singrdk/base/Kernel/Singularity.Hal.ApicPC/Hpet.cs

///////////////////////////////////////////////////////////////////////////////
//
//  Microsoft Research Singularity
//
//  Copyright (c) Microsoft Corporation.  All rights reserved.
//
//  File:   Hpet.cs
//
//
//  Note:
//    Based on IA-PC HPET (High Precision Event Timers) Specification
//    Revision 1.0, June 2004.
//
//    The HPET code includes unchecked I/O memory operations so
//    methods can be marked as NoHeapAllocation.  CreateDevice()
//    must verify that there is at least enough memory for the
//    MainTimer.

namespace Microsoft.Singularity.Hal
{
    using Microsoft.Singularity.Io;
    using Microsoft.Singularity.Configuration;

    using System;
    using System.Runtime.CompilerServices;

    internal struct HpetTimerCaps
    {
        internal const uint FsbDelivery     = 1u << 15;
        internal const uint Width64         = 1u << 5;
        internal const uint PeriodicSupport = 1u << 4;

        internal const uint Mask = FsbDelivery | Width64 | PeriodicSupport;
    }

    internal struct HpetTimerConf
    {
        internal const uint LevelTriggered  = 1u << 1;
        internal const uint InterruptEnable = 1u << 2;
        internal const uint PeriodicMode    = 1u << 3;
        internal const uint Force32Bit      = 1u << 8;
    }

    [DriverCategory]
    [Signature("/pnp/PNP0103")]
    public sealed class HpetResources : DriverCategoryDeclaration
    {
        [IoMemoryRange(0, Default = 0, Length = 0x400)]
        public IoMemoryRange mem1;
    }

    internal sealed class Hpet : IDevice
    {
        private PnpConfig config;
        private IoMemory  region;

        private const int MainCounterOffset = 0xf0;

        internal const int MinRegionBytes = 0xf8;

        uint periodFs;              // femtoseconds
        uint capabilities;          // bits 0-31 at offset 0

        internal Hpet(PnpConfig config)
        {
            this.config = config;
            IoMemoryRange imr = (IoMemoryRange) config.DynamicRanges[0];
            this.region = imr.MemoryAtOffset(0, (int) imr.Length.ToUInt32(),
                                             Access.ReadWrite);

            capabilities = region.Read32(0x00);
            periodFs     = region.Read32(0x04);

            // Disable interrupts on timers
            for (uint i = 0; i <= MaxCounterIndex; i++) {
                DisableInterrupt(i);
            }

            uint gc = region.Read32(0x10) & ~3u;    // Clear legacy bits
            region.Write32(0x10, gc | 1);           // Enable main counter
        }

        void IDevice.Initialize()
        {
        }

        void IDevice.Finalize()
        {
        }

        /// <summary> Period in femptoseconds (10^-15) </summary>
        internal uint PeriodFs
        {
            [NoHeapAllocation]
            get { return periodFs; }
        }

        internal ushort VendorId
        {
            [NoHeapAllocation]
            get { return (ushort) (capabilities >> 16); }
        }

        internal uint Width
        {
            [NoHeapAllocation]
            get { return ((capabilities & 0x2000) != 0) ? 64u : 32u; }
        }

        internal uint MaxCounterIndex
        {
            [NoHeapAllocation]
            get { return ((capabilities >> 8) & 0xf); }
        }

        internal uint AvailableCounters
        {
            [NoHeapAllocation]
            get { return MaxCounterIndex + 1; }
        }

        internal uint Revision
        {
            [NoHeapAllocation]
            get { return capabilities & 0xff; }
        }

        internal ulong MainCounterValue
        {
            [NoHeapAllocation]
            get {
                ulong value;
                uint hi;
                do {
                    IoResult r;
                    r = region.Read64NoThrow(MainCounterOffset, out value);
                    DebugStub.Assert(IoResult.Success == r);
                    r = region.Read32NoThrow(MainCounterOffset + 4, out hi);
                    DebugStub.Assert(IoResult.Success == r);
                } while ((uint)(value >> 32) != hi);
                return value;
            }
        }

        internal uint MainCounterValue32
        {
            [NoHeapAllocation]
            get {
                uint value;
                IoResult r = region.Read32NoThrow(MainCounterOffset,
                                                  out value);
                DebugStub.Assert(IoResult.Success == r);
                return value;
            }
        }

