878ddf1f |
1 | /*++\r |
2 | \r |
3 | Copyright (c) 2006, Intel Corporation\r |
4 | All rights reserved. This program and the accompanying materials\r |
5 | are licensed and made available under the terms and conditions of the BSD License\r |
6 | which accompanies this distribution. The full text of the license may be found at\r |
7 | http://opensource.org/licenses/bsd-license.php\r |
8 | \r |
9 | THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS,\r |
10 | WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED.\r |
11 | \r |
12 | Module Name:\r |
13 | \r |
14 | SecMain.c\r |
15 | \r |
16 | Abstract:\r |
17 | WinNt emulator of SEC phase. It's really a Win32 application, but this is\r |
18 | Ok since all the other modules for NT32 are NOT Win32 applications.\r |
19 | \r |
20 | This program processes Windows environment variables and figures out\r |
21 | what the memory layout will be, how may FD's will be loaded and also\r |
22 | what the boot mode is.\r |
23 | \r |
24 | The SEC registers a set of services with the SEC core. gPrivateDispatchTable\r |
25 | is a list of PPI's produced by the SEC that are availble for usage in PEI.\r |
26 | \r |
27 | This code produces 128 K of temporary memory for the PEI stack by opening a\r |
28 | Windows file and mapping it directly to memory addresses.\r |
29 | \r |
30 | The system.cmd script is used to set windows environment variables that drive\r |
31 | the configuration opitons of the SEC.\r |
32 | \r |
33 | --*/\r |
34 | \r |
35 | #include "SecMain.h"\r |
f55a0ac9 |
36 | #pragma warning(disable : 4996)\r |
878ddf1f |
37 | \r |
38 | //\r |
39 | // Globals\r |
40 | //\r |
41 | EFI_PEI_PE_COFF_LOADER_PROTOCOL_INSTANCE mPeiEfiPeiPeCoffLoaderInstance = {\r |
42 | {\r |
43 | SecNt32PeCoffGetImageInfo,\r |
44 | SecNt32PeCoffLoadImage,\r |
45 | SecNt32PeCoffRelocateImage,\r |
46 | SecNt32PeCoffUnloadimage\r |
47 | },\r |
48 | NULL\r |
49 | };\r |
50 | \r |
51 | \r |
52 | \r |
53 | EFI_PEI_PE_COFF_LOADER_PROTOCOL *gPeiEfiPeiPeCoffLoader = &mPeiEfiPeiPeCoffLoaderInstance.PeCoff;\r |
54 | \r |
55 | NT_PEI_LOAD_FILE_PPI mSecNtLoadFilePpi = { SecWinNtPeiLoadFile };\r |
56 | \r |
57 | PEI_NT_AUTOSCAN_PPI mSecNtAutoScanPpi = { SecWinNtPeiAutoScan };\r |
58 | \r |
59 | PEI_NT_THUNK_PPI mSecWinNtThunkPpi = { SecWinNtWinNtThunkAddress };\r |
60 | \r |
61 | EFI_PEI_PROGRESS_CODE_PPI mSecStatusCodePpi = { SecPeiReportStatusCode };\r |
62 | \r |
63 | NT_FWH_PPI mSecFwhInformationPpi = { SecWinNtFdAddress };\r |
64 | \r |
65 | \r |
66 | EFI_PEI_PPI_DESCRIPTOR gPrivateDispatchTable[] = {\r |
67 | {\r |
68 | EFI_PEI_PPI_DESCRIPTOR_PPI,\r |
69 | &gEfiPeiPeCoffLoaderGuid,\r |
70 | NULL\r |
71 | },\r |
72 | {\r |
73 | EFI_PEI_PPI_DESCRIPTOR_PPI,\r |
74 | &gNtPeiLoadFilePpiGuid,\r |
75 | &mSecNtLoadFilePpi\r |
76 | },\r |
77 | {\r |
78 | EFI_PEI_PPI_DESCRIPTOR_PPI,\r |
79 | &gPeiNtAutoScanPpiGuid,\r |
80 | &mSecNtAutoScanPpi\r |
81 | },\r |
82 | {\r |
83 | EFI_PEI_PPI_DESCRIPTOR_PPI,\r |
84 | &gPeiNtThunkPpiGuid,\r |
85 | &mSecWinNtThunkPpi\r |
86 | },\r |
87 | {\r |
88 | EFI_PEI_PPI_DESCRIPTOR_PPI,\r |
89 | &gEfiPeiStatusCodePpiGuid,\r |
90 | &mSecStatusCodePpi\r |
91 | },\r |
92 | {\r |
93 | EFI_PEI_PPI_DESCRIPTOR_PPI | EFI_PEI_PPI_DESCRIPTOR_TERMINATE_LIST,\r |
94 | &gNtFwhPpiGuid,\r |
95 | &mSecFwhInformationPpi\r |
96 | }\r |
97 | };\r |
98 | \r |
99 | \r |
100 | //\r |
101 | // Default information about where the FD is located.\r |
102 | // This array gets filled in with information from EFI_FIRMWARE_VOLUMES\r |
103 | // EFI_FIRMWARE_VOLUMES is a Windows environment variable set by system.cmd.\r |
104 | // The number of array elements is allocated base on parsing\r |
105 | // EFI_FIRMWARE_VOLUMES and the memory is never freed.\r |
106 | //\r |
107 | UINTN gFdInfoCount = 0;\r |
108 | NT_FD_INFO *gFdInfo;\r |
109 | \r |
110 | //\r |
111 | // Array that supports seperate memory rantes.\r |
112 | // The memory ranges are set in system.cmd via the EFI_MEMORY_SIZE variable.\r |
113 | // The number of array elements is allocated base on parsing\r |
114 | // EFI_MEMORY_SIZE and the memory is never freed.\r |
115 | //\r |
116 | UINTN gSystemMemoryCount = 0;\r |
117 | NT_SYSTEM_MEMORY *gSystemMemory;\r |
118 | \r |
119 | \r |
120 | UINTN mPdbNameModHandleArraySize = 0;\r |
121 | PDB_NAME_TO_MOD_HANDLE *mPdbNameModHandleArray = NULL;\r |
122 | \r |
123 | \r |
124 | \r |
125 | \r |
126 | INTN\r |
127 | EFIAPI\r |
128 | main (\r |
129 | IN INTN Argc,\r |
130 | IN CHAR8 **Argv,\r |
131 | IN CHAR8 **Envp\r |
132 | )\r |
133 | /*++\r |
134 | \r |
135 | Routine Description:\r |
136 | Main entry point to SEC for WinNt. This is a Windows program\r |
137 | \r |
138 | Arguments:\r |
139 | Argc - Number of command line arguments\r |
140 | Argv - Array of command line argument strings\r |
141 | Envp - Array of environmemt variable strings\r |
142 | \r |
143 | Returns:\r |
144 | 0 - Normal exit\r |
145 | 1 - Abnormal exit\r |
146 | \r |
147 | --*/\r |
148 | {\r |
149 | EFI_STATUS Status;\r |
150 | EFI_PHYSICAL_ADDRESS InitialStackMemory;\r |
151 | UINT64 InitialStackMemorySize;\r |
152 | UINTN Index;\r |
153 | UINTN Index1;\r |
154 | UINTN Index2;\r |
155 | UINTN PeiIndex;\r |
156 | CHAR16 *FileName;\r |
157 | CHAR16 *FileNamePtr;\r |
158 | BOOLEAN Done;\r |
159 | VOID *PeiCoreFile;\r |
160 | CHAR16 *MemorySizeStr;\r |
