/* $Id: DevACPI.cpp 29250 2010-05-09 17:53:58Z vboxsync $ */ /** @file * DevACPI - Advanced Configuration and Power Interface (ACPI) Device. */ /* * Copyright (C) 2006-2009 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. */ /******************************************************************************* * Header Files * *******************************************************************************/ #define LOG_GROUP LOG_GROUP_DEV_ACPI #include #include #include #include #include #include #include #ifdef IN_RING3 # include # include # include #endif /* IN_RING3 */ #include "../Builtins.h" #ifdef LOG_ENABLED # define DEBUG_ACPI #endif #if defined(IN_RING3) && !defined(VBOX_DEVICE_STRUCT_TESTCASE) int acpiPrepareDsdt(PPDMDEVINS pDevIns, void* *ppPtr, size_t *puDsdtLen); int acpiCleanupDsdt(PPDMDEVINS pDevIns, void* pPtr); int acpiPrepareSsdt(PPDMDEVINS pDevIns, void* *ppPtr, size_t *puSsdtLen); int acpiCleanupSsdt(PPDMDEVINS pDevIns, void* pPtr); #endif /* !IN_RING3 */ /******************************************************************************* * Defined Constants And Macros * *******************************************************************************/ #define DEBUG_HEX 0x3000 #define DEBUG_CHR 0x3001 #define PM_TMR_FREQ 3579545 /* Default base for PM PIIX4 device */ #define PM_PORT_BASE 0x4000 /* Port offsets in PM device */ enum { PM1a_EVT_OFFSET = 0x00, PM1b_EVT_OFFSET = -1, /**< not supported */ PM1a_CTL_OFFSET = 0x04, PM1b_CTL_OFFSET = -1, /**< not supported */ PM2_CTL_OFFSET = -1, /**< not supported */ PM_TMR_OFFSET = 0x08, GPE0_OFFSET = 0x20, GPE1_OFFSET = -1 /**< not supported */ }; #define BAT_INDEX 0x00004040 #define BAT_DATA 0x00004044 #define SYSI_INDEX 0x00004048 #define SYSI_DATA 0x0000404c #define ACPI_RESET_BLK 0x00004050 /* PM1x status register bits */ #define TMR_STS RT_BIT(0) #define RSR1_STS (RT_BIT(1) | RT_BIT(2) | RT_BIT(3)) #define BM_STS RT_BIT(4) #define GBL_STS RT_BIT(5) #define RSR2_STS (RT_BIT(6) | RT_BIT(7)) #define PWRBTN_STS RT_BIT(8) #define SLPBTN_STS RT_BIT(9) #define RTC_STS RT_BIT(10) #define IGN_STS RT_BIT(11) #define RSR3_STS (RT_BIT(12) | RT_BIT(13) | RT_BIT(14)) #define WAK_STS RT_BIT(15) #define RSR_STS (RSR1_STS | RSR2_STS | RSR3_STS) /* PM1x enable register bits */ #define TMR_EN RT_BIT(0) #define RSR1_EN (RT_BIT(1) | RT_BIT(2) | RT_BIT(3) | RT_BIT(4)) #define GBL_EN RT_BIT(5) #define RSR2_EN (RT_BIT(6) | RT_BIT(7)) #define PWRBTN_EN RT_BIT(8) #define SLPBTN_EN RT_BIT(9) #define RTC_EN RT_BIT(10) #define RSR3_EN (RT_BIT(11) | RT_BIT(12) | RT_BIT(13) | RT_BIT(14) | RT_BIT(15)) #define RSR_EN (RSR1_EN | RSR2_EN | RSR3_EN) #define IGN_EN 0 /* PM1x control register bits */ #define SCI_EN RT_BIT(0) #define BM_RLD RT_BIT(1) #define GBL_RLS RT_BIT(2) #define RSR1_CNT (RT_BIT(3) | RT_BIT(4) | RT_BIT(5) | RT_BIT(6) | RT_BIT(7) | RT_BIT(8)) #define IGN_CNT RT_BIT(9) #define SLP_TYPx_SHIFT 10 #define SLP_TYPx_MASK 7 #define SLP_EN RT_BIT(13) #define RSR2_CNT (RT_BIT(14) | RT_BIT(15)) #define RSR_CNT (RSR1_CNT | RSR2_CNT) #define GPE0_BATTERY_INFO_CHANGED RT_BIT(0) enum { BAT_STATUS_STATE = 0x00, /**< BST battery state */ BAT_STATUS_PRESENT_RATE = 0x01, /**< BST battery present rate */ BAT_STATUS_REMAINING_CAPACITY = 0x02, /**< BST battery remaining capacity */ BAT_STATUS_PRESENT_VOLTAGE = 0x03, /**< BST battery present voltage */ BAT_INFO_UNITS = 0x04, /**< BIF power unit */ BAT_INFO_DESIGN_CAPACITY = 0x05, /**< BIF design capacity */ BAT_INFO_LAST_FULL_CHARGE_CAPACITY = 0x06, /**< BIF last full charge capacity */ BAT_INFO_TECHNOLOGY = 0x07, /**< BIF battery technology */ BAT_INFO_DESIGN_VOLTAGE = 0x08, /**< BIF design voltage */ BAT_INFO_DESIGN_CAPACITY_OF_WARNING = 0x09, /**< BIF design capacity of warning */ BAT_INFO_DESIGN_CAPACITY_OF_LOW = 0x0A, /**< BIF design capacity of low */ BAT_INFO_CAPACITY_GRANULARITY_1 = 0x0B, /**< BIF battery capacity granularity 1 */ BAT_INFO_CAPACITY_GRANULARITY_2 = 0x0C, /**< BIF battery capacity granularity 2 */ BAT_DEVICE_STATUS = 0x0D, /**< STA device status */ BAT_POWER_SOURCE = 0x0E, /**< PSR power source */ BAT_INDEX_LAST }; enum { CPU_EVENT_TYPE_ADD = 0x01, /**< Event type add */ CPU_EVENT_TYPE_REMOVE = 0x03 /**< Event type remove */ }; enum { SYSTEM_INFO_INDEX_LOW_MEMORY_LENGTH = 0, SYSTEM_INFO_INDEX_USE_IOAPIC = 1, SYSTEM_INFO_INDEX_HPET_STATUS = 2, SYSTEM_INFO_INDEX_SMC_STATUS = 3, SYSTEM_INFO_INDEX_FDC_STATUS = 4, SYSTEM_INFO_INDEX_CPU0_STATUS = 5, /**< For compatability with older saved states. */ SYSTEM_INFO_INDEX_CPU1_STATUS = 6, /**< For compatability with older saved states. */ SYSTEM_INFO_INDEX_CPU2_STATUS = 7, /**< For compatability with older saved states. */ SYSTEM_INFO_INDEX_CPU3_STATUS = 8, /**< For compatability with older saved states. */ SYSTEM_INFO_INDEX_HIGH_MEMORY_LENGTH= 9, SYSTEM_INFO_INDEX_RTC_STATUS = 10, SYSTEM_INFO_INDEX_CPU_LOCKED = 11, /**< Contains a flag indicating whether the CPU is locked or not */ SYSTEM_INFO_INDEX_CPU_LOCK_CHECK = 12, /**< For which CPU the lock status should be checked */ SYSTEM_INFO_INDEX_CPU_EVENT_TYPE = 13, /**< Type of the CPU hot-plug event */ SYSTEM_INFO_INDEX_CPU_EVENT = 14, /**< The CPU id the event is for */ SYSTEM_INFO_INDEX_NIC_ADDRESS = 15, /**< NIC PCI address, or 0 */ SYSTEM_INFO_INDEX_END = 16, SYSTEM_INFO_INDEX_INVALID = 0x80, SYSTEM_INFO_INDEX_VALID = 0x200 }; #define AC_OFFLINE 0 #define AC_ONLINE 1 #define BAT_TECH_PRIMARY 1 #define BAT_TECH_SECONDARY 2 #define STA_DEVICE_PRESENT_MASK RT_BIT(0) /**< present */ #define STA_DEVICE_ENABLED_MASK RT_BIT(1) /**< enabled and decodes its resources */ #define STA_DEVICE_SHOW_IN_UI_MASK RT_BIT(2) /**< should be shown in UI */ #define STA_DEVICE_FUNCTIONING_PROPERLY_MASK RT_BIT(3) /**< functioning properly */ #define STA_BATTERY_PRESENT_MASK RT_BIT(4) /**< the battery is present */ /******************************************************************************* * Structures and Typedefs * *******************************************************************************/ /** * The ACPI device state. */ typedef struct ACPIState { PCIDevice dev; uint16_t pm1a_en; uint16_t pm1a_sts; uint16_t pm1a_ctl; /** Number of logical CPUs in guest */ uint16_t cCpus; int64_t pm_timer_initial; PTMTIMERR3 tsR3; PTMTIMERR0 tsR0; PTMTIMERRC tsRC; uint32_t gpe0_en; uint32_t gpe0_sts; unsigned int uBatteryIndex; uint32_t au8BatteryInfo[13]; unsigned int uSystemInfoIndex; uint64_t u64RamSize; /** The number of bytes above 4GB. */ uint64_t cbRamHigh; /** The number of bytes below 4GB. */ uint32_t cbRamLow; /** Current ACPI S* state. We support S0 and S5 */ uint32_t uSleepState; uint8_t au8RSDPPage[0x1000]; /** This is a workaround for incorrect index field handling by Intels ACPICA. * The system info _INI method writes to offset 0x200. We either observe a * write request to index 0x80 (in that case we don't change the index) or a * write request to offset 0x200 (in that case we divide the index value by * 4. Note that the _STA method is sometimes called prior to the _INI method * (ACPI spec 6.3.7, _STA). See the special case for BAT_DEVICE_STATUS in * acpiBatIndexWrite() for handling this. */ uint8_t u8IndexShift; /** provide an I/O-APIC */ uint8_t u8UseIOApic; /** provide a floppy controller */ bool fUseFdc; /** If High Precision Event Timer device should be supported */ bool fUseHpet; /** If System Management Controller device should be supported */ bool fUseSmc; /** the guest handled the last power button event */ bool fPowerButtonHandled; /** If ACPI CPU device should be shown */ bool fShowCpu; /** If Real Time Clock ACPI object to be shown */ bool fShowRtc; /** I/O port address of PM device. */ RTIOPORT uPmIoPortBase; /** Flag whether the GC part of the device is enabled. */ bool fGCEnabled; /** Flag whether the R0 part of the device is enabled. */ bool fR0Enabled; /** Array of flags of attached CPUs */ VMCPUSET CpuSetAttached; /** Which CPU to check for the locked status. */ uint32_t idCpuLockCheck; /** Mask of locked CPUs (used by the guest) */ VMCPUSET CpuSetLocked; /** The CPU event type */ uint32_t u32CpuEventType; /** The CPU id affected */ uint32_t u32CpuEvent; /** Flag whether CPU hot plugging is enabled */ bool fCpuHotPlug; /** Primary NIC PCI address */ uint32_t u32NicPciAddress; /** ACPI port base interface. */ PDMIBASE IBase; /** ACPI port interface. */ PDMIACPIPORT IACPIPort; /** Pointer to the device instance. */ PPDMDEVINSR3 pDevIns; /** Pointer to the driver base interface */ R3PTRTYPE(PPDMIBASE) pDrvBase; /** Pointer to the driver connector interface */ R3PTRTYPE(PPDMIACPICONNECTOR) pDrv; /* Pointer to default PCI config read function */ R3PTRTYPE(PFNPCICONFIGREAD) pfnAcpiPciConfigRead; /* Pointer to default PCI config write function */ R3PTRTYPE(PFNPCICONFIGWRITE) pfnAcpiPciConfigWrite; } ACPIState; #pragma pack(1) /** Generic Address Structure (see ACPIspec 3.0, 5.2.3.1) */ struct ACPIGENADDR { uint8_t u8AddressSpaceId; /**< 0=sys, 1=IO, 2=PCICfg, 3=emb, 4=SMBus */ uint8_t u8RegisterBitWidth; /**< size in bits of the given register */ uint8_t u8RegisterBitOffset; /**< bit offset of register */ uint8_t u8AccessSize; /**< 1=byte, 2=word, 3=dword, 4=qword */ uint64_t u64Address; /**< 64-bit address of register */ }; AssertCompileSize(ACPIGENADDR, 12); /** Root System Description Pointer */ struct ACPITBLRSDP { uint8_t au8Signature[8]; /**< 'RSD PTR ' */ uint8_t u8Checksum; /**< checksum for the first 20 bytes */ uint8_t au8OemId[6]; /**< OEM-supplied identifier */ uint8_t u8Revision; /**< revision number, currently 2 */ #define ACPI_REVISION 2 /**< ACPI 3.0 */ uint32_t u32RSDT; /**< phys addr of RSDT */ uint32_t u32Length; /**< bytes of this