CS计算机代考程序代写 ASSIGNMENT #1: LINUX CS246, FALL 2021

ASSIGNMENT #1: LINUX CS246, FALL 2021

Assignment #1: Linux

Due Date 1: Friday, September 17, 2021, 5:00 pm EST
Due Date 2: Friday, September 24, 2021, 5:00 pm EST

Online Quiz: Monday, September 27, 2021, 5:00 pm EST

Questions 1 and 2 are due on Due Date 1; the remainder of the assignment is due on Due Date 2. If you joined the
course within two days of Due Date 1, then the entire assignment is due on Due Date 2. You must submit the online
quiz on Learn by the Quiz date.

Topics that must have been completed before starting Due Date 1:

1. Linux: The Teaching Environment

2. Linux: Interacting with the Shell

3. Linux: Directories and Files

4. Linux: Regular Expressions

5. Handouts: Getting Started

6. Handouts: Linux Commands

Topics that must have been completed before starting Due Date 2:

1. Linux: bash scripts

2. Software Testing

Note 1: We suggest creating the directory ~/cs246/f21/a1 and creating all the assignment solutions in this directory.
Note 2: If you finish A1 DD1 i.e. questions 1 and 2 early, we strongly recommend that you start the other questions, since

debugging bash scripts can take a lot of time. Make sure that you take advantage of using the -x option to the shbang line
(though remove it from your submitted scripts!) if your scripts aren’t behaving as expected, so that you can see exactly
what is happening.

bash and Regular Expressions
1. 10 marks. Provide a Linux command line to accomplish each of the following tasks. Your answer in each subquestion

should consist of a single command or pipeline of commands, with no separating semicolons (;). (Please verify before
submitting that your solution consists of a single line. Use wc for this.) Before beginning this question, familiarize
yourself with the commands outlined on the Linux handout. Keep in mind that some commands have options not listed
on the sheet, so you may need to examine some manual pages. Note that some tasks refer to a file myfile.txt. No
myfile.txt is given. You should create your own version for testing.

(a) Print the 10th through 25th words (including the 10th and 25th words) in /usr/share/dict/words. You
may take advantage of the fact that the words in this file are each on a separate line. Place your command pipeline
in the file a1q1a.txt.

(b) Print the (non-hidden) file/directory names contained by the current directory, in reverse of the normal, alphabetical
order. Place your command pipeline in the file a1q1b.txt.

(c) Print the number of lines in the text file myfile.txt that do not contain the string cs246 (all in lower-case).
Place your command pipeline in the file a1q1c.txt.

(d) Print the first line that contains the string cs246 (all in lower-case) from the text file myfile.txt. Place your
command pipeline in the file a1q1d.txt.

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ASSIGNMENT #1: LINUX CS246, FALL 2021

(e) Print the number of lines in the text file myfile.txt that contain the string
linux.student.cs.uwaterloo.ca where each letter could be in either upper-case or lower-case. (Hint:
this is not as obvious as you may think–carefully re-read the special symbols and their meanings first!) Place your
command pipeline in the file a1q1e.txt.

(f) Print the names of all (non-hidden) files/directories in any subdirectory of the current directory whose names end
with lower-case .c (immediate subdirectories only, not subdirectories of subdirectories). Do not use find. (Hint:
there’s an easy way to do this using only ls if you’re creative with globbing patterns.) You do not need to worry
about what happens if there are no subdirectories or matches found. Place your command pipeline in the file
a1q1f.txt.

(g) Out of the first 20 lines of myfile.txt, how many contain at least one digit i.e. characters ’0’ to ’9’? Place the
command pipeline that prints this number in the file a1q1g.txt.

(h) Print the names of all (non-hidden) files/directories in the current directory whose names start with the lower-case
letter a, contain at least one lower-case letter b, and end with the lower-case letter .c. Place your command
pipeline in the file a1q1h.txt.

(i) Print a listing, in long form, of all non-hidden entries (files, directories, etc.) in the current directory that are
executable by at least one of owner, group, other (the other permission bits could be anything). You may assume
that you only need to have the execution bit set to ’x’ i.e. you do not need to worry about the special ’s’ permission
value. Do not attempt to solve this problem with find. Place your command pipeline in the file a1q1i.txt.

