nanogpt-experiments/data/openwebtext/prepare.py

# saves the openwebtext dataset to a binary file for training. following was helpful:
# https://github.com/HazyResearch/flash-attention/blob/main/training/src/datamodules/language_modeling_hf.py

from tqdm import tqdm
import numpy as np
import tiktoken
from datasets import load_dataset # huggingface datasets

# number of workers in .map() call
# good number to use is ~order number of cpu cores // 2
num_proc = 8

# takes 54GB in huggingface .cache dir, about 8M documents (8,013,769)
dataset = load_dataset("openwebtext")

# owt by default only contains the 'train' split, so create a test split
split_dataset = dataset["train"].train_test_split(test_size=0.0005, seed=2357, shuffle=True)
split_dataset['val'] = split_dataset.pop('test') # rename the test split to val

# this results in:
# >>> split_dataset
# DatasetDict({
#     train: Dataset({
#         features: ['text'],
#         num_rows: 8009762
#     })
#     val: Dataset({
#         features: ['text'],
#         num_rows: 4007
#     })
# })

# we now want to tokenize the dataset. first define the encoding function (gpt2 bpe)
enc = tiktoken.get_encoding("gpt2")
def process(example):
    ids = enc.encode_ordinary(example['text']) # encode_ordinary ignores any special tokens
    ids.append(enc.eot_token) # add the end of text token, e.g. 50256 for gpt2 bpe
    # note: I think eot should be prepended not appended... hmm. it's called "eot" though...
    out = {'ids': ids, 'len': len(ids)}
    return out

# tokenize the dataset
tokenized = split_dataset.map(
    process,
    remove_columns=['text'],
    desc="tokenizing the splits",
    num_proc=num_proc,
)

# concatenate all the ids in each dataset into one large file we can use for training
for split, dset in tokenized.items():
    arr_len = np.sum(dset['len'])
    filename = f'{split}.bin'
    dtype = np.uint16 # (can do since enc.max_token_value == 50256 is < 2**16)
    arr = np.memmap(filename, dtype=dtype, mode='w+', shape=(arr_len,))

    print(f"writing {filename}...")
    idx = 0
    for example in tqdm(dset):
        arr[idx : idx + example['len']] = example['ids']
        idx += example['len']
    arr.flush()

# train.bin is ~17GB, val.bin ~8.5MB
# train has ~9B tokens (9,035,582,198)
# val has ~4M tokens (4,434,897)

# to read the bin files later, e.g. with numpy:
# m = np.memmap('train.bin', dtype=np.uint16, mode='r')
first very bad commit 2022-12-28 00:58:19 +00:00			`# saves the openwebtext dataset to a binary file for training. following was helpful:`
			`# https://github.com/HazyResearch/flash-attention/blob/main/training/src/datamodules/language_modeling_hf.py`

simplify the prepare script a lot, write only using one process, seems sufficient for now. ty @LaihoE for suggestion and @proger for flagging 2022-12-30 22:18:20 +00:00			`from tqdm import tqdm`
first very bad commit 2022-12-28 00:58:19 +00:00			`import numpy as np`
			`import tiktoken`
			`from datasets import load_dataset # huggingface datasets`

simplify the prepare script a lot, write only using one process, seems sufficient for now. ty @LaihoE for suggestion and @proger for flagging 2022-12-30 22:18:20 +00:00			`# number of workers in .map() call`
			`# good number to use is ~order number of cpu cores // 2`
			`num_proc = 8`
first very bad commit 2022-12-28 00:58:19 +00:00
			`# takes 54GB in huggingface .cache dir, about 8M documents (8,013,769)`
			`dataset = load_dataset("openwebtext")`

			`# owt by default only contains the 'train' split, so create a test split`
			`split_dataset = dataset["train"].train_test_split(test_size=0.0005, seed=2357, shuffle=True)`
			`split_dataset['val'] = split_dataset.pop('test') # rename the test split to val`

			`# this results in:`
			`# >>> split_dataset`
			`# DatasetDict({`
			`# train: Dataset({`
			`# features: ['text'],`
			`# num_rows: 8009762`
			`# })`
			`# val: Dataset({`
			`# features: ['text'],`
			`# num_rows: 4007`
			`# })`
			`# })`

			`# we now want to tokenize the dataset. first define the encoding function (gpt2 bpe)`
			`enc = tiktoken.get_encoding("gpt2")`
			`def process(example):`
			`ids = enc.encode_ordinary(example['text']) # encode_ordinary ignores any special tokens`
			`ids.append(enc.eot_token) # add the end of text token, e.g. 50256 for gpt2 bpe`
candidate changes to apis, have to think through more 2023-01-01 01:29:48 +00:00			`# note: I think eot should be prepended not appended... hmm. it's called "eot" though...`
first very bad commit 2022-12-28 00:58:19 +00:00			`out = {'ids': ids, 'len': len(ids)}`
			`return out`

			`# tokenize the dataset`
			`tokenized = split_dataset.map(`
			`process,`
			`remove_columns=['text'],`
			`desc="tokenizing the splits",`
			`num_proc=num_proc,`
			`)`

			`# concatenate all the ids in each dataset into one large file we can use for training`
			`for split, dset in tokenized.items():`
simplify the prepare script a lot, write only using one process, seems sufficient for now. ty @LaihoE for suggestion and @proger for flagging 2022-12-30 22:18:20 +00:00			`arr_len = np.sum(dset['len'])`
first very bad commit 2022-12-28 00:58:19 +00:00			`filename = f'{split}.bin'`
			`dtype = np.uint16 # (can do since enc.max_token_value == 50256 is < 2**16)`
simplify the prepare script a lot, write only using one process, seems sufficient for now. ty @LaihoE for suggestion and @proger for flagging 2022-12-30 22:18:20 +00:00			`arr = np.memmap(filename, dtype=dtype, mode='w+', shape=(arr_len,))`
first very bad commit 2022-12-28 00:58:19 +00:00
simplify the prepare script a lot, write only using one process, seems sufficient for now. ty @LaihoE for suggestion and @proger for flagging 2022-12-30 22:18:20 +00:00			`print(f"writing {filename}...")`
			`idx = 0`
			`for example in tqdm(dset):`
			`arr[idx : idx + example['len']] = example['ids']`
			`idx += example['len']`
			`arr.flush()`
first very bad commit 2022-12-28 00:58:19 +00:00
			`# train.bin is ~17GB, val.bin ~8.5MB`
			`# train has ~9B tokens (9,035,582,198)`
			`# val has ~4M tokens (4,434,897)`

			`# to read the bin files later, e.g. with numpy:`
			`# m = np.memmap('train.bin', dtype=np.uint16, mode='r')`