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e2929573be
This shouldn't break anything, no variable name is changed. Documentation and strings are fixed, strings that do not come in a 'command' or those that are required for 'pwncat' to work are not changed.
314 lines
11 KiB
Markdown
314 lines
11 KiB
Markdown
# Feature and Changes Ideas
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I'm just rambling some ideas I have here.
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## C2 Channels
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I think it could be helpful to establish an abstract C2 channel class
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to allow pwncat to communicate over different C2 methods. For example,
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`Bind` and `Reverse` channel classes could handle the standard bind and
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reverse methods. An `SSH` channel could handle SSH connections.
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There is also potential for numerous other methods such as DNS, ICMP,
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etc. A Channel class would look a lot like a socket, but would guarantee
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a consistent interface across C2 types.
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```python
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class Channel:
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PLATFORM = Platform.UNKNOWN
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def recv(self, count: Optional[int] = None):
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raise NotImplementedError
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def send(self, data: bytes):
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raise NotImplementedError
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@classmethod
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def connect(cls, connection_string: str, port: int, platform: Platform) -> "Channel":
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""" Called by the connect command. May look like:
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# Connect via ssh
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connect ssh user@host
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connect ssh -p 2222 user@host
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# Connect via raw socket
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connect host 4444
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# Connect via bind socket
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connect bind -p 4444
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# Connect via other types
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connect icmp host
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# Connect for specific platform
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connect -P windows host 4444
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connect bind -P linux -p 4444
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Technically, the first positional parameter is the connection string
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and the second is the port number. You can also specify the port number
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with `-p` or `--port`. The positional syntax is more natural for raw
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socket connect channels, while the `-p` is more natural for ssh and
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bind sockets.
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"""
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raise NotImplementedError
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```
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## Platform Abstraction
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To facilitate true multi-platform functionality, some information should be abstracted
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away from the platform. I think this would look like separating the victim object out
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into a base class and sub-classes. The base class could be called `Platform` and take
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over for the `Platform` Flags class we currently have. Instead of testing a flags class,
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we could have `PLATFORM` in modules be an array of supported platform classes, and use
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a similar syntax where it would look like `type(pwncat.victim) in module.PLATFORM` or
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`isinstance(pwncat.victim, platform.Linux)`.
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```python
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class Platform:
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def __init__(self, channel: Channel):
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# Save the channel for future use
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self.channel = channel
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# Set the prompt
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self.update_prompt()
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# Spawn a pty if we don't have one
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if not self.has_pty():
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self.spawn_pty()
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def has_pty(self) -> bool:
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""" Check if the current shell has a PTY """
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def spawn_pty(self):
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""" Spawn a PTY in the current shell for full interactive features """
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def update_prompt(self):
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""" Set the prompt for the current shell """
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def which(self, name: str) -> str:
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""" Look up a binary on the remote host and return it's path """
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def cd(self, directory: str):
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""" Change directories """
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def listdir(self, directory: str = None) -> Generator[int, None, None]:
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""" Return a list of all items in the current directory """
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def cwd(self) -> str:
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""" Get the current working directory """
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def current_user(self) -> User:
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""" Get a user object representing the current user """
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def current_uid(self) -> int:
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""" Get the current user id. This is faster than querying the whole user object """
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def open(self, path: str, mode: str, content_length: int) -> Union[TextIO, BinaryIO]:
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""" Mimic built-in open function to open a remote file and return a stream. """
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def exec(self, argv: List[str], envp: List[str], stdout: str, stderr: str, stream: bool = False) -> Union[str, BinaryIO]:
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""" Execute a remote binary and return the stdout. If stream is true, return a
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file-like object where we can read the results. """
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def process(self, argv: List[str], envp: List[str], stdout: str, stderr: str) -> bytes:
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""" Execute a remote binary, but do not wait for completion. Return string which
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indicates the completion of the command """
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class Linux(Platform):
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""" Implement the above abstract methods """
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class Windows(Platform):
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""" Implement the above abstract methods """
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```
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With both channels and platforms implemented, the initialization would
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look something like this:
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```python
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# Initialize scripting engine
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script_parser = pwncat.commands.Parser()
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# Run the connect command
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try:
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script_parser.dispatch_line(shlex.join(["connect", *remaining_args]), command="pwncat")
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except:
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# Connection failed
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exit(1)
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# The connect command initialized the `pwncat.victim` object,
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# but it doesn't have a parser yet. We already initialized one
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# so store it there.
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pwncat.victim.parser = script_parser
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```
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## Module access
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Modules are currently segmented by type. There are persistence, privilege
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escalation, and enumeration modules. These modules are all implemented
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independently and accessed through separate commands.
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This is helpful for segmenting the different parts of pwncat into different
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base goals, but hinders the ease of development for new modules. This
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interface does not provide a simple way for complex modules to accept
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parameters and forces the developer to remember the interface for all of
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these different command frameworks.
