辅导COM S 352编程、讲解c/c++程序、program语言程序调试
- 首页 >> Matlab编程 Project 1: 352> Shell
COM S 352 Spring 2021
1. Introduction
This project consists of designing a C program to serve as a shell interface that accepts user
commands and then executes each command in a separate process. Your implementation will
support input and output redirection, pipes, and background processes. Completing this project
will involve using the Linux fork(), exec(), wait(), waitpid(), pipe() and dup2()
system calls. It must be tested on pyrite.
2. Main Loop
In its normal mode of operation, the shell prompts the user, after which the next command is
entered. In the example below, the prompt is 352> and the user's next command is cat -n
prog.c.
352> cat -n prog.c
The command is executed while the shell waits for it to complete, after completion the shell
prompts the user for the next command. Following the UNIX philosophy, most commands are
separate utility programs distributed along with the OS, there are only a few built-in
commands: exit, jobs and bg. The purpose of exit should be clear, jobs and bg are
described in Section 7.
Most of the main loop is provided for you in the starter code in Section 9.
3. Basic Commands
A basic command consists of the name of an executable file, followed by zero or more space
separated arguments. The input and parsing of the command line is performed for you in the
starter code. Parsing populates an instance of the Cmd struct. For example, calling the parser
with the argument cmd having the field cmd->line of "cat -n prog.c" results in the
following assignments (note that the character \0 in a string literal means NULL).
cmd->line = "cat -n prog.c";
cmd->tokenLine = "cat\0-n\0prog.c";
cmd->args = {pointer_to_c, pointer_to_minus_sign, pointer_to_p, NULL…};
cmd->symbols = {NULL, NULL, NULL, NULL…};
Commands should be run in a separate child process. Basic commands must be executed in the
foreground, this means the shell is blocked (waiting) until the child process terminates. The
child process is created using the fork() system call, the user's command is executed using
one of the system calls in the exec() family and the shell waits for the command to complete
using one of the system calls in the wait() family. Get started by writing a function to execute
a command and call it from main() at the location indicated by the line:
/* TODO: Run command in foreground. */
4. File Redirection
Your shell should be modified to support the ‘>’ and ‘<’ redirection operators, where ‘>’
redirects the output of a command to a file and ‘<’ redirects the input to a command from a
file. For example, if a user enters
352> ls > out.txt
the output from the ls command will be redirected to the file out.txt. Similarly, input can
be redirected as well. For example, if the user enters
352> sort < in.txt
the file in.txt will serve as input to the sort command.
The parser recognizes ‘<’ and ‘>’ as special symbols, for example, calling the parser with the
argument cmd having the field cmd->line of "sort < in.txt" results in the following.
cmd->line = "sort < in.txt";
cmd->tokenLine = "sort\0<\0in.txt";
cmd->args = {pointer_to_s, NULL, pointer_to_i, NULL…};
cmd->symbols = {NULL, pointer_to_lt, NULL, NULL…};
Simplifying Assumption: You can assume that commands will contain either one input or one
output redirection and will not contain both. In other words, you do not have to be concerned
with command sequences such as sort < in.txt > out.txt.
5. Pipes
Your shell should be modified to support the ‘|’ pipe operator, which connects the stdout
of one process to the stdin of another.
352> ls | grep txt
The output from the ls command will be piped to the utility grep.
Managing the redirection of both input and output will involve using the dup2() function,
which duplicates an existing file descriptor to another file descriptor. For example, if fd is a file
descriptor to the file out.txt, the call
dup2(fd, STDOUT_FILENO);
duplicates fd to standard output (the terminal). This means that any writes to standard output
will in fact be sent to the out.txt file.
Simplifying Assumption: You can assume that commands will contain no more than one pipe.
In other words, you do not have to be concerned with command sequences such as
ls | grep txt | wc -l.
6. Background Commands
The use of an ampersand (&) at the end of a line indicates that the command should be
executed in the background. The shell does not wait for background commands to complete, it
immediately prompts the user for the next command. However, the shell is expected to
monitor the status of background commands, in order to inform the user when a command
completes. Helper functions should be created and called from main() to start a command and
check if a command is completed at the following TODO lines.
