audk/EmulatorPkg/Unix/Host/Host.c

1071 lines
29 KiB
C

/*++ @file
Copyright (c) 2006 - 2022, Intel Corporation. All rights reserved.<BR>
Portions copyright (c) 2008 - 2011, Apple Inc. All rights reserved.<BR>
SPDX-License-Identifier: BSD-2-Clause-Patent
**/
#include "Host.h"
#ifdef __APPLE__
#define MAP_ANONYMOUS MAP_ANON
#endif
//
// Globals
//
EMU_THUNK_PPI mSecEmuThunkPpi = {
GasketSecUnixPeiAutoScan,
GasketSecUnixFdAddress,
GasketSecEmuThunkAddress
};
char *gGdbWorkingFileName = NULL;
unsigned int mScriptSymbolChangesCount = 0;
//
// Default information about where the FD is located.
// This array gets filled in with information from EFI_FIRMWARE_VOLUMES
// EFI_FIRMWARE_VOLUMES is a host environment variable set by system.cmd.
// The number of array elements is allocated base on parsing
// EFI_FIRMWARE_VOLUMES and the memory is never freed.
//
UINTN gFdInfoCount = 0;
EMU_FD_INFO *gFdInfo;
//
// Array that supports separate memory ranges.
// The memory ranges are set in system.cmd via the EFI_MEMORY_SIZE variable.
// The number of array elements is allocated base on parsing
// EFI_MEMORY_SIZE and the memory is never freed.
//
UINTN gSystemMemoryCount = 0;
EMU_SYSTEM_MEMORY *gSystemMemory;
EFI_PEI_PPI_DESCRIPTOR *gPpiList;
int gInXcode = 0;
/*++
Breakpoint target for Xcode project. Set in the Xcode XML
Xcode breakpoint will 'source Host.gdb'
gGdbWorkingFileName is set to Host.gdb
**/
VOID
SecGdbConfigBreak (
VOID
)
{
}
/*++
Routine Description:
Main entry point to SEC for Unix. This is a unix program
Arguments:
Argc - Number of command line arguments
Argv - Array of command line argument strings
Envp - Array of environment variable strings
Returns:
0 - Normal exit
1 - Abnormal exit
**/
int
main (
IN int Argc,
IN char **Argv,
IN char **Envp
)
{
EFI_STATUS Status;
EFI_PHYSICAL_ADDRESS InitialStackMemory;
UINT64 InitialStackMemorySize;
UINTN Index;
UINTN Index1;
UINTN Index2;
UINTN PeiIndex;
CHAR8 *FileName;
BOOLEAN Done;
EFI_PEI_FILE_HANDLE FileHandle;
VOID *SecFile;
UINT32 SecFileSize;
CHAR16 *MemorySizeStr;
CHAR16 *FirmwareVolumesStr;
UINTN *StackPointer;
FILE *GdbTempFile;
EMU_THUNK_PPI *SecEmuThunkPpi;
UINT32 AuthenticationStatus;
//
// Xcode does not support sourcing gdb scripts directly, so the Xcode XML
// has a break point script to source the GdbRun.sh script.
//
SecGdbConfigBreak ();
//
// We build a gdb script to allow the symbols to be loaded.
//
Index = strlen (*Argv);
gGdbWorkingFileName = AllocatePool (Index + strlen (".gdb") + 1);
strcpy (gGdbWorkingFileName, *Argv);
strcat (gGdbWorkingFileName, ".gdb");
//
// Empty out the gdb symbols script file.
