aten/src/ATen/native/Copy.cpp - platform/external/pytorch - Git at Google

 #include <ATen/native/Copy.h>

 #include <ATen/ATen.h>
 #include <ATen/Dispatch.h>
 #include <ATen/NativeFunctions.h>
 #include <ATen/native/TensorIterator.h>
 #include <ATen/native/quantized/Copy.h>
 #include <ATen/quantized/Quantizer.h>
 #include <ATen/vulkan/Context.h>
 #include <ATen/MemoryOverlap.h>
 #include <ATen/NamedTensorUtils.h>
 #include <torch/library.h>

 namespace {

 using namespace at;

 bool copy_transpose_valid(const Tensor& self, const Tensor& src) {
   const int MIN_SZ = 60 * 60;
   return self.is_contiguous() && src.numel() != 0 && src.dim() == 2 &&
       src.stride(0) == 1 && src.stride(1) == src.size(0) &&
       self.scalar_type() == src.scalar_type() &&
       self.numel() >= MIN_SZ;
 }

 // special case copy where tensor is contiguous and src is a transposed matrix
 // This can be generalized to most copies, but it's trickier
 void copy_same_type_transpose_(Tensor& self, const Tensor& src) {
   int64_t BLOCK_SZ;
   if (self.scalar_type() == kByte) {
     BLOCK_SZ = 120;
   } else {
     BLOCK_SZ = 60;
   }
   Tensor buf = empty({BLOCK_SZ, BLOCK_SZ}, self.options());

   AT_DISPATCH_ALL_TYPES_AND3(kHalf, kBool, kBFloat16, self.scalar_type(), "copy_", [&] {
     scalar_t* sp = src.data_ptr<scalar_t>();
     scalar_t* rp = self.data_ptr<scalar_t>();
     scalar_t* bp = buf.data_ptr<scalar_t>();

     int64_t NR = src.size(0);
     int64_t NC = src.size(1);
     for (int64_t R = 0; R < NR; R += BLOCK_SZ) {
       for (int64_t C = 0; C < NC; C += BLOCK_SZ) {
         scalar_t* spo = sp + R + C * NR;
         scalar_t* rpo = rp + C + R * NC;

         int nr = std::min(NR - R, BLOCK_SZ);
         int nc = std::min(NC - C, BLOCK_SZ);

         // 1. copy columns from src to buf
         for (int c = 0; c < nc; c++) {
           memcpy(bp + c * BLOCK_SZ, spo + c * NR, nr * sizeof(scalar_t));
         }

         // 2. transpose buf in place
         int rc_max = std::max(nr, nc);
         int rc_min = std::min(nr, nc);
         for (int r = 0; r < rc_max; r++) {
           int end = std::min(r, rc_min);
           for (int c = 0; c < end; c++) {
             scalar_t tmp = bp[r + BLOCK_SZ * c];
             bp[r + BLOCK_SZ * c] = bp[r * BLOCK_SZ + c];
             bp[r * BLOCK_SZ + c] = tmp;
           }
         }

         // 3. copy rows from buf to dst
         for (int r = 0; r < nr; r++) {
           memcpy(rpo + r * NC, bp + r * BLOCK_SZ, nc * sizeof(scalar_t));
         }
       }
     }
   });
 }

 // Devices directly supported by this copy implementation. Other device types
 // (e.g. XLA) may be supported by overriding copy_ and _copy_from.
 bool is_supported_device(Device device) {
   DeviceType device_type = device.type();
   return device_type == kCPU || device_type == kCUDA || device_type == kHIP || device_type == kVulkan;
 }

 } // namespace

 namespace at {
 namespace native {

 static Tensor & copy_impl(Tensor & self, const Tensor & src, bool non_blocking) {
   // TODO: this should be handled during dispatch, but that's missing...
   TORCH_CHECK(self.defined(), "self is undefined");
   TORCH_CHECK(src.defined(), "src is undefined");

   if (self.is_sparse() && src.is_sparse()) {
     return at::copy_sparse_to_sparse_(self, src, non_blocking);
   } else if (self.is_sparse() || src.is_sparse()) {
     AT_ERROR("copy_() between dense and sparse Tensors is not implemented! Found self type = ",
              self.toString(), " and src type = ", src.toString());
   }

   if (self.is_same(src)) {
     return self;
   }

   // Re-dispatch copies when either src or self device not implemented here (e.g. XLA).
   // _copy_from has a proper device dispatch setup.
   // This includes:
   //   cpu_tensor.copy_(xla_tensor) => xla_tensor._copy_from(cpu_tensor)
   //   xla_tensor.copy_(cpu_tensor) => cpu_tensor._copy_from(xla_tensor)
   // Both the _copy_from calls above will be dispatched to XLA's _copy_from kernels.
   if (!is_supported_device(src.device()) || !is_supported_device(self.device())) {
     at::_copy_from(src, self, non_blocking);
     return self;
   }

