/**@file Memory Detection for Virtual Machines. Copyright (c) 2006 - 2016, Intel Corporation. All rights reserved.
SPDX-License-Identifier: BSD-2-Clause-Patent Module Name: MemDetect.c **/ // // The package level header files this module uses // #include #include #include #include #include #include #include // // The Library classes this module consumes // #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include VOID EFIAPI PlatformQemuUc32BaseInitialization ( IN OUT EFI_HOB_PLATFORM_INFO *PlatformInfoHob ) { UINT32 LowerMemorySize; if (PlatformInfoHob->HostBridgeDevId == 0xffff /* microvm */) { return; } if (PlatformInfoHob->HostBridgeDevId == INTEL_Q35_MCH_DEVICE_ID) { // // On q35, the 32-bit area that we'll mark as UC, through variable MTRRs, // starts at PcdPciExpressBaseAddress. The platform DSC is responsible for // setting PcdPciExpressBaseAddress such that describing the // [PcdPciExpressBaseAddress, 4GB) range require a very small number of // variable MTRRs (preferably 1 or 2). // ASSERT (PcdGet64 (PcdPciExpressBaseAddress) <= MAX_UINT32); PlatformInfoHob->Uc32Base = (UINT32)PcdGet64 (PcdPciExpressBaseAddress); return; } if (PlatformInfoHob->HostBridgeDevId == CLOUDHV_DEVICE_ID) { PlatformInfoHob->Uc32Size = CLOUDHV_MMIO_HOLE_SIZE; PlatformInfoHob->Uc32Base = CLOUDHV_MMIO_HOLE_ADDRESS; return; } ASSERT (PlatformInfoHob->HostBridgeDevId == INTEL_82441_DEVICE_ID); // // On i440fx, start with the [LowerMemorySize, 4GB) range. Make sure one // variable MTRR suffices by truncating the size to a whole power of two, // while keeping the end affixed to 4GB. This will round the base up. // LowerMemorySize = PlatformGetSystemMemorySizeBelow4gb (PlatformInfoHob); PlatformInfoHob->Uc32Size = GetPowerOfTwo32 ((UINT32)(SIZE_4GB - LowerMemorySize)); PlatformInfoHob->Uc32Base = (UINT32)(SIZE_4GB - PlatformInfoHob->Uc32Size); // // Assuming that LowerMemorySize is at least 1 byte, Uc32Size is at most 2GB. // Therefore Uc32Base is at least 2GB. // ASSERT (PlatformInfoHob->Uc32Base >= BASE_2GB); if (PlatformInfoHob->Uc32Base != LowerMemorySize) { DEBUG (( DEBUG_VERBOSE, "%a: rounded UC32 base from 0x%x up to 0x%x, for " "an UC32 size of 0x%x\n", __FUNCTION__, LowerMemorySize, PlatformInfoHob->Uc32Base, PlatformInfoHob->Uc32Size )); } } /** Iterate over the RAM entries in QEMU's fw_cfg E820 RAM map that start outside of the 32-bit address range. Find the highest exclusive >=4GB RAM address, or produce memory resource descriptor HOBs for RAM entries that start at or above 4GB. @param[out] MaxAddress If MaxAddress is NULL, then PlatformScanOrAdd64BitE820Ram() produces memory resource descriptor HOBs for RAM entries that start at or above 4GB. Otherwise, MaxAddress holds the highest exclusive >=4GB RAM address on output. If QEMU's fw_cfg E820 RAM map contains no RAM entry that starts outside of the 32-bit address range, then MaxAddress is exactly 4GB on output. @retval EFI_SUCCESS The fw_cfg E820 RAM map was found and processed. @retval EFI_PROTOCOL_ERROR The RAM map was found, but its size wasn't a whole multiple of sizeof(EFI_E820_ENTRY64). No RAM entry was processed. @return Error codes from QemuFwCfgFindFile(). No RAM entry was processed. **/ STATIC EFI_STATUS PlatformScanOrAdd64BitE820Ram ( IN BOOLEAN AddHighHob, OUT UINT64 *LowMemory OPTIONAL, OUT UINT64 *MaxAddress OPTIONAL ) { EFI_STATUS Status; FIRMWARE_CONFIG_ITEM FwCfgItem; UINTN FwCfgSize; EFI_E820_ENTRY64 E820Entry; UINTN Processed; Status = QemuFwCfgFindFile ("etc/e820", &FwCfgItem, &FwCfgSize); if (EFI_ERROR (Status)) { return Status; } if (FwCfgSize % sizeof E820Entry != 0) { return EFI_PROTOCOL_ERROR; } if (LowMemory != NULL) { *LowMemory = 0; } if (MaxAddress != NULL) { *MaxAddress = BASE_4GB; } QemuFwCfgSelectItem (FwCfgItem); for (Processed = 0; Processed < FwCfgSize; Processed += sizeof E820Entry) { QemuFwCfgReadBytes (sizeof E820Entry, &E820Entry); DEBUG (( DEBUG_VERBOSE, "%a: Base=0x%Lx Length=0x%Lx Type=%u\n", __FUNCTION__, E820Entry.BaseAddr, E820Entry.Length, E820Entry.Type )); if (E820Entry.Type == EfiAcpiAddressRangeMemory) { if (AddHighHob && (E820Entry.BaseAddr >= BASE_4GB)) { UINT64 Base; UINT64 End; // // Round up the start address, and round down the end address. // Base = ALIGN_VALUE (E820Entry.BaseAddr, (UINT64)EFI_PAGE_SIZE); End = (E820Entry.BaseAddr + E820Entry.Length) & ~(UINT64)EFI_PAGE_MASK; if (Base < End) { PlatformAddMemoryRangeHob (Base, End); DEBUG (( DEBUG_VERBOSE, "%a: PlatformAddMemoryRangeHob [0x%Lx, 0x%Lx)\n", __FUNCTION__, Base, End )); } } if (MaxAddress || LowMemory) { UINT64 Candidate; Candidate = E820Entry.BaseAddr + E820Entry.Length; if (MaxAddress && (Candidate > *MaxAddress)) { *MaxAddress = Candidate; DEBUG (( DEBUG_VERBOSE, "%a: MaxAddress=0x%Lx\n", __FUNCTION__, *MaxAddress )); } if (LowMemory && (Candidate > *LowMemory) && (Candidate < BASE_4GB)) { *LowMemory = Candidate; DEBUG (( DEBUG_VERBOSE, "%a: LowMemory=0x%Lx\n", __FUNCTION__, *LowMemory )); } } } } return EFI_SUCCESS; } /** Returns PVH memmap @param Entries Pointer to PVH memmap @param Count Number of entries @return EFI_STATUS **/ EFI_STATUS GetPvhMemmapEntries ( struct hvm_memmap_table_entry **Entries, UINT32 *Count ) { UINT32 *PVHResetVectorData; struct hvm_start_info *pvh_start_info; PVHResetVectorData = (VOID *)(UINTN)PcdGet32 (PcdXenPvhStartOfDayStructPtr); if (PVHResetVectorData == 0) { return EFI_NOT_FOUND; } pvh_start_info = (struct hvm_start_info *)(UINTN)PVHResetVectorData[0]; *Entries = (struct hvm_memmap_table_entry *)(UINTN)pvh_start_info->memmap_paddr; *Count = pvh_start_info->memmap_entries; return EFI_SUCCESS; } STATIC UINT64 GetHighestSystemMemoryAddressFromPvhMemmap ( BOOLEAN Below4gb ) { struct hvm_memmap_table_entry *Memmap; UINT32 MemmapEntriesCount; struct hvm_memmap_table_entry *Entry; EFI_STATUS Status; UINT32 Loop; UINT64 HighestAddress; UINT64 EntryEnd; HighestAddress = 0; Status = GetPvhMemmapEntries (&Memmap, &MemmapEntriesCount); ASSERT_EFI_ERROR (Status); for (Loop = 0; Loop < MemmapEntriesCount; Loop++) { Entry = Memmap + Loop; EntryEnd = Entry->addr + Entry->size; if ((Entry->type == XEN_HVM_MEMMAP_TYPE_RAM) && (EntryEnd > HighestAddress)) { if (Below4gb && (EntryEnd <= BASE_4GB)) { HighestAddress = EntryEnd; } else if (!Below4gb && (EntryEnd >= BASE_4GB)) { HighestAddress = EntryEnd; } } } return HighestAddress; } UINT32 EFIAPI PlatformGetSystemMemorySizeBelow4gb ( IN EFI_HOB_PLATFORM_INFO *PlatformInfoHob ) { EFI_STATUS Status; UINT64 LowerMemorySize = 0; UINT8 Cmos0x34; UINT8 