table */ uint64_t u64XSDT; /**< 64-bit phys addr of XSDT */ uint8_t u8ExtChecksum; /**< checksum of entire table */ uint8_t u8Reserved[3]; /**< reserved */ }; AssertCompileSize(ACPITBLRSDP, 36); /** System Description Table Header */ struct ACPITBLHEADER { uint8_t au8Signature[4]; /**< table identifier */ uint32_t u32Length; /**< length of the table including header */ uint8_t u8Revision; /**< revision number */ uint8_t u8Checksum; /**< all fields inclusive this add to zero */ uint8_t au8OemId[6]; /**< OEM-supplied string */ uint8_t au8OemTabId[8]; /**< to identify the particular data table */ uint32_t u32OemRevision; /**< OEM-supplied revision number */ uint8_t au8CreatorId[4]; /**< ID for the ASL compiler */ uint32_t u32CreatorRev; /**< revision for the ASL compiler */ }; AssertCompileSize(ACPITBLHEADER, 36); /** Root System Description Table */ struct ACPITBLRSDT { ACPITBLHEADER header; uint32_t u32Entry[1]; /**< array of phys. addresses to other tables */ }; AssertCompileSize(ACPITBLRSDT, 40); /** Extended System Description Table */ struct ACPITBLXSDT { ACPITBLHEADER header; uint64_t u64Entry[1]; /**< array of phys. addresses to other tables */ }; AssertCompileSize(ACPITBLXSDT, 44); /** Fixed ACPI Description Table */ struct ACPITBLFADT { ACPITBLHEADER header; uint32_t u32FACS; /**< phys. address of FACS */ uint32_t u32DSDT; /**< phys. address of DSDT */ uint8_t u8IntModel; /**< was eleminated in ACPI 2.0 */ #define INT_MODEL_DUAL_PIC 1 /**< for ACPI 2+ */ #define INT_MODEL_MULTIPLE_APIC 2 uint8_t u8PreferredPMProfile; /**< preferred power management profile */ uint16_t u16SCIInt; /**< system vector the SCI is wired in 8259 mode */ #define SCI_INT 9 uint32_t u32SMICmd; /**< system port address of SMI command port */ #define SMI_CMD 0x0000442e uint8_t u8AcpiEnable; /**< SMICmd val to disable ownship of ACPIregs */ #define ACPI_ENABLE 0xa1 uint8_t u8AcpiDisable; /**< SMICmd val to re-enable ownship of ACPIregs */ #define ACPI_DISABLE 0xa0 uint8_t u8S4BIOSReq; /**< SMICmd val to enter S4BIOS state */ uint8_t u8PStateCnt; /**< SMICmd val to assume processor performance state control responsibility */ uint32_t u32PM1aEVTBLK; /**< port addr of PM1a event regs block */ uint32_t u32PM1bEVTBLK; /**< port addr of PM1b event regs block */ uint32_t u32PM1aCTLBLK; /**< port addr of PM1a control regs block */ uint32_t u32PM1bCTLBLK; /**< port addr of PM1b control regs block */ uint32_t u32PM2CTLBLK; /**< port addr of PM2 control regs block */ uint32_t u32PMTMRBLK; /**< port addr of PMTMR regs block */ uint32_t u32GPE0BLK; /**< port addr of gen-purp event 0 regs block */ uint32_t u32GPE1BLK; /**< port addr of gen-purp event 1 regs block */ uint8_t u8PM1EVTLEN; /**< bytes decoded by PM1a_EVT_BLK. >= 4 */ uint8_t u8PM1CTLLEN; /**< bytes decoded by PM1b_CNT_BLK. >= 2 */ uint8_t u8PM2CTLLEN; /**< bytes decoded by PM2_CNT_BLK. >= 1 or 0 */ uint8_t u8PMTMLEN; /**< bytes decoded by PM_TMR_BLK. ==4 */ uint8_t u8GPE0BLKLEN; /**< bytes decoded by GPE0_BLK. %2==0 */ #define GPE0_BLK_LEN 2 uint8_t u8GPE1BLKLEN; /**< bytes decoded by GPE1_BLK. %2==0 */ #define GPE1_BLK_LEN 0 uint8_t u8GPE1BASE; /**< offset of GPE1 based events */ #define GPE1_BASE 0 uint8_t u8CSTCNT; /**< SMICmd val to indicate OS supp for C states */ uint16_t u16PLVL2LAT; /**< us to enter/exit C2. >100 => unsupported */ #define P_LVL2_LAT 101 /**< C2 state not supported */ uint16_t u16PLVL3LAT; /**< us to enter/exit C3. >1000 => unsupported */ #define P_LVL3_LAT 1001 /**< C3 state not supported */ uint16_t u16FlushSize; /**< # of flush strides to read to flush dirty lines from any processors memory caches */ #define FLUSH_SIZE 0 /**< Ignored if WBVIND set in FADT_FLAGS */ uint16_t u16FlushStride; /**< cache line width */ #define FLUSH_STRIDE 0 /**< Ignored if WBVIND set in FADT_FLAGS */ uint8_t u8DutyOffset; uint8_t u8DutyWidth; uint8_t u8DayAlarm; /**< RTC CMOS RAM index of day-of-month alarm */ uint8_t u8MonAlarm; /**< RTC CMOS RAM index of month-of-year alarm */ uint8_t u8Century; /**< RTC CMOS RAM index of century */ uint16_t u16IAPCBOOTARCH; /**< IA-PC boot architecture flags */ #define IAPC_BOOT_ARCH_LEGACY_DEV RT_BIT(0) /**< legacy devices present such as LPT (COM too?) */ #define IAPC_BOOT_ARCH_8042 RT_BIT(1) /**< legacy keyboard device present */ #define IAPC_BOOT_ARCH_NO_VGA RT_BIT(2) /**< VGA not present */ uint8_t u8Must0_0; /**< must be 0 */ uint32_t u32Flags; /**< fixed feature flags */ #define FADT_FL_WBINVD RT_BIT(0) /**< emulation of WBINVD available */ #define FADT_FL_WBINVD_FLUSH RT_BIT(1) #define FADT_FL_PROC_C1 RT_BIT(2) /**< 1=C1 supported on all processors */ #define FADT_FL_P_LVL2_UP RT_BIT(3) /**< 1=C2 works on SMP and UNI systems */ #define FADT_FL_PWR_BUTTON RT_BIT(4) /**< 1=power button handled as ctrl method dev */ #define FADT_FL_SLP_BUTTON RT_BIT(5) /**< 1=sleep button handled as ctrl method dev */ #define FADT_FL_FIX_RTC RT_BIT(6) /**< 0=RTC wake status in fixed register */ #define FADT_FL_RTC_S4 RT_BIT(7) /**< 1=RTC can wake system from S4 */ #define FADT_FL_TMR_VAL_EXT RT_BIT(8) /**< 1=TMR_VAL implemented as 32 bit */ #define FADT_FL_DCK_CAP RT_BIT(9) /**< 0=system cannot support docking */ #define FADT_FL_RESET_REG_SUP RT_BIT(10) /**< 1=system supports system resets */ #define FADT_FL_SEALED_CASE RT_BIT(11) /**< 1=case is sealed */ #define FADT_FL_HEADLESS RT_BIT(12) /**< 1=system cannot detect moni/keyb/mouse */ #define FADT_FL_CPU_SW_SLP RT_BIT(13) #define FADT_FL_PCI_EXT_WAK RT_BIT(14) /**< 1=system supports PCIEXP_WAKE_STS */ #define FADT_FL_USE_PLATFORM_CLOCK RT_BIT(15) /**< 1=system has ACPI PM timer */ #define FADT_FL_S4_RTC_STS_VALID RT_BIT(16) /**< 1=RTC_STS flag is valid when waking from S4 */ #define FADT_FL_REMOVE_POWER_ON_CAPABLE RT_BIT(17) /**< 1=platform can remote power on */ #define FADT_FL_FORCE_APIC_CLUSTER_MODEL RT_BIT(18) #define FADT_FL_FORCE_APIC_PHYS_DEST_MODE RT_BIT(19) /** Start of the ACPI 2.0 extension. */ ACPIGENADDR ResetReg; /**< ext addr of reset register */ uint8_t u8ResetVal; /**< ResetReg value to reset the system */ #define ACPI_RESET_REG_VAL 0x10 uint8_t au8Must0_1[3]; /**< must be 0 */ uint64_t u64XFACS; /**< 64-bit phys address of FACS */ uint64_t u64XDSDT; /**< 64-bit phys address of DSDT */ ACPIGENADDR X_PM1aEVTBLK; /**< ext addr of PM1a event regs block */ ACPIGENADDR X_PM1bEVTBLK; /**< ext addr of PM1b event regs block */ ACPIGENADDR X_PM1aCTLBLK; /**< ext addr of PM1a control regs block */ ACPIGENADDR X_PM1bCTLBLK; /**< ext addr of PM1b control regs block */ ACPIGENADDR X_PM2CTLBLK; /**< ext addr of PM2 control regs block */ ACPIGENADDR X_PMTMRBLK; /**< ext addr of PMTMR control regs block */ ACPIGENADDR X_GPE0BLK; /**< ext addr of GPE1 regs block */ ACPIGENADDR X_GPE1BLK; /**< ext addr of GPE1 regs block */ }; AssertCompileSize(ACPITBLFADT, 244); #define ACPITBLFADT_VERSION1_SIZE RT_OFFSETOF(ACPITBLFADT, ResetReg) /** Firmware ACPI Control Structure */ struct ACPITBLFACS { uint8_t au8Signature[4]; /**< 'FACS' */ uint32_t u32Length; /**< bytes of entire FACS structure >= 64 */ uint32_t u32HWSignature; /**< systems HW signature at last boot */ uint32_t u32FWVector; /**< address of waking vector */ uint32_t u32GlobalLock; /**< global lock to sync HW/SW */ uint32_t u32Flags; /**< FACS flags */ uint64_t u64X_FWVector; /**< 64-bit waking vector */ uint8_t u8Version; /**< version of this table */ uint8_t au8Reserved[31]; /**< zero */ }; AssertCompileSize(ACPITBLFACS, 64); /** Processor Local APIC Structure */ struct ACPITBLLAPIC { uint8_t u8Type; /**< 0 = LAPIC */ uint8_t u8Length; /**< 8 */ uint8_t u8ProcId; /**< processor ID */ uint8_t u8ApicId; /**< local APIC ID */ uint32_t u32Flags; /**< Flags */ #define LAPIC_ENABLED 0x1 }; AssertCompileSize(ACPITBLLAPIC, 8); /** I/O APIC Structure */ struct ACPITBLIOAPIC { uint8_t u8Type; /**< 1 == I/O APIC */ uint8_t u8Length; /**< 12 */ uint8_t u8IOApicId; /**< I/O APIC ID */ uint8_t u8Reserved; /**< 0 */ uint32_t u32Address; /**< phys address to access I/O APIC */ uint32_t u32GSIB; /**< global system interrupt number to start */ }; AssertCompileSize(ACPITBLIOAPIC, 12); /** Interrupt Source Override Structure */ struct ACPITBLISO { uint8_t u8Type; /**< 2 == Interrupt Source Override*/ uint8_t u8Length; /**< 10 */ uint8_t u8Bus; /**< Bus */ uint8_t u8Source; /**< Bus-relative interrupt source (IRQ) */ uint32_t u32GSI; /**< Global System Interrupt */ uint16_t u16Flags; /**< MPS INTI flags Global */ }; AssertCompileSize(ACPITBLISO, 10); #define NUMBER_OF_IRQ_SOURCE_OVERRIDES 1 /** HPET Descriptor Structure */ struct ACPITBLHPET { ACPITBLHEADER aHeader; uint32_t u32Id; /**< hardware ID of event timer block [31:16] PCI vendor ID of first timer block [15] legacy replacement IRQ routing capable [14] reserved [13] COUNT_SIZE_CAP counter size [12:8] number of comparators in first timer block [7:0] hardware rev ID */ ACPIGENADDR HpetAddr; /**< lower 32-bit base address */ uint8_t u32Number; /**< sequence number starting at 0 */ uint16_t u32MinTick; /**< minimum clock ticks which can be set without lost interrupts while the counter is programmed to operate in periodic mode. Unit: clock tick. */ uint8_t u8Attributes; /**< page protextion and OEM attribute. */ }; AssertCompileSize(ACPITBLHPET, 56); # ifdef IN_RING3 /** @todo r=bird: Move this down to where it's used. */ # define PCAT_COMPAT 0x1 /**< system has also a dual-8259 setup */ /** * Multiple APIC Description Table. * * This structure looks somewhat convoluted due layout of MADT table in MP case. * There extpected to be multiple LAPIC records for each CPU, thus we cannot * use regular C structure and proxy to raw memory