HardenedBSD/lib/libefivar/efivar-dp-parse.c
Warner Losh 1d386b48a5 Remove $FreeBSD$: one-line .c pattern
Remove /^[\s*]*__FBSDID\("\$FreeBSD\$"\);?\s*\n/
2023-08-16 11:54:42 -06:00

3885 lines
109 KiB
C

/*-
* Copyright (c) 2017 Netflix, Inc.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
/*
* Routines to format EFI_DEVICE_PATHs from the UEFI standard. Much of
* this file is taken from EDK2 and rototilled.
*/
#include <sys/cdefs.h>
#include <ctype.h>
#include <efivar.h>
#include <stdio.h>
#include <string.h>
#include <wchar.h>
#include "efichar.h"
#include "efi-osdep.h"
#include "efivar-dp.h"
#include "uefi-dplib.h"
/* XXX STUBS -- this stuff doesn't work yet */
#define StrToIpv4Address(str, unk, ipv4ptr, unk2) (void)(str)
#define StrToIpv6Address(str, unk, ipv6ptr, unk2) (void)(str)
/*
* OK. Now this is evil. Can't typedef it again. Sure beats changing them all.
* Since we're doing it all as narrow characters since wchar_t can't be used on
* FreeBSD and CHAR16 strings generally aren't a good fit. Since this parsing
* doesn't need Unicode for anything, this works out well.
*/
#define CHAR16 char
/*
* Taken from MdePkg/Library/UefiDevicePathLib/DevicePathFromText.c
*/
/** @file
DevicePathFromText protocol as defined in the UEFI 2.0 specification.
Copyright (c) 2013 - 2018, Intel Corporation. All rights reserved.<BR>
SPDX-License-Identifier: BSD-2-Clause-Patent
**/
// #include "UefiDevicePathLib.h"
/**
Duplicates a string.
@param Src Source string.
@return The duplicated string.
**/
static
CHAR16 *
UefiDevicePathLibStrDuplicate (
IN CONST CHAR16 *Src
)
{
return AllocateCopyPool (StrSize (Src), Src);
}
/**
Get parameter in a pair of parentheses follow the given node name.
For example, given the "Pci(0,1)" and NodeName "Pci", it returns "0,1".
@param Str Device Path Text.
@param NodeName Name of the node.
@return Parameter text for the node.
**/
static
CHAR16 *
GetParamByNodeName (
IN CHAR16 *Str,
IN const CHAR16 *NodeName
)
{
CHAR16 *ParamStr;
CHAR16 *StrPointer;
UINTN NodeNameLength;
UINTN ParameterLength;
//
// Check whether the node name matchs
//
NodeNameLength = StrLen (NodeName);
if (StrnCmp (Str, NodeName, NodeNameLength) != 0) {
return NULL;
}
ParamStr = Str + NodeNameLength;
if (!IS_LEFT_PARENTH (*ParamStr)) {
return NULL;
}
//
// Skip the found '(' and find first occurrence of ')'
//
ParamStr++;
ParameterLength = 0;
StrPointer = ParamStr;
while (!IS_NULL (*StrPointer)) {
if (IS_RIGHT_PARENTH (*StrPointer)) {
break;
}
StrPointer++;
ParameterLength++;
}
if (IS_NULL (*StrPointer)) {
//
// ')' not found
//
return NULL;
}
ParamStr = AllocateCopyPool ((ParameterLength + 1) * sizeof (CHAR16), ParamStr);
if (ParamStr == NULL) {
return NULL;
}
//
// Terminate the parameter string
//
ParamStr[ParameterLength] = '\0';
return ParamStr;
}
/**
Gets current sub-string from a string list, before return
the list header is moved to next sub-string. The sub-string is separated
by the specified character. For example, the separator is ',', the string
list is "2,0,3", it returns "2", the remain list move to "0,3"
@param List A string list separated by the specified separator
@param Separator The separator character
@return A pointer to the current sub-string
**/
static
CHAR16 *
SplitStr (
IN OUT CHAR16 **List,
IN CHAR16 Separator
)
{
CHAR16 *Str;
CHAR16 *ReturnStr;
Str = *List;
ReturnStr = Str;
if (IS_NULL (*Str)) {
return ReturnStr;
}
//
// Find first occurrence of the separator
//
while (!IS_NULL (*Str)) {
if (*Str == Separator) {
break;
}
Str++;
}
if (*Str == Separator) {
//
// Find a sub-string, terminate it
//
*Str = '\0';
Str++;
}
//
// Move to next sub-string
//
*List = Str;
return ReturnStr;
}
/**
Gets the next parameter string from the list.
@param List A string list separated by the specified separator
@return A pointer to the current sub-string
**/
static
CHAR16 *
GetNextParamStr (
IN OUT CHAR16 **List
)
{
//
// The separator is comma
//
return SplitStr (List, ',');
}
/**
Get one device node from entire device path text.
@param DevicePath On input, the current Device Path node; on output, the next device path node
@param IsInstanceEnd This node is the end of a device path instance
@return A device node text or NULL if no more device node available
**/
static
CHAR16 *
GetNextDeviceNodeStr (
IN OUT CHAR16 **DevicePath,
OUT BOOLEAN *IsInstanceEnd
)
{
CHAR16 *Str;
CHAR16 *ReturnStr;
UINTN ParenthesesStack;
Str = *DevicePath;
if (IS_NULL (*Str)) {
return NULL;
}
//
// Skip the leading '/', '(', ')' and ','
//
while (!IS_NULL (*Str)) {
if (!IS_SLASH (*Str) &&
!IS_COMMA (*Str) &&
!IS_LEFT_PARENTH (*Str) &&
!IS_RIGHT_PARENTH (*Str))
{
break;
}
Str++;
}
ReturnStr = Str;
//
// Scan for the separator of this device node, '/' or ','
//
ParenthesesStack = 0;
while (!IS_NULL (*Str)) {
if ((IS_COMMA (*Str) || IS_SLASH (*Str)) && (ParenthesesStack == 0)) {
break;
}
if (IS_LEFT_PARENTH (*Str)) {
ParenthesesStack++;
} else if (IS_RIGHT_PARENTH (*Str)) {
ParenthesesStack--;
}
Str++;
}
if (ParenthesesStack != 0) {
//
// The '(' doesn't pair with ')', invalid device path text
//
return NULL;
}
if (IS_COMMA (*Str)) {
*IsInstanceEnd = TRUE;
*Str = '\0';
Str++;
} else {
*IsInstanceEnd = FALSE;
if (!IS_NULL (*Str)) {
*Str = '\0';
Str++;
}
}
*DevicePath = Str;
return ReturnStr;
}
#ifndef __FreeBSD__
/**
Return whether the integer string is a hex string.
@param Str The integer string
@retval TRUE Hex string
@retval FALSE Decimal string
**/
static
BOOLEAN
IsHexStr (
IN CHAR16 *Str
)
{
//
// skip preceeding white space
//
while ((*Str != 0) && *Str == ' ') {
Str++;
}
//
// skip preceeding zeros
//
while ((*Str != 0) && *Str == '0') {
Str++;
}
return (BOOLEAN)(*Str == 'x' || *Str == 'X');
}
/**
Convert integer string to uint.
@param Str The integer string. If leading with "0x" or "0X", it's hexadecimal.
@return A UINTN value represented by Str
**/
static
UINTN
Strtoi (
IN CHAR16 *Str
)
{
if (IsHexStr (Str)) {
return StrHexToUintn (Str);
} else {
return StrDecimalToUintn (Str);
}
}
/**
Convert integer string to 64 bit data.
@param Str The integer string. If leading with "0x" or "0X", it's hexadecimal.
@param Data A pointer to the UINT64 value represented by Str
**/
static
VOID
Strtoi64 (
IN CHAR16 *Str,
OUT UINT64 *Data
)
{
if (IsHexStr (Str)) {
*Data = StrHexToUint64 (Str);
} else {
*Data = StrDecimalToUint64 (Str);
}
}
#endif
/**
Converts a Unicode string to ASCII string.
@param Str The equivalent Unicode string
@param AsciiStr On input, it points to destination ASCII string buffer; on output, it points
to the next ASCII string next to it
**/
static
VOID
StrToAscii (
IN CHAR16 *Str,
IN OUT CHAR8 **AsciiStr
)
{
CHAR8 *Dest;
Dest = *AsciiStr;
while (!IS_NULL (*Str)) {
*(Dest++) = (CHAR8)*(Str++);
}
*Dest = 0;
//
// Return the string next to it
//
*AsciiStr = Dest + 1;
}
/**
Converts a generic text device path node to device path structure.
@param Type The type of the device path node.
@param TextDeviceNode The input text device path node.
@return A pointer to device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextGenericPath (
IN UINT8 Type,
IN CHAR16 *TextDeviceNode
)
{
EFI_DEVICE_PATH_PROTOCOL *Node;
CHAR16 *SubtypeStr;
CHAR16 *DataStr;
UINTN DataLength;
SubtypeStr = GetNextParamStr (&TextDeviceNode);
DataStr = GetNextParamStr (&TextDeviceNode);
if (DataStr == NULL) {
DataLength = 0;
} else {
DataLength = StrLen (DataStr) / 2;
}
Node = CreateDeviceNode (
Type,
(UINT8)Strtoi (SubtypeStr),
(UINT16)(sizeof (EFI_DEVICE_PATH_PROTOCOL) + DataLength)
);
StrHexToBytes (DataStr, DataLength * 2, (UINT8 *)(Node + 1), DataLength);
return Node;
}
/**
Converts a generic text device path node to device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextPath (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *TypeStr;
TypeStr = GetNextParamStr (&TextDeviceNode);
return DevPathFromTextGenericPath ((UINT8)Strtoi (TypeStr), TextDeviceNode);
}
/**
Converts a generic hardware text device path node to Hardware device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to Hardware device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextHardwarePath (
IN CHAR16 *TextDeviceNode
)
{
return DevPathFromTextGenericPath (HARDWARE_DEVICE_PATH, TextDeviceNode);
}
/**
Converts a text device path node to Hardware PCI device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to Hardware PCI device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextPci (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *FunctionStr;
CHAR16 *DeviceStr;
PCI_DEVICE_PATH *Pci;
DeviceStr = GetNextParamStr (&TextDeviceNode);
FunctionStr = GetNextParamStr (&TextDeviceNode);
Pci = (PCI_DEVICE_PATH *)CreateDeviceNode (
HARDWARE_DEVICE_PATH,
HW_PCI_DP,
(UINT16)sizeof (PCI_DEVICE_PATH)
);
Pci->Function = (UINT8)Strtoi (FunctionStr);
Pci->Device = (UINT8)Strtoi (DeviceStr);
return (EFI_DEVICE_PATH_PROTOCOL *)Pci;
}
/**
Converts a text device path node to Hardware PC card device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to Hardware PC card device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextPcCard (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *FunctionNumberStr;
PCCARD_DEVICE_PATH *Pccard;
FunctionNumberStr = GetNextParamStr (&TextDeviceNode);
Pccard = (PCCARD_DEVICE_PATH *)CreateDeviceNode (
HARDWARE_DEVICE_PATH,
HW_PCCARD_DP,
(UINT16)sizeof (PCCARD_DEVICE_PATH)
);
Pccard->FunctionNumber = (UINT8)Strtoi (FunctionNumberStr);
return (EFI_DEVICE_PATH_PROTOCOL *)Pccard;
}
/**
Converts a text device path node to Hardware memory map device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to Hardware memory map device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextMemoryMapped (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *MemoryTypeStr;
CHAR16 *StartingAddressStr;
CHAR16 *EndingAddressStr;
MEMMAP_DEVICE_PATH *MemMap;
MemoryTypeStr = GetNextParamStr (&TextDeviceNode);
StartingAddressStr = GetNextParamStr (&TextDeviceNode);
EndingAddressStr = GetNextParamStr (&TextDeviceNode);
MemMap = (MEMMAP_DEVICE_PATH *)CreateDeviceNode (
HARDWARE_DEVICE_PATH,
HW_MEMMAP_DP,
(UINT16)sizeof (MEMMAP_DEVICE_PATH)
);
MemMap->MemoryType = (UINT32)Strtoi (MemoryTypeStr);
Strtoi64 (StartingAddressStr, &MemMap->StartingAddress);
Strtoi64 (EndingAddressStr, &MemMap->EndingAddress);
return (EFI_DEVICE_PATH_PROTOCOL *)MemMap;
}
/**
Converts a text device path node to Vendor device path structure based on the input Type
and SubType.
@param TextDeviceNode The input Text device path node.
@param Type The type of device path node.
@param SubType The subtype of device path node.
