reactos/subsystems/mvdm/ntvdm/hardware/cmos.c

536 lines
14 KiB
C

/*
* COPYRIGHT: GPL - See COPYING in the top level directory
* PROJECT: ReactOS Virtual DOS Machine
* FILE: subsystems/mvdm/ntvdm/hardware/cmos.c
* PURPOSE: CMOS Real Time Clock emulation
* PROGRAMMERS: Aleksandar Andrejevic <theflash AT sdf DOT lonestar DOT org>
*/
/* INCLUDES *******************************************************************/
#include "ntvdm.h"
#define NDEBUG
#include <debug.h>
#include "emulator.h"
#include "cmos.h"
#include "io.h"
#include "pic.h"
#include "clock.h"
/* PRIVATE VARIABLES **********************************************************/
static HANDLE hCmosRam = INVALID_HANDLE_VALUE;
static CMOS_MEMORY CmosMemory;
static BOOLEAN NmiEnabled = TRUE;
static CMOS_REGISTERS SelectedRegister = CMOS_REG_STATUS_D;
static PHARDWARE_TIMER ClockTimer;
static PHARDWARE_TIMER PeriodicTimer;
/* PRIVATE FUNCTIONS **********************************************************/
static VOID RtcUpdatePeriodicTimer(VOID)
{
BYTE RateSelect = CmosMemory.StatusRegA & 0x0F;
if (RateSelect == 0)
{
/* No periodic interrupt */
DisableHardwareTimer(PeriodicTimer);
return;
}
/* 1 and 2 act like 8 and 9 */
if (RateSelect <= 2) RateSelect += 7;
SetHardwareTimerDelay(PeriodicTimer, HZ_TO_NS(1 << (16 - RateSelect)));
// FIXME: This call keeps EnableCount increasing without compensating it!
EnableHardwareTimer(PeriodicTimer);
}
static VOID FASTCALL RtcPeriodicTick(ULONGLONG ElapsedTime)
{
UNREFERENCED_PARAMETER(ElapsedTime);
/* Set PF */
CmosMemory.StatusRegC |= CMOS_STC_PF;
/* Check if there should be an interrupt on a periodic timer tick */
if (CmosMemory.StatusRegB & CMOS_STB_INT_PERIODIC)
{
CmosMemory.StatusRegC |= CMOS_STC_IRQF;
/* Interrupt! */
PicInterruptRequest(RTC_IRQ_NUMBER);
}
}
/* Should be called every second */
static VOID FASTCALL RtcTimeUpdate(ULONGLONG ElapsedTime)
{
SYSTEMTIME CurrentTime;
UNREFERENCED_PARAMETER(ElapsedTime);
/* Get the current time */
GetLocalTime(&CurrentTime);
/* Set UF */
CmosMemory.StatusRegC |= CMOS_STC_UF;
/* Check if the time matches the alarm time */
if ((CurrentTime.wHour == CmosMemory.AlarmHour ) &&
(CurrentTime.wMinute == CmosMemory.AlarmMinute) &&
(CurrentTime.wSecond == CmosMemory.AlarmSecond))
{
/* Set the alarm flag */
CmosMemory.StatusRegC |= CMOS_STC_AF;
/* Set IRQF if there should be an interrupt */
if (CmosMemory.StatusRegB & CMOS_STB_INT_ON_ALARM) CmosMemory.StatusRegC |= CMOS_STC_IRQF;
}
/* Check if there should be an interrupt on update */
if (CmosMemory.StatusRegB & CMOS_STB_INT_ON_UPDATE) CmosMemory.StatusRegC |= CMOS_STC_IRQF;
if (CmosMemory.StatusRegC & CMOS_STC_IRQF)
{
/* Interrupt! */
PicInterruptRequest(RTC_IRQ_NUMBER);
}
}
static VOID WINAPI CmosWriteAddress(USHORT Port, BYTE Data)
{
UNREFERENCED_PARAMETER(Port);