/* TODO: Run command in background. */
/* TODO: Check on status of background processes. */
When a background command is started the shell assigns it a number (starting at 1) and
displays the pid of the process. When the process exits normally the shell displays the
message Done commandArgs as shown in the following example.
352> ls -la &
[1] 84653
-rw-r--r-- 1 user group 100 Aug 28 03:22 file1
-rw-r--r-- 1 user group 100 Aug 28 03:22 file2
-rw-r--r-- 1 user group 100 Aug 28 03:22 file3
352>
[1] Done ls -la
It is common for the Done message to not be displayed immediately, for example it may only
be displayed after the user’s next line of input (which can be a blank line as shown above). This
is due to the status check only being called once per iteration of the main loop. Because the
status check cannot block the shell, like it does with foreground processes, waitpid() should
be called in a non-blocking mode as discussed in lecture.
Sometimes a process exits with a non-zero exit code, in that case the shell should display
(replacing exitCode and commandArgs): Exit exitCode commandArgs
352> grep &
[1] 84867
usage: grep [-abcDEFGHhIiJLlmnOoqRSsUVvwxZ] [-A num]
[-B num] [-C[num]] [-e pattern] [-f file]
[--binary-files=value] [--color=when]
[--context[=num]] [--directories=action] [--label]
[--line-buffered] [--null] [pattern] [file ...]
352>
[1] Exit 2 grep
A process might not exit on its own and instead it is terminated using the kill command, when
that happens the shell should display (replacing commandArgs): Terminated
commandArgs.
352> cat &
[1] 84665
352> kill 84665
[1] Terminated cat
The kill command works by sending an unhandled signal such as SIGTERM to a process. You
can test if a child process was terminated in this way, as opposed to the process self-exiting
with a call to exit(), by using WIFSIGNALED.
Finally, add the capacity to run multiple background processes concurrently.
352> sleep 15 &
[1] 85119
352> sleep 8 &
[2] 85120
352> sleep 20 &
[3] 85122
352>
[2] Done sleep 8
352>
[1] Done sleep 15
352>
[3] Done sleep 20
Your shell can now perform sleep sort!
Simplifying Assumption: You can assume that background commands will not contain a pipe. In
other words, you do not have to be concerned with command sequences such as
ls | grep txt &.
7. Job Control Commands
Jobs include background commands and stopped foreground commands. Implement the
following built-in commands to control jobs.
jobs
Implement the built-in jobs command which prints the list of background commands and
stopped commands. The status of a job can be running or stopped. Background commands
created with & are running by default. The following is an example.
352> jobs
[1] Stopped sleep 100
[2] Running sleep 100 &
[3] Running sleep 100 &
The next two requirements provide situations where a command may switch between running
and stopped.
control+z
Implement control+z to stop the currently running foreground command. When a user
presses control+z, the terminal send the signal SIGTSTP (SIGnal - Terminal
SToP) to the shell. Forwarding this signal, from the shell to the process running in the
foreground, has already be implemented for you with the function sigtstpHandler().
What still needs to be done, is the stopped command needs to be add to the list of jobs. Its
status is stopped.
bg job_id
Implement the bg job_id command which resumes a stopped command. The status of the
command should be set to running. For example, consider the following scenario.
352> sleep 100
[User presses control+z.]
352> jobs
[1] Stopped sleep 100
352> bg 1
[1] Running sleep 100
To make a process continue from a stopped state, send it a SIGCONT signal.
Simplifying Assumption: You can assume that stoped commands will not contain a pipe. In
other words, you do not have to be concerned with the user pressing control+z on a command
sequence such as ls | grep txt.
8. Additional Requirements
makefile (5 points)
You get 5 points for simply using a makefile. Name your source files whatever you like. Please
name your executable shell352. Be sure that "make" will build your executable on pyrite.
