cvs/02/assignment2.tex

%Assignment is conducted in pairs. Max. 8 pages.
\documentclass[12pt, a4paper]{article}
\usepackage[latin1]{inputenc}

\begin{document}
  \pagenumbering{roman}
  \thispagestyle{empty}
  \begin{centering}
    Assignment 1 - PAC003: Software Metrics, 5p\\
    Jonas Petersson \& Mathias Börjeson\\
    \emph{jopd01@student.bth.se \& tb00mbo@student.bth.se}\\
  \end{centering}
  \tableofcontents
  \newpage
  \pagenumbering{arabic}
  \section{Internal product attributes}
    \subsection{Explain how the three aspects of the software size (Length,
    Functionality and Complexity) are supplementing each other to describe
    the notion of software size.}
        %length        = is a physical size of the product
        %functionality = counts the functions supplied by the product
        %complexity    = measures the complexity od underlying problem, or a solution
%utan att ha en aning om hur notationen ser ut drar jag till med följande
        These three supplements each other adding references to
        each other. None of these is useful by itself, but by
        adding them up one can get a better perspective of the
        size of the software. The length itself don't tell
        anything of how large the completed software will be, but
        together with functions and complexity one can understand
        the size of the software. Once the size of the software is
        established one may come with effort estimations, and
        based on those make a budget for what resources the
        project will need. Given these three it is possible to get
        an idea of how productive a programmer is during a time
        unit. It will not be a perfect answer, but it will be
        something that could be used to measure deviations in work
        etc.
    \subsection{Give an example where code length measure can be useful and an
    example where source code length measure is not useful.}
        Code length is useful if it is not going to be used by
        itself. One example of this could be if we are interested
        in how much work is done in a week. Then we could look at
        loc, and also take into account the complexity and the functions provided
        (like loc * complexity / functions or something similar).
        Then loc could be useful.

        Code length is useless if it is used by itself. For
        example the statement I am a good programmer since I
        produce more then n loc per week useless.
    \subsection{Explain what are the main ideas behind Albrecht's Function Points.
    Discuss advantages and disadvantages of the measure. Motivate.}
        %denna var bra http://www.spr.com/products/function.htm
        The main idea behind FP's are to provide  language
        independent metric that can be used no matter what
        language are used. Albrech thought it was wrong that the
        only way to tell effort and cost per effort until he begun
        was in loc. A often used metric to tell productivity was
        cost/loc, and that don't tell anything since different
        languages require different number of loc's to solve the
        same problem. This cost could be lover if the language
        requires a lot of code, but the end cost could still get
        higher if the program takes longer time to complete.
        The main idea behind FP's is to give ways to
        tell cost and productivity in a way that is language
        independent. FP's does satisfy this idea. A easier
        language will get a lower cost/FP and a greater number of
        FP's/person\&month then a more complex language.

        The great advantage with this method is that it is (almost) truly
        language independent, while a disadvantage would be that
        if this is established in the beginning of a project and
        should be used to choose a appropriate language to use, if
        the language is unfamiliar, then these metrics can't be
        computed (like FP's/person\&month). Also this way of presenting
        the result does not take into account training and
        inexperience while showing the result. Also this should
        not be used to compare different projects or groups to se
        the difference between them since this does not take
        everything into account. Also one might be tempted to
        always use the language with the highest productivity,
        this is good in most cases, but sometimes there are other
        factors to sum in, like speed, security etc.
    \subsection{Describe structural measures presented by Fenton. (Control flow
    structure, Data flow structure, Data structure). Give an example
    where you explain how one could use the structural measures
    (specify which structural measure) to ensure the quality of the
    software product.}
        %http://sern.ucalgary.ca/~kliewerc/SENG/623/summaries.htm#sum02 var lite halvbra... det bästa jag kunde hitta dock, + F4...
        Control flow is a diagram with nodes, connected via the
        directed connections showing the possible routs the
        program (or actually the flow of data in the program) may
        take. This could be broken down to several diagrams if it
        gets to large and complex. This diagram can be used to
        decide how many test cases is needed to test the program
        completely.

