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autograd_meta.cpp
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autograd_meta.cpp
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#define TORCH_ASSERT_ONLY_METHOD_OPERATORS
#include <c10/util/irange.h>
#include <torch/csrc/autograd/variable.h>
#ifndef AT_PER_OPERATOR_HEADERS
#include <ATen/Functions.h>
#else
#include <ATen/ops/_has_same_storage_numel.h>
#include <ATen/ops/_new_zeros_with_same_feature_meta.h>
#include <ATen/ops/zeros.h>
#endif
namespace torch {
namespace autograd {
using at::Tensor;
// [Forward Grad View/inplace]
// It is important to us to allow view and inplace to work with dual Tensors.
// These operations should either compute the right gradient or raise a
// user-friendly error.
// The basic case where all Tensors are dual Tensors is as follows:
// # Have:
// # foo is a dual Tensor that is not a view
// # bar is a dual Tensor of appropriate size (depending on cases) that is
// not a view
//
// # Case 1: no view
// foo.copy_(bar)
//
// # Case 2: with view, propagate from view to base
// view = foo[0]
// view.copy_(bar)
//
// # Case 3: with view, propagate from base to view
// view = foo[0]
// foo.copy_(bar)
//
// # In both cases, the forward grad of foo must be properly updated.
// # In the second and third cases, the forward grad of view must match
// # the one of foo for the subset they have in common.
//
// All these cases can be handled by the following layout constraint on the
// forward grad:
// - A Tensor and its forward grad (for all levels) must have the same
// metadata (size, stride
// conj/neg bit and storage offset). Storage offset must be in this metadata
// because of as_strided. conj/neg bit must be part of this metadata because
// of ops like `real`.
// - View operations must create a forward grad that is a view of the base's
// forward grad.
// - Inplace operations must modify the input's forward grad inplace.
//
// This layout constraint is ensured in the `set_fw_grad` function below
// More complex cases arrise when non-dual Tensor interact with dual Tensors.
// The two most important cases are:
//
// # Have:
// # foo is a regular Tensor that is not a view
// # bar is a dual Tensor of appropriate size (depending on cases) that is
// not a view
//
// # Case 4: Changes on the view must propagate to its base
// view = foo[0]
// # view is still a regular Tensor here
// view.copy_(bar)
// # Now both view and foo are dual Tensor with appropriate forward grad
//
// # Case 5: Changes on the base must propagate on all its views
// view = foo[0]
// # view is still a regular Tensor here
// base.copy_(bar)
// # Now both view and foo are dual Tensor with appropriate forward grad
//
// # NB there is a case 6 involving changes on a view propagating to other
// views # but it is fully described by the two others and is skipped in
// this discussion.
//
// Case 4 is handled by set_fw_grad by properly setting the forward grad of the
// base if needed. Case 5 is handled in fw_grad by reading the forward grad from
// the base if needed.
namespace utils {
// Enforcing that the metadata between the primal and tangent are same has two
// goals:
// - When properties of the primal are checked in composite op's to determine
// control flow, the code path decided upon is also reasonable for the tangent
// - Make sure that when the same as_strided is applied to both primal and
// and tangent, it behaves similarly.
//
// We do that by checking:
// 1) the storages have same properties: size and conj/neg-ness
// 2) the same indices refer to the same elements in storage
// (we are more strict than necessary here to satisfy the goal 1)
bool has_same_meta(const Variable& base, const Variable& other) {
if (!base.defined() || !other.defined()) {
return false;
}
// 1) The storages have the same properties
if (!at::_has_same_storage_numel(base, other)) {
return false;
}
if (base.is_conj() != other.is_conj() || base.is_neg() != other.is_neg()) {
return false;
}
// Technically dim and size belong as part of (2), so we shouldn't really care
// if a zero-numel tensor violates these. But since these properties
// (unlike offset and strides) often determine control flow in composite ops
// it is useful to enforce that they match for primal and tangent here so
// nothing funny happens later (See goal 1).
if (base.dim() != other.dim()) {
return false;
}
for (const auto i : c10::irange(base.dim())) {
if (base.sizes()[i] != other.sizes()[i]) {
return false;
}
}
// The check below will always be vacuously true for 0-element tensors
if (base.numel() == 0 && other.numel() == 0) {
return true;
}
// 2) The same indices refer to the same elements in storage
if (base.storage_offset() != other.storage_offset()) {
return false;
}
for (const auto i : c10::irange(base.dim())) {
if (base.strides()[i] != other.strides()[i] && base.sizes()[i] != 1 &&
base.sizes()[i] != 0) {
return false;
}
}
return true;
}
} // namespace utils
// This function is will ensure that the fw_grad_ is properly a view of the base
// for inplace ops on Tensors that do not have forward grad originally.
void AutogradMeta::set_fw_grad(
const at::TensorBase& new_grad_base,
const at::TensorBase& self_base,
uint64_t level,
bool is_inplace_op) {
TORCH_CHECK(
!new_grad_base._fw_grad(level).defined(),
"Setting a forward grad that "
"itself has a forward gradient at the same level",
level,
" is not supported.");
TORCH_INTERNAL_ASSERT(
(new_grad_base.is_floating_point() || new_grad_base.is_complex()) &&
(self_base.is_floating_point() || self_base.is_complex()),
"Expected both tensor and its forward grad to be floating point or complex");
// Lazy initialization
{
std::lock_guard<std::mutex> lock(mutex_);
if (!fw_grad_) {
fw_grad_ = std::make_shared<ForwardGrad>();
}
}
if (fw_grad_->contains(level)) {
// Setting the forward grad again is only allowed if it is a no-op.
