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Compréhension approfondie du module de collection Python et de la copie profonde et superficielle

高洛峰
Libérer: 2017-03-15 13:27:23
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Le module de collection

c est une extension des conteneurs généraux intégrés de Python : dictionnaires, listes, tuples et ensembles. Il contient des types de données de conteneurs professionnels. :

Counter (counter) : sous-classe dict, utilisée pour compter le nombre d'objets hachables .

OrderedDict (dictionnaire ordonné) : sous-classe dict, enregistrant l'ordre dans lequel les données membres sont ajoutées.

defaultdict (dictionnaire par défaut) : sous-classe dict, appelant une fonction d'usine pour fournir une valeur par défaut pour les valeurs manquantes de dict.

namedtuple (named tuple) : La fonction d'usine génère une sous-classe de tuple avec des champs nommés.

deque (file d'attente bidirectionnelle ) : une fonction qui peut rapidement sortir de la file d'attente et rejoindre la file d'attente aux deux extrémités de la "file d'attente", similaire à la file d'attente (list-like) conteneur.

ChainMap : type de type dictionnaire qui crée une seule View pour plusieurs cartes.

UserDict : envelopper un dictionnaire facilite la sous-classe d'un dictionnaire.

UserList : envelopper un objet de liste facilite la création de sous-classes de la liste.

UserString : envelopper un objet String facilite la création de sous-classes de chaîne.

1. Counter (counter)

Counter est une sous-classe de dict, utilisée pour compter les objets hachables. Il s'agit d'un conteneur non ordonné avec des éléments stockés sous forme de clés de dictionnaire et des valeurs de comptage en tant que valeurs de dictionnaire. Count autorise n’importe quelle valeur entière, y compris les comptes nuls ou négatifs. La classe Counter est similaire aux cours de langue tels que les sacs ou les multiset.

Ses éléments sont comptés à partir d'un itérable, ou initialisés à partir d'une autre carte (ou compteur).

class Counter(dict):
    '''Dict subclass for counting hashable items.  Sometimes called a bag
    or multiset.  Elements are stored as dictionary keys and their counts
    are stored as dictionary values.

    >>> c = Counter('abcdeabcdabcaba')  # count elements from a string

    >>> c.most_common(3)                # three most common elements
    [('a', 5), ('b', 4), ('c', 3)]
    >>> sorted(c)                       # list all unique elements
    ['a', 'b', 'c', 'd', 'e']
    >>> ''.join(sorted(c.elements()))   # list elements with repetitions
    'aaaaabbbbcccdde'
    >>> sum(c.values())                 # total of all counts
    15

    >>> c['a']                          # count of letter 'a'
    5
    >>> for elem in 'shazam':           # update counts from an iterable
    ...     c[elem] += 1                # by adding 1 to each element's count
    >>> c['a']                          # now there are seven 'a'
    7
    >>> del c['b']                      # remove all 'b'
    >>> c['b']                          # now there are zero 'b'
    0

    >>> d = Counter('simsalabim')       # make another counter
    >>> c.update(d)                     # add in the second counter
    >>> c['a']                          # now there are nine 'a'
    9

    >>> c.clear()                       # empty the counter
    >>> c
    Counter()

    Note:  If a count is set to zero or reduced to zero, it will remain
    in the counter until the entry is deleted or the counter is cleared:

    >>> c = Counter('aaabbc')
    >>> c['b'] -= 2                     # reduce the count of 'b' by two
    >>> c.most_common()                 # 'b' is still in, but its count is zero
    [('a', 3), ('c', 1), ('b', 0)]

    '''
    # References:
    #   http://en.wikipedia.org/wiki/Multiset
    #   http://www.gnu.org/software/smalltalk/manual-base/html_node/Bag.html
    #   http://www.demo2s.com/Tutorial/Cpp/0380set-multiset/Catalog0380set-multiset.htm
    #   http://code.activestate.com/recipes/259174/
    #   Knuth, TAOCP Vol. II section 4.6.3

    def init(*args, **kwds):
        '''Create a new, empty Counter object.  And if given, count elements
        from an input iterable.  Or, initialize the count from another mapping
        of elements to their counts.

        >>> c = Counter()                           # a new, empty counter
        >>> c = Counter('gallahad')                 # a new counter from an iterable
        >>> c = Counter({'a': 4, 'b': 2})           # a new counter from a mapping
        >>> c = Counter(a=4, b=2)                   # a new counter from keyword args

        '''
        if not args:
            raise TypeError("descriptor 'init' of 'Counter' object "
                            "needs an argument")
        self, *args = args
        if len(args) > 1:
            raise TypeError('expected at most 1 arguments, got %d' % len(args))
        super(Counter, self).init()
        self.update(*args, **kwds)

    def missing(self, key):
        'The count of elements not in the Counter is zero.'
        # Needed so that self[missing_item] does not raise KeyError
        return 0

    def most_common(self, n=None):
        '''List the n most common elements and their counts from the most
        common to the least.  If n is None, then list all element counts.

        >>> Counter('abcdeabcdabcaba').most_common(3)
        [('a', 5), ('b', 4), ('c', 3)]

        '''
        # Emulate Bag.sortedByCount from Smalltalk
        if n is None:
            return sorted(self.items(), key=_itemgetter(1), reverse=True)
        return _heapq.nlargest(n, self.items(), key=_itemgetter(1))

    def elements(self):
        '''Iterator over elements repeating each as many times as its count.

        >>> c = Counter('ABCABC')
        >>> sorted(c.elements())
        ['A', 'A', 'B', 'B', 'C', 'C']

        # Knuth's example for prime factors of 1836:  2**2 * 3**3 * 17**1
        >>> prime_factors = Counter({2: 2, 3: 3, 17: 1})
        >>> product = 1
        >>> for factor in prime_factors.elements():     # loop over factors
        ...     product *= factor                       # and multiply them
        >>> product
        1836

        Note, if an element's count has been set to zero or is a negative
        number, elements() will ignore it.

        '''
        # Emulate Bag.do from Smalltalk and Multiset.begin from C++.
        return _chain.from_iterable(_starmap(_repeat, self.items()))

    # Override dict methods where necessary

    @classmethod
    def fromkeys(cls, iterable, v=None):
        # There is no equivalent method for counters because setting v=1
        # means that no element can have a count greater than one.
        raise NotImplementedError(
            'Counter.fromkeys() is undefined.  Use Counter(iterable) instead.')

    def update(*args, **kwds):
        '''Like dict.update() but add counts instead of replacing them.