//
GdbTempFile = fopen (gGdbWorkingFileName, "w");
if (GdbTempFile != NULL) {
fclose (GdbTempFile);
}
printf ("\nEDK II UNIX Host Emulation Environment from http://www.tianocore.org/edk2/\n");
setbuf (stdout, 0);
setbuf (stderr, 0);
MemorySizeStr = (CHAR16 *)PcdGetPtr (PcdEmuMemorySize);
FirmwareVolumesStr = (CHAR16 *)PcdGetPtr (PcdEmuFirmwareVolume);
//
// PPIs pased into PEI_CORE
//
SecEmuThunkPpi = AllocateZeroPool (sizeof (EMU_THUNK_PPI) + FixedPcdGet32 (PcdPersistentMemorySize));
if (SecEmuThunkPpi == NULL) {
printf ("ERROR : Can not allocate memory for SecEmuThunkPpi. Exiting.\n");
exit (1);
}
CopyMem (SecEmuThunkPpi, &mSecEmuThunkPpi, sizeof (EMU_THUNK_PPI));
SecEmuThunkPpi->Argc = Argc;
SecEmuThunkPpi->Argv = Argv;
SecEmuThunkPpi->Envp = Envp;
SecEmuThunkPpi->PersistentMemorySize = FixedPcdGet32 (PcdPersistentMemorySize);
AddThunkPpi (EFI_PEI_PPI_DESCRIPTOR_PPI, &gEmuThunkPpiGuid, SecEmuThunkPpi);
SecInitThunkProtocol ();
//
// Emulator Bus Driver Thunks
//
AddThunkProtocol (&gX11ThunkIo, (CHAR16 *)PcdGetPtr (PcdEmuGop), TRUE);
AddThunkProtocol (&gPosixFileSystemThunkIo, (CHAR16 *)PcdGetPtr (PcdEmuFileSystem), TRUE);
AddThunkProtocol (&gBlockIoThunkIo, (CHAR16 *)PcdGetPtr (PcdEmuVirtualDisk), TRUE);
AddThunkProtocol (&gSnpThunkIo, (CHAR16 *)PcdGetPtr (PcdEmuNetworkInterface), TRUE);
//
// Emulator other Thunks
//
AddThunkProtocol (&gPthreadThunkIo, (CHAR16 *)PcdGetPtr (PcdEmuApCount), FALSE);
// EmuSecLibConstructor ();
gPpiList = GetThunkPpiList ();
//
// Allocate space for gSystemMemory Array
//
gSystemMemoryCount = CountSeparatorsInString (MemorySizeStr, '!') + 1;
gSystemMemory = AllocateZeroPool (gSystemMemoryCount * sizeof (EMU_SYSTEM_MEMORY));
if (gSystemMemory == NULL) {
printf ("ERROR : Can not allocate memory for system. Exiting.\n");
exit (1);
}
//
// Allocate space for gSystemMemory Array
//
gFdInfoCount = CountSeparatorsInString (FirmwareVolumesStr, '!') + 1;
gFdInfo = AllocateZeroPool (gFdInfoCount * sizeof (EMU_FD_INFO));
if (gFdInfo == NULL) {
printf ("ERROR : Can not allocate memory for fd info. Exiting.\n");
exit (1);
}
printf (" BootMode 0x%02x\n", (unsigned int)PcdGet32 (PcdEmuBootMode));
//
// Open up a 128K file to emulate temp memory for SEC.
// on a real platform this would be SRAM, or using the cache as RAM.
// Set InitialStackMemory to zero so UnixOpenFile will allocate a new mapping
//
InitialStackMemorySize = STACK_SIZE;
InitialStackMemory = (UINTN)MapMemory (
0,
(UINT32)InitialStackMemorySize,
PROT_READ | PROT_WRITE | PROT_EXEC,
MAP_ANONYMOUS | MAP_PRIVATE
);
if (InitialStackMemory == 0) {
printf ("ERROR : Can not open SecStack Exiting\n");
exit (1);
}
printf (
" OS Emulator passing in %u KB of temp RAM at 0x%08lx to SEC\n",
(unsigned int)(InitialStackMemorySize / 1024),
(unsigned long)InitialStackMemory
);
for (StackPointer = (UINTN *)(UINTN)InitialStackMemory;
StackPointer < (UINTN *)(UINTN)((UINTN)InitialStackMemory + (UINT64)InitialStackMemorySize);
StackPointer++)
{
*StackPointer = 0x5AA55AA5;
}
//
// Open All the firmware volumes and remember the info in the gFdInfo global
//
FileName = (CHAR8 *)AllocatePool (StrLen (FirmwareVolumesStr) + 1);
if (FileName == NULL) {
