Current File : //lib64/python2.7/compiler/symbols.py
"""Module symbol-table generator"""

from compiler import ast
from compiler.consts import SC_LOCAL, SC_GLOBAL_IMPLICIT, SC_GLOBAL_EXPLICIT, \
    SC_FREE, SC_CELL, SC_UNKNOWN
from compiler.misc import mangle
import types


import sys

MANGLE_LEN = 256

class Scope:
    # XXX how much information do I need about each name?
    def __init__(self, name, module, klass=None):
        self.name = name
        self.module = module
        self.defs = {}
        self.uses = {}
        self.globals = {}
        self.params = {}
        self.frees = {}
        self.cells = {}
        self.children = []
        # nested is true if the class could contain free variables,
        # i.e. if it is nested within another function.
        self.nested = None
        self.generator = None
        self.klass = None
        if klass is not None:
            for i in range(len(klass)):
                if klass[i] != '_':
                    self.klass = klass[i:]
                    break

    def __repr__(self):
        return "<%s: %s>" % (self.__class__.__name__, self.name)

    def mangle(self, name):
        if self.klass is None:
            return name
        return mangle(name, self.klass)

    def add_def(self, name):
        self.defs[self.mangle(name)] = 1

    def add_use(self, name):
        self.uses[self.mangle(name)] = 1

    def add_global(self, name):
        name = self.mangle(name)
        if name in self.uses or name in self.defs:
            pass # XXX warn about global following def/use
        if name in self.params:
            raise SyntaxError, "%s in %s is global and parameter" % \
                  (name, self.name)
        self.globals[name] = 1
        self.module.add_def(name)

    def add_param(self, name):
        name = self.mangle(name)
        self.defs[name] = 1
        self.params[name] = 1

    def get_names(self):
        d = {}
        d.update(self.defs)
        d.update(self.uses)
        d.update(self.globals)
        return d.keys()

    def add_child(self, child):
        self.children.append(child)

    def get_children(self):
        return self.children

    def DEBUG(self):
        print >> sys.stderr, self.name, self.nested and "nested" or ""
        print >> sys.stderr, "\tglobals: ", self.globals
        print >> sys.stderr, "\tcells: ", self.cells
        print >> sys.stderr, "\tdefs: ", self.defs
        print >> sys.stderr, "\tuses: ", self.uses
        print >> sys.stderr, "\tfrees:", self.frees

    def check_name(self, name):
        """Return scope of name.

        The scope of a name could be LOCAL, GLOBAL, FREE, or CELL.
        """
        if name in self.globals:
            return SC_GLOBAL_EXPLICIT
        if name in self.cells:
            return SC_CELL
        if name in self.defs:
            return SC_LOCAL
        if self.nested and (name in self.frees or name in self.uses):
            return SC_FREE
        if self.nested:
            return SC_UNKNOWN
        else:
            return SC_GLOBAL_IMPLICIT

    def get_free_vars(self):
        if not self.nested:
            return ()
        free = {}
        free.update(self.frees)
        for name in self.uses.keys():
            if name not in self.defs and name not in self.globals:
                free[name] = 1
        return free.keys()

    def handle_children(self):
        for child in self.children:
            frees = child.get_free_vars()
            globals = self.add_frees(frees)
            for name in globals:
                child.force_global(name)

    def force_global(self, name):
        """Force name to be global in scope.

        Some child of the current node had a free reference to name.
        When the child was processed, it was labelled a free
        variable.  Now that all its enclosing scope have been
        processed, the name is known to be a global or builtin.  So
        walk back down the child chain and set the name to be global
        rather than free.

        Be careful to stop if a child does not think the name is
        free.
        """
        self.globals[name] = 1
        if name in self.frees:
            del self.frees[name]
        for child in self.children:
            if child.check_name(name) == SC_FREE:
                child.force_global(name)

    def add_frees(self, names):
        """Process list of free vars from nested scope.

