Question

I'm testing subprocesses pipelines with python. I'm aware that I can do what the programs below do in python directly, but that's not the point. I just want to test the pipeline so I know how to use it.

My system is Linux Ubuntu 9.04 with default python 2.6.

I started with this documentation example.

from subprocess import Popen, PIPE
p1 = Popen(["grep", "-v", "not"], stdout=PIPE)
p2 = Popen(["cut", "-c", "1-10"], stdin=p1.stdout, stdout=PIPE)
output = p2.communicate()[0]
print output

That works, but since p1's stdin is not being redirected, I have to type stuff in the terminal to feed the pipe. When I type ^D closing stdin, I get the output I want.

However, I want to send data to the pipe using a python string variable. First I tried writing on stdin:

p1 = Popen(["grep", "-v", "not"], stdin=PIPE, stdout=PIPE)
p2 = Popen(["cut", "-c", "1-10"], stdin=p1.stdout, stdout=PIPE)
p1.stdin.write('test\n')
output = p2.communicate()[0] # blocks forever here

Didn't work. I tried using p2.stdout.read() instead on last line, but it also blocks. I added p1.stdin.flush() and p1.stdin.close() but it didn't work either. I Then I moved to communicate:

p1 = Popen(["grep", "-v", "not"], stdin=PIPE, stdout=PIPE)
p2 = Popen(["cut", "-c", "1-10"], stdin=p1.stdout, stdout=PIPE)
p1.communicate('test\n') # blocks forever here
output = p2.communicate()[0]

So that's still not it.

I noticed that running a single process (like p1 above, removing p2) works perfectly. And passing a file handle to p1 (stdin=open(...)) also works. So the problem is:

Is it possible to pass data to a pipeline of 2 or more subprocesses in python, without blocking? Why not?

I'm aware I could run a shell and run the pipeline in the shell, but that's not what I want.

---

UPDATE 1: Following Aaron Digulla's hint below I'm now trying to use threads to make it work.

First I've tried running p1.communicate on a thread.

p1 = Popen(["grep", "-v", "not"], stdin=PIPE, stdout=PIPE)
p2 = Popen(["cut", "-c", "1-10"], stdin=p1.stdout, stdout=PIPE)
t = threading.Thread(target=p1.communicate, args=('some data\n',))
t.start()
output = p2.communicate()[0] # blocks forever here

Okay, didn't work. Tried other combinations like changing it to .write() and also p2.read(). Nothing. Now let's try the opposite approach:

def get_output(subp):
    output = subp.communicate()[0] # blocks on thread
    print 'GOT:', output

p1 = Popen(["grep", "-v", "not"], stdin=PIPE, stdout=PIPE)
p2 = Popen(["cut", "-c", "1-10"], stdin=p1.stdout, stdout=PIPE)
t = threading.Thread(target=get_output, args=(p2,)) 
t.start()
p1.communicate('data\n') # blocks here.
t.join()

code ends up blocking somewhere. Either in the spawned thread, or in the main thread, or both. So it didn't work. If you know how to make it work it would make easier if you can provide working code. I'm trying here.

---

UPDATE 2

Paul Du Bois answered below with some information, so I did more tests. I've read entire subprocess.py module and got how it works. So I tried applying exactly that to code.

I'm on linux, but since I was testing with threads, my first approach was to replicate the exact windows threading code seen on subprocess.py's communicate() method, but for two processes instead of one. Here's the entire listing of what I tried:

import os
from subprocess import Popen, PIPE
import threading

def get_output(fobj, buffer):
    while True:
        chunk = fobj.read() # BLOCKS HERE
        if not chunk:
            break
        buffer.append(chunk)

p1 = Popen(["grep", "-v", "not"], stdin=PIPE, stdout=PIPE)
p2 = Popen(["cut", "-c", "1-10"], stdin=p1.stdout, stdout=PIPE)

b = [] # create a buffer
t = threading.Thread(target=get_output, args=(p2.stdout, b))
t.start() # start reading thread

for x in xrange(100000):
    p1.stdin.write('hello world\n') # write data
    p1.stdin.flush()
p1.stdin.close() # close input...
t.join()

Well. It didn't work. Even after p1.stdin.close() was called, p2.stdout.read() still blocks.

