`Tensor.split` calls `TensorBase.split` whose `handle_torch_function` statement passes `func` as `Tensor.split` which is usually correct, but not here because of the use of `super()`. Instead this calls `torch._VF.split` which correctly differentiates from `torch.split`. This is currently okay since we never hit `TensorBase.split` for types with `__torch_function__` however, once we allow skipping only one hop of `__torch_function__` this will expose the error.
Pull Request resolved: https://github.com/pytorch/pytorch/pull/83866
Approved by: https://github.com/albanD
This is a new version of #15648 based on the latest master branch.
Unlike the previous PR where I fixed a lot of the doctests in addition to integrating xdoctest, I'm going to reduce the scope here. I'm simply going to integrate xdoctest, and then I'm going to mark all of the failing tests as "SKIP". This will let xdoctest run on the dashboards, provide some value, and still let the dashboards pass. I'll leave fixing the doctests themselves to another PR.
In my initial commit, I do the bare minimum to get something running with failing dashboards. The few tests that I marked as skip are causing segfaults. Running xdoctest results in 293 failed, 201 passed tests. The next commits will be to disable those tests. (unfortunately I don't have a tool that will insert the `#xdoctest: +SKIP` directive over every failing test, so I'm going to do this mostly manually.)
Fixes https://github.com/pytorch/pytorch/issues/71105
@ezyang
Pull Request resolved: https://github.com/pytorch/pytorch/pull/82797
Approved by: https://github.com/ezyang
## Motivation
The DLPack device type kDLOneAPI stands for the Unified Shared Memory allocated on a oneAPI device. The corresponding Pytorch backend type is XPU.
Support to export/import the Pytorch XPU tensor as a DLPack tensor of kDLOneAPI device.
## Solution
1. Update the DLPack protocol to v0.7.
2. Add the XPU hooks to map the Aten device and DLPack device with the address value and device information.
Pull Request resolved: https://github.com/pytorch/pytorch/pull/82867
Approved by: https://github.com/kit1980
## Motivation
The DLPack device type kDLOneAPI stands for the Unified Shared Memory allocated on a oneAPI device. The corresponding Pytorch backend type is XPU.
Support to export/import the Pytorch XPU tensor as a DLPack tensor of kDLOneAPI device.
## Solution
1. Update the DLPack protocol to v0.7.
2. Add the XPU hooks to map the Aten device and DLPack device with the address value and device information.
Pull Request resolved: https://github.com/pytorch/pytorch/pull/81021
Approved by: https://github.com/ezyang
### Description
Since the major changes for `_TypedStorage` and `_UntypedStorage` are now complete, they can be renamed to be public.
`TypedStorage._untyped()` is renamed to `TypedStorage.untyped()`.
Documentation for storages is improved as well.
### Issue
Fixes#82436
### Testing
N/A
Pull Request resolved: https://github.com/pytorch/pytorch/pull/82438
Approved by: https://github.com/ezyang
unflatten now has a free function version in torch.flatten in addition to
the method in torch.Tensor.flatten.
Updated docs to reflect this and polished them a little.
For consistency, changed the signature of the int version of unflatten in
native_functions.yaml.
Some override tests were failing because unflatten has unusual
characteristics in terms of the .int and .Dimname versions having
different number of arguments so this required some changes
to test/test_override.py
Removed support for using mix of integer and string arguments
when specifying dimensions in unflatten.
Pull Request resolved: https://github.com/pytorch/pytorch/pull/81399
Approved by: https://github.com/Lezcano, https://github.com/ngimel
## Motivation
The DLPack device type kDLOneAPI stands for the Unified Shared Memory allocated on a oneAPI device. The corresponding Pytorch backend type is XPU.
Support to export/import the Pytorch XPU tensor as a DLPack tensor of kDLOneAPI device.
## Solution
1. Update the DLPack protocol to v0.7.
2. Add the XPU hooks to map the Aten device and DLPack device with the address value and device information.
Pull Request resolved: https://github.com/pytorch/pytorch/pull/78154
Approved by: https://github.com/ezyang
We don't have any coverage for meta tensor correctness for backwards
because torch function mode can only allow us to interpose on
Python torch API calls, but backwards invocations happen from C++.
