1 /* 2 * This is the Fusion MPT base driver providing common API layer interface 3 * for access to MPT (Message Passing Technology) firmware. 4 * 5 * This code is based on drivers/scsi/mpt3sas/mpt3sas_base.c 6 * Copyright (C) 2012-2014 LSI Corporation 7 * Copyright (C) 2013-2014 Avago Technologies 8 * (mailto: MPT-FusionLinux.pdl@avagotech.com) 9 * 10 * This program is free software; you can redistribute it and/or 11 * modify it under the terms of the GNU General Public License 12 * as published by the Free Software Foundation; either version 2 13 * of the License, or (at your option) any later version. 14 * 15 * This program is distributed in the hope that it will be useful, 16 * but WITHOUT ANY WARRANTY; without even the implied warranty of 17 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the 18 * GNU General Public License for more details. 19 * 20 * NO WARRANTY 21 * THE PROGRAM IS PROVIDED ON AN "AS IS" BASIS, WITHOUT WARRANTIES OR 22 * CONDITIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED INCLUDING, WITHOUT 23 * LIMITATION, ANY WARRANTIES OR CONDITIONS OF TITLE, NON-INFRINGEMENT, 24 * MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. Each Recipient is 25 * solely responsible for determining the appropriateness of using and 26 * distributing the Program and assumes all risks associated with its 27 * exercise of rights under this Agreement, including but not limited to 28 * the risks and costs of program errors, damage to or loss of data, 29 * programs or equipment, and unavailability or interruption of operations. 30 31 * DISCLAIMER OF LIABILITY 32 * NEITHER RECIPIENT NOR ANY CONTRIBUTORS SHALL HAVE ANY LIABILITY FOR ANY 33 * DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL 34 * DAMAGES (INCLUDING WITHOUT LIMITATION LOST PROFITS), HOWEVER CAUSED AND 35 * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR 36 * TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE 37 * USE OR DISTRIBUTION OF THE PROGRAM OR THE EXERCISE OF ANY RIGHTS GRANTED 38 * HEREUNDER, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGES 39 40 * You should have received a copy of the GNU General Public License 41 * along with this program; if not, write to the Free Software 42 * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, 43 * USA. 44 */ 45 46 #include <linux/kernel.h> 47 #include <linux/module.h> 48 #include <linux/errno.h> 49 #include <linux/init.h> 50 #include <linux/slab.h> 51 #include <linux/types.h> 52 #include <linux/pci.h> 53 #include <linux/kdev_t.h> 54 #include <linux/blkdev.h> 55 #include <linux/delay.h> 56 #include <linux/interrupt.h> 57 #include <linux/dma-mapping.h> 58 #include <linux/io.h> 59 #include <linux/time.h> 60 #include <linux/ktime.h> 61 #include <linux/kthread.h> 62 #include <asm/page.h> /* To get host page size per arch */ 63 #include <linux/aer.h> 64 65 66 #include "mpt3sas_base.h" 67 68 static MPT_CALLBACK mpt_callbacks[MPT_MAX_CALLBACKS]; 69 70 71 #define FAULT_POLLING_INTERVAL 1000 /* in milliseconds */ 72 73 /* maximum controller queue depth */ 74 #define MAX_HBA_QUEUE_DEPTH 30000 75 #define MAX_CHAIN_DEPTH 100000 76 static int max_queue_depth = -1; 77 module_param(max_queue_depth, int, 0444); 78 MODULE_PARM_DESC(max_queue_depth, " max controller queue depth "); 79 80 static int max_sgl_entries = -1; 81 module_param(max_sgl_entries, int, 0444); 82 MODULE_PARM_DESC(max_sgl_entries, " max sg entries "); 83 84 static int msix_disable = -1; 85 module_param(msix_disable, int, 0444); 86 MODULE_PARM_DESC(msix_disable, " disable msix routed interrupts (default=0)"); 87 88 static int smp_affinity_enable = 1; 89 module_param(smp_affinity_enable, int, 0444); 90 MODULE_PARM_DESC(smp_affinity_enable, "SMP affinity feature enable/disable Default: enable(1)"); 91 92 static int max_msix_vectors = -1; 93 module_param(max_msix_vectors, int, 0444); 94 MODULE_PARM_DESC(max_msix_vectors, 95 " max msix vectors"); 96 97 static int irqpoll_weight = -1; 98 module_param(irqpoll_weight, int, 0444); 99 MODULE_PARM_DESC(irqpoll_weight, 100 "irq poll weight (default= one fourth of HBA queue depth)"); 101 102 static int mpt3sas_fwfault_debug; 103 MODULE_PARM_DESC(mpt3sas_fwfault_debug, 104 " enable detection of firmware fault and halt firmware - (default=0)"); 105 106 static int perf_mode = -1; 107 module_param(perf_mode, int, 0444); 108 MODULE_PARM_DESC(perf_mode, 109 "Performance mode (only for Aero/Sea Generation), options:\n\t\t" 110 "0 - balanced: high iops mode is enabled &\n\t\t" 111 "interrupt coalescing is enabled only on high iops queues,\n\t\t" 112 "1 - iops: high iops mode is disabled &\n\t\t" 113 "interrupt coalescing is enabled on all queues,\n\t\t" 114 "2 - latency: high iops mode is disabled &\n\t\t" 115 "interrupt coalescing is enabled on all queues with timeout value 0xA,\n" 116 "\t\tdefault - default perf_mode is 'balanced'" 117 ); 118 119 static int poll_queues; 120 module_param(poll_queues, int, 0444); 121 MODULE_PARM_DESC(poll_queues, "Number of queues to be use for io_uring poll mode.\n\t\t" 122 "This parameter is effective only if host_tagset_enable=1. &\n\t\t" 123 "when poll_queues are enabled then &\n\t\t" 124 "perf_mode is set to latency mode. &\n\t\t" 125 ); 126 127 enum mpt3sas_perf_mode { 128 MPT_PERF_MODE_DEFAULT = -1, 129 MPT_PERF_MODE_BALANCED = 0, 130 MPT_PERF_MODE_IOPS = 1, 131 MPT_PERF_MODE_LATENCY = 2, 132 }; 133 134 static int 135 _base_wait_on_iocstate(struct MPT3SAS_ADAPTER *ioc, 136 u32 ioc_state, int timeout); 137 static int 138 _base_get_ioc_facts(struct MPT3SAS_ADAPTER *ioc); 139 static void 140 _base_clear_outstanding_commands(struct MPT3SAS_ADAPTER *ioc); 141 142 /** 143 * mpt3sas_base_check_cmd_timeout - Function 144 * to check timeout and command termination due 145 * to Host reset. 146 * 147 * @ioc: per adapter object. 148 * @status: Status of issued command. 149 * @mpi_request:mf request pointer. 150 * @sz: size of buffer. 151 * 152 * Return: 1/0 Reset to be done or Not 153 */ 154 u8 155 mpt3sas_base_check_cmd_timeout(struct MPT3SAS_ADAPTER *ioc, 156 u8 status, void *mpi_request, int sz) 157 { 158 u8 issue_reset = 0; 159 160 if (!(status & MPT3_CMD_RESET)) 161 issue_reset = 1; 162 163 ioc_err(ioc, "Command %s\n", 164 issue_reset == 0 ? "terminated due to Host Reset" : "Timeout"); 165 _debug_dump_mf(mpi_request, sz); 166 167 return issue_reset; 168 } 169 170 /** 171 * _scsih_set_fwfault_debug - global setting of ioc->fwfault_debug. 172 * @val: ? 173 * @kp: ? 174 * 175 * Return: ? 176 */ 177 static int 178 _scsih_set_fwfault_debug(const char *val, const struct kernel_param *kp) 179 { 180 int ret = param_set_int(val, kp); 181 struct MPT3SAS_ADAPTER *ioc; 182 183 if (ret) 184 return ret; 185 186 /* global ioc spinlock to protect controller list on list operations */ 187 pr_info("setting fwfault_debug(%d)\n", mpt3sas_fwfault_debug); 188 spin_lock(&gioc_lock); 189 list_for_each_entry(ioc, &mpt3sas_ioc_list, list) 190 ioc->fwfault_debug = mpt3sas_fwfault_debug; 191 spin_unlock(&gioc_lock); 192 return 0; 193 } 194 module_param_call(mpt3sas_fwfault_debug, _scsih_set_fwfault_debug, 195 param_get_int, &mpt3sas_fwfault_debug, 0644); 196 197 /** 198 * _base_readl_aero - retry readl for max three times. 199 * @addr: MPT Fusion system interface register address 200 * 201 * Retry the readl() for max three times if it gets zero value 202 * while reading the system interface register. 203 */ 204 static inline u32 205 _base_readl_aero(const volatile void __iomem *addr) 206 { 207 u32 i = 0, ret_val; 208 209 do { 210 ret_val = readl(addr); 211 i++; 212 } while (ret_val == 0 && i < 3); 213 214 return ret_val; 215 } 216 217 static inline u32 218 _base_readl(const volatile void __iomem *addr) 219 { 220 return readl(addr); 221 } 222 223 /** 224 * _base_clone_reply_to_sys_mem - copies reply to reply free iomem 225 * in BAR0 space. 226 * 227 * @ioc: per adapter object 228 * @reply: reply message frame(lower 32bit addr) 229 * @index: System request message index. 230 */ 231 static void 232 _base_clone_reply_to_sys_mem(struct MPT3SAS_ADAPTER *ioc, u32 reply, 233 u32 index) 234 { 235 /* 236 * 256 is offset within sys register. 237 * 256 offset MPI frame starts. Max MPI frame supported is 32. 238 * 32 * 128 = 4K. From here, Clone of reply free for mcpu starts 239 */ 240 u16 cmd_credit = ioc->facts.RequestCredit + 1; 241 void __iomem *reply_free_iomem = (void __iomem *)ioc->chip + 242 MPI_FRAME_START_OFFSET + 243 (cmd_credit * ioc->request_sz) + (index * sizeof(u32)); 244 245 writel(reply, reply_free_iomem); 246 } 247 248 /** 249 * _base_clone_mpi_to_sys_mem - Writes/copies MPI frames 250 * to system/BAR0 region. 251 * 252 * @dst_iomem: Pointer to the destination location in BAR0 space. 253 * @src: Pointer to the Source data. 254 * @size: Size of data to be copied. 255 */ 256 static void 257 _base_clone_mpi_to_sys_mem(void *dst_iomem, void *src, u32 size) 258 { 259 int i; 260 u32 *src_virt_mem = (u32 *)src; 261 262 for (i = 0; i < size/4; i++) 263 writel((u32)src_virt_mem[i], 264 (void __iomem *)dst_iomem + (i * 4)); 265 } 266 267 /** 268 * _base_clone_to_sys_mem - Writes/copies data to system/BAR0 region 269 * 270 * @dst_iomem: Pointer to the destination location in BAR0 space. 271 * @src: Pointer to the Source data. 272 * @size: Size of data to be copied. 273 */ 274 static void 275 _base_clone_to_sys_mem(void __iomem *dst_iomem, void *src, u32 size) 276 { 277 int i; 278 u32 *src_virt_mem = (u32 *)(src); 279 280 for (i = 0; i < size/4; i++) 281 writel((u32)src_virt_mem[i], 282 (void __iomem *)dst_iomem + (i * 4)); 283 } 284 285 /** 286 * _base_get_chain - Calculates and Returns virtual chain address 287 * for the provided smid in BAR0 space. 288 * 289 * @ioc: per adapter object 290 * @smid: system request message index 291 * @sge_chain_count: Scatter gather chain count. 292 * 293 * Return: the chain address. 294 */ 295 static inline void __iomem* 296 _base_get_chain(struct MPT3SAS_ADAPTER *ioc, u16 smid, 297 u8 sge_chain_count) 298 { 299 void __iomem *base_chain, *chain_virt; 300 u16 cmd_credit = ioc->facts.RequestCredit + 1; 301 302 base_chain = (void __iomem *)ioc->chip + MPI_FRAME_START_OFFSET + 303 (cmd_credit * ioc->request_sz) + 304 REPLY_FREE_POOL_SIZE; 305 chain_virt = base_chain + (smid * ioc->facts.MaxChainDepth * 306 ioc->request_sz) + (sge_chain_count * ioc->request_sz); 307 return chain_virt; 308 } 309 310 /** 311 * _base_get_chain_phys - Calculates and Returns physical address 312 * in BAR0 for scatter gather chains, for 313 * the provided smid. 314 * 315 * @ioc: per adapter object 316 * @smid: system request message index 317 * @sge_chain_count: Scatter gather chain count. 318 * 319 * Return: Physical chain address. 320 */ 321 static inline phys_addr_t 322 _base_get_chain_phys(struct MPT3SAS_ADAPTER *ioc, u16 smid, 323 u8 sge_chain_count) 324 { 325 phys_addr_t base_chain_phys, chain_phys; 326 u16 cmd_credit = ioc->facts.RequestCredit + 1; 327 328 base_chain_phys = ioc->chip_phys + MPI_FRAME_START_OFFSET + 329 (cmd_credit * ioc->request_sz) + 330 REPLY_FREE_POOL_SIZE; 331 chain_phys = base_chain_phys + (smid * ioc->facts.MaxChainDepth * 332 ioc->request_sz) + (sge_chain_count * ioc->request_sz); 333 return chain_phys; 334 } 335 336 /** 337 * _base_get_buffer_bar0 - Calculates and Returns BAR0 mapped Host 338 * buffer address for the provided smid. 339 * (Each smid can have 64K starts from 17024) 340 * 341 * @ioc: per adapter object 342 * @smid: system request message index 343 * 344 * Return: Pointer to buffer location in BAR0. 345 */ 346 347 static void __iomem * 348 _base_get_buffer_bar0(struct MPT3SAS_ADAPTER *ioc, u16 smid) 349 { 350 u16 cmd_credit = ioc->facts.RequestCredit + 1; 351 // Added extra 1 to reach end of chain. 352 void __iomem *chain_end = _base_get_chain(ioc, 353 cmd_credit + 1, 354 ioc->facts.MaxChainDepth); 355 return chain_end + (smid * 64 * 1024); 356 } 357 358 /** 359 * _base_get_buffer_phys_bar0 - Calculates and Returns BAR0 mapped 360 * Host buffer Physical address for the provided smid. 361 * (Each smid can have 64K starts from 17024) 362 * 363 * @ioc: per adapter object 364 * @smid: system request message index 365 * 366 * Return: Pointer to buffer location in BAR0. 367 */ 368 static phys_addr_t 369 _base_get_buffer_phys_bar0(struct MPT3SAS_ADAPTER *ioc, u16 smid) 370 { 371 u16 cmd_credit = ioc->facts.RequestCredit + 1; 372 phys_addr_t chain_end_phys = _base_get_chain_phys(ioc, 373 cmd_credit + 1, 374 ioc->facts.MaxChainDepth); 375 return chain_end_phys + (smid * 64 * 1024); 376 } 377 378 /** 379 * _base_get_chain_buffer_dma_to_chain_buffer - Iterates chain 380 * lookup list and Provides chain_buffer 381 * address for the matching dma address. 382 * (Each smid can have 64K starts from 17024) 383 * 384 * @ioc: per adapter object 385 * @chain_buffer_dma: Chain buffer dma address. 386 * 387 * Return: Pointer to chain buffer. Or Null on Failure. 388 */ 389 static void * 390 _base_get_chain_buffer_dma_to_chain_buffer(struct MPT3SAS_ADAPTER *ioc, 391 dma_addr_t chain_buffer_dma) 392 { 393 u16 index, j; 394 struct chain_tracker *ct; 395 396 for (index = 0; index < ioc->scsiio_depth; index++) { 397 for (j = 0; j < ioc->chains_needed_per_io; j++) { 398 ct = &ioc->chain_lookup[index].chains_per_smid[j]; 399 if (ct && ct->chain_buffer_dma == chain_buffer_dma) 400 return ct->chain_buffer; 401 } 402 } 403 ioc_info(ioc, "Provided chain_buffer_dma address is not in the lookup list\n"); 404 return NULL; 405 } 406 407 /** 408 * _clone_sg_entries - MPI EP's scsiio and config requests 409 * are handled here. Base function for 410 * double buffering, before submitting 411 * the requests. 412 * 413 * @ioc: per adapter object. 414 * @mpi_request: mf request pointer. 415 * @smid: system request message index. 416 */ 417 static void _clone_sg_entries(struct MPT3SAS_ADAPTER *ioc, 418 void *mpi_request, u16 smid) 419 { 420 Mpi2SGESimple32_t *sgel, *sgel_next; 421 u32 sgl_flags, sge_chain_count = 0; 422 bool is_write = false; 423 u16 i = 0; 424 void __iomem *buffer_iomem; 425 phys_addr_t buffer_iomem_phys; 426 void __iomem *buff_ptr; 427 phys_addr_t buff_ptr_phys; 428 void __iomem *dst_chain_addr[MCPU_MAX_CHAINS_PER_IO]; 429 void *src_chain_addr[MCPU_MAX_CHAINS_PER_IO]; 430 phys_addr_t dst_addr_phys; 431 MPI2RequestHeader_t *request_hdr; 432 struct scsi_cmnd *scmd; 433 struct scatterlist *sg_scmd = NULL; 434 int is_scsiio_req = 0; 435 436 request_hdr = (MPI2RequestHeader_t *) mpi_request; 437 438 if (request_hdr->Function == MPI2_FUNCTION_SCSI_IO_REQUEST) { 439 Mpi25SCSIIORequest_t *scsiio_request = 440 (Mpi25SCSIIORequest_t *)mpi_request; 441 sgel = (Mpi2SGESimple32_t *) &scsiio_request->SGL; 442 is_scsiio_req = 1; 443 } else if (request_hdr->Function == MPI2_FUNCTION_CONFIG) { 444 Mpi2ConfigRequest_t *config_req = 445 (Mpi2ConfigRequest_t *)mpi_request; 446 sgel = (Mpi2SGESimple32_t *) &config_req->PageBufferSGE; 447 } else 448 return; 449 450 /* From smid we can get scsi_cmd, once we have sg_scmd, 451 * we just need to get sg_virt and sg_next to get virtual 452 * address associated with sgel->Address. 453 */ 454 455 if (is_scsiio_req) { 456 /* Get scsi_cmd using smid */ 457 scmd = mpt3sas_scsih_scsi_lookup_get(ioc, smid); 458 if (scmd == NULL) { 459 ioc_err(ioc, "scmd is NULL\n"); 460 return; 461 } 462 463 /* Get sg_scmd from scmd provided */ 464 sg_scmd = scsi_sglist(scmd); 465 } 466 467 /* 468 * 0 - 255 System register 469 * 256 - 4352 MPI Frame. (This is based on maxCredit 32) 470 * 4352 - 4864 Reply_free pool (512 byte is reserved 471 * considering maxCredit 32. Reply need extra 472 * room, for mCPU case kept four times of 473 * maxCredit). 474 * 4864 - 17152 SGE chain element. (32cmd * 3 chain of 475 * 128 byte size = 12288) 476 * 17152 - x Host buffer mapped with smid. 477 * (Each smid can have 64K Max IO.) 478 * BAR0+Last 1K MSIX Addr and Data 479 * Total size in use 2113664 bytes of 4MB BAR0 480 */ 481 482 buffer_iomem = _base_get_buffer_bar0(ioc, smid); 483 buffer_iomem_phys = _base_get_buffer_phys_bar0(ioc, smid); 484 485 buff_ptr = buffer_iomem; 486 buff_ptr_phys = buffer_iomem_phys; 487 WARN_ON(buff_ptr_phys > U32_MAX); 488 489 if (le32_to_cpu(sgel->FlagsLength) & 490 (MPI2_SGE_FLAGS_HOST_TO_IOC << MPI2_SGE_FLAGS_SHIFT)) 491 is_write = true; 492 493 for (i = 0; i < MPT_MIN_PHYS_SEGMENTS + ioc->facts.MaxChainDepth; i++) { 494 495 sgl_flags = 496 (le32_to_cpu(sgel->FlagsLength) >> MPI2_SGE_FLAGS_SHIFT); 497 498 switch (sgl_flags & MPI2_SGE_FLAGS_ELEMENT_MASK) { 499 case MPI2_SGE_FLAGS_CHAIN_ELEMENT: 500 /* 501 * Helper function which on passing 502 * chain_buffer_dma returns chain_buffer. Get 503 * the virtual address for sgel->Address 504 */ 505 sgel_next = 506 _base_get_chain_buffer_dma_to_chain_buffer(ioc, 507 le32_to_cpu(sgel->Address)); 508 if (sgel_next == NULL) 509 return; 510 /* 511 * This is coping 128 byte chain 512 * frame (not a host buffer) 513 */ 514 dst_chain_addr[sge_chain_count] = 515 _base_get_chain(ioc, 516 smid, sge_chain_count); 517 src_chain_addr[sge_chain_count] = 518 (void *) sgel_next; 519 dst_addr_phys = _base_get_chain_phys(ioc, 520 smid, sge_chain_count); 521 WARN_ON(dst_addr_phys > U32_MAX); 522 sgel->Address = 523 cpu_to_le32(lower_32_bits(dst_addr_phys)); 524 sgel = sgel_next; 525 sge_chain_count++; 526 break; 527 case MPI2_SGE_FLAGS_SIMPLE_ELEMENT: 528 if (is_write) { 529 if (is_scsiio_req) { 530 _base_clone_to_sys_mem(buff_ptr, 531 sg_virt(sg_scmd), 532 (le32_to_cpu(sgel->FlagsLength) & 533 0x00ffffff)); 534 /* 535 * FIXME: this relies on a a zero 536 * PCI mem_offset. 537 */ 538 sgel->Address = 539 cpu_to_le32((u32)buff_ptr_phys); 540 } else { 541 _base_clone_to_sys_mem(buff_ptr, 542 ioc->config_vaddr, 543 (le32_to_cpu(sgel->FlagsLength) & 544 0x00ffffff)); 545 sgel->Address = 546 cpu_to_le32((u32)buff_ptr_phys); 547 } 548 } 549 buff_ptr += (le32_to_cpu(sgel->FlagsLength) & 550 0x00ffffff); 551 buff_ptr_phys += (le32_to_cpu(sgel->FlagsLength) & 552 0x00ffffff); 553 if ((le32_to_cpu(sgel->FlagsLength) & 554 (MPI2_SGE_FLAGS_END_OF_BUFFER 555 << MPI2_SGE_FLAGS_SHIFT))) 556 goto eob_clone_chain; 557 else { 558 /* 559 * Every single element in MPT will have 560 * associated sg_next. Better to sanity that 561 * sg_next is not NULL, but it will be a bug 562 * if it is null. 563 */ 564 if (is_scsiio_req) { 565 sg_scmd = sg_next(sg_scmd); 566 if (sg_scmd) 567 sgel++; 568 else 569 goto eob_clone_chain; 570 } 571 } 572 break; 573 } 574 } 575 576 eob_clone_chain: 577 for (i = 0; i < sge_chain_count; i++) { 578 if (is_scsiio_req) 579 _base_clone_to_sys_mem(dst_chain_addr[i], 580 src_chain_addr[i], ioc->request_sz); 581 } 582 } 583 584 /** 585 * mpt3sas_remove_dead_ioc_func - kthread context to remove dead ioc 586 * @arg: input argument, used to derive ioc 587 * 588 * Return: 589 * 0 if controller is removed from pci subsystem. 590 * -1 for other case. 591 */ 592 static int mpt3sas_remove_dead_ioc_func(void *arg) 593 { 594 struct MPT3SAS_ADAPTER *ioc = (struct MPT3SAS_ADAPTER *)arg; 595 struct pci_dev *pdev; 596 597 if (!ioc) 598 return -1; 599 600 pdev = ioc->pdev; 601 if (!pdev) 602 return -1; 603 pci_stop_and_remove_bus_device_locked(pdev); 604 return 0; 605 } 606 607 /** 608 * _base_sync_drv_fw_timestamp - Sync Drive-Fw TimeStamp. 609 * @ioc: Per Adapter Object 610 * 611 * Return: nothing. 612 */ 613 static void _base_sync_drv_fw_timestamp(struct MPT3SAS_ADAPTER *ioc) 614 { 615 Mpi26IoUnitControlRequest_t *mpi_request; 616 Mpi26IoUnitControlReply_t *mpi_reply; 617 u16 smid; 618 ktime_t current_time; 619 u64 TimeStamp = 0; 620 u8 issue_reset = 0; 621 622 mutex_lock(&ioc->scsih_cmds.mutex); 623 if (ioc->scsih_cmds.status != MPT3_CMD_NOT_USED) { 624 ioc_err(ioc, "scsih_cmd in use %s\n", __func__); 625 goto out; 626 } 627 ioc->scsih_cmds.status = MPT3_CMD_PENDING; 628 smid = mpt3sas_base_get_smid(ioc, ioc->scsih_cb_idx); 629 if (!smid) { 630 ioc_err(ioc, "Failed obtaining a smid %s\n", __func__); 631 ioc->scsih_cmds.status = MPT3_CMD_NOT_USED; 632 goto out; 633 } 634 mpi_request = mpt3sas_base_get_msg_frame(ioc, smid); 635 ioc->scsih_cmds.smid = smid; 636 memset(mpi_request, 0, sizeof(Mpi26IoUnitControlRequest_t)); 637 mpi_request->Function = MPI2_FUNCTION_IO_UNIT_CONTROL; 638 mpi_request->Operation = MPI26_CTRL_OP_SET_IOC_PARAMETER; 639 mpi_request->IOCParameter = MPI26_SET_IOC_PARAMETER_SYNC_TIMESTAMP; 640 current_time = ktime_get_real(); 641 TimeStamp = ktime_to_ms(current_time); 642 mpi_request->Reserved7 = cpu_to_le32(TimeStamp >> 32); 643 mpi_request->IOCParameterValue = cpu_to_le32(TimeStamp & 0xFFFFFFFF); 644 init_completion(&ioc->scsih_cmds.done); 645 ioc->put_smid_default(ioc, smid); 646 dinitprintk(ioc, ioc_info(ioc, 647 "Io Unit Control Sync TimeStamp (sending), @time %lld ms\n", 648 TimeStamp)); 649 wait_for_completion_timeout(&ioc->scsih_cmds.done, 650 MPT3SAS_TIMESYNC_TIMEOUT_SECONDS*HZ); 651 if (!(ioc->scsih_cmds.status & MPT3_CMD_COMPLETE)) { 652 mpt3sas_check_cmd_timeout(ioc, 653 ioc->scsih_cmds.status, mpi_request, 654 sizeof(Mpi2SasIoUnitControlRequest_t)/4, issue_reset); 655 goto issue_host_reset; 656 } 657 if (ioc->scsih_cmds.status & MPT3_CMD_REPLY_VALID) { 658 mpi_reply = ioc->scsih_cmds.reply; 659 dinitprintk(ioc, ioc_info(ioc, 660 "Io Unit Control sync timestamp (complete): ioc_status(0x%04x), loginfo(0x%08x)\n", 661 le16_to_cpu(mpi_reply->IOCStatus), 662 le32_to_cpu(mpi_reply->IOCLogInfo))); 663 } 664 issue_host_reset: 665 if (issue_reset) 666 mpt3sas_base_hard_reset_handler(ioc, FORCE_BIG_HAMMER); 667 ioc->scsih_cmds.status = MPT3_CMD_NOT_USED; 668 out: 669 mutex_unlock(&ioc->scsih_cmds.mutex); 670 } 671 672 /** 673 * _base_fault_reset_work - workq handling ioc fault conditions 674 * @work: input argument, used to derive ioc 675 * 676 * Context: sleep. 677 */ 678 static void 679 _base_fault_reset_work(struct work_struct *work) 680 { 681 struct MPT3SAS_ADAPTER *ioc = 682 container_of(work, struct MPT3SAS_ADAPTER, fault_reset_work.work); 683 unsigned long flags; 684 u32 doorbell; 685 int rc; 686 struct task_struct *p; 687 688 689 spin_lock_irqsave(&ioc->ioc_reset_in_progress_lock, flags); 690 if ((ioc->shost_recovery && (ioc->ioc_coredump_loop == 0)) || 691 ioc->pci_error_recovery) 692 goto rearm_timer; 693 spin_unlock_irqrestore(&ioc->ioc_reset_in_progress_lock, flags); 694 695 doorbell = mpt3sas_base_get_iocstate(ioc, 0); 696 if ((doorbell & MPI2_IOC_STATE_MASK) == MPI2_IOC_STATE_MASK) { 697 ioc_err(ioc, "SAS host is non-operational !!!!\n"); 698 699 /* It may be possible that EEH recovery can resolve some of 700 * pci bus failure issues rather removing the dead ioc function 701 * by considering controller is in a non-operational state. So 702 * here priority is given to the EEH recovery. If it doesn't 703 * not resolve this issue, mpt3sas driver will consider this 704 * controller to non-operational state and remove the dead ioc 705 * function. 706 */ 707 if (ioc->non_operational_loop++ < 5) { 708 spin_lock_irqsave(&ioc->ioc_reset_in_progress_lock, 709 flags); 710 goto rearm_timer; 711 } 712 713 /* 714 * Call _scsih_flush_pending_cmds callback so that we flush all 715 * pending commands back to OS. This call is required to avoid 716 * deadlock at block layer. Dead IOC will fail to do diag reset, 717 * and this call is safe since dead ioc will never return any 718 * command back from HW. 719 */ 720 mpt3sas_base_pause_mq_polling(ioc); 721 ioc->schedule_dead_ioc_flush_running_cmds(ioc); 722 /* 723 * Set remove_host flag early since kernel thread will 724 * take some time to execute. 725 */ 726 ioc->remove_host = 1; 727 /*Remove the Dead Host */ 728 p = kthread_run(mpt3sas_remove_dead_ioc_func, ioc, 729 "%s_dead_ioc_%d", ioc->driver_name, ioc->id); 730 if (IS_ERR(p)) 731 ioc_err(ioc, "%s: Running mpt3sas_dead_ioc thread failed !!!!\n", 732 __func__); 733 else 734 ioc_err(ioc, "%s: Running mpt3sas_dead_ioc thread success !!!!\n", 735 __func__); 736 return; /* don't rearm timer */ 737 } 738 739 if ((doorbell & MPI2_IOC_STATE_MASK) == MPI2_IOC_STATE_COREDUMP) { 740 u8 timeout = (ioc->manu_pg11.CoreDumpTOSec) ? 741 ioc->manu_pg11.CoreDumpTOSec : 742 MPT3SAS_DEFAULT_COREDUMP_TIMEOUT_SECONDS; 743 744 timeout /= (FAULT_POLLING_INTERVAL/1000); 745 746 if (ioc->ioc_coredump_loop == 0) { 747 mpt3sas_print_coredump_info(ioc, 748 doorbell & MPI2_DOORBELL_DATA_MASK); 749 /* do not accept any IOs and disable the interrupts */ 750 spin_lock_irqsave( 751 &ioc->ioc_reset_in_progress_lock, flags); 752 ioc->shost_recovery = 1; 753 spin_unlock_irqrestore( 754 &ioc->ioc_reset_in_progress_lock, flags); 755 mpt3sas_base_mask_interrupts(ioc); 756 mpt3sas_base_pause_mq_polling(ioc); 757 _base_clear_outstanding_commands(ioc); 758 } 759 760 ioc_info(ioc, "%s: CoreDump loop %d.", 761 __func__, ioc->ioc_coredump_loop); 762 763 /* Wait until CoreDump completes or times out */ 764 if (ioc->ioc_coredump_loop++ < timeout) { 765 spin_lock_irqsave( 766 &ioc->ioc_reset_in_progress_lock, flags); 767 goto rearm_timer; 768 } 769 } 770 771 if (ioc->ioc_coredump_loop) { 772 if ((doorbell & MPI2_IOC_STATE_MASK) != MPI2_IOC_STATE_COREDUMP) 773 ioc_err(ioc, "%s: CoreDump completed. LoopCount: %d", 774 __func__, ioc->ioc_coredump_loop); 775 else 776 ioc_err(ioc, "%s: CoreDump Timed out. LoopCount: %d", 777 __func__, ioc->ioc_coredump_loop); 778 ioc->ioc_coredump_loop = MPT3SAS_COREDUMP_LOOP_DONE; 779 } 780 ioc->non_operational_loop = 0; 781 if ((doorbell & MPI2_IOC_STATE_MASK) != MPI2_IOC_STATE_OPERATIONAL) { 782 rc = mpt3sas_base_hard_reset_handler(ioc, FORCE_BIG_HAMMER); 783 ioc_warn(ioc, "%s: hard reset: %s\n", 784 __func__, rc == 0 ? "success" : "failed"); 785 doorbell = mpt3sas_base_get_iocstate(ioc, 0); 786 if ((doorbell & MPI2_IOC_STATE_MASK) == MPI2_IOC_STATE_FAULT) { 787 mpt3sas_print_fault_code(ioc, doorbell & 788 MPI2_DOORBELL_DATA_MASK); 789 } else if ((doorbell & MPI2_IOC_STATE_MASK) == 790 MPI2_IOC_STATE_COREDUMP) 791 mpt3sas_print_coredump_info(ioc, doorbell & 792 MPI2_DOORBELL_DATA_MASK); 793 if (rc && (doorbell & MPI2_IOC_STATE_MASK) != 794 MPI2_IOC_STATE_OPERATIONAL) 795 return; /* don't rearm timer */ 796 } 797 ioc->ioc_coredump_loop = 0; 798 if (ioc->time_sync_interval && 799 ++ioc->timestamp_update_count >= ioc->time_sync_interval) { 800 ioc->timestamp_update_count = 0; 801 _base_sync_drv_fw_timestamp(ioc); 802 } 803 spin_lock_irqsave(&ioc->ioc_reset_in_progress_lock, flags); 804 rearm_timer: 805 if (ioc->fault_reset_work_q) 806 queue_delayed_work(ioc->fault_reset_work_q, 807 &ioc->fault_reset_work, 808 msecs_to_jiffies(FAULT_POLLING_INTERVAL)); 809 spin_unlock_irqrestore(&ioc->ioc_reset_in_progress_lock, flags); 810 } 811 812 /** 813 * mpt3sas_base_start_watchdog - start the fault_reset_work_q 814 * @ioc: per adapter object 815 * 816 * Context: sleep. 817 */ 818 void 819 mpt3sas_base_start_watchdog(struct MPT3SAS_ADAPTER *ioc) 820 { 821 unsigned long flags; 822 823 if (ioc->fault_reset_work_q) 824 return; 825 826 ioc->timestamp_update_count = 0; 827 /* initialize fault polling */ 828 829 INIT_DELAYED_WORK(&ioc->fault_reset_work, _base_fault_reset_work); 830 snprintf(ioc->fault_reset_work_q_name, 831 sizeof(ioc->fault_reset_work_q_name), "poll_%s%d_status", 832 ioc->driver_name, ioc->id); 833 ioc->fault_reset_work_q = 834 create_singlethread_workqueue(ioc->fault_reset_work_q_name); 835 if (!ioc->fault_reset_work_q) { 836 ioc_err(ioc, "%s: failed (line=%d)\n", __func__, __LINE__); 837 return; 838 } 839 spin_lock_irqsave(&ioc->ioc_reset_in_progress_lock, flags); 840 if (ioc->fault_reset_work_q) 841 queue_delayed_work(ioc->fault_reset_work_q, 842 &ioc->fault_reset_work, 843 msecs_to_jiffies(FAULT_POLLING_INTERVAL)); 844 spin_unlock_irqrestore(&ioc->ioc_reset_in_progress_lock, flags); 845 } 846 847 /** 848 * mpt3sas_base_stop_watchdog - stop the fault_reset_work_q 849 * @ioc: per adapter object 850 * 851 * Context: sleep. 852 */ 853 void 854 mpt3sas_base_stop_watchdog(struct MPT3SAS_ADAPTER *ioc) 855 { 856 unsigned long flags; 857 struct workqueue_struct *wq; 858 859 spin_lock_irqsave(&ioc->ioc_reset_in_progress_lock, flags); 860 wq = ioc->fault_reset_work_q; 861 ioc->fault_reset_work_q = NULL; 862 spin_unlock_irqrestore(&ioc->ioc_reset_in_progress_lock, flags); 863 if (wq) { 864 if (!cancel_delayed_work_sync(&ioc->fault_reset_work)) 865 flush_workqueue(wq); 866 destroy_workqueue(wq); 867 } 868 } 869 870 /** 871 * mpt3sas_base_fault_info - verbose translation of firmware FAULT code 872 * @ioc: per adapter object 873 * @fault_code: fault code 874 */ 875 void 876 mpt3sas_base_fault_info(struct MPT3SAS_ADAPTER *ioc, u16 fault_code) 877 { 878 ioc_err(ioc, "fault_state(0x%04x)!\n", fault_code); 879 } 880 881 /** 882 * mpt3sas_base_coredump_info - verbose translation of firmware CoreDump state 883 * @ioc: per adapter object 884 * @fault_code: fault code 885 * 886 * Return: nothing. 887 */ 888 void 889 mpt3sas_base_coredump_info(struct MPT3SAS_ADAPTER *ioc, u16 fault_code) 890 { 891 ioc_err(ioc, "coredump_state(0x%04x)!\n", fault_code); 892 } 893 894 /** 895 * mpt3sas_base_wait_for_coredump_completion - Wait until coredump 896 * completes or times out 897 * @ioc: per adapter object 898 * @caller: caller function name 899 * 900 * Return: 0 for success, non-zero for failure. 901 */ 902 int 903 mpt3sas_base_wait_for_coredump_completion(struct MPT3SAS_ADAPTER *ioc, 904 const char *caller) 905 { 906 u8 timeout = (ioc->manu_pg11.CoreDumpTOSec) ? 907 ioc->manu_pg11.CoreDumpTOSec : 908 MPT3SAS_DEFAULT_COREDUMP_TIMEOUT_SECONDS; 909 910 int ioc_state = _base_wait_on_iocstate(ioc, MPI2_IOC_STATE_FAULT, 911 timeout); 912 913 if (ioc_state) 914 ioc_err(ioc, 915 "%s: CoreDump timed out. (ioc_state=0x%x)\n", 916 caller, ioc_state); 917 else 918 ioc_info(ioc, 919 "%s: CoreDump completed. (ioc_state=0x%x)\n", 920 caller, ioc_state); 921 922 return ioc_state; 923 } 924 925 /** 926 * mpt3sas_halt_firmware - halt's mpt controller firmware 927 * @ioc: per adapter object 928 * 929 * For debugging timeout related issues. Writing 0xCOFFEE00 930 * to the doorbell register will halt controller firmware. With 931 * the purpose to stop both driver and firmware, the enduser can 932 * obtain a ring buffer from controller UART. 933 */ 934 void 935 mpt3sas_halt_firmware(struct MPT3SAS_ADAPTER *ioc) 936 { 937 u32 doorbell; 938 939 if (!ioc->fwfault_debug) 940 return; 941 942 dump_stack(); 943 944 doorbell = ioc->base_readl(&ioc->chip->Doorbell); 945 if ((doorbell & MPI2_IOC_STATE_MASK) == MPI2_IOC_STATE_FAULT) { 946 mpt3sas_print_fault_code(ioc, doorbell & 947 MPI2_DOORBELL_DATA_MASK); 948 } else if ((doorbell & MPI2_IOC_STATE_MASK) == 949 MPI2_IOC_STATE_COREDUMP) { 950 mpt3sas_print_coredump_info(ioc, doorbell & 951 MPI2_DOORBELL_DATA_MASK); 952 } else { 953 writel(0xC0FFEE00, &ioc->chip->Doorbell); 954 ioc_err(ioc, "Firmware is halted due to command timeout\n"); 955 } 956 957 if (ioc->fwfault_debug == 2) 958 for (;;) 959 ; 960 else 961 panic("panic in %s\n", __func__); 962 } 963 964 /** 965 * _base_sas_ioc_info - verbose translation of the ioc status 966 * @ioc: per adapter object 967 * @mpi_reply: reply mf payload returned from firmware 968 * @request_hdr: request mf 969 */ 970 static void 971 _base_sas_ioc_info(struct MPT3SAS_ADAPTER *ioc, MPI2DefaultReply_t *mpi_reply, 972 MPI2RequestHeader_t *request_hdr) 973 { 974 u16 ioc_status = le16_to_cpu(mpi_reply->IOCStatus) & 975 MPI2_IOCSTATUS_MASK; 976 char *desc = NULL; 977 u16 frame_sz; 978 char *func_str = NULL; 979 980 /* SCSI_IO, RAID_PASS are handled from _scsih_scsi_ioc_info */ 981 if (request_hdr->Function == MPI2_FUNCTION_SCSI_IO_REQUEST || 982 request_hdr->Function == MPI2_FUNCTION_RAID_SCSI_IO_PASSTHROUGH || 983 request_hdr->Function == MPI2_FUNCTION_EVENT_NOTIFICATION) 984 return; 985 986 if (ioc_status == MPI2_IOCSTATUS_CONFIG_INVALID_PAGE) 987 return; 988 /* 989 * Older Firmware version doesn't support driver trigger pages. 990 * So, skip displaying 'config invalid type' type 991 * of error message. 992 */ 993 if (request_hdr->Function == MPI2_FUNCTION_CONFIG) { 994 Mpi2ConfigRequest_t *rqst = (Mpi2ConfigRequest_t *)request_hdr; 995 996 if ((rqst->ExtPageType == 997 MPI2_CONFIG_EXTPAGETYPE_DRIVER_PERSISTENT_TRIGGER) && 998 !(ioc->logging_level & MPT_DEBUG_CONFIG)) { 999 return; 1000 } 1001 } 1002 1003 switch (ioc_status) { 1004 1005 /**************************************************************************** 1006 * Common IOCStatus values for all replies 1007 ****************************************************************************/ 1008 1009 case MPI2_IOCSTATUS_INVALID_FUNCTION: 1010 desc = "invalid function"; 1011 break; 1012 case MPI2_IOCSTATUS_BUSY: 1013 desc = "busy"; 1014 break; 1015 case MPI2_IOCSTATUS_INVALID_SGL: 1016 desc = "invalid sgl"; 1017 break; 1018 case MPI2_IOCSTATUS_INTERNAL_ERROR: 1019 desc = "internal error"; 1020 break; 1021 case MPI2_IOCSTATUS_INVALID_VPID: 1022 desc = "invalid vpid"; 1023 break; 1024 case MPI2_IOCSTATUS_INSUFFICIENT_RESOURCES: 1025 desc = "insufficient resources"; 1026 break; 1027 case MPI2_IOCSTATUS_INSUFFICIENT_POWER: 1028 desc = "insufficient power"; 1029 break; 1030 case MPI2_IOCSTATUS_INVALID_FIELD: 1031 desc = "invalid field"; 1032 break; 1033 case MPI2_IOCSTATUS_INVALID_STATE: 1034 desc = "invalid state"; 1035 break; 1036 case MPI2_IOCSTATUS_OP_STATE_NOT_SUPPORTED: 1037 desc = "op state not supported"; 1038 break; 1039 1040 /**************************************************************************** 1041 * Config IOCStatus values 1042 ****************************************************************************/ 1043 1044 case MPI2_IOCSTATUS_CONFIG_INVALID_ACTION: 1045 desc = "config invalid action"; 1046 break; 1047 case MPI2_IOCSTATUS_CONFIG_INVALID_TYPE: 1048 desc = "config invalid type"; 1049 break; 1050 case MPI2_IOCSTATUS_CONFIG_INVALID_PAGE: 1051 desc = "config invalid page"; 1052 break; 1053 case MPI2_IOCSTATUS_CONFIG_INVALID_DATA: 1054 desc = "config invalid data"; 1055 break; 1056 case MPI2_IOCSTATUS_CONFIG_NO_DEFAULTS: 1057 desc = "config no defaults"; 1058 break; 1059 case MPI2_IOCSTATUS_CONFIG_CANT_COMMIT: 1060 desc = "config can't commit"; 1061 break; 1062 1063 /**************************************************************************** 1064 * SCSI IO Reply 1065 ****************************************************************************/ 1066 1067 case MPI2_IOCSTATUS_SCSI_RECOVERED_ERROR: 1068 case MPI2_IOCSTATUS_SCSI_INVALID_DEVHANDLE: 1069 case MPI2_IOCSTATUS_SCSI_DEVICE_NOT_THERE: 1070 case MPI2_IOCSTATUS_SCSI_DATA_OVERRUN: 1071 case MPI2_IOCSTATUS_SCSI_DATA_UNDERRUN: 1072 case MPI2_IOCSTATUS_SCSI_IO_DATA_ERROR: 1073 case MPI2_IOCSTATUS_SCSI_PROTOCOL_ERROR: 1074 case MPI2_IOCSTATUS_SCSI_TASK_TERMINATED: 1075 case MPI2_IOCSTATUS_SCSI_RESIDUAL_MISMATCH: 1076 case MPI2_IOCSTATUS_SCSI_TASK_MGMT_FAILED: 1077 case MPI2_IOCSTATUS_SCSI_IOC_TERMINATED: 1078 case MPI2_IOCSTATUS_SCSI_EXT_TERMINATED: 1079 break; 1080 1081 /**************************************************************************** 1082 * For use by SCSI Initiator and SCSI Target end-to-end data protection 1083 ****************************************************************************/ 1084 1085 case MPI2_IOCSTATUS_EEDP_GUARD_ERROR: 1086 desc = "eedp guard error"; 1087 break; 1088 case MPI2_IOCSTATUS_EEDP_REF_TAG_ERROR: 1089 desc = "eedp ref tag error"; 1090 break; 1091 case MPI2_IOCSTATUS_EEDP_APP_TAG_ERROR: 1092 desc = "eedp app tag error"; 1093 break; 1094 1095 /**************************************************************************** 1096 * SCSI Target values 1097 ****************************************************************************/ 1098 1099 case MPI2_IOCSTATUS_TARGET_INVALID_IO_INDEX: 1100 desc = "target invalid io index"; 1101 break; 1102 case MPI2_IOCSTATUS_TARGET_ABORTED: 1103 desc = "target aborted"; 1104 break; 1105 case MPI2_IOCSTATUS_TARGET_NO_CONN_RETRYABLE: 1106 desc = "target no conn retryable"; 1107 break; 1108 case MPI2_IOCSTATUS_TARGET_NO_CONNECTION: 1109 desc = "target no connection"; 1110 break; 1111 case MPI2_IOCSTATUS_TARGET_XFER_COUNT_MISMATCH: 1112 desc = "target xfer count mismatch"; 1113 break; 1114 case MPI2_IOCSTATUS_TARGET_DATA_OFFSET_ERROR: 1115 desc = "target data offset error"; 1116 break; 1117 case MPI2_IOCSTATUS_TARGET_TOO_MUCH_WRITE_DATA: 1118 desc = "target too much write data"; 1119 break; 1120 case MPI2_IOCSTATUS_TARGET_IU_TOO_SHORT: 1121 desc = "target iu too short"; 1122 break; 1123 case MPI2_IOCSTATUS_TARGET_ACK_NAK_TIMEOUT: 1124 desc = "target ack nak timeout"; 1125 break; 1126 case MPI2_IOCSTATUS_TARGET_NAK_RECEIVED: 1127 desc = "target nak received"; 1128 break; 1129 1130 /**************************************************************************** 1131 * Serial Attached SCSI values 1132 ****************************************************************************/ 1133 1134 case MPI2_IOCSTATUS_SAS_SMP_REQUEST_FAILED: 1135 desc = "smp request failed"; 1136 break; 1137 case MPI2_IOCSTATUS_SAS_SMP_DATA_OVERRUN: 1138 desc = "smp data overrun"; 1139 break; 1140 1141 /**************************************************************************** 1142 * Diagnostic Buffer Post / Diagnostic Release values 1143 ****************************************************************************/ 1144 1145 case MPI2_IOCSTATUS_DIAGNOSTIC_RELEASED: 1146 desc = "diagnostic released"; 1147 break; 1148 default: 1149 break; 1150 } 1151 1152 if (!desc) 1153 return; 1154 1155 switch (request_hdr->Function) { 1156 case MPI2_FUNCTION_CONFIG: 1157 frame_sz = sizeof(Mpi2ConfigRequest_t) + ioc->sge_size; 1158 func_str = "config_page"; 1159 break; 1160 case MPI2_FUNCTION_SCSI_TASK_MGMT: 1161 frame_sz = sizeof(Mpi2SCSITaskManagementRequest_t); 1162 func_str = "task_mgmt"; 1163 break; 1164 case MPI2_FUNCTION_SAS_IO_UNIT_CONTROL: 1165 frame_sz = sizeof(Mpi2SasIoUnitControlRequest_t); 1166 func_str = "sas_iounit_ctl"; 1167 break; 1168 case MPI2_FUNCTION_SCSI_ENCLOSURE_PROCESSOR: 1169 frame_sz = sizeof(Mpi2SepRequest_t); 1170 func_str = "enclosure"; 1171 break; 1172 case MPI2_FUNCTION_IOC_INIT: 1173 frame_sz = sizeof(Mpi2IOCInitRequest_t); 1174 func_str = "ioc_init"; 1175 break; 1176 case MPI2_FUNCTION_PORT_ENABLE: 1177 frame_sz = sizeof(Mpi2PortEnableRequest_t); 1178 func_str = "port_enable"; 1179 break; 1180 case MPI2_FUNCTION_SMP_PASSTHROUGH: 1181 frame_sz = sizeof(Mpi2SmpPassthroughRequest_t) + ioc->sge_size; 1182 func_str = "smp_passthru"; 1183 break; 1184 case MPI2_FUNCTION_NVME_ENCAPSULATED: 1185 frame_sz = sizeof(Mpi26NVMeEncapsulatedRequest_t) + 1186 ioc->sge_size; 1187 func_str = "nvme_encapsulated"; 1188 break; 1189 default: 1190 frame_sz = 32; 1191 func_str = "unknown"; 1192 break; 1193 } 1194 1195 ioc_warn(ioc, "ioc_status: %s(0x%04x), request(0x%p),(%s)\n", 1196 desc, ioc_status, request_hdr, func_str); 1197 1198 _debug_dump_mf(request_hdr, frame_sz/4); 1199 } 1200 1201 /** 1202 * _base_display_event_data - verbose translation of firmware asyn events 1203 * @ioc: per adapter object 1204 * @mpi_reply: reply mf payload returned from firmware 1205 */ 1206 static void 1207 _base_display_event_data(struct MPT3SAS_ADAPTER *ioc, 1208 Mpi2EventNotificationReply_t *mpi_reply) 1209 { 1210 char *desc = NULL; 1211 u16 event; 1212 1213 if (!