        Returns a list of names that are either 1) declared global in the
        parent or 2) undefined in a top-level parent.  In either case,
        the nested scope should treat them as globals.
        """
        child_globals = []
        for name in names:
            sc = self.check_name(name)
            if self.nested:
                if sc == SC_UNKNOWN or sc == SC_FREE \
                   or isinstance(self, ClassScope):
                    self.frees[name] = 1
                elif sc == SC_GLOBAL_IMPLICIT:
                    child_globals.append(name)
                elif isinstance(self, FunctionScope) and sc == SC_LOCAL:
                    self.cells[name] = 1
                elif sc != SC_CELL:
                    child_globals.append(name)
            else:
                if sc == SC_LOCAL:
                    self.cells[name] = 1
                elif sc != SC_CELL:
                    child_globals.append(name)
        return child_globals

    def get_cell_vars(self):
        return self.cells.keys()

class ModuleScope(Scope):
    __super_init = Scope.__init__

    def __init__(self):
        self.__super_init("global", self)

class FunctionScope(Scope):
    pass

class GenExprScope(Scope):
    __super_init = Scope.__init__

    __counter = 1

    def __init__(self, module, klass=None):
        i = self.__counter
        self.__counter += 1
        self.__super_init("generator expression<%d>"%i, module, klass)
        self.add_param('.0')

    def get_names(self):
        keys = Scope.get_names(self)
        return keys

class LambdaScope(FunctionScope):
    __super_init = Scope.__init__

    __counter = 1

    def __init__(self, module, klass=None):
        i = self.__counter
        self.__counter += 1
        self.__super_init("lambda.%d" % i, module, klass)

class ClassScope(Scope):
    __super_init = Scope.__init__

    def __init__(self, name, module):
        self.__super_init(name, module, name)

class SymbolVisitor:
    def __init__(self):
        self.scopes = {}
        self.klass = None

    # node that define new scopes

    def visitModule(self, node):
        scope = self.module = self.scopes[node] = ModuleScope()
        self.visit(node.node, scope)

    visitExpression = visitModule

    def visitFunction(self, node, parent):
        if node.decorators:
            self.visit(node.decorators, parent)
        parent.add_def(node.name)
        for n in node.defaults:
            self.visit(n, parent)
        scope = FunctionScope(node.name, self.module, self.klass)
        if parent.nested or isinstance(parent, FunctionScope):
            scope.nested = 1
        self.scopes[node] = scope
        self._do_args(scope, node.argnames)
        self.visit(node.code, scope)
        self.handle_free_vars(scope, parent)

    def visitGenExpr(self, node, parent):
        scope = GenExprScope(self.module, self.klass);
        if parent.nested or isinstance(parent, FunctionScope) \
                or isinstance(parent, GenExprScope):
            scope.nested = 1

        self.scopes[node] = scope
        self.visit(node.code, scope)

        self.handle_free_vars(scope, parent)

    def visitGenExprInner(self, node, scope):
        for genfor in node.quals:
            self.visit(genfor, scope)

        self.visit(node.expr, scope)

    def visitGenExprFor(self, node, scope):
        self.visit(node.assign, scope, 1)
        self.visit(node.iter, scope)
        for if_ in node.ifs:
            self.visit(if_, scope)

    def visitGenExprIf(self, node, scope):
        self.visit(node.test, scope)

    def visitLambda(self, node, parent, assign=0):
        # Lambda is an expression, so it could appear in an expression
        # context where assign is passed.  The transformer should catch
        # any code that has a lambda on the left-hand side.
        assert not assign

        for n in node.defaults:
            self.visit(n, parent)
        scope = LambdaScope(self.module, self.klass)
        if parent.nested or isinstance(parent, FunctionScope):
            scope.nested = 1
        self.scopes[node] = scope
        self._do_args(scope, node.argnames)
        self.visit(node.code, scope)
        self.handle_free_vars(scope, parent)

    def _do_args(self, scope, args):
        for name in args:
            if type(name) == types.TupleType:
                self._do_args(scope, name)
            else:
                scope.add_param(name)

    def handle_free_vars(self, scope, parent):
        parent.add_child(scope)
        scope.handle_children()

    def visitClass(self, node, parent):
        parent.add_def(node.name)
        for n in node.bases:
            self.visit(n, parent)
        scope = ClassScope(node.name, self.module)
        if parent.nested or isinstance(parent, FunctionScope):
            scope.nested = 1
        if node.doc is not None:
            scope.add_def('__doc__')
        scope.add_def('__module__')
        self.scopes[node] = scope
        prev = self.klass
        self.klass = node.name
        self.visit(node.code, scope)
        self.klass = prev
        self.handle_free_vars(scope, parent)

