mlx/docs/build/html/_sources/python/optimizers.rst

.. _optimizers:

.. currentmodule:: mlx.optimizers

Optimizers
==========

The optimizers in MLX can be used both with :mod:`mlx.nn` but also with pure
:mod:`mlx.core` functions. A typical example involves calling
:meth:`Optimizer.update` to update a model's parameters based on the loss
gradients and subsequently calling :func:`mlx.core.eval` to evaluate both the
model's parameters and the **optimizer state**.

.. code-block:: python

    # Create a model
    model = MLP(num_layers, train_images.shape[-1], hidden_dim, num_classes)
    mx.eval(model.parameters())

    # Create the gradient function and the optimizer
    loss_and_grad_fn = nn.value_and_grad(model, loss_fn)
    optimizer = optim.SGD(learning_rate=learning_rate)

    for e in range(num_epochs):
        for X, y in batch_iterate(batch_size, train_images, train_labels):
            loss, grads = loss_and_grad_fn(model, X, y)

            # Update the model with the gradients. So far no computation has happened.
            optimizer.update(model, grads)

            # Compute the new parameters but also the optimizer state.
            mx.eval(model.parameters(), optimizer.state)

Saving and Loading
------------------

To serialize an optimizer, save its state. To load an optimizer, load and set
the saved state. Here's a simple example:

.. code-block:: python

   import mlx.core as mx
   from mlx.utils import tree_flatten, tree_unflatten
   import mlx.optimizers as optim

   optimizer = optim.Adam(learning_rate=1e-2)

   # Perform some updates with the optimizer
   model = {"w" : mx.zeros((5, 5))}
   grads = {"w" : mx.ones((5, 5))}
   optimizer.update(model, grads)

   # Save the state
   state = tree_flatten(optimizer.state)
   mx.save_safetensors("optimizer.safetensors", dict(state))

   # Later on, for example when loading from a checkpoint,
   # recreate the optimizer and load the state
   optimizer = optim.Adam(learning_rate=1e-2)

   state = tree_unflatten(list(mx.load("optimizer.safetensors").items()))
   optimizer.state = state

Note, not every optimizer configuation parameter is saved in the state. For
example, for Adam the learning rate is saved but the ``betas`` and ``eps``
parameters are not. A good rule of thumb is if the parameter can be scheduled
then it will be included in the optimizer state.

.. toctree::

   optimizers/optimizer
   optimizers/common_optimizers
   optimizers/schedulers

.. autosummary::
   :toctree: _autosummary

   clip_grad_norm
docs 2023-11-30 04:41:56 +08:00			`.. _optimizers:`

docs update 2024-05-10 23:49:36 +08:00			`.. currentmodule:: mlx.optimizers`

docs 2023-11-30 04:41:56 +08:00			`Optimizers`
			`==========`

			The optimizers in MLX can be used both with :mod:`mlx.nn` but also with pure
			:mod:`mlx.core` functions. A typical example involves calling
			:meth:`Optimizer.update` to update a model's parameters based on the loss
			gradients and subsequently calling :func:`mlx.core.eval` to evaluate both the
			`model's parameters and the optimizer state.`

			`.. code-block:: python`

			`# Create a model`
			`model = MLP(num_layers, train_images.shape[-1], hidden_dim, num_classes)`
			`mx.eval(model.parameters())`

			`# Create the gradient function and the optimizer`
			`loss_and_grad_fn = nn.value_and_grad(model, loss_fn)`
			`optimizer = optim.SGD(learning_rate=learning_rate)`

			`for e in range(num_epochs):`
			`for X, y in batch_iterate(batch_size, train_images, train_labels):`
			`loss, grads = loss_and_grad_fn(model, X, y)`

			`# Update the model with the gradients. So far no computation has happened.`
			`optimizer.update(model, grads)`

			`# Compute the new parameters but also the optimizer state.`
			`mx.eval(model.parameters(), optimizer.state)`

docs update 2024-07-26 02:59:11 +08:00			`Saving and Loading`
			`------------------`

			`To serialize an optimizer, save its state. To load an optimizer, load and set`
			`the saved state. Here's a simple example:`

			`.. code-block:: python`

			`import mlx.core as mx`
			`from mlx.utils import tree_flatten, tree_unflatten`
			`import mlx.optimizers as optim`

			`optimizer = optim.Adam(learning_rate=1e-2)`

			`# Perform some updates with the optimizer`
			`model = {"w" : mx.zeros((5, 5))}`
			`grads = {"w" : mx.ones((5, 5))}`
			`optimizer.update(model, grads)`

			`# Save the state`
			`state = tree_flatten(optimizer.state)`
			`mx.save_safetensors("optimizer.safetensors", dict(state))`

			`# Later on, for example when loading from a checkpoint,`
			`# recreate the optimizer and load the state`
			`optimizer = optim.Adam(learning_rate=1e-2)`

			`state = tree_unflatten(list(mx.load("optimizer.safetensors").items()))`
			`optimizer.state = state`

			`Note, not every optimizer configuation parameter is saved in the state. For`
			example, for Adam the learning rate is saved but the ``betas`` and ``eps``
			`parameters are not. A good rule of thumb is if the parameter can be scheduled`
			`then it will be included in the optimizer state.`

docs update 2024-02-09 04:44:23 +08:00			`.. toctree::`

docs update 2024-02-18 05:25:37 +08:00			`optimizers/optimizer`
			`optimizers/common_optimizers`
			`optimizers/schedulers`
docs update 2024-05-10 23:49:36 +08:00
			`.. autosummary::`
			`:toctree: _autosummary`

			`clip_grad_norm`