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

///////////////////////////////////////////////////////////////////////////////
//
//  Microsoft Research Singularity
//
//  Copyright (c) Microsoft Corporation.  All rights reserved.
//
//  File:   ApicTimer.cs
//

namespace Microsoft.Singularity.Hal
{
    using System;
    using System.Diagnostics;
    using System.Runtime.CompilerServices;

    public class ApicTimer
    {
        //
        // Constants
        //
        private readonly byte [] divisors = new byte [] {
            11 /*   1 */, 0 /*   2 */, 1 /*   4 */,  2 /*   8 */,
             3 /*  16 */, 8 /*  32 */, 9 /*  64 */, 10 /* 128 */
        };

        private const uint TimerPending  = 1u << 12;
        private const uint TimerMasked   = 1u << 16;
        private const uint TimerPeriodic = 1u << 17;

        private const uint TimeSpanHz = 10 * 1000 * 1000;
        private const long maxInterruptInterval = TimeSpanHz / 10;     // 100ms
        private const long minInterruptInterval = TimeSpanHz / 2000;   // 500us
        private const long interruptGranularity = TimeSpanHz / 100000; //  10us

        //
        // Members
        //
        private Apic apic;
        private uint divisor      = 1;
        private uint busFrequency = 100000000;
        private uint frequency;     // == busFrequency / divisor
        private byte interrupt;

        //
        // Methods
        //
        internal ApicTimer(Apic apic)
        {
            this.apic = apic;
            SetDivisor(1);
            SetOneShot();
            SetInterruptEnabled(false);
            interrupt = apic.IrqToInterrupt(Apic.TimerIrq);
        }

        internal void Finalize()
        {
        }

        internal byte Initialize()
        {
            SetInterruptVector(interrupt);
            SetDivisor(1);
            SetOneShot();
            SetBusFrequency(busFrequency);
            return interrupt;
        }

        internal void Start()
        {
            SetInterruptEnabled(true);
            SetNextInterrupt(maxInterruptInterval);
        }

        [NoHeapAllocation]
        internal void SetBusFrequency(uint measuredFrequency)
        {
            busFrequency = measuredFrequency;
            for (divisor = 1; divisor <= 128; divisor *= 2) {
                frequency = busFrequency / divisor;
                if (frequency < 100 * 1000 * 1000) {
                    break;
                }
            }
            SetDivisor(divisor);
        }

        /// <summary>
        /// Set processor clock bus divider.
        /// </summary>
        ///
        /// <param name ="amount">
        /// Amount to divide by.  Must be a power of 2 between 1 and 128.
        /// </param>
        [NoHeapAllocation]
        internal void SetDivisor(uint amount)
        {
            for (int i = 0; i < divisors.Length; i++) {
                if (amount <= (1u << i)) {
                    uint v = apic.Read(ApicOffset.TimerDivideConf) & ~0xfu;
                    v |= (uint)divisors[i];
                    apic.Write(ApicOffset.TimerDivideConf, v);
                    divisor = 1u << i;
                    return;
                }
            }
        }

        /// <summary>
        /// Get processor clock bus divider.
        /// </summary>
        [NoHeapAllocation]
        internal uint GetDivisor()
        {
            uint v = apic.Read(ApicOffset.TimerDivideConf) & 0xbu;
            for (int i = 0; i < divisors.Length; i++) {
                if ((uint)divisors[i] == v) {
                    return 1u << i;
                }
            }
            return ~0u;
        }

        [NoHeapAllocation]
        internal uint GetCurrentCount()
        {
            return apic.Read(ApicOffset.TimerCurrentCount);
        }

        internal uint Value
        {
            [NoHeapAllocation]
            get { return GetCurrentCount(); }
        }

        [NoHeapAllocation]
        internal void SetInitialCount(uint value)
        {
            apic.Write(ApicOffset.TimerInitialCount, value);
        }

        [NoHeapAllocation]
        internal void SetInterruptEnabled(bool enabled)
        {
            uint r = apic.Read(ApicOffset.LvtTimer) & ~TimerMasked;
            if (enabled == false) {
                r |= TimerMasked;
            }
            apic.Write(ApicOffset.LvtTimer, r);
        }

        [NoHeapAllocation]
        internal bool InterruptEnabled()
        {
            return (apic.Read(ApicOffset.LvtTimer) & TimerMasked) == 0;
        }

        [NoHeapAllocation]
        private void SetInterruptVector(byte interrupt)
        {
            uint r = (apic.Read(ApicOffset.LvtTimer) & ~0xffu) | interrupt;
            apic.Write(ApicOffset.LvtTimer, r);
        }

        [NoHeapAllocation]
        internal void SetPeriodic()
        {
            uint r = apic.Read(ApicOffset.LvtTimer) & ~TimerPeriodic;
            apic.Write(ApicOffset.LvtTimer, r | TimerPeriodic);
        }

        [NoHeapAllocation]
        internal void SetOneShot()
        {
            uint r = apic.Read(ApicOffset.LvtTimer) & ~TimerPeriodic;
            apic.Write(ApicOffset.LvtTimer, r);
        }

        internal byte Interrupt
        {
            [NoHeapAllocation]
            get { return interrupt; }
        }

