提交 56b8784c 编写于 作者: V Varun Arora

Update design doc based on early implementation

上级 5550bd10
### Background # Background
[ONNX (Open Neural Network Exchange)](https://github.com/onnx/onnx) bridges different deep learning frameworks by providing an open source graph format for models. The models trained in other frameworks can be converted into the ONNX format to execute inference by utilizing the built-in operators in ONNX. With the inverse conversion, different frameworks can share any models supported by ONNX in principle. Now most mainstream frameworks have joined the ONNX community, e.g. Caffe2, TensorFlow, and MXNet etc. And there is a tendency that more and more vendors begin to support ONNX or even choose ONNX as the only machine learning engine in their devices. [ONNX (Open Neural Network Exchange)](https://github.com/onnx/onnx) bridges different deep learning frameworks by providing an open source graph format for models. The models trained in other frameworks can be converted into the ONNX format to execute inference by utilizing the built-in operators in ONNX - this is called a **frontend**. With the inverse conversion (called a **backend**), different frameworks can share any models supported by ONNX in principle. Now most mainstream frameworks have joined the ONNX community, e.g. Caffe2, PyTorch, and MXNet etc. And there is a momentum driving more and more vendors to begin supporting ONNX or even choose ONNX as the only machine learning runtime in their devices.
Therefore, it is necessary to enable the conversion between PaddlePaddle and ONNX. This design doc aims to implement the convertor, mainly for the ONNX conversion of models in Fluid and possibly including some important models in V2 format in the future. A complete convertor should be bidirectional, but considering the importance, the conversion from Fluid to ONNX will be implemented preferentially. Therefore, it is necessary to enable the conversion between PaddlePaddle and ONNX. This design doc is aimed at implementing a convertor, mainly for converting between **Fluid** models and ONNX (it is very likely that we may support older v2 models in the future). A complete convertor should be bidirectional - with a frontend AND a backend, but considering the importance, the we will start with the frontend i.e. Fluid models to ONNX models.
One thing that makes it doable in Fluid's case is the use of a static IR - the `ProgramDesc` - as opposed to a dynamic graph, as created in the cases of frameworks like PyTorch. One thing that makes it doable in Fluid's case is the use of a static IR - the `ProgramDesc` - as opposed to a dynamic graph, as created in the cases of frameworks like PyTorch.
### How it works # How it works
As the first step, Fluid must cover [all the listed operators](https://github.com/onnx/onnx/blob/master/docs/Operators.md) in ONNX. The complement is being carried out and only a few minor operators need to be newly added or enhanced, which would not postpone the convertor and the test of common models. ONNX has a [working list of operators](https://github.com/onnx/onnx/blob/master/docs/Operators.md) which is versioned.
About the convertor, several things need to be considered: When prioritizing implementation of a frontend over a backend, choice of coverage of Fluid -> ONNX operators comes down to choices of models to be supported (see section `Supported models`). Eventually, this will allow us to reach a really-wide coverage of all operators.
- OP-level conversion Here are a few major considerations when it comes to converting models:
- How to map the inputs, attributes, weights, and outputs each operator.
- Data type mapping
- Network representation adapation
- The model in Fluid is represented by nested `Block`, how to parse and reconstruct it in ONNX graph format, and vice versa;
- Model validation - **Op-level conversion**: How to map the inputs, attributes, and outputs of each Paddle operator to those of the ONNX operator. In several cases, these require transformations. For each direction (frontend vs. backend), a different conversion mapping is needed.
- To assure the correctness of conversion. A simple way may be to generate some dummy data as the input and compare the inference results. - **Parameters (weights) initialization**: Setting initial parameters on different nodes.
- Long term support - **Tensor data type mapping** (Note: Some ONNX data types are not supported in Fluid)
- As ONNX keeps evolving, a mechanism to make sure long term support is needed. - **Network representation adaption**: Fluid `ProgramDesc` include nested blocks. Since ONNX is free of nesting, the `ProgramDesc` ops need to be traversed to only include ops from the global scope in the root block. The variables used as inputs and outputs should also be in this scope.
- **Model validation**: There are two kinds of validations that are necessary:
1. We need to ensure that the inference outputs of the ops in run inside a model are the same as those when running the ONNX converted ops through an alternative ONNX backend.
2. Checking to see if the generated nodes on the graph are validated by the internal ONNX checkers.
- **Versioning**: ONNX versions its op listing over versions. In fact, it has versioning on 3 different levels: ops, graphs, and ONNX models. This requires that we are conscious about versioning the convertor and updating tests and op convertor logic for each release. It also implies that we release pre-trained ONNX models upon each version release.
### Project structure
# Project structure
<p align="center"> <p align="center">
<img src="./images/project_structure.png"/> <img src="./images/project_structure.png"/>
...@@ -32,41 +33,42 @@ About the convertor, several things need to be considered: ...@@ -32,41 +33,42 @@ About the convertor, several things need to be considered:
The project contains four important parts: The project contains four important parts:
* **fluid**: The directory that contains wrappers for fluid related APIs. Fluid has provided some low-level APIs to parse or generate the inference model. However, directly using these low-level APIs makes the code tediously long. This module wraps low-level APIs to provide simplied interfaces. * **fluid**: The directory that contains wrappers for fluid related APIs. Fluid has provided some low-level APIs to parse or generate the inference model. However, directly using these low-level APIs makes the code tediously long. This module wraps low-level APIs to provide simplified interfaces.
* **onnx**: This is a Python package provided by ONNX containing helpers for creating nodes, graphs, and eventually binary protobuf models with initializer parameters.
