1 // SPDX-License-Identifier: (GPL-2.0 OR BSD-3-Clause) 2 // Copyright(c) 2015-17 Intel Corporation. 3 4 #include <linux/acpi.h> 5 #include <linux/delay.h> 6 #include <linux/mod_devicetable.h> 7 #include <linux/pm_runtime.h> 8 #include <linux/soundwire/sdw_registers.h> 9 #include <linux/soundwire/sdw.h> 10 #include <linux/soundwire/sdw_type.h> 11 #include "bus.h" 12 #include "sysfs_local.h" 13 14 static DEFINE_IDA(sdw_bus_ida); 15 static DEFINE_IDA(sdw_peripheral_ida); 16 17 static int sdw_get_id(struct sdw_bus *bus) 18 { 19 int rc = ida_alloc(&sdw_bus_ida, GFP_KERNEL); 20 21 if (rc < 0) 22 return rc; 23 24 bus->id = rc; 25 return 0; 26 } 27 28 /** 29 * sdw_bus_master_add() - add a bus Master instance 30 * @bus: bus instance 31 * @parent: parent device 32 * @fwnode: firmware node handle 33 * 34 * Initializes the bus instance, read properties and create child 35 * devices. 36 */ 37 int sdw_bus_master_add(struct sdw_bus *bus, struct device *parent, 38 struct fwnode_handle *fwnode) 39 { 40 struct sdw_master_prop *prop = NULL; 41 int ret; 42 43 if (!parent) { 44 pr_err("SoundWire parent device is not set\n"); 45 return -ENODEV; 46 } 47 48 ret = sdw_get_id(bus); 49 if (ret < 0) { 50 dev_err(parent, "Failed to get bus id\n"); 51 return ret; 52 } 53 54 ret = sdw_master_device_add(bus, parent, fwnode); 55 if (ret < 0) { 56 dev_err(parent, "Failed to add master device at link %d\n", 57 bus->link_id); 58 return ret; 59 } 60 61 if (!bus->ops) { 62 dev_err(bus->dev, "SoundWire Bus ops are not set\n"); 63 return -EINVAL; 64 } 65 66 if (!bus->compute_params) { 67 dev_err(bus->dev, 68 "Bandwidth allocation not configured, compute_params no set\n"); 69 return -EINVAL; 70 } 71 72 /* 73 * Give each bus_lock and msg_lock a unique key so that lockdep won't 74 * trigger a deadlock warning when the locks of several buses are 75 * grabbed during configuration of a multi-bus stream. 76 */ 77 lockdep_register_key(&bus->msg_lock_key); 78 __mutex_init(&bus->msg_lock, "msg_lock", &bus->msg_lock_key); 79 80 lockdep_register_key(&bus->bus_lock_key); 81 __mutex_init(&bus->bus_lock, "bus_lock", &bus->bus_lock_key); 82 83 INIT_LIST_HEAD(&bus->slaves); 84 INIT_LIST_HEAD(&bus->m_rt_list); 85 86 /* 87 * Initialize multi_link flag 88 */ 89 bus->multi_link = false; 90 if (bus->ops->read_prop) { 91 ret = bus->ops->read_prop(bus); 92 if (ret < 0) { 93 dev_err(bus->dev, 94 "Bus read properties failed:%d\n", ret); 95 return ret; 96 } 97 } 98 99 sdw_bus_debugfs_init(bus); 100 101 /* 102 * Device numbers in SoundWire are 0 through 15. Enumeration device 103 * number (0), Broadcast device number (15), Group numbers (12 and 104 * 13) and Master device number (14) are not used for assignment so 105 * mask these and other higher bits. 106 */ 107 108 /* Set higher order bits */ 109 *bus->assigned = ~GENMASK(SDW_BROADCAST_DEV_NUM, SDW_ENUM_DEV_NUM); 110 111 /* Set enumuration device number and broadcast device number */ 112 set_bit(SDW_ENUM_DEV_NUM, bus->assigned); 113 set_bit(SDW_BROADCAST_DEV_NUM, bus->assigned); 114 115 /* Set group device numbers and master device number */ 116 set_bit(SDW_GROUP12_DEV_NUM, bus->assigned); 117 set_bit(SDW_GROUP13_DEV_NUM, bus->assigned); 118 set_bit(SDW_MASTER_DEV_NUM, bus->assigned); 119 120 /* 121 * SDW is an enumerable bus, but devices can be powered off. So, 122 * they won't be able to report as present. 123 * 124 * Create Slave devices based on Slaves described in 125 * the respective firmware (ACPI/DT) 126 */ 127 if (IS_ENABLED(CONFIG_ACPI) && ACPI_HANDLE(bus->dev)) 128 ret = sdw_acpi_find_slaves(bus); 129 else if (IS_ENABLED(CONFIG_OF) && bus->dev->of_node) 130 ret = sdw_of_find_slaves(bus); 131 else 132 ret = -ENOTSUPP; /* No ACPI/DT so error out */ 133 134 if (ret < 0) { 135 dev_err(bus->dev, "Finding slaves failed:%d\n", ret); 136 return ret; 137 } 138 139 /* 140 * Initialize clock values based on Master properties. The max 141 * frequency is read from max_clk_freq property. Current assumption 142 * is that the bus will start at highest clock frequency when 143 * powered on. 144 * 145 * Default active bank will be 0 as out of reset the Slaves have 146 * to start with bank 0 (Table 40 of Spec) 147 */ 148 prop = &bus->prop; 149 bus->params.max_dr_freq = prop->max_clk_freq * SDW_DOUBLE_RATE_FACTOR; 150 bus->params.curr_dr_freq = bus->params.max_dr_freq; 151 bus->params.curr_bank = SDW_BANK0; 152 bus->params.next_bank = SDW_BANK1; 153 154 return 0; 155 } 156 EXPORT_SYMBOL(sdw_bus_master_add); 157 158 static int sdw_delete_slave(struct device *dev, void *data) 159 { 160 struct sdw_slave *slave = dev_to_sdw_dev(dev); 161 struct sdw_bus *bus = slave->bus; 162 163 pm_runtime_disable(dev); 164 165 sdw_slave_debugfs_exit(slave); 166 167 mutex_lock(&bus->bus_lock); 168 169 if (slave->dev_num) { /* clear dev_num if assigned */ 170 clear_bit(slave->dev_num, bus->assigned); 171 if (bus->dev_num_ida_min) 172 ida_free(&sdw_peripheral_ida, slave->dev_num); 173 } 174 list_del_init(&slave->node); 175 mutex_unlock(&bus->bus_lock); 176 177 device_unregister(dev); 178 return 0; 179 } 180 181 /** 182 * sdw_bus_master_delete() - delete the bus master instance 183 * @bus: bus to be deleted 184 * 185 * Remove the instance, delete the child devices. 186 */ 187 void sdw_bus_master_delete(struct sdw_bus *bus) 188 { 189 device_for_each_child(bus->dev, NULL, sdw_delete_slave); 190 sdw_master_device_del(bus); 191 192 sdw_bus_debugfs_exit(bus); 193 lockdep_unregister_key(&bus->bus_lock_key); 194 lockdep_unregister_key(&bus->msg_lock_key); 195 ida_free(&sdw_bus_ida, bus->id); 196 } 197 EXPORT_SYMBOL(sdw_bus_master_delete); 198 199 /* 200 * SDW IO Calls 201 */ 202 203 static inline int find_response_code(enum sdw_command_response resp) 204 { 205 switch (resp) { 206 case SDW_CMD_OK: 207 return 0; 208 209 case SDW_CMD_IGNORED: 210 return -ENODATA; 211 212 case SDW_CMD_TIMEOUT: 213 return -ETIMEDOUT; 214 215 default: 216 return -EIO; 217 } 218 } 219 220 static inline int do_transfer(struct sdw_bus *bus, struct sdw_msg *msg) 221 { 222 int retry = bus->prop.err_threshold; 223 enum sdw_command_response resp; 224 int ret = 0, i; 225 226 for (i = 0; i <= retry; i++) { 227 resp = bus->ops->xfer_msg(bus, msg); 228 ret = find_response_code(resp); 229 230 /* if cmd is ok or ignored return */ 231 if (ret == 0 || ret == -ENODATA) 232 return ret; 233 } 234 235 return ret; 236 } 237 238 static inline int do_transfer_defer(struct sdw_bus *bus, 239 struct sdw_msg *msg) 240 { 241 struct sdw_defer *defer = &bus->defer_msg; 242 int retry = bus->prop.err_threshold; 243 enum sdw_command_response resp; 244 int ret = 0, i; 245 246 defer->msg = msg; 247 defer->length = msg->len; 248 init_completion(&defer->complete); 249 250 for (i = 0; i <= retry; i++) { 251 resp = bus->ops->xfer_msg_defer(bus); 252 ret = find_response_code(resp); 253 /* if cmd is ok or ignored return */ 254 if (ret == 0 || ret == -ENODATA) 