printf ("ERROR : Can not allocate memory for firmware volume string\n");
exit (1);
}
Index2 = 0;
for (Done = FALSE, Index = 0, PeiIndex = 0, SecFile = NULL;
FirmwareVolumesStr[Index2] != 0;
Index++)
{
for (Index1 = 0; (FirmwareVolumesStr[Index2] != '!') && (FirmwareVolumesStr[Index2] != 0); Index2++) {
FileName[Index1++] = FirmwareVolumesStr[Index2];
}
if (FirmwareVolumesStr[Index2] == '!') {
Index2++;
}
FileName[Index1] = '\0';
if (Index == 0) {
// Map FV Recovery Read Only and other areas Read/Write
Status = MapFd0 (
FileName,
&gFdInfo[0].Address,
&gFdInfo[0].Size
);
} else {
//
// Open the FD and remember where it got mapped into our processes address space
// Maps Read Only
//
Status = MapFile (
FileName,
&gFdInfo[Index].Address,
&gFdInfo[Index].Size
);
}
if (EFI_ERROR (Status)) {
printf ("ERROR : Can not open Firmware Device File %s (%x). Exiting.\n", FileName, (unsigned int)Status);
exit (1);
}
printf (" FD loaded from %s at 0x%08lx", FileName, (unsigned long)gFdInfo[Index].Address);
if (SecFile == NULL) {
//
// Assume the beginning of the FD is an FV and look for the SEC Core.
// Load the first one we find.
//
FileHandle = NULL;
Status = PeiServicesFfsFindNextFile (
EFI_FV_FILETYPE_SECURITY_CORE,
(EFI_PEI_FV_HANDLE)(UINTN)gFdInfo[Index].Address,
&FileHandle
);
if (!EFI_ERROR (Status)) {
Status = PeiServicesFfsFindSectionData4 (
EFI_SECTION_PE32,
0,
FileHandle,
&SecFile,
&SecFileSize,
&AuthenticationStatus
);
if (!EFI_ERROR (Status)) {
PeiIndex = Index;
printf (" contains SEC Core");
}
}
}
printf ("\n");
}
if (SecFile == NULL) {
printf ("ERROR : SEC not found!\n");
exit (1);
}
//
// Calculate memory regions and store the information in the gSystemMemory
// global for later use. The autosizing code will use this data to
// map this memory into the SEC process memory space.
//
Index1 = 0;
Index = 0;
while (1) {
UINTN val = 0;
//
// Save the size of the memory.
//
while (MemorySizeStr[Index1] >= '0' && MemorySizeStr[Index1] <= '9') {
val = val * 10 + MemorySizeStr[Index1] - '0';
Index1++;
}
gSystemMemory[Index++].Size = val * 0x100000;
if (MemorySizeStr[Index1] == 0) {
break;
}
Index1++;
}
printf ("\n");
//
// Hand off to SEC
//
SecLoadFromCore ((UINTN)InitialStackMemory, (UINTN)InitialStackMemorySize, (UINTN)gFdInfo[0].Address, SecFile, SecFileSize);
//
// If we get here, then the SEC Core returned. This is an error as SEC should
// always hand off to PEI Core and then on to DXE Core.
//
printf ("ERROR : SEC returned\n");
exit (1);
}
EFI_PHYSICAL_ADDRESS *
MapMemory (
IN INTN fd,
IN UINT64 length,
IN INTN prot,
IN INTN flags
)
{
STATIC UINTN base = 0x40000000;
CONST UINTN align = (1 << 24);
VOID *res = NULL;
BOOLEAN isAligned = 0;
//
// Try to get an aligned block somewhere in the address space of this
// process.
//
while ((!isAligned) && (base != 0)) {
res = mmap ((void *)base, length, prot, flags, fd, 0);
if (res == MAP_FAILED) {
return NULL;
}
if ((((UINTN)res) & ~(align-1)) == (UINTN)res) {
isAligned = 1;
} else {
munmap (res, length);
base += align;
}
}
return res;
}
/*++
Routine Description:
Opens and memory maps a file using Unix services. If BaseAddress is non zero
the process will try and allocate the memory starting at BaseAddress.