        Source can be an iterable, a dictionary, or another Counter instance.

        >>> c = Counter('which')
        >>> c.update('witch')           # add elements from another iterable
        >>> d = Counter('watch')
        >>> c.update(d)                 # add elements from another counter
        >>> c['h']                      # four 'h' in which, witch, and watch
        4

        '''
        # The regular dict.update() operation makes no sense here because the
        # replace behavior results in the some of original untouched counts
        # being mixed-in with all of the other counts for a mismash that
        # doesn't have a straight-forward interpretation in most counting
        # contexts.  Instead, we implement straight-addition.  Both the inputs
        # and outputs are allowed to contain zero and negative counts.

        if not args:
            raise TypeError("descriptor 'update' of 'Counter' object "
                            "needs an argument")
        self, *args = args
        if len(args) > 1:
            raise TypeError('expected at most 1 arguments, got %d' % len(args))
        iterable = args[0] if args else None
        if iterable is not None:
            if isinstance(iterable, Mapping):
                if self:
                    self_get = self.get
                    for elem, count in iterable.items():
                        self[elem] = count + self_get(elem, 0)
                else:
                    super(Counter, self).update(iterable) # fast path when counter is empty
            else:
                _count_elements(self, iterable)
        if kwds:
            self.update(kwds)

    def subtract(*args, **kwds):
        '''Like dict.update() but subtracts counts instead of replacing them.
        Counts can be reduced below zero.  Both the inputs and outputs are
        allowed to contain zero and negative counts.

        Source can be an iterable, a dictionary, or another Counter instance.

        >>> c = Counter('which')
        >>> c.subtract('witch')             # subtract elements from another iterable
        >>> c.subtract(Counter('watch'))    # subtract elements from another counter
        >>> c['h']                          # 2 in which, minus 1 in witch, minus 1 in watch
        0
        >>> c['w']                          # 1 in which, minus 1 in witch, minus 1 in watch
        -1

        '''
        if not args:
            raise TypeError("descriptor 'subtract' of 'Counter' object "
                            "needs an argument")
        self, *args = args
        if len(args) > 1:
            raise TypeError('expected at most 1 arguments, got %d' % len(args))
        iterable = args[0] if args else None
        if iterable is not None:
            self_get = self.get
            if isinstance(iterable, Mapping):
                for elem, count in iterable.items():
                    self[elem] = self_get(elem, 0) - count
            else:
                for elem in iterable:
                    self[elem] = self_get(elem, 0) - 1
        if kwds:
            self.subtract(kwds)

    def copy(self):
        'Return a shallow copy.'
        return self.class(self)

    def reduce(self):
        return self.class, (dict(self),)

    def delitem(self, elem):
        'Like dict.delitem() but does not raise KeyError for missing values.'
        if elem in self:
            super().delitem(elem)

    def repr(self):
        if not self:
            return '%s()' % self.class.name
        try:
            items = ', '.join(map('%r: %r'.mod, self.most_common()))
            return '%s({%s})' % (self.class.name, items)
        except TypeError:
            # handle case where values are not orderable
            return '{0}({1!r})'.format(self.class.name, dict(self))

    # Multiset-style mathematical operations discussed in:
    #       Knuth TAOCP Volume II section 4.6.3 exercise 19
    #       and at http://en.wikipedia.org/wiki/Multiset
    #
    # Outputs guaranteed to only include positive counts.
    #
    # To strip negative and zero counts, add-in an empty counter:
    #       c += Counter()

    def add(self, other):
        '''Add counts from two counters.

        >>> Counter('abbb') + Counter('bcc')
        Counter({'b': 4, 'c': 2, 'a': 1})

        '''
        if not isinstance(other, Counter):
            return NotImplemented
        result = Counter()
        for elem, count in self.items():
            newcount = count + other[elem]
            if newcount > 0:
                result[elem] = newcount
        for elem, count in other.items():
            if elem not in self and count > 0:
                result[elem] = count
        return result

    def sub(self, other):
        ''' Subtract count, but keep only results with positive counts.

        >>> Counter('abbbc') - Counter('bccd')
        Counter({'b': 2, 'a': 1})

        '''
        if not isinstance(other, Counter):
            return NotImplemented
        result = Counter()
        for elem, count in self.items():
            newcount = count - other[elem]
            if newcount > 0:
                result[elem] = newcount
        for elem, count in other.items():
            if elem not in self and count < 0:
                result[elem] = 0 - count
        return result

    def or(self, other):
        &#39;&#39;&#39;Union is the maximum of value in either of the input counters.

        >>> Counter(&#39;abbb&#39;) | Counter(&#39;bcc&#39;)
        Counter({&#39;b&#39;: 3, &#39;c&#39;: 2, &#39;a&#39;: 1})

        &#39;&#39;&#39;
        if not isinstance(other, Counter):
            return NotImplemented
        result = Counter()
        for elem, count in self.items():
            other_count = other[elem]
            newcount = other_count if count < other_count else count
            if newcount > 0:
                result[elem] = newcount
        for elem, count in other.items():
            if elem not in self and count > 0:
                result[elem] = count
        return result

    def and(self, other):
        &#39;&#39;&#39; Intersection is the minimum of corresponding counts.

        >>> Counter(&#39;abbb&#39;) & Counter(&#39;bcc&#39;)
        Counter({&#39;b&#39;: 1})

        &#39;&#39;&#39;
        if not isinstance(other, Counter):
            return NotImplemented
        result = Counter()
        for elem, count in self.items():
            other_count = other[elem]
            newcount = count if count < other_count else other_count
            if newcount > 0:
                result[elem] = newcount
        return result

    def pos(self):
        &#39;Adds an empty counter, effectively stripping negative and zero counts&#39;
        result = Counter()
        for elem, count in self.items():
            if count > 0:
                result[elem] = count
        return result

    def neg(self):
        &#39;&#39;&#39;Subtracts from an empty counter.  Strips positive and zero counts,
        and flips the sign on negative counts.

        &#39;&#39;&#39;
        result = Counter()
        for elem, count in self.items():
            if count < 0:
                result[elem] = 0 - count
        return result

    def _keep_positive(self):
        &#39;&#39;&#39;Internal method to strip elements with a negative or zero count&#39;&#39;&#39;
        nonpositive = [elem for elem, count in self.items() if not count > 0]
        for elem in nonpositive:
            del self[elem]
        return self

    def iadd(self, other):
        &#39;&#39;&#39;Inplace add from another counter, keeping only positive counts.

