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TensorBase.h
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TensorBase.h
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#pragma once
#include <c10/core/Device.h>
#include <c10/core/Layout.h>
#include <c10/core/MemoryFormat.h>
#include <c10/core/ScalarType.h>
#include <c10/core/ScalarTypeToTypeMeta.h>
#include <c10/core/Storage.h>
#include <c10/core/SymIntArrayRef.h>
#include <c10/core/TensorImpl.h>
#include <c10/core/TensorOptions.h>
#include <c10/core/UndefinedTensorImpl.h>
#include <c10/core/WrapDimMinimal.h>
#include <c10/util/Exception.h>
#include <c10/util/ExclusivelyOwned.h>
#include <c10/util/ExclusivelyOwnedTensorTraits.h>
#include <c10/util/MaybeOwned.h>
#include <c10/util/Optional.h>
#include <c10/util/intrusive_ptr.h>
#include <ATen/core/NamedTensor.h>
#include <ATen/core/QuantizerBase.h>
#include <ATen/core/TensorAccessor.h>
#include <ATen/StorageUtils.h>
namespace c10 {
class Scalar;
}
namespace torch { namespace autograd {
struct Node;
}} // namespace torch::autograd
namespace at {
class Tensor;
class TensorBase;
// Convert Tensor to TensorBase without any need to include Tensor.h
TORCH_API const TensorBase& get_tensor_base(const Tensor& t);
namespace impl {
inline bool variable_excluded_from_dispatch() {
#ifdef C10_MOBILE
// Please read the comment in `VariableFallbackKernel.cpp` about the background of this change.
return true;
#else
return c10::impl::tls_local_dispatch_key_set().excluded_.isSupersetOf(c10::autograd_dispatch_keyset);
#endif
}
}
// NOTE: [Tensor vs. TensorBase]
//
// Tensor, being the central data structure in PyTorch, gets used and
// it's header included almost everywhere. Unfortunately this means
// every time an operator signature is updated or changed in
// native_functions.yaml, you (and every other PyTorch developer) need
// to recompile all of ATen and it's dependencies.
//
// TensorBase aims to break up these header dependencies, and improve
// incremental build times for all PyTorch developers. TensorBase
// represents a reference counted handle to TensorImpl, exactly the
// same as Tensor. However, TensorBase doesn't have code generated
// methods in it's API and thus no dependence on native_functions.yaml.
//
// Usage tips
// ----------
// - You can `#define TORCH_ASSERT_NO_OPERATORS` at the top of a .cpp
// or .cu file to ensure it has no header dependencies on
// native_functions.yaml (direct or indirect).
// - Tensor inherits from TensorBase, so functions taking
// `const TensorBase &` are callable with Tensor as well.
// - TensorBase can be converted to tensor with `Tensor(tensor_base)`,
// but this requires a reference-count bump. OptionalTensorRef on
// the other hand can materialize a `const Tensor &` without
// touching the reference-count.
class TORCH_API TensorBase {
public:
struct unsafe_borrow_t { explicit unsafe_borrow_t() = default; };
protected:
// Create a Tensor with a +0 reference count. Special care must be
// taken to avoid decrementing this reference count at destruction
// time. Intended to support MaybeOwnedTraits<Tensor>.
explicit TensorBase(unsafe_borrow_t, const TensorBase& rhs)
: impl_(c10::intrusive_ptr<at::TensorImpl, UndefinedTensorImpl>::reclaim(rhs.impl_.get())) {}
friend MaybeOwnedTraits<TensorBase>;
public:
TensorBase() = default;
// This constructor should not be used by end users and is an implementation
// detail invoked by autogenerated code.
explicit TensorBase(
c10::intrusive_ptr<TensorImpl, UndefinedTensorImpl> tensor_impl)
: impl_(std::move(tensor_impl)) {
if (impl_.get() == nullptr) {
throw std::runtime_error("TensorImpl with nullptr is not supported");
}
}
TensorBase(const TensorBase&) = default;
TensorBase(TensorBase&&) noexcept = default;
public:
// Creates a new wrapper from TensorImpl. Intentionally a free method because
// it should be used with care. Checks necessary invariants
static TensorBase wrap_tensor_impl(
c10::intrusive_ptr<TensorImpl, UndefinedTensorImpl> tensor_impl) {
TensorBase r(std::move(tensor_impl));
r.enforce_invariants();
return r;
}
int64_t dim() const {
return impl_->dim();
}
int64_t storage_offset() const {
return impl_->storage_offset();
}
TensorBase contiguous(MemoryFormat memory_format=MemoryFormat::Contiguous) const {
if (is_contiguous(memory_format)) {
return *this;
} else {
return __dispatch_contiguous(memory_format);
}
}
/// Should be used if *this can reasonably be expected to be contiguous and
/// performance is important.