(j) Before attempting this subquestion, do some reading (either skim the manual page or have a look on the Web) on
the awk utility. In particular, be sure you understand the effect of the command:

awk ’{print $1}’ < myfile.txt Give a Linux pipeline that gives a sorted, duplicate-free list of userids currently signed on to the (school) machine the command is running on. Place your command pipeline in the file a1q1j.txt. 2. 9 marks. For each of the following text search criteria, provide a regular expression that matches the criterion, suitable for use with egrep. Your answer in each case should be a text file that contains just the regular expression (i.e., you don’t need to include the egrep command in your submitted solution), on a single line (again, use wc to verify this). If your pattern contains special characters, enclose it in quotes. (a) Lines that contain both cs246 and cs247, in lower-case. Place your answer in the file a1q2a.txt. (b) Lines that contain nothing but a single occurrence of laughter, where laughter is defined as a string of the form Hahahahahahahahahahahahahaha!, with arbitrarily many ha’s. The string must start with H and end with !. Place your answer in the file a1q2b.txt. (c) Lines that contain nothing but a single occurrence of generalized laughter, which is like ordinary laughter, except that there can be arbitrarily many (but at least one) a’s between each pair of consecutive H/h’s. (For example: Haahahaaaa!) Place your answer in the file a1q2c.txt. (d) Lines that contain at least one lower-case a and at least two lower-case b’s. Place your answer in the file a1q2d.txt. (e) Lines consisting of a definition of a single C variable of type int, without initialization, optionally preceded by unsigned, and optionally followed by any single line // comment. Example: int varname; // optional comment You may assume that all of the whitespace in the line consists of space characters (no tabs). You may also assume that varname will not be a C keyword (i.e., you do not have to try to check for this with your regular expression). If you don’t remember the rules for naming a C variable, please consult https://www.programiz.com/ c-programming/c-variables-constants Place your answer in the file a1q2e.txt. Page 2 of 9 https://www.programiz.com/c-programming/c-variables-constants https://www.programiz.com/c-programming/c-variables-constants ASSIGNMENT #1: LINUX CS246, FALL 2021 Hints • Lecture “Software Testing: Examples” gives an example of how the produceOutputs and runSuite scripts (Q3-Q5) should be used. • Lecture “Pipes” gives an example of how to substitute the output of one bash command as the arguments to another bash command. It also explains why you shouldn’t use echo combined with cat to output the contents of a file. • Lecture “Exercise: good password” gives an example of how to redirect standard output to standard error. • It is up to the person running the script to specify the path to the program to be tested as part of the command-line argument information. Your script should not make any assumptions about the location of the program executable. Note that questions 3-5 all follow the same error-handling in terms of validating the command-line arguments for each of produceOutputs and runSuite. The following sample execution shows you that the error messages are being redirected to the standard error stream, and that the shell script exit code is non-zero. # Invalid number of command-line arguments. $ ./produceOutputs 1> err1.stdout 2> err1.stderr
$ echo $?
1
$ cat err1.stdout
$ cat err1.stderr
Incorrect number of arguments
$ ./produceOutputs a b c 1> err2.stdout 2> err2.stderr
$ echo $?
1
$ cat err2.stdout
$ cat err2.stderr
Incorrect number of arguments
# Test suite file that cannot be read.
$ ./produceOutputs no_read.args ./my_factorial_correct 1> err3.stdout 2> err3.stderr
$ echo $?
1
$ cat err3.stdout
$ cat err3.stderr
no_read.args is not readable
# Program that cannot be executed.
$ ./produceOutputs test_suite.txt no_execute.sh 1> err4.stdout 2> err4.stderr
$ echo $?
1
$ cat err4.stdout
$ cat err4.stderr
no_execute.sh is not executable
$ ./produceOutputs test_suite.txt ./my_factorial_correct 1> good.stdout 2> good.stderr
$ echo $?
0
$ cat good.stdout
$ cat good.stderr

3. 5 marks. Write a bash script called produceOutputs that is invoked as follows:

./produceOutputs suite-file program

The argument suite-file is the name of a file containing a list of filename stems (more details below), and the
argument program is the name of a program to be run.

The produceOutputs script runs program on each test in the test suite and, for each test, creates a file that contains
the output produced for that test.

