1 /** @file 2 PCI eunmeration implementation on entire PCI bus system for PCI Bus module. 3 4 Copyright (c) 2006 - 2013, Intel Corporation. All rights reserved.<BR> 5 (C) Copyright 2015 Hewlett Packard Enterprise Development LP<BR> 6 This program and the accompanying materials 7 are licensed and made available under the terms and conditions of the BSD License 8 which accompanies this distribution. The full text of the license may be found at 9 http://opensource.org/licenses/bsd-license.php 10 11 THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS, 12 WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED. 13 14 **/ 15 16 #include "PciBus.h" 17 18 /** 19 This routine is used to enumerate entire pci bus system 20 in a given platform. 21 22 @param Controller Parent controller handle. 23 24 @retval EFI_SUCCESS PCI enumeration finished successfully. 25 @retval other Some error occurred when enumerating the pci bus system. 26 27 **/ 28 EFI_STATUS 29 PciEnumerator ( 30 IN EFI_HANDLE Controller 31 ) 32 { 33 EFI_HANDLE HostBridgeHandle; 34 EFI_STATUS Status; 35 EFI_PCI_HOST_BRIDGE_RESOURCE_ALLOCATION_PROTOCOL *PciResAlloc; 36 EFI_PCI_ROOT_BRIDGE_IO_PROTOCOL *PciRootBridgeIo; 37 38 // 39 // If PCI bus has already done the full enumeration, never do it again 40 // 41 if (!gFullEnumeration) { 42 return PciEnumeratorLight (Controller); 43 } 44 45 // 46 // Get the rootbridge Io protocol to find the host bridge handle 47 // 48 Status = gBS->OpenProtocol ( 49 Controller, 50 &gEfiPciRootBridgeIoProtocolGuid, 51 (VOID **) &PciRootBridgeIo, 52 gPciBusDriverBinding.DriverBindingHandle, 53 Controller, 54 EFI_OPEN_PROTOCOL_GET_PROTOCOL 55 ); 56 57 if (EFI_ERROR (Status)) { 58 return Status; 59 } 60 61 // 62 // Get the host bridge handle 63 // 64 HostBridgeHandle = PciRootBridgeIo->ParentHandle; 65 66 // 67 // Get the pci host bridge resource allocation protocol 68 // 69 Status = gBS->OpenProtocol ( 70 HostBridgeHandle, 71 &gEfiPciHostBridgeResourceAllocationProtocolGuid, 72 (VOID **) &PciResAlloc, 73 gPciBusDriverBinding.DriverBindingHandle, 74 Controller, 75 EFI_OPEN_PROTOCOL_GET_PROTOCOL 76 ); 77 78 if (EFI_ERROR (Status)) { 79 return Status; 80 } 81 82 // 83 // Notify the pci bus enumeration is about to begin 84 // 85 Status = NotifyPhase (PciResAlloc, EfiPciHostBridgeBeginEnumeration); 86 87 if (EFI_ERROR (Status)) { 88 return Status; 89 } 90 91 // 92 // Start the bus allocation phase 93 // 94 Status = PciHostBridgeEnumerator (PciResAlloc); 95 96 if (EFI_ERROR (Status)) { 97 return Status; 98 } 99 100 // 101 // Submit the resource request 102 // 103 Status = PciHostBridgeResourceAllocator (PciResAlloc); 104 105 if (EFI_ERROR (Status)) { 106 return Status; 107 } 108 109 // 110 // Notify the pci bus enumeration is about to complete 111 // 112 Status = NotifyPhase (PciResAlloc, EfiPciHostBridgeEndEnumeration); 113 114 if (EFI_ERROR (Status)) { 115 return Status; 116 } 117 118 // 119 // Process P2C 120 // 121 Status = PciHostBridgeP2CProcess (PciResAlloc); 122 123 if (EFI_ERROR (Status)) { 124 return Status; 125 } 126 127 // 128 // Process attributes for devices on this host bridge 129 // 130 Status = PciHostBridgeDeviceAttribute (PciResAlloc); 131 if (EFI_ERROR (Status)) { 132 return Status; 133 } 134 135 gFullEnumeration = FALSE; 136 137 Status = gBS->InstallProtocolInterface ( 138 &HostBridgeHandle, 139 &gEfiPciEnumerationCompleteProtocolGuid, 140 EFI_NATIVE_INTERFACE, 141 NULL 142 ); 143 if (EFI_ERROR (Status)) { 144 return Status; 145 } 146 147 return EFI_SUCCESS; 148 } 149 150 /** 151 Enumerate PCI root bridge. 152 153 @param PciResAlloc Pointer to protocol instance of EFI_PCI_HOST_BRIDGE_RESOURCE_ALLOCATION_PROTOCOL. 154 @param RootBridgeDev Instance of root bridge device. 155 156 @retval EFI_SUCCESS Successfully enumerated root bridge. 157 @retval other Failed to enumerate root bridge. 158 159 **/ 160 EFI_STATUS 161 PciRootBridgeEnumerator ( 162 IN EFI_PCI_HOST_BRIDGE_RESOURCE_ALLOCATION_PROTOCOL *PciResAlloc, 163 IN PCI_IO_DEVICE *RootBridgeDev 164 ) 165 { 166 EFI_STATUS Status; 167 EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR *Configuration; 168 EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR *Configuration1; 169 EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR *Configuration2; 170 EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR *Configuration3; 171 UINT8 SubBusNumber; 172 UINT8 StartBusNumber; 173 UINT8 PaddedBusRange; 174 EFI_HANDLE RootBridgeHandle; 175 UINT8 Desc; 176 UINT64 AddrLen; 177 UINT64 AddrRangeMin; 178 179 SubBusNumber = 0; 180 StartBusNumber = 0; 181 PaddedBusRange = 0; 182 183 // 184 // Get the root bridge handle 185 // 186 RootBridgeHandle = RootBridgeDev->Handle; 187 188 REPORT_STATUS_CODE_WITH_DEVICE_PATH ( 189 EFI_PROGRESS_CODE, 190 EFI_IO_BUS_PCI | EFI_IOB_PCI_BUS_ENUM, 191 RootBridgeDev->DevicePath 192 ); 193 194 // 195 // Get the Bus information 196 // 197 Status = PciResAlloc->StartBusEnumeration ( 198 PciResAlloc, 199 RootBridgeHandle, 200 (VOID **) &Configuration 201 ); 202 203 if (EFI_ERROR (Status)) { 204 return Status; 205 } 206 207 if (Configuration == NULL || Configuration->Desc == ACPI_END_TAG_DESCRIPTOR) { 208 return EFI_INVALID_PARAMETER; 209 } 210 RootBridgeDev->BusNumberRanges = Configuration; 211 212 // 213 // Sort the descriptors in ascending order 214 // 215 for (Configuration1 = Configuration; Configuration1->Desc != ACPI_END_TAG_DESCRIPTOR; Configuration1++) { 216 Configuration2 = Configuration1; 217 for (Configuration3 = Configuration1 + 1; Configuration3->Desc != ACPI_END_TAG_DESCRIPTOR; Configuration3++) { 218 if (Configuration2->AddrRangeMin > Configuration3->AddrRangeMin) { 219 Configuration2 = Configuration3; 220 } 221 } 222 // 223 // All other fields other than AddrRangeMin and AddrLen are ignored in a descriptor, 224 // so only need to swap these two fields. 225 // 226 if (Configuration2 != Configuration1) { 227 AddrRangeMin = Configuration1->AddrRangeMin; 228 Configuration1->AddrRangeMin = Configuration2->AddrRangeMin; 229 Configuration2->AddrRangeMin = AddrRangeMin; 230 231 AddrLen = Configuration1->AddrLen; 232 Configuration1->AddrLen = Configuration2->AddrLen; 233 Configuration2->AddrLen = AddrLen; 234 } 235 } 236 237 // 238 // Get the bus number to start with 239 // 240 StartBusNumber = (UINT8) (Configuration->AddrRangeMin); 241 242 // 243 // Initialize the subordinate bus number 244 // 245 SubBusNumber = StartBusNumber; 246 247 // 248 // Reset all assigned PCI bus number 249 // 250 ResetAllPpbBusNumber ( 251 RootBridgeDev, 252 StartBusNumber 253 ); 254 255 // 256 // Assign bus number 257 // 258 Status = PciScanBus ( 259 RootBridgeDev, 260 StartBusNumber, 261 &SubBusNumber, 262 &PaddedBusRange 263 ); 264 265 if (EFI_ERROR (Status)) { 266 return Status; 267 } 268 269 270 // 271 // Assign max bus number scanned 272 // 273 274 Status = PciAllocateBusNumber (RootBridgeDev, SubBusNumber, PaddedBusRange, &SubBusNumber); 275 if (EFI_ERROR (Status)) { 276 return Status; 277 } 278 279 // 280 // Find the bus range which contains the higest bus number, then returns the number of buses 281 // that should be decoded. 282 // 283 while (Configuration->AddrRangeMin + Configuration->AddrLen - 1 < SubBusNumber) { 284 Configuration++; 285 } 286 AddrLen = Configuration->AddrLen; 287 Configuration->AddrLen = SubBusNumber - Configuration->AddrRangeMin + 1; 288 289 // 290 // Save the Desc field of the next descriptor. Mark the next descriptor as an END descriptor. 