161 | CHAR16 *FirmwareVolumesStr;\r |
162 | \r |
b144ae9a |
163 | MemorySizeStr = (CHAR16 *)PcdGetPtr (PcdWinNtMemorySizeForSecMain);\r |
164 | FirmwareVolumesStr = (CHAR16 *)PcdGetPtr (PcdWinNtFirmwareVolume);\r |
878ddf1f |
165 | \r |
166 | printf ("\nEDK SEC Main NT Emulation Environment from www.TianoCore.org\n");\r |
167 | \r |
168 | //\r |
169 | // Make some Windows calls to Set the process to the highest priority in the\r |
170 | // idle class. We need this to have good performance.\r |
171 | //\r |
172 | SetPriorityClass (GetCurrentProcess (), IDLE_PRIORITY_CLASS);\r |
173 | SetThreadPriority (GetCurrentThread (), THREAD_PRIORITY_HIGHEST);\r |
174 | \r |
175 | //\r |
176 | // Allocate space for gSystemMemory Array\r |
177 | //\r |
178 | gSystemMemoryCount = CountSeperatorsInString (MemorySizeStr, '!') + 1;\r |
179 | gSystemMemory = calloc (gSystemMemoryCount, sizeof (NT_SYSTEM_MEMORY));\r |
180 | if (gSystemMemory == NULL) {\r |
181 | printf ("ERROR : Can not allocate memory for %s. Exiting.\n", MemorySizeStr);\r |
182 | exit (1);\r |
183 | }\r |
184 | //\r |
185 | // Allocate space for gSystemMemory Array\r |
186 | //\r |
187 | gFdInfoCount = CountSeperatorsInString (FirmwareVolumesStr, '!') + 1;\r |
188 | gFdInfo = calloc (gFdInfoCount, sizeof (NT_FD_INFO));\r |
189 | if (gFdInfo == NULL) {\r |
190 | printf ("ERROR : Can not allocate memory for %s. Exiting.\n", FirmwareVolumesStr);\r |
191 | exit (1);\r |
192 | }\r |
193 | //\r |
194 | // Setup Boot Mode. If BootModeStr == "" then BootMode = 0 (BOOT_WITH_FULL_CONFIGURATION)\r |
195 | //\r |
196 | printf (" BootMode 0x%02x\n", FixedPcdGet32 (PcdWinNtBootMode));\r |
197 | \r |
198 | //\r |
199 | // Open up a 128K file to emulate temp memory for PEI.\r |
200 | // on a real platform this would be SRAM, or using the cache as RAM.\r |
201 | // Set InitialStackMemory to zero so WinNtOpenFile will allocate a new mapping\r |
202 | //\r |
203 | InitialStackMemory = 0;\r |
204 | InitialStackMemorySize = 0x20000;\r |
205 | Status = WinNtOpenFile (\r |
206 | L"SecStack",\r |
207 | (UINT32) InitialStackMemorySize,\r |
208 | OPEN_ALWAYS,\r |
209 | &InitialStackMemory,\r |
210 | &InitialStackMemorySize\r |
211 | );\r |
212 | if (EFI_ERROR (Status)) {\r |
213 | printf ("ERROR : Can not open SecStack Exiting\n");\r |
214 | exit (1);\r |
215 | }\r |
216 | \r |
217 | printf (" SEC passing in %d bytes of temp RAM to PEI\n", InitialStackMemorySize);\r |
218 | \r |
219 | //\r |
220 | // Open All the firmware volumes and remember the info in the gFdInfo global\r |
221 | //\r |
222 | FileNamePtr = (CHAR16 *)malloc (StrLen ((CHAR16 *)FirmwareVolumesStr) * sizeof(CHAR16));\r |
223 | if (FileNamePtr == NULL) {\r |
224 | printf ("ERROR : Can not allocate memory for firmware volume string\n");\r |
225 | exit (1);\r |
226 | }\r |
227 | \r |
228 | StrCpy (FileNamePtr, (CHAR16*)FirmwareVolumesStr);\r |
229 | \r |
230 | for (Done = FALSE, Index = 0, PeiIndex = 0, PeiCoreFile = NULL; !Done; Index++) {\r |
231 | FileName = FileNamePtr;\r |
232 | for (Index1 = 0; (FileNamePtr[Index1] != '!') && (FileNamePtr[Index1] != 0); Index1++)\r |
233 | ;\r |
234 | if (FileNamePtr[Index1] == 0) {\r |
235 | Done = TRUE;\r |
236 | } else {\r |
237 | FileNamePtr[Index1] = '\0';\r |
238 | FileNamePtr = FileNamePtr + Index1 + 1;\r |
239 | }\r |
240 | \r |
241 | //\r |
242 | // Open the FD and remmeber where it got mapped into our processes address space\r |
243 | //\r |
244 | Status = WinNtOpenFile (\r |
245 | FileName,\r |
246 | 0,\r |
247 | OPEN_EXISTING,\r |
248 | &gFdInfo[Index].Address,\r |
249 | &gFdInfo[Index].Size\r |
250 | );\r |
251 | if (EFI_ERROR (Status)) {\r |
252 | printf ("ERROR : Can not open Firmware Device File %S (%r). Exiting.\n", FileName, Status);\r |
253 | exit (1);\r |
254 | }\r |
255 | \r |
256 | printf (" FD loaded from");\r |
257 | //\r |
258 | // printf can't print filenames directly as the \ gets interperted as an\r |
259 | // escape character.\r |
260 | //\r |
261 | for (Index2 = 0; FileName[Index2] != '\0'; Index2++) {\r |
262 | printf ("%c", FileName[Index2]);\r |
263 | }\r |
264 | \r |
265 | if (PeiCoreFile == NULL) {\r |
266 | //\r |
267 | // Assume the beginning of the FD is an FV and look for the PEI Core.\r |
268 | // Load the first one we find.\r |
269 | //\r |
270 | Status = SecFfsFindPeiCore ((EFI_FIRMWARE_VOLUME_HEADER *) (UINTN) gFdInfo[Index].Address, &PeiCoreFile);\r |
271 | if (!EFI_ERROR (Status)) {\r |
272 | PeiIndex = Index;\r |
273 | printf (" contains SEC Core");\r |
274 | }\r |
275 | }\r |
276 | \r |
277 | printf ("\n");\r |
278 | }\r |
279 | //\r |
280 | // Calculate memory regions and store the information in the gSystemMemory\r |
281 | // global for later use. The autosizing code will use this data to\r |
282 | // map this memory into the SEC process memory space.\r |
283 | //\r |
284 | for (Index = 0, Done = FALSE; !Done; Index++) {\r |
285 | //\r |
286 | // Save the size of the memory and make a Unicode filename SystemMemory00, ...\r |
287 | //\r |
288 | gSystemMemory[Index].Size = _wtoi (MemorySizeStr) * 0x100000;\r |
289 | _snwprintf (gSystemMemory[Index].FileName, NT_SYSTEM_MEMORY_FILENAME_SIZE, L"SystemMemory%02d", Index);\r |
290 | \r |
291 | //\r |
292 | // Find the next region\r |
293 | //\r |
294 | for (Index1 = 0; MemorySizeStr[Index1] != '!' && MemorySizeStr[Index1] != 0; Index1++)\r |