/// Compared to contiguous, it saves a reference count
/// increment/decrement if *this is already contiguous, at the cost
/// in all cases of an extra pointer of stack usage, an extra branch
/// to access, and an extra branch at destruction time.
c10::MaybeOwned<TensorBase> expect_contiguous(
MemoryFormat memory_format=MemoryFormat::Contiguous) const &;
// Use .contiguous() instead. Trying to borrow from a prvalue
// will only lead to trouble and dangling references.
c10::MaybeOwned<TensorBase> expect_contiguous(
MemoryFormat memory_format=MemoryFormat::Contiguous) && = delete;
const TensorBase& fill_(const c10::Scalar& scalar) const;
const TensorBase& zero_() const;
TensorBase to(at::TensorOptions options={}, bool non_blocking=false, bool copy=false, c10::optional<at::MemoryFormat> memory_format=c10::nullopt) const;
bool is_complex() const {
return at::isComplexType(this->scalar_type());
}
bool is_floating_point() const {
return at::isFloatingType(this->scalar_type());
}
bool is_signed() const {
return at::isSignedType(this->scalar_type());
}
c10::SymInt sym_size(int64_t dim) const {
return impl_->sym_size(dim);
}
c10::SymInt sym_stride(int64_t dim) const {
const auto sizes = this->sym_strides();
const auto ndim = static_cast<int64_t>(sizes.size());
// false is passed to maybe_wrap_dim so behavior is identical to array access (but with wrapping)
return sizes[c10::maybe_wrap_dim(dim, ndim, /*wrap_scalar=*/false)];
}
int64_t size(int64_t dim) const {
return impl_->size(dim);
}
int64_t stride(int64_t dim) const {
const auto strides = this->strides();
const auto ndim = static_cast<int64_t>(strides.size());
// false is passed to maybe_wrap_dim so behavior is identical to array access (but with wrapping)
return strides[c10::maybe_wrap_dim(dim, ndim, /*wrap_scalar=*/false)];
}
TensorImpl * unsafeGetTensorImpl() const {
return impl_.get();
}
TensorImpl * unsafeReleaseTensorImpl() {
return impl_.release();
}
const c10::intrusive_ptr<TensorImpl, UndefinedTensorImpl>& getIntrusivePtr() const {
return impl_;
}
c10::intrusive_ptr<TensorImpl, UndefinedTensorImpl> unsafeReleaseIntrusivePtr() {
return std::move(impl_);
}
bool defined() const {
return impl_;
}
void reset() {
impl_.reset();
}
#if defined (_MSC_VER)
TensorBase& operator=(const TensorBase& x) & {
impl_ = x.impl_;
return *this;
};
TensorBase& operator=(TensorBase&& x) & noexcept {
impl_ = std::move(x.impl_);
return *this;
}
#else
TensorBase& operator=(const TensorBase& x) & = default;
TensorBase& operator=(TensorBase&& x) & noexcept = default;
#endif
// Ban assignment to rvalues, since at::Tensor (weirdly) performs a deep copy here
TensorBase& operator=(const TensorBase&) && = delete;
TensorBase& operator=(TensorBase&&) && noexcept = delete;
bool is_same(const TensorBase& other) const noexcept {
return impl_ == other.impl_;
}
size_t use_count() const noexcept {
return impl_.use_count();
}
size_t weak_use_count() const noexcept {
return impl_.weak_use_count();
}
std::string toString() const;
IntArrayRef sizes() const {
return impl_->sizes();
}
c10::SymIntArrayRef sym_sizes() const {
return impl_->sym_sizes();
}
c10::SymIntArrayRef sym_strides() const {
return impl_->sym_strides();
}
IntArrayRef strides() const {
return impl_->strides();
}
// See impl::get_opt_names in ATen/NamedTensor.h for docs.
c10::optional<DimnameList> opt_names() const {
return impl::get_opt_names(unsafeGetTensorImpl());
}
// See impl::get_names in ATen/NamedTensor.h for docs.