To make this possible, I add torch_dispatch_meta test which runs the
tests with __torch_dispatch__
While doing this, I needed to generate fresh expected failure / skip
lists for the new test suite, and I discovered that my original
scaffolding for this purpose was woefully insufficient. So I rewrote
how the test framework worked, and at the same time rewrote the
__torch_function__ code to also use the new logic. Here's whats
new:
- Expected failure / skip is now done on a per function call basis,
rather than the entire test. This means that separate OpInfo
samples for a function don't affect each other.
- There are now only two lists: expect failure list (where the test
consistently fails on all runs) and skip list (where the test
sometimes passes and fails.
- We explicitly notate the dtype that failed. I considered detecting
when something failed on all dtypes, but this was complicated and
listing everything out seemed to be nice and simple. To keep the
dtypes short, I introduce a shorthand notation for dtypes.
- Conversion to meta tensors is factored into its own class
MetaConverter
- To regenerate the expected failure / skip lists, just run with
PYTORCH_COLLECT_EXPECT and filter on a specific test type
(test_meta or test_dispatch_meta) for whichever you want to update.
Other misc fixes:
- Fix max_pool1d to work with BFloat16 in all circumstances, by making
it dispatch and then fixing a minor compile error (constexpr doesn't
work with BFloat16)
- Add resolve_name for turning random torch API functions into string
names
- Add push classmethod to the Mode classes, so that you can more easily
push a mode onto the mode stack
- Add some more skips for missing LAPACK
- Added an API to let you query if there's already a registration for
a function, added a test to check that we register_meta for all
decompositions (except detach, that decomp is wrong lol), and then
update all the necessary sites to make the test pass.
Signed-off-by: Edward Z. Yang <ezyangfb.com>
Pull Request resolved: https://github.com/pytorch/pytorch/pull/77477
Approved by: https://github.com/zou3519
I figured these out by unconditionally turning on a no-op torch function
mode on the test suite and then fixing errors as they showed up. Here's
what I found:
- _parse_to failed internal assert when __torch_function__'ed because it
claims its name is "to" to the argument parser; added a name override
so we know how to find the correct name
- Infix operator magic methods on Tensor did not uniformly handle
__torch_function__ and TypeError to NotImplemented. Now, we always
do the __torch_function__ handling in
_wrap_type_error_to_not_implemented and your implementation of
__torch_function__ gets its TypeErrors converted to NotImplemented
(for better or for worse; see
https://github.com/pytorch/pytorch/issues/75462 )
- A few cases where code was incorrectly testing if a Tensor was
Tensor-like in the wrong way, now use is_tensor_like (in grad
and in distributions). Also update docs for has_torch_function to
push people to use is_tensor_like.
- is_grads_batched was dropped from grad in handle_torch_function, now
fixed
- Report that you have a torch function even if torch function is
disabled if a mode is enabled. This makes it possible for a mode
to return NotImplemented, pass to a subclass which does some
processing and then pass back to the mode even after the subclass
disables __torch_function__ (so the tensors are treated "as if"
they are regular Tensors). This brings the C++ handling behavior
in line with the Python behavior.
- Make the Python implementation of overloaded types computation match
the C++ version: when torch function is disabled, there are no
overloaded types (because they all report they are not overloaded).
Signed-off-by: Edward Z. Yang <ezyangfb.com>
Pull Request resolved: https://github.com/pytorch/pytorch/pull/75484
Approved by: https://github.com/zou3519
Numpy array is chosen to be the rebuild component for
HPU. so add it to the backend list.
Signed-off-by: Ayman Yousef<ayousef@habana.ai>
Signed-off-by: Jeeja <jeejakp@habana.ai>
Fixes #ISSUE_NUMBER
Pull Request resolved: https://github.com/pytorch/pytorch/pull/74738
Approved by: https://github.com/albanD
I was working on an explanation of how to call into the "super"
implementation of some given ATen operation inside of __torch_dispatch__
(https://github.com/albanD/subclass_zoo/blob/main/trivial_tensors.py)
and I kept thinking to myself "Why doesn't just calling super() on
__torch_dispatch__ work"? Well, after this patch, it does! The idea
is if you don't actually unwrap the input tensors, you can call
super().__torch_dispatch__ to get at the original behavior.
