shape_determination_fns_.layout_preference_fn(
          device_tensor->shape(), device_tensor->dtype(), std::nullopt);
  Status status = [&]() -> Status {
    TF_ASSIGN_OR_RETURN(xla::Shape shape,
                        shape_determination_fns_.shape_representation_fn(
                            device_tensor->shape(), device_tensor->dtype(),
                            /*fast_mem=*/false, layout_preference));

  FunctionDef make_ref_float = FunctionDefHelper::Define(
      "RefFloatFn", {}, {"r:float"}, {},
      {{{"var"},
        "VariableV2",
        {},
        {{"dtype", DT_FLOAT}, {"shape", TensorShape({})}}},
       {{"r"}, "Identity", {"var"}, {{"T", DT_FLOAT}}}});
  *fdef_lib->add_function() = make_ref_float;
}

void AddRegularFunctionFunctionDef(FunctionDefLibrary* fdef_lib) {

  const tensorflow::Tensor& arg_tensor = cc_ctx->input(index);
  absl::Status cc_status;
  if (arg_tensor.dtype() != tensorflow::DT_RESOURCE) {
    cc_status = absl::InvalidArgumentError(
        absl::StrCat("Trying to obtain resource handle from Input[", index,
                     "], which is not type DT_RESOURCE."));
    status->status = cc_status;
    return nullptr;
  }
  const tensorflow::ResourceHandle& handle =

  TF_Status* status = TF_NewStatus();
  // Create the variable handle.
  TFE_Op* op = TFE_NewOp(ctx, "VarHandleOp", status);
  if (TF_GetCode(status) != TF_OK) return nullptr;
  TFE_OpSetAttrType(op, "dtype", TF_FLOAT);
  TFE_OpSetAttrShape(op, "shape", {}, 0, status);
  TFE_OpSetAttrString(op, "container", "localhost", 0);
  TFE_OpSetAttrString(op, "shared_name", "", 0);
  if (!device_name.empty()) {

  }
  strings::StrAppend(&ret, "}");
  return ret;
}

string PrintTensor(const TensorProto& tensor_proto) {
  Tensor t(tensor_proto.dtype());
  CHECK(t.FromProto(tensor_proto));
  const int64_t num_elts = t.NumElements();
  switch (t.dtype()) {
    case DT_FLOAT:
      return PrintArray(num_elts, t.flat<float>().data());
    case DT_DOUBLE:
      return PrintArray(num_elts, t.flat<double>().data());

  }

  // Derive the output types. The result type is derived by using the
  // attributes attched to the result type of the signature. The attribute
  // value should be either in the attribute argument list or the derived
  // attribute from the input tensors. All the result type
  // are unranked, and shape inference should be applied afterwards.
  SmallVector<Type, 4> output_types;

  }

  tensorflow::AbstractTensorInterface* t =
      tensorflow::unwrap(ctx)->CreateTensor(
          static_cast<tensorflow::DataType>(dtype), dimvec);

  if (t == nullptr) {
    status->status =
        tensorflow::errors::InvalidArgument("Unsupported dtype: ", dtype);
    return nullptr;
  }

  return new TF_Tensor{t};
}

TFE_TensorHandle* TFE_NewTensorHandleFromTensor(TFE_Context* ctx, TF_Tensor* t,

Status DefaultPaddedShapeFn(const Tensor& tensor, xla::Shape* shape) {
  const tensorflow::XlaTensor* xla_tensor =
      tensorflow::XlaTensor::FromTensor(&tensor);
  if (xla_tensor == nullptr) {
    return TensorShapeToXLAShape(tensor.dtype(), tensor.shape(), shape);
  }

  const xla::ShapedBuffer& shaped_buffer = xla_tensor->shaped_buffer();
  *shape = shaped_buffer.on_device_shape();
  return absl::OkStatus();
}

                         kSavedModelVariablesFilename);
        ImmediateTensorHandlePtr restored_output;
        TF_RETURN_IF_ERROR(internal::SingleRestore(
            context, variables_path_prefix, checkpoint_key, variable->dtype(),
            &restored_output));

        // Assign the restored tensor's value to the variable
        return variable->Assign(restored_output.get());
      }));

  return Status();
}

  CreateContext();

  std::vector<XlaCompiler::Argument> args(2);
  args[0].kind = XlaCompiler::Argument::kParameter;
  args[0].type = DT_INT32;
  args[0].shape = TensorShape({1, 3});
  args[1].kind = XlaCompiler::Argument::kParameter;
  args[1].type = DT_INT32;
  args[1].shape = TensorShape({1, 3});

  const XlaCompiler::CompilationResult* result;
  xla::PjRtLoadedExecutable* executable;