torch.cuda.amp
provides convenience methods for mixed precision, where some operations use the torch.float32
(float
) datatype and other operations use torch.float16
(half
). Some ops, like linear layers and convolutions, are much faster in float16
. Other ops, like reductions, often require the dynamic range of float32
. Mixed precision tries to match each op to its appropriate datatype.
Ordinarily, “automatic mixed precision training” uses torch.cuda.amp.autocast
and torch.cuda.amp.GradScaler
together, as shown in the Automatic Mixed Precision examples and Automatic Mixed Precision recipe. However, autocast
and GradScaler
are modular, and may be used separately if desired.
class torch.cuda.amp.autocast(enabled=True)
[source]
Instances of autocast
serve as context managers or decorators that allow regions of your script to run in mixed precision.
In these regions, CUDA ops run in an op-specific dtype chosen by autocast to improve performance while maintaining accuracy. See the Autocast Op Reference for details.
When entering an autocast-enabled region, Tensors may be any type. You should not call .half()
on your model(s) or inputs when using autocasting.
autocast
should wrap only the forward pass(es) of your network, including the loss computation(s). Backward passes under autocast are not recommended. Backward ops run in the same type that autocast used for corresponding forward ops.
Example:
# Creates model and optimizer in default precision model = Net().cuda() optimizer = optim.SGD(model.parameters(), ...) for input, target in data: optimizer.zero_grad() # Enables autocasting for the forward pass (model + loss) with autocast(): output = model(input) loss = loss_fn(output, target) # Exits the context manager before backward() loss.backward() optimizer.step()
See the Automatic Mixed Precision examples for usage (along with gradient scaling) in more complex scenarios (e.g., gradient penalty, multiple models/losses, custom autograd functions).
autocast
can also be used as a decorator, e.g., on the forward
method of your model:
class AutocastModel(nn.Module): ... @autocast() def forward(self, input): ...
Floating-point Tensors produced in an autocast-enabled region may be float16
. After returning to an autocast-disabled region, using them with floating-point Tensors of different dtypes may cause type mismatch errors. If so, cast the Tensor(s) produced in the autocast region back to float32
(or other dtype if desired). If a Tensor from the autocast region is already float32
, the cast is a no-op, and incurs no additional overhead. Example:
# Creates some tensors in default dtype (here assumed to be float32) a_float32 = torch.rand((8, 8), device="cuda") b_float32 = torch.rand((8, 8), device="cuda") c_float32 = torch.rand((8, 8), device="cuda") d_float32 = torch.rand((8, 8), device="cuda") with autocast(): # torch.mm is on autocast's list of ops that should run in float16. # Inputs are float32, but the op runs in float16 and produces float16 output. # No manual casts are required. e_float16 = torch.mm(a_float32, b_float32) # Also handles mixed input types f_float16 = torch.mm(d_float32, e_float16) # After exiting autocast, calls f_float16.float() to use with d_float32 g_float32 = torch.mm(d_float32, f_float16.float())
Type mismatch errors in an autocast-enabled region are a bug; if this is what you observe, please file an issue.
autocast(enabled=False)
subregions can be nested in autocast-enabled regions. Locally disabling autocast can be useful, for example, if you want to force a subregion to run in a particular dtype
. Disabling autocast gives you explicit control over the execution type. In the subregion, inputs from the surrounding region should be cast to dtype
before use:
# Creates some tensors in default dtype (here assumed to be float32) a_float32 = torch.rand((8, 8), device="cuda") b_float32 = torch.rand((8, 8), device="cuda") c_float32 = torch.rand((8, 8), device="cuda") d_float32 = torch.rand((8, 8), device="cuda") with autocast(): e_float16 = torch.mm(a_float32, b_float32) with autocast(enabled=False): # Calls e_float16.float() to ensure float32 execution # (necessary because e_float16 was created in an autocasted region) f_float32 = torch.mm(c_float32, e_float16.float()) # No manual casts are required when re-entering the autocast-enabled region. # torch.mm again runs in float16 and produces float16 output, regardless of input types. g_float16 = torch.mm(d_float32, f_float32)
The autocast state is thread-local. If you want it enabled in a new thread, the context manager or decorator must be invoked in that thread. This affects torch.nn.DataParallel
and torch.nn.parallel.DistributedDataParallel
when used with more than one GPU per process (see Working with Multiple GPUs).
enabled (bool, optional, default=True) – Whether autocasting should be enabled in the region.
torch.cuda.amp.custom_fwd(fwd=None, **kwargs)
[source]
Helper decorator for forward
methods of custom autograd functions (subclasses of torch.autograd.Function
). See the example page for more detail.
cast_inputs (torch.dtype
or None, optional, default=None) – If not None
, when forward
runs in an autocast-enabled region, casts incoming floating-point CUDA Tensors to the target dtype (non-floating-point Tensors are not affected), then executes forward
with autocast disabled. If None
, forward
’s internal ops execute with the current autocast state.