Internally, this is implemented by disabling PythonKey and then
redispatching. This implementation of disabled_torch_dispatch is
not /quite/ right, and some reasons why are commented in the code.
There is then some extra work I have to do to make sure we recognize
disabled_torch_dispatch as the "default" implementation (so we don't
start slapping PythonKey on all tensors, including base Tensors),
which is modeled the same way as how disabled_torch_function is done.
Signed-off-by: Edward Z. Yang <ezyangfb.com>
Pull Request resolved: https://github.com/pytorch/pytorch/pull/73684
Approved by: albanD
Summary:
A small bug that misses `lazy` in tensor.__deepcopy__, which results in segmentation when deepcopy a lazy model.
Pull Request resolved: https://github.com/pytorch/pytorch/pull/73197
Reviewed By: jbschlosser
Differential Revision: D34394482
Pulled By: wconstab
fbshipit-source-id: c84fdb9b3a827677971fd3477a92679d7dbce3c0
(cherry picked from commit c003d150ce)
Summary:
Pull Request resolved: https://github.com/pytorch/pytorch/pull/69265
This is used in tab completion, we should not put warning here
Test Plan:
ci
Imported from OSS
Reviewed By: albanD
Differential Revision: D32778736
fbshipit-source-id: f1bec5e09a8238ab41329ac2b64e6f3267799f6a
Summary:
Pull Request resolved: https://github.com/pytorch/pytorch/pull/62030
Remove dtype tracking from Python Storage interface, remove all the different `<type>Storage` classes except for `ByteStorage`, and update serialization accordingly, while maintaining as much FC/BC as possible
Fixes https://github.com/pytorch/pytorch/issues/47442
* **THE SERIALIZATION FORMAT IS FULLY FC/BC.** We worked very hard to make sure this is the case. We will probably want to break FC at some point to make the serialization structure of tensors make more sense, but not today.
* There is now only a single torch.ByteStorage class. Methods like `Tensor.set_` no longer check that the dtype of storage is appropriate.
* As we no longer know what dtype of a storage is, we've **removed** the size method from Storage, replacing it with nbytes. This is to help catch otherwise silent errors where you confuse number of elements with number of bytes.
* `Storage._new_shared` takes a `nbytes` kwarg and will reject previous positional only calls. `Storage._new_with_file` and `_set_from_file` require explicit element size arguments.
* It's no longer possible to convert storages to different types using the float/double/etc methods. Instead, do the conversion using a tensor.
* It's no longer possible to allocate a typed storage directly using FloatStorage/DoubleStorage/etc constructors. Instead, construct a tensor and extract its storage. The classes still exist but they are used purely for unpickling.
* The preexisting serialization format stores dtype with storage, and in fact this dtype is used to determine the dtype of the tensor overall.
To accommodate this case, we introduce a new TypedStorage concept that exists only during unpickling time which is used to temporarily store the dtype so we can construct a tensor. **If you overrode the handling of pickling/unpickling, you MUST add handling for TypedStorage** or your serialization code will degrade to standard file-based serialization.
Original pull request: https://github.com/pytorch/pytorch/pull/59671
Reviewed By: soulitzer, ngimel
Differential Revision: D29466819
Pulled By: ezyang
fbshipit-source-id: 4a14e5d3c2b08e06e558683d97f7378a3180b00e
Summary:
Happy to get any feedback on how to make this code cleaner!
This:
- Fix Tensor attribute deepcopy BC-breaking?
- Add a test for Tensor attribute deepcopy
- Fix subclass deepcopy
- Moves the subclass serialization tests into their own class not to interfere with other serialization test logic
- Add a test for subclass deepcopy
cc ezyang gchanan
Pull Request resolved: https://github.com/pytorch/pytorch/pull/65584
Reviewed By: gchanan
Differential Revision: D31206590
Pulled By: albanD
fbshipit-source-id: 74a8f0767f4933b9c941fbea880a8fd1b893ea2f
Summary:
Fixes https://github.com/pytorch/pytorch/issues/60548
`Tensor.__floordiv__` was indirectly deprecated by deprecation of `torch.floor_divide` (see https://github.com/pytorch/pytorch/issues/43874). Deprecating it directly provides clearer feedback.