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ASSIGNMENT #1: LINUX CS246, FALL 2021

The file suite-file contains a list of stems, from which we construct the names of files containing the command-line
arguments used by each test. Stems will not contain spaces. For example, suppose our suite file is called suite.txt
and contains the following entries:

test1 test2
reallyBigTest

Then our test suite consists of three tests. The first one (test1) will use the file test1.args. The second one
(test2) will use the file test2.args. The last one (reallyBigTest) will use the file reallyBigTest.args.

A sample run of produceOutputs would be as follows:

./produceOutputs suite.txt ./myprogram

The script will then run ./myprogram three times, once for each test specified in suite.txt:

• The first time, it will run ./myprogramwith command-line arguments provided to the program from test1.args.
The results, captured from standard output, will be stored in test1.out.

• The second time, it will run ./myprogramwith command-line arguments provided to the program from test2.args.
The results, captured from standard output, will be stored in test2.out.

• The third time, it will run ./myprogram with command-line arguments provided to the program from
reallyBigTest.args. The results, captured from standard output, will be stored in reallyBigTest.out.

Note that if the test suite contains a stem but a corresponding .args file is not present, the program is run without
providing any command-line arguments.

Your script must also check for incorrect number of command-line arguments to produceOutputs and invalid
command-line arguments as described in the preceding “Hints” section. If such an error condition arises, print an
informative error message to standard error (the exact message is up to you) and abort the script with a non-zero exit
status (exact value is up to you). For example, running produceOutputs with .args or .out files with invalid
permisisons would produce output and exit codes similar to the following:

$ ls -l | egrep “test|no_”
-rw-r—– 1 cs246 cs246 0 May 31 12:41 no_execute.sh
–w-r—– 1 cs246 cs246 0 Aug 11 14:45 no_read.args
-r–r—– 1 cs246 cs246 0 May 4 10:08 no_write.out
-rw-r—– 1 cs246 cs246 0 May 4 10:08 test0.args
-rw-r—– 1 cs246 cs246 2 May 4 10:08 test1.args
-rw-r—– 1 cs246 cs246 3 May 4 10:08 test2.args
-rw-r—– 1 cs246 cs246 2 May 4 10:08 test3.args
–w-r—– 1 cs246 cs246 0 Aug 11 14:45 test4.args
-rw-r—– 1 cs246 cs246 24 May 4 10:14 test_suite.txt
-rw-r—– 1 cs246 cs246 47 Jun 1 15:30 test_suite_V2.txt
# Example of test run without any errors.
$ cat test_suite.txt
test0
test1
test2
test3
$ ./produceOutputs test_suite.txt ./my_factorial_correct 1> good.stdout 2> good.stderr
$ echo $?
0
$ cat good.stdout
$ cat good.stderr
$ ls -l | egrep “test|no_”
-rw-r—– 1 cs246 cs246 0 May 31 12:41 no_execute.sh
–w-r—– 1 cs246 cs246 0 Aug 11 14:45 no_read.args
-r–r—– 1 cs246 cs246 0 May 4 10:08 no_write.out
-rw-r—– 1 cs246 cs246 0 May 4 10:08 test0.args

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ASSIGNMENT #1: LINUX CS246, FALL 2021

