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snick snack CPSC 121: Models of Computation 2008/9 Winter Term 2 Functions Steve Wolfman, based on notes by Patrice Belleville and others
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Lecture Prerequisites Read Section 7.1. Solve problems like Exercise Set 7.1, #1-4, 13-14, 23-24.
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Learning Goals: Pre-Class By the start of class, you should be able to: –Define the terms domain, co-domain, range, image, and pre-image –Use appropriate function syntax to relate these terms (e.g., f : A B indicates that f is a function mapping domain A to co- domain B ). –Determine whether f : A B is a function given a definition for f as an equation or arrow diagram.
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Learning Goals: In-Class By the end of this unit, you should be able to: –Define the terms injective (one-to-one), surjective (onto), bijective (one-to-one correspondence), and inverse. –Determine whether a given function is injective, surjective, and/or bijective. –Apply your proof skills to proofs about the properties (e.g., injectiveness, surjectiveness, bijectiveness, and function-ness) of functions and their inverses.
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Outline Functions as “Computation Abstractions” Definition of Functions and Function Terminology Function Properties –Injective –Surjective –Bijective Function Operations –Inverse –Composition Dropped from learning goals and exam.
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What is this? control data1 data2 output
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What is this? control data1 data2 output
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What is this? control data1 data2 output
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What is this? control data1 data2 output In the lab, you implemented a multiplexer and then used it as a piece in larger circuits. You abstracted from the concrete implementation to a description of its function: f(control, data1, data2) = output = (~control data1) (control data2) = data1 if control is 0, but data2 otherwise
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Functions, Abstraction, and CPSC 121 Computer scientists use many abstraction levels, with reasoning and often execution tools at each level. In 121, we learn tools for some key abstraction levels: wiring physical gates, computer-based hardware design techniques, propositional logic, predicate logic, sets, … Functions are a new level that let us talk about how computations work and fit together. Bonus: functions alone are enough for all of computation, using the “λ calculus”.
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Outline Functions as “Computation Abstractions” Definition of Functions and Function Terminology Function Properties –Injective –Surjective –Bijective Function Operations –Inverse –Composition
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What is a Function? Mostly, a function is what you learned it was all through K-12 mathematics, with strange vocabulary to make it more interesting… A function f:A B maps values from its domain A to its co-domain B. Domain Co-domain f(x) = x 3 f(x) = x mod 4 f(x) = x Look, sets! CORRESPONDS TO TEXTBOOK READING (NOT COVERED IN CLASS)
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What is a Function? Mostly, a function is what you learned it was all through K-12 mathematics, with strange vocabulary to make it more interesting… A function f:A B maps values from its domain A to its co-domain B. Domain Co-domain f(x) = x 3 R or Z or... R or Z or... f(x) = x mod 4 Z or Z + or... Z or Z + or... f(x) = x R or R + or... Z or Z + or... CORRESPONDS TO TEXTBOOK READING (NOT COVERED IN CLASS)
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Plotting Functions f(x) = x 3 f(x) = x mod 4 f(x) = x Not every function is easy to plot! CORRESPONDS TO TEXTBOOK READING (NOT COVERED IN CLASS)
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Plotting Functions f(x) = x 3 f(x) = x mod 4 f(x) = x Not every function is easy to plot! CORRESPONDS TO TEXTBOOK READING (NOT COVERED IN CLASS)
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What is a Function? Not every function has to do with numbers… A function f:A B maps values from its domain A to its co-domain B. Domain Co-domain f(x) = ~x f(x,y) = x y f(x) = x ’s phone # CORRESPONDS TO TEXTBOOK READING (NOT COVERED IN CLASS)
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What is a Function? Not every function has to do with numbers… A function f:A B maps values from its domain A to its co-domain B. Domain Co-domain f(x) = ~x{T, F} {T, F} f(x,y) = x y{T,F} {T,F}{T, F} f(x) = x ’s phone #Set of people?10-dig #s? CORRESPONDS TO TEXTBOOK READING (NOT COVERED IN CLASS)
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What is a Function? A function f:A B maps values from its domain A to its co-domain B. f(control, data1, data2) = (~control data1) (control data2) Domain? Co-domain? CORRESPONDS TO TEXTBOOK READING (NOT COVERED IN CLASS)
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What is a Function? A function f:A B maps values from its domain A to its co-domain B. f(control, data1, data2) = (~control data1) (control data2) Let B = {T,F} : Domain? B B B Co-domain? B CORRESPONDS TO TEXTBOOK READING (NOT COVERED IN CLASS)
