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HandTrackerEdge.py
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HandTrackerEdge.py
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import numpy as np
from collections import namedtuple
from numpy.lib.arraysetops import isin
import mediapipe_utils as mpu
import depthai as dai
import cv2
from pathlib import Path
from FPS import FPS, now
import time
import sys
from string import Template
import marshal
SCRIPT_DIR = Path(__file__).resolve().parent
PALM_DETECTION_MODEL = str(SCRIPT_DIR / "models/palm_detection_sh4.blob")
LANDMARK_MODEL_FULL = str(SCRIPT_DIR / "models/hand_landmark_full_sh4.blob")
LANDMARK_MODEL_LITE = str(SCRIPT_DIR / "models/hand_landmark_lite_sh4.blob")
LANDMARK_MODEL_SPARSE = str(SCRIPT_DIR / "models/hand_landmark_sparse_sh4.blob")
DETECTION_POSTPROCESSING_MODEL = str(SCRIPT_DIR / "custom_models/PDPostProcessing_top2_sh1.blob")
TEMPLATE_MANAGER_SCRIPT_SOLO = str(SCRIPT_DIR / "template_manager_script_solo.py")
TEMPLATE_MANAGER_SCRIPT_DUO = str(SCRIPT_DIR / "template_manager_script_duo.py")
def to_planar(arr: np.ndarray, shape: tuple) -> np.ndarray:
return cv2.resize(arr, shape).transpose(2,0,1).flatten()
class HandTracker:
"""
Mediapipe Hand Tracker for depthai
Arguments:
- input_src: frame source,
- "rgb" or None: OAK* internal color camera,
- "rgb_laconic": same as "rgb" but without sending the frames to the host (Edge mode only),
- a file path of an image or a video,
- an integer (eg 0) for a webcam id,
In edge mode, only "rgb" and "rgb_laconic" are possible
- pd_model: palm detection model blob file,
- pd_score: confidence score to determine whether a detection is reliable (a float between 0 and 1).
- pd_nms_thresh: NMS threshold.
- use_lm: boolean. When True, run landmark model. Otherwise, only palm detection model is run
- lm_model: landmark model. Either:
- 'full' for LANDMARK_MODEL_FULL,
- 'lite' for LANDMARK_MODEL_LITE,
- 'sparse' for LANDMARK_MODEL_SPARSE,
- a path of a blob file.
- lm_score_thresh : confidence score to determine whether landmarks prediction is reliable (a float between 0 and 1).
- use_world_landmarks: boolean. The landmarks model yields 2 types of 3D coordinates :
- coordinates expressed in pixels in the image, always stored in hand.landmarks,
- coordinates expressed in meters in the world, stored in hand.world_landmarks
only if use_world_landmarks is True.
- pp_model: path to the detection post processing model,
- solo: boolean, when True detect one hand max (much faster since we run the pose detection model only if no hand was detected in the previous frame)
On edge mode, always True
- xyz : boolean, when True calculate the (x, y, z) coords of the detected palms.
- crop : boolean which indicates if square cropping on source images is applied or not
- internal_fps : when using the internal color camera as input source, set its FPS to this value (calling setFps()).
- resolution : sensor resolution "full" (1920x1080) or "ultra" (3840x2160),
- internal_frame_height : when using the internal color camera, set the frame height (calling setIspScale()).
The width is calculated accordingly to height and depends on value of 'crop'
- use_gesture : boolean, when True, recognize hand poses froma predefined set of poses
(ONE, TWO, THREE, FOUR, FIVE, OK, PEACE, FIST)
- use_handedness_average : boolean, when True the handedness is the average of the last collected handednesses.
This brings robustness since the inferred robustness is not reliable on ambiguous hand poses.
When False, handedness is the last inferred handedness.
- single_hand_tolerance_thresh (Duo mode only) : In Duo mode, if there is only one hand in a frame,
in order to know when a second hand will appear you need to run the palm detection
in the following frames. Because palm detection is slow, you may want to delay
the next time you will run it. 'single_hand_tolerance_thresh' is the number of
frames during only one hand is detected before palm detection is run again.
