tools/test_generator/spec_visualizer.py - platform/packages/modules/NeuralNetworks - Git at Google

 #!/usr/bin/python3

 # Copyright 2019, The Android Open Source Project
 #
 # Licensed 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.

 """Spec Visualizer

 Visualize python spec file for test generator.
 Invoked by ml/nn/runtime/test/specs/visualize_spec.sh;
 See that script for details on how this script is used.
 """

 from __future__ import absolute_import
 from __future__ import division
 from __future__ import print_function
 import argparse
 import json
 import os
 import sys
 from string import Template

 # Stuff from test generator
 import test_generator as tg
 from test_generator import ActivationConverter
 from test_generator import BoolScalar
 from test_generator import Configuration
 from test_generator import DataTypeConverter
 from test_generator import DataLayoutConverter
 from test_generator import Example
 from test_generator import Float16Scalar
 from test_generator import Float32Scalar
 from test_generator import Float32Vector
 from test_generator import GetJointStr
 from test_generator import IgnoredOutput
 from test_generator import Input
 from test_generator import Int32Scalar
 from test_generator import Int32Vector
 from test_generator import Internal
 from test_generator import Model
 from test_generator import Operand
 from test_generator import Output
 from test_generator import Parameter
 from test_generator import RelaxedModeConverter
 from test_generator import SymmPerChannelQuantParams


 TEMPLATE_FILE = os.path.join(os.path.dirname(os.path.realpath(__file__)), "spec_viz_template.html")
 global_graphs = dict()


 def FormatArray(data, is_scalar=False):
     if is_scalar:
         assert len(data) == 1
         return str(data[0])
     else:
         return "[%s]" % (", ".join(str(i) for i in data))


 def FormatDict(data):
     return "<br/>".join("<b>%s:</b> %s"%(k.capitalize(), v) for k, v in data.items())


 def GetOperandInfo(op):
     op_info = {"lifetime": op.lifetime, "type": op.type.type}

     if not op.type.IsScalar():
         op_info["dimensions"] = FormatArray(op.type.dimensions)

     if op.type.scale != 0:
         op_info["scale"] = op.type.scale
         op_info["zero point"] = op.type.zeroPoint
     if op.type.type == "TENSOR_QUANT8_SYMM_PER_CHANNEL":
         op_info["scale"] = FormatArray(op.type.extraParams.scales)
         op_info["channel dim"] = op.type.extraParams.channelDim

     return op_info


 def FormatOperand(op):
     # All keys and values in op_info will appear in the tooltip. We only display the operand data
     # if the length is less than 10. This should be convenient enough for most parameters.
     op_info = GetOperandInfo(op)
     if isinstance(op, Parameter) and len(op.value) <= 10:
         op_info["data"] = FormatArray(op.value, op.type.IsScalar())

     template = "<span class='tooltip'><span class='tooltipcontent'>{tooltip_content}</span><a href=\"{inpage_link}\">{op_name}</a></span>"
     return template.format(
         op_name=str(op),
         tooltip_content=FormatDict(op_info),
         inpage_link="#details-operands-%d" % (op.model_index),
     )


 def GetSubgraph(example):
     """Produces the nodes and edges information for d3 visualization."""

     node_index_map = {}
     topological_order = []

     def AddToTopologicalOrder(op):
         if op not in node_index_map:
             node_index_map[op] = len(topological_order)
             topological_order.append(op)

     # Get the topological order, both operands and operations are treated the same.
     # Given that the example.model.operations is already topologically sorted, here we simply
     # iterate through and insert inputs and outputs.
     for op in example.model.operations:
         for i in op.ins:
             AddToTopologicalOrder(i)
         AddToTopologicalOrder(op)
         for o in op.outs:
             AddToTopologicalOrder(o)

     # Assign layers to the nodes.
     layers = {}
     for node in topological_order:
         layers[node] = max([layers[i] for i in node.ins], default=-1) + 1
     for node in reversed(topological_order):
         layers[node] = min([layers[o] for o in node.outs], default=layers[node]+1) - 1
     num_layers = max(layers.values()) + 1

