程序代写 data structure algorithm Last Updated: 2021-09-28 Tue 15:18

Last Updated: 2021-09-28 Tue 15:18
CSCI 2021 Project 1: C Programming
Due: 11:59pm Mon 10/04/2021
Approximately 4.0% of total grade
Submit to Gradescope (Submission Now Open)
Projects are individual work: no collaboration with other students is allowed. Seek help from course staff if you get stuck for too long.
CODE DISTRIBUTION: p1-code.zip
VIDEO OVERVIEW: Canvas – Week 3 Videos
CHANGELOG:
Tue Sep 28 03:11:49 PM CDT 2021
A bug in the test cases for Problem 2 has been reported and corrected. This bug affects several tests for stock_plot() where correct code would not pass tests. To patch the tests, download new versions of the following two files and copy them into your project directory:
test_stock2.org test_stock_funcs.c
All students will need to do this in order to pass the tests. The Gradescope autograder has been updated with these fixes as has the p1-code.zip codepack. Thanks to the student who brought this to our attention.
Mon Sep 27 12:54:59 PM CDT 2021
The submission link for Project 1 is now open on Gradescope.
Fri Sep 24 04:21:44 PM CDT 2021
Added a link to the project overview video on Canvas and fixed the broken images for the Gradescope upload instructions.
Tue Sep 21 04:25:26 PM CDT 2021
The file stock.h had a few comments that have been removed. These were discarded fields in the stock_t type and an incorrect comment mentioning a hashset. They do not affect any other parts of the project but have been removed to reduce confusion such as what appeared in Post 41.
Table of Contents
1. Introduction
1.1. Grading Criteria
1.2. Getting Started 2. Download Code and Setup
2.1. Makefile
2.2. Automated Tests 3. Problem 1: Stock Plotting
3.1. Overview and Demo
3.2. Outline of stock_funcs.c 3.3. Editing and Testing
3.4. Implementation Notes
3.5. Grading Criteria for Problem 1
4. Problem 2: Completing Stock Plot 4.1. Overview
4.2. Setting Min/ 4.3. /Sell Index 4.4. Stock Files
4.5. Counting Lines
4.6. Loading Stock Files
4.7. Plotting Stocks
4.8. Optional MAKEUP CREDIT 4.9. Grading Criteria for Problem 2
5. Problem 3: Tree Sets in C 5.1. Overview
5.2. treeset_main Demonstration
5.3. tree_funcs.c: tree functions
5.4. treeset_main.c: main function / application 5.5. Grading Criteria for Problem 3

6. Project Submission
6.1. Submit to Gradescope
6.2. Late Policies
1 Introduction
Basic application programming in C is an essential step downward towards the lower levels of computing. This project explores fundamental aspects of getting work done in C:
Dynamic memory management with malloc()/free() Reading data from files in text format
Displaying information to the screen
Reading commands from users in interactive programs Building data structures with C structs
The assignment is divided into several problems utilizing many of the above techniques.
Problem 1 implements a few simple function surrounding a struct representing stock prices. Problem 2 builds on the previous routines to complete a stock plotting program.
Problem 3 builds a simple binary tree application which stores unique strings.
Problems 1 and 2 build on each other and are somewhat easier than Problem 3. Strong consider going in order on the Project to take advantage of the structure in early problems before reaching the more open-ended final problem.
1.1 Grading Criteria
Credit for this assignment will be given based on two categories.
Manual Inspection Criteria (~50%): Each problem has a checklist of things that graders will look for. The checklist is in the spec and often contains hints on what to do. Make sure you have a look at these.
Automated Testing (~50%): Each problem has tests associated with it along with instructions on how to run those tests from the command line. Tests require that code compiles and runs according to the descriptions given so make sure you verify that these work.
1.2 Getting Started
Take the following steps to get started
1. Download the code associated with the project linked at the top of the spec. Unzip it and examine some of the provided code.
2. Examine the overview of the files provided listed in the Download and Setup section. This gives brief descriptions of files that already exist and those that you must create.
3. Pick a problem and read. There is a lot of information and many examples provided for each problem. Reading this will help you write the correct code earlier rather than later.
4. Ask questions: if its not clear how to proceed, put up a Piazza post or visit an office hour.
5. Get coding: don’t wait to start for too long as this will greatly increase your stress level an potentially result in late
submissions.
6. Familiarize yourself with the late submission policy for assignments so you are not caught off guard. No submissions will
be accepted more than 48 hours after the deadline.
2 Download Code and Setup
Download the code pack linked at the top of the page. Unzip this which will create a project folder. Create new files in this folder. Ultimately you will re-zip this folder to submit it.
File
stock_funcs.c
stock_demo.c
stock_main.c
stock.h
State
Provided
EDIT Provided Provided Provided
Notes
Build file to compile all programs
Problem 1/2 functions to write
Problem 1/2 demo code to show some function invocations Problem 2 main function, do not edit
Problem 1/2 header file
Makefile