291 // 292 Configuration++; 293 Desc = Configuration->Desc; 294 Configuration->Desc = ACPI_END_TAG_DESCRIPTOR; 295 296 // 297 // Set bus number 298 // 299 Status = PciResAlloc->SetBusNumbers ( 300 PciResAlloc, 301 RootBridgeHandle, 302 RootBridgeDev->BusNumberRanges 303 ); 304 305 // 306 // Restore changed fields 307 // 308 Configuration->Desc = Desc; 309 (Configuration - 1)->AddrLen = AddrLen; 310 311 return Status; 312 } 313 314 /** 315 This routine is used to process all PCI devices' Option Rom 316 on a certain root bridge. 317 318 @param Bridge Given parent's root bridge. 319 @param RomBase Base address of ROM driver loaded from. 320 @param MaxLength Maximum rom size. 321 322 **/ 323 VOID 324 ProcessOptionRom ( 325 IN PCI_IO_DEVICE *Bridge, 326 IN UINT64 RomBase, 327 IN UINT64 MaxLength 328 ) 329 { 330 LIST_ENTRY *CurrentLink; 331 PCI_IO_DEVICE *Temp; 332 333 // 334 // Go through bridges to reach all devices 335 // 336 CurrentLink = Bridge->ChildList.ForwardLink; 337 while (CurrentLink != NULL && CurrentLink != &Bridge->ChildList) { 338 Temp = PCI_IO_DEVICE_FROM_LINK (CurrentLink); 339 if (!IsListEmpty (&Temp->ChildList)) { 340 341 // 342 // Go further to process the option rom under this bridge 343 // 344 ProcessOptionRom (Temp, RomBase, MaxLength); 345 } 346 347 if (Temp->RomSize != 0 && Temp->RomSize <= MaxLength) { 348 349 // 350 // Load and process the option rom 351 // 352 LoadOpRomImage (Temp, RomBase); 353 } 354 355 CurrentLink = CurrentLink->ForwardLink; 356 } 357 } 358 359 /** 360 This routine is used to assign bus number to the given PCI bus system 361 362 @param Bridge Parent root bridge instance. 363 @param StartBusNumber Number of beginning. 364 @param SubBusNumber The number of sub bus. 365 366 @retval EFI_SUCCESS Successfully assigned bus number. 367 @retval EFI_DEVICE_ERROR Failed to assign bus number. 368 369 **/ 370 EFI_STATUS 371 PciAssignBusNumber ( 372 IN PCI_IO_DEVICE *Bridge, 373 IN UINT8 StartBusNumber, 374 OUT UINT8 *SubBusNumber 375 ) 376 { 377 EFI_STATUS Status; 378 PCI_TYPE00 Pci; 379 UINT8 Device; 380 UINT8 Func; 381 UINT64 Address; 382 UINTN SecondBus; 383 UINT16 Register; 384 UINT8 Register8; 385 EFI_PCI_ROOT_BRIDGE_IO_PROTOCOL *PciRootBridgeIo; 386 387 PciRootBridgeIo = Bridge->PciRootBridgeIo; 388 389 SecondBus = 0; 390 Register = 0; 391 392 *SubBusNumber = StartBusNumber; 393 394 // 395 // First check to see whether the parent is ppb 396 // 397 for (Device = 0; Device <= PCI_MAX_DEVICE; Device++) { 398 for (Func = 0; Func <= PCI_MAX_FUNC; Func++) { 399 400 // 401 // Check to see whether a pci device is present 402 // 403 Status = PciDevicePresent ( 404 PciRootBridgeIo, 405 &Pci, 406 StartBusNumber, 407 Device, 408 Func 409 ); 410 411 if (EFI_ERROR (Status) && Func == 0) { 412 // 413 // go to next device if there is no Function 0 414 // 415 break; 416 } 417 418 if (!EFI_ERROR (Status) && 419 (IS_PCI_BRIDGE (&Pci) || IS_CARDBUS_BRIDGE (&Pci))) { 420 421 // 422 // Reserved one bus for cardbus bridge 423 // 424 Status = PciAllocateBusNumber (Bridge, *SubBusNumber, 1, SubBusNumber); 425 if (EFI_ERROR (Status)) { 426 return Status; 427 } 428 SecondBus = *SubBusNumber; 429 430 Register = (UINT16) ((SecondBus << 8) | (UINT16) StartBusNumber); 431 432 Address = EFI_PCI_ADDRESS (StartBusNumber, Device, Func, 0x18); 433 434 Status = PciRootBridgeIo->Pci.Write ( 435 PciRootBridgeIo, 436 EfiPciWidthUint16, 437 Address, 438 1, 439 &Register 440 ); 441 442 // 443 // Initialize SubBusNumber to SecondBus 444 // 445 Address = EFI_PCI_ADDRESS (StartBusNumber, Device, Func, 0x1A); 446 Status = PciRootBridgeIo->Pci.Write ( 447 PciRootBridgeIo, 448 EfiPciWidthUint8, 449 Address, 450 1, 451 SubBusNumber 452 ); 453 // 454 // If it is PPB, resursively search down this bridge 455 // 456 if (IS_PCI_BRIDGE (&Pci)) { 457 458 Register8 = 0xFF; 459 Status = PciRootBridgeIo->Pci.Write ( 460 PciRootBridgeIo, 461 EfiPciWidthUint8, 462 Address, 463 1, 464 &Register8 465 ); 466 467 Status = PciAssignBusNumber ( 468 Bridge, 469 (UINT8) (SecondBus), 470 SubBusNumber 471 ); 472 473 if (EFI_ERROR (Status)) { 474 return EFI_DEVICE_ERROR; 475 } 476 } 477 478 // 479 // Set the current maximum bus number under the PPB 480 // 481 Address = EFI_PCI_ADDRESS (StartBusNumber, Device, Func, 0x1A); 482 483 Status = PciRootBridgeIo->Pci.Write ( 484 PciRootBridgeIo, 485 EfiPciWidthUint8, 486 Address, 487 1, 488 SubBusNumber 489 ); 490 491 } 492 493 if (Func == 0 && !IS_PCI_MULTI_FUNC (&Pci)) { 494 495 // 496 // Skip sub functions, this is not a multi function device 497 // 498 Func = PCI_MAX_FUNC; 499 } 500 } 501 } 502 503 return EFI_SUCCESS; 504 } 505 506 /** 507 This routine is used to determine the root bridge attribute by interfacing 508 the host bridge resource allocation protocol. 509 510 @param PciResAlloc Protocol instance of EFI_PCI_HOST_BRIDGE_RESOURCE_ALLOCATION_PROTOCOL 511 @param RootBridgeDev Root bridge instance 512 513 @retval EFI_SUCCESS Successfully got root bridge's attribute. 514 @retval other Failed to get attribute. 515 516 **/ 517 EFI_STATUS 518 DetermineRootBridgeAttributes ( 519 IN EFI_PCI_HOST_BRIDGE_RESOURCE_ALLOCATION_PROTOCOL *PciResAlloc, 520 IN PCI_IO_DEVICE *RootBridgeDev 521 ) 522 { 523 UINT64 Attributes; 524 EFI_STATUS Status; 525 EFI_HANDLE RootBridgeHandle; 526 527 Attributes = 0; 528 RootBridgeHandle = RootBridgeDev->Handle; 529 530 // 531 // Get root bridge attribute by calling into pci host bridge resource allocation protocol 532 // 533 Status = PciResAlloc->GetAllocAttributes ( 534 PciResAlloc, 535 RootBridgeHandle, 536 &Attributes 537 ); 538 539 if (EFI_ERROR (Status)) { 540 return Status; 541 } 542 543 // 544 // Here is the point where PCI bus driver calls HOST bridge allocation protocol 545 // Currently we hardcoded for ea815 546 // 547 if ((Attributes & EFI_PCI_HOST_BRIDGE_COMBINE_MEM_PMEM) != 0) { 548 RootBridgeDev->Decodes |= EFI_BRIDGE_PMEM_MEM_COMBINE_SUPPORTED; 549 } 550 551 if ((Attributes & EFI_PCI_HOST_BRIDGE_MEM64_DECODE) != 0) { 552 RootBridgeDev->Decodes |= EFI_BRIDGE_MEM64_DECODE_SUPPORTED; 553 RootBridgeDev->Decodes |= EFI_BRIDGE_PMEM64_DECODE_SUPPORTED; 554 } 555 556 RootBridgeDev->Decodes |= EFI_BRIDGE_MEM32_DECODE_SUPPORTED; 557 RootBridgeDev->Decodes |= EFI_BRIDGE_PMEM32_DECODE_SUPPORTED; 558 RootBridgeDev->Decodes |= EFI_BRIDGE_IO16_DECODE_SUPPORTED; 559 560 return EFI_SUCCESS; 561 } 562 563 /** 564 Get Max Option Rom size on specified bridge. 565 566 @param Bridge Given bridge device instance. 567 568 @return Max size of option rom needed. 569 570 **/ 571 UINT64 572 GetMaxOptionRomSize ( 573 IN PCI_IO_DEVICE *Bridge 574 ) 575 { 576 LIST_ENTRY *CurrentLink; 577 PCI_IO_DEVICE *Temp; 578 UINT64 MaxOptionRomSize; 579 UINT64 TempOptionRomSize; 580 581 MaxOptionRomSize = 0; 582 583 // 584 // Go through bridges to reach all devices 585 // 586 CurrentLink = Bridge->ChildList.ForwardLink; 587 while (CurrentLink != NULL && CurrentLink != &Bridge->ChildList) { 588 Temp = PCI_IO_DEVICE_FROM_LINK (CurrentLink); 589 if (!IsListEmpty (&Temp->ChildList)) { 590 591 // 592 // Get max option rom size under this bridge 593 // 594 TempOptionRomSize = GetMaxOptionRomSize (Temp); 595 596 // 597 // Compare with the option rom size of the bridge 598 // Get the larger one 599 // 600 if (Temp->RomSize > TempOptionRomSize) { 601 TempOptionRomSize = Temp->RomSize; 602 } 603 604 } else { 605 606 // 607 // For devices get the rom size directly 608 // 609 TempOptionRomSize = Temp->RomSize; 610 } 611 612 // 613 // Get the largest rom size on this bridge 614 // 615 if (TempOptionRomSize > MaxOptionRomSize) { 616 MaxOptionRomSize = TempOptionRomSize; 617 } 618 619 CurrentLink = CurrentLink->ForwardLink; 620 } 621 622 return MaxOptionRomSize; 623 } 624 625 /** 626 Process attributes of devices on this host bridge 627 628 @param PciResAlloc Protocol instance of EFI_PCI_HOST_BRIDGE_RESOURCE_ALLOCATION_PROTOCOL. 