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phoenix-firestorm/indra/llcommon/tests/llprocess_test.cpp

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/**
* @file llprocess_test.cpp
* @author Nat Goodspeed
* @date 2011-12-19
* @brief Test for llprocess.
*
* $LicenseInfo:firstyear=2011&license=viewerlgpl$
* Copyright (c) 2011, Linden Research, Inc.
* $/LicenseInfo$
*/
// Precompiled header
#include "linden_common.h"
// associated header
#include "llprocess.h"
// STL headers
#include <vector>
#include <list>
// std headers
#include <fstream>
// external library headers
#include "llapr.h"
#include "apr_thread_proc.h"
#include <boost/foreach.hpp>
#include <boost/function.hpp>
#include <boost/algorithm/string/find_iterator.hpp>
#include <boost/algorithm/string/finder.hpp>
//#include <boost/lambda/lambda.hpp>
//#include <boost/lambda/bind.hpp>
// other Linden headers
#include "../test/lltut.h"
#include "../test/manageapr.h"
#include "../test/namedtempfile.h"
#include "stringize.h"
#include "llsdutil.h"
#if defined(LL_WINDOWS)
#define sleep(secs) _sleep((secs) * 1000)
#define EOL "\r\n"
#else
#define EOL "\n"
#include <sys/wait.h>
#endif
//namespace lambda = boost::lambda;
// static instance of this manages APR init/cleanup
static ManageAPR manager;
/*****************************************************************************
* Helpers
*****************************************************************************/
#define ensure_equals_(left, right) \
ensure_equals(STRINGIZE(#left << " != " << #right), (left), (right))
#define aprchk(expr) aprchk_(#expr, (expr))
static void aprchk_(const char* call, apr_status_t rv, apr_status_t expected=APR_SUCCESS)
{
tut::ensure_equals(STRINGIZE(call << " => " << rv << ": " << manager.strerror(rv)),
rv, expected);
}
/**
* Read specified file using std::getline(). It is assumed to be an error if
* the file is empty: don't use this function if that's an acceptable case.
* Last line will not end with '\n'; this is to facilitate the usual case of
* string compares with a single line of output.
* @param pathname The file to read.
* @param desc Optional description of the file for error message;
* defaults to "in <pathname>"
*/
static std::string readfile(const std::string& pathname, const std::string& desc="")
{
std::string use_desc(desc);
if (use_desc.empty())
{
use_desc = STRINGIZE("in " << pathname);
}
std::ifstream inf(pathname.c_str());
std::string output;
tut::ensure(STRINGIZE("No output " << use_desc), std::getline(inf, output));
std::string more;
while (std::getline(inf, more))
{
output += '\n' + more;
}
return output;
}
/**
* Construct an LLProcess to run a Python script.
*/
struct PythonProcessLauncher
{
/**
* @param desc Arbitrary description for error messages
* @param script Python script, any form acceptable to NamedTempFile,
* typically either a std::string or an expression of the form
* (lambda::_1 << "script content with " << variable_data)
*/
template <typename CONTENT>
PythonProcessLauncher(const std::string& desc, const CONTENT& script):
mDesc(desc),
mScript("py", script)
{
const char* PYTHON(getenv("PYTHON"));
tut::ensure("Set $PYTHON to the Python interpreter", PYTHON);
mParams["executable"] = PYTHON;
mParams["args"].append(mScript.getName());
}
/// Run Python script and wait for it to complete.
void run()
{
mPy = LLProcess::create(mParams);
tut::ensure(STRINGIZE("Couldn't launch " << mDesc << " script"), mPy);
// One of the irritating things about LLProcess is that
// there's no API to wait for the child to terminate -- but given
// its use in our graphics-intensive interactive viewer, it's
// understandable.
while (mPy->isRunning())
{
sleep(1);
}
}
/**
* Run a Python script using LLProcess, expecting that it will
* write to the file passed as its sys.argv[1]. Retrieve that output.
*
* Until January 2012, LLProcess provided distressingly few
* mechanisms for a child process to communicate back to its caller --
* not even its return code. We've introduced a convention by which we
* create an empty temp file, pass the name of that file to our child
* as sys.argv[1] and expect the script to write its output to that
* file. This function implements the C++ (parent process) side of
* that convention.
*/
std::string run_read()
{
NamedTempFile out("out", ""); // placeholder
// pass name of this temporary file to the script
mParams["args"].append(out.getName());
run();
// assuming the script wrote to that file, read it
return readfile(out.getName(), STRINGIZE("from " << mDesc << " script"));
}
LLSD mParams;
LLProcessPtr mPy;
std::string mDesc;
NamedTempFile mScript;
};
/// convenience function for PythonProcessLauncher::run()
template <typename CONTENT>
static void python(const std::string& desc, const CONTENT& script)
{
PythonProcessLauncher py(desc, script);
py.run();
}
/// convenience function for PythonProcessLauncher::run_read()
template <typename CONTENT>
static std::string python_out(const std::string& desc, const CONTENT& script)
{
PythonProcessLauncher py(desc, script);
return py.run_read();
}
/// Create a temporary directory and clean it up later.
class NamedTempDir: public boost::noncopyable
{
public:
// Use python() function to create a temp directory: I've found
// nothing in either Boost.Filesystem or APR quite like Python's
// tempfile.mkdtemp().
// Special extra bonus: on Mac, mkdtemp() reports a pathname
// starting with /var/folders/something, whereas that's really a
// symlink to /private/var/folders/something. Have to use
// realpath() to compare properly.
NamedTempDir():
mPath(python_out("mkdtemp()",
"from __future__ import with_statement\n"
"import os.path, sys, tempfile\n"
"with open(sys.argv[1], 'w') as f:\n"
" f.write(os.path.realpath(tempfile.mkdtemp()))\n"))
{}
~NamedTempDir()
{
aprchk(apr_dir_remove(mPath.c_str(), gAPRPoolp));
}
std::string getName() const { return mPath; }
private:
std::string mPath;
};
/*****************************************************************************
* TUT
*****************************************************************************/
namespace tut
{
struct llprocess_data
{
LLAPRPool pool;
};
typedef test_group<llprocess_data> llprocess_group;
typedef llprocess_group::object object;
llprocess_group llprocessgrp("llprocess");
struct Item
{
Item(): tries(0) {}
unsigned tries;
std::string which;
std::string what;
};
/*==========================================================================*|
#define tabent(symbol) { symbol, #symbol }
static struct ReasonCode
{
int code;
const char* name;
} reasons[] =
{
tabent(APR_OC_REASON_DEATH),
tabent(APR_OC_REASON_UNWRITABLE),
tabent(APR_OC_REASON_RESTART),
tabent(APR_OC_REASON_UNREGISTER),
tabent(APR_OC_REASON_LOST),
tabent(APR_OC_REASON_RUNNING)
};
#undef tabent
|*==========================================================================*/
struct WaitInfo
{
WaitInfo(apr_proc_t* child_):
child(child_),
rv(-1), // we haven't yet called apr_proc_wait()
rc(0),
why(apr_exit_why_e(0))
{}
apr_proc_t* child; // which subprocess
apr_status_t rv; // return from apr_proc_wait()
int rc; // child's exit code
apr_exit_why_e why; // APR_PROC_EXIT, APR_PROC_SIGNAL, APR_PROC_SIGNAL_CORE
};
void child_status_callback(int reason, void* data, int status)
{
/*==========================================================================*|
std::string reason_str;
BOOST_FOREACH(const ReasonCode& rcp, reasons)
{
if (reason == rcp.code)
{
reason_str = rcp.name;
break;
}
}
if (reason_str.empty())
{
reason_str = STRINGIZE("unknown reason " << reason);
}
std::cout << "child_status_callback(" << reason_str << ")\n";
|*==========================================================================*/
if (reason == APR_OC_REASON_DEATH || reason == APR_OC_REASON_LOST)
{
// Somewhat oddly, APR requires that you explicitly unregister
// even when it already knows the child has terminated.
apr_proc_other_child_unregister(data);
WaitInfo* wi(static_cast<WaitInfo*>(data));
// It's just wrong to call apr_proc_wait() here. The only way APR
// knows to call us with APR_OC_REASON_DEATH is that it's already
// reaped this child process, so calling wait() will only produce
// "huh?" from the OS. We must rely on the status param passed in,
// which unfortunately comes straight from the OS wait() call.
// wi->rv = apr_proc_wait(wi->child, &wi->rc, &wi->why, APR_NOWAIT);
wi->rv = APR_CHILD_DONE; // fake apr_proc_wait() results
#if defined(LL_WINDOWS)
wi->why = APR_PROC_EXIT;
wi->rc = status; // no encoding on Windows (no signals)
#else // Posix
if (WIFEXITED(status))
{
wi->why = APR_PROC_EXIT;
wi->rc = WEXITSTATUS(status);
}
else if (WIFSIGNALED(status))
{
wi->why = APR_PROC_SIGNAL;
wi->rc = WTERMSIG(status);
}
else // uh, shouldn't happen?
{
wi->why = APR_PROC_EXIT;
wi->rc = status; // someone else will have to decode
}
#endif // Posix
}
}
template<> template<>
void object::test<1>()
{
set_test_name("raw APR nonblocking I/O");
// Create a script file in a temporary place.
NamedTempFile script("py",
"import sys" EOL
"import time" EOL
EOL
"time.sleep(2)" EOL
"print >>sys.stdout, 'stdout after wait'" EOL
"sys.stdout.flush()" EOL
"time.sleep(2)" EOL
"print >>sys.stderr, 'stderr after wait'" EOL
"sys.stderr.flush()" EOL
);
// Arrange to track the history of our interaction with child: what we
// fetched, which pipe it came from, how many tries it took before we
// got it.
std::vector<Item> history;
history.push_back(Item());
// Run the child process.
apr_procattr_t *procattr = NULL;
aprchk(apr_procattr_create(&procattr, pool.getAPRPool()));
aprchk(apr_procattr_io_set(procattr, APR_CHILD_BLOCK, APR_CHILD_BLOCK, APR_CHILD_BLOCK));
aprchk(apr_procattr_cmdtype_set(procattr, APR_PROGRAM_PATH));
std::vector<const char*> argv;
apr_proc_t child;
argv.push_back("python");
// Have to have a named copy of this std::string so its c_str() value
// will persist.
std::string scriptname(script.getName());
argv.push_back(scriptname.c_str());
argv.push_back(NULL);
aprchk(apr_proc_create(&child, argv[0],
&argv[0],
NULL, // if we wanted to pass explicit environment
procattr,
pool.getAPRPool()));
// We do not want this child process to outlive our APR pool. On
// destruction of the pool, forcibly kill the process. Tell APR to try
// SIGTERM and wait 3 seconds. If that didn't work, use SIGKILL.
apr_pool_note_subprocess(pool.getAPRPool(), &child, APR_KILL_AFTER_TIMEOUT);
// arrange to call child_status_callback()
WaitInfo wi(&child);
apr_proc_other_child_register(&child, child_status_callback, &wi, child.in, pool.getAPRPool());
// TODO:
// Stuff child.in until it (would) block to verify EWOULDBLOCK/EAGAIN.
// Have child script clear it later, then write one more line to prove
// that it gets through.
// Monitor two different output pipes. Because one will be closed
// before the other, keep them in a list so we can drop whichever of
// them is closed first.
typedef std::pair<std::string, apr_file_t*> DescFile;
typedef std::list<DescFile> DescFileList;
DescFileList outfiles;
outfiles.push_back(DescFile("out", child.out));
outfiles.push_back(DescFile("err", child.err));
while (! outfiles.empty())
{
// This peculiar for loop is designed to let us erase(dfli). With
// a list, that invalidates only dfli itself -- but even so, we
// lose the ability to increment it for the next item. So at the
// top of every loop, while dfli is still valid, increment
// dflnext. Then before the next iteration, set dfli to dflnext.
for (DescFileList::iterator
dfli(outfiles.begin()), dflnext(outfiles.begin()), dflend(outfiles.end());
dfli != dflend; dfli = dflnext)
{
// Only valid to increment dflnext once we're sure it's not
// already at dflend.
++dflnext;
char buf[4096];
apr_status_t rv = apr_file_gets(buf, sizeof(buf), dfli->second);
if (APR_STATUS_IS_EOF(rv))
{
// std::cout << "(EOF on " << dfli->first << ")\n";
// history.back().which = dfli->first;
// history.back().what = "*eof*";
// history.push_back(Item());
outfiles.erase(dfli);
continue;
}
if (rv == EWOULDBLOCK || rv == EAGAIN)
{
// std::cout << "(waiting; apr_file_gets(" << dfli->first << ") => " << rv << ": " << manager.strerror(rv) << ")\n";
++history.back().tries;
continue;
}
aprchk_("apr_file_gets(buf, sizeof(buf), dfli->second)", rv);
// Is it even possible to get APR_SUCCESS but read 0 bytes?
// Hope not, but defend against that anyway.
if (buf[0])
{
// std::cout << dfli->first << ": " << buf;
history.back().which = dfli->first;
history.back().what.append(buf);
if (buf[strlen(buf) - 1] == '\n')
history.push_back(Item());
else
{
// Just for pretty output... if we only read a partial
// line, terminate it.
// std::cout << "...\n";
}
}
}
// Do this once per tick, as we expect the viewer will
apr_proc_other_child_refresh_all(APR_OC_REASON_RUNNING);
sleep(1);
}
apr_file_close(child.in);
apr_file_close(child.out);
apr_file_close(child.err);
// Okay, we've broken the loop because our pipes are all closed. If we
// haven't yet called wait, give the callback one more chance. This
// models the fact that unlike this small test program, the viewer
// will still be running.
if (wi.rv == -1)
{
std::cout << "last gasp apr_proc_other_child_refresh_all()\n";
apr_proc_other_child_refresh_all(APR_OC_REASON_RUNNING);
}
if (wi.rv == -1)
{
std::cout << "child_status_callback(APR_OC_REASON_DEATH) wasn't called" << std::endl;
wi.rv = apr_proc_wait(wi.child, &wi.rc, &wi.why, APR_NOWAIT);
}
// std::cout << "child done: rv = " << rv << " (" << manager.strerror(rv) << "), why = " << why << ", rc = " << rc << '\n';
aprchk_("apr_proc_wait(wi->child, &wi->rc, &wi->why, APR_NOWAIT)", wi.rv, APR_CHILD_DONE);
ensure_equals_(wi.why, APR_PROC_EXIT);
ensure_equals_(wi.rc, 0);
// Beyond merely executing all the above successfully, verify that we
// obtained expected output -- and that we duly got control while
// waiting, proving the non-blocking nature of these pipes.
try
{
unsigned i = 0;
ensure("blocking I/O on child pipe (0)", history[i].tries);
ensure_equals_(history[i].which, "out");
ensure_equals_(history[i].what, "stdout after wait" EOL);
// ++i;
// ensure_equals_(history[i].which, "out");
// ensure_equals_(history[i].what, "*eof*");
++i;
ensure("blocking I/O on child pipe (1)", history[i].tries);
ensure_equals_(history[i].which, "err");
ensure_equals_(history[i].what, "stderr after wait" EOL);
// ++i;
// ensure_equals_(history[i].which, "err");
// ensure_equals_(history[i].what, "*eof*");
}
catch (const failure&)
{
std::cout << "History:\n";
BOOST_FOREACH(const Item& item, history)
{
std::string what(item.what);
if ((! what.empty()) && what[what.length() - 1] == '\n')
{
what.erase(what.length() - 1);
if ((! what.empty()) && what[what.length() - 1] == '\r')
{
what.erase(what.length() - 1);
what.append("\\r");
}
what.append("\\n");
}
std::cout << " " << item.which << ": '" << what << "' ("
<< item.tries << " tries)\n";
}
std::cout << std::flush;
// re-raise same error; just want to enrich the output
throw;
}
}
template<> template<>
void object::test<2>()
{
set_test_name("setWorkingDirectory()");
// We want to test setWorkingDirectory(). But what directory is
// guaranteed to exist on every machine, under every OS? Have to
// create one. Naturally, ensure we clean it up when done.
NamedTempDir tempdir;
PythonProcessLauncher py("getcwd()",
"from __future__ import with_statement\n"
"import os, sys\n"
"with open(sys.argv[1], 'w') as f:\n"
" f.write(os.getcwd())\n");
// Before running, call setWorkingDirectory()
py.mParams["cwd"] = tempdir.getName();
ensure_equals("os.getcwd()", py.run_read(), tempdir.getName());
}
template<> template<>
void object::test<3>()
{
set_test_name("arguments");
PythonProcessLauncher py("args",
"from __future__ import with_statement\n"
"import sys\n"
// note nonstandard output-file arg!
"with open(sys.argv[3], 'w') as f:\n"
" for arg in sys.argv[1:]:\n"
" print >>f, arg\n");
// We expect that PythonProcessLauncher has already appended
// its own NamedTempFile to mParams["args"] (sys.argv[0]).
py.mParams["args"].append("first arg"); // sys.argv[1]
py.mParams["args"].append("second arg"); // sys.argv[2]
// run_read() appends() one more argument, hence [3]
std::string output(py.run_read());
boost::split_iterator<std::string::const_iterator>
li(output, boost::first_finder("\n")), lend;
ensure("didn't get first arg", li != lend);
std::string arg(li->begin(), li->end());
ensure_equals(arg, "first arg");
++li;
ensure("didn't get second arg", li != lend);
arg.assign(li->begin(), li->end());
ensure_equals(arg, "second arg");
++li;
ensure("didn't get output filename?!", li != lend);
arg.assign(li->begin(), li->end());
ensure("output filename empty?!", ! arg.empty());
++li;
ensure("too many args", li == lend);
}
template<> template<>
void object::test<4>()
{
set_test_name("explicit kill()");
PythonProcessLauncher py("kill()",
"from __future__ import with_statement\n"
"import sys, time\n"
"with open(sys.argv[1], 'w') as f:\n"
" f.write('ok')\n"
"# now sleep; expect caller to kill\n"
"time.sleep(120)\n"
"# if caller hasn't managed to kill by now, bad\n"
"with open(sys.argv[1], 'w') as f:\n"
" f.write('bad')\n");
NamedTempFile out("out", "not started");
py.mParams["args"].append(out.getName());
py.mPy = LLProcess::create(py.mParams);
ensure("couldn't launch kill() script", py.mPy);
// Wait for the script to wake up and do its first write
int i = 0, timeout = 60;
for ( ; i < timeout; ++i)
{
sleep(1);
if (readfile(out.getName(), "from kill() script") == "ok")
break;
}
// If we broke this loop because of the counter, something's wrong
ensure("script never started", i < timeout);
// script has performed its first write and should now be sleeping.
py.mPy->kill();
// wait for the script to terminate... one way or another.
while (py.mPy->isRunning())
{
sleep(1);
}
// If kill() failed, the script would have woken up on its own and
// overwritten the file with 'bad'. But if kill() succeeded, it should
// not have had that chance.
ensure_equals("kill() script output", readfile(out.getName()), "ok");
}
template<> template<>
void object::test<5>()
{
set_test_name("implicit kill()");
NamedTempFile out("out", "not started");
LLProcess::id pid(0);
{
PythonProcessLauncher py("kill()",
"from __future__ import with_statement\n"
"import sys, time\n"
"with open(sys.argv[1], 'w') as f:\n"
" f.write('ok')\n"
"# now sleep; expect caller to kill\n"
"time.sleep(120)\n"
"# if caller hasn't managed to kill by now, bad\n"
"with open(sys.argv[1], 'w') as f:\n"
" f.write('bad')\n");
py.mParams["args"].append(out.getName());
py.mPy = LLProcess::create(py.mParams);
ensure("couldn't launch kill() script", py.mPy);
// Capture id for later
pid = py.mPy->getProcessID();
// Wait for the script to wake up and do its first write
int i = 0, timeout = 60;
for ( ; i < timeout; ++i)
{
sleep(1);
if (readfile(out.getName(), "from kill() script") == "ok")
break;
}
// If we broke this loop because of the counter, something's wrong
ensure("script never started", i < timeout);
// Script has performed its first write and should now be sleeping.
// Destroy the LLProcess, which should kill the child.
}
// wait for the script to terminate... one way or another.
while (LLProcess::isRunning(pid))
{
sleep(1);
}
// If kill() failed, the script would have woken up on its own and
// overwritten the file with 'bad'. But if kill() succeeded, it should
// not have had that chance.
ensure_equals("kill() script output", readfile(out.getName()), "ok");
}
template<> template<>
void object::test<6>()
{
set_test_name("autokill");
NamedTempFile from("from", "not started");
NamedTempFile to("to", "");
LLProcess::id pid(0);
{
PythonProcessLauncher py("autokill",
"from __future__ import with_statement\n"
"import sys, time\n"
"with open(sys.argv[1], 'w') as f:\n"
" f.write('ok')\n"
"# wait for 'go' from test program\n"
"for i in xrange(60):\n"
" time.sleep(1)\n"
" with open(sys.argv[2]) as f:\n"
" go = f.read()\n"
" if go == 'go':\n"
" break\n"
"else:\n"
" with open(sys.argv[1], 'w') as f:\n"
" f.write('never saw go')\n"
" sys.exit(1)\n"
"# okay, saw 'go', write 'ack'\n"
"with open(sys.argv[1], 'w') as f:\n"
" f.write('ack')\n");
py.mParams["args"].append(from.getName());
py.mParams["args"].append(to.getName());
py.mParams["autokill"] = false;
py.mPy = LLProcess::create(py.mParams);
ensure("couldn't launch kill() script", py.mPy);
// Capture id for later
pid = py.mPy->getProcessID();
// Wait for the script to wake up and do its first write
int i = 0, timeout = 60;
for ( ; i < timeout; ++i)
{
sleep(1);
if (readfile(from.getName(), "from autokill script") == "ok")
break;
}
// If we broke this loop because of the counter, something's wrong
ensure("script never started", i < timeout);
// Now destroy the LLProcess, which should NOT kill the child!
}
// If the destructor killed the child anyway, give it time to die
sleep(2);
// How do we know it's not terminated? By making it respond to
// a specific stimulus in a specific way.
{
std::ofstream outf(to.getName().c_str());
outf << "go";
} // flush and close.
// now wait for the script to terminate... one way or another.
while (LLProcess::isRunning(pid))
{
sleep(1);
}
// If the LLProcess destructor implicitly called kill(), the
// script could not have written 'ack' as we expect.
ensure_equals("autokill script output", readfile(from.getName()), "ack");
}
} // namespace tut
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