File State
Notes
test_stock_funcs.c Testing
data/stock-ascending.txt Data data/stock-valley.txt Data data/stock-jagged.txt Data … Data
treeset.h Provided treeset_funcs.c CREATE treeset_main.c CREATE
data/stranger-demo.script Data data/1.tree Data data/2.tree Data data/big.tree Data …
TESTING
testy Testing test-results/ Testing test_stock1.org Testing test_stock2.org Testing test_treeset.org Testing
2.1 Makefile
A Makefile is provided as part of this project.
make is the oldest. The instructions and dependencies to create programs are written in a Makefile which is then interpreted by the make program which will run gcc and other commands to create programs.
Use this Makefile by issuing commands like make prob1
Testing file for Problems 1 & 2
Data files for problems 1 & 2
Problem 3 header file
Problem 3 functions to write Problem 3 main function to write
Problem 3 sample input scripts to main program Problem 3 sample tree set save files
Test running script
Directory in which temporary testing files are written Problem 1 tests
Problem 2 tests
Problem 3 tests
Building programs in C is a bit tedious and most folks use build systems of which
> make prob2 # build problem 2 main program
gcc -Wall -Wno-comment -Werror -g -c stock_main.c
gcc -Wall -Wno-comment -Werror -g -c stock_funcs.c
gcc -Wall -Wno-comment -Werror -g -o stock_main stock_main.o stock_funcs.o
> make clean # remove all programs/binary object files
rm -f stock_main stock_demo test_stock_funcs treeset_main *.o
> make prob3 # build problem 3 main program
gcc -Wall -Wno-comment -Werror -g -c treeset_main.c
gcc -Wall -Wno-comment -Werror -g -c treeset_funcs.c
gcc -Wall -Wno-comment -Werror -g -o treeset_main treeset_main.o treeset_funcs.o
> make clean # remove all programs/binary object files
rm -f stock_main stock_demo test_stock_funcs treeset_main *.o
> make # build all programs/objects for the assignment
gcc -Wall -Wno-comment -Werror -g -c stock_main.c
gcc -Wall -Wno-comment -Werror -g -c stock_funcs.c

You are not required to understand all that is in the Makefile (yet) but it is a very useful tool and may be worth your while to inspect.
Running make help will provide a summary of the build/test commands present in the Makefile.
> make help
Typical usage is:
> make
> make clean
> make zip
> make prob1
> make test
> make test-prob2
> make test-prob2 testnum=5
# build all programs
# remove all compiled items
# create a zip file for submission
# built targets associated with problem 1
# run all tests
# run test for problem 2
# run problem 2 test #5 only
2.2 Automated Tests
Automated tests are included with the code distribution. These tests are known to work on lab machines only but in most cases
they should run identically in Linux environments such as the Windows subsystem for Linux or a virtual machine.
The provided Makefile allows automated tests to be run via calls like make test-prob1 to test Problem 1 and make test-prob2 to test Problem 2. See the transcript below.
gcc -Wall -Wno-comment -Werror -g -o stock_main stock_main.o stock_funcs.o
gcc -Wall -Wno-comment -Werror -g -c stock_demo.c
gcc -Wall -Wno-comment -Werror -g -o stock_demo stock_demo.o stock_funcs.o
gcc -Wall -Wno-comment -Werror -g -o test_stock_funcs test_stock_funcs.c stock_fu
gcc -Wall -Wno-comment -Werror -g -c treeset_main.c
gcc -Wall -Wno-comment -Werror -g -c treeset_funcs.c
gcc -Wall -Wno-comment -Werror -g -o treeset_main treeset_main.o treeset_funcs.o
>> make test-prob1 # run tests for problem 1, compiles required code
gcc -Wall -Wno-comment -Werror -g -c stock_funcs.c
gcc -Wall -Wno-comment -Werror -g -o test_stock_funcs test_stock_funcs.c stock_fu
./testy test_stock1.org
============================================================
== test_stock1.org : Problem 1 First 3 Functions in stock_funcs.c == Running 15 / 15 tests
1) stock_new :ok
2) stock_free1 :ok
3) stock_free2 :ok
4) stock_free3 :ok
5) stock_free4 :ok
6) stock_print1 :ok
7) stock_print2 :ok
8) stock_print3 :ok
9) stock_print4 :ok
10) stock_print5 :ok
11) stock_print_prices_0 : ok
12) stock_print_prices_1 : ok
13) stock_print_prices_2 : ok
14) stock_print_prices_3 : ok
15) stock_print_final :ok ============================================================ RESULTS: 15 / 15 tests passed
>> make test-prob2 # run tests for problem 2
gcc -Wall -Wno-comment -Werror -g -c stock_main.c
gcc -Wall -Wno-comment -Werror -g -o stock_main stock_main.o stock_funcs.o
./testy test_stock2.org
============================================================
== test_stock2.org : Problem 2 Remaining Functions in stock_funcs.c
== Running 15 / 15 tests
1) stock_set_minmax1 : ok
2) stock_set_minmax2 : ok
n
n

Each problem describes specifically how tests can be run and how credit will be assigned. Note that one can run a single test with the following make invocation which sets testnum.
This is useful when debugging to limit the output and time it takes to check program results.
3 Problem 1: Stock Plotting 3.1 Overview and Demo
Problems 1 and 2 create a small plotting application that is focused on stock prices. In stock trading, the idea is to buy a stock when it is priced low and sell it at a later time point when the price is high which will net the profit of the difference between each. Of course, this must be done by predicting when prices are at their highest and lowest points and some insight can be garnered from examining historical data for stock prices. The application you will build allows for easy analysis of a simple data file containing times/prices for stocks and display of their information in simple text plots. At the end of problems 1 and 2, you will have an application which produces the following kind of output.
> make test-prob2 testnum=5
3) stock_set_minmax3 :ok 4) stock_set_best1 :ok 5) stock_set_best2 and 3 :ok 6) stock_set_best4 :ok 7) count_lines :ok 8) stock_load1 :ok 9) stock_load2 and 3 :ok 10) stock_load pathological : ok 11) stock_plot1 :ok 12) stock_plot2 34 :ok 13) stock_plot5 6 :ok
14) stock_main1
15) stock_main2
============================================================
RESULTS: 15 / 15 tests passed
> make test # run tests for all problems