629 630 @retval EFI_SUCCESS Successfully process attribute. 631 @retval EFI_NOT_FOUND Can not find the specific root bridge device. 632 @retval other Failed to determine the root bridge device's attribute. 633 634 **/ 635 EFI_STATUS 636 PciHostBridgeDeviceAttribute ( 637 IN EFI_PCI_HOST_BRIDGE_RESOURCE_ALLOCATION_PROTOCOL *PciResAlloc 638 ) 639 { 640 EFI_HANDLE RootBridgeHandle; 641 PCI_IO_DEVICE *RootBridgeDev; 642 EFI_STATUS Status; 643 644 RootBridgeHandle = NULL; 645 646 while (PciResAlloc->GetNextRootBridge (PciResAlloc, &RootBridgeHandle) == EFI_SUCCESS) { 647 648 // 649 // Get RootBridg Device by handle 650 // 651 RootBridgeDev = GetRootBridgeByHandle (RootBridgeHandle); 652 653 if (RootBridgeDev == NULL) { 654 return EFI_NOT_FOUND; 655 } 656 657 // 658 // Set the attributes for devcies behind the Root Bridge 659 // 660 Status = DetermineDeviceAttribute (RootBridgeDev); 661 if (EFI_ERROR (Status)) { 662 return Status; 663 } 664 665 } 666 667 return EFI_SUCCESS; 668 } 669 670 /** 671 Get resource allocation status from the ACPI resource descriptor. 672 673 @param AcpiConfig Point to Acpi configuration table. 674 @param IoResStatus Return the status of I/O resource. 675 @param Mem32ResStatus Return the status of 32-bit Memory resource. 676 @param PMem32ResStatus Return the status of 32-bit Prefetchable Memory resource. 677 @param Mem64ResStatus Return the status of 64-bit Memory resource. 678 @param PMem64ResStatus Return the status of 64-bit Prefetchable Memory resource. 679 680 **/ 681 VOID 682 GetResourceAllocationStatus ( 683 VOID *AcpiConfig, 684 OUT UINT64 *IoResStatus, 685 OUT UINT64 *Mem32ResStatus, 686 OUT UINT64 *PMem32ResStatus, 687 OUT UINT64 *Mem64ResStatus, 688 OUT UINT64 *PMem64ResStatus 689 ) 690 { 691 UINT8 *Temp; 692 UINT64 ResStatus; 693 EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR *ACPIAddressDesc; 694 695 Temp = (UINT8 *) AcpiConfig; 696 697 while (*Temp == ACPI_ADDRESS_SPACE_DESCRIPTOR) { 698 699 ACPIAddressDesc = (EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR *) Temp; 700 ResStatus = ACPIAddressDesc->AddrTranslationOffset; 701 702 switch (ACPIAddressDesc->ResType) { 703 case 0: 704 if (ACPIAddressDesc->AddrSpaceGranularity == 32) { 705 if (ACPIAddressDesc->SpecificFlag == 0x06) { 706 // 707 // Pmem32 708 // 709 *PMem32ResStatus = ResStatus; 710 } else { 711 // 712 // Mem32 713 // 714 *Mem32ResStatus = ResStatus; 715 } 716 } 717 718 if (ACPIAddressDesc->AddrSpaceGranularity == 64) { 719 if (ACPIAddressDesc->SpecificFlag == 0x06) { 720 // 721 // PMem64 722 // 723 *PMem64ResStatus = ResStatus; 724 } else { 725 // 726 // Mem64 727 // 728 *Mem64ResStatus = ResStatus; 729 } 730 } 731 732 break; 733 734 case 1: 735 // 736 // Io 737 // 738 *IoResStatus = ResStatus; 739 break; 740 741 default: 742 break; 743 } 744 745 Temp += sizeof (EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR); 746 } 747 } 748 749 /** 750 Remove a PCI device from device pool and mark its bar. 751 752 @param PciDevice Instance of Pci device. 753 754 @retval EFI_SUCCESS Successfully remove the PCI device. 755 @retval EFI_ABORTED Pci device is a root bridge or a PCI-PCI bridge. 756 757 **/ 758 EFI_STATUS 759 RejectPciDevice ( 760 IN PCI_IO_DEVICE *PciDevice 761 ) 762 { 763 PCI_IO_DEVICE *Bridge; 764 PCI_IO_DEVICE *Temp; 765 LIST_ENTRY *CurrentLink; 766 767 // 768 // Remove the padding resource from a bridge 769 // 770 if ( IS_PCI_BRIDGE(&PciDevice->Pci) && 771 PciDevice->ResourcePaddingDescriptors != NULL ) { 772 FreePool (PciDevice->ResourcePaddingDescriptors); 773 PciDevice->ResourcePaddingDescriptors = NULL; 774 return EFI_SUCCESS; 775 } 776 777 // 778 // Skip RB and PPB 779 // 780 if (IS_PCI_BRIDGE (&PciDevice->Pci) || (PciDevice->Parent == NULL)) { 781 return EFI_ABORTED; 782 } 783 784 if (IS_CARDBUS_BRIDGE (&PciDevice->Pci)) { 785 // 786 // Get the root bridge device 787 // 788 Bridge = PciDevice; 789 while (Bridge->Parent != NULL) { 790 Bridge = Bridge->Parent; 791 } 792 793 RemoveAllPciDeviceOnBridge (Bridge->Handle, PciDevice); 794 795 // 796 // Mark its bar 797 // 798 InitializeP2C (PciDevice); 799 } 800 801 // 802 // Remove the device 803 // 804 Bridge = PciDevice->Parent; 805 CurrentLink = Bridge->ChildList.ForwardLink; 806 while (CurrentLink != NULL && CurrentLink != &Bridge->ChildList) { 807 Temp = PCI_IO_DEVICE_FROM_LINK (CurrentLink); 808 if (Temp == PciDevice) { 809 InitializePciDevice (Temp); 810 RemoveEntryList (CurrentLink); 811 return EFI_SUCCESS; 812 } 813 814 CurrentLink = CurrentLink->ForwardLink; 815 } 816 817 return EFI_ABORTED; 818 } 819 820 /** 821 Determine whethter a PCI device can be rejected. 822 823 @param PciResNode Pointer to Pci resource node instance. 824 825 @retval TRUE The PCI device can be rejected. 826 @retval TRUE The PCI device cannot be rejected. 827 828 **/ 829 BOOLEAN 830 IsRejectiveDevice ( 831 IN PCI_RESOURCE_NODE *PciResNode 832 ) 833 { 834 PCI_IO_DEVICE *Temp; 835 836 Temp = PciResNode->PciDev; 837 838 // 839 // Ensure the device is present 840 // 841 if (Temp == NULL) { 842 return FALSE; 843 } 844 845 // 846 // PPB and RB should go ahead 847 // 848 if (IS_PCI_BRIDGE (&Temp->Pci) || (Temp->Parent == NULL)) { 849 return TRUE; 850 } 851 852 // 853 // Skip device on Bus0 854 // 855 if ((Temp->Parent != NULL) && (Temp->BusNumber == 0)) { 856 return FALSE; 857 } 858 859 // 860 // Skip VGA 861 // 862 if (IS_PCI_VGA (&Temp->Pci)) { 863 return FALSE; 864 } 865 866 return TRUE; 867 } 868 869 /** 870 Compare two resource nodes and get the larger resource consumer. 871 872 @param PciResNode1 resource node 1 want to be compared 873 @param PciResNode2 resource node 2 want to be compared 874 875 @return Larger resource node. 876 877 **/ 878 PCI_RESOURCE_NODE * 879 GetLargerConsumerDevice ( 880 IN PCI_RESOURCE_NODE *PciResNode1, 881 IN PCI_RESOURCE_NODE *PciResNode2 882 ) 883 { 884 if (PciResNode2 == NULL) { 885 return PciResNode1; 886 } 887 888 if ((IS_PCI_BRIDGE(&(PciResNode2->PciDev->Pci)) || (PciResNode2->PciDev->Parent == NULL)) \ 889 && (PciResNode2->ResourceUsage != PciResUsagePadding) ) 890 { 891 return PciResNode1; 892 } 893 894 if (PciResNode1 == NULL) { 895 return PciResNode2; 896 } 897 898 if ((PciResNode1->Length) > (PciResNode2->Length)) { 899 return PciResNode1; 900 } 901 902 return PciResNode2; 903 } 904 905 906 /** 907 Get the max resource consumer in the host resource pool. 908 909 @param ResPool Pointer to resource pool node. 910 911 @return The max resource consumer in the host resource pool. 912 913 **/ 914 PCI_RESOURCE_NODE * 915 GetMaxResourceConsumerDevice ( 916 IN PCI_RESOURCE_NODE *ResPool 917 ) 918 { 919 PCI_RESOURCE_NODE *Temp; 920 LIST_ENTRY *CurrentLink; 921 PCI_RESOURCE_NODE *PciResNode; 922 PCI_RESOURCE_NODE *PPBResNode; 923 924 PciResNode = NULL; 925 926 CurrentLink = ResPool->ChildList.ForwardLink; 927 while (CurrentLink != NULL && CurrentLink != &ResPool->ChildList) { 928 929 Temp = RESOURCE_NODE_FROM_LINK (CurrentLink); 930 931 if (!IsRejectiveDevice (Temp)) { 932 CurrentLink = CurrentLink->ForwardLink; 933 continue; 934 } 935 936 if ((IS_PCI_BRIDGE (&(Temp->PciDev->Pci)) || (Temp->PciDev->Parent == NULL)) \ 937 && (Temp->ResourceUsage != PciResUsagePadding)) 938 { 939 PPBResNode = GetMaxResourceConsumerDevice (Temp); 940 PciResNode = GetLargerConsumerDevice (PciResNode, PPBResNode); 941 } else { 942 PciResNode = GetLargerConsumerDevice (PciResNode, Temp); 943 } 944 945 CurrentLink = CurrentLink->ForwardLink; 946 } 947 948 return PciResNode; 949 } 950 951 /** 952 Adjust host bridge allocation so as to reduce resource requirement 953 954 @param IoPool Pointer to instance of I/O resource Node. 955 @param Mem32Pool Pointer to instance of 32-bit memory resource Node. 956 @param PMem32Pool Pointer to instance of 32-bit Prefetchable memory resource node. 957 @param Mem64Pool Pointer to instance of 64-bit memory resource node. 958 @param PMem64Pool Pointer to instance of 64-bit Prefetchable memory resource node. 959 @param IoResStatus Status of I/O resource Node. 960 @param Mem32ResStatus Status of 32-bit memory resource Node. 961 @param PMem32ResStatus Status of 32-bit Prefetchable memory resource node. 962 @param Mem64ResStatus Status of 64-bit memory resource node. 963 @param PMem64ResStatus Status of 64-bit Prefetchable memory resource node. 964 965 @retval EFI_SUCCESS Successfully adjusted resoruce on host bridge. 966 @retval EFI_ABORTED Host bridge hasn't this resource type or no resource be adjusted. 967 968 **/ 969 EFI_STATUS 970 PciHostBridgeAdjustAllocation ( 971 IN PCI_RESOURCE_NODE *IoPool, 972 IN PCI_RESOURCE_NODE *Mem32Pool, 973 IN PCI_RESOURCE_NODE *PMem32Pool, 974 IN PCI_RESOURCE_NODE *Mem64Pool, 975 IN PCI_RESOURCE_NODE *PMem64Pool, 976 IN UINT64 IoResStatus, 977 IN UINT64 Mem32ResStatus, 978 IN UINT64 PMem32ResStatus, 979 IN UINT64 Mem64ResStatus, 980 IN UINT64 PMem64ResStatus 981 ) 982 { 983 BOOLEAN AllocationAjusted; 984 PCI_RESOURCE_NODE *PciResNode; 985 PCI_RESOURCE_NODE *ResPool[5]; 986 PCI_IO_DEVICE *RemovedPciDev[5]; 987 UINT64 ResStatus[5]; 988 UINTN RemovedPciDevNum; 989 UINTN DevIndex; 990 UINTN ResType; 991 EFI_STATUS Status; 992 EFI_RESOURCE_ALLOC_FAILURE_ERROR_DATA_PAYLOAD AllocFailExtendedData; 993 994 PciResNode = NULL; 995 ZeroMem (RemovedPciDev, 5 * sizeof (PCI_IO_DEVICE *)); 996 RemovedPciDevNum = 0; 997 998 ResPool[0] = IoPool; 999 ResPool[1] = Mem32Pool; 1000 ResPool[2] = PMem32Pool; 1001 ResPool[3] = Mem64Pool; 1002 ResPool[4] = PMem64Pool; 1003 1004 ResStatus[0] = IoResStatus; 1005 ResStatus[1] = Mem32ResStatus; 1006 ResStatus[2] = PMem32ResStatus; 1007 ResStatus[3] = Mem64ResStatus; 1008 ResStatus[4] = PMem64ResStatus; 1009 1010 AllocationAjusted = FALSE; 1011 1012 for (ResType = 0; ResType < 5; ResType++) { 1013 1014 if (ResStatus[ResType] == EFI_RESOURCE_SATISFIED) { 1015 continue; 1016 } 1017 1018 if (ResStatus[ResType] == EFI_RESOURCE_NOT_SATISFIED) { 1019 // 1020 // Host bridge hasn't this resource type 1021 // 1022 return EFI_ABORTED; 1023 } 1024 1025 // 1026 // Hostbridge hasn't enough resource 1027 // 1028 PciResNode = GetMaxResourceConsumerDevice (ResPool[ResType]); 1029 if (PciResNode == NULL) { 1030 continue; 1031 } 1032 1033 // 1034 // Check if the device has been removed before 1035 // 1036 for (DevIndex = 0; DevIndex < RemovedPciDevNum; DevIndex++) { 1037 if (PciResNode->PciDev == RemovedPciDev[DevIndex]) { 1038 break; 1039 } 1040 } 1041 1042 if (DevIndex != RemovedPciDevNum) { 1043 continue; 1044 } 1045 1046 // 1047 // Remove the device if it isn't in the array 1048 // 1049 Status = RejectPciDevice (PciResNode->PciDev); 1050 if (Status == EFI_SUCCESS) { 1051 DEBUG (( 1052 EFI_D_ERROR, 1053 "PciBus: [%02x|%02x|%02x] was rejected due to resource confliction.\n", 1054 PciResNode->PciDev->BusNumber, PciResNode->PciDev->DeviceNumber, PciResNode->PciDev->FunctionNumber 1055 )); 1056 1057 // 1058 // Raise the EFI_IOB_EC_RESOURCE_CONFLICT status code 1059 // 1060 // 1061 // Have no way to get ReqRes, AllocRes & Bar here 1062 // 1063 ZeroMem (&AllocFailExtendedData, sizeof (AllocFailExtendedData)); 1064 AllocFailExtendedData.DevicePathSize = (UINT16) sizeof (EFI_DEVICE_PATH_PROTOCOL); 1065 AllocFailExtendedData.DevicePath = (UINT8 *) PciResNode->PciDev->DevicePath; 1066 AllocFailExtendedData.Bar = PciResNode->Bar; 1067 1068 REPORT_STATUS_CODE_WITH_EXTENDED_DATA ( 1069 EFI_PROGRESS_CODE, 1070 EFI_IO_BUS_PCI | EFI_IOB_EC_RESOURCE_CONFLICT, 1071 (VOID *) &AllocFailExtendedData, 1072 sizeof (AllocFailExtendedData) 1073 ); 1074 1075 // 1076 // Add it to the array and indicate at least a device has been rejected 1077 // 1078 RemovedPciDev[RemovedPciDevNum++] = PciResNode->PciDev; 1079 AllocationAjusted = TRUE; 1080 } 1081 } 1082 // 1083 // End for 1084 // 1085 1086 if (AllocationAjusted) { 1087 return EFI_SUCCESS; 1088 } else { 1089 return EFI_ABORTED; 1090 } 1091 } 1092 1093 /** 1094 Summary requests for all resource type, and contruct ACPI resource 1095 requestor instance. 1096 1097 @param Bridge detecting bridge 1098 @param IoNode Pointer to instance of I/O resource Node 1099 @param Mem32Node Pointer to instance of 32-bit memory resource Node 1100 @param PMem32Node Pointer to instance of 32-bit Pmemory resource node 1101 @param Mem64Node Pointer to instance of 64-bit memory resource node 1102 @param PMem64Node Pointer to instance of 64-bit Pmemory resource node 1103 @param Config Output buffer holding new constructed APCI resource requestor 1104 1105 @retval EFI_SUCCESS Successfully constructed ACPI resource. 1106 @retval EFI_OUT_OF_RESOURCES No memory availabe. 1107 1108 **/ 1109 EFI_STATUS 1110 ConstructAcpiResourceRequestor ( 1111 IN PCI_IO_DEVICE *Bridge, 1112 IN PCI_RESOURCE_NODE *IoNode, 1113 IN PCI_RESOURCE_NODE *Mem32Node, 1114 IN PCI_RESOURCE_NODE *PMem32Node, 1115 IN PCI_RESOURCE_NODE *Mem64Node, 1116 IN PCI_RESOURCE_NODE *PMem64Node, 1117 OUT VOID **Config 1118 ) 1119 { 1120 UINT8 NumConfig; 1121 UINT8 Aperture; 1122 UINT8 *Configuration; 1123 EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR *Ptr; 1124 EFI_ACPI_END_TAG_DESCRIPTOR *PtrEnd; 1125 1126 NumConfig = 0; 1127 Aperture = 0; 1128 1129 *Config = NULL; 1130 1131 // 1132 // if there is io request, add to the io aperture 1133 // 1134 if (ResourceRequestExisted (IoNode)) { 1135 NumConfig++; 1136 Aperture |= 0x01; 1137 } 1138 1139 // 1140 // if there is mem32 request, add to the mem32 aperture 1141 // 1142 if (ResourceRequestExisted (Mem32Node)) { 1143 NumConfig++; 1144 Aperture |= 0x02; 1145 } 1146 1147 // 1148 // if there is pmem32 request, add to the pmem32 aperture 1149 // 1150 if (ResourceRequestExisted (PMem32Node)) { 1151 NumConfig++; 1152 Aperture |= 0x04; 1153 } 1154 1155 // 1156 // if there is mem64 request, add to the mem64 aperture 1157 // 1158 if (ResourceRequestExisted (Mem64Node)) { 1159 NumConfig++; 1160 Aperture |= 0x08; 1161 } 1162 1163 // 1164 // if there is pmem64 request, add to the pmem64 aperture 1165 // 1166 if (ResourceRequestExisted (PMem64Node)) { 1167 NumConfig++; 1168 Aperture |= 0x10; 1169 } 1170 1171 if (NumConfig != 0) { 1172 1173 // 1174 // If there is at least one type of resource request, 1175 // allocate a acpi resource node 1176 // 1177 Configuration = AllocateZeroPool (sizeof (EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR) * NumConfig + sizeof (EFI_ACPI_END_TAG_DESCRIPTOR)); 1178 if (Configuration == NULL) { 1179 return