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I was initially hesitant to adopt the Metasploit Framework way of doing
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things where every action was a module, because I wanted to keep things
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simpler, but as the framework grows and more complex modules are
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implemented, I think this is needed, but needs to be implemented in such
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a way that the modules can be interfaced with programmatically as well.
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I'm thinking of something like this from a programmatic standpoint:
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```python
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# Attempt all privileg escalation modules
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for module in pwncat.modules.match(r"escalate/.*"):
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try:
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module.run(target=user)
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break
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except PrivescError:
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pass
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# Collect facts from all enumeration modules
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facts = []
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for module in pwncat.modules.match(r"enumerate/.*"):
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facts.extend(module.run())
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# Install persistence
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pwncat.modules.match(r"persist/.*").run(
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user = "root",
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lhost = "10.0.0.1",
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lport = "4444",
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)
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```
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A module may look something like this:
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```python
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class Module(BaseModule):
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ARGUMENTS = {
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"user": { "type": str, "default": None },
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"lhost": { "type": ipaddress.ip_address },
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"lport": { "type": int, "default": 4444 }
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}
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def run(self, user, lhost, lport):
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""" Install this persistence method """
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return
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```
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From a REPL point of view, it would look a lot like metasploit. You can
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`use` a module. After using a module, any `set` actions would set
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configurations for this specific module. If you do not have a module
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loaded, then using `set` will set the configuration globally. If a
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configuration is not set locally when `run` is executed, then the global
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configuration will be checked for matching arguments for the module.
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```sh
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# Install a persistence method with a bind channel
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use persistence/system/cron
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set method channels/bind
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set schedule "* * */1 *"
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set lhost 10.0.0.1
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set lport 4444
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run
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# Same as above
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run persistence/system/cron method=channels/bind lhost=10.0.0.1 lport=4444
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# Set a global configuration, applies to all modules
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set -g lhost 10.0.0.1
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```
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The above programmatic interface could be used to implement the same
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automated escalation features we had before.
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```python
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attempted_modules = []
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attempted_users = []
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for module in pwncat.modules.match("escalate/.*"):
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if module in attempted_modules:
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continue
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try:
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module.run(
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user=target_user,
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ignore_users=attempted_users,
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ignore_modules=[m.name for m in attempted_modules]
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)
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except PrivescFailed as exc:
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attempted_modules.extend(exc.attempted_modules)
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attempted_users.extend(exc.attempted_users)
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```
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The `escalate` modules would be created separately from others. They
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would inherit from a `EscalationModule` class, which provides a
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standard interface to the `run` method. The subclasses would be
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responsible for similar `enumerate`, `escalate`, `write` and `read`
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methods that are currently implemented.
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This allows an individual privilege escalation method to be run
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like this:
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```sh
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run escalate/sudo user=admin
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```
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While the standard automated privilege escalation can be accomplished
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with a simple:
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```sh
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use escalate
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set user admin
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set ignore_module ["sudo"]
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run
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# Or completely automated for root
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run escalate
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```
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Enumerate possibly valid escalation methods
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```sh
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# List possibly valid escalation methods to user admin
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run escalate/list user=admin
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# List possibly valid escalation methods, ignoring the given modules
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run escalate/list ignore_module=["sudo"]
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```
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## Better Progress Handling
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Currently, progress is handled in a syntactically interesting but possibly confusing way.
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I utilize Python generators to yield the results of iterative modules. The generators
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can also yield `Status` objects. These objects are filtered from the actual results of
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generators and used to only update the progress bar. This allows modules to provide updates
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without having to worry about the state or existence of a progress bar.
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The problem is that if these modules call other methods or functions, passing this
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capability on becomes problematic unless a `yield from` is used. The module wrapper currently
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uses some python magic to check if a method returns a generator and yield/return
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appropriately. I'd prefer to keep this kind of language-level code out of modules, so I'm
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considering changing this design. A global (or rather, victim-level) progress bar can be
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managed. Something like this:
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```python
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# Update the most recent task
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pwncat.victim.progress.status("Here's a status update")
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# Create a new task
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task = pwncat.victim.progress.task("module or action", category="goal")
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# Update a specific task
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pwncat.victim.progress.status("Here's a status update", task=task)
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```
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The progress bar itself will be managed by the `Victim` object. We can keep the standard
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now where iterative/generator based results are used to update a task, but also allows
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modules to directly call `pwncat.victim.progress.status`. This would do away with the `Status`
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class. Further, it allows the `module.run` method to return the raw result of the underlying
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method allowing more flexibility in the return values of modules. It allows modules to have
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asynchronous (generator) return values.
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This in turn may allow intermediate results to be displayed by the `run` command. Currently,
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the `run` command categorizes the results before displaying. It may be able to be adopted
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to asynchronously print results as the module runs.
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