     # Assign coordinates to the nodes. Nodes are equally spaced.
     CoordX = lambda index: (index + 0.5) * 200  # 200px spacing horizontally
     CoordY = lambda index: (index + 0.5) * 100  # 100px spacing vertically
     coords = {}
     layer_cnt = [0] * num_layers
     for node in topological_order:
         coords[node] = (CoordX(layer_cnt[layers[node]]), CoordY(layers[node]))
         layer_cnt[layers[node]] += 1

     # Create edges and nodes dictionaries for d3 visualization.
     OpName = lambda idx: "operation%d" % idx
     edges = []
     nodes = []
     for ind, op in enumerate(example.model.operations):
         for tensor in op.ins:
             edges.append({
                 "source": str(tensor),
                 "target": OpName(ind)
             })
         for tensor in op.outs:
             edges.append({
                 "target": str(tensor),
                 "source": OpName(ind)
             })
         nodes.append({
             "index": ind,
             "id": OpName(ind),
             "name": op.optype,
             "group": 2,
             "x": coords[op][0],
             "y": coords[op][1],
         })

     for ind, op in enumerate(example.model.operands):
         nodes.append({
             "index": ind,
             "id": str(op),
             "name": str(op),
             "group": 1,
             "x": coords[op][0],
             "y": coords[op][1],
         })

     return {"nodes": nodes, "edges": edges}


 # The following Get**Info methods will each return a list of dictionaries,
 # whose content will appear in the tables and sidebar views.
 def GetConfigurationsInfo(example):
     return [{
         "relaxed": str(example.model.isRelaxed),
         "use shared memory": str(tg.Configuration.useSHM()),
         "expect failure": str(example.expectFailure),
     }]


 def GetOperandsInfo(example):
     ret = []
     for index, op in enumerate(example.model.operands):
         ret.append({
                 "index": index,
                 "name": str(op),
                 "group": "operand"
             })
         ret[-1].update(GetOperandInfo(op))
         if isinstance(op, (Parameter, Input, Output)):
             ret[-1]["data"] = FormatArray(op.value, op.type.IsScalar())
     return ret


 def GetOperationsInfo(example):
     return [{
             "index": index,
             "name": op.optype,
             "group": "operation",
             "opcode": op.optype,
             "inputs": ", ".join(FormatOperand(i) for i in op.ins),
             "outputs": ", ".join(FormatOperand(o) for o in op.outs),
         } for index,op in enumerate(example.model.operations)]


 # TODO: Remove the unused fd from the parameter.
 def ProcessExample(example, fd):
     """Process an example and save the information into the global dictionary global_graphs."""

     global global_graphs
     print("    Processing variation %s" % example.testName)
     global_graphs[str(example.testName)] = {
         "subgraph": GetSubgraph(example),
         "details": {
             "configurations": GetConfigurationsInfo(example),
             "operands": GetOperandsInfo(example),
             "operations": GetOperationsInfo(example)
         }
     }


 def DumpHtml(spec_file, out_file):
     """Dump the final HTML file by replacing entries from a template file."""

     with open(TEMPLATE_FILE, "r") as template_fd:
         html_template = template_fd.read()

     with open(out_file, "w") as out_fd:
         out_fd.write(Template(html_template).substitute(
             spec_name=os.path.basename(spec_file),
             graph_dump=json.dumps(global_graphs),
         ))


 def ParseCmdLine():
     parser = argparse.ArgumentParser()
     parser.add_argument("spec", help="the spec file")
     parser.add_argument("-o", "--out", help="the output html path", default="out.html")
     args = parser.parse_args()
     tg.FileNames.InitializeFileLists(args.spec, "-")
     tg.FileNames.NextFile()
     return os.path.abspath(args.spec), os.path.abspath(args.out)


 if __name__ == '__main__':
     spec_file, out_file = ParseCmdLine()
     print("Visualizing from spec: %s" % spec_file)
     exec(open(spec_file, "r").read())
     Example.DumpAllExamples(DumpExample=ProcessExample, example_fd=0)
     DumpHtml(spec_file, out_file)
     print("Output HTML file: %s" % out_file)
	#!/usr/bin/python3