:ok :ok
>> ./stock_main 10 data/stock-ascending.txt
data_file: data/stock-ascending.txt
count: 10
prices: [10.00, 20.00, 30.00, …]
min_index: 0
max_index: 9
best_buy: 0
best_sell: 9
profit: 90.00
max_width: 10
range: 90.00
plot step: 9.00
# plot a stock-ascending dat
# shows the first few stock
# calculates time for min/ma
# calculates optimal buy/sel
# 10 specifed on command lin
# difference between max/min
# amount represented by each
# visual representation of s
# prices over time
# same file make the bars bi
# 20 hashes wide rather than
0: B MIN
1:
2:
3:
4:
5:
6:
7:
8:
9: S MAX
+———-
10.00 |
20.00 |
30.00 |##
40.00 |###
50.00 |####
60.00 |#####
70.00 |######
80.00 |#######
90.00 |########
100.00 |##########
>> ./stock_main 20 data/stock-ascending.txt
data_file: data/stock-ascending.txt
a
p x
l e
t
g

count: 10
prices: [10.00, 20.00, 30.00, …]
min_index: 0
max_index: 9
best_buy: 0
profit: 90.00
best_sell: 9
max_width: 20
range: 90.00
plot step: 4.50
# 20 specified on command li
# makes the bars wider
0: B MIN
1:
2:
3:
4:
5:
6:
7:
8:
9: S MAX
+——————–
10.00 |
20.00 |##
30.00 |####
40.00 |######
50.00 |########
60.00 |###########
70.00 |#############
80.00 |###############
90.00 |#################
100.00 |####################
>> ./stock_main 20 data/stock-valley.txt
data_file: data/stock-valley.txt
count: 12
prices: [100.00, 90.00, 80.00, …]
min_index: 5
max_index: 11
best_buy: 5
best_sell: 11
profit: 55.00
max_width: 20
range: 55.00
plot step: 2.75
# plot a different file
# which has a valley shape
0:
1:
2:
3:
4:
5: B MIN
6:
7: 8: 9:
10:
11: S MAX
+——————–
100.00 |##################
90.00 |##############
80.00 |##########
70.00 |#######
60.00 |###
50.00 |
55.00 |#
65.00 |#####
75.00 |#########
85.00 |############
95.00 |################
105.00 |####################
>> ./stock_main 20 data/stock-jagged.txt
data_file: data/stock-jagged.txt
count: 15
prices: [103.00, 250.00, 133.00, …]
min_index: 8
max_index: 11
best_buy: 8
best_sell: 11
profit: 232.00
max_width: 20
range: 232.00
plot step: 11.60
+——————–
0: 103.00 |#####
1: 250.00 |##################
2: 133.00 |########
3: 143.00 |#########
4: 168.00 |###########
5: 91.00 |####
6: 234.00 |################
7: 59.00 |#
# plot a file with greater
# variance in prices
n

3.2 Outline of stock_funcs.c
The file stock_funcs.c will contain most of the support functions for the stock plotting program. An outline of these functions are presented below. Note that each function has the Problem # to which it belongs.
8: B MIN
9: 10:
11: S MAX
12:
13:
14:
38.00 |
45.00 |
254.00 |##################
270.00 |####################
59.00 |#
72.00 |##
107.00 |#####
>> ./stock_main 25 data/stock-min-after-max.txt
data_file: data/stock-min-after-max.txt
count: 15
prices: [223.00, 292.00, 27.00, …]
min_index: 10
max_index: 4
best_buy: 2
best_sell: 4
profit: 296.00
max_width: 25
range: 309.00
plot step: 12.36
# plot a stock with varying
# prices
# minimum price appear after
# the maximum price
# finding the optimal buy/se
# point is harder in this ca
0:
1:
2: B
3:
4: S MAX
5:
6: 7: 8: 9:
10: MIN
11:
12:
13:
14:
+————————-
223.00 |################
292.00 |######################
27.00 |#
92.00 |######
323.00 |#########################
189.00 |##############
207.00 |###############
142.00 |##########
321.00 |########################
89.00 |######
14.00 |
182.00 |#############
164.00 |############
156.00 |###########
169.00 |############
>> ./stock_main 9 data/stock-descending.txt
No viable buy/sell point
data_file: data/stock-descending.txt
count: 10
prices: [100.00, 90.00, 80.00, …]
min_index: 9
max_index: 0
best_buy: -1
best_sell: -1
profit: 0.00
max_width: 9
range: 90.00
plot step: 10.00
# if the stock is continuall
# declining, its best not to
# not worthwhile to buy/sell
# this situation
0: MAX 1:
2:
3:
4:
5:
6:
7:
8:
9: MIN
+———
100.00 |#########
90.00 |######## 80.00 |####### 70.00 |###### 60.00 |##### 50.00 |#### 40.00 |### 30.00 |## 20.00 |# 10.00|
l s
y