EFI_OUT_OF_RESOURCES; 1180 } 1181 1182 Ptr = (EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR *) Configuration; 1183 1184 // 1185 // Deal with io aperture 1186 // 1187 if ((Aperture & 0x01) != 0) { 1188 Ptr->Desc = ACPI_ADDRESS_SPACE_DESCRIPTOR; 1189 Ptr->Len = (UINT16) (sizeof (EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR) - 3); 1190 // 1191 // Io 1192 // 1193 Ptr->ResType = ACPI_ADDRESS_SPACE_TYPE_IO; 1194 // 1195 // non ISA range 1196 // 1197 Ptr->SpecificFlag = 1; 1198 Ptr->AddrLen = IoNode->Length; 1199 Ptr->AddrRangeMax = IoNode->Alignment; 1200 1201 Ptr++; 1202 } 1203 // 1204 // Deal with mem32 aperture 1205 // 1206 if ((Aperture & 0x02) != 0) { 1207 Ptr->Desc = ACPI_ADDRESS_SPACE_DESCRIPTOR; 1208 Ptr->Len = (UINT16) (sizeof (EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR) - 3); 1209 // 1210 // Mem 1211 // 1212 Ptr->ResType = ACPI_ADDRESS_SPACE_TYPE_MEM; 1213 // 1214 // Nonprefechable 1215 // 1216 Ptr->SpecificFlag = 0; 1217 // 1218 // 32 bit 1219 // 1220 Ptr->AddrSpaceGranularity = 32; 1221 Ptr->AddrLen = Mem32Node->Length; 1222 Ptr->AddrRangeMax = Mem32Node->Alignment; 1223 1224 Ptr++; 1225 } 1226 1227 // 1228 // Deal with Pmem32 aperture 1229 // 1230 if ((Aperture & 0x04) != 0) { 1231 Ptr->Desc = ACPI_ADDRESS_SPACE_DESCRIPTOR; 1232 Ptr->Len = (UINT16) (sizeof (EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR) - 3); 1233 // 1234 // Mem 1235 // 1236 Ptr->ResType = ACPI_ADDRESS_SPACE_TYPE_MEM; 1237 // 1238 // prefechable 1239 // 1240 Ptr->SpecificFlag = 0x6; 1241 // 1242 // 32 bit 1243 // 1244 Ptr->AddrSpaceGranularity = 32; 1245 Ptr->AddrLen = PMem32Node->Length; 1246 Ptr->AddrRangeMax = PMem32Node->Alignment; 1247 1248 Ptr++; 1249 } 1250 // 1251 // Deal with mem64 aperture 1252 // 1253 if ((Aperture & 0x08) != 0) { 1254 Ptr->Desc = ACPI_ADDRESS_SPACE_DESCRIPTOR; 1255 Ptr->Len = (UINT16) (sizeof (EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR) - 3); 1256 // 1257 // Mem 1258 // 1259 Ptr->ResType = ACPI_ADDRESS_SPACE_TYPE_MEM; 1260 // 1261 // nonprefechable 1262 // 1263 Ptr->SpecificFlag = 0; 1264 // 1265 // 64 bit 1266 // 1267 Ptr->AddrSpaceGranularity = 64; 1268 Ptr->AddrLen = Mem64Node->Length; 1269 Ptr->AddrRangeMax = Mem64Node->Alignment; 1270 1271 Ptr++; 1272 } 1273 // 1274 // Deal with Pmem64 aperture 1275 // 1276 if ((Aperture & 0x10) != 0) { 1277 Ptr->Desc = ACPI_ADDRESS_SPACE_DESCRIPTOR; 1278 Ptr->Len = (UINT16) (sizeof (EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR) - 3); 1279 // 1280 // Mem 1281 // 1282 Ptr->ResType = ACPI_ADDRESS_SPACE_TYPE_MEM; 1283 // 1284 // prefechable 1285 // 1286 Ptr->SpecificFlag = 0x06; 1287 // 1288 // 64 bit 1289 // 1290 Ptr->AddrSpaceGranularity = 64; 1291 Ptr->AddrLen = PMem64Node->Length; 1292 Ptr->AddrRangeMax = PMem64Node->Alignment; 1293 1294 Ptr++; 1295 } 1296 1297 // 1298 // put the checksum 1299 // 1300 PtrEnd = (EFI_ACPI_END_TAG_DESCRIPTOR *) Ptr; 1301 1302 PtrEnd->Desc = ACPI_END_TAG_DESCRIPTOR; 1303 PtrEnd->Checksum = 0; 1304 1305 } else { 1306 1307 // 1308 // If there is no resource request 1309 // 1310 Configuration = AllocateZeroPool (sizeof (EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR) + sizeof (EFI_ACPI_END_TAG_DESCRIPTOR)); 1311 if (Configuration == NULL) { 1312 return EFI_OUT_OF_RESOURCES; 1313 } 1314 1315 Ptr = (EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR *) (Configuration); 1316 Ptr->Desc = ACPI_ADDRESS_SPACE_DESCRIPTOR; 1317 1318 PtrEnd = (EFI_ACPI_END_TAG_DESCRIPTOR *) (Ptr + 1); 1319 PtrEnd->Desc = ACPI_END_TAG_DESCRIPTOR; 1320 PtrEnd->Checksum = 0; 1321 } 1322 1323 *Config = Configuration; 1324 1325 return EFI_SUCCESS; 1326 } 1327 1328 /** 1329 Get resource base from an acpi configuration descriptor. 1330 1331 @param Config An acpi configuration descriptor. 1332 @param IoBase Output of I/O resource base address. 1333 @param Mem32Base Output of 32-bit memory base address. 1334 @param PMem32Base Output of 32-bit prefetchable memory base address. 1335 @param Mem64Base Output of 64-bit memory base address. 1336 @param PMem64Base Output of 64-bit prefetchable memory base address. 1337 1338 **/ 1339 VOID 1340 GetResourceBase ( 1341 IN VOID *Config, 1342 OUT UINT64 *IoBase, 1343 OUT UINT64 *Mem32Base, 1344 OUT UINT64 *PMem32Base, 1345 OUT UINT64 *Mem64Base, 1346 OUT UINT64 *PMem64Base 1347 ) 1348 { 1349 UINT8 *Temp; 1350 EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR *Ptr; 1351 UINT64 ResStatus; 1352 1353 ASSERT (Config != NULL); 1354 1355 *IoBase = 0xFFFFFFFFFFFFFFFFULL; 1356 *Mem32Base = 0xFFFFFFFFFFFFFFFFULL; 1357 *PMem32Base = 0xFFFFFFFFFFFFFFFFULL; 1358 *Mem64Base = 0xFFFFFFFFFFFFFFFFULL; 1359 *PMem64Base = 0xFFFFFFFFFFFFFFFFULL; 1360 1361 Temp = (UINT8 *) Config; 1362 1363 while (*Temp == ACPI_ADDRESS_SPACE_DESCRIPTOR) { 1364 1365 Ptr = (EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR *) Temp; 1366 ResStatus = Ptr->AddrTranslationOffset; 1367 1368 if (ResStatus == EFI_RESOURCE_SATISFIED) { 1369 1370 switch (Ptr->ResType) { 1371 1372 // 1373 // Memory type aperture 1374 // 1375 case 0: 1376 1377 // 1378 // Check to see the granularity 1379 // 1380 if (Ptr->AddrSpaceGranularity == 32) { 1381 if ((Ptr->SpecificFlag & 0x06) != 0) { 1382 *PMem32Base = Ptr->AddrRangeMin; 1383 } else { 1384 *Mem32Base = Ptr->AddrRangeMin; 1385 } 1386 } 1387 1388 if (Ptr->AddrSpaceGranularity == 64) { 1389 if ((Ptr->SpecificFlag & 0x06) != 0) { 1390 *PMem64Base = Ptr->AddrRangeMin; 1391 } else { 1392 *Mem64Base = Ptr->AddrRangeMin; 1393 } 1394 } 1395 break; 1396 1397 case 1: 1398 1399 // 1400 // Io type aperture 1401 // 1402 *IoBase = Ptr->AddrRangeMin; 1403 break; 1404 1405 default: 1406 break; 1407 1408 } 1409 // 1410 // End switch 1411 // 1412 } 1413 // 1414 // End for 1415 // 1416 Temp += sizeof (EFI_ACPI_ADDRESS_SPACE_DESCRIPTOR); 1417 } 1418 } 1419 1420 /** 1421 Enumerate pci bridge, allocate resource and determine attribute 1422 for devices on this bridge. 1423 1424 @param BridgeDev Pointer to instance of bridge device. 1425 1426 @retval EFI_SUCCESS Successfully enumerated PCI bridge. 1427 @retval other Failed to enumerate. 1428 1429 **/ 1430 EFI_STATUS 1431 PciBridgeEnumerator ( 1432 IN PCI_IO_DEVICE *BridgeDev 1433 ) 1434 { 1435 UINT8 SubBusNumber; 1436 UINT8 StartBusNumber; 1437 EFI_PCI_IO_PROTOCOL *PciIo; 1438 EFI_STATUS Status; 1439 1440 SubBusNumber = 0; 1441 StartBusNumber = 0; 1442 PciIo = &(BridgeDev->PciIo); 1443 Status = PciIo->Pci.Read (PciIo, EfiPciIoWidthUint8, 0x19, 1, &StartBusNumber); 1444 1445 if (EFI_ERROR (Status)) { 1446 return Status; 1447 } 1448 1449 Status = PciAssignBusNumber ( 1450 BridgeDev, 1451 StartBusNumber, 1452 &SubBusNumber 1453 ); 1454 1455 if (EFI_ERROR (Status)) { 1456 return Status; 1457 } 1458 1459 Status = PciPciDeviceInfoCollector (BridgeDev, StartBusNumber); 1460 1461 if (EFI_ERROR (Status)) { 1462 return Status; 1463 } 1464 1465 Status = PciBridgeResourceAllocator (BridgeDev); 1466 1467 if (EFI_ERROR (Status)) { 1468 return Status; 1469 } 1470 1471 Status = DetermineDeviceAttribute (BridgeDev); 1472 1473 if (EFI_ERROR (Status)) { 1474 return Status; 1475 } 1476 1477 return EFI_SUCCESS; 1478 1479 } 1480 1481 /** 1482 Allocate all kinds of resource for PCI bridge. 1483 1484 @param Bridge Pointer to bridge instance. 1485 1486 @retval EFI_SUCCESS Successfully allocated resource for PCI bridge. 1487 @retval other Failed to allocate resource for bridge. 