@return A pointer to the newly-created Vendor device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
ConvertFromTextVendor (
IN CHAR16 *TextDeviceNode,
IN UINT8 Type,
IN UINT8 SubType
)
{
CHAR16 *GuidStr;
CHAR16 *DataStr;
UINTN Length;
VENDOR_DEVICE_PATH *Vendor;
GuidStr = GetNextParamStr (&TextDeviceNode);
DataStr = GetNextParamStr (&TextDeviceNode);
Length = StrLen (DataStr);
//
// Two hex characters make up 1 buffer byte
//
Length = (Length + 1) / 2;
Vendor = (VENDOR_DEVICE_PATH *)CreateDeviceNode (
Type,
SubType,
(UINT16)(sizeof (VENDOR_DEVICE_PATH) + Length)
);
StrToGuid (GuidStr, &Vendor->Guid);
StrHexToBytes (DataStr, Length * 2, (UINT8 *)(Vendor + 1), Length);
return (EFI_DEVICE_PATH_PROTOCOL *)Vendor;
}
/**
Converts a text device path node to Vendor Hardware device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Vendor Hardware device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextVenHw (
IN CHAR16 *TextDeviceNode
)
{
return ConvertFromTextVendor (
TextDeviceNode,
HARDWARE_DEVICE_PATH,
HW_VENDOR_DP
);
}
/**
Converts a text device path node to Hardware Controller device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Hardware Controller device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextCtrl (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *ControllerStr;
CONTROLLER_DEVICE_PATH *Controller;
ControllerStr = GetNextParamStr (&TextDeviceNode);
Controller = (CONTROLLER_DEVICE_PATH *)CreateDeviceNode (
HARDWARE_DEVICE_PATH,
HW_CONTROLLER_DP,
(UINT16)sizeof (CONTROLLER_DEVICE_PATH)
);
Controller->ControllerNumber = (UINT32)Strtoi (ControllerStr);
return (EFI_DEVICE_PATH_PROTOCOL *)Controller;
}
/**
Converts a text device path node to BMC device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created BMC device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextBmc (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *InterfaceTypeStr;
CHAR16 *BaseAddressStr;
BMC_DEVICE_PATH *BmcDp;
InterfaceTypeStr = GetNextParamStr (&TextDeviceNode);
BaseAddressStr = GetNextParamStr (&TextDeviceNode);
BmcDp = (BMC_DEVICE_PATH *)CreateDeviceNode (
HARDWARE_DEVICE_PATH,
HW_BMC_DP,
(UINT16)sizeof (BMC_DEVICE_PATH)
);
BmcDp->InterfaceType = (UINT8)Strtoi (InterfaceTypeStr);
WriteUnaligned64 (
(UINT64 *)(&BmcDp->BaseAddress),
StrHexToUint64 (BaseAddressStr)
);
return (EFI_DEVICE_PATH_PROTOCOL *)BmcDp;
}
/**
Converts a generic ACPI text device path node to ACPI device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to ACPI device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextAcpiPath (
IN CHAR16 *TextDeviceNode
)
{
return DevPathFromTextGenericPath (ACPI_DEVICE_PATH, TextDeviceNode);
}
/**
Converts a string to EisaId.
@param Text The input string.
@return UINT32 EISA ID.
**/
static
UINT32
EisaIdFromText (
IN CHAR16 *Text
)
{
return (((Text[0] - 'A' + 1) & 0x1f) << 10)
+ (((Text[1] - 'A' + 1) & 0x1f) << 5)
+ (((Text[2] - 'A' + 1) & 0x1f) << 0)
+ (UINT32)(StrHexToUintn (&Text[3]) << 16)
;
}
/**
Converts a text device path node to ACPI HID device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created ACPI HID device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextAcpi (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *HIDStr;
CHAR16 *UIDStr;
ACPI_HID_DEVICE_PATH *Acpi;
HIDStr = GetNextParamStr (&TextDeviceNode);
UIDStr = GetNextParamStr (&TextDeviceNode);
Acpi = (ACPI_HID_DEVICE_PATH *)CreateDeviceNode (
ACPI_DEVICE_PATH,
ACPI_DP,
(UINT16)sizeof (ACPI_HID_DEVICE_PATH)
);
Acpi->HID = EisaIdFromText (HIDStr);
Acpi->UID = (UINT32)Strtoi (UIDStr);
return (EFI_DEVICE_PATH_PROTOCOL *)Acpi;
}
/**
Converts a text device path node to ACPI HID device path structure.
@param TextDeviceNode The input Text device path node.
@param PnPId The input plug and play identification.
@return A pointer to the newly-created ACPI HID device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
ConvertFromTextAcpi (
IN CHAR16 *TextDeviceNode,
IN UINT32 PnPId
)
{
CHAR16 *UIDStr;
ACPI_HID_DEVICE_PATH *Acpi;
UIDStr = GetNextParamStr (&TextDeviceNode);
Acpi = (ACPI_HID_DEVICE_PATH *)CreateDeviceNode (
ACPI_DEVICE_PATH,
ACPI_DP,
(UINT16)sizeof (ACPI_HID_DEVICE_PATH)
);
Acpi->HID = EFI_PNP_ID (PnPId);
Acpi->UID = (UINT32)Strtoi (UIDStr);
return (EFI_DEVICE_PATH_PROTOCOL *)Acpi;
}
/**
Converts a text device path node to PCI root device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created PCI root device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextPciRoot (
IN CHAR16 *TextDeviceNode
)
{
return ConvertFromTextAcpi (TextDeviceNode, 0x0a03);
}
/**
Converts a text device path node to PCIE root device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created PCIE root device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextPcieRoot (
IN CHAR16 *TextDeviceNode
)
{
return ConvertFromTextAcpi (TextDeviceNode, 0x0a08);
}
/**
Converts a text device path node to Floppy device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Floppy device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextFloppy (
IN CHAR16 *TextDeviceNode
)
{
return ConvertFromTextAcpi (TextDeviceNode, 0x0604);
}
/**
Converts a text device path node to Keyboard device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Keyboard device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextKeyboard (
IN CHAR16 *TextDeviceNode
)
{
return ConvertFromTextAcpi (TextDeviceNode, 0x0301);
}
/**
Converts a text device path node to Serial device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Serial device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextSerial (
IN CHAR16 *TextDeviceNode
)
{
return ConvertFromTextAcpi (TextDeviceNode, 0x0501);
}
/**
Converts a text device path node to Parallel Port device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Parallel Port device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextParallelPort (
IN CHAR16 *TextDeviceNode
)
{
return ConvertFromTextAcpi (TextDeviceNode, 0x0401);
}
/**
Converts a text device path node to ACPI extension device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created ACPI extension device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextAcpiEx (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *HIDStr;
CHAR16 *CIDStr;
CHAR16 *UIDStr;
CHAR16 *HIDSTRStr;
CHAR16 *CIDSTRStr;
CHAR16 *UIDSTRStr;
CHAR8 *AsciiStr;
UINT16 Length;
ACPI_EXTENDED_HID_DEVICE_PATH *AcpiEx;
HIDStr = GetNextParamStr (&TextDeviceNode);
CIDStr = GetNextParamStr (&TextDeviceNode);
UIDStr = GetNextParamStr (&TextDeviceNode);
HIDSTRStr = GetNextParamStr (&TextDeviceNode);
CIDSTRStr = GetNextParamStr (&TextDeviceNode);
UIDSTRStr = GetNextParamStr (&TextDeviceNode);
Length = (UINT16)(sizeof (ACPI_EXTENDED_HID_DEVICE_PATH) + StrLen (HIDSTRStr) + 1);
Length = (UINT16)(Length + StrLen (UIDSTRStr) + 1);
Length = (UINT16)(Length + StrLen (CIDSTRStr) + 1);
AcpiEx = (ACPI_EXTENDED_HID_DEVICE_PATH *)CreateDeviceNode (
ACPI_DEVICE_PATH,
ACPI_EXTENDED_DP,
Length
);
AcpiEx->HID = EisaIdFromText (HIDStr);
AcpiEx->CID = EisaIdFromText (CIDStr);
AcpiEx->UID = (UINT32)Strtoi (UIDStr);
AsciiStr = (CHAR8 *)((UINT8 *)AcpiEx + sizeof (ACPI_EXTENDED_HID_DEVICE_PATH));
StrToAscii (HIDSTRStr, &AsciiStr);
StrToAscii (UIDSTRStr, &AsciiStr);
StrToAscii (CIDSTRStr, &AsciiStr);
return (EFI_DEVICE_PATH_PROTOCOL *)AcpiEx;
}
/**
Converts a text device path node to ACPI extension device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created ACPI extension device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextAcpiExp (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *HIDStr;
CHAR16 *CIDStr;
CHAR16 *UIDSTRStr;
CHAR8 *AsciiStr;
UINT16 Length;
ACPI_EXTENDED_HID_DEVICE_PATH *AcpiEx;
HIDStr = GetNextParamStr (&TextDeviceNode);
CIDStr = GetNextParamStr (&TextDeviceNode);
UIDSTRStr = GetNextParamStr (&TextDeviceNode);
Length = (UINT16)(sizeof (ACPI_EXTENDED_HID_DEVICE_PATH) + StrLen (UIDSTRStr) + 3);
AcpiEx = (ACPI_EXTENDED_HID_DEVICE_PATH *)CreateDeviceNode (
ACPI_DEVICE_PATH,
ACPI_EXTENDED_DP,
Length
);
AcpiEx->HID = EisaIdFromText (HIDStr);
//
// According to UEFI spec, the CID parameter is optional and has a default value of 0.
// So when the CID parameter is not specified or specified as 0 in the text device node.
// Set the CID to 0 in the ACPI extension device path structure.