-rw-r—– 1 cs246 cs246 0 Aug 11 15:00 test0.out
-rw-r—– 1 cs246 cs246 2 May 4 10:08 test1.args
-rw-r—– 1 cs246 cs246 9 Aug 11 15:00 test1.out
-rw-r—– 1 cs246 cs246 3 May 4 10:08 test2.args
-rw-r—– 1 cs246 cs246 14 Aug 11 15:00 test2.out
-rw-r—– 1 cs246 cs246 2 May 4 10:08 test3.args
-rw-r—– 1 cs246 cs246 7 Aug 11 15:00 test3.out
–w-r—– 1 cs246 cs246 0 Aug 11 14:45 test4.args
-rw-r—– 1 cs246 cs246 24 May 4 10:14 test_suite.txt
-rw-r—– 1 cs246 cs246 47 Jun 1 15:30 test_suite_V2.txt
$ rm *.stdout *.stderr test*.out
$ ls -l | egrep “test|no_”
-rw-r—– 1 cs246 cs246 0 May 31 12:41 no_execute.sh
–w-r—– 1 cs246 cs246 0 Aug 11 14:45 no_read.args
-r–r—– 1 cs246 cs246 0 May 4 10:08 no_write.out
-rw-r—– 1 cs246 cs246 0 May 4 10:08 test0.args
-rw-r—– 1 cs246 cs246 2 May 4 10:08 test1.args
-rw-r—– 1 cs246 cs246 3 May 4 10:08 test2.args
-rw-r—– 1 cs246 cs246 2 May 4 10:08 test3.args
–w-r—– 1 cs246 cs246 0 Aug 11 14:45 test4.args
-rw-r—– 1 cs246 cs246 24 May 4 10:14 test_suite.txt
-rw-r—– 1 cs246 cs246 47 Jun 1 15:30 test_suite_V2.txt
# Example of test run where cannot read from or write to some files.
$ cat test_suite_V2.txt
test0
test1
no_read
no_write
test2
test3
test4
$ ./produceOutputs test_suite_V2.txt ./my_factorial_correct 1> err.stdout 2> err.stderr
$ echo $?
1
$ cat err.stdout
$ cat err.stderr
no_read.args is not readable
no_write.out is not writable
test4.args is not readable
$ ls -l | egrep “test|no_”
-rw-r—– 1 cs246 cs246 0 May 31 12:41 no_execute.sh
–w-r—– 1 cs246 cs246 0 Aug 11 14:45 no_read.args
-r–r—– 1 cs246 cs246 0 May 4 10:08 no_write.out
-rw-r—– 1 cs246 cs246 0 May 4 10:08 test0.args
-rw-r—– 1 cs246 cs246 0 Aug 11 15:00 test0.out
-rw-r—– 1 cs246 cs246 2 May 4 10:08 test1.args
-rw-r—– 1 cs246 cs246 9 Aug 11 15:00 test1.out
-rw-r—– 1 cs246 cs246 3 May 4 10:08 test2.args
-rw-r—– 1 cs246 cs246 14 Aug 11 15:00 test2.out
-rw-r—– 1 cs246 cs246 2 May 4 10:08 test3.args
-rw-r—– 1 cs246 cs246 7 Aug 11 15:00 test3.out
–w-r—– 1 cs246 cs246 0 Aug 11 14:45 test4.args
-rw-r—– 1 cs246 cs246 24 May 4 10:14 test_suite.txt
-rw-r—– 1 cs246 cs246 47 Jun 1 15:30 test_suite_V2.txt

You can find an example of the expected output of produceOutputs in the file sample output.txt in the
directory a1/codeForStudents/q3 in your Git repository. Using the contents of this directory, running your
script as:

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ASSIGNMENT #1: LINUX CS246, FALL 2021

./produceOutputs test_suite.txt ./my_factorial_correct

should produce files named test0.out, test1.out, test2.out, and test3.out identical to those provided
to you as examples in the same directory.

Note on purpose of this script: This script will be useful in situations where we provide you with a binary version of
a program (but not its source code) that you must implement. By creating your own test cases (.args files) and then
using this script to produce the intended output you will have something to compare with when you implement your
own solution (see the next question for how to automate the comparisons). Only the program being run will be able
to tell if the provided command-line arguments are correct or not. It is not something that produceOutputs can
determine.

4. 10 marks. Create a bash script called runSuite that is invoked as follows:

./runSuite suite-file program

The argument suite-file is the name of a file containing a list of filename stems (more details below), and the
argument program is the name of the program to be run.

In summary, the runSuite script runs program on each test in the test suite (as specified by suite-file) and
reports on any tests whose output does not match the expected output. Note that if all of the tests are passed, no output
will be produced by the script.

The file suite-file contains a list of stems, from which we construct the names of files containing the command-
line arguments and expected output of each test. Stems will not contain spaces. For example, suppose our suite file is
called suite.txt and contains the following entries:

test1 test2
reallyBigTest

Then our test suite consists of three tests. The first one (test1) will use the file test1.args to hold its command-
line arguments, and test1.out to hold its expected output. The second one (test2) will use the file test2.args
to hold its command-line arguments, and test2.out to hold its expected output. The last one (reallyBigTest)
will use the file reallyBigTest.args to hold its command-line arguments, and reallyBigTest.out to hold
its expected output.