* **onnx**: ONNX uses protobuf to save computation flow and model weights. This directory consists of scripts responsible for parsing and generating an ONNX binary model. * **onnx_fluid**: Contains two-way mapping (Fluid -> ONNX ops and ONNX -> Fluid ops). Called from `convert.py`, the program uses this mapping along with modifier functions to construct ONNX nodes with the help of ONNX's `make_node` helper. It also contains mapping between datatypes and tensor deprecation / amplification logic.
* **onnx_fluid**: Concepts in fluid like ```program```, ```block``` etc. don't have direct corresponding concepts in ONNX. Even though both contain the operator concept, the adaption is also necessary for many operators. This directory consists of the most important modules responsible for acutal converting. Adaption for different level concepts should be provided like fluid ```program/block``` to ONNX graph, fluid operators to ONNX operators etc. * **convert.py**: The interface exposed to users. This will traverse the global program blocks/variables and construct the write-able model.
* **convert.py**: The interface exposed to users.
### Usage # Usage
The converter is designed to very easy-to-use. Bidirectional conversion between Fluid inference model and ONNX binary model is supported. Model validation is also provided to verify the correctness of converted model. The converter should be designed to very easy-to-use. Bidirectional conversion between a Fluid inference model and an ONNX binary model will be supported. Model validation will also provided to verify the correctness of converted model.
* Fluid inference model to ONNX binary model * Fluid inference model to ONNX binary model
``` ```
python convert.py --input <fluid inference model> --output <ONNX model> --to_validate True python convert.py --fluid_model <fluid inference model> --onnx_model <ONNX model> validate True
``` ```
The conversion and model validation will be completed consecutively, finally output a readable model structure description. And for the converse conversion, users only need to exchange the input and output. The conversion and model validation will be completed consecutively, finally output a readable model structure description. And for the converse conversion, users only need to exchange the input and output.
### Challenges and mitigation # Challenges and mitigation
#### Cycles ## Cycles
Cycles are unsupported in ONNX. In Paddle, the `while` op is the most prominent example of a cycle. Cycles are unsupported in ONNX. In Paddle, the `while` op is the most prominent example of a cycle.
*Resolution*: We won't support models with `while`s which can't be substituted until ONNX adds support for such ops. *Resolution*: We won't support models with `while`s which can't be substituted until ONNX adds support for such ops.
#### Sequences ## Sequences
Sequence processing operators like `sequence_expand`, `sequence_reshape`, `sequence_concat`, and `sequence_pool` are not supported by ONNX as well, because they do not support non-padded datatypes like LoDTensors. Sequence processing operators like `sequence_expand`, `sequence_reshape`, `sequence_concat`, and `sequence_pool` are not supported by ONNX as well, because they do not support non-padded datatypes like LoDTensors.
*Resolution*: Since the runtimes using our ONNX exported graphs won't be using LoDTensors in the first place, such sequence operators should be mapped to ONNX ops that will do the necessary transposing ops with the knowledge of the padding and shape of the Tensors. *Resolution*: Since the runtimes using our ONNX exported graphs won't be using LoDTensors in the first place, such sequence operators should be mapped to ONNX ops that will do the necessary transposing ops with the knowledge of the padding and shape of the Tensors.
#### Ops that can't easily be mapped ## Ops that can't easily be mapped
There are ops that just aren't possible to map today: There are ops that just aren't possible to map today:
...@@ -101,26 +103,23 @@ There are ops in ONNX whose job can't be accomplished by a single corresponding ...@@ -101,26 +103,23 @@ There are ops in ONNX whose job can't be accomplished by a single corresponding
*Resolution*: Chain multiple Paddle operators. *Resolution*: Chain multiple Paddle operators.
#### Lack of LoDTensors ## Lack of LoDTensors
As stated above, ONNX only supports simple Tensor data.
(...) As stated above, ONNX only supports simple Tensor values.
TBD *Resolution*: Deprecate to plain old numpy-able tensors.
#### Reconstruction from deprecated ONNX ops ## Reconstruction from deprecated ONNX ops
For higher-level Fluid ops, such as a few offered by the `nn` layer that do not have direct corresponding mappings but can be converted to ONNX by chaining a series of ops without cycles, it would be useful to map them back to the higher-level Fluid ops once converted back from the deprecated ONNX graphs. For higher-level Fluid ops, such as a few offered by the `nn` layer that do not have direct corresponding mappings but can be converted to ONNX by chaining a series of ops without cycles, it would be useful to map them back to the higher-level Fluid ops once converted back from the deprecated ONNX graphs.
*Resolution*: Graphs that have the deprecation from Paddle -> ONNX. When converting back from ONNX, if we encounter the identical graphs by doing a forward search, we can replace the subgraphs with the matching ONNX op. *Resolution*: Graphs that have the deprecation from Paddle -> ONNX. When converting back from ONNX, if we encounter the identical graphs by doing a forward search, we can replace the subgraphs with the matching ONNX op.
### Supported models # Supported models
Potential risks may come from the conversion of sequence-related models, including the LodTensor, ```if/else``` and ```while``` operator. As mentioned above, potential risks may come from the conversion of sequence-related models, including the LodTensor, ```if/else``` and ```while``` operator. So a good choice is to focus on some important feedforward models first, then implement some simple recurrent models.
So a good choice is to focus on some important feedforward models first, then implement some simple recurrent models.
- Feedforward models: common models selected in PaddleBook, e.g. VGG, ResNet and some other models proposed by application teams. - Feedforward models: common models selected in PaddleBook, e.g. VGG, ResNet and some other models proposed by application teams.
- Recurrent models: language model, stacked LSTMs etc. - Recurrent models: language model, stacked LSTMs etc.
Markdown is supported
0% .
You are about to add 0 people to the discussion. Proceed with caution.
先完成此消息的编辑!
想要评论请 注册