Cmos0x35; if (PlatformInfoHob->HostBridgeDevId == CLOUDHV_DEVICE_ID) { // Get the information from PVH memmap return (UINT32)GetHighestSystemMemoryAddressFromPvhMemmap (TRUE); } Status = PlatformScanOrAdd64BitE820Ram (FALSE, &LowerMemorySize, NULL); if ((Status == EFI_SUCCESS) && (LowerMemorySize > 0)) { return (UINT32)LowerMemorySize; } // // CMOS 0x34/0x35 specifies the system memory above 16 MB. // * CMOS(0x35) is the high byte // * CMOS(0x34) is the low byte // * The size is specified in 64kb chunks // * Since this is memory above 16MB, the 16MB must be added // into the calculation to get the total memory size. // Cmos0x34 = (UINT8)PlatformCmosRead8 (0x34); Cmos0x35 = (UINT8)PlatformCmosRead8 (0x35); return (UINT32)(((UINTN)((Cmos0x35 << 8) + Cmos0x34) << 16) + SIZE_16MB); } STATIC UINT64 PlatformGetSystemMemorySizeAbove4gb ( ) { UINT32 Size; UINTN CmosIndex; // // CMOS 0x5b-0x5d specifies the system memory above 4GB MB. // * CMOS(0x5d) is the most significant size byte // * CMOS(0x5c) is the middle size byte // * CMOS(0x5b) is the least significant size byte // * The size is specified in 64kb chunks // Size = 0; for (CmosIndex = 0x5d; CmosIndex >= 0x5b; CmosIndex--) { Size = (UINT32)(Size << 8) + (UINT32)PlatformCmosRead8 (CmosIndex); } return LShiftU64 (Size, 16); } /** Return the highest address that DXE could possibly use, plus one. **/ STATIC UINT64 PlatformGetFirstNonAddress ( IN OUT EFI_HOB_PLATFORM_INFO *PlatformInfoHob ) { UINT64 FirstNonAddress; UINT32 FwCfgPciMmio64Mb; EFI_STATUS Status; FIRMWARE_CONFIG_ITEM FwCfgItem; UINTN FwCfgSize; UINT64 HotPlugMemoryEnd; // // set FirstNonAddress to suppress incorrect compiler/analyzer warnings // FirstNonAddress = 0; // // If QEMU presents an E820 map, then get the highest exclusive >=4GB RAM // address from it. This can express an address >= 4GB+1TB. // // Otherwise, get the flat size of the memory above 4GB from the CMOS (which // can only express a size smaller than 1TB), and add it to 4GB. // Status = PlatformScanOrAdd64BitE820Ram (FALSE, NULL, &FirstNonAddress); if (EFI_ERROR (Status)) { FirstNonAddress = BASE_4GB + PlatformGetSystemMemorySizeAbove4gb (); } // // If DXE is 32-bit, then we're done; PciBusDxe will degrade 64-bit MMIO // resources to 32-bit anyway. See DegradeResource() in // "PciResourceSupport.c". // #ifdef MDE_CPU_IA32 if (!FeaturePcdGet (PcdDxeIplSwitchToLongMode)) { return FirstNonAddress; } #endif // // See if the user specified the number of megabytes for the 64-bit PCI host // aperture. Accept an aperture size up to 16TB. // // As signaled by the "X-" prefix, this knob is experimental, and might go // away at any time. // Status = QemuFwCfgParseUint32 ( "opt/ovmf/X-PciMmio64Mb", FALSE, &FwCfgPciMmio64Mb ); switch (Status) { case EFI_UNSUPPORTED: case EFI_NOT_FOUND: break; case EFI_SUCCESS: if (FwCfgPciMmio64Mb <= 0x1000000) { PlatformInfoHob->PcdPciMmio64Size = LShiftU64 (FwCfgPciMmio64Mb, 20); break; } // // fall through // default: DEBUG (( DEBUG_WARN, "%a: ignoring malformed 64-bit PCI host aperture size from fw_cfg\n", __FUNCTION__ )); break; } if (PlatformInfoHob->PcdPciMmio64Size == 0) { if (PlatformInfoHob->BootMode != BOOT_ON_S3_RESUME) { DEBUG (( DEBUG_INFO, "%a: disabling 64-bit PCI host