1 /** @file 2 Provide functions to initialize NVME controller and perform NVME commands 3 4 Copyright (c) 2016, Intel Corporation. All rights reserved.<BR> 5 This program and the accompanying materials 6 are licensed and made available under the terms and conditions of the BSD License 7 which accompanies this distribution. The full text of the license may be found at 8 http://opensource.org/licenses/bsd-license.php 9 10 THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS, 11 WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED. 12 13 **/ 14 15 #include "OpalPasswordSmm.h" 16 17 18 #define ALIGN(v, a) (UINTN)((((v) - 1) | ((a) - 1)) + 1) 19 20 /// 21 /// NVME Host controller registers operation 22 /// 23 #define NVME_GET_CAP(Nvme, Cap) NvmeMmioRead (Cap, Nvme->Nbar + NVME_CAP_OFFSET, sizeof (NVME_CAP)) 24 #define NVME_GET_CC(Nvme, Cc) NvmeMmioRead (Cc, Nvme->Nbar + NVME_CC_OFFSET, sizeof (NVME_CC)) 25 #define NVME_SET_CC(Nvme, Cc) NvmeMmioWrite (Nvme->Nbar + NVME_CC_OFFSET, Cc, sizeof (NVME_CC)) 26 #define NVME_GET_CSTS(Nvme, Csts) NvmeMmioRead (Csts, Nvme->Nbar + NVME_CSTS_OFFSET, sizeof (NVME_CSTS)) 27 #define NVME_GET_AQA(Nvme, Aqa) NvmeMmioRead (Aqa, Nvme->Nbar + NVME_AQA_OFFSET, sizeof (NVME_AQA)) 28 #define NVME_SET_AQA(Nvme, Aqa) NvmeMmioWrite (Nvme->Nbar + NVME_AQA_OFFSET, Aqa, sizeof (NVME_AQA)) 29 #define NVME_GET_ASQ(Nvme, Asq) NvmeMmioRead (Asq, Nvme->Nbar + NVME_ASQ_OFFSET, sizeof (NVME_ASQ)) 30 #define NVME_SET_ASQ(Nvme, Asq) NvmeMmioWrite (Nvme->Nbar + NVME_ASQ_OFFSET, Asq, sizeof (NVME_ASQ)) 31 #define NVME_GET_ACQ(Nvme, Acq) NvmeMmioRead (Acq, Nvme->Nbar + NVME_ACQ_OFFSET, sizeof (NVME_ACQ)) 32 #define NVME_SET_ACQ(Nvme, Acq) NvmeMmioWrite (Nvme->Nbar + NVME_ACQ_OFFSET, Acq, sizeof (NVME_ACQ)) 33 #define NVME_GET_VER(Nvme, Ver) NvmeMmioRead (Ver, Nvme->Nbar + NVME_VER_OFFSET, sizeof (NVME_VER)) 34 #define NVME_SET_SQTDBL(Nvme, Qid, Sqtdbl) NvmeMmioWrite (Nvme->Nbar + NVME_SQTDBL_OFFSET(Qid, Nvme->Cap.Dstrd), Sqtdbl, sizeof (NVME_SQTDBL)) 35 #define NVME_SET_CQHDBL(Nvme, Qid, Cqhdbl) NvmeMmioWrite (Nvme->Nbar + NVME_CQHDBL_OFFSET(Qid, Nvme->Cap.Dstrd), Cqhdbl, sizeof (NVME_CQHDBL)) 36 37 /// 38 /// Base memory address 39 /// 40 enum { 41 BASEMEM_CONTROLLER_DATA, 42 BASEMEM_IDENTIFY_DATA, 43 BASEMEM_ASQ, 44 BASEMEM_ACQ, 45 BASEMEM_SQ, 46 BASEMEM_CQ, 47 BASEMEM_PRP, 48 BASEMEM_SECURITY, 49 MAX_BASEMEM_COUNT 50 }; 51 52 /// 53 /// All of base memories are 4K(0x1000) alignment 54 /// 55 #define NVME_MEM_BASE(Nvme) (Nvme->BaseMem) 56 #define NVME_CONTROL_DATA_BASE(Nvme) (ALIGN (NVME_MEM_BASE(Nvme) + ((NvmeGetBaseMemPages (BASEMEM_CONTROLLER_DATA)) * EFI_PAGE_SIZE), EFI_PAGE_SIZE)) 57 #define NVME_NAMESPACE_DATA_BASE(Nvme) (ALIGN (NVME_MEM_BASE(Nvme) + ((NvmeGetBaseMemPages (BASEMEM_IDENTIFY_DATA)) * EFI_PAGE_SIZE), EFI_PAGE_SIZE)) 58 #define NVME_ASQ_BASE(Nvme) (ALIGN (NVME_MEM_BASE(Nvme) + ((NvmeGetBaseMemPages (BASEMEM_ASQ)) * EFI_PAGE_SIZE), EFI_PAGE_SIZE)) 59 #define NVME_ACQ_BASE(Nvme) (ALIGN (NVME_MEM_BASE(Nvme) + ((NvmeGetBaseMemPages (BASEMEM_ACQ)) * EFI_PAGE_SIZE), EFI_PAGE_SIZE)) 60 #define NVME_SQ_BASE(Nvme, index) (ALIGN (NVME_MEM_BASE(Nvme) + ((NvmeGetBaseMemPages (BASEMEM_SQ) + ((index)*(NVME_MAX_IO_QUEUES-1))) * EFI_PAGE_SIZE), EFI_PAGE_SIZE)) 61 #define NVME_CQ_BASE(Nvme, index) (ALIGN (NVME_MEM_BASE(Nvme) + ((NvmeGetBaseMemPages (BASEMEM_CQ) + ((index)*(NVME_MAX_IO_QUEUES-1))) * EFI_PAGE_SIZE), EFI_PAGE_SIZE)) 62 #define NVME_PRP_BASE(Nvme, index) (ALIGN (NVME_MEM_BASE(Nvme) + ((NvmeGetBaseMemPages (BASEMEM_PRP) + ((index)*NVME_PRP_SIZE)) * EFI_PAGE_SIZE), EFI_PAGE_SIZE)) 63 #define NVME_SEC_BASE(Nvme) (ALIGN (NVME_MEM_BASE(Nvme) + ((NvmeGetBaseMemPages (BASEMEM_SECURITY)) * EFI_PAGE_SIZE), EFI_PAGE_SIZE)) 64 65 /** 66 Transfer MMIO Data to memory. 67 68 @param[in,out] MemBuffer - Destination: Memory address 69 @param[in] MmioAddr - Source: MMIO address 70 @param[in] Size - Size for read 71 72 @retval EFI_SUCCESS - MMIO read sucessfully 73 **/ 74 EFI_STATUS 75 NvmeMmioRead ( 76 IN OUT VOID *MemBuffer, 77 IN UINTN MmioAddr, 78 IN UINTN Size 79 ) 80 { 81 UINTN Offset; 82 UINT8 Data; 83 UINT8 *Ptr; 84 85 // priority has adjusted 86 switch (Size) { 87 case 4: 88 *((UINT32 *)MemBuffer) = MmioRead32 (MmioAddr); 89 break; 90 91 case 8: 92 *((UINT64 *)MemBuffer) = MmioRead64 (MmioAddr); 93 break; 94 95 case 2: 96 *((UINT16 *)MemBuffer) = MmioRead16 (MmioAddr); 97 break; 98 99 case 1: 100 *((UINT8 *)MemBuffer) = MmioRead8 (MmioAddr); 101 break; 102 103 default: 104 Ptr = (UINT8 *)MemBuffer; 105 for (Offset = 0; Offset < Size; Offset += 1) { 106 Data = MmioRead8 (MmioAddr + Offset); 107 Ptr[Offset] = Data; 108 } 109 break; 110 } 111 112 return EFI_SUCCESS; 113 } 114 115 /** 116 Transfer memory data to MMIO. 117 118 @param[in,out] MmioAddr - Destination: MMIO address 119 @param[in] MemBuffer - Source: Memory address 120 @param[in] Size - Size for write 121 122 @retval EFI_SUCCESS - MMIO write sucessfully 123 **/ 124 EFI_STATUS 125 NvmeMmioWrite ( 126 IN OUT UINTN MmioAddr, 127 IN VOID *MemBuffer, 128 IN UINTN Size 129 ) 130 { 131 UINTN Offset; 132 UINT8 Data; 133 UINT8 *Ptr; 134 135 // priority has adjusted 136 switch (Size) { 137 case 4: 138 MmioWrite32 (MmioAddr, *((UINT32 *)MemBuffer)); 139 break; 140 141 case 8: 142 MmioWrite64 (MmioAddr, *((UINT64 *)MemBuffer)); 143 break; 144 145 case 2: 146 MmioWrite16 (MmioAddr, *((UINT16 *)MemBuffer)); 147 break; 148 149 case 1: 150 MmioWrite8 (MmioAddr, *((UINT8 *)MemBuffer)); 151 break; 152 153 default: 154 Ptr = (UINT8 *)MemBuffer; 155 for (Offset = 0; Offset < Size; Offset += 1) { 156 Data = Ptr[Offset]; 157 MmioWrite8 (MmioAddr + Offset, Data); 158 } 159 break; 160 } 161 162 return EFI_SUCCESS; 163 } 164 165 /** 166 Transfer MMIO data to memory. 167 168 @param[in,out] MemBuffer - Destination: Memory address 169 @param[in] MmioAddr - Source: MMIO address 170 @param[in] Size - Size for read 171 172 @retval EFI_SUCCESS - MMIO read sucessfully 173 **/ 174 EFI_STATUS 175 OpalPciRead ( 176 IN OUT VOID *MemBuffer, 177 IN UINTN MmioAddr, 178 IN UINTN Size 179 ) 180 { 181 UINTN Offset; 182 UINT8 Data; 183 UINT8 *Ptr; 184 185 // priority has adjusted 186 switch (Size) { 187 case 4: 188 *((UINT32 *)MemBuffer) = PciRead32 (MmioAddr); 189 break; 190 191 case 2: 192 *((UINT16 *)MemBuffer) = PciRead16 (MmioAddr); 193 break; 194 195 case 1: 196 *((UINT8 *)MemBuffer) = PciRead8 (MmioAddr); 197 break; 198 199 default: 200 Ptr = (UINT8 *)MemBuffer; 201 for (Offset = 0; Offset < Size; Offset += 1) { 202 Data = PciRead8 (MmioAddr + Offset); 203 Ptr[Offset] = Data; 204 } 205 break; 206 } 207 208 return EFI_SUCCESS; 209 } 210 211 /** 212 Transfer memory data to MMIO. 213 214 @param[in,out] MmioAddr - Destination: MMIO address 215 @param[in] MemBuffer - Source: Memory address 216 @param[in] Size - Size for write 217 218 @retval EFI_SUCCESS - MMIO write sucessfully 219 **/ 220 EFI_STATUS 221 OpalPciWrite ( 222 IN OUT UINTN MmioAddr, 223 IN VOID *MemBuffer, 224 IN UINTN Size 225 ) 226 { 227 UINTN Offset; 228 UINT8 Data; 229 UINT8 *Ptr; 230 231 // priority has adjusted 232 switch (Size) { 233 case 4: 234 PciWrite32 (MmioAddr, *((UINT32 *)MemBuffer)); 235 break; 236 237 case 2: 238 PciWrite16 (MmioAddr, *((UINT16 *)MemBuffer)); 239 break; 240 241 case 1: 242 PciWrite8 (MmioAddr, *((UINT8 *)MemBuffer)); 243 break; 244 245 default: 246 Ptr = (UINT8 *)MemBuffer; 247 for (Offset = 0; Offset < Size; Offset += 1) { 248 Data = Ptr[Offset]; 249 PciWrite8 (MmioAddr + Offset, Data); 250 } 251 break; 252 } 253 254 return EFI_SUCCESS; 255 } 256 257 /** 258 Get total pages for specific NVME based memory. 259 260 @param[in] BaseMemIndex - The Index of BaseMem (0-based). 