1 // SPDX-License-Identifier: GPL-2.0+ 2 /* 3 * SSH request transport layer. 4 * 5 * Copyright (C) 2019-2022 Maximilian Luz <luzmaximilian@gmail.com> 6 */ 7 8 #include <asm/unaligned.h> 9 #include <linux/atomic.h> 10 #include <linux/completion.h> 11 #include <linux/error-injection.h> 12 #include <linux/ktime.h> 13 #include <linux/limits.h> 14 #include <linux/list.h> 15 #include <linux/slab.h> 16 #include <linux/spinlock.h> 17 #include <linux/types.h> 18 #include <linux/workqueue.h> 19 20 #include <linux/surface_aggregator/serial_hub.h> 21 #include <linux/surface_aggregator/controller.h> 22 23 #include "ssh_packet_layer.h" 24 #include "ssh_request_layer.h" 25 26 #include "trace.h" 27 28 /* 29 * SSH_RTL_REQUEST_TIMEOUT - Request timeout. 30 * 31 * Timeout as ktime_t delta for request responses. If we have not received a 32 * response in this time-frame after finishing the underlying packet 33 * transmission, the request will be completed with %-ETIMEDOUT as status 34 * code. 35 */ 36 #define SSH_RTL_REQUEST_TIMEOUT ms_to_ktime(3000) 37 38 /* 39 * SSH_RTL_REQUEST_TIMEOUT_RESOLUTION - Request timeout granularity. 40 * 41 * Time-resolution for timeouts. Should be larger than one jiffy to avoid 42 * direct re-scheduling of reaper work_struct. 43 */ 44 #define SSH_RTL_REQUEST_TIMEOUT_RESOLUTION ms_to_ktime(max(2000 / HZ, 50)) 45 46 /* 47 * SSH_RTL_MAX_PENDING - Maximum number of pending requests. 48 * 49 * Maximum number of requests concurrently waiting to be completed (i.e. 50 * waiting for the corresponding packet transmission to finish if they don't 51 * have a response or waiting for a response if they have one). 52 */ 53 #define SSH_RTL_MAX_PENDING 3 54 55 /* 56 * SSH_RTL_TX_BATCH - Maximum number of requests processed per work execution. 57 * Used to prevent livelocking of the workqueue. Value chosen via educated 58 * guess, may be adjusted. 59 */ 60 #define SSH_RTL_TX_BATCH 10 61 62 #ifdef CONFIG_SURFACE_AGGREGATOR_ERROR_INJECTION 63 64 /** 65 * ssh_rtl_should_drop_response() - Error injection hook to drop request 66 * responses. 67 * 68 * Useful to cause request transmission timeouts in the driver by dropping the 69 * response to a request. 70 */ 71 static noinline bool ssh_rtl_should_drop_response(void) 72 { 73 return false; 74 } 75 ALLOW_ERROR_INJECTION(ssh_rtl_should_drop_response, TRUE); 76 77 #else 78 79 static inline bool ssh_rtl_should_drop_response(void) 80 { 81 return false; 82 } 83 84 #endif 85 86 static u16 ssh_request_get_rqid(struct ssh_request *rqst) 87 { 88 return get_unaligned_le16(rqst->packet.data.ptr 89 + SSH_MSGOFFSET_COMMAND(rqid)); 90 } 91 92 static u32 ssh_request_get_rqid_safe(struct ssh_request *rqst) 93 { 94 if (!rqst->packet.data.ptr) 95 return U32_MAX; 96 97 return ssh_request_get_rqid(rqst); 98 } 99 100 static void ssh_rtl_queue_remove(struct ssh_request *rqst) 101 { 102 struct ssh_rtl *rtl = ssh_request_rtl(rqst); 103 104 spin_lock(&rtl->queue.lock); 105 106 if (!test_and_clear_bit(SSH_REQUEST_SF_QUEUED_BIT, &rqst->state)) { 107 spin_unlock(&rtl->queue.lock); 108 return; 109 } 110 111 list_del(&rqst->node); 112 113 spin_unlock(&rtl->queue.lock); 114 ssh_request_put(rqst); 115 } 116 117 static bool ssh_rtl_queue_empty(struct ssh_rtl *rtl) 118 { 119 bool empty; 120 121 spin_lock(&rtl->queue.lock); 122 empty = list_empty(&rtl->queue.head); 123 spin_unlock(&rtl->queue.lock); 124 125 return empty; 126 } 127 128 static void ssh_rtl_pending_remove(struct ssh_request *rqst) 129 { 130 struct ssh_rtl *rtl = ssh_request_rtl(rqst); 131 132 spin_lock(&rtl->pending.lock); 133 134 if (!test_and_clear_bit(SSH_REQUEST_SF_PENDING_BIT, &rqst->state)) { 135 spin_unlock(&rtl->pending.lock); 136 return; 137 } 138 139 atomic_dec(&rtl->pending.count); 140 list_del(&rqst->node); 141 142 spin_unlock(&rtl->pending.lock); 143 144 ssh_request_put(rqst); 145 } 146 147 static int ssh_rtl_tx_pending_push(struct ssh_request *rqst) 148 { 149 struct ssh_rtl *rtl = ssh_request_rtl(rqst); 150 151 spin_lock(&rtl->pending.lock); 152 153 if (test_bit(SSH_REQUEST_SF_LOCKED_BIT, &rqst->state)) { 154 spin_unlock(&rtl->pending.lock); 155 return -EINVAL; 156 } 157 158 if (test_and_set_bit(SSH_REQUEST_SF_PENDING_BIT, &rqst->state)) { 159 spin_unlock(&rtl->pending.lock); 160 return -EALREADY; 161 } 162 163 atomic_inc(&rtl->pending.count); 164 list_add_tail(&ssh_request_get(rqst)->node, &rtl->pending.head); 165 166 spin_unlock(&rtl->pending.lock); 167 return 0; 168 } 169 170 static void ssh_rtl_complete_with_status(struct ssh_request *rqst, int status) 171 { 172 struct ssh_rtl *rtl = ssh_request_rtl(rqst); 173 174 trace_ssam_request_complete(rqst, status); 175 176 /* rtl/ptl may not be set if we're canceling before submitting. */ 177 rtl_dbg_cond(rtl, "rtl: completing request (rqid: %#06x, status: %d)\n", 178 ssh_request_get_rqid_safe(rqst), status); 179 180 rqst->ops->complete(rqst, NULL, NULL, status); 181 } 182 183 static void ssh_rtl_complete_with_rsp(struct ssh_request *rqst, 184 const struct ssh_command *cmd, 185 const struct ssam_span *data) 186 { 187 struct ssh_rtl *rtl = ssh_request_rtl(rqst); 188 189 trace_ssam_request_complete(rqst, 0); 190 191 rtl_dbg(rtl, "rtl: completing request with response (rqid: %#06x)\n", 192 ssh_request_get_rqid(rqst)); 193 194 rqst->ops->complete(rqst, cmd, data, 0); 195 } 196 197 static bool ssh_rtl_tx_can_process(struct ssh_request *rqst) 198 { 199 struct ssh_rtl *rtl = ssh_request_rtl(rqst); 200 201 if (test_bit(SSH_REQUEST_TY_FLUSH_BIT, &rqst->state)) 202 return !atomic_read(&rtl->pending.count); 203 204 return atomic_read(&rtl->pending.count) < SSH_RTL_MAX_PENDING; 205 } 206 207 static struct ssh_request *ssh_rtl_tx_next(struct ssh_rtl *rtl) 208 { 209 struct ssh_request *rqst = ERR_PTR(-ENOENT); 210 struct ssh_request *p, *n; 211 212 spin_lock(&rtl->queue.lock); 213 214 /* Find first non-locked request and remove it. */ 215 list_for_each_entry_safe(p, n, &rtl->queue.head, node) { 216 if (unlikely(test_bit(SSH_REQUEST_SF_LOCKED_BIT, &p->state))) 217 continue; 218 219 if (!ssh_rtl_tx_can_process(p)) { 220 rqst = ERR_PTR(-EBUSY); 221 break; 222 } 223 224 /* Remove from queue and mark as transmitting. */ 225 set_bit(SSH_REQUEST_SF_TRANSMITTING_BIT, &p->state); 226 /* Ensure state never gets zero. */ 227 smp_mb__before_atomic(); 228 clear_bit(SSH_REQUEST_SF_QUEUED_BIT, &p->state); 229 230 list_del(&p->node); 231 232 rqst = p; 233 break; 234 } 235 236 spin_unlock(&rtl->queue.lock); 237 return rqst; 238 } 239 240 static int ssh_rtl_tx_try_process_one(struct ssh_rtl *rtl) 241 { 242 struct ssh_request *rqst; 243 int status; 244 245 /* Get and prepare next request for transmit. */ 246 rqst = ssh_rtl_tx_next(rtl); 247 if (IS_ERR(rqst)) 248 return PTR_ERR(rqst); 249 250 /* Add it to/mark it as pending. */ 251 status = ssh_rtl_tx_pending_push(rqst); 252 if (status) { 253 ssh_request_put(rqst); 254 return -EAGAIN; 255 } 256 257 /* Submit packet. */ 258 status = ssh_ptl_submit(&rtl->ptl, &rqst->packet); 259 if (status == -ESHUTDOWN) { 260 /* 261 * Packet has been refused due to the packet layer shutting 262 * down. Complete it here. 263 */ 264 set_bit(SSH_REQUEST_SF_LOCKED_BIT, &rqst->state); 265 /* 266 * Note: A barrier is not required here, as there are only two 267 * references in the system at this point: The one that we have, 268 * and the other one that belongs to the pending set. Due to the 269 * request being marked as "transmitting", our process is the 270 * only one allowed to remove the pending node and change the 271 * state. Normally, the task would fall to the packet callback, 272 * but as this is a path where submission failed, this callback 273 * will never be executed. 274 */ 275 276 ssh_rtl_pending_remove(rqst); 277 ssh_rtl_complete_with_status(rqst, -ESHUTDOWN); 278 279 ssh_request_put(rqst); 280 return -ESHUTDOWN; 281 282 } else if (status) { 283 /* 284 * If submitting the packet failed and the packet layer isn't 285 * shutting down, the packet has either been submitted/queued 286 * before (-EALREADY, which cannot happen as we have 287 * guaranteed that requests cannot be re-submitted), or the 288 * packet was marked as locked (-EINVAL). To mark the packet 289 * locked at this stage, the request, and thus the packets 290 * itself, had to have been canceled. Simply drop the 291 * reference. Cancellation itself will remove it from the set 292 * of pending requests. 293 */ 294 295 WARN_ON(status != -EINVAL); 296 297 ssh_request_put(rqst); 298 return -EAGAIN; 299 } 300 301 ssh_request_put(rqst); 302 return 0; 303 } 304 305 static bool ssh_rtl_tx_schedule(struct ssh_rtl *rtl) 306 { 307 if (atomic_read(&rtl->pending.count) >= SSH_RTL_MAX_PENDING) 308 return false; 309 310 if (ssh_rtl_queue_empty(rtl)) 311 return false; 312 313 return schedule_work(&rtl->tx.work); 314 } 315 316 static void ssh_rtl_tx_work_fn(struct work_struct *work) 317 { 318 struct ssh_rtl *rtl = to_ssh_rtl(work, tx.work); 319 unsigned int iterations = SSH_RTL_TX_BATCH; 320 int status; 321 322 /* 323 * Try to be nice and not block/live-lock the workqueue: Run a maximum 324 * of 10 tries, then re-submit if necessary. This should not be 325 * necessary for normal execution, but guarantee it anyway. 326 */ 327 do { 328 status = ssh_rtl_tx_try_process_one(rtl); 329 if (status == -ENOENT || status == -EBUSY) 330 return; /* No more requests to process. */ 331 332 if (status == -ESHUTDOWN) { 333 /* 334 * Packet system shutting down. No new packets can be 335 * transmitted. Return silently, the party initiating 336 * the shutdown should handle the rest. 337 */ 338 return; 339 } 340 341 WARN_ON(status != 0 && status != -EAGAIN); 342 } while (--iterations); 343 344 /* Out of tries, reschedule. */ 345 ssh_rtl_tx_schedule(rtl); 346 } 347 348 /** 349 * ssh_rtl_submit() - Submit a request to the transport layer. 350 * @rtl: The request transport layer. 351 * @rqst: The request to submit. 