Announcements

Announcements • No Labs / Recitation this week • On Friday we will talk about Project 3 • Release late afternoon / evening tomorrow • Cryptography

Midterm Curve • 0-35 D • 36-39 C- • 40-50 C • 51-55 C+ • 56-59 B- • 60-68 B • 69-74 B+ • 75-79 A- • 80-100 A

Data Structures • More List Methods • Our first encoding • Matrix

CQ:Are these programs equivalent? 1 2 b = [‘h’,’e’,’l’,’l’,’o’] b.insert(len(b), “w”) print(b) b = [‘h’,’e’,’l’,’l’,’o’] b.append(“w”) print(b) A: yes B: no

Advanced List Operations • L = [0, 1, 2, 0] • L.reverse() • print(L) will print: [0, 2, 1, 0] • L.remove(0) • print(L) will print: [2, 1, 0] • L.remove(0) • print(L) will print: [2, 1] • print (L.index(2)) will print 0

Why are Lists useful? • They provide a mechanism for creating a collection of items defdoubleList(b): i = 0 whilei < len(b): b[i] = 2 * b[i] i = i +1 return (b) print(doubleList([1,2,3]))

Using Lists to Create Our Own Encodings • Python provides a number of encodings for us: • Binary, ASCII, Unicode, RGB, Pictures etc. • We know the basic building blocks, but we are still missing something … • We need to be able to create our own encodings What if I want to write a program that operates on proteins?

Under the hood: what is a matrix? • A matrix is not “pre defined” in python • We “construct” a way to encode a matrix through the use of lists • We will see how to do so using a single list (not ideal) • We will see how to do so using a list of lists • Two different ways • Row by Row • Column by Column 1 2 3 4 ( )

Lists • Suppose we wanted to extract the value 3 • The first set of [] get the array in position 1 of y. The second [] is selecting the element in position 2 of that array. This is equiv. to: y =[“ABCD”, [1,2,3] , ”CD”, ”D”] y[1][2] z = y[1] z[2]

Lets make it more concrete! • Lets revisit encoding a matrix • Lets try something simple: • A = [1, -1, 0, 2] • B = [1, 0, 0, 0.5, 3, 4, -1, -3, 6]

Does this work? • We lose a bit of information in this encoding • Which numbers correspond to which row • We can explicitly keep track of rows through a row length variable • B = [1, 0, 0, 0.5, 3, 4, -1, -3, 6] • rowLength = 3 • B[rowLength*y +x]

Lets convince ourselves • B = [1, 0, 0, 0.5, 3, 4, -1, -3, 6] • rowLength = 3 • B[rowLength*y +x] x = 0 y = 0 B[3*0 + 0] x = 1 y = 1 B[3*1 + 1] x = 2 y = 1 B[3*1 + 2]

Can we encode it another way? • We can encode column by column, but we lose some information again • Which numbers correspond to which column • We can explicitly keep track of columns through a column length variable • B = [1, 0.5, -1, 0, 3, -3, 0, 4, 6] • columnLength = 3 • B[columnLength*x + y]

Lets convince ourselves • B = [1, 0.5, -1, 0, 3, -3, 0, 4, 6] • columnLength = 3 • B[columnLength*x + y] x = 0 y = 0 B[3*0 + 0] x = 1 y = 1 B[3*1 + 1] x = 2 y = 1 B[3*2 + 1]

Lists of Lists • Recall that when we had a string in our list • B = [“ABCD”, 0, 1, 3] • We could utilize the bracket syntax multiple times • print B[0][1] would print B • Lists can store other Lists • B = [[0, 1, 3], 4, 5, 6]

Another way to encode a Matrix • Lets take a look at our example matrix • What about this? • B= [[1, 0, 0], [0.5, 3, 4], [-1, -3, 6]]

Why is this important? • We can now write code that more closely resembles mathematical notation • i.e., we can use x and y to index into our matrix • B = [[1, 0, 0], [0.5, 3, 4], [-1, -3, 6]] • for x in range(3): • for y in range(3): • print (B[x][y])

…but first some more notation • We can use the “*” to create a multi element sequence • 6 * [0] results in a sequence of 6 0’s • [0, 0, 0, 0, 0, 0] • 3 * [0, 0] results in a sequence of 6 0’s • [0, 0, 0, 0, 0, 0] • 10 * [0, 1, 2] results in what?

