""" bpe is short for Byte Pair Encoder. It translates arbitrary utf-8 strings into sequences of integers, where each integer represents small chunks of commonly occuring characters. This implementation is based on openai's gpt2 encoder.py: https://github.com/openai/gpt-2/blob/master/src/encoder.py but was mildly modified because the original implementation is a bit confusing. I also tried to add as many comments as possible, my own understanding of what's going on. """ import os import json import regex as re import requests import torch # ----------------------------------------------------------------------------- def bytes_to_unicode(): """ Every possible byte (really an integer 0..255) gets mapped by OpenAI to a unicode character that represents it visually. Some bytes have their appearance preserved because they don't cause any trouble. These are defined in list bs. For example: chr(33) returns "!", so in the returned dictionary we simply have d[33] -> "!". However, chr(0), for example, is '\x00', which looks ugly. So OpenAI maps these bytes, into new characters in a range where chr() returns a single nice character. So in the final dictionary we have d[0] -> 'Ā' instead, which is just chr(0 + 2**8). In particular, the space character is 32, which we can see by ord(' '). Instead, this function will shift space (32) by 256 to 288, so d[32] -> 'Ġ'. So this is just a simple one-to-one mapping of bytes 0..255 into unicode characters that "look nice", either in their original form, or a funny shifted character like 'Ā', or 'Ġ', etc. """ # the 188 integers that render fine in their original form and need no shifting bs = list(range(ord("!"), ord("~")+1))+list(range(ord("¡"), ord("¬")+1))+list(range(ord("®"), ord("ÿ")+1)) cs = bs[:] # all integers b in bs will simply map to chr(b) in the output dict # now get the representations of the other 68 integers that do need shifting # each will get mapped chr(256 + n), where n will grow from 0...67 in the loop n = 0 for b in range(2**8): if b not in bs: # if this byte is "ugly" then map it to the next available "nice" character bs.append(b) cs.append(2**8+n) n += 1 cs = [chr(n) for n in cs] d = dict(zip(bs, cs)) return d def get_pairs(word): """ Return all bigrams as a set of tuples, of consecutive elements in the iterable word. """ pairs = set() prev_char = word[0] for char in word[1:]: pairs.add((prev_char, char)) prev_char = char return pairs class Encoder: def __init__(self, encoder, bpe_merges): # byte encoder/decoder self.byte_encoder = bytes_to_unicode() self.byte_decoder = {v:k for k, v in self.byte_encoder.items()} # bpe token encoder/decoder self.encoder = encoder self.decoder = {v:k for k,v in self.encoder.items()} # bpe merge list that defines the bpe "tree", of tuples (a,b) that are to merge to token ab self.bpe_ranks = dict(zip(bpe_merges, range(len(bpe_merges)))) # the splitting pattern used for pre-tokenization # Should haved added re.IGNORECASE so BPE merges can happen for capitalized versions of contractions <-- original openai comment """ ok so what is this regex looking for, exactly? python re reference: https://docs.python.org/3/library/re.html - the vertical bars | is OR, so re.findall will chunkate text as the pieces match, from left to right - '\'s' would split up things like Andrej's -> (Andrej, 's) - ' ?\p{L}': optional space followed by 1+ unicode code points in the category "letter" - ' ?\p{N}': optional space followed by 1+ unicode code points in the category "number" - ' ?[^\s\p{L}\p{N}]+': optional space, then 1+ things that are NOT a whitespace, letter or number - '\s+(?!\S)': 1+ whitespace characters (e.g. space or tab or etc) UNLESS they are followed by non-whitespace so this will consume whitespace characters in a sequence but exclude the last whitespace in that sequence. that last whitespace has the opportunity to then match the optional ' ?' in earlier patterns. - '\s+': 1+ whitespace characters, intended probably to catch a full trailing sequence of whitespaces at end of string So TLDR: - we are special casing a few common apostrophe constructs ('s, 't, 're, ...) and making those into separate tokens - we then separate out strings into consecutive chunks of 1) letters, 2) numbers, 3) non-letter-numbers, 4) whitespaces """ self.pat = re.compile(r"""'s|'t|'re|'ve|'m|'ll|'d| ?\p{L}+| ?\p{N}+| ?[^\s\p{L}\p{N}]+|\s+(?!\S)|\s+""") self.cache = {} def bpe(self, token): """ this function uses self.bpe_ranks to iteratively merge all the possible bpe tokens up the tree. token is a string of one individual 'word' (after regex tokenization) and after byte encoding, e.g. 