1157 lines
41 KiB
Python
1157 lines
41 KiB
Python
# EDITING THIS FILE? READ THIS FIRST!
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# see Note [Edit Symbolic Files] in README.md
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# This file exports ONNX ops for opset 13
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import functools
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import torch
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import torch._C._onnx as _C_onnx
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from torch.onnx import (
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_constants,
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_type_utils,
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errors,
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symbolic_helper,
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symbolic_opset11 as opset11,
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symbolic_opset9 as opset9,
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utils,
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)
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from torch.onnx._internal import _beartype, jit_utils, registration
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_onnx_symbolic = functools.partial(registration.onnx_symbolic, opset=13)
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def _apply_params(*args, **kwargs):
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"""Returns a decorator that calls the decorated (higher-order) function with the given parameters."""
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def _apply(fn):
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return fn(*args, **kwargs)
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return _apply
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@_onnx_symbolic("aten::softmax")
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@symbolic_helper.parse_args("v", "i", "none")
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@_beartype.beartype
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def softmax(g: jit_utils.GraphContext, input, dim, dtype=None):
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softmax = g.op("Softmax", input, axis_i=dim)
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if dtype and dtype.node().kind() != "prim::Constant":
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parsed_dtype = symbolic_helper._get_const(dtype, "i", "dtype")
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softmax = g.op(
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"Cast", softmax, to_i=_type_utils.JitScalarType(parsed_dtype).onnx_type()
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)
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return softmax
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@_onnx_symbolic("aten::log_softmax")
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@symbolic_helper.parse_args("v", "i", "none")
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@_beartype.beartype
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def log_softmax(g: jit_utils.GraphContext, input, dim, dtype=None):
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return_op = g.op("LogSoftmax", input, axis_i=dim)
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if dtype and dtype.node().kind() != "prim::Constant":
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parsed_dtype = symbolic_helper._get_const(dtype, "i", "dtype")
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return_op = g.op(
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"Cast", return_op, to_i=_type_utils.JitScalarType(parsed_dtype).onnx_type()
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)
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return return_op
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@_onnx_symbolic("aten::frobenius_norm")
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@symbolic_helper.parse_args("v", "v", "i")
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@_beartype.beartype
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def frobenius_norm(g: jit_utils.GraphContext, self, dim=None, keepdim=False):
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dim_val = symbolic_helper._maybe_get_const(dim, "is")
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if not symbolic_helper._is_value(dim_val) and len(dim_val) == 0:
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return g.op("ReduceL2", self, keepdims_i=0)
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sqr = g.op("Mul", self, self)
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sumsqr = symbolic_helper._reducesum_helper(g, sqr, dim, keepdims_i=keepdim)
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return g.op("Sqrt", sumsqr)
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@_onnx_symbolic("aten::split")
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@symbolic_helper.parse_args("v", "v", "i", "i")
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@_beartype.beartype
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def split(g: jit_utils.GraphContext, self, split_size_or_sizes, dim, _outputs=None):
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if not symbolic_helper._is_split_static(split_size_or_sizes, _outputs):
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split_out = g.op("SplitToSequence", self, split_size_or_sizes, axis_i=dim)
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if _outputs is None:
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return split_out
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# Convert to multiple slice nodes iff number of splits and number of outputs are statically known.
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if (
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symbolic_helper._is_packed_list(split_size_or_sizes)
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and len(symbolic_helper._unpack_list(split_size_or_sizes)) == _outputs
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):
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split_sizes = [
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symbolic_helper._unsqueeze_helper(g, v, [0])
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for v in symbolic_helper._unpack_list(split_size_or_sizes)
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]
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start = g.op("Constant", value_t=torch.tensor([0], dtype=torch.long))
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axis = g.op("Constant", value_t=torch.tensor([dim], dtype=torch.long))
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res = []
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for i in range(_outputs):
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end = g.op(
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"Add", start, split_sizes[i]
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) # split_sizes is a list of same length as _outputs
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res.append(g.op("Slice", self, start, end, axis))
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start = end
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return res
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return [
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g.op(
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"SequenceAt",
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split_out,
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g.op("Constant", value_t=torch.tensor([i], dtype=torch.long)),
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)
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for i in range(_outputs)
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]
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split_val = symbolic_helper._node_get(split_size_or_sizes.node(), "value")
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if split_val.dim() > 0:
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return g.op("Split", self, split_size_or_sizes, axis_i=dim, outputs=_outputs)
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split_size = symbolic_helper._get_const(split_size_or_sizes, "i", "split_size")
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size = symbolic_helper._get_tensor_dim_size(self, dim)
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if size is None:
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if _outputs is not None:
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size = split_size * _outputs
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else:
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raise errors.SymbolicValueError(
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"Unknown dimension size not supported", self
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)
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splits = [split_size] * (size // split_size)
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leftover = size % split_size
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if leftover:
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splits.append(leftover)
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splits = g.op("Constant", value_t=torch.tensor(splits))
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return g.op("Split", self, splits, axis_i=dim, outputs=_outputs)
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@_onnx_symbolic("aten::split_with_sizes")
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@_beartype.beartype
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def split_with_sizes(g: jit_utils.GraphContext, self, split_sizes, dim, _outputs=None):
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return split(g, self, split_sizes, dim, _outputs)
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@_onnx_symbolic("aten::unsafe_split")
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@_beartype.beartype
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def unsafe_split(
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g: jit_utils.GraphContext, self, split_size_or_sizes, dim, _outputs=None
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):
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return split(g, self, split_size_or_sizes, dim, _outputs)
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@_onnx_symbolic("aten::unsafe_split_with_sizes")
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@_beartype.beartype
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def unsafe_split_with_sizes(
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g: jit_utils.GraphContext, self, split_sizes, dim, _outputs=None
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):
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return split_with_sizes(g, self, split_sizes, dim, _outputs)
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@_onnx_symbolic("aten::tensor_split")
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@symbolic_helper.parse_args("v", "v", "i", "i")
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@_beartype.beartype
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def tensor_split(
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g: jit_utils.GraphContext, self, indices_or_sections, dim, _outputs=None
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):
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axis = g.op("Constant", value_t=torch.tensor(dim, dtype=torch.long))
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axis = opset11.unsqueeze(g, axis, 0)
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const_1 = g.op("Constant", value_t=torch.tensor(1, dtype=torch.long))
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if symbolic_helper._is_split_static(indices_or_sections, _outputs):
