1 /** @file 2 This file contains the internal functions required to generate a Firmware Volume. 3 4 Copyright (c) 2004 - 2014, Intel Corporation. All rights reserved.<BR> 5 Portions Copyright (c) 2011 - 2013, ARM Ltd. All rights reserved.<BR> 6 This program and the accompanying materials 7 are licensed and made available under the terms and conditions of the BSD License 8 which accompanies this distribution. The full text of the license may be found at 9 http://opensource.org/licenses/bsd-license.php 10 11 THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS, 12 WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED. 13 14 **/ 15 16 // 17 // Include files 18 // 19 20 #if defined(__FreeBSD__) 21 #include <uuid.h> 22 #elif defined(__GNUC__) 23 #include <uuid/uuid.h> 24 #endif 25 #ifdef __GNUC__ 26 #include <sys/stat.h> 27 #endif 28 #include <string.h> 29 #ifndef __GNUC__ 30 #include <io.h> 31 #endif 32 #include <assert.h> 33 34 #include <Guid/FfsSectionAlignmentPadding.h> 35 36 #include "GenFvInternalLib.h" 37 #include "FvLib.h" 38 #include "PeCoffLib.h" 39 #include "WinNtInclude.h" 40 41 BOOLEAN mArm = FALSE; 42 STATIC UINT32 MaxFfsAlignment = 0; 43 44 EFI_GUID mEfiFirmwareVolumeTopFileGuid = EFI_FFS_VOLUME_TOP_FILE_GUID; 45 EFI_GUID mFileGuidArray [MAX_NUMBER_OF_FILES_IN_FV]; 46 EFI_GUID mZeroGuid = {0x0, 0x0, 0x0, {0x0, 0x0, 0x0, 0x0, 0x0, 0x0, 0x0, 0x0}}; 47 EFI_GUID mDefaultCapsuleGuid = {0x3B6686BD, 0x0D76, 0x4030, { 0xB7, 0x0E, 0xB5, 0x51, 0x9E, 0x2F, 0xC5, 0xA0 }}; 48 EFI_GUID mEfiFfsSectionAlignmentPaddingGuid = EFI_FFS_SECTION_ALIGNMENT_PADDING_GUID; 49 50 CHAR8 *mFvbAttributeName[] = { 51 EFI_FVB2_READ_DISABLED_CAP_STRING, 52 EFI_FVB2_READ_ENABLED_CAP_STRING, 53 EFI_FVB2_READ_STATUS_STRING, 54 EFI_FVB2_WRITE_DISABLED_CAP_STRING, 55 EFI_FVB2_WRITE_ENABLED_CAP_STRING, 56 EFI_FVB2_WRITE_STATUS_STRING, 57 EFI_FVB2_LOCK_CAP_STRING, 58 EFI_FVB2_LOCK_STATUS_STRING, 59 NULL, 60 EFI_FVB2_STICKY_WRITE_STRING, 61 EFI_FVB2_MEMORY_MAPPED_STRING, 62 EFI_FVB2_ERASE_POLARITY_STRING, 63 EFI_FVB2_READ_LOCK_CAP_STRING, 64 EFI_FVB2_READ_LOCK_STATUS_STRING, 65 EFI_FVB2_WRITE_LOCK_CAP_STRING, 66 EFI_FVB2_WRITE_LOCK_STATUS_STRING 67 }; 68 69 CHAR8 *mFvbAlignmentName[] = { 70 EFI_FVB2_ALIGNMENT_1_STRING, 71 EFI_FVB2_ALIGNMENT_2_STRING, 72 EFI_FVB2_ALIGNMENT_4_STRING, 73 EFI_FVB2_ALIGNMENT_8_STRING, 74 EFI_FVB2_ALIGNMENT_16_STRING, 75 EFI_FVB2_ALIGNMENT_32_STRING, 76 EFI_FVB2_ALIGNMENT_64_STRING, 77 EFI_FVB2_ALIGNMENT_128_STRING, 78 EFI_FVB2_ALIGNMENT_256_STRING, 79 EFI_FVB2_ALIGNMENT_512_STRING, 80 EFI_FVB2_ALIGNMENT_1K_STRING, 81 EFI_FVB2_ALIGNMENT_2K_STRING, 82 EFI_FVB2_ALIGNMENT_4K_STRING, 83 EFI_FVB2_ALIGNMENT_8K_STRING, 84 EFI_FVB2_ALIGNMENT_16K_STRING, 85 EFI_FVB2_ALIGNMENT_32K_STRING, 86 EFI_FVB2_ALIGNMENT_64K_STRING, 87 EFI_FVB2_ALIGNMENT_128K_STRING, 88 EFI_FVB2_ALIGNMENT_256K_STRING, 89 EFI_FVB2_ALIGNMENT_512K_STRING, 90 EFI_FVB2_ALIGNMENT_1M_STRING, 91 EFI_FVB2_ALIGNMENT_2M_STRING, 92 EFI_FVB2_ALIGNMENT_4M_STRING, 93 EFI_FVB2_ALIGNMENT_8M_STRING, 94 EFI_FVB2_ALIGNMENT_16M_STRING, 95 EFI_FVB2_ALIGNMENT_32M_STRING, 96 EFI_FVB2_ALIGNMENT_64M_STRING, 97 EFI_FVB2_ALIGNMENT_128M_STRING, 98 EFI_FVB2_ALIGNMENT_256M_STRING, 99 EFI_FVB2_ALIGNMENT_512M_STRING, 100 EFI_FVB2_ALIGNMENT_1G_STRING, 101 EFI_FVB2_ALIGNMENT_2G_STRING 102 }; 103 104 // 105 // This data array will be located at the base of the Firmware Volume Header (FVH) 106 // in the boot block. It must not exceed 14 bytes of code. The last 2 bytes 107 // will be used to keep the FVH checksum consistent. 108 // This code will be run in response to a starutp IPI for HT-enabled systems. 109 // 110 #define SIZEOF_STARTUP_DATA_ARRAY 0x10 111 112 UINT8 m128kRecoveryStartupApDataArray[SIZEOF_STARTUP_DATA_ARRAY] = { 113 // 114 // EA D0 FF 00 F0 ; far jmp F000:FFD0 115 // 0, 0, 0, 0, 0, 0, 0, 0, 0, ; Reserved bytes 116 // 0, 0 ; Checksum Padding 117 // 118 0xEA, 119 0xD0, 120 0xFF, 121 0x0, 122 0xF0, 123 0x00, 124 0x00, 125 0x00, 126 0x00, 127 0x00, 128 0x00, 129 0x00, 130 0x00, 131 0x00, 132 0x00, 133 0x00 134 }; 135 136 UINT8 m64kRecoveryStartupApDataArray[SIZEOF_STARTUP_DATA_ARRAY] = { 137 // 138 // EB CE ; jmp short ($-0x30) 139 // ; (from offset 0x0 to offset 0xFFD0) 140 // 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, ; Reserved bytes 141 // 0, 0 ; Checksum Padding 142 // 143 0xEB, 144 0xCE, 145 0x00, 146 0x00, 147 0x00, 148 0x00, 149 0x00, 150 0x00, 151 0x00, 152 0x00, 153 0x00, 154 0x00, 155 0x00, 156 0x00, 157 0x00, 158 0x00 159 }; 160 161 FV_INFO mFvDataInfo; 162 CAP_INFO mCapDataInfo; 163 BOOLEAN mIsLargeFfs = FALSE; 164 165 EFI_PHYSICAL_ADDRESS mFvBaseAddress[0x10]; 166 UINT32 mFvBaseAddressNumber = 0; 167 168 EFI_STATUS 169 ParseFvInf ( 170 IN MEMORY_FILE *InfFile, 171 OUT FV_INFO *FvInfo 172 ) 173 /*++ 174 175 Routine Description: 176 177 This function parses a FV.INF file and copies info into a FV_INFO structure. 178 179 Arguments: 180 181 InfFile Memory file image. 182 FvInfo Information read from INF file. 183 184 Returns: 185 186 EFI_SUCCESS INF file information successfully retrieved. 187 EFI_ABORTED INF file has an invalid format. 188 EFI_NOT_FOUND A required string was not found in the INF file. 189 --*/ 190 { 191 CHAR8 Value[MAX_LONG_FILE_PATH]; 192 UINT64 Value64; 193 UINTN Index; 194 UINTN Number; 195 EFI_STATUS Status; 196 EFI_GUID GuidValue; 197 198 // 199 // Read the FV base address 200 // 201 if (!mFvDataInfo.BaseAddressSet) { 202 Status = FindToken (InfFile, OPTIONS_SECTION_STRING, EFI_FV_BASE_ADDRESS_STRING, 0, Value); 203 if (Status == EFI_SUCCESS) { 204 // 205 // Get the base address 206 // 207 Status = AsciiStringToUint64 (Value, FALSE, &Value64); 208 if (EFI_ERROR (Status)) { 209 Error (NULL, 0, 2000, "Invalid parameter", "%s = %s", EFI_FV_BASE_ADDRESS_STRING, Value); 210 return EFI_ABORTED; 211 } 212 DebugMsg (NULL, 0, 9, "rebase address", "%s = %s", EFI_FV_BASE_ADDRESS_STRING, Value); 213 214 FvInfo->BaseAddress = Value64; 215 FvInfo->BaseAddressSet = TRUE; 216 } 217 } 218 219 // 220 // Read the FV File System Guid 221 // 222 if (!FvInfo->FvFileSystemGuidSet) { 223 Status = FindToken (InfFile, OPTIONS_SECTION_STRING, EFI_FV_FILESYSTEMGUID_STRING, 0, Value); 224 if (Status == EFI_SUCCESS) { 225 // 226 // Get the guid value 227 // 228 Status = StringToGuid (Value, &GuidValue); 229 if (EFI_ERROR (Status)) { 230 Error (NULL, 0, 2000, "Invalid parameter", "%s = %s", EFI_FV_FILESYSTEMGUID_STRING, Value); 231 return EFI_ABORTED; 232 } 233 memcpy (&FvInfo->FvFileSystemGuid, &GuidValue, sizeof (EFI_GUID)); 234 FvInfo->FvFileSystemGuidSet = TRUE; 235 } 236 } 237 238 // 239 // Read the FV Extension Header File Name 240 // 241 Status = FindToken (InfFile, ATTRIBUTES_SECTION_STRING, EFI_FV_EXT_HEADER_FILE_NAME, 0, Value); 242 if (Status == EFI_SUCCESS) { 243 strcpy (FvInfo->FvExtHeaderFile, Value); 244 } 245 246 // 247 // Read the FV file name 248 // 249 Status = FindToken (InfFile, OPTIONS_SECTION_STRING, EFI_FV_FILE_NAME_STRING, 0, Value); 250 if (Status == EFI_SUCCESS) { 251 // 252 // copy the file name 253 // 254 strcpy (FvInfo->FvName, Value); 255 } 256 257 // 258 // Read Fv Attribute 259 // 260 for (Index = 0; Index < sizeof (mFvbAttributeName)/sizeof (CHAR8 *); Index ++) { 261 if ((mFvbAttributeName [Index] != NULL) && \ 262 (FindToken (InfFile, ATTRIBUTES_SECTION_STRING, mFvbAttributeName [Index], 0, Value) == EFI_SUCCESS)) { 263 if ((strcmp (Value, TRUE_STRING) == 0) || (strcmp (Value, ONE_STRING) == 0)) { 264 FvInfo->FvAttributes |= 1 << Index; 265 } else if ((strcmp (Value, FALSE_STRING) != 0) && (strcmp (Value, ZERO_STRING) != 0)) { 266 Error (NULL, 0, 2000, "Invalid parameter", "%s expected %s | %s", mFvbAttributeName [Index], TRUE_STRING, FALSE_STRING); 267 return EFI_ABORTED; 268 } 269 } 270 } 271 272 // 273 // Read Fv Alignment 274 // 275 for (Index = 0; Index < sizeof (mFvbAlignmentName)/sizeof (CHAR8 *); Index ++) { 276 if (FindToken (InfFile, ATTRIBUTES_SECTION_STRING, mFvbAlignmentName [Index], 0, Value) == EFI_SUCCESS) { 277 if (strcmp (Value, TRUE_STRING) == 0) { 278 FvInfo->FvAttributes |= Index << 16; 279 DebugMsg (NULL, 0, 9, "FV file alignment", "Align = %s", mFvbAlignmentName [Index]); 280 break; 281 } 282 } 283 } 284 285 // 286 // Read weak alignment flag 287 // 288 Status = FindToken (InfFile, ATTRIBUTES_SECTION_STRING, EFI_FV_WEAK_ALIGNMENT_STRING, 0, Value); 289 if (Status == EFI_SUCCESS) { 290 if ((strcmp (Value, TRUE_STRING) == 0) || (strcmp (Value, ONE_STRING) == 0)) { 291 FvInfo->FvAttributes |= EFI_FVB2_WEAK_ALIGNMENT; 292 } else if ((strcmp (Value, FALSE_STRING) != 0) && (strcmp (Value, ZERO_STRING) != 0)) { 293 Error (NULL, 0, 2000, "Invalid parameter", "Weak alignment value expected one of TRUE, FALSE, 1 or 0."); 294 return EFI_ABORTED; 295 } 296 } 297 298 // 299 // Read block maps 300 // 301 for (Index = 0; Index < MAX_NUMBER_OF_FV_BLOCKS; Index++) { 302 if (FvInfo->FvBlocks[Index].Length == 0) { 303 // 304 // Read block size 305 // 306 Status = FindToken (InfFile, OPTIONS_SECTION_STRING, EFI_BLOCK_SIZE_STRING, Index, Value); 307 308 if (Status == EFI_SUCCESS) { 309 // 310 // Update the size of block 311 // 312 Status = AsciiStringToUint64 (Value, FALSE, &Value64); 313 if (EFI_ERROR (Status)) { 314 Error (NULL, 0, 2000, "Invalid parameter", "%s = %s", EFI_BLOCK_SIZE_STRING, Value); 315 return EFI_ABORTED; 316 } 317 318 FvInfo->FvBlocks[Index].Length = (UINT32) Value64; 319 DebugMsg (NULL, 0, 9, "FV Block Size", "%s = %s", EFI_BLOCK_SIZE_STRING, Value); 320 } else { 321 // 322 // If there is no blocks size, but there is the number of block, then we have a mismatched pair 323 // and should return an error. 324 // 325 Status = FindToken (InfFile, OPTIONS_SECTION_STRING, EFI_NUM_BLOCKS_STRING, Index, Value); 326 if (!EFI_ERROR (Status)) { 327 Error (NULL, 0, 2000, "Invalid parameter", "both %s and %s must be specified.", EFI_NUM_BLOCKS_STRING, EFI_BLOCK_SIZE_STRING); 328 return EFI_ABORTED; 329 } else { 330 // 331 // We are done 332 // 333 break; 334 } 335 } 336 337 // 338 // Read blocks number 339 // 340 Status = FindToken (InfFile, OPTIONS_SECTION_STRING, EFI_NUM_BLOCKS_STRING, Index, Value); 341 342 if (Status == EFI_SUCCESS) { 343 // 344 // Update the number of blocks 345 // 346 Status = AsciiStringToUint64 (Value, FALSE, &Value64); 347 if (EFI_ERROR (Status)) { 348 Error (NULL, 0, 2000, "Invalid parameter", "%s = %s", EFI_NUM_BLOCKS_STRING, Value); 349 return EFI_ABORTED; 350 } 351 352 FvInfo->FvBlocks[Index].NumBlocks = (UINT32) Value64; 353 DebugMsg (NULL, 0, 9, "FV Block Number", "%s = %s", EFI_NUM_BLOCKS_STRING, Value); 354 } 355 } 356 } 357 358 if (Index == 0) { 359 Error (NULL, 0, 2001, "Missing required argument", "block size."); 360 return EFI_ABORTED; 361 } 362 363 // 364 // Read files 365 // 366 Number = 0; 367 for (Number = 0; Number < MAX_NUMBER_OF_FILES_IN_FV; Number ++) { 368 if (FvInfo->FvFiles[Number][0] == '\0') { 369 break; 370 } 371 } 372 373 for (Index = 0; Index < MAX_NUMBER_OF_FILES_IN_FV; Index++) { 374 // 375 // Read the FFS file list 376 // 377 Status = FindToken (InfFile, FILES_SECTION_STRING, EFI_FILE_NAME_STRING, Index, Value); 378 379 if (Status == EFI_SUCCESS) { 380 // 381 // Add the file 382 // 383 strcpy (FvInfo->FvFiles[Number + Index], Value); 384 DebugMsg (NULL, 0, 9, "FV component file", "the %uth name is %s", (unsigned) Index, Value); 385 } else { 386 break; 387 } 388 } 389 390 if ((Index + Number) == 0) { 391 Warning (NULL, 0, 0, "FV components are not specified.", NULL); 392 } 393 394 return EFI_SUCCESS; 395 } 396 397 VOID 398 UpdateFfsFileState ( 399 IN EFI_FFS_FILE_HEADER *FfsFile, 400 IN EFI_FIRMWARE_VOLUME_HEADER *FvHeader 401 ) 402 /*++ 403 404 Routine Description: 405 406 This function changes the FFS file attributes based on the erase polarity 407 of the FV. Update the reserved bits of State to EFI_FVB2_ERASE_POLARITY. 408 409 Arguments: 410 411 FfsFile File header. 412 FvHeader FV header. 413 414 Returns: 415 416 None 417 418 --*/ 419 { 420 if (FvHeader->Attributes & EFI_FVB2_ERASE_POLARITY) { 421 FfsFile->State = (UINT8)~(FfsFile->State); 422 // FfsFile->State |= ~(UINT8) EFI_FILE_ALL_STATE_BITS; 423 } 424 } 425 426 EFI_STATUS 427 ReadFfsAlignment ( 428 IN EFI_FFS_FILE_HEADER *FfsFile, 429 IN OUT UINT32 *Alignment 430 ) 431 /*++ 432 433 Routine Description: 434 435 This function determines the alignment of the FFS input file from the file 436 attributes. 437 438 Arguments: 439 440 FfsFile FFS file to parse 441 Alignment The minimum required alignment offset of the FFS file 442 443 Returns: 444 445 EFI_SUCCESS The function completed successfully. 446 EFI_INVALID_PARAMETER One of the input parameters was invalid. 447 EFI_ABORTED An error occurred. 448 449 --*/ 450 { 451 // 452 // Verify input parameters. 453 // 454 if (FfsFile == NULL || Alignment == NULL) { 455 return EFI_INVALID_PARAMETER; 456 } 457 458 switch ((FfsFile->Attributes >> 3) & 0x07) { 459 460 case 0: 461 // 462 // 1 byte alignment 463 // 464 *Alignment = 0; 465 break; 466 467 case 1: 468 // 469 // 16 byte alignment 470 // 471 *Alignment = 4; 472 break; 473 474 case 2: 475 // 476 // 128 byte alignment 477 // 478 *Alignment = 7; 479 break; 480 481 case 3: 482 // 483 // 512 byte alignment 484 // 485 *Alignment = 9; 486 break; 487 488 case 4: 489 // 490 // 1K byte alignment 491 // 492 *Alignment = 10; 493 break; 494 495 case 5: 496 // 497 // 4K byte alignment 498 // 499 *Alignment = 12; 500 break; 501 502 case 6: 503 // 504 // 32K byte alignment 505 // 506 *Alignment = 15; 507 break; 508 509 case 7: 510 // 511 // 64K byte alignment 512 // 513 *Alignment = 16; 514 break; 515 516 default: 517 break; 518 } 519 520 return EFI_SUCCESS; 521 } 522 523 EFI_STATUS 524 AddPadFile ( 525 IN OUT MEMORY_FILE *FvImage, 526 IN UINT32 DataAlignment, 527 IN VOID *FvEnd, 528 IN EFI_FIRMWARE_VOLUME_EXT_HEADER *ExtHeader, 529 IN UINT32 NextFfsSize 530 ) 531 /*++ 532 533 Routine Description: 534 535 This function adds a pad file to the FV image if it required to align the 536 data of the next file. 537 538 Arguments: 539 540 FvImage The memory image of the FV to add it to. 541 The current offset must be valid. 542 DataAlignment The data alignment of the next FFS file. 543 FvEnd End of the empty data in FvImage. 544 ExtHeader PI FvExtHeader Optional 545 546 Returns: 547 548 EFI_SUCCESS The function completed successfully. 549 EFI_INVALID_PARAMETER One of the input parameters was invalid. 550 EFI_OUT_OF_RESOURCES Insufficient resources exist in the FV to complete 551 the pad file add. 552 553 --*/ 554 { 555 EFI_FFS_FILE_HEADER *PadFile; 556 UINTN PadFileSize; 557 UINT32 NextFfsHeaderSize; 558 UINT32 CurFfsHeaderSize; 559 560 CurFfsHeaderSize = sizeof (EFI_FFS_FILE_HEADER); 561 // 562 // Verify input parameters. 