In Matplotlib, it's not too tough to make a legend (example_legend(), below), but I think it's better style to put labels right on the curves being plotted (as in example_inline(), below). This can be very fiddly, because I have to specify coordinates by hand, and, if I re-format the plot, I probably have to reposition the labels. Is there a way to automatically generate labels on curves in Matplotlib? Bonus points for being able to orient the text at an angle corresponding to the angle of the curve.

import numpy as np
import matplotlib.pyplot as plt

def example_legend():
    x = np.linspace(0, 1, 101)
    y1 = np.sin(x * np.pi / 2)
    y2 = np.cos(x * np.pi / 2)
    plt.plot(x, y1, label='sin')
    plt.plot(x, y2, label='cos')

Figure with legend

def example_inline():
    x = np.linspace(0, 1, 101)
    y1 = np.sin(x * np.pi / 2)
    y2 = np.cos(x * np.pi / 2)
    plt.plot(x, y1, label='sin')
    plt.plot(x, y2, label='cos')
    plt.text(0.08, 0.2, 'sin')
    plt.text(0.9, 0.2, 'cos')

Figure with inline labels

6 Answers 6


Update: User cphyc has kindly created a Github repository for the code in this answer (see here), and bundled the code into a package which may be installed using pip install matplotlib-label-lines.

Pretty Picture:

semi-automatic plot-labeling

In matplotlib it's pretty easy to label contour plots (either automatically or by manually placing labels with mouse clicks). There does not (yet) appear to be any equivalent capability to label data series in this fashion! There may be some semantic reason for not including this feature which I am missing.

Regardless, I have written the following module which takes any allows for semi-automatic plot labelling. It requires only numpy and a couple of functions from the standard math library.


The default behaviour of the labelLines function is to space the labels evenly along the x axis (automatically placing at the correct y-value of course). If you want you can just pass an array of the x co-ordinates of each of the labels. You can even tweak the location of one label (as shown in the bottom right plot) and space the rest evenly if you like.

In addition, the label_lines function does not account for the lines which have not had a label assigned in the plot command (or more accurately if the label contains '_line').

Keyword arguments passed to labelLines or labelLine are passed on to the text function call (some keyword arguments are set if the calling code chooses not to specify).


  • Annotation bounding boxes sometimes interfere undesirably with other curves. As shown by the 1 and 10 annotations in the top left plot. I'm not even sure this can be avoided.
  • It would be nice to specify a y position instead sometimes.
  • It's still an iterative process to get annotations in the right location
  • It only works when the x-axis values are floats


  • By default, the labelLines function assumes that all data series span the range specified by the axis limits. Take a look at the blue curve in the top left plot of the pretty picture. If there were only data available for the x range 0.5-1 then then we couldn't possibly place a label at the desired location (which is a little less than 0.2). See this question for a particularly nasty example. Right now, the code does not intelligently identify this scenario and re-arrange the labels, however there is a reasonable workaround. The labelLines function takes the xvals argument; a list of x-values specified by the user instead of the default linear distribution across the width. So the user can decide which x-values to use for the label placement of each data series.

Also, I believe this is the first answer to complete the bonus objective of aligning the labels with the curve they're on. :)


from math import atan2,degrees
import numpy as np

#Label line with line2D label data
def labelLine(line,x,label=None,align=True,**kwargs):

    ax = line.axes
    xdata = line.get_xdata()
    ydata = line.get_ydata()

    if (x < xdata[0]) or (x > xdata[-1]):
        print('x label location is outside data range!')

    #Find corresponding y co-ordinate and angle of the line
    ip = 1
    for i in range(len(xdata)):
        if x < xdata[i]:
            ip = i

    y = ydata[ip-1] + (ydata[ip]-ydata[ip-1])*(x-xdata[ip-1])/(xdata[ip]-xdata[ip-1])

    if not label:
        label = line.get_label()

    if align:
        #Compute the slope
        dx = xdata[ip] - xdata[ip-1]
        dy = ydata[ip] - ydata[ip-1]
        ang = degrees(atan2(dy,dx))

        #Transform to screen co-ordinates
        pt = np.array([x,y]).reshape((1,2))
        trans_angle = ax.transData.transform_angles(np.array((ang,)),pt)[0]

        trans_angle = 0

    #Set a bunch of keyword arguments
    if 'color' not in kwargs:
        kwargs['color'] = line.get_color()

    if ('horizontalalignment' not in kwargs) and ('ha' not in kwargs):
        kwargs['ha'] = 'center'

    if ('verticalalignment' not in kwargs) and ('va' not in kwargs):
        kwargs['va'] = 'center'

    if 'backgroundcolor' not in kwargs:
        kwargs['backgroundcolor'] = ax.get_facecolor()

    if 'clip_on' not in kwargs:
        kwargs['clip_on'] = True

    if 'zorder' not in kwargs:
        kwargs['zorder'] = 2.5


def labelLines(lines,align=True,xvals=None,**kwargs):

    ax = lines[0].axes
    labLines = []
    labels = []