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split_val = symbolic_helper._node_get(indices_or_sections.node(), "value")
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if split_val.dim() > 0:
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start = g.op("Constant", value_t=torch.tensor([0], dtype=torch.long))
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res = []
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assert _outputs is not None
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for i in range(_outputs - 1):
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end = g.op(
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"Gather",
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indices_or_sections,
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g.op("Constant", value_t=torch.tensor([i], dtype=torch.long)),
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axis_i=0,
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)
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res.append(g.op("Slice", self, start, end, axis))
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start = end
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end = symbolic_helper._size_helper(g, self, axis)
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res.append(g.op("Slice", self, start, end, axis))
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return res
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split_size = symbolic_helper._get_const(
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indices_or_sections, "i", "indices_or_sections"
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)
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size = symbolic_helper._get_tensor_dim_size(self, dim)
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if size is None:
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if _outputs is not None:
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size = split_size * _outputs
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else:
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raise errors.SymbolicValueError(
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"Unknown dimension size not supported", self
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)
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min_split_size = size // split_size
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num_splits_one_extra = size % split_size
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splits = num_splits_one_extra * [min_split_size + 1]
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leftover = (split_size - num_splits_one_extra) * [min_split_size]
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splits = g.op(
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"Constant", value_t=torch.tensor(splits + leftover, dtype=torch.long)
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)
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return g.op("Split", self, splits, axis_i=dim, outputs=_outputs)
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if (
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symbolic_helper._is_tensor(indices_or_sections)
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and symbolic_helper._get_tensor_rank(indices_or_sections) == 1
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):
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loop_len = symbolic_helper._size_helper(
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g, indices_or_sections, g.op("Constant", value_t=torch.tensor(0))
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)
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loop_len = opset11.unsqueeze(g, loop_len, 0)
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loop_condition = g.op("Cast", const_1, to_i=_C_onnx.TensorProtoDataType.BOOL)
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# To make the first slice in the below loop work,
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# we pad a zero to the first position so that it will be the initial start of slice.
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padding_0 = g.op("Constant", value_t=torch.tensor([0], dtype=torch.long))
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indices_or_sections = g.op("Concat", padding_0, indices_or_sections, axis_i=0)
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final_splits = g.op("SequenceEmpty")
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# Loop inputs
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loop, (loop_context,), _ = jit_utils.add_op_with_blocks(
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g, "Loop", loop_len, loop_condition, final_splits, outputs=1, n_blocks=1
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)
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loop_block = loop_context.block
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block_input_iter = utils._add_input_to_block(loop_block)
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cond = utils._add_input_to_block(loop_block)
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final_splits = utils._add_input_to_block(loop_block)
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start = loop_context.op(
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"Gather", indices_or_sections, block_input_iter, axis_i=0
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)
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end = loop_context.op(
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"Gather",
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indices_or_sections,
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loop_context.op("Add", block_input_iter, const_1),
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axis_i=0,
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)
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slice = loop_context.op("Slice", self, start, end, axis)
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final_splits = loop_context.op("SequenceInsert", final_splits, slice)
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# Loop outputs
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cond_out = loop_context.op("Identity", loop_condition)
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utils._add_output_to_block(loop_block, cond_out)
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utils._add_output_to_block(loop_block, final_splits)
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loop_out = loop.node().output()
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start = g.op(
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"Gather",
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indices_or_sections,
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g.op("Constant", value_t=torch.tensor(-1, dtype=torch.long)),
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axis_i=0,
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)
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start = opset11.unsqueeze(g, start, 0)
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end = symbolic_helper._size_helper(g, self, axis)
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last_slice = g.op("Slice", self, start, end, axis)
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return g.op("SequenceInsert", loop_out, last_slice)
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else: # scalar tensor
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dim_size = symbolic_helper._size_helper(g, self, axis)
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min_split_size = g.op("Div", dim_size, indices_or_sections)
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min_split_size_plus_1 = g.op(
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"Add",
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min_split_size,
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const_1,
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)
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num_splits_one_extra = g.op("Mod", dim_size, indices_or_sections)
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splits = g.op("Tile", min_split_size_plus_1, num_splits_one_extra)
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leftover = g.op(
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"Tile",
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min_split_size,
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g.op(
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"Sub",
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opset11.unsqueeze(g, indices_or_sections, 0),
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num_splits_one_extra,
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),
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)
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splits = g.op("Concat", splits, leftover, axis_i=0)
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if _outputs is None:
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return g.op("SplitToSequence", self, splits, axis_i=dim)
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return g.op("Split", self, splits, axis_i=dim, outputs=_outputs)
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@_onnx_symbolic("aten::unbind")
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@symbolic_helper.parse_args("v", "i", "i")
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@_beartype.beartype
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def unbind(g: jit_utils.GraphContext, self, dim=0, _outputs=None):
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if _outputs is None:
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return g.op(
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"SplitToSequence",
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self,
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g.op("Constant", value_t=torch.tensor(1, dtype=torch.long)),
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axis_i=dim,
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keepdims_i=0,
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)
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splits = g.op("Constant", value_t=torch.tensor([1] * _outputs))
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outputs = g.op("Split", self, splits, axis_i=dim, outputs=_outputs)
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outputs = [outputs] if _outputs == 1 else outputs
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squeezed_outputs = [
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g.op("Squeeze", out, g.op("Constant", value_t=torch.tensor([dim])))
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for out in outputs
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]
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return squeezed_outputs
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@_onnx_symbolic("aten::nonzero_numpy")
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# Emitted from `torch.nonzero(x, as_tuple=True)`
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@_beartype.beartype
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def nonzero_numpy(g: jit_utils.GraphContext, input, _outputs=None):
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return unbind(g, opset9.nonzero(g, input), 1, _outputs=_outputs)
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@_onnx_symbolic("aten::where")
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@symbolic_helper.parse_args("v", "v", "v", "i")
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@_beartype.beartype
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def where(g: jit_utils.GraphContext, condition, self=None, other=None, _outputs=None):
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# Assumes that torch.where's first argument takes only Bool and Byte tensors.
