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template_manager_script_solo.py
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template_manager_script_solo.py
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"""
This file is the template of the scripting node source code in edge mode
Substitution is made in HandTrackerEdge.py
In the following:
rrn_ : normalized [0:1] coordinates in rotated rectangle coordinate systems
sqn_ : normalized [0:1] coordinates in squared input image
"""
import marshal
from math import sin, cos, atan2, pi, degrees, floor, dist
pad_h = ${_pad_h}
img_h = ${_img_h}
img_w = ${_img_w}
frame_size = ${_frame_size}
crop_w = ${_crop_w}
${_TRACE1} ("Starting manager script node")
${_IF_USE_HANDEDNESS_AVERAGE}
class HandednessAverage:
# Used to store the average handeness
# Why ? Handedness inferred by the landmark model is not perfect. For certain poses, it is not rare that the model thinks
# that a right hand is a left hand (or vice versa). Instead of using the last inferred handedness, we prefer to use the average
# of the inferred handedness on the last frames. This gives more robustness.
def __init__(self):
self._total_handedness = 0
self._nb = 0
def update(self, new_handedness):
self._total_handedness += new_handedness
self._nb += 1
return self._total_handedness / self._nb
def reset(self):
self._total_handedness = self._nb = 0
handedness_avg = HandednessAverage()
${_IF_USE_HANDEDNESS_AVERAGE}
# BufferMgr is used to statically allocate buffers once
# (replace dynamic allocation).
# These buffers are used for sending result to host
class BufferMgr:
def __init__(self):
self._bufs = {}
def __call__(self, size):
try:
buf = self._bufs[size]
except KeyError:
buf = self._bufs[size] = Buffer(size)
${_TRACE2} (f"New buffer allocated: {size}")
return buf
buffer_mgr = BufferMgr()
def send_result(result):
result_serial = marshal.dumps(result)
buffer = buffer_mgr(len(result_serial))
buffer.getData()[:] = result_serial
node.io['host'].send(buffer)
${_TRACE2} ("Manager sent result to host")
# pd_inf: boolean. Has the palm detection run on the frame ?
# nb_lm_inf: 0 or 1 (or 2 in duo mode). Number of landmark regression inferences on the frame.
# pd_inf=True and nb_lm_inf=0 means the palm detection hasn't found any hand
# pd_inf, nb_lm_inf are used for statistics
def send_result_no_hand(pd_inf, nb_lm_inf):
result = dict([("pd_inf", pd_inf), ("nb_lm_inf", nb_lm_inf)])
send_result(result)
def send_result_hand(pd_inf, nb_lm_inf, lm_score=0, handedness=0, rect_center_x=0, rect_center_y=0, rect_size=0, rotation=0, rrn_lms=0, sqn_lms=0, world_lms=0, xyz=0, xyz_zone=0):
result = dict([("pd_inf", pd_inf), ("nb_lm_inf", nb_lm_inf), ("lm_score", [lm_score]), ("handedness", [handedness]), ("rotation", [rotation]),
("rect_center_x", [rect_center_x]), ("rect_center_y", [rect_center_y]), ("rect_size", [rect_size]),
("rrn_lms", [rrn_lms]), ('sqn_lms', [sqn_lms]), ('world_lms', [world_lms]), ("xyz", [xyz]), ("xyz_zone", [xyz_zone])])
send_result(result)
def rr2img(rrn_x, rrn_y):
# Convert a point (rrn_x, rrn_y) expressed in normalized rotated rectangle (rrn)
# into (X, Y) expressed in normalized image (sqn)
X = sqn_rr_center_x + sqn_rr_size * ((rrn_x - 0.5) * cos_rot + (0.5 - rrn_y) * sin_rot)
