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template_manager_script_bpf_duo.py
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template_manager_script_bpf_duo.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}
${_TRACE1} ("Starting manager script node")
single_hand_count = 0
# Note that the output of the movenet model is a list named 'body' of 17*3 elements
# The information for the ith keypoint is :
# y coord: body[3*i]
# x coord: body[1+3*i]
# score : body[2+3*i]
body_score_thresh=${_body_score_thresh}
hands_up_only = ${_hands_up_only}
BODY_KP = {
'nose': 0,
'left_eye': 1,
'right_eye': 2,
'left_ear': 3,
'right_ear': 4,
'left_shoulder': 5,
'right_shoulder': 6,
'left_elbow': 7,
'right_elbow': 8,
'left_wrist': 9,
'right_wrist': 10,
'left_hip': 11,
'right_hip': 12,
'left_knee': 13,
'right_knee': 14,
'left_ankle': 15,
'right_ankle': 16
}
torso_joints = [BODY_KP["left_hip"], BODY_KP["right_hip"], BODY_KP["left_shoulder"], BODY_KP["right_shoulder"]]
# For Movenet smart croppping, defines the default crop region (pads the full image from both sides to make it a square image)
# Used when the algorithm cannot reliably determine the crop region from the previous frame.
init_crop_region = {'xmin': 0, 'ymin': -pad_h, 'xmax': frame_size, 'ymax': -pad_h+frame_size, 'size': frame_size}
crop_region = init_crop_region
def torso_visible(scores):
# Checks whether there are enough torso keypoints.
# This function checks whether the model is confident at predicting one of the
# shoulders/hips which is required to determine a good crop region.
return ((scores[BODY_KP["left_hip"]] > body_score_thresh or
scores[BODY_KP["right_hip"]] > body_score_thresh) and
(scores[BODY_KP["left_shoulder"]] > body_score_thresh or
scores[BODY_KP["right_shoulder"]] > body_score_thresh))
def determine_torso_and_body_range(x, y, scores, center_x, center_y):
# Calculates the maximum distance from each keypoints to the center location.
# The function returns the maximum distances from the two sets of keypoints:
# full 17 keypoints and 4 torso keypoints. The returned information will be
# used to determine the crop size. See determine_crop_region for more detail.
max_torso_yrange = 0.0
max_torso_xrange = 0.0
for i in torso_joints:
dist_y = abs(center_y - y[i])
dist_x = abs(center_x - x[i])
if dist_y > max_torso_yrange:
max_torso_yrange = dist_y
if dist_x > max_torso_xrange:
max_torso_xrange = dist_x
max_body_yrange = 0.0
max_body_xrange = 0.0
for i in range(17):
if scores[i] < body_score_thresh:
continue
dist_y = abs(center_y - y[i])
dist_x = abs(center_x - x[i])
if dist_y > max_body_yrange:
max_body_yrange = dist_y
if dist_x > max_body_xrange:
max_body_xrange = dist_x
return [max_torso_yrange, max_torso_xrange, max_body_yrange, max_body_xrange]
def determine_crop_region(scores, x, y):