A sample run of runSuite would be as follows:

./runSuite suite.txt ./myprogram

The script will then run ./myprogram three times, once for each test specified in suite.txt:

• The first time, it will run ./myprogramwith command-line arguments provided to the program from test1.args.
The results, captured from standard output, will be compared with the contents of test1.out.

• The second time, it will run ./myprogramwith command-line arguments provided to the program from test2.args.
The results, captured from standard output, will be compared with the contents of test2.out.

• The third time, it will run ./myprogram with command-line arguments provided to the program from
reallyBigTest.args. The results, captured from standard output, will be compared with the contents of
reallyBigTest.out.

Note that if the test suite contains a stem but a corresponding .args file is not present, the program is run without
providing any command-line arguments.

If the output of a given test case differs from the expected output, print the following to standard output (assuming test
test2 failed):

Test failed: test2
Args:
(contents of test2.args, if it exists)
Expected:
(contents of test2.out)
Actual:
(contents of the actual program output)

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ASSIGNMENT #1: LINUX CS246, FALL 2021

with the (contents …) lines replaced with actual file contents, without any changes, as described. The literal output
Args: must appear, even if the corresponding file does not exist. Note that there is no whitespace after the colon for
each of Args:, Expected:, and Actual: except for the newline character.

An example of such execution would look like:

$ ls -l | egrep “test|no_”
–w-r—– 1 cs246 cs246 0 May 4 11:20 no_such_file.args
-rw-r—– 1 cs246 cs246 0 May 4 11:15 test0.out
-rw-r—– 1 cs246 cs246 2 May 4 11:13 test1.args
-rw-r—– 1 cs246 cs246 9 May 4 11:15 test1.out
-rw-r—– 1 cs246 cs246 3 May 4 11:13 test2.args
-rw-r—– 1 cs246 cs246 14 May 4 11:15 test2.out
-rw-r—– 1 cs246 cs246 2 May 4 11:13 test3.args
-rw-r—– 1 cs246 cs246 7 May 4 11:15 test3.out
-rw-r—– 1 cs246 cs246 4 May 4 11:13 test4.args
-rw-r—– 1 cs246 cs246 0 May 4 11:15 test4.out
–w-r—– 1 cs246 cs246 6 May 4 11:13 test5.args
-rw-r—– 1 cs246 cs246 22 May 4 11:15 test5.out
-r–r—– 1 cs246 cs246 8 May 4 11:15 test6.out
-rw-r—– 1 cs246 cs246 30 Aug 11 15:33 test_suite1.txt
-rw-r—– 1 cs246 cs246 55 Aug 11 15:27 test_suite2.txt
-rw-r—– 1 cs246 cs246 55 Aug 11 15:27 test_suite3.txt
# runSuite runs successfully
$ cat test_suite1.txt
test0
test1
test2
test3
test4
$ ./runSuite test_suite1.txt ./my_factorial_buggy 1> t1.stdout 2> t1.stderr
$ echo $?
0
$ cat t1.stdout
Test failed: test3
Args:
0
Expected:
0! = 1
Actual:
0! = 0
$ cat t1.stderr
# runSuite runs unsuccessfully since a .args file exists but cannot be read
$ cat test_suite2.txt
test0
test1
test2
test3
test4
test5
test6
no_such_file
$ ./runSuite test_suite2.txt ./my_factorial_buggy 1> t2.stdout 2> t2.stderr
$ echo $?
1
$ cat t2.stdout
Test failed: test3
Args:
0

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ASSIGNMENT #1: LINUX CS246, FALL 2021

Expected:
0! = 1
Actual:
0! = 0
Test failed: test6
Args:
Expected:
-3! = 1
Actual:
$ cat t2.stderr
test5.args is not readable
File no_such_file.out does not exist or is not readable
# runSuite exits early since a .out file cannot be read
$ cat test_suite3.txt
test0
test1
test2
no_such_file
test3
test4
test5
test6
$ ./runSuite test_suite3.txt ./my_factorial_buggy 1> t2.stdout 2> t2.stderr
$ echo $?
1
$ cat t3.stdout
$ cat t3.stderr
File no_such_file.out does not exist or is not readable

Follow these output specifications very carefully. You will lose a lot of marks if your output does not match them.
If you need to create temporary files, create them in /tmp, and use the mktemp command to prevent name duplications.
Also be sure to delete any temporary files you create in /tmp.
You can find an example of the expected output of runSuite in the file buggy output.txt in the directory
a1/codeForStudents/q4 on your Git repository. Using the contents of this directory, running your script as:

./runSuite test_suite1.txt ./my_factorial_buggy

should produce an output identical to the example provided to you in the file buggy output.txt in the same direc-
tory.