        The data flow structure could be shown in a module-call
        graph. The module-call graph shows what modules calls what
        other modules, and thereby showing more the flow of
        information within the program. This may also be used to
        show coupling and cohesion in the program.

        The data structure can be measured both locally and
        globally. Locally it is interesting how much data
        structure each data item has, and globally it is the
        amount of data for the system. For the local data
        structures very little research has been done, but for the
        global there are more.
    \subsection{Draw the flow graph for the program, which
    based on the data provided by everyday measurements of the air
    temperature will calculate the maximum, minimum and the most
    commonly occurred temperature (the temperature that occurs twice
    or more) for a given month. Present program paths that has to be
    executed in order to satisfy the following testing strategies:}
        See appendix a for the diagram.
        \subsubsection{Statement coverage}
            a-b-c-d-e-f-g-h-i-j-k-l-m-n
        \subsubsection{Branch coverage}
            a-b-c-d-e-f-g-h-i-j-k-l-m-n \\
            a-b-c-b-c-d-e-g-i-j-k-m-n \\
            a-b-c-d-e-f-g-h-i-j-k-l-m-k-m-n \\
        \subsubsection{Visit each loop}
%osäker på om detta är rätt...jag har bara antagit att man skall göra ett test så att man kör alla looparna
            a-b-c-b-c-d-e-f-g-e-f-g-h-i-g-h-i-j-k-l-m-k-m-n
    \subsection{Calculate the cyclomatic complexity of your program. What does
    this figure tell you?}
        %Cyclomatic complexity (CC) = E - N + p
        %where E = the number of edges of the graph
        %N = the number of nodes of the graph
        %p = the number of connected components
        %http://www.sei.cmu.edu/str/descriptions/cyclomatic.html
        Hopefully you mean McCabe's cyclomatic complexity\\
        % e = no of arcs | n = no of nodes
        e-n+2 | 18 - 14 + 2 = 18 - 16 = 2 \\ %men vad säger nu detta
        This tells us the number of tests we have to do to cover
        each path in the program. It could also be used to give a
        estimation of how complex the final software will be. If
        higher then 20 it should be seen as a high risk project,
        and if higher then 50 as a very high risk project.  %nuffrorna kommer från http://www.sei.cmu.edu/str/descriptions/cyclomatic.html
  \section{OO metrics}
  \textbf{Measuring the use cases}
    %vi skall använda templaten, och bifoga denna...
    \subsection{Measure the use case specifications shown in Design 1 using the
    chosen use case metrics suite from the lecture}
        svar
    \subsection{Measure the use case specifications shown in Design 2 using the
    chosen use case metrics suite from the lecture}
        svar
    \subsection{Write a short section (up to ½ page) with answers to the following
    questions:}
        \subsubsection{Which of the two systems presented can be expected to be
             more complex and why?}
                svar
        \subsubsection{Which of the two systems can be expected to require more
            effort to be built? Why?}
                svar
  \textbf{Measuring designs}
  \subsection{Measure the class diagram presented in Design 1 using the CK metrics suite presented on the
    lecture.}
          svar
    \subsection{Measure the class diagram presented in Design 2 using
    the CK metrics suite presented on the lecture.}
          svar
    \subsection{Measure the code in the files .java from Design 1 with the CK metrics suite
    presented on the lecture.}
          svar
    \subsection{ Measure the code in the files .java
    from Design 2 with the CK metrics suite presented on the lecture.}
          svar
    \subsection{Write a short section (up to ½ page) with answers to the following
    questions:}
        \subsubsection{Which of the metrics could not be computed based on the class
        diagrams? Why?}
            svar
        \subsubsection{Which of the two systems is more complex? Why?}
            svar
        \subsubsection{Which method of gathering metrics - from UML designs or source
        code - is less time consuming?}
            svar
  \section{External product attributes}
    \subsection{Describe how the external product attributes differ from the
    internal ones. Describe the connection between external and
    internal product attributes.}
          The internal attributes can be measured from within the
          system (like loc etc) while for the external attributes
          one must look at the finished product to se the external
          attributes. Also in general internal attributes are
          considered easier to measure (and then predict) then the
          external attributes.