Note
If the decorated forward
is called outside an autocast-enabled region, custom_fwd
is a no-op and cast_inputs
has no effect.
torch.cuda.amp.custom_bwd(bwd)
[source]
Helper decorator for backward methods of custom autograd functions (subclasses of torch.autograd.Function
). Ensures that backward
executes with the same autocast state as forward
. See the example page for more detail.
If the forward pass for a particular op has float16
inputs, the backward pass for that op will produce float16
gradients. Gradient values with small magnitudes may not be representable in float16
. These values will flush to zero (“underflow”), so the update for the corresponding parameters will be lost.
To prevent underflow, “gradient scaling” multiplies the network’s loss(es) by a scale factor and invokes a backward pass on the scaled loss(es). Gradients flowing backward through the network are then scaled by the same factor. In other words, gradient values have a larger magnitude, so they don’t flush to zero.
Each parameter’s gradient (.grad
attribute) should be unscaled before the optimizer updates the parameters, so the scale factor does not interfere with the learning rate.
class torch.cuda.amp.GradScaler(init_scale=65536.0, growth_factor=2.0, backoff_factor=0.5, growth_interval=2000, enabled=True)
[source]
get_backoff_factor()
[source]
Returns a Python float containing the scale backoff factor.
get_growth_factor()
[source]
Returns a Python float containing the scale growth factor.
get_growth_interval()
[source]
Returns a Python int containing the growth interval.
get_scale()
[source]
Returns a Python float containing the current scale, or 1.0 if scaling is disabled.
Warning
get_scale()
incurs a CPU-GPU sync.
is_enabled()
[source]
Returns a bool indicating whether this instance is enabled.
load_state_dict(state_dict)
[source]
Loads the scaler state. If this instance is disabled, load_state_dict()
is a no-op.
state_dict (dict) – scaler state. Should be an object returned from a call to state_dict()
.
scale(outputs)
[source]
Multiplies (‘scales’) a tensor or list of tensors by the scale factor.
Returns scaled outputs. If this instance of GradScaler
is not enabled, outputs are returned unmodified.
outputs (Tensor or iterable of Tensors) – Outputs to scale.
set_backoff_factor(new_factor)
[source]
new_scale (float) – Value to use as the new scale backoff factor.
set_growth_factor(new_factor)
[source]
new_scale (float) – Value to use as the new scale growth factor.
set_growth_interval(new_interval)
[source]
new_interval (int) – Value to use as the new growth interval.
state_dict()
[source]
Returns the state of the scaler as a dict
. It contains five entries:
"scale"
- a Python float containing the current scale"growth_factor"
- a Python float containing the current growth factor"backoff_factor"
- a Python float containing the current backoff factor"growth_interval"
- a Python int containing the current growth interval"_growth_tracker"
- a Python int containing the number of recent consecutive unskipped steps.If this instance is not enabled, returns an empty dict.
Note
If you wish to checkpoint the scaler’s state after a particular iteration, state_dict()
should be called after update()
.
step(optimizer, *args, **kwargs)
[source]
step()
carries out the following two operations:
unscale_(optimizer)
(unless unscale_()
was explicitly called for optimizer
earlier in the iteration). As part of the unscale_()
, gradients are checked for infs/NaNs.optimizer.step()
using the unscaled gradients. Otherwise, optimizer.step()
is skipped to avoid corrupting the params.*args
and **kwargs
are forwarded to optimizer.step()
.
Returns the return value of optimizer.step(*args, **kwargs)
.
Warning
Closure use is not currently supported.
unscale_(optimizer)
[source]
Divides (“unscales”) the optimizer’s gradient tensors by the scale factor.
unscale_()
is optional, serving cases where you need to modify or inspect gradients between the backward pass(es) and step()
. If unscale_()
is not called explicitly, gradients will be unscaled automatically during step()
.
Simple example, using unscale_()
to enable clipping of unscaled gradients:
... scaler.scale(loss).backward() scaler.unscale_(optimizer) torch.nn.utils.clip_grad_norm_(model.parameters(), max_norm) scaler.step(optimizer) scaler.update()
optimizer (torch.optim.Optimizer) – Optimizer that owns the gradients to be unscaled.
Note
unscale_()
does not incur a CPU-GPU sync.
Warning
unscale_()
should only be called once per optimizer per step()
call, and only after all gradients for that optimizer’s assigned parameters have been accumulated. Calling unscale_()
twice for a given optimizer between each step()
triggers a RuntimeError.
