1 /* 2 * USB xHCI controller emulation 3 * 4 * Copyright (c) 2011 Securiforest 5 * Date: 2011-05-11 ; Author: Hector Martin <hector@marcansoft.com> 6 * Based on usb-ohci.c, emulates Renesas NEC USB 3.0 7 * 8 * This library is free software; you can redistribute it and/or 9 * modify it under the terms of the GNU Lesser General Public 10 * License as published by the Free Software Foundation; either 11 * version 2 of the License, or (at your option) any later version. 12 * 13 * This library is distributed in the hope that it will be useful, 14 * but WITHOUT ANY WARRANTY; without even the implied warranty of 15 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU 16 * Lesser General Public License for more details. 17 * 18 * You should have received a copy of the GNU Lesser General Public 19 * License along with this library; if not, see <http://www.gnu.org/licenses/>. 20 */ 21 #include "hw/hw.h" 22 #include "qemu-timer.h" 23 #include "hw/usb.h" 24 #include "hw/pci.h" 25 #include "hw/msi.h" 26 27 //#define DEBUG_XHCI 28 //#define DEBUG_DATA 29 30 #ifdef DEBUG_XHCI 31 #define DPRINTF(...) fprintf(stderr, __VA_ARGS__) 32 #else 33 #define DPRINTF(...) do {} while (0) 34 #endif 35 #define FIXME() do { fprintf(stderr, "FIXME %s:%d\n", \ 36 __func__, __LINE__); abort(); } while (0) 37 38 #define MAXSLOTS 8 39 #define MAXINTRS 1 40 41 #define USB2_PORTS 4 42 #define USB3_PORTS 4 43 44 #define MAXPORTS (USB2_PORTS+USB3_PORTS) 45 46 #define TD_QUEUE 24 47 #define BG_XFERS 8 48 #define BG_PKTS 8 49 50 /* Very pessimistic, let's hope it's enough for all cases */ 51 #define EV_QUEUE (((3*TD_QUEUE)+16)*MAXSLOTS) 52 /* Do not deliver ER Full events. NEC's driver does some things not bound 53 * to the specs when it gets them */ 54 #define ER_FULL_HACK 55 56 #define LEN_CAP 0x40 57 #define OFF_OPER LEN_CAP 58 #define LEN_OPER (0x400 + 0x10 * MAXPORTS) 59 #define OFF_RUNTIME ((OFF_OPER + LEN_OPER + 0x20) & ~0x1f) 60 #define LEN_RUNTIME (0x20 + MAXINTRS * 0x20) 61 #define OFF_DOORBELL (OFF_RUNTIME + LEN_RUNTIME) 62 #define LEN_DOORBELL ((MAXSLOTS + 1) * 0x20) 63 64 /* must be power of 2 */ 65 #define LEN_REGS 0x2000 66 67 #if (OFF_DOORBELL + LEN_DOORBELL) > LEN_REGS 68 # error Increase LEN_REGS 69 #endif 70 71 #if MAXINTRS > 1 72 # error TODO: only one interrupter supported 73 #endif 74 75 /* bit definitions */ 76 #define USBCMD_RS (1<<0) 77 #define USBCMD_HCRST (1<<1) 78 #define USBCMD_INTE (1<<2) 79 #define USBCMD_HSEE (1<<3) 80 #define USBCMD_LHCRST (1<<7) 81 #define USBCMD_CSS (1<<8) 82 #define USBCMD_CRS (1<<9) 83 #define USBCMD_EWE (1<<10) 84 #define USBCMD_EU3S (1<<11) 85 86 #define USBSTS_HCH (1<<0) 87 #define USBSTS_HSE (1<<2) 88 #define USBSTS_EINT (1<<3) 89 #define USBSTS_PCD (1<<4) 90 #define USBSTS_SSS (1<<8) 91 #define USBSTS_RSS (1<<9) 92 #define USBSTS_SRE (1<<10) 93 #define USBSTS_CNR (1<<11) 94 #define USBSTS_HCE (1<<12) 95 96 97 #define PORTSC_CCS (1<<0) 98 #define PORTSC_PED (1<<1) 99 #define PORTSC_OCA (1<<3) 100 #define PORTSC_PR (1<<4) 101 #define PORTSC_PLS_SHIFT 5 102 #define PORTSC_PLS_MASK 0xf 103 #define PORTSC_PP (1<<9) 104 #define PORTSC_SPEED_SHIFT 10 105 #define PORTSC_SPEED_MASK 0xf 106 #define PORTSC_SPEED_FULL (1<<10) 107 #define PORTSC_SPEED_LOW (2<<10) 108 #define PORTSC_SPEED_HIGH (3<<10) 109 #define PORTSC_SPEED_SUPER (4<<10) 110 #define PORTSC_PIC_SHIFT 14 111 #define PORTSC_PIC_MASK 0x3 112 #define PORTSC_LWS (1<<16) 113 #define PORTSC_CSC (1<<17) 114 #define PORTSC_PEC (1<<18) 115 #define PORTSC_WRC (1<<19) 116 #define PORTSC_OCC (1<<20) 117 #define PORTSC_PRC (1<<21) 118 #define PORTSC_PLC (1<<22) 119 #define PORTSC_CEC (1<<23) 120 #define PORTSC_CAS (1<<24) 121 #define PORTSC_WCE (1<<25) 122 #define PORTSC_WDE (1<<26) 123 #define PORTSC_WOE (1<<27) 124 #define PORTSC_DR (1<<30) 125 #define PORTSC_WPR (1<<31) 126 127 #define CRCR_RCS (1<<0) 128 #define CRCR_CS (1<<1) 129 #define CRCR_CA (1<<2) 130 #define CRCR_CRR (1<<3) 131 132 #define IMAN_IP (1<<0) 133 #define IMAN_IE (1<<1) 134 135 #define ERDP_EHB (1<<3) 136 137 #define TRB_SIZE 16 138 typedef struct XHCITRB { 139 uint64_t parameter; 140 uint32_t status; 141 uint32_t control; 142 dma_addr_t addr; 143 bool ccs; 144 } XHCITRB; 145 146 147 typedef enum TRBType { 148 TRB_RESERVED = 0, 149 TR_NORMAL, 150 TR_SETUP, 151 TR_DATA, 152 TR_STATUS, 153 TR_ISOCH, 154 TR_LINK, 155 TR_EVDATA, 156 TR_NOOP, 157 CR_ENABLE_SLOT, 158 CR_DISABLE_SLOT, 159 CR_ADDRESS_DEVICE, 160 CR_CONFIGURE_ENDPOINT, 161 CR_EVALUATE_CONTEXT, 162 CR_RESET_ENDPOINT, 163 CR_STOP_ENDPOINT, 164 CR_SET_TR_DEQUEUE, 165 CR_RESET_DEVICE, 166 CR_FORCE_EVENT, 167 CR_NEGOTIATE_BW, 168 CR_SET_LATENCY_TOLERANCE, 169 CR_GET_PORT_BANDWIDTH, 170 CR_FORCE_HEADER, 171 CR_NOOP, 172 ER_TRANSFER = 32, 173 ER_COMMAND_COMPLETE, 174 ER_PORT_STATUS_CHANGE, 175 ER_BANDWIDTH_REQUEST, 176 ER_DOORBELL, 177 ER_HOST_CONTROLLER, 178 ER_DEVICE_NOTIFICATION, 179 ER_MFINDEX_WRAP, 180 /* vendor specific bits */ 181 CR_VENDOR_VIA_CHALLENGE_RESPONSE = 48, 182 CR_VENDOR_NEC_FIRMWARE_REVISION = 49, 183 CR_VENDOR_NEC_CHALLENGE_RESPONSE = 50, 184 } TRBType; 185 186 #define CR_LINK TR_LINK 187 188 typedef enum TRBCCode { 189 CC_INVALID = 0, 190 CC_SUCCESS, 191 CC_DATA_BUFFER_ERROR, 192 CC_BABBLE_DETECTED, 193 CC_USB_TRANSACTION_ERROR, 194 CC_TRB_ERROR, 195 CC_STALL_ERROR, 196 CC_RESOURCE_ERROR, 197 CC_BANDWIDTH_ERROR, 198 CC_NO_SLOTS_ERROR, 199 CC_INVALID_STREAM_TYPE_ERROR, 200 CC_SLOT_NOT_ENABLED_ERROR, 201 CC_EP_NOT_ENABLED_ERROR, 202 CC_SHORT_PACKET, 203 CC_RING_UNDERRUN, 204 CC_RING_OVERRUN, 205 CC_VF_ER_FULL, 206 CC_PARAMETER_ERROR, 207 CC_BANDWIDTH_OVERRUN, 208 CC_CONTEXT_STATE_ERROR, 209 CC_NO_PING_RESPONSE_ERROR, 210 CC_EVENT_RING_FULL_ERROR, 211 CC_INCOMPATIBLE_DEVICE_ERROR, 212 CC_MISSED_SERVICE_ERROR, 213 CC_COMMAND_RING_STOPPED, 214 CC_COMMAND_ABORTED, 215 CC_STOPPED, 216 CC_STOPPED_LENGTH_INVALID, 217 CC_MAX_EXIT_LATENCY_TOO_LARGE_ERROR = 29, 218 CC_ISOCH_BUFFER_OVERRUN = 31, 219 CC_EVENT_LOST_ERROR, 220 CC_UNDEFINED_ERROR, 221 CC_INVALID_STREAM_ID_ERROR, 222 CC_SECONDARY_BANDWIDTH_ERROR, 223 CC_SPLIT_TRANSACTION_ERROR 224 } TRBCCode; 225 226 #define TRB_C (1<<0) 227 #define TRB_TYPE_SHIFT 10 228 #define TRB_TYPE_MASK 0x3f 229 #define TRB_TYPE(t) (((t).control >> TRB_TYPE_SHIFT) & TRB_TYPE_MASK) 230 231 #define TRB_EV_ED (1<<2) 232 233 #define TRB_TR_ENT (1<<1) 234 #define TRB_TR_ISP (1<<2) 235 #define TRB_TR_NS (1<<3) 236 #define TRB_TR_CH (1<<4) 237 #define TRB_TR_IOC (1<<5) 238 #define TRB_TR_IDT (1<<6) 239 #define TRB_TR_TBC_SHIFT 7 240 #define TRB_TR_TBC_MASK 0x3 241 #define TRB_TR_BEI (1<<9) 242 #define TRB_TR_TLBPC_SHIFT 16 243 #define TRB_TR_TLBPC_MASK 0xf 244 #define TRB_TR_FRAMEID_SHIFT 20 245 #define TRB_TR_FRAMEID_MASK 0x7ff 246 #define TRB_TR_SIA (1<<31) 247 248 #define TRB_TR_DIR (1<<16) 249 250 #define TRB_CR_SLOTID_SHIFT 24 251 #define TRB_CR_SLOTID_MASK 0xff 252 #define TRB_CR_EPID_SHIFT 16 253 #define TRB_CR_EPID_MASK 0x1f 254 255 #define TRB_CR_BSR (1<<9) 256 #define TRB_CR_DC (1<<9) 257 258 #define TRB_LK_TC (1<<1) 259 260 #define EP_TYPE_MASK 0x7 261 #define EP_TYPE_SHIFT 3 262 263 #define EP_STATE_MASK 0x7 264 #define EP_DISABLED (0<<0) 265 #define EP_RUNNING (1<<0) 266 #define EP_HALTED (2<<0) 267 #define EP_STOPPED (3<<0) 268 #define EP_ERROR (4<<0) 269 270 #define SLOT_STATE_MASK 0x1f 271 #define SLOT_STATE_SHIFT 27 272 #define SLOT_STATE(s) (((s)>>SLOT_STATE_SHIFT)&SLOT_STATE_MASK) 273 #define SLOT_ENABLED 0 274 #define SLOT_DEFAULT 1 275 #define SLOT_ADDRESSED 2 276 #define SLOT_CONFIGURED 3 277 278 #define SLOT_CONTEXT_ENTRIES_MASK 0x1f 279 #define SLOT_CONTEXT_ENTRIES_SHIFT 27 280 281 typedef enum EPType { 282 ET_INVALID = 0, 283 ET_ISO_OUT, 284 ET_BULK_OUT, 285 ET_INTR_OUT, 286 ET_CONTROL, 287 ET_ISO_IN, 288 ET_BULK_IN, 289 ET_INTR_IN, 290 } EPType; 291 292 typedef struct XHCIRing { 293 dma_addr_t base; 294 dma_addr_t dequeue; 295 bool ccs; 296 } XHCIRing; 297 298 typedef struct XHCIPort { 299 USBPort port; 300 uint32_t portsc; 301 } XHCIPort; 302 303 struct XHCIState; 304 typedef struct XHCIState XHCIState; 305 306 typedef struct XHCITransfer { 307 XHCIState *xhci; 308 USBPacket packet; 309 bool running_async; 310 bool running_retry; 311 bool cancelled; 312 bool complete; 313 bool backgrounded; 314 unsigned int iso_pkts; 315 unsigned int slotid; 316 unsigned int epid; 317 bool in_xfer; 318 bool iso_xfer; 319 bool bg_xfer; 320 321 unsigned int trb_count; 322 unsigned int trb_alloced; 323 XHCITRB *trbs; 324 325 unsigned int data_length; 326 unsigned int data_alloced; 327 uint8_t *data; 328 329 TRBCCode status; 330 331 unsigned int pkts; 332 unsigned int pktsize; 333 unsigned int cur_pkt; 334 } XHCITransfer; 335 336 typedef struct XHCIEPContext { 337 XHCIRing ring; 338 unsigned int next_xfer; 339 unsigned int comp_xfer; 340 XHCITransfer transfers[TD_QUEUE]; 341 XHCITransfer *retry; 342 bool bg_running; 343 bool bg_updating; 344 unsigned int next_bg; 345 XHCITransfer bg_transfers[BG_XFERS]; 346 EPType type; 347 dma_addr_t pctx; 348 unsigned int max_psize; 349 bool has_bg; 350 uint32_t state; 351 } XHCIEPContext; 352 353 typedef struct XHCISlot { 354 bool enabled; 355 dma_addr_t ctx; 356 unsigned int port; 357 unsigned int devaddr; 358 XHCIEPContext * eps[31]; 359 } XHCISlot; 360 361 typedef struct XHCIEvent { 362 TRBType type; 363 TRBCCode ccode; 364 uint64_t ptr; 365 uint32_t length; 366 uint32_t flags; 367 uint8_t slotid; 368 uint8_t epid; 369 } XHCIEvent; 370 371 struct XHCIState { 372 PCIDevice pci_dev; 373 USBBus bus; 374 qemu_irq irq; 375 MemoryRegion mem; 376 const char *name; 377 uint32_t msi; 378 unsigned int devaddr; 379 380 /* Operational Registers */ 381 uint32_t usbcmd; 382 uint32_t usbsts; 383 uint32_t dnctrl; 384 uint32_t crcr_low; 385 uint32_t crcr_high; 386 uint32_t dcbaap_low; 387 uint32_t dcbaap_high; 388 uint32_t config; 389 390 XHCIPort ports[MAXPORTS]; 391 XHCISlot slots[MAXSLOTS]; 392 393 /* Runtime Registers */ 394 uint32_t mfindex; 395 /* note: we only support one interrupter */ 396 uint32_t iman; 397 uint32_t imod; 398 uint32_t erstsz; 399 uint32_t erstba_low; 400 uint32_t erstba_high; 401 uint32_t erdp_low; 402 uint32_t erdp_high; 403 404 dma_addr_t er_start; 405 uint32_t er_size; 406 bool