def f(_cache, e, seen): def f_cache(e): return _cache(f, e, seen) if z3.is_app_of(e, z3.Z3_OP_UMINUS): return f_cache((-1) * (e.arg(0))) elif z3.is_sub(e): return f_cache(e.arg(0) + (-1) * e.arg(1)) elif z3.is_app(e) and e.num_args() == 2: c1 = f_cache(e.arg(0)) c2 = f_cache(e.arg(1)) if z3.is_add(e): return c1 + c2 elif z3.is_mul(e): if z3.is_add(c1): c11 = c1.arg(0) c12 = c1.arg(1) return f_cache(c11 * c2 + c12 * c2) elif z3.is_add(c2): c21 = c2.arg(0) c22 = c2.arg(1) return f_cache(c1 * c21 + c1 * c22) else: return c1 * c2 else: return e else: return e
def f(_cache, e, seen): def f_cache(e): return _cache(f, e, seen) r = z3.is_mul(e) and \ all(cls._is_literal_expr(c) or f_cache(c) for c in e.children()) return r
def mk_app(self, f, args): if z3.is_eq(f): return args[0] == args[1] elif z3.is_and(f): return And(*args) elif z3.is_or(f): return Or(*args) elif z3.is_not(f): return Not(*args) elif z3.is_add(f): return reduce(operator.add, args[1:], args[0]) elif z3.is_mul(f): return reduce(operator.mul, args[1:], args[0]) elif z3.is_sub(f): return args[0] - args[1] elif z3.is_div(f): return args[0] / args[1] elif z3.is_lt(f): return args[0] < args[1] elif z3.is_le(f): return args[0] <= args[1] elif z3.is_gt(f): return args[0] > args[1] elif z3.is_ge(f): return args[0] >= args[1] elif z3.is_to_real(f): # TODO: ignore coercions? return args[0] elif z3.is_to_int(f): return args[0] elif f.name() == '=>': return implies(args[0], args[1]) else: dom_types = [self.mk_sort(f.domain(i))\ for i in range(0, f.arity())] cod_type = self.mk_sort(f.range()) dom_types.reverse() fun_type = reduce((lambda X, Y: type_arrow(Y, X)), \ dom_types, cod_type) func = self.mk_fun(f) return func(*args)
def _back_single_term(self, expr, args, model=None): assert z3.is_expr(expr) if z3.is_quantifier(expr): raise NotImplementedError( "Quantified back conversion is currently not supported") assert not len(args) > 2 or \ (z3.is_and(expr) or z3.is_or(expr) or z3.is_add(expr) or z3.is_mul(expr) or (len(args) == 3 and (z3.is_ite(expr) or z3.is_array_store(expr)))),\ "Unexpected n-ary term: %s" % expr res = None try: decl = z3.Z3_get_app_decl(expr.ctx_ref(), expr.as_ast()) kind = z3.Z3_get_decl_kind(expr.ctx.ref(), decl) # Try to get the back-conversion function for the given Kind fun = self._back_fun[kind] return fun(args, expr) except KeyError as ex: pass if z3.is_const(expr): # Const or Symbol if z3.is_rational_value(expr): n = expr.numerator_as_long() d = expr.denominator_as_long() f = Fraction(n, d) return self.mgr.Real(f) elif z3.is_int_value(expr): n = expr.as_long() return self.mgr.Int(n) elif z3.is_bv_value(expr): n = expr.as_long() w = expr.size() return self.mgr.BV(n, w) elif z3.is_as_array(expr): if model is None: raise NotImplementedError("As-array expressions cannot be" \ " handled as they are not " \ "self-contained") else: interp_decl = z3.get_as_array_func(expr) interp = model[interp_decl] default = self.back(interp.else_value(), model=model) assign = {} for i in xrange(interp.num_entries()): e = interp.entry(i) assert e.num_args() == 1 idx = self.back(e.arg_value(0), model=model) val = self.back(e.value(), model=model) assign[idx] = val arr_type = self._z3_to_type(expr.sort()) return self.mgr.Array(arr_type.index_type, default, assign) elif z3.is_algebraic_value(expr): # Algebraic value return self.mgr._Algebraic(Numeral(expr)) else: # it must be a symbol try: return self.mgr.get_symbol(str(expr)) except UndefinedSymbolError: import warnings symb_type = self._z3_to_type(expr.sort()) warnings.warn("Defining new symbol: %s" % str(expr)) return self.mgr.FreshSymbol(symb_type, template="__z3_%d") elif z3.is_function(expr): # This needs to be after we try to convert regular Symbols fsymbol = self.mgr.get_symbol(expr.decl().name()) return self.mgr.Function(fsymbol, args) # If we reach this point, we did not manage to translate the expression raise ConvertExpressionError(message=("Unsupported expression: %s" % (str(expr))), expression=expr)
def _back_single_term(self, expr, args): assert z3.is_expr(expr) if z3.is_quantifier(expr): raise NotImplementedError( "Quantified back conversion is currently not supported") res = None if z3.is_and(expr): res = self.mgr.And(args) elif z3.is_or(expr): res = self.mgr.Or(args) elif z3.is_add(expr): res = self.mgr.Plus(args) elif z3.is_div(expr): res = self.mgr.Div(args[0], args[1]) elif z3.is_eq(expr): if self._get_type(args[0]).is_bool_type(): res = self.mgr.Iff(args[0], args[1]) else: res = self.mgr.Equals(args[0], args[1]) elif z3.is_iff(expr): res = self.mgr.Iff(args[0], args[1]) elif z3.is_xor(expr): res = self.mgr.Xor(args[0], args[1]) elif z3.is_false(expr): res = self.mgr.FALSE() elif z3.is_true(expr): res = self.mgr.TRUE() elif z3.is_gt(expr): res = self.mgr.GT(args[0], args[1]) elif z3.is_ge(expr): res = self.mgr.GE(args[0], args[1]) elif z3.is_lt(expr): res = self.mgr.LT(args[0], args[1]) elif z3.is_le(expr): res = self.mgr.LE(args[0], args[1]) elif z3.is_mul(expr): res = self.mgr.Times(args[0], args[1]) elif z3.is_uminus(expr): tp = self._get_type(args[0]) if tp.is_real_type(): minus_one = self.mgr.Real(-1) else: assert tp.is_int_type() minus_one = self.mgr.Int(-1) res = self.mgr.Times(args[0], minus_one) elif z3.is_sub(expr): res = self.mgr.Minus(args[0], args[1]) elif z3.is_not(expr): res = self.mgr.Not(args[0]) elif z3.is_implies(expr): res = self.mgr.Implies(args[0], args[1]) elif z3.is_quantifier(expr): raise NotImplementedError elif z3.is_const(expr): if z3.is_rational_value(expr): n = expr.numerator_as_long() d = expr.denominator_as_long() f = Fraction(n, d) res = self.mgr.Real(f) elif z3.is_int_value(expr): n = expr.as_long() res = self.mgr.Int(n) elif z3.is_bv_value(expr): n = expr.as_long() w = expr.size() res = self.mgr.BV(n, w) else: # it must be a symbol res = self.mgr.get_symbol(str(expr)) elif z3.is_ite(expr): res = self.mgr.Ite(args[0], args[1], args[2]) elif z3.is_function(expr): res = self.mgr.Function(self.mgr.get_symbol(expr.decl().name()), args) elif z3.is_to_real(expr): res = self.mgr.ToReal(args[0]) elif z3.is_bv_and(expr): res = self.mgr.BVAnd(args[0], args[1]) elif z3.is_bv_or(expr): res = self.mgr.BVOr(args[0], args[1]) elif z3.is_bv_xor(expr): res = self.mgr.BVXor(args[0], args[1]) elif z3.is_bv_not(expr): res = self.mgr.BVNot(args[0]) elif z3.is_bv_neg(expr): res = self.mgr.BVNeg(args[0]) elif z3.is_bv_concat(expr): res = self.mgr.BVConcat(args[0], args[1]) elif z3.is_bv_ult(expr): res = self.mgr.BVULT(args[0], args[1]) elif z3.is_bv_uleq(expr): res = self.mgr.BVULE(args[0], args[1]) elif z3.is_bv_slt(expr): res = self.mgr.BVSLT(args[0], args[1]) elif z3.is_bv_sleq(expr): res = self.mgr.BVSLE(args[0], args[1]) elif z3.is_bv_ugt(expr): res = self.mgr.BVUGT(args[0], args[1]) elif z3.is_bv_ugeq(expr): res = self.mgr.BVUGE(args[0], args[1]) elif z3.is_bv_sgt(expr): res = self.mgr.BVSGT(args[0], args[1]) elif z3.is_bv_sgeq(expr): res = self.mgr.BVSGE(args[0], args[1]) elif z3.is_bv_extract(expr): end = z3.get_payload(expr, 0) start = z3.get_payload(expr, 1) res = self.mgr.BVExtract(args[0], start, end) elif z3.is_bv_add(expr): res = self.mgr.BVAdd(args[0], args[1]) elif z3.is_bv_mul(expr): res = self.mgr.BVMul(args[0], args[1]) elif z3.is_bv_udiv(expr): res = self.mgr.BVUDiv(args[0], args[1]) elif z3.is_bv_sdiv(expr): res = self.mgr.BVSDiv(args[0], args[1]) elif z3.is_bv_urem(expr): res = self.mgr.BVURem(args[0], args[1]) elif z3.is_bv_srem(expr): res = self.mgr.BVSRem(args[0], args[1]) elif z3.is_bv_lshl(expr): res = self.mgr.BVLShl(args[0], args[1]) elif z3.is_bv_lshr(expr): res = self.mgr.BVLShr(args[0], args[1]) elif z3.is_bv_ashr(expr): res = self.mgr.BVAShr(args[0], args[1]) elif z3.is_bv_sub(expr): res = self.mgr.BVSub(args[0], args[1]) elif z3.is_bv_rol(expr): amount = z3.get_payload(expr, 0) res = self.mgr.BVRol(args[0], amount) elif z3.is_bv_ror(expr): amount = z3.get_payload(expr, 0) res = self.mgr.BVRor(args[0], amount) elif z3.is_bv_ext_rol(expr): amount = args[1].bv_unsigned_value() res = self.mgr.BVRol(args[0], amount) elif z3.is_bv_ext_ror(expr): amount = args[1].bv_unsigned_value() res = self.mgr.BVRor(args[0], amount) elif z3.is_bv_sext(expr): amount = z3.get_payload(expr, 0) res = self.mgr.BVSExt(args[0], amount) elif z3.is_bv_zext(expr): amount = z3.get_payload(expr, 0) res = self.mgr.BVZExt(args[0], amount) if res is None: raise ConvertExpressionError(message=("Unsupported expression: %s" % str(expr)), expression=expr) return res
def back(self, expr): assert z3.is_expr(expr) if askey(expr) in self.backconversion: return self.backconversion[askey(expr)] if z3.is_quantifier(expr): raise NotImplementedError( "Quantified back conversion is currently not supported") args = [self.back(x) for x in expr.children()] res = None if z3.is_and(expr): res = self.mgr.And(args) elif z3.is_or(expr): res = self.mgr.Or(args) elif z3.is_add(expr): res = self.mgr.Plus(args) elif z3.is_div(expr): res = self.mgr.Div(args[0], args[1]) elif z3.is_eq(expr): if self._get_type(args[0]) == types.BOOL: res = self.mgr.Iff(args[0], args[1]) else: res = self.mgr.Equals(args[0], args[1]) elif z3.is_false(expr): res = self.mgr.FALSE() elif z3.is_true(expr): res = self.mgr.TRUE() elif z3.is_gt(expr): res = self.mgr.GT(args[0], args[1]) elif z3.is_ge(expr): res = self.mgr.GE(args[0], args[1]) elif z3.is_lt(expr): res = self.mgr.LT(args[0], args[1]) elif z3.is_le(expr): res = self.mgr.LE(args[0], args[1]) elif