261 262 @retval - The page count for specific BaseMem Index 263 264 **/ 265 UINT32 266 NvmeGetBaseMemPages ( 267 IN UINTN BaseMemIndex 268 ) 269 { 270 UINT32 Pages; 271 UINTN Index; 272 UINT32 PageSizeList[8]; 273 274 PageSizeList[0] = 1; /* Controller Data */ 275 PageSizeList[1] = 1; /* Identify Data */ 276 PageSizeList[2] = 1; /* ASQ */ 277 PageSizeList[3] = 1; /* ACQ */ 278 PageSizeList[4] = 1; /* SQs */ 279 PageSizeList[5] = 1; /* CQs */ 280 PageSizeList[6] = NVME_PRP_SIZE * NVME_CSQ_DEPTH; /* PRPs */ 281 PageSizeList[7] = 1; /* Security Commands */ 282 283 if (BaseMemIndex > MAX_BASEMEM_COUNT) { 284 ASSERT (FALSE); 285 return 0; 286 } 287 288 Pages = 0; 289 for (Index = 0; Index < BaseMemIndex; Index++) { 290 Pages += PageSizeList[Index]; 291 } 292 293 return Pages; 294 } 295 296 /** 297 Wait for NVME controller status to be ready or not. 298 299 @param[in] Nvme - The pointer to the NVME_CONTEXT Data structure. 300 @param[in] WaitReady - Flag for waitting status ready or not 301 302 @return EFI_SUCCESS - Successfully to wait specific status. 303 @return others - Fail to wait for specific controller status. 304 305 **/ 306 STATIC 307 EFI_STATUS 308 NvmeWaitController ( 309 IN NVME_CONTEXT *Nvme, 310 IN BOOLEAN WaitReady 311 ) 312 { 313 NVME_CSTS Csts; 314 EFI_STATUS Status; 315 UINT32 Index; 316 UINT8 Timeout; 317 318 // 319 // Cap.To specifies max delay time in 500ms increments for Csts.Rdy to set after 320 // Cc.Enable. Loop produces a 1 millisecond delay per itteration, up to 500 * Cap.To. 321 // 322 if (Nvme->Cap.To == 0) { 323 Timeout = 1; 324 } else { 325 Timeout = Nvme->Cap.To; 326 } 327 328 Status = EFI_SUCCESS; 329 for(Index = (Timeout * 500); Index != 0; --Index) { 330 MicroSecondDelay (1000); 331 332 // 333 // Check if the controller is initialized 334 // 335 Status = NVME_GET_CSTS (Nvme, &Csts); 336 if (EFI_ERROR(Status)) { 337 DEBUG ((DEBUG_ERROR, "NVME_GET_CSTS fail, Status = %r\n", Status)); 338 return Status; 339 } 340 341 if ((BOOLEAN) Csts.Rdy == WaitReady) { 342 break; 343 } 344 } 345 346 if (Index == 0) { 347 Status = EFI_TIMEOUT; 348 } 349 350 return Status; 351 } 352 353 /** 354 Disable the Nvm Express controller. 355 356 @param[in] Nvme - The pointer to the NVME_CONTEXT Data structure. 357 358 @return EFI_SUCCESS - Successfully disable the controller. 359 @return others - Fail to disable the controller. 360 361 **/ 362 STATIC 363 EFI_STATUS 364 NvmeDisableController ( 365 IN NVME_CONTEXT *Nvme 366 ) 367 { 368 NVME_CC Cc; 369 NVME_CSTS Csts; 370 EFI_STATUS Status; 371 372 Status = NVME_GET_CSTS (Nvme, &Csts); 373 374 /// 375 /// Read Controller Configuration Register. 376 /// 377 Status = NVME_GET_CC (Nvme, &Cc); 378 if (EFI_ERROR(Status)) { 379 DEBUG ((DEBUG_ERROR, "NVME_GET_CC fail, Status = %r\n", Status)); 380 goto Done; 381 } 382 383 if (Cc.En == 1) { 384 Cc.En = 0; 385 /// 386 /// Disable the controller. 387 /// 388 Status = NVME_SET_CC (Nvme, &Cc); 389 if (EFI_ERROR(Status)) { 390 DEBUG ((DEBUG_ERROR, "NVME_SET_CC fail, Status = %r\n", Status)); 391 goto Done; 392 } 393 } 394 395 Status = NvmeWaitController (Nvme, FALSE); 396 if (EFI_ERROR(Status)) { 397 DEBUG ((DEBUG_ERROR, "NvmeWaitController fail, Status = %r\n", Status)); 398 goto Done; 399 } 400 401 return EFI_SUCCESS; 402 403 Done: 404 DEBUG ((DEBUG_INFO, "NvmeDisableController fail, Status: %r\n", Status)); 405 return Status; 406 } 407 408 /** 409 Enable the Nvm Express controller. 410 411 @param[in] Nvme - The pointer to the NVME_CONTEXT Data structure. 412 413 @return EFI_SUCCESS - Successfully enable the controller. 414 @return EFI_DEVICE_ERROR - Fail to enable the controller. 415 @return EFI_TIMEOUT - Fail to enable the controller in given time slot. 416 417 **/ 418 STATIC 419 EFI_STATUS 420 NvmeEnableController ( 421 IN NVME_CONTEXT *Nvme 422 ) 423 { 424 NVME_CC Cc; 425 EFI_STATUS Status; 426 427 // 428 // Enable the controller 429 // 430 ZeroMem (&Cc, sizeof (NVME_CC)); 431 Cc.En = 1; 432 Cc.Iosqes = 6; 433 Cc.Iocqes = 4; 434 Status = NVME_SET_CC (Nvme, &Cc); 435 if (EFI_ERROR(Status)) { 436 DEBUG ((DEBUG_ERROR, "NVME_SET_CC fail, Status = %r\n", Status)); 437 goto Done; 438 } 439 440 Status = NvmeWaitController (Nvme, TRUE); 441 if (EFI_ERROR(Status)) { 442 DEBUG ((DEBUG_ERROR, "NvmeWaitController fail, Status = %r\n", Status)); 443 goto Done; 444 } 445 446 return EFI_SUCCESS; 447 448 Done: 449 DEBUG ((DEBUG_INFO, "NvmeEnableController fail, Status: %r\n", Status)); 450 return Status; 451 } 452 453 /** 454 Shutdown the Nvm Express controller. 455 456 @param[in] Nvme - The pointer to the NVME_CONTEXT Data structure. 457 458 @return EFI_SUCCESS - Successfully shutdown the controller. 459 @return EFI_DEVICE_ERROR - Fail to shutdown the controller. 460 @return EFI_TIMEOUT - Fail to shutdown the controller in given time slot. 461 462 **/ 463 STATIC 464 EFI_STATUS 465 NvmeShutdownController ( 466 IN NVME_CONTEXT *Nvme 467 ) 468 { 469 NVME_CC Cc; 470 NVME_CSTS Csts; 471 EFI_STATUS Status; 472 UINT32 Index; 473 UINTN Timeout; 474 475 Status = NVME_GET_CC (Nvme, &Cc); 476 if (EFI_ERROR(Status)) { 477 DEBUG ((DEBUG_ERROR, "NVME_GET_CC fail, Status = %r\n", Status)); 478 return Status; 479 } 480 481 Cc.Shn = 1; // Normal shutdown 482 483 Status = NVME_SET_CC (Nvme, &Cc); 484 if (EFI_ERROR(Status)) { 485 DEBUG ((DEBUG_ERROR, "NVME_SET_CC fail, Status = %r\n", Status)); 486 return Status; 487 } 488 489 Timeout = NVME_GENERIC_TIMEOUT/1000; // ms 490 for(Index = (UINT32)(Timeout); Index != 0; --Index) { 491 MicroSecondDelay (1000); 492 493 Status = NVME_GET_CSTS (Nvme, &Csts); 494 if (EFI_ERROR(Status)) { 495 DEBUG ((DEBUG_ERROR, "NVME_GET_CSTS fail, Status = %r\n", Status)); 496 return Status; 497 } 498 499 if (Csts.Shst == 2) { // Shutdown processing complete 500 break; 501 } 502 } 503 504 if (Index == 0) { 505 Status = EFI_TIMEOUT; 506 } 507 508 return Status; 509 } 510 511 /** 512 Check the execution status from a given completion queue entry. 513 514 @param[in] Cq - A pointer to the NVME_CQ item. 515 516 **/ 517 EFI_STATUS 518 NvmeCheckCqStatus ( 519 IN NVME_CQ *Cq 520 ) 521 { 522 if (Cq->Sct == 0x0 && Cq->Sc == 0x0) { 523 return EFI_SUCCESS; 524 } 525 526 DEBUG ((DEBUG_INFO, "Dump NVMe Completion Entry Status from [0x%x]:\n", (UINTN)Cq)); 527 DEBUG ((DEBUG_INFO, " SQ Identifier : [0x%x], Phase Tag : [%d], Cmd Identifier : [0x%x]\n", Cq->Sqid, Cq->Pt, Cq->Cid)); 528 DEBUG ((DEBUG_INFO, " NVMe Cmd Execution Result - ")); 529 530 switch (Cq->Sct) { 531 case 0x0: 532 switch (Cq->Sc) { 533 case 0x0: 534 DEBUG ((DEBUG_INFO, "Successful Completion\n")); 535 return EFI_SUCCESS; 536 case 0x1: 537 DEBUG ((DEBUG_INFO, "Invalid Command Opcode\n")); 538 break; 539 case 0x2: 540 DEBUG ((DEBUG_INFO, "Invalid Field in Command\n")); 541 break; 542 case 0x3: 543 DEBUG ((DEBUG_INFO, "Command ID Conflict\n")); 544 break; 545 case 0x4: 546 DEBUG ((DEBUG_INFO, "Data Transfer Error\n")); 547 break; 548 case 0x5: 549 DEBUG ((DEBUG_INFO, "Commands Aborted due to Power Loss Notification\n")); 550 break; 551 case 0x6: 552 DEBUG ((DEBUG_INFO, "Internal Device Error\n")); 553 break; 554 case 0x7: 555 DEBUG ((DEBUG_INFO, "Command Abort Requested\n")); 556 break; 557 case 0x8: 558 DEBUG ((DEBUG_INFO, "Command Aborted due to SQ Deletion\n")); 559 break; 560 case 0x9: 561 DEBUG ((DEBUG_INFO, "Command Aborted due to Failed Fused Command\n")); 562 break; 563 case 0xA: 564 DEBUG ((DEBUG_INFO, "Command Aborted due to Missing Fused Command\n")); 565 break; 566 case 0xB: 567 DEBUG ((DEBUG_INFO, "Invalid Namespace or Format\n")); 568 break; 569 case 0xC: 570 DEBUG ((DEBUG_INFO, "Command Sequence Error\n")); 571 break; 572 case 0xD: 573 DEBUG ((DEBUG_INFO, "Invalid SGL Last Segment Descriptor\n")); 574 break; 575 case 0xE: 576 DEBUG ((DEBUG_INFO, "Invalid Number of SGL Descriptors\n")); 577 break; 578 case 0xF: 579 DEBUG ((DEBUG_INFO, "Data SGL Length Invalid\n")); 580 break; 581 case 0x10: 582 DEBUG ((DEBUG_INFO, "Metadata SGL Length Invalid\n")); 583 break; 584 case 0x11: 585 DEBUG ((DEBUG_INFO, "SGL Descriptor Type Invalid\n")); 586 break; 587 case 0x80: 588 DEBUG ((DEBUG_INFO, "LBA Out