// stock_funcs.c: support functions for the stock_main program.
stock_t *stock_new();
// PROBLEM 1: Allocate a new stock struct and initialize its fields.
// Integer fields like ‘count’ and ‘min_index’ should be initialied to
// -1. Pointer fields like ‘prices’ should be initialized to
// NULL. The stock should be heap-allocated using malloc() and
// returned. Since this is an allocation function, no use of ‘free()’
// should appear.
void stock_free(stock_t *stock);
// PROBLEM 1: Free a stock. Check the ‘data_file’ and ‘prices’ fields:
// if they are non-NULL, then free them. Then free the pointer to
// ‘stock’ itself.
void stock_print(stock_t *stock);
// PROBLEM 1: Prints data about a stock that is passed in via a
// pointer. Uses the syntax ptr->field to access fields of the struct
// pointed by ‘stock’. Output follows the general convention:
//
// data_file: data/stock-jagged.txt
// count: 15
// prices: [103.00, 250.00, 133.00, …]
// min_index: 8
// max_index: 11
// best_buy: 8
// best_sell: 11
// profit: 232.00
//
// Where each line prints a field of the stock_t struct. In all cases,
// floating point numbers are printed with 2 decimal digits of accuracy.
//
// NULLS FOR FIELDS
// The fields ‘data_file’ and ‘prices’ may be NULL in which case they
// will be printed specially as in
//
// data_file: NULL
// prices: NULL
//
// This requires a manual if/else check for NULL values for these pointers.
//
// PRICES FIELD
// When printing the ‘prices’ field, if the ‘count’ field is 0 to 3,
// print the entire array as in
//
// prices: []
// prices: [70.00]
// prices: [50.00,
// prices: [59.00,
//
// Otherwise, print the first 3 elements with a … at the end as in
//
// prices: [10.00, 20.00, 30.00, …] # count > 3
//
// PROFIT
// There is no ‘profit’ field in the struct. Instead, calculate the
// profit as the difference between the price at the ‘best_sell’ index
// and ‘best_buy’ index. If these indices are -1 indicating the best
// buy/sell time is not known or not viable, print a proit of 0.0
void stock_set_minmax(stock_t *stock);
// PROBLEM 1: Sets the index of ‘min_index’ and ‘max_index’ fields of
// the stock to be the positions in ‘prices’ of the minimum and
// maximum values present in it. Uses a simple loop over the array
// ‘prices’ which is ‘count’ elements long to examine each for
// max/min. If ‘count’ is zero, makes no changes to ‘min_index’ and
// ‘max_index’.
int stock_set_best(stock_t *stock);
#count==1 90.00] #count==2 45.00, 103.00] #count==3
#count==0

// PROBLEM 2: Sets the ‘best_buy’ and ‘best_sell’ fields of ‘stock’.
// This corresponds to the pair which produces the best profit. On
// determining the best buy/sell indices which produce a positive
// profit, sets these fields in ‘stock’ and returns 0. If there is no
// buy/sell point which would result in a positive profit, sets the
// ‘best_buy’ and ‘best_sell’ indices to -1 and returns -1. Always
// calculates the earliest buy/sell pair of indices that would get the
// best profit: if 5,8 and 5,9 and 7,10 all give the same, maximal
// profit, the best buy/sell indices are set to 5,7.
//
// ALGORITHM NOTES
// One intuitive algorithm to compute this is to try every possible
// buy index (outer loop) and every possible sell index after it
// (inner loop) looking for the maximum profit produced in it. This is
// a O(N^2) algorithm with N=count. Using this algorithm is a good
// start. Some MAKEUP CREDIT will be awarded for implementing a more
// efficient, O(N) algorithm here. See the specification for more details.
int count_lines(char *filename);
// PROBLEM 2: Opens file named ‘filename’ and counts how many times
// the ‘\n’ newline character appears in it which corresponds to how
// many lines of text are in it. Makes use of either fscanf() with
// the %c format to read single characters or alternative I/O
// functions like fgetc(). Closes the file before returning a count of
// how many lines are it it. If for any reason the file cannot be
// opened, prints a message like
//
// Could not open file ‘not-there.txt’
//
// and returns -1 to indicate failure.
int stock_load(stock_t *stock, char *filename);
// PROBLEM 2: Loads a stock from file ‘filename’ into ‘stock’ filling
// its ‘prices’ and ‘count’ fields in. Makes use of the count_lines()
// function to determine how many lines are in the file which will
// dictate ‘count’ and the length of ‘prices’. Allocates space in the
// heap for the stock’s ‘prices’ array, opens the ‘filename’ and
// iterates through reading prices into the array. The data format for
// prices files is
//
// time_03 133.00
// time_04 143.00
// time_05 168.00
// time_06 91.00
//
// where each line has a time as as single string and a price which is
// floating point number. The times can be ignored which can be
// accomplished with a fscanf() call with format “%*s” to read a
// string but ignore/discard it.
//
// Assigns the ‘datafile’ field to be a duplicated string of
// ‘filename’ for which ‘strdup()’ is extremely useful. This string
// must be free()’d later likely in ‘stock_free()’
//
// On successfully loading the stock, returns 0.
//
// If ‘filename’ cannot be opened, prints the message
//
// Unable to open stock file ‘some-stock.txt’, bailing out
//
// with ‘filename’ substituted in for the name of the stock and
// returns -1.
void stock_plot(stock_t *stock, int max_width);
// PROBLEM 2: Plots a graphical representation of stock
// information. First calculates and prints plot which is in the
// following format:
//
// max_width: 25

3.3 Editing and Testing
The project code contains a skeleton version of stock_funcs.c which you should fill in with definitions. With this skeleton version, you can immediately start testing your code by typing make test-prob1. Without changes, you will get failures for all tests as in
n
m m m
However, the ability to run tests on your code an see progress is extremely important. Your first goal when starting a new project should be to see some results or running the program which is much easier if some benevolent dictator has provided a bunch of tests.
You can also use the invocation
to run a single test and see its results in the terminal.
Failed tests generate results files which can be viewed in any text editor or in the terminal. The cat command can show such results in the terminal via cat test-results/some-file.txt.
>> make test-prob1
gcc -Wall -Wno-comment -Werror -g -o test_stock_funcs test_stock_funcs.c stock_fu
./testy test_stock1.org
============================================================
== test_stock1.org : Problem 1 First 3 Functions in stock_funcs.c
== Running 15 / 15 tests
1) stock_new
2) stock_free1
3) stock_free2