        [NoHeapAllocation]
        public void ClearInterrupt()
        {
            apic.Write(ApicOffset.EoiRegister, 0);
            SetNextInterrupt(maxInterruptInterval);
        }

        /// <summary>
        /// Set relative time of next interrupt.
        ///
        /// <param name="delta">Relative time of next interrupt in units
        /// of 100ns.  The time should be with the range between
        /// from <c>SetNextInterruptMinDelta</c> to
        /// <c>SetNextInterruptMaxDelta</c></param>.
        /// <returns> true on success.</returns>
        /// </summary>
        [NoHeapAllocation]
        public bool SetNextInterrupt(long delta)
        {
            DebugStub.Assert(delta <= maxInterruptInterval);

            SetInitialCount(TimeSpanToTimerTicks(delta));

            return true;
        }

        /// <value>
        /// Maximum value accepted by SetNextInterrupt (in units of 100ns).
        /// </value>
        public long MaxInterruptInterval
        {
            [NoHeapAllocation]
            get { return maxInterruptInterval; }
        }

        /// <value>
        /// Minimum value accepted by SetNextInterrupt (in units of 100ns).
        /// </value>
        public long MinInterruptInterval
        {
            [NoHeapAllocation]
            get { return minInterruptInterval; }
        }

        /// <value>
        /// Granularity of interrupt timeout (in units of 100ns).
        /// </value>
        public long InterruptIntervalGranularity
        {
            [NoHeapAllocation]
            get { return interruptGranularity; }
        }

        [NoHeapAllocation]
        public long TimerToTimeSpanTicks(uint timerTicks)
        {
            long r = ((long) TimeSpanHz * (long) timerTicks) / frequency;
            return r;
        }

        [NoHeapAllocation]
        public uint TimeSpanToTimerTicks(long timeSpanTicks)
        {
            return (uint) (((long) frequency) * timeSpanTicks / TimeSpanHz);
        }
    }
}
RDK 1.1 2008-03-05 09:52:00 -05:00			`///////////////////////////////////////////////////////////////////////////////`
			`//`
			`// Microsoft Research Singularity`
			`//`
			`// Copyright (c) Microsoft Corporation. All rights reserved.`
			`//`
			`// File: ApicTimer.cs`
			`//`

			`namespace Microsoft.Singularity.Hal`
			`{`
			`using System;`
			`using System.Diagnostics;`
			`using System.Runtime.CompilerServices;`

			`public class ApicTimer`
			`{`
			`//`
			`// Constants`
			`//`
			`private readonly byte [] divisors = new byte [] {`
			`11 /* 1 /, 0 / 2 /, 1 / 4 /, 2 / 8 */,`
			`3 /* 16 /, 8 / 32 /, 9 / 64 /, 10 / 128 */`
			`};`

			`private const uint TimerPending = 1u << 12;`
			`private const uint TimerMasked = 1u << 16;`
			`private const uint TimerPeriodic = 1u << 17;`

			`private const uint TimeSpanHz = 10 * 1000 * 1000;`
			`private const long maxInterruptInterval = TimeSpanHz / 10; // 100ms`
			`private const long minInterruptInterval = TimeSpanHz / 2000; // 500us`
			`private const long interruptGranularity = TimeSpanHz / 100000; // 10us`

			`//`
			`// Members`
			`//`
			`private Apic apic;`
			`private uint divisor = 1;`
			`private uint busFrequency = 100000000;`
			`private uint frequency; // == busFrequency / divisor`
			`private byte interrupt;`

			`//`
			`// Methods`
			`//`
			`internal ApicTimer(Apic apic)`
			`{`
			`this.apic = apic;`
			`SetDivisor(1);`
			`SetOneShot();`
			`SetInterruptEnabled(false);`
			`interrupt = apic.IrqToInterrupt(Apic.TimerIrq);`
			`}`

			`internal void Finalize()`
			`{`
			`}`

			`internal byte Initialize()`
			`{`
			`SetInterruptVector(interrupt);`
			`SetDivisor(1);`
			`SetOneShot();`
			`SetBusFrequency(busFrequency);`
			`return interrupt;`
			`}`

			`internal void Start()`
			`{`
			`SetInterruptEnabled(true);`
			`SetNextInterrupt(maxInterruptInterval);`
			`}`

			`[NoHeapAllocation]`
			`internal void SetBusFrequency(uint measuredFrequency)`
			`{`
			`busFrequency = measuredFrequency;`
			`for (divisor = 1; divisor <= 128; divisor *= 2) {`
			`frequency = busFrequency / divisor;`
			`if (frequency < 100 * 1000 * 1000) {`
			`break;`
			`}`
			`}`
			`SetDivisor(divisor);`
			`}`