563 // 564 if (FvImage == NULL) { 565 return EFI_INVALID_PARAMETER; 566 } 567 568 // 569 // Calculate the pad file size 570 // 571 572 // 573 // Append extension header size 574 // 575 if (ExtHeader != NULL) { 576 PadFileSize = ExtHeader->ExtHeaderSize; 577 if (PadFileSize + sizeof (EFI_FFS_FILE_HEADER) >= MAX_FFS_SIZE) { 578 CurFfsHeaderSize = sizeof (EFI_FFS_FILE_HEADER2); 579 } 580 PadFileSize += CurFfsHeaderSize; 581 } else { 582 NextFfsHeaderSize = sizeof (EFI_FFS_FILE_HEADER); 583 if (NextFfsSize >= MAX_FFS_SIZE) { 584 NextFfsHeaderSize = sizeof (EFI_FFS_FILE_HEADER2); 585 } 586 // 587 // Check if a pad file is necessary 588 // 589 if (((UINTN) FvImage->CurrentFilePointer - (UINTN) FvImage->FileImage + NextFfsHeaderSize) % DataAlignment == 0) { 590 return EFI_SUCCESS; 591 } 592 PadFileSize = (UINTN) FvImage->CurrentFilePointer - (UINTN) FvImage->FileImage + sizeof (EFI_FFS_FILE_HEADER) + NextFfsHeaderSize; 593 // 594 // Add whatever it takes to get to the next aligned address 595 // 596 while ((PadFileSize % DataAlignment) != 0) { 597 PadFileSize++; 598 } 599 // 600 // Subtract the next file header size 601 // 602 PadFileSize -= NextFfsHeaderSize; 603 // 604 // Subtract the starting offset to get size 605 // 606 PadFileSize -= (UINTN) FvImage->CurrentFilePointer - (UINTN) FvImage->FileImage; 607 } 608 609 // 610 // Verify that we have enough space for the file header 611 // 612 if (((UINTN) FvImage->CurrentFilePointer + PadFileSize) > (UINTN) FvEnd) { 613 return EFI_OUT_OF_RESOURCES; 614 } 615 616 // 617 // Write pad file header 618 // 619 PadFile = (EFI_FFS_FILE_HEADER *) FvImage->CurrentFilePointer; 620 621 // 622 // Write PadFile FFS header with PadType, don't need to set PAD file guid in its header. 623 // 624 PadFile->Type = EFI_FV_FILETYPE_FFS_PAD; 625 PadFile->Attributes = 0; 626 627 // 628 // Write pad file size (calculated size minus next file header size) 629 // 630 if (PadFileSize >= MAX_FFS_SIZE) { 631 memset(PadFile->Size, 0, sizeof(UINT8) * 3); 632 ((EFI_FFS_FILE_HEADER2 *)PadFile)->ExtendedSize = PadFileSize; 633 PadFile->Attributes |= FFS_ATTRIB_LARGE_FILE; 634 } else { 635 PadFile->Size[0] = (UINT8) (PadFileSize & 0xFF); 636 PadFile->Size[1] = (UINT8) ((PadFileSize >> 8) & 0xFF); 637 PadFile->Size[2] = (UINT8) ((PadFileSize >> 16) & 0xFF); 638 } 639 640 // 641 // Fill in checksums and state, they must be 0 for checksumming. 642 // 643 PadFile->IntegrityCheck.Checksum.Header = 0; 644 PadFile->IntegrityCheck.Checksum.File = 0; 645 PadFile->State = 0; 646 PadFile->IntegrityCheck.Checksum.Header = CalculateChecksum8 ((UINT8 *) PadFile, CurFfsHeaderSize); 647 PadFile->IntegrityCheck.Checksum.File = FFS_FIXED_CHECKSUM; 648 649 PadFile->State = EFI_FILE_HEADER_CONSTRUCTION | EFI_FILE_HEADER_VALID | EFI_FILE_DATA_VALID; 650 UpdateFfsFileState ( 651 (EFI_FFS_FILE_HEADER *) PadFile, 652 (EFI_FIRMWARE_VOLUME_HEADER *) FvImage->FileImage 653 ); 654 655 // 656 // Update the current FV pointer 657 // 658 FvImage->CurrentFilePointer += PadFileSize; 659 660 if (ExtHeader != NULL) { 661 // 662 // Copy Fv Extension Header and Set Fv Extension header offset 663 // 664 memcpy ((UINT8 *)PadFile + CurFfsHeaderSize, ExtHeader, ExtHeader->ExtHeaderSize); 665 ((EFI_FIRMWARE_VOLUME_HEADER *) FvImage->FileImage)->ExtHeaderOffset = (UINT16) ((UINTN) ((UINT8 *)PadFile + CurFfsHeaderSize) - (UINTN) FvImage->FileImage); 666 // 667 // Make next file start at QWord Boundry 668 // 669 while (((UINTN) FvImage->CurrentFilePointer & (EFI_FFS_FILE_HEADER_ALIGNMENT - 1)) != 0) { 670 FvImage->CurrentFilePointer++; 671 } 672 } 673 674 return EFI_SUCCESS; 675 } 676 677 BOOLEAN 678 IsVtfFile ( 679 IN EFI_FFS_FILE_HEADER *FileBuffer 680 ) 681 /*++ 682 683 Routine Description: 684 685 This function checks the header to validate if it is a VTF file 686 687 Arguments: 688 689 FileBuffer Buffer in which content of a file has been read. 690 691 Returns: 692 693 TRUE If this is a VTF file 694 FALSE If this is not a VTF file 695 696 --*/ 697 { 698 if (!memcmp (&FileBuffer->Name, &mEfiFirmwareVolumeTopFileGuid, sizeof (EFI_GUID))) { 699 return TRUE; 700 } else { 701 return FALSE; 702 } 703 } 704 705 EFI_STATUS 706 WriteMapFile ( 707 IN OUT FILE *FvMapFile, 708 IN CHAR8 *FileName, 709 IN EFI_FFS_FILE_HEADER *FfsFile, 710 IN EFI_PHYSICAL_ADDRESS ImageBaseAddress, 711 IN PE_COFF_LOADER_IMAGE_CONTEXT *pImageContext 712 ) 713 /*++ 714 715 Routine Description: 716 717 This function gets the basic debug information (entrypoint, baseaddress, .text, .data section base address) 718 from PE/COFF image and abstracts Pe Map file information and add them into FvMap file for Debug. 719 720 Arguments: 721 722 FvMapFile A pointer to FvMap File 723 FileName Ffs File PathName 724 FfsFile A pointer to Ffs file image. 725 ImageBaseAddress PeImage Base Address. 726 pImageContext Image Context Information. 727 728 Returns: 729 730 EFI_SUCCESS Added required map information. 731 732 --*/ 733 { 734 CHAR8 PeMapFileName [MAX_LONG_FILE_PATH]; 735 CHAR8 *Cptr, *Cptr2; 736 CHAR8 FileGuidName [MAX_LINE_LEN]; 737 FILE *PeMapFile; 738 CHAR8 Line [MAX_LINE_LEN]; 739 CHAR8 KeyWord [MAX_LINE_LEN]; 740 CHAR8 FunctionName [MAX_LINE_LEN]; 741 EFI_PHYSICAL_ADDRESS FunctionAddress; 742 UINT32 FunctionType; 743 CHAR8 FunctionTypeName [MAX_LINE_LEN]; 744 UINT32 Index; 745 UINT32 AddressOfEntryPoint; 746 UINT32 Offset; 747 EFI_IMAGE_OPTIONAL_HEADER_UNION *ImgHdr; 748 EFI_TE_IMAGE_HEADER *TEImageHeader; 749 EFI_IMAGE_SECTION_HEADER *SectionHeader; 750 unsigned long long TempLongAddress; 751 UINT32 TextVirtualAddress; 752 UINT32 DataVirtualAddress; 753 EFI_PHYSICAL_ADDRESS LinkTimeBaseAddress; 754 755 // 756 // Init local variable 757 // 758 FunctionType = 0; 759 // 760 // Print FileGuid to string buffer. 761 // 762 PrintGuidToBuffer (&FfsFile->Name, (UINT8 *)FileGuidName, MAX_LINE_LEN, TRUE); 763 764 // 765 // Construct Map file Name 766 // 767 strcpy (PeMapFileName, FileName); 768 769 // 770 // Change '\\' to '/', unified path format. 771 // 772 Cptr = PeMapFileName; 773 while (*Cptr != '\0') { 774 if (*Cptr == '\\') { 775 *Cptr = FILE_SEP_CHAR; 776 } 777 Cptr ++; 778 } 779 780 // 781 // Get Map file 782 // 783 Cptr = PeMapFileName + strlen (PeMapFileName); 784 while ((*Cptr != '.') && (Cptr >= PeMapFileName)) { 785 Cptr --; 786 } 787 if (Cptr < PeMapFileName) { 788 return EFI_NOT_FOUND; 789 } else { 790 *(Cptr + 1) = 'm'; 791 *(Cptr + 2) = 'a'; 792 *(Cptr + 3) = 'p'; 793 *(Cptr + 4) = '\0'; 794 } 795 796 // 797 // Get module Name 798 // 799 Cptr2 = Cptr; 800 while ((*Cptr != FILE_SEP_CHAR) && (Cptr >= PeMapFileName)) { 801 Cptr --; 802 } 803 *Cptr2 = '\0'; 804 strcpy (KeyWord, Cptr + 1); 805 *Cptr2 = '.'; 806 807 // 808 // AddressOfEntryPoint and Offset in Image 809 // 810 if (!pImageContext->IsTeImage) { 811 ImgHdr = (EFI_IMAGE_OPTIONAL_HEADER_UNION *) ((UINT8 *) pImageContext->Handle + pImageContext->PeCoffHeaderOffset); 812 AddressOfEntryPoint = ImgHdr->Pe32.OptionalHeader.AddressOfEntryPoint; 813 Offset = 0; 814 SectionHeader = (EFI_IMAGE_SECTION_HEADER *) ( 815 (UINT8 *) ImgHdr + 816 sizeof (UINT32) + 817 sizeof (EFI_IMAGE_FILE_HEADER) + 818 ImgHdr->Pe32.FileHeader.SizeOfOptionalHeader 819 ); 820 Index = ImgHdr->Pe32.FileHeader.NumberOfSections; 821 } else { 822 TEImageHeader = (EFI_TE_IMAGE_HEADER *) pImageContext->Handle; 823 AddressOfEntryPoint = TEImageHeader->AddressOfEntryPoint; 824 Offset = TEImageHeader->StrippedSize - sizeof (EFI_TE_IMAGE_HEADER); 825 SectionHeader = (EFI_IMAGE_SECTION_HEADER *) (TEImageHeader + 1); 826 Index = TEImageHeader->NumberOfSections; 827 } 828 829 // 830 // module information output 831 // 832 if (ImageBaseAddress == 0) { 833 fprintf (FvMapFile, "%s (dummy) (", KeyWord); 834 fprintf (FvMapFile, "BaseAddress=%010llx, ", (unsigned long long) ImageBaseAddress); 835 } else { 836 fprintf (FvMapFile, "%s (Fixed Flash Address, ", KeyWord); 837 fprintf (FvMapFile, "BaseAddress=0x%010llx, ", (unsigned long long) (ImageBaseAddress + Offset)); 838 } 839 840 if (FfsFile->Type != EFI_FV_FILETYPE_SECURITY_CORE && pImageContext->Machine == EFI_IMAGE_MACHINE_IA64) { 841 // 842 // Process IPF PLABEL to get the real address after the image has been rebased. 843 // PLABEL structure is got by AddressOfEntryPoint offset to ImageBuffer stored in pImageContext->Handle. 844 // 845 fprintf (FvMapFile, "EntryPoint=0x%010llx", (unsigned long long) (*(UINT64 *)((UINTN) pImageContext->Handle + (UINTN) AddressOfEntryPoint))); 846 } else { 847 fprintf (FvMapFile, "EntryPoint=0x%010llx", (unsigned long long) (ImageBaseAddress + AddressOfEntryPoint)); 848 } 849 fprintf (FvMapFile, ")\n"); 850 851 fprintf (FvMapFile, "(GUID=%s", FileGuidName); 852 TextVirtualAddress = 0; 853 DataVirtualAddress = 0; 854 for (; Index > 0; Index --, SectionHeader ++) { 855 if (stricmp ((CHAR8 *)SectionHeader->Name, ".text") == 0) { 856 TextVirtualAddress = SectionHeader->VirtualAddress; 857 } else if (stricmp ((CHAR8 *)SectionHeader->Name, ".data") == 0) { 858 DataVirtualAddress = SectionHeader->VirtualAddress; 859 } else if (stricmp ((CHAR8 *)SectionHeader->Name, ".sdata") == 0) { 860 DataVirtualAddress = SectionHeader->VirtualAddress; 861 } 862 } 863 fprintf (FvMapFile, " .textbaseaddress=0x%010llx", (unsigned long long) (ImageBaseAddress + TextVirtualAddress)); 864 fprintf (FvMapFile, " .databaseaddress=0x%010llx", (unsigned long long) (ImageBaseAddress + DataVirtualAddress)); 865 fprintf (FvMapFile, ")\n\n"); 866 867 // 868 // Open PeMapFile 869 // 870 PeMapFile = fopen (LongFilePath (PeMapFileName), "r"); 871 if (PeMapFile == NULL) { 872 // fprintf (stdout, "can't open %s file to reading\n", PeMapFileName); 873 return EFI_ABORTED; 874 } 875 VerboseMsg ("The map file is %s", PeMapFileName); 876 877 // 878 // Output Functions information into Fv Map file 879 // 880 LinkTimeBaseAddress = 0; 881 while (fgets (Line, MAX_LINE_LEN, PeMapFile) != NULL) { 882 // 883 // Skip blank line 884 // 885 if (Line[0] == 0x0a) { 886 FunctionType = 0; 887 continue; 888 } 889 // 890 // By Address and Static keyword 891 // 892 if (FunctionType == 0) { 893 sscanf (Line, "%s", KeyWord); 894 if (stricmp (KeyWord, "Address") == 0) { 895 // 896 // function list 897 // 898 FunctionType = 1; 899 fgets (Line, MAX_LINE_LEN, PeMapFile); 900 } else if (stricmp (KeyWord, "Static") == 0) { 901 // 902 // static function list 903 // 904 FunctionType = 2; 905 fgets (Line, MAX_LINE_LEN, PeMapFile); 906 } else if (stricmp (KeyWord, "Preferred") ==0) { 907 sscanf (Line + strlen (" Preferred load address is"), "%llx", &TempLongAddress); 908 LinkTimeBaseAddress = (UINT64) TempLongAddress; 909 } 910 continue; 911 } 912 // 913 // Printf Function Information 914 // 915 if (FunctionType == 1) { 916 sscanf (Line, "%s %s %llx %s", KeyWord, FunctionName, &TempLongAddress, FunctionTypeName); 917 FunctionAddress = (UINT64) TempLongAddress; 918 if (FunctionTypeName [1] == '\0' && (FunctionTypeName [0] == 'f' || FunctionTypeName [0] == 'F')) { 919 fprintf (FvMapFile, " 0x%010llx ", (unsigned long long) (ImageBaseAddress + FunctionAddress - LinkTimeBaseAddress)); 920 fprintf (FvMapFile, "%s\n", FunctionName); 921 } 922 } else if (FunctionType == 2) { 923 sscanf (Line, "%s %s %llx %s", KeyWord, FunctionName, &TempLongAddress, FunctionTypeName); 924 FunctionAddress = (UINT64) TempLongAddress; 925 if (FunctionTypeName [1] == '\0' && (FunctionTypeName [0] == 'f' || FunctionTypeName [0] == 'F')) { 926 fprintf (FvMapFile, " 0x%010llx ", (unsigned long long) (ImageBaseAddress + FunctionAddress - LinkTimeBaseAddress)); 927 fprintf (FvMapFile, "%s\n", FunctionName); 928 } 929 } 930 } 931 // 932 // Close PeMap file 933 // 934 fprintf (FvMapFile, "\n\n"); 935 fclose (PeMapFile); 936 937 return EFI_SUCCESS; 938 } 939 940 STATIC 941 BOOLEAN 942 AdjustInternalFfsPadding ( 943 IN OUT EFI_FFS_FILE_HEADER *FfsFile, 944 IN OUT MEMORY_FILE *FvImage, 945 IN UINTN Alignment, 946 IN OUT UINTN *FileSize 947 ) 948 /*++ 949 950 Routine Description: 951 952 This function looks for a dedicated alignment padding section in the FFS, and 953 shrinks it to the size required to line up subsequent sections correctly. 954 955 Arguments: 956 957 FfsFile A pointer to Ffs file image. 958 FvImage The memory image of the FV to adjust it to. 959 Alignment Current file alignment 960 FileSize Reference to a variable holding the size of the FFS file 961 962 Returns: 963 964 TRUE Padding section was found and updated successfully 965 FALSE Otherwise 966 967 --*/ 968 { 969 EFI_FILE_SECTION_POINTER PadSection; 970 UINT8 *Remainder; 971 EFI_STATUS Status; 972 UINT32 FfsHeaderLength; 973 UINT32 FfsFileLength; 974 UINT32 PadSize; 975 UINTN Misalignment; 976 EFI_FFS_INTEGRITY_CHECK *IntegrityCheck; 977 978 // 979 // Figure out the misalignment: all FFS sections are aligned relative to the 980 // start of the FFS payload, so use that as the base of the misalignment 981 // computation. 982 // 983 FfsHeaderLength = GetFfsHeaderLength(FfsFile); 984 Misalignment = (UINTN) FvImage->CurrentFilePointer - 985 (UINTN) FvImage->FileImage + FfsHeaderLength; 986 Misalignment &= Alignment - 1; 987 if (Misalignment == 0) { 988 // Nothing to do, return success 989 return TRUE; 990 } 991 992 // 993 // We only apply this optimization to FFS files with the FIXED attribute set, 994 // since the FFS will not be loadable at arbitrary offsets anymore after 995 // we adjust the size of the padding section. 996 // 997 if ((FfsFile->Attributes & FFS_ATTRIB_FIXED) == 0) { 998 return FALSE; 999 } 1000 1001 // 1002 // Look for a dedicated padding section that we can adjust to compensate 1003 // for the misalignment. If such a padding section exists, it precedes all 1004 // sections with alignment requirements, and so the adjustment will correct 1005 // all of them. 1006 // 1007 Status = GetSectionByType (FfsFile, EFI_SECTION_FREEFORM_SUBTYPE_GUID, 1, 1008 &PadSection); 1009 if (EFI_ERROR (Status) || 1010 CompareGuid (&PadSection.FreeformSubtypeSection->SubTypeGuid, 1011 &mEfiFfsSectionAlignmentPaddingGuid) != 0) { 1012 return FALSE; 1013 } 1014 1015 // 1016 // Find out if the size of the padding section is sufficient to compensate 1017 // for the misalignment. 1018 // 1019 PadSize = GetSectionFileLength (PadSection.CommonHeader); 1020 if (Misalignment > PadSize - sizeof (EFI_FREEFORM_SUBTYPE_GUID_SECTION)) { 1021 return FALSE; 1022 } 1023 1024 // 1025 // Move the remainder of the FFS file towards the front, and adjust the 1026 // file size output parameter. 1027 // 1028 Remainder = (UINT8 *) PadSection.CommonHeader + PadSize; 1029 memmove (Remainder - Misalignment, Remainder, 1030 *FileSize - (UINTN) (Remainder - (UINTN) FfsFile)); 1031 *FileSize -= Misalignment; 1032 1033 // 1034 // Update the padding section's length with the new values. Note that the 1035 // padding is always < 64 KB, so we can ignore EFI_COMMON_SECTION_HEADER2 1036 // ExtendedSize. 1037 // 1038 PadSize -= Misalignment; 1039 PadSection.CommonHeader->Size[0] = (UINT8) (PadSize & 0xff); 1040 PadSection.CommonHeader->Size[1] = (UINT8) ((PadSize & 0xff00) >> 8); 1041 PadSection.CommonHeader->Size[2] = (UINT8) ((PadSize & 0xff0000) >> 16); 1042 1043 // 1044 // Update the FFS header with the new overall length 1045 // 1046 FfsFileLength = GetFfsFileLength (FfsFile) - Misalignment; 1047 if (FfsHeaderLength > sizeof(EFI_FFS_FILE_HEADER)) { 1048 ((EFI_FFS_FILE_HEADER2 *)FfsFile)->ExtendedSize = FfsFileLength; 1049 } else { 1050 FfsFile->Size[0] = (UINT8) (FfsFileLength & 0x000000FF); 1051 FfsFile->Size[1] = (UINT8) ((FfsFileLength & 0x0000FF00) >> 8); 1052 FfsFile->Size[2] = (UINT8) ((FfsFileLength & 0x00FF0000) >> 16); 1053 } 1054 1055 // 1056 // Clear the alignment bits: these have become meaningless now that we have 1057 // adjusted the padding section. 