============================================================
RESULTS: 0 / 15 tests passed
: FAIL -> results in file ‘test-results/prob1-01-result.t
: FAIL -> results in file ‘test-results/prob1-02-result.t
: FAIL -> results in file ‘test-results/prob1-03-result.t
> make test-prob1 testnum=5
// range: 40.00
// plot step: 1.60
//
// The prints a header line and iterates through each stock data on it
// along with a bar which varies in width with the stock price. A
// sample format is as follows with some annotations.
//
//….20 spaces…….+ …max_width dashes…..
//01234567890123456789
//
// 0:
// 1:
// 2: B
// 3:
// 4: S MAX
// 5:
// 6:
// 7:
// 8:
// 9:
// 10:
// 11:
// 12:
// 13:
// 14:
//01234567890123456789
//| || | |
//| | | | +-> Each bar is (price-min)/plot_step hashes wide
//| | | +-> Stock price printed with format %8.2f
//| | +-> Print MIN or MAX if the stock is at min_index/max_index
//| +-> Print B or S if the stock is at the best_buy/best_sell index
//+–> Index in the array printed with format %3d
MIN
321.00 |########################
89.00 |######
14.00 |
+————————-
223.00 |################
292.00 |######################
27.00 |#
92.00 |######
323.00 |#########################
189.00 |##############
207.00 |###############
142.00 |##########
182.00 |#############
164.00 |############
156.00 |###########
169.00 |############

Below the results for the first test are shown and from the comparison and Valgrind report, it appears that there is some sort of Memory problem with the stock_new() function.
>> cat test-results/prob1-01-result.tmp
* (TEST 1) stock_new
COMMENTS:
** program: ./test_stock_funcs stock_new
** — Failure messages —
– FAILURE(139) due to SIGSEGV (segmentation fault) from OS
– FAILURE: Output Mismatch at lines marked
** — Side by Side Differences —
– Expect output in: test-results/raw/prob1-01-expect.tmp
– Actual output in: test-results/raw/prob1-01-actual.tmp
– Differing lines have a character like ‘|’ ‘>’ or ‘<' in the middle #+BEGIN_SRC sbs-diff ==== EXPECT ==== {{ // Tests stock_new() function and whether it initializes fields // correctly before returning a stock. stock_t *stock = stock_new(); // call function to allocate/init printf("stock->data_file: %p\n” , stock->data_file);
printf(“stock->count: %d\n” , stock->count);
printf(“stock->prices: %p\n” , stock->prices);
printf(“stock->min_index: %d\n” , stock->min_index);
printf(“stock->max_index: %d\n” , stock->max_index);
printf(“stock->best_buy: %d\n” , stock->best_buy);
printf(“stock->best_sell: %d\n” , stock->best_sell);
free(stock); // de-allocate manually }}
stock->data_file: (nil)
stock->count: -1
stock->prices: (nil)
stock->min_index: -1
stock->max_index: -1
stock->best_buy: -1
stock->best_sell: -1
#+END_SRC
** — Line Differences —
EXPECT: 17) stock->data_file: (nil)
EXPECT: 18) stock->count: -1
EXPECT: 19) stock->prices: (nil)
EXPECT: 20) stock->min_index: -1
EXPECT: 21) stock->max_index: -1
EXPECT: 22) stock->best_buy: -1
EXPECT: 23) stock->best_sell: -1
ACTUAL: 17) Segmentation Fault
| Segmentation
< < < < < < --- Valgrind Log from: test-results/raw/prob1-01-valgrd.tmp --- ==150464== Memcheck, a memory error detector ==150464== Copyright (C) 2002-2017, and GNU GPL'd, by et al. ==150464== Using Valgrind-3.17.0 and LibVEX; rerun with -h for copyright info ==150464== Command: ./test_stock_funcs stock_new ==150464== Parent PID: 150463 ==150464== ==150464== Invalid read of size 8 ==150464== at 0x109354: main (test_stock_funcs.c:33) ==150464== Address 0x0 is not stack'd, malloc'd or (recently) free'd ==150464== ==150464== ==150464== Process terminating with default action of signal 11 (SIGSEGV): dumping ==150464== Access not within mapped region at address 0x0 ==== ACTUAL // Tests // corre stock_t printf(" printf(" printf(" printf(" printf(" printf(" printf(" free(sto = c * s s s s s s s c 3.4 Implementation Notes Use the Arrow The first 3 functions to implement in stock_funcs.c are utility functions for stocks to allocate, de-allocate and print them. As will be covered in lecture, C often deals with pointers to a struct and that is the case in these functions. For this, the sp->fld syntax is used to first dereference the struct pointer and access a field of the struct. For example, in stock_print() one could use the following code to print the count field of the parameter struct:
Throughout most of this problem and the next, the Arrow syntax will be used in most functions.
Allocating Stocks in Heap Memory
In order to get dynamically allocated memory in the Heap, the malloc() function should be used. This function takes a number of bytes and returns a void * pointer for that number of bytes if available. As will be discussed in lecture, C provides the sizeof() operator to calculate the size of various intrinsic and user-defined types. To allocate enough space for a stock_t, use malloc(sizeof(stock_t)).
Though malloc() returns a void *, it is typical to simply assign it to a pointer of some other kind. For example, the following is a typical way to allocate space for a single stock_t struct and save the reference for later use.
Once allocated, the Arrow syntax mentioned above, stock->min_index can be used to adjust fields.
To understand which fields are present in the stock_t struct, open up the header file stock.h which declares the struct. There will be a list of fields like prices and max_index: these will all need to receive initial values like -1 or NULL. Don’t alter anything in the header as this may break tests that you’ll run later.
Avoid Freeing NULL
While the free() function is used to de-allocate memory that has been obtained via malloc(), it should never be called with a NULL pointer. In the stock_free() function, one should check the data_file and prices fields and free them only if they are not NULL. The following code demonstrates how this can be done for one of those fields.
void print_stock(stock_t *stock){
// …
printf(“count: %d\n”, stock->count);
// ^^^^^^^^^^^^
stock_t *stock = malloc(sizeof(stock_t));
==150464== at 0x109354: main (test_stock_funcs.c:33)
==150464== If you believe this happened as a result of a stack
==150464== overflow in your program’s main thread (unlikely but
==150464== possible), you can try to increase the size of the
==150464== main thread stack using the –main-stacksize= flag.
==150464== The main thread stack size used in this run was 10022912.
==150464==
==150464== HEAP SUMMARY:
==150464== in use at exit: 0 bytes in 0 blocks
==150464== total heap usage: 0 allocs, 0 frees, 0 bytes allocated
==150464==
==150464== All heap blocks were freed — no leaks are possible
==150464==
==150464== For lists of detected and suppressed errors, rerun with: -s
==150464== ERROR SUMMARY: 1 errors from 1 contexts (suppressed: 0 from 0)
void stock_free(stock_t *stock){
// …
if(stock->data_file != NULL){
free(stock->data_file);
}
// …

