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singrdk/base/Kernel/Singularity.Hal.LegacyPC/RTClock.cs

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RDK 1.1
2008-03-05 09:52:00 -05:00
///////////////////////////////////////////////////////////////////////////////
//
// Microsoft Research Singularity
//
// Copyright (c) Microsoft Corporation. All rights reserved.
//
// File: RTClock.cs
//
// Useful reference URLs:
// http://developer.intel.com/design/archives/periphrl/index.htm
// http://developer.intel.com/design/archives/periphrl/docs/7203.htm
// http://developer.intel.com/design/archives/periphrl/docs/23124406.htm
//
// The basic ideas for this driver come from the MMOSA code,
// though the implementation differs. This is partly because
// the code needs to run on Virtual PC and it isn't able to do
// a very accurate emulation of the i8254.
//
// There are two source available for timing - the Real-Time
// Clock (RTC) and the programmable interval timer (PIT). The
// standard PC RTC is based on derivatives of the Motorola
// MC146818A. It's able to provide the time with a resolution
// of 1 second and also has a programmable periodic interrupt.
//
// The programmable interrupt timer is based on the i8254. It
// can be programmed in a variety of modes - we use it to
// generate an interrupt at a configurable time in the future
// and then reprogram it each interrupt. The maximum interrupt
// period is 65535 ticks of a 1.193MHz clock.
//
// We use both of the RTC and the programmable interrupt timer to
// maintain our estimate of the current time. The RTC provides granularity
// to with 1/64 seconds and the time is used to get an estimate to within
// 1/1.193 * 10e-6 seconds within each RTC interval.
//
// The key variables are:
//
// upTime - the time the system has been up. This variable gets
// updated during the periodic RTC interrupt handling
// (delta = 1/64Hz).
//
// pitLast - the last value programmed into the PIT. The PIT counts down
// and generates an interrupt at (or shortly after) the instant
// the current PIT value reaches zero.
//
// pitAccum - the accumulated time measured by the PIT since upTime
// was updated.
//
// The current kernel time is always:
// upTime + pitAccum + (pitLast - pitCurrent)
//
// The PIT is always programmed to run, either by the consumer of the timer
// interface or by the timer itself.
//
// Timer::SetNextInterrupt(t)
// pitAccum += (pitLast - pitCurrent)
// // program PIT (not shown)
// pitLast = t
//
// Timer::Interrupt()
// pitAccum += pitLast;
// // But PIT time may accumulate between interrupt dispatch and crossing
// // Zero so.
// if (pitCurrent != 0)
// pitAccum += (MaxPitValue - pitCurrent)
// // Inform user of interrupt
// if (userNotScheduledInterrupt)
// SetNextInterrupt(MaxInterruptInterval)
//
// RTC::Interrupt()
// pitLast = pitNow
// pitAccum = 0
// upTime += RTCInterruptPeriod
//
// All of these methods are atomic interrupt-wise.
//
// Note: if we want to test the accuracy of the timer over a
// period we can set RTC::Interrupt to just return without
// touching any variables. All of the time accumulated will end
// up in pitAccum.
//
// Conditionals
//
// TIMER_NO_GO - disables timer and scheduling of timer interrupts.
//
// RTC_NO_GO - disable RTC.
//
// DEBUG_TIMER - enable timer debug messages and boot-time diagnostics.
//
// DEBUG_CLOCK - enable clock debug messages
//
// LOG_CLOCK - log adjustments to clock time and dump out later.
//
// LOG_SNI - log calls to SetNextInterrupt to see what's being thrown in.
//
// Tip: When this code does not behave useful things to check
// are the interrupt rate and the rate of calls to
// SetNextInterrupt.
//
// #define VERBOSE
using Microsoft.Singularity.Io;
using System;
using System.Threading;
using System.Diagnostics;
using System.Runtime.CompilerServices;
using Microsoft.Singularity.Configuration;
namespace Microsoft.Singularity.Hal
{
// declare resources for the kernel manifest
[DriverCategory]
[Signature("/pnp/PNP0B00")]
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public sealed class RtcResourcesLegacyPC : DriverCategoryDeclaration
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{
[IoPortRange(0, Default = 0x70, Length = 0x02)]
public IoPortRange port1;
[IoIrqRange(1, Default = 0x08)]
public IoIrqRange irq1;
}
/// <remarks>
/// Class <c>RTClock</c> represents the system
/// Real-Time Clock. RTC chips in PCs are based on the
/// Motorola MC1461818A. It provides timing resolution of 1
/// second, but can generate periodic interrupts more
/// frequently. By combining information from
/// <c>Timer8254</c> programmable timer time can be read
/// with a resolution of 0.838 microseconds.