352 * 353 * Submits a request to the transport layer. A single request may not be 354 * submitted multiple times without reinitializing it. 355 * 356 * Return: Returns zero on success, %-EINVAL if the request type is invalid or 357 * the request has been canceled prior to submission, %-EALREADY if the 358 * request has already been submitted, or %-ESHUTDOWN in case the request 359 * transport layer has been shut down. 360 */ 361 int ssh_rtl_submit(struct ssh_rtl *rtl, struct ssh_request *rqst) 362 { 363 trace_ssam_request_submit(rqst); 364 365 /* 366 * Ensure that requests expecting a response are sequenced. If this 367 * invariant ever changes, see the comment in ssh_rtl_complete() on what 368 * is required to be changed in the code. 369 */ 370 if (test_bit(SSH_REQUEST_TY_HAS_RESPONSE_BIT, &rqst->state)) 371 if (!test_bit(SSH_PACKET_TY_SEQUENCED_BIT, &rqst->packet.state)) 372 return -EINVAL; 373 374 spin_lock(&rtl->queue.lock); 375 376 /* 377 * Try to set ptl and check if this request has already been submitted. 378 * 379 * Must be inside lock as we might run into a lost update problem 380 * otherwise: If this were outside of the lock, cancellation in 381 * ssh_rtl_cancel_nonpending() may run after we've set the ptl 382 * reference but before we enter the lock. In that case, we'd detect 383 * that the request is being added to the queue and would try to remove 384 * it from that, but removal might fail because it hasn't actually been 385 * added yet. By putting this cmpxchg in the critical section, we 386 * ensure that the queuing detection only triggers when we are already 387 * in the critical section and the remove process will wait until the 388 * push operation has been completed (via lock) due to that. Only then, 389 * we can safely try to remove it. 390 */ 391 if (cmpxchg(&rqst->packet.ptl, NULL, &rtl->ptl)) { 392 spin_unlock(&rtl->queue.lock); 393 return -EALREADY; 394 } 395 396 /* 397 * Ensure that we set ptl reference before we continue modifying state. 398 * This is required for non-pending cancellation. This barrier is paired 399 * with the one in ssh_rtl_cancel_nonpending(). 400 * 401 * By setting the ptl reference before we test for "locked", we can 402 * check if the "locked" test may have already run. See comments in 403 * ssh_rtl_cancel_nonpending() for more detail. 404 */ 405 smp_mb__after_atomic(); 406 407 if (test_bit(SSH_RTL_SF_SHUTDOWN_BIT, &rtl->state)) { 408 spin_unlock(&rtl->queue.lock); 409 return -ESHUTDOWN; 410 } 411 412 if (test_bit(SSH_REQUEST_SF_LOCKED_BIT, &rqst->state)) { 413 spin_unlock(&rtl->queue.lock); 414 return -EINVAL; 415 } 416 417 set_bit(SSH_REQUEST_SF_QUEUED_BIT, &rqst->state); 418 list_add_tail(&ssh_request_get(rqst)->node, &rtl->queue.head); 419 420 spin_unlock(&rtl->queue.lock); 421 422 ssh_rtl_tx_schedule(rtl); 423 return 0; 424 } 425 426 static void ssh_rtl_timeout_reaper_mod(struct ssh_rtl *rtl, ktime_t now, 427 ktime_t expires) 428 { 429 unsigned long delta = msecs_to_jiffies(ktime_ms_delta(expires, now)); 430 ktime_t aexp = ktime_add(expires, SSH_RTL_REQUEST_TIMEOUT_RESOLUTION); 431 432 spin_lock(&rtl->rtx_timeout.lock); 433 434 /* Re-adjust / schedule reaper only if it is above resolution delta. */ 435 if (ktime_before(aexp, rtl->rtx_timeout.expires)) { 436 rtl->rtx_timeout.expires = expires; 437 mod_delayed_work(system_wq, &rtl->rtx_timeout.reaper, delta); 438 } 439 440 spin_unlock(&rtl->rtx_timeout.lock); 441 } 442 443 static void ssh_rtl_timeout_start(struct ssh_request *rqst) 444 { 445 struct ssh_rtl *rtl = ssh_request_rtl(rqst); 446 ktime_t timestamp = ktime_get_coarse_boottime(); 447 ktime_t timeout = rtl->rtx_timeout.timeout; 448 449 if (test_bit(SSH_REQUEST_SF_LOCKED_BIT, &rqst->state)) 450 return; 451 452 /* 453 * Note: The timestamp gets set only once. This happens on the packet 454 * callback. All other access to it is read-only. 455 */ 456 WRITE_ONCE(rqst->timestamp, timestamp); 457 /* 458 * Ensure timestamp is set before starting the reaper. Paired with 459 * implicit barrier following check on ssh_request_get_expiration() in 460 * ssh_rtl_timeout_reap. 461 */ 462 smp_mb__after_atomic(); 463 464 ssh_rtl_timeout_reaper_mod(rtl, timestamp, timestamp + timeout); 465 } 466 467 static void ssh_rtl_complete(struct ssh_rtl *rtl, 468 const struct ssh_command *command, 469 const struct ssam_span *command_data) 470 { 471 struct ssh_request *r = NULL; 472 struct ssh_request *p, *n; 473 u16 rqid = get_unaligned_le16(&command->rqid); 474 475 trace_ssam_rx_response_received(command, command_data->len); 476 477 /* 478 * Get request from pending based on request ID and mark it as response 479 * received and locked. 480 */ 481 spin_lock(&rtl->pending.lock); 482 list_for_each_entry_safe(p, n, &rtl->pending.head, node) { 483 /* We generally expect requests to be processed in order. */ 484 if (unlikely(ssh_request_get_rqid(p) != rqid)) 485 continue; 486 487 /* Simulate response timeout. */ 488 if (ssh_rtl_should_drop_response()) { 489 spin_unlock(&rtl->pending.lock); 490 491 trace_ssam_ei_rx_drop_response(p); 492 rtl_info(rtl, "request error injection: dropping response for request %p\n", 493 &p->packet); 494 return; 495 } 496 497 /* 498 * Mark as "response received" and "locked" as we're going to 499 * complete it. 500 */ 501 set_bit(SSH_REQUEST_SF_LOCKED_BIT, &p->state); 502 set_bit(SSH_REQUEST_SF_RSPRCVD_BIT, &p->state); 503 /* Ensure state never gets zero. */ 504 smp_mb__before_atomic(); 505 clear_bit(SSH_REQUEST_SF_PENDING_BIT, &p->state); 506 507 atomic_dec(&rtl->pending.count); 508 list_del(&p->node); 509 510 r = p; 511 break; 512 } 513 spin_unlock(&rtl->pending.lock); 