          This is partly since the internal attributes can be
          measured more ``directly'' then the external. For
          instance loc is easy to count while usability is a lot
          harder to measure. For the internal attributes one can
          expect to be able to get absolute values while on the
          external attributes one can expect them to be less
          accurate.

          However several of the internal attributes (if not all)
          does affect the external attributes in a way that can
          (in most cases) be predicted. One can for instance say
          that in a specific solution if the loc is increased
          (both with comments) then one could expect to get a
          higher maintainability. Also most of the external
          attributes can be affected via the internal if the
          developers keep the external attributes in mind.

          In most cases (if not always) the customer of the product
          is more interested in the external attributes. Does this
          mean that the external attributes are of ``greater''
          value to the team developing the product?

          Not always but in many cases. Also one should keep in
          mind that just because the external attributes are more
          important that the internal could be forgotten.
    %\subsection{Assume that you are working at the company that
    %mainly specializes on developing of web-based applications.
    %Your manager gives you an assignment to develop a software
    %quality model for the company. The model should show external
    %quality attributes, corresponding internal attributes and
    %metrics. Present the assumptions that you will use while
    %creating of the quality model. Provide an explanatory text
    %for your model.} %Jag tyckte inte om att läsa den texten;)
    \subsection{Assume that you are working at a company that
    mainly specializes in development of web-based applications.
    Your manager gives you an assignment to develop a software
    quality model for the company. The model should show external
    quality attributes, corresponding internal attributes and
    metrics. Present the assumptions that you will use while
    creating the quality model. Provide an explanatory text
    for your model.}
%huh? - jag kollar på denna... men vill du ha den så;)
        max 8 sidor (totalt; inte på denna;)
\end{document}
1	%Assignment is conducted in pairs. Max. 8 pages.
2	\documentclass[12pt, a4paper]{article}
3	\usepackage[latin1]{inputenc}
4
5	\begin{document}
6	\pagenumbering{roman}
7	\thispagestyle{empty}
8	\begin{centering}
9	Assignment 1 - PAC003: Software Metrics, 5p\\
10	Jonas Petersson \& Mathias Börjeson\\
11	\emph{jopd01@student.bth.se \& tb00mbo@student.bth.se}\\
12	\end{centering}
13	\tableofcontents
14	\newpage
15	\pagenumbering{arabic}
16	\section{Internal product attributes}
17	\subsection{Explain how the three aspects of the software size (Length,
18	Functionality and Complexity) are supplementing each other to describe
19	the notion of software size.}
20	%length = is a physical size of the product
21	%functionality = counts the functions supplied by the product
22	%complexity = measures the complexity od underlying problem, or a solution
23	%utan att ha en aning om hur notationen ser ut drar jag till med följande
24	These three supplements each other adding references to
25	each other. None of these is useful by itself, but by
26	adding them up one can get a better perspective of the
27	size of the software. The length itself don't tell
28	anything of how large the completed software will be, but
29	together with functions and complexity one can understand
30	the size of the software. Once the size of the software is
31	established one may come with effort estimations, and
32	based on those make a budget for what resources the
33	project will need. Given these three it is possible to get
34	an idea of how productive a programmer is during a time
35	unit. It will not be a perfect answer, but it will be
36	something that could be used to measure deviations in work
37	etc.
38	\subsection{Give an example where code length measure can be useful and an
39	example where source code length measure is not useful.}
40	Code length is useful if it is not going to be used by
41	itself. One example of this could be if we are interested
42	in how much work is done in a week. Then we could look at
43	loc, and also take into account the complexity and the functions provided
44	(like loc * complexity / functions or something similar).
45	Then loc could be useful.
46
47	Code length is useless if it is used by itself. For
48	example the statement I am a good programmer since I
49	produce more then n loc per week useless.