1058 // 1059 FfsFile->Attributes &= ~FFS_ATTRIB_DATA_ALIGNMENT; 1060 1061 // 1062 // Recalculate the FFS header checksum. Instead of setting Header and State 1063 // both to zero, set Header to (UINT8)(-State) so State preserves its original 1064 // value 1065 // 1066 IntegrityCheck = &FfsFile->IntegrityCheck; 1067 IntegrityCheck->Checksum.Header = (UINT8) (0x100 - FfsFile->State); 1068 IntegrityCheck->Checksum.File = 0; 1069 1070 IntegrityCheck->Checksum.Header = CalculateChecksum8 ( 1071 (UINT8 *) FfsFile, FfsHeaderLength); 1072 1073 if (FfsFile->Attributes & FFS_ATTRIB_CHECKSUM) { 1074 // 1075 // Ffs header checksum = zero, so only need to calculate ffs body. 1076 // 1077 IntegrityCheck->Checksum.File = CalculateChecksum8 ( 1078 (UINT8 *) FfsFile + FfsHeaderLength, 1079 FfsFileLength - FfsHeaderLength); 1080 } else { 1081 IntegrityCheck->Checksum.File = FFS_FIXED_CHECKSUM; 1082 } 1083 1084 return TRUE; 1085 } 1086 1087 EFI_STATUS 1088 AddFile ( 1089 IN OUT MEMORY_FILE *FvImage, 1090 IN FV_INFO *FvInfo, 1091 IN UINTN Index, 1092 IN OUT EFI_FFS_FILE_HEADER **VtfFileImage, 1093 IN FILE *FvMapFile, 1094 IN FILE *FvReportFile 1095 ) 1096 /*++ 1097 1098 Routine Description: 1099 1100 This function adds a file to the FV image. The file will pad to the 1101 appropriate alignment if required. 1102 1103 Arguments: 1104 1105 FvImage The memory image of the FV to add it to. The current offset 1106 must be valid. 1107 FvInfo Pointer to information about the FV. 1108 Index The file in the FvInfo file list to add. 1109 VtfFileImage A pointer to the VTF file within the FvImage. If this is equal 1110 to the end of the FvImage then no VTF previously found. 1111 FvMapFile Pointer to FvMap File 1112 FvReportFile Pointer to FvReport File 1113 1114 Returns: 1115 1116 EFI_SUCCESS The function completed successfully. 1117 EFI_INVALID_PARAMETER One of the input parameters was invalid. 1118 EFI_ABORTED An error occurred. 1119 EFI_OUT_OF_RESOURCES Insufficient resources exist to complete the add. 1120 1121 --*/ 1122 { 1123 FILE *NewFile; 1124 UINTN FileSize; 1125 UINT8 *FileBuffer; 1126 UINTN NumBytesRead; 1127 UINT32 CurrentFileAlignment; 1128 EFI_STATUS Status; 1129 UINTN Index1; 1130 UINT8 FileGuidString[PRINTED_GUID_BUFFER_SIZE]; 1131 1132 Index1 = 0; 1133 // 1134 // Verify input parameters. 1135 // 1136 if (FvImage == NULL || FvInfo == NULL || FvInfo->FvFiles[Index][0] == 0 || VtfFileImage == NULL) { 1137 return EFI_INVALID_PARAMETER; 1138 } 1139 1140 // 1141 // Read the file to add 1142 // 1143 NewFile = fopen (LongFilePath (FvInfo->FvFiles[Index]), "rb"); 1144 1145 if (NewFile == NULL) { 1146 Error (NULL, 0, 0001, "Error opening file", FvInfo->FvFiles[Index]); 1147 return EFI_ABORTED; 1148 } 1149 1150 // 1151 // Get the file size 1152 // 1153 FileSize = _filelength (fileno (NewFile)); 1154 1155 // 1156 // Read the file into a buffer 1157 // 1158 FileBuffer = malloc (FileSize); 1159 if (FileBuffer == NULL) { 1160 Error (NULL, 0, 4001, "Resouce", "memory cannot be allocated!"); 1161 return EFI_OUT_OF_RESOURCES; 1162 } 1163 1164 NumBytesRead = fread (FileBuffer, sizeof (UINT8), FileSize, NewFile); 1165 1166 // 1167 // Done with the file, from this point on we will just use the buffer read. 1168 // 1169 fclose (NewFile); 1170 1171 // 1172 // Verify read successful 1173 // 1174 if (NumBytesRead != sizeof (UINT8) * FileSize) { 1175 free (FileBuffer); 1176 Error (NULL, 0, 0004, "Error reading file", FvInfo->FvFiles[Index]); 1177 return EFI_ABORTED; 1178 } 1179 1180 // 1181 // For None PI Ffs file, directly add them into FvImage. 1182 // 1183 if (!FvInfo->IsPiFvImage) { 1184 memcpy (FvImage->CurrentFilePointer, FileBuffer, FileSize); 1185 if (FvInfo->SizeofFvFiles[Index] > FileSize) { 1186 FvImage->CurrentFilePointer += FvInfo->SizeofFvFiles[Index]; 1187 } else { 1188 FvImage->CurrentFilePointer += FileSize; 1189 } 1190 goto Done; 1191 } 1192 1193 // 1194 // Verify Ffs file 1195 // 1196 Status = VerifyFfsFile ((EFI_FFS_FILE_HEADER *)FileBuffer); 1197 if (EFI_ERROR (Status)) { 1198 free (FileBuffer); 1199 Error (NULL, 0, 3000, "Invalid", "%s is not a valid FFS file.", FvInfo->FvFiles[Index]); 1200 return EFI_INVALID_PARAMETER; 1201 } 1202 1203 // 1204 // Verify space exists to add the file 1205 // 1206 if (FileSize > (UINTN) ((UINTN) *VtfFileImage - (UINTN) FvImage->CurrentFilePointer)) { 1207 free (FileBuffer); 1208 Error (NULL, 0, 4002, "Resource", "FV space is full, not enough room to add file %s.", FvInfo->FvFiles[Index]); 1209 return EFI_OUT_OF_RESOURCES; 1210 } 1211 1212 // 1213 // Verify the input file is the duplicated file in this Fv image 1214 // 1215 for (Index1 = 0; Index1 < Index; Index1 ++) { 1216 if (CompareGuid ((EFI_GUID *) FileBuffer, &mFileGuidArray [Index1]) == 0) { 1217 Error (NULL, 0, 2000, "Invalid parameter", "the %dth file and %uth file have the same file GUID.", (unsigned) Index1 + 1, (unsigned) Index + 1); 1218 PrintGuid ((EFI_GUID *) FileBuffer); 1219 return EFI_INVALID_PARAMETER; 1220 } 1221 } 1222 CopyMem (&mFileGuidArray [Index], FileBuffer, sizeof (EFI_GUID)); 1223 1224 // 1225 // Update the file state based on polarity of the FV. 1226 // 1227 UpdateFfsFileState ( 1228 (EFI_FFS_FILE_HEADER *) FileBuffer, 1229 (EFI_FIRMWARE_VOLUME_HEADER *) FvImage->FileImage 1230 ); 1231 1232 // 1233 // Check if alignment is required 1234 // 1235 ReadFfsAlignment ((EFI_FFS_FILE_HEADER *) FileBuffer, &CurrentFileAlignment); 1236 1237 // 1238 // Find the largest alignment of all the FFS files in the FV 1239 // 1240 if (CurrentFileAlignment > MaxFfsAlignment) { 1241 MaxFfsAlignment = CurrentFileAlignment; 1242 } 1243 // 1244 // If we have a VTF file, add it at the top. 1245 // 1246 if (IsVtfFile ((EFI_FFS_FILE_HEADER *) FileBuffer)) { 1247 if ((UINTN) *VtfFileImage == (UINTN) FvImage->Eof) { 1248 // 1249 // No previous VTF, add this one. 1250 // 1251 *VtfFileImage = (EFI_FFS_FILE_HEADER *) (UINTN) ((UINTN) FvImage->FileImage + FvInfo->Size - FileSize); 1252 // 1253 // Sanity check. The file MUST align appropriately 1254 // 1255 if (((UINTN) *VtfFileImage + GetFfsHeaderLength((EFI_FFS_FILE_HEADER *)FileBuffer) - (UINTN) FvImage->FileImage) % (1 << CurrentFileAlignment)) { 1256 Error (NULL, 0, 3000, "Invalid", "VTF file cannot be aligned on a %u-byte boundary.", (unsigned) (1 << CurrentFileAlignment)); 1257 free (FileBuffer); 1258 return EFI_ABORTED; 1259 } 1260 // 1261 // Rebase the PE or TE image in FileBuffer of FFS file for XIP 1262 // Rebase for the debug genfvmap tool 1263 // 1264 Status = FfsRebase (FvInfo, FvInfo->FvFiles[Index], (EFI_FFS_FILE_HEADER *) FileBuffer, (UINTN) *VtfFileImage - (UINTN) FvImage->FileImage, FvMapFile); 1265 if (EFI_ERROR (Status)) { 1266 Error (NULL, 0, 3000, "Invalid", "Could not rebase %s.", FvInfo->FvFiles[Index]); 1267 return Status; 1268 } 1269 // 1270 // copy VTF File 1271 // 1272 memcpy (*VtfFileImage, FileBuffer, FileSize); 1273 1274 PrintGuidToBuffer ((EFI_GUID *) FileBuffer, FileGuidString, sizeof (FileGuidString), TRUE); 1275 fprintf (FvReportFile, "0x%08X %s\n", (unsigned)(UINTN) (((UINT8 *)*VtfFileImage) - (UINTN)FvImage->FileImage), FileGuidString); 1276 1277 free (FileBuffer); 1278 DebugMsg (NULL, 0, 9, "Add VTF FFS file in FV image", NULL); 1279 return EFI_SUCCESS; 1280 } else { 1281 // 1282 // Already found a VTF file. 1283 // 1284 Error (NULL, 0, 3000, "Invalid", "multiple VTF files are not permitted within a single FV."); 1285 free (FileBuffer); 1286 return EFI_ABORTED; 1287 } 1288 } 1289 1290 // 1291 // Add pad file if necessary 1292 // 1293 if (!AdjustInternalFfsPadding ((EFI_FFS_FILE_HEADER *) FileBuffer, FvImage, 1294 1 << CurrentFileAlignment, &FileSize)) { 1295 Status = AddPadFile (FvImage, 1 << CurrentFileAlignment, *VtfFileImage, NULL, FileSize); 1296 if (EFI_ERROR (Status)) { 1297 Error (NULL, 0, 4002, "Resource", "FV space is full, could not add pad file for data alignment property."); 1298 free (FileBuffer); 1299 return EFI_ABORTED; 1300 } 1301 } 1302 // 1303 // Add file 1304 // 1305 if ((UINTN) (FvImage->CurrentFilePointer + FileSize) <= (UINTN) (*VtfFileImage)) { 1306 // 1307 // Rebase the PE or TE image in FileBuffer of FFS file for XIP. 1308 // Rebase Bs and Rt drivers for the debug genfvmap tool. 1309 // 1310 Status = FfsRebase (FvInfo, FvInfo->FvFiles[Index], (EFI_FFS_FILE_HEADER *) FileBuffer, (UINTN) FvImage->CurrentFilePointer - (UINTN) FvImage->FileImage, FvMapFile); 1311 if (EFI_ERROR (Status)) { 1312 Error (NULL, 0, 3000, "Invalid", "Could not rebase %s.", FvInfo->FvFiles[Index]); 1313 return Status; 1314 } 1315 // 1316 // Copy the file 1317 // 1318 memcpy (FvImage->CurrentFilePointer, FileBuffer, FileSize); 1319 PrintGuidToBuffer ((EFI_GUID *) FileBuffer, FileGuidString, sizeof (FileGuidString), TRUE); 1320 fprintf (FvReportFile, "0x%08X %s\n", (unsigned) (FvImage->CurrentFilePointer - FvImage->FileImage), FileGuidString); 1321 FvImage->CurrentFilePointer += FileSize; 1322 } else { 1323 Error (NULL, 0, 4002, "Resource", "FV space is full, cannot add file %s.", FvInfo->FvFiles[Index]); 1324 free (FileBuffer); 1325 return EFI_ABORTED; 1326 } 1327 // 1328 // Make next file start at QWord Boundry 1329 // 1330 while (((UINTN) FvImage->CurrentFilePointer & (EFI_FFS_FILE_HEADER_ALIGNMENT - 1)) != 0) { 1331 FvImage->CurrentFilePointer++; 1332 } 1333 1334 Done: 1335 // 1336 // Free allocated memory. 1337 // 1338 free (FileBuffer); 1339 1340 return EFI_SUCCESS; 1341 } 1342 1343 EFI_STATUS 1344 PadFvImage ( 1345 IN MEMORY_FILE *FvImage, 1346 IN EFI_FFS_FILE_HEADER *VtfFileImage 1347 ) 1348 /*++ 1349 1350 Routine Description: 1351 1352 This function places a pad file between the last file in the FV and the VTF 1353 file if the VTF file exists. 1354 1355 Arguments: 1356 1357 FvImage Memory file for the FV memory image 1358 VtfFileImage The address of the VTF file. If this is the end of the FV 1359 image, no VTF exists and no pad file is needed. 1360 1361 Returns: 1362 1363 EFI_SUCCESS Completed successfully. 1364 EFI_INVALID_PARAMETER One of the input parameters was NULL. 1365 1366 --*/ 1367 { 1368 EFI_FFS_FILE_HEADER *PadFile; 1369 UINTN FileSize; 1370 UINT32 FfsHeaderSize; 1371 1372 // 1373 // If there is no VTF or the VTF naturally follows the previous file without a 1374 // pad file, then there's nothing to do 1375 // 1376 if ((UINTN) VtfFileImage == (UINTN) FvImage->Eof || \ 1377 ((UINTN) VtfFileImage == (UINTN) FvImage->CurrentFilePointer)) { 1378 return EFI_SUCCESS; 1379 } 1380 1381 if ((UINTN) VtfFileImage < (UINTN) FvImage->CurrentFilePointer) { 1382 return EFI_INVALID_PARAMETER; 1383 } 1384 1385 // 1386 // Pad file starts at beginning of free space 1387 // 1388 PadFile = (EFI_FFS_FILE_HEADER *) FvImage->CurrentFilePointer; 1389 1390 // 1391 // write PadFile FFS header with PadType, don't need to set PAD file guid in its header. 1392 // 1393 PadFile->Type = EFI_FV_FILETYPE_FFS_PAD; 1394 PadFile->Attributes = 0; 1395 1396 // 1397 // FileSize includes the EFI_FFS_FILE_HEADER 1398 // 1399 FileSize = (UINTN) VtfFileImage - (UINTN) FvImage->CurrentFilePointer; 1400 if (FileSize >= MAX_FFS_SIZE) { 1401 PadFile->Attributes |= FFS_ATTRIB_LARGE_FILE; 1402 memset(PadFile->Size, 0, sizeof(UINT8) * 3); 1403 ((EFI_FFS_FILE_HEADER2 *)PadFile)->ExtendedSize = FileSize; 1404 FfsHeaderSize = sizeof(EFI_FFS_FILE_HEADER2); 1405 mIsLargeFfs = TRUE; 1406 } else { 1407 PadFile->Size[0] = (UINT8) (FileSize & 0x000000FF); 1408 PadFile->Size[1] = (UINT8) ((FileSize & 0x0000FF00) >> 8); 1409 PadFile->Size[2] = (UINT8) ((FileSize & 0x00FF0000) >> 16); 1410 FfsHeaderSize = sizeof(EFI_FFS_FILE_HEADER); 1411 } 1412 1413 // 1414 // Fill in checksums and state, must be zero during checksum calculation. 1415 // 1416 PadFile->IntegrityCheck.Checksum.Header = 0; 1417 PadFile->IntegrityCheck.Checksum.File = 0; 1418 PadFile->State = 0; 1419 PadFile->IntegrityCheck.Checksum.Header = CalculateChecksum8 ((UINT8 *) PadFile, FfsHeaderSize); 1420 PadFile->IntegrityCheck.Checksum.File = FFS_FIXED_CHECKSUM; 1421 1422 PadFile->State = EFI_FILE_HEADER_CONSTRUCTION | EFI_FILE_HEADER_VALID | EFI_FILE_DATA_VALID; 1423 1424 UpdateFfsFileState ( 1425 (EFI_FFS_FILE_HEADER *) PadFile, 1426 (EFI_FIRMWARE_VOLUME_HEADER *) FvImage->FileImage 1427 ); 1428 // 1429 // Update the current FV pointer 1430 // 1431 FvImage->CurrentFilePointer = FvImage->Eof; 1432 1433 return EFI_SUCCESS; 1434 } 1435 1436 EFI_STATUS 1437 UpdateResetVector ( 1438 IN MEMORY_FILE *FvImage, 1439 IN FV_INFO *FvInfo, 1440 IN EFI_FFS_FILE_HEADER *VtfFile 1441 ) 1442 /*++ 1443 1444 Routine Description: 1445 1446 This parses the FV looking for the PEI core and then plugs the address into 1447 the SALE_ENTRY point of the BSF/VTF for IPF and does BUGBUG TBD action to 1448 complete an IA32 Bootstrap FV. 1449 1450 Arguments: 1451 1452 FvImage Memory file for the FV memory image 1453 FvInfo Information read from INF file. 1454 VtfFile Pointer to the VTF file in the FV image. 1455 1456 Returns: 1457 1458 EFI_SUCCESS Function Completed successfully. 1459 EFI_ABORTED Error encountered. 1460 EFI_INVALID_PARAMETER A required parameter was NULL. 1461 EFI_NOT_FOUND PEI Core file not found. 1462 1463 --*/ 1464 { 1465 EFI_FFS_FILE_HEADER *PeiCoreFile; 1466 EFI_FFS_FILE_HEADER *SecCoreFile; 1467 EFI_STATUS Status; 1468 EFI_FILE_SECTION_POINTER Pe32Section; 1469 UINT32 EntryPoint; 1470 UINT32 BaseOfCode; 1471 UINT16 MachineType; 1472 EFI_PHYSICAL_ADDRESS PeiCorePhysicalAddress; 1473 EFI_PHYSICAL_ADDRESS SecCorePhysicalAddress; 1474 EFI_PHYSICAL_ADDRESS *SecCoreEntryAddressPtr; 1475 INT32 Ia32SecEntryOffset; 1476 UINT32 *Ia32ResetAddressPtr; 1477 UINT8 *BytePointer; 1478 UINT8 *BytePointer2; 1479 UINT16 *WordPointer; 1480 UINT16 CheckSum; 1481 UINT32 IpiVector; 1482 UINTN Index; 1483 EFI_FFS_FILE_STATE SavedState; 1484 UINT64 FitAddress; 1485 FIT_TABLE *FitTablePtr; 1486 BOOLEAN Vtf0Detected; 1487 UINT32 FfsHeaderSize; 1488 UINT32 SecHeaderSize; 1489 1490 // 1491 // Verify input parameters 1492 // 1493 if (FvImage == NULL || FvInfo == NULL || VtfFile == NULL) { 1494 return EFI_INVALID_PARAMETER; 1495 } 1496 // 1497 // Initialize FV library 1498 // 1499 InitializeFvLib (FvImage->FileImage, FvInfo->Size); 1500 1501 // 1502 // Verify VTF file 1503 // 1504 Status = VerifyFfsFile (VtfFile); 1505 if (EFI_ERROR (Status)) { 1506 return EFI_INVALID_PARAMETER; 1507 } 1508 1509 if ( 1510 (((UINTN)FvImage->Eof - (UINTN)FvImage->FileImage) >= 1511 IA32_X64_VTF_SIGNATURE_OFFSET) && 1512 (*(UINT32 *)(VOID*)((UINTN) FvImage->Eof - 1513 IA32_X64_VTF_SIGNATURE_OFFSET) == 1514 IA32_X64_VTF0_SIGNATURE) 1515 ) { 1516 Vtf0Detected = TRUE; 1517 } else { 1518 Vtf0Detected = FALSE; 1519 } 1520 1521 // 1522 // Find the Sec Core 1523 // 1524 Status = GetFileByType (EFI_FV_FILETYPE_SECURITY_CORE, 1, &SecCoreFile); 1525 if (EFI_ERROR (Status) || SecCoreFile == NULL) { 1526 if (Vtf0Detected) { 1527 // 1528 // If the SEC core file is not found, but the VTF-0 signature 1529 // is found, we'll treat it as a VTF-0 'Volume Top File'. 1530 // This means no modifications are required to the VTF. 1531 // 1532 return EFI_SUCCESS; 1533 } 1534 1535 Error (NULL, 0, 3000, "Invalid", "could not find the SEC core file in the FV."); 1536 return EFI_ABORTED; 1537 } 1538 // 1539 // Sec Core found, now find PE32 section 1540 // 1541 Status = GetSectionByType (SecCoreFile, EFI_SECTION_PE32, 1, &Pe32Section); 1542 if (Status == EFI_NOT_FOUND) { 1543 Status = GetSectionByType (SecCoreFile, EFI_SECTION_TE, 1, &Pe32Section); 1544 } 1545 1546 if (EFI_ERROR (Status)) { 1547 Error (NULL, 0, 3000, "Invalid", "could not find a PE32 section in the SEC core file."); 1548 return EFI_ABORTED; 1549 } 1550 1551 SecHeaderSize = GetSectionHeaderLength(Pe32Section.CommonHeader); 1552 Status = GetPe32Info ( 1553 (VOID *) ((UINTN) Pe32Section.Pe32Section + SecHeaderSize), 1554 &EntryPoint, 1555 &BaseOfCode, 1556 &MachineType 1557 ); 1558 1559 if (EFI_ERROR (Status)) { 1560 Error (NULL, 0, 3000, "Invalid", "could not get the PE32 entry point for the SEC core."); 1561 return EFI_ABORTED; 1562 } 1563 1564 if ( 1565 Vtf0Detected && 1566 (MachineType == EFI_IMAGE_MACHINE_IA32 || 1567 MachineType == EFI_IMAGE_MACHINE_X64) 1568 ) { 1569 // 1570 // If the SEC core code is IA32 or X64 and the VTF-0 signature 1571 // is found, we'll treat it as a VTF-0 'Volume Top File'. 