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What is a Function? A function f:A B maps values from its domain A to its co-domain B. Domain? Co-domain? Other examples? Alan Steve Paul Patrice Karon George 111 121 211 CORRESPONDS TO TEXTBOOK READING (NOT COVERED IN CLASS)
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What is a Function? A function f:A B maps values from its domain A to its co-domain B. Domain? {Alan, Steve, Paul, Patrice, Karon, George} Co-domain? {111, 121, 211} Other examples? Alan Steve Paul Patrice Karon George 111 121 211 CORRESPONDS TO TEXTBOOK READING (NOT COVERED IN CLASS)
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What is a Function? A function f:A B maps values from its domain A to its co-domain B. f can’t map one element of its domain to more than one element of its co-domain: x A, y 1,y 2 B, [(f(x) = y 1 ) (f(x) = y 2 )] (y 1 = y 2 ). Why insist on this? A B f CORRESPONDS TO TEXTBOOK READING (NOT COVERED IN CLASS)
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What is a Function? A function f:A B maps values from its domain A to its co-domain B. f can’t map one element of its domain to more than one element of its co-domain: x A, y 1,y 2 B, [(f(x) = y 1 ) (f(x) = y 2 )] (y 1 = y 2 ). Why insist on this? Why not? We give a different name (relation) to things that do. A B f CORRESPONDS TO TEXTBOOK READING (NOT COVERED IN CLASS)
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Not a Function Why isn’t this a function? (The Laffer Curve: a non-functional tax policy.) CORRESPONDS TO TEXTBOOK READING (NOT COVERED IN CLASS)
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Not a Function Why isn’t this a function? (The Laffer Curve: a non-functional tax policy.) CORRESPONDS TO TEXTBOOK READING (NOT COVERED IN CLASS) x There is some single value x such that f(x) has more than one value. It may also be true that there is a value y such that f(y) has no value (depending on f’s domain!).
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Function Terminology A function f:A B maps values from its domain A to its co-domain B. For f to be a function, it must map every element in its domain: x A, y B, f(x) = y. Why insist on this? A B f Warning: some mathematicians would say that makes f “total”. CORRESPONDS TO TEXTBOOK READING (NOT COVERED IN CLASS)
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Function Terminology A function f:A B maps values from its domain A to its co-domain B. For f to be a function, it must map every element in its domain: x A, y B, f(x) = y. Why insist on this? This proves handy in some later definitions. A B f CORRESPONDS TO TEXTBOOK READING (NOT COVERED IN CLASS)
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Not a Function Foiled by sabbatical. Alan Steve Paul Patrice Karon George 111 121 211 Anne CORRESPONDS TO TEXTBOOK READING (NOT COVERED IN CLASS)
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Not a Function Anne does not map to anything: not a function. Alan Steve Paul Patrice Karon George 111 121 211 Anne CORRESPONDS TO TEXTBOOK READING (NOT COVERED IN CLASS)
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Function Terminology A function f:A B maps values from its domain A to its co-domain B. f(x) is called the image of x (under f ). x is called the pre-image of f(x) (under f ). A B f x y CORRESPONDS TO TEXTBOOK READING (NOT COVERED IN CLASS)
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Function Terminology A function f:A B maps values from its domain A to its co-domain B. The range of f is the set of all images of elements of f ’s domain. In other words: { f(x) | x A } A B f x y Which is clearer, the English or the logic? CORRESPONDS TO TEXTBOOK READING (NOT COVERED IN CLASS)
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Trying out Terminology f(x) = x 2 What is the image of 16? What is the range of f ? x f(x) CORRESPONDS TO TEXTBOOK READING (NOT COVERED IN CLASS)
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Trying out Terminology f(x) = x 2 What is the image of 16? f(16) = 16 2 = 256 What is the range of f ? R 0 (assuming the domain is R ) x f(x) CORRESPONDS TO TEXTBOOK READING (NOT COVERED IN CLASS)
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Functions We’ve Used Any combinational logic circuit The “inverse” and “zip” operations over algorithms from the midterm The operation that gives you a student’s grade given the student: G(s) = s’s grade Arrays, as long as they’re immutable (unchangeable): A(i) = the i th value in array A. Sequential circuits and mutable arrays aren’t functions. Why not? (Actually we can model them as functions by making time explicit)
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Outline Functions as “Computation Abstractions” Definition of Functions and Function Terminology Function Properties –Injective –Surjective –Bijective Function Operations –Inverse –Composition
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Function Properties: Injective A function f:A B is injective (also one- to-one) if each image is associated with at most one pre-image: x,y A, x y f(x) f(y). Alan Steve Paul Patrice Karon George 111 121 211 Alan Steve Paul Patrice Karon George 211/201 211/202 211/BCS 111 121/202 121/203 121/BCS Injective?
