# Perplexity of fixed-length models [[open-in-colab]] Perplexity (PPL) is one of the most common metrics for evaluating language models. Before diving in, we should note that the metric applies specifically to classical language models (sometimes called autoregressive or causal language models) and is not well defined for masked language models like BERT (see [summary of the models](model_summary)). Perplexity is defined as the exponentiated average negative log-likelihood of a sequence. If we have a tokenized sequence \$X = (x_0, x_1, \dots, x_t)\$, then the perplexity of \$X\$ is, $$\text{PPL}(X) = \exp \left\{ {-\frac{1}{t}\sum_i^t \log p_\theta (x_i|x_{ When working with approximate models, however, we typically have a constraint on the number of tokens the model can process. The largest version of [GPT-2](model_doc/gpt2), for example, has a fixed length of 1024 tokens, so we cannot calculate \\(p_\theta(x_t|x_{ This is quick to compute since the perplexity of each segment can be computed in one forward pass, but serves as a poor approximation of the fully-factorized perplexity and will typically yield a higher (worse) PPL because the model will have less context at most of the prediction steps. Instead, the PPL of fixed-length models should be evaluated with a sliding-window strategy. This involves repeatedly sliding the context window so that the model has more context when making each prediction. Sliding window PPL taking advantage of all available context

Sliding window PPL taking advantage of all available context

This is a closer approximation to the true decomposition of the sequence probability and will typically yield a more favorable score. The downside is that it requires a separate forward pass for each token in the corpus. A good practical compromise is to employ a strided sliding window, moving the context by larger strides rather than sliding by 1 token a time. This allows computation to proceed much faster while still giving the model a large context to make predictions at each step. ## Example: Calculating perplexity with GPT-2 in 🤗 Transformers Let's demonstrate this process with GPT-2. ```python from transformers import GPT2LMHeadModel, GPT2TokenizerFast device = "cuda" model_id = "gpt2-large" model = GPT2LMHeadModel.from_pretrained(model_id).to(device) tokenizer = GPT2TokenizerFast.from_pretrained(model_id) ``` We'll load in the WikiText-2 dataset and evaluate the perplexity using a few different sliding-window strategies. Since this dataset is small and we're just doing one forward pass over the set, we can just load and encode the entire dataset in memory. ```python from datasets import load_dataset test = load_dataset("wikitext", "wikitext-2-raw-v1", split="test") encodings = tokenizer("\n\n".join(test["text"]), return_tensors="pt") ``` With 🤗 Transformers, we can simply pass the `input_ids` as the `labels` to our model, and the average negative log-likelihood for each token is returned as the loss. With our sliding window approach, however, there is overlap in the tokens we pass to the model at each iteration. We don't want the log-likelihood for the tokens we're just treating as context to be included in our loss, so we can set these targets to `-100` so that they are ignored. The following is an example of how we could do this with a stride of `512`. This means that the model will have at least 512 tokens for context when calculating the conditional likelihood of any one token (provided there are 512 preceding tokens available to condition on). ```python import torch from tqdm import tqdm max_length = model.config.n_positions stride = 512 seq_len = encodings.input_ids.size(1) nlls = [] prev_end_loc = 0 for begin_loc in tqdm(range(0, seq_len, stride)): end_loc = min(begin_loc + max_length, seq_len) trg_len = end_loc - prev_end_loc # may be different from stride on last loop input_ids = encodings.input_ids[:, begin_loc:end_loc].to(device) target_ids = input_ids.clone() target_ids[:, :-trg_len] = -100 with torch.no_grad(): outputs = model(input_ids, labels=target_ids) # loss is calculated using CrossEntropyLoss which averages over valid labels # N.B. the model only calculates loss over trg_len - 1 labels, because it internally shifts the labels # to the left by 1. neg_log_likelihood = outputs.loss nlls.append(neg_log_likelihood) prev_end_loc = end_loc if end_loc == seq_len: break ppl = torch.exp(torch.stack(nlls).mean()) ``` Running this with the stride length equal to the max input length is equivalent to the suboptimal, non-sliding-window strategy we discussed above. The smaller the stride, the more context the model will have in making each prediction, and the better the reported perplexity will typically be. When we run the above with `stride = 1024`, i.e. no overlap, the resulting PPL is `19.44`, which is about the same as the `19.93` reported in the GPT-2 paper. By using `stride = 512` and thereby employing our striding window strategy, this jumps down to `16.45`. This is not only a more favorable score, but is calculated in a way that is closer to the true autoregressive decomposition of a sequence likelihood.