1 /** @file 2 The implementation of IPSEC_CONFIG_PROTOCOL. 3 4 Copyright (c) 2009 - 2016, Intel Corporation. All rights reserved.<BR> 5 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 #include "IpSecConfigImpl.h" 17 #include "IpSecDebug.h" 18 19 LIST_ENTRY mConfigData[IPsecConfigDataTypeMaximum]; 20 BOOLEAN mSetBySelf = FALSE; 21 22 // 23 // Common CompareSelector routine entry for SPD/SAD/PAD. 24 // 25 IPSEC_COMPARE_SELECTOR mCompareSelector[] = { 26 (IPSEC_COMPARE_SELECTOR) CompareSpdSelector, 27 (IPSEC_COMPARE_SELECTOR) CompareSaId, 28 (IPSEC_COMPARE_SELECTOR) ComparePadId 29 }; 30 31 // 32 // Common IsZeroSelector routine entry for SPD/SAD/PAD. 33 // 34 IPSEC_IS_ZERO_SELECTOR mIsZeroSelector[] = { 35 (IPSEC_IS_ZERO_SELECTOR) IsZeroSpdSelector, 36 (IPSEC_IS_ZERO_SELECTOR) IsZeroSaId, 37 (IPSEC_IS_ZERO_SELECTOR) IsZeroPadId 38 }; 39 40 // 41 // Common DuplicateSelector routine entry for SPD/SAD/PAD. 42 // 43 IPSEC_DUPLICATE_SELECTOR mDuplicateSelector[] = { 44 (IPSEC_DUPLICATE_SELECTOR) DuplicateSpdSelector, 45 (IPSEC_DUPLICATE_SELECTOR) DuplicateSaId, 46 (IPSEC_DUPLICATE_SELECTOR) DuplicatePadId 47 }; 48 49 // 50 // Common FixPolicyEntry routine entry for SPD/SAD/PAD. 51 // 52 IPSEC_FIX_POLICY_ENTRY mFixPolicyEntry[] = { 53 (IPSEC_FIX_POLICY_ENTRY) FixSpdEntry, 54 (IPSEC_FIX_POLICY_ENTRY) FixSadEntry, 55 (IPSEC_FIX_POLICY_ENTRY) FixPadEntry 56 }; 57 58 // 59 // Common UnfixPolicyEntry routine entry for SPD/SAD/PAD. 60 // 61 IPSEC_FIX_POLICY_ENTRY mUnfixPolicyEntry[] = { 62 (IPSEC_FIX_POLICY_ENTRY) UnfixSpdEntry, 63 (IPSEC_FIX_POLICY_ENTRY) UnfixSadEntry, 64 (IPSEC_FIX_POLICY_ENTRY) UnfixPadEntry 65 }; 66 67 // 68 // Common SetPolicyEntry routine entry for SPD/SAD/PAD. 69 // 70 IPSEC_SET_POLICY_ENTRY mSetPolicyEntry[] = { 71 (IPSEC_SET_POLICY_ENTRY) SetSpdEntry, 72 (IPSEC_SET_POLICY_ENTRY) SetSadEntry, 73 (IPSEC_SET_POLICY_ENTRY) SetPadEntry 74 }; 75 76 // 77 // Common GetPolicyEntry routine entry for SPD/SAD/PAD. 78 // 79 IPSEC_GET_POLICY_ENTRY mGetPolicyEntry[] = { 80 (IPSEC_GET_POLICY_ENTRY) GetSpdEntry, 81 (IPSEC_GET_POLICY_ENTRY) GetSadEntry, 82 (IPSEC_GET_POLICY_ENTRY) GetPadEntry 83 }; 84 85 // 86 // Routine entry for IpSecConfig protocol. 87 // 88 EFI_IPSEC_CONFIG_PROTOCOL mIpSecConfigInstance = { 89 EfiIpSecConfigSetData, 90 EfiIpSecConfigGetData, 91 EfiIpSecConfigGetNextSelector, 92 EfiIpSecConfigRegisterNotify, 93 EfiIpSecConfigUnregisterNotify 94 }; 95 96 /** 97 Get the all IPSec configuration variables and store those variables 98 to the internal data structure. 99 100 This founction is called by IpSecConfigInitialize() that is to intialize the 101 IPsecConfiguration Protocol. 102 103 @param[in] Private Point to IPSEC_PRIVATE_DATA. 104 105 @retval EFI_OUT_OF_RESOURCES The required system resource could not be allocated. 106 @retval EFI_SUCCESS Restore the IPsec Configuration successfully. 107 @retval others Other errors is found during the variable getting. 108 109 **/ 110 EFI_STATUS 111 IpSecConfigRestore ( 112 IN IPSEC_PRIVATE_DATA *Private 113 ); 114 115 /** 116 Check if the specified EFI_IP_ADDRESS_INFO is in EFI_IP_ADDRESS_INFO list. 117 118 @param[in] AddressInfo Pointer of IP_ADDRESS_INFO to be search in AddressInfo list. 119 @param[in] AddressInfoList A list that contains IP_ADDRESS_INFOs. 120 @param[in] AddressCount Point out how many IP_ADDRESS_INFO in the list. 121 122 @retval TRUE The specified AddressInfo is in the AddressInfoList. 123 @retval FALSE The specified AddressInfo is not in the AddressInfoList. 124 125 **/ 126 BOOLEAN 127 IsInAddressInfoList( 128 IN EFI_IP_ADDRESS_INFO *AddressInfo, 129 IN EFI_IP_ADDRESS_INFO *AddressInfoList, 130 IN UINT32 AddressCount 131 ) 132 { 133 UINT8 Index; 134 EFI_IP_ADDRESS ZeroAddress; 135 136 ZeroMem(&ZeroAddress, sizeof (EFI_IP_ADDRESS)); 137 138 // 139 // Zero Address means any address is matched. 140 // 141 if (AddressCount == 1) { 142 if (CompareMem ( 143 &AddressInfoList[0].Address, 144 &ZeroAddress, 145 sizeof (EFI_IP_ADDRESS) 146 ) == 0) { 147 return TRUE; 148 } 149 } 150 for (Index = 0; Index < AddressCount ; Index++) { 151 if (CompareMem ( 152 AddressInfo, 153 &AddressInfoList[Index].Address, 154 sizeof (EFI_IP_ADDRESS) 155 ) == 0 && 156 AddressInfo->PrefixLength == AddressInfoList[Index].PrefixLength 157 ) { 158 return TRUE; 159 } 160 } 161 return FALSE; 162 } 163 164 /** 165 Compare two SPD Selectors. 166 167 Compare two SPD Selector by the fields of LocalAddressCount/RemoteAddressCount/ 168 NextLayerProtocol/LocalPort/LocalPortRange/RemotePort/RemotePortRange and the 169 Local Addresses and remote Addresses. 170 171 @param[in] Selector1 Pointer of first SPD Selector. 172 @param[in] Selector2 Pointer of second SPD Selector. 173 174 @retval TRUE This two Selector have the same value in above fields. 175 @retval FALSE Not all above fields have the same value in these two Selectors. 176 177 **/ 178 BOOLEAN 179 CompareSpdSelector ( 180 IN EFI_IPSEC_CONFIG_SELECTOR *Selector1, 181 IN EFI_IPSEC_CONFIG_SELECTOR *Selector2 182 ) 183 { 184 EFI_IPSEC_SPD_SELECTOR *SpdSel1; 185 EFI_IPSEC_SPD_SELECTOR *SpdSel2; 186 BOOLEAN IsMatch; 187 UINTN Index; 188 189 SpdSel1 = &Selector1->SpdSelector; 190 SpdSel2 = &Selector2->SpdSelector; 191 IsMatch = TRUE; 192 193 // 194 // Compare the LocalAddressCount/RemoteAddressCount/NextLayerProtocol/ 195 // LocalPort/LocalPortRange/RemotePort/RemotePortRange fields in the 196 // two Spdselectors. Since the SPD supports two directions, it needs to 197 // compare two directions. 198 // 199 if ((SpdSel1->LocalAddressCount != SpdSel2->LocalAddressCount && 200 SpdSel1->LocalAddressCount != SpdSel2->RemoteAddressCount) || 201 (SpdSel1->RemoteAddressCount != SpdSel2->RemoteAddressCount && 202 SpdSel1->RemoteAddressCount != SpdSel2->LocalAddressCount) || 203 SpdSel1->NextLayerProtocol != SpdSel2->NextLayerProtocol || 204 SpdSel1->LocalPort != SpdSel2->LocalPort || 205 SpdSel1->LocalPortRange != SpdSel2->LocalPortRange || 206 SpdSel1->RemotePort != SpdSel2->RemotePort || 207 SpdSel1->RemotePortRange != SpdSel2->RemotePortRange 208 ) { 209 IsMatch = FALSE; 210 return IsMatch; 211 } 212 213 // 214 // Compare the all LocalAddress and RemoteAddress fields in the two Spdselectors. 215 // First, SpdSel1->LocalAddress to SpdSel2->LocalAddress && Compare 216 // SpdSel1->RemoteAddress to SpdSel2->RemoteAddress. If all match, return 217 // TRUE. 218 // 219 for (Index = 0; Index < SpdSel1->LocalAddressCount; Index++) { 220 if (!IsInAddressInfoList ( 221 &SpdSel1->LocalAddress[Index], 222 SpdSel2->LocalAddress, 223 SpdSel2->LocalAddressCount 224 )) { 225 IsMatch = FALSE; 226 break; 227 } 228 } 229 if (IsMatch) { 230 for (Index = 0; Index < SpdSel2->LocalAddressCount; Index++) { 231 if (!IsInAddressInfoList ( 232 &SpdSel2->LocalAddress[Index], 233 SpdSel1->LocalAddress, 234 SpdSel1->LocalAddressCount 235 )) { 236 IsMatch = FALSE; 237 break; 238 } 239 } 240 } 241 if (IsMatch) { 242 for (Index = 0; Index < SpdSel1->RemoteAddressCount; Index++) { 243 if (!IsInAddressInfoList ( 244 &SpdSel1->RemoteAddress[Index], 245 SpdSel2->RemoteAddress, 246 SpdSel2->RemoteAddressCount 247 )) { 248 IsMatch = FALSE; 249 break; 250 } 251 } 252 } 253 if (IsMatch) { 254 for (Index = 0; Index < SpdSel2->RemoteAddressCount; Index++) { 255 if (!IsInAddressInfoList ( 256 &SpdSel2->RemoteAddress[Index], 257 SpdSel1->RemoteAddress, 258 SpdSel1->RemoteAddressCount 259 )) { 260 IsMatch = FALSE; 261 break; 262 } 263 } 264 } 265 // 266 // Finish the one direction compare. If it is matched, return; otherwise, 267 // compare the other direction. 268 // 269 if (IsMatch) { 270 return IsMatch; 271 } 272 // 273 // Secondly, the SpdSel1->LocalAddress doesn't equal to SpdSel2->LocalAddress and 274 // SpdSel1->RemoteAddress doesn't equal to SpdSel2->RemoteAddress. Try to compare 275 // the RemoteAddress to LocalAddress. 276 // 277 IsMatch = TRUE; 278 for (Index = 0; Index < SpdSel1->RemoteAddressCount; Index++) { 279 if (!IsInAddressInfoList ( 280 &SpdSel1->RemoteAddress[Index], 281 SpdSel2->LocalAddress, 282 SpdSel2->LocalAddressCount 283 )) { 284 IsMatch = FALSE; 285 break; 286 } 287 } 288 if (IsMatch) { 289 for (Index = 0; Index < SpdSel2->RemoteAddressCount; Index++) { 290 if (!IsInAddressInfoList ( 291 &SpdSel2->RemoteAddress[Index], 292 SpdSel1->LocalAddress, 293 SpdSel1->LocalAddressCount 294 )) { 295 IsMatch = FALSE; 296 break; 297 } 298 } 299 } 300 if (IsMatch) { 301 for (Index = 0; Index < SpdSel1->LocalAddressCount; Index++) { 302 if (!IsInAddressInfoList ( 303 &SpdSel1->LocalAddress[Index], 304 SpdSel2->RemoteAddress, 305 SpdSel2->RemoteAddressCount 306 )) { 307 IsMatch = FALSE; 308 break; 309 } 310 } 311 } 312 if (IsMatch) { 313 for (Index = 0; Index < SpdSel2->LocalAddressCount; Index++) { 314 if (!IsInAddressInfoList ( 315 &SpdSel2->LocalAddress[Index], 316 SpdSel1->RemoteAddress, 317 SpdSel1->RemoteAddressCount 318 )) { 319 IsMatch = FALSE; 320 break; 321 } 322 } 323 } 324 return IsMatch; 325 } 326 327 /** 328 Find if the two SPD Selectors has subordinative. 329 330 Compare two SPD Selector by the fields of LocalAddressCount/RemoteAddressCount/ 331 NextLayerProtocol/LocalPort/LocalPortRange/RemotePort/RemotePortRange and the 332 Local Addresses and remote Addresses. 333 334 @param[in] Selector1 Pointer of first SPD Selector. 335 @param[in] Selector2 Pointer of second SPD Selector. 336 337 @retval TRUE The first SPD Selector is subordinate Selector of second SPD Selector. 338 @retval FALSE The first SPD Selector is not subordinate Selector of second 339 SPD Selector. 340 341 **/ 342 BOOLEAN 343 IsSubSpdSelector ( 344 IN EFI_IPSEC_CONFIG_SELECTOR *Selector1, 345 IN EFI_IPSEC_CONFIG_SELECTOR *Selector2 346 ) 347 { 348 EFI_IPSEC_SPD_SELECTOR *SpdSel1; 349 EFI_IPSEC_SPD_SELECTOR *SpdSel2; 350 BOOLEAN IsMatch; 351 UINTN Index; 352 353 SpdSel1 = &Selector1->SpdSelector; 354 SpdSel2 = &Selector2->SpdSelector; 355 IsMatch = TRUE; 356 357 // 358 // Compare the LocalAddressCount/RemoteAddressCount/NextLayerProtocol/ 359 // LocalPort/LocalPortRange/RemotePort/RemotePortRange fields in the 360 // two Spdselectors. Since the SPD supports two directions, it needs to 361 // compare two directions. 362 // 363 if (SpdSel1->LocalAddressCount > SpdSel2->LocalAddressCount || 364 SpdSel1->RemoteAddressCount > SpdSel2->RemoteAddressCount || 365 (SpdSel1->NextLayerProtocol != SpdSel2->NextLayerProtocol && SpdSel2->NextLayerProtocol != 0xffff) || 366 (SpdSel1->LocalPort > SpdSel2->LocalPort && SpdSel2->LocalPort != 0)|| 367 (SpdSel1->LocalPortRange > SpdSel2->LocalPortRange && SpdSel1->LocalPort != 0)|| 368 (SpdSel1->RemotePort > SpdSel2->RemotePort && SpdSel2->RemotePort != 0) || 369 (SpdSel1->RemotePortRange > SpdSel2->RemotePortRange && SpdSel2->RemotePort != 0) 370 ) { 371 IsMatch = FALSE; 372 } 373 374 // 375 // Compare the all LocalAddress and RemoteAddress fields in the two Spdselectors. 376 // First, SpdSel1->LocalAddress to SpdSel2->LocalAddress && Compare 377 // SpdSel1->RemoteAddress to SpdSel2->RemoteAddress. If all match, return 378 // TRUE. 379 // 380 if (IsMatch) { 381 for (Index = 0; Index < SpdSel1->LocalAddressCount; Index++) { 382 if (!IsInAddressInfoList ( 383 &SpdSel1->LocalAddress[Index], 384 SpdSel2->LocalAddress, 385 SpdSel2->LocalAddressCount 386 )) { 387 IsMatch = FALSE; 388 break; 389 } 390 } 391 392 if (IsMatch) { 393 for (Index = 0; Index < SpdSel1->RemoteAddressCount; Index++) { 394 if (!IsInAddressInfoList ( 395 &SpdSel1->RemoteAddress[Index], 396 SpdSel2->RemoteAddress, 397 SpdSel2->RemoteAddressCount 398 )) { 399 IsMatch = FALSE; 400 break; 401 } 402 } 403 } 404 } 405 if (IsMatch) { 406 return IsMatch; 407 } 408 409 // 410 // 411 // The SPD selector in SPD entry is two way. 412 // 413 // Compare the LocalAddressCount/RemoteAddressCount/NextLayerProtocol/ 414 // LocalPort/LocalPortRange/RemotePort/RemotePortRange fields in the 415 // two Spdselectors. Since the SPD supports two directions, it needs to 416 // compare two directions. 