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if not symbolic_helper._is_bool(condition):
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condition = g.op("Cast", condition, to_i=_C_onnx.TensorProtoDataType.BOOL)
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if self is None:
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condition = opset9.nonzero(g, condition)
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return symbolic_helper._unbind_helper(
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g, condition, g.op("Constant", value_t=torch.tensor(1)), _outputs
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)
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return g.op("Where", condition, self, other)
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@_onnx_symbolic("aten::fake_quantize_per_channel_affine")
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@symbolic_helper.parse_args("v", "v", "v", "i", "i", "i")
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@_beartype.beartype
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def fake_quantize_per_channel_affine(
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g: jit_utils.GraphContext,
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inputs,
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scale,
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zero_point,
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axis,
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quant_min=-128,
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quant_max=127,
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):
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# NOTE: (0, 127) is allowed as special case. PyTorch restricts activations to be in the range (0, 127).
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# https://github.com/pytorch/pytorch/blob/b34b192d6b97325c9f78e5995c48c8498ede34bd/torch/ao/quantization/observer.py#L1422
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if (quant_min, quant_max) not in [(0, 255), (-128, 127), (0, 127)]:
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raise errors.SymbolicValueError(
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"For (quant_min, quant_max), ONNX allows only (0, 127), (0, 255) and (-128, 127). "
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f"Got ({quant_min}, {quant_max})",
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inputs,
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)
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# ONNX defines zero_point to be int8 or uint8
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if quant_min == 0:
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zero_point = g.op("Cast", zero_point, to_i=_C_onnx.TensorProtoDataType.UINT8)
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else:
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zero_point = g.op("Cast", zero_point, to_i=_C_onnx.TensorProtoDataType.INT8)
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quantized = g.op("QuantizeLinear", inputs, scale, zero_point, axis_i=axis)
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if (quant_min, quant_max) == (0, 127):
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quantized = g.op(
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"Clip",
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quantized,
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opset9.unused(g),
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g.op("Constant", value_t=torch.tensor(127, dtype=torch.uint8)),
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)
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return g.op("DequantizeLinear", quantized, scale, zero_point, axis_i=axis)
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@_onnx_symbolic("aten::fake_quantize_per_tensor_affine")
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@symbolic_helper.parse_args("v", "v", "v", "i", "i")
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@_beartype.beartype
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def fake_quantize_per_tensor_affine(
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g: jit_utils.GraphContext,
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inputs,
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scale,
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zero_point,
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quant_min=-128,
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quant_max=127,
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):
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# NOTE: (0, 127) is allowed as special case. PyTorch restricts activations to be in the range (0, 127).
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# https://github.com/pytorch/pytorch/blob/b34b192d6b97325c9f78e5995c48c8498ede34bd/torch/ao/quantization/observer.py#L1422
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if (quant_min, quant_max) not in [(0, 255), (-128, 127), (0, 127)]:
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raise errors.SymbolicValueError(
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"For (quant_min, quant_max), ONNX allows only (0, 127), (0, 255) and (-128, 127). "
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f"Got ({quant_min}, {quant_max})",
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inputs,
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)
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if quant_min == 0:
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zero_point = g.op("Cast", zero_point, to_i=_C_onnx.TensorProtoDataType.UINT8)
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else:
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zero_point = g.op("Cast", zero_point, to_i=_C_onnx.TensorProtoDataType.INT8)
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if (
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_type_utils.JitScalarType.from_value(scale, _type_utils.JitScalarType.UNDEFINED)
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!= _type_utils.JitScalarType.FLOAT
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):
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scale = g.op("Cast", scale, to_i=_C_onnx.TensorProtoDataType.FLOAT)
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quantized = g.op("QuantizeLinear", inputs, scale, zero_point)
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if (quant_min, quant_max) == (0, 127):
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quantized = g.op(
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"Clip",
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quantized,
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opset9.unused(g),
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g.op("Constant", value_t=torch.tensor(127, dtype=torch.uint8)),
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)
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return g.op("DequantizeLinear", quantized, scale, zero_point)
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@_beartype.beartype
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def _reduce_op_symbolic(onnx_op_name):
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@_beartype.beartype
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def symbolic(g, self, dim=None, keepdim=None):
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self = opset9._maybe_cast_reduce_op_input(g, self)
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if dim is None:
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# all-reduce path
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return symbolic_helper._handle_reduce_dim_none(g, self, onnx_op_name)
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else:
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keepdim = symbolic_helper._get_const(keepdim, "i", "keepdim")
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return g.op(onnx_op_name, self, dim, keepdims_i=keepdim)
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return symbolic
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@_onnx_symbolic(
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"aten::sum",
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decorate=[_apply_params("ReduceSum", "sum")],
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)
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@_beartype.beartype
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def _reduce_with_dtype(onnx_op, name):
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symbolic = _reduce_op_symbolic(onnx_op)
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|
|
@opset9.overload_by_arg_count
|
|
@_beartype.beartype
|
|
def reduce(g, *args, **kwargs):
|
|
@symbolic_helper.parse_args("v", "none")
|
|
@_beartype.beartype
|
|
def reduce_nodim(g, self, dtype):
|
|
dtype_onnx = None
|
|
if dtype.node().kind() == "onnx::Constant":
|
|
dtype = symbolic_helper._get_const(dtype, "i", "dtype")
|
|
dtype_onnx = _type_utils.JitScalarType(dtype).onnx_type()
|
|
self = g.op("Cast", self, to_i=dtype_onnx)
|
|
elif dtype.node().kind() != "prim::Constant":
|
|
return symbolic_helper._unimplemented(name, "dtype", dtype)
|
|
result = symbolic(g, self)
|
|
if dtype_onnx is not None:
|
|
result_dtype_onnx = _type_utils.JitScalarType.from_value(
|
|
result
|
|
).onnx_type()
|
|
if result_dtype_onnx != dtype_onnx:
|
|
result = g.op("Cast", result, to_i=dtype_onnx)
|
|
return result
|
|
|
|
@symbolic_helper.parse_args("v", "v", "i", "none")
|
|
@_beartype.beartype
|
|
def reduce_dim(g, self, dim, keepdim, dtype):
|
|
dtype_onnx = None
|
|
if dtype.node().kind() == "onnx::Constant":
|
|
dtype = symbolic_helper._get_const(dtype, "i", "dtype")
|
|
dtype_onnx = _type_utils.JitScalarType(dtype).onnx_type()
|
|
self = g.op("Cast", self, to_i=dtype_onnx)
|
|
elif dtype.node().kind() != "prim::Constant":
|
|
return symbolic_helper._unimplemented(name, "dtype", dtype)
|
|
result = symbolic(g, self, dim, keepdim)
|
|
if dtype_onnx is not None:
|
|
result_dtype_onnx = _type_utils.JitScalarType.from_value(
|
|
result
|
|
).onnx_type()
|
|
if result_dtype_onnx != dtype_onnx:
|
|
result = g.op("Cast", result, to_i=dtype_onnx)
|
|
return result
|
|
|
|
return reduce_nodim, reduce_dim
|
|
|
|
return reduce
|
|
|
|
|
|
# Ported from
|
|
# https://github.com/microsoft/onnxscript/blob/6b1b81700b4523f31d8c6d3321e5d8ef5d42b764/onnxscript/function_libs/torch_aten/ops/core.py#L6097
