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Fundamentals of Python: From First Programs Through Data Structures

Fundamentals of Python: From First Programs Through Data Structures . Chapter 14 Linear Collections: Stacks. Objectives. After completing this chapter, you will be able to: Describe the behavior of a stack from a user’s perspective

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Fundamentals of Python: From First Programs Through Data Structures

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  1. Fundamentals of Python:From First Programs Through Data Structures Chapter 14 Linear Collections: Stacks

  2. Objectives After completing this chapter, you will be able to: • Describe the behavior of a stack from a user’s perspective • Explain how a stack can be used to support a backtracking algorithm • Describe the use of a stack in evaluating postfix expressions Fundamentals of Python: From First Programs Through Data Structures

  3. Objectives (continued) • Explain how the Python virtual machine uses a stack to support function and method calls • Analyze the performance trade-offs between an array-based implementation of a stack and a linked implementation of a stack Fundamentals of Python: From First Programs Through Data Structures

  4. Overview of Stacks • Stack: LIFO structure in which access is completely restricted to just one end, called the top • Basic operations: push and pop Fundamentals of Python: From First Programs Through Data Structures

  5. Using a Stack • A stack type is not built into Python • Can use a Python list to emulate a stack • Use appendto push and popto pop • Drawback: stack can be manipulated by all of the other list operations as well • Extra operations violate the spirit of a stack as an ADT • We define a more restricted interface or set of operations for any authentic stack implementation and show how these operations are used in a brief example Fundamentals of Python: From First Programs Through Data Structures

  6. The Stack Interface Fundamentals of Python: From First Programs Through Data Structures

  7. Instantiating a Stack • We assume that any stack class that implements this interface will also have a constructor that allows its user to create a new stack instance • Later, we’ll consider two different implementations: • ArrayStackand LinkedStack • With different performance trade-offs • For now, assume that someone has coded these so we can use them: s1 = ArrayStack() s2 = LinkedStack() Fundamentals of Python: From First Programs Through Data Structures

  8. Example Application: Matching Parentheses • Compilers need to determine if the bracketing symbols in expressions are balanced correctly Fundamentals of Python: From First Programs Through Data Structures

  9. Example Application: Matching Parentheses (continued) • Approach 1: Count left and right parentheses • Does not work • Approach 2: • Scan expression; push left brackets onto a stack • On encountering a closing bracket, if stack is empty or if item on top of stack is not an opening bracket of the same type, we know the brackets do not balance • Pop an item off the top of the stack and, if it is the right type, continue scanning the expression • When we reach the end of the expression, stack should be empty; if not, brackets do not balance Fundamentals of Python: From First Programs Through Data Structures

  10. Three Applications of Stacks • We now discuss three other applications of stacks: • First, we present algorithms for evaluating arithmetic expressions • Second, we describe a general technique for using stacks to solve backtracking problems • Third, we examine the role of stacks in computer memory management Fundamentals of Python: From First Programs Through Data Structures

  11. Evaluating Arithmetic Expressions • In the infix form of an arithmetic expression, each operator is located between its operands • In the postfix form of an arithmetic expression, an operator immediately follows its operands Fundamentals of Python: From First Programs Through Data Structures

  12. Evaluating Postfix Expressions • Steps: • Scan across the expression from left to right • On encountering an operator, apply it to the two preceding operands; replace all three by the result • Continue scanning until you reach expression’s end, at which point only the expression’s value remains • To express this procedure as a computer algorithm, you use a stack of operands • The time complexity of the algorithm is O(n), where n is the number of tokens in the expression Fundamentals of Python: From First Programs Through Data Structures

  13. Evaluating Postfix Expressions (continued) • In the algorithm, token refers to an operand or an operator: Create a new stack While there are more tokens in the expression Get the next token If the token is an operand Push the operand onto the stack Else if the token is an operator Pop the top-two operands from the stack Apply the operator to the two operands just popped Push the resulting value onto the stack Return the value at the top of the stack Fundamentals of Python: From First Programs Through Data Structures

  14. Evaluating Postfix Expressions (continued) Fundamentals of Python: From First Programs Through Data Structures

  15. Converting Infix to Postfix • Start with an empty postfix expression and an empty stack • Stack will hold operators and left parentheses • Scan across infix expression from left to right • On encountering an operand, append it to postfix expression • On encountering a (, push it onto the stack Fundamentals of Python: From First Programs Through Data Structures

  16. Converting Infix to Postfix (continued) • On encountering an operator • Pop operators with equal or higher precedence • Append them to postfix expression • Push scanned operator onto stack • On encountering a ), shift operators from stack to postfix expression until meeting matching (, which is discarded • On encountering the end of the infix expression, transfer remaining operators from the stack to the postfix expression Fundamentals of Python: From First Programs Through Data Structures

  17. Backtracking • A backtracking algorithm begins in a predefined starting state and moves from state to state in search of a desired ending state • When there is a choice between alternative states, picks one, possibly at random, and continues • If it reaches a state that represents an undesirable outcome, it backs up to last point at which there was an unexplored alternative and tries it • It searches all states or reaches desired ending state • Two implementation techniques: • Use stacks or use recursion Fundamentals of Python: From First Programs Through Data Structures

  18. Backtracking (continued) • Stack approach: Create an empty stack Push the starting state onto the stack While the stack is not empty Pop the stack and examine the state If the state represents an ending state Return SUCCESSFUL CONCLUSION Else if the state has not been visited previously Mark the state as visited Push onto the stack all unvisited adjacent states Return UNSUCCESSFUL CONCLUSION Fundamentals of Python: From First Programs Through Data Structures