   if (self.is_quantized() && !src.is_quantized()) {
     return quantized_copy_from_float_cpu_(self, src);
   }

   if (self.is_quantized() && src.is_quantized()) {
     TORCH_CHECK(self.qscheme() == src.qscheme(),
                 "Quantized Copy only works with same qscheme");
     TORCH_CHECK(self.scalar_type() == src.scalar_type());
     self.set_quantizer_(src.quantizer());
   }

   if (!self.is_quantized() && src.is_quantized()) {
     TORCH_CHECK(false, "Copying from quantized Tensor to non-quantized Tensor is not allowed, please use dequantize to get a float Tensor from a quantized Tensor");
   }

   if (self.device().type() == at::kVulkan || src.device().type() == at::kVulkan) {
     return at::vulkan::vulkan_copy_(self, src);
   }

   auto iter = TensorIteratorConfig()
     .add_output(self)
     .add_input(src)
     .resize_outputs(false)
     .check_all_same_dtype(false)
     .check_all_same_device(false)
     .build();

   if (iter.numel() == 0) {
     return self;
   }

   DeviceType device_type = iter.device_type(0);
   if (iter.device_type(1) == kCUDA) {
     device_type = kCUDA;
   } else if (iter.device_type(1) == kHIP) {
     device_type = kHIP;
   }

   // TODO: if we need to, we can also enable this path for quantized tensor
   if (device_type == kCPU && copy_transpose_valid(self, src) && !self.is_quantized()) {
     copy_same_type_transpose_(self, src);
     return self;
   }

   if(!self.is_complex() && src.is_complex()) {
     TORCH_WARN_ONCE("Casting complex values to real discards the imaginary part");
   }

   copy_stub(device_type, iter, non_blocking);
   return self;
 }

 Tensor& copy_(Tensor& self, const Tensor& src, bool non_blocking) {
   auto maybe_outnames = namedinference::compute_broadcast_outnames(self, src);
   {
     NoNamesGuard guard;
     copy_impl(self, src, non_blocking);
   }
   namedinference::propagate_names_if_nonempty(self, maybe_outnames);
   return self;
 }

 DEFINE_DISPATCH(copy_stub);

 } // namespace native
 } // namespace at
	#include <ATen/native/Copy.h>

	#include <ATen/ATen.h>
	#include <ATen/Dispatch.h>
	#include <ATen/NativeFunctions.h>
	#include <ATen/native/TensorIterator.h>
	#include <ATen/native/quantized/Copy.h>
	#include <ATen/quantized/Quantizer.h>
	#include <ATen/vulkan/Context.h>
	#include <ATen/MemoryOverlap.h>
	#include <ATen/NamedTensorUtils.h>
	#include <torch/library.h>

	namespace {

	using namespace at;

	bool copy_transpose_valid(const Tensor& self, const Tensor& src) {
	const int MIN_SZ = 60 * 60;
	return self.is_contiguous() && src.numel() != 0 && src.dim() == 2 &&
	src.stride(0) == 1 && src.stride(1) == src.size(0) &&
	self.scalar_type() == src.scalar_type() &&
	self.numel() >= MIN_SZ;
	}

	// special case copy where tensor is contiguous and src is a transposed matrix
	// This can be generalized to most copies, but it's trickier
	void copy_same_type_transpose_(Tensor& self, const Tensor& src) {
	int64_t BLOCK_SZ;
	if (self.scalar_type() == kByte) {
	BLOCK_SZ = 120;
	} else {
	BLOCK_SZ = 60;
	}
	Tensor buf = empty({BLOCK_SZ, BLOCK_SZ}, self.options());

	AT_DISPATCH_ALL_TYPES_AND3(kHalf, kBool, kBFloat16, self.scalar_type(), "copy_", [&] {
	scalar_t* sp = src.data_ptr<scalar_t>();
	scalar_t* rp = self.data_ptr<scalar_t>();
	scalar_t* bp = buf.data_ptr<scalar_t>();

	int64_t NR = src.size(0);
	int64_t NC = src.size(1);
	for (int64_t R = 0; R < NR; R += BLOCK_SZ) {
	for (int64_t C = 0; C < NC; C += BLOCK_SZ) {
	scalar_t* spo = sp + R + C * NR;
	scalar_t* rpo = rp + C + R * NC;

	int nr = std::min(NR - R, BLOCK_SZ);
	int nc = std::min(NC - C, BLOCK_SZ);

	// 1. copy columns from src to buf
	for (int c = 0; c < nc; c++) {
	memcpy(bp + c * BLOCK_SZ, spo + c * NR, nr * sizeof(scalar_t));
	}