(ioc->logging_level & MPT_DEBUG_EVENTS)) 1214 return; 1215 1216 event = le16_to_cpu(mpi_reply->Event); 1217 1218 switch (event) { 1219 case MPI2_EVENT_LOG_DATA: 1220 desc = "Log Data"; 1221 break; 1222 case MPI2_EVENT_STATE_CHANGE: 1223 desc = "Status Change"; 1224 break; 1225 case MPI2_EVENT_HARD_RESET_RECEIVED: 1226 desc = "Hard Reset Received"; 1227 break; 1228 case MPI2_EVENT_EVENT_CHANGE: 1229 desc = "Event Change"; 1230 break; 1231 case MPI2_EVENT_SAS_DEVICE_STATUS_CHANGE: 1232 desc = "Device Status Change"; 1233 break; 1234 case MPI2_EVENT_IR_OPERATION_STATUS: 1235 if (!ioc->hide_ir_msg) 1236 desc = "IR Operation Status"; 1237 break; 1238 case MPI2_EVENT_SAS_DISCOVERY: 1239 { 1240 Mpi2EventDataSasDiscovery_t *event_data = 1241 (Mpi2EventDataSasDiscovery_t *)mpi_reply->EventData; 1242 ioc_info(ioc, "Discovery: (%s)", 1243 event_data->ReasonCode == MPI2_EVENT_SAS_DISC_RC_STARTED ? 1244 "start" : "stop"); 1245 if (event_data->DiscoveryStatus) 1246 pr_cont(" discovery_status(0x%08x)", 1247 le32_to_cpu(event_data->DiscoveryStatus)); 1248 pr_cont("\n"); 1249 return; 1250 } 1251 case MPI2_EVENT_SAS_BROADCAST_PRIMITIVE: 1252 desc = "SAS Broadcast Primitive"; 1253 break; 1254 case MPI2_EVENT_SAS_INIT_DEVICE_STATUS_CHANGE: 1255 desc = "SAS Init Device Status Change"; 1256 break; 1257 case MPI2_EVENT_SAS_INIT_TABLE_OVERFLOW: 1258 desc = "SAS Init Table Overflow"; 1259 break; 1260 case MPI2_EVENT_SAS_TOPOLOGY_CHANGE_LIST: 1261 desc = "SAS Topology Change List"; 1262 break; 1263 case MPI2_EVENT_SAS_ENCL_DEVICE_STATUS_CHANGE: 1264 desc = "SAS Enclosure Device Status Change"; 1265 break; 1266 case MPI2_EVENT_IR_VOLUME: 1267 if (!ioc->hide_ir_msg) 1268 desc = "IR Volume"; 1269 break; 1270 case MPI2_EVENT_IR_PHYSICAL_DISK: 1271 if (!ioc->hide_ir_msg) 1272 desc = "IR Physical Disk"; 1273 break; 1274 case MPI2_EVENT_IR_CONFIGURATION_CHANGE_LIST: 1275 if (!ioc->hide_ir_msg) 1276 desc = "IR Configuration Change List"; 1277 break; 1278 case MPI2_EVENT_LOG_ENTRY_ADDED: 1279 if (!ioc->hide_ir_msg) 1280 desc = "Log Entry Added"; 1281 break; 1282 case MPI2_EVENT_TEMP_THRESHOLD: 1283 desc = "Temperature Threshold"; 1284 break; 1285 case MPI2_EVENT_ACTIVE_CABLE_EXCEPTION: 1286 desc = "Cable Event"; 1287 break; 1288 case MPI2_EVENT_SAS_DEVICE_DISCOVERY_ERROR: 1289 desc = "SAS Device Discovery Error"; 1290 break; 1291 case MPI2_EVENT_PCIE_DEVICE_STATUS_CHANGE: 1292 desc = "PCIE Device Status Change"; 1293 break; 1294 case MPI2_EVENT_PCIE_ENUMERATION: 1295 { 1296 Mpi26EventDataPCIeEnumeration_t *event_data = 1297 (Mpi26EventDataPCIeEnumeration_t *)mpi_reply->EventData; 1298 ioc_info(ioc, "PCIE Enumeration: (%s)", 1299 event_data->ReasonCode == MPI26_EVENT_PCIE_ENUM_RC_STARTED ? 1300 "start" : "stop"); 1301 if (event_data->EnumerationStatus) 1302 pr_cont("enumeration_status(0x%08x)", 1303 le32_to_cpu(event_data->EnumerationStatus)); 1304 pr_cont("\n"); 1305 return; 1306 } 1307 case MPI2_EVENT_PCIE_TOPOLOGY_CHANGE_LIST: 1308 desc = "PCIE Topology Change List"; 1309 break; 1310 } 1311 1312 if (!desc) 1313 return; 1314 1315 ioc_info(ioc, "%s\n", desc); 1316 } 1317 1318 /** 1319 * _base_sas_log_info - verbose translation of firmware log info 1320 * @ioc: per adapter object 1321 * @log_info: log info 1322 */ 1323 static void 1324 _base_sas_log_info(struct MPT3SAS_ADAPTER *ioc, u32 log_info) 1325 { 1326 union loginfo_type { 1327 u32 loginfo; 1328 struct { 1329 u32 subcode:16; 1330 u32 code:8; 1331 u32 originator:4; 1332 u32 bus_type:4; 1333 } dw; 1334 }; 1335 union loginfo_type sas_loginfo; 1336 char *originator_str = NULL; 1337 1338 sas_loginfo.loginfo = log_info; 1339 if (sas_loginfo.dw.bus_type != 3 /*SAS*/) 1340 return; 1341 1342 /* each nexus loss loginfo */ 1343 if (log_info == 0x31170000) 1344 return; 1345 1346 /* eat the loginfos associated with task aborts */ 1347 if (ioc->ignore_loginfos && (log_info == 0x30050000 || log_info == 1348 0x31140000 || log_info == 0x31130000)) 1349 return; 1350 1351 switch (sas_loginfo.dw.originator) { 1352 case 0: 1353 originator_str = "IOP"; 1354 break; 1355 case 1: 1356 originator_str = "PL"; 1357 break; 1358 case 2: 1359 if (!ioc->hide_ir_msg) 1360 originator_str = "IR"; 1361 else 1362 originator_str = "WarpDrive"; 1363 break; 1364 } 1365 1366 ioc_warn(ioc, "log_info(0x%08x): originator(%s), code(0x%02x), sub_code(0x%04x)\n", 1367 log_info, 1368 originator_str, sas_loginfo.dw.code, sas_loginfo.dw.subcode); 1369 } 1370 1371 /** 1372 * _base_display_reply_info - handle reply descriptors depending on IOC Status 1373 * @ioc: per adapter object 1374 * @smid: system request message index 1375 * @msix_index: MSIX table index supplied by the OS 1376 * @reply: reply message frame (lower 32bit addr) 1377 */ 1378 static void 1379 _base_display_reply_info(struct MPT3SAS_ADAPTER *ioc, u16 smid, u8 msix_index, 1380 u32 reply) 1381 { 1382 MPI2DefaultReply_t *mpi_reply; 1383 u16 ioc_status; 1384 u32 loginfo = 0; 1385 1386 mpi_reply = mpt3sas_base_get_reply_virt_addr(ioc, reply); 1387 if (unlikely(!mpi_reply)) { 1388 ioc_err(ioc, "mpi_reply not valid at %s:%d/%s()!\n", 1389 __FILE__, __LINE__, __func__); 1390 return; 1391 } 1392 ioc_status = le16_to_cpu(mpi_reply->IOCStatus); 1393 1394 if ((ioc_status & MPI2_IOCSTATUS_MASK) && 1395 (ioc->logging_level & MPT_DEBUG_REPLY)) { 1396 _base_sas_ioc_info(ioc, mpi_reply, 1397 mpt3sas_base_get_msg_frame(ioc, smid)); 1398 } 1399 1400 if (ioc_status & MPI2_IOCSTATUS_FLAG_LOG_INFO_AVAILABLE) { 1401 loginfo = le32_to_cpu(mpi_reply->IOCLogInfo); 1402 _base_sas_log_info(ioc, loginfo); 1403 } 1404 1405 if (ioc_status || loginfo) { 1406 ioc_status &= MPI2_IOCSTATUS_MASK; 1407 mpt3sas_trigger_mpi(ioc, ioc_status, loginfo); 1408 } 1409 } 1410 1411 /** 1412 * mpt3sas_base_done - base internal command completion routine 1413 * @ioc: per adapter object 1414 * @smid: system request message index 1415 * @msix_index: MSIX table index supplied by the OS 1416 * @reply: reply message frame(lower 32bit addr) 1417 * 1418 * Return: 1419 * 1 meaning mf should be freed from _base_interrupt 1420 * 0 means the mf is freed from this function. 1421 */ 1422 u8 1423 mpt3sas_base_done(struct MPT3SAS_ADAPTER *ioc, u16 smid, u8 msix_index, 1424 u32 reply) 1425 { 1426 MPI2DefaultReply_t *mpi_reply; 1427 1428 mpi_reply = mpt3sas_base_get_reply_virt_addr(ioc, reply); 1429 if (mpi_reply && mpi_reply->Function == MPI2_FUNCTION_EVENT_ACK) 1430 return mpt3sas_check_for_pending_internal_cmds(ioc, smid); 1431 1432 if (ioc->base_cmds.status == MPT3_CMD_NOT_USED) 1433 return 1; 1434 1435 ioc->base_cmds.status |= MPT3_CMD_COMPLETE; 1436 if (mpi_reply) { 1437 ioc->base_cmds.status |= MPT3_CMD_REPLY_VALID; 1438 memcpy(ioc->base_cmds.reply, mpi_reply, mpi_reply->MsgLength*4); 1439 } 1440 ioc->base_cmds.status &= ~MPT3_CMD_PENDING; 1441 1442 complete(&ioc->base_cmds.done); 1443 return 1; 1444 } 1445 1446 /** 1447 * _base_async_event - main callback handler for firmware asyn events 1448 * @ioc: per adapter object 1449 * @msix_index: MSIX table index supplied by the OS 1450 * @reply: reply message frame(lower 32bit addr) 1451 * 1452 * Return: 1453 * 1 meaning mf should be freed from _base_interrupt 1454 * 0 means the mf is freed from this function. 1455 */ 1456 static u8 1457 _base_async_event(struct MPT3SAS_ADAPTER *ioc, u8 msix_index, u32 reply) 1458 { 1459 Mpi2EventNotificationReply_t *mpi_reply; 1460 Mpi2EventAckRequest_t *ack_request; 1461 u16 smid; 1462 struct _event_ack_list *delayed_event_ack; 1463 1464 mpi_reply = mpt3sas_base_get_reply_virt_addr(ioc, reply); 1465 if (!mpi_reply) 1466 return 1; 1467 if (mpi_reply->Function != MPI2_FUNCTION_EVENT_NOTIFICATION) 1468 return 1; 1469 1470 _base_display_event_data(ioc, mpi_reply); 1471 1472 if (!(mpi_reply->AckRequired & MPI2_EVENT_NOTIFICATION_ACK_REQUIRED)) 1473 goto out; 1474 smid = mpt3sas_base_get_smid(ioc, ioc->base_cb_idx); 1475 if (!smid) { 1476 delayed_event_ack = kzalloc(sizeof(*delayed_event_ack), 1477 GFP_ATOMIC); 1478 if (!delayed_event_ack) 1479 goto out; 1480 INIT_LIST_HEAD(&delayed_event_ack->list); 1481 delayed_event_ack->Event = mpi_reply->Event; 1482 delayed_event_ack->EventContext = mpi_reply->EventContext; 1483 list_add_tail(&delayed_event_ack->list, 1484 &ioc->delayed_event_ack_list); 1485 dewtprintk(ioc, 1486 ioc_info(ioc, "DELAYED: EVENT ACK: event (0x%04x)\n", 1487 le16_to_cpu(mpi_reply->Event))); 1488 goto out; 1489 } 1490 1491 ack_request = mpt3sas_base_get_msg_frame(ioc, smid); 1492 memset(ack_request, 0, sizeof(Mpi2EventAckRequest_t)); 1493 ack_request->Function = MPI2_FUNCTION_EVENT_ACK; 1494 ack_request->Event = mpi_reply->Event; 1495 ack_request->EventContext = mpi_reply->EventContext; 1496 ack_request->VF_ID = 0; /* TODO */ 1497 ack_request->VP_ID = 0; 1498 ioc->put_smid_default(ioc, smid); 1499 1500 out: 1501 1502 /* scsih callback handler */ 1503 mpt3sas_scsih_event_callback(ioc, msix_index, reply); 1504 1505 /* ctl callback handler */ 1506 mpt3sas_ctl_event_callback(ioc, msix_index, reply); 1507 1508 return 1; 1509 } 1510 1511 static struct scsiio_tracker * 1512 _get_st_from_smid(struct MPT3SAS_ADAPTER *ioc, u16 smid) 1513 { 1514 struct scsi_cmnd *cmd; 1515 1516 if (WARN_ON(!smid) || 1517 WARN_ON(smid >= ioc->hi_priority_smid)) 1518 return NULL; 1519 1520 cmd = mpt3sas_scsih_scsi_lookup_get(ioc, smid); 1521 if (cmd) 1522 return scsi_cmd_priv(cmd); 1523 1524 return NULL; 1525 } 1526 1527 /** 1528 * _base_get_cb_idx - obtain the callback index 1529 * @ioc: per adapter object 1530 * @smid: system request message index 1531 * 1532 * Return: callback index. 1533 */ 1534 static u8 1535 _base_get_cb_idx(struct MPT3SAS_ADAPTER *ioc, u16 smid) 1536 { 1537 int i; 1538 u16 ctl_smid = ioc->scsiio_depth - INTERNAL_SCSIIO_CMDS_COUNT + 1; 1539 u8 cb_idx = 0xFF; 1540 1541 if (smid < ioc->hi_priority_smid) { 1542 struct scsiio_tracker *st; 1543 1544 if (smid < ctl_smid) { 1545 st = _get_st_from_smid(ioc, smid); 1546 if (st) 1547 cb_idx = st->cb_idx; 1548 } else if (smid == ctl_smid) 1549 cb_idx = ioc->ctl_cb_idx; 1550 } else if (smid < ioc->internal_smid) { 1551 i = smid - ioc->hi_priority_smid; 1552 cb_idx = ioc->hpr_lookup[i].cb_idx; 1553 } else if (smid <= ioc->hba_queue_depth) { 1554 i = smid - ioc->internal_smid; 1555 cb_idx = ioc->internal_lookup[i].cb_idx; 1556 } 1557 return cb_idx; 1558 } 1559 1560 /** 1561 * mpt3sas_base_pause_mq_polling - pause polling on the mq poll queues 1562 * when driver is flushing out the IOs. 1563 * @ioc: per adapter object 1564 * 1565 * Pause polling on the mq poll (io uring) queues when driver is flushing 1566 * out the IOs. Otherwise we may see the race condition of completing the same 1567 * IO from two paths. 1568 * 1569 * Returns nothing. 1570 */ 1571 void 1572 mpt3sas_base_pause_mq_polling(struct MPT3SAS_ADAPTER *ioc) 1573 { 1574 int iopoll_q_count = 1575 ioc->reply_queue_count - ioc->iopoll_q_start_index; 1576 int qid; 1577 1578 for (qid = 0; qid < iopoll_q_count; qid++) 1579 atomic_set(&ioc->io_uring_poll_queues[qid].pause, 1); 1580 1581 /* 1582 * wait for current poll to complete. 1583 */ 1584 for (qid = 0; qid < iopoll_q_count; qid++) { 1585 while (atomic_read(&ioc->io_uring_poll_queues[qid].busy)) { 1586 cpu_relax(); 1587 udelay(500); 1588 } 1589 } 1590 } 1591 1592 /** 1593 * mpt3sas_base_resume_mq_polling - Resume polling on mq poll queues. 1594 * @ioc: per adapter object 1595 * 1596 * Returns nothing. 1597 */ 1598 void 1599 mpt3sas_base_resume_mq_polling(struct MPT3SAS_ADAPTER *ioc) 1600 { 1601 int iopoll_q_count = 1602 ioc->reply_queue_count - ioc->iopoll_q_start_index; 1603 int qid; 1604 1605 for (qid = 0; qid < iopoll_q_count; qid++) 1606 atomic_set(&ioc->io_uring_poll_queues[qid].pause, 0); 1607 } 1608 1609 /** 1610 * mpt3sas_base_mask_interrupts - disable interrupts 1611 * @ioc: per adapter object 1612 * 1613 * Disabling ResetIRQ, Reply and Doorbell Interrupts 1614 */ 1615 void 1616 mpt3sas_base_mask_interrupts(struct MPT3SAS_ADAPTER *ioc) 1617 { 1618 u32 him_register; 1619 1620 ioc->mask_interrupts = 1; 1621 him_register = ioc->base_readl(&ioc->chip->HostInterruptMask); 1622 him_register |= MPI2_HIM_DIM + MPI2_HIM_RIM + MPI2_HIM_RESET_IRQ_MASK; 1623 writel(him_register, &ioc->chip->HostInterruptMask); 1624 ioc->base_readl(&ioc->chip->HostInterruptMask); 1625 } 1626 1627 /** 1628 * mpt3sas_base_unmask_interrupts - enable interrupts 1629 * @ioc: per adapter object 1630 * 1631 * Enabling only Reply Interrupts 1632 */ 1633 void 1634 mpt3sas_base_unmask_interrupts(struct MPT3SAS_ADAPTER *ioc) 1635 { 1636 u32 him_register; 1637 1638 him_register = ioc->base_readl(&ioc->chip->HostInterruptMask); 1639 him_register &= ~MPI2_HIM_RIM; 1640 writel(him_register, &ioc->chip->HostInterruptMask); 1641 ioc->mask_interrupts = 0; 1642 } 1643 1644 union reply_descriptor { 1645 u64 word; 1646 struct { 1647 u32 low; 1648 u32 high; 1649 } u; 1650 }; 1651 1652 static u32 base_mod64(u64 dividend, u32 divisor) 1653 { 1654 u32 remainder; 1655 1656 if (!divisor) 1657 pr_err("mpt3sas: DIVISOR is zero, in div fn\n"); 1658 remainder = do_div(dividend, divisor); 1659 return remainder; 1660 } 1661 1662 /** 1663 * _base_process_reply_queue - Process reply descriptors from reply 1664 * descriptor post queue. 1665 * @reply_q: per IRQ's reply queue object. 1666 * 1667 * Return: number of reply descriptors processed from reply 1668 * descriptor queue. 1669 */ 1670 static int 1671 _base_process_reply_queue(struct adapter_reply_queue *reply_q) 1672 { 1673 union reply_descriptor rd; 1674 u64 completed_cmds; 1675 u8 request_descript_type; 1676 u16 smid; 1677 u8 cb_idx; 1678 u32 reply; 1679 u8 msix_index = reply_q->msix_index; 1680 struct MPT3SAS_ADAPTER *ioc = reply_q->ioc; 1681 Mpi2ReplyDescriptorsUnion_t *rpf; 1682 u8 rc; 1683 1684 completed_cmds = 0; 1685 if (!atomic_add_unless(&reply_q->busy, 1, 1)) 1686 return completed_cmds; 1687 1688 rpf = &reply_q->reply_post_free[reply_q->reply_post_host_index]; 1689 request_descript_type = rpf->Default.ReplyFlags 1690 & MPI2_RPY_DESCRIPT_FLAGS_TYPE_MASK; 1691 if (request_descript_type == MPI2_RPY_DESCRIPT_FLAGS_UNUSED) { 1692 atomic_dec(&reply_q->busy); 1693 return completed_cmds; 1694 } 1695 1696 cb_idx = 0xFF; 1697 do { 1698 rd.word = le64_to_cpu(rpf->Words); 1699 if (rd.u.low == UINT_MAX || rd.u.high == UINT_MAX) 1700 goto out; 1701 reply = 0; 1702 smid = le16_to_cpu(rpf->Default.DescriptorTypeDependent1); 1703 if (request_descript_type == 1704 MPI25_RPY_DESCRIPT_FLAGS_FAST_PATH_SCSI_IO_SUCCESS || 1705 request_descript_type == 1706 MPI2_RPY_DESCRIPT_FLAGS_SCSI_IO_SUCCESS || 1707 request_descript_type == 1708 MPI26_RPY_DESCRIPT_FLAGS_PCIE_ENCAPSULATED_SUCCESS) { 1709 cb_idx = _base_get_cb_idx(ioc, smid); 1710 if ((likely(cb_idx < MPT_MAX_CALLBACKS)) && 1711 (likely(mpt_callbacks[cb_idx] != NULL))) { 1712 rc = mpt_callbacks[cb_idx](ioc, smid, 1713 msix_index, 0); 1714 if (rc) 1715 mpt3sas_base_free_smid(ioc, smid); 1716 } 1717 } else if (request_descript_type == 1718 MPI2_RPY_DESCRIPT_FLAGS_ADDRESS_REPLY) { 1719 reply = le32_to_cpu( 1720 rpf->AddressReply.ReplyFrameAddress); 1721 if (reply > ioc->reply_dma_max_address || 1722 reply < ioc->reply_dma_min_address) 1723 reply = 0; 1724 if (smid) { 1725 cb_idx = _base_get_cb_idx(ioc, smid); 1726 if ((likely(cb_idx < MPT_MAX_CALLBACKS)) && 1727 (likely(mpt_callbacks[cb_idx] != NULL))) { 1728 rc = mpt_callbacks[cb_idx](ioc, smid, 1729 msix_index, reply); 1730 if (reply) 1731 _base_display_reply_info(ioc, 1732 smid, msix_index, reply); 1733 if (rc) 1734 mpt3sas_base_free_smid(ioc, 1735 smid); 1736 } 1737 } else { 1738 _base_async_event(ioc, msix_index, reply); 1739 } 1740 1741 /* reply free queue handling */ 1742 if (reply) { 1743 ioc->reply_free_host_index = 1744 (ioc->reply_free_host_index == 1745 (ioc->reply_free_queue_depth - 1)) ? 1746 0 : ioc->reply_free_host_index + 1; 1747 ioc->reply_free[ioc->reply_free_host_index] = 1748 cpu_to_le32(reply); 1749 if (ioc->is_mcpu_endpoint) 1750 _base_clone_reply_to_sys_mem(ioc, 1751 reply, 1752 ioc->reply_free_host_index); 1753 writel(ioc->reply_free_host_index, 1754 &ioc->chip->ReplyFreeHostIndex); 1755 } 1756 } 1757 1758 rpf->Words = cpu_to_le64(ULLONG_MAX); 1759 reply_q->reply_post_host_index = 1760 (reply_q->reply_post_host_index == 1761 (ioc->reply_post_queue_depth - 1)) ? 0 : 1762 reply_q->reply_post_host_index + 1; 1763 request_descript_type = 1764 reply_q->reply_post_free[reply_q->reply_post_host_index]. 1765 Default.ReplyFlags & MPI2_RPY_DESCRIPT_FLAGS_TYPE_MASK; 1766 completed_cmds++; 1767 /* Update the reply post host index after continuously 1768 * processing the threshold number of Reply Descriptors. 1769 * So that FW can find enough entries to post the Reply 1770 * Descriptors in the reply descriptor post queue. 1771 */ 1772 if (completed_cmds >= ioc->thresh_hold) { 1773 if (ioc->combined_reply_queue) { 1774 writel(reply_q->reply_post_host_index | 1775 ((msix_index & 7) << 1776 MPI2_RPHI_MSIX_INDEX_SHIFT), 1777 ioc->replyPostRegisterIndex[msix_index/8]); 1778 } else { 1779 writel(reply_q->reply_post_host_index | 1780 (msix_index << 1781 MPI2_RPHI_MSIX_INDEX_SHIFT), 1782 &ioc->chip->ReplyPostHostIndex); 1783 } 1784 if (!reply_q->is_iouring_poll_q && 1785 !reply_q->irq_poll_scheduled) { 1786 reply_q->irq_poll_scheduled = true; 1787 irq_poll_sched(&reply_q->irqpoll); 1788 } 1789 atomic_dec(&reply_q->busy); 1790 return completed_cmds; 1791 } 1792 if (request_descript_type == MPI2_RPY_DESCRIPT_FLAGS_UNUSED) 1793 goto out; 1794 if (!reply_q->reply_post_host_index) 1795 rpf = reply_q->reply_post_free; 1796 else 1797 rpf++; 1798 } while (1); 1799 1800 out: 1801 1802 if (!completed_cmds) { 1803 atomic_dec(&reply_q->busy); 1804 return completed_cmds; 1805 } 1806 1807 if (ioc->is_warpdrive) { 1808 writel(reply_q->reply_post_host_index, 1809 ioc->reply_post_host_index[msix_index]); 1810 atomic_dec(&reply_q->busy); 1811 return completed_cmds; 1812 } 1813 1814 /* Update Reply Post Host Index. 1815 * For those HBA's which support combined reply queue feature 1816 * 1. Get the correct Supplemental Reply Post Host Index Register. 1817 * i.e. (msix_index / 8)th entry from Supplemental Reply Post Host 1818 * Index Register address bank i.e replyPostRegisterIndex[], 1819 * 2. Then update this register with new reply host index value 1820 * in ReplyPostIndex field and the MSIxIndex field with 1821 * msix_index value reduced to a value between 0 and 7, 1822 * using a modulo 8 operation. Since each Supplemental Reply Post 1823 * Host Index Register supports 8 MSI-X vectors. 1824 * 1825 * For other HBA's just update the Reply Post Host Index register with 1826 * new reply host index value in ReplyPostIndex Field and msix_index 1827 * value in MSIxIndex field. 1828 */ 1829 if (ioc->combined_reply_queue) 1830 writel(reply_q->reply_post_host_index | ((msix_index & 7) << 1831 MPI2_RPHI_MSIX_INDEX_SHIFT), 1832 ioc->replyPostRegisterIndex[msix_index/8]); 1833 else 1834 writel(reply_q->reply_post_host_index | (msix_index << 1835 MPI2_RPHI_MSIX_INDEX_SHIFT), 1836 &ioc->chip->ReplyPostHostIndex); 1837 atomic_dec(&reply_q->busy); 1838 return completed_cmds; 1839 } 1840 1841 /** 1842 * mpt3sas_blk_mq_poll - poll the blk mq poll queue 1843 * @shost: Scsi_Host object 1844 * @queue_num: hw ctx queue number 1845 * 1846 * Return number of entries that has been processed from poll queue. 1847 */ 1848 int mpt3sas_blk_mq_poll(struct Scsi_Host *shost, unsigned int queue_num) 1849 { 1850 struct MPT3SAS_ADAPTER *ioc = 1851 (struct MPT3SAS_ADAPTER *)shost->hostdata; 1852 struct adapter_reply_queue *reply_q; 1853 int num_entries = 0; 1854 int qid = queue_num - ioc->iopoll_q_start_index; 1855 1856 if (atomic_read(&ioc->io_uring_poll_queues[qid].pause) || 1857 !atomic_add_unless(&ioc->io_uring_poll_queues[qid].busy, 1, 1)) 1858 return 0; 1859 1860 reply_q = ioc->io_uring_poll_queues[qid].reply_q; 1861 1862 num_entries = _base_process_reply_queue(reply_q); 1863 atomic_dec(&ioc->io_uring_poll_queues[qid].busy); 1864 1865 return num_entries; 1866 } 1867 1868 /** 1869 * _base_interrupt - MPT adapter (IOC) specific interrupt handler. 1870 * @irq: irq number (not used) 1871 * @bus_id: bus identifier cookie == pointer to MPT_ADAPTER structure 1872 * 1873 * Return: IRQ_HANDLED if processed, else IRQ_NONE. 1874 */ 1875 static irqreturn_t 1876 _base_interrupt(int irq, void *bus_id) 1877 { 1878 struct adapter_reply_queue *reply_q = bus_id; 1879 struct MPT3SAS_ADAPTER *ioc = reply_q->ioc; 1880 1881 if (ioc->mask_interrupts) 1882 return IRQ_NONE; 1883 if (reply_q->irq_poll_scheduled) 1884 return IRQ_HANDLED; 1885 return ((_base_process_reply_queue(reply_q) > 0) ? 1886 IRQ_HANDLED : IRQ_NONE); 1887 } 1888 1889 /** 1890 * _base_irqpoll - IRQ poll callback handler 1891 * @irqpoll: irq_poll object 1892 * @budget: irq poll weight 1893 * 1894 * Return: number of reply descriptors processed 1895 */ 1896 static int 1897 _base_irqpoll(struct irq_poll *irqpoll, int budget) 1898 { 1899 struct adapter_reply_queue *reply_q; 1900 int num_entries = 0; 1901 1902 reply_q = container_of(irqpoll, struct adapter_reply_queue, 1903 irqpoll); 1904 if (reply_q->irq_line_enable) { 1905 disable_irq_nosync(reply_q->os_irq); 1906 reply_q->irq_line_enable = false; 1907 } 1908 num_entries = _base_process_reply_queue(reply_q); 1909 if (num_entries < budget) { 1910 irq_poll_complete(irqpoll); 1911 reply_q->irq_poll_scheduled = false; 1912 reply_q->irq_line_enable = true; 1913 enable_irq(reply_q->os_irq); 1914 /* 1915 * Go for one more round of processing the 1916 * reply descriptor post queue in case the HBA 1917 * Firmware has posted some reply descriptors 1918 * while reenabling the IRQ. 1919 */ 1920 _base_process_reply_queue(reply_q); 1921 } 1922 1923 return num_entries; 1924 } 1925 1926 /** 1927 * _base_init_irqpolls - initliaze IRQ polls 1928 * @ioc: per adapter object 1929 * 1930 * Return: nothing 1931 */ 1932 static void 1933 _base_init_irqpolls(struct MPT3SAS_ADAPTER *ioc) 1934 { 1935 struct adapter_reply_queue *reply_q, *next; 1936 1937 if (list_empty(&ioc->reply_queue_list)) 1938 return; 1939 1940 list_for_each_entry_safe(reply_q, next, &ioc->reply_queue_list, list) { 1941 if (reply_q->is_iouring_poll_q) 1942 continue; 1943 irq_poll_init(&reply_q->irqpoll, 1944 ioc->hba_queue_depth/4, _base_irqpoll); 1945 reply_q->irq_poll_scheduled = false; 1946 reply_q->irq_line_enable = true; 1947 reply_q->os_irq = pci_irq_vector(ioc->pdev, 1948 reply_q->msix_index); 1949 } 1950 } 1951 1952 /** 1953 * _base_is_controller_msix_enabled - is controller support muli-reply queues 1954 * @ioc: per adapter object 1955 * 1956 * Return: Whether or not MSI/X is enabled. 1957 */ 1958 static inline int 1959 _base_is_controller_msix_enabled(struct MPT3SAS_ADAPTER *ioc) 1960 { 1961 return (ioc->facts.IOCCapabilities & 1962 MPI2_IOCFACTS_CAPABILITY_MSI_X_INDEX) && ioc->msix_enable; 1963 } 1964 1965 /** 1966 * mpt3sas_base_sync_reply_irqs - flush pending MSIX interrupts 1967 * @ioc: per adapter object 1968 * @poll: poll over reply descriptor pools incase interrupt for 1969 * timed-out SCSI command got delayed 1970 * Context: non-ISR context 1971 * 1972 * Called when a Task Management request has completed. 1973 */ 1974 void 1975 mpt3sas_base_sync_reply_irqs(struct MPT3SAS_ADAPTER *ioc, u8 poll) 1976 { 1977 struct adapter_reply_queue *reply_q; 1978 1979 /* If MSIX capability is turned off 1980 * then multi-queues are not enabled 1981 */ 1982 if (!_base_is_controller_msix_enabled(ioc)) 1983 return; 1984 1985 list_for_each_entry(reply_q, &ioc->reply_queue_list, list) { 1986 if (ioc->shost_recovery || ioc->remove_host || 1987 ioc->pci_error_recovery) 1988 return; 1989 /* TMs are on msix_index == 0 */ 1990 if (reply_q->msix_index == 0) 1991 continue; 1992 1993 if (reply_q->is_iouring_poll_q) { 1994 _base_process_reply_queue(reply_q); 1995 continue; 1996 } 1997 1998 synchronize_irq(pci_irq_vector(ioc->pdev, reply_q->msix_index)); 1999 if (reply_q->irq_poll_scheduled) { 2000 /* Calling irq_poll_disable will wait for any pending 2001 * callbacks to have completed. 2002 */ 2003 irq_poll_disable(&reply_q->irqpoll); 2004 irq_poll_enable(&reply_q->irqpoll); 2005 /* check how the scheduled poll has ended, 2006 * clean up only if necessary 2007 */ 2008 if (reply_q->irq_poll_scheduled) { 2009 reply_q->irq_poll_scheduled = false; 2010 reply_q->irq_line_enable = true; 2011 enable_irq(reply_q->os_irq); 2012 } 2013 } 2014 2015 if (poll) 2016 _base_process_reply_queue(reply_q); 2017 } 2018 } 2019 2020 /** 2021 * mpt3sas_base_release_callback_handler - clear interrupt callback handler 2022 * @cb_idx: callback index 2023 */ 2024 void 2025 mpt3sas_base_release_callback_handler(u8 cb_idx) 2026 { 2027 mpt_callbacks[cb_idx] = NULL; 2028 } 2029 2030 /** 2031 * mpt3sas_base_register_callback_handler - obtain index for the interrupt callback handler 2032 * @cb_func: callback function 2033 * 2034 * Return: Index of @cb_func. 2035 */ 2036 u8 2037 mpt3sas_base_register_callback_handler(MPT_CALLBACK cb_func) 2038 { 2039 u8 cb_idx; 2040 2041 for (cb_idx = MPT_MAX_CALLBACKS-1; cb_idx; cb_idx--) 2042 if (mpt_callbacks[cb_idx] == NULL) 2043 break; 2044 2045 mpt_callbacks[cb_idx] = cb_func; 2046 return cb_idx; 2047 } 2048 2049 /** 2050 * mpt3sas_base_initialize_callback_handler - initialize the interrupt callback handler 2051 */ 2052 void 2053 mpt3sas_base_initialize_callback_handler(void) 2054 { 2055 u8 cb_idx; 2056 2057 for (cb_idx = 0; cb_idx < MPT_MAX_CALLBACKS; cb_idx++) 2058 mpt3sas_base_release_callback_handler(cb_idx); 2059 } 2060 2061 2062 /** 2063 * _base_build_zero_len_sge - build zero length sg entry 2064 * @ioc: per adapter object 2065 * @paddr: virtual address for SGE 2066 * 2067 * Create a zero length scatter gather entry to insure the IOCs hardware has 2068 * something to use if the target device goes brain dead and tries 2069 * to send data even when none is asked for. 2070 */ 2071 static void 2072 _base_build_zero_len_sge(struct MPT3SAS_ADAPTER *ioc, void *paddr) 2073 { 2074 u32 flags_length = (u32)((MPI2_SGE_FLAGS_LAST_ELEMENT | 2075 MPI2_SGE_FLAGS_END_OF_BUFFER | MPI2_SGE_FLAGS_END_OF_LIST | 2076 MPI2_SGE_FLAGS_SIMPLE_ELEMENT) << 2077 MPI2_SGE_FLAGS_SHIFT); 2078 ioc->base_add_sg_single(paddr, flags_length, -1); 2079 } 2080 2081 /** 2082 * _base_add_sg_single_32 - Place a simple 32 bit SGE at address pAddr. 2083 * @paddr: virtual address for SGE 2084 * @flags_length: SGE flags and data transfer length 2085 * @dma_addr: Physical address 2086 */ 2087 static void 2088 _base_add_sg_single_32(void *paddr, u32 flags_length, dma_addr_t dma_addr) 2089 { 2090 Mpi2SGESimple32_t *sgel = paddr; 2091 2092 flags_length |= (MPI2_SGE_FLAGS_32_BIT_ADDRESSING | 2093 MPI2_SGE_FLAGS_SYSTEM_ADDRESS) << MPI2_SGE_FLAGS_SHIFT; 2094 sgel->FlagsLength = cpu_to_le32(flags_length); 2095 sgel->Address = cpu_to_le32(dma_addr); 2096 } 2097 2098 2099 /** 2100 * _base_add_sg_single_64 - Place a simple 64 bit SGE at address pAddr. 2101 * @paddr: virtual address for SGE 2102 * @flags_length: SGE flags and data transfer length 2103 * @dma_addr: Physical address 2104 */ 2105 static void 2106 _base_add_sg_single_64(void *paddr, u32 flags_length, dma_addr_t dma_addr) 2107 { 2108 Mpi2SGESimple64_t *sgel = paddr; 2109 2110 flags_length |= (MPI2_SGE_FLAGS_64_BIT_ADDRESSING | 2111 MPI2_SGE_FLAGS_SYSTEM_ADDRESS) << MPI2_SGE_FLAGS_SHIFT; 2112 sgel->FlagsLength = cpu_to_le32(flags_length); 2113 sgel->Address = cpu_to_le64(dma_addr); 2114 } 2115 2116 /** 2117 * _base_get_chain_buffer_tracker - obtain chain tracker 2118 * @ioc: per adapter object 2119 * @scmd: SCSI commands of the IO request 2120 * 2121 * Return: chain tracker from chain_lookup table using key as 2122 * smid and smid's chain_offset. 2123 */ 2124 static struct chain_tracker * 2125 _base_get_chain_buffer_tracker(struct MPT3SAS_ADAPTER *ioc, 2126 struct scsi_cmnd *scmd) 2127 { 2128 struct chain_tracker *chain_req; 2129 struct scsiio_tracker *st = scsi_cmd_priv(scmd); 2130 u16 smid = st->smid; 2131 u8 chain_offset = 2132 atomic_read(&ioc->chain_lookup[smid - 1].chain_offset); 2133 2134 if (chain_offset == ioc->chains_needed_per_io) 2135 return NULL; 2136 2137 chain_req = &ioc->chain_lookup[smid - 1].chains_per_smid[chain_offset]; 2138 atomic_inc(&ioc->chain_lookup[smid - 1].chain_offset); 2139 return chain_req; 2140 } 2141 2142 2143 /** 2144 * _base_build_sg - build generic sg 2145 * @ioc: per adapter object 2146 * @psge: virtual address for SGE 2147 * @data_out_dma: physical address for WRITES 2148 * @data_out_sz: data xfer size for WRITES 2149 * @data_in_dma: physical address for READS 2150 * @data_in_sz: data xfer size for READS 2151 */ 2152 static void 2153 _base_build_sg(struct MPT3SAS_ADAPTER *ioc, void *psge, 2154 dma_addr_t data_out_dma, size_t data_out_sz, dma_addr_t data_in_dma, 2155 size_t data_in_sz) 2156 { 2157 u32 sgl_flags; 2158 2159 if (!data_out_sz && !data_in_sz) { 2160 _base_build_zero_len_sge(ioc, psge); 2161 return; 2162 } 2163 2164 if (data_out_sz && data_in_sz) { 2165 /* WRITE sgel first */ 2166 sgl_flags = (MPI2_SGE_FLAGS_SIMPLE_ELEMENT | 2167 MPI2_SGE_FLAGS_END_OF_BUFFER | MPI2_SGE_FLAGS_HOST_TO_IOC); 2168 sgl_flags = sgl_flags << MPI2_SGE_FLAGS_SHIFT; 2169 ioc->base_add_sg_single(psge, sgl_flags | 2170 data_out_sz, data_out_dma); 2171 2172 /* incr sgel */ 2173 psge += ioc->sge_size; 2174 2175 /* READ sgel last */ 2176 sgl_flags = (MPI2_SGE_FLAGS_SIMPLE_ELEMENT | 2177 MPI2_SGE_FLAGS_LAST_ELEMENT | MPI2_SGE_FLAGS_END_OF_BUFFER | 2178 MPI2_SGE_FLAGS_END_OF_LIST); 2179 sgl_flags = sgl_flags << MPI2_SGE_FLAGS_SHIFT; 2180 ioc->base_add_sg_single(psge, sgl_flags | 2181 data_in_sz, data_in_dma); 2182 } else if (data_out_sz) /* WRITE */ { 2183 sgl_flags = (MPI2_SGE_FLAGS_SIMPLE_ELEMENT | 2184 MPI2_SGE_FLAGS_LAST_ELEMENT | MPI2_SGE_FLAGS_END_OF_BUFFER | 2185 MPI2_SGE_FLAGS_END_OF_LIST | MPI2_SGE_FLAGS_HOST_TO_IOC); 2186 sgl_flags = sgl_flags << MPI2_SGE_FLAGS_SHIFT; 2187 ioc->base_add_sg_single(psge, sgl_flags | 2188 data_out_sz, data_out_dma); 2189 } else if (data_in_sz) /* READ */ { 2190 sgl_flags = (MPI2_SGE_FLAGS_SIMPLE_ELEMENT | 2191 MPI2_SGE_FLAGS_LAST_ELEMENT | MPI2_SGE_FLAGS_END_OF_BUFFER | 2192 MPI2_SGE_FLAGS_END_OF_LIST); 2193 sgl_flags = sgl_flags << MPI2_SGE_FLAGS_SHIFT; 2194 ioc->base_add_sg_single(psge, sgl_flags | 2195 data_in_sz, data_in_dma); 2196 } 2197 } 2198 2199 /* IEEE format sgls */ 2200 2201 /** 2202 * _base_build_nvme_prp - This function is called for NVMe end devices to build 2203 * a native SGL (NVMe PRP). 2204 * @ioc: per adapter object 2205 * @smid: system request message index for getting asscociated SGL 2206 * @nvme_encap_request: the NVMe request msg frame pointer 2207 * @data_out_dma: physical address for WRITES 2208 * @data_out_sz: data xfer size for WRITES 2209 * @data_in_dma: physical address for READS 2210 * @data_in_sz: data xfer size for READS 2211 * 2212 * The native SGL is built starting in the first PRP 2213 * entry of the NVMe message (PRP1). If the data buffer is small enough to be 2214 * described entirely using PRP1, then PRP2 is not used. If needed, PRP2 is 2215 * used to describe a larger data buffer. If the data buffer is too large to 2216 * describe using the two PRP entriess inside the NVMe message, then PRP1 2217 * describes the first data memory segment, and PRP2 contains a pointer to a PRP 2218 * list located elsewhere in memory to describe the remaining data memory 2219 * segments. The PRP list will be contiguous. 2220 * 2221 * The native SGL for NVMe devices is a Physical Region Page (PRP). A PRP 2222 * consists of a list of PRP entries to describe a number of noncontigous 2223 * physical memory segments as a single memory buffer, just as a SGL does. Note 2224 * however, that this function is only used by the IOCTL call, so the memory 2225 * given will be guaranteed to be contiguous. There is no need to translate 2226 * non-contiguous SGL into a PRP in this case. All PRPs will describe 2227 * contiguous space that is one page size each. 2228 * 2229 * Each NVMe message contains two PRP entries. The first (PRP1) either contains 2230 * a PRP list pointer or a PRP element, depending upon the command. PRP2 2231 * contains the second PRP element if the memory being described fits within 2 2232 * PRP entries, or a PRP list pointer if the PRP spans more than two entries. 2233 * 2234 * A PRP list pointer contains the address of a PRP list, structured as a linear 2235 * array of PRP entries. Each PRP entry in this list describes a segment of 2236 * physical memory. 