# Determines the region to crop the image for the model to run inference on.
# The algorithm uses the detected joints from the previous frame to estimate
# the square region that encloses the full body of the target person and
# centers at the midpoint of two hip joints. The crop size is determined by
# the distances between each joints and the center point.
# When the model is not confident with the four torso joint predictions, the
# function returns a default crop which is the full image padded to square.
if torso_visible(scores):
center_x = (x[11] + x[12]) // 2
center_y = (y[11] + y[12]) // 2
max_torso_yrange, max_torso_xrange, max_body_yrange, max_body_xrange = determine_torso_and_body_range(x, y, scores, center_x, center_y)
crop_length_half = max(max_torso_xrange * 1.9, max_torso_yrange * 1.9, max_body_yrange * 1.2, max_body_xrange * 1.2)
crop_length_half = int(round(min(crop_length_half, max(center_x, img_w - center_x, center_y, img_h - center_y))))
crop_corner = [center_x - crop_length_half, center_y - crop_length_half]
if crop_length_half > max(img_w, img_h) / 2:
return init_crop_region
else:
crop_length = crop_length_half * 2
return {'xmin': crop_corner[0], 'ymin': crop_corner[1], 'xmax': crop_corner[0]+crop_length, 'ymax': crop_corner[1]+crop_length, 'size': crop_length}
else:
return init_crop_region
def movenet_postprocess(body, crop_region):
size = crop_region['size']
xmin = crop_region['xmin']
ymin = crop_region['ymin']
scores = []
x = []
y = []
for i in range(17):
xn = body[3*i+1]
yn = body[3*i]
scores.append(body[3*i+2])
# x any are the body keypoint coordinates in the source image in pixels
x.append(int(xmin + xn * size))
y.append(int(ymin + yn * size))
next_crop_region = determine_crop_region(scores, x, y)
return x, y, scores, next_crop_region
def estimate_focus_zone_size(scale=1.0):
segments = [
("left_shoulder", "left_elbow", 2.3),
("left_elbow", "left_wrist", 2.3),
("left_shoulder", "left_hip", 1),
("left_shoulder", "right_shoulder", 1.5),
("right_shoulder", "right_elbow", 2.3),
("right_elbow", "right_wrist", 2.3),
("right_shoulder", "right_hip", 1),
]
lengths = []
for s in segments:
id0 = BODY_KP[s[0]]
id1 = BODY_KP[s[1]]
if body_scores[id0] > body_score_thresh and body_scores[id1] > body_score_thresh:
l = dist((body_x[id0],body_y[id0]), (body_x[id1],body_y[id1]))
lengths.append(l)
if lengths:
if ( body_scores[BODY_KP["left_hip"]] < body_score_thresh and
body_scores[BODY_KP["right_hip"]] < body_score_thresh or
body_scores[BODY_KP["left_shoulder"]] < body_score_thresh and
body_scores[BODY_KP["right_shoulder"]] < body_score_thresh) :
coef = 1.0
else:
coef = 1.0
return 2 * int(coef * scale * max(lengths) / 2) # The size is made even
# return coef * scale * max(lengths)
else:
return 0
def zone_from_center_size(x, y, size):
# Return zone [left, top, right, bottom]
# from zone center (x,y) and zone size (the zone is square).
half_size = size // 2
size = half_size * 2
if size > img_w:
x = img_w // 2
x1 = x - half_size
if x1 < 0:
x1 = 0
elif x1 + size > img_w:
x1 = img_w - size
x2 = x1 + size
if size > img_h:
y = img_h // 2
y1 = y - half_size
if y1 < -pad_h:
y1 = -pad_h
elif y1 + size > img_h + pad_h:
y1 = img_h + pad_h - size
y2 = y1 + size
return [x1, y1, x2, y2]
def get_one_hand_zone(hand_label):
# Return the zone [left, top, right, bottom] around the hand given by its label "hand_label" ("left" or "right")
# Values are expressed in pixels in the source image C.S.
# If the wrist keypoint is not visible, return None.
# If self.hands_up_only is True, return None if wrist keypoint is below elbow keypoint.
wrist_kp = hand_label + "_wrist"
id_wrist = BODY_KP[wrist_kp]
if body_scores[id_wrist] < body_score_thresh:
return None
x = body_x[id_wrist]
y = body_y[id_wrist]
if hands_up_only:
# We want to detect only hands where the wrist is above the elbow (when visible)
elbow_kp = hand_label + "_elbow"
id_elbow = BODY_KP[elbow_kp]
if body_scores[id_elbow] > body_score_thresh and \
body_y[id_elbow] < y:
return None
# Let's evaluate the size of the focus zone
size = estimate_focus_zone_size()
if size == 0: return [0, -pad_h, frame_size, frame_size-pad_h]
return zone_from_center_size(x, y, size)
def get_focus_zone(hand_label):