255 return ret; 256 } 257 258 return ret; 259 } 260 261 static int sdw_transfer_unlocked(struct sdw_bus *bus, struct sdw_msg *msg) 262 { 263 int ret; 264 265 ret = do_transfer(bus, msg); 266 if (ret != 0 && ret != -ENODATA) 267 dev_err(bus->dev, "trf on Slave %d failed:%d %s addr %x count %d\n", 268 msg->dev_num, ret, 269 (msg->flags & SDW_MSG_FLAG_WRITE) ? "write" : "read", 270 msg->addr, msg->len); 271 272 return ret; 273 } 274 275 /** 276 * sdw_transfer() - Synchronous transfer message to a SDW Slave device 277 * @bus: SDW bus 278 * @msg: SDW message to be xfered 279 */ 280 int sdw_transfer(struct sdw_bus *bus, struct sdw_msg *msg) 281 { 282 int ret; 283 284 mutex_lock(&bus->msg_lock); 285 286 ret = sdw_transfer_unlocked(bus, msg); 287 288 mutex_unlock(&bus->msg_lock); 289 290 return ret; 291 } 292 293 /** 294 * sdw_show_ping_status() - Direct report of PING status, to be used by Peripheral drivers 295 * @bus: SDW bus 296 * @sync_delay: Delay before reading status 297 */ 298 void sdw_show_ping_status(struct sdw_bus *bus, bool sync_delay) 299 { 300 u32 status; 301 302 if (!bus->ops->read_ping_status) 303 return; 304 305 /* 306 * wait for peripheral to sync if desired. 10-15ms should be more than 307 * enough in most cases. 308 */ 309 if (sync_delay) 310 usleep_range(10000, 15000); 311 312 mutex_lock(&bus->msg_lock); 313 314 status = bus->ops->read_ping_status(bus); 315 316 mutex_unlock(&bus->msg_lock); 317 318 if (!status) 319 dev_warn(bus->dev, "%s: no peripherals attached\n", __func__); 320 else 321 dev_dbg(bus->dev, "PING status: %#x\n", status); 322 } 323 EXPORT_SYMBOL(sdw_show_ping_status); 324 325 /** 326 * sdw_transfer_defer() - Asynchronously transfer message to a SDW Slave device 327 * @bus: SDW bus 328 * @msg: SDW message to be xfered 329 * 330 * Caller needs to hold the msg_lock lock while calling this 331 */ 332 int sdw_transfer_defer(struct sdw_bus *bus, struct sdw_msg *msg) 333 { 334 int ret; 335 336 if (!bus->ops->xfer_msg_defer) 337 return -ENOTSUPP; 338 339 ret = do_transfer_defer(bus, msg); 340 if (ret != 0 && ret != -ENODATA) 341 dev_err(bus->dev, "Defer trf on Slave %d failed:%d\n", 342 msg->dev_num, ret); 343 344 return ret; 345 } 346 347 int sdw_fill_msg(struct sdw_msg *msg, struct sdw_slave *slave, 348 u32 addr, size_t count, u16 dev_num, u8 flags, u8 *buf) 349 { 350 memset(msg, 0, sizeof(*msg)); 351 msg->addr = addr; /* addr is 16 bit and truncated here */ 352 msg->len = count; 353 msg->dev_num = dev_num; 354 msg->flags = flags; 355 msg->buf = buf; 356 357 if (addr < SDW_REG_NO_PAGE) /* no paging area */ 358 return 0; 359 360 if (addr >= SDW_REG_MAX) { /* illegal addr */ 361 pr_err("SDW: Invalid address %x passed\n", addr); 362 return -EINVAL; 363 } 364 365 if (addr < SDW_REG_OPTIONAL_PAGE) { /* 32k but no page */ 366 if (slave && !slave->prop.paging_support) 367 return 0; 368 /* no need for else as that will fall-through to paging */ 369 } 370 371 /* paging mandatory */ 372 if (dev_num == SDW_ENUM_DEV_NUM || dev_num == SDW_BROADCAST_DEV_NUM) { 373 pr_err("SDW: Invalid device for paging :%d\n", dev_num); 374 return -EINVAL; 375 } 376 377 if (!slave) { 378 pr_err("SDW: No slave for paging addr\n"); 379 return -EINVAL; 380 } 381 382 if (!slave->prop.paging_support) { 383 dev_err(&slave->dev, 384 "address %x needs paging but no support\n", addr); 385 return -EINVAL; 386 } 387 388 msg->addr_page1 = FIELD_GET(SDW_SCP_ADDRPAGE1_MASK, addr); 389 msg->addr_page2 = FIELD_GET(SDW_SCP_ADDRPAGE2_MASK, addr); 390 msg->addr |= BIT(15); 391 msg->page = true; 392 393 return 0; 394 } 395 396 /* 397 * Read/Write IO functions. 398 */ 399 400 static int sdw_ntransfer_no_pm(struct sdw_slave *slave, u32 addr, u8 flags, 401 size_t count, u8 *val) 402 { 403 struct sdw_msg msg; 404 size_t size; 405 int ret; 406 407 while (count) { 408 // Only handle bytes up to next page boundary 409 size = min_t(size_t, count, (SDW_REGADDR + 1) - (addr & SDW_REGADDR)); 410 411 ret = sdw_fill_msg(&msg, slave, addr, size, slave->dev_num, flags, val); 412 if (ret < 0) 413 return ret; 414 415 ret = sdw_transfer(slave->bus, &msg); 416 if (ret < 0 && !slave->is_mockup_device) 417 return ret; 418 419 addr += size; 420 val += size; 421 count -= size; 422 } 423 424 return 0; 425 } 426 427 /** 428 * sdw_nread_no_pm() - Read "n" contiguous SDW Slave registers with no PM 429 * @slave: SDW Slave 430 * @addr: Register address 431 * @count: length 432 * @val: Buffer for values to be read 433 * 434 * Note that if the message crosses a page boundary each page will be 435 * transferred under a separate invocation of the msg_lock. 436 */ 437 int sdw_nread_no_pm(struct sdw_slave *slave, u32 addr, size_t count, u8 *val) 438 { 439 return sdw_ntransfer_no_pm(slave, addr, SDW_MSG_FLAG_READ, count, val); 440 } 441 EXPORT_SYMBOL(sdw_nread_no_pm); 442 443 /** 444 * sdw_nwrite_no_pm() - Write "n" contiguous SDW Slave registers with no PM 445 * @slave: SDW Slave 446 * @addr: Register address 447 * @count: length 448 * @val: Buffer for values to be written 449 * 450 * Note that if the message crosses a page boundary each page will be 451 * transferred under a separate invocation of the msg_lock. 452 */ 453 int sdw_nwrite_no_pm(struct sdw_slave *slave, u32 addr, size_t count, const u8 *val) 454 { 455 return sdw_ntransfer_no_pm(slave, addr, SDW_MSG_FLAG_WRITE, count, (u8 *)val); 456 } 457 EXPORT_SYMBOL(sdw_nwrite_no_pm); 458 459 /** 460 * sdw_write_no_pm() - Write a SDW Slave register with no PM 461 * @slave: SDW Slave 462 * @addr: Register address 463 * @value: Register value 464 */ 465 int sdw_write_no_pm(struct sdw_slave *slave, u32 addr, u8 value) 466 { 467 return sdw_nwrite_no_pm(slave, addr, 1, &value); 468 } 469 EXPORT_SYMBOL(sdw_write_no_pm); 470 471 static int 472 sdw_bread_no_pm(struct sdw_bus *bus, u16 dev_num, u32 addr) 473 { 474 struct sdw_msg msg; 475 u8 buf; 476 int ret; 477 478 ret = sdw_fill_msg(&msg, NULL, addr, 1, dev_num, 479 SDW_MSG_FLAG_READ, &buf); 480 if (ret < 0) 481 return ret; 482 483 ret = sdw_transfer(bus, &msg); 484 if (ret < 0) 485 return ret; 486 487 return buf; 488 } 489 490 static int 491 sdw_bwrite_no_pm(struct sdw_bus *bus, u16 dev_num, u32 addr, u8 value) 492 { 493 struct sdw_msg msg; 494 int ret; 495 496 ret = sdw_fill_msg(&msg, NULL, addr, 1, dev_num, 497 SDW_MSG_FLAG_WRITE, &value); 498 if (ret < 0) 499 return ret; 500 501 return sdw_transfer(bus, &msg); 502 } 503 504 int sdw_bread_no_pm_unlocked(struct sdw_bus *bus, u16 dev_num, u32 addr) 505 { 506 struct sdw_msg msg; 507 u8 buf; 508 int ret; 509 510 ret = sdw_fill_msg(&msg, NULL, addr, 1, dev_num, 511 SDW_MSG_FLAG_READ, &buf); 512 if (ret < 0) 513 return ret; 514 515 ret = sdw_transfer_unlocked(bus, &msg); 516 if (ret < 0) 517 return ret; 518 519 return buf; 520 } 521 EXPORT_SYMBOL(sdw_bread_no_pm_unlocked); 522 523 int sdw_bwrite_no_pm_unlocked(struct sdw_bus *bus, u16 dev_num, u32 addr, u8 value) 524 { 525 struct sdw_msg msg; 526 int ret; 527 528 ret = sdw_fill_msg(&msg, NULL, addr, 1, dev_num, 529 SDW_MSG_FLAG_WRITE, &value); 530 if (ret < 0) 531 return ret; 532 533 return sdw_transfer_unlocked(bus, &msg); 534 } 535 EXPORT_SYMBOL(sdw_bwrite_no_pm_unlocked); 536 537 /** 538 * sdw_read_no_pm() - Read a SDW Slave register with no PM 539 * @slave: SDW Slave 540 * @addr: Register address 541 */ 542 int sdw_read_no_pm(struct sdw_slave *slave, u32 addr) 543 { 544 u8 buf; 545 int ret; 546 547 ret = sdw_nread_no_pm(slave, addr, 1, &buf); 548 if (ret < 0) 549 return ret; 550 else 551 return buf; 552 } 553 EXPORT_SYMBOL(sdw_read_no_pm); 554 555 int sdw_update_no_pm(struct sdw_slave *slave, u32 addr, u8 mask, u8 val) 556 { 557 int tmp; 558 559 tmp = sdw_read_no_pm(slave, addr); 560 if (tmp < 0) 561 return tmp; 562 563 tmp = (tmp & ~mask) | val; 564 return sdw_write_no_pm(slave, addr, tmp); 565 } 566 EXPORT_SYMBOL(sdw_update_no_pm); 567 568 /* Read-Modify-Write Slave register */ 569 int sdw_update(struct sdw_slave *slave, u32 addr, u8 mask, u8 val) 570 { 571 int tmp; 572 573 tmp = sdw_read(slave, addr); 574 if (tmp < 0) 575 return tmp; 576 577 tmp = (tmp & ~mask) | val; 578 return sdw_write(slave, addr, tmp); 579 } 580 EXPORT_SYMBOL(sdw_update); 581 582 /** 583 * sdw_nread() - Read "n" contiguous SDW Slave registers 584 * @slave: SDW Slave 585 * @addr: Register address 586 * @count: length 587 * @val: Buffer for values to be read 588 * 589 * This version of the function will take a PM reference to the slave 590 * device. 591 * Note that if the message crosses a page boundary each page will be 592 * transferred under a separate invocation of the msg_lock. 593 */ 594 int sdw_nread(struct sdw_slave *slave, u32 addr, size_t count, u8 *val) 595 { 596 int ret; 597 598 ret = pm_runtime_get_sync(&slave->dev); 599 if (ret < 0 && ret != -EACCES) { 600 pm_runtime_put_noidle(&slave->dev); 601 return ret; 602 } 603 604 ret = sdw_nread_no_pm(slave, addr, count, val); 605 606 pm_runtime_mark_last_busy(&slave->dev); 607 pm_runtime_put(&slave->dev); 608 609 return ret; 610 } 611 EXPORT_SYMBOL(sdw_nread); 612 613 /** 614 * sdw_nwrite() - Write "n" contiguous SDW Slave registers 615 * @slave: SDW Slave 616 * @addr: Register address 617 * @count: length 618 * @val: Buffer for values to be written 619 * 620 * This version of the function will take a PM reference to the slave 621 * device. 622 * Note that if the message crosses a page boundary each page will be 623 * transferred under a separate invocation of the msg_lock. 624 */ 625 int sdw_nwrite(struct sdw_slave *slave, u32 addr, size_t count, const u8 *val) 626 { 627 int ret; 628 629 ret = pm_runtime_get_sync(&slave->dev); 630 if (ret < 0 && ret != -EACCES) { 631 pm_runtime_put_noidle(&slave->dev); 632 return ret; 633 } 634 635 ret = sdw_nwrite_no_pm(slave, addr, count, val); 636 637 pm_runtime_mark_last_busy(&slave->dev); 638 pm_runtime_put(&slave->dev); 639 640 return ret; 641 } 642 EXPORT_SYMBOL(sdw_nwrite); 643 644 /** 645 * sdw_read() - Read a SDW Slave register 646 * @slave: SDW Slave 647 * @addr: Register address 648 * 649 * This version of the function will take a PM reference to the slave 650 * device. 651 */ 652 int sdw_read(struct sdw_slave *slave, u32 addr) 653 { 654 u8 buf; 655 int ret; 656 657 ret = sdw_nread(slave, addr, 1, &buf); 658 if (ret < 0) 659 return ret; 660 661 return buf; 662 } 663 EXPORT_SYMBOL(sdw_read); 664 665 /** 666 * sdw_write() - Write a SDW Slave register 667 * @slave: SDW Slave 668 * @addr: Register address 669 * @value: Register value 670 * 671 * This version of the function will take a PM reference to the slave 672 * device. 673 */ 674 int sdw_write(struct sdw_slave *slave, u32 addr, u8 value) 675 { 676 return sdw_nwrite(slave, addr, 1, &value); 677 } 678 EXPORT_SYMBOL(sdw_write); 679 680 /* 681 * SDW alert handling 682 */ 683 684 /* called with bus_lock held */ 685 static struct sdw_slave *sdw_get_slave(struct sdw_bus *bus, int i) 686 { 687 struct sdw_slave *slave; 688 689 list_for_each_entry(slave, &bus->slaves, node) { 690 if (slave->dev_num == i) 691 return slave; 692 } 693 694 return NULL; 695 } 696 697 int sdw_compare_devid(struct sdw_slave *slave, struct sdw_slave_id id) 698 { 699 if (slave->id.mfg_id != id.mfg_id || 700 slave->id.part_id != id.part_id || 701 slave->id.class_id != id.class_id || 702 (slave->id.unique_id != SDW_IGNORED_UNIQUE_ID && 703 slave->id.unique_id != id.unique_id)) 704 return -ENODEV; 705 706 return 0; 707 } 708 EXPORT_SYMBOL(sdw_compare_devid); 709 710 /* called with bus_lock held */ 711 static int sdw_get_device_num(struct sdw_slave *slave) 712 { 713 int bit; 714 715 if (slave->bus->dev_num_ida_min) { 716 bit = ida_alloc_range(&sdw_peripheral_ida, 717 slave->bus->dev_num_ida_min, SDW_MAX_DEVICES, 718 GFP_KERNEL); 719 if (bit < 0) 720 goto err; 721 } else { 722 bit = find_first_zero_bit(slave->bus->assigned, SDW_MAX_DEVICES); 723 if (bit == SDW_MAX_DEVICES) { 724 bit = -ENODEV; 725 goto err; 726 } 727 } 728 729 /* 730 * Do not update dev_num in Slave data structure here, 731 * Update once program dev_num is successful 732 */ 733 set_bit(bit, slave->bus->assigned); 734 735 err: 736 return bit; 737 } 738 739 static int sdw_assign_device_num(struct sdw_slave *slave) 740 { 741 struct sdw_bus *bus = slave->bus; 742 int ret, dev_num; 743 bool new_device = false; 744 745 /* check first if device number is assigned, if so reuse that */ 746 if (!slave->dev_num) { 747 if (!slave->dev_num_sticky) { 748 mutex_lock(&slave->bus->bus_lock); 749 dev_num = sdw_get_device_num(slave); 750 mutex_unlock(&slave->bus->bus_lock); 751 if (dev_num < 0) { 752 dev_err(bus->dev, "Get dev_num failed: %d\n", 753 dev_num); 754 return dev_num; 755 } 756 slave->dev_num = dev_num; 757 slave->dev_num_sticky = dev_num; 758 new_device = true; 759 } else { 760 slave->dev_num = slave->dev_num_sticky; 761 } 762 } 763 764 if (!new_device) 765 dev_dbg(bus->dev, 766 "Slave already registered, reusing dev_num:%d\n", 767 slave->dev_num); 768 769 /* Clear the slave->dev_num to transfer message on device 0 */ 770 dev_num = slave->dev_num; 771 slave->dev_num = 0; 772 773 ret = sdw_write_no_pm(slave, SDW_SCP_DEVNUMBER, dev_num); 774 if (ret < 0) { 775 dev_err(bus->dev, "Program device_num %d failed: %d\n", 776 dev_num, ret); 777 return ret; 778 } 779 780 /* After xfer of msg, restore dev_num */ 781 slave->dev_num = slave->dev_num_sticky; 782 783 if (bus->ops && bus->ops->new_peripheral_assigned) 784 bus->ops->new_peripheral_assigned(bus, dev_num); 785 786 return 0; 787 } 788 789 void sdw_extract_slave_id(struct sdw_bus *bus, 790 u64 addr, struct sdw_slave_id *id) 791 { 792 dev_dbg(bus->dev, "SDW Slave Addr: %llx\n", addr); 793 794 id->sdw_version = SDW_VERSION(addr); 795 id->unique_id = SDW_UNIQUE_ID(addr); 796 id->mfg_id = SDW_MFG_ID(addr); 797 id->part_id = SDW_PART_ID(addr); 798 id->class_id = SDW_CLASS_ID(addr); 799 800 dev_dbg(bus->dev, 801 "SDW Slave class_id 0x%02x, mfg_id 0x%04x, part_id 0x%04x, unique_id 0x%x, version 0x%x\n", 802 id->class_id, id->mfg_id, id->part_id, id->unique_id, id->sdw_version); 803 } 804 EXPORT_SYMBOL(sdw_extract_slave_id); 805 806 static int sdw_program_device_num(struct sdw_bus *bus, bool *programmed) 807 { 808 u8 buf[SDW_NUM_DEV_ID_REGISTERS] = {0}; 809 struct sdw_slave *slave, *_s; 810 struct sdw_slave_id id; 811 struct sdw_msg msg; 812 bool found; 813 int count = 0, ret; 814 u64 addr; 815 816 *programmed = false; 817 818 /* No Slave, so use raw xfer api */ 819 ret = sdw_fill_msg(&msg, NULL, SDW_SCP_DEVID_0, 820 SDW_NUM_DEV_ID_REGISTERS, 0, SDW_MSG_FLAG_READ, buf); 821 if (ret < 0) 822 return ret; 823 824 do { 825 ret = sdw_transfer(bus, &msg); 826 if (ret == -ENODATA) { /* end of device id reads */ 827 dev_dbg(bus->dev, "No more devices to enumerate\n"); 828 ret = 0; 829 break; 830 } 831 if (ret < 0) { 832 dev_err(bus->dev, "DEVID read fail:%d\n", ret); 833 break; 834 } 835 836 /* 837 * Construct the addr and extract. Cast the higher shift 838 * bits to avoid truncation due to size limit. 839 */ 840 addr = buf[5] | (buf[4] << 8) | (buf[3] << 16) | 841 ((u64)buf[2] << 24) | ((u64)buf[1] << 32) | 842 ((u64)buf[0] << 40); 843 844 sdw_extract_slave_id(bus, addr, &id); 845 846 found = false; 847 /* Now compare with entries */ 848 list_for_each_entry_safe(slave, _s, &bus->slaves, node) { 849 if (sdw_compare_devid(slave, id) == 0) { 850 found = true; 851 852 /* 853 * To prevent skipping state-machine stages don't 854 * program a device until we've seen it UNATTACH. 855 * Must return here because no other device on #0 856 * can be detected until this one has been 857 * assigned a device ID. 858 */ 859 if (slave->status != SDW_SLAVE_UNATTACHED) 860 return 0; 861 862 /* 863 * Assign a new dev_num to this Slave and 864 * not mark it present. It will be marked 865 * present after it reports ATTACHED on new 866 * dev_num 867 */ 868 ret = sdw_assign_device_num(slave); 869 if (ret < 0) { 870 dev_err(bus->dev, 871 "Assign dev_num failed:%d\n", 872 ret); 873 return ret; 874 } 875 876 *programmed = true; 877 878 break; 879 } 880 } 881 882 if (!found) { 883 /* TODO: Park this device in Group 13 */ 884 885 /* 886 * add Slave device even if there is no platform 887 * firmware description. There will be no driver probe 888 * but the user/integration will be able to see the 889 * device, enumeration status and device number in sysfs 890 */ 891 sdw_slave_add(bus, &id, NULL); 892 893 dev_err(bus->dev, "Slave Entry not found\n"); 894 } 895 896 count++; 897 898 /* 899 * Check till error out or retry (count) exhausts. 900 * Device can drop off and rejoin during enumeration 901 * so count till twice the bound. 902 */ 903 904 } while (ret == 0 && count < (SDW_MAX_DEVICES * 2)); 905 906 return ret; 907 } 908 909 static void sdw_modify_slave_status(struct sdw_slave *slave, 910 enum sdw_slave_status status) 911 { 912 struct sdw_bus *bus = slave->bus; 913 914 mutex_lock(&bus->bus_lock); 915 916 dev_vdbg(bus->dev, 917 "changing status slave %d status %d new status %d\n", 918 slave->dev_num, slave->status, status); 919 920 if (status == SDW_SLAVE_UNATTACHED) { 921 dev_dbg(&slave->dev, 922 "initializing enumeration and init completion for Slave %d\n", 923 slave->dev_num); 924 925 reinit_completion(&slave->enumeration_complete); 926 reinit_completion(&slave->initialization_complete); 927 928 } else if ((status == SDW_SLAVE_ATTACHED) && 929 (slave->status == SDW_SLAVE_UNATTACHED)) { 930 dev_dbg(&slave->dev, 931 "signaling enumeration completion for Slave %d\n", 932 slave->dev_num); 933 934 complete_all(&slave->enumeration_complete); 935 } 936 slave->status = status; 937 mutex_unlock(&bus->bus_lock); 938 } 939 940 static int sdw_slave_clk_stop_callback(struct sdw_slave *slave, 941 enum sdw_clk_stop_mode mode, 942 enum sdw_clk_stop_type type) 943 { 944 int ret = 0; 945 946 mutex_lock(&slave->sdw_dev_lock); 947 948 if (slave->probed) { 949 struct device *dev = &slave->dev; 950 struct sdw_driver *drv = drv_to_sdw_driver(dev->driver); 951 952 if (drv->ops && drv->ops->clk_stop) 953 ret = drv->ops->clk_stop(slave, mode, type); 954 } 955 956 mutex_unlock(&slave->sdw_dev_lock); 957 958 return ret; 959 } 960 961 static int sdw_slave_clk_stop_prepare(struct sdw_slave *slave, 962 enum sdw_clk_stop_mode mode, 963 bool prepare) 964 { 965 bool wake_en; 966 u32 val = 0; 967 int ret; 968 969 wake_en = slave->prop.wake_capable; 970 971 if (prepare) { 972 val = SDW_SCP_SYSTEMCTRL_CLK_STP_PREP; 973 974 if (mode == SDW_CLK_STOP_MODE1) 975 val |= SDW_SCP_SYSTEMCTRL_CLK_STP_MODE1; 976 977 if (wake_en) 978 val |= SDW_SCP_SYSTEMCTRL_WAKE_UP_EN; 979 } else { 980 ret = sdw_read_no_pm(slave, SDW_SCP_SYSTEMCTRL); 981 if (ret < 0) { 982 if (ret != -ENODATA) 983 dev_err(&slave->dev, "SDW_SCP_SYSTEMCTRL read failed:%d\n", ret); 984 return ret; 985 } 986 val = ret; 987 val &= ~(SDW_SCP_SYSTEMCTRL_CLK_STP_PREP); 988 } 989 990 ret = sdw_write_no_pm(slave, SDW_SCP_SYSTEMCTRL, val); 991 992 if (ret < 0 && ret != -ENODATA) 993 dev_err(&slave->dev, "SDW_SCP_SYSTEMCTRL write failed:%d\n", ret); 994 995 return ret; 996 } 997 998 static int sdw_bus_wait_for_clk_prep_deprep(struct sdw_bus *bus, u16 dev_num) 999 { 1000 int retry = bus->clk_stop_timeout; 1001 int val; 1002 1003 do { 1004 val = sdw_bread_no_pm(bus, dev_num, SDW_SCP_STAT); 1005 if (val < 0) { 1006 if (val != -ENODATA) 1007 dev_err(bus->dev, "SDW_SCP_STAT bread failed:%d\n", val); 1008 return val; 1009 } 1010 val &= SDW_SCP_STAT_CLK_STP_NF; 1011 if (!val) { 1012 dev_dbg(bus->dev, "clock stop prep/de-prep done slave:%d\n", 1013 dev_num); 1014 return 0; 1015 } 1016 1017 usleep_range(1000, 1500); 1018 retry--; 1019 } while (retry); 1020 1021 dev_err(bus->dev, "clock stop prep/de-prep failed slave:%d\n", 1022 dev_num); 1023 1024 return -ETIMEDOUT; 1025 } 1026 1027 /** 1028 * sdw_bus_prep_clk_stop: prepare Slave(s) for clock stop 1029 * 1030 * @bus: SDW bus instance 1031 * 1032 * Query Slave for clock stop mode and prepare for that mode. 1033 */ 1034 int sdw_bus_prep_clk_stop(struct sdw_bus *bus) 1035 { 1036 bool simple_clk_stop = true; 1037 struct sdw_slave *slave; 1038 bool is_slave = false; 1039 int ret = 0; 1040 1041 /* 1042 * In order to save on transition time, prepare 1043 * each Slave and then wait for all Slave(s) to be 1044 * prepared for clock stop. 1045 * If one of the Slave devices has lost sync and 1046 * replies with Command Ignored/-ENODATA, we continue 1047 * the loop 1048 */ 1049 list_for_each_entry(slave, &bus->slaves, node) { 1050 if (!slave->dev_num) 1051 continue; 1052 1053 if (slave->status != SDW_SLAVE_ATTACHED && 1054 slave->status != SDW_SLAVE_ALERT) 1055 continue; 1056 1057 /* Identify if Slave(s) are available on Bus */ 1058 is_slave = true; 1059 1060 ret = sdw_slave_clk_stop_callback(slave, 1061 