2237 * 2238 * Each 64-bit PRP entry comprises an address and an offset field. The address 2239 * always points at the beginning of a 4KB physical memory page, and the offset 2240 * describes where within that 4KB page the memory segment begins. Only the 2241 * first element in a PRP list may contain a non-zero offset, implying that all 2242 * memory segments following the first begin at the start of a 4KB page. 2243 * 2244 * Each PRP element normally describes 4KB of physical memory, with exceptions 2245 * for the first and last elements in the list. If the memory being described 2246 * by the list begins at a non-zero offset within the first 4KB page, then the 2247 * first PRP element will contain a non-zero offset indicating where the region 2248 * begins within the 4KB page. The last memory segment may end before the end 2249 * of the 4KB segment, depending upon the overall size of the memory being 2250 * described by the PRP list. 2251 * 2252 * Since PRP entries lack any indication of size, the overall data buffer length 2253 * is used to determine where the end of the data memory buffer is located, and 2254 * how many PRP entries are required to describe it. 2255 */ 2256 static void 2257 _base_build_nvme_prp(struct MPT3SAS_ADAPTER *ioc, u16 smid, 2258 Mpi26NVMeEncapsulatedRequest_t *nvme_encap_request, 2259 dma_addr_t data_out_dma, size_t data_out_sz, dma_addr_t data_in_dma, 2260 size_t data_in_sz) 2261 { 2262 int prp_size = NVME_PRP_SIZE; 2263 __le64 *prp_entry, *prp1_entry, *prp2_entry; 2264 __le64 *prp_page; 2265 dma_addr_t prp_entry_dma, prp_page_dma, dma_addr; 2266 u32 offset, entry_len; 2267 u32 page_mask_result, page_mask; 2268 size_t length; 2269 struct mpt3sas_nvme_cmd *nvme_cmd = 2270 (void *)nvme_encap_request->NVMe_Command; 2271 2272 /* 2273 * Not all commands require a data transfer. If no data, just return 2274 * without constructing any PRP. 2275 */ 2276 if (!data_in_sz && !data_out_sz) 2277 return; 2278 prp1_entry = &nvme_cmd->prp1; 2279 prp2_entry = &nvme_cmd->prp2; 2280 prp_entry = prp1_entry; 2281 /* 2282 * For the PRP entries, use the specially allocated buffer of 2283 * contiguous memory. 2284 */ 2285 prp_page = (__le64 *)mpt3sas_base_get_pcie_sgl(ioc, smid); 2286 prp_page_dma = mpt3sas_base_get_pcie_sgl_dma(ioc, smid); 2287 2288 /* 2289 * Check if we are within 1 entry of a page boundary we don't 2290 * want our first entry to be a PRP List entry. 2291 */ 2292 page_mask = ioc->page_size - 1; 2293 page_mask_result = (uintptr_t)((u8 *)prp_page + prp_size) & page_mask; 2294 if (!page_mask_result) { 2295 /* Bump up to next page boundary. */ 2296 prp_page = (__le64 *)((u8 *)prp_page + prp_size); 2297 prp_page_dma = prp_page_dma + prp_size; 2298 } 2299 2300 /* 2301 * Set PRP physical pointer, which initially points to the current PRP 2302 * DMA memory page. 2303 */ 2304 prp_entry_dma = prp_page_dma; 2305 2306 /* Get physical address and length of the data buffer. */ 2307 if (data_in_sz) { 2308 dma_addr = data_in_dma; 2309 length = data_in_sz; 2310 } else { 2311 dma_addr = data_out_dma; 2312 length = data_out_sz; 2313 } 2314 2315 /* Loop while the length is not zero. */ 2316 while (length) { 2317 /* 2318 * Check if we need to put a list pointer here if we are at 2319 * page boundary - prp_size (8 bytes). 2320 */ 2321 page_mask_result = (prp_entry_dma + prp_size) & page_mask; 2322 if (!page_mask_result) { 2323 /* 2324 * This is the last entry in a PRP List, so we need to 2325 * put a PRP list pointer here. What this does is: 2326 * - bump the current memory pointer to the next 2327 * address, which will be the next full page. 2328 * - set the PRP Entry to point to that page. This 2329 * is now the PRP List pointer. 2330 * - bump the PRP Entry pointer the start of the 2331 * next page. Since all of this PRP memory is 2332 * contiguous, no need to get a new page - it's 2333 * just the next address. 2334 */ 2335 prp_entry_dma++; 2336 *prp_entry = cpu_to_le64(prp_entry_dma); 2337 prp_entry++; 2338 } 2339 2340 /* Need to handle if entry will be part of a page. */ 2341 offset = dma_addr & page_mask; 2342 entry_len = ioc->page_size - offset; 2343 2344 if (prp_entry == prp1_entry) { 2345 /* 2346 * Must fill in the first PRP pointer (PRP1) before 2347 * moving on. 2348 */ 2349 *prp1_entry = cpu_to_le64(dma_addr); 2350 2351 /* 2352 * Now point to the second PRP entry within the 2353 * command (PRP2). 2354 */ 2355 prp_entry = prp2_entry; 2356 } else if (prp_entry == prp2_entry) { 2357 /* 2358 * Should the PRP2 entry be a PRP List pointer or just 2359 * a regular PRP pointer? If there is more than one 2360 * more page of data, must use a PRP List pointer. 2361 */ 2362 if (length > ioc->page_size) { 2363 /* 2364 * PRP2 will contain a PRP List pointer because 2365 * more PRP's are needed with this command. The 2366 * list will start at the beginning of the 2367 * contiguous buffer. 2368 */ 2369 *prp2_entry = cpu_to_le64(prp_entry_dma); 2370 2371 /* 2372 * The next PRP Entry will be the start of the 2373 * first PRP List. 2374 */ 2375 prp_entry = prp_page; 2376 } else { 2377 /* 2378 * After this, the PRP Entries are complete. 2379 * This command uses 2 PRP's and no PRP list. 2380 */ 2381 *prp2_entry = cpu_to_le64(dma_addr); 2382 } 2383 } else { 2384 /* 2385 * Put entry in list and bump the addresses. 2386 * 2387 * After PRP1 and PRP2 are filled in, this will fill in 2388 * all remaining PRP entries in a PRP List, one per 2389 * each time through the loop. 2390 */ 2391 *prp_entry = cpu_to_le64(dma_addr); 2392 prp_entry++; 2393 prp_entry_dma++; 2394 } 2395 2396 /* 2397 * Bump the phys address of the command's data buffer by the 2398 * entry_len. 2399 */ 2400 dma_addr += entry_len; 2401 2402 /* Decrement length accounting for last partial page. */ 2403 if (entry_len > length) 2404 length = 0; 2405 else 2406 length -= entry_len; 2407 } 2408 } 2409 2410 /** 2411 * base_make_prp_nvme - Prepare PRPs (Physical Region Page) - 2412 * SGLs specific to NVMe drives only 2413 * 2414 * @ioc: per adapter object 2415 * @scmd: SCSI command from the mid-layer 2416 * @mpi_request: mpi request 2417 * @smid: msg Index 2418 * @sge_count: scatter gather element count. 2419 * 2420 * Return: true: PRPs are built 2421 * false: IEEE SGLs needs to be built 2422 */ 2423 static void 2424 base_make_prp_nvme(struct MPT3SAS_ADAPTER *ioc, 2425 struct scsi_cmnd *scmd, 2426 Mpi25SCSIIORequest_t *mpi_request, 2427 u16 smid, int sge_count) 2428 { 2429 int sge_len, num_prp_in_chain = 0; 2430 Mpi25IeeeSgeChain64_t *main_chain_element, *ptr_first_sgl; 2431 __le64 *curr_buff; 2432 dma_addr_t msg_dma, sge_addr, offset; 2433 u32 page_mask, page_mask_result; 2434 struct scatterlist *sg_scmd; 2435 u32 first_prp_len; 2436 int data_len = scsi_bufflen(scmd); 2437 u32 nvme_pg_size; 2438 2439 nvme_pg_size = max_t(u32, ioc->page_size, NVME_PRP_PAGE_SIZE); 2440 /* 2441 * Nvme has a very convoluted prp format. One prp is required 2442 * for each page or partial page. Driver need to split up OS sg_list 2443 * entries if it is longer than one page or cross a page 2444 * boundary. Driver also have to insert a PRP list pointer entry as 2445 * the last entry in each physical page of the PRP list. 2446 * 2447 * NOTE: The first PRP "entry" is actually placed in the first 2448 * SGL entry in the main message as IEEE 64 format. The 2nd 2449 * entry in the main message is the chain element, and the rest 2450 * of the PRP entries are built in the contiguous pcie buffer. 2451 */ 2452 page_mask = nvme_pg_size - 1; 2453 2454 /* 2455 * Native SGL is needed. 2456 * Put a chain element in main message frame that points to the first 2457 * chain buffer. 2458 * 2459 * NOTE: The ChainOffset field must be 0 when using a chain pointer to 2460 * a native SGL. 2461 */ 2462 2463 /* Set main message chain element pointer */ 2464 main_chain_element = (pMpi25IeeeSgeChain64_t)&mpi_request->SGL; 2465 /* 2466 * For NVMe the chain element needs to be the 2nd SG entry in the main 2467 * message. 2468 */ 2469 main_chain_element = (Mpi25IeeeSgeChain64_t *) 2470 ((u8 *)main_chain_element + sizeof(MPI25_IEEE_SGE_CHAIN64)); 2471 2472 /* 2473 * For the PRP entries, use the specially allocated buffer of 2474 * contiguous memory. Normal chain buffers can't be used 2475 * because each chain buffer would need to be the size of an OS 2476 * page (4k). 2477 */ 2478 curr_buff = mpt3sas_base_get_pcie_sgl(ioc, smid); 2479 msg_dma = mpt3sas_base_get_pcie_sgl_dma(ioc, smid); 2480 2481 main_chain_element->Address = cpu_to_le64(msg_dma); 2482 main_chain_element->NextChainOffset = 0; 2483 main_chain_element->Flags = MPI2_IEEE_SGE_FLAGS_CHAIN_ELEMENT | 2484 MPI2_IEEE_SGE_FLAGS_SYSTEM_ADDR | 2485 MPI26_IEEE_SGE_FLAGS_NSF_NVME_PRP; 2486 2487 /* Build first prp, sge need not to be page aligned*/ 2488 ptr_first_sgl = (pMpi25IeeeSgeChain64_t)&mpi_request->SGL; 2489 sg_scmd = scsi_sglist(scmd); 2490 sge_addr = sg_dma_address(sg_scmd); 2491 sge_len = sg_dma_len(sg_scmd); 2492 2493 offset = sge_addr & page_mask; 2494 first_prp_len = nvme_pg_size - offset; 2495 2496 ptr_first_sgl->Address = cpu_to_le64(sge_addr); 2497 ptr_first_sgl->Length = cpu_to_le32(first_prp_len); 2498 2499 data_len -= first_prp_len; 2500 2501 if (sge_len > first_prp_len) { 2502 sge_addr += first_prp_len; 2503 sge_len -= first_prp_len; 2504 } else if (data_len && (sge_len == first_prp_len)) { 2505 sg_scmd = sg_next(sg_scmd); 2506 sge_addr = sg_dma_address(sg_scmd); 2507 sge_len = sg_dma_len(sg_scmd); 2508 } 2509 2510 for (;;) { 2511 offset = sge_addr & page_mask; 2512 2513 /* Put PRP pointer due to page boundary*/ 2514 page_mask_result = (uintptr_t)(curr_buff + 1) & page_mask; 2515 if (unlikely(!page_mask_result)) { 2516 scmd_printk(KERN_NOTICE, 2517 scmd, "page boundary curr_buff: 0x%p\n", 2518 curr_buff); 2519 msg_dma += 8; 2520 *curr_buff = cpu_to_le64(msg_dma); 2521 curr_buff++; 2522 num_prp_in_chain++; 2523 } 2524 2525 *curr_buff = cpu_to_le64(sge_addr); 2526 curr_buff++; 2527 msg_dma += 8; 2528 num_prp_in_chain++; 2529 2530 sge_addr += nvme_pg_size; 2531 sge_len -= nvme_pg_size; 2532 data_len -= nvme_pg_size; 2533 2534 if (data_len <= 0) 2535 break; 2536 2537 if (sge_len > 0) 2538 continue; 2539 2540 sg_scmd = sg_next(sg_scmd); 2541 sge_addr = sg_dma_address(sg_scmd); 2542 sge_len = sg_dma_len(sg_scmd); 2543 } 2544 2545 main_chain_element->Length = 2546 cpu_to_le32(num_prp_in_chain * sizeof(u64)); 2547 return; 2548 } 2549 2550 static bool 2551 base_is_prp_possible(struct MPT3SAS_ADAPTER *ioc, 2552 struct _pcie_device *pcie_device, struct scsi_cmnd *scmd, int sge_count) 2553 { 2554 u32 data_length = 0; 2555 bool build_prp = true; 2556 2557 data_length = scsi_bufflen(scmd); 2558 if (pcie_device && 2559 (mpt3sas_scsih_is_pcie_scsi_device(pcie_device->device_info))) { 2560 build_prp = false; 2561 return build_prp; 2562 } 2563 2564 /* If Datalenth is <= 16K and number of SGE’s entries are <= 2 2565 * we built IEEE SGL 2566 */ 2567 if ((data_length <= NVME_PRP_PAGE_SIZE*4) && (sge_count <= 2)) 2568 build_prp = false; 2569 2570 return build_prp; 2571 } 2572 2573 /** 2574 * _base_check_pcie_native_sgl - This function is called for PCIe end devices to 2575 * determine if the driver needs to build a native SGL. If so, that native 2576 * SGL is built in the special contiguous buffers allocated especially for 2577 * PCIe SGL creation. If the driver will not build a native SGL, return 2578 * TRUE and a normal IEEE SGL will be built. Currently this routine 2579 * supports NVMe. 2580 * @ioc: per adapter object 2581 * @mpi_request: mf request pointer 2582 * @smid: system request message index 2583 * @scmd: scsi command 2584 * @pcie_device: points to the PCIe device's info 2585 * 2586 * Return: 0 if native SGL was built, 1 if no SGL was built 2587 */ 2588 static int 2589 _base_check_pcie_native_sgl(struct MPT3SAS_ADAPTER *ioc, 2590 Mpi25SCSIIORequest_t *mpi_request, u16 smid, struct scsi_cmnd *scmd, 2591 struct _pcie_device *pcie_device) 2592 { 2593 int sges_left; 2594 2595 /* Get the SG list pointer and info. */ 2596 sges_left = scsi_dma_map(scmd); 2597 if (sges_left < 0) 2598 return 1; 2599 2600 /* Check if we need to build a native SG list. */ 2601 if (!base_is_prp_possible(ioc, pcie_device, 2602 scmd, sges_left)) { 2603 /* We built a native SG list, just return. */ 2604 goto out; 2605 } 2606 2607 /* 2608 * Build native NVMe PRP. 2609 */ 2610 base_make_prp_nvme(ioc, scmd, mpi_request, 2611 smid, sges_left); 2612 2613 return 0; 2614 out: 2615 scsi_dma_unmap(scmd); 2616 return 1; 2617 } 2618 2619 /** 2620 * _base_add_sg_single_ieee - add sg element for IEEE format 2621 * @paddr: virtual address for SGE 2622 * @flags: SGE flags 2623 * @chain_offset: number of 128 byte elements from start of segment 2624 * @length: data transfer length 2625 * @dma_addr: Physical address 2626 */ 2627 static void 2628 _base_add_sg_single_ieee(void *paddr, u8 flags, u8 chain_offset, u32 length, 2629 dma_addr_t dma_addr) 2630 { 2631 Mpi25IeeeSgeChain64_t *sgel = paddr; 2632 2633 sgel->Flags = flags; 2634 sgel->NextChainOffset = chain_offset; 2635 sgel->Length = cpu_to_le32(length); 2636 sgel->Address = cpu_to_le64(dma_addr); 2637 } 2638 2639 /** 2640 * _base_build_zero_len_sge_ieee - build zero length sg entry for IEEE format 2641 * @ioc: per adapter object 2642 * @paddr: virtual address for SGE 2643 * 2644 * Create a zero length scatter gather entry to insure the IOCs hardware has 2645 * something to use if the target device goes brain dead and tries 2646 * to send data even when none is asked for. 2647 */ 2648 static void 2649 _base_build_zero_len_sge_ieee(struct MPT3SAS_ADAPTER *ioc, void *paddr) 2650 { 2651 u8 sgl_flags = (MPI2_IEEE_SGE_FLAGS_SIMPLE_ELEMENT | 2652 MPI2_IEEE_SGE_FLAGS_SYSTEM_ADDR | 2653 MPI25_IEEE_SGE_FLAGS_END_OF_LIST); 2654 2655 _base_add_sg_single_ieee(paddr, sgl_flags, 0, 0, -1); 2656 } 2657 2658 /** 2659 * _base_build_sg_scmd - main sg creation routine 2660 * pcie_device is unused here! 2661 * @ioc: per adapter object 2662 * @scmd: scsi command 2663 * @smid: system request message index 2664 * @unused: unused pcie_device pointer 2665 * Context: none. 2666 * 2667 * The main routine that builds scatter gather table from a given 2668 * scsi request sent via the .queuecommand main handler. 2669 * 2670 * Return: 0 success, anything else error 2671 */ 2672 static int 2673 _base_build_sg_scmd(struct MPT3SAS_ADAPTER *ioc, 2674 struct scsi_cmnd *scmd, u16 smid, struct _pcie_device *unused) 2675 { 2676 Mpi2SCSIIORequest_t *mpi_request; 2677 dma_addr_t chain_dma; 2678 struct scatterlist *sg_scmd; 2679 void *sg_local, *chain; 2680 u32 chain_offset; 2681 u32 chain_length; 2682 u32 chain_flags; 2683 int sges_left; 2684 u32 sges_in_segment; 2685 u32 sgl_flags; 2686 u32 sgl_flags_last_element; 2687 u32 sgl_flags_end_buffer; 2688 struct chain_tracker *chain_req; 2689 2690 mpi_request = mpt3sas_base_get_msg_frame(ioc, smid); 2691 2692 /* init scatter gather flags */ 2693 sgl_flags = MPI2_SGE_FLAGS_SIMPLE_ELEMENT; 2694 if (scmd->sc_data_direction == DMA_TO_DEVICE) 2695 sgl_flags |= MPI2_SGE_FLAGS_HOST_TO_IOC; 2696 sgl_flags_last_element = (sgl_flags | MPI2_SGE_FLAGS_LAST_ELEMENT) 2697 << MPI2_SGE_FLAGS_SHIFT; 2698 sgl_flags_end_buffer = (sgl_flags | MPI2_SGE_FLAGS_LAST_ELEMENT | 2699 MPI2_SGE_FLAGS_END_OF_BUFFER | MPI2_SGE_FLAGS_END_OF_LIST) 2700 << MPI2_SGE_FLAGS_SHIFT; 2701 sgl_flags = sgl_flags << MPI2_SGE_FLAGS_SHIFT; 2702 2703 sg_scmd = scsi_sglist(scmd); 2704 sges_left = scsi_dma_map(scmd); 2705 if (sges_left < 0) 2706 return -ENOMEM; 2707 2708 sg_local = &mpi_request->SGL; 2709 sges_in_segment = ioc->max_sges_in_main_message; 2710 if (sges_left <= sges_in_segment) 2711 goto fill_in_last_segment; 2712 2713 mpi_request->ChainOffset = (offsetof(Mpi2SCSIIORequest_t, SGL) + 2714 (sges_in_segment * ioc->sge_size))/4; 2715 2716 /* fill in main message segment when there is a chain following */ 2717 while (sges_in_segment) { 2718 if (sges_in_segment == 1) 2719 ioc->base_add_sg_single(sg_local, 2720 sgl_flags_last_element | sg_dma_len(sg_scmd), 2721 sg_dma_address(sg_scmd)); 2722 else 2723 ioc->base_add_sg_single(sg_local, sgl_flags | 2724 sg_dma_len(sg_scmd), sg_dma_address(sg_scmd)); 2725 sg_scmd = sg_next(sg_scmd); 2726 sg_local += ioc->sge_size; 2727 sges_left--; 2728 sges_in_segment--; 2729 } 2730 2731 /* initializing the chain flags and pointers */ 2732 chain_flags = MPI2_SGE_FLAGS_CHAIN_ELEMENT << MPI2_SGE_FLAGS_SHIFT; 2733 chain_req = _base_get_chain_buffer_tracker(ioc, scmd); 2734 if (!chain_req) 2735 return -1; 2736 chain = chain_req->chain_buffer; 2737 chain_dma = chain_req->chain_buffer_dma; 2738 do { 2739 sges_in_segment = (sges_left <= 2740 ioc->max_sges_in_chain_message) ? sges_left : 2741 ioc->max_sges_in_chain_message; 2742 chain_offset = (sges_left == sges_in_segment) ? 2743 0 : (sges_in_segment * ioc->sge_size)/4; 2744 chain_length = sges_in_segment * ioc->sge_size; 2745 if (chain_offset) { 2746 chain_offset = chain_offset << 2747 MPI2_SGE_CHAIN_OFFSET_SHIFT; 2748 chain_length += ioc->sge_size; 2749 } 2750 ioc->base_add_sg_single(sg_local, chain_flags | chain_offset | 2751 chain_length, chain_dma); 2752 sg_local = chain; 2753 if (!chain_offset) 2754 goto fill_in_last_segment; 2755 2756 /* fill in chain segments */ 2757 while (sges_in_segment) { 2758 if (sges_in_segment == 1) 2759 ioc->base_add_sg_single(sg_local, 2760 sgl_flags_last_element | 2761 sg_dma_len(sg_scmd), 2762 sg_dma_address(sg_scmd)); 2763 else 2764 ioc->base_add_sg_single(sg_local, sgl_flags | 2765 sg_dma_len(sg_scmd), 2766 sg_dma_address(sg_scmd)); 2767 sg_scmd = sg_next(sg_scmd); 2768 sg_local += ioc->sge_size; 2769 sges_left--; 2770 sges_in_segment--; 2771 } 2772 2773 chain_req = _base_get_chain_buffer_tracker(ioc, scmd); 2774 if (!chain_req) 2775 return -1; 2776 chain = chain_req->chain_buffer; 2777 chain_dma = chain_req->chain_buffer_dma; 2778 } while (1); 2779 2780 2781 fill_in_last_segment: 2782 2783 /* fill the last segment */ 2784 while (sges_left) { 2785 if (sges_left == 1) 2786 ioc->base_add_sg_single(sg_local, sgl_flags_end_buffer | 2787 sg_dma_len(sg_scmd), sg_dma_address(sg_scmd)); 2788 else 2789 ioc->base_add_sg_single(sg_local, sgl_flags | 2790 sg_dma_len(sg_scmd), sg_dma_address(sg_scmd)); 2791 sg_scmd = sg_next(sg_scmd); 2792 sg_local += ioc->sge_size; 2793 sges_left--; 2794 } 2795 2796 return 0; 2797 } 2798 2799 /** 2800 * _base_build_sg_scmd_ieee - main sg creation routine for IEEE format 2801 * @ioc: per adapter object 2802 * @scmd: scsi command 2803 * @smid: system request message index 2804 * @pcie_device: Pointer to pcie_device. If set, the pcie native sgl will be 2805 * constructed on need. 2806 * Context: none. 2807 * 2808 * The main routine that builds scatter gather table from a given 2809 * scsi request sent via the .queuecommand main handler. 2810 * 2811 * Return: 0 success, anything else error 2812 */ 2813 static int 2814 _base_build_sg_scmd_ieee(struct MPT3SAS_ADAPTER *ioc, 2815 struct scsi_cmnd *scmd, u16 smid, struct _pcie_device *pcie_device) 2816 { 2817 Mpi25SCSIIORequest_t *mpi_request; 2818 dma_addr_t chain_dma; 2819 struct scatterlist *sg_scmd; 2820 void *sg_local, *chain; 2821 u32 chain_offset; 2822 u32 chain_length; 2823 int sges_left; 2824 u32 sges_in_segment; 2825 u8 simple_sgl_flags; 2826 u8 simple_sgl_flags_last; 2827 u8 chain_sgl_flags; 2828 struct chain_tracker *chain_req; 2829 2830 mpi_request = mpt3sas_base_get_msg_frame(ioc, smid); 2831 2832 /* init scatter gather flags */ 2833 simple_sgl_flags = MPI2_IEEE_SGE_FLAGS_SIMPLE_ELEMENT | 2834 MPI2_IEEE_SGE_FLAGS_SYSTEM_ADDR; 2835 simple_sgl_flags_last = simple_sgl_flags | 2836 MPI25_IEEE_SGE_FLAGS_END_OF_LIST; 2837 chain_sgl_flags = MPI2_IEEE_SGE_FLAGS_CHAIN_ELEMENT | 2838 MPI2_IEEE_SGE_FLAGS_SYSTEM_ADDR; 2839 2840 /* Check if we need to build a native SG list. */ 2841 if ((pcie_device) && (_base_check_pcie_native_sgl(ioc, mpi_request, 2842 smid, scmd, pcie_device) == 0)) { 2843 /* We built a native SG list, just return. */ 2844 return 0; 2845 } 2846 2847 sg_scmd = scsi_sglist(scmd); 2848 sges_left = scsi_dma_map(scmd); 2849 if (sges_left < 0) 2850 return -ENOMEM; 2851 2852 sg_local = &mpi_request->SGL; 2853 sges_in_segment = (ioc->request_sz - 2854 offsetof(Mpi25SCSIIORequest_t, SGL))/ioc->sge_size_ieee; 2855 if (sges_left <= sges_in_segment) 2856 goto fill_in_last_segment; 2857 2858 mpi_request->ChainOffset = (sges_in_segment - 1 /* chain element */) + 2859 (offsetof(Mpi25SCSIIORequest_t, SGL)/ioc->sge_size_ieee); 2860 2861 /* fill in main message segment when there is a chain following */ 2862 while (sges_in_segment > 1) { 2863 _base_add_sg_single_ieee(sg_local, simple_sgl_flags, 0, 2864 sg_dma_len(sg_scmd), sg_dma_address(sg_scmd)); 2865 sg_scmd = sg_next(sg_scmd); 2866 sg_local += ioc->sge_size_ieee; 2867 sges_left--; 2868 sges_in_segment--; 2869 } 2870 2871 /* initializing the pointers */ 2872 chain_req = _base_get_chain_buffer_tracker(ioc, scmd); 2873 if (!chain_req) 2874 return -1; 2875 chain = chain_req->chain_buffer; 2876 chain_dma = chain_req->chain_buffer_dma; 2877 do { 2878 sges_in_segment = (sges_left <= 2879 ioc->max_sges_in_chain_message) ? sges_left : 2880 ioc->max_sges_in_chain_message; 2881 chain_offset = (sges_left == sges_in_segment) ? 2882 0 : sges_in_segment; 2883 chain_length = sges_in_segment * ioc->sge_size_ieee; 2884 if (chain_offset) 2885 chain_length += ioc->sge_size_ieee; 2886 _base_add_sg_single_ieee(sg_local, chain_sgl_flags, 2887 chain_offset, chain_length, chain_dma); 2888 2889 sg_local = chain; 2890 if (!chain_offset) 2891 goto fill_in_last_segment; 2892 2893 /* fill in chain segments */ 2894 while (sges_in_segment) { 2895 _base_add_sg_single_ieee(sg_local, simple_sgl_flags, 0, 2896 sg_dma_len(sg_scmd), sg_dma_address(sg_scmd)); 2897 sg_scmd = sg_next(sg_scmd); 2898 sg_local += ioc->sge_size_ieee; 2899 sges_left--; 2900 sges_in_segment--; 2901 } 2902 2903 chain_req = _base_get_chain_buffer_tracker(ioc, scmd); 2904 if (!chain_req) 2905 return -1; 2906 chain = chain_req->chain_buffer; 2907 chain_dma = chain_req->chain_buffer_dma; 2908 } while (1); 2909 2910 2911 fill_in_last_segment: 2912 2913 /* fill the last segment */ 2914 while (sges_left > 0) { 2915 if (sges_left == 1) 2916 _base_add_sg_single_ieee(sg_local, 2917 simple_sgl_flags_last, 0, sg_dma_len(sg_scmd), 2918 sg_dma_address(sg_scmd)); 2919 else 2920 _base_add_sg_single_ieee(sg_local, simple_sgl_flags, 0, 2921 sg_dma_len(sg_scmd), sg_dma_address(sg_scmd)); 2922 sg_scmd = sg_next(sg_scmd); 2923 sg_local += ioc->sge_size_ieee; 2924 sges_left--; 2925 } 2926 2927 return 0; 2928 } 2929 2930 /** 2931 * _base_build_sg_ieee - build generic sg for IEEE format 2932 * @ioc: per adapter object 2933 * @psge: virtual address for SGE 2934 * @data_out_dma: physical address for WRITES 2935 * @data_out_sz: data xfer size for WRITES 2936 * @data_in_dma: physical address for READS 2937 * @data_in_sz: data xfer size for READS 2938 */ 2939 static void 2940 _base_build_sg_ieee(struct MPT3SAS_ADAPTER *ioc, void *psge, 2941 dma_addr_t data_out_dma, size_t data_out_sz, dma_addr_t data_in_dma, 2942 size_t data_in_sz) 2943 { 2944 u8 sgl_flags; 2945 2946 if (!data_out_sz && !data_in_sz) { 2947 _base_build_zero_len_sge_ieee(ioc, psge); 2948 return; 2949 } 2950 2951 if (data_out_sz && data_in_sz) { 2952 /* WRITE sgel first */ 2953 sgl_flags = MPI2_IEEE_SGE_FLAGS_SIMPLE_ELEMENT | 2954 MPI2_IEEE_SGE_FLAGS_SYSTEM_ADDR; 2955 _base_add_sg_single_ieee(psge, sgl_flags, 0, data_out_sz, 2956 data_out_dma); 2957 2958 /* incr sgel */ 2959 psge += ioc->sge_size_ieee; 2960 2961 /* READ sgel last */ 2962 sgl_flags |= MPI25_IEEE_SGE_FLAGS_END_OF_LIST; 2963 _base_add_sg_single_ieee(psge, sgl_flags, 0, data_in_sz, 2964 data_in_dma); 2965 } else if (data_out_sz) /* WRITE */ { 2966 sgl_flags = MPI2_IEEE_SGE_FLAGS_SIMPLE_ELEMENT | 2967 MPI25_IEEE_SGE_FLAGS_END_OF_LIST | 2968 MPI2_IEEE_SGE_FLAGS_SYSTEM_ADDR; 2969 _base_add_sg_single_ieee(psge, sgl_flags, 0, data_out_sz, 2970 data_out_dma); 2971 } else if (data_in_sz) /* READ */ { 2972 sgl_flags = MPI2_IEEE_SGE_FLAGS_SIMPLE_ELEMENT | 2973 MPI25_IEEE_SGE_FLAGS_END_OF_LIST | 2974 MPI2_IEEE_SGE_FLAGS_SYSTEM_ADDR; 2975 _base_add_sg_single_ieee(psge, sgl_flags, 0, data_in_sz, 2976 data_in_dma); 2977 } 2978 } 2979 2980 #define convert_to_kb(x) ((x) << (PAGE_SHIFT - 10)) 2981 2982 /** 2983 * _base_config_dma_addressing - set dma addressing 2984 * @ioc: per adapter object 2985 * @pdev: PCI device struct 2986 * 2987 * Return: 0 for success, non-zero for failure. 2988 */ 2989 static int 2990 _base_config_dma_addressing(struct MPT3SAS_ADAPTER *ioc, struct pci_dev *pdev) 2991 { 2992 struct sysinfo s; 2993 u64 coherent_dma_mask, dma_mask; 2994 2995 if (ioc->is_mcpu_endpoint || sizeof(dma_addr_t) == 4) { 2996 ioc->dma_mask = 32; 2997 coherent_dma_mask = dma_mask = DMA_BIT_MASK(32); 2998 /* Set 63 bit DMA mask for all SAS3 and SAS35 controllers */ 2999 } else if (ioc->hba_mpi_version_belonged > MPI2_VERSION) { 3000 ioc->dma_mask = 63; 3001 coherent_dma_mask = dma_mask = DMA_BIT_MASK(63); 3002 } else { 3003 ioc->dma_mask = 64; 3004 coherent_dma_mask = dma_mask = DMA_BIT_MASK(64); 3005 } 3006 3007 if (ioc->use_32bit_dma) 3008 coherent_dma_mask = DMA_BIT_MASK(32); 3009 3010 if (dma_set_mask(&pdev->dev, dma_mask) || 3011 dma_set_coherent_mask(&pdev->dev, coherent_dma_mask)) 3012 return -ENODEV; 3013 3014 if (ioc->dma_mask > 32) { 3015 ioc->base_add_sg_single = &_base_add_sg_single_64; 3016 ioc->sge_size = sizeof(Mpi2SGESimple64_t); 3017 } else { 3018 ioc->base_add_sg_single = &_base_add_sg_single_32; 3019 ioc->sge_size = sizeof(Mpi2SGESimple32_t); 3020 } 3021 3022 si_meminfo(&s); 3023 ioc_info(ioc, "%d BIT PCI BUS DMA ADDRESSING SUPPORTED, total mem (%ld kB)\n", 3024 ioc->dma_mask, convert_to_kb(s.totalram)); 3025 3026 return 0; 3027 } 3028 3029 /** 3030 * _base_check_enable_msix - checks MSIX capabable. 3031 * @ioc: per adapter object 3032 * 3033 * Check to see if card is capable of MSIX, and set number 3034 * of available msix vectors 3035 */ 3036 static int 3037 _base_check_enable_msix(struct MPT3SAS_ADAPTER *ioc) 3038 { 3039 int base; 3040 u16 message_control; 3041 3042 /* Check whether controller SAS2008 B0 controller, 3043 * if it is SAS2008 B0 controller use IO-APIC instead of MSIX 3044 */ 3045 if (ioc->pdev->device == MPI2_MFGPAGE_DEVID_SAS2008 && 3046 ioc->pdev->revision == SAS2_PCI_DEVICE_B0_REVISION) { 3047 return -EINVAL; 3048 } 3049 3050 base = pci_find_capability(ioc->pdev, PCI_CAP_ID_MSIX); 3051 if (!base) { 3052 dfailprintk(ioc, ioc_info(ioc, "msix not supported\n")); 3053 return -EINVAL; 3054 } 3055 3056 /* get msix vector count */ 3057 /* NUMA_IO not supported for older controllers */ 3058 if (ioc->pdev->device == MPI2_MFGPAGE_DEVID_SAS2004 || 3059 ioc->pdev->device == MPI2_MFGPAGE_DEVID_SAS2008 || 3060 ioc->pdev->device == MPI2_MFGPAGE_DEVID_SAS2108_1 || 3061 ioc->pdev->device == MPI2_MFGPAGE_DEVID_SAS2108_2 || 3062 ioc->pdev->device == MPI2_MFGPAGE_DEVID_SAS2108_3 || 3063 ioc->pdev->device == MPI2_MFGPAGE_DEVID_SAS2116_1 || 3064 ioc->pdev->device == MPI2_MFGPAGE_DEVID_SAS2116_2) 3065 ioc->msix_vector_count = 1; 3066 else { 3067 pci_read_config_word(ioc->pdev, base + 2, &message_control); 3068 ioc->msix_vector_count = (message_control & 0x3FF) + 1; 3069 } 3070 dinitprintk(ioc, ioc_info(ioc, "msix is supported, vector_count(%d)\n", 3071 ioc->msix_vector_count)); 3072 return 0; 3073 } 3074 3075 /** 3076 * mpt3sas_base_free_irq - free irq 3077 * @ioc: per adapter object 3078 * 3079 * Freeing respective reply_queue from the list. 3080 */ 3081 void 3082 mpt3sas_base_free_irq(struct MPT3SAS_ADAPTER *ioc) 3083 { 3084 unsigned int irq; 3085 struct adapter_reply_queue *reply_q, *next; 3086 3087 if (list_empty(&ioc->reply_queue_list)) 3088 return; 3089 3090 list_for_each_entry_safe(reply_q, next, &ioc->reply_queue_list, list) { 3091 list_del(&reply_q->list); 3092 if (reply_q->is_iouring_poll_q) { 3093 kfree(reply_q); 3094 continue; 3095 } 3096 3097 if (ioc->smp_affinity_enable) { 3098 irq = pci_irq_vector(ioc->pdev, reply_q->msix_index); 3099 irq_update_affinity_hint(irq, NULL); 3100 } 3101 free_irq(pci_irq_vector(ioc->pdev, reply_q->msix_index), 3102 reply_q); 3103 kfree(reply_q); 3104 } 3105 } 3106 3107 /** 3108 * _base_request_irq - request irq 3109 * @ioc: per adapter object 3110 * @index: msix index into vector table 3111 * 3112 * Inserting respective reply_queue into the list. 3113 */ 3114 static int 3115 _base_request_irq(struct MPT3SAS_ADAPTER *ioc, u8 index) 3116 { 3117 struct pci_dev *pdev = ioc->pdev; 3118 struct adapter_reply_queue *reply_q; 3119 int r, qid; 3120 3121 reply_q = kzalloc(sizeof(struct adapter_reply_queue), GFP_KERNEL); 3122 if (!reply_q) { 3123 ioc_err(ioc, "unable to allocate memory %zu!\n", 3124 sizeof(struct adapter_reply_queue)); 3125 return -ENOMEM; 3126 } 3127 reply_q->ioc = ioc; 3128 reply_q->msix_index = index; 3129 3130 atomic_set(&reply_q->busy, 0); 3131 3132 if (index >= ioc->iopoll_q_start_index) { 3133 qid = index - ioc->iopoll_q_start_index; 3134 snprintf(reply_q->name, MPT_NAME_LENGTH, "%s%d-mq-poll%d", 3135 ioc->driver_name, ioc->id, qid); 3136 reply_q->is_iouring_poll_q = 1; 3137 ioc->io_uring_poll_queues[qid].reply_q = reply_q; 3138 goto out; 3139 } 3140 3141 3142 if (ioc->msix_enable) 3143 snprintf(reply_q->name, MPT_NAME_LENGTH, "%s%d-msix%d", 3144 ioc->driver_name, ioc->id, index); 3145 else 3146 snprintf(reply_q->name, MPT_NAME_LENGTH, "%s%d", 3147 ioc->driver_name, ioc->id); 3148 r = request_irq(pci_irq_vector(pdev, index), _base_interrupt, 3149 IRQF_SHARED, reply_q->name, reply_q); 3150 if (r) { 3151 pr_err("%s: unable to allocate interrupt %d!\n", 3152 reply_q->name, pci_irq_vector(pdev, index)); 3153 kfree(reply_q); 3154 return -EBUSY; 3155 } 3156 out: 3157 INIT_LIST_HEAD(&reply_q->list); 3158 list_add_tail(&reply_q->list, &ioc->reply_queue_list); 3159 return 0; 3160 } 3161 3162 /** 3163 * _base_assign_reply_queues - assigning msix index for each cpu 3164 * @ioc: per adapter object 3165 * 3166 * The enduser would need to set the affinity via /proc/irq/#/smp_affinity 3167 */ 3168 static void 3169 _base_assign_reply_queues(struct MPT3SAS_ADAPTER *ioc) 3170 { 3171 unsigned int cpu, nr_cpus, nr_msix, index = 0, irq; 3172 struct adapter_reply_queue *reply_q; 3173 int iopoll_q_count = ioc->reply_queue_count - 3174 ioc->iopoll_q_start_index; 3175 const struct cpumask *mask; 3176 3177 if (!_base_is_controller_msix_enabled(ioc)) 3178 return; 3179 3180 if (ioc->msix_load_balance) 3181 return; 3182 3183 memset(ioc->cpu_msix_table, 0, ioc->cpu_msix_table_sz); 3184 3185 nr_cpus = num_online_cpus(); 3186 nr_msix = ioc->reply_queue_count = min(ioc->reply_queue_count, 3187 ioc->facts.MaxMSIxVectors); 3188 if (!nr_msix) 3189 return; 3190 3191 if (ioc->smp_affinity_enable) { 3192 3193 /* 3194 * set irq affinity to local numa node for those irqs 3195 * corresponding to high iops queues. 3196 */ 3197 if (ioc->high_iops_queues) { 3198 mask = cpumask_of_node(dev_to_node(&ioc->pdev->dev)); 3199 for (index = 0; index < ioc->high_iops_queues; 3200 index++) { 3201 irq = pci_irq_vector(ioc->pdev, index); 3202 irq_set_affinity_and_hint(irq, mask); 3203 } 3204 } 3205 3206 list_for_each_entry(reply_q, &ioc->reply_queue_list, list) { 3207 const cpumask_t *mask; 3208 3209 if (reply_q->msix_index < ioc->high_iops_queues || 3210 reply_q->msix_index >= ioc->iopoll_q_start_index) 3211 continue; 3212 3213 mask = pci_irq_get_affinity(ioc->pdev, 3214 reply_q->msix_index); 3215 if (!mask) { 3216 ioc_warn(ioc, "no affinity for msi %x\n", 3217 reply_q->msix_index); 3218 goto fall_back; 3219 } 3220 3221 for_each_cpu_and(cpu, mask, cpu_online_mask) { 3222 if (cpu >= ioc->cpu_msix_table_sz) 3223 break; 3224 ioc->cpu_msix_table[cpu] = reply_q->msix_index; 3225 } 3226 } 3227 return; 3228 } 3229 3230 fall_back: 3231 cpu = cpumask_first(cpu_online_mask); 3232 nr_msix -= (ioc->high_iops_queues - iopoll_q_count); 3233 index = 0; 3234 3235 list_for_each_entry(reply_q, &ioc->reply_queue_list, list) { 3236 unsigned int i, group = nr_cpus / nr_msix; 3237 3238 if (reply_q->msix_index < ioc->high_iops_queues || 3239 reply_q->msix_index >= ioc->iopoll_q_start_index) 3240 continue; 3241 3242 if (cpu >= nr_cpus) 3243 break; 3244 3245 if (index < nr_cpus % nr_msix) 3246 group++; 3247 3248 for (i = 0 ; i < group ; i++) { 3249 ioc->cpu_msix_table[cpu] = reply_q->msix_index; 3250 cpu = cpumask_next(cpu, cpu_online_mask); 3251 } 3252 index++; 3253 } 3254 } 3255 3256 /** 3257 * _base_check_and_enable_high_iops_queues - enable high iops mode 3258 * @ioc: per adapter object 3259 * @hba_msix_vector_count: msix vectors supported by HBA 3260 * 3261 * Enable high iops queues only if 3262 * - HBA is a SEA/AERO controller and 3263 * - MSI-Xs vector supported by the HBA is 128 and 3264 * - total CPU count in the system >=16 and 3265 * - loaded driver with default max_msix_vectors module parameter and 3266 * - system booted in non kdump mode 3267 * 3268 * Return: nothing. 3269 */ 3270 static void 3271 _base_check_and_enable_high_iops_queues(struct MPT3SAS_ADAPTER *ioc, 3272 int hba_msix_vector_count) 3273 { 3274 u16 lnksta, speed; 3275 3276 /* 3277 * Disable high iops queues if io uring poll queues are enabled. 3278 */ 3279 if (perf_mode == MPT_PERF_MODE_IOPS || 3280 perf_mode == MPT_PERF_MODE_LATENCY || 3281 ioc->io_uring_poll_queues) { 3282 ioc->high_iops_queues = 0; 3283 return; 3284 } 3285 3286 if (perf_mode == MPT_PERF_MODE_DEFAULT) { 3287 3288 pcie_capability_read_word(ioc->pdev, PCI_EXP_LNKSTA, &lnksta); 3289 speed = lnksta & PCI_EXP_LNKSTA_CLS; 3290 3291 if (speed < 0x4) { 3292 ioc->high_iops_queues = 0; 3293 return; 3294 } 3295 } 3296 3297 if (!reset_devices && ioc->is_aero_ioc && 3298 hba_msix_vector_count == MPT3SAS_GEN35_MAX_MSIX_QUEUES && 3299 num_online_cpus() >= MPT3SAS_HIGH_IOPS_REPLY_QUEUES && 3300 max_msix_vectors == -1) 3301 ioc->high_iops_queues = MPT3SAS_HIGH_IOPS_REPLY_QUEUES; 3302 else 3303 ioc->high_iops_queues = 0; 3304 } 3305 3306 /** 3307 * mpt3sas_base_disable_msix - disables msix 3308 * @ioc: per adapter object 3309 * 3310 */ 3311 void 3312 mpt3sas_base_disable_msix(struct MPT3SAS_ADAPTER *ioc) 3313 { 3314 if (!ioc->msix_enable) 3315 return; 3316 pci_free_irq_vectors(ioc->pdev); 3317 ioc->msix_enable = 0; 3318 kfree(ioc->io_uring_poll_queues); 3319 } 3320 3321 /** 3322 * _base_alloc_irq_vectors - allocate msix vectors 3323 * @ioc: per adapter object 3324 * 3325 */ 3326 static int 3327 _base_alloc_irq_vectors(struct MPT3SAS_ADAPTER *ioc) 3328 { 3329 int i, irq_flags = PCI_IRQ_MSIX; 3330 struct irq_affinity desc = { .pre_vectors = ioc->high_iops_queues }; 3331 struct irq_affinity *descp = &desc; 3332 /* 3333 * Don't allocate msix vectors for poll_queues. 3334 * msix_vectors is always within a range of FW supported reply queue. 3335 */ 3336 int nr_msix_vectors = ioc->iopoll_q_start_index; 3337 3338 3339 if (ioc->smp_affinity_enable) 3340 irq_flags |= PCI_IRQ_AFFINITY | PCI_IRQ_ALL_TYPES; 3341 else 3342 descp = NULL; 3343 3344 ioc_info(ioc, " %d %d %d\n", ioc->high_iops_queues, 3345 ioc->reply_queue_count, nr_msix_vectors); 3346 3347 i = pci_alloc_irq_vectors_affinity(ioc->pdev, 3348 ioc->high_iops_queues, 3349 nr_msix_vectors, irq_flags, descp); 3350 3351 return i; 3352 } 3353 3354 /** 3355 * _base_enable_msix - enables msix, failback to io_apic 3356 * @ioc: per adapter object 3357 * 3358 */ 3359 static int 3360 _base_enable_msix(struct MPT3SAS_ADAPTER *ioc) 3361 { 3362 int r; 3363 int i, local_max_msix_vectors; 3364 u8 try_msix = 0; 3365 int iopoll_q_count = 0; 3366 3367 ioc->msix_load_balance = false; 3368 3369 if (msix_disable == -1 || msix_disable == 0) 3370 try_msix = 1; 3371 3372 if (!try_msix) 3373 goto try_ioapic; 3374 3375 if (_base_check_enable_msix(ioc) != 0) 3376 goto try_ioapic; 3377 3378 ioc_info(ioc, "MSI-X vectors supported: %d\n", ioc->msix_vector_count); 3379 pr_info("\t no of cores: %d, max_msix_vectors: %d\n", 3380 ioc->cpu_count, max_msix_vectors); 3381 3382 ioc->reply_queue_count = 3383 min_t(int, ioc->cpu_count, ioc->msix_vector_count); 3384 3385 if (!ioc->rdpq_array_enable && max_msix_vectors == -1) 3386 local_max_msix_vectors = (reset_devices) ? 