/*
This file is part of Fennix Kernel.
Fennix Kernel 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 3 of
the License, or (at your option) any later version.
Fennix Kernel 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 Fennix Kernel. If not, see .
*/
#include "acpi.hpp"
#include
#include
#include
#include
#include "cpu/apic.hpp"
#include "../../kernel.h"
#define ACPI_TIMER 0x0001
#define ACPI_BUSMASTER 0x0010
#define ACPI_GLOBAL 0x0020
#define ACPI_POWER_BUTTON 0x0100
#define ACPI_SLEEP_BUTTON 0x0200
#define ACPI_RTC_ALARM 0x0400
#define ACPI_PCIE_WAKE 0x4000
#define ACPI_WAKE 0x8000
namespace ACPI
{
__always_inline inline bool IsCanonical(uint64_t Address)
{
return ((Address <= 0x00007FFFFFFFFFFF) || ((Address >= 0xFFFF800000000000) && (Address <= 0xFFFFFFFFFFFFFFFF)));
}
#define ACPI_ENABLED 0x0001
#define ACPI_SLEEP 0x2000
#define ACPI_GAS_MMIO 0
#define ACPI_GAS_IO 1
#define ACPI_GAS_PCI 2
void DSDT::OnInterruptReceived(CPU::x64::TrapFrame *Frame)
{
debug("SCI Handle Triggered");
uint16_t Event = 0;
{
uint16_t a = 0, b = 0;
if (acpi->FADT->PM1aEventBlock)
{
a = inw(s_cst(uint16_t, acpi->FADT->PM1aEventBlock));
outw(s_cst(uint16_t, acpi->FADT->PM1aEventBlock), a);
}
if (acpi->FADT->PM1bEventBlock)
{
b = inw(s_cst(uint16_t, acpi->FADT->PM1bEventBlock));
outw(s_cst(uint16_t, acpi->FADT->PM1bEventBlock), b);
}
Event = a | b;
}
debug("SCI Event: %#lx", Event);
if (Event & ACPI_BUSMASTER)
{
fixme("ACPI Busmaster");
}
else if (Event & ACPI_GLOBAL)
{
fixme("ACPI Global");
}
else if (Event & ACPI_POWER_BUTTON)
{
if (TaskManager && !TaskManager->IsPanic())
{
TaskManager->CreateThread(TaskManager->CreateProcess(nullptr,
"Shutdown",
Tasking::TaskTrustLevel::Kernel),
(Tasking::IP)KST_Shutdown);
}
else
KernelShutdownThread(false);
}
else if (Event & ACPI_SLEEP_BUTTON)
{
fixme("ACPI Sleep Button");
}
else if (Event & ACPI_RTC_ALARM)
{
fixme("ACPI RTC Alarm");
}
else if (Event & ACPI_PCIE_WAKE)
{
fixme("ACPI PCIe Wake");
}
else if (Event & ACPI_WAKE)
{
fixme("ACPI Wake");
}
else if (Event & ACPI_TIMER)
{
fixme("ACPI Timer");
}
else
{
error("ACPI unknown event %#lx on CPU %d", Event, GetCurrentCPU()->ID);
CPU::Stop();
}
UNUSED(Frame);
}
void DSDT::Shutdown()
{
trace("Shutting down...");
if (SCI_EN == 1)
{
outw(s_cst(uint16_t, acpi->FADT->PM1aControlBlock),
s_cst(uint16_t,
(inw(s_cst(uint16_t,
acpi->FADT->PM1aControlBlock)) &
0xE3FF) |
((SLP_TYPa << 10) | ACPI_SLEEP)));
if (acpi->FADT->PM1bControlBlock)
outw(s_cst(uint16_t, acpi->FADT->PM1bControlBlock),
s_cst(uint16_t,
(inw(
s_cst(uint16_t, acpi->FADT->PM1bControlBlock)) &
0xE3FF) |
((SLP_TYPb << 10) | ACPI_SLEEP)));
outw(s_cst(uint16_t, PM1a_CNT), SLP_TYPa | SLP_EN);
if (PM1b_CNT)
outw(s_cst(uint16_t, PM1b_CNT), SLP_TYPb | SLP_EN);
}
}