1488 1489 **/ 1490 EFI_STATUS 1491 PciBridgeResourceAllocator ( 1492 IN PCI_IO_DEVICE *Bridge 1493 ) 1494 { 1495 PCI_RESOURCE_NODE *IoBridge; 1496 PCI_RESOURCE_NODE *Mem32Bridge; 1497 PCI_RESOURCE_NODE *PMem32Bridge; 1498 PCI_RESOURCE_NODE *Mem64Bridge; 1499 PCI_RESOURCE_NODE *PMem64Bridge; 1500 UINT64 IoBase; 1501 UINT64 Mem32Base; 1502 UINT64 PMem32Base; 1503 UINT64 Mem64Base; 1504 UINT64 PMem64Base; 1505 EFI_STATUS Status; 1506 1507 IoBridge = CreateResourceNode ( 1508 Bridge, 1509 0, 1510 Bridge->BridgeIoAlignment, 1511 0, 1512 PciBarTypeIo16, 1513 PciResUsageTypical 1514 ); 1515 1516 Mem32Bridge = CreateResourceNode ( 1517 Bridge, 1518 0, 1519 0xFFFFF, 1520 0, 1521 PciBarTypeMem32, 1522 PciResUsageTypical 1523 ); 1524 1525 PMem32Bridge = CreateResourceNode ( 1526 Bridge, 1527 0, 1528 0xFFFFF, 1529 0, 1530 PciBarTypePMem32, 1531 PciResUsageTypical 1532 ); 1533 1534 Mem64Bridge = CreateResourceNode ( 1535 Bridge, 1536 0, 1537 0xFFFFF, 1538 0, 1539 PciBarTypeMem64, 1540 PciResUsageTypical 1541 ); 1542 1543 PMem64Bridge = CreateResourceNode ( 1544 Bridge, 1545 0, 1546 0xFFFFF, 1547 0, 1548 PciBarTypePMem64, 1549 PciResUsageTypical 1550 ); 1551 1552 // 1553 // Create resourcemap by going through all the devices subject to this root bridge 1554 // 1555 CreateResourceMap ( 1556 Bridge, 1557 IoBridge, 1558 Mem32Bridge, 1559 PMem32Bridge, 1560 Mem64Bridge, 1561 PMem64Bridge 1562 ); 1563 1564 Status = GetResourceBaseFromBridge ( 1565 Bridge, 1566 &IoBase, 1567 &Mem32Base, 1568 &PMem32Base, 1569 &Mem64Base, 1570 &PMem64Base 1571 ); 1572 1573 if (EFI_ERROR (Status)) { 1574 return Status; 1575 } 1576 1577 // 1578 // Program IO resources 1579 // 1580 ProgramResource ( 1581 IoBase, 1582 IoBridge 1583 ); 1584 1585 // 1586 // Program Mem32 resources 1587 // 1588 ProgramResource ( 1589 Mem32Base, 1590 Mem32Bridge 1591 ); 1592 1593 // 1594 // Program PMem32 resources 1595 // 1596 ProgramResource ( 1597 PMem32Base, 1598 PMem32Bridge 1599 ); 1600 1601 // 1602 // Program Mem64 resources 1603 // 1604 ProgramResource ( 1605 Mem64Base, 1606 Mem64Bridge 1607 ); 1608 1609 // 1610 // Program PMem64 resources 1611 // 1612 ProgramResource ( 1613 PMem64Base, 1614 PMem64Bridge 1615 ); 1616 1617 DestroyResourceTree (IoBridge); 1618 DestroyResourceTree (Mem32Bridge); 1619 DestroyResourceTree (PMem32Bridge); 1620 DestroyResourceTree (PMem64Bridge); 1621 DestroyResourceTree (Mem64Bridge); 1622 1623 gBS->FreePool (IoBridge); 1624 gBS->FreePool (Mem32Bridge); 1625 gBS->FreePool (PMem32Bridge); 1626 gBS->FreePool (PMem64Bridge); 1627 gBS->FreePool (Mem64Bridge); 1628 1629 return EFI_SUCCESS; 1630 } 1631 1632 /** 1633 Get resource base address for a pci bridge device. 1634 1635 @param Bridge Given Pci driver instance. 1636 @param IoBase Output for base address of I/O type resource. 1637 @param Mem32Base Output for base address of 32-bit memory type resource. 1638 @param PMem32Base Ooutput for base address of 32-bit Pmemory type resource. 1639 @param Mem64Base Output for base address of 64-bit memory type resource. 1640 @param PMem64Base Output for base address of 64-bit Pmemory type resource. 1641 1642 @retval EFI_SUCCESS Successfully got resource base address. 1643 @retval EFI_OUT_OF_RESOURCES PCI bridge is not available. 1644 1645 **/ 1646 EFI_STATUS 1647 GetResourceBaseFromBridge ( 1648 IN PCI_IO_DEVICE *Bridge, 1649 OUT UINT64 *IoBase, 1650 OUT UINT64 *Mem32Base, 1651 OUT UINT64 *PMem32Base, 1652 OUT UINT64 *Mem64Base, 1653 OUT UINT64 *PMem64Base 1654 ) 1655 { 1656 if (!Bridge->Allocated) { 1657 return EFI_OUT_OF_RESOURCES; 1658 } 1659 1660 *IoBase = gAllOne; 1661 *Mem32Base = gAllOne; 1662 *PMem32Base = gAllOne; 1663 *Mem64Base = gAllOne; 1664 *PMem64Base = gAllOne; 1665 1666 if (IS_PCI_BRIDGE (&Bridge->Pci)) { 1667 1668 if (Bridge->PciBar[PPB_IO_RANGE].Length > 0) { 1669 *IoBase = Bridge->PciBar[PPB_IO_RANGE].BaseAddress; 1670 } 1671 1672 if (Bridge->PciBar[PPB_MEM32_RANGE].Length > 0) { 1673 *Mem32Base = Bridge->PciBar[PPB_MEM32_RANGE].BaseAddress; 1674 } 1675 1676 if (Bridge->PciBar[PPB_PMEM32_RANGE].Length > 0) { 1677 *PMem32Base = Bridge->PciBar[PPB_PMEM32_RANGE].BaseAddress; 1678 } 1679 1680 if (Bridge->PciBar[PPB_PMEM64_RANGE].Length > 0) { 1681 *PMem64Base = Bridge->PciBar[PPB_PMEM64_RANGE].BaseAddress; 1682 } else { 1683 *PMem64Base = gAllOne; 1684 } 1685 1686 } 1687 1688 if (IS_CARDBUS_BRIDGE (&Bridge->Pci)) { 1689 if (Bridge->PciBar[P2C_IO_1].Length > 0) { 1690 *IoBase = Bridge->PciBar[P2C_IO_1].BaseAddress; 1691 } else { 1692 if (Bridge->PciBar[P2C_IO_2].Length > 0) { 1693 *IoBase = Bridge->PciBar[P2C_IO_2].BaseAddress; 1694 } 1695 } 1696 1697 if (Bridge->PciBar[P2C_MEM_1].Length > 0) { 1698 if (Bridge->PciBar[P2C_MEM_1].BarType == PciBarTypePMem32) { 1699 *PMem32Base = Bridge->PciBar[P2C_MEM_1].BaseAddress; 1700 } 1701 1702 if (Bridge->PciBar[P2C_MEM_1].BarType == PciBarTypeMem32) { 1703 *Mem32Base = Bridge->PciBar[P2C_MEM_1].BaseAddress; 1704 } 1705 } 1706 1707 if (Bridge->PciBar[P2C_MEM_2].Length > 0) { 1708 if (Bridge->PciBar[P2C_MEM_2].BarType == PciBarTypePMem32) { 1709 *PMem32Base = Bridge->PciBar[P2C_MEM_2].BaseAddress; 1710 } 1711 1712 if (Bridge->PciBar[P2C_MEM_2].BarType == PciBarTypeMem32) { 1713 *Mem32Base = Bridge->PciBar[P2C_MEM_2].BaseAddress; 1714 } 1715 } 1716 } 1717 1718 return EFI_SUCCESS; 1719 } 1720 1721 /** 1722 These are the notifications from the PCI bus driver that it is about to enter a certain 1723 phase of the PCI enumeration process. 1724 1725 This member function can be used to notify the host bridge driver to perform specific actions, 1726 including any chipset-specific initialization, so that the chipset is ready to enter the next phase. 1727 Eight notification points are defined at this time. See belows: 1728 EfiPciHostBridgeBeginEnumeration Resets the host bridge PCI apertures and internal data 1729 structures. The PCI enumerator should issue this notification 1730 before starting a fresh enumeration process. Enumeration cannot 1731 be restarted after sending any other notification such as 1732 EfiPciHostBridgeBeginBusAllocation. 1733 EfiPciHostBridgeBeginBusAllocation The bus allocation phase is about to begin. No specific action is 1734 required here. This notification can be used to perform any 1735 chipset-specific programming. 1736 EfiPciHostBridgeEndBusAllocation The bus allocation and bus programming phase is complete. No 1737 specific action is required here. This notification can be used to 1738 perform any chipset-specific programming. 1739 EfiPciHostBridgeBeginResourceAllocation 1740 The resource allocation phase is about to begin. No specific 1741 action is required here. This notification can be used to perform 1742 any chipset-specific programming. 1743 EfiPciHostBridgeAllocateResources Allocates resources per previously submitted requests for all the PCI 1744 root bridges. These resource settings are returned on the next call to 1745 GetProposedResources(). Before calling NotifyPhase() with a Phase of 1746 EfiPciHostBridgeAllocateResource, the PCI bus enumerator is responsible 1747 for gathering I/O and memory requests for 1748 all the PCI root bridges and submitting these requests using 1749 SubmitResources(). This function pads the resource amount 1750 to suit the root bridge hardware, takes care of dependencies between 1751 the PCI root bridges, and calls the Global Coherency Domain (GCD) 1752 with the allocation request. In the case of padding, the allocated range 1753 could be bigger than what was requested. 