417 // 418 IsMatch = TRUE; 419 if (SpdSel1->LocalAddressCount > SpdSel2->RemoteAddressCount || 420 SpdSel1->RemoteAddressCount > SpdSel2->LocalAddressCount || 421 (SpdSel1->NextLayerProtocol != SpdSel2->NextLayerProtocol && SpdSel2->NextLayerProtocol != 0xffff) || 422 (SpdSel1->LocalPort > SpdSel2->RemotePort && SpdSel2->RemotePort != 0)|| 423 (SpdSel1->LocalPortRange > SpdSel2->RemotePortRange && SpdSel1->RemotePort != 0)|| 424 (SpdSel1->RemotePort > SpdSel2->LocalPort && SpdSel2->LocalPort != 0) || 425 (SpdSel1->RemotePortRange > SpdSel2->LocalPortRange && SpdSel2->LocalPort != 0) 426 ) { 427 IsMatch = FALSE; 428 return IsMatch; 429 } 430 431 // 432 // Compare the all LocalAddress and RemoteAddress fields in the two Spdselectors. 433 // First, SpdSel1->LocalAddress to SpdSel2->RemoteAddress && Compare 434 // SpdSel1->RemoteAddress to SpdSel2->LocalAddress. If all match, return 435 // TRUE. 436 // 437 for (Index = 0; Index < SpdSel1->LocalAddressCount; Index++) { 438 if (!IsInAddressInfoList ( 439 &SpdSel1->LocalAddress[Index], 440 SpdSel2->RemoteAddress, 441 SpdSel2->RemoteAddressCount 442 )) { 443 IsMatch = FALSE; 444 break; 445 } 446 } 447 448 if (IsMatch) { 449 for (Index = 0; Index < SpdSel1->RemoteAddressCount; Index++) { 450 if (!IsInAddressInfoList ( 451 &SpdSel1->RemoteAddress[Index], 452 SpdSel2->LocalAddress, 453 SpdSel2->LocalAddressCount 454 )) { 455 IsMatch = FALSE; 456 break; 457 } 458 } 459 } 460 return IsMatch; 461 462 } 463 464 /** 465 Compare two SA IDs. 466 467 @param[in] Selector1 Pointer of first SA ID. 468 @param[in] Selector2 Pointer of second SA ID. 469 470 @retval TRUE This two Selectors have the same SA ID. 471 @retval FALSE This two Selecotrs don't have the same SA ID. 472 473 **/ 474 BOOLEAN 475 CompareSaId ( 476 IN EFI_IPSEC_CONFIG_SELECTOR *Selector1, 477 IN EFI_IPSEC_CONFIG_SELECTOR *Selector2 478 ) 479 { 480 EFI_IPSEC_SA_ID *SaId1; 481 EFI_IPSEC_SA_ID *SaId2; 482 BOOLEAN IsMatch; 483 484 SaId1 = &Selector1->SaId; 485 SaId2 = &Selector2->SaId; 486 IsMatch = TRUE; 487 488 if (CompareMem (SaId1, SaId2, sizeof (EFI_IPSEC_SA_ID)) != 0) { 489 IsMatch = FALSE; 490 } 491 492 return IsMatch; 493 } 494 495 /** 496 Compare two PAD IDs. 497 498 @param[in] Selector1 Pointer of first PAD ID. 499 @param[in] Selector2 Pointer of second PAD ID. 500 501 @retval TRUE This two Selectors have the same PAD ID. 502 @retval FALSE This two Selecotrs don't have the same PAD ID. 503 504 **/ 505 BOOLEAN 506 ComparePadId ( 507 IN EFI_IPSEC_CONFIG_SELECTOR *Selector1, 508 IN EFI_IPSEC_CONFIG_SELECTOR *Selector2 509 ) 510 { 511 EFI_IPSEC_PAD_ID *PadId1; 512 EFI_IPSEC_PAD_ID *PadId2; 513 BOOLEAN IsMatch; 514 515 PadId1 = &Selector1->PadId; 516 PadId2 = &Selector2->PadId; 517 IsMatch = TRUE; 518 519 // 520 // Compare the PeerIdValid fields in PadId. 521 // 522 if (PadId1->PeerIdValid != PadId2->PeerIdValid) { 523 IsMatch = FALSE; 524 } 525 // 526 // Compare the PeerId fields in PadId if PeerIdValid is true. 527 // 528 if (IsMatch && 529 PadId1->PeerIdValid && 530 AsciiStriCmp ((CONST CHAR8 *) PadId1->Id.PeerId, (CONST CHAR8 *) PadId2->Id.PeerId) != 0 531 ) { 532 IsMatch = FALSE; 533 } 534 // 535 // Compare the IpAddress fields in PadId if PeerIdValid is false. 536 // 537 if (IsMatch && 538 !PadId1->PeerIdValid && 539 (PadId1->Id.IpAddress.PrefixLength != PadId2->Id.IpAddress.PrefixLength || 540 CompareMem (&PadId1->Id.IpAddress.Address, &PadId2->Id.IpAddress.Address, sizeof (EFI_IP_ADDRESS)) != 0) 541 ) { 542 IsMatch = FALSE; 543 } 544 545 return IsMatch; 546 } 547 548 /** 549 Check if the SPD Selector is Zero by its LocalAddressCount and RemoteAddressCount 550 fields. 551 552 @param[in] Selector Pointer of the SPD Selector. 553 554 @retval TRUE If the SPD Selector is Zero. 555 @retval FALSE If the SPD Selector is not Zero. 556 557 **/ 558 BOOLEAN 559 IsZeroSpdSelector ( 560 IN EFI_IPSEC_CONFIG_SELECTOR *Selector 561 ) 562 { 563 EFI_IPSEC_SPD_SELECTOR *SpdSel; 564 BOOLEAN IsZero; 565 566 SpdSel = &Selector->SpdSelector; 567 IsZero = FALSE; 568 569 if (SpdSel->LocalAddressCount == 0 && SpdSel->RemoteAddressCount == 0) { 570 IsZero = TRUE; 571 } 572 573 return IsZero; 574 } 575 576 /** 577 Check if the SA ID is Zero by its DestAddress. 578 579 @param[in] Selector Pointer of the SA ID. 580 581 @retval TRUE If the SA ID is Zero. 582 @retval FALSE If the SA ID is not Zero. 583 584 **/ 585 BOOLEAN 586 IsZeroSaId ( 587 IN EFI_IPSEC_CONFIG_SELECTOR *Selector 588 ) 589 { 590 BOOLEAN IsZero; 591 EFI_IPSEC_CONFIG_SELECTOR ZeroSelector; 592 593 IsZero = FALSE; 594 595 ZeroMem (&ZeroSelector, sizeof (EFI_IPSEC_CONFIG_SELECTOR)); 596 597 if (CompareMem (&ZeroSelector, Selector, sizeof (EFI_IPSEC_CONFIG_SELECTOR)) == 0) { 598 IsZero = TRUE; 599 } 600 601 return IsZero; 602 } 603 604 /** 605 Check if the PAD ID is Zero. 606 607 @param[in] Selector Pointer of the PAD ID. 608 609 @retval TRUE If the PAD ID is Zero. 610 @retval FALSE If the PAD ID is not Zero. 611 612 **/ 613 BOOLEAN 614 IsZeroPadId ( 615 IN EFI_IPSEC_CONFIG_SELECTOR *Selector 616 ) 617 { 618 EFI_IPSEC_PAD_ID *PadId; 619 EFI_IPSEC_PAD_ID ZeroId; 620 BOOLEAN IsZero; 621 622 PadId = &Selector->PadId; 623 IsZero = FALSE; 624 625 ZeroMem (&ZeroId, sizeof (EFI_IPSEC_PAD_ID)); 626 627 if (CompareMem (PadId, &ZeroId, sizeof (EFI_IPSEC_PAD_ID)) == 0) { 628 IsZero = TRUE; 629 } 630 631 return IsZero; 632 } 633 634 /** 635 Copy Source SPD Selector to the Destination SPD Selector. 636 637 @param[in, out] DstSel Pointer of Destination SPD Selector. 638 @param[in] SrcSel Pointer of Source SPD Selector. 639 @param[in, out] Size The size of the Destination SPD Selector. If it 640 not NULL and its value less than the size of 641 Source SPD Selector, the value of Source SPD 642 Selector's size will be passed to caller by this 643 parameter. 644 645 @retval EFI_INVALID_PARAMETER If the Destination or Source SPD Selector is NULL 646 @retval EFI_BUFFER_TOO_SMALL If the input Size is less than size of the Source SPD Selector. 647 @retval EFI_SUCCESS Copy Source SPD Selector to the Destination SPD 648 Selector successfully. 649 650 **/ 651 EFI_STATUS 652 DuplicateSpdSelector ( 653 IN OUT EFI_IPSEC_CONFIG_SELECTOR *DstSel, 654 IN EFI_IPSEC_CONFIG_SELECTOR *SrcSel, 655 IN OUT UINTN *Size 656 ) 657 { 658 EFI_IPSEC_SPD_SELECTOR *Dst; 659 EFI_IPSEC_SPD_SELECTOR *Src; 660 661 Dst = &DstSel->SpdSelector; 662 Src = &SrcSel->SpdSelector; 663 664 if (Dst == NULL || Src == NULL) { 665 return EFI_INVALID_PARAMETER; 666 } 667 668 if (Size != NULL && (*Size) < SIZE_OF_SPD_SELECTOR (Src)) { 669 *Size = SIZE_OF_SPD_SELECTOR (Src); 670 return EFI_BUFFER_TOO_SMALL; 671 } 672 // 673 // Copy the base structure of SPD selector. 674 // 675 CopyMem (Dst, Src, sizeof (EFI_IPSEC_SPD_SELECTOR)); 676 677 // 678 // Copy the local address array of SPD selector. 679 // 680 Dst->LocalAddress = (EFI_IP_ADDRESS_INFO *) (Dst + 1); 681 CopyMem ( 682 Dst->LocalAddress, 683 Src->LocalAddress, 684 sizeof (EFI_IP_ADDRESS_INFO) * Dst->LocalAddressCount 685 ); 686 687 // 688 // Copy the remote address array of SPD selector. 689 // 690 Dst->RemoteAddress = Dst->LocalAddress + Dst->LocalAddressCount; 691 CopyMem ( 692 Dst->RemoteAddress, 693 Src->RemoteAddress, 694 sizeof (EFI_IP_ADDRESS_INFO) * Dst->RemoteAddressCount 695 ); 696 697 return EFI_SUCCESS; 698 } 699 700 /** 701 Copy Source SA ID to the Destination SA ID. 702 703 @param[in, out] DstSel Pointer of Destination SA ID. 704 @param[in] SrcSel Pointer of Source SA ID. 705 @param[in, out] Size The size of the Destination SA ID. If it 706 not NULL and its value less than the size of 707 Source SA ID, the value of Source SA ID's size 708 will be passed to caller by this parameter. 709 710 @retval EFI_INVALID_PARAMETER If the Destination or Source SA ID is NULL. 711 @retval EFI_BUFFER_TOO_SMALL If the input Size less than size of source SA ID. 712 @retval EFI_SUCCESS Copy Source SA ID to the Destination SA ID successfully. 713 714 **/ 715 EFI_STATUS 716 DuplicateSaId ( 717 IN OUT EFI_IPSEC_CONFIG_SELECTOR *DstSel, 718 IN EFI_IPSEC_CONFIG_SELECTOR *SrcSel, 719 IN OUT UINTN *Size 720 ) 721 { 722 EFI_IPSEC_SA_ID *Dst; 723 EFI_IPSEC_SA_ID *Src; 724 725 Dst = &DstSel->SaId; 726 Src = &SrcSel->SaId; 727 728 if (Dst == NULL || Src == NULL) { 729 return EFI_INVALID_PARAMETER; 730 } 731 732 if (Size != NULL && *Size < sizeof (EFI_IPSEC_SA_ID)) { 733 *Size = sizeof (EFI_IPSEC_SA_ID); 734 return EFI_BUFFER_TOO_SMALL; 735 } 736 737 CopyMem (Dst, Src, sizeof (EFI_IPSEC_SA_ID)); 738 739 return EFI_SUCCESS; 740 } 741 742 /** 743 Copy Source PAD ID to the Destination PAD ID. 744 745 @param[in, out] DstSel Pointer of Destination PAD ID. 746 @param[in] SrcSel Pointer of Source PAD ID. 747 @param[in, out] Size The size of the Destination PAD ID. If it 748 not NULL and its value less than the size of 749 Source PAD ID, the value of Source PAD ID's size 750 will be passed to caller by this parameter. 751 752 @retval EFI_INVALID_PARAMETER If the Destination or Source PAD ID is NULL. 753 @retval EFI_BUFFER_TOO_SMALL If the input Size less than size of source PAD ID . 754 @retval EFI_SUCCESS Copy Source PAD ID to the Destination PAD ID successfully. 755 756 **/ 757 EFI_STATUS 758 DuplicatePadId ( 759 IN OUT EFI_IPSEC_CONFIG_SELECTOR *DstSel, 760 IN EFI_IPSEC_CONFIG_SELECTOR *SrcSel, 761 IN OUT UINTN *Size 762 ) 763 { 764 EFI_IPSEC_PAD_ID *Dst; 765 EFI_IPSEC_PAD_ID *Src; 766 767 Dst = &DstSel->PadId; 768 Src = &SrcSel->PadId; 769 770 if (Dst == NULL || Src == NULL) { 771 return EFI_INVALID_PARAMETER; 772 } 773 774 if (Size != NULL && *Size < sizeof (EFI_IPSEC_PAD_ID)) { 775 *Size = sizeof (EFI_IPSEC_PAD_ID); 776 return EFI_BUFFER_TOO_SMALL; 777 } 778 779 CopyMem (Dst, Src, sizeof (EFI_IPSEC_PAD_ID)); 780 781 return EFI_SUCCESS; 782 } 783 784 /** 785 Fix the value of some members of SPD Selector. 786 787 This function is called by IpSecCopyPolicyEntry()which copy the Policy 788 Entry into the Variable. Since some members in SPD Selector are pointers, 789 a physical address to relative address convertion is required before copying 790 this SPD entry into the variable. 791 792 @param[in] Selector Pointer of SPD Selector. 793 @param[in, out] Data Pointer of SPD Data. 794 795 **/ 796 VOID 797 FixSpdEntry ( 798 IN EFI_IPSEC_SPD_SELECTOR *Selector, 799 IN OUT EFI_IPSEC_SPD_DATA *Data 800 ) 801 { 802 // 803 // It assumes that all ref buffers in SPD selector and data are 804 // stored in the continous memory and close to the base structure. 805 // 806 FIX_REF_BUF_ADDR (Selector->LocalAddress, Selector); 807 FIX_REF_BUF_ADDR (Selector->RemoteAddress, Selector); 808 809 if (Data->ProcessingPolicy != NULL) { 810 if (Data->ProcessingPolicy->TunnelOption != NULL) { 811 FIX_REF_BUF_ADDR (Data->ProcessingPolicy->TunnelOption, Data); 812 } 813 814 FIX_REF_BUF_ADDR (Data->ProcessingPolicy, Data); 815 } 816 817 } 818 819 /** 820 Fix the value of some members of SA ID. 821 822 This function is called by IpSecCopyPolicyEntry()which copy the Policy 823 Entry into the Variable. Since some members in SA ID are pointers, 824 a physical address to relative address conversion is required before copying 825 this SAD into the variable. 826 827 @param[in] SaId Pointer of SA ID 828 @param[in, out] Data Pointer of SA Data. 829 830 **/ 831 VOID 832 FixSadEntry ( 833 IN EFI_IPSEC_SA_ID *SaId, 834 IN OUT EFI_IPSEC_SA_DATA2 *Data 835 ) 836 { 837 // 838 // It assumes that all ref buffers in SAD selector and data are 839 // stored in the continous memory and close to the base structure. 840 // 841 if (Data->AlgoInfo.EspAlgoInfo.AuthKey != NULL) { 842 FIX_REF_BUF_ADDR (Data->AlgoInfo.EspAlgoInfo.AuthKey, Data); 843 } 844 845 if (SaId->Proto == EfiIPsecESP && Data->AlgoInfo.EspAlgoInfo.EncKey != NULL) { 846 FIX_REF_BUF_ADDR (Data->AlgoInfo.EspAlgoInfo.EncKey, Data); 847 } 848 849 if (Data->SpdSelector != NULL) { 850 if (Data->SpdSelector->LocalAddress != NULL) { 851 FIX_REF_BUF_ADDR (Data->SpdSelector->LocalAddress, Data); 852 } 853 854 FIX_REF_BUF_ADDR (Data->SpdSelector->RemoteAddress, Data); 855 FIX_REF_BUF_ADDR (Data->SpdSelector, Data); 856 } 857 858 } 859 860 /** 861 Fix the value of some members of PAD ID. 862 863 This function is called by IpSecCopyPolicyEntry()which copy the Policy 864 Entry into the Variable. Since some members in PAD ID are pointers, 865 a physical address to relative address conversion is required before copying 866 this PAD into the variable. 