What is going on under the hood? • Lets leverage some algebraic properties • 3 * [0, 0] is another way to write • [0, 0] + [0, 0] + [0, 0] • We know that “+” concatenates two sequences together

What about lists of lists? • We have another syntax for creating lists • [ X for i in range(y)] • This creates a list with y elements of X • Example: [ 0 fori in range(6)] ≡ [0]*6 • [0, 0 ,0 ,0 ,0 ,0] • Example: [[0, 0] fori in range(3)] ≡ [[0,0]]*3 • [[0, 0], [0, 0], [0, 0]] • What does this does: [2*[0] fori in range(3)]?

Lets put it all together • m1 = [ [1, 2, 3, 0], [4, 5, 6, 0], [7, 8, 9, 0] ] • m2 = [ [2, 4, 6, 0], [1, 3, 5, 0], [0, -1, -2, 0] ] • m3= [ 4*[0] for i in range(3) ] • for x in range(3): • fory in range(4): • m3[x][y]= m1[x][y]+m2[x][y]

Data structures • We have constructed our first data structure! • As the name implies, we have given structure to the data • The data corresponds to the elements in the matrix • The structure is a list of lists • The structure allows us to utilize math-like notation

Homework • Read through the entire project description when it becomes available

Announcements: Project 3 • Taking a look at cryptography Message -> Encrypted Message -> Message Encryption Decryption

Shift Cipher • How many possible elements do we have? • Answer: 95 printable characters • What happens if we shift something more than 95 positions? • Answer: we need to loop around (shifting 99 is the same as shifting 4) • What happens if we shift by a negative shift? • Answer: we can modify a negative shift into a positive shift

Simple Example • Consider if we had 4 options: “A” “B” “C” “D” • Assume encoding for “A” is 0, “B” is 1, “C” is 2, and “D” is 3 • Shifting “A” by 2 yields “C” (0+2) • Shifting “B” by 2 yields “D” (1+2) • Shifting “C” by 2 yields “A” (2+2) ? • Shifting “D” by 2 yields “D” (3+2)?

Modular Arithmetic • Modular arithmetic allows us to count “in circles” • 0 mod 4 = 0 • 1 mod 4 = 1 • 2 mod 4 = 2 • 3 mod 4 = 3 • 4 mod 4 = 0 • 5 mod 4 = 1 • 6 mod 4 = 2 • 7 mod 4 = 3

Simple Example • Consider if we had 4 options: “A” “B” “C” “D” • Assume encoding for “A” is 0, “B” is 1, “C” is 2, and “D” is 3 • Shifting “A” by 2 yields “C” (0+2) mod 4 = 2 • Shifting “B” by 2 yields “D” (1+2) mod 4 = 3 • Shifting “C” by 2 yields “A” (2+2) mod 4 = 0 • Shifting “D” by 2 yields “B” (3+2) mod 4 = 1

Negative Shifts? • Lets think about negative shifts … conceptually we just “go the other way” • “D” shifted by -1 is “C” (3-1) mod 4 = 2 • “C” shifted by -1 is “B” (2-1) mod 4 = 1 • Observe that since we are effectively moving in a circle, a negative shift can be expressed as a positive shift • “D” shifted by 3 is “C” (3 + 3) mod 4 = 2 • “C” shifted by 3 is “B” (2 + 3) mod 4 = 1

What about large negative shifts? • Observe that shifting -10 is equivalent to shifting -2 • Why? We shift 2 times around our “circle” of letters and then need to shift -2 additional letters • Notice that both shifting -10 and shifting -2 are equivalent to shifting 2 • -10 mod 4 = 2 • -2 mod 4 = 2 • Notice that we can compute a positive shift from a negative shift by: shift modulo the total number of elements

Clicker Question: did we encode the same matrix in both programs? 1 2 [[1, 2], [3, 4]] [[1, 3], [2, 4]] A: yes B: no C: maybe

Lets explore why it depends 1 2 [[1, 2], [3, 4]] [[1, 3], [2, 4]] 1 2 3 4 1 3 2 4 ( ) ( ) Both lists of lists can either be a row by row or a column by column encoding

Let us encode something else using lists!