1754 EfiPciHostBridgeSetResources Programs the host bridge hardware to decode previously allocated 1755 resources (proposed resources) for all the PCI root bridges. After the 1756 hardware is programmed, reassigning resources will not be supported. 1757 The bus settings are not affected. 1758 EfiPciHostBridgeFreeResources Deallocates resources that were previously allocated for all the PCI 1759 root bridges and resets the I/O and memory apertures to their initial 1760 state. The bus settings are not affected. If the request to allocate 1761 resources fails, the PCI enumerator can use this notification to 1762 deallocate previous resources, adjust the requests, and retry 1763 allocation. 1764 EfiPciHostBridgeEndResourceAllocation The resource allocation phase is completed. No specific action is 1765 required here. This notification can be used to perform any chipsetspecific 1766 programming. 1767 1768 @param[in] PciResAlloc The instance pointer of EFI_PCI_HOST_BRIDGE_RESOURCE_ALLOCATION_PROTOCOL 1769 @param[in] Phase The phase during enumeration 1770 1771 @retval EFI_NOT_READY This phase cannot be entered at this time. For example, this error 1772 is valid for a Phase of EfiPciHostBridgeAllocateResources if 1773 SubmitResources() has not been called for one or more 1774 PCI root bridges before this call 1775 @retval EFI_DEVICE_ERROR Programming failed due to a hardware error. This error is valid 1776 for a Phase of EfiPciHostBridgeSetResources. 1777 @retval EFI_INVALID_PARAMETER Invalid phase parameter 1778 @retval EFI_OUT_OF_RESOURCES The request could not be completed due to a lack of resources. 1779 This error is valid for a Phase of EfiPciHostBridgeAllocateResources if the 1780 previously submitted resource requests cannot be fulfilled or 1781 were only partially fulfilled. 1782 @retval EFI_SUCCESS The notification was accepted without any errors. 1783 1784 **/ 1785 EFI_STATUS 1786 NotifyPhase ( 1787 IN EFI_PCI_HOST_BRIDGE_RESOURCE_ALLOCATION_PROTOCOL *PciResAlloc, 1788 EFI_PCI_HOST_BRIDGE_RESOURCE_ALLOCATION_PHASE Phase 1789 ) 1790 { 1791 EFI_HANDLE HostBridgeHandle; 1792 EFI_HANDLE RootBridgeHandle; 1793 EFI_PCI_ROOT_BRIDGE_IO_PROTOCOL *PciRootBridgeIo; 1794 EFI_STATUS Status; 1795 1796 HostBridgeHandle = NULL; 1797 RootBridgeHandle = NULL; 1798 if (gPciPlatformProtocol != NULL) { 1799 // 1800 // Get Host Bridge Handle. 1801 // 1802 PciResAlloc->GetNextRootBridge (PciResAlloc, &RootBridgeHandle); 1803 1804 // 1805 // Get the rootbridge Io protocol to find the host bridge handle 1806 // 1807 Status = gBS->HandleProtocol ( 1808 RootBridgeHandle, 1809 &gEfiPciRootBridgeIoProtocolGuid, 1810 (VOID **) &PciRootBridgeIo 1811 ); 1812 1813 if (EFI_ERROR (Status)) { 1814 return EFI_NOT_FOUND; 1815 } 1816 1817 HostBridgeHandle = PciRootBridgeIo->ParentHandle; 1818 1819 // 1820 // Call PlatformPci::PlatformNotify() if the protocol is present. 1821 // 1822 gPciPlatformProtocol->PlatformNotify ( 1823 gPciPlatformProtocol, 1824 HostBridgeHandle, 1825 Phase, 1826 ChipsetEntry 1827 ); 1828 } else if (gPciOverrideProtocol != NULL){ 1829 // 1830 // Get Host Bridge Handle. 1831 // 1832 PciResAlloc->GetNextRootBridge (PciResAlloc, &RootBridgeHandle); 1833 1834 // 1835 // Get the rootbridge Io protocol to find the host bridge handle 1836 // 1837 Status = gBS->HandleProtocol ( 1838 RootBridgeHandle, 1839 &gEfiPciRootBridgeIoProtocolGuid, 1840 (VOID **) &PciRootBridgeIo 1841 ); 1842 1843 if (EFI_ERROR (Status)) { 1844 return EFI_NOT_FOUND; 1845 } 1846 1847 HostBridgeHandle = PciRootBridgeIo->ParentHandle; 1848 1849 // 1850 // Call PlatformPci::PhaseNotify() if the protocol is present. 1851 // 1852 gPciOverrideProtocol->PlatformNotify ( 1853 gPciOverrideProtocol, 1854 HostBridgeHandle, 1855 Phase, 1856 ChipsetEntry 1857 ); 1858 } 1859 1860 Status = PciResAlloc->NotifyPhase ( 1861 PciResAlloc, 1862 Phase 1863 ); 1864 1865 if (gPciPlatformProtocol != NULL) { 1866 // 1867 // Call PlatformPci::PlatformNotify() if the protocol is present. 1868 // 1869 gPciPlatformProtocol->PlatformNotify ( 1870 gPciPlatformProtocol, 1871 HostBridgeHandle, 1872 Phase, 1873 ChipsetExit 1874 ); 1875 1876 } else if (gPciOverrideProtocol != NULL) { 1877 // 1878 // Call PlatformPci::PhaseNotify() if the protocol is present. 1879 // 1880 gPciOverrideProtocol->PlatformNotify ( 1881 gPciOverrideProtocol, 1882 HostBridgeHandle, 1883 Phase, 1884 ChipsetExit 1885 ); 1886 } 1887 1888 return Status; 1889 } 1890 1891 /** 1892 Provides the hooks from the PCI bus driver to every PCI controller (device/function) at various 1893 stages of the PCI enumeration process that allow the host bridge driver to preinitialize individual 1894 PCI controllers before enumeration. 1895 1896 This function is called during the PCI enumeration process. No specific action is expected from this 1897 member function. It allows the host bridge driver to preinitialize individual PCI controllers before 1898 enumeration. 1899 1900 @param Bridge Pointer to the EFI_PCI_HOST_BRIDGE_RESOURCE_ALLOCATION_PROTOCOL instance. 1901 @param Bus The bus number of the pci device. 1902 @param Device The device number of the pci device. 1903 @param Func The function number of the pci device. 1904 @param Phase The phase of the PCI device enumeration. 1905 1906 @retval EFI_SUCCESS The requested parameters were returned. 1907 @retval EFI_INVALID_PARAMETER RootBridgeHandle is not a valid root bridge handle. 1908 @retval EFI_INVALID_PARAMETER Phase is not a valid phase that is defined in 1909 EFI_PCI_CONTROLLER_RESOURCE_ALLOCATION_PHASE. 1910 @retval EFI_DEVICE_ERROR Programming failed due to a hardware error. The PCI enumerator should 1911 not enumerate this device, including its child devices if it is a PCI-to-PCI 1912 bridge. 1913 1914 **/ 1915 EFI_STATUS 1916 PreprocessController ( 1917 IN PCI_IO_DEVICE *Bridge, 1918 IN UINT8 Bus, 1919 IN UINT8 Device, 1920 IN UINT8 Func, 1921 IN EFI_PCI_CONTROLLER_RESOURCE_ALLOCATION_PHASE Phase 1922 ) 1923 { 1924 EFI_PCI_ROOT_BRIDGE_IO_PROTOCOL_PCI_ADDRESS RootBridgePciAddress; 1925 EFI_PCI_HOST_BRIDGE_RESOURCE_ALLOCATION_PROTOCOL *PciResAlloc; 1926 EFI_HANDLE RootBridgeHandle; 1927 EFI_HANDLE HostBridgeHandle; 1928 EFI_STATUS Status; 1929 1930 // 1931 // Get the host bridge handle 1932 // 1933 HostBridgeHandle = Bridge->PciRootBridgeIo->ParentHandle; 1934 1935 // 1936 // Get the pci host bridge resource allocation protocol 1937 // 1938 Status = gBS->OpenProtocol ( 1939 HostBridgeHandle, 1940 &gEfiPciHostBridgeResourceAllocationProtocolGuid, 1941 (VOID **) &PciResAlloc, 1942 NULL, 1943 NULL, 1944 EFI_OPEN_PROTOCOL_GET_PROTOCOL 1945 ); 1946 1947 if (EFI_ERROR (Status)) { 1948 return EFI_UNSUPPORTED; 1949 } 1950 1951 // 1952 // Get Root Brige Handle 1953 // 1954 while (Bridge->Parent != NULL) { 1955 Bridge = Bridge->Parent; 1956 } 1957 1958 RootBridgeHandle = Bridge->Handle; 1959 1960 RootBridgePciAddress.Register = 0; 1961 RootBridgePciAddress.Function = Func; 1962 RootBridgePciAddress.Device = Device; 1963 RootBridgePciAddress.Bus = Bus; 1964 RootBridgePciAddress.ExtendedRegister = 0; 1965 1966 if (gPciPlatformProtocol != NULL) { 1967 // 1968 // Call PlatformPci::PrepController() if the protocol is present. 1969 // 1970 gPciPlatformProtocol->PlatformPrepController ( 1971 gPciPlatformProtocol, 1972 HostBridgeHandle, 1973 RootBridgeHandle, 1974 RootBridgePciAddress, 1975 Phase, 1976 ChipsetEntry 1977 ); 1978 } else if (gPciOverrideProtocol != NULL) { 1979 // 1980 // Call PlatformPci::PrepController() if the protocol is present. 