        >>> c = Counter(&#39;abbb&#39;)
        >>> c += Counter(&#39;bcc&#39;)
        >>> c
        Counter({&#39;b&#39;: 4, &#39;c&#39;: 2, &#39;a&#39;: 1})

        &#39;&#39;&#39;
        for elem, count in other.items():
            self[elem] += count
        return self._keep_positive()

    def isub(self, other):
        &#39;&#39;&#39;Inplace subtract counter, but keep only results with positive counts.

        >>> c = Counter(&#39;abbbc&#39;)
        >>> c -= Counter(&#39;bccd&#39;)
        >>> c
        Counter({&#39;b&#39;: 2, &#39;a&#39;: 1})

        &#39;&#39;&#39;
        for elem, count in other.items():
            self[elem] -= count
        return self._keep_positive()

    def ior(self, other):
        &#39;&#39;&#39;Inplace union is the maximum of value from either counter.

        >>> c = Counter(&#39;abbb&#39;)
        >>> c |= Counter(&#39;bcc&#39;)
        >>> c
        Counter({&#39;b&#39;: 3, &#39;c&#39;: 2, &#39;a&#39;: 1})

        &#39;&#39;&#39;
        for elem, other_count in other.items():
            count = self[elem]
            if other_count > count:
                self[elem] = other_count
        return self._keep_positive()

    def iand(self, other):
        &#39;&#39;&#39;Inplace intersection is the minimum of corresponding counts.

        >>> c = Counter(&#39;abbb&#39;)
        >>> c &= Counter(&#39;bcc&#39;)
        >>> c
        Counter({&#39;b&#39;: 1})

        &#39;&#39;&#39;
        for elem, count in self.items():
            other_count = other[elem]
            if other_count < count:
                self[elem] = other_count
        return self._keep_positive()

Counter
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1) Création du compteur :

from collections import Counter    #Counter 需要申明

a=Counter()                            # 创建空计数器
b=Counter(&#39;aabbbcccc&#39;)                 # 可迭代对象计数的方式创建对象
c = Counter({&#39;red&#39;: 4, &#39;blue&#39;: 2})     # 映射方法创建计数器
d = Counter(cats=4, dogs=8)            # 键值的方法创建计数器
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2) Suppression de l'élément compteur

a=Counter({&#39;a&#39;:2,&#39;b&#39;:6,&#39;c&#39;:4,&#39;d&#39;:0,&#39;e&#39;:-2})
print(a)
a[&#39;a&#39;]=0    #修改了计数器元素里的值
print(a)
del a[&#39;b&#39;]   #删除了元素
print(a)

#运行结果
Counter({&#39;b&#39;: 6, &#39;c&#39;: 4, &#39;a&#39;: 2, &#39;d&#39;: 0, &#39;e&#39;: -2})
Counter({&#39;b&#39;: 6, &#39;c&#39;: 4, &#39;a&#39;: 0, &#39;d&#39;: 0, &#39;e&#39;: -2})
Counter({&#39;c&#39;: 4, &#39;a&#39;: 0, &#39;d&#39;: 0, &#39;e&#39;: -2})

del
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3) Partie du compteur Fonction attribut

most_common(self, n=None) :

convertit le compteur en liste, les éléments en tuple, et renvoie les n éléments les plus courants et leur liste comptée, du plus courant au moins courant. Si n est omis ou None, most_common() renvoie tous les éléments du compteur. Les éléments avec des nombres égaux sont ordonnés arbitrairement.

a=Counter({&#39;a&#39;:2,&#39;b&#39;:6,&#39;c&#39;:4,&#39;d&#39;:0,&#39;e&#39;:-2})
b=a.most_common()
c=a.most_common(2)
print(a)
print(b,type(b))
print(c,type(c))

#运行结果
Counter({&#39;b&#39;: 6, &#39;c&#39;: 4, &#39;a&#39;: 2, &#39;d&#39;: 0, &#39;e&#39;: -2})
[(&#39;b&#39;, 6), (&#39;c&#39;, 4), (&#39;a&#39;, 2), (&#39;d&#39;, 0), (&#39;e&#39;, -2)] <class &#39;list&#39;>
[(&#39;b&#39;, 6), (&#39;c&#39;, 4)] <class &#39;list&#39;>

demo
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elements(self) :

Renvoie un itérateur qui parcourt les éléments un certain nombre de fois. Les éléments sont renvoyés dans un ordre aléatoire. Si le nombre d'éléments est inférieur à 1, elements() l'ignorera.

a=Counter({&#39;a&#39;:2,&#39;b&#39;:6,&#39;c&#39;:4,&#39;d&#39;:0,&#39;e&#39;:-2})
b=a.elements()
c=sorted(a.elements())
print(a)
print(b,type(b))
print(c,type(c))

#运行结果
Counter({&#39;b&#39;: 6, &#39;c&#39;: 4, &#39;a&#39;: 2, &#39;d&#39;: 0, &#39;e&#39;: -2})
<itertools.chain object at 0x00225A50> <class &#39;itertools.chain&#39;>
[&#39;a&#39;, &#39;a&#39;, &#39;b&#39;, &#39;b&#39;, &#39;b&#39;, &#39;b&#39;, &#39;b&#39;, &#39;b&#39;, &#39;c&#39;, &#39;c&#39;, &#39;c&#39;, &#39;c&#39;] <class &#39;list&#39;>

demo
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update(*args, **kwds):

Les éléments sont comptés à partir d'un itérable ou incrémentés à partir d'une autre carte (ou compteur). Comme dict.update(), mais les incréments comptent au lieu de les remplacer. De plus, les itérables doivent être une séquence d’éléments et non des paires (clé, valeur).

a=Counter({&#39;a&#39;:2,&#39;b&#39;:6,&#39;c&#39;:4,&#39;d&#39;:0,&#39;e&#39;:-2})
a.update(&#39;abe&#39;)
a.update({&#39;g&#39;:1})
print(a)

#运行结果
Counter({&#39;b&#39;: 7, &#39;c&#39;: 4, &#39;a&#39;: 3, &#39;g&#39;: 1, &#39;d&#39;: 0, &#39;e&#39;: -1})

demo
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subtract(*args, **kwds):
Soustraire des éléments d'un itérable ou d'une autre carte (ou compteur). Comme dict.update(), mais soustrait les comptes au lieu de les remplacer. L'entrée et la sortie peuvent être nulles ou négatives.

