This library contains code for doing text embedding inversion. We can train various architectures that reconstruct text sequences from embeddings as well as run pre-trained models. This repository contains code for the paper "Text Embeddings Reveal (Almost) As Much As Text".
To get started, install this on PyPI:
pip install vec2text
If you're training a model you'll need to set up nltk:
import nltk
nltk.download('punkt')
Before pushing any code, please run precommit:
pre-commit run --all
The library can be used to embed text and then invert it, or invert directly from embeddings. First you'll need to construct a Corrector
object which wraps the necessary models, embedders, and tokenizers:
load_pretrained_corrector
corrector = vec2text.load_pretrained_corrector("text-embedding-ada-002")
load_corrector
If you have trained you own custom models using vec2text, you can load them in using the load_corrector
function.
inversion_model = vec2text.models.InversionModel.from_pretrained("jxm/gtr__nq__32")
corrector_model = vec2text.models.CorrectorEncoderModel.from_pretrained("jxm/gtr__nq__32__correct")
corrector = vec2text.load_corrector(inversion_model, corrector_model)
Both vec2text.models.InversionModel
and vec2text.models.CorrectorEncoderModel
classes inherit transformers.PreTrainedModel
therefore you can pass in a huggingface model name or path to a local directory.
invert_strings
vec2text.invert_strings(
[
"Jack Morris is a PhD student at Cornell Tech in New York City",
"It was the best of times, it was the worst of times, it was the age of wisdom, it was the age of foolishness, it was the epoch of belief, it was the epoch of incredulity"
],
corrector=corrector,
)
['Morris is a PhD student at Cornell University in New York City',
'It was the age of incredulity, the age of wisdom, the age of apocalypse, the age of apocalypse, it was the age of faith, the age of best faith, it was the age of foolishness']
By default, this will make a single guess (using the hypothesizer). For better results, you can make multiple steps:
vec2text.invert_strings(
[
"Jack Morris is a PhD student at Cornell Tech in New York City",
"It was the best of times, it was the worst of times, it was the age of wisdom, it was the age of foolishness, it was the epoch of belief, it was the epoch of incredulity"
],
corrector=corrector,
num_steps=20,
)
['Jack Morris is a PhD student in tech at Cornell University in New York City',
'It was the best time of the epoch, it was the worst time of the epoch, it was the best time of the age of wisdom, it was the age of incredulity, it was the age of betrayal']
And for even better results, you can increase the size of the search space by setting sequence_beam_width
to a positive integer:
vec2text.invert_strings(
[
"Jack Morris is a PhD student at Cornell Tech in New York City",
"It was the best of times, it was the worst of times, it was the age of wisdom, it was the age of foolishness, it was the epoch of belief, it was the epoch of incredulity"
],
corrector=corrector,
num_steps=20,
sequence_beam_width=4,
)
['Jack Morris is a PhD student at Cornell Tech in New York City',
'It was the best of times, it was the worst of times, it was the age of wisdom, it was the age of foolishness, it was the epoch of belief, it was the epoch of incredulity']
Note that this technique has to store sequence_beam_width * sequence_beam_width
hypotheses at each step, so if you set it too high, you'll run out of GPU memory.
invert_embeddings
If you only have embeddings, you can invert them directly:
import torch
def get_embeddings_openai(text_list, model="text-embedding-ada-002") -> torch.Tensor:
client = openai.OpenAI()
response = client.embeddings.create(
input=text_list,
model=model,
encoding_format="float", # override default base64 encoding...
)
outputs.extend([e["embedding"] for e in response["data"]])
return torch.tensor(outputs)
embeddings = get_embeddings_openai([
"Jack Morris is a PhD student at Cornell Tech in New York City",
"It was the best of times, it was the worst of times, it was the age of wisdom, it was the age of foolishness, it was the epoch of belief, it was the epoch of incredulity"
])
vec2text.invert_embeddings(
embeddings=embeddings.cuda(),
corrector=corrector
)
['Morris is a PhD student at Cornell University in New York City',
'It was the age of incredulity, the age of wisdom, the age of apocalypse, the age of apocalypse, it was the age of faith, the age of best faith, it was the age of foolishness']
This function also takes the same optional hyperparameters, num_steps
and sequence_beam_width
.