DimnameList names() const {
return impl::get_names(unsafeGetTensorImpl());
}
int64_t ndimension() const {
return dim();
}
bool is_contiguous(at::MemoryFormat memory_format=at::MemoryFormat::Contiguous) const {
return impl_->is_contiguous(memory_format);
}
bool is_non_overlapping_and_dense() const {
return impl_->is_non_overlapping_and_dense();
}
at::MemoryFormat suggest_memory_format(
bool channels_last_strides_exact_match = false) const {
// Setting channels_last_strides_exact_match to true forces function to
// check 0,1 - sized dimension strides.
if (layout() == at::kStrided) {
if (impl_->is_strides_like_channels_last()) {
if (!channels_last_strides_exact_match ||
get_channels_last_strides_2d(sizes()) == strides()) {
return at::MemoryFormat::ChannelsLast;
}
}
else if (impl_->is_strides_like_channels_last_3d()) {
if (!channels_last_strides_exact_match ||
get_channels_last_strides_3d(sizes()) == strides()) {
return at::MemoryFormat::ChannelsLast3d;
}
}
}
return at::MemoryFormat::Contiguous;
}
// Total bytes consumed by the "view" of elements of the array. Does not
// include size of metadata. The number reported here does not necessarily
// correspond to the true physical memory consumed by a tensor; instead,
// it reports the memory the tensor would take *if* it were contiguous.
// Defined to be numel() * itemsize()
size_t nbytes() const {
TORCH_CHECK(layout () != at::kSparse,
"nbytes is not defined for sparse tensors. If you want the size of the constituent " \
"tensors, add the nbytes of the indices and values. If you want the size of the " \
"equivalent dense tensor, multiply numel() by element_size()");
return impl_->numel() * impl_->itemsize();
}
c10::SymInt sym_nbytes() const {
TORCH_CHECK(layout () != at::kSparse,
"nbytes is not defined for sparse tensors. If you want the size of the constituent " \
"tensors, add the nbytes of the indices and values. If you want the size of the " \
"equivalent dense tensor, multiply numel() by element_size()");
return impl_->sym_numel() * impl_->itemsize();
}
int64_t numel() const {
return impl_->numel();
}
c10::SymInt sym_numel() const {
return impl_->sym_numel();
}
c10::SymInt sym_storage_offset() const {
return impl_->sym_storage_offset();
}
// Length of one array element in bytes. This is the traditional
// Numpy naming.
size_t itemsize() const {
return impl_->itemsize();
}
// Same as itemsize(). This is the PyTorch naming.
int64_t element_size() const {
return static_cast<int64_t>(impl_->itemsize());
}
DispatchKeySet key_set() const {
return impl_->key_set();
}
ScalarType scalar_type() const {
return typeMetaToScalarType(impl_->dtype());
}
bool has_storage() const {
return defined() && impl_->has_storage();
}
const Storage& storage() const {
return impl_->storage();
}
bool is_alias_of(const at::TensorBase& other) const{
return impl_->storage().is_alias_of(other.storage());
}
// Move the storage backend to shm based
// to enable memory sharing across processes.
//
// NB1: the ideal behavior of this API still requires further discussion
// but for now we are inclined to keep it consistent with existing THP behavior
// https://github.com/pytorch/pytorch/blob/4dca9bde0552afc67b5b74f4a0696fe6055709c4/torch/storage.py#L196-L212
// so we don't assert on anything here and rely on caller knowing
// what it's doing.
//
// NB2: this currently provides Linux fd based shm support only
// to simplify the storage lifetime management logic in ATen
// and similarly for now we are not adding support for file system based
// shm support like in THP due to additional GC manager support needed
// to prevent leaks.
// As such, calling this from non supported systems (e.g. Windows) would fail.
void share_memory_() {
at::share_memory_(*this);
}
inline bool _is_zerotensor() const {
return impl_->_is_zerotensor();
}
inline void _set_zero(bool zero) const {
impl_->_set_zero(zero);
}
inline bool is_conj() const {
return impl_->is_conj();
}
// sets the conjugate bit of a tensor.
// NOTE: Conjugate bit is supposed to be a read-only field. Only change this, if you are sure
// that's what you want. Changing this might lead to incorrect behavior since conjugation is
// a lazy operation and we rely on this bit to determine if a conjugation needs to be materialized.
inline void _set_conj(bool conjugate) const {
impl_->_set_conj(conjugate);
}
inline bool is_neg() const {
return impl_->is_neg();
}
// sets the negative bit of a tensor.