//
if ((*CIDStr == '\0') || (*CIDStr == '0')) {
AcpiEx->CID = 0;
} else {
AcpiEx->CID = EisaIdFromText (CIDStr);
}
AcpiEx->UID = 0;
AsciiStr = (CHAR8 *)((UINT8 *)AcpiEx + sizeof (ACPI_EXTENDED_HID_DEVICE_PATH));
//
// HID string is NULL
//
*AsciiStr = '\0';
//
// Convert UID string
//
AsciiStr++;
StrToAscii (UIDSTRStr, &AsciiStr);
//
// CID string is NULL
//
*AsciiStr = '\0';
return (EFI_DEVICE_PATH_PROTOCOL *)AcpiEx;
}
/**
Converts a text device path node to ACPI _ADR device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created ACPI _ADR device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextAcpiAdr (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *DisplayDeviceStr;
ACPI_ADR_DEVICE_PATH *AcpiAdr;
UINTN Index;
UINTN Length;
AcpiAdr = (ACPI_ADR_DEVICE_PATH *)CreateDeviceNode (
ACPI_DEVICE_PATH,
ACPI_ADR_DP,
(UINT16)sizeof (ACPI_ADR_DEVICE_PATH)
);
ASSERT (AcpiAdr != NULL);
for (Index = 0; ; Index++) {
DisplayDeviceStr = GetNextParamStr (&TextDeviceNode);
if (IS_NULL (*DisplayDeviceStr)) {
break;
}
if (Index > 0) {
Length = DevicePathNodeLength (AcpiAdr);
AcpiAdr = ReallocatePool (
Length,
Length + sizeof (UINT32),
AcpiAdr
);
ASSERT (AcpiAdr != NULL);
SetDevicePathNodeLength (AcpiAdr, Length + sizeof (UINT32));
}
(&AcpiAdr->ADR)[Index] = (UINT32)Strtoi (DisplayDeviceStr);
}
return (EFI_DEVICE_PATH_PROTOCOL *)AcpiAdr;
}
/**
Converts a generic messaging text device path node to messaging device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to messaging device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextMsg (
IN CHAR16 *TextDeviceNode
)
{
return DevPathFromTextGenericPath (MESSAGING_DEVICE_PATH, TextDeviceNode);
}
/**
Converts a text device path node to Parallel Port device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Parallel Port device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextAta (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *PrimarySecondaryStr;
CHAR16 *SlaveMasterStr;
CHAR16 *LunStr;
ATAPI_DEVICE_PATH *Atapi;
Atapi = (ATAPI_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_ATAPI_DP,
(UINT16)sizeof (ATAPI_DEVICE_PATH)
);
PrimarySecondaryStr = GetNextParamStr (&TextDeviceNode);
SlaveMasterStr = GetNextParamStr (&TextDeviceNode);
LunStr = GetNextParamStr (&TextDeviceNode);
if (StrCmp (PrimarySecondaryStr, "Primary") == 0) {
Atapi->PrimarySecondary = 0;
} else if (StrCmp (PrimarySecondaryStr, "Secondary") == 0) {
Atapi->PrimarySecondary = 1;
} else {
Atapi->PrimarySecondary = (UINT8)Strtoi (PrimarySecondaryStr);
}
if (StrCmp (SlaveMasterStr, "Master") == 0) {
Atapi->SlaveMaster = 0;
} else if (StrCmp (SlaveMasterStr, "Slave") == 0) {
Atapi->SlaveMaster = 1;
} else {
Atapi->SlaveMaster = (UINT8)Strtoi (SlaveMasterStr);
}
Atapi->Lun = (UINT16)Strtoi (LunStr);
return (EFI_DEVICE_PATH_PROTOCOL *)Atapi;
}
/**
Converts a text device path node to SCSI device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created SCSI device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextScsi (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *PunStr;
CHAR16 *LunStr;
SCSI_DEVICE_PATH *Scsi;
PunStr = GetNextParamStr (&TextDeviceNode);
LunStr = GetNextParamStr (&TextDeviceNode);
Scsi = (SCSI_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_SCSI_DP,
(UINT16)sizeof (SCSI_DEVICE_PATH)
);
Scsi->Pun = (UINT16)Strtoi (PunStr);
Scsi->Lun = (UINT16)Strtoi (LunStr);
return (EFI_DEVICE_PATH_PROTOCOL *)Scsi;
}
/**
Converts a text device path node to Fibre device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Fibre device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextFibre (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *WWNStr;
CHAR16 *LunStr;
FIBRECHANNEL_DEVICE_PATH *Fibre;
WWNStr = GetNextParamStr (&TextDeviceNode);
LunStr = GetNextParamStr (&TextDeviceNode);
Fibre = (FIBRECHANNEL_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_FIBRECHANNEL_DP,
(UINT16)sizeof (FIBRECHANNEL_DEVICE_PATH)
);
Fibre->Reserved = 0;
Strtoi64 (WWNStr, &Fibre->WWN);
Strtoi64 (LunStr, &Fibre->Lun);
return (EFI_DEVICE_PATH_PROTOCOL *)Fibre;
}
/**
Converts a text device path node to FibreEx device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created FibreEx device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextFibreEx (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *WWNStr;
CHAR16 *LunStr;
FIBRECHANNELEX_DEVICE_PATH *FibreEx;
WWNStr = GetNextParamStr (&TextDeviceNode);
LunStr = GetNextParamStr (&TextDeviceNode);
FibreEx = (FIBRECHANNELEX_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_FIBRECHANNELEX_DP,
(UINT16)sizeof (FIBRECHANNELEX_DEVICE_PATH)
);
FibreEx->Reserved = 0;
Strtoi64 (WWNStr, (UINT64 *)(&FibreEx->WWN));
Strtoi64 (LunStr, (UINT64 *)(&FibreEx->Lun));
*(UINT64 *)(&FibreEx->WWN) = SwapBytes64 (*(UINT64 *)(&FibreEx->WWN));
*(UINT64 *)(&FibreEx->Lun) = SwapBytes64 (*(UINT64 *)(&FibreEx->Lun));
return (EFI_DEVICE_PATH_PROTOCOL *)FibreEx;
}
/**
Converts a text device path node to 1394 device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created 1394 device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromText1394 (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *GuidStr;
F1394_DEVICE_PATH *F1394DevPath;
GuidStr = GetNextParamStr (&TextDeviceNode);
F1394DevPath = (F1394_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_1394_DP,
(UINT16)sizeof (F1394_DEVICE_PATH)
);
F1394DevPath->Reserved = 0;
F1394DevPath->Guid = StrHexToUint64 (GuidStr);
return (EFI_DEVICE_PATH_PROTOCOL *)F1394DevPath;
}
/**
Converts a text device path node to USB device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created USB device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextUsb (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *PortStr;
CHAR16 *InterfaceStr;
USB_DEVICE_PATH *Usb;
PortStr = GetNextParamStr (&TextDeviceNode);
InterfaceStr = GetNextParamStr (&TextDeviceNode);
Usb = (USB_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_USB_DP,
(UINT16)sizeof (USB_DEVICE_PATH)
);
Usb->ParentPortNumber = (UINT8)Strtoi (PortStr);
Usb->InterfaceNumber = (UINT8)Strtoi (InterfaceStr);
return (EFI_DEVICE_PATH_PROTOCOL *)Usb;
}
/**
Converts a text device path node to I20 device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created I20 device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextI2O (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *TIDStr;
I2O_DEVICE_PATH *I2ODevPath;
TIDStr = GetNextParamStr (&TextDeviceNode);
I2ODevPath = (I2O_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_I2O_DP,
(UINT16)sizeof (I2O_DEVICE_PATH)
);
I2ODevPath->Tid = (UINT32)Strtoi (TIDStr);
return (EFI_DEVICE_PATH_PROTOCOL *)I2ODevPath;
}
/**
Converts a text device path node to Infini Band device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Infini Band device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextInfiniband (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *FlagsStr;
CHAR16 *GuidStr;
CHAR16 *SidStr;
CHAR16 *TidStr;
CHAR16 *DidStr;
INFINIBAND_DEVICE_PATH *InfiniBand;
FlagsStr = GetNextParamStr (&TextDeviceNode);
GuidStr = GetNextParamStr (&TextDeviceNode);
SidStr = GetNextParamStr (&TextDeviceNode);
TidStr = GetNextParamStr (&TextDeviceNode);
DidStr = GetNextParamStr (&TextDeviceNode);
InfiniBand = (INFINIBAND_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_INFINIBAND_DP,
(UINT16)sizeof (INFINIBAND_DEVICE_PATH)
);
InfiniBand->ResourceFlags = (UINT32)Strtoi (FlagsStr);
StrToGuid (GuidStr, (EFI_GUID *)InfiniBand->PortGid);
Strtoi64 (SidStr, &InfiniBand->ServiceId);
Strtoi64 (TidStr, &InfiniBand->TargetPortId);
Strtoi64 (DidStr, &InfiniBand->DeviceId);
return (EFI_DEVICE_PATH_PROTOCOL *)InfiniBand;
}
/**
Converts a text device path node to Vendor-Defined Messaging device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Vendor-Defined Messaging device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextVenMsg (
IN CHAR16 *TextDeviceNode
)
{
return ConvertFromTextVendor (
TextDeviceNode,
MESSAGING_DEVICE_PATH,
MSG_VENDOR_DP
);
}
/**
Converts a text device path node to Vendor defined PC-ANSI device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Vendor defined PC-ANSI device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextVenPcAnsi (
IN CHAR16 *TextDeviceNode
)
{
VENDOR_DEVICE_PATH *Vendor;
Vendor = (VENDOR_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_VENDOR_DP,
(UINT16)sizeof (VENDOR_DEVICE_PATH)
);
CopyGuid (&Vendor->Guid, &gEfiPcAnsiGuid);
return (EFI_DEVICE_PATH_PROTOCOL *)Vendor;
}
/**
Converts a text device path node to Vendor defined VT100 device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Vendor defined VT100 device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextVenVt100 (
IN CHAR16 *TextDeviceNode
)
{
VENDOR_DEVICE_PATH *Vendor;
Vendor = (VENDOR_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_VENDOR_DP,
(UINT16)sizeof (VENDOR_DEVICE_PATH)
);
CopyGuid (&Vendor->Guid, &gEfiVT100Guid);
return (EFI_DEVICE_PATH_PROTOCOL *)Vendor;
}
/**
Converts a text device path node to Vendor defined VT100 Plus device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Vendor defined VT100 Plus device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextVenVt100Plus (
IN CHAR16 *TextDeviceNode
)
{
VENDOR_DEVICE_PATH *Vendor;
Vendor = (VENDOR_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_VENDOR_DP,
(UINT16)sizeof (VENDOR_DEVICE_PATH)
);
CopyGuid (&Vendor->Guid, &gEfiVT100PlusGuid);
return (EFI_DEVICE_PATH_PROTOCOL *)Vendor;
}
/**
Converts a text device path node to Vendor defined UTF8 device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Vendor defined UTF8 device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextVenUtf8 (
IN CHAR16 *TextDeviceNode
)
{
VENDOR_DEVICE_PATH *Vendor;
Vendor = (VENDOR_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_VENDOR_DP,
(UINT16)sizeof (VENDOR_DEVICE_PATH)
);
CopyGuid (&Vendor->Guid, &gEfiVTUTF8Guid);
return (EFI_DEVICE_PATH_PROTOCOL *)Vendor;
}
/**
Converts a text device path node to UART Flow Control device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created UART Flow Control device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextUartFlowCtrl (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *ValueStr;
UART_FLOW_CONTROL_DEVICE_PATH *UartFlowControl;
ValueStr = GetNextParamStr (&TextDeviceNode);
UartFlowControl = (UART_FLOW_CONTROL_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_VENDOR_DP,
(UINT16)sizeof (UART_FLOW_CONTROL_DEVICE_PATH)
);
CopyGuid (&UartFlowControl->Guid, &gEfiUartDevicePathGuid);
if (StrCmp (ValueStr, "XonXoff") == 0) {
UartFlowControl->FlowControlMap = 2;
} else if (StrCmp (ValueStr, "Hardware") == 0) {
UartFlowControl->FlowControlMap = 1;
} else {
UartFlowControl->FlowControlMap = 0;
}
return (EFI_DEVICE_PATH_PROTOCOL *)UartFlowControl;
}
/**
Converts a text device path node to Serial Attached SCSI device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Serial Attached SCSI device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextSAS (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *AddressStr;
CHAR16 *LunStr;
CHAR16 *RTPStr;
CHAR16 *SASSATAStr;
CHAR16 *LocationStr;
CHAR16 *ConnectStr;
CHAR16 *DriveBayStr;
CHAR16 *ReservedStr;
UINT16 Info;
UINT16 Uint16;
SAS_DEVICE_PATH *Sas;
AddressStr = GetNextParamStr (&TextDeviceNode);
LunStr = GetNextParamStr (&TextDeviceNode);
RTPStr = GetNextParamStr (&TextDeviceNode);
SASSATAStr = GetNextParamStr (&TextDeviceNode);
LocationStr = GetNextParamStr (&TextDeviceNode);
ConnectStr = GetNextParamStr (&TextDeviceNode);
DriveBayStr = GetNextParamStr (&TextDeviceNode);
ReservedStr = GetNextParamStr (&TextDeviceNode);
Sas = (SAS_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_VENDOR_DP,
(UINT16)sizeof (SAS_DEVICE_PATH)
);
CopyGuid (&Sas->Guid, &gEfiSasDevicePathGuid);
Strtoi64 (AddressStr, &Sas->SasAddress);
Strtoi64 (LunStr, &Sas->Lun);
Sas->RelativeTargetPort = (UINT16)Strtoi (RTPStr);
if (StrCmp (SASSATAStr, "NoTopology") == 0) {
Info = 0x0;
} else if ((StrCmp (SASSATAStr, "SATA") == 0) || (StrCmp (SASSATAStr, "SAS") == 0)) {
Uint16 = (UINT16)Strtoi (DriveBayStr);
if (Uint16 == 0) {
Info = 0x1;
} else {
Info = (UINT16)(0x2 | ((Uint16 - 1) << 8));
}
if (StrCmp (SASSATAStr, "SATA") == 0) {
Info |= BIT4;
}
//
// Location is an integer between 0 and 1 or else
// the keyword Internal (0) or External (1).
//
if (StrCmp (LocationStr, "External") == 0) {
Uint16 = 1;
} else if (StrCmp (LocationStr, "Internal") == 0) {
Uint16 = 0;
} else {
Uint16 = ((UINT16)Strtoi (LocationStr) & BIT0);
}
Info |= (Uint16 << 5);
//
// Connect is an integer between 0 and 3 or else
// the keyword Direct (0) or Expanded (1).