SDW_CLK_STOP_MODE0, 1062 SDW_CLK_PRE_PREPARE); 1063 if (ret < 0 && ret != -ENODATA) { 1064 dev_err(&slave->dev, "clock stop pre-prepare cb failed:%d\n", ret); 1065 return ret; 1066 } 1067 1068 /* Only prepare a Slave device if needed */ 1069 if (!slave->prop.simple_clk_stop_capable) { 1070 simple_clk_stop = false; 1071 1072 ret = sdw_slave_clk_stop_prepare(slave, 1073 SDW_CLK_STOP_MODE0, 1074 true); 1075 if (ret < 0 && ret != -ENODATA) { 1076 dev_err(&slave->dev, "clock stop prepare failed:%d\n", ret); 1077 return ret; 1078 } 1079 } 1080 } 1081 1082 /* Skip remaining clock stop preparation if no Slave is attached */ 1083 if (!is_slave) 1084 return 0; 1085 1086 /* 1087 * Don't wait for all Slaves to be ready if they follow the simple 1088 * state machine 1089 */ 1090 if (!simple_clk_stop) { 1091 ret = sdw_bus_wait_for_clk_prep_deprep(bus, 1092 SDW_BROADCAST_DEV_NUM); 1093 /* 1094 * if there are no Slave devices present and the reply is 1095 * Command_Ignored/-ENODATA, we don't need to continue with the 1096 * flow and can just return here. The error code is not modified 1097 * and its handling left as an exercise for the caller. 1098 */ 1099 if (ret < 0) 1100 return ret; 1101 } 1102 1103 /* Inform slaves that prep is done */ 1104 list_for_each_entry(slave, &bus->slaves, node) { 1105 if (!slave->dev_num) 1106 continue; 1107 1108 if (slave->status != SDW_SLAVE_ATTACHED && 1109 slave->status != SDW_SLAVE_ALERT) 1110 continue; 1111 1112 ret = sdw_slave_clk_stop_callback(slave, 1113 SDW_CLK_STOP_MODE0, 1114 SDW_CLK_POST_PREPARE); 1115 1116 if (ret < 0 && ret != -ENODATA) { 1117 dev_err(&slave->dev, "clock stop post-prepare cb failed:%d\n", ret); 1118 return ret; 1119 } 1120 } 1121 1122 return 0; 1123 } 1124 EXPORT_SYMBOL(sdw_bus_prep_clk_stop); 1125 1126 /** 1127 * sdw_bus_clk_stop: stop bus clock 1128 * 1129 * @bus: SDW bus instance 1130 * 1131 * After preparing the Slaves for clock stop, stop the clock by broadcasting 1132 * write to SCP_CTRL register. 1133 */ 1134 int sdw_bus_clk_stop(struct sdw_bus *bus) 1135 { 1136 int ret; 1137 1138 /* 1139 * broadcast clock stop now, attached Slaves will ACK this, 1140 * unattached will ignore 1141 */ 1142 ret = sdw_bwrite_no_pm(bus, SDW_BROADCAST_DEV_NUM, 1143 SDW_SCP_CTRL, SDW_SCP_CTRL_CLK_STP_NOW); 1144 if (ret < 0) { 1145 if (ret != -ENODATA) 1146 dev_err(bus->dev, "ClockStopNow Broadcast msg failed %d\n", ret); 1147 return ret; 1148 } 1149 1150 return 0; 1151 } 1152 EXPORT_SYMBOL(sdw_bus_clk_stop); 1153 1154 /** 1155 * sdw_bus_exit_clk_stop: Exit clock stop mode 1156 * 1157 * @bus: SDW bus instance 1158 * 1159 * This De-prepares the Slaves by exiting Clock Stop Mode 0. For the Slaves 1160 * exiting Clock Stop Mode 1, they will be de-prepared after they enumerate 1161 * back. 1162 */ 1163 int sdw_bus_exit_clk_stop(struct sdw_bus *bus) 1164 { 1165 bool simple_clk_stop = true; 1166 struct sdw_slave *slave; 1167 bool is_slave = false; 1168 int ret; 1169 1170 /* 1171 * In order to save on transition time, de-prepare 1172 * each Slave and then wait for all Slave(s) to be 1173 * de-prepared after clock resume. 1174 */ 1175 list_for_each_entry(slave, &bus->slaves, node) { 1176 if (!slave->dev_num) 1177 continue; 1178 1179 if (slave->status != SDW_SLAVE_ATTACHED && 1180 slave->status != SDW_SLAVE_ALERT) 1181 continue; 1182 1183 /* Identify if Slave(s) are available on Bus */ 1184 is_slave = true; 1185 1186 ret = sdw_slave_clk_stop_callback(slave, SDW_CLK_STOP_MODE0, 1187 SDW_CLK_PRE_DEPREPARE); 1188 if (ret < 0) 1189 dev_warn(&slave->dev, "clock stop pre-deprepare cb failed:%d\n", ret); 1190 1191 /* Only de-prepare a Slave device if needed */ 1192 if (!slave->prop.simple_clk_stop_capable) { 1193 simple_clk_stop = false; 1194 1195 ret = sdw_slave_clk_stop_prepare(slave, SDW_CLK_STOP_MODE0, 1196 false); 1197 1198 if (ret < 0) 1199 dev_warn(&slave->dev, "clock stop deprepare failed:%d\n", ret); 1200 } 1201 } 1202 1203 /* Skip remaining clock stop de-preparation if no Slave is attached */ 1204 if (!is_slave) 1205 return 0; 1206 1207 /* 1208 * Don't wait for all Slaves to be ready if they follow the simple 1209 * state machine 1210 */ 1211 if (!simple_clk_stop) { 1212 ret = sdw_bus_wait_for_clk_prep_deprep(bus, SDW_BROADCAST_DEV_NUM); 1213 if (ret < 0) 1214 dev_warn(bus->dev, "clock stop deprepare wait failed:%d\n", ret); 1215 } 1216 1217 list_for_each_entry(slave, &bus->slaves, node) { 1218 if (!slave->dev_num) 1219 continue; 1220 1221 if (slave->status != SDW_SLAVE_ATTACHED && 1222 slave->status != SDW_SLAVE_ALERT) 1223 continue; 1224 1225 ret = sdw_slave_clk_stop_callback(slave, SDW_CLK_STOP_MODE0, 1226 SDW_CLK_POST_DEPREPARE); 1227 if (ret < 0) 1228 dev_warn(&slave->dev, "clock stop post-deprepare cb failed:%d\n", ret); 1229 } 1230 1231 return 0; 1232 } 1233 EXPORT_SYMBOL(sdw_bus_exit_clk_stop); 1234 1235 int sdw_configure_dpn_intr(struct sdw_slave *slave, 1236 int port, bool enable, int mask) 1237 { 1238 u32 addr; 1239 int ret; 1240 u8 val = 0; 1241 1242 if (slave->bus->params.s_data_mode != SDW_PORT_DATA_MODE_NORMAL) { 1243 dev_dbg(&slave->dev, "TEST FAIL interrupt %s\n", 1244 enable ? "on" : "off"); 1245 mask |= SDW_DPN_INT_TEST_FAIL; 1246 } 1247 1248 addr = SDW_DPN_INTMASK(port); 1249 1250 /* Set/Clear port ready interrupt mask */ 1251 if (enable) { 1252 val |= mask; 1253 val |= SDW_DPN_INT_PORT_READY; 1254 } else { 1255 val &= ~(mask); 1256 val &= ~SDW_DPN_INT_PORT_READY; 1257 } 1258 1259 ret = sdw_update_no_pm(slave, addr, (mask | SDW_DPN_INT_PORT_READY), val); 1260 if (ret < 0) 1261 dev_err(&slave->dev, 1262 "SDW_DPN_INTMASK write failed:%d\n", val); 1263 1264 return ret; 1265 } 1266 1267 static int sdw_slave_set_frequency(struct sdw_slave *slave) 1268 { 1269 u32 mclk_freq = slave->bus->prop.mclk_freq; 1270 u32 curr_freq = slave->bus->params.curr_dr_freq >> 1; 1271 unsigned int scale; 1272 u8 scale_index; 1273 u8 base; 1274 int ret; 1275 1276 /* 1277 * frequency base and scale registers are required for SDCA 1278 * devices. They may also be used for 1.2+/non-SDCA devices. 1279 * Driver can set the property, we will need a DisCo property 1280 * to discover this case from platform firmware. 1281 */ 1282 if (!slave->id.class_id && !slave->prop.clock_reg_supported) 1283 return 0; 1284 1285 if (!mclk_freq) { 1286 dev_err(&slave->dev, 1287 "no bus MCLK, cannot set SDW_SCP_BUS_CLOCK_BASE\n"); 1288 return -EINVAL; 1289 } 1290 1291 /* 1292 * map base frequency using Table 89 of SoundWire 1.2 spec. 1293 * The order of the tests just follows the specification, this 1294 * is not a selection between possible values or a search for 1295 * the best value but just a mapping. Only one case per platform 1296 * is relevant. 1297 * Some BIOS have inconsistent values for mclk_freq but a 1298 * correct root so we force the mclk_freq to avoid variations. 1299 */ 1300 if (!(19200000 % mclk_freq)) { 1301 mclk_freq = 19200000; 1302 base = SDW_SCP_BASE_CLOCK_19200000_HZ; 1303 } else if (!