a=Counter({&#39;a&#39;:2,&#39;b&#39;:6,&#39;c&#39;:4,&#39;d&#39;:0,&#39;e&#39;:-2})
a.subtract(&#39;ade&#39;)
print(a)

#运行结果
Counter({&#39;b&#39;: 6, &#39;c&#39;: 4, &#39;a&#39;: 1, &#39;d&#39;: -1, &#39;e&#39;: -3})

demo
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2. Dictionnaire ordonné (OrderedDict)
Les dictionnaires ordonnés sont similaires aux dictionnaires ordinaires, mais ils mémorisent l'ordre dans lequel les paires clé-valeur sont insérées. Lors d’une itération sur un dictionnaire ordonné, les éléments sont renvoyés dans l’ordre dans lequel leurs clés ont été ajoutées pour la première fois.

class OrderedDict(dict):
    &#39;Dictionary that remembers insertion order&#39;
    # An inherited dict maps keys to values.
    # The inherited dict provides getitem, len, contains, and get.
    # The remaining methods are order-aware.
    # Big-O running times for all methods are the same as regular dictionaries.

    # The internal self.map dict maps keys to links in a doubly linked list.
    # The circular doubly linked list starts and ends with a sentinel element.
    # The sentinel element never gets deleted (this simplifies the algorithm).
    # The sentinel is in self.hardroot with a weakref proxy in self.root.
    # The prev links are weakref proxies (to prevent circular references).
    # Individual links are kept alive by the hard reference in self.map.
    # Those hard references disappear when a key is deleted from an OrderedDict.

    def init(*args, **kwds):
        &#39;&#39;&#39;Initialize an ordered dictionary.  The signature is the same as
        regular dictionaries, but keyword arguments are not recommended because
        their insertion order is arbitrary.

        &#39;&#39;&#39;
        if not args:
            raise TypeError("descriptor &#39;init&#39; of &#39;OrderedDict&#39; object "
                            "needs an argument")
        self, *args = args
        if len(args) > 1:
            raise TypeError(&#39;expected at most 1 arguments, got %d&#39; % len(args))
        try:
            self.root
        except AttributeError:
            self.hardroot = _Link()
            self.root = root = _proxy(self.hardroot)
            root.prev = root.next = root
            self.map = {}
        self.update(*args, **kwds)

    def setitem(self, key, value,
                    dict_setitem=dict.setitem, proxy=_proxy, Link=_Link):
        &#39;od.setitem(i, y) <==> od[i]=y&#39;
        # Setting a new item creates a new link at the end of the linked list,
        # and the inherited dictionary is updated with the new key/value pair.
        if key not in self:
            self.map[key] = link = Link()
            root = self.root
            last = root.prev
            link.prev, link.next, link.key = last, root, key
            last.next = link
            root.prev = proxy(link)
        dict_setitem(self, key, value)

    def delitem(self, key, dict_delitem=dict.delitem):
        &#39;od.delitem(y) <==> del od[y]&#39;
        # Deleting an existing item uses self.map to find the link which gets
        # removed by updating the links in the predecessor and successor nodes.
        dict_delitem(self, key)
        link = self.map.pop(key)
        link_prev = link.prev
        link_next = link.next
        link_prev.next = link_next
        link_next.prev = link_prev
        link.prev = None
        link.next = None

    def iter(self):
        &#39;od.iter() <==> iter(od)&#39;
        # Traverse the linked list in order.
        root = self.root
        curr = root.next
        while curr is not root:
            yield curr.key
            curr = curr.next

    def reversed(self):
        &#39;od.reversed() <==> reversed(od)&#39;
        # Traverse the linked list in reverse order.
        root = self.root
        curr = root.prev
        while curr is not root:
            yield curr.key
            curr = curr.prev

    def clear(self):
        &#39;od.clear() -> None.  Remove all items from od.&#39;
        root = self.root
        root.prev = root.next = root
        self.map.clear()
        dict.clear(self)

    def popitem(self, last=True):
        &#39;&#39;&#39;od.popitem() -> (k, v), return and remove a (key, value) pair.
        Pairs are returned in LIFO order if last is true or FIFO order if false.

        &#39;&#39;&#39;
        if not self:
            raise KeyError(&#39;dictionary is empty&#39;)
        root = self.root
        if last:
            link = root.prev
            link_prev = link.prev
            link_prev.next = root
            root.prev = link_prev
        else:
            link = root.next
            link_next = link.next
            root.next = link_next
            link_next.prev = root
        key = link.key
        del self.map[key]
        value = dict.pop(self, key)
        return key, value

    def move_to_end(self, key, last=True):
        &#39;&#39;&#39;Move an existing element to the end (or beginning if last==False).

        Raises KeyError if the element does not exist.
        When last=True, acts like a fast version of self[key]=self.pop(key).

        &#39;&#39;&#39;
        link = self.map[key]
        link_prev = link.prev
        link_next = link.next
        link_prev.next = link_next
        link_next.prev = link_prev
        root = self.root
        if last:
            last = root.prev
            link.prev = last
            link.next = root
            last.next = root.prev = link
        else:
            first = root.next
            link.prev = root
            link.next = first
            root.next = first.prev = link

    def sizeof(self):
        sizeof = _sys.getsizeof
        n = len(self) + 1                       # number of links including root
        size = sizeof(self.dict)            # instance dictionary
        size += sizeof(self.map) * 2          # internal dict and inherited dict
        size += sizeof(self.hardroot) * n     # link objects
        size += sizeof(self.root) * n         # proxy objects
        return size

    update = update = MutableMapping.update

    def keys(self):
        "D.keys() -> a set-like object providing a view on D&#39;s keys"
        return _OrderedDictKeysView(self)

    def items(self):
        "D.items() -> a set-like object providing a view on D&#39;s items"
        return _OrderedDictItemsView(self)

    def values(self):
        "D.values() -> an object providing a view on D&#39;s values"
        return _OrderedDictValuesView(self)

    ne = MutableMapping.ne

    marker = object()

    def pop(self, key, default=marker):
        &#39;&#39;&#39;od.pop(k[,d]) -> v, remove specified key and return the corresponding
        value.  If key is not found, d is returned if given, otherwise KeyError
        is raised.