Warning
unscale_()
may unscale sparse gradients out of place, replacing the .grad
attribute.
update(new_scale=None)
[source]
Updates the scale factor.
If any optimizer steps were skipped the scale is multiplied by backoff_factor
to reduce it. If growth_interval
unskipped iterations occurred consecutively, the scale is multiplied by growth_factor
to increase it.
Passing new_scale
sets the scale directly.
new_scale (float or torch.cuda.FloatTensor
, optional, default=None) – New scale factor.
Warning
update()
should only be called at the end of the iteration, after scaler.step(optimizer)
has been invoked for all optimizers used this iteration.
Only CUDA ops are eligible for autocasting.
Ops that run in float64
or non-floating-point dtypes are not eligible, and will run in these types whether or not autocast is enabled.
Only out-of-place ops and Tensor methods are eligible. In-place variants and calls that explicitly supply an out=...
Tensor are allowed in autocast-enabled regions, but won’t go through autocasting. For example, in an autocast-enabled region a.addmm(b, c)
can autocast, but a.addmm_(b, c)
and a.addmm(b, c, out=d)
cannot. For best performance and stability, prefer out-of-place ops in autocast-enabled regions.
Ops called with an explicit dtype=...
argument are not eligible, and will produce output that respects the dtype
argument.
The following lists describe the behavior of eligible ops in autocast-enabled regions. These ops always go through autocasting whether they are invoked as part of a torch.nn.Module
, as a function, or as a torch.Tensor
method. If functions are exposed in multiple namespaces, they go through autocasting regardless of the namespace.
Ops not listed below do not go through autocasting. They run in the type defined by their inputs. However, autocasting may still change the type in which unlisted ops run if they’re downstream from autocasted ops.
If an op is unlisted, we assume it’s numerically stable in float16
. If you believe an unlisted op is numerically unstable in float16
, please file an issue.
float16
__matmul__
, addbmm
, addmm
, addmv
, addr
, baddbmm
, bmm
, chain_matmul
, conv1d
, conv2d
, conv3d
, conv_transpose1d
, conv_transpose2d
, conv_transpose3d
, GRUCell
, linear
, LSTMCell
, matmul
, mm
, mv
, prelu
, RNNCell
float32
__pow__
, __rdiv__
, __rpow__
, __rtruediv__
, acos
, asin
, binary_cross_entropy_with_logits
, cosh
, cosine_embedding_loss
, cdist
, cosine_similarity
, cross_entropy
, cumprod
, cumsum
, dist
, erfinv
, exp
, expm1
, gelu
, group_norm
, hinge_embedding_loss
, kl_div
, l1_loss
, layer_norm
, log
, log_softmax
, log10
, log1p
, log2
, margin_ranking_loss
, mse_loss
, multilabel_margin_loss
, multi_margin_loss
, nll_loss
, norm
, normalize
, pdist
, poisson_nll_loss
, pow
, prod
, reciprocal
, rsqrt
, sinh
, smooth_l1_loss
, soft_margin_loss
, softmax
, softmin
, softplus
, sum
, renorm
, tan
, triplet_margin_loss
These ops don’t require a particular dtype for stability, but take multiple inputs and require that the inputs’ dtypes match. If all of the inputs are float16
, the op runs in float16
. If any of the inputs is float32
, autocast casts all inputs to float32
and runs the op in float32
.
addcdiv
, addcmul
, atan2
, bilinear
, cat
, cross
, dot
, equal
, index_put
, stack
, tensordot
Some ops not listed here (e.g., binary ops like add
) natively promote inputs without autocasting’s intervention. If inputs are a mixture of float16
and float32
, these ops run in float32
and produce float32
output, regardless of whether autocast is enabled.
binary_cross_entropy_with_logits
over binary_cross_entropy
The backward passes of torch.nn.functional.binary_cross_entropy()
(and torch.nn.BCELoss
, which wraps it) can produce gradients that aren’t representable in float16
. In autocast-enabled regions, the forward input may be float16
, which means the backward gradient must be representable in float16
(autocasting float16
forward inputs to float32
doesn’t help, because that cast must be reversed in backward). Therefore, binary_cross_entropy
and BCELoss
raise an error in autocast-enabled regions.
Many models use a sigmoid layer right before the binary cross entropy layer. In this case, combine the two layers using torch.nn.functional.binary_cross_entropy_with_logits()
or torch.nn.BCEWithLogitsLoss
. binary_cross_entropy_with_logits
and BCEWithLogits
are safe to autocast.
© 2019 Torch Contributors
Licensed under the 3-clause BSD License.
https://pytorch.org/docs/1.7.0/amp.html