X-Git-Url: https://svn.cri.ensmp.fr/git/linpy.git/blobdiff_plain/0da8076d0fb7aab6c4cb61b55db4fcf3a916f588..9cb18415eee0e4eb2a5126da5ba7bd916aa85dd1:/examples/squares.py?ds=inline diff --git a/examples/squares.py b/examples/squares.py index 898f765..98e2ca8 100755 --- a/examples/squares.py +++ b/examples/squares.py @@ -1,54 +1,87 @@ #!/usr/bin/env python3 -from pypol import * +from linpy import * +import matplotlib.pyplot as plt +from matplotlib import pylab -x, y = symbols('x y') +a, x, y, z = symbols('a x y z') sq1 = Le(0, x) & Le(x, 2) & Le(0, y) & Le(y, 2) -sq2 = Le(1, x) & Le(x, 3) & Le(1, y) & Le(y, 3) - +sq2 = Le(2, x) & Le(x, 4) & Le(2, y) & Le(y, 4) sq3 = Le(0, x) & Le(x, 3) & Le(0, y) & Le(y, 3) sq4 = Le(1, x) & Le(x, 2) & Le(1, y) & Le(y, 2) -sq5 = Le(1, x) & Le(x, 2) & Le(1, y) -u = Polyhedron([]) +sq5 = Le(1, x) & Le(x, 2) & Le(1, y) +sq6 = Le(1, x) & Le(x, 2) & Le(1, y) & Le(y, 3) +sq7 = Le(0, x) & Le(x, 2) & Le(0, y) & Eq(z, 2) & Le(a, 3) +p = Le(2*x+1, y) & Le(-2*x-1, y) & Le(y, 1) + +universe = Polyhedron([]) +q = sq1 - sq2 +e = Empty print('sq1 =', sq1) #print correct square print('sq2 =', sq2) #print correct square print('sq3 =', sq3) #print correct square print('sq4 =', sq4) #print correct square -print('u =', u) #print correct square +print('universe =', universe) #print correct square print() -print('¬sq1 =', ~sq1) #test compliment +print('¬sq1 =', ~sq1) #test complement print() print('sq1 + sq1 =', sq1 + sq2) #test addition -print('sq1 + sq2 =', Polyhedron(sq1 + sq2)) -print('sq1 - sq1 =', u - u) +print('sq1 + sq2 =', Polyhedron(sq1 + sq2)) #test addition +print() +print('universe + universe =', universe + universe)#test addition +print('universe - universe =', universe - universe) #test subtraction +print() print('sq2 - sq1 =', sq2 - sq1) #test subtraction -print('sq2 - sq1 =', Polyhedron(sq2 - sq1)) -print('sq1 - sq1 =', Polyhedron(sq1 - sq1)) #test polyhedreon +print('sq2 - sq1 =', Polyhedron(sq2 - sq1)) #test subtraction +print('sq1 - sq1 =', Polyhedron(sq1 - sq1)) #test subtraction print() print('sq1 ∩ sq2 =', sq1 & sq2) #test intersection print('sq1 ∪ sq2 =', sq1 | sq2) #test union print() -print('sq1 ⊔ sq2 =', Polyhedron(sq1 | sq2)) #test convex union +print('sq1 ⊔ sq2 =', Polyhedron(sq1 | sq2)) # test convex union print() print('check if sq1 and sq2 disjoint:', sq1.isdisjoint(sq2)) #should return false print() -print('sq1 disjoint:', sq1.disjoint()) #make disjoint +print('sq1 disjoint:', sq1.disjoint()) #make disjoint print('sq2 disjoint:', sq2.disjoint()) #make disjoint print() print('is square 1 universe?:', sq1.isuniverse()) #test if square is universe -print('is u universe?:', u.isuniverse()) #test if square is universe +print('is u universe?:', universe.isuniverse()) #test if square is universe print() print('is sq1 a subset of sq2?:', sq1.issubset(sq2)) #test issubset() print('is sq4 less than sq3?:', sq4.__lt__(sq3)) # test lt(), must be a strict subset print() print('lexographic min of sq1:', sq1.lexmin()) #test lexmin() print('lexographic max of sq1:', sq1.lexmax()) #test lexmin() +print() print('lexographic min of sq2:', sq2.lexmin()) #test lexmax() print('lexographic max of sq2:', sq2.lexmax()) #test lexmax() print() -print('Polyhedral hull of sq1 is:', sq1.polyhedral_hull()) +print('Polyhedral hull of sq1 + sq2 is:', q.aspolyhedron()) #test polyhedral hull +print() +print('is sq1 bounded?', sq1.isbounded()) #bounded should return True +print('is sq5 bounded?', sq5.isbounded()) #unbounded should return False +print() +print('sq6:', sq6) +print('sample Polyhedron from sq6:', sq6.sample()) print() -print('is sq1 bounded?', sq1.isbounded()) -print('is sq5 bounded?', sq5.isbounded()) +print('sq7 with out constraints involving y and a', sq7.project([a, z, x, y])) +print() +print('the verticies for s are:', p.vertices()) + + +# plotting the intersection of two squares +square1 = Le(0, x) & Le(x, 2) & Le(0, y) & Le(y, 2) +square2 = Le(1, x) & Le(x, 3) & Le(1, y) & Le(y, 3) + +fig = plt.figure() +plot = fig.add_subplot(1, 1, 1, aspect='equal') +square1.plot(plot, facecolor='red', alpha=0.3) +square2.plot(plot, facecolor='blue', alpha=0.3) + +squares = Polyhedron(square1 + square2) +squares.plot(plot, facecolor='blue', alpha=0.3) + +pylab.show()