//
if (StrCmp (ConnectStr, "Expanded") == 0) {
Uint16 = 1;
} else if (StrCmp (ConnectStr, "Direct") == 0) {
Uint16 = 0;
} else {
Uint16 = ((UINT16)Strtoi (ConnectStr) & (BIT0 | BIT1));
}
Info |= (Uint16 << 6);
} else {
Info = (UINT16)Strtoi (SASSATAStr);
}
Sas->DeviceTopology = Info;
Sas->Reserved = (UINT32)Strtoi (ReservedStr);
return (EFI_DEVICE_PATH_PROTOCOL *)Sas;
}
/**
Converts a text device path node to Serial Attached SCSI Ex device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Serial Attached SCSI Ex device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextSasEx (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *AddressStr;
CHAR16 *LunStr;
CHAR16 *RTPStr;
CHAR16 *SASSATAStr;
CHAR16 *LocationStr;
CHAR16 *ConnectStr;
CHAR16 *DriveBayStr;
UINT16 Info;
UINT16 Uint16;
UINT64 SasAddress;
UINT64 Lun;
SASEX_DEVICE_PATH *SasEx;
AddressStr = GetNextParamStr (&TextDeviceNode);
LunStr = GetNextParamStr (&TextDeviceNode);
RTPStr = GetNextParamStr (&TextDeviceNode);
SASSATAStr = GetNextParamStr (&TextDeviceNode);
LocationStr = GetNextParamStr (&TextDeviceNode);
ConnectStr = GetNextParamStr (&TextDeviceNode);
DriveBayStr = GetNextParamStr (&TextDeviceNode);
SasEx = (SASEX_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_SASEX_DP,
(UINT16)sizeof (SASEX_DEVICE_PATH)
);
Strtoi64 (AddressStr, &SasAddress);
Strtoi64 (LunStr, &Lun);
WriteUnaligned64 ((UINT64 *)&SasEx->SasAddress, SwapBytes64 (SasAddress));
WriteUnaligned64 ((UINT64 *)&SasEx->Lun, SwapBytes64 (Lun));
SasEx->RelativeTargetPort = (UINT16)Strtoi (RTPStr);
if (StrCmp (SASSATAStr, "NoTopology") == 0) {
Info = 0x0;
} else if ((StrCmp (SASSATAStr, "SATA") == 0) || (StrCmp (SASSATAStr, "SAS") == 0)) {
Uint16 = (UINT16)Strtoi (DriveBayStr);
if (Uint16 == 0) {
Info = 0x1;
} else {
Info = (UINT16)(0x2 | ((Uint16 - 1) << 8));
}
if (StrCmp (SASSATAStr, "SATA") == 0) {
Info |= BIT4;
}
//
// Location is an integer between 0 and 1 or else
// the keyword Internal (0) or External (1).
//
if (StrCmp (LocationStr, "External") == 0) {
Uint16 = 1;
} else if (StrCmp (LocationStr, "Internal") == 0) {
Uint16 = 0;
} else {
Uint16 = ((UINT16)Strtoi (LocationStr) & BIT0);
}
Info |= (Uint16 << 5);
//
// Connect is an integer between 0 and 3 or else
// the keyword Direct (0) or Expanded (1).
//
if (StrCmp (ConnectStr, "Expanded") == 0) {
Uint16 = 1;
} else if (StrCmp (ConnectStr, "Direct") == 0) {
Uint16 = 0;
} else {
Uint16 = ((UINT16)Strtoi (ConnectStr) & (BIT0 | BIT1));
}
Info |= (Uint16 << 6);
} else {
Info = (UINT16)Strtoi (SASSATAStr);
}
SasEx->DeviceTopology = Info;
return (EFI_DEVICE_PATH_PROTOCOL *)SasEx;
}
/**
Converts a text device path node to NVM Express Namespace device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created NVM Express Namespace device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextNVMe (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *NamespaceIdStr;
CHAR16 *NamespaceUuidStr;
NVME_NAMESPACE_DEVICE_PATH *Nvme;
UINT8 *Uuid;
UINTN Index;
NamespaceIdStr = GetNextParamStr (&TextDeviceNode);
NamespaceUuidStr = GetNextParamStr (&TextDeviceNode);
Nvme = (NVME_NAMESPACE_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_NVME_NAMESPACE_DP,
(UINT16)sizeof (NVME_NAMESPACE_DEVICE_PATH)
);
Nvme->NamespaceId = (UINT32)Strtoi (NamespaceIdStr);
Uuid = (UINT8 *)&Nvme->NamespaceUuid;
Index = sizeof (Nvme->NamespaceUuid) / sizeof (UINT8);
while (Index-- != 0) {
Uuid[Index] = (UINT8)StrHexToUintn (SplitStr (&NamespaceUuidStr, '-'));
}
return (EFI_DEVICE_PATH_PROTOCOL *)Nvme;
}
/**
Converts a text device path node to UFS device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created UFS device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextUfs (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *PunStr;
CHAR16 *LunStr;
UFS_DEVICE_PATH *Ufs;
PunStr = GetNextParamStr (&TextDeviceNode);
LunStr = GetNextParamStr (&TextDeviceNode);
Ufs = (UFS_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_UFS_DP,
(UINT16)sizeof (UFS_DEVICE_PATH)
);
Ufs->Pun = (UINT8)Strtoi (PunStr);
Ufs->Lun = (UINT8)Strtoi (LunStr);
return (EFI_DEVICE_PATH_PROTOCOL *)Ufs;
}
/**
Converts a text device path node to SD (Secure Digital) device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created SD device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextSd (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *SlotNumberStr;
SD_DEVICE_PATH *Sd;
SlotNumberStr = GetNextParamStr (&TextDeviceNode);
Sd = (SD_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_SD_DP,
(UINT16)sizeof (SD_DEVICE_PATH)
);
Sd->SlotNumber = (UINT8)Strtoi (SlotNumberStr);
return (EFI_DEVICE_PATH_PROTOCOL *)Sd;
}
/**
Converts a text device path node to EMMC (Embedded MMC) device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created EMMC device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextEmmc (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *SlotNumberStr;
EMMC_DEVICE_PATH *Emmc;
SlotNumberStr = GetNextParamStr (&TextDeviceNode);
Emmc = (EMMC_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_EMMC_DP,
(UINT16)sizeof (EMMC_DEVICE_PATH)
);
Emmc->SlotNumber = (UINT8)Strtoi (SlotNumberStr);
return (EFI_DEVICE_PATH_PROTOCOL *)Emmc;
}
/**
Converts a text device path node to Debug Port device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Debug Port device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextDebugPort (
IN CHAR16 *TextDeviceNode
)
{
VENDOR_DEVICE_PATH *Vend;
Vend = (VENDOR_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_VENDOR_DP,
(UINT16)sizeof (VENDOR_DEVICE_PATH)
);
CopyGuid (&Vend->Guid, &gEfiDebugPortProtocolGuid);
return (EFI_DEVICE_PATH_PROTOCOL *)Vend;
}
/**
Converts a text device path node to MAC device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created MAC device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextMAC (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *AddressStr;
CHAR16 *IfTypeStr;
UINTN Length;
MAC_ADDR_DEVICE_PATH *MACDevPath;
AddressStr = GetNextParamStr (&TextDeviceNode);
IfTypeStr = GetNextParamStr (&TextDeviceNode);
MACDevPath = (MAC_ADDR_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_MAC_ADDR_DP,
(UINT16)sizeof (MAC_ADDR_DEVICE_PATH)
);
MACDevPath->IfType = (UINT8)Strtoi (IfTypeStr);
Length = sizeof (EFI_MAC_ADDRESS);
if ((MACDevPath->IfType == 0x01) || (MACDevPath->IfType == 0x00)) {
Length = 6;
}
StrHexToBytes (AddressStr, Length * 2, MACDevPath->MacAddress.Addr, Length);
return (EFI_DEVICE_PATH_PROTOCOL *)MACDevPath;
}
/**
Converts a text format to the network protocol ID.
@param Text String of protocol field.
@return Network protocol ID .
**/
static
UINTN
NetworkProtocolFromText (
IN CHAR16 *Text
)
{
if (StrCmp (Text, "UDP") == 0) {
return RFC_1700_UDP_PROTOCOL;
}
if (StrCmp (Text, "TCP") == 0) {
return RFC_1700_TCP_PROTOCOL;
}
return Strtoi (Text);
}
/**
Converts a text device path node to IPV4 device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created IPV4 device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextIPv4 (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *RemoteIPStr;
CHAR16 *ProtocolStr;
CHAR16 *TypeStr;
CHAR16 *LocalIPStr;
CHAR16 *GatewayIPStr;
CHAR16 *SubnetMaskStr;
IPv4_DEVICE_PATH *IPv4;
RemoteIPStr = GetNextParamStr (&TextDeviceNode);
ProtocolStr = GetNextParamStr (&TextDeviceNode);
TypeStr = GetNextParamStr (&TextDeviceNode);
LocalIPStr = GetNextParamStr (&TextDeviceNode);
GatewayIPStr = GetNextParamStr (&TextDeviceNode);
SubnetMaskStr = GetNextParamStr (&TextDeviceNode);
IPv4 = (IPv4_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_IPv4_DP,
(UINT16)sizeof (IPv4_DEVICE_PATH)
);
StrToIpv4Address (RemoteIPStr, NULL, &IPv4->RemoteIpAddress, NULL);
IPv4->Protocol = (UINT16)NetworkProtocolFromText (ProtocolStr);
if (StrCmp (TypeStr, "Static") == 0) {
IPv4->StaticIpAddress = TRUE;
} else {
IPv4->StaticIpAddress = FALSE;
}
StrToIpv4Address (LocalIPStr, NULL, &IPv4->LocalIpAddress, NULL);
if (!IS_NULL (*GatewayIPStr) && !IS_NULL (*SubnetMaskStr)) {
StrToIpv4Address (GatewayIPStr, NULL, &IPv4->GatewayIpAddress, NULL);
StrToIpv4Address (SubnetMaskStr, NULL, &IPv4->SubnetMask, NULL);
} else {
ZeroMem (&IPv4->GatewayIpAddress, sizeof (IPv4->GatewayIpAddress));
ZeroMem (&IPv4->SubnetMask, sizeof (IPv4->SubnetMask));
}
IPv4->LocalPort = 0;
IPv4->RemotePort = 0;
return (EFI_DEVICE_PATH_PROTOCOL *)IPv4;
}
/**
Converts a text device path node to IPV6 device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created IPV6 device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextIPv6 (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *RemoteIPStr;
CHAR16 *ProtocolStr;
CHAR16 *TypeStr;
CHAR16 *LocalIPStr;
CHAR16 *GatewayIPStr;
CHAR16 *PrefixLengthStr;
IPv6_DEVICE_PATH *IPv6;
RemoteIPStr = GetNextParamStr (&TextDeviceNode);
ProtocolStr = GetNextParamStr (&TextDeviceNode);
TypeStr = GetNextParamStr (&TextDeviceNode);
LocalIPStr = GetNextParamStr (&TextDeviceNode);
PrefixLengthStr = GetNextParamStr (&TextDeviceNode);
GatewayIPStr = GetNextParamStr (&TextDeviceNode);
IPv6 = (IPv6_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_IPv6_DP,
(UINT16)sizeof (IPv6_DEVICE_PATH)
);
StrToIpv6Address (RemoteIPStr, NULL, &IPv6->RemoteIpAddress, NULL);
IPv6->Protocol = (UINT16)NetworkProtocolFromText (ProtocolStr);
if (StrCmp (TypeStr, "Static") == 0) {
IPv6->IpAddressOrigin = 0;
} else if (StrCmp (TypeStr, "StatelessAutoConfigure") == 0) {
IPv6->IpAddressOrigin = 1;
} else {
IPv6->IpAddressOrigin = 2;
}
StrToIpv6Address (LocalIPStr, NULL, &IPv6->LocalIpAddress, NULL);
if (!IS_NULL (*GatewayIPStr) && !IS_NULL (*PrefixLengthStr)) {
StrToIpv6Address (GatewayIPStr, NULL, &IPv6->GatewayIpAddress, NULL);
IPv6->PrefixLength = (UINT8)Strtoi (PrefixLengthStr);
} else {
ZeroMem (&IPv6->GatewayIpAddress, sizeof (IPv6->GatewayIpAddress));
IPv6->PrefixLength = 0;
}
IPv6->LocalPort = 0;
IPv6->RemotePort = 0;
return (EFI_DEVICE_PATH_PROTOCOL *)IPv6;
}
/**
Converts a text device path node to UART device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created UART device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextUart (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *BaudStr;
CHAR16 *DataBitsStr;
CHAR16 *ParityStr;
CHAR16 *StopBitsStr;
UART_DEVICE_PATH *Uart;
BaudStr = GetNextParamStr (&TextDeviceNode);
DataBitsStr = GetNextParamStr (&TextDeviceNode);
ParityStr = GetNextParamStr (&TextDeviceNode);
StopBitsStr = GetNextParamStr (&TextDeviceNode);
Uart = (UART_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_UART_DP,
(UINT16)sizeof (UART_DEVICE_PATH)
);
if (StrCmp (BaudStr, "DEFAULT") == 0) {
Uart->BaudRate = 115200;
} else {
Strtoi64 (BaudStr, &Uart->BaudRate);
}
Uart->DataBits = (UINT8)((StrCmp (DataBitsStr, "DEFAULT") == 0) ? 8 : Strtoi (DataBitsStr));
switch (*ParityStr) {
case 'D':
Uart->Parity = 0;
break;
case 'N':
Uart->Parity = 1;
break;
case 'E':
Uart->Parity = 2;
break;
case 'O':
Uart->Parity = 3;
break;
case 'M':
Uart->Parity = 4;
break;
case 'S':
Uart->Parity = 5;
break;
default:
Uart->Parity = (UINT8)Strtoi (ParityStr);
break;
}
if (StrCmp (StopBitsStr, "D") == 0) {
Uart->StopBits = (UINT8)0;
} else if (StrCmp (StopBitsStr, "1") == 0) {
Uart->StopBits = (UINT8)1;
} else if (StrCmp (StopBitsStr, "1.5") == 0) {
Uart->StopBits = (UINT8)2;
} else if (StrCmp (StopBitsStr, "2") == 0) {
Uart->StopBits = (UINT8)3;
} else {
Uart->StopBits = (UINT8)Strtoi (StopBitsStr);
}
return (EFI_DEVICE_PATH_PROTOCOL *)Uart;
}
/**
Converts a text device path node to USB class device path structure.