867 868 @param[in] PadId Pointer of PAD ID. 869 @param[in, out] Data Pointer of PAD Data. 870 871 **/ 872 VOID 873 FixPadEntry ( 874 IN EFI_IPSEC_PAD_ID *PadId, 875 IN OUT EFI_IPSEC_PAD_DATA *Data 876 ) 877 { 878 // 879 // It assumes that all ref buffers in pad selector and data are 880 // stored in the continous memory and close to the base structure. 881 // 882 if (Data->AuthData != NULL) { 883 FIX_REF_BUF_ADDR (Data->AuthData, Data); 884 } 885 886 if (Data->RevocationData != NULL) { 887 FIX_REF_BUF_ADDR (Data->RevocationData, Data); 888 } 889 890 } 891 892 /** 893 Recover the value of some members of SPD Selector. 894 895 This function is corresponding to FixSpdEntry(). It recovers the value of members 896 of SPD Selector that are fixed by FixSpdEntry(). 897 898 @param[in, out] Selector Pointer of SPD Selector. 899 @param[in, out] Data Pointer of SPD Data. 900 901 **/ 902 VOID 903 UnfixSpdEntry ( 904 IN OUT EFI_IPSEC_SPD_SELECTOR *Selector, 905 IN OUT EFI_IPSEC_SPD_DATA *Data 906 ) 907 { 908 // 909 // It assumes that all ref buffers in SPD selector and data are 910 // stored in the continous memory and close to the base structure. 911 // 912 UNFIX_REF_BUF_ADDR (Selector->LocalAddress, Selector); 913 UNFIX_REF_BUF_ADDR (Selector->RemoteAddress, Selector); 914 915 if (Data->ProcessingPolicy != NULL) { 916 UNFIX_REF_BUF_ADDR (Data->ProcessingPolicy, Data); 917 if (Data->ProcessingPolicy->TunnelOption != NULL) { 918 UNFIX_REF_BUF_ADDR (Data->ProcessingPolicy->TunnelOption, Data); 919 } 920 } 921 922 } 923 924 /** 925 Recover the value of some members of SA ID. 926 927 This function is corresponding to FixSadEntry(). It recovers the value of members 928 of SAD ID that are fixed by FixSadEntry(). 929 930 @param[in, out] SaId Pointer of SAD ID. 931 @param[in, out] Data Pointer of SAD Data. 932 933 **/ 934 VOID 935 UnfixSadEntry ( 936 IN OUT EFI_IPSEC_SA_ID *SaId, 937 IN OUT EFI_IPSEC_SA_DATA2 *Data 938 ) 939 { 940 // 941 // It assumes that all ref buffers in SAD selector and data are 942 // stored in the continous memory and close to the base structure. 943 // 944 if (Data->AlgoInfo.EspAlgoInfo.AuthKey != NULL) { 945 UNFIX_REF_BUF_ADDR (Data->AlgoInfo.EspAlgoInfo.AuthKey, Data); 946 } 947 948 if (SaId->Proto == EfiIPsecESP && Data->AlgoInfo.EspAlgoInfo.EncKey != NULL) { 949 UNFIX_REF_BUF_ADDR (Data->AlgoInfo.EspAlgoInfo.EncKey, Data); 950 } 951 952 if (Data->SpdSelector != NULL) { 953 UNFIX_REF_BUF_ADDR (Data->SpdSelector, Data); 954 if (Data->SpdSelector->LocalAddress != NULL) { 955 UNFIX_REF_BUF_ADDR (Data->SpdSelector->LocalAddress, Data); 956 } 957 958 UNFIX_REF_BUF_ADDR (Data->SpdSelector->RemoteAddress, Data); 959 } 960 961 } 962 963 /** 964 Recover the value of some members of PAD ID. 965 966 This function is corresponding to FixPadEntry(). It recovers the value of members 967 of PAD ID that are fixed by FixPadEntry(). 968 969 @param[in] PadId Pointer of PAD ID. 970 @param[in, out] Data Pointer of PAD Data. 971 972 **/ 973 VOID 974 UnfixPadEntry ( 975 IN EFI_IPSEC_PAD_ID *PadId, 976 IN OUT EFI_IPSEC_PAD_DATA *Data 977 ) 978 { 979 // 980 // It assumes that all ref buffers in pad selector and data are 981 // stored in the continous memory and close to the base structure. 982 // 983 if (Data->AuthData != NULL) { 984 UNFIX_REF_BUF_ADDR (Data->AuthData, Data); 985 } 986 987 if (Data->RevocationData != NULL) { 988 UNFIX_REF_BUF_ADDR (Data->RevocationData, Data); 989 } 990 991 } 992 993 /** 994 Set the security policy information for the EFI IPsec driver. 995 996 The IPsec configuration data has a unique selector/identifier separately to 997 identify a data entry. 998 999 @param[in] Selector Pointer to an entry selector on operated 1000 configuration data specified by DataType. 1001 A NULL Selector causes the entire specified-type 1002 configuration information to be flushed. 1003 @param[in] Data The data buffer to be set. The structure 1004 of the data buffer should be EFI_IPSEC_SPD_DATA. 1005 @param[in] Context Pointer to one entry selector that describes 1006 the expected position the new data entry will 1007 be added. If Context is NULL, the new entry will 1008 be appended the end of database. 1009 1010 @retval EFI_INVALID_PARAMETER One or more of the following are TRUE: 1011 - Selector is not NULL and its LocalAddress 1012 is NULL or its RemoteAddress is NULL. 1013 - Data is not NULL and its Action is Protected 1014 and its plolicy is NULL. 1015 - Data is not NULL, its Action is not protected, 1016 and its policy is not NULL. 1017 - The Action of Data is Protected, its policy 1018 mode is Tunnel, and its tunnel option is NULL. 1019 - The Action of Data is protected and its policy 1020 mode is not Tunnel and it tunnel option is not NULL. 1021 - SadEntry requied to be set into new SpdEntry's Sas has 1022 been found but it is invalid. 1023 @retval EFI_OUT_OF_RESOURCED The required system resource could not be allocated. 1024 @retval EFI_SUCCESS The specified configuration data was obtained successfully. 1025 1026 **/ 1027 EFI_STATUS 1028 SetSpdEntry ( 1029 IN EFI_IPSEC_CONFIG_SELECTOR *Selector, 1030 IN VOID *Data, 1031 IN VOID *Context OPTIONAL 1032 ) 1033 { 1034 EFI_IPSEC_SPD_SELECTOR *SpdSel; 1035 EFI_IPSEC_SPD_DATA *SpdData; 1036 EFI_IPSEC_SPD_SELECTOR *InsertBefore; 1037 LIST_ENTRY *SpdList; 1038 LIST_ENTRY *SadList; 1039 LIST_ENTRY *SpdSas; 1040 LIST_ENTRY *EntryInsertBefore; 1041 LIST_ENTRY *Entry; 1042 LIST_ENTRY *Entry2; 1043 LIST_ENTRY *NextEntry; 1044 LIST_ENTRY *NextEntry2; 1045 IPSEC_SPD_ENTRY *SpdEntry; 1046 IPSEC_SAD_ENTRY *SadEntry; 1047 UINTN SpdEntrySize; 1048 UINTN Index; 1049 1050 SpdSel = (Selector == NULL) ? NULL : &Selector->SpdSelector; 1051 SpdData = (Data == NULL) ? NULL : (EFI_IPSEC_SPD_DATA *) Data; 1052 InsertBefore = (Context == NULL) ? NULL : &((EFI_IPSEC_CONFIG_SELECTOR *) Context)->SpdSelector; 1053 SpdList = &mConfigData[IPsecConfigDataTypeSpd]; 1054 1055 if (SpdSel != NULL) { 1056 if (SpdSel->LocalAddress == NULL || SpdSel->RemoteAddress == NULL) { 1057 return EFI_INVALID_PARAMETER; 1058 } 1059 } 1060 1061 if (SpdData != NULL) { 1062 if ((SpdData->Action == EfiIPsecActionProtect && SpdData->ProcessingPolicy == NULL) || 1063 (SpdData->Action != EfiIPsecActionProtect && SpdData->ProcessingPolicy != NULL) 1064 ) { 1065 return EFI_INVALID_PARAMETER; 1066 } 1067 1068 if (SpdData->Action == EfiIPsecActionProtect) { 1069 if ((SpdData->ProcessingPolicy->Mode == EfiIPsecTunnel && SpdData->ProcessingPolicy->TunnelOption == NULL) || 1070 (SpdData->ProcessingPolicy->Mode != EfiIPsecTunnel && SpdData->ProcessingPolicy->TunnelOption != NULL) 1071 ) { 1072 return EFI_INVALID_PARAMETER; 1073 } 1074 } 1075 } 1076 // 1077 // The default behavior is to insert the node ahead of the header. 1078 // 1079 EntryInsertBefore = SpdList; 1080 1081 // 1082 // Remove the existed SPD entry. 1083 // 1084 NET_LIST_FOR_EACH_SAFE (Entry, NextEntry, SpdList) { 1085 1086 SpdEntry = IPSEC_SPD_ENTRY_FROM_LIST (Entry); 1087 1088 if (SpdSel == NULL || 1089 CompareSpdSelector ((EFI_IPSEC_CONFIG_SELECTOR *) SpdEntry->Selector, (EFI_IPSEC_CONFIG_SELECTOR *) SpdSel) 1090 ) { 1091 // 1092 // Record the existed entry position to keep the original order. 1093 // 1094 EntryInsertBefore = SpdEntry->List.ForwardLink; 1095 RemoveEntryList (&SpdEntry->List); 1096 1097 // 1098 // Update the reverse ref of SAD entry in the SPD.sas list. 1099 // 1100 SpdSas = &SpdEntry->Data->Sas; 1101 1102 // 1103 // Remove the related SAs from Sas(SadEntry->BySpd). If the SA entry is established by 1104 // IKE, remove from mConfigData list(SadEntry->List) and then free it directly since its 1105 // SpdEntry will be freed later. 1106 // 1107 NET_LIST_FOR_EACH_SAFE (Entry2, NextEntry2, SpdSas) { 1108 SadEntry = IPSEC_SAD_ENTRY_FROM_SPD (Entry2); 1109 1110 if (SadEntry->Data->SpdEntry != NULL) { 1111 RemoveEntryList (&SadEntry->BySpd); 1112 SadEntry->Data->SpdEntry = NULL; 1113 } 1114 1115 if (!(SadEntry->Data->ManualSet)) { 1116 RemoveEntryList (&SadEntry->List); 1117 FreePool (SadEntry); 1118 } 1119 } 1120 1121 // 1122 // Free the existed SPD entry 1123 // 1124 FreePool (SpdEntry); 1125 } 1126 } 1127 // 1128 // Return success here if only want to remove the SPD entry. 1129 // 1130 if (SpdData == NULL || SpdSel == NULL) { 1131 return EFI_SUCCESS; 1132 } 1133 // 1134 // Search the appointed entry position if InsertBefore is not NULL. 1135 // 1136 if (InsertBefore != NULL) { 1137 1138 NET_LIST_FOR_EACH (Entry, SpdList) { 1139 SpdEntry = IPSEC_SPD_ENTRY_FROM_LIST (Entry); 1140 1141 if (CompareSpdSelector ( 1142 (EFI_IPSEC_CONFIG_SELECTOR *) SpdEntry->Selector, 1143 (EFI_IPSEC_CONFIG_SELECTOR *) InsertBefore 1144 )) { 1145 EntryInsertBefore = Entry; 1146 break; 1147 } 1148 } 1149 } 1150 1151 // 1152 // Do Padding for the different Arch. 1153 // 1154 SpdEntrySize = ALIGN_VARIABLE (sizeof (IPSEC_SPD_ENTRY)); 1155 SpdEntrySize = ALIGN_VARIABLE (SpdEntrySize + (UINTN)SIZE_OF_SPD_SELECTOR (SpdSel)); 1156 SpdEntrySize += IpSecGetSizeOfEfiSpdData (SpdData); 1157 1158 SpdEntry = AllocateZeroPool (SpdEntrySize); 1159 1160 if (SpdEntry == NULL) { 1161 return EFI_OUT_OF_RESOURCES; 1162 } 1163 // 1164 // Fix the address of Selector and Data buffer and copy them, which is 1165 // continous memory and close to the base structure of SPD entry. 1166 // 1167 SpdEntry->Selector = (EFI_IPSEC_SPD_SELECTOR *) ALIGN_POINTER ((SpdEntry + 1), sizeof (UINTN)); 1168 SpdEntry->Data = (IPSEC_SPD_DATA *) ALIGN_POINTER ( 1169 ((UINT8 *) SpdEntry->Selector + SIZE_OF_SPD_SELECTOR (SpdSel)), 1170 sizeof (UINTN) 1171 ); 1172 1173 DuplicateSpdSelector ( 1174 (EFI_IPSEC_CONFIG_SELECTOR *) SpdEntry->Selector, 1175 (EFI_IPSEC_CONFIG_SELECTOR *) SpdSel, 1176 NULL 1177 ); 1178 1179 CopyMem ( 1180 SpdEntry->Data->Name, 1181 SpdData->Name, 1182 sizeof (SpdData->Name) 1183 ); 1184 SpdEntry->Data->PackageFlag = SpdData->PackageFlag; 1185 SpdEntry->Data->TrafficDirection = SpdData->TrafficDirection; 1186 SpdEntry->Data->Action = SpdData->Action; 1187 1188 // 1189 // Fix the address of ProcessingPolicy and copy it if need, which is continous 1190 // memory and close to the base structure of SAD data. 1191 // 1192 if (SpdData->Action != EfiIPsecActionProtect) { 1193 SpdEntry->Data->ProcessingPolicy = NULL; 1194 } else { 1195 SpdEntry->Data->ProcessingPolicy = (EFI_IPSEC_PROCESS_POLICY *) ALIGN_POINTER ( 1196 SpdEntry->Data + 1, 1197 sizeof (UINTN) 1198 ); 1199 IpSecDuplicateProcessPolicy (SpdEntry->Data->ProcessingPolicy, SpdData->ProcessingPolicy); 1200 } 1201 // 1202 // Update the sas list of the new SPD entry. 1203 // 1204 InitializeListHead (&SpdEntry->Data->Sas); 1205 1206 SadList = &mConfigData[IPsecConfigDataTypeSad]; 1207 1208 NET_LIST_FOR_EACH (Entry, SadList) { 1209 SadEntry = IPSEC_SAD_ENTRY_FROM_LIST (Entry); 1210 1211 for (Index = 0; Index < SpdData->SaIdCount; Index++) { 1212 if (CompareSaId ( 1213 (EFI_IPSEC_CONFIG_SELECTOR *) &SpdData->SaId[Index], 1214 (EFI_IPSEC_CONFIG_SELECTOR *) SadEntry->Id 1215 )) { 1216 // 1217 // Check whether the found SadEntry is vaild. 1218 // 1219 if (IsSubSpdSelector ( 1220 (EFI_IPSEC_CONFIG_SELECTOR *) SadEntry->Data->SpdSelector, 1221 (EFI_IPSEC_CONFIG_SELECTOR *) SpdEntry->Selector 1222 )) { 1223 if (SadEntry->Data->SpdEntry != NULL) { 1224 RemoveEntryList (&SadEntry->BySpd); 1225 } 1226 InsertTailList (&SpdEntry->Data->Sas, &SadEntry->BySpd); 1227 SadEntry->Data->SpdEntry = SpdEntry; 1228 } else { 1229 return EFI_INVALID_PARAMETER; 1230 } 1231 } 1232 } 1233 } 1234 1235 // 1236 // Insert the new SPD entry. 