        [NoHeapAllocation]
        internal void ClearInterrupt(uint timer)
        {
            if (timer <= MaxCounterIndex) {

                uint value;
                IoResult result = region.Read32NoThrow(0x20, out value);
                DebugStub.Assert(IoResult.Success == result);
                value = value & ~(1u << (int)timer);

                result = region.Write32NoThrow(0x20, value);
                DebugStub.Assert(IoResult.Success == result);
            }
        }

        [NoHeapAllocation]
        private int TimerOffset(uint timer)
        {
            return 0x100 + 0x20 * (int)timer;
        }

        internal void DisableInterrupt(uint timer)
        {
            if (timer <= MaxCounterIndex) {
                uint m = region.Read32(TimerOffset(timer));
                m &= ~HpetTimerConf.InterruptEnable;
                region.Write32(TimerOffset(timer), m);
            }
        }

        internal static IDevice CreateDevice(IoConfig config, string name)
        {
            PnpConfig pnpConfig = config as PnpConfig;
            if (pnpConfig == null) {
                return null;
            }

            IoMemoryRange imr = config.DynamicRanges[0] as IoMemoryRange;
            if (imr == null) {
                return null;
            }

            int imrBytes = (int)imr.Length.ToUInt32();
            if (imrBytes < Hpet.MinRegionBytes) {
                DebugStub.Write(
                    "HPET failed as region too small ({0} bytes).\n",
                    __arglist(imrBytes));
                return null;
            }

            Hpet hpet = new Hpet(pnpConfig);
            HalDevices.SwitchToHpetClock(hpet);
            return hpet;
        }
    }
}
RDK 1.1 2008-03-05 09:52:00 -05:00			`///////////////////////////////////////////////////////////////////////////////`
			`//`
			`// Microsoft Research Singularity`
			`//`
			`// Copyright (c) Microsoft Corporation. All rights reserved.`
			`//`
			`// File: Hpet.cs`
			`//`
			`//`
			`// Note:`
			`// Based on IA-PC HPET (High Precision Event Timers) Specification`
			`// Revision 1.0, June 2004.`
			`//`
			`// The HPET code includes unchecked I/O memory operations so`
			`// methods can be marked as NoHeapAllocation. CreateDevice()`
			`// must verify that there is at least enough memory for the`
			`// MainTimer.`

			`namespace Microsoft.Singularity.Hal`
			`{`
			`using Microsoft.Singularity.Io;`
			`using Microsoft.Singularity.Configuration;`

			`using System;`
			`using System.Runtime.CompilerServices;`

			`internal struct HpetTimerCaps`
			`{`
			`internal const uint FsbDelivery = 1u << 15;`
			`internal const uint Width64 = 1u << 5;`
			`internal const uint PeriodicSupport = 1u << 4;`

			`internal const uint Mask = FsbDelivery \| Width64 \| PeriodicSupport;`
			`}`

			`internal struct HpetTimerConf`
			`{`
			`internal const uint LevelTriggered = 1u << 1;`
			`internal const uint InterruptEnable = 1u << 2;`
			`internal const uint PeriodicMode = 1u << 3;`
			`internal const uint Force32Bit = 1u << 8;`
			`}`

			`[DriverCategory]`
			`[Signature("/pnp/PNP0103")]`
			`public sealed class HpetResources : DriverCategoryDeclaration`
			`{`
			`[IoMemoryRange(0, Default = 0, Length = 0x400)]`
			`public IoMemoryRange mem1;`
			`}`

			`internal sealed class Hpet : IDevice`
			`{`
			`private PnpConfig config;`
			`private IoMemory region;`

			`private const int MainCounterOffset = 0xf0;`

			`internal const int MinRegionBytes = 0xf8;`

			`uint periodFs; // femtoseconds`
			`uint capabilities; // bits 0-31 at offset 0`

			`internal Hpet(PnpConfig config)`
			`{`
			`this.config = config;`
			`IoMemoryRange imr = (IoMemoryRange) config.DynamicRanges[0];`
			`this.region = imr.MemoryAtOffset(0, (int) imr.Length.ToUInt32(),`
			`Access.ReadWrite);`