er_pcs; 407 unsigned int er_ep_idx; 408 bool er_full; 409 410 XHCIEvent ev_buffer[EV_QUEUE]; 411 unsigned int ev_buffer_put; 412 unsigned int ev_buffer_get; 413 414 XHCIRing cmd_ring; 415 }; 416 417 typedef struct XHCIEvRingSeg { 418 uint32_t addr_low; 419 uint32_t addr_high; 420 uint32_t size; 421 uint32_t rsvd; 422 } XHCIEvRingSeg; 423 424 #ifdef DEBUG_XHCI 425 static const char *TRBType_names[] = { 426 [TRB_RESERVED] = "TRB_RESERVED", 427 [TR_NORMAL] = "TR_NORMAL", 428 [TR_SETUP] = "TR_SETUP", 429 [TR_DATA] = "TR_DATA", 430 [TR_STATUS] = "TR_STATUS", 431 [TR_ISOCH] = "TR_ISOCH", 432 [TR_LINK] = "TR_LINK", 433 [TR_EVDATA] = "TR_EVDATA", 434 [TR_NOOP] = "TR_NOOP", 435 [CR_ENABLE_SLOT] = "CR_ENABLE_SLOT", 436 [CR_DISABLE_SLOT] = "CR_DISABLE_SLOT", 437 [CR_ADDRESS_DEVICE] = "CR_ADDRESS_DEVICE", 438 [CR_CONFIGURE_ENDPOINT] = "CR_CONFIGURE_ENDPOINT", 439 [CR_EVALUATE_CONTEXT] = "CR_EVALUATE_CONTEXT", 440 [CR_RESET_ENDPOINT] = "CR_RESET_ENDPOINT", 441 [CR_STOP_ENDPOINT] = "CR_STOP_ENDPOINT", 442 [CR_SET_TR_DEQUEUE] = "CR_SET_TR_DEQUEUE", 443 [CR_RESET_DEVICE] = "CR_RESET_DEVICE", 444 [CR_FORCE_EVENT] = "CR_FORCE_EVENT", 445 [CR_NEGOTIATE_BW] = "CR_NEGOTIATE_BW", 446 [CR_SET_LATENCY_TOLERANCE] = "CR_SET_LATENCY_TOLERANCE", 447 [CR_GET_PORT_BANDWIDTH] = "CR_GET_PORT_BANDWIDTH", 448 [CR_FORCE_HEADER] = "CR_FORCE_HEADER", 449 [CR_NOOP] = "CR_NOOP", 450 [ER_TRANSFER] = "ER_TRANSFER", 451 [ER_COMMAND_COMPLETE] = "ER_COMMAND_COMPLETE", 452 [ER_PORT_STATUS_CHANGE] = "ER_PORT_STATUS_CHANGE", 453 [ER_BANDWIDTH_REQUEST] = "ER_BANDWIDTH_REQUEST", 454 [ER_DOORBELL] = "ER_DOORBELL", 455 [ER_HOST_CONTROLLER] = "ER_HOST_CONTROLLER", 456 [ER_DEVICE_NOTIFICATION] = "ER_DEVICE_NOTIFICATION", 457 [ER_MFINDEX_WRAP] = "ER_MFINDEX_WRAP", 458 [CR_VENDOR_VIA_CHALLENGE_RESPONSE] = "CR_VENDOR_VIA_CHALLENGE_RESPONSE", 459 [CR_VENDOR_NEC_FIRMWARE_REVISION] = "CR_VENDOR_NEC_FIRMWARE_REVISION", 460 [CR_VENDOR_NEC_CHALLENGE_RESPONSE] = "CR_VENDOR_NEC_CHALLENGE_RESPONSE", 461 }; 462 463 static const char *lookup_name(uint32_t index, const char **list, uint32_t llen) 464 { 465 if (index >= llen || list[index] == NULL) { 466 return "???"; 467 } 468 return list[index]; 469 } 470 471 static const char *trb_name(XHCITRB *trb) 472 { 473 return lookup_name(TRB_TYPE(*trb), TRBType_names, 474 ARRAY_SIZE(TRBType_names)); 475 } 476 #endif 477 478 static void xhci_kick_ep(XHCIState *xhci, unsigned int slotid, 479 unsigned int epid); 480 481 static inline dma_addr_t xhci_addr64(uint32_t low, uint32_t high) 482 { 483 if (sizeof(dma_addr_t) == 4) { 484 return low; 485 } else { 486 return low | (((dma_addr_t)high << 16) << 16); 487 } 488 } 489 490 static inline dma_addr_t xhci_mask64(uint64_t addr) 491 { 492 if (sizeof(dma_addr_t) == 4) { 493 return addr & 0xffffffff; 494 } else { 495 return addr; 496 } 497 } 498 499 static void xhci_irq_update(XHCIState *xhci) 500 { 501 int level = 0; 502 503 if (xhci->iman & IMAN_IP && xhci->iman & IMAN_IE && 504 xhci->usbcmd & USBCMD_INTE) { 505 level = 1; 506 } 507 508 DPRINTF("xhci_irq_update(): %d\n", level); 509 510 if (xhci->msi && msi_enabled(&xhci->pci_dev)) { 511 if (level) { 512 DPRINTF("xhci_irq_update(): MSI signal\n"); 513 msi_notify(&xhci->pci_dev, 0); 514 } 515 } else { 516 qemu_set_irq(xhci->irq, level); 517 } 518 } 519 520 static inline int xhci_running(XHCIState *xhci) 521 { 522 return !(xhci->usbsts & USBSTS_HCH) && !xhci->er_full; 523 } 524 525 static void xhci_die(XHCIState *xhci) 526 { 527 xhci->usbsts |= USBSTS_HCE; 528 fprintf(stderr, "xhci: asserted controller error\n"); 529 } 530 531 static void xhci_write_event(XHCIState *xhci, XHCIEvent *event) 532 { 533 XHCITRB ev_trb; 534 dma_addr_t addr; 535 536 ev_trb.parameter = cpu_to_le64(event->ptr); 537 ev_trb.status = cpu_to_le32(event->length | (event->ccode << 24)); 538 ev_trb.control = (event->slotid << 24) | (event->epid << 16) | 539 event->flags | (event->type << TRB_TYPE_SHIFT); 540 if (xhci->er_pcs) { 541 ev_trb.control |= TRB_C; 542 } 543 ev_trb.control = cpu_to_le32(ev_trb.control); 544 545 DPRINTF("xhci_write_event(): [%d] %016"PRIx64" %08x %08x %s\n", 546 xhci->er_ep_idx, ev_trb.parameter, ev_trb.status, ev_trb.control, 547 trb_name(&ev_trb)); 548 549 addr = xhci->er_start + TRB_SIZE*xhci->er_ep_idx; 550 pci_dma_write(&xhci->pci_dev, addr, &ev_trb, TRB_SIZE); 551 552 xhci->er_ep_idx++; 553 if (xhci->er_ep_idx >= xhci->er_size) { 554 xhci->er_ep_idx = 0; 555 xhci->er_pcs = !xhci->er_pcs; 556 } 557 } 558 559 static void xhci_events_update(XHCIState *xhci) 560 { 561 dma_addr_t erdp; 562 unsigned int dp_idx; 563 bool do_irq = 0; 564 565 if (xhci->usbsts & USBSTS_HCH) { 566 return; 567 } 568 569 erdp = xhci_addr64(xhci->erdp_low, xhci->erdp_high); 570 if (erdp < xhci->er_start || 571 erdp >= (xhci->er_start + TRB_SIZE*xhci->er_size)) { 572 fprintf(stderr, "xhci: ERDP out of bounds: "DMA_ADDR_FMT"\n", erdp); 573 fprintf(stderr, "xhci: ER at "DMA_ADDR_FMT" len %d\n", 574 xhci->er_start, xhci->er_size); 575 xhci_die(xhci); 576 return; 577 } 578 dp_idx = (erdp - xhci->er_start) / TRB_SIZE; 579 assert(dp_idx < xhci->er_size); 580 581 /* NEC didn't read section 4.9.4 of the spec (v1.0 p139 top Note) and thus 582 * deadlocks when the ER is full. Hack it by holding off events until 583 * the driver decides to free at least half of the ring */ 584 if (xhci->er_full) { 585 int er_free = dp_idx - xhci->er_ep_idx; 586 if (er_free <= 0) { 587 er_free += xhci->er_size; 588 } 589 if (er_free < (xhci->er_size/2)) { 590 DPRINTF("xhci_events_update(): event ring still " 591 "more than half full (hack)\n"); 592 return; 593 } 594 } 595 596 while (xhci->ev_buffer_put != xhci->ev_buffer_get) { 597 assert(xhci->er_full); 598 if (((xhci->er_ep_idx+1) % xhci->er_size) == dp_idx) { 599 DPRINTF("xhci_events_update(): event ring full again\n"); 600 #ifndef ER_FULL_HACK 601 XHCIEvent full = {ER_HOST_CONTROLLER, CC_EVENT_RING_FULL_ERROR}; 602 xhci_write_event(xhci, &full); 603 #endif 604 do_irq = 1; 605 break; 606 } 607 XHCIEvent *event = &xhci->ev_buffer[xhci->ev_buffer_get]; 608 xhci_write_event(xhci, event); 609 xhci->ev_buffer_get++; 610 do_irq = 1; 611 if (xhci->ev_buffer_get == EV_QUEUE) { 612 xhci->ev_buffer_get = 0; 613 } 614 } 615 616 if (do_irq) { 617 xhci->erdp_low |= ERDP_EHB; 618 xhci->iman |= IMAN_IP; 619 xhci->usbsts |= USBSTS_EINT; 620 xhci_irq_update(xhci); 621 } 622 623 if (xhci->er_full && xhci->ev_buffer_put == xhci->ev_buffer_get) { 624 DPRINTF("xhci_events_update(): event ring no longer full\n"); 625 xhci->er_full = 0; 626 } 627 return; 628 } 629 630 static void xhci_event(XHCIState *xhci, XHCIEvent *event) 631 { 632 dma_addr_t erdp; 633 unsigned int dp_idx; 634 635 if (xhci->er_full) { 636 DPRINTF("xhci_event(): ER full, queueing\n"); 637 if (((xhci->ev_buffer_put+1) % EV_QUEUE) == xhci->ev_buffer_get) { 638 fprintf(stderr, "xhci: event queue full, dropping event!\n"); 639 return; 640 } 641 xhci->ev_buffer[xhci->ev_buffer_put++] = *event; 642 if (xhci->ev_buffer_put == EV_QUEUE) { 643 xhci->ev_buffer_put = 0; 644 } 645 return; 646 } 647 648 erdp = xhci_addr64(xhci->erdp_low, xhci->erdp_high); 649 if (erdp < xhci->er_start || 650 erdp >= (xhci->er_start + TRB_SIZE*xhci->er_size)) { 651 fprintf(stderr, "xhci: ERDP out of bounds: "DMA_ADDR_FMT"\n", erdp); 652 fprintf(stderr, "xhci: ER at "DMA_ADDR_FMT" len %d\n", 653 xhci->er_start, xhci->er_size); 654 xhci_die(xhci); 655 return; 656 } 657 658 dp_idx = (erdp - xhci->er_start) / TRB_SIZE; 659 assert(dp_idx < xhci->er_size); 660 661 if ((xhci->er_ep_idx+1) % xhci->er_size == dp_idx) { 662 DPRINTF("xhci_event(): ER full, queueing\n"); 663 #ifndef ER_FULL_HACK 664 XHCIEvent full = {ER_HOST_CONTROLLER, CC_EVENT_RING_FULL_ERROR}; 665 xhci_write_event(xhci, &full); 666 #endif 667 xhci->er_full = 1; 668 if (((xhci->ev_buffer_put+1) % EV_QUEUE) == xhci->ev_buffer_get) { 669 fprintf(stderr, "xhci: event queue full, dropping event!\n"); 670 return; 671 } 672 xhci->ev_buffer[xhci->ev_buffer_put++] = *event; 673 if (xhci->ev_buffer_put == EV_QUEUE) { 674 xhci->ev_buffer_put = 0; 675 } 676 } else { 677 xhci_write_event(xhci, event); 678 } 679 680 xhci->erdp_low |= ERDP_EHB; 681 xhci->iman |= IMAN_IP; 682 xhci->usbsts |= USBSTS_EINT; 683 684 xhci_irq_update(xhci); 685 } 686 687 static void xhci_ring_init(XHCIState *xhci, XHCIRing *ring, 688 dma_addr_t base) 689 { 690 ring->base = base; 691 ring->dequeue = base; 692 ring->ccs = 1; 693 } 694 695 static TRBType xhci_ring_fetch(XHCIState *xhci, XHCIRing *ring, XHCITRB *trb, 696 dma_addr_t *addr) 697 { 698 while (1) { 699 TRBType type; 700 pci_dma_read(&xhci->pci_dev, ring->dequeue, trb, TRB_SIZE); 701 trb->addr = ring->dequeue; 702 trb->ccs = ring->ccs; 703 le64_to_cpus(&trb->parameter); 704 le32_to_cpus(&trb->status); 705 le32_to_cpus(&trb->control); 706 707 DPRINTF("xhci: TRB fetched [" DMA_ADDR_FMT "]: " 708 "%016" PRIx64 " %08x %08x %s\n", 709 ring->dequeue, trb->parameter, trb->status, trb->control, 710 trb_name(trb)); 711 712 if ((trb->control & TRB_C) != ring->ccs) { 713 return 0; 714 } 715 716 type = TRB_TYPE(*trb); 717 718 if (type != TR_LINK) { 719 if (addr) { 720 *addr = ring->dequeue; 721 } 722 ring->dequeue += TRB_SIZE; 723 return type; 724 } else { 725 ring->dequeue = xhci_mask64(trb->parameter); 726 if (trb->control & TRB_LK_TC) { 727 ring->ccs = !ring->ccs; 728 } 729 } 730 } 731 } 732 733 static int xhci_ring_chain_length(XHCIState *xhci, const XHCIRing *ring) 734 { 735 XHCITRB trb; 736 int length = 0; 737 dma_addr_t dequeue = ring->dequeue; 738 bool ccs = ring->ccs; 739 /* hack to bundle together the two/three TDs that make a setup transfer */ 740 bool control_td_set = 0; 741 742 while (1) { 743 TRBType type; 744 pci_dma_read(&xhci->pci_dev, dequeue, &trb, TRB_SIZE); 745 le64_to_cpus(&trb.parameter); 746 le32_to_cpus(&trb.status); 747 le32_to_cpus(&trb.control); 748 749 DPRINTF("xhci: TRB peeked [" DMA_ADDR_FMT "]: " 750 "%016" PRIx64 " %08x %08x\n", 751 dequeue, trb.parameter, trb.status, trb.control); 752 753 if ((trb.control & TRB_C) != ccs) { 754 return -length; 755 } 756 757 type = TRB_TYPE(trb); 758 759 if (type == TR_LINK) { 760 dequeue = xhci_mask64(trb.parameter); 761 if (trb.control & TRB_LK_TC) { 762 ccs = !ccs; 763 } 764 continue; 765 } 766 767 length += 1; 768 dequeue += TRB_SIZE; 769 770 if (type == TR_SETUP) { 771 control_td_set = 1; 772 } else if (type == TR_STATUS) { 773 control_td_set = 0; 774 } 775 776 if (!control_td_set && !