(24000000 % mclk_freq)) { 1304 mclk_freq = 24000000; 1305 base = SDW_SCP_BASE_CLOCK_24000000_HZ; 1306 } else if (!(24576000 % mclk_freq)) { 1307 mclk_freq = 24576000; 1308 base = SDW_SCP_BASE_CLOCK_24576000_HZ; 1309 } else if (!(22579200 % mclk_freq)) { 1310 mclk_freq = 22579200; 1311 base = SDW_SCP_BASE_CLOCK_22579200_HZ; 1312 } else if (!(32000000 % mclk_freq)) { 1313 mclk_freq = 32000000; 1314 base = SDW_SCP_BASE_CLOCK_32000000_HZ; 1315 } else { 1316 dev_err(&slave->dev, 1317 "Unsupported clock base, mclk %d\n", 1318 mclk_freq); 1319 return -EINVAL; 1320 } 1321 1322 if (mclk_freq % curr_freq) { 1323 dev_err(&slave->dev, 1324 "mclk %d is not multiple of bus curr_freq %d\n", 1325 mclk_freq, curr_freq); 1326 return -EINVAL; 1327 } 1328 1329 scale = mclk_freq / curr_freq; 1330 1331 /* 1332 * map scale to Table 90 of SoundWire 1.2 spec - and check 1333 * that the scale is a power of two and maximum 64 1334 */ 1335 scale_index = ilog2(scale); 1336 1337 if (BIT(scale_index) != scale || scale_index > 6) { 1338 dev_err(&slave->dev, 1339 "No match found for scale %d, bus mclk %d curr_freq %d\n", 1340 scale, mclk_freq, curr_freq); 1341 return -EINVAL; 1342 } 1343 scale_index++; 1344 1345 ret = sdw_write_no_pm(slave, SDW_SCP_BUS_CLOCK_BASE, base); 1346 if (ret < 0) { 1347 dev_err(&slave->dev, 1348 "SDW_SCP_BUS_CLOCK_BASE write failed:%d\n", ret); 1349 return ret; 1350 } 1351 1352 /* initialize scale for both banks */ 1353 ret = sdw_write_no_pm(slave, SDW_SCP_BUSCLOCK_SCALE_B0, scale_index); 1354 if (ret < 0) { 1355 dev_err(&slave->dev, 1356 "SDW_SCP_BUSCLOCK_SCALE_B0 write failed:%d\n", ret); 1357 return ret; 1358 } 1359 ret = sdw_write_no_pm(slave, SDW_SCP_BUSCLOCK_SCALE_B1, scale_index); 1360 if (ret < 0) 1361 dev_err(&slave->dev, 1362 "SDW_SCP_BUSCLOCK_SCALE_B1 write failed:%d\n", ret); 1363 1364 dev_dbg(&slave->dev, 1365 "Configured bus base %d, scale %d, mclk %d, curr_freq %d\n", 1366 base, scale_index, mclk_freq, curr_freq); 1367 1368 return ret; 1369 } 1370 1371 static int sdw_initialize_slave(struct sdw_slave *slave) 1372 { 1373 struct sdw_slave_prop *prop = &slave->prop; 1374 int status; 1375 int ret; 1376 u8 val; 1377 1378 ret = sdw_slave_set_frequency(slave); 1379 if (ret < 0) 1380 return ret; 1381 1382 if (slave->bus->prop.quirks & SDW_MASTER_QUIRKS_CLEAR_INITIAL_CLASH) { 1383 /* Clear bus clash interrupt before enabling interrupt mask */ 1384 status = sdw_read_no_pm(slave, SDW_SCP_INT1); 1385 if (status < 0) { 1386 dev_err(&slave->dev, 1387 "SDW_SCP_INT1 (BUS_CLASH) read failed:%d\n", status); 1388 return status; 1389 } 1390 if (status & SDW_SCP_INT1_BUS_CLASH) { 1391 dev_warn(&slave->dev, "Bus clash detected before INT mask is enabled\n"); 1392 ret = sdw_write_no_pm(slave, SDW_SCP_INT1, SDW_SCP_INT1_BUS_CLASH); 1393 if (ret < 0) { 1394 dev_err(&slave->dev, 1395 "SDW_SCP_INT1 (BUS_CLASH) write failed:%d\n", ret); 1396 return ret; 1397 } 1398 } 1399 } 1400 if ((slave->bus->prop.quirks & SDW_MASTER_QUIRKS_CLEAR_INITIAL_PARITY) && 1401 !(slave->prop.quirks & SDW_SLAVE_QUIRKS_INVALID_INITIAL_PARITY)) { 1402 /* Clear parity interrupt before enabling interrupt mask */ 1403 status = sdw_read_no_pm(slave, SDW_SCP_INT1); 1404 if (status < 0) { 1405 dev_err(&slave->dev, 1406 "SDW_SCP_INT1 (PARITY) read failed:%d\n", status); 1407 return status; 1408 } 1409 if (status & SDW_SCP_INT1_PARITY) { 1410 dev_warn(&slave->dev, "PARITY error detected before INT mask is enabled\n"); 1411 ret = sdw_write_no_pm(slave, SDW_SCP_INT1, SDW_SCP_INT1_PARITY); 1412 if (ret < 0) { 1413 dev_err(&slave->dev, 1414 "SDW_SCP_INT1 (PARITY) write failed:%d\n", ret); 1415 return ret; 1416 } 1417 } 1418 } 1419 1420 /* 1421 * Set SCP_INT1_MASK register, typically bus clash and 1422 * implementation-defined interrupt mask. The Parity detection 1423 * may not always be correct on startup so its use is 1424 * device-dependent, it might e.g. only be enabled in 1425 * steady-state after a couple of frames. 1426 */ 1427 val = slave->prop.scp_int1_mask; 1428 1429 /* Enable SCP interrupts */ 1430 ret = sdw_update_no_pm(slave, SDW_SCP_INTMASK1, val, val); 1431 if (ret < 0) { 1432 dev_err(&slave->dev, 1433 "SDW_SCP_INTMASK1 write failed:%d\n", ret); 1434 return ret; 1435 } 1436 1437 /* No need to continue if DP0 is not present */ 1438 if (!slave->prop.dp0_prop) 1439 return 0; 1440 1441 /* Enable DP0 interrupts */ 1442 val = prop->dp0_prop->imp_def_interrupts; 1443 val |= SDW_DP0_INT_PORT_READY | SDW_DP0_INT_BRA_FAILURE; 1444 1445 ret = sdw_update_no_pm(slave, SDW_DP0_INTMASK, val, val); 1446 if (ret < 0) 1447 dev_err(&slave->dev, 1448 "SDW_DP0_INTMASK read failed:%d\n", ret); 1449 return ret; 1450 } 1451 1452 static int sdw_handle_dp0_interrupt(struct sdw_slave *slave, u8 *slave_status) 1453 { 1454 u8 clear, impl_int_mask; 1455 int status, status2, ret, count = 0; 1456 1457 status = sdw_read_no_pm(slave, SDW_DP0_INT); 1458 if (status < 0) { 1459 dev_err(&slave->dev, 1460 "SDW_DP0_INT read failed:%d\n", status); 1461 return status; 1462 } 1463 1464 do { 1465 clear = status & ~SDW_DP0_INTERRUPTS; 1466 1467 if (status & SDW_DP0_INT_TEST_FAIL) { 1468 dev_err(&slave->dev, "Test fail for port 0\n"); 1469 clear |= SDW_DP0_INT_TEST_FAIL; 1470 } 1471 1472 /* 1473 * Assumption: PORT_READY interrupt will be received only for 1474 * ports implementing Channel Prepare state machine (CP_SM) 1475 */ 1476 1477 if (status & SDW_DP0_INT_PORT_READY) { 1478 complete(&slave->port_ready[0]); 1479 clear |= SDW_DP0_INT_PORT_READY; 1480 } 1481 1482 if (status & SDW_DP0_INT_BRA_FAILURE) { 1483 dev_err(&slave->dev, "BRA failed\n"); 1484 clear |= SDW_DP0_INT_BRA_FAILURE; 1485 } 1486 1487 impl_int_mask = SDW_DP0_INT_IMPDEF1 | 1488 SDW_DP0_INT_IMPDEF2 | SDW_DP0_INT_IMPDEF3; 1489 1490 if (status & impl_int_mask) { 1491 clear |= impl_int_mask; 1492 *slave_status = clear; 1493 } 1494 1495 /* clear the interrupts but don't touch reserved and SDCA_CASCADE fields */ 1496 ret = sdw_write_no_pm(slave, SDW_DP0_INT, clear); 1497 if (ret < 0) { 1498 dev_err(&slave->dev, 1499 "SDW_DP0_INT write failed:%d\n", ret); 1500 return ret; 1501 } 1502 1503 /* Read DP0 interrupt again */ 1504 status2 = sdw_read_no_pm(slave, SDW_DP0_INT); 1505 if (status2 < 0) { 1506 dev_err(&slave->dev, 1507 "SDW_DP0_INT read failed:%d\n", status2); 1508 return status2; 1509 } 1510 /* filter to limit loop to interrupts identified in the first status read */ 1511 status &= status2; 1512 1513 count++; 1514 1515 /* we can get alerts while processing so keep retrying */ 1516 } while ((status & SDW_DP0_INTERRUPTS) && (count < SDW_READ_INTR_CLEAR_RETRY)); 1517 1518 if (count == SDW_READ_INTR_CLEAR_RETRY) 1519 dev_warn(&slave->dev, "Reached MAX_RETRY on DP0 read\n"); 1520 1521 return ret; 1522 } 1523 1524 static int sdw_handle_port_interrupt(struct sdw_slave *slave, 1525 int port, u8 *slave_status) 1526 { 1527 u8 