[edk2-devel] [PATCH v2 5/6] OvmfPkg: Copy LegacyBios protocol definitions from IntelFrameworkPkg
Wu, Hao A
hao.a.wu at intel.com
Tue Jun 11 01:43:12 UTC 2019
REF:https://bugzilla.tianocore.org/show_bug.cgi?id=1843
This commit copies the exact LegacyBios protocol header file from
IntelFrameworkPkg to OvmfPkg. Also, the protocol GUID definition is
duplicated in the OvmfPkg DEC file.
Cc: Ray Ni <ray.ni at intel.com>
Cc: Jordan Justen <jordan.l.justen at intel.com>
Cc: Laszlo Ersek <lersek at redhat.com>
Cc: Ard Biesheuvel <ard.biesheuvel at linaro.org>
Signed-off-by: Hao A Wu <hao.a.wu at intel.com>
---
OvmfPkg/OvmfPkg.dec | 1 +
OvmfPkg/Include/Protocol/LegacyBios.h | 1553 ++++++++++++++++++++
2 files changed, 1554 insertions(+)
diff --git a/OvmfPkg/OvmfPkg.dec b/OvmfPkg/OvmfPkg.dec
index 8d6a5ededc..fa58fa5160 100644
--- a/OvmfPkg/OvmfPkg.dec
+++ b/OvmfPkg/OvmfPkg.dec
@@ -86,6 +86,7 @@ [Protocols]
gXenIoProtocolGuid = {0x6efac84f, 0x0ab0, 0x4747, {0x81, 0xbe, 0x85, 0x55, 0x62, 0x59, 0x04, 0x49}}
gIoMmuAbsentProtocolGuid = {0xf8775d50, 0x8abd, 0x4adf, {0x92, 0xac, 0x85, 0x3e, 0x51, 0xf6, 0xc8, 0xdc}}
gEfiLegacy8259ProtocolGuid = {0x38321dba, 0x4fe0, 0x4e17, {0x8a, 0xec, 0x41, 0x30, 0x55, 0xea, 0xed, 0xc1}}
+ gEfiLegacyBiosProtocolGuid = {0xdb9a1e3d, 0x45cb, 0x4abb, {0x85, 0x3b, 0xe5, 0x38, 0x7f, 0xdb, 0x2e, 0x2d}}
[PcdsFixedAtBuild]
gUefiOvmfPkgTokenSpaceGuid.PcdOvmfPeiMemFvBase|0x0|UINT32|0
diff --git a/OvmfPkg/Include/Protocol/LegacyBios.h b/OvmfPkg/Include/Protocol/LegacyBios.h
new file mode 100644
index 0000000000..36761da397
--- /dev/null
+++ b/OvmfPkg/Include/Protocol/LegacyBios.h
@@ -0,0 +1,1553 @@
+/** @file
+ The EFI Legacy BIOS Protocol is used to abstract legacy Option ROM usage
+ under EFI and Legacy OS boot. This file also includes all the related
+ COMPATIBILIY16 structures and defintions.
+
+ Note: The names for EFI_IA32_REGISTER_SET elements were picked to follow
+ well known naming conventions.
+
+ Thunk is the code that switches from 32-bit protected environment into the 16-bit real-mode
+ environment. Reverse thunk is the code that does the opposite.
+
+Copyright (c) 2007 - 2018, Intel Corporation. All rights reserved.<BR>
+SPDX-License-Identifier: BSD-2-Clause-Patent
+
+ @par Revision Reference:
+ This protocol is defined in Framework for EFI Compatibility Support Module spec
+ Version 0.98.
+
+**/
+
+#ifndef _EFI_LEGACY_BIOS_H_
+#define _EFI_LEGACY_BIOS_H_
+
+///
+///
+///
+#pragma pack(1)
+
+typedef UINT8 SERIAL_MODE;
+typedef UINT8 PARALLEL_MODE;
+
+#define EFI_COMPATIBILITY16_TABLE_SIGNATURE SIGNATURE_32 ('I', 'F', 'E', '$')
+
+///
+/// There is a table located within the traditional BIOS in either the 0xF000:xxxx or 0xE000:xxxx
+/// physical address range. It is located on a 16-byte boundary and provides the physical address of the
+/// entry point for the Compatibility16 functions. These functions provide the platform-specific
+/// information that is required by the generic EfiCompatibility code. The functions are invoked via
+/// thunking by using EFI_LEGACY_BIOS_PROTOCOL.FarCall86() with the 32-bit physical
+/// entry point.
+///
+typedef struct {
+ ///
+ /// The string "$EFI" denotes the start of the EfiCompatibility table. Byte 0 is "I," byte
+ /// 1 is "F," byte 2 is "E," and byte 3 is "$" and is normally accessed as a DWORD or UINT32.
+ ///
+ UINT32 Signature;
+
+ ///
+ /// The value required such that byte checksum of TableLength equals zero.
+ ///
+ UINT8 TableChecksum;
+
+ ///
+ /// The length of this table.
+ ///
+ UINT8 TableLength;
+
+ ///
+ /// The major EFI revision for which this table was generated.
+ ///
+ UINT8 EfiMajorRevision;
+
+ ///
+ /// The minor EFI revision for which this table was generated.
+ ///
+ UINT8 EfiMinorRevision;
+
+ ///
+ /// The major revision of this table.
+ ///
+ UINT8 TableMajorRevision;
+
+ ///
+ /// The minor revision of this table.
+ ///
+ UINT8 TableMinorRevision;
+
+ ///
+ /// Reserved for future usage.
+ ///
+ UINT16 Reserved;
+
+ ///
+ /// The segment of the entry point within the traditional BIOS for Compatibility16 functions.
+ ///
+ UINT16 Compatibility16CallSegment;
+
+ ///
+ /// The offset of the entry point within the traditional BIOS for Compatibility16 functions.
+ ///
+ UINT16 Compatibility16CallOffset;
+
+ ///
+ /// The segment of the entry point within the traditional BIOS for EfiCompatibility
+ /// to invoke the PnP installation check.
+ ///
+ UINT16 PnPInstallationCheckSegment;
+
+ ///
+ /// The Offset of the entry point within the traditional BIOS for EfiCompatibility
+ /// to invoke the PnP installation check.
+ ///
+ UINT16 PnPInstallationCheckOffset;
+
+ ///
+ /// EFI system resources table. Type EFI_SYSTEM_TABLE is defined in the IntelPlatform
+ ///Innovation Framework for EFI Driver Execution Environment Core Interface Specification (DXE CIS).
+ ///
+ UINT32 EfiSystemTable;
+
+ ///
+ /// The address of an OEM-provided identifier string. The string is null terminated.
+ ///
+ UINT32 OemIdStringPointer;
+
+ ///
+ /// The 32-bit physical address where ACPI RSD PTR is stored within the traditional
+ /// BIOS. The remained of the ACPI tables are located at their EFI addresses. The size
+ /// reserved is the maximum for ACPI 2.0. The EfiCompatibility will fill in the ACPI
+ /// RSD PTR with either the ACPI 1.0b or 2.0 values.
+ ///
+ UINT32 AcpiRsdPtrPointer;
+
+ ///
+ /// The OEM revision number. Usage is undefined but provided for OEM module usage.
+ ///
+ UINT16 OemRevision;
+
+ ///
+ /// The 32-bit physical address where INT15 E820 data is stored within the traditional
+ /// BIOS. The EfiCompatibility code will fill in the E820Pointer value and copy the
+ /// data to the indicated area.
+ ///
+ UINT32 E820Pointer;
+
+ ///
+ /// The length of the E820 data and is filled in by the EfiCompatibility code.
+ ///
+ UINT32 E820Length;
+
+ ///
+ /// The 32-bit physical address where the $PIR table is stored in the traditional BIOS.
