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- extends Control
- export(NodePath) var target
- export var min_scale = 0.1
- export var max_scale = 3.0
- export var one_finger_rot_x = true
- export var one_finger_rot_y = true
- export var two_fingers_rot_z = true
- export var two_fingers_zoom = true
- var base_state
- var curr_state
- var target_node
- # We keep here a copy of the state before the number of fingers changed to avoid accumulation errors.
- var base_xform
- func _ready():
- base_state = {}
- curr_state = {}
- target_node = get_node(target)
- func _gui_input(event):
- # We must start touching inside, but we can drag or unpress outside.
- # if not (event is InputEventScreenDrag or
- # (event is InputEventScreenTouch and (not event.pressed or get_global_rect().has_point(event.position)))):
- # return
- var finger_count = base_state.size()
- if finger_count == 0:
- # No fingers => Accept press.
- if event is InputEventScreenTouch:
- if event.pressed:
- # A finger started touching.
- base_state = {
- event.index: event.position,
- }
- elif finger_count == 1:
- # One finger => For rotating around X and Y.
- # Accept one more press, unpress or drag.
- if event is InputEventScreenTouch:
- if event.pressed:
- # One more finger started touching.
- # Reset the base state to the only current and the new fingers.
- base_state = {
- curr_state.keys()[0]: curr_state.values()[0],
- event.index: event.position,
- }
- else:
- if base_state.has(event.index):
- # Only touching finger released.
- base_state.clear()
- elif event is InputEventScreenDrag:
- if curr_state.has(event.index):
- # Touching finger dragged.
- var unit_drag = _px2unit(base_state[base_state.keys()[0]] - event.position)
- if one_finger_rot_x:
- target_node.global_rotate(Vector3.UP, deg2rad(180.0 * unit_drag.x))
- if one_finger_rot_y:
- target_node.global_rotate(Vector3.RIGHT, deg2rad(180.0 * unit_drag.y))
- # Since rotating around two axes, we have to reset the base constantly.
- curr_state[event.index] = event.position
- base_state[event.index] = event.position
- base_xform = target_node.get_transform()
- elif finger_count == 2:
- # Two fingers => To pinch-zoom and rotate around Z.
- # Accept unpress or drag.
- if event is InputEventScreenTouch:
- if not event.pressed and base_state.has(event.index):
- # Some known touching finger released.
- # Clear the base state
- base_state.clear()
- elif event is InputEventScreenDrag:
- if curr_state.has(event.index):
- # Some known touching finger dragged.
- curr_state[event.index] = event.position
- # Compute base and current inter-finger vectors.
- var base_segment = base_state[base_state.keys()[0]] - base_state[base_state.keys()[1]]
- var new_segment = curr_state[curr_state.keys()[0]] - curr_state[curr_state.keys()[1]]
- # Get the base scale from the base matrix.
- var base_scale = Vector3(base_xform.basis.x.x, base_xform.basis.y.y, base_xform.basis.z.z).length()
- if two_fingers_zoom:
- # Compute the new scale limiting it and taking into account the base scale.
- var new_scale = clamp(base_scale * (new_segment.length() / base_segment.length()), min_scale, max_scale) / base_scale
- target_node.set_transform(base_xform.scaled(new_scale * Vector3.ONE))
- else:
- target_node.set_transform(base_xform)
- if two_fingers_rot_z:
- # Apply rotation between base inter-finger vector and the current one.
- var rot = new_segment.angle_to(base_segment)
- target_node.global_rotate(Vector3.BACK, rot)
- # Finger count changed?
- if base_state.size() != finger_count:
- # Copy new base state to the current state.
- curr_state = {}
- for idx in base_state.keys():
- curr_state[idx] = base_state[idx]
- # Remember the base transform.
- base_xform = target_node.get_transform()
- # Converts a vector in pixels to a unitary magnitude,
- # considering the number of pixels of the shorter axis is the unit.
- func _px2unit(v):
- var shortest = min(get_size().x, get_size().y)
- return v * (1.0 / shortest)
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