			`/// <summary>`
			`/// Set processor clock bus divider.`
			`/// </summary>`
			`///`
			`/// <param name ="amount">`
			`/// Amount to divide by. Must be a power of 2 between 1 and 128.`
			`/// </param>`
			`[NoHeapAllocation]`
			`internal void SetDivisor(uint amount)`
			`{`
			`for (int i = 0; i < divisors.Length; i++) {`
			`if (amount <= (1u << i)) {`
			`uint v = apic.Read(ApicOffset.TimerDivideConf) & ~0xfu;`
			`v \|= (uint)divisors[i];`
			`apic.Write(ApicOffset.TimerDivideConf, v);`
			`divisor = 1u << i;`
			`return;`
			`}`
			`}`
			`}`

			`/// <summary>`
			`/// Get processor clock bus divider.`
			`/// </summary>`
			`[NoHeapAllocation]`
			`internal uint GetDivisor()`
			`{`
			`uint v = apic.Read(ApicOffset.TimerDivideConf) & 0xbu;`
			`for (int i = 0; i < divisors.Length; i++) {`
			`if ((uint)divisors[i] == v) {`
			`return 1u << i;`
			`}`
			`}`
			`return ~0u;`
			`}`

			`[NoHeapAllocation]`
			`internal uint GetCurrentCount()`
			`{`
			`return apic.Read(ApicOffset.TimerCurrentCount);`
			`}`

			`internal uint Value`
			`{`
			`[NoHeapAllocation]`
			`get { return GetCurrentCount(); }`
			`}`

			`[NoHeapAllocation]`
			`internal void SetInitialCount(uint value)`
			`{`
			`apic.Write(ApicOffset.TimerInitialCount, value);`
			`}`

			`[NoHeapAllocation]`
			`internal void SetInterruptEnabled(bool enabled)`
			`{`
			`uint r = apic.Read(ApicOffset.LvtTimer) & ~TimerMasked;`
			`if (enabled == false) {`
			`r \|= TimerMasked;`
			`}`
			`apic.Write(ApicOffset.LvtTimer, r);`
			`}`

			`[NoHeapAllocation]`
			`internal bool InterruptEnabled()`
			`{`
			`return (apic.Read(ApicOffset.LvtTimer) & TimerMasked) == 0;`
			`}`

			`[NoHeapAllocation]`
			`private void SetInterruptVector(byte interrupt)`
			`{`
			`uint r = (apic.Read(ApicOffset.LvtTimer) & ~0xffu) \| interrupt;`
			`apic.Write(ApicOffset.LvtTimer, r);`
			`}`

			`[NoHeapAllocation]`
			`internal void SetPeriodic()`
			`{`
			`uint r = apic.Read(ApicOffset.LvtTimer) & ~TimerPeriodic;`
			`apic.Write(ApicOffset.LvtTimer, r \| TimerPeriodic);`
			`}`

			`[NoHeapAllocation]`
			`internal void SetOneShot()`
			`{`
			`uint r = apic.Read(ApicOffset.LvtTimer) & ~TimerPeriodic;`
			`apic.Write(ApicOffset.LvtTimer, r);`
			`}`

			`internal byte Interrupt`
			`{`
			`[NoHeapAllocation]`
			`get { return interrupt; }`
			`}`

			`[NoHeapAllocation]`
			`public void ClearInterrupt()`
			`{`
			`apic.Write(ApicOffset.EoiRegister, 0);`
			`SetNextInterrupt(maxInterruptInterval);`
			`}`

			`/// <summary>`
			`/// Set relative time of next interrupt.`
			`///`
			`/// <param name="delta">Relative time of next interrupt in units`
			`/// of 100ns. The time should be with the range between`
			`/// from <c>SetNextInterruptMinDelta</c> to`
			`/// <c>SetNextInterruptMaxDelta</c></param>.`
			`/// <returns> true on success.</returns>`
			`/// </summary>`
			`[NoHeapAllocation]`
			`public bool SetNextInterrupt(long delta)`
			`{`
			`DebugStub.Assert(delta <= maxInterruptInterval);`

			`SetInitialCount(TimeSpanToTimerTicks(delta));`

			`return true;`
			`}`

			`/// <value>`
			`/// Maximum value accepted by SetNextInterrupt (in units of 100ns).`
			`/// </value>`
			`public long MaxInterruptInterval`
			`{`
			`[NoHeapAllocation]`
			`get { return maxInterruptInterval; }`
			`}`

			`/// <value>`
			`/// Minimum value accepted by SetNextInterrupt (in units of 100ns).`
			`/// </value>`
			`public long MinInterruptInterval`
			`{`
			`[NoHeapAllocation]`
			`get { return minInterruptInterval; }`
			`}`

			`/// <value>`
			`/// Granularity of interrupt timeout (in units of 100ns).`
			`/// </value>`
			`public long InterruptIntervalGranularity`
			`{`
			`[NoHeapAllocation]`
			`get { return interruptGranularity; }`
			`}`

			`[NoHeapAllocation]`
			`public long TimerToTimeSpanTicks(uint timerTicks)`
			`{`
			`long r = ((long) TimeSpanHz * (long) timerTicks) / frequency;`
			`return r;`
			`}`

			`[NoHeapAllocation]`
			`public uint TimeSpanToTimerTicks(long timeSpanTicks)`
			`{`
			`return (uint) (((long) frequency) * timeSpanTicks / TimeSpanHz);`
			`}`
			`}`
			`}`