50	\subsection{Explain what are the main ideas behind Albrecht's Function Points.
51	Discuss advantages and disadvantages of the measure. Motivate.}
52	%denna var bra http://www.spr.com/products/function.htm
53	The main idea behind FP's are to provide language
54	independent metric that can be used no matter what
55	language are used. Albrech thought it was wrong that the
56	only way to tell effort and cost per effort until he begun
57	was in loc. A often used metric to tell productivity was
58	cost/loc, and that don't tell anything since different
59	languages require different number of loc's to solve the
60	same problem. This cost could be lover if the language
61	requires a lot of code, but the end cost could still get
62	higher if the program takes longer time to complete.
63	The main idea behind FP's is to give ways to
64	tell cost and productivity in a way that is language
65	independent. FP's does satisfy this idea. A easier
66	language will get a lower cost/FP and a greater number of
67	FP's/person\&month then a more complex language.
68
69	The great advantage with this method is that it is (almost) truly
70	language independent, while a disadvantage would be that
71	if this is established in the beginning of a project and
72	should be used to choose a appropriate language to use, if
73	the language is unfamiliar, then these metrics can't be
74	computed (like FP's/person\&month). Also this way of presenting
75	the result does not take into account training and
76	inexperience while showing the result. Also this should
77	not be used to compare different projects or groups to se
78	the difference between them since this does not take
79	everything into account. Also one might be tempted to
80	always use the language with the highest productivity,
81	this is good in most cases, but sometimes there are other
82	factors to sum in, like speed, security etc.
83	\subsection{Describe structural measures presented by Fenton. (Control flow
84	structure, Data flow structure, Data structure). Give an example
85	where you explain how one could use the structural measures
86	(specify which structural measure) to ensure the quality of the
87	software product.}
88	%http://sern.ucalgary.ca/~kliewerc/SENG/623/summaries.htm#sum02 var lite halvbra... det bästa jag kunde hitta dock, + F4...
89	Control flow is a diagram with nodes, connected via the
90	directed connections showing the possible routs the
91	program (or actually the flow of data in the program) may
92	take. This could be broken down to several diagrams if it
93	gets to large and complex. This diagram can be used to
94	decide how many test cases is needed to test the program
95	completely.
96
97	The data flow structure could be shown in a module-call
98	graph. The module-call graph shows what modules calls what
99	other modules, and thereby showing more the flow of
100	information within the program. This may also be used to
101	show coupling and cohesion in the program.
102
103	The data structure can be measured both locally and
104	globally. Locally it is interesting how much data
105	structure each data item has, and globally it is the
106	amount of data for the system. For the local data
107	structures very little research has been done, but for the
108	global there are more.
109	\subsection{Draw the flow graph for the program, which
110	based on the data provided by everyday measurements of the air
111	temperature will calculate the maximum, minimum and the most
112	commonly occurred temperature (the temperature that occurs twice
113	or more) for a given month. Present program paths that has to be
114	executed in order to satisfy the following testing strategies:}
115	See appendix a for the diagram.
116	\subsubsection{Statement coverage}
117	a-b-c-d-e-f-g-h-i-j-k-l-m-n
118	\subsubsection{Branch coverage}
119	a-b-c-d-e-f-g-h-i-j-k-l-m-n \\
120	a-b-c-b-c-d-e-g-i-j-k-m-n \\
121	a-b-c-d-e-f-g-h-i-j-k-l-m-k-m-n \\
122	\subsubsection{Visit each loop}
123	%osäker på om detta är rätt...jag har bara antagit att man skall göra ett test så att man kör alla looparna
124	a-b-c-b-c-d-e-f-g-e-f-g-h-i-g-h-i-j-k-l-m-k-m-n
125	\subsection{Calculate the cyclomatic complexity of your program. What does
126	this figure tell you?}
127	%Cyclomatic complexity (CC) = E - N + p
128	%where E = the number of edges of the graph
129	%N = the number of nodes of the graph
130	%p = the number of connected components
131	%http://www.sei.cmu.edu/str/descriptions/cyclomatic.html
132	Hopefully you mean McCabe's cyclomatic complexity\\
133	% e = no of arcs \| n = no of nodes
134	e-n+2 \| 18 - 14 + 2 = 18 - 16 = 2 \\ %men vad säger nu detta
135	This tells us the number of tests we have to do to cover
136	each path in the program. It could also be used to give a