Printing Prices Array
During stock_print(), some special code will be needed to print the prices[] array if it has 3 or fewer elements. As per the function documentation, the line associated with prices will like one of the following depending on the value for count:
There are a couple tricks for producing this type of output and it may take some care to get the output formatted correctly for all situations. You might try either of the following:
1. Brute force: establish 5 cases for each of the formats above with separate printf() call for each. Since the number of cases is relatively small, this should not be unmanageable.
2. Use the count==0 as a special case and then write a carefully crafted loop with conditionals to handle the remaining cases. This can get tricky but is more flexible if for later one wants to see the first 5 numbers instead.
Either approach is acceptable in this case.
Keep in mind that though prices is declared as a double *prices (pointer to double data), it is fine to use array syntax like square brace indexing with it. Syntax like stock->prices[2] will follow a pointer to a stock_t struct then find the prices field and index into it as an array.
3.5 Grading Criteria for Problem 1 grading 30 The following criteria will be checked.
Weight Criteria
AUTOMATED TESTS via make test-prob1
15 Runs tests in test_prob1.org on the first 3 functions in stock_funcs.c
Runs all code under Valgrind to ensure that no memory errors are present. 1 point per test passed
MANUAL INSPECTION
5 Overall Style and Readability
Good indentation of code clearly denoting function/loop/conditional scopes Presence of some comments to indicate intent in gnarly code
5 stock_new()andstock_free()
Appropriate use of malloc() and sizeof() to get heap memory
Correct initialization of all fields to -1 or NULL
Appropriate use of the Arrow syntax for field access
Checks for data_file and prices fields to avoid calling free() on a NULL pointer Appropriate use of the Arrow syntax for field access
5 stock_print()
Appropriate use of the Arrow syntax for field access
Clear logic which deals with printing prices[] array with 3 or fewer elements specially
prices: []
prices: [70.00]
prices: [50.00, 90.00]
prices: [59.00, 45.00, 103.00]
prices: [10.00, 20.00, 30.00, …] # count > 3
# count == 0
# count == 1
# count == 2
# count == 3

Weight Criteria
Clear section to calculate Profit from best_buy/best_sell or print 0.0 if these are -1 4 Problem 2: Completing Stock Plot
4.1 Overview
This problem implements further functions to complete the Stock Plotting application. These functions are somewhat more complex and utilize functions and techniques that are part of Problem 1. When this problem is complete, all functions in stock_funcs.c will be working which will allow the provided stock_main.c program to be compiled and run on the command line.
The remainder of this section gives some notes and implementation hints on how to handle the various functions.
4.2 Setting Min/
This function should be implemented as a simple “scan” across the prices[] array. Each step will check an element of prices[] and adjust a running min/max. Make use of similar syntax here as you used in stock_print() in order to access the elements of prices and subsequently set the min_index and max_index fields.
4.3 /Sell Index
In many cases it is best to buy at a minimum price and sell at a maximum price. This approach fails if the maximum price occurs before the minimum price. The job of stock_set_best() is to run an algorithm to locate the best possible buy/sell pair and set the best_buy / best_sell fields of a stock. As the documentation for the function indicates, one can use a simple “brute force” approach to this by simply trying every buy index paired with every sell index (which must occur later in the array than the buy index). This approach leads to the following pattern of iteration through the prices array which uses a doubly nested pair of loops.
void stock_set_minmax(stock_t *stock)
int stock_set_best(stock_t *stock);
set best_buy and best_sell to -1
set best_profit to 0.0
for every buy index I in prices
for every sell index J later than I in prices
if prices[J] – prices[I] > best_profit
set best_buy,best_sell, to I,J
set best_profit to prices[J] – prices[I]
done
done
Start by adapting this approach in the function and make sure it works. Then move on to solve other problems here.
For those that want a bit more fun, revisit this function later to implement a more efficient version of it as described in the Optional
MAKEUP CREDIT Section. 4.4 Stock Files
Data on stock prices over time are stored in several example files in the data/ directory such as data/stock- ascending.txt and data/stock-jagged.txt.
>> ls data/stock-*
data/stock-1only.txt
data/stock-2only.txt
data/stock-3only.txt
data/stock-ascending.txt data/stock-jagged.txt
data/stock-descending.txt data/stock-min-after-max.txt
# list all the sample stock data
data/stock-empty.txt data/stock-TSLA-08-02-2
data/stock-FB-08-02-2021.txt data/stock-TSLA-08-12-2
data/stock-GOOG-08-02-2021.txt data/stock-valley.txt
0 0