        &#39;&#39;&#39;
        if key in self:
            result = self[key]
            del self[key]
            return result
        if default is self.marker:
            raise KeyError(key)
        return default

    def setdefault(self, key, default=None):
        &#39;od.setdefault(k[,d]) -> od.get(k,d), also set od[k]=d if k not in od&#39;
        if key in self:
            return self[key]
        self[key] = default
        return default

    @_recursive_repr()
    def repr(self):
        &#39;od.repr() <==> repr(od)&#39;
        if not self:
            return &#39;%s()&#39; % (self.class.name,)
        return &#39;%s(%r)&#39; % (self.class.name, list(self.items()))

    def reduce(self):
        &#39;Return state information for pickling&#39;
        inst_dict = vars(self).copy()
        for k in vars(OrderedDict()):
            inst_dict.pop(k, None)
        return self.class, (), inst_dict or None, None, iter(self.items())

    def copy(self):
        &#39;od.copy() -> a shallow copy of od&#39;
        return self.class(self)

    @classmethod
    def fromkeys(cls, iterable, value=None):
        &#39;&#39;&#39;OD.fromkeys(S[, v]) -> New ordered dictionary with keys from S.
        If not specified, the value defaults to None.

        &#39;&#39;&#39;
        self = cls()
        for key in iterable:
            self[key] = value
        return self

    def eq(self, other):
        &#39;&#39;&#39;od.eq(y) <==> od==y.  Comparison to another OD is order-sensitive
        while comparison to a regular mapping is order-insensitive.

        &#39;&#39;&#39;
        if isinstance(other, OrderedDict):
            return dict.eq(self, other) and all(map(_eq, self, other))
        return dict.eq(self, other)


try:
    from _collections import OrderedDict
except ImportError:
    # Leave the pure Python version in place.
    pass

OrderedDict
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1) Création de dictionnaire ordonné :

from collections import OrderedDict

a=dict()                 #
b=OrderedDict()
a[&#39;a&#39;]=1
a[&#39;b&#39;]=2
a[&#39;c&#39;]=3
a[&#39;d&#39;]=4
b[&#39;a&#39;]=1
b[&#39;b&#39;]=2
b[&#39;c&#39;]=3
b[&#39;d&#39;]=4
print(a,type(a))
print(b,type(b))

#运行结果
{&#39;a&#39;: 1, &#39;c&#39;: 3, &#39;d&#39;: 4, &#39;b&#39;: 2} <class &#39;dict&#39;>   
OrderedDict([(&#39;a&#39;, 1), (&#39;b&#39;, 2), (&#39;c&#39;, 3), (&#39;d&#39;, 4)]) <class &#39;collections.OrderedDict&#39;>

demo
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2) Fonction de dictionnaire ordonné :
Dictionnaire ordonné Hérité Les fonctions de le dictionnaire est expliqué ci-dessous, et seules les fonctions différentes du dictionnaire sont présentées ci-dessous.
popitem(self, last=True):
Renvoyer et supprimer la paire clé-valeur dans le dictionnaire. Si last est True (valeur par défaut), ces paires clé-valeur sont renvoyées dans l'ordre LIFO, si False, elles sont renvoyées dans l'ordre FIFO.

a=OrderedDict()
a[&#39;a&#39;]=1
a[&#39;b&#39;]=2
a[&#39;c&#39;]=3
a[&#39;d&#39;]=4
b=a.popitem()
print(a)
print(b)

#运行结果
OrderedDict([(&#39;a&#39;, 1), (&#39;b&#39;, 2), (&#39;c&#39;, 3)])
(&#39;d&#39;, 4)

demo
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move_to_end(self, key, last=True) :
Déplacez une clé existante à l'autre extrémité du dictionnaire ordonné. Si last est True (valeur par défaut), l'élément est déplacé vers la fin, si last est False, il est déplacé vers le début. Si la clé n'existe pas, KeyError est levée.

a=OrderedDict()
a[&#39;a&#39;]=1
a[&#39;b&#39;]=2
a[&#39;c&#39;]=3
a[&#39;d&#39;]=4
print(a)
b=a.move_to_end(&#39;b&#39;)
print(a)

#运行结果
OrderedDict([(&#39;a&#39;, 1), (&#39;b&#39;, 2), (&#39;c&#39;, 3), (&#39;d&#39;, 4)])
OrderedDict([(&#39;a&#39;, 1), (&#39;c&#39;, 3), (&#39;d&#39;, 4), (&#39;b&#39;, 2)])

demo
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3. Dictionnaire par défaut (defaultdict)
defaultdict peut spécifier une valeur par défaut pour le dictionnaire, qui peut être un dictionnaire/une liste, etc. Renvoie un nouvel objet de type dictionnaire avec les mêmes fonctionnalités que la classe dict.
Par exemple :

from collections import defaultdict             

a=defaultdict(list)              #默认value为list
b=defaultdict(tuple)             #默认value为tuple
c=defaultdict(dict)             #默认value为dict
d=dict()
print(a)
print(b)
print(c)
print(d)

#运行结果
defaultdict(<class &#39;list&#39;>, {})
defaultdict(<class &#39;tuple&#39;>, {})
defaultdict(<class &#39;dict&#39;>, {})
{}

demo
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Application :

s = [(&#39;yellow&#39;, 1), (&#39;blue&#39;, 2), (&#39;yellow&#39;, 3), (&#39;blue&#39;, 4), (&#39;red&#39;, 1)]
d = defaultdict(list)
for k, v in s:
     d[k].append(v)            #如果使用普通字典,需要先给字典初始化键值对
c=sorted(d.items())
print(type(s))
print(d)
print(c,type(c))

#运行结果
<class &#39;list&#39;>
defaultdict(<class &#39;list&#39;>, {&#39;red&#39;: [1], &#39;blue&#39;: [2, 4], &#39;yellow&#39;: [1, 3]})
[(&#39;blue&#39;, [2, 4]), (&#39;red&#39;, [1]), (&#39;yellow&#39;, [1, 3])] <class &#39;list&#39;>

demo
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Fonction de dictionnaire par défaut :

class defaultdict(dict):
    """
    defaultdict(default_factory[, ...]) --> dict with default factory
    
    The default factory is called without arguments to produce
    a new value when a key is not present, in getitem only.
    A defaultdict compares equal to a dict with the same items.
    All remaining arguments are treated the same as if they were
    passed to the dict constructor, including keyword arguments.
    """
    def copy(self): # real signature unknown; restored from doc
        """ D.copy() -> a shallow copy of D. """
        pass

    def copy(self, *args, **kwargs): # real signature unknown
        """ D.copy() -> a shallow copy of D. """
        pass

    def getattribute(self, *args, **kwargs): # real signature unknown
        """ Return getattr(self, name). """
        pass

    def init(self, default_factory=None, **kwargs): # known case of _collections.defaultdict.init
        """
        defaultdict(default_factory[, ...]) --> dict with default factory
        
        The default factory is called without arguments to produce
        a new value when a key is not present, in getitem only.
        A defaultdict compares equal to a dict with the same items.
        All remaining arguments are treated the same as if they were
        passed to the dict constructor, including keyword arguments.
        
