I have a program with an interactive figure where occasionally many artists are drawn. In this figure, you can also zoom and pan using the mouse. However, the performace during zooming an panning is not very good because every artist is always redrawn. Is there a way to check which artists are in the currently displayed area and only redraw those? (In the example below the perfomace is still relatively good, but it can be made arbitrarily worse by using more or more complex artists)

I had a similar performace problem with the `hover`

method that whenever it was called it ran `canvas.draw()`

at the end. But as you can see I found a neat workaround for that by making use of caching and restoring the background of the axes (based on this). This significantly improved the performace and now even with many artists it runs very smooth. Maybe there is a similar way of doing this but for the `pan`

and `zoom`

method?

Sorry for the long code sample, most of it is not directly relevant for the question but necessary for a working example to highlight the issue.

**EDIT**

I updated the MWE to something that is more representative of my actual code.

```
import numpy as np
import sys
import matplotlib.pyplot as plt
from matplotlib.backends.backend_qt5agg import \
FigureCanvasQTAgg
import matplotlib.patheffects as PathEffects
from matplotlib.text import Annotation
from matplotlib.collections import LineCollection
from PyQt5.QtWidgets import QApplication, QVBoxLayout, QDialog
def check_limits(base_xlim, base_ylim, new_xlim, new_ylim):
if new_xlim[0] < base_xlim[0]:
overlap = base_xlim[0] - new_xlim[0]
new_xlim[0] = base_xlim[0]
if new_xlim[1] + overlap > base_xlim[1]:
new_xlim[1] = base_xlim[1]
else:
new_xlim[1] += overlap
if new_xlim[1] > base_xlim[1]:
overlap = new_xlim[1] - base_xlim[1]
new_xlim[1] = base_xlim[1]
if new_xlim[0] - overlap < base_xlim[0]:
new_xlim[0] = base_xlim[0]
else:
new_xlim[0] -= overlap
if new_ylim[1] < base_ylim[1]:
overlap = base_ylim[1] - new_ylim[1]
new_ylim[1] = base_ylim[1]
if new_ylim[0] + overlap > base_ylim[0]:
new_ylim[0] = base_ylim[0]
else:
new_ylim[0] += overlap
if new_ylim[0] > base_ylim[0]:
overlap = new_ylim[0] - base_ylim[0]
new_ylim[0] = base_ylim[0]
if new_ylim[1] - overlap < base_ylim[1]:
new_ylim[1] = base_ylim[1]
else:
new_ylim[1] -= overlap
return new_xlim, new_ylim
class FigureCanvas(FigureCanvasQTAgg):
def __init__(self, *args, **kwargs):
super().__init__(*args, **kwargs)
self.bg_cache = None
def draw(self):
ax = self.figure.axes[0]
hid_annotation = False
if ax.annot.get_visible():
ax.annot.set_visible(False)
hid_annotation = True
hid_highlight = False
if ax.last_artist:
ax.last_artist.set_path_effects([PathEffects.Normal()])
hid_highlight = True
super().draw()
self.bg_cache = self.copy_from_bbox(self.figure.bbox)
if hid_highlight:
ax.last_artist.set_path_effects(
[PathEffects.withStroke(
linewidth=7, foreground="c", alpha=0.4
)]
)
ax.draw_artist(ax.last_artist)
if hid_annotation:
ax.annot.set_visible(True)
ax.draw_artist(ax.annot)
if hid_highlight:
self.update()
def position(t_, coeff, var=0.1):
x_ = np.random.normal(np.polyval(coeff[:, 0], t_), var)
y_ = np.random.normal(np.polyval(coeff[:, 1], t_), var)
return x_, y_
class Data:
def __init__(self, times):
self.length = np.random.randint(1, 20)
self.t = np.sort(
np.random.choice(times, size=self.length, replace=False)
)
self.vel = [np.random.uniform(-2, 2), np.random.uniform(-2, 2)]
self.accel = [np.random.uniform(-0.01, 0.01), np.random.uniform(-0.01,
0.01)]
x0, y0 = np.random.uniform(0, 1000, 2)
self.x, self.y = position(
self.t, np.array([self.accel, self.vel, [x0, y0]])
)
class Test(QDialog):
def __init__(self):
super().__init__()
self.fig, self.ax = plt.subplots()
self.canvas = FigureCanvas(self.fig)
self.artists = []
self.zoom_factor = 1.5
self.x_press = None
self.y_press = None
self.annot = Annotation(
"", xy=(0, 0), xytext=(-20, 20), textcoords="offset points",
bbox=dict(boxstyle="round", fc="w", alpha=0.7), color='black',
arrowprops=dict(arrowstyle="->"), zorder=6, visible=False,
annotation_clip=False, in_layout=False,
)
self.annot.set_clip_on(False)
setattr(self.ax, 'annot', self.annot)
self.ax.add_artist(self.annot)
