The goal of this ungraded problem set is to introduce you to course infrastructure, and to warm up your skills in the programming language we use, C++, and the kinds of programs we’ll write. The programming is not intended to be difficult, but don’t settle for sloppy results. The course aims to teach you robust, secure, and understandable coding, as well as fast and correct coding.
Solutions are provided, and you should look at them. Try to work through the problems yourself first, but don’t worry if you get stuck and peek at the solution. Understanding the solution is already a great step. The problems get progressively harder. If you get through all of the problems you are definitely ready for the course; if you get through part 4, you are very likely ready for the course.
You do not need to submit anything for this problem set.
Overview
This course teaches you the fundamentals of computer systems and systems programming, using C++ as its primary implementation language. C++ is a popular language for low-level systems coding, and unlike C, its predecessor, it comes with an extensive data structure library and high-level abstraction facilities.
Though the course uses C++, it is about systems programming. We don’t dive deep into the language, we do not use its object-oriented features, and we attempt to avoid its most difficult byways.
Some familiarity with C++’s data structures and libraries will be useful. You can get this from free resources on the web, although a textbook and reference is better. Some web resources, such as reference pages, contain an almost overwhelming amount of information. Don’t despair! A good way to use reference pages is to scan down for example code, which can be more concise and clear than the English-language reference material.
-
C++ tutorial from w3schools.com
LearnCpp.com has an extensive set of tutorials. The cplusplus.com one is a good short tutorial.
-
C++ reference from cppreference.com
As of 2021, cplusplus.com’s text is more approachable, though its layout is uglier and its technical material slightly out of date. Eddie prefers cppreference.com.
-
See also this Python to C++ mini-course developed by Professor Mike Smith and the CS 32 staff.
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These C and C++ Patterns may come in handy.
It will also be useful to have some familiarity with Unix shell syntax. You should know what standard input and standard output mean, and how to perform simple redirections. Specifically:
-
A simple shell command like
prog1
runsprog1
in the current context: its standard input and standard output are inherited from the shell, which usually means that its input reads from the keyboard and its output is printed to the terminal. -
Typing
prog1 < IN
redirectsprog1
’s standard input to come from a file. In this instance,prog1
will observe the contents of theIN
file when reading from its standard input. -
Similarly,
prog1 > OUT
redirectsprog1
’s standard output to go to a file. If the fileOUT
already exists, its contents are overwritten. -
prog1 < IN > OUT
performs both redirections. -
prog1 | prog2
(pronounced “prog1
pipe toprog2
”) redirectsprog2
’s standard input to read fromprog1
’s standard output. Thus, all the bytes written byprog1
are read byprog2
in order.
Part 0. Course setup and Git
Objective: Prepare a CS 61 environment and get familiar with the terminal.
-
Follow the GitHub setup instructions.
-
Follow the Docker setup instructions.
-
Create a file in your
cs61-psets/pset0
directory calledhello.txt
that contains one line, the word “awesome
”. Hit 'return' or 'enter' on your keyboard to create a line break after the word. You can use your favorite text editor (such as Visual Studio Code), or use an editor included in the CS 61 Docker (Nano, Emacs, or vi).Check your work by entering the Docker environment and running the command
make test-hello
. This should print something like this:cs61-user@04feeb3aadd2:~/cs61-psets/pset0$ make test-hello ✅ Cool! hello.txt exists and has the right contents.
-
The
git status
command will show you thathello.txt
is not yet part of your official repository:cs61-user@9ba17834d87b:~/cs61-psets/pset0$ git status On branch main Your branch is up to date with 'origin/main'. Untracked files: (use "git add <file>..." to include in what will be committed) hello.txt no changes added to commit (use "git add" and/or "git commit -a")
Add the
hello.txt
file to your repository and push it to GitHub (that is, upload it to the shared GitHub repository). Verify that it has arrived on GitHub by looking at the web page for your repository (its link will resemble “https://github.com/cs61/cs61-f23-psets-YOURUSERNAME”).
Part 1. Invoke the compiler
Objective: Use the C++ compiler and make
to build a program.
Create a C++ source file exiter.cc
containing the following code.
#include <cstdlib>
int main() {
exit(0);
}
QUESTION. What would this program do?
Then compile the program and run it. Do this two ways.