Arguments:
FileName - The name of the file to open and map
MapSize - The amount of the file to map in bytes
CreationDisposition - The flags to pass to CreateFile(). Use to create new files for
memory emulation, and exiting files for firmware volume emulation
BaseAddress - The base address of the mapped file in the user address space.
If passed in as NULL the a new memory region is used.
If passed in as non NULL the request memory region is used for
the mapping of the file into the process space.
Length - The size of the mapped region in bytes
Returns:
EFI_SUCCESS - The file was opened and mapped.
EFI_NOT_FOUND - FileName was not found in the current directory
EFI_DEVICE_ERROR - An error occurred attempting to map the opened file
**/
EFI_STATUS
MapFile (
IN CHAR8 *FileName,
IN OUT EFI_PHYSICAL_ADDRESS *BaseAddress,
OUT UINT64 *Length
)
{
int fd;
VOID *res;
UINTN FileSize;
fd = open (FileName, O_RDWR);
if (fd < 0) {
return EFI_NOT_FOUND;
}
FileSize = lseek (fd, 0, SEEK_END);
res = MapMemory (fd, FileSize, PROT_READ | PROT_EXEC, MAP_PRIVATE);
close (fd);
if (res == NULL) {
perror ("MapFile() Failed");
return EFI_DEVICE_ERROR;
}
*Length = (UINT64)FileSize;
*BaseAddress = (EFI_PHYSICAL_ADDRESS)(UINTN)res;
return EFI_SUCCESS;
}
EFI_STATUS
MapFd0 (
IN CHAR8 *FileName,
IN OUT EFI_PHYSICAL_ADDRESS *BaseAddress,
OUT UINT64 *Length
)
{
int fd;
void *res, *res2, *res3;
UINTN FileSize;
UINTN FvSize;
void *EmuMagicPage;
fd = open (FileName, O_RDWR);
if (fd < 0) {
return EFI_NOT_FOUND;
}
FileSize = lseek (fd, 0, SEEK_END);
FvSize = FixedPcdGet64 (PcdEmuFlashFvRecoverySize);
// Assume start of FD is Recovery FV, and make it write protected
res = mmap (
(void *)(UINTN)FixedPcdGet64 (PcdEmuFlashFvRecoveryBase),
FvSize,
PROT_READ | PROT_EXEC,
MAP_PRIVATE,
fd,
0
);
if (res == MAP_FAILED) {
perror ("MapFd0() Failed res =");
close (fd);
return EFI_DEVICE_ERROR;
} else if (res != (void *)(UINTN)FixedPcdGet64 (PcdEmuFlashFvRecoveryBase)) {
// We could not load at the build address, so we need to allow writes
munmap (res, FvSize);
res = mmap (
(void *)(UINTN)FixedPcdGet64 (PcdEmuFlashFvRecoveryBase),
FvSize,
PROT_READ | PROT_WRITE | PROT_EXEC,
MAP_PRIVATE,
fd,
0
);
if (res == MAP_FAILED) {
perror ("MapFd0() Failed res =");
close (fd);
return EFI_DEVICE_ERROR;
}
}
// Map the rest of the FD as read/write
res2 = mmap (
(void *)(UINTN)(FixedPcdGet64 (PcdEmuFlashFvRecoveryBase) + FvSize),
FileSize - FvSize,
PROT_READ | PROT_WRITE | PROT_EXEC,
MAP_SHARED,
fd,
FvSize
);
close (fd);
if (res2 == MAP_FAILED) {
perror ("MapFd0() Failed res2 =");
return EFI_DEVICE_ERROR;
}
//
// If enabled use the magic page to communicate between modules
// This replaces the PI PeiServicesTable pointer mechanism that
// deos not work in the emulator. It also allows the removal of
// writable globals from SEC, PEI_CORE (libraries), PEIMs
//
EmuMagicPage = (void *)(UINTN)FixedPcdGet64 (PcdPeiServicesTablePage);
if (EmuMagicPage != NULL) {
res3 = mmap (
(void *)EmuMagicPage,
4096,
PROT_READ | PROT_WRITE,
MAP_PRIVATE | MAP_ANONYMOUS,
0,
0
);
if (res3 != EmuMagicPage) {
printf ("MapFd0(): Could not allocate PeiServicesTablePage @ %lx\n", (long unsigned int)EmuMagicPage);
return EFI_DEVICE_ERROR;
}
}
*Length = (UINT64)FileSize;
*BaseAddress = (EFI_PHYSICAL_ADDRESS)(UINTN)res;
return EFI_SUCCESS;
}
/*++
Routine Description:
This is the service to load the SEC Core from the Firmware Volume
Arguments:
LargestRegion - Memory to use for SEC.