import vec2text
import torch
from transformers import AutoModel, AutoTokenizer, PreTrainedTokenizer, PreTrainedModel
def get_gtr_embeddings(text_list,
encoder: PreTrainedModel,
tokenizer: PreTrainedTokenizer) -> torch.Tensor:
inputs = tokenizer(text_list,
return_tensors="pt",
max_length=128,
truncation=True,
padding="max_length",).to("cuda")
with torch.no_grad():
model_output = encoder(input_ids=inputs['input_ids'], attention_mask=inputs['attention_mask'])
hidden_state = model_output.last_hidden_state
embeddings = vec2text.models.model_utils.mean_pool(hidden_state, inputs['attention_mask'])
return embeddings
encoder = AutoModel.from_pretrained("sentence-transformers/gtr-t5-base").encoder.to("cuda")
tokenizer = AutoTokenizer.from_pretrained("sentence-transformers/gtr-t5-base")
corrector = vec2text.load_pretrained_corrector("gtr-base")
embeddings = get_gtr_embeddings([
"Jack Morris is a PhD student at Cornell Tech in New York City",
"It was the best of times, it was the worst of times, it was the age of wisdom, it was the age of foolishness, it was the epoch of belief, it was the epoch of incredulity"
], encoder, tokenizer)
vec2text.invert_embeddings(
embeddings=embeddings.cuda(),
corrector=corrector,
num_steps=20,
)
['Jack Morris Morris is a PhD student at Cornell Tech in New York City ',
'It was the best of times, it was the worst of times, it was the age of wisdom, it was the epoch of foolishness']
You can mix two embeddings together for interesting results. Given embeddings of the previous two inputs, we can invert their mean:
vec2text.invert_embeddings(
embeddings=embeddings.mean(dim=0, keepdim=True).cuda(),
corrector=corrector
)
['Morris was in the age of physics, the age of astronomy, the age of physics, the age of physics PhD at New York']
Or do linear interpolation (this isn't particularly interesting, feel free to submit a PR with a cooler example):
import numpy as np
for alpha in np.arange(0.0, 1.0, 0.1):
mixed_embedding = torch.lerp(input=embeddings[0], end=embeddings[1], weight=alpha)
text = vec2text.invert_embeddings(
embeddings=mixed_embedding[None].cuda(),
corrector=corrector,
num_steps=20,
sequence_beam_width=4,
)[0]
print(f'alpha={alpha:.1f}\t', text)
alpha=0.0 Jack Morris is a PhD student at Cornell Tech in New York City
alpha=0.1 Jack Morris is a PhD student at Cornell Tech in New York City
alpha=0.2 Jack Morris is a PhD student at Cornell Tech in New York City
alpha=0.3 Jack Morris is a PhD student at Cornell Institute of Technology in New York City
alpha=0.4 Jack Morris was a PhD student at Cornell Tech in New York City It is the epoch of wisdom, it is the epoch of incredulity
alpha=0.5 Jack Morris is a Ph.D. student at Cornell Tech in New York City It was the epoch of wisdom, it was the epoch of incredulity, it was the epoch of times
alpha=0.6 James Morris is a PhD student at New York Tech It was the epoch of wisdom, it was the age of incredulity, it was the best of times
alpha=0.7 It was the best of times, it was the worst of times, it was the age of wisdom, it was the age of incredulity, it was the epoch of incredulity at Morris, Ph.D
alpha=0.8 It was the best of times, it was the worst of times, it was the epoch of wisdom, it was the age of incredulity, it was the age of incredulity
alpha=0.9 It was the best of times, it was the worst of times, it was the age of wisdom, it was the age of incredulity, it was the age of belief, it was the epoch of foolishness
Most of the code in this repository facilitates training inversion models, which happens in essentially three steps:
Steps 2 and 3 happen together by simply executing the training script. Our code also supports precomputing hypotheses using DDP, which is useful because hypothesis generation on the full MSMARCO can take quite some time (even a few days) on a single GPU. Also note that you'll need a good amount of disk space; for example, storing full-precision ada-2 embeddings for all 8.8m documents from MSMARCO takes 54 GB of disk space.
Here's how you might train the zero-step model for GTR:
python run.py --per_device_train_batch_size 128 --per_device_eval_batch_size 128 --max_seq_length 128 --model_name_or_path t5-base --dataset_name msmarco --embedder_model_name gtr_base --num_repeat_tokens 16 --embedder_no_grad True --num_train_epochs 100 --max_eval_samples 500 --eval_steps 20000 --warmup_steps 10000 --bf16=1 --use_wandb=1 --use_frozen_embeddings_as_input True --experiment inversion --lr_scheduler_type constant_with_warmup --exp_group_name oct-gtr --learning_rate 0.001 --output_dir ./saves/gtr-1 --save_steps 2000
Note that there are a lot of options to change things about the data and model architecture. If you want to train the small GTR inverter from the paper, this command will work, but you'll have to reduce the maximum sequence length to 32. Once this model trains, add its path to the file aliases.py
along with the key gtr_msmarco__msl128__100epoch
and then run the following command to train the corrector:
python run.py --per_device_train_batch_size 32 --per_device_eval_batch_size 32 --max_seq_length 128 --model_name_or_path t5-base --dataset_name msmarco --embedder_model_name gtr_base --num_repeat_tokens 16 --embedder_no_grad True --num_train_epochs 100 --max_eval_samples 500 --eval_steps 20000 --warmup_steps 10000 --bf16=1 --use_wandb=1 --use_frozen_embeddings_as_input True --experiment corrector --lr_scheduler_type constant_with_warmup --exp_group_name oct-gtr --learning_rate 0.001 --output_dir ./saves/gtr-corrector-1 --save_steps 2000 --corrector_model_alias gtr_msmarco__msl128__100epoch
If using DDP, run the same command using torchrun run.py
instead of python run.py
. You can upload these models to the HuggingFace using our script by running python scripts/upload_model.py <model_alias> <model_hub_name>
.
