Definition of Algorithm (after Al Kho-war-iz-mi a 9th century Persian mathematician) - an ordered sequence of unambiguous and well-defined instructions that performs some task and halts in finite time
Let's examine the four parts of this definition more closely
- an ordered sequence means that you can number the steps (it's socks then shoes!)
- unambiguous and well-defined instructions means that each instruction is clear, do-able, and can be done without difficulty
- performs some task
- halts in finite time (algorithms terminate!)
Algorithms can be executed by a computing agent which is not necessarily a computer.
Three Catagories of Algorithmic Operations
Algorithmic operations are ordered in that there is a first instruction, a second instruction etc. However, this is not enough. An algorithm must have the ability to alter the order of its instructions. An instruction that alters the order of an algorithm is called a control structure
Three Categories of Algorithmic Operations:
- sequential operations - instructions are executed in order
- conditional ("question asking") operations - a control structure that asks a true/false question and then selects the next instruction based on the answer
- iterative operations (loops) - a control structure that repeats the execution of a block of instructions
Unfortunately not every problem or task has a "good" algorithmic solution. There are
- unsolvable problems - no algorithm can exist to solve the problem (Halting Problem)
- "hard" (intractable) problems - algorithm takes too long to solve the problem (Traveling Salesman Problem)
- problems with no known algorithmic solution
How to represent algorithms?
- Use natural languages
- too verbose
- too "context-sensitive"- relies on experience of reader
- too verbose
- Use formal programming languages
- too low level
- requires us to deal with complicated syntax of programming language
- too low level
- Pseudo-Code - natural language constructs modeled to look like statements available in many programming languages
Pseudo-Code is simply a numbered list of instructions to perform some task. In this course we will enforce three standards for good pseudo code
- Number each instruction. This is to enforce the notion of an ordered sequence of ... operations. Furthermore we introduce a dot notation (e.g. 3.1 come after 3 but before 4) to number subordinate operations for conditional and iterative operations
- Each instruction should be unambiguous (that is the computing agent, in this case the reader, is capable of carrying out the instruction) and effectively computable (do-able).
- Completeness. Nothing is left out.
Pseudo-code is best understood by looking at examples. Each example below demonstrates one of the control structures used in algorithms : sequential operations, conditional operations, and iterative operations. We also list all variables used at the end of the pseudo-code.
Example #1 - Computing Sales Tax : Pseudo-code the task of computing the final price of an item after figuring in sales tax. Note the three types of instructions: input (get), process/calculate (=) and output (display)
1. get price of item
2. get sales tax rate
3. sales tax = price of time times sales tax rate
4 final prince = price of item plus sales tax
5. display final price
6. halt
Variables: price of item, sales tax rate, sales tax, final price
Note that the operations are numbered and each operation is unambiguous and effectively computable. We also extract and list all variables used in our pseudo-code. This will be useful when translating pseudo-code into a programming language
Example #2 - Computing Weekly Wages: Gross pay depends on the pay rate and the number of hours worked per week. However, if you work more than 40 hours, you get paid time-and-a-half for all hours worked over 40. Pseudo-code the task of computing gross pay given pay rate and hours worked.
1. get hours worked
2. get pay rate
3. if hours worked ≤ 40 then
3.1 gross pay = pay rate times hours worked
4. else
4.1 gross pay = pay rate times 40 plus 1.5 times pay rate times (hours worked minus 40)
5. display gross pay
6. halt
variables: hours worked, ray rate, gross pay
This example introduces the conditional control structure. On the basis of the true/false question asked in line 3, we execute line 3.1 if the answer is True; otherwise if the answer is False we execute the lines subordinate to line 4 (i.e. line 4.1). In both cases we resume the pseudo-code at line 5.
Example #3 - Computing a Quiz Average: Pseudo-code a routine to calculate your quiz average.
1. get number of quizzes
2. sum = 0
3. count = 0
4. while count < number of quizzes
4.1 get quiz grade
4.2 sum = sum + quiz grade
4.3 count = count + 1
5. average = sum / number of quizzes
6. display average
7. halt
variables: number of quizzes, sum ,count, quiz grade, average
This example introduces an iterative control statement. As long as the condition in line 4 is True, we execute the subordinate operations 4.1 - 4.3. When the condition becomes False, we resume the pseudo-code at line 5.
This is an example of a top-test or while do iterative control structure. There is also a bottom-test or repeat until iterative control structure which executes a block of statements until the condition tested at the end of the block is False.
Pseudo-code is one important step in the process of writing a program.
Pseudo-code Language Constructions : A Summary
Computation/Assignment
set the value of "variable" to :"arithmetic expression" or
"variable" equals "expression" or
"variable" = "expression"
Input/Output
get "variable", "variable", ...
display "variable", "variable", ...
Conditional (dot notation used for numbering subordinate statements)
6. if "condition"
6.1 (subordinate) statement 1
6.2 etc ...
7. else
7.1 (subordinate) statement 2
7.2 etc ...
Iterative (dot notation used for numbering subordinate statements)
9. while "condition"
9.1 (subordinate) statement 1
9.2 etc ...
출처 : http://userpages.wittenberg.edu/bshelburne/Comp150/Algorithms.htm
