One of the fundamental features that makes Linux and other Unices useful is the “pipe”. Pipes allow separate processes to communicate without having been designed explicitly to work together. This allows tools quite narrow in their function to be combined in complex ways.
A simple example of using a pipe is the command:
ls | grep x
When bash examines the command line, it finds the vertical bar character | that separates the two commands. Bash and other shells run both commands, connecting the output of the first to the input of the second. The ls program produces a list of files in the current directory, while the grep program reads the output of ls and prints only those lines containing the letter x.
The above, familiar to most Unix users, is an example of an “unnamed pipe”. The pipe exists only inside the kernel and cannot be accessed by processes that created it, in this case, the bash shell. For those who don't already know, a parent process is the first process started by a program that in turn creates separate child processes that execute the program.
The other sort of pipe is a “named” pipe, which is sometimes called a FIFO. FIFO stands for “First In, First Out” and refers to the property that the order of bytes going in is the same coming out. The “name” of a named pipe is actually a file name within the file system. Pipes are shown by ls as any other file with a couple of differences:
% ls -l fifo1 prw-r--r-- 1 andy users 0 Jan 22 23:11 fifo1|
The p in the leftmost column indicates that fifo1 is a pipe. The rest of the permission bits control who can read or write to the pipe just like a regular file. On systems with a modern ls, the | character at the end of the file name is another clue, and on Linux systems with the color option enabled, fifo| is printed in red by default.
On older Linux systems, named pipes are created by the mknod program, usually located in the /etc directory. On more modern systems, mkfifo is a standard utility. The mkfifo program takes one or more file names as arguments for this task and creates pipes with those names. For example, to create a named pipe with the name pipe1 give the command:
mkfifo pipe
The simplest way to show how named pipes work is with an example. Suppose we've created pipe as shown above. In one virtual console1, type:
ls -l > pipe1and in another type:
cat < pipeVoila! The output of the command run on the first console shows up on the second console. Note that the order in which you run the commands doesn't matter.
If you haven't used virtual consoles before, see the article “Keyboards, Consoles and VT Cruising” by John M. Fisk in the November 1996 Linux Journal.
If you watch closely, you'll notice that the first command you run appears to hang. This happens because the other end of the pipe is not yet connected, and so the kernel suspends the first process until the second process opens the pipe. In Unix jargon, the process is said to be “blocked”, since it is waiting for something to happen.
One very useful application of named pipes is to allow totally unrelated programs to communicate with each other. For example, a program that services requests of some sort (print files, access a database) could open the pipe for reading. Then, another process could make a request by opening the pipe and writing a command. That is, the “server” can perform a task on behalf of the “client”. Blocking can also happen if the client isn't writing, or the server isn't reading.
Create two named pipes, pipe1 and pipe2. Run the commands:
echo -n x | cat - pipe1 > pipe2 & cat <pipe2 > pipe1
On screen, it will not appear that anything is happening, but if you run top (a command similar to ps for showing process status), you'll see that both cat programs are running like crazy copying the letter x back and forth in an endless loop.
After you press ctrl-C to get out of the loop, you may receive the message “broken pipe”. This error occurs when a process writing to a pipe when the process reading the pipe closes its end. Since the reader is gone, the data has no place to go. Normally, the writer will finish writing its data and close the pipe. At this point, the reader sees the EOF (end of file) and executes the request.
Whether or not the “broken pipe” message is issued depends on events at the exact instant the ctrl-C is pressed. If the second cat has just read the x, pressing ctrl-C stops the second cat, pipe1 is closed and the first cat stops quietly, i.e., without a message. On the other hand, if the second cat is waiting for the first to write the x, ctrl-C causes pipe2 to close before the first cat can write to it, and the error message is issued. This sort of random behavior is known as a “race condition”.
Bash uses named pipes in a really neat way. Recall that when you enclose a command in parenthesis, the command is actually run in a “subshell”; that is, the shell clones itself and the clone interprets the command(s) within the parenthesis. Since the outer shell is running only a single “command”, the output of a complete set of commands can be redirected as a unit. For example, the command:
(ls -l; ls -l) >ls.out
writes two copies of the current directory listing to the file ls.out.