|
|
# NOTE: Supporting aten::unflatten before opset13 needs helper function to adjust ONNX op changes in Concat, Slice, ...
|
|
@_onnx_symbolic("aten::unflatten")
|
|
@_beartype.beartype
|
|
def unflatten(g: jit_utils.GraphContext, input, dim, unflattened_size):
|
|
input_dim = symbolic_helper._get_tensor_rank(input)
|
|
if input_dim is None:
|
|
return symbolic_helper._unimplemented(
|
|
"dim",
|
|
"ONNX and PyTorch use different strategies to split the input. "
|
|
"Input rank must be known at export time.",
|
|
)
|
|
|
|
# dim could be negative
|
|
input_dim = g.op("Constant", value_t=torch.tensor([input_dim], dtype=torch.int64))
|
|
dim = g.op("Add", input_dim, dim)
|
|
dim = g.op("Mod", dim, input_dim)
|
|
|
|
input_size = g.op("Shape", input)
|
|
|
|
head_start_idx = g.op("Constant", value_t=torch.tensor([0], dtype=torch.int64))
|
|
head_end_idx = g.op(
|
|
"Reshape", dim, g.op("Constant", value_t=torch.tensor([1], dtype=torch.int64))
|
|
)
|
|
head_part_rank = g.op("Slice", input_size, head_start_idx, head_end_idx)
|
|
|
|
dim_plus_one = g.op(
|
|
"Add", dim, g.op("Constant", value_t=torch.tensor([1], dtype=torch.int64))
|
|
)
|
|
tail_start_idx = g.op(
|
|
"Reshape",
|
|
dim_plus_one,
|
|
g.op("Constant", value_t=torch.tensor([1], dtype=torch.int64)),
|
|
)
|
|
tail_end_idx = g.op(
|
|
"Constant", value_t=torch.tensor([_constants.INT64_MAX], dtype=torch.int64)
|
|
)
|
|
tail_part_rank = g.op("Slice", input_size, tail_start_idx, tail_end_idx)
|
|
|
|
final_shape = g.op(
|
|
"Concat", head_part_rank, unflattened_size, tail_part_rank, axis_i=0
|
|
)
|
|
|
|
return symbolic_helper._reshape_helper(g, input, final_shape)
|
|
|
|
|
|
@_onnx_symbolic("aten::unsafe_chunk")
|
|
@symbolic_helper.parse_args("v", "i", "i", "i")
|
|
@_beartype.beartype
|
|
def unsafe_chunk(g: jit_utils.GraphContext, self, chunks, dim, _outputs=None):
|
|
if _outputs is None:
|
|
return g.op(
|
|
"SplitToSequence",
|
|
self,
|
|
g.op("Constant", value_t=torch.tensor(1, dtype=torch.long)),
|
|
axis_i=dim,
|
|
keepdims_i=0,
|
|
)
|
|
|
|
size = symbolic_helper._get_tensor_dim_size(self, dim)
|
|
if size is None:
|
|
return symbolic_helper._unimplemented("unsafe_chunk", "unknown dimension size")
|
|
split_size = (size + chunks - 1) // chunks
|
|
splits = [split_size] * (size // split_size)
|
|
leftover = size % split_size
|
|
if leftover:
|
|
splits.append(leftover)
|
|
|
|
# TODO: So far we don"t have a module using this method. We"ll keep
|
|
# this as a constant unless we see a request of dynamics in any
|
|
# user's modules.
|
|
splits = g.op("Constant", value_t=torch.tensor(splits, dtype=torch.long))
|
|
return g.op("Split", self, splits, axis_i=dim, outputs=_outputs)
|
|
|
|
|
|
@_onnx_symbolic("aten::tile")
|
|
@_beartype.beartype
|
|
def tile(g: jit_utils.GraphContext, self, dims):
|
|
self_shape = g.op("Shape", self)
|
|
self_rank = g.op("Size", self_shape)
|
|
dims_rank = g.op("Size", dims)
|
|
diff = g.op("Sub", self_rank, dims_rank)
|
|
const_zero = g.op("Constant", value_t=torch.tensor([0]))
|
|
|
|
# 1. If dims is shorter than self.shape pad dims with 1
|
|
dims_shorter_than_self_shape = g.op("Greater", diff, const_zero)
|
|
(
|
|
if_op_greater,
|
|
(if_context_greater, else_context_greater),
|
|
_,
|
|
) = jit_utils.add_op_with_blocks(
|
|
g, "If", dims_shorter_than_self_shape, n_blocks=2, outputs=1
|
|
)
|
|
const_one = if_context_greater.op("Constant", value_t=torch.LongTensor([1]))
|
|
diff_1d_greater = if_context_greater.op("Reshape", diff, const_one)
|
|
exapnd_ones_greater = if_context_greater.op("Expand", const_one, diff_1d_greater)
|
|
dims_ = if_context_greater.op("Concat", exapnd_ones_greater, dims, axis_i=0)
|
|
utils._add_output_to_block(if_context_greater.block, dims_)
|
|
identity_dim = else_context_greater.op("Identity", dims)
|
|
utils._add_output_to_block(else_context_greater.block, identity_dim)
|
|
dims_final = if_op_greater.node().output()
|
|
|
|
# 2. If dims is longer than self.shape pad self.shape with 1
|
|
dims_longer_than_self_shape = g.op("Less", diff, const_zero)
|
|
(
|
|
if_op_less,
|
|
(if_context_less, else_context_less),
|
|
_,
|
|
) = jit_utils.add_op_with_blocks(
|
|
g, "If", dims_longer_than_self_shape, n_blocks=2, outputs=1
|
|
)
|
|
const_one = if_context_less.op("Constant", value_t=torch.LongTensor([1]))
|
|
diff_1d_less = if_context_less.op(
|
|
"Reshape",
|
|
if_context_less.op("Abs", diff),
|
|
const_one,
|
|
)
|
|
exapnd_ones_less = if_context_less.op("Expand", const_one, diff_1d_less)
|
|
self_final_shape = if_context_less.op(
|
|