1572 // This means no modifications are required to the VTF. 1573 // 1574 return EFI_SUCCESS; 1575 } 1576 1577 // 1578 // Physical address is FV base + offset of PE32 + offset of the entry point 1579 // 1580 SecCorePhysicalAddress = FvInfo->BaseAddress; 1581 SecCorePhysicalAddress += (UINTN) Pe32Section.Pe32Section + SecHeaderSize - (UINTN) FvImage->FileImage; 1582 SecCorePhysicalAddress += EntryPoint; 1583 DebugMsg (NULL, 0, 9, "SecCore physical entry point address", "Address = 0x%llX", (unsigned long long) SecCorePhysicalAddress); 1584 1585 // 1586 // Find the PEI Core 1587 // 1588 Status = GetFileByType (EFI_FV_FILETYPE_PEI_CORE, 1, &PeiCoreFile); 1589 if (EFI_ERROR (Status) || PeiCoreFile == NULL) { 1590 Error (NULL, 0, 3000, "Invalid", "could not find the PEI core in the FV."); 1591 return EFI_ABORTED; 1592 } 1593 // 1594 // PEI Core found, now find PE32 or TE section 1595 // 1596 Status = GetSectionByType (PeiCoreFile, EFI_SECTION_PE32, 1, &Pe32Section); 1597 if (Status == EFI_NOT_FOUND) { 1598 Status = GetSectionByType (PeiCoreFile, EFI_SECTION_TE, 1, &Pe32Section); 1599 } 1600 1601 if (EFI_ERROR (Status)) { 1602 Error (NULL, 0, 3000, "Invalid", "could not find either a PE32 or a TE section in PEI core file."); 1603 return EFI_ABORTED; 1604 } 1605 1606 SecHeaderSize = GetSectionHeaderLength(Pe32Section.CommonHeader); 1607 Status = GetPe32Info ( 1608 (VOID *) ((UINTN) Pe32Section.Pe32Section + SecHeaderSize), 1609 &EntryPoint, 1610 &BaseOfCode, 1611 &MachineType 1612 ); 1613 1614 if (EFI_ERROR (Status)) { 1615 Error (NULL, 0, 3000, "Invalid", "could not get the PE32 entry point for the PEI core."); 1616 return EFI_ABORTED; 1617 } 1618 // 1619 // Physical address is FV base + offset of PE32 + offset of the entry point 1620 // 1621 PeiCorePhysicalAddress = FvInfo->BaseAddress; 1622 PeiCorePhysicalAddress += (UINTN) Pe32Section.Pe32Section + SecHeaderSize - (UINTN) FvImage->FileImage; 1623 PeiCorePhysicalAddress += EntryPoint; 1624 DebugMsg (NULL, 0, 9, "PeiCore physical entry point address", "Address = 0x%llX", (unsigned long long) PeiCorePhysicalAddress); 1625 1626 if (MachineType == EFI_IMAGE_MACHINE_IA64) { 1627 // 1628 // Update PEI_CORE address 1629 // 1630 // 1631 // Set the uncached attribute bit in the physical address 1632 // 1633 PeiCorePhysicalAddress |= 0x8000000000000000ULL; 1634 1635 // 1636 // Check if address is aligned on a 16 byte boundary 1637 // 1638 if (PeiCorePhysicalAddress & 0xF) { 1639 Error (NULL, 0, 3000, "Invalid", 1640 "PEI_CORE entry point is not aligned on a 16 byte boundary, address specified is %llXh.", 1641 (unsigned long long) PeiCorePhysicalAddress 1642 ); 1643 return EFI_ABORTED; 1644 } 1645 // 1646 // First Get the FIT table address 1647 // 1648 FitAddress = (*(UINT64 *) (FvImage->Eof - IPF_FIT_ADDRESS_OFFSET)) & 0xFFFFFFFF; 1649 1650 FitTablePtr = (FIT_TABLE *) (FvImage->FileImage + (FitAddress - FvInfo->BaseAddress)); 1651 1652 Status = UpdatePeiCoreEntryInFit (FitTablePtr, PeiCorePhysicalAddress); 1653 1654 if (!EFI_ERROR (Status)) { 1655 UpdateFitCheckSum (FitTablePtr); 1656 } 1657 1658 // 1659 // Update SEC_CORE address 1660 // 1661 // 1662 // Set the uncached attribute bit in the physical address 1663 // 1664 SecCorePhysicalAddress |= 0x8000000000000000ULL; 1665 // 1666 // Check if address is aligned on a 16 byte boundary 1667 // 1668 if (SecCorePhysicalAddress & 0xF) { 1669 Error (NULL, 0, 3000, "Invalid", 1670 "SALE_ENTRY entry point is not aligned on a 16 byte boundary, address specified is %llXh.", 1671 (unsigned long long) SecCorePhysicalAddress 1672 ); 1673 return EFI_ABORTED; 1674 } 1675 // 1676 // Update the address 1677 // 1678 SecCoreEntryAddressPtr = (EFI_PHYSICAL_ADDRESS *) ((UINTN) FvImage->Eof - IPF_SALE_ENTRY_ADDRESS_OFFSET); 1679 *SecCoreEntryAddressPtr = SecCorePhysicalAddress; 1680 1681 } else if (MachineType == EFI_IMAGE_MACHINE_IA32 || MachineType == EFI_IMAGE_MACHINE_X64) { 1682 // 1683 // Get the location to update 1684 // 1685 Ia32ResetAddressPtr = (UINT32 *) ((UINTN) FvImage->Eof - IA32_PEI_CORE_ENTRY_OFFSET); 1686 1687 // 1688 // Write lower 32 bits of physical address for Pei Core entry 1689 // 1690 *Ia32ResetAddressPtr = (UINT32) PeiCorePhysicalAddress; 1691 1692 // 1693 // Write SecCore Entry point relative address into the jmp instruction in reset vector. 1694 // 1695 Ia32ResetAddressPtr = (UINT32 *) ((UINTN) FvImage->Eof - IA32_SEC_CORE_ENTRY_OFFSET); 1696 1697 Ia32SecEntryOffset = (INT32) (SecCorePhysicalAddress - (FV_IMAGES_TOP_ADDRESS - IA32_SEC_CORE_ENTRY_OFFSET + 2)); 1698 if (Ia32SecEntryOffset <= -65536) { 1699 Error (NULL, 0, 3000, "Invalid", "The SEC EXE file size is too large, it must be less than 64K."); 1700 return STATUS_ERROR; 1701 } 1702 1703 *(UINT16 *) Ia32ResetAddressPtr = (UINT16) Ia32SecEntryOffset; 1704 1705 // 1706 // Update the BFV base address 1707 // 1708 Ia32ResetAddressPtr = (UINT32 *) ((UINTN) FvImage->Eof - 4); 1709 *Ia32ResetAddressPtr = (UINT32) (FvInfo->BaseAddress); 1710 DebugMsg (NULL, 0, 9, "update BFV base address in the top FV image", "BFV base address = 0x%llX.", (unsigned long long) FvInfo->BaseAddress); 1711 1712 // 1713 // Update the Startup AP in the FVH header block ZeroVector region. 1714 // 1715 BytePointer = (UINT8 *) ((UINTN) FvImage->FileImage); 1716 if (FvInfo->Size <= 0x10000) { 1717 BytePointer2 = m64kRecoveryStartupApDataArray; 1718 } else if (FvInfo->Size <= 0x20000) { 1719 BytePointer2 = m128kRecoveryStartupApDataArray; 1720 } else { 1721 BytePointer2 = m128kRecoveryStartupApDataArray; 1722 // 1723 // Find the position to place Ap reset vector, the offset 1724 // between the position and the end of Fvrecovery.fv file 1725 // should not exceed 128kB to prevent Ap reset vector from 1726 // outside legacy E and F segment 1727 // 1728 Status = FindApResetVectorPosition (FvImage, &BytePointer); 1729 if (EFI_ERROR (Status)) { 1730 Error (NULL, 0, 3000, "Invalid", "FV image does not have enough space to place AP reset vector. The FV image needs to reserve at least 4KB of unused space."); 1731 return EFI_ABORTED; 1732 } 1733 } 1734 1735 for (Index = 0; Index < SIZEOF_STARTUP_DATA_ARRAY; Index++) { 1736 BytePointer[Index] = BytePointer2[Index]; 1737 } 1738 // 1739 // Calculate the checksum 1740 // 1741 CheckSum = 0x0000; 1742 WordPointer = (UINT16 *) (BytePointer); 1743 for (Index = 0; Index < SIZEOF_STARTUP_DATA_ARRAY / 2; Index++) { 1744 CheckSum = (UINT16) (CheckSum + ((UINT16) *WordPointer)); 1745 WordPointer++; 1746 } 1747 // 1748 // Update the checksum field 1749 // 1750 WordPointer = (UINT16 *) (BytePointer + SIZEOF_STARTUP_DATA_ARRAY - 2); 1751 *WordPointer = (UINT16) (0x10000 - (UINT32) CheckSum); 1752 1753 // 1754 // IpiVector at the 4k aligned address in the top 2 blocks in the PEI FV. 1755 // 1756 IpiVector = (UINT32) (FV_IMAGES_TOP_ADDRESS - ((UINTN) FvImage->Eof - (UINTN) BytePointer)); 1757 DebugMsg (NULL, 0, 9, "Startup AP Vector address", "IpiVector at 0x%X", (unsigned) IpiVector); 1758 if ((IpiVector & 0xFFF) != 0) { 1759 Error (NULL, 0, 3000, "Invalid", "Startup AP Vector address are not 4K aligned, because the FV size is not 4K aligned"); 1760 return EFI_ABORTED; 1761 } 1762 IpiVector = IpiVector >> 12; 1763 IpiVector = IpiVector & 0xFF; 1764 1765 // 1766 // Write IPI Vector at Offset FvrecoveryFileSize - 8 1767 // 1768 Ia32ResetAddressPtr = (UINT32 *) ((UINTN) FvImage->Eof - 8); 1769 *Ia32ResetAddressPtr = IpiVector; 1770 } else if (MachineType == EFI_IMAGE_MACHINE_ARMT) { 1771 // 1772 // Since the ARM reset vector is in the FV Header you really don't need a 1773 // Volume Top File, but if you have one for some reason don't crash... 1774 // 1775 } else if (MachineType == EFI_IMAGE_MACHINE_AARCH64) { 1776 // 1777 // Since the AArch64 reset vector is in the FV Header you really don't need a 1778 // Volume Top File, but if you have one for some reason don't crash... 1779 // 1780 } else { 1781 Error (NULL, 0, 3000, "Invalid", "machine type=0x%X in PEI core.", MachineType); 1782 return EFI_ABORTED; 1783 } 1784 1785 // 1786 // Now update file checksum 1787 // 1788 SavedState = VtfFile->State; 1789 VtfFile->IntegrityCheck.Checksum.File = 0; 1790 VtfFile->State = 0; 1791 if (VtfFile->Attributes & FFS_ATTRIB_CHECKSUM) { 1792 FfsHeaderSize = GetFfsHeaderLength(VtfFile); 1793 VtfFile->IntegrityCheck.Checksum.File = CalculateChecksum8 ( 1794 (UINT8 *) ((UINT8 *)VtfFile + FfsHeaderSize), 1795 GetFfsFileLength (VtfFile) - FfsHeaderSize 1796 ); 1797 } else { 1798 VtfFile->IntegrityCheck.Checksum.File = FFS_FIXED_CHECKSUM; 1799 } 1800 1801 VtfFile->State = SavedState; 1802 1803 return EFI_SUCCESS; 1804 } 1805 1806 1807 EFI_STATUS 1808 UpdateArmResetVectorIfNeeded ( 1809 IN MEMORY_FILE *FvImage, 1810 IN FV_INFO *FvInfo 1811 ) 1812 /*++ 1813 1814 Routine Description: 1815 This parses the FV looking for SEC and patches that address into the 1816 beginning of the FV header. 1817 1818 For ARM32 the reset vector is at 0x00000000 or 0xFFFF0000. 1819 For AArch64 the reset vector is at 0x00000000. 1820 1821 This would commonly map to the first entry in the ROM. 1822 ARM32 Exceptions: 1823 Reset +0 1824 Undefined +4 1825 SWI +8 1826 Prefetch Abort +12 1827 Data Abort +16 1828 IRQ +20 1829 FIQ +24 1830 1831 We support two schemes on ARM. 1832 1) Beginning of the FV is the reset vector 1833 2) Reset vector is data bytes FDF file and that code branches to reset vector 1834 in the beginning of the FV (fixed size offset). 1835 1836 Need to have the jump for the reset vector at location zero. 1837 We also need to store the address or PEI (if it exists). 1838 We stub out a return from interrupt in case the debugger 1839 is using SWI (not done for AArch64, not enough space in struct). 1840 The optional entry to the common exception handler is 1841 to support full featured exception handling from ROM and is currently 1842 not support by this tool. 1843 1844 Arguments: 1845 FvImage Memory file for the FV memory image 1846 FvInfo Information read from INF file. 1847 1848 Returns: 1849 1850 EFI_SUCCESS Function Completed successfully. 1851 EFI_ABORTED Error encountered. 1852 EFI_INVALID_PARAMETER A required parameter was NULL. 1853 EFI_NOT_FOUND PEI Core file not found. 1854 1855 --*/ 1856 { 1857 EFI_FFS_FILE_HEADER *PeiCoreFile; 1858 EFI_FFS_FILE_HEADER *SecCoreFile; 1859 EFI_STATUS Status; 1860 EFI_FILE_SECTION_POINTER Pe32Section; 1861 UINT32 EntryPoint; 1862 UINT32 BaseOfCode; 1863 UINT16 MachineType; 1864 EFI_PHYSICAL_ADDRESS PeiCorePhysicalAddress; 1865 EFI_PHYSICAL_ADDRESS SecCorePhysicalAddress; 1866 INT32 ResetVector[4]; // ARM32: 1867 // 0 - is branch relative to SEC entry point 1868 // 1 - PEI Entry Point 1869 // 2 - movs pc,lr for a SWI handler 1870 // 3 - Place holder for Common Exception Handler 1871 // AArch64: Used as UINT64 ResetVector[2] 1872 // 0 - is branch relative to SEC entry point 1873 // 1 - PEI Entry Point 1874 1875 // 1876 // Verify input parameters 1877 // 1878 if (FvImage == NULL || FvInfo == NULL) { 1879 return EFI_INVALID_PARAMETER; 1880 } 1881 // 1882 // Initialize FV library 1883 // 1884 InitializeFvLib (FvImage->FileImage, FvInfo->Size); 1885 1886 // 1887 // Find the Sec Core 1888 // 1889 Status = GetFileByType (EFI_FV_FILETYPE_SECURITY_CORE, 1, &SecCoreFile); 1890 if (EFI_ERROR (Status) || SecCoreFile == NULL) { 1891 // 1892 // Maybe hardware does SEC job and we only have PEI Core? 1893 // 1894 1895 // 1896 // Find the PEI Core. It may not exist if SEC loads DXE core directly 1897 // 1898 PeiCorePhysicalAddress = 0; 1899 Status = GetFileByType (EFI_FV_FILETYPE_PEI_CORE, 1, &PeiCoreFile); 1900 if (!EFI_ERROR (Status) && PeiCoreFile != NULL) { 1901 // 1902 // PEI Core found, now find PE32 or TE section 1903 // 1904 Status = GetSectionByType (PeiCoreFile, EFI_SECTION_PE32, 1, &Pe32Section); 1905 if (Status == EFI_NOT_FOUND) { 1906 Status = GetSectionByType (PeiCoreFile, EFI_SECTION_TE, 1, &Pe32Section); 1907 } 1908 1909 if (EFI_ERROR (Status)) { 1910 Error (NULL, 0, 3000, "Invalid", "could not find either a PE32 or a TE section in PEI core file!"); 1911 return EFI_ABORTED; 1912 } 1913 1914 Status = GetPe32Info ( 1915 (VOID *) ((UINTN) Pe32Section.Pe32Section + GetSectionHeaderLength(Pe32Section.CommonHeader)), 1916 &EntryPoint, 1917 &BaseOfCode, 1918 &MachineType 1919 ); 1920 1921 if (EFI_ERROR (Status)) { 1922 Error (NULL, 0, 3000, "Invalid", "could not get the PE32 entry point for the PEI core!"); 1923 return EFI_ABORTED; 1924 } 1925 // 1926 // Physical address is FV base + offset of PE32 + offset of the entry point 1927 // 1928 PeiCorePhysicalAddress = FvInfo->BaseAddress; 1929 PeiCorePhysicalAddress += (UINTN) Pe32Section.Pe32Section + GetSectionHeaderLength(Pe32Section.CommonHeader) - (UINTN) FvImage->FileImage; 1930 PeiCorePhysicalAddress += EntryPoint; 1931 DebugMsg (NULL, 0, 9, "PeiCore physical entry point address", "Address = 0x%llX", (unsigned long long) PeiCorePhysicalAddress); 1932 1933 if (MachineType == EFI_IMAGE_MACHINE_ARMT || MachineType == EFI_IMAGE_MACHINE_AARCH64) { 1934 memset (ResetVector, 0, sizeof (ResetVector)); 1935 // Address of PEI Core, if we have one 1936 ResetVector[1] = (UINT32)PeiCorePhysicalAddress; 1937 } 1938 1939 // 1940 // Copy to the beginning of the FV 1941 // 1942 memcpy ((UINT8 *) ((UINTN) FvImage->FileImage), ResetVector, sizeof (ResetVector)); 1943 1944 } 1945 1946 return EFI_SUCCESS; 1947 } 1948 1949 // 1950 // Sec Core found, now find PE32 section 1951 // 1952 Status = GetSectionByType (SecCoreFile, EFI_SECTION_PE32, 1, &Pe32Section); 1953 if (Status == EFI_NOT_FOUND) { 1954 Status = GetSectionByType (SecCoreFile, EFI_SECTION_TE, 1, &Pe32Section); 1955 } 1956 1957 if (EFI_ERROR (Status)) { 1958 Error (NULL, 0, 3000, "Invalid", "could not find a PE32 section in the SEC core file."); 1959 return EFI_ABORTED; 1960 } 1961 1962 Status = GetPe32Info ( 1963 (VOID *) ((UINTN) Pe32Section.Pe32Section + GetSectionHeaderLength(Pe32Section.CommonHeader)), 1964 &EntryPoint, 1965 &BaseOfCode, 1966 &MachineType 1967 ); 1968 if (EFI_ERROR (Status)) { 1969 Error (NULL, 0, 3000, "Invalid", "could not get the PE32 entry point for the SEC core."); 1970 return EFI_ABORTED; 1971 } 1972 1973 if ((MachineType != EFI_IMAGE_MACHINE_ARMT) && (MachineType != EFI_IMAGE_MACHINE_AARCH64)) { 1974 // 1975 // If SEC is not ARM we have nothing to do 1976 // 1977 return EFI_SUCCESS; 1978 } 1979 1980 // 1981 // Physical address is FV base + offset of PE32 + offset of the entry point 1982 // 1983 SecCorePhysicalAddress = FvInfo->BaseAddress; 1984 SecCorePhysicalAddress += (UINTN) Pe32Section.Pe32Section + GetSectionHeaderLength(Pe32Section.CommonHeader) - (UINTN) FvImage->FileImage; 1985 SecCorePhysicalAddress += EntryPoint; 1986 DebugMsg (NULL, 0, 9, "SecCore physical entry point address", "Address = 0x%llX", (unsigned long long) SecCorePhysicalAddress); 1987 1988 // 1989 // Find the PEI Core. It may not exist if SEC loads DXE core directly 1990 // 1991 PeiCorePhysicalAddress = 0; 1992 Status = GetFileByType (EFI_FV_FILETYPE_PEI_CORE, 1, &PeiCoreFile); 1993 if (!EFI_ERROR (Status) && PeiCoreFile != NULL) { 1994 // 1995 // PEI Core found, now find PE32 or TE section 1996 // 1997 Status = GetSectionByType (PeiCoreFile, EFI_SECTION_PE32, 1, &Pe32Section); 1998 if (Status == EFI_NOT_FOUND) { 1999 Status = GetSectionByType (PeiCoreFile, EFI_SECTION_TE, 1, &Pe32Section); 2000 } 2001 2002 if (EFI_ERROR (Status)) { 2003 Error (NULL, 0, 3000, "Invalid", "could not find either a PE32 or a TE section in PEI core file!"); 2004 return EFI_ABORTED; 2005 } 2006 2007 Status = GetPe32Info ( 2008 (VOID *) ((UINTN) Pe32Section.Pe32Section + GetSectionHeaderLength(Pe32Section.CommonHeader)), 2009 &EntryPoint, 2010 &BaseOfCode, 2011 &MachineType 2012 ); 2013 2014 if (EFI_ERROR (Status)) { 2015 Error (NULL, 0, 3000, "Invalid", "could not get the PE32 entry point for the PEI core!"); 2016 return EFI_ABORTED; 2017 } 2018 // 2019 // Physical address is FV base + offset of PE32 + offset of the entry point 2020 // 2021 PeiCorePhysicalAddress = FvInfo->BaseAddress; 2022 PeiCorePhysicalAddress += (UINTN) Pe32Section.Pe32Section + GetSectionHeaderLength(Pe32Section.CommonHeader) - (UINTN) FvImage->FileImage; 2023 PeiCorePhysicalAddress += EntryPoint; 2024 DebugMsg (NULL, 0, 9, "PeiCore physical entry point address", "Address = 0x%llX", (unsigned long long) PeiCorePhysicalAddress); 2025 } 2026 2027 if (MachineType == EFI_IMAGE_MACHINE_ARMT) { 2028 // B SecEntryPoint - signed_immed_24 part +/-32MB offset 2029 // on ARM, the PC is always 8 ahead, so we're not really jumping from the base address, but from base address + 8 2030 ResetVector[0] = (INT32)(SecCorePhysicalAddress - FvInfo->BaseAddress - 8) >> 2; 2031 2032 if (ResetVector[0] > 0x00FFFFFF) { 2033 Error (NULL, 0, 3000, "Invalid", "SEC Entry point must be within 32MB of the start of the FV"); 2034 return EFI_ABORTED; 2035 } 2036 2037 // Add opcode for an uncondional branch with no link. AKA B SecEntryPoint 2038 ResetVector[0] |= 0xEB000000; 2039 2040 2041 // Address of PEI Core, if we have one 2042 ResetVector[1] = (UINT32)PeiCorePhysicalAddress; 2043 2044 // SWI handler movs pc,lr. Just in case a debugger uses SWI 2045 ResetVector[2] = 0xE1B0F07E; 2046 2047 // Place holder to support a common interrupt handler from ROM. 2048 // Currently not suppprted. For this to be used the reset vector would not be in this FV 2049 // and the exception vectors would be hard coded in the ROM and just through this address 2050 // to find a common handler in the a module in the FV. 2051 ResetVector[3] = 0; 2052 } else if (MachineType == EFI_IMAGE_MACHINE_AARCH64) { 2053 2054 /* NOTE: 2055 ARMT above has an entry in ResetVector[2] for SWI. The way we are using the ResetVector 2056 array at the moment, for AArch64, does not allow us space for this as the header only 2057 allows for a fixed amount of bytes at the start. If we are sure that UEFI will live 2058 within the first 4GB of addressable RAM we could potensioally adopt the same ResetVector 2059 layout as above. But for the moment we replace the four 32bit vectors with two 64bit 2060 vectors in the same area of the Image heasder. This allows UEFI to start from a 64bit 2061 base. 2062 */ 2063 2064 ((UINT64*)ResetVector)[0] = (UINT64)(SecCorePhysicalAddress - FvInfo->BaseAddress) >> 2; 2065 2066 // B SecEntryPoint - signed_immed_26 part +/-128MB offset 2067 if ( ((UINT64*)ResetVector)[0] > 0x03FFFFFF) { 2068 Error (NULL, 0, 3000, "Invalid", "SEC Entry point must be within 128MB of the start of the FV"); 2069 return EFI_ABORTED; 2070 } 2071 // Add opcode for an uncondional branch with no link. AKA B SecEntryPoint 2072 ((UINT64*)ResetVector)[0] |= 0x14000000; 2073 2074 // Address of PEI Core, if we have one 2075 ((UINT64*)ResetVector)[1] = (UINT64)PeiCorePhysicalAddress; 2076 2077 } else { 2078 Error (NULL, 0, 3000, "Invalid", "Unknown ARM machine type"); 2079 return EFI_ABORTED; 2080 } 2081 2082 // 2083 // Copy to the beginning of the FV 2084 // 2085 memcpy ((UINT8 *) ((UINTN) FvImage->FileImage), ResetVector, sizeof (ResetVector)); 2086 2087 DebugMsg (NULL, 0, 9, "Update Reset vector in FV Header", NULL); 2088 2089 return EFI_SUCCESS; 2090 } 2091 2092 EFI_STATUS 2093 GetPe32Info ( 2094 IN UINT8 *Pe32, 2095 OUT UINT32 *EntryPoint, 2096 OUT UINT32 *BaseOfCode, 2097 OUT UINT16 *MachineType 2098 ) 2099 /*++ 2100 2101 Routine Description: 2102 2103 Retrieves the PE32 entry point offset and machine type from PE image or TeImage. 2104 See EfiImage.h for machine types. The entry point offset is from the beginning 2105 of the PE32 buffer passed in. 2106 2107 Arguments: 2108 2109 Pe32 Beginning of the PE32. 2110 EntryPoint Offset from the beginning of the PE32 to the image entry point. 2111 BaseOfCode Base address of code. 2112 MachineType Magic number for the machine type. 2113 2114 Returns: 2115 2116 EFI_SUCCESS Function completed successfully. 2117 EFI_ABORTED Error encountered. 2118 EFI_INVALID_PARAMETER A required parameter was NULL. 2119 EFI_UNSUPPORTED The operation is unsupported. 2120 2121 --*/ 2122 { 2123 EFI_IMAGE_DOS_HEADER *DosHeader; 2124 EFI_IMAGE_OPTIONAL_HEADER_UNION *ImgHdr; 2125 EFI_TE_IMAGE_HEADER *TeHeader; 2126 2127 // 2128 // Verify input parameters 2129 // 2130 if (Pe32 == NULL) { 2131 return EFI_INVALID_PARAMETER; 2132 } 2133 2134 // 2135 // First check whether it is one TE Image. 2136 // 2137 TeHeader = (EFI_TE_IMAGE_HEADER *) Pe32; 2138 if (TeHeader->Signature == EFI_TE_IMAGE_HEADER_SIGNATURE) { 2139 // 2140 // By TeImage Header to get output 2141 // 2142 *EntryPoint = TeHeader->AddressOfEntryPoint + sizeof (EFI_TE_IMAGE_HEADER) - TeHeader->StrippedSize; 2143 *BaseOfCode = TeHeader->BaseOfCode + sizeof (EFI_TE_IMAGE_HEADER) - TeHeader->StrippedSize; 2144 *MachineType = TeHeader->Machine; 2145 } else { 2146 2147 // 2148 // Then check whether 2149 // First is the DOS header 2150 // 2151 DosHeader = (EFI_IMAGE_DOS_HEADER *) Pe32; 2152 2153 // 2154 // Verify DOS header is expected 2155 // 2156 if (DosHeader->e_magic != EFI_IMAGE_DOS_SIGNATURE) { 2157 Error (NULL, 0, 3000, "Invalid", "Unknown magic number in the DOS header, 0x%04X.", DosHeader->e_magic); 2158 return EFI_UNSUPPORTED; 2159 } 2160 // 2161 // Immediately following is the NT header. 2162 // 2163 ImgHdr = (EFI_IMAGE_OPTIONAL_HEADER_UNION *) ((UINTN) Pe32 + DosHeader->e_lfanew); 2164 2165 // 2166 // Verify NT header is expected 2167 // 2168 if (ImgHdr->Pe32.Signature != EFI_IMAGE_NT_SIGNATURE) { 2169 Error (NULL, 0, 3000, "Invalid", "Unrecognized image signature 0x%08X.", (unsigned) ImgHdr->Pe32.Signature); 2170 return EFI_UNSUPPORTED; 2171 } 2172 // 2173 // Get output 2174 // 2175 *EntryPoint = ImgHdr->Pe32.OptionalHeader.AddressOfEntryPoint; 2176 *BaseOfCode = ImgHdr->Pe32.OptionalHeader.BaseOfCode; 2177 *MachineType = ImgHdr->Pe32.FileHeader.Machine; 2178 } 2179 2180 // 2181 // Verify machine type is supported 2182 // 2183 if ((*MachineType != EFI_IMAGE_MACHINE_IA32) && (*MachineType != EFI_IMAGE_MACHINE_IA64) && (*MachineType != EFI_IMAGE_MACHINE_X64) && (*MachineType != EFI_IMAGE_MACHINE_EBC) && 2184 (*MachineType != EFI_IMAGE_MACHINE_ARMT) && (*MachineType != EFI_IMAGE_MACHINE_AARCH64)) { 2185 Error (NULL, 0, 3000, "Invalid", "Unrecognized machine type in the PE32 file."); 2186 return EFI_UNSUPPORTED; 2187 } 2188 2189 return EFI_SUCCESS; 2190 } 2191 2192 EFI_STATUS 2193 GenerateFvImage ( 2194 IN CHAR8 *InfFileImage, 2195 IN UINTN InfFileSize, 2196 IN CHAR8 *FvFileName, 2197 IN CHAR8 *MapFileName 2198 ) 2199 /*++ 2200 2201 Routine Description: 2202 2203 This is the main function which will be called from application. 2204 2205 Arguments: 2206 2207 InfFileImage Buffer containing the INF file contents. 2208 InfFileSize Size of the contents of the InfFileImage buffer. 2209 FvFileName Requested name for the FV file. 2210 MapFileName Fv map file to log fv driver information. 2211 2212 Returns: 2213 2214 EFI_SUCCESS Function completed successfully. 2215 EFI_OUT_OF_RESOURCES Could not allocate required resources. 2216 EFI_ABORTED Error encountered. 2217 EFI_INVALID_PARAMETER A required parameter was NULL. 2218 2219 --*/ 2220 { 2221 EFI_STATUS Status; 2222 MEMORY_FILE InfMemoryFile; 2223 MEMORY_FILE FvImageMemoryFile; 2224 UINTN Index; 2225 EFI_FIRMWARE_VOLUME_HEADER *FvHeader; 2226 EFI_FFS_FILE_HEADER *VtfFileImage; 2227 UINT8 *FvBufferHeader; // to make sure fvimage header 8 type alignment. 2228 UINT8 *FvImage; 2229 UINTN FvImageSize; 2230 FILE *FvFile; 2231 CHAR8 FvMapName [MAX_LONG_FILE_PATH]; 2232 FILE *FvMapFile; 2233 EFI_FIRMWARE_VOLUME_EXT_HEADER *FvExtHeader; 2234 FILE *FvExtHeaderFile; 2235 UINTN FileSize; 2236 CHAR8 FvReportName[MAX_LONG_FILE_PATH]; 2237 FILE *FvReportFile; 2238 2239 FvBufferHeader = NULL; 2240 FvFile = NULL; 2241 FvMapFile = NULL; 2242 FvReportFile = NULL; 2243 2244 if (InfFileImage != NULL) { 2245 // 2246 // Initialize file structures 2247 // 2248 InfMemoryFile.FileImage = InfFileImage; 2249 InfMemoryFile.CurrentFilePointer = InfFileImage; 2250 InfMemoryFile.Eof = InfFileImage + InfFileSize; 2251 2252 // 2253 // Parse the FV inf file for header information 2254 // 2255 Status = ParseFvInf (&InfMemoryFile, &mFvDataInfo); 2256 if (EFI_ERROR (Status)) { 2257 Error (NULL, 0, 0003, "Error parsing file", "the input FV INF file."); 2258 return Status; 2259 } 2260 } 2261 2262 // 2263 // Update the file name return values 2264 // 2265 if (FvFileName == NULL && mFvDataInfo.FvName[0] != '\0') { 2266 FvFileName = mFvDataInfo.FvName; 2267 } 2268 2269 if (FvFileName == NULL) { 2270 Error (NULL, 0, 1001, "Missing option", "Output file name"); 2271 return EFI_ABORTED; 2272 } 2273 2274 if (mFvDataInfo.FvBlocks[0].Length == 0) { 2275 Error (NULL, 0, 1001, "Missing required argument", "Block Size"); 2276 return EFI_ABORTED; 2277 } 2278 2279 // 2280 // Debug message Fv File System Guid 2281 // 2282 if (mFvDataInfo.FvFileSystemGuidSet) { 2283 DebugMsg (NULL, 0, 9, "FV File System Guid", "%08X-%04X-%04X-%02X%02X-%02X%02X%02X%02X%02X%02X", 2284 (unsigned) mFvDataInfo.FvFileSystemGuid.Data1, 2285 mFvDataInfo.FvFileSystemGuid.Data2, 2286 mFvDataInfo.FvFileSystemGuid.Data3, 2287 mFvDataInfo.FvFileSystemGuid.Data4[0], 2288 mFvDataInfo.FvFileSystemGuid.Data4[1], 2289 mFvDataInfo.FvFileSystemGuid.Data4[2], 2290 mFvDataInfo.FvFileSystemGuid.Data4[3], 2291 mFvDataInfo.FvFileSystemGuid.Data4[4], 2292 mFvDataInfo.FvFileSystemGuid.Data4[5], 2293 mFvDataInfo.FvFileSystemGuid.Data4[6], 2294 mFvDataInfo.FvFileSystemGuid.Data4[7]); 2295 } 2296 2297 // 2298 // Add PI FV extension header 2299 // 2300 FvExtHeader = NULL; 2301 FvExtHeaderFile = NULL; 2302 if (mFvDataInfo.FvExtHeaderFile[0] != 0) { 2303 // 2304 // Open the FV Extension Header file 2305 // 2306 FvExtHeaderFile = fopen (LongFilePath (mFvDataInfo.FvExtHeaderFile), "rb"); 2307 2308 // 2309 // Get the file size 2310 // 2311 FileSize = _filelength (fileno (FvExtHeaderFile)); 2312 2313 // 2314 // Allocate a buffer for the FV Extension Header 2315 // 2316 FvExtHeader = malloc(FileSize); 2317 if (FvExtHeader == NULL) { 2318 fclose (FvExtHeaderFile); 2319 return EFI_OUT_OF_RESOURCES; 2320 } 2321 2322 // 2323 // Read the FV Extension Header 2324 // 2325 fread (FvExtHeader, sizeof (UINT8), FileSize, FvExtHeaderFile); 2326 fclose (FvExtHeaderFile); 2327 2328 // 2329 // See if there is an override for the FV Name GUID 2330 // 2331 if (mFvDataInfo.FvNameGuidSet) { 2332 memcpy (&FvExtHeader->FvName, &mFvDataInfo.FvNameGuid, sizeof (EFI_GUID)); 2333 } 2334 memcpy (&mFvDataInfo.FvNameGuid, &FvExtHeader->FvName, sizeof (EFI_GUID)); 2335 mFvDataInfo.FvNameGuidSet = TRUE; 2336 } else if (mFvDataInfo.FvNameGuidSet) { 2337 // 2338 // Allocate a buffer for the FV Extension Header 2339 // 2340 FvExtHeader = malloc(sizeof (EFI_FIRMWARE_VOLUME_EXT_HEADER)); 2341 if (FvExtHeader == NULL) { 2342 return EFI_OUT_OF_RESOURCES; 2343 } 2344 memcpy (&FvExtHeader->FvName, &mFvDataInfo.FvNameGuid, sizeof (EFI_GUID)); 2345 FvExtHeader->ExtHeaderSize = sizeof (EFI_FIRMWARE_VOLUME_EXT_HEADER); 2346 } 2347 2348 // 2349 // Debug message Fv Name Guid 2350 // 2351 if (mFvDataInfo.FvNameGuidSet) { 2352 DebugMsg (NULL, 0, 9, "FV Name Guid", "%08X-%04X-%04X-%02X%02X-%02X%02X%02X%02X%02X%02X", 2353 (unsigned) mFvDataInfo.FvNameGuid.Data1, 2354 mFvDataInfo.FvNameGuid.Data2, 2355 mFvDataInfo.FvNameGuid.Data3, 2356 mFvDataInfo.FvNameGuid.Data4[0], 2357 mFvDataInfo.FvNameGuid.Data4[1], 2358 mFvDataInfo.FvNameGuid.Data4[2], 2359 mFvDataInfo.FvNameGuid.Data4[3], 2360 mFvDataInfo.FvNameGuid.Data4[4], 2361 mFvDataInfo.FvNameGuid.Data4[5], 2362 mFvDataInfo.FvNameGuid.Data4[6], 2363 mFvDataInfo.FvNameGuid.Data4[7]); 2364 } 2365 2366 if (CompareGuid (&mFvDataInfo.FvFileSystemGuid, &mEfiFirmwareFileSystem2Guid) == 0 || 2367 CompareGuid (&mFvDataInfo.FvFileSystemGuid, &mEfiFirmwareFileSystem3Guid) == 0) { 2368 mFvDataInfo.IsPiFvImage = TRUE; 2369 } 2370 2371 // 2372 // FvMap file to log the function address of all modules in one Fvimage 2373 // 2374 if (MapFileName != NULL) { 2375 strcpy (FvMapName, MapFileName); 2376 } else { 2377 strcpy (FvMapName, FvFileName); 2378 strcat (FvMapName, ".map"); 2379 } 2380 VerboseMsg ("FV Map file name is %s", FvMapName); 2381 2382 // 2383 // FvReport file to log the FV information in one Fvimage 2384 // 2385 strcpy (FvReportName, FvFileName); 2386 strcat (FvReportName, ".txt"); 2387 2388 // 2389 // Calculate the FV size and Update Fv Size based on the actual FFS files. 2390 // And Update mFvDataInfo data. 2391 // 2392 Status = CalculateFvSize (&mFvDataInfo); 2393 if (EFI_ERROR (Status)) { 2394 return Status; 2395 } 2396 VerboseMsg ("the generated FV image size is %u bytes", (unsigned) mFvDataInfo.Size); 2397 2398 // 2399 // support fv image and empty fv image 2400 // 2401 FvImageSize = mFvDataInfo.Size; 2402 2403 // 2404 // Allocate the FV, assure FvImage Header 8 byte alignment 2405 // 2406 FvBufferHeader = malloc (FvImageSize + sizeof (UINT64)); 2407 if (FvBufferHeader == NULL) { 2408 return EFI_OUT_OF_RESOURCES; 2409 } 2410 FvImage = (UINT8 *) (((UINTN) FvBufferHeader + 7) & ~7); 2411 2412 // 2413 // Initialize the FV to the erase polarity 2414 // 2415 if (mFvDataInfo.FvAttributes == 0) { 2416 // 2417 // Set Default Fv Attribute 2418 // 2419 mFvDataInfo.FvAttributes = FV_DEFAULT_ATTRIBUTE; 2420 } 2421 if (mFvDataInfo.FvAttributes & EFI_FVB2_ERASE_POLARITY) { 2422 memset (FvImage, -1, FvImageSize); 2423 } else { 2424 memset (FvImage, 0, FvImageSize); 2425 } 2426 2427 // 2428 // Initialize FV header 2429 // 2430 FvHeader = (EFI_FIRMWARE_VOLUME_HEADER *) FvImage; 2431 2432 // 2433 // Initialize the zero vector to all zeros. 2434 // 2435 memset (FvHeader->ZeroVector, 0, 16); 2436 2437 // 2438 // Copy the Fv file system GUID 2439 // 2440 memcpy (&FvHeader->FileSystemGuid, &mFvDataInfo.FvFileSystemGuid, sizeof (EFI_GUID)); 2441 2442 FvHeader->FvLength = FvImageSize; 2443 FvHeader->Signature = EFI_FVH_SIGNATURE; 2444 FvHeader->Attributes = mFvDataInfo.FvAttributes; 2445 FvHeader->Revision = EFI_FVH_REVISION; 2446 FvHeader->ExtHeaderOffset = 0; 2447 FvHeader->Reserved[0] = 0; 2448 2449 // 2450 // Copy firmware block map 2451 // 2452 for (Index = 0; mFvDataInfo.FvBlocks[Index].Length != 0; Index++) { 2453 FvHeader->BlockMap[Index].NumBlocks = mFvDataInfo.FvBlocks[Index].NumBlocks; 2454 FvHeader->BlockMap[Index].Length = mFvDataInfo.FvBlocks[Index].Length; 2455 } 2456 2457 // 2458 // Add block map terminator 2459 // 2460 FvHeader->BlockMap[Index].NumBlocks = 0; 2461 FvHeader->BlockMap[Index].Length = 0; 2462 2463 // 2464 // Complete the header 2465 // 2466 FvHeader->HeaderLength = (UINT16) (((UINTN) &(FvHeader->BlockMap[Index + 1])) - (UINTN) FvImage); 2467 FvHeader->Checksum = 0; 2468 FvHeader->Checksum = CalculateChecksum16 ((UINT16 *) FvHeader, FvHeader->HeaderLength / sizeof (UINT16)); 2469 2470 // 2471 // If there is no FFS file, generate one empty FV 2472 // 2473 if (mFvDataInfo.FvFiles[0][0] == 0 && !mFvDataInfo.FvNameGuidSet) { 2474 goto WriteFile; 2475 } 2476 2477 // 2478 // Initialize our "file" view of the buffer 2479 // 2480 FvImageMemoryFile.FileImage = (CHAR8 *)FvImage; 2481 FvImageMemoryFile.CurrentFilePointer = (CHAR8 *)FvImage + FvHeader->HeaderLength; 2482 FvImageMemoryFile.Eof = (CHAR8 *)FvImage + FvImageSize; 2483 2484 // 2485 // Initialize the FV library. 