1237 // 1238 InsertTailList (EntryInsertBefore, &SpdEntry->List); 1239 1240 return EFI_SUCCESS; 1241 } 1242 1243 /** 1244 Set the security association information for the EFI IPsec driver. 1245 1246 The IPsec configuration data has a unique selector/identifier separately to 1247 identify a data entry. 1248 1249 @param[in] Selector Pointer to an entry selector on operated 1250 configuration data specified by DataType. 1251 A NULL Selector causes the entire specified-type 1252 configuration information to be flushed. 1253 @param[in] Data The data buffer to be set. The structure 1254 of the data buffer should be EFI_IPSEC_SA_DATA. 1255 @param[in] Context Pointer to one entry selector which describes 1256 the expected position the new data entry will 1257 be added. If Context is NULL,the new entry will 1258 be appended the end of database. 1259 1260 @retval EFI_OUT_OF_RESOURCED The required system resource could not be allocated. 1261 @retval EFI_SUCCESS The specified configuration data was obtained successfully. 1262 1263 **/ 1264 EFI_STATUS 1265 SetSadEntry ( 1266 IN EFI_IPSEC_CONFIG_SELECTOR *Selector, 1267 IN VOID *Data, 1268 IN VOID *Context OPTIONAL 1269 ) 1270 { 1271 IPSEC_SAD_ENTRY *SadEntry; 1272 IPSEC_SPD_ENTRY *SpdEntry; 1273 LIST_ENTRY *Entry; 1274 LIST_ENTRY *NextEntry; 1275 LIST_ENTRY *SadList; 1276 LIST_ENTRY *SpdList; 1277 EFI_IPSEC_SA_ID *SaId; 1278 EFI_IPSEC_SA_DATA2 *SaData; 1279 EFI_IPSEC_SA_ID *InsertBefore; 1280 LIST_ENTRY *EntryInsertBefore; 1281 UINTN SadEntrySize; 1282 1283 SaId = (Selector == NULL) ? NULL : &Selector->SaId; 1284 SaData = (Data == NULL) ? NULL : (EFI_IPSEC_SA_DATA2 *) Data; 1285 InsertBefore = (Context == NULL) ? NULL : &((EFI_IPSEC_CONFIG_SELECTOR *) Context)->SaId; 1286 SadList = &mConfigData[IPsecConfigDataTypeSad]; 1287 1288 // 1289 // The default behavior is to insert the node ahead of the header. 1290 // 1291 EntryInsertBefore = SadList; 1292 1293 // 1294 // Remove the existed SAD entry. 1295 // 1296 NET_LIST_FOR_EACH_SAFE (Entry, NextEntry, SadList) { 1297 1298 SadEntry = IPSEC_SAD_ENTRY_FROM_LIST (Entry); 1299 1300 if (SaId == NULL || 1301 CompareSaId ( 1302 (EFI_IPSEC_CONFIG_SELECTOR *) SadEntry->Id, 1303 (EFI_IPSEC_CONFIG_SELECTOR *) SaId 1304 )) { 1305 // 1306 // Record the existed entry position to keep the original order. 1307 // 1308 EntryInsertBefore = SadEntry->List.ForwardLink; 1309 1310 // 1311 // Update the related SAD.byspd field. 1312 // 1313 if (SadEntry->Data->SpdEntry != NULL) { 1314 RemoveEntryList (&SadEntry->BySpd); 1315 } 1316 1317 RemoveEntryList (&SadEntry->List); 1318 FreePool (SadEntry); 1319 } 1320 } 1321 // 1322 // Return success here if only want to remove the SAD entry 1323 // 1324 if (SaData == NULL || SaId == NULL) { 1325 return EFI_SUCCESS; 1326 } 1327 // 1328 // Search the appointed entry position if InsertBefore is not NULL. 1329 // 1330 if (InsertBefore != NULL) { 1331 1332 NET_LIST_FOR_EACH (Entry, SadList) { 1333 SadEntry = IPSEC_SAD_ENTRY_FROM_LIST (Entry); 1334 1335 if (CompareSaId ( 1336 (EFI_IPSEC_CONFIG_SELECTOR *) SadEntry->Id, 1337 (EFI_IPSEC_CONFIG_SELECTOR *) InsertBefore 1338 )) { 1339 EntryInsertBefore = Entry; 1340 break; 1341 } 1342 } 1343 } 1344 1345 // 1346 // Do Padding for different Arch. 1347 // 1348 SadEntrySize = ALIGN_VARIABLE (sizeof (IPSEC_SAD_ENTRY)); 1349 SadEntrySize = ALIGN_VARIABLE (SadEntrySize + sizeof (EFI_IPSEC_SA_ID)); 1350 SadEntrySize = ALIGN_VARIABLE (SadEntrySize + sizeof (IPSEC_SAD_DATA)); 1351 1352 if (SaId->Proto == EfiIPsecAH) { 1353 SadEntrySize += SaData->AlgoInfo.AhAlgoInfo.AuthKeyLength; 1354 } else { 1355 SadEntrySize = ALIGN_VARIABLE (SadEntrySize + SaData->AlgoInfo.EspAlgoInfo.AuthKeyLength); 1356 SadEntrySize += ALIGN_VARIABLE (SaData->AlgoInfo.EspAlgoInfo.EncKeyLength); 1357 } 1358 1359 if (SaData->SpdSelector != NULL) { 1360 SadEntrySize += SadEntrySize + (UINTN)SIZE_OF_SPD_SELECTOR (SaData->SpdSelector); 1361 } 1362 SadEntry = AllocateZeroPool (SadEntrySize); 1363 1364 if (SadEntry == NULL) { 1365 return EFI_OUT_OF_RESOURCES; 1366 } 1367 // 1368 // Fix the address of Id and Data buffer and copy them, which is 1369 // continous memory and close to the base structure of SAD entry. 1370 // 1371 SadEntry->Id = (EFI_IPSEC_SA_ID *) ALIGN_POINTER ((SadEntry + 1), sizeof (UINTN)); 1372 SadEntry->Data = (IPSEC_SAD_DATA *) ALIGN_POINTER ((SadEntry->Id + 1), sizeof (UINTN)); 1373 1374 CopyMem (SadEntry->Id, SaId, sizeof (EFI_IPSEC_SA_ID)); 1375 1376 SadEntry->Data->Mode = SaData->Mode; 1377 SadEntry->Data->SequenceNumber = SaData->SNCount; 1378 SadEntry->Data->AntiReplayWindowSize = SaData->AntiReplayWindows; 1379 1380 ZeroMem ( 1381 &SadEntry->Data->AntiReplayBitmap, 1382 sizeof (SadEntry->Data->AntiReplayBitmap) 1383 ); 1384 1385 ZeroMem ( 1386 &SadEntry->Data->AlgoInfo, 1387 sizeof (EFI_IPSEC_ALGO_INFO) 1388 ); 1389 1390 SadEntry->Data->AlgoInfo.EspAlgoInfo.AuthAlgoId = SaData->AlgoInfo.EspAlgoInfo.AuthAlgoId; 1391 SadEntry->Data->AlgoInfo.EspAlgoInfo.AuthKeyLength = SaData->AlgoInfo.EspAlgoInfo.AuthKeyLength; 1392 1393 if (SadEntry->Data->AlgoInfo.EspAlgoInfo.AuthKeyLength != 0) { 1394 SadEntry->Data->AlgoInfo.EspAlgoInfo.AuthKey = (VOID *) ALIGN_POINTER ((SadEntry->Data + 1), sizeof (UINTN)); 1395 CopyMem ( 1396 SadEntry->Data->AlgoInfo.EspAlgoInfo.AuthKey, 1397 SaData->AlgoInfo.EspAlgoInfo.AuthKey, 1398 SadEntry->Data->AlgoInfo.EspAlgoInfo.AuthKeyLength 1399 ); 1400 } 1401 1402 if (SaId->Proto == EfiIPsecESP) { 1403 SadEntry->Data->AlgoInfo.EspAlgoInfo.EncAlgoId = SaData->AlgoInfo.EspAlgoInfo.EncAlgoId; 1404 SadEntry->Data->AlgoInfo.EspAlgoInfo.EncKeyLength = SaData->AlgoInfo.EspAlgoInfo.EncKeyLength; 1405 1406 if (SadEntry->Data->AlgoInfo.EspAlgoInfo.EncKeyLength != 0) { 1407 SadEntry->Data->AlgoInfo.EspAlgoInfo.EncKey = (VOID *) ALIGN_POINTER ( 1408 ((UINT8 *) (SadEntry->Data + 1) + 1409 SadEntry->Data->AlgoInfo.EspAlgoInfo.AuthKeyLength), 1410 sizeof (UINTN) 1411 ); 1412 CopyMem ( 1413 SadEntry->Data->AlgoInfo.EspAlgoInfo.EncKey, 1414 SaData->AlgoInfo.EspAlgoInfo.EncKey, 1415 SadEntry->Data->AlgoInfo.EspAlgoInfo.EncKeyLength 1416 ); 1417 } 1418 } 1419 1420 CopyMem ( 1421 &SadEntry->Data->SaLifetime, 1422 &SaData->SaLifetime, 1423 sizeof (EFI_IPSEC_SA_LIFETIME) 1424 ); 1425 1426 SadEntry->Data->PathMTU = SaData->PathMTU; 1427 SadEntry->Data->SpdSelector = NULL; 1428 SadEntry->Data->ESNEnabled = FALSE; 1429 SadEntry->Data->ManualSet = SaData->ManualSet; 1430 1431 // 1432 // Copy Tunnel Source/Destination Address 1433 // 1434 if (SaData->Mode == EfiIPsecTunnel) { 1435 CopyMem ( 1436 &SadEntry->Data->TunnelDestAddress, 1437 &SaData->TunnelDestinationAddress, 1438 sizeof (EFI_IP_ADDRESS) 1439 ); 1440 CopyMem ( 1441 &SadEntry->Data->TunnelSourceAddress, 1442 &SaData->TunnelSourceAddress, 1443 sizeof (EFI_IP_ADDRESS) 1444 ); 1445 } 1446 // 1447 // Update the spd.sas list of the spd entry specified by SAD selector 1448 // 1449 SpdList = &mConfigData[IPsecConfigDataTypeSpd]; 1450 1451 for (Entry = SpdList->ForwardLink; Entry != SpdList && SaData->SpdSelector != NULL; Entry = Entry->ForwardLink) { 1452 1453 SpdEntry = IPSEC_SPD_ENTRY_FROM_LIST (Entry); 1454 if (IsSubSpdSelector ( 1455 (EFI_IPSEC_CONFIG_SELECTOR *) SaData->SpdSelector, 1456 (EFI_IPSEC_CONFIG_SELECTOR *) SpdEntry->Selector 1457 ) && SpdEntry->Data->Action == EfiIPsecActionProtect) { 1458 SadEntry->Data->SpdEntry = SpdEntry; 1459 SadEntry->Data->SpdSelector = (EFI_IPSEC_SPD_SELECTOR *)((UINT8 *)SadEntry + 1460 SadEntrySize - 1461 (UINTN)SIZE_OF_SPD_SELECTOR (SaData->SpdSelector) 1462 ); 1463 DuplicateSpdSelector ( 1464 (EFI_IPSEC_CONFIG_SELECTOR *) SadEntry->Data->SpdSelector, 1465 (EFI_IPSEC_CONFIG_SELECTOR *) SaData->SpdSelector, 1466 NULL 1467 ); 1468 InsertTailList (&SpdEntry->Data->Sas, &SadEntry->BySpd); 1469 } 1470 } 1471 // 1472 // Insert the new SAD entry. 1473 // 1474 InsertTailList (EntryInsertBefore, &SadEntry->List); 1475 1476 return EFI_SUCCESS; 1477 } 1478 1479 /** 1480 Set the peer authorization configuration information for the EFI IPsec driver. 1481 1482 The IPsec configuration data has a unique selector/identifier separately to 1483 identify a data entry. 1484 1485 @param[in] Selector Pointer to an entry selector on operated 1486 configuration data specified by DataType. 1487 A NULL Selector causes the entire specified-type 1488 configuration information to be flushed. 1489 @param[in] Data The data buffer to be set. The structure 1490 of the data buffer should be EFI_IPSEC_PAD_DATA. 1491 @param[in] Context Pointer to one entry selector that describes 1492 the expected position the new data entry will 1493 be added. If Context is NULL, the new entry will 1494 be appended the end of database. 1495 1496 @retval EFI_OUT_OF_RESOURCES The required system resources could not be allocated. 1497 @retval EFI_SUCCESS The specified configuration data was obtained successfully. 1498 1499 **/ 1500 EFI_STATUS 1501 SetPadEntry ( 1502 IN EFI_IPSEC_CONFIG_SELECTOR *Selector, 1503 IN VOID *Data, 1504 IN VOID *Context OPTIONAL 1505 ) 1506 { 1507 IPSEC_PAD_ENTRY *PadEntry; 1508 EFI_IPSEC_PAD_ID *PadId; 1509 EFI_IPSEC_PAD_DATA *PadData; 1510 LIST_ENTRY *PadList; 1511 LIST_ENTRY *Entry; 1512 LIST_ENTRY *NextEntry; 1513 EFI_IPSEC_PAD_ID *InsertBefore; 1514 LIST_ENTRY *EntryInsertBefore; 1515 UINTN PadEntrySize; 1516 1517 PadId = (Selector == NULL) ? NULL : &Selector->PadId; 1518 PadData = (Data == NULL) ? NULL : (EFI_IPSEC_PAD_DATA *) Data; 1519 InsertBefore = (Context == NULL) ? NULL : &((EFI_IPSEC_CONFIG_SELECTOR *) Context)->PadId; 1520 PadList = &mConfigData[IPsecConfigDataTypePad]; 1521 1522 // 1523 // The default behavior is to insert the node ahead of the header. 1524 // 1525 EntryInsertBefore = PadList; 1526 1527 // 1528 // Remove the existed pad entry. 1529 // 1530 NET_LIST_FOR_EACH_SAFE (Entry, NextEntry, PadList) { 1531 1532 PadEntry = IPSEC_PAD_ENTRY_FROM_LIST (Entry); 1533 1534 if (PadId == NULL || 1535 ComparePadId ((EFI_IPSEC_CONFIG_SELECTOR *) PadEntry->Id, (EFI_IPSEC_CONFIG_SELECTOR *) PadId) 1536 ) { 1537 // 1538 // Record the existed entry position to keep the original order. 1539 // 1540 EntryInsertBefore = PadEntry->List.ForwardLink; 1541 RemoveEntryList (&PadEntry->List); 1542 1543 FreePool (PadEntry); 1544 } 1545 } 1546 // 1547 // Return success here if only want to remove the pad entry 1548 // 1549 if (PadData == NULL || PadId == NULL) { 1550 return EFI_SUCCESS; 1551 } 1552 // 1553 // Search the appointed entry position if InsertBefore is not NULL. 1554 // 1555 if (InsertBefore != NULL) { 1556 1557 NET_LIST_FOR_EACH (Entry, PadList) { 1558 PadEntry = IPSEC_PAD_ENTRY_FROM_LIST (Entry); 1559 1560 if (ComparePadId ( 1561 (EFI_IPSEC_CONFIG_SELECTOR *) PadEntry->Id, 1562 (EFI_IPSEC_CONFIG_SELECTOR *) InsertBefore 1563 )) { 1564 EntryInsertBefore = Entry; 1565 break; 1566 } 1567 } 1568 } 1569 1570 // 1571 // Do PADDING for different arch. 1572 // 1573 PadEntrySize = ALIGN_VARIABLE (sizeof (IPSEC_PAD_ENTRY)); 1574 PadEntrySize = ALIGN_VARIABLE (PadEntrySize + sizeof (EFI_IPSEC_PAD_ID)); 1575 PadEntrySize = ALIGN_VARIABLE (PadEntrySize + sizeof (EFI_IPSEC_PAD_DATA)); 1576 PadEntrySize = ALIGN_VARIABLE (PadEntrySize + (PadData->AuthData != NULL ? PadData->AuthDataSize : 0)); 1577 PadEntrySize += PadData->RevocationData != NULL ? PadData->RevocationDataSize : 0; 1578 1579 PadEntry = AllocateZeroPool (PadEntrySize); 1580 1581 if (PadEntry == NULL) { 1582 return EFI_OUT_OF_RESOURCES; 1583 } 1584 // 1585 // Fix the address of Id and Data buffer and copy them, which is 1586 // continous memory and close to the base structure of pad entry. 