aperture\n", __FUNCTION__ )); } // // There's nothing more to do; the amount of memory above 4GB fully // determines the highest address plus one. The memory hotplug area (see // below) plays no role for the firmware in this case. // return FirstNonAddress; } // // The "etc/reserved-memory-end" fw_cfg file, when present, contains an // absolute, exclusive end address for the memory hotplug area. This area // starts right at the end of the memory above 4GB. The 64-bit PCI host // aperture must be placed above it. // Status = QemuFwCfgFindFile ( "etc/reserved-memory-end", &FwCfgItem, &FwCfgSize ); if (!EFI_ERROR (Status) && (FwCfgSize == sizeof HotPlugMemoryEnd)) { QemuFwCfgSelectItem (FwCfgItem); QemuFwCfgReadBytes (FwCfgSize, &HotPlugMemoryEnd); DEBUG (( DEBUG_VERBOSE, "%a: HotPlugMemoryEnd=0x%Lx\n", __FUNCTION__, HotPlugMemoryEnd )); ASSERT (HotPlugMemoryEnd >= FirstNonAddress); FirstNonAddress = HotPlugMemoryEnd; } // // SeaBIOS aligns both boundaries of the 64-bit PCI host aperture to 1GB, so // that the host can map it with 1GB hugepages. Follow suit. // PlatformInfoHob->PcdPciMmio64Base = ALIGN_VALUE (FirstNonAddress, (UINT64)SIZE_1GB); PlatformInfoHob->PcdPciMmio64Size = ALIGN_VALUE (PlatformInfoHob->PcdPciMmio64Size, (UINT64)SIZE_1GB); // // The 64-bit PCI host aperture should also be "naturally" aligned. The // alignment is determined by rounding the size of the aperture down to the // next smaller or equal power of two. That is, align the aperture by the // largest BAR size that can fit into it. // PlatformInfoHob->PcdPciMmio64Base = ALIGN_VALUE (PlatformInfoHob->PcdPciMmio64Base, GetPowerOfTwo64 (PlatformInfoHob->PcdPciMmio64Size)); // // The useful address space ends with the 64-bit PCI host aperture. // FirstNonAddress = PlatformInfoHob->PcdPciMmio64Base + PlatformInfoHob->PcdPciMmio64Size; return FirstNonAddress; } /* * Use CPUID to figure physical address width. Does *not* work * reliable on qemu. For historical reasons qemu returns phys-bits=40 * even in case the host machine supports less than that. * * qemu has a cpu property (host-phys-bits={on,off}) to change that * and make sure guest phys-bits are not larger than host phys-bits., * but it is off by default. Exception: microvm machine type * hard-wires that property to on. */ VOID EFIAPI PlatformAddressWidthFromCpuid ( IN OUT EFI_HOB_PLATFORM_INFO *PlatformInfoHob ) { UINT32 RegEax; AsmCpuid (0x80000000, &RegEax, NULL, NULL, NULL); if (RegEax >= 0x80000008) { AsmCpuid (0x80000008, &RegEax, NULL, NULL, NULL); PlatformInfoHob->PhysMemAddressWidth = (UINT8)RegEax; } else { PlatformInfoHob->PhysMemAddressWidth = 36; } PlatformInfoHob->FirstNonAddress = LShiftU64 (1, PlatformInfoHob->PhysMemAddressWidth); DEBUG (( DEBUG_INFO, "%a: cpuid: phys-bits is %d\n", __FUNCTION__, PlatformInfoHob->PhysMemAddressWidth )); } /** Iterate over the PCI host bridges resources information optionally provided in fw-cfg and find the highest address contained in the PCI MMIO windows. If the information is found, return the exclusive end; one past the last usable address. @param[out] PciMmioAddressEnd Pointer to one-after End Address updated with information extracted from host-provided data or zero if no information available or an error happened @retval EFI_SUCCESS PCI information was read and the output parameter updated with the last valid address in the 64-bit MMIO range. @retval EFI_INVALID_PARAMETER Pointer parameter is invalid @retval EFI_INCOMPATIBLE_VERSION Hardware information found in fw-cfg has an incompatible format @retval EFI_UNSUPPORTED Fw-cfg is not supported, thus host provided information, if any, cannot be read @retval EFI_NOT_FOUND No PCI host bridge information provided by the host. **/ STATIC EFI_STATUS PlatformScanHostProvided64BitPciMmioEnd ( OUT UINT64 *PciMmioAddressEnd ) { EFI_STATUS Status; HOST_BRIDGE_INFO HostBridge; FIRMWARE_CONFIG_ITEM FwCfgItem; UINTN FwCfgSize; UINTN FwCfgReadIndex; UINTN ReadDataSize; UINT64 Above4GMmioEnd; if (PciMmioAddressEnd == NULL) { return EFI_INVALID_PARAMETER; } *PciMmioAddressEnd = 0; Above4GMmioEnd = 0; Status = QemuFwCfgFindFile ("etc/hardware-info", &FwCfgItem, &FwCfgSize); if (EFI_ERROR (Status)) { return Status; } QemuFwCfgSelectItem (FwCfgItem); FwCfgReadIndex = 0; while (FwCfgReadIndex < FwCfgSize) { Status = QemuFwCfgReadNextHardwareInfoByType ( HardwareInfoTypeHostBridge, sizeof (HostBridge), FwCfgSize, &HostBridge, &ReadDataSize, &FwCfgReadIndex ); if (Status != EFI_SUCCESS) { // // No more data available to read in the file, break // loop and finish process // break; } Status = HardwareInfoPciHostBridgeLastMmioAddress ( &HostBridge, ReadDataSize, TRUE, &Above4GMmioEnd ); if (Status != EFI_SUCCESS) { // // Error parsing MMIO apertures and extracting last MMIO // address, reset PciMmioAddressEnd as if no information was // found, to avoid moving forward with incomplete data, and // bail out // DEBUG (( DEBUG_ERROR, "%a: ignoring malformed hardware information from fw_cfg\n", __FUNCTION__ )); *PciMmioAddressEnd = 0; return Status; } if (Above4GMmioEnd > *PciMmioAddressEnd) { *PciMmioAddressEnd = Above4GMmioEnd; } } if (*PciMmioAddressEnd > 0) { // // Host-provided PCI information was found and a MMIO window end // derived from it. // Increase the End address by one to have the output pointing to // one after the address in use (exclusive end). // *PciMmioAddressEnd += 1; DEBUG (( DEBUG_INFO, "%a: Pci64End=0x%Lx\n", __FUNCTION__, *PciMmioAddressEnd )); return EFI_SUCCESS; } return EFI_NOT_FOUND; } /** Initialize the PhysMemAddressWidth field in PlatformInfoHob based on guest RAM size. **/ VOID EFIAPI PlatformAddressWidthInitialization ( IN OUT EFI_HOB_PLATFORM_INFO *PlatformInfoHob ) { UINT64 FirstNonAddress; UINT8 PhysMemAddressWidth; EFI_STATUS Status; if (PlatformInfoHob->HostBridgeDevId == 0xffff /* microvm */) { PlatformAddressWidthFromCpuid (PlatformInfoHob); return; } // // First scan host-provided hardware information to assess if the address // space is already known. If so, guest must use those values. // Status = PlatformScanHostProvided64BitPciMmioEnd (&FirstNonAddress); if (EFI_ERROR (Status)) { // // If the host did not provide valid hardware information leading to a // hard-defined 64-bit MMIO end, fold back to calculating the minimum range // needed. // As guest-physical memory size grows, the permanent PEI RAM requirements // are dominated by the identity-mapping page tables built by the DXE IPL. // The DXL IPL keys off of the physical address bits