Each of has a simple data format which looks like the following.
>> cat data/stock-jagged.txt
time_01 103.00
time_02 250.00
time_03 133.00
time_04 143.00
time_05 168.00
time_06 91.00
time_07 234.00
time_08 59.00
time_09 38.00
time_10 45.00
time_11 254.00
time_12 270.00
time_13 59.00
time_14 72.00
time_15 107.00
Each time/price pair appears on its own line so that the number of lines in the file is the number of time/price pairs The first item on each line is a time at which a price appears: this will be ignored.
The second item that appears on each line is a floating point number which is the stock price at that time.
4.5 Counting Lines
Since the number of lines in stock files corresponded to the number of prices, it is useful to have a utility function to count lines in a file which is required.
As the documentation for the function indicates, this function will open the named file and count the lines in it. This can be done most easily via treating the file as a long array of characters and looking for the special \n newline character which designates a line break. Character comparisons are done in C like other equality comparisons via syntax like
To read a single character from a file, a common approach is to use the fscanf() function with the %c format specifier as in
Keep in mind that the fscanf() function will fail to read a character when it reaches the end of a file. In these cases it will return the special return value EOF which should be checked. A common structure is
int count_lines(char *filename)
if(somevar == ‘\n’){ … }
if(somevar == ‘X’){ … }
char c;
int ret = fscanf(fin, “%c”, &c);
int ret = fscanf(fin, …, …);
if(ret == EOF){
// take action for end of file, like breaking out of a loop
// or returning
}
else{
// fscanf() completed normally so variables should contain
// new values
}
Experiment with these elements to complete the count_lines() function.

Keep in mind that count_lines() should fail gracefully if a file cannot be opened. In such cases, the fopen() function returns NULL. Make sure to check for this, print an error message as indicated in the function documentation, and return -1 from the function to indicate a failure has occurred.
4.6 Loading Stock Files
This function takes an existing stock and fills in its price and count fields based on the contents of the given file. An example:
int stock_load(stock_t *stock, char *filename)
stock_t *stock = new_stock();
// all fields of stock have default values like -1 and NULL
int ret = stock_load(stock, “data/stock-ascending.txt”);
// Specified data file as 10 lines so
// stock->count is now 10
// stock->prices is an array of 10 values read from the file
// If the load failed, -1 would be returned
Make use of the count_lines() function to determine how many lines are in the stock file. This will allow you to immediately allocate enough space for a double array for all of the prices in the file.
You will need to skip the first string on each line in prices files:
An easy way to accomplish this is to use the C format modifier * which reads a field but does not place it in memory anywhere. For example:
would read a string but ignore it thus one does not have to provide a memory address to store the string.
One requirement of stock_load() is to set the data_file field to be a copy of the filename parameter. While this can be done manually with malloc() and a loop, the strdup() function makes this easy and is encouraged here. Look up documentation for it either in the Unix man pages (type man strdup in a terminal) or via an internet search.
Ensure that at the end of stock_load() the data_file, prices, and count fields have been set according to the data from the file. Do not modify any other fields in the stock.
4.7 Plotting Stocks
The ultimate goal of the Stock Plot application is fulfilled in this function which is meant to print a graphical representation of stock data. A sample of output is below and will be discussed in more detail.
time_03 133.00
time_04 143.00
||
| +—> Read these into prices +—> Skip these times
fscanf(fin, “%*s”);
void stock_plot(stock_t *stock, int max_width);
max_width: 25
range: 40.00
plot step: 1.60
+————————-
0: 223.00 |################
1: 292.00 |######################

The output comes from the following code fragment which is present in the provided file stock_demo.c.
The initial output is
and shows the calculation needed to compute the “plot step”. This relies on knowing the Minimum and Maximum price (found via stock_set_minmax()) to first get the Range (difference between min/max). The range is then divided by the max_width parameter. max_width dictates how wide the widest “bar” of the plot should be. The reported “plot step” is 1.60 in this case so that each of the # has marks corresponds to 1.60 in price in the below bars.
Next an axis line appears as in
The left area has a fixed number of spaces followed by a + then a number of dashes equal to the max_width parameter. Use a loop to print out the proper number of dashes.
The remainder of the plot has one line per stock price. Examples of the first few lines:
Note that the initial index at the left is printed with format %3d which leaves spaces on the left for single and double digit numbers. Next appears the price for the stock at that time. This is printed using the format specifier %8.2f which leaves 2 digits beyond the
decimal place and again, may add some space on the left for smaller prices. At the right, each “bar” has a length which can be computed by the formula
{
stock_t *stock = stock_new();
stock_load(stock, “data/stock-min-after-max.txt”);
stock_set_minmax(stock);
stock_set_best(stock);
stock_plot(stock, 25);
}
max_width: 25
range: 40.00
plot step: 1.60
+————————-
….20 spaces…. ….max_width dashes…..
// 0: 223.00 |################
// 1: 292.00 |######################
int width = (price[i] – minimum_price) / plot_step
This will convert a double value into an integer which can then be used in a loop to print out the proper number of # marks.
2: B
3:
4: S MAX
5:
6:
7:
8:
9:
10: MIN
11:
12:
13:
14:
27.00 |#
92.00 |######
323.00 |#########################
189.00 |##############
207.00 |###############
142.00 |##########
321.00 |########################
89.00 |######
14.00 |
182.00 |#############
164.00 |############
156.00 |###########
169.00 |############

The space in between the index and the price is used to denote the optimal buy/sell time and the min/max stock prices. As a couple examples here are possible outputs that combine some of these.
Use a B or S at the index that matches best_buy / best_sell. Print this as a single character string OR print a space here if the stock is not at the best buy/sell index.
Print MAX or MIN if the stock is at the min/max index or print 3 spaces if not. In either case follow with 1 more space.
A common tactic to solve such problems is to use a conditional structure like the following which re-assigns a string based on whether a particular stock price is one of the best buy/sell or min/max.
2: B
4: S MAX
10: MIN
27.00 |#
323.00 |#########################
14.00 |
char *min_or_max_str = ” “;
if(i == stock->min_index){
min_or_max_str = “MIN”;
}
if(i == stock->max_index){

