LLaMPPL is a research prototype for language model probabilistic programming: specifying language generation tasks by writing probabilistic programs that combine calls to LLMs, symbolic program logic, and probabilistic conditioning. To solve these tasks, LLaMPPL uses a specialized sequential Monte Carlo inference algorithm. This technique, SMC steering, is described in our recent workshop abstract.
This repository implements LLaMPPL for use with HuggingFace Transformers.
If you just want to try out LLaMPPL, check out our demo notebook on Colab, which performs a simple constrained generation task using GPT-2. (Larger models may require more RAM or GPU resources than Colab's free version provides.)
Note
We use poetry to manage dependencies. If you don't have poetry installed, you can install it with pip install poetry
.
To get started on your own machine, clone this repository and run poetry install
to install hfppl
and its dependencies.
git clone https://github.com/probcomp/hfppl
cd hfppl
poetry install
Then, try running an example. Note that this will cause the weights for Vicuna-7b-v1.5 to be downloaded.
poetry run python examples/hard_constraints.py
If everything is working, you should see the model generate political news using words that are at most five letters long (e.g., "Dr. Jill Biden may still be a year away from the White House but she is set to make her first trip to the U.N. today.").
A LLaMPPL program is a subclass of the hfppl.Model
class.
from hfppl import Model, LMContext, CachedCausalLM
# A LLaMPPL model subclasses the Model class
class MyModel(Model):
# The __init__ method is used to process arguments
# and initialize instance variables.
def __init__(self, lm, prompt, forbidden_letter):
super().__init__()
# A stateful context object for the LLM, initialized with the prompt
self.context = LMContext(lm, prompt)
self.eos_token = lm.tokenizer.eos_token_id
# The forbidden letter
self.forbidden_tokens = set(i for (i, v) in enumerate(lm.vocab)
if forbidden_letter in v)
# The step method is used to perform a single 'step' of generation.
# This might be a single token, a single phrase, or any other division.
# Here, we generate one token at a time.
async def step(self):
# Condition on the next token *not* being a forbidden token.
await self.observe(self.context.mask_dist(self.forbidden_tokens), False)
# Sample the next token from the LLM -- automatically extends `self.context`.
token = await self.sample(self.context.next_token())
# Check for EOS or end of sentence
if token.token_id == self.eos_token or str(token) in ['.', '!', '?']:
# Finish generation
self.finish()
# To improve performance, a hint that `self.forbidden_tokens` is immutable
def immutable_properties(self):
return set(['forbidden_tokens'])
The Model class provides a number of useful methods for specifying a LLaMPPL program:
self.sample(dist[, proposal])
samples from the given distribution. Providing a proposal does not modify the task description, but can improve inference. Here, for example, we use a proposal that pre-emptively avoids the forbidden letter.self.condition(cond)
conditions on the given Boolean expression.self.finish()
indicates that generation is complete.self.observe(dist, obs)
performs a form of 'soft conditioning' on the given distribution. It is equivalent to (but more efficient than) sampling a valuev
fromdist
and then immediately runningcondition(v == obs)
.
To run inference, we use the smc_steer
or smc_standard
methods:
import asyncio
from hfppl import smc_steer
# Initialize the HuggingFace model
lm = CachedCausalLM.from_pretrained("meta-llama/Llama-2-7b-hf", auth_token=<YOUR_HUGGINGFACE_API_TOKEN_HERE>)
# Create a model instance
model = MyModel(lm, "The weather today is expected to be", "e")
# Run inference
particles = asyncio.run(smc_steer(model, 5, 3)) # number of particles N, and beam factor K
Sample output:
sunny.
sunny and cool.
34° (81°F) in Chicago with winds at 5mph.
34° (81°F) in Chicago with winds at 2-9 mph.
hot and humid with a possibility of rain, which is not uncommon for this part of Mississippi.
Further documentation can be found at https://probcomp.github.io/hfppl.