# Getting individual colors from a color map in matplotlib

If you have a Colormap `cmap`, for example:

``````cmap = matplotlib.cm.get_cmap('Spectral')
``````

How can you get a particular colour out of it between 0 and 1, where 0 is the first colour in the map and 1 is the last colour in the map?

Ideally, I would be able to get the middle colour in the map by doing:

``````>>> do_some_magic(cmap, 0.5) # Return an RGBA tuple
(0.1, 0.2, 0.3, 1.0)
``````

You can do this with the code below, and the code in your question was actually very close to what you needed, all you have to do is call the `cmap` object you have.

``````import matplotlib

cmap = matplotlib.cm.get_cmap('Spectral')

rgba = cmap(0.5)
print(rgba) # (0.99807766255210428, 0.99923106502084169, 0.74602077638401709, 1.0)
``````

For values outside of the range [0.0, 1.0] it will return the under and over colour (respectively). This, by default, is the minimum and maximum colour within the range (so 0.0 and 1.0). This default can be changed with `cmap.set_under()` and `cmap.set_over()`.

For "special" numbers such as `np.nan` and `np.inf` the default is to use the 0.0 value, this can be changed using `cmap.set_bad()` similarly to under and over as above.

Finally it may be necessary for you to normalize your data such that it conforms to the range `[0.0, 1.0]`. This can be done using `matplotlib.colors.Normalize` simply as shown in the small example below where the arguments `vmin` and `vmax` describe what numbers should be mapped to 0.0 and 1.0 respectively.

``````import matplotlib

norm = matplotlib.colors.Normalize(vmin=10.0, vmax=20.0)

print(norm(15.0)) # 0.5
``````

A logarithmic normaliser (matplotlib.colors.LogNorm) is also available for data ranges with a large range of values.

(Thanks to both Joe Kington and tcaswell for suggestions on how to improve the answer.)

• Actually, for values less than 0 or more than 1 it will return the "over" or "under" color. By default it's the color at the bottom/top of the colormap, but that's changable. For example: `cmap.set_under('red'); print cmap(0.0), cmap(-0.01)` Commented Aug 20, 2014 at 15:55
• Hi @Joe, thanks for the correction, I've modified my answer :) Commented Aug 20, 2014 at 15:58
• Very useful information and why on earth is it impossible to find this in the documentation!?! Commented Jan 8, 2017 at 19:55
• If this isn't working for anyone, and you see `module 'matplotlib' has no attribute 'cm'`, try replacing the first two lines with `import matplotlib.pyplot as plt; cmap = plt.cm.get_cmap('Spectral')` Commented Jul 20, 2018 at 20:41
• Since this way is getting deprecated, here's an up-to-date one: `import matplotlib` `cmap = matplotlib.colormaps["Spectral"]` Commented Aug 4, 2023 at 9:09

In order to get rgba integer value instead of float value, we can do

``````rgba = cmap(0.5,bytes=True)
``````

So to simplify the code based on answer from Ffisegydd, the code would be like this:

``````#import colormap
from matplotlib import cm

#normalize item number values to colormap
norm = matplotlib.colors.Normalize(vmin=0, vmax=1000)

#colormap possible values = viridis, jet, spectral
rgba_color = cm.jet(norm(400),bytes=True)

#400 is one of value between 0 and 1000
``````

I once ran into a similar situation where I needed "n" no. of colors from a colormap so that I can assign each color to my data. I have compiled a code to this in a package called "mycolorpy". You can pip install it using:

``````pip install mycolorpy
``````

You can then do:

``````from mycolorpy import colorlist as mcp
import numpy as np
``````

Example: To create a list of 5 hex strings from cmap "winter"

``````color1=mcp.gen_color(cmap="winter",n=5)
print(color1)
``````

Output:

``````['#0000ff', '#0040df', '#0080bf', '#00c09f', '#00ff80']
``````

Another example to generate 16 list of colors from cmap bwr:

``````color2=mcp.gen_color(cmap="bwr",n=16)
print(color2)
``````

Output:

``````['#0000ff', '#2222ff', '#4444ff', '#6666ff', '#8888ff', '#aaaaff', '#ccccff', '#eeeeff', '#ffeeee', '#ffcccc', '#ffaaaa', '#ff8888', '#ff6666', '#ff4444', '#ff2222', '#ff0000']
``````

There is a python notebook with usage examples to better visualize this.