@param TextDeviceNode The input Text device path node.
@param UsbClassText A pointer to USB_CLASS_TEXT structure to be integrated to USB Class Text.
@return A pointer to the newly-created USB class device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
ConvertFromTextUsbClass (
IN CHAR16 *TextDeviceNode,
IN USB_CLASS_TEXT *UsbClassText
)
{
CHAR16 *VIDStr;
CHAR16 *PIDStr;
CHAR16 *ClassStr;
CHAR16 *SubClassStr;
CHAR16 *ProtocolStr;
USB_CLASS_DEVICE_PATH *UsbClass;
UsbClass = (USB_CLASS_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_USB_CLASS_DP,
(UINT16)sizeof (USB_CLASS_DEVICE_PATH)
);
VIDStr = GetNextParamStr (&TextDeviceNode);
PIDStr = GetNextParamStr (&TextDeviceNode);
if (UsbClassText->ClassExist) {
ClassStr = GetNextParamStr (&TextDeviceNode);
if (*ClassStr == '\0') {
UsbClass->DeviceClass = 0xFF;
} else {
UsbClass->DeviceClass = (UINT8)Strtoi (ClassStr);
}
} else {
UsbClass->DeviceClass = UsbClassText->Class;
}
if (UsbClassText->SubClassExist) {
SubClassStr = GetNextParamStr (&TextDeviceNode);
if (*SubClassStr == '\0') {
UsbClass->DeviceSubClass = 0xFF;
} else {
UsbClass->DeviceSubClass = (UINT8)Strtoi (SubClassStr);
}
} else {
UsbClass->DeviceSubClass = UsbClassText->SubClass;
}
ProtocolStr = GetNextParamStr (&TextDeviceNode);
if (*VIDStr == '\0') {
UsbClass->VendorId = 0xFFFF;
} else {
UsbClass->VendorId = (UINT16)Strtoi (VIDStr);
}
if (*PIDStr == '\0') {
UsbClass->ProductId = 0xFFFF;
} else {
UsbClass->ProductId = (UINT16)Strtoi (PIDStr);
}
if (*ProtocolStr == '\0') {
UsbClass->DeviceProtocol = 0xFF;
} else {
UsbClass->DeviceProtocol = (UINT8)Strtoi (ProtocolStr);
}
return (EFI_DEVICE_PATH_PROTOCOL *)UsbClass;
}
/**
Converts a text device path node to USB class device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created USB class device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextUsbClass (
IN CHAR16 *TextDeviceNode
)
{
USB_CLASS_TEXT UsbClassText;
UsbClassText.ClassExist = TRUE;
UsbClassText.SubClassExist = TRUE;
return ConvertFromTextUsbClass (TextDeviceNode, &UsbClassText);
}
/**
Converts a text device path node to USB audio device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created USB audio device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextUsbAudio (
IN CHAR16 *TextDeviceNode
)
{
USB_CLASS_TEXT UsbClassText;
UsbClassText.ClassExist = FALSE;
UsbClassText.Class = USB_CLASS_AUDIO;
UsbClassText.SubClassExist = TRUE;
return ConvertFromTextUsbClass (TextDeviceNode, &UsbClassText);
}
/**
Converts a text device path node to USB CDC Control device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created USB CDC Control device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextUsbCDCControl (
IN CHAR16 *TextDeviceNode
)
{
USB_CLASS_TEXT UsbClassText;
UsbClassText.ClassExist = FALSE;
UsbClassText.Class = USB_CLASS_CDCCONTROL;
UsbClassText.SubClassExist = TRUE;
return ConvertFromTextUsbClass (TextDeviceNode, &UsbClassText);
}
/**
Converts a text device path node to USB HID device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created USB HID device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextUsbHID (
IN CHAR16 *TextDeviceNode
)
{
USB_CLASS_TEXT UsbClassText;
UsbClassText.ClassExist = FALSE;
UsbClassText.Class = USB_CLASS_HID;
UsbClassText.SubClassExist = TRUE;
return ConvertFromTextUsbClass (TextDeviceNode, &UsbClassText);
}
/**
Converts a text device path node to USB Image device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created USB Image device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextUsbImage (
IN CHAR16 *TextDeviceNode
)
{
USB_CLASS_TEXT UsbClassText;
UsbClassText.ClassExist = FALSE;
UsbClassText.Class = USB_CLASS_IMAGE;
UsbClassText.SubClassExist = TRUE;
return ConvertFromTextUsbClass (TextDeviceNode, &UsbClassText);
}
/**
Converts a text device path node to USB Print device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created USB Print device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextUsbPrinter (
IN CHAR16 *TextDeviceNode
)
{
USB_CLASS_TEXT UsbClassText;
UsbClassText.ClassExist = FALSE;
UsbClassText.Class = USB_CLASS_PRINTER;
UsbClassText.SubClassExist = TRUE;
return ConvertFromTextUsbClass (TextDeviceNode, &UsbClassText);
}
/**
Converts a text device path node to USB mass storage device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created USB mass storage device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextUsbMassStorage (
IN CHAR16 *TextDeviceNode
)
{
USB_CLASS_TEXT UsbClassText;
UsbClassText.ClassExist = FALSE;
UsbClassText.Class = USB_CLASS_MASS_STORAGE;
UsbClassText.SubClassExist = TRUE;
return ConvertFromTextUsbClass (TextDeviceNode, &UsbClassText);
}
/**
Converts a text device path node to USB HUB device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created USB HUB device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextUsbHub (
IN CHAR16 *TextDeviceNode
)
{
USB_CLASS_TEXT UsbClassText;
UsbClassText.ClassExist = FALSE;
UsbClassText.Class = USB_CLASS_HUB;
UsbClassText.SubClassExist = TRUE;
return ConvertFromTextUsbClass (TextDeviceNode, &UsbClassText);
}
/**
Converts a text device path node to USB CDC data device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created USB CDC data device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextUsbCDCData (
IN CHAR16 *TextDeviceNode
)
{
USB_CLASS_TEXT UsbClassText;
UsbClassText.ClassExist = FALSE;
UsbClassText.Class = USB_CLASS_CDCDATA;
UsbClassText.SubClassExist = TRUE;
return ConvertFromTextUsbClass (TextDeviceNode, &UsbClassText);
}
/**
Converts a text device path node to USB smart card device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created USB smart card device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextUsbSmartCard (
IN CHAR16 *TextDeviceNode
)
{
USB_CLASS_TEXT UsbClassText;
UsbClassText.ClassExist = FALSE;
UsbClassText.Class = USB_CLASS_SMART_CARD;
UsbClassText.SubClassExist = TRUE;
return ConvertFromTextUsbClass (TextDeviceNode, &UsbClassText);
}
/**
Converts a text device path node to USB video device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created USB video device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextUsbVideo (
IN CHAR16 *TextDeviceNode
)
{
USB_CLASS_TEXT UsbClassText;
UsbClassText.ClassExist = FALSE;
UsbClassText.Class = USB_CLASS_VIDEO;
UsbClassText.SubClassExist = TRUE;
return ConvertFromTextUsbClass (TextDeviceNode, &UsbClassText);
}
/**
Converts a text device path node to USB diagnostic device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created USB diagnostic device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextUsbDiagnostic (
IN CHAR16 *TextDeviceNode
)
{
USB_CLASS_TEXT UsbClassText;
UsbClassText.ClassExist = FALSE;
UsbClassText.Class = USB_CLASS_DIAGNOSTIC;
UsbClassText.SubClassExist = TRUE;
return ConvertFromTextUsbClass (TextDeviceNode, &UsbClassText);
}
/**
Converts a text device path node to USB wireless device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created USB wireless device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextUsbWireless (
IN CHAR16 *TextDeviceNode
)
{
USB_CLASS_TEXT UsbClassText;
UsbClassText.ClassExist = FALSE;
UsbClassText.Class = USB_CLASS_WIRELESS;
UsbClassText.SubClassExist = TRUE;
return ConvertFromTextUsbClass (TextDeviceNode, &UsbClassText);
}
/**
Converts a text device path node to USB device firmware update device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created USB device firmware update device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextUsbDeviceFirmwareUpdate (
IN CHAR16 *TextDeviceNode
)
{
USB_CLASS_TEXT UsbClassText;
UsbClassText.ClassExist = FALSE;
UsbClassText.Class = USB_CLASS_RESERVE;
UsbClassText.SubClassExist = FALSE;
UsbClassText.SubClass = USB_SUBCLASS_FW_UPDATE;
return ConvertFromTextUsbClass (TextDeviceNode, &UsbClassText);
}
/**
Converts a text device path node to USB IRDA bridge device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created USB IRDA bridge device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextUsbIrdaBridge (
IN CHAR16 *TextDeviceNode
)
{
USB_CLASS_TEXT UsbClassText;
UsbClassText.ClassExist = FALSE;
UsbClassText.Class = USB_CLASS_RESERVE;
UsbClassText.SubClassExist = FALSE;
UsbClassText.SubClass = USB_SUBCLASS_IRDA_BRIDGE;
return ConvertFromTextUsbClass (TextDeviceNode, &UsbClassText);
}
/**
Converts a text device path node to USB text and measurement device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created USB text and measurement device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextUsbTestAndMeasurement (
IN CHAR16 *TextDeviceNode
)
{
USB_CLASS_TEXT UsbClassText;
UsbClassText.ClassExist = FALSE;
UsbClassText.Class = USB_CLASS_RESERVE;
UsbClassText.SubClassExist = FALSE;
UsbClassText.SubClass = USB_SUBCLASS_TEST;
return ConvertFromTextUsbClass (TextDeviceNode, &UsbClassText);
}
/**
Converts a text device path node to USB WWID device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created USB WWID device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextUsbWwid (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *VIDStr;
CHAR16 *PIDStr;
CHAR16 *InterfaceNumStr;
CHAR16 *SerialNumberStr;
USB_WWID_DEVICE_PATH *UsbWwid;
UINTN SerialNumberStrLen;
VIDStr = GetNextParamStr (&TextDeviceNode);
PIDStr = GetNextParamStr (&TextDeviceNode);
InterfaceNumStr = GetNextParamStr (&TextDeviceNode);
SerialNumberStr = GetNextParamStr (&TextDeviceNode);
SerialNumberStrLen = StrLen (SerialNumberStr);
if ((SerialNumberStrLen >= 2) &&
(SerialNumberStr[0] == '\"') &&
(SerialNumberStr[SerialNumberStrLen - 1] == '\"')
)
{
SerialNumberStr[SerialNumberStrLen - 1] = '\0';
SerialNumberStr++;
SerialNumberStrLen -= 2;
}
UsbWwid = (USB_WWID_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_USB_WWID_DP,
(UINT16)(sizeof (USB_WWID_DEVICE_PATH) + SerialNumberStrLen * sizeof (CHAR16))
);
UsbWwid->VendorId = (UINT16)Strtoi (VIDStr);
UsbWwid->ProductId = (UINT16)Strtoi (PIDStr);
UsbWwid->InterfaceNumber = (UINT16)Strtoi (InterfaceNumStr);
//
// There is no memory allocated in UsbWwid for the '\0' in SerialNumberStr.
// Therefore, the '\0' will not be copied.
