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Title: Fundamentals of Python: From First Programs Through Data Structures


1
Fundamentals of PythonFrom First Programs
Through Data Structures
  • Chapter 15
  • Linear Collections Queues

2
Objectives
  • After completing this chapter, you will be able
    to
  • Describe the behavior of a queue from a users
    perspective
  • Explain how a queue can be used to support a
    simulation
  • Describe the use of a queue in scheduling
    processes for computational resources

3
Objectives (continued)
  • Explain the difference between a queue and a
    priority queue
  • Describe a case where a queue would be used
    rather than a priority queue
  • Analyze the performance trade-offs between an
    array-based implementation of a queue and a
    linked implementation of a queue

4
Overview of Queues
5
Overview of Queues (continued)
  • Insertions are restricted to one end (rear)
  • Removals are restricted to one end (front)
  • Queues supports a first-in first-out (FIFO)
    protocol
  • Fundamental operations enqueue and dequeue
  • Item dequeued, or served next, is always the item
    that has been waiting the longest
  • Priority queue Higher-priority items are
    dequeued first equal priority items dequeued in
    FIFO order
  • Most queues in CS involve scheduling access to
    shared resources CPU/Disk/Printer access

6
The Queue Interface and Its Use
  • You can use a Python list to emulate a queue
  • Use append to add an element to rear of queue
  • Use pop to remove an element from front of queue
  • Drawback Queue can be manipulated by all of the
    other list operations as well
  • Violate spirit of queue as ADT
  • We define a more restricted interface, or set of
    operations, for any queue implementation and show
    how these operations are used

7
The Queue Interface and Its Use (continued)
8
The Queue Interface and Its Use (continued)
  • Assume that any queue class that implements this
    interface will also have a constructor that
    allows its user to create a new queue instance
  • Later, well consider two different
    implementations
  • ArrayQueue and LinkedQueue
  • q1 ArrayQueue()
  • q2 LinkedQueue()

9
Two Applications of Queues
  • We now look briefly at two applications of
    queues
  • One involving computer simulations
  • The other involving round-robin CPU scheduling

10
Simulations
  • Computer simulations are used to study behavior
    of real-world systems, especially if it is
    impractical or dangerous to experiment with these
    systems directly
  • Example Mimic traffic flow on a busy highway
  • Another example Manager of supermarket wants to
    determine number of checkout cashiers to schedule
    at various times of the day and must consider
  • Frequency with which new customers arrive
  • Number of checkout cashiers available
  • Number of items in a customers shopping cart
  • Period of time considered

11
Simulations (continued)
  • Simulations avoid need for formulas by imitating
    actual situation and collecting pertinent
    statistics
  • Simple technique to mimic variability
  • Suppose new customers are expected to arrive on
    average once every four minutes
  • During each minute of simulated time, a program
    can generate a random number between 0 and 1
  • If number is less than 1/4, program adds a new
    customer to a checkout line otherwise, it does
    not
  • Probability distribution functions produce more
    realistic results

12
Simulations (continued)
  • Examples presented involve service providers and
    service consumers
  • We associate each service provider with a queue
    of service consumers
  • Simulations operate by manipulating these queues
  • At each tick of an imaginary clock, add
    consumer(s) to the queues and give consumers at
    the head of each queue another unit of service
  • OO methods can be used to implement simulations

13
Simulations (continued)
  • Example Supermarket simulation
  • A Customer object keeps track of when the
    customer starts standing in line, when service is
    first received, and how much service is required
  • A Cashier object has a queue of customer objects
  • A simulator object coordinates customer/cashier
    activities by doing the following at each clock
    tick
  • Generates new customer objects as appropriate
  • Assigns customers to cashiers
  • Tells each cashier to provide one unit of service
    to the customer at the head of the queue

14
Round-Robin CPU Scheduling
  • Each process on the ready queue is dequeued in
    turn and given a slice of CPU time
  • Improvement Can use a priority queue

15
Implementations of Queues
  • Our approach to the implementation of queues is
    similar to the one we used for stacks
  • The structure of a queue lends itself to either
    an array implementation or a linked
    implementation
  • The linked implementation is somewhat more
    straight-forward

16
A Linked Implementation
  • enqueue adds a node at the end
  • For fast access to both ends of a queues linked
    structure, provide external pointers to both ends
  • Instance variables front and rear of LinkedQueue
    are given an initial value of None
  • size tracks number of elements currently in queue