Say you want to generate a list of colors from a cmap that is normalized to a given data. You can do that using:

``````a=random.randint(1000, size=(200))
a=np.array(a)
color1=mcp.gen_color_normalized(cmap="seismic",data_arr=a)
plt.scatter(a,a,c=color1)
``````

Output:

You can also reverse the color using:

``````color1=mcp.gen_color_normalized(cmap="seismic",data_arr=a,reverse=True)
plt.scatter(a,a,c=color1)
``````

Output:

• This does not answer the OP's question, while it already has an excellent approved answer. Added to this is that there are already tools out there that do a great job at the performing the process you describe, like CMasher (cmasher.readthedocs.io/index.html). Commented Nov 30, 2021 at 11:05
• @1313e: The "excellent approved answer" doesn't work anymore. So there's that. Thanks for the link to this excellent library, though. Commented Jan 20, 2022 at 7:07
• Thank you so much! Saved my day. Commented Feb 8, 2022 at 17:13

I had precisely this problem, but I needed sequential plots to have highly contrasting color. I was also doing plots with a common sub-plot containing reference data, so I wanted the color sequence to be consistently repeatable.

I initially tried simply generating colors randomly, reseeding the RNG before each plot. This worked OK (commented-out in code below), but could generate nearly indistinguishable colors. I wanted highly contrasting colors, ideally sampled from a colormap containing all colors.

I could have as many as 31 data series in a single plot, so I chopped the colormap into that many steps. Then I walked the steps in an order that ensured I wouldn't return to the neighborhood of a given color very soon.

My data is in a highly irregular time series, so I wanted to see the points and the lines, with the point having the 'opposite' color of the line.

Given all the above, it was easiest to generate a dictionary with the relevant parameters for plotting the individual series, then expand it as part of the call.

Here's my code. Perhaps not pretty, but functional.

``````from matplotlib import cm
cmap = cm.get_cmap('gist_rainbow')  #('hsv') #('nipy_spectral')

max_colors = 31   # Constant, max mumber of series in any plot.  Ideally prime.
color_number = 0  # Variable, incremented for each series.

def restart_colors():
global color_number
color_number = 0
#np.random.seed(1)

def next_color():
global color_number
color_number += 1
#color = tuple(np.random.uniform(0.0, 0.5, 3))
color = cmap( ((5 * color_number) % max_colors) / max_colors )
return color

def plot_args():  # Invoked for each plot in a series as: '**(plot_args())'
mkr = next_color()
clr = (1 - mkr[0], 1 - mkr[1], 1 - mkr[2], mkr[3])  # Give line inverse of marker color
return {
"marker": "o",
"color": clr,
"mfc": mkr,
"mec": mkr,
"markersize": 0.5,
"linewidth": 1,
}

``````

My context is JupyterLab and Pandas, so here's sample plot code:

``````restart_colors()  # Repeatable color sequence for every plot

fig, axs = plt.subplots(figsize=(15, 8))
plt.title("%s + T-meter"%name)

# Plot reference temperatures:
axs.set_ylabel("°C", rotation=0)
for s in ["T1", "T2", "T3", "T4"]:
df_tmeter.plot(ax=axs, x="Timestamp", y=s, label="T-meter:%s" % s, **(plot_args()))

# Other series gets their own axis labels
ax2 = axs.twinx()
ax2.set_ylabel(units)

for c in df_uptime_sensors:
df_uptime[df_uptime["UUID"] == c].plot(
ax=ax2, x="Timestamp", y=units, label="%s - %s" % (units, c), **(plot_args())
)

fig.tight_layout()
plt.show()
``````

The resulting plot may not be the best example, but it becomes more relevant when interactively zoomed in.