1 : 8; 3387 else 3388 local_max_msix_vectors = max_msix_vectors; 3389 3390 if (local_max_msix_vectors == 0) 3391 goto try_ioapic; 3392 3393 /* 3394 * Enable msix_load_balance only if combined reply queue mode is 3395 * disabled on SAS3 & above generation HBA devices. 3396 */ 3397 if (!ioc->combined_reply_queue && 3398 ioc->hba_mpi_version_belonged != MPI2_VERSION) { 3399 ioc_info(ioc, 3400 "combined ReplyQueue is off, Enabling msix load balance\n"); 3401 ioc->msix_load_balance = true; 3402 } 3403 3404 /* 3405 * smp affinity setting is not need when msix load balance 3406 * is enabled. 3407 */ 3408 if (ioc->msix_load_balance) 3409 ioc->smp_affinity_enable = 0; 3410 3411 if (!ioc->smp_affinity_enable || ioc->reply_queue_count <= 1) 3412 ioc->shost->host_tagset = 0; 3413 3414 /* 3415 * Enable io uring poll queues only if host_tagset is enabled. 3416 */ 3417 if (ioc->shost->host_tagset) 3418 iopoll_q_count = poll_queues; 3419 3420 if (iopoll_q_count) { 3421 ioc->io_uring_poll_queues = kcalloc(iopoll_q_count, 3422 sizeof(struct io_uring_poll_queue), GFP_KERNEL); 3423 if (!ioc->io_uring_poll_queues) 3424 iopoll_q_count = 0; 3425 } 3426 3427 if (ioc->is_aero_ioc) 3428 _base_check_and_enable_high_iops_queues(ioc, 3429 ioc->msix_vector_count); 3430 3431 /* 3432 * Add high iops queues count to reply queue count if high iops queues 3433 * are enabled. 3434 */ 3435 ioc->reply_queue_count = min_t(int, 3436 ioc->reply_queue_count + ioc->high_iops_queues, 3437 ioc->msix_vector_count); 3438 3439 /* 3440 * Adjust the reply queue count incase reply queue count 3441 * exceeds the user provided MSIx vectors count. 3442 */ 3443 if (local_max_msix_vectors > 0) 3444 ioc->reply_queue_count = min_t(int, local_max_msix_vectors, 3445 ioc->reply_queue_count); 3446 /* 3447 * Add io uring poll queues count to reply queues count 3448 * if io uring is enabled in driver. 3449 */ 3450 if (iopoll_q_count) { 3451 if (ioc->reply_queue_count < (iopoll_q_count + MPT3_MIN_IRQS)) 3452 iopoll_q_count = 0; 3453 ioc->reply_queue_count = min_t(int, 3454 ioc->reply_queue_count + iopoll_q_count, 3455 ioc->msix_vector_count); 3456 } 3457 3458 /* 3459 * Starting index of io uring poll queues in reply queue list. 3460 */ 3461 ioc->iopoll_q_start_index = 3462 ioc->reply_queue_count - iopoll_q_count; 3463 3464 r = _base_alloc_irq_vectors(ioc); 3465 if (r < 0) { 3466 ioc_info(ioc, "pci_alloc_irq_vectors failed (r=%d) !!!\n", r); 3467 goto try_ioapic; 3468 } 3469 3470 /* 3471 * Adjust the reply queue count if the allocated 3472 * MSIx vectors is less then the requested number 3473 * of MSIx vectors. 3474 */ 3475 if (r < ioc->iopoll_q_start_index) { 3476 ioc->reply_queue_count = r + iopoll_q_count; 3477 ioc->iopoll_q_start_index = 3478 ioc->reply_queue_count - iopoll_q_count; 3479 } 3480 3481 ioc->msix_enable = 1; 3482 for (i = 0; i < ioc->reply_queue_count; i++) { 3483 r = _base_request_irq(ioc, i); 3484 if (r) { 3485 mpt3sas_base_free_irq(ioc); 3486 mpt3sas_base_disable_msix(ioc); 3487 goto try_ioapic; 3488 } 3489 } 3490 3491 ioc_info(ioc, "High IOPs queues : %s\n", 3492 ioc->high_iops_queues ? "enabled" : "disabled"); 3493 3494 return 0; 3495 3496 /* failback to io_apic interrupt routing */ 3497 try_ioapic: 3498 ioc->high_iops_queues = 0; 3499 ioc_info(ioc, "High IOPs queues : disabled\n"); 3500 ioc->reply_queue_count = 1; 3501 ioc->iopoll_q_start_index = ioc->reply_queue_count - 0; 3502 r = pci_alloc_irq_vectors(ioc->pdev, 1, 1, PCI_IRQ_LEGACY); 3503 if (r < 0) { 3504 dfailprintk(ioc, 3505 ioc_info(ioc, "pci_alloc_irq_vector(legacy) failed (r=%d) !!!\n", 3506 r)); 3507 } else 3508 r = _base_request_irq(ioc, 0); 3509 3510 return r; 3511 } 3512 3513 /** 3514 * mpt3sas_base_unmap_resources - free controller resources 3515 * @ioc: per adapter object 3516 */ 3517 static void 3518 mpt3sas_base_unmap_resources(struct MPT3SAS_ADAPTER *ioc) 3519 { 3520 struct pci_dev *pdev = ioc->pdev; 3521 3522 dexitprintk(ioc, ioc_info(ioc, "%s\n", __func__)); 3523 3524 mpt3sas_base_free_irq(ioc); 3525 mpt3sas_base_disable_msix(ioc); 3526 3527 kfree(ioc->replyPostRegisterIndex); 3528 ioc->replyPostRegisterIndex = NULL; 3529 3530 3531 if (ioc->chip_phys) { 3532 iounmap(ioc->chip); 3533 ioc->chip_phys = 0; 3534 } 3535 3536 if (pci_is_enabled(pdev)) { 3537 pci_release_selected_regions(ioc->pdev, ioc->bars); 3538 pci_disable_pcie_error_reporting(pdev); 3539 pci_disable_device(pdev); 3540 } 3541 } 3542 3543 static int 3544 _base_diag_reset(struct MPT3SAS_ADAPTER *ioc); 3545 3546 /** 3547 * mpt3sas_base_check_for_fault_and_issue_reset - check if IOC is in fault state 3548 * and if it is in fault state then issue diag reset. 3549 * @ioc: per adapter object 3550 * 3551 * Return: 0 for success, non-zero for failure. 3552 */ 3553 int 3554 mpt3sas_base_check_for_fault_and_issue_reset(struct MPT3SAS_ADAPTER *ioc) 3555 { 3556 u32 ioc_state; 3557 int rc = -EFAULT; 3558 3559 dinitprintk(ioc, pr_info("%s\n", __func__)); 3560 if (ioc->pci_error_recovery) 3561 return 0; 3562 ioc_state = mpt3sas_base_get_iocstate(ioc, 0); 3563 dhsprintk(ioc, pr_info("%s: ioc_state(0x%08x)\n", __func__, ioc_state)); 3564 3565 if ((ioc_state & MPI2_IOC_STATE_MASK) == MPI2_IOC_STATE_FAULT) { 3566 mpt3sas_print_fault_code(ioc, ioc_state & 3567 MPI2_DOORBELL_DATA_MASK); 3568 mpt3sas_base_mask_interrupts(ioc); 3569 rc = _base_diag_reset(ioc); 3570 } else if ((ioc_state & MPI2_IOC_STATE_MASK) == 3571 MPI2_IOC_STATE_COREDUMP) { 3572 mpt3sas_print_coredump_info(ioc, ioc_state & 3573 MPI2_DOORBELL_DATA_MASK); 3574 mpt3sas_base_wait_for_coredump_completion(ioc, __func__); 3575 mpt3sas_base_mask_interrupts(ioc); 3576 rc = _base_diag_reset(ioc); 3577 } 3578 3579 return rc; 3580 } 3581 3582 /** 3583 * mpt3sas_base_map_resources - map in controller resources (io/irq/memap) 3584 * @ioc: per adapter object 3585 * 3586 * Return: 0 for success, non-zero for failure. 3587 */ 3588 int 3589 mpt3sas_base_map_resources(struct MPT3SAS_ADAPTER *ioc) 3590 { 3591 struct pci_dev *pdev = ioc->pdev; 3592 u32 memap_sz; 3593 u32 pio_sz; 3594 int i, r = 0, rc; 3595 u64 pio_chip = 0; 3596 phys_addr_t chip_phys = 0; 3597 struct adapter_reply_queue *reply_q; 3598 int iopoll_q_count = 0; 3599 3600 dinitprintk(ioc, ioc_info(ioc, "%s\n", __func__)); 3601 3602 ioc->bars = pci_select_bars(pdev, IORESOURCE_MEM); 3603 if (pci_enable_device_mem(pdev)) { 3604 ioc_warn(ioc, "pci_enable_device_mem: failed\n"); 3605 ioc->bars = 0; 3606 return -ENODEV; 3607 } 3608 3609 3610 if (pci_request_selected_regions(pdev, ioc->bars, 3611 ioc->driver_name)) { 3612 ioc_warn(ioc, "pci_request_selected_regions: failed\n"); 3613 ioc->bars = 0; 3614 r = -ENODEV; 3615 goto out_fail; 3616 } 3617 3618 /* AER (Advanced Error Reporting) hooks */ 3619 pci_enable_pcie_error_reporting(pdev); 3620 3621 pci_set_master(pdev); 3622 3623 3624 if (_base_config_dma_addressing(ioc, pdev) != 0) { 3625 ioc_warn(ioc, "no suitable DMA mask for %s\n", pci_name(pdev)); 3626 r = -ENODEV; 3627 goto out_fail; 3628 } 3629 3630 for (i = 0, memap_sz = 0, pio_sz = 0; (i < DEVICE_COUNT_RESOURCE) && 3631 (!memap_sz || !pio_sz); i++) { 3632 if (pci_resource_flags(pdev, i) & IORESOURCE_IO) { 3633 if (pio_sz) 3634 continue; 3635 pio_chip = (u64)pci_resource_start(pdev, i); 3636 pio_sz = pci_resource_len(pdev, i); 3637 } else if (pci_resource_flags(pdev, i) & IORESOURCE_MEM) { 3638 if (memap_sz) 3639 continue; 3640 ioc->chip_phys = pci_resource_start(pdev, i); 3641 chip_phys = ioc->chip_phys; 3642 memap_sz = pci_resource_len(pdev, i); 3643 ioc->chip = ioremap(ioc->chip_phys, memap_sz); 3644 } 3645 } 3646 3647 if (ioc->chip == NULL) { 3648 ioc_err(ioc, 3649 "unable to map adapter memory! or resource not found\n"); 3650 r = -EINVAL; 3651 goto out_fail; 3652 } 3653 3654 mpt3sas_base_mask_interrupts(ioc); 3655 3656 r = _base_get_ioc_facts(ioc); 3657 if (r) { 3658 rc = mpt3sas_base_check_for_fault_and_issue_reset(ioc); 3659 if (rc || (_base_get_ioc_facts(ioc))) 3660 goto out_fail; 3661 } 3662 3663 if (!ioc->rdpq_array_enable_assigned) { 3664 ioc->rdpq_array_enable = ioc->rdpq_array_capable; 3665 ioc->rdpq_array_enable_assigned = 1; 3666 } 3667 3668 r = _base_enable_msix(ioc); 3669 if (r) 3670 goto out_fail; 3671 3672 iopoll_q_count = ioc->reply_queue_count - ioc->iopoll_q_start_index; 3673 for (i = 0; i < iopoll_q_count; i++) { 3674 atomic_set(&ioc->io_uring_poll_queues[i].busy, 0); 3675 atomic_set(&ioc->io_uring_poll_queues[i].pause, 0); 3676 } 3677 3678 if (!ioc->is_driver_loading) 3679 _base_init_irqpolls(ioc); 3680 /* Use the Combined reply queue feature only for SAS3 C0 & higher 3681 * revision HBAs and also only when reply queue count is greater than 8 3682 */ 3683 if (ioc->combined_reply_queue) { 3684 /* Determine the Supplemental Reply Post Host Index Registers 3685 * Addresse. Supplemental Reply Post Host Index Registers 3686 * starts at offset MPI25_SUP_REPLY_POST_HOST_INDEX_OFFSET and 3687 * each register is at offset bytes of 3688 * MPT3_SUP_REPLY_POST_HOST_INDEX_REG_OFFSET from previous one. 3689 */ 3690 ioc->replyPostRegisterIndex = kcalloc( 3691 ioc->combined_reply_index_count, 3692 sizeof(resource_size_t *), GFP_KERNEL); 3693 if (!ioc->replyPostRegisterIndex) { 3694 ioc_err(ioc, 3695 "allocation for replyPostRegisterIndex failed!\n"); 3696 r = -ENOMEM; 3697 goto out_fail; 3698 } 3699 3700 for (i = 0; i < ioc->combined_reply_index_count; i++) { 3701 ioc->replyPostRegisterIndex[i] = 3702 (resource_size_t __iomem *) 3703 ((u8 __force *)&ioc->chip->Doorbell + 3704 MPI25_SUP_REPLY_POST_HOST_INDEX_OFFSET + 3705 (i * MPT3_SUP_REPLY_POST_HOST_INDEX_REG_OFFSET)); 3706 } 3707 } 3708 3709 if (ioc->is_warpdrive) { 3710 ioc->reply_post_host_index[0] = (resource_size_t __iomem *) 3711 &ioc->chip->ReplyPostHostIndex; 3712 3713 for (i = 1; i < ioc->cpu_msix_table_sz; i++) 3714 ioc->reply_post_host_index[i] = 3715 (resource_size_t __iomem *) 3716 ((u8 __iomem *)&ioc->chip->Doorbell + (0x4000 + ((i - 1) 3717 * 4))); 3718 } 3719 3720 list_for_each_entry(reply_q, &ioc->reply_queue_list, list) { 3721 if (reply_q->msix_index >= ioc->iopoll_q_start_index) { 3722 pr_info("%s: enabled: index: %d\n", 3723 reply_q->name, reply_q->msix_index); 3724 continue; 3725 } 3726 3727 pr_info("%s: %s enabled: IRQ %d\n", 3728 reply_q->name, 3729 ioc->msix_enable ? "PCI-MSI-X" : "IO-APIC", 3730 pci_irq_vector(ioc->pdev, reply_q->msix_index)); 3731 } 3732 3733 ioc_info(ioc, "iomem(%pap), mapped(0x%p), size(%d)\n", 3734 &chip_phys, ioc->chip, memap_sz); 3735 ioc_info(ioc, "ioport(0x%016llx), size(%d)\n", 3736 (unsigned long long)pio_chip, pio_sz); 3737 3738 /* Save PCI configuration state for recovery from PCI AER/EEH errors */ 3739 pci_save_state(pdev); 3740 return 0; 3741 3742 out_fail: 3743 mpt3sas_base_unmap_resources(ioc); 3744 return r; 3745 } 3746 3747 /** 3748 * mpt3sas_base_get_msg_frame - obtain request mf pointer 3749 * @ioc: per adapter object 3750 * @smid: system request message index(smid zero is invalid) 3751 * 3752 * Return: virt pointer to message frame. 3753 */ 3754 void * 3755 mpt3sas_base_get_msg_frame(struct MPT3SAS_ADAPTER *ioc, u16 smid) 3756 { 3757 return (void *)(ioc->request + (smid * ioc->request_sz)); 3758 } 3759 3760 /** 3761 * mpt3sas_base_get_sense_buffer - obtain a sense buffer virt addr 3762 * @ioc: per adapter object 3763 * @smid: system request message index 3764 * 3765 * Return: virt pointer to sense buffer. 3766 */ 3767 void * 3768 mpt3sas_base_get_sense_buffer(struct MPT3SAS_ADAPTER *ioc, u16 smid) 3769 { 3770 return (void *)(ioc->sense + ((smid - 1) * SCSI_SENSE_BUFFERSIZE)); 3771 } 3772 3773 /** 3774 * mpt3sas_base_get_sense_buffer_dma - obtain a sense buffer dma addr 3775 * @ioc: per adapter object 3776 * @smid: system request message index 3777 * 3778 * Return: phys pointer to the low 32bit address of the sense buffer. 3779 */ 3780 __le32 3781 mpt3sas_base_get_sense_buffer_dma(struct MPT3SAS_ADAPTER *ioc, u16 smid) 3782 { 3783 return cpu_to_le32(ioc->sense_dma + ((smid - 1) * 3784 SCSI_SENSE_BUFFERSIZE)); 3785 } 3786 3787 /** 3788 * mpt3sas_base_get_pcie_sgl - obtain a PCIe SGL virt addr 3789 * @ioc: per adapter object 3790 * @smid: system request message index 3791 * 3792 * Return: virt pointer to a PCIe SGL. 3793 */ 3794 void * 3795 mpt3sas_base_get_pcie_sgl(struct MPT3SAS_ADAPTER *ioc, u16 smid) 3796 { 3797 return (void *)(ioc->pcie_sg_lookup[smid - 1].pcie_sgl); 3798 } 3799 3800 /** 3801 * mpt3sas_base_get_pcie_sgl_dma - obtain a PCIe SGL dma addr 3802 * @ioc: per adapter object 3803 * @smid: system request message index 3804 * 3805 * Return: phys pointer to the address of the PCIe buffer. 3806 */ 3807 dma_addr_t 3808 mpt3sas_base_get_pcie_sgl_dma(struct MPT3SAS_ADAPTER *ioc, u16 smid) 3809 { 3810 return ioc->pcie_sg_lookup[smid - 1].pcie_sgl_dma; 3811 } 3812 3813 /** 3814 * mpt3sas_base_get_reply_virt_addr - obtain reply frames virt address 3815 * @ioc: per adapter object 3816 * @phys_addr: lower 32 physical addr of the reply 3817 * 3818 * Converts 32bit lower physical addr into a virt address. 3819 */ 3820 void * 3821 mpt3sas_base_get_reply_virt_addr(struct MPT3SAS_ADAPTER *ioc, u32 phys_addr) 3822 { 3823 if (!phys_addr) 3824 return NULL; 3825 return ioc->reply + (phys_addr - (u32)ioc->reply_dma); 3826 } 3827 3828 /** 3829 * _base_get_msix_index - get the msix index 3830 * @ioc: per adapter object 3831 * @scmd: scsi_cmnd object 3832 * 3833 * Return: msix index of general reply queues, 3834 * i.e. reply queue on which IO request's reply 3835 * should be posted by the HBA firmware. 3836 */ 3837 static inline u8 3838 _base_get_msix_index(struct MPT3SAS_ADAPTER *ioc, 3839 struct scsi_cmnd *scmd) 3840 { 3841 /* Enables reply_queue load balancing */ 3842 if (ioc->msix_load_balance) 3843 return ioc->reply_queue_count ? 3844 base_mod64(atomic64_add_return(1, 3845 &ioc->total_io_cnt), ioc->reply_queue_count) : 0; 3846 3847 if (scmd && ioc->shost->nr_hw_queues > 1) { 3848 u32 tag = blk_mq_unique_tag(scsi_cmd_to_rq(scmd)); 3849 3850 return blk_mq_unique_tag_to_hwq(tag) + 3851 ioc->high_iops_queues; 3852 } 3853 3854 return ioc->cpu_msix_table[raw_smp_processor_id()]; 3855 } 3856 3857 /** 3858 * _base_get_high_iops_msix_index - get the msix index of 3859 * high iops queues 3860 * @ioc: per adapter object 3861 * @scmd: scsi_cmnd object 3862 * 3863 * Return: msix index of high iops reply queues. 3864 * i.e. high iops reply queue on which IO request's 3865 * reply should be posted by the HBA firmware. 3866 */ 3867 static inline u8 3868 _base_get_high_iops_msix_index(struct MPT3SAS_ADAPTER *ioc, 3869 struct scsi_cmnd *scmd) 3870 { 3871 /** 3872 * Round robin the IO interrupts among the high iops 3873 * reply queues in terms of batch count 16 when outstanding 3874 * IOs on the target device is >=8. 3875 */ 3876 3877 if (scsi_device_busy(scmd->device) > MPT3SAS_DEVICE_HIGH_IOPS_DEPTH) 3878 return base_mod64(( 3879 atomic64_add_return(1, &ioc->high_iops_outstanding) / 3880 MPT3SAS_HIGH_IOPS_BATCH_COUNT), 3881 MPT3SAS_HIGH_IOPS_REPLY_QUEUES); 3882 3883 return _base_get_msix_index(ioc, scmd); 3884 } 3885 3886 /** 3887 * mpt3sas_base_get_smid - obtain a free smid from internal queue 3888 * @ioc: per adapter object 3889 * @cb_idx: callback index 3890 * 3891 * Return: smid (zero is invalid) 3892 */ 3893 u16 3894 mpt3sas_base_get_smid(struct MPT3SAS_ADAPTER *ioc, u8 cb_idx) 3895 { 3896 unsigned long flags; 3897 struct request_tracker *request; 3898 u16 smid; 3899 3900 spin_lock_irqsave(&ioc->scsi_lookup_lock, flags); 3901 if (list_empty(&ioc->internal_free_list)) { 3902 spin_unlock_irqrestore(&ioc->scsi_lookup_lock, flags); 3903 ioc_err(ioc, "%s: smid not available\n", __func__); 3904 return 0; 3905 } 3906 3907 request = list_entry(ioc->internal_free_list.next, 3908 struct request_tracker, tracker_list); 3909 request->cb_idx = cb_idx; 3910 smid = request->smid; 3911 list_del(&request->tracker_list); 3912 spin_unlock_irqrestore(&ioc->scsi_lookup_lock, flags); 3913 return smid; 3914 } 3915 3916 /** 3917 * mpt3sas_base_get_smid_scsiio - obtain a free smid from scsiio queue 3918 * @ioc: per adapter object 3919 * @cb_idx: callback index 3920 * @scmd: pointer to scsi command object 3921 * 3922 * Return: smid (zero is invalid) 3923 */ 3924 u16 3925 mpt3sas_base_get_smid_scsiio(struct MPT3SAS_ADAPTER *ioc, u8 cb_idx, 3926 struct scsi_cmnd *scmd) 3927 { 3928 struct scsiio_tracker *request = scsi_cmd_priv(scmd); 3929 u16 smid; 3930 u32 tag, unique_tag; 3931 3932 unique_tag = blk_mq_unique_tag(scsi_cmd_to_rq(scmd)); 3933 tag = blk_mq_unique_tag_to_tag(unique_tag); 3934 3935 /* 3936 * Store hw queue number corresponding to the tag. 3937 * This hw queue number is used later to determine 3938 * the unique_tag using the logic below. This unique_tag 3939 * is used to retrieve the scmd pointer corresponding 3940 * to tag using scsi_host_find_tag() API. 3941 * 3942 * tag = smid - 1; 3943 * unique_tag = ioc->io_queue_num[tag] << BLK_MQ_UNIQUE_TAG_BITS | tag; 3944 */ 3945 ioc->io_queue_num[tag] = blk_mq_unique_tag_to_hwq(unique_tag); 3946 3947 smid = tag + 1; 3948 request->cb_idx = cb_idx; 3949 request->smid = smid; 3950 request->scmd = scmd; 3951 INIT_LIST_HEAD(&request->chain_list); 3952 return smid; 3953 } 3954 3955 /** 3956 * mpt3sas_base_get_smid_hpr - obtain a free smid from hi-priority queue 3957 * @ioc: per adapter object 3958 * @cb_idx: callback index 3959 * 3960 * Return: smid (zero is invalid) 3961 */ 3962 u16 3963 mpt3sas_base_get_smid_hpr(struct MPT3SAS_ADAPTER *ioc, u8 cb_idx) 3964 { 3965 unsigned long flags; 3966 struct request_tracker *request; 3967 u16 smid; 3968 3969 spin_lock_irqsave(&ioc->scsi_lookup_lock, flags); 3970 if (list_empty(&ioc->hpr_free_list)) { 3971 spin_unlock_irqrestore(&ioc->scsi_lookup_lock, flags); 3972 return 0; 3973 } 3974 3975 request = list_entry(ioc->hpr_free_list.next, 3976 struct request_tracker, tracker_list); 3977 request->cb_idx = cb_idx; 3978 smid = request->smid; 3979 list_del(&request->tracker_list); 3980 spin_unlock_irqrestore(&ioc->scsi_lookup_lock, flags); 3981 return smid; 3982 } 3983 3984 static void 3985 _base_recovery_check(struct MPT3SAS_ADAPTER *ioc) 3986 { 3987 /* 3988 * See _wait_for_commands_to_complete() call with regards to this code. 3989 */ 3990 if (ioc->shost_recovery && ioc->pending_io_count) { 3991 ioc->pending_io_count = scsi_host_busy(ioc->shost); 3992 if (ioc->pending_io_count == 0) 3993 wake_up(&ioc->reset_wq); 3994 } 3995 } 3996 3997 void mpt3sas_base_clear_st(struct MPT3SAS_ADAPTER *ioc, 3998 struct scsiio_tracker *st) 3999 { 4000 if (WARN_ON(st->smid == 0)) 4001 return; 4002 st->cb_idx = 0xFF; 4003 st->direct_io = 0; 4004 st->scmd = NULL; 4005 atomic_set(&ioc->chain_lookup[st->smid - 1].chain_offset, 0); 4006 st->smid = 0; 4007 } 4008 4009 /** 4010 * mpt3sas_base_free_smid - put smid back on free_list 4011 * @ioc: per adapter object 4012 * @smid: system request message index 4013 */ 4014 void 4015 mpt3sas_base_free_smid(struct MPT3SAS_ADAPTER *ioc, u16 smid) 4016 { 4017 unsigned long flags; 4018 int i; 4019 4020 if (smid < ioc->hi_priority_smid) { 4021 struct scsiio_tracker *st; 4022 void *request; 4023 4024 st = _get_st_from_smid(ioc, smid); 4025 if (!st) { 4026 _base_recovery_check(ioc); 4027 return; 4028 } 4029 4030 /* Clear MPI request frame */ 4031 request = mpt3sas_base_get_msg_frame(ioc, smid); 4032 memset(request, 0, ioc->request_sz); 4033 4034 mpt3sas_base_clear_st(ioc, st); 4035 _base_recovery_check(ioc); 4036 ioc->io_queue_num[smid - 1] = 0; 4037 return; 4038 } 4039 4040 spin_lock_irqsave(&ioc->scsi_lookup_lock, flags); 4041 if (smid < ioc->internal_smid) { 4042 /* hi-priority */ 4043 i = smid - ioc->hi_priority_smid; 4044 ioc->hpr_lookup[i].cb_idx = 0xFF; 4045 list_add(&ioc->hpr_lookup[i].tracker_list, &ioc->hpr_free_list); 4046 } else if (smid <= ioc->hba_queue_depth) { 4047 /* internal queue */ 4048 i = smid - ioc->internal_smid; 4049 ioc->internal_lookup[i].cb_idx = 0xFF; 4050 list_add(&ioc->internal_lookup[i].tracker_list, 4051 &ioc->internal_free_list); 4052 } 4053 spin_unlock_irqrestore(&ioc->scsi_lookup_lock, flags); 4054 } 4055 4056 /** 4057 * _base_mpi_ep_writeq - 32 bit write to MMIO 4058 * @b: data payload 4059 * @addr: address in MMIO space 4060 * @writeq_lock: spin lock 4061 * 4062 * This special handling for MPI EP to take care of 32 bit 4063 * environment where its not quarenteed to send the entire word 4064 * in one transfer. 4065 */ 4066 static inline void 4067 _base_mpi_ep_writeq(__u64 b, volatile void __iomem *addr, 4068 spinlock_t *writeq_lock) 4069 { 4070 unsigned long flags; 4071 4072 spin_lock_irqsave(writeq_lock, flags); 4073 __raw_writel((u32)(b), addr); 4074 __raw_writel((u32)(b >> 32), (addr + 4)); 4075 spin_unlock_irqrestore(writeq_lock, flags); 4076 } 4077 4078 /** 4079 * _base_writeq - 64 bit write to MMIO 4080 * @b: data payload 4081 * @addr: address in MMIO space 4082 * @writeq_lock: spin lock 4083 * 4084 * Glue for handling an atomic 64 bit word to MMIO. This special handling takes 4085 * care of 32 bit environment where its not quarenteed to send the entire word 4086 * in one transfer. 4087 */ 4088 #if defined(writeq) && defined(CONFIG_64BIT) 4089 static inline void 4090 _base_writeq(__u64 b, volatile void __iomem *addr, spinlock_t *writeq_lock) 4091 { 4092 wmb(); 4093 __raw_writeq(b, addr); 4094 barrier(); 4095 } 4096 #else 4097 static inline void 4098 _base_writeq(__u64 b, volatile void __iomem *addr, spinlock_t *writeq_lock) 4099 { 4100 _base_mpi_ep_writeq(b, addr, writeq_lock); 4101 } 4102 #endif 4103 4104 /** 4105 * _base_set_and_get_msix_index - get the msix index and assign to msix_io 4106 * variable of scsi tracker 4107 * @ioc: per adapter object 4108 * @smid: system request message index 4109 * 4110 * Return: msix index. 4111 */ 4112 static u8 4113 _base_set_and_get_msix_index(struct MPT3SAS_ADAPTER *ioc, u16 smid) 4114 { 4115 struct scsiio_tracker *st = NULL; 4116 4117 if (smid < ioc->hi_priority_smid) 4118 st = _get_st_from_smid(ioc, smid); 4119 4120 if (st == NULL) 4121 return _base_get_msix_index(ioc, NULL); 4122 4123 st->msix_io = ioc->get_msix_index_for_smlio(ioc, st->scmd); 4124 return st->msix_io; 4125 } 4126 4127 /** 4128 * _base_put_smid_mpi_ep_scsi_io - send SCSI_IO request to firmware 4129 * @ioc: per adapter object 4130 * @smid: system request message index 4131 * @handle: device handle 4132 */ 4133 static void 4134 _base_put_smid_mpi_ep_scsi_io(struct MPT3SAS_ADAPTER *ioc, 4135 u16 smid, u16 handle) 4136 { 4137 Mpi2RequestDescriptorUnion_t descriptor; 4138 u64 *request = (u64 *)&descriptor; 4139 void *mpi_req_iomem; 4140 __le32 *mfp = (__le32 *)mpt3sas_base_get_msg_frame(ioc, smid); 4141 4142 _clone_sg_entries(ioc, (void *) mfp, smid); 4143 mpi_req_iomem = (void __force *)ioc->chip + 4144 MPI_FRAME_START_OFFSET + (smid * ioc->request_sz); 4145 _base_clone_mpi_to_sys_mem(mpi_req_iomem, (void *)mfp, 4146 ioc->request_sz); 4147 descriptor.SCSIIO.RequestFlags = MPI2_REQ_DESCRIPT_FLAGS_SCSI_IO; 4148 descriptor.SCSIIO.MSIxIndex = _base_set_and_get_msix_index(ioc, smid); 4149 descriptor.SCSIIO.SMID = cpu_to_le16(smid); 4150 descriptor.SCSIIO.DevHandle = cpu_to_le16(handle); 4151 descriptor.SCSIIO.LMID = 0; 4152 _base_mpi_ep_writeq(*request, &ioc->chip->RequestDescriptorPostLow, 4153 &ioc->scsi_lookup_lock); 4154 } 4155 4156 /** 4157 * _base_put_smid_scsi_io - send SCSI_IO request to firmware 4158 * @ioc: per adapter object 4159 * @smid: system request message index 4160 * @handle: device handle 4161 */ 4162 static void 4163 _base_put_smid_scsi_io(struct MPT3SAS_ADAPTER *ioc, u16 smid, u16 handle) 4164 { 4165 Mpi2RequestDescriptorUnion_t descriptor; 4166 u64 *request = (u64 *)&descriptor; 4167 4168 4169 descriptor.SCSIIO.RequestFlags = MPI2_REQ_DESCRIPT_FLAGS_SCSI_IO; 4170 descriptor.SCSIIO.MSIxIndex = _base_set_and_get_msix_index(ioc, smid); 4171 descriptor.SCSIIO.SMID = cpu_to_le16(smid); 4172 descriptor.SCSIIO.DevHandle = cpu_to_le16(handle); 4173 descriptor.SCSIIO.LMID = 0; 4174 _base_writeq(*request, &ioc->chip->RequestDescriptorPostLow, 4175 &ioc->scsi_lookup_lock); 4176 } 4177 4178 /** 4179 * _base_put_smid_fast_path - send fast path request to firmware 4180 * @ioc: per adapter object 4181 * @smid: system request message index 4182 * @handle: device handle 4183 */ 4184 static void 4185 _base_put_smid_fast_path(struct MPT3SAS_ADAPTER *ioc, u16 smid, 4186 u16 handle) 4187 { 4188 Mpi2RequestDescriptorUnion_t descriptor; 4189 u64 *request = (u64 *)&descriptor; 4190 4191 descriptor.SCSIIO.RequestFlags = 4192 MPI25_REQ_DESCRIPT_FLAGS_FAST_PATH_SCSI_IO; 4193 descriptor.SCSIIO.MSIxIndex = _base_set_and_get_msix_index(ioc, smid); 4194 descriptor.SCSIIO.SMID = cpu_to_le16(smid); 4195 descriptor.SCSIIO.DevHandle = cpu_to_le16(handle); 4196 descriptor.SCSIIO.LMID = 0; 4197 _base_writeq(*request, &ioc->chip->RequestDescriptorPostLow, 4198 &ioc->scsi_lookup_lock); 4199 } 4200 4201 /** 4202 * _base_put_smid_hi_priority - send Task Management request to firmware 4203 * @ioc: per adapter object 4204 * @smid: system request message index 4205 * @msix_task: msix_task will be same as msix of IO in case of task abort else 0 4206 */ 4207 static void 4208 _base_put_smid_hi_priority(struct MPT3SAS_ADAPTER *ioc, u16 smid, 4209 u16 msix_task) 4210 { 4211 Mpi2RequestDescriptorUnion_t descriptor; 4212 void *mpi_req_iomem; 4213 u64 *request; 4214 4215 if (ioc->is_mcpu_endpoint) { 4216 __le32 *mfp = (__le32 *)mpt3sas_base_get_msg_frame(ioc, smid); 4217 4218 /* TBD 256 is offset within sys register. */ 4219 mpi_req_iomem = (void __force *)ioc->chip 4220 + MPI_FRAME_START_OFFSET 4221 + (smid * ioc->request_sz); 4222 _base_clone_mpi_to_sys_mem(mpi_req_iomem, (void *)mfp, 4223 ioc->request_sz); 4224 } 4225 4226 request = (u64 *)&descriptor; 4227 4228 descriptor.HighPriority.RequestFlags = 4229 MPI2_REQ_DESCRIPT_FLAGS_HIGH_PRIORITY; 4230 descriptor.HighPriority.MSIxIndex = msix_task; 4231 descriptor.HighPriority.SMID = cpu_to_le16(smid); 4232 descriptor.HighPriority.LMID = 0; 4233 descriptor.HighPriority.Reserved1 = 0; 4234 if (ioc->is_mcpu_endpoint) 4235 _base_mpi_ep_writeq(*request, 4236 &ioc->chip->RequestDescriptorPostLow, 4237 &ioc->scsi_lookup_lock); 4238 else 4239 _base_writeq(*request, &ioc->chip->RequestDescriptorPostLow, 4240 &ioc->scsi_lookup_lock); 4241 } 4242 4243 /** 4244 * mpt3sas_base_put_smid_nvme_encap - send NVMe encapsulated request to 4245 * firmware 4246 * @ioc: per adapter object 4247 * @smid: system request message index 4248 */ 4249 void 4250 mpt3sas_base_put_smid_nvme_encap(struct MPT3SAS_ADAPTER *ioc, u16 smid) 4251 { 4252 Mpi2RequestDescriptorUnion_t descriptor; 4253 u64 *request = (u64 *)&descriptor; 4254 4255 descriptor.Default.RequestFlags = 4256 MPI26_REQ_DESCRIPT_FLAGS_PCIE_ENCAPSULATED; 4257 descriptor.Default.MSIxIndex = _base_set_and_get_msix_index(ioc, smid); 4258 descriptor.Default.SMID = cpu_to_le16(smid); 4259 descriptor.Default.LMID = 0; 4260 descriptor.Default.DescriptorTypeDependent = 0; 4261 _base_writeq(*request, &ioc->chip->RequestDescriptorPostLow, 4262 &ioc->scsi_lookup_lock); 4263 } 4264 4265 /** 4266 * _base_put_smid_default - Default, primarily used for config pages 4267 * @ioc: per adapter object 4268 * @smid: system request message index 4269 */ 4270 static void 4271 _base_put_smid_default(struct MPT3SAS_ADAPTER *ioc, u16 smid) 4272 { 4273 Mpi2RequestDescriptorUnion_t descriptor; 4274 void *mpi_req_iomem; 4275 u64 *request; 4276 4277 if (ioc->is_mcpu_endpoint) { 4278 __le32 *mfp = (__le32 *)mpt3sas_base_get_msg_frame(ioc, smid); 4279 4280 _clone_sg_entries(ioc, (void *) mfp, smid); 4281 /* TBD 256 is offset within sys register */ 4282 mpi_req_iomem = (void __force *)ioc->chip + 4283 MPI_FRAME_START_OFFSET + (smid * ioc->request_sz); 4284 _base_clone_mpi_to_sys_mem(mpi_req_iomem, (void *)mfp, 4285 ioc->request_sz); 4286 } 4287 request = (u64 *)&descriptor; 4288 descriptor.Default.RequestFlags = MPI2_REQ_DESCRIPT_FLAGS_DEFAULT_TYPE; 4289 descriptor.Default.MSIxIndex = _base_set_and_get_msix_index(ioc, smid); 4290 descriptor.Default.SMID = cpu_to_le16(smid); 4291 descriptor.Default.LMID = 0; 4292 descriptor.Default.DescriptorTypeDependent = 0; 4293 if (ioc->is_mcpu_endpoint) 4294 _base_mpi_ep_writeq(*request, 4295 &ioc->chip->RequestDescriptorPostLow, 4296 &ioc->scsi_lookup_lock); 4297 else 4298 _base_writeq(*request, &ioc->chip->RequestDescriptorPostLow, 4299 &ioc->scsi_lookup_lock); 4300 } 4301 4302 /** 4303 * _base_put_smid_scsi_io_atomic - send SCSI_IO request to firmware using 4304 * Atomic Request Descriptor 4305 * @ioc: per adapter object 4306 * @smid: system request message index 4307 * @handle: device handle, unused in this function, for function type match 4308 * 4309 * Return: nothing. 4310 */ 4311 static void 4312 _base_put_smid_scsi_io_atomic(struct MPT3SAS_ADAPTER *ioc, u16 smid, 4313 u16 handle) 4314 { 4315 Mpi26AtomicRequestDescriptor_t descriptor; 4316 u32 *request = (u32 *)&descriptor; 4317 4318 descriptor.RequestFlags = MPI2_REQ_DESCRIPT_FLAGS_SCSI_IO; 4319 descriptor.MSIxIndex = _base_set_and_get_msix_index(ioc, smid); 4320 descriptor.SMID = cpu_to_le16(smid); 4321 4322 writel(cpu_to_le32(*request), &ioc->chip->AtomicRequestDescriptorPost); 4323 } 4324 4325 /** 4326 * _base_put_smid_fast_path_atomic - send fast path request to firmware 4327 * using Atomic Request Descriptor 4328 * @ioc: per adapter object 4329 * @smid: system request message index 4330 * @handle: device handle, unused in this function, for function type match 4331 * Return: nothing 4332 */ 4333 static void 4334 _base_put_smid_fast_path_atomic(struct MPT3SAS_ADAPTER *ioc, u16 smid, 4335 u16 handle) 4336 { 4337 Mpi26AtomicRequestDescriptor_t descriptor; 4338 u32 *request = (u32 *)&descriptor; 4339 4340 descriptor.RequestFlags = MPI25_REQ_DESCRIPT_FLAGS_FAST_PATH_SCSI_IO; 4341 descriptor.MSIxIndex = _base_set_and_get_msix_index(ioc, smid); 4342 descriptor.SMID = cpu_to_le16(smid); 4343 4344 writel(cpu_to_le32(*request), &ioc->chip->AtomicRequestDescriptorPost); 4345 } 4346 4347 /** 4348 * _base_put_smid_hi_priority_atomic - send Task Management request to 4349 * firmware using Atomic Request Descriptor 4350 * @ioc: per adapter object 4351 * @smid: system request message index 4352 * @msix_task: msix_task will be same as msix of IO in case of task abort else 0 4353 * 4354 * Return: nothing. 4355 */ 4356 static void 4357 _base_put_smid_hi_priority_atomic(struct MPT3SAS_ADAPTER *ioc, u16 smid, 4358 u16 msix_task) 4359 { 4360 Mpi26AtomicRequestDescriptor_t descriptor; 4361 u32 *request = (u32 *)&descriptor; 4362 4363 descriptor.RequestFlags = MPI2_REQ_DESCRIPT_FLAGS_HIGH_PRIORITY; 4364 descriptor.MSIxIndex = msix_task; 4365 descriptor.SMID = cpu_to_le16(smid); 4366 4367 writel(cpu_to_le32(*request), &ioc->chip->AtomicRequestDescriptorPost); 4368 } 4369 4370 /** 4371 * _base_put_smid_default_atomic - Default, primarily used for config pages 4372 * use Atomic Request Descriptor 4373 * @ioc: per adapter object 4374 * @smid: system request message index 4375 * 4376 * Return: nothing. 4377 */ 4378 static void 4379 _base_put_smid_default_atomic(struct MPT3SAS_ADAPTER *ioc, u16 smid) 4380 { 4381 Mpi26AtomicRequestDescriptor_t descriptor; 4382 u32 *request = (u32 *)&descriptor; 4383 4384 descriptor.RequestFlags = MPI2_REQ_DESCRIPT_FLAGS_DEFAULT_TYPE; 4385 descriptor.MSIxIndex = _base_set_and_get_msix_index(ioc, smid); 4386 descriptor.SMID = cpu_to_le16(smid); 4387 4388 writel(cpu_to_le32(*request), &ioc->chip->AtomicRequestDescriptorPost); 4389 } 4390 4391 /** 4392 * _base_display_OEMs_branding - Display branding string 4393 * @ioc: per adapter object 4394 */ 4395 static void 4396 _base_display_OEMs_branding(struct MPT3SAS_ADAPTER *ioc) 4397 { 4398 if (ioc->pdev->subsystem_vendor != PCI_VENDOR_ID_INTEL) 4399 return; 4400 4401 switch (ioc->pdev->subsystem_vendor) { 4402 case PCI_VENDOR_ID_INTEL: 4403 switch (ioc->pdev->device) { 4404 case MPI2_MFGPAGE_DEVID_SAS2008: 4405 switch (ioc->pdev->subsystem_device) { 4406 case MPT2SAS_INTEL_RMS2LL080_SSDID: 4407 ioc_info(ioc, "%s\n", 4408 MPT2SAS_INTEL_RMS2LL080_BRANDING); 4409 break; 4410 case MPT2SAS_INTEL_RMS2LL040_SSDID: 4411 ioc_info(ioc, "%s\n", 4412 MPT2SAS_INTEL_RMS2LL040_BRANDING); 4413 break; 4414 case MPT2SAS_INTEL_SSD910_SSDID: 4415 ioc_info(ioc, "%s\n", 4416 MPT2SAS_INTEL_SSD910_BRANDING); 4417 break; 4418 default: 4419 ioc_info(ioc, "Intel(R) Controller: Subsystem ID: 0x%X\n", 4420 ioc->pdev->subsystem_device); 4421 break; 4422 } 4423 break; 4424 case MPI2_MFGPAGE_DEVID_SAS2308_2: 4425 switch (ioc->pdev->subsystem_device) { 4426 case MPT2SAS_INTEL_RS25GB008_SSDID: 4427 ioc_info(ioc, "%s\n", 4428 MPT2SAS_INTEL_RS25GB008_BRANDING); 4429 break; 4430 case MPT2SAS_INTEL_RMS25JB080_SSDID: 4431 ioc_info(ioc, "%s\n", 4432 MPT2SAS_INTEL_RMS25JB080_BRANDING); 4433 break; 4434 case MPT2SAS_INTEL_RMS25JB040_SSDID: 4435 ioc_info(ioc, "%s\n", 4436 MPT2SAS_INTEL_RMS25JB040_BRANDING); 4437 break; 4438 case MPT2SAS_INTEL_RMS25KB080_SSDID: 4439 ioc_info(ioc, "%s\n", 4440 MPT2SAS_INTEL_RMS25KB080_BRANDING); 4441 break; 4442 case MPT2SAS_INTEL_RMS25KB040_SSDID: 4443 ioc_info(ioc, "%s\n", 4444 MPT2SAS_INTEL_RMS25KB040_BRANDING); 4445 break; 4446 case MPT2SAS_INTEL_RMS25LB040_SSDID: 4447 ioc_info(ioc, "%s\n", 4448 MPT2SAS_INTEL_RMS25LB040_BRANDING); 4449 break; 4450 case MPT2SAS_INTEL_RMS25LB080_SSDID: 4451 ioc_info(ioc, "%s\n", 4452 MPT2SAS_INTEL_RMS25LB080_BRANDING); 4453 break; 4454 default: 4455 ioc_info(ioc, "Intel(R) Controller: Subsystem ID: 0x%X\n", 4456 ioc->pdev->subsystem_device); 4457 break; 4458 } 4459 break; 4460 case MPI25_MFGPAGE_DEVID_SAS3008: 4461 switch (ioc->pdev->subsystem_device) { 4462 case MPT3SAS_INTEL_RMS3JC080_SSDID: 4463 ioc_info(ioc, "%s\n", 4464 MPT3SAS_INTEL_RMS3JC080_BRANDING); 4465 break; 4466 4467 case MPT3SAS_INTEL_RS3GC008_SSDID: 4468 ioc_info(ioc, "%s\n", 4469 MPT3SAS_INTEL_RS3GC008_BRANDING); 4470 break; 4471 case MPT3SAS_INTEL_RS3FC044_SSDID: 4472 ioc_info(ioc, "%s\n", 4473 MPT3SAS_INTEL_RS3FC044_BRANDING); 4474 break; 4475 case MPT3SAS_INTEL_RS3UC080_SSDID: 4476 ioc_info(ioc, "%s\n", 4477 MPT3SAS_INTEL_RS3UC080_BRANDING); 4478 break; 4479 default: 4480 ioc_info(ioc, "Intel(R) Controller: Subsystem ID: 0x%X\n", 4481 ioc->pdev->subsystem_device); 4482 break; 4483 } 4484 break; 4485 default: 4486 ioc_info(ioc, "Intel(R) Controller: Subsystem ID: 0x%X\n", 4487 ioc->pdev->subsystem_device); 4488 break; 4489 } 4490 break; 4491 case PCI_VENDOR_ID_DELL: 4492 switch (ioc->pdev->device) { 4493 case MPI2_MFGPAGE_DEVID_SAS2008: 4494 switch (ioc->pdev->subsystem_device) { 4495 case MPT2SAS_DELL_6GBPS_SAS_HBA_SSDID: 4496 ioc_info(ioc, "%s\n", 4497 MPT2SAS_DELL_6GBPS_SAS_HBA_BRANDING); 4498 break; 4499 case MPT2SAS_DELL_PERC_H200_ADAPTER_SSDID: 4500 ioc_info(ioc, "%s\n", 4501 MPT2SAS_DELL_PERC_H200_ADAPTER_BRANDING); 4502 break; 4503 case MPT2SAS_DELL_PERC_H200_INTEGRATED_SSDID: 4504 ioc_info(ioc, "%s\n", 4505 MPT2SAS_DELL_PERC_H200_INTEGRATED_BRANDING); 4506 break; 4507 case MPT2SAS_DELL_PERC_H200_MODULAR_SSDID: 4508 ioc_info(ioc, "%s\n", 4509 MPT2SAS_DELL_PERC_H200_MODULAR_BRANDING); 4510 break; 4511 case MPT2SAS_DELL_PERC_H200_EMBEDDED_SSDID: 4512 ioc_info(ioc, "%s\n", 4513 MPT2SAS_DELL_PERC_H200_EMBEDDED_BRANDING); 4514 break; 4515 case MPT2SAS_DELL_PERC_H200_SSDID: 4516 ioc_info(ioc, "%s\n", 4517 MPT2SAS_DELL_PERC_H200_BRANDING); 4518 break; 4519 case MPT2SAS_DELL_6GBPS_SAS_SSDID: 4520 ioc_info(ioc, "%s\n", 4521 MPT2SAS_DELL_6GBPS_SAS_BRANDING); 4522 break; 4523 default: 4524 ioc_info(ioc, "Dell 6Gbps HBA: Subsystem ID: 0x%X\n", 4525 ioc->pdev->subsystem_device); 4526 break; 4527 } 4528 break; 4529 case MPI25_MFGPAGE_DEVID_SAS3008: 4530 switch (ioc->pdev->subsystem_device) { 4531 case MPT3SAS_DELL_12G_HBA_SSDID: 4532 ioc_info(ioc, "%s\n", 4533 MPT3SAS_DELL_12G_HBA_BRANDING); 4534 break; 4535 default: 4536 ioc_info(ioc, "Dell 12Gbps HBA: Subsystem ID: 0x%X\n", 4537 ioc->pdev->subsystem_device); 4538 break; 4539 } 4540 break; 4541 default: 4542 ioc_info(ioc, "Dell HBA: Subsystem ID: 0x%X\n", 4543 ioc->pdev->subsystem_device); 4544 break; 4545 } 4546 break; 4547 case PCI_VENDOR_ID_CISCO: 4548 switch (ioc->pdev->device) { 4549 case MPI25_MFGPAGE_DEVID_SAS3008: 4550 switch (ioc->pdev->subsystem_device) { 4551 case MPT3SAS_CISCO_12G_8E_HBA_SSDID: 4552 ioc_info(ioc, "%s\n", 4553 MPT3SAS_CISCO_12G_8E_HBA_BRANDING); 4554 break; 4555 case MPT3SAS_CISCO_12G_8I_HBA_SSDID: 4556 ioc_info(ioc, "%s\n", 4557 MPT3SAS_CISCO_12G_8I_HBA_BRANDING); 4558 break; 4559 case MPT3SAS_CISCO_12G_AVILA_HBA_SSDID: 4560 ioc_info(ioc, "%s\n", 4561 MPT3SAS_CISCO_12G_AVILA_HBA_BRANDING); 4562 break; 4563 default: 4564 ioc_info(ioc, "Cisco 12Gbps SAS HBA: Subsystem ID: 0x%X\n", 4565 ioc->pdev->subsystem_device); 4566 break; 4567 } 4568 break; 4569 case MPI25_MFGPAGE_DEVID_SAS3108_1: 4570 switch (ioc->pdev->subsystem_device) { 4571 case MPT3SAS_CISCO_12G_AVILA_HBA_SSDID: 4572 ioc_info(ioc, "%s\n", 4573 MPT3SAS_CISCO_12G_AVILA_HBA_BRANDING); 4574 break; 4575 case MPT3SAS_CISCO_12G_COLUSA_MEZZANINE_HBA_SSDID: 4576 ioc_info(ioc, "%s\n", 4577 MPT3SAS_CISCO_12G_COLUSA_MEZZANINE_HBA_BRANDING); 4578 break; 4579 default: 4580 ioc_info(ioc, "Cisco 12Gbps SAS HBA: Subsystem ID: 0x%X\n", 4581 ioc->pdev->subsystem_device); 4582 break; 4583 } 4584 break; 4585 default: 4586 ioc_info(ioc, "Cisco SAS HBA: Subsystem ID: 0x%X\n", 4587 ioc->pdev->subsystem_device); 4588 break; 4589 } 4590 break; 4591 case MPT2SAS_HP_3PAR_SSVID: 4592 switch (ioc->pdev->device) { 4593 case MPI2_MFGPAGE_DEVID_SAS2004: 4594 switch (ioc->pdev->subsystem_device) { 4595 case MPT2SAS_HP_DAUGHTER_2_4_INTERNAL_SSDID: 4596 ioc_info(ioc, "%s\n", 4597 MPT2SAS_HP_DAUGHTER_2_4_INTERNAL_BRANDING); 4598 break; 4599 default: 4600 ioc_info(ioc, "HP 6Gbps SAS HBA: Subsystem ID: 0x%X\n", 4601 ioc->pdev->subsystem_device); 4602 break; 4603 } 4604 break; 4605 case MPI2_MFGPAGE_DEVID_SAS2308_2: 4606 switch (ioc->pdev->subsystem_device) { 4607 case MPT2SAS_HP_2_4_INTERNAL_SSDID: 4608 ioc_info(ioc, "%s\n", 4609 MPT2SAS_HP_2_4_INTERNAL_BRANDING); 4610 break; 4611 case MPT2SAS_HP_2_4_EXTERNAL_SSDID: 4612 ioc_info(ioc, "%s\n", 4613 MPT2SAS_HP_2_4_EXTERNAL_BRANDING); 4614 break; 4615 case MPT2SAS_HP_1_4_INTERNAL_1_4_EXTERNAL_SSDID: 4616 ioc_info(ioc, "%s\n", 4617 MPT2SAS_HP_1_4_INTERNAL_1_4_EXTERNAL_BRANDING); 4618 break; 4619 case MPT2SAS_HP_EMBEDDED_2_4_INTERNAL_SSDID: 4620 ioc_info(ioc, "%s\n", 4621 MPT2SAS_HP_EMBEDDED_2_4_INTERNAL_BRANDING); 4622 break; 4623 default: 4624 ioc_info(ioc, "HP 6Gbps SAS HBA: Subsystem ID: 0x%X\n", 4625 ioc->pdev->subsystem_device); 4626 break; 4627 } 4628 break; 4629 default: 4630 ioc_info(ioc, "HP SAS HBA: Subsystem ID: 0x%X\n", 4631 ioc->pdev->subsystem_device); 4632 break; 4633 } 4634 break; 4635 default: 4636 break; 4637 } 4638 } 4639 4640 /** 4641 * _base_display_fwpkg_version - sends FWUpload request to pull FWPkg 4642 * version from FW Image Header. 