ladybird/Kernel/TimerQueue.cpp

#include <AK/Function.h>
#include <AK/NonnullOwnPtr.h>
#include <AK/OwnPtr.h>
#include <Kernel/Scheduler.h>
#include <Kernel/TimerQueue.h>

static TimerQueue* s_the;

TimerQueue& TimerQueue::the()
{
    if (!s_the)
        s_the = new TimerQueue;
    return *s_the;
}

u64 TimerQueue::add_timer(NonnullOwnPtr<Timer>&& timer)
{
    ASSERT(timer->expires > g_uptime);

    timer->id = ++m_timer_id_count;

    auto following_timer = m_timer_queue.find([&timer](auto& other) { return other->expires > timer->expires; });
    if (following_timer.is_end())
        m_timer_queue.append(move(timer));
    else
        m_timer_queue.insert_before(following_timer, move(timer));

    update_next_timer_due();

    return m_timer_id_count;
}

u64 TimerQueue::add_timer(u64 duration, TimeUnit unit, Function<void()>&& callback)
{
    NonnullOwnPtr timer = make<Timer>();
    timer->expires = g_uptime + duration * unit;
    timer->callback = move(callback);
    return add_timer(move(timer));
}

bool TimerQueue::cancel_timer(u64 id)
{
    auto it = m_timer_queue.find([id](auto& timer) { return timer->id == id; });
    if (it.is_end())
        return false;
    m_timer_queue.remove(it);
    update_next_timer_due();
    return true;
}

void TimerQueue::fire()
{
    if (m_timer_queue.is_empty())
        return;

    ASSERT(m_next_timer_due == m_timer_queue.first()->expires);

    while (!m_timer_queue.is_empty() && g_uptime > m_timer_queue.first()->expires) {
        auto timer = m_timer_queue.take_first();
        timer->callback();
    }

    update_next_timer_due();
}

void TimerQueue::update_next_timer_due()
{
    if (m_timer_queue.is_empty())
        m_next_timer_due = 0;
    else
        m_next_timer_due = m_timer_queue.first()->expires;
}
Kernel: Add kernel-level timer queue (heavily based on @juliusf's work) PR #591 defines the rationale for kernel-level timers. They're most immediately useful for TCP retransmission, but will most likely see use in many other areas as well. 2019-12-27 00:58:28 +00:00			`#include <AK/Function.h>`
			`#include <AK/NonnullOwnPtr.h>`
			`#include <AK/OwnPtr.h>`
			`#include <Kernel/Scheduler.h>`
			`#include <Kernel/TimerQueue.h>`

			`static TimerQueue* s_the;`

			`TimerQueue& TimerQueue::the()`
			`{`
			`if (!s_the)`
			`s_the = new TimerQueue;`
			`return *s_the;`
			`}`

			`u64 TimerQueue::add_timer(NonnullOwnPtr<Timer>&& timer)`
			`{`
			`ASSERT(timer->expires > g_uptime);`

			`timer->id = ++m_timer_id_count;`

			`auto following_timer = m_timer_queue.find([&timer](auto& other) { return other->expires > timer->expires; });`
			`if (following_timer.is_end())`
			`m_timer_queue.append(move(timer));`
			`else`
			`m_timer_queue.insert_before(following_timer, move(timer));`

			`update_next_timer_due();`

			`return m_timer_id_count;`
			`}`

			`u64 TimerQueue::add_timer(u64 duration, TimeUnit unit, Function<void()>&& callback)`
			`{`
			`NonnullOwnPtr timer = make<Timer>();`
			`timer->expires = g_uptime + duration * unit;`
			`timer->callback = move(callback);`
			`return add_timer(move(timer));`
			`}`

			`bool TimerQueue::cancel_timer(u64 id)`
			`{`
			`auto it = m_timer_queue.find([id](auto& timer) { return timer->id == id; });`
			`if (it.is_end())`
			`return false;`
			`m_timer_queue.remove(it);`
			`update_next_timer_due();`
			`return true;`
			`}`

			`void TimerQueue::fire()`
			`{`
			`if (m_timer_queue.is_empty())`
			`return;`

			`ASSERT(m_next_timer_due == m_timer_queue.first()->expires);`

			`while (!m_timer_queue.is_empty() && g_uptime > m_timer_queue.first()->expires) {`
			`auto timer = m_timer_queue.take_first();`
			`timer->callback();`
			`}`

			`update_next_timer_due();`
			`}`

			`void TimerQueue::update_next_timer_due()`
			`{`
			`if (m_timer_queue.is_empty())`
			`m_next_timer_due = 0;`
			`else`
			`m_next_timer_due = m_timer_queue.first()->expires;`
			`}`