I found quite short way to return the list of `N` hex colors with matplotlib:

``````import matplotlib

# Choose colormap
cmap = plt.cm.get_cmap('terrain', N)
colors = [matplotlib.colors.to_hex(cmap(i)) for i in range(N)]
``````

Hope, it helps!

To build on the solutions from Ffisegydd and amaliammr, here's an example where we make CSV representation for a custom colormap:

``````#! /usr/bin/env python3
import matplotlib
import numpy as np

vmin = 0.1
vmax = 1000

norm = matplotlib.colors.Normalize(np.log10(vmin), np.log10(vmax))
lognum = norm(np.log10([.5, 2., 10, 40, 150,1000]))

cdict = {
'red':
(
(0., 0, 0),
(lognum[0], 0, 0),
(lognum[1], 0, 0),
(lognum[2], 1, 1),
(lognum[3], 0.8, 0.8),
(lognum[4], .7, .7),
(lognum[5], .7, .7)
),
'green':
(
(0., .6, .6),
(lognum[0], 0.8, 0.8),
(lognum[1], 1, 1),
(lognum[2], 1, 1),
(lognum[3], 0, 0),
(lognum[4], 0, 0),
(lognum[5], 0, 0)
),
'blue':
(
(0., 0, 0),
(lognum[0], 0, 0),
(lognum[1], 0, 0),
(lognum[2], 0, 0),
(lognum[3], 0, 0),
(lognum[4], 0, 0),
(lognum[5], 1, 1)
)
}

mycmap = matplotlib.colors.LinearSegmentedColormap('my_colormap', cdict, 256)
norm = matplotlib.colors.LogNorm(vmin, vmax)
colors = {}
count = 0
step_size = 0.001
for value in np.arange(vmin, vmax+step_size, step_size):
count += 1
print("%d/%d %f%%" % (count, vmax*(1./step_size), 100.*count/(vmax*(1./step_size))))
rgba = mycmap(norm(value), bytes=True)
color = (rgba[0], rgba[1], rgba[2])
if color not in colors.values():
colors[value] = color

print ("value, red, green, blue")
for value in sorted(colors.keys()):
rgb = colors[value]
print("%s, %s, %s, %s" % (value, rgb[0], rgb[1], rgb[2]))
``````

Colormaps come with their own normalize method, so if you have a plot already made you can access the color at a certain value.

``````import matplotlib.pyplot as plt
import numpy as np

cmap = plt.cm.viridis

cm = plt.pcolormesh(np.random.randn(10, 10), cmap=cmap)

print(cmap(cm.norm(2.2)))
``````

Here is a solution that gives a discrete number of color values. The midpoint can be determined by dividing the discrete color map in half.

``````import matplotlib.pyplot as plt
from matplotlib.colors import ListedColormap

# Choose a colormap from Matplotlib
colormap = plt.cm.viridis

# Set number of colors
num_colors = 5

# Create a ListedColormap with discrete colors
discrete_cmap = ListedColormap(colormap(np.linspace(0, 1, num_colors)))

# Output RGB values
for i, rgb in enumerate(discrete_cmap.colors):
print(f"Color {i + 1}: RGB = {rgb}")

# Plot a colorbar to visualize
plt.imshow([[i] for i in range(num_colors)], cmap=discrete_cmap, aspect='auto')
plt.colorbar(ticks=range(num_colors))
plt.show()
``````

What I usually used is

``````import matplotlib.pyplot as plt

n=10 # number of colors you want to get
cmap = plt.cm.get_cmap('rainbow', n) # get 10 colors from rainbow palette

# Use the color
cmap(0)
cmap(1)
...
cmap(9)
``````