query the database and log any changes, given a new dataset. Using data_science is very simple. The class constructor takes three arguments:

  • a TyORM object that is already instantiated with the database which is to be operated on
  • a dataset
  • a table name that the dataset should be compared against

The dataset should be an array of dictionaries. Each item in the array should be a dictionary where each key of the dictionary represents a column in the database and each corresponding value represents a corresponding value. It's OK if some columns of the table are not in the dictionary, but the name column should always be present. Although TyORM has it's own transparent primary key system using the id column, for the sake of data_science, the name column should be present and it should be unique. The data_science code will then select all of the data from the given table and compare it against the supplied dataset, printing out log lines illustrating all data that has been added, removed and changed.

Decorators

The file midas/lib/decorators.py contains a bunch of decorators that can be used for a variety of things, but currently predominantly code execution frequency.

Property List parsing

This is the utility that MIDAS uses to operate on property list files such as LaunchAgents and LaunchDaemons. This is mostly the biplist python module, however, you should never actually call any of the biplist functions directly.

The read_plist function is what you should call when trying to read a plist. When you call read_plist, it first tries to use biplist's readPlist. That code determines if the plist is a binary plist or an XML plist. If it is an XML plist, it just uses python's plistlib to read the plist. If it is a binary plist, it uses a native python implementation to parse it and return it's contents. If that, for whatever reason, fails, the read_plist function will then try to shell out to plutil to parse the plist.

The get_plist_key function takes a plist and a key as input. It returns the key (if the key exists) or False if it does not. This is so that, when operating on property lists, you don't have to roll your own exception handling on every access.

read_plist and get_plist_key are the only two functions that should be called from this file.

Customization

A MIDAS deployment in an organization typically follows these steps:

  • Create a private fork of MIDAS
  • Add modules and helpers that implement instrumentation specific to the environment
  • Deploy the code (with updated modules) to OS X endpoints in the organization
  • Set a crontab/LaunchAgent that executes MIDAS at a set interval
  • Use syslog/a log aggregation mechanism to forward the logs to a central logging host
  • Analyze the collected data and create alerts for anomalies

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