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Python Crash Course Containers Bachelors V1.0 dd 13-01-2015 Hour 6 Introduction to language - containers Container data types in Python are types whose instances are capable of storing other objects. Some of the fundamental built-in container objects include: • lists – the most popular container data type in python; can store any number of any objects. • tuples – similar to list, yet once created are immutable, • sets – can store only unique elements, • bytes – immutable sequence of integers in the range 0 <= x < 256, • bytearray – like bytes, but mutable, • dictionary – also known as associative arrays. They contain mapping of keys into value, • str – string, a sequence of unicode characters, • range – a sequence of numbers — more precisely a list containing arithmetic progressions • array.array – present in the array module. Similar to list, yet during the construction it is restricted to holding a specific data type, Containers – Mutable, Immutable, Hashable Containers in Python can be either mutable or immutable. The fact that a container object is immutable doesn’t always mean that the objects it holds are also immutable (e.g. an immutable tuple holding mutable lists). However, container objects are fully immutable only if the object itself, and the objects it contains are recursively immutable. Recursively immutable objects may be hashable. This is important as only hashable objects can be used in a mapping container object (see below) as keys. Mutable Definition: Mutable objects can change their value but keep their id(). Immutable Definition: An object with a fixed value. Immutable objects include numbers, strings and tuples. Such an object cannot be altered. A new object has to be created if a different value has to be stored. They play an important role in places where a constant hash value is needed, for example as a key in a dictionary. Hashable Definition: An object is hashable if it has a hash value which never changes during its lifetime (it needs a hash()method), and can be compared to other objects (it needs an eq() method). Hashable objects which compare equal must have the same hash value. Containers – Mutable, Immutable, Hashable All of Python’s immutable built-in objects are hashable, while no mutable containers (such as lists or dictionaries) are. Examples of mutable containers include: • list, • set, • dictionary, • bytearray • array Examples of immutable containers include: • numbers • string, • frozenset, • tuple, • bytes The main implication of the mutable/immutable distinction and hashability is that not all container objects can store all other container objects, in particular: • sets can store only hashable object (each object in set has to have a unique hash — sets do not store duplicate objects, as opposed to e.g. lists or tuples) • dictionaries can have only hashable objects as keys Containers – Ordered or Unordered Container object can store their content in either an ordered or unordered manner. Order, or lack of thereof, is unrelated to the mutability of objects. This means that both mutable and immutable objects can be either ordered or unordered. Examples of ordered containers include: • list, • string, • tuple, • bytes, • bytearrays, • array Examples of unordered containers include: • dictionary, • set, • frozenset. Introduction to language - containers Data type Mutable Ordered Literal example Constructor Sequence types list yes yes [1,2,3] list() tuple no yes (1,2,3) tuple() str no yes “text” / ‘text’ range no yes – range() bytes no yes b’abcde’ / b”abc” bytes() bytearray yes yes – bytearray() array * yes yes – array.array() set yes no {1,2,3} frozenset no no – yes no {“key1″: “val”, “key2″: “val”} str() Set types set() frozenset() Mapping types dict dict() Containers - Lists Lists are the most versatile of Python's compound data types. A list contains items separated by commas and enclosed within square brackets ([]). To some extent, lists are similar to arrays in C. One difference between them is that all the items belonging to a list can be of different data type. The values stored in a list can be accessed using the slice operator ( [ ] and [ : ] ) with indexes starting at 0 in the beginning of the list and working their way to end-1. The plus ( + ) sign is the list concatenation operator, and the asterisk ( * ) is the repetition operator. Lists: >>> a = [1, 2, 4, 8, 16] # list of ints >>> c = [4, 'candles', 4.0, 'handles'] # can mix types >>> c[1] 'candles' >>> c[2] = 'knife' >>> c[-1] # negative indices count from end 'handles' >>> c[1:3] # slicing ['candles', 'knife'] >>> c[2:] # omitting defaults to start or end ['knife', 'handles'] >>> c[0:4:2] # variable stride (could just write c[::2]) [4, 'knife'] >>> a + c # concatenate [1, 2, 4, 8, 16, 4, 'candles', 'knife', 'handles'] >>> len(a) 5 Lists Methods SN Function with Description SN Methods with Description 1 list.append(obj) Appends object obj to list 2 list.count(obj) Returns count of how many times obj occurs in list 1 cmp(list1, list2) Compares elements of both lists. 2 len(list) Gives the total length of the list. 3 max(list) Returns item from the list with max index. 3 list.extend(seq) Appends the contents of seq to list 4 min(list) Returns item from the list with min index. 4 5 list(seq) Converts a tuple into list. list.index(obj) Returns the lowest index in list that obj appears 5 list.insert(index, obj) Inserts object obj into list at offset index 6 list.pop(obj=list[-1]) Removes and returns last object or obj from list 7 list.remove(value) Removes object obj with value from list 8 list.reverse() Reverses objects of list in place 9 list.sort([func]) Sorts objects of list, use compare func if given List operations list1 = ['physics', 'chemistry', 1997, 2000] for item in L: print list1 print item del list1[2] print "After deleting value at index 2 : " for index, item in enumerate(L): print list1 print index, item L = [] #empty list i = iter(L) L = list() item = i.next() # fetch first value item = i.next() # fetch second value A = B = [] # both names will point to the same list A = [] stack = [] B = A # both names will point to the same list stack.append(object) # push A = []; B = [] # independent lists object = stack.pop() # pop from end queue = [] queue.append(object) # push object = queue.pop(0) # pop from beginning List Comprehension List comprehensions provide a concise way to create lists. Common applications are to make new lists where each element is the result of some operations applied to each member of another sequence or iterable, or to create a subsequence of those elements that satisfy a certain condition. >>> >>> ... ... >>> [0, squares = [] for x in range(10): squares.append(x**2) squares 1, 4, 9, 16, 25, 36, 49, 64, 81] squares = [x**2 for x in range(10)] Nested list comprehension >>> matrix = [ ... [1, 2, 3, 4], ... [5, 6, 7, 8], ... [9, 10, 11, 12], ... ] To transpose this matrix: >>> [[row[i] for row in matrix] for i in range(4)] [[1, 5, 9], [2, 6, 10], [3, 7, 11], [4, 8, 12]] Containers - Tuples A tuple is another sequence data type that is similar to the list. A tuple consists of a number of values separated by commas. Unlike lists, however, tuples are enclosed within parentheses. The main differences between lists and tuples are: Lists are enclosed in brackets ( [ ] ), and their elements and size can be changed, while tuples are enclosed in parentheses ( ( ) ) and cannot be updated. Tuples can be thought of as read-only lists. Tuples: >>> q = (1, 2, 4, 8, 16) # tuple of ints >>> r = (4, 'candles', 4.0, 'handles') # can mix types >>> s = ('lonely',) # singleton >>> t = () # empty >>> r[1] 'candles' >>> r[2] = 'knife' # cannot change tuples Traceback (most recent call last): File "<stdin>", line 1, in <module> TypeError: 'tuple' object does not support item assignment >>> u = 3, 2, 1 # parentheses not necessary >>> v, w = 'this', 'that' >>> v 'this' >>> w 'that' >>> >>> (3, >>> >>> >>> (4, >>> u = 3, 2,1 print u 2, 1) v= 4,6,7 w=v+u print w 6, 7, 3, 2, 1) Use of tuples def func(x,y): # code to compute x and y return (x,y) (x,y) = func(1,2) Python Expression Results Description len((1, 2, 3)) 3 Length (1, 2, 3) + (4, 5, 6) (1, 2, 3, 4, 5, 6) Concatenation ('Hi!',) * 4 ('Hi!', 'Hi!', 'Hi!', 'Hi!') Repetition 3 in (1, 2, 3) True Membership for x in (1, 2, 3): print x, 123 Iteration Tuple methods SN Function with Description 1 cmp(tuple1, tuple2) Compares elements of both tuples. 2 len(tuple) Gives the total length of the tuple. 3 max(tuple) Returns item from the tuple with max value. 