In Part I we discussed about the fork system call and its caveats. In this post, we shall explore how to execute commands.

Exec

This brings us to the exec family of functions. Namely, it has the following functions:

execl

execv

execle

execve

execlp

execvp

For our needs, we will use execvp whose signature looks like this:

int execvp ( const char * file , char * const argv []);

The vp in the name of the function indicates that, it accepts the name of a file, for which it will search for in the $PATH variable of the system and an array of arguments to be executed.

You may read the man page for exec for more information on the other functions.

Let us take a look at the following code, which executes the command ls -l -h -a :

execvp.c

1 2 3 4 5 6 7 8 #include <unistd.h> int main () { char * argv [] = { "ls" , "-l" , "-h" , "-a" , NULL }; execvp ( argv [ 0 ], argv ); return 0 ; }

A few things to note about the execvp function:

The first argument is the name of the command The second argument consists of the name of the command and the arguments passed to the command itself. It must also be terminated by NULL . It also swaps out the current process image with that of the command being executed, but more on that later.

If you compile and execute the above, you will see an output similar to the following:

total 32 drwxr-xr-x 5 dhanush staff 170B Jun 11 11:32 . drwxr-xr-x 4 dhanush staff 136B Jun 11 11:30 .. -rwxr-xr-x 1 dhanush staff 8.7K Jun 11 11:32 a.out drwxr-xr-x 3 dhanush staff 102B Jun 11 11:32 a.out.dSYM -rw-r--r-- 1 dhanush staff 130B Jun 11 11:32 execvp.c

Which is exactly the same if you manually execute ls -l -h -a in your primary shell.

Now that we can execute commands, we need to construct something useful using the fork system call that we learned about in part I. In effect we will do the following:

Accept the command as user input. Call fork to create a child process. Execute the command in the child process while the parent waits for the command to complete. Return back to step 1.

Let us take a look at the following function. which takes a string as the input . We use the library function strtok to split the string by the character space and return an array of strings instead. We also terminate the array by NULL .

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 #include <stdlib.h> #include <string.h> char ** get_input ( char * input ) { char ** command = malloc ( 8 * sizeof ( char * )); char * separator = " " ; char * parsed ; int index = 0 ; parsed = strtok ( input , separator ); while ( parsed != NULL ) { command [ index ] = parsed ; index ++ ; parsed = strtok ( NULL , separator ); } command [ index ] = NULL ; return command ; }

If the input to the function is the string "ls -l -h -a" , then the function will create an array of the form ["ls", "-l", "-h", "-a", NULL] and return the pointer to this array.

Now in our main function, we invoke readline to read an input from the user, and pass it to get_input we just defined above. Once the input has been parsed, we call fork and call execvp in the child process. Before we dive into the code, take a look at the following diagram, to understand the semantics of execvp first:

When the fork command completes, the child is an exact copy of the parent process. However, when we invoke execvp , it replaces the current program with the program passed to it in the arguments. What this means is that although the current text, data, heap and stack segments of the process are replaced, the process id still remains unchanged, but the program gets overwritten completely. If the invocation is successful, then execvp never returns, and any code in the child after this will not be executed. And here is the main function:

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 #include <stdlib.h> #include <stdio.h> #include <string.h> #include <readline/readline.h> #include <unistd.h> #include <sys/wait.h> int main () { char ** command ; char * input ; pid_t child_pid ; int stat_loc ; while ( 1 ) { input = readline ( "unixsh> " ); command = get_input ( input ); child_pid = fork (); if ( child_pid == 0 ) { /* Never returns if the call is successful */ execvp ( command [ 0 ], command ); printf ( "This won't be printed if execvp is successul

" ); } else { waitpid ( child_pid , & stat_loc , WUNTRACED ); } free ( input ); free ( command ); } return 0 ; }

The entire code is available in a single file here. If you compile it with gcc -g -lreadline shell.c and execute the binary, you will have a minimal working shell, and you can use it to run system commands like pwd and ls -lha :

unixsh> pwd /Users/dhanush/github.com/indradhanush.github.io/code/shell-part-2 unixsh> ls -lha total 28K drwxr-xr-x 6 root root 204 Jun 11 18:27 . drwxr-xr-x 3 root root 4.0K Jun 11 16:50 .. -rwxr-xr-x 1 root root 16K Jun 11 18:27 a.out drwxr-xr-x 3 root root 102 Jun 11 15:32 a.out.dSYM -rw-r--r-- 1 root root 130 Jun 11 15:38 execvp.c -rw-r--r-- 1 root root 997 Jun 11 18:25 shell.c unixsh>

Note that the fork is only called after the command has been entered by the user, which means that the user prompt accepting input from the user is the parent process.

