mirror of
https://github.com/ml-explore/mlx-examples.git
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328 lines
10 KiB
Python
328 lines
10 KiB
Python
# Copyright © 2024 Apple Inc.
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import glob
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import shutil
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import time
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from dataclasses import dataclass, field
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from pathlib import Path
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from typing import Union
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import mlx.core as mx
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import mlx.nn as nn
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import numpy as np
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from mlx.nn.utils import average_gradients
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from mlx.utils import tree_flatten
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def grad_checkpoint(layer):
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"""
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Update all instances of type(layer) to use gradient checkpointing.
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"""
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fn = type(layer).__call__
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def checkpointed_fn(model, *args, **kwargs):
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def inner_fn(params, *args, **kwargs):
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model.update(params)
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return fn(model, *args, **kwargs)
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return mx.checkpoint(inner_fn)(model.trainable_parameters(), *args, **kwargs)
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type(layer).__call__ = checkpointed_fn
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@dataclass
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class TrainingArgs:
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batch_size: int = field(default=4, metadata={"help": "Minibatch size."})
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iters: int = field(default=100, metadata={"help": "Iterations to train for."})
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val_batches: int = field(
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default=25,
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metadata={
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"help": "Number of validation batches, -1 uses the entire validation set."
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},
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)
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steps_per_report: int = field(
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default=10,
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metadata={"help": "Number of training steps between loss reporting."},
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)
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steps_per_eval: int = field(
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default=200, metadata={"help": "Number of training steps between validations."}
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)
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steps_per_save: int = field(
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default=100, metadata={"help": "Save the model every number steps"}
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)
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max_seq_length: int = field(
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default=2048, metadata={"help": "Maximum sequence length."}
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)
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adapter_file: str = field(
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default="adapters.safetensors",
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metadata={"help": "Save/load path for the trained adapter weights."},
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)
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grad_checkpoint: bool = field(
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default=False,
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metadata={"help": "Use gradient checkpointing to reduce memory use."},
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)
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def default_loss(model, inputs, targets, lengths):
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logits = model(inputs)
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logits = logits.astype(mx.float32)
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length_mask = mx.arange(inputs.shape[1])[None, :] < lengths[:, None]
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ce = nn.losses.cross_entropy(logits, targets) * length_mask
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ntoks = length_mask.sum()
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ce = ce.sum() / ntoks
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return ce, ntoks
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def iterate_batches(dataset, tokenizer, batch_size, max_seq_length, train=False):
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# Sort by length:
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idx = sorted(range(len(dataset)), key=lambda idx: len(dataset[idx]))
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if len(dataset) < batch_size:
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raise ValueError(
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f"Dataset must have at least batch_size={batch_size}"
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f" examples but only has {len(dataset)}."
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)
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# If running in distributed mode (N machines) then each one should skip N-1
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# samples
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step = mx.distributed.init().size()
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if batch_size % step != 0:
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raise ValueError("The batch size must be divisible by the number of workers")
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# Make the batches:
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batch_idx = [
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idx[i : i + batch_size : step]
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for i in range(0, len(idx) - batch_size + 1, batch_size)
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]
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while True:
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indices = np.random.permutation(len(batch_idx))
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for i in indices:
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batch = [dataset[j] for j in batch_idx[i]]
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lengths = [len(x) for x in batch]
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if max(lengths) > max_seq_length:
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print(
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f"[WARNING] Some sequences are longer than {max_seq_length} tokens. "
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f"The longest sentence {max(lengths)} will be truncated to {max_seq_length}. "
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"Consider pre-splitting your data to save memory."
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)
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# Pad to the nearest multiple of 8 or the maximum length
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pad_to = 8
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max_length_in_batch = pad_to * ((max(lengths) + pad_to - 1) // pad_to)
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max_length_in_batch = min(max_length_in_batch, max_seq_length)
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batch_arr = np.zeros((batch_size // step, max_length_in_batch), np.int32)
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for j in range(batch_size // step):
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truncated_length = min(lengths[j], max_seq_length)
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batch_arr[j, :truncated_length] = batch[j][:truncated_length]
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lengths[j] = (
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truncated_length # Update lengths to match truncated lengths
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)
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batch = mx.array(batch_arr)
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yield batch[:, :-1], batch[:, 1:], mx.array(lengths)
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if not train:
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break
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def evaluate(
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model,
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dataset,
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tokenizer,
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batch_size,
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num_batches,
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max_seq_length=2048,
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loss: callable = default_loss,
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iterate_batches: callable = iterate_batches,
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):
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all_losses = mx.array(0.0)
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ntokens = mx.array(0)
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index_iterator = iter(range(num_batches)) if num_batches != -1 else iter(int, 1)
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for _, batch in zip(
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index_iterator,
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iterate_batches(
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dataset=dataset,
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tokenizer=tokenizer,
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batch_size=batch_size,
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max_seq_length=max_seq_length,
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),
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):
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losses, toks = loss(model, *batch)
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all_losses += losses * toks
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ntokens += toks
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mx.eval(all_losses, ntokens)
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all_losses = mx.distributed.all_sum(all_losses, stream=mx.cpu)
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ntokens = mx.distributed.all_sum(ntokens, stream=mx.cpu)
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return (all_losses / ntokens).item()
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class TrainingCallback:
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def on_train_loss_report(self, train_info: dict):
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"""Called to report training loss at specified intervals."""