clear, impl_int_mask; 1528 int status, status2, ret, count = 0; 1529 u32 addr; 1530 1531 if (port == 0) 1532 return sdw_handle_dp0_interrupt(slave, slave_status); 1533 1534 addr = SDW_DPN_INT(port); 1535 status = sdw_read_no_pm(slave, addr); 1536 if (status < 0) { 1537 dev_err(&slave->dev, 1538 "SDW_DPN_INT read failed:%d\n", status); 1539 1540 return status; 1541 } 1542 1543 do { 1544 clear = status & ~SDW_DPN_INTERRUPTS; 1545 1546 if (status & SDW_DPN_INT_TEST_FAIL) { 1547 dev_err(&slave->dev, "Test fail for port:%d\n", port); 1548 clear |= SDW_DPN_INT_TEST_FAIL; 1549 } 1550 1551 /* 1552 * Assumption: PORT_READY interrupt will be received only 1553 * for ports implementing CP_SM. 1554 */ 1555 if (status & SDW_DPN_INT_PORT_READY) { 1556 complete(&slave->port_ready[port]); 1557 clear |= SDW_DPN_INT_PORT_READY; 1558 } 1559 1560 impl_int_mask = SDW_DPN_INT_IMPDEF1 | 1561 SDW_DPN_INT_IMPDEF2 | SDW_DPN_INT_IMPDEF3; 1562 1563 if (status & impl_int_mask) { 1564 clear |= impl_int_mask; 1565 *slave_status = clear; 1566 } 1567 1568 /* clear the interrupt but don't touch reserved fields */ 1569 ret = sdw_write_no_pm(slave, addr, clear); 1570 if (ret < 0) { 1571 dev_err(&slave->dev, 1572 "SDW_DPN_INT write failed:%d\n", ret); 1573 return ret; 1574 } 1575 1576 /* Read DPN interrupt again */ 1577 status2 = sdw_read_no_pm(slave, addr); 1578 if (status2 < 0) { 1579 dev_err(&slave->dev, 1580 "SDW_DPN_INT read failed:%d\n", status2); 1581 return status2; 1582 } 1583 /* filter to limit loop to interrupts identified in the first status read */ 1584 status &= status2; 1585 1586 count++; 1587 1588 /* we can get alerts while processing so keep retrying */ 1589 } while ((status & SDW_DPN_INTERRUPTS) && (count < SDW_READ_INTR_CLEAR_RETRY)); 1590 1591 if (count == SDW_READ_INTR_CLEAR_RETRY) 1592 dev_warn(&slave->dev, "Reached MAX_RETRY on port read"); 1593 1594 return ret; 1595 } 1596 1597 static int sdw_handle_slave_alerts(struct sdw_slave *slave) 1598 { 1599 struct sdw_slave_intr_status slave_intr; 1600 u8 clear = 0, bit, port_status[15] = {0}; 1601 int port_num, stat, ret, count = 0; 1602 unsigned long port; 1603 bool slave_notify; 1604 u8 sdca_cascade = 0; 1605 u8 buf, buf2[2]; 1606 bool parity_check; 1607 bool parity_quirk; 1608 1609 sdw_modify_slave_status(slave, SDW_SLAVE_ALERT); 1610 1611 ret = pm_runtime_get_sync(&slave->dev); 1612 if (ret < 0 && ret != -EACCES) { 1613 dev_err(&slave->dev, "Failed to resume device: %d\n", ret); 1614 pm_runtime_put_noidle(&slave->dev); 1615 return ret; 1616 } 1617 1618 /* Read Intstat 1, Intstat 2 and Intstat 3 registers */ 1619 ret = sdw_read_no_pm(slave, SDW_SCP_INT1); 1620 if (ret < 0) { 1621 dev_err(&slave->dev, 1622 "SDW_SCP_INT1 read failed:%d\n", ret); 1623 goto io_err; 1624 } 1625 buf = ret; 1626 1627 ret = sdw_nread_no_pm(slave, SDW_SCP_INTSTAT2, 2, buf2); 1628 if (ret < 0) { 1629 dev_err(&slave->dev, 1630 "SDW_SCP_INT2/3 read failed:%d\n", ret); 1631 goto io_err; 1632 } 1633 1634 if (slave->id.class_id) { 1635 ret = sdw_read_no_pm(slave, SDW_DP0_INT); 1636 if (ret < 0) { 1637 dev_err(&slave->dev, 1638 "SDW_DP0_INT read failed:%d\n", ret); 1639 goto io_err; 1640 } 1641 sdca_cascade = ret & SDW_DP0_SDCA_CASCADE; 1642 } 1643 1644 do { 1645 slave_notify = false; 1646 1647 /* 1648 * Check parity, bus clash and Slave (impl defined) 1649 * interrupt 1650 */ 1651 if (buf & SDW_SCP_INT1_PARITY) { 1652 parity_check = slave->prop.scp_int1_mask & SDW_SCP_INT1_PARITY; 1653 parity_quirk = !slave->first_interrupt_done && 1654 (slave->prop.quirks & SDW_SLAVE_QUIRKS_INVALID_INITIAL_PARITY); 1655 1656 if (parity_check && !parity_quirk) 1657 dev_err(&slave->dev, "Parity error detected\n"); 1658 clear |= SDW_SCP_INT1_PARITY; 1659 } 1660 1661 if (buf & SDW_SCP_INT1_BUS_CLASH) { 1662 if (slave->prop.scp_int1_mask & SDW_SCP_INT1_BUS_CLASH) 1663 dev_err(&slave->dev, "Bus clash detected\n"); 1664 clear |= SDW_SCP_INT1_BUS_CLASH; 1665 } 1666 1667 /* 1668 * When bus clash or parity errors are detected, such errors 1669 * are unlikely to be recoverable errors. 1670 * TODO: In such scenario, reset bus. Make this configurable 1671 * via sysfs property with bus reset being the default. 1672 */ 1673 1674 if (buf & SDW_SCP_INT1_IMPL_DEF) { 1675 if (slave->prop.scp_int1_mask & SDW_SCP_INT1_IMPL_DEF) { 1676 dev_dbg(&slave->dev, "Slave impl defined interrupt\n"); 1677 slave_notify = true; 1678 } 1679 clear |= SDW_SCP_INT1_IMPL_DEF; 1680 } 1681 1682 /* the SDCA interrupts are cleared in the codec driver .interrupt_callback() */ 1683 if (sdca_cascade) 1684 slave_notify = true; 1685 1686 /* Check port 0 - 3 interrupts */ 1687 port = buf & SDW_SCP_INT1_PORT0_3; 1688 1689 /* To get port number corresponding to bits, shift it */ 1690 port = FIELD_GET(SDW_SCP_INT1_PORT0_3, port); 1691 for_each_set_bit(bit, &port, 8) { 1692 sdw_handle_port_interrupt(slave, bit, 1693 &port_status[bit]); 1694 } 1695 1696 /* Check if cascade 2 interrupt is present */ 1697 if (buf & SDW_SCP_INT1_SCP2_CASCADE) { 1698 port = buf2[0] & SDW_SCP_INTSTAT2_PORT4_10; 1699 for_each_set_bit(bit, &port, 8) { 1700 /* scp2 ports start from 4 */ 1701 port_num = bit + 4; 1702 sdw_handle_port_interrupt(slave, 1703 port_num, 1704 &port_status[port_num]); 1705 } 1706 } 1707 1708 /* now check last cascade */ 1709 if (buf2[0] & SDW_SCP_INTSTAT2_SCP3_CASCADE) { 1710 port = buf2[1] & SDW_SCP_INTSTAT3_PORT11_14; 1711 for_each_set_bit(bit, &port, 8) { 1712 /* scp3 ports start from 11 */ 1713 port_num = bit + 11; 1714 sdw_handle_port_interrupt(slave, 1715 port_num, 1716 &port_status[port_num]); 1717 } 1718 } 1719 1720 /* Update the Slave driver */ 1721 if (slave_notify) { 1722 mutex_lock(&slave->sdw_dev_lock); 1723 1724 if (slave->probed) { 1725 struct device *dev = &slave->dev; 1726 struct sdw_driver *drv = drv_to_sdw_driver(dev->driver); 1727 1728 if (drv->ops && drv->ops->interrupt_callback) { 1729 slave_intr.sdca_cascade = sdca_cascade; 1730 slave_intr.control_port = clear; 1731 memcpy(slave_intr.port, &port_status, 1732 sizeof(slave_intr.port)); 1733 1734 drv->ops->interrupt_callback(slave, &slave_intr); 1735 } 1736 } 1737 1738 mutex_unlock(&slave->sdw_dev_lock); 1739 } 1740 1741 /* Ack interrupt */ 1742 ret = sdw_write_no_pm(slave, SDW_SCP_INT1, clear); 1743 if (ret < 0) { 1744 dev_err(&slave->dev, 1745 "SDW_SCP_INT1 write failed:%d\n", ret); 1746 goto io_err; 1747 } 1748 1749 /* at this point all initial interrupt sources were handled */ 1750 slave->first_interrupt_done = true; 1751 1752 /* 1753 * Read status again to ensure no new interrupts arrived 1754 * while servicing interrupts. 