/* $Id: DevHPET.cpp 56284 2015-06-09 10:46:34Z vboxsync $ */ /** @file * HPET virtual device - High Precision Event Timer emulation. */ /* * Copyright (C) 2009-2013 Oracle Corporation * * This file is part of VirtualBox Open Source Edition (OSE), as * available from http://www.virtualbox.org. This file is free software; * you can redistribute it and/or modify it under the terms of the GNU * General Public License (GPL) as published by the Free Software * Foundation, in version 2 as it comes in the "COPYING" file of the * VirtualBox OSE distribution. VirtualBox OSE is distributed in the * hope that it will be useful, but WITHOUT ANY WARRANTY of any kind. */ /* This implementation is based on the (generic) Intel IA-PC HPET specification * and the Intel ICH9 datasheet. */ /******************************************************************************* * Header Files * *******************************************************************************/ #define LOG_GROUP LOG_GROUP_DEV_HPET #include #include #include #include #include #include #include "VBoxDD.h" /******************************************************************************* * Defined Constants And Macros * *******************************************************************************/ /* * Current limitations: * - not entirely correct time of interrupt, i.e. never * schedule interrupt earlier than in 1ms * - statistics not implemented * - level-triggered mode not implemented */ /** Base address for MMIO. * On ICH9, it is 0xFED0x000 where 'x' is 0-3, default 0. We do not support * relocation as the platform firmware is responsible for configuring the * HPET base address and the OS isn't expected to move it. * WARNING: This has to match the ACPI tables! */ #define HPET_BASE 0xfed00000 /** HPET reserves a 1K range. */ #define HPET_BAR_SIZE 0x1000 /** The number of timers for PIIX4 / PIIX3. */ #define HPET_NUM_TIMERS_PIIX 3 /* Minimal implementation. */ /** The number of timers for ICH9. */ #define HPET_NUM_TIMERS_ICH9 4 /** HPET clock period for PIIX4 / PIIX3. * 10000000 femtoseconds == 10ns. */ #define HPET_CLK_PERIOD_PIIX UINT32_C(10000000) /** HPET clock period for ICH9. * 69841279 femtoseconds == 69.84 ns (1 / 14.31818MHz). */ #define HPET_CLK_PERIOD_ICH9 UINT32_C(69841279) /** * Femtosecods in a nanosecond */ #define FS_PER_NS 1000000 /** @name Interrupt type * @{ */ #define HPET_TIMER_TYPE_LEVEL (1 << 1) #define HPET_TIMER_TYPE_EDGE (0 << 1) /** @} */ /** @name Delivery mode * @{ */ #define HPET_TIMER_DELIVERY_APIC 0 /**< Delivery through APIC. */ #define HPET_TIMER_DELIVERY_FSB 1 /**< Delivery through FSB. */ /** @} */ #define HPET_TIMER_CAP_FSB_INT_DEL (1 << 15) #define HPET_TIMER_CAP_PER_INT (1 << 4) #define HPET_CFG_ENABLE 0x001 /**< ENABLE_CNF */ #define HPET_CFG_LEGACY 0x002 /**< LEG_RT_CNF */ /** @name Register offsets in HPET space. * @{ */ #define HPET_ID 0x000 /**< Device ID. */ #define HPET_PERIOD 0x004 /**< Clock period in femtoseconds. */ #define HPET_CFG 0x010 /**< Configuration register. */ #define HPET_STATUS 0x020 /**< Status register. */ #define HPET_COUNTER 0x0f0 /**< Main HPET counter. */ /** @} */ /** @name Timer N offsets (within each timer's space). * @{ */ #define HPET_TN_CFG 0x000 /**< Timer N configuration. */ #define HPET_TN_CMP 0x008 /**< Timer N comparator. */ #define HPET_TN_ROUTE 0x010 /**< Timer N interrupt route. */ /** @} */ #define HPET_CFG_WRITE_MASK 0x3 #define HPET_TN_INT_TYPE RT_BIT_64(1) #define HPET_TN_ENABLE RT_BIT_64(2) #define HPET_TN_PERIODIC RT_BIT_64(3) #define HPET_TN_PERIODIC_CAP RT_BIT_64(4) #define HPET_TN_SIZE_CAP RT_BIT_64(5) #define HPET_TN_SETVAL RT_BIT_64(6) #define HPET_TN_32BIT RT_BIT_64(8) #define HPET_TN_INT_ROUTE_MASK UINT64_C(0x3e00) #define HPET_TN_CFG_WRITE_MASK UINT64_C(0x3e46) #define HPET_TN_INT_ROUTE_SHIFT 9 #define HPET_TN_INT_ROUTE_CAP_SHIFT 32 #define HPET_TN_CFG_BITS_READONLY_OR_RESERVED 0xffff80b1U /** Extract the timer count from the capabilities. */ #define HPET_CAP_GET_TIMERS(a_u32) ( ((a_u32) >> 8) & 0x1f ) /** The version of the saved state. */ #define HPET_SAVED_STATE_VERSION 2 /** Empty saved state */ #define HPET_SAVED_STATE_VERSION_EMPTY 1 /** * Acquires the HPET lock or returns. */ #define DEVHPET_LOCK_RETURN(a_pThis, a_rcBusy) \ do { \ int rcLock = PDMCritSectEnter(&(a_pThis)->CritSect, (a_rcBusy)); \ if (rcLock != VINF_SUCCESS) \ return rcLock; \ } while (0) /** * Releases the HPET lock. */ #define DEVHPET_UNLOCK(a_pThis) \ do { PDMCritSectLeave(&(a_pThis)->CritSect); } while (0) /** * Acquires the TM lock and HPET lock, returns on failure. */ #define DEVHPET_LOCK_BOTH_RETURN(a_pThis, a_rcBusy) \ do { \ int rcLock = TMTimerLock((a_pThis)->aTimers[0].CTX_SUFF(pTimer), (a_rcBusy)); \ if (rcLock != VINF_SUCCESS) \ return rcLock; \ rcLock = PDMCritSectEnter(&(a_pThis)->CritSect, (a_rcBusy)); \ if (rcLock != VINF_SUCCESS) \ { \ TMTimerUnlock((a_pThis)->aTimers[0].CTX_SUFF(pTimer)); \ return rcLock; \ } \ } while (0) /** * Releases the HPET lock and TM lock. */ #define