- lm_nb_threads : 1 or 2 (default=2), number of inference threads for the landmark model
- use_same_image (Edge Duo mode only) : boolean, when True, use the same image when inferring the landmarks of the 2 hands
(setReusePreviousImage(True) in the ImageManip node before the landmark model).
When True, the FPS is significantly higher but the skeleton may appear shifted on one of the 2 hands.
- stats : boolean, when True, display some statistics when exiting.
- trace : int, 0 = no trace, otherwise print some debug messages or show output of ImageManip nodes
if trace & 1, print application level info like number of palm detections,
if trace & 2, print lower level info like when a message is sent or received by the manager script node,
if trace & 4, show in cv2 windows outputs of ImageManip node,
if trace & 8, save in file tmp_code.py the python code of the manager script node
Ex: if trace==3, both application and low level info are displayed.
"""
def __init__(self, input_src=None,
pd_model=PALM_DETECTION_MODEL,
pd_score_thresh=0.5, pd_nms_thresh=0.3,
use_lm=True,
lm_model="lite",
lm_score_thresh=0.5,
use_world_landmarks=False,
pp_model = DETECTION_POSTPROCESSING_MODEL,
solo=True,
xyz=False,
crop=False,
internal_fps=None,
resolution="full",
internal_frame_height=640,
use_gesture=False,
use_handedness_average=True,
single_hand_tolerance_thresh=10,
use_same_image=True,
lm_nb_threads=2,
stats=False,
trace=0
):
self.use_lm = use_lm
if not use_lm:
print("use_lm=False is not supported in Edge mode.")
sys.exit()
self.pd_model = pd_model
print(f"Palm detection blob : {self.pd_model}")
if lm_model == "full":
self.lm_model = LANDMARK_MODEL_FULL
elif lm_model == "lite":
self.lm_model = LANDMARK_MODEL_LITE
elif lm_model == "sparse":
self.lm_model = LANDMARK_MODEL_SPARSE
else:
self.lm_model = lm_model
print(f"Landmark blob : {self.lm_model}")
self.pd_score_thresh = pd_score_thresh
self.pd_nms_thresh = pd_nms_thresh
self.lm_score_thresh = lm_score_thresh
self.pp_model = pp_model
print(f"PD post processing blob : {self.pp_model}")
self.solo = solo
if self.solo:
print("In Solo mode, # of landmark model threads is forced to 1")
self.lm_nb_threads = 1
else:
assert lm_nb_threads in [1, 2]
self.lm_nb_threads = lm_nb_threads
self.xyz = False
self.crop = crop
self.use_world_landmarks = use_world_landmarks
self.stats = stats
self.trace = trace
self.use_gesture = use_gesture
self.use_handedness_average = use_handedness_average
self.single_hand_tolerance_thresh = single_hand_tolerance_thresh
self.use_same_image = use_same_image
self.device = dai.Device()
if input_src == None or input_src == "rgb" or input_src == "rgb_laconic":
# Note that here (in Host mode), specifying "rgb_laconic" has no effect
# Color camera frames are systematically transferred to the host
self.input_type = "rgb" # OAK* internal color camera
self.laconic = input_src == "rgb_laconic" # Camera frames are not sent to the host
if resolution == "full":
self.resolution = (1920, 1080)
elif resolution == "ultra":
self.resolution = (3840, 2160)
else:
print(f"Error: {resolution} is not a valid resolution !")