1587 // 1588 PadEntry->Id = (EFI_IPSEC_PAD_ID *) ALIGN_POINTER ((PadEntry + 1), sizeof (UINTN)); 1589 PadEntry->Data = (EFI_IPSEC_PAD_DATA *) ALIGN_POINTER ((PadEntry->Id + 1), sizeof (UINTN)); 1590 1591 CopyMem (PadEntry->Id, PadId, sizeof (EFI_IPSEC_PAD_ID)); 1592 1593 PadEntry->Data->AuthProtocol = PadData->AuthProtocol; 1594 PadEntry->Data->AuthMethod = PadData->AuthMethod; 1595 PadEntry->Data->IkeIdFlag = PadData->IkeIdFlag; 1596 1597 if (PadData->AuthData != NULL) { 1598 PadEntry->Data->AuthDataSize = PadData->AuthDataSize; 1599 PadEntry->Data->AuthData = (VOID *) ALIGN_POINTER (PadEntry->Data + 1, sizeof (UINTN)); 1600 CopyMem ( 1601 PadEntry->Data->AuthData, 1602 PadData->AuthData, 1603 PadData->AuthDataSize 1604 ); 1605 } else { 1606 PadEntry->Data->AuthDataSize = 0; 1607 PadEntry->Data->AuthData = NULL; 1608 } 1609 1610 if (PadData->RevocationData != NULL) { 1611 PadEntry->Data->RevocationDataSize = PadData->RevocationDataSize; 1612 PadEntry->Data->RevocationData = (VOID *) ALIGN_POINTER ( 1613 ((UINT8 *) (PadEntry->Data + 1) + PadData->AuthDataSize), 1614 sizeof (UINTN) 1615 ); 1616 CopyMem ( 1617 PadEntry->Data->RevocationData, 1618 PadData->RevocationData, 1619 PadData->RevocationDataSize 1620 ); 1621 } else { 1622 PadEntry->Data->RevocationDataSize = 0; 1623 PadEntry->Data->RevocationData = NULL; 1624 } 1625 // 1626 // Insert the new pad entry. 1627 // 1628 InsertTailList (EntryInsertBefore, &PadEntry->List); 1629 1630 return EFI_SUCCESS; 1631 } 1632 1633 /** 1634 This function lookup the data entry from IPsec SPD. Return the configuration 1635 value of the specified SPD Entry. 1636 1637 @param[in] Selector Pointer to an entry selector which is an identifier 1638 of the SPD entry. 1639 @param[in, out] DataSize On output the size of data returned in Data. 1640 @param[out] Data The buffer to return the contents of the IPsec 1641 configuration data. The type of the data buffer 1642 is associated with the DataType. 1643 1644 @retval EFI_SUCCESS The specified configuration data was obtained successfully. 1645 @retval EFI_INVALID_PARAMETER Data is NULL and *DataSize is not zero. 1646 @retval EFI_NOT_FOUND The configuration data specified by Selector is not found. 1647 @retval EFI_BUFFER_TOO_SMALL The DataSize is too small for the result. DataSize has been 1648 updated with the size needed to complete the request. 1649 1650 **/ 1651 EFI_STATUS 1652 GetSpdEntry ( 1653 IN EFI_IPSEC_CONFIG_SELECTOR *Selector, 1654 IN OUT UINTN *DataSize, 1655 OUT VOID *Data 1656 ) 1657 { 1658 IPSEC_SPD_ENTRY *SpdEntry; 1659 IPSEC_SAD_ENTRY *SadEntry; 1660 EFI_IPSEC_SPD_SELECTOR *SpdSel; 1661 EFI_IPSEC_SPD_DATA *SpdData; 1662 LIST_ENTRY *SpdList; 1663 LIST_ENTRY *SpdSas; 1664 LIST_ENTRY *Entry; 1665 UINTN RequiredSize; 1666 1667 SpdSel = &Selector->SpdSelector; 1668 SpdData = (EFI_IPSEC_SPD_DATA *) Data; 1669 SpdList = &mConfigData[IPsecConfigDataTypeSpd]; 1670 1671 NET_LIST_FOR_EACH (Entry, SpdList) { 1672 SpdEntry = IPSEC_SPD_ENTRY_FROM_LIST (Entry); 1673 1674 // 1675 // Find the required SPD entry 1676 // 1677 if (CompareSpdSelector ( 1678 (EFI_IPSEC_CONFIG_SELECTOR *) SpdSel, 1679 (EFI_IPSEC_CONFIG_SELECTOR *) SpdEntry->Selector 1680 )) { 1681 1682 RequiredSize = IpSecGetSizeOfSpdData (SpdEntry->Data); 1683 if (*DataSize < RequiredSize) { 1684 *DataSize = RequiredSize; 1685 return EFI_BUFFER_TOO_SMALL; 1686 } 1687 1688 if (SpdData == NULL) { 1689 return EFI_INVALID_PARAMETER; 1690 } 1691 1692 *DataSize = RequiredSize; 1693 1694 // 1695 // Extract and fill all SaId array from the SPD.sas list 1696 // 1697 SpdSas = &SpdEntry->Data->Sas; 1698 SpdData->SaIdCount = 0; 1699 1700 NET_LIST_FOR_EACH (Entry, SpdSas) { 1701 SadEntry = IPSEC_SAD_ENTRY_FROM_SPD (Entry); 1702 CopyMem ( 1703 &SpdData->SaId[SpdData->SaIdCount++], 1704 SadEntry->Id, 1705 sizeof (EFI_IPSEC_SA_ID) 1706 ); 1707 } 1708 // 1709 // Fill the other fields in SPD data. 1710 // 1711 CopyMem (SpdData->Name, SpdEntry->Data->Name, sizeof (SpdData->Name)); 1712 1713 SpdData->PackageFlag = SpdEntry->Data->PackageFlag; 1714 SpdData->TrafficDirection = SpdEntry->Data->TrafficDirection; 1715 SpdData->Action = SpdEntry->Data->Action; 1716 1717 if (SpdData->Action != EfiIPsecActionProtect) { 1718 SpdData->ProcessingPolicy = NULL; 1719 } else { 1720 SpdData->ProcessingPolicy = (EFI_IPSEC_PROCESS_POLICY *) ((UINT8 *) SpdData + sizeof (EFI_IPSEC_SPD_DATA) + (SpdData->SaIdCount - 1) * sizeof (EFI_IPSEC_SA_ID)); 1721 1722 IpSecDuplicateProcessPolicy ( 1723 SpdData->ProcessingPolicy, 1724 SpdEntry->Data->ProcessingPolicy 1725 ); 1726 } 1727 1728 return EFI_SUCCESS; 1729 } 1730 } 1731 1732 return EFI_NOT_FOUND; 1733 } 1734 1735 /** 1736 This function lookup the data entry from IPsec SAD. Return the configuration 1737 value of the specified SAD Entry. 1738 1739 @param[in] Selector Pointer to an entry selector which is an identifier 1740 of the SAD entry. 1741 @param[in, out] DataSize On output, the size of data returned in Data. 1742 @param[out] Data The buffer to return the contents of the IPsec 1743 configuration data. The type of the data buffer 1744 is associated with the DataType. 1745 1746 @retval EFI_SUCCESS The specified configuration data was obtained successfully. 1747 @retval EFI_NOT_FOUND The configuration data specified by Selector is not found. 1748 @retval EFI_BUFFER_TOO_SMALL The DataSize is too small for the result. DataSize has been 1749 updated with the size needed to complete the request. 1750 1751 **/ 1752 EFI_STATUS 1753 GetSadEntry ( 1754 IN EFI_IPSEC_CONFIG_SELECTOR *Selector, 1755 IN OUT UINTN *DataSize, 1756 OUT VOID *Data 1757 ) 1758 { 1759 IPSEC_SAD_ENTRY *SadEntry; 1760 LIST_ENTRY *Entry; 1761 LIST_ENTRY *SadList; 1762 EFI_IPSEC_SA_ID *SaId; 1763 EFI_IPSEC_SA_DATA2 *SaData; 1764 UINTN RequiredSize; 1765 1766 SaId = &Selector->SaId; 1767 SaData = (EFI_IPSEC_SA_DATA2 *) Data; 1768 SadList = &mConfigData[IPsecConfigDataTypeSad]; 1769 1770 NET_LIST_FOR_EACH (Entry, SadList) { 1771 SadEntry = IPSEC_SAD_ENTRY_FROM_LIST (Entry); 1772 1773 // 1774 // Find the required SAD entry. 1775 // 1776 if (CompareSaId ( 1777 (EFI_IPSEC_CONFIG_SELECTOR *) SaId, 1778 (EFI_IPSEC_CONFIG_SELECTOR *) SadEntry->Id 1779 )) { 1780 // 1781 // Calculate the required size of the SAD entry. 1782 // Data Layout is follows: 1783 // |EFI_IPSEC_SA_DATA 1784 // |AuthKey 1785 // |EncryptKey (Optional) 1786 // |SpdSelector (Optional) 1787 // 1788 RequiredSize = ALIGN_VARIABLE (sizeof (EFI_IPSEC_SA_DATA2)); 1789 1790 if (SaId->Proto == EfiIPsecAH) { 1791 RequiredSize = ALIGN_VARIABLE (RequiredSize + SadEntry->Data->AlgoInfo.AhAlgoInfo.AuthKeyLength); 1792 } else { 1793 RequiredSize = ALIGN_VARIABLE (RequiredSize + SadEntry->Data->AlgoInfo.EspAlgoInfo.AuthKeyLength); 1794 RequiredSize = ALIGN_VARIABLE (RequiredSize + SadEntry->Data->AlgoInfo.EspAlgoInfo.EncKeyLength); 1795 } 1796 1797 if (SadEntry->Data->SpdSelector != NULL) { 1798 RequiredSize += SIZE_OF_SPD_SELECTOR (SadEntry->Data->SpdSelector); 1799 } 1800 1801 if (*DataSize < RequiredSize) { 1802 *DataSize = RequiredSize; 1803 return EFI_BUFFER_TOO_SMALL; 1804 } 1805 1806 // 1807 // Fill the data fields of SAD entry. 1808 // 1809 *DataSize = RequiredSize; 1810 SaData->Mode = SadEntry->Data->Mode; 1811 SaData->SNCount = SadEntry->Data->SequenceNumber; 1812 SaData->AntiReplayWindows = SadEntry->Data->AntiReplayWindowSize; 1813 1814 CopyMem ( 1815 &SaData->SaLifetime, 1816 &SadEntry->Data->SaLifetime, 1817 sizeof (EFI_IPSEC_SA_LIFETIME) 1818 ); 1819 1820 ZeroMem ( 1821 &SaData->AlgoInfo, 1822 sizeof (EFI_IPSEC_ALGO_INFO) 1823 ); 1824 1825 if (SaId->Proto == EfiIPsecAH) { 1826 // 1827 // Copy AH alogrithm INFO to SaData 1828 // 1829 SaData->AlgoInfo.AhAlgoInfo.AuthAlgoId = SadEntry->Data->AlgoInfo.AhAlgoInfo.AuthAlgoId; 1830 SaData->AlgoInfo.AhAlgoInfo.AuthKeyLength = SadEntry->Data->AlgoInfo.AhAlgoInfo.AuthKeyLength; 1831 if (SaData->AlgoInfo.AhAlgoInfo.AuthKeyLength != 0) { 1832 SaData->AlgoInfo.AhAlgoInfo.AuthKey = (VOID *) ALIGN_POINTER ((SaData + 1), sizeof (UINTN)); 1833 CopyMem ( 1834 SaData->AlgoInfo.AhAlgoInfo.AuthKey, 1835 SadEntry->Data->AlgoInfo.AhAlgoInfo.AuthKey, 1836 SaData->AlgoInfo.AhAlgoInfo.AuthKeyLength 1837 ); 1838 } 1839 } else if (SaId->Proto == EfiIPsecESP) { 1840 // 1841 // Copy ESP alogrithem INFO to SaData 1842 // 1843 SaData->AlgoInfo.EspAlgoInfo.AuthAlgoId = SadEntry->Data->AlgoInfo.EspAlgoInfo.AuthAlgoId; 1844 SaData->AlgoInfo.EspAlgoInfo.AuthKeyLength = SadEntry->Data->AlgoInfo.EspAlgoInfo.AuthKeyLength; 1845 if (SaData->AlgoInfo.EspAlgoInfo.AuthKeyLength != 0) { 1846 SaData->AlgoInfo.EspAlgoInfo.AuthKey = (VOID *) ALIGN_POINTER ((SaData + 1), sizeof (UINTN)); 1847 CopyMem ( 1848 SaData->AlgoInfo.EspAlgoInfo.AuthKey, 1849 SadEntry->Data->AlgoInfo.EspAlgoInfo.AuthKey, 1850 SaData->AlgoInfo.EspAlgoInfo.AuthKeyLength 1851 ); 1852 } 1853 1854 SaData->AlgoInfo.EspAlgoInfo.EncAlgoId = SadEntry->Data->AlgoInfo.EspAlgoInfo.EncAlgoId; 1855 SaData->AlgoInfo.EspAlgoInfo.EncKeyLength = SadEntry->Data->AlgoInfo.EspAlgoInfo.EncKeyLength; 1856 1857 if (SaData->AlgoInfo.EspAlgoInfo.EncKeyLength != 0) { 1858 SaData->AlgoInfo.EspAlgoInfo.EncKey = (VOID *) ALIGN_POINTER ( 1859 ((UINT8 *) (SaData + 1) + 1860 SaData->AlgoInfo.EspAlgoInfo.AuthKeyLength), 1861 sizeof (UINTN) 1862 ); 1863 CopyMem ( 1864 SaData->AlgoInfo.EspAlgoInfo.EncKey, 1865 SadEntry->Data->AlgoInfo.EspAlgoInfo.EncKey, 1866 SaData->AlgoInfo.EspAlgoInfo.EncKeyLength 1867 ); 1868 } 1869 } 1870 1871 SaData->PathMTU = SadEntry->Data->PathMTU; 1872 1873 // 1874 // Fill Tunnel Address if it is Tunnel Mode 1875 // 1876 if (SadEntry->Data->Mode == EfiIPsecTunnel) { 1877 CopyMem ( 1878 &SaData->TunnelDestinationAddress, 1879 &SadEntry->Data->TunnelDestAddress, 1880 sizeof (EFI_IP_ADDRESS) 1881 ); 1882 CopyMem ( 1883 &SaData->TunnelSourceAddress, 1884 &SadEntry->Data->TunnelSourceAddress, 1885 sizeof (EFI_IP_ADDRESS) 1886 ); 1887 } 1888 // 1889 // Fill the spd selector field of SAD data 1890 // 1891 if (SadEntry->Data->SpdSelector != NULL) { 1892 1893 SaData->SpdSelector = (EFI_IPSEC_SPD_SELECTOR *) ( 1894 (UINT8 *)SaData + 1895 RequiredSize - 1896 SIZE_OF_SPD_SELECTOR (SadEntry->Data->SpdSelector) 1897 ); 1898 1899 DuplicateSpdSelector ( 1900 (EFI_IPSEC_CONFIG_SELECTOR *) SaData->SpdSelector, 1901 (EFI_IPSEC_CONFIG_SELECTOR *) SadEntry->Data->SpdSelector, 1902 NULL 1903 ); 1904 1905 } else { 1906 1907 SaData->SpdSelector = NULL; 1908 } 1909 1910 SaData->ManualSet = SadEntry->Data->ManualSet; 1911 1912 return EFI_SUCCESS; 1913 } 1914 } 1915 1916 return EFI_NOT_FOUND; 1917 } 1918 1919 /** 1920 This function lookup the data entry from IPsec PAD. Return the configuration 1921 value of the specified PAD Entry. 1922 1923 @param[in] Selector Pointer to an entry selector which is an identifier 1924 of the PAD entry. 1925 @param[in, out] DataSize On output the size of data returned in Data. 1926 @param[out] Data The buffer to return the contents of the IPsec 1927 configuration data. The type of the data buffer 1928 is associated with the DataType. 1929 1930 @retval EFI_SUCCESS The specified configuration data was obtained successfully. 1931 @retval EFI_NOT_FOUND The configuration data specified by Selector is not found. 1932 @retval EFI_BUFFER_TOO_SMALL The DataSize is too small for the result. DataSize has been 1933 updated with the size needed to complete the request. 1934 1935 **/ 1936 EFI_STATUS 1937 GetPadEntry ( 1938 IN EFI_IPSEC_CONFIG_SELECTOR *Selector, 1939 IN OUT UINTN *DataSize, 1940 OUT VOID *Data 1941 ) 1942 { 1943 IPSEC_PAD_ENTRY *PadEntry; 1944 LIST_ENTRY *PadList; 1945 LIST_ENTRY *Entry; 1946 EFI_IPSEC_PAD_ID *PadId; 1947 EFI_IPSEC_PAD_DATA *PadData; 1948 UINTN RequiredSize; 1949 1950 PadId = &Selector->PadId; 1951 PadData = (EFI_IPSEC_PAD_DATA *) Data; 1952 PadList = &mConfigData[IPsecConfigDataTypePad]; 1953 1954 NET_LIST_FOR_EACH (Entry, PadList) { 1955 PadEntry = IPSEC_PAD_ENTRY_FROM_LIST (Entry); 1956 1957 // 1958 // Find the required pad entry. 1959 // 1960 if (ComparePadId ( 1961 (EFI_IPSEC_CONFIG_SELECTOR *) PadId, 1962 (EFI_IPSEC_CONFIG_SELECTOR *) PadEntry->Id 1963 )) { 1964 // 1965 // Calculate the required size of the pad entry. 