ruslo/from_mxnet.py

## from_mxnet.py
"""
.. _tutorial-from-mxnet:

Compile MXNet Models
====================
**Author**: `Joshua Z. Zhang <https://zhreshold.github.io/>`_

This article is an introductory tutorial to deploy mxnet models with NNVM.

For us to begin with, mxnet module is required to be installed.

A quick solution is

.. code-block:: bash

    pip install mxnet --user

or please refer to offical installation guide.
https://mxnet.incubator.apache.org/versions/master/install/index.html
"""
# some standard imports
import mxnet as mx
import nnvm
import tvm
import numpy as np

######################################################################
# Download Resnet18 model from Gluon Model Zoo
# ---------------------------------------------
# In this section, we download a pretrained imagenet model and classify an image.
from mxnet.gluon.model_zoo.vision import get_model
from mxnet.gluon.utils import download
from PIL import Image
block = get_model('resnet18_v1', pretrained=True)
img_name = 'cat.png'
synset_url = ''.join(['https://gist.githubusercontent.com/zhreshold/',
                      '4d0b62f3d01426887599d4f7ede23ee5/raw/',
                      '596b27d23537e5a1b5751d2b0481ef172f58b539/',
                      'imagenet1000_clsid_to_human.txt'])
synset_name = 'synset.txt'
download('https://github.com/dmlc/mxnet.js/blob/master/data/cat.png?raw=true', img_name)
download(synset_url, synset_name)
with open(synset_name) as f:
    synset = eval(f.read())
image = Image.open(img_name).resize((224, 224))

def transform_image(image):
    image = np.array(image) - np.array([123., 117., 104.])
    image /= np.array([58.395, 57.12, 57.375])
    image = image.transpose((2, 0, 1))
    image = image[np.newaxis, :]
    return image

x = transform_image(image)
print('x', x.shape)

######################################################################
# Compile the Graph
# -----------------
# Now we would like to port the Gluon model to a portable computational graph.
# It's as easy as several lines.
# We support MXNet static graph(symbol) and HybridBlock in mxnet.gluon
sym, params = nnvm.frontend.from_mxnet(block)
# we want a probability so add a softmax operator
sym = nnvm.sym.softmax(sym)

######################################################################
# now compile the graph
import nnvm.compiler
target = 'llvm' # <<<<<<<<<<<<<<<<<<<<<<<<<<< Configuration without GPU
shape_dict = {'data': x.shape}
with nnvm.compiler.build_config(opt_level=3):
    graph, lib, params = nnvm.compiler.build(sym, target, shape_dict, params=params)

######################################################################
# Execute the portable graph on TVM
# ---------------------------------
# Now, we would like to reproduce the same forward computation using TVM.
from tvm.contrib import graph_runtime
ctx = tvm.cpu(0) # <<<<<<<<<<<<<<<<<<<<<<<<<<<<<<< Configuration without GPU
dtype = 'float32'
m = graph_runtime.create(graph, lib, ctx)
# set inputs
m.set_input('data', tvm.nd.array(x.astype(dtype)))
m.set_input(**params)
# execute
m.run()
# get outputs
tvm_output = m.get_output(0)
top1 = np.argmax(tvm_output.asnumpy()[0])
print('TVM prediction top-1:', top1, synset[top1])

######################################################################
# Use MXNet symbol with pretrained weights
# ----------------------------------------
# MXNet often use `arg_params` and `aux_params` to store network parameters
# separately, here we show how to use these weights with existing API
def block2symbol(block):
    data = mx.sym.Variable('data')
    sym = block(data)
    args = {}
    auxs = {}
    for k, v in block.collect_params().items():
        args[k] = mx.nd.array(v.data().asnumpy())
    return sym, args, auxs
mx_sym, args, auxs = block2symbol(block)
# usually we would save/load it as checkpoint
mx.model.save_checkpoint('resnet18_v1', 0, mx_sym, args, auxs)
# there are 'resnet18_v1-0000.params' and 'resnet18_v1-symbol.json' on disk

######################################################################
# for a normal mxnet model, we start from here
mx_sym, args, auxs = mx.model.load_checkpoint('resnet18_v1', 0)
# now we use the same API to get NNVM compatible symbol
nnvm_sym, nnvm_params = nnvm.frontend.from_mxnet(mx_sym, args, auxs)
# repeat the same steps to run this model using TVM
	"""
	.. _tutorial-from-mxnet:

	Compile MXNet Models
	====================
	Author: `Joshua Z. Zhang <https://zhreshold.github.io/>`_

	This article is an introductory tutorial to deploy mxnet models with NNVM.

	For us to begin with, mxnet module is required to be installed.

	A quick solution is

	.. code-block:: bash

	pip install mxnet --user

	or please refer to offical installation guide.
	https://mxnet.incubator.apache.org/versions/master/install/index.html
	"""
	# some standard imports
	import mxnet as mx
	import nnvm
	import tvm
	import numpy as np

	######################################################################
	# Download Resnet18 model from Gluon Model Zoo
	# ---------------------------------------------
	# In this section, we download a pretrained imagenet model and classify an image.
	from mxnet.gluon.model_zoo.vision import get_model
	from mxnet.gluon.utils import download
	from PIL import Image
	block = get_model('resnet18_v1', pretrained=True)
	img_name = 'cat.png'
	synset_url = ''.join(['https://gist.githubusercontent.com/zhreshold/',
	'4d0b62f3d01426887599d4f7ede23ee5/raw/',
	'596b27d23537e5a1b5751d2b0481ef172f58b539/',
	'imagenet1000_clsid_to_human.txt'])
	synset_name = 'synset.txt'
	download('https://github.com/dmlc/mxnet.js/blob/master/data/cat.png?raw=true', img_name)
	download(synset_url, synset_name)
	with open(synset_name) as f:
	synset = eval(f.read())
	image = Image.open(img_name).resize((224, 224))

	def transform_image(image):
	image = np.array(image) - np.array([123., 117., 104.])
	image /= np.array([58.395, 57.12, 57.375])
	image = image.transpose((2, 0, 1))
	image = image[np.newaxis, :]
	return image

	x = transform_image(image)
	print('x', x.shape)

	######################################################################
	# Compile the Graph
	# -----------------
	# Now we would like to port the Gluon model to a portable computational graph.
	# It's as easy as several lines.
	# We support MXNet static graph(symbol) and HybridBlock in mxnet.gluon
	sym, params = nnvm.frontend.from_mxnet(block)
	# we want a probability so add a softmax operator
	sym = nnvm.sym.softmax(sym)

	######################################################################
	# now compile the graph
	import nnvm.compiler
	target = 'llvm' # <<<<<<<<<<<<<<<<<<<<<<<<<<< Configuration without GPU
	shape_dict = {'data': x.shape}
	with nnvm.compiler.build_config(opt_level=3):
	graph, lib, params = nnvm.compiler.build(sym, target, shape_dict, params=params)

	######################################################################
	# Execute the portable graph on TVM
	# ---------------------------------
	# Now, we would like to reproduce the same forward computation using TVM.
	from tvm.contrib import graph_runtime
	ctx = tvm.cpu(0) # <<<<<<<<<<<<<<<<<<<<<<<<<<<<<<< Configuration without GPU
	dtype = 'float32'
	m = graph_runtime.create(graph, lib, ctx)
	# set inputs
	m.set_input('data', tvm.nd.array(x.astype(dtype)))
	m.set_input(**params)
	# execute
	m.run()
	# get outputs
	tvm_output = m.get_output(0)
	top1 = np.argmax(tvm_output.asnumpy()[0])
	print('TVM prediction top-1:', top1, synset[top1])

	######################################################################
	# Use MXNet symbol with pretrained weights
	# ----------------------------------------
	# MXNet often use `arg_params` and `aux_params` to store network parameters
	# separately, here we show how to use these weights with existing API
	def block2symbol(block):
	data = mx.sym.Variable('data')
	sym = block(data)
	args = {}
	auxs = {}
	for k, v in block.collect_params().items():
	args[k] = mx.nd.array(v.data().asnumpy())
	return sym, args, auxs
	mx_sym, args, auxs = block2symbol(block)
	# usually we would save/load it as checkpoint
	mx.model.save_checkpoint('resnet18_v1', 0, mx_sym, args, auxs)
	# there are 'resnet18_v1-0000.params' and 'resnet18_v1-symbol.json' on disk

	######################################################################
	# for a normal mxnet model, we start from here
	mx_sym, args, auxs = mx.model.load_checkpoint('resnet18_v1', 0)
	# now we use the same API to get NNVM compatible symbol
	nnvm_sym, nnvm_params = nnvm.frontend.from_mxnet(mx_sym, args, auxs)
	# repeat the same steps to run this model using TVM