of Range\n")); 589 break; 590 case 0x81: 591 DEBUG ((DEBUG_INFO, "Capacity Exceeded\n")); 592 break; 593 case 0x82: 594 DEBUG ((DEBUG_INFO, "Namespace Not Ready\n")); 595 break; 596 case 0x83: 597 DEBUG ((DEBUG_INFO, "Reservation Conflict\n")); 598 break; 599 } 600 break; 601 602 case 0x1: 603 switch (Cq->Sc) { 604 case 0x0: 605 DEBUG ((DEBUG_INFO, "Completion Queue Invalid\n")); 606 break; 607 case 0x1: 608 DEBUG ((DEBUG_INFO, "Invalid Queue Identifier\n")); 609 break; 610 case 0x2: 611 DEBUG ((DEBUG_INFO, "Maximum Queue Size Exceeded\n")); 612 break; 613 case 0x3: 614 DEBUG ((DEBUG_INFO, "Abort Command Limit Exceeded\n")); 615 break; 616 case 0x5: 617 DEBUG ((DEBUG_INFO, "Asynchronous Event Request Limit Exceeded\n")); 618 break; 619 case 0x6: 620 DEBUG ((DEBUG_INFO, "Invalid Firmware Slot\n")); 621 break; 622 case 0x7: 623 DEBUG ((DEBUG_INFO, "Invalid Firmware Image\n")); 624 break; 625 case 0x8: 626 DEBUG ((DEBUG_INFO, "Invalid Interrupt Vector\n")); 627 break; 628 case 0x9: 629 DEBUG ((DEBUG_INFO, "Invalid Log Page\n")); 630 break; 631 case 0xA: 632 DEBUG ((DEBUG_INFO, "Invalid Format\n")); 633 break; 634 case 0xB: 635 DEBUG ((DEBUG_INFO, "Firmware Application Requires Conventional Reset\n")); 636 break; 637 case 0xC: 638 DEBUG ((DEBUG_INFO, "Invalid Queue Deletion\n")); 639 break; 640 case 0xD: 641 DEBUG ((DEBUG_INFO, "Feature Identifier Not Saveable\n")); 642 break; 643 case 0xE: 644 DEBUG ((DEBUG_INFO, "Feature Not Changeable\n")); 645 break; 646 case 0xF: 647 DEBUG ((DEBUG_INFO, "Feature Not Namespace Specific\n")); 648 break; 649 case 0x10: 650 DEBUG ((DEBUG_INFO, "Firmware Application Requires NVM Subsystem Reset\n")); 651 break; 652 case 0x80: 653 DEBUG ((DEBUG_INFO, "Conflicting Attributes\n")); 654 break; 655 case 0x81: 656 DEBUG ((DEBUG_INFO, "Invalid Protection Information\n")); 657 break; 658 case 0x82: 659 DEBUG ((DEBUG_INFO, "Attempted Write to Read Only Range\n")); 660 break; 661 } 662 break; 663 664 case 0x2: 665 switch (Cq->Sc) { 666 case 0x80: 667 DEBUG ((DEBUG_INFO, "Write Fault\n")); 668 break; 669 case 0x81: 670 DEBUG ((DEBUG_INFO, "Unrecovered Read Error\n")); 671 break; 672 case 0x82: 673 DEBUG ((DEBUG_INFO, "End-to-end Guard Check Error\n")); 674 break; 675 case 0x83: 676 DEBUG ((DEBUG_INFO, "End-to-end Application Tag Check Error\n")); 677 break; 678 case 0x84: 679 DEBUG ((DEBUG_INFO, "End-to-end Reference Tag Check Error\n")); 680 break; 681 case 0x85: 682 DEBUG ((DEBUG_INFO, "Compare Failure\n")); 683 break; 684 case 0x86: 685 DEBUG ((DEBUG_INFO, "Access Denied\n")); 686 break; 687 } 688 break; 689 690 default: 691 DEBUG ((DEBUG_INFO, "Unknown error\n")); 692 break; 693 } 694 695 return EFI_DEVICE_ERROR; 696 } 697 698 /** 699 Create PRP lists for Data transfer which is larger than 2 memory pages. 700 Note here we calcuate the number of required PRP lists and allocate them at one time. 701 702 @param[in] Nvme - The pointer to the NVME_CONTEXT Data structure. 703 @param[in] SqId - The SQ index for this PRP 704 @param[in] PhysicalAddr - The physical base address of Data Buffer. 705 @param[in] Pages - The number of pages to be transfered. 706 @param[out] PrpListHost - The host base address of PRP lists. 707 @param[in,out] PrpListNo - The number of PRP List. 708 709 @retval The pointer Value to the first PRP List of the PRP lists. 710 711 **/ 712 STATIC 713 UINT64 714 NvmeCreatePrpList ( 715 IN NVME_CONTEXT *Nvme, 716 IN UINT16 SqId, 717 IN EFI_PHYSICAL_ADDRESS PhysicalAddr, 718 IN UINTN Pages, 719 OUT VOID **PrpListHost, 720 IN OUT UINTN *PrpListNo 721 ) 722 { 723 UINTN PrpEntryNo; 724 UINT64 PrpListBase; 725 UINTN PrpListIndex; 726 UINTN PrpEntryIndex; 727 UINT64 Remainder; 728 EFI_PHYSICAL_ADDRESS PrpListPhyAddr; 729 UINTN Bytes; 730 UINT8 *PrpEntry; 731 EFI_PHYSICAL_ADDRESS NewPhyAddr; 732 733 /// 734 /// The number of Prp Entry in a memory page. 735 /// 736 PrpEntryNo = EFI_PAGE_SIZE / sizeof (UINT64); 737 738 /// 739 /// Calculate total PrpList number. 740 /// 741 *PrpListNo = (UINTN) DivU64x64Remainder ((UINT64)Pages, (UINT64)PrpEntryNo, &Remainder); 742 if (Remainder != 0) { 743 *PrpListNo += 1; 744 } 745 746 if (*PrpListNo > NVME_PRP_SIZE) { 747 DEBUG ((DEBUG_INFO, "NvmeCreatePrpList (PhysicalAddr: %lx, Pages: %x) PrpEntryNo: %x\n", 748 PhysicalAddr, Pages, PrpEntryNo)); 749 DEBUG ((DEBUG_INFO, "*PrpListNo: %x, Remainder: %lx", *PrpListNo, Remainder)); 750 ASSERT (FALSE); 751 } 752 *PrpListHost = (VOID *)(UINTN) NVME_PRP_BASE (Nvme, SqId); 753 754 Bytes = EFI_PAGES_TO_SIZE (*PrpListNo); 755 PrpListPhyAddr = (UINT64)(UINTN)(*PrpListHost); 756 757 /// 758 /// Fill all PRP lists except of last one. 759 /// 760 ZeroMem (*PrpListHost, Bytes); 761 for (PrpListIndex = 0; PrpListIndex < *PrpListNo - 1; ++PrpListIndex) { 762 PrpListBase = *(UINT64*)PrpListHost + PrpListIndex * EFI_PAGE_SIZE; 763 764 for (PrpEntryIndex = 0; PrpEntryIndex < PrpEntryNo; ++PrpEntryIndex) { 765 PrpEntry = (UINT8 *)(UINTN) (PrpListBase + PrpEntryIndex * sizeof(UINT64)); 766 if (PrpEntryIndex != PrpEntryNo - 1) { 767 /// 768 /// Fill all PRP entries except of last one. 769 /// 770 CopyMem (PrpEntry, (VOID *)(UINTN) (&PhysicalAddr), sizeof (UINT64)); 771 PhysicalAddr += EFI_PAGE_SIZE; 772 } else { 773 /// 774 /// Fill last PRP entries with next PRP List pointer. 775 /// 776 NewPhyAddr = (PrpListPhyAddr + (PrpListIndex + 1) * EFI_PAGE_SIZE); 777 CopyMem (PrpEntry, (VOID *)(UINTN) (&NewPhyAddr), sizeof (UINT64)); 778 } 779 } 780 } 781 782 /// 783 /// Fill last PRP list. 784 /// 785 PrpListBase = *(UINT64*)PrpListHost + PrpListIndex * EFI_PAGE_SIZE; 786 for (PrpEntryIndex = 0; PrpEntryIndex < ((Remainder != 0) ? Remainder : PrpEntryNo); ++PrpEntryIndex) { 787 PrpEntry = (UINT8 *)(UINTN) (PrpListBase + PrpEntryIndex * sizeof(UINT64)); 788 CopyMem (PrpEntry, (VOID *)(UINTN) (&PhysicalAddr), sizeof (UINT64)); 789 790 PhysicalAddr += EFI_PAGE_SIZE; 791 } 792 793 return PrpListPhyAddr; 794 } 795 796 /** 797 Check whether there are available command slots. 798 799 @param[in] Nvme - The pointer to the NVME_CONTEXT Data structure. 800 @param[in] Qid - Queue index 801 802 @retval EFI_SUCCESS - Available command slot is found 803 @retval EFI_NOT_READY - No available command slot is found 804 @retval EFI_DEVICE_ERROR - Error occurred on device side. 805 806 **/ 807 EFI_STATUS 808 NvmeHasFreeCmdSlot ( 809 IN NVME_CONTEXT *Nvme, 810 IN UINT8 Qid 811 ) 812 { 813 return TRUE; 814 } 815 816 /** 817 Check whether all command slots are clean. 818 819 @param[in] Nvme - The pointer to the NVME_CONTEXT Data structure. 820 @param[in] Qid - Queue index 821 822 @retval EFI_SUCCESS - All command slots are clean 823 @retval EFI_NOT_READY - Not all command slots are clean 824 @retval EFI_DEVICE_ERROR - Error occurred on device side. 825 826 **/ 827 EFI_STATUS 828 NvmeIsAllCmdSlotClean ( 829 IN NVME_CONTEXT *Nvme, 830 IN UINT8 Qid 831 ) 832 { 833 return EFI_SUCCESS; 834 } 835 836 /** 837 Waits until all NVME commands completed. 838 839 @param[in] Nvme - The pointer to the NVME_CONTEXT Data structure. 840 @param[in] Qid - Queue index 841 842 @retval EFI_SUCCESS - All NVME commands have completed 843 @retval EFI_TIMEOUT - Timeout occured 844 @retval EFI_NOT_READY - Not all NVME commands have completed 845 @retval others - Error occurred on device side. 846 **/ 847 EFI_STATUS 848 NvmeWaitAllComplete ( 849 IN NVME_CONTEXT *Nvme, 850 IN UINT8 Qid 851 ) 852 { 853 return EFI_SUCCESS; 854 } 855 856 /** 857 Sends an NVM Express Command Packet to an NVM Express controller or namespace. This function supports 858 both blocking I/O and nonblocking I/O. The blocking I/O functionality is required, and the nonblocking 859 I/O functionality is optional. 860 861 @param[in] Nvme - The pointer to the NVME_CONTEXT Data structure. 