295 | ;\r |
296 | if (MemorySizeStr[Index1] == 0) {\r |
297 | Done = TRUE;\r |
298 | }\r |
299 | \r |
300 | MemorySizeStr = MemorySizeStr + Index1 + 1;\r |
301 | }\r |
302 | \r |
303 | printf ("\n");\r |
304 | \r |
305 | //\r |
306 | // Hand off to PEI Core\r |
307 | //\r |
308 | SecLoadFromCore ((UINTN) InitialStackMemory, (UINTN) InitialStackMemorySize, (UINTN) gFdInfo[0].Address, PeiCoreFile);\r |
309 | \r |
310 | //\r |
311 | // If we get here, then the PEI Core returned. This is an error as PEI should\r |
312 | // always hand off to DXE.\r |
313 | //\r |
314 | printf ("ERROR : PEI Core returned\n");\r |
315 | exit (1);\r |
316 | }\r |
317 | \r |
318 | EFI_STATUS\r |
319 | WinNtOpenFile (\r |
320 | IN CHAR16 *FileName,\r |
321 | IN UINT32 MapSize,\r |
322 | IN DWORD CreationDisposition,\r |
323 | IN OUT EFI_PHYSICAL_ADDRESS *BaseAddress,\r |
324 | OUT UINT64 *Length\r |
325 | )\r |
326 | /*++\r |
327 | \r |
328 | Routine Description:\r |
329 | Opens and memory maps a file using WinNt services. If BaseAddress is non zero\r |
330 | the process will try and allocate the memory starting at BaseAddress.\r |
331 | \r |
332 | Arguments:\r |
333 | FileName - The name of the file to open and map\r |
334 | MapSize - The amount of the file to map in bytes\r |
335 | CreationDisposition - The flags to pass to CreateFile(). Use to create new files for\r |
336 | memory emulation, and exiting files for firmware volume emulation\r |
337 | BaseAddress - The base address of the mapped file in the user address space.\r |
338 | If passed in as NULL the a new memory region is used.\r |
339 | If passed in as non NULL the request memory region is used for\r |
340 | the mapping of the file into the process space.\r |
341 | Length - The size of the mapped region in bytes\r |
342 | \r |
343 | Returns:\r |
344 | EFI_SUCCESS - The file was opened and mapped.\r |
345 | EFI_NOT_FOUND - FileName was not found in the current directory\r |
346 | EFI_DEVICE_ERROR - An error occured attempting to map the opened file\r |
347 | \r |
348 | --*/\r |
349 | {\r |
350 | HANDLE NtFileHandle;\r |
351 | HANDLE NtMapHandle;\r |
352 | VOID *VirtualAddress;\r |
353 | UINTN FileSize;\r |
354 | \r |
355 | //\r |
356 | // Use Win API to open/create a file\r |
357 | //\r |
358 | NtFileHandle = CreateFile (\r |
359 | FileName,\r |
360 | GENERIC_READ | GENERIC_WRITE,\r |
361 | FILE_SHARE_READ,\r |
362 | NULL,\r |
363 | CreationDisposition,\r |
364 | FILE_ATTRIBUTE_NORMAL,\r |
365 | NULL\r |
366 | );\r |
367 | if (NtFileHandle == INVALID_HANDLE_VALUE) {\r |
368 | return EFI_NOT_FOUND;\r |
369 | }\r |
370 | //\r |
371 | // Map the open file into a memory range\r |
372 | //\r |
373 | NtMapHandle = CreateFileMapping (\r |
374 | NtFileHandle,\r |
375 | NULL,\r |
376 | PAGE_READWRITE,\r |
377 | 0,\r |
378 | MapSize,\r |
379 | NULL\r |
380 | );\r |
381 | if (NtMapHandle == NULL) {\r |
382 | return EFI_DEVICE_ERROR;\r |
383 | }\r |
384 | //\r |
385 | // Get the virtual address (address in the emulator) of the mapped file\r |
386 | //\r |
387 | VirtualAddress = MapViewOfFileEx (\r |
388 | NtMapHandle,\r |
389 | FILE_MAP_ALL_ACCESS,\r |
390 | 0,\r |
391 | 0,\r |
392 | MapSize,\r |
393 | (LPVOID) (UINTN) *BaseAddress\r |
394 | );\r |
395 | if (VirtualAddress == NULL) {\r |
396 | return EFI_DEVICE_ERROR;\r |
397 | }\r |
398 | \r |
399 | if (MapSize == 0) {\r |
400 | //\r |
401 | // Seek to the end of the file to figure out the true file size.\r |
402 | //\r |
403 | FileSize = SetFilePointer (\r |
404 | NtFileHandle,\r |
405 | 0,\r |
406 | NULL,\r |
407 | FILE_END\r |
408 | );\r |
409 | if (FileSize == -1) {\r |
410 | return EFI_DEVICE_ERROR;\r |
411 | }\r |
412 | \r |
413 | *Length = (UINT64) FileSize;\r |
414 | } else {\r |
415 | *Length = (UINT64) MapSize;\r |
416 | }\r |
417 | \r |
418 | *BaseAddress = (EFI_PHYSICAL_ADDRESS) (UINTN) VirtualAddress;\r |
419 | \r |
420 | return EFI_SUCCESS;\r |
421 | }\r |
422 | \r |
423 | #define BYTES_PER_RECORD 512\r |
424 | \r |
35b309d6 |
425 | /**\r |
426 | Extracts ASSERT() information from a status code structure.\r |
427 | \r |
428 | Converts the status code specified by CodeType, Value, and Data to the ASSERT()\r |
429 | arguments specified by Filename, Description, and LineNumber. If CodeType is \r |
430 | an EFI_ERROR_CODE, and CodeType has a severity of EFI_ERROR_UNRECOVERED, and \r |
431 | Value has an operation mask of EFI_SW_EC_ILLEGAL_SOFTWARE_STATE, extract \r |
432 | Filename, Description, and LineNumber from the optional data area of the \r |
433 | status code buffer specified by Data. The optional data area of Data contains \r |
434 | a Null-terminated ASCII string for the FileName, followed by a Null-terminated \r |
435 | ASCII string for the Description, followed by a 32-bit LineNumber. If the \r |
436 | ASSERT() information could be extracted from Data, then return TRUE. \r |
437 | Otherwise, FALSE is returned. \r |
438 | \r |
439 | If Data is NULL, then ASSERT().\r |
440 | If Filename is NULL, then ASSERT().\r |
441 | If Description is NULL, then ASSERT().\r |
442 | If LineNumber is NULL, then ASSERT().\r |
443 | \r |
444 | @param CodeType The type of status code being converted.\r |
445 | @param Value The status code value being converted.\r |
446 | @param Data Pointer to status code data buffer. \r |