4643 * @ioc: per adapter object 4644 * 4645 * Return: 0 for success, non-zero for failure. 4646 */ 4647 static int 4648 _base_display_fwpkg_version(struct MPT3SAS_ADAPTER *ioc) 4649 { 4650 Mpi2FWImageHeader_t *fw_img_hdr; 4651 Mpi26ComponentImageHeader_t *cmp_img_hdr; 4652 Mpi25FWUploadRequest_t *mpi_request; 4653 Mpi2FWUploadReply_t mpi_reply; 4654 int r = 0, issue_diag_reset = 0; 4655 u32 package_version = 0; 4656 void *fwpkg_data = NULL; 4657 dma_addr_t fwpkg_data_dma; 4658 u16 smid, ioc_status; 4659 size_t data_length; 4660 4661 dinitprintk(ioc, ioc_info(ioc, "%s\n", __func__)); 4662 4663 if (ioc->base_cmds.status & MPT3_CMD_PENDING) { 4664 ioc_err(ioc, "%s: internal command already in use\n", __func__); 4665 return -EAGAIN; 4666 } 4667 4668 data_length = sizeof(Mpi2FWImageHeader_t); 4669 fwpkg_data = dma_alloc_coherent(&ioc->pdev->dev, data_length, 4670 &fwpkg_data_dma, GFP_KERNEL); 4671 if (!fwpkg_data) { 4672 ioc_err(ioc, 4673 "Memory allocation for fwpkg data failed at %s:%d/%s()!\n", 4674 __FILE__, __LINE__, __func__); 4675 return -ENOMEM; 4676 } 4677 4678 smid = mpt3sas_base_get_smid(ioc, ioc->base_cb_idx); 4679 if (!smid) { 4680 ioc_err(ioc, "%s: failed obtaining a smid\n", __func__); 4681 r = -EAGAIN; 4682 goto out; 4683 } 4684 4685 ioc->base_cmds.status = MPT3_CMD_PENDING; 4686 mpi_request = mpt3sas_base_get_msg_frame(ioc, smid); 4687 ioc->base_cmds.smid = smid; 4688 memset(mpi_request, 0, sizeof(Mpi25FWUploadRequest_t)); 4689 mpi_request->Function = MPI2_FUNCTION_FW_UPLOAD; 4690 mpi_request->ImageType = MPI2_FW_UPLOAD_ITYPE_FW_FLASH; 4691 mpi_request->ImageSize = cpu_to_le32(data_length); 4692 ioc->build_sg(ioc, &mpi_request->SGL, 0, 0, fwpkg_data_dma, 4693 data_length); 4694 init_completion(&ioc->base_cmds.done); 4695 ioc->put_smid_default(ioc, smid); 4696 /* Wait for 15 seconds */ 4697 wait_for_completion_timeout(&ioc->base_cmds.done, 4698 FW_IMG_HDR_READ_TIMEOUT*HZ); 4699 ioc_info(ioc, "%s: complete\n", __func__); 4700 if (!(ioc->base_cmds.status & MPT3_CMD_COMPLETE)) { 4701 ioc_err(ioc, "%s: timeout\n", __func__); 4702 _debug_dump_mf(mpi_request, 4703 sizeof(Mpi25FWUploadRequest_t)/4); 4704 issue_diag_reset = 1; 4705 } else { 4706 memset(&mpi_reply, 0, sizeof(Mpi2FWUploadReply_t)); 4707 if (ioc->base_cmds.status & MPT3_CMD_REPLY_VALID) { 4708 memcpy(&mpi_reply, ioc->base_cmds.reply, 4709 sizeof(Mpi2FWUploadReply_t)); 4710 ioc_status = le16_to_cpu(mpi_reply.IOCStatus) & 4711 MPI2_IOCSTATUS_MASK; 4712 if (ioc_status == MPI2_IOCSTATUS_SUCCESS) { 4713 fw_img_hdr = (Mpi2FWImageHeader_t *)fwpkg_data; 4714 if (le32_to_cpu(fw_img_hdr->Signature) == 4715 MPI26_IMAGE_HEADER_SIGNATURE0_MPI26) { 4716 cmp_img_hdr = 4717 (Mpi26ComponentImageHeader_t *) 4718 (fwpkg_data); 4719 package_version = 4720 le32_to_cpu( 4721 cmp_img_hdr->ApplicationSpecific); 4722 } else 4723 package_version = 4724 le32_to_cpu( 4725 fw_img_hdr->PackageVersion.Word); 4726 if (package_version) 4727 ioc_info(ioc, 4728 "FW Package Ver(%02d.%02d.%02d.%02d)\n", 4729 ((package_version) & 0xFF000000) >> 24, 4730 ((package_version) & 0x00FF0000) >> 16, 4731 ((package_version) & 0x0000FF00) >> 8, 4732 (package_version) & 0x000000FF); 4733 } else { 4734 _debug_dump_mf(&mpi_reply, 4735 sizeof(Mpi2FWUploadReply_t)/4); 4736 } 4737 } 4738 } 4739 ioc->base_cmds.status = MPT3_CMD_NOT_USED; 4740 out: 4741 if (fwpkg_data) 4742 dma_free_coherent(&ioc->pdev->dev, data_length, fwpkg_data, 4743 fwpkg_data_dma); 4744 if (issue_diag_reset) { 4745 if (ioc->drv_internal_flags & MPT_DRV_INTERNAL_FIRST_PE_ISSUED) 4746 return -EFAULT; 4747 if (mpt3sas_base_check_for_fault_and_issue_reset(ioc)) 4748 return -EFAULT; 4749 r = -EAGAIN; 4750 } 4751 return r; 4752 } 4753 4754 /** 4755 * _base_display_ioc_capabilities - Display IOC's capabilities. 4756 * @ioc: per adapter object 4757 */ 4758 static void 4759 _base_display_ioc_capabilities(struct MPT3SAS_ADAPTER *ioc) 4760 { 4761 int i = 0; 4762 char desc[17] = {0}; 4763 u32 iounit_pg1_flags; 4764 u32 bios_version; 4765 4766 bios_version = le32_to_cpu(ioc->bios_pg3.BiosVersion); 4767 strncpy(desc, ioc->manu_pg0.ChipName, 16); 4768 ioc_info(ioc, "%s: FWVersion(%02d.%02d.%02d.%02d), ChipRevision(0x%02x), BiosVersion(%02d.%02d.%02d.%02d)\n", 4769 desc, 4770 (ioc->facts.FWVersion.Word & 0xFF000000) >> 24, 4771 (ioc->facts.FWVersion.Word & 0x00FF0000) >> 16, 4772 (ioc->facts.FWVersion.Word & 0x0000FF00) >> 8, 4773 ioc->facts.FWVersion.Word & 0x000000FF, 4774 ioc->pdev->revision, 4775 (bios_version & 0xFF000000) >> 24, 4776 (bios_version & 0x00FF0000) >> 16, 4777 (bios_version & 0x0000FF00) >> 8, 4778 bios_version & 0x000000FF); 4779 4780 _base_display_OEMs_branding(ioc); 4781 4782 if (ioc->facts.ProtocolFlags & MPI2_IOCFACTS_PROTOCOL_NVME_DEVICES) { 4783 pr_info("%sNVMe", i ? "," : ""); 4784 i++; 4785 } 4786 4787 ioc_info(ioc, "Protocol=("); 4788 4789 if (ioc->facts.ProtocolFlags & MPI2_IOCFACTS_PROTOCOL_SCSI_INITIATOR) { 4790 pr_cont("Initiator"); 4791 i++; 4792 } 4793 4794 if (ioc->facts.ProtocolFlags & MPI2_IOCFACTS_PROTOCOL_SCSI_TARGET) { 4795 pr_cont("%sTarget", i ? "," : ""); 4796 i++; 4797 } 4798 4799 i = 0; 4800 pr_cont("), Capabilities=("); 4801 4802 if (!ioc->hide_ir_msg) { 4803 if (ioc->facts.IOCCapabilities & 4804 MPI2_IOCFACTS_CAPABILITY_INTEGRATED_RAID) { 4805 pr_cont("Raid"); 4806 i++; 4807 } 4808 } 4809 4810 if (ioc->facts.IOCCapabilities & MPI2_IOCFACTS_CAPABILITY_TLR) { 4811 pr_cont("%sTLR", i ? "," : ""); 4812 i++; 4813 } 4814 4815 if (ioc->facts.IOCCapabilities & MPI2_IOCFACTS_CAPABILITY_MULTICAST) { 4816 pr_cont("%sMulticast", i ? "," : ""); 4817 i++; 4818 } 4819 4820 if (ioc->facts.IOCCapabilities & 4821 MPI2_IOCFACTS_CAPABILITY_BIDIRECTIONAL_TARGET) { 4822 pr_cont("%sBIDI Target", i ? "," : ""); 4823 i++; 4824 } 4825 4826 if (ioc->facts.IOCCapabilities & MPI2_IOCFACTS_CAPABILITY_EEDP) { 4827 pr_cont("%sEEDP", i ? "," : ""); 4828 i++; 4829 } 4830 4831 if (ioc->facts.IOCCapabilities & 4832 MPI2_IOCFACTS_CAPABILITY_SNAPSHOT_BUFFER) { 4833 pr_cont("%sSnapshot Buffer", i ? "," : ""); 4834 i++; 4835 } 4836 4837 if (ioc->facts.IOCCapabilities & 4838 MPI2_IOCFACTS_CAPABILITY_DIAG_TRACE_BUFFER) { 4839 pr_cont("%sDiag Trace Buffer", i ? "," : ""); 4840 i++; 4841 } 4842 4843 if (ioc->facts.IOCCapabilities & 4844 MPI2_IOCFACTS_CAPABILITY_EXTENDED_BUFFER) { 4845 pr_cont("%sDiag Extended Buffer", i ? "," : ""); 4846 i++; 4847 } 4848 4849 if (ioc->facts.IOCCapabilities & 4850 MPI2_IOCFACTS_CAPABILITY_TASK_SET_FULL_HANDLING) { 4851 pr_cont("%sTask Set Full", i ? "," : ""); 4852 i++; 4853 } 4854 4855 iounit_pg1_flags = le32_to_cpu(ioc->iounit_pg1.Flags); 4856 if (!(iounit_pg1_flags & MPI2_IOUNITPAGE1_NATIVE_COMMAND_Q_DISABLE)) { 4857 pr_cont("%sNCQ", i ? "," : ""); 4858 i++; 4859 } 4860 4861 pr_cont(")\n"); 4862 } 4863 4864 /** 4865 * mpt3sas_base_update_missing_delay - change the missing delay timers 4866 * @ioc: per adapter object 4867 * @device_missing_delay: amount of time till device is reported missing 4868 * @io_missing_delay: interval IO is returned when there is a missing device 4869 * 4870 * Passed on the command line, this function will modify the device missing 4871 * delay, as well as the io missing delay. This should be called at driver 4872 * load time. 4873 */ 4874 void 4875 mpt3sas_base_update_missing_delay(struct MPT3SAS_ADAPTER *ioc, 4876 u16 device_missing_delay, u8 io_missing_delay) 4877 { 4878 u16 dmd, dmd_new, dmd_orignal; 4879 u8 io_missing_delay_original; 4880 u16 sz; 4881 Mpi2SasIOUnitPage1_t *sas_iounit_pg1 = NULL; 4882 Mpi2ConfigReply_t mpi_reply; 4883 u8 num_phys = 0; 4884 u16 ioc_status; 4885 4886 mpt3sas_config_get_number_hba_phys(ioc, &num_phys); 4887 if (!num_phys) 4888 return; 4889 4890 sz = offsetof(Mpi2SasIOUnitPage1_t, PhyData) + (num_phys * 4891 sizeof(Mpi2SasIOUnit1PhyData_t)); 4892 sas_iounit_pg1 = kzalloc(sz, GFP_KERNEL); 4893 if (!sas_iounit_pg1) { 4894 ioc_err(ioc, "failure at %s:%d/%s()!\n", 4895 __FILE__, __LINE__, __func__); 4896 goto out; 4897 } 4898 if ((mpt3sas_config_get_sas_iounit_pg1(ioc, &mpi_reply, 4899 sas_iounit_pg1, sz))) { 4900 ioc_err(ioc, "failure at %s:%d/%s()!\n", 4901 __FILE__, __LINE__, __func__); 4902 goto out; 4903 } 4904 ioc_status = le16_to_cpu(mpi_reply.IOCStatus) & 4905 MPI2_IOCSTATUS_MASK; 4906 if (ioc_status != MPI2_IOCSTATUS_SUCCESS) { 4907 ioc_err(ioc, "failure at %s:%d/%s()!\n", 4908 __FILE__, __LINE__, __func__); 4909 goto out; 4910 } 4911 4912 /* device missing delay */ 4913 dmd = sas_iounit_pg1->ReportDeviceMissingDelay; 4914 if (dmd & MPI2_SASIOUNIT1_REPORT_MISSING_UNIT_16) 4915 dmd = (dmd & MPI2_SASIOUNIT1_REPORT_MISSING_TIMEOUT_MASK) * 16; 4916 else 4917 dmd = dmd & MPI2_SASIOUNIT1_REPORT_MISSING_TIMEOUT_MASK; 4918 dmd_orignal = dmd; 4919 if (device_missing_delay > 0x7F) { 4920 dmd = (device_missing_delay > 0x7F0) ? 0x7F0 : 4921 device_missing_delay; 4922 dmd = dmd / 16; 4923 dmd |= MPI2_SASIOUNIT1_REPORT_MISSING_UNIT_16; 4924 } else 4925 dmd = device_missing_delay; 4926 sas_iounit_pg1->ReportDeviceMissingDelay = dmd; 4927 4928 /* io missing delay */ 4929 io_missing_delay_original = sas_iounit_pg1->IODeviceMissingDelay; 4930 sas_iounit_pg1->IODeviceMissingDelay = io_missing_delay; 4931 4932 if (!mpt3sas_config_set_sas_iounit_pg1(ioc, &mpi_reply, sas_iounit_pg1, 4933 sz)) { 4934 if (dmd & MPI2_SASIOUNIT1_REPORT_MISSING_UNIT_16) 4935 dmd_new = (dmd & 4936 MPI2_SASIOUNIT1_REPORT_MISSING_TIMEOUT_MASK) * 16; 4937 else 4938 dmd_new = 4939 dmd & MPI2_SASIOUNIT1_REPORT_MISSING_TIMEOUT_MASK; 4940 ioc_info(ioc, "device_missing_delay: old(%d), new(%d)\n", 4941 dmd_orignal, dmd_new); 4942 ioc_info(ioc, "ioc_missing_delay: old(%d), new(%d)\n", 4943 io_missing_delay_original, 4944 io_missing_delay); 4945 ioc->device_missing_delay = dmd_new; 4946 ioc->io_missing_delay = io_missing_delay; 4947 } 4948 4949 out: 4950 kfree(sas_iounit_pg1); 4951 } 4952 4953 /** 4954 * _base_update_ioc_page1_inlinewith_perf_mode - Update IOC Page1 fields 4955 * according to performance mode. 4956 * @ioc : per adapter object 4957 * 4958 * Return: zero on success; otherwise return EAGAIN error code asking the 4959 * caller to retry. 4960 */ 4961 static int 4962 _base_update_ioc_page1_inlinewith_perf_mode(struct MPT3SAS_ADAPTER *ioc) 4963 { 4964 Mpi2IOCPage1_t ioc_pg1; 4965 Mpi2ConfigReply_t mpi_reply; 4966 int rc; 4967 4968 rc = mpt3sas_config_get_ioc_pg1(ioc, &mpi_reply, &ioc->ioc_pg1_copy); 4969 if (rc) 4970 return rc; 4971 memcpy(&ioc_pg1, &ioc->ioc_pg1_copy, sizeof(Mpi2IOCPage1_t)); 4972 4973 switch (perf_mode) { 4974 case MPT_PERF_MODE_DEFAULT: 4975 case MPT_PERF_MODE_BALANCED: 4976 if (ioc->high_iops_queues) { 4977 ioc_info(ioc, 4978 "Enable interrupt coalescing only for first\t" 4979 "%d reply queues\n", 4980 MPT3SAS_HIGH_IOPS_REPLY_QUEUES); 4981 /* 4982 * If 31st bit is zero then interrupt coalescing is 4983 * enabled for all reply descriptor post queues. 4984 * If 31st bit is set to one then user can 4985 * enable/disable interrupt coalescing on per reply 4986 * descriptor post queue group(8) basis. So to enable 4987 * interrupt coalescing only on first reply descriptor 4988 * post queue group 31st bit and zero th bit is enabled. 4989 */ 4990 ioc_pg1.ProductSpecific = cpu_to_le32(0x80000000 | 4991 ((1 << MPT3SAS_HIGH_IOPS_REPLY_QUEUES/8) - 1)); 4992 rc = mpt3sas_config_set_ioc_pg1(ioc, &mpi_reply, &ioc_pg1); 4993 if (rc) 4994 return rc; 4995 ioc_info(ioc, "performance mode: balanced\n"); 4996 return 0; 4997 } 4998 fallthrough; 4999 case MPT_PERF_MODE_LATENCY: 5000 /* 5001 * Enable interrupt coalescing on all reply queues 5002 * with timeout value 0xA 5003 */ 5004 ioc_pg1.CoalescingTimeout = cpu_to_le32(0xa); 5005 ioc_pg1.Flags |= cpu_to_le32(MPI2_IOCPAGE1_REPLY_COALESCING); 5006 ioc_pg1.ProductSpecific = 0; 5007 rc = mpt3sas_config_set_ioc_pg1(ioc, &mpi_reply, &ioc_pg1); 5008 if (rc) 5009 return rc; 5010 ioc_info(ioc, "performance mode: latency\n"); 5011 break; 5012 case MPT_PERF_MODE_IOPS: 5013 /* 5014 * Enable interrupt coalescing on all reply queues. 5015 */ 5016 ioc_info(ioc, 5017 "performance mode: iops with coalescing timeout: 0x%x\n", 5018 le32_to_cpu(ioc_pg1.CoalescingTimeout)); 5019 ioc_pg1.Flags |= cpu_to_le32(MPI2_IOCPAGE1_REPLY_COALESCING); 5020 ioc_pg1.ProductSpecific = 0; 5021 rc = mpt3sas_config_set_ioc_pg1(ioc, &mpi_reply, &ioc_pg1); 5022 if (rc) 5023 return rc; 5024 break; 5025 } 5026 return 0; 5027 } 5028 5029 /** 5030 * _base_get_event_diag_triggers - get event diag trigger values from 5031 * persistent pages 5032 * @ioc : per adapter object 5033 * 5034 * Return: nothing. 5035 */ 5036 static int 5037 _base_get_event_diag_triggers(struct MPT3SAS_ADAPTER *ioc) 5038 { 5039 Mpi26DriverTriggerPage2_t trigger_pg2; 5040 struct SL_WH_EVENT_TRIGGER_T *event_tg; 5041 MPI26_DRIVER_MPI_EVENT_TIGGER_ENTRY *mpi_event_tg; 5042 Mpi2ConfigReply_t mpi_reply; 5043 int r = 0, i = 0; 5044 u16 count = 0; 5045 u16 ioc_status; 5046 5047 r = mpt3sas_config_get_driver_trigger_pg2(ioc, &mpi_reply, 5048 &trigger_pg2); 5049 if (r) 5050 return r; 5051 5052 ioc_status = le16_to_cpu(mpi_reply.IOCStatus) & 5053 MPI2_IOCSTATUS_MASK; 5054 if (ioc_status != MPI2_IOCSTATUS_SUCCESS) { 5055 dinitprintk(ioc, 5056 ioc_err(ioc, 5057 "%s: Failed to get trigger pg2, ioc_status(0x%04x)\n", 5058 __func__, ioc_status)); 5059 return 0; 5060 } 5061 5062 if (le16_to_cpu(trigger_pg2.NumMPIEventTrigger)) { 5063 count = le16_to_cpu(trigger_pg2.NumMPIEventTrigger); 5064 count = min_t(u16, NUM_VALID_ENTRIES, count); 5065 ioc->diag_trigger_event.ValidEntries = count; 5066 5067 event_tg = &ioc->diag_trigger_event.EventTriggerEntry[0]; 5068 mpi_event_tg = &trigger_pg2.MPIEventTriggers[0]; 5069 for (i = 0; i < count; i++) { 5070 event_tg->EventValue = le16_to_cpu( 5071 mpi_event_tg->MPIEventCode); 5072 event_tg->LogEntryQualifier = le16_to_cpu( 5073 mpi_event_tg->MPIEventCodeSpecific); 5074 event_tg++; 5075 mpi_event_tg++; 5076 } 5077 } 5078 return 0; 5079 } 5080 5081 /** 5082 * _base_get_scsi_diag_triggers - get scsi diag trigger values from 5083 * persistent pages 5084 * @ioc : per adapter object 5085 * 5086 * Return: 0 on success; otherwise return failure status. 5087 */ 5088 static int 5089 _base_get_scsi_diag_triggers(struct MPT3SAS_ADAPTER *ioc) 5090 { 5091 Mpi26DriverTriggerPage3_t trigger_pg3; 5092 struct SL_WH_SCSI_TRIGGER_T *scsi_tg; 5093 MPI26_DRIVER_SCSI_SENSE_TIGGER_ENTRY *mpi_scsi_tg; 5094 Mpi2ConfigReply_t mpi_reply; 5095 int r = 0, i = 0; 5096 u16 count = 0; 5097 u16 ioc_status; 5098 5099 r = mpt3sas_config_get_driver_trigger_pg3(ioc, &mpi_reply, 5100 &trigger_pg3); 5101 if (r) 5102 return r; 5103 5104 ioc_status = le16_to_cpu(mpi_reply.IOCStatus) & 5105 MPI2_IOCSTATUS_MASK; 5106 if (ioc_status != MPI2_IOCSTATUS_SUCCESS) { 5107 dinitprintk(ioc, 5108 ioc_err(ioc, 5109 "%s: Failed to get trigger pg3, ioc_status(0x%04x)\n", 5110 __func__, ioc_status)); 5111 return 0; 5112 } 5113 5114 if (le16_to_cpu(trigger_pg3.NumSCSISenseTrigger)) { 5115 count = le16_to_cpu(trigger_pg3.NumSCSISenseTrigger); 5116 count = min_t(u16, NUM_VALID_ENTRIES, count); 5117 ioc->diag_trigger_scsi.ValidEntries = count; 5118 5119 scsi_tg = &ioc->diag_trigger_scsi.SCSITriggerEntry[0]; 5120 mpi_scsi_tg = &trigger_pg3.SCSISenseTriggers[0]; 5121 for (i = 0; i < count; i++) { 5122 scsi_tg->ASCQ = mpi_scsi_tg->ASCQ; 5123 scsi_tg->ASC = mpi_scsi_tg->ASC; 5124 scsi_tg->SenseKey = mpi_scsi_tg->SenseKey; 5125 5126 scsi_tg++; 5127 mpi_scsi_tg++; 5128 } 5129 } 5130 return 0; 5131 } 5132 5133 /** 5134 * _base_get_mpi_diag_triggers - get mpi diag trigger values from 5135 * persistent pages 5136 * @ioc : per adapter object 5137 * 5138 * Return: 0 on success; otherwise return failure status. 5139 */ 5140 static int 5141 _base_get_mpi_diag_triggers(struct MPT3SAS_ADAPTER *ioc) 5142 { 5143 Mpi26DriverTriggerPage4_t trigger_pg4; 5144 struct SL_WH_MPI_TRIGGER_T *status_tg; 5145 MPI26_DRIVER_IOCSTATUS_LOGINFO_TIGGER_ENTRY *mpi_status_tg; 5146 Mpi2ConfigReply_t mpi_reply; 5147 int r = 0, i = 0; 5148 u16 count = 0; 5149 u16 ioc_status; 5150 5151 r = mpt3sas_config_get_driver_trigger_pg4(ioc, &mpi_reply, 5152 &trigger_pg4); 5153 if (r) 5154 return r; 5155 5156 ioc_status = le16_to_cpu(mpi_reply.IOCStatus) & 5157 MPI2_IOCSTATUS_MASK; 5158 if (ioc_status != MPI2_IOCSTATUS_SUCCESS) { 5159 dinitprintk(ioc, 5160 ioc_err(ioc, 5161 "%s: Failed to get trigger pg4, ioc_status(0x%04x)\n", 5162 __func__, ioc_status)); 5163 return 0; 5164 } 5165 5166 if (le16_to_cpu(trigger_pg4.NumIOCStatusLogInfoTrigger)) { 5167 count = le16_to_cpu(trigger_pg4.NumIOCStatusLogInfoTrigger); 5168 count = min_t(u16, NUM_VALID_ENTRIES, count); 5169 ioc->diag_trigger_mpi.ValidEntries = count; 5170 5171 status_tg = &ioc->diag_trigger_mpi.MPITriggerEntry[0]; 5172 mpi_status_tg = &trigger_pg4.IOCStatusLoginfoTriggers[0]; 5173 5174 for (i = 0; i < count; i++) { 5175 status_tg->IOCStatus = le16_to_cpu( 5176 mpi_status_tg->IOCStatus); 5177 status_tg->IocLogInfo = le32_to_cpu( 5178 mpi_status_tg->LogInfo); 5179 5180 status_tg++; 5181 mpi_status_tg++; 5182 } 5183 } 5184 return 0; 5185 } 5186 5187 /** 5188 * _base_get_master_diag_triggers - get master diag trigger values from 5189 * persistent pages 5190 * @ioc : per adapter object 5191 * 5192 * Return: nothing. 5193 */ 5194 static int 5195 _base_get_master_diag_triggers(struct MPT3SAS_ADAPTER *ioc) 5196 { 5197 Mpi26DriverTriggerPage1_t trigger_pg1; 5198 Mpi2ConfigReply_t mpi_reply; 5199 int r; 5200 u16 ioc_status; 5201 5202 r = mpt3sas_config_get_driver_trigger_pg1(ioc, &mpi_reply, 5203 &trigger_pg1); 5204 if (r) 5205 return r; 5206 5207 ioc_status = le16_to_cpu(mpi_reply.IOCStatus) & 5208 MPI2_IOCSTATUS_MASK; 5209 if (ioc_status != MPI2_IOCSTATUS_SUCCESS) { 5210 dinitprintk(ioc, 5211 ioc_err(ioc, 5212 "%s: Failed to get trigger pg1, ioc_status(0x%04x)\n", 5213 __func__, ioc_status)); 5214 return 0; 5215 } 5216 5217 if (le16_to_cpu(trigger_pg1.NumMasterTrigger)) 5218 ioc->diag_trigger_master.MasterData |= 5219 le32_to_cpu( 5220 trigger_pg1.MasterTriggers[0].MasterTriggerFlags); 5221 return 0; 5222 } 5223 5224 /** 5225 * _base_check_for_trigger_pages_support - checks whether HBA FW supports 5226 * driver trigger pages or not 5227 * @ioc : per adapter object 5228 * @trigger_flags : address where trigger page0's TriggerFlags value is copied 5229 * 5230 * Return: trigger flags mask if HBA FW supports driver trigger pages; 5231 * otherwise returns %-EFAULT if driver trigger pages are not supported by FW or 5232 * return EAGAIN if diag reset occurred due to FW fault and asking the 5233 * caller to retry the command. 5234 * 5235 */ 5236 static int 5237 _base_check_for_trigger_pages_support(struct MPT3SAS_ADAPTER *ioc, u32 *trigger_flags) 5238 { 5239 Mpi26DriverTriggerPage0_t trigger_pg0; 5240 int r = 0; 5241 Mpi2ConfigReply_t mpi_reply; 5242 u16 ioc_status; 5243 5244 r = mpt3sas_config_get_driver_trigger_pg0(ioc, &mpi_reply, 5245 &trigger_pg0); 5246 if (r) 5247 return r; 5248 5249 ioc_status = le16_to_cpu(mpi_reply.IOCStatus) & 5250 MPI2_IOCSTATUS_MASK; 5251 if (ioc_status != MPI2_IOCSTATUS_SUCCESS) 5252 return -EFAULT; 5253 5254 *trigger_flags = le16_to_cpu(trigger_pg0.TriggerFlags); 5255 return 0; 5256 } 5257 5258 /** 5259 * _base_get_diag_triggers - Retrieve diag trigger values from 5260 * persistent pages. 5261 * @ioc : per adapter object 5262 * 5263 * Return: zero on success; otherwise return EAGAIN error codes 5264 * asking the caller to retry. 5265 */ 5266 static int 5267 _base_get_diag_triggers(struct MPT3SAS_ADAPTER *ioc) 5268 { 5269 int trigger_flags; 5270 int r; 5271 5272 /* 5273 * Default setting of master trigger. 5274 */ 5275 ioc->diag_trigger_master.MasterData = 5276 (MASTER_TRIGGER_FW_FAULT + MASTER_TRIGGER_ADAPTER_RESET); 5277 5278 r = _base_check_for_trigger_pages_support(ioc, &trigger_flags); 5279 if (r) { 5280 if (r == -EAGAIN) 5281 return r; 5282 /* 5283 * Don't go for error handling when FW doesn't support 5284 * driver trigger pages. 5285 */ 5286 return 0; 5287 } 5288 5289 ioc->supports_trigger_pages = 1; 5290 5291 /* 5292 * Retrieve master diag trigger values from driver trigger pg1 5293 * if master trigger bit enabled in TriggerFlags. 5294 */ 5295 if ((u16)trigger_flags & 5296 MPI26_DRIVER_TRIGGER0_FLAG_MASTER_TRIGGER_VALID) { 5297 r = _base_get_master_diag_triggers(ioc); 5298 if (r) 5299 return r; 5300 } 5301 5302 /* 5303 * Retrieve event diag trigger values from driver trigger pg2 5304 * if event trigger bit enabled in TriggerFlags. 5305 */ 5306 if ((u16)trigger_flags & 5307 MPI26_DRIVER_TRIGGER0_FLAG_MPI_EVENT_TRIGGER_VALID) { 5308 r = _base_get_event_diag_triggers(ioc); 5309 if (r) 5310 return r; 5311 } 5312 5313 /* 5314 * Retrieve scsi diag trigger values from driver trigger pg3 5315 * if scsi trigger bit enabled in TriggerFlags. 5316 */ 5317 if ((u16)trigger_flags & 5318 MPI26_DRIVER_TRIGGER0_FLAG_SCSI_SENSE_TRIGGER_VALID) { 5319 r = _base_get_scsi_diag_triggers(ioc); 5320 if (r) 5321 return r; 5322 } 5323 /* 5324 * Retrieve mpi error diag trigger values from driver trigger pg4 5325 * if loginfo trigger bit enabled in TriggerFlags. 5326 */ 5327 if ((u16)trigger_flags & 5328 MPI26_DRIVER_TRIGGER0_FLAG_LOGINFO_TRIGGER_VALID) { 5329 r = _base_get_mpi_diag_triggers(ioc); 5330 if (r) 5331 return r; 5332 } 5333 return 0; 5334 } 5335 5336 /** 5337 * _base_update_diag_trigger_pages - Update the driver trigger pages after 5338 * online FW update, in case updated FW supports driver 5339 * trigger pages. 5340 * @ioc : per adapter object 5341 * 5342 * Return: nothing. 5343 */ 5344 static void 5345 _base_update_diag_trigger_pages(struct MPT3SAS_ADAPTER *ioc) 5346 { 5347 5348 if (ioc->diag_trigger_master.MasterData) 5349 mpt3sas_config_update_driver_trigger_pg1(ioc, 5350 &ioc->diag_trigger_master, 1); 5351 5352 if (ioc->diag_trigger_event.ValidEntries) 5353 mpt3sas_config_update_driver_trigger_pg2(ioc, 5354 &ioc->diag_trigger_event, 1); 5355 5356 if (ioc->diag_trigger_scsi.ValidEntries) 5357 mpt3sas_config_update_driver_trigger_pg3(ioc, 5358 &ioc->diag_trigger_scsi, 1); 5359 5360 if (ioc->diag_trigger_mpi.ValidEntries) 5361 mpt3sas_config_update_driver_trigger_pg4(ioc, 5362 &ioc->diag_trigger_mpi, 1); 5363 } 5364 5365 /** 5366 * _base_assign_fw_reported_qd - Get FW reported QD for SAS/SATA devices. 5367 * - On failure set default QD values. 5368 * @ioc : per adapter object 5369 * 5370 * Returns 0 for success, non-zero for failure. 5371 * 5372 */ 5373 static int _base_assign_fw_reported_qd(struct MPT3SAS_ADAPTER *ioc) 5374 { 5375 Mpi2ConfigReply_t mpi_reply; 5376 Mpi2SasIOUnitPage1_t *sas_iounit_pg1 = NULL; 5377 Mpi26PCIeIOUnitPage1_t pcie_iounit_pg1; 5378 u16 depth; 5379 int sz; 5380 int rc = 0; 5381 5382 ioc->max_wideport_qd = MPT3SAS_SAS_QUEUE_DEPTH; 5383 ioc->max_narrowport_qd = MPT3SAS_SAS_QUEUE_DEPTH; 5384 ioc->max_sata_qd = MPT3SAS_SATA_QUEUE_DEPTH; 5385 ioc->max_nvme_qd = MPT3SAS_NVME_QUEUE_DEPTH; 5386 if (!ioc->is_gen35_ioc) 5387 goto out; 5388 /* sas iounit page 1 */ 5389 sz = offsetof(Mpi2SasIOUnitPage1_t, PhyData); 5390 sas_iounit_pg1 = kzalloc(sizeof(Mpi2SasIOUnitPage1_t), GFP_KERNEL); 5391 if (!sas_iounit_pg1) { 5392 pr_err("%s: failure at %s:%d/%s()!\n", 5393 ioc->name, __FILE__, __LINE__, __func__); 5394 return rc; 5395 } 5396 rc = mpt3sas_config_get_sas_iounit_pg1(ioc, &mpi_reply, 5397 sas_iounit_pg1, sz); 5398 if (rc) { 5399 pr_err("%s: failure at %s:%d/%s()!\n", 5400 ioc->name, __FILE__, __LINE__, __func__); 5401 goto out; 5402 } 5403 5404 depth = le16_to_cpu(sas_iounit_pg1->SASWideMaxQueueDepth); 5405 ioc->max_wideport_qd = (depth ? depth : MPT3SAS_SAS_QUEUE_DEPTH); 5406 5407 depth = le16_to_cpu(sas_iounit_pg1->SASNarrowMaxQueueDepth); 5408 ioc->max_narrowport_qd = (depth ? depth : MPT3SAS_SAS_QUEUE_DEPTH); 5409 5410 depth = sas_iounit_pg1->SATAMaxQDepth; 5411 ioc->max_sata_qd = (depth ? depth : MPT3SAS_SATA_QUEUE_DEPTH); 5412 5413 /* pcie iounit page 1 */ 5414 rc = mpt3sas_config_get_pcie_iounit_pg1(ioc, &mpi_reply, 5415 &pcie_iounit_pg1, sizeof(Mpi26PCIeIOUnitPage1_t)); 5416 if (rc) { 5417 pr_err("%s: failure at %s:%d/%s()!\n", 5418 ioc->name, __FILE__, __LINE__, __func__); 5419 goto out; 5420 } 5421 ioc->max_nvme_qd = (le16_to_cpu(pcie_iounit_pg1.NVMeMaxQueueDepth)) ? 5422 (le16_to_cpu(pcie_iounit_pg1.NVMeMaxQueueDepth)) : 5423 MPT3SAS_NVME_QUEUE_DEPTH; 5424 out: 5425 dinitprintk(ioc, pr_err( 5426 "MaxWidePortQD: 0x%x MaxNarrowPortQD: 0x%x MaxSataQD: 0x%x MaxNvmeQD: 0x%x\n", 5427 ioc->max_wideport_qd, ioc->max_narrowport_qd, 5428 ioc->max_sata_qd, ioc->max_nvme_qd)); 5429 kfree(sas_iounit_pg1); 5430 return rc; 5431 } 5432 5433 /** 5434 * mpt3sas_atto_validate_nvram - validate the ATTO nvram read from mfg pg1 5435 * 5436 * @ioc : per adapter object 5437 * @n : ptr to the ATTO nvram structure 5438 * Return: 0 for success, non-zero for failure. 5439 */ 5440 static int 5441 mpt3sas_atto_validate_nvram(struct MPT3SAS_ADAPTER *ioc, 5442 struct ATTO_SAS_NVRAM *n) 5443 { 5444 int r = -EINVAL; 5445 union ATTO_SAS_ADDRESS *s1; 5446 u32 len; 5447 u8 *pb; 5448 u8 ckSum; 5449 5450 /* validate nvram checksum */ 5451 pb = (u8 *) n; 5452 ckSum = ATTO_SASNVR_CKSUM_SEED; 5453 len = sizeof(struct ATTO_SAS_NVRAM); 5454 5455 while (len--) 5456 ckSum = ckSum + pb[len]; 5457 5458 if (ckSum) { 5459 ioc_err(ioc, "Invalid ATTO NVRAM checksum\n"); 5460 return r; 5461 } 5462 5463 s1 = (union ATTO_SAS_ADDRESS *) n->SasAddr; 5464 5465 if (n->Signature[0] != 'E' 5466 || n->Signature[1] != 'S' 5467 || n->Signature[2] != 'A' 5468 || n->Signature[3] != 'S') 5469 ioc_err(ioc, "Invalid ATTO NVRAM signature\n"); 5470 else if (n->Version > ATTO_SASNVR_VERSION) 5471 ioc_info(ioc, "Invalid ATTO NVRAM version"); 5472 else if ((n->SasAddr[7] & (ATTO_SAS_ADDR_ALIGN - 1)) 5473 || s1->b[0] != 0x50 5474 || s1->b[1] != 0x01 5475 || s1->b[2] != 0x08 5476 || (s1->b[3] & 0xF0) != 0x60 5477 || ((s1->b[3] & 0x0F) | le32_to_cpu(s1->d[1])) == 0) { 5478 ioc_err(ioc, "Invalid ATTO SAS address\n"); 5479 } else 5480 r = 0; 5481 return r; 5482 } 5483 5484 /** 5485 * mpt3sas_atto_get_sas_addr - get the ATTO SAS address from mfg page 1 5486 * 5487 * @ioc : per adapter object 5488 * @*sas_addr : return sas address 5489 * Return: 0 for success, non-zero for failure. 5490 */ 5491 static int 5492 mpt3sas_atto_get_sas_addr(struct MPT3SAS_ADAPTER *ioc, union ATTO_SAS_ADDRESS *sas_addr) 5493 { 5494 Mpi2ManufacturingPage1_t mfg_pg1; 5495 Mpi2ConfigReply_t mpi_reply; 5496 struct ATTO_SAS_NVRAM *nvram; 5497 int r; 5498 __be64 addr; 5499 5500 r = mpt3sas_config_get_manufacturing_pg1(ioc, &mpi_reply, &mfg_pg1); 5501 if (r) { 5502 ioc_err(ioc, "Failed to read manufacturing page 1\n"); 5503 return r; 5504 } 5505 5506 /* validate nvram */ 5507 nvram = (struct ATTO_SAS_NVRAM *) mfg_pg1.VPD; 5508 r = mpt3sas_atto_validate_nvram(ioc, nvram); 5509 if (r) 5510 return r; 5511 5512 addr = *((__be64 *) nvram->SasAddr); 5513 sas_addr->q = cpu_to_le64(be64_to_cpu(addr)); 5514 return r; 5515 } 5516 5517 /** 5518 * mpt3sas_atto_init - perform initializaion for ATTO branded 5519 * adapter. 5520 * @ioc : per adapter object 5521 *5 5522 * Return: 0 for success, non-zero for failure. 5523 */ 5524 static int 5525 mpt3sas_atto_init(struct MPT3SAS_ADAPTER *ioc) 5526 { 5527 int sz = 0; 5528 Mpi2BiosPage4_t *bios_pg4 = NULL; 5529 Mpi2ConfigReply_t mpi_reply; 5530 int r; 5531 int ix; 5532 union ATTO_SAS_ADDRESS sas_addr; 5533 union ATTO_SAS_ADDRESS temp; 5534 union ATTO_SAS_ADDRESS bias; 5535 5536 r = mpt3sas_atto_get_sas_addr(ioc, &sas_addr); 5537 if (r) 5538 return r; 5539 5540 /* get header first to get size */ 5541 r = mpt3sas_config_get_bios_pg4(ioc, &mpi_reply, NULL, 0); 5542 if (r) { 5543 ioc_err(ioc, "Failed to read ATTO bios page 4 header.\n"); 5544 return r; 5545 } 5546 5547 sz = mpi_reply.Header.PageLength * sizeof(u32); 5548 bios_pg4 = kzalloc(sz, GFP_KERNEL); 5549 if (!bios_pg4) { 5550 ioc_err(ioc, "Failed to allocate memory for ATTO bios page.\n"); 5551 return -ENOMEM; 5552 } 5553 5554 /* read bios page 4 */ 5555 r = mpt3sas_config_get_bios_pg4(ioc, &mpi_reply, bios_pg4, sz); 5556 if (r) { 5557 ioc_err(ioc, "Failed to read ATTO bios page 4\n"); 5558 goto out; 5559 } 5560 5561 /* Update bios page 4 with the ATTO WWID */ 5562 bias.q = sas_addr.q; 5563 bias.b[7] += ATTO_SAS_ADDR_DEVNAME_BIAS; 5564 5565 for (ix = 0; ix < bios_pg4->NumPhys; ix++) { 5566 temp.q = sas_addr.q; 5567 temp.b[7] += ix; 5568 bios_pg4->Phy[ix].ReassignmentWWID = temp.q; 5569 bios_pg4->Phy[ix].ReassignmentDeviceName = bias.q; 5570 } 5571 r = mpt3sas_config_set_bios_pg4(ioc, &mpi_reply, bios_pg4, sz); 5572 5573 out: 5574 kfree(bios_pg4); 5575 return r; 5576 } 5577 5578 /** 5579 * _base_static_config_pages - static start of day config pages 5580 * @ioc: per adapter object 5581 */ 5582 static int 5583 _base_static_config_pages(struct MPT3SAS_ADAPTER *ioc) 5584 { 5585 Mpi2ConfigReply_t mpi_reply; 5586 u32 iounit_pg1_flags; 5587 int tg_flags = 0; 5588 int rc; 5589 ioc->nvme_abort_timeout = 30; 5590 5591 rc = mpt3sas_config_get_manufacturing_pg0(ioc, &mpi_reply, 5592 &ioc->manu_pg0); 5593 if (rc) 5594 return rc; 5595 if (ioc->ir_firmware) { 5596 rc = mpt3sas_config_get_manufacturing_pg10(ioc, &mpi_reply, 5597 &ioc->manu_pg10); 5598 if (rc) 5599 return rc; 5600 } 5601 5602 if (ioc->pdev->vendor == MPI2_MFGPAGE_VENDORID_ATTO) { 5603 rc = mpt3sas_atto_init(ioc); 5604 if (rc) 5605 return rc; 5606 } 5607 5608 /* 5609 * Ensure correct T10 PI operation if vendor left EEDPTagMode 5610 * flag unset in NVDATA. 5611 */ 5612 rc = mpt3sas_config_get_manufacturing_pg11(ioc, &mpi_reply, 5613 &ioc->manu_pg11); 5614 if (rc) 5615 return rc; 5616 if (!ioc->is_gen35_ioc && ioc->manu_pg11.EEDPTagMode == 0) { 5617 pr_err("%s: overriding NVDATA EEDPTagMode setting\n", 5618 ioc->name); 5619 ioc->manu_pg11.EEDPTagMode &= ~0x3; 5620 ioc->manu_pg11.EEDPTagMode |= 0x1; 5621 mpt3sas_config_set_manufacturing_pg11(ioc, &mpi_reply, 5622 &ioc->manu_pg11); 5623 } 5624 if (ioc->manu_pg11.AddlFlags2 & NVME_TASK_MNGT_CUSTOM_MASK) 5625 ioc->tm_custom_handling = 1; 5626 else { 5627 ioc->tm_custom_handling = 0; 5628 if (ioc->manu_pg11.NVMeAbortTO < NVME_TASK_ABORT_MIN_TIMEOUT) 5629 ioc->nvme_abort_timeout = NVME_TASK_ABORT_MIN_TIMEOUT; 5630 else if (ioc->manu_pg11.NVMeAbortTO > 5631 NVME_TASK_ABORT_MAX_TIMEOUT) 5632 ioc->nvme_abort_timeout = NVME_TASK_ABORT_MAX_TIMEOUT; 5633 else 5634 ioc->nvme_abort_timeout = ioc->manu_pg11.NVMeAbortTO; 5635 } 5636 ioc->time_sync_interval = 5637 ioc->manu_pg11.TimeSyncInterval & MPT3SAS_TIMESYNC_MASK; 5638 if (ioc->time_sync_interval) { 5639 if (ioc->manu_pg11.TimeSyncInterval & MPT3SAS_TIMESYNC_UNIT_MASK) 5640 ioc->time_sync_interval = 5641 ioc->time_sync_interval * SECONDS_PER_HOUR; 5642 else 5643 ioc->time_sync_interval = 5644 ioc->time_sync_interval * SECONDS_PER_MIN; 5645 dinitprintk(ioc, ioc_info(ioc, 5646 "Driver-FW TimeSync interval is %d seconds. ManuPg11 TimeSync Unit is in %s\n", 5647 ioc->time_sync_interval, (ioc->manu_pg11.TimeSyncInterval & 5648 MPT3SAS_TIMESYNC_UNIT_MASK) ? "Hour" : "Minute")); 5649 } else { 5650 if (ioc->is_gen35_ioc) 5651 ioc_warn(ioc, 5652 "TimeSync Interval in Manuf page-11 is not enabled. Periodic Time-Sync will be disabled\n"); 5653 } 5654 rc = _base_assign_fw_reported_qd(ioc); 5655 if (rc) 5656 return rc; 5657 5658 /* 5659 * ATTO doesn't use bios page 2 and 3 for bios settings. 5660 */ 5661 if (ioc->pdev->vendor == MPI2_MFGPAGE_VENDORID_ATTO) 5662 ioc->bios_pg3.BiosVersion = 0; 5663 else { 5664 rc = mpt3sas_config_get_bios_pg2(ioc, &mpi_reply, &ioc->bios_pg2); 5665 if (rc) 5666 return rc; 5667 rc = mpt3sas_config_get_bios_pg3(ioc, &mpi_reply, &ioc->bios_pg3); 5668 if (rc) 5669 return rc; 5670 } 5671 5672 rc = mpt3sas_config_get_ioc_pg8(ioc, &mpi_reply, &ioc->ioc_pg8); 5673 if (rc) 5674 return rc; 5675 rc = mpt3sas_config_get_iounit_pg0(ioc, &mpi_reply, &ioc->iounit_pg0); 5676 if (rc) 5677 return rc; 5678 rc = mpt3sas_config_get_iounit_pg1(ioc, &mpi_reply, &ioc->iounit_pg1); 5679 if (rc) 5680 return rc; 5681 rc = mpt3sas_config_get_iounit_pg8(ioc, &mpi_reply, &ioc->iounit_pg8); 5682 if (rc) 5683 return rc; 5684 _base_display_ioc_capabilities(ioc); 5685 5686 /* 5687 * Enable task_set_full handling in iounit_pg1 when the 5688 * facts capabilities indicate that its supported. 