# Return a list [focus_zone, label]
# 'focus_zone' is a zone around a hand or hands, depending on the value
# of hand_label ("left", "right", "higher" or "group") and on the value of self.hands_up_only.
# - hand_label = "left" (resp "right"): we are looking for the zone around the left (resp right) wrist,
# - hand_label = "group": the zone encompasses both wrists,
# - hand_label = "higher": the zone is around the higher wrist (smaller y value),
# - hands_up_only = True: we don't take into consideration the wrist if the corresponding elbow is above the wrist,
# focus_zone is a list [left, top, right, bottom] defining the top-left and right-bottom corners of a square.
# Values are expressed in pixels in the source image C.S.
# The zone is constrained to the squared source image (= source image with padding if necessary).
# It means that values can be negative.
# left and right in [-pad_w, img_w + pad_w]
# top and bottom in [-pad_h, img_h + pad_h]
# 'label' describes which wrist keypoint(s) were used to build the zone : "left", "right" or "group" (if built from both wrists)
# If the wrist keypoint(s) is(are) not present or is(are) present but self.hands_up_only = True and
# wrist(s) is(are) below corresponding elbow(s), then focus_zone = None.
if hand_label == "group":
zonel = get_one_hand_zone("left")
if zonel:
zoner = get_one_hand_zone("right")
if zoner:
xl1, yl1, xl2, yl2 = zonel
xr1, yr1, xr2, yr2 = zoner
x1 = min(xl1, xr1)
y1 = min(yl1, yr1)
x2 = max(xl2, xr2)
y2 = max(yl2, yr2)
# Center (x,y)
x = (x1+x2)//2
y = (y1+y2)//2
size_x = x2-x1
size_y = y2-y1
size = max(size_x, size_y)
zone_hand = [zone_from_center_size(x, y, size), "group"]
else:
zone_hand = [zonel, "left"]
else:
zoner = get_one_hand_zone("right")
if zoner:
zone_hand = [zoner, "right"]
else:
zone_hand = [None, None]
elif hand_label == "higher":
id_left_wrist = BODY_KP["left_wrist"]
id_right_wrist = BODY_KP["right_wrist"]
if body_scores[id_left_wrist] > body_score_thresh:
if body_scores[id_right_wrist] > body_score_thresh:
if body_y[id_left_wrist] > body_y[id_right_wrist]:
hand_label = "right"
else:
hand_label = "left"
else:
hand_label = "left"
else:
if body_scores[id_right_wrist] > body_score_thresh:
hand_label = "right"
else:
return [None, None]
zone = get_one_hand_zone(hand_label)
if zone:
zone_hand = [zone, hand_label]
else:
zone_hand = [None, None]
else: # "left" or "right"
zone_hand = [get_one_hand_zone(hand_label), hand_label]