"Concat", exapnd_ones_less, self_shape, axis_i=0
|
|
)
|
|
self_ = if_context_less.op("Reshape", self, self_final_shape)
|
|
utils._add_output_to_block(if_context_less.block, self_)
|
|
identity_self = else_context_less.op("Identity", self)
|
|
utils._add_output_to_block(else_context_less.block, identity_self)
|
|
self_final = if_op_less.node().output()
|
|
|
|
dims_final = g.op("Cast", dims_final, to_i=_C_onnx.TensorProtoDataType.INT64)
|
|
return g.op("Tile", self_final, dims_final)
|
|
|
|
|
|
@_onnx_symbolic("aten::repeat_interleave")
|
|
@_beartype.beartype
|
|
def repeat_interleave(
|
|
g: jit_utils.GraphContext, self, repeats, dim=None, output_size=None
|
|
):
|
|
repeats_dim = symbolic_helper._get_tensor_rank(repeats)
|
|
repeats_sizes = symbolic_helper._get_tensor_sizes(repeats)
|
|
input_sizes = symbolic_helper._get_tensor_sizes(self)
|
|
if repeats_dim is None:
|
|
raise errors.SymbolicValueError(
|
|
"Unsupported: ONNX export of repeat_interleave for unknown repeats rank.",
|
|
self,
|
|
)
|
|
if repeats_sizes is None:
|
|
raise errors.SymbolicValueError(
|
|
"Unsupported: ONNX export of repeat_interleave for unknown repeats size.",
|
|
self,
|
|
)
|
|
if input_sizes is None:
|
|
raise errors.SymbolicValueError(
|
|
"Unsupported: ONNX export of repeat_interleave for unknown input size.",
|
|
self,
|
|
)
|
|
|
|
final_dim = dim
|
|
# if dim is None flatten
|
|
# By default, use the flattened input array, and return a flat output array
|
|
if symbolic_helper._is_none(dim):
|
|
self = symbolic_helper._reshape_helper(
|
|
g, self, g.op("Constant", value_t=torch.tensor([-1]))
|
|
)
|
|
dim = torch.tensor(0, dtype=torch.int64)
|
|
else:
|
|
dim = symbolic_helper._maybe_get_scalar(dim)
|
|
|
|
# Handle cases where dim is negative
|
|
if dim < 0:
|
|
dim += len(input_sizes)
|
|
|
|
output_sizes = input_sizes.copy()
|
|
for idx, input_size in enumerate(input_sizes):
|
|
if input_size is None:
|
|
output_sizes[idx], input_sizes[idx] = 0, -1
|
|
|
|
# Check if all indices should be repeated the same number of times.
|
|
if repeats_dim == 0 or (repeats_dim == 1 and repeats_sizes[0] == 1):
|
|
return symbolic_helper._repeat_interleave_single_value_repeat_helper(
|
|
g, self, repeats, dim
|
|
)
|
|
|
|
cond_dynamic_repeats = repeats_dim == 1 and repeats_sizes[0] is None
|
|
# If input size is dynamic or repeats vector is dynamic
|
|
if output_sizes[dim] == 0 or cond_dynamic_repeats:
|
|
reps = symbolic_helper._size_helper(g, self, dim)
|
|
reps = opset11.unsqueeze(g, reps, 0)
|
|
|
|
# Check if repeats is dynamic
|
|
# As repeats is dynamic, we use a where node as a substitute for the if statement
|
|
# If repests_dim = 1, expand repeats otherwise use original tensor
|
|
if cond_dynamic_repeats:
|
|
repeat_dim = symbolic_helper._size_helper(
|
|
g, repeats, g.op("Constant", value_t=torch.LongTensor([0]))
|
|
)
|
|
repeat_cond = g.op(
|
|
"Equal", repeat_dim, g.op("Constant", value_t=torch.LongTensor([1]))
|
|
)
|
|
repeats = where(g, repeat_cond, g.op("Expand", repeats, reps), repeats)
|
|
# There are cases when the repeats are 1-d tensor with multiple repeats, but dim
|
|
# provided along one of the dynamic axes provided. A simple example would be
|
|
# input.shape -> [1, 1, *] where * represents the dynamic axes, and dim = 2
|
|
# Now, repeat interleaving can be performed in pytorch when the value of * matches
|
|
# with the number of elements in repeat, for example if * -> 2, number of repeats
|
|
# should be 2 as well.
|
|
else:
|
|
return opset9.repeat_interleave(g, self, repeats, final_dim)
|
|
|
|
reps_like = g.op(
|
|
"ConstantOfShape",
|
|
g.op("Shape", repeats),
|
|
value_t=torch.tensor([1], dtype=torch.long),
|
|
)
|
|
r_splits = split(g, repeats, reps_like, 0)
|
|
i_splits = split(g, self, reps_like, dim)
|
|
|
|
output_sizes[dim], input_sizes[dim] = -1, 1
|
|
|
|
# Create a loop to iterate over each value along the dimension
|
|
# and perform individual interleaving using the repeats tensor
|
|
# Loop is of the following pattern
|
|
# input (trip_count, cond)
|
|
# int trip_count = ...;
|
|
# bool cond = ...;
|
|
# for (int i=0; i < trip_count && cond; ++i) {
|
|
# cond = ...;
|
|
# }
|
|
|
|
# Loop conditions
|
|
loop_condition = g.op("Constant", value_t=torch.tensor(1))
|
|
loop_condition = g.op("Cast", loop_condition, to_i=_C_onnx.TensorProtoDataType.BOOL)
|
|
loop_len = reps
|
|
|
|
# Create an empty sequence to store final expansions
|
|
final_splits = g.op("SequenceEmpty")
|
|
|
|
# Loop inputs
|
|
loop, (loop_context,), _ = jit_utils.add_op_with_blocks(