advertized in the CPU // HOB. To conserve memory, we calculate the minimum address width here. // FirstNonAddress = PlatformGetFirstNonAddress (PlatformInfoHob); } PhysMemAddressWidth = (UINT8)HighBitSet64 (FirstNonAddress); // // If FirstNonAddress is not an integral power of two, then we need an // additional bit. // if ((FirstNonAddress & (FirstNonAddress - 1)) != 0) { ++PhysMemAddressWidth; } // // The minimum address width is 36 (covers up to and excluding 64 GB, which // is the maximum for Ia32 + PAE). The theoretical architecture maximum for // X64 long mode is 52 bits, but the DXE IPL clamps that down to 48 bits. We // can simply assert that here, since 48 bits are good enough for 256 TB. // if (PhysMemAddressWidth <= 36) { PhysMemAddressWidth = 36; } #if defined (MDE_CPU_X64) if (TdIsEnabled ()) { if (TdSharedPageMask () == (1ULL << 47)) { PhysMemAddressWidth = 48; } else { PhysMemAddressWidth = 52; } } ASSERT (PhysMemAddressWidth <= 52); #else ASSERT (PhysMemAddressWidth <= 48); #endif PlatformInfoHob->FirstNonAddress = FirstNonAddress; PlatformInfoHob->PhysMemAddressWidth = PhysMemAddressWidth; } STATIC VOID QemuInitializeRamBelow1gb ( IN EFI_HOB_PLATFORM_INFO *PlatformInfoHob ) { if (PlatformInfoHob->SmmSmramRequire && PlatformInfoHob->Q35SmramAtDefaultSmbase) { PlatformAddMemoryRangeHob (0, SMM_DEFAULT_SMBASE); PlatformAddReservedMemoryBaseSizeHob ( SMM_DEFAULT_SMBASE, MCH_DEFAULT_SMBASE_SIZE, TRUE /* Cacheable */ ); STATIC_ASSERT ( SMM_DEFAULT_SMBASE + MCH_DEFAULT_SMBASE_SIZE < BASE_512KB + BASE_128KB, "end of SMRAM at default SMBASE ends at, or exceeds, 640KB" ); PlatformAddMemoryRangeHob ( SMM_DEFAULT_SMBASE + MCH_DEFAULT_SMBASE_SIZE, BASE_512KB + BASE_128KB ); } else { PlatformAddMemoryRangeHob (0, BASE_512KB + BASE_128KB); } } /** Peform Memory Detection for QEMU / KVM **/ VOID EFIAPI PlatformQemuInitializeRam ( IN EFI_HOB_PLATFORM_INFO *PlatformInfoHob ) { UINT64 LowerMemorySize; UINT64 UpperMemorySize; MTRR_SETTINGS MtrrSettings; EFI_STATUS Status; DEBUG ((DEBUG_INFO, "%a called\n", __FUNCTION__)); // // Determine total memory size available // LowerMemorySize = PlatformGetSystemMemorySizeBelow4gb (PlatformInfoHob); if (PlatformInfoHob->BootMode == BOOT_ON_S3_RESUME) { // // Create the following memory HOB as an exception on the S3 boot path. // // Normally we'd create memory HOBs only on the normal boot path. However, // CpuMpPei specifically needs such a low-memory HOB on the S3 path as // well, for "borrowing" a subset of it temporarily, for the AP startup // vector. // // CpuMpPei saves the original contents of the borrowed area in permanent // PEI RAM, in a backup buffer allocated with the normal PEI services. // CpuMpPei restores the original contents ("returns" the borrowed area) at // End-of-PEI. End-of-PEI in turn is emitted by S3Resume2Pei before // transferring control to the OS's wakeup vector in the FACS. // // We expect any other PEIMs that "borrow" memory similarly to CpuMpPei to // restore the original contents. Furthermore, we expect all such PEIMs // (CpuMpPei included) to claim the borrowed areas by producing memory // allocation HOBs, and to honor preexistent memory allocation HOBs when // looking for an area to borrow. // QemuInitializeRamBelow1gb (PlatformInfoHob); } else { // // Create memory HOBs // QemuInitializeRamBelow1gb (PlatformInfoHob); if (PlatformInfoHob->SmmSmramRequire) { UINT32 TsegSize; TsegSize = PlatformInfoHob->Q35TsegMbytes * SIZE_1MB; PlatformAddMemoryRangeHob (BASE_1MB, LowerMemorySize - TsegSize); PlatformAddReservedMemoryBaseSizeHob ( LowerMemorySize - TsegSize, TsegSize, TRUE ); } else { PlatformAddMemoryRangeHob (BASE_1MB, LowerMemorySize); } // // If QEMU presents an E820 map, then create memory HOBs for the >=4GB RAM // entries. Otherwise, create a single memory HOB with the flat >=4GB // memory size read from the CMOS. // Status = PlatformScanOrAdd64BitE820Ram (TRUE, NULL, NULL); if (EFI_ERROR (Status)) { UpperMemorySize = PlatformGetSystemMemorySizeAbove4gb (); if (UpperMemorySize != 0) { PlatformAddMemoryBaseSizeHob (BASE_4GB, UpperMemorySize); } } } // // We'd like to keep the following ranges uncached: // - [640 KB, 1 MB) // - [LowerMemorySize, 4 GB) // // Everything else should be WB. Unfortunately, programming the inverse (ie. // keeping the default UC, and configuring the complement set of the above as // WB) is not reliable in general, because the end of the upper RAM can have // practically any alignment, and we may not have enough variable MTRRs to // cover it exactly. // if (IsMtrrSupported () && (PlatformInfoHob->HostBridgeDevId != CLOUDHV_DEVICE_ID)) { MtrrGetAllMtrrs (&MtrrSettings); // // MTRRs disabled, fixed MTRRs disabled, default type is uncached // ASSERT ((MtrrSettings.MtrrDefType & BIT11) == 0); ASSERT ((MtrrSettings.MtrrDefType & BIT10) == 0); ASSERT ((MtrrSettings.MtrrDefType & 0xFF) == 0); // // flip default type to writeback // SetMem (&MtrrSettings.Fixed, sizeof MtrrSettings.Fixed, 0x06); ZeroMem (&MtrrSettings.Variables, sizeof MtrrSettings.Variables); MtrrSettings.MtrrDefType |= BIT11 | BIT10 | 6; MtrrSetAllMtrrs (&MtrrSettings); // // Set memory range from 640KB to 1MB to uncacheable // Status = MtrrSetMemoryAttribute ( BASE_512KB + BASE_128KB, BASE_1MB - (BASE_512KB + BASE_128KB), CacheUncacheable ); ASSERT_EFI_ERROR (Status); // // Set the memory range from the start of the 32-bit MMIO area (32-bit PCI // MMIO aperture on i440fx, PCIEXBAR on q35) to 4GB as uncacheable. // Status = MtrrSetMemoryAttribute ( PlatformInfoHob->Uc32Base, SIZE_4GB - PlatformInfoHob->Uc32Base, CacheUncacheable ); ASSERT_EFI_ERROR (Status); } } VOID EFIAPI PlatformQemuInitializeRamForS3 ( IN EFI_HOB_PLATFORM_INFO *PlatformInfoHob ) { if (PlatformInfoHob->S3Supported && (PlatformInfoHob->BootMode != BOOT_ON_S3_RESUME)) { // // This is the memory range that will be used for PEI on S3 resume // BuildMemoryAllocationHob ( PlatformInfoHob->S3AcpiReservedMemoryBase, PlatformInfoHob->S3AcpiReservedMemorySize, EfiACPIMemoryNVS ); // // Cover the initial RAM area used as stack and temporary PEI heap. // // This is reserved as ACPI NVS so it can be used on S3 resume. // BuildMemoryAllocationHob ( PcdGet32 (PcdOvmfSecPeiTempRamBase), PcdGet32 (PcdOvmfSecPeiTempRamSize), EfiACPIMemoryNVS ); // // SEC stores its table of GUIDed section handlers here. // BuildMemoryAllocationHob ( PcdGet64 (PcdGuidedExtractHandlerTableAddress), PcdGet32 (PcdGuidedExtractHandlerTableSize), EfiACPIMemoryNVS ); #ifdef MDE_CPU_X64 // // Reserve the initial page tables built by the reset vector code. // // Since this memory range will be used by the Reset Vector on S3 // resume, it must be reserved as ACPI NVS. // BuildMemoryAllocationHob ( (EFI_PHYSICAL_ADDRESS)(UINTN)PcdGet32 (PcdOvmfSecPageTablesBase), (UINT64)(UINTN)PcdGet32 (PcdOvmfSecPageTablesSize), EfiACPIMemoryNVS ); if (PlatformInfoHob->SevEsIsEnabled) { // // If SEV-ES is enabled, reserve the GHCB-related memory area. This // includes the extra page table used to break down the 2MB page // mapping into 4KB page entries where the GHCB resides and the // GHCB area itself. // // Since this memory range will be used by the Reset Vector on S3 // resume, it must be reserved as ACPI NVS. // BuildMemoryAllocationHob ( (EFI_PHYSICAL_ADDRESS)(UINTN)PcdGet32 (PcdOvmfSecGhcbPageTableBase), (UINT64)(UINTN)PcdGet32 (PcdOvmfSecGhcbPageTableSize), EfiACPIMemoryNVS ); BuildMemoryAllocationHob ( (EFI_PHYSICAL_ADDRESS)(UINTN)PcdGet32 (PcdOvmfSecGhcbBase), (UINT64)(UINTN)PcdGet32 (PcdOvmfSecGhcbSize), EfiACPIMemoryNVS ); BuildMemoryAllocationHob ( (EFI_PHYSICAL_ADDRESS)(UINTN)PcdGet32 (PcdOvmfSecGhcbBackupBase), (UINT64)(UINTN)PcdGet32 (PcdOvmfSecGhcbBackupSize), EfiACPIMemoryNVS ); } #endif } if (PlatformInfoHob->BootMode != BOOT_ON_S3_RESUME) { if (!PlatformInfoHob->SmmSmramRequire) { // // Reserve the lock box storage area // // Since this memory range will be used on S3 resume, it must be // reserved as ACPI NVS. // // If S3 is unsupported, then various drivers might still write to the // LockBox area. We ought to prevent DXE from serving allocation requests // such that they would overlap the LockBox storage. // ZeroMem ( (VOID *)(UINTN)PcdGet32 (PcdOvmfLockBoxStorageBase), (UINTN)PcdGet32 (PcdOvmfLockBoxStorageSize) ); BuildMemoryAllocationHob ( (EFI_PHYSICAL_ADDRESS)(UINTN)PcdGet32 (PcdOvmfLockBoxStorageBase), (UINT64)(UINTN)PcdGet32 (PcdOvmfLockBoxStorageSize), PlatformInfoHob->S3Supported ? EfiACPIMemoryNVS : EfiBootServicesData ); } if (PlatformInfoHob->SmmSmramRequire) { UINT32 TsegSize; // // Make sure the TSEG area that we reported as a reserved memory resource // cannot be used for reserved memory allocations. // TsegSize = PlatformInfoHob->Q35TsegMbytes * SIZE_1MB; BuildMemoryAllocationHob ( PlatformGetSystemMemorySizeBelow4gb (PlatformInfoHob) - TsegSize, TsegSize, EfiReservedMemoryType ); // // Similarly, allocate away the (already reserved) SMRAM at the default // SMBASE, if it exists. // if (PlatformInfoHob->Q35SmramAtDefaultSmbase) { BuildMemoryAllocationHob ( SMM_DEFAULT_SMBASE, MCH_DEFAULT_SMBASE_SIZE, EfiReservedMemoryType ); } } #ifdef MDE_CPU_X64 if (FixedPcdGet32 (PcdOvmfWorkAreaSize) != 0) { // // Reserve the work area. // // Since this memory range will be used by the Reset Vector on S3 // resume, it must be reserved as ACPI NVS. // // If S3 is unsupported, then various drivers might still write to the // work area. We ought to prevent DXE from serving allocation requests // such that they would overlap the work area. // BuildMemoryAllocationHob ( (EFI_PHYSICAL_ADDRESS)(UINTN)FixedPcdGet32 (PcdOvmfWorkAreaBase), (UINT64)(UINTN)FixedPcdGet32 (PcdOvmfWorkAreaSize), PlatformInfoHob->S3Supported ? EfiACPIMemoryNVS : EfiBootServicesData ); } #endif } }