    #Take only the lines which have labels other than the default ones
    for line in lines:
        label = line.get_label()
        if "_line" not in label:

    if xvals is None:
        xmin,xmax = ax.get_xlim()
        xvals = np.linspace(xmin,xmax,len(labLines)+2)[1:-1]

    for line,x,label in zip(labLines,xvals,labels):

Test code to generate the pretty picture above:

from matplotlib import pyplot as plt
from scipy.stats import loglaplace,chi2

from labellines import *

X = np.linspace(0,1,500)
A = [1,2,5,10,20]
funcs = [np.arctan,np.sin,loglaplace(4).pdf,chi2(5).pdf]

for a in A:


for a in A:


for a in A:

xvals = [0.8,0.55,0.22,0.104,0.045]

for a in A:

lines = plt.gca().get_lines()
labelLine(l1,0.6,label=r'$Re=${}'.format(l1.get_label()),ha='left',va='bottom',align = False)

  • 1
    @blujay I'm glad you were able to adapt it to suit your needs. I'll add that constraint as an issue. Oct 11, 2016 at 1:07
  • 1
    @Liza Read my Gotcha I just added for why this is happening. For your case (I'm assuming it's like the one in this question ) unless you want to manually create a list of xvals, you might want to modify the labelLines code a little: change the code under the if xvals is None: scope to create a list based other criteria. You could start with xvals = [(np.min(l.get_xdata())+np.max(l.get_xdata()))/2 for l in lines] Jun 22, 2017 at 16:34
  • 1
    @Liza Your graph intrigues me though. The problem is that your data is not evenly spread across the plot, and you have a lot of curves which are nearly on top of each other. With my solution it might be very difficult to tell labels apart in many cases. I think the best solution is to have blocks of stacked labels in different empty parts of your plot. See this graph for an example with two blocks of stacked labels (one block with 1 label, and another block with 4). Implementing this would be a fair bit of legwork, I might do it at some point in the future. Jun 22, 2017 at 16:51
  • 1
    Note: since Matplotlib 2.0, .get_axes() and .get_axis_bgcolor() have been deprecated. Please replace with .axes and .get_facecolor(), resp.
    – Jiageng
    May 14, 2018 at 11:14
  • 1
    Another awesome thing about labellines is that properties related to plt.text or ax.text applies to it. Meaning you can set fontsize and bbox parameters in the labelLines() function.
    – tionichm
    Jul 4, 2019 at 14:00

@Jan Kuiken's answer is certainly well-thought and thorough, but there are some caveats:

  • it does not work in all cases
  • it requires a fair amount of extra code
  • it may vary considerably from one plot to the next

A much simpler approach is to annotate the last point of each plot. The point can also be circled, for emphasis. This can be accomplished with one extra line:

import matplotlib.pyplot as plt

for i, (x, y) in enumerate(samples):
    plt.plot(x, y)
    plt.text(x[-1], y[-1], f'sample {i}')

A variant would be to use the method matplotlib.axes.Axes.annotate.

  • 3
    +1! It looks like a nice and simple solution. Sorry for the laziness, but how would this look? Would the text be inside the plot or on top of the right y axis?
    – rocarvaj
    Mar 30, 2016 at 14:36
  • 1
    @rocarvaj It depends on other settings. It is possible for the labels to protrude outside the plot box. Two ways to avoid this behavior are: 1) use an index different than -1, 2) set appropriate axis limits to allow space for the labels.
    – 0 _
    Sep 14, 2017 at 11:05
  • 2
    It also becomes a mess, if the plots concentrate on some y value - the endpoints become too close for the text to look nice
    – LazyCat
    Mar 8, 2018 at 20:48
  • @LazyCat: That's true. To fix this, one can make the annotations draggable. A bit of a pain I guess but it would do the trick.
    – PlacidLush
    Apr 20, 2020 at 20:08
  • 1
    Give this guy a medal. Jan 15, 2022 at 4:36

Nice question, a while ago I've experimented a bit with this, but haven't used it a lot because it's still not bulletproof. I divided the plot area into a 32x32 grid and calculated a 'potential field' for the best position of a label for each line according the following rules:

  • white space is a good place for a label
  • Label should be near corresponding line
  • Label should be away from the other lines

The code was something like this:

import matplotlib.pyplot as plt
import numpy as np
from scipy import ndimage

def my_legend(axis = None):

    if axis == None:
        axis = plt.gca()

    N = 32
    Nlines = len(axis.lines)
    print Nlines

    xmin, xmax = axis.get_xlim()
    ymin, ymax = axis.get_ylim()

    # the 'point of presence' matrix
    pop = np.zeros((Nlines, N, N), dtype=np.float)    

    for l in range(Nlines):
        # get xy data and scale it to the NxN squares
        xy = axis.lines[l].get_xydata()
        xy = (xy - [xmin,ymin]) / ([xmax-xmin, ymax-ymin]) * N
        xy = xy.astype(np.int32)
        # mask stuff outside plot        
        mask = (xy[:,0] >= 0) & (xy[:,0] < N) & (xy[:,1] >= 0) & (xy[:,1] < N)
        xy = xy[mask]
        # add to pop
        for p in xy:
            pop[l][tuple(p)] = 1.0