Documentation (10 points)
If you have more than one source file, then you must submit a Readme file containing a brief
explanation of the functionality of each source file. Each source file must also be welldocumented.
There should be a paragraph or so at the beginning of each source file describing
the code; functions and data structures should also be explained. Basically, another
programmer should be able to understand your code from the comments.
Project Submission
Put all your source files (including the makefile and the README file) in a folder. Then use
command zip -r to create a .zip file. For
example, if your Net-ID is ksmith and project1 is the name of the folder that contains all
your source files, then you will type zip -r ksmith project1 to create a file named
ksmith.zip and then submit this file.
9. Starter Code
You are not required to use this code, however, it is highly recommended. Use the TODOs as a
guide to start working on the project.
#include
#include
#include
#include
#include
#include
#include
#include
#define MAX_LINE 80
#define MAX_ARGS (MAX_LINE/2 + 1)
#define REDIRECT_OUT_OP '>'
#define REDIRECT_IN_OP '<'
#define PIPE_OP '|'
#define BG_OP '&'
/* Holds a single command. */
typedef struct Cmd {
/* The command as input by the user. */
char line[MAX_LINE + 1];
/* The command as null terminated tokens. */
char tokenLine[MAX_LINE + 1];
/* Pointers to each argument in tokenLine, non-arguments are NULL. */
char* args[MAX_ARGS];
/* Pointers to each symbol in tokenLine, non-symbols are NULL. */
char* symbols[MAX_ARGS];
/* The process id of the executing command. */
pid_t pid;
/* TODO: Additional fields may be helpful. */
} Cmd;
/* The process of the currently executing foreground command, or 0. */
pid_t foregroundPid = 0;
/* Parses the command string contained in cmd->line.
* Assumes all fields in cmd (except cmd->line) are initailized to zero.
* On return, all fields of cmd are appropriatly populated. */
void parseCmd(Cmd* cmd) {
char* token;
int i=0;
strcpy(cmd->tokenLine, cmd->line);
strtok(cmd->tokenLine, "\n");
token = strtok(cmd->tokenLine, " ");
while (token != NULL) {
if (*token == '\n') {
cmd->args[i] = NULL;
} else if (*token == REDIRECT_OUT_OP || *token == REDIRECT_IN_OP
|| *token == PIPE_OP || *token == BG_OP) {
cmd->symbols[i] = token;
cmd->args[i] = NULL;
} else {
cmd->args[i] = token;
}
token = strtok(NULL, " ");
i++;
}
cmd->args[i] = NULL;
}
/* Finds the index of the first occurance of symbol in cmd->symbols.
* Returns -1 if not found. */
int findSymbol(Cmd* cmd, char symbol) {
for (int i = 0; i < MAX_ARGS; i++) {
if (cmd->symbols[i] && *cmd->symbols[i] == symbol) {
return i;
}
}
return -1;
}
/* Signal handler for SIGTSTP (SIGnal - Terminal SToP),
* which is caused by the user pressing control+z. */
void sigtstpHandler(int sig_num) {
/* Reset handler to catch next SIGTSTP. */
signal(SIGTSTP, sigtstpHandler);
if (foregroundPid > 0) {
/* Foward SIGTSTP to the currently running foreground process. */
kill(foregroundPid, SIGTSTP);
/* TODO: Add foreground command to the list of jobs. */
}
}
int main(void) {
/* Listen for control+z (suspend process). */
signal(SIGTSTP, sigtstpHandler);
while (1) {
printf("352> ");
fflush(stdout);
Cmd *cmd = (Cmd*) calloc(1, sizeof(Cmd));
fgets(cmd->line, MAX_LINE, stdin);
parseCmd(cmd);
if (!cmd->args[0]) {
free(cmd);
} else if (strcmp(cmd->args[0], "exit") == 0) {
free(cmd);
exit(0);
/* TODO: Add built-in commands: jobs and bg. */
} else {
if (findSymbol(cmd, BG_OP) != -1) {
/* TODO: Run command in background. */
} else {
/* TODO: Run command in foreground. */
}
}
/* TODO: Check on status of background processes. */
}
return 0;
}
COM S 352 Spring 2021
1. Introduction
This project consists of designing a C program to serve as a shell interface that accepts user
commands and then executes each command in a separate process. Your implementation will
support input and output redirection, pipes, and background processes. Completing this project
will involve using the Linux fork(), exec(), wait(), waitpid(), pipe() and dup2()
system calls. It must be tested on pyrite.