return zone_hand
# 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")
# bd_pd_inf: 0, 1 or 2.
# 0: neither body and palm detections has been run on the frame;
# 1: only body detection run (but no boundy found);
# 2: both body and palm detections run (body found).
# nb_lm_inf: 0 or 1 (or 2 in duo mode). Number of landmark regression inferences on the frame.
# bd_pd_inf=1 or 2 and nb_lm_inf=0 means the body or palm detection hasn't found any hand
# bd_pd_inf, nb_lm_inf are used for statistics
def send_result_no_hand(bd_pd_inf, nb_lm_inf):
result = dict([("bd_pd_inf", bd_pd_inf), ("nb_lm_inf", nb_lm_inf)])
send_result(result)
def send_result_hands(bd_pd_inf, nb_lm_inf, lm_score, handedness, rect_center_x, rect_center_y, rect_size, rotation, rrn_lms, sqn_lms, world_lms, xyz, xyz_zone):
result = dict([("bd_pd_inf", bd_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
# 0 = body detection branch
# 1 = palm detection branch
# 2 = hand landmark branch
send_new_frame_to_branch = 0
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
nb_hands_in_previous_frame = 0
detected_hands = []
reuse_prev_image = False
while True:
hand_label = None
nb_lm_inf = 0
if send_new_frame_to_branch == 0: # Routing frame to body detection
cfg_pre_body = ImageManipConfig()
points = [
[crop_region['xmin'], crop_region['ymin']],
[crop_region['xmax']-1, crop_region['ymin']],
[crop_region['xmax']-1, crop_region['ymax']-1],
[crop_region['xmin'], crop_region['ymax']-1]]
point2fList = []
for p in points:
pt = Point2f()
pt.x, pt.y = p[0], p[1]
point2fList.append(pt)
cfg_pre_body.setWarpTransformFourPoints(point2fList, False)
cfg_pre_body.setResize(${_body_input_length}, ${_body_input_length})
cfg_pre_body.setFrameType(ImgFrame.Type.RGB888p)
node.io['pre_body_manip_cfg'].send(cfg_pre_body)
${_TRACE2} ("Manager sent thumbnail config to pre_body manip")
# Wait for body detection result
body = node.io['from_body_nn'].get().getLayerFp16("Identity")
${_TRACE2} ("Manager received result from body_nn")
# Extract body keypoints and calculate smart crop for next frame
body_x, body_y, body_scores, crop_region = movenet_postprocess(body, crop_region)
iwr = BODY_KP['right_wrist']
# Calculate pre focus zone
zone, hand_label = get_focus_zone("${_body_pre_focusing}")
if zone:
xmin, ymin, xmax, ymax = zone
${_TRACE1} (f"Body pre focusing zone: ({xmin}, {ymin}), ({xmax}, {ymax})")
points = [
[xmin,ymin],
[xmax,ymin],
[xmax,ymax],
[xmin,ymax]]
point2fList = []
for p in points:
pt = Point2f()
pt.x, pt.y = p[0], p[1]
point2fList.append(pt)
cfg_pre_pd = ImageManipConfig()
cfg_pre_pd.setWarpTransformFourPoints(point2fList, False)
cfg_pre_pd.setResize(128, 128)
send_new_frame_to_branch = 1
else:
${_TRACE1} (f"Body pre focusing zone: None")
send_result_no_hand(1, 0)
nb_hands_in_previous_frame = 0
continue
if send_new_frame_to_branch == 1: # Routing frame to pd branch
hands = []
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} ("Manager received pd result (len={len(detection)}) : "+str(detection))
# detection is list of 2x8 float
# Looping the detection twice to obtain data for 2 hands
for i in range(2):
pd_score, box_x, box_y, box_size, kp0_x, kp0_y, kp2_x, kp2_y = detection[i*8:(i+1)*8]
if pd_score >= ${_pd_score_thresh} and box_size > 0:
if zone:
# xmin, ymin, xmax are expressed in pixel in the source image C.S.
# box_x, box_y, box_size, kp0_x, kp0_y, kp2_x, kp2_y are normalized coords in square zone
# We need box_x, box_y, box_size, kp0_x, kp0_y, kp2_x, kp2_y expressed in normalized coords in squared source image (sqn_)!
sqn_zone_size = (xmax - xmin) / frame_size
box_size *= sqn_zone_size
sqn_xmin = xmin / frame_size
sqn_ymin = (ymin + pad_h) / frame_size
box_x = sqn_xmin + box_x * sqn_zone_size
box_y = sqn_ymin + box_y * sqn_zone_size
kp0_x = sqn_xmin + kp0_x * sqn_zone_size
kp0_y = sqn_ymin + kp0_y * sqn_zone_size
kp2_x = sqn_xmin + kp2_x * sqn_zone_size
kp2_y = sqn_ymin + kp2_y * sqn_zone_size
# 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)
hands.append([sqn_rr_size, rotation, sqn_rr_center_x, sqn_rr_center_y])
${_TRACE1} (f"Palm detection - nb hands detected: {len(hands)}")
# If list is empty, meaning no hand is detected
if len(hands) == 0:
send_result_no_hand(2, 0)
send_new_frame_to_branch = 0
nb_hands_in_previous_frame = 0
continue
if not(nb_hands_in_previous_frame == 1 and len(hands) <= 1):
detected_hands = hands
else:
# otherwise detected_hands come from last frame
${_TRACE1} (f"Keep previous landmarks")
