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174 lines
5.4 KiB
C++
174 lines
5.4 KiB
C++
/*
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* Copyright (c) 2020, the SerenityOS developers.
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*
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* SPDX-License-Identifier: BSD-2-Clause
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*/
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#include <Kernel/Interrupts/APIC.h>
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#include <Kernel/Panic.h>
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#include <Kernel/Sections.h>
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#include <Kernel/Time/APICTimer.h>
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#include <Kernel/Time/TimeManagement.h>
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namespace Kernel {
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#define APIC_TIMER_MEASURE_CPU_CLOCK
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UNMAP_AFTER_INIT APICTimer* APICTimer::initialize(u8 interrupt_number, HardwareTimerBase& calibration_source)
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{
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auto timer = adopt_ref(*new APICTimer(interrupt_number, nullptr));
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timer->register_interrupt_handler();
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if (!timer->calibrate(calibration_source)) {
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return nullptr;
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}
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return &timer.leak_ref();
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}
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UNMAP_AFTER_INIT APICTimer::APICTimer(u8 interrupt_number, Function<void(RegisterState const&)> callback)
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: HardwareTimer<GenericInterruptHandler>(interrupt_number, move(callback))
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{
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disable_remap();
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}
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UNMAP_AFTER_INIT bool APICTimer::calibrate(HardwareTimerBase& calibration_source)
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{
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VERIFY_INTERRUPTS_DISABLED();
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dmesgln("APICTimer: Using {} as calibration source", calibration_source.model());
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auto& apic = APIC::the();
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#ifdef APIC_TIMER_MEASURE_CPU_CLOCK
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bool supports_tsc = Processor::current().has_feature(CPUFeature::TSC);
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#endif
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// temporarily replace the timer callbacks
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const size_t ticks_in_100ms = calibration_source.ticks_per_second() / 10;
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Atomic<size_t, AK::memory_order_relaxed> calibration_ticks = 0;
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#ifdef APIC_TIMER_MEASURE_CPU_CLOCK
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volatile u64 start_tsc = 0, end_tsc = 0;
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#endif
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volatile u64 start_reference = 0, end_reference = 0;
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volatile u32 start_apic_count = 0, end_apic_count = 0;
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bool query_reference = calibration_source.can_query_raw();
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auto original_source_callback = calibration_source.set_callback([&](RegisterState const&) {
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u32 current_timer_count = apic.get_timer_current_count();
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#ifdef APIC_TIMER_MEASURE_CPU_CLOCK
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u64 current_tsc = supports_tsc ? read_tsc() : 0;
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#endif
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u64 current_reference = query_reference ? calibration_source.current_raw() : 0;
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auto prev_tick = calibration_ticks.fetch_add(1);
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if (prev_tick == 0) {
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#ifdef APIC_TIMER_MEASURE_CPU_CLOCK
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start_tsc = current_tsc;
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#endif
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start_apic_count = current_timer_count;
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start_reference = current_reference;
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} else if (prev_tick + 1 == ticks_in_100ms + 1) {
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#ifdef APIC_TIMER_MEASURE_CPU_CLOCK
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end_tsc = current_tsc;
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#endif
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end_apic_count = current_timer_count;
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end_reference = current_reference;
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}
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});
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// Setup a counter that should be much longer than our calibration time.
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// We don't want the APIC timer to actually fire. We do however want the
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// calbibration_source timer to fire so that we can read the current
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// tick count from the APIC timer
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auto original_callback = set_callback([&](RegisterState const&) {
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// TODO: How should we handle this?
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PANIC("APICTimer: Timer fired during calibration!");
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});
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apic.setup_local_timer(0xffffffff, APIC::TimerMode::Periodic, true);
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sti();
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// Loop for about 100 ms
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while (calibration_ticks.load() <= ticks_in_100ms)
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;
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cli();
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// Restore timer callbacks
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calibration_source.set_callback(move(original_source_callback));
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set_callback(move(original_callback));
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disable_local_timer();
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if (query_reference) {
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u64 one_tick_ns = calibration_source.raw_to_ns((end_reference - start_reference) / ticks_in_100ms);
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m_frequency = (u32)(1000000000ull / one_tick_ns);
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dmesgln("APICTimer: Ticks per second: {} ({}.{}ms)", m_frequency, one_tick_ns / 1000000, one_tick_ns % 1000000);
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} else {
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// For now, assume the frequency is exactly the same
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m_frequency = calibration_source.ticks_per_second();
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dmesgln("APICTimer: Ticks per second: {} (assume same frequency as reference clock)", m_frequency);
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}
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auto delta_apic_count = start_apic_count - end_apic_count; // The APIC current count register decrements!
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m_timer_period = (delta_apic_count * apic.get_timer_divisor()) / ticks_in_100ms;
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u64 apic_freq = delta_apic_count * apic.get_timer_divisor() * 10;
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dmesgln("APICTimer: Bus clock speed: {}.{} MHz", apic_freq / 1000000, apic_freq % 1000000);
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if (apic_freq < 1000000) {
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dmesgln("APICTimer: Frequency too slow!");
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return false;
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}
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#ifdef APIC_TIMER_MEASURE_CPU_CLOCK
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if (supports_tsc) {
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auto delta_tsc = (end_tsc - start_tsc) * 10;
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dmesgln("APICTimer: CPU clock speed: {}.{} MHz", delta_tsc / 1000000, delta_tsc % 1000000);
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}
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#endif
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enable_local_timer();
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return true;
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}
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void APICTimer::enable_local_timer()
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{
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APIC::the().setup_local_timer(m_timer_period, m_timer_mode, true);
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}
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void APICTimer::disable_local_timer()
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{
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APIC::the().setup_local_timer(0, APIC::TimerMode::OneShot, false);
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}
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size_t APICTimer::ticks_per_second() const
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{
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return m_frequency;
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}
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void APICTimer::set_periodic()
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{
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// FIXME: Implement it...
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VERIFY_NOT_REACHED();
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}
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void APICTimer::set_non_periodic()
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{
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// FIXME: Implement it...
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VERIFY_NOT_REACHED();
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}
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void APICTimer::reset_to_default_ticks_per_second()
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{
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}
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bool APICTimer::try_to_set_frequency([[maybe_unused]] size_t frequency)
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{
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return true;
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}
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bool APICTimer::is_capable_of_frequency([[maybe_unused]] size_t frequency) const
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{
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return false;
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}
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size_t APICTimer::calculate_nearest_possible_frequency([[maybe_unused]] size_t frequency) const
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{
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return 0;
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}
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}
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