862 @param[in] NamespaceId - Is a 32 bit Namespace ID to which the Express HCI command packet will be sent. 863 A Value of 0 denotes the NVM Express controller, a Value of all 0FFh in the namespace 864 ID specifies that the command packet should be sent to all valid namespaces. 865 @param[in] NamespaceUuid - Is a 64 bit Namespace UUID to which the Express HCI command packet will be sent. 866 A Value of 0 denotes the NVM Express controller, a Value of all 0FFh in the namespace 867 UUID specifies that the command packet should be sent to all valid namespaces. 868 @param[in,out] Packet - A pointer to the NVM Express HCI Command Packet to send to the NVMe namespace specified 869 by NamespaceId. 870 871 @retval EFI_SUCCESS - The NVM Express Command Packet was sent by the host. TransferLength bytes were transferred 872 to, or from DataBuffer. 873 @retval EFI_NOT_READY - The NVM Express Command Packet could not be sent because the controller is not ready. The caller 874 may retry again later. 875 @retval EFI_DEVICE_ERROR - A device error occurred while attempting to send the NVM Express Command Packet. 876 @retval EFI_INVALID_PARAMETER - Namespace, or the contents of NVM_EXPRESS_PASS_THRU_COMMAND_PACKET are invalid. The NVM 877 Express Command Packet was not sent, so no additional status information is available. 878 @retval EFI_UNSUPPORTED - The command described by the NVM Express Command Packet is not supported by the host adapter. 879 The NVM Express Command Packet was not sent, so no additional status information is available. 880 @retval EFI_TIMEOUT - A timeout occurred while waiting for the NVM Express Command Packet to execute. 881 882 **/ 883 EFI_STATUS 884 NvmePassThru ( 885 IN NVME_CONTEXT *Nvme, 886 IN UINT32 NamespaceId, 887 IN UINT64 NamespaceUuid, 888 IN OUT NVM_EXPRESS_PASS_THRU_COMMAND_PACKET *Packet 889 ) 890 { 891 EFI_STATUS Status; 892 NVME_SQ *Sq; 893 NVME_CQ *Cq; 894 UINT8 Qid; 895 UINT32 Bytes; 896 UINT32 Offset; 897 EFI_PHYSICAL_ADDRESS PhyAddr; 898 VOID *PrpListHost; 899 UINTN PrpListNo; 900 UINT32 Timer; 901 UINTN SqSize; 902 UINTN CqSize; 903 904 /// 905 /// check the Data fields in Packet parameter. 906 /// 907 if ((Nvme == NULL) || (Packet == NULL)) { 908 DEBUG ((DEBUG_ERROR, "NvmePassThru, invalid parameter: Nvme(%x)/Packet(%x)\n", 909 (UINTN)Nvme, (UINTN)Packet)); 910 return EFI_INVALID_PARAMETER; 911 } 912 913 if ((Packet->NvmeCmd == NULL) || (Packet->NvmeResponse == NULL)) { 914 DEBUG ((DEBUG_ERROR, "NvmePassThru, invalid parameter: NvmeCmd(%x)/NvmeResponse(%x)\n", 915 (UINTN)Packet->NvmeCmd, (UINTN)Packet->NvmeResponse)); 916 return EFI_INVALID_PARAMETER; 917 } 918 919 if (Packet->QueueId != NVME_ADMIN_QUEUE && Packet->QueueId != NVME_IO_QUEUE) { 920 DEBUG ((DEBUG_ERROR, "NvmePassThru, invalid parameter: QueueId(%x)\n", 921 Packet->QueueId)); 922 return EFI_INVALID_PARAMETER; 923 } 924 925 PrpListHost = NULL; 926 PrpListNo = 0; 927 Status = EFI_SUCCESS; 928 929 Qid = Packet->QueueId; 930 Sq = Nvme->SqBuffer[Qid] + Nvme->SqTdbl[Qid].Sqt; 931 Cq = Nvme->CqBuffer[Qid] + Nvme->CqHdbl[Qid].Cqh; 932 if (Qid == NVME_ADMIN_QUEUE) { 933 SqSize = NVME_ASQ_SIZE + 1; 934 CqSize = NVME_ACQ_SIZE + 1; 935 } else { 936 SqSize = NVME_CSQ_DEPTH; 937 CqSize = NVME_CCQ_DEPTH; 938 } 939 940 if (Packet->NvmeCmd->Nsid != NamespaceId) { 941 DEBUG ((DEBUG_ERROR, "NvmePassThru: Nsid mismatch (%x, %x)\n", 942 Packet->NvmeCmd->Nsid, NamespaceId)); 943 return EFI_INVALID_PARAMETER; 944 } 945 946 ZeroMem (Sq, sizeof (NVME_SQ)); 947 Sq->Opc = Packet->NvmeCmd->Cdw0.Opcode; 948 Sq->Fuse = Packet->NvmeCmd->Cdw0.FusedOperation; 949 Sq->Cid = Packet->NvmeCmd->Cdw0.Cid; 950 Sq->Nsid = Packet->NvmeCmd->Nsid; 951 952 /// 953 /// Currently we only support PRP for Data transfer, SGL is NOT supported. 954 /// 955 ASSERT (Sq->Psdt == 0); 956 if (Sq->Psdt != 0) { 957 DEBUG ((DEBUG_ERROR, "NvmePassThru: doesn't support SGL mechanism\n")); 958 return EFI_UNSUPPORTED; 959 } 960 961 Sq->Prp[0] = Packet->TransferBuffer; 962 Sq->Prp[1] = 0; 963 964 if(Packet->MetadataBuffer != (UINT64)(UINTN)NULL) { 965 Sq->Mptr = Packet->MetadataBuffer; 966 } 967 968 /// 969 /// If the Buffer Size spans more than two memory pages (page Size as defined in CC.Mps), 970 /// then build a PRP list in the second PRP submission queue entry. 971 /// 972 Offset = ((UINT32)Sq->Prp[0]) & (EFI_PAGE_SIZE - 1); 973 Bytes = Packet->TransferLength; 974 975 if ((Offset + Bytes) > (EFI_PAGE_SIZE * 2)) { 976 /// 977 /// Create PrpList for remaining Data Buffer. 978 /// 979 PhyAddr = (Sq->Prp[0] + EFI_PAGE_SIZE) & ~(EFI_PAGE_SIZE - 1); 980 Sq->Prp[1] = NvmeCreatePrpList (Nvme, Nvme->SqTdbl[Qid].Sqt, PhyAddr, EFI_SIZE_TO_PAGES(Offset + Bytes) - 1, &PrpListHost, &PrpListNo); 981 if (Sq->Prp[1] == 0) { 982 Status = EFI_OUT_OF_RESOURCES; 983 DEBUG ((DEBUG_ERROR, "NvmeCreatePrpList fail, Status: %r\n", Status)); 984 goto EXIT; 985 } 986 987 } else if ((Offset + Bytes) > EFI_PAGE_SIZE) { 988 Sq->Prp[1] = (Sq->Prp[0] + EFI_PAGE_SIZE) & ~(EFI_PAGE_SIZE - 1); 989 } 990 991 if(Packet->NvmeCmd->Flags & CDW10_VALID) { 992 Sq->Payload.Raw.Cdw10 = Packet->NvmeCmd->Cdw10; 993 } 994 if(Packet->NvmeCmd->Flags & CDW11_VALID) { 995 Sq->Payload.Raw.Cdw11 = Packet->NvmeCmd->Cdw11; 996 } 997 if(Packet->NvmeCmd->Flags & CDW12_VALID) { 998 Sq->Payload.Raw.Cdw12 = Packet->NvmeCmd->Cdw12; 999 } 1000 if(Packet->NvmeCmd->Flags & CDW13_VALID) { 1001 Sq->Payload.Raw.Cdw13 = Packet->NvmeCmd->Cdw13; 1002 } 1003 if(Packet->NvmeCmd->Flags & CDW14_VALID) { 1004 Sq->Payload.Raw.Cdw14 = Packet->NvmeCmd->Cdw14; 1005 } 1006 if(Packet->NvmeCmd->Flags & CDW15_VALID) { 1007 Sq->Payload.Raw.Cdw15 = Packet->NvmeCmd->Cdw15; 1008 } 1009 1010 /// 1011 /// Ring the submission queue doorbell. 1012 /// 1013 Nvme->SqTdbl[Qid].Sqt++; 1014 if(Nvme->SqTdbl[Qid].Sqt == SqSize) { 1015 Nvme->SqTdbl[Qid].Sqt = 0; 1016 } 1017 Status = NVME_SET_SQTDBL (Nvme, Qid, &Nvme->SqTdbl[Qid]); 1018 if (EFI_ERROR(Status)) { 1019 DEBUG ((DEBUG_ERROR, "NVME_SET_SQTDBL fail, Status: %r\n", Status)); 1020 goto EXIT; 1021 } 1022 1023 /// 1024 /// Wait for completion queue to get filled in. 1025 /// 1026 Status = EFI_TIMEOUT; 1027 Timer = 0; 1028 while (Timer < NVME_CMD_TIMEOUT) { 1029 //DEBUG ((DEBUG_VERBOSE, "Timer: %x, Cq:\n", Timer)); 1030 //DumpMem (Cq, sizeof (NVME_CQ)); 1031 if (Cq->Pt != Nvme->Pt[Qid]) { 1032 Status = EFI_SUCCESS; 1033 break; 1034 } 1035 1036 MicroSecondDelay (NVME_CMD_WAIT); 1037 Timer += NVME_CMD_WAIT; 1038 } 1039 1040 Nvme->CqHdbl[Qid].Cqh++; 1041 if (Nvme->CqHdbl[Qid].Cqh == CqSize) { 1042 Nvme->CqHdbl[Qid].Cqh = 0; 1043 Nvme->Pt[Qid] ^= 1; 1044 } 1045 1046 /// 1047 /// Copy the Respose Queue entry for this command to the callers response Buffer 1048 /// 1049 CopyMem (Packet->NvmeResponse, Cq, sizeof(NVM_EXPRESS_RESPONSE)); 1050 1051 if (!EFI_ERROR(Status)) { // We still need to check CQ status if no timeout error occured 1052 Status = NvmeCheckCqStatus (Cq); 1053 } 1054 NVME_SET_CQHDBL (Nvme, Qid, &Nvme->CqHdbl[Qid]); 1055 1056 EXIT: 1057 return Status; 1058 } 1059 1060 /** 1061 Get identify controller Data. 1062 1063 @param[in] Nvme - The pointer to the NVME_CONTEXT Data structure. 1064 @param[in] Buffer - The Buffer used to store the identify controller Data. 1065 1066 @return EFI_SUCCESS - Successfully get the identify controller Data. 1067 @return others - Fail to get the identify controller Data. 1068 1069 **/ 1070 STATIC 1071 EFI_STATUS 1072 NvmeIdentifyController ( 1073 IN NVME_CONTEXT *Nvme, 1074 IN VOID *Buffer 1075 ) 1076 { 1077 NVM_EXPRESS_PASS_THRU_COMMAND_PACKET CommandPacket; 1078 NVM_EXPRESS_COMMAND Command; 1079 NVM_EXPRESS_RESPONSE Response; 1080 EFI_STATUS Status; 1081 1082 ZeroMem (&CommandPacket, sizeof(NVM_EXPRESS_PASS_THRU_COMMAND_PACKET)); 1083 ZeroMem (&Command, sizeof(NVM_EXPRESS_COMMAND)); 1084 ZeroMem (&Response, sizeof(NVM_EXPRESS_RESPONSE)); 1085 1086 Command.Cdw0.Opcode = NVME_ADMIN_IDENTIFY_OPC; 1087 Command.Cdw0.Cid = Nvme->Cid[NVME_ADMIN_QUEUE]++; 1088 // 1089 // According to Nvm Express 1.1 spec Figure 38, When not used, the field shall be cleared to 0h. 1090 // For the Identify command, the Namespace Identifier is only used for the Namespace Data structure. 