//
CopyMem (
(UINT8 *)UsbWwid + sizeof (USB_WWID_DEVICE_PATH),
SerialNumberStr,
SerialNumberStrLen * sizeof (CHAR16)
);
return (EFI_DEVICE_PATH_PROTOCOL *)UsbWwid;
}
/**
Converts a text device path node to Logic Unit device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Logic Unit device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextUnit (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *LunStr;
DEVICE_LOGICAL_UNIT_DEVICE_PATH *LogicalUnit;
LunStr = GetNextParamStr (&TextDeviceNode);
LogicalUnit = (DEVICE_LOGICAL_UNIT_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_DEVICE_LOGICAL_UNIT_DP,
(UINT16)sizeof (DEVICE_LOGICAL_UNIT_DEVICE_PATH)
);
LogicalUnit->Lun = (UINT8)Strtoi (LunStr);
return (EFI_DEVICE_PATH_PROTOCOL *)LogicalUnit;
}
/**
Converts a text device path node to iSCSI device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created iSCSI device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextiSCSI (
IN CHAR16 *TextDeviceNode
)
{
UINT16 Options;
CHAR16 *NameStr;
CHAR16 *PortalGroupStr;
CHAR16 *LunStr;
CHAR16 *HeaderDigestStr;
CHAR16 *DataDigestStr;
CHAR16 *AuthenticationStr;
CHAR16 *ProtocolStr;
CHAR8 *AsciiStr;
ISCSI_DEVICE_PATH_WITH_NAME *ISCSIDevPath;
UINT64 Lun;
NameStr = GetNextParamStr (&TextDeviceNode);
PortalGroupStr = GetNextParamStr (&TextDeviceNode);
LunStr = GetNextParamStr (&TextDeviceNode);
HeaderDigestStr = GetNextParamStr (&TextDeviceNode);
DataDigestStr = GetNextParamStr (&TextDeviceNode);
AuthenticationStr = GetNextParamStr (&TextDeviceNode);
ProtocolStr = GetNextParamStr (&TextDeviceNode);
ISCSIDevPath = (ISCSI_DEVICE_PATH_WITH_NAME *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_ISCSI_DP,
(UINT16)(sizeof (ISCSI_DEVICE_PATH_WITH_NAME) + StrLen (NameStr))
);
AsciiStr = ISCSIDevPath->TargetName;
StrToAscii (NameStr, &AsciiStr);
ISCSIDevPath->TargetPortalGroupTag = (UINT16)Strtoi (PortalGroupStr);
Strtoi64 (LunStr, &Lun);
WriteUnaligned64 ((UINT64 *)&ISCSIDevPath->Lun, SwapBytes64 (Lun));
Options = 0x0000;
if (StrCmp (HeaderDigestStr, "CRC32C") == 0) {
Options |= 0x0002;
}
if (StrCmp (DataDigestStr, "CRC32C") == 0) {
Options |= 0x0008;
}
if (StrCmp (AuthenticationStr, "None") == 0) {
Options |= 0x0800;
}
if (StrCmp (AuthenticationStr, "CHAP_UNI") == 0) {
Options |= 0x1000;
}
ISCSIDevPath->LoginOption = (UINT16)Options;
if (IS_NULL (*ProtocolStr) || (StrCmp (ProtocolStr, "TCP") == 0)) {
ISCSIDevPath->NetworkProtocol = 0;
} else {
//
// Undefined and reserved.
//
ISCSIDevPath->NetworkProtocol = 1;
}
return (EFI_DEVICE_PATH_PROTOCOL *)ISCSIDevPath;
}
/**
Converts a text device path node to VLAN device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created VLAN device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextVlan (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *VlanStr;
VLAN_DEVICE_PATH *Vlan;
VlanStr = GetNextParamStr (&TextDeviceNode);
Vlan = (VLAN_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_VLAN_DP,
(UINT16)sizeof (VLAN_DEVICE_PATH)
);
Vlan->VlanId = (UINT16)Strtoi (VlanStr);
return (EFI_DEVICE_PATH_PROTOCOL *)Vlan;
}
/**
Converts a text device path node to Bluetooth device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Bluetooth device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextBluetooth (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *BluetoothStr;
BLUETOOTH_DEVICE_PATH *BluetoothDp;
BluetoothStr = GetNextParamStr (&TextDeviceNode);
BluetoothDp = (BLUETOOTH_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_BLUETOOTH_DP,
(UINT16)sizeof (BLUETOOTH_DEVICE_PATH)
);
StrHexToBytes (
BluetoothStr,
sizeof (BLUETOOTH_ADDRESS) * 2,
BluetoothDp->BD_ADDR.Address,
sizeof (BLUETOOTH_ADDRESS)
);
return (EFI_DEVICE_PATH_PROTOCOL *)BluetoothDp;
}
/**
Converts a text device path node to Wi-Fi device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Wi-Fi device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextWiFi (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *SSIdStr;
CHAR8 AsciiStr[33];
UINTN DataLen;
WIFI_DEVICE_PATH *WiFiDp;
SSIdStr = GetNextParamStr (&TextDeviceNode);
WiFiDp = (WIFI_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_WIFI_DP,
(UINT16)sizeof (WIFI_DEVICE_PATH)
);
if (NULL != SSIdStr) {
DataLen = StrLen (SSIdStr);
if (StrLen (SSIdStr) > 32) {
SSIdStr[32] = '\0';
DataLen = 32;
}
UnicodeStrToAsciiStrS (SSIdStr, AsciiStr, sizeof (AsciiStr));
CopyMem (WiFiDp->SSId, AsciiStr, DataLen);
}
return (EFI_DEVICE_PATH_PROTOCOL *)WiFiDp;
}
/**
Converts a text device path node to Bluetooth LE device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Bluetooth LE device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextBluetoothLE (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *BluetoothLeAddrStr;
CHAR16 *BluetoothLeAddrTypeStr;
BLUETOOTH_LE_DEVICE_PATH *BluetoothLeDp;
BluetoothLeAddrStr = GetNextParamStr (&TextDeviceNode);
BluetoothLeAddrTypeStr = GetNextParamStr (&TextDeviceNode);
BluetoothLeDp = (BLUETOOTH_LE_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_BLUETOOTH_LE_DP,
(UINT16)sizeof (BLUETOOTH_LE_DEVICE_PATH)
);
BluetoothLeDp->Address.Type = (UINT8)Strtoi (BluetoothLeAddrTypeStr);
StrHexToBytes (
BluetoothLeAddrStr,
sizeof (BluetoothLeDp->Address.Address) * 2,
BluetoothLeDp->Address.Address,
sizeof (BluetoothLeDp->Address.Address)
);
return (EFI_DEVICE_PATH_PROTOCOL *)BluetoothLeDp;
}
/**
Converts a text device path node to DNS device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created DNS device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextDns (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *DeviceNodeStr;
CHAR16 *DeviceNodeStrPtr;
UINT32 DnsServerIpCount;
UINT16 DnsDeviceNodeLength;
DNS_DEVICE_PATH *DnsDeviceNode;
UINT32 DnsServerIpIndex;
CHAR16 *DnsServerIp;
//
// Count the DNS server address number.
//
DeviceNodeStr = UefiDevicePathLibStrDuplicate (TextDeviceNode);
if (DeviceNodeStr == NULL) {
return NULL;
}
DeviceNodeStrPtr = DeviceNodeStr;
DnsServerIpCount = 0;
while (DeviceNodeStrPtr != NULL && *DeviceNodeStrPtr != '\0') {
GetNextParamStr (&DeviceNodeStrPtr);
DnsServerIpCount++;
}
FreePool (DeviceNodeStr);
DeviceNodeStr = NULL;
//
// One or more instances of the DNS server address in EFI_IP_ADDRESS,
// otherwise, NULL will be returned.
//
if (DnsServerIpCount == 0) {
return NULL;
}
//
// Create the DNS DeviceNode.
//
DnsDeviceNodeLength = (UINT16)(sizeof (EFI_DEVICE_PATH_PROTOCOL) + sizeof (UINT8) + DnsServerIpCount * sizeof (EFI_IP_ADDRESS));
DnsDeviceNode = (DNS_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_DNS_DP,
DnsDeviceNodeLength
);
if (DnsDeviceNode == NULL) {
return NULL;
}
//
// Confirm the DNS server address is IPv4 or IPv6 type.
//
DeviceNodeStrPtr = TextDeviceNode;
while (!IS_NULL (*DeviceNodeStrPtr)) {
if (*DeviceNodeStrPtr == '.') {
DnsDeviceNode->IsIPv6 = 0x00;
break;
}
if (*DeviceNodeStrPtr == ':') {
DnsDeviceNode->IsIPv6 = 0x01;
break;
}
DeviceNodeStrPtr++;
}
for (DnsServerIpIndex = 0; DnsServerIpIndex < DnsServerIpCount; DnsServerIpIndex++) {
DnsServerIp = GetNextParamStr (&TextDeviceNode);
if (DnsDeviceNode->IsIPv6 == 0x00) {
StrToIpv4Address (DnsServerIp, NULL, &(DnsDeviceNode->DnsServerIp[DnsServerIpIndex].v4), NULL);
} else {
StrToIpv6Address (DnsServerIp, NULL, &(DnsDeviceNode->DnsServerIp[DnsServerIpIndex].v6), NULL);
}
}
return (EFI_DEVICE_PATH_PROTOCOL *)DnsDeviceNode;
}
/**
Converts a text device path node to URI device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created URI device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextUri (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *UriStr;
UINTN UriLength;
URI_DEVICE_PATH *Uri;
UriStr = GetNextParamStr (&TextDeviceNode);
UriLength = StrnLenS (UriStr, MAX_UINT16 - sizeof (URI_DEVICE_PATH));
Uri = (URI_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_URI_DP,
(UINT16)(sizeof (URI_DEVICE_PATH) + UriLength)
);
while (UriLength-- != 0) {
Uri->Uri[UriLength] = (CHAR8)UriStr[UriLength];
}
return (EFI_DEVICE_PATH_PROTOCOL *)Uri;
}
/**
Converts a media text device path node to media device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to media device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextMediaPath (
IN CHAR16 *TextDeviceNode
)
{
return DevPathFromTextGenericPath (MEDIA_DEVICE_PATH, TextDeviceNode);
}
/**
Converts a text device path node to HD device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created HD device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextHD (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *PartitionStr;
CHAR16 *TypeStr;
CHAR16 *SignatureStr;
CHAR16 *StartStr;
CHAR16 *SizeStr;
UINT32 Signature32;
HARDDRIVE_DEVICE_PATH *Hd;
PartitionStr = GetNextParamStr (&TextDeviceNode);
TypeStr = GetNextParamStr (&TextDeviceNode);
SignatureStr = GetNextParamStr (&TextDeviceNode);
StartStr = GetNextParamStr (&TextDeviceNode);
SizeStr = GetNextParamStr (&TextDeviceNode);
Hd = (HARDDRIVE_DEVICE_PATH *)CreateDeviceNode (
MEDIA_DEVICE_PATH,
MEDIA_HARDDRIVE_DP,
(UINT16)sizeof (HARDDRIVE_DEVICE_PATH)
);
Hd->PartitionNumber = (UINT32)Strtoi (PartitionStr);
ZeroMem (Hd->Signature, 16);
Hd->MBRType = (UINT8)0;
if (StrCmp (TypeStr, "MBR") == 0) {
Hd->SignatureType = SIGNATURE_TYPE_MBR;
Hd->MBRType = 0x01;
Signature32 = (UINT32)Strtoi (SignatureStr);
CopyMem (Hd->Signature, &Signature32, sizeof (UINT32));
} else if (StrCmp (TypeStr, "GPT") == 0) {
Hd->SignatureType = SIGNATURE_TYPE_GUID;
Hd->MBRType = 0x02;
StrToGuid (SignatureStr, (EFI_GUID *)Hd->Signature);
} else {
Hd->SignatureType = (UINT8)Strtoi (TypeStr);
}
Strtoi64 (StartStr, &Hd->PartitionStart);
Strtoi64 (SizeStr, &Hd->PartitionSize);
return (EFI_DEVICE_PATH_PROTOCOL *)Hd;
}
/**
Converts a text device path node to CDROM device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created CDROM device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextCDROM (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *EntryStr;
CHAR16 *StartStr;
CHAR16 *SizeStr;
CDROM_DEVICE_PATH *CDROMDevPath;
EntryStr = GetNextParamStr (&TextDeviceNode);
StartStr = GetNextParamStr (&TextDeviceNode);
SizeStr = GetNextParamStr (&TextDeviceNode);
CDROMDevPath = (CDROM_DEVICE_PATH *)CreateDeviceNode (
MEDIA_DEVICE_PATH,
MEDIA_CDROM_DP,
(UINT16)sizeof (CDROM_DEVICE_PATH)
);
CDROMDevPath->BootEntry = (UINT32)Strtoi (EntryStr);
Strtoi64 (StartStr, &CDROMDevPath->PartitionStart);
Strtoi64 (SizeStr, &CDROMDevPath->PartitionSize);
return (EFI_DEVICE_PATH_PROTOCOL *)CDROMDevPath;
}
/**
Converts a text device path node to Vendor-defined media device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Vendor-defined media device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextVenMedia (
IN CHAR16 *TextDeviceNode
)
{
return ConvertFromTextVendor (
TextDeviceNode,
MEDIA_DEVICE_PATH,
MEDIA_VENDOR_DP
);
}
/**
Converts a text device path node to File device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created File device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextFilePath (
IN CHAR16 *TextDeviceNode
)
{
FILEPATH_DEVICE_PATH *File;
#ifndef __FreeBSD__
File = (FILEPATH_DEVICE_PATH *)CreateDeviceNode (
MEDIA_DEVICE_PATH,
MEDIA_FILEPATH_DP,
(UINT16)(sizeof (FILEPATH_DEVICE_PATH) + StrLen (TextDeviceNode) * 2)
);
StrCpyS (File->PathName, StrLen (TextDeviceNode) + 1, TextDeviceNode);
#else
size_t len = (sizeof (FILEPATH_DEVICE_PATH) + StrLen (TextDeviceNode) * 2);
efi_char *v;
File = (FILEPATH_DEVICE_PATH *)CreateDeviceNode (
MEDIA_DEVICE_PATH,
MEDIA_FILEPATH_DP,
(UINT16)len
);
v = File->PathName;
utf8_to_ucs2(TextDeviceNode, &v, &len);
#endif
return (EFI_DEVICE_PATH_PROTOCOL *)File;
}
/**
Converts a text device path node to Media protocol device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Media protocol device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextMedia (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *GuidStr;
MEDIA_PROTOCOL_DEVICE_PATH *Media;
GuidStr = GetNextParamStr (&TextDeviceNode);
Media = (MEDIA_PROTOCOL_DEVICE_PATH *)CreateDeviceNode (
MEDIA_DEVICE_PATH,
MEDIA_PROTOCOL_DP,
(UINT16)sizeof (MEDIA_PROTOCOL_DEVICE_PATH)
);
StrToGuid (GuidStr, &Media->Protocol);
return (EFI_DEVICE_PATH_PROTOCOL *)Media;
}
/**
Converts a text device path node to firmware volume device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created firmware volume device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextFv (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *GuidStr;
MEDIA_FW_VOL_DEVICE_PATH *Fv;
GuidStr = GetNextParamStr (&TextDeviceNode);
Fv = (MEDIA_FW_VOL_DEVICE_PATH *)CreateDeviceNode (
MEDIA_DEVICE_PATH,
MEDIA_PIWG_FW_VOL_DP,
(UINT16)sizeof (MEDIA_FW_VOL_DEVICE_PATH)
);
StrToGuid (GuidStr, &Fv->FvName);
return (EFI_DEVICE_PATH_PROTOCOL *)Fv;
}
/**
Converts a text device path node to firmware file device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created firmware file device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextFvFile (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *GuidStr;
MEDIA_FW_VOL_FILEPATH_DEVICE_PATH *FvFile;
GuidStr = GetNextParamStr (&TextDeviceNode);
FvFile = (MEDIA_FW_VOL_FILEPATH_DEVICE_PATH *)CreateDeviceNode (
MEDIA_DEVICE_PATH,
MEDIA_PIWG_FW_FILE_DP,
(UINT16)sizeof (MEDIA_FW_VOL_FILEPATH_DEVICE_PATH)
);
StrToGuid (GuidStr, &FvFile->FvFileName);
return (EFI_DEVICE_PATH_PROTOCOL *)FvFile;
}
/**
Converts a text device path node to text relative offset device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Text device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextRelativeOffsetRange (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *StartingOffsetStr;
CHAR16 *EndingOffsetStr;
MEDIA_RELATIVE_OFFSET_RANGE_DEVICE_PATH *Offset;
StartingOffsetStr = GetNextParamStr (&TextDeviceNode);
EndingOffsetStr = GetNextParamStr (&TextDeviceNode);
Offset = (MEDIA_RELATIVE_OFFSET_RANGE_DEVICE_PATH *)CreateDeviceNode (
MEDIA_DEVICE_PATH,
MEDIA_RELATIVE_OFFSET_RANGE_DP,
(UINT16)sizeof (MEDIA_RELATIVE_OFFSET_RANGE_DEVICE_PATH)
);
Strtoi64 (StartingOffsetStr, &Offset->StartingOffset);
Strtoi64 (EndingOffsetStr, &Offset->EndingOffset);
return (EFI_DEVICE_PATH_PROTOCOL *)Offset;
}
/**
Converts a text device path node to text ram disk device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Text device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextRamDisk (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *StartingAddrStr;
CHAR16 *EndingAddrStr;
CHAR16 *TypeGuidStr;
CHAR16 *InstanceStr;
MEDIA_RAM_DISK_DEVICE_PATH *RamDisk;
UINT64 StartingAddr;
UINT64 EndingAddr;
StartingAddrStr = GetNextParamStr (&TextDeviceNode);
EndingAddrStr = GetNextParamStr (&TextDeviceNode);
InstanceStr = GetNextParamStr (&TextDeviceNode);
TypeGuidStr = GetNextParamStr (&TextDeviceNode);
RamDisk = (MEDIA_RAM_DISK_DEVICE_PATH *)CreateDeviceNode (
MEDIA_DEVICE_PATH,
MEDIA_RAM_DISK_DP,
(UINT16)sizeof (MEDIA_RAM_DISK_DEVICE_PATH)
);
Strtoi64 (StartingAddrStr, &StartingAddr);
WriteUnaligned64 ((UINT64 *)&(RamDisk->StartingAddr[0]), StartingAddr);
Strtoi64 (EndingAddrStr, &EndingAddr);
WriteUnaligned64 ((UINT64 *)&(RamDisk->EndingAddr[0]), EndingAddr);
RamDisk->Instance = (UINT16)Strtoi (InstanceStr);
StrToGuid (TypeGuidStr, &RamDisk->TypeGuid);
return (EFI_DEVICE_PATH_PROTOCOL *)RamDisk;
}
/**
Converts a text device path node to text virtual disk device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Text device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextVirtualDisk (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *StartingAddrStr;
CHAR16 *EndingAddrStr;
CHAR16 *InstanceStr;
MEDIA_RAM_DISK_DEVICE_PATH *RamDisk;
UINT64 StartingAddr;
UINT64 EndingAddr;
StartingAddrStr = GetNextParamStr (&TextDeviceNode);
EndingAddrStr = GetNextParamStr (&TextDeviceNode);
InstanceStr = GetNextParamStr (&TextDeviceNode);
RamDisk = (MEDIA_RAM_DISK_DEVICE_PATH *)CreateDeviceNode (
MEDIA_DEVICE_PATH,
MEDIA_RAM_DISK_DP,
(UINT16)sizeof (MEDIA_RAM_DISK_DEVICE_PATH)
);
Strtoi64 (StartingAddrStr, &StartingAddr);
WriteUnaligned64 ((UINT64 *)&(RamDisk->StartingAddr[0]), StartingAddr);
Strtoi64 (EndingAddrStr, &EndingAddr);
WriteUnaligned64 ((UINT64 *)&(RamDisk->EndingAddr[0]), EndingAddr);
RamDisk->Instance = (UINT16)Strtoi (InstanceStr);
CopyGuid (&RamDisk->TypeGuid, &gEfiVirtualDiskGuid);
return (EFI_DEVICE_PATH_PROTOCOL *)RamDisk;
}
/**
Converts a text device path node to text virtual cd device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Text device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextVirtualCd (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *StartingAddrStr;
CHAR16 *EndingAddrStr;
CHAR16 *InstanceStr;
MEDIA_RAM_DISK_DEVICE_PATH *RamDisk;
UINT64 StartingAddr;
UINT64 EndingAddr;
StartingAddrStr = GetNextParamStr (&TextDeviceNode);
EndingAddrStr = GetNextParamStr (&TextDeviceNode);
InstanceStr = GetNextParamStr (&TextDeviceNode);
RamDisk = (MEDIA_RAM_DISK_DEVICE_PATH *)CreateDeviceNode (
MEDIA_DEVICE_PATH,
MEDIA_RAM_DISK_DP,
(UINT16)sizeof (MEDIA_RAM_DISK_DEVICE_PATH)
);
Strtoi64 (StartingAddrStr, &StartingAddr);
WriteUnaligned64 ((UINT64 *)&(RamDisk->StartingAddr[0]), StartingAddr);
Strtoi64 (EndingAddrStr, &EndingAddr);
WriteUnaligned64 ((UINT64 *)&(RamDisk->EndingAddr[0]), EndingAddr);
RamDisk->Instance = (UINT16)Strtoi (InstanceStr);
CopyGuid (&RamDisk->TypeGuid, &gEfiVirtualCdGuid);
return (EFI_DEVICE_PATH_PROTOCOL *)RamDisk;
}
/**
Converts a text device path node to text persistent virtual disk device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Text device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextPersistentVirtualDisk (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *StartingAddrStr;
CHAR16 *EndingAddrStr;
CHAR16 *InstanceStr;
MEDIA_RAM_DISK_DEVICE_PATH *RamDisk;
UINT64 StartingAddr;
UINT64 EndingAddr;
StartingAddrStr = GetNextParamStr (&TextDeviceNode);
EndingAddrStr = GetNextParamStr (&TextDeviceNode);
InstanceStr = GetNextParamStr (&TextDeviceNode);
RamDisk = (MEDIA_RAM_DISK_DEVICE_PATH *)CreateDeviceNode (
MEDIA_DEVICE_PATH,
MEDIA_RAM_DISK_DP,
(UINT16)sizeof (MEDIA_RAM_DISK_DEVICE_PATH)
);
Strtoi64 (StartingAddrStr, &StartingAddr);
WriteUnaligned64 ((UINT64 *)&(RamDisk->StartingAddr[0]), StartingAddr);
Strtoi64 (EndingAddrStr, &EndingAddr);
WriteUnaligned64 ((UINT64 *)&(RamDisk->EndingAddr[0]), EndingAddr);
RamDisk->Instance = (UINT16)Strtoi (InstanceStr);
CopyGuid (&RamDisk->TypeGuid, &gEfiPersistentVirtualDiskGuid);
return (EFI_DEVICE_PATH_PROTOCOL *)RamDisk;
}
/**
Converts a text device path node to text persistent virtual cd device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created Text device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextPersistentVirtualCd (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *StartingAddrStr;
CHAR16 *EndingAddrStr;
CHAR16 *InstanceStr;
MEDIA_RAM_DISK_DEVICE_PATH *RamDisk;
UINT64 StartingAddr;
UINT64 EndingAddr;
StartingAddrStr = GetNextParamStr (&TextDeviceNode);
EndingAddrStr = GetNextParamStr (&TextDeviceNode);
InstanceStr = GetNextParamStr (&TextDeviceNode);
RamDisk = (MEDIA_RAM_DISK_DEVICE_PATH *)CreateDeviceNode (
MEDIA_DEVICE_PATH,
MEDIA_RAM_DISK_DP,
(UINT16)sizeof (MEDIA_RAM_DISK_DEVICE_PATH)
);
Strtoi64 (StartingAddrStr, &StartingAddr);
WriteUnaligned64 ((UINT64 *)&(RamDisk->StartingAddr[0]), StartingAddr);
Strtoi64 (EndingAddrStr, &EndingAddr);
WriteUnaligned64 ((UINT64 *)&(RamDisk->EndingAddr[0]), EndingAddr);
RamDisk->Instance = (UINT16)Strtoi (InstanceStr);
CopyGuid (&RamDisk->TypeGuid, &gEfiPersistentVirtualCdGuid);
return (EFI_DEVICE_PATH_PROTOCOL *)RamDisk;
}
/**
Converts a BBS text device path node to BBS device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to BBS device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextBbsPath (
IN CHAR16 *TextDeviceNode
)
{
return DevPathFromTextGenericPath (BBS_DEVICE_PATH, TextDeviceNode);
}
/**
Converts a text device path node to BIOS Boot Specification device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created BIOS Boot Specification device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextBBS (
IN CHAR16 *TextDeviceNode
)
{
CHAR16 *TypeStr;
CHAR16 *IdStr;
CHAR16 *FlagsStr;
CHAR8 *AsciiStr;
BBS_BBS_DEVICE_PATH *Bbs;
TypeStr = GetNextParamStr (&TextDeviceNode);
IdStr = GetNextParamStr (&TextDeviceNode);
FlagsStr = GetNextParamStr (&TextDeviceNode);
Bbs = (BBS_BBS_DEVICE_PATH *)CreateDeviceNode (
BBS_DEVICE_PATH,
BBS_BBS_DP,
(UINT16)(sizeof (BBS_BBS_DEVICE_PATH) + StrLen (IdStr))
);
if (StrCmp (TypeStr, "Floppy") == 0) {
Bbs->DeviceType = BBS_TYPE_FLOPPY;
} else if (StrCmp (TypeStr, "HD") == 0) {
Bbs->DeviceType = BBS_TYPE_HARDDRIVE;
} else if (StrCmp (TypeStr, "CDROM") == 0) {
Bbs->DeviceType = BBS_TYPE_CDROM;
} else if (StrCmp (TypeStr, "PCMCIA") == 0) {
Bbs->DeviceType = BBS_TYPE_PCMCIA;
} else if (StrCmp (TypeStr, "USB") == 0) {
Bbs->DeviceType = BBS_TYPE_USB;
} else if (StrCmp (TypeStr, "Network") == 0) {
Bbs->DeviceType = BBS_TYPE_EMBEDDED_NETWORK;
} else {
Bbs->DeviceType = (UINT16)Strtoi (TypeStr);
}
AsciiStr = Bbs->String;
StrToAscii (IdStr, &AsciiStr);
Bbs->StatusFlag = (UINT16)Strtoi (FlagsStr);
return (EFI_DEVICE_PATH_PROTOCOL *)Bbs;
}
/**
Converts a text device path node to SATA device path structure.