447 | @param Filename Pointer to the source file name that generated the ASSERT().\r |
448 | @param Description Pointer to the description of the ASSERT().\r |
449 | @param LineNumber Pointer to source line number that generated the ASSERT().\r |
450 | \r |
451 | @retval TRUE The status code specified by CodeType, Value, and Data was \r |
452 | converted ASSERT() arguments specified by Filename, Description, \r |
453 | and LineNumber.\r |
454 | @retval FALSE The status code specified by CodeType, Value, and Data could \r |
455 | not be converted to ASSERT() arguments.\r |
456 | \r |
457 | **/\r |
458 | STATIC\r |
459 | BOOLEAN\r |
460 | ReportStatusCodeExtractAssertInfo (\r |
461 | IN EFI_STATUS_CODE_TYPE CodeType,\r |
462 | IN EFI_STATUS_CODE_VALUE Value, \r |
463 | IN CONST EFI_STATUS_CODE_DATA *Data, \r |
464 | OUT CHAR8 **Filename,\r |
465 | OUT CHAR8 **Description,\r |
466 | OUT UINT32 *LineNumber\r |
467 | )\r |
468 | {\r |
469 | EFI_DEBUG_ASSERT_DATA *AssertData;\r |
470 | \r |
471 | ASSERT (Data != NULL);\r |
472 | ASSERT (Filename != NULL);\r |
473 | ASSERT (Description != NULL);\r |
474 | ASSERT (LineNumber != NULL);\r |
475 | \r |
476 | if (((CodeType & EFI_STATUS_CODE_TYPE_MASK) == EFI_ERROR_CODE) && \r |
477 | ((CodeType & EFI_STATUS_CODE_SEVERITY_MASK) == EFI_ERROR_UNRECOVERED) &&\r |
478 | ((Value & EFI_STATUS_CODE_OPERATION_MASK) == EFI_SW_EC_ILLEGAL_SOFTWARE_STATE)) {\r |
479 | AssertData = (EFI_DEBUG_ASSERT_DATA *)(Data + 1);\r |
480 | *Filename = (CHAR8 *)(AssertData + 1);\r |
481 | *Description = *Filename + AsciiStrLen (*Filename) + 1;\r |
482 | *LineNumber = AssertData->LineNumber;\r |
483 | return TRUE;\r |
484 | }\r |
485 | return FALSE;\r |
486 | }\r |
487 | \r |
878ddf1f |
488 | EFI_STATUS\r |
489 | EFIAPI\r |
490 | SecPeiReportStatusCode (\r |
491 | IN EFI_PEI_SERVICES **PeiServices,\r |
492 | IN EFI_STATUS_CODE_TYPE CodeType,\r |
493 | IN EFI_STATUS_CODE_VALUE Value,\r |
494 | IN UINT32 Instance,\r |
495 | IN EFI_GUID * CallerId,\r |
496 | IN EFI_STATUS_CODE_DATA * Data OPTIONAL\r |
497 | )\r |
498 | /*++\r |
499 | \r |
500 | Routine Description:\r |
501 | \r |
502 | This routine produces the ReportStatusCode PEI service. It's passed\r |
503 | up to the PEI Core via a PPI. T\r |
504 | \r |
505 | This code currently uses the NT clib printf. This does not work the same way\r |
506 | as the EFI Print (), as %t, %g, %s as Unicode are not supported.\r |
507 | \r |
508 | Arguments:\r |
509 | (see EFI_PEI_REPORT_STATUS_CODE)\r |
510 | \r |
511 | Returns:\r |
512 | EFI_SUCCESS - Always return success\r |
513 | \r |
514 | --*/\r |
515 | // TODO: PeiServices - add argument and description to function comment\r |
516 | // TODO: CodeType - add argument and description to function comment\r |
517 | // TODO: Value - add argument and description to function comment\r |
518 | // TODO: Instance - add argument and description to function comment\r |
519 | // TODO: CallerId - add argument and description to function comment\r |
520 | // TODO: Data - add argument and description to function comment\r |
521 | {\r |
522 | CHAR8 *Format;\r |
523 | EFI_DEBUG_INFO *DebugInfo;\r |
524 | VA_LIST Marker;\r |
525 | CHAR8 PrintBuffer[BYTES_PER_RECORD * 2];\r |
526 | CHAR8 *Filename;\r |
527 | CHAR8 *Description;\r |
528 | UINT32 LineNumber;\r |
529 | \r |
530 | if ((CodeType & EFI_STATUS_CODE_TYPE_MASK) == EFI_DEBUG_CODE) {\r |
531 | //\r |
532 | // This supports DEBUG () marcos\r |
533 | // Data format\r |
534 | // EFI_STATUS_CODE_DATA\r |
535 | // EFI_DEBUG_INFO\r |
536 | //\r |
537 | // The first 12 * UINT64 bytes of the string are really an\r |
538 | // arguement stack to support varargs on the Format string.\r |
539 | //\r |
21802505 |
540 | if (Data != NULL) {\r |
541 | DebugInfo = (EFI_DEBUG_INFO *) (Data + 1);\r |
542 | Marker = (VA_LIST) (DebugInfo + 1);\r |
543 | Format = (CHAR8 *) (((UINT64 *) Marker) + 12);\r |
878ddf1f |
544 | \r |
21802505 |
545 | AsciiVSPrint (PrintBuffer, BYTES_PER_RECORD, Format, Marker);\r |
546 | printf (PrintBuffer);\r |
547 | } else {\r |
548 | printf ("DEBUG <null>\n");\r |
549 | }\r |
878ddf1f |
550 | }\r |
551 | \r |
552 | if (((CodeType & EFI_STATUS_CODE_TYPE_MASK) == EFI_ERROR_CODE) &&\r |
553 | ((CodeType & EFI_STATUS_CODE_SEVERITY_MASK) == EFI_ERROR_UNRECOVERED)\r |
554 | ) {\r |
21802505 |
555 | if (Data != NULL && ReportStatusCodeExtractAssertInfo (CodeType, Value, Data, &Filename, &Description, &LineNumber)) {\r |
878ddf1f |
556 | //\r |
557 | // Support ASSERT () macro\r |
558 | //\r |
559 | printf ("ASSERT %s(%d): %s\n", Filename, LineNumber, Description);\r |
21802505 |
560 | } else {\r |
561 | printf ("ASSERT <null>\n");\r |
878ddf1f |
562 | }\r |
21802505 |
563 | CpuBreakpoint ();\r |
878ddf1f |
564 | }\r |
565 | \r |
566 | return EFI_SUCCESS;\r |
567 | }\r |
568 | \r |
569 | \r |
570 | VOID\r |
571 | SecLoadFromCore (\r |
572 | IN UINTN LargestRegion,\r |
573 | IN UINTN LargestRegionSize,\r |
574 | IN UINTN BootFirmwareVolumeBase,\r |
575 | IN VOID *PeiCorePe32File\r |
576 | )\r |
577 | /*++\r |
578 | \r |
579 | Routine Description:\r |
580 | This is the service to load the PEI Core from the Firmware Volume\r |
581 | \r |
582 | Arguments:\r |
583 | LargestRegion - Memory to use for PEI.\r |
584 | LargestRegionSize - Size of Memory to use for PEI\r |
585 | BootFirmwareVolumeBase - Start of the Boot FV\r |