// NOTE: Negative bit is supposed to be a read-only field. Only change this, if you are sure
// that's what you want. Changing this might lead to incorrect behavior since we rely on this
// bit to determine if a negation needs to be materialized.
inline void _set_neg(bool negative) const {
impl_->_set_neg(negative);
}
/// Returns a `Tensor`'s layout.
Layout layout() const {
return impl_->layout();
}
/// Returns a `Tensor`'s dtype (`TypeMeta`).
caffe2::TypeMeta dtype() const {
return impl_->dtype();
}
/// Returns a `Tensor`'s device.
inline Device device() const {
return impl_->device();
}
/// Returns a `Tensor`'s device index.
int64_t get_device() const {
// NB: this is not a native function to avoid dispatching overhead.
return impl_->get_device();
}
/// Returns if a `Tensor` has CPU backend.
bool is_cpu() const {
// NB: this is not a native function to avoid dispatching overhead.
return impl_->is_cpu();
}
/// Returns if a `Tensor` has CUDA backend.
bool is_cuda() const {
// NB: this is not a native function to avoid dispatching overhead.
return impl_->is_cuda();
}
/// Returns if a `Tensor` has IPU backend.
bool is_ipu() const {
// NB: this is not a native function to avoid dispatching overhead.
return impl_->is_ipu();
}
/// Returns if a `Tensor` has XPU backend.
bool is_xpu() const {
// NB: this is not a native function to avoid dispatching overhead.
return impl_->is_xpu();
}
/// Returns if a `Tensor` has XLA backend.
bool is_xla() const {
return impl_->is_xla();
}
/// Returns if a `Tensor` has MTIA backend.
bool is_mtia() const {
return impl_->is_mtia();
}
/// Returns if a `Tensor` has HPU backend.
bool is_hpu() const {
return impl_->is_hpu();
}
/// Returns if a `Tensor` has Lazy backend.
bool is_lazy() const {
return impl_->is_lazy();
}
/// Returns if a `Tensor` has HIP backend.
bool is_hip() const {
// NB: this is not a native function to avoid dispatching overhead.
return impl_->is_hip();
}
/// Returns if a `Tensor` has VE backend.
bool is_ve() const {
// NB: this is not a native function to avoid dispatching overhead.
return impl_->is_ve();
}
/// Returns if a `Tensor` has sparse backend.
bool is_sparse() const {
// NB: this is not a native function to avoid dispatching overhead.
return impl_->is_sparse();
}
/// Returns is a `Tensor` has a sparse CSR backend.
bool is_sparse_csr() const {
// NB: this is not a native function to avoid dispatching overhead.
return impl_->is_sparse_csr();
}
/// Returns if a `Tensor` is mkldnn tensor.
bool is_mkldnn() const {
// NB: this is not a native function to avoid dispatching overhead.
return impl_->is_mkldnn();
}
/// Returns if a `Tensor` is mps tensor.
bool is_mps() const {
// NB: this is not a native function to avoid dispatching overhead.
return impl_->is_mps();
}
/// Returns if a `Tensor` is ort tensor.
bool is_ort() const {
// NB: this is not a native function to avoid dispatching overhead.
return impl_->is_ort();
}
/// Returns if a `Tensor` is vulkan tensor.
bool is_vulkan() const {
// NB: this is not a native function to avoid dispatching overhead.
return impl_->is_vulkan();
}
/// Returns if a `Tensor` is metal tensor.
bool is_metal() const {
// NB: this is not a native function to avoid dispatching overhead.
return impl_->is_metal();
}
/// Returns if a `Tensor` has quantized backend.
bool is_quantized() const {
// NB: this is not a native function to avoid dispatching overhead.
return impl_->is_quantized();
}
/// Returns if a `Tensor` is a meta tensor. Meta tensors can
/// also have other designations.
bool is_meta() const {
return impl_->is_meta();
}
/// Returns if a `Tensor` is an inference tensor.
bool is_inference() const {
return impl_->is_inference();
}
// Returns if a `Tensor` is a NestedTensor.
bool is_nested() const {
return impl_->is_nested();
}
/// If a tensor is a quantized tensor, returns its quantizer
/// TODO: it's not in native_functions.yaml yet as it's not exposed to python
QuantizerPtr quantizer() const;
/// Returns if a `Tensor` has any dimension names
bool has_names() const {
// If a user is using unnamed tensors, then we can short-circuit right here.