	# Copyright 2019, The Android Open Source Project
	#
	# Licensed 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.

	"""Spec Visualizer

	Visualize python spec file for test generator.
	Invoked by ml/nn/runtime/test/specs/visualize_spec.sh;
	See that script for details on how this script is used.
	"""

	from __future__ import absolute_import
	from __future__ import division
	from __future__ import print_function
	import argparse
	import json
	import os
	import sys
	from string import Template

	# Stuff from test generator
	import test_generator as tg
	from test_generator import ActivationConverter
	from test_generator import BoolScalar
	from test_generator import Configuration
	from test_generator import DataTypeConverter
	from test_generator import DataLayoutConverter
	from test_generator import Example
	from test_generator import Float16Scalar
	from test_generator import Float32Scalar
	from test_generator import Float32Vector
	from test_generator import GetJointStr
	from test_generator import IgnoredOutput
	from test_generator import Input
	from test_generator import Int32Scalar
	from test_generator import Int32Vector
	from test_generator import Internal
	from test_generator import Model
	from test_generator import Operand
	from test_generator import Output
	from test_generator import Parameter
	from test_generator import RelaxedModeConverter
	from test_generator import SymmPerChannelQuantParams


	TEMPLATE_FILE = os.path.join(os.path.dirname(os.path.realpath(__file__)), "spec_viz_template.html")
	global_graphs = dict()


	def FormatArray(data, is_scalar=False):
	if is_scalar:
	assert len(data) == 1
	return str(data[0])
	else:
	return "[%s]" % (", ".join(str(i) for i in data))


	def FormatDict(data):
	return "<br/>".join("<b>%s:</b> %s"%(k.capitalize(), v) for k, v in data.items())


	def GetOperandInfo(op):
	op_info = {"lifetime": op.lifetime, "type": op.type.type}

	if not op.type.IsScalar():
	op_info["dimensions"] = FormatArray(op.type.dimensions)

	if op.type.scale != 0:
	op_info["scale"] = op.type.scale
	op_info["zero point"] = op.type.zeroPoint
	if op.type.type == "TENSOR_QUANT8_SYMM_PER_CHANNEL":
	op_info["scale"] = FormatArray(op.type.extraParams.scales)
	op_info["channel dim"] = op.type.extraParams.channelDim

	return op_info


	def FormatOperand(op):
	# All keys and values in op_info will appear in the tooltip. We only display the operand data
	# if the length is less than 10. This should be convenient enough for most parameters.
	op_info = GetOperandInfo(op)
	if isinstance(op, Parameter) and len(op.value) <= 10:
	op_info["data"] = FormatArray(op.value, op.type.IsScalar())

	template = "<span class='tooltip'><span class='tooltipcontent'>{tooltip_content}</span><a href=\"{inpage_link}\">{op_name}</a></span>"
	return template.format(
	op_name=str(op),
	tooltip_content=FormatDict(op_info),
	inpage_link="#details-operands-%d" % (op.model_index),
	)


	def GetSubgraph(example):
	"""Produces the nodes and edges information for d3 visualization."""

	node_index_map = {}
	topological_order = []

	def AddToTopologicalOrder(op):
	if op not in node_index_map:
	node_index_map[op] = len(topological_order)
	topological_order.append(op)

	# Get the topological order, both operands and operations are treated the same.
	# Given that the example.model.operations is already topologically sorted, here we simply
	# iterate through and insert inputs and outputs.
	for op in example.model.operations:
	for i in op.ins:
	AddToTopologicalOrder(i)
	AddToTopologicalOrder(op)
	for o in op.outs:
	AddToTopologicalOrder(o)

	# Assign layers to the nodes.
	layers = {}
	for node in topological_order:
	layers[node] = max([layers[i] for i in node.ins], default=-1) + 1
	for node in reversed(topological_order):
	layers[node] = min([layers[o] for o in node.outs], default=layers[node]+1) - 1
	num_layers = max(layers.values()) + 1

