I'm not entirely clear on what you want, so I'm going to guess, here...

You want the "Probability/Percentile" values to be a cumulative histogram?

So for a single plot, you'd have something like this? (Plotting it with markers as you've shown above, instead of the more traditional step plot...)

```
import scipy.stats
import numpy as np
import matplotlib.pyplot as plt
# 100 values from a normal distribution with a std of 3 and a mean of 0.5
data = 3.0 * np.random.randn(100) + 0.5
counts, start, dx, _ = scipy.stats.cumfreq(data, numbins=20)
x = np.arange(counts.size) * dx + start
plt.plot(x, counts, 'ro')
plt.xlabel('Value')
plt.ylabel('Cumulative Frequency')
plt.show()
```

If that's roughly what you want for a single plot, there are multiple ways of making multiple plots on a figure. The easiest is just to use subplots.

Here, we'll generate some datasets and plot them on different subplots with different symbols...

```
import itertools
import scipy.stats
import numpy as np
import matplotlib.pyplot as plt
# Generate some data... (Using a list to hold it so that the datasets don't
# have to be the same length...)
numdatasets = 4
stds = np.random.randint(1, 10, size=numdatasets)
means = np.random.randint(-5, 5, size=numdatasets)
values = [std * np.random.randn(100) + mean for std, mean in zip(stds, means)]
# Set up several subplots
fig, axes = plt.subplots(nrows=1, ncols=numdatasets, figsize=(12,6))
# Set up some colors and markers to cycle through...
colors = itertools.cycle(['b', 'g', 'r', 'c', 'm', 'y', 'k'])
markers = itertools.cycle(['o', '^', 's', r'$\Phi$', 'h'])
# Now let's actually plot our data...
for ax, data, color, marker in zip(axes, values, colors, markers):
counts, start, dx, _ = scipy.stats.cumfreq(data, numbins=20)
x = np.arange(counts.size) * dx + start
ax.plot(x, counts, color=color, marker=marker,
markersize=10, linestyle='none')
# Next we'll set the various labels...
axes[0].set_ylabel('Cumulative Frequency')
labels = ['This', 'That', 'The Other', 'And Another']
for ax, label in zip(axes, labels):
ax.set_xlabel(label)
plt.show()
```

If we want this to look like one continuous plot, we can just squeeze the subplots together and turn off some of the boundaries. Just add the following in before calling `plt.show()`

```
# Because we want this to look like a continuous plot, we need to hide the
# boundaries (a.k.a. "spines") and yticks on most of the subplots
for ax in axes[1:]:
ax.spines['left'].set_color('none')
ax.spines['right'].set_color('none')
ax.yaxis.set_ticks([])
axes[0].spines['right'].set_color('none')
# To reduce clutter, let's leave off the first and last x-ticks.
for ax in axes:
xticks = ax.get_xticks()
ax.set_xticks(xticks[1:-1])
# Now, we'll "scrunch" all of the subplots together, so that they look like one
fig.subplots_adjust(wspace=0)
```

Hopefully that helps a bit, at any rate!

Edit: If you want percentile values, instead a cumulative histogram (I really shouldn't have used 100 as the sample size!), it's easy to do.

Just do something like this (using `numpy.percentile`

instead of normalizing things by hand):

```
# Replacing the for loop from before...
plot_percentiles = range(0, 110, 10)
for ax, data, color, marker in zip(axes, values, colors, markers):
x = np.percentile(data, plot_percentiles)
ax.plot(x, plot_percentiles, color=color, marker=marker,
markersize=10, linestyle='none')
```