586 | PeiCorePe32File - PEI Core PE32\r |
587 | \r |
588 | Returns:\r |
589 | Success means control is transfered and thus we should never return\r |
590 | \r |
591 | --*/\r |
592 | {\r |
593 | EFI_STATUS Status;\r |
594 | EFI_PHYSICAL_ADDRESS TopOfMemory;\r |
595 | VOID *TopOfStack;\r |
596 | UINT64 PeiCoreSize;\r |
597 | EFI_PHYSICAL_ADDRESS PeiCoreEntryPoint;\r |
598 | EFI_PHYSICAL_ADDRESS PeiImageAddress;\r |
599 | EFI_PEI_STARTUP_DESCRIPTOR *PeiStartup;\r |
600 | \r |
601 | //\r |
602 | // Compute Top Of Memory for Stack and PEI Core Allocations\r |
603 | //\r |
e7e9595a |
604 | TopOfMemory = LargestRegion + LargestRegionSize;\r |
878ddf1f |
605 | \r |
606 | //\r |
607 | // Allocate 128KB for the Stack\r |
608 | //\r |
e7e9595a |
609 | TopOfStack = (VOID *)((UINTN)TopOfMemory - sizeof (EFI_PEI_STARTUP_DESCRIPTOR) - CPU_STACK_ALIGNMENT);\r |
610 | TopOfStack = ALIGN_POINTER (TopOfStack, CPU_STACK_ALIGNMENT);\r |
878ddf1f |
611 | TopOfMemory = TopOfMemory - STACK_SIZE;\r |
612 | \r |
613 | //\r |
614 | // Patch value in dispatch table values\r |
615 | //\r |
616 | gPrivateDispatchTable[0].Ppi = gPeiEfiPeiPeCoffLoader;\r |
617 | \r |
618 | //\r |
619 | // Bind this information into the SEC hand-off state\r |
620 | //\r |
621 | PeiStartup = (EFI_PEI_STARTUP_DESCRIPTOR *) (UINTN) TopOfStack;\r |
622 | PeiStartup->DispatchTable = (EFI_PEI_PPI_DESCRIPTOR *) &gPrivateDispatchTable;\r |
623 | PeiStartup->SizeOfCacheAsRam = STACK_SIZE;\r |
624 | PeiStartup->BootFirmwareVolume = BootFirmwareVolumeBase;\r |
625 | \r |
626 | //\r |
627 | // Load the PEI Core from a Firmware Volume\r |
628 | //\r |
629 | Status = SecWinNtPeiLoadFile (\r |
630 | PeiCorePe32File,\r |
631 | &PeiImageAddress,\r |
632 | &PeiCoreSize,\r |
633 | &PeiCoreEntryPoint\r |
634 | );\r |
635 | if (EFI_ERROR (Status)) {\r |
636 | return ;\r |
637 | }\r |
638 | //\r |
639 | // Transfer control to the PEI Core\r |
640 | //\r |
641 | SwitchStack (\r |
642 | (SWITCH_STACK_ENTRY_POINT) (UINTN) PeiCoreEntryPoint,\r |
643 | PeiStartup,\r |
644 | NULL,\r |
645 | TopOfStack\r |
646 | );\r |
647 | //\r |
648 | // If we get here, then the PEI Core returned. This is an error\r |
649 | //\r |
650 | return ;\r |
651 | }\r |
652 | \r |
653 | EFI_STATUS\r |
654 | EFIAPI\r |
655 | SecWinNtPeiAutoScan (\r |
656 | IN UINTN Index,\r |
657 | OUT EFI_PHYSICAL_ADDRESS *MemoryBase,\r |
658 | OUT UINT64 *MemorySize\r |
659 | )\r |
660 | /*++\r |
661 | \r |
662 | Routine Description:\r |
663 | This service is called from Index == 0 until it returns EFI_UNSUPPORTED.\r |
664 | It allows discontiguous memory regions to be supported by the emulator.\r |
665 | It uses gSystemMemory[] and gSystemMemoryCount that were created by\r |
666 | parsing the Windows environment variable EFI_MEMORY_SIZE.\r |
667 | The size comes from the varaible and the address comes from the call to\r |
668 | WinNtOpenFile.\r |
669 | \r |
670 | Arguments:\r |
671 | Index - Which memory region to use\r |
672 | MemoryBase - Return Base address of memory region\r |
673 | MemorySize - Return size in bytes of the memory region\r |
674 | \r |
675 | Returns:\r |
676 | EFI_SUCCESS - If memory region was mapped\r |
677 | EFI_UNSUPPORTED - If Index is not supported\r |
678 | \r |
679 | --*/\r |
680 | {\r |
681 | EFI_STATUS Status;\r |
682 | \r |
683 | if (Index >= gSystemMemoryCount) {\r |
684 | return EFI_UNSUPPORTED;\r |
685 | }\r |
686 | \r |
687 | *MemoryBase = 0;\r |
688 | Status = WinNtOpenFile (\r |
689 | gSystemMemory[Index].FileName,\r |
690 | (UINT32) gSystemMemory[Index].Size,\r |
691 | OPEN_ALWAYS,\r |
692 | MemoryBase,\r |
693 | MemorySize\r |
694 | );\r |
695 | \r |
696 | gSystemMemory[Index].Memory = *MemoryBase;\r |
697 | \r |
698 | return Status;\r |
699 | }\r |
700 | \r |
701 | VOID *\r |
702 | EFIAPI\r |
703 | SecWinNtWinNtThunkAddress (\r |
704 | VOID\r |
705 | )\r |
706 | /*++\r |
707 | \r |
708 | Routine Description:\r |
709 | Since the SEC is the only Windows program in stack it must export\r |
710 | an interface to do Win API calls. That's what the WinNtThunk address\r |
711 | is for. gWinNt is initailized in WinNtThunk.c.\r |
712 | \r |
713 | Arguments:\r |
714 | InterfaceSize - sizeof (EFI_WIN_NT_THUNK_PROTOCOL);\r |
715 | InterfaceBase - Address of the gWinNt global\r |
716 | \r |
717 | Returns:\r |
718 | EFI_SUCCESS - Data returned\r |
719 | \r |
720 | --*/\r |
721 | {\r |
722 | return gWinNt;\r |
723 | }\r |
724 | \r |
725 | \r |
726 | EFI_STATUS\r |
727 | EFIAPI\r |
728 | SecWinNtPeiLoadFile (\r |
729 | IN VOID *Pe32Data,\r |
730 | IN EFI_PHYSICAL_ADDRESS *ImageAddress,\r |
731 | IN UINT64 *ImageSize,\r |
732 | IN EFI_PHYSICAL_ADDRESS *EntryPoint\r |
733 | )\r |
734 | /*++\r |
735 | \r |
736 | Routine Description:\r |
737 | Loads and relocates a PE/COFF image into memory.\r |
738 | \r |
739 | Arguments:\r |
740 | Pe32Data - The base address of the PE/COFF file that is to be loaded and relocated\r |
741 | ImageAddress - The base address of the relocated PE/COFF image\r |
742 | ImageSize - The size of the relocated PE/COFF image\r |
743 | EntryPoint - The entry point of the relocated PE/COFF image\r |
744 | \r |
745 | Returns:\r |
746 | EFI_SUCCESS - The file was loaded and relocated\r |
747 | EFI_OUT_OF_RESOURCES - There was not enough memory to load and relocate the PE/COFF file\r |
748 | \r |
749 | --*/\r |
750 | {\r |