(trb.control & TRB_TR_CH)) { 777 return length; 778 } 779 } 780 } 781 782 static void xhci_er_reset(XHCIState *xhci) 783 { 784 XHCIEvRingSeg seg; 785 786 /* cache the (sole) event ring segment location */ 787 if (xhci->erstsz != 1) { 788 fprintf(stderr, "xhci: invalid value for ERSTSZ: %d\n", xhci->erstsz); 789 xhci_die(xhci); 790 return; 791 } 792 dma_addr_t erstba = xhci_addr64(xhci->erstba_low, xhci->erstba_high); 793 pci_dma_read(&xhci->pci_dev, erstba, &seg, sizeof(seg)); 794 le32_to_cpus(&seg.addr_low); 795 le32_to_cpus(&seg.addr_high); 796 le32_to_cpus(&seg.size); 797 if (seg.size < 16 || seg.size > 4096) { 798 fprintf(stderr, "xhci: invalid value for segment size: %d\n", seg.size); 799 xhci_die(xhci); 800 return; 801 } 802 xhci->er_start = xhci_addr64(seg.addr_low, seg.addr_high); 803 xhci->er_size = seg.size; 804 805 xhci->er_ep_idx = 0; 806 xhci->er_pcs = 1; 807 xhci->er_full = 0; 808 809 DPRINTF("xhci: event ring:" DMA_ADDR_FMT " [%d]\n", 810 xhci->er_start, xhci->er_size); 811 } 812 813 static void xhci_run(XHCIState *xhci) 814 { 815 DPRINTF("xhci_run()\n"); 816 817 xhci->usbsts &= ~USBSTS_HCH; 818 } 819 820 static void xhci_stop(XHCIState *xhci) 821 { 822 DPRINTF("xhci_stop()\n"); 823 xhci->usbsts |= USBSTS_HCH; 824 xhci->crcr_low &= ~CRCR_CRR; 825 } 826 827 static void xhci_set_ep_state(XHCIState *xhci, XHCIEPContext *epctx, 828 uint32_t state) 829 { 830 uint32_t ctx[5]; 831 if (epctx->state == state) { 832 return; 833 } 834 835 pci_dma_read(&xhci->pci_dev, epctx->pctx, ctx, sizeof(ctx)); 836 ctx[0] &= ~EP_STATE_MASK; 837 ctx[0] |= state; 838 ctx[2] = epctx->ring.dequeue | epctx->ring.ccs; 839 ctx[3] = (epctx->ring.dequeue >> 16) >> 16; 840 DPRINTF("xhci: set epctx: " DMA_ADDR_FMT " state=%d dequeue=%08x%08x\n", 841 epctx->pctx, state, ctx[3], ctx[2]); 842 pci_dma_write(&xhci->pci_dev, epctx->pctx, ctx, sizeof(ctx)); 843 epctx->state = state; 844 } 845 846 static TRBCCode xhci_enable_ep(XHCIState *xhci, unsigned int slotid, 847 unsigned int epid, dma_addr_t pctx, 848 uint32_t *ctx) 849 { 850 XHCISlot *slot; 851 XHCIEPContext *epctx; 852 dma_addr_t dequeue; 853 int i; 854 855 assert(slotid >= 1 && slotid <= MAXSLOTS); 856 assert(epid >= 1 && epid <= 31); 857 858 DPRINTF("xhci_enable_ep(%d, %d)\n", slotid, epid); 859 860 slot = &xhci->slots[slotid-1]; 861 if (slot->eps[epid-1]) { 862 fprintf(stderr, "xhci: slot %d ep %d already enabled!\n", slotid, epid); 863 return CC_TRB_ERROR; 864 } 865 866 epctx = g_malloc(sizeof(XHCIEPContext)); 867 memset(epctx, 0, sizeof(XHCIEPContext)); 868 869 slot->eps[epid-1] = epctx; 870 871 dequeue = xhci_addr64(ctx[2] & ~0xf, ctx[3]); 872 xhci_ring_init(xhci, &epctx->ring, dequeue); 873 epctx->ring.ccs = ctx[2] & 1; 874 875 epctx->type = (ctx[1] >> EP_TYPE_SHIFT) & EP_TYPE_MASK; 876 DPRINTF("xhci: endpoint %d.%d type is %d\n", epid/2, epid%2, epctx->type); 877 epctx->pctx = pctx; 878 epctx->max_psize = ctx[1]>>16; 879 epctx->max_psize *= 1+((ctx[1]>>8)&0xff); 880 epctx->has_bg = false; 881 if (epctx->type == ET_ISO_IN) { 882 epctx->has_bg = true; 883 } 884 DPRINTF("xhci: endpoint %d.%d max transaction (burst) size is %d\n", 885 epid/2, epid%2, epctx->max_psize); 886 for (i = 0; i < ARRAY_SIZE(epctx->transfers); i++) { 887 usb_packet_init(&epctx->transfers[i].packet); 888 } 889 890 epctx->state = EP_RUNNING; 891 ctx[0] &= ~EP_STATE_MASK; 892 ctx[0] |= EP_RUNNING; 893 894 return CC_SUCCESS; 895 } 896 897 static int xhci_ep_nuke_xfers(XHCIState *xhci, unsigned int slotid, 898 unsigned int epid) 899 { 900 XHCISlot *slot; 901 XHCIEPContext *epctx; 902 int i, xferi, killed = 0; 903 assert(slotid >= 1 && slotid <= MAXSLOTS); 904 assert(epid >= 1 && epid <= 31); 905 906 DPRINTF("xhci_ep_nuke_xfers(%d, %d)\n", slotid, epid); 907 908 slot = &xhci->slots[slotid-1]; 909 910 if (!slot->eps[epid-1]) { 911 return 0; 912 } 913 914 epctx = slot->eps[epid-1]; 915 916 xferi = epctx->next_xfer; 917 for (i = 0; i < TD_QUEUE; i++) { 918 XHCITransfer *t = &epctx->transfers[xferi]; 919 if (t->running_async) { 920 usb_cancel_packet(&t->packet); 921 t->running_async = 0; 922 t->cancelled = 1; 923 DPRINTF("xhci: cancelling transfer %d, waiting for it to complete...\n", i); 924 killed++; 925 } 926 if (t->running_retry) { 927 t->running_retry = 0; 928 epctx->retry = NULL; 929 } 930 if (t->backgrounded) { 931 t->backgrounded = 0; 932 } 933 if (t->trbs) { 934 g_free(t->trbs); 935 } 936 if (t->data) { 937 g_free(t->data); 938 } 939 940 t->trbs = NULL; 941 t->data = NULL; 942 t->trb_count = t->trb_alloced = 0; 943 t->data_length = t->data_alloced = 0; 944 xferi = (xferi + 1) % TD_QUEUE; 945 } 946 if (epctx->has_bg) { 947 xferi = epctx->next_bg; 948 for (i = 0; i < BG_XFERS; i++) { 949 XHCITransfer *t = &epctx->bg_transfers[xferi]; 950 if (t->running_async) { 951 usb_cancel_packet(&t->packet); 952 t->running_async = 0; 953 t->cancelled = 1; 954 DPRINTF("xhci: cancelling bg transfer %d, waiting for it to complete...\n", i); 955 killed++; 956 } 957 if (t->data) { 958 g_free(t->data); 959 } 960 961 t->data = NULL; 962 xferi = (xferi + 1) % BG_XFERS; 963 } 964 } 965 return killed; 966 } 967 968 static TRBCCode xhci_disable_ep(XHCIState *xhci, unsigned int slotid, 969 unsigned int epid) 970 { 971 XHCISlot *slot; 972 XHCIEPContext *epctx; 973 974 assert(slotid >= 1 && slotid <= MAXSLOTS); 975 assert(epid >= 1 && epid <= 31); 976 977 DPRINTF("xhci_disable_ep(%d, %d)\n", slotid, epid); 978 979 slot = &xhci->slots[slotid-1]; 980 981 if (!slot->eps[epid-1]) { 982 DPRINTF("xhci: slot %d ep %d already disabled\n", slotid, epid); 983 return CC_SUCCESS; 984 } 985 986 xhci_ep_nuke_xfers(xhci, slotid, epid); 987 988 epctx = slot->eps[epid-1]; 989 990 xhci_set_ep_state(xhci, epctx, EP_DISABLED); 991 992 g_free(epctx); 993 slot->eps[epid-1] = NULL; 994 995 return CC_SUCCESS; 996 } 997 998 static TRBCCode xhci_stop_ep(XHCIState *xhci, unsigned int slotid, 999 unsigned int epid) 1000 { 1001 XHCISlot *slot; 1002 XHCIEPContext *epctx; 1003 1004 DPRINTF("xhci_stop_ep(%d, %d)\n", slotid, epid); 1005 1006 assert(slotid >= 1 && slotid <= MAXSLOTS); 1007 1008 if (epid < 1 || epid > 31) { 1009 fprintf(stderr, "xhci: bad ep %d\n", epid); 1010 return CC_TRB_ERROR; 1011 } 1012 1013 slot = &xhci->slots[slotid-1]; 1014 1015 if (!slot->eps[epid-1]) { 1016 DPRINTF("xhci: slot %d ep %d not enabled\n", slotid, epid); 1017 return CC_EP_NOT_ENABLED_ERROR; 1018 } 1019 1020 if (xhci_ep_nuke_xfers(xhci, slotid, epid) > 0) { 1021 fprintf(stderr, "xhci: FIXME: endpoint stopped w/ xfers running, " 1022 "data might be lost\n"); 1023 } 1024 1025 epctx = slot->eps[epid-1]; 1026 1027 xhci_set_ep_state(xhci, epctx, EP_STOPPED); 1028 1029 return CC_SUCCESS; 1030 } 1031 1032 static TRBCCode xhci_reset_ep(XHCIState *xhci, unsigned int slotid, 1033 unsigned int epid) 1034 { 1035 XHCISlot *slot; 1036 XHCIEPContext *epctx; 1037 USBDevice *dev; 1038 1039 assert(slotid >= 1 && slotid <= MAXSLOTS); 1040 1041 DPRINTF("xhci_reset_ep(%d, %d)\n", slotid, epid); 1042 1043 if (epid < 1 || epid > 31) { 1044 fprintf(stderr, "xhci: bad ep %d\n", epid); 1045 return CC_TRB_ERROR; 1046 } 1047 1048 slot = &xhci->slots[slotid-1]; 1049 1050 if (!slot->eps[epid-1]) { 1051 DPRINTF("xhci: slot %d ep %d not enabled\n", slotid, epid); 1052 return CC_EP_NOT_ENABLED_ERROR; 1053 } 1054 1055 epctx = slot->eps[epid-1]; 1056 1057 if (epctx->state != EP_HALTED) { 1058 fprintf(stderr, "xhci: reset EP while EP %d not halted (%d)\n", 1059 epid, epctx->state); 1060 return CC_CONTEXT_STATE_ERROR; 1061 } 1062 1063 if (xhci_ep_nuke_xfers(xhci, slotid, epid) > 0) { 1064 fprintf(stderr, "xhci: FIXME: endpoint reset w/ xfers running, " 1065 "data might be lost\n"); 1066 } 1067 1068 uint8_t ep = epid>>1; 1069 1070 if (epid & 1) { 1071 ep |= 0x80; 1072 } 1073 1074 dev = xhci->ports[xhci->slots[slotid-1].port-1].port.dev; 1075 if (!dev) { 1076 return CC_USB_TRANSACTION_ERROR; 1077 } 1078 1079 xhci_set_ep_state(xhci, epctx, EP_STOPPED); 1080 1081 return CC_SUCCESS; 1082 } 1083 1084 static TRBCCode xhci_set_ep_dequeue(XHCIState *xhci, unsigned int slotid, 1085 unsigned int epid, uint64_t pdequeue) 1086 { 1087 XHCISlot *slot; 1088 XHCIEPContext *epctx; 1089 dma_addr_t dequeue; 1090 1091 assert(slotid >= 1 && slotid <= MAXSLOTS); 1092 1093 if (epid < 1 || epid > 31) { 1094 fprintf(stderr, "xhci: bad ep %d\n", epid); 1095 return CC_TRB_ERROR; 1096 } 1097 1098 DPRINTF("xhci_set_ep_dequeue(%d, %d, %016"PRIx64")\n", slotid, epid, pdequeue); 1099 dequeue = xhci_mask64(pdequeue); 1100 1101 slot = &xhci->slots[slotid-1]; 1102 1103 if (!slot->eps[epid-1]) { 1104 DPRINTF("xhci: slot %d ep %d not enabled\n", slotid, epid); 1105 return CC_EP_NOT_ENABLED_ERROR; 1106 } 1107 1108 epctx = slot->eps[epid-1]; 1109 1110 1111 if (epctx->state != EP_STOPPED) { 1112 fprintf(stderr, "xhci: set EP dequeue pointer while EP %d not stopped\n", epid); 1113 return CC_CONTEXT_STATE_ERROR; 1114 } 1115 1116 xhci_ring_init(xhci, &epctx->ring, dequeue & ~0xF); 1117 epctx->ring.ccs = dequeue & 1; 1118 1119 xhci_set_ep_state(xhci, epctx, EP_STOPPED); 1120 1121 return CC_SUCCESS; 1122 } 1123 1124 static int xhci_xfer_data(XHCITransfer *xfer, uint8_t *data, 1125 unsigned int length, bool in_xfer, bool out_xfer, 1126 bool report) 1127 { 1128 int i; 1129 uint32_t edtla = 0; 1130 unsigned int transferred = 0; 1131 unsigned int left = length; 1132 bool reported = 0; 1133 bool shortpkt = 0; 1134 XHCIEvent event = {ER_TRANSFER, CC_SUCCESS}; 1135 XHCIState *xhci = xfer->xhci; 1136 1137 DPRINTF("xhci_xfer_data(len=%d, in_xfer=%d, out_xfer=%d, report=%d)\n", 1138 length, in_xfer, out_xfer, report); 1139 1140 assert(!(in_xfer && out_xfer)); 1141 1142 for (i = 0; i < xfer->trb_count; i++) { 1143 XHCITRB *trb = &xfer->trbs[i]; 1144 dma_addr_t addr; 1145 unsigned int chunk = 0; 1146 1147 switch (TRB_TYPE(*trb)) { 1148 case TR_DATA: 1149 if ((!