-
First, call the compiler directly and run the program on the terminal. Here’s how:
$ c++ -std=gnu++2a -Wall -g -O3 exiter.cc -o exiter $ ./exiter
The first command invokes the compiler, asking it to compile your source file (
exiter.cc
) into an executable (a program that can be run, here calledexiter
). The flags supplied to the compiler are:-std=gnu++2a
selects a recent version of the C++ standard.-Wall
asks the compiler to warn you about possible mistakes in your code. You should always make sure that your code compiles without warnings.-g
adds debugging information to the compiler’s output.-O3
asks the compiler to optimize its code. This makes the code run faster, but can make the result harder to debug and can slow down compilation.
The compiler exits silently if can complete its work without encountering an error or warning, so be excited if there’s no output! If there is an error, you’ll need to fix that error and invoke the compiler again.
The second command (
./exiter
) invokes the compiled executable, which, as advertised, does nothing. -
Second, use our provided makefile to build the program. Here’s how:
$ rm -f exiter $ make exiter COMPILE exiter.cc LINK exiter $ ./exiter
The first command,
rm -f exiter
, removes the old executable if you made one. The second command,make exiter
, builds the new executable from rules in the providedGNUmakefile
.
Why?
Makefiles and the make
program are often used to build software. A makefile defines a set of recipes
for building programs and other targets; the make
program reads these
recipes and builds targets according to their rules. Crucially, make
analyzes which sources change from run to run and uses this information to
speed up the build process. We provide makefiles for all problem sets and
lecture codes in this course, and these makefiles have recipes for invoking
the compiler, so you will not generally need to invoke the compiler yourself.
But it’s super useful to know how to do so!
Our makefiles often hide the arguments of the programs they run. This is to
help focus your attention on any warnings or errors. If you want to see the
arguments, supply V=1
as an argument to make
. For instance:
$ make clean
$ make V=1 exiter
g++ -std=gnu++2a -Wall -Wextra -Wshadow -g -fsanitize=undefined -MD -MF .deps/exiter.d -MP -O3 -o exiter.o -c exiter.cc
g++ -std=gnu++2a -Wall -Wextra -Wshadow -g -fsanitize=undefined -O3 exiter.o -o exiter
As you can see, the makefile supplies more arguments than the simple compiler
invocation! For fun, why not try to figure out what those arguments do?
(-Wextra
and -Wshadow
especially.)
Unlike the direct invocation in step 1, our makefile runs the compiler twice
to produce an executable. The first invocation, COMPILE exiter.cc
, produces
an intermediate file called an object file, exiter.o
; the second
invocation, LINK exiter
, uses the object file to produce an executable. This
is unnecessary for a single-file program like exiter.cc
, but useful for
programs generated from multiple source files.
Part 2. Say hello
Objective: Recall C++’s output facility.
Create a program hello
that prints hello, kitty
to the terminal (the
standard output) and then exits. That is, write a C++ source file hello.cc
,
then compile it into a hello
executable that behaves like this:
$ make hello
$ ./hello
hello, kitty
$
It’s important that the “hello” message appears on its own line—this output is wrong:
cs61-user@caddb9e3ab14:~/cs61-psets/pset0$ ./hello
hello, kittycs61-user@caddb9e3ab14:~/cs61-psets/pset0$
Hints:
- Start with the code from
exiter.cc
. - Use the
fprintf
library function. - To get access to
fprintf
, you will need to#include <cstdio>
. - If you make changes to your code, you need to recompile it before you run it again.
Part 3. Count bytes
Objective: Recall more of C++’s input/output facilities.
Now let’s start really programming. Write a program bc61
that counts the
number of bytes in its standard input and prints the result to
standard output. Examples:
$ make bc61
$ echo foo | ./bc61
4
$ ./bc61 < /dev/null
0
$ yes | head -c 1000 | ./bc61
1000
$ ./hello | ./bc61
13
Use the fgetc
and fprintf
library functions for
C-style I/O. Make sure you test your bc61
program with different inputs.
Because your
bc61
program waits for input, runningbc61
on its own will appear to hang the terminal. This can be confusing!$ ./bc61 [...... nothing happens here forever!!! .......]
When this happens, press Control-C to kill
bc61
without waiting for it to complete its work. Alternately, type stuff, press Return to start a new line, and then press Control-D to passbc61
some input. (Pressing Control-D at the beginning of a line informs the terminal thatbc61
’s input has ended; ifbc61
attempts to read more characters, it will receive an end-of-file indication. Pressing Control-D anywhere but at the beginning of a blank line will simply release whatever you've typed on the current line so thatbc61
can read it.)
Part 4. Count words and lines (harder)
Objective: Reason through a nontrivial specification for an input/output program.