5689 */ 5690 iounit_pg1_flags = le32_to_cpu(ioc->iounit_pg1.Flags); 5691 if ((ioc->facts.IOCCapabilities & 5692 MPI2_IOCFACTS_CAPABILITY_TASK_SET_FULL_HANDLING)) 5693 iounit_pg1_flags &= 5694 ~MPI2_IOUNITPAGE1_DISABLE_TASK_SET_FULL_HANDLING; 5695 else 5696 iounit_pg1_flags |= 5697 MPI2_IOUNITPAGE1_DISABLE_TASK_SET_FULL_HANDLING; 5698 ioc->iounit_pg1.Flags = cpu_to_le32(iounit_pg1_flags); 5699 rc = mpt3sas_config_set_iounit_pg1(ioc, &mpi_reply, &ioc->iounit_pg1); 5700 if (rc) 5701 return rc; 5702 5703 if (ioc->iounit_pg8.NumSensors) 5704 ioc->temp_sensors_count = ioc->iounit_pg8.NumSensors; 5705 if (ioc->is_aero_ioc) { 5706 rc = _base_update_ioc_page1_inlinewith_perf_mode(ioc); 5707 if (rc) 5708 return rc; 5709 } 5710 if (ioc->is_gen35_ioc) { 5711 if (ioc->is_driver_loading) { 5712 rc = _base_get_diag_triggers(ioc); 5713 if (rc) 5714 return rc; 5715 } else { 5716 /* 5717 * In case of online HBA FW update operation, 5718 * check whether updated FW supports the driver trigger 5719 * pages or not. 5720 * - If previous FW has not supported driver trigger 5721 * pages and newer FW supports them then update these 5722 * pages with current diag trigger values. 5723 * - If previous FW has supported driver trigger pages 5724 * and new FW doesn't support them then disable 5725 * support_trigger_pages flag. 5726 */ 5727 _base_check_for_trigger_pages_support(ioc, &tg_flags); 5728 if (!ioc->supports_trigger_pages && tg_flags != -EFAULT) 5729 _base_update_diag_trigger_pages(ioc); 5730 else if (ioc->supports_trigger_pages && 5731 tg_flags == -EFAULT) 5732 ioc->supports_trigger_pages = 0; 5733 } 5734 } 5735 return 0; 5736 } 5737 5738 /** 5739 * mpt3sas_free_enclosure_list - release memory 5740 * @ioc: per adapter object 5741 * 5742 * Free memory allocated during enclosure add. 5743 */ 5744 void 5745 mpt3sas_free_enclosure_list(struct MPT3SAS_ADAPTER *ioc) 5746 { 5747 struct _enclosure_node *enclosure_dev, *enclosure_dev_next; 5748 5749 /* Free enclosure list */ 5750 list_for_each_entry_safe(enclosure_dev, 5751 enclosure_dev_next, &ioc->enclosure_list, list) { 5752 list_del(&enclosure_dev->list); 5753 kfree(enclosure_dev); 5754 } 5755 } 5756 5757 /** 5758 * _base_release_memory_pools - release memory 5759 * @ioc: per adapter object 5760 * 5761 * Free memory allocated from _base_allocate_memory_pools. 5762 */ 5763 static void 5764 _base_release_memory_pools(struct MPT3SAS_ADAPTER *ioc) 5765 { 5766 int i = 0; 5767 int j = 0; 5768 int dma_alloc_count = 0; 5769 struct chain_tracker *ct; 5770 int count = ioc->rdpq_array_enable ? ioc->reply_queue_count : 1; 5771 5772 dexitprintk(ioc, ioc_info(ioc, "%s\n", __func__)); 5773 5774 if (ioc->request) { 5775 dma_free_coherent(&ioc->pdev->dev, ioc->request_dma_sz, 5776 ioc->request, ioc->request_dma); 5777 dexitprintk(ioc, 5778 ioc_info(ioc, "request_pool(0x%p): free\n", 5779 ioc->request)); 5780 ioc->request = NULL; 5781 } 5782 5783 if (ioc->sense) { 5784 dma_pool_free(ioc->sense_dma_pool, ioc->sense, ioc->sense_dma); 5785 dma_pool_destroy(ioc->sense_dma_pool); 5786 dexitprintk(ioc, 5787 ioc_info(ioc, "sense_pool(0x%p): free\n", 5788 ioc->sense)); 5789 ioc->sense = NULL; 5790 } 5791 5792 if (ioc->reply) { 5793 dma_pool_free(ioc->reply_dma_pool, ioc->reply, ioc->reply_dma); 5794 dma_pool_destroy(ioc->reply_dma_pool); 5795 dexitprintk(ioc, 5796 ioc_info(ioc, "reply_pool(0x%p): free\n", 5797 ioc->reply)); 5798 ioc->reply = NULL; 5799 } 5800 5801 if (ioc->reply_free) { 5802 dma_pool_free(ioc->reply_free_dma_pool, ioc->reply_free, 5803 ioc->reply_free_dma); 5804 dma_pool_destroy(ioc->reply_free_dma_pool); 5805 dexitprintk(ioc, 5806 ioc_info(ioc, "reply_free_pool(0x%p): free\n", 5807 ioc->reply_free)); 5808 ioc->reply_free = NULL; 5809 } 5810 5811 if (ioc->reply_post) { 5812 dma_alloc_count = DIV_ROUND_UP(count, 5813 RDPQ_MAX_INDEX_IN_ONE_CHUNK); 5814 for (i = 0; i < count; i++) { 5815 if (i % RDPQ_MAX_INDEX_IN_ONE_CHUNK == 0 5816 && dma_alloc_count) { 5817 if (ioc->reply_post[i].reply_post_free) { 5818 dma_pool_free( 5819 ioc->reply_post_free_dma_pool, 5820 ioc->reply_post[i].reply_post_free, 5821 ioc->reply_post[i].reply_post_free_dma); 5822 dexitprintk(ioc, ioc_info(ioc, 5823 "reply_post_free_pool(0x%p): free\n", 5824 ioc->reply_post[i].reply_post_free)); 5825 ioc->reply_post[i].reply_post_free = 5826 NULL; 5827 } 5828 --dma_alloc_count; 5829 } 5830 } 5831 dma_pool_destroy(ioc->reply_post_free_dma_pool); 5832 if (ioc->reply_post_free_array && 5833 ioc->rdpq_array_enable) { 5834 dma_pool_free(ioc->reply_post_free_array_dma_pool, 5835 ioc->reply_post_free_array, 5836 ioc->reply_post_free_array_dma); 5837 ioc->reply_post_free_array = NULL; 5838 } 5839 dma_pool_destroy(ioc->reply_post_free_array_dma_pool); 5840 kfree(ioc->reply_post); 5841 } 5842 5843 if (ioc->pcie_sgl_dma_pool) { 5844 for (i = 0; i < ioc->scsiio_depth; i++) { 5845 dma_pool_free(ioc->pcie_sgl_dma_pool, 5846 ioc->pcie_sg_lookup[i].pcie_sgl, 5847 ioc->pcie_sg_lookup[i].pcie_sgl_dma); 5848 ioc->pcie_sg_lookup[i].pcie_sgl = NULL; 5849 } 5850 dma_pool_destroy(ioc->pcie_sgl_dma_pool); 5851 } 5852 kfree(ioc->pcie_sg_lookup); 5853 ioc->pcie_sg_lookup = NULL; 5854 5855 if (ioc->config_page) { 5856 dexitprintk(ioc, 5857 ioc_info(ioc, "config_page(0x%p): free\n", 5858 ioc->config_page)); 5859 dma_free_coherent(&ioc->pdev->dev, ioc->config_page_sz, 5860 ioc->config_page, ioc->config_page_dma); 5861 } 5862 5863 kfree(ioc->hpr_lookup); 5864 ioc->hpr_lookup = NULL; 5865 kfree(ioc->internal_lookup); 5866 ioc->internal_lookup = NULL; 5867 if (ioc->chain_lookup) { 5868 for (i = 0; i < ioc->scsiio_depth; i++) { 5869 for (j = ioc->chains_per_prp_buffer; 5870 j < ioc->chains_needed_per_io; j++) { 5871 ct = &ioc->chain_lookup[i].chains_per_smid[j]; 5872 if (ct && ct->chain_buffer) 5873 dma_pool_free(ioc->chain_dma_pool, 5874 ct->chain_buffer, 5875 ct->chain_buffer_dma); 5876 } 5877 kfree(ioc->chain_lookup[i].chains_per_smid); 5878 } 5879 dma_pool_destroy(ioc->chain_dma_pool); 5880 kfree(ioc->chain_lookup); 5881 ioc->chain_lookup = NULL; 5882 } 5883 5884 kfree(ioc->io_queue_num); 5885 ioc->io_queue_num = NULL; 5886 } 5887 5888 /** 5889 * mpt3sas_check_same_4gb_region - checks whether all reply queues in a set are 5890 * having same upper 32bits in their base memory address. 5891 * @start_address: Base address of a reply queue set 5892 * @pool_sz: Size of single Reply Descriptor Post Queues pool size 5893 * 5894 * Return: 1 if reply queues in a set have a same upper 32bits in their base 5895 * memory address, else 0. 5896 */ 5897 static int 5898 mpt3sas_check_same_4gb_region(dma_addr_t start_address, u32 pool_sz) 5899 { 5900 dma_addr_t end_address; 5901 5902 end_address = start_address + pool_sz - 1; 5903 5904 if (upper_32_bits(start_address) == upper_32_bits(end_address)) 5905 return 1; 5906 else 5907 return 0; 5908 } 5909 5910 /** 5911 * _base_reduce_hba_queue_depth- Retry with reduced queue depth 5912 * @ioc: Adapter object 5913 * 5914 * Return: 0 for success, non-zero for failure. 5915 **/ 5916 static inline int 5917 _base_reduce_hba_queue_depth(struct MPT3SAS_ADAPTER *ioc) 5918 { 5919 int reduce_sz = 64; 5920 5921 if ((ioc->hba_queue_depth - reduce_sz) > 5922 (ioc->internal_depth + INTERNAL_SCSIIO_CMDS_COUNT)) { 5923 ioc->hba_queue_depth -= reduce_sz; 5924 return 0; 5925 } else 5926 return -ENOMEM; 5927 } 5928 5929 /** 5930 * _base_allocate_pcie_sgl_pool - Allocating DMA'able memory 5931 * for pcie sgl pools. 5932 * @ioc: Adapter object 5933 * @sz: DMA Pool size 5934 * 5935 * Return: 0 for success, non-zero for failure. 5936 */ 5937 5938 static int 5939 _base_allocate_pcie_sgl_pool(struct MPT3SAS_ADAPTER *ioc, u32 sz) 5940 { 5941 int i = 0, j = 0; 5942 struct chain_tracker *ct; 5943 5944 ioc->pcie_sgl_dma_pool = 5945 dma_pool_create("PCIe SGL pool", &ioc->pdev->dev, sz, 5946 ioc->page_size, 0); 5947 if (!ioc->pcie_sgl_dma_pool) { 5948 ioc_err(ioc, "PCIe SGL pool: dma_pool_create failed\n"); 5949 return -ENOMEM; 5950 } 5951 5952 ioc->chains_per_prp_buffer = sz/ioc->chain_segment_sz; 5953 ioc->chains_per_prp_buffer = 5954 min(ioc->chains_per_prp_buffer, ioc->chains_needed_per_io); 5955 for (i = 0; i < ioc->scsiio_depth; i++) { 5956 ioc->pcie_sg_lookup[i].pcie_sgl = 5957 dma_pool_alloc(ioc->pcie_sgl_dma_pool, GFP_KERNEL, 5958 &ioc->pcie_sg_lookup[i].pcie_sgl_dma); 5959 if (!ioc->pcie_sg_lookup[i].pcie_sgl) { 5960 ioc_err(ioc, "PCIe SGL pool: dma_pool_alloc failed\n"); 5961 return -EAGAIN; 5962 } 5963 5964 if (!mpt3sas_check_same_4gb_region( 5965 ioc->pcie_sg_lookup[i].pcie_sgl_dma, sz)) { 5966 ioc_err(ioc, "PCIE SGLs are not in same 4G !! pcie sgl (0x%p) dma = (0x%llx)\n", 5967 ioc->pcie_sg_lookup[i].pcie_sgl, 5968 (unsigned long long) 5969 ioc->pcie_sg_lookup[i].pcie_sgl_dma); 5970 ioc->use_32bit_dma = true; 5971 return -EAGAIN; 5972 } 5973 5974 for (j = 0; j < ioc->chains_per_prp_buffer; j++) { 5975 ct = &ioc->chain_lookup[i].chains_per_smid[j]; 5976 ct->chain_buffer = 5977 ioc->pcie_sg_lookup[i].pcie_sgl + 5978 (j * ioc->chain_segment_sz); 5979 ct->chain_buffer_dma = 5980 ioc->pcie_sg_lookup[i].pcie_sgl_dma + 5981 (j * ioc->chain_segment_sz); 5982 } 5983 } 5984 dinitprintk(ioc, ioc_info(ioc, 5985 "PCIe sgl pool depth(%d), element_size(%d), pool_size(%d kB)\n", 5986 ioc->scsiio_depth, sz, (sz * ioc->scsiio_depth)/1024)); 5987 dinitprintk(ioc, ioc_info(ioc, 5988 "Number of chains can fit in a PRP page(%d)\n", 5989 ioc->chains_per_prp_buffer)); 5990 return 0; 5991 } 5992 5993 /** 5994 * _base_allocate_chain_dma_pool - Allocating DMA'able memory 5995 * for chain dma pool. 5996 * @ioc: Adapter object 5997 * @sz: DMA Pool size 5998 * 5999 * Return: 0 for success, non-zero for failure. 6000 */ 6001 static int 6002 _base_allocate_chain_dma_pool(struct MPT3SAS_ADAPTER *ioc, u32 sz) 6003 { 6004 int i = 0, j = 0; 6005 struct chain_tracker *ctr; 6006 6007 ioc->chain_dma_pool = dma_pool_create("chain pool", &ioc->pdev->dev, 6008 ioc->chain_segment_sz, 16, 0); 6009 if (!ioc->chain_dma_pool) 6010 return -ENOMEM; 6011 6012 for (i = 0; i < ioc->scsiio_depth; i++) { 6013 for (j = ioc->chains_per_prp_buffer; 6014 j < ioc->chains_needed_per_io; j++) { 6015 ctr = &ioc->chain_lookup[i].chains_per_smid[j]; 6016 ctr->chain_buffer = dma_pool_alloc(ioc->chain_dma_pool, 6017 GFP_KERNEL, &ctr->chain_buffer_dma); 6018 if (!ctr->chain_buffer) 6019 return -EAGAIN; 6020 if (!mpt3sas_check_same_4gb_region( 6021 ctr->chain_buffer_dma, ioc->chain_segment_sz)) { 6022 ioc_err(ioc, 6023 "Chain buffers are not in same 4G !!! Chain buff (0x%p) dma = (0x%llx)\n", 6024 ctr->chain_buffer, 6025 (unsigned long long)ctr->chain_buffer_dma); 6026 ioc->use_32bit_dma = true; 6027 return -EAGAIN; 6028 } 6029 } 6030 } 6031 dinitprintk(ioc, ioc_info(ioc, 6032 "chain_lookup depth (%d), frame_size(%d), pool_size(%d kB)\n", 6033 ioc->scsiio_depth, ioc->chain_segment_sz, ((ioc->scsiio_depth * 6034 (ioc->chains_needed_per_io - ioc->chains_per_prp_buffer) * 6035 ioc->chain_segment_sz))/1024)); 6036 return 0; 6037 } 6038 6039 /** 6040 * _base_allocate_sense_dma_pool - Allocating DMA'able memory 6041 * for sense dma pool. 6042 * @ioc: Adapter object 6043 * @sz: DMA Pool size 6044 * Return: 0 for success, non-zero for failure. 6045 */ 6046 static int 6047 _base_allocate_sense_dma_pool(struct MPT3SAS_ADAPTER *ioc, u32 sz) 6048 { 6049 ioc->sense_dma_pool = 6050 dma_pool_create("sense pool", &ioc->pdev->dev, sz, 4, 0); 6051 if (!ioc->sense_dma_pool) 6052 return -ENOMEM; 6053 ioc->sense = dma_pool_alloc(ioc->sense_dma_pool, 6054 GFP_KERNEL, &ioc->sense_dma); 6055 if (!ioc->sense) 6056 return -EAGAIN; 6057 if (!mpt3sas_check_same_4gb_region(ioc->sense_dma, sz)) { 6058 dinitprintk(ioc, pr_err( 6059 "Bad Sense Pool! sense (0x%p) sense_dma = (0x%llx)\n", 6060 ioc->sense, (unsigned long long) ioc->sense_dma)); 6061 ioc->use_32bit_dma = true; 6062 return -EAGAIN; 6063 } 6064 ioc_info(ioc, 6065 "sense pool(0x%p) - dma(0x%llx): depth(%d), element_size(%d), pool_size (%d kB)\n", 6066 ioc->sense, (unsigned long long)ioc->sense_dma, 6067 ioc->scsiio_depth, SCSI_SENSE_BUFFERSIZE, sz/1024); 6068 return 0; 6069 } 6070 6071 /** 6072 * _base_allocate_reply_pool - Allocating DMA'able memory 6073 * for reply pool. 6074 * @ioc: Adapter object 6075 * @sz: DMA Pool size 6076 * Return: 0 for success, non-zero for failure. 6077 */ 6078 static int 6079 _base_allocate_reply_pool(struct MPT3SAS_ADAPTER *ioc, u32 sz) 6080 { 6081 /* reply pool, 4 byte align */ 6082 ioc->reply_dma_pool = dma_pool_create("reply pool", 6083 &ioc->pdev->dev, sz, 4, 0); 6084 if (!ioc->reply_dma_pool) 6085 return -ENOMEM; 6086 ioc->reply = dma_pool_alloc(ioc->reply_dma_pool, GFP_KERNEL, 6087 &ioc->reply_dma); 6088 if (!ioc->reply) 6089 return -EAGAIN; 6090 if (!mpt3sas_check_same_4gb_region(ioc->reply_dma, sz)) { 6091 dinitprintk(ioc, pr_err( 6092 "Bad Reply Pool! Reply (0x%p) Reply dma = (0x%llx)\n", 6093 ioc->reply, (unsigned long long) ioc->reply_dma)); 6094 ioc->use_32bit_dma = true; 6095 return -EAGAIN; 6096 } 6097 ioc->reply_dma_min_address = (u32)(ioc->reply_dma); 6098 ioc->reply_dma_max_address = (u32)(ioc->reply_dma) + sz; 6099 ioc_info(ioc, 6100 "reply pool(0x%p) - dma(0x%llx): depth(%d), frame_size(%d), pool_size(%d kB)\n", 6101 ioc->reply, (unsigned long long)ioc->reply_dma, 6102 ioc->reply_free_queue_depth, ioc->reply_sz, sz/1024); 6103 return 0; 6104 } 6105 6106 /** 6107 * _base_allocate_reply_free_dma_pool - Allocating DMA'able memory 6108 * for reply free dma pool. 6109 * @ioc: Adapter object 6110 * @sz: DMA Pool size 6111 * Return: 0 for success, non-zero for failure. 6112 */ 6113 static int 6114 _base_allocate_reply_free_dma_pool(struct MPT3SAS_ADAPTER *ioc, u32 sz) 6115 { 6116 /* reply free queue, 16 byte align */ 6117 ioc->reply_free_dma_pool = dma_pool_create( 6118 "reply_free pool", &ioc->pdev->dev, sz, 16, 0); 6119 if (!ioc->reply_free_dma_pool) 6120 return -ENOMEM; 6121 ioc->reply_free = dma_pool_alloc(ioc->reply_free_dma_pool, 6122 GFP_KERNEL, &ioc->reply_free_dma); 6123 if (!ioc->reply_free) 6124 return -EAGAIN; 6125 if (!mpt3sas_check_same_4gb_region(ioc->reply_free_dma, sz)) { 6126 dinitprintk(ioc, 6127 pr_err("Bad Reply Free Pool! Reply Free (0x%p) Reply Free dma = (0x%llx)\n", 6128 ioc->reply_free, (unsigned long long) ioc->reply_free_dma)); 6129 ioc->use_32bit_dma = true; 6130 return -EAGAIN; 6131 } 6132 memset(ioc->reply_free, 0, sz); 6133 dinitprintk(ioc, ioc_info(ioc, 6134 "reply_free pool(0x%p): depth(%d), element_size(%d), pool_size(%d kB)\n", 6135 ioc->reply_free, ioc->reply_free_queue_depth, 4, sz/1024)); 6136 dinitprintk(ioc, ioc_info(ioc, 6137 "reply_free_dma (0x%llx)\n", 6138 (unsigned long long)ioc->reply_free_dma)); 6139 return 0; 6140 } 6141 6142 /** 6143 * _base_allocate_reply_post_free_array - Allocating DMA'able memory 6144 * for reply post free array. 6145 * @ioc: Adapter object 6146 * @reply_post_free_array_sz: DMA Pool size 6147 * Return: 0 for success, non-zero for failure. 6148 */ 6149 6150 static int 6151 _base_allocate_reply_post_free_array(struct MPT3SAS_ADAPTER *ioc, 6152 u32 reply_post_free_array_sz) 6153 { 6154 ioc->reply_post_free_array_dma_pool = 6155 dma_pool_create("reply_post_free_array pool", 6156 &ioc->pdev->dev, reply_post_free_array_sz, 16, 0); 6157 if (!ioc->reply_post_free_array_dma_pool) 6158 return -ENOMEM; 6159 ioc->reply_post_free_array = 6160 dma_pool_alloc(ioc->reply_post_free_array_dma_pool, 6161 GFP_KERNEL, &ioc->reply_post_free_array_dma); 6162 if (!ioc->reply_post_free_array) 6163 return -EAGAIN; 6164 if (!mpt3sas_check_same_4gb_region(ioc->reply_post_free_array_dma, 6165 reply_post_free_array_sz)) { 6166 dinitprintk(ioc, pr_err( 6167 "Bad Reply Free Pool! Reply Free (0x%p) Reply Free dma = (0x%llx)\n", 6168 ioc->reply_free, 6169 (unsigned long long) ioc->reply_free_dma)); 6170 ioc->use_32bit_dma = true; 6171 return -EAGAIN; 6172 } 6173 return 0; 6174 } 6175 /** 6176 * base_alloc_rdpq_dma_pool - Allocating DMA'able memory 6177 * for reply queues. 6178 * @ioc: per adapter object 6179 * @sz: DMA Pool size 6180 * Return: 0 for success, non-zero for failure. 6181 */ 6182 static int 6183 base_alloc_rdpq_dma_pool(struct MPT3SAS_ADAPTER *ioc, int sz) 6184 { 6185 int i = 0; 6186 u32 dma_alloc_count = 0; 6187 int reply_post_free_sz = ioc->reply_post_queue_depth * 6188 sizeof(Mpi2DefaultReplyDescriptor_t); 6189 int count = ioc->rdpq_array_enable ? ioc->reply_queue_count : 1; 6190 6191 ioc->reply_post = kcalloc(count, sizeof(struct reply_post_struct), 6192 GFP_KERNEL); 6193 if (!ioc->reply_post) 6194 return -ENOMEM; 6195 /* 6196 * For INVADER_SERIES each set of 8 reply queues(0-7, 8-15, ..) and 6197 * VENTURA_SERIES each set of 16 reply queues(0-15, 16-31, ..) should 6198 * be within 4GB boundary i.e reply queues in a set must have same 6199 * upper 32-bits in their memory address. so here driver is allocating 6200 * the DMA'able memory for reply queues according. 6201 * Driver uses limitation of 6202 * VENTURA_SERIES to manage INVADER_SERIES as well. 6203 */ 6204 dma_alloc_count = DIV_ROUND_UP(count, 6205 RDPQ_MAX_INDEX_IN_ONE_CHUNK); 6206 ioc->reply_post_free_dma_pool = 6207 dma_pool_create("reply_post_free pool", 6208 &ioc->pdev->dev, sz, 16, 0); 6209 if (!ioc->reply_post_free_dma_pool) 6210 return -ENOMEM; 6211 for (i = 0; i < count; i++) { 6212 if ((i % RDPQ_MAX_INDEX_IN_ONE_CHUNK == 0) && dma_alloc_count) { 6213 ioc->reply_post[i].reply_post_free = 6214 dma_pool_zalloc(ioc->reply_post_free_dma_pool, 6215 GFP_KERNEL, 6216 &ioc->reply_post[i].reply_post_free_dma); 6217 if (!ioc->reply_post[i].reply_post_free) 6218 return -ENOMEM; 6219 /* 6220 * Each set of RDPQ pool must satisfy 4gb boundary 6221 * restriction. 6222 * 1) Check if allocated resources for RDPQ pool are in 6223 * the same 4GB range. 6224 * 2) If #1 is true, continue with 64 bit DMA. 6225 * 3) If #1 is false, return 1. which means free all the 6226 * resources and set DMA mask to 32 and allocate. 6227 */ 6228 if (!mpt3sas_check_same_4gb_region( 6229 ioc->reply_post[i].reply_post_free_dma, sz)) { 6230 dinitprintk(ioc, 6231 ioc_err(ioc, "bad Replypost free pool(0x%p)" 6232 "reply_post_free_dma = (0x%llx)\n", 6233 ioc->reply_post[i].reply_post_free, 6234 (unsigned long long) 6235 ioc->reply_post[i].reply_post_free_dma)); 6236 return -EAGAIN; 6237 } 6238 dma_alloc_count--; 6239 6240 } else { 6241 ioc->reply_post[i].reply_post_free = 6242 (Mpi2ReplyDescriptorsUnion_t *) 6243 ((long)ioc->reply_post[i-1].reply_post_free 6244 + reply_post_free_sz); 6245 ioc->reply_post[i].reply_post_free_dma = 6246 (dma_addr_t) 6247 (ioc->reply_post[i-1].reply_post_free_dma + 6248 reply_post_free_sz); 6249 } 6250 } 6251 return 0; 6252 } 6253 6254 /** 6255 * _base_allocate_memory_pools - allocate start of day memory pools 6256 * @ioc: per adapter object 6257 * 6258 * Return: 0 success, anything else error. 6259 */ 6260 static int 6261 _base_allocate_memory_pools(struct MPT3SAS_ADAPTER *ioc) 6262 { 6263 struct mpt3sas_facts *facts; 6264 u16 max_sge_elements; 6265 u16 chains_needed_per_io; 6266 u32 sz, total_sz, reply_post_free_sz, reply_post_free_array_sz; 6267 u32 retry_sz; 6268 u32 rdpq_sz = 0, sense_sz = 0; 6269 u16 max_request_credit, nvme_blocks_needed; 6270 unsigned short sg_tablesize; 6271 u16 sge_size; 6272 int i; 6273 int ret = 0, rc = 0; 6274 6275 dinitprintk(ioc, ioc_info(ioc, "%s\n", __func__)); 6276 6277 6278 retry_sz = 0; 6279 facts = &ioc->facts; 6280 6281 /* command line tunables for max sgl entries */ 6282 if (max_sgl_entries != -1) 6283 sg_tablesize = max_sgl_entries; 6284 else { 6285 if (ioc->hba_mpi_version_belonged == MPI2_VERSION) 6286 sg_tablesize = MPT2SAS_SG_DEPTH; 6287 else 6288 sg_tablesize = MPT3SAS_SG_DEPTH; 6289 } 6290 6291 /* max sgl entries <= MPT_KDUMP_MIN_PHYS_SEGMENTS in KDUMP mode */ 6292 if (reset_devices) 6293 sg_tablesize = min_t(unsigned short, sg_tablesize, 6294 MPT_KDUMP_MIN_PHYS_SEGMENTS); 6295 6296 if (ioc->is_mcpu_endpoint) 6297 ioc->shost->sg_tablesize = MPT_MIN_PHYS_SEGMENTS; 6298 else { 6299 if (sg_tablesize < MPT_MIN_PHYS_SEGMENTS) 6300 sg_tablesize = MPT_MIN_PHYS_SEGMENTS; 6301 else if (sg_tablesize > MPT_MAX_PHYS_SEGMENTS) { 6302 sg_tablesize = min_t(unsigned short, sg_tablesize, 6303 SG_MAX_SEGMENTS); 6304 ioc_warn(ioc, "sg_tablesize(%u) is bigger than kernel defined SG_CHUNK_SIZE(%u)\n", 6305 sg_tablesize, MPT_MAX_PHYS_SEGMENTS); 6306 } 6307 ioc->shost->sg_tablesize = sg_tablesize; 6308 } 6309 6310 ioc->internal_depth = min_t(int, (facts->HighPriorityCredit + (5)), 6311 (facts->RequestCredit / 4)); 6312 if (ioc->internal_depth < INTERNAL_CMDS_COUNT) { 6313 if (facts->RequestCredit <= (INTERNAL_CMDS_COUNT + 6314 INTERNAL_SCSIIO_CMDS_COUNT)) { 6315 ioc_err(ioc, "IOC doesn't have enough Request Credits, it has just %d number of credits\n", 6316 facts->RequestCredit); 6317 return -ENOMEM; 6318 } 6319 ioc->internal_depth = 10; 6320 } 6321 6322 ioc->hi_priority_depth = ioc->internal_depth - (5); 6323 /* command line tunables for max controller queue depth */ 6324 if (max_queue_depth != -1 && max_queue_depth != 0) { 6325 max_request_credit = min_t(u16, max_queue_depth + 6326 ioc->internal_depth, facts->RequestCredit); 6327 if (max_request_credit > MAX_HBA_QUEUE_DEPTH) 6328 max_request_credit = MAX_HBA_QUEUE_DEPTH; 6329 } else if (reset_devices) 6330 max_request_credit = min_t(u16, facts->RequestCredit, 6331 (MPT3SAS_KDUMP_SCSI_IO_DEPTH + ioc->internal_depth)); 6332 else 6333 max_request_credit = min_t(u16, facts->RequestCredit, 6334 MAX_HBA_QUEUE_DEPTH); 6335 6336 /* Firmware maintains additional facts->HighPriorityCredit number of 6337 * credits for HiPriprity Request messages, so hba queue depth will be 6338 * sum of max_request_credit and high priority queue depth. 6339 */ 6340 ioc->hba_queue_depth = max_request_credit + ioc->hi_priority_depth; 6341 6342 /* request frame size */ 6343 ioc->request_sz = facts->IOCRequestFrameSize * 4; 6344 6345 /* reply frame size */ 6346 ioc->reply_sz = facts->ReplyFrameSize * 4; 6347 6348 /* chain segment size */ 6349 if (ioc->hba_mpi_version_belonged != MPI2_VERSION) { 6350 if (facts->IOCMaxChainSegmentSize) 6351 ioc->chain_segment_sz = 6352 facts->IOCMaxChainSegmentSize * 6353 MAX_CHAIN_ELEMT_SZ; 6354 else 6355 /* set to 128 bytes size if IOCMaxChainSegmentSize is zero */ 6356 ioc->chain_segment_sz = DEFAULT_NUM_FWCHAIN_ELEMTS * 6357 MAX_CHAIN_ELEMT_SZ; 6358 } else 6359 ioc->chain_segment_sz = ioc->request_sz; 6360 6361 /* calculate the max scatter element size */ 6362 sge_size = max_t(u16, ioc->sge_size, ioc->sge_size_ieee); 6363 6364 retry_allocation: 6365 total_sz = 0; 6366 /* calculate number of sg elements left over in the 1st frame */ 6367 max_sge_elements = ioc->request_sz - ((sizeof(Mpi2SCSIIORequest_t) - 6368 sizeof(Mpi2SGEIOUnion_t)) + sge_size); 6369 ioc->max_sges_in_main_message = max_sge_elements/sge_size; 6370 6371 /* now do the same for a chain buffer */ 6372 max_sge_elements = ioc->chain_segment_sz - sge_size; 6373 ioc->max_sges_in_chain_message = max_sge_elements/sge_size; 6374 6375 /* 6376 * MPT3SAS_SG_DEPTH = CONFIG_FUSION_MAX_SGE 6377 */ 6378 chains_needed_per_io = ((ioc->shost->sg_tablesize - 6379 ioc->max_sges_in_main_message)/ioc->max_sges_in_chain_message) 6380 + 1; 6381 if (chains_needed_per_io > facts->MaxChainDepth) { 6382 chains_needed_per_io = facts->MaxChainDepth; 6383 ioc->shost->sg_tablesize = min_t(u16, 6384 ioc->max_sges_in_main_message + (ioc->max_sges_in_chain_message 6385 * chains_needed_per_io), ioc->shost->sg_tablesize); 6386 } 6387 ioc->chains_needed_per_io = chains_needed_per_io; 6388 6389 /* reply free queue sizing - taking into account for 64 FW events */ 6390 ioc->reply_free_queue_depth = ioc->hba_queue_depth + 64; 6391 6392 /* mCPU manage single counters for simplicity */ 6393 if (ioc->is_mcpu_endpoint) 6394 ioc->reply_post_queue_depth = ioc->reply_free_queue_depth; 6395 else { 6396 /* calculate reply descriptor post queue depth */ 6397 ioc->reply_post_queue_depth = ioc->hba_queue_depth + 6398 ioc->reply_free_queue_depth + 1; 6399 /* align the reply post queue on the next 16 count boundary */ 6400 if (ioc->reply_post_queue_depth % 16) 6401 ioc->reply_post_queue_depth += 16 - 6402 (ioc->reply_post_queue_depth % 16); 6403 } 6404 6405 if (ioc->reply_post_queue_depth > 6406 facts->MaxReplyDescriptorPostQueueDepth) { 6407 ioc->reply_post_queue_depth = 6408 facts->MaxReplyDescriptorPostQueueDepth - 6409 (facts->MaxReplyDescriptorPostQueueDepth % 16); 6410 ioc->hba_queue_depth = 6411 ((ioc->reply_post_queue_depth - 64) / 2) - 1; 6412 ioc->reply_free_queue_depth = ioc->hba_queue_depth + 64; 6413 } 6414 6415 ioc_info(ioc, 6416 "scatter gather: sge_in_main_msg(%d), sge_per_chain(%d), " 6417 "sge_per_io(%d), chains_per_io(%d)\n", 6418 ioc->max_sges_in_main_message, 6419 ioc->max_sges_in_chain_message, 6420 ioc->shost->sg_tablesize, 6421 ioc->chains_needed_per_io); 6422 6423 /* reply post queue, 16 byte align */ 6424 reply_post_free_sz = ioc->reply_post_queue_depth * 6425 sizeof(Mpi2DefaultReplyDescriptor_t); 6426 rdpq_sz = reply_post_free_sz * RDPQ_MAX_INDEX_IN_ONE_CHUNK; 6427 if ((_base_is_controller_msix_enabled(ioc) && !ioc->rdpq_array_enable) 6428 || (ioc->reply_queue_count < RDPQ_MAX_INDEX_IN_ONE_CHUNK)) 6429 rdpq_sz = reply_post_free_sz * ioc->reply_queue_count; 6430 ret = base_alloc_rdpq_dma_pool(ioc, rdpq_sz); 6431 if (ret == -EAGAIN) { 6432 /* 6433 * Free allocated bad RDPQ memory pools. 6434 * Change dma coherent mask to 32 bit and reallocate RDPQ 6435 */ 6436 _base_release_memory_pools(ioc); 6437 ioc->use_32bit_dma = true; 6438 if (_base_config_dma_addressing(ioc, ioc->pdev) != 0) { 6439 ioc_err(ioc, 6440 "32 DMA mask failed %s\n", pci_name(ioc->pdev)); 6441 return -ENODEV; 6442 } 6443 if (base_alloc_rdpq_dma_pool(ioc, rdpq_sz)) 6444 return -ENOMEM; 6445 } else if (ret == -ENOMEM) 6446 return -ENOMEM; 6447 total_sz = rdpq_sz * (!ioc->rdpq_array_enable ? 1 : 6448 DIV_ROUND_UP(ioc->reply_queue_count, RDPQ_MAX_INDEX_IN_ONE_CHUNK)); 6449 ioc->scsiio_depth = ioc->hba_queue_depth - 6450 ioc->hi_priority_depth - ioc->internal_depth; 6451 6452 /* set the scsi host can_queue depth 6453 * with some internal commands that could be outstanding 6454 */ 6455 ioc->shost->can_queue = ioc->scsiio_depth - INTERNAL_SCSIIO_CMDS_COUNT; 6456 dinitprintk(ioc, 6457 ioc_info(ioc, "scsi host: can_queue depth (%d)\n", 6458 ioc->shost->can_queue)); 6459 6460 /* contiguous pool for request and chains, 16 byte align, one extra " 6461 * "frame for smid=0 6462 */ 6463 ioc->chain_depth = ioc->chains_needed_per_io * ioc->scsiio_depth; 6464 sz = ((ioc->scsiio_depth + 1) * ioc->request_sz); 6465 6466 /* hi-priority queue */ 6467 sz += (ioc->hi_priority_depth * ioc->request_sz); 6468 6469 /* internal queue */ 6470 sz += (ioc->internal_depth * ioc->request_sz); 6471 6472 ioc->request_dma_sz = sz; 6473 ioc->request = dma_alloc_coherent(&ioc->pdev->dev, sz, 6474 &ioc->request_dma, GFP_KERNEL); 6475 if (!ioc->request) { 6476 ioc_err(ioc, "request pool: dma_alloc_coherent failed: hba_depth(%d), chains_per_io(%d), frame_sz(%d), total(%d kB)\n", 6477 ioc->hba_queue_depth, ioc->chains_needed_per_io, 6478 ioc->request_sz, sz / 1024); 6479 if (ioc->scsiio_depth < MPT3SAS_SAS_QUEUE_DEPTH) 6480 goto out; 6481 retry_sz = 64; 6482 ioc->hba_queue_depth -= retry_sz; 6483 _base_release_memory_pools(ioc); 6484 goto retry_allocation; 6485 } 6486 6487 if (retry_sz) 6488 ioc_err(ioc, "request pool: dma_alloc_coherent succeed: hba_depth(%d), chains_per_io(%d), frame_sz(%d), total(%d kb)\n", 6489 ioc->hba_queue_depth, ioc->chains_needed_per_io, 6490 ioc->request_sz, sz / 1024); 6491 6492 /* hi-priority queue */ 6493 ioc->hi_priority = ioc->request + ((ioc->scsiio_depth + 1) * 6494 ioc->request_sz); 6495 ioc->hi_priority_dma = ioc->request_dma + ((ioc->scsiio_depth + 1) * 6496 ioc->request_sz); 6497 6498 /* internal queue */ 6499 ioc->internal = ioc->hi_priority + (ioc->hi_priority_depth * 6500 ioc->request_sz); 6501 ioc->internal_dma = ioc->hi_priority_dma + (ioc->hi_priority_depth * 6502 ioc->request_sz); 6503 6504 ioc_info(ioc, 6505 "request pool(0x%p) - dma(0x%llx): " 6506 "depth(%d), frame_size(%d), pool_size(%d kB)\n", 6507 ioc->request, (unsigned long long) ioc->request_dma, 6508 ioc->hba_queue_depth, ioc->request_sz, 6509 (ioc->hba_queue_depth * ioc->request_sz) / 1024); 6510 6511 total_sz += sz; 6512 6513 dinitprintk(ioc, 6514 ioc_info(ioc, "scsiio(0x%p): depth(%d)\n", 6515 ioc->request, ioc->scsiio_depth)); 6516 6517 ioc->chain_depth = min_t(u32, ioc->chain_depth, MAX_CHAIN_DEPTH); 6518 sz = ioc->scsiio_depth * sizeof(struct chain_lookup); 6519 ioc->chain_lookup = kzalloc(sz, GFP_KERNEL); 6520 if (!ioc->chain_lookup) { 6521 ioc_err(ioc, "chain_lookup: __get_free_pages failed\n"); 6522 goto out; 6523 } 6524 6525 sz = ioc->chains_needed_per_io * sizeof(struct chain_tracker); 6526 for (i = 0; i < ioc->scsiio_depth; i++) { 6527 ioc->chain_lookup[i].chains_per_smid = kzalloc(sz, GFP_KERNEL); 6528 if (!ioc->chain_lookup[i].chains_per_smid) { 6529 ioc_err(ioc, "chain_lookup: kzalloc failed\n"); 6530 goto out; 6531 } 6532 } 6533 6534 /* initialize hi-priority queue smid's */ 6535 ioc->hpr_lookup = kcalloc(ioc->hi_priority_depth, 6536 sizeof(struct request_tracker), GFP_KERNEL); 6537 if (!ioc->hpr_lookup) { 6538 ioc_err(ioc, "hpr_lookup: kcalloc failed\n"); 6539 goto out; 6540 } 6541 ioc->hi_priority_smid = ioc->scsiio_depth + 1; 6542 dinitprintk(ioc, 6543 ioc_info(ioc, "hi_priority(0x%p): depth(%d), start smid(%d)\n", 6544 ioc->hi_priority, 6545 ioc->hi_priority_depth, ioc->hi_priority_smid)); 6546 6547 /* initialize internal queue smid's */ 6548 ioc->internal_lookup = kcalloc(ioc->internal_depth, 6549 sizeof(struct request_tracker), GFP_KERNEL); 6550 if (!ioc->internal_lookup) { 6551 ioc_err(ioc, "internal_lookup: kcalloc failed\n"); 6552 goto out; 6553 } 6554 ioc->internal_smid = ioc->hi_priority_smid + ioc->hi_priority_depth; 6555 dinitprintk(ioc, 6556 ioc_info(ioc, "internal(0x%p): depth(%d), start smid(%d)\n", 6557 ioc->internal, 6558 ioc->internal_depth, ioc->internal_smid)); 6559 6560 ioc->io_queue_num = kcalloc(ioc->scsiio_depth, 6561 sizeof(u16), GFP_KERNEL); 6562 if (!ioc->io_queue_num) 6563 goto out; 6564 /* 6565 * The number of NVMe page sized blocks needed is: 6566 * (((sg_tablesize * 8) - 1) / (page_size - 8)) + 1 6567 * ((sg_tablesize * 8) - 1) is the max PRP's minus the first PRP entry 6568 * that is placed in the main message frame. 8 is the size of each PRP 6569 * entry or PRP list pointer entry. 8 is subtracted from page_size 6570 * because of the PRP list pointer entry at the end of a page, so this 6571 * is not counted as a PRP entry. The 1 added page is a round up. 6572 * 6573 * To avoid allocation failures due to the amount of memory that could 6574 * be required for NVMe PRP's, only each set of NVMe blocks will be 6575 * contiguous, so a new set is allocated for each possible I/O. 6576 */ 6577 6578 ioc->chains_per_prp_buffer = 0; 6579 if (ioc->facts.ProtocolFlags & MPI2_IOCFACTS_PROTOCOL_NVME_DEVICES) { 6580 nvme_blocks_needed = 6581 (ioc->shost->sg_tablesize * NVME_PRP_SIZE) - 1; 6582 nvme_blocks_needed /= (ioc->page_size - NVME_PRP_SIZE); 6583 nvme_blocks_needed++; 6584 6585 sz = sizeof(struct pcie_sg_list) * ioc->scsiio_depth; 6586 ioc->pcie_sg_lookup = kzalloc(sz, GFP_KERNEL); 6587 if (!ioc->pcie_sg_lookup) { 6588 ioc_info(ioc, "PCIe SGL lookup: kzalloc failed\n"); 6589 goto out; 6590 } 6591 sz = nvme_blocks_needed * ioc->page_size; 6592 rc = _base_allocate_pcie_sgl_pool(ioc, sz); 6593 if (rc == -ENOMEM) 6594 return -ENOMEM; 6595 else if (rc == -EAGAIN) 6596 goto try_32bit_dma; 6597 total_sz += sz * ioc->scsiio_depth; 6598 } 6599 6600 rc = _base_allocate_chain_dma_pool(ioc, ioc->chain_segment_sz); 6601 if (rc == -ENOMEM) 6602 return -ENOMEM; 6603 else if (rc == -EAGAIN) 6604 goto try_32bit_dma; 6605 total_sz += ioc->chain_segment_sz * ((ioc->chains_needed_per_io - 6606 ioc->chains_per_prp_buffer) * ioc->scsiio_depth); 6607 dinitprintk(ioc, 6608 ioc_info(ioc, "chain pool depth(%d), frame_size(%d), pool_size(%d kB)\n", 6609 ioc->chain_depth, ioc->chain_segment_sz, 6610 (ioc->chain_depth * ioc->chain_segment_sz) / 1024)); 6611 /* sense buffers, 4 byte align */ 6612 sense_sz = ioc->scsiio_depth * SCSI_SENSE_BUFFERSIZE; 6613 rc = _base_allocate_sense_dma_pool(ioc, sense_sz); 6614 if (rc == -ENOMEM) 6615 return -ENOMEM; 6616 else if (rc == -EAGAIN) 6617 goto try_32bit_dma; 6618 total_sz += sense_sz; 6619 /* reply pool, 4 byte align */ 6620 sz = ioc->reply_free_queue_depth * ioc->reply_sz; 6621 rc = _base_allocate_reply_pool(ioc, sz); 6622 if (rc == -ENOMEM) 6623 return -ENOMEM; 6624 else if (rc == -EAGAIN) 6625 goto try_32bit_dma; 6626 total_sz += sz; 6627 6628 /* reply free queue, 16 byte align */ 6629 sz = ioc->reply_free_queue_depth * 4; 6630 rc = _base_allocate_reply_free_dma_pool(ioc, sz); 6631 if (rc == -ENOMEM) 6632 return -ENOMEM; 6633 else if (rc == -EAGAIN) 6634 goto try_32bit_dma; 6635 dinitprintk(ioc, 6636 ioc_info(ioc, "reply_free_dma (0x%llx)\n", 6637 (unsigned long long)ioc->reply_free_dma)); 6638 total_sz += sz; 6639 if (ioc->rdpq_array_enable) { 6640 reply_post_free_array_sz = ioc->reply_queue_count * 6641 sizeof(Mpi2IOCInitRDPQArrayEntry); 6642 rc = _base_allocate_reply_post_free_array(ioc, 6643 reply_post_free_array_sz); 6644 if (rc == -ENOMEM) 6645 return -ENOMEM; 6646 else if (rc == -EAGAIN) 6647 goto try_32bit_dma; 6648 } 6649 ioc->config_page_sz = 512; 6650 ioc->config_page = dma_alloc_coherent(&ioc->pdev->dev, 6651 ioc->config_page_sz, &ioc->config_page_dma, GFP_KERNEL); 6652 if (!ioc->config_page) { 6653 ioc_err(ioc, "config page: dma_pool_alloc failed\n"); 6654 goto out; 6655 } 6656 6657 ioc_info(ioc, "config page(0x%p) - dma(0x%llx): size(%d)\n", 6658 ioc->config_page, (unsigned long long)ioc->config_page_dma, 6659 ioc->config_page_sz); 6660 total_sz += ioc->config_page_sz; 6661 6662 ioc_info(ioc, "Allocated physical memory: size(%d kB)\n", 6663 total_sz / 1024); 6664 ioc_info(ioc, "Current Controller Queue Depth(%d),Max Controller Queue Depth(%d)\n", 6665 ioc->shost->can_queue, facts->RequestCredit); 6666 ioc_info(ioc, "Scatter Gather Elements per IO(%d)\n", 6667 ioc->shost->sg_tablesize); 6668 return 0; 6669 6670 try_32bit_dma: 6671 _base_release_memory_pools(ioc); 6672 if (ioc->use_32bit_dma && (ioc->dma_mask > 32)) { 6673 /* Change dma coherent mask to 32 bit and reallocate */ 6674 if (_base_config_dma_addressing(ioc, ioc->pdev) != 0) { 6675 pr_err("Setting 32 bit coherent DMA mask Failed %s\n", 6676 pci_name(ioc->pdev)); 6677 return -ENODEV; 6678 } 6679 } else if (_base_reduce_hba_queue_depth(ioc) != 0) 6680 return -ENOMEM; 6681 goto retry_allocation; 6682 6683 out: 6684 return -ENOMEM; 6685 } 6686 6687 /** 6688 * mpt3sas_base_get_iocstate - Get the current state of a MPT adapter. 6689 * @ioc: Pointer to MPT_ADAPTER structure 6690 * @cooked: Request raw or cooked IOC state 6691 * 6692 * Return: all IOC Doorbell register bits if cooked==0, else just the 6693 * Doorbell bits in MPI_IOC_STATE_MASK. 6694 */ 6695 u32 6696 mpt3sas_base_get_iocstate(struct MPT3SAS_ADAPTER *ioc, int cooked) 6697 { 6698 u32 s, sc; 6699 6700 s = ioc->base_readl(&ioc->chip->Doorbell); 6701 sc = s & MPI2_IOC_STATE_MASK; 6702 return cooked ? sc : s; 6703 } 6704 6705 /** 6706 * _base_wait_on_iocstate - waiting on a particular ioc state 6707 * @ioc: ? 6708 * @ioc_state: controller state { READY, OPERATIONAL, or RESET } 6709 * @timeout: timeout in second 6710 * 6711 * Return: 0 for success, non-zero for failure. 6712 */ 6713 static int 6714 _base_wait_on_iocstate(struct MPT3SAS_ADAPTER *ioc, u32 ioc_state, int timeout) 6715 { 6716 u32 count, cntdn; 6717 u32 current_state; 6718 6719 count = 0; 6720 cntdn = 1000 * timeout; 6721 do { 6722 current_state = mpt3sas_base_get_iocstate(ioc, 1); 6723 if (current_state == ioc_state) 6724 return 0; 6725 if (count && current_state == MPI2_IOC_STATE_FAULT) 6726 break; 6727 if (count && current_state == MPI2_IOC_STATE_COREDUMP) 6728 break; 6729 6730 usleep_range(1000, 1500); 6731 count++; 6732 } while (--cntdn); 6733 6734 return current_state; 6735 } 6736 6737 /** 6738 * _base_dump_reg_set - This function will print hexdump of register set. 6739 * @ioc: per adapter object 6740 * 6741 * Return: nothing. 