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[Tutorial, QNN] Add tutorial for loading quantized PyTorch model (apa…
…che#5321) * add pytorch tutorial code and doc stub * add more docs * formatting, more docs * typo fix * try make sphinx happy * add performance section * type and nit fix * format fix
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# Licensed to the Apache Software Foundation (ASF) under one | ||
# or more contributor license agreements. See the NOTICE file | ||
# distributed with this work for additional information | ||
# regarding copyright ownership. The ASF licenses this file | ||
# to you under the Apache License, Version 2.0 (the | ||
# "License"); you may not use this file except in compliance | ||
# with the License. You may obtain a copy of the License at | ||
# | ||
# http://www.apache.org/licenses/LICENSE-2.0 | ||
# | ||
# Unless required by applicable law or agreed to in writing, | ||
# software distributed under the License is distributed on an | ||
# "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY | ||
# KIND, either express or implied. See the License for the | ||
# specific language governing permissions and limitations | ||
# under the License. | ||
""" | ||
Deploy a Framework-prequantized Model with TVM | ||
============================================== | ||
**Author**: `Masahiro Masuda <https://github.com/masahi>`_ | ||
This is a tutorial on loading models quantized by deep learning frameworks into TVM. | ||
Pre-quantized model import is one of the quantization support we have in TVM. More details on | ||
the quantization story in TVM can be found | ||
`here <https://discuss.tvm.ai/t/quantization-story/3920>`_. | ||
Here, we demonstrate how to load and run models quantized by PyTorch, MXNet, and TFLite. | ||
Once loaded, we can run compiled, quantized models on any hardware TVM supports. | ||
""" | ||
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################################################################################# | ||
# First, necessary imports | ||
from PIL import Image | ||
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import numpy as np | ||
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import torch | ||
from torchvision.models.quantization import mobilenet as qmobilenet | ||
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import tvm | ||
from tvm import relay | ||
from tvm.contrib.download import download_testdata | ||
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################################################################################# | ||
# Helper functions to run the demo | ||
def get_transform(): | ||
import torchvision.transforms as transforms | ||
normalize = transforms.Normalize(mean=[0.485, 0.456, 0.406], | ||
std=[0.229, 0.224, 0.225]) | ||
return transforms.Compose([ | ||
transforms.Resize(256), | ||
transforms.CenterCrop(224), | ||
transforms.ToTensor(), | ||
normalize, | ||
]) | ||
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def get_real_image(im_height, im_width): | ||
img_url = 'https://github.com/dmlc/mxnet.js/blob/master/data/cat.png?raw=true' | ||
img_path = download_testdata(img_url, 'cat.png', module='data') | ||
return Image.open(img_path).resize((im_height, im_width)) | ||
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def get_imagenet_input(): | ||
im = get_real_image(224, 224) | ||
preprocess = get_transform() | ||
pt_tensor = preprocess(im) | ||
return np.expand_dims(pt_tensor.numpy(), 0) | ||
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def get_synset(): | ||
synset_url = ''.join(['https://gist.githubusercontent.com/zhreshold/', | ||
'4d0b62f3d01426887599d4f7ede23ee5/raw/', | ||
'596b27d23537e5a1b5751d2b0481ef172f58b539/', | ||
'imagenet1000_clsid_to_human.txt']) | ||
synset_name = 'imagenet1000_clsid_to_human.txt' | ||
synset_path = download_testdata(synset_url, synset_name, module='data') | ||
with open(synset_path) as f: | ||
return eval(f.read()) | ||
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def run_tvm_model(mod, params, input_name, inp, target="llvm"): | ||
with relay.build_config(opt_level=3): | ||
json, lib, params = relay.build(mod, target=target, params=params) | ||
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runtime = tvm.contrib.graph_runtime.create(json, lib, tvm.context(target, 0)) | ||
runtime.set_input(**params) | ||
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runtime.set_input(input_name, inp) | ||
runtime.run() | ||
return runtime.get_output(0).asnumpy(), runtime | ||
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################################################################################# | ||
# A mapping from label to class name, to verify that the outputs from models below | ||
# are reasonable | ||
synset = get_synset() | ||
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################################################################################# | ||
# Everyone's favorite cat image for demonstration | ||
inp = get_imagenet_input() | ||
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################################################################################ | ||
# Deploy a quantized PyTorch Model | ||
# -------------------------------- | ||
# First, we demonstrate how to load deep learning models quantized by PyTorch, | ||
# using our PyTorch frontend. | ||
# | ||
# Please refer to the PyTorch static quantization tutorial below to learn about | ||
# their quantization workflow. | ||
# https://pytorch.org/tutorials/advanced/static_quantization_tutorial.html | ||
# | ||
# We use this function to quantize PyTorch models. | ||
# In short, this function takes a floating point model and converts it to uint8. | ||
# The model is per-channel quantized. | ||
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def quantize_model(model, inp): | ||
model.fuse_model() | ||
model.qconfig = torch.quantization.get_default_qconfig('fbgemm') | ||
torch.quantization.prepare(model, inplace=True) | ||
# Dummy calibration | ||
model(inp) | ||
torch.quantization.convert(model, inplace=True) | ||
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############################################################################## | ||
