C語言loops基礎程序作寫代寫、writing a C program
C語言loops基礎程序作寫代寫、writing a C program
In this project you will demonstrate your understanding of loops and if statements by writing a program
that sequentially processes a file of text data. You are also expected to make use of functions (Chapters
5 and 6) and arrays (Chapter 7, covered in lectures in Weeks 6 and 7). The sample solution that will be
provided to you will also make use of structures (Chapter 8), and you may do likewise if you wish. But
there is no requirement for you to make use of struct types, and they will not have been covered in
lectures before the due date.
Sequential Data
Scientific and engineering datasets are often stored in text files using comma separated values (.csv
format) or tab separated values (.tsv format), usually with a one- or two-line header describing the
contents of the columns.
The data file used in this project was generated by the City of Melbourne, and uses .tsv format to
record pedestrians as measured by counting devices at a number of locations around the CBD1
. That data
file was then edited to make the test files provided on the LMS. In particular, some of the columns were
removed, some of the columns were reformatted, the hourly counts were aggregated into daily counts,
and three recording stations were extracted into separate files, with the rest of the recording stations
discarded. Smaller subsets of those three data files were also then prepared, see the LMS and Assignment
to a full set of data files. The first few and last two lines of the file pedestrians-melbcent-full.tsv
are:
# Melbourne Central Daily Pedestrian Counts
# yyyy mm dd day daycount
2009 06 01 2 22663
2009 06 02 3 22960
2009 06 03 4 23618
...
2018 02 27 3 33722
2018 02 28 4 33164
There will always be two heading lines in all input files, and then rows of five values separated by
“tab” characters (’\t’ in C). Once the first two lines have been bypassed, each data line can be read
using scanf("%d%d%d%d%d",...). The number in the fifth column is the pedestrian count for the day
indicated by the dd/mm/yyyy date, with the fourth field, day, indicating the day of the week, numbered
from Sunday to Saturday as integers 1 to 7 respectively. You can open these data files using jEdit if
you wish to view them, and they can also be manipulated using Excel.
Stage 1 – Control of Reading and Printing (marks up to 4/10)
Your first program should read the entire input dataset into a collection of five parallel arrays (or, if you
are adventurous, an array of struct), counting the data rows as they are read. The two heading lines
should be discarded and not processed in any way.
1
See http://go.unimelb.edu.au/sht6 for a link through to the source dataset, which was accessed from https:
//data.melbourne.vic.gov.au on 28 March 2018.
1
Once the entire dataset is in memory, your program should print the first and last of the input records,
and the total number of data lines that were read. The output from your program for this stage for file
pedestrians-melbcent-full.tsv must be:
mac: myass1 < pedestrians-melbcent-full.tsv
S1: total data lines = 3067 days
S1: first data line = 01/06/2009, 22663 people counted
S1: last data line = 28/02/2018, 33164 people counted
mac:
Note that the input is to be read from stdin in the usual manner, via “<” input redirection at the shell
level; and that you should not try and make use of the file manipulation functions described in Chapter 11.
You may (and should) assume that at most 10,000 days will be covered by the input data. Note that
some of the marking process will be automatic, and you should seek to exactly reproduce these three
output lines. Further examples can be found on the FAQ page linked from the LMS.
Stage 2 – Computing Stuff (marks up to 6/10)
Now add further functionality to your program so that it computes the number of entries there would be
in the given date range if every day had a corresponding line in the data file. For the same data file, these
additional lines should appear in your program’s output:
S2: range spanned = 3195 days
S2: coverage ratio = 96.0%
The range spanned is to total number of days (including the two endpoints) in the date range that you
reported in Stage 1, and the coverage ratio is the percentage of dates in this range for which the data
file contains pedestrian count records. In this example, there are 3195 days between 1 June 2009 and 28
February 2018 (inclusive), and 3067/3195 is 96.0%. You can check date range calculations using Excel.
Note that code should be shared between the stages through the use of functions wherever it is
possible to do so. In particular, there shouldn’t be long (or even short) stretches of repeated or similar
code appearing in different places in your program. Functions should also be used to break up long runs
of code, to make them more understandable, even if those functions are only called once. As a general
rule of thumb, functions shouldn’t be longer than a single screen in the editor. If they are, break that code
up further into smaller functions.
You may assume that the data records are presented in strictly increasing date order, and that you
are not required to sort them. Note also that there will be no duplicate dates. On the other hand, you
must not assume that there will be any particular year range in the input data, and must not assume that
the months and dates will be exhaustive (there may be missing days, missing months and maybe even
missing years).
Stage 3 – Make Summary Report (marks up to 8/10)
Modify your program further so that it also generates a “by the month” listing showing the average
observed daily pedestrian numbers for each month for which there is any data provided in the input
listing. Months that have no daily data provided should not be included in the output. For this stage, the
required output for the test file pedestrians-melbcent-p100.tsv (with a total of 98 data lines) is:
S3: 06/2009 28/30 days covered, average count = 24.8k
S3: 07/2009 31/31 days covered, average count = 26.7k
S3: 08/2009 31/31 days covered, average count = 26.7k
S3: 09/2009 8/30 days covered, average count = 24.4k
where “k” means “thousands”. See the LMS for the full output associated with the test files.