1966 // 1967 RequiredSize = ALIGN_VARIABLE (sizeof (EFI_IPSEC_PAD_DATA)); 1968 RequiredSize = ALIGN_VARIABLE (RequiredSize + PadEntry->Data->AuthDataSize); 1969 RequiredSize += PadEntry->Data->RevocationDataSize; 1970 1971 if (*DataSize < RequiredSize) { 1972 *DataSize = RequiredSize; 1973 return EFI_BUFFER_TOO_SMALL; 1974 } 1975 // 1976 // Fill the data fields of pad entry 1977 // 1978 *DataSize = RequiredSize; 1979 PadData->AuthProtocol = PadEntry->Data->AuthProtocol; 1980 PadData->AuthMethod = PadEntry->Data->AuthMethod; 1981 PadData->IkeIdFlag = PadEntry->Data->IkeIdFlag; 1982 1983 // 1984 // Copy Authentication data. 1985 // 1986 if (PadEntry->Data->AuthData != NULL) { 1987 1988 PadData->AuthDataSize = PadEntry->Data->AuthDataSize; 1989 PadData->AuthData = (VOID *) ALIGN_POINTER ((PadData + 1), sizeof (UINTN)); 1990 CopyMem ( 1991 PadData->AuthData, 1992 PadEntry->Data->AuthData, 1993 PadData->AuthDataSize 1994 ); 1995 } else { 1996 1997 PadData->AuthDataSize = 0; 1998 PadData->AuthData = NULL; 1999 } 2000 // 2001 // Copy Revocation Data. 2002 // 2003 if (PadEntry->Data->RevocationData != NULL) { 2004 2005 PadData->RevocationDataSize = PadEntry->Data->RevocationDataSize; 2006 PadData->RevocationData = (VOID *) ALIGN_POINTER ( 2007 ((UINT8 *) (PadData + 1) + PadData->AuthDataSize), 2008 sizeof (UINTN) 2009 ); 2010 CopyMem ( 2011 PadData->RevocationData, 2012 PadEntry->Data->RevocationData, 2013 PadData->RevocationDataSize 2014 ); 2015 } else { 2016 2017 PadData->RevocationDataSize = 0; 2018 PadData->RevocationData = NULL; 2019 } 2020 2021 return EFI_SUCCESS; 2022 } 2023 } 2024 2025 return EFI_NOT_FOUND; 2026 } 2027 2028 /** 2029 Copy Source Process Policy to the Destination Process Policy. 2030 2031 @param[in] Dst Pointer to the Source Process Policy. 2032 @param[in] Src Pointer to the Destination Process Policy. 2033 2034 **/ 2035 VOID 2036 IpSecDuplicateProcessPolicy ( 2037 IN EFI_IPSEC_PROCESS_POLICY *Dst, 2038 IN EFI_IPSEC_PROCESS_POLICY *Src 2039 ) 2040 { 2041 // 2042 // Firstly copy the structure content itself. 2043 // 2044 CopyMem (Dst, Src, sizeof (EFI_IPSEC_PROCESS_POLICY)); 2045 2046 // 2047 // Recursively copy the tunnel option if needed. 2048 // 2049 if (Dst->Mode != EfiIPsecTunnel) { 2050 ASSERT (Dst->TunnelOption == NULL); 2051 } else { 2052 Dst->TunnelOption = (EFI_IPSEC_TUNNEL_OPTION *) ALIGN_POINTER ((Dst + 1), sizeof (UINTN)); 2053 CopyMem ( 2054 Dst->TunnelOption, 2055 Src->TunnelOption, 2056 sizeof (EFI_IPSEC_TUNNEL_OPTION) 2057 ); 2058 } 2059 } 2060 2061 /** 2062 Calculate the a whole size of EFI_IPSEC_SPD_DATA, which includes the buffer size pointed 2063 to by the pointer members. 2064 2065 @param[in] SpdData Pointer to a specified EFI_IPSEC_SPD_DATA. 2066 2067 @return the whole size the specified EFI_IPSEC_SPD_DATA. 2068 2069 **/ 2070 UINTN 2071 IpSecGetSizeOfEfiSpdData ( 2072 IN EFI_IPSEC_SPD_DATA *SpdData 2073 ) 2074 { 2075 UINTN Size; 2076 2077 Size = ALIGN_VARIABLE (sizeof (IPSEC_SPD_DATA)); 2078 2079 if (SpdData->Action == EfiIPsecActionProtect) { 2080 Size = ALIGN_VARIABLE (Size + sizeof (EFI_IPSEC_PROCESS_POLICY)); 2081 2082 if (SpdData->ProcessingPolicy->Mode == EfiIPsecTunnel) { 2083 Size = ALIGN_VARIABLE (Size + sizeof (EFI_IPSEC_TUNNEL_OPTION)); 2084 } 2085 } 2086 2087 return Size; 2088 } 2089 2090 /** 2091 Calculate the a whole size of IPSEC_SPD_DATA which includes the buffer size pointed 2092 to by the pointer members and the buffer size used by the Sa List. 2093 2094 @param[in] SpdData Pointer to the specified IPSEC_SPD_DATA. 2095 2096 @return the whole size of IPSEC_SPD_DATA. 2097 2098 **/ 2099 UINTN 2100 IpSecGetSizeOfSpdData ( 2101 IN IPSEC_SPD_DATA *SpdData 2102 ) 2103 { 2104 UINTN Size; 2105 LIST_ENTRY *Link; 2106 2107 Size = sizeof (EFI_IPSEC_SPD_DATA) - sizeof (EFI_IPSEC_SA_ID); 2108 2109 if (SpdData->Action == EfiIPsecActionProtect) { 2110 Size += sizeof (EFI_IPSEC_PROCESS_POLICY); 2111 2112 if (SpdData->ProcessingPolicy->Mode == EfiIPsecTunnel) { 2113 Size += sizeof (EFI_IPSEC_TUNNEL_OPTION); 2114 } 2115 } 2116 2117 NET_LIST_FOR_EACH (Link, &SpdData->Sas) { 2118 Size += sizeof (EFI_IPSEC_SA_ID); 2119 } 2120 2121 return Size; 2122 } 2123 2124 /** 2125 Get the IPsec Variable. 2126 2127 Get the all variables which start with the string contained in VaraiableName. 2128 Since all IPsec related variable store in continual space, those kinds of 2129 variable can be searched by the EfiGetNextVariableName. Those variables also are 2130 returned in a continual buffer. 2131 2132 @param[in] VariableName Pointer to a specified Variable Name. 2133 @param[in] VendorGuid Pointer to a specified Vendor Guid. 2134 @param[in] Attributes Point to memory location to return the attributes 2135 of variable. If the point is NULL, the parameter 2136 would be ignored. 2137 @param[in, out] DataSize As input, point to the maximum size of return 2138 Data-Buffer. As output, point to the actual 2139 size of the returned Data-Buffer. 2140 @param[in] Data Point to return Data-Buffer. 2141 2142 @retval EFI_ABORTED If the Variable size which contained in the variable 2143 structure doesn't match the variable size obtained 2144 from the EFIGetVariable. 2145 @retval EFI_BUFFER_TOO_SMALL The DataSize is too small for the result. DataSize has 2146 been updated with the size needed to complete the request. 2147 @retval EFI_SUCCESS The function completed successfully. 2148 @retval others Other errors found during the variable getting. 2149 **/ 2150 EFI_STATUS 2151 IpSecGetVariable ( 2152 IN CHAR16 *VariableName, 2153 IN EFI_GUID *VendorGuid, 2154 IN UINT32 *Attributes, OPTIONAL 2155 IN OUT UINTN *DataSize, 2156 IN VOID *Data 2157 ) 2158 { 2159 EFI_STATUS Status; 2160 EFI_GUID VendorGuidI; 2161 UINTN VariableNameLength; 2162 CHAR16 *VariableNameI; 2163 UINTN VariableNameISize; 2164 UINTN VariableNameISizeNew; 2165 UINTN VariableIndex; 2166 UINTN VariableCount; 2167 IP_SEC_VARIABLE_INFO IpSecVariableInfo; 2168 UINTN DataSizeI; 2169 2170 // 2171 // The variable name constructor is "VariableName + Info/0001/0002/... + NULL". 2172 // So the varialbe name is like "VariableNameInfo", "VariableName0001", ... 2173 // "VariableNameNULL". 2174 // 2175 VariableNameLength = StrLen (VariableName); 2176 VariableNameISize = (VariableNameLength + 5) * sizeof (CHAR16); 2177 VariableNameI = AllocateZeroPool (VariableNameISize); 2178 if (VariableNameI == NULL) { 2179 Status = EFI_OUT_OF_RESOURCES; 2180 goto ON_EXIT; 2181 } 2182 2183 // 2184 // Construct the varible name of ipsecconfig meta data. 2185 // 2186 UnicodeSPrint (VariableNameI, VariableNameISize, L"%s%s", VariableName, L"Info"); 2187 2188 DataSizeI = sizeof (IpSecVariableInfo); 2189 2190 Status = gRT->GetVariable ( 2191 VariableNameI, 2192 VendorGuid, 2193 Attributes, 2194 &DataSizeI, 2195 &IpSecVariableInfo 2196 ); 2197 if (EFI_ERROR (Status)) { 2198 goto ON_EXIT; 2199 } 2200 2201 if (*DataSize < IpSecVariableInfo.VariableSize) { 2202 *DataSize = IpSecVariableInfo.VariableSize; 2203 Status = EFI_BUFFER_TOO_SMALL; 2204 goto ON_EXIT; 2205 } 2206 2207 VariableCount = IpSecVariableInfo.VariableCount; 2208 VariableNameI[0] = L'\0'; 2209 2210 while (VariableCount != 0) { 2211 // 2212 // Get the variable name one by one in the variable database. 2213 // 2214 VariableNameISizeNew = VariableNameISize; 2215 Status = gRT->GetNextVariableName ( 2216 &VariableNameISizeNew, 2217 VariableNameI, 2218 &VendorGuidI 2219 ); 2220 if (Status == EFI_BUFFER_TOO_SMALL) { 2221 VariableNameI = ReallocatePool ( 2222 VariableNameISize, 2223 VariableNameISizeNew, 2224 VariableNameI 2225 ); 2226 if (VariableNameI == NULL) { 2227 Status = EFI_OUT_OF_RESOURCES; 2228 break; 2229 } 2230 VariableNameISize = VariableNameISizeNew; 2231 2232 Status = gRT->GetNextVariableName ( 2233 &VariableNameISizeNew, 2234 VariableNameI, 2235 &VendorGuidI 2236 ); 2237 } 2238 2239 if (EFI_ERROR (Status)) { 2240 break; 2241 } 2242 // 2243 // Check whether the current variable is the required "ipsecconfig". 2244 // 2245 if (StrnCmp (VariableNameI, VariableName, VariableNameLength) == 0 || 2246 CompareGuid (VendorGuid, &VendorGuidI) 2247 ) { 2248 // 2249 // Parse the variable count of the current ipsecconfig data. 2250 // 2251 VariableIndex = StrDecimalToUintn (VariableNameI + VariableNameLength); 2252 if (VariableIndex!= 0 && VariableIndex <= IpSecVariableInfo.VariableCount) { 2253 // 2254 // Get the variable size of the current ipsecconfig data. 2255 // 2256 DataSizeI = 0; 2257 Status = gRT->GetVariable ( 2258 VariableNameI, 2259 VendorGuid, 2260 Attributes, 2261 &DataSizeI, 2262 NULL 2263 ); 2264 ASSERT (Status == EFI_BUFFER_TOO_SMALL); 2265 // 2266 // Validate the variable count and variable size. 2267 // 2268 if (VariableIndex != IpSecVariableInfo.VariableCount) { 2269 // 2270 // If the varaibe is not the last one, its size should be the max 2271 // size of the single variable. 2272 // 2273 if (DataSizeI != IpSecVariableInfo.SingleVariableSize) { 2274 return EFI_ABORTED; 2275 } 2276 } else { 2277 if (DataSizeI != IpSecVariableInfo.VariableSize % IpSecVariableInfo.SingleVariableSize) { 2278 return EFI_ABORTED; 2279 } 2280 } 2281 // 2282 // Get the variable data of the current ipsecconfig data and 2283 // store it into user buffer continously. 2284 // 2285 Status = gRT->GetVariable ( 2286 VariableNameI, 2287 VendorGuid, 2288 Attributes, 2289 &DataSizeI, 2290 (UINT8 *) Data + (VariableIndex - 1) * IpSecVariableInfo.SingleVariableSize 2291 ); 2292 ASSERT_EFI_ERROR (Status); 2293 VariableCount--; 2294 } 2295 } 2296 } 2297 // 2298 // The VariableCount in "VariableNameInfo" varaible should have the correct 2299 // numbers of variables which name starts with VariableName. 2300 // 2301 if (VariableCount != 0) { 2302 Status = EFI_ABORTED; 2303 } 2304 2305 ON_EXIT: 2306 if (VariableNameI != NULL) { 2307 FreePool (VariableNameI); 2308 } 2309 return Status; 2310 } 2311 2312 /** 2313 Set the IPsec variables. 2314 2315 Set all IPsec variables which start with the specified variable name. Those variables 2316 are set one by one. 2317 2318 @param[in] VariableName The name of the vendor's variable. It is a 2319 Null-Terminated Unicode String. 2320 @param[in] VendorGuid Unify identifier for vendor. 2321 @param[in] Attributes Point to memory location to return the attributes of 2322 variable. If the point is NULL, the parameter would be ignored. 2323 @param[in] DataSize The size in bytes of Data-Buffer. 2324 @param[in] Data Points to the content of the variable. 2325 2326 @retval EFI_SUCCESS The firmware successfully stored the variable and its data, as 2327 defined by the Attributes. 2328 @retval others Storing the variables failed. 2329 2330 **/ 2331 EFI_STATUS 2332 IpSecSetVariable ( 2333 IN CHAR16 *VariableName, 2334 IN EFI_GUID *VendorGuid, 2335 IN UINT32 Attributes, 2336 IN UINTN DataSize, 2337 IN VOID *Data 2338 ) 2339 { 2340 EFI_STATUS Status; 2341 CHAR16 *VariableNameI; 2342 UINTN VariableNameSize; 2343 UINTN VariableIndex; 2344 IP_SEC_VARIABLE_INFO IpSecVariableInfo; 2345 UINT64 MaximumVariableStorageSize; 2346 UINT64 RemainingVariableStorageSize; 2347 UINT64 MaximumVariableSize; 2348 2349 Status = gRT->QueryVariableInfo ( 2350 Attributes, 2351 &MaximumVariableStorageSize, 2352 &RemainingVariableStorageSize, 2353 &MaximumVariableSize 2354 ); 2355 if (EFI_ERROR (Status)) { 2356 return Status; 2357 } 2358 2359 // 2360 // "VariableName + Info/0001/0002/... + NULL" 2361 // 2362 VariableNameSize = (StrLen (VariableName) + 5) * sizeof (CHAR16); 2363 VariableNameI = AllocateZeroPool (VariableNameSize); 2364 2365 if (VariableNameI == NULL) { 2366 Status = EFI_OUT_OF_RESOURCES; 2367 goto ON_EXIT; 2368 } 2369 // 2370 // Construct the variable of ipsecconfig general information. Like the total 2371 // numbers of the Ipsecconfig variables, the total size of all ipsecconfig variables. 2372 // 2373 UnicodeSPrint (VariableNameI, VariableNameSize, L"%s%s", VariableName, L"Info"); 2374 MaximumVariableSize -= VariableNameSize; 2375 2376 IpSecVariableInfo.VariableCount = (UINT32) ((DataSize + (UINTN) MaximumVariableSize - 1) / (UINTN) MaximumVariableSize); 2377 IpSecVariableInfo.VariableSize = (UINT32) DataSize; 2378 IpSecVariableInfo.SingleVariableSize = (UINT32) MaximumVariableSize; 2379 2380 // 2381 // Set the variable of ipsecconfig general information. 