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CS Data Structures Chapter 6 Stacks Mehmet H Gunes

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1 CS 302 - Data Structures Chapter 6 Stacks Mehmet H Gunes
Modified from authors’ slides

2 The Abstract Data Type Stack
Operations on a stack Last-in, First-out behavior. Applications demonstrated Evaluating algebraic expressions Searching for a path between two points © 2017 Pearson Education, Hoboken, NJ. All rights reserved

3 Developing an ADT During the Design of a Solution
Consider typing a line of text on a keyboard Use of backspace key to make corrections You type Corrected input will be Must decide how to store the input line. © 2017 Pearson Education, Hoboken, NJ. All rights reserved

4 Developing an ADT During the Design of a Solution
Initial draft of solution Two required operations Add new item to ADT Remove item added most recently © 2017 Pearson Education, Hoboken, NJ. All rights reserved

5 Developing an ADT During the Design of a Solution
Read and correct algorithm Third operation required See whether ADT is empty © 2017 Pearson Education, Hoboken, NJ. All rights reserved

6 Developing an ADT During the Design of a Solution
Write-backward algorithm Fourth operation required Get item that was added to ADT most recently. © 2017 Pearson Education, Hoboken, NJ. All rights reserved

7 Specifications for the ADT Stack
See whether stack is empty. Add new item to the stack. Remove from and discard stack item that was added most recently. Get copy of item that was added to stack most recently. © 2017 Pearson Education, Hoboken, NJ. All rights reserved

8 Specifications for the ADT Stack
A stack of cafeteria plates LIFO: The last item inserted onto a stack is the first item out © 2017 Pearson Education, Hoboken, NJ. All rights reserved

9 Specifications for the ADT Stack
UML diagram for the class Stack © 2017 Pearson Education, Hoboken, NJ. All rights reserved

10 Specifications for the ADT Stack
A C++ interface for stacks © 2017 Pearson Education, Hoboken, NJ. All rights reserved

11 Specifications for the ADT Stack
A C++ interface for stacks © 2017 Pearson Education, Hoboken, NJ. All rights reserved

12 Specifications for the ADT Stack
Axioms for multiplication Axioms for ADT stack © 2017 Pearson Education, Hoboken, NJ. All rights reserved

13 Checking for Balanced Braces
Example of curly braces in C++ language Balanced Not balanced Requirements for balanced braces For each }, must match an already encountered { At end of string, must have matched each { © 2017 Pearson Education, Hoboken, NJ. All rights reserved

14 Checking for Balanced Braces
Initial draft of a solution. © 2017 Pearson Education, Hoboken, NJ. All rights reserved

15 Checking for Balanced Braces
Detailed pseudocode solution. © 2017 Pearson Education, Hoboken, NJ. All rights reserved

16 Checking for Balanced Braces
Detailed pseudocode solution. © 2017 Pearson Education, Hoboken, NJ. All rights reserved

17 Checking for Balanced Braces
Traces of algorithm that checks for balanced braces push { pop stack empty -> balanced © 2017 Pearson Education, Hoboken, NJ. All rights reserved

18 Recognizing Strings in a Language
Given a definition of a language, L Special palindromes Special middle character $ Example ABC$CBA ɛ L, but AB$AB ɛ L A stack is useful in determining whether a given string is in a language Traverse first half of string Push each character onto stack Reach $, undo, pop character, match or not © 2017 Pearson Education, Hoboken, NJ. All rights reserved

19 Recognizing Strings in a Language
Algorithm to recognize string in language L © 2017 Pearson Education, Hoboken, NJ. All rights reserved

20 Recognizing Strings in a Language
Algorithm to recognize string in language L © 2017 Pearson Education, Hoboken, NJ. All rights reserved

21 Using Stacks with Algebraic Expressions
Strategy Develop algorithm to evaluate postfix Develop algorithm to transform infix to postfix These give us capability to evaluate infix expressions This strategy easier than directly evaluating infix expression © 2017 Pearson Education, Hoboken, NJ. All rights reserved

22 Evaluating Postfix Expressions
Infix expression 2 * (3 + 4) Equivalent postfix * Operator in postfix applies to two operands immediately preceding Assumptions for our algorithm Given string is correct postfix No unary, no exponentiation operators Operands are single lowercase letters, integers © 2017 Pearson Education, Hoboken, NJ. All rights reserved

23 Evaluating Postfix Expressions
The effect of a postfix calculator on a stack when evaluating the expression 2 * (3 + 4) © 2017 Pearson Education, Hoboken, NJ. All rights reserved

24 Evaluating Postfix Expressions
A pseudocode algorithm that evaluates postfix expressions © 2017 Pearson Education, Hoboken, NJ. All rights reserved

25 Infix to Postfix Important facts
Operands always stay in same order with respect to one another. Operator will move only “to the right” with respect to the operands; If in the infix expression the operand x precedes the operator op, Also true that in the postfix expression the operand x precedes the operator op . All parentheses are removed. © 2017 Pearson Education, Hoboken, NJ. All rights reserved

26 Infix to Postfix First draft of algorithm to convert infix to postfix
© 2017 Pearson Education, Hoboken, NJ. All rights reserved

27 Infix to Postfix Determining where to place operators in postfix expression Parentheses Operator precedence Left-to-right association Note difficulty Infix expression not always fully parenthesized Precedence and left-to-right association also affect results © 2017 Pearson Education, Hoboken, NJ. All rights reserved