(trb->control & TRB_TR_DIR)) != (!in_xfer)) { 1150 fprintf(stderr, "xhci: data direction mismatch for TR_DATA\n"); 1151 xhci_die(xhci); 1152 return transferred; 1153 } 1154 /* fallthrough */ 1155 case TR_NORMAL: 1156 case TR_ISOCH: 1157 addr = xhci_mask64(trb->parameter); 1158 chunk = trb->status & 0x1ffff; 1159 if (chunk > left) { 1160 chunk = left; 1161 shortpkt = 1; 1162 } 1163 if (in_xfer || out_xfer) { 1164 if (trb->control & TRB_TR_IDT) { 1165 uint64_t idata; 1166 if (chunk > 8 || in_xfer) { 1167 fprintf(stderr, "xhci: invalid immediate data TRB\n"); 1168 xhci_die(xhci); 1169 return transferred; 1170 } 1171 idata = le64_to_cpu(trb->parameter); 1172 memcpy(data, &idata, chunk); 1173 } else { 1174 DPRINTF("xhci_xfer_data: r/w(%d) %d bytes at " 1175 DMA_ADDR_FMT "\n", in_xfer, chunk, addr); 1176 if (in_xfer) { 1177 pci_dma_write(&xhci->pci_dev, addr, data, chunk); 1178 } else { 1179 pci_dma_read(&xhci->pci_dev, addr, data, chunk); 1180 } 1181 #ifdef DEBUG_DATA 1182 unsigned int count = chunk; 1183 int i; 1184 if (count > 16) { 1185 count = 16; 1186 } 1187 DPRINTF(" ::"); 1188 for (i = 0; i < count; i++) { 1189 DPRINTF(" %02x", data[i]); 1190 } 1191 DPRINTF("\n"); 1192 #endif 1193 } 1194 } 1195 left -= chunk; 1196 data += chunk; 1197 edtla += chunk; 1198 transferred += chunk; 1199 break; 1200 case TR_STATUS: 1201 reported = 0; 1202 shortpkt = 0; 1203 break; 1204 } 1205 1206 if (report && !reported && (trb->control & TRB_TR_IOC || 1207 (shortpkt && (trb->control & TRB_TR_ISP)))) { 1208 event.slotid = xfer->slotid; 1209 event.epid = xfer->epid; 1210 event.length = (trb->status & 0x1ffff) - chunk; 1211 event.flags = 0; 1212 event.ptr = trb->addr; 1213 if (xfer->status == CC_SUCCESS) { 1214 event.ccode = shortpkt ? CC_SHORT_PACKET : CC_SUCCESS; 1215 } else { 1216 event.ccode = xfer->status; 1217 } 1218 if (TRB_TYPE(*trb) == TR_EVDATA) { 1219 event.ptr = trb->parameter; 1220 event.flags |= TRB_EV_ED; 1221 event.length = edtla & 0xffffff; 1222 DPRINTF("xhci_xfer_data: EDTLA=%d\n", event.length); 1223 edtla = 0; 1224 } 1225 xhci_event(xhci, &event); 1226 reported = 1; 1227 } 1228 } 1229 return transferred; 1230 } 1231 1232 static void xhci_stall_ep(XHCITransfer *xfer) 1233 { 1234 XHCIState *xhci = xfer->xhci; 1235 XHCISlot *slot = &xhci->slots[xfer->slotid-1]; 1236 XHCIEPContext *epctx = slot->eps[xfer->epid-1]; 1237 1238 epctx->ring.dequeue = xfer->trbs[0].addr; 1239 epctx->ring.ccs = xfer->trbs[0].ccs; 1240 xhci_set_ep_state(xhci, epctx, EP_HALTED); 1241 DPRINTF("xhci: stalled slot %d ep %d\n", xfer->slotid, xfer->epid); 1242 DPRINTF("xhci: will continue at "DMA_ADDR_FMT"\n", epctx->ring.dequeue); 1243 } 1244 1245 static int xhci_submit(XHCIState *xhci, XHCITransfer *xfer, 1246 XHCIEPContext *epctx); 1247 1248 static void xhci_bg_update(XHCIState *xhci, XHCIEPContext *epctx) 1249 { 1250 if (epctx->bg_updating) { 1251 return; 1252 } 1253 DPRINTF("xhci_bg_update(%p, %p)\n", xhci, epctx); 1254 assert(epctx->has_bg); 1255 DPRINTF("xhci: fg=%d bg=%d\n", epctx->comp_xfer, epctx->next_bg); 1256 epctx->bg_updating = 1; 1257 while (epctx->transfers[epctx->comp_xfer].backgrounded && 1258 epctx->bg_transfers[epctx->next_bg].complete) { 1259 XHCITransfer *fg = &epctx->transfers[epctx->comp_xfer]; 1260 XHCITransfer *bg = &epctx->bg_transfers[epctx->next_bg]; 1261 #if 0 1262 DPRINTF("xhci: completing fg %d from bg %d.%d (stat: %d)\n", 1263 epctx->comp_xfer, epctx->next_bg, bg->cur_pkt, 1264 bg->usbxfer->iso_packet_desc[bg->cur_pkt].status 1265 ); 1266 #endif 1267 assert(epctx->type == ET_ISO_IN); 1268 assert(bg->iso_xfer); 1269 assert(bg->in_xfer); 1270 uint8_t *p = bg->data + bg->cur_pkt * bg->pktsize; 1271 #if 0 1272 int len = bg->usbxfer->iso_packet_desc[bg->cur_pkt].actual_length; 1273 fg->status = libusb_to_ccode(bg->usbxfer->iso_packet_desc[bg->cur_pkt].status); 1274 #else 1275 int len = 0; 1276 FIXME(); 1277 #endif 1278 fg->complete = 1; 1279 fg->backgrounded = 0; 1280 1281 if (fg->status == CC_STALL_ERROR) { 1282 xhci_stall_ep(fg); 1283 } 1284 1285 xhci_xfer_data(fg, p, len, 1, 0, 1); 1286 1287 epctx->comp_xfer++; 1288 if (epctx->comp_xfer == TD_QUEUE) { 1289 epctx->comp_xfer = 0; 1290 } 1291 DPRINTF("next fg xfer: %d\n", epctx->comp_xfer); 1292 bg->cur_pkt++; 1293 if (bg->cur_pkt == bg->pkts) { 1294 bg->complete = 0; 1295 if (xhci_submit(xhci, bg, epctx) < 0) { 1296 fprintf(stderr, "xhci: bg resubmit failed\n"); 1297 } 1298 epctx->next_bg++; 1299 if (epctx->next_bg == BG_XFERS) { 1300 epctx->next_bg = 0; 1301 } 1302 DPRINTF("next bg xfer: %d\n", epctx->next_bg); 1303 1304 xhci_kick_ep(xhci, fg->slotid, fg->epid); 1305 } 1306 } 1307 epctx->bg_updating = 0; 1308 } 1309 1310 #if 0 1311 static void xhci_xfer_cb(struct libusb_transfer *transfer) 1312 { 1313 XHCIState *xhci; 1314 XHCITransfer *xfer; 1315 1316 xfer = (XHCITransfer *)transfer->user_data; 1317 xhci = xfer->xhci; 1318 1319 DPRINTF("xhci_xfer_cb(slot=%d, ep=%d, status=%d)\n", xfer->slotid, 1320 xfer->epid, transfer->status); 1321 1322 assert(xfer->slotid >= 1 && xfer->slotid <= MAXSLOTS); 1323 assert(xfer->epid >= 1 && xfer->epid <= 31); 1324 1325 if (xfer->cancelled) { 1326 DPRINTF("xhci: transfer cancelled, not reporting anything\n"); 1327 xfer->running = 0; 1328 return; 1329 } 1330 1331 XHCIEPContext *epctx; 1332 XHCISlot *slot; 1333 slot = &xhci->slots[xfer->slotid-1]; 1334 assert(slot->eps[xfer->epid-1]); 1335 epctx = slot->eps[xfer->epid-1]; 1336 1337 if (xfer->bg_xfer) { 1338 DPRINTF("xhci: background transfer, updating\n"); 1339 xfer->complete = 1; 1340 xfer->running = 0; 1341 xhci_bg_update(xhci, epctx); 1342 return; 1343 } 1344 1345 if (xfer->iso_xfer) { 1346 transfer->status = transfer->iso_packet_desc[0].status; 1347 transfer->actual_length = transfer->iso_packet_desc[0].actual_length; 1348 } 1349 1350 xfer->status = libusb_to_ccode(transfer->status); 1351 1352 xfer->complete = 1; 1353 xfer->running = 0; 1354 1355 if (transfer->status == LIBUSB_TRANSFER_STALL) 1356 xhci_stall_ep(xhci, epctx, xfer); 1357 1358 DPRINTF("xhci: transfer actual length = %d\n", transfer->actual_length); 1359 1360 if (xfer->in_xfer) { 1361 if (xfer->epid == 1) { 1362 xhci_xfer_data(xhci, xfer, xfer->data + 8, 1363 transfer->actual_length, 1, 0, 1); 1364 } else { 1365 xhci_xfer_data(xhci, xfer, xfer->data, 1366 transfer->actual_length, 1, 0, 1); 1367 } 1368 } else { 1369 xhci_xfer_data(xhci, xfer, NULL, transfer->actual_length, 0, 0, 1); 1370 } 1371 1372 xhci_kick_ep(xhci, xfer->slotid, xfer->epid); 1373 } 1374 1375 static int xhci_hle_control(XHCIState *xhci, XHCITransfer *xfer, 1376 uint8_t bmRequestType, uint8_t bRequest, 1377 uint16_t wValue, uint16_t wIndex, uint16_t wLength) 1378 { 1379 uint16_t type_req = (bmRequestType << 8) | bRequest; 1380 1381 switch (type_req) { 1382 case 0x0000 | USB_REQ_SET_CONFIGURATION: 1383 DPRINTF("xhci: HLE switch configuration\n"); 1384 return xhci_switch_config(xhci, xfer->slotid, wValue) == 0; 1385 case 0x0100 | USB_REQ_SET_INTERFACE: 1386 DPRINTF("xhci: HLE set interface altsetting\n"); 1387 return xhci_set_iface_alt(xhci, xfer->slotid, wIndex, wValue) == 0; 1388 case 0x0200 | USB_REQ_CLEAR_FEATURE: 1389 if (wValue == 0) { // endpoint halt 1390 DPRINTF("xhci: HLE clear halt\n"); 1391 return xhci_clear_halt(xhci, xfer->slotid, wIndex); 1392 } 1393 case 0x0000 | USB_REQ_SET_ADDRESS: 1394 fprintf(stderr, "xhci: warn: illegal SET_ADDRESS request\n"); 1395 return 0; 1396 default: 1397 return 0; 1398 } 1399 } 1400 #endif 1401 1402 static int xhci_setup_packet(XHCITransfer *xfer, USBDevice *dev) 1403 { 1404 USBEndpoint *ep; 1405 int dir; 1406 1407 dir = xfer->in_xfer ? USB_TOKEN_IN : USB_TOKEN_OUT; 1408 ep = usb_ep_get(dev, dir, xfer->epid >> 1); 1409 usb_packet_setup(&xfer->packet, dir, ep); 1410 usb_packet_addbuf(&xfer->packet, xfer->data, xfer->data_length); 1411 DPRINTF("xhci: setup packet pid 0x%x addr %d ep %d\n", 1412 xfer->packet.pid, dev->addr, ep->nr); 1413 return 0; 1414 } 1415 1416 static int xhci_complete_packet(XHCITransfer *xfer, int ret) 1417 { 1418 if (ret == USB_RET_ASYNC) { 1419 xfer->running_async = 1; 1420 xfer->running_retry = 0; 1421 xfer->complete = 0; 1422 xfer->cancelled = 0; 1423 return 0; 1424 } else if (ret == USB_RET_NAK) { 1425 xfer->running_async = 0; 1426 xfer->running_retry = 1; 1427 xfer->complete = 0; 1428 xfer->cancelled = 0; 1429 return 0; 1430 } else { 1431 xfer->running_async = 0; 1432 xfer->running_retry = 0; 1433 xfer->complete = 1; 1434 } 1435 1436 if (ret >= 0) { 1437 xfer->status = CC_SUCCESS; 1438 xhci_xfer_data(xfer, xfer->data, ret, xfer->in_xfer, 0, 1); 1439 return 0; 1440 } 1441 1442 /* error */ 1443 switch (ret) { 1444 case USB_RET_NODEV: 1445 xfer->status = CC_USB_TRANSACTION_ERROR; 1446 xhci_xfer_data(xfer, xfer->data, 0, xfer->in_xfer, 0, 1); 1447 xhci_stall_ep(xfer); 1448 break; 1449 case USB_RET_STALL: 1450 xfer->status = CC_STALL_ERROR; 1451 xhci_xfer_data(xfer, xfer->data, 0, xfer->in_xfer, 0, 1); 1452 xhci_stall_ep(xfer); 1453 break; 1454 default: 1455 fprintf(stderr, "%s: FIXME: ret = %d\n", __FUNCTION__, ret); 1456 FIXME(); 1457 } 1458 return 0; 1459 } 1460 1461 static USBDevice *xhci_find_device(XHCIPort *port, uint8_t addr) 1462 { 1463 if (!(port->portsc & PORTSC_PED)) { 1464 return NULL; 1465 } 1466 return usb_find_device(&port->port, addr); 1467 } 1468 1469 static int xhci_fire_ctl_transfer(XHCIState *xhci, XHCITransfer *xfer) 1470 { 1471 XHCITRB *trb_setup, *trb_status; 1472 uint8_t bmRequestType; 1473 uint16_t wLength; 1474 XHCIPort *port; 1475 USBDevice *dev; 1476 int ret; 1477 1478 DPRINTF("xhci_fire_ctl_transfer(slot=%d)\n", xfer->slotid); 1479 1480 trb_setup = &xfer->trbs[0]; 1481 trb_status = &xfer->trbs[xfer->trb_count-1]; 1482 1483 /* at most one Event Data TRB allowed after STATUS */ 1484 if (TRB_TYPE(*trb_status) == TR_EVDATA && xfer->trb_count > 2) { 1485 trb_status--; 1486 } 1487 1488 /* do some sanity checks */ 1489 if (TRB_TYPE(*trb_setup) != TR_SETUP) { 1490 fprintf(stderr, "xhci: ep0 first TD not SETUP: %d\n", 1491 TRB_TYPE(*trb_setup)); 1492 return -1; 1493 } 1494 if (TRB_TYPE(*trb_status) != TR_STATUS) { 1495 fprintf(stderr, "xhci: ep0 last TD not STATUS: %d\n", 1496 TRB_TYPE(*trb_status)); 1497 return -1; 1498 } 1499 if (!