    # name can be a def or a use

    # XXX a few calls and nodes expect a third "assign" arg that is
    # true if the name is being used as an assignment.  only
    # expressions contained within statements may have the assign arg.

    def visitName(self, node, scope, assign=0):
        if assign:
            scope.add_def(node.name)
        else:
            scope.add_use(node.name)

    # operations that bind new names

    def visitFor(self, node, scope):
        self.visit(node.assign, scope, 1)
        self.visit(node.list, scope)
        self.visit(node.body, scope)
        if node.else_:
            self.visit(node.else_, scope)

    def visitFrom(self, node, scope):
        for name, asname in node.names:
            if name == "*":
                continue
            scope.add_def(asname or name)

    def visitImport(self, node, scope):
        for name, asname in node.names:
            i = name.find(".")
            if i > -1:
                name = name[:i]
            scope.add_def(asname or name)

    def visitGlobal(self, node, scope):
        for name in node.names:
            scope.add_global(name)

    def visitAssign(self, node, scope):
        """Propagate assignment flag down to child nodes.

        The Assign node doesn't itself contains the variables being
        assigned to.  Instead, the children in node.nodes are visited
        with the assign flag set to true.  When the names occur in
        those nodes, they are marked as defs.

        Some names that occur in an assignment target are not bound by
        the assignment, e.g. a name occurring inside a slice.  The
        visitor handles these nodes specially; they do not propagate
        the assign flag to their children.
        """
        for n in node.nodes:
            self.visit(n, scope, 1)
        self.visit(node.expr, scope)

    def visitAssName(self, node, scope, assign=1):
        scope.add_def(node.name)

    def visitAssAttr(self, node, scope, assign=0):
        self.visit(node.expr, scope, 0)

    def visitSubscript(self, node, scope, assign=0):
        self.visit(node.expr, scope, 0)
        for n in node.subs:
            self.visit(n, scope, 0)

    def visitSlice(self, node, scope, assign=0):
        self.visit(node.expr, scope, 0)
        if node.lower:
            self.visit(node.lower, scope, 0)
        if node.upper:
            self.visit(node.upper, scope, 0)

    def visitAugAssign(self, node, scope):
        # If the LHS is a name, then this counts as assignment.
        # Otherwise, it's just use.
        self.visit(node.node, scope)
        if isinstance(node.node, ast.Name):
            self.visit(node.node, scope, 1) # XXX worry about this
        self.visit(node.expr, scope)

    # prune if statements if tests are false

    _const_types = types.StringType, types.IntType, types.FloatType

    def visitIf(self, node, scope):
        for test, body in node.tests:
            if isinstance(test, ast.Const):
                if type(test.value) in self._const_types:
                    if not test.value:
                        continue
            self.visit(test, scope)
            self.visit(body, scope)
        if node.else_:
            self.visit(node.else_, scope)

    # a yield statement signals a generator

    def visitYield(self, node, scope):
        scope.generator = 1
        self.visit(node.value, scope)

def list_eq(l1, l2):
    return sorted(l1) == sorted(l2)

if __name__ == "__main__":
    import sys
    from compiler import parseFile, walk
    import symtable

    def get_names(syms):
        return [s for s in [s.get_name() for s in syms.get_symbols()]
                if not (s.startswith('_[') or s.startswith('.'))]

    for file in sys.argv[1:]:
        print file
        f = open(file)
        buf = f.read()
        f.close()
        syms = symtable.symtable(buf, file, "exec")
        mod_names = get_names(syms)
        tree = parseFile(file)
        s = SymbolVisitor()
        walk(tree, s)

        # compare module-level symbols
        names2 = s.scopes[tree].get_names()

        if not list_eq(mod_names, names2):
            print
            print "oops", file
            print sorted(mod_names)
            print sorted(names2)
            sys.exit(-1)

        d = {}
        d.update(s.scopes)
        del d[tree]
        scopes = d.values()
        del d

        for s in syms.get_symbols():
            if s.is_namespace():
                l = [sc for sc in scopes
                     if sc.name == s.get_name()]
                if len(l) > 1:
                    print "skipping", s.get_name()
                else:
                    if not list_eq(get_names(s.get_namespace()),
                                   l[0].get_names()):
                        print s.get_name()
                        print sorted(get_names(s.get_namespace()))
                        print sorted(l[0].get_names())
                        sys.exit(-1)
BDM Cricket India: tips, teams, tournaments
BDM Cricket India