1981 // 1982 gPciOverrideProtocol->PlatformPrepController ( 1983 gPciOverrideProtocol, 1984 HostBridgeHandle, 1985 RootBridgeHandle, 1986 RootBridgePciAddress, 1987 Phase, 1988 ChipsetEntry 1989 ); 1990 } 1991 1992 Status = PciResAlloc->PreprocessController ( 1993 PciResAlloc, 1994 RootBridgeHandle, 1995 RootBridgePciAddress, 1996 Phase 1997 ); 1998 1999 if (gPciPlatformProtocol != NULL) { 2000 // 2001 // Call PlatformPci::PrepController() if the protocol is present. 2002 // 2003 gPciPlatformProtocol->PlatformPrepController ( 2004 gPciPlatformProtocol, 2005 HostBridgeHandle, 2006 RootBridgeHandle, 2007 RootBridgePciAddress, 2008 Phase, 2009 ChipsetExit 2010 ); 2011 } else if (gPciOverrideProtocol != NULL) { 2012 // 2013 // Call PlatformPci::PrepController() if the protocol is present. 2014 // 2015 gPciOverrideProtocol->PlatformPrepController ( 2016 gPciOverrideProtocol, 2017 HostBridgeHandle, 2018 RootBridgeHandle, 2019 RootBridgePciAddress, 2020 Phase, 2021 ChipsetExit 2022 ); 2023 } 2024 2025 return EFI_SUCCESS; 2026 } 2027 2028 /** 2029 This function allows the PCI bus driver to be notified to act as requested when a hot-plug event has 2030 happened on the hot-plug controller. Currently, the operations include add operation and remove operation.. 2031 2032 @param This A pointer to the hot plug request protocol. 2033 @param Operation The operation the PCI bus driver is requested to make. 2034 @param Controller The handle of the hot-plug controller. 2035 @param RemainingDevicePath The remaining device path for the PCI-like hot-plug device. 2036 @param NumberOfChildren The number of child handles. 2037 For a add operation, it is an output parameter. 2038 For a remove operation, it's an input parameter. 2039 @param ChildHandleBuffer The buffer which contains the child handles. 2040 2041 @retval EFI_INVALID_PARAMETER Operation is not a legal value. 2042 Controller is NULL or not a valid handle. 2043 NumberOfChildren is NULL. 2044 ChildHandleBuffer is NULL while Operation is add. 2045 @retval EFI_OUT_OF_RESOURCES There are no enough resources to start the devices. 2046 @retval EFI_NOT_FOUND Can not find bridge according to controller handle. 2047 @retval EFI_SUCCESS The handles for the specified device have been created or destroyed 2048 as requested, and for an add operation, the new handles are 2049 returned in ChildHandleBuffer. 2050 **/ 2051 EFI_STATUS 2052 EFIAPI 2053 PciHotPlugRequestNotify ( 2054 IN EFI_PCI_HOTPLUG_REQUEST_PROTOCOL * This, 2055 IN EFI_PCI_HOTPLUG_OPERATION Operation, 2056 IN EFI_HANDLE Controller, 2057 IN EFI_DEVICE_PATH_PROTOCOL * RemainingDevicePath OPTIONAL, 2058 IN OUT UINT8 *NumberOfChildren, 2059 IN OUT EFI_HANDLE * ChildHandleBuffer 2060 ) 2061 { 2062 PCI_IO_DEVICE *Bridge; 2063 PCI_IO_DEVICE *Temp; 2064 EFI_PCI_IO_PROTOCOL *PciIo; 2065 UINTN Index; 2066 EFI_HANDLE RootBridgeHandle; 2067 EFI_STATUS Status; 2068 2069 // 2070 // Check input parameter validity 2071 // 2072 if ((Controller == NULL) || (NumberOfChildren == NULL)){ 2073 return EFI_INVALID_PARAMETER; 2074 } 2075 2076 if ((Operation != EfiPciHotPlugRequestAdd) && (Operation != EfiPciHotplugRequestRemove)) { 2077 return EFI_INVALID_PARAMETER; 2078 } 2079 2080 if (Operation == EfiPciHotPlugRequestAdd){ 2081 if (ChildHandleBuffer == NULL) { 2082 return EFI_INVALID_PARAMETER; 2083 } 2084 } else if ((Operation == EfiPciHotplugRequestRemove) && (*NumberOfChildren != 0)) { 2085 if (ChildHandleBuffer == NULL) { 2086 return EFI_INVALID_PARAMETER; 2087 } 2088 } 2089 2090 Status = gBS->OpenProtocol ( 2091 Controller, 2092 &gEfiPciIoProtocolGuid, 2093 (VOID **) &PciIo, 2094 gPciBusDriverBinding.DriverBindingHandle, 2095 Controller, 2096 EFI_OPEN_PROTOCOL_GET_PROTOCOL 2097 ); 2098 2099 if (EFI_ERROR (Status)) { 2100 return EFI_NOT_FOUND; 2101 } 2102 2103 Bridge = PCI_IO_DEVICE_FROM_PCI_IO_THIS (PciIo); 2104 2105 // 2106 // Get root bridge handle 2107 // 2108 Temp = Bridge; 2109 while (Temp->Parent != NULL) { 2110 Temp = Temp->Parent; 2111 } 2112 2113 RootBridgeHandle = Temp->Handle; 2114 2115 if (Operation == EfiPciHotPlugRequestAdd) { 2116 // 2117 // Report Status Code to indicate hot plug happens 2118 // 2119 REPORT_STATUS_CODE_WITH_DEVICE_PATH ( 2120 EFI_PROGRESS_CODE, 2121 (EFI_IO_BUS_PCI | EFI_IOB_PC_HOTPLUG), 2122 Temp->DevicePath 2123 ); 2124 2125 if (NumberOfChildren != NULL) { 2126 *NumberOfChildren = 0; 2127 } 2128 2129 if (IsListEmpty (&Bridge->ChildList)) { 2130 2131 Status = PciBridgeEnumerator (Bridge); 2132 2133 if (EFI_ERROR (Status)) { 2134 return Status; 2135 } 2136 } 2137 2138 Status = StartPciDevicesOnBridge ( 2139 RootBridgeHandle, 2140 Bridge, 2141 RemainingDevicePath, 2142 NumberOfChildren, 2143 ChildHandleBuffer 2144 ); 2145 2146 return Status; 2147 } 2148 2149 if (Operation == EfiPciHotplugRequestRemove) { 2150 2151 if (*NumberOfChildren == 0) { 2152 // 2153 // Remove all devices on the bridge 2154 // 2155 RemoveAllPciDeviceOnBridge (RootBridgeHandle, Bridge); 2156 return EFI_SUCCESS; 2157 2158 } 2159 2160 for (Index = 0; Index < *NumberOfChildren; Index++) { 2161 // 2162 // De register all the pci device 2163 // 2164 Status = DeRegisterPciDevice (RootBridgeHandle, ChildHandleBuffer[Index]); 2165 2166 if (EFI_ERROR (Status)) { 2167 return Status; 2168 } 2169 2170 } 2171 // 2172 // End for 2173 // 2174 return EFI_SUCCESS; 2175 } 2176 2177 return EFI_SUCCESS; 2178 } 2179 2180 /** 2181 Search hostbridge according to given handle 2182 2183 @param RootBridgeHandle Host bridge handle. 2184 2185 @retval TRUE Found host bridge handle. 2186 @retval FALSE Not found hot bridge handle. 2187 2188 **/ 2189 BOOLEAN 2190 SearchHostBridgeHandle ( 2191 IN EFI_HANDLE RootBridgeHandle 2192 ) 2193 { 2194 EFI_HANDLE HostBridgeHandle; 2195 EFI_PCI_ROOT_BRIDGE_IO_PROTOCOL *PciRootBridgeIo; 2196 UINTN Index; 2197 EFI_STATUS Status; 2198 2199 // 2200 // Get the rootbridge Io protocol to find the host bridge handle 2201 // 2202 Status = gBS->OpenProtocol ( 2203 RootBridgeHandle, 2204 &gEfiPciRootBridgeIoProtocolGuid, 2205 (VOID **) &PciRootBridgeIo, 2206 gPciBusDriverBinding.DriverBindingHandle, 2207 RootBridgeHandle, 2208 EFI_OPEN_PROTOCOL_GET_PROTOCOL 2209 ); 2210 2211 if (EFI_ERROR (Status)) { 2212 return FALSE; 2213 } 2214 2215 HostBridgeHandle = PciRootBridgeIo->ParentHandle; 2216 for (Index = 0; Index < gPciHostBridgeNumber; Index++) { 2217 if (HostBridgeHandle == gPciHostBrigeHandles[Index]) { 2218 return TRUE; 2219 } 2220 } 2221 2222 return FALSE; 2223 } 2224 2225 /** 2226 Add host bridge handle to global variable for enumerating. 2227 2228 @param HostBridgeHandle Host bridge handle. 2229 2230 @retval EFI_SUCCESS Successfully added host bridge. 2231 @retval EFI_ABORTED Host bridge is NULL, or given host bridge 2232 has been in host bridge list. 2233 2234 **/ 2235 EFI_STATUS 2236 AddHostBridgeEnumerator ( 2237 IN EFI_HANDLE HostBridgeHandle 2238 ) 2239 { 2240 UINTN Index; 2241 2242 if (HostBridgeHandle == NULL) { 2243 return EFI_ABORTED; 2244 } 2245 2246 for (Index = 0; Index < gPciHostBridgeNumber; Index++) { 2247 if (HostBridgeHandle == gPciHostBrigeHandles[Index]) { 2248 return EFI_ABORTED; 2249 } 2250 } 2251 2252 if (Index < PCI_MAX_HOST_BRIDGE_NUM) { 2253 gPciHostBrigeHandles[Index] = HostBridgeHandle; 2254 gPciHostBridgeNumber++; 2255 } 2256 2257 return EFI_SUCCESS; 2258 } 2259 2260