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--- lfa:lab01-python-intro [2021/09/08 11:21]
pdmatei
+++ lfa:lab01-python-intro [2021/10/07 11:32] (current)
ioana.georgescu [List comprehensions]
@@ Line 12: / Line 12: @@
 ==== List traversal ====
-**1.1.** Write a function ''f(l)'' which determines the maximum of a list ''l'' of integers.
+**Exercise 1.1.** Write a function ''f(l)'' which determines the maximum of a list ''l'' of integers.
 <hidden The pythonic way>
@@ Line 23: / Line 23: @@
 </hidden>
-**1.2.** Modify the previous function to ''f(l,start,stop)'' and determine the maximum between positions ''start'' and ''stop''.
+**Exercise 1.2.** Modify the previous function to ''f(l,start,stop)'' and determine the maximum between positions ''start'' and ''stop''.
 <hidden The pythonic way>
@@ Line 35: / Line 35: @@
 ==== Slicing lists ====
-**1.3.** Find the **longest** sequence of positive integers from a list. E.g. for the list ''[1,3,-1,2,0,1,5,4,-2,4,5,-3,0,1,2]'' the answer is ''[2,0,1,5,4]''.
+**Exercise 1.3.** Find the **longest** sequence of positive integers from a list. E.g. for the list ''[1,3,-1,2,0,1,5,4,-2,4,5,-3,0,1,2]'' the answer is ''[2,0,1,5,4]''.
 <hidden The pythonic way>
@@ Line 45: / Line 45: @@
 l[:x]
 # the last element of a list:
-l[:-1]
+l[-1]
 # the last three elements of a list:
-l[:-3]
+l[-3:]
 # the slice from n-3 to n-1, where n is the number of elements from the list
 l[-3:-1]
@@ Line 53: / Line 53: @@
 </hidden>
-**1.4.** Write a pythonic function to check if a list is palindrome.
+**Exercise 1.4.** Write a pythonic function to check if a list is palindrome.
 ===== Other datatypes =====
@@ Line 69: / Line 69: @@
 </code>
-**1.5.** Write a function which determines (and returns) the **longest** sequence of consecutive integers from a list.
+**Exercise 1.5.** Write a function which determines (and returns) the **longest** sequence of consecutive integers from a list.
 ==== Dictionaries ====
@@ Line 87: / Line 87: @@
 </code>
-**1.6.** Write a function which determines the number of occurrences of each character in a string.
+**Exercise 1.6.** Write a function which determines the number of occurrences of each character in a string.
 <hidden The pythonic way>
 <code python>
@@ Line 115: / Line 115: @@
 </code>
-**1.7.** Determine the list of characters which occur in a string. E.g. for "limbajeformale" we have: "limbajefor". (Hint 1: in Python there is no difference between a character and a singleton string and strings are just lists; Hint 2: to create a list from another object, use ''list()'').
+**Exercise 1.7.** Determine the list of characters which occur in a string. E.g. for "limbajeformale" we have: "limbajefor". (Hint 1: in Python there is no difference between a character and a singleton string and strings are just lists; Hint 2: to create a list from another object, use ''list()'').
