# Copyright (c) 2021 PaddlePaddle Authors. All Rights Reserved. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. import sys import numpy as np from . import unique_name from . import core import paddle MAX_INTEGER = 2**31 - 1 def is_list_tuple(index, contain_type): def _is_list_tuple(item): if not (isinstance(item, (list, tuple)) or type(item) == contain_type): return False if isinstance(item, (tuple, list)): for s in item: if not _is_list_tuple(s): return False return True if not isinstance(index, (tuple, list)): return False for s in index: if not _is_list_tuple(s): return False return True def is_one_dim_list(index, contain_type): if isinstance(index, list): for i in index: if not isinstance(i, contain_type): return False else: return False return True def get_list_index_shape(var_dims, index_dims): var_dims_size = len(var_dims) index_dims_size = len(index_dims) out_dims_size = var_dims_size - index_dims[0] + index_dims_size - 1 out_dims_shape = [1] * out_dims_size out_dims_shape[:index_dims_size - 1] = index_dims[1:] out_dims_shape[index_dims_size - 1:] = var_dims[index_dims[0]:] return out_dims_shape class SliceInfo: def __init__(self): self.pre_shape = None self.indexes = [] self.dtype = None def update(self, index): if is_list_tuple(index, int) or isinstance(index, ( paddle.fluid.Variable, np.ndarray)): # convert index to Tensor if not isinstance(index, paddle.fluid.Variable): index = paddle.assign(index) if self.dtype is None: self.dtype = index.dtype else: if index.dtype != self.dtype: raise IndexError( "Data type of Tensor/List index should be same. The current data type is {}, but the previous data type is {}.". format(index.dtype, self.dtype)) self.indexes.append(index) if self.pre_shape is None: self.pre_shape = index.shape else: if self.pre_shape != index.shape: # broadcast cur_shape = paddle.broadcast_shape(self.pre_shape, index.shape) for i in range(len(self.indexes)): self.indexes[i] = paddle.broadcast_to(self.indexes[i], cur_shape) self.pre_shape = self.indexes[-1].shape else: raise ValueError( "Index should be list/tuple of int or Tensor, but received {}.". format(index)) def shape_stride(self, shape): s = [1] * len(shape) for i in range(len(shape) - 2, -1, -1): s[i] = shape[i + 1] * s[i + 1] return s def numel(self, shape): return reduce(lambda x, y: x * y, shape) def get_offset_stride(self, tensor_shape): for index in self.indexes: if not isinstance(index, paddle.fluid.Variable): raise ValueError( "only support list/tensor index, but received {}.".format( type(index))) if len(self.indexes) <= len(tensor_shape) or len(self.indexes) == 1: shape = paddle.stack(self.indexes) axes = list(range(1, len(self.pre_shape) + 1)) + [0, ] else: raise ValueError( "too many indices for tensor: tensor is {}-dimensional, but {} were indexed". format(len(tensor_shape), self.pre_shape[0])) shape_transpose = paddle.transpose(shape, axes) return shape_transpose def get_item(self, tensor): shape_transpose = self.get_offset_stride(tensor.shape) index = paddle.assign(shape_transpose) return paddle.gather_nd(tensor, index) def set_item(self, tensor_origin, value): if not isinstance(value, paddle.fluid.Variable): value = paddle.assign(value) tensor_type = None if tensor_origin.dtype in [ core.VarDesc.VarType.FP32, core.VarDesc.VarType.FP64 ]: tensor = tensor_origin else: tensor_type = tensor_origin.dtype tensor = tensor_origin.astype(core.VarDesc.VarType.FP32) if value.dtype != tensor.dtype: value = value.astype(tensor.dtype) shape_transpose = self.get_offset_stride(tensor_origin.shape) index = paddle.assign(shape_transpose) gather_tensor_shape = get_list_index_shape( tensor.shape, [len(self.indexes), ] + list(self.indexes[-1].shape)) value_dims_bd = [1, ] * len(gather_tensor_shape) value_dims_bd[-len(value.shape):] = list(value.shape) for i in range(len(gather_tensor_shape)): if not (value_dims_bd[i] == gather_tensor_shape[i] or value_dims_bd[i] == 1): raise ValueError("{} can not broadcast into {}".format( value.shape, gather_tensor_shape)) value_broadcast = paddle.broadcast_to(value, gather_tensor_shape) value_1d = value_broadcast.reshape([-1] + gather_tensor_shape[len( index.shape) - 1:]) index_1d = index.reshape([-1, index.shape[-1]]) tensor_stride = paddle.assign( self.shape_stride(tensor.shape[:index.shape[-1]])) inds = [] for i in range(index_1d.shape[0]): temp = (index_1d[i] * tensor_stride).sum() inds.append(temp) index_1d = paddle.stack(inds).reshape([-1]) t_reshape = tensor.reshape([-1] + list(tensor.shape[index.shape[-1]:])) out = paddle.scatter(t_reshape, index_1d, value_1d) if tensor_type is not None: out = out.astype(tensor_type) tensor_origin[:] = out.reshape(tensor_origin.shape) return tensor_origin def replace_ellipsis(var, item): from .framework import Variable # Use slice(None) to replace Ellipsis. # For var, var.shape = [3,4,5,6] # # var[..., 1:2] -> var[:, :, :, 1:2] # var[0, ...] -> var[0] # var[0, ..., 1:2] -> var[0, :, :, 1:2] item = list(item) # Remove Variable to skip bug when counting Ellipsis item_remove_var = [ ele for ele in item if not isinstance(ele, (Variable, np.ndarray)) and ele is not None ] ell_count = item_remove_var.count(Ellipsis) if ell_count == 0: return item elif ell_count > 1: raise IndexError("An index can only have a single ellipsis ('...')") ell_idx = item.index(Ellipsis) if ell_idx == len(item) - 1: return item[:-1] else: item[ell_idx:ell_idx + 1] = [slice(None)] * ( len(var.shape) - len(item) + item.count(None) + 1) return item def replace_ndarray(item): new_item = [] for slice_item in item: if isinstance(slice_item, np.ndarray): new_item.append(paddle.assign(slice_item)) else: new_item.append(slice_item) return new_item def replace_none(item): new_item = [] none_axes = [] for i, slice_item in enumerate(item): if slice_item is None: none_axes.append(i) else: new_item.append(slice_item) return new_item, none_axes def is_integer_or_scalar_tensor(ele): from .framework import Variable if isinstance(ele, int): return True elif isinstance(ele, Variable): if len(ele.shape) == 1 and ele.shape[0] == 1: return True return False def deal_attrs(attrs, attr, attr_name, tensor_attr_name, inputs, infer_flags): from .framework import Variable from .layers import utils if utils._contain_var(attr): inputs[tensor_attr_name] = utils._convert_to_tensor_list( attr, dtype="int64") for i, dim in enumerate(attr): if isinstance(dim, Variable): attrs[attr_name].append(-1) infer_flags[i] = -1 else: attrs[attr_name].append(dim) else: attrs[attr_name] = attr def _getitem_impl_(var, item): """ Slice the variable. Args: item(int/slice/tuple) : the index. Returns: Sliced variable """ from .framework import default_main_program, Variable if isinstance(item, list): if not is_one_dim_list(item, int): item = tuple(item) if not isinstance(item, tuple): item = (item, ) decrease_axes = [] axes = [] starts = [] ends = [] steps = [] reverse_axes = [] use_strided_slice = False item = replace_ndarray(item) item = replace_ellipsis(var, item) item, none_axes = replace_none(item) slice_info = SliceInfo() for dim, slice_item in enumerate(item): if is_integer_or_scalar_tensor(slice_item): if isinstance(slice_item, int) and var.shape[dim] is not None and var.shape[ dim] >= 0 and slice_item >= var.shape[dim]: # For python, if users write a, b = var, the __getitem__ # method will iterate through 0, 1, 2 ... until __getitem__ # throws an IndexError, then stop. The var[0], var[1] will # be given to a, b respectively. If more values are given, # the unpack size