+ /// The EfiCompatibility code will fill in the IrqRoutingTablePointer value and
+ /// copy the data to the indicated area.
+ ///
+ UINT32 IrqRoutingTablePointer;
+
+ ///
+ /// The length of the $PIR table and is filled in by the EfiCompatibility code.
+ ///
+ UINT32 IrqRoutingTableLength;
+
+ ///
+ /// The 32-bit physical address where the MP table is stored in the traditional BIOS.
+ /// The EfiCompatibility code will fill in the MpTablePtr value and copy the data
+ /// to the indicated area.
+ ///
+ UINT32 MpTablePtr;
+
+ ///
+ /// The length of the MP table and is filled in by the EfiCompatibility code.
+ ///
+ UINT32 MpTableLength;
+
+ ///
+ /// The segment of the OEM-specific INT table/code.
+ ///
+ UINT16 OemIntSegment;
+
+ ///
+ /// The offset of the OEM-specific INT table/code.
+ ///
+ UINT16 OemIntOffset;
+
+ ///
+ /// The segment of the OEM-specific 32-bit table/code.
+ ///
+ UINT16 Oem32Segment;
+
+ ///
+ /// The offset of the OEM-specific 32-bit table/code.
+ ///
+ UINT16 Oem32Offset;
+
+ ///
+ /// The segment of the OEM-specific 16-bit table/code.
+ ///
+ UINT16 Oem16Segment;
+
+ ///
+ /// The offset of the OEM-specific 16-bit table/code.
+ ///
+ UINT16 Oem16Offset;
+
+ ///
+ /// The segment of the TPM binary passed to 16-bit CSM.
+ ///
+ UINT16 TpmSegment;
+
+ ///
+ /// The offset of the TPM binary passed to 16-bit CSM.
+ ///
+ UINT16 TpmOffset;
+
+ ///
+ /// A pointer to a string identifying the independent BIOS vendor.
+ ///
+ UINT32 IbvPointer;
+
+ ///
+ /// This field is NULL for all systems not supporting PCI Express. This field is the base
+ /// value of the start of the PCI Express memory-mapped configuration registers and
+ /// must be filled in prior to EfiCompatibility code issuing the Compatibility16 function
+ /// Compatibility16InitializeYourself().
+ /// Compatibility16InitializeYourself() is defined in Compatability16
+ /// Functions.
+ ///
+ UINT32 PciExpressBase;
+
+ ///
+ /// Maximum PCI bus number assigned.
+ ///
+ UINT8 LastPciBus;
+
+ ///
+ /// Start Address of Upper Memory Area (UMA) to be set as Read/Write. If
+ /// UmaAddress is a valid address in the shadow RAM, it also indicates that the region
+ /// from 0xC0000 to (UmaAddress - 1) can be used for Option ROM.
+ ///
+ UINT32 UmaAddress;
+
+ ///
+ /// Upper Memory Area size in bytes to be set as Read/Write. If zero, no UMA region
+ /// will be set as Read/Write (i.e. all Shadow RAM is set as Read-Only).
+ ///
+ UINT32 UmaSize;
+
+ ///
+ /// Start Address of high memory that can be used for permanent allocation. If zero,
+ /// high memory is not available for permanent allocation.
+ ///
+ UINT32 HiPermanentMemoryAddress;
+
+ ///
+ /// Size of high memory that can be used for permanent allocation in bytes. If zero,
+ /// high memory is not available for permanent allocation.
+ ///
+ UINT32 HiPermanentMemorySize;
+} EFI_COMPATIBILITY16_TABLE;
+
+///
+/// Functions provided by the CSM binary which communicate between the EfiCompatibility
+/// and Compatability16 code.
+///
+/// Inconsistent with the specification here:
+/// The member's name started with "Compatibility16" [defined in Intel Framework
+/// Compatibility Support Module Specification / 0.97 version]
+/// has been changed to "Legacy16" since keeping backward compatible.
+///
+typedef enum {
+ ///
+ /// Causes the Compatibility16 code to do any internal initialization required.
+ /// Input:
+ /// AX = Compatibility16InitializeYourself
+ /// ES:BX = Pointer to EFI_TO_COMPATIBILITY16_INIT_TABLE
+ /// Return:
+ /// AX = Return Status codes
+ ///
+ Legacy16InitializeYourself = 0x0000,
+
+ ///
+ /// Causes the Compatibility16 BIOS to perform any drive number translations to match the boot sequence.
+ /// Input:
+ /// AX = Compatibility16UpdateBbs
+ /// ES:BX = Pointer to EFI_TO_COMPATIBILITY16_BOOT_TABLE
+ /// Return:
+ /// AX = Returned status codes
+ ///
+ Legacy16UpdateBbs = 0x0001,
+
+ ///
+ /// Allows the Compatibility16 code to perform any final actions before booting. The Compatibility16
+ /// code is read/write.
+ /// Input:
+ /// AX = Compatibility16PrepareToBoot
+ /// ES:BX = Pointer to EFI_TO_COMPATIBILITY16_BOOT_TABLE structure
+ /// Return:
+ /// AX = Returned status codes
+ ///
+ Legacy16PrepareToBoot = 0x0002,
+
+ ///
+ /// Causes the Compatibility16 BIOS to boot. The Compatibility16 code is Read/Only.
+ /// Input:
+ /// AX = Compatibility16Boot
+ /// Output:
+ /// AX = Returned status codes
+ ///
+ Legacy16Boot = 0x0003,
+
+ ///
+ /// Allows the Compatibility16 code to get the last device from which a boot was attempted. This is
+ /// stored in CMOS and is the priority number of the last attempted boot device.
+ /// Input:
+ /// AX = Compatibility16RetrieveLastBootDevice
+ /// Output:
+ /// AX = Returned status codes
+ /// BX = Priority number of the boot device.
+ ///
+ Legacy16RetrieveLastBootDevice = 0x0004,
+
+ ///
+ /// Allows the Compatibility16 code rehook INT13, INT18, and/or INT19 after dispatching a legacy OpROM.
+ /// Input:
+ /// AX = Compatibility16DispatchOprom
+ /// ES:BX = Pointer to EFI_DISPATCH_OPROM_TABLE
+ /// Output:
+ /// AX = Returned status codes
+ /// BX = Number of non-BBS-compliant devices found. Equals 0 if BBS compliant.
+ ///
+ Legacy16DispatchOprom = 0x0005,
+
+ ///
+ /// Finds a free area in the 0xFxxxx or 0xExxxx region of the specified length and returns the address
+ /// of that region.
+ /// Input:
+ /// AX = Compatibility16GetTableAddress
+ /// BX = Allocation region
+ /// 00 = Allocate from either 0xE0000 or 0xF0000 64 KB blocks.
+ /// Bit 0 = 1 Allocate from 0xF0000 64 KB block
+ /// Bit 1 = 1 Allocate from 0xE0000 64 KB block
+ /// CX = Requested length in bytes.
+ /// DX = Required address alignment. Bit mapped. First non-zero bit from the right is the alignment.
+ /// Output:
+ /// AX = Returned status codes
+ /// DS:BX = Address of the region
+ ///
+ Legacy16GetTableAddress = 0x0006,
+
+ ///
+ /// Enables the EfiCompatibility module to do any nonstandard processing of keyboard LEDs or state.
+ /// Input:
+ /// AX = Compatibility16SetKeyboardLeds
+ /// CL = LED status.
+ /// Bit 0 Scroll Lock 0 = Off
+ /// Bit 1 NumLock
+ /// Bit 2 Caps Lock
+ /// Output:
+ /// AX = Returned status codes
+ ///
+ Legacy16SetKeyboardLeds = 0x0007,
+
+ ///
+ /// Enables the EfiCompatibility module to install an interrupt handler for PCI mass media devices that
+ /// do not have an OpROM associated with them. An example is SATA.