    # find whitespace, nice place for labels
    ws = 1.0 - (np.sum(pop, axis=0) > 0) * 1.0 
    # don't use the borders
    ws[:,0]   = 0
    ws[:,N-1] = 0
    ws[0,:]   = 0  
    ws[N-1,:] = 0  

    # blur the pop's
    for l in range(Nlines):
        pop[l] = ndimage.gaussian_filter(pop[l], sigma=N/5)

    for l in range(Nlines):
        # positive weights for current line, negative weight for others....
        w = -0.3 * np.ones(Nlines, dtype=np.float)
        w[l] = 0.5

        # calculate a field         
        p = ws + np.sum(w[:, np.newaxis, np.newaxis] * pop, axis=0)
        plt.imshow(p, interpolation='nearest')

        pos = np.argmax(p)  # note, argmax flattens the array first 
        best_x, best_y =  (pos / N, pos % N) 
        x = xmin + (xmax-xmin) * best_x / N       
        y = ymin + (ymax-ymin) * best_y / N       

        axis.text(x, y, axis.lines[l].get_label(), 


x = np.linspace(0, 1, 101)
y1 = np.sin(x * np.pi / 2)
y2 = np.cos(x * np.pi / 2)
y3 = x * x
plt.plot(x, y1, 'b', label='blue')
plt.plot(x, y2, 'r', label='red')
plt.plot(x, y3, 'g', label='green')

And the resulting plot: enter image description here

  • Very nice. However, I have an example that doesn't completely work: plt.plot(x2, 3*x2**2, label="3x*x"); plt.plot(x2, 2*x2**2, label="2x*x"); plt.plot(x2, 0.5*x2**2, label="0.5x*x"); plt.plot(x2, -1*x2**2, label="-x*x"); plt.plot(x2, -2.5*x2**2, label="-2.5*x*x"); my_legend(); This puts one of the labels in the upper left corner. Any ideas on how to fix this? Seems like the problem may be that the lines are too close together.
    – egpbos
    Mar 12, 2014 at 12:58
  • Sorry, forgot x2 = np.linspace(0,0.5,100).
    – egpbos
    Mar 12, 2014 at 13:06
  • Is there any way to use this without scipy? On my current system it's a pain to install.
    – AnnanFay
    Mar 15, 2016 at 21:44
  • 1
    This doesn't work for me under Python 3.6.4, Matplotlib 2.1.2, and Scipy 1.0.0. After updating the print command, it runs and creates 4 plots, 3 of which appear to be pixelated gibberish (probably something to do with the 32x32), and the fourth with labels in odd places.
    – Y Davis
    Feb 27, 2018 at 13:46

matplotx (which I wrote) has line_labels() which plots the labels to the right of the lines. It's also smart enough to avoid overlaps when too many lines are concentrated in one spot. (See stargraph for examples.) It does that by solving a particular non-negative-least-squares problem on the target positions of the labels. Anyway, in many cases where there's no overlap to begin with, such as the example below, that's not even necessary.

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

# create data
rng = np.random.default_rng(0)
offsets = [1.0, 1.50, 1.60]
labels = ["no balancing", "CRV-27", "CRV-27*"]
x0 = np.linspace(0.0, 3.0, 100)
y = [offset * x0 / (x0 + 1) + 0.1 * rng.random(len(x0)) for offset in offsets]

# plot
with plt.style.context(matplotx.styles.dufte):
    for yy, label in zip(y, labels):
        plt.plot(x0, yy, label=label)
    plt.xlabel("distance [m]")
    matplotx.ylabel_top("voltage [V]")  # move ylabel to the top, rotate
    matplotx.line_labels()  # line labels to the right
    # plt.savefig("out.png", bbox_inches="tight")

enter image description here


I have made another approach from @NauticalMile idea, packaged by @cphyc, adding automatic label positioning using Shapely to avoid overlaps. It can be helpful if you have many graphs with many lines, as it avoids manual label positioning.

With the original examples, it gives: Examples

You can try it with pip install matplotlib-inline-labels. See repo.


A simpler approach like the one Ioannis Filippidis do :

import matplotlib.pyplot as plt
import numpy as np

# evenly sampled time at 200ms intervals
tMin=-1 ;tMax=10
t = np.arange(tMin, tMax, 0.1)

# red dashes, blue points default
plt.plot(t, 22*t, 'r--', t, t**2, 'b')

factor=3/4 ;offset=20  # text position in view  
plt.text(textPosition[0],textPosition[1]+offset,'22  t',color='red',fontsize=20)
plt.text(textPosition[0],textPosition[1]+offset, 't^2', bbox=dict(facecolor='blue', alpha=0.5),fontsize=20)

code python 3 on sageCell

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