// Otherwise, impl::has_names attempts to retrieve names.
if (!impl_->has_named_tensor_meta()) {
return false;
}
return impl::has_names(unsafeGetTensorImpl());
}
/// Returns a `Tensor`'s dimension names data structure
const NamedTensorMeta* get_named_tensor_meta() const {
return static_cast<NamedTensorMeta*>(impl_->named_tensor_meta());
}
NamedTensorMeta* get_named_tensor_meta() {
return static_cast<NamedTensorMeta*>(impl_->named_tensor_meta());
}
/// Returns the `TensorOptions` corresponding to this `Tensor`. Defined in
/// TensorOptions.h.
TensorOptions options() const {
return TensorOptions().dtype(dtype())
.device(device())
.layout(layout());
}
const void* const_data_ptr() const {
return this->unsafeGetTensorImpl()->data();
}
void* mutable_data_ptr() const {
return this->unsafeGetTensorImpl()->mutable_data();
}
// TODO(#97856) Make this return a const pointer. This currently
// returns a non-const pointer because of the large
// number of clients that we still want to audit before
// migrating to mutable_data_ptr().
void* data_ptr() const {
return mutable_data_ptr();
}
template <typename T>
const T* const_data_ptr() const;
template <typename T>
T* mutable_data_ptr() const;
// Legacy interface during the migration to indicate that a callsite
// has not been audited for mutability.
//
// Do not add new uses of this, use const_data_ptr() if possible,
// mutable_data_ptr() otherwise.
//
// TODO(#97856) Make this return a const pointer. This is currently
// const because of the vast number of clients that
// rely on this.
template <typename T>
T* data_ptr() const;
// Purposely not defined here to avoid inlining
void print() const;
// Return a `TensorAccessor` for CPU `Tensor`s. You have to specify scalar type and
// dimension.
template<typename T, size_t N>
TensorAccessor<T,N> accessor() const& {
static_assert(N > 0, "accessor is used for indexing tensor, for scalars use *data_ptr<T>()");
TORCH_CHECK(dim() == N, "TensorAccessor expected ", N, " dims but tensor has ", dim());
return TensorAccessor<T,N>(data_ptr<T>(),sizes().data(),strides().data());
}
template<typename T, size_t N>
TensorAccessor<T,N> accessor() && = delete;
// Return a `GenericPackedTensorAccessor` for CUDA `Tensor`s. You have to specify scalar type and
// dimension. You can optionally specify RestrictPtrTraits as a template parameter to
// cast the data pointer to a __restrict__ pointer.
// In order to use this, your CUDA kernel has to take a corresponding GenericPackedTensorAccessor
// as an argument.
template<typename T, size_t N, template <typename U> class PtrTraits = DefaultPtrTraits, typename index_t = int64_t>
GenericPackedTensorAccessor<T,N,PtrTraits,index_t> generic_packed_accessor() const& {
static_assert(N > 0, "accessor is used for indexing tensor, for scalars use *data_ptr<T>()");
TORCH_CHECK(dim() == N, "TensorAccessor expected ", N, " dims but tensor has ", dim());
return GenericPackedTensorAccessor<T,N,PtrTraits,index_t>(static_cast<typename PtrTraits<T>::PtrType>(data_ptr<T>()),sizes().data(),strides().data());
}
template<typename T, size_t N, template <typename U> class PtrTraits = DefaultPtrTraits, typename index_t = int64_t>
GenericPackedTensorAccessor<T,N> generic_packed_accessor() && = delete;
template<typename T, size_t N, template <typename U> class PtrTraits = DefaultPtrTraits>
PackedTensorAccessor32<T,N,PtrTraits> packed_accessor32() const& {
TORCH_CHECK(
impl_->numel() <=
static_cast<int64_t>(std::numeric_limits<int32_t>::max()),
"numel needs to be smaller than int32_t max; otherwise, please use packed_accessor64");
return generic_packed_accessor<T,N,PtrTraits,int32_t>();
}
template<typename T, size_t N, template <typename U> class PtrTraits = DefaultPtrTraits>
PackedTensorAccessor32<T,N,PtrTraits> packed_accessor32() && = delete;
template<typename T, size_t N, template <typename U> class PtrTraits = DefaultPtrTraits>
PackedTensorAccessor64<T,N,PtrTraits> packed_accessor64() const& {
return generic_packed_accessor<T,N,PtrTraits,int64_t>();
}
template<typename T, size_t N, template <typename U> class PtrTraits = DefaultPtrTraits>
PackedTensorAccessor64<T,N,PtrTraits> packed_accessor64() && = delete;
// ~~~~~ Autograd API ~~~~~
/// \fn bool is_leaf() const;
///
/// All Tensors that have `requires_grad()` which is ``false`` will be leaf Tensors by convention.