514 515 if (!r) { 516 rtl_warn(rtl, "rtl: dropping unexpected command message (rqid = %#06x)\n", 517 rqid); 518 return; 519 } 520 521 /* If the request hasn't been completed yet, we will do this now. */ 522 if (test_and_set_bit(SSH_REQUEST_SF_COMPLETED_BIT, &r->state)) { 523 ssh_request_put(r); 524 ssh_rtl_tx_schedule(rtl); 525 return; 526 } 527 528 /* 529 * Make sure the request has been transmitted. In case of a sequenced 530 * request, we are guaranteed that the completion callback will run on 531 * the receiver thread directly when the ACK for the packet has been 532 * received. Similarly, this function is guaranteed to run on the 533 * receiver thread. Thus we are guaranteed that if the packet has been 534 * successfully transmitted and received an ACK, the transmitted flag 535 * has been set and is visible here. 536 * 537 * We are currently not handling unsequenced packets here, as those 538 * should never expect a response as ensured in ssh_rtl_submit. If this 539 * ever changes, one would have to test for 540 * 541 * (r->state & (transmitting | transmitted)) 542 * 543 * on unsequenced packets to determine if they could have been 544 * transmitted. There are no synchronization guarantees as in the 545 * sequenced case, since, in this case, the callback function will not 546 * run on the same thread. Thus an exact determination is impossible. 547 */ 548 if (!test_bit(SSH_REQUEST_SF_TRANSMITTED_BIT, &r->state)) { 549 rtl_err(rtl, "rtl: received response before ACK for request (rqid = %#06x)\n", 550 rqid); 551 552 /* 553 * NB: Timeout has already been canceled, request already been 554 * removed from pending and marked as locked and completed. As 555 * we receive a "false" response, the packet might still be 556 * queued though. 557 */ 558 ssh_rtl_queue_remove(r); 559 560 ssh_rtl_complete_with_status(r, -EREMOTEIO); 561 ssh_request_put(r); 562 563 ssh_rtl_tx_schedule(rtl); 564 return; 565 } 566 567 /* 568 * NB: Timeout has already been canceled, request already been 569 * removed from pending and marked as locked and completed. The request 570 * can also not be queued any more, as it has been marked as 571 * transmitting and later transmitted. Thus no need to remove it from 572 * anywhere. 573 */ 574 575 ssh_rtl_complete_with_rsp(r, command, command_data); 576 ssh_request_put(r); 577 578 ssh_rtl_tx_schedule(rtl); 579 } 580 581 static bool ssh_rtl_cancel_nonpending(struct ssh_request *r) 582 { 583 struct ssh_rtl *rtl; 584 unsigned long flags, fixed; 585 bool remove; 586 587 /* 588 * Handle unsubmitted request: Try to mark the packet as locked, 589 * expecting the state to be zero (i.e. unsubmitted). Note that, if 590 * setting the state worked, we might still be adding the packet to the 591 * queue in a currently executing submit call. In that case, however, 592 * ptl reference must have been set previously, as locked is checked 593 * after setting ptl. Furthermore, when the ptl reference is set, the 594 * submission process is guaranteed to have entered the critical 595 * section. Thus only if we successfully locked this request and ptl is 596 * NULL, we have successfully removed the request, i.e. we are 597 * guaranteed that, due to the "locked" check in ssh_rtl_submit(), the 598 * packet will never be added. Otherwise, we need to try and grab it 599 * from the queue, where we are now guaranteed that the packet is or has 600 * been due to the critical section. 601 * 602 * Note that if the cmpxchg() fails, we are guaranteed that ptl has 603 * been set and is non-NULL, as states can only be nonzero after this 604 * has been set. Also note that we need to fetch the static (type) 605 * flags to ensure that they don't cause the cmpxchg() to fail. 606 */ 607 fixed = READ_ONCE(r->state) & SSH_REQUEST_FLAGS_TY_MASK; 608 flags = cmpxchg(&r->state, fixed, SSH_REQUEST_SF_LOCKED_BIT); 609 610 /* 611 * Force correct ordering with regards to state and ptl reference access 612 * to safe-guard cancellation to concurrent submission against a 613 * lost-update problem. First try to exchange state, then also check 614 * ptl if that worked. This barrier is paired with the 615 * one in ssh_rtl_submit(). 616 */ 617 smp_mb__after_atomic(); 618 619 if (flags == fixed && !READ_ONCE(r->packet.ptl)) { 620 if (test_and_set_bit(SSH_REQUEST_SF_COMPLETED_BIT, &r->state)) 621 return true; 622 623 ssh_rtl_complete_with_status(r, -ECANCELED); 624 return true; 625 } 626 627 rtl = ssh_request_rtl(r); 628 spin_lock(&rtl->queue.lock); 629 630 /* 631 * Note: 1) Requests cannot be re-submitted. 2) If a request is 632 * queued, it cannot be "transmitting"/"pending" yet. Thus, if we 633 * successfully remove the request here, we have removed all its 634 * occurrences in the system. 