def test_quantifier_syntax():
b = BDD()
[b.add_var(var) for var in ['x', 'y']]
# constants
u = b.add_expr('\E x: True')
assert u == b.true, u
u = b.add_expr('\E x, y: True')
assert u == b.true, u
u = b.add_expr('\E x: False')
assert u == b.false, u
u = b.add_expr('\A x: True')
assert u == b.true, u
u = b.add_expr('\A x: False')
assert u == b.false, u
u = b.add_expr('\A x, y: False')
assert u == b.false, u
# variables
u = b.add_expr('\E x: x')
assert u == b.true, u
u = b.add_expr('\A x: x')
assert u == b.false, u
u = b.add_expr('\E x, y: x')
assert u == b.true, u
u = b.add_expr('\E x, y: y')
assert u == b.true, u
u = b.add_expr('\A x: y')
assert u == b.var('y'), u
u = b.add_expr('\A x: ! y')
u_ = b.apply('not', b.var('y'))
assert u == u_, (u, u_)
def test_quantifier_syntax():
b = BDD()
[b.add_var(var) for var in ['x', 'y']]
# constants
u = b.add_expr('\E x: True')
assert u == b.true, u
u = b.add_expr('\E x, y: True')
assert u == b.true, u
u = b.add_expr('\E x: False')
assert u == b.false, u
u = b.add_expr('\A x: True')
assert u == b.true, u
u = b.add_expr('\A x: False')
assert u == b.false, u
u = b.add_expr('\A x, y: False')
assert u == b.false, u
# variables
u = b.add_expr('\E x: x')
assert u == b.true, u
u = b.add_expr('\A x: x')
assert u == b.false, u
u = b.add_expr('\E x, y: x')
assert u == b.true, u
u = b.add_expr('\E x, y: y')
assert u == b.true, u
u = b.add_expr('\A x: y')
assert u == b.var('y'), u
u = b.add_expr('\A x: ! y')
u_ = b.apply('not', b.var('y'))
assert u == u_, (u, u_)
def test_preimage():
# exists: x, y
# forall: z
ordering = {'x': 0, 'xp': 1,
'y': 2, 'yp': 3,
'z': 4, 'zp': 5}
rename = {0: 1, 2: 3, 4: 5}
g = BDD(ordering)
f = g.add_expr('!x')
t = g.add_expr('x <-> !xp')
qvars = {1, 3}
p = preimage(t, f, rename, qvars, g)
x = g.add_expr('x')
assert x == p, (x, p)
# a cycle
# (x & y) -> (!x & y) ->
# (!x & !y) -> (x & !y) -> wrap around
t = g.add_expr(
'((x & y) -> (!xp & yp)) && '
'((!x & y) -> (!xp & !yp)) && '
'((!x & !y) -> (xp & !yp)) && '
'((x & !y) -> (xp & yp))')
f = g.add_expr('x && y')
p = preimage(t, f, rename, qvars, g)
assert p == g.add_expr('x & !y')
f = g.add_expr('x && !y')
p = preimage(t, f, rename, qvars, g)
assert p == g.add_expr('!x & !y')
# backward reachable set
f = g.add_expr('x & y')
oldf = None
while oldf != f:
p = preimage(t, f, rename, qvars, g)
oldf = f
f = g.apply('or', p, oldf)
assert f == 1
# go around once
f = g.add_expr('x & y')
start = f
for i in range(4):
f = preimage(t, f, rename, qvars, g)
end = f
assert start == end
# forall z exists x, y
t = g.add_expr(
'('
' ((x & y) -> (zp & xp & !yp)) | '
' ((x & y) -> (!zp & !xp & yp))'
') & '
'(!(x & y) -> False)')
f = g.add_expr('x && !y')
ep = preimage(t, f, rename, qvars, g)
p = g.quantify(ep, {'zp'}, forall=True)
assert p == -1
f = g.add_expr('(x & !y) | (!x & y)')
ep = preimage(t, f, rename, qvars, g)
p = g.quantify(ep, {'zp'}, forall=True)
assert p == g.add_expr('x & y')
def test_preimage():
# exists: x, y
# forall: z
ordering = {'x': 0, 'xp': 1, 'y': 2, 'yp': 3, 'z': 4, 'zp': 5}
rename = {0: 1, 2: 3, 4: 5}
g = BDD(ordering)
f = g.add_expr('!x')
t = g.add_expr('x <-> !xp')
qvars = {1, 3}
p = preimage(t, f, rename, qvars, g)
x = g.add_expr('x')
assert x == p, (x, p)
# a cycle
# (x & y) -> (!x & y) ->
# (!x & !y) -> (x & !y) -> wrap around
t = g.add_expr('((x & y) -> (!xp & yp)) && '
'((!x & y) -> (!xp & !yp)) && '
'((!x & !y) -> (xp & !yp)) && '
'((x & !y) -> (xp & yp))')
f = g.add_expr('x && y')
p = preimage(t, f, rename, qvars, g)
assert p == g.add_expr('x & !y')
f = g.add_expr('x && !y')
p = preimage(t, f, rename, qvars, g)
assert p == g.add_expr('!x & !y')
# backward reachable set
f = g.add_expr('x & y')
oldf = None
while oldf != f:
p = preimage(t, f, rename, qvars, g)
oldf = f
f = g.apply('or', p, oldf)
assert f == 1
# go around once
f = g.add_expr('x & y')
start = f
for i in xrange(4):
f = preimage(t, f, rename, qvars, g)
end = f
assert start == end
# forall z exists x, y
t = g.add_expr('('
' ((x & y) -> (zp & xp & !yp)) | '
' ((x & y) -> (!zp & !xp & yp))'
') & '
'(!(x & y) -> False)')
f = g.add_expr('x && !y')
ep = preimage(t, f, rename, qvars, g)
p = g.quantify(ep, {'zp'}, forall=True)
assert p == -1
f = g.add_expr('(x & !y) | (!x & y)')
ep = preimage(t, f, rename, qvars, g)
p = g.quantify(ep, {'zp'}, forall=True)
assert p == g.add_expr('x & y')
