đ Can explain pros and cons of software engineering
Software Engineering: Software Engineering is the application of a systematic, disciplined, quantifiable approach to the development, operation, and maintenance of software" -- IEEE Standard Glossary of Software Engineering Terminology
The following description of the Joys of the Programming Craft was taken from Chapter 1 of the famous book
Why is programming fun? What delights may its practitioner expect as his reward?
First is the sheer joy of making things. As the child delights in his mud pie, so the adult enjoys building things, especially things of his own design. I think this delight must be an image of God's delight in making things, a delight shown in the distinctness and newness of each leaf and each snowflake.
Second is the pleasure of making things that are useful to other people. Deep within, we want others to use our work and to find it helpful. In this respect the programming system is not essentially different from the child's first clay pencil holder "for Daddy's office."
Third is the fascination of fashioning complex puzzle-like objects of interlocking moving parts and watching them work in subtle cycles, playing out the consequences of principles built in from the beginning. The programmed computer has all the fascination of the pinball machine or the jukebox mechanism, carried to the ultimate.
Fourth is the joy of always learning, which springs from the nonrepeating nature of the task. In one way or another the problem is ever new, and its solver learns something: sometimes practical, sometimes theoretical, and sometimes both.
Finally, there is the delight of working in such a tractable medium. The programmer, like the poet, works only slightly removed from pure thought-stuff. He builds his castles in the air, from air, creating by the exertion of the imagination. Few media of creation are so flexible, so easy to polish and rework, so readily capable of realizing grand conceptual structures....
Yet the program construct, unlike the poet's words, is real in the sense that it moves and works, producing visible outputs separate from the construct itself. It prints results, draws pictures, produces sounds, moves arms. The magic of myth and legend has come true in our time. One types the correct incantation on a keyboard, and a display screen comes to life, showing things that never were nor could be.
Programming then is fun because it gratifies creative longings built deep within us and delights sensibilities we have in common with all men.
Not all is delight, however, and knowing the inherent woes makes it easier to bear them when they appear.
First, one must perform perfectly. The computer resembles the magic of legend in this respect, too. If one character, one pause, of the incantation is not strictly in proper form, the magic doesn't work. Human beings are not accustomed to being perfect, and few areas of human activity demand it. Adjusting to the requirement for perfection is, I think, the most difficult part of learning to program.
Next, other people set one's objectives, provide one's resources, and furnish one's information. One rarely controls the circumstances of his work, or even its goal. In management terms, one's authority is not sufficient for his responsibility. It seems that in all fields, however, the jobs where things get done never have formal authority commensurate with responsibility. In practice, actual (as opposed to formal) authority is acquired from the very momentum of accomplishment.
The dependence upon others has a particular case that is especially painful for the system programmer. He depends upon other people's programs. These are often maldesigned, poorly implemented, incompletely delivered (no source code or test cases), and poorly documented. So he must spend hours studying and fixing things that in an ideal world would be complete, available, and usable.
The next woe is that designing grand concepts is fun; finding nitty little bugs is just work. With any creative activity come dreary hours of tedious, painstaking labor, and programming is no exception.
Next, one finds that debugging has a linear convergence, or worse, where one somehow expects a quadratic sort of approach to the end. So testing drags on and on, the last difficult bugs taking more time to find than the first.
The last woe, and sometimes the last straw, is that the product over which one has labored so long appears to be obsolete upon (or before) completion. Already colleagues and competitors are in hot pursuit of new and better ideas. Already the displacement of one's thought-child is not only conceived, but scheduled.
This always seems worse than it really is. The new and better product is generally not available when one completes his own; it is only talked about. It, too, will require months of development. The real tiger is never a match for the paper one, unless actual use is wanted. Then the virtues of reality have a satisfaction all their own.
Of course the technological base on which one builds is always advancing. As soon as one freezes a design, it becomes obsolete in terms of its concepts. But implementation of real products demands phasing and quantizing. The obsolescence of an implementation must be measured against other existing implementations, not against unrealized concepts. The challenge and the mission are to find real solutions to real problems on actual schedules with available resources.
This then is programming, both a tar pit in which many efforts have floundered and a creative activity with joys and woes all its own. For many, the joys far outweigh the woes....
The Mythical Man-Month: Essays on Software Engineering is a book on software engineering and project management by Fred Brooks, whose central theme is that "adding manpower to a late software project makes it later". This idea is known as Brooks's law, and is presented along with the second-system effect and advocacy of prototyping.
Compare Software Engineering with Civil Engineering in terms of how work products in CE (i.e. buildings) differ from those of SE (i.e. software).
Buildings | Software |
---|---|
Visible, tangible | Invisible, intangible |
Wears out over time | Does not wear out |
Change is limited by physical restrictions (e.g. difficult to remove a floor from a high rise building) | Change is not limited by such restrictions. Just change the code and recompile. |
Creating an exact copy of a building is impossible. Creating a near copy is almost as costly as creating the original. | Any number of exact copies can be made with near zero cost. |
Difficult to move. | Easily delivered from one place to another. |
Many low-skilled workers following tried-and-tested procedures. | No low-skilled workers involved. Workers have more freedom to follow their own procedures. |
Easier to assure quality (just follow accepted procedure). | Not easy to assure quality. |
Majority of the work force has to be on location. | Can be built by people who are not even in the same country. |
Raw materials are costly, costly equipment required. | Almost free raw materials and relatively cheap equipment. |
Once construction is started, it is hard to do drastic changes to the design. | Building process is very flexible. Drastic design changes can be done, although costly |
A lot of manual and menial labor involved. | Most work involves highly-skilled labor. |
Generally robust. E.g. removing a single brick is unlikely to destroy a building. | More fragile than buildings. A single misplaced semicolon can render the whole system useless. |
Comment on this statement: Building software is cheaper and easier than building bridges (all we need is a PC!).
Depends on the size of the software. Manpower required for software is very costly. On the other hand, we can create a very valuable software (e.g. an iPhone application that can make million dollars in a month) with a just a PC and a few days of work!
Justify this statement: Coding is still a âdesignâ activity, not a âmanufacturingâ activity. You may use a comparison (or an analogy) of Software engineering versus Civil Engineering to argue this point.
Arguments to support this statement:
- If coding is a manufacturing activity, we should be able to do it using robotic machines (just like in the car industry) or low-skilled laborers (like in the construction industry).
- If coding is a manufacturing activity, we wouldnât be changing it so much after we code software. But if the code is in fact a âdesignâ, yes, we would fiddle with it until we get it right.
- Manufacturing is the process of building a finished product based on the design. Code is the design. Manufacturing is what is done by the compiler (fully automated).
However, the type of âdesignâ that occurs during coding is at a much lower level than the âdesignâ that occurs before coding.
List some (at least three each) pros and cons of Software Engineering compared to other traditional Engineering careers.
- a. Need for perfection when developing software
- b. Requiring some amount of tedious, painstaking labor
- c. Ease of copying and transporting software makes it difficult to keep track of versions
- d. High dependence on others
- e. Seemingly never ending effort required for testing and debugging software
- f. Fast moving industry making our work obsolete quickly
- a. Need for perfection when developing software
- b. Requiring some amount of tedious, painstaking labor
- c. Ease of copying and transporting software makes it difficult to keep track of versions
- d. High dependence on others
- e. Seemingly never ending effort required for testing and debugging software
- f. Fast moving industry making our work obsolete quickly