LargestRegionSize - Size of Memory to use for PEI
BootFirmwareVolumeBase - Start of the Boot FV
PeiCorePe32File - SEC PE32
Returns:
Success means control is transferred and thus we should never return
**/
VOID
SecLoadFromCore (
IN UINTN LargestRegion,
IN UINTN LargestRegionSize,
IN UINTN BootFirmwareVolumeBase,
IN VOID *PeiCorePe32File,
IN UINT32 PeiCorePe32Size
)
{
EFI_STATUS Status;
EFI_PHYSICAL_ADDRESS TopOfMemory;
VOID *TopOfStack;
EFI_PHYSICAL_ADDRESS PeiCoreEntryPoint;
EFI_SEC_PEI_HAND_OFF *SecCoreData;
UINTN PeiStackSize;
//
// Compute Top Of Memory for Stack and PEI Core Allocations
//
TopOfMemory = LargestRegion + LargestRegionSize;
PeiStackSize = (UINTN)RShiftU64 ((UINT64)STACK_SIZE, 1);
//
// |-----------| <---- TemporaryRamBase + TemporaryRamSize
// | Heap |
// | |
// |-----------| <---- StackBase / PeiTemporaryMemoryBase
// | |
// | Stack |
// |-----------| <---- TemporaryRamBase
//
TopOfStack = (VOID *)(LargestRegion + PeiStackSize);
TopOfMemory = LargestRegion + PeiStackSize;
//
// Reservet space for storing PeiCore's parament in stack.
//
TopOfStack = (VOID *)((UINTN)TopOfStack - sizeof (EFI_SEC_PEI_HAND_OFF) - CPU_STACK_ALIGNMENT);
TopOfStack = ALIGN_POINTER (TopOfStack, CPU_STACK_ALIGNMENT);
//
// Bind this information into the SEC hand-off state
//
SecCoreData = (EFI_SEC_PEI_HAND_OFF *)(UINTN)TopOfStack;
SecCoreData->DataSize = sizeof (EFI_SEC_PEI_HAND_OFF);
SecCoreData->BootFirmwareVolumeBase = (VOID *)BootFirmwareVolumeBase;
SecCoreData->BootFirmwareVolumeSize = PcdGet32 (PcdEmuFirmwareFdSize);
SecCoreData->TemporaryRamBase = (VOID *)(UINTN)LargestRegion;
SecCoreData->TemporaryRamSize = STACK_SIZE;
SecCoreData->StackBase = SecCoreData->TemporaryRamBase;
SecCoreData->StackSize = PeiStackSize;
SecCoreData->PeiTemporaryRamBase = (VOID *)((UINTN)SecCoreData->TemporaryRamBase + PeiStackSize);
SecCoreData->PeiTemporaryRamSize = STACK_SIZE - PeiStackSize;
//
// Find the SEC Core Entry Point
//
Status = SecUefiImageGetEntryPoint (PeiCorePe32File, PeiCorePe32Size, (VOID **)&PeiCoreEntryPoint);
if (EFI_ERROR (Status)) {
return;
}
//
// Transfer control to the SEC Core
//
PeiSwitchStacks (
(SWITCH_STACK_ENTRY_POINT)(UINTN)PeiCoreEntryPoint,
SecCoreData,
(VOID *)gPpiList,
TopOfStack
);
//
// If we get here, then the SEC Core returned. This is an error
//
return;
}
/*++
Routine Description:
This service is called from Index == 0 until it returns EFI_UNSUPPORTED.
It allows discontinuous memory regions to be supported by the emulator.