/// </remarks>
[ CLSCompliant(false) ]
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internal sealed class RTClockLegacyPC : HalClock
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{
private PnpConfig config;
private byte irq;
private Pic pic;
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// Real time clock registers - for calibration
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private IoPort rtcadd;
private IoPort rtcdat;
// Data registers
private const byte DS1287_SECONDS = 0x00;
private const byte DS1287_SECONDS_ALARM = 0x01;
private const byte DS1287_MINUTES = 0x02;
private const byte DS1287_MINUTES_ALARM = 0x03;
private const byte DS1287_HOURS = 0x04;
private const byte DS1287_HOURS_ALARM = 0x05;
private const byte DS1287_DAY_OF_WEEK = 0x06; // 1 is Sunday
private const byte DS1287_DAY_OF_MONTH = 0x07;
private const byte DS1287_MONTH = 0x08;
private const byte DS1287_YEAR = 0x09;
private const byte DS1287_USERDATA = 0x32; // Randomly chosen user reg.
// Control registers and masks
private const byte DS1287_A = 0x0a;
private const byte DS1287_A_UIP = 0x80; // Update Cycle Status
private const byte DS1287_A_DIVON = 0x20; // Osc and Freq Div on
private const byte DS1287_A_8KHZ = 0x03;
private const byte DS1287_A_4KHZ = 0x04;
private const byte DS1287_A_2KHZ = 0x05;
private const byte DS1287_A_1KHZ = 0x06;
private const byte DS1287_A_64HZ = 0x0a;
private const byte DS1287_A_2HZ = 0x0f;
private const byte DS1287_B = 0x0b;
private const byte DS1287_B_UTI = 0x80; // Update Transfer Inhibit
private const byte DS1287_B_PIE = 0x40; // Periodic Interrupt Enable
private const byte DS1287_B_24H = 0x20; // Alarm Interrupt Enable
private const byte DS1287_B_UIE = 0x10; // Update Cycle Inter. Enable
private const byte DS1287_B_SQWE = 0x08; // Square-Wave Enable
private const byte DS1287_B_DF = 0x04; // Data Format
private const byte DS1287_B_DF_BINARY = 0x04; // Binary
private const byte DS1287_B_DF_BCD = 0x00; // Binary Coded Decimal (BCD)
private const byte DS1287_B_HF = 0x02; // Hour Format
private const byte DS1287_B_HF_24H = 0x02; // 24-hour format
private const byte DS1287_B_HF_12H = 0x00; // 12-hour format
private const byte DS1287_B_DSE = 0x01; // Daylight Saving Enable
private const byte DS1287_C = 0x0c;
private const byte DS1287_C_UF = 0x10; // Update Event Flag
private const byte DS1287_C_AF = 0x20; // Alarm Event Flag
private const byte DS1287_C_PF = 0x40; // Periodic Event Flag
private const byte DS1287_C_INTF = 0x80; // Interrupt Request Flag
private const byte DS1287_D = 0x0d;
private const byte DS1287_D_VRT = 0x80; // Valid RAM and Time
// Rate if rtc used for generating profiling interrupts
const byte DS1287_A_SAMPLING_HZ = DS1287_A_1KHZ;
const int InterruptGapTicks = 156250; // units of 100ns
const uint maxAttempts = 1000000;
private RtcPitState rps = null;
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private Timer8254LegacyPC timer = null;
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private long rtcBootTime;
private volatile uint irqCount = 0;
// Variables for fast GetKernelTicks implementation that uses
// TSC when it is deemed safe.
