+
import functools
import numbers
from . import islhelper
from .islhelper import mainctx, libisl
-from .linexprs import Expression, Constant
+from .linexprs import Expression, Symbol, Rational
from .domains import Domain
elif isinstance(equalities, Domain):
if inequalities is not None:
raise TypeError('too many arguments')
- return equalities.polyhedral_hull()
+ return equalities.aspolyhedron()
if equalities is None:
equalities = []
else:
for i, equality in enumerate(equalities):
if not isinstance(equality, Expression):
raise TypeError('equalities must be linear expressions')
- equalities[i] = equality._toint()
+ equalities[i] = equality.scaleint()
if inequalities is None:
inequalities = []
else:
for i, inequality in enumerate(inequalities):
if not isinstance(inequality, Expression):
raise TypeError('inequalities must be linear expressions')
- inequalities[i] = inequality._toint()
+ inequalities[i] = inequality.scaleint()
symbols = cls._xsymbols(equalities + inequalities)
islbset = cls._toislbasicset(equalities, inequalities, symbols)
return cls._fromislbasicset(islbset, symbols)
libisl.isl_basic_set_free(islbset)
return universe
- def polyhedral_hull(self):
+ def aspolyhedron(self):
return self
+ def subs(self, symbol, expression=None):
+ equalities = [equality.subs(symbol, expression)
+ for equality in self.equalities]
+ inequalities = [inequality.subs(symbol, expression)
+ for inequality in self.inequalities]
+ return Polyhedron(equalities, inequalities)
+
@classmethod
def _fromislbasicset(cls, islbset, symbols):
islconstraints = islhelper.isl_basic_set_constraints(islbset)
constant = islhelper.isl_val_to_int(constant)
coefficients = {}
for index, symbol in enumerate(symbols):
- coefficient = libisl.isl_constraint_get_coefficient_val(islconstraint, libisl.isl_dim_set, index)
+ coefficient = libisl.isl_constraint_get_coefficient_val(islconstraint,
+ libisl.isl_dim_set, index)
coefficient = islhelper.isl_val_to_int(coefficient)
if coefficient != 0:
coefficients[symbol] = coefficient
else:
strings = []
for equality in self.equalities:
- strings.append('Eq({}, 0)'.format(equality))
+ strings.append('0 == {}'.format(equality))
for inequality in self.inequalities:
- strings.append('Ge({}, 0)'.format(inequality))
+ strings.append('0 <= {}'.format(inequality))
if len(strings) == 1:
return strings[0]
else:
return 'And({})'.format(', '.join(strings))
- @classmethod
- def _fromsympy(cls, expr):
- import sympy
- equalities = []
- inequalities = []
- if expr.func == sympy.And:
- for arg in expr.args:
- arg_eqs, arg_ins = cls._fromsympy(arg)
- equalities.extend(arg_eqs)
- inequalities.extend(arg_ins)
- elif expr.func == sympy.Eq:
- expr = Expression.fromsympy(expr.args[0] - expr.args[1])
- equalities.append(expr)
- else:
- if expr.func == sympy.Lt:
- expr = Expression.fromsympy(expr.args[1] - expr.args[0] - 1)
- elif expr.func == sympy.Le:
- expr = Expression.fromsympy(expr.args[1] - expr.args[0])
- elif expr.func == sympy.Ge:
- expr = Expression.fromsympy(expr.args[0] - expr.args[1])
- elif expr.func == sympy.Gt:
- expr = Expression.fromsympy(expr.args[0] - expr.args[1] - 1)
- else:
- raise ValueError('non-polyhedral expression: {!r}'.format(expr))
- inequalities.append(expr)
- return equalities, inequalities
-
@classmethod
def fromsympy(cls, expr):
- import sympy
- equalities, inequalities = cls._fromsympy(expr)
- return cls(equalities, inequalities)
+ domain = Domain.fromsympy(expr)
+ if not isinstance(domain, Polyhedron):
+ raise ValueError('non-polyhedral expression: {!r}'.format(expr))
+ return domain
def tosympy(self):
import sympy
for inequality in self.inequalities:
constraints.append(sympy.Ge(inequality.tosympy(), 0))
return sympy.And(*constraints)
+
+ def plot(self):
+ import matplotlib.pyplot as plt
+ from matplotlib.path import Path
+ import matplotlib.patches as patches
+
+ if len(self.symbols)> 3:
+ raise TypeError
+
+ elif len(self.symbols) == 2:
+ verts = self.vertices()
+ points = []
+ codes = [Path.MOVETO]
+ for vert in verts:
+ pairs = ()
+ for sym in sorted(vert, key=Symbol.sortkey):
+ num = vert.get(sym)
+ pairs = pairs + (num,)
+ points.append(pairs)
+ points.append((0.0, 0.0))
+ num = len(points)
+ while num > 2:
+ codes.append(Path.LINETO)
+ num = num - 1
+ else:
+ codes.append(Path.CLOSEPOLY)
+ path = Path(points, codes)
+ fig = plt.figure()
+ ax = fig.add_subplot(111)
+ patch = patches.PathPatch(path, facecolor='blue', lw=2)
+ ax.add_patch(patch)
+ ax.set_xlim(-5,5)
+ ax.set_ylim(-5,5)
+ plt.show()
+
+ elif len(self.symbols)==3:
+ return 0
+
+ return points
def _polymorphic(func):
@functools.wraps(func)
def wrapper(left, right):
if isinstance(left, numbers.Rational):
- left = Constant(left)
+ left = Rational(left)
elif not isinstance(left, Expression):
raise TypeError('left must be a a rational number '
'or a linear expression')
if isinstance(right, numbers.Rational):
- right = Constant(right)
+ right = Rational(right)
elif not isinstance(right, Expression):
raise TypeError('right must be a a rational number '
'or a linear expression')