751 | EFI_STATUS Status;\r |
752 | PE_COFF_LOADER_IMAGE_CONTEXT ImageContext;\r |
753 | \r |
754 | ZeroMem (&ImageContext, sizeof (ImageContext));\r |
755 | ImageContext.Handle = Pe32Data;\r |
756 | \r |
757 | ImageContext.ImageRead = (PE_COFF_LOADER_READ_FILE) SecImageRead;\r |
758 | \r |
759 | Status = gPeiEfiPeiPeCoffLoader->GetImageInfo (gPeiEfiPeiPeCoffLoader, &ImageContext);\r |
760 | if (EFI_ERROR (Status)) {\r |
761 | return Status;\r |
762 | }\r |
763 | //\r |
764 | // Allocate space in NT (not emulator) memory. Extra space is for alignment\r |
765 | //\r |
766 | ImageContext.ImageAddress = (EFI_PHYSICAL_ADDRESS) (UINTN) malloc ((UINTN) (ImageContext.ImageSize + (ImageContext.SectionAlignment * 2)));\r |
767 | if (ImageContext.ImageAddress == 0) {\r |
768 | return EFI_OUT_OF_RESOURCES;\r |
769 | }\r |
770 | //\r |
771 | // Align buffer on section boundry\r |
772 | //\r |
773 | ImageContext.ImageAddress += ImageContext.SectionAlignment;\r |
774 | ImageContext.ImageAddress &= ~(ImageContext.SectionAlignment - 1);\r |
775 | \r |
776 | Status = gPeiEfiPeiPeCoffLoader->LoadImage (gPeiEfiPeiPeCoffLoader, &ImageContext);\r |
777 | if (EFI_ERROR (Status)) {\r |
778 | return Status;\r |
779 | }\r |
780 | \r |
781 | Status = gPeiEfiPeiPeCoffLoader->RelocateImage (gPeiEfiPeiPeCoffLoader, &ImageContext);\r |
782 | if (EFI_ERROR (Status)) {\r |
783 | return Status;\r |
784 | }\r |
785 | \r |
786 | //\r |
787 | // BugBug: Flush Instruction Cache Here when CPU Lib is ready\r |
788 | //\r |
789 | \r |
790 | *ImageAddress = ImageContext.ImageAddress;\r |
791 | *ImageSize = ImageContext.ImageSize;\r |
792 | *EntryPoint = ImageContext.EntryPoint;\r |
793 | \r |
794 | return EFI_SUCCESS;\r |
795 | }\r |
796 | \r |
797 | EFI_STATUS\r |
798 | EFIAPI\r |
799 | SecWinNtFdAddress (\r |
800 | IN UINTN Index,\r |
801 | IN OUT EFI_PHYSICAL_ADDRESS *FdBase,\r |
802 | IN OUT UINT64 *FdSize\r |
803 | )\r |
804 | /*++\r |
805 | \r |
806 | Routine Description:\r |
807 | Return the FD Size and base address. Since the FD is loaded from a\r |
808 | file into Windows memory only the SEC will know it's address.\r |
809 | \r |
810 | Arguments:\r |
811 | Index - Which FD, starts at zero.\r |
812 | FdSize - Size of the FD in bytes\r |
813 | FdBase - Start address of the FD. Assume it points to an FV Header\r |
814 | \r |
815 | Returns:\r |
816 | EFI_SUCCESS - Return the Base address and size of the FV\r |
817 | EFI_UNSUPPORTED - Index does nto map to an FD in the system\r |
818 | \r |
819 | --*/\r |
820 | {\r |
821 | if (Index >= gFdInfoCount) {\r |
822 | return EFI_UNSUPPORTED;\r |
823 | }\r |
824 | \r |
825 | *FdBase = gFdInfo[Index].Address;\r |
826 | *FdSize = gFdInfo[Index].Size;\r |
827 | \r |
828 | if (*FdBase == 0 && *FdSize == 0) {\r |
829 | return EFI_UNSUPPORTED;\r |
830 | }\r |
831 | \r |
832 | return EFI_SUCCESS;\r |
833 | }\r |
834 | \r |
835 | EFI_STATUS\r |
836 | EFIAPI\r |
837 | SecImageRead (\r |
838 | IN VOID *FileHandle,\r |
839 | IN UINTN FileOffset,\r |
840 | IN OUT UINTN *ReadSize,\r |
841 | OUT VOID *Buffer\r |
842 | )\r |
843 | /*++\r |
844 | \r |
845 | Routine Description:\r |
846 | Support routine for the PE/COFF Loader that reads a buffer from a PE/COFF file\r |
847 | \r |
848 | Arguments:\r |
849 | FileHandle - The handle to the PE/COFF file\r |
850 | FileOffset - The offset, in bytes, into the file to read\r |
851 | ReadSize - The number of bytes to read from the file starting at FileOffset\r |
852 | Buffer - A pointer to the buffer to read the data into.\r |
853 | \r |
854 | Returns:\r |
855 | EFI_SUCCESS - ReadSize bytes of data were read into Buffer from the PE/COFF file starting at FileOffset\r |
856 | \r |
857 | --*/\r |
858 | {\r |
859 | CHAR8 *Destination8;\r |
860 | CHAR8 *Source8;\r |
861 | UINTN Length;\r |
862 | \r |
863 | Destination8 = Buffer;\r |
864 | Source8 = (CHAR8 *) ((UINTN) FileHandle + FileOffset);\r |
865 | Length = *ReadSize;\r |
866 | while (Length--) {\r |
867 | *(Destination8++) = *(Source8++);\r |
868 | }\r |
869 | \r |
870 | return EFI_SUCCESS;\r |
871 | }\r |
872 | \r |
873 | CHAR16 *\r |
874 | AsciiToUnicode (\r |
875 | IN CHAR8 *Ascii,\r |
876 | IN UINTN *StrLen OPTIONAL\r |
877 | )\r |
878 | /*++\r |
879 | \r |
880 | Routine Description:\r |
881 | Convert the passed in Ascii string to Unicode.\r |
882 | Optionally return the length of the strings.\r |
883 | \r |
884 | Arguments:\r |
885 | Ascii - Ascii string to convert\r |
886 | StrLen - Length of string\r |
887 | \r |
888 | Returns:\r |
889 | Pointer to malloc'ed Unicode version of Ascii\r |
890 | \r |
891 | --*/\r |
892 | {\r |
893 | UINTN Index;\r |
894 | CHAR16 *Unicode;\r |
895 | \r |
896 | //\r |
897 | // Allocate a buffer for unicode string\r |
898 | //\r |
899 | for (Index = 0; Ascii[Index] != '\0'; Index++)\r |
900 | ;\r |
901 | Unicode = malloc ((Index + 1) * sizeof (CHAR16));\r |
902 | if (Unicode == NULL) {\r |
903 | return NULL;\r |
904 | }\r |
905 | \r |
906 | for (Index = 0; Ascii[Index] != '\0'; Index++) {\r |
907 | Unicode[Index] = (CHAR16) Ascii[Index];\r |
908 | }\r |
909 | \r |
910 | Unicode[Index] = '\0';\r |
911 | \r |
912 | if (StrLen != NULL) {\r |
913 | *StrLen = Index;\r |
914 | }\r |
915 | \r |
916 | return Unicode;\r |
917 | }\r |
918 | \r |
919 | UINTN\r |
920 | CountSeperatorsInString (\r |
921 | IN const CHAR16 *String,\r |
