Perplexity measures how predictable a text is by a language model (LM), and it is often used to evaluate fluency or proto-typicality of the text (lower the perplexity is, more fluent or proto-typical the text is). LM-PPL is a python library to calculate perplexity on a text with any types of pre-trained LMs. We compute an ordinary perplexity for recurrent LMs such as GPT3 (Brown et al., 2020) and the perplexity of the decoder for encoder-decoder LMs such as BART (Lewis et al., 2020) or T5 (Raffel et al., 2020), while we compute pseudo-perplexity (Wang and Cho, 2018) for masked LMs.
Install via pip.
pip install lmppl
Let's solve sentiment analysis with perplexity as an example! Remember the text with lower perplexity is better, so we compare two texts (positive and negative) and choose the one with lower perplexity as the model prediction.
- Recurrent LM including variants of GPT.
import lmppl
scorer = lmppl.LM('gpt2')
text = [
'sentiment classification: I dropped my laptop on my knee, and someone stole my coffee. I am happy.',
'sentiment classification: I dropped my laptop on my knee, and someone stole my coffee. I am sad.'
]
ppl = scorer.get_perplexity(text)
print(list(zip(text, ppl)))
>>> [
('sentiment classification: I dropped my laptop on my knee, and someone stole my coffee. I am happy.', 136.64255272925908),
('sentiment classification: I dropped my laptop on my knee, and someone stole my coffee. I am sad.', 139.2400838400971)
]
print(f"prediction: {text[ppl.index(min(ppl))]}")
>>> "prediction: sentiment classification: I dropped my laptop on my knee, and someone stole my coffee. I am happy."
- Masked LM including variants of BERT.
import lmppl
scorer = lmppl.MaskedLM('microsoft/deberta-v3-small')
text = [
'sentiment classification: I dropped my laptop on my knee, and someone stole my coffee. I am happy.',
'sentiment classification: I dropped my laptop on my knee, and someone stole my coffee. I am sad.'
]
ppl = scorer.get_perplexity(text)
print(list(zip(text, ppl)))
>>> [
('sentiment classification: I dropped my laptop on my knee, and someone stole my coffee. I am happy.', 1190212.1699246117),
('sentiment classification: I dropped my laptop on my knee, and someone stole my coffee. I am sad.', 1152767.482071837)
]
print(f"prediction: {text[ppl.index(min(ppl))]}")
>>> "prediction: sentiment classification: I dropped my laptop on my knee, and someone stole my coffee. I am sad."
- Encoder-Decoder LM including variants of T5 and BART.
import lmppl
scorer = lmppl.EncoderDecoderLM('google/flan-t5-small')
inputs = [
'sentiment classification: I dropped my laptop on my knee, and someone stole my coffee.',
'sentiment classification: I dropped my laptop on my knee, and someone stole my coffee.'
]
outputs = [
'I am happy.',
'I am sad.'
]
ppl = scorer.get_perplexity(input_texts=inputs, output_texts=outputs)
print(list(zip(outputs, ppl)))
>>> [
('I am happy.', 4138.748977714201),
('I am sad.', 2991.629250051472)
]
print(f"prediction: {outputs[ppl.index(min(ppl))]}")
>>> "prediction: I am sad."
-
Max Token Length: Each LM has its own max-token length (
max_length
for recurrent/masked LMs, andmax_length_encoder
andmax_length_decoder
for encoder-decoder LMs). Limiting those max-token will reduce the time to process the text, but it may affect the accuracy of the perplexity, so please experiment on your texts and decide an optimal token length. -
Batch Size: One can pass batch size to the function
get_perplexity
(eg.get_perplexity(text, batch_size=32)
). As default, it will process all the text once, that may cause memory error if the number of texts is too large.