Command substitution occurs when you put a < or > in front of the left parenthesis. For instance, typing the command:
cat <(ls -l)
results in the command ls -l executing in a subshell as usual, but redirects the output to a temporary named pipe, which bash creates, names and later deletes. Therefore, cat has a valid file name to read from, and we see the output of ls -l, taking one more step than usual to do so. Similarly, giving >(commands) results in Bash naming a temporary pipe, which the commands inside the parenthesis read for input.
If you want to see whether two directories contain the same file names, run the single command:
cmp <(ls /dir1) <(ls /dir2)
The compare program cmp will see the names of two files which it will read and compare.
Command substitution also makes the tee command (used to view and save the output of a command) much more useful in that you can cause a single stream of input to be read by multiple readers without resorting to temporary files—bash does all the work for you. The command:
ls | tee >(grep foo | wc >foo.count)
>(grep bar | wc >bar.count)
| grep baz | wc >baz.count
counts the number of occurrences of foo, bar and baz in the output of ls and writes this information to three separate files. Command substitutions can even be nested:
cat <(cat <(cat <(ls -l))))works as a very roundabout way to list the current directory.
As you can see, while the unnamed pipes allow simple commands to be strung together, named pipes, with a little help from bash, allow whole trees of pipes to be created. The possibilities are limited only by your imagination.
摘抄自: https://www.linuxjournal.com/article/2156
Named Pipe or FIFO with example C program
In computing, a named pipe (also known as a FIFO) is one of the methods for intern-process communication.
- It is an extension to the traditional pipe concept on Unix. A traditional pipe is “unnamed” and lasts only as long as the process.
- A named pipe, however, can last as long as the system is up, beyond the life of the process. It can be deleted if no longer used.
- Usually a named pipe appears as a file, and generally processes attach to it for inter-process communication. A FIFO file is a special kind of file on the local storage which allows two or more processes to communicate with each other by reading/writing to/from this file.
- A FIFO special file is entered into the filesystem by calling mkfifo() in C. Once we have created a FIFO special file in this way, any process can open it for reading or writing, in the same way as an ordinary file. However, it has to be open at both ends simultaneously before you can proceed to do any input or output operations on it.
Creating a FIFO file
In order to create a FIFO file, a function calls i.e. mkfifo is used.
Using FIFO
As named pipe(FIFO) is a kind of file, we can use all the system calls associated with it i.e. open, read, write, close.
Example Programs to illustrate the named pipe.
There are two programs that use same FIFO. The program 1 writes first, then reads. The program 2 reads first, then writes. They both keep doing it until terminated.
Program 1(Writes first)
// C program to implement one side of FIFO // This side writes first, then reads #include <stdio.h> #include <string.h> #include <fcntl.h> #include <sys/stat.h> #include <sys/types.h> #include <unistd.h> int main() { int fd; // FIFO file path char * myfifo = "/tmp/myfifo"; // Creating the named file(FIFO) // mkfifo(<pathname>, <permission>) mkfifo(myfifo, 0666); char arr1[80], arr2[80]; while (1) { // Open FIFO for write only fd = open(myfifo, O_WRONLY); // Take an input arr2ing from user. // 80 is maximum length fgets(arr2, 80, stdin); // Write the input arr2ing on FIFO // and close it write(fd, arr2, strlen(arr2)+1); close(fd); // Open FIFO for Read only fd = open(myfifo, O_RDONLY); // Read from FIFO read(fd, arr1, sizeof(arr1)); // Print the read message printf("User2: %s ", arr1); close(fd); } return 0; }
Program 2(Reads First)
// C program to implement one side of FIFO // This side reads first, then reads #include <stdio.h> #include <string.h> #include <fcntl.h> #include <sys/stat.h> #include <sys/types.h> #include <unistd.h> int main() { int fd1; // FIFO file path char * myfifo = "/tmp/myfifo"; // Creating the named file(FIFO) // mkfifo(<pathname>,<permission>) mkfifo(myfifo, 0666); char str1[80], str2[80]; while (1) { // First open in read only and read fd1 = open(myfifo,O_RDONLY); read(fd1, str1, 80); // Print the read string and close printf("User1: %s ", str1); close(fd1); // Now open in write mode and write // string taken from user. fd1 = open(myfifo,O_WRONLY); fgets(str2, 80, stdin); write(fd1, str2, strlen(str2)+1); close(fd1); } return 0; }
Output: Run the two programs simultaneously on two terminals.
摘抄自:https://www.geeksforgeeks.org/named-pipe-fifo-example-c-program/