922 | IN CHAR16 Seperator\r |
923 | )\r |
924 | /*++\r |
925 | \r |
926 | Routine Description:\r |
927 | Count the number of seperators in String\r |
928 | \r |
929 | Arguments:\r |
930 | String - String to process\r |
931 | Seperator - Item to count\r |
932 | \r |
933 | Returns:\r |
934 | Number of Seperator in String\r |
935 | \r |
936 | --*/\r |
937 | {\r |
938 | UINTN Count;\r |
939 | \r |
940 | for (Count = 0; *String != '\0'; String++) {\r |
941 | if (*String == Seperator) {\r |
942 | Count++;\r |
943 | }\r |
944 | }\r |
945 | \r |
946 | return Count;\r |
947 | }\r |
948 | \r |
949 | \r |
950 | EFI_STATUS\r |
951 | AddModHandle (\r |
952 | IN PE_COFF_LOADER_IMAGE_CONTEXT *ImageContext,\r |
953 | IN VOID *ModHandle\r |
954 | )\r |
955 | /*++\r |
956 | \r |
957 | Routine Description:\r |
958 | Store the ModHandle in an array indexed by the Pdb File name.\r |
959 | The ModHandle is needed to unload the image. \r |
960 | \r |
961 | Arguments:\r |
962 | ImageContext - Input data returned from PE Laoder Library. Used to find the \r |
963 | .PDB file name of the PE Image.\r |
964 | ModHandle - Returned from LoadLibraryEx() and stored for call to \r |
965 | FreeLibrary().\r |
966 | \r |
967 | Returns:\r |
968 | EFI_SUCCESS - ModHandle was stored. \r |
969 | \r |
970 | --*/\r |
971 | {\r |
972 | UINTN Index;\r |
973 | PDB_NAME_TO_MOD_HANDLE *Array;\r |
974 | UINTN PreviousSize;\r |
975 | \r |
976 | \r |
977 | Array = mPdbNameModHandleArray;\r |
978 | for (Index = 0; Index < mPdbNameModHandleArraySize; Index++, Array++) {\r |
979 | if (Array->PdbPointer == NULL) {\r |
980 | //\r |
981 | // Make a copy of the stirng and store the ModHandle\r |
982 | //\r |
983 | Array->PdbPointer = malloc (strlen (ImageContext->PdbPointer) + 1);\r |
984 | ASSERT (Array->PdbPointer != NULL);\r |
985 | \r |
986 | strcpy (Array->PdbPointer, ImageContext->PdbPointer);\r |
987 | Array->ModHandle = ModHandle;\r |
988 | return EFI_SUCCESS;\r |
989 | }\r |
990 | }\r |
991 | \r |
992 | //\r |
993 | // No free space in mPdbNameModHandleArray so grow it by \r |
994 | // MAX_PDB_NAME_TO_MOD_HANDLE_ARRAY_SIZE entires. realloc will\r |
995 | // copy the old values to the new locaiton. But it does\r |
996 | // not zero the new memory area.\r |
997 | //\r |
998 | PreviousSize = mPdbNameModHandleArraySize * sizeof (PDB_NAME_TO_MOD_HANDLE);\r |
999 | mPdbNameModHandleArraySize += MAX_PDB_NAME_TO_MOD_HANDLE_ARRAY_SIZE;\r |
1000 | \r |
1001 | mPdbNameModHandleArray = realloc (mPdbNameModHandleArray, mPdbNameModHandleArraySize * sizeof (PDB_NAME_TO_MOD_HANDLE));\r |
1002 | if (mPdbNameModHandleArray == NULL) {\r |
1003 | ASSERT (FALSE);\r |
1004 | return EFI_OUT_OF_RESOURCES;\r |
1005 | }\r |
1006 | \r |
1007 | memset (mPdbNameModHandleArray + PreviousSize, 0, MAX_PDB_NAME_TO_MOD_HANDLE_ARRAY_SIZE * sizeof (PDB_NAME_TO_MOD_HANDLE));\r |
1008 | \r |
1009 | return AddModHandle (ImageContext, ModHandle);\r |
1010 | }\r |
1011 | \r |
1012 | \r |
1013 | VOID *\r |
1014 | RemoveModeHandle (\r |
1015 | IN PE_COFF_LOADER_IMAGE_CONTEXT *ImageContext\r |
1016 | )\r |
1017 | /*++\r |
1018 | \r |
1019 | Routine Description:\r |
1020 | Return the ModHandle and delete the entry in the array.\r |
1021 | \r |
1022 | Arguments:\r |
1023 | ImageContext - Input data returned from PE Laoder Library. Used to find the \r |
1024 | .PDB file name of the PE Image.\r |
1025 | \r |
1026 | Returns:\r |
1027 | ModHandle - ModHandle assoicated with ImageContext is returned\r |
1028 | NULL - No ModHandle associated with ImageContext\r |
1029 | \r |
1030 | --*/\r |
1031 | {\r |
1032 | UINTN Index;\r |
1033 | PDB_NAME_TO_MOD_HANDLE *Array;\r |
1034 | \r |
1035 | if (ImageContext->PdbPointer == NULL) {\r |
1036 | //\r |
1037 | // If no PDB pointer there is no ModHandle so return NULL\r |
1038 | //\r |
1039 | return NULL;\r |
1040 | }\r |
1041 | \r |
1042 | Array = mPdbNameModHandleArray;\r |
1043 | for (Index = 0; Index < mPdbNameModHandleArraySize; Index++, Array++) {\r |
1044 | if ((Array->PdbPointer != NULL) && (strcmp(Array->PdbPointer, ImageContext->PdbPointer) == 0)) {\r |
1045 | //\r |
1046 | // If you find a match return it and delete the entry\r |
1047 | //\r |
1048 | free (Array->PdbPointer);\r |
1049 | Array->PdbPointer = NULL;\r |
1050 | return Array->ModHandle;\r |
1051 | }\r |
1052 | }\r |
1053 | \r |
1054 | return NULL;\r |
1055 | }\r |
1056 | \r |
1057 | \r |
1058 | \r |
1059 | EFI_STATUS\r |
1060 | EFIAPI\r |
1061 | SecNt32PeCoffGetImageInfo (\r |
1062 | IN EFI_PEI_PE_COFF_LOADER_PROTOCOL *This,\r |
1063 | IN OUT PE_COFF_LOADER_IMAGE_CONTEXT *ImageContext\r |
1064 | )\r |
1065 | {\r |
1066 | EFI_STATUS Status;\r |
1067 | \r |
1068 | Status = PeCoffLoaderGetImageInfo (ImageContext);\r |
1069 | if (EFI_ERROR (Status)) {\r |
1070 | return Status;\r |
1071 | }\r |
1072 | \r |
1073 | switch (ImageContext->ImageType) {\r |
1074 | \r |
1075 | case EFI_IMAGE_SUBSYSTEM_EFI_APPLICATION:\r |
1076 | ImageContext->ImageCodeMemoryType = EfiLoaderCode;\r |
1077 | ImageContext->ImageDataMemoryType = EfiLoaderData;\r |
1078 | break;\r |
1079 | \r |
1080 | case EFI_IMAGE_SUBSYSTEM_EFI_BOOT_SERVICE_DRIVER:\r |
1081 | ImageContext->ImageCodeMemoryType = EfiBootServicesCode;\r |
1082 | ImageContext->ImageDataMemoryType = EfiBootServicesData;\r |
1083 | break;\r |
1084 | \r |
1085 | case EFI_IMAGE_SUBSYSTEM_EFI_RUNTIME_DRIVER:\r |