DEVHPET_UNLOCK_BOTH(a_pThis) \ do { \ PDMCritSectLeave(&(a_pThis)->CritSect); \ TMTimerUnlock((a_pThis)->aTimers[0].CTX_SUFF(pTimer)); \ } while (0) /******************************************************************************* * Structures and Typedefs * *******************************************************************************/ /** * A HPET timer. */ typedef struct HPETTIMER { /** The HPET timer - R3 Ptr. */ PTMTIMERR3 pTimerR3; /** Pointer to the instance data - R3 Ptr. */ R3PTRTYPE(struct HPET *) pHpetR3; /** The HPET timer - R0 Ptr. */ PTMTIMERR0 pTimerR0; /** Pointer to the instance data - R0 Ptr. */ R0PTRTYPE(struct HPET *) pHpetR0; /** The HPET timer - RC Ptr. */ PTMTIMERRC pTimerRC; /** Pointer to the instance data - RC Ptr. */ RCPTRTYPE(struct HPET *) pHpetRC; /** Timer index. */ uint8_t idxTimer; /** Wrap. */ uint8_t u8Wrap; /** Alignment. */ uint32_t alignment0; /** @name Memory-mapped, software visible timer registers. * @{ */ /** Configuration/capabilities. */ uint64_t u64Config; /** Comparator. */ uint64_t u64Cmp; /** FSB route, not supported now. */ uint64_t u64Fsb; /** @} */ /** @name Hidden register state. * @{ */ /** Last value written to comparator. */ uint64_t u64Period; /** @} */ } HPETTIMER; AssertCompileMemberAlignment(HPETTIMER, u64Config, sizeof(uint64_t)); /** * The HPET state. */ typedef struct HPET { /** Pointer to the device instance. - R3 ptr. */ PPDMDEVINSR3 pDevInsR3; /** The HPET helpers - R3 Ptr. */ PCPDMHPETHLPR3 pHpetHlpR3; /** Pointer to the device instance. - R0 ptr. */ PPDMDEVINSR0 pDevInsR0; /** The HPET helpers - R0 Ptr. */ PCPDMHPETHLPR0 pHpetHlpR0; /** Pointer to the device instance. - RC ptr. */ PPDMDEVINSRC pDevInsRC; /** The HPET helpers - RC Ptr. */ PCPDMHPETHLPRC pHpetHlpRC; /** Timer structures. */ HPETTIMER aTimers[RT_MAX(HPET_NUM_TIMERS_PIIX, HPET_NUM_TIMERS_ICH9)]; /** Offset realtive to the virtual sync clock. */ uint64_t u64HpetOffset; /** @name Memory-mapped, software visible registers * @{ */ /** Capabilities. */ uint32_t u32Capabilities; /** HPET_PERIOD - . */ uint32_t u32Period; /** Configuration. */ uint64_t u64HpetConfig; /** Interrupt status register. */ uint64_t u64Isr; /** Main counter. */ uint64_t u64HpetCounter; /** @} */ /** Global device lock. */ PDMCRITSECT CritSect; /** Whether we emulate ICH9 HPET (different frequency & timer count). */ bool fIch9; /** Size alignment padding. */ uint8_t abPadding0[7]; } HPET; #ifndef VBOX_DEVICE_STRUCT_TESTCASE DECLINLINE(bool) hpet32bitTimer(HPETTIMER *pHpetTimer) { uint64_t u64Cfg = pHpetTimer->u64Config; return ((u64Cfg & HPET_TN_SIZE_CAP) == 0) || ((u64Cfg & HPET_TN_32BIT) != 0); } DECLINLINE(uint64_t) hpetInvalidValue(HPETTIMER *pHpetTimer) { return hpet32bitTimer(pHpetTimer) ? UINT32_MAX : UINT64_MAX; } DECLINLINE(uint64_t) hpetTicksToNs(HPET *pThis, uint64_t value) { return ASMMultU64ByU32DivByU32(value, pThis->u32Period, FS_PER_NS); } DECLINLINE(uint64_t) nsToHpetTicks(HPET const *pThis, uint64_t u64Value) { return ASMMultU64ByU32DivByU32(u64Value, FS_PER_NS, pThis->u32Period); } DECLINLINE(uint64_t) hpetGetTicks(HPET const *pThis) { /* * We can use any timer to get current time, they all go * with the same speed. */ return nsToHpetTicks(pThis, TMTimerGet(pThis->aTimers[0].CTX_SUFF(pTimer)) + pThis->u64HpetOffset); } DECLINLINE(uint64_t) hpetUpdateMasked(uint64_t u64NewValue, uint64_t u64OldValue, uint64_t u64Mask) { u64NewValue &= u64Mask; u64NewValue |= (u64OldValue & ~u64Mask); return u64NewValue; } DECLINLINE(bool) hpetBitJustSet(uint64_t u64OldValue, uint64_t u64NewValue, uint64_t u64Mask) { return !(u64OldValue & u64Mask) && !!(u64NewValue & u64Mask); } DECLINLINE(bool) hpetBitJustCleared(uint64_t u64OldValue, uint64_t u64NewValue, uint64_t u64Mask) { return !!(u64OldValue & u64Mask) && !(u64NewValue & u64Mask); } DECLINLINE(uint64_t) hpetComputeDiff(HPETTIMER *pHpetTimer, uint64_t u64Now) { if (hpet32bitTimer(pHpetTimer)) { uint32_t u32Diff; u32Diff = (uint32_t)pHpetTimer->u64Cmp - (uint32_t)u64Now; u32Diff = ((int32_t)u32Diff > 0) ? u32Diff : (uint32_t)0; return (uint64_t)u32Diff; } else { uint64_t u64Diff; u64Diff = pHpetTimer->u64Cmp - u64Now; u64Diff = ((int64_t)u64Diff > 0) ? u64Diff : (uint64_t)0; return u64Diff; } } static void hpetAdjustComparator(HPETTIMER *pHpetTimer, uint64_t u64Now) { uint64_t u64Period = pHpetTimer->u64Period; if ((pHpetTimer->u64Config & HPET_TN_PERIODIC) && u64Period) { uint64_t cPeriods = (u64Now - pHpetTimer->u64Cmp) / u64Period; pHpetTimer->u64Cmp += (cPeriods + 1) * u64Period; } } /** * Sets the frequency hint if it's a periodic timer. * * @param pThis The HPET state. * @param pHpetTimer The timer. */ DECLINLINE(void) hpetTimerSetFrequencyHint(HPET *pThis, HPETTIMER *pHpetTimer) { if (pHpetTimer->u64Config & HPET_TN_PERIODIC) { uint64_t const u64Period = pHpetTimer->u64Period; uint32_t const u32Freq = pThis->u32Period; if (u64Period > 0 && u64Period < u32Freq) TMTimerSetFrequencyHint(pHpetTimer->CTX_SUFF(pTimer), u32Freq / (uint32_t)u64Period); } } static void hpetProgramTimer(HPETTIMER *pHpetTimer) { /* no wrapping on new timers */ pHpetTimer->u8Wrap = 0; uint64_t u64Ticks = hpetGetTicks(pHpetTimer->CTX_SUFF(pHpet)); hpetAdjustComparator(pHpetTimer, u64Ticks); uint64_t u64Diff = hpetComputeDiff(pHpetTimer, u64Ticks); /* * HPET spec says in one-shot 32-bit mode, generate an interrupt when * counter wraps in addition to an interrupt with comparator match. */ if ( hpet32bitTimer(pHpetTimer) && !