# Logarithmic plot of a cumulative distribution function in matplotlib

I have a file containing logged events. Each entry has a time and latency. I'm interested in plotting the cumulative distribution function of the latencies. I'm most interested in tail latencies so I want the plot to have a logarithmic y-axis. I'm interested in the latencies at the following percentiles: 90th, 99th, 99.9th, 99.99th, and 99.999th. Here is my code so far that generates a regular CDF plot:

``````# retrieve event times and latencies from the file
# compute the CDF
cdfx = numpy.sort(latencies)
cdfy = numpy.linspace(1 / len(latencies), 1.0, len(latencies))
# plot the CDF
plt.plot(cdfx, cdfy)
plt.show()
`````` I know what I want the plot to look like, but I've struggled to get it. I want it to look like this (I did not generate this plot): Making the x-axis logarithmic is simple. The y-axis is the one giving me problems. Using `set_yscale('log')` doesn't work because it wants to use powers of 10. I really want the y-axis to have the same ticklabels as this plot.

How can I get my data into a logarithmic plot like this one?

EDIT:

If I set the yscale to 'log', and ylim to [0.1, 1], I get the following plot: The problem is that a typical log scale plot on a data set ranging from 0 to 1 will focus on values close to zero. Instead, I want to focus on the values close to 1.

• What kind of problems are you having wtih `set_yscale('symlog')`? – mziccard Jun 30 '15 at 20:34
• Setting labels positions is a whole different story altogether too. I suppose you could make the scale logarithmic on the y axis (it works, if you have a 0 or -ve number the data are wrong) and then adjuct the labels. – Aleksander Lidtke Jun 30 '15 at 21:12
• What do you mean when you say that the log y-axis "doesn't work"? Could you show us? It isn't mathematically possible to represent 0 on a log scale, so the first value will have to either be masked or clipped to a very small positive number. You can control this behavior by passing either `'mask'` or `'clip'` as the `nonposy=` parameter to `ax.set_yscale()`. – ali_m Jul 1 '15 at 9:36
• have you tried using `loglog` plot function? – basic_bgnr Jul 1 '15 at 11:56

Essentially you need to apply the following transformation to your `Y` values: `-log10(1-y)`. This imposes the only limitation that `y < 1`, so you should be able to have negative values on the transformed plot.

Here's a modified example from `matplotlib` documentation that shows how to incorporate custom transformations into "scales":

``````import numpy as np
from numpy import ma
from matplotlib import scale as mscale
from matplotlib import transforms as mtransforms
from matplotlib.ticker import FixedFormatter, FixedLocator

class CloseToOne(mscale.ScaleBase):
name = 'close_to_one'

def __init__(self, axis, **kwargs):
mscale.ScaleBase.__init__(self)
self.nines = kwargs.get('nines', 5)

def get_transform(self):
return self.Transform(self.nines)

def set_default_locators_and_formatters(self, axis):
axis.set_major_locator(FixedLocator(
np.array([1-10**(-k) for k in range(1+self.nines)])))
axis.set_major_formatter(FixedFormatter(
[str(1-10**(-k)) for k in range(1+self.nines)]))

def limit_range_for_scale(self, vmin, vmax, minpos):
return vmin, min(1 - 10**(-self.nines), vmax)

class Transform(mtransforms.Transform):
input_dims = 1
output_dims = 1
is_separable = True

def __init__(self, nines):
mtransforms.Transform.__init__(self)
self.nines = nines

def transform_non_affine(self, a):
return -ma.log10(1-a)
else:
return -np.log10(1-a)

def inverted(self):
return CloseToOne.InvertedTransform(self.nines)

class InvertedTransform(mtransforms.Transform):
input_dims = 1
output_dims = 1
is_separable = True

def __init__(self, nines):
mtransforms.Transform.__init__(self)
self.nines = nines

def transform_non_affine(self, a):
return 1. - 10**(-a)

def inverted(self):
return CloseToOne.Transform(self.nines)

mscale.register_scale(CloseToOne)

if __name__ == '__main__':
import pylab
pylab.figure(figsize=(20, 9))
t = np.arange(-0.5, 1, 0.00001)
pylab.subplot(121)
pylab.plot(t)
pylab.subplot(122)
pylab.plot(t)
pylab.yscale('close_to_one')

pylab.grid(True)
pylab.show()
`````` Note that you can control the number of 9's via a keyword argument:

``````pylab.figure()
pylab.plot(t)
pylab.yscale('close_to_one', nines=3)
pylab.grid(True)
`````` • great answer. This is exactly what I was looking for. Everything works as expected except one thing... When I try to use scatter() instead of plot(), it doesn't work (nothing shows up). What do I need to do to get scatter() to work? – nic Jul 29 '15 at 18:49
• @nic How do you call `scatter()`? Everything works fine for me if I just replace the `plot()` calls with: `pylab.scatter(t, t)`. – Lev Levitsky Jul 29 '15 at 20:43
• you are right. I had a problem elsewhere. Thanks again for your answer. It was well worth +100 – nic Jul 30 '15 at 0:19
• @nic I have not received it yet, but thanks! And also thanks for the occasion to learn something new: I actually had no idea about this scaling machinery when I saw your question with a nice bounty on it. – Lev Levitsky Jul 30 '15 at 0:45
• Any idea why only works for the `df.plot(...).set_yscale` and not yscale when using pandas? `ValueError: posx and posy should be finite values` This fixes it when adjusting the `bottom` spine. – phant0m Dec 2 '17 at 17:17

Ok, this isn't the cleanest code, but I can't see a way around it. Maybe what I'm really asking for isn't a logarithmic CDF, but I'll wait for a statistician to tell me otherwise. Anyway, here is what I came up with:

``````# retrieve event times and latencies from the file
cdfx = numpy.sort(latencies)
cdfy = numpy.linspace(1 / len(latencies), 1.0, len(latencies))

# find the logarithmic CDF and ylabels
logcdfy = [-math.log10(1.0 - (float(idx) / len(latencies)))
for idx in range(len(latencies))]
labels = ['', '90', '99', '99.9', '99.99', '99.999', '99.9999', '99.99999']
labels = labels[0:math.ceil(max(logcdfy))+1]

# plot the logarithmic CDF
fig = plt.figure()
The messy part is where I change the yticklabels. The `logcdfy` variable will hold values between 0 and 10, and in my example it was between 0 and 6. In this code, I swap the labels with percentiles. The `plot` function could also be used but I like the way the `scatter` function shows the outliers on the tail. Also, I choose not to make the x-axis on a log scale because my particular data has a good linear line without it. 