ONNX Script enables developers to naturally author ONNX functions and models using a subset of Python. ONNX Script is:
- Expressive: enables the authoring of all ONNX functions.
- Simple and concise: function code is natural and simple.
- Debuggable: allows for eager-mode evaluation that provides for a more delightful ONNX model debugging experience.
This repo also covers:
- ONNX IR: an in-memory IR that supports the full ONNX spec, designed for graph construction, analysis and transformation.
- ONNX Script Optimizer: provides functionality to optimize an ONNX model by performing optimizations and clean-ups such as constant folding, dead code elimination, etc.
- ONNX Rewriter: provides functionality to replace certain patterns in an ONNX graph with replacement patterns based on user-defined rewrite rules.
Note however that ONNX Script does not intend to support the entirety of the Python language.
Website: https://onnxscript.ai/
ONNX Script provides a few major capabilities for authoring and debugging ONNX models and functions:
-
A converter which translates a Python ONNX Script function into an ONNX graph, accomplished by traversing the Python Abstract Syntax Tree to build an ONNX graph equivalent of the function.
-
A converter that operates inversely, translating ONNX models and functions into ONNX Script. This capability can be used to fully round-trip ONNX Script ↔ ONNX graph.
-
A runtime shim that allows such functions to be evaluated (in an "eager mode"). This functionality currently relies on ONNX Runtime for executing every ONNX Operator, and there is a Python-only reference runtime for ONNX underway that will also be supported.
Note that the runtime is intended to help understand and debug function definitions. Performance is not a goal here.
pip install --upgrade onnxscript
git clone https://github.com/microsoft/onnxscript
cd onnxscript
pip install -r requirements-dev.txt
pip install -e .
pytest .
import onnx
# We use ONNX opset 15 to define the function below.
from onnxscript import FLOAT, script
from onnxscript import opset15 as op
# We use the script decorator to indicate that
# this is meant to be translated to ONNX.
@script()
def onnx_hardmax(X, axis: int):
"""Hardmax is similar to ArgMax, with the result being encoded OneHot style."""
# The type annotation on X indicates that it is a float tensor of
# unknown rank. The type annotation on axis indicates that it will
# be treated as an int attribute in ONNX.
#
# Invoke ONNX opset 15 op ArgMax.
# Use unnamed arguments for ONNX input parameters, and named
# arguments for ONNX attribute parameters.
argmax = op.ArgMax(X, axis=axis, keepdims=False)
xshape = op.Shape(X, start=axis)
# use the Constant operator to create constant tensors
zero = op.Constant(value_ints=[0])
depth = op.GatherElements(xshape, zero)
empty_shape = op.Constant(value_ints=[0])
depth = op.Reshape(depth, empty_shape)
values = op.Constant(value_ints=[0, 1])
cast_values = op.CastLike(values, X)
return op.OneHot(argmax, depth, cast_values, axis=axis)
# We use the script decorator to indicate that
# this is meant to be translated to ONNX.
@script()
def sample_model(X: FLOAT[64, 128], Wt: FLOAT[128, 10], Bias: FLOAT[10]) -> FLOAT[64, 10]:
matmul = op.MatMul(X, Wt) + Bias
return onnx_hardmax(matmul, axis=1)
# onnx_model is an in-memory ModelProto
onnx_model = sample_model.to_model_proto()
# Save the ONNX model at a given path
onnx.save(onnx_model, "sample_model.onnx")
# Check the model
try:
onnx.checker.check_model(onnx_model)
except onnx.checker.ValidationError as e:
print(f"The model is invalid: {e}")
else:
print("The model is valid!")
The decorator parses the code of the function, converting it into an
intermediate representation. If it fails, it produces an error message
indicating the line where the error was detected. If it succeeds, the
intermediate representation can be converted into an ONNX graph
structure of type FunctionProto
:
Hardmax.to_function_proto()
returns aFunctionProto
Eager mode is mostly used to debug and validate that intermediate results are as expected. The function defined above can be called as below, executing in an eager-evaluation mode:
import numpy as np
v = np.array([[0, 1], [2, 3]], dtype=np.float32)
result = Hardmax(v)
More examples can be found in the docs/examples directory.
An in-memory IR that supports the full ONNX spec, designed for graph construction, analysis and transformation.
- Full ONNX spec support: all valid models representable by ONNX protobuf, and a subset of invalid models (so you can load and fix them).
- Low memory footprint: mmap'ed external tensors; unified interface for ONNX TensorProto, Numpy arrays and PyTorch Tensors etc. No tensor size limitation. Zero copies.