        # (copied from class doc)
        """
        pass

    def missing(self, key): # real signature unknown; restored from doc
        """
        missing(key) # Called by getitem for missing key; pseudo-code:
          if self.default_factory is None: raise KeyError((key,))
          self[key] = value = self.default_factory()
          return value
        """
        pass

    def reduce(self, *args, **kwargs): # real signature unknown
        """ Return state information for pickling. """
        pass

    def repr(self, *args, **kwargs): # real signature unknown
        """ Return repr(self). """
        pass

    default_factory = property(lambda self: object(), lambda self, v: None, lambda self: None)  # default
    """Factory for default value called by missing()."""

defaultdict
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4.

1) Description des tuples nommés

给元组中每个位置上的元素命名,它们可以使用常规的元组方法,可以让访问元素可以按名称而不是按位置索引

collections.namedtuple(typename, field_names, verbose=False, rename=False):

返回一个叫做 typename 的tuple子类,这个新的子类用来创建类tuple(tuple-like)的对象,这个对象拥有可以通过属性访问的字段,并且可以通过下标索引和迭代。

field_names 是一个单独的字符串,这个字符串中包含的所有字段用空格或逗号隔开,例如 'xy' 或 'x,y'.另外, field_names 也可以是字符串的列表,例如 ['x', 'y']。

如果verbose 为 True, 在类被建立后将打印类的定义。相反,它打印的是类的 _source 属性,也就是打印源代码。

如果 rename参数 为 True, 无效的field_names会被自动转换成位置的名称.例如, ['abc', 'def', 'ghi', 'abc'] 将被转换为 ['abc', '_1', 'ghi', '_3'], 来消除关键字 def 和重复的字段名 abc。

2)可命名元组的创建

需要先创建一个类。

from collections import namedtuple

myTupleClass=namedtuple(&#39;myTupleClass&#39;,[&#39;x&#39;,&#39;y&#39;])
a=point(1,2)
b=point(2,0)
print(a,a.x,a.y,type(a))
print(b,b.x,b.y,type(b))

#运行结果
myTupleClass(x=1, y=2) 1 2 <class &#39;main.myTupleClass&#39;>
myTupleClass(x=2, y=0) 2 0 <class &#39;main.myTupleClass&#39;>
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3)可命名元组新创建类的功能属性

如上面创建的myTupleCalss类:

print(help(myTupleClass))    #运行help打印获取

class myTupleClass(builtins.tuple)
 |  myTupleClass(x, y)
 |  
 |  Method resolution order:
 |      myTupleClass
 |      builtins.tuple
 |      builtins.object
 |  
 |  Methods defined here:
 |  
 |  getnewargs(self)
 |      Return self as a plain tuple.  Used by copy and pickle.
 |  
 |  repr(self)
 |      Return a nicely formatted representation string
 |  
 |  _asdict(self)
 |      Return a new OrderedDict which maps field names to their values.
 |  
 |  _replace(_self, **kwds)
 |      Return a new myTupleClass object replacing specified fields with new values
 |  
 |  ----------------------------------------------------------------------
 |  Class methods defined here:
 |  
 |  _make(iterable, new=<built-in method new of type object at 0x6143B5C8>, len=<built-in function len>) from builtins.type
 |      Make a new myTupleClass object from a sequence or iterable
 |  
 |  ----------------------------------------------------------------------
 |  Static methods defined here:
 |  
 |  new(_cls, x, y)
 |      Create new instance of myTupleClass(x, y)
 |  
 |  ----------------------------------------------------------------------
 |  Data descriptors defined here:
 |  
 |  x
 |      Alias for field number 0
 |  
 |  y
 |      Alias for field number 1
 |  
 |  ----------------------------------------------------------------------
 |  Data and other attributes defined here:
 |  
 |  _fields = (&#39;x&#39;, &#39;y&#39;)
 |  
 |  _source = "from builtins import property as _property, tupl..._itemget...
 |  
 |  ----------------------------------------------------------------------
 |  Methods inherited from builtins.tuple:
 |  
 |  add(self, value, /)
 |      Return self+value.
 |  
 |  contains(self, key, /)
 |      Return key in self.
 |  
 |  eq(self, value, /)
 |      Return self==value.
 |  
 |  ge(self, value, /)
 |      Return self>=value.
 |  
 |  getattribute(self, name, /)
 |      Return getattr(self, name).
 |  
 |  getitem(self, key, /)
 |      Return self[key].
 |  
 |  gt(self, value, /)
 |      Return self>value.
 |  
 |  hash(self, /)
 |      Return hash(self).
 |  
 |  iter(self, /)
 |      Implement iter(self).
 |  
 |  le(self, value, /)
 |      Return self<=value.
 |  
 |  len(self, /)
 |      Return len(self).
 |  
 |  lt(self, value, /)
 |      Return self<value.
 |  
 |  mul(self, value, /)
 |      Return self*value.n
 |  
 |  ne(self, value, /)
 |      Return self!=value.
 |  
 |  rmul(self, value, /)
 |      Return self*value.
 |  
 |  count(...)
 |      T.count(value) -> integer -- return number of occurrences of value
 |  
 |  index(...)
 |      T.index(value, [start, [stop]]) -> integer -- return first index of value.
 |      Raises ValueError if the value is not present.