|
|
g, "Loop", loop_len, loop_condition, final_splits, n_blocks=1
|
|
)
|
|
|
|
loop_block = loop_context.block
|
|
block_input_iter = utils._add_input_to_block(loop_block)
|
|
cond = utils._add_input_to_block(loop_block)
|
|
final_splits = utils._add_input_to_block(loop_block)
|
|
|
|
r_split = loop_context.op("SequenceAt", r_splits, block_input_iter)
|
|
i_split = loop_context.op("SequenceAt", i_splits, block_input_iter)
|
|
|
|
i_split = opset11.unsqueeze(loop_context, i_split, dim + 1)
|
|
r_concat = [
|
|
loop_context.op("Constant", value_t=torch.LongTensor(input_sizes[: dim + 1])),
|
|
r_split,
|
|
loop_context.op("Constant", value_t=torch.LongTensor(input_sizes[dim + 1 :])),
|
|
]
|
|
r_concat = loop_context.op("Concat", *r_concat, axis_i=0)
|
|
i_split = opset9.expand(loop_context, i_split, r_concat, None)
|
|
i_split = symbolic_helper._reshape_helper(
|
|
loop_context, i_split, g.op("Constant", value_t=torch.LongTensor(output_sizes))
|
|
)
|
|
final_splits = loop_context.op("SequenceInsert", final_splits, i_split)
|
|
|
|
# Loop outputs
|
|
cond_out = loop_context.op(
|
|
"Cast", loop_condition, to_i=_C_onnx.TensorProtoDataType.BOOL
|
|
)
|
|
utils._add_output_to_block(loop_block, cond_out)
|
|
utils._add_output_to_block(loop_block, final_splits)
|
|
|
|
loop_out = loop.node().output()
|
|
loop_out = g.op("ConcatFromSequence", loop_out, axis_i=dim)
|
|
return loop_out
|
|
|
|
|
|
@_onnx_symbolic("aten::diagonal")
|
|
@symbolic_helper.parse_args("v", "i", "i", "i")
|
|
@_beartype.beartype
|
|
def diagonal(g: jit_utils.GraphContext, self, offset, dim1, dim2):
|
|
rank = symbolic_helper._get_tensor_rank(self)
|
|
# Replace negative indexing when rank is known
|
|
if rank is not None:
|
|
dim1 = dim1 if dim1 >= 0 else dim1 + rank
|
|
dim2 = dim2 if dim2 >= 0 else dim2 + rank
|
|
|
|
dim1_size = opset9.size(
|
|
g, self, dim=g.op("Constant", value_t=torch.LongTensor([dim1]))
|
|
)
|
|
dim2_size = opset9.size(
|
|
g, self, dim=g.op("Constant", value_t=torch.LongTensor([dim2]))
|
|
)
|
|
# Create appropriate mask
|
|
mask_shape = g.op("Concat", dim1_size, dim2_size, axis_i=0)
|
|
mask = opset9.zeros(g, mask_shape, None, None, None)
|
|
mask = g.op("EyeLike", mask, k_i=offset)
|
|
# dim1 and dim2 appended as a dimension at the end of the shape
|
|
|
|
if rank is not None:
|
|
axes = list(range(rank))
|
|
axes.remove(dim1)
|
|
axes.remove(dim2)
|
|
self = g.op("Transpose", self, perm_i=axes + [dim1, dim2])
|
|
else:
|
|
return symbolic_helper._unimplemented("diagonal", "unknown input rank")
|
|
|
|
# Multiply input and mask to calculate values along diagonal
|
|
# The mask consists of one values where diagonal values are to be calculated
|
|
# For example:
|
|
# [[1.1, 1.2, 1.3], * [[1, 0, 0] = [[1.1, 0, 0],
|
|
# [2.1, 2.2, 2.3], [0, 1, 0] [0, 2.2, 0],
|
|
# [3.1, 3.2, 3.3]] [0, 0, 1]] [0, 0, 3.3]]
|
|
result = g.op("Mul", self, mask)
|
|
result = symbolic_helper._reducesum_helper(g, result, axes_i=[-1], keepdims_i=0)
|
|
|
|
# Calculate gather indices based on offset and dims
|
|
# If offset is greater than zero, set offset to zero as this aids in
|
|
# calculation of selection window
|
|
offset_op = g.op("Constant", value_t=torch.LongTensor([offset]))
|
|
if offset >= 0:
|
|
diag_size = g.op(
|
|
"Max",
|
|
g.op("Min", dim1_size, g.op("Sub", dim2_size, offset_op)),
|
|
g.op("Constant", value_t=torch.LongTensor([0])),
|
|
)
|
|
offset = 0
|
|
else:
|
|
diag_size = g.op(
|
|
"Max",
|
|
g.op("Min", g.op("Add", dim1_size, offset_op), dim2_size),
|
|
g.op("Constant", value_t=torch.LongTensor([0])),
|
|
)
|
|
diag_size = g.op("Concat", diag_size, axis_i=0)
|
|
|
|
# Calculate which diagonal values to select
|
|
# For example, in cases with offsets:
|
|
# [[0, 1.1, 0]
|
|
# [0, 0, 2.2]]
|
|
# we need to select the last two columns, so we create a tensor
|
|
# with all columns that are to be selected
|
|
# So in this example, it is [1, 2]
|
|
select_window_ones_fill = opset9.ones(g, diag_size, 4, None, None)
|
|
select_window = g.op(
|
|
"CumSum",
|
|
select_window_ones_fill,
|
|
g.op("Constant", value_t=torch.LongTensor([0])),
|
|
)
|
|
select_window = g.op(
|
|
"Add",
|
|
select_window,
|
|
g.op("Constant", value_t=torch.LongTensor([abs(offset) - 1])),
|
|
)
|
|
|
|
gather_shape = [
|
|
opset9.size(g, result, dim=g.op("Constant", value_t=torch.LongTensor([axis])))
|
|
for axis in list(range(rank))[:-2]
|
|
]
|
|
gather_shape.append(diag_size)
|
|
gather_shape = g.op("Concat", *gather_shape, axis_i=0)
|
|
gather_indices = opset9.zeros(g, gather_shape, 4, None, None)
|
|
|
|
# There might be cases where offset value is greater than number of rows/columns
|
|
# and might cause the diagonal to overrun and as a result of this, diag_size would be zero.
|
|
# For example, if
|
|
# offset = 9, dim1_size = 2 (columns), dim2_size = 4 (rows)
|
|
# diag_size = max(min(2, (4-9)), 0) = 0, based on calculation above
|
|
# Cases with diagonal overrun always result in diag_size = max(0, -ve value) = 0
|
|
# In cases without diagonal overrun, we select the appropriate rows/columns along which we
|
|
# are calculating diagonal values. In cases with diagonal overrun, we return a tensor which has
|
|
# the dimension of the row/column where overrun occurred as 0-dim, as we are essentially
|
|
# returning an empty tensor
|
|
overrun_cond = g.op(
|
|
"Not",
|
|
g.op(
|
|
"Equal",
|
|
diag_size,
|
|
g.op("Constant", value_t=torch.tensor(0, dtype=torch.int64)),
|
|
),
|
|
)
|
|
|
|
if_op, (if_context, else_context), _ = jit_utils.add_op_with_blocks(
|
|
g, "If", overrun_cond, n_blocks=2
|
|
)
|
|
|
|
gather_indices_if_block = if_context.op("Add", gather_indices, select_window)
|
|
gather_indices_if_block = symbolic_helper._unsqueeze_helper(
|
|
if_context, gather_indices_if_block, [rank - 1]
|
|
)
|
|
final_non_overrun = if_context.op(
|
|
"GatherND", result, gather_indices_if_block, batch_dims_i=rank - 2
|
|
)
|
|
final_overrun = opset9.zeros(else_context, gather_shape, 6, None, None)
|
|
utils._add_output_to_block(if_context.block, final_non_overrun)
|
|
utils._add_output_to_block(else_context.block, final_overrun)
|
|
return if_op
|
|
|
|
|
|
# Quantized ops
|
|
|
|
|
|
@_onnx_symbolic("quantized::linear")
|
|
@_beartype.beartype
|
|
def quantized_linear(
|
|
g: jit_utils.GraphContext, q_input, q_weight, bias, op_scale, op_zero_point
|
|
):
|
|
input, input_scale, _, _ = symbolic_helper.dequantize_helper(g, q_input)
|
|
weight, weight_scale, _, axis = symbolic_helper.dequantize_helper(g, q_weight)
|
|
q_bias = symbolic_helper.requantize_bias_helper(
|
|
g, bias, input_scale, weight_scale, axis
|
|
)
|
|
bias, _, _, _ = symbolic_helper.dequantize_helper(g, q_bias)
|
|
|
|
output = opset9.linear(g, input, weight, bias)
|
|
|
|
return symbolic_helper.quantize_helper(g, output, op_scale, op_zero_point)
|
|
|
|
|
|
@_onnx_symbolic("quantized::linear_relu")
|
|
@_beartype.beartype
|
|
def quantized_linear_relu(
|
|
g: jit_utils.GraphContext, q_input, q_weight, bias, op_scale, op_zero_point
|
|
):
|
|
input, input_scale, _, _ = symbolic_helper.dequantize_helper(g, q_input)
|
|
weight, weight_scale, _, axis = symbolic_helper.dequantize_helper(g, q_weight)
|
|
q_bias = symbolic_helper.requantize_bias_helper(
|
|
g, bias, input_scale, weight_scale, axis
|
|
)
|
|
bias, _, _, _ = symbolic_helper.dequantize_helper(g, q_bias)
|
|
|
|
output = opset9.linear(g, input, weight, bias)
|
|
output = opset9.relu(g, output)
|
|
|
|
return symbolic_helper.quantize_helper(g, output, op_scale, op_zero_point)
|
|
|
|
|
|
@_onnx_symbolic("quantized::conv1d_relu")
|
|
@_beartype.beartype
|
|
def quantized_conv1d_relu(
|
|
g: jit_utils.GraphContext,
|
|
q_input,
|
|
q_weight,
|
|
bias,
|
|
stride,
|
|
padding,
|
|
dilation,
|
|
groups,
|
|
op_scale,
|
|
op_zero_point,
|
|
):
|
|
input, input_scale, _, _ = symbolic_helper.dequantize_helper(g, q_input)
|
|
weight, weight_scale, _, axis = symbolic_helper.dequantize_helper(g, q_weight)
|
|
q_bias = symbolic_helper.requantize_bias_helper(
|
|
g, bias, input_scale, weight_scale, axis
|
|
)
|
|
bias, _, _, _ = symbolic_helper.dequantize_helper(g, q_bias)
|
|
|
|
output = opset9.conv1d(g, input, weight, bias, stride, padding, dilation, groups)
|
|
output = opset9.relu(g, output)
|
|
|
|
return symbolic_helper.quantize_helper(g, output, op_scale, op_zero_point)
|
|
|
|
|
|
@_onnx_symbolic("quantized::conv2d_relu")
|
|
@_beartype.beartype
|
|
def quantized_conv2d_relu(
|
|
g: jit_utils.GraphContext,
|
|
q_input,
|
|
q_weight,
|
|
bias,
|
|
stride,
|
|
padding,
|
|
dilation,
|
|
groups,
|
|
op_scale,
|
|
op_zero_point,
|
|
):
|
|
input, input_scale, _, _ = symbolic_helper.dequantize_helper(g, q_input)
|
|
weight, weight_scale, _, axis = symbolic_helper.dequantize_helper(g, q_weight)
|
|
q_bias = symbolic_helper.requantize_bias_helper(
|
|
g, bias, input_scale, weight_scale, axis
|
|
)
|
|
bias, _, _, _ = symbolic_helper.dequantize_helper(g, q_bias)
|
|
|
|
output = opset9.conv2d(g, input, weight, bias, stride, padding, dilation, groups)
|
|
output = opset9.relu(g, output)
|
|
|
|
return symbolic_helper.quantize_helper(g, output, op_scale, op_zero_point)
|
|
|
|
|
|
@_onnx_symbolic("quantized::conv3d_relu")
|
|
@_beartype.beartype
|
|
def quantized_conv3d_relu(
|
|
g: jit_utils.GraphContext,
|
|
q_input,
|
|
q_weight,
|
|
bias,
|
|
stride,
|
|
padding,
|
|
dilation,
|
|
groups,
|
|
op_scale,
|
|
op_zero_point,
|
|
):
|
|
input, input_scale, _, _ = symbolic_helper.dequantize_helper(g, q_input)
|
|
weight, weight_scale, _, axis = symbolic_helper.dequantize_helper(g, q_weight)
|
|
q_bias = symbolic_helper.requantize_bias_helper(
|
|
g, bias, input_scale, weight_scale, axis