Write a program wc61
that counts words and lines as well as bytes. A word is
a sequence of one or more non-whitespace characters, and a line is zero or
more bytes terminated by the newline character \n
. The printout should give
lines, words, and bytes in that order. Examples:
$ echo foo | ./wc61
1 1 4
$ ./wc61 < /dev/null
0 0 0
$ yes | head -c 1000 | ./wc61
500 500 1000
$ yes Hello | head -c 1000 | ./wc61
166 167 1000
$ ./hello | ./wc61
1 2 13
$ echo " hi " | ./wc61
1 1 7
Use the isspace
library function, which is declared in the
<cctype>
header, to detect whitespace.
Though this seems like a simple specification, getting simple things right on
all input cases is always hard, and it may take you a while to get the answer
right! Make sure you create your own test cases; the echo " WORDS " | ./wc61
pattern is quite useful.
Part 5. Implement a library function (hard)
Objective: Understand a library function’s specification, reason about special cases, and practice pointer notation.
Implement a function mystrstr
that has exactly the same behavior as
strstr
.
This driver program strstr61.cc
may be useful for testing:
#include <cstring>
#include <cassert>
#include <cstdio>
char* mystrstr(const char* s1, const char* s2) {
// Your code here
return nullptr;
}
int main(int argc, char* argv[]) {
assert(argc == 3);
printf("strstr(\"%s\", \"%s\") = %p\n",
argv[1], argv[2], strstr(argv[1], argv[2]));
printf("mystrstr(\"%s\", \"%s\") = %p\n",
argv[1], argv[2], mystrstr(argv[1], argv[2]));
assert(strstr(argv[1], argv[2]) == mystrstr(argv[1], argv[2]));
}
Examples:
$ make strstr61
$ ./strstr61 "hello, world" "world"
strstr("hello, world", "world") = 0x7ffee2c97bca
mystrstr("hello, world", "world") = 0x7ffee2c97bca
$ ./strstr61 "nfsnafndkanfkan" ""
strstr("nfsnafndkanfkan", "") = 0x7ffee579bbcb
mystrstr("nfsnafndkanfkan", "") = 0x7ffee579bbcb
No matter what arguments you supply, the strstr
and mystrstr
lines should
print the same result.
-
First, implement
mystrstr
using array notation (brackets[]
). Make sure you read the specification forstrstr
carefully so you catch all special cases; do not call any library functions. -
Second, implement
mystrstr
exclusively using pointer operations: do not use brackets at any point.
Part 6. Sort arguments (hard)
Objective: Handle C strings, program arguments, and more complex library functions. Implement algorithms described in pseudocode (such as insertion sort).
Write a program sortargs61
that prints out its command-line arguments, one
per line, in dictionary order (also called lexicographic order). Examples:
$ ./sortargs61 a b c
a
b
c
$ ./sortargs61 e d c b a
a
b
c
d
e
$ ./sortargs61 A a A a A a
A
A
A
a
a
a
$ ./sortargs61
$ ./sortargs61 hello, world, this is a program
a
hello,
is
program
this
world,
A C or C++ program’s command-line arguments are passed in an array called
argv
that is passed tomain
. Up til now, yourmain
functions have taken no arguments;sortargs61
’smain
function should take two arguments, as follows:int main(int argc, char* argv[])
argc
is the number of arguments, andargv[I]
is theI
th argument represented as a C string. Note that theargv[0]
argument is always the name of the program and should generally not be considered a true argument. (Tutorial)
-
First, use a minimal subset of the C library: use
strcmp
and an O(n^2) algorithm such as insertion sort or selection sort. (Recall thatstrcmp(x, y)
returns an integer that is less than zero whenx < y
in lexicographic order, equal to zero whenx
andy
have the same characters in the same order, and greater than zero whenx > y
in lexicographic order.) -
(More advanced) Now do it using C++ library features: use
std::string
(the C++ library type for automatically-managed strings),std::vector
(the C++ library type for automatically-managed, dynamically-sized arrays),std::sort
(the C++ library’s sort algorithm), and C++-style basic input/output. (Those links are to portions of a C++ tutorial, so do follow them if you’re new to C++.)
Going further
Here are some other things you should be able to do in C++:
- Dynamically allocate and free an object with
new
anddelete
. - Dynamically allocate and free an array of objects with
new[]
anddelete[]
. - Define a structure type.
- Use the C library’s string functions correctly, including memory management.
- Write a function that takes three arguments, a size and two
void*
pointers to objects, and exchanges the values of the two objects (each of which have the given size).
Recommended reference: C for Java Programmers
This pset was created for CS61.