None

myTupleCalss
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5.队列(deque)

1)双向队列(deque)

双向队列(Deque)是栈和队列的一般化。可以在两端添加和删除元素。

双向队列的创建:

from collections import deque

a=deque()
b=deque(&#39;abcd&#39;)
print(a,type(a))
print(b,type(b))

#运行结果
deque([]) <class &#39;collections.deque&#39;>
deque([&#39;a&#39;, &#39;b&#39;, &#39;c&#39;, &#39;d&#39;]) <class &#39;collections.deque&#39;>
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双向队列的功能属性:

class deque(object):
    """
    deque([iterable[, maxlen]]) --> deque object
    
    A list-like sequence optimized for data accesses near its endpoints.
    """
    def append(self, *args, **kwargs): # real signature unknown
        """ Add an element to the right side of the deque. """
        pass

    def appendleft(self, *args, **kwargs): # real signature unknown
        """ Add an element to the left side of the deque. """
        pass

    def clear(self, *args, **kwargs): # real signature unknown
        """ Remove all elements from the deque. """
        pass

    def copy(self, *args, **kwargs): # real signature unknown
        """ Return a shallow copy of a deque. """
        pass

    def count(self, value): # real signature unknown; restored from doc
        """ D.count(value) -> integer -- return number of occurrences of value """
        return 0

    def extend(self, *args, **kwargs): # real signature unknown
        """ Extend the right side of the deque with elements from the iterable """
        pass

    def extendleft(self, *args, **kwargs): # real signature unknown
        """ Extend the left side of the deque with elements from the iterable """
        pass

    def index(self, value, start=None, stop=None): # real signature unknown; restored from doc
        """
        D.index(value, [start, [stop]]) -> integer -- return first index of value.
        Raises ValueError if the value is not present.
        """
        return 0

    def insert(self, index, p_object): # real signature unknown; restored from doc
        """ D.insert(index, object) -- insert object before index """
        pass

    def pop(self, *args, **kwargs): # real signature unknown
        """ Remove and return the rightmost element. """
        pass

    def popleft(self, *args, **kwargs): # real signature unknown
        """ Remove and return the leftmost element. """
        pass

    def remove(self, value): # real signature unknown; restored from doc
        """ D.remove(value) -- remove first occurrence of value. """
        pass

    def reverse(self): # real signature unknown; restored from doc
        """ D.reverse() -- reverse *IN PLACE* """
        pass

    def rotate(self, *args, **kwargs): # real signature unknown
        """ Rotate the deque n steps to the right (default n=1).  If n is negative, rotates left. """
        pass

    def add(self, *args, **kwargs): # real signature unknown
        """ Return self+value. """
        pass

    def bool(self, *args, **kwargs): # real signature unknown
        """ self != 0 """
        pass

    def contains(self, *args, **kwargs): # real signature unknown
        """ Return key in self. """
        pass

    def copy(self, *args, **kwargs): # real signature unknown
        """ Return a shallow copy of a deque. """
        pass

    def delitem(self, *args, **kwargs): # real signature unknown
        """ Delete self[key]. """
        pass

    def eq(self, *args, **kwargs): # real signature unknown
        """ Return self==value. """
        pass

    def getattribute(self, *args, **kwargs): # real signature unknown
        """ Return getattr(self, name). """
        pass

    def getitem(self, *args, **kwargs): # real signature unknown
        """ Return self[key]. """
        pass

    def ge(self, *args, **kwargs): # real signature unknown
        """ Return self>=value. """
        pass

    def gt(self, *args, **kwargs): # real signature unknown
        """ Return self>value. """
        pass

    def iadd(self, *args, **kwargs): # real signature unknown
        """ Implement self+=value. """
        pass

    def imul(self, *args, **kwargs): # real signature unknown
        """ Implement self*=value. """
        pass

    def init(self, iterable=(), maxlen=None): # known case of _collections.deque.init
        """
        deque([iterable[, maxlen]]) --> deque object
        
        A list-like sequence optimized for data accesses near its endpoints.
        # (copied from class doc)
        """
        pass

    def iter(self, *args, **kwargs): # real signature unknown
        """ Implement iter(self). """
        pass

    def len(self, *args, **kwargs): # real signature unknown
        """ Return len(self). """
        pass

    def le(self, *args, **kwargs): # real signature unknown
        """ Return self<=value. """
        pass

    def lt(self, *args, **kwargs): # real signature unknown
        """ Return self<value. """
        pass

    def mul(self, *args, **kwargs): # real signature unknown
        """ Return self*value.n """
        pass

    @staticmethod # known case of new
    def new(*args, **kwargs): # real signature unknown
        """ Create and return a new object.  See help(type) for accurate signature. """
        pass

    def ne(self, *args, **kwargs): # real signature unknown
        """ Return self!=value. """
        pass

    def reduce(self, *args, **kwargs): # real signature unknown
        """ Return state information for pickling. """
        pass

    def repr(self, *args, **kwargs): # real signature unknown
        """ Return repr(self). """
        pass

    def reversed(self): # real signature unknown; restored from doc
        """ D.reversed() -- return a reverse iterator over the deque """
        pass

    def rmul(self, *args, **kwargs): # real signature unknown
        """ Return self*value. """
        pass

    def setitem(self, *args, **kwargs): # real signature unknown
        """ Set self[key] to value. """
        pass

    def sizeof(self): # real signature unknown; restored from doc
        """ D.sizeof() -- size of D in memory, in bytes """
        pass

    maxlen = property(lambda self: object(), lambda self, v: None, lambda self: None)  # default
    """maximum size of a deque or None if unbounded"""


    hash = None

deque
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2)单向队列(queue.Queue)

class queue.Queue(maxsize=0)

单向队列与双向队列的区别是FIFO(先进先出),maxsize是个整数,指明了队列中能存放的数据个数的上限。一旦达到上限,插入会导致阻塞,直到队列中的数据被取出。如果maxsize小于或者等于0,则队列大小没有限制。

单向队列的创建:

import queue

a=queue.Queue()
b=queue.Queue(&#39;abcd&#39;)
print(a,type(a))
print(b,type(b))

#运行结果
<queue.Queue object at 0x00FBB310> <class &#39;queue.Queue&#39;>
<queue.Queue object at 0x01522DF0> <class &#39;queue.Queue&#39;>
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单向队列的功能属性:

class Queue:
    &#39;&#39;&#39;Create a queue object with a given maximum size.