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Trying out Terminology f(x) = x 2 Injective? What if f: R + R + ? x f(x)
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Trying out Terminology f:{s|s is a 121 student} {A+, A, …, D, F} f(s) = s’s mark in 121 Is f injective? What if we didn’t know what f represented, only its “type” and the fact that there are lots of 121 students: f:{s|s is a 121 student} {A+, A, …, D, F}
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Nifty Injective Function: Error-Correcting Codes Error-correcting codes must be injective. Why?
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Outline Functions as “Computation Abstractions” Definition of Functions and Function Terminology Function Properties –Injective –Surjective –Bijective Function Operations –Inverse –Composition
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Function Properties: Surjective f:A B is surjective (also onto) if every element of the co-domain has a pre-image: y B, x A, y = f(x). Alan Steve Paul Patrice Karon George 121 211 Alan Steve Paul Patrice Karon George 211/201 211/202 211/BCS 111 121/202 121/203 121/BCS Surjective? Can we define “surjective” in terms of “range” and “co-domain”?
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Trying out Terminology f(x) = x 2 f: R R 0 ? Surjective? What if f: R R? What if f: Z Z 0 ? How about f(x) = x ? For what types is it surjective? x f(x)
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Trying out Terminology f:{s|s is a 121 student} {A+, A, …, D, F} f(s) = s’s mark in 121 Is f surjective? Could we ever know that f was surjective just by knowing f ’s domain and co-domain?
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Nifty Surjective Function: “Lossy” Compression WARNING: Lossy compression functions are not always surjective… But it’s valuable if they are. Why?
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Surjective Functions So Far Under what circumstances is a combinational circuit with one ouput surjective? Under what circumstances is it not surjective? So, are our circuits usually surjective or not?
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Outline Functions as “Computation Abstractions” Definition of Functions and Function Terminology Function Properties –Injective –Surjective –Bijective Function Operations –Inverse –Composition
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Function Properties: Bijective A function f:A B is bijective (also one- to-one correspondence) if it is both one-to- one and onto. Every element in the domain has exactly one unique image. Every element in the co-domain has exactly one unique pre- image.
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Function Properties: Bijective A function f:A B is bijective (also one- to-one correspondence) if it is both one-to- one and onto. Alan Steve Paul Patrice Karon George 121 211 Alan Steve Paul Patrice Karon George 211/201 211/202 211/BCS 121/202 121/203 121/BCS Bijective? 111
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Trying out Terminology f(x) = x 2 f:? ? Bijective for what domain/co-domain? x f(x)
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Nifty Bijective Function: Encryption/Lossless Compression Two sets have the same cardinality if we can put them in a bijection. What does that say about lossless compression?
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Outline Functions as “Computation Abstractions” Definition of Functions and Function Terminology Function Properties –Injective –Surjective –Bijective Function Operations –Inverse –Composition
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Function Operations: Inverse The inverse of a function f:A B is f -1 :B A. f(x) = y f -1 (y) = x. How can we tell whether f -1 is a function? (Hint: what would make f -1 not a function?) Can we prove it?
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Trying out Terminology What’s the inverse of each of these f s? Alan Steve Paul Patrice Karon George 121 211 Alan Steve Paul Patrice Karon George 211/201 211/202 211/BCS 121/202 121/203 121/BCS 111
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Trying out Terminology f(x) = x 2 What’s the inverse of f ? What should the domain/co-domain be? x f(x)
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Outline Functions as “Computation Abstractions” Definition of Functions and Function Terminology Function Properties –Injective –Surjective –Bijective Function Operations –Inverse –Composition Dropped from learning goals and exam.
