################################################################################################# # # Copyright (c) 2023 - 2025 NVIDIA CORPORATION & AFFILIATES. All rights reserved. # SPDX-License-Identifier: BSD-3-Clause # # Redistribution and use in source and binary forms, with or without # modification, are permitted provided that the following conditions are met: # # 1. Redistributions of source code must retain the above copyright notice, this # list of conditions and the following disclaimer. # # 2. Redistributions in binary form must reproduce the above copyright notice, # this list of conditions and the following disclaimer in the documentation # and/or other materials provided with the distribution. # # 3. Neither the name of the copyright holder nor the names of its # contributors may be used to endorse or promote products derived from # this software without specific prior written permission. # # THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" # AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE # IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE # DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE # FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL # DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR # SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER # CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, # OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE # OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. # ################################################################################################# """ Store node and implementations """ import ctypes from cutlass_library import DataType from cutlass.backend.c_types import tuple_factory from cutlass.backend.epilogue import dtype2ctype, to_ctype_value from cutlass.backend.evt.ir.node import NodeBase, ImplBase, NoOpImpl from cutlass.backend.evt.ir.tensor import Tensor from cutlass.backend.library import FloatRoundStyle, FunctionalOp class StoreImplBase(ImplBase): """ Base class for store node implementation """ reserved_names = ["D"] def __init__(self, node) -> None: super().__init__(node) self.element = node.element self.element_output = node.element_output self.stride = node.store_tensor.stride class StoreDImpl(StoreImplBase): """ Store D implementation """ @property def argument_type_d(self): stride_mnl = self.get_stride_mnl() tuple_type = tuple_factory(stride_mnl, self.stride_dtype) class _Argument(ctypes.Structure): _fields_ = [ ("ptr_D", ctypes.c_void_p), ("stride_D", tuple_type) ] def __init__(self, ptr: int) -> None: self.ptr_D = ptr self.stride_D = tuple_type(stride_mnl) return _Argument @staticmethod def match(node, problem_size: tuple): if node.name == "D" and node.store_tensor.shape == problem_size: return True return False class AuxStoreImpl(StoreImplBase): def __init__(self, node) -> None: super().__init__(node) self.round_style = FloatRoundStyle.ToNearest @property def argument_type(self): stride_mnl = self.get_stride_mnl() name = self.name tuple_type = tuple_factory(stride_mnl, self.stride_dtype) class _Argument(ctypes.Structure): _fields_ = [ ("ptr_aux", ctypes.c_void_p), ("dAux", tuple_type) ] def __init__(self, kwargs) -> None: ptr = kwargs[name] self.ptr_aux = ptr self.dAux = tuple_type(stride_mnl) return _Argument @staticmethod def match(node, problem_size: tuple): if not node.is_output: return False if node.name in StoreImplBase.reserved_names: return False strideMN = node.store_tensor.stride[-2:] if (strideMN[0] == 1 and strideMN[1] != 0 or strideMN[0] != 0 and strideMN[1] == 1 ): return True else: return False class ReductionImplBase(StoreImplBase): def __init__(self, node) -> None: super().__init__(node) self.element = node.store_tensor.element self.element_compute = node.element_compute self.reg_reduce_fn = self.node.reg_reduce_fn self.gmem_reduce_fn = self.node.gmem_reduce_fn self.round_style = node.round_style self.stride_dtype = "int" def get_reduce_identity(self): """ Return the reduction identity of the current reduce_fn """ maxes = { DataType.f32: (2 ** 31) - 1, DataType.f16: (2 ** 15), DataType.s32: (2 ** 31) - 1, DataType.s8: (2 ** 7) - 1 } mins = { DataType.f32: -maxes[DataType.f32], DataType.f16: -maxes[DataType.f16], DataType.s32: -maxes[DataType.s32], DataType.s8: -maxes[DataType.s8] } if self.reg_reduce_fn == FunctionalOp.Maximum: if self.element_compute not in mins: raise Exception(f"No min entry for data type {self.element_compute}") return to_ctype_value(mins[self.element_compute], self.element_compute) elif self.reg_reduce_fn == FunctionalOp.Multiplies: return to_ctype_value(1., self.element_compute) elif self.reg_reduce_fn == FunctionalOp.Minimum: if self.element_compute not in maxes: raise Exception(f"No max entry for data type {self.element_compute}") return to_ctype_value(maxes[self.element_compute], self.element_compute) else: return to_ctype_value(0., self.element_compute) @property def argument_type(self): self.get_reduce_identity() stride_mnl = self.get_stride_mnl() name = self.name tuple_type = tuple_factory(stride_mnl, self.stride_dtype) element_compute = self.element_compute reduce_identity = self.get_reduce_identity() class _Argument(ctypes.Structure): _fields_ = [ ("ptr", ctypes.c_void_p), ("reduce_identity", dtype2ctype[element_compute]), ("dMNL", tuple_type) ] def __init__(self, kwargs) -> None: ptr = kwargs[name] self.ptr = ptr self.reduce_identity = reduce_identity self.dMNL = tuple_type(stride_mnl) return _Argument class ColumnReductionImpl(ReductionImplBase): @staticmethod def match(node, problem_size: tuple): if not node.is_output: return False if node.name in StoreImplBase.reserved_names: return False strideMN = node.store_tensor.stride[-2:] if strideMN == (1, 0): return True else: return False class RowReductionImpl(ReductionImplBase): @staticmethod def match(node, problem_size: tuple): if not node.is_output: return False if node.name in StoreImplBase.reserved_names: return False strideMN = node.store_tensor.stride[-2:] if strideMN == (0, 1): return True else: return False class ScalarReductionImpl(ReductionImplBase): @staticmethod def match(node, problem_size: tuple): if not node.is_output: return False if node.name in StoreImplBase.reserved_names: return False strideMN = node.store_tensor.stride[-2:] if strideMN == (0, 0): return True else: return False class StoreNode(NodeBase): """ Store node """ possible_impls = [ AuxStoreImpl, RowReductionImpl, ColumnReductionImpl, ScalarReductionImpl, NoOpImpl, StoreDImpl ] def __init__(self, name: str) -> None: super().__init__(name) self.op = "store" self.is_output = False self._store_tensor = None @property def store_tensor(self) -> Tensor: """ Return the output tensor (concept: cutlass.backend.evt.ir.tensor) """ return self._store_tensor @store_tensor.setter def store_tensor(self, kwargs): """ Setting the tensor """ self._store_tensor = Tensor(**kwargs) def type_propagation(self, input_node_metas: 'list[NodeBase]'): """ The store nodes has element_output = element_input """ if self.is_output: if self.store_tensor is None: raise RuntimeError(f"The store tensor of node {self.name} is unknown.") self.element = self.store_tensor.element assert len(input_node_metas) == 1, "Store node can only have one input node" self.element_output = input_node_metas[0].element_output def broadcast_propagation(self, input_node_metas: 'list[NodeBase]'): super().broadcast_propagation(input_node_metas) if self.is_output: self._store_tensor.broadcast(self.tensor.shape)