z3.is_mul(expr): res = self.mgr.Times(args[0], args[1]) elif z3.is_sub(expr): res = self.mgr.Minus(args[0], args[1]) elif z3.is_not(expr): res = self.mgr.Not(args[0]) elif z3.is_quantifier(expr): if expr.is_forall(): pass else: pass raise NotImplementedError elif z3.is_const(expr): if z3.is_rational_value(expr): n = expr.numerator_as_long() d = expr.denominator_as_long() f = Fraction(n, d) res = self.mgr.Real(f) elif z3.is_int_value(expr): n = expr.as_long() res = self.mgr.Int(n) else: # it must be a symbol res = self.mgr.get_symbol(str(expr)) elif z3.is_ite(expr): res = self.mgr.Ite(args[0], args[1], args[2]) else: raise TypeError("Unsupported expression:", expr) if res is None: raise TypeError("Unsupported expression:", expr) self.backconversion[askey(expr)] = res return res
def _back_single_term(self, expr, args, model=None): assert z3.is_expr(expr) if z3.is_quantifier(expr): raise NotImplementedError( "Quantified back conversion is currently not supported") res = None if z3.is_and(expr): res = self.mgr.And(args) elif z3.is_or(expr): res = self.mgr.Or(args) elif z3.is_add(expr): res = self.mgr.Plus(args) elif z3.is_div(expr): res = self.mgr.Div(args[0], args[1]) elif z3.is_eq(expr): if self._get_type(args[0]).is_bool_type(): res = self.mgr.Iff(args[0], args[1]) else: res = self.mgr.Equals(args[0], args[1]) elif z3.is_iff(expr): res = self.mgr.Iff(args[0], args[1]) elif z3.is_xor(expr): res = self.mgr.Xor(args[0], args[1]) elif z3.is_false(expr): res = self.mgr.FALSE() elif z3.is_true(expr): res = self.mgr.TRUE() elif z3.is_gt(expr): res = self.mgr.GT(args[0], args[1]) elif z3.is_ge(expr): res = self.mgr.GE(args[0], args[1]) elif z3.is_lt(expr): res = self.mgr.LT(args[0], args[1]) elif z3.is_le(expr): res = self.mgr.LE(args[0], args[1]) elif z3.is_mul(expr): res = self.mgr.Times(args[0], args[1]) elif z3.is_uminus(expr): tp = self._get_type(args[0]) if tp.is_real_type(): minus_one = self.mgr.Real(-1) else: assert tp.is_int_type() minus_one = self.mgr.Int(-1) res = self.mgr.Times(args[0], minus_one) elif z3.is_sub(expr): res = self.mgr.Minus(args[0], args[1]) elif z3.is_not(expr): res = self.mgr.Not(args[0]) elif z3.is_implies(expr): res = self.mgr.Implies(args[0], args[1]) elif z3.is_quantifier(expr): raise NotImplementedError elif z3.is_const(expr): if z3.is_rational_value(expr): n = expr.numerator_as_long() d = expr.denominator_as_long() f = Fraction(n, d) res = self.mgr.Real(f) elif z3.is_int_value(expr): n = expr.as_long() res = self.mgr.Int(n) elif z3.is_bv_value(expr): n = expr.as_long() w = expr.size() res = self.mgr.BV(n, w) elif z3.is_as_array(expr): if model is None: raise NotImplementedError("As-array expressions cannot be" \ " handled as they are not " \ "self-contained") else: interp_decl = z3.get_as_array_func(expr) interp = model[interp_decl] default = self.back(interp.else_value(), model=model) assign = {} for i in xrange(interp.num_entries()): e = interp.entry(i) assert e.num_args() == 1 idx = self.back(e.arg_value(0), model=model) val = self.back(e.value(), model=model) assign[idx] = val arr_type = self._z3_to_type(expr.sort()) res = self.mgr.Array(arr_type.index_type, default, assign) elif z3.is_algebraic_value(expr): # Algebraic value return self.mgr._Algebraic(Numeral(expr)) else: # it must be a symbol res = self.mgr.get_symbol(str(expr)) elif z3.is_ite(expr): res = self.mgr.Ite(args[0], args[1], args[2]) elif z3.is_function(expr): res = self.mgr.Function(self.mgr.get_symbol(expr.decl().name()), args) elif z3.is_to_real(expr): res = self.mgr.ToReal(args[0]) elif z3.is_bv_and(expr): res = self.mgr.BVAnd(args[0], args[1]) elif z3.is_bv_or(expr): res = self.mgr.BVOr(args[0], args[1]) elif z3.is_bv_xor(expr): res = self.mgr.BVXor(args[0], args[1]) elif z3.is_bv_not(expr): res = self.mgr.BVNot(args[0]) elif z3.is_bv_neg(expr): res = self.mgr.BVNeg(args[0]) elif z3.is_bv_concat(expr): res = self.mgr.BVConcat(args[0], args[1]) elif z3.is_bv_ult(expr): res = self.mgr.BVULT(args[0], args[1]) elif z3.is_bv_uleq(expr): res = self.mgr.BVULE(args[0], args[1]) elif z3.is_bv_slt(expr): res = self.mgr.BVSLT(args[0], args[1]) elif z3.is_bv_sleq(expr): res = self.mgr.BVSLE(args[0], args[1]) elif z3.is_bv_ugt(expr): res = self.mgr.BVUGT(args[0], args[1]) elif z3.is_bv_ugeq(expr): res = self.mgr.BVUGE(args[0], args[1]) elif z3.is_bv_sgt(expr): res = self.mgr.BVSGT(args[0], args[1]) elif z3.is_bv_sgeq(expr): res = self.mgr.BVSGE(args[0], args[1]) elif z3.is_bv_extract(expr): end = z3.get_payload(expr, 0) start = z3.get_payload(expr, 1) res = self.mgr.BVExtract(args[0], start, end) elif z3.is_bv_add(expr): res = self.mgr.BVAdd(args[0], args[1]) elif z3.is_bv_mul(expr): res = self.mgr.BVMul(args[0], args[1]) elif z3.is_bv_udiv(expr): res = self.mgr.BVUDiv(args[0], args[1]) elif z3.is_bv_sdiv(expr): res = self.mgr.BVSDiv(args[0], args[1]) elif z3.is_bv_urem(expr): res = self.mgr.BVURem(args[0], args[1]) elif z3.is_bv_srem(expr): res = self.mgr.BVSRem(args[0], args[1]) elif z3.is_bv_lshl(expr): res = self.mgr.BVLShl(args[0], args[1]) elif z3.is_bv_lshr(expr): res = self.mgr.BVLShr(args[0], args[1]) elif z3.is_bv_ashr(expr): res = self.mgr.BVAShr(args[0], args[1]) elif z3.is_bv_sub(expr): res = self.mgr.BVSub(args[0], args[1]) elif z3.is_bv_rol(expr): amount = z3.get_payload(expr, 0) res = self.mgr.BVRol(args[0], amount) elif z3.is_bv_ror(expr): amount = z3.get_payload(expr, 0) res = self.mgr.BVRor(args[0], amount) elif z3.is_bv_ext_rol(expr): amount = args[1].bv_unsigned_value() res = self.mgr.BVRol(args[0], amount) elif z3.is_bv_ext_ror(expr): amount = args[1].bv_unsigned_value() res = self.mgr.BVRor(args[0], amount) elif z3.is_bv_sext(expr): amount = z3.get_payload(expr, 0) res = self.mgr.BVSExt(args[0], amount) elif z3.is_bv_zext(expr): amount = z3.get_payload(expr, 0) res = self.mgr.BVZExt(args[0], amount) elif z3.is_array_select(expr): res = self.mgr.Select(args[0], args[1]) elif z3.is_array_store(expr): res = self.mgr.Store(args[0], args[1], args[2]) elif z3.is_const_array(expr): arr_ty = self._z3_to_type(expr.sort()) k = args[0] res = self.mgr.Array(arr_ty.index_type, k) elif z3.is_power(expr): res = self.mgr.Pow(args[0], args[1]) if res is None: raise ConvertExpressionError(message=("Unsupported expression: %s" % str(expr)), expression=expr) return res