- Straightforward access patterns: Access value information and traverse the graph topology at ease.
- Robust mutation: Create as many iterators as you like on the graph while mutating it.
- Speed: Performant graph manipulation, serialization/deserialization to Protobuf.
- Pythonic and familiar APIs: Classes define Pythonic apis and still map to ONNX protobuf concepts in an intuitive way.
The ONNX Script Optimizer tool provides the user with the functionality to optimize an ONNX model by performing optimizations and clean-ups such as constant folding, dead code elimination, etc. In order to utilize the optimizer tool:
import onnxscript
onnxscript.optimizer.optimize(onnx_model)
For a detailed summary of all the optimizations applied by the optimizer call, refer to the tutorial Optimizing a Model using the Optimizer
The ONNX Rewriter tool provides the user with the functionality to replace certain patterns in an ONNX graph with another pattern based on user-defined rewrite rules. The rewriter tools allows two different methods in which patterns in the graph can be rewritten.
For this style of rewriting, the user provides a target_pattern
that is to be replaced, a replacement_pattern
and a match_condition
(pattern rewrite will occur only if the match condition is satisfied). A simple example on how to use the pattern-based rewriting tool is as follows:
from onnxscript.rewriter import pattern
# The target pattern
def erf_gelu_pattern(op, x):
return 0.5 * (x * (op.Erf(x / math.sqrt(2)) + 1.0))
def erf_gelu_pattern_2(op, x):
return (x * (op.Erf(x / math.sqrt(2)) + 1.0)) * 0.5
# The replacement pattern
def gelu(op, x: ir.Value):
return op.Gelu(x, domain="com.microsoft")
# Create multiple rules
rule1 = pattern.RewriteRule(
erf_gelu_pattern, # Target Pattern
gelu, # Replacement
)
rule2 = pattern.RewriteRule(
erf_gelu_pattern_2, # Target Pattern
gelu, # Replacement
)
# Create a Rewrite Rule Set with multiple rules.
rewrite_rule_set = pattern.RewriteRuleSet([rule1, rule2])
# Apply rewrites
model_with_rewrite_applied = onnxscript.rewriter.rewrite(
model, # Original ONNX Model
pattern_rewrite_rules=rewrite_rule_set,
)
return model_with_rewrite_applied
For a detailed tutorial on how to create target_pattern, replacement_pattern and match_condition blocks in order to utilize the pattern-based rewriter, refer to the tutorial Pattern-based Rewrite Using Rules
This style of rewriting matches a FUNCTION_KEYWORD
and PACKAGE_NAME
provided by the user to an existing function within the graph and replaces it with a new function provided by the user.
Every change impacting the converter or the eager evaluation must be
unit tested with class OnnxScriptTestCase
to ensure both systems do
return the same results with the same inputs.
We use ruff
, black
, isort
, and mypy
etc. to check code formatting and use lintrunner
to run all linters.
You can install the dependencies and initialize with
pip install lintrunner lintrunner-adapters
lintrunner init
This will install lintrunner on your system and download all the necessary dependencies to run linters locally.
If you want to see what lintrunner init will install, run lintrunner init --dry-run
.
To lint local changes:
lintrunner
To format files:
lintrunner f
To lint all files:
lintrunner --all-files
Use --output oneline
to produce a compact list of lint errors, useful when
there are many errors to fix.
See all available options with lintrunner -h
.
To read more about lintrunner, see wiki.
To update an existing linting rule or create a new one, modify .lintrunner.toml
or create a
new adapter following examples in https://github.com/justinchuby/lintrunner-adapters.
We're always looking for your help to improve the product (bug fixes, new features, documentation, etc). Currently ONNX Script is under early and heavy development, so we encourage proposing any major changes by filing an issue to discuss your idea with the team first.
Please do not report security vulnerabilities through public GitHub issues.
Please refer to our guidance on filing Security Issues.
This project welcomes contributions and suggestions. Most contributions require you to agree to a Contributor License Agreement (CLA) declaring that you have the right to, and actually do, grant us the rights to use your contribution. For details, visit https://cla.microsoft.com.
When you submit a pull request, a CLA-bot will automatically determine whether you need to provide a CLA and decorate the PR appropriately (e.g., label, comment). Simply follow the instructions provided by the bot. You will only need to do this once across all repositories using our CLA.
This project has adopted the Microsoft Open Source Code of Conduct. For more information see the Code of Conduct FAQ or contact opencode@microsoft.com with any additional questions or comments.
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