2486 // 2487 InitializeFvLib (FvImageMemoryFile.FileImage, FvImageSize); 2488 2489 // 2490 // Initialize the VTF file address. 2491 // 2492 VtfFileImage = (EFI_FFS_FILE_HEADER *) FvImageMemoryFile.Eof; 2493 2494 // 2495 // Open FvMap file 2496 // 2497 FvMapFile = fopen (LongFilePath (FvMapName), "w"); 2498 if (FvMapFile == NULL) { 2499 Error (NULL, 0, 0001, "Error opening file", FvMapName); 2500 return EFI_ABORTED; 2501 } 2502 2503 // 2504 // Open FvReport file 2505 // 2506 FvReportFile = fopen (LongFilePath (FvReportName), "w"); 2507 if (FvReportFile == NULL) { 2508 Error (NULL, 0, 0001, "Error opening file", FvReportName); 2509 return EFI_ABORTED; 2510 } 2511 // 2512 // record FV size information into FvMap file. 2513 // 2514 if (mFvTotalSize != 0) { 2515 fprintf (FvMapFile, EFI_FV_TOTAL_SIZE_STRING); 2516 fprintf (FvMapFile, " = 0x%x\n", (unsigned) mFvTotalSize); 2517 } 2518 if (mFvTakenSize != 0) { 2519 fprintf (FvMapFile, EFI_FV_TAKEN_SIZE_STRING); 2520 fprintf (FvMapFile, " = 0x%x\n", (unsigned) mFvTakenSize); 2521 } 2522 if (mFvTotalSize != 0 && mFvTakenSize != 0) { 2523 fprintf (FvMapFile, EFI_FV_SPACE_SIZE_STRING); 2524 fprintf (FvMapFile, " = 0x%x\n\n", (unsigned) (mFvTotalSize - mFvTakenSize)); 2525 } 2526 2527 // 2528 // record FV size information to FvReportFile. 2529 // 2530 fprintf (FvReportFile, "%s = 0x%x\n", EFI_FV_TOTAL_SIZE_STRING, (unsigned) mFvTotalSize); 2531 fprintf (FvReportFile, "%s = 0x%x\n", EFI_FV_TAKEN_SIZE_STRING, (unsigned) mFvTakenSize); 2532 2533 // 2534 // Add PI FV extension header 2535 // 2536 if (FvExtHeader != NULL) { 2537 // 2538 // Add FV Extended Header contents to the FV as a PAD file 2539 // 2540 AddPadFile (&FvImageMemoryFile, 4, VtfFileImage, FvExtHeader, 0); 2541 2542 // 2543 // Fv Extension header change update Fv Header Check sum 2544 // 2545 FvHeader->Checksum = 0; 2546 FvHeader->Checksum = CalculateChecksum16 ((UINT16 *) FvHeader, FvHeader->HeaderLength / sizeof (UINT16)); 2547 } 2548 2549 // 2550 // Add files to FV 2551 // 2552 for (Index = 0; mFvDataInfo.FvFiles[Index][0] != 0; Index++) { 2553 // 2554 // Add the file 2555 // 2556 Status = AddFile (&FvImageMemoryFile, &mFvDataInfo, Index, &VtfFileImage, FvMapFile, FvReportFile); 2557 2558 // 2559 // Exit if error detected while adding the file 2560 // 2561 if (EFI_ERROR (Status)) { 2562 goto Finish; 2563 } 2564 } 2565 2566 // 2567 // If there is a VTF file, some special actions need to occur. 2568 // 2569 if ((UINTN) VtfFileImage != (UINTN) FvImageMemoryFile.Eof) { 2570 // 2571 // Pad from the end of the last file to the beginning of the VTF file. 2572 // If the left space is less than sizeof (EFI_FFS_FILE_HEADER)? 2573 // 2574 Status = PadFvImage (&FvImageMemoryFile, VtfFileImage); 2575 if (EFI_ERROR (Status)) { 2576 Error (NULL, 0, 4002, "Resource", "FV space is full, cannot add pad file between the last file and the VTF file."); 2577 goto Finish; 2578 } 2579 if (!mArm) { 2580 // 2581 // Update reset vector (SALE_ENTRY for IPF) 2582 // Now for IA32 and IA64 platform, the fv which has bsf file must have the 2583 // EndAddress of 0xFFFFFFFF. Thus, only this type fv needs to update the 2584 // reset vector. If the PEI Core is found, the VTF file will probably get 2585 // corrupted by updating the entry point. 2586 // 2587 if ((mFvDataInfo.BaseAddress + mFvDataInfo.Size) == FV_IMAGES_TOP_ADDRESS) { 2588 Status = UpdateResetVector (&FvImageMemoryFile, &mFvDataInfo, VtfFileImage); 2589 if (EFI_ERROR(Status)) { 2590 Error (NULL, 0, 3000, "Invalid", "Could not update the reset vector."); 2591 goto Finish; 2592 } 2593 DebugMsg (NULL, 0, 9, "Update Reset vector in VTF file", NULL); 2594 } 2595 } 2596 } 2597 2598 if (mArm) { 2599 Status = UpdateArmResetVectorIfNeeded (&FvImageMemoryFile, &mFvDataInfo); 2600 if (EFI_ERROR (Status)) { 2601 Error (NULL, 0, 3000, "Invalid", "Could not update the reset vector."); 2602 goto Finish; 2603 } 2604 2605 // 2606 // Update Checksum for FvHeader 2607 // 2608 FvHeader->Checksum = 0; 2609 FvHeader->Checksum = CalculateChecksum16 ((UINT16 *) FvHeader, FvHeader->HeaderLength / sizeof (UINT16)); 2610 } 2611 2612 // 2613 // Update FV Alignment attribute to the largest alignment of all the FFS files in the FV 2614 // 2615 if (((FvHeader->Attributes & EFI_FVB2_WEAK_ALIGNMENT) != EFI_FVB2_WEAK_ALIGNMENT) && 2616 (((FvHeader->Attributes & EFI_FVB2_ALIGNMENT) >> 16)) < MaxFfsAlignment) { 2617 FvHeader->Attributes = ((MaxFfsAlignment << 16) | (FvHeader->Attributes & 0xFFFF)); 2618 // 2619 // Update Checksum for FvHeader 2620 // 2621 FvHeader->Checksum = 0; 2622 FvHeader->Checksum = CalculateChecksum16 ((UINT16 *) FvHeader, FvHeader->HeaderLength / sizeof (UINT16)); 2623 } 2624 2625 // 2626 // If there are large FFS in FV, the file system GUID should set to system 3 GUID. 2627 // 2628 if (mIsLargeFfs && CompareGuid (&FvHeader->FileSystemGuid, &mEfiFirmwareFileSystem2Guid) == 0) { 2629 memcpy (&FvHeader->FileSystemGuid, &mEfiFirmwareFileSystem3Guid, sizeof (EFI_GUID)); 2630 FvHeader->Checksum = 0; 2631 FvHeader->Checksum = CalculateChecksum16 ((UINT16 *) FvHeader, FvHeader->HeaderLength / sizeof (UINT16)); 2632 } 2633 2634 WriteFile: 2635 // 2636 // Write fv file 2637 // 2638 FvFile = fopen (LongFilePath (FvFileName), "wb"); 2639 if (FvFile == NULL) { 2640 Error (NULL, 0, 0001, "Error opening file", FvFileName); 2641 Status = EFI_ABORTED; 2642 goto Finish; 2643 } 2644 2645 if (fwrite (FvImage, 1, FvImageSize, FvFile) != FvImageSize) { 2646 Error (NULL, 0, 0002, "Error writing file", FvFileName); 2647 Status = EFI_ABORTED; 2648 goto Finish; 2649 } 2650 2651 Finish: 2652 if (FvBufferHeader != NULL) { 2653 free (FvBufferHeader); 2654 } 2655 2656 if (FvExtHeader != NULL) { 2657 free (FvExtHeader); 2658 } 2659 2660 if (FvFile != NULL) { 2661 fflush (FvFile); 2662 fclose (FvFile); 2663 } 2664 2665 if (FvMapFile != NULL) { 2666 fflush (FvMapFile); 2667 fclose (FvMapFile); 2668 } 2669 2670 if (FvReportFile != NULL) { 2671 fflush (FvReportFile); 2672 fclose (FvReportFile); 2673 } 2674 return Status; 2675 } 2676 2677 EFI_STATUS 2678 UpdatePeiCoreEntryInFit ( 2679 IN FIT_TABLE *FitTablePtr, 2680 IN UINT64 PeiCorePhysicalAddress 2681 ) 2682 /*++ 2683 2684 Routine Description: 2685 2686 This function is used to update the Pei Core address in FIT, this can be used by Sec core to pass control from 2687 Sec to Pei Core 2688 2689 Arguments: 2690 2691 FitTablePtr - The pointer of FIT_TABLE. 2692 PeiCorePhysicalAddress - The address of Pei Core entry. 2693 2694 Returns: 2695 2696 EFI_SUCCESS - The PEI_CORE FIT entry was updated successfully. 2697 EFI_NOT_FOUND - Not found the PEI_CORE FIT entry. 2698 2699 --*/ 2700 { 2701 FIT_TABLE *TmpFitPtr; 2702 UINTN Index; 2703 UINTN NumFitComponents; 2704 2705 TmpFitPtr = FitTablePtr; 2706 NumFitComponents = TmpFitPtr->CompSize; 2707 2708 for (Index = 0; Index < NumFitComponents; Index++) { 2709 if ((TmpFitPtr->CvAndType & FIT_TYPE_MASK) == COMP_TYPE_FIT_PEICORE) { 2710 TmpFitPtr->CompAddress = PeiCorePhysicalAddress; 2711 return EFI_SUCCESS; 2712 } 2713 2714 TmpFitPtr++; 2715 } 2716 2717 return EFI_NOT_FOUND; 2718 } 2719 2720 VOID 2721 UpdateFitCheckSum ( 2722 IN FIT_TABLE *FitTablePtr 2723 ) 2724 /*++ 2725 2726 Routine Description: 2727 2728 This function is used to update the checksum for FIT. 2729 2730 2731 Arguments: 2732 2733 FitTablePtr - The pointer of FIT_TABLE. 2734 2735 Returns: 2736 2737 None. 2738 2739 --*/ 2740 { 2741 if ((FitTablePtr->CvAndType & CHECKSUM_BIT_MASK) >> 7) { 2742 FitTablePtr->CheckSum = 0; 2743 FitTablePtr->CheckSum = CalculateChecksum8 ((UINT8 *) FitTablePtr, FitTablePtr->CompSize * 16); 2744 } 2745 } 2746 2747 EFI_STATUS 2748 CalculateFvSize ( 2749 FV_INFO *FvInfoPtr 2750 ) 2751 /*++ 2752 Routine Description: 2753 Calculate the FV size and Update Fv Size based on the actual FFS files. 2754 And Update FvInfo data. 2755 2756 Arguments: 2757 FvInfoPtr - The pointer to FV_INFO structure. 2758 2759 Returns: 2760 EFI_ABORTED - Ffs Image Error 2761 EFI_SUCCESS - Successfully update FvSize 2762 --*/ 2763 { 2764 UINTN CurrentOffset; 2765 UINTN Index; 2766 FILE *fpin; 2767 UINTN FfsFileSize; 2768 UINTN FvExtendHeaderSize; 2769 UINT32 FfsAlignment; 2770 UINT32 FfsHeaderSize; 2771 EFI_FFS_FILE_HEADER FfsHeader; 2772 BOOLEAN VtfFileFlag; 2773 UINTN VtfFileSize; 2774 2775 FvExtendHeaderSize = 0; 2776 VtfFileSize = 0; 2777 VtfFileFlag = FALSE; 2778 fpin = NULL; 2779 Index = 0; 2780 2781 // 2782 // Compute size for easy access later 2783 // 2784 FvInfoPtr->Size = 0; 2785 for (Index = 0; FvInfoPtr->FvBlocks[Index].NumBlocks > 0 && FvInfoPtr->FvBlocks[Index].Length > 0; Index++) { 2786 FvInfoPtr->Size += FvInfoPtr->FvBlocks[Index].NumBlocks * FvInfoPtr->FvBlocks[Index].Length; 2787 } 2788 2789 // 2790 // Calculate the required sizes for all FFS files. 2791 // 2792 CurrentOffset = sizeof (EFI_FIRMWARE_VOLUME_HEADER); 2793 2794 for (Index = 1;; Index ++) { 2795 CurrentOffset += sizeof (EFI_FV_BLOCK_MAP_ENTRY); 2796 if (FvInfoPtr->FvBlocks[Index].NumBlocks == 0 || FvInfoPtr->FvBlocks[Index].Length == 0) { 2797 break; 2798 } 2799 } 2800 2801 // 2802 // Calculate PI extension header 2803 // 2804 if (mFvDataInfo.FvExtHeaderFile[0] != '\0') { 2805 fpin = fopen (LongFilePath (mFvDataInfo.FvExtHeaderFile), "rb"); 2806 if (fpin == NULL) { 2807 Error (NULL, 0, 0001, "Error opening file", mFvDataInfo.FvExtHeaderFile); 2808 return EFI_ABORTED; 2809 } 2810 FvExtendHeaderSize = _filelength (fileno (fpin)); 2811 fclose (fpin); 2812 if (sizeof (EFI_FFS_FILE_HEADER) + FvExtendHeaderSize >= MAX_FFS_SIZE) { 2813 CurrentOffset += sizeof (EFI_FFS_FILE_HEADER2) + FvExtendHeaderSize; 2814 mIsLargeFfs = TRUE; 2815 } else { 2816 CurrentOffset += sizeof (EFI_FFS_FILE_HEADER) + FvExtendHeaderSize; 2817 } 2818 CurrentOffset = (CurrentOffset + 7) & (~7); 2819 } else if (mFvDataInfo.FvNameGuidSet) { 2820 CurrentOffset += sizeof (EFI_FFS_FILE_HEADER) + sizeof (EFI_FIRMWARE_VOLUME_EXT_HEADER); 2821 CurrentOffset = (CurrentOffset + 7) & (~7); 2822 } 2823 2824 // 2825 // Accumlate every FFS file size. 2826 // 2827 for (Index = 0; FvInfoPtr->FvFiles[Index][0] != 0; Index++) { 2828 // 2829 // Open FFS file 2830 // 2831 fpin = NULL; 2832 fpin = fopen (LongFilePath (FvInfoPtr->FvFiles[Index]), "rb"); 2833 if (fpin == NULL) { 2834 Error (NULL, 0, 0001, "Error opening file", FvInfoPtr->FvFiles[Index]); 2835 return EFI_ABORTED; 2836 } 2837 // 2838 // Get the file size 2839 // 2840 FfsFileSize = _filelength (fileno (fpin)); 2841 if (FfsFileSize >= MAX_FFS_SIZE) { 2842 FfsHeaderSize = sizeof(EFI_FFS_FILE_HEADER2); 2843 mIsLargeFfs = TRUE; 2844 } else { 2845 FfsHeaderSize = sizeof(EFI_FFS_FILE_HEADER); 2846 } 2847 // 2848 // Read Ffs File header 2849 // 2850 fread (&FfsHeader, sizeof (UINT8), sizeof (EFI_FFS_FILE_HEADER), fpin); 2851 // 2852 // close file 2853 // 2854 fclose (fpin); 2855 2856 if (FvInfoPtr->IsPiFvImage) { 2857 // 2858 // Check whether this ffs file is vtf file 2859 // 2860 if (IsVtfFile (&FfsHeader)) { 2861 if (VtfFileFlag) { 2862 // 2863 // One Fv image can't have two vtf files. 2864 // 2865 Error (NULL, 0, 3000,"Invalid", "One Fv image can't have two vtf files."); 2866 return EFI_ABORTED; 2867 } 2868 VtfFileFlag = TRUE; 2869 VtfFileSize = FfsFileSize; 2870 continue; 2871 } 2872 2873 // 2874 // Get the alignment of FFS file 2875 // 2876 ReadFfsAlignment (&FfsHeader, &FfsAlignment); 2877 FfsAlignment = 1 << FfsAlignment; 2878 // 2879 // Add Pad file 2880 // 2881 if (((CurrentOffset + FfsHeaderSize) % FfsAlignment) != 0) { 2882 // 2883 // Only EFI_FFS_FILE_HEADER is needed for a pad section. 2884 // 2885 CurrentOffset = (CurrentOffset + FfsHeaderSize + sizeof(EFI_FFS_FILE_HEADER) + FfsAlignment - 1) & ~(FfsAlignment - 1); 2886 CurrentOffset -= FfsHeaderSize; 2887 } 2888 } 2889 2890 // 2891 // Add ffs file size 2892 // 2893 if (FvInfoPtr->SizeofFvFiles[Index] > FfsFileSize) { 2894 CurrentOffset += FvInfoPtr->SizeofFvFiles[Index]; 2895 } else { 2896 CurrentOffset += FfsFileSize; 2897 } 2898 2899 // 2900 // Make next ffs file start at QWord Boundry 2901 // 2902 if (FvInfoPtr->IsPiFvImage) { 2903 CurrentOffset = (CurrentOffset + EFI_FFS_FILE_HEADER_ALIGNMENT - 1) & ~(EFI_FFS_FILE_HEADER_ALIGNMENT - 1); 2904 } 2905 } 2906 CurrentOffset += VtfFileSize; 2907 DebugMsg (NULL, 0, 9, "FvImage size", "The calculated fv image size is 0x%x and the current set fv image size is 0x%x", (unsigned) CurrentOffset, (unsigned) FvInfoPtr->Size); 2908 2909 if (FvInfoPtr->Size == 0) { 2910 // 2911 // Update FvInfo data 2912 // 2913 FvInfoPtr->FvBlocks[0].NumBlocks = CurrentOffset / FvInfoPtr->FvBlocks[0].Length + ((CurrentOffset % FvInfoPtr->FvBlocks[0].Length)?1:0); 2914 FvInfoPtr->Size = FvInfoPtr->FvBlocks[0].NumBlocks * FvInfoPtr->FvBlocks[0].Length; 2915 FvInfoPtr->FvBlocks[1].NumBlocks = 0; 2916 FvInfoPtr->FvBlocks[1].Length = 0; 2917 } else if (FvInfoPtr->Size < CurrentOffset) { 2918 // 2919 // Not invalid 2920 // 2921 Error (NULL, 0, 3000, "Invalid", "the required fv image size 0x%x exceeds the set fv image size 0x%x", (unsigned) CurrentOffset, (unsigned) FvInfoPtr->Size); 2922 return EFI_INVALID_PARAMETER; 2923 } 2924 2925 // 2926 // Set Fv Size Information 2927 // 2928 mFvTotalSize = FvInfoPtr->Size; 2929 mFvTakenSize = CurrentOffset; 2930 2931 return EFI_SUCCESS; 2932 } 2933 2934 EFI_STATUS 2935 FfsRebaseImageRead ( 2936 IN VOID *FileHandle, 2937 IN UINTN FileOffset, 2938 IN OUT UINT32 *ReadSize, 2939 OUT VOID *Buffer 2940 ) 2941 /*++ 2942 2943 Routine Description: 2944 2945 Support routine for the PE/COFF Loader that reads a buffer from a PE/COFF file 2946 2947 Arguments: 2948 2949 FileHandle - The handle to the PE/COFF file 2950 2951 FileOffset - The offset, in bytes, into the file to read 2952 2953 ReadSize - The number of bytes to read from the file starting at FileOffset 2954 2955 Buffer - A pointer to the buffer to read the data into. 2956 2957 Returns: 2958 2959 EFI_SUCCESS - ReadSize bytes of data were read into Buffer from the PE/COFF file starting at FileOffset 2960 2961 --*/ 2962 { 2963 CHAR8 *Destination8; 2964 CHAR8 *Source8; 2965 UINT32 Length; 2966 2967 Destination8 = Buffer; 2968 Source8 = (CHAR8 *) ((UINTN) FileHandle + FileOffset); 2969 Length = *ReadSize; 2970 while (Length--) { 2971 *(Destination8++) = *(Source8++); 2972 } 2973 2974 return EFI_SUCCESS; 2975 } 2976 2977 EFI_STATUS 2978 GetChildFvFromFfs ( 2979 IN FV_INFO *FvInfo, 2980 IN EFI_FFS_FILE_HEADER *FfsFile, 2981 IN UINTN XipOffset 2982 ) 2983 /*++ 2984 2985 Routine Description: 2986 2987 This function gets all child FvImages in the input FfsFile, and records 2988 their base address to the parent image. 2989 2990 Arguments: 2991 FvInfo A pointer to FV_INFO struture. 2992 FfsFile A pointer to Ffs file image that may contain FvImage. 