635 */ 636 637 remove = test_and_clear_bit(SSH_REQUEST_SF_QUEUED_BIT, &r->state); 638 if (!remove) { 639 spin_unlock(&rtl->queue.lock); 640 return false; 641 } 642 643 set_bit(SSH_REQUEST_SF_LOCKED_BIT, &r->state); 644 list_del(&r->node); 645 646 spin_unlock(&rtl->queue.lock); 647 648 ssh_request_put(r); /* Drop reference obtained from queue. */ 649 650 if (test_and_set_bit(SSH_REQUEST_SF_COMPLETED_BIT, &r->state)) 651 return true; 652 653 ssh_rtl_complete_with_status(r, -ECANCELED); 654 return true; 655 } 656 657 static bool ssh_rtl_cancel_pending(struct ssh_request *r) 658 { 659 /* If the packet is already locked, it's going to be removed shortly. */ 660 if (test_and_set_bit(SSH_REQUEST_SF_LOCKED_BIT, &r->state)) 661 return true; 662 663 /* 664 * Now that we have locked the packet, we have guaranteed that it can't 665 * be added to the system any more. If ptl is NULL, the locked 666 * check in ssh_rtl_submit() has not been run and any submission, 667 * currently in progress or called later, won't add the packet. Thus we 668 * can directly complete it. 669 * 670 * The implicit memory barrier of test_and_set_bit() should be enough 671 * to ensure that the correct order (first lock, then check ptl) is 672 * ensured. This is paired with the barrier in ssh_rtl_submit(). 673 */ 674 if (!READ_ONCE(r->packet.ptl)) { 675 if (test_and_set_bit(SSH_REQUEST_SF_COMPLETED_BIT, &r->state)) 676 return true; 677 678 ssh_rtl_complete_with_status(r, -ECANCELED); 679 return true; 680 } 681 682 /* 683 * Try to cancel the packet. If the packet has not been completed yet, 684 * this will subsequently (and synchronously) call the completion 685 * callback of the packet, which will complete the request. 686 */ 687 ssh_ptl_cancel(&r->packet); 688 689 /* 690 * If the packet has been completed with success, i.e. has not been 691 * canceled by the above call, the request may not have been completed 692 * yet (may be waiting for a response). Check if we need to do this 693 * here. 694 */ 695 if (test_and_set_bit(SSH_REQUEST_SF_COMPLETED_BIT, &r->state)) 696 return true; 697 698 ssh_rtl_queue_remove(r); 699 ssh_rtl_pending_remove(r); 700 ssh_rtl_complete_with_status(r, -ECANCELED); 701 702 return true; 703 } 704 705 /** 706 * ssh_rtl_cancel() - Cancel request. 707 * @rqst: The request to cancel. 708 * @pending: Whether to also cancel pending requests. 709 * 710 * Cancels the given request. If @pending is %false, this will not cancel 711 * pending requests, i.e. requests that have already been submitted to the 712 * packet layer but not been completed yet. If @pending is %true, this will 713 * cancel the given request regardless of the state it is in. 714 * 715 * If the request has been canceled by calling this function, both completion 716 * and release callbacks of the request will be executed in a reasonable 717 * time-frame. This may happen during execution of this function, however, 718 * there is no guarantee for this. For example, a request currently 719 * transmitting will be canceled/completed only after transmission has 720 * completed, and the respective callbacks will be executed on the transmitter 721 * thread, which may happen during, but also some time after execution of the 722 * cancel function. 723 * 724 * Return: Returns %true if the given request has been canceled or completed, 725 * either by this function or prior to calling this function, %false 726 * otherwise. If @pending is %true, this function will always return %true. 727 */ 728 bool ssh_rtl_cancel(struct ssh_request *rqst, bool pending) 729 { 730 struct ssh_rtl *rtl; 731 bool canceled; 732 733 if (test_and_set_bit(SSH_REQUEST_SF_CANCELED_BIT, &rqst->state)) 734 return true; 735 736 trace_ssam_request_cancel(rqst); 737 738 if (pending) 739 canceled = ssh_rtl_cancel_pending(rqst); 740 else 741 canceled = ssh_rtl_cancel_nonpending(rqst); 742 743 /* Note: rtl may be NULL if request has not been submitted yet. */ 744 rtl = ssh_request_rtl(rqst); 745 if (canceled && rtl) 746 ssh_rtl_tx_schedule(rtl); 747 748 return canceled; 749 } 750 751 static void ssh_rtl_packet_callback(struct ssh_packet *p, int status) 752 { 753 struct ssh_request *r = to_ssh_request(p); 754 755 if (unlikely(status)) { 756 set_bit(SSH_REQUEST_SF_LOCKED_BIT, &r->state); 757 758 if (test_and_set_bit(SSH_REQUEST_SF_COMPLETED_BIT, &r->state)) 759 return; 760 761 /* 762 * The packet may get canceled even though it has not been 763 * submitted yet. The request may still be queued. Check the 764 * queue and remove it if necessary. As the timeout would have 765 * been started in this function on success, there's no need 766 * to cancel it here. 767 */ 768 ssh_rtl_queue_remove(r); 769 ssh_rtl_pending_remove(r); 770 ssh_rtl_complete_with_status(r, status); 771 772 ssh_rtl_tx_schedule(ssh_request_rtl(r)); 773 return; 774 } 775 776 /* Update state: Mark as transmitted and clear transmitting. */ 777 set_bit(SSH_REQUEST_SF_TRANSMITTED_BIT, &r->state); 778 /* Ensure state never gets zero. */ 779 smp_mb__before_atomic(); 780 clear_bit(SSH_REQUEST_SF_TRANSMITTING_BIT, &r->state); 781 782 /* If we expect a response, we just need to start the timeout. */ 783 if (test_bit(SSH_REQUEST_TY_HAS_RESPONSE_BIT, &r->state)) { 784 /* 785 * Note: This is the only place where the timestamp gets set, 786 * all other access to it is read-only. 787 */ 788 ssh_rtl_timeout_start(r); 789 return; 790 } 791 792 /* 793 * If we don't expect a response, lock, remove, and complete the 794 * request. Note that, at this point, the request is guaranteed to have 795 * left the queue and no timeout has been started. Thus we only need to 796 * remove it from pending. If the request has already been completed (it 797 * may have been canceled) return. 