+ /// Input:
+ /// AX = Compatibility16InstallPciHandler
+ /// ES:BX = Pointer to EFI_LEGACY_INSTALL_PCI_HANDLER structure
+ /// Output:
+ /// AX = Returned status codes
+ ///
+ Legacy16InstallPciHandler = 0x0008
+} EFI_COMPATIBILITY_FUNCTIONS;
+
+
+///
+/// EFI_DISPATCH_OPROM_TABLE
+///
+typedef struct {
+ UINT16 PnPInstallationCheckSegment; ///< A pointer to the PnpInstallationCheck data structure.
+ UINT16 PnPInstallationCheckOffset; ///< A pointer to the PnpInstallationCheck data structure.
+ UINT16 OpromSegment; ///< The segment where the OpROM was placed. Offset is assumed to be 3.
+ UINT8 PciBus; ///< The PCI bus.
+ UINT8 PciDeviceFunction; ///< The PCI device * 0x08 | PCI function.
+ UINT8 NumberBbsEntries; ///< The number of valid BBS table entries upon entry and exit. The IBV code may
+ ///< increase this number, if BBS-compliant devices also hook INTs in order to force the
+ ///< OpROM BIOS Setup to be executed.
+ UINT32 BbsTablePointer; ///< A pointer to the BBS table.
+ UINT16 RuntimeSegment; ///< The segment where the OpROM can be relocated to. If this value is 0x0000, this
+ ///< means that the relocation of this run time code is not supported.
+ ///< Inconsistent with specification here:
+ ///< The member's name "OpromDestinationSegment" [defined in Intel Framework Compatibility Support Module Specification / 0.97 version]
+ ///< has been changed to "RuntimeSegment" since keeping backward compatible.
+
+} EFI_DISPATCH_OPROM_TABLE;
+
+///
+/// EFI_TO_COMPATIBILITY16_INIT_TABLE
+///
+typedef struct {
+ ///
+ /// Starting address of memory under 1 MB. The ending address is assumed to be 640 KB or 0x9FFFF.
+ ///
+ UINT32 BiosLessThan1MB;
+
+ ///
+ /// The starting address of the high memory block.
+ ///
+ UINT32 HiPmmMemory;
+
+ ///
+ /// The length of high memory block.
+ ///
+ UINT32 HiPmmMemorySizeInBytes;
+
+ ///
+ /// The segment of the reverse thunk call code.
+ ///
+ UINT16 ReverseThunkCallSegment;
+
+ ///
+ /// The offset of the reverse thunk call code.
+ ///
+ UINT16 ReverseThunkCallOffset;
+
+ ///
+ /// The number of E820 entries copied to the Compatibility16 BIOS.
+ ///
+ UINT32 NumberE820Entries;
+
+ ///
+ /// The amount of usable memory above 1 MB, e.g., E820 type 1 memory.
+ ///
+ UINT32 OsMemoryAbove1Mb;
+
+ ///
+ /// The start of thunk code in main memory. Memory cannot be used by BIOS or PMM.
+ ///
+ UINT32 ThunkStart;
+
+ ///
+ /// The size of the thunk code.
+ ///
+ UINT32 ThunkSizeInBytes;
+
+ ///
+ /// Starting address of memory under 1 MB.
+ ///
+ UINT32 LowPmmMemory;
+
+ ///
+ /// The length of low Memory block.
+ ///
+ UINT32 LowPmmMemorySizeInBytes;
+} EFI_TO_COMPATIBILITY16_INIT_TABLE;
+
+///
+/// DEVICE_PRODUCER_SERIAL.
+///
+typedef struct {
+ UINT16 Address; ///< I/O address assigned to the serial port.
+ UINT8 Irq; ///< IRQ assigned to the serial port.
+ SERIAL_MODE Mode; ///< Mode of serial port. Values are defined below.
+} DEVICE_PRODUCER_SERIAL;
+
+///
+/// DEVICE_PRODUCER_SERIAL's modes.
+///@{
+#define DEVICE_SERIAL_MODE_NORMAL 0x00
+#define DEVICE_SERIAL_MODE_IRDA 0x01
+#define DEVICE_SERIAL_MODE_ASK_IR 0x02
+#define DEVICE_SERIAL_MODE_DUPLEX_HALF 0x00
+#define DEVICE_SERIAL_MODE_DUPLEX_FULL 0x10
+///@)
+
+///
+/// DEVICE_PRODUCER_PARALLEL.
+///
+typedef struct {
+ UINT16 Address; ///< I/O address assigned to the parallel port.
+ UINT8 Irq; ///< IRQ assigned to the parallel port.
+ UINT8 Dma; ///< DMA assigned to the parallel port.
+ PARALLEL_MODE Mode; ///< Mode of the parallel port. Values are defined below.
+} DEVICE_PRODUCER_PARALLEL;
+
+///
+/// DEVICE_PRODUCER_PARALLEL's modes.
+///@{
+#define DEVICE_PARALLEL_MODE_MODE_OUTPUT_ONLY 0x00
+#define DEVICE_PARALLEL_MODE_MODE_BIDIRECTIONAL 0x01
+#define DEVICE_PARALLEL_MODE_MODE_EPP 0x02
+#define DEVICE_PARALLEL_MODE_MODE_ECP 0x03
+///@}
+
+///
+/// DEVICE_PRODUCER_FLOPPY
+///
+typedef struct {
+ UINT16 Address; ///< I/O address assigned to the floppy.
+ UINT8 Irq; ///< IRQ assigned to the floppy.
+ UINT8 Dma; ///< DMA assigned to the floppy.
+ UINT8 NumberOfFloppy; ///< Number of floppies in the system.
+} DEVICE_PRODUCER_FLOPPY;
+
+///
+/// LEGACY_DEVICE_FLAGS
+///
+typedef struct {
+ UINT32 A20Kybd : 1; ///< A20 controller by keyboard controller.
+ UINT32 A20Port90 : 1; ///< A20 controlled by port 0x92.
+ UINT32 Reserved : 30; ///< Reserved for future usage.
+} LEGACY_DEVICE_FLAGS;
+
+///
+/// DEVICE_PRODUCER_DATA_HEADER
+///
+typedef struct {
+ DEVICE_PRODUCER_SERIAL Serial[4]; ///< Data for serial port x. Type DEVICE_PRODUCER_SERIAL is defined below.
+ DEVICE_PRODUCER_PARALLEL Parallel[3]; ///< Data for parallel port x. Type DEVICE_PRODUCER_PARALLEL is defined below.
+ DEVICE_PRODUCER_FLOPPY Floppy; ///< Data for floppy. Type DEVICE_PRODUCER_FLOPPY is defined below.
+ UINT8 MousePresent; ///< Flag to indicate if mouse is present.
+ LEGACY_DEVICE_FLAGS Flags; ///< Miscellaneous Boolean state information passed to CSM.
+} DEVICE_PRODUCER_DATA_HEADER;
+
+///
+/// ATAPI_IDENTIFY
+///
+typedef struct {
+ UINT16 Raw[256]; ///< Raw data from the IDE IdentifyDrive command.
+} ATAPI_IDENTIFY;
+
+///
+/// HDD_INFO
+///
+typedef struct {
+ ///
+ /// Status of IDE device. Values are defined below. There is one HDD_INFO structure
+ /// per IDE controller. The IdentifyDrive is per drive. Index 0 is master and index
+ /// 1 is slave.
+ ///
+ UINT16 Status;
+
+ ///
+ /// PCI bus of IDE controller.
+ ///
+ UINT32 Bus;
+
+ ///
+ /// PCI device of IDE controller.