It uses gSystemMemory[] and gSystemMemoryCount that were created by
parsing the host environment variable EFI_MEMORY_SIZE.
The size comes from the variable and the address comes from the call to
UnixOpenFile.
Arguments:
Index - Which memory region to use
MemoryBase - Return Base address of memory region
MemorySize - Return size in bytes of the memory region
Returns:
EFI_SUCCESS - If memory region was mapped
EFI_UNSUPPORTED - If Index is not supported
**/
EFI_STATUS
SecUnixPeiAutoScan (
IN UINTN Index,
OUT EFI_PHYSICAL_ADDRESS *MemoryBase,
OUT UINT64 *MemorySize
)
{
void *res;
if (Index >= gSystemMemoryCount) {
return EFI_UNSUPPORTED;
}
*MemoryBase = 0;
res = MapMemory (
0,
gSystemMemory[Index].Size,
PROT_READ | PROT_WRITE | PROT_EXEC,
MAP_PRIVATE | MAP_ANONYMOUS
);
if (res == MAP_FAILED) {
return EFI_DEVICE_ERROR;
}
*MemorySize = gSystemMemory[Index].Size;
*MemoryBase = (UINTN)res;
gSystemMemory[Index].Memory = *MemoryBase;
return EFI_SUCCESS;
}
/*++
Routine Description:
Check to see if an address range is in the EFI GCD memory map.
This is all of GCD for system memory passed to DXE Core. FV
mapping and other device mapped into system memory are not
included in the check.
Arguments:
Index - Which memory region to use
MemoryBase - Return Base address of memory region
MemorySize - Return size in bytes of the memory region
Returns:
TRUE - Address is in the EFI GCD memory map
FALSE - Address is NOT in memory map
**/
BOOLEAN
EfiSystemMemoryRange (
IN VOID *MemoryAddress
)
{
UINTN Index;
EFI_PHYSICAL_ADDRESS MemoryBase;
MemoryBase = (EFI_PHYSICAL_ADDRESS)(UINTN)MemoryAddress;
for (Index = 0; Index < gSystemMemoryCount; Index++) {
if ((MemoryBase >= gSystemMemory[Index].Memory) &&
(MemoryBase < (gSystemMemory[Index].Memory + gSystemMemory[Index].Size)))
{
return TRUE;
}
}
return FALSE;
}
/*++
Routine Description:
Since the SEC is the only Unix program in stack it must export
an interface to do POSIX calls. gUnix is initialized in UnixThunk.c.
Arguments:
InterfaceSize - sizeof (EFI_WIN_NT_THUNK_PROTOCOL);
InterfaceBase - Address of the gUnix global
Returns:
EFI_SUCCESS - Data returned
**/
VOID *
SecEmuThunkAddress (
VOID
)
{
return &gEmuThunkProtocol;
}
RETURN_STATUS
EFIAPI
SecUefiImageGetEntryPoint (
IN VOID *Pe32Data,
IN UINT32 Pe32Size,
IN OUT VOID **EntryPoint
)
{
EFI_STATUS Status;
UEFI_IMAGE_LOADER_IMAGE_CONTEXT ImageContext;
Status = UefiImageInitializeContext (&ImageContext, Pe32Data, Pe32Size);
if (EFI_ERROR (Status)) {
return Status;
}
//
// FIXME: This modifies the FD data (which is not possible on real platforms)
// and thus re-relocation (i.e., PEIM shadowing) fails badly due to
// not updating ImageBase.
//
Status = UefiImageRelocateImageInplaceForExecution (&ImageContext);
if (EFI_ERROR (Status)) {
return Status;
}
SecUefiImageRelocateImageExtraAction (&ImageContext);
*EntryPoint = (VOID *) (UefiImageLoaderGetImageEntryPoint (&ImageContext));
return Status;
}
/*++
Routine Description:
Return the FD Size and base address. Since the FD is loaded from a
file into host memory only the SEC will know its address.
Arguments:
Index - Which FD, starts at zero.