2993 XipOffset The offset address to the parent FvImage base. 2994 2995 Returns: 2996 2997 EFI_SUCCESS Base address of child Fv image is recorded. 2998 --*/ 2999 { 3000 EFI_STATUS Status; 3001 UINTN Index; 3002 EFI_FILE_SECTION_POINTER SubFvSection; 3003 EFI_FIRMWARE_VOLUME_HEADER *SubFvImageHeader; 3004 EFI_PHYSICAL_ADDRESS SubFvBaseAddress; 3005 3006 for (Index = 1;; Index++) { 3007 // 3008 // Find FV section 3009 // 3010 Status = GetSectionByType (FfsFile, EFI_SECTION_FIRMWARE_VOLUME_IMAGE, Index, &SubFvSection); 3011 if (EFI_ERROR (Status)) { 3012 break; 3013 } 3014 SubFvImageHeader = (EFI_FIRMWARE_VOLUME_HEADER *) ((UINT8 *) SubFvSection.FVImageSection + GetSectionHeaderLength(SubFvSection.FVImageSection)); 3015 // 3016 // Rebase on Flash 3017 // 3018 SubFvBaseAddress = FvInfo->BaseAddress + (UINTN) SubFvImageHeader - (UINTN) FfsFile + XipOffset; 3019 mFvBaseAddress[mFvBaseAddressNumber ++ ] = SubFvBaseAddress; 3020 } 3021 3022 return EFI_SUCCESS; 3023 } 3024 3025 EFI_STATUS 3026 FfsRebase ( 3027 IN OUT FV_INFO *FvInfo, 3028 IN CHAR8 *FileName, 3029 IN OUT EFI_FFS_FILE_HEADER *FfsFile, 3030 IN UINTN XipOffset, 3031 IN FILE *FvMapFile 3032 ) 3033 /*++ 3034 3035 Routine Description: 3036 3037 This function determines if a file is XIP and should be rebased. It will 3038 rebase any PE32 sections found in the file using the base address. 3039 3040 Arguments: 3041 3042 FvInfo A pointer to FV_INFO struture. 3043 FileName Ffs File PathName 3044 FfsFile A pointer to Ffs file image. 3045 XipOffset The offset address to use for rebasing the XIP file image. 3046 FvMapFile FvMapFile to record the function address in one Fvimage 3047 3048 Returns: 3049 3050 EFI_SUCCESS The image was properly rebased. 3051 EFI_INVALID_PARAMETER An input parameter is invalid. 3052 EFI_ABORTED An error occurred while rebasing the input file image. 3053 EFI_OUT_OF_RESOURCES Could not allocate a required resource. 3054 EFI_NOT_FOUND No compressed sections could be found. 3055 3056 --*/ 3057 { 3058 EFI_STATUS Status; 3059 PE_COFF_LOADER_IMAGE_CONTEXT ImageContext; 3060 PE_COFF_LOADER_IMAGE_CONTEXT OrigImageContext; 3061 EFI_PHYSICAL_ADDRESS XipBase; 3062 EFI_PHYSICAL_ADDRESS NewPe32BaseAddress; 3063 UINTN Index; 3064 EFI_FILE_SECTION_POINTER CurrentPe32Section; 3065 EFI_FFS_FILE_STATE SavedState; 3066 EFI_IMAGE_OPTIONAL_HEADER_UNION *ImgHdr; 3067 EFI_TE_IMAGE_HEADER *TEImageHeader; 3068 UINT8 *MemoryImagePointer; 3069 EFI_IMAGE_SECTION_HEADER *SectionHeader; 3070 CHAR8 PeFileName [MAX_LONG_FILE_PATH]; 3071 CHAR8 *Cptr; 3072 FILE *PeFile; 3073 UINT8 *PeFileBuffer; 3074 UINT32 PeFileSize; 3075 CHAR8 *PdbPointer; 3076 UINT32 FfsHeaderSize; 3077 UINT32 CurSecHdrSize; 3078 3079 Index = 0; 3080 MemoryImagePointer = NULL; 3081 TEImageHeader = NULL; 3082 ImgHdr = NULL; 3083 SectionHeader = NULL; 3084 Cptr = NULL; 3085 PeFile = NULL; 3086 PeFileBuffer = NULL; 3087 3088 // 3089 // Don't need to relocate image when BaseAddress is zero and no ForceRebase Flag specified. 3090 // 3091 if ((FvInfo->BaseAddress == 0) && (FvInfo->ForceRebase == -1)) { 3092 return EFI_SUCCESS; 3093 } 3094 3095 // 3096 // If ForceRebase Flag specified to FALSE, will always not take rebase action. 3097 // 3098 if (FvInfo->ForceRebase == 0) { 3099 return EFI_SUCCESS; 3100 } 3101 3102 3103 XipBase = FvInfo->BaseAddress + XipOffset; 3104 3105 // 3106 // We only process files potentially containing PE32 sections. 3107 // 3108 switch (FfsFile->Type) { 3109 case EFI_FV_FILETYPE_SECURITY_CORE: 3110 case EFI_FV_FILETYPE_PEI_CORE: 3111 case EFI_FV_FILETYPE_PEIM: 3112 case EFI_FV_FILETYPE_COMBINED_PEIM_DRIVER: 3113 case EFI_FV_FILETYPE_DRIVER: 3114 case EFI_FV_FILETYPE_DXE_CORE: 3115 break; 3116 case EFI_FV_FILETYPE_FIRMWARE_VOLUME_IMAGE: 3117 // 3118 // Rebase the inside FvImage. 3119 // 3120 GetChildFvFromFfs (FvInfo, FfsFile, XipOffset); 3121 3122 // 3123 // Search PE/TE section in FV sectin. 3124 // 3125 break; 3126 default: 3127 return EFI_SUCCESS; 3128 } 3129 3130 FfsHeaderSize = GetFfsHeaderLength(FfsFile); 3131 // 3132 // Rebase each PE32 section 3133 // 3134 Status = EFI_SUCCESS; 3135 for (Index = 1;; Index++) { 3136 // 3137 // Init Value 3138 // 3139 NewPe32BaseAddress = 0; 3140 3141 // 3142 // Find Pe Image 3143 // 3144 Status = GetSectionByType (FfsFile, EFI_SECTION_PE32, Index, &CurrentPe32Section); 3145 if (EFI_ERROR (Status)) { 3146 break; 3147 } 3148 CurSecHdrSize = GetSectionHeaderLength(CurrentPe32Section.CommonHeader); 3149 3150 // 3151 // Initialize context 3152 // 3153 memset (&ImageContext, 0, sizeof (ImageContext)); 3154 ImageContext.Handle = (VOID *) ((UINTN) CurrentPe32Section.Pe32Section + CurSecHdrSize); 3155 ImageContext.ImageRead = (PE_COFF_LOADER_READ_FILE) FfsRebaseImageRead; 3156 Status = PeCoffLoaderGetImageInfo (&ImageContext); 3157 if (EFI_ERROR (Status)) { 3158 Error (NULL, 0, 3000, "Invalid PeImage", "The input file is %s and the return status is %x", FileName, (int) Status); 3159 return Status; 3160 } 3161 3162 if ( (ImageContext.Machine == EFI_IMAGE_MACHINE_ARMT) || 3163 (ImageContext.Machine == EFI_IMAGE_MACHINE_AARCH64) ) { 3164 mArm = TRUE; 3165 } 3166 3167 // 3168 // Keep Image Context for PE image in FV 3169 // 3170 memcpy (&OrigImageContext, &ImageContext, sizeof (ImageContext)); 3171 3172 // 3173 // Get File PdbPointer 3174 // 3175 PdbPointer = PeCoffLoaderGetPdbPointer (ImageContext.Handle); 3176 3177 // 3178 // Get PeHeader pointer 3179 // 3180 ImgHdr = (EFI_IMAGE_OPTIONAL_HEADER_UNION *)((UINTN) CurrentPe32Section.Pe32Section + CurSecHdrSize + ImageContext.PeCoffHeaderOffset); 3181 3182 // 3183 // Calculate the PE32 base address, based on file type 3184 // 3185 switch (FfsFile->Type) { 3186 case EFI_FV_FILETYPE_SECURITY_CORE: 3187 case EFI_FV_FILETYPE_PEI_CORE: 3188 case EFI_FV_FILETYPE_PEIM: 3189 case EFI_FV_FILETYPE_COMBINED_PEIM_DRIVER: 3190 // 3191 // Check if section-alignment and file-alignment match or not 3192 // 3193 if ((ImgHdr->Pe32.OptionalHeader.SectionAlignment != ImgHdr->Pe32.OptionalHeader.FileAlignment)) { 3194 // 3195 // Xip module has the same section alignment and file alignment. 3196 // 3197 Error (NULL, 0, 3000, "Invalid", "Section-Alignment and File-Alignment do not match : %s.", FileName); 3198 return EFI_ABORTED; 3199 } 3200 // 3201 // PeImage has no reloc section. It will try to get reloc data from the original EFI image. 3202 // 3203 if (ImageContext.RelocationsStripped) { 3204 // 3205 // Construct the original efi file Name 3206 // 3207 strcpy (PeFileName, FileName); 3208 Cptr = PeFileName + strlen (PeFileName); 3209 while (*Cptr != '.') { 3210 Cptr --; 3211 } 3212 if (*Cptr != '.') { 3213 Error (NULL, 0, 3000, "Invalid", "The file %s has no .reloc section.", FileName); 3214 return EFI_ABORTED; 3215 } else { 3216 *(Cptr + 1) = 'e'; 3217 *(Cptr + 2) = 'f'; 3218 *(Cptr + 3) = 'i'; 3219 *(Cptr + 4) = '\0'; 3220 } 3221 PeFile = fopen (LongFilePath (PeFileName), "rb"); 3222 if (PeFile == NULL) { 3223 Warning (NULL, 0, 0, "Invalid", "The file %s has no .reloc section.", FileName); 3224 //Error (NULL, 0, 3000, "Invalid", "The file %s has no .reloc section.", FileName); 3225 //return EFI_ABORTED; 3226 break; 3227 } 3228 // 3229 // Get the file size 3230 // 3231 PeFileSize = _filelength (fileno (PeFile)); 3232 PeFileBuffer = (UINT8 *) malloc (PeFileSize); 3233 if (PeFileBuffer == NULL) { 3234 Error (NULL, 0, 4001, "Resource", "memory cannot be allocated on rebase of %s", FileName); 3235 return EFI_OUT_OF_RESOURCES; 3236 } 3237 // 3238 // Read Pe File 3239 // 3240 fread (PeFileBuffer, sizeof (UINT8), PeFileSize, PeFile); 3241 // 3242 // close file 3243 // 3244 fclose (PeFile); 3245 // 3246 // Handle pointer to the original efi image. 3247 // 3248 ImageContext.Handle = PeFileBuffer; 3249 Status = PeCoffLoaderGetImageInfo (&ImageContext); 3250 if (EFI_ERROR (Status)) { 3251 Error (NULL, 0, 3000, "Invalid PeImage", "The input file is %s and the return status is %x", FileName, (int) Status); 3252 return Status; 3253 } 3254 ImageContext.RelocationsStripped = FALSE; 3255 } 3256 3257 NewPe32BaseAddress = XipBase + (UINTN) CurrentPe32Section.Pe32Section + CurSecHdrSize - (UINTN)FfsFile; 3258 break; 3259 3260 case EFI_FV_FILETYPE_DRIVER: 3261 case EFI_FV_FILETYPE_DXE_CORE: 3262 // 3263 // Check if section-alignment and file-alignment match or not 3264 // 3265 if ((ImgHdr->Pe32.OptionalHeader.SectionAlignment != ImgHdr->Pe32.OptionalHeader.FileAlignment)) { 3266 // 3267 // Xip module has the same section alignment and file alignment. 3268 // 3269 Error (NULL, 0, 3000, "Invalid", "Section-Alignment and File-Alignment do not match : %s.", FileName); 3270 return EFI_ABORTED; 3271 } 3272 NewPe32BaseAddress = XipBase + (UINTN) CurrentPe32Section.Pe32Section + CurSecHdrSize - (UINTN)FfsFile; 3273 break; 3274 3275 default: 3276 // 3277 // Not supported file type 3278 // 3279 return EFI_SUCCESS; 3280 } 3281 3282 // 3283 // Relocation doesn't exist 3284 // 3285 if (ImageContext.RelocationsStripped) { 3286 Warning (NULL, 0, 0, "Invalid", "The file %s has no .reloc section.", FileName); 3287 continue; 3288 } 3289 3290 // 3291 // Relocation exist and rebase 3292 // 3293 // 3294 // Load and Relocate Image Data 3295 // 3296 MemoryImagePointer = (UINT8 *) malloc ((UINTN) ImageContext.ImageSize + ImageContext.SectionAlignment); 3297 if (MemoryImagePointer == NULL) { 3298 Error (NULL, 0, 4001, "Resource", "memory cannot be allocated on rebase of %s", FileName); 3299 return EFI_OUT_OF_RESOURCES; 3300 } 3301 memset ((VOID *) MemoryImagePointer, 0, (UINTN) ImageContext.ImageSize + ImageContext.SectionAlignment); 3302 ImageContext.ImageAddress = ((UINTN) MemoryImagePointer + ImageContext.SectionAlignment - 1) & (~((UINTN) ImageContext.SectionAlignment - 1)); 3303 3304 Status = PeCoffLoaderLoadImage (&ImageContext); 3305 if (EFI_ERROR (Status)) { 3306 Error (NULL, 0, 3000, "Invalid", "LocateImage() call failed on rebase of %s", FileName); 3307 free ((VOID *) MemoryImagePointer); 3308 return Status; 3309 } 3310 3311 ImageContext.DestinationAddress = NewPe32BaseAddress; 3312 Status = PeCoffLoaderRelocateImage (&ImageContext); 3313 if (EFI_ERROR (Status)) { 3314 Error (NULL, 0, 3000, "Invalid", "RelocateImage() call failed on rebase of %s", FileName); 3315 free ((VOID *) MemoryImagePointer); 3316 return Status; 3317 } 3318 3319 // 3320 // Copy Relocated data to raw image file. 3321 // 3322 SectionHeader = (EFI_IMAGE_SECTION_HEADER *) ( 3323 (UINTN) ImgHdr + 3324 sizeof (UINT32) + 3325 sizeof (EFI_IMAGE_FILE_HEADER) + 3326 ImgHdr->Pe32.FileHeader.SizeOfOptionalHeader 3327 ); 3328 3329 for (Index = 0; Index < ImgHdr->Pe32.FileHeader.NumberOfSections; Index ++, SectionHeader ++) { 3330 CopyMem ( 3331 (UINT8 *) CurrentPe32Section.Pe32Section + CurSecHdrSize + SectionHeader->PointerToRawData, 3332 (VOID*) (UINTN) (ImageContext.ImageAddress + SectionHeader->VirtualAddress), 3333 SectionHeader->SizeOfRawData 3334 ); 3335 } 3336 3337 free ((VOID *) MemoryImagePointer); 3338 MemoryImagePointer = NULL; 3339 if (PeFileBuffer != NULL) { 3340 free (PeFileBuffer); 3341 PeFileBuffer = NULL; 3342 } 3343 3344 // 3345 // Update Image Base Address 3346 // 3347 if (ImgHdr->Pe32.OptionalHeader.Magic == EFI_IMAGE_NT_OPTIONAL_HDR32_MAGIC) { 3348 ImgHdr->Pe32.OptionalHeader.ImageBase = (UINT32) NewPe32BaseAddress; 3349 } else if (ImgHdr->Pe32Plus.OptionalHeader.Magic == EFI_IMAGE_NT_OPTIONAL_HDR64_MAGIC) { 3350 ImgHdr->Pe32Plus.OptionalHeader.ImageBase = NewPe32BaseAddress; 3351 } else { 3352 Error (NULL, 0, 3000, "Invalid", "unknown PE magic signature %X in PE32 image %s", 3353 ImgHdr->Pe32.OptionalHeader.Magic, 3354 FileName 3355 ); 3356 return EFI_ABORTED; 3357 } 3358 3359 // 3360 // Now update file checksum 3361 // 3362 if (FfsFile->Attributes & FFS_ATTRIB_CHECKSUM) { 3363 SavedState = FfsFile->State; 3364 FfsFile->IntegrityCheck.Checksum.File = 0; 3365 FfsFile->State = 0; 3366 FfsFile->IntegrityCheck.Checksum.File = CalculateChecksum8 ( 3367 (UINT8 *) ((UINT8 *)FfsFile + FfsHeaderSize), 3368 GetFfsFileLength (FfsFile) - FfsHeaderSize 3369 ); 3370 FfsFile->State = SavedState; 3371 } 3372 3373 // 3374 // Get this module function address from ModulePeMapFile and add them into FvMap file 3375 // 3376 3377 // 3378 // Default use FileName as map file path 3379 // 3380 if (PdbPointer == NULL) { 3381 PdbPointer = FileName; 3382 } 3383 3384 WriteMapFile (FvMapFile, PdbPointer, FfsFile, NewPe32BaseAddress, &OrigImageContext); 3385 } 3386 3387 if (FfsFile->Type != EFI_FV_FILETYPE_SECURITY_CORE && 3388 FfsFile->Type != EFI_FV_FILETYPE_PEI_CORE && 3389 FfsFile->Type != EFI_FV_FILETYPE_PEIM && 3390 FfsFile->Type != EFI_FV_FILETYPE_COMBINED_PEIM_DRIVER && 3391 FfsFile->Type != EFI_FV_FILETYPE_FIRMWARE_VOLUME_IMAGE 3392 ) { 3393 // 3394 // Only Peim code may have a TE section 3395 // 3396 return EFI_SUCCESS; 3397 } 3398 3399 // 3400 // Now process TE sections 3401 // 3402 for (Index = 1;; Index++) { 3403 NewPe32BaseAddress = 0; 3404 3405 // 3406 // Find Te Image 3407 // 3408 Status = GetSectionByType (FfsFile, EFI_SECTION_TE, Index, &CurrentPe32Section); 3409 if (EFI_ERROR (Status)) { 3410 break; 3411 } 3412 3413 CurSecHdrSize = GetSectionHeaderLength(CurrentPe32Section.CommonHeader); 3414 3415 // 3416 // Calculate the TE base address, the FFS file base plus the offset of the TE section less the size stripped off 3417 // by GenTEImage 3418 // 3419 TEImageHeader = (EFI_TE_IMAGE_HEADER *) ((UINT8 *) CurrentPe32Section.Pe32Section + CurSecHdrSize); 3420 3421 // 3422 // Initialize context, load image info. 3423 // 3424 memset (&ImageContext, 0, sizeof (ImageContext)); 3425 ImageContext.Handle = (VOID *) TEImageHeader; 3426 ImageContext.ImageRead = (PE_COFF_LOADER_READ_FILE) FfsRebaseImageRead; 3427 Status = PeCoffLoaderGetImageInfo (&ImageContext); 3428 if (EFI_ERROR (Status)) { 3429 Error (NULL, 0, 3000, "Invalid TeImage", "The input file is %s and the return status is %x", FileName, (int) Status); 3430 return Status; 3431 } 3432 3433 if ( (ImageContext.Machine == EFI_IMAGE_MACHINE_ARMT) || 3434 (ImageContext.Machine == EFI_IMAGE_MACHINE_AARCH64) ) { 3435 mArm = TRUE; 3436 } 3437 3438 // 3439 // Keep Image Context for TE image in FV 3440 // 3441 memcpy (&OrigImageContext, &ImageContext, sizeof (ImageContext)); 3442 3443 // 3444 // Get File PdbPointer 3445 // 3446 PdbPointer = PeCoffLoaderGetPdbPointer (ImageContext.Handle); 3447 3448 // 3449 // Set new rebased address. 