ppsspp/unittest/TestThreadManager.cpp

153 lines
3.6 KiB
C++

#include <thread>
#include <vector>
#include "Common/Log.h"
#include "Common/TimeUtil.h"
#include "Common/Thread/Barrier.h"
#include "Common/Thread/ThreadManager.h"
#include "Common/Thread/Channel.h"
#include "Common/Thread/Promise.h"
#include "Common/Thread/ParallelLoop.h"
#include "Common/Thread/ThreadUtil.h"
#include "Common/Thread/Waitable.h"
#include "UnitTest.h"
struct ResultObject {
bool ok;
};
ResultObject *ResultProducer() {
sleep_ms(250);
printf("result produced: thread %d\n", GetCurrentThreadIdForDebug());
return new ResultObject{ true };
}
bool TestMailbox() {
Mailbox<ResultObject *> *mailbox = new Mailbox<ResultObject *>();
mailbox->Send(new ResultObject{ true });
ResultObject *data;
data = mailbox->Wait();
_assert_(data && data->ok);
delete data;
mailbox->Release();
return true;
}
void rangeFunc(int lower, int upper) {
sleep_ms(30);
printf(" - range %d-%d (thread %d)\n", lower, upper, GetCurrentThreadIdForDebug());
}
// This always passes unless something is badly broken, the interesting thing is the
// logged output.
bool TestParallelLoop(ThreadManager *threadMan) {
printf("tester thread ID: %d\n", GetCurrentThreadIdForDebug());
printf("waitable test\n");
WaitableCounter *waitable = ParallelRangeLoopWaitable(threadMan, rangeFunc, 0, 7, 1);
// Can do stuff here if we like.
waitable->WaitAndRelease();
// Now it's done.
// Try a loop with stragglers.
printf("blocking test #1 [0-65)\n");
ParallelRangeLoop(threadMan, rangeFunc, 0, 65, 1);
// Try a loop with a relatively large minimum size.
printf("blocking test #2 [0-100)\n");
ParallelRangeLoop(threadMan, rangeFunc, 0, 100, 40);
// Try a loop with minimum size larger than range.
printf("waitable test [10-30)\n");
WaitableCounter *waitable2 = ParallelRangeLoopWaitable(threadMan, rangeFunc, 10, 30, 40);
waitable2->WaitAndRelease();
return true;
}
const size_t THREAD_COUNT = 9;
const size_t ITERATIONS = 40000;
static std::atomic<int> g_atomicCounter;
static ThreadManager *g_threadMan;
static CountingBarrier g_barrier(THREAD_COUNT + 1);
class IncrementTask : public Task {
public:
IncrementTask(TaskType type, LimitedWaitable *waitable) : type_(type), waitable_(waitable) {}
~IncrementTask() {}
virtual TaskType Type() const { return type_; }
virtual void Run() {
g_atomicCounter++;
waitable_->Notify();
}
private:
TaskType type_;
LimitedWaitable *waitable_;
};
void ThreadFunc() {
for (int i = 0; i < ITERATIONS; i++) {
auto threadWaitable = new LimitedWaitable();
g_threadMan->EnqueueTask(new IncrementTask((i & 1) ? TaskType::CPU_COMPUTE : TaskType::IO_BLOCKING, threadWaitable));
threadWaitable->WaitAndRelease();
}
g_barrier.Arrive();
}
bool TestMultithreadedScheduling() {
g_atomicCounter = 0;
auto start = Instant::Now();
std::vector<std::thread> threads;
for (int i = 0; i < THREAD_COUNT; i++) {
threads.push_back(std::thread(ThreadFunc));
}
// Just testing the barrier
g_barrier.Arrive();
// OK, all are done.
EXPECT_EQ_INT(g_atomicCounter, THREAD_COUNT * ITERATIONS);
for (int i = 0; i < THREAD_COUNT; i++) {
threads[i].join();
}
threads.clear();
printf("Stress test elapsed: %0.2f", start.Elapsed());
return true;
}
bool TestThreadManager() {
ThreadManager manager;
manager.Init(8, 1);
g_threadMan = &manager;
Promise<ResultObject *> *object(Promise<ResultObject *>::Spawn(&manager, &ResultProducer, TaskType::IO_BLOCKING));
if (!TestParallelLoop(&manager)) {
return false;
}
sleep_ms(100);
ResultObject *result = object->BlockUntilReady();
if (result) {
printf("Got result back!\n");
}
delete object;
if (!TestMailbox()) {
return false;
}
if (!TestMultithreadedScheduling()) {
return false;
}
return true;
}