FdSize - Size of the FD in bytes
FdBase - Start address of the FD. Assume it points to an FV Header
FixUp - Difference between actual FD address and build address
Returns:
EFI_SUCCESS - Return the Base address and size of the FV
EFI_UNSUPPORTED - Index does nto map to an FD in the system
**/
EFI_STATUS
SecUnixFdAddress (
IN UINTN Index,
IN OUT EFI_PHYSICAL_ADDRESS *FdBase,
IN OUT UINT64 *FdSize,
IN OUT EFI_PHYSICAL_ADDRESS *FixUp
)
{
if (Index >= gFdInfoCount) {
return EFI_UNSUPPORTED;
}
*FdBase = gFdInfo[Index].Address;
*FdSize = gFdInfo[Index].Size;
*FixUp = 0;
if ((*FdBase == 0) && (*FdSize == 0)) {
return EFI_UNSUPPORTED;
}
if (Index == 0) {
//
// FD 0 has XIP code and well known PCD values
// If the memory buffer could not be allocated at the FD build address
// the Fixup is the difference.
//
*FixUp = *FdBase - PcdGet64 (PcdEmuFdBaseAddress);
}
return EFI_SUCCESS;
}
/*++
Routine Description:
Count the number of separators in String
Arguments:
String - String to process
Separator - Item to count
Returns:
Number of Separator in String
**/
UINTN
CountSeparatorsInString (
IN const CHAR16 *String,
IN CHAR16 Separator
)
{
UINTN Count;
for (Count = 0; *String != '\0'; String++) {
if (*String == Separator) {
Count++;
}
}
return Count;
}
BOOLEAN
IsPdbFile (
IN CONST CHAR8 *PdbFileName
)
{
UINTN Len;
if (PdbFileName == NULL) {
return FALSE;
}
Len = strlen (PdbFileName);
if ((Len < 5) || (PdbFileName[Len - 4] != '.')) {
return FALSE;
}
if (((PdbFileName[Len - 3] == 'P') || (PdbFileName[Len - 3] == 'p')) &&
((PdbFileName[Len - 2] == 'D') || (PdbFileName[Len - 2] == 'd')) &&
((PdbFileName[Len - 1] == 'B') || (PdbFileName[Len - 1] == 'b')))
{
return TRUE;
}
return FALSE;
}
#define MAX_SPRINT_BUFFER_SIZE 0x200
void
PrintLoadAddress (
IN CONST UEFI_IMAGE_LOADER_IMAGE_CONTEXT *ImageContext
)
{
EFI_STATUS Status;
CONST CHAR8 *PdbPath;
UINT32 PdbPathSize;
Status = UefiImageGetSymbolsPath (ImageContext, &PdbPath, &PdbPathSize);
if (EFI_ERROR (Status)) {
fprintf (
stderr,
"0x%08lx Loading NO DEBUG with entry point 0x%08lx\n",
(unsigned long) UefiImageLoaderGetImageAddress (ImageContext),
(unsigned long) UefiImageLoaderGetImageEntryPoint (ImageContext)
);
} else {
fprintf (
stderr,
"0x%08lx Loading %s with entry point 0x%08lx\n",
(unsigned long) UefiImageLoaderGetImageAddress (ImageContext),
PdbPath,
(unsigned long) UefiImageLoaderGetImageEntryPoint (ImageContext)
);
}
// Keep output synced up
fflush (stderr);
}
#ifdef __APPLE__
__attribute__ ((noinline))
#endif
VOID
SecGdbScriptBreak (
const char *FileName,
int FileNameLength,
long unsigned int LoadAddress,
int AddSymbolFlag
)
{
return;
}
/**
Adds the image to a gdb script so its symbols can be loaded.
The AddFirmwareSymbolFile helper macro is used.