Repro:
```
import torch
x = torch.tensor(0)
x // 1
```
Before this change, a deprecation warning was triggered within the C++ implementation of floor_divide:
```
UserWarning: floor_divide is deprecated, and will be removed in a future version of pytorch. It currently rounds toward 0 (like the 'trunc' function NOT 'floor'). This results in incorrect rounding for negative values.
To keep the current behavior, use torch.div(a, b, rounding_mode='trunc'), or for actual floor division, use torch.div(a, b, rounding_mode='floor'). (Triggered internally at ../aten/src/ATen/native/BinaryOps.cpp:571.)
return torch.floor_divide(self, other)
```
After this change, the warning instead cites the user's offending line of Python code:
```
UserWarning: __floordiv__ is deprecated, and its behavior will change in a future version of pytorch. It currently rounds toward 0 (like the 'trunc' function NOT 'floor'). This results in incorrect rounding for negative values.
To keep the current behavior, use torch.div(a, b, rounding_mode='trunc'), or for actual floor division, use torch.div(a, b, rounding_mode='floor').
x // 1
```
Pull Request resolved: https://github.com/pytorch/pytorch/pull/64034
Reviewed By: mruberry
Differential Revision: D30658010
Pulled By: saketh-are
fbshipit-source-id: b0e6c5008d741897509d102f4a89efb47de4aa2a
Summary:
This PR implements the necessary hooks/stubs/enums/etc for complete ONNX Runtime (ORT) Eager Mode integration. The actual extension will live out of tree at https://github.com/pytorch/ort.
We have been [working on this at Microsoft](https://github.com/microsoft/onnxruntime-pytorch/tree/eager-ort/torch_onnxruntime) for the last few months, and are finally ready to contribute the PyTorch core changes upstream (nothing major or exciting, just the usual boilerplate for adding new backends).
The ORT backend will allow us to ferry [almost] all torch ops into granular ONNX kernels that ORT will eagerly execute against any devices it supports (therefore, we only need a single ORT backend from a PyTorch perspective).
Pull Request resolved: https://github.com/pytorch/pytorch/pull/58248
Reviewed By: astaff
Differential Revision: D30344992
Pulled By: albanD
fbshipit-source-id: 69082b32121246340d686e16653626114b7714b2
Summary:
Pull Request resolved: https://github.com/pytorch/pytorch/pull/62744
The `Tensor._reduce_ex_internal` function can only be called via the `Tensor.__reduce_ex__` function.
And that second function already properly handles the `__torch_function__` overwrites. So no need to handle them again in `Tensor._reduce_ex_internal`.
This PR also updates `Tensor.__reduce_ex__` to use the specialized unary API for `__torch_function__` that makes it nicer to read.
Test Plan: Imported from OSS
Reviewed By: H-Huang
Differential Revision: D30113113
Pulled By: albanD
fbshipit-source-id: c94f5d2597ee3afe799d9de991f75615c3c172d6
Summary:
Pull Request resolved: https://github.com/pytorch/pytorch/pull/62192
This support is hacky because it doesn't preserve meta tensor storage
sharing (e.g., if you serialize a model with shared storage, e.g., a
tensor and a view on a tensor, when I deserialize the viewing
relationship will be broken and these are just different tensors.) The
hack is also durable, in the sense that we will be on the hook for
supporting `_rebuild_meta_tensor_no_storage` in perpetuity in the
future, even if we change our mind about the serialization format.
This unblocks an FB production use case. I didn't add C++ support to minimize
blast area of this patch.
Signed-off-by: Edward Z. Yang <ezyang@fb.com>
Test Plan: Imported from OSS
Reviewed By: zou3519
Differential Revision: D29910535
Pulled By: ezyang
fbshipit-source-id: d98dcdd0108dfc3ae730a071d3c583b6d0281d21
Summary:
Pull Request resolved: https://github.com/pytorch/pytorch/pull/56058
User facing changes:
1. Adds a negative bit and corresponding new API (`is_neg()`,`resolve_neg()`)
2. `tensor.conj().imag` now returns a floating point tensor with neg bit set to 1 instead of a tensor with no notion of negative bit. Note that imag is still a view and all the view properties still hold for imag.