6742 */ 6743 static inline void 6744 _base_dump_reg_set(struct MPT3SAS_ADAPTER *ioc) 6745 { 6746 unsigned int i, sz = 256; 6747 u32 __iomem *reg = (u32 __iomem *)ioc->chip; 6748 6749 ioc_info(ioc, "System Register set:\n"); 6750 for (i = 0; i < (sz / sizeof(u32)); i++) 6751 pr_info("%08x: %08x\n", (i * 4), readl(®[i])); 6752 } 6753 6754 /** 6755 * _base_wait_for_doorbell_int - waiting for controller interrupt(generated by 6756 * a write to the doorbell) 6757 * @ioc: per adapter object 6758 * @timeout: timeout in seconds 6759 * 6760 * Return: 0 for success, non-zero for failure. 6761 * 6762 * Notes: MPI2_HIS_IOC2SYS_DB_STATUS - set to one when IOC writes to doorbell. 6763 */ 6764 6765 static int 6766 _base_wait_for_doorbell_int(struct MPT3SAS_ADAPTER *ioc, int timeout) 6767 { 6768 u32 cntdn, count; 6769 u32 int_status; 6770 6771 count = 0; 6772 cntdn = 1000 * timeout; 6773 do { 6774 int_status = ioc->base_readl(&ioc->chip->HostInterruptStatus); 6775 if (int_status & MPI2_HIS_IOC2SYS_DB_STATUS) { 6776 dhsprintk(ioc, 6777 ioc_info(ioc, "%s: successful count(%d), timeout(%d)\n", 6778 __func__, count, timeout)); 6779 return 0; 6780 } 6781 6782 usleep_range(1000, 1500); 6783 count++; 6784 } while (--cntdn); 6785 6786 ioc_err(ioc, "%s: failed due to timeout count(%d), int_status(%x)!\n", 6787 __func__, count, int_status); 6788 return -EFAULT; 6789 } 6790 6791 static int 6792 _base_spin_on_doorbell_int(struct MPT3SAS_ADAPTER *ioc, int timeout) 6793 { 6794 u32 cntdn, count; 6795 u32 int_status; 6796 6797 count = 0; 6798 cntdn = 2000 * timeout; 6799 do { 6800 int_status = ioc->base_readl(&ioc->chip->HostInterruptStatus); 6801 if (int_status & MPI2_HIS_IOC2SYS_DB_STATUS) { 6802 dhsprintk(ioc, 6803 ioc_info(ioc, "%s: successful count(%d), timeout(%d)\n", 6804 __func__, count, timeout)); 6805 return 0; 6806 } 6807 6808 udelay(500); 6809 count++; 6810 } while (--cntdn); 6811 6812 ioc_err(ioc, "%s: failed due to timeout count(%d), int_status(%x)!\n", 6813 __func__, count, int_status); 6814 return -EFAULT; 6815 6816 } 6817 6818 /** 6819 * _base_wait_for_doorbell_ack - waiting for controller to read the doorbell. 6820 * @ioc: per adapter object 6821 * @timeout: timeout in second 6822 * 6823 * Return: 0 for success, non-zero for failure. 6824 * 6825 * Notes: MPI2_HIS_SYS2IOC_DB_STATUS - set to one when host writes to 6826 * doorbell. 6827 */ 6828 static int 6829 _base_wait_for_doorbell_ack(struct MPT3SAS_ADAPTER *ioc, int timeout) 6830 { 6831 u32 cntdn, count; 6832 u32 int_status; 6833 u32 doorbell; 6834 6835 count = 0; 6836 cntdn = 1000 * timeout; 6837 do { 6838 int_status = ioc->base_readl(&ioc->chip->HostInterruptStatus); 6839 if (!(int_status & MPI2_HIS_SYS2IOC_DB_STATUS)) { 6840 dhsprintk(ioc, 6841 ioc_info(ioc, "%s: successful count(%d), timeout(%d)\n", 6842 __func__, count, timeout)); 6843 return 0; 6844 } else if (int_status & MPI2_HIS_IOC2SYS_DB_STATUS) { 6845 doorbell = ioc->base_readl(&ioc->chip->Doorbell); 6846 if ((doorbell & MPI2_IOC_STATE_MASK) == 6847 MPI2_IOC_STATE_FAULT) { 6848 mpt3sas_print_fault_code(ioc, doorbell); 6849 return -EFAULT; 6850 } 6851 if ((doorbell & MPI2_IOC_STATE_MASK) == 6852 MPI2_IOC_STATE_COREDUMP) { 6853 mpt3sas_print_coredump_info(ioc, doorbell); 6854 return -EFAULT; 6855 } 6856 } else if (int_status == 0xFFFFFFFF) 6857 goto out; 6858 6859 usleep_range(1000, 1500); 6860 count++; 6861 } while (--cntdn); 6862 6863 out: 6864 ioc_err(ioc, "%s: failed due to timeout count(%d), int_status(%x)!\n", 6865 __func__, count, int_status); 6866 return -EFAULT; 6867 } 6868 6869 /** 6870 * _base_wait_for_doorbell_not_used - waiting for doorbell to not be in use 6871 * @ioc: per adapter object 6872 * @timeout: timeout in second 6873 * 6874 * Return: 0 for success, non-zero for failure. 6875 */ 6876 static int 6877 _base_wait_for_doorbell_not_used(struct MPT3SAS_ADAPTER *ioc, int timeout) 6878 { 6879 u32 cntdn, count; 6880 u32 doorbell_reg; 6881 6882 count = 0; 6883 cntdn = 1000 * timeout; 6884 do { 6885 doorbell_reg = ioc->base_readl(&ioc->chip->Doorbell); 6886 if (!(doorbell_reg & MPI2_DOORBELL_USED)) { 6887 dhsprintk(ioc, 6888 ioc_info(ioc, "%s: successful count(%d), timeout(%d)\n", 6889 __func__, count, timeout)); 6890 return 0; 6891 } 6892 6893 usleep_range(1000, 1500); 6894 count++; 6895 } while (--cntdn); 6896 6897 ioc_err(ioc, "%s: failed due to timeout count(%d), doorbell_reg(%x)!\n", 6898 __func__, count, doorbell_reg); 6899 return -EFAULT; 6900 } 6901 6902 /** 6903 * _base_send_ioc_reset - send doorbell reset 6904 * @ioc: per adapter object 6905 * @reset_type: currently only supports: MPI2_FUNCTION_IOC_MESSAGE_UNIT_RESET 6906 * @timeout: timeout in second 6907 * 6908 * Return: 0 for success, non-zero for failure. 6909 */ 6910 static int 6911 _base_send_ioc_reset(struct MPT3SAS_ADAPTER *ioc, u8 reset_type, int timeout) 6912 { 6913 u32 ioc_state; 6914 int r = 0; 6915 unsigned long flags; 6916 6917 if (reset_type != MPI2_FUNCTION_IOC_MESSAGE_UNIT_RESET) { 6918 ioc_err(ioc, "%s: unknown reset_type\n", __func__); 6919 return -EFAULT; 6920 } 6921 6922 if (!(ioc->facts.IOCCapabilities & 6923 MPI2_IOCFACTS_CAPABILITY_EVENT_REPLAY)) 6924 return -EFAULT; 6925 6926 ioc_info(ioc, "sending message unit reset !!\n"); 6927 6928 writel(reset_type << MPI2_DOORBELL_FUNCTION_SHIFT, 6929 &ioc->chip->Doorbell); 6930 if ((_base_wait_for_doorbell_ack(ioc, 15))) { 6931 r = -EFAULT; 6932 goto out; 6933 } 6934 6935 ioc_state = _base_wait_on_iocstate(ioc, MPI2_IOC_STATE_READY, timeout); 6936 if (ioc_state) { 6937 ioc_err(ioc, "%s: failed going to ready state (ioc_state=0x%x)\n", 6938 __func__, ioc_state); 6939 r = -EFAULT; 6940 goto out; 6941 } 6942 out: 6943 if (r != 0) { 6944 ioc_state = mpt3sas_base_get_iocstate(ioc, 0); 6945 spin_lock_irqsave(&ioc->ioc_reset_in_progress_lock, flags); 6946 /* 6947 * Wait for IOC state CoreDump to clear only during 6948 * HBA initialization & release time. 6949 */ 6950 if ((ioc_state & MPI2_IOC_STATE_MASK) == 6951 MPI2_IOC_STATE_COREDUMP && (ioc->is_driver_loading == 1 || 6952 ioc->fault_reset_work_q == NULL)) { 6953 spin_unlock_irqrestore( 6954 &ioc->ioc_reset_in_progress_lock, flags); 6955 mpt3sas_print_coredump_info(ioc, ioc_state); 6956 mpt3sas_base_wait_for_coredump_completion(ioc, 6957 __func__); 6958 spin_lock_irqsave( 6959 &ioc->ioc_reset_in_progress_lock, flags); 6960 } 6961 spin_unlock_irqrestore(&ioc->ioc_reset_in_progress_lock, flags); 6962 } 6963 ioc_info(ioc, "message unit reset: %s\n", 6964 r == 0 ? "SUCCESS" : "FAILED"); 6965 return r; 6966 } 6967 6968 /** 6969 * mpt3sas_wait_for_ioc - IOC's operational state is checked here. 6970 * @ioc: per adapter object 6971 * @timeout: timeout in seconds 6972 * 6973 * Return: Waits up to timeout seconds for the IOC to 6974 * become operational. Returns 0 if IOC is present 6975 * and operational; otherwise returns %-EFAULT. 6976 */ 6977 6978 int 6979 mpt3sas_wait_for_ioc(struct MPT3SAS_ADAPTER *ioc, int timeout) 6980 { 6981 int wait_state_count = 0; 6982 u32 ioc_state; 6983 6984 do { 6985 ioc_state = mpt3sas_base_get_iocstate(ioc, 1); 6986 if (ioc_state == MPI2_IOC_STATE_OPERATIONAL) 6987 break; 6988 6989 /* 6990 * Watchdog thread will be started after IOC Initialization, so 6991 * no need to wait here for IOC state to become operational 6992 * when IOC Initialization is on. Instead the driver will 6993 * return ETIME status, so that calling function can issue 6994 * diag reset operation and retry the command. 6995 */ 6996 if (ioc->is_driver_loading) 6997 return -ETIME; 6998 6999 ssleep(1); 7000 ioc_info(ioc, "%s: waiting for operational state(count=%d)\n", 7001 __func__, ++wait_state_count); 7002 } while (--timeout); 7003 if (!timeout) { 7004 ioc_err(ioc, "%s: failed due to ioc not operational\n", __func__); 7005 return -EFAULT; 7006 } 7007 if (wait_state_count) 7008 ioc_info(ioc, "ioc is operational\n"); 7009 return 0; 7010 } 7011 7012 /** 7013 * _base_handshake_req_reply_wait - send request thru doorbell interface 7014 * @ioc: per adapter object 7015 * @request_bytes: request length 7016 * @request: pointer having request payload 7017 * @reply_bytes: reply length 7018 * @reply: pointer to reply payload 7019 * @timeout: timeout in second 7020 * 7021 * Return: 0 for success, non-zero for failure. 7022 */ 7023 static int 7024 _base_handshake_req_reply_wait(struct MPT3SAS_ADAPTER *ioc, int request_bytes, 7025 u32 *request, int reply_bytes, u16 *reply, int timeout) 7026 { 7027 MPI2DefaultReply_t *default_reply = (MPI2DefaultReply_t *)reply; 7028 int i; 7029 u8 failed; 7030 __le32 *mfp; 7031 7032 /* make sure doorbell is not in use */ 7033 if ((ioc->base_readl(&ioc->chip->Doorbell) & MPI2_DOORBELL_USED)) { 7034 ioc_err(ioc, "doorbell is in use (line=%d)\n", __LINE__); 7035 return -EFAULT; 7036 } 7037 7038 /* clear pending doorbell interrupts from previous state changes */ 7039 if (ioc->base_readl(&ioc->chip->HostInterruptStatus) & 7040 MPI2_HIS_IOC2SYS_DB_STATUS) 7041 writel(0, &ioc->chip->HostInterruptStatus); 7042 7043 /* send message to ioc */ 7044 writel(((MPI2_FUNCTION_HANDSHAKE<<MPI2_DOORBELL_FUNCTION_SHIFT) | 7045 ((request_bytes/4)<<MPI2_DOORBELL_ADD_DWORDS_SHIFT)), 7046 &ioc->chip->Doorbell); 7047 7048 if ((_base_spin_on_doorbell_int(ioc, 5))) { 7049 ioc_err(ioc, "doorbell handshake int failed (line=%d)\n", 7050 __LINE__); 7051 return -EFAULT; 7052 } 7053 writel(0, &ioc->chip->HostInterruptStatus); 7054 7055 if ((_base_wait_for_doorbell_ack(ioc, 5))) { 7056 ioc_err(ioc, "doorbell handshake ack failed (line=%d)\n", 7057 __LINE__); 7058 return -EFAULT; 7059 } 7060 7061 /* send message 32-bits at a time */ 7062 for (i = 0, failed = 0; i < request_bytes/4 && !failed; i++) { 7063 writel(cpu_to_le32(request[i]), &ioc->chip->Doorbell); 7064 if ((_base_wait_for_doorbell_ack(ioc, 5))) 7065 failed = 1; 7066 } 7067 7068 if (failed) { 7069 ioc_err(ioc, "doorbell handshake sending request failed (line=%d)\n", 7070 __LINE__); 7071 return -EFAULT; 7072 } 7073 7074 /* now wait for the reply */ 7075 if ((_base_wait_for_doorbell_int(ioc, timeout))) { 7076 ioc_err(ioc, "doorbell handshake int failed (line=%d)\n", 7077 __LINE__); 7078 return -EFAULT; 7079 } 7080 7081 /* read the first two 16-bits, it gives the total length of the reply */ 7082 reply[0] = le16_to_cpu(ioc->base_readl(&ioc->chip->Doorbell) 7083 & MPI2_DOORBELL_DATA_MASK); 7084 writel(0, &ioc->chip->HostInterruptStatus); 7085 if ((_base_wait_for_doorbell_int(ioc, 5))) { 7086 ioc_err(ioc, "doorbell handshake int failed (line=%d)\n", 7087 __LINE__); 7088 return -EFAULT; 7089 } 7090 reply[1] = le16_to_cpu(ioc->base_readl(&ioc->chip->Doorbell) 7091 & MPI2_DOORBELL_DATA_MASK); 7092 writel(0, &ioc->chip->HostInterruptStatus); 7093 7094 for (i = 2; i < default_reply->MsgLength * 2; i++) { 7095 if ((_base_wait_for_doorbell_int(ioc, 5))) { 7096 ioc_err(ioc, "doorbell handshake int failed (line=%d)\n", 7097 __LINE__); 7098 return -EFAULT; 7099 } 7100 if (i >= reply_bytes/2) /* overflow case */ 7101 ioc->base_readl(&ioc->chip->Doorbell); 7102 else 7103 reply[i] = le16_to_cpu( 7104 ioc->base_readl(&ioc->chip->Doorbell) 7105 & MPI2_DOORBELL_DATA_MASK); 7106 writel(0, &ioc->chip->HostInterruptStatus); 7107 } 7108 7109 _base_wait_for_doorbell_int(ioc, 5); 7110 if (_base_wait_for_doorbell_not_used(ioc, 5) != 0) { 7111 dhsprintk(ioc, 7112 ioc_info(ioc, "doorbell is in use (line=%d)\n", 7113 __LINE__)); 7114 } 7115 writel(0, &ioc->chip->HostInterruptStatus); 7116 7117 if (ioc->logging_level & MPT_DEBUG_INIT) { 7118 mfp = (__le32 *)reply; 7119 pr_info("\toffset:data\n"); 7120 for (i = 0; i < reply_bytes/4; i++) 7121 ioc_info(ioc, "\t[0x%02x]:%08x\n", i*4, 7122 le32_to_cpu(mfp[i])); 7123 } 7124 return 0; 7125 } 7126 7127 /** 7128 * mpt3sas_base_sas_iounit_control - send sas iounit control to FW 7129 * @ioc: per adapter object 7130 * @mpi_reply: the reply payload from FW 7131 * @mpi_request: the request payload sent to FW 7132 * 7133 * The SAS IO Unit Control Request message allows the host to perform low-level 7134 * operations, such as resets on the PHYs of the IO Unit, also allows the host 7135 * to obtain the IOC assigned device handles for a device if it has other 7136 * identifying information about the device, in addition allows the host to 7137 * remove IOC resources associated with the device. 7138 * 7139 * Return: 0 for success, non-zero for failure. 7140 */ 7141 int 7142 mpt3sas_base_sas_iounit_control(struct MPT3SAS_ADAPTER *ioc, 7143 Mpi2SasIoUnitControlReply_t *mpi_reply, 7144 Mpi2SasIoUnitControlRequest_t *mpi_request) 7145 { 7146 u16 smid; 7147 u8 issue_reset = 0; 7148 int rc; 7149 void *request; 7150 7151 dinitprintk(ioc, ioc_info(ioc, "%s\n", __func__)); 7152 7153 mutex_lock(&ioc->base_cmds.mutex); 7154 7155 if (ioc->base_cmds.status != MPT3_CMD_NOT_USED) { 7156 ioc_err(ioc, "%s: base_cmd in use\n", __func__); 7157 rc = -EAGAIN; 7158 goto out; 7159 } 7160 7161 rc = mpt3sas_wait_for_ioc(ioc, IOC_OPERATIONAL_WAIT_COUNT); 7162 if (rc) 7163 goto out; 7164 7165 smid = mpt3sas_base_get_smid(ioc, ioc->base_cb_idx); 7166 if (!smid) { 7167 ioc_err(ioc, "%s: failed obtaining a smid\n", __func__); 7168 rc = -EAGAIN; 7169 goto out; 7170 } 7171 7172 rc = 0; 7173 ioc->base_cmds.status = MPT3_CMD_PENDING; 7174 request = mpt3sas_base_get_msg_frame(ioc, smid); 7175 ioc->base_cmds.smid = smid; 7176 memcpy(request, mpi_request, sizeof(Mpi2SasIoUnitControlRequest_t)); 7177 if (mpi_request->Operation == MPI2_SAS_OP_PHY_HARD_RESET || 7178 mpi_request->Operation == MPI2_SAS_OP_PHY_LINK_RESET) 7179 ioc->ioc_link_reset_in_progress = 1; 7180 init_completion(&ioc->base_cmds.done); 7181 ioc->put_smid_default(ioc, smid); 7182 wait_for_completion_timeout(&ioc->base_cmds.done, 7183 msecs_to_jiffies(10000)); 7184 if ((mpi_request->Operation == MPI2_SAS_OP_PHY_HARD_RESET || 7185 mpi_request->Operation == MPI2_SAS_OP_PHY_LINK_RESET) && 7186 ioc->ioc_link_reset_in_progress) 7187 ioc->ioc_link_reset_in_progress = 0; 7188 if (!(ioc->base_cmds.status & MPT3_CMD_COMPLETE)) { 7189 mpt3sas_check_cmd_timeout(ioc, ioc->base_cmds.status, 7190 mpi_request, sizeof(Mpi2SasIoUnitControlRequest_t)/4, 7191 issue_reset); 7192 goto issue_host_reset; 7193 } 7194 if (ioc->base_cmds.status & MPT3_CMD_REPLY_VALID) 7195 memcpy(mpi_reply, ioc->base_cmds.reply, 7196 sizeof(Mpi2SasIoUnitControlReply_t)); 7197 else 7198 memset(mpi_reply, 0, sizeof(Mpi2SasIoUnitControlReply_t)); 7199 ioc->base_cmds.status = MPT3_CMD_NOT_USED; 7200 goto out; 7201 7202 issue_host_reset: 7203 if (issue_reset) 7204 mpt3sas_base_hard_reset_handler(ioc, FORCE_BIG_HAMMER); 7205 ioc->base_cmds.status = MPT3_CMD_NOT_USED; 7206 rc = -EFAULT; 7207 out: 7208 mutex_unlock(&ioc->base_cmds.mutex); 7209 return rc; 7210 } 7211 7212 /** 7213 * mpt3sas_base_scsi_enclosure_processor - sending request to sep device 7214 * @ioc: per adapter object 7215 * @mpi_reply: the reply payload from FW 7216 * @mpi_request: the request payload sent to FW 7217 * 7218 * The SCSI Enclosure Processor request message causes the IOC to 7219 * communicate with SES devices to control LED status signals. 7220 * 7221 * Return: 0 for success, non-zero for failure. 7222 */ 7223 int 7224 mpt3sas_base_scsi_enclosure_processor(struct MPT3SAS_ADAPTER *ioc, 7225 Mpi2SepReply_t *mpi_reply, Mpi2SepRequest_t *mpi_request) 7226 { 7227 u16 smid; 7228 u8 issue_reset = 0; 7229 int rc; 7230 void *request; 7231 7232 dinitprintk(ioc, ioc_info(ioc, "%s\n", __func__)); 7233 7234 mutex_lock(&ioc->base_cmds.mutex); 7235 7236 if (ioc->base_cmds.status != MPT3_CMD_NOT_USED) { 7237 ioc_err(ioc, "%s: base_cmd in use\n", __func__); 7238 rc = -EAGAIN; 7239 goto out; 7240 } 7241 7242 rc = mpt3sas_wait_for_ioc(ioc, IOC_OPERATIONAL_WAIT_COUNT); 7243 if (rc) 7244 goto out; 7245 7246 smid = mpt3sas_base_get_smid(ioc, ioc->base_cb_idx); 7247 if (!smid) { 7248 ioc_err(ioc, "%s: failed obtaining a smid\n", __func__); 7249 rc = -EAGAIN; 7250 goto out; 7251 } 7252 7253 rc = 0; 7254 ioc->base_cmds.status = MPT3_CMD_PENDING; 7255 request = mpt3sas_base_get_msg_frame(ioc, smid); 7256 ioc->base_cmds.smid = smid; 7257 memset(request, 0, ioc->request_sz); 7258 memcpy(request, mpi_request, sizeof(Mpi2SepReply_t)); 7259 init_completion(&ioc->base_cmds.done); 7260 ioc->put_smid_default(ioc, smid); 7261 wait_for_completion_timeout(&ioc->base_cmds.done, 7262 msecs_to_jiffies(10000)); 7263 if (!(ioc->base_cmds.status & MPT3_CMD_COMPLETE)) { 7264 mpt3sas_check_cmd_timeout(ioc, 7265 ioc->base_cmds.status, mpi_request, 7266 sizeof(Mpi2SepRequest_t)/4, issue_reset); 7267 goto issue_host_reset; 7268 } 7269 if (ioc->base_cmds.status & MPT3_CMD_REPLY_VALID) 7270 memcpy(mpi_reply, ioc->base_cmds.reply, 7271 sizeof(Mpi2SepReply_t)); 7272 else 7273 memset(mpi_reply, 0, sizeof(Mpi2SepReply_t)); 7274 ioc->base_cmds.status = MPT3_CMD_NOT_USED; 7275 goto out; 7276 7277 issue_host_reset: 7278 if (issue_reset) 7279 mpt3sas_base_hard_reset_handler(ioc, FORCE_BIG_HAMMER); 7280 ioc->base_cmds.status = MPT3_CMD_NOT_USED; 7281 rc = -EFAULT; 7282 out: 7283 mutex_unlock(&ioc->base_cmds.mutex); 7284 return rc; 7285 } 7286 7287 /** 7288 * _base_get_port_facts - obtain port facts reply and save in ioc 7289 * @ioc: per adapter object 7290 * @port: ? 7291 * 7292 * Return: 0 for success, non-zero for failure. 7293 */ 7294 static int 7295 _base_get_port_facts(struct MPT3SAS_ADAPTER *ioc, int port) 7296 { 7297 Mpi2PortFactsRequest_t mpi_request; 7298 Mpi2PortFactsReply_t mpi_reply; 7299 struct mpt3sas_port_facts *pfacts; 7300 int mpi_reply_sz, mpi_request_sz, r; 7301 7302 dinitprintk(ioc, ioc_info(ioc, "%s\n", __func__)); 7303 7304 mpi_reply_sz = sizeof(Mpi2PortFactsReply_t); 7305 mpi_request_sz = sizeof(Mpi2PortFactsRequest_t); 7306 memset(&mpi_request, 0, mpi_request_sz); 7307 mpi_request.Function = MPI2_FUNCTION_PORT_FACTS; 7308 mpi_request.PortNumber = port; 7309 r = _base_handshake_req_reply_wait(ioc, mpi_request_sz, 7310 (u32 *)&mpi_request, mpi_reply_sz, (u16 *)&mpi_reply, 5); 7311 7312 if (r != 0) { 7313 ioc_err(ioc, "%s: handshake failed (r=%d)\n", __func__, r); 7314 return r; 7315 } 7316 7317 pfacts = &ioc->pfacts[port]; 7318 memset(pfacts, 0, sizeof(struct mpt3sas_port_facts)); 7319 pfacts->PortNumber = mpi_reply.PortNumber; 7320 pfacts->VP_ID = mpi_reply.VP_ID; 7321 pfacts->VF_ID = mpi_reply.VF_ID; 7322 pfacts->MaxPostedCmdBuffers = 7323 le16_to_cpu(mpi_reply.MaxPostedCmdBuffers); 7324 7325 return 0; 7326 } 7327 7328 /** 7329 * _base_wait_for_iocstate - Wait until the card is in READY or OPERATIONAL 7330 * @ioc: per adapter object 7331 * @timeout: 7332 * 7333 * Return: 0 for success, non-zero for failure. 7334 */ 7335 static int 7336 _base_wait_for_iocstate(struct MPT3SAS_ADAPTER *ioc, int timeout) 7337 { 7338 u32 ioc_state; 7339 int rc; 7340 7341 dinitprintk(ioc, ioc_info(ioc, "%s\n", __func__)); 7342 7343 if (ioc->pci_error_recovery) { 7344 dfailprintk(ioc, 7345 ioc_info(ioc, "%s: host in pci error recovery\n", 7346 __func__)); 7347 return -EFAULT; 7348 } 7349 7350 ioc_state = mpt3sas_base_get_iocstate(ioc, 0); 7351 dhsprintk(ioc, 7352 ioc_info(ioc, "%s: ioc_state(0x%08x)\n", 7353 __func__, ioc_state)); 7354 7355 if (((ioc_state & MPI2_IOC_STATE_MASK) == MPI2_IOC_STATE_READY) || 7356 (ioc_state & MPI2_IOC_STATE_MASK) == MPI2_IOC_STATE_OPERATIONAL) 7357 return 0; 7358 7359 if (ioc_state & MPI2_DOORBELL_USED) { 7360 dhsprintk(ioc, ioc_info(ioc, "unexpected doorbell active!\n")); 7361 goto issue_diag_reset; 7362 } 7363 7364 if ((ioc_state & MPI2_IOC_STATE_MASK) == MPI2_IOC_STATE_FAULT) { 7365 mpt3sas_print_fault_code(ioc, ioc_state & 7366 MPI2_DOORBELL_DATA_MASK); 7367 goto issue_diag_reset; 7368 } else if ((ioc_state & MPI2_IOC_STATE_MASK) == 7369 MPI2_IOC_STATE_COREDUMP) { 7370 ioc_info(ioc, 7371 "%s: Skipping the diag reset here. (ioc_state=0x%x)\n", 7372 __func__, ioc_state); 7373 return -EFAULT; 7374 } 7375 7376 ioc_state = _base_wait_on_iocstate(ioc, MPI2_IOC_STATE_READY, timeout); 7377 if (ioc_state) { 7378 dfailprintk(ioc, 7379 ioc_info(ioc, "%s: failed going to ready state (ioc_state=0x%x)\n", 7380 __func__, ioc_state)); 7381 return -EFAULT; 7382 } 7383 7384 issue_diag_reset: 7385 rc = _base_diag_reset(ioc); 7386 return rc; 7387 } 7388 7389 /** 7390 * _base_get_ioc_facts - obtain ioc facts reply and save in ioc 7391 * @ioc: per adapter object 7392 * 7393 * Return: 0 for success, non-zero for failure. 7394 */ 7395 static int 7396 _base_get_ioc_facts(struct MPT3SAS_ADAPTER *ioc) 7397 { 7398 Mpi2IOCFactsRequest_t mpi_request; 7399 Mpi2IOCFactsReply_t mpi_reply; 7400 struct mpt3sas_facts *facts; 7401 int mpi_reply_sz, mpi_request_sz, r; 7402 7403 dinitprintk(ioc, ioc_info(ioc, "%s\n", __func__)); 7404 7405 r = _base_wait_for_iocstate(ioc, 10); 7406 if (r) { 7407 dfailprintk(ioc, 7408 ioc_info(ioc, "%s: failed getting to correct state\n", 7409 __func__)); 7410 return r; 7411 } 7412 mpi_reply_sz = sizeof(Mpi2IOCFactsReply_t); 7413 mpi_request_sz = sizeof(Mpi2IOCFactsRequest_t); 7414 memset(&mpi_request, 0, mpi_request_sz); 7415 mpi_request.Function = MPI2_FUNCTION_IOC_FACTS; 7416 r = _base_handshake_req_reply_wait(ioc, mpi_request_sz, 7417 (u32 *)&mpi_request, mpi_reply_sz, (u16 *)&mpi_reply, 5); 7418 7419 if (r != 0) { 7420 ioc_err(ioc, "%s: handshake failed (r=%d)\n", __func__, r); 7421 return r; 7422 } 7423 7424 facts = &ioc->facts; 7425 memset(facts, 0, sizeof(struct mpt3sas_facts)); 7426 facts->MsgVersion = le16_to_cpu(mpi_reply.MsgVersion); 7427 facts->HeaderVersion = le16_to_cpu(mpi_reply.HeaderVersion); 7428 facts->VP_ID = mpi_reply.VP_ID; 7429 facts->VF_ID = mpi_reply.VF_ID; 7430 facts->IOCExceptions = le16_to_cpu(mpi_reply.IOCExceptions); 7431 facts->MaxChainDepth = mpi_reply.MaxChainDepth; 7432 facts->WhoInit = mpi_reply.WhoInit; 7433 facts->NumberOfPorts = mpi_reply.NumberOfPorts; 7434 facts->MaxMSIxVectors = mpi_reply.MaxMSIxVectors; 7435 if (ioc->msix_enable && (facts->MaxMSIxVectors <= 7436 MAX_COMBINED_MSIX_VECTORS(ioc->is_gen35_ioc))) 7437 ioc->combined_reply_queue = 0; 7438 facts->RequestCredit = le16_to_cpu(mpi_reply.RequestCredit); 7439 facts->MaxReplyDescriptorPostQueueDepth = 7440 le16_to_cpu(mpi_reply.MaxReplyDescriptorPostQueueDepth); 7441 facts->ProductID = le16_to_cpu(mpi_reply.ProductID); 7442 facts->IOCCapabilities = le32_to_cpu(mpi_reply.IOCCapabilities); 7443 if ((facts->IOCCapabilities & MPI2_IOCFACTS_CAPABILITY_INTEGRATED_RAID)) 7444 ioc->ir_firmware = 1; 7445 if ((facts->IOCCapabilities & 7446 MPI2_IOCFACTS_CAPABILITY_RDPQ_ARRAY_CAPABLE) && (!reset_devices)) 7447 ioc->rdpq_array_capable = 1; 7448 if ((facts->IOCCapabilities & MPI26_IOCFACTS_CAPABILITY_ATOMIC_REQ) 7449 && ioc->is_aero_ioc) 7450 ioc->atomic_desc_capable = 1; 7451 facts->FWVersion.Word = le32_to_cpu(mpi_reply.FWVersion.Word); 7452 facts->IOCRequestFrameSize = 7453 le16_to_cpu(mpi_reply.IOCRequestFrameSize); 7454 if (ioc->hba_mpi_version_belonged != MPI2_VERSION) { 7455 facts->IOCMaxChainSegmentSize = 7456 le16_to_cpu(mpi_reply.IOCMaxChainSegmentSize); 7457 } 7458 facts->MaxInitiators = le16_to_cpu(mpi_reply.MaxInitiators); 7459 facts->MaxTargets = le16_to_cpu(mpi_reply.MaxTargets); 7460 ioc->shost->max_id = -1; 7461 facts->MaxSasExpanders = le16_to_cpu(mpi_reply.MaxSasExpanders); 7462 facts->MaxEnclosures = le16_to_cpu(mpi_reply.MaxEnclosures); 7463 facts->ProtocolFlags = le16_to_cpu(mpi_reply.ProtocolFlags); 7464 facts->HighPriorityCredit = 7465 le16_to_cpu(mpi_reply.HighPriorityCredit); 7466 facts->ReplyFrameSize = mpi_reply.ReplyFrameSize; 7467 facts->MaxDevHandle = le16_to_cpu(mpi_reply.MaxDevHandle); 7468 facts->CurrentHostPageSize = mpi_reply.CurrentHostPageSize; 7469 7470 /* 7471 * Get the Page Size from IOC Facts. If it's 0, default to 4k. 7472 */ 7473 ioc->page_size = 1 << facts->CurrentHostPageSize; 7474 if (ioc->page_size == 1) { 7475 ioc_info(ioc, "CurrentHostPageSize is 0: Setting default host page size to 4k\n"); 7476 ioc->page_size = 1 << MPT3SAS_HOST_PAGE_SIZE_4K; 7477 } 7478 dinitprintk(ioc, 7479 ioc_info(ioc, "CurrentHostPageSize(%d)\n", 7480 facts->CurrentHostPageSize)); 7481 7482 dinitprintk(ioc, 7483 ioc_info(ioc, "hba queue depth(%d), max chains per io(%d)\n", 7484 facts->RequestCredit, facts->MaxChainDepth)); 7485 dinitprintk(ioc, 7486 ioc_info(ioc, "request frame size(%d), reply frame size(%d)\n", 7487 facts->IOCRequestFrameSize * 4, 7488 facts->ReplyFrameSize * 4)); 7489 return 0; 7490 } 7491 7492 /** 7493 * _base_send_ioc_init - send ioc_init to firmware 7494 * @ioc: per adapter object 7495 * 7496 * Return: 0 for success, non-zero for failure. 7497 */ 7498 static int 7499 _base_send_ioc_init(struct MPT3SAS_ADAPTER *ioc) 7500 { 7501 Mpi2IOCInitRequest_t mpi_request; 7502 Mpi2IOCInitReply_t mpi_reply; 7503 int i, r = 0; 7504 ktime_t current_time; 7505 u16 ioc_status; 7506 u32 reply_post_free_array_sz = 0; 7507 7508 dinitprintk(ioc, ioc_info(ioc, "%s\n", __func__)); 7509 7510 memset(&mpi_request, 0, sizeof(Mpi2IOCInitRequest_t)); 7511 mpi_request.Function = MPI2_FUNCTION_IOC_INIT; 7512 mpi_request.WhoInit = MPI2_WHOINIT_HOST_DRIVER; 7513 mpi_request.VF_ID = 0; /* TODO */ 7514 mpi_request.VP_ID = 0; 7515 mpi_request.MsgVersion = cpu_to_le16(ioc->hba_mpi_version_belonged); 7516 mpi_request.HeaderVersion = cpu_to_le16(MPI2_HEADER_VERSION); 7517 mpi_request.HostPageSize = MPT3SAS_HOST_PAGE_SIZE_4K; 7518 7519 if (_base_is_controller_msix_enabled(ioc)) 7520 mpi_request.HostMSIxVectors = ioc->reply_queue_count; 7521 mpi_request.SystemRequestFrameSize = cpu_to_le16(ioc->request_sz/4); 7522 mpi_request.ReplyDescriptorPostQueueDepth = 7523 cpu_to_le16(ioc->reply_post_queue_depth); 7524 mpi_request.ReplyFreeQueueDepth = 7525 cpu_to_le16(ioc->reply_free_queue_depth); 7526 7527 mpi_request.SenseBufferAddressHigh = 7528 cpu_to_le32((u64)ioc->sense_dma >> 32); 7529 mpi_request.SystemReplyAddressHigh = 7530 cpu_to_le32((u64)ioc->reply_dma >> 32); 7531 mpi_request.SystemRequestFrameBaseAddress = 7532 cpu_to_le64((u64)ioc->request_dma); 7533 mpi_request.ReplyFreeQueueAddress = 7534 cpu_to_le64((u64)ioc->reply_free_dma); 7535 7536 if (ioc->rdpq_array_enable) { 7537 reply_post_free_array_sz = ioc->reply_queue_count * 7538 sizeof(Mpi2IOCInitRDPQArrayEntry); 7539 memset(ioc->reply_post_free_array, 0, reply_post_free_array_sz); 7540 for (i = 0; i < ioc->reply_queue_count; i++) 7541 ioc->reply_post_free_array[i].RDPQBaseAddress = 7542 cpu_to_le64( 7543 (u64)ioc->reply_post[i].reply_post_free_dma); 7544 mpi_request.MsgFlags = MPI2_IOCINIT_MSGFLAG_RDPQ_ARRAY_MODE; 7545 mpi_request.ReplyDescriptorPostQueueAddress = 7546 cpu_to_le64((u64)ioc->reply_post_free_array_dma); 7547 } else { 7548 mpi_request.ReplyDescriptorPostQueueAddress = 7549 cpu_to_le64((u64)ioc->reply_post[0].reply_post_free_dma); 7550 } 7551 7552 /* 7553 * Set the flag to enable CoreDump state feature in IOC firmware. 7554 */ 7555 mpi_request.ConfigurationFlags |= 7556 cpu_to_le16(MPI26_IOCINIT_CFGFLAGS_COREDUMP_ENABLE); 7557 7558 /* This time stamp specifies number of milliseconds 7559 * since epoch ~ midnight January 1, 1970. 7560 */ 7561 current_time = ktime_get_real(); 7562 mpi_request.TimeStamp = cpu_to_le64(ktime_to_ms(current_time)); 7563 7564 if (ioc->logging_level & MPT_DEBUG_INIT) { 7565 __le32 *mfp; 7566 int i; 7567 7568 mfp = (__le32 *)&mpi_request; 7569 ioc_info(ioc, "\toffset:data\n"); 7570 for (i = 0; i < sizeof(Mpi2IOCInitRequest_t)/4; i++) 7571 ioc_info(ioc, "\t[0x%02x]:%08x\n", i*4, 7572 le32_to_cpu(mfp[i])); 7573 } 7574 7575 r = _base_handshake_req_reply_wait(ioc, 7576 sizeof(Mpi2IOCInitRequest_t), (u32 *)&mpi_request, 7577 sizeof(Mpi2IOCInitReply_t), (u16 *)&mpi_reply, 30); 7578 7579 if (r != 0) { 7580 ioc_err(ioc, "%s: handshake failed (r=%d)\n", __func__, r); 7581 return r; 7582 } 7583 7584 ioc_status = le16_to_cpu(mpi_reply.IOCStatus) & MPI2_IOCSTATUS_MASK; 7585 if (ioc_status != MPI2_IOCSTATUS_SUCCESS || 7586 mpi_reply.IOCLogInfo) { 7587 ioc_err(ioc, "%s: failed\n", __func__); 7588 r = -EIO; 7589 } 7590 7591 /* Reset TimeSync Counter*/ 7592 ioc->timestamp_update_count = 0; 7593 return r; 7594 } 7595 7596 /** 7597 * mpt3sas_port_enable_done - command completion routine for port enable 7598 * @ioc: per adapter object 7599 * @smid: system request message index 7600 * @msix_index: MSIX table index supplied by the OS 7601 * @reply: reply message frame(lower 32bit addr) 7602 * 7603 * Return: 1 meaning mf should be freed from _base_interrupt 7604 * 0 means the mf is freed from this function. 7605 */ 7606 u8 7607 mpt3sas_port_enable_done(struct MPT3SAS_ADAPTER *ioc, u16 smid, u8 msix_index, 7608 u32 reply) 7609 { 7610 MPI2DefaultReply_t *mpi_reply; 7611 u16 ioc_status; 7612 7613 if (ioc->port_enable_cmds.status == MPT3_CMD_NOT_USED) 7614 return 1; 7615 7616 mpi_reply = mpt3sas_base_get_reply_virt_addr(ioc, reply); 7617 if (!mpi_reply) 7618 return 1; 7619 7620 if (mpi_reply->Function != MPI2_FUNCTION_PORT_ENABLE) 7621 return 1; 7622 7623 ioc->port_enable_cmds.status &= ~MPT3_CMD_PENDING; 7624 ioc->port_enable_cmds.status |= MPT3_CMD_COMPLETE; 7625 ioc->port_enable_cmds.status |= MPT3_CMD_REPLY_VALID; 7626 memcpy(ioc->port_enable_cmds.reply, mpi_reply, mpi_reply->MsgLength*4); 7627 ioc_status = le16_to_cpu(mpi_reply->IOCStatus) & MPI2_IOCSTATUS_MASK; 7628 if (ioc_status != MPI2_IOCSTATUS_SUCCESS) 7629 ioc->port_enable_failed = 1; 7630 7631 if (ioc->port_enable_cmds.status & MPT3_CMD_COMPLETE_ASYNC) { 7632 ioc->port_enable_cmds.status &= ~MPT3_CMD_COMPLETE_ASYNC; 7633 if (ioc_status == MPI2_IOCSTATUS_SUCCESS) { 7634 mpt3sas_port_enable_complete(ioc); 7635 return 1; 7636 } else { 7637 ioc->start_scan_failed = ioc_status; 7638 ioc->start_scan = 0; 7639 return 1; 7640 } 7641 } 7642 complete(&ioc->port_enable_cmds.done); 7643 return 1; 7644 } 7645 7646 /** 7647 * _base_send_port_enable - send port_enable(discovery stuff) to firmware 7648 * @ioc: per adapter object 7649 * 7650 * Return: 0 for success, non-zero for failure. 7651 */ 7652 static int 7653 _base_send_port_enable(struct MPT3SAS_ADAPTER *ioc) 7654 { 7655 Mpi2PortEnableRequest_t *mpi_request; 7656 Mpi2PortEnableReply_t *mpi_reply; 7657 int r = 0; 7658 u16 smid; 7659 u16 ioc_status; 7660 7661 ioc_info(ioc, "sending port enable !!\n"); 7662 7663 if (ioc->port_enable_cmds.status & MPT3_CMD_PENDING) { 7664 ioc_err(ioc, "%s: internal command already in use\n", __func__); 7665 return -EAGAIN; 7666 } 7667 7668 smid = mpt3sas_base_get_smid(ioc, ioc->port_enable_cb_idx); 7669 if (!smid) { 7670 ioc_err(ioc, "%s: failed obtaining a smid\n", __func__); 7671 return -EAGAIN; 7672 } 7673 7674 ioc->port_enable_cmds.status = MPT3_CMD_PENDING; 7675 mpi_request = mpt3sas_base_get_msg_frame(ioc, smid); 7676 ioc->port_enable_cmds.smid = smid; 7677 memset(mpi_request, 0, sizeof(Mpi2PortEnableRequest_t)); 7678 mpi_request->Function = MPI2_FUNCTION_PORT_ENABLE; 7679 7680 init_completion(&ioc->port_enable_cmds.done); 7681 ioc->put_smid_default(ioc, smid); 7682 wait_for_completion_timeout(&ioc->port_enable_cmds.done, 300*HZ); 7683 if (!(ioc->port_enable_cmds.status & MPT3_CMD_COMPLETE)) { 7684 ioc_err(ioc, "%s: timeout\n", __func__); 7685 _debug_dump_mf(mpi_request, 7686 sizeof(Mpi2PortEnableRequest_t)/4); 7687 if (ioc->port_enable_cmds.status & MPT3_CMD_RESET) 7688 r = -EFAULT; 7689 else 7690 r = -ETIME; 7691 goto out; 7692 } 7693 7694 mpi_reply = ioc->port_enable_cmds.reply; 7695 ioc_status = le16_to_cpu(mpi_reply->IOCStatus) & MPI2_IOCSTATUS_MASK; 7696 if (ioc_status != MPI2_IOCSTATUS_SUCCESS) { 7697 ioc_err(ioc, "%s: failed with (ioc_status=0x%08x)\n", 7698 __func__, ioc_status); 7699 r = -EFAULT; 7700 goto out; 7701 } 7702 7703 out: 7704 ioc->port_enable_cmds.status = MPT3_CMD_NOT_USED; 7705 ioc_info(ioc, "port enable: %s\n", r == 0 ? "SUCCESS" : "FAILED"); 7706 return r; 7707 } 7708 7709 /** 7710 * mpt3sas_port_enable - initiate firmware discovery (don't wait for reply) 7711 * @ioc: per adapter object 7712 * 7713 * Return: 0 for success, non-zero for failure. 7714 */ 7715 int 7716 mpt3sas_port_enable(struct MPT3SAS_ADAPTER *ioc) 7717 { 7718 Mpi2PortEnableRequest_t *mpi_request; 7719 u16 smid; 7720 7721 ioc_info(ioc, "sending port enable !!\n"); 7722 7723 if (ioc->port_enable_cmds.status & MPT3_CMD_PENDING) { 7724 ioc_err(ioc, "%s: internal command already in use\n", __func__); 7725 return -EAGAIN; 7726 } 7727 7728 smid = mpt3sas_base_get_smid(ioc, ioc->port_enable_cb_idx); 7729 if (!smid) { 7730 ioc_err(ioc, "%s: failed obtaining a smid\n", __func__); 7731 return -EAGAIN; 7732 } 7733 ioc->drv_internal_flags |= MPT_DRV_INTERNAL_FIRST_PE_ISSUED; 7734 ioc->port_enable_cmds.status = MPT3_CMD_PENDING; 7735 ioc->port_enable_cmds.status |= MPT3_CMD_COMPLETE_ASYNC; 7736 mpi_request = mpt3sas_base_get_msg_frame(ioc, smid); 7737 ioc->port_enable_cmds.smid = smid; 7738 memset(mpi_request, 0, sizeof(Mpi2PortEnableRequest_t)); 7739 mpi_request->Function = MPI2_FUNCTION_PORT_ENABLE; 7740 7741 ioc->put_smid_default(ioc, smid); 7742 return 0; 7743 } 7744 7745 /** 7746 * _base_determine_wait_on_discovery - desposition 7747 * @ioc: per adapter object 7748 * 7749 * Decide whether to wait on discovery to complete. Used to either 7750 * locate boot device, or report volumes ahead of physical devices. 7751 * 7752 * Return: 1 for wait, 0 for don't wait. 7753 */ 7754 static int 7755 _base_determine_wait_on_discovery(struct MPT3SAS_ADAPTER *ioc) 7756 { 7757 /* We wait for discovery to complete if IR firmware is loaded. 7758 * The sas topology events arrive before PD events, so we need time to 7759 * turn on the bit in ioc->pd_handles to indicate PD 7760 * Also, it maybe required to report Volumes ahead of physical 7761 * devices when MPI2_IOCPAGE8_IRFLAGS_LOW_VOLUME_MAPPING is set. 7762 */ 7763 if (ioc->ir_firmware) 7764 return 1; 7765 7766 /* if no Bios, then we don't need to wait */ 7767 if (!ioc->bios_pg3.BiosVersion) 7768 return 0; 7769 7770 /* Bios is present, then we drop down here. 7771 * 7772 * If there any entries in the Bios Page 2, then we wait 7773 * for discovery to complete. 7774 */ 7775 7776 /* Current Boot Device */ 7777 if ((ioc->bios_pg2.CurrentBootDeviceForm & 7778 MPI2_BIOSPAGE2_FORM_MASK) == 7779 MPI2_BIOSPAGE2_FORM_NO_DEVICE_SPECIFIED && 7780 /* Request Boot Device */ 7781 (ioc->bios_pg2.ReqBootDeviceForm & 7782 MPI2_BIOSPAGE2_FORM_MASK) == 7783 MPI2_BIOSPAGE2_FORM_NO_DEVICE_SPECIFIED && 7784 /* Alternate Request Boot Device */ 7785 (ioc->bios_pg2.ReqAltBootDeviceForm & 7786 MPI2_BIOSPAGE2_FORM_MASK) == 7787 MPI2_BIOSPAGE2_FORM_NO_DEVICE_SPECIFIED) 7788 return 0; 7789 7790 return 1; 7791 } 7792 7793 /** 7794 * _base_unmask_events - turn on notification for this event 7795 * @ioc: per adapter object 7796 * @event: firmware event 7797 * 7798 * The mask is stored in ioc->event_masks. 7799 */ 7800 static void 7801 _base_unmask_events(struct MPT3SAS_ADAPTER *ioc, u16 event) 7802 { 7803 u32 desired_event; 7804 7805 if (event >= 128) 7806 return; 7807 7808 desired_event = (1 << (event % 32)); 7809 7810 if (event < 32) 7811 ioc->event_masks[0] &= ~desired_event; 7812 else if (event < 64) 7813 ioc->event_masks[1] &= ~desired_event; 7814 else if (event < 96) 7815 ioc->event_masks[2] &= ~desired_event; 7816 else if (event < 128) 7817 ioc->event_masks[3] &= ~desired_event; 7818 } 7819 7820 /** 7821 * _base_event_notification - send event notification 7822 * @ioc: per adapter object 7823 * 7824 * Return: 0 for success, non-zero for failure. 7825 */ 7826 static int 7827 _base_event_notification(struct MPT3SAS_ADAPTER *ioc) 7828 { 7829 Mpi2EventNotificationRequest_t *mpi_request; 7830 u16 smid; 7831 int r = 0; 7832 int i, issue_diag_reset = 0; 7833 7834 dinitprintk(ioc, ioc_info(ioc, "%s\n", __func__)); 7835 7836 if (ioc->base_cmds.status & MPT3_CMD_PENDING) { 7837 ioc_err(ioc, "%s: internal command already in use\n", __func__); 7838 return -EAGAIN; 7839 } 7840 7841 smid = mpt3sas_base_get_smid(ioc, ioc->base_cb_idx); 7842 if (!smid) { 7843 ioc_err(ioc, "%s: failed obtaining a smid\n", __func__); 7844 return -EAGAIN; 7845 } 7846 ioc->base_cmds.status = MPT3_CMD_PENDING; 7847 mpi_request = mpt3sas_base_get_msg_frame(ioc, smid); 7848 ioc->base_cmds.smid = smid; 7849 memset(mpi_request, 0, sizeof(Mpi2EventNotificationRequest_t)); 7850 mpi_request->Function = MPI2_FUNCTION_EVENT_NOTIFICATION; 7851 mpi_request->VF_ID = 0; /* TODO */ 7852 mpi_request->VP_ID = 0; 7853 for (i = 0; i < MPI2_EVENT_NOTIFY_EVENTMASK_WORDS; i++) 7854 mpi_request->EventMasks[i] = 7855 cpu_to_le32(ioc->event_masks[i]); 7856 init_completion(&ioc->base_cmds.done); 7857 ioc->put_smid_default(ioc, smid); 7858 wait_for_completion_timeout(&ioc->base_cmds.done, 30*HZ); 7859 if (!