bool noisyTimer; // Running on VPC? Disable optimization
long tscSnapshot; // TSC value at sync point
long ticksSnapshot; // Kernel ticks at sync point
long lastKernelTicks; // Last kernel ticks reported
bool tscSnapshotValid = false;
bool initedFastTime = false;
int tickScale;
const int tickRoll = 24;
// Constructor
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internal RTClockLegacyPC(PnpConfig config, Pic pic, Timer8254LegacyPC timer)
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{
DebugStub.Print("RTClock: create\n");
// /pnp/08/03/01/PNP0B00 0003 cfg dis : ISA RTC Controller : AT RTC
// IRQ mask=0100 type=47
// I/O Port inf=01 min=0070 max=0070 aln=01 len=02 0070..0071
this.config = config;
this.pic = pic;
this.irq = ((IoIrqRange)config.DynamicRanges[1]).Irq;
this.timer = timer;
rtcadd = ((IoPortRange)config.DynamicRanges[0])
.PortAtOffset(0, 1, Access.ReadWrite);
rtcdat = ((IoPortRange)config.DynamicRanges[0])
.PortAtOffset(1, 1, Access.ReadWrite);
}
[NoHeapAllocation]
private byte ReadRtc(byte addr)
{
IoResult result;
byte value;
result = rtcadd.Write8NoThrow(addr);
DebugStub.Assert(IoResult.Success == result);
result = rtcdat.Read8NoThrow(out value);
DebugStub.Assert(IoResult.Success == result);
return value;
}
[NoHeapAllocation]
private void WriteRtc(byte addr, byte val)
{
IoResult result;
result = rtcadd.Write8NoThrow(addr);
DebugStub.Assert(IoResult.Success == result);
result = rtcdat.Write8NoThrow(val);
DebugStub.Assert(IoResult.Success == result);
}
[NoHeapAllocation]
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public override void ClearInterrupt()
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{
#if RTC_NO_GO
DebugStub.Print("Unwanted RTC interrupt! (b = {0})\n",
__arglist(ReadRtc(DS1287_B)));
return;
#endif // RTC_NO_GO
byte status = ReadRtc(DS1287_C);
if ((status & 0x40) != 0x40) {
// We may get Update-Ended interrupts even though we've
// not requested them.
pic.AckIrq(irq);
return;
}
ClockLogger.AddEntry(4, rps, timer);
rps.pitLastClock = timer.Timer2Read();
rps.upTime += InterruptGapTicks;
ClockLogger.AddEntry(5, rps, timer);
irqCount++;
if (timer.InterruptPending == false) {
// This is to keep time progressing if the user has
// not set an interrupt
timer.SetKeepAliveInterrupt();
}
pic.AckIrq(irq);
// Invalidate TSC snapshot to force clock synchronization
this.tscSnapshotValid = false;
}
internal byte Initialize()
{
DebugStub.Print("RTClock: initialize\n");
rps = timer.rps;
// Turn oscillator on, but disable and clear interrupts
if (Processor.SamplingEnabled()) {
WriteRtc(DS1287_A, DS1287_A_DIVON | DS1287_A_SAMPLING_HZ);
}
else {
WriteRtc(DS1287_A, DS1287_A_DIVON | DS1287_A_64HZ);
}
WriteRtc(DS1287_B, DS1287_B_24H | DS1287_B_DF_BCD);
ReadRtc(DS1287_C); // Clear any update bits
if ((ReadRtc(DS1287_D) & DS1287_D_VRT) == 0) {
DebugStub.Print("RTClock weak or defective power source.\n");
}
rtcBootTime = PullRtcTime().Ticks;
// Enable and clear interrupts
// NB it may take 500ms for first interrupt to be generated.
pic.EnableIrq(irq);
return pic.IrqToInterrupt(irq);
}
internal void Start()
{
DebugStub.Print("RTClock::Start()\n");
#if RTC_NO_GO
WriteRtc(DS1287_B, DS1287_B_24H | DS1287_B_UTI);
#endif
// XXX A #else does not work here with sgc (!)
