def __init__(self):
self._timer: utils.Timer = utils.Timer()
self._application: application.Application = application.Application.instance(
)
self._source_np: Optional[np.ndarray] = None
self._source_cp: Optional[cp.ndarray] = None
self.offset: tuples.PixelPoint = tuples.PixelPoint(0, 0)
# portal arrays that only change when window is resized
self.frame_shape: Optional[tuples.ImageShape] = None
self._pan: tuples.PixelPoint = tuples.PixelPoint(0, 0)
self._rotation_degrees: float = 0.0
self._scale: float = 1.0
self._scale_point: tuples.PixelPoint = tuples.PixelPoint(0, 0)
self._use_gpu: bool = True
# numpy transformations
self._matrix: Optional[np.ndarray] = None
self._vector: Optional[np.ndarray] = None
self._source_frame_matrix: Optional[np.ndarray] = None
self._source_frame_vector: Optional[np.ndarray] = None
# numpy and cupy frame array (both prepared in advance)
self._frame_pixels_np: Optional[np.ndarray] = None
self._frame_pixels_cp: Optional[cp.ndarray] = None
# result (GPU or CPU)
self._frame_rgba: Optional[np.ndarray] = None
def total_pan(self) -> tuples.PixelPoint:
if self.released_pan_delta is None:
return tuples.PixelPoint(x=self.mouse_pan_delta.x,
y=self.mouse_pan_delta.y)
else:
return tuples.PixelPoint(
x=self.released_pan_delta.x + self.mouse_pan_delta.x,
y=self.released_pan_delta.y + self.mouse_pan_delta.y)
def _fill_boxes(self):
rows, cols = self.box_value.shape
for row in range(rows):
for col in range(cols):
if self.box_same[row, col]:
# define inside of box
bottom_left = tuples.PixelPoint(x=col * self.mesh_step + 1,
y=row * self.mesh_step + 1)
top_right = tuples.PixelPoint(
x=(col + 1) * self.mesh_step - 1,
y=(row + 1) * self.mesh_step - 1)
self.server.fill_box_request(bottom_left, top_right,
self.box_value[row, col])
def source_to_transformed_frame(self, source_point: tuples.PixelPoint):
# always uses numpy as just one point
source_np = np.array([source_point.x, source_point.y], dtype=float)
frame_np = np.matmul(self._source_frame_matrix,
source_np) + self._source_frame_vector
frame_point = tuples.PixelPoint(x=frame_np[0], y=frame_np[1])
return frame_point
def center_frame_point(self) -> Optional[tuples.ImageShape]:
frame_shape = self.frame_shape
if frame_shape is None:
return None
else:
center_frame_point = tuples.PixelPoint(
x=(self.frame_shape.x - 1) * 0.5,
y=(self.frame_shape.y - 1) * 0.5)
return center_frame_point
def get_complex_from_frame_point(
self, frame_shape: tuples.ImageShape,
frame_point: tuples.PixelPoint) -> complex:
# print(f"frame_shape: {frame_shape}")
# print(f"frame_point: {frame_point}")
# print(f"shape: {self.shape}")
center_diff = tuples.PixelPoint(
x=frame_point.x - 0.5 * (frame_shape.x - 1),
y=frame_point.y - 0.5 * (frame_shape.y - 1))
return self.get_complex_from_center_diff(center_diff)
def _calc_offset(
self,
previous_shape: tuples.ImageShape,
new_shape: tuples.ImageShape,
pan: Optional[tuples.PixelPoint] = None) -> tuples.PixelPoint:
# possibly should be floats, especially if pan is None
x = int((previous_shape.x - new_shape.x) / 2.0)
y = int((previous_shape.y - new_shape.y) / 2.0)
if pan is not None:
x += pan.x
y += pan.y
return tuples.PixelPoint(x, y)
def _update_offset(self):
"""Called once canvas or frame is updated"""
canvas_shape = self._canvas_source.shape
frame_shape = self._frame.frame_shape
# print(f"canvas_shape: {canvas_shape}")
# print(f"frame_shape: {frame_shape}")
if canvas_shape is not None and frame_shape is not None:
current_frame_offset = self._frame.offset
# offset when frame centered in canvas
offset = tuples.PixelPoint(
x=int((canvas_shape.x - frame_shape.x) / 2.0),
y=int((canvas_shape.y - frame_shape.y) / 2.0))
# print(f"offset: {offset}")
if current_frame_offset is None or offset != current_frame_offset:
self._frame.set_offset(offset)
def add_border(self, mandel: mandelbrot.Mandel):
border_size = 14 * 4 * 10 # add 5 large boxes in all directions
current_shape = mandel.shape
new_shape = tuples.ImageShape(current_shape.x + border_size * 2,
current_shape.y + border_size * 2)
self.new_mandel = mandel.lite_copy(shape=new_shape, has_border=True)
offset = tuples.PixelPoint(x=-border_size, y=-border_size)
job = mandelbrot.MandelJob(
compute_manager=self._compute_manager,
new_mandel=self.new_mandel,
prev_mandel=mandel,
offset=offset,
display_progress=False, # background job
save_history=False)
self._calc_thread_manager.request_job(job,
queue_as=thread.QueueAs.ENQUEUE)
def get_source_point_from_complex(
self, z: complex) -> Optional[tuples.PixelPoint]:
dz = z - self.centre