(ioc->base_cmds.status & MPT3_CMD_COMPLETE)) { 7860 ioc_err(ioc, "%s: timeout\n", __func__); 7861 _debug_dump_mf(mpi_request, 7862 sizeof(Mpi2EventNotificationRequest_t)/4); 7863 if (ioc->base_cmds.status & MPT3_CMD_RESET) 7864 r = -EFAULT; 7865 else 7866 issue_diag_reset = 1; 7867 7868 } else 7869 dinitprintk(ioc, ioc_info(ioc, "%s: complete\n", __func__)); 7870 ioc->base_cmds.status = MPT3_CMD_NOT_USED; 7871 7872 if (issue_diag_reset) { 7873 if (ioc->drv_internal_flags & MPT_DRV_INTERNAL_FIRST_PE_ISSUED) 7874 return -EFAULT; 7875 if (mpt3sas_base_check_for_fault_and_issue_reset(ioc)) 7876 return -EFAULT; 7877 r = -EAGAIN; 7878 } 7879 return r; 7880 } 7881 7882 /** 7883 * mpt3sas_base_validate_event_type - validating event types 7884 * @ioc: per adapter object 7885 * @event_type: firmware event 7886 * 7887 * This will turn on firmware event notification when application 7888 * ask for that event. We don't mask events that are already enabled. 7889 */ 7890 void 7891 mpt3sas_base_validate_event_type(struct MPT3SAS_ADAPTER *ioc, u32 *event_type) 7892 { 7893 int i, j; 7894 u32 event_mask, desired_event; 7895 u8 send_update_to_fw; 7896 7897 for (i = 0, send_update_to_fw = 0; i < 7898 MPI2_EVENT_NOTIFY_EVENTMASK_WORDS; i++) { 7899 event_mask = ~event_type[i]; 7900 desired_event = 1; 7901 for (j = 0; j < 32; j++) { 7902 if (!(event_mask & desired_event) && 7903 (ioc->event_masks[i] & desired_event)) { 7904 ioc->event_masks[i] &= ~desired_event; 7905 send_update_to_fw = 1; 7906 } 7907 desired_event = (desired_event << 1); 7908 } 7909 } 7910 7911 if (!send_update_to_fw) 7912 return; 7913 7914 mutex_lock(&ioc->base_cmds.mutex); 7915 _base_event_notification(ioc); 7916 mutex_unlock(&ioc->base_cmds.mutex); 7917 } 7918 7919 /** 7920 * _base_diag_reset - the "big hammer" start of day reset 7921 * @ioc: per adapter object 7922 * 7923 * Return: 0 for success, non-zero for failure. 7924 */ 7925 static int 7926 _base_diag_reset(struct MPT3SAS_ADAPTER *ioc) 7927 { 7928 u32 host_diagnostic; 7929 u32 ioc_state; 7930 u32 count; 7931 u32 hcb_size; 7932 7933 ioc_info(ioc, "sending diag reset !!\n"); 7934 7935 pci_cfg_access_lock(ioc->pdev); 7936 7937 drsprintk(ioc, ioc_info(ioc, "clear interrupts\n")); 7938 7939 count = 0; 7940 do { 7941 /* Write magic sequence to WriteSequence register 7942 * Loop until in diagnostic mode 7943 */ 7944 drsprintk(ioc, ioc_info(ioc, "write magic sequence\n")); 7945 writel(MPI2_WRSEQ_FLUSH_KEY_VALUE, &ioc->chip->WriteSequence); 7946 writel(MPI2_WRSEQ_1ST_KEY_VALUE, &ioc->chip->WriteSequence); 7947 writel(MPI2_WRSEQ_2ND_KEY_VALUE, &ioc->chip->WriteSequence); 7948 writel(MPI2_WRSEQ_3RD_KEY_VALUE, &ioc->chip->WriteSequence); 7949 writel(MPI2_WRSEQ_4TH_KEY_VALUE, &ioc->chip->WriteSequence); 7950 writel(MPI2_WRSEQ_5TH_KEY_VALUE, &ioc->chip->WriteSequence); 7951 writel(MPI2_WRSEQ_6TH_KEY_VALUE, &ioc->chip->WriteSequence); 7952 7953 /* wait 100 msec */ 7954 msleep(100); 7955 7956 if (count++ > 20) { 7957 ioc_info(ioc, 7958 "Stop writing magic sequence after 20 retries\n"); 7959 _base_dump_reg_set(ioc); 7960 goto out; 7961 } 7962 7963 host_diagnostic = ioc->base_readl(&ioc->chip->HostDiagnostic); 7964 drsprintk(ioc, 7965 ioc_info(ioc, "wrote magic sequence: count(%d), host_diagnostic(0x%08x)\n", 7966 count, host_diagnostic)); 7967 7968 } while ((host_diagnostic & MPI2_DIAG_DIAG_WRITE_ENABLE) == 0); 7969 7970 hcb_size = ioc->base_readl(&ioc->chip->HCBSize); 7971 7972 drsprintk(ioc, ioc_info(ioc, "diag reset: issued\n")); 7973 writel(host_diagnostic | MPI2_DIAG_RESET_ADAPTER, 7974 &ioc->chip->HostDiagnostic); 7975 7976 /*This delay allows the chip PCIe hardware time to finish reset tasks*/ 7977 msleep(MPI2_HARD_RESET_PCIE_FIRST_READ_DELAY_MICRO_SEC/1000); 7978 7979 /* Approximately 300 second max wait */ 7980 for (count = 0; count < (300000000 / 7981 MPI2_HARD_RESET_PCIE_SECOND_READ_DELAY_MICRO_SEC); count++) { 7982 7983 host_diagnostic = ioc->base_readl(&ioc->chip->HostDiagnostic); 7984 7985 if (host_diagnostic == 0xFFFFFFFF) { 7986 ioc_info(ioc, 7987 "Invalid host diagnostic register value\n"); 7988 _base_dump_reg_set(ioc); 7989 goto out; 7990 } 7991 if (!(host_diagnostic & MPI2_DIAG_RESET_ADAPTER)) 7992 break; 7993 7994 msleep(MPI2_HARD_RESET_PCIE_SECOND_READ_DELAY_MICRO_SEC / 1000); 7995 } 7996 7997 if (host_diagnostic & MPI2_DIAG_HCB_MODE) { 7998 7999 drsprintk(ioc, 8000 ioc_info(ioc, "restart the adapter assuming the HCB Address points to good F/W\n")); 8001 host_diagnostic &= ~MPI2_DIAG_BOOT_DEVICE_SELECT_MASK; 8002 host_diagnostic |= MPI2_DIAG_BOOT_DEVICE_SELECT_HCDW; 8003 writel(host_diagnostic, &ioc->chip->HostDiagnostic); 8004 8005 drsprintk(ioc, ioc_info(ioc, "re-enable the HCDW\n")); 8006 writel(hcb_size | MPI2_HCB_SIZE_HCB_ENABLE, 8007 &ioc->chip->HCBSize); 8008 } 8009 8010 drsprintk(ioc, ioc_info(ioc, "restart the adapter\n")); 8011 writel(host_diagnostic & ~MPI2_DIAG_HOLD_IOC_RESET, 8012 &ioc->chip->HostDiagnostic); 8013 8014 drsprintk(ioc, 8015 ioc_info(ioc, "disable writes to the diagnostic register\n")); 8016 writel(MPI2_WRSEQ_FLUSH_KEY_VALUE, &ioc->chip->WriteSequence); 8017 8018 drsprintk(ioc, ioc_info(ioc, "Wait for FW to go to the READY state\n")); 8019 ioc_state = _base_wait_on_iocstate(ioc, MPI2_IOC_STATE_READY, 20); 8020 if (ioc_state) { 8021 ioc_err(ioc, "%s: failed going to ready state (ioc_state=0x%x)\n", 8022 __func__, ioc_state); 8023 _base_dump_reg_set(ioc); 8024 goto out; 8025 } 8026 8027 pci_cfg_access_unlock(ioc->pdev); 8028 ioc_info(ioc, "diag reset: SUCCESS\n"); 8029 return 0; 8030 8031 out: 8032 pci_cfg_access_unlock(ioc->pdev); 8033 ioc_err(ioc, "diag reset: FAILED\n"); 8034 return -EFAULT; 8035 } 8036 8037 /** 8038 * mpt3sas_base_make_ioc_ready - put controller in READY state 8039 * @ioc: per adapter object 8040 * @type: FORCE_BIG_HAMMER or SOFT_RESET 8041 * 8042 * Return: 0 for success, non-zero for failure. 8043 */ 8044 int 8045 mpt3sas_base_make_ioc_ready(struct MPT3SAS_ADAPTER *ioc, enum reset_type type) 8046 { 8047 u32 ioc_state; 8048 int rc; 8049 int count; 8050 8051 dinitprintk(ioc, ioc_info(ioc, "%s\n", __func__)); 8052 8053 if (ioc->pci_error_recovery) 8054 return 0; 8055 8056 ioc_state = mpt3sas_base_get_iocstate(ioc, 0); 8057 dhsprintk(ioc, 8058 ioc_info(ioc, "%s: ioc_state(0x%08x)\n", 8059 __func__, ioc_state)); 8060 8061 /* if in RESET state, it should move to READY state shortly */ 8062 count = 0; 8063 if ((ioc_state & MPI2_IOC_STATE_MASK) == MPI2_IOC_STATE_RESET) { 8064 while ((ioc_state & MPI2_IOC_STATE_MASK) != 8065 MPI2_IOC_STATE_READY) { 8066 if (count++ == 10) { 8067 ioc_err(ioc, "%s: failed going to ready state (ioc_state=0x%x)\n", 8068 __func__, ioc_state); 8069 return -EFAULT; 8070 } 8071 ssleep(1); 8072 ioc_state = mpt3sas_base_get_iocstate(ioc, 0); 8073 } 8074 } 8075 8076 if ((ioc_state & MPI2_IOC_STATE_MASK) == MPI2_IOC_STATE_READY) 8077 return 0; 8078 8079 if (ioc_state & MPI2_DOORBELL_USED) { 8080 ioc_info(ioc, "unexpected doorbell active!\n"); 8081 goto issue_diag_reset; 8082 } 8083 8084 if ((ioc_state & MPI2_IOC_STATE_MASK) == MPI2_IOC_STATE_FAULT) { 8085 mpt3sas_print_fault_code(ioc, ioc_state & 8086 MPI2_DOORBELL_DATA_MASK); 8087 goto issue_diag_reset; 8088 } 8089 8090 if ((ioc_state & MPI2_IOC_STATE_MASK) == MPI2_IOC_STATE_COREDUMP) { 8091 /* 8092 * if host reset is invoked while watch dog thread is waiting 8093 * for IOC state to be changed to Fault state then driver has 8094 * to wait here for CoreDump state to clear otherwise reset 8095 * will be issued to the FW and FW move the IOC state to 8096 * reset state without copying the FW logs to coredump region. 8097 */ 8098 if (ioc->ioc_coredump_loop != MPT3SAS_COREDUMP_LOOP_DONE) { 8099 mpt3sas_print_coredump_info(ioc, ioc_state & 8100 MPI2_DOORBELL_DATA_MASK); 8101 mpt3sas_base_wait_for_coredump_completion(ioc, 8102 __func__); 8103 } 8104 goto issue_diag_reset; 8105 } 8106 8107 if (type == FORCE_BIG_HAMMER) 8108 goto issue_diag_reset; 8109 8110 if ((ioc_state & MPI2_IOC_STATE_MASK) == MPI2_IOC_STATE_OPERATIONAL) 8111 if (!(_base_send_ioc_reset(ioc, 8112 MPI2_FUNCTION_IOC_MESSAGE_UNIT_RESET, 15))) { 8113 return 0; 8114 } 8115 8116 issue_diag_reset: 8117 rc = _base_diag_reset(ioc); 8118 return rc; 8119 } 8120 8121 /** 8122 * _base_make_ioc_operational - put controller in OPERATIONAL state 8123 * @ioc: per adapter object 8124 * 8125 * Return: 0 for success, non-zero for failure. 8126 */ 8127 static int 8128 _base_make_ioc_operational(struct MPT3SAS_ADAPTER *ioc) 8129 { 8130 int r, i, index, rc; 8131 unsigned long flags; 8132 u32 reply_address; 8133 u16 smid; 8134 struct _tr_list *delayed_tr, *delayed_tr_next; 8135 struct _sc_list *delayed_sc, *delayed_sc_next; 8136 struct _event_ack_list *delayed_event_ack, *delayed_event_ack_next; 8137 u8 hide_flag; 8138 struct adapter_reply_queue *reply_q; 8139 Mpi2ReplyDescriptorsUnion_t *reply_post_free_contig; 8140 8141 dinitprintk(ioc, ioc_info(ioc, "%s\n", __func__)); 8142 8143 /* clean the delayed target reset list */ 8144 list_for_each_entry_safe(delayed_tr, delayed_tr_next, 8145 &ioc->delayed_tr_list, list) { 8146 list_del(&delayed_tr->list); 8147 kfree(delayed_tr); 8148 } 8149 8150 8151 list_for_each_entry_safe(delayed_tr, delayed_tr_next, 8152 &ioc->delayed_tr_volume_list, list) { 8153 list_del(&delayed_tr->list); 8154 kfree(delayed_tr); 8155 } 8156 8157 list_for_each_entry_safe(delayed_sc, delayed_sc_next, 8158 &ioc->delayed_sc_list, list) { 8159 list_del(&delayed_sc->list); 8160 kfree(delayed_sc); 8161 } 8162 8163 list_for_each_entry_safe(delayed_event_ack, delayed_event_ack_next, 8164 &ioc->delayed_event_ack_list, list) { 8165 list_del(&delayed_event_ack->list); 8166 kfree(delayed_event_ack); 8167 } 8168 8169 spin_lock_irqsave(&ioc->scsi_lookup_lock, flags); 8170 8171 /* hi-priority queue */ 8172 INIT_LIST_HEAD(&ioc->hpr_free_list); 8173 smid = ioc->hi_priority_smid; 8174 for (i = 0; i < ioc->hi_priority_depth; i++, smid++) { 8175 ioc->hpr_lookup[i].cb_idx = 0xFF; 8176 ioc->hpr_lookup[i].smid = smid; 8177 list_add_tail(&ioc->hpr_lookup[i].tracker_list, 8178 &ioc->hpr_free_list); 8179 } 8180 8181 /* internal queue */ 8182 INIT_LIST_HEAD(&ioc->internal_free_list); 8183 smid = ioc->internal_smid; 8184 for (i = 0; i < ioc->internal_depth; i++, smid++) { 8185 ioc->internal_lookup[i].cb_idx = 0xFF; 8186 ioc->internal_lookup[i].smid = smid; 8187 list_add_tail(&ioc->internal_lookup[i].tracker_list, 8188 &ioc->internal_free_list); 8189 } 8190 8191 spin_unlock_irqrestore(&ioc->scsi_lookup_lock, flags); 8192 8193 /* initialize Reply Free Queue */ 8194 for (i = 0, reply_address = (u32)ioc->reply_dma ; 8195 i < ioc->reply_free_queue_depth ; i++, reply_address += 8196 ioc->reply_sz) { 8197 ioc->reply_free[i] = cpu_to_le32(reply_address); 8198 if (ioc->is_mcpu_endpoint) 8199 _base_clone_reply_to_sys_mem(ioc, 8200 reply_address, i); 8201 } 8202 8203 /* initialize reply queues */ 8204 if (ioc->is_driver_loading) 8205 _base_assign_reply_queues(ioc); 8206 8207 /* initialize Reply Post Free Queue */ 8208 index = 0; 8209 reply_post_free_contig = ioc->reply_post[0].reply_post_free; 8210 list_for_each_entry(reply_q, &ioc->reply_queue_list, list) { 8211 /* 8212 * If RDPQ is enabled, switch to the next allocation. 8213 * Otherwise advance within the contiguous region. 8214 */ 8215 if (ioc->rdpq_array_enable) { 8216 reply_q->reply_post_free = 8217 ioc->reply_post[index++].reply_post_free; 8218 } else { 8219 reply_q->reply_post_free = reply_post_free_contig; 8220 reply_post_free_contig += ioc->reply_post_queue_depth; 8221 } 8222 8223 reply_q->reply_post_host_index = 0; 8224 for (i = 0; i < ioc->reply_post_queue_depth; i++) 8225 reply_q->reply_post_free[i].Words = 8226 cpu_to_le64(ULLONG_MAX); 8227 if (!_base_is_controller_msix_enabled(ioc)) 8228 goto skip_init_reply_post_free_queue; 8229 } 8230 skip_init_reply_post_free_queue: 8231 8232 r = _base_send_ioc_init(ioc); 8233 if (r) { 8234 /* 8235 * No need to check IOC state for fault state & issue 8236 * diag reset during host reset. This check is need 8237 * only during driver load time. 8238 */ 8239 if (!ioc->is_driver_loading) 8240 return r; 8241 8242 rc = mpt3sas_base_check_for_fault_and_issue_reset(ioc); 8243 if (rc || (_base_send_ioc_init(ioc))) 8244 return r; 8245 } 8246 8247 /* initialize reply free host index */ 8248 ioc->reply_free_host_index = ioc->reply_free_queue_depth - 1; 8249 writel(ioc->reply_free_host_index, &ioc->chip->ReplyFreeHostIndex); 8250 8251 /* initialize reply post host index */ 8252 list_for_each_entry(reply_q, &ioc->reply_queue_list, list) { 8253 if (ioc->combined_reply_queue) 8254 writel((reply_q->msix_index & 7)<< 8255 MPI2_RPHI_MSIX_INDEX_SHIFT, 8256 ioc->replyPostRegisterIndex[reply_q->msix_index/8]); 8257 else 8258 writel(reply_q->msix_index << 8259 MPI2_RPHI_MSIX_INDEX_SHIFT, 8260 &ioc->chip->ReplyPostHostIndex); 8261 8262 if (!_base_is_controller_msix_enabled(ioc)) 8263 goto skip_init_reply_post_host_index; 8264 } 8265 8266 skip_init_reply_post_host_index: 8267 8268 mpt3sas_base_unmask_interrupts(ioc); 8269 8270 if (ioc->hba_mpi_version_belonged != MPI2_VERSION) { 8271 r = _base_display_fwpkg_version(ioc); 8272 if (r) 8273 return r; 8274 } 8275 8276 r = _base_static_config_pages(ioc); 8277 if (r) 8278 return r; 8279 8280 r = _base_event_notification(ioc); 8281 if (r) 8282 return r; 8283 8284 if (!ioc->shost_recovery) { 8285 8286 if (ioc->is_warpdrive && ioc->manu_pg10.OEMIdentifier 8287 == 0x80) { 8288 hide_flag = (u8) ( 8289 le32_to_cpu(ioc->manu_pg10.OEMSpecificFlags0) & 8290 MFG_PAGE10_HIDE_SSDS_MASK); 8291 if (hide_flag != MFG_PAGE10_HIDE_SSDS_MASK) 8292 ioc->mfg_pg10_hide_flag = hide_flag; 8293 } 8294 8295 ioc->wait_for_discovery_to_complete = 8296 _base_determine_wait_on_discovery(ioc); 8297 8298 return r; /* scan_start and scan_finished support */ 8299 } 8300 8301 r = _base_send_port_enable(ioc); 8302 if (r) 8303 return r; 8304 8305 return r; 8306 } 8307 8308 /** 8309 * mpt3sas_base_free_resources - free resources controller resources 8310 * @ioc: per adapter object 8311 */ 8312 void 8313 mpt3sas_base_free_resources(struct MPT3SAS_ADAPTER *ioc) 8314 { 8315 dexitprintk(ioc, ioc_info(ioc, "%s\n", __func__)); 8316 8317 /* synchronizing freeing resource with pci_access_mutex lock */ 8318 mutex_lock(&ioc->pci_access_mutex); 8319 if (ioc->chip_phys && ioc->chip) { 8320 mpt3sas_base_mask_interrupts(ioc); 8321 ioc->shost_recovery = 1; 8322 mpt3sas_base_make_ioc_ready(ioc, SOFT_RESET); 8323 ioc->shost_recovery = 0; 8324 } 8325 8326 mpt3sas_base_unmap_resources(ioc); 8327 mutex_unlock(&ioc->pci_access_mutex); 8328 return; 8329 } 8330 8331 /** 8332 * mpt3sas_base_attach - attach controller instance 8333 * @ioc: per adapter object 8334 * 8335 * Return: 0 for success, non-zero for failure. 8336 */ 8337 int 8338 mpt3sas_base_attach(struct MPT3SAS_ADAPTER *ioc) 8339 { 8340 int r, i, rc; 8341 int cpu_id, last_cpu_id = 0; 8342 8343 dinitprintk(ioc, ioc_info(ioc, "%s\n", __func__)); 8344 8345 /* setup cpu_msix_table */ 8346 ioc->cpu_count = num_online_cpus(); 8347 for_each_online_cpu(cpu_id) 8348 last_cpu_id = cpu_id; 8349 ioc->cpu_msix_table_sz = last_cpu_id + 1; 8350 ioc->cpu_msix_table = kzalloc(ioc->cpu_msix_table_sz, GFP_KERNEL); 8351 ioc->reply_queue_count = 1; 8352 if (!ioc->cpu_msix_table) { 8353 ioc_info(ioc, "Allocation for cpu_msix_table failed!!!\n"); 8354 r = -ENOMEM; 8355 goto out_free_resources; 8356 } 8357 8358 if (ioc->is_warpdrive) { 8359 ioc->reply_post_host_index = kcalloc(ioc->cpu_msix_table_sz, 8360 sizeof(resource_size_t *), GFP_KERNEL); 8361 if (!ioc->reply_post_host_index) { 8362 ioc_info(ioc, "Allocation for reply_post_host_index failed!!!\n"); 8363 r = -ENOMEM; 8364 goto out_free_resources; 8365 } 8366 } 8367 8368 ioc->smp_affinity_enable = smp_affinity_enable; 8369 8370 ioc->rdpq_array_enable_assigned = 0; 8371 ioc->use_32bit_dma = false; 8372 ioc->dma_mask = 64; 8373 if (ioc->is_aero_ioc) 8374 ioc->base_readl = &_base_readl_aero; 8375 else 8376 ioc->base_readl = &_base_readl; 8377 r = mpt3sas_base_map_resources(ioc); 8378 if (r) 8379 goto out_free_resources; 8380 8381 pci_set_drvdata(ioc->pdev, ioc->shost); 8382 r = _base_get_ioc_facts(ioc); 8383 if (r) { 8384 rc = mpt3sas_base_check_for_fault_and_issue_reset(ioc); 8385 if (rc || (_base_get_ioc_facts(ioc))) 8386 goto out_free_resources; 8387 } 8388 8389 switch (ioc->hba_mpi_version_belonged) { 8390 case MPI2_VERSION: 8391 ioc->build_sg_scmd = &_base_build_sg_scmd; 8392 ioc->build_sg = &_base_build_sg; 8393 ioc->build_zero_len_sge = &_base_build_zero_len_sge; 8394 ioc->get_msix_index_for_smlio = &_base_get_msix_index; 8395 break; 8396 case MPI25_VERSION: 8397 case MPI26_VERSION: 8398 /* 8399 * In SAS3.0, 8400 * SCSI_IO, SMP_PASSTHRU, SATA_PASSTHRU, Target Assist, and 8401 * Target Status - all require the IEEE formatted scatter gather 8402 * elements. 8403 */ 8404 ioc->build_sg_scmd = &_base_build_sg_scmd_ieee; 8405 ioc->build_sg = &_base_build_sg_ieee; 8406 ioc->build_nvme_prp = &_base_build_nvme_prp; 8407 ioc->build_zero_len_sge = &_base_build_zero_len_sge_ieee; 8408 ioc->sge_size_ieee = sizeof(Mpi2IeeeSgeSimple64_t); 8409 if (ioc->high_iops_queues) 8410 ioc->get_msix_index_for_smlio = 8411 &_base_get_high_iops_msix_index; 8412 else 8413 ioc->get_msix_index_for_smlio = &_base_get_msix_index; 8414 break; 8415 } 8416 if (ioc->atomic_desc_capable) { 8417 ioc->put_smid_default = &_base_put_smid_default_atomic; 8418 ioc->put_smid_scsi_io = &_base_put_smid_scsi_io_atomic; 8419 ioc->put_smid_fast_path = 8420 &_base_put_smid_fast_path_atomic; 8421 ioc->put_smid_hi_priority = 8422 &_base_put_smid_hi_priority_atomic; 8423 } else { 8424 ioc->put_smid_default = &_base_put_smid_default; 8425 ioc->put_smid_fast_path = &_base_put_smid_fast_path; 8426 ioc->put_smid_hi_priority = &_base_put_smid_hi_priority; 8427 if (ioc->is_mcpu_endpoint) 8428 ioc->put_smid_scsi_io = 8429 &_base_put_smid_mpi_ep_scsi_io; 8430 else 8431 ioc->put_smid_scsi_io = &_base_put_smid_scsi_io; 8432 } 8433 /* 8434 * These function pointers for other requests that don't 8435 * the require IEEE scatter gather elements. 8436 * 8437 * For example Configuration Pages and SAS IOUNIT Control don't. 8438 */ 8439 ioc->build_sg_mpi = &_base_build_sg; 8440 ioc->build_zero_len_sge_mpi = &_base_build_zero_len_sge; 8441 8442 r = mpt3sas_base_make_ioc_ready(ioc, SOFT_RESET); 8443 if (r) 8444 goto out_free_resources; 8445 8446 ioc->pfacts = kcalloc(ioc->facts.NumberOfPorts, 8447 sizeof(struct mpt3sas_port_facts), GFP_KERNEL); 8448 if (!ioc->pfacts) { 8449 r = -ENOMEM; 8450 goto out_free_resources; 8451 } 8452 8453 for (i = 0 ; i < ioc->facts.NumberOfPorts; i++) { 8454 r = _base_get_port_facts(ioc, i); 8455 if (r) { 8456 rc = mpt3sas_base_check_for_fault_and_issue_reset(ioc); 8457 if (rc || (_base_get_port_facts(ioc, i))) 8458 goto out_free_resources; 8459 } 8460 } 8461 8462 r = _base_allocate_memory_pools(ioc); 8463 if (r) 8464 goto out_free_resources; 8465 8466 if (irqpoll_weight > 0) 8467 ioc->thresh_hold = irqpoll_weight; 8468 else 8469 ioc->thresh_hold = ioc->hba_queue_depth/4; 8470 8471 _base_init_irqpolls(ioc); 8472 init_waitqueue_head(&ioc->reset_wq); 8473 8474 /* allocate memory pd handle bitmask list */ 8475 ioc->pd_handles_sz = (ioc->facts.MaxDevHandle / 8); 8476 if (ioc->facts.MaxDevHandle % 8) 8477 ioc->pd_handles_sz++; 8478 ioc->pd_handles = kzalloc(ioc->pd_handles_sz, 8479 GFP_KERNEL); 8480 if (!ioc->pd_handles) { 8481 r = -ENOMEM; 8482 goto out_free_resources; 8483 } 8484 ioc->blocking_handles = kzalloc(ioc->pd_handles_sz, 8485 GFP_KERNEL); 8486 if (!ioc->blocking_handles) { 8487 r = -ENOMEM; 8488 goto out_free_resources; 8489 } 8490 8491 /* allocate memory for pending OS device add list */ 8492 ioc->pend_os_device_add_sz = (ioc->facts.MaxDevHandle / 8); 8493 if (ioc->facts.MaxDevHandle % 8) 8494 ioc->pend_os_device_add_sz++; 8495 ioc->pend_os_device_add = kzalloc(ioc->pend_os_device_add_sz, 8496 GFP_KERNEL); 8497 if (!ioc->pend_os_device_add) { 8498 r = -ENOMEM; 8499 goto out_free_resources; 8500 } 8501 8502 ioc->device_remove_in_progress_sz = ioc->pend_os_device_add_sz; 8503 ioc->device_remove_in_progress = 8504 kzalloc(ioc->device_remove_in_progress_sz, GFP_KERNEL); 8505 if (!ioc->device_remove_in_progress) { 8506 r = -ENOMEM; 8507 goto out_free_resources; 8508 } 8509 8510 ioc->fwfault_debug = mpt3sas_fwfault_debug; 8511 8512 /* base internal command bits */ 8513 mutex_init(&ioc->base_cmds.mutex); 8514 ioc->base_cmds.reply = kzalloc(ioc->reply_sz, GFP_KERNEL); 8515 ioc->base_cmds.status = MPT3_CMD_NOT_USED; 8516 8517 /* port_enable command bits */ 8518 ioc->port_enable_cmds.reply = kzalloc(ioc->reply_sz, GFP_KERNEL); 8519 ioc->port_enable_cmds.status = MPT3_CMD_NOT_USED; 8520 8521 /* transport internal command bits */ 8522 ioc->transport_cmds.reply = kzalloc(ioc->reply_sz, GFP_KERNEL); 8523 ioc->transport_cmds.status = MPT3_CMD_NOT_USED; 8524 mutex_init(&ioc->transport_cmds.mutex); 8525 8526 /* scsih internal command bits */ 8527 ioc->scsih_cmds.reply = kzalloc(ioc->reply_sz, GFP_KERNEL); 8528 ioc->scsih_cmds.status = MPT3_CMD_NOT_USED; 8529 mutex_init(&ioc->scsih_cmds.mutex); 8530 8531 /* task management internal command bits */ 8532 ioc->tm_cmds.reply = kzalloc(ioc->reply_sz, GFP_KERNEL); 8533 ioc->tm_cmds.status = MPT3_CMD_NOT_USED; 8534 mutex_init(&ioc->tm_cmds.mutex); 8535 8536 /* config page internal command bits */ 8537 ioc->config_cmds.reply = kzalloc(ioc->reply_sz, GFP_KERNEL); 8538 ioc->config_cmds.status = MPT3_CMD_NOT_USED; 8539 mutex_init(&ioc->config_cmds.mutex); 8540 8541 /* ctl module internal command bits */ 8542 ioc->ctl_cmds.reply = kzalloc(ioc->reply_sz, GFP_KERNEL); 8543 ioc->ctl_cmds.sense = kzalloc(SCSI_SENSE_BUFFERSIZE, GFP_KERNEL); 8544 ioc->ctl_cmds.status = MPT3_CMD_NOT_USED; 8545 mutex_init(&ioc->ctl_cmds.mutex); 8546 8547 if (!ioc->base_cmds.reply || !ioc->port_enable_cmds.reply || 8548 !ioc->transport_cmds.reply || !ioc->scsih_cmds.reply || 8549 !ioc->tm_cmds.reply || !ioc->config_cmds.reply || 8550 !ioc->ctl_cmds.reply || !ioc->ctl_cmds.sense) { 8551 r = -ENOMEM; 8552 goto out_free_resources; 8553 } 8554 8555 for (i = 0; i < MPI2_EVENT_NOTIFY_EVENTMASK_WORDS; i++) 8556 ioc->event_masks[i] = -1; 8557 8558 /* here we enable the events we care about */ 8559 _base_unmask_events(ioc, MPI2_EVENT_SAS_DISCOVERY); 8560 _base_unmask_events(ioc, MPI2_EVENT_SAS_BROADCAST_PRIMITIVE); 8561 _base_unmask_events(ioc, MPI2_EVENT_SAS_TOPOLOGY_CHANGE_LIST); 8562 _base_unmask_events(ioc, MPI2_EVENT_SAS_DEVICE_STATUS_CHANGE); 8563 _base_unmask_events(ioc, MPI2_EVENT_SAS_ENCL_DEVICE_STATUS_CHANGE); 8564 _base_unmask_events(ioc, MPI2_EVENT_IR_CONFIGURATION_CHANGE_LIST); 8565 _base_unmask_events(ioc, MPI2_EVENT_IR_VOLUME); 8566 _base_unmask_events(ioc, MPI2_EVENT_IR_PHYSICAL_DISK); 8567 _base_unmask_events(ioc, MPI2_EVENT_IR_OPERATION_STATUS); 8568 _base_unmask_events(ioc, MPI2_EVENT_LOG_ENTRY_ADDED); 8569 _base_unmask_events(ioc, MPI2_EVENT_TEMP_THRESHOLD); 8570 _base_unmask_events(ioc, MPI2_EVENT_ACTIVE_CABLE_EXCEPTION); 8571 _base_unmask_events(ioc, MPI2_EVENT_SAS_DEVICE_DISCOVERY_ERROR); 8572 if (ioc->hba_mpi_version_belonged == MPI26_VERSION) { 8573 if (ioc->is_gen35_ioc) { 8574 _base_unmask_events(ioc, 8575 MPI2_EVENT_PCIE_DEVICE_STATUS_CHANGE); 8576 _base_unmask_events(ioc, MPI2_EVENT_PCIE_ENUMERATION); 8577 _base_unmask_events(ioc, 8578 MPI2_EVENT_PCIE_TOPOLOGY_CHANGE_LIST); 8579 } 8580 } 8581 r = _base_make_ioc_operational(ioc); 8582 if (r == -EAGAIN) { 8583 r = _base_make_ioc_operational(ioc); 8584 if (r) 8585 goto out_free_resources; 8586 } 8587 8588 /* 8589 * Copy current copy of IOCFacts in prev_fw_facts 8590 * and it will be used during online firmware upgrade. 8591 */ 8592 memcpy(&ioc->prev_fw_facts, &ioc->facts, 8593 sizeof(struct mpt3sas_facts)); 8594 8595 ioc->non_operational_loop = 0; 8596 ioc->ioc_coredump_loop = 0; 8597 ioc->got_task_abort_from_ioctl = 0; 8598 return 0; 8599 8600 out_free_resources: 8601 8602 ioc->remove_host = 1; 8603 8604 mpt3sas_base_free_resources(ioc); 8605 _base_release_memory_pools(ioc); 8606 pci_set_drvdata(ioc->pdev, NULL); 8607 kfree(ioc->cpu_msix_table); 8608 if (ioc->is_warpdrive) 8609 kfree(ioc->reply_post_host_index); 8610 kfree(ioc->pd_handles); 8611 kfree(ioc->blocking_handles); 8612 kfree(ioc->device_remove_in_progress); 8613 kfree(ioc->pend_os_device_add); 8614 kfree(ioc->tm_cmds.reply); 8615 kfree(ioc->transport_cmds.reply); 8616 kfree(ioc->scsih_cmds.reply); 8617 kfree(ioc->config_cmds.reply); 8618 kfree(ioc->base_cmds.reply); 8619 kfree(ioc->port_enable_cmds.reply); 8620 kfree(ioc->ctl_cmds.reply); 8621 kfree(ioc->ctl_cmds.sense); 8622 kfree(ioc->pfacts); 8623 ioc->ctl_cmds.reply = NULL; 8624 ioc->base_cmds.reply = NULL; 8625 ioc->tm_cmds.reply = NULL; 8626 ioc->scsih_cmds.reply = NULL; 8627 ioc->transport_cmds.reply = NULL; 8628 ioc->config_cmds.reply = NULL; 8629 ioc->pfacts = NULL; 8630 return r; 8631 } 8632 8633 8634 /** 8635 * mpt3sas_base_detach - remove controller instance 8636 * @ioc: per adapter object 8637 */ 8638 void 8639 mpt3sas_base_detach(struct MPT3SAS_ADAPTER *ioc) 8640 { 8641 dexitprintk(ioc, ioc_info(ioc, "%s\n", __func__)); 8642 8643 mpt3sas_base_stop_watchdog(ioc); 8644 mpt3sas_base_free_resources(ioc); 8645 _base_release_memory_pools(ioc); 8646 mpt3sas_free_enclosure_list(ioc); 8647 pci_set_drvdata(ioc->pdev, NULL); 8648 kfree(ioc->cpu_msix_table); 8649 if (ioc->is_warpdrive) 8650 kfree(ioc->reply_post_host_index); 8651 kfree(ioc->pd_handles); 8652 kfree(ioc->blocking_handles); 8653 kfree(ioc->device_remove_in_progress); 8654 kfree(ioc->pend_os_device_add); 8655 kfree(ioc->pfacts); 8656 kfree(ioc->ctl_cmds.reply); 8657 kfree(ioc->ctl_cmds.sense); 8658 kfree(ioc->base_cmds.reply); 8659 kfree(ioc->port_enable_cmds.reply); 8660 kfree(ioc->tm_cmds.reply); 8661 kfree(ioc->transport_cmds.reply); 8662 kfree(ioc->scsih_cmds.reply); 8663 kfree(ioc->config_cmds.reply); 8664 } 8665 8666 /** 8667 * _base_pre_reset_handler - pre reset handler 8668 * @ioc: per adapter object 8669 */ 8670 static void _base_pre_reset_handler(struct MPT3SAS_ADAPTER *ioc) 8671 { 8672 mpt3sas_scsih_pre_reset_handler(ioc); 8673 mpt3sas_ctl_pre_reset_handler(ioc); 8674 dtmprintk(ioc, ioc_info(ioc, "%s: MPT3_IOC_PRE_RESET\n", __func__)); 8675 } 8676 8677 /** 8678 * _base_clear_outstanding_mpt_commands - clears outstanding mpt commands 8679 * @ioc: per adapter object 8680 */ 8681 static void 8682 _base_clear_outstanding_mpt_commands(struct MPT3SAS_ADAPTER *ioc) 8683 { 8684 dtmprintk(ioc, 8685 ioc_info(ioc, "%s: clear outstanding mpt cmds\n", __func__)); 8686 if (ioc->transport_cmds.status & MPT3_CMD_PENDING) { 8687 ioc->transport_cmds.status |= MPT3_CMD_RESET; 8688 mpt3sas_base_free_smid(ioc, ioc->transport_cmds.smid); 8689 complete(&ioc->transport_cmds.done); 8690 } 8691 if (ioc->base_cmds.status & MPT3_CMD_PENDING) { 8692 ioc->base_cmds.status |= MPT3_CMD_RESET; 8693 mpt3sas_base_free_smid(ioc, ioc->base_cmds.smid); 8694 complete(&ioc->base_cmds.done); 8695 } 8696 if (ioc->port_enable_cmds.status & MPT3_CMD_PENDING) { 8697 ioc->port_enable_failed = 1; 8698 ioc->port_enable_cmds.status |= MPT3_CMD_RESET; 8699 mpt3sas_base_free_smid(ioc, ioc->port_enable_cmds.smid); 8700 if (ioc->is_driver_loading) { 8701 ioc->start_scan_failed = 8702 MPI2_IOCSTATUS_INTERNAL_ERROR; 8703 ioc->start_scan = 0; 8704 } else { 8705 complete(&ioc->port_enable_cmds.done); 8706 } 8707 } 8708 if (ioc->config_cmds.status & MPT3_CMD_PENDING) { 8709 ioc->config_cmds.status |= MPT3_CMD_RESET; 8710 mpt3sas_base_free_smid(ioc, ioc->config_cmds.smid); 8711 ioc->config_cmds.smid = USHRT_MAX; 8712 complete(&ioc->config_cmds.done); 8713 } 8714 } 8715 8716 /** 8717 * _base_clear_outstanding_commands - clear all outstanding commands 8718 * @ioc: per adapter object 8719 */ 8720 static void _base_clear_outstanding_commands(struct MPT3SAS_ADAPTER *ioc) 8721 { 8722 mpt3sas_scsih_clear_outstanding_scsi_tm_commands(ioc); 8723 mpt3sas_ctl_clear_outstanding_ioctls(ioc); 8724 _base_clear_outstanding_mpt_commands(ioc); 8725 } 8726 8727 /** 8728 * _base_reset_done_handler - reset done handler 8729 * @ioc: per adapter object 8730 */ 8731 static void _base_reset_done_handler(struct MPT3SAS_ADAPTER *ioc) 8732 { 8733 mpt3sas_scsih_reset_done_handler(ioc); 8734 mpt3sas_ctl_reset_done_handler(ioc); 8735 dtmprintk(ioc, ioc_info(ioc, "%s: MPT3_IOC_DONE_RESET\n", __func__)); 8736 } 8737 8738 /** 8739 * mpt3sas_wait_for_commands_to_complete - reset controller 8740 * @ioc: Pointer to MPT_ADAPTER structure 8741 * 8742 * This function is waiting 10s for all pending commands to complete 8743 * prior to putting controller in reset. 8744 */ 8745 void 8746 mpt3sas_wait_for_commands_to_complete(struct MPT3SAS_ADAPTER *ioc) 8747 { 8748 u32 ioc_state; 8749 8750 ioc->pending_io_count = 0; 8751 8752 ioc_state = mpt3sas_base_get_iocstate(ioc, 0); 8753 if ((ioc_state & MPI2_IOC_STATE_MASK) != MPI2_IOC_STATE_OPERATIONAL) 8754 return; 8755 8756 /* pending command count */ 8757 ioc->pending_io_count = scsi_host_busy(ioc->shost); 8758 8759 if (!ioc->pending_io_count) 8760 return; 8761 8762 /* wait for pending commands to complete */ 8763 wait_event_timeout(ioc->reset_wq, ioc->pending_io_count == 0, 10 * HZ); 8764 } 8765 8766 /** 8767 * _base_check_ioc_facts_changes - Look for increase/decrease of IOCFacts 8768 * attributes during online firmware upgrade and update the corresponding 8769 * IOC variables accordingly. 8770 * 8771 * @ioc: Pointer to MPT_ADAPTER structure 8772 */ 8773 static int 8774 _base_check_ioc_facts_changes(struct MPT3SAS_ADAPTER *ioc) 8775 { 8776 u16 pd_handles_sz; 8777 void *pd_handles = NULL, *blocking_handles = NULL; 8778 void *pend_os_device_add = NULL, *device_remove_in_progress = NULL; 8779 struct mpt3sas_facts *old_facts = &ioc->prev_fw_facts; 8780 8781 if (ioc->facts.MaxDevHandle > old_facts->MaxDevHandle) { 8782 pd_handles_sz = (ioc->facts.MaxDevHandle / 8); 8783 if (ioc->facts.MaxDevHandle % 8) 8784 pd_handles_sz++; 8785 8786 pd_handles = krealloc(ioc->pd_handles, pd_handles_sz, 8787 GFP_KERNEL); 8788 if (!pd_handles) { 8789 ioc_info(ioc, 8790 "Unable to allocate the memory for pd_handles of sz: %d\n", 8791 pd_handles_sz); 8792 return -ENOMEM; 8793 } 8794 memset(pd_handles + ioc->pd_handles_sz, 0, 8795 (pd_handles_sz - ioc->pd_handles_sz)); 8796 ioc->pd_handles = pd_handles; 8797 8798 blocking_handles = krealloc(ioc->blocking_handles, 8799 pd_handles_sz, GFP_KERNEL); 8800 if (!blocking_handles) { 8801 ioc_info(ioc, 8802 "Unable to allocate the memory for " 8803 "blocking_handles of sz: %d\n", 8804 pd_handles_sz); 8805 return -ENOMEM; 8806 } 8807 memset(blocking_handles + ioc->pd_handles_sz, 0, 8808 (pd_handles_sz - ioc->pd_handles_sz)); 8809 ioc->blocking_handles = blocking_handles; 8810 ioc->pd_handles_sz = pd_handles_sz; 8811 8812 pend_os_device_add = krealloc(ioc->pend_os_device_add, 8813 pd_handles_sz, GFP_KERNEL); 8814 if (!pend_os_device_add) { 8815 ioc_info(ioc, 8816 "Unable to allocate the memory for pend_os_device_add of sz: %d\n", 8817 pd_handles_sz); 8818 return -ENOMEM; 8819 } 8820 memset(pend_os_device_add + ioc->pend_os_device_add_sz, 0, 8821 (pd_handles_sz - ioc->pend_os_device_add_sz)); 8822 ioc->pend_os_device_add = pend_os_device_add; 8823 ioc->pend_os_device_add_sz = pd_handles_sz; 8824 8825 device_remove_in_progress = krealloc( 8826 ioc->device_remove_in_progress, pd_handles_sz, GFP_KERNEL); 8827 if (!device_remove_in_progress) { 8828 ioc_info(ioc, 8829 "Unable to allocate the memory for " 8830 "device_remove_in_progress of sz: %d\n " 8831 , pd_handles_sz); 8832 return -ENOMEM; 8833 } 8834 memset(device_remove_in_progress + 8835 ioc->device_remove_in_progress_sz, 0, 8836 (pd_handles_sz - ioc->device_remove_in_progress_sz)); 8837 ioc->device_remove_in_progress = device_remove_in_progress; 8838 ioc->device_remove_in_progress_sz = pd_handles_sz; 8839 } 8840 8841 memcpy(&ioc->prev_fw_facts, &ioc->facts, sizeof(struct mpt3sas_facts)); 8842 return 0; 8843 } 8844 8845 /** 8846 * mpt3sas_base_hard_reset_handler - reset controller 8847 * @ioc: Pointer to MPT_ADAPTER structure 8848 * @type: FORCE_BIG_HAMMER or SOFT_RESET 8849 * 8850 * Return: 0 for success, non-zero for failure. 8851 */ 8852 int 8853 mpt3sas_base_hard_reset_handler(struct MPT3SAS_ADAPTER *ioc, 8854 enum reset_type type) 8855 { 8856 int r; 8857 unsigned long flags; 8858 u32 ioc_state; 8859 u8 is_fault = 0, is_trigger = 0; 8860 8861 dtmprintk(ioc, ioc_info(ioc, "%s: enter\n", __func__)); 8862 8863 if (ioc->pci_error_recovery) { 8864 ioc_err(ioc, "%s: pci error recovery reset\n", __func__); 8865 r = 0; 8866 goto out_unlocked; 8867 } 8868 8869 if (mpt3sas_fwfault_debug) 8870 mpt3sas_halt_firmware(ioc); 8871 8872 /* wait for an active reset in progress to complete */ 8873 mutex_lock(&ioc->reset_in_progress_mutex); 8874 8875 spin_lock_irqsave(&ioc->ioc_reset_in_progress_lock, flags); 8876 ioc->shost_recovery = 1; 8877 spin_unlock_irqrestore(&ioc->ioc_reset_in_progress_lock, flags); 8878 8879 if ((ioc->diag_buffer_status[MPI2_DIAG_BUF_TYPE_TRACE] & 8880 MPT3_DIAG_BUFFER_IS_REGISTERED) && 8881 (!(ioc->diag_buffer_status[MPI2_DIAG_BUF_TYPE_TRACE] & 8882 MPT3_DIAG_BUFFER_IS_RELEASED))) { 8883 is_trigger = 1; 8884 ioc_state = mpt3sas_base_get_iocstate(ioc, 0); 8885 if ((ioc_state & MPI2_IOC_STATE_MASK) == MPI2_IOC_STATE_FAULT || 8886 (ioc_state & MPI2_IOC_STATE_MASK) == 8887 MPI2_IOC_STATE_COREDUMP) { 8888 is_fault = 1; 8889 ioc->htb_rel.trigger_info_dwords[1] = 8890 (ioc_state & MPI2_DOORBELL_DATA_MASK); 8891 } 8892 } 8893 _base_pre_reset_handler(ioc); 8894 mpt3sas_wait_for_commands_to_complete(ioc); 8895 mpt3sas_base_mask_interrupts(ioc); 8896 mpt3sas_base_pause_mq_polling(ioc); 8897 r = mpt3sas_base_make_ioc_ready(ioc, type); 8898 if (r) 8899 goto out; 8900 _base_clear_outstanding_commands(ioc); 8901 8902 /* If this hard reset is called while port enable is active, then 8903 * there is no reason to call make_ioc_operational 8904 */ 8905 if (ioc->is_driver_loading && ioc->port_enable_failed) { 8906 ioc->remove_host = 1; 8907 r = -EFAULT; 8908 goto out; 8909 } 8910 r = _base_get_ioc_facts(ioc); 8911 if (r) 8912 goto out; 8913 8914 r = _base_check_ioc_facts_changes(ioc); 8915 if (r) { 8916 ioc_info(ioc, 8917 "Some of the parameters got changed in this new firmware" 8918 " image and it requires system reboot\n"); 8919 goto out; 8920 } 8921 if (ioc->rdpq_array_enable && !ioc->rdpq_array_capable) 8922 panic("%s: Issue occurred with flashing controller firmware." 8923 "Please reboot the system and ensure that the correct" 8924 " firmware version is running\n", ioc->name); 8925 8926 r = _base_make_ioc_operational(ioc); 8927 if (!r) 8928 _base_reset_done_handler(ioc); 8929 8930 out: 8931 ioc_info(ioc, "%s: %s\n", __func__, r == 0 ? "SUCCESS" : "FAILED"); 8932 8933 spin_lock_irqsave(&ioc->ioc_reset_in_progress_lock, flags); 8934 ioc->shost_recovery = 0; 8935 spin_unlock_irqrestore(&ioc->ioc_reset_in_progress_lock, flags); 8936 ioc->ioc_reset_count++; 8937 mutex_unlock(&ioc->reset_in_progress_mutex); 8938 mpt3sas_base_resume_mq_polling(ioc); 8939 8940 out_unlocked: 8941 if ((r == 0) && is_trigger) { 8942 if (is_fault) 8943 mpt3sas_trigger_master(ioc, MASTER_TRIGGER_FW_FAULT); 8944 else 8945 mpt3sas_trigger_master(ioc, 8946 MASTER_TRIGGER_ADAPTER_RESET); 8947 } 8948 dtmprintk(ioc, ioc_info(ioc, "%s: exit\n", __func__)); 8949 return r; 8950 } 8951