'Ġthere'. """ # token is a string of one individual 'word', after byte encoding, e.g. 'Ġthere' # memoization, for efficiency if token in self.cache: return self.cache[token] word = tuple(token) # individual characters that make up the token, in a tuple pairs = get_pairs(word) # get all bigrams if not pairs: return token while True: # find the next lowest rank bigram that can be merged bigram = min(pairs, key = lambda pair: self.bpe_ranks.get(pair, float('inf'))) if bigram not in self.bpe_ranks: break # no more bigrams are eligible to be merged first, second = bigram # we will now replace all occurences of (first, second) in the list of current # words into one merged token first_second, in the output list new_words new_word = [] i = 0 while i < len(word): # find the next occurence of first in the sequence of current words try: j = word.index(first, i) new_word.extend(word[i:j]) i = j except: new_word.extend(word[i:]) break # if this occurence is also followed by second, then merge them into one if word[i] == first and i < len(word)-1 and word[i+1] == second: new_word.append(first+second) i += 2 else: new_word.append(word[i]) i += 1 # all occurences of (first, second) have been merged to first_second new_word = tuple(new_word) word = new_word if len(word) == 1: break else: pairs = get_pairs(word) # concat all words into a string, and use ' ' as the separator. Note that # by now all characters have been byte encoded, guaranteeing that ' ' is # not used in the actual data and is a 'special' delimiter character word = ' '.join(word) # cache the result and return self.cache[token] = word return word def encode(self, text): """ string goes in, list of integers comes out """ bpe_idx = [] # pre-tokenize the input text into string tokens (words, roughly speaking) tokens = re.findall(self.pat, text) # process each token into BPE integers for token in tokens: # encode the token as a bytes (b'') object token_bytes = token.encode('utf-8') # translate all bytes to their unicode string representation and flatten token_translated = ''.join(self.byte_encoder[b] for b in token_bytes) # perform all the applicable bpe merges according to self.bpe_ranks token_merged = self.bpe(token_translated).split(' ') # translate all bpe tokens to integers token_ix = [self.encoder[bpe_token] for bpe_token in token_merged] # extend our running list of all output integers bpe_idx.extend(token_ix) return bpe_idx def encode_and_show_work(self, text): """ debugging function, same as encode but returns all intermediate work """ bpe_idx = [] parts = [] tokens = re.findall(self.pat, text) for token in tokens: token_bytes = token.encode('utf-8') token_translated = ''.join(self.byte_encoder[b] for b in token_bytes) token_merged = self.bpe(token_translated).split(' ') token_ix = [self.encoder[bpe_token] for bpe_token in token_merged] bpe_idx.extend(token_ix) parts.append({ 'token': token, 'token_bytes': token_bytes, 'token_translated': token_translated, 'token_merged': token_merged, 'token_ix': token_ix, }) out = { 'bpe_idx': bpe_idx, # the actual output sequence 'tokens': tokens, # result of pre-tokenization 'parts': parts, # intermediates for each token part } return out def decode(self, bpe_idx): """ list of integers comes in, string comes out """ # inverse map the integers to get the tokens tokens_merged = [self.decoder[token] for token in bpe_idx] # inverse the byte encoder, e.g. recovering 'Ġ' -> ' ', and get the bytes tokens_flat = ''.join(tokens_merged) tokens_bytes = bytearray([self.byte_decoder[c] for c in tokens_flat]) # recover the full utf-8 string text = tokens_bytes.decode('utf-8', errors='replace') return text def get_file(local_file, remote_file): """ downloads remote_file to local_file if necessary """ if not os.path.isfile(local_file): print(f"downloading {remote_file} to {local_file}") response = requests.get(remote_file) open(local_file, "wb").write(response.content) def get_encoder(): """ Returns an instance of the GPT BPE Encoder/Decoder and handles caching of "database" files. """ home_dir = os.path.expanduser('~') cache_dir = os.path.join(home_dir, '.cache', 'mingpt') os.makedirs(cache_dir, exist_ok=True) # load encoder.json that has the raw mappings from token -> bpe index encoder_local_file = os.path.join(cache_dir, 'encoder.json') encoder_remote_file = 'https://openaipublic.blob.core.windows.net/gpt-2/models/124M/encoder.json' get_file(encoder_local_file, encoder_remote_file) with open(encoder_local_file, 'r') as f: encoder = json.load(f) assert