Error handling

So far we have assumed that all our commands would work perfectly all the time and we are not handling the errors. So we will make a few changes to shell.c:

fork - If the OS runs out of memory or reaches the maximum number of allowed processes, a child process will not be created and it will return -1. We add the following to our code:

... while ( 1 ) { input = readline ( "unixsh> " ); command = get_input ( input ); child_pid = fork (); if ( child_pid < 0 ) { perror ( "Fork failed" ); exit ( 1 ); } ...

execvp - As explained above, it will never return on a successful invocation. However, if it will return -1 if the execution has failed. Likewise, we modify our call to execvp :

... if ( execvp ( command [ 0 ], command ) < 0 ) { perror ( command [ 0 ]); exit ( 1 ); } ...

Note that, while the exit call after fork terminates the entire program, the exit call after execvp will only terminate the child, since the code belongs to the child process only.

malloc - It can fail if the OS runs out of memory. We should exit the program in such a scenario:

char ** get_input ( char * input ) { char ** command = malloc ( 8 * sizeof ( char * )); if ( command == NULL ) { perror ( "malloc failed" ); exit ( 1 ); } ...

Dynamic memory allocation - Currently our command buffer allocates 8 blocks only. If we enter a command which has more than 8 words, our command will not work as expected. This has been done to keep the example easy to understand and has been left as an exercise for the reader.

The code with error handling as shown above is available here.

Builtin commands

If you try to execute the cd command, you will get an error that says:

cd: No such file or directory

Our shell does not recognize the cd command yet. The reason behind this is that it is not a system program like ls or pwd . Let us take a step back and assume for a moment that cd is a system program as well. What do you think the execution flow will be like? You may want to think about it before reading further.

The flow proceeds like this:

The user sends the input cd / . The shell forks the current process and executes the command in the child. After a successful invocation, the child exits and the control is returned to the parent process. The current working directory of the parent has not changed, since the command was executed in the child. As a result, the cd command although successful, did not produce the result that we desired.

Thus, to support cd we will have to implement it on our own. We also need to ensure that, if the command entered by the user is cd (or belongs to a list of pre-defined built-in commands), we will not fork the process at all. Instead, we will execute our implementation of cd (or any other built-in) and move on to wait for the next user input. For cd , thankfully we have the chdir function call available to us and using it is straightforward. It accepts the path as an argument and returns 0 upon success and -1 upon a failure. We define our function:

int cd ( char * path ) { return chdir ( path ); }

And add a check in our main function for it:

while ( 1 ) { input = readline ( "unixsh> " ); command = get_input ( input ); if ( strcmp ( command [ 0 ], "cd" ) == 0 ) { if ( cd ( command [ 1 ]) < 0 ) { perror ( command [ 1 ]); } /* Skip the fork */ continue ; } ...

The code with the above changes is available here and if you compile and execute it, you will be able to run the cd command. Here is an example output:

unixsh> pwd /Users/dhanush/github.com/indradhanush.github.io/code/shell-part-2 unixsh> cd / unixsh> pwd / unixsh>

And that brings us to the end of part II. All the code examples shown in this blog post are available here. In the next blog post we will explore the topic of signals and implement handling user interrupts (Ctrl-C). Stay tuned.

Acknowledgements

Thanks to Dominic Spadacene for pairing with me on this and to Saul Pwanson for helping me solve the weird memory leaks when nothing seemed to be working.

Update: Saul mentioned that checking for errors with < 0 is conventionally better than == -1 , since some APIs might return negative values other than just -1 and < 0 helps protect against those. I’ve updated the post and the code examples accordingly.

Resources

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