+ ///
+ UINT32 Device;
+
+ ///
+ /// PCI function of IDE controller.
+ ///
+ UINT32 Function;
+
+ ///
+ /// Command ports base address.
+ ///
+ UINT16 CommandBaseAddress;
+
+ ///
+ /// Control ports base address.
+ ///
+ UINT16 ControlBaseAddress;
+
+ ///
+ /// Bus master address.
+ ///
+ UINT16 BusMasterAddress;
+
+ UINT8 HddIrq;
+
+ ///
+ /// Data that identifies the drive data; one per possible attached drive.
+ ///
+ ATAPI_IDENTIFY IdentifyDrive[2];
+} HDD_INFO;
+
+///
+/// HDD_INFO status bits
+///
+#define HDD_PRIMARY 0x01
+#define HDD_SECONDARY 0x02
+#define HDD_MASTER_ATAPI_CDROM 0x04
+#define HDD_SLAVE_ATAPI_CDROM 0x08
+#define HDD_MASTER_IDE 0x20
+#define HDD_SLAVE_IDE 0x40
+#define HDD_MASTER_ATAPI_ZIPDISK 0x10
+#define HDD_SLAVE_ATAPI_ZIPDISK 0x80
+
+///
+/// BBS_STATUS_FLAGS;\.
+///
+typedef struct {
+ UINT16 OldPosition : 4; ///< Prior priority.
+ UINT16 Reserved1 : 4; ///< Reserved for future use.
+ UINT16 Enabled : 1; ///< If 0, ignore this entry.
+ UINT16 Failed : 1; ///< 0 = Not known if boot failure occurred.
+ ///< 1 = Boot attempted failed.
+
+ ///
+ /// State of media present.
+ /// 00 = No bootable media is present in the device.
+ /// 01 = Unknown if a bootable media present.
+ /// 10 = Media is present and appears bootable.
+ /// 11 = Reserved.
+ ///
+ UINT16 MediaPresent : 2;
+ UINT16 Reserved2 : 4; ///< Reserved for future use.
+} BBS_STATUS_FLAGS;
+
+///
+/// BBS_TABLE, device type values & boot priority values.
+///
+typedef struct {
+ ///
+ /// The boot priority for this boot device. Values are defined below.
+ ///
+ UINT16 BootPriority;
+
+ ///
+ /// The PCI bus for this boot device.
+ ///
+ UINT32 Bus;
+
+ ///
+ /// The PCI device for this boot device.
+ ///
+ UINT32 Device;
+
+ ///
+ /// The PCI function for the boot device.
+ ///
+ UINT32 Function;
+
+ ///
+ /// The PCI class for this boot device.
+ ///
+ UINT8 Class;
+
+ ///
+ /// The PCI Subclass for this boot device.
+ ///
+ UINT8 SubClass;
+
+ ///
+ /// Segment:offset address of an ASCIIZ description string describing the manufacturer.
+ ///
+ UINT16 MfgStringOffset;
+
+ ///
+ /// Segment:offset address of an ASCIIZ description string describing the manufacturer.
+ ///
+ UINT16 MfgStringSegment;
+
+ ///
+ /// BBS device type. BBS device types are defined below.
+ ///
+ UINT16 DeviceType;
+
+ ///
+ /// Status of this boot device. Type BBS_STATUS_FLAGS is defined below.
+ ///
+ BBS_STATUS_FLAGS StatusFlags;
+
+ ///
+ /// Segment:Offset address of boot loader for IPL devices or install INT13 handler for
+ /// BCV devices.
+ ///
+ UINT16 BootHandlerOffset;
+
+ ///
+ /// Segment:Offset address of boot loader for IPL devices or install INT13 handler for
+ /// BCV devices.
+ ///
+ UINT16 BootHandlerSegment;
+
+ ///
+ /// Segment:offset address of an ASCIIZ description string describing this device.
+ ///
+ UINT16 DescStringOffset;
+
+ ///
+ /// Segment:offset address of an ASCIIZ description string describing this device.
+ ///
+ UINT16 DescStringSegment;
+
+ ///
+ /// Reserved.
+ ///
+ UINT32 InitPerReserved;
+
+ ///
+ /// The use of these fields is IBV dependent. They can be used to flag that an OpROM
+ /// has hooked the specified IRQ. The OpROM may be BBS compliant as some SCSI
+ /// BBS-compliant OpROMs also hook IRQ vectors in order to run their BIOS Setup
+ ///
+ UINT32 AdditionalIrq13Handler;
+
+ ///
+ /// The use of these fields is IBV dependent. They can be used to flag that an OpROM
+ /// has hooked the specified IRQ. The OpROM may be BBS compliant as some SCSI
+ /// BBS-compliant OpROMs also hook IRQ vectors in order to run their BIOS Setup
+ ///
+ UINT32 AdditionalIrq18Handler;
+
+ ///
+ /// The use of these fields is IBV dependent. They can be used to flag that an OpROM
+ /// has hooked the specified IRQ. The OpROM may be BBS compliant as some SCSI
+ /// BBS-compliant OpROMs also hook IRQ vectors in order to run their BIOS Setup
+ ///
+ UINT32 AdditionalIrq19Handler;
+
+ ///
+ /// The use of these fields is IBV dependent. They can be used to flag that an OpROM
+ /// has hooked the specified IRQ. The OpROM may be BBS compliant as some SCSI
+ /// BBS-compliant OpROMs also hook IRQ vectors in order to run their BIOS Setup
+ ///
+ UINT32 AdditionalIrq40Handler;
+ UINT8 AssignedDriveNumber;
+ UINT32 AdditionalIrq41Handler;
+ UINT32 AdditionalIrq46Handler;
+ UINT32 IBV1;
+ UINT32 IBV2;
+} BBS_TABLE;
+
+///
+/// BBS device type values
+///@{
+#define BBS_FLOPPY 0x01
+#define BBS_HARDDISK 0x02
+#define BBS_CDROM 0x03
+#define BBS_PCMCIA 0x04
+#define BBS_USB 0x05
+#define BBS_EMBED_NETWORK 0x06
+#define BBS_BEV_DEVICE 0x80
+#define BBS_UNKNOWN 0xff
+///@}
+
+///
+/// BBS boot priority values
+///@{
+#define BBS_DO_NOT_BOOT_FROM 0xFFFC
+#define BBS_LOWEST_PRIORITY 0xFFFD
+#define BBS_UNPRIORITIZED_ENTRY 0xFFFE
+#define BBS_IGNORE_ENTRY 0xFFFF
+///@}
+
+///
+/// SMM_ATTRIBUTES
+///
+typedef struct {
+ ///
+ /// Access mechanism used to generate the soft SMI. Defined types are below. The other
+ /// values are reserved for future usage.
+ ///
+ UINT16 Type : 3;
+
+ ///
+ /// The size of "port" in bits. Defined values are below.
+ ///
+ UINT16 PortGranularity : 3;
+
+ ///
+ /// The size of data in bits. Defined values are below.
+ ///
+ UINT16 DataGranularity : 3;
+
+ ///
+ /// Reserved for future use.
+ ///
+ UINT16 Reserved : 7;
+} SMM_ATTRIBUTES;
+
+///
+/// SMM_ATTRIBUTES type values.
+///@{
+#define STANDARD_IO 0x00
+#define STANDARD_MEMORY 0x01
+///@}
+
+///
+/// SMM_ATTRIBUTES port size constants.
+///@{
+#define PORT_SIZE_8 0x00
+#define PORT_SIZE_16 0x01
+#define PORT_SIZE_32 0x02
+#define PORT_SIZE_64 0x03
+///@}
+
+///
+/// SMM_ATTRIBUTES data size constants.