1091 // 1092 Command.Nsid = 0; 1093 1094 CommandPacket.NvmeCmd = &Command; 1095 CommandPacket.NvmeResponse = &Response; 1096 CommandPacket.TransferBuffer = (UINT64)(UINTN)Buffer; 1097 CommandPacket.TransferLength = sizeof (NVME_ADMIN_CONTROLLER_DATA); 1098 CommandPacket.CommandTimeout = NVME_GENERIC_TIMEOUT; 1099 CommandPacket.QueueId = NVME_ADMIN_QUEUE; 1100 // 1101 // Set bit 0 (Cns bit) to 1 to identify a controller 1102 // 1103 Command.Cdw10 = 1; 1104 Command.Flags = CDW10_VALID; 1105 1106 Status = NvmePassThru ( 1107 Nvme, 1108 NVME_CONTROLLER_ID, 1109 0, 1110 &CommandPacket 1111 ); 1112 if (!EFI_ERROR (Status)) { 1113 Status = NvmeWaitAllComplete (Nvme, CommandPacket.QueueId); 1114 } 1115 1116 return Status; 1117 } 1118 1119 /** 1120 Get specified identify namespace Data. 1121 1122 @param[in] Nvme - The pointer to the NVME_CONTEXT Data structure. 1123 @param[in] NamespaceId - The specified namespace identifier. 1124 @param[in] Buffer - The Buffer used to store the identify namespace Data. 1125 1126 @return EFI_SUCCESS - Successfully get the identify namespace Data. 1127 @return others - Fail to get the identify namespace Data. 1128 1129 **/ 1130 STATIC 1131 EFI_STATUS 1132 NvmeIdentifyNamespace ( 1133 IN NVME_CONTEXT *Nvme, 1134 IN UINT32 NamespaceId, 1135 IN VOID *Buffer 1136 ) 1137 { 1138 NVM_EXPRESS_PASS_THRU_COMMAND_PACKET CommandPacket; 1139 NVM_EXPRESS_COMMAND Command; 1140 NVM_EXPRESS_RESPONSE Response; 1141 EFI_STATUS Status; 1142 1143 ZeroMem (&CommandPacket, sizeof(NVM_EXPRESS_PASS_THRU_COMMAND_PACKET)); 1144 ZeroMem (&Command, sizeof(NVM_EXPRESS_COMMAND)); 1145 ZeroMem (&Response, sizeof(NVM_EXPRESS_RESPONSE)); 1146 1147 CommandPacket.NvmeCmd = &Command; 1148 CommandPacket.NvmeResponse = &Response; 1149 1150 Command.Cdw0.Opcode = NVME_ADMIN_IDENTIFY_OPC; 1151 Command.Cdw0.Cid = Nvme->Cid[NVME_ADMIN_QUEUE]++; 1152 Command.Nsid = NamespaceId; 1153 CommandPacket.TransferBuffer = (UINT64)(UINTN)Buffer; 1154 CommandPacket.TransferLength = sizeof (NVME_ADMIN_NAMESPACE_DATA); 1155 CommandPacket.CommandTimeout = NVME_GENERIC_TIMEOUT; 1156 CommandPacket.QueueId = NVME_ADMIN_QUEUE; 1157 // 1158 // Set bit 0 (Cns bit) to 1 to identify a namespace 1159 // 1160 CommandPacket.NvmeCmd->Cdw10 = 0; 1161 CommandPacket.NvmeCmd->Flags = CDW10_VALID; 1162 1163 Status = NvmePassThru ( 1164 Nvme, 1165 NamespaceId, 1166 0, 1167 &CommandPacket 1168 ); 1169 if (!EFI_ERROR (Status)) { 1170 Status = NvmeWaitAllComplete (Nvme, CommandPacket.QueueId); 1171 } 1172 1173 return Status; 1174 } 1175 1176 /** 1177 Get Block Size for specific namespace of NVME. 1178 1179 @param[in] Nvme - The pointer to the NVME_CONTEXT Data structure. 1180 1181 @return - Block Size in bytes 1182 1183 **/ 1184 STATIC 1185 UINT32 1186 NvmeGetBlockSize ( 1187 IN NVME_CONTEXT *Nvme 1188 ) 1189 { 1190 UINT32 BlockSize; 1191 UINT32 Lbads; 1192 UINT32 Flbas; 1193 UINT32 LbaFmtIdx; 1194 1195 Flbas = Nvme->NamespaceData->Flbas; 1196 LbaFmtIdx = Flbas & 3; 1197 Lbads = Nvme->NamespaceData->LbaFormat[LbaFmtIdx].Lbads; 1198 1199 BlockSize = (UINT32)1 << Lbads; 1200 return BlockSize; 1201 } 1202 1203 /** 1204 Get last LBA for specific namespace of NVME. 1205 1206 @param[in] Nvme - The pointer to the NVME_CONTEXT Data structure. 1207 1208 @return - Last LBA address 1209 1210 **/ 1211 STATIC 1212 EFI_LBA 1213 NvmeGetLastLba ( 1214 IN NVME_CONTEXT *Nvme 1215 ) 1216 { 1217 EFI_LBA LastBlock; 1218 LastBlock = Nvme->NamespaceData->Nsze - 1; 1219 return LastBlock; 1220 } 1221 1222 /** 1223 Create io completion queue. 1224 1225 @param[in] Nvme - The pointer to the NVME_CONTEXT Data structure. 1226 1227 @return EFI_SUCCESS - Successfully create io completion queue. 1228 @return others - Fail to create io completion queue. 1229 1230 **/ 1231 STATIC 1232 EFI_STATUS 1233 NvmeCreateIoCompletionQueue ( 1234 IN NVME_CONTEXT *Nvme 1235 ) 1236 { 1237 NVM_EXPRESS_PASS_THRU_COMMAND_PACKET CommandPacket; 1238 NVM_EXPRESS_COMMAND Command; 1239 NVM_EXPRESS_RESPONSE Response; 1240 EFI_STATUS Status; 1241 NVME_ADMIN_CRIOCQ CrIoCq; 1242 1243 ZeroMem (&CommandPacket, sizeof(NVM_EXPRESS_PASS_THRU_COMMAND_PACKET)); 1244 ZeroMem (&Command, sizeof(NVM_EXPRESS_COMMAND)); 1245 ZeroMem (&Response, sizeof(NVM_EXPRESS_RESPONSE)); 1246 ZeroMem (&CrIoCq, sizeof(NVME_ADMIN_CRIOCQ)); 1247 1248 CommandPacket.NvmeCmd = &Command; 1249 CommandPacket.NvmeResponse = &Response; 1250 1251 Command.Cdw0.Opcode = NVME_ADMIN_CRIOCQ_OPC; 1252 Command.Cdw0.Cid = Nvme->Cid[NVME_ADMIN_QUEUE]++; 1253 CommandPacket.TransferBuffer = (UINT64)(UINTN)Nvme->CqBuffer[NVME_IO_QUEUE]; 1254 CommandPacket.TransferLength = EFI_PAGE_SIZE; 1255 CommandPacket.CommandTimeout = NVME_GENERIC_TIMEOUT; 1256 CommandPacket.QueueId = NVME_ADMIN_QUEUE; 1257 1258 CrIoCq.Qid = NVME_IO_QUEUE; 1259 CrIoCq.Qsize = NVME_CCQ_SIZE; 1260 CrIoCq.Pc = 1; 1261 CopyMem (&CommandPacket.NvmeCmd->Cdw10, &CrIoCq, sizeof (NVME_ADMIN_CRIOCQ)); 1262 CommandPacket.NvmeCmd->Flags = CDW10_VALID | CDW11_VALID; 1263 1264 Status = NvmePassThru ( 1265 Nvme, 1266 NVME_CONTROLLER_ID, 1267 0, 1268 &CommandPacket 1269 ); 1270 if (!EFI_ERROR (Status)) { 1271 Status = NvmeWaitAllComplete (Nvme, CommandPacket.QueueId); 1272 } 1273 1274 return Status; 1275 } 1276 1277 /** 1278 Create io submission queue. 1279 1280 @param[in] Nvme - The pointer to the NVME_CONTEXT Data structure. 1281 1282 @return EFI_SUCCESS - Successfully create io submission queue. 1283 @return others - Fail to create io submission queue. 1284 1285 **/ 1286 STATIC 1287 EFI_STATUS 1288 NvmeCreateIoSubmissionQueue ( 1289 IN NVME_CONTEXT *Nvme 1290 ) 1291 { 1292 NVM_EXPRESS_PASS_THRU_COMMAND_PACKET CommandPacket; 1293 NVM_EXPRESS_COMMAND Command; 1294 NVM_EXPRESS_RESPONSE Response; 1295 EFI_STATUS Status; 1296 NVME_ADMIN_CRIOSQ CrIoSq; 1297 1298 ZeroMem (&CommandPacket, sizeof(NVM_EXPRESS_PASS_THRU_COMMAND_PACKET)); 1299 ZeroMem (&Command, sizeof(NVM_EXPRESS_COMMAND)); 1300 ZeroMem (&Response, sizeof(NVM_EXPRESS_RESPONSE)); 1301 ZeroMem (&CrIoSq, sizeof(NVME_ADMIN_CRIOSQ)); 1302 1303 CommandPacket.NvmeCmd = &Command; 1304 CommandPacket.NvmeResponse = &Response; 1305 1306 Command.Cdw0.Opcode = NVME_ADMIN_CRIOSQ_OPC; 1307 Command.Cdw0.Cid = Nvme->Cid[NVME_ADMIN_QUEUE]++; 1308 CommandPacket.TransferBuffer = (UINT64)(UINTN)Nvme->SqBuffer[NVME_IO_QUEUE]; 1309 CommandPacket.TransferLength = EFI_PAGE_SIZE; 1310 CommandPacket.CommandTimeout = NVME_GENERIC_TIMEOUT; 1311 CommandPacket.QueueId = NVME_ADMIN_QUEUE; 1312 1313 CrIoSq.Qid = NVME_IO_QUEUE; 1314 CrIoSq.Qsize = NVME_CSQ_SIZE; 1315 CrIoSq.Pc = 1; 1316 CrIoSq.Cqid = NVME_IO_QUEUE; 1317 CrIoSq.Qprio = 0; 1318 CopyMem (&CommandPacket.NvmeCmd->Cdw10, &CrIoSq, sizeof (NVME_ADMIN_CRIOSQ)); 1319 CommandPacket.NvmeCmd->Flags = CDW10_VALID | CDW11_VALID; 1320 1321 Status = NvmePassThru ( 1322 Nvme, 1323 NVME_CONTROLLER_ID, 1324 0, 1325 &CommandPacket 1326 ); 1327 if (!EFI_ERROR (Status)) { 1328 Status = NvmeWaitAllComplete (Nvme, CommandPacket.QueueId); 1329 } 1330 1331 return Status; 1332 } 1333 1334 /** 1335 Security send and receive commands. 1336 1337 @param[in] Nvme - The pointer to the NVME_CONTEXT Data structure. 1338 @param[in] SendCommand - The flag to indicate the command type, TRUE for Send command and FALSE for receive command 1339 @param[in] SecurityProtocol - Security Protocol 1340 @param[in] SpSpecific - Security Protocol Specific 1341 @param[in] TransferLength - Transfer Length of Buffer (in bytes) - always a multiple of 512 1342 @param[in,out] TransferBuffer - Address of Data to transfer 1343 1344 @return EFI_SUCCESS - Successfully create io submission queue. 1345 @return others - Fail to send/receive commands. 