Convert rst files (#14888)
* Convert all tutorials and guides * Convert all remaining rst to mdx * Track and fix bad links
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<!--Copyright 2020 The HuggingFace Team. All rights reserved.
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Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with
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the License. You may obtain a copy of the License at
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http://www.apache.org/licenses/LICENSE-2.0
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Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on
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an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the
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specific language governing permissions and limitations under the License.
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-->
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# Exporting transformers models
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## ONNX / ONNXRuntime
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Projects [ONNX (Open Neural Network eXchange)](http://onnx.ai) and [ONNXRuntime (ORT)](https://microsoft.github.io/onnxruntime/) are part of an effort from leading industries in the AI field to provide a
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unified and community-driven format to store and, by extension, efficiently execute neural network leveraging a variety
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of hardware and dedicated optimizations.
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Starting from transformers v2.10.0 we partnered with ONNX Runtime to provide an easy export of transformers models to
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the ONNX format. You can have a look at the effort by looking at our joint blog post [Accelerate your NLP pipelines
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using Hugging Face Transformers and ONNX Runtime](https://medium.com/microsoftazure/accelerate-your-nlp-pipelines-using-hugging-face-transformers-and-onnx-runtime-2443578f4333).
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### Configuration-based approach
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Transformers v4.9.0 introduces a new package: `transformers.onnx`. This package allows converting checkpoints to an
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ONNX graph by leveraging configuration objects. These configuration objects come ready made for a number of model
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architectures, and are made to be easily extendable to other architectures.
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Ready-made configurations include the following models:
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<!--This table is automatically generated by make style, do not fill manually!-->
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- ALBERT
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- BART
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- BERT
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- CamemBERT
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- DistilBERT
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- GPT Neo
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- LayoutLM
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- Longformer
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- mBART
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- OpenAI GPT-2
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- RoBERTa
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- T5
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- XLM-RoBERTa
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This conversion is handled with the PyTorch version of models - it, therefore, requires PyTorch to be installed. If you
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would like to be able to convert from TensorFlow, please let us know by opening an issue.
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<Tip>
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The models showcased here are close to fully feature complete, but do lack some features that are currently in
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development. Namely, the ability to handle the past key values for decoder models is currently in the works.
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</Tip>
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#### Converting an ONNX model using the `transformers.onnx` package
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The package may be used as a Python module:
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```bash
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python -m transformers.onnx --help
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usage: Hugging Face ONNX Exporter tool [-h] -m MODEL -f {pytorch} [--features {default}] [--opset OPSET] [--atol ATOL] output
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positional arguments:
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output Path indicating where to store generated ONNX model.
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optional arguments:
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-h, --help show this help message and exit
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-m MODEL, --model MODEL
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Model's name of path on disk to load.
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--features {default} Export the model with some additional features.
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--opset OPSET ONNX opset version to export the model with (default 12).
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--atol ATOL Absolute difference tolerance when validating the model.
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```
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Exporting a checkpoint using a ready-made configuration can be done as follows:
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```bash
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python -m transformers.onnx --model=bert-base-cased onnx/bert-base-cased/
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```
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This exports an ONNX graph of the mentioned checkpoint. Here it is *bert-base-cased*, but it can be any model from the
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hub, or a local path.
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It will be exported under `onnx/bert-base-cased`. You should see similar logs:
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```bash
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Validating ONNX model...