137	estimation of how complex the final software will be. If
138	higher then 20 it should be seen as a high risk project,
139	and if higher then 50 as a very high risk project. %nuffrorna kommer från http://www.sei.cmu.edu/str/descriptions/cyclomatic.html
140	\section{OO metrics}
141	\textbf{Measuring the use cases}
142	%vi skall använda templaten, och bifoga denna...
143	\subsection{Measure the use case specifications shown in Design 1 using the
144	chosen use case metrics suite from the lecture}
145	svar
146	\subsection{Measure the use case specifications shown in Design 2 using the
147	chosen use case metrics suite from the lecture}
148	svar
149	\subsection{Write a short section (up to ½ page) with answers to the following
150	questions:}
151	\subsubsection{Which of the two systems presented can be expected to be
152	more complex and why?}
153	svar
154	\subsubsection{Which of the two systems can be expected to require more
155	effort to be built? Why?}
156	svar
157	\textbf{Measuring designs}
158	\subsection{Measure the class diagram presented in Design 1 using the CK metrics suite presented on the
159	lecture.}
160	svar
161	\subsection{Measure the class diagram presented in Design 2 using
162	the CK metrics suite presented on the lecture.}
163	svar
164	\subsection{Measure the code in the files .java from Design 1 with the CK metrics suite
165	presented on the lecture.}
166	svar
167	\subsection{ Measure the code in the files .java
168	from Design 2 with the CK metrics suite presented on the lecture.}
169	svar
170	\subsection{Write a short section (up to ½ page) with answers to the following
171	questions:}
172	\subsubsection{Which of the metrics could not be computed based on the class
173	diagrams? Why?}
174	svar
175	\subsubsection{Which of the two systems is more complex? Why?}
176	svar
177	\subsubsection{Which method of gathering metrics - from UML designs or source
178	code - is less time consuming?}
179	svar
180	\section{External product attributes}
181	\subsection{Describe how the external product attributes differ from the
182	internal ones. Describe the connection between external and
183	internal product attributes.}
184	The internal attributes can be measured from within the
185	system (like loc etc) while for the external attributes
186	one must look at the finished product to se the external
187	attributes. Also in general internal attributes are
188	considered easier to measure (and then predict) then the
189	external attributes.
190
191	This is partly since the internal attributes can be
192	measured more ``directly'' then the external. For
193	instance loc is easy to count while usability is a lot
194	harder to measure. For the internal attributes one can
195	expect to be able to get absolute values while on the
196	external attributes one can expect them to be less
197	accurate.
198
199	However several of the internal attributes (if not all)
200	does affect the external attributes in a way that can
201	(in most cases) be predicted. One can for instance say
202	that in a specific solution if the loc is increased
203	(both with comments) then one could expect to get a
204	higher maintainability. Also most of the external
205	attributes can be affected via the internal if the
206	developers keep the external attributes in mind.
207
208	In most cases (if not always) the customer of the product
209	is more interested in the external attributes. Does this
210	mean that the external attributes are of ``greater''
211	value to the team developing the product?
212
213	Not always but in many cases. Also one should keep in
214	mind that just because the external attributes are more
215	important that the internal could be forgotten.
216	%\subsection{Assume that you are working at the company that
217	%mainly specializes on developing of web-based applications.
218	%Your manager gives you an assignment to develop a software
219	%quality model for the company. The model should show external
220	%quality attributes, corresponding internal attributes and
221	%metrics. Present the assumptions that you will use while
222	%creating of the quality model. Provide an explanatory text
223	%for your model.} %Jag tyckte inte om att läsa den texten;)
224	\subsection{Assume that you are working at a company that
225	mainly specializes in development of web-based applications.
226	Your manager gives you an assignment to develop a software
227	quality model for the company. The model should show external
228	quality attributes, corresponding internal attributes and
229	metrics. Present the assumptions that you will use while
230	creating the quality model. Provide an explanatory text
231	for your model.}
232	%huh? - jag kollar på denna... men vill du ha den så;)
233	max 8 sidor (totalt; inte på denna;)
234	\end{document}