1755 */ 1756 ret = sdw_read_no_pm(slave, SDW_SCP_INT1); 1757 if (ret < 0) { 1758 dev_err(&slave->dev, 1759 "SDW_SCP_INT1 recheck read failed:%d\n", ret); 1760 goto io_err; 1761 } 1762 buf = ret; 1763 1764 ret = sdw_nread_no_pm(slave, SDW_SCP_INTSTAT2, 2, buf2); 1765 if (ret < 0) { 1766 dev_err(&slave->dev, 1767 "SDW_SCP_INT2/3 recheck read failed:%d\n", ret); 1768 goto io_err; 1769 } 1770 1771 if (slave->id.class_id) { 1772 ret = sdw_read_no_pm(slave, SDW_DP0_INT); 1773 if (ret < 0) { 1774 dev_err(&slave->dev, 1775 "SDW_DP0_INT recheck read failed:%d\n", ret); 1776 goto io_err; 1777 } 1778 sdca_cascade = ret & SDW_DP0_SDCA_CASCADE; 1779 } 1780 1781 /* 1782 * Make sure no interrupts are pending 1783 */ 1784 stat = buf || buf2[0] || buf2[1] || sdca_cascade; 1785 1786 /* 1787 * Exit loop if Slave is continuously in ALERT state even 1788 * after servicing the interrupt multiple times. 1789 */ 1790 count++; 1791 1792 /* we can get alerts while processing so keep retrying */ 1793 } while (stat != 0 && count < SDW_READ_INTR_CLEAR_RETRY); 1794 1795 if (count == SDW_READ_INTR_CLEAR_RETRY) 1796 dev_warn(&slave->dev, "Reached MAX_RETRY on alert read\n"); 1797 1798 io_err: 1799 pm_runtime_mark_last_busy(&slave->dev); 1800 pm_runtime_put_autosuspend(&slave->dev); 1801 1802 return ret; 1803 } 1804 1805 static int sdw_update_slave_status(struct sdw_slave *slave, 1806 enum sdw_slave_status status) 1807 { 1808 int ret = 0; 1809 1810 mutex_lock(&slave->sdw_dev_lock); 1811 1812 if (slave->probed) { 1813 struct device *dev = &slave->dev; 1814 struct sdw_driver *drv = drv_to_sdw_driver(dev->driver); 1815 1816 if (drv->ops && drv->ops->update_status) 1817 ret = drv->ops->update_status(slave, status); 1818 } 1819 1820 mutex_unlock(&slave->sdw_dev_lock); 1821 1822 return ret; 1823 } 1824 1825 /** 1826 * sdw_handle_slave_status() - Handle Slave status 1827 * @bus: SDW bus instance 1828 * @status: Status for all Slave(s) 1829 */ 1830 int sdw_handle_slave_status(struct sdw_bus *bus, 1831 enum sdw_slave_status status[]) 1832 { 1833 enum sdw_slave_status prev_status; 1834 struct sdw_slave *slave; 1835 bool attached_initializing, id_programmed; 1836 int i, ret = 0; 1837 1838 /* first check if any Slaves fell off the bus */ 1839 for (i = 1; i <= SDW_MAX_DEVICES; i++) { 1840 mutex_lock(&bus->bus_lock); 1841 if (test_bit(i, bus->assigned) == false) { 1842 mutex_unlock(&bus->bus_lock); 1843 continue; 1844 } 1845 mutex_unlock(&bus->bus_lock); 1846 1847 slave = sdw_get_slave(bus, i); 1848 if (!slave) 1849 continue; 1850 1851 if (status[i] == SDW_SLAVE_UNATTACHED && 1852 slave->status != SDW_SLAVE_UNATTACHED) { 1853 dev_warn(&slave->dev, "Slave %d state check1: UNATTACHED, status was %d\n", 1854 i, slave->status); 1855 sdw_modify_slave_status(slave, SDW_SLAVE_UNATTACHED); 1856 1857 /* Ensure driver knows that peripheral unattached */ 1858 ret = sdw_update_slave_status(slave, status[i]); 1859 if (ret < 0) 1860 dev_warn(&slave->dev, "Update Slave status failed:%d\n", ret); 1861 } 1862 } 1863 1864 if (status[0] == SDW_SLAVE_ATTACHED) { 1865 dev_dbg(bus->dev, "Slave attached, programming device number\n"); 1866 1867 /* 1868 * Programming a device number will have side effects, 1869 * so we deal with other devices at a later time. 1870 * This relies on those devices reporting ATTACHED, which will 1871 * trigger another call to this function. This will only 1872 * happen if at least one device ID was programmed. 1873 * Error returns from sdw_program_device_num() are currently 1874 * ignored because there's no useful recovery that can be done. 1875 * Returning the error here could result in the current status 1876 * of other devices not being handled, because if no device IDs 1877 * were programmed there's nothing to guarantee a status change 1878 * to trigger another call to this function. 1879 */ 1880 sdw_program_device_num(bus, &id_programmed); 1881 if (id_programmed) 1882 return 0; 1883 } 1884 1885 /* Continue to check other slave statuses */ 1886 for (i = 1; i <= SDW_MAX_DEVICES; i++) { 1887 mutex_lock(&bus->bus_lock); 1888 if (test_bit(i, bus->assigned) == false) { 1889 mutex_unlock(&bus->bus_lock); 1890 continue; 1891 } 1892 mutex_unlock(&bus->bus_lock); 1893 1894 slave = sdw_get_slave(bus, i); 1895 if (!slave) 1896 continue; 1897 1898 attached_initializing = false; 1899 1900 switch (status[i]) { 1901 case SDW_SLAVE_UNATTACHED: 1902 if (slave->status == SDW_SLAVE_UNATTACHED) 1903 break; 1904 1905 dev_warn(&slave->dev, "Slave %d state check2: UNATTACHED, status was %d\n", 1906 i, slave->status); 1907 1908 sdw_modify_slave_status(slave, SDW_SLAVE_UNATTACHED); 1909 break; 1910 1911 case SDW_SLAVE_ALERT: 1912 ret = sdw_handle_slave_alerts(slave); 1913 if (ret < 0) 1914 dev_err(&slave->dev, 1915 "Slave %d alert handling failed: %d\n", 1916 i, ret); 1917 break; 1918 1919 case SDW_SLAVE_ATTACHED: 1920 if (slave->status == SDW_SLAVE_ATTACHED) 1921 break; 1922 1923 prev_status = slave->status; 1924 sdw_modify_slave_status(slave, SDW_SLAVE_ATTACHED); 1925 1926 if (prev_status == SDW_SLAVE_ALERT) 1927 break; 1928 1929 attached_initializing = true; 1930 1931 ret = sdw_initialize_slave(slave); 1932 if (ret < 0) 1933 dev_err(&slave->dev, 1934 "Slave %d initialization failed: %d\n", 1935 i, ret); 1936 1937 break; 1938 1939 default: 1940 dev_err(&slave->dev, "Invalid slave %d status:%d\n", 1941 i, status[i]); 1942 break; 1943 } 1944 1945 ret = sdw_update_slave_status(slave, status[i]); 1946 if (ret < 0) 1947 dev_err(&slave->dev, 1948 "Update Slave status failed:%d\n", ret); 1949 if (attached_initializing) { 1950 dev_dbg(&slave->dev, 1951 "signaling initialization completion for Slave %d\n", 1952 slave->dev_num); 1953 1954 complete_all(&slave->initialization_complete); 1955 1956 /* 1957 * If the manager became pm_runtime active, the peripherals will be 1958 * restarted and attach, but their pm_runtime status may remain 1959 * suspended. If the 'update_slave_status' callback initiates 1960 * any sort of deferred processing, this processing would not be 1961 * cancelled on pm_runtime suspend. 1962 * To avoid such zombie states, we queue a request to resume. 1963 * This would be a no-op in case the peripheral was being resumed 1964 * by e.g. the ALSA/ASoC framework. 1965 */ 1966 pm_request_resume(&slave->dev); 1967 } 1968 } 1969 1970 return ret; 1971 } 1972 EXPORT_SYMBOL(sdw_handle_slave_status); 1973 1974 void sdw_clear_slave_status(struct sdw_bus *bus, u32 request) 1975 { 1976 struct sdw_slave *slave; 1977 int i; 1978 1979 /* Check all non-zero devices */ 1980 for (i = 1; i <= SDW_MAX_DEVICES; i++) { 1981 mutex_lock(&bus->bus_lock); 1982 if (test_bit(i, bus->assigned) == false) { 1983 mutex_unlock(&bus->bus_lock); 1984 continue; 1985 } 1986 mutex_unlock(&bus->bus_lock); 1987 1988 slave = sdw_get_slave(bus, i); 1989 if (!slave) 1990 continue; 1991 1992 if (slave->status != SDW_SLAVE_UNATTACHED) { 1993 sdw_modify_slave_status(slave, SDW_SLAVE_UNATTACHED); 1994 slave->first_interrupt_done = false; 1995 sdw_update_slave_status(slave, SDW_SLAVE_UNATTACHED); 1996 } 1997 1998 /* keep track of request, used in pm_runtime resume */ 1999 slave->unattach_request = request; 2000 } 2001 } 2002 EXPORT_SYMBOL(sdw_clear_slave_status); 2003