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lumiera_/tests/library/random-concurrent-test.cpp
Ichthyostega a20e233ca0 Library: now using controlled seed and replaced rand (closes #1378) 
After augmenting our `lib/random.hpp` abstraction framework to add the necessary flexibility,
a common seeding scheme was ''built into the Test-Runner.''
 * all tests relying on some kind of randomness should invoke `seedRand()`
 * this draws a seed from the `entropyGen` — which is also documented in the log
 * individual tests can now be launched with `--seed` to force a dedicated seed
 * moreover, tests should build a coherent structure of linked generators,
   especially when running concurrently. The existing tests were adapted accordingly

All usages of `rand()` in the code base were investigated and replaced
by suitable calls to our abstraction framework; the code base is thus
isolated from the actual implementation, simplifying further adaptation.
2024-11-17 19:45:41 +01:00

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/*
RandomConcurrent(Test) - investigate concurrent random number generation
Copyright (C) Lumiera.org
2024, Hermann Vosseler <Ichthyostega@web.de>
This program is free software; you can redistribute it and/or
modify it under the terms of the GNU General Public License as
published by the Free Software Foundation; either version 2 of
the License, or (at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
* *****************************************************/
/** @file random-concurrent-test.cpp
** unit test \ref RandomConcurrent_test
*/
#include "lib/test/run.hpp"
#include "lib/sync-barrier.hpp"
#include "lib/random.hpp"
#include "lib/thread.hpp"
#include "lib/sync.hpp"
#include "lib/util.hpp"
#include "lib/scoped-collection.hpp"
#include "lib/test/microbenchmark.hpp"
#include "lib/format-string.hpp"
#include "lib/format-cout.hpp"
#include "lib/test/diagnostic-output.hpp"
#include <deque>
#include <tuple>
using std::tuple;
using std::deque;
using util::_Fmt;
namespace lib {
namespace test {
namespace {
const uint NUM_THREADS = 8; ///< for concurrent probes
const uint NUM_SAMPLES = 80; ///< overall number measurement runs
const uint NUM_INVOKES = 1'000'000; ///< invocations of the target per measurment
}
/******************************************************************//**
* @test demonstrate simple access to random number generation,
* as well as the setup of controlled random number sequences.
* @see random.hpp
*/
class RandomConcurrent_test : public Test
{
virtual void
run (Arg arg)
{
seedRand();
benchmark_random_gen();
if ("quick" != firstTok (arg))
investigate_concurrentAccess();
}
/** @test microbenchmark of various random number generators
* @remark typical values
* - `rand()` (trinomial generator) : 15ns / 10ns (O3)
* - Mersenne twister 64bit : 55ns / 25ns (O3)
* - reading /dev/urandom : 480ns / 470 (O3)
*/
void
benchmark_random_gen()
{
auto do_nothing = []{ /* take it easy */ };
auto mersenne64 = []{ return rani(); };
auto legacy_gen = []{ return rand(); };
std::random_device entropySource{"/dev/urandom"};
auto rly_random = [&]{ return entropySource(); };
_Fmt resultDisplay{"µ-bench(%s)%|45T.| %5.3f µs"};
double d1 = microBenchmark (do_nothing, NUM_INVOKES).first;
cout << resultDisplay % "(empty call)" % d1 <<endl;
double d2 = microBenchmark (mersenne64, NUM_INVOKES).first;
cout << resultDisplay % "Mersenne-64" % d2 <<endl;
double d3 = microBenchmark (legacy_gen, NUM_INVOKES).first;
cout << resultDisplay % "std::rand()" % d3 <<endl;
double d4 = microBenchmark (rly_random, NUM_INVOKES).first;
cout << resultDisplay % "/dev/urandom" % d4 <<endl;
CHECK (d3 < d2 and d2 < d4);
}
/**
* Research setup to investigate concurrent access to a random generator.
* From each test thread, the shared generator instance is invoked a huge number times
* (defined by NUM_INVOKES), thereby computing the mean value and checking for defect
* numbers outside the generator's definition range. This probe cycle is repeated
* several times (defined by NUM_SAMPLES) and the results are collected and evaluated
* afterwards to detect signs of a skewed distribution.