len(encoder) == 50257 # 256 individual byte tokens, 50,000 merged tokens, and 1 special <|endoftext|> token # load vocab.bpe that contains the bpe merges, i.e. the bpe tree structure # in the form tuples (a, b), that indicate that (a, b) is to be merged to one token ab vocab_local_file = os.path.join(cache_dir, 'vocab.bpe') vocab_remote_file = 'https://openaipublic.blob.core.windows.net/gpt-2/models/124M/vocab.bpe' get_file(vocab_local_file, vocab_remote_file) with open(vocab_local_file, 'r', encoding="utf-8") as f: bpe_data = f.read() # light postprocessing: strip the version on first line and the last line is a blank bpe_merges = [tuple(merge_str.split()) for merge_str in bpe_data.split('\n')[1:-1]] assert len(bpe_merges) == 50000 # 50,000 merged tokens # construct the Encoder object and return enc = Encoder(encoder, bpe_merges) return enc # ----------------------------------------------------------------------------- class BPETokenizer: """ PyTorch-aware class that wraps the Encoder above """ def __init__(self): self.encoder = get_encoder() def __call__(self, text, return_tensors='pt'): # PyTorch only; here because we want to match huggingface/transformers interface assert return_tensors == 'pt' # single string input for now, in the future potentially a list of strings assert isinstance(text, str) # encode and create a "batch dimension" of 1 idx = [self.encoder.encode(text)] # wrap into PyTorch tensor out = torch.tensor(idx, dtype=torch.long) return out def decode(self, idx): # ensure a simple 1D tensor for now assert idx.ndim == 1 # decode indices to text text = self.encoder.decode(idx.tolist()) return text if __name__ == '__main__': # here is an encoding example text = "Hello!! I'm Andrej Karpathy. It's 2022. w00t :D 🤗" e = get_encoder() r = e.encode_and_show_work(text) print("Original text is:") print(text) print("First the text gets pre-tokenized, broken up into chunks, the outcome is:") print(r['tokens']) # ['Hello', '!!', ' I', "'m", ' Andrej', ' Karpathy', '.', ' It', "'s", ' 2022', '.', ' w', '00', 't', ' :', 'D', ' 🤗'] print("Then we iterate over each chunk and process them in turn...") for part in r['parts']: print(part) # {'token': 'Hello', 'token_bytes': b'Hello', 'token_translated': 'Hello', 'token_merged': ['Hello'], 'token_ix': [15496]} # {'token': '!!', 'token_bytes': b'!!', 'token_translated': '!!', 'token_merged': ['!!'], 'token_ix': [3228]} # {'token': ' I', 'token_bytes': b' I', 'token_translated': 'ĠI', 'token_merged': ['ĠI'], 'token_ix': [314]} # {'token': "'m", 'token_bytes': b"'m", 'token_translated': "'m", 'token_merged': ["'m"], 'token_ix': [1101]} # {'token': ' Andrej', 'token_bytes': b' Andrej', 'token_translated': 'ĠAndrej', 'token_merged': ['ĠAndre', 'j'], 'token_ix': [10948, 73]} # {'token': ' Karpathy', 'token_bytes': b' Karpathy', 'token_translated': 'ĠKarpathy', 'token_merged': ['ĠK', 'arp', 'athy'], 'token_ix': [509, 5117, 10036]} # {'token': '.', 'token_bytes': b'.', 'token_translated': '.', 'token_merged': ['.'], 'token_ix': [13]} # {'token': ' It', 'token_bytes': b' It', 'token_translated': 'ĠIt', 'token_merged': ['ĠIt'], 'token_ix': [632]} # {'token': "'s", 'token_bytes': b"'s", 'token_translated': "'s", 'token_merged': ["'s"], 'token_ix': [338]} # {'token': ' 2022', 'token_bytes': b' 2022', 'token_translated': 'Ġ2022', 'token_merged': ['Ġ2022'], 'token_ix': [33160]} # {'token': '.', 'token_bytes': b'.', 'token_translated': '.', 'token_merged': ['.'], 'token_ix': [13]} # {'token': ' w', 'token_bytes': b' w', 'token_translated': 'Ġw', 'token_merged': ['Ġw'], 'token_ix': [266]} # {'token': '00', 'token_bytes': b'00', 'token_translated': '00', 'token_merged': ['00'], 'token_ix': [405]} # {'token': 't', 'token_bytes': b't', 'token_translated': 't', 'token_merged': ['t'], 'token_ix': [83]} # {'token': ' :', 'token_bytes': b' :', 'token_translated': 'Ġ:', 'token_merged': ['Ġ:'], 'token_ix': [1058]} # {'token': 'D', 'token_bytes': b'D', 'token_translated': 'D', 'token_merged': ['D'], 'token_ix': [35]} # {'token': ' 🤗', 'token_bytes': b' \xf0\x9f\xa4\x97', 'token_translated': 'ĠðŁ¤Ĺ', 'token_merged': ['ĠðŁ', '¤', 'Ĺ'], 'token_ix': [12520, 97, 245]} # (refer to the code inside Encoder.encode for what these intermediates are) print("and the final outcome is concatenating and flattening all the token_ix:") print(r['bpe_idx']) # [15496, 3228, 314, 1101, 10948, 73, 509, 5117, 10036, 13, 632, 338, 33160, 13, 266, 405, 83, 1058, 35, 12520, 97, 245] # this would then become the integer input sequence to the transformer print("ready to feed into a Transformer!")