 ==== Pairs ====
@@ Line 140: / Line 140: @@
 from functools import reduce
+# adds 1 to each element of a list
 def allplus1(l):
    return map(lambda x:x+1,l)
+# computes the sum of elements of a list
 def sum_l (l):
    # inner functions are very useful for defining local, reusable functionality
@@ Line 155: / Line 157: @@
 ==== List comprehensions ====
-**1.8.** Write a function which takes a list of records //first name, last name, CNP// (encoded as tuples), and returns a list of **the last names** of all females having the age **below** the average of all ages. E.g. ''[ ("Mary", "Smith", 2030694123456), ("Anne", "Doe", 2121092123456), ("Matei", "Dan", 1121202123456), ("Maggie", "Byrne", 2121078123456)]'' yields ''["Smith", "Doe"]''. Maggie was born in '78
+List comprehensions are widely used programming tools in Python. Usage examples:
+<code python>
+# adding 1 to each element of a list
+l1 = [x+1 for x in [1,2,3]]
+# [2,3,4]
-Inner functions
+# packing elements into pairs
-List comprehensions, filters
+l2 = [(x,x+1) for x in [1,2,3]]
-Classes and inheritance, instance-of
+# [(1,2), (2,3), (3,4)]
-toString
-Higher-order functions and lambdas
-Unpacking (for tuples, lists)
+# unpacking pairs in the for notation
+l3 = [x+y for (x,y) in [(1,2), (2,3), (3,4)]]
+# [3,5,7]
-<hidden The Pythonic way> This text will be hidden <code python> solution </code> </hidden>
+# combined list comprehensions
+l4 = [(x,y) for x in [1,2,3] for y in [4,5,6]]
+# [(1, 4), (1, 5), (1, 6), (2, 4), (2, 5), (2, 6), (3, 4), (3, 5), (3, 6)]
+# filters
+l5 = [x for x in [1,2,3,4] if x>2]
+# [3,4]
+</code>
+**Exercise 1.8.** Write a function which takes a list of records //first name, last name, CNP// (encoded as tuples), and returns a list of **the last names** and **ages** of all females which are younger than the average of the entire list. E.g. ''[ ("Mary", "Smith", "2030602123456"), ("Anne", "Doe", "2121092123456"), ("Matei", "Dan", "1121202123456"), ("Maggie", "Byrne", "2121078123456")]'' yields ''[("Smith",19), ("Doe",29)]''. Maggie was born in '78, whereas Mary, Anne and Matei were born in '94, '92 and 2002, respectively.
-**Exercise 6** Write a function which searches for a list of patterns in a text.
+<hidden The pythonic way>
 <code python>
-def find_patterns (pattern_list, text):
+from functools import reduce
-    # checks if pattern is found at position index in text
-    def inner_search (pattern,index):
-</code>
-Remark:
+def getYouth(l):
-  * Python supports functional-style programming to some extent.
+	# this function computes the age of a given CNP
-<code python>
+    def age(cnp):
-def plus1(x):
+        # conversion to integer of the two-character year code
-    return x + 1
+        if int(cnp[5:8]) <= 21:
+            return 2021 - int("20"+cnp[5:7])
+        else:
+            return 2021 - int("19"+cnp[5:7])
-print(map(plus1,[1,2,3]))
+    # computing the average ages (a map could have also been used)
-print(map(lambda x:x+1, [1,2,3]))
+    avg = reduce(lambda a,b:a+b, [age(x[-1]) for x in l]) / len(l)
+    # we return the last name and the age of the filtered list l
+    return [(ln,age(cnp)) for (fn,ln,cnp) in l if cnp[0]=='2' and age(cnp) <= avg]
 </code>
+</hidden>
-**Exercise 8** Modify the previous implementation and instead of ''for'', use ''map'' (cast the return of ''map'' to ''list'': ''list(map(...))'')
-However, it is more common in Python to employ //list comprehensions// instead of ''map'':
-<code python>
-def plus1(x):
-    return x + 1
-print([plus1(x) for x in [1,2,3]])
-print([(x + 1) for x in [1,2,3]]))
-</code>
-List comprehensions also support the functionality of ''filter'':
-<code python>
-print([(x+1) for x in [1,2,3,4,5,6] if (x % 2 == 0)])
-</code>
-**Exercise 9** Modify the previous implementation and instead of ''for'', use list comprehensions.
+/*
 ==== Classes and inheritance ====
@@ Line 272: / Line 279: @@
   * Extend the class example shown previously to include class ''Node'' which models non-empty trees. Implement methods ''size'' and ''contains''.
+*/
+===== Practice =====
+A labelled graph is encoded as a file where:
+  * **the first line** consists of the number of nodes
+  * **each subsequent line** is an edge ''<from> <label> <to>''
+Example:
+<code>
+X 1
+O 2
+X 3
+O 4
+X 1
+O 2
+</code>
+  * Suppose we encode streets as labelled graphs, where each label 'X' or 'O' denotes if a street is closed or open.
+  * Compute the set of accessible nodes from a given **source**, via open streets.
+  * (Hint1: google //Python read lines// to see how to read from a file; also, google ''split'' in Python)
+  * (Hint2: you will need a dictionary to store, for each node and label l, the list of its l-successors)
+===== Haskell practice =====
+Solve the same exercise, only build your own input as a string, instead of a file.