# Load quantization-ready, pretrained Mobilenet v2 model from torchvision | ||
# ----------------------------------------------------------------------- | ||
# We choose mobilenet v2 because this model was trained with quantization aware | ||
# training. Other models require a full post training calibration. | ||
qmodel = qmobilenet.mobilenet_v2(pretrained=True).eval() | ||
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############################################################################## | ||
# Quantize, trace and run the PyTorch Mobilenet v2 model | ||
# ------------------------------------------------------ | ||
# The details are out of scope for this tutorial. Please refer to the tutorials | ||
# on the PyTorch website to learn about quantization and jit. | ||
pt_inp = torch.from_numpy(inp) | ||
quantize_model(qmodel, pt_inp) | ||
script_module = torch.jit.trace(qmodel, pt_inp).eval() | ||
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with torch.no_grad(): | ||
pt_result = script_module(pt_inp).numpy() | ||
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############################################################################## | ||
# Convert quantized Mobilenet v2 to Relay-QNN using the PyTorch frontend | ||
# ---------------------------------------------------------------------- | ||
# The PyTorch frontend has support for converting a quantized PyTorch model to | ||
# an equivalent Relay module enriched with quantization-aware operators. | ||
# We call this representation Relay QNN dialect. | ||
# | ||
# You can print the output from the frontend to see how quantized models are | ||
# represented. | ||
# | ||
# You would see operators specific to quantization such as | ||
# qnn.quantize, qnn.dequantize, qnn.requantize, and qnn.conv2d etc. | ||
input_name = "input" # the input name can be be arbitrary for PyTorch frontend. | ||
input_shapes = [(input_name, (1, 3, 224, 224))] | ||
mod, params = relay.frontend.from_pytorch(script_module, input_shapes) | ||
# print(mod) # comment in to see the QNN IR dump | ||
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############################################################################## | ||
# Compile and run the Relay module | ||
# -------------------------------- | ||
# Once we obtained the quantized Relay module, the rest of the workflow | ||
# is the same as running floating point models. Please refer to other | ||
# tutorials for more details. | ||
# | ||
# Under the hood, quantization specific operators are lowered to a sequence of | ||
# standard Relay operators before compilation. | ||
tvm_result, rt_mod = run_tvm_model(mod, params, input_name, inp, target="llvm") | ||
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########################################################################## | ||
# Compare the output labels | ||
# ------------------------- | ||
# We should see identical labels printed. | ||
pt_top3_labels = np.argsort(pt_result[0])[::-1][:3] | ||
tvm_top3_labels = np.argsort(tvm_result[0])[::-1][:3] | ||
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print("PyTorch top3 labels:", [synset[label] for label in pt_top3_labels]) | ||
print("TVM top3 labels:", [synset[label] for label in tvm_top3_labels]) | ||
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########################################################################################### | ||
# However, due to the difference in numerics, in general the raw floating point | ||
# outputs are not expected to be identical. Here, we print how many floating point | ||
# output values are identical out of 1000 outputs from mobilenet v2. | ||
print("%d in 1000 raw floating outputs identical." % np.sum(tvm_result[0] == pt_result[0])) | ||
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########################################################################## | ||
# Measure performance | ||
# ------------------------- | ||
# Here we give an example of how to measure performance of TVM compiled models. | ||
n_repeat = 100 # should be bigger to make the measurement more accurate | ||
ctx = tvm.cpu(0) | ||
ftimer = rt_mod.module.time_evaluator("run", ctx, number=1, | ||
repeat=n_repeat) | ||
prof_res = np.array(ftimer().results) * 1e3 | ||
print("Elapsed average ms:", np.mean(prof_res)) | ||
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###################################################################### | ||
# .. note:: | ||
# | ||
# We recommend this method for the following reasons: | ||
# | ||
# * Measurements are done in C++, so there is no Python overhead | ||
# * It includes several warm up runs | ||
# * The same method can be used to profile on remote devices (android etc.). | ||
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###################################################################### | ||
# .. note:: | ||
# | ||
# Unless the hardware has special support for fast 8 bit instructions, quantized models are | ||
# not expected to be any faster than FP32 models. Without fast 8 bit instructions, TVM does | ||
# quantized convolution in 16 bit, even if the model itself is 8 bit. | ||
# | ||
# For x86, the best performance can be achieved on CPUs with AVX512 instructions set. | ||
# In this case, TVM utilizes the fastest available 8 bit instructions for the given target. | ||
# This includes support for the VNNI 8 bit dot product instruction (CascadeLake or newer). | ||
# | ||
# Moreover, the following general tips for CPU performance equally applies: | ||
# | ||
# * Set the environment variable TVM_NUM_THREADS to the number of physical cores | ||
# * Choose the best target for your hardware, such as "llvm -mcpu=skylake-avx512" or | ||
# "llvm -mcpu=cascadelake" (more CPUs with AVX512 would come in the future) | ||
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############################################################################### | ||
# Deploy a quantized MXNet Model | ||
# ------------------------------ | ||
# TODO | ||
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############################################################################### | ||
# Deploy a quantized TFLite Model | ||
# ------------------------------- | ||
# TODO |
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