--- language: en tags: - timelms - twitter license: mit datasets: - twitter-api --- # Twitter June 2021 (RoBERTa-base, 115M) This is a RoBERTa-base model trained on 115.46M tweets until the end of June 2021. More details and performance scores are available in the [TimeLMs paper](https://arxiv.org/abs/2202.03829). Below, we provide some usage examples using the standard Transformers interface. For another interface more suited to comparing predictions and perplexity scores between models trained at different temporal intervals, check the [TimeLMs repository](https://github.com/cardiffnlp/timelms). For other models trained until different periods, check this [table](https://github.com/cardiffnlp/timelms#released-models). ## Preprocess Text Replace usernames and links for placeholders: "@user" and "http". If you're interested in retaining verified users which were also retained during training, you may keep the users listed [here](https://github.com/cardiffnlp/timelms/tree/main/data). ```python def preprocess(text): preprocessed_text = [] for t in text.split(): if len(t) > 1: t = '@user' if t[0] == '@' and t.count('@') == 1 else t t = 'http' if t.startswith('http') else t preprocessed_text.append(t) return ' '.join(preprocessed_text) ``` ## Example Masked Language Model ```python from transformers import pipeline, AutoTokenizer MODEL = "cardiffnlp/twitter-roberta-base-jun2021" fill_mask = pipeline("fill-mask", model=MODEL, tokenizer=MODEL) tokenizer = AutoTokenizer.from_pretrained(MODEL) def pprint(candidates, n): for i in range(n): token = tokenizer.decode(candidates[i]['token']) score = candidates[i]['score'] print("%d) %.5f %s" % (i+1, score, token)) texts = [ "So glad I'm vaccinated.", "I keep forgetting to bring a .", "Looking forward to watching Game tonight!", ] for text in texts: t = preprocess(text) print(f"{'-'*30}\n{t}") candidates = fill_mask(t) pprint(candidates, 5) ``` Output: ``` ------------------------------ So glad I'm vaccinated. 1) 0.45169 fully 2) 0.22353 getting 3) 0.18540 not 4) 0.02392 still 5) 0.02231 already ------------------------------ I keep forgetting to bring a . 1) 0.06331 mask 2) 0.05423 book 3) 0.04505 knife 4) 0.03742 laptop 5) 0.03456 bag ------------------------------ Looking forward to watching Game tonight! 1) 0.69811 the 2) 0.14435 The 3) 0.02396 this 4) 0.00932 Championship 5) 0.00785 End ``` ## Example Tweet Embeddings ```python from transformers import AutoTokenizer, AutoModel, TFAutoModel import numpy as np from scipy.spatial.distance import cosine from collections import Counter def get_embedding(text): # naive approach for demonstration text = preprocess(text) encoded_input = tokenizer(text, return_tensors='pt') features = model(**encoded_input) features = features[0].detach().cpu().numpy() return np.mean(features[0], axis=0) MODEL = "cardiffnlp/twitter-roberta-base-jun2021" tokenizer = AutoTokenizer.from_pretrained(MODEL) model = AutoModel.from_pretrained(MODEL) query = "The book was awesome" tweets = ["I just ordered fried chicken 🐣", "The movie was great", "What time is the next game?", "Just finished reading 'Embeddings in NLP'"] sims = Counter() for tweet in tweets: sim = 1 - cosine(get_embedding(query), get_embedding(tweet)) sims[tweet] = sim print('Most similar to: ', query) print(f"{'-'*30}") for idx, (tweet, sim) in enumerate(sims.most_common()): print("%d) %.5f %s" % (idx+1, sim, tweet)) ``` Output: ``` Most similar to: The book was awesome ------------------------------ 1) 0.99014 The movie was great 2) 0.96346 Just finished reading 'Embeddings in NLP' 3) 0.95836 I just ordered fried chicken 🐣 4) 0.95051 What time is the next game? ``` ## Example Feature Extraction ```python from transformers import AutoTokenizer, AutoModel, TFAutoModel import numpy as np MODEL = "cardiffnlp/twitter-roberta-base-jun2021" tokenizer = AutoTokenizer.from_pretrained(MODEL) text = "Good night 😊" text = preprocess(text) # Pytorch model = AutoModel.from_pretrained(MODEL) encoded_input = tokenizer(text, return_tensors='pt') features = model(**encoded_input) features = features[0].detach().cpu().numpy() features_mean = np.mean(features[0], axis=0) #features_max = np.max(features[0], axis=0) # # Tensorflow # model = TFAutoModel.from_pretrained(MODEL) # encoded_input = tokenizer(text, return_tensors='tf') # features = model(encoded_input) # features = features[0].numpy() # features_mean = np.mean(features[0], axis=0) # #features_max = np.max(features[0], axis=0) ```