I'm plotting several images at once, sharing axes, because I use it for exploratory purposes. Each image is the same satellite image at different dates. I'm experimenting a slow response from matplotlib when zooming and panning, and I would like to ask for any tips that could speed up the process.
What I am doing now is:
Load data from several netcdf files.
Calculate maximum value of all the data, for normalization.
Create a grid of subplots using ImageGrid. As each subplot is generated, I delete the array to free some memory (each array is stored in a list, the "deletion" is just a list.pop()). See the code below.
It's 15 images, single-channel, of 4600x3840 pixels each. I've noticed that the bottleneck is not the RAM (I have 8 GB), but the processor. Python spikes to 100% usage on one of the cores when zooming or panning (it's an Intel(R) Core(TM) i5-2500 CPU @ 3.30GHz, 4 cores, 64 bit).
The code is:
import os import sys import numpy as np import netCDF4 as ncdf import matplotlib.pyplot as plt from mpl_toolkits.axes_grid1 import ImageGrid from matplotlib.colors import LogNorm MIN = 0.001 # Hardcoded minimum data value used in normalization variable = 'conc_chl' units = r'$mg/m^3$' data =  dates =  # Get a list of only netCDF files filelist = os.listdir(sys.argv) filelist = [f for f in filelist if os.path.splitext(f) == '.nc'] filelist.sort() filelist.reverse() # Load data and extract dates from filenames for f in filelist: dataset = ncdf.Dataset(os.path.join(sys.argv,f), 'r') data.append(dataset.variables[variable][:]) dataset.close() dates.append((f.split('_')[:-3],f.split('_'))) # Get the maximum value of all data. Will be used for normalization maxc = np.array(data).max() # Plot the grid of images + dates fig = plt.figure() grid = ImageGrid(fig, 111,\ nrows_ncols = (3, 5),\ axes_pad = 0.0,\ share_all=True,\ aspect = False,\ cbar_location = "right",\ cbar_mode = "single",\ cbar_size = '2.5%',\ ) for g in grid: v = data.pop() d = dates.pop() im = g.imshow(v, interpolation='none', norm=LogNorm(), vmin=MIN, vmax=maxc) g.text(0.01, 0.01, '-'.join(d), transform = g.transAxes) # Date on a corner cticks = np.logspace(np.log10(MIN), np.log10(maxc), 5) cbar = grid.cbar_axes.colorbar(im) cbar.ax.set_yticks(cticks) cbar.ax.set_yticklabels([str(np.round(t, 2)) for t in cticks]) cbar.set_label_text(units) # Fine-tune figure; make subplots close to each other and hide x ticks for # all fig.subplots_adjust(left=0.02, bottom=0.02, right=0.95, top=0.98, hspace=0, wspace=0) grid.axes_llc.set_yticklabels(, visible=False) grid.axes_llc.set_xticklabels(, visible=False) plt.show()
Any clue about what could be improved to make it more responsive?