+///@{
+#define DATA_SIZE_8 0x00
+#define DATA_SIZE_16 0x01
+#define DATA_SIZE_32 0x02
+#define DATA_SIZE_64 0x03
+///@}
+
+///
+/// SMM_FUNCTION & relating constants.
+///
+typedef struct {
+ UINT16 Function : 15;
+ UINT16 Owner : 1;
+} SMM_FUNCTION;
+
+///
+/// SMM_FUNCTION Function constants.
+///@{
+#define INT15_D042 0x0000
+#define GET_USB_BOOT_INFO 0x0001
+#define DMI_PNP_50_57 0x0002
+///@}
+
+///
+/// SMM_FUNCTION Owner constants.
+///@{
+#define STANDARD_OWNER 0x0
+#define OEM_OWNER 0x1
+///@}
+
+///
+/// This structure assumes both port and data sizes are 1. SmmAttribute must be
+/// properly to reflect that assumption.
+///
+typedef struct {
+ ///
+ /// Describes the access mechanism, SmmPort, and SmmData sizes. Type
+ /// SMM_ATTRIBUTES is defined below.
+ ///
+ SMM_ATTRIBUTES SmmAttributes;
+
+ ///
+ /// Function Soft SMI is to perform. Type SMM_FUNCTION is defined below.
+ ///
+ SMM_FUNCTION SmmFunction;
+
+ ///
+ /// SmmPort size depends upon SmmAttributes and ranges from2 bytes to 16 bytes.
+ ///
+ UINT8 SmmPort;
+
+ ///
+ /// SmmData size depends upon SmmAttributes and ranges from2 bytes to 16 bytes.
+ ///
+ UINT8 SmmData;
+} SMM_ENTRY;
+
+///
+/// SMM_TABLE
+///
+typedef struct {
+ UINT16 NumSmmEntries; ///< Number of entries represented by SmmEntry.
+ SMM_ENTRY SmmEntry; ///< One entry per function. Type SMM_ENTRY is defined below.
+} SMM_TABLE;
+
+///
+/// UDC_ATTRIBUTES
+///
+typedef struct {
+ ///
+ /// This bit set indicates that the ServiceAreaData is valid.
+ ///
+ UINT8 DirectoryServiceValidity : 1;
+
+ ///
+ /// This bit set indicates to use the Reserve Area Boot Code Address (RACBA) only if
+ /// DirectoryServiceValidity is 0.
+ ///
+ UINT8 RabcaUsedFlag : 1;
+
+ ///
+ /// This bit set indicates to execute hard disk diagnostics.
+ ///
+ UINT8 ExecuteHddDiagnosticsFlag : 1;
+
+ ///
+ /// Reserved for future use. Set to 0.
+ ///
+ UINT8 Reserved : 5;
+} UDC_ATTRIBUTES;
+
+///
+/// UD_TABLE
+///
+typedef struct {
+ ///
+ /// This field contains the bit-mapped attributes of the PARTIES information. Type
+ /// UDC_ATTRIBUTES is defined below.
+ ///
+ UDC_ATTRIBUTES Attributes;
+
+ ///
+ /// This field contains the zero-based device on which the selected
+ /// ServiceDataArea is present. It is 0 for master and 1 for the slave device.
+ ///
+ UINT8 DeviceNumber;
+
+ ///
+ /// This field contains the zero-based index into the BbsTable for the parent device.
+ /// This index allows the user to reference the parent device information such as PCI
+ /// bus, device function.
+ ///
+ UINT8 BbsTableEntryNumberForParentDevice;
+
+ ///
+ /// This field contains the zero-based index into the BbsTable for the boot entry.
+ ///
+ UINT8 BbsTableEntryNumberForBoot;
+
+ ///
+ /// This field contains the zero-based index into the BbsTable for the HDD diagnostics entry.
+ ///
+ UINT8 BbsTableEntryNumberForHddDiag;
+
+ ///
+ /// The raw Beer data.
+ ///
+ UINT8 BeerData[128];
+
+ ///
+ /// The raw data of selected service area.
+ ///
+ UINT8 ServiceAreaData[64];
+} UD_TABLE;
+
+#define EFI_TO_LEGACY_MAJOR_VERSION 0x02
+#define EFI_TO_LEGACY_MINOR_VERSION 0x00
+#define MAX_IDE_CONTROLLER 8
+
+///
+/// EFI_TO_COMPATIBILITY16_BOOT_TABLE
+///
+typedef struct {
+ UINT16 MajorVersion; ///< The EfiCompatibility major version number.
+ UINT16 MinorVersion; ///< The EfiCompatibility minor version number.
+ UINT32 AcpiTable; ///< The location of the RSDT ACPI table. < 4G range.
+ UINT32 SmbiosTable; ///< The location of the SMBIOS table in EFI memory. < 4G range.
+ UINT32 SmbiosTableLength;
+ //
+ // Legacy SIO state
+ //
+ DEVICE_PRODUCER_DATA_HEADER SioData; ///< Standard traditional device information.
+ UINT16 DevicePathType; ///< The default boot type.
+ UINT16 PciIrqMask; ///< Mask of which IRQs have been assigned to PCI.
+ UINT32 NumberE820Entries; ///< Number of E820 entries. The number can change from the
+ ///< Compatibility16InitializeYourself() function.
+ //
+ // Controller & Drive Identify[2] per controller information
+ //
+ HDD_INFO HddInfo[MAX_IDE_CONTROLLER]; ///< Hard disk drive information, including raw Identify Drive data.
+ UINT32 NumberBbsEntries; ///< Number of entries in the BBS table
+ UINT32 BbsTable; ///< A pointer to the BBS table. Type BBS_TABLE is defined below.
+ UINT32 SmmTable; ///< A pointer to the SMM table. Type SMM_TABLE is defined below.
+ UINT32 OsMemoryAbove1Mb; ///< The amount of usable memory above 1 MB, i.e. E820 type 1 memory. This value can
+ ///< differ from the value in EFI_TO_COMPATIBILITY16_INIT_TABLE as more
+ ///< memory may have been discovered.
+ UINT32 UnconventionalDeviceTable; ///< Information to boot off an unconventional device like a PARTIES partition. Type
+ ///< UD_TABLE is defined below.
+} EFI_TO_COMPATIBILITY16_BOOT_TABLE;
+
+///
+/// EFI_LEGACY_INSTALL_PCI_HANDLER
+///
+typedef struct {
+ UINT8 PciBus; ///< The PCI bus of the device.
+ UINT8 PciDeviceFun; ///< The PCI device in bits 7:3 and function in bits 2:0.
+ UINT8 PciSegment; ///< The PCI segment of the device.
+ UINT8 PciClass; ///< The PCI class code of the device.
+ UINT8 PciSubclass; ///< The PCI subclass code of the device.
+ UINT8 PciInterface; ///< The PCI interface code of the device.
+ //
+ // Primary section
+ //
+ UINT8 PrimaryIrq; ///< The primary device IRQ.
+ UINT8 PrimaryReserved; ///< Reserved.
+ UINT16 PrimaryControl; ///< The primary device control I/O base.
+ UINT16 PrimaryBase; ///< The primary device I/O base.
+ UINT16 PrimaryBusMaster; ///< The primary device bus master I/O base.
+ //
+ // Secondary Section
+ //
+ UINT8 SecondaryIrq; ///< The secondary device IRQ.
+ UINT8 SecondaryReserved; ///< Reserved.
+ UINT16 SecondaryControl; ///< The secondary device control I/O base.
+ UINT16 SecondaryBase; ///< The secondary device I/O base.
+ UINT16 SecondaryBusMaster; ///< The secondary device bus master I/O base.
