# Copyright (c) ONNX Project Contributors # SPDX-License-Identifier: Apache-2.0 """Convenience methods for constructing the IR.""" from __future__ import annotations from collections.abc import Mapping, Sequence from typing import ( Any, Optional, ) import onnx_ir as ir from onnx_ir import _convenience # A type representing the domains/versions used in creating nodes in IR. UsedOpsets = set[tuple[str, Optional[int]]] class Tape: """Tape class. A tape is a recorder that collects nodes and initializers that are created so that they can be used for creating a graph. Example:: import onnx_ir as ir tape = ir.tape.Tape() a = tape.initializer(ir.tensor([1, 2, 3], name="a")) b: ir.Value = ... c: ir.Value = ... x = tape.op("Add", [a, b], attributes={"alpha": 1.0}) y = tape.op("Mul", [x, c], attributes={"beta": 2.0}) model = ir.Model( graph := ir.Graph( inputs=[b, c], outputs=[y], nodes=tape.nodes, initializers=tape.initializers opset_imports={"": 20}, ), ir_version=10, ) Attributes: graph_like: The graph to append the new nodes and initializers to. When it is None, the nodes and initializers are creating without owned by a graph. Initializers will not be added to functions because it is not supported by ONNX. """ def __init__(self, graph_like: ir.Graph | ir.Function | None = None) -> None: self._nodes: list[ir.Node] = [] self._initializers: list[ir.Value] = [] self._used_opsets: UsedOpsets = set() self.graph_like = graph_like def __repr__(self) -> str: return f"Tape(nodes={self._nodes}, initializers={self._initializers})" @property def nodes(self) -> Sequence[ir.Node]: return tuple(self._nodes) @property def initializers(self) -> Sequence[ir.Value]: return tuple(self._initializers) @property def used_opsets(self) -> UsedOpsets: return self._used_opsets def op( self, op_type: str, inputs: Sequence[ir.Value | None], attributes: Mapping[str, _convenience.SupportedAttrTypes] | None = None, *, domain: str = "", overload: str = "", version: int | None = None, graph: ir.Graph | None = None, name: str | None = None, doc_string: str | None = None, metadata_props: dict[str, str] | None = None, output: ir.Value | None = None, ) -> ir.Value: if attributes is None: attrs: Sequence[ir.Attr] = () else: attrs = _convenience.convert_attributes(attributes) output_kwargs: dict[str, Any] if output is None: output_kwargs = dict(num_outputs=1) else: output_kwargs = dict(outputs=[output]) node = ir.Node( domain, op_type, inputs, attributes=attrs, **output_kwargs, overload=overload, version=version, graph=graph or self.graph_like, name=name, doc_string=doc_string, metadata_props=metadata_props, ) self._nodes.append(node) self._used_opsets.add((domain, version)) return node.outputs[0] def op_multi_out( self, op_type: str, inputs: Sequence[ir.Value | None], attributes: Mapping[str, _convenience.SupportedAttrTypes] | None = None, *, num_outputs: int | None = None, outputs: Sequence[ir.Value] | None = None, domain: str = "", overload: str = "", version: int | None = None, graph: ir.Graph | None = None, name: str | None = None, doc_string: str | None = None, metadata_props: dict[str, str] | None = None, ) -> Sequence[ir.Value]: if num_outputs is None and outputs is None: raise ValueError("Either num_outputs or outputs must be provided.") if num_outputs is not None and outputs is not None: raise ValueError("Both num_outputs and outputs cannot be provided simultaneously.") output_kwargs: dict[str, Any] if outputs is None: output_kwargs = dict(num_outputs=num_outputs) else: output_kwargs = dict(outputs=outputs) if attributes is None: attrs: Sequence[ir.Attr] = () else: attrs = _convenience.convert_attributes(attributes) node = ir.Node( domain, op_type, inputs, attributes=attrs, **output_kwargs, overload=overload, version=version, graph=graph or self.graph_like, name=name, doc_string=doc_string, metadata_props=metadata_props, ) self._nodes.append(node) self._used_opsets.add((domain, version)) return node.outputs def initializer(self, tensor: ir.TensorProtocol, name: str | None = None) -> ir.Value: name = name or tensor.name if name is None: raise ValueError("Name must be provided for initializer.") shape = ir.Shape((d if isinstance(d, int) else d.value) for d in tensor.shape.dims) value = ir.Value( name=name, shape=shape, type=ir.TensorType(tensor.dtype), const_value=tensor ) self._initializers.append(value) if isinstance(self.graph_like, ir.Graph): self.graph_like.register_initializer(value) return value class Builder(Tape): """An extension of the tape that provides a more convenient API for constructing the IR.""" def __getattr__(self, op_type: str) -> Any: return lambda *args, **kwargs: self._make_node(op_type, args, kwargs) def _make_node(self, op_type: str, inputs: Sequence[ir.Value], kwargs: dict[str, Any]): domain = kwargs.pop("_domain", "") version = kwargs.pop("_version", None) outputs = kwargs.pop("_outputs", 1) if isinstance(outputs, Sequence): num_outputs = len(outputs) else: assert isinstance(outputs, int) num_outputs = outputs if num_outputs == 1: value = super().op( op_type, inputs=inputs, attributes=kwargs, domain=domain, version=version ) if isinstance(outputs, Sequence): value.name = outputs[0] return value values = super().op_multi_out( op_type, inputs=inputs, attributes=kwargs, domain=domain, version=version, num_outputs=num_outputs, ) if isinstance(outputs, Sequence): for value, name in zip(values, outputs): value.name = name return values