/* Update the NMI enabled flag */
NmiEnabled = !(Data & CMOS_DISABLE_NMI);
/* Get the register number */
Data &= ~CMOS_DISABLE_NMI;
if (Data < CMOS_REG_MAX)
{
/* Select the new register */
SelectedRegister = Data;
}
else
{
/* Default to Status Register D */
SelectedRegister = CMOS_REG_STATUS_D;
}
}
static BYTE WINAPI CmosReadData(USHORT Port)
{
BYTE Value;
SYSTEMTIME CurrentTime;
UNREFERENCED_PARAMETER(Port);
/* Get the current time */
GetLocalTime(&CurrentTime);
switch (SelectedRegister)
{
case CMOS_REG_SECONDS:
{
Value = READ_CMOS_DATA(CmosMemory, CurrentTime.wSecond);
break;
}
case CMOS_REG_ALARM_SEC:
{
Value = READ_CMOS_DATA(CmosMemory, CmosMemory.AlarmSecond);
break;
}
case CMOS_REG_MINUTES:
{
Value = READ_CMOS_DATA(CmosMemory, CurrentTime.wMinute);
break;
}
case CMOS_REG_ALARM_MIN:
{
Value = READ_CMOS_DATA(CmosMemory, CmosMemory.AlarmMinute);
break;
}
case CMOS_REG_HOURS:
{
BOOLEAN Afternoon = FALSE;
Value = CurrentTime.wHour;
if (!(CmosMemory.StatusRegB & CMOS_STB_24HOUR) && (Value >= 12))
{
Value -= 12;
Afternoon = TRUE;
}
Value = READ_CMOS_DATA(CmosMemory, Value);
/* Convert to 12-hour */
if (Afternoon) Value |= 0x80;
break;
}
case CMOS_REG_ALARM_HRS:
{
BOOLEAN Afternoon = FALSE;
Value = CmosMemory.AlarmHour;
if (!(CmosMemory.StatusRegB & CMOS_STB_24HOUR) && (Value >= 12))
{
Value -= 12;
Afternoon = TRUE;
}
Value = READ_CMOS_DATA(CmosMemory, Value);
/* Convert to 12-hour */
if (Afternoon) Value |= 0x80;
break;
}
case CMOS_REG_DAY_OF_WEEK:
{
/*
* The CMOS value is 1-based but the
* GetLocalTime API value is 0-based.
* Correct it.
*/
Value = READ_CMOS_DATA(CmosMemory, CurrentTime.wDayOfWeek + 1);
break;
}
case CMOS_REG_DAY:
{
Value = READ_CMOS_DATA(CmosMemory, CurrentTime.wDay);
break;
}
case CMOS_REG_MONTH:
{
Value = READ_CMOS_DATA(CmosMemory, CurrentTime.wMonth);
break;
}
case CMOS_REG_YEAR:
{
Value = READ_CMOS_DATA(CmosMemory, CurrentTime.wYear % 100);
break;
}
case CMOS_REG_CENTURY:
{
Value = READ_CMOS_DATA(CmosMemory, CurrentTime.wYear / 100 + 19);
break;
}
case CMOS_REG_STATUS_C:
{
/* Return the old status register value, then clear it */
Value = CmosMemory.StatusRegC;
CmosMemory.StatusRegC = 0x00;
break;
}
case CMOS_REG_STATUS_A:
case CMOS_REG_STATUS_B:
case CMOS_REG_STATUS_D:
case CMOS_REG_DIAGNOSTICS:
case CMOS_REG_SHUTDOWN_STATUS:
default:
{
// ASSERT(SelectedRegister < CMOS_REG_MAX);
Value = CmosMemory.Regs[SelectedRegister];
}
}
/* Return to Status Register D */
SelectedRegister = CMOS_REG_STATUS_D;
return Value;
}
static VOID WINAPI CmosWriteData(USHORT Port, BYTE Data)
{
BOOLEAN ChangeTime = FALSE;
SYSTEMTIME CurrentTime;
UNREFERENCED_PARAMETER(Port);
/* Get the current time */
GetLocalTime(&CurrentTime);
switch (SelectedRegister)
{
case CMOS_REG_SECONDS:
{
ChangeTime = TRUE;
CurrentTime.wSecond = WRITE_CMOS_DATA(CmosMemory, Data);