sys.exit()
print("Sensor resolution:", self.resolution)
if xyz:
# Check if the device supports stereo
cameras = self.device.getConnectedCameras()
if dai.CameraBoardSocket.LEFT in cameras and dai.CameraBoardSocket.RIGHT in cameras:
self.xyz = True
else:
print("Warning: depth unavailable on this device, 'xyz' argument is ignored")
if internal_fps is None:
if lm_model == "full":
if self.xyz:
self.internal_fps = 22
else:
self.internal_fps = 26
elif lm_model == "lite":
if self.xyz:
self.internal_fps = 29
else:
self.internal_fps = 36
elif lm_model == "sparse":
if self.xyz:
self.internal_fps = 24
else:
self.internal_fps = 29
else:
self.internal_fps = 39
else:
self.internal_fps = internal_fps
print(f"Internal camera FPS set to: {self.internal_fps}")
self.video_fps = self.internal_fps # Used when saving the output in a video file. Should be close to the real fps
if self.crop:
self.frame_size, self.scale_nd = mpu.find_isp_scale_params(internal_frame_height, self.resolution)
self.img_h = self.img_w = self.frame_size
self.pad_w = self.pad_h = 0
self.crop_w = (int(round(self.resolution[0] * self.scale_nd[0] / self.scale_nd[1])) - self.img_w) // 2
else:
width, self.scale_nd = mpu.find_isp_scale_params(internal_frame_height * self.resolution[0] / self.resolution[1], self.resolution, is_height=False)
self.img_h = int(round(self.resolution[1] * self.scale_nd[0] / self.scale_nd[1]))
self.img_w = int(round(self.resolution[0] * self.scale_nd[0] / self.scale_nd[1]))
self.pad_h = (self.img_w - self.img_h) // 2
self.pad_w = 0
self.frame_size = self.img_w
self.crop_w = 0
print(f"Internal camera image size: {self.img_w} x {self.img_h} - pad_h: {self.pad_h}")
else:
print("Invalid input source:", input_src)
sys.exit()
# Define and start pipeline
usb_speed = self.device.getUsbSpeed()
self.device.startPipeline(self.create_pipeline())
print(f"Pipeline started - USB speed: {str(usb_speed).split('.')[-1]}")
# Define data queues
if not self.laconic:
self.q_video = self.device.getOutputQueue(name="cam_out", maxSize=1, blocking=False)
self.q_manager_out = self.device.getOutputQueue(name="manager_out", maxSize=1, blocking=False)
# For showing outputs of ImageManip nodes (debugging)
if self.trace & 4:
self.q_pre_pd_manip_out = self.device.getOutputQueue(name="pre_pd_manip_out", maxSize=1, blocking=False)
self.q_pre_lm_manip_out = self.device.getOutputQueue(name="pre_lm_manip_out", maxSize=1, blocking=False)
self.fps = FPS()
self.nb_frames_pd_inference = 0
self.nb_frames_lm_inference = 0
self.nb_lm_inferences = 0
self.nb_failed_lm_inferences = 0
self.nb_frames_lm_inference_after_landmarks_ROI = 0
self.nb_frames_no_hand = 0
def create_pipeline(self):
print("Creating pipeline...")
# Start defining a pipeline
pipeline = dai.Pipeline()
pipeline.setOpenVINOVersion(version = dai.OpenVINO.Version.VERSION_2021_4)
self.pd_input_length = 128
# ColorCamera
print("Creating Color Camera...")
cam = pipeline.createColorCamera()
if self.resolution[0] == 1920:
cam.setResolution(dai.ColorCameraProperties.SensorResolution.THE_1080_P)
else:
cam.setResolution(dai.ColorCameraProperties.SensorResolution.THE_4_K)
cam.setBoardSocket(dai.CameraBoardSocket.RGB)
cam.setInterleaved(False)
cam.setIspScale(self.scale_nd[0], self.scale_nd[1])
cam.setFps(self.internal_fps)
if self.crop:
cam.setVideoSize(self.frame_size, self.frame_size)
cam.setPreviewSize(self.frame_size, self.frame_size)
else:
cam.setVideoSize(self.img_w, self.img_h)
cam.setPreviewSize(self.img_w, self.img_h)
if not self.laconic:
cam_out = pipeline.createXLinkOut()
cam_out.setStreamName("cam_out")
cam_out.input.setQueueSize(1)
cam_out.input.setBlocking(False)
cam.video.link(cam_out.input)
# Define manager script node
manager_script = pipeline.create(dai.node.Script)
manager_script.setScript(self.build_manager_script())
if self.xyz:
print("Creating MonoCameras, Stereo and SpatialLocationCalculator nodes...")