Non user facing changes:
1. Added a new Negative dispatch key and a backend fallback to handle it
2. Updated copy kernel to handle negative bit
3. Merged conjugate and negative bit fallback kernel
4. fixed https://github.com/pytorch/pytorch/issues/60478 (caused due to https://github.com/pytorch/pytorch/pull/54987)
Testing:
1. Added a new OpInfo based test `test_neg_view` (verifies that out-of-place and in-place operations work correctly for all operations when the input is a neg view tensor by checking the result against an actually negated tensor, verifies that autograd returns the same output for both neg view and actually negated tensors as well as it works fine when grad_out is a neg view).
2. Added a new test class containing `test_conj_view`, `test_neg_view`.
Test Plan: Imported from OSS
Reviewed By: soulitzer
Differential Revision: D29636403
fbshipit-source-id: 12214c9dc4806c51850f4a72a109db9527c0ca63
Summary:
Pull Request resolved: https://github.com/pytorch/pytorch/pull/59760
See https://github.com/pytorch/pytorch/issues/59049
There are some moving parts to this PR, I'll structure this explanation so the straightforward parts go first, and then the less straightforward parts.
**The actual dispatch to Python.** The core logic of dispatch to Python lives in `concrete_dispatch_fn` in `torch/csrc/autograd/python_variable.cpp`. It takes the input IValue stack, scans all the arguments for Tensor arguments, and defers most of the heavy lifting to `handle_torch_function_no_python_arg_parser` which actually does all of the logic for calling out to torch dispatch (in particular, this function handles multiple dispatch situations for you). Because we have a different function name than regular `__torch_function__` handling, `handle_torch_function_no_python_arg_parser` is generalized to accept a magic method name to look for when testing if Tensors have custom handling or not. Unlike `__torch_function__`, by default there is no `__torch_dispatch__` on Tensor classes.
**Maintaining the Python dispatch key.** In order to get to the dispatch to Python logic, we must tag Tensors with the `__torch_dispatch__` magic method with the newly added Python dispatch key (separated from PythonFuncTorch to allow for a transitional period while they migrate to this mechanism). We expose a new private property `_is_python_dispatch` that assists in debugging if a Tensor is participating in Python dispatch or not. We apply the Python dispatch key the first time a PyObject for a Tensor is constructed (THPVariable_NewWithVar), testing if `__torch_dispatch__` exists with then newly added `check_has_torch_dispatch`.
**Shallow copy and detach.** For the simple examples tested in this PR, most creations of Tensor route through the dispatcher. The exception to this is `shallow_copy_and_detach`, which bypasses the dispatcher and is used when saving tensors for backwards. When a Tensor is Python dispatch, we override the behavior of `shallow_copy_and_detach` to instead directly call into `__torch_dispatch__` to perform a `detach` operation (in the same way it would be invoked if you called `detach` directly). Because this Python call is triggered directly from c10::TensorImpl, it must be indirected through `PyInterpreter::detach`, which is the general mechanism for dynamic dispatching to the Python interpreter associated with a TensorImpl.
**torchdeploy compatibility.** The dispatch to Python logic cannot be directly registered to the dispatcher as it is compiled in the Python library, which will get loaded multiple times per torchdeploy interpreter. Thus, we must employ a two phase process. First, we register a fallback inside a non-Python library (aten/src/ATen/core/PythonFallbackKernel.cpp). Its job is to determine the appropriate PyInterpreter to handle the Python dispatch by going through all of the arguments and finding the first argument that has a PyObject/PyInterpreter. With this PyInterpreter, it makes another dynamic dispatch via "dispatch" which will go to the correct torchdeploy interpreter to handle dispatching to actual Python.
**Testing.** We provide a simple example of a LoggingTensor for testing, which can be used to generate TorchScript-like traces to observe what operations are being called when a Tensor is invoked. Although a LoggingTensor would be better implemented via an is-a relationship rather than a has-a relationship (as is done in the test), we've done it this way to show that arbitrarily complex compositions of tensors inside a tensor work properly.