1086 | case EFI_IMAGE_SUBSYSTEM_SAL_RUNTIME_DRIVER:\r |
1087 | ImageContext->ImageCodeMemoryType = EfiRuntimeServicesCode;\r |
1088 | ImageContext->ImageDataMemoryType = EfiRuntimeServicesData;\r |
1089 | break;\r |
1090 | \r |
1091 | default:\r |
1092 | ImageContext->ImageError = IMAGE_ERROR_INVALID_SUBSYSTEM;\r |
1093 | return RETURN_UNSUPPORTED;\r |
1094 | }\r |
1095 | \r |
1096 | return Status;\r |
1097 | }\r |
1098 | \r |
1099 | EFI_STATUS\r |
1100 | EFIAPI\r |
1101 | SecNt32PeCoffLoadImage (\r |
1102 | IN EFI_PEI_PE_COFF_LOADER_PROTOCOL *This,\r |
1103 | IN OUT PE_COFF_LOADER_IMAGE_CONTEXT *ImageContext\r |
1104 | )\r |
1105 | {\r |
1106 | EFI_STATUS Status;\r |
1107 | \r |
1108 | Status = PeCoffLoaderLoadImage (ImageContext);\r |
1109 | return Status;\r |
1110 | }\r |
1111 | \r |
1112 | EFI_STATUS\r |
1113 | EFIAPI\r |
1114 | SecNt32PeCoffRelocateImage (\r |
1115 | IN EFI_PEI_PE_COFF_LOADER_PROTOCOL *This,\r |
1116 | IN OUT PE_COFF_LOADER_IMAGE_CONTEXT *ImageContext\r |
1117 | )\r |
1118 | {\r |
1119 | EFI_STATUS Status;\r |
1120 | VOID *DllEntryPoint;\r |
1121 | CHAR16 *DllFileName;\r |
1122 | HMODULE Library;\r |
1123 | UINTN Index;\r |
1124 | \r |
1125 | \r |
1126 | Status = PeCoffLoaderRelocateImage (ImageContext);\r |
1127 | if (EFI_ERROR (Status)) {\r |
1128 | //\r |
1129 | // We could not relocated the image in memory properly\r |
1130 | //\r |
1131 | return Status;\r |
1132 | }\r |
1133 | \r |
1134 | //\r |
1135 | // If we load our own PE COFF images the Windows debugger can not source\r |
1136 | // level debug our code. If a valid PDB pointer exists usw it to load\r |
1137 | // the *.dll file as a library using Windows* APIs. This allows \r |
1138 | // source level debug. The image is still loaded and reloaced\r |
1139 | // in the Framework memory space like on a real system (by the code above),\r |
1140 | // but the entry point points into the DLL loaded by the code bellow. \r |
1141 | //\r |
1142 | \r |
1143 | DllEntryPoint = NULL;\r |
1144 | \r |
1145 | //\r |
1146 | // Load the DLL if it's not an EBC image.\r |
1147 | //\r |
1148 | if ((ImageContext->PdbPointer != NULL) &&\r |
1149 | (ImageContext->Machine != EFI_IMAGE_MACHINE_EBC)) {\r |
1150 | //\r |
1151 | // Convert filename from ASCII to Unicode\r |
1152 | //\r |
1153 | DllFileName = AsciiToUnicode (ImageContext->PdbPointer, &Index);\r |
1154 | \r |
1155 | //\r |
1156 | // Check that we have a valid filename\r |
1157 | //\r |
1158 | if (Index < 5 || DllFileName[Index - 4] != '.') {\r |
1159 | free (DllFileName);\r |
1160 | \r |
1161 | //\r |
1162 | // Never return an error if PeCoffLoaderRelocateImage() succeeded.\r |
1163 | // The image will run, but we just can't source level debug. If we\r |
1164 | // return an error the image will not run.\r |
1165 | //\r |
1166 | return EFI_SUCCESS;\r |
1167 | }\r |
1168 | //\r |
1169 | // Replace .PDB with .DLL on the filename\r |
1170 | //\r |
1171 | DllFileName[Index - 3] = 'D';\r |
1172 | DllFileName[Index - 2] = 'L';\r |
1173 | DllFileName[Index - 1] = 'L';\r |
1174 | \r |
1175 | //\r |
1176 | // Load the .DLL file into the user process's address space for source \r |
1177 | // level debug\r |
1178 | //\r |
1179 | Library = LoadLibraryEx (DllFileName, NULL, DONT_RESOLVE_DLL_REFERENCES);\r |
1180 | if (Library != NULL) {\r |
1181 | //\r |
1182 | // InitializeDriver is the entry point we put in all our EFI DLL's. The\r |
1183 | // DONT_RESOLVE_DLL_REFERENCES argument to LoadLIbraryEx() supresses the \r |
1184 | // normal DLL entry point of DllMain, and prevents other modules that are\r |
1185 | // referenced in side the DllFileName from being loaded. There is no error \r |
1186 | // checking as the we can point to the PE32 image loaded by Tiano. This \r |
1187 | // step is only needed for source level debuging\r |
1188 | //\r |
1189 | DllEntryPoint = (VOID *) (UINTN) GetProcAddress (Library, "InitializeDriver");\r |
1190 | \r |
1191 | }\r |
1192 | \r |
1193 | if ((Library != NULL) && (DllEntryPoint != NULL)) {\r |
1194 | AddModHandle (ImageContext, Library);\r |
1195 | ImageContext->EntryPoint = (EFI_PHYSICAL_ADDRESS) (UINTN) DllEntryPoint;\r |
1196 | wprintf (L"LoadLibraryEx (%s,\n NULL, DONT_RESOLVE_DLL_REFERENCES)\n", DllFileName);\r |
1197 | } else {\r |
1198 | wprintf (L"WARNING: No source level debug %s. \n", DllFileName);\r |
1199 | }\r |
1200 | \r |
1201 | free (DllFileName);\r |
1202 | }\r |
1203 | \r |
1204 | //\r |
1205 | // Never return an error if PeCoffLoaderRelocateImage() succeeded.\r |
1206 | // The image will run, but we just can't source level debug. If we\r |
1207 | // return an error the image will not run.\r |
1208 | //\r |
1209 | return EFI_SUCCESS;\r |
1210 | }\r |
1211 | \r |
1212 | \r |
1213 | EFI_STATUS\r |
1214 | EFIAPI\r |
1215 | SecNt32PeCoffUnloadimage (\r |
1216 | IN EFI_PEI_PE_COFF_LOADER_PROTOCOL *This,\r |
1217 | IN PE_COFF_LOADER_IMAGE_CONTEXT *ImageContext\r |
1218 | )\r |
1219 | {\r |
1220 | VOID *ModHandle;\r |
1221 | \r |
1222 | ModHandle = RemoveModeHandle (ImageContext);\r |
1223 | if (ModHandle != NULL) {\r |
1224 | FreeLibrary (ModHandle);\r |
1225 | }\r |
1226 | return EFI_SUCCESS;\r |
1227 | }\r |
1228 | \r |
1229 | VOID\r |
1230 | _ModuleEntryPoint (\r |
1231 | VOID\r |
1232 | )\r |
1233 | {\r |
1234 | }\r |
f55a0ac9 |
1235 | \r |
1236 | #pragma warning(default : 4996)\r |