4 min(tuple) Returns item from the tuple with min value. 5 tuple(seq) Converts a list into tuple. Note: Tuples have no append or extend methods, nor can you remove items as there are no remove or pop methods either. Containers - Sets A set is an unordered collection with no duplicate elements. Basic uses include membership testing and eliminating duplicate entries. Set objects also support mathematical operations like union, intersection, difference, and symmetric difference. >>> basket = ['apple', 'orange', 'apple', 'pear', 'orange', 'banana'] >>> fruit = set(basket) # create a set without duplicates >>> fruit set(['orange', 'pear', 'apple', 'banana']) >>> 'orange' in fruit # fast membership testing True >>> 'crabgrass' in fruit False >>> x = set("A Python Tutorial") >>> x set(['A', ' ', 'i', 'h', 'l', 'o', 'n', 'P', 'r', 'u', 't', 'a', 'y', 'T']) >>> type(x) <type 'set'> >>> Containers - Sets No mutable objects >>> cities = set((["Python","Perl"], ["Paris", "Berlin", "London"])) Traceback (most recent call last): File "<stdin>", line 1, in <module> TypeError: unhashable type: 'list' >>> But sets are mutable >>> cities = set(["Frankfurt", "Basel","Freiburg"]) >>> cities.add("Strasbourg") >>> cities set(['Freiburg', 'Basel', 'Frankfurt', 'Strasbourg']) >>> frozensets are immutable >>> cities = frozenset(["Frankfurt", "Basel","Freiburg"]) >>> cities.add("Strasbourg") Traceback (most recent call last): File "<stdin>", line 1, in <module> AttributeError: 'frozenset' object has no attribute 'add' >>> Sets - operations No mutable objects >>> a = set('abracadabra') >>> b = set('alacazam') >>> a # unique letters in a set(['a', 'r', 'b', 'c', 'd']) >>> a - b # letters in a but not in b set(['r', 'd', 'b']) >>> a | b # letters in either a or b set(['a', 'c', 'r', 'd', 'b', 'm', 'z', 'l']) >>> a & b # letters in both a and b set(['a', 'c']) >>> a ^ b # letters in a or b but not both set(['r', 'd', 'b', 'm', 'z', 'l']) frozensets are immutable >>> cities = frozenset(["Frankfurt", "Basel","Freiburg"]) >>> cities.add("Strasbourg") Traceback (most recent call last): File "<stdin>", line 1, in <module> AttributeError: 'frozenset' object has no attribute 'add' >>> Sets - operations SN Methods with Description SN Methods with Description 1 set.add(obj) Adds object obj to set 8 2 set.clear(obj) removes all objects from a set 3 set.copy () Creates a shallow copy of a set set.intersection(set) Returns the intersection of the instance set and the set s as a new set. In other words: A set with all the elements which are contained in both sets is returned. 9 4 set.difference(set) Returns the difference of two or more sets as a new set. set.isdisjoint(ser) This method returns True if two sets have a null intersection. 10 set.difference_uodate(set) Removes all elements of another set from this set. x.difference_update() is the same as "x = x - y" set.issubset(set) x.issubset(y) returns True, if x is a subset of y. "<=" is an abbreviation for "Subset of" 11 set.issuperset(obj) x.issuperset(y) returns True, if x is a superset of y. ">=" is an abbreviation for "issuperset of" 12 set.pop() pop() removes and returns an arbitrary set element. The method raises a KeyError if the set is empty 5 6 set.discard(obj) Removes obj from the set 7 set.remove(value) Works like discard(), but if el is not a member of the set, a KeyError will be raised. Containers - Dictionaries Python 's dictionaries are hash table type. They work like associative arrays or hashes found in Perl and consist of key-value pairs. Keys can be almost any Python type, but are usually numbers or strings. Values, on the other hand, can be any arbitrary Python object. Dictionaries are enclosed by curly braces ( { } ) and values can be assigned and accessed using square braces ( [] ). Dictionaries: >>> a = {'eyecolour': 'blue', 'height': 152.0, 42: 'the answer'} >>> a['age'] = 28 >>> a {42: 'the answer', 'age': 28, 'eyecolour': 'blue', 'height': 152.0} >>> del(a['height']) >>> a {42: 'the answer', 'age': 28, 'eyecolour': 'blue'} >>> b = {} >>> b['hello'] = 'Hi! ' >>> a.keys() [42, 'age’, 'eyecolour’] >>> a.values() ['the answer', 28, 'blue'] Dictionary use >>> colors = { "blue": (0x30,0x30,0xff), "green": (0x30,0xff,0x97), ... "red": (0xff,0x30,0x97), "yellow": (0xff,0xff,0x30) } >>> for c in colors: ... print c, colors[c] en_ne = {"red" : "rood", "green" : "groen", "blue" : "blauw", "yellow":"geel"} print en_ne["red"] ne_fr = {"rood" : "rouge", "groen" : "vert", "blauw" : "bleu", "geel":"jaune"} print "The French word for red is: " + ne_fr[en_ne["red"]] >>> dic = { [1,2,3]:"abc"} Traceback (most recent call last): File "<stdin>", line 1, in <module> TypeError: list objects are unhashable >>> dic = { (1,2,3):"abc", 3.1415:"abc"} >>> dic {(1, 2, 3): 'abc'} dictionaries = {"en_ne" : en_ne, "ne_fr" : ne_fr } print dictionaries["ne_fr"]["blauw"] Dictionary methods SN Function with Description SN Methods with Description 1 cmp(dict1, dict2) Compares elements of both dict. 1 dict.clear() Removes all elements of dictionary dict 2 len(dict) Gives the total length of the dictionary. This would be equal to the number of items in the dictionary. 2 dict.copy() Returns a shallow copy of dictionary dict 2 dict.fromkeys() Create a new dictionary with keys from seq and values set to value. 3 dict.get(key, default=None) For key key, returns value or default if key not in dictionary 4 dict.has_key(key) Returns true if key in dictionary dict, false otherwise 5 dict.items() Returns a list of dict's (key, value) tuple pairs 6 dict.keys() Returns list of dictionary dict's keys 7 dict.setdefault(key, default=None) Similar to get(), but will set dict[key]=default if key is not already in dict 8 dict.update(dict2) Adds dictionary dict2's key-values pairs to dict 9 dict.values() Returns list of dictionary dict2's values 3 str(dict) Produces a printable string representation of a dictionary 4 type(variable) Returns the type of the passed variable. If passed variable is dictionary then it would return a dictionary type. Dictionary operations for key, value in someDictionary.items(): # process key and value for value in someDictionary.values(): # process the value >>> i = { "two":2, "three":3, "quatro":4 } >>> del i["quatro"] >>> i {'two': 2, 'three': 3} >>> i = { "two":2, "three":3, "quatro":4 } >>> i.pop("quatro") 4 >>> i {'two': 2, 'three': 3} # zipping two lists into a dictionary >>> dishes = ["pizza", "sauerkraut", "paella", "Hamburger"] >>> countries = ["Italy", "Germany", "Spain", "USA"] >>> country_specialities_dict = dict(country_specialities) >>> print country_specialities_dict {'Germany': 'sauerkraut', 'Spain': 'paella', 'Italy': 'pizza', 'USA': 'Hamburger'} Type Conversions Function int(x [,base]) Description Converts x to an integer. base specifies the base if x is a string. long(x [,base] ) float(x) Converts x to a long integer. base specifies the base if x is a string. Converts x to a floating-point number. complex(real [,imag]) str(x) Creates a complex number. Converts object x to a string representation. repr(x) eval(str) Converts object x to an expression string. Evaluates a string and returns an object. tuple(s) list(s) set(s) dict(d) Converts s to a tuple. Converts s to a list. Converts s to a set. Creates a dictionary. d must be a sequence of (key,value) tuples. frozenset(s) chr(x) unichr(x) Converts s to a frozen set. Converts an integer to a character. Converts an integer to a Unicode character. ord(x) Converts a single character to its integer value. hex(x) oct(x) Converts an integer to a hexadecimal string. Converts an integer to an octal string. Shallow and Deep copy Python creates real copies only if it has to, i.e. if the user, the programmer, explicitly demands it. # Expected behaviour >> colours1 = ["red", "green"] >>> colours2 = colours1 >>> colours2 = ["rouge", "vert"] >>> print colours1 ['red', 'green'] # Watch OUT! >>> colours1 = ["red", "green"] >>> colours2 = colours1 >>> colours2[1] = "blue" >>> colours1 ['red', 'blue'] # Force to copy >>> list1 = ['a','b','c','d'] >>> list2 = list1[:] >>> list2[1] = 'x' >>> print list2 ['a', 'x', 'c', 'd'] >>> print list1 ['a', 'b', 'c', 'd'] >>> # But be carefull with sublists! >>> lst1 = ['a','b',['ab','ba']] >>> lst2 = lst1[:] >>> lst2[0] = 'c' >>> lst2[2][1] = 'd' >>> print(lst1) ['a', 'b', ['ab', 'd']] Shallow and Deep copy Special module copy allows for deepcopy of the whole object >>> from copy import deepcopy >>> >>> lst1 = ['a','b',['ab','ba']] >>> >>> lst2 = deepcopy(lst1) >>> >>> lst2[2][1] = "d" >>> lst2[0] = "c"; >>> >>> print lst2 ['c', 'b', ['ab', 'd']] >>> print lst1 ['a', 'b', ['ab', 'ba']] >>> Logical Operators End