pass
# Constructing input data for landmark inference, the input data of both hands are sent for inference without
# waiting for inference results.
last_hand = len(detected_hands) - 1
for i,hand in enumerate(detected_hands):
sqn_rr_size, rotation, sqn_rr_center_x, sqn_rr_center_y = hand
# 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)
${_IF_USE_SAME_IMAGE}
reuse_prev_image = True if len(detected_hands) > 1 and i == last_hand else False
cfg.setReusePreviousImage(reuse_prev_image)
${_IF_USE_SAME_IMAGE}
node.io['pre_lm_manip_cfg'].send(cfg)
nb_lm_inf += 1
${_TRACE2} (f"Manager sent config to pre_lm manip (reuse previous frame = {reuse_prev_image})")
hand_landmarks = dict([("lm_score", []), ("handedness", []), ("rotation", []),
("rect_center_x", []), ("rect_center_y", []), ("rect_size", []), ("rrn_lms", []), ('sqn_lms', []),
("world_lms", []), ("xyz", []), ("xyz_zone", [])])
updated_detect_hands = []
# Retrieve inference results in here for both hands
for ih, hand in enumerate(detected_hands):
sqn_rr_size, rotation, sqn_rr_center_x, sqn_rr_center_y = hand
# 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]
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}
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}
hand_landmarks["lm_score"].append(lm_score)
hand_landmarks["handedness"].append(handedness)
hand_landmarks["rotation"].append(rotation)
hand_landmarks["rect_center_x"].append(sqn_rr_center_x)
hand_landmarks["rect_center_y"].append(sqn_rr_center_y)
hand_landmarks["rect_size"].append(sqn_rr_size)
hand_landmarks["rrn_lms"].append(rrn_lms)
hand_landmarks["sqn_lms"].append(sqn_lms)
hand_landmarks["world_lms"].append(world_lms)
hand_landmarks["xyz"].append(xyz)
hand_landmarks["xyz_zone"].append(xyz_zone)
# 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)
hand[0] = sqn_rr_size
hand[1] = rotation
hand[2] = sqn_rr_center_x
hand[3] = sqn_rr_center_y
updated_detect_hands.append(hand)
last_detected_hands_id = ih
detected_hands = updated_detect_hands
${_TRACE1} (f"Landmarks - nb hands confirmed : {len(detected_hands)}")
# Check that 2 detected hands do not correspond to the same hand in the image
# That may happen when one hand in the image cross another one
# A simple method is to assure that the center of the rotated rectangles are not too close
if len(detected_hands) == 2:
dist_rr_centers = dist([detected_hands[0][2], detected_hands[0][3]], [detected_hands[1][2], detected_hands[1][3]])
if dist_rr_centers < 0.02:
# Keep the hand with higher landmark score
if hand_landmarks["lm_score"][0] > hand_landmarks["lm_score"][1]:
pop_i = 1
else:
pop_i = 0
for k in hand_landmarks:
hand_landmarks[k].pop(pop_i)
detected_hands.pop(pop_i)
${_TRACE1} ("!!! Removing one hand because too close to the other one")
nb_hands = len(detected_hands)
body_detection_needed = False
# w = wrist
# rw = right wrist
# lw = left wrist
if send_new_frame_to_branch != 2 :
if hand_label is not None:
body_rw_x = body_x[10]
body_rw_y = body_y[10] + ${_pad_h}
body_lw_x = body_x[9]
body_lw_y = body_y[9] + ${_pad_h}
if nb_hands == 2:
h0_w_x = int(hand_landmarks['sqn_lms'][0][0] * ${_frame_size})
h0_w_y = int(hand_landmarks['sqn_lms'][0][1] * ${_frame_size})
h1_w_x = int(hand_landmarks['sqn_lms'][1][0] * ${_frame_size})
h1_w_y = int(hand_landmarks['sqn_lms'][1][1] * ${_frame_size})