# For now, RGB needs fixed focus to properly align with depth.
# The value used during calibration should be used here
calib_data = self.device.readCalibration()
calib_lens_pos = calib_data.getLensPosition(dai.CameraBoardSocket.RGB)
print(f"RGB calibration lens position: {calib_lens_pos}")
cam.initialControl.setManualFocus(calib_lens_pos)
mono_resolution = dai.MonoCameraProperties.SensorResolution.THE_400_P
left = pipeline.createMonoCamera()
left.setBoardSocket(dai.CameraBoardSocket.LEFT)
left.setResolution(mono_resolution)
left.setFps(self.internal_fps)
right = pipeline.createMonoCamera()
right.setBoardSocket(dai.CameraBoardSocket.RIGHT)
right.setResolution(mono_resolution)
right.setFps(self.internal_fps)
stereo = pipeline.createStereoDepth()
stereo.setConfidenceThreshold(230)
# LR-check is required for depth alignment
stereo.setLeftRightCheck(True)
stereo.setDepthAlign(dai.CameraBoardSocket.RGB)
stereo.setSubpixel(False) # subpixel True brings latency
# MEDIAN_OFF necessary in depthai 2.7.2.
# Otherwise : [critical] Fatal error. Please report to developers. Log: 'StereoSipp' '533'
# stereo.setMedianFilter(dai.StereoDepthProperties.MedianFilter.MEDIAN_OFF)
spatial_location_calculator = pipeline.createSpatialLocationCalculator()
spatial_location_calculator.setWaitForConfigInput(True)
spatial_location_calculator.inputDepth.setBlocking(False)
spatial_location_calculator.inputDepth.setQueueSize(1)
left.out.link(stereo.left)
right.out.link(stereo.right)
stereo.depth.link(spatial_location_calculator.inputDepth)
manager_script.outputs['spatial_location_config'].link(spatial_location_calculator.inputConfig)
spatial_location_calculator.out.link(manager_script.inputs['spatial_data'])
# Define palm detection pre processing: resize preview to (self.pd_input_length, self.pd_input_length)
print("Creating Palm Detection pre processing image manip...")
pre_pd_manip = pipeline.create(dai.node.ImageManip)
pre_pd_manip.setMaxOutputFrameSize(self.pd_input_length*self.pd_input_length*3)
pre_pd_manip.setWaitForConfigInput(True)
pre_pd_manip.inputImage.setQueueSize(1)
pre_pd_manip.inputImage.setBlocking(False)
cam.preview.link(pre_pd_manip.inputImage)
manager_script.outputs['pre_pd_manip_cfg'].link(pre_pd_manip.inputConfig)
# For debugging
if self.trace & 4:
pre_pd_manip_out = pipeline.createXLinkOut()
pre_pd_manip_out.setStreamName("pre_pd_manip_out")
pre_pd_manip.out.link(pre_pd_manip_out.input)
# Define palm detection model
print("Creating Palm Detection Neural Network...")
pd_nn = pipeline.create(dai.node.NeuralNetwork)
pd_nn.setBlobPath(self.pd_model)
pre_pd_manip.out.link(pd_nn.input)
# Define pose detection post processing "model"
print("Creating Palm Detection post processing Neural Network...")
post_pd_nn = pipeline.create(dai.node.NeuralNetwork)
post_pd_nn.setBlobPath(self.pp_model)
pd_nn.out.link(post_pd_nn.input)
post_pd_nn.out.link(manager_script.inputs['from_post_pd_nn'])
# Define link to send result to host
manager_out = pipeline.create(dai.node.XLinkOut)
manager_out.setStreamName("manager_out")
manager_script.outputs['host'].link(manager_out.input)
# Define landmark pre processing image manip
print("Creating Hand Landmark pre processing image manip...")