break;
}
case CMOS_REG_ALARM_SEC:
{
CmosMemory.AlarmSecond = WRITE_CMOS_DATA(CmosMemory, Data);
break;
}
case CMOS_REG_MINUTES:
{
ChangeTime = TRUE;
CurrentTime.wMinute = WRITE_CMOS_DATA(CmosMemory, Data);
break;
}
case CMOS_REG_ALARM_MIN:
{
CmosMemory.AlarmMinute = WRITE_CMOS_DATA(CmosMemory, Data);
break;
}
case CMOS_REG_HOURS:
{
BOOLEAN Afternoon = FALSE;
ChangeTime = TRUE;
if (!(CmosMemory.StatusRegB & CMOS_STB_24HOUR) && (Data & 0x80))
{
Data &= ~0x80;
Afternoon = TRUE;
}
CurrentTime.wHour = WRITE_CMOS_DATA(CmosMemory, Data);
/* Convert to 24-hour format */
if (Afternoon) CurrentTime.wHour += 12;
break;
}
case CMOS_REG_ALARM_HRS:
{
BOOLEAN Afternoon = FALSE;
if (!(CmosMemory.StatusRegB & CMOS_STB_24HOUR) && (Data & 0x80))
{
Data &= ~0x80;
Afternoon = TRUE;
}
CmosMemory.AlarmHour = WRITE_CMOS_DATA(CmosMemory, Data);
/* Convert to 24-hour format */
if (Afternoon) CmosMemory.AlarmHour += 12;
break;
}
case CMOS_REG_DAY_OF_WEEK:
{
ChangeTime = TRUE;
/*
* The CMOS value is 1-based but the
* SetLocalTime API value is 0-based.
* Correct it.
*/
Data -= 1;
CurrentTime.wDayOfWeek = WRITE_CMOS_DATA(CmosMemory, Data);
break;
}
case CMOS_REG_DAY:
{
ChangeTime = TRUE;
CurrentTime.wDay = WRITE_CMOS_DATA(CmosMemory, Data);
break;
}
case CMOS_REG_MONTH:
{
ChangeTime = TRUE;
CurrentTime.wMonth = WRITE_CMOS_DATA(CmosMemory, Data);
break;
}
case CMOS_REG_YEAR:
{
ChangeTime = TRUE;
/* Clear everything except the century */
CurrentTime.wYear = (CurrentTime.wYear / 100) * 100;
CurrentTime.wYear += WRITE_CMOS_DATA(CmosMemory, Data);
break;
}
case CMOS_REG_CENTURY:
{
UNIMPLEMENTED;
break;
}
case CMOS_REG_STATUS_A:
{
CmosMemory.StatusRegA = Data & 0x7F; // Bit 7 is read-only
RtcUpdatePeriodicTimer();
break;
}
case CMOS_REG_STATUS_B:
{
CmosMemory.StatusRegB = Data;
break;
}
case CMOS_REG_STATUS_C:
case CMOS_REG_STATUS_D:
// Status registers C and D are read-only
break;
/* Is the following correct? */
case CMOS_REG_EXT_MEMORY_LOW:
case CMOS_REG_ACTUAL_EXT_MEMORY_LOW:
{
/* Sync EMS and UMS */
CmosMemory.ExtMemoryLow =
CmosMemory.ActualExtMemoryLow = Data;
break;
}
/* Is the following correct? */
case CMOS_REG_EXT_MEMORY_HIGH:
case CMOS_REG_ACTUAL_EXT_MEMORY_HIGH:
{
/* Sync EMS and UMS */
CmosMemory.ExtMemoryHigh =
CmosMemory.ActualExtMemoryHigh = Data;
break;
}
default:
{
CmosMemory.Regs[SelectedRegister] = Data;
}
}
if (ChangeTime) SetLocalTime(&CurrentTime);
/* Return to Status Register D */
SelectedRegister = CMOS_REG_STATUS_D;
}
/* PUBLIC FUNCTIONS ***********************************************************/
BOOLEAN IsNmiEnabled(VOID)
{
return NmiEnabled;
}
VOID CmosInitialize(VOID)
{
DWORD CmosSize = sizeof(CmosMemory);
/* File must not be opened before */
ASSERT(hCmosRam == INVALID_HANDLE_VALUE);
/* Clear the CMOS memory */
RtlZeroMemory(&CmosMemory, sizeof(CmosMemory));