Then I tried the posix code on subprocess.py:

import os
from subprocess import Popen, PIPE
import select

p1 = Popen(["grep", "-v", "not"], stdin=PIPE, stdout=PIPE)
p2 = Popen(["cut", "-c", "1-10"], stdin=p1.stdout, stdout=PIPE)

numwrites = 100000
to_read = [p2.stdout]
to_write = [p1.stdin]
b = [] # create buffer

while to_read or to_write:
    read_now, write_now, xlist = select.select(to_read, to_write, [])
    if read_now:
        data = os.read(p2.stdout.fileno(), 1024)
        if not data:
            p2.stdout.close()
            to_read = []
        else:
            b.append(data)

    if write_now:
        if numwrites > 0:
            numwrites -= 1
            p1.stdin.write('hello world!\n'); p1.stdin.flush()
        else:
            p1.stdin.close()
            to_write = []

print b

Also blocks on select.select(). By spreading prints around, I found out this:

• Reading is working. Code reads many times during execution.
• Writing is also working. Data is written to p1.stdin.
• At the end of numwrites, p1.stdin.close() is called.
• When select() starts blocking, only to_read has something, p2.stdout. to_write is already empty.
• os.read() call always returns something, so p2.stdout.close() is never called.

Conclusion from both tests: Closing the stdin of the first process on the pipeline (grep in the example) is not making it dump its buffered output to the next and die.

No way to make it work?

PS: I don't want to use a temporary file, I've already tested with files and I know it works. And I don't want to use windows.

Answer 1

I found out how to do it.

It is not about threads, and not about select().

When I run the first process (grep), it creates two low-level file descriptors, one for each pipe. Lets call those a and b.

When I run the second process, b gets passed to cut sdtin. But there is a brain-dead default on Popen - close_fds=False.

The effect of that is that cut also inherits a. So grep can't die even if I close a, because stdin is still open on cut's process (cut ignores it).

The following code now runs perfectly.

from subprocess import Popen, PIPE

p1 = Popen(["grep", "-v", "not"], stdin=PIPE, stdout=PIPE)
p2 = Popen(["cut", "-c", "1-10"], stdin=p1.stdout, stdout=PIPE, close_fds=True)
p1.stdin.write('Hello World\n')
p1.stdin.close()
result = p2.stdout.read() 
assert result == "Hello Worl\n"

close_fds=True SHOULD BE THE DEFAULT on unix systems. On windows it closes all fds, so it prevents piping.

Answer 2

What about using a SpooledTemporaryFile ? This bypasses (but perhaps doesn't solve) the issue:

http://docs.python.org/library/tempfile.html#tempfile.SpooledTemporaryFile

You can write to it like a file, but it's actually a memory block.

Or am I totally misunderstanding...

Answer 3

I think you may be examining the wrong problem. Certainly as Aaron says if you try to be both a producer to the beginning of a pipeline, and a consumer of the end of the pipeline, it is easy to get into a deadlock situation. This is the problem that communicate() solves.

communicate() isn't exactly correct for you since stdin and stdout are on different subprocess objects; but if you take a look at the implementation in subprocess.py you'll see that it does exactly what Aaron suggested.

Once you see that communicate both reads and writes, you'll see that in your second try communicate() competes with p2 for the output of p1:

p1 = Popen(["grep", "-v", "not"], stdin=PIPE, stdout=PIPE)
p2 = Popen(["cut", "-c", "1-10"], stdin=p1.stdout, stdout=PIPE)
# ...
p1.communicate('data\n')       # reads from p1.stdout, as does p2

I am running on win32, which definitely has different i/o and buffering characteristics, but this works for me:

p1 = Popen(["grep", "-v", "not"], stdin=PIPE, stdout=PIPE)
p2 = Popen(["cut", "-c", "1-10"], stdin=p1.stdout, stdout=PIPE)
t = threading.Thread(target=get_output, args=(p2,)) 
t.start()
p1.stdin.write('hello world\n' * 100000)
p1.stdin.close()
t.join()

I tuned the input size to produce a deadlock when using a naive unthreaded p2.read()

You might also try buffering into a file, eg

fd, _ = tempfile.mkstemp()
os.write(fd, 'hello world\r\n' * 100000)
os.lseek(fd, 0, os.SEEK_SET)
p1 = Popen(["grep", "-v", "not"], stdin=fd, stdout=PIPE)
p2 = Popen(["cut", "-c", "1-10"], stdin=p1.stdout, stdout=PIPE)
print p2.stdout.read()

That also works for me without deadlocks.

Answer 4

You must do this in several threads. Otherwise, you'll end up in a situation where you can't send data: child p1 won't read your input since p2 doesn't read p1's output because you don't read p2's output.

So you need a background thread that reads what p2 writes out. That will allow p2 to continue after writing some data to the pipe, so it can read the next line of input from p1 which again allows p1 to process the data which you send to it.

Alternatively, you can send the data to p1 with a background thread and read the output from p2 in the main thread. But either side must be a thread.