# take dot products
x_dist = dz.real * self.x_unit.real + dz.imag * self.x_unit.imag
y_dist = dz.real * self.y_unit.real + dz.imag * self.y_unit.imag
x_pixels_from_center = x_dist / self.size_per_gap
y_pixels_from_center = y_dist / self.size_per_gap
x_pixel = 0.5 * float(self.shape.x - 1) + x_pixels_from_center
y_pixel = 0.5 * float(self.shape.y - 1) + y_pixels_from_center
x = round(x_pixel)
y = round(y_pixel)
if 0 <= x <= self.shape.x - 1 and 0 <= y <= self.shape.y - 1:
return tuples.PixelPoint(x, y)
else:
return None
def top_right(self) -> tuples.PixelPoint:
return tuples.PixelPoint(x=self.x_max, y=self.y_min)
def bottom_left(self) -> tuples.PixelPoint:
return tuples.PixelPoint(x=self.x_min, y=self.y_min)
def mouse_pan_delta(self) -> Optional[tuples.PixelPoint]:
if self.pan_start is not None and self.pan_end is not None:
return tuples.PixelPoint(x=self.pan_start.x - self.pan_end.x,
y=self.pan_start.y - self.pan_end.y)
else:
return tuples.PixelPoint(0, 0)
def _reset_transform(self):
self._pan = tuples.PixelPoint(0, 0)
self._rotation_degrees = 0
self._scale = 1.0
self._scale_point = tuples.PixelPoint(0, 0)
def _calculate_transform(self):
"""takes 0.0001s"""
# purely numpy
# functions
identity = transform.Transform.identity
flip_y = transform.Transform.flip_y
translate = transform.Transform.translate
scale = transform.Transform.scale
rotate_degrees = transform.Transform.rotate_degrees
# values
# source_x = float(self._source.shape[1])
source_y = float(self._source_np.shape[0])
frame_x = float(self.frame_shape.x)
frame_y = float(self.frame_shape.y)
# cartesian offset when source and portal were first generated, x and y are both positive
offset_x = float(self.offset.x)
offset_y = float(self.offset.y)
# goal is to get from frame_image co-ordinates to transformed source_image co-ordinates
# want to do all the transforms in portal cartesian co-ordinates
# path portal-image -> portal-cartesian -> portal-cartesian-transformed -> source-cartesian -> source-image
# can't directly chain transforms.Affine2D so just deal in matrices
# x unchanged, flip y (inverse of itself)
frame_image_to_frame_cartesian = flip_y(frame_y)
if self._rotation_degrees != 0.0:
center_x, centre_y = frame_x * 0.5, frame_y * 0.5
# 1) move center to origin
# 2) rotate
# 3) move origin back to center
# so in reserve order:
frame_transform = translate(center_x, centre_y) @ \
rotate_degrees(self._rotation_degrees) @ \
translate(-center_x, -centre_y)
elif self._scale != 1.0:
center_x, centre_y = frame_x * 0.5, frame_y * 0.5
# 1) move scale_point to origin
# 2) scale
# 3) move origin back to center
# so in reserve order:
frame_transform = translate(self._scale_point.x, self._scale_point.y) @ \
scale(self._scale) @ \
translate(-center_x, -centre_y)
elif self._pan != tuples.PixelPoint(0, 0):
frame_transform = translate(self._pan.x, self._pan.y)
else:
frame_transform = identity()
frame_cartesian_to_source_cartesian = translate(offset_x, offset_y)
# x unchanged, flip y (inverse of itself)
source_cartesian_to_source_image = flip_y(source_y)
# combine matrices using multiplication, so in reserve order:
frame_image_to_source_image = source_cartesian_to_source_image @ \
frame_cartesian_to_source_cartesian @ \
frame_transform @ \
frame_image_to_frame_cartesian
# final transform for frame_image to source_image
self._matrix = frame_image_to_source_image[0:2, 0:2]
self._vector = frame_image_to_source_image[0:2, 2]
# source_point to frame_point transform
source_cartesian_to_frame_cartesian = translate(-offset_x, -offset_y)
inv_frame_transform = np.linalg.inv(frame_transform)
# combine matrices using multiplication, so in reserve order:
source_cartesian_to_frame_point = inv_frame_transform @ \
source_cartesian_to_frame_cartesian
self._source_frame_matrix = source_cartesian_to_frame_point[0:2, 0:2]
self._source_frame_vector = source_cartesian_to_frame_point[0:2, 2]
def _frame_image_to_frame_cartesian(self, x: int,
y: int) -> tuples.PixelPoint:
frame_y = self._view_state.frame_shape.y
frame_point = tuples.PixelPoint(x=x, y=frame_y - y)
return frame_point
def on_resized(self, new_image_shape: tuples.ImageShape) -> tuples.ImageShape:
self.clear_graph()
min_length = min(new_image_shape.x, new_image_shape.y)
self._image_shape = tuples.PixelPoint(x=min_length, y=min_length)
return self._image_shape
def run(self) -> np.ndarray:
bottom_left = tuples.PixelPoint(0, 0)
top_right = tuples.PixelPoint(x=self.shape.x, y=self.shape.y)
self.server.box_request(bottom_left, top_right)
self.server.serve()
return self.server.iteration_cpu