1346 1347 **/ 1348 EFI_STATUS 1349 NvmeSecuritySendReceive ( 1350 IN NVME_CONTEXT *Nvme, 1351 IN BOOLEAN SendCommand, 1352 IN UINT8 SecurityProtocol, 1353 IN UINT16 SpSpecific, 1354 IN UINTN TransferLength, 1355 IN OUT VOID *TransferBuffer 1356 ) 1357 { 1358 NVM_EXPRESS_PASS_THRU_COMMAND_PACKET CommandPacket; 1359 NVM_EXPRESS_COMMAND Command; 1360 NVM_EXPRESS_RESPONSE Response; 1361 EFI_STATUS Status; 1362 NVME_ADMIN_SECSEND SecSend; 1363 OACS *Oacs; 1364 UINT8 Opcode; 1365 VOID* *SecBuff; 1366 1367 Oacs = (OACS *)&Nvme->ControllerData->Oacs; 1368 1369 // 1370 // Verify security bit for Security Send/Receive commands 1371 // 1372 if (Oacs->Security == 0) { 1373 DEBUG ((DEBUG_ERROR, "Security command doesn't support.\n")); 1374 return EFI_NOT_READY; 1375 } 1376 1377 SecBuff = (VOID *)(UINTN) NVME_SEC_BASE (Nvme); 1378 1379 // 1380 // Actions for sending security command 1381 // 1382 if (SendCommand) { 1383 CopyMem (SecBuff, TransferBuffer, TransferLength); 1384 } 1385 1386 ZeroMem (&CommandPacket, sizeof(NVM_EXPRESS_PASS_THRU_COMMAND_PACKET)); 1387 ZeroMem (&Command, sizeof(NVM_EXPRESS_COMMAND)); 1388 ZeroMem (&Response, sizeof(NVM_EXPRESS_RESPONSE)); 1389 ZeroMem (&SecSend, sizeof(NVME_ADMIN_SECSEND)); 1390 1391 CommandPacket.NvmeCmd = &Command; 1392 CommandPacket.NvmeResponse = &Response; 1393 1394 Opcode = (UINT8)(SendCommand ? NVME_ADMIN_SECURITY_SEND_OPC : NVME_ADMIN_SECURITY_RECV_OPC); 1395 Command.Cdw0.Opcode = Opcode; 1396 Command.Cdw0.Cid = Nvme->Cid[NVME_ADMIN_QUEUE]++; 1397 CommandPacket.TransferBuffer = (UINT64)(UINTN)SecBuff; 1398 CommandPacket.TransferLength = (UINT32)TransferLength; 1399 CommandPacket.CommandTimeout = NVME_GENERIC_TIMEOUT; 1400 CommandPacket.QueueId = NVME_ADMIN_QUEUE; 1401 1402 SecSend.Spsp = SpSpecific; 1403 SecSend.Secp = SecurityProtocol; 1404 SecSend.Tl = (UINT32)TransferLength; 1405 1406 CopyMem (&CommandPacket.NvmeCmd->Cdw10, &SecSend, sizeof (NVME_ADMIN_SECSEND)); 1407 CommandPacket.NvmeCmd->Flags = CDW10_VALID | CDW11_VALID; 1408 1409 Status = NvmePassThru ( 1410 Nvme, 1411 NVME_CONTROLLER_ID, 1412 0, 1413 &CommandPacket 1414 ); 1415 if (!EFI_ERROR (Status)) { 1416 Status = NvmeWaitAllComplete (Nvme, CommandPacket.QueueId); 1417 } 1418 1419 // 1420 // Actions for receiving security command 1421 // 1422 if (!SendCommand) { 1423 CopyMem (TransferBuffer, SecBuff, TransferLength); 1424 } 1425 1426 return Status; 1427 } 1428 1429 /** 1430 Destroy io completion queue. 1431 1432 @param[in] Nvme - The pointer to the NVME_CONTEXT Data structure. 1433 1434 @return EFI_SUCCESS - Successfully destroy io completion queue. 1435 @return others - Fail to destroy io completion queue. 1436 1437 **/ 1438 STATIC 1439 EFI_STATUS 1440 NvmeDestroyIoCompletionQueue ( 1441 IN NVME_CONTEXT *Nvme 1442 ) 1443 { 1444 NVM_EXPRESS_PASS_THRU_COMMAND_PACKET CommandPacket; 1445 NVM_EXPRESS_COMMAND Command; 1446 NVM_EXPRESS_RESPONSE Response; 1447 EFI_STATUS Status; 1448 NVME_ADMIN_DEIOCQ DelIoCq; 1449 1450 ZeroMem (&CommandPacket, sizeof(NVM_EXPRESS_PASS_THRU_COMMAND_PACKET)); 1451 ZeroMem (&Command, sizeof(NVM_EXPRESS_COMMAND)); 1452 ZeroMem (&Response, sizeof(NVM_EXPRESS_RESPONSE)); 1453 ZeroMem (&DelIoCq, sizeof(NVME_ADMIN_DEIOCQ)); 1454 1455 CommandPacket.NvmeCmd = &Command; 1456 CommandPacket.NvmeResponse = &Response; 1457 1458 Command.Cdw0.Opcode = NVME_ADMIN_DELIOCQ_OPC; 1459 Command.Cdw0.Cid = Nvme->Cid[NVME_ADMIN_QUEUE]++; 1460 CommandPacket.TransferBuffer = (UINT64)(UINTN)Nvme->CqBuffer[NVME_IO_QUEUE]; 1461 CommandPacket.TransferLength = EFI_PAGE_SIZE; 1462 CommandPacket.CommandTimeout = NVME_GENERIC_TIMEOUT; 1463 CommandPacket.QueueId = NVME_ADMIN_QUEUE; 1464 1465 DelIoCq.Qid = NVME_IO_QUEUE; 1466 CopyMem (&CommandPacket.NvmeCmd->Cdw10, &DelIoCq, sizeof (NVME_ADMIN_DEIOCQ)); 1467 CommandPacket.NvmeCmd->Flags = CDW10_VALID | CDW11_VALID; 1468 1469 Status = NvmePassThru ( 1470 Nvme, 1471 NVME_CONTROLLER_ID, 1472 0, 1473 &CommandPacket 1474 ); 1475 if (!EFI_ERROR (Status)) { 1476 Status = NvmeWaitAllComplete (Nvme, CommandPacket.QueueId); 1477 } 1478 1479 return Status; 1480 } 1481 1482 /** 1483 Destroy io submission queue. 1484 1485 @param[in] Nvme - The pointer to the NVME_CONTEXT Data structure. 1486 1487 @return EFI_SUCCESS - Successfully destroy io submission queue. 1488 @return others - Fail to destroy io submission queue. 1489 1490 **/ 1491 STATIC 1492 EFI_STATUS 1493 NvmeDestroyIoSubmissionQueue ( 1494 IN NVME_CONTEXT *Nvme 1495 ) 1496 { 1497 NVM_EXPRESS_PASS_THRU_COMMAND_PACKET CommandPacket; 1498 NVM_EXPRESS_COMMAND Command; 1499 NVM_EXPRESS_RESPONSE Response; 1500 EFI_STATUS Status; 1501 NVME_ADMIN_DEIOSQ DelIoSq; 1502 1503 ZeroMem (&CommandPacket, sizeof(NVM_EXPRESS_PASS_THRU_COMMAND_PACKET)); 1504 ZeroMem (&Command, sizeof(NVM_EXPRESS_COMMAND)); 1505 ZeroMem (&Response, sizeof(NVM_EXPRESS_RESPONSE)); 1506 ZeroMem (&DelIoSq, sizeof(NVME_ADMIN_DEIOSQ)); 1507 1508 CommandPacket.NvmeCmd = &Command; 1509 CommandPacket.NvmeResponse = &Response; 1510 1511 Command.Cdw0.Opcode = NVME_ADMIN_DELIOSQ_OPC; 1512 Command.Cdw0.Cid = Nvme->Cid[NVME_ADMIN_QUEUE]++; 1513 CommandPacket.TransferBuffer = (UINT64)(UINTN)Nvme->SqBuffer[NVME_IO_QUEUE]; 1514 CommandPacket.TransferLength = EFI_PAGE_SIZE; 1515 CommandPacket.CommandTimeout = NVME_GENERIC_TIMEOUT; 1516 CommandPacket.QueueId = NVME_ADMIN_QUEUE; 1517 1518 DelIoSq.Qid = NVME_IO_QUEUE; 1519 CopyMem (&CommandPacket.NvmeCmd->Cdw10, &DelIoSq, sizeof (NVME_ADMIN_DEIOSQ)); 1520 CommandPacket.NvmeCmd->Flags = CDW10_VALID | CDW11_VALID; 1521 1522 Status = NvmePassThru ( 1523 Nvme, 1524 NVME_CONTROLLER_ID, 1525 0, 1526 &CommandPacket 1527 ); 1528 if (!EFI_ERROR (Status)) { 1529 Status = NvmeWaitAllComplete (Nvme, CommandPacket.QueueId); 1530 } 1531 1532 return Status; 1533 } 1534 1535 /** 1536 Allocate transfer-related Data struct which is used at Nvme. 1537 1538 @param[in] ImageHandle Image handle for this driver image 1539 @param[in] Nvme The pointer to the NVME_CONTEXT Data structure. 1540 1541 @retval EFI_OUT_OF_RESOURCE The allocation is failure. 1542 @retval EFI_SUCCESS Successful to allocate memory. 1543 1544 **/ 1545 EFI_STATUS 1546 EFIAPI 1547 NvmeAllocateResource ( 1548 IN EFI_HANDLE ImageHandle, 1549 IN NVME_CONTEXT *Nvme 1550 ) 1551 { 1552 EFI_STATUS Status; 1553 EFI_PHYSICAL_ADDRESS Addr; 1554 UINT32 Size; 1555 1556 // 1557 // Allocate resources required by NVMe host controller. 1558 // 1559 // NBAR 1560 Size = 0x10000; 1561 Addr = 0xFFFFFFFF; 1562 Status = gDS->AllocateMemorySpace ( 1563 EfiGcdAllocateMaxAddressSearchBottomUp, 1564 EfiGcdMemoryTypeMemoryMappedIo, 1565 15, // 2^15: 32K Alignment 1566 Size, 1567 &Addr, 1568 ImageHandle, 1569 NULL 1570 ); 1571 if (EFI_ERROR (Status)) { 1572 return EFI_OUT_OF_RESOURCES; 1573 } 1574 Nvme->Nbar = (UINT32) Addr; 1575 1576 // DMA Buffer 1577 Size = NVME_MEM_MAX_SIZE; 1578 Addr = 0xFFFFFFFF; 1579 Status = gBS->AllocatePages ( 1580 AllocateMaxAddress, 1581 EfiACPIMemoryNVS, 1582 EFI_SIZE_TO_PAGES (Size), 1583 (EFI_PHYSICAL_ADDRESS *)&Addr 1584 ); 1585 if (EFI_ERROR (Status)) { 1586 return EFI_OUT_OF_RESOURCES; 1587 } 1588 Nvme->BaseMem = (UINT32) Addr; 1589 1590 // Clean up DMA Buffer before using 1591 ZeroMem ((VOID *)(UINTN)Addr, NVME_MEM_MAX_SIZE); 1592 1593 return EFI_SUCCESS; 1594 } 1595 1596 /** 1597 Free allocated transfer-related Data struct which is used at NVMe. 1598 1599 @param[in] Nvme The pointer to the NVME_CONTEXT Data structure. 1600 1601 **/ 1602 VOID 1603 EFIAPI 1604 NvmeFreeResource ( 1605 IN NVME_CONTEXT *Nvme 1606 ) 1607 { 1608 UINT32 Size; 1609 1610 // NBAR 1611 if (Nvme->BaseMem != 0) { 1612 Size = 0x10000; 1613 gDS->FreeMemorySpace (Nvme->Nbar, Size); 1614 } 1615 1616 // DMA Buffer 1617 if (Nvme->Nbar != 0) { 1618 Size = NVME_MEM_MAX_SIZE; 1619 gBS->FreePages ((EFI_PHYSICAL_ADDRESS)(UINTN) Nvme->Nbar, EFI_SIZE_TO_PAGES (Size)); 1620 } 1621 } 1622 1623 1624 /** 1625 Initialize the Nvm Express controller. 1626 1627 @param[in] Nvme - The pointer to the NVME_CONTEXT Data structure. 