@param TextDeviceNode The input Text device path node.
@return A pointer to the newly-created SATA device path structure.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
DevPathFromTextSata (
IN CHAR16 *TextDeviceNode
)
{
SATA_DEVICE_PATH *Sata;
CHAR16 *Param1;
CHAR16 *Param2;
CHAR16 *Param3;
Param1 = GetNextParamStr (&TextDeviceNode);
Param2 = GetNextParamStr (&TextDeviceNode);
Param3 = GetNextParamStr (&TextDeviceNode);
Sata = (SATA_DEVICE_PATH *)CreateDeviceNode (
MESSAGING_DEVICE_PATH,
MSG_SATA_DP,
(UINT16)sizeof (SATA_DEVICE_PATH)
);
Sata->HBAPortNumber = (UINT16)Strtoi (Param1);
//
// According to UEFI spec, if PMPN is not provided, the default is 0xFFFF
//
if (*Param2 == '\0' ) {
Sata->PortMultiplierPortNumber = 0xFFFF;
} else {
Sata->PortMultiplierPortNumber = (UINT16)Strtoi (Param2);
}
Sata->Lun = (UINT16)Strtoi (Param3);
return (EFI_DEVICE_PATH_PROTOCOL *)Sata;
}
GLOBAL_REMOVE_IF_UNREFERENCED DEVICE_PATH_FROM_TEXT_TABLE mUefiDevicePathLibDevPathFromTextTable[] = {
{ "Path", DevPathFromTextPath },
{ "HardwarePath", DevPathFromTextHardwarePath },
{ "Pci", DevPathFromTextPci },
{ "PcCard", DevPathFromTextPcCard },
{ "MemoryMapped", DevPathFromTextMemoryMapped },
{ "VenHw", DevPathFromTextVenHw },
{ "Ctrl", DevPathFromTextCtrl },
{ "BMC", DevPathFromTextBmc },
{ "AcpiPath", DevPathFromTextAcpiPath },
{ "Acpi", DevPathFromTextAcpi },
{ "PciRoot", DevPathFromTextPciRoot },
{ "PcieRoot", DevPathFromTextPcieRoot },
{ "Floppy", DevPathFromTextFloppy },
{ "Keyboard", DevPathFromTextKeyboard },
{ "Serial", DevPathFromTextSerial },
{ "ParallelPort", DevPathFromTextParallelPort },
{ "AcpiEx", DevPathFromTextAcpiEx },
{ "AcpiExp", DevPathFromTextAcpiExp },
{ "AcpiAdr", DevPathFromTextAcpiAdr },
{ "Msg", DevPathFromTextMsg },
{ "Ata", DevPathFromTextAta },
{ "Scsi", DevPathFromTextScsi },
{ "Fibre", DevPathFromTextFibre },
{ "FibreEx", DevPathFromTextFibreEx },
{ "I1394", DevPathFromText1394 },
{ "USB", DevPathFromTextUsb },
{ "I2O", DevPathFromTextI2O },
{ "Infiniband", DevPathFromTextInfiniband },
{ "VenMsg", DevPathFromTextVenMsg },
{ "VenPcAnsi", DevPathFromTextVenPcAnsi },
{ "VenVt100", DevPathFromTextVenVt100 },
{ "VenVt100Plus", DevPathFromTextVenVt100Plus },
{ "VenUtf8", DevPathFromTextVenUtf8 },
{ "UartFlowCtrl", DevPathFromTextUartFlowCtrl },
{ "SAS", DevPathFromTextSAS },
{ "SasEx", DevPathFromTextSasEx },
{ "NVMe", DevPathFromTextNVMe },
{ "UFS", DevPathFromTextUfs },
{ "SD", DevPathFromTextSd },
{ "eMMC", DevPathFromTextEmmc },
{ "DebugPort", DevPathFromTextDebugPort },
{ "MAC", DevPathFromTextMAC },
{ "IPv4", DevPathFromTextIPv4 },
{ "IPv6", DevPathFromTextIPv6 },
{ "Uart", DevPathFromTextUart },
{ "UsbClass", DevPathFromTextUsbClass },
{ "UsbAudio", DevPathFromTextUsbAudio },
{ "UsbCDCControl", DevPathFromTextUsbCDCControl },
{ "UsbHID", DevPathFromTextUsbHID },
{ "UsbImage", DevPathFromTextUsbImage },
{ "UsbPrinter", DevPathFromTextUsbPrinter },
{ "UsbMassStorage", DevPathFromTextUsbMassStorage },
{ "UsbHub", DevPathFromTextUsbHub },
{ "UsbCDCData", DevPathFromTextUsbCDCData },
{ "UsbSmartCard", DevPathFromTextUsbSmartCard },
{ "UsbVideo", DevPathFromTextUsbVideo },
{ "UsbDiagnostic", DevPathFromTextUsbDiagnostic },
{ "UsbWireless", DevPathFromTextUsbWireless },
{ "UsbDeviceFirmwareUpdate", DevPathFromTextUsbDeviceFirmwareUpdate },
{ "UsbIrdaBridge", DevPathFromTextUsbIrdaBridge },
{ "UsbTestAndMeasurement", DevPathFromTextUsbTestAndMeasurement },
{ "UsbWwid", DevPathFromTextUsbWwid },
{ "Unit", DevPathFromTextUnit },
{ "iSCSI", DevPathFromTextiSCSI },
{ "Vlan", DevPathFromTextVlan },
{ "Dns", DevPathFromTextDns },
{ "Uri", DevPathFromTextUri },
{ "Bluetooth", DevPathFromTextBluetooth },
{ "Wi-Fi", DevPathFromTextWiFi },
{ "BluetoothLE", DevPathFromTextBluetoothLE },
{ "MediaPath", DevPathFromTextMediaPath },
{ "HD", DevPathFromTextHD },
{ "CDROM", DevPathFromTextCDROM },
{ "VenMedia", DevPathFromTextVenMedia },
{ "Media", DevPathFromTextMedia },
{ "Fv", DevPathFromTextFv },
{ "FvFile", DevPathFromTextFvFile },
{ "File", DevPathFromTextFilePath },
{ "Offset", DevPathFromTextRelativeOffsetRange },
{ "RamDisk", DevPathFromTextRamDisk },
{ "VirtualDisk", DevPathFromTextVirtualDisk },
{ "VirtualCD", DevPathFromTextVirtualCd },
{ "PersistentVirtualDisk", DevPathFromTextPersistentVirtualDisk },
{ "PersistentVirtualCD", DevPathFromTextPersistentVirtualCd },
{ "BbsPath", DevPathFromTextBbsPath },
{ "BBS", DevPathFromTextBBS },
{ "Sata", DevPathFromTextSata },
{ NULL, NULL }
};
/**
Convert text to the binary representation of a device node.
@param TextDeviceNode TextDeviceNode points to the text representation of a device
node. Conversion starts with the first character and continues
until the first non-device node character.
@return A pointer to the EFI device node or NULL if TextDeviceNode is NULL or there was
insufficient memory or text unsupported.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
EFIAPI
UefiDevicePathLibConvertTextToDeviceNode (
IN CONST CHAR16 *TextDeviceNode
)
{
DEVICE_PATH_FROM_TEXT FromText;
CHAR16 *ParamStr;
EFI_DEVICE_PATH_PROTOCOL *DeviceNode;
CHAR16 *DeviceNodeStr;
UINTN Index;
if ((TextDeviceNode == NULL) || (IS_NULL (*TextDeviceNode))) {
return NULL;
}
ParamStr = NULL;
FromText = NULL;
DeviceNodeStr = UefiDevicePathLibStrDuplicate (TextDeviceNode);
ASSERT (DeviceNodeStr != NULL);
for (Index = 0; mUefiDevicePathLibDevPathFromTextTable[Index].Function != NULL; Index++) {
ParamStr = GetParamByNodeName (DeviceNodeStr, mUefiDevicePathLibDevPathFromTextTable[Index].DevicePathNodeText);
if (ParamStr != NULL) {
FromText = mUefiDevicePathLibDevPathFromTextTable[Index].Function;
break;
}
}
if (FromText == NULL) {
//
// A file path
//
FromText = DevPathFromTextFilePath;
DeviceNode = FromText (DeviceNodeStr);
} else {
DeviceNode = FromText (ParamStr);
FreePool (ParamStr);
}
FreePool (DeviceNodeStr);
return DeviceNode;
}
/**
Convert text to the binary representation of a device path.
@param TextDevicePath TextDevicePath points to the text representation of a device
path. Conversion starts with the first character and continues
until the first non-device node character.
@return A pointer to the allocated device path or NULL if TextDeviceNode is NULL or
there was insufficient memory.
**/
static
EFI_DEVICE_PATH_PROTOCOL *
EFIAPI
UefiDevicePathLibConvertTextToDevicePath (
IN CONST CHAR16 *TextDevicePath
)
{
EFI_DEVICE_PATH_PROTOCOL *DeviceNode;
EFI_DEVICE_PATH_PROTOCOL *NewDevicePath;
CHAR16 *DevicePathStr;
CHAR16 *Str;
CHAR16 *DeviceNodeStr;
BOOLEAN IsInstanceEnd;
EFI_DEVICE_PATH_PROTOCOL *DevicePath;
if ((TextDevicePath == NULL) || (IS_NULL (*TextDevicePath))) {
return NULL;
}
DevicePath = (EFI_DEVICE_PATH_PROTOCOL *)AllocatePool (END_DEVICE_PATH_LENGTH);
ASSERT (DevicePath != NULL);
SetDevicePathEndNode (DevicePath);
DevicePathStr = UefiDevicePathLibStrDuplicate (TextDevicePath);
Str = DevicePathStr;
while ((DeviceNodeStr = GetNextDeviceNodeStr (&Str, &IsInstanceEnd)) != NULL) {
DeviceNode = UefiDevicePathLibConvertTextToDeviceNode (DeviceNodeStr);
NewDevicePath = AppendDevicePathNode (DevicePath, DeviceNode);
FreePool (DevicePath);
FreePool (DeviceNode);
DevicePath = NewDevicePath;
if (IsInstanceEnd) {
DeviceNode = (EFI_DEVICE_PATH_PROTOCOL *)AllocatePool (END_DEVICE_PATH_LENGTH);
ASSERT (DeviceNode != NULL);
SetDevicePathEndNode (DeviceNode);
DeviceNode->SubType = END_INSTANCE_DEVICE_PATH_SUBTYPE;
NewDevicePath = AppendDevicePathNode (DevicePath, DeviceNode);
FreePool (DevicePath);
FreePool (DeviceNode);
DevicePath = NewDevicePath;
}
}
FreePool (DevicePathStr);
return DevicePath;
}
ssize_t
efidp_parse_device_path(char *path, efidp out, size_t max)
{
EFI_DEVICE_PATH_PROTOCOL *dp;
UINTN len;
dp = UefiDevicePathLibConvertTextToDevicePath (path);
if (dp == NULL)
return -1;
len = GetDevicePathSize(dp);
if (len > max) {
free(dp);
return -1;
}
memcpy(out, dp, len);
free(dp);
return len;
}