// We do allow this case to simplify writing codegen for inplace ops.
TORCH_INTERNAL_ASSERT(
new_grad_base.defined(),
"Cannot set a forward grad that is an undefined Tensor. Use "
"_fw_primal(level) to get a new Tensor with this forward grad unset.");
TORCH_INTERNAL_ASSERT(
is_inplace_op,
"Only inplace operations can re-set the forward grad of a Tensor that "
"already has one.");
TORCH_INTERNAL_ASSERT(
fw_grad_->value(level).is_same(new_grad_base),
"Cannot set a value of a forward grad if it "
"already exists. Inplace operations should modify it inplace.");
} else {
// TODO(alband) remove this spurious version counter bump
Tensor new_grad(new_grad_base);
at::OptionalTensorRef self_ref(self_base);
const Tensor& self = *self_ref;
TORCH_CHECK(
self.is_same_size(new_grad),
"Trying to set a forward gradient that has a different size than that "
"of the original Tensor, this is not supported. Tensor is of size ",
self.sizes(),
" while the given "
"forward gradient is of size ",
new_grad.sizes(),
".");
if (is_inplace_op && is_view_) {
auto this_view_meta = static_cast<DifferentiableViewMeta*>(this);
// For inplace ops on a Tensor that does not already have a forward grad
// and is a view, we propagate the tangent to the base and ensure that the
// new_grad is a view of that base's tangent. This ensure that case 4 from
// [Forward Grad View/inplace] above works fine What happens in this long
// if statement is:
// - Check if the base already has a grad
// - If not, set a new fw_grad for it full of zeros
// - Take a view of the base's forward grad
// - Copy the given new_grad into this view
// - Use this view as the new new_grad
if (this_view_meta->has_fw_view()) {
auto& view_info = this_view_meta->get_forward_view();
auto& base = view_info.base_;
if (!base._fw_grad(level).defined()) {
// Enforce same meta here to make sure that the view op below is
// always valid
Tensor new_base_fw_grad;
if (utils::has_same_meta(new_grad, base) &&
utils::has_same_meta(new_grad, self)) {
// TODO extend this special case to when the underlying storage of
// new_grad can be re-used.
new_base_fw_grad = new_grad;
} else {
new_base_fw_grad =
at::_new_zeros_with_same_feature_meta(new_grad, base);
new_base_fw_grad._set_conj(base.is_conj());
new_base_fw_grad._set_neg(base.is_neg());
// Update new_grad to be a view of the base
Tensor new_fw_grad_value;
if (view_info.has_view_fn()) {
new_fw_grad_value = view_info.view_fn()(new_base_fw_grad);
} else {
new_fw_grad_value = new_base_fw_grad.as_strided(
self.sizes(), self.strides(), self.storage_offset());
}
new_fw_grad_value.copy_(new_grad);
new_grad = new_fw_grad_value;
}
base._set_fw_grad(new_base_fw_grad, level, /* is_inplace_op */ false);
}
}
}
// Enforce the basic layout constraint
if (!utils::has_same_meta(new_grad, self)) {
if (is_view_) {
auto this_view_meta = static_cast<DifferentiableViewMeta*>(this);
TORCH_INTERNAL_ASSERT(
!this_view_meta->has_fw_view(),
"Expected the output of forward differentiable view operations to have the tangent have the same layout as primal")
}
auto res = at::_new_zeros_with_same_feature_meta(new_grad, self);
res._set_conj(self.is_conj());
res._set_neg(self.is_neg());
res.copy_(new_grad);
new_grad = res;
}
fw_grad_->set_value(new_grad, level);
}
}
const Variable& AutogradMeta::fw_grad(
uint64_t level,
const at::TensorBase& self) const {
// TLS that disables forward AD.
if (!c10::AutogradState::get_tls_state().get_fw_grad_mode()) {
return ForwardGrad::undef_grad();
}
// Ensure that concurrent fw_grad() "reads" are thread safe
std::lock_guard<std::mutex> lock(mutex_);
const auto& direct_fw_grad =
fw_grad_ ? fw_grad_->value(level) : ForwardGrad::undef_grad();
if (!direct_fw_grad.defined() && is_view_) {
// For view that don't have a forward grad, check if their base has one that
// has been defined by an inplace operation.
// This ensure that case 5 from [Forward Grad View/inplace] above works fine
auto const_view_meta =
static_cast<const torch::autograd::DifferentiableViewMeta*>(this);
// This is ok to do as we ONLY modify fw_grad_ and this field is properly
// locked in all methods
if (const_view_meta->has_fw_view()) {
const auto& view_info = const_view_meta->get_forward_view();
const auto& base = view_info.base_;
const auto& base_val = base._fw_grad(level);
if (base_val.defined()) {
// Lazy initialization of fw_grad_
const_view_meta->fw_grad_ = std::make_shared<ForwardGrad>();
Variable new_val;
if (view_info.has_view_fn()) {
new_val = view_info.view_fn()(base_val);
} else {
new_val = base_val.as_strided(
self.sizes(), self.strides(), self.storage_offset());
}
const_view_meta->fw_grad_->set_value(new_val, level);
return const_view_meta->fw_grad_->value(level);
}
}
}
return direct_fw_grad;
}
} // namespace autograd
} // namespace torch