|
|
)
|
|
bias, _, _, _ = symbolic_helper.dequantize_helper(g, q_bias)
|
|
|
|
output = opset9.conv3d(g, input, weight, bias, stride, padding, dilation, groups)
|
|
output = opset9.relu(g, output)
|
|
|
|
return symbolic_helper.quantize_helper(g, output, op_scale, op_zero_point)
|
|
|
|
|
|
@_onnx_symbolic("quantized::conv1d")
|
|
@_beartype.beartype
|
|
def quantized_conv1d(
|
|
g: jit_utils.GraphContext,
|
|
q_input,
|
|
q_weight,
|
|
bias,
|
|
stride,
|
|
padding,
|
|
dilation,
|
|
groups,
|
|
op_scale,
|
|
op_zero_point,
|
|
):
|
|
input, input_scale, _, _ = symbolic_helper.dequantize_helper(g, q_input)
|
|
weight, weight_scale, _, axis = symbolic_helper.dequantize_helper(g, q_weight)
|
|
q_bias = symbolic_helper.requantize_bias_helper(
|
|
g, bias, input_scale, weight_scale, axis
|
|
)
|
|
bias, _, _, _ = symbolic_helper.dequantize_helper(g, q_bias)
|
|
|
|
output = opset9.conv1d(g, input, weight, bias, stride, padding, dilation, groups)
|
|
|
|
return symbolic_helper.quantize_helper(g, output, op_scale, op_zero_point)
|
|
|
|
|
|
@_onnx_symbolic("quantized::conv2d")
|
|
@_beartype.beartype
|
|
def quantized_conv2d(
|
|
g: jit_utils.GraphContext,
|
|
q_input,
|
|
q_weight,
|
|
bias,
|
|
stride,
|
|
padding,
|
|
dilation,
|
|
groups,
|
|
op_scale,
|
|
op_zero_point,
|
|
):
|
|
input, input_scale, _, _ = symbolic_helper.dequantize_helper(g, q_input)
|
|
weight, weight_scale, _, axis = symbolic_helper.dequantize_helper(g, q_weight)
|
|
q_bias = symbolic_helper.requantize_bias_helper(
|
|
g, bias, input_scale, weight_scale, axis
|
|
)
|
|
bias, _, _, _ = symbolic_helper.dequantize_helper(g, q_bias)
|
|
|
|
output = opset9.conv2d(g, input, weight, bias, stride, padding, dilation, groups)
|
|
|
|
return symbolic_helper.quantize_helper(g, output, op_scale, op_zero_point)
|
|
|
|
|
|
@_onnx_symbolic("quantized::conv3d")
|
|
@_beartype.beartype
|
|
def quantized_conv3d(
|
|
g: jit_utils.GraphContext,
|
|
q_input,
|
|
q_weight,
|
|
bias,
|
|
stride,
|
|
padding,
|
|
dilation,
|
|
groups,
|
|
op_scale,
|
|
op_zero_point,
|
|
):
|
|
input, input_scale, _, _ = symbolic_helper.dequantize_helper(g, q_input)
|
|
weight, weight_scale, _, axis = symbolic_helper.dequantize_helper(g, q_weight)
|
|
q_bias = symbolic_helper.requantize_bias_helper(
|
|
g, bias, input_scale, weight_scale, axis
|
|
)
|
|
bias, _, _, _ = symbolic_helper.dequantize_helper(g, q_bias)
|
|
|
|
output = opset9.conv3d(g, input, weight, bias, stride, padding, dilation, groups)
|
|
|
|
return symbolic_helper.quantize_helper(g, output, op_scale, op_zero_point)
|
|
|
|
|
|
@_onnx_symbolic("quantized::conv_transpose1d")
|
|
@_beartype.beartype
|
|
def quantized_conv_transpose1d(
|
|
g: jit_utils.GraphContext,
|
|
q_input,
|
|
q_weight,
|
|
bias,
|
|
stride,
|
|
padding,
|
|
output_padding,
|
|
dilation,
|
|
groups,
|
|
op_scale,
|
|
op_zero_point,
|
|
):
|
|
input, input_scale, _, _ = symbolic_helper.dequantize_helper(g, q_input)
|
|
weight, weight_scale, _, axis = symbolic_helper.dequantize_helper(g, q_weight)
|
|
q_bias = symbolic_helper.requantize_bias_helper(
|
|
g, bias, input_scale, weight_scale, axis
|
|
)
|
|
bias, _, _, _ = symbolic_helper.dequantize_helper(g, q_bias)
|
|
|
|
output = opset9.conv_transpose2d(
|
|
g, input, weight, bias, stride, padding, output_padding, groups, dilation
|
|
)
|
|
|
|
return symbolic_helper.quantize_helper(g, output, op_scale, op_zero_point)
|
|
|
|
|
|
@_onnx_symbolic("quantized::conv_transpose2d")
|
|
@_beartype.beartype
|
|
def quantized_conv_transpose2d(
|
|
g: jit_utils.GraphContext,
|
|
q_input,
|
|
q_weight,
|
|
bias,
|
|
stride,
|
|
padding,
|
|
output_padding,
|
|
dilation,
|
|
groups,
|
|
op_scale,
|
|
op_zero_point,
|
|
):
|
|
input, input_scale, _, _ = symbolic_helper.dequantize_helper(g, q_input)
|
|
weight, weight_scale, _, axis = symbolic_helper.dequantize_helper(g, q_weight)
|
|
q_bias = symbolic_helper.requantize_bias_helper(
|
|
g, bias, input_scale, weight_scale, axis
|
|
)
|
|
bias, _, _, _ = symbolic_helper.dequantize_helper(g, q_bias)
|
|
|
|
output = opset9.conv_transpose2d(
|
|
g, input, weight, bias, stride, padding, output_padding, groups, dilation
|
|
)
|
|
|
|
return symbolic_helper.quantize_helper(g, output, op_scale, op_zero_point)
|
|
|
|
|
|
@_onnx_symbolic("quantized::conv_transpose3d")
|
|
@_beartype.beartype
|
|
def quantized_conv_transpose3d(
|
|
g: jit_utils.GraphContext,
|
|
q_input,
|
|
q_weight,
|
|
bias,
|
|
stride,
|
|
padding,
|
|
output_padding,
|
|
dilation,
|
|
groups,
|
|
op_scale,
|
|
op_zero_point,
|
|
):
|
|
input, input_scale, _, _ = symbolic_helper.dequantize_helper(g, q_input)
|
|
weight, weight_scale, _, axis = symbolic_helper.dequantize_helper(g, q_weight)
|
|
q_bias = symbolic_helper.requantize_bias_helper(
|
|
g, bias, input_scale, weight_scale, axis
|
|
)
|
|
bias, _, _, _ = symbolic_helper.dequantize_helper(g, q_bias)
|
|
|
|
output = opset9.conv_transpose3d(
|
|
g, input, weight, bias, stride, padding, output_padding, groups, dilation
|
|
)
|
|
|
|
return symbolic_helper.quantize_helper(g, output, op_scale, op_zero_point)
|