Y = sqn_rr_center_y + sqn_rr_size * ((rrn_y - 0.5) * cos_rot + (rrn_x - 0.5) * sin_rot)
return X, Y
def normalize_radians(angle):
return angle - 2 * pi * floor((angle + pi) / (2 * pi))
# send_new_frame_to_branch defines on which branch new incoming frames are sent
# 1 = palm detection branch
# 2 = hand landmark branch
send_new_frame_to_branch = 1
cfg_pre_pd = ImageManipConfig()
cfg_pre_pd.setResizeThumbnail(128, 128, 0, 0, 0)
id_wrist = 0
id_index_mcp = 5
id_middle_mcp = 9
id_ring_mcp =13
ids_for_bounding_box = [0, 1, 2, 3, 5, 6, 9, 10, 13, 14, 17, 18]
lm_input_size = 224
while True:
nb_lm_inf = 0
if send_new_frame_to_branch == 1: # Routing frame to pd branch
node.io['pre_pd_manip_cfg'].send(cfg_pre_pd)
${_TRACE2} ("Manager sent thumbnail config to pre_pd manip")
# Wait for pd post processing's result
detection = node.io['from_post_pd_nn'].get().getLayerFp16("result")
${_TRACE2} (f"Manager received pd result (len={len(detection)}) : "+str(detection))
# detection is list of 2x8 float
# Currently we keep only the 8 first values as we are in solo mode
pd_score, box_x, box_y, box_size, kp0_x, kp0_y, kp2_x, kp2_y = detection[:8]
if pd_score < ${_pd_score_thresh} or box_size < 0:
send_result_no_hand(True, 0)
send_new_frame_to_branch = 1
${_TRACE1} (f"Palm detection - no hand detected")
continue
${_TRACE1} (f"Palm detection - hand detected")
# scale_center_x = sqn_scale_x - sqn_rr_center_x
# scale_center_y = sqn_scale_y - sqn_rr_center_y
kp02_x = kp2_x - kp0_x
kp02_y = kp2_y - kp0_y
sqn_rr_size = 2.9 * box_size
rotation = 0.5 * pi - atan2(-kp02_y, kp02_x)
rotation = normalize_radians(rotation)
sqn_rr_center_x = box_x + 0.5*box_size*sin(rotation)
sqn_rr_center_y = box_y - 0.5*box_size*cos(rotation)
# Tell pre_lm_manip how to crop hand region
rr = RotatedRect()
rr.center.x = sqn_rr_center_x
rr.center.y = (sqn_rr_center_y * frame_size - pad_h) / img_h
rr.size.width = sqn_rr_size
rr.size.height = sqn_rr_size * frame_size / img_h
rr.angle = degrees(rotation)
cfg = ImageManipConfig()
cfg.setCropRotatedRect(rr, True)
cfg.setResize(lm_input_size, lm_input_size)
node.io['pre_lm_manip_cfg'].send(cfg)
nb_lm_inf += 1
${_TRACE2} ("Manager sent config to pre_lm manip")
# Wait for lm's result
lm_result = node.io['from_lm_nn'].get()
${_TRACE2} ("Manager received result from lm nn")
lm_score = lm_result.getLayerFp16("Identity_1")[0]
if lm_score > ${_lm_score_thresh}:
handedness = lm_result.getLayerFp16("Identity_2")[0]
${_IF_USE_HANDEDNESS_AVERAGE}
handedness = handedness_avg.update(handedness)
${_IF_USE_HANDEDNESS_AVERAGE}
rrn_lms = lm_result.getLayerFp16("Identity_dense/BiasAdd/Add")
world_lms = 0
${_IF_USE_WORLD_LANDMARKS}
world_lms = lm_result.getLayerFp16("Identity_3_dense/BiasAdd/Add")
${_IF_USE_WORLD_LANDMARKS}
# Retroproject landmarks into the original squared image
sqn_lms = []
cos_rot = cos(rotation)
sin_rot = sin(rotation)
for i in range(21):
rrn_lms[3*i] /= lm_input_size
rrn_lms[3*i+1] /= lm_input_size
rrn_lms[3*i+2] /= lm_input_size #* 0.4
sqn_x, sqn_y = rr2img(rrn_lms[3*i], rrn_lms[3*i+1])
sqn_lms += [sqn_x, sqn_y]
xyz = 0
xyz_zone = 0
# Query xyz
${_IF_XYZ}