///
/// For Tensors that have `requires_grad()` which is ``true``, they will be leaf Tensors if they were
/// created by the user. This means that they are not the result of an operation and so
/// `grad_fn()` is `nullptr`.
///
/// Only leaf Tensors will have their `grad()` populated during a call to `backward()`.
/// To get `grad()` populated for non-leaf Tensors, you can use `retain_grad()`.
///
/// Example:
/// @code
/// auto a = torch::rand(10, torch::requires_grad());
/// std::cout << a.is_leaf() << std::endl; // prints `true`
///
/// auto b = torch::rand(10, torch::requires_grad()).to(torch::kCUDA);
/// std::cout << b.is_leaf() << std::endl; // prints `false`
/// // b was created by the operation that cast a cpu Tensor into a cuda Tensor
///
/// auto c = torch::rand(10, torch::requires_grad()) + 2;
/// std::cout << c.is_leaf() << std::endl; // prints `false`
/// // c was created by the addition operation
///
/// auto d = torch::rand(10).cuda();
/// std::cout << d.is_leaf() << std::endl; // prints `true`
/// // d does not require gradients and so has no operation creating it (that is tracked by the autograd engine)
///
/// auto e = torch::rand(10).cuda().requires_grad_();
/// std::cout << e.is_leaf() << std::endl; // prints `true`
/// // e requires gradients and has no operations creating it
///
/// auto f = torch::rand(10, torch::device(torch::kCUDA).requires_grad(true));
/// std::cout << f.is_leaf() << std::endl; // prints `true`
/// // f requires grad, has no operation creating it
/// @endcode
/// \fn void backward(const Tensor & gradient={}, c10::optional<bool> retain_graph=c10::nullopt, bool create_graph=false, c10::optional<TensorList> inputs=c10::nullopt) const;
///
/// Computes the gradient of current tensor with respect to graph leaves.
///
/// The graph is differentiated using the chain rule. If the tensor is
/// non-scalar (i.e. its data has more than one element) and requires
/// gradient, the function additionally requires specifying ``gradient``.
/// It should be a tensor of matching type and location, that contains
/// the gradient of the differentiated function w.r.t. this Tensor.
///
/// This function accumulates gradients in the leaves - you might need to
/// zero them before calling it.
///
/// \param gradient Gradient w.r.t. the
/// tensor. If it is a tensor, it will be automatically converted
/// to a Tensor that does not require grad unless ``create_graph`` is True.
/// None values can be specified for scalar Tensors or ones that
/// don't require grad. If a None value would be acceptable then
/// this argument is optional.
/// \param retain_graph If ``false``, the graph used to compute
/// the grads will be freed. Note that in nearly all cases setting
/// this option to True is not needed and often can be worked around
/// in a much more efficient way. Defaults to the value of
/// ``create_graph``.
/// \param create_graph If ``true``, graph of the derivative will
/// be constructed, allowing to compute higher order derivative
/// products. Defaults to ``false``.
/// \param inputs Inputs w.r.t. which the gradient will be accumulated into
/// ``at::Tensor::grad``. All other Tensors will be ignored. If not
/// provided, the gradient is accumulated into all the leaf Tensors
/// that were used to compute the current tensor.
/// When inputs are provided and a given input is not a leaf,
/// the current implementation will call its grad_fn (even though it is not strictly needed to get this gradients).
/// It is an implementation detail on which the user should not rely.
/// See https://github.com/pytorch/pytorch/pull/60521#issuecomment-867061780 for more details.
/// \fn Tensor detach() const;
///
/// Returns a new Tensor, detached from the current graph.
/// The result will never require gradient.
/// \fn Tensor & detach_() const;
///
/// Detaches the Tensor from the graph that created it, making it a leaf.
/// Views cannot be detached in-place.
/// \fn void retain_grad() const;
///
/// Enables this Tensor to have their :attr:`grad` populated during
/// :func:`backward`. This is a no-op for leaf tensors.
