dave/py-media-grader
1
0
Fork 0
Code Issues Pull Requests Actions Packages Projects Releases Wiki Activity

Compare commits

base: dave:0570256f6541f3b81b1e8d8b9e7e52bbe85c4754
Branches Tags
dave:master
..
compare: dave:b123b12d0d15d4ba5eccbf6f7e266ccabab9dedb
Branches Tags
dave:master

3 Commits
0570256f65 ... b123b12d0d

Author SHA1 Message Date
PhatPhuckDave
b123b12d0d Refactor motion path logic in VideoEditor for clarity 
This commit updates the VideoEditor class to improve the logic for drawing and checking motion paths between tracking points. The comments have been adjusted to clarify the conditions for drawing lines between previous→current and previous→next frames. Additionally, debug statements have been enhanced to provide clearer insights during the snapping process, ensuring better tracking point interactions.
 2025-09-17 15:46:39 +02:00
PhatPhuckDave
1bd935646e Refactor motion path and snapping logic in VideoEditor 
This commit enhances the VideoEditor class by refining the logic for drawing motion paths and checking line snapping between tracking points. It introduces a unified approach to handle both previous→next and previous→current lines, improving the clarity of the visual representation. Additionally, debug statements have been updated to provide better insights during the snapping process, ensuring accurate tracking point interactions. The display update method is also called to refresh the visual state after changes.
 2025-09-17 15:44:55 +02:00
PhatPhuckDave
c3e0088a60 Refactor point-to-line distance calculation in VideoEditor 
This commit refines the distance calculation method in the VideoEditor class by introducing a new function, _point_to_line_distance_and_foot, which computes the distance from a point to an infinite line and returns the foot of the perpendicular. The snapping logic has been updated to utilize this new method, enhancing the accuracy of line snapping between tracking points. Additionally, debug statements have been added to assist in tracking the snapping process and verifying point conversions.
 2025-09-17 15:38:57 +02:00
1 changed files with 54 additions and 52 deletions
Expand all files Collapse all files