cfg = SpatialLocationCalculatorConfig()
conf_data = SpatialLocationCalculatorConfigData()
conf_data.depthThresholds.lowerThreshold = 100
conf_data.depthThresholds.upperThreshold = 10000
zone_size = max(int(sqn_rr_size * frame_size / 10), 8)
c_x = int(sqn_lms[0] * frame_size -zone_size/2 + crop_w)
c_y = int(sqn_lms[1] * frame_size -zone_size/2 - pad_h)
rect_center = Point2f(c_x, c_y)
rect_size = Size2f(zone_size, zone_size)
conf_data.roi = Rect(rect_center, rect_size)
cfg = SpatialLocationCalculatorConfig()
cfg.addROI(conf_data)
node.io['spatial_location_config'].send(cfg)
${_TRACE2} ("Manager sent ROI to spatial_location_config")
# Wait xyz response
xyz_data = node.io['spatial_data'].get().getSpatialLocations()
${_TRACE2} ("Manager received spatial_location")
coords = xyz_data[0].spatialCoordinates
xyz = [coords.x, coords.y, coords.z]
roi = xyz_data[0].config.roi
xyz_zone = [int(roi.topLeft().x - crop_w), int(roi.topLeft().y), int(roi.bottomRight().x - crop_w), int(roi.bottomRight().y)]
${_IF_XYZ}
# Send result to host
send_result_hand(send_new_frame_to_branch==1, nb_lm_inf, lm_score, handedness, sqn_rr_center_x, sqn_rr_center_y, sqn_rr_size, rotation, rrn_lms, sqn_lms, world_lms, xyz, xyz_zone)
send_new_frame_to_branch = 2
# Calculate the ROI for next frame
# Compute rotation
x0 = sqn_lms[0]
y0 = sqn_lms[1]
x1 = 0.25 * (sqn_lms[2*id_index_mcp] + sqn_lms[2*id_ring_mcp]) + 0.5 * sqn_lms[2*id_middle_mcp]
y1 = 0.25 * (sqn_lms[2*id_index_mcp+1] + sqn_lms[2*id_ring_mcp+1]) + 0.5 * sqn_lms[2*id_middle_mcp+1]
rotation = 0.5 * pi - atan2(y0 - y1, x1 - x0)
rotation = normalize_radians(rotation)
# Find boundaries of landmarks
min_x = min_y = 1
max_x = max_y = 0
for id in ids_for_bounding_box:
min_x = min(min_x, sqn_lms[2*id])
max_x = max(max_x, sqn_lms[2*id])
min_y = min(min_y, sqn_lms[2*id+1])
max_y = max(max_y, sqn_lms[2*id+1])
axis_aligned_center_x = 0.5 * (max_x + min_x)
axis_aligned_center_y = 0.5 * (max_y + min_y)
cos_rot = cos(rotation)
sin_rot = sin(rotation)
# Find boundaries of rotated landmarks
min_x = min_y = 1
max_x = max_y = -1
for id in ids_for_bounding_box:
original_x = sqn_lms[2*id] - axis_aligned_center_x
original_y = sqn_lms[2*id+1] - axis_aligned_center_y
projected_x = original_x * cos_rot + original_y * sin_rot
projected_y = -original_x * sin_rot + original_y * cos_rot
min_x = min(min_x, projected_x)
max_x = max(max_x, projected_x)
min_y = min(min_y, projected_y)
max_y = max(max_y, projected_y)
projected_center_x = 0.5 * (max_x + min_x)
projected_center_y = 0.5 * (max_y + min_y)
center_x = (projected_center_x * cos_rot - projected_center_y * sin_rot + axis_aligned_center_x)
center_y = (projected_center_x * sin_rot + projected_center_y * cos_rot + axis_aligned_center_y)
width = (max_x - min_x)
height = (max_y - min_y)
#
sqn_rr_size = 2 * max(width, height)
sqn_rr_center_x = (center_x + 0.1 * height * sin_rot)
sqn_rr_center_y = (center_y - 0.1 * height * cos_rot)
${_TRACE1} (f"Landmarks - hand confirmed")
else:
send_result_no_hand(send_new_frame_to_branch==1, nb_lm_inf)
send_new_frame_to_branch = 1
${_TRACE1} (f"Landmarks - hand not confirmed")
${_IF_USE_HANDEDNESS_AVERAGE}
handedness_avg.reset()
${_IF_USE_HANDEDNESS_AVERAGE}