+} EFI_LEGACY_INSTALL_PCI_HANDLER;
+
+//
+// Restore default pack value
+//
+#pragma pack()
+
+#define EFI_LEGACY_BIOS_PROTOCOL_GUID \
+ { \
+ 0xdb9a1e3d, 0x45cb, 0x4abb, {0x85, 0x3b, 0xe5, 0x38, 0x7f, 0xdb, 0x2e, 0x2d } \
+ }
+
+typedef struct _EFI_LEGACY_BIOS_PROTOCOL EFI_LEGACY_BIOS_PROTOCOL;
+
+///
+/// Flags returned by CheckPciRom().
+///
+#define NO_ROM 0x00
+#define ROM_FOUND 0x01
+#define VALID_LEGACY_ROM 0x02
+#define ROM_WITH_CONFIG 0x04 ///< Not defined in the Framework CSM Specification.
+
+///
+/// The following macros do not appear in the Framework CSM Specification and
+/// are kept for backward compatibility only. They convert 32-bit address (_Adr)
+/// to Segment:Offset 16-bit form.
+///
+///@{
+#define EFI_SEGMENT(_Adr) (UINT16) ((UINT16) (((UINTN) (_Adr)) >> 4) & 0xf000)
+#define EFI_OFFSET(_Adr) (UINT16) (((UINT16) ((UINTN) (_Adr))) & 0xffff)
+///@}
+
+#define CARRY_FLAG 0x01
+
+///
+/// EFI_EFLAGS_REG
+///
+typedef struct {
+ UINT32 CF:1;
+ UINT32 Reserved1:1;
+ UINT32 PF:1;
+ UINT32 Reserved2:1;
+ UINT32 AF:1;
+ UINT32 Reserved3:1;
+ UINT32 ZF:1;
+ UINT32 SF:1;
+ UINT32 TF:1;
+ UINT32 IF:1;
+ UINT32 DF:1;
+ UINT32 OF:1;
+ UINT32 IOPL:2;
+ UINT32 NT:1;
+ UINT32 Reserved4:2;
+ UINT32 VM:1;
+ UINT32 Reserved5:14;
+} EFI_EFLAGS_REG;
+
+///
+/// EFI_DWORD_REGS
+///
+typedef struct {
+ UINT32 EAX;
+ UINT32 EBX;
+ UINT32 ECX;
+ UINT32 EDX;
+ UINT32 ESI;
+ UINT32 EDI;
+ EFI_EFLAGS_REG EFlags;
+ UINT16 ES;
+ UINT16 CS;
+ UINT16 SS;
+ UINT16 DS;
+ UINT16 FS;
+ UINT16 GS;
+ UINT32 EBP;
+ UINT32 ESP;
+} EFI_DWORD_REGS;
+
+///
+/// EFI_FLAGS_REG
+///
+typedef struct {
+ UINT16 CF:1;
+ UINT16 Reserved1:1;
+ UINT16 PF:1;
+ UINT16 Reserved2:1;
+ UINT16 AF:1;
+ UINT16 Reserved3:1;
+ UINT16 ZF:1;
+ UINT16 SF:1;
+ UINT16 TF:1;
+ UINT16 IF:1;
+ UINT16 DF:1;
+ UINT16 OF:1;
+ UINT16 IOPL:2;
+ UINT16 NT:1;
+ UINT16 Reserved4:1;
+} EFI_FLAGS_REG;
+
+///
+/// EFI_WORD_REGS
+///
+typedef struct {
+ UINT16 AX;
+ UINT16 ReservedAX;
+ UINT16 BX;
+ UINT16 ReservedBX;
+ UINT16 CX;
+ UINT16 ReservedCX;
+ UINT16 DX;
+ UINT16 ReservedDX;
+ UINT16 SI;
+ UINT16 ReservedSI;
+ UINT16 DI;
+ UINT16 ReservedDI;
+ EFI_FLAGS_REG Flags;
+ UINT16 ReservedFlags;
+ UINT16 ES;
+ UINT16 CS;
+ UINT16 SS;
+ UINT16 DS;
+ UINT16 FS;
+ UINT16 GS;
+ UINT16 BP;
+ UINT16 ReservedBP;
+ UINT16 SP;
+ UINT16 ReservedSP;
+} EFI_WORD_REGS;
+
+///
+/// EFI_BYTE_REGS
+///
+typedef struct {
+ UINT8 AL, AH;
+ UINT16 ReservedAX;
+ UINT8 BL, BH;
+ UINT16 ReservedBX;
+ UINT8 CL, CH;
+ UINT16 ReservedCX;
+ UINT8 DL, DH;
+ UINT16 ReservedDX;
+} EFI_BYTE_REGS;
+
+///
+/// EFI_IA32_REGISTER_SET
+///
+typedef union {
+ EFI_DWORD_REGS E;
+ EFI_WORD_REGS X;
+ EFI_BYTE_REGS H;
+} EFI_IA32_REGISTER_SET;
+
+/**
+ Thunk to 16-bit real mode and execute a software interrupt with a vector
+ of BiosInt. Regs will contain the 16-bit register context on entry and
+ exit.
+
+ @param[in] This The protocol instance pointer.
+ @param[in] BiosInt The processor interrupt vector to invoke.
+ @param[in,out] Reg Register contexted passed into (and returned) from thunk to
+ 16-bit mode.
+
+ @retval TRUE Thunk completed with no BIOS errors in the target code. See Regs for status.
+ @retval FALSE There was a BIOS error in the target code.
+**/
+typedef
+BOOLEAN
+(EFIAPI *EFI_LEGACY_BIOS_INT86)(
+ IN EFI_LEGACY_BIOS_PROTOCOL *This,
+ IN UINT8 BiosInt,
+ IN OUT EFI_IA32_REGISTER_SET *Regs
+ );
+
+/**
+ Thunk to 16-bit real mode and call Segment:Offset. Regs will contain the
+ 16-bit register context on entry and exit. Arguments can be passed on
+ the Stack argument
+
+ @param[in] This The protocol instance pointer.
+ @param[in] Segment The segemnt of 16-bit mode call.
+ @param[in] Offset The offset of 16-bit mdoe call.
+ @param[in] Reg Register contexted passed into (and returned) from thunk to
+ 16-bit mode.
+ @param[in] Stack The caller allocated stack used to pass arguments.
+ @param[in] StackSize The size of Stack in bytes.
+
+ @retval FALSE Thunk completed with no BIOS errors in the target code. See Regs for status. @retval TRUE There was a BIOS error in the target code.
+**/
+typedef
+BOOLEAN
+(EFIAPI *EFI_LEGACY_BIOS_FARCALL86)(
+ IN EFI_LEGACY_BIOS_PROTOCOL *This,
+ IN UINT16 Segment,
+ IN UINT16 Offset,
+ IN EFI_IA32_REGISTER_SET *Regs,
+ IN VOID *Stack,
+ IN UINTN StackSize
+ );
+
+/**
+ Test to see if a legacy PCI ROM exists for this device. Optionally return
+ the Legacy ROM instance for this PCI device.
+
+ @param[in] This The protocol instance pointer.
+ @param[in] PciHandle The PCI PC-AT OPROM from this devices ROM BAR will be loaded
+ @param[out] RomImage Return the legacy PCI ROM for this device.
+ @param[out] RomSize The size of ROM Image.
+ @param[out] Flags Indicates if ROM found and if PC-AT. Multiple bits can be set as follows:
+ - 00 = No ROM.
+ - 01 = ROM Found.
+ - 02 = ROM is a valid legacy ROM.
+
+ @retval EFI_SUCCESS The Legacy Option ROM available for this device
+ @retval EFI_UNSUPPORTED The Legacy Option ROM is not supported.