	# Assign coordinates to the nodes. Nodes are equally spaced.
	CoordX = lambda index: (index + 0.5) * 200 # 200px spacing horizontally
	CoordY = lambda index: (index + 0.5) * 100 # 100px spacing vertically
	coords = {}
	layer_cnt = [0] * num_layers
	for node in topological_order:
	coords[node] = (CoordX(layer_cnt[layers[node]]), CoordY(layers[node]))
	layer_cnt[layers[node]] += 1

	# Create edges and nodes dictionaries for d3 visualization.
	OpName = lambda idx: "operation%d" % idx
	edges = []
	nodes = []
	for ind, op in enumerate(example.model.operations):
	for tensor in op.ins:
	edges.append({
	"source": str(tensor),
	"target": OpName(ind)
	})
	for tensor in op.outs:
	edges.append({
	"target": str(tensor),
	"source": OpName(ind)
	})
	nodes.append({
	"index": ind,
	"id": OpName(ind),
	"name": op.optype,
	"group": 2,
	"x": coords[op][0],
	"y": coords[op][1],
	})

	for ind, op in enumerate(example.model.operands):
	nodes.append({
	"index": ind,
	"id": str(op),
	"name": str(op),
	"group": 1,
	"x": coords[op][0],
	"y": coords[op][1],
	})

	return {"nodes": nodes, "edges": edges}


	# The following Get**Info methods will each return a list of dictionaries,
	# whose content will appear in the tables and sidebar views.
	def GetConfigurationsInfo(example):
	return [{
	"relaxed": str(example.model.isRelaxed),
	"use shared memory": str(tg.Configuration.useSHM()),
	"expect failure": str(example.expectFailure),
	}]


	def GetOperandsInfo(example):
	ret = []
	for index, op in enumerate(example.model.operands):
	ret.append({
	"index": index,
	"name": str(op),
	"group": "operand"
	})
	ret[-1].update(GetOperandInfo(op))
	if isinstance(op, (Parameter, Input, Output)):
	ret[-1]["data"] = FormatArray(op.value, op.type.IsScalar())
	return ret


	def GetOperationsInfo(example):
	return [{
	"index": index,
	"name": op.optype,
	"group": "operation",
	"opcode": op.optype,
	"inputs": ", ".join(FormatOperand(i) for i in op.ins),
	"outputs": ", ".join(FormatOperand(o) for o in op.outs),
	} for index,op in enumerate(example.model.operations)]


	# TODO: Remove the unused fd from the parameter.
	def ProcessExample(example, fd):
	"""Process an example and save the information into the global dictionary global_graphs."""

	global global_graphs
	print(" Processing variation %s" % example.testName)
	global_graphs[str(example.testName)] = {
	"subgraph": GetSubgraph(example),
	"details": {
	"configurations": GetConfigurationsInfo(example),
	"operands": GetOperandsInfo(example),
	"operations": GetOperationsInfo(example)
	}
	}


	def DumpHtml(spec_file, out_file):
	"""Dump the final HTML file by replacing entries from a template file."""

	with open(TEMPLATE_FILE, "r") as template_fd:
	html_template = template_fd.read()

	with open(out_file, "w") as out_fd:
	out_fd.write(Template(html_template).substitute(
	spec_name=os.path.basename(spec_file),
	graph_dump=json.dumps(global_graphs),
	))


	def ParseCmdLine():
	parser = argparse.ArgumentParser()
	parser.add_argument("spec", help="the spec file")
	parser.add_argument("-o", "--out", help="the output html path", default="out.html")
	args = parser.parse_args()
	tg.FileNames.InitializeFileLists(args.spec, "-")
	tg.FileNames.NextFile()
	return os.path.abspath(args.spec), os.path.abspath(args.out)


	if __name__ == '__main__':
	spec_file, out_file = ParseCmdLine()
	print("Visualizing from spec: %s" % spec_file)
	exec(open(spec_file, "r").read())
	Example.DumpAllExamples(DumpExample=ProcessExample, example_fd=0)
	DumpHtml(spec_file, out_file)
	print("Output HTML file: %s" % out_file)