17
A Linked Implementation (continued)
18
An Array Implementation
  • Array implementations of stacks and queues have
    less in common than the linked implementations
  • Array implementation of a queue must access items
    at the logical beginning and the logical end
  • Doing this in computationally effective manner is
    complex
  • We approach problem in a sequence of three
    attempts

19
A First Attempt
  • Fixes front of queue at position 0
  • rear variable points to last item at position n
    1
  • n is the number of items in queue
  • Analysis
  • enqueue is efficient
  • dequeue entails shifting all but first item ? O(n)

20
A Second Attempt
  • Maintain a second index (front) that points to
    item at front of queue
  • Starts at 0 and advances as items are dequeued
  • Analysis
  • dequeue is O(1)
  • Maximum running time of enqueue is O(n)

21
A Third Attempt
  • Use a circular array implementation
  • rear starts at 1 front starts at 0
  • front chases rear pointer through the array
  • When a pointer is about to run off the end of the
    array, it is reset to 0
  • Running times of enqueue and dequeue are O(1)

22
A Third Attempt (continued)
  • What happens when the queue becomes full?
  • Maintain a count of the items in the queue
  • When this count equals the size of the array
    Resize
  • After resizing, we would like queue to occupy
    initial segment of array, with front pointer set
    to 0
  • If front pointer is less than rear pointer
  • Copy positions 0 through size-1 in new array
  • If rear pointer is less than front pointer
  • Copy positions 0 through size-front and size
    front 1 through size-1 in new array
  • Resizing process is linear

23
Time and Space Analysis for the Two
Implementations
  • Linked implementation
  • Running time __str__ is O(n) all other are O(1)
  • Space requirement 2n 3, n size of queue
  • Circular array implementation
  • Static array Maximum running time of all methods
    other than __str__ is O(1)
  • Dynamic array enqueue/dequeue are O(n) when
    array is resized, but are O(1) on average
  • Space utilization For load factors above 1/2,
    array implementation makes more efficient use of
    memory than a linked implementation

24
Case Study Simulating a Supermarket Checkout Line
  • Request
  • Write program that allows user to predict
    behavior of supermarket checkout line under
    various conditions
  • Analysis

25
Case Study Simulating a Supermarket Checkout
Line (continued)
  • The Interface
  • Classes and responsibilities
  • We divide the system into a main function and
    several model classes

26
Case Study Simulating a Supermarket Checkout
Line (continued)
27
Case Study Simulating a Supermarket Checkout
Line (continued)
28
Case Study Simulating a Supermarket Checkout
Line (continued)
29
Priority Queues
  • A priority queue is a specialized type of queue
  • Items added to queue are assigned an order of
    rank
  • Items of higher priority are removed before those
    of lower priority
  • Items of equal priority are removed in FIFO order
  • Item A has a higher priority than item B if A lt B
  • Objects that recognize the comparison operators
    can be ordered in priority queues
  • If not, object can be wrapped with a priority
    number in another object that does recognize
    these operators

30
Priority Queues (continued)
31
Priority Queues (continued)
  • Wrapper class used to build a comparable item
    from one that is not already comparable

32
Priority Queues (continued)
  • During insertions, a priority queue does not know
    whether it is comparing items in wrappers or just
    items
  • When a wrapped item is accessed (e.g., with peek
    or dequeue), it must be unwrapped with the method
    getItem before processing
  • Two implementations Sorted linked list or heap

33
Priority Queues (continued)
34
Case Study An Emergency Room Scheduler
  • Request
  • Write a program that allows a supervisor to
    schedule treatments for patients coming into
    emergency room
  • Patients are assigned a priority when admitted
  • Higher priority patients receive attention first
  • Analysis
  • Patient priorities critical, serious, and fair

35
Case Study An Emergency Room Scheduler
(continued)
36
Case Study An Emergency Room Scheduler
(continued)
37
Case Study An Emergency Room Scheduler
(continued)
  • Classes
  • Design and Implementation
  • Patient and Condition classes maintain a
    patients name and condition
  • Patients can be compared (according to their
    conditions) and viewed as strings

38
Case Study An Emergency Room Scheduler
(continued)
39
Summary
  • A queue is a linear collection that adds elements
    to the rear and removes them from the front
  • Queues are used in applications that manage data
    items in a first-in, first-out order (FIFO)
  • Example Scheduling items for processing or
    access to resources
  • Arrays and singly linked structures support
    simple implementations of queues
  • Priority queues schedule their elements using a
    rating scheme as well as a FIFO order
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