3450 // 3451 NewPe32BaseAddress = XipBase + (UINTN) TEImageHeader + sizeof (EFI_TE_IMAGE_HEADER) \ 3452 - TEImageHeader->StrippedSize - (UINTN) FfsFile; 3453 3454 // 3455 // if reloc is stripped, try to get the original efi image to get reloc info. 3456 // 3457 if (ImageContext.RelocationsStripped) { 3458 // 3459 // Construct the original efi file name 3460 // 3461 strcpy (PeFileName, FileName); 3462 Cptr = PeFileName + strlen (PeFileName); 3463 while (*Cptr != '.') { 3464 Cptr --; 3465 } 3466 3467 if (*Cptr != '.') { 3468 Error (NULL, 0, 3000, "Invalid", "The file %s has no .reloc section.", FileName); 3469 return EFI_ABORTED; 3470 } else { 3471 *(Cptr + 1) = 'e'; 3472 *(Cptr + 2) = 'f'; 3473 *(Cptr + 3) = 'i'; 3474 *(Cptr + 4) = '\0'; 3475 } 3476 3477 PeFile = fopen (LongFilePath (PeFileName), "rb"); 3478 if (PeFile == NULL) { 3479 Warning (NULL, 0, 0, "Invalid", "The file %s has no .reloc section.", FileName); 3480 //Error (NULL, 0, 3000, "Invalid", "The file %s has no .reloc section.", FileName); 3481 //return EFI_ABORTED; 3482 } else { 3483 // 3484 // Get the file size 3485 // 3486 PeFileSize = _filelength (fileno (PeFile)); 3487 PeFileBuffer = (UINT8 *) malloc (PeFileSize); 3488 if (PeFileBuffer == NULL) { 3489 Error (NULL, 0, 4001, "Resource", "memory cannot be allocated on rebase of %s", FileName); 3490 return EFI_OUT_OF_RESOURCES; 3491 } 3492 // 3493 // Read Pe File 3494 // 3495 fread (PeFileBuffer, sizeof (UINT8), PeFileSize, PeFile); 3496 // 3497 // close file 3498 // 3499 fclose (PeFile); 3500 // 3501 // Append reloc section into TeImage 3502 // 3503 ImageContext.Handle = PeFileBuffer; 3504 Status = PeCoffLoaderGetImageInfo (&ImageContext); 3505 if (EFI_ERROR (Status)) { 3506 Error (NULL, 0, 3000, "Invalid TeImage", "The input file is %s and the return status is %x", FileName, (int) Status); 3507 return Status; 3508 } 3509 ImageContext.RelocationsStripped = FALSE; 3510 } 3511 } 3512 // 3513 // Relocation doesn't exist 3514 // 3515 if (ImageContext.RelocationsStripped) { 3516 Warning (NULL, 0, 0, "Invalid", "The file %s has no .reloc section.", FileName); 3517 continue; 3518 } 3519 3520 // 3521 // Relocation exist and rebase 3522 // 3523 // 3524 // Load and Relocate Image Data 3525 // 3526 MemoryImagePointer = (UINT8 *) malloc ((UINTN) ImageContext.ImageSize + ImageContext.SectionAlignment); 3527 if (MemoryImagePointer == NULL) { 3528 Error (NULL, 0, 4001, "Resource", "memory cannot be allocated on rebase of %s", FileName); 3529 return EFI_OUT_OF_RESOURCES; 3530 } 3531 memset ((VOID *) MemoryImagePointer, 0, (UINTN) ImageContext.ImageSize + ImageContext.SectionAlignment); 3532 ImageContext.ImageAddress = ((UINTN) MemoryImagePointer + ImageContext.SectionAlignment - 1) & (~((UINTN) ImageContext.SectionAlignment - 1)); 3533 3534 Status = PeCoffLoaderLoadImage (&ImageContext); 3535 if (EFI_ERROR (Status)) { 3536 Error (NULL, 0, 3000, "Invalid", "LocateImage() call failed on rebase of %s", FileName); 3537 free ((VOID *) MemoryImagePointer); 3538 return Status; 3539 } 3540 // 3541 // Reloacate TeImage 3542 // 3543 ImageContext.DestinationAddress = NewPe32BaseAddress; 3544 Status = PeCoffLoaderRelocateImage (&ImageContext); 3545 if (EFI_ERROR (Status)) { 3546 Error (NULL, 0, 3000, "Invalid", "RelocateImage() call failed on rebase of TE image %s", FileName); 3547 free ((VOID *) MemoryImagePointer); 3548 return Status; 3549 } 3550 3551 // 3552 // Copy the relocated image into raw image file. 3553 // 3554 SectionHeader = (EFI_IMAGE_SECTION_HEADER *) (TEImageHeader + 1); 3555 for (Index = 0; Index < TEImageHeader->NumberOfSections; Index ++, SectionHeader ++) { 3556 if (!ImageContext.IsTeImage) { 3557 CopyMem ( 3558 (UINT8 *) TEImageHeader + sizeof (EFI_TE_IMAGE_HEADER) - TEImageHeader->StrippedSize + SectionHeader->PointerToRawData, 3559 (VOID*) (UINTN) (ImageContext.ImageAddress + SectionHeader->VirtualAddress), 3560 SectionHeader->SizeOfRawData 3561 ); 3562 } else { 3563 CopyMem ( 3564 (UINT8 *) TEImageHeader + sizeof (EFI_TE_IMAGE_HEADER) - TEImageHeader->StrippedSize + SectionHeader->PointerToRawData, 3565 (VOID*) (UINTN) (ImageContext.ImageAddress + sizeof (EFI_TE_IMAGE_HEADER) - TEImageHeader->StrippedSize + SectionHeader->VirtualAddress), 3566 SectionHeader->SizeOfRawData 3567 ); 3568 } 3569 } 3570 3571 // 3572 // Free the allocated memory resource 3573 // 3574 free ((VOID *) MemoryImagePointer); 3575 MemoryImagePointer = NULL; 3576 if (PeFileBuffer != NULL) { 3577 free (PeFileBuffer); 3578 PeFileBuffer = NULL; 3579 } 3580 3581 // 3582 // Update Image Base Address 3583 // 3584 TEImageHeader->ImageBase = NewPe32BaseAddress; 3585 3586 // 3587 // Now update file checksum 3588 // 3589 if (FfsFile->Attributes & FFS_ATTRIB_CHECKSUM) { 3590 SavedState = FfsFile->State; 3591 FfsFile->IntegrityCheck.Checksum.File = 0; 3592 FfsFile->State = 0; 3593 FfsFile->IntegrityCheck.Checksum.File = CalculateChecksum8 ( 3594 (UINT8 *)((UINT8 *)FfsFile + FfsHeaderSize), 3595 GetFfsFileLength (FfsFile) - FfsHeaderSize 3596 ); 3597 FfsFile->State = SavedState; 3598 } 3599 // 3600 // Get this module function address from ModulePeMapFile and add them into FvMap file 3601 // 3602 3603 // 3604 // Default use FileName as map file path 3605 // 3606 if (PdbPointer == NULL) { 3607 PdbPointer = FileName; 3608 } 3609 3610 WriteMapFile ( 3611 FvMapFile, 3612 PdbPointer, 3613 FfsFile, 3614 NewPe32BaseAddress, 3615 &OrigImageContext 3616 ); 3617 } 3618 3619 return EFI_SUCCESS; 3620 } 3621 3622 EFI_STATUS 3623 FindApResetVectorPosition ( 3624 IN MEMORY_FILE *FvImage, 3625 OUT UINT8 **Pointer 3626 ) 3627 /*++ 3628 3629 Routine Description: 3630 3631 Find the position in this FvImage to place Ap reset vector. 3632 3633 Arguments: 3634 3635 FvImage Memory file for the FV memory image. 3636 Pointer Pointer to pointer to position. 3637 3638 Returns: 3639 3640 EFI_NOT_FOUND - No satisfied position is found. 3641 EFI_SUCCESS - The suitable position is return. 3642 3643 --*/ 3644 { 3645 EFI_FFS_FILE_HEADER *PadFile; 3646 UINT32 Index; 3647 EFI_STATUS Status; 3648 UINT8 *FixPoint; 3649 UINT32 FileLength; 3650 3651 for (Index = 1; ;Index ++) { 3652 // 3653 // Find Pad File to add ApResetVector info 3654 // 3655 Status = GetFileByType (EFI_FV_FILETYPE_FFS_PAD, Index, &PadFile); 3656 if (EFI_ERROR (Status) || (PadFile == NULL)) { 3657 // 3658 // No Pad file to be found. 3659 // 3660 break; 3661 } 3662 // 3663 // Get Pad file size. 3664 // 3665 FileLength = GetFfsFileLength(PadFile); 3666 FileLength = (FileLength + EFI_FFS_FILE_HEADER_ALIGNMENT - 1) & ~(EFI_FFS_FILE_HEADER_ALIGNMENT - 1); 3667 // 3668 // FixPoint must be align on 0x1000 relative to FvImage Header 3669 // 3670 FixPoint = (UINT8*) PadFile + GetFfsHeaderLength(PadFile); 3671 FixPoint = FixPoint + 0x1000 - (((UINTN) FixPoint - (UINTN) FvImage->FileImage) & 0xFFF); 3672 // 3673 // FixPoint be larger at the last place of one fv image. 3674 // 3675 while (((UINTN) FixPoint + SIZEOF_STARTUP_DATA_ARRAY - (UINTN) PadFile) <= FileLength) { 3676 FixPoint += 0x1000; 3677 } 3678 FixPoint -= 0x1000; 3679 3680 if ((UINTN) FixPoint < ((UINTN) PadFile + GetFfsHeaderLength(PadFile))) { 3681 // 3682 // No alignment FixPoint in this Pad File. 3683 // 3684 continue; 3685 } 3686 3687 if ((UINTN) FvImage->Eof - (UINTN)FixPoint <= 0x20000) { 3688 // 3689 // Find the position to place ApResetVector 3690 // 3691 *Pointer = FixPoint; 3692 return EFI_SUCCESS; 3693 } 3694 } 3695 3696 return EFI_NOT_FOUND; 3697 } 3698 3699 EFI_STATUS 3700 ParseCapInf ( 3701 IN MEMORY_FILE *InfFile, 3702 OUT CAP_INFO *CapInfo 3703 ) 3704 /*++ 3705 3706 Routine Description: 3707 3708 This function parses a Cap.INF file and copies info into a CAP_INFO structure. 3709 3710 Arguments: 3711 3712 InfFile Memory file image. 3713 CapInfo Information read from INF file. 3714 3715 Returns: 3716 3717 EFI_SUCCESS INF file information successfully retrieved. 3718 EFI_ABORTED INF file has an invalid format. 3719 EFI_NOT_FOUND A required string was not found in the INF file. 3720 --*/ 3721 { 3722 CHAR8 Value[MAX_LONG_FILE_PATH]; 3723 UINT64 Value64; 3724 UINTN Index, Number; 3725 EFI_STATUS Status; 3726 3727 // 3728 // Initialize Cap info 3729 // 3730 // memset (CapInfo, 0, sizeof (CAP_INFO)); 3731 // 3732 3733 // 3734 // Read the Capsule Guid 3735 // 3736 Status = FindToken (InfFile, OPTIONS_SECTION_STRING, EFI_CAPSULE_GUID_STRING, 0, Value); 3737 if (Status == EFI_SUCCESS) { 3738 // 3739 // Get the Capsule Guid 3740 // 3741 Status = StringToGuid (Value, &CapInfo->CapGuid); 3742 if (EFI_ERROR (Status)) { 3743 Error (NULL, 0, 2000, "Invalid parameter", "%s = %s", EFI_CAPSULE_GUID_STRING, Value); 3744 return EFI_ABORTED; 3745 } 3746 DebugMsg (NULL, 0, 9, "Capsule Guid", "%s = %s", EFI_CAPSULE_GUID_STRING, Value); 3747 } 3748 3749 // 3750 // Read the Capsule Header Size 3751 // 3752 Status = FindToken (InfFile, OPTIONS_SECTION_STRING, EFI_CAPSULE_HEADER_SIZE_STRING, 0, Value); 3753 if (Status == EFI_SUCCESS) { 3754 Status = AsciiStringToUint64 (Value, FALSE, &Value64); 3755 if (EFI_ERROR (Status)) { 3756 Error (NULL, 0, 2000, "Invalid parameter", "%s = %s", EFI_CAPSULE_HEADER_SIZE_STRING, Value); 3757 return EFI_ABORTED; 3758 } 3759 CapInfo->HeaderSize = (UINT32) Value64; 3760 DebugMsg (NULL, 0, 9, "Capsule Header size", "%s = %s", EFI_CAPSULE_HEADER_SIZE_STRING, Value); 3761 } 3762 3763 // 3764 // Read the Capsule Flag 3765 // 3766 Status = FindToken (InfFile, OPTIONS_SECTION_STRING, EFI_CAPSULE_FLAGS_STRING, 0, Value); 3767 if (Status == EFI_SUCCESS) { 3768 if (strstr (Value, "PopulateSystemTable") != NULL) { 3769 CapInfo->Flags |= CAPSULE_FLAGS_PERSIST_ACROSS_RESET | CAPSULE_FLAGS_POPULATE_SYSTEM_TABLE; 3770 if (strstr (Value, "InitiateReset") != NULL) { 3771 CapInfo->Flags |= CAPSULE_FLAGS_INITIATE_RESET; 3772 } 3773 } else if (strstr (Value, "PersistAcrossReset") != NULL) { 3774 CapInfo->Flags |= CAPSULE_FLAGS_PERSIST_ACROSS_RESET; 3775 if (strstr (Value, "InitiateReset") != NULL) { 3776 CapInfo->Flags |= CAPSULE_FLAGS_INITIATE_RESET; 3777 } 3778 } else { 3779 Error (NULL, 0, 2000, "Invalid parameter", "invalid Flag setting for %s.", EFI_CAPSULE_FLAGS_STRING); 3780 return EFI_ABORTED; 3781 } 3782 DebugMsg (NULL, 0, 9, "Capsule Flag", Value); 3783 } 3784 3785 Status = FindToken (InfFile, OPTIONS_SECTION_STRING, EFI_OEM_CAPSULE_FLAGS_STRING, 0, Value); 3786 if (Status == EFI_SUCCESS) { 3787 Status = AsciiStringToUint64 (Value, FALSE, &Value64); 3788 if (EFI_ERROR (Status) || Value64 > 0xffff) { 3789 Error (NULL, 0, 2000, "Invalid parameter", 3790 "invalid Flag setting for %s. Must be integer value between 0x0000 and 0xffff.", 3791 EFI_OEM_CAPSULE_FLAGS_STRING); 3792 return EFI_ABORTED; 3793 } 3794 CapInfo->Flags |= Value64; 3795 DebugMsg (NULL, 0, 9, "Capsule Extend Flag", Value); 3796 } 3797 3798 // 3799 // Read Capsule File name 3800 // 3801 Status = FindToken (InfFile, OPTIONS_SECTION_STRING, EFI_FILE_NAME_STRING, 0, Value); 3802 if (Status == EFI_SUCCESS) { 3803 // 3804 // Get output file name 3805 // 3806 strcpy (CapInfo->CapName, Value); 3807 } 3808 3809 // 3810 // Read the Capsule FileImage 3811 // 3812 Number = 0; 3813 for (Index = 0; Index < MAX_NUMBER_OF_FILES_IN_CAP; Index++) { 3814 if (CapInfo->CapFiles[Index][0] != '\0') { 3815 continue; 3816 } 3817 // 3818 // Read the capsule file name 3819 // 3820 Status = FindToken (InfFile, FILES_SECTION_STRING, EFI_FILE_NAME_STRING, Number++, Value); 3821 3822 if (Status == EFI_SUCCESS) { 3823 // 3824 // Add the file 3825 // 3826 strcpy (CapInfo->CapFiles[Index], Value); 3827 DebugMsg (NULL, 0, 9, "Capsule component file", "the %uth file name is %s", (unsigned) Index, CapInfo->CapFiles[Index]); 3828 } else { 3829 break; 3830 } 3831 } 3832 3833 if (Index == 0) { 3834 Warning (NULL, 0, 0, "Capsule components are not specified.", NULL); 3835 } 3836 3837 return EFI_SUCCESS; 3838 } 3839 3840 EFI_STATUS 3841 GenerateCapImage ( 3842 IN CHAR8 *InfFileImage, 3843 IN UINTN InfFileSize, 3844 IN CHAR8 *CapFileName 3845 ) 3846 /*++ 3847 3848 Routine Description: 3849 3850 This is the main function which will be called from application to create UEFI Capsule image. 3851 3852 Arguments: 3853 3854 InfFileImage Buffer containing the INF file contents. 3855 InfFileSize Size of the contents of the InfFileImage buffer. 3856 CapFileName Requested name for the Cap file. 3857 3858 Returns: 3859 3860 EFI_SUCCESS Function completed successfully. 3861 EFI_OUT_OF_RESOURCES Could not allocate required resources. 3862 EFI_ABORTED Error encountered. 3863 EFI_INVALID_PARAMETER A required parameter was NULL. 3864 3865 --*/ 3866 { 3867 UINT32 CapSize; 3868 UINT8 *CapBuffer; 3869 EFI_CAPSULE_HEADER *CapsuleHeader; 3870 MEMORY_FILE InfMemoryFile; 3871 UINT32 FileSize; 3872 UINT32 Index; 3873 FILE *fpin, *fpout; 3874 EFI_STATUS Status; 3875 3876 if (InfFileImage != NULL) { 3877 // 3878 // Initialize file structures 3879 // 3880 InfMemoryFile.FileImage = InfFileImage; 3881 InfMemoryFile.CurrentFilePointer = InfFileImage; 3882 InfMemoryFile.Eof = InfFileImage + InfFileSize; 3883 3884 // 3885 // Parse the Cap inf file for header information 3886 // 3887 Status = ParseCapInf (&InfMemoryFile, &mCapDataInfo); 3888 if (Status != EFI_SUCCESS) { 3889 return Status; 3890 } 3891 } 3892 3893 if (mCapDataInfo.HeaderSize == 0) { 3894 // 3895 // make header size align 16 bytes. 3896 // 3897 mCapDataInfo.HeaderSize = sizeof (EFI_CAPSULE_HEADER); 3898 mCapDataInfo.HeaderSize = (mCapDataInfo.HeaderSize + 0xF) & ~0xF; 3899 } 3900 3901 if (mCapDataInfo.HeaderSize < sizeof (EFI_CAPSULE_HEADER)) { 3902 Error (NULL, 0, 2000, "Invalid parameter", "The specified HeaderSize cannot be less than the size of EFI_CAPSULE_HEADER."); 3903 return EFI_INVALID_PARAMETER; 3904 } 3905 3906 if (CapFileName == NULL && mCapDataInfo.CapName[0] != '\0') { 3907 CapFileName = mCapDataInfo.CapName; 3908 } 3909 3910 if (CapFileName == NULL) { 3911 Error (NULL, 0, 2001, "Missing required argument", "Output Capsule file name"); 3912 return EFI_INVALID_PARAMETER; 3913 } 3914 3915 // 3916 // Set Default Capsule Guid value 3917 // 3918 if (CompareGuid (&mCapDataInfo.CapGuid, &mZeroGuid) == 0) { 3919 memcpy (&mCapDataInfo.CapGuid, &mDefaultCapsuleGuid, sizeof (EFI_GUID)); 3920 } 3921 // 3922 // Calculate the size of capsule image. 3923 // 3924 Index = 0; 3925 FileSize = 0; 3926 CapSize = mCapDataInfo.HeaderSize; 3927 while (mCapDataInfo.CapFiles [Index][0] != '\0') { 3928 fpin = fopen (LongFilePath (mCapDataInfo.CapFiles[Index]), "rb"); 3929 if (fpin == NULL) { 3930 Error (NULL, 0, 0001, "Error opening file", mCapDataInfo.CapFiles[Index]); 3931 return EFI_ABORTED; 3932 } 3933 FileSize = _filelength (fileno (fpin)); 3934 CapSize += FileSize; 3935 fclose (fpin); 3936 Index ++; 3937 } 3938 3939 // 3940 // Allocate buffer for capsule image. 3941 // 3942 CapBuffer = (UINT8 *) malloc (CapSize); 3943 if (CapBuffer == NULL) { 3944 Error (NULL, 0, 4001, "Resource", "memory cannot be allocated for creating the capsule."); 3945 return EFI_OUT_OF_RESOURCES; 3946 } 3947 3948 // 3949 // Initialize the capsule header to zero 3950 // 3951 memset (CapBuffer, 0, mCapDataInfo.HeaderSize); 3952 3953 // 3954 // create capsule header and get capsule body 3955 // 3956 CapsuleHeader = (EFI_CAPSULE_HEADER *) CapBuffer; 3957 memcpy (&CapsuleHeader->CapsuleGuid, &mCapDataInfo.CapGuid, sizeof (EFI_GUID)); 3958 CapsuleHeader->HeaderSize = mCapDataInfo.HeaderSize; 3959 CapsuleHeader->Flags = mCapDataInfo.Flags; 3960 CapsuleHeader->CapsuleImageSize = CapSize; 3961 3962 Index = 0; 3963 FileSize = 0; 3964 CapSize = CapsuleHeader->HeaderSize; 3965 while (mCapDataInfo.CapFiles [Index][0] != '\0') { 3966 fpin = fopen (LongFilePath (mCapDataInfo.CapFiles[Index]), "rb"); 3967 if (fpin == NULL) { 3968 Error (NULL, 0, 0001, "Error opening file", mCapDataInfo.CapFiles[Index]); 3969 free (CapBuffer); 3970 return EFI_ABORTED; 3971 } 3972 FileSize = _filelength (fileno (fpin)); 3973 fread (CapBuffer + CapSize, 1, FileSize, fpin); 3974 fclose (fpin); 3975 Index ++; 3976 CapSize += FileSize; 3977 } 3978 3979 // 3980 // write capsule data into the output file 3981 // 3982 fpout = fopen (LongFilePath (CapFileName), "wb"); 3983 if (fpout == NULL) { 3984 Error (NULL, 0, 0001, "Error opening file", CapFileName); 3985 free (CapBuffer); 3986 return EFI_ABORTED; 3987 } 3988 3989 fwrite (CapBuffer, 1, CapSize, fpout); 3990 fclose (fpout); 3991 3992 VerboseMsg ("The size of the generated capsule image is %u bytes", (unsigned) CapSize); 3993 3994 return EFI_SUCCESS; 3995 } 3996