2. Main Loop
In its normal mode of operation, the shell prompts the user, after which the next command is
entered. In the example below, the prompt is 352> and the user's next command is cat -n
prog.c.
352> cat -n prog.c
The command is executed while the shell waits for it to complete, after completion the shell
prompts the user for the next command. Following the UNIX philosophy, most commands are
separate utility programs distributed along with the OS, there are only a few built-in
commands: exit, jobs and bg. The purpose of exit should be clear, jobs and bg are
described in Section 7.
Most of the main loop is provided for you in the starter code in Section 9.
3. Basic Commands
A basic command consists of the name of an executable file, followed by zero or more space
separated arguments. The input and parsing of the command line is performed for you in the
starter code. Parsing populates an instance of the Cmd struct. For example, calling the parser
with the argument cmd having the field cmd->line of "cat -n prog.c" results in the
following assignments (note that the character \0 in a string literal means NULL).
cmd->line = "cat -n prog.c";
cmd->tokenLine = "cat\0-n\0prog.c";
cmd->args = {pointer_to_c, pointer_to_minus_sign, pointer_to_p, NULL…};
cmd->symbols = {NULL, NULL, NULL, NULL…};
Commands should be run in a separate child process. Basic commands must be executed in the
foreground, this means the shell is blocked (waiting) until the child process terminates. The
child process is created using the fork() system call, the user's command is executed using
one of the system calls in the exec() family and the shell waits for the command to complete
using one of the system calls in the wait() family. Get started by writing a function to execute
a command and call it from main() at the location indicated by the line:
/* TODO: Run command in foreground. */
4. File Redirection
Your shell should be modified to support the ‘>’ and ‘<’ redirection operators, where ‘>’
redirects the output of a command to a file and ‘<’ redirects the input to a command from a
file. For example, if a user enters
352> ls > out.txt
the output from the ls command will be redirected to the file out.txt. Similarly, input can
be redirected as well. For example, if the user enters
352> sort < in.txt
the file in.txt will serve as input to the sort command.
The parser recognizes ‘<’ and ‘>’ as special symbols, for example, calling the parser with the
argument cmd having the field cmd->line of "sort < in.txt" results in the following.
cmd->line = "sort < in.txt";
cmd->tokenLine = "sort\0<\0in.txt";
cmd->args = {pointer_to_s, NULL, pointer_to_i, NULL…};
cmd->symbols = {NULL, pointer_to_lt, NULL, NULL…};
Simplifying Assumption: You can assume that commands will contain either one input or one
output redirection and will not contain both. In other words, you do not have to be concerned
with command sequences such as sort < in.txt > out.txt.
5. Pipes
Your shell should be modified to support the ‘|’ pipe operator, which connects the stdout
of one process to the stdin of another.
352> ls | grep txt
The output from the ls command will be piped to the utility grep.
Managing the redirection of both input and output will involve using the dup2() function,
which duplicates an existing file descriptor to another file descriptor. For example, if fd is a file
descriptor to the file out.txt, the call
dup2(fd, STDOUT_FILENO);
duplicates fd to standard output (the terminal). This means that any writes to standard output
will in fact be sent to the out.txt file.
Simplifying Assumption: You can assume that commands will contain no more than one pipe.
In other words, you do not have to be concerned with command sequences such as
ls | grep txt | wc -l.
6. Background Commands
The use of an ampersand (&) at the end of a line indicates that the command should be
executed in the background. The shell does not wait for background commands to complete, it
immediately prompts the user for the next command. However, the shell is expected to
monitor the status of background commands, in order to inform the user when a command
completes. Helper functions should be created and called from main() to start a command and
check if a command is completed at the following TODO lines.