instead. */ class AcpiTableMADT { /** * All actual data stored in dynamically allocated memory pointed by this field. */ uint8_t *m_pbData; /** * Number of CPU entries in this MADT. */ uint32_t m_cCpus; /** * Number of interrupt overrides. */ uint32_t m_cIsos; public: /** * Address of ACPI header */ inline ACPITBLHEADER *header_addr(void) const { return (ACPITBLHEADER *)m_pbData; } /** * Address of local APIC for each CPU. Note that different CPUs address different LAPICs, * although address is the same for all of them. */ inline uint32_t *u32LAPIC_addr(void) const { return (uint32_t *)(header_addr() + 1); } /** * Address of APIC flags */ inline uint32_t *u32Flags_addr(void) const { return (uint32_t *)(u32LAPIC_addr() + 1); } /** * Address of ISO description */ inline ACPITBLISO *ISO_addr(void) const { return (ACPITBLISO *)(u32Flags_addr() + 1); } /** * Address of per-CPU LAPIC descriptions */ inline ACPITBLLAPIC *LApics_addr(void) const { return (ACPITBLLAPIC *)(ISO_addr() + m_cIsos); } /** * Address of IO APIC description */ inline ACPITBLIOAPIC *IOApic_addr(void) const { return (ACPITBLIOAPIC *)(LApics_addr() + m_cCpus); } /** * Size of MADT. * Note that this function assumes IOApic to be the last field in structure. */ inline uint32_t size(void) const { return (uint8_t *)(IOApic_addr() + 1) - (uint8_t *)header_addr(); } /** * Raw data of MADT. */ inline const uint8_t *data(void) const { return m_pbData; } /** * Size of MADT for given ACPI config, useful to compute layout. */ static uint32_t sizeFor(ACPIState *s, uint32_t cIsos) { return AcpiTableMADT(s->cCpus, cIsos).size(); } /* * Constructor, only works in Ring 3, doesn't look like a big deal. */ AcpiTableMADT(uint32_t cCpus, uint32_t cIsos) { m_cCpus = cCpus; m_cIsos = cIsos; m_pbData = NULL; /* size() uses this and gcc will complain if not initilized. */ uint32_t cb = size(); m_pbData = (uint8_t *)RTMemAllocZ(cb); } ~AcpiTableMADT() { RTMemFree(m_pbData); } }; # endif /* IN_RING3 */ #pragma pack() #ifndef VBOX_DEVICE_STRUCT_TESTCASE /* exclude the rest of the file */ /******************************************************************************* * Internal Functions * *******************************************************************************/ RT_C_DECLS_BEGIN PDMBOTHCBDECL(int) acpiPMTmrRead( PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t *pu32, unsigned cb); #ifdef IN_RING3 PDMBOTHCBDECL(int) acpiPm1aEnRead( PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t *pu32, unsigned cb); PDMBOTHCBDECL(int) acpiPM1aEnWrite( PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t u32, unsigned cb); PDMBOTHCBDECL(int) acpiPm1aStsRead( PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t *pu32, unsigned cb); PDMBOTHCBDECL(int) acpiPM1aStsWrite( PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t u32, unsigned cb); PDMBOTHCBDECL(int) acpiPm1aCtlRead( PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t *pu32, unsigned cb); PDMBOTHCBDECL(int) acpiPM1aCtlWrite( PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t u32, unsigned cb); PDMBOTHCBDECL(int) acpiSmiWrite( PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t u32, unsigned cb); PDMBOTHCBDECL(int) acpiBatIndexWrite( PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t u32, unsigned cb); PDMBOTHCBDECL(int) acpiBatDataRead( PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t *pu32, unsigned cb); PDMBOTHCBDECL(int) acpiSysInfoDataRead( PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t *pu32, unsigned cb); PDMBOTHCBDECL(int) acpiSysInfoDataWrite(PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t u32, unsigned cb); PDMBOTHCBDECL(int) acpiGpe0EnRead( PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t *pu32, unsigned cb); PDMBOTHCBDECL(int) acpiGpe0EnWrite( PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t u32, unsigned cb); PDMBOTHCBDECL(int) acpiGpe0StsRead( PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t *pu32, unsigned cb); PDMBOTHCBDECL(int) acpiGpe0StsWrite( PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t u32, unsigned cb); PDMBOTHCBDECL(int) acpiResetWrite( PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t u32, unsigned cb); # ifdef DEBUG_ACPI PDMBOTHCBDECL(int) acpiDhexWrite( PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t u32, unsigned cb); PDMBOTHCBDECL(int) acpiDchrWrite( PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t u32, unsigned cb); # endif #endif /* IN_RING3 */ RT_C_DECLS_END #ifdef IN_RING3 static RTIOPORT acpiPmPort(ACPIState* pAcpi, int32_t offset) { Assert(pAcpi->uPmIoPortBase != 0); if (offset == -1) return 0; return RTIOPORT(pAcpi->uPmIoPortBase + offset); } /* Simple acpiChecksum: all the bytes must add up to 0. */ static uint8_t acpiChecksum(const uint8_t * const data, size_t len) { uint8_t sum = 0; for (size_t i = 0; i < len; ++i) sum += data[i]; return -sum; } static void acpiPrepareHeader(ACPITBLHEADER *header, const char au8Signature[4], uint32_t u32Length, uint8_t u8Revision) { memcpy(header->au8Signature, au8Signature, 4); header->u32Length = RT_H2LE_U32(u32Length); header->u8Revision = u8Revision; memcpy(header->au8OemId, "VBOX ", 6); memcpy(header->au8OemTabId, "VBOX", 4); memcpy(header->au8OemTabId+4, au8Signature, 4); header->u32OemRevision = RT_H2LE_U32(1); memcpy(header->au8CreatorId, "ASL ", 4); header->u32CreatorRev = RT_H2LE_U32(0x61); } static void acpiWriteGenericAddr(ACPIGENADDR *g, uint8_t u8AddressSpaceId, uint8_t u8RegisterBitWidth, uint8_t u8RegisterBitOffset, uint8_t u8AccessSize, uint64_t u64Address) { g->u8AddressSpaceId = u8AddressSpaceId; g->u8RegisterBitWidth = u8RegisterBitWidth; g->u8RegisterBitOffset = u8RegisterBitOffset; g->u8AccessSize = u8AccessSize; g->u64Address = RT_H2LE_U64(u64Address); } static void acpiPhyscpy(ACPIState *s, RTGCPHYS32 dst, const void * const src, size_t size) { PDMDevHlpPhysWrite(s->pDevIns, dst, src, size); } /** Differentiated System Description Table (DSDT) */ static void acpiSetupDSDT(ACPIState *s, RTGCPHYS32 addr, void* pPtr, size_t uDsdtLen) { acpiPhyscpy(s, addr, pPtr, uDsdtLen); } /** Secondary System Description Table (SSDT) */ static void acpiSetupSSDT(ACPIState *s, RTGCPHYS32 addr, void* pPtr, size_t uSsdtLen) { acpiPhyscpy(s, addr, pPtr, uSsdtLen); } /** Firmware ACPI Control Structure (FACS) */ static void acpiSetupFACS(ACPIState *s, RTGCPHYS32 addr) { ACPITBLFACS facs; memset(&facs, 0, sizeof(facs)); memcpy(facs.au8Signature, "FACS", 4); facs.u32Length = RT_H2LE_U32(sizeof(ACPITBLFACS)); facs.u32HWSignature = RT_H2LE_U32(0); facs.u32FWVector = RT_H2LE_U32(0); facs.u32GlobalLock = RT_H2LE_U32(0); facs.u32Flags = RT_H2LE_U32(0); facs.u64X_FWVector = RT_H2LE_U64(0); facs.u8Version = 1; acpiPhyscpy(s, addr, (const uint8_t *)&facs, sizeof(facs)); } /** Fixed ACPI Description Table (FADT aka FACP) */ static void acpiSetupFADT(ACPIState *s, RTGCPHYS32 GCPhysAcpi1, RTGCPHYS32 GCPhysAcpi2, RTGCPHYS32 GCPhysFacs, RTGCPHYS GCPhysDsdt) { ACPITBLFADT fadt; /* First the ACPI version 2+ version of the structure. */ memset(&fadt, 0, sizeof(fadt)); acpiPrepareHeader(&fadt.header, "FACP", sizeof(fadt), 4); fadt.u32FACS = RT_H2LE_U32(GCPhysFacs); fadt.u32DSDT = RT_H2LE_U32(GCPhysDsdt); fadt.u8IntModel = 0; /* dropped from the ACPI 2.0 spec. */ fadt.u8PreferredPMProfile = 0; /* unspecified */ fadt.u16SCIInt = RT_H2LE_U16(SCI_INT); fadt.u32SMICmd = RT_H2LE_U32(SMI_CMD); fadt.u8AcpiEnable = ACPI_ENABLE; fadt.u8AcpiDisable = ACPI_DISABLE; fadt.u8S4BIOSReq = 0; fadt.u8PStateCnt = 0; fadt.u32PM1aEVTBLK = RT_H2LE_U32(acpiPmPort(s, PM1a_EVT_OFFSET)); fadt.u32PM1bEVTBLK = RT_H2LE_U32(acpiPmPort(s, PM1b_EVT_OFFSET)); fadt.u32PM1aCTLBLK = RT_H2LE_U32(acpiPmPort(s, PM1a_CTL_OFFSET)); fadt.u32PM1bCTLBLK = RT_H2LE_U32(acpiPmPort(s, PM1b_CTL_OFFSET)); fadt.u32PM2CTLBLK = RT_H2LE_U32(acpiPmPort(s, PM2_CTL_OFFSET)); fadt.u32PMTMRBLK = RT_H2LE_U32(acpiPmPort(s, PM_TMR_OFFSET)); fadt.u32GPE0BLK = RT_H2LE_U32(acpiPmPort(s, GPE0_OFFSET)); fadt.u32GPE1BLK = RT_H2LE_U32(acpiPmPort(s, GPE1_OFFSET)); fadt.u8PM1EVTLEN = 4; fadt.u8PM1CTLLEN = 2; fadt.u8PM2CTLLEN = 0; fadt.u8PMTMLEN = 4; fadt.u8GPE0BLKLEN = GPE0_BLK_LEN; fadt.u8GPE1BLKLEN = GPE1_BLK_LEN; fadt.u8GPE1BASE = GPE1_BASE; fadt.u8CSTCNT = 0; fadt.u16PLVL2LAT = RT_H2LE_U16(P_LVL2_LAT); fadt.u16PLVL3LAT = RT_H2LE_U16(P_LVL3_LAT); fadt.u16FlushSize = RT_H2LE_U16(FLUSH_SIZE); fadt.u16FlushStride = RT_H2LE_U16(FLUSH_STRIDE); fadt.u8DutyOffset = 0; fadt.u8DutyWidth = 0; fadt.u8DayAlarm = 0; fadt.u8MonAlarm = 0; fadt.u8Century = 0; fadt.u16IAPCBOOTARCH = RT_H2LE_U16(IAPC_BOOT_ARCH_LEGACY_DEV | IAPC_BOOT_ARCH_8042); /** @note WBINVD is required for ACPI versions newer than 1.0 */ fadt.u32Flags = RT_H2LE_U32( FADT_FL_WBINVD | FADT_FL_FIX_RTC | FADT_FL_TMR_VAL_EXT | FADT_FL_RESET_REG_SUP); /* We have to force physical APIC mode or Linux can't use more than 8 CPUs */ if (s->fCpuHotPlug) fadt.u32Flags |= RT_H2LE_U32(FADT_FL_FORCE_APIC_PHYS_DEST_MODE); acpiWriteGenericAddr(&fadt.ResetReg, 1, 8, 0, 1, ACPI_RESET_BLK); fadt.u8ResetVal = ACPI_RESET_REG_VAL; fadt.u64XFACS = RT_H2LE_U64((uint64_t)GCPhysFacs); fadt.u64XDSDT = RT_H2LE_U64((uint64_t)GCPhysDsdt); acpiWriteGenericAddr(&fadt.X_PM1aEVTBLK, 1, 32, 0, 2, acpiPmPort(s, PM1a_EVT_OFFSET)); acpiWriteGenericAddr(&fadt.X_PM1bEVTBLK, 0, 0, 0, 0, acpiPmPort(s, PM1b_EVT_OFFSET)); acpiWriteGenericAddr(&fadt.X_PM1aCTLBLK, 1, 16, 0, 2, acpiPmPort(s, PM1a_CTL_OFFSET)); acpiWriteGenericAddr(&fadt.X_PM1bCTLBLK, 0, 0, 0, 0, acpiPmPort(s, PM1b_CTL_OFFSET)); acpiWriteGenericAddr(&fadt.X_PM2CTLBLK, 0, 0, 0, 0, acpiPmPort(s, PM2_CTL_OFFSET)); acpiWriteGenericAddr(&fadt.X_PMTMRBLK, 1, 32, 0, 