2382 // 2383 Status = gRT->SetVariable ( 2384 VariableNameI, 2385 VendorGuid, 2386 Attributes, 2387 sizeof (IpSecVariableInfo), 2388 &IpSecVariableInfo 2389 ); 2390 if (EFI_ERROR (Status)) { 2391 DEBUG ((DEBUG_ERROR, "Error set ipsecconfig meta data with %r\n", Status)); 2392 goto ON_EXIT; 2393 } 2394 2395 for (VariableIndex = 0; VariableIndex < IpSecVariableInfo.VariableCount; VariableIndex++) { 2396 // 2397 // Construct and set the variable of ipsecconfig data one by one. 2398 // The index of variable name begin from 0001, and the varaible name 2399 // likes "VariableName0001", "VaraiableName0002".... 2400 // 2401 UnicodeSPrint (VariableNameI, VariableNameSize, L"%s%04d", VariableName, VariableIndex + 1); 2402 Status = gRT->SetVariable ( 2403 VariableNameI, 2404 VendorGuid, 2405 Attributes, 2406 (VariableIndex == IpSecVariableInfo.VariableCount - 1) ? 2407 (DataSize % (UINTN) MaximumVariableSize) : 2408 (UINTN) MaximumVariableSize, 2409 (UINT8 *) Data + VariableIndex * (UINTN) MaximumVariableSize 2410 ); 2411 2412 if (EFI_ERROR (Status)) { 2413 DEBUG ((DEBUG_ERROR, "Error set ipsecconfig variable data with %r\n", Status)); 2414 goto ON_EXIT; 2415 } 2416 } 2417 2418 ON_EXIT: 2419 if (VariableNameI != NULL) { 2420 FreePool (VariableNameI); 2421 } 2422 2423 return Status; 2424 } 2425 2426 /** 2427 Return the configuration value for the EFI IPsec driver. 2428 2429 This function lookup the data entry from IPsec database or IKEv2 configuration 2430 information. The expected data type and unique identification are described in 2431 DataType and Selector parameters. 2432 2433 @param[in] This Pointer to the EFI_IPSEC_CONFIG_PROTOCOL instance. 2434 @param[in] DataType The type of data to retrieve. 2435 @param[in] Selector Pointer to an entry selector that is an identifier of the IPsec 2436 configuration data entry. 2437 @param[in, out] DataSize On output the size of data returned in Data. 2438 @param[out] Data The buffer to return the contents of the IPsec configuration data. 2439 The type of the data buffer associated with the DataType. 2440 2441 @retval EFI_SUCCESS The specified configuration data was obtained successfully. 2442 @retval EFI_INVALID_PARAMETER One or more of the followings are TRUE: 2443 - This is NULL. 2444 - Selector is NULL. 2445 - DataSize is NULL. 2446 - Data is NULL and *DataSize is not zero 2447 @retval EFI_NOT_FOUND The configuration data specified by Selector is not found. 2448 @retval EFI_UNSUPPORTED The specified DataType is not supported. 2449 @retval EFI_BUFFER_TOO_SMALL The DataSize is too small for the result. DataSize has been 2450 updated with the size needed to complete the request. 2451 2452 **/ 2453 EFI_STATUS 2454 EFIAPI 2455 EfiIpSecConfigGetData ( 2456 IN EFI_IPSEC_CONFIG_PROTOCOL *This, 2457 IN EFI_IPSEC_CONFIG_DATA_TYPE DataType, 2458 IN EFI_IPSEC_CONFIG_SELECTOR *Selector, 2459 IN OUT UINTN *DataSize, 2460 OUT VOID *Data 2461 ) 2462 { 2463 if (This == NULL || Selector == NULL || DataSize == NULL) { 2464 return EFI_INVALID_PARAMETER; 2465 } 2466 2467 if (*DataSize != 0 && Data == NULL) { 2468 return EFI_INVALID_PARAMETER; 2469 } 2470 2471 if (DataType >= IPsecConfigDataTypeMaximum) { 2472 return EFI_UNSUPPORTED; 2473 } 2474 2475 return mGetPolicyEntry[DataType](Selector, DataSize, Data); 2476 } 2477 2478 /** 2479 Set the security association, security policy and peer authorization configuration 2480 information for the EFI IPsec driver. 2481 2482 This function is used to set the IPsec configuration information of type DataType for 2483 the EFI IPsec driver. 2484 The IPsec configuration data has a unique selector/identifier separately to identify 2485 a data entry. The selector structure depends on DataType's definition. 2486 Using SetData() with a Data of NULL causes the IPsec configuration data entry identified 2487 by DataType and Selector to be deleted. 2488 2489 @param[in] This Pointer to the EFI_IPSEC_CONFIG_PROTOCOL instance. 2490 @param[in] DataType The type of data to be set. 2491 @param[in] Selector Pointer to an entry selector on operated configuration data 2492 specified by DataType. A NULL Selector causes the entire 2493 specified-type configuration information to be flushed. 2494 @param[in] Data The data buffer to be set. The structure of the data buffer is 2495 associated with the DataType. 2496 @param[in] InsertBefore Pointer to one entry selector which describes the expected 2497 position the new data entry will be added. If InsertBefore is NULL, 2498 the new entry will be appended to the end of the database. 2499 2500 @retval EFI_SUCCESS The specified configuration entry data was set successfully. 2501 @retval EFI_INVALID_PARAMETER One or more of the following are TRUE: 2502 - This is NULL. 2503 @retval EFI_UNSUPPORTED The specified DataType is not supported. 2504 @retval EFI_OUT_OF_RESOURCED The required system resource could not be allocated. 2505 2506 **/ 2507 EFI_STATUS 2508 EFIAPI 2509 EfiIpSecConfigSetData ( 2510 IN EFI_IPSEC_CONFIG_PROTOCOL *This, 2511 IN EFI_IPSEC_CONFIG_DATA_TYPE DataType, 2512 IN EFI_IPSEC_CONFIG_SELECTOR *Selector, 2513 IN VOID *Data, 2514 IN EFI_IPSEC_CONFIG_SELECTOR *InsertBefore OPTIONAL 2515 ) 2516 { 2517 EFI_STATUS Status; 2518 2519 if (This == NULL) { 2520 return EFI_INVALID_PARAMETER; 2521 } 2522 2523 if (DataType >= IPsecConfigDataTypeMaximum) { 2524 return EFI_UNSUPPORTED; 2525 } 2526 2527 Status = mSetPolicyEntry[DataType](Selector, Data, InsertBefore); 2528 2529 if (!EFI_ERROR (Status) && !mSetBySelf) { 2530 // 2531 // Save the updated config data into variable. 2532 // 2533 IpSecConfigSave (); 2534 } 2535 2536 return Status; 2537 } 2538 2539 /** 2540 Enumerates the current selector for IPsec configuration data entry. 2541 2542 This function is called multiple times to retrieve the entry Selector in IPsec 2543 configuration database. On each call to GetNextSelector(), the next entry 2544 Selector are retrieved into the output interface. 2545 2546 If the entire IPsec configuration database has been iterated, the error 2547 EFI_NOT_FOUND is returned. 2548 If the Selector buffer is too small for the next Selector copy, an 2549 EFI_BUFFER_TOO_SMALL error is returned, and SelectorSize is updated to reflect 2550 the size of buffer needed. 2551 2552 On the initial call to GetNextSelector() to start the IPsec configuration database 2553 search, a pointer to the buffer with all zero value is passed in Selector. Calls 2554 to SetData() between calls to GetNextSelector may produce unpredictable results. 2555 2556 @param[in] This Pointer to the EFI_IPSEC_CONFIG_PROTOCOL instance. 2557 @param[in] DataType The type of IPsec configuration data to retrieve. 2558 @param[in, out] SelectorSize The size of the Selector buffer. 2559 @param[in, out] Selector On input, supplies the pointer to last Selector that was 2560 returned by GetNextSelector(). 2561 On output, returns one copy of the current entry Selector 2562 of a given DataType. 2563 2564 @retval EFI_SUCCESS The specified configuration data was obtained successfully. 2565 @retval EFI_INVALID_PARAMETER One or more of the followings are TRUE: 2566 - This is NULL. 2567 - SelectorSize is NULL. 2568 - Selector is NULL. 2569 @retval EFI_NOT_FOUND The next configuration data entry was not found. 2570 @retval EFI_UNSUPPORTED The specified DataType is not supported. 2571 @retval EFI_BUFFER_TOO_SMALL The SelectorSize is too small for the result. This parameter 2572 has been updated with the size needed to complete the search 2573 request. 2574 2575 **/ 2576 EFI_STATUS 2577 EFIAPI 2578 EfiIpSecConfigGetNextSelector ( 2579 IN EFI_IPSEC_CONFIG_PROTOCOL *This, 2580 IN EFI_IPSEC_CONFIG_DATA_TYPE DataType, 2581 IN OUT UINTN *SelectorSize, 2582 IN OUT EFI_IPSEC_CONFIG_SELECTOR *Selector 2583 ) 2584 { 2585 LIST_ENTRY *Link; 2586 IPSEC_COMMON_POLICY_ENTRY *CommonEntry; 2587 BOOLEAN IsFound; 2588 2589 if (This == NULL || Selector == NULL || SelectorSize == NULL) { 2590 return EFI_INVALID_PARAMETER; 2591 } 2592 2593 if (DataType >= IPsecConfigDataTypeMaximum) { 2594 return EFI_UNSUPPORTED; 2595 } 2596 2597 IsFound = FALSE; 2598 2599 NET_LIST_FOR_EACH (Link, &mConfigData[DataType]) { 2600 CommonEntry = BASE_CR (Link, IPSEC_COMMON_POLICY_ENTRY, List); 2601 2602 if (IsFound || (BOOLEAN)(mIsZeroSelector[DataType](Selector))) { 2603 // 2604 // If found the appointed entry, then duplicate the next one and return, 2605 // or if the appointed entry is zero, then return the first one directly. 2606 // 2607 return mDuplicateSelector[DataType](Selector, CommonEntry->Selector, SelectorSize); 2608 } else { 2609 // 2610 // Set the flag if find the appointed entry. 2611 // 2612 IsFound = mCompareSelector[DataType](Selector, CommonEntry->Selector); 2613 } 2614 } 2615 2616 return EFI_NOT_FOUND; 2617 } 2618 2619 /** 2620 Register an event that is to be signaled whenever a configuration process on the 2621 specified IPsec configuration information is done. 2622 2623 The register function is not surpport now and always returns EFI_UNSUPPORTED. 2624 2625 @param[in] This Pointer to the EFI_IPSEC_CONFIG_PROTOCOL instance. 2626 @param[in] DataType The type of data to be registered the event for. 2627 @param[in] Event The event to be registered. 2628 2629 @retval EFI_SUCCESS The event is registered successfully. 2630 @retval EFI_INVALID_PARAMETER This is NULL or Event is NULL. 2631 @retval EFI_ACCESS_DENIED The Event is already registered for the DataType. 2632 @retval EFI_UNSUPPORTED The notify registration is unsupported, or the specified 2633 DataType is not supported. 2634 2635 **/ 2636 EFI_STATUS 2637 EFIAPI 2638 EfiIpSecConfigRegisterNotify ( 2639 IN EFI_IPSEC_CONFIG_PROTOCOL *This, 2640 IN EFI_IPSEC_CONFIG_DATA_TYPE DataType, 2641 IN EFI_EVENT Event 2642 ) 2643 { 2644 return EFI_UNSUPPORTED; 2645 } 2646 2647 /** 2648 Remove the specified event that was previously registered on the specified IPsec 2649 configuration data. 2650 2651 This function is not support now and alwasy return EFI_UNSUPPORTED. 2652 2653 @param[in] This Pointer to the EFI_IPSEC_CONFIG_PROTOCOL instance. 2654 @param[in] DataType The configuration data type to remove the registered event for. 2655 @param[in] Event The event to be unregistered. 2656 2657 @retval EFI_SUCCESS The event was removed successfully. 2658 @retval EFI_NOT_FOUND The Event specified by DataType could not be found in the 2659 database. 2660 @retval EFI_INVALID_PARAMETER This is NULL or Event is NULL. 2661 @retval EFI_UNSUPPORTED The notify registration is unsupported, or the specified 2662 DataType is not supported. 2663 2664 **/ 2665 EFI_STATUS 2666 EFIAPI 2667 EfiIpSecConfigUnregisterNotify ( 2668 IN EFI_IPSEC_CONFIG_PROTOCOL *This, 2669 IN EFI_IPSEC_CONFIG_DATA_TYPE DataType, 2670 IN EFI_EVENT Event 2671 ) 2672 { 2673 return EFI_UNSUPPORTED; 2674 } 2675 2676 /** 2677 Copy whole data in specified EFI_SIPEC_CONFIG_SELECTOR and the Data to a buffer. 2678 2679 This function is a caller defined function, and it is called by the IpSecVisitConfigData(). 2680 The orignal caller is IpSecConfigSave(), which calls the IpsecVisitConfigData() to 2681 copy all types of IPsec Config datas into one buffer and store this buffer into firmware in 2682 the form of several variables. 2683 2684 @param[in] Type A specified IPSEC_CONFIG_DATA_TYPE. 2685 @param[in] Selector Points to a EFI_IPSEC_CONFIG_SELECTOR to be copied 2686 to the buffer. 2687 @param[in] Data Points to data to be copied to the buffer. The 2688 Data type is related to the Type. 2689 @param[in] SelectorSize The size of the Selector. 2690 @param[in] DataSize The size of the Data. 2691 @param[in, out] Buffer The buffer to store the Selector and Data. 2692 2693 @retval EFI_SUCCESS Copy the Selector and Data to a buffer successfully. 2694 @retval EFI_OUT_OF_RESOURCES The required system resource could not be allocated. 