if hand_label == "group": # It is expected to have 2 hands
dist_h0_rw = dist((h0_w_x, h0_w_y), (body_rw_x, body_rw_y))
dist_h0_lw = dist((h0_w_x, h0_w_y), (body_lw_x, body_lw_y))
dist_h1_rw = dist((h1_w_x, h1_w_y), (body_rw_x, body_rw_y))
dist_h1_lw = dist((h1_w_x, h1_w_y), (body_lw_x, body_lw_y))
if dist_h0_rw + dist_h1_lw > dist_h0_lw + dist_h1_rw:
hand_landmarks['handedness'][0] = 0
hand_landmarks['handedness'][1] = 1
else:
hand_landmarks['handedness'][0] = 1
hand_landmarks['handedness'][1] = 0
elif hand_label == "left":
dist_h0_lw = dist((h0_w_x, h0_w_y), (body_lw_x, body_lw_y))
dist_h1_lw = dist((h1_w_x, h1_w_y), (body_lw_x, body_lw_y))
if dist_h0_lw < dist_h1_lw:
hand_landmarks['handedness'][0] = 0
hand_landmarks['handedness'][1] = 1
else:
hand_landmarks['handedness'][0] = 1
hand_landmarks['handedness'][1] = 0
elif hand_label == "right":
dist_h0_rw = dist((h0_w_x, h0_w_y), (body_rw_x, body_rw_y))
dist_h1_rw = dist((h1_w_x, h1_w_y), (body_rw_x, body_rw_y))
if dist_h0_rw < dist_h1_rw:
hand_landmarks['handedness'][0] = 1
hand_landmarks['handedness'][1] = 0
else:
hand_landmarks['handedness'][0] = 0
hand_landmarks['handedness'][1] = 1
previous_handedness = [hand_landmarks['handedness'][0], hand_landmarks['handedness'][1]]
elif nb_hands == 1:
if hand_label == "group": # We would have expected 2 hands
h0_w_x = int(hand_landmarks['sqn_lms'][0][0] * ${_frame_size})
h0_w_y = int(hand_landmarks['sqn_lms'][0][1] * ${_frame_size})
dist_h0_rw = dist((h0_w_x, h0_w_y), (body_rw_x, body_rw_y))
dist_h0_lw = dist((h0_w_x, h0_w_y), (body_lw_x, body_lw_y))
hand_landmarks['handedness'][0] = 1 if dist_h0_rw < dist_h0_lw else 0
else: # hand_label == "left" or "right"
hand_landmarks['handedness'][0] = 1 if hand_label == "right" else 0
previous_handedness = [hand_landmarks['handedness'][0]]
elif nb_hands != nb_hands_in_previous_frame:
# We ask for body detection for the next frame
body_detection_needed = True
# ...but there is a chance that we don't use body detection result
# if there is only one hand
if nb_hands == 1:
# Actually we have also nb_hands_in_previous_frame = 2
# The current detected hand was detected from one of the 2 elements sof detected_hands
# Which one ? The one whose index is last_detected_hands_id
hand_landmarks['handedness'][0] = previous_handedness[last_detected_hands_id]
else:
if nb_hands == 2:
hand_landmarks['handedness'][0] = previous_handedness[0]
hand_landmarks['handedness'][1] = previous_handedness[1]
elif nb_hands == 1:
hand_landmarks['handedness'][0] = previous_handedness[0]
if nb_hands == 1:
single_hand_count += 1
else:
single_hand_count = 0
send_result_hands(2 if send_new_frame_to_branch==1 else 0, nb_lm_inf, hand_landmarks["lm_score"], hand_landmarks["handedness"], hand_landmarks["rect_center_x"], hand_landmarks["rect_center_y"], hand_landmarks["rect_size"], hand_landmarks["rotation"], hand_landmarks["rrn_lms"], hand_landmarks["sqn_lms"], hand_landmarks["world_lms"], hand_landmarks["xyz"], hand_landmarks["xyz_zone"])
if nb_hands == 0 or body_detection_needed:
send_new_frame_to_branch = 0
elif nb_hands == 1 and single_hand_count >= ${_single_hand_tolerance_thresh}:
send_new_frame_to_branch = 0
single_hand_count = 0
else:
send_new_frame_to_branch = 2
nb_hands_in_previous_frame = nb_hands