28 Infix to Postfix A trace of the algorithm that converts the infix expression a − (b + c * d) /e to postfix form © 2017 Pearson Education, Hoboken, NJ. All rights reserved

29 Infix to Postfix Pseudocode algorithm that converts infix to postfix
© 2017 Pearson Education, Hoboken, NJ. All rights reserved

30 Infix to Postfix Pseudocode algorithm that converts infix to postfix
© 2017 Pearson Education, Hoboken, NJ. All rights reserved

31 Using Stack to Search a Flight Map
© 2017 Pearson Education, Hoboken, NJ. All rights reserved

32 Using Stack to Search a Flight Map
Recall recursive search strategy. © 2017 Pearson Education, Hoboken, NJ. All rights reserved

33 Using Stack to Search a Flight Map
Possible outcomes of exhaustive search strategy Reach destination city, decide possible to fly from origin to destination Reach a city, C from which no departing flights You go around in circles Use backtracking to recover from a wrong choice (2 or 3) © 2017 Pearson Education, Hoboken, NJ. All rights reserved

34 Using Stack to Search a Flight Map
Strategy requires information about order in which it visits cities The stack of cities as you travel from P to W © 2017 Pearson Education, Hoboken, NJ. All rights reserved

35 Using Stack to Search a Flight Map
Stack will contain directed path from Origin city at bottom to … Current visited city at top When to backtrack No flights out of current city Top of stack city already somewhere in the stack © 2017 Pearson Education, Hoboken, NJ. All rights reserved

36 Using Stack to Search a Flight Map
The effect of revisits on the stack of cities © 2017 Pearson Education, Hoboken, NJ. All rights reserved

37 Using Stack to Search a Flight Map
Final draft of algorithm. © 2017 Pearson Education, Hoboken, NJ. All rights reserved

38 Using Stack to Search a Flight Map
Final draft of algorithm. © 2017 Pearson Education, Hoboken, NJ. All rights reserved

39 Using Stack to Search a Flight Map
A trace of the search algorithm, given the flight map © 2017 Pearson Education, Hoboken, NJ. All rights reserved

40 Using Stack to Search a Flight Map
C++ implementation of searchS © 2017 Pearson Education, Hoboken, NJ. All rights reserved

41 Using Stack to Search a Flight Map
C++ implementation of searchS © 2017 Pearson Education, Hoboken, NJ. All rights reserved

42 Using Stack to Search a Flight Map
Flight map for Checkpoint Question 8 © 2017 Pearson Education, Hoboken, NJ. All rights reserved

43 Stacks of Boxes and Books
TOP OF THE STACK TOP OF THE STACK 43

44 Relationship Between Stacks and Recursion
Key aspects of common strategy Visiting a new city Backtracking Termination © 2017 Pearson Education, Hoboken, NJ. All rights reserved

45 Relationship Between Stacks and Recursion
Visiting city P , then R , then X : (a) box trace versus (b) stack © 2017 Pearson Education, Hoboken, NJ. All rights reserved

46 Relationship Between Stacks and Recursion
Backtracking from city X to R to P : (a) box trace versus (b) stack © 2017 Pearson Education, Hoboken, NJ. All rights reserved

47 Stack Activation Frames
The activation record stores the return address for this function call, the parameters, local variables, and the function’s return value, if non-void. The activation record for a particular function call is popped off the run-time stack when the final closing brace in the function code is reached, or when a return statement is reached in the function code. At this time the function’s return value, if non-void, is brought back to the calling block return address for use there.

48 What operation does Func(a, b) simulate?
// Another recursive function int Func ( int a, int b ) // Pre: a and b have been assigned values // Post: Function value = ?? { int result; if ( b == 0 ) // base case result = 0; else if ( b > 0 ) // first general case result = a + Func ( a , b - 1 ) ); // instruction 50 else // second general case result = Func ( - a , - b ); // instruction 70 } return result; What operation does Func(a, b) simulate?

49 x = Func(5, 2); // original call is instruction 100
Run-Time Stack Activation Records x = Func(5, 2); // original call is instruction 100 FCTVAL ? result ? b a Return Address original call at instruction 100 pushes on this record for Func(5,2)

50 Run-Time Stack Activation Records
x = Func(5, 2); // original call at instruction 100 FCTVAL ? result ? b a Return Address result Func(5,1) = ? b a Return Address call in Func(5,2) code at instruction 50 pushes on this record for Func(5,1) record for Func(5,2)

51 Run-Time Stack Activation Records
call in Func(5,1) code at instruction 50 pushes on this record for Func(5,0) FCTVAL ? result ? b a Return Address FCTVAL ? result Func(5,0) = ? b Return Address result Func(5,1) = ? b a Return Address record for Func(5,1) record for Func(5,2)

52 Run-Time Stack Activation Records
record for Func(5,2) record for Func(5,1) record for Func(5,0) is popped first with its FCTVAL FCTVAL result b a Return Address FCTVAL ? result Func(5,0) = ? b Return Address FCTVAL ? result Func(5,1) = ? b a Return Address

53 Run-Time Stack Activation Records
FCTVAL result 5+Func(5,0) = b a Return Address FCTVAL ? result Func(5,1) = ? b a Return Address record for Func(5,1) is popped next with its FCTVAL record for Func(5,2)

54 x = Func(5, 2); // original call at line 100
Run-Time Stack Activation Records x = Func(5, 2); // original call at line 100 FCTVAL result 5+Func(5,1) = 5+5 b a Return Address record for Func(5,2) is popped last with its FCTVAL

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