2
Stage 4 – Find the Trend (marks up to 10/10)
The Melbourne City Council is concerned that pedestrian traffic is increasing, and that the footpaths are
becoming congested. To help them understand the growth rate over the sample period, further modify
your program so that the input data is split into NGRPS near-equal sized (in terms of data records in the
input file) groups of consecutive data lines from the input, where you should assume that NGRPS is to
be three at present. The group sizes should be computed so that they differ by at most one from each
other, and so that each input data line is in exactly one of the groups. There are several examples of the
required output linked from the FAQ page.
The average number of pedestrians for each day of the week for each of the groups should then be
computed, and plotted as a simple bar chart, to highlight any variations over the days of the week and
over the NGRPS groups. For the data file pedestrians-melbcent-full.tsv the additional output from
your program should be:
S4: group 0 data, 01/06/2009 to 20/03/2012, 1022 data records
S4: group 1 data, 21/03/2012 to 08/01/2015, 1022 data records
S4: group 2 data, 09/01/2015 to 28/02/2018, 1023 data records
S4: Sun, g0 = 22.2k |**********************
S4: Sun, g1 = 27.6k |****************************
S4: Sun, g2 = 28.8k |*****************************
S4: Mon, g0 = 24.4k |************************
S4: Mon, g1 = 27.6k |****************************
S4: Mon, g2 = 28.3k |****************************
S4: Tue, g0 = 24.9k |*************************
S4: Tue, g1 = 28.6k |*****************************
S4: Tue, g2 = 29.3k |*****************************
and so on, covering the other four days too, see the LMS for full output, where each ’*’ represents
(correctly rounded off) one thousand people. Note that NGRPS should be a #define in your program,
and that you should test your program using a range of values to ensure that the right output is produced.
Modifications to the Specification
There are bound to be areas where this specification needs clarification or correction. Refer to the
for updates to these instructions. There is already a range of information provided there that you need to
be aware of, with more to follow.
Real Software
If you want to explore a much more sophisticated analysis tool for this pedestrian data, go via the redirection
The Boring Stuff...
This project is worth 10% of your final mark. A rubric explaining the marking expectations will be
provided on the FAQ page.
You need to submit your program for assessment; detailed instructions on how to do that will be
posted on the LMS once submissions are opened. Submission will not be done via the LMS; instead you
will need to log in to a Unix server and submit your files to a software system known as submit. You can
(and should) use submit both early and often – to get used to the way it works, and also to check that
3
your program compiles correctly on our test system, which has some different characteristics to the lab
machines. Failure to follow this simple advice is highly likely to result in tears. Only the last submission
that you make before the deadline will be marked.
You may discuss your work during your workshop, and with others in the class, but what gets typed
into your program must be individual work, not copied from anyone else. So, do not give hard copy
or soft copy of your work to anyone else; do not “lend” your “Uni backup” memory stick to others
for any reason at all; and do not ask others to give you their programs “just so that I can take a look
and get some ideas, I won’t copy, honest”. The best way to help your friends in this regard is to say a
very firm “no” when they ask for a copy of, or to see, your program, pointing out that your “no”, and
their acceptance of that decision, is the only thing that will preserve your friendship. A sophisticated
program that undertakes deep structural analysis of C code identifying regions of similarity will be run
over all submissions in “compare every pair” mode. Students whose programs are so identified will be
referred to the Student Center for possible disciplinary action without further warning. This message is
the warning. Note also
that solicitation of solutions via posts to online forums, whether or not there is payment involved, is also
taken very seriously. In the past students have had their enrolment terminated for such behavior.
Deadline: Programs not submitted by 10:00am on Monday 30 30 April will lose penalty marks
at the rate of two marks per day or part day late. Students seeking extensions for medical or other
“outside my control” reasons should email [email protected] as soon as possible after those
circumstances arise. If you attend a GP or other health care professional as a result of illness, be sure
to take a Health Professional Report form with you (get it from the Special Consideration section of the
Student Portal), you will need this form to be filled out if your illness develops in to something that later
requires a Special Consideration application to be lodged. You should scan the HPR form and send it in
connection with any non-Special Consideration assignment extension requests.
Marks and a sample solution will be available on the LMS by Monday 14 May.
And remember, programming is fun!
http://www.6daixie.com/contents/13/1347.html
我們的方向領域:window編程 數值算法 AI人工智能 金融統計 計量分析 大數據 網絡編程 WEB編程 通訊編程 遊戲編程多媒體linux 外掛編程 程序API圖像處理 嵌入式/單片機 數據庫編程 控制臺 進程與線程 網絡安全 匯編語言 硬件編程 軟件設計 工程標準規等。其中代寫代做編程語言或工具包括但不限於以下範圍:
C/C++/C#代寫
Java代寫
IT代寫
Python代寫
輔導編程作業
Matlab代寫
Haskell代寫
Processing代寫
Linux環境搭建
Rust代寫
Data Structure Assginment 數據結構代寫
MIPS代寫
Machine Learning 作業 代寫
Oracle/SQL/PostgreSQL/Pig 數據庫代寫/代做/輔導
Web開發、網站開發、網站作業
ASP.NET網站開發
Finance Insurace Statistics統計、回歸、叠代
Prolog代寫
Computer Computational method代做
因為專業,所以值得信賴。如有需要,請加QQ:99515681 或郵箱:[email protected]
微信:codinghelp
C語言loops基礎程序作寫代寫、writing a C program