3, acpiPmPort(s, PM_TMR_OFFSET)); acpiWriteGenericAddr(&fadt.X_GPE0BLK, 1, 16, 0, 1, acpiPmPort(s, GPE0_OFFSET)); acpiWriteGenericAddr(&fadt.X_GPE1BLK, 0, 0, 0, 0, acpiPmPort(s, GPE1_OFFSET)); fadt.header.u8Checksum = acpiChecksum((uint8_t *)&fadt, sizeof(fadt)); acpiPhyscpy(s, GCPhysAcpi2, &fadt, sizeof(fadt)); /* Now the ACPI 1.0 version. */ fadt.header.u32Length = ACPITBLFADT_VERSION1_SIZE; fadt.u8IntModel = INT_MODEL_DUAL_PIC; fadt.header.u8Checksum = 0; /* Must be zeroed before recalculating checksum! */ fadt.header.u8Checksum = acpiChecksum((uint8_t *)&fadt, ACPITBLFADT_VERSION1_SIZE); acpiPhyscpy(s, GCPhysAcpi1, &fadt, ACPITBLFADT_VERSION1_SIZE); } /** * Root System Description Table. * The RSDT and XSDT tables are basically identical. The only difference is 32 vs 64 bits * addresses for description headers. RSDT is for ACPI 1.0. XSDT for ACPI 2.0 and up. */ static int acpiSetupRSDT(ACPIState *s, RTGCPHYS32 addr, unsigned int nb_entries, uint32_t *addrs) { ACPITBLRSDT *rsdt; const size_t size = sizeof(ACPITBLHEADER) + nb_entries * sizeof(rsdt->u32Entry[0]); rsdt = (ACPITBLRSDT*)RTMemAllocZ(size); if (!rsdt) return PDMDEV_SET_ERROR(s->pDevIns, VERR_NO_TMP_MEMORY, N_("Cannot allocate RSDT")); acpiPrepareHeader(&rsdt->header, "RSDT", (uint32_t)size, 1); for (unsigned int i = 0; i < nb_entries; ++i) { rsdt->u32Entry[i] = RT_H2LE_U32(addrs[i]); Log(("Setup RSDT: [%d] = %x\n", i, rsdt->u32Entry[i])); } rsdt->header.u8Checksum = acpiChecksum((uint8_t*)rsdt, size); acpiPhyscpy(s, addr, rsdt, size); RTMemFree(rsdt); return VINF_SUCCESS; } /** Extended System Description Table. */ static int acpiSetupXSDT(ACPIState *s, RTGCPHYS32 addr, unsigned int nb_entries, uint32_t *addrs) { ACPITBLXSDT *xsdt; const size_t size = sizeof(ACPITBLHEADER) + nb_entries * sizeof(xsdt->u64Entry[0]); xsdt = (ACPITBLXSDT*)RTMemAllocZ(size); if (!xsdt) return VERR_NO_TMP_MEMORY; acpiPrepareHeader(&xsdt->header, "XSDT", (uint32_t)size, 1 /* according to ACPI 3.0 specs */); for (unsigned int i = 0; i < nb_entries; ++i) { xsdt->u64Entry[i] = RT_H2LE_U64((uint64_t)addrs[i]); Log(("Setup XSDT: [%d] = %RX64\n", i, xsdt->u64Entry[i])); } xsdt->header.u8Checksum = acpiChecksum((uint8_t*)xsdt, size); acpiPhyscpy(s, addr, xsdt, size); RTMemFree(xsdt); return VINF_SUCCESS; } /** Root System Description Pointer (RSDP) */ static void acpiSetupRSDP(ACPITBLRSDP *rsdp, RTGCPHYS32 GCPhysRsdt, RTGCPHYS GCPhysXsdt) { memset(rsdp, 0, sizeof(*rsdp)); /* ACPI 1.0 part (RSDT */ memcpy(rsdp->au8Signature, "RSD PTR ", 8); memcpy(rsdp->au8OemId, "VBOX ", 6); rsdp->u8Revision = ACPI_REVISION; rsdp->u32RSDT = RT_H2LE_U32(GCPhysRsdt); rsdp->u8Checksum = acpiChecksum((uint8_t*)rsdp, RT_OFFSETOF(ACPITBLRSDP, u32Length)); /* ACPI 2.0 part (XSDT) */ rsdp->u32Length = RT_H2LE_U32(sizeof(ACPITBLRSDP)); rsdp->u64XSDT = RT_H2LE_U64(GCPhysXsdt); rsdp->u8ExtChecksum = acpiChecksum((uint8_t*)rsdp, sizeof(ACPITBLRSDP)); } /** * Multiple APIC Description Table. * * @note APIC without IO-APIC hangs Windows Vista therefore we setup both * * @todo All hardcoded, should set this up based on the actual VM config!!!!! */ static void acpiSetupMADT(ACPIState *s, RTGCPHYS32 addr) { uint16_t cpus = s->cCpus; AcpiTableMADT madt(cpus, 1 /* one source override */ ); acpiPrepareHeader(madt.header_addr(), "APIC", madt.size(), 2); *madt.u32LAPIC_addr() = RT_H2LE_U32(0xfee00000); *madt.u32Flags_addr() = RT_H2LE_U32(PCAT_COMPAT); /* LAPICs records */ ACPITBLLAPIC* lapic = madt.LApics_addr(); for (uint16_t i = 0; i < cpus; i++) { lapic->u8Type = 0; lapic->u8Length = sizeof(ACPITBLLAPIC); lapic->u8ProcId = i; /** Must match numbering convention in MPTABLES */ lapic->u8ApicId = i; lapic->u32Flags = VMCPUSET_IS_PRESENT(&s->CpuSetAttached, i) ? RT_H2LE_U32(LAPIC_ENABLED) : 0; lapic++; } /* IO-APIC record */ ACPITBLIOAPIC* ioapic = madt.IOApic_addr(); ioapic->u8Type = 1; ioapic->u8Length = sizeof(ACPITBLIOAPIC); /** Must match MP tables ID */ ioapic->u8IOApicId = cpus; ioapic->u8Reserved = 0; ioapic->u32Address = RT_H2LE_U32(0xfec00000); ioapic->u32GSIB = RT_H2LE_U32(0); /* Interrupt Source Overrides */ /* If changing, also update PDMIsaSetIrq() and MPS */ ACPITBLISO* isos = madt.ISO_addr(); isos[0].u8Type = 2; isos[0].u8Length = sizeof(ACPITBLISO); isos[0].u8Bus = 0; /* Must be 0 */ isos[0].u8Source = 0; /* IRQ0 */ isos[0].u32GSI = 2; /* connected to pin 2 */ isos[0].u16Flags = 0; /* conform to the bus */ Assert(NUMBER_OF_IRQ_SOURCE_OVERRIDES == 1); madt.header_addr()->u8Checksum = acpiChecksum(madt.data(), madt.size()); acpiPhyscpy(s, addr, madt.data(), madt.size()); } /** High Performance Event Timer (HPET) descriptor */ static void acpiSetupHPET(ACPIState *s, RTGCPHYS32 addr) { ACPITBLHPET hpet; memset(&hpet, 0, sizeof(hpet)); acpiPrepareHeader(&hpet.aHeader, "HPET", sizeof(hpet), 1); /* Keep base address consistent with appropriate DSDT entry (vbox.dsl) */ acpiWriteGenericAddr(&hpet.HpetAddr, 0 /* Memory address space */, 64 /* Register bit width */, 0 /* Bit offset */, 0, /* Register access size, is it correct? */ 0xfed00000 /* Address */); hpet.u32Id = 0x8086a201; /* must match what HPET ID returns, is it correct ? */ hpet.u32Number = 0; hpet.u32MinTick = 4096; hpet.u8Attributes = 0; hpet.aHeader.u8Checksum = acpiChecksum((uint8_t *)&hpet, sizeof(hpet)); acpiPhyscpy(s, addr, (const uint8_t *)&hpet, sizeof(hpet)); } /* SCI IRQ */ DECLINLINE(void) acpiSetIrq(ACPIState *s, int level) { if (s->pm1a_ctl & SCI_EN) PDMDevHlpPCISetIrq(s->pDevIns, -1, level); } DECLINLINE(uint32_t) pm1a_pure_en(uint32_t en) { return en & ~(RSR_EN | IGN_EN); } DECLINLINE(uint32_t) pm1a_pure_sts(uint32_t sts) { return sts & ~(RSR_STS | IGN_STS); } DECLINLINE(int) pm1a_level(ACPIState *s) { return (pm1a_pure_en(s->pm1a_en) & pm1a_pure_sts(s->pm1a_sts)) != 0; } DECLINLINE(int) gpe0_level(ACPIState *s) { return (s->gpe0_en & s->gpe0_sts) != 0; } static void update_pm1a(ACPIState *s, uint32_t sts, uint32_t en) { int old_level, new_level; if (gpe0_level(s)) return; old_level = pm1a_level(s); new_level = (pm1a_pure_en(en) & pm1a_pure_sts(sts)) != 0; s->pm1a_en = en; s->pm1a_sts = sts; if (new_level != old_level) acpiSetIrq(s, new_level); } static void update_gpe0(ACPIState *s, uint32_t sts, uint32_t en) { int old_level, new_level; if (pm1a_level(s)) return; old_level = (s->gpe0_en & s->gpe0_sts) != 0; new_level = (en & sts) != 0; s->gpe0_en = en; s->gpe0_sts = sts; if (new_level != old_level) acpiSetIrq(s, new_level); } static int acpiPowerDown(ACPIState *s) { int rc = PDMDevHlpVMPowerOff(s->pDevIns); if (RT_FAILURE(rc)) AssertMsgFailed(("Could not power down the VM. rc = %Rrc\n", rc)); return rc; } /** Converts a ACPI port interface pointer to an ACPI state pointer. */ #define IACPIPORT_2_ACPISTATE(pInterface) ( (ACPIState*)((uintptr_t)pInterface - RT_OFFSETOF(ACPIState, IACPIPort)) ) /** * Send an ACPI power off event. * * @returns VBox status code * @param pInterface Pointer to the interface structure containing the called function pointer. */ static DECLCALLBACK(int) acpiPowerButtonPress(PPDMIACPIPORT pInterface) { ACPIState *s = IACPIPORT_2_ACPISTATE(pInterface); s->fPowerButtonHandled = false; update_pm1a(s, s->pm1a_sts | PWRBTN_STS, s->pm1a_en); return VINF_SUCCESS; } /** * Check if the ACPI power button event was handled. * * @returns VBox status code * @param pInterface Pointer to the interface structure containing the called function pointer. * @param pfHandled Return true if the power button event was handled by the guest. */ static DECLCALLBACK(int) acpiGetPowerButtonHandled(PPDMIACPIPORT pInterface, bool *pfHandled) { ACPIState *s = IACPIPORT_2_ACPISTATE(pInterface); *pfHandled = s->fPowerButtonHandled; return VINF_SUCCESS; } /** * Check if the Guest entered into G0 (working) or G1 (sleeping). * * @returns VBox status code * @param pInterface Pointer to the interface structure containing the called function pointer. * @param pfEntered Return true if the guest entered the ACPI mode. */ static DECLCALLBACK(int) acpiGetGuestEnteredACPIMode(PPDMIACPIPORT pInterface, bool *pfEntered) { ACPIState *s = IACPIPORT_2_ACPISTATE(pInterface); *pfEntered = (s->pm1a_ctl & SCI_EN) != 0; return VINF_SUCCESS; } static DECLCALLBACK(int) acpiGetCpuStatus(PPDMIACPIPORT pInterface, unsigned uCpu, bool *pfLocked) { ACPIState *s = IACPIPORT_2_ACPISTATE(pInterface); *pfLocked = VMCPUSET_IS_PRESENT(&s->CpuSetLocked, uCpu); return VINF_SUCCESS; } /** * Send an ACPI sleep button event. * * @returns VBox status code * @param pInterface Pointer to the interface structure containing the called function pointer. */ static DECLCALLBACK(int) acpiSleepButtonPress(PPDMIACPIPORT pInterface) { ACPIState *s = IACPIPORT_2_ACPISTATE(pInterface); update_pm1a(s, s->pm1a_sts | SLPBTN_STS, s->pm1a_en); return VINF_SUCCESS; } /* PM1a_EVT_BLK enable */ static uint32_t acpiPm1aEnReadw(ACPIState *s, uint32_t addr) { uint16_t val = s->pm1a_en; Log(("acpi: acpiPm1aEnReadw -> %#x\n", val)); return val; } static void acpiPM1aEnWritew(ACPIState *s, uint32_t addr, uint32_t val) { Log(("acpi: acpiPM1aEnWritew <- %#x (%#x)\n", val, val & ~(RSR_EN | IGN_EN))); val &= ~(RSR_EN | IGN_EN); update_pm1a(s, s->pm1a_sts, val); } /* PM1a_EVT_BLK status */ static uint32_t acpiPm1aStsReadw(ACPIState *s, uint32_t addr) { uint16_t val = s->pm1a_sts; Log(("acpi: acpiPm1aStsReadw -> %#x\n", val)); return val; } static void acpiPM1aStsWritew(ACPIState *s, uint32_t addr, uint32_t val) { Log(("acpi: acpiPM1aStsWritew <- %#x (%#x)\n", val, val & ~(RSR_STS | IGN_STS))); if (val & PWRBTN_STS) s->fPowerButtonHandled = true; /* Remember that the guest handled the last power button event */ val = s->pm1a_sts & ~(val & ~(RSR_STS | IGN_STS)); update_pm1a(s, val, s->pm1a_en); } /* PM1a_CTL_BLK */ static uint32_t acpiPm1aCtlReadw(ACPIState *s, uint32_t addr) { uint16_t val = s->pm1a_ctl; Log(("acpi: acpiPm1aCtlReadw -> %#x\n", val)); return val; } static int acpiPM1aCtlWritew(ACPIState *s, uint32_t addr, uint32_t val) { uint32_t uSleepState; Log(("acpi: acpiPM1aCtlWritew <- %#x (%#x)\n", val, val & ~(RSR_CNT | IGN_CNT))); s->pm1a_ctl = val & ~(RSR_CNT | IGN_CNT); uSleepState = (s->pm1a_ctl >> SLP_TYPx_SHIFT) & SLP_TYPx_MASK; if (uSleepState != s->uSleepState) { s->uSleepState = uSleepState; switch (uSleepState) { case 0x00: /* S0 */ break; case 0x05: /* S5 */ LogRel(("Entering S5 (power down)\n")); return acpiPowerDown(s); default: AssertMsgFailed(("Unknown sleep state %#x\n", uSleepState)); break; } } return VINF_SUCCESS; } /* GPE0_BLK */ static uint32_t acpiGpe0EnReadb(ACPIState *s, uint32_t addr) { uint8_t val = s->gpe0_en; Log(("acpi: acpiGpe0EnReadl -> %#x\n", val)); return val; } static void acpiGpe0EnWriteb(ACPIState *s, uint32_t addr, uint32_t val) { Log(("acpi: acpiGpe0EnWritel <- %#x\n", val)); update_gpe0(s, s->gpe0_sts, val); } static uint32_t acpiGpe0StsReadb(ACPIState *s, uint32_t addr) { uint8_t val = s->gpe0_sts; Log(("acpi: acpiGpe0StsReadl -> %#x\n", val)); return val; } static void acpiGpe0StsWriteb(ACPIState *s, uint32_t addr, uint32_t val) { val = s->gpe0_sts & ~val; update_gpe0(s, val, s->gpe0_en); Log(("acpi: acpiGpe0StsWritel <- %#x\n", val)); } static int acpiResetWriteU8(ACPIState *s, uint32_t addr, uint32_t val) { int rc = VINF_SUCCESS; Log(("ACPI: acpiResetWriteU8: %x %x\n", addr, val)); if (val == ACPI_RESET_REG_VAL) { # ifndef IN_RING3 rc = VINF_IOM_HC_IOPORT_WRITE; # else /* IN_RING3 */ rc = PDMDevHlpVMReset(s->pDevIns); # endif /* !IN_RING3 */ } return rc; } /* SMI */ static void acpiSmiWriteU8(ACPIState *s, uint32_t addr, uint32_t val) { Log(("acpi: acpiSmiWriteU8 %#x\n", val)); if (val == ACPI_ENABLE) s->pm1a_ctl |= SCI_EN; else if (val == ACPI_DISABLE) s->pm1a_ctl &= ~SCI_EN; else Log(("acpi: acpiSmiWriteU8 %#x <- unknown value\n", val)); } static uint32_t find_rsdp_space(void) { return 0xe0000; } static int acpiPMTimerReset(ACPIState *s) { uint64_t interval, freq; freq = TMTimerGetFreq(s->CTX_SUFF(ts)); interval = ASMMultU64ByU32DivByU32(0xffffffff, freq, PM_TMR_FREQ); Log(("interval = %RU64\n", interval)); TMTimerSet(s->CTX_SUFF(ts), TMTimerGet(s->CTX_SUFF(ts)) + interval); return VINF_SUCCESS; } static DECLCALLBACK(void) acpiTimer(PPDMDEVINS pDevIns, PTMTIMER pTimer, void *pvUser) { ACPIState *s = (ACPIState *)pvUser; Log(("acpi: pm timer sts %#x (%d), en %#x (%d)\n", s->pm1a_sts, (s->pm1a_sts & TMR_STS) != 0, s->pm1a_en, (s->pm1a_en & TMR_EN) != 0)); update_pm1a(s, s->pm1a_sts | TMR_STS, s->pm1a_en); acpiPMTimerReset(s); } /** * _BST method. */ static int acpiFetchBatteryStatus(ACPIState *s) { uint32_t *p = s->au8BatteryInfo; bool fPresent; /* battery present? */ PDMACPIBATCAPACITY hostRemainingCapacity; /* 0..100 */ PDMACPIBATSTATE hostBatteryState; /* bitfield */ uint32_t hostPresentRate; /* 0..1000 */ int rc; if (!s->pDrv) return VINF_SUCCESS; rc = s->pDrv->pfnQueryBatteryStatus(s->pDrv, &fPresent, &hostRemainingCapacity, &hostBatteryState, &hostPresentRate); AssertRC(rc); /* default values */ p[BAT_STATUS_STATE] = hostBatteryState; p[BAT_STATUS_PRESENT_RATE] = hostPresentRate == ~0U ? 0xFFFFFFFF : hostPresentRate * 50; /* mW */ p[BAT_STATUS_REMAINING_CAPACITY] = 50000; /* mWh */ p[BAT_STATUS_PRESENT_VOLTAGE] = 10000; /* mV */ /* did we get a valid battery state? */ if (hostRemainingCapacity != PDM_ACPI_BAT_CAPACITY_UNKNOWN) p[BAT_STATUS_REMAINING_CAPACITY] = hostRemainingCapacity * 500; /* mWh */ if (hostBatteryState == PDM_ACPI_BAT_STATE_CHARGED) p[BAT_STATUS_PRESENT_RATE] = 0; /* mV */ return VINF_SUCCESS; } /** * _BIF method. */ static int acpiFetchBatteryInfo(ACPIState *s) { uint32_t *p = s->au8BatteryInfo; p[BAT_INFO_UNITS] = 0; /* mWh */ p[BAT_INFO_DESIGN_CAPACITY] = 50000; /* mWh */ p[BAT_INFO_LAST_FULL_CHARGE_CAPACITY] = 50000; /* mWh */ p[BAT_INFO_TECHNOLOGY] = BAT_TECH_PRIMARY; p[BAT_INFO_DESIGN_VOLTAGE] = 10000; /* mV */ p[BAT_INFO_DESIGN_CAPACITY_OF_WARNING] = 100; /* mWh */ p[BAT_INFO_DESIGN_CAPACITY_OF_LOW] = 50; /* mWh */ p[BAT_INFO_CAPACITY_GRANULARITY_1] = 1; /* mWh */ p[BAT_INFO_CAPACITY_GRANULARITY_2] = 1; /* mWh */ return VINF_SUCCESS; } /** * _STA method. */ static uint32_t acpiGetBatteryDeviceStatus(ACPIState *s) { bool fPresent; /* battery present? */ PDMACPIBATCAPACITY hostRemainingCapacity; /* 0..100 */ PDMACPIBATSTATE hostBatteryState; /* bitfield */ uint32_t hostPresentRate; /* 0..1000 */ int rc; if (!s->pDrv) return 0; rc = s->pDrv->pfnQueryBatteryStatus(s->pDrv, &fPresent, &hostRemainingCapacity, &hostBatteryState, &hostPresentRate); AssertRC(rc); return fPresent ? STA_DEVICE_PRESENT_MASK /* present */ | STA_DEVICE_ENABLED_MASK /* enabled and decodes its resources */ | STA_DEVICE_SHOW_IN_UI_MASK /* should be shown in UI */ | STA_DEVICE_FUNCTIONING_PROPERLY_MASK /* functioning properly */ | STA_BATTERY_PRESENT_MASK /* battery is present */ : 0; /* device not present */ } static uint32_t acpiGetPowerSource(ACPIState *s) { PDMACPIPOWERSOURCE ps; /* query the current power source from the host driver */ if (!s->pDrv) return AC_ONLINE; int rc = s->pDrv->pfnQueryPowerSource(s->pDrv, &ps); AssertRC(rc); return ps == PDM_ACPI_POWER_SOURCE_BATTERY ? AC_OFFLINE : AC_ONLINE; } PDMBOTHCBDECL(int) acpiBatIndexWrite(PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t u32, unsigned cb) { ACPIState *s = (ACPIState *)pvUser; switch (cb) { case 4: u32 >>= s->u8IndexShift; /* see comment at the declaration of u8IndexShift */ if (s->u8IndexShift == 0 && u32 == (BAT_DEVICE_STATUS << 2)) { s->u8IndexShift = 2; u32 >>= 2; } Assert(u32 < BAT_INDEX_LAST); s->uBatteryIndex = u32; break; default: AssertMsgFailed(("Port=%#x cb=%d u32=%#x\n", Port, cb, u32)); break; } return VINF_SUCCESS; } PDMBOTHCBDECL(int) acpiBatDataRead(PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t *pu32, unsigned cb) { ACPIState *s = (ACPIState *)pvUser; switch (cb) { case 4: switch (s->uBatteryIndex) { case BAT_STATUS_STATE: acpiFetchBatteryStatus(s); case BAT_STATUS_PRESENT_RATE: case BAT_STATUS_REMAINING_CAPACITY: case BAT_STATUS_PRESENT_VOLTAGE: *pu32 = s->au8BatteryInfo[s->uBatteryIndex]; break; case BAT_INFO_UNITS: acpiFetchBatteryInfo(s); case BAT_INFO_DESIGN_CAPACITY: case BAT_INFO_LAST_FULL_CHARGE_CAPACITY: case BAT_INFO_TECHNOLOGY: case BAT_INFO_DESIGN_VOLTAGE: case BAT_INFO_DESIGN_CAPACITY_OF_WARNING: case BAT_INFO_DESIGN_CAPACITY_OF_LOW: case BAT_INFO_CAPACITY_GRANULARITY_1: case BAT_INFO_CAPACITY_GRANULARITY_2: *pu32 = s->au8BatteryInfo[s->uBatteryIndex]; break; case BAT_DEVICE_STATUS: *pu32 = acpiGetBatteryDeviceStatus(s); break; case BAT_POWER_SOURCE: *pu32 = acpiGetPowerSource(s); break; default: AssertMsgFailed(("Invalid battery index %d\n", s->uBatteryIndex)); break; } break; default: return VERR_IOM_IOPORT_UNUSED; } return VINF_SUCCESS; } PDMBOTHCBDECL(int) acpiSysInfoIndexWrite(PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t u32, unsigned cb) { ACPIState *s = (ACPIState *)pvUser; Log(("system_index = %d, %d\n", u32, u32 >> 2)); switch (cb) { case 4: if (u32 == SYSTEM_INFO_INDEX_VALID || u32 == SYSTEM_INFO_INDEX_INVALID) s->uSystemInfoIndex = u32; else { /* see comment at the declaration of u8IndexShift */ if (s->u8IndexShift == 0) { if (((u32 >> 2) < SYSTEM_INFO_INDEX_END) && ((u32 & 0x3)) == 0) { s->u8IndexShift = 2; } } u32 >>= s->u8IndexShift; Assert(u32 < SYSTEM_INFO_INDEX_END); s->uSystemInfoIndex = u32; } break; default: AssertMsgFailed(("Port=%#x cb=%d u32=%#x\n", Port, cb, u32)); break; } return VINF_SUCCESS; } PDMBOTHCBDECL(int) acpiSysInfoDataRead(PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t *pu32, unsigned cb) { ACPIState *s = (ACPIState *)pvUser; switch (cb) { case 4: switch (s->uSystemInfoIndex) { case SYSTEM_INFO_INDEX_LOW_MEMORY_LENGTH: *pu32 = s->cbRamLow; break; case SYSTEM_INFO_INDEX_HIGH_MEMORY_LENGTH: *pu32 = s->cbRamHigh >> 16; /* 64KB units */ Assert(((uint64_t)*pu32 << 16) == s->cbRamHigh); break; case SYSTEM_INFO_INDEX_USE_IOAPIC: *pu32 = s->u8UseIOApic; break; case SYSTEM_INFO_INDEX_HPET_STATUS: *pu32 = s->fUseHpet ? ( STA_DEVICE_PRESENT_MASK | STA_DEVICE_ENABLED_MASK | STA_DEVICE_SHOW_IN_UI_MASK | STA_DEVICE_FUNCTIONING_PROPERLY_MASK) : 0; break; case SYSTEM_INFO_INDEX_SMC_STATUS: *pu32 = s->fUseSmc ? ( STA_DEVICE_PRESENT_MASK | STA_DEVICE_ENABLED_MASK /* no need to show this device in the UI */ | STA_DEVICE_FUNCTIONING_PROPERLY_MASK) : 0; break; case SYSTEM_INFO_INDEX_FDC_STATUS: *pu32 = s->fUseFdc ? ( STA_DEVICE_PRESENT_MASK | STA_DEVICE_ENABLED_MASK | STA_DEVICE_SHOW_IN_UI_MASK | STA_DEVICE_FUNCTIONING_PROPERLY_MASK) : 0; break; case SYSTEM_INFO_INDEX_NIC_ADDRESS: *pu32 = s->u32NicPciAddress; break; /* This is only for compatability with older saved states that may include ACPI code that read these values. Legacy is a wonderful thing, isn't it? :-) */ case SYSTEM_INFO_INDEX_CPU0_STATUS: case SYSTEM_INFO_INDEX_CPU1_STATUS: case SYSTEM_INFO_INDEX_CPU2_STATUS: case SYSTEM_INFO_INDEX_CPU3_STATUS: *pu32 = ( s->fShowCpu && s->uSystemInfoIndex - SYSTEM_INFO_INDEX_CPU0_STATUS < s->cCpus && VMCPUSET_IS_PRESENT(&s->CpuSetAttached, s->uSystemInfoIndex - SYSTEM_INFO_INDEX_CPU0_STATUS)) ? ( STA_DEVICE_PRESENT_MASK | STA_DEVICE_ENABLED_MASK | STA_DEVICE_SHOW_IN_UI_MASK | STA_DEVICE_FUNCTIONING_PROPERLY_MASK) : 0; break; case SYSTEM_INFO_INDEX_RTC_STATUS: *pu32 = s->fShowRtc ? ( STA_DEVICE_PRESENT_MASK | STA_DEVICE_ENABLED_MASK | STA_DEVICE_SHOW_IN_UI_MASK | STA_DEVICE_FUNCTIONING_PROPERLY_MASK) : 