/* TODO: Run command in background. */
/* TODO: Check on status of background processes. */
When a background command is started the shell assigns it a number (starting at 1) and
displays the pid of the process. When the process exits normally the shell displays the
message Done commandArgs as shown in the following example.
352> ls -la &
[1] 84653
-rw-r--r-- 1 user group 100 Aug 28 03:22 file1
-rw-r--r-- 1 user group 100 Aug 28 03:22 file2
-rw-r--r-- 1 user group 100 Aug 28 03:22 file3
352>
[1] Done ls -la
It is common for the Done message to not be displayed immediately, for example it may only
be displayed after the user’s next line of input (which can be a blank line as shown above). This
is due to the status check only being called once per iteration of the main loop. Because the
status check cannot block the shell, like it does with foreground processes, waitpid() should
be called in a non-blocking mode as discussed in lecture.
Sometimes a process exits with a non-zero exit code, in that case the shell should display
(replacing exitCode and commandArgs): Exit exitCode commandArgs
352> grep &
[1] 84867
usage: grep [-abcDEFGHhIiJLlmnOoqRSsUVvwxZ] [-A num]
[-B num] [-C[num]] [-e pattern] [-f file]
[--binary-files=value] [--color=when]
[--context[=num]] [--directories=action] [--label]
[--line-buffered] [--null] [pattern] [file ...]
352>
[1] Exit 2 grep
A process might not exit on its own and instead it is terminated using the kill command, when
that happens the shell should display (replacing commandArgs): Terminated
commandArgs.
352> cat &
[1] 84665
352> kill 84665
[1] Terminated cat
The kill command works by sending an unhandled signal such as SIGTERM to a process. You
can test if a child process was terminated in this way, as opposed to the process self-exiting
with a call to exit(), by using WIFSIGNALED.
Finally, add the capacity to run multiple background processes concurrently.
352> sleep 15 &
[1] 85119
352> sleep 8 &
[2] 85120
352> sleep 20 &
[3] 85122
352>
[2] Done sleep 8
352>
[1] Done sleep 15
352>
[3] Done sleep 20
Your shell can now perform sleep sort!
Simplifying Assumption: You can assume that background commands will not contain a pipe. In
other words, you do not have to be concerned with command sequences such as
ls | grep txt &.
7. Job Control Commands
Jobs include background commands and stopped foreground commands. Implement the
following built-in commands to control jobs.
jobs
Implement the built-in jobs command which prints the list of background commands and
stopped commands. The status of a job can be running or stopped. Background commands
created with & are running by default. The following is an example.
352> jobs
[1] Stopped sleep 100
[2] Running sleep 100 &
[3] Running sleep 100 &
The next two requirements provide situations where a command may switch between running
and stopped.
control+z
Implement control+z to stop the currently running foreground command. When a user
presses control+z, the terminal send the signal SIGTSTP (SIGnal - Terminal
SToP) to the shell. Forwarding this signal, from the shell to the process running in the
foreground, has already be implemented for you with the function sigtstpHandler().
What still needs to be done, is the stopped command needs to be add to the list of jobs. Its
status is stopped.
bg job_id
Implement the bg job_id command which resumes a stopped command. The status of the
command should be set to running. For example, consider the following scenario.
352> sleep 100
[User presses control+z.]
352> jobs
[1] Stopped sleep 100
352> bg 1
[1] Running sleep 100
To make a process continue from a stopped state, send it a SIGCONT signal.
Simplifying Assumption: You can assume that stoped commands will not contain a pipe. In
other words, you do not have to be concerned with the user pressing control+z on a command
sequence such as ls | grep txt.
8. Additional Requirements
makefile (5 points)
You get 5 points for simply using a makefile. Name your source files whatever you like. Please
name your executable shell352. Be sure that "make" will build your executable on pyrite.
Documentation (10 points)
If you have more than one source file, then you must submit a Readme file containing a brief
explanation of the functionality of each source file. Each source file must also be welldocumented.