**Known limitations.**
* We haven't adjusted any operator code, so some patterns may not work (as they lose the Python subclass in an unrecoverable way)
* `__torch_function__` must be explicitly disabled with `_disabled_torch_function_impl` otherwise things don't work quite correctly (in particular, what is being disabled is default subclass preservation behavior.)
* We don't ever populate kwargs, even when an argument is kwarg-only
Signed-off-by: Edward Z. Yang <ezyang@fb.com>
Differential Revision:
D29017912
D29017912
Test Plan: Imported from OSS
Reviewed By: bdhirsh
Pulled By: ezyang
fbshipit-source-id: a67714d9e541d09203a8cfc85345b8967db86238
Summary:
Pull Request resolved: https://github.com/pytorch/pytorch/pull/60464
Fixes https://github.com/szagoruyko/pytorchviz/issues/65
An alternate implementation of this PR would be to remove the
__torch_function__ interposition points for these accessors entirely.
In the end, I decided to opt for extra expressivity. See
torch.overrides for the criterion on how I decided which accessors
should get the nowrap treatment.
Signed-off-by: Edward Z. Yang <ezyang@fb.com>
Test Plan: Imported from OSS
Reviewed By: albanD
Differential Revision: D29302835
Pulled By: ezyang
fbshipit-source-id: fbe0ac4530a6cc9d6759a3fdf5514d4d7b1f7690
Summary:
Fixes https://github.com/pytorch/pytorch/issues/35379
- Adds `retains_grad` attribute backed by cpp as a native function. The python bindings for the function are skipped to be consistent with `is_leaf`.
- Tried writing it without native function, but the jit test `test_tensor_properties` seems to require that it be a native function (or alternatively maybe it could also work if we manually add a prim implementation?).
- Python API now uses `retain_grad` implementation from cpp
Pull Request resolved: https://github.com/pytorch/pytorch/pull/59362
Reviewed By: jbschlosser
Differential Revision: D28969298
Pulled By: soulitzer
fbshipit-source-id: 335f2be50b9fb870cd35dc72f7dadd6c8666cc02
Summary:
Pull Request resolved: https://github.com/pytorch/pytorch/pull/54987
Based off of ezyang (https://github.com/pytorch/pytorch/pull/44799) and bdhirsh (https://github.com/pytorch/pytorch/pull/43702) 's prototype:
Here's a summary of the changes in this PR:
This PR adds a new dispatch key called Conjugate. This enables us to make conjugate operation a view and leverage the specialized library functions that fast path with the hermitian operation (conj + transpose).
1. Conjugate operation will now return a view with conj bit (1) for complex tensors and returns self for non-complex tensors as before. This also means `torch.view_as_real` will no longer be a view on conjugated complex tensors and is hence disabled. To fill the gap, we have added `torch.view_as_real_physical` which would return the real tensor agnostic of the conjugate bit on the input complex tensor. The information about conjugation on the old tensor can be obtained by calling `.is_conj()` on the new tensor.
2. NEW API:
a) `.conj()` -- now returning a view.
b) `.conj_physical()` -- does the physical conjugate operation. If the conj bit for input was set, you'd get `self.clone()`, else you'll get a new tensor with conjugated value in its memory.
c) `.conj_physical_()`, and `out=` variant
d) `.resolve_conj()` -- materializes the conjugation. returns self if the conj bit is unset, else returns a new tensor with conjugated values and conj bit set to 0.
e) `.resolve_conj_()` in-place version of (d)
f) `view_as_real_physical` -- as described in (1), it's functionally same as `view_as_real`, just that it doesn't error out on conjugated tensors.
g) `view_as_real` -- existing function, but now errors out on conjugated tensors.
3. Conjugate Fallback
a) Vast majority of PyTorch functions would currently use this fallback when they are called on a conjugated tensor.
b) This fallback is well equipped to handle the following cases:
- functional operation e.g., `torch.sin(input)`
- Mutable inputs and in-place operations e.g., `tensor.add_(2)`
- out-of-place operation e.g., `torch.sin(input, out=out)`
- Tensorlist input args
- NOTE: Meta tensors don't work with conjugate fallback.