+
+**/
+typedef
+EFI_STATUS
+(EFIAPI *EFI_LEGACY_BIOS_CHECK_ROM)(
+ IN EFI_LEGACY_BIOS_PROTOCOL *This,
+ IN EFI_HANDLE PciHandle,
+ OUT VOID **RomImage, OPTIONAL
+ OUT UINTN *RomSize, OPTIONAL
+ OUT UINTN *Flags
+ );
+
+/**
+ Load a legacy PC-AT OPROM on the PciHandle device. Return information
+ about how many disks were added by the OPROM and the shadow address and
+ size. DiskStart & DiskEnd are INT 13h drive letters. Thus 0x80 is C:
+
+ @param[in] This The protocol instance pointer.
+ @param[in] PciHandle The PCI PC-AT OPROM from this devices ROM BAR will be loaded.
+ This value is NULL if RomImage is non-NULL. This is the normal
+ case.
+ @param[in] RomImage A PCI PC-AT ROM image. This argument is non-NULL if there is
+ no hardware associated with the ROM and thus no PciHandle,
+ otherwise is must be NULL.
+ Example is PXE base code.
+ @param[out] Flags The type of ROM discovered. Multiple bits can be set, as follows:
+ - 00 = No ROM.
+ - 01 = ROM found.
+ - 02 = ROM is a valid legacy ROM.
+ @param[out] DiskStart The disk number of first device hooked by the ROM. If DiskStart
+ is the same as DiskEnd no disked were hooked.
+ @param[out] DiskEnd disk number of the last device hooked by the ROM.
+ @param[out] RomShadowAddress Shadow address of PC-AT ROM.
+ @param[out] RomShadowSize Size of RomShadowAddress in bytes.
+
+ @retval EFI_SUCCESS Thunk completed, see Regs for status.
+ @retval EFI_INVALID_PARAMETER PciHandle not found
+
+**/
+typedef
+EFI_STATUS
+(EFIAPI *EFI_LEGACY_BIOS_INSTALL_ROM)(
+ IN EFI_LEGACY_BIOS_PROTOCOL *This,
+ IN EFI_HANDLE PciHandle,
+ IN VOID **RomImage,
+ OUT UINTN *Flags,
+ OUT UINT8 *DiskStart, OPTIONAL
+ OUT UINT8 *DiskEnd, OPTIONAL
+ OUT VOID **RomShadowAddress, OPTIONAL
+ OUT UINT32 *ShadowedRomSize OPTIONAL
+ );
+
+/**
+ This function attempts to traditionally boot the specified BootOption. If the EFI context has
+ been compromised, this function will not return. This procedure is not used for loading an EFI-aware
+ OS off a traditional device. The following actions occur:
+ - Get EFI SMBIOS data structures, convert them to a traditional format, and copy to
+ Compatibility16.
+ - Get a pointer to ACPI data structures and copy the Compatibility16 RSD PTR to F0000 block.
+ - Find the traditional SMI handler from a firmware volume and register the traditional SMI
+ handler with the EFI SMI handler.
+ - Build onboard IDE information and pass this information to the Compatibility16 code.
+ - Make sure all PCI Interrupt Line registers are programmed to match 8259.
+ - Reconfigure SIO devices from EFI mode (polled) into traditional mode (interrupt driven).
+ - Shadow all PCI ROMs.
+ - Set up BDA and EBDA standard areas before the legacy boot.
+ - Construct the Compatibility16 boot memory map and pass it to the Compatibility16 code.
+ - Invoke the Compatibility16 table function Compatibility16PrepareToBoot(). This
+ invocation causes a thunk into the Compatibility16 code, which sets all appropriate internal
+ data structures. The boot device list is a parameter.
+ - Invoke the Compatibility16 Table function Compatibility16Boot(). This invocation
+ causes a thunk into the Compatibility16 code, which does an INT19.
+ - If the Compatibility16Boot() function returns, then the boot failed in a graceful
+ manner--meaning that the EFI code is still valid. An ungraceful boot failure causes a reset because the state
+ of EFI code is unknown.
+
+ @param[in] This The protocol instance pointer.
+ @param[in] BootOption The EFI Device Path from BootXXXX variable.
+ @param[in] LoadOptionSize The size of LoadOption in size.
+ @param[in] LoadOption LThe oadOption from BootXXXX variable.
+
+ @retval EFI_DEVICE_ERROR Failed to boot from any boot device and memory is uncorrupted. Note: This function normally does not returns. It will either boot the OS or reset the system if memory has been "corrupted" by loading a boot sector and passing control to it.
+**/
+typedef
+EFI_STATUS
+(EFIAPI *EFI_LEGACY_BIOS_BOOT)(
+ IN EFI_LEGACY_BIOS_PROTOCOL *This,
+ IN BBS_BBS_DEVICE_PATH *BootOption,
+ IN UINT32 LoadOptionsSize,
+ IN VOID *LoadOptions
+ );
+
+/**
+ This function takes the Leds input parameter and sets/resets the BDA accordingly.
+ Leds is also passed to Compatibility16 code, in case any special processing is required.
+ This function is normally called from EFI Setup drivers that handle user-selectable
+ keyboard options such as boot with NUM LOCK on/off. This function does not
+ touch the keyboard or keyboard LEDs but only the BDA.
+
+ @param[in] This The protocol instance pointer.
+ @param[in] Leds The status of current Scroll, Num & Cap lock LEDS:
+ - Bit 0 is Scroll Lock 0 = Not locked.
+ - Bit 1 is Num Lock.
+ - Bit 2 is Caps Lock.
+
+ @retval EFI_SUCCESS The BDA was updated successfully.
+
+**/
+typedef
+EFI_STATUS
+(EFIAPI *EFI_LEGACY_BIOS_UPDATE_KEYBOARD_LED_STATUS)(
+ IN EFI_LEGACY_BIOS_PROTOCOL *This,
+ IN UINT8 Leds
+ );
+
+/**
+ Retrieve legacy BBS info and assign boot priority.
+
+ @param[in] This The protocol instance pointer.
+ @param[out] HddCount The number of HDD_INFO structures.
+ @param[out] HddInfo Onboard IDE controller information.
+ @param[out] BbsCount The number of BBS_TABLE structures.
+ @param[in,out] BbsTable Points to List of BBS_TABLE.
+
+ @retval EFI_SUCCESS Tables were returned.
+
+**/
+typedef
+EFI_STATUS
+(EFIAPI *EFI_LEGACY_BIOS_GET_BBS_INFO)(
+ IN EFI_LEGACY_BIOS_PROTOCOL *This,
+ OUT UINT16 *HddCount,
+ OUT HDD_INFO **HddInfo,
+ OUT UINT16 *BbsCount,
+ IN OUT BBS_TABLE **BbsTable
+ );
+
+/**
+ Assign drive number to legacy HDD drives prior to booting an EFI
+ aware OS so the OS can access drives without an EFI driver.
+
+ @param[in] This The protocol instance pointer.
+ @param[out] BbsCount The number of BBS_TABLE structures
+ @param[out] BbsTable List of BBS entries
+
+ @retval EFI_SUCCESS Drive numbers assigned.
+
+**/
+typedef
+EFI_STATUS
+(EFIAPI *EFI_LEGACY_BIOS_PREPARE_TO_BOOT_EFI)(
+ IN EFI_LEGACY_BIOS_PROTOCOL *This,
+ OUT UINT16 *BbsCount,
+ OUT BBS_TABLE **BbsTable
+ );
+
+/**
+ To boot from an unconventional device like parties and/or execute
+ HDD diagnostics.
+
+ @param[in] This The protocol instance pointer.
+ @param[in] Attributes How to interpret the other input parameters.
+ @param[in] BbsEntry The 0-based index into the BbsTable for the parent
+ device.
+ @param[in] BeerData A pointer to the 128 bytes of ram BEER data.