would cause error. # # We raises IndexError here to support grammar like `a, b = var` raise IndexError( "slice_item %d at dim %d should be >= 0 and < var.shape[%d]: %d" % (slice_item, dim, dim, var.shape[dim])) decrease_axes.append(dim) start = slice_item step = 1 end = slice_item + 1 if slice_item != -1 else MAX_INTEGER elif isinstance(slice_item, slice): start = slice_item.start end = slice_item.stop step = slice_item.step if start is None and end is None and step is None: continue step = 1 if step is None else step if start is None: start = 0 if step > 0 else MAX_INTEGER if end is None: end = MAX_INTEGER if step > 0 else -1 elif isinstance(slice_item, list): all_bool = True if is_list_tuple(slice_item, int): slice_info.update(slice_item) continue for i in slice_item: if type(i) is int: all_bool = False elif not isinstance(i, bool): raise TypeError("Only support int or bool in index list.") if len(item) != 1: raise IndexError( "When index contains a list, its length must be 1, but received {}.". format(len(item))) new_slice_item = [] if all_bool: if len(slice_item) != var.shape[0]: raise IndexError( "The dimension of bool index doesn't match indexed array along "\ "dimension 0, the target dimension is {}, but received {}.". format(var.shape[0], len(slice_item))) for idx, ele in enumerate(slice_item): if ele is True: new_slice_item.append(idx) slice_item = new_slice_item else: for idx, ele in enumerate(slice_item): if type(ele) is int: new_slice_item.append(ele) elif ele is True: new_slice_item.append(1) else: new_slice_item.append(0) slice_item = new_slice_item from .layers import assign from ..tensor import index_select idx = assign(np.array(slice_item).astype("int32")) return index_select(var, index=idx, axis=0) elif isinstance(slice_item, (Variable)): if len(item) == 1: from ..tensor import index_select, gather_nd from .layers.nn import where if slice_item.dtype == paddle.bool: if len(slice_item.shape) > len(var.shape): raise IndexError( "The dims of bool index doesn't match indexed array, " "the dims of bool index except to be equal or less " "than {}, but received {}.".format( len(var.shape), len(slice_item.shape))) for i, dim_len in enumerate(slice_item.shape): if dim_len != var.shape[i]: raise IndexError( "The dimension of bool index doesn't match indexed array along "\ "dimension {}, the target dimension is {}, but received {}.". format(i, var.shape[i], dim_len)) bool_2_idx = where(slice_item == True) return gather_nd(var, bool_2_idx) else: if len(slice_item.shape) == 1: return index_select(var, index=slice_item, axis=0) else: slice_info.update(slice_item) continue else: slice_info.update(slice_item) continue else: raise IndexError( "Valid index accept int or slice or ellipsis or list, but received {}.". format(slice_item)) axes.append(dim) starts.append(start) ends.append(end) steps.append(step) use_strided_slice = True if step != 1 else use_strided_slice if slice_info.indexes: if len(slice_info.indexes) != len(item): raise IndexError( "Valid index accept int or slice or ellipsis or list, but received {}.". format(item)) return slice_info.get_item(var) inputs = {'Input': [var]} attrs = { 'axes': axes, 'starts': [], 'ends': [], 'decrease_axis': decrease_axes } if use_strided_slice: attrs['strides'] = [] infer_flags = [1] * len(axes) deal_attrs(attrs, starts, "starts", "StartsTensorList", inputs, infer_flags) deal_attrs(attrs, ends, "ends", "EndsTensorList", inputs, infer_flags) deal_attrs(attrs, steps, "strides", "StridesTensorList", inputs, infer_flags) attrs['infer_flags'] = infer_flags out = var if len(axes) > 0: target_block = default_main_program().current_block() op_type = "strided_slice" if use_strided_slice else "slice" slice_out_var = target_block.create_var( name=unique_name.generate_with_ignorable_key(var.name + "_" + op_type), dtype=var.dtype) target_block.append_op( type=op_type, inputs=inputs, outputs={'Out': [slice_out_var]}, attrs=attrs) out = slice_out_var if len(reverse_axes) > 0: from .layers.tensor import reverse out = reverse(out, axis=reverse_axes) # Deal with cases when all axes are decreased. # After slice, the shape of out is [1], which should have been [], but Paddle doesn't support scalar. # In order to ensure the correctness of the final shape of out, one dimension of out needs to be decreased. # For example: # # x.shape: (2,3,4) # out = x[0, 1, 1, None] # out.shape : (1) if len(decrease_axes) == len(var.shape): none_axes = none_axes[1:] if len(none_axes) > 0: # Deal with cases that decrease_axes is not empty # For example: # # x.shape: (2,3,4) # out = x[0, 0:2, None] # out.shape : (2, 1, 4) for idx, axis in enumerate(none_axes): l = len([i for i in decrease_axes if i < axis]) new_axis = axis - l none_axes[idx] = new_axis # Deal with cases when all axes are decreased. # After slice, the shape of out is [1], which should have been [], but Paddle doesn't support scalar. # In order to ensure the correctness of the final shape of out, one dimension of out needs to be decreased. # For example: # # x.shape: (2,3,4) # out = x[0, 1, 1, None] # out.shape : (1) from ..tensor import unsqueeze out = unsqueeze(out, axis=none_axes) return out def _setitem_impl_(var, item, value): from .framework import default_main_program, Variable inputs = {'Input': var} if isinstance(item, list): if not is_one_dim_list(item, int): item = tuple(item) # 1. Parse item if not isinstance(item, tuple): item = (item, ) decrease_axes = [] axes = [] starts = [] ends = [] steps = [] item = replace_ndarray(item) item = replace_ellipsis(var, item) item, none_axes = replace_none(item) slice_info = SliceInfo() dim = 0 for _, slice_item in enumerate(item): if is_integer_or_scalar_tensor(slice_item): decrease_axes.append(dim) start = slice_item end = slice_item + 1 if slice_item != -1 else MAX_INTEGER step = 1 elif isinstance(slice_item, slice): start = slice_item.start end = slice_item.stop step = slice_item.step if start is None and end is None and step is None: dim += 1 continue step = 1 if step is None else step if not isinstance(step, Variable) and step == 0: raise ValueError( "When assign a value to a paddle.Tensor, step can not be 0, " "but received step is {}.".format(step)) if isinstance(step, Variable) and (start is None or end is None): raise ValueError( "When assign a value to a paddle.Tensor, it's not supported that " "the start or end is None when the type of step is paddle.Tensor." ) if start is None: start = 0 if step > 0 else MAX_INTEGER if end is None: end = MAX_INTEGER if step > 0 else (0 - MAX_INTEGER) elif isinstance(slice_item, list): if is_list_tuple(slice_item, int): slice_info.update(slice_item) continue for i in slice_item: if not isinstance(i, bool): raise TypeError("Doesn't support {} in index list.".format( type(i))) if len(item) != 1: raise IndexError( "When index contains a bool list, its length must be 1, but received {}.". format(len(item))) from .layers import assign idx_tensor = assign(slice_item) return set_value_for_bool_tensor(var, idx_tensor, value) elif isinstance(slice_item, Variable): if slice_item.dtype == core.VarDesc.VarType.BOOL: if len(item) != 1: raise IndexError( "When index contains a bool tensor, its length must be 1, but received {}.". format(len(item))) return set_value_for_bool_tensor(var, slice_item, value) else: slice_info.update(slice_item) continue else: raise IndexError( "Valid index accept int, slice, ellipsis, None, list of bool, Variable, " "but received {}.".format(slice_item)) axes.append(dim) starts.append(start) ends.append(end) steps.append(step) dim += 1 if slice_info.indexes: if len(slice_info.indexes) != len(item): raise IndexError( "Valid index accept int or slice or ellipsis or list, but received {}.". format(item)) return slice_info.set_item(var, value) attrs = { 'axes': axes, 'starts': starts, 'ends': ends, 'steps': steps, 'decrease_axes': decrease_axes, 'none_axes': none_axes } from .layers import utils if utils._contain_var(starts): inputs['StartsTensorList'] = utils._convert_to_tensor_list(starts) del attrs['starts'] if utils._contain_var(ends): inputs['EndsTensorList'] = utils._convert_to_tensor_list(ends) del attrs['ends'] if utils._contain_var(steps): inputs['StepsTensorList'] = utils._convert_to_tensor_list(steps) del attrs['steps'] # 2. Parse value dtype = var.dtype attrs['dtype'] = dtype from .data_feeder import convert_dtype # 2.1 value is an integer of float if isinstance(value, (int, float)): value = np.array([value]).astype(convert_dtype(dtype)) # 2.2 value is a np.ndarray if isinstance(value, np.ndarray): shape = list(value.shape) if dtype == core.VarDesc.VarType.BOOL: value_name = "bool_values" values = [bool(v) for v in value.flat] elif dtype == core.VarDesc.VarType.FP32: value_name = "fp32_values" values = [float(v) for v in value.flat] elif dtype == core.VarDesc.VarType.FP64: value_name = "fp64_values" values = [float(v) for v in value.flat] elif dtype == core.VarDesc.VarType.INT32: value_name = "int32_values" values = [int(v) for v in value.flat] elif dtype == core.VarDesc.VarType.INT64: value_name = "int64_values" values = [int(v) for v in value.flat] else: raise TypeError( "When assign a numpy.ndarray, integer or float to a paddle.Tensor, " "the data type of the paddle.Tensor must be bool, float32, int32 or int64, but " "received %s." % convert_dtype(dtype)) attrs[value_name] = values attrs["shape"] = shape elif isinstance(value, Variable): inputs["ValueTensor"] = value else: raise TypeError( "Only support to assign an integer, float, numpy.ndarray or " "paddle.Tensor to a paddle.Tensor, but received {}".format( type(value))) cur_block = default_main_program().current_block() cur_block.append_op( type="set_value", inputs=inputs, outputs={'Out': var}, attrs=attrs) return var # the item is a tensor of bool def set_value_for_bool_tensor(var, item, value): # TODO(zyfncg): Now scatter_nd_add only support float32 and float64 tensor, # so in the current version we also only support float32 and float64 tensor, # this problem will be fixed in the future. if var.dtype != core.VarDesc.VarType.FP32 and var.dtype != core.VarDesc.VarType.FP64: raise TypeError("Only support float and double tensor for bool index, " "but received {}.".format(var.dtype)) if len(item.shape) > len(var.shape): raise IndexError("The dims of bool index doesn't match indexed array, " "the dims of bool index except to be equal or less " "than {}, but received {}.".format( len(var.shape), len(item.shape))) for i, dim_len in enumerate(item.shape): if dim_len != var.shape[i]: raise IndexError( "The dimension of bool index doesn't match indexed array along " "dimension {}, the target dimension is {}, but received {}.". format(i, var.shape[i], dim_len)) def idx_not_empty(var, item, value): from .framework import Variable from .layers import assign from .layers.nn import where from ..tensor import gather_nd, scatter_nd_add if not isinstance(value, Variable): value = assign(value).cast(var.dtype) idx = where(item) gather_val = gather_nd(var, idx) gather_val_new = value - gather_val out = scatter_nd_add(var, idx, gather_val_new) var[:] = out from .layers.control_flow import cond # If all the bool index is False, just do nothing cond(item.any(), lambda: idx_not_empty(var, item, value)) return var