(trb_setup->control & TRB_TR_IDT)) { 1500 fprintf(stderr, "xhci: Setup TRB doesn't have IDT set\n"); 1501 return -1; 1502 } 1503 if ((trb_setup->status & 0x1ffff) != 8) { 1504 fprintf(stderr, "xhci: Setup TRB has bad length (%d)\n", 1505 (trb_setup->status & 0x1ffff)); 1506 return -1; 1507 } 1508 1509 bmRequestType = trb_setup->parameter; 1510 wLength = trb_setup->parameter >> 48; 1511 1512 if (xfer->data && xfer->data_alloced < wLength) { 1513 xfer->data_alloced = 0; 1514 g_free(xfer->data); 1515 xfer->data = NULL; 1516 } 1517 if (!xfer->data) { 1518 DPRINTF("xhci: alloc %d bytes data\n", wLength); 1519 xfer->data = g_malloc(wLength+1); 1520 xfer->data_alloced = wLength; 1521 } 1522 xfer->data_length = wLength; 1523 1524 port = &xhci->ports[xhci->slots[xfer->slotid-1].port-1]; 1525 dev = xhci_find_device(port, xhci->slots[xfer->slotid-1].devaddr); 1526 if (!dev) { 1527 fprintf(stderr, "xhci: slot %d port %d has no device\n", xfer->slotid, 1528 xhci->slots[xfer->slotid-1].port); 1529 return -1; 1530 } 1531 1532 xfer->in_xfer = bmRequestType & USB_DIR_IN; 1533 xfer->iso_xfer = false; 1534 1535 xhci_setup_packet(xfer, dev); 1536 xfer->packet.parameter = trb_setup->parameter; 1537 if (!xfer->in_xfer) { 1538 xhci_xfer_data(xfer, xfer->data, wLength, 0, 1, 0); 1539 } 1540 1541 ret = usb_handle_packet(dev, &xfer->packet); 1542 1543 xhci_complete_packet(xfer, ret); 1544 if (!xfer->running_async && !xfer->running_retry) { 1545 xhci_kick_ep(xhci, xfer->slotid, xfer->epid); 1546 } 1547 return 0; 1548 } 1549 1550 static int xhci_submit(XHCIState *xhci, XHCITransfer *xfer, XHCIEPContext *epctx) 1551 { 1552 XHCIPort *port; 1553 USBDevice *dev; 1554 int ret; 1555 1556 DPRINTF("xhci_submit(slotid=%d,epid=%d)\n", xfer->slotid, xfer->epid); 1557 1558 xfer->in_xfer = epctx->type>>2; 1559 1560 if (xfer->data && xfer->data_alloced < xfer->data_length) { 1561 xfer->data_alloced = 0; 1562 g_free(xfer->data); 1563 xfer->data = NULL; 1564 } 1565 if (!xfer->data && xfer->data_length) { 1566 DPRINTF("xhci: alloc %d bytes data\n", xfer->data_length); 1567 xfer->data = g_malloc(xfer->data_length); 1568 xfer->data_alloced = xfer->data_length; 1569 } 1570 if (epctx->type == ET_ISO_IN || epctx->type == ET_ISO_OUT) { 1571 if (!xfer->bg_xfer) { 1572 xfer->pkts = 1; 1573 } 1574 } else { 1575 xfer->pkts = 0; 1576 } 1577 1578 port = &xhci->ports[xhci->slots[xfer->slotid-1].port-1]; 1579 dev = xhci_find_device(port, xhci->slots[xfer->slotid-1].devaddr); 1580 if (!dev) { 1581 fprintf(stderr, "xhci: slot %d port %d has no device\n", xfer->slotid, 1582 xhci->slots[xfer->slotid-1].port); 1583 return -1; 1584 } 1585 1586 xhci_setup_packet(xfer, dev); 1587 1588 switch(epctx->type) { 1589 case ET_INTR_OUT: 1590 case ET_INTR_IN: 1591 case ET_BULK_OUT: 1592 case ET_BULK_IN: 1593 break; 1594 case ET_ISO_OUT: 1595 case ET_ISO_IN: 1596 FIXME(); 1597 break; 1598 default: 1599 fprintf(stderr, "xhci: unknown or unhandled EP " 1600 "(type %d, in %d, ep %02x)\n", 1601 epctx->type, xfer->in_xfer, xfer->epid); 1602 return -1; 1603 } 1604 1605 if (!xfer->in_xfer) { 1606 xhci_xfer_data(xfer, xfer->data, xfer->data_length, 0, 1, 0); 1607 } 1608 ret = usb_handle_packet(dev, &xfer->packet); 1609 1610 xhci_complete_packet(xfer, ret); 1611 if (!xfer->running_async && !xfer->running_retry) { 1612 xhci_kick_ep(xhci, xfer->slotid, xfer->epid); 1613 } 1614 return 0; 1615 } 1616 1617 static int xhci_fire_transfer(XHCIState *xhci, XHCITransfer *xfer, XHCIEPContext *epctx) 1618 { 1619 int i; 1620 unsigned int length = 0; 1621 XHCITRB *trb; 1622 1623 DPRINTF("xhci_fire_transfer(slotid=%d,epid=%d)\n", xfer->slotid, xfer->epid); 1624 1625 for (i = 0; i < xfer->trb_count; i++) { 1626 trb = &xfer->trbs[i]; 1627 if (TRB_TYPE(*trb) == TR_NORMAL || TRB_TYPE(*trb) == TR_ISOCH) { 1628 length += trb->status & 0x1ffff; 1629 } 1630 } 1631 DPRINTF("xhci: total TD length=%d\n", length); 1632 1633 if (!epctx->has_bg) { 1634 xfer->data_length = length; 1635 xfer->backgrounded = 0; 1636 return xhci_submit(xhci, xfer, epctx); 1637 } else { 1638 if (!epctx->bg_running) { 1639 for (i = 0; i < BG_XFERS; i++) { 1640 XHCITransfer *t = &epctx->bg_transfers[i]; 1641 t->xhci = xhci; 1642 t->epid = xfer->epid; 1643 t->slotid = xfer->slotid; 1644 t->pkts = BG_PKTS; 1645 t->pktsize = epctx->max_psize; 1646 t->data_length = t->pkts * t->pktsize; 1647 t->bg_xfer = 1; 1648 if (xhci_submit(xhci, t, epctx) < 0) { 1649 fprintf(stderr, "xhci: bg submit failed\n"); 1650 return -1; 1651 } 1652 } 1653 epctx->bg_running = 1; 1654 } 1655 xfer->backgrounded = 1; 1656 xhci_bg_update(xhci, epctx); 1657 return 0; 1658 } 1659 } 1660 1661 static void xhci_kick_ep(XHCIState *xhci, unsigned int slotid, unsigned int epid) 1662 { 1663 XHCIEPContext *epctx; 1664 int length; 1665 int i; 1666 1667 assert(slotid >= 1 && slotid <= MAXSLOTS); 1668 assert(epid >= 1 && epid <= 31); 1669 DPRINTF("xhci_kick_ep(%d, %d)\n", slotid, epid); 1670 1671 if (!xhci->slots[slotid-1].enabled) { 1672 fprintf(stderr, "xhci: xhci_kick_ep for disabled slot %d\n", slotid); 1673 return; 1674 } 1675 epctx = xhci->slots[slotid-1].eps[epid-1]; 1676 if (!epctx) { 1677 fprintf(stderr, "xhci: xhci_kick_ep for disabled endpoint %d,%d\n", 1678 epid, slotid); 1679 return; 1680 } 1681 1682 if (epctx->retry) { 1683 /* retry nak'ed transfer */ 1684 XHCITransfer *xfer = epctx->retry; 1685 int result; 1686 1687 DPRINTF("xhci: retry nack'ed transfer ...\n"); 1688 assert(xfer->running_retry); 1689 xhci_setup_packet(xfer, xfer->packet.ep->dev); 1690 result = usb_handle_packet(xfer->packet.ep->dev, &xfer->packet); 1691 if (result == USB_RET_NAK) { 1692 DPRINTF("xhci: ... xfer still nacked\n"); 1693 return; 1694 } 1695 DPRINTF("xhci: ... result %d\n", result); 1696 xhci_complete_packet(xfer, result); 1697 assert(!xfer->running_retry); 1698 epctx->retry = NULL; 1699 } 1700 1701 if (epctx->state == EP_HALTED) { 1702 DPRINTF("xhci: ep halted, not running schedule\n"); 1703 return; 1704 } 1705 1706 xhci_set_ep_state(xhci, epctx, EP_RUNNING); 1707 1708 while (1) { 1709 XHCITransfer *xfer = &epctx->transfers[epctx->next_xfer]; 1710 if (xfer->running_async || xfer->running_retry || xfer->backgrounded) { 1711 DPRINTF("xhci: ep is busy (#%d,%d,%d,%d)\n", 1712 epctx->next_xfer, xfer->running_async, 1713 xfer->running_retry, xfer->backgrounded); 1714 break; 1715 } else { 1716 DPRINTF("xhci: ep: using #%d\n", epctx->next_xfer); 1717 } 1718 length = xhci_ring_chain_length(xhci, &epctx->ring); 1719 if (length < 0) { 1720 DPRINTF("xhci: incomplete TD (%d TRBs)\n", -length); 1721 break; 1722 } else if (length == 0) { 1723 break; 1724 } 1725 DPRINTF("xhci: fetching %d-TRB TD\n", length); 1726 if (xfer->trbs && xfer->trb_alloced < length) { 1727 xfer->trb_count = 0; 1728 xfer->trb_alloced = 0; 1729 g_free(xfer->trbs); 1730 xfer->trbs = NULL; 1731 } 1732 if (!xfer->trbs) { 1733 xfer->trbs = g_malloc(sizeof(XHCITRB) * length); 1734 xfer->trb_alloced = length; 1735 } 1736 xfer->trb_count = length; 1737 1738 for (i = 0; i < length; i++) { 1739 assert(xhci_ring_fetch(xhci, &epctx->ring, &xfer->trbs[i], NULL)); 1740 } 1741 xfer->xhci = xhci; 1742 xfer->epid = epid; 1743 xfer->slotid = slotid; 1744 1745 if (epid == 1) { 1746 if (xhci_fire_ctl_transfer(xhci, xfer) >= 0) { 1747 epctx->next_xfer = (epctx->next_xfer + 1) % TD_QUEUE; 1748 } else { 1749 fprintf(stderr, "xhci: error firing CTL transfer\n"); 1750 } 1751 } else { 1752 if (xhci_fire_transfer(xhci, xfer, epctx) >= 0) { 1753 epctx->next_xfer = (epctx->next_xfer + 1) % TD_QUEUE; 1754 } else { 1755 fprintf(stderr, "xhci: error firing data transfer\n"); 1756 } 1757 } 1758 1759 if (epctx->state == EP_HALTED) { 1760 DPRINTF("xhci: ep halted, stopping schedule\n"); 1761 break; 1762 } 1763 if (xfer->running_retry) { 1764 DPRINTF("xhci: xfer nacked, stopping schedule\n"); 1765 epctx->retry = xfer; 1766 break; 1767 } 1768 } 1769 } 1770 1771 static TRBCCode xhci_enable_slot(XHCIState *xhci, unsigned int slotid) 1772 { 1773 assert(slotid >= 1 && slotid <= MAXSLOTS); 1774 DPRINTF("xhci_enable_slot(%d)\n", slotid); 1775 xhci->slots[slotid-1].enabled = 1; 1776 xhci->slots[slotid-1].port = 0; 1777 memset(xhci->slots[slotid-1].eps, 0, sizeof(XHCIEPContext*)*31); 1778 1779 return CC_SUCCESS; 1780 } 1781 1782 static TRBCCode xhci_disable_slot(XHCIState *xhci, unsigned int slotid) 1783 { 1784 int i; 1785 1786 assert(slotid >= 1 && slotid <= MAXSLOTS); 1787 DPRINTF("xhci_disable_slot(%d)\n", slotid); 1788 1789 for (i = 1; i <= 31; i++) { 1790 if (xhci->slots[slotid-1].eps[i-1]) { 1791 xhci_disable_ep(xhci, slotid, i); 1792 } 1793 } 1794 1795 xhci->slots[slotid-1].enabled = 0; 1796 return CC_SUCCESS; 1797 } 1798 1799 static TRBCCode xhci_address_slot(XHCIState *xhci, unsigned int slotid, 1800 uint64_t pictx, bool bsr) 1801 { 1802 XHCISlot *slot; 1803 USBDevice *dev; 1804 dma_addr_t ictx, octx, dcbaap; 1805 uint64_t poctx; 1806 uint32_t ictl_ctx[2]; 1807 uint32_t slot_ctx[4]; 1808 uint32_t ep0_ctx[5]; 1809 unsigned int port; 1810 int i; 1811 TRBCCode res; 1812 1813 assert(slotid >= 1 && slotid <= MAXSLOTS); 1814 DPRINTF("xhci_address_slot(%d)\n", slotid); 1815 1816 dcbaap = xhci_addr64(xhci->dcbaap_low, xhci->dcbaap_high); 1817 pci_dma_read(&xhci->pci_dev, dcbaap + 8*slotid, &poctx, sizeof(poctx)); 1818 ictx = xhci_mask64(pictx); 1819 octx = xhci_mask64(le64_to_cpu(poctx)); 1820 1821 DPRINTF("xhci: input context at "DMA_ADDR_FMT"\n", ictx); 1822 DPRINTF("xhci: output context at "DMA_ADDR_FMT"\n", octx); 1823 1824 pci_dma_read(&xhci->pci_dev, ictx, ictl_ctx, sizeof(ictl_ctx)); 1825 1826 if (ictl_ctx[0] != 0x0 || ictl_ctx[1] != 0x3) { 1827 fprintf(stderr, "xhci: invalid input context control %08x %08x\n", 1828 ictl_ctx[0], ictl_ctx[1]); 1829 return CC_TRB_ERROR; 1830 } 1831 1832 pci_dma_read(&xhci->pci_dev, ictx+32, slot_ctx, sizeof(slot_ctx)); 1833 pci_dma_read(&xhci->pci_dev, ictx+64, ep0_ctx, sizeof(ep0_ctx)); 1834 1835 DPRINTF("xhci: input slot context: %08x %08x %08x %08x\n", 1836 slot_ctx[0], slot_ctx[1], slot_ctx[2], slot_ctx[3]); 1837 1838 DPRINTF("xhci: input ep0 context: %08x %08x %08x %08x %08x\n", 1839 ep0_ctx[0], ep0_ctx[1], ep0_ctx[2], ep0_ctx[3], ep0_ctx[4]); 1840 1841 port = (slot_ctx[1]>>16) & 0xFF; 1842 dev = xhci->ports[port-1].port.dev; 1843 1844 if (port < 1 || port > MAXPORTS) { 