(pHpetTimer->u64Config & HPET_TN_PERIODIC)) { uint32_t u32TillWrap = 0xffffffff - (uint32_t)u64Ticks + 1; if (u32TillWrap < (uint32_t)u64Diff) { Log(("wrap on timer %d: till=%u ticks=%lld diff64=%lld\n", pHpetTimer->idxTimer, u32TillWrap, u64Ticks, u64Diff)); u64Diff = u32TillWrap; pHpetTimer->u8Wrap = 1; } } /* * HACK ALERT! Avoid killing VM with interrupts. */ #if 1 /** @todo: HACK, rethink, may have negative impact on the guest */ if (u64Diff == 0) u64Diff = 100000; /* 1 millisecond */ #endif Log4(("HPET: next IRQ in %lld ticks (%lld ns)\n", u64Diff, hpetTicksToNs(pHpetTimer->CTX_SUFF(pHpet), u64Diff))); TMTimerSetNano(pHpetTimer->CTX_SUFF(pTimer), hpetTicksToNs(pHpetTimer->CTX_SUFF(pHpet), u64Diff)); hpetTimerSetFrequencyHint(pHpetTimer->CTX_SUFF(pHpet), pHpetTimer); } /* -=-=-=-=-=- Timer register accesses -=-=-=-=-=- */ /** * Reads a HPET timer register. * * @returns VBox strict status code. * @param pThis The HPET instance. * @param iTimerNo The timer index. * @param iTimerReg The index of the timer register to read. * @param pu32Value Where to return the register value. * * @remarks ASSUMES the caller holds the HPET lock. */ static int hpetTimerRegRead32(HPET const *pThis, uint32_t iTimerNo, uint32_t iTimerReg, uint32_t *pu32Value) { Assert(PDMCritSectIsOwner(&pThis->CritSect)); if ( iTimerNo >= HPET_CAP_GET_TIMERS(pThis->u32Capabilities) /* The second check is only to satisfy Parfait; */ || iTimerNo >= RT_ELEMENTS(pThis->aTimers) ) /* in practice, the number of configured timers */ { /* will always be <= aTimers elements. */ LogRelMax(10, ("HPET: using timer above configured range: %d\n", iTimerNo)); *pu32Value = 0; return VINF_SUCCESS; } HPETTIMER const *pHpetTimer = &pThis->aTimers[iTimerNo]; uint32_t u32Value; switch (iTimerReg) { case HPET_TN_CFG: u32Value = (uint32_t)pHpetTimer->u64Config; Log(("read HPET_TN_CFG on %d: %#x\n", iTimerNo, u32Value)); break; case HPET_TN_CFG + 4: u32Value = (uint32_t)(pHpetTimer->u64Config >> 32); Log(("read HPET_TN_CFG+4 on %d: %#x\n", iTimerNo, u32Value)); break; case HPET_TN_CMP: u32Value = (uint32_t)pHpetTimer->u64Cmp; Log(("read HPET_TN_CMP on %d: %#x (%#llx)\n", pHpetTimer->idxTimer, u32Value, pHpetTimer->u64Cmp)); break; case HPET_TN_CMP + 4: u32Value = (uint32_t)(pHpetTimer->u64Cmp >> 32); Log(("read HPET_TN_CMP+4 on %d: %#x (%#llx)\n", pHpetTimer->idxTimer, u32Value, pHpetTimer->u64Cmp)); break; case HPET_TN_ROUTE: u32Value = (uint32_t)(pHpetTimer->u64Fsb >> 32); /** @todo Looks wrong, but since it's not supported, who cares. */ Log(("read HPET_TN_ROUTE on %d: %#x\n", iTimerNo, u32Value)); break; default: { LogRelMax(10, ("invalid HPET register read %d on %d\n", iTimerReg, pHpetTimer->idxTimer)); u32Value = 0; break; } } *pu32Value = u32Value; return VINF_SUCCESS; } /** * 32-bit write to a HPET timer register. * * @returns Strict VBox status code. * * @param pThis The HPET state. * @param idxReg The register being written to. * @param u32NewValue The value being written. * * @remarks The caller should not hold the device lock, unless it also holds * the TM lock. */ static int hpetTimerRegWrite32(HPET *pThis, uint32_t iTimerNo, uint32_t iTimerReg, uint32_t u32NewValue) { Assert(!PDMCritSectIsOwner(&pThis->CritSect) || TMTimerIsLockOwner(pThis->aTimers[0].CTX_SUFF(pTimer))); if ( iTimerNo >= HPET_CAP_GET_TIMERS(pThis->u32Capabilities) || iTimerNo >= RT_ELEMENTS(pThis->aTimers) ) /* Parfait - see above. */ { LogRelMax(10, ("HPET: using timer above configured range: %d\n", iTimerNo)); return VINF_SUCCESS; } HPETTIMER *pHpetTimer = &pThis->aTimers[iTimerNo]; switch (iTimerReg) { case HPET_TN_CFG: { DEVHPET_LOCK_RETURN(pThis, VINF_IOM_R3_MMIO_WRITE); uint64_t u64Mask = HPET_TN_CFG_WRITE_MASK; Log(("write HPET_TN_CFG: %d: %x\n", iTimerNo, u32NewValue)); if (pHpetTimer->u64Config & HPET_TN_PERIODIC_CAP) u64Mask |= HPET_TN_PERIODIC; if (pHpetTimer->u64Config & HPET_TN_SIZE_CAP) u64Mask |= HPET_TN_32BIT; else u32NewValue &= ~HPET_TN_32BIT; if (u32NewValue & HPET_TN_32BIT) { Log(("setting timer %d to 32-bit mode\n", iTimerNo)); pHpetTimer->u64Cmp = (uint32_t)pHpetTimer->u64Cmp; pHpetTimer->u64Period = (uint32_t)pHpetTimer->u64Period; } if ((u32NewValue & HPET_TN_INT_TYPE) == HPET_TIMER_TYPE_LEVEL) { LogRelMax(10, ("level-triggered config not yet supported\n")); AssertFailed(); } /* We only care about lower 32-bits so far */ pHpetTimer->u64Config = hpetUpdateMasked(u32NewValue, pHpetTimer->u64Config, u64Mask); DEVHPET_UNLOCK(pThis); break; } case HPET_TN_CFG + 4: /* Interrupt capabilities - read only. */ Log(("write HPET_TN_CFG + 4, useless\n")); break; case HPET_TN_CMP: /* lower bits of comparator register */ { DEVHPET_LOCK_BOTH_RETURN(pThis, VINF_IOM_R3_MMIO_WRITE); Log(("write HPET_TN_CMP on %d: %#x\n", iTimerNo, u32NewValue)); if (pHpetTimer->u64Config & HPET_TN_PERIODIC) pHpetTimer->u64Period = RT_MAKE_U64(u32NewValue, RT_HI_U32(pHpetTimer->u64Period)); pHpetTimer->u64Cmp = RT_MAKE_U64(u32NewValue, RT_HI_U32(pHpetTimer->u64Cmp)); pHpetTimer->u64Config &= ~HPET_TN_SETVAL; Log2(("after HPET_TN_CMP cmp=%#llx per=%#llx\n", pHpetTimer->u64Cmp, pHpetTimer->u64Period)); if (pThis->u64HpetConfig & HPET_CFG_ENABLE) hpetProgramTimer(pHpetTimer); DEVHPET_UNLOCK_BOTH(pThis); break; } case HPET_TN_CMP + 4: /* upper bits of comparator register */ { DEVHPET_LOCK_BOTH_RETURN(pThis, VINF_IOM_R3_MMIO_WRITE); Log(("write HPET_TN_CMP + 4 on %d: %#x\n", iTimerNo, u32NewValue)); if (!hpet32bitTimer(pHpetTimer)) { if (pHpetTimer->u64Config & HPET_TN_PERIODIC) pHpetTimer->u64Period = RT_MAKE_U64(RT_LO_U32(pHpetTimer->u64Period), u32NewValue); pHpetTimer->u64Cmp = RT_MAKE_U64(RT_LO_U32(pHpetTimer->u64Cmp), u32NewValue); Log2(("after HPET_TN_CMP+4 cmp=%llx per=%llx tmr=%d\n", pHpetTimer->u64Cmp, pHpetTimer->u64Period, iTimerNo)); pHpetTimer->u64Config &= ~HPET_TN_SETVAL; if (pThis->u64HpetConfig & HPET_CFG_ENABLE) hpetProgramTimer(pHpetTimer); } DEVHPET_UNLOCK_BOTH(pThis); break; } case HPET_TN_ROUTE: Log(("write HPET_TN_ROUTE\n")); break; case HPET_TN_ROUTE + 4: Log(("write HPET_TN_ROUTE + 4\n")); break; default: LogRelMax(10, ("invalid timer register write: %d\n", iTimerReg)); break; } return VINF_SUCCESS; } /* -=-=-=-=-=- Non-timer register accesses -=-=-=-=-=- */ /** * Read a 32-bit HPET register. * * @returns Strict VBox status code. * @param pThis The HPET state. * @param idxReg The register to read. * @param pu32Value Where to return the register value. * * @remarks The caller must not own the device lock if HPET_COUNTER is read. */ static int hpetConfigRegRead32(HPET *pThis, uint32_t idxReg, uint32_t *pu32Value) { Assert(!PDMCritSectIsOwner(&pThis->CritSect) || (idxReg != HPET_COUNTER && idxReg != HPET_COUNTER + 4)); uint32_t u32Value; switch (idxReg) { case HPET_ID: DEVHPET_LOCK_RETURN(pThis, VINF_IOM_R3_MMIO_READ); u32Value = pThis->u32Capabilities; DEVHPET_UNLOCK(pThis); Log(("read HPET_ID: %#x\n", u32Value)); break; case HPET_PERIOD: DEVHPET_LOCK_RETURN(pThis, VINF_IOM_R3_MMIO_READ); u32Value = pThis->u32Period; DEVHPET_UNLOCK(pThis); Log(("read HPET_PERIOD: %#x\n", u32Value)); break; case HPET_CFG: DEVHPET_LOCK_RETURN(pThis, VINF_IOM_R3_MMIO_READ); u32Value = (uint32_t)pThis->u64HpetConfig; DEVHPET_UNLOCK(pThis); Log(("read HPET_CFG: %#x\n", u32Value)); break; case HPET_CFG + 4: DEVHPET_LOCK_RETURN(pThis, VINF_IOM_R3_MMIO_READ); u32Value = (uint32_t)(pThis->u64HpetConfig >> 32); DEVHPET_UNLOCK(pThis); Log(("read of HPET_CFG + 4: %#x\n", u32Value)); break; case HPET_COUNTER: case HPET_COUNTER + 4: { DEVHPET_LOCK_BOTH_RETURN(pThis, VINF_IOM_R3_MMIO_READ); uint64_t u64Ticks; if (pThis->u64HpetConfig & HPET_CFG_ENABLE) u64Ticks = hpetGetTicks(pThis); else u64Ticks = pThis->u64HpetCounter; DEVHPET_UNLOCK_BOTH(pThis); /** @todo is it correct? */ u32Value = (idxReg == HPET_COUNTER) ? (uint32_t)u64Ticks : (uint32_t)(u64Ticks >> 32); Log(("read HPET_COUNTER: %s part value %x (%#llx)\n", (idxReg == HPET_COUNTER) ? "low" : "high", u32Value, u64Ticks)); break; } case HPET_STATUS: DEVHPET_LOCK_RETURN(pThis, VINF_IOM_R3_MMIO_READ); u32Value = (uint32_t)pThis->u64Isr; DEVHPET_UNLOCK(pThis); Log(("read HPET_STATUS: %#x\n", u32Value)); break; default: Log(("invalid HPET register read: %x\n", idxReg)); u32Value = 0; break; } *pu32Value = u32Value; return VINF_SUCCESS; } /** * 32-bit write to a config register. * * @returns Strict VBox status code. * * @param pThis The HPET state. * @param idxReg The register being written to. * @param u32NewValue The value being written. * * @remarks The caller should not hold the device lock, unless it also holds * the TM lock. */ static int hpetConfigRegWrite32(HPET *pThis, uint32_t idxReg, uint32_t u32NewValue) { Assert(!PDMCritSectIsOwner(&pThis->CritSect) || TMTimerIsLockOwner(pThis->aTimers[0].CTX_SUFF(pTimer))); int rc = VINF_SUCCESS; switch (idxReg) { case HPET_ID: case HPET_ID + 4: { Log(("write HPET_ID, useless\n")); break; } case HPET_CFG: { DEVHPET_LOCK_BOTH_RETURN(pThis, VINF_IOM_R3_MMIO_WRITE); uint32_t const iOldValue = (uint32_t)(pThis->u64HpetConfig); Log(("write HPET_CFG: %x (old %x)\n", u32NewValue, iOldValue)); /* * This check must be here, before actual update, as hpetLegacyMode * may request retry in R3 - so we must keep state intact. */ if ( ((iOldValue ^ u32NewValue) & HPET_CFG_LEGACY) && pThis->pHpetHlpR3 != NIL_RTR3PTR) { #ifdef IN_RING3 rc = pThis->pHpetHlpR3->pfnSetLegacyMode(pThis->pDevInsR3, RT_BOOL(u32NewValue & HPET_CFG_LEGACY)); if (rc != VINF_SUCCESS) #else rc = VINF_IOM_R3_MMIO_WRITE; #endif { DEVHPET_UNLOCK_BOTH(pThis); break; } } pThis->u64HpetConfig = hpetUpdateMasked(u32NewValue, iOldValue, HPET_CFG_WRITE_MASK); uint32_t