1628 1629 @retval EFI_SUCCESS - The NVM Express Controller is initialized successfully. 1630 @retval Others - A device error occurred while initializing the controller. 1631 1632 **/ 1633 EFI_STATUS 1634 NvmeControllerInit ( 1635 IN NVME_CONTEXT *Nvme 1636 ) 1637 { 1638 EFI_STATUS Status; 1639 NVME_AQA Aqa; 1640 NVME_ASQ Asq; 1641 NVME_ACQ Acq; 1642 NVME_VER Ver; 1643 1644 UINT32 MlBAR; 1645 UINT32 MuBAR; 1646 1647 /// 1648 /// Update PCIE BAR0/1 for NVME device 1649 /// 1650 MlBAR = Nvme->Nbar; 1651 MuBAR = 0; 1652 PciWrite32 (Nvme->PciBase + 0x10, MlBAR); // MLBAR (BAR0) 1653 PciWrite32 (Nvme->PciBase + 0x14, MuBAR); // MUBAR (BAR1) 1654 1655 /// 1656 /// Enable PCIE decode 1657 /// 1658 PciWrite8 (Nvme->PciBase + NVME_PCIE_PCICMD, 0x6); 1659 1660 // Version 1661 NVME_GET_VER (Nvme, &Ver); 1662 if (!(Ver.Mjr == 0x0001) && (Ver.Mnr == 0x0000)) { 1663 DEBUG ((DEBUG_INFO, "\n!!!\n!!! NVME Version mismatch for the implementation !!!\n!!!\n")); 1664 } 1665 1666 /// 1667 /// Read the Controller Capabilities register and verify that the NVM command set is supported 1668 /// 1669 Status = NVME_GET_CAP (Nvme, &Nvme->Cap); 1670 if (EFI_ERROR (Status)) { 1671 DEBUG ((DEBUG_ERROR, "NVME_GET_CAP fail, Status: %r\n", Status)); 1672 goto Done; 1673 } 1674 1675 if (Nvme->Cap.Css != 0x01) { 1676 DEBUG ((DEBUG_ERROR, "NvmeControllerInit fail: the controller doesn't support NVMe command set\n")); 1677 Status = EFI_UNSUPPORTED; 1678 goto Done; 1679 } 1680 1681 /// 1682 /// Currently the driver only supports 4k page Size. 1683 /// 1684 if ((Nvme->Cap.Mpsmin + 12) > EFI_PAGE_SHIFT) { 1685 DEBUG ((DEBUG_ERROR, "NvmeControllerInit fail: only supports 4k page Size\n")); 1686 ASSERT (FALSE); 1687 Status = EFI_UNSUPPORTED; 1688 goto Done; 1689 } 1690 1691 Nvme->Cid[0] = 0; 1692 Nvme->Cid[1] = 0; 1693 1694 Nvme->Pt[0] = 0; 1695 Nvme->Pt[1] = 0; 1696 1697 ZeroMem ((VOID *)(UINTN)(&(Nvme->SqTdbl[0])), sizeof (NVME_SQTDBL) * NVME_MAX_IO_QUEUES); 1698 ZeroMem ((VOID *)(UINTN)(&(Nvme->CqHdbl[0])), sizeof (NVME_CQHDBL) * NVME_MAX_IO_QUEUES); 1699 1700 ZeroMem ((VOID *)(UINTN)Nvme->BaseMem, NVME_MEM_MAX_SIZE); 1701 1702 Status = NvmeDisableController (Nvme); 1703 if (EFI_ERROR(Status)) { 1704 DEBUG ((DEBUG_ERROR, "NvmeDisableController fail, Status: %r\n", Status)); 1705 goto Done; 1706 } 1707 1708 /// 1709 /// set number of entries admin submission & completion queues. 1710 /// 1711 Aqa.Asqs = NVME_ASQ_SIZE; 1712 Aqa.Rsvd1 = 0; 1713 Aqa.Acqs = NVME_ACQ_SIZE; 1714 Aqa.Rsvd2 = 0; 1715 1716 /// 1717 /// Address of admin submission queue. 1718 /// 1719 Asq = (UINT64)(UINTN)(NVME_ASQ_BASE (Nvme) & ~0xFFF); 1720 1721 /// 1722 /// Address of admin completion queue. 1723 /// 1724 Acq = (UINT64)(UINTN)(NVME_ACQ_BASE (Nvme) & ~0xFFF); 1725 1726 /// 1727 /// Address of I/O submission & completion queue. 1728 /// 1729 Nvme->SqBuffer[0] = (NVME_SQ *)(UINTN)NVME_ASQ_BASE (Nvme); // NVME_ADMIN_QUEUE 1730 Nvme->CqBuffer[0] = (NVME_CQ *)(UINTN)NVME_ACQ_BASE (Nvme); // NVME_ADMIN_QUEUE 1731 Nvme->SqBuffer[1] = (NVME_SQ *)(UINTN)NVME_SQ_BASE (Nvme, 0); // NVME_IO_QUEUE 1732 Nvme->CqBuffer[1] = (NVME_CQ *)(UINTN)NVME_CQ_BASE (Nvme, 0); // NVME_IO_QUEUE 1733 1734 DEBUG ((DEBUG_INFO, "BaseMem = [%08X]\n", Nvme->BaseMem)); 1735 DEBUG ((DEBUG_INFO, "Admin Submission Queue Size (Aqa.Asqs) = [%08X]\n", Aqa.Asqs)); 1736 DEBUG ((DEBUG_INFO, "Admin Completion Queue Size (Aqa.Acqs) = [%08X]\n", Aqa.Acqs)); 1737 DEBUG ((DEBUG_INFO, "Admin Submission Queue (SqBuffer[0]) = [%08X]\n", Nvme->SqBuffer[0])); 1738 DEBUG ((DEBUG_INFO, "Admin Completion Queue (CqBuffer[0]) = [%08X]\n", Nvme->CqBuffer[0])); 1739 DEBUG ((DEBUG_INFO, "I/O Submission Queue (SqBuffer[1]) = [%08X]\n", Nvme->SqBuffer[1])); 1740 DEBUG ((DEBUG_INFO, "I/O Completion Queue (CqBuffer[1]) = [%08X]\n", Nvme->CqBuffer[1])); 1741 1742 /// 1743 /// Program admin queue attributes. 1744 /// 1745 Status = NVME_SET_AQA (Nvme, &Aqa); 1746 if (EFI_ERROR(Status)) { 1747 goto Done; 1748 } 1749 1750 /// 1751 /// Program admin submission queue address. 1752 /// 1753 Status = NVME_SET_ASQ (Nvme, &Asq); 1754 if (EFI_ERROR(Status)) { 1755 goto Done; 1756 } 1757 1758 /// 1759 /// Program admin completion queue address. 1760 /// 1761 Status = NVME_SET_ACQ (Nvme, &Acq); 1762 if (EFI_ERROR(Status)) { 1763 goto Done; 1764 } 1765 1766 Status = NvmeEnableController (Nvme); 1767 if (EFI_ERROR(Status)) { 1768 goto Done; 1769 } 1770 1771 /// 1772 /// Create one I/O completion queue. 1773 /// 1774 Status = NvmeCreateIoCompletionQueue (Nvme); 1775 if (EFI_ERROR(Status)) { 1776 goto Done; 1777 } 1778 1779 /// 1780 /// Create one I/O Submission queue. 1781 /// 1782 Status = NvmeCreateIoSubmissionQueue (Nvme); 1783 if (EFI_ERROR(Status)) { 1784 goto Done; 1785 } 1786 1787 /// 1788 /// Get current Identify Controller Data 1789 /// 1790 Nvme->ControllerData = (NVME_ADMIN_CONTROLLER_DATA *)(UINTN) NVME_CONTROL_DATA_BASE (Nvme); 1791 Status = NvmeIdentifyController (Nvme, Nvme->ControllerData); 1792 if (EFI_ERROR(Status)) { 1793 goto Done; 1794 } 1795 1796 /// 1797 /// Dump NvmExpress Identify Controller Data 1798 /// 1799 Nvme->ControllerData->Sn[19] = 0; 1800 Nvme->ControllerData->Mn[39] = 0; 1801 //NvmeDumpIdentifyController (Nvme->ControllerData); 1802 1803 /// 1804 /// Get current Identify Namespace Data 1805 /// 1806 Nvme->NamespaceData = (NVME_ADMIN_NAMESPACE_DATA *)NVME_NAMESPACE_DATA_BASE (Nvme); 1807 Status = NvmeIdentifyNamespace (Nvme, Nvme->Nsid, Nvme->NamespaceData); 1808 if (EFI_ERROR(Status)) { 1809 DEBUG ((DEBUG_ERROR, "NvmeIdentifyNamespace fail, Status = %r\n", Status)); 1810 goto Done; 1811 } 1812 1813 /// 1814 /// Dump NvmExpress Identify Namespace Data 1815 /// 1816 if (Nvme->NamespaceData->Ncap == 0) { 1817 DEBUG ((DEBUG_ERROR, "Invalid Namespace, Ncap: %lx\n", Nvme->NamespaceData->Ncap)); 1818 Status = EFI_DEVICE_ERROR; 1819 goto Done; 1820 } 1821 1822 Nvme->BlockSize = NvmeGetBlockSize (Nvme); 1823 Nvme->LastBlock = NvmeGetLastLba (Nvme); 1824 1825 Nvme->State = NvmeStatusInit; 1826 1827 return EFI_SUCCESS; 1828 1829 Done: 1830 return Status; 1831 } 1832 1833 /** 1834 Un-initialize the Nvm Express controller. 1835 1836 @param[in] Nvme - The pointer to the NVME_CONTEXT Data structure. 1837 1838 @retval EFI_SUCCESS - The NVM Express Controller is un-initialized successfully. 1839 @retval Others - A device error occurred while un-initializing the controller. 1840 1841 **/ 1842 EFI_STATUS 1843 NvmeControllerExit ( 1844 IN NVME_CONTEXT *Nvme 1845 ) 1846 { 1847 EFI_STATUS Status; 1848 1849 Status = EFI_SUCCESS; 1850 if (Nvme->State == NvmeStatusInit || Nvme->State == NvmeStatusMax) { 1851 /// 1852 /// Destroy I/O Submission queue. 1853 /// 1854 Status = NvmeDestroyIoSubmissionQueue (Nvme); 1855 if (EFI_ERROR(Status)) { 1856 DEBUG ((DEBUG_ERROR, "NvmeDestroyIoSubmissionQueue fail, Status = %r\n", Status)); 1857 return Status; 1858 } 1859 1860 /// 1861 /// Destroy I/O completion queue. 1862 /// 1863 Status = NvmeDestroyIoCompletionQueue (Nvme); 1864 if (EFI_ERROR(Status)) { 1865 DEBUG ((DEBUG_ERROR, "NvmeDestroyIoCompletionQueue fail, Status = %r\n", Status)); 1866 return Status; 1867 } 1868 1869 Status = NvmeShutdownController (Nvme); 1870 if (EFI_ERROR(Status)) { 1871 DEBUG ((DEBUG_ERROR, "NvmeShutdownController fail, Status: %r\n", Status)); 1872 } 1873 } 1874 1875 /// 1876 /// Disable PCIE decode 1877 /// 1878 PciWrite8 (Nvme->PciBase + NVME_PCIE_PCICMD, 0x0); 1879 PciWrite32 (Nvme->PciBase + 0x10, 0); // MLBAR (BAR0) 1880 PciWrite32 (Nvme->PciBase + 0x14, 0); // MUBAR (BAR1) 1881 1882 Nvme->State = NvmeStatusUnknown; 1883 return Status; 1884 } 1885 1886 /** 1887 Read sector Data from the NVMe device. 1888 1889 @param[in] Nvme - The pointer to the NVME_CONTEXT Data structure. 1890 @param[in,out] Buffer - The Buffer used to store the Data read from the device. 1891 @param[in] Lba - The start block number. 