/* Always open (and if needed, create) a RAM file with shared access */
SetLastError(0); // For debugging purposes
hCmosRam = CreateFileW(L"cmos.ram",
GENERIC_READ | GENERIC_WRITE,
FILE_SHARE_READ | FILE_SHARE_WRITE,
NULL,
OPEN_ALWAYS,
FILE_ATTRIBUTE_NORMAL,
NULL);
DPRINT1("CMOS opening %s (Error: %u)\n", hCmosRam != INVALID_HANDLE_VALUE ? "succeeded" : "failed", GetLastError());
if (hCmosRam != INVALID_HANDLE_VALUE)
{
BOOL Success;
/* Attempt to fill the CMOS memory with the RAM file */
SetLastError(0); // For debugging purposes
Success = ReadFile(hCmosRam, &CmosMemory, CmosSize, &CmosSize, NULL);
if (CmosSize != sizeof(CmosMemory))
{
/* Bad CMOS RAM file. Reinitialize the CMOS memory. */
DPRINT1("Invalid CMOS file, read bytes %u, expected bytes %u\n", CmosSize, sizeof(CmosMemory));
RtlZeroMemory(&CmosMemory, sizeof(CmosMemory));
}
DPRINT1("CMOS loading %s (Error: %u)\n", Success ? "succeeded" : "failed", GetLastError());
SetFilePointer(hCmosRam, 0, NULL, FILE_BEGIN);
}
/* Overwrite some registers with default values */
CmosMemory.StatusRegA = CMOS_DEFAULT_STA;
CmosMemory.StatusRegB = CMOS_DEFAULT_STB;
CmosMemory.StatusRegC = 0x00;
CmosMemory.StatusRegD = CMOS_BATTERY_OK; // Our CMOS battery works perfectly forever.
CmosMemory.Diagnostics = 0x00; // Diagnostics must not find any errors.
CmosMemory.ShutdownStatus = 0x00;
CmosMemory.EquipmentList = CMOS_EQUIPMENT_LIST;
// HACK: For the moment, set the boot sequence to: 1-Floppy, 2-Hard Disk .
CmosMemory.Regs[CMOS_REG_SYSOP] |= (1 << 5);
/* Memory settings */
/*
* Conventional memory size is 640 kB,
* see: http://webpages.charter.net/danrollins/techhelp/0184.HTM
* and see Ralf Brown: http://www.ctyme.com/intr/rb-0598.htm
* for more information.
*/
CmosMemory.BaseMemoryLow = LOBYTE(0x0280);
CmosMemory.BaseMemoryHigh = HIBYTE(0x0280);
CmosMemory.ExtMemoryLow =
CmosMemory.ActualExtMemoryLow = LOBYTE((MAX_ADDRESS - 0x100000) / 1024);
CmosMemory.ExtMemoryHigh =
CmosMemory.ActualExtMemoryHigh = HIBYTE((MAX_ADDRESS - 0x100000) / 1024);
/* Register the I/O Ports */
RegisterIoPort(CMOS_ADDRESS_PORT, NULL, CmosWriteAddress);
RegisterIoPort(CMOS_DATA_PORT , CmosReadData, CmosWriteData );
ClockTimer = CreateHardwareTimer(HARDWARE_TIMER_ENABLED,
HZ_TO_NS(1),
RtcTimeUpdate);
PeriodicTimer = CreateHardwareTimer(HARDWARE_TIMER_ENABLED | HARDWARE_TIMER_PRECISE,
HZ_TO_NS(1000),
RtcPeriodicTick);
}
VOID CmosCleanup(VOID)
{
DWORD CmosSize = sizeof(CmosMemory);
if (hCmosRam == INVALID_HANDLE_VALUE) return;
DestroyHardwareTimer(PeriodicTimer);
DestroyHardwareTimer(ClockTimer);
/* Flush the CMOS memory back to the RAM file and close it */
SetFilePointer(hCmosRam, 0, NULL, FILE_BEGIN);
WriteFile(hCmosRam, &CmosMemory, CmosSize, &CmosSize, NULL);
CloseHandle(hCmosRam);
hCmosRam = INVALID_HANDLE_VALUE;
}
/* EOF */