#if !RTC_NO_GO
if (Processor.SamplingEnabled()) {
WriteRtc(DS1287_A, DS1287_A_DIVON | DS1287_A_SAMPLING_HZ);
}
else {
WriteRtc(DS1287_A, DS1287_A_DIVON | DS1287_A_64HZ);
}
WriteRtc(DS1287_B, DS1287_B_24H | DS1287_B_PIE);
ReadRtc(DS1287_C);
#endif
}
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internal void ReleaseResources()
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{
pic.DisableIrq(irq);
}
[NoHeapAllocation]
bool InitializeFastTime()
{
const ulong KernelTicksPerSecond = 10000000;
ulong cps = Processor.CyclesPerSecond;
if (cps >= KernelTicksPerSecond) {
this.tscSnapshot = 0;
this.ticksSnapshot = 0;
this.tickScale =
(int)((1 << tickRoll) * KernelTicksPerSecond / cps);
#if VERBOSE
DebugStub.Print(
"tick scale = {0} (actual {1:d}, fast {2:d})",
__arglist(this.tickScale,
cps,
((1 << tickRoll) * KernelTicksPerSecond /
(ulong)this.tickScale))
);
#endif // VERBOSE
return true;
}
return false;
}
internal void SetNoisyTimer(bool noisy)
{
this.noisyTimer = noisy;
}
[NoHeapAllocation]
private long GetKernelTicksFromHW()
{
bool iflag = Processor.DisableInterrupts();
try {
ClockLogger.AddEntry(100, rps, timer);
long r = rps.GetKernelTicks(timer.Timer2Read());
return r;
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}
finally {
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Processor.RestoreInterrupts(iflag);
}
}
[NoHeapAllocation]
private long GetKernelTicksFromTsc()
{
long now = unchecked((long)Processor.CycleCount);
long tscDelta = now - this.tscSnapshot;
long tickDelta = (tscDelta * tickScale) >> tickRoll;
DebugStub.Assert(tickDelta >= 0);
return ticksSnapshot + tickDelta;
}
[NoHeapAllocation]
private long InternalGetKernelTicks()
{
if (!initedFastTime) {
initedFastTime = InitializeFastTime();
}
if (this.noisyTimer || !initedFastTime) {
// Looks like Virtual PC or one not suited to
// fast time calculation. Always pull time from
// the hardware as the TSC is not virtualized
// and is not to be trusted.
return GetKernelTicksFromHW();
}
else {
if (!tscSnapshotValid) {
// When waking up from a processor halt
// event or from a clock interrupt, sync
// with the fixed h/w's concept of time.
this.ticksSnapshot = GetKernelTicksFromHW();
this.tscSnapshot = unchecked((long)Processor.CycleCount);
this.tscSnapshotValid = true;
return ticksSnapshot;
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}
else {
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return GetKernelTicksFromTsc();
}
}
}
[NoHeapAllocation]
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public override long GetKernelTicks()
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{
#if DEBUG_TIMER
{
long cpuT = GetKernelTicksFromTsc();
long hwT = GetKernelTicksFromHW();
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if (cpuT - hwT > 5000 || hwT - cpuT < -5000) {
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DebugStub.Print("Delta = {0:d} (hw {1:d} cpu {2:d})\n",
__arglist(cpuT - hwT, hwT, cpuT));
}
}
#endif // DEBUG_TIMER
// We use the TSC to provide fast kernel ticks as
// far as possible, and periodically sync against an
// off-chip clock. Because there are different time
// sources and we don't ever want to report time
// going backwards, we need to check that time would
// reported to have advanced or remained the same,
// and that the clock has not wrapped.
long kernelTicks = InternalGetKernelTicks();
if (kernelTicks >= lastKernelTicks) {
lastKernelTicks = kernelTicks;
return kernelTicks;
}
else if (kernelTicks < 0 && lastKernelTicks > 0) {
// clock wrap
return kernelTicks;
}
#if DEBUG_TIMER
// Skew from switching between tsc and underlying clock
DebugStub.Print("Backwards delta = {0} (HW {1} TSC {2})\n",
__arglist(kernelTicks - lastKernelTicks,
GetKernelTicksFromHW(),
GetKernelTicksFromTsc())
);
#endif // DEBUG_TIMER
return lastKernelTicks;
}
[NoHeapAllocation]
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public override void CpuResumeFromHaltEvent()
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{
tscSnapshotValid = false;
}
[NoHeapAllocation]
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public override long GetRtcTime()
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{
return rtcBootTime + GetKernelTicks();
}
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public override void SetRtcTime(long rtcTime)
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{
long delta = rtcTime - GetRtcTime();
rtcBootTime = rtcBootTime + delta;
PushRtcTime(new DateTime(rtcTime));
}
[NoHeapAllocation]
internal static byte BcdToHex(byte bcd)
{
return (byte) (10 * (bcd >> 4) + (bcd & 0x0f));
}
[NoHeapAllocation]
internal static byte HexToBcd(int hex)
{
int h = hex / 10;
return (byte) ((h << 4) | (hex - h * 10));
}
internal bool UpdateInProgress()
{
return (ReadRtc(DS1287_A) & DS1287_A_UIP) == DS1287_A_UIP;
}
private DateTime PullRtcTime()
{
for (uint iters = 0; iters < maxAttempts; iters++) {
bool iflag = Processor.DisableInterrupts();
try {
ReadRtc(DS1287_C); // Clear update flag if set
if ((ReadRtc(DS1287_A) & DS1287_A_UIP) != 0) {
// Update is in progress, try again
continue;
}
// There is no update
// pending. The specs suggest at least
// ~244us to read values (T_BUC)...