1845 fprintf(stderr, "xhci: bad port %d\n", port); 1846 return CC_TRB_ERROR; 1847 } else if (!dev) { 1848 fprintf(stderr, "xhci: port %d not connected\n", port); 1849 return CC_USB_TRANSACTION_ERROR; 1850 } 1851 1852 for (i = 0; i < MAXSLOTS; i++) { 1853 if (xhci->slots[i].port == port) { 1854 fprintf(stderr, "xhci: port %d already assigned to slot %d\n", 1855 port, i+1); 1856 return CC_TRB_ERROR; 1857 } 1858 } 1859 1860 slot = &xhci->slots[slotid-1]; 1861 slot->port = port; 1862 slot->ctx = octx; 1863 1864 if (bsr) { 1865 slot_ctx[3] = SLOT_DEFAULT << SLOT_STATE_SHIFT; 1866 } else { 1867 slot->devaddr = xhci->devaddr++; 1868 slot_ctx[3] = (SLOT_ADDRESSED << SLOT_STATE_SHIFT) | slot->devaddr; 1869 DPRINTF("xhci: device address is %d\n", slot->devaddr); 1870 usb_device_handle_control(dev, NULL, 1871 DeviceOutRequest | USB_REQ_SET_ADDRESS, 1872 slot->devaddr, 0, 0, NULL); 1873 } 1874 1875 res = xhci_enable_ep(xhci, slotid, 1, octx+32, ep0_ctx); 1876 1877 DPRINTF("xhci: output slot context: %08x %08x %08x %08x\n", 1878 slot_ctx[0], slot_ctx[1], slot_ctx[2], slot_ctx[3]); 1879 DPRINTF("xhci: output ep0 context: %08x %08x %08x %08x %08x\n", 1880 ep0_ctx[0], ep0_ctx[1], ep0_ctx[2], ep0_ctx[3], ep0_ctx[4]); 1881 1882 pci_dma_write(&xhci->pci_dev, octx, slot_ctx, sizeof(slot_ctx)); 1883 pci_dma_write(&xhci->pci_dev, octx+32, ep0_ctx, sizeof(ep0_ctx)); 1884 1885 return res; 1886 } 1887 1888 1889 static TRBCCode xhci_configure_slot(XHCIState *xhci, unsigned int slotid, 1890 uint64_t pictx, bool dc) 1891 { 1892 dma_addr_t ictx, octx; 1893 uint32_t ictl_ctx[2]; 1894 uint32_t slot_ctx[4]; 1895 uint32_t islot_ctx[4]; 1896 uint32_t ep_ctx[5]; 1897 int i; 1898 TRBCCode res; 1899 1900 assert(slotid >= 1 && slotid <= MAXSLOTS); 1901 DPRINTF("xhci_configure_slot(%d)\n", slotid); 1902 1903 ictx = xhci_mask64(pictx); 1904 octx = xhci->slots[slotid-1].ctx; 1905 1906 DPRINTF("xhci: input context at "DMA_ADDR_FMT"\n", ictx); 1907 DPRINTF("xhci: output context at "DMA_ADDR_FMT"\n", octx); 1908 1909 if (dc) { 1910 for (i = 2; i <= 31; i++) { 1911 if (xhci->slots[slotid-1].eps[i-1]) { 1912 xhci_disable_ep(xhci, slotid, i); 1913 } 1914 } 1915 1916 pci_dma_read(&xhci->pci_dev, octx, slot_ctx, sizeof(slot_ctx)); 1917 slot_ctx[3] &= ~(SLOT_STATE_MASK << SLOT_STATE_SHIFT); 1918 slot_ctx[3] |= SLOT_ADDRESSED << SLOT_STATE_SHIFT; 1919 DPRINTF("xhci: output slot context: %08x %08x %08x %08x\n", 1920 slot_ctx[0], slot_ctx[1], slot_ctx[2], slot_ctx[3]); 1921 pci_dma_write(&xhci->pci_dev, octx, slot_ctx, sizeof(slot_ctx)); 1922 1923 return CC_SUCCESS; 1924 } 1925 1926 pci_dma_read(&xhci->pci_dev, ictx, ictl_ctx, sizeof(ictl_ctx)); 1927 1928 if ((ictl_ctx[0] & 0x3) != 0x0 || (ictl_ctx[1] & 0x3) != 0x1) { 1929 fprintf(stderr, "xhci: invalid input context control %08x %08x\n", 1930 ictl_ctx[0], ictl_ctx[1]); 1931 return CC_TRB_ERROR; 1932 } 1933 1934 pci_dma_read(&xhci->pci_dev, ictx+32, islot_ctx, sizeof(islot_ctx)); 1935 pci_dma_read(&xhci->pci_dev, octx, slot_ctx, sizeof(slot_ctx)); 1936 1937 if (SLOT_STATE(slot_ctx[3]) < SLOT_ADDRESSED) { 1938 fprintf(stderr, "xhci: invalid slot state %08x\n", slot_ctx[3]); 1939 return CC_CONTEXT_STATE_ERROR; 1940 } 1941 1942 for (i = 2; i <= 31; i++) { 1943 if (ictl_ctx[0] & (1<<i)) { 1944 xhci_disable_ep(xhci, slotid, i); 1945 } 1946 if (ictl_ctx[1] & (1<<i)) { 1947 pci_dma_read(&xhci->pci_dev, ictx+32+(32*i), ep_ctx, 1948 sizeof(ep_ctx)); 1949 DPRINTF("xhci: input ep%d.%d context: %08x %08x %08x %08x %08x\n", 1950 i/2, i%2, ep_ctx[0], ep_ctx[1], ep_ctx[2], 1951 ep_ctx[3], ep_ctx[4]); 1952 xhci_disable_ep(xhci, slotid, i); 1953 res = xhci_enable_ep(xhci, slotid, i, octx+(32*i), ep_ctx); 1954 if (res != CC_SUCCESS) { 1955 return res; 1956 } 1957 DPRINTF("xhci: output ep%d.%d context: %08x %08x %08x %08x %08x\n", 1958 i/2, i%2, ep_ctx[0], ep_ctx[1], ep_ctx[2], 1959 ep_ctx[3], ep_ctx[4]); 1960 pci_dma_write(&xhci->pci_dev, octx+(32*i), ep_ctx, sizeof(ep_ctx)); 1961 } 1962 } 1963 1964 slot_ctx[3] &= ~(SLOT_STATE_MASK << SLOT_STATE_SHIFT); 1965 slot_ctx[3] |= SLOT_CONFIGURED << SLOT_STATE_SHIFT; 1966 slot_ctx[0] &= ~(SLOT_CONTEXT_ENTRIES_MASK << SLOT_CONTEXT_ENTRIES_SHIFT); 1967 slot_ctx[0] |= islot_ctx[0] & (SLOT_CONTEXT_ENTRIES_MASK << 1968 SLOT_CONTEXT_ENTRIES_SHIFT); 1969 DPRINTF("xhci: output slot context: %08x %08x %08x %08x\n", 1970 slot_ctx[0], slot_ctx[1], slot_ctx[2], slot_ctx[3]); 1971 1972 pci_dma_write(&xhci->pci_dev, octx, slot_ctx, sizeof(slot_ctx)); 1973 1974 return CC_SUCCESS; 1975 } 1976 1977 1978 static TRBCCode xhci_evaluate_slot(XHCIState *xhci, unsigned int slotid, 1979 uint64_t pictx) 1980 { 1981 dma_addr_t ictx, octx; 1982 uint32_t ictl_ctx[2]; 1983 uint32_t iep0_ctx[5]; 1984 uint32_t ep0_ctx[5]; 1985 uint32_t islot_ctx[4]; 1986 uint32_t slot_ctx[4]; 1987 1988 assert(slotid >= 1 && slotid <= MAXSLOTS); 1989 DPRINTF("xhci_evaluate_slot(%d)\n", slotid); 1990 1991 ictx = xhci_mask64(pictx); 1992 octx = xhci->slots[slotid-1].ctx; 1993 1994 DPRINTF("xhci: input context at "DMA_ADDR_FMT"\n", ictx); 1995 DPRINTF("xhci: output context at "DMA_ADDR_FMT"\n", octx); 1996 1997 pci_dma_read(&xhci->pci_dev, ictx, ictl_ctx, sizeof(ictl_ctx)); 1998 1999 if (ictl_ctx[0] != 0x0 || ictl_ctx[1] & ~0x3) { 2000 fprintf(stderr, "xhci: invalid input context control %08x %08x\n", 2001 ictl_ctx[0], ictl_ctx[1]); 2002 return CC_TRB_ERROR; 2003 } 2004 2005 if (ictl_ctx[1] & 0x1) { 2006 pci_dma_read(&xhci->pci_dev, ictx+32, islot_ctx, sizeof(islot_ctx)); 2007 2008 DPRINTF("xhci: input slot context: %08x %08x %08x %08x\n", 2009 islot_ctx[0], islot_ctx[1], islot_ctx[2], islot_ctx[3]); 2010 2011 pci_dma_read(&xhci->pci_dev, octx, slot_ctx, sizeof(slot_ctx)); 2012 2013 slot_ctx[1] &= ~0xFFFF; /* max exit latency */ 2014 slot_ctx[1] |= islot_ctx[1] & 0xFFFF; 2015 slot_ctx[2] &= ~0xFF00000; /* interrupter target */ 2016 slot_ctx[2] |= islot_ctx[2] & 0xFF000000; 2017 2018 DPRINTF("xhci: output slot context: %08x %08x %08x %08x\n", 2019 slot_ctx[0], slot_ctx[1], slot_ctx[2], slot_ctx[3]); 2020 2021 pci_dma_write(&xhci->pci_dev, octx, slot_ctx, sizeof(slot_ctx)); 2022 } 2023 2024 if (ictl_ctx[1] & 0x2) { 2025 pci_dma_read(&xhci->pci_dev, ictx+64, iep0_ctx, sizeof(iep0_ctx)); 2026 2027 DPRINTF("xhci: input ep0 context: %08x %08x %08x %08x %08x\n", 2028 iep0_ctx[0], iep0_ctx[1], iep0_ctx[2], 2029 iep0_ctx[3], iep0_ctx[4]); 2030 2031 pci_dma_read(&xhci->pci_dev, octx+32, ep0_ctx, sizeof(ep0_ctx)); 2032 2033 ep0_ctx[1] &= ~0xFFFF0000; /* max packet size*/ 2034 ep0_ctx[1] |= iep0_ctx[1] & 0xFFFF0000; 2035 2036 DPRINTF("xhci: output ep0 context: %08x %08x %08x %08x %08x\n", 2037 ep0_ctx[0], ep0_ctx[1], ep0_ctx[2], ep0_ctx[3], ep0_ctx[4]); 2038 2039 pci_dma_write(&xhci->pci_dev, octx+32, ep0_ctx, sizeof(ep0_ctx)); 2040 } 2041 2042 return CC_SUCCESS; 2043 } 2044 2045 static TRBCCode xhci_reset_slot(XHCIState *xhci, unsigned int slotid) 2046 { 2047 uint32_t slot_ctx[4]; 2048 dma_addr_t octx; 2049 int i; 2050 2051 assert(slotid >= 1 && slotid <= MAXSLOTS); 2052 DPRINTF("xhci_reset_slot(%d)\n", slotid); 2053 2054 octx = xhci->slots[slotid-1].ctx; 2055 2056 DPRINTF("xhci: output context at "DMA_ADDR_FMT"\n", octx); 2057 2058 for (i = 2; i <= 31; i++) { 2059 if (xhci->slots[slotid-1].eps[i-1]) { 2060 xhci_disable_ep(xhci, slotid, i); 2061 } 2062 } 2063 2064 pci_dma_read(&xhci->pci_dev, octx, slot_ctx, sizeof(slot_ctx)); 2065 slot_ctx[3] &= ~(SLOT_STATE_MASK << SLOT_STATE_SHIFT); 2066 slot_ctx[3] |= SLOT_DEFAULT << SLOT_STATE_SHIFT; 2067 DPRINTF("xhci: output slot context: %08x %08x %08x %08x\n", 2068 slot_ctx[0], slot_ctx[1], slot_ctx[2], slot_ctx[3]); 2069 pci_dma_write(&xhci->pci_dev, octx, slot_ctx, sizeof(slot_ctx)); 2070 2071 return CC_SUCCESS; 2072 } 2073 2074 static unsigned int xhci_get_slot(XHCIState *xhci, XHCIEvent *event, XHCITRB *trb) 2075 { 2076 unsigned int slotid; 2077 slotid = (trb->control >> TRB_CR_SLOTID_SHIFT) & TRB_CR_SLOTID_MASK; 2078 if (slotid < 1 || slotid > MAXSLOTS) { 2079 fprintf(stderr, "xhci: bad slot id %d\n", slotid); 2080 event->ccode = CC_TRB_ERROR; 2081 return 0; 2082 } else if (!xhci->slots[slotid-1].enabled) { 2083 fprintf(stderr, "xhci: slot id %d not enabled\n", slotid); 2084 event->ccode = CC_SLOT_NOT_ENABLED_ERROR; 2085 return 0; 2086 } 2087 return slotid; 2088 } 2089 2090 static TRBCCode xhci_get_port_bandwidth(XHCIState *xhci, uint64_t pctx) 2091 { 2092 dma_addr_t ctx; 2093 uint8_t bw_ctx[MAXPORTS+1]; 2094 2095 DPRINTF("xhci_get_port_bandwidth()\n"); 2096 2097 ctx = xhci_mask64(pctx); 2098 2099 DPRINTF("xhci: bandwidth context at "DMA_ADDR_FMT"\n", ctx); 2100 2101 /* TODO: actually implement real values here */ 2102 bw_ctx[0] = 0; 2103 memset(&bw_ctx[1], 80, MAXPORTS); /* 80% */ 2104 pci_dma_write(&xhci->pci_dev, ctx, bw_ctx, sizeof(bw_ctx)); 2105 2106 return CC_SUCCESS; 2107 } 2108 2109 static uint32_t rotl(uint32_t v, unsigned count) 2110 { 2111 count &= 31; 2112 return (v << count) | (v >> (32 - count)); 2113 } 2114 2115 2116 static uint32_t xhci_nec_challenge(uint32_t hi, uint32_t lo) 2117 { 2118 uint32_t val; 2119 val = rotl(lo - 0x49434878, 32 - ((hi>>8) & 0x1F)); 2120 val += rotl(lo + 0x49434878, hi & 0x1F); 2121 val -= rotl(hi ^ 0x49434878, (lo >> 16) & 0x1F); 2122 return ~val; 2123 } 2124 2125 static void xhci_via_challenge(XHCIState *xhci, uint64_t addr) 2126 { 2127 uint32_t buf[8]; 2128 uint32_t obuf[8]; 2129 dma_addr_t paddr = xhci_mask64(addr); 2130 2131 pci_dma_read(&xhci->pci_dev, paddr, &buf, 32); 2132 2133 memcpy(obuf, buf, sizeof(obuf)); 2134 2135 if ((buf[0] & 0xff) == 2) { 2136 obuf[0] = 0x49932000 + 0x54dc200 * buf[2] + 0x7429b578 * buf[3]; 2137 obuf[0] |= (buf[2] * buf[3]) & 0xff; 2138 obuf[1] = 0x0132bb37 + 0xe89 * buf[2] + 0xf09 * buf[3]; 2139 obuf[2] = 0x0066c2e9 + 0x2091 * buf[2] + 0x19bd * buf[3]; 2140 obuf[3] = 0xd5281342 + 0x2cc9691 * buf[2] + 0x2367662 * buf[3]; 2141 obuf[4] = 0x0123c75c + 0x1595 * buf[2] + 0x19ec * buf[3]; 2142 obuf[5] = 0x00f695de + 0x26fd * buf[2] + 0x3e9 * buf[3]; 2143 obuf[6] = obuf[2] ^ obuf[3] ^ 0x29472956; 2144 obuf[7] = obuf[2] ^ obuf[3] ^ 0x65866593; 2145 } 2146 2147 pci_dma_write(&xhci->pci_dev, paddr, &obuf, 32); 2148 } 2149 2150 static void xhci_process_commands(XHCIState *xhci) 