from typing import Any, Dict, List, Optional, Union

from enum import IntEnum

import numpy as np

from onnx import NodeProto, SparseTensorProto, TensorProto, ValueInfoProto

from onnx.checker import check_model

from onnx.defs import onnx_opset_version

from onnx.helper import (

make_graph,

make_model,

make_node,

make_opsetid,

make_tensor_value_info,

make_tensor_type_proto,

)

from onnx.numpy_helper import from_array

from ..ext_test_case import is_azure, is_windows

from ..annotations import (

elem_type_int,

make_shape,

GRAPH_PROTO,

ELEMENT_TYPE,

SHAPE_TYPE,

VAR_CONSTANT_TYPE,

)

class ProtoType(IntEnum):

"""

The same code can be used to output a GraphProto, a FunctionProto or a ModelProto.

This class specifies the output type at the beginning of the code.

"""

FUNCTION = 1

GRAPH = 2

MODEL = 3

class OnnxGraph:

"""

Contains every piece needed to create an onnx model in a single instructions.

This API is meant to be light and allows the description of a graph.

:param opset: main opset version

:param opsets: other opsets as a dictionary

:param ir_version: to specify an ir_version

:param is_function: a :class:`onnx.ModelProto` or a :class:`onnx.FunctionProto`

"""

def __init__(

self,

opset: Optional[int] = None,

opsets: Optional[Dict[str, int]] = None,

ir_version: Optional[int] = None,

proto_type: ProtoType = ProtoType.MODEL,

):

if opsets is not None and "" in opsets:

if opset is None:

opset = opsets[""]

elif opset != opsets[""]:

raise ValueError(

"The main opset can be specified twice with different values."

)

if proto_type == ProtoType.FUNCTION:

raise NotImplementedError(

"The first version of this API does not support functions."

)

self.proto_type = proto_type

self.opsets = opsets

self.opset = opset

self.ir_version = ir_version

self.nodes: List[Union[NodeProto, TensorProto]] = []

self.inputs: List[ValueInfoProto] = []

self.outputs: List[ValueInfoProto] = []

self.initializers: List[TensorProto] = []

self.unique_names_: Dict[str, Any] = {}

self.renames_: Dict[str, str] = {}

@property

def is_function(self) -> bool:

return self.proto_type == ProtoType.FUNCTION

def __repr__(self) -> str:

"usual"

sts = [f"{self.__class__.__name__}("]

els = [

repr(getattr(self, o))

for o in ["opset", "opsets"]

if getattr(self, o) is not None

]

if self.is_function:

els.append("is_function=True")

sts.append(", ".join(els))

sts.append(")")

return "".join(sts)

@property

def input_names(self) -> List[str]:

"Returns the input names"

return [v.name for v in self.inputs]

@property

def output_names(self) -> List[str]:

"Returns the output names"

return [v.name for v in self.outputs]

def has_name(self, name: str) -> bool:

"Tells if a name is already used."

return name in self.unique_names_

def unique_name(self, prefix="r", value: Optional[Any] = None) -> str:

"""

Returns a unique name.

:param prefix: prefix

:param value: this name is mapped to this value

:return: unique name

"""

if isinstance(value, int):

raise TypeError(f"Unexpected type {type(value)}, prefix={prefix!r}.")

name = prefix

i = len(self.unique_names_)

while name in self.unique_names_:

name = f"prefix{i}"

i += 1

self.unique_names_[name] = value

return name

def make_input(

self,

name: str,

elem_type: ELEMENT_TYPE = TensorProto.FLOAT,

shape: Optional[SHAPE_TYPE] = None,

) -> ValueInfoProto:

"""

Adds an input to the graph.

:param name: input name

:param elem_type: element type (the input is assumed to be a tensor)

:param shape: shape

:return: an instance of ValueInfoProto

"""

if self.has_name(name):

raise ValueError(f"Name {name!r} is already taken.")

var = make_tensor_value_info(name, elem_type, shape)

self.inputs.append(var)

self.unique_names_[name] = var

return var

def vin(

self,

name: str,

elem_type: ELEMENT_TYPE = TensorProto.FLOAT,

shape: Optional[SHAPE_TYPE] = None,

) -> "Var":

"""

Declares a new input to the graph.

:param name: input name

:param elem_type: element_type

:param shape: shape

:return: instance of :class:`onnx_array_api.light_api.Var`

"""

from .var import Var

proto = self.make_input(name, elem_type=elem_type_int(elem_type), shape=shape)

return Var(

self,

proto.name,

elem_type=proto.type.tensor_type.elem_type,

shape=make_shape(proto.type.tensor_type.shape),

)

def make_output(

self,

name: str,

elem_type: ELEMENT_TYPE = TensorProto.FLOAT,

shape: Optional[SHAPE_TYPE] = None,

) -> ValueInfoProto:

"""

Adds an output to the graph.

:param name: input name

:param elem_type: element type (the input is assumed to be a tensor)

:param shape: shape

:return: an instance of ValueInfoProto

If the checker fails, try `shape=[]`.

"""

if not self.has_name(name):

raise ValueError(f"Name {name!r} does not exist.")

var = make_tensor_value_info(name, elem_type_int(elem_type), shape)

self.outputs.append(var)

self.unique_names_[name] = var

return var

def make_constant(

self, value: np.ndarray, name: Optional[str] = None

) -> TensorProto:

"Adds an initializer to the graph."

if self.is_function:

raise NotImplementedError(

"Adding a constant to a FunctionProto is not supported yet."

)

if isinstance(value, np.ndarray):

if name is None:

name = self.unique_name()

elif self.has_name(name):

raise RuntimeError(f"Name {name!r} already exists.")

tensor = from_array(value, name=name)

self.unique_names_[name] = tensor

self.initializers.append(tensor)

return tensor

raise TypeError(f"Unexpected type {type(value)} for constant {name!r}.")

def make_node(

self,

op_type: str,

*inputs: List[VAR_CONSTANT_TYPE],

domain: str = "",

n_outputs: int = 1,

output_names: Optional[List[str]] = None,

**kwargs: Dict[str, Any],

) -> NodeProto:

"""

Creates a node.

:param op_type: operator type

:param inputs: others inputs

:param domain: domain

:param n_outputs: number of outputs

:param output_names: output names, if not specified, outputs are given

unique names

:param kwargs: node attributes

:return: NodeProto

"""

if output_names is None:

output_names = [

self.unique_name(prefix=f"r{len(self.nodes)}_{i}")

for i in range(n_outputs)

]

elif n_outputs != len(output_names):

raise ValueError(

f"Expecting {n_outputs} outputs but received {output_names}."

)

input_names = []

for i in inputs:

if hasattr(i, "name"):

input_names.append(i.name)

elif isinstance(i, np.ndarray):

input_names.append(self.make_constant(i))

else:

raise TypeError(f"Unexpected type {type(i)} for one input.")

node = make_node(op_type, input_names, output_names, domain=domain, **kwargs)

self.nodes.append(node)

if domain != "":

if not self.opsets or domain not in self.opsets:

raise RuntimeError(f"No opset value was given for domain {domain!r}.")

return node

def cst(self, value: np.ndarray, name: Optional[str] = None) -> "Var":

"""

Adds an initializer

:param value: constant tensor

:param name: input name

:return: instance of :class:`onnx_array_api.light_api.Var`

"""

from .var import Var

c = self.make_constant(value, name=name)

return Var(self, c.name, elem_type=c.data_type, shape=tuple(c.dims))

def true_name(self, name: str) -> str:

"""

Some names were renamed. If name is one of them, the function

returns the new name.

"""

if not isinstance(name, str):

raise TypeError(

f"Unexpected type {type(name)}, rename must be placed before vout."