2695 2696 **/ 2697 EFI_STATUS 2698 IpSecCopyPolicyEntry ( 2699 IN EFI_IPSEC_CONFIG_DATA_TYPE Type, 2700 IN EFI_IPSEC_CONFIG_SELECTOR *Selector, 2701 IN VOID *Data, 2702 IN UINTN SelectorSize, 2703 IN UINTN DataSize, 2704 IN OUT IPSEC_VARIABLE_BUFFER *Buffer 2705 ) 2706 { 2707 IPSEC_VAR_ITEM_HEADER SelectorHeader; 2708 IPSEC_VAR_ITEM_HEADER DataHeader; 2709 UINTN EntrySize; 2710 UINT8 *TempPoint; 2711 2712 if (Type == IPsecConfigDataTypeSad) { 2713 // 2714 // Don't save automatically-generated SA entry into variable. 2715 // 2716 if (((EFI_IPSEC_SA_DATA2 *) Data)->ManualSet == FALSE) { 2717 return EFI_SUCCESS; 2718 } 2719 } 2720 // 2721 // Increase the capacity size of the buffer if needed. 2722 // 2723 EntrySize = ALIGN_VARIABLE (sizeof (SelectorHeader)); 2724 EntrySize = ALIGN_VARIABLE (EntrySize + SelectorSize); 2725 EntrySize = ALIGN_VARIABLE (EntrySize + sizeof (SelectorHeader)); 2726 EntrySize = ALIGN_VARIABLE (EntrySize + DataSize); 2727 2728 //EntrySize = SelectorSize + DataSize + 2 * sizeof (SelectorHeader); 2729 if (Buffer->Capacity - Buffer->Size < EntrySize) { 2730 // 2731 // Calculate the required buffer 2732 // 2733 Buffer->Capacity += EntrySize; 2734 TempPoint = AllocatePool (Buffer->Capacity); 2735 2736 if (TempPoint == NULL) { 2737 return EFI_OUT_OF_RESOURCES; 2738 } 2739 // 2740 // Copy the old Buffer to new buffer and free the old one. 2741 // 2742 CopyMem (TempPoint, Buffer->Ptr, Buffer->Size); 2743 FreePool (Buffer->Ptr); 2744 2745 Buffer->Ptr = TempPoint; 2746 } 2747 2748 mFixPolicyEntry[Type](Selector, Data); 2749 2750 // 2751 // Fill the selector header and copy it into buffer. 2752 // 2753 SelectorHeader.Type = (UINT8) (Type | IPSEC_VAR_ITEM_HEADER_LOGO_BIT); 2754 SelectorHeader.Size = (UINT16) SelectorSize; 2755 2756 CopyMem ( 2757 Buffer->Ptr + Buffer->Size, 2758 &SelectorHeader, 2759 sizeof (SelectorHeader) 2760 ); 2761 Buffer->Size = ALIGN_VARIABLE (Buffer->Size + sizeof (SelectorHeader)); 2762 2763 // 2764 // Copy the selector into buffer. 2765 // 2766 CopyMem ( 2767 Buffer->Ptr + Buffer->Size, 2768 Selector, 2769 SelectorSize 2770 ); 2771 Buffer->Size = ALIGN_VARIABLE (Buffer->Size + SelectorSize); 2772 2773 // 2774 // Fill the data header and copy it into buffer. 2775 // 2776 DataHeader.Type = (UINT8) Type; 2777 DataHeader.Size = (UINT16) DataSize; 2778 2779 CopyMem ( 2780 Buffer->Ptr + Buffer->Size, 2781 &DataHeader, 2782 sizeof (DataHeader) 2783 ); 2784 Buffer->Size = ALIGN_VARIABLE (Buffer->Size + sizeof (DataHeader)); 2785 // 2786 // Copy the data into buffer. 2787 // 2788 CopyMem ( 2789 Buffer->Ptr + Buffer->Size, 2790 Data, 2791 DataSize 2792 ); 2793 Buffer->Size = ALIGN_VARIABLE (Buffer->Size + DataSize); 2794 2795 mUnfixPolicyEntry[Type](Selector, Data); 2796 2797 return EFI_SUCCESS; 2798 } 2799 2800 /** 2801 Visit all IPsec Configurations of specified Type and call the caller defined 2802 interface. 2803 2804 @param[in] DataType The specified IPsec Config Data Type. 2805 @param[in] Routine The function defined by the caller. 2806 @param[in] Context The data passed to the Routine. 2807 2808 @retval EFI_OUT_OF_RESOURCES The required system resource could not be allocated 2809 @retval EFI_SUCCESS This function completed successfully. 2810 2811 **/ 2812 EFI_STATUS 2813 IpSecVisitConfigData ( 2814 IN EFI_IPSEC_CONFIG_DATA_TYPE DataType, 2815 IN IPSEC_COPY_POLICY_ENTRY Routine, 2816 IN VOID *Context 2817 ) 2818 { 2819 EFI_STATUS GetNextStatus; 2820 EFI_STATUS GetDataStatus; 2821 EFI_STATUS RoutineStatus; 2822 EFI_IPSEC_CONFIG_SELECTOR *Selector; 2823 VOID *Data; 2824 UINTN SelectorSize; 2825 UINTN DataSize; 2826 UINTN SelectorBufferSize; 2827 UINTN DataBufferSize; 2828 BOOLEAN FirstGetNext; 2829 2830 FirstGetNext = TRUE; 2831 DataBufferSize = 0; 2832 Data = NULL; 2833 SelectorBufferSize = sizeof (EFI_IPSEC_CONFIG_SELECTOR); 2834 Selector = AllocateZeroPool (SelectorBufferSize); 2835 2836 if (Selector == NULL) { 2837 return EFI_OUT_OF_RESOURCES; 2838 } 2839 2840 while (TRUE) { 2841 // 2842 // Get the real size of the selector. 2843 // 2844 SelectorSize = SelectorBufferSize; 2845 GetNextStatus = EfiIpSecConfigGetNextSelector ( 2846 &mIpSecConfigInstance, 2847 DataType, 2848 &SelectorSize, 2849 Selector 2850 ); 2851 if (GetNextStatus == EFI_BUFFER_TOO_SMALL) { 2852 FreePool (Selector); 2853 SelectorBufferSize = SelectorSize; 2854 // 2855 // Allocate zero pool for the first selector, while store the last 2856 // selector content for the other selectors. 2857 // 2858 if (FirstGetNext) { 2859 Selector = AllocateZeroPool (SelectorBufferSize); 2860 } else { 2861 Selector = AllocateCopyPool (SelectorBufferSize, Selector); 2862 } 2863 2864 if (Selector == NULL) { 2865 return EFI_OUT_OF_RESOURCES; 2866 } 2867 // 2868 // Get the content of the selector. 2869 // 2870 GetNextStatus = EfiIpSecConfigGetNextSelector ( 2871 &mIpSecConfigInstance, 2872 DataType, 2873 &SelectorSize, 2874 Selector 2875 ); 2876 } 2877 2878 if (EFI_ERROR (GetNextStatus)) { 2879 break; 2880 } 2881 2882 FirstGetNext = FALSE; 2883 2884 // 2885 // Get the real size of the policy entry according to the selector. 2886 // 2887 DataSize = DataBufferSize; 2888 GetDataStatus = EfiIpSecConfigGetData ( 2889 &mIpSecConfigInstance, 2890 DataType, 2891 Selector, 2892 &DataSize, 2893 Data 2894 ); 2895 if (GetDataStatus == EFI_BUFFER_TOO_SMALL) { 2896 if (Data != NULL) { 2897 FreePool (Data); 2898 } 2899 2900 DataBufferSize = DataSize; 2901 Data = AllocateZeroPool (DataBufferSize); 2902 2903 if (Data == NULL) { 2904 return EFI_OUT_OF_RESOURCES; 2905 } 2906 // 2907 // Get the content of the policy entry according to the selector. 2908 // 2909 GetDataStatus = EfiIpSecConfigGetData ( 2910 &mIpSecConfigInstance, 2911 DataType, 2912 Selector, 2913 &DataSize, 2914 Data 2915 ); 2916 } 2917 2918 if (EFI_ERROR (GetDataStatus)) { 2919 break; 2920 } 2921 // 2922 // Prepare the buffer of updated policy entry, which is stored in 2923 // the continous memory, and then save into variable later. 2924 // 2925 RoutineStatus = Routine ( 2926 DataType, 2927 Selector, 2928 Data, 2929 SelectorSize, 2930 DataSize, 2931 Context 2932 ); 2933 if (EFI_ERROR (RoutineStatus)) { 2934 break; 2935 } 2936 } 2937 2938 if (Data != NULL) { 2939 FreePool (Data); 2940 } 2941 2942 if (Selector != NULL) { 2943 FreePool (Selector); 2944 } 2945 2946 return EFI_SUCCESS; 2947 } 2948 2949 /** 2950 This function is the subfunction of EFIIpSecConfigSetData. 2951 2952 This function call IpSecSetVaraible to set the IPsec Configuration into the firmware. 2953 2954 @retval EFI_OUT_OF_RESOURCES The required system resource could not be allocated. 2955 @retval EFI_SUCCESS Saved the configration successfully. 2956 @retval Others Other errors were found while obtaining the variable. 2957 2958 **/ 2959 EFI_STATUS 2960 IpSecConfigSave ( 2961 VOID 2962 ) 2963 { 2964 IPSEC_VARIABLE_BUFFER Buffer; 2965 EFI_STATUS Status; 2966 EFI_IPSEC_CONFIG_DATA_TYPE Type; 2967 2968 Buffer.Size = 0; 2969 Buffer.Capacity = IPSEC_DEFAULT_VARIABLE_SIZE; 2970 Buffer.Ptr = AllocateZeroPool (Buffer.Capacity); 2971 2972 if (Buffer.Ptr == NULL) { 2973 return EFI_OUT_OF_RESOURCES; 2974 } 2975 // 2976 // For each policy database, prepare the contious buffer to save into variable. 2977 // 2978 for (Type = IPsecConfigDataTypeSpd; Type < IPsecConfigDataTypeMaximum; Type++) { 2979 IpSecVisitConfigData ( 2980 Type, 2981 (IPSEC_COPY_POLICY_ENTRY) IpSecCopyPolicyEntry, 2982 &Buffer 2983 ); 2984 } 2985 // 2986 // Save the updated policy database into variable. 2987 // 2988 Status = IpSecSetVariable ( 2989 IPSECCONFIG_VARIABLE_NAME, 2990 &gEfiIpSecConfigProtocolGuid, 2991 EFI_VARIABLE_BOOTSERVICE_ACCESS | EFI_VARIABLE_NON_VOLATILE, 2992 Buffer.Size, 2993 Buffer.Ptr 2994 ); 2995 2996 FreePool (Buffer.Ptr); 2997 2998 return Status; 2999 } 3000 3001 /** 3002 Get the all IPSec configuration variables and store those variables 3003 to the internal data structure. 3004 3005 This founction is called by IpSecConfigInitialize() which is to intialize the 3006 IPsecConfiguration Protocol. 3007 3008 @param[in] Private Point to IPSEC_PRIVATE_DATA. 3009 3010 @retval EFI_OUT_OF_RESOURCES The required system resource could not be allocated 3011 @retval EFI_SUCCESS Restore the IPsec Configuration successfully. 3012 @retval others Other errors is found while obtaining the variable. 3013 3014 **/ 3015 EFI_STATUS 3016 IpSecConfigRestore ( 3017 IN IPSEC_PRIVATE_DATA *Private 3018 ) 3019 { 3020 EFI_STATUS Status; 3021 UINTN BufferSize; 3022 UINT8 *Buffer; 3023 IPSEC_VAR_ITEM_HEADER *Header; 3024 UINT8 *Ptr; 3025 EFI_IPSEC_CONFIG_SELECTOR *Selector; 3026 EFI_IPSEC_CONFIG_DATA_TYPE Type; 3027 VOID *Data; 3028 UINT8 Value; 3029 UINTN Size; 3030 3031 Value = 0; 3032 Size = sizeof (Value); 3033 BufferSize = 0; 3034 Buffer = NULL; 3035 3036 Status = gRT->GetVariable ( 3037 IPSECCONFIG_STATUS_NAME, 3038 &gEfiIpSecConfigProtocolGuid, 3039 NULL, 3040 &Size, 3041 &Value 3042 ); 3043 3044 if (!EFI_ERROR (Status) && Value == IPSEC_STATUS_ENABLED) { 3045 Private->IpSec.DisabledFlag = FALSE; 3046 } 3047 // 3048 // Get the real size of policy database in variable. 3049 // 3050 Status = IpSecGetVariable ( 3051 IPSECCONFIG_VARIABLE_NAME, 3052 &gEfiIpSecConfigProtocolGuid, 3053 NULL, 3054 &BufferSize, 3055 Buffer 3056 ); 3057 if (Status == EFI_BUFFER_TOO_SMALL) { 3058 3059 Buffer = AllocateZeroPool (BufferSize); 3060 if (Buffer == NULL) { 3061 return EFI_OUT_OF_RESOURCES; 3062 } 3063 // 3064 // Get the content of policy database in variable. 3065 // 3066 Status = IpSecGetVariable ( 3067 IPSECCONFIG_VARIABLE_NAME, 3068 &gEfiIpSecConfigProtocolGuid, 3069 NULL, 3070 &BufferSize, 3071 Buffer 3072 ); 3073 if (EFI_ERROR (Status)) { 3074 FreePool (Buffer); 3075 return Status; 3076 } 3077 3078 for (Ptr = Buffer; Ptr < Buffer + BufferSize;) { 3079 3080 Header = (IPSEC_VAR_ITEM_HEADER *) Ptr; 3081 Type = (EFI_IPSEC_CONFIG_DATA_TYPE) (Header->Type & IPSEC_VAR_ITEM_HEADER_CONTENT_BIT); 3082 ASSERT (((Header->Type & 0x80) == IPSEC_VAR_ITEM_HEADER_LOGO_BIT) && (Type < IPsecConfigDataTypeMaximum)); 3083 3084 Selector = (EFI_IPSEC_CONFIG_SELECTOR *) ALIGN_POINTER (Header + 1, sizeof (UINTN)); 3085 Header = (IPSEC_VAR_ITEM_HEADER *) ALIGN_POINTER ( 3086 (UINT8 *) Selector + Header->Size, 3087 sizeof (UINTN) 3088 ); 3089 ASSERT (Header->Type == Type); 3090 3091 Data = ALIGN_POINTER (Header + 1, sizeof (UINTN)); 3092 3093 mUnfixPolicyEntry[Type](Selector, Data); 3094 3095 // 3096 // Update each policy entry according to the content in variable. 3097 // 3098 mSetBySelf = TRUE; 3099 Status = EfiIpSecConfigSetData ( 3100 &Private->IpSecConfig, 3101 Type, 3102 Selector, 3103 Data, 3104 NULL 3105 ); 3106 mSetBySelf = FALSE; 3107 3108 if (EFI_ERROR (Status)) { 3109 FreePool (Buffer); 3110 return Status; 3111 } 3112 3113 Ptr = ALIGN_POINTER ((UINT8 *) Data + Header->Size, sizeof (UINTN)); 3114 } 3115 3116 FreePool (Buffer); 3117 } 3118 3119 return EFI_SUCCESS; 3120 } 3121 3122 /** 3123 Install and Initialize IPsecConfig protocol 3124 3125 @param[in, out] Private Pointer to IPSEC_PRIVATE_DATA. After this function finish, 3126 the pointer of IPsecConfig Protocol implementation will copy 3127 into its IPsecConfig member. 3128 3129 @retval EFI_SUCCESS Initialized the IPsecConfig Protocol successfully. 3130 @retval Others Initializing the IPsecConfig Protocol failed. 3131 **/ 3132 EFI_STATUS 3133 IpSecConfigInitialize ( 3134 IN OUT IPSEC_PRIVATE_DATA *Private 3135 ) 3136 { 3137 EFI_IPSEC_CONFIG_DATA_TYPE Type; 3138 3139 CopyMem ( 3140 &Private->IpSecConfig, 3141 &mIpSecConfigInstance, 3142 sizeof (EFI_IPSEC_CONFIG_PROTOCOL) 3143 ); 3144 3145 // 3146 // Initialize the list head of policy database. 3147 // 3148 for (Type = IPsecConfigDataTypeSpd; Type < IPsecConfigDataTypeMaximum; Type++) { 3149 InitializeListHead (&mConfigData[Type]); 3150 } 3151 // 3152 // Restore the content of policy database according to the variable. 3153 // 3154 IpSecConfigRestore (Private); 3155 3156 return gBS->InstallMultipleProtocolInterfaces ( 3157 &Private->Handle, 3158 &gEfiIpSecConfigProtocolGuid, 3159 &Private->IpSecConfig, 3160 NULL 3161 ); 3162 } 3163