+ @param[in] ServiceAreaData A pointer to the 64 bytes of raw Service Area data. The
+ caller must provide a pointer to the specific Service
+ Area and not the start all Service Areas.
+
+ @retval EFI_INVALID_PARAMETER If error. Does NOT return if no error.
+
+**/
+typedef
+EFI_STATUS
+(EFIAPI *EFI_LEGACY_BIOS_BOOT_UNCONVENTIONAL_DEVICE)(
+ IN EFI_LEGACY_BIOS_PROTOCOL *This,
+ IN UDC_ATTRIBUTES Attributes,
+ IN UINTN BbsEntry,
+ IN VOID *BeerData,
+ IN VOID *ServiceAreaData
+ );
+
+/**
+ Shadow all legacy16 OPROMs that haven't been shadowed.
+ Warning: Use this with caution. This routine disconnects all EFI
+ drivers. If used externally, then the caller must re-connect EFI
+ drivers.
+
+ @param[in] This The protocol instance pointer.
+
+ @retval EFI_SUCCESS OPROMs were shadowed.
+
+**/
+typedef
+EFI_STATUS
+(EFIAPI *EFI_LEGACY_BIOS_SHADOW_ALL_LEGACY_OPROMS)(
+ IN EFI_LEGACY_BIOS_PROTOCOL *This
+ );
+
+/**
+ Get a region from the LegacyBios for S3 usage.
+
+ @param[in] This The protocol instance pointer.
+ @param[in] LegacyMemorySize The size of required region.
+ @param[in] Region The region to use.
+ 00 = Either 0xE0000 or 0xF0000 block.
+ - Bit0 = 1 0xF0000 block.
+ - Bit1 = 1 0xE0000 block.
+ @param[in] Alignment Address alignment. Bit mapped. The first non-zero
+ bit from right is alignment.
+ @param[out] LegacyMemoryAddress The Region Assigned
+
+ @retval EFI_SUCCESS The Region was assigned.
+ @retval EFI_ACCESS_DENIED The function was previously invoked.
+ @retval Other The Region was not assigned.
+
+**/
+typedef
+EFI_STATUS
+(EFIAPI *EFI_LEGACY_BIOS_GET_LEGACY_REGION)(
+ IN EFI_LEGACY_BIOS_PROTOCOL *This,
+ IN UINTN LegacyMemorySize,
+ IN UINTN Region,
+ IN UINTN Alignment,
+ OUT VOID **LegacyMemoryAddress
+ );
+
+/**
+ Get a region from the LegacyBios for Tiano usage. Can only be invoked once.
+
+ @param[in] This The protocol instance pointer.
+ @param[in] LegacyMemorySize The size of data to copy.
+ @param[in] LegacyMemoryAddress The Legacy Region destination address.
+ Note: must be in region assigned by
+ LegacyBiosGetLegacyRegion.
+ @param[in] LegacyMemorySourceAddress The source of the data to copy.
+
+ @retval EFI_SUCCESS The Region assigned.
+ @retval EFI_ACCESS_DENIED Destination was outside an assigned region.
+
+**/
+typedef
+EFI_STATUS
+(EFIAPI *EFI_LEGACY_BIOS_COPY_LEGACY_REGION)(
+ IN EFI_LEGACY_BIOS_PROTOCOL *This,
+ IN UINTN LegacyMemorySize,
+ IN VOID *LegacyMemoryAddress,
+ IN VOID *LegacyMemorySourceAddress
+ );
+
+///
+/// Abstracts the traditional BIOS from the rest of EFI. The LegacyBoot()
+/// member function allows the BDS to support booting a traditional OS.
+/// EFI thunks drivers that make EFI bindings for BIOS INT services use
+/// all the other member functions.
+///
+struct _EFI_LEGACY_BIOS_PROTOCOL {
+ ///
+ /// Performs traditional software INT. See the Int86() function description.
+ ///
+ EFI_LEGACY_BIOS_INT86 Int86;
+
+ ///
+ /// Performs a far call into Compatibility16 or traditional OpROM code.
+ ///
+ EFI_LEGACY_BIOS_FARCALL86 FarCall86;
+
+ ///
+ /// Checks if a traditional OpROM exists for this device.
+ ///
+ EFI_LEGACY_BIOS_CHECK_ROM CheckPciRom;
+
+ ///
+ /// Loads a traditional OpROM in traditional OpROM address space.
+ ///
+ EFI_LEGACY_BIOS_INSTALL_ROM InstallPciRom;
+
+ ///
+ /// Boots a traditional OS.
+ ///
+ EFI_LEGACY_BIOS_BOOT LegacyBoot;
+
+ ///
+ /// Updates BDA to reflect the current EFI keyboard LED status.
+ ///
+ EFI_LEGACY_BIOS_UPDATE_KEYBOARD_LED_STATUS UpdateKeyboardLedStatus;
+
+ ///
+ /// Allows an external agent, such as BIOS Setup, to get the BBS data.
+ ///
+ EFI_LEGACY_BIOS_GET_BBS_INFO GetBbsInfo;
+
+ ///
+ /// Causes all legacy OpROMs to be shadowed.
+ ///
+ EFI_LEGACY_BIOS_SHADOW_ALL_LEGACY_OPROMS ShadowAllLegacyOproms;
+
+ ///
+ /// Performs all actions prior to boot. Used when booting an EFI-aware OS
+ /// rather than a legacy OS.
+ ///
+ EFI_LEGACY_BIOS_PREPARE_TO_BOOT_EFI PrepareToBootEfi;
+
+ ///
+ /// Allows EFI to reserve an area in the 0xE0000 or 0xF0000 block.
+ ///
+ EFI_LEGACY_BIOS_GET_LEGACY_REGION GetLegacyRegion;
+
+ ///
+ /// Allows EFI to copy data to the area specified by GetLegacyRegion.
+ ///
+ EFI_LEGACY_BIOS_COPY_LEGACY_REGION CopyLegacyRegion;
+
+ ///
+ /// Allows the user to boot off an unconventional device such as a PARTIES partition.
+ ///
+ EFI_LEGACY_BIOS_BOOT_UNCONVENTIONAL_DEVICE BootUnconventionalDevice;
+};
+
+//
+// Legacy BIOS needs to access memory in page 0 (0-4095), which is disabled if
+// NULL pointer detection feature is enabled. Following macro can be used to
+// enable/disable page 0 before/after accessing it.
+//
+#define ACCESS_PAGE0_CODE(statements) \
+ do { \
+ EFI_STATUS Status_; \
+ EFI_GCD_MEMORY_SPACE_DESCRIPTOR Desc_; \
+ \
+ Desc_.Attributes = 0; \
+ Status_ = gDS->GetMemorySpaceDescriptor (0, &Desc_); \
+ ASSERT_EFI_ERROR (Status_); \
+ if ((Desc_.Attributes & EFI_MEMORY_RP) != 0) { \
+ Status_ = gDS->SetMemorySpaceAttributes ( \
+ 0, \
+ EFI_PAGES_TO_SIZE(1), \
+ Desc_.Attributes & ~(UINT64)EFI_MEMORY_RP \
+ ); \
+ ASSERT_EFI_ERROR (Status_); \
+ } \
+ \
+ { \
+ statements; \
+ } \
+ \
+ if ((Desc_.Attributes & EFI_MEMORY_RP) != 0) { \
+ Status_ = gDS->SetMemorySpaceAttributes ( \
+ 0, \
+ EFI_PAGES_TO_SIZE(1), \
+ Desc_.Attributes \
+ ); \
+ ASSERT_EFI_ERROR (Status_); \
+ } \
+ } while (FALSE)
+
+extern EFI_GUID gEfiLegacyBiosProtocolGuid;
+
+#endif
--
2.12.0.windows.1
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