1892 @param[in] Blocks - Total block number to be read. 1893 1894 @retval EFI_SUCCESS - Datum are read from the device. 1895 @retval Others - Fail to read all the datum. 1896 1897 **/ 1898 EFI_STATUS 1899 NvmeReadSectors ( 1900 IN NVME_CONTEXT *Nvme, 1901 IN OUT UINT64 Buffer, 1902 IN UINT64 Lba, 1903 IN UINT32 Blocks 1904 ) 1905 { 1906 UINT32 Bytes; 1907 NVM_EXPRESS_PASS_THRU_COMMAND_PACKET CommandPacket; 1908 NVM_EXPRESS_COMMAND Command; 1909 NVM_EXPRESS_RESPONSE Response; 1910 EFI_STATUS Status; 1911 UINT32 BlockSize; 1912 1913 BlockSize = Nvme->BlockSize; 1914 Bytes = Blocks * BlockSize; 1915 1916 ZeroMem (&CommandPacket, sizeof(NVM_EXPRESS_PASS_THRU_COMMAND_PACKET)); 1917 ZeroMem (&Command, sizeof(NVM_EXPRESS_COMMAND)); 1918 ZeroMem (&Response, sizeof(NVM_EXPRESS_RESPONSE)); 1919 1920 CommandPacket.NvmeCmd = &Command; 1921 CommandPacket.NvmeResponse = &Response; 1922 1923 CommandPacket.NvmeCmd->Cdw0.Opcode = NVME_IO_READ_OPC; 1924 CommandPacket.NvmeCmd->Cdw0.Cid = Nvme->Cid[NVME_IO_QUEUE]++; 1925 CommandPacket.NvmeCmd->Nsid = Nvme->Nsid; 1926 CommandPacket.TransferBuffer = Buffer; 1927 1928 CommandPacket.TransferLength = Bytes; 1929 CommandPacket.CommandTimeout = NVME_GENERIC_TIMEOUT; 1930 CommandPacket.QueueId = NVME_IO_QUEUE; 1931 1932 CommandPacket.NvmeCmd->Cdw10 = (UINT32)Lba; 1933 CommandPacket.NvmeCmd->Cdw11 = (UINT32)(RShiftU64 (Lba, 32)); 1934 CommandPacket.NvmeCmd->Cdw12 = (Blocks - 1) & 0xFFFF; 1935 1936 CommandPacket.NvmeCmd->Flags = CDW10_VALID | CDW11_VALID | CDW12_VALID; 1937 1938 Status = NvmePassThru ( 1939 Nvme, 1940 Nvme->Nsid, 1941 0, 1942 &CommandPacket 1943 ); 1944 1945 return Status; 1946 } 1947 1948 /** 1949 Write sector Data to the NVMe device. 1950 1951 @param[in] Nvme - The pointer to the NVME_CONTEXT Data structure. 1952 @param[in] Buffer - The Buffer to be written into the device. 1953 @param[in] Lba - The start block number. 1954 @param[in] Blocks - Total block number to be written. 1955 1956 @retval EFI_SUCCESS - Datum are written into the Buffer. 1957 @retval Others - Fail to write all the datum. 1958 1959 **/ 1960 EFI_STATUS 1961 NvmeWriteSectors ( 1962 IN NVME_CONTEXT *Nvme, 1963 IN UINT64 Buffer, 1964 IN UINT64 Lba, 1965 IN UINT32 Blocks 1966 ) 1967 { 1968 NVM_EXPRESS_PASS_THRU_COMMAND_PACKET CommandPacket; 1969 NVM_EXPRESS_COMMAND Command; 1970 NVM_EXPRESS_RESPONSE Response; 1971 EFI_STATUS Status; 1972 UINT32 Bytes; 1973 UINT32 BlockSize; 1974 1975 BlockSize = Nvme->BlockSize; 1976 Bytes = Blocks * BlockSize; 1977 1978 ZeroMem (&CommandPacket, sizeof(NVM_EXPRESS_PASS_THRU_COMMAND_PACKET)); 1979 ZeroMem (&Command, sizeof(NVM_EXPRESS_COMMAND)); 1980 ZeroMem (&Response, sizeof(NVM_EXPRESS_RESPONSE)); 1981 1982 CommandPacket.NvmeCmd = &Command; 1983 CommandPacket.NvmeResponse = &Response; 1984 1985 CommandPacket.NvmeCmd->Cdw0.Opcode = NVME_IO_WRITE_OPC; 1986 CommandPacket.NvmeCmd->Cdw0.Cid = Nvme->Cid[NVME_IO_QUEUE]++; 1987 CommandPacket.NvmeCmd->Nsid = Nvme->Nsid; 1988 CommandPacket.TransferBuffer = Buffer; 1989 1990 CommandPacket.TransferLength = Bytes; 1991 CommandPacket.CommandTimeout = NVME_GENERIC_TIMEOUT; 1992 CommandPacket.QueueId = NVME_IO_QUEUE; 1993 1994 CommandPacket.NvmeCmd->Cdw10 = (UINT32)Lba; 1995 CommandPacket.NvmeCmd->Cdw11 = (UINT32)(RShiftU64 (Lba, 32)); 1996 CommandPacket.NvmeCmd->Cdw12 = (Blocks - 1) & 0xFFFF; 1997 1998 CommandPacket.MetadataBuffer = (UINT64)(UINTN)NULL; 1999 CommandPacket.MetadataLength = 0; 2000 2001 CommandPacket.NvmeCmd->Flags = CDW10_VALID | CDW11_VALID | CDW12_VALID; 2002 2003 Status = NvmePassThru ( 2004 Nvme, 2005 Nvme->Nsid, 2006 0, 2007 &CommandPacket 2008 ); 2009 2010 return Status; 2011 } 2012 2013 /** 2014 Flushes all modified Data to the device. 2015 2016 @param[in] Nvme - The pointer to the NVME_CONTEXT Data structure. 2017 2018 @retval EFI_SUCCESS - Datum are written into the Buffer. 2019 @retval Others - Fail to write all the datum. 2020 2021 **/ 2022 EFI_STATUS 2023 NvmeFlush ( 2024 IN NVME_CONTEXT *Nvme 2025 ) 2026 { 2027 NVM_EXPRESS_PASS_THRU_COMMAND_PACKET CommandPacket; 2028 NVM_EXPRESS_COMMAND Command; 2029 NVM_EXPRESS_RESPONSE Response; 2030 EFI_STATUS Status; 2031 2032 ZeroMem (&CommandPacket, sizeof(NVM_EXPRESS_PASS_THRU_COMMAND_PACKET)); 2033 ZeroMem (&Command, sizeof(NVM_EXPRESS_COMMAND)); 2034 ZeroMem (&Response, sizeof(NVM_EXPRESS_RESPONSE)); 2035 2036 CommandPacket.NvmeCmd = &Command; 2037 CommandPacket.NvmeResponse = &Response; 2038 2039 CommandPacket.NvmeCmd->Cdw0.Opcode = NVME_IO_FLUSH_OPC; 2040 CommandPacket.NvmeCmd->Cdw0.Cid = Nvme->Cid[NVME_IO_QUEUE]++; 2041 CommandPacket.NvmeCmd->Nsid = Nvme->Nsid; 2042 CommandPacket.CommandTimeout = NVME_GENERIC_TIMEOUT; 2043 CommandPacket.QueueId = NVME_IO_QUEUE; 2044 2045 Status = NvmePassThru ( 2046 Nvme, 2047 Nvme->Nsid, 2048 0, 2049 &CommandPacket 2050 ); 2051 if (!EFI_ERROR (Status)) { 2052 Status = NvmeWaitAllComplete (Nvme, CommandPacket.QueueId); 2053 } 2054 2055 return Status; 2056 } 2057 2058 /** 2059 Read some blocks from the device. 2060 2061 @param[in] Nvme - The pointer to the NVME_CONTEXT Data structure. 2062 @param[out] Buffer - The Buffer used to store the Data read from the device. 2063 @param[in] Lba - The start block number. 2064 @param[in] Blocks - Total block number to be read. 2065 2066 @retval EFI_SUCCESS - Datum are read from the device. 2067 @retval Others - Fail to read all the datum. 2068 2069 **/ 2070 EFI_STATUS 2071 NvmeRead ( 2072 IN NVME_CONTEXT *Nvme, 2073 OUT UINT64 Buffer, 2074 IN UINT64 Lba, 2075 IN UINTN Blocks 2076 ) 2077 { 2078 EFI_STATUS Status; 2079 UINT32 BlockSize; 2080 UINT32 MaxTransferBlocks; 2081 2082 ASSERT (Blocks <= NVME_MAX_SECTORS); 2083 Status = EFI_SUCCESS; 2084 BlockSize = Nvme->BlockSize; 2085 if (Nvme->ControllerData->Mdts != 0) { 2086 MaxTransferBlocks = (1 << (Nvme->ControllerData->Mdts)) * (1 << (Nvme->Cap.Mpsmin + 12)) / BlockSize; 2087 } else { 2088 MaxTransferBlocks = 1024; 2089 } 2090 2091 while (Blocks > 0) { 2092 if (Blocks > MaxTransferBlocks) { 2093 Status = NvmeReadSectors (Nvme, Buffer, Lba, MaxTransferBlocks); 2094 2095 Blocks -= MaxTransferBlocks; 2096 Buffer += (MaxTransferBlocks * BlockSize); 2097 Lba += MaxTransferBlocks; 2098 } else { 2099 Status = NvmeReadSectors (Nvme, Buffer, Lba, (UINT32) Blocks); 2100 Blocks = 0; 2101 } 2102 2103 if (EFI_ERROR(Status)) { 2104 DEBUG ((DEBUG_ERROR, "NvmeRead fail, Status = %r\n", Status)); 2105 break; 2106 } 2107 } 2108 2109 return Status; 2110 } 2111 2112 /** 2113 Write some blocks to the device. 2114 2115 @param[in] Nvme - The pointer to the NVME_CONTEXT Data structure. 2116 @param[in] Buffer - The Buffer to be written into the device. 2117 @param[in] Lba - The start block number. 2118 @param[in] Blocks - Total block number to be written. 2119 2120 @retval EFI_SUCCESS - Datum are written into the Buffer. 2121 @retval Others - Fail to write all the datum. 2122 2123 **/ 2124 EFI_STATUS 2125 NvmeWrite ( 2126 IN NVME_CONTEXT *Nvme, 2127 IN UINT64 Buffer, 2128 IN UINT64 Lba, 2129 IN UINTN Blocks 2130 ) 2131 { 2132 EFI_STATUS Status; 2133 UINT32 BlockSize; 2134 UINT32 MaxTransferBlocks; 2135 2136 ASSERT (Blocks <= NVME_MAX_SECTORS); 2137 Status = EFI_SUCCESS; 2138 BlockSize = Nvme->BlockSize; 2139 2140 if (Nvme->ControllerData->Mdts != 0) { 2141 MaxTransferBlocks = (1 << (Nvme->ControllerData->Mdts)) * (1 << (Nvme->Cap.Mpsmin + 12)) / BlockSize; 2142 } else { 2143 MaxTransferBlocks = 1024; 2144 } 2145 2146 while (Blocks > 0) { 2147 if (Blocks > MaxTransferBlocks) { 2148 Status = NvmeWriteSectors (Nvme, Buffer, Lba, MaxTransferBlocks); 2149 2150 Blocks -= MaxTransferBlocks; 2151 Buffer += (MaxTransferBlocks * BlockSize); 2152 Lba += MaxTransferBlocks; 2153 } else { 2154 Status = NvmeWriteSectors (Nvme, Buffer, Lba, (UINT32) Blocks); 2155 Blocks = 0; 2156 } 2157 2158 if (EFI_ERROR(Status)) { 2159 DEBUG ((DEBUG_ERROR, "NvmeWrite fail, Status = %r\n", Status)); 2160 break; 2161 } 2162 } 2163 2164 return Status; 2165 } 2166