)

while name in self.renames_:

name = self.renames_[name]

return name

def get_var(self, name: str) -> "Var":

from .var import Var

tr = self.true_name(name)

proto = self.unique_names_[tr]

if proto is None:

return Var(self, name)

if isinstance(proto, ValueInfoProto):

return Var(

self,

proto.name,

elem_type=proto.type.tensor_type.elem_type,

shape=make_shape(proto.type.tensor_type.shape),

)

if isinstance(proto, TensorProto):

return Var(

self, proto.name, elem_type=proto.data_type, shape=tuple(proto.dims)

)

raise TypeError(f"Unexpected type {type(proto)} for name {name!r}.")

def rename(self, old_name: str, new_name: str):

"""

Renames a variable. The renaming does not

change anything but is stored in a container.

:param old_name: old name

:param new_name: new name

"""

if not self.has_name(old_name):

raise RuntimeError(f"Name {old_name!r} does not exist.")

if self.has_name(new_name):

raise RuntimeError(f"Name {old_name!r} already exist.")

value = self.unique_names_[old_name]

if isinstance(value, int):

raise TypeError(

f"Unexpected type {type(value)} for value {old_name!r} "

f"renamed into {new_name!r}."

)

self.unique_names_[new_name] = value

self.renames_[old_name] = new_name

def _fix_name_tensor(

self, obj: Union[TensorProto, SparseTensorProto, ValueInfoProto]

) -> Union[TensorProto, SparseTensorProto, ValueInfoProto]:

true_name = self.true_name(obj.name)

if true_name != obj.name:

obj.name = true_name

return obj

def _fix_name_tensor_input(

self, obj: Union[TensorProto, SparseTensorProto, ValueInfoProto]

) -> Union[TensorProto, SparseTensorProto, ValueInfoProto]:

obj = self._fix_name_tensor(obj)

shape = make_shape(obj.type.tensor_type.shape)

if not shape:

tensor_type_proto = make_tensor_type_proto(

obj.type.tensor_type.elem_type, []

)

obj.type.CopyFrom(tensor_type_proto)

return obj

def _fix_name_tensor_output(

self, obj: Union[TensorProto, SparseTensorProto, ValueInfoProto]

) -> Union[TensorProto, SparseTensorProto, ValueInfoProto]:

obj = self._fix_name_tensor(obj)

shape = make_shape(obj.type.tensor_type.shape)

if not shape:

tensor_type_proto = make_tensor_type_proto(

obj.type.tensor_type.elem_type, []

)

obj.type.CopyFrom(tensor_type_proto)

return obj

def _fix_name_node(self, obj: NodeProto) -> NodeProto:

new_inputs = [self.true_name(i) for i in obj.input]

if new_inputs != obj.input:

del obj.input[:]

obj.input.extend(new_inputs)

new_outputs = [self.true_name(o) for o in obj.output]

if new_outputs != obj.output:

del obj.output[:]

obj.output.extend(new_outputs)

return obj

def _check_input(self, i):

"Checks one input is fully specified."

if i.type.tensor_type.elem_type <= 0:

raise ValueError(f"Input {i.name!r} has no element type.")

return i

def to_onnx(self) -> GRAPH_PROTO:

"""

Converts the graph into an ONNX graph.

"""

if self.is_function:

raise NotImplementedError("Unable to convert a graph input ")

dense = [

self._fix_name_tensor(i)

for i in self.initializers

if isinstance(i, TensorProto)

]

sparse = [

self._fix_name_tensor(i)

for i in self.initializers

if isinstance(i, SparseTensorProto)

]

graph = make_graph(

[self._fix_name_node(n) for n in self.nodes],

"light_api",

[self._check_input(self._fix_name_tensor_input(i)) for i in self.inputs],

[self._fix_name_tensor_output(o) for o in self.outputs],

dense,

sparse,

)

opsets = [make_opsetid("", self.opset or onnx_opset_version() - 1)]

if self.opsets:

for k, v in self.opsets.items():

opsets.append(make_opsetid(k, v))

if self.proto_type == ProtoType.GRAPH:

# If no opsets, it a subgraph, not a model.

return graph

model = make_model(graph, opset_imports=opsets)

if self.ir_version:

model.ir_version = self.ir_version

if not is_windows() or not is_azure():

# check_model fails sometimes on Windows

check_model(model)

return model