98
croppa/main.py
View File

@@ -510,7 +510,7 @@ class VideoEditor:
CROP_SIZE_STEP = 15 # pixels to expand/contract crop
# Motion tracking settings
TRACKING_POINT_THRESHOLD = 20 # pixels for delete/snap radius
TRACKING_POINT_THRESHOLD = 10 # pixels for delete/snap radius
# Seek frame counts
SEEK_FRAMES_CTRL = 60 # Ctrl modifier: 60 frames
@@ -2033,35 +2033,42 @@ class VideoEditor:
prev_result = self._get_previous_tracking_point()
next_result = self._get_next_tracking_point()
# Draw motion path if we have both previous and next points
if prev_result and next_result:
prev_frame, prev_pts = prev_result
next_frame, next_pts = next_result
# Draw motion path - either previous→current OR previous→next
line_to_draw = None
if prev_result and self.current_frame in self.tracking_points:
# Draw previous→current line (we're on a frame with tracking points)
line_to_draw = ("prev_current", prev_result, (self.current_frame, self.tracking_points[self.current_frame]))
elif prev_result and next_result:
# Draw previous→next line (we're between frames)
line_to_draw = ("prev_next", prev_result, next_result)
if line_to_draw:
line_type, (frame1, pts1), (frame2, pts2) = line_to_draw
# Draw lines between corresponding tracking points
for i, (prev_rx, prev_ry) in enumerate(prev_pts):
if i < len(next_pts):
next_rx, next_ry = next_pts[i]
prev_sx, prev_sy = self._map_rotated_to_screen(prev_rx, prev_ry)
next_sx, next_sy = self._map_rotated_to_screen(next_rx, next_ry)
for i, (px1, py1) in enumerate(pts1):
if i < len(pts2):
px2, py2 = pts2[i]
sx1, sy1 = self._map_rotated_to_screen(px1, py1)
sx2, sy2 = self._map_rotated_to_screen(px2, py2)
# Draw motion path line with arrow (thin and transparent)
overlay = canvas.copy()
cv2.line(overlay, (prev_sx, prev_sy), (next_sx, next_sy), (255, 255, 0), 1) # Thin yellow line
cv2.line(overlay, (sx1, sy1), (sx2, sy2), (255, 255, 0), 1) # Thin yellow line
# Draw arrow head pointing from previous to next
angle = np.arctan2(next_sy - prev_sy, next_sx - prev_sx)
# Draw arrow head pointing from first to second point
angle = np.arctan2(sy2 - sy1, sx2 - sx1)
arrow_length = 12
arrow_angle = np.pi / 6 # 30 degrees
# Calculate arrow head points
arrow_x1 = int(next_sx - arrow_length * np.cos(angle - arrow_angle))
arrow_y1 = int(next_sy - arrow_length * np.sin(angle - arrow_angle))
arrow_x2 = int(next_sx - arrow_length * np.cos(angle + arrow_angle))
arrow_y2 = int(next_sy - arrow_length * np.sin(angle + arrow_angle))
arrow_x1 = int(sx2 - arrow_length * np.cos(angle - arrow_angle))
arrow_y1 = int(sy2 - arrow_length * np.sin(angle - arrow_angle))
arrow_x2 = int(sx2 - arrow_length * np.cos(angle + arrow_angle))
arrow_y2 = int(sy2 - arrow_length * np.sin(angle + arrow_angle))
cv2.line(overlay, (next_sx, next_sy), (arrow_x1, arrow_y1), (255, 255, 0), 1)
cv2.line(overlay, (next_sx, next_sy), (arrow_x2, arrow_y2), (255, 255, 0), 1)
cv2.line(overlay, (sx2, sy2), (arrow_x1, arrow_y1), (255, 255, 0), 1)
cv2.line(overlay, (sx2, sy2), (arrow_x2, arrow_y2), (255, 255, 0), 1)
cv2.addWeighted(overlay, 0.3, canvas, 0.7, 0, canvas) # Very transparent
# Previous tracking point (red) - from the most recent frame with tracking points before current
@@ -2196,22 +2203,30 @@ class VideoEditor:
best_snap_distance = distance
best_snap_point = (int(px), int(py))
# Check for line snapping between previous and next tracking points (the actual cyan arrows)
# Check for line snapping - either previous→next OR previous→current
prev_result = self._get_previous_tracking_point()
next_result = self._get_next_tracking_point()
print(f"DEBUG: Line snapping - prev_result: {prev_result}, next_result: {next_result}")
if prev_result and next_result:
prev_frame, prev_pts = prev_result
next_frame, next_pts = next_result
# Determine which line to check: previous→current OR previous→next
line_to_check = None
if prev_result and self.current_frame in self.tracking_points:
# Check previous→current line (we're on a frame with tracking points)
line_to_check = ("prev_current", prev_result, (self.current_frame, self.tracking_points[self.current_frame]))
print(f"DEBUG: Checking prev->current line")
elif prev_result and next_result:
# Check previous→next line (we're between frames)
line_to_check = ("prev_next", prev_result, next_result)
print(f"DEBUG: Checking prev->next line")
print(f"DEBUG: Checking line between prev frame {prev_frame} and next frame {next_frame}")
if line_to_check:
line_type, (frame1, pts1), (frame2, pts2) = line_to_check
# Check each corresponding pair of points between previous and next
for j in range(min(len(prev_pts), len(next_pts))):
px1, py1 = prev_pts[j]
px2, py2 = next_pts[j]
# Check each corresponding pair of points
for j in range(min(len(pts1), len(pts2))):
px1, py1 = pts1[j]
px2, py2 = pts2[j]
# Convert to screen coordinates
sx1, sy1 = self._map_rotated_to_screen(px1, py1)
@@ -2220,35 +2235,19 @@ class VideoEditor:
# Calculate distance to infinite line and foot of perpendicular
line_distance, (foot_x, foot_y) = self._point_to_line_distance_and_foot(x, y, sx1, sy1, sx2, sy2)
print(f"DEBUG: Line {j}: ({sx1},{sy1}) to ({sx2},{sy2}), distance to click ({x},{y}) = {line_distance:.2f}, foot = ({foot_x:.1f}, {foot_y:.1f})")
print(f"DEBUG: {line_type} Line {j}: ({sx1},{sy1}) to ({sx2},{sy2}), distance to click ({x},{y}) = {line_distance:.2f}, foot = ({foot_x:.1f}, {foot_y:.1f})")
if line_distance <= threshold and line_distance < best_snap_distance:
print(f"DEBUG: Line snap found! Distance {line_distance:.2f} <= threshold {threshold}")
# Clamp the foot to the line segment
# Calculate parameter t for the foot point
line_dx = sx2 - sx1
line_dy = sy2 - sy1
line_length_sq = line_dx * line_dx + line_dy * line_dy
if line_length_sq > 0:
t = ((foot_x - sx1) * line_dx + (foot_y - sy1) * line_dy) / line_length_sq
t = max(0, min(1, t)) # Clamp to [0, 1]
# Calculate clamped foot point
clamped_foot_x = sx1 + t * line_dx
clamped_foot_y = sy1 + t * line_dy
print(f"DEBUG: Clamped foot from ({foot_x:.1f}, {foot_y:.1f}) to ({clamped_foot_x:.1f}, {clamped_foot_y:.1f})")
# Convert clamped foot back to rotated coordinates
closest_rx, closest_ry = self._map_screen_to_rotated(int(clamped_foot_x), int(clamped_foot_y))
# Convert foot of perpendicular back to rotated coordinates (no clamping - infinite line)
closest_rx, closest_ry = self._map_screen_to_rotated(int(foot_x), int(foot_y))
best_snap_distance = line_distance
best_snap_point = (int(closest_rx), int(closest_ry))
print(f"DEBUG: Best line snap point: ({closest_rx}, {closest_ry})")
else:
print(f"DEBUG: No prev/next points found for line snapping")
print(f"DEBUG: No line found for snapping")
# Apply the best snap if found
if best_snap_point:
@@ -2272,6 +2271,9 @@ class VideoEditor:
self.clear_transformation_cache()
self.save_state()
# Force immediate display update to recalculate previous/next points and arrows
self.display_current_frame()
# Handle scroll wheel: Ctrl+scroll -> zoom; plain scroll -> seek ±1 frame (independent of multiplier)
if event == cv2.EVENT_MOUSEWHEEL:
if flags & cv2.EVENT_FLAG_CTRLKEY: