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|
/**
* @file llleap_test.cpp
* @author Nat Goodspeed
* @date 2012-02-21
* @brief Test for llleap.
*
* $LicenseInfo:firstyear=2012&license=viewerlgpl$
* Copyright (c) 2012, Linden Research, Inc.
* $/LicenseInfo$
*/
// Precompiled header
#include "linden_common.h"
// associated header
#include "llleap.h"
// STL headers
// std headers
// external library headers
#include <boost/assign/list_of.hpp>
#include <boost/phoenix/core/argument.hpp>
#include <boost/foreach.hpp>
// other Linden headers
#include "../test/lltut.h"
#include "../test/namedtempfile.h"
#include "../test/catch_and_store_what_in.h"
#include "wrapllerrs.h"
#include "llevents.h"
#include "llprocess.h"
#include "stringize.h"
#include "StringVec.h"
#include <functional>
using boost::assign::list_of;
StringVec sv(const StringVec& listof) { return listof; }
#if defined(LL_WINDOWS)
#define sleep(secs) _sleep((secs) * 1000)
// WOLF-300: It appears that driving a megabyte of data through an LLLeap pipe
// causes Windows abdominal pain such that it later fails code-signing in some
// mysterious way. Entirely suppressing these LLLeap tests pushes the failure
// rate MUCH lower. Can we re-enable them with a smaller data size on Windows?
const size_t BUFFERED_LENGTH = 100*1024;
#else // not Windows
const size_t BUFFERED_LENGTH = 1023*1024; // try wrangling just under a megabyte of data
#endif
void waitfor(const std::vector<LLLeap*>& instances, int timeout=60)
{
int i;
for (i = 0; i < timeout; ++i)
{
// Every iteration, test whether any of the passed LLLeap instances
// still exist (are still running).
std::vector<LLLeap*>::const_iterator vli(instances.begin()), vlend(instances.end());
for ( ; vli != vlend; ++vli)
{
// getInstance() returns NULL if it's terminated/gone, non-NULL if
// it's still running
if (LLLeap::getInstance(*vli))
break;
}
// If we made it through all of 'instances' without finding one that's
// still running, we're done.
if (vli == vlend)
{
/*==========================================================================*|
std::cout << instances.size() << " LLLeap instances terminated in "
<< i << " seconds, proceeding" << std::endl;
|*==========================================================================*/
return;
}
// Found an instance that's still running. Wait and pump LLProcess.
sleep(1);
LLEventPumps::instance().obtain("mainloop").post(LLSD());
}
tut::ensure(STRINGIZE("at least 1 of " << instances.size()
<< " LLLeap instances timed out ("
<< timeout << " seconds) without terminating"),
i < timeout);
}
void waitfor(LLLeap* instance, int timeout=60)
{
std::vector<LLLeap*> instances;
instances.push_back(instance);
waitfor(instances, timeout);
}
/*****************************************************************************
* TUT
*****************************************************************************/
namespace tut
{
struct llleap_data
{
llleap_data():
reader(".py",
// This logic is adapted from vita.viewerclient.receiveEvent()
boost::phoenix::placeholders::arg1 <<
"import re\n"
"import os\n"
"import sys\n"
"\n"
// Don't forget that this Python script is written to some
// temp directory somewhere! Its __file__ is useless in
// finding indra/lib/python. Use our __FILE__, with
// raw-string syntax to deal with Windows pathnames.
"mydir = os.path.dirname(r'" << __FILE__ << "')\n"
// We expect mydir to be .../indra/llcommon/tests.
"sys.path.insert(0,\n"
" os.path.join(mydir, os.pardir, os.pardir, 'lib', 'python'))\n"
"from llbase import llsd\n"
"\n"
"class ProtocolError(Exception):\n"
" def __init__(self, msg, data):\n"
" Exception.__init__(self, msg)\n"
" self.data = data\n"
"\n"
"class ParseError(ProtocolError):\n"
" pass\n"
"\n"
"def get():\n"
" hdr = ''\n"
" while ':' not in hdr and len(hdr) < 20:\n"
" hdr += sys.stdin.read(1)\n"
" if not hdr:\n"
" sys.exit(0)\n"
" if not hdr.endswith(':'):\n"
" raise ProtocolError('Expected len:data, got %r' % hdr, hdr)\n"
" try:\n"
" length = int(hdr[:-1])\n"
" except ValueError:\n"
" raise ProtocolError('Non-numeric len %r' % hdr[:-1], hdr[:-1])\n"
" parts = []\n"
" received = 0\n"
" while received < length:\n"
" parts.append(sys.stdin.read(length - received))\n"
" received += len(parts[-1])\n"
" data = ''.join(parts)\n"
" assert len(data) == length\n"
" try:\n"
" return llsd.parse(data)\n"
// Seems the old indra.base.llsd module didn't properly
// convert IndexError (from running off end of string) to
// LLSDParseError.
" except (IndexError, llsd.LLSDParseError), e:\n"
" msg = 'Bad received packet (%s)' % e\n"
" print >>sys.stderr, '%s, %s bytes:' % (msg, len(data))\n"
" showmax = 40\n"
// We've observed failures with very large packets;
// dumping the entire packet wastes time and space.
// But if the error states a particular byte offset,
// truncate to (near) that offset when dumping data.
" location = re.search(r' at (byte|index) ([0-9]+)', str(e))\n"
" if not location:\n"
" # didn't find offset, dump whole thing, no ellipsis\n"
" ellipsis = ''\n"
" else:\n"
" # found offset within error message\n"
" trunc = int(location.group(2)) + showmax\n"
" data = data[:trunc]\n"
" ellipsis = '... (%s more)' % (length - trunc)\n"
" offset = -showmax\n"
" for offset in xrange(0, len(data)-showmax, showmax):\n"
" print >>sys.stderr, '%04d: %r +' % \\\n"
" (offset, data[offset:offset+showmax])\n"
" offset += showmax\n"
" print >>sys.stderr, '%04d: %r%s' % \\\n"
" (offset, data[offset:], ellipsis)\n"
" raise ParseError(msg, data)\n"
"\n"
"# deal with initial stdin message\n"
// this will throw if the initial write to stdin doesn't
// follow len:data protocol, or if we couldn't find 'pump'
// in the dict
"_reply = get()['pump']\n"
"\n"
"def replypump():\n"
" return _reply\n"
"\n"
"def put(req):\n"
" sys.stdout.write(':'.join((str(len(req)), req)))\n"
" sys.stdout.flush()\n"
"\n"
"def send(pump, data):\n"
" put(llsd.format_notation(dict(pump=pump, data=data)))\n"
"\n"
"def request(pump, data):\n"
" # we expect 'data' is a dict\n"
" data['reply'] = _reply\n"
" send(pump, data)\n"),
// Get the actual pathname of the NamedExtTempFile and trim off
// the ".py" extension. (We could cache reader.getName() in a
// separate member variable, but I happen to know getName() just
// returns a NamedExtTempFile member rather than performing any
// computation, so I don't mind calling it twice.) Then take the
// basename.
reader_module(LLProcess::basename(
reader.getName().substr(0, reader.getName().length()-3))),
pPYTHON(getenv("PYTHON")),
PYTHON(pPYTHON? pPYTHON : "")
{
ensure("Set PYTHON to interpreter pathname", pPYTHON);
}
NamedExtTempFile reader;
const std::string reader_module;
const char* pPYTHON;
const std::string PYTHON;
};
typedef test_group<llleap_data> llleap_group;
typedef llleap_group::object object;
llleap_group llleapgrp("llleap");
template<> template<>
void object::test<1>()
{
set_test_name("multiple LLLeap instances");
NamedTempFile script("py",
"import time\n"
"time.sleep(1)\n");
std::vector<LLLeap*> instances;
instances.push_back(LLLeap::create(get_test_name(),
sv(list_of(PYTHON)(script.getName()))));
instances.push_back(LLLeap::create(get_test_name(),
sv(list_of(PYTHON)(script.getName()))));
// In this case we're simply establishing that two LLLeap instances
// can coexist without throwing exceptions or bombing in any other
// way. Wait for them to terminate.
waitfor(instances);
}
template<> template<>
void object::test<2>()
{
set_test_name("stderr to log");
NamedTempFile script("py",
"import sys\n"
"sys.stderr.write('''Hello from Python!\n"
"note partial line''')\n");
CaptureLog log(LLError::LEVEL_INFO);
waitfor(LLLeap::create(get_test_name(),
sv(list_of(PYTHON)(script.getName()))));
log.messageWith("Hello from Python!");
log.messageWith("note partial line");
}
template<> template<>
void object::test<3>()
{
set_test_name("bad stdout protocol");
NamedTempFile script("py",
"print 'Hello from Python!'\n");
CaptureLog log(LLError::LEVEL_WARN);
waitfor(LLLeap::create(get_test_name(),
sv(list_of(PYTHON)(script.getName()))));
ensure_contains("error log line",
log.messageWith("invalid protocol"), "Hello from Python!");
}
template<> template<>
void object::test<4>()
{
set_test_name("leftover stdout");
NamedTempFile script("py",
"import sys\n"
// note lack of newline
"sys.stdout.write('Hello from Python!')\n");
CaptureLog log(LLError::LEVEL_WARN);
waitfor(LLLeap::create(get_test_name(),
sv(list_of(PYTHON)(script.getName()))));
ensure_contains("error log line",
log.messageWith("Discarding"), "Hello from Python!");
}
template<> template<>
void object::test<5>()
{
set_test_name("bad stdout len prefix");
NamedTempFile script("py",
"import sys\n"
"sys.stdout.write('5a2:something')\n");
CaptureLog log(LLError::LEVEL_WARN);
waitfor(LLLeap::create(get_test_name(),
sv(list_of(PYTHON)(script.getName()))));
ensure_contains("error log line",
log.messageWith("invalid protocol"), "5a2:");
}
template<> template<>
void object::test<6>()
{
set_test_name("empty plugin vector");
std::string threw;
try
{
LLLeap::create("empty", StringVec());
}
CATCH_AND_STORE_WHAT_IN(threw, LLLeap::Error)
ensure_contains("LLLeap::Error", threw, "no plugin");
// try the suppress-exception variant
ensure("bad launch returned non-NULL", ! LLLeap::create("empty", StringVec(), false));
}
template<> template<>
void object::test<7>()
{
set_test_name("bad launch");
// Synthesize bogus executable name
std::string BADPYTHON(PYTHON.substr(0, PYTHON.length()-1) + "x");
CaptureLog log;
std::string threw;
try
{
LLLeap::create("bad exe", BADPYTHON);
}
CATCH_AND_STORE_WHAT_IN(threw, LLLeap::Error)
ensure_contains("LLLeap::create() didn't throw", threw, "failed");
log.messageWith("failed");
log.messageWith(BADPYTHON);
// try the suppress-exception variant
ensure("bad launch returned non-NULL", ! LLLeap::create("bad exe", BADPYTHON, false));
}
// Generic self-contained listener: derive from this and override its
// call() method, then tell somebody to post on the pump named getName().
// Control will reach your call() override.
struct ListenerBase
{
// Pass the pump name you want; will tweak for uniqueness.
ListenerBase(const std::string& name):
mPump(name, true)
{
mPump.listen(name, boost::bind(&ListenerBase::call, this, _1));
}
virtual ~ListenerBase() {} // pacify MSVC
virtual bool call(const LLSD& request)
{
return false;
}
LLEventPump& getPump() { return mPump; }
const LLEventPump& getPump() const { return mPump; }
std::string getName() const { return mPump.getName(); }
void post(const LLSD& data) { mPump.post(data); }
LLEventStream mPump;
};
// Mimic a dummy little LLEventAPI that merely sends a reply back to its
// requester on the "reply" pump.
struct AckAPI: public ListenerBase
{
AckAPI(): ListenerBase("AckAPI") {}
virtual bool call(const LLSD& request)
{
LLEventPumps::instance().obtain(request["reply"]).post("ack");
return false;
}
};
// Give LLLeap script a way to post success/failure.
struct Result: public ListenerBase
{
Result(): ListenerBase("Result") {}
virtual bool call(const LLSD& request)
{
mData = request;
return false;
}
void ensure() const
{
tut::ensure(std::string("never posted to ") + getName(), mData.isDefined());
// Post an empty string for success, non-empty string is failure message.
tut::ensure(mData, mData.asString().empty());
}
LLSD mData;
};
template<> template<>
void object::test<8>()
{
set_test_name("round trip");
AckAPI api;
Result result;
NamedTempFile script("py",
boost::phoenix::placeholders::arg1 <<
"from " << reader_module << " import *\n"
// make a request on our little API
"request(pump='" << api.getName() << "', data={})\n"
// wait for its response
"resp = get()\n"
"result = '' if resp == dict(pump=replypump(), data='ack')\\\n"
" else 'bad: ' + str(resp)\n"
"send(pump='" << result.getName() << "', data=result)\n");
waitfor(LLLeap::create(get_test_name(), sv(list_of(PYTHON)(script.getName()))));
result.ensure();
}
struct ReqIDAPI: public ListenerBase
{
ReqIDAPI(): ListenerBase("ReqIDAPI") {}
virtual bool call(const LLSD& request)
{
// free function from llevents.h
sendReply(LLSD(), request);
return false;
}
};
template<> template<>
void object::test<9>()
{
set_test_name("many small messages");
// It's not clear to me whether there's value in iterating many times
// over a send/receive loop -- I don't think that will exercise any
// interesting corner cases. This test first sends a large number of
// messages, then receives all the responses. The intent is to ensure
// that some of that data stream crosses buffer boundaries, loop
// iterations etc. in OS pipes and the LLLeap/LLProcess implementation.
ReqIDAPI api;
Result result;
NamedTempFile script("py",
boost::phoenix::placeholders::arg1 <<
"import sys\n"
"from " << reader_module << " import *\n"
// Note that since reader imports llsd, this
// 'import *' gets us llsd too.
"sample = llsd.format_notation(dict(pump='" <<
api.getName() << "', data=dict(reqid=999999, reply=replypump())))\n"
// The whole packet has length prefix too: "len:data"
"samplen = len(str(len(sample))) + 1 + len(sample)\n"
// guess how many messages it will take to
// accumulate BUFFERED_LENGTH
"count = int(" << BUFFERED_LENGTH << "/samplen)\n"
"print >>sys.stderr, 'Sending %s requests' % count\n"
"for i in xrange(count):\n"
" request('" << api.getName() << "', dict(reqid=i))\n"
// The assumption in this specific test that
// replies will arrive in the same order as
// requests is ONLY valid because the API we're
// invoking sends replies instantly. If the API
// had to wait for some external event before
// sending its reply, replies could arrive in
// arbitrary order, and we'd have to tick them
// off from a set.
"result = ''\n"
"for i in xrange(count):\n"
" resp = get()\n"
" if resp['data']['reqid'] != i:\n"
" result = 'expected reqid=%s in %s' % (i, resp)\n"
" break\n"
"send(pump='" << result.getName() << "', data=result)\n");
waitfor(LLLeap::create(get_test_name(), sv(list_of(PYTHON)(script.getName()))),
300); // needs more realtime than most tests
result.ensure();
}
// This is the body of test<10>, extracted so we can run it over a number
// of large-message sizes.
void test_large_message(const std::string& PYTHON, const std::string& reader_module,
const std::string& test_name, size_t size)
{
ReqIDAPI api;
Result result;
NamedTempFile script("py",
boost::phoenix::placeholders::arg1 <<
"import sys\n"
"from " << reader_module << " import *\n"
// Generate a very large string value.
"desired = int(sys.argv[1])\n"
// 7 chars per item: 6 digits, 1 comma
"count = int((desired - 50)/7)\n"
"large = ''.join('%06d,' % i for i in xrange(count))\n"
// Pass 'large' as reqid because we know the API
// will echo reqid, and we want to receive it back.
"request('" << api.getName() << "', dict(reqid=large))\n"
"try:\n"
" resp = get()\n"
"except ParseError, e:\n"
" # try to find where e.data diverges from expectation\n"
// Normally we'd expect a 'pump' key in there,
// too, with value replypump(). But Python
// serializes keys in a different order than C++,
// so incoming data start with 'data'.
// Truthfully, though, if we get as far as 'pump'
// before we find a difference, something's very
// strange.
" expect = llsd.format_notation(dict(data=dict(reqid=large)))\n"
" chunk = 40\n"
" for offset in xrange(0, max(len(e.data), len(expect)), chunk):\n"
" if e.data[offset:offset+chunk] != \\\n"
" expect[offset:offset+chunk]:\n"
" print >>sys.stderr, 'Offset %06d: expect %r,\\n'\\\n"
" ' get %r' %\\\n"
" (offset,\n"
" expect[offset:offset+chunk],\n"
" e.data[offset:offset+chunk])\n"
" break\n"
" else:\n"
" print >>sys.stderr, 'incoming data matches expect?!'\n"
" send('" << result.getName() << "', '%s: %s' % (e.__class__.__name__, e))\n"
" sys.exit(1)\n"
"\n"
"echoed = resp['data']['reqid']\n"
"if echoed == large:\n"
" send('" << result.getName() << "', '')\n"
" sys.exit(0)\n"
// Here we know echoed did NOT match; try to find where
"for i in xrange(count):\n"
" start = 7*i\n"
" end = 7*(i+1)\n"
" if end > len(echoed)\\\n"
" or echoed[start:end] != large[start:end]:\n"
" send('" << result.getName() << "',\n"
" 'at offset %s, expected %r but got %r' %\n"
" (start, large[start:end], echoed[start:end]))\n"
"sys.exit(1)\n");
waitfor(LLLeap::create(test_name,
sv(list_of
(PYTHON)
(script.getName())
(stringize(size)))),
180); // try a longer timeout
result.ensure();
}
struct TestLargeMessage: public std::binary_function<size_t, size_t, bool>
{
TestLargeMessage(const std::string& PYTHON_, const std::string& reader_module_,
const std::string& test_name_):
PYTHON(PYTHON_),
reader_module(reader_module_),
test_name(test_name_)
{}
bool operator()(size_t left, size_t right) const
{
// We don't know whether upper_bound is going to pass the "sought
// value" as the left or the right operand. We pass 0 as the
// "sought value" so we can distinguish it. Of course that means
// the sequence we're searching must not itself contain 0!
size_t size;
bool success;
if (left)
{
size = left;
// Consider our return value carefully. Normal binary_search
// (or, in our case, upper_bound) expects a container sorted
// in ascending order, and defaults to the std::less
// comparator. Our container is in fact in ascending order, so
// return consistently with std::less. Here we were called as
// compare(item, sought). If std::less were called that way,
// 'true' would mean to move right (to higher numbers) within
// the sequence: the item being considered is less than the
// sought value. For us, that means that test_large_message()
// success should return 'true'.
success = true;
}
else
{
size = right;
// Here we were called as compare(sought, item). If std::less
// were called that way, 'true' would mean to move left (to
// lower numbers) within the sequence: the sought value is
// less than the item being considered. For us, that means
// test_large_message() FAILURE should return 'true', hence
// test_large_message() success should return 'false'.
success = false;
}
try
{
test_large_message(PYTHON, reader_module, test_name, size);
std::cout << "test_large_message(" << size << ") succeeded" << std::endl;
return success;
}
catch (const failure& e)
{
std::cout << "test_large_message(" << size << ") failed: " << e.what() << std::endl;
return ! success;
}
}
const std::string PYTHON, reader_module, test_name;
};
// The point of this function is to try to find a size at which
// test_large_message() can succeed. We still want the overall test to
// fail; otherwise we won't get the coder's attention -- but if
// test_large_message() fails, try to find a plausible size at which it
// DOES work.
void test_or_split(const std::string& PYTHON, const std::string& reader_module,
const std::string& test_name, size_t size)
{
try
{
test_large_message(PYTHON, reader_module, test_name, size);
}
catch (const failure& e)
{
std::cout << "test_large_message(" << size << ") failed: " << e.what() << std::endl;
// If it still fails below 4K, give up: subdividing any further is
// pointless.
if (size >= 4096)
{
try
{
// Recur with half the size
size_t smaller(size/2);
test_or_split(PYTHON, reader_module, test_name, smaller);
// Recursive call will throw if test_large_message()
// failed, therefore we only reach the line below if it
// succeeded.
std::cout << "but test_large_message(" << smaller << ") succeeded" << std::endl;
// Binary search for largest size that works. But since
// std::binary_search() only returns bool, actually use
// std::upper_bound(), consistent with our desire to find
// the LARGEST size that works. First generate a sorted
// container of all the sizes we intend to try, from
// 'smaller' (known to work) to 'size' (known to fail). We
// could whomp up magic iterators to do this dynamically,
// without actually instantiating a vector, but for a test
// program this will do. At least preallocate the vector.
// Per TestLargeMessage comments, it's important that this
// vector not contain 0.
std::vector<size_t> sizes;
sizes.reserve((size - smaller)/4096 + 1);
for (size_t sz(smaller), szend(size); sz < szend; sz += 4096)
sizes.push_back(sz);
// our comparator
TestLargeMessage tester(PYTHON, reader_module, test_name);
// Per TestLargeMessage comments, pass 0 as the sought value.
std::vector<size_t>::const_iterator found =
std::upper_bound(sizes.begin(), sizes.end(), 0, tester);
if (found != sizes.end() && found != sizes.begin())
{
std::cout << "test_large_message(" << *(found - 1)
<< ") is largest that succeeds" << std::endl;
}
else
{
std::cout << "cannot determine largest test_large_message(size) "
<< "that succeeds" << std::endl;
}
}
catch (const failure&)
{
// The recursive test_or_split() call above has already
// handled the exception. We don't want our caller to see
// innermost exception; propagate outermost (below).
}
}
// In any case, because we reached here through failure of
// our original test_large_message(size) call, ensure failure
// propagates.
throw e;
}
}
template<> template<>
void object::test<10>()
{
set_test_name("very large message");
test_or_split(PYTHON, reader_module, get_test_name(), BUFFERED_LENGTH);
}
} // namespace tut
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