/// \fn bool retains_grad() const;
///
/// Is ``true`` if this Tensor is non-leaf and its :attr:`grad` is enabled to be
/// populated during :func:`backward`, ``false`` otherwise.
const TensorBase& set_requires_grad(bool requires_grad) const {
impl_->set_requires_grad(requires_grad);
return *this;
}
bool requires_grad() const {
return impl_->requires_grad();
}
// The Forward AD API functions below are low level and are not to be used by end
// users who should use the API provided in torch/csrc/autograd.h
/// This function returns the forward gradient for this Tensor at the given level.
const Tensor& _fw_grad(uint64_t level) const {
return impl_->_fw_grad(level, *this);
}
/// This function can be used to set the value of the forward grad.
/// Note that the given new_grad might not be used directly if it has different
/// metadata (size/stride/storage offset) compared to this Tensor. In that case,
/// new_grad content will be copied into a new Tensor
void _set_fw_grad(const TensorBase& new_grad, uint64_t level, bool is_inplace_op) const {
impl_->_set_fw_grad(new_grad, *this, level, is_inplace_op);
}
/// NOTE: This is similar to the legacy `.data()` function on `Variable`, and is intended
/// to be used from functions that need to access the `Variable`'s equivalent `Tensor`
/// (i.e. `Tensor` that shares the same storage and tensor metadata with the `Variable`).
///
/// One notable difference with the legacy `.data()` function is that changes to the
/// returned `Tensor`'s tensor metadata (e.g. sizes / strides / storage / storage_offset)
/// will not update the original `Variable`, due to the fact that this function
/// shallow-copies the `Variable`'s underlying TensorImpl.
at::TensorBase tensor_data() const;
/// NOTE: `var.variable_data()` in C++ has the same semantics as `tensor.data`
/// in Python, which create a new `Variable` that shares the same storage and
/// tensor metadata with the original `Variable`, but with a completely new
/// autograd history.
///
/// NOTE: If we change the tensor metadata (e.g. sizes / strides /
/// storage / storage_offset) of a variable created from `var.variable_data()`, those
/// changes will not update the original variable `var`. In `.variable_data()`, we set
/// `allow_tensor_metadata_change_` to false to make such changes explicitly illegal,
/// in order to prevent users from changing metadata of `var.variable_data()`
/// and expecting the original variable `var` to also be updated.
at::TensorBase variable_data() const;
// Gradient Node and Edges
//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
/// Gets the gradient function of the `Variable`. If this is a leaf variable,
/// the pointer returned will be null.
///
/// For View Variables:
/// Gets the up-to-date grad_fn. If the shared data or base was modified, we
/// re-create the grad_fn to express the up-to-date view relationship between
/// this and the base Variable.
const std::shared_ptr<torch::autograd::Node>& grad_fn() const;
// Hooks
//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
template <typename T>
using hook_return_void_t = std::enable_if_t<std::is_void<typename c10::invoke_result_t<T&, TensorBase>>::value, unsigned>;
template <typename T>
using hook_return_var_t = std::enable_if_t<std::is_same<typename c10::invoke_result_t<T&, TensorBase>, TensorBase>::value, unsigned>;
/// Registers a backward hook.
///
/// The hook will be called every time a gradient with respect to the Tensor is computed.
/// The hook should have one of the following signature:
/// ```
/// hook(TensorBase grad) -> TensorBase
/// ```
/// ```
/// hook(TensorBase grad) -> void
/// ```
/// The hook should not modify its argument, but it can optionally return a new gradient
/// which will be used in place of `grad`.
///
/// This function returns the index of the hook in the list which can be used to remove hook.
///
/// Example:
/// @code
/// auto v = torch::tensor({0., 0., 0.}, torch::requires_grad());
/// auto h = v.register_hook([](torch::Tensor grad){ return grad * 2; }); // double the gradient
/// v.backward(torch::tensor({1., 2., 3.}));
/// // This prints:
/// // ```
/// // 2
/// // 4
/// // 6
/// // [ CPUFloatType{3} ]
/// // ```
/// std::cout << v.grad() << std::endl;
/// v.remove_hook(h); // removes the hook
/// @endcode
template <typename T>
hook_return_void_t<T> register_hook(T&& hook) const;
template <typename T>
hook_return_var_t<T> register_hook(T&& hook) const;
protected:
unsigned _register_hook(std::function<TensorBase(const TensorBase&)> hook) const;
public:
/// Remove hook at given position
void remove_hook(unsigned pos) const;
// Variable methods
//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
bool is_leaf() const;
int64_t output_nr() const;
void set_data(const TensorBase & new_data) const;
TensorBase data() const;
int64_t _version() const;
void retain_grad() const;
bool retains_grad() const;
const TensorBase& requires_grad_(bool _requires_grad=true) const;
// View Variables
//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
/// Returns true if this `Variable` is a view of another `Variable`.