0; break; case SYSTEM_INFO_INDEX_CPU_LOCKED: { if (s->idCpuLockCheck < VMM_MAX_CPU_COUNT) { *pu32 = VMCPUSET_IS_PRESENT(&s->CpuSetLocked, s->idCpuLockCheck); s->idCpuLockCheck = UINT32_C(0xffffffff); /* Make the entry invalid */ } else { AssertMsgFailed(("ACPI: CPU lock check protocol violation\n")); /* Always return locked status just to be safe */ *pu32 = 1; } break; } case SYSTEM_INFO_INDEX_CPU_EVENT_TYPE: *pu32 = s->u32CpuEventType; break; case SYSTEM_INFO_INDEX_CPU_EVENT: *pu32 = s->u32CpuEvent; break; /* Solaris 9 tries to read from this index */ case SYSTEM_INFO_INDEX_INVALID: *pu32 = 0; break; default: AssertMsgFailed(("Invalid system info index %d\n", s->uSystemInfoIndex)); break; } break; default: return VERR_IOM_IOPORT_UNUSED; } Log(("index %d val %d\n", s->uSystemInfoIndex, *pu32)); return VINF_SUCCESS; } PDMBOTHCBDECL(int) acpiSysInfoDataWrite(PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t u32, unsigned cb) { ACPIState *s = (ACPIState *)pvUser; Log(("addr=%#x cb=%d u32=%#x si=%#x\n", Port, cb, u32, s->uSystemInfoIndex)); if (cb == 4) { switch (s->uSystemInfoIndex) { case SYSTEM_INFO_INDEX_INVALID: AssertMsg(u32 == 0xbadc0de, ("u32=%u\n", u32)); s->u8IndexShift = 0; break; case SYSTEM_INFO_INDEX_VALID: AssertMsg(u32 == 0xbadc0de, ("u32=%u\n", u32)); s->u8IndexShift = 2; break; case SYSTEM_INFO_INDEX_CPU_LOCK_CHECK: s->idCpuLockCheck = u32; break; case SYSTEM_INFO_INDEX_CPU_LOCKED: if (u32 < s->cCpus) VMCPUSET_DEL(&s->CpuSetLocked, u32); /* Unlock the CPU */ else LogRel(("ACPI: CPU %u does not exist\n", u32)); break; default: AssertMsgFailed(("Port=%#x cb=%d u32=%#x system_index=%#x\n", Port, cb, u32, s->uSystemInfoIndex)); break; } } else AssertMsgFailed(("Port=%#x cb=%d u32=%#x\n", Port, cb, u32)); return VINF_SUCCESS; } /** @todo Don't call functions, but do the job in the read/write handlers * here! */ /* IO Helpers */ PDMBOTHCBDECL(int) acpiPm1aEnRead(PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t *pu32, unsigned cb) { switch (cb) { case 2: *pu32 = acpiPm1aEnReadw((ACPIState*)pvUser, Port); break; default: return VERR_IOM_IOPORT_UNUSED; } return VINF_SUCCESS; } PDMBOTHCBDECL(int) acpiPm1aStsRead(PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t *pu32, unsigned cb) { switch (cb) { case 2: *pu32 = acpiPm1aStsReadw((ACPIState*)pvUser, Port); break; default: return VERR_IOM_IOPORT_UNUSED; } return VINF_SUCCESS; } PDMBOTHCBDECL(int) acpiPm1aCtlRead(PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t *pu32, unsigned cb) { switch (cb) { case 2: *pu32 = acpiPm1aCtlReadw((ACPIState*)pvUser, Port); break; default: return VERR_IOM_IOPORT_UNUSED; } return VINF_SUCCESS; } PDMBOTHCBDECL(int) acpiPM1aEnWrite(PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t u32, unsigned cb) { switch (cb) { case 2: acpiPM1aEnWritew((ACPIState*)pvUser, Port, u32); break; case 4: acpiPM1aEnWritew((ACPIState*)pvUser, Port, u32 & 0xffff); break; default: AssertMsgFailed(("Port=%#x cb=%d u32=%#x\n", Port, cb, u32)); break; } return VINF_SUCCESS; } PDMBOTHCBDECL(int) acpiPM1aStsWrite(PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t u32, unsigned cb) { switch (cb) { case 2: acpiPM1aStsWritew((ACPIState*)pvUser, Port, u32); break; case 4: acpiPM1aStsWritew((ACPIState*)pvUser, Port, u32 & 0xffff); break; default: AssertMsgFailed(("Port=%#x cb=%d u32=%#x\n", Port, cb, u32)); break; } return VINF_SUCCESS; } PDMBOTHCBDECL(int) acpiPM1aCtlWrite(PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t u32, unsigned cb) { switch (cb) { case 2: return acpiPM1aCtlWritew((ACPIState*)pvUser, Port, u32); case 4: return acpiPM1aCtlWritew((ACPIState*)pvUser, Port, u32 & 0xffff); default: AssertMsgFailed(("Port=%#x cb=%d u32=%#x\n", Port, cb, u32)); break; } return VINF_SUCCESS; } #endif /* IN_RING3 */ /** * PMTMR readable from host/guest. */ PDMBOTHCBDECL(int) acpiPMTmrRead(PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t *pu32, unsigned cb) { if (cb == 4) { ACPIState *s = PDMINS_2_DATA(pDevIns, ACPIState *); int64_t now = TMTimerGet(s->CTX_SUFF(ts)); int64_t elapsed = now - s->pm_timer_initial; *pu32 = ASMMultU64ByU32DivByU32(elapsed, PM_TMR_FREQ, TMTimerGetFreq(s->CTX_SUFF(ts))); Log(("acpi: acpiPMTmrRead -> %#x\n", *pu32)); return VINF_SUCCESS; } return VERR_IOM_IOPORT_UNUSED; } #ifdef IN_RING3 PDMBOTHCBDECL(int) acpiGpe0StsRead(PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t *pu32, unsigned cb) { switch (cb) { case 1: *pu32 = acpiGpe0StsReadb((ACPIState*)pvUser, Port); break; default: return VERR_IOM_IOPORT_UNUSED; } return VINF_SUCCESS; } PDMBOTHCBDECL(int) acpiGpe0EnRead(PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t *pu32, unsigned cb) { switch (cb) { case 1: *pu32 = acpiGpe0EnReadb((ACPIState*)pvUser, Port); break; default: return VERR_IOM_IOPORT_UNUSED; } return VINF_SUCCESS; } PDMBOTHCBDECL(int) acpiGpe0StsWrite(PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t u32, unsigned cb) { switch (cb) { case 1: acpiGpe0StsWriteb((ACPIState*)pvUser, Port, u32); break; default: AssertMsgFailed(("Port=%#x cb=%d u32=%#x\n", Port, cb, u32)); break; } return VINF_SUCCESS; } PDMBOTHCBDECL(int) acpiGpe0EnWrite(PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t u32, unsigned cb) { switch (cb) { case 1: acpiGpe0EnWriteb((ACPIState*)pvUser, Port, u32); break; default: AssertMsgFailed(("Port=%#x cb=%d u32=%#x\n", Port, cb, u32)); break; } return VINF_SUCCESS; } PDMBOTHCBDECL(int) acpiSmiWrite(PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t u32, unsigned cb) { switch (cb) { case 1: acpiSmiWriteU8((ACPIState*)pvUser, Port, u32); break; default: AssertMsgFailed(("Port=%#x cb=%d u32=%#x\n", Port, cb, u32)); break; } return VINF_SUCCESS; } PDMBOTHCBDECL(int) acpiResetWrite(PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t u32, unsigned cb) { switch (cb) { case 1: return acpiResetWriteU8((ACPIState*)pvUser, Port, u32); default: AssertMsgFailed(("Port=%#x cb=%d u32=%#x\n", Port, cb, u32)); break; } return VINF_SUCCESS; } #ifdef DEBUG_ACPI PDMBOTHCBDECL(int) acpiDhexWrite(PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t u32, unsigned cb) { switch (cb) { case 1: Log(("%#x\n", u32 & 0xff)); break; case 2: Log(("%#6x\n", u32 & 0xffff)); case 4: Log(("%#10x\n", u32)); break; default: AssertMsgFailed(("Port=%#x cb=%d u32=%#x\n", Port, cb, u32)); break; } return VINF_SUCCESS; } PDMBOTHCBDECL(int) acpiDchrWrite(PPDMDEVINS pDevIns, void *pvUser, RTIOPORT Port, uint32_t u32, unsigned cb) { switch (cb) { case 1: Log(("%c", u32 & 0xff)); break; default: AssertMsgFailed(("Port=%#x cb=%d u32=%#x\n", Port, cb, u32)); break; } return VINF_SUCCESS; } #endif /* DEBUG_ACPI */ static int acpiRegisterPmHandlers(ACPIState* pThis) { int rc = VINF_SUCCESS; #define R(offset, cnt, writer, reader, description) \ do { \ rc = PDMDevHlpIOPortRegister(pThis->pDevIns, acpiPmPort(pThis, offset), cnt, pThis, writer, reader, \ NULL, NULL, description); \ if (RT_FAILURE(rc)) \ return rc; \ } while (0) #define L (GPE0_BLK_LEN / 2) R(PM1a_EVT_OFFSET+2, 1, acpiPM1aEnWrite, acpiPm1aEnRead, "ACPI PM1a Enable"); R(PM1a_EVT_OFFSET, 1, acpiPM1aStsWrite, acpiPm1aStsRead, "ACPI PM1a Status"); R(PM1a_CTL_OFFSET, 1, acpiPM1aCtlWrite, acpiPm1aCtlRead, "ACPI PM1a Control"); R(PM_TMR_OFFSET, 1, NULL, acpiPMTmrRead, "ACPI PM Timer"); R(GPE0_OFFSET + L, L, acpiGpe0EnWrite, acpiGpe0EnRead, "ACPI GPE0 Enable"); R(GPE0_OFFSET, L, acpiGpe0StsWrite, acpiGpe0StsRead, "ACPI GPE0 Status"); #undef L #undef R /* register RC stuff */ if (pThis->fGCEnabled) { rc = PDMDevHlpIOPortRegisterRC(pThis->pDevIns, acpiPmPort(pThis, PM_TMR_OFFSET), 1, 0, NULL, "acpiPMTmrRead", NULL, NULL, "ACPI PM Timer"); AssertRCReturn(rc, rc); } /* register R0 stuff */ if (pThis->fR0Enabled) { rc = PDMDevHlpIOPortRegisterR0(pThis->pDevIns, acpiPmPort(pThis, PM_TMR_OFFSET), 1, 0, NULL, "acpiPMTmrRead", NULL, NULL, "ACPI PM Timer"); AssertRCReturn(rc, rc); } return rc; } static int acpiUnregisterPmHandlers(ACPIState *pThis) { #define U(offset, cnt) \ do { \ int rc = PDMDevHlpIOPortDeregister(pThis->pDevIns, acpiPmPort(pThis, offset), cnt); \ AssertRCReturn(rc, rc); \ } while (0) #define L (GPE0_BLK_LEN / 2) U(PM1a_EVT_OFFSET+2, 1); U(PM1a_EVT_OFFSET, 1); U(PM1a_CTL_OFFSET, 1); U(PM_TMR_OFFSET, 1); U(GPE0_OFFSET + L, L); U(GPE0_OFFSET, L); #undef L #undef U return VINF_SUCCESS; } /** * Saved state structure description, version 4. */ static const SSMFIELD g_AcpiSavedStateFields4[] = { SSMFIELD_ENTRY(ACPIState, pm1a_en), SSMFIELD_ENTRY(ACPIState, pm1a_sts), SSMFIELD_ENTRY(ACPIState, pm1a_ctl), SSMFIELD_ENTRY(ACPIState, pm_timer_initial), SSMFIELD_ENTRY(ACPIState, gpe0_en), SSMFIELD_ENTRY(ACPIState, gpe0_sts), SSMFIELD_ENTRY(ACPIState, uBatteryIndex), SSMFIELD_ENTRY(ACPIState, uSystemInfoIndex), SSMFIELD_ENTRY(ACPIState, u64RamSize), SSMFIELD_ENTRY(ACPIState, u8IndexShift), SSMFIELD_ENTRY(ACPIState, u8UseIOApic), SSMFIELD_ENTRY(ACPIState, uSleepState), SSMFIELD_ENTRY_TERM() }; /** * Saved state structure description, version 5. */ static const SSMFIELD g_AcpiSavedStateFields5[] = { SSMFIELD_ENTRY(ACPIState, pm1a_en), SSMFIELD_ENTRY(ACPIState, pm1a_sts), SSMFIELD_ENTRY(ACPIState, pm1a_ctl), SSMFIELD_ENTRY(ACPIState, pm_timer_initial), SSMFIELD_ENTRY(ACPIState, gpe0_en), SSMFIELD_ENTRY(ACPIState, gpe0_sts), SSMFIELD_ENTRY(ACPIState, uBatteryIndex), SSMFIELD_ENTRY(ACPIState, uSystemInfoIndex), SSMFIELD_ENTRY(ACPIState, uSleepState), SSMFIELD_ENTRY(ACPIState, u8IndexShift), SSMFIELD_ENTRY(ACPIState, uPmIoPortBase), SSMFIELD_ENTRY_TERM() }; static DECLCALLBACK(int) acpi_save_state(PPDMDEVINS pDevIns, PSSMHANDLE pSSMHandle) { ACPIState *s = PDMINS_2_DATA(pDevIns, ACPIState *); return SSMR3PutStruct(pSSMHandle, s, &g_AcpiSavedStateFields5[0]); } static DECLCALLBACK(int) acpi_load_state(PPDMDEVINS pDevIns, PSSMHANDLE pSSMHandle, uint32_t uVersion, uint32_t uPass) { ACPIState *s = PDMINS_2_DATA(pDevIns, ACPIState *); Assert(uPass == SSM_PASS_FINAL); NOREF(uPass); /* * Unregister PM handlers, will register with actual base * after state successfully loaded. */ int rc = acpiUnregisterPmHandlers(s); if (RT_FAILURE(rc)) return rc; switch (uVersion) { case 4: rc = SSMR3GetStruct(pSSMHandle, s, &g_AcpiSavedStateFields4[0]); /** @todo Provide saner defaults for fields not found in saved state. */ break; case 5: rc = SSMR3GetStruct(pSSMHandle, s, &g_AcpiSavedStateFields5[0]); break; default: return VERR_SSM_UNSUPPORTED_DATA_UNIT_VERSION; } if (RT_SUCCESS(rc)) { rc = acpiRegisterPmHandlers(s); if (RT_FAILURE(rc)) return rc; rc = acpiFetchBatteryStatus(s); if (RT_FAILURE(rc)) return rc; rc = acpiFetchBatteryInfo(s); if (RT_FAILURE(rc)) return rc; rc = acpiPMTimerReset(s); if (RT_FAILURE(rc)) return rc; } return rc; } /** * @interface_method_impl{PDMIBASE,pfnQueryInterface} */ static DECLCALLBACK(void *) acpiQueryInterface(PPDMIBASE pInterface, const char *pszIID) { ACPIState *pThis = RT_FROM_MEMBER(pInterface, ACPIState, IBase); PDMIBASE_RETURN_INTERFACE(pszIID, PDMIBASE, &pThis->IBase); PDMIBASE_RETURN_INTERFACE(pszIID, PDMIACPIPORT, &pThis->IACPIPort); return NULL; } /** * Create the ACPI tables. */ static int acpiPlantTables(ACPIState *s) { int rc; RTGCPHYS32 GCPhysCur, GCPhysRsdt, GCPhysXsdt, GCPhysFadtAcpi1, GCPhysFadtAcpi2, GCPhysFacs, GCPhysDsdt; RTGCPHYS32 GCPhysHpet = 0, GCPhysApic = 0, GCPhysSsdt = 0; uint32_t addend = 0; RTGCPHYS32 aGCPhysRsdt[4]; RTGCPHYS32 aGCPhysXsdt[4]; uint32_t cAddr, iMadt = 0, iHpet = 0, iSsdt = 0; size_t cbRsdt = sizeof(ACPITBLHEADER); size_t cbXsdt = sizeof(ACPITBLHEADER); cAddr = 1; /* FADT */ if (s->u8UseIOApic) iMadt = cAddr++; /* MADT */ if (s->fUseHpet) iHpet = cAddr++; /* HPET */ iSsdt = cAddr++; /* SSDT */ cbRsdt += cAddr*sizeof(uint32_t); /* each entry: 32 bits phys. address. */ cbXsdt += cAddr*sizeof(uint64_t); /* each entry: 64 bits phys. address. */ rc = CFGMR3QueryU64(s->pDevIns->pCfg, "RamSize", &s->u64RamSize); if (RT_FAILURE(rc)) return PDMDEV_SET_ERROR(s->pDevIns, rc, N_("Configuration error: Querying \"RamSize\" as integer failed")); uint32_t cbRamHole; rc = CFGMR3QueryU32Def(s->pDevIns->pCfg, "RamHoleSize", &cbRamHole, MM_RAM_HOLE_SIZE_DEFAULT); if (RT_FAILURE(rc)) return PDMDEV_SET_ERROR(s->pDevIns, rc, N_("Configuration error: Querying \"RamHoleSize\" as integer failed")); /* * Calculate the sizes for the high and low regions. */ const uint64_t offRamHole = _4G - cbRamHole; s->cbRamHigh = offRamHole < s->u64RamSize ? s->u64RamSize - offRamHole : 0; uint64_t cbRamLow = offRamHole < s->u64RamSize ? offRamHole : s->u64RamSize; if (cbRamLow > UINT32_C(0xffe00000)) /* See MEM3. */ { /* Note: This is also enforced by DevPcBios.cpp. */ LogRel(("DevACPI: Clipping cbRamLow=%#RX64 down to 0xffe00000.\n", cbRamLow)); cbRamLow = UINT32_C(0xffe00000); } s->cbRamLow = (uint32_t)cbRamLow; GCPhysCur = 0; GCPhysRsdt = GCPhysCur; GCPhysCur = RT_ALIGN_32(GCPhysCur + cbRsdt, 16); GCPhysXsdt = GCPhysCur; GCPhysCur = RT_ALIGN_32(GCPhysCur + cbXsdt, 16); GCPhysFadtAcpi1 = GCPhysCur; GCPhysCur = RT_ALIGN_32(GCPhysCur + ACPITBLFADT_VERSION1_SIZE, 16); GCPhysFadtAcpi2 = GCPhysCur; GCPhysCur = RT_ALIGN_32(GCPhysCur + sizeof(ACPITBLFADT), 64); GCPhysFacs = GCPhysCur; GCPhysCur = RT_ALIGN_32(GCPhysCur + sizeof(ACPITBLFACS), 16); if (s->u8UseIOApic) { GCPhysApic = GCPhysCur; GCPhysCur = RT_ALIGN_32(GCPhysCur + AcpiTableMADT::sizeFor(s, NUMBER_OF_IRQ_SOURCE_OVERRIDES), 16); } if (s->fUseHpet) { GCPhysHpet = GCPhysCur; GCPhysCur = RT_ALIGN_32(GCPhysCur + sizeof(ACPITBLHPET), 16); } void* pSsdtCode = NULL; size_t cbSsdtSize = 0; rc = acpiPrepareSsdt(s->pDevIns, &pSsdtCode, &cbSsdtSize); if (RT_FAILURE(rc)) return rc; GCPhysSsdt = GCPhysCur; GCPhysCur = RT_ALIGN_32(GCPhysCur + cbSsdtSize, 16); GCPhysDsdt = GCPhysCur; void* pDsdtCode = NULL; size_t cbDsdtSize = 0; rc = acpiPrepareDsdt(s->pDevIns, &pDsdtCode, &cbDsdtSize); if (RT_FAILURE(rc)) return rc; GCPhysCur = RT_ALIGN_32(GCPhysCur + cbDsdtSize, 16); if (GCPhysCur > 0x10000) return PDMDEV_SET_ERROR(s->pDevIns, VERR_TOO_MUCH_DATA, N_("Error: ACPI tables bigger than 64KB")); Log(("RSDP 0x%08X\n", find_rsdp_space())); addend = s->cbRamLow - 0x10000; Log(("RSDT 0x%08X XSDT 0x%08X\n", GCPhysRsdt + addend, GCPhysXsdt + addend)); Log(("FACS 0x%08X FADT (1.0) 0x%08X, FADT (2+) 0x%08X\n", GCPhysFacs + addend, GCPhysFadtAcpi1 + addend, GCPhysFadtAcpi2 + addend)); Log(("DSDT 0x%08X", GCPhysDsdt + addend)); if (s->u8UseIOApic) Log((" MADT 0x%08X", GCPhysApic + addend)); if (s->fUseHpet) Log((" HPET 0x%08X", GCPhysHpet + addend)); Log((" SSDT 0x%08X", GCPhysSsdt + addend)); Log(("\n")); acpiSetupRSDP((ACPITBLRSDP*)s->au8RSDPPage, GCPhysRsdt + addend, GCPhysXsdt + addend); acpiSetupDSDT(s, GCPhysDsdt + addend, pDsdtCode, cbDsdtSize); acpiCleanupDsdt(s->pDevIns, pDsdtCode); acpiSetupFACS(s, GCPhysFacs + addend); acpiSetupFADT(s, GCPhysFadtAcpi1 + addend, GCPhysFadtAcpi2 + addend, GCPhysFacs + addend, GCPhysDsdt + addend); aGCPhysRsdt[0] = GCPhysFadtAcpi1 + addend; aGCPhysXsdt[0] = GCPhysFadtAcpi2 + addend; if (s->u8UseIOApic) { acpiSetupMADT(s, GCPhysApic + addend); aGCPhysRsdt[iMadt] = GCPhysApic + addend; aGCPhysXsdt[iMadt] = GCPhysApic + addend; } if (s->fUseHpet) { acpiSetupHPET(s, GCPhysHpet + addend); aGCPhysRsdt[iHpet] = GCPhysHpet + addend; aGCPhysXsdt[iHpet] = GCPhysHpet + addend; } acpiSetupSSDT(s, GCPhysSsdt + addend, pSsdtCode, cbSsdtSize); acpiCleanupSsdt(s->pDevIns, pSsdtCode); aGCPhysRsdt[iSsdt] = GCPhysSsdt + addend; aGCPhysXsdt[iSsdt] = GCPhysSsdt + addend; rc = acpiSetupRSDT(s, GCPhysRsdt + addend, cAddr, aGCPhysRsdt); if (RT_FAILURE(rc)) return rc; return acpiSetupXSDT(s, GCPhysXsdt + addend, cAddr, aGCPhysXsdt); } static int acpiUpdatePmHandlers(ACPIState *pThis, RTIOPORT uNewBase) { Log(("acpi: rebasing PM 0x%x -> 0x%x\n", pThis->uPmIoPortBase, uNewBase)); if (uNewBase != pThis->uPmIoPortBase) { int rc; rc = acpiUnregisterPmHandlers(pThis); if (RT_FAILURE(rc)) return rc; pThis->uPmIoPortBase = uNewBase; rc = acpiRegisterPmHandlers(pThis); if (RT_FAILURE(rc)) return rc; /* We have to update FADT table acccording to the new base */ rc = acpiPlantTables(pThis); AssertRC(rc); if (RT_FAILURE(rc)) return rc; } return VINF_SUCCESS; } static uint32_t acpiPciConfigRead(PPCIDEVICE pPciDev, uint32_t Address, unsigned cb) { PPDMDEVINS pDevIns = pPciDev->pDevIns; ACPIState* pThis = PDMINS_2_DATA(pDevIns, ACPIState *); Log2(("acpi: PCI config read: 0x%x (%d)\n", Address, cb)); return pThis->pfnAcpiPciConfigRead(pPciDev, Address, cb); } static void acpiPciConfigWrite(PPCIDEVICE pPciDev, uint32_t Address, uint32_t u32Value, unsigned cb) { PPDMDEVINS pDevIns = pPciDev->pDevIns; ACPIState *pThis = PDMINS_2_DATA(pDevIns, ACPIState *); Log2(("acpi: PCI config write: 0x%x -> 0x%x (%d)\n", u32Value, Address, cb)); pThis->pfnAcpiPciConfigWrite(pPciDev, Address, u32Value, cb); /* PMREGMISC written */ if (Address == 0x80) { /* Check Power Management IO Space Enable (PMIOSE) bit */ if (pPciDev->config[0x80] & 0x1) { int rc; RTIOPORT uNewBase = RTIOPORT(RT_LE2H_U32(*(uint32_t*)&pPciDev->config[0x40])); uNewBase &= 0xffc0; rc = acpiUpdatePmHandlers(pThis, uNewBase); AssertRC(rc); } } } /** * Attach a new CPU. * * @returns VBox status code. * @param pDevIns The device instance. * @param iLUN The logical unit which is being attached. * @param fFlags Flags, combination of the PDMDEVATT_FLAGS_* \#defines. * * @remarks This code path is not used during construction. */ static DECLCALLBACK(int) acpiAttach(PPDMDEVINS pDevIns, unsigned iLUN, uint32_t fFlags) { ACPIState *s = PDMINS_2_DATA(pDevIns, ACPIState *); LogFlow(("acpiAttach: pDevIns=%p iLUN=%u fFlags=%#x\n", pDevIns, iLUN, fFlags)); AssertMsgReturn(!(fFlags & PDM_TACH_FLAGS_NOT_HOT_PLUG), ("Hot-plug flag is not set\n"), VERR_NOT_SUPPORTED); AssertReturn(iLUN < VMM_MAX_CPU_COUNT, VERR_PDM_NO_SUCH_LUN); /* Check if it was already attached */ if (VMCPUSET_IS_PRESENT(&s->CpuSetAttached, iLUN)) return VINF_SUCCESS; PPDMIBASE IBaseTmp; int rc = PDMDevHlpDriverAttach(pDevIns, iLUN, &s->IBase, &IBaseTmp, "ACPI CPU"); if (RT_SUCCESS(rc)) { /* Enable the CPU */ VMCPUSET_ADD(&s->CpuSetAttached, iLUN); /* * Lock the CPU because we don't know if the guest will use it or not. * Prevents ejection while the CPU is still used */ VMCPUSET_ADD(&s->CpuSetLocked, iLUN); s->u32CpuEventType = CPU_EVENT_TYPE_ADD; s->u32CpuEvent = iLUN; /* Notify the guest */ update_gpe0(s, s->gpe0_sts | 0x2, s->gpe0_en); } return rc; } /** * Detach notification. * * @param pDevIns The device instance. * @param iLUN The logical unit which is being detached. * @param fFlags Flags, combination of the PDMDEVATT_FLAGS_* \#defines. */ static DECLCALLBACK(void) acpiDetach(PPDMDEVINS pDevIns, unsigned iLUN, uint32_t fFlags) { ACPIState *s = PDMINS_2_DATA(pDevIns, ACPIState *); LogFlow(("acpiDetach: pDevIns=%p iLUN=%u fFlags=%#x\n", pDevIns, iLUN, fFlags)); AssertMsgReturnVoid(!(fFlags & PDM_TACH_FLAGS_NOT_HOT_PLUG), ("Hot-plug flag is not set\n")); /* Check if it was already detached */ if (VMCPUSET_IS_PRESENT(&s->CpuSetAttached, iLUN)) { AssertMsgReturnVoid(!