const cTimers = HPET_CAP_GET_TIMERS(pThis->u32Capabilities); if (hpetBitJustSet(iOldValue, u32NewValue, HPET_CFG_ENABLE)) { /** @todo Only get the time stamp once when reprogramming? */ /* Enable main counter and interrupt generation. */ pThis->u64HpetOffset = hpetTicksToNs(pThis, pThis->u64HpetCounter) - TMTimerGet(pThis->aTimers[0].CTX_SUFF(pTimer)); for (uint32_t i = 0; i < cTimers; i++) if (pThis->aTimers[i].u64Cmp != hpetInvalidValue(&pThis->aTimers[i])) hpetProgramTimer(&pThis->aTimers[i]); } else if (hpetBitJustCleared(iOldValue, u32NewValue, HPET_CFG_ENABLE)) { /* Halt main counter and disable interrupt generation. */ pThis->u64HpetCounter = hpetGetTicks(pThis); for (uint32_t i = 0; i < cTimers; i++) TMTimerStop(pThis->aTimers[i].CTX_SUFF(pTimer)); } DEVHPET_UNLOCK_BOTH(pThis); break; } case HPET_CFG + 4: { DEVHPET_LOCK_RETURN(pThis, VINF_IOM_R3_MMIO_WRITE); pThis->u64HpetConfig = hpetUpdateMasked((uint64_t)u32NewValue << 32, pThis->u64HpetConfig, UINT64_C(0xffffffff00000000)); Log(("write HPET_CFG + 4: %x -> %#llx\n", u32NewValue, pThis->u64HpetConfig)); DEVHPET_UNLOCK(pThis); break; } case HPET_STATUS: { DEVHPET_LOCK_RETURN(pThis, VINF_IOM_R3_MMIO_WRITE); /* Clear ISR for all set bits in u32NewValue, see p. 14 of the HPET spec. */ pThis->u64Isr &= ~((uint64_t)u32NewValue); Log(("write HPET_STATUS: %x -> ISR=%#llx\n", u32NewValue, pThis->u64Isr)); DEVHPET_UNLOCK(pThis); break; } case HPET_STATUS + 4: { Log(("write HPET_STATUS + 4: %x\n", u32NewValue)); if (u32NewValue != 0) LogRelMax(10, ("Writing HPET_STATUS + 4 with non-zero, ignored\n")); break; } case HPET_COUNTER: { DEVHPET_LOCK_RETURN(pThis, VINF_IOM_R3_MMIO_WRITE); pThis->u64HpetCounter = RT_MAKE_U64(u32NewValue, RT_HI_U32(pThis->u64HpetCounter)); Log(("write HPET_COUNTER: %#x -> %llx\n", u32NewValue, pThis->u64HpetCounter)); DEVHPET_UNLOCK(pThis); break; } case HPET_COUNTER + 4: { DEVHPET_LOCK_RETURN(pThis, VINF_IOM_R3_MMIO_WRITE); pThis->u64HpetCounter = RT_MAKE_U64(RT_LO_U32(pThis->u64HpetCounter), u32NewValue); Log(("write HPET_COUNTER + 4: %#x -> %llx\n", u32NewValue, pThis->u64HpetCounter)); DEVHPET_UNLOCK(pThis); break; } default: LogRelMax(10, ("invalid HPET config write: %x\n", idxReg)); break; } return rc; } /* -=-=-=-=-=- MMIO callbacks -=-=-=-=-=- */ /** * @callback_method_impl{FNIOMMMIOREAD} */ PDMBOTHCBDECL(int) hpetMMIORead(PPDMDEVINS pDevIns, void *pvUser, RTGCPHYS GCPhysAddr, void *pv, unsigned cb) { HPET *pThis = PDMINS_2_DATA(pDevIns, HPET*); uint32_t const idxReg = (uint32_t)(GCPhysAddr - HPET_BASE); NOREF(pvUser); Assert(cb == 4 || cb == 8); LogFlow(("hpetMMIORead (%d): %llx (%x)\n", cb, (uint64_t)GCPhysAddr, idxReg)); int rc; if (cb == 4) { /* * 4-byte access. */ if (idxReg >= 0x100 && idxReg < 0x400) { DEVHPET_LOCK_RETURN(pThis, VINF_IOM_R3_MMIO_READ); rc = hpetTimerRegRead32(pThis, (idxReg - 0x100) / 0x20, (idxReg - 0x100) % 0x20, (uint32_t *)pv); DEVHPET_UNLOCK(pThis); } else rc = hpetConfigRegRead32(pThis, idxReg, (uint32_t *)pv); } else { /* * 8-byte access - Split the access except for timing sensitive registers. * The others assume the protection of the lock. */ PRTUINT64U pValue = (PRTUINT64U)pv; if (idxReg == HPET_COUNTER) { /* When reading HPET counter we must read it in a single read, to avoid unexpected time jumps on 32-bit overflow. */ DEVHPET_LOCK_BOTH_RETURN(pThis, VINF_IOM_R3_MMIO_READ); if (pThis->u64HpetConfig & HPET_CFG_ENABLE) pValue->u = hpetGetTicks(pThis); else pValue->u = pThis->u64HpetCounter; DEVHPET_UNLOCK_BOTH(pThis); rc = VINF_SUCCESS; } else { DEVHPET_LOCK_RETURN(pThis, VINF_IOM_R3_MMIO_READ); if (idxReg >= 0x100 && idxReg < 0x400) { uint32_t iTimer = (idxReg - 0x100) / 0x20; uint32_t iTimerReg = (idxReg - 0x100) % 0x20; rc = hpetTimerRegRead32(pThis, iTimer, iTimerReg, &pValue->s.Lo); if (rc == VINF_SUCCESS) rc = hpetTimerRegRead32(pThis, iTimer, iTimerReg + 4, &pValue->s.Hi); } else { /* for most 8-byte accesses we just split them, happens under lock anyway. */ rc = hpetConfigRegRead32(pThis, idxReg, &pValue->s.Lo); if (rc == VINF_SUCCESS) rc = hpetConfigRegRead32(pThis, idxReg + 4, &pValue->s.Hi); } DEVHPET_UNLOCK(pThis); } } return rc; } /** * @callback_method_impl{FNIOMMMIOWRITE} */ PDMBOTHCBDECL(int) hpetMMIOWrite(PPDMDEVINS pDevIns, void *pvUser, RTGCPHYS GCPhysAddr, void const *pv, unsigned cb) { HPET *pThis = PDMINS_2_DATA(pDevIns, HPET*); uint32_t idxReg = (uint32_t)(GCPhysAddr - HPET_BASE); LogFlow(("hpetMMIOWrite: cb=%u reg=%03x (%RGp) val=%llx\n", cb, idxReg, GCPhysAddr, cb == 4 ? *(uint32_t *)pv : cb == 8 ? *(uint64_t *)pv : 0xdeadbeef)); NOREF(pvUser); Assert(cb == 4 || cb == 8); int rc; if (cb == 4) { if (idxReg >= 0x100 && idxReg < 0x400) rc = hpetTimerRegWrite32(pThis, (idxReg - 0x100) / 0x20, (idxReg - 0x100) % 0x20, *(uint32_t const *)pv); else rc = hpetConfigRegWrite32(pThis, idxReg, *(uint32_t const *)pv); } else { /* * 8-byte access. */ /* Split the access and rely on the locking to prevent trouble. */ DEVHPET_LOCK_BOTH_RETURN(pThis, VINF_IOM_R3_MMIO_WRITE); RTUINT64U