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-[✓] ONNX model outputs' name match reference model ({'pooler_output', 'last_hidden_state'}
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- Validating ONNX Model output "last_hidden_state":
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-[✓] (2, 8, 768) matchs (2, 8, 768)
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-[✓] all values close (atol: 0.0001)
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- Validating ONNX Model output "pooler_output":
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-[✓] (2, 768) matchs (2, 768)
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-[✓] all values close (atol: 0.0001)
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All good, model saved at: onnx/bert-base-cased/model.onnx
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```
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This export can now be used in the ONNX inference runtime:
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```python
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import onnxruntime as ort
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from transformers import BertTokenizerFast
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tokenizer = BertTokenizerFast.from_pretrained("bert-base-cased")
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ort_session = ort.InferenceSession("onnx/bert-base-cased/model.onnx")
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inputs = tokenizer("Using BERT in ONNX!", return_tensors="np")
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outputs = ort_session.run(["last_hidden_state", "pooler_output"], dict(inputs))
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```
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The outputs used (`["last_hidden_state", "pooler_output"]`) can be obtained by taking a look at the ONNX
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configuration of each model. For example, for BERT:
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```python
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from transformers.models.bert import BertOnnxConfig, BertConfig
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config = BertConfig()
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onnx_config = BertOnnxConfig(config)
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output_keys = list(onnx_config.outputs.keys())
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```
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#### Implementing a custom configuration for an unsupported architecture
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Let's take a look at the changes necessary to add a custom configuration for an unsupported architecture. Firstly, we
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will need a custom ONNX configuration object that details the model inputs and outputs. The BERT ONNX configuration is
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visible below:
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```python
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class BertOnnxConfig(OnnxConfig):
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@property
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def inputs(self) -> Mapping[str, Mapping[int, str]]:
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return OrderedDict(
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[
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("input_ids", {0: "batch", 1: "sequence"}),
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("attention_mask", {0: "batch", 1: "sequence"}),
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("token_type_ids", {0: "batch", 1: "sequence"}),
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]
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)
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@property
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def outputs(self) -> Mapping[str, Mapping[int, str]]:
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return OrderedDict([("last_hidden_state", {0: "batch", 1: "sequence"}), ("pooler_output", {0: "batch"})])
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```
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Let's understand what's happening here. This configuration has two properties: the inputs, and the outputs.
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The inputs return a dictionary, where each key corresponds to an expected input, and each value indicates the axis of
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that input.
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For BERT, there are three necessary inputs. These three inputs are of similar shape, which is made up of two
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dimensions: the batch is the first dimension, and the second is the sequence.
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The outputs return a similar dictionary, where, once again, each key corresponds to an expected output, and each value
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indicates the axis of that output.
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Once this is done, a single step remains: adding this configuration object to the initialisation of the model class,
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and to the general `transformers` initialisation.
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An important fact to notice is the use of *OrderedDict* in both inputs and outputs properties. This is a requirements
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as inputs are matched against their relative position within the *PreTrainedModel.forward()* prototype and outputs are
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match against there position in the returned *BaseModelOutputX* instance.
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An example of such an addition is visible here, for the MBart model: [Making MBART ONNX-convertible](https://github.com/huggingface/transformers/pull/13049/commits/d097adcebd89a520f04352eb215a85916934204f)
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If you would like to contribute your addition to the library, we recommend you implement tests. An example of such
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tests is visible here: [Adding tests to the MBART ONNX conversion](https://github.com/huggingface/transformers/pull/13049/commits/5d642f65abf45ceeb72bd855ca7bfe2506a58e6a)
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### Graph conversion
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<Tip>
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The approach detailed here is bing deprecated. We recommend you follow the part above for an up to date approach.
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</Tip>
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Exporting a model is done through the script *convert_graph_to_onnx.py* at the root of the transformers sources. The
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following command shows how easy it is to export a BERT model from the library, simply run:
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```bash
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python convert_graph_to_onnx.py --framework <pt, tf> --model bert-base-cased bert-base-cased.onnx
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```
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The conversion tool works for both PyTorch and Tensorflow models and ensures:
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- The model and its weights are correctly initialized from the Hugging Face model hub or a local checkpoint.
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- The inputs and outputs are correctly generated to their ONNX counterpart.
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- The generated model can be correctly loaded through onnxruntime.
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<Tip>
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Currently, inputs and outputs are always exported with dynamic sequence axes preventing some optimizations on the
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ONNX Runtime. If you would like to see such support for fixed-length inputs/outputs, please open up an issue on
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transformers.