bool is_view() const;
/// Returns the `Variable` that this `Variable` is a view of. If this
/// `Variable` is not a view, throw a `std::runtime_error`.
const TensorBase& _base() const;
// Miscellaneous
//~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
const std::string& name() const;
protected:
void enforce_invariants();
c10::intrusive_ptr<TensorImpl, UndefinedTensorImpl> impl_;
private:
TensorBase __dispatch_contiguous(c10::MemoryFormat) const;
};
inline int64_t get_device(const TensorBase& self) {
return self.get_device();
}
template <typename T>
auto TensorBase::register_hook(T&& hook) const -> TensorBase::hook_return_void_t<T> {
// Return the grad argument in case of a hook with void return type to have an
// std::function with Tensor return type
static_assert(std::is_same<decltype(hook(TensorBase())), void>::value,
"Expected hook to return void");
return _register_hook([fn=std::forward<T>(hook)](const TensorBase& grad) {
fn(grad);
return TensorBase();
});
}
template <typename T>
auto TensorBase::register_hook(T&& hook) const -> TensorBase::hook_return_var_t<T> {
return _register_hook(std::forward<T>(hook));
}
namespace detail {
// Helper creator for Tensor class which doesn't requires the users to pass
// in an intrusive_ptr instead it just converts the argument passed to
// requested intrusive_ptr type.
template <typename T, typename... Args>
TensorBase make_tensor_base(Args&&... args) {
return TensorBase(c10::make_intrusive<T>(std::forward<Args>(args)...));
}
} // namespace detail
static inline DispatchKey legacyExtractDispatchKey(const TensorBase& t) {
return legacyExtractDispatchKey(t.key_set());
}
} // namespace at
namespace c10 {
template <>
struct MaybeOwnedTraits<at::TensorBase> {
using owned_type = at::TensorBase;
using borrow_type = at::TensorBase;
static borrow_type createBorrow(const owned_type& from) {
// NOTE: this can be implemented without the special
// unsafe_borrow_t Tensor constructor as
//
// return borrow_type(c10::intrusive_ptr<at::TensorImpl, at::UndefinedTensorImpl>::reclaim(from.unsafeGetTensorImpl()));
//
// but that hurts inlining due to the nullptr check in the
// Tensor(c10::intrusive_ptr<...>) constructor. We already know
// that from.impl_ isn't null because from is a valid Tensor, so
// we needn't do the check again. (using __builtin_assume can
// avoid this, but wouldn't be portable to MSVC.)
return borrow_type(borrow_type::unsafe_borrow_t{}, from);
}
static void assignBorrow(borrow_type& lhs, const borrow_type& rhs) {
lhs.unsafeReleaseTensorImpl();
// See above note: this can be implemented with public API
// similarly to createBorrow(), but that would hurt inlining.
lhs = borrow_type(borrow_type::unsafe_borrow_t{}, rhs);
}
static void destroyBorrow(borrow_type& toDestroy) {
toDestroy.unsafeReleaseTensorImpl(); // "leak" it, but it was already +0.
}
static const owned_type& referenceFromBorrow(const borrow_type& borrow) {
return borrow;
}
static const owned_type* pointerFromBorrow(const borrow_type& borrow) {
return &borrow;
}
static bool debugBorrowIsValid(const borrow_type& /*borrow*/) {
return true;
}
};
template <>
struct ExclusivelyOwnedTraits<at::TensorBase> : public c10::ExclusivelyOwnedTensorTraits<at::TensorBase> {};
} // namespace c10
namespace at {
inline c10::MaybeOwned<TensorBase> borrow_from_optional_tensor(
const c10::optional<TensorBase>& opt) {
return opt.has_value()
? c10::MaybeOwned<TensorBase>::borrowed(*opt)
: c10::MaybeOwned<TensorBase>::owned(c10::in_place);
}
inline c10::MaybeOwned<TensorBase> TensorBase::expect_contiguous(MemoryFormat memory_format) const & {
if (is_contiguous(memory_format)) {
return c10::MaybeOwned<TensorBase>::borrowed(*this);
} else {
return c10::MaybeOwned<TensorBase>::owned(__dispatch_contiguous(memory_format));