Note: Do NOT attempt to compare outputs by storing them in shell variables, and then comparing the shell variables.
This is a very bad idea, and it does not scale well to programs that produce large outputs. We reserve the right to deduct
marks (on this and all assignments) for bad solutions like this would be.

You can get most of the marks for this question by fulfilling the above requirements. For full marks, your script
must also check for the following error conditions:

• incorrect number of command-line arguments to runSuite as described in the preceding “Hints” section

• incorrect permissions on the command-line arguments to runSuite as described in the preceding “Hints” section

• if a .args file exists but isn’t readable,

(a) produce an error message,
(b) do not run the test,
(c) do not compare the outputs i.e. just move on to the next test, and
(d) ensure that the script will eventually terminate with a non-zero exit status

• missing or unreadable .out file (for example, the suite file contains an entry xxx, but xxx.out doesn’t exist or
is unreadable), in which case print an informative error message to standard error and terminate the script with a
non-zero exit status.

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ASSIGNMENT #1: LINUX CS246, FALL 2021

5. 15 marks. In this question, you will generalize the produceOutputs and runSuite scripts that you created in
questions 3 and 4. As they are currently written, these scripts cannot be used with programs that take input from standard
input. For this problem, you will enhance produceOutputs and runSuite so that, in addition to (optionally)
passing command-line arguments to the program being executed, the program can also be (optionally) provided input
from standard input. The interface to the scripts remains the same:

./produceOutputs suite.txt ./myprogram

./runSuite suite.txt ./myprogram

The format of the suite file remains the same. But now, for each testname in the suite file, there might be an
optional testname.in. If the file testname.in is present, then the script (produceOutputs or runSuite)
will run myprogram with the contents of testname.args passed on the command-line as before and the contents
of testname.in used for input on stdin. If testname.in is not present, then the behaviour is almost identical
to question 3/4 (see below for a difference in the output).

The output of runSuite is changed to now also show the input provided to a test if the test failed. Assuming test
test2 from Q4 failed, the output generated by the updated runSuite is as follows:

Test failed: test2
Args:
(contents of test2.args, if it exists)
Input:
(contents of test2.in, if it exists)
Expected:
(contents of test2.out)
Actual:
(contents of the actual program output)

with the (contents …) lines replaced with actual file contents, as described. The literal output Args: and Input:
must appear, even if the corresponding files do not exist. Note that there is no whitespace after the colon for each of
Args:, Input:, Expected:, and Actual: except for the newline character.

You can find an example of the expected output of the updated produceOutputs and runSuite in the directory
a1/codeForStudents/q5/sample output.txt on your Git repository. Using the contents of this directory,
running your script as:

./produceOutputs test_suite1.txt ./my_factorial_correct

should produce files named test0.out, test2.out, test3.out, and test4.out identical to those provided
to you as examples in the same directory.

And using the contents of this directory, running your script as:

./runSuite test_suite1.txt ./my_factorial_buggy

should produce an output identical to the example provided to you in the file sample output.txt in the same
directory.

All error-checking that was required in questions 3 and 4 is required here as well.

(a) Modify produceOutputs to handle input from standard input.

(b) Modify runSuite to handle input from standard input.

Note: To get this working should require only very small changes to your solution to questions 3 and 4.

Submission
The following files are due at Due Date 1: a1q1a.txt, a1q1b.txt, a1q1c.txt, a1q1d.txt, a1q1e.txt, a1q1f.txt,
a1q1g.txt, a1q1h.txt, a1q1i.txt, a1q1j.txt, a1q2a.txt, a1q2b.txt, a1q2c.txt, a1q2d.txt, a1q2e.txt.
The following files are due at Due Date 2: produceOutputs, runSuite, produceOutputs, runSuite.

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