self.last_artist = None
setattr(self.ax, 'last_artist', self.last_artist)
self.image = np.random.uniform(0, 100, 1000000).reshape((1000, 1000))
self.ax.imshow(self.image, cmap='gray', interpolation='nearest')
self.times = np.linspace(0, 20)
for i in range(1000):
data = Data(self.times)
points = np.array([data.x, data.y]).T.reshape(-1, 1, 2)
segments = np.concatenate([points[:-1], points[1:]], axis=1)
z = np.linspace(0, 1, data.length)
norm = plt.Normalize(z.min(), z.max())
lc = LineCollection(
segments, cmap='autumn', norm=norm, alpha=1,
linewidths=2, picker=8, capstyle='round',
joinstyle='round'
)
setattr(lc, 'data_id', i)
lc.set_array(z)
self.ax.add_artist(lc)
self.artists.append(lc)
self.default_xlim = self.ax.get_xlim()
self.default_ylim = self.ax.get_ylim()
self.canvas.draw()
self.cid_motion = self.fig.canvas.mpl_connect(
'motion_notify_event', self.motion_event
)
self.cid_button = self.fig.canvas.mpl_connect(
'button_press_event', self.pan_press
)
self.cid_zoom = self.fig.canvas.mpl_connect(
'scroll_event', self.zoom
)
layout = QVBoxLayout()
layout.addWidget(self.canvas)
self.setLayout(layout)
def zoom(self, event):
if event.inaxes == self.ax:
scale_factor = np.power(self.zoom_factor, -event.step)
xdata = event.xdata
ydata = event.ydata
cur_xlim = self.ax.get_xlim()
cur_ylim = self.ax.get_ylim()
x_left = xdata - cur_xlim[0]
x_right = cur_xlim[1] - xdata
y_top = ydata - cur_ylim[0]
y_bottom = cur_ylim[1] - ydata
new_xlim = [
xdata - x_left * scale_factor, xdata + x_right * scale_factor
]
new_ylim = [
ydata - y_top * scale_factor, ydata + y_bottom * scale_factor
]
# intercept new plot parameters if they are out of bounds
new_xlim, new_ylim = check_limits(
self.default_xlim, self.default_ylim, new_xlim, new_ylim
)
if cur_xlim != tuple(new_xlim) or cur_ylim != tuple(new_ylim):
self.ax.set_xlim(new_xlim)
self.ax.set_ylim(new_ylim)
self.canvas.draw_idle()
def motion_event(self, event):
if event.button == 1:
self.pan_move(event)
else:
self.hover(event)
def pan_press(self, event):
if event.inaxes == self.ax:
self.x_press = event.xdata
self.y_press = event.ydata
def pan_move(self, event):
if event.inaxes == self.ax:
xdata = event.xdata
ydata = event.ydata
cur_xlim = self.ax.get_xlim()
cur_ylim = self.ax.get_ylim()
dx = xdata - self.x_press
dy = ydata - self.y_press
new_xlim = [cur_xlim[0] - dx, cur_xlim[1] - dx]
new_ylim = [cur_ylim[0] - dy, cur_ylim[1] - dy]
# intercept new plot parameters that are out of bound
new_xlim, new_ylim = check_limits(
self.default_xlim, self.default_ylim, new_xlim, new_ylim
)
if cur_xlim != tuple(new_xlim) or cur_ylim != tuple(new_ylim):
self.ax.set_xlim(new_xlim)
self.ax.set_ylim(new_ylim)
self.canvas.draw_idle()
def update_annot(self, event, artist):
self.ax.annot.xy = (event.xdata, event.ydata)
text = f'Data #{artist.data_id}'
self.ax.annot.set_text(text)
self.ax.annot.set_visible(True)
self.ax.draw_artist(self.ax.annot)
def hover(self, event):
vis = self.ax.annot.get_visible()
if event.inaxes == self.ax:
ind = 0
cont = None
while (
ind in range(len(self.artists))
and not cont
):
artist = self.artists[ind]
cont, _ = artist.contains(event)
if cont and artist is not self.ax.last_artist:
if self.ax.last_artist is not None:
self.canvas.restore_region(self.canvas.bg_cache)
self.ax.last_artist.set_path_effects(
[PathEffects.Normal()]
)
self.ax.last_artist = None
artist.set_path_effects(
[PathEffects.withStroke(
linewidth=7, foreground="c", alpha=0.4
)]
)
self.ax.last_artist = artist
self.ax.draw_artist(self.ax.last_artist)
self.update_annot(event, self.ax.last_artist)
ind += 1
if vis and not cont and self.ax.last_artist:
self.canvas.restore_region(self.canvas.bg_cache)
self.ax.last_artist.set_path_effects([PathEffects.Normal()])
self.ax.last_artist = None
self.ax.annot.set_visible(False)
elif vis:
self.canvas.restore_region(self.canvas.bg_cache)
self.ax.last_artist.set_path_effects([PathEffects.Normal()])
self.ax.last_artist = None
self.ax.annot.set_visible(False)
self.canvas.update()
self.canvas.flush_events()
if __name__ == '__main__':
app = QApplication(sys.argv)
test = Test()
test.show()
sys.exit(app.exec_())
```

`plot`

with all points, the problem would not occur.