def predownload(nnDir):
import os
import sys
# change this property
NOMEROFF_NET_DIR = os.path.abspath(nnDir)
sys.path.append(NOMEROFF_NET_DIR)
from NomeroffNet.YoloV5Detector import Detector
detector = Detector()
detector.load()
from NomeroffNet.BBoxNpPoints import NpPointsCraft, getCvZoneRGB, convertCvZonesRGBtoBGR, reshapePoints
npPointsCraft = NpPointsCraft()
npPointsCraft.load()
from NomeroffNet.OptionsDetector import OptionsDetector
from NomeroffNet.TextDetector import TextDetector
from NomeroffNet.TextPostprocessing import textPostprocessing
# load models
optionsDetector = OptionsDetector()
optionsDetector.load("latest")
textDetector = TextDetector.get_static_module("eu")()
textDetector.load("latest")
return npPointsCraft, optionsDetector, textDetector, detector
import copy
# NomeroffNet path
NOMEROFF_NET_DIR = os.path.abspath('../../../')
sys.path.append(NOMEROFF_NET_DIR)
from NomeroffNet import __version__
from NomeroffNet.YoloV5Detector import Detector
detector = Detector()
detector.load()
from NomeroffNet.BBoxNpPoints import (NpPointsCraft, getCvZoneRGB,
convertCvZonesRGBtoBGR, reshapePoints)
npPointsCraft = NpPointsCraft()
npPointsCraft.load()
from NomeroffNet.OptionsDetector import OptionsDetector
from NomeroffNet.TextDetector import TextDetector
optionsDetector = OptionsDetector()
optionsDetector.load("latest")
# Initialize text detector.
textDetector = TextDetector({
"eu_ua_2004_2015": {
"for_regions": ["eu_ua_2015", "eu_ua_2004"],
"model_path": "latest"
},
"eu_ua_1995": {
def main():
args = parse_args()
res_model = args["craft_net_res"]
res_refine_model = args["craft_refine_net_res"]
batch_size = args["batch_size"]
n = args["number_tests"]
# get models
npPointsCraft = NpPointsCraft()
npPointsCraft.load()
net = npPointsCraft.net
refine_net = npPointsCraft.refine_net
print(net)
print(refine_net)
# xs define
x = torch.randn(batch_size, 3, 224, 224, requires_grad=True)
# to device
device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
net = net.to(device)
refine_net = refine_net.to(device)
x = x.to(device)
# predict
out1, out2 = net(x)
_ = refine_net(out1, out2)
# make dirs
p = pathlib.Path(os.path.dirname(res_model))
p.mkdir(parents=True, exist_ok=True)
p = pathlib.Path(os.path.dirname(res_refine_model))
p.mkdir(parents=True, exist_ok=True)
# Export the refine
torch.onnx.export(
refine_net, # model being run
(out1, out2), # model input (or a tuple for multiple inputs)
res_refine_model, # where to save the model (can be a file or file-like object)
export_params=
True, # store the trained parameter weights inside the model file
opset_version=10, # the ONNX version to export the model to
do_constant_folding=
True, # whether to execute constant folding for optimization
input_names=['refine_input',
'refine_feature'], # the model's input names
output_names=['refine_output'], # the model's output names
dynamic_axes={
'refine_input': {
0: 'batch_size',
1: 'width',
2: 'height'
},
'refine_feature': {
0: 'batch_size',
2: 'width',
3: 'height'
},
"refine_output": {
0: 'batch_size',
1: 'width',
2: 'height'
}
})
# Export the model
torch.onnx.export(
net, # model being run
x, # model input (or a tuple for multiple inputs)
res_model, # where to save the model (can be a file or file-like object)
export_params=
True, # store the trained parameter weights inside the model file
opset_version=10, # the ONNX version to export the model to
do_constant_folding=
True, # whether to execute constant folding for optimization
input_names=['input'], # the model's input names
output_names=['output', "284"], # the model's output names
dynamic_axes={
'input': {
0: 'batch_size',
2: 'width',
3: 'height'
},
'output': {
0: 'batch_size',
1: 'width',
2: 'height'
},
"284": {
0: 'batch_size',
2: 'width',
3: 'height'
}
})
# Test torch model
out1, out2 = net(x)
_ = refine_net(out1, out2)
start_time = time.time()
for _ in range(n):
out1, out2 = net(x)
_ = refine_net(out1, out2)
print(f"[INFO] torch time {(time.time() - start_time) / n * 1000}ms")
# Load onnx model
ort_session_craft = onnxruntime.InferenceSession(
res_model, providers=['CUDAExecutionProvider', 'CPUExecutionProvider'])
input_name = ort_session_craft.get_inputs()[0].name
ort_session_craft_refine = onnxruntime.InferenceSession(
res_refine_model,
providers=['CUDAExecutionProvider', 'CPUExecutionProvider'])
input_name_refine = "refine_input"
input_feather_name_refine = "refine_feature"
ort_inputs = {
input_name: np.random.randn(batch_size, 3, 224, 224).astype(np.float32)
}
# run onnx model
print(f"[INFO] available_providers", onnxruntime.get_available_providers())
out1, out2 = ort_session_craft.run(None, ort_inputs)
_ = ort_session_craft_refine.run(None, {
input_name_refine: out1,
input_feather_name_refine: out2
})
start_time = time.time()
for _ in range(n):
out1, out2 = ort_session_craft.run(None, ort_inputs)
_ = ort_session_craft_refine.run(None, {
input_name_refine: out1,
input_feather_name_refine: out2
})
print(f"[INFO] onnx time {(time.time() - start_time) / n * 1000}ms")
# NomeroffNet path
NOMEROFF_NET_DIR = os.path.abspath('../../')
sys.path.append(NOMEROFF_NET_DIR)
from NomeroffNet.YoloV5Detector import Detector
detector = Detector()
detector.load()
from NomeroffNet.BBoxNpPoints import (NpPointsCraft,
getCvZoneRGB,
convertCvZonesRGBtoBGR,
reshapePoints)
npPointsCraft = NpPointsCraft()
npPointsCraft.load()
from NomeroffNet.OptionsDetector import OptionsDetector
from NomeroffNet.TextDetector import TextDetector
optionsDetector = OptionsDetector()
optionsDetector.load("latest")
# Initialize text detector.
textDetector = TextDetector({
"eu_ua_2004_2015": {
"for_regions": ["eu_ua_2015", "eu_ua_2004"],
"model_path": "latest"
},
"eu_ua_1995": {