  19. Backtracking (continued) • Backtracking algorithm to solve maze problem: Instantiate a stack Locate the character “P” in the grid Push its location onto the stack While the stack is not empty Pop a location, (row, column), off the stack If the grid contains “T” at this location, then A path has been found Return SUCCESS Else if this location does not contain a dot Place a dot in the grid at this location Examine the adjacent cells to this one and for each one that contains a space, push its location onto the stack Return FAILURE Fundamentals of Python: From First Programs Through Data Structures

  20. Memory Management • The computer’s run-time system must keep track of various details that are invisible to the programmer: • Associating variables with data objects stored in memory so they can be located when these variables are referenced • Remembering the address of the instruction in which a method or function is called, so control can return to the next instruction when that function or method finishes execution • Allocating memory for a function’s or a method’s arguments and temporary variables, which exist only during the execution of that function or method Fundamentals of Python: From First Programs Through Data Structures

  21. Memory Management (continued) Fundamentals of Python: From First Programs Through Data Structures

  22. Memory Management (continued) • When a subroutine is called, the PVM: • Creates the subroutine’s activation record and pushes it onto the call stack • Saves the basePtr’s current value in the region labeled Prev basePtr and sets the basePtr to the new activation record’s base • Saves the locationCounter’s current value in region labeled Return Address and sets locationCounter to the first instruction of the called subroutine • Copies calling parameters into Parameters region • Starts executing the called subroutine at location indicated by locationCounter Fundamentals of Python: From First Programs Through Data Structures

  23. Memory Management (continued) • When a subroutine has finished executing, the PVM does the following: • Reestablishes the settings needed by the calling subroutine by restoring the values of the locationCounter and the basePtr from values stored in the activation record • Pops the activation record from the call stack • Resumes execution of the calling subroutine at the location indicated by the locationCounter Fundamentals of Python: From First Programs Through Data Structures

  24. Implementations of Stacks • Because of their simple behavior and linear structure, stacks are implemented easily using arrays or linked structures • Our two implementations of stacks illustrate the typical trade-offs involved in using these two recurring approaches Fundamentals of Python: From First Programs Through Data Structures

  25. Test Driver Fundamentals of Python: From First Programs Through Data Structures

  26. Test Driver (continued) • Output: • Note that the items in the stack print from bottom to top in the stack’s string representation, whereas when they are popped, they print from top to bottom Fundamentals of Python: From First Programs Through Data Structures

  27. Array Implementation • Built around an array called itemsand two integers called topand size • Initially, the array has a default capacity of 10 positions, topequals -1, and sizeequals 0 Fundamentals of Python: From First Programs Through Data Structures

  28. Linked Implementation • Uses a singly linked sequence of nodes with a variable toppointing at the list’s head, and a variable sizeto track the items on the stack Fundamentals of Python: From First Programs Through Data Structures

  29. Linked Implementation (continued) • The implementation of stris complicated by the fact that the items must be visited from the end of the linked structure to its beginning • Solution: use recursion Fundamentals of Python: From First Programs Through Data Structures

  30. Linked Implementation (continued) Fundamentals of Python: From First Programs Through Data Structures

  31. Linked Implementation (continued) Fundamentals of Python: From First Programs Through Data Structures

  32. Time and Space Analysis of the Two Implementations • With the exception of __str__, all of the stack methods have a maximum running time of O(1) • __str__runs in linear time; recursive function used in linked stack causes a linear growth of memory • In the array implementation, at the moment of doubling, push’s running time jumps to O(n) • The rest of the time it remains at O(1) • Similar remarks can be made about pop • Space requirement: 2n + 2 for linked stack and capacity + 2 for array implementation Fundamentals of Python: From First Programs Through Data Structures

  33. Case Study: Evaluating Postfix Expressions • Request: • Write an interactive program for evaluating postfix expressions • Analysis: • Program should detect and report all input errors, be they intentional or unintentional • The view class is named PFView • The model class is named PFEvaluatorModel • Processes are worth encapsulating in separate classes: Scannerand PFEvaluator Fundamentals of Python: From First Programs Through Data Structures

  34. Case Study: Evaluating Postfix Expressions (continued) Fundamentals of Python: From First Programs Through Data Structures

  35. Case Study: Evaluating Postfix Expressions (continued) Fundamentals of Python: From First Programs Through Data Structures

  36. Case Study: Evaluating Postfix Expressions (continued) Fundamentals of Python: From First Programs Through Data Structures

  37. Case Study: Evaluating Postfix Expressions (continued) Fundamentals of Python: From First Programs Through Data Structures

  38. Case Study: Evaluating Postfix Expressions (continued) • Implementation: Fundamentals of Python: From First Programs Through Data Structures

  39. Case Study: Evaluating Postfix Expressions (continued) Fundamentals of Python: From First Programs Through Data Structures

  40. Summary • A stack allows access to one end only, called the top, where items are pushed onto or popped from • Stacks are used in applications that manage data items in LIFO manner, such as: • Matching bracket symbols in expressions • Evaluating postfix expressions • Backtracking algorithms • Managing memory for subroutine calls on a VM • Arrays and singly linked structures support simple implementations of stacks Fundamentals of Python: From First Programs Through Data Structures

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