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pass
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def on_val_loss_report(self, val_info: dict):
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"""Called to report validation loss at specified intervals or the beginning."""
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pass
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def train(
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model,
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tokenizer,
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optimizer,
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train_dataset,
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val_dataset,
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args: TrainingArgs = TrainingArgs(),
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loss: callable = default_loss,
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iterate_batches: callable = iterate_batches,
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training_callback: TrainingCallback = None,
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):
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print(f"Starting training..., iters: {args.iters}")
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world = mx.distributed.init()
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world_size = world.size()
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rank = world.rank()
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if world_size > 1:
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print(f"Node {rank} of {world_size}")
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if args.grad_checkpoint:
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grad_checkpoint(model.layers[0])
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state = [model.state, optimizer.state]
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def step(batch):
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# Forward and backward pass
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(lvalue, toks), grad = loss_value_and_grad(model, *batch)
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# All reduce the gradients if running in distributed mode
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grad = average_gradients(grad)
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# Model update
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optimizer.update(model, grad)
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return lvalue, toks
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loss_value_and_grad = nn.value_and_grad(model, loss)
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losses = 0
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n_tokens = 0
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steps = 0
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trained_tokens = 0
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# Main training loop
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start = time.perf_counter()
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for it, batch in zip(
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range(1, args.iters + 1),
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iterate_batches(
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dataset=train_dataset,
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tokenizer=tokenizer,
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batch_size=args.batch_size,
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max_seq_length=args.max_seq_length,
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train=True,
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),
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):
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# Report validation loss if needed, the first validation loss
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# is always measured before any training.
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if it == 1 or it % args.steps_per_eval == 0 or it == args.iters:
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stop = time.perf_counter()
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val_loss = evaluate(
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model=model,
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dataset=val_dataset,
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loss=loss,
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tokenizer=tokenizer,
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batch_size=args.batch_size,
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num_batches=args.val_batches,
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max_seq_length=args.max_seq_length,
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iterate_batches=iterate_batches,
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)
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val_time = time.perf_counter() - stop
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if rank == 0:
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print(
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f"Iter {it}: "
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f"Val loss {val_loss:.3f}, "
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f"Val took {val_time:.3f}s",
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flush=True,
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)
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if training_callback is not None:
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val_info = {
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"iteration": it,
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"val_loss": val_loss,
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"val_time": val_time,
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}
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training_callback.on_val_loss_report(val_info)
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start = time.perf_counter()
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lvalue, toks = step(batch)
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losses += lvalue
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n_tokens += toks
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steps += 1
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mx.eval(state, losses, n_tokens)
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# Report training loss if needed
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if it % args.steps_per_report == 0 or it == args.iters:
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stop = time.perf_counter()
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train_loss = mx.distributed.all_sum(losses, stream=mx.cpu).item()
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train_loss /= steps * mx.distributed.init().size()
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n_tokens = mx.distributed.all_sum(n_tokens, stream=mx.cpu).item()
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learning_rate = optimizer.learning_rate.item()
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it_sec = args.steps_per_report / (stop - start)
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tokens_sec = float(n_tokens) / (stop - start)
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trained_tokens += n_tokens
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peak_mem = mx.metal.get_peak_memory() / 1e9
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if rank == 0:
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print(
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f"Iter {it}: Train loss {train_loss:.3f}, "
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f"Learning Rate {learning_rate:.3e}, "
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f"It/sec {it_sec:.3f}, "
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f"Tokens/sec {tokens_sec:.3f}, "
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f"Trained Tokens {trained_tokens}, "
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f"Peak mem {peak_mem:.3f} GB",
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flush=True,
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)
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if training_callback is not None:
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train_info = {
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"iteration": it,
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"train_loss": train_loss,
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"learning_rate": learning_rate,
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"iterations_per_second": it_sec,
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"tokens_per_second": tokens_sec,
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"trained_tokens": trained_tokens,
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"peak_memory": peak_mem,
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}
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training_callback.on_train_loss_report(train_info)
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losses = 0
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n_tokens = 0
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steps = 0
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start = time.perf_counter()
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# Save adapter weights
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if it % args.steps_per_save == 0:
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adapter_weights = dict(tree_flatten(model.trainable_parameters()))
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mx.save_safetensors(str(args.adapter_file), adapter_weights)
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checkpoint = (
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Path(args.adapter_file).parent / f"{it:07d}_adapters.safetensors"
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)
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mx.save_safetensors(str(checkpoint), adapter_weights)
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print(
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f"Iter {it}: Saved adapter weights to "
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f"{args.adapter_file} and {checkpoint}."
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)
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# Save final weights
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adapter_weights = dict(tree_flatten(model.trainable_parameters()))
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mx.save_safetensors(str(args.adapter_file), adapter_weights)
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print(f"Saved final weights to {args.adapter_file}.")
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