There should be a paragraph or so at the beginning of each source file describing
the code; functions and data structures should also be explained. Basically, another
programmer should be able to understand your code from the comments.
Project Submission
Put all your source files (including the makefile and the README file) in a folder. Then use
command zip -r
example, if your Net-ID is ksmith and project1 is the name of the folder that contains all
your source files, then you will type zip -r ksmith project1 to create a file named
ksmith.zip and then submit this file.
9. Starter Code
You are not required to use this code, however, it is highly recommended. Use the TODOs as a
guide to start working on the project.
#include
#include
#include
#include
#include
#include
#include
#include
#define MAX_LINE 80
#define MAX_ARGS (MAX_LINE/2 + 1)
#define REDIRECT_OUT_OP '>'
#define REDIRECT_IN_OP '<'
#define PIPE_OP '|'
#define BG_OP '&'
/* Holds a single command. */
typedef struct Cmd {
/* The command as input by the user. */
char line[MAX_LINE + 1];
/* The command as null terminated tokens. */
char tokenLine[MAX_LINE + 1];
/* Pointers to each argument in tokenLine, non-arguments are NULL. */
char* args[MAX_ARGS];
/* Pointers to each symbol in tokenLine, non-symbols are NULL. */
char* symbols[MAX_ARGS];
/* The process id of the executing command. */
pid_t pid;
/* TODO: Additional fields may be helpful. */
} Cmd;
/* The process of the currently executing foreground command, or 0. */
pid_t foregroundPid = 0;
/* Parses the command string contained in cmd->line.
* Assumes all fields in cmd (except cmd->line) are initailized to zero.
* On return, all fields of cmd are appropriatly populated. */
void parseCmd(Cmd* cmd) {
char* token;
int i=0;
strcpy(cmd->tokenLine, cmd->line);
strtok(cmd->tokenLine, "\n");
token = strtok(cmd->tokenLine, " ");
while (token != NULL) {
if (*token == '\n') {
cmd->args[i] = NULL;
} else if (*token == REDIRECT_OUT_OP || *token == REDIRECT_IN_OP
|| *token == PIPE_OP || *token == BG_OP) {
cmd->symbols[i] = token;
cmd->args[i] = NULL;
} else {
cmd->args[i] = token;
}
token = strtok(NULL, " ");
i++;
}
cmd->args[i] = NULL;
}
/* Finds the index of the first occurance of symbol in cmd->symbols.
* Returns -1 if not found. */
int findSymbol(Cmd* cmd, char symbol) {
for (int i = 0; i < MAX_ARGS; i++) {
if (cmd->symbols[i] && *cmd->symbols[i] == symbol) {
return i;
}
}
return -1;
}
/* Signal handler for SIGTSTP (SIGnal - Terminal SToP),
* which is caused by the user pressing control+z. */
void sigtstpHandler(int sig_num) {
/* Reset handler to catch next SIGTSTP. */
signal(SIGTSTP, sigtstpHandler);
if (foregroundPid > 0) {
/* Foward SIGTSTP to the currently running foreground process. */
kill(foregroundPid, SIGTSTP);
/* TODO: Add foreground command to the list of jobs. */
}
}
int main(void) {
/* Listen for control+z (suspend process). */
signal(SIGTSTP, sigtstpHandler);
while (1) {
printf("352> ");
fflush(stdout);
Cmd *cmd = (Cmd*) calloc(1, sizeof(Cmd));
fgets(cmd->line, MAX_LINE, stdin);
parseCmd(cmd);
if (!cmd->args[0]) {
free(cmd);
} else if (strcmp(cmd->args[0], "exit") == 0) {
free(cmd);
exit(0);
/* TODO: Add built-in commands: jobs and bg. */
} else {
if (findSymbol(cmd, BG_OP) != -1) {
/* TODO: Run command in background. */
} else {
/* TODO: Run command in foreground. */
}
}
/* TODO: Check on status of background processes. */
}
return 0;
}