798 */ 799 800 set_bit(SSH_REQUEST_SF_LOCKED_BIT, &r->state); 801 if (test_and_set_bit(SSH_REQUEST_SF_COMPLETED_BIT, &r->state)) 802 return; 803 804 ssh_rtl_pending_remove(r); 805 ssh_rtl_complete_with_status(r, 0); 806 807 ssh_rtl_tx_schedule(ssh_request_rtl(r)); 808 } 809 810 static ktime_t ssh_request_get_expiration(struct ssh_request *r, ktime_t timeout) 811 { 812 ktime_t timestamp = READ_ONCE(r->timestamp); 813 814 if (timestamp != KTIME_MAX) 815 return ktime_add(timestamp, timeout); 816 else 817 return KTIME_MAX; 818 } 819 820 static void ssh_rtl_timeout_reap(struct work_struct *work) 821 { 822 struct ssh_rtl *rtl = to_ssh_rtl(work, rtx_timeout.reaper.work); 823 struct ssh_request *r, *n; 824 LIST_HEAD(claimed); 825 ktime_t now = ktime_get_coarse_boottime(); 826 ktime_t timeout = rtl->rtx_timeout.timeout; 827 ktime_t next = KTIME_MAX; 828 829 trace_ssam_rtl_timeout_reap(atomic_read(&rtl->pending.count)); 830 831 /* 832 * Mark reaper as "not pending". This is done before checking any 833 * requests to avoid lost-update type problems. 834 */ 835 spin_lock(&rtl->rtx_timeout.lock); 836 rtl->rtx_timeout.expires = KTIME_MAX; 837 spin_unlock(&rtl->rtx_timeout.lock); 838 839 spin_lock(&rtl->pending.lock); 840 list_for_each_entry_safe(r, n, &rtl->pending.head, node) { 841 ktime_t expires = ssh_request_get_expiration(r, timeout); 842 843 /* 844 * Check if the timeout hasn't expired yet. Find out next 845 * expiration date to be handled after this run. 846 */ 847 if (ktime_after(expires, now)) { 848 next = ktime_before(expires, next) ? expires : next; 849 continue; 850 } 851 852 /* Avoid further transitions if locked. */ 853 if (test_and_set_bit(SSH_REQUEST_SF_LOCKED_BIT, &r->state)) 854 continue; 855 856 /* 857 * We have now marked the packet as locked. Thus it cannot be 858 * added to the pending or queued lists again after we've 859 * removed it here. We can therefore re-use the node of this 860 * packet temporarily. 861 */ 862 863 clear_bit(SSH_REQUEST_SF_PENDING_BIT, &r->state); 864 865 atomic_dec(&rtl->pending.count); 866 list_move_tail(&r->node, &claimed); 867 } 868 spin_unlock(&rtl->pending.lock); 869 870 /* Cancel and complete the request. */ 871 list_for_each_entry_safe(r, n, &claimed, node) { 872 trace_ssam_request_timeout(r); 873 874 /* 875 * At this point we've removed the packet from pending. This 876 * means that we've obtained the last (only) reference of the 877 * system to it. Thus we can just complete it. 878 */ 879 if (!test_and_set_bit(SSH_REQUEST_SF_COMPLETED_BIT, &r->state)) 880 ssh_rtl_complete_with_status(r, -ETIMEDOUT); 881 882 /* 883 * Drop the reference we've obtained by removing it from the 884 * pending set. 885 */ 886 list_del(&r->node); 887 ssh_request_put(r); 888 } 889 890 /* Ensure that the reaper doesn't run again immediately. */ 891 next = max(next, ktime_add(now, SSH_RTL_REQUEST_TIMEOUT_RESOLUTION)); 892 if (next != KTIME_MAX) 893 ssh_rtl_timeout_reaper_mod(rtl, now, next); 894 895 ssh_rtl_tx_schedule(rtl); 896 } 897 898 static void ssh_rtl_rx_event(struct ssh_rtl *rtl, const struct ssh_command *cmd, 899 const struct ssam_span *data) 900 { 901 trace_ssam_rx_event_received(cmd, data->len); 902 903 rtl_dbg(rtl, "rtl: handling event (rqid: %#06x)\n", 904 get_unaligned_le16(&cmd->rqid)); 905 906 rtl->ops.handle_event(rtl, cmd, data); 907 } 908 909 static void ssh_rtl_rx_command(struct ssh_ptl *p, const struct ssam_span *data) 910 { 911 struct ssh_rtl *rtl = to_ssh_rtl(p, ptl); 912 struct device *dev = &p->serdev->dev; 913 struct ssh_command *command; 914 struct ssam_span command_data; 915 916 if (sshp_parse_command(dev, data, &command, &command_data)) 917 return; 918 919 if (ssh_rqid_is_event(get_unaligned_le16(&command->rqid))) 920 ssh_rtl_rx_event(rtl, command, &command_data); 921 else 922 ssh_rtl_complete(rtl, command, &command_data); 923 } 924 925 static void ssh_rtl_rx_data(struct ssh_ptl *p, const struct ssam_span *data) 926 { 927 if (!data->len) { 928 ptl_err(p, "rtl: rx: no data frame payload\n"); 929 return; 930 } 931 932 switch (data->ptr[0]) { 933 case SSH_PLD_TYPE_CMD: 934 ssh_rtl_rx_command(p, data); 935 break; 936 937 default: 938 ptl_err(p, "rtl: rx: unknown frame payload type (type: %#04x)\n", 939 data->ptr[0]); 940 break; 941 } 942 } 943 944 static void ssh_rtl_packet_release(struct ssh_packet *p) 945 { 946 struct ssh_request *rqst; 947 948 rqst = to_ssh_request(p); 949 rqst->ops->release(rqst); 950 } 951 952 static const struct ssh_packet_ops ssh_rtl_packet_ops = { 953 .complete = ssh_rtl_packet_callback, 954 .release = ssh_rtl_packet_release, 955 }; 956 957 /** 958 * ssh_request_init() - Initialize SSH request. 959 * @rqst: The request to initialize. 960 * @flags: Request flags, determining the type of the request. 961 * @ops: Request operations. 962 * 963 * Initializes the given SSH request and underlying packet. Sets the message 964 * buffer pointer to %NULL and the message buffer length to zero. This buffer 965 * has to be set separately via ssh_request_set_data() before submission and 966 * must contain a valid SSH request message. 