uValue; uValue.u = *(uint64_t const *)pv; if (idxReg >= 0x100 && idxReg < 0x400) { uint32_t iTimer = (idxReg - 0x100) / 0x20; uint32_t iTimerReg = (idxReg - 0x100) % 0x20; /** @todo Consider handling iTimerReg == HPET_TN_CMP specially here */ rc = hpetTimerRegWrite32(pThis, iTimer, iTimerReg, uValue.s.Lo); if (RT_LIKELY(rc == VINF_SUCCESS)) rc = hpetTimerRegWrite32(pThis, iTimer, iTimerReg + 4, uValue.s.Hi); } else { rc = hpetConfigRegWrite32(pThis, idxReg, uValue.s.Lo); if (RT_LIKELY(rc == VINF_SUCCESS)) rc = hpetConfigRegWrite32(pThis, idxReg + 4, uValue.s.Hi); } DEVHPET_UNLOCK_BOTH(pThis); } return rc; } #ifdef IN_RING3 /* -=-=-=-=-=- Timer Callback Processing -=-=-=-=-=- */ /** * Gets the IRQ of an HPET timer. * * @returns IRQ number. * @param pHpetTimer The HPET timer. */ static uint32_t hpetR3TimerGetIrq(struct HPETTIMER const *pHpetTimer) { /* * Per spec, in legacy mode the HPET timers are wired as follows: * timer 0: IRQ0 for PIC and IRQ2 for APIC * timer 1: IRQ8 for both PIC and APIC * * ISA IRQ delivery logic will take care of correct delivery * to the different ICs. */ if ( (pHpetTimer->idxTimer <= 1) && (pHpetTimer->CTX_SUFF(pHpet)->u64HpetConfig & HPET_CFG_LEGACY)) return (pHpetTimer->idxTimer == 0) ? 0 : 8; return (pHpetTimer->u64Config & HPET_TN_INT_ROUTE_MASK) >> HPET_TN_INT_ROUTE_SHIFT; } /** * Used by hpetR3Timer to update the IRQ status. * * @param pThis The HPET device state. * @param pHpetTimer The HPET timer. */ static void hpetR3TimerUpdateIrq(HPET *pThis, struct HPETTIMER *pHpetTimer) { /** @todo: is it correct? */ if ( !!(pHpetTimer->u64Config & HPET_TN_ENABLE) && !!(pThis->u64HpetConfig & HPET_CFG_ENABLE)) { uint32_t irq = hpetR3TimerGetIrq(pHpetTimer); Log4(("HPET: raising IRQ %d\n", irq)); /* ISR bits are only set in level-triggered mode. */ if ((pHpetTimer->u64Config & HPET_TN_INT_TYPE) == HPET_TIMER_TYPE_LEVEL) pThis->u64Isr |= (uint64_t)(1 << pHpetTimer->idxTimer); /* We trigger flip/flop in edge-triggered mode and do nothing in level-triggered mode yet. */ if ((pHpetTimer->u64Config & HPET_TN_INT_TYPE) == HPET_TIMER_TYPE_EDGE) pThis->pHpetHlpR3->pfnSetIrq(pThis->CTX_SUFF(pDevIns), irq, PDM_IRQ_LEVEL_FLIP_FLOP); else AssertFailed(); /** @todo: implement IRQs in level-triggered mode */ } } /** * Device timer callback function. * * @param pDevIns Device instance of the device which registered the timer. * @param pTimer The timer handle. * @param pvUser Pointer to the HPET timer state. */ static DECLCALLBACK(void) hpetR3Timer(PPDMDEVINS pDevIns, PTMTIMER pTimer, void *pvUser) { HPET *pThis = PDMINS_2_DATA(pDevIns, HPET *); HPETTIMER *pHpetTimer = (HPETTIMER *)pvUser; uint64_t u64Period = pHpetTimer->u64Period; uint64_t u64CurTick = hpetGetTicks(pThis); uint64_t u64Diff; if (pHpetTimer->u64Config & HPET_TN_PERIODIC) { if (u64Period) { hpetAdjustComparator(pHpetTimer, u64CurTick); u64Diff = hpetComputeDiff(pHpetTimer, u64CurTick); Log4(("HPET: periodic: next in %llu\n", hpetTicksToNs(pThis, u64Diff))); TMTimerSetNano(pTimer, hpetTicksToNs(pThis, u64Diff)); } } else if (hpet32bitTimer(pHpetTimer)) { /* For 32-bit non-periodic timers, generate wrap-around interrupts. */ if (pHpetTimer->u8Wrap) { u64Diff = hpetComputeDiff(pHpetTimer, u64CurTick); TMTimerSetNano(pTimer, hpetTicksToNs(pThis, u64Diff)); pHpetTimer->u8Wrap = 0; } } /* Should it really be under lock, does it really matter? */ hpetR3TimerUpdateIrq(pThis, pHpetTimer); } /* -=-=-=-=-=- DBGF Info Handlers -=-=-=-=-=- */ /** * @callback_method_impl{FNDBGFHANDLERDEV} */ static DECLCALLBACK(void) hpetR3Info(PPDMDEVINS pDevIns, PCDBGFINFOHLP pHlp, const char *pszArgs) { HPET *pThis = PDMINS_2_DATA(pDevIns, HPET *); NOREF(pszArgs); pHlp->pfnPrintf(pHlp, "HPET status:\n" " config=%016RX64 isr=%016RX64\n" " offset=%016RX64 counter=%016RX64 frequency=%08x\n" " legacy-mode=%s timer-count=%u\n", pThis->u64HpetConfig, pThis->u64Isr, pThis->u64HpetOffset, pThis->u64HpetCounter, pThis->u32Period, !!(pThis->u64HpetConfig & HPET_CFG_LEGACY) ? "on " : "off", HPET_CAP_GET_TIMERS(pThis->u32Capabilities)); pHlp->pfnPrintf(pHlp, "Timers:\n"); for (unsigned i = 0; i < RT_ELEMENTS(pThis->aTimers); i++) { pHlp->pfnPrintf(pHlp, " %d: comparator=%016RX64 period(hidden)=%016RX64 cfg=%016RX64\n", pThis->aTimers[i].idxTimer, pThis->aTimers[i].u64Cmp, pThis->aTimers[i].u64Period, pThis->aTimers[i].u64Config); } } /* -=-=-=-=-=- Saved State -=-=-=-=-=- */ /** * @callback_method_impl{FNSSMDEVLIVEEXEC} */ static DECLCALLBACK(int) hpetR3LiveExec(PPDMDEVINS pDevIns, PSSMHANDLE pSSM, uint32_t uPass) { HPET *pThis = PDMINS_2_DATA(pDevIns, HPET *); NOREF(uPass); SSMR3PutU8(pSSM, HPET_CAP_GET_TIMERS(pThis->u32Capabilities)); return VINF_SSM_DONT_CALL_AGAIN; } /** * @callback_method_impl{FNSSMDEVSAVEEXEC} */ static DECLCALLBACK(int) hpetR3SaveExec(PPDMDEVINS pDevIns, PSSMHANDLE pSSM) { HPET *pThis = PDMINS_2_DATA(pDevIns, HPET *); /* * The config. */ hpetR3LiveExec(pDevIns, pSSM, SSM_PASS_FINAL); /* * The state. */ uint32_t const cTimers = HPET_CAP_GET_TIMERS(pThis->u32Capabilities); for (uint32_t iTimer = 0; iTimer < cTimers; iTimer++) { HPETTIMER *pHpetTimer = &pThis->aTimers[iTimer]; TMR3TimerSave(pHpetTimer->pTimerR3, pSSM); SSMR3PutU8(pSSM, pHpetTimer->u8Wrap); SSMR3PutU64(pSSM, pHpetTimer->u64Config); SSMR3PutU64(pSSM, pHpetTimer->u64Cmp); SSMR3PutU64(pSSM, pHpetTimer->u64Fsb); SSMR3PutU64(pSSM, pHpetTimer->u64Period); } SSMR3PutU64(pSSM, pThis->u64HpetOffset); uint64_t u64CapPer = RT_MAKE_U64(pThis->u32Capabilities, pThis->u32Period); SSMR3PutU64(pSSM, u64CapPer); SSMR3PutU64(pSSM, pThis->u64HpetConfig); SSMR3PutU64(pSSM, pThis->u64Isr); return SSMR3PutU64(pSSM, pThis->u64HpetCounter); } /** * @callback_method_impl{FNSSMDEVLOADEXEC} */ static DECLCALLBACK(int) hpetR3LoadExec(PPDMDEVINS pDevIns, PSSMHANDLE pSSM, uint32_t uVersion, uint32_t uPass) { HPET *pThis = PDMINS_2_DATA(pDevIns, HPET *); /* * Version checks. */ if (uVersion == HPET_SAVED_STATE_VERSION_EMPTY) return VINF_SUCCESS; if (uVersion != HPET_SAVED_STATE_VERSION) return VERR_SSM_UNSUPPORTED_DATA_UNIT_VERSION; /* * The config. */ uint8_t cTimers; int rc = SSMR3GetU8(pSSM, &cTimers); AssertRCReturn(rc, rc); if (cTimers > RT_ELEMENTS(pThis->aTimers)) return SSMR3SetCfgError(pSSM, RT_SRC_POS, N_("Config mismatch - too many timers: saved=%#x config=%#x"), cTimers, RT_ELEMENTS(pThis->aTimers)); if (uPass != SSM_PASS_FINAL) return VINF_SUCCESS; /* * The state. */ for (uint32_t iTimer = 0; iTimer < cTimers; iTimer++) { HPETTIMER *pHpetTimer = &pThis->aTimers[iTimer]; TMR3TimerLoad(pHpetTimer->pTimerR3, pSSM); SSMR3GetU8(pSSM, &pHpetTimer->u8Wrap); SSMR3GetU64(pSSM, &pHpetTimer->u64Config); SSMR3GetU64(pSSM, &pHpetTimer->u64Cmp); SSMR3GetU64(pSSM, &pHpetTimer->u64Fsb); SSMR3GetU64(pSSM, &pHpetTimer->u64Period); } SSMR3GetU64(pSSM, &pThis->u64HpetOffset); uint64_t u64CapPer; SSMR3GetU64(pSSM, &u64CapPer); SSMR3GetU64(pSSM, &pThis->u64HpetConfig); SSMR3GetU64(pSSM, &pThis->u64Isr); rc = SSMR3GetU64(pSSM, &pThis->u64HpetCounter); if (RT_FAILURE(rc)) return rc; if (HPET_CAP_GET_TIMERS(RT_LO_U32(u64CapPer)) != cTimers) return SSMR3SetCfgError(pSSM, RT_SRC_POS, N_("Capabilities does not match timer count: cTimers=%#x caps=%#x"), cTimers, (unsigned)HPET_CAP_GET_TIMERS(u64CapPer)); pThis->u32Capabilities = RT_LO_U32(u64CapPer); pThis->u32Period = RT_HI_U32(u64CapPer); /* * Set the timer frequency hints. */ PDMCritSectEnter(&pThis->CritSect, VERR_IGNORED); for (uint32_t iTimer = 0; iTimer < cTimers; iTimer++) { HPETTIMER *pHpetTimer = &pThis->aTimers[iTimer]; if (TMTimerIsActive(pHpetTimer->CTX_SUFF(pTimer))) hpetTimerSetFrequencyHint(pThis, pHpetTimer); } PDMCritSectLeave(&pThis->CritSect); return VINF_SUCCESS; } /* -=-=-=-=-=- PDMDEVREG -=-=-=-=-=- */ /** * @interface_method_impl{PDMDEVREG,pfnRelocate} */ static DECLCALLBACK(void) hpetR3Relocate(PPDMDEVINS pDevIns, RTGCINTPTR offDelta) { HPET *pThis = PDMINS_2_DATA(pDevIns, HPET *); LogFlow(("hpetR3Relocate:\n")); NOREF(offDelta); pThis->pDevInsRC = PDMDEVINS_2_RCPTR(pDevIns); pThis->pHpetHlpRC = pThis->pHpetHlpR3->pfnGetRCHelpers(pDevIns); for (unsigned i = 0; i < RT_ELEMENTS(pThis->aTimers); i++) { HPETTIMER *pTm = &pThis->aTimers[i]; if (pTm->pTimerR3) pTm->pTimerRC = TMTimerRCPtr(pTm->pTimerR3); pTm->pHpetRC = PDMINS_2_DATA_RCPTR(pDevIns); } } /** * @interface_method_impl{PDMDEVREG,pfnReset} */ static DECLCALLBACK(void) hpetR3Reset(PPDMDEVINS pDevIns) { HPET *pThis = PDMINS_2_DATA(pDevIns, HPET *); LogFlow(("hpetR3Reset:\n")); /* * The timers first. */ TMTimerLock(pThis->aTimers[0].pTimerR3, VERR_IGNORED); for (unsigned i = 0; i < RT_ELEMENTS(pThis->aTimers); i++) { HPETTIMER *pHpetTimer = &pThis->aTimers[i]; Assert(pHpetTimer->idxTimer == i); TMTimerStop(pHpetTimer->pTimerR3); /* capable of periodic operations and 64-bits */ if (pThis->fIch9) pHpetTimer->u64Config = (i == 0) ? (HPET_TN_PERIODIC_CAP | HPET_TN_SIZE_CAP) : 0; else pHpetTimer->u64Config = HPET_TN_PERIODIC_CAP | HPET_TN_SIZE_CAP; /* We can do all IRQs */ uint32_t u32RoutingCap = 0xffffffff; pHpetTimer->u64Config |= ((uint64_t)u32RoutingCap) << 32; pHpetTimer->u64Period = 0; pHpetTimer->u8Wrap = 0; pHpetTimer->u64Cmp = hpetInvalidValue(pHpetTimer); } TMTimerUnlock(pThis->aTimers[0].pTimerR3); /* * The HPET state. */ pThis->u64HpetConfig = 0; pThis->u64HpetCounter = 0; pThis->u64HpetOffset = 0; /* 64-bit main counter; 3 timers supported; LegacyReplacementRoute. */ pThis->u32Capabilities = (1 << 15) /* LEG_RT_CAP - LegacyReplacementRoute capable. */ | (1 << 13) /* COUNTER_SIZE_CAP - Main counter is 64-bit capable. */ | 1; /* REV_ID - Revision, must not be 0 */ if (pThis->fIch9) /* NUM_TIM_CAP - Number of timers -1. */ pThis->u32Capabilities |= (HPET_NUM_TIMERS_ICH9 - 1) << 8; else pThis->u32Capabilities |= (HPET_NUM_TIMERS_PIIX - 1) << 8; pThis->u32Capabilities |= UINT32_C(0x80860000); /* VENDOR */ AssertCompile(HPET_NUM_TIMERS_ICH9 <= RT_ELEMENTS(pThis->aTimers)); AssertCompile(HPET_NUM_TIMERS_PIIX <= RT_ELEMENTS(pThis->aTimers)); pThis->u32Period = pThis->fIch9 ? HPET_CLK_PERIOD_ICH9 : HPET_CLK_PERIOD_PIIX; /* * Notify the PIT/RTC devices. */ if (pThis->pHpetHlpR3) pThis->pHpetHlpR3->pfnSetLegacyMode(pDevIns, false /*fActive*/); } /** * @interface_method_impl{PDMDEVREG,pfnConstruct} */ static DECLCALLBACK(int) hpetR3Construct(PPDMDEVINS pDevIns, int iInstance, PCFGMNODE pCfg) { PDMDEV_CHECK_VERSIONS_RETURN(pDevIns); HPET *pThis = PDMINS_2_DATA(pDevIns, HPET *); /* Only one HPET device now, as we use fixed MMIO region. */ Assert(iInstance == 0); /* * Initialize the device state. */ pThis->pDevInsR3 = pDevIns; pThis->pDevInsR0 = PDMDEVINS_2_R0PTR(pDevIns); pThis->pDevInsRC = PDMDEVINS_2_RCPTR(pDevIns); /* Init the HPET timers (init all regardless of how many we expose). */ for (unsigned i = 0; i < RT_ELEMENTS(pThis->aTimers); i++) { HPETTIMER *pHpetTimer = &pThis->aTimers[i]; pHpetTimer->idxTimer = i; pHpetTimer->pHpetR3 = pThis; pHpetTimer->pHpetR0 = PDMINS_2_DATA_R0PTR(pDevIns); pHpetTimer->pHpetRC = PDMINS_2_DATA_RCPTR(pDevIns); } /* * Validate and read the configuration. */ PDMDEV_VALIDATE_CONFIG_RETURN(pDevIns, "GCEnabled|R0Enabled|ICH9", ""); bool fRCEnabled; int rc = CFGMR3QueryBoolDef(pCfg, "GCEnabled", &fRCEnabled, true); if (RT_FAILURE(rc)) return PDMDEV_SET_ERROR(pDevIns, rc, N_("Configuration error: Querying \"GCEnabled\" as a bool failed")); bool fR0Enabled; rc = CFGMR3QueryBoolDef(pCfg, "R0Enabled", &fR0Enabled, true); if (RT_FAILURE(rc)) return PDMDEV_SET_ERROR(pDevIns, rc, N_("Configuration error: failed to read R0Enabled as boolean")); rc = CFGMR3QueryBoolDef(pCfg, "ICH9", &pThis->fIch9, false); if (RT_FAILURE(rc)) return PDMDEV_SET_ERROR(pDevIns, rc, N_("Configuration error: failed to read ICH9 as boolean")); /* * Create critsect and timers. * Note! We don't use the default critical section of the device, but our own. */ rc = PDMDevHlpCritSectInit(pDevIns, &pThis->CritSect, RT_SRC_POS, "HPET"); AssertRCReturn(rc, rc); rc = PDMDevHlpSetDeviceCritSect(pDevIns, PDMDevHlpCritSectGetNop(pDevIns)); AssertRCReturn(rc, rc); /* Init the HPET timers (init all regardless of how many we expose). */ for (unsigned i = 0; i < RT_ELEMENTS(pThis->aTimers); i++) { HPETTIMER *pHpetTimer = &pThis->aTimers[i]; rc = PDMDevHlpTMTimerCreate(pDevIns, TMCLOCK_VIRTUAL_SYNC, hpetR3Timer, pHpetTimer, TMTIMER_FLAGS_NO_CRIT_SECT, "HPET Timer", &pThis->aTimers[i].pTimerR3); AssertRCReturn(rc, rc); pThis->aTimers[i].pTimerRC = TMTimerRCPtr(pThis->aTimers[i].pTimerR3); pThis->aTimers[i].pTimerR0 = TMTimerR0Ptr(pThis->aTimers[i].pTimerR3); rc = TMR3TimerSetCritSect(pThis->aTimers[i].pTimerR3, &pThis->CritSect); AssertRCReturn(rc, rc); } /* * This must be done prior to registering the HPET, right? */ hpetR3Reset(pDevIns); /* * Register the HPET and get helpers. */ PDMHPETREG HpetReg; HpetReg.u32Version = PDM_HPETREG_VERSION; rc = PDMDevHlpHPETRegister(pDevIns, &HpetReg, &pThis->pHpetHlpR3); AssertRCReturn(rc, rc); /* * Register the MMIO range, PDM API requests page aligned * addresses and sizes. */ rc = PDMDevHlpMMIORegister(pDevIns, HPET_BASE, HPET_BAR_SIZE, pThis, IOMMMIO_FLAGS_READ_DWORD_QWORD | IOMMMIO_FLAGS_WRITE_ONLY_DWORD_QWORD, hpetMMIOWrite, hpetMMIORead, "HPET Memory"); AssertRCReturn(rc, rc); if (fRCEnabled) { rc = PDMDevHlpMMIORegisterRC(pDevIns, HPET_BASE, HPET_BAR_SIZE, NIL_RTRCPTR /*pvUser*/, "hpetMMIOWrite", "hpetMMIORead"); AssertRCReturn(rc, rc); pThis->pHpetHlpRC = pThis->pHpetHlpR3->pfnGetRCHelpers(pDevIns); } if (fR0Enabled) { rc = PDMDevHlpMMIORegisterR0(pDevIns, HPET_BASE, HPET_BAR_SIZE, NIL_RTR0PTR /*pvUser*/, "hpetMMIOWrite", "hpetMMIORead"); AssertRCReturn(rc, rc); pThis->pHpetHlpR0 = pThis->pHpetHlpR3->pfnGetR0Helpers(pDevIns); AssertReturn(pThis->pHpetHlpR0 != NIL_RTR0PTR, VERR_INTERNAL_ERROR); } /* Register SSM callbacks */ rc = PDMDevHlpSSMRegister3(pDevIns, HPET_SAVED_STATE_VERSION, sizeof(*pThis), hpetR3LiveExec, hpetR3SaveExec, hpetR3LoadExec); AssertRCReturn(rc, rc); /* Register an info callback. */ PDMDevHlpDBGFInfoRegister(pDevIns, "hpet", "Display HPET status. (no arguments)", hpetR3Info); return VINF_SUCCESS; } /** * The device registration structure. */ const PDMDEVREG g_DeviceHPET = { /* u32Version */ PDM_DEVREG_VERSION, /* szName */ "hpet", /* szRCMod */ "VBoxDDRC.rc", /* szR0Mod */ "VBoxDDR0.r0", /* pszDescription */ " High Precision Event Timer (HPET) Device", /* fFlags */ PDM_DEVREG_FLAGS_HOST_BITS_DEFAULT | PDM_DEVREG_FLAGS_GUEST_BITS_32_64 | PDM_DEVREG_FLAGS_PAE36 | PDM_DEVREG_FLAGS_RC | PDM_DEVREG_FLAGS_R0, /* fClass */ PDM_DEVREG_CLASS_PIT, /* cMaxInstances */ 1, /* cbInstance */ sizeof(HPET), /* pfnConstruct */ hpetR3Construct, /* pfnDestruct */ NULL, /* pfnRelocate */ hpetR3Relocate, /* pfnMemSetup */ NULL, /* pfnPowerOn */ NULL, /* pfnReset */ hpetR3Reset, /* pfnSuspend */ NULL, /* pfnResume */ NULL, /* pfnAttach */ NULL, /* pfnDetach */ NULL, /* pfnQueryInterface. */ NULL, /* pfnInitComplete */ NULL, /* pfnPowerOff */ NULL, /* pfnSoftReset */ NULL, /* u32VersionEnd */ PDM_DEVREG_VERSION }; #endif /* IN_RING3 */ #endif /* !VBOX_DEVICE_STRUCT_TESTCASE */