self.lm_input_length = 224
pre_lm_manip = pipeline.create(dai.node.ImageManip)
pre_lm_manip.setMaxOutputFrameSize(self.lm_input_length*self.lm_input_length*3)
pre_lm_manip.setWaitForConfigInput(True)
pre_lm_manip.inputImage.setQueueSize(1)
pre_lm_manip.inputImage.setBlocking(False)
cam.preview.link(pre_lm_manip.inputImage)
# For debugging
if self.trace & 4:
pre_lm_manip_out = pipeline.createXLinkOut()
pre_lm_manip_out.setStreamName("pre_lm_manip_out")
pre_lm_manip.out.link(pre_lm_manip_out.input)
manager_script.outputs['pre_lm_manip_cfg'].link(pre_lm_manip.inputConfig)
# Define landmark model
print(f"Creating Hand Landmark Neural Network ({'1 thread' if self.lm_nb_threads == 1 else '2 threads'})...")
lm_nn = pipeline.create(dai.node.NeuralNetwork)
lm_nn.setBlobPath(self.lm_model)
lm_nn.setNumInferenceThreads(self.lm_nb_threads)
pre_lm_manip.out.link(lm_nn.input)
lm_nn.out.link(manager_script.inputs['from_lm_nn'])
print("Pipeline created.")
return pipeline
def build_manager_script(self):
'''
The code of the scripting node 'manager_script' depends on :
- the score threshold,
- the video frame shape
So we build this code from the content of the file template_manager_script_*.py which is a python template
'''
# Read the template
with open(TEMPLATE_MANAGER_SCRIPT_SOLO if self.solo else TEMPLATE_MANAGER_SCRIPT_DUO, 'r') as file:
template = Template(file.read())
# Perform the substitution
code = template.substitute(
_TRACE1 = "node.warn" if self.trace & 1 else "#",
_TRACE2 = "node.warn" if self.trace & 2 else "#",
_pd_score_thresh = self.pd_score_thresh,
_lm_score_thresh = self.lm_score_thresh,
_pad_h = self.pad_h,
_img_h = self.img_h,
_img_w = self.img_w,
_frame_size = self.frame_size,
_crop_w = self.crop_w,
_IF_XYZ = "" if self.xyz else '"""',
_IF_USE_HANDEDNESS_AVERAGE = "" if self.use_handedness_average else '"""',
_single_hand_tolerance_thresh= self.single_hand_tolerance_thresh,
_IF_USE_SAME_IMAGE = "" if self.use_same_image else '"""',
_IF_USE_WORLD_LANDMARKS = "" if self.use_world_landmarks else '"""',
)
# Remove comments and empty lines
import re
code = re.sub(r'"{3}.*?"{3}', '', code, flags=re.DOTALL)
code = re.sub(r'#.*', '', code)
code = re.sub('\n\s*\n', '\n', code)
# For debugging
if self.trace & 8:
with open("tmp_code.py", "w") as file:
file.write(code)
return code
def extract_hand_data(self, res, hand_idx):
hand = mpu.HandRegion()
hand.rect_x_center_a = res["rect_center_x"][hand_idx] * self.frame_size
hand.rect_y_center_a = res["rect_center_y"][hand_idx] * self.frame_size
hand.rect_w_a = hand.rect_h_a = res["rect_size"][hand_idx] * self.frame_size
hand.rotation = res["rotation"][hand_idx]
hand.rect_points = mpu.rotated_rect_to_points(hand.rect_x_center_a, hand.rect_y_center_a, hand.rect_w_a, hand.rect_h_a, hand.rotation)
hand.lm_score = res["lm_score"][hand_idx]
hand.handedness = res["handedness"][hand_idx]
hand.label = "right" if hand.handedness > 0.5 else "left"
hand.norm_landmarks = np.array(res['rrn_lms'][hand_idx]).reshape(-1,3)