byte second = BcdToHex(ReadRtc(DS1287_SECONDS));
byte minute = BcdToHex(ReadRtc(DS1287_MINUTES));
byte hour = BcdToHex(ReadRtc(DS1287_HOURS));
byte day = BcdToHex(ReadRtc(DS1287_DAY_OF_MONTH));
byte month = BcdToHex(ReadRtc(DS1287_MONTH));
byte year = BcdToHex(ReadRtc(DS1287_YEAR));
byte century = BcdToHex(ReadRtc(DS1287_USERDATA));
// ...but we don't
// trust the specs, particularly as we may
// be running on emulated hardware. Retry
// if an update is pending or appears to
// have completed whilst reading the time.
if ((ReadRtc(DS1287_A) & DS1287_A_UIP) != 0 ||
(ReadRtc(DS1287_C) & DS1287_C_UF) != 0) {
continue;
}
DebugStub.Print("PullRtcTime: " +
"{0:d4}-{1:d2}-{2:d} {3:2}:{4:d2}:{5:d2}" +
"\n",
__arglist(100*century+year, month, day,
hour, minute, second));
// There appears to be an issue with the timer that
// doesn't clear/zero out the most significant digit
// when a value can be represented by a single digit.
// Attempt to recover from this scenario.
second = (second < 60) ? second : (byte) (second % 10);
minute = (minute < 60) ? minute : (byte) (minute % 10);
hour = (hour < 24) ? hour : (byte) (hour % 10);
day = (day <= 31) ? day : (byte) (day % 10);
month = (month <= 12) ? month : (byte) (month % 10);
year = (year < 100) ? year : (byte) (year % 100);
return new DateTime(century * 100 + year,
month, day, hour, minute,
second);
}
catch (ArgumentOutOfRangeException e) {
DebugStub.Print("PullRtcTime failed: {0} "+
"(1:x}:{2:x}:{3:x} {4:x}/{5:x} "+
"100*{6:x}+{7:x})\n",
__arglist(e,
ReadRtc(DS1287_HOURS),
ReadRtc(DS1287_MINUTES),
ReadRtc(DS1287_SECONDS),
ReadRtc(DS1287_MONTH),
ReadRtc(DS1287_DAY_OF_MONTH),
ReadRtc(DS1287_USERDATA),
ReadRtc(DS1287_YEAR)));
if (iters > (maxAttempts >> 1)) {
DebugStub.Break();
}
}
finally {
Processor.RestoreInterrupts(iflag);
}
}
return new DateTime(2005, 1, 1, 0, 0, 0);
}
private void PushRtcTime(DateTime dt)
{
bool iflag = Processor.DisableInterrupts();
byte saved = ReadRtc(DS1287_B);
try {
// Set UTI bit to stop transfers between RTC
// bytes and user buffer.
WriteRtc(DS1287_B, (byte)(saved | DS1287_B_UTI));
// Write new values
WriteRtc(DS1287_SECONDS, HexToBcd(dt.Second));
WriteRtc(DS1287_MINUTES, HexToBcd(dt.Minute));
WriteRtc(DS1287_HOURS, HexToBcd(dt.Hour));
WriteRtc(DS1287_DAY_OF_MONTH, HexToBcd(dt.Day));
WriteRtc(DS1287_MONTH, HexToBcd(dt.Month));
int century = dt.Year / 100;
WriteRtc(9, HexToBcd(dt.Year - century * 100));
WriteRtc(DS1287_YEAR, HexToBcd(dt.Year - century*100));
WriteRtc(DS1287_USERDATA, HexToBcd(century));
// Clear UTI bit to enable transfers again
DebugStub.Print("PushRtcTime {3:2}:{4:d2}:{5:d2} {0}/{1}-{2:d4}\n",
__arglist(dt.Month, dt.Day,
100*century + dt.Year, dt.Hour,
dt.Minute, dt.Second));
}
finally {
WriteRtc(DS1287_B, saved);
Processor.RestoreInterrupts(iflag);
}
}
}
}