LegacyBatchedTensorImpl.h

#pragma once

#include <bitset>
#include <utility>

#include <ATen/ArrayRef.h>
#include <ATen/SmallVector.h>
#include <ATen/Tensor.h>

namespace at {

// We assume this in a few other places in the codebase,
// but there isn't a centralized definition.
constexpr int64_t kVmapMaxTensorDims = 64;

// The valid vmap levels range from [0, 64). This effectively means that we
// support a maximum of 64 nested vmaps.
constexpr int64_t kVmapNumLevels = 64;

// Store this number of elements of BatchDims on the stack. Most people will
// probably use <= 5 nested vmaps, but adjust this number as necessary.
constexpr int64_t kBatchDimsStackSize = 5;

// a BatchDim represents a "private" dimension on a Tensor created inside of
// vmap. It is a (level, dim) tuple, with the `dim` indicating which dimension
// is being vmap'ed over and the `level` being an identifier for which vmap
// said dimension was created inside. The `dim` corresponds to a "physical
// dim" - it is a dimension index on the underlying physical tensor that is
// being vmapped over.
struct BatchDim {
  BatchDim(int64_t level, int64_t dim) : dim_(dim), level_(level) {}
  int64_t dim() const {
    return dim_;
  }
  int64_t level() const {
    return level_;
  }

 private:
  int64_t dim_;
  int64_t level_;
};

using BatchDims = SmallVector<BatchDim, kBatchDimsStackSize>;
using BatchDimsRef = ArrayRef<BatchDim>;

// A BatchedTensorImpl holds an underlying Tensor and a list of BatchDim
// NB: We use the term "BatchedTensor" to mean a Tensor that is backed with a
// BatchedTensorImpl.
//
// The batch dimensions are treated as being "private"; they are not
// user-visible. For example, in the following Tensor,
//    bt = BatchedTensorImpl(ones(2, 3, 5, 7), [(lvl=1, dim=0), (lvl=2, dim=1)])
// dimensions 0 and 1 are batch dimensions.
//
// bt.sizes() returns (5, 7); bt.sum(0) performs a reduction over the (public)
// dim 0, which is equivalent to dim 3 in the underlying ones(2, 3, 5, 7)
// tensor.
struct TORCH_API BatchedTensorImpl : public c10::TensorImpl {
  explicit BatchedTensorImpl(Tensor value, BatchDims bdims);

  // Returns a reference to BatchDims that represent which dimensions of this
  // tensor are private.
  BatchDimsRef bdims() const {
    return bdims_;
  }

  // BatchedTensorImpl wraps a Tensor
  const Tensor& value() const {
    return value_;
  };

  // Given a public dimension index, return the dimension index in the
  // underlying value() tensor. For example, if we have
  //    bt = BatchedTensorImpl(ones(2, 3, 5, 7), [(lvl=1, dim=0), (lvl=2,
  //    dim=2)])
  // bt.actualDim(0) -> 1
  // bt.actualDim(1) -> 3
  // bt.actualDim(2) -> Error
  int64_t actualDim(int64_t dim, bool wrap_dim = true) const;

  // We have to override this because we opted into CustomStrides
  IntArrayRef strides_custom() const override;
  // Override a bunch of methods inherited from TensorImpl to return error
  // messages.
  bool is_contiguous_custom(at::MemoryFormat memory_format) const override;
  void set_size(int64_t dim, int64_t new_size) override;
  void set_stride(int64_t dim, int64_t new_stride) override;
  void set_storage_offset(int64_t storage_offset) override;
#ifdef DEBUG
  bool has_storage() const override;
#endif

 private:
  // see NOTE: [BatchedTensorImpl levels invariant]
  void checkInvariants() const;
  const char* tensorimpl_type_name() const override;

  Tensor value_;

  // Note: [BatchedTensorImpl levels invariant]
  // There is an invariant that the BatchDims must be stored in increasing
  // `level` order. That is, for i < j, bdims_[i].level must be less than
  // bdims_[j].level.
  BatchDims bdims_;
};

// NB: We use the term "BatchedTensor" to mean a Tensor that is backed with a
// BatchedTensorImpl.
inline bool isBatchedTensor(const Tensor& tensor) {
  return tensor.unsafeGetTensorImpl()->key_set().has(DispatchKey::Batched);
}

// It is unsafe to call this on a Tensor that is not backed by a
// BatchedTensorImpl. Please use `maybeGetBatchedImpl` whenever possible.
inline BatchedTensorImpl* unsafeGetBatchedImpl(Tensor tensor) {
  return static_cast<BatchedTensorImpl*>(tensor.unsafeGetTensorImpl());
}

inline BatchedTensorImpl* maybeGetBatchedImpl(Tensor tensor) {
  if (!isBatchedTensor(tensor)) {
    return nullptr;
  }
  return unsafeGetBatchedImpl(std::move(tensor));
}

// Returns a bitset. If bit i is set, then that means dim i is a batchdim.
inline std::bitset<kVmapMaxTensorDims> createBatchDimBitset(
    BatchDimsRef bdims) {
  std::bitset<kVmapMaxTensorDims> is_bdim;
  for (const auto& bdim : bdims) {
    is_bdim.set(bdim.dim());
  }
  return is_bdim;
}

// Creates a bitset for all of the levels present in `bdims`
inline std::bitset<kVmapNumLevels> createVmapLevelsBitset(BatchDimsRef bdims) {
  std::bitset<kVmapNumLevels> result;
  for (const auto& bdim : bdims) {
    result.set(bdim.level());
  }
  return result;
}

inline std::ostream& operator<<(std::ostream& out, const BatchDim& bdim) {
  out << "(lvl=" << bdim.level() << ", dim=" << bdim.dim() << ")";
  return out;
}

// Use this to construct a BatchedTensor from a regular Tensor
TORCH_API Tensor makeBatched(const Tensor& tensor, BatchDims bdims);

// Adds a batch dim to `tensor`, returning a BatchedTensor
TORCH_API Tensor addBatchDim(const Tensor& tensor, int64_t level, int64_t dim);

// Checks if an inplace operation on self and other is "vmap compatible".
// See NOTE: [vmap-incompatible in-place operations] for the definition of this.
TORCH_API bool inplaceIsVmapCompatible(const Tensor& self, const Tensor& other);

} // namespace at