hand.landmarks = (np.array(res["sqn_lms"][hand_idx]) * self.frame_size).reshape(-1,2).astype(np.int32)
if self.xyz:
hand.xyz = np.array(res["xyz"][hand_idx])
hand.xyz_zone = res["xyz_zone"][hand_idx]
# If we added padding to make the image square, we need to remove this padding from landmark coordinates and from rect_points
if self.pad_h > 0:
hand.landmarks[:,1] -= self.pad_h
for i in range(len(hand.rect_points)):
hand.rect_points[i][1] -= self.pad_h
if self.pad_w > 0:
hand.landmarks[:,0] -= self.pad_w
for i in range(len(hand.rect_points)):
hand.rect_points[i][0] -= self.pad_w
# World landmarks
if self.use_world_landmarks:
hand.world_landmarks = np.array(res["world_lms"][hand_idx]).reshape(-1, 3)
if self.use_gesture: mpu.recognize_gesture(hand)
return hand
def next_frame(self):
self.fps.update()
if self.laconic:
video_frame = np.zeros((self.img_h, self.img_w, 3), dtype=np.uint8)
else:
in_video = self.q_video.get()
video_frame = in_video.getCvFrame()
# For debugging
if self.trace & 4:
pre_pd_manip = self.q_pre_pd_manip_out.tryGet()
if pre_pd_manip:
pre_pd_manip = pre_pd_manip.getCvFrame()
cv2.imshow("pre_pd_manip", pre_pd_manip)
pre_lm_manip = self.q_pre_lm_manip_out.tryGet()
if pre_lm_manip:
pre_lm_manip = pre_lm_manip.getCvFrame()
cv2.imshow("pre_lm_manip", pre_lm_manip)
# Get result from device
res = marshal.loads(self.q_manager_out.get().getData())
hands = []
for i in range(len(res.get("lm_score",[]))):
hand = self.extract_hand_data(res, i)
hands.append(hand)
# Statistics
if self.stats:
if res["pd_inf"]:
self.nb_frames_pd_inference += 1
else:
if res["nb_lm_inf"] > 0:
self.nb_frames_lm_inference_after_landmarks_ROI += 1
if res["nb_lm_inf"] == 0:
self.nb_frames_no_hand += 1
else:
self.nb_frames_lm_inference += 1
self.nb_lm_inferences += res["nb_lm_inf"]
self.nb_failed_lm_inferences += res["nb_lm_inf"] - len(hands)
return video_frame, hands, None
def exit(self):
self.device.close()
# Print some stats
if self.stats:
nb_frames = self.fps.nb_frames()
print(f"FPS : {self.fps.get_global():.1f} f/s (# frames = {nb_frames})")
print(f"# frames w/ no hand : {self.nb_frames_no_hand} ({100*self.nb_frames_no_hand/nb_frames:.1f}%)")
print(f"# frames w/ palm detection : {self.nb_frames_pd_inference} ({100*self.nb_frames_pd_inference/nb_frames:.1f}%)")
print(f"# frames w/ landmark inference : {self.nb_frames_lm_inference} ({100*self.nb_frames_lm_inference/nb_frames:.1f}%)- # after palm detection: {self.nb_frames_lm_inference - self.nb_frames_lm_inference_after_landmarks_ROI} - # after landmarks ROI prediction: {self.nb_frames_lm_inference_after_landmarks_ROI}")
if not self.solo:
print(f"On frames with at least one landmark inference, average number of landmarks inferences/frame: {self.nb_lm_inferences/self.nb_frames_lm_inference:.2f}")
if self.nb_lm_inferences:
print(f"# lm inferences: {self.nb_lm_inferences} - # failed lm inferences: {self.nb_failed_lm_inferences} ({100*self.nb_failed_lm_inferences/self.nb_lm_inferences:.1f}%)")