Currently we only support models for inverting OpenAI text-embedding-ada-002
embeddings but are hoping to add more soon. (We can provide the GTR inverters used in the paper upon request.)
Our models come in one of two forms: a zero-step 'hypothesizer' model that makes a guess for what text is from an embedding and a 'corrector' model that iteratively corrects and re-embeds text to bring it closer to the target embedding. We also support sequence-level beam search which makes multiple corrective guesses at each step and takes the one closest to the ground-truth embedding.
CHECKPOINT_FOLDERS_DICT
in aliases.py
. This tells our codebase (i) what the name (alias) of your model is and (ii) the folder where its weights are stored.huggingface-cli login
python scripts/upload_model.py <model_alias> <hf_alias>
where <model_alias>
is the key of the model you added to aliases.py and <hf_alias>
will be the model's name on HuggingFacepip install isort black flake8 mypy --upgrade
pre-commit run --all
Here's how to load and evaluate the sequence-length 32 GTR inversion model in the paper:
from vec2text import analyze_utils
experiment, trainer = analyze_utils.load_experiment_and_trainer_from_pretrained(
"jxm/gtr__nq__32__correct"
)
train_datasets = experiment._load_train_dataset_uncached(
model=trainer.model,
tokenizer=trainer.tokenizer,
embedder_tokenizer=trainer.embedder_tokenizer
)
val_datasets = experiment._load_val_datasets_uncached(
model=trainer.model,
tokenizer=trainer.tokenizer,
embedder_tokenizer=trainer.embedder_tokenizer
)
trainer.args.per_device_eval_batch_size = 16
trainer.sequence_beam_width = 1
trainer.num_gen_recursive_steps = 20
trainer.evaluate(
eval_dataset=train_datasets["validation"]
)
This repository was also used to train language model inverters for our paper Language Model Inversion.
This is the dataset of prompts used for training (referred two as "Two Million Instructions" in the manuscript but One Million Instructions on HuggingFace): https://huggingface.co/datasets/wentingzhao/one-million-instructions
Here is a sample command for training a language model inverter:
python vec2text/run.py --per_device_train_batch_size 16 --per_device_eval_batch_size 16 --max_seq_length 128 --num_train_epochs 100 --max_eval_samples 1000 --eval_steps 25000 --warmup_steps 100000 --learning_rate 0.0002 --dataset_name one_million_instructions --model_name_or_path t5-base --use_wandb=0 --embedder_model_name gpt2 --experiment inversion_from_logits_emb --bf16=1 --embedder_torch_dtype float16 --lr_scheduler_type constant_with_warmup --use_frozen_embeddings_as_input 1 --mock_embedder 0
The models used for our Language Model Inversion paper are available for download from HuggingFace. Here is the LLAMA-2 base inverter and the LLAMA-2 chat inverter. Those models can also be pre-trained from scratch using this repository (everything you need should be downloaded automatically from HuggingFace).
The training dataset of 2.33M prompts is available here: https://huggingface.co/datasets/wentingzhao/one-million-instructions As well as our Private Prompts synthetic evaluation data: https://huggingface.co/datasets/jxm/private_prompts
Here's an example of how to evaluate on the Python-Alpaca dataset:
from vec2text import analyze_utils
experiment, trainer = analyze_utils.load_experiment_and_trainer_from_pretrained(
"jxm/t5-base__llama-7b__one-million-instructions__emb"
)
trainer.model.use_frozen_embeddings_as_input = False
trainer.args.per_device_eval_batch_size = 16
trainer.evaluate(
eval_dataset=trainer.eval_dataset["python_code_alpaca"].remove_columns("frozen_embeddings").select(range(200))
)
if you benefit from the code or the research, please cite our papers!
This repository includes code for two papers:
Text Embeddings Reveal (Almost) As Much As Text (EMNLP 2023)
@misc{morris2023text,
title={Text Embeddings Reveal (Almost) As Much As Text},
author={John X. Morris and Volodymyr Kuleshov and Vitaly Shmatikov and Alexander M. Rush},
year={2023},
eprint={2310.06816},
archivePrefix={arXiv},
primaryClass={cs.CL}
}
Language Model Inversion (ICLR 2024)
@misc{morris2023language,
title={Language Model Inversion},
author={John X. Morris and Wenting Zhao and Justin T. Chiu and Vitaly Shmatikov and Alexander M. Rush},
year={2023},
eprint={2311.13647},
archivePrefix={arXiv},
primaryClass={cs.CL}
}