* @tparam GEN a C++ compliant generator type
* @tparam threads number of threads to run in parallel
* @remark Pseudo random number generation as such is not threadsafe, and pressing for
* concurrent access (as done here) will produce a corrupted internal generator
* state sooner or later. Under some circumstances however, theses glitches
* can be ignored, if quality of generated numbers actually does not matter.
*/
template<typename GEN, uint threads>
struct Experiment
: Sync<>
{
deque<tuple<double,uint>> results;
void
recordRun (double err, uint fails)
{
Lock sync(this);
results.emplace_back (err, fails);
}
GEN generator;
Experiment(GEN&& fun)
: generator{move (fun)}
{ }
const uint N = NUM_INVOKES;
const uint REPEATS = NUM_SAMPLES / threads;
using ResVal = typename GEN::result_type;
ResVal expect = (GEN::max() - GEN::min()) / 2;
/* === Measurement Results === */
double percentGlitches{0.0};
double percentTilted {0.0};
bool isFailure {false};
/** run the experiment series */
void
perform()
{
auto drawRandom = [&]()
{
uint fail{0};
double avg{0.0};
for (uint i=0; i<N; ++i)
{
auto r = generator();
if (r < GEN::min() or r > GEN::max())
++fail;
avg += 1.0/N * r;
}
auto error = avg/expect - 1;
recordRun (error, fail);
};
threadBenchmark<threads> (drawRandom, REPEATS);
uint cases{0}, lows{0}, glitches{0};
_Fmt resultLine{"%6.3f ‰ : %d %s"};
for (auto [err,fails] : results)
{
bool isGlitch = fails or fabs(err) > 3 * 1/sqrt(N); // mean of a sound distribution will remain within bounds
cout << resultLine % (err*1000)
% fails
% (fails? "FAIL": isGlitch? " !! ":"") << endl;
++cases;
if (err < 0) ++lows;
if (isGlitch) ++glitches;
}
// assess overall results......
percentGlitches = 100.0 * glitches/cases;
percentTilted = 100.0 * fabs(double(lows)/cases - 0.5)*2; // degree to which mean is biased for one side
isFailure = glitches or percentTilted > 30; // (empirical trigger criterion)
cout << _Fmt{"++-------------++ %s\n"
" Glitches: %5.1f %%\n"
" Tilted: %5.1f %%\n"
"++-------------++\n"}
% (isFailure? "FAIL": "(ok)")
% percentGlitches
% percentTilted
<< endl;
}
};
/** @test examine behaviour of PRNG under concurrency stress
* - running a 32bit generator single threaded should not trigger alarms
* - while under concurrent pressure several defect numbers should be produced
* - even the 64bit generator will show uneven distribution due to corrupted state
* - the 32bit generator capped to its valid range exhibits skew only occasionally
* @see lib::CappedGen
*/
void
investigate_concurrentAccess()
{
using Mersenne64 = std::mt19937_64;
using Mersenne32 = std::mt19937;
using CappedMs32 = CappedGen<Mersenne32>;
Experiment<Mersenne32,1> single_mers32{Mersenne32(defaultGen.uni())};
Experiment<Mersenne32,NUM_THREADS> concurr_mers32{Mersenne32(defaultGen.uni())};
Experiment<Mersenne64,NUM_THREADS> concurr_mers64{Mersenne64(defaultGen.uni())};
Experiment<CappedMs32,NUM_THREADS> concCap_mers32{CappedMs32(defaultGen.uni())};
single_mers32.perform();
concurr_mers32.perform();
concurr_mers64.perform();
concCap_mers32.perform();
CHECK (not single_mers32.isFailure, "ALARM : single-threaded Mersenne-Twister 32bit produces skewed distribution");
CHECK ( concurr_mers32.isFailure, "SURPRISE : Mersenne-Twister 32bit encountered NO glitches under concurrent pressure");
CHECK ( concurr_mers64.isFailure, "SURPRISE : Mersenne-Twister 64bit encountered NO glitches under concurrent pressure");
}
};
LAUNCHER (RandomConcurrent_test, "unit common");
}} // namespace lib::test
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