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</Tip>
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Also, the conversion tool supports different options which let you tune the behavior of the generated model:
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- **Change the target opset version of the generated model.** (More recent opset generally supports more operators and
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enables faster inference)
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- **Export pipeline-specific prediction heads.** (Allow to export model along with its task-specific prediction
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head(s))
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- **Use the external data format (PyTorch only).** (Lets you export model which size is above 2Gb ([More info](https://github.com/pytorch/pytorch/pull/33062)))
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### Optimizations
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ONNXRuntime includes some transformers-specific transformations to leverage optimized operations in the graph. Below
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are some of the operators which can be enabled to speed up inference through ONNXRuntime (*see note below*):
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- Constant folding
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- Attention Layer fusing
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- Skip connection LayerNormalization fusing
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- FastGeLU approximation
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Some of the optimizations performed by ONNX runtime can be hardware specific and thus lead to different performances if
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used on another machine with a different hardware configuration than the one used for exporting the model. For this
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reason, when using `convert_graph_to_onnx.py` optimizations are not enabled, ensuring the model can be easily
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exported to various hardware. Optimizations can then be enabled when loading the model through ONNX runtime for
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inference.
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<Tip>
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When quantization is enabled (see below), `convert_graph_to_onnx.py` script will enable optimizations on the
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model because quantization would modify the underlying graph making it impossible for ONNX runtime to do the
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optimizations afterwards.
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</Tip>
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<Tip>
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For more information about the optimizations enabled by ONNXRuntime, please have a look at the [ONNXRuntime Github](https://github.com/microsoft/onnxruntime/tree/master/onnxruntime/python/tools/transformers).
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</Tip>
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### Quantization
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ONNX exporter supports generating a quantized version of the model to allow efficient inference.
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Quantization works by converting the memory representation of the parameters in the neural network to a compact integer
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format. By default, weights of a neural network are stored as single-precision float (*float32*) which can express a
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wide-range of floating-point numbers with decent precision. These properties are especially interesting at training
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where you want fine-grained representation.
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On the other hand, after the training phase, it has been shown one can greatly reduce the range and the precision of
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*float32* numbers without changing the performances of the neural network.
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More technically, *float32* parameters are converted to a type requiring fewer bits to represent each number, thus
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reducing the overall size of the model. Here, we are enabling *float32* mapping to *int8* values (a non-floating,
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single byte, number representation) according to the following formula:
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$$y_{float32} = scale * x_{int8} - zero\_point$$
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<Tip>
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The quantization process will infer the parameter *scale* and *zero_point* from the neural network parameters
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</Tip>
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Leveraging tiny-integers has numerous advantages when it comes to inference:
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- Storing fewer bits instead of 32 bits for the *float32* reduces the size of the model and makes it load faster.
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- Integer operations execute a magnitude faster on modern hardware
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- Integer operations require less power to do the computations
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In order to convert a transformers model to ONNX IR with quantized weights you just need to specify `--quantize` when
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using `convert_graph_to_onnx.py`. Also, you can have a look at the `quantize()` utility-method in this same script
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file.
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Example of quantized BERT model export:
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```bash
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python convert_graph_to_onnx.py --framework <pt, tf> --model bert-base-cased --quantize bert-base-cased.onnx
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```
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<Tip>
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Quantization support requires ONNX Runtime >= 1.4.0
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</Tip>
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<Tip>
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When exporting quantized model you will end up with two different ONNX files. The one specified at the end of the
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above command will contain the original ONNX model storing *float32* weights. The second one, with `-quantized`
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suffix, will hold the quantized parameters.
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</Tip>
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## TorchScript
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<Tip>
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This is the very beginning of our experiments with TorchScript and we are still exploring its capabilities with
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variable-input-size models. It is a focus of interest to us and we will deepen our analysis in upcoming releases,
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with more code examples, a more flexible implementation, and benchmarks comparing python-based codes with compiled
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TorchScript.
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</Tip>
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According to Pytorch's documentation: "TorchScript is a way to create serializable and optimizable models from PyTorch
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code". Pytorch's two modules [JIT and TRACE](https://pytorch.org/docs/stable/jit.html) allow the developer to export
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their model to be re-used in other programs, such as efficiency-oriented C++ programs.
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We have provided an interface that allows the export of 🤗 Transformers models to TorchScript so that they can be reused
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in a different environment than a Pytorch-based python program. Here we explain how to export and use our models using
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TorchScript.
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Exporting a model requires two things:
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- a forward pass with dummy inputs.