    If maxsize is <= 0, the queue size is infinite.
    &#39;&#39;&#39;

    def init(self, maxsize=0):
        self.maxsize = maxsize
        self._init(maxsize)

        # mutex must be held whenever the queue is mutating.  All methods
        # that acquire mutex must release it before returning.  mutex
        # is shared between the three conditions, so acquiring and
        # releasing the conditions also acquires and releases mutex.
        self.mutex = threading.Lock()

        # Notify not_empty whenever an item is added to the queue; a
        # thread waiting to get is notified then.
        self.not_empty = threading.Condition(self.mutex)

        # Notify not_full whenever an item is removed from the queue;
        # a thread waiting to put is notified then.
        self.not_full = threading.Condition(self.mutex)

        # Notify all_tasks_done whenever the number of unfinished tasks
        # drops to zero; thread waiting to join() is notified to resume
        self.all_tasks_done = threading.Condition(self.mutex)
        self.unfinished_tasks = 0

    def task_done(self):
        &#39;&#39;&#39;Indicate that a formerly enqueued task is complete.

        Used by Queue consumer threads.  For each get() used to fetch a task,
        a subsequent call to task_done() tells the queue that the processing
        on the task is complete.

        If a join() is currently blocking, it will resume when all items
        have been processed (meaning that a task_done() call was received
        for every item that had been put() into the queue).

        Raises a ValueError if called more times than there were items
        placed in the queue.
        &#39;&#39;&#39;
        with self.all_tasks_done:
            unfinished = self.unfinished_tasks - 1
            if unfinished <= 0:
                if unfinished < 0:
                    raise ValueError(&#39;task_done() called too many times&#39;)
                self.all_tasks_done.notify_all()
            self.unfinished_tasks = unfinished

    def join(self):
        &#39;&#39;&#39;Blocks until all items in the Queue have been gotten and processed.

        The count of unfinished tasks goes up whenever an item is added to the
        queue. The count goes down whenever a consumer thread calls task_done()
        to indicate the item was retrieved and all work on it is complete.

        When the count of unfinished tasks drops to zero, join() unblocks.
        &#39;&#39;&#39;
        with self.all_tasks_done:
            while self.unfinished_tasks:
                self.all_tasks_done.wait()

    def qsize(self):
        &#39;&#39;&#39;Return the approximate size of the queue (not reliable!).&#39;&#39;&#39;
        with self.mutex:
            return self._qsize()

    def empty(self):
        &#39;&#39;&#39;Return True if the queue is empty, False otherwise (not reliable!).

        This method is likely to be removed at some point.  Use qsize() == 0
        as a direct substitute, but be aware that either approach risks a race
        condition where a queue can grow before the result of empty() or
        qsize() can be used.

        To create code that needs to wait for all queued tasks to be
        completed, the preferred technique is to use the join() method.
        &#39;&#39;&#39;
        with self.mutex:
            return not self._qsize()

    def full(self):
        &#39;&#39;&#39;Return True if the queue is full, False otherwise (not reliable!).

        This method is likely to be removed at some point.  Use qsize() >= n
        as a direct substitute, but be aware that either approach risks a race
        condition where a queue can shrink before the result of full() or
        qsize() can be used.
        &#39;&#39;&#39;
        with self.mutex:
            return 0 < self.maxsize <= self._qsize()

    def put(self, item, block=True, timeout=None):
        &#39;&#39;&#39;Put an item into the queue.

        If optional args &#39;block&#39; is true and &#39;timeout&#39; is None (the default),
        block if necessary until a free slot is available. If &#39;timeout&#39; is
        a non-negative number, it blocks at most &#39;timeout&#39; seconds and raises
        the Full exception if no free slot was available within that time.
        Otherwise (&#39;block&#39; is false), put an item on the queue if a free slot
        is immediately available, else raise the Full exception (&#39;timeout&#39;
        is ignored in that case).
        &#39;&#39;&#39;
        with self.not_full:
            if self.maxsize > 0:
                if not block:
                    if self._qsize() >= self.maxsize:
                        raise Full
                elif timeout is None:
                    while self._qsize() >= self.maxsize:
                        self.not_full.wait()
                elif timeout < 0:
                    raise ValueError("&#39;timeout&#39; must be a non-negative number")
                else:
                    endtime = time() + timeout
                    while self._qsize() >= self.maxsize:
                        remaining = endtime - time()
                        if remaining <= 0.0:
                            raise Full
                        self.not_full.wait(remaining)
            self._put(item)
            self.unfinished_tasks += 1
            self.not_empty.notify()

    def get(self, block=True, timeout=None):
        &#39;&#39;&#39;Remove and return an item from the queue.

        If optional args &#39;block&#39; is true and &#39;timeout&#39; is None (the default),
        block if necessary until an item is available. If &#39;timeout&#39; is
        a non-negative number, it blocks at most &#39;timeout&#39; seconds and raises
        the Empty exception if no item was available within that time.
        Otherwise (&#39;block&#39; is false), return an item if one is immediately
        available, else raise the Empty exception (&#39;timeout&#39; is ignored
        in that case).
        &#39;&#39;&#39;
        with self.not_empty:
            if not block:
                if not self._qsize():
                    raise Empty
            elif timeout is None:
                while not self._qsize():
                    self.not_empty.wait()
            elif timeout < 0:
                raise ValueError("&#39;timeout&#39; must be a non-negative number")
            else:
                endtime = time() + timeout
                while not self._qsize():
                    remaining = endtime - time()
                    if remaining <= 0.0:
                        raise Empty
                    self.not_empty.wait(remaining)
            item = self._get()
            self.not_full.notify()
            return item

    def put_nowait(self, item):
        &#39;&#39;&#39;Put an item into the queue without blocking.

        Only enqueue the item if a free slot is immediately available.
        Otherwise raise the Full exception.
        &#39;&#39;&#39;
        return self.put(item, block=False)

    def get_nowait(self):
        &#39;&#39;&#39;Remove and return an item from the queue without blocking.

        Only get an item if one is immediately available. Otherwise
        raise the Empty exception.
        &#39;&#39;&#39;
        return self.get(block=False)

    # Override these methods to implement other queue organizations
    # (e.g. stack or priority queue).
    # These will only be called with appropriate locks held

    # Initialize the queue representation
    def _init(self, maxsize):
        self.queue = deque()

    def _qsize(self):
        return len(self.queue)

    # Put a new item in the queue
    def _put(self, item):
        self.queue.append(item)

    # Get an item from the queue
    def _get(self):
        return self.queue.popleft()

queue.Queue
Copier après la connexion

6.深浅拷贝

浅拷贝和深拷贝的主要区别在与操作后内存地址的变化是不同的。


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