We call this structure a tree Root Root

How might we encode such a structure? • What structures do we know of in python? • Strings, Ranges, Lists • We know that lists allow us to encode complex structures via sub lists • We used sub list to encode either a row or a column in the matrix • We used an ‘outer’ list of rows or columns as a matrix

Can we use the same strategy? • How might we encode a simple tree? Root Leaf1 Leaf2 Leaf3 Tree = [‘Leaf1’, ‘Leaf2’, ‘Leaf3’]

Trees can be more complex Root Leaf1 Leaf2 Leaf3 Leaf4 Leaf5 Tree = [‘Leaf1’, ‘Leaf2’, [‘Leaf3’, ‘Leaf4’, ‘Leaf5’]]

Trees can be more complex Root Leaf2 Leaf0 Leaf1 Leaf3 Leaf4 Leaf5 Tree = [[‘Leaf0’,‘Leaf1’], ‘Leaf2’, [‘Leaf3’, ‘Leaf4’, ‘Leaf5’]]

Trees can be more complex Root Leaf2 Leaf0 Leaf1 Leaf3 Leaf4 Leaf5 Leaf6 Tree = [[‘Leaf0’,‘Leaf1’], ‘Leaf2’, [‘Leaf3’, ‘Leaf4’, [‘Leaf5’, ‘Leaf6’]]]

What is the intuition • Each sub list encodes the ‘branches’ of the tree • We can think of each sub list as a ‘sub tree’ • We can use indexes (the bracket notation []) to select out elements or ‘sub trees’

How can we select out the leaves? Root Leaf1 Tree[0] Leaf2 Tree[1] Leaf3 Tree[2] Tree = [‘Leaf1’, ‘Leaf2’, ‘Leaf3’]

Indexes provide us a way to “traverse” the tree Root 1 2 0 Leaf2 0 1 0 1 2 Leaf0 Leaf1 Leaf3 Leaf4 0 1 Leaf5 Leaf6 Tree = [[‘Leaf0’,‘Leaf1’], ‘Leaf2’, [‘Leaf3’, ‘Leaf4’, [‘Leaf5’, ‘Leaf6’]]]

Indexes provide us a way to “traverse” the tree Root 1 2 0 Leaf2 0 1 0 1 2 Leaf0 Leaf1 Leaf3 Leaf4 0 1 Leaf5 Leaf6 Tree = [[‘Leaf0’,‘Leaf1’], ‘Leaf2’, [‘Leaf3’, ‘Leaf4’, [‘Leaf5’, ‘Leaf6’]]] Tree[2]

Indexes provide us a way to “traverse” the tree Root 1 2 0 Leaf2 0 1 0 1 2 Leaf0 Leaf1 Leaf3 Leaf4 0 1 Leaf5 Leaf6 Tree = [[‘Leaf0’,‘Leaf1’], ‘Leaf2’, [‘Leaf3’, ‘Leaf4’, [‘Leaf5’, ‘Leaf6’]]] Tree[2][2]

Indexes provide us a way to “traverse” the tree Root 1 2 0 Leaf2 0 1 0 1 2 Leaf0 Leaf1 Leaf3 Leaf4 0 1 Leaf5 Leaf6 Tree = [[‘Leaf0’,‘Leaf1’], ‘Leaf2’, [‘Leaf3’, ‘Leaf4’, [‘Leaf5’, ‘Leaf6’]]] Tree[2][2][1]

CQ: How do we select ‘Leaf4’ from the Tree? Tree = [[‘Leaf0’,‘Leaf1’], ‘Leaf2’, [‘Leaf3’, ‘Leaf4’, [‘Leaf5’, ‘Leaf6’]]] A: Tree[2][1] B: Tree[3][2] C: Tree[1][2]

Operations on Trees • Trees, since they are encoded via lists support the same operations lists support • We can “+” two trees • We can embedded two trees within a list • This creates a larger tree with each of the smaller trees as sub trees • Example: • Tree1 = [‘Leaf1’, ‘Leaf2’] • Tree2 = [‘Leaf3’, ‘Leaf4’] • Tree = [Tree1, Tree2]

“+” two trees Leaf2 Leaf0 Leaf1 Leaf3 Leaf4 Leaf5 Leaf6 Tree1 = [[‘Leaf0’, ‘Leaf1’]] Tree2 = [‘Leaf2’] Tree3 = [[‘Leaf3’, ‘Leaf4’, [‘Leaf5’, ‘Leaf6’]]]

“+” two trees Leaf2 Leaf0 Leaf1 Leaf3 Leaf4 Leaf5 Leaf6 Tree1 = [[‘Leaf0’, ‘Leaf1’]] Tree2 = [‘Leaf2’] Tree4 = Tree1+Tree2 [[‘Leaf0’, ‘Leaf1’], ‘Leaf2’]

“+” two trees Leaf2 Leaf0 Leaf1 Leaf3 Leaf4 Leaf5 Leaf6 Tree4 = [[‘Leaf0’, ‘Leaf1’], ‘Leaf2’] Tree3 = [[‘Leaf3’, ‘Leaf4’, [‘Leaf5’, ‘Leaf6’]]] Tree = Tree4+Tree3

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