(VMCPUSET_IS_PRESENT(&s->CpuSetLocked, iLUN)), ("CPU is still locked by the guest\n")); /* Disable the CPU */ VMCPUSET_DEL(&s->CpuSetAttached, iLUN); s->u32CpuEventType = CPU_EVENT_TYPE_REMOVE; s->u32CpuEvent = iLUN; /* Notify the guest */ update_gpe0(s, s->gpe0_sts | 0x2, s->gpe0_en); } } static DECLCALLBACK(void) acpiReset(PPDMDEVINS pDevIns) { ACPIState *s = PDMINS_2_DATA(pDevIns, ACPIState *); s->pm1a_en = 0; s->pm1a_sts = 0; s->pm1a_ctl = 0; s->pm_timer_initial = TMTimerGet(s->CTX_SUFF(ts)); acpiPMTimerReset(s); s->uBatteryIndex = 0; s->uSystemInfoIndex = 0; s->gpe0_en = 0; s->gpe0_sts = 0; s->uSleepState = 0; /** @todo Should we really reset PM base? */ acpiUpdatePmHandlers(s, PM_PORT_BASE); acpiPlantTables(s); } /** * Relocates the GC pointer members. */ static DECLCALLBACK(void) acpiRelocate(PPDMDEVINS pDevIns, RTGCINTPTR offDelta) { ACPIState *s = PDMINS_2_DATA(pDevIns, ACPIState *); s->tsRC = TMTimerRCPtr(s->CTX_SUFF(ts)); } /** * @interface_method_impl{PDMDEVREG,pfnConstruct} */ static DECLCALLBACK(int) acpiConstruct(PPDMDEVINS pDevIns, int iInstance, PCFGMNODE pCfg) { ACPIState *s = PDMINS_2_DATA(pDevIns, ACPIState *); PCIDevice *dev = &s->dev; PDMDEV_CHECK_VERSIONS_RETURN(pDevIns); /* Validate and read the configuration. */ if (!CFGMR3AreValuesValid(pCfg, "RamSize\0" "RamHoleSize\0" "IOAPIC\0" "NumCPUs\0" "GCEnabled\0" "R0Enabled\0" "HpetEnabled\0" "SmcEnabled\0" "FdcEnabled\0" "ShowRtc\0" "ShowCpu\0" "NicPciAddress\0" "CpuHotPlug\0" "AmlFilePath\0" )) return PDMDEV_SET_ERROR(pDevIns, VERR_PDM_DEVINS_UNKNOWN_CFG_VALUES, N_("Configuration error: Invalid config key for ACPI device")); s->pDevIns = pDevIns; /* query whether we are supposed to present an IOAPIC */ int rc = CFGMR3QueryU8Def(pCfg, "IOAPIC", &s->u8UseIOApic, 1); if (RT_FAILURE(rc)) return PDMDEV_SET_ERROR(pDevIns, rc, N_("Configuration error: Failed to read \"IOAPIC\"")); rc = CFGMR3QueryU16Def(pCfg, "NumCPUs", &s->cCpus, 1); if (RT_FAILURE(rc)) return PDMDEV_SET_ERROR(pDevIns, rc, N_("Configuration error: Querying \"NumCPUs\" as integer failed")); /* query whether we are supposed to present an FDC controller */ rc = CFGMR3QueryBoolDef(pCfg, "FdcEnabled", &s->fUseFdc, true); if (RT_FAILURE(rc)) return PDMDEV_SET_ERROR(pDevIns, rc, N_("Configuration error: Failed to read \"FdcEnabled\"")); /* query whether we are supposed to present HPET */ rc = CFGMR3QueryBoolDef(pCfg, "HpetEnabled", &s->fUseHpet, false); if (RT_FAILURE(rc)) return PDMDEV_SET_ERROR(pDevIns, rc, N_("Configuration error: Failed to read \"HpetEnabled\"")); /* query whether we are supposed to present SMC */ rc = CFGMR3QueryBoolDef(pCfg, "SmcEnabled", &s->fUseSmc, false); if (RT_FAILURE(rc)) return PDMDEV_SET_ERROR(pDevIns, rc, N_("Configuration error: Failed to read \"SmcEnabled\"")); /* query whether we are supposed to present RTC object */ rc = CFGMR3QueryBoolDef(pCfg, "ShowRtc", &s->fShowRtc, false); if (RT_FAILURE(rc)) return PDMDEV_SET_ERROR(pDevIns, rc, N_("Configuration error: Failed to read \"ShowRtc\"")); /* query whether we are supposed to present CPU objects */ rc = CFGMR3QueryBoolDef(pCfg, "ShowCpu", &s->fShowCpu, false); if (RT_FAILURE(rc)) return PDMDEV_SET_ERROR(pDevIns, rc, N_("Configuration error: Failed to read \"ShowCpu\"")); /* query primary NIC PCI address */ rc = CFGMR3QueryU32Def(pCfg, "NicPciAddress", &s->u32NicPciAddress, 0); if (RT_FAILURE(rc)) return PDMDEV_SET_ERROR(pDevIns, rc, N_("Configuration error: Failed to read \"NicPciAddress\"")); /* query whether we are allow CPU hot plugging */ rc = CFGMR3QueryBoolDef(pCfg, "CpuHotPlug", &s->fCpuHotPlug, false); if (RT_FAILURE(rc)) return PDMDEV_SET_ERROR(pDevIns, rc, N_("Configuration error: Failed to read \"CpuHotPlug\"")); rc = CFGMR3QueryBool(pCfg, "GCEnabled", &s->fGCEnabled); if (rc == VERR_CFGM_VALUE_NOT_FOUND) s->fGCEnabled = true; else if (RT_FAILURE(rc)) return PDMDEV_SET_ERROR(pDevIns, rc, N_("Configuration error: Failed to read \"GCEnabled\"")); rc = CFGMR3QueryBool(pCfg, "R0Enabled", &s->fR0Enabled); if (rc == VERR_CFGM_VALUE_NOT_FOUND) s->fR0Enabled = true; else if (RT_FAILURE(rc)) return PDMDEV_SET_ERROR(pDevIns, rc, N_("configuration error: failed to read R0Enabled as boolean")); /* * Interfaces */ /* IBase */ s->IBase.pfnQueryInterface = acpiQueryInterface; /* IACPIPort */ s->IACPIPort.pfnSleepButtonPress = acpiSleepButtonPress; s->IACPIPort.pfnPowerButtonPress = acpiPowerButtonPress; s->IACPIPort.pfnGetPowerButtonHandled = acpiGetPowerButtonHandled; s->IACPIPort.pfnGetGuestEnteredACPIMode = acpiGetGuestEnteredACPIMode; s->IACPIPort.pfnGetCpuStatus = acpiGetCpuStatus; VMCPUSET_EMPTY(&s->CpuSetAttached); VMCPUSET_EMPTY(&s->CpuSetLocked); s->idCpuLockCheck = UINT32_C(0xffffffff); s->u32CpuEventType = 0; s->u32CpuEvent = UINT32_C(0xffffffff); /* The first CPU can't be attached/detached */ VMCPUSET_ADD(&s->CpuSetAttached, 0); VMCPUSET_ADD(&s->CpuSetLocked, 0); /* Try to attach the other CPUs */ for (unsigned i = 1; i < s->cCpus; i++) { if (s->fCpuHotPlug) { PPDMIBASE IBaseTmp; rc = PDMDevHlpDriverAttach(pDevIns, i, &s->IBase, &IBaseTmp, "ACPI CPU"); if (RT_SUCCESS(rc)) { VMCPUSET_ADD(&s->CpuSetAttached, i); VMCPUSET_ADD(&s->CpuSetLocked, i); Log(("acpi: Attached CPU %u\n", i)); } else if (rc == VERR_PDM_NO_ATTACHED_DRIVER) Log(("acpi: CPU %u not attached yet\n", i)); else return PDMDEV_SET_ERROR(pDevIns, rc, N_("Failed to attach CPU object\n")); } else { /* CPU is always attached if hot-plug is not enabled. */ VMCPUSET_ADD(&s->CpuSetAttached, i); VMCPUSET_ADD(&s->CpuSetLocked, i); } } /* Set default port base */ s->uPmIoPortBase = PM_PORT_BASE; /* * FDC and SMC try to use the same non-shareable interrupt (6), * enable only one device. */ if (s->fUseSmc) s->fUseFdc = false; /* */ RTGCPHYS32 GCPhysRsdp = find_rsdp_space(); if (!GCPhysRsdp) return PDMDEV_SET_ERROR(pDevIns, VERR_NO_MEMORY, N_("Can not find space for RSDP. ACPI is disabled")); rc = acpiPlantTables(s); if (RT_FAILURE(rc)) return rc; rc = PDMDevHlpROMRegister(pDevIns, GCPhysRsdp, 0x1000, s->au8RSDPPage, PGMPHYS_ROM_FLAGS_PERMANENT_BINARY, "ACPI RSDP"); if (RT_FAILURE(rc)) return rc; rc = acpiRegisterPmHandlers(s); if (RT_FAILURE(rc)) return rc; #define R(addr, cnt, writer, reader, description) \ do { \ rc = PDMDevHlpIOPortRegister(pDevIns, addr, cnt, s, writer, reader, \ NULL, NULL, description); \ if (RT_FAILURE(rc)) \ return rc; \ } while (0) R(SMI_CMD, 1, acpiSmiWrite, NULL, "ACPI SMI"); #ifdef DEBUG_ACPI R(DEBUG_HEX, 1, acpiDhexWrite, NULL, "ACPI Debug hex"); R(DEBUG_CHR, 1, acpiDchrWrite, NULL, "ACPI Debug char"); #endif R(BAT_INDEX, 1, acpiBatIndexWrite, NULL, "ACPI Battery status index"); R(BAT_DATA, 1, NULL, acpiBatDataRead, "ACPI Battery status data"); R(SYSI_INDEX, 1, acpiSysInfoIndexWrite, NULL, "ACPI system info index"); R(SYSI_DATA, 1, acpiSysInfoDataWrite, acpiSysInfoDataRead, "ACPI system info data"); R(ACPI_RESET_BLK, 1, acpiResetWrite, NULL, "ACPI Reset"); #undef R rc = PDMDevHlpTMTimerCreate(pDevIns, TMCLOCK_VIRTUAL_SYNC, acpiTimer, dev, TMTIMER_FLAGS_DEFAULT_CRIT_SECT, "ACPI Timer", &s->tsR3); if (RT_FAILURE(rc)) { AssertMsgFailed(("pfnTMTimerCreate -> %Rrc\n", rc)); return rc; } s->tsR0 = TMTimerR0Ptr(s->tsR3); s->tsRC = TMTimerRCPtr(s->tsR3); s->pm_timer_initial = TMTimerGet(s->tsR3); acpiPMTimerReset(s); PCIDevSetVendorId(dev, 0x8086); /* Intel */ PCIDevSetDeviceId(dev, 0x7113); /* 82371AB */ /* See p. 50 of PIIX4 manual */ dev->config[0x04] = 0x01; /* command */ dev->config[0x05] = 0x00; dev->config[0x06] = 0x80; /* status */ dev->config[0x07] = 0x02; dev->config[0x08] = 0x08; /* revision number */ dev->config[0x09] = 0x00; /* class code */ dev->config[0x0a] = 0x80; dev->config[0x0b] = 0x06; dev->config[0x0e] = 0x80; /* header type */ dev->config[0x0f] = 0x00; /* reserved */ dev->config[0x3c] = SCI_INT; /* interrupt line */ #if 0 dev->config[0x3d] = 0x01; /* interrupt pin */ #endif dev->config[0x40] = 0x01; /* PM base address, this bit marks it as IO range, not PA */ #if 0 int smb_io_base = 0xb100; dev->config[0x90] = smb_io_base | 1; /* SMBus base address */ dev->config[0x90] = smb_io_base >> 8; #endif rc = PDMDevHlpPCIRegister(pDevIns, dev); if (RT_FAILURE(rc)) return rc; PDMDevHlpPCISetConfigCallbacks(pDevIns, dev, acpiPciConfigRead, &s->pfnAcpiPciConfigRead, acpiPciConfigWrite, &s->pfnAcpiPciConfigWrite); rc = PDMDevHlpSSMRegister(pDevIns, 5, sizeof(*s), acpi_save_state, acpi_load_state); if (RT_FAILURE(rc)) return rc; /* * Get the corresponding connector interface */ rc = PDMDevHlpDriverAttach(pDevIns, 0, &s->IBase, &s->pDrvBase, "ACPI Driver Port"); if (RT_SUCCESS(rc)) { s->pDrv = PDMIBASE_QUERY_INTERFACE(s->pDrvBase, PDMIACPICONNECTOR); if (!s->pDrv) return PDMDEV_SET_ERROR(pDevIns, VERR_PDM_MISSING_INTERFACE, N_("LUN #0 doesn't have an ACPI connector interface")); } else if (rc == VERR_PDM_NO_ATTACHED_DRIVER) { Log(("acpi: %s/%d: warning: no driver attached to LUN #0!\n", pDevIns->pReg->szName, pDevIns->iInstance)); rc = VINF_SUCCESS; } else return PDMDEV_SET_ERROR(pDevIns, rc, N_("Failed to attach LUN #0")); return rc; } /** * The device registration structure. */ const PDMDEVREG g_DeviceACPI = { /* u32Version */ PDM_DEVREG_VERSION, /* szName */ "acpi", /* szRCMod */ "VBoxDDGC.gc", /* szR0Mod */ "VBoxDDR0.r0", /* pszDescription */ "Advanced Configuration and Power Interface", /* fFlags */ PDM_DEVREG_FLAGS_DEFAULT_BITS | PDM_DEVREG_FLAGS_RC | PDM_DEVREG_FLAGS_R0, /* fClass */ PDM_DEVREG_CLASS_ACPI, /* cMaxInstances */ ~0, /* cbInstance */ sizeof(ACPIState), /* pfnConstruct */ acpiConstruct, /* pfnDestruct */ NULL, /* pfnRelocate */ acpiRelocate, /* pfnIOCtl */ NULL, /* pfnPowerOn */ NULL, /* pfnReset */ acpiReset, /* pfnSuspend */ NULL, /* pfnResume */ NULL, /* pfnAttach */ acpiAttach, /* pfnDetach */ acpiDetach, /* pfnQueryInterface. */ NULL, /* pfnInitComplete */ NULL, /* pfnPowerOff */ NULL, /* pfnSoftReset */ NULL, /* u32VersionEnd */ PDM_DEVREG_VERSION }; #endif /* IN_RING3 */ #endif /* !VBOX_DEVICE_STRUCT_TESTCASE */