967 * 968 * Return: Returns zero on success or %-EINVAL if the given flags are invalid. 969 */ 970 int ssh_request_init(struct ssh_request *rqst, enum ssam_request_flags flags, 971 const struct ssh_request_ops *ops) 972 { 973 unsigned long type = BIT(SSH_PACKET_TY_BLOCKING_BIT); 974 975 /* Unsequenced requests cannot have a response. */ 976 if (flags & SSAM_REQUEST_UNSEQUENCED && flags & SSAM_REQUEST_HAS_RESPONSE) 977 return -EINVAL; 978 979 if (!(flags & SSAM_REQUEST_UNSEQUENCED)) 980 type |= BIT(SSH_PACKET_TY_SEQUENCED_BIT); 981 982 ssh_packet_init(&rqst->packet, type, SSH_PACKET_PRIORITY(DATA, 0), 983 &ssh_rtl_packet_ops); 984 985 INIT_LIST_HEAD(&rqst->node); 986 987 rqst->state = 0; 988 if (flags & SSAM_REQUEST_HAS_RESPONSE) 989 rqst->state |= BIT(SSH_REQUEST_TY_HAS_RESPONSE_BIT); 990 991 rqst->timestamp = KTIME_MAX; 992 rqst->ops = ops; 993 994 return 0; 995 } 996 997 /** 998 * ssh_rtl_init() - Initialize request transport layer. 999 * @rtl: The request transport layer to initialize. 1000 * @serdev: The underlying serial device, i.e. the lower-level transport. 1001 * @ops: Request transport layer operations. 1002 * 1003 * Initializes the given request transport layer and associated packet 1004 * transport layer. Transmitter and receiver threads must be started 1005 * separately via ssh_rtl_start(), after the request-layer has been 1006 * initialized and the lower-level serial device layer has been set up. 1007 * 1008 * Return: Returns zero on success and a nonzero error code on failure. 1009 */ 1010 int ssh_rtl_init(struct ssh_rtl *rtl, struct serdev_device *serdev, 1011 const struct ssh_rtl_ops *ops) 1012 { 1013 struct ssh_ptl_ops ptl_ops; 1014 int status; 1015 1016 ptl_ops.data_received = ssh_rtl_rx_data; 1017 1018 status = ssh_ptl_init(&rtl->ptl, serdev, &ptl_ops); 1019 if (status) 1020 return status; 1021 1022 spin_lock_init(&rtl->queue.lock); 1023 INIT_LIST_HEAD(&rtl->queue.head); 1024 1025 spin_lock_init(&rtl->pending.lock); 1026 INIT_LIST_HEAD(&rtl->pending.head); 1027 atomic_set_release(&rtl->pending.count, 0); 1028 1029 INIT_WORK(&rtl->tx.work, ssh_rtl_tx_work_fn); 1030 1031 spin_lock_init(&rtl->rtx_timeout.lock); 1032 rtl->rtx_timeout.timeout = SSH_RTL_REQUEST_TIMEOUT; 1033 rtl->rtx_timeout.expires = KTIME_MAX; 1034 INIT_DELAYED_WORK(&rtl->rtx_timeout.reaper, ssh_rtl_timeout_reap); 1035 1036 rtl->ops = *ops; 1037 1038 return 0; 1039 } 1040 1041 /** 1042 * ssh_rtl_destroy() - Deinitialize request transport layer. 1043 * @rtl: The request transport layer to deinitialize. 1044 * 1045 * Deinitializes the given request transport layer and frees resources 1046 * associated with it. If receiver and/or transmitter threads have been 1047 * started, the layer must first be shut down via ssh_rtl_shutdown() before 1048 * this function can be called. 1049 */ 1050 void ssh_rtl_destroy(struct ssh_rtl *rtl) 1051 { 1052 ssh_ptl_destroy(&rtl->ptl); 1053 } 1054 1055 /** 1056 * ssh_rtl_start() - Start request transmitter and receiver. 1057 * @rtl: The request transport layer. 1058 * 1059 * Return: Returns zero on success, a negative error code on failure. 1060 */ 1061 int ssh_rtl_start(struct ssh_rtl *rtl) 1062 { 1063 int status; 1064 1065 status = ssh_ptl_tx_start(&rtl->ptl); 1066 if (status) 1067 return status; 1068 1069 ssh_rtl_tx_schedule(rtl); 1070 1071 status = ssh_ptl_rx_start(&rtl->ptl); 1072 if (status) { 1073 ssh_rtl_flush(rtl, msecs_to_jiffies(5000)); 1074 ssh_ptl_tx_stop(&rtl->ptl); 1075 return status; 1076 } 1077 1078 return 0; 1079 } 1080 1081 struct ssh_flush_request { 1082 struct ssh_request base; 1083 struct completion completion; 1084 int status; 1085 }; 1086 1087 static void ssh_rtl_flush_request_complete(struct ssh_request *r, 1088 const struct ssh_command *cmd, 1089 const struct ssam_span *data, 1090 int status) 1091 { 1092 struct ssh_flush_request *rqst; 1093 1094 rqst = container_of(r, struct ssh_flush_request, base); 1095 rqst->status = status; 1096 } 1097 1098 static void ssh_rtl_flush_request_release(struct ssh_request *r) 1099 { 1100 struct ssh_flush_request *rqst; 1101 1102 rqst = container_of(r, struct ssh_flush_request, base); 1103 complete_all(&rqst->completion); 1104 } 1105 1106 static const struct ssh_request_ops ssh_rtl_flush_request_ops = { 1107 .complete = ssh_rtl_flush_request_complete, 1108 .release = ssh_rtl_flush_request_release, 1109 }; 1110 1111 /** 1112 * ssh_rtl_flush() - Flush the request transport layer. 1113 * @rtl: request transport layer 1114 * @timeout: timeout for the flush operation in jiffies 1115 * 1116 * Queue a special flush request and wait for its completion. This request 1117 * will be completed after all other currently queued and pending requests 1118 * have been completed. Instead of a normal data packet, this request submits 1119 * a special flush packet, meaning that upon completion, also the underlying 1120 * packet transport layer has been flushed. 1121 * 1122 * Flushing the request layer guarantees that all previously submitted 1123 * requests have been fully completed before this call returns. Additionally, 1124 * flushing blocks execution of all later submitted requests until the flush 1125 * has been completed. 