	// 2. transpose buf in place
	int rc_max = std::max(nr, nc);
	int rc_min = std::min(nr, nc);
	for (int r = 0; r < rc_max; r++) {
	int end = std::min(r, rc_min);
	for (int c = 0; c < end; c++) {
	scalar_t tmp = bp[r + BLOCK_SZ * c];
	bp[r + BLOCK_SZ * c] = bp[r * BLOCK_SZ + c];
	bp[r * BLOCK_SZ + c] = tmp;
	}
	}

	// 3. copy rows from buf to dst
	for (int r = 0; r < nr; r++) {
	memcpy(rpo + r * NC, bp + r * BLOCK_SZ, nc * sizeof(scalar_t));
	}
	}
	}
	});
	}

	// Devices directly supported by this copy implementation. Other device types
	// (e.g. XLA) may be supported by overriding copy_ and _copy_from.
	bool is_supported_device(Device device) {
	DeviceType device_type = device.type();
	return device_type == kCPU \|\| device_type == kCUDA \|\| device_type == kHIP \|\| device_type == kVulkan;
	}

	} // namespace

	namespace at {
	namespace native {

	static Tensor & copy_impl(Tensor & self, const Tensor & src, bool non_blocking) {
	// TODO: this should be handled during dispatch, but that's missing...
	TORCH_CHECK(self.defined(), "self is undefined");
	TORCH_CHECK(src.defined(), "src is undefined");

	if (self.is_sparse() && src.is_sparse()) {
	return at::copy_sparse_to_sparse_(self, src, non_blocking);
	} else if (self.is_sparse() \|\| src.is_sparse()) {
	AT_ERROR("copy_() between dense and sparse Tensors is not implemented! Found self type = ",
	self.toString(), " and src type = ", src.toString());
	}

	if (self.is_same(src)) {
	return self;
	}

	// Re-dispatch copies when either src or self device not implemented here (e.g. XLA).
	// _copy_from has a proper device dispatch setup.
	// This includes:
	// cpu_tensor.copy_(xla_tensor) => xla_tensor._copy_from(cpu_tensor)
	// xla_tensor.copy_(cpu_tensor) => cpu_tensor._copy_from(xla_tensor)
	// Both the _copy_from calls above will be dispatched to XLA's _copy_from kernels.
	if (!is_supported_device(src.device()) \|\| !is_supported_device(self.device())) {
	at::_copy_from(src, self, non_blocking);
	return self;
	}

	if (self.is_quantized() && !src.is_quantized()) {
	return quantized_copy_from_float_cpu_(self, src);
	}

	if (self.is_quantized() && src.is_quantized()) {
	TORCH_CHECK(self.qscheme() == src.qscheme(),
	"Quantized Copy only works with same qscheme");
	TORCH_CHECK(self.scalar_type() == src.scalar_type());
	self.set_quantizer_(src.quantizer());
	}

	if (!self.is_quantized() && src.is_quantized()) {
	TORCH_CHECK(false, "Copying from quantized Tensor to non-quantized Tensor is not allowed, please use dequantize to get a float Tensor from a quantized Tensor");
	}

	if (self.device().type() == at::kVulkan \|\| src.device().type() == at::kVulkan) {
	return at::vulkan::vulkan_copy_(self, src);
	}

	auto iter = TensorIteratorConfig()
	.add_output(self)
	.add_input(src)
	.resize_outputs(false)
	.check_all_same_dtype(false)
	.check_all_same_device(false)
	.build();

	if (iter.numel() == 0) {
	return self;
	}

	DeviceType device_type = iter.device_type(0);
	if (iter.device_type(1) == kCUDA) {
	device_type = kCUDA;
	} else if (iter.device_type(1) == kHIP) {
	device_type = kHIP;
	}

	// TODO: if we need to, we can also enable this path for quantized tensor
	if (device_type == kCPU && copy_transpose_valid(self, src) && !self.is_quantized()) {
	copy_same_type_transpose_(self, src);
	return self;
	}

	if(!self.is_complex() && src.is_complex()) {
	TORCH_WARN_ONCE("Casting complex values to real discards the imaginary part");
	}

	copy_stub(device_type, iter, non_blocking);
	return self;
	}

	Tensor& copy_(Tensor& self, const Tensor& src, bool non_blocking) {
	auto maybe_outnames = namedinference::compute_broadcast_outnames(self, src);
	{
	NoNamesGuard guard;
	copy_impl(self, src, non_blocking);
	}
	namedinference::propagate_names_if_nonempty(self, maybe_outnames);
	return self;
	}

	DEFINE_DISPATCH(copy_stub);

	} // namespace native
	} // namespace at