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Function Operations: Composition The composition of two functions f:B C and g:A B written f o g is the function h:A C, where: x A, h(x) = f(g(x)). 121 211 Alan Steve Paul Patrice Karon George 211/201 211/202 211/BCS 121/202 121/203 121/BCS 111 211/201 211/202 211/BCS 121/202 121/203 121/BCS What is f ? What is g ? What is f o g ? Dropped from learning goals and exam.
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Proving a function injective Recall: A function f : A B is injective exactly when: x,y A, x y f(x) f(y). A typical approach is to prove the contrapositive by antecedent assumption: assume f(x) = f(y) and show that x = y.
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Problem: x 3 + 5 is injective Theorem: f(x) = x 3 + 5 is injective, where f : Z Z.
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Worked Problem: x 3 + 5 is injective Theorem: f(x) = x 3 +5 is injective, where f : Z Z. Recall: A function f : A B is injective exactly when: x,y A, x y f(x) f(y). We proceed by establishing the contrapositive of this definition. Then, x 3 + 5 = y 3 + 5by antecedent assumption x 3 = y 3 subtracting 5 from both sides x = ycube root of both sides QED Be careful! Would the same proof work for x 2 + 5 ? No: the square root of x 2 may be +x or -x !
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Proving a function surjective Recall: A function f : A B is surjective exactly when: y B, x A, y = f(x). That existential gives us a lot of freedom to pick a witness! A typical approach is to “solve for” the necessary x given a y.
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Problem: w + 2z is surjective Theorem: f(w,z) = w + 2z is surjective, where f : (Z Z) Z.
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Worked Problem: w + 2z is surjective Theorem: f(w,z) = w + 2z is surjective, where f : (Z Z) Z. Recall: A function f : A B is surjective exactly when: y B, x A, y = f(x). WLOG, let y be an arbitrary integer. Let w = y and z = 0. Then, w + 2z = y + 2(0) = y. QED
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Proving a function bijective Prove that it’s injective. Prove that it’s surjective. Done.
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Proving a function has an inverse Prove that it’s bijective. Done.
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An Inverse Proof Theorem: If f:A B is bijective, then f -1 : B A is a function. Recall that f -1 (f(x)) = x.
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An Inverse Proof, Worked Theorem: If f : A B is bijective, then f -1 : B A is a function. We proceed by antecedent assumption. Assume f : A B is bijective. Consider an arbitrary element y of B. Because f is surjective, there is some x in A such that f(x) = y. Because f is injective, that is the only such x. f -1 (y) = x by definition; so, f -1 maps every element of B to exactly one element of A. QED
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A Composition Proof Theorem: If g:A B and f:B C are functions, then f o g is a function. Recall that (f o g)(x) = f(g(x)). Dropped from learning goals and exam.
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A Composition Proof, Worked Theorem: If g:A B and f:B C are functions, then f o g is a function. We proceed by antecedent assumption. Assume g and f are functions. We must show that fog is a function: every element of the domain of f o g ( A ), is mapped to one and only one element of its co-domain ( C ). (Continued on next slide.) Dropped from learning goals and exam.
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A Composition Proof, Worked WLOG, let x be an arbitrary element of A. By the definition of f o g, (f o g)(x) = f(g(x)). We know g(x) is an (i.e., “one and only one”) element of B, since g is a function, x A, and g : A B. By similar reasoning, since g(x) B, we know f(g(x)) C because f is a function. QED
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Aside: Functions are Just Sets We can define functions in terms of sets and tuples (and we can define tuples in terms of sets!). The function f:A B is the set {(x, f(x)) | x A}. f is a subset of A B !
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Learning Goals: In-Class By the end of this unit, you should be able to: –Define the terms injective (one-to-one), surjective (onto), bijective (one-to-one correspondence), and inverse. –Determine whether a given function is injective, surjective, and/or bijective. –Apply your proof skills to proofs about the properties (e.g., injectiveness, surjectiveness, bijectiveness, and function-ness) of functions and their inverses.
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