			`capabilities = region.Read32(0x00);`
			`periodFs = region.Read32(0x04);`

			`// Disable interrupts on timers`
			`for (uint i = 0; i <= MaxCounterIndex; i++) {`
			`DisableInterrupt(i);`
			`}`

			`uint gc = region.Read32(0x10) & ~3u; // Clear legacy bits`
			`region.Write32(0x10, gc \| 1); // Enable main counter`
			`}`

			`void IDevice.Initialize()`
			`{`
			`}`

			`void IDevice.Finalize()`
			`{`
			`}`

			`/// <summary> Period in femptoseconds (10^-15) </summary>`
			`internal uint PeriodFs`
			`{`
			`[NoHeapAllocation]`
			`get { return periodFs; }`
			`}`

			`internal ushort VendorId`
			`{`
			`[NoHeapAllocation]`
			`get { return (ushort) (capabilities >> 16); }`
			`}`

			`internal uint Width`
			`{`
			`[NoHeapAllocation]`
			`get { return ((capabilities & 0x2000) != 0) ? 64u : 32u; }`
			`}`

			`internal uint MaxCounterIndex`
			`{`
			`[NoHeapAllocation]`
			`get { return ((capabilities >> 8) & 0xf); }`
			`}`

			`internal uint AvailableCounters`
			`{`
			`[NoHeapAllocation]`
			`get { return MaxCounterIndex + 1; }`
			`}`

			`internal uint Revision`
			`{`
			`[NoHeapAllocation]`
			`get { return capabilities & 0xff; }`
			`}`

			`internal ulong MainCounterValue`
			`{`
			`[NoHeapAllocation]`
			`get {`
			`ulong value;`
			`uint hi;`
			`do {`
			`IoResult r;`
			`r = region.Read64NoThrow(MainCounterOffset, out value);`
			`DebugStub.Assert(IoResult.Success == r);`
			`r = region.Read32NoThrow(MainCounterOffset + 4, out hi);`
			`DebugStub.Assert(IoResult.Success == r);`
			`} while ((uint)(value >> 32) != hi);`
			`return value;`
			`}`
			`}`

			`internal uint MainCounterValue32`
			`{`
			`[NoHeapAllocation]`
			`get {`
			`uint value;`
			`IoResult r = region.Read32NoThrow(MainCounterOffset,`
			`out value);`
			`DebugStub.Assert(IoResult.Success == r);`
			`return value;`
			`}`
			`}`

			`[NoHeapAllocation]`
			`internal void ClearInterrupt(uint timer)`
			`{`
			`if (timer <= MaxCounterIndex) {`

			`uint value;`
			`IoResult result = region.Read32NoThrow(0x20, out value);`
			`DebugStub.Assert(IoResult.Success == result);`
			`value = value & ~(1u << (int)timer);`

			`result = region.Write32NoThrow(0x20, value);`
			`DebugStub.Assert(IoResult.Success == result);`
			`}`
			`}`

			`[NoHeapAllocation]`
			`private int TimerOffset(uint timer)`
			`{`
			`return 0x100 + 0x20 * (int)timer;`
			`}`

			`internal void DisableInterrupt(uint timer)`
			`{`
			`if (timer <= MaxCounterIndex) {`
			`uint m = region.Read32(TimerOffset(timer));`
			`m &= ~HpetTimerConf.InterruptEnable;`
			`region.Write32(TimerOffset(timer), m);`
			`}`
			`}`

			`internal static IDevice CreateDevice(IoConfig config, string name)`
			`{`
			`PnpConfig pnpConfig = config as PnpConfig;`
			`if (pnpConfig == null) {`
			`return null;`
			`}`

			`IoMemoryRange imr = config.DynamicRanges[0] as IoMemoryRange;`
			`if (imr == null) {`
			`return null;`
			`}`

			`int imrBytes = (int)imr.Length.ToUInt32();`
			`if (imrBytes < Hpet.MinRegionBytes) {`
			`DebugStub.Write(`
			`"HPET failed as region too small ({0} bytes).\n",`
			`__arglist(imrBytes));`
			`return null;`
			`}`

			`Hpet hpet = new Hpet(pnpConfig);`
			`HalDevices.SwitchToHpetClock(hpet);`
			`return hpet;`
			`}`
			`}`
			`}`