4. Autograd
a) `resolve_conj()` is an identity function w.r.t. autograd
b) Everything else works as expected.
5. Testing:
a) All method_tests run with conjugate view tensors.
b) OpInfo tests that run with conjugate views
- test_variant_consistency_eager/jit
- gradcheck, gradgradcheck
- test_conj_views (that only run for `torch.cfloat` dtype)
NOTE: functions like `empty_like`, `zero_like`, `randn_like`, `clone` don't propagate the conjugate bit.
Follow up work:
1. conjugate view RFC
2. Add neg bit to re-enable view operation on conjugated tensors
3. Update linalg functions to call into specialized functions that fast path with the hermitian operation.
Test Plan: Imported from OSS
Reviewed By: VitalyFedyunin
Differential Revision: D28227315
Pulled By: anjali411
fbshipit-source-id: acab9402b9d6a970c6d512809b627a290c8def5f
Summary:
Fixes https://github.com/pytorch/pytorch/issues/57719.
This PR fixes `torch.Tensor{__rsub__, __rdiv__, __rtruediv__, __pow__, __rmatmul__}` to return `NotImplemented` instead of raising a `TypeError`.
cc/ mruberry: The first commit of this PR is the same as 1d209db1cc excepts the commit message.
Pull Request resolved: https://github.com/pytorch/pytorch/pull/57934
Reviewed By: mruberry
Differential Revision: D28351931
Pulled By: albanD
fbshipit-source-id: 985457a44dba24d2496794dfb8c1661cbcd4ff8f
Summary:
This makes detach both forward and backward non-differentiable by default.
You can pass the `only_backward_mode=True` argument to make it forward differentiable but backward non-differentiable.
The important side effect of this change is that, by default, detach is not tracking any view information.
Pull Request resolved: https://github.com/pytorch/pytorch/pull/57820
Reviewed By: ezyang
Differential Revision: D28287633
Pulled By: albanD
fbshipit-source-id: bdc4726fcd05889f6ac84e5a3a3ef71b2ec41015
Summary:
Pull Request resolved: https://github.com/pytorch/pytorch/pull/54702
This fixes subclassing for __iter__ so that it returns an iterator over
subclasses properly instead of Tensor.
Test Plan: Imported from OSS
Reviewed By: H-Huang
Differential Revision: D27352563
Pulled By: ezyang
fbshipit-source-id: 4c195a86c8f2931a6276dc07b1e74ee72002107c
Summary:
Pull Request resolved: https://github.com/pytorch/pytorch/pull/53973
Two parts to this PR; I had to put them together because adding support for X causes more test code to be exercised, which in turn may require a fix for Y.
The first part is restoring the concept of storage to meta tensors. Previously, meta tensors had a nullptr storage (e.g., `meta_tensor.storage()` is an error.) As I was increasing the coverage of meta tensors, I started running into test cases (specifically memory overlap tests) that were failing because not having storage meant I couldn't check for memory overlap. After some discussion, we decided that it would make sense for meta tensors to model this as well (we already model strides, so getting accurate view information also seems useful). This PR does that by:
* Rewrite all of the factory functions in MetaTensor.cpp to use the generic versions (which are very carefully written to not actually poke at the data pointer, so everything works out). The key idea here is we give meta tensors a special allocator, MetaAllocator, which always returns a nullptr even if you ask for a nonzero number of bytes. resize_ is also made generic; the normal variant can be used directly rather than having to instruct it to avoid resizing storage
* Turn on memory overlap checking in TensorIterator even for meta tensors
* Although meta tensors now have storage, the concept of meta storage is NOT exposed to Python land (as it would imply I would have to codegen MetaFloatStorage, MetaDoubleStorage, etc. classes). So `x.storage()` still raises an error and I have a cludge in `__deepcopy__` to break storage sharing upon deep copy (this is wrong, but no tests exercise this at the moment).
The second part is adding more support for the most used functions in the test suite.
* Inplace operations have very simple meta functions. I added `fill_`, `zero_`, `random_`, `uniform_` and `normal_`. In the case of random, I take advantage of pbelevich's templates for defining random kernels, so that I can reuse the common scaffolding, and then just register a noop stub that actually does the RNG. (Look, another structured kernels tiny variant!)