1126 * 1127 * If the caller ensures that no new requests are submitted after a call to 1128 * this function, the request transport layer is guaranteed to have no 1129 * remaining requests when this call returns. The same guarantee does not hold 1130 * for the packet layer, on which control packets may still be queued after 1131 * this call. 1132 * 1133 * Return: Returns zero on success, %-ETIMEDOUT if the flush timed out and has 1134 * been canceled as a result of the timeout, or %-ESHUTDOWN if the packet 1135 * and/or request transport layer has been shut down before this call. May 1136 * also return %-EINTR if the underlying packet transmission has been 1137 * interrupted. 1138 */ 1139 int ssh_rtl_flush(struct ssh_rtl *rtl, unsigned long timeout) 1140 { 1141 const unsigned int init_flags = SSAM_REQUEST_UNSEQUENCED; 1142 struct ssh_flush_request rqst; 1143 int status; 1144 1145 ssh_request_init(&rqst.base, init_flags, &ssh_rtl_flush_request_ops); 1146 rqst.base.packet.state |= BIT(SSH_PACKET_TY_FLUSH_BIT); 1147 rqst.base.packet.priority = SSH_PACKET_PRIORITY(FLUSH, 0); 1148 rqst.base.state |= BIT(SSH_REQUEST_TY_FLUSH_BIT); 1149 1150 init_completion(&rqst.completion); 1151 1152 status = ssh_rtl_submit(rtl, &rqst.base); 1153 if (status) 1154 return status; 1155 1156 ssh_request_put(&rqst.base); 1157 1158 if (!wait_for_completion_timeout(&rqst.completion, timeout)) { 1159 ssh_rtl_cancel(&rqst.base, true); 1160 wait_for_completion(&rqst.completion); 1161 } 1162 1163 WARN_ON(rqst.status != 0 && rqst.status != -ECANCELED && 1164 rqst.status != -ESHUTDOWN && rqst.status != -EINTR); 1165 1166 return rqst.status == -ECANCELED ? -ETIMEDOUT : rqst.status; 1167 } 1168 1169 /** 1170 * ssh_rtl_shutdown() - Shut down request transport layer. 1171 * @rtl: The request transport layer. 1172 * 1173 * Shuts down the request transport layer, removing and canceling all queued 1174 * and pending requests. Requests canceled by this operation will be completed 1175 * with %-ESHUTDOWN as status. Receiver and transmitter threads will be 1176 * stopped, the lower-level packet layer will be shutdown. 1177 * 1178 * As a result of this function, the transport layer will be marked as shut 1179 * down. Submission of requests after the transport layer has been shut down 1180 * will fail with %-ESHUTDOWN. 1181 */ 1182 void ssh_rtl_shutdown(struct ssh_rtl *rtl) 1183 { 1184 struct ssh_request *r, *n; 1185 LIST_HEAD(claimed); 1186 int pending; 1187 1188 set_bit(SSH_RTL_SF_SHUTDOWN_BIT, &rtl->state); 1189 /* 1190 * Ensure that the layer gets marked as shut-down before actually 1191 * stopping it. In combination with the check in ssh_rtl_submit(), 1192 * this guarantees that no new requests can be added and all already 1193 * queued requests are properly canceled. 1194 */ 1195 smp_mb__after_atomic(); 1196 1197 /* Remove requests from queue. */ 1198 spin_lock(&rtl->queue.lock); 1199 list_for_each_entry_safe(r, n, &rtl->queue.head, node) { 1200 set_bit(SSH_REQUEST_SF_LOCKED_BIT, &r->state); 1201 /* Ensure state never gets zero. */ 1202 smp_mb__before_atomic(); 1203 clear_bit(SSH_REQUEST_SF_QUEUED_BIT, &r->state); 1204 1205 list_move_tail(&r->node, &claimed); 1206 } 1207 spin_unlock(&rtl->queue.lock); 1208 1209 /* 1210 * We have now guaranteed that the queue is empty and no more new 1211 * requests can be submitted (i.e. it will stay empty). This means that 1212 * calling ssh_rtl_tx_schedule() will not schedule tx.work any more. So 1213 * we can simply call cancel_work_sync() on tx.work here and when that 1214 * returns, we've locked it down. This also means that after this call, 1215 * we don't submit any more packets to the underlying packet layer, so 1216 * we can also shut that down. 1217 */ 1218 1219 cancel_work_sync(&rtl->tx.work); 1220 ssh_ptl_shutdown(&rtl->ptl); 1221 cancel_delayed_work_sync(&rtl->rtx_timeout.reaper); 1222 1223 /* 1224 * Shutting down the packet layer should also have canceled all 1225 * requests. Thus the pending set should be empty. Attempt to handle 1226 * this gracefully anyways, even though this should be dead code. 1227 */ 1228 1229 pending = atomic_read(&rtl->pending.count); 1230 if (WARN_ON(pending)) { 1231 spin_lock(&rtl->pending.lock); 1232 list_for_each_entry_safe(r, n, &rtl->pending.head, node) { 1233 set_bit(SSH_REQUEST_SF_LOCKED_BIT, &r->state); 1234 /* Ensure state never gets zero. */ 1235 smp_mb__before_atomic(); 1236 clear_bit(SSH_REQUEST_SF_PENDING_BIT, &r->state); 1237 1238 list_move_tail(&r->node, &claimed); 1239 } 1240 spin_unlock(&rtl->pending.lock); 1241 } 1242 1243 /* Finally, cancel and complete the requests we claimed before. */ 1244 list_for_each_entry_safe(r, n, &claimed, node) { 1245 /* 1246 * We need test_and_set() because we still might compete with 1247 * cancellation. 1248 */ 1249 if (!test_and_set_bit(SSH_REQUEST_SF_COMPLETED_BIT, &r->state)) 1250 ssh_rtl_complete_with_status(r, -ESHUTDOWN); 1251 1252 /* 1253 * Drop the reference we've obtained by removing it from the 1254 * lists. 1255 */ 1256 list_del(&r->node); 1257 ssh_request_put(r); 1258 } 1259 } 1260