Metadata-Version: 1.1
Name: matplotlib-venn
Version: 0.7
Summary: Functions for plotting area-proportional two- and three-way Venn diagrams in matplotlib.
Home-page: https://github.com/konstantint/matplotlib-venn
Author: Konstantin Tretyakov
Author-email: kt@ut.ee
License: MIT
Description: ====================================================
        Venn diagram plotting routines for Python/Matplotlib
        ====================================================
        
        Routines for plotting area-weighted two- and three-circle venn diagrams.
        
        Installation
        ------------
        
        The simplest way to install the package is via ``easy_install`` or ``pip``::
        
            $ easy_install matplotlib-venn
        
        Dependencies
        ------------
        
        - ``numpy``, ``scipy``, ``matplotlib``.
        
        Usage
        -----
        The package provides four main functions: ``venn2``, ``venn2_circles``, ``venn3`` and ``venn3_circles``.
        
        The functions ``venn2`` and ``venn2_circles`` accept as their only required argument a 3-element list ``(Ab, aB, AB)`` of subset sizes, e.g.::
        
            venn2(subsets = (3, 2, 1))
        
        and draw a two-circle venn diagram with respective region areas. In the particular example, the region, corresponding to subset ``A and not B`` will
        be three times larger in area than the region, corresponding to subset ``A and B``. Alternatively, you can simply provide a list of two ``set`` objects instead (new in version 0.7), e.g.::
        
            venn2([set(['A', 'B', 'C', 'D']), set(['D', 'E', 'F'])])
        
        Similarly, the functions ``venn3`` and ``venn3_circles`` take a 7-element list of subset sizes ``(Abc, aBc, ABc, abC, AbC, aBC, ABC)``, and draw a three-circle area-weighted venn diagram. Alternatively, you can provide a list of three set objects (rather than counting sizes for all 7 subsets).
        
        The functions ``venn2_circles`` and ``venn3_circles`` draw just the circles, whereas the functions ``venn2`` and ``venn3`` draw the diagrams as a collection of colored patches, annotated with text labels. In addition (version 0.7+), functions ``venn2_unweighted`` and ``venn3_unweighted`` draw the Venn diagrams without area-weighting.
        
        Note that for a three-circle venn diagram it is not in general possible to achieve exact correspondence between the required set sizes and region areas, however in most cases the picture will still provide a decent indication.
        
        The functions ``venn2_circles`` and ``venn3_circles`` return the list of ``matplotlib.patch.Circle`` objects that may be tuned further 
        to your liking. The functions ``venn2`` and ``venn3`` return an object of class ``VennDiagram``,
        which gives access to constituent patches, text elements, and (since version 0.7) the information about the centers and radii of the circles.
        
        Basic Example::
        
            from matplotlib_venn import venn2
            venn2(subsets = (3, 2, 1))
        
        For the three-circle case::
        
            from matplotlib_venn import venn3
            venn3(subsets = (1, 1, 1, 2, 1, 2, 2), set_labels = ('Set1', 'Set2', 'Set3'))
        
        A more elaborate example::
        
            from matplotlib import pyplot as plt
            import numpy as np
            from matplotlib_venn import venn3, venn3_circles
            plt.figure(figsize=(4,4))
            v = venn3(subsets=(1, 1, 1, 1, 1, 1, 1), set_labels = ('A', 'B', 'C'))
            v.get_patch_by_id('100').set_alpha(1.0)
            v.get_patch_by_id('100').set_color('white')
            v.get_label_by_id('100').set_text('Unknown')
            v.get_label_by_id('A').set_text('Set "A"')
            c = venn3_circles(subsets=(1, 1, 1, 1, 1, 1, 1), linestyle='dashed')
            c[0].set_lw(1.0)
            c[0].set_ls('dotted')
            plt.title("Sample Venn diagram")
            plt.annotate('Unknown set', xy=v.get_label_by_id('100').get_position() - np.array([0, 0.05]), xytext=(-70,-70), 
                        ha='center', textcoords='offset points', bbox=dict(boxstyle='round,pad=0.5', fc='gray', alpha=0.1),
                        arrowprops=dict(arrowstyle='->', connectionstyle='arc3,rad=0.5',color='gray'))
            plt.show()
        
        An example with multiple subplots (new in version 0.6)::
        
            figure, axes = plt.subplots(2, 2)
            venn2(subsets={'10': 1, '01': 1, '11': 1}, set_labels = ('A', 'B'), ax=axes[0][0])
            venn2_circles((1, 2, 3), ax=axes[0][1])
            venn3(subsets=(1, 1, 1, 1, 1, 1, 1), set_labels = ('A', 'B', 'C'), ax=axes[1][0])
            venn3_circles({'001': 10, '100': 20, '010': 21, '110': 13, '011': 14}, ax=axes[1][1])
        
        Perhaps the most common use case is generating a Venn diagram given three sets of objects::
        
            set1 = set(['A', 'B', 'C', 'D'])
            set2 = set(['B', 'C', 'D', 'E'])
            set3 = set(['C', 'D',' E', 'F', 'G'])
        
            venn3([set1, set2, set3], ('Set1', 'Set2', 'Set3'))
           
        See also
        --------
        
        * Blog post: http://fouryears.eu/2012/10/13/venn-diagrams-in-python/
        * Report issues and submit fixes at Github: https://github.com/konstantint/matplotlib-venn
        
Keywords: matplotlib plotting charts venn-diagrams
Platform: Platform Independent
Classifier: Development Status :: 4 - Beta
Classifier: Intended Audience :: Science/Research
Classifier: License :: OSI Approved :: MIT License
Classifier: Operating System :: OS Independent
Classifier: Programming Language :: Python :: 2
Classifier: Topic :: Scientific/Engineering :: Visualization