Betting tips

Scrolling Block

News In Picture

Cricket

Recent Posts

Apostas Desportivas Site De Apostas Vave Online Bónus

June 27, 2025 0

“Sign In Mostbet Guia Content Entrar No Website Oficial Programa De Afiliados Da Mosbet No Brasil Stáhnout Soubor Apk Pro Android Benefícios Exclusivos Pra Brasileiros Bônus Elizabeth Promoções Mais Atraentes Usabilidade Da Plataforma Como Faço Para Hacer O Aplicativo Mostbet Em Meu Dispositivo Android? Programa Sobre Bônus Da Mostbet No …

Read More »

Beginner’s Facts Casino Betting: Tips & Strategies

June 27, 2025 0

How To Play Slots And Even Win Big Understand Online Slots Content Best Games & Strategies To Earn Money Casino Betting: The Entire Guide For Beginners Best Free Spins Casino Uk – Sky Vegas Multiple Paylines Practice With Free Games Understand The Way To Play Your Slot Find Alternatives To …

Read More »

Отнесение к разряду интерактивный казино в 2025 топ-десял намного лучших веб сайтов в видах игры нате действительные аржаны, благонадежные обзоры

June 27, 2025 3

А как промахнуться во западней а еще выбрать истинное аптерия для игры в онлайн игорный дом объективные деньги? Регистрация получите и распишитесь ненадежной площадке сопряжена с рисками. Эти операторы нередко обманывают инвесторов, заблокируют их учетные календарь, задерживают выплаты. Вдобавок они могут воздействовать нате норма занятия слотов, вероломствуя барыш отдачи в …

Read More »

Laissez-vous ensorceler par lunivers fascinant de Win Unique Wiz !

June 27, 2025 1

Laissez-vous ensorceler par lunivers fascinant de Win Unique Wiz ! Plongée dans l’univers des jeux en ligne Les machines à sous révélatrices Les jeux de table : tradition et stratégie Les bonus et promotions La sécurité des joueurs L’impact des technologies modernes La mobile gaming L’importance du soutien client Les …

Read More »

CASHlib Casinos in Deutschland – Was bieten sie?

CASHlib Casinos gewinnen in Deutschland immer mehr an Bedeutung. Diese Casinos ermöglichen es Spielern, anonym und sicher mit Prepaid-Guthaben zu bezahlen – ganz ohne Bankverbindung oder Kreditkarte. Besonders für Nutzer, die auf Datenschutz und schnelle Transaktionen Wert legen, sind sie eine interessante Alternative.

Was bieten CASHlib Casinos?

  • Schnelle und anonyme Einzahlungen ohne Registrierung bei Drittanbietern
  • Breites Spielangebot von Slots bis zu Live-Dealer-Spielen
  • Regelmäßige Aktionen wie Freispiele und Cashback
  • Attraktive Willkommensboni für neue Spieler
  • EU-lizenzierte Anbieter mit hohen Sicherheitsstandards

Ein großer Vorteil von CASHlib ist, dass keine sensiblen Bankdaten im Casino hinterlegt werden müssen. Die Gutscheine sind online oder in vielen Verkaufsstellen erhältlich und können sofort verwendet werden. Dadurch entfällt auch die Notwendigkeit, persönliche Daten bei Einzahlungen preiszugeben – ein echter Pluspunkt für sicherheitsbewusste Spieler.

Viele spielothekgermany.com/de/spielothek/cashlib-casinos/ bieten zudem mobile Kompatibilität, einfache Menüführung und professionellen Spielerschutz. Wer nach einem unkomplizierten Zahlungsweg mit solider Auswahl an Spielen und Bonusangeboten sucht, wird bei diesen Plattformen fündig. Die Kombination aus Bequemlichkeit, Sicherheit und einem attraktiven Bonusangebot macht CASHlib Casinos zu einer beliebten Wahl für deutsche Nutzer.

© Copyright 2025, All Rights Reserved
slot 7