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- model instantiation with the `torchscript` flag.
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These necessities imply several things developers should be careful about. These are detailed below.
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### Implications
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### TorchScript flag and tied weights
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This flag is necessary because most of the language models in this repository have tied weights between their
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`Embedding` layer and their `Decoding` layer. TorchScript does not allow the export of models that have tied
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weights, therefore it is necessary to untie and clone the weights beforehand.
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This implies that models instantiated with the `torchscript` flag have their `Embedding` layer and `Decoding`
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layer separate, which means that they should not be trained down the line. Training would de-synchronize the two
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layers, leading to unexpected results.
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This is not the case for models that do not have a Language Model head, as those do not have tied weights. These models
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can be safely exported without the `torchscript` flag.
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### Dummy inputs and standard lengths
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The dummy inputs are used to do a model forward pass. While the inputs' values are propagating through the layers,
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Pytorch keeps track of the different operations executed on each tensor. These recorded operations are then used to
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create the "trace" of the model.
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The trace is created relatively to the inputs' dimensions. It is therefore constrained by the dimensions of the dummy
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input, and will not work for any other sequence length or batch size. When trying with a different size, an error such
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as:
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`The expanded size of the tensor (3) must match the existing size (7) at non-singleton dimension 2`
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will be raised. It is therefore recommended to trace the model with a dummy input size at least as large as the largest
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input that will be fed to the model during inference. Padding can be performed to fill the missing values. As the model
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will have been traced with a large input size however, the dimensions of the different matrix will be large as well,
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resulting in more calculations.
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It is recommended to be careful of the total number of operations done on each input and to follow performance closely
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when exporting varying sequence-length models.
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### Using TorchScript in Python
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Below is an example, showing how to save, load models as well as how to use the trace for inference.
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#### Saving a model
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This snippet shows how to use TorchScript to export a `BertModel`. Here the `BertModel` is instantiated according
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to a `BertConfig` class and then saved to disk under the filename `traced_bert.pt`
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```python
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from transformers import BertModel, BertTokenizer, BertConfig
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import torch
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enc = BertTokenizer.from_pretrained("bert-base-uncased")
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# Tokenizing input text
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text = "[CLS] Who was Jim Henson ? [SEP] Jim Henson was a puppeteer [SEP]"
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tokenized_text = enc.tokenize(text)
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# Masking one of the input tokens
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masked_index = 8
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tokenized_text[masked_index] = '[MASK]'
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indexed_tokens = enc.convert_tokens_to_ids(tokenized_text)
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segments_ids = [0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1]
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# Creating a dummy input
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tokens_tensor = torch.tensor([indexed_tokens])
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segments_tensors = torch.tensor([segments_ids])
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dummy_input = [tokens_tensor, segments_tensors]
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# Initializing the model with the torchscript flag
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# Flag set to True even though it is not necessary as this model does not have an LM Head.
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config = BertConfig(vocab_size_or_config_json_file=32000, hidden_size=768,
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num_hidden_layers=12, num_attention_heads=12, intermediate_size=3072, torchscript=True)
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# Instantiating the model
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model = BertModel(config)
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# The model needs to be in evaluation mode
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model.eval()
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# If you are instantiating the model with *from_pretrained* you can also easily set the TorchScript flag
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model = BertModel.from_pretrained("bert-base-uncased", torchscript=True)
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# Creating the trace
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traced_model = torch.jit.trace(model, [tokens_tensor, segments_tensors])
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torch.jit.save(traced_model, "traced_bert.pt")
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```
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#### Loading a model
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This snippet shows how to load the `BertModel` that was previously saved to disk under the name `traced_bert.pt`.
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We are re-using the previously initialised `dummy_input`.
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```python
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loaded_model = torch.jit.load("traced_bert.pt")
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loaded_model.eval()
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all_encoder_layers, pooled_output = loaded_model(*dummy_input)
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```
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#### Using a traced model for inference
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Using the traced model for inference is as simple as using its `__call__` dunder method:
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|
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```python
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traced_model(tokens_tensor, segments_tensors)
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```
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Reference in New Issue
Block a user