* `copy_` is now implemented. Copying into a meta tensor is always OK, but copying out of a meta tensor raises an error (as we don't know what the "correct" data to copy out is in this case)
* `empty_strided` usage from structured kernels now is implemented (TBH, this could have been done as soon as `empty_strided` was added)
* Meta was missing in a few places in TensorOptions/DispatchKey utility functions, so I added them
* Autograd engine now correctly homes meta tensors with CPU tensors (they have -1 device index so CUDA queues wouldn't work anyway)
* `apply_`, `map_` and `map2_` are special cased to no-op on meta tensor self. These count as inplace operations too but they are implemented a little differently.
Getting more meta function support triggers a number of bugs in the test suite, which I then fix:
- Linear algebra functions sometimes don't report NotImplementedError because they get swallowed by catch all try blocks. This is tracked in https://github.com/pytorch/pytorch/issues/53739
- dlpack obviously doesn't work with meta tensors, I just disabled the test
Signed-off-by: Edward Z. Yang <ezyang@fb.com>
Differential Revision: D27036572
Test Plan: Imported from OSS
Reviewed By: agolynski, bdhirsh
Pulled By: ezyang
fbshipit-source-id: 7005ecf4feb92a643c37389fdfbd852dbf00ac78
Summary:
As per title.
Numerical stability increased by replacing inverses with solutions to systems of linear triangular equations.
Unblocks computing `torch.det` for FULL-rank inputs of complex dtypes via the LU decomposition once https://github.com/pytorch/pytorch/pull/48125/files is merged:
```
LU, pivots = input.lu()
P, L, U = torch.lu_unpack(LU, pivots)
det_input = P.det() * torch.prod(U.diagonal(0, -1, -2), dim=-1) # P is not differentiable, so we are fine even if it is complex.
```
Unfortunately, since `lu_backward` is implemented as `autograd.Function`, we cannot support both autograd and scripting at the moment.
The solution would be to move all the lu-related methods to ATen, see https://github.com/pytorch/pytorch/issues/53364.
Resolves https://github.com/pytorch/pytorch/issues/52891
TODOs:
* extend lu_backward for tall/wide matrices of full rank.
* move lu-related functionality to ATen and make it differentiable.
* handle rank-deficient inputs.
Pull Request resolved: https://github.com/pytorch/pytorch/pull/53994
Reviewed By: pbelevich
Differential Revision: D27188529
Pulled By: anjali411
fbshipit-source-id: 8e053b240413dbf074904dce01cd564583d1f064
Summary:
Pull Request resolved: https://github.com/pytorch/pytorch/pull/53424
Fixes https://github.com/pytorch/pytorch/issues/24807 and supersedes the stale https://github.com/pytorch/pytorch/issues/25093 (Cc Microsheep). If you now run the reproduction
```python
import torch
if __name__ == "__main__":
t = torch.tensor([1, 2, 3], dtype=torch.float64)
```
with `pylint==2.6.0`, you get the following output
```
test_pylint.py:1:0: C0114: Missing module docstring (missing-module-docstring)
test_pylint.py:4:8: E1101: Module 'torch' has no 'tensor' member; maybe 'Tensor'? (no-
member)
test_pylint.py:4:38: E1101: Module 'torch' has no 'float64' member (no-member)
```
Now `pylint` doesn't recognize `torch.tensor` at all, but it is promoted in the stub. Given that it also doesn't recognize `torch.float64`, I think fixing this is out of scope of this PR.
---
## TL;DR
This BC-breaking only for users that rely on unintended behavior. Since `torch/__init__.py` loaded `torch/tensor.py` it was populated in `sys.modules`. `torch/__init__.py` then overwrote `torch.tensor` with the actual function. With this `import torch.tensor as tensor` does not fail, but returns the function rather than the module. Users that rely on this import need to change it to `from torch import tensor`.
Reviewed By: zou3519
Differential Revision: D26223815
Pulled By: bdhirsh
fbshipit-source-id: 125b9ff3d276e84a645cd7521e8d6160b1ca1c21