void DSDT::Reboot()
{
trace("Rebooting...");
switch (acpi->FADT->ResetReg.AddressSpace)
{
case ACPI_GAS_MMIO:
{
*(uint8_t *)(acpi->FADT->ResetReg.Address) = acpi->FADT->ResetValue;
break;
}
case ACPI_GAS_IO:
{
outb(s_cst(uint16_t, acpi->FADT->ResetReg.Address), acpi->FADT->ResetValue);
break;
}
case ACPI_GAS_PCI:
{
fixme("ACPI_GAS_PCI not supported.");
/*
seg - 0
bus - 0
dev - (FADT->ResetReg.Address >> 32) & 0xFFFF
function - (FADT->ResetReg.Address >> 16) & 0xFFFF
offset - FADT->ResetReg.Address & 0xFFFF
value - FADT->ResetValue
*/
break;
}
default:
{
error("Unknown reset register address space: %d", acpi->FADT->ResetReg.AddressSpace);
break;
}
}
}
DSDT::DSDT(ACPI *acpi) : Interrupts::Handler(acpi->FADT->SCI_Interrupt)
{
this->acpi = acpi;
uint64_t Address = ((IsCanonical(acpi->FADT->X_Dsdt) && acpi->XSDTSupported) ? acpi->FADT->X_Dsdt : acpi->FADT->Dsdt);
uint8_t *S5Address = (uint8_t *)(Address) + 36;
ACPI::ACPI::ACPIHeader *Header = (ACPI::ACPI::ACPIHeader *)Address;
size_t Length = Header->Length;
while (Length-- > 0)
{
if (!memcmp(S5Address, "_S5_", 4))
break;
S5Address++;
}
if (Length <= 0)
{
warn("_S5 not present in ACPI");
return;
}
if ((*(S5Address - 1) == 0x08 || (*(S5Address - 2) == 0x08 && *(S5Address - 1) == '\\')) && *(S5Address + 4) == 0x12)
{
S5Address += 5;
S5Address += ((*S5Address & 0xC0) >> 6) + 2;
if (*S5Address == 0x0A)
S5Address++;
SLP_TYPa = s_cst(uint16_t, *(S5Address) << 10);
S5Address++;
if (*S5Address == 0x0A)
S5Address++;
SLP_TYPb = s_cst(uint16_t, *(S5Address) << 10);
SMI_CMD = acpi->FADT->SMI_CommandPort;
ACPI_ENABLE = acpi->FADT->AcpiEnable;
ACPI_DISABLE = acpi->FADT->AcpiDisable;
PM1a_CNT = acpi->FADT->PM1aControlBlock;
PM1b_CNT = acpi->FADT->PM1bControlBlock;
PM1_CNT_LEN = acpi->FADT->PM1ControlLength;
SLP_EN = 1 << 13;
SCI_EN = 1;
trace("ACPI Shutdown is supported");
ACPIShutdownSupported = true;
uint16_t value = ACPI_POWER_BUTTON | ACPI_SLEEP_BUTTON | ACPI_WAKE;
{
uint16_t a = s_cst(uint16_t, acpi->FADT->PM1aEventBlock + (acpi->FADT->PM1EventLength / 2));
uint16_t b = s_cst(uint16_t, acpi->FADT->PM1bEventBlock + (acpi->FADT->PM1EventLength / 2));
debug("SCI Event: %#llx [a:%#x b:%#x]", value, a, b);
if (acpi->FADT->PM1aEventBlock)
outw(a, value);
if (acpi->FADT->PM1bEventBlock)
outw(b, value);
}
{
uint16_t a = 0, b = 0;
if (acpi->FADT->PM1aEventBlock)
{
a = inw(s_cst(uint16_t, acpi->FADT->PM1aEventBlock));
outw(s_cst(uint16_t, acpi->FADT->PM1aEventBlock), a);
}
if (acpi->FADT->PM1bEventBlock)
{
b = inw(s_cst(uint16_t, acpi->FADT->PM1bEventBlock));
outw(s_cst(uint16_t, acpi->FADT->PM1bEventBlock), b);
}
}
((APIC::APIC *)Interrupts::apic[0])->RedirectIRQ(0, acpi->FADT->SCI_Interrupt, 1);
return;
}
warn("Failed to parse _S5 in ACPI");
SCI_EN = 0;
}
DSDT::~DSDT()
{
}
}