@param ImageContext The PE/COFF image context
**/
VOID
GdbScriptAddImage (
IN CONST UEFI_IMAGE_LOADER_IMAGE_CONTEXT *ImageContext
)
{
EFI_STATUS Status;
CONST CHAR8 *PdbPath;
UINT32 PdbPathSize;
PrintLoadAddress (ImageContext);
Status = UefiImageGetSymbolsPath (ImageContext, &PdbPath, &PdbPathSize);
if (EFI_ERROR (Status)) {
return;
}
if (!IsPdbFile (PdbPath)) {
FILE *GdbTempFile;
if (FeaturePcdGet (PcdEmulatorLazyLoadSymbols)) {
GdbTempFile = fopen (gGdbWorkingFileName, "a");
if (GdbTempFile != NULL) {
long unsigned int SymbolsAddr = (long unsigned int)UefiImageLoaderGetImageAddress (ImageContext);
mScriptSymbolChangesCount++;
fprintf (
GdbTempFile,
"AddFirmwareSymbolFile 0x%x %s 0x%08lx\n",
mScriptSymbolChangesCount,
PdbPath,
SymbolsAddr
);
fclose (GdbTempFile);
// This is for the lldb breakpoint only
SecGdbScriptBreak (PdbPath, PdbPathSize, (long unsigned int)UefiImageLoaderGetImageAddress (ImageContext), 1);
} else {
ASSERT (FALSE);
}
} else {
GdbTempFile = fopen (gGdbWorkingFileName, "w");
if (GdbTempFile != NULL) {
fprintf (
GdbTempFile,
"add-symbol-file %s -o 0x%08lx\n",
PdbPath,
(long unsigned int)UefiImageLoaderGetImageAddress (ImageContext)
);
fclose (GdbTempFile);
//
// Target for gdb breakpoint in a script that uses gGdbWorkingFileName to set a breakpoint.
// Hey what can you say scripting in gdb is not that great....
// Also used for the lldb breakpoint script. The lldb breakpoint script does
// not use the file, it uses the arguments.
//
SecGdbScriptBreak (PdbPath, PdbPathSize, (long unsigned int)UefiImageLoaderGetImageAddress (ImageContext), 1);
} else {
ASSERT (FALSE);
}
}
}
}
VOID
EFIAPI
SecUefiImageRelocateImageExtraAction (
IN CONST UEFI_IMAGE_LOADER_IMAGE_CONTEXT *ImageContext
)
{
GdbScriptAddImage (ImageContext);
}
/**
Adds the image to a gdb script so its symbols can be unloaded.
The RemoveFirmwareSymbolFile helper macro is used.
@param ImageContext The PE/COFF image context
**/
VOID
GdbScriptRemoveImage (
IN OUT UEFI_IMAGE_LOADER_IMAGE_CONTEXT *ImageContext
)
{
FILE *GdbTempFile;
EFI_STATUS Status;
CONST CHAR8 *PdbPath;
UINT32 PdbPathSize;
Status = UefiImageGetSymbolsPath (ImageContext, &PdbPath, &PdbPathSize);
if (EFI_ERROR (Status)) {
return;
}
//
// Need to skip .PDB files created from VC++
//
if (IsPdbFile (PdbPath)) {
return;
}
if (FeaturePcdGet (PcdEmulatorLazyLoadSymbols)) {
//
// Write the file we need for the gdb script
//
GdbTempFile = fopen (gGdbWorkingFileName, "a");
if (GdbTempFile != NULL) {
mScriptSymbolChangesCount++;
fprintf (
GdbTempFile,
"RemoveFirmwareSymbolFile 0x%x %s\n",
mScriptSymbolChangesCount,
PdbPath
);
fclose (GdbTempFile);
SecGdbScriptBreak (PdbPath, PdbPathSize, 0, 0);
} else {
ASSERT (FALSE);
}
} else {
GdbTempFile = fopen (gGdbWorkingFileName, "w");
if (GdbTempFile != NULL) {
fprintf (GdbTempFile, "remove-symbol-file %s\n", PdbPath);
fclose (GdbTempFile);
//
// Target for gdb breakpoint in a script that uses gGdbWorkingFileName to set a breakpoint.
// Hey what can you say scripting in gdb is not that great....
//
SecGdbScriptBreak (PdbPath, PdbPathSize, 0, 0);
} else {
ASSERT (FALSE);
}
}
}
VOID
EFIAPI
SecUefiImageUnloadImageExtraAction (
IN UEFI_IMAGE_LOADER_IMAGE_CONTEXT *ImageContext
)
{
GdbScriptRemoveImage (ImageContext);
}