}
printf(“%s “,min_or_max_string);
The same process can be executed to print out either a blank space or B/S for the best buy/sell designator as well.
It may take some time to get the output for the stock_plot() correct but this can be expedited through careful inspection of test
feedback.
4.8 Optional MAKEUP CREDIT
The “brute force” approach initially suggested to find best_buy / best_sell indices compares all possible buy/sell pairs to determine the best profit possible. This is a Quadratic algorithm with complexity O(N^2) with N being the length of the prices[] array.
One can improve upon this algorithm to get an O(N) linear algorithm. This takes some cleverness or some research. For example, the problem is directly related to the Maximum Subarray Problem and its various solutions. These are described here:
https://en.wikipedia.org/wiki/Maximum_subarray_problem https://cs.gmu.edu/~kauffman/cs310/01-intro.pdf
Note that adapting these approaches to the current setting will require some care: the Maximum Subarray problem assumes elements in the array are added together whereas in our Stock setting, it is the difference between elements that matter. However, buy absorbing the tricks used the linear time Maximum Subarray algorithm, one can get the same effect for the Stocks, an O(N) algorithm to set best_buy / best_sell.
Code that implements a Linear Time algorithm for stock_set_best() will be awarded 10 POINTS of PROJECT MAKEUP CREDIT.
Makeup Credit will go into the general pool of points earned for projects to make up for points missed on projects elsewhere. If a student scores 110/100 on Project 1 and 90 / 100 on Project 2, the 10 points from Project 1 will make up for the credit lost on Project 2. Your total score on All Projects cannot exceed 100% so any points beyond the overall total will simply be dropped.
4.9 Grading Criteria for Problem 2 grading 30 The following criteria will be checked.
Weight Criteria
AUTOMATED TESTS via make test-prob2
15 Runs the tests provided in test_prob2.org for last functions in stock_funcs.c and stock_main
Runs all code under Valgrind to ensure that no memory errors are present.

Weight Criteria
1 point per test passed
MANUAL INSPECTION
5 stock_set_minmax()andstock_set_best()
Clear loop to scan through the prices array to find the min/max and best buy/sell
Proper changes to the fields min_index / max_index / best_buy / best_sell
5 stock_load()andcount_lines()
Use of fopen() and fscanf() to read in data from the file
Code to gracefully handle failure to open a file and print appropriate messages.
Proper use of count_lines() to determine the number of lines in the data file
Use of malloc() to allocate memory for the prices array
Use of the “%*s” format specifier to skip leading “time” string in files
Duplication of the filename to the data_file field likely using the strdup() function
5 stock_plot()
Clear section that calculates the “plot step” with appropriate variables like range Code to print out the initial plot information and loop to print the upper axis “bar” Section of conditional code which prints if stock is min/max and best buy/sell Clear loop that prints out bars with width proportional to the price of the stock
10 OPTIONAL MAKEUP CREDIT
Implement stock_set_best() in linear time rather than Quadratic time.
Such solutions will have a single loop rather than 2 nested loops BUT not every single loop is linear time. Credit will be deducted if the code is not concise and clear.
5 Problem 3: Tree Sets in C 5.1 Overview
This problem implements a rudimentary “tree set” application in C along with a program that uses it. The architecture is similar to a HW problem involving linked lists so reviewing that code can provide some insight.
Basic Binary Search Trees are covered in most introductory data structure classes such as CSCI 1913 and 1933. A “Tree Set” is simply a binary search tree which only allows one copy of each unique item in it. When searching for an item, the organization of the binary search tree is exploited to speed up the location of the time or determine that it is not present. When adding items, duplicate items are discarded without altering the tree.
5.2 treeset_main Demonstration
The intent of this problem is to develop a small application which behaves as the following demo indicates. Study this demo carefully as it illustrates most of the capabilities of the application with each capability being checked by automated tests.
> make treeset_main # build with Makefile
gcc -Wall -Wno-comment -Werror -g -c treeset_main.c
gcc -Wall -Wno-comment -Werror -g -c treeset_funcs.c
gcc -Wall -Wno-comment -Werror -g -o treeset_main treeset_main.o treeset_funcs.o

> ./treeset_main
Treeset Main
Commands:
print:
size:
clear:
quit:
add :
find :
preorder:
save :
load :
TS#> add S#> add S#> add S#> add S#> add El
TS#> size
5 nodes
TS#> print

S#> preorder
El
Mike S#> find OUND
TS#> find OT FOUND
TS#> add S#> size
6 nodes
TS#> print

El S#> add Mike
duplicate element ignored
TS#> add El
duplicate element ignored
TS#> find OT FOUND
TS#> add S#> print

S#> find OUND
TS#> find OT FOUND
TS#> add S#> print

# run main program
shows contents of the tree in reverse sorted order
prints the number of nodes currently in the tree
eliminates all elements from the tree
exit the program
inserts the given string into the tree, duplicates ignored
prints FOUND if the name is in the tree, NOT FOUND otherwise
prints contents of the tree in pre-order which is how it will be
writes the contents of the tree in pre-order to the given file
clears the current tree and loads the one in the given file
# add some data
# show number of nodes in the tree
# print tree, reverse order, indentation indicates
# root->right->right
# root->right
# root
# root->left->right
# root->left
# show tree in preorder, root first
# root
# root->left
# root
# root->right
# root->right->right
# add Nancy
# show size of tree has increased
# root->right->right->left
# adding duplicates is ignored
# add max
# root->right->left
# add Barb

5.3 tree_funcs.c: tree functions
Examine the header file tree.h to see the two C structs which will be used to represent trees.

Dustin S#> save stranger.tree
TS#> clear
TS#> size
0 nodes
TS#> print
TS#> add Demigorgon
TS#> print
Demigorgon
TS#> load stranger.tree
TS#> size
8 nodes
TS#> print

Dustin S#> add S#> add S#> print

Dustin S#> load stranger.tree
TS#> print

Dustin S#> quit
# root->left->left
# save tree into named file
# eliminate tree
# show tree is empty now
# print shows nothing: empty tree
# add Demigorgon to empty
# root
# clear tree, replace with contents of file
# 8 nodes loaded from file
#