2151 { 2152 XHCITRB trb; 2153 TRBType type; 2154 XHCIEvent event = {ER_COMMAND_COMPLETE, CC_SUCCESS}; 2155 dma_addr_t addr; 2156 unsigned int i, slotid = 0; 2157 2158 DPRINTF("xhci_process_commands()\n"); 2159 if (!xhci_running(xhci)) { 2160 DPRINTF("xhci_process_commands() called while xHC stopped or paused\n"); 2161 return; 2162 } 2163 2164 xhci->crcr_low |= CRCR_CRR; 2165 2166 while ((type = xhci_ring_fetch(xhci, &xhci->cmd_ring, &trb, &addr))) { 2167 event.ptr = addr; 2168 switch (type) { 2169 case CR_ENABLE_SLOT: 2170 for (i = 0; i < MAXSLOTS; i++) { 2171 if (!xhci->slots[i].enabled) { 2172 break; 2173 } 2174 } 2175 if (i >= MAXSLOTS) { 2176 fprintf(stderr, "xhci: no device slots available\n"); 2177 event.ccode = CC_NO_SLOTS_ERROR; 2178 } else { 2179 slotid = i+1; 2180 event.ccode = xhci_enable_slot(xhci, slotid); 2181 } 2182 break; 2183 case CR_DISABLE_SLOT: 2184 slotid = xhci_get_slot(xhci, &event, &trb); 2185 if (slotid) { 2186 event.ccode = xhci_disable_slot(xhci, slotid); 2187 } 2188 break; 2189 case CR_ADDRESS_DEVICE: 2190 slotid = xhci_get_slot(xhci, &event, &trb); 2191 if (slotid) { 2192 event.ccode = xhci_address_slot(xhci, slotid, trb.parameter, 2193 trb.control & TRB_CR_BSR); 2194 } 2195 break; 2196 case CR_CONFIGURE_ENDPOINT: 2197 slotid = xhci_get_slot(xhci, &event, &trb); 2198 if (slotid) { 2199 event.ccode = xhci_configure_slot(xhci, slotid, trb.parameter, 2200 trb.control & TRB_CR_DC); 2201 } 2202 break; 2203 case CR_EVALUATE_CONTEXT: 2204 slotid = xhci_get_slot(xhci, &event, &trb); 2205 if (slotid) { 2206 event.ccode = xhci_evaluate_slot(xhci, slotid, trb.parameter); 2207 } 2208 break; 2209 case CR_STOP_ENDPOINT: 2210 slotid = xhci_get_slot(xhci, &event, &trb); 2211 if (slotid) { 2212 unsigned int epid = (trb.control >> TRB_CR_EPID_SHIFT) 2213 & TRB_CR_EPID_MASK; 2214 event.ccode = xhci_stop_ep(xhci, slotid, epid); 2215 } 2216 break; 2217 case CR_RESET_ENDPOINT: 2218 slotid = xhci_get_slot(xhci, &event, &trb); 2219 if (slotid) { 2220 unsigned int epid = (trb.control >> TRB_CR_EPID_SHIFT) 2221 & TRB_CR_EPID_MASK; 2222 event.ccode = xhci_reset_ep(xhci, slotid, epid); 2223 } 2224 break; 2225 case CR_SET_TR_DEQUEUE: 2226 slotid = xhci_get_slot(xhci, &event, &trb); 2227 if (slotid) { 2228 unsigned int epid = (trb.control >> TRB_CR_EPID_SHIFT) 2229 & TRB_CR_EPID_MASK; 2230 event.ccode = xhci_set_ep_dequeue(xhci, slotid, epid, 2231 trb.parameter); 2232 } 2233 break; 2234 case CR_RESET_DEVICE: 2235 slotid = xhci_get_slot(xhci, &event, &trb); 2236 if (slotid) { 2237 event.ccode = xhci_reset_slot(xhci, slotid); 2238 } 2239 break; 2240 case CR_GET_PORT_BANDWIDTH: 2241 event.ccode = xhci_get_port_bandwidth(xhci, trb.parameter); 2242 break; 2243 case CR_VENDOR_VIA_CHALLENGE_RESPONSE: 2244 xhci_via_challenge(xhci, trb.parameter); 2245 break; 2246 case CR_VENDOR_NEC_FIRMWARE_REVISION: 2247 event.type = 48; /* NEC reply */ 2248 event.length = 0x3025; 2249 break; 2250 case CR_VENDOR_NEC_CHALLENGE_RESPONSE: 2251 { 2252 uint32_t chi = trb.parameter >> 32; 2253 uint32_t clo = trb.parameter; 2254 uint32_t val = xhci_nec_challenge(chi, clo); 2255 event.length = val & 0xFFFF; 2256 event.epid = val >> 16; 2257 slotid = val >> 24; 2258 event.type = 48; /* NEC reply */ 2259 } 2260 break; 2261 default: 2262 fprintf(stderr, "xhci: unimplemented command %d\n", type); 2263 event.ccode = CC_TRB_ERROR; 2264 break; 2265 } 2266 event.slotid = slotid; 2267 xhci_event(xhci, &event); 2268 } 2269 } 2270 2271 static void xhci_update_port(XHCIState *xhci, XHCIPort *port, int is_detach) 2272 { 2273 int nr = port->port.index + 1; 2274 2275 port->portsc = PORTSC_PP; 2276 if (port->port.dev && port->port.dev->attached && !is_detach) { 2277 port->portsc |= PORTSC_CCS; 2278 switch (port->port.dev->speed) { 2279 case USB_SPEED_LOW: 2280 port->portsc |= PORTSC_SPEED_LOW; 2281 break; 2282 case USB_SPEED_FULL: 2283 port->portsc |= PORTSC_SPEED_FULL; 2284 break; 2285 case USB_SPEED_HIGH: 2286 port->portsc |= PORTSC_SPEED_HIGH; 2287 break; 2288 } 2289 } 2290 2291 if (xhci_running(xhci)) { 2292 port->portsc |= PORTSC_CSC; 2293 XHCIEvent ev = { ER_PORT_STATUS_CHANGE, CC_SUCCESS, nr << 24}; 2294 xhci_event(xhci, &ev); 2295 DPRINTF("xhci: port change event for port %d\n", nr); 2296 } 2297 } 2298 2299 static void xhci_reset(void *opaque) 2300 { 2301 XHCIState *xhci = opaque; 2302 int i; 2303 2304 DPRINTF("xhci: full reset\n"); 2305 if (!(xhci->usbsts & USBSTS_HCH)) { 2306 fprintf(stderr, "xhci: reset while running!\n"); 2307 } 2308 2309 xhci->usbcmd = 0; 2310 xhci->usbsts = USBSTS_HCH; 2311 xhci->dnctrl = 0; 2312 xhci->crcr_low = 0; 2313 xhci->crcr_high = 0; 2314 xhci->dcbaap_low = 0; 2315 xhci->dcbaap_high = 0; 2316 xhci->config = 0; 2317 xhci->devaddr = 2; 2318 2319 for (i = 0; i < MAXSLOTS; i++) { 2320 xhci_disable_slot(xhci, i+1); 2321 } 2322 2323 for (i = 0; i < MAXPORTS; i++) { 2324 xhci_update_port(xhci, xhci->ports + i, 0); 2325 } 2326 2327 xhci->mfindex = 0; 2328 xhci->iman = 0; 2329 xhci->imod = 0; 2330 xhci->erstsz = 0; 2331 xhci->erstba_low = 0; 2332 xhci->erstba_high = 0; 2333 xhci->erdp_low = 0; 2334 xhci->erdp_high = 0; 2335 2336 xhci->er_ep_idx = 0; 2337 xhci->er_pcs = 1; 2338 xhci->er_full = 0; 2339 xhci->ev_buffer_put = 0; 2340 xhci->ev_buffer_get = 0; 2341 } 2342 2343 static uint32_t xhci_cap_read(XHCIState *xhci, uint32_t reg) 2344 { 2345 DPRINTF("xhci_cap_read(0x%x)\n", reg); 2346 2347 switch (reg) { 2348 case 0x00: /* HCIVERSION, CAPLENGTH */ 2349 return 0x01000000 | LEN_CAP; 2350 case 0x04: /* HCSPARAMS 1 */ 2351 return (MAXPORTS<<24) | (MAXINTRS<<8) | MAXSLOTS; 2352 case 0x08: /* HCSPARAMS 2 */ 2353 return 0x0000000f; 2354 case 0x0c: /* HCSPARAMS 3 */ 2355 return 0x00000000; 2356 case 0x10: /* HCCPARAMS */ 2357 #if TARGET_PHYS_ADDR_BITS > 32 2358 return 0x00081001; 2359 #else 2360 return 0x00081000; 2361 #endif 2362 case 0x14: /* DBOFF */ 2363 return OFF_DOORBELL; 2364 case 0x18: /* RTSOFF */ 2365 return OFF_RUNTIME; 2366 2367 /* extended capabilities */ 2368 case 0x20: /* Supported Protocol:00 */ 2369 #if USB3_PORTS > 0 2370 return 0x02000402; /* USB 2.0 */ 2371 #else 2372 return 0x02000002; /* USB 2.0 */ 2373 #endif 2374 case 0x24: /* Supported Protocol:04 */ 2375 return 0x20425455; /* "USB " */ 2376 case 0x28: /* Supported Protocol:08 */ 2377 return 0x00000001 | (USB2_PORTS<<8); 2378 case 0x2c: /* Supported Protocol:0c */ 2379 return 0x00000000; /* reserved */ 2380 #if USB3_PORTS > 0 2381 case 0x30: /* Supported Protocol:00 */ 2382 return 0x03000002; /* USB 3.0 */ 2383 case 0x34: /* Supported Protocol:04 */ 2384 return 0x20425455; /* "USB " */ 2385 case 0x38: /* Supported Protocol:08 */ 2386 return 0x00000000 | (USB2_PORTS+1) | (USB3_PORTS<<8); 2387 case 0x3c: /* Supported Protocol:0c */ 2388 return 0x00000000; /* reserved */ 2389 #endif 2390 default: 2391 fprintf(stderr, "xhci_cap_read: reg %d unimplemented\n", reg); 2392 } 2393 return 0; 2394 } 2395 2396 static uint32_t xhci_port_read(XHCIState *xhci, uint32_t reg) 2397 { 2398 uint32_t port = reg >> 4; 2399 if (port >= MAXPORTS) { 2400 fprintf(stderr, "xhci_port_read: port %d out of bounds\n", port); 2401 return 0; 2402 } 2403 2404 switch (reg & 0xf) { 2405 case 0x00: /* PORTSC */ 2406 return xhci->ports[port].portsc; 2407 case 0x04: /* PORTPMSC */ 2408 case 0x08: /* PORTLI */ 2409 return 0; 2410 case 0x0c: /* reserved */ 2411 default: 2412 fprintf(stderr, "xhci_port_read (port %d): reg 0x%x unimplemented\n", 2413 port, reg); 2414 return 0; 2415 } 2416 } 2417 2418 static void xhci_port_write(XHCIState *xhci, uint32_t reg, uint32_t val) 2419 { 2420 uint32_t port = reg >> 4; 2421 uint32_t portsc; 2422 2423 if (port >= MAXPORTS) { 2424 fprintf(stderr, "xhci_port_read: port %d out of bounds\n", port); 2425 return; 2426 } 2427 2428 switch (reg & 0xf) { 2429 case 0x00: /* PORTSC */ 2430 portsc = xhci->ports[port].portsc; 2431 /* write-1-to-clear bits*/ 2432 portsc &= ~(val & (PORTSC_CSC|PORTSC_PEC|PORTSC_WRC|PORTSC_OCC| 2433 PORTSC_PRC|PORTSC_PLC|PORTSC_CEC)); 2434 if (val & PORTSC_LWS) { 2435 /* overwrite PLS only when LWS=1 */ 2436 portsc &= ~(PORTSC_PLS_MASK << PORTSC_PLS_SHIFT); 2437 portsc |= val & (PORTSC_PLS_MASK << PORTSC_PLS_SHIFT); 2438 } 2439 /* read/write bits */ 2440 portsc &= ~(PORTSC_PP|PORTSC_WCE|PORTSC_WDE|PORTSC_WOE); 2441 portsc |= (val & (PORTSC_PP|PORTSC_WCE|PORTSC_WDE|PORTSC_WOE)); 2442 /* write-1-to-start bits */ 2443 if (val & PORTSC_PR) { 2444 DPRINTF("xhci: port %d reset\n", port); 2445 usb_device_reset(xhci->ports[port].port.dev); 2446 portsc |= PORTSC_PRC | PORTSC_PED; 2447 } 2448 xhci->ports[port].portsc = portsc; 2449 break; 2450 case 0x04: /* PORTPMSC */ 2451 case 0x08: /* PORTLI */ 2452 default: 2453 fprintf(stderr, "xhci_port_write (port %d): reg 0x%x unimplemented\n", 2454 port, reg); 2455 } 2456 } 2457 2458 static uint32_t xhci_oper_read(XHCIState *xhci, uint32_t reg) 2459 { 2460 DPRINTF("xhci_oper_read(0x%x)\n", reg); 2461 2462 if (reg >= 0x400) { 2463 return xhci_port_read(xhci, reg - 0x400); 2464 } 2465 2466 switch (reg) { 2467 case 0x00: /* USBCMD */ 2468 return xhci->usbcmd; 2469 case 0x04: /* USBSTS */ 2470 return xhci->usbsts; 2471 case 0x08: /* PAGESIZE */ 2472 return 1; /* 4KiB */ 2473 case 0x14: /* DNCTRL */ 2474 return xhci->dnctrl; 2475 case 0x18: /* CRCR low */ 2476 return xhci->crcr_low & ~0xe; 2477 case 0x1c: /* CRCR high */ 2478 return xhci->crcr_high; 2479 case 0x30: /* DCBAAP low */ 2480 return xhci->dcbaap_low; 2481 case 0x34: /* DCBAAP high */ 2482 return xhci->dcbaap_high; 2483 case 0x38: /* CONFIG */ 2484 return xhci->config; 2485 default: 2486 fprintf(stderr, "xhci_oper_read: reg 0x%x unimplemented\n", reg); 2487 } 2488 return 0; 2489 } 2490 2491 static void xhci_oper_write(XHCIState *xhci, uint32_t reg, uint32_t val) 2492 { 2493 DPRINTF("xhci_oper_write(0x%x, 0x%08x)\n", reg, val); 2494 2495 if (reg >= 0x400) { 2496 xhci_port_write(xhci, reg - 0x400, val); 2497 return; 2498 } 2499 2500 switch (reg) { 2501 case 0x00: /* USBCMD */ 2502 if ((val & USBCMD_RS) && !(xhci->usbcmd & USBCMD_RS)) { 2503 xhci_run(xhci); 2504 } else if (!(val & USBCMD_RS) && (xhci->usbcmd & USBCMD_RS)) { 2505 xhci_stop(xhci); 2506 } 2507 xhci->usbcmd = val & 0xc0f; 2508 if (val & USBCMD_HCRST) { 2509 xhci_reset(xhci); 2510 } 2511 xhci_irq_update(xhci); 2512 break; 2513 2514 case 0x04: /* USBSTS */ 2515 /* these bits are write-1-to-clear */ 2516 xhci->usbsts &= ~(val & (USBSTS_HSE|USBSTS_EINT|USBSTS_PCD|USBSTS_SRE)); 2517 xhci_irq_update(xhci); 2518 break; 2519 2520 case 0x14: /* DNCTRL */ 2521 xhci->dnctrl = val & 0xffff; 2522 break; 2523 case 0x18: /* CRCR low */ 2524 xhci->crcr_low = (val & 0xffffffcf) | (xhci->crcr_low & CRCR_CRR); 2525 break; 2526 case 0x1c: /* CRCR high */ 2527 xhci->crcr_high = val; 2528 if (xhci->crcr_low & (CRCR_CA|CRCR_CS) && (xhci->crcr_low & CRCR_CRR)) { 2529 XHCIEvent event = {ER_COMMAND_COMPLETE, CC_COMMAND_RING_STOPPED}; 2530 xhci->crcr_low &= ~CRCR_CRR; 2531 xhci_event(xhci, &event); 2532 DPRINTF("xhci: command ring stopped (CRCR=%08x)\n", xhci->crcr_low); 2533 } else { 2534 dma_addr_t base = xhci_addr64(xhci->crcr_low & ~0x3f, val); 2535 xhci_ring_init(xhci, &xhci->cmd_ring, base); 2536 } 2537 xhci->crcr_low &= ~(CRCR_CA | CRCR_CS); 2538 break; 2539 case 0x30: /* DCBAAP low */ 2540 xhci->dcbaap_low = val & 0xffffffc0; 2541 break; 2542 case 0x34: /* DCBAAP high */ 2543 xhci->dcbaap_high = val; 2544 break; 2545 case 0x38: /* CONFIG */ 2546 xhci->config = val & 0xff; 2547 break; 2548 default: 2549 fprintf(stderr, "xhci_oper_write: reg 0x%x unimplemented\n", reg); 2550 } 2551 } 2552 2553 static uint32_t xhci_runtime_read(XHCIState *xhci, uint32_t reg) 2554 { 2555 DPRINTF("xhci_runtime_read(0x%x)\n", reg); 2556 2557 switch (reg) { 2558 case 0x00: /* MFINDEX */ 2559 fprintf(stderr, "xhci_runtime_read: MFINDEX not yet implemented\n"); 2560 return xhci->mfindex; 2561 case 0x20: /* IMAN */ 2562 return xhci->iman; 2563 case 0x24: /* IMOD */ 2564 return xhci->imod; 2565 case 0x28: /* ERSTSZ */ 2566 return xhci->erstsz; 2567 case 0x30: /* ERSTBA low */ 2568 return xhci->erstba_low; 2569 case 0x34: /* ERSTBA high */ 2570 return xhci->erstba_high; 2571 case 0x38: /* ERDP low */ 2572 return xhci->erdp_low; 2573 case 0x3c: /* ERDP high */ 2574 return xhci->erdp_high; 2575 default: 2576 fprintf(stderr, "xhci_runtime_read: reg 0x%x unimplemented\n", reg); 2577 } 2578 return 0; 2579 } 2580 2581 static void xhci_runtime_write(XHCIState *xhci, uint32_t reg, uint32_t val) 2582 { 2583 DPRINTF("xhci_runtime_write(0x%x, 0x%08x)\n", reg, val); 2584 2585 switch (reg) { 2586 case 0x20: /* IMAN */ 2587 if (val & IMAN_IP) { 2588 xhci->iman &= ~IMAN_IP; 2589 } 2590 xhci->iman &= ~IMAN_IE; 2591 xhci->iman |= val & IMAN_IE; 2592 xhci_irq_update(xhci); 2593 break; 2594 case 0x24: /* IMOD */ 2595 xhci->imod = val; 2596 break; 2597 case 0x28: /* ERSTSZ */ 2598 xhci->erstsz = val & 0xffff; 2599 break; 2600 case 0x30: /* ERSTBA low */ 2601 /* XXX NEC driver bug: it doesn't align this to 64 bytes 2602 xhci->erstba_low = val & 0xffffffc0; */ 2603 xhci->erstba_low = val & 0xfffffff0; 2604 break; 2605 case 0x34: /* ERSTBA high */ 2606 xhci->erstba_high = val; 2607 xhci_er_reset(xhci); 2608 break; 2609 case 0x38: /* ERDP low */ 2610 if (val & ERDP_EHB) { 2611 xhci->erdp_low &= ~ERDP_EHB; 2612 } 2613 xhci->erdp_low = (val & ~ERDP_EHB) | (xhci->erdp_low & ERDP_EHB); 2614 break; 2615 case 0x3c: /* ERDP high */ 2616 xhci->erdp_high = val; 2617 xhci_events_update(xhci); 2618 break; 2619 default: 2620 fprintf(stderr, "xhci_oper_write: reg 0x%x unimplemented\n", reg); 2621 } 2622 } 2623 2624 static uint32_t xhci_doorbell_read(XHCIState *xhci, uint32_t reg) 2625 { 2626 DPRINTF("xhci_doorbell_read(0x%x)\n", reg); 2627 /* doorbells always read as 0 */ 2628 return 0; 2629 } 2630 2631 static void xhci_doorbell_write(XHCIState *xhci, uint32_t reg, uint32_t val) 2632 { 2633 DPRINTF("xhci_doorbell_write(0x%x, 0x%08x)\n", reg, val); 2634 2635 if (!xhci_running(xhci)) { 2636 fprintf(stderr, "xhci: wrote doorbell while xHC stopped or paused\n"); 2637 return; 2638 } 2639 2640 reg >>= 2; 2641 2642 if (reg == 0) { 2643 if (val == 0) { 2644 xhci_process_commands(xhci); 2645 } else { 2646 fprintf(stderr, "xhci: bad doorbell 0 write: 0x%x\n", val); 2647 } 2648 } else { 2649 if (reg > MAXSLOTS) { 2650 fprintf(stderr, "xhci: bad doorbell %d\n", reg); 2651 } else if (val > 31) { 2652 fprintf(stderr, "xhci: bad doorbell %d write: 0x%x\n", reg, val); 2653 } else { 2654 xhci_kick_ep(xhci, reg, val); 2655 } 2656 } 2657 } 2658 2659 static uint64_t xhci_mem_read(void *ptr, target_phys_addr_t addr, 2660 unsigned size) 2661 { 2662 XHCIState *xhci = ptr; 2663 2664 /* Only aligned reads are allowed on xHCI */ 2665 if (addr & 3) { 2666 fprintf(stderr, "xhci_mem_read: Mis-aligned read\n"); 2667 return 0; 2668 } 2669 2670 if (addr < LEN_CAP) { 2671 return xhci_cap_read(xhci, addr); 2672 } else if (addr >= OFF_OPER && addr < (OFF_OPER + LEN_OPER)) { 2673 return xhci_oper_read(xhci, addr - OFF_OPER); 2674 } else if (addr >= OFF_RUNTIME && addr < (OFF_RUNTIME + LEN_RUNTIME)) { 2675 return xhci_runtime_read(xhci, addr - OFF_RUNTIME); 2676 } else if (addr >= OFF_DOORBELL && addr < (OFF_DOORBELL + LEN_DOORBELL)) { 2677 return xhci_doorbell_read(xhci, addr - OFF_DOORBELL); 2678 } else { 2679 fprintf(stderr, "xhci_mem_read: Bad offset %x\n", (int)addr); 2680 return 0; 2681 } 2682 } 2683 2684 static void xhci_mem_write(void *ptr, target_phys_addr_t addr, 2685 uint64_t val, unsigned size) 2686 { 2687 XHCIState *xhci = ptr; 2688 2689 /* Only aligned writes are allowed on xHCI */ 2690 if (addr & 3) { 2691 fprintf(stderr, "xhci_mem_write: Mis-aligned write\n"); 2692 return; 2693 } 2694 2695 if (addr >= OFF_OPER && addr < (OFF_OPER + LEN_OPER)) { 2696 xhci_oper_write(xhci, addr - OFF_OPER, val); 2697 } else if (addr >= OFF_RUNTIME && addr < (OFF_RUNTIME + LEN_RUNTIME)) { 2698 xhci_runtime_write(xhci, addr - OFF_RUNTIME, val); 2699 } else if (addr >= OFF_DOORBELL && addr < (OFF_DOORBELL + LEN_DOORBELL)) { 2700 xhci_doorbell_write(xhci, addr - OFF_DOORBELL, val); 2701 } else { 2702 fprintf(stderr, "xhci_mem_write: Bad offset %x\n", (int)addr); 2703 } 2704 } 2705 2706 static const MemoryRegionOps xhci_mem_ops = { 2707 .read = xhci_mem_read, 2708 .write = xhci_mem_write, 2709 .valid.min_access_size = 4, 2710 .valid.max_access_size = 4, 2711 .endianness = DEVICE_LITTLE_ENDIAN, 2712 }; 2713 2714 static void xhci_attach(USBPort *usbport) 2715 { 2716 XHCIState *xhci = usbport->opaque; 2717 XHCIPort *port = &xhci->ports[usbport->index]; 2718 2719 xhci_update_port(xhci, port, 0); 2720 } 2721 2722 static void xhci_detach(USBPort *usbport) 2723 { 2724 XHCIState *xhci = usbport->opaque; 2725 XHCIPort *port = &xhci->ports[usbport->index]; 2726 2727 xhci_update_port(xhci, port, 1); 2728 } 2729 2730 static void xhci_wakeup(USBPort *usbport) 2731 { 2732 XHCIState *xhci = usbport->opaque; 2733 XHCIPort *port = &xhci->ports[usbport->index]; 2734 int nr = port->port.index + 1; 2735 XHCIEvent ev = { ER_PORT_STATUS_CHANGE, CC_SUCCESS, nr << 24}; 2736 uint32_t pls; 2737 2738 pls = (port->portsc >> PORTSC_PLS_SHIFT) & PORTSC_PLS_MASK; 2739 if (pls != 3) { 2740 return; 2741 } 2742 port->portsc |= 0xf << PORTSC_PLS_SHIFT; 2743 if (port->portsc & PORTSC_PLC) { 2744 return; 2745 } 2746 port->portsc |= PORTSC_PLC; 2747 xhci_event(xhci, &ev); 2748 } 2749 2750 static void xhci_complete(USBPort *port, USBPacket *packet) 2751 { 2752 XHCITransfer *xfer = container_of(packet, XHCITransfer, packet); 2753 2754 xhci_complete_packet(xfer, packet->result); 2755 xhci_kick_ep(xfer->xhci, xfer->slotid, xfer->epid); 2756 } 2757 2758 static void xhci_child_detach(USBPort *port, USBDevice *child) 2759 { 2760 FIXME(); 2761 } 2762 2763 static USBPortOps xhci_port_ops = { 2764 .attach = xhci_attach, 2765 .detach = xhci_detach, 2766 .wakeup = xhci_wakeup, 2767 .complete = xhci_complete, 2768 .child_detach = xhci_child_detach, 2769 }; 2770 2771 static int xhci_find_slotid(XHCIState *xhci, USBDevice *dev) 2772 { 2773 XHCISlot *slot; 2774 int slotid; 2775 2776 for (slotid = 1; slotid <= MAXSLOTS; slotid++) { 2777 slot = &xhci->slots[slotid-1]; 2778 if (slot->devaddr == dev->addr) { 2779 return slotid; 2780 } 2781 } 2782 return 0; 2783 } 2784 2785 static int xhci_find_epid(USBEndpoint *ep) 2786 { 2787 if (ep->nr == 0) { 2788 return 1; 2789 } 2790 if (ep->pid == USB_TOKEN_IN) { 2791 return ep->nr * 2 + 1; 2792 } else { 2793 return ep->nr * 2; 2794 } 2795 } 2796 2797 static void xhci_wakeup_endpoint(USBBus *bus, USBEndpoint *ep) 2798 { 2799 XHCIState *xhci = container_of(bus, XHCIState, bus); 2800 int slotid; 2801 2802 DPRINTF("%s\n", __func__); 2803 slotid = xhci_find_slotid(xhci, ep->dev); 2804 if (slotid == 0 || !xhci->slots[slotid-1].enabled) { 2805 DPRINTF("%s: oops, no slot for dev %d\n", __func__, ep->dev->addr); 2806 return; 2807 } 2808 xhci_kick_ep(xhci, slotid, xhci_find_epid(ep)); 2809 } 2810 2811 static USBBusOps xhci_bus_ops = { 2812 .wakeup_endpoint = xhci_wakeup_endpoint, 2813 }; 2814 2815 static void usb_xhci_init(XHCIState *xhci, DeviceState *dev) 2816 { 2817 int i; 2818 2819 xhci->usbsts = USBSTS_HCH; 2820 2821 usb_bus_new(&xhci->bus, &xhci_bus_ops, &xhci->pci_dev.qdev); 2822 2823 for (i = 0; i < MAXPORTS; i++) { 2824 memset(&xhci->ports[i], 0, sizeof(xhci->ports[i])); 2825 usb_register_port(&xhci->bus, &xhci->ports[i].port, xhci, i, 2826 &xhci_port_ops, 2827 USB_SPEED_MASK_LOW | 2828 USB_SPEED_MASK_FULL | 2829 USB_SPEED_MASK_HIGH); 2830 } 2831 for (i = 0; i < MAXSLOTS; i++) { 2832 xhci->slots[i].enabled = 0; 2833 } 2834 2835 qemu_register_reset(xhci_reset, xhci); 2836 } 2837 2838 static int usb_xhci_initfn(struct PCIDevice *dev) 2839 { 2840 int ret; 2841 2842 XHCIState *xhci = DO_UPCAST(XHCIState, pci_dev, dev); 2843 2844 xhci->pci_dev.config[PCI_CLASS_PROG] = 0x30; /* xHCI */ 2845 xhci->pci_dev.config[PCI_INTERRUPT_PIN] = 0x01; /* interrupt pin 1 */ 2846 xhci->pci_dev.config[PCI_CACHE_LINE_SIZE] = 0x10; 2847 xhci->pci_dev.config[0x60] = 0x30; /* release number */ 2848 2849 usb_xhci_init(xhci, &dev->qdev); 2850 2851 xhci->irq = xhci->pci_dev.irq[0]; 2852 2853 memory_region_init_io(&xhci->mem, &xhci_mem_ops, xhci, 2854 "xhci", LEN_REGS); 2855 pci_register_bar(&xhci->pci_dev, 0, 2856 PCI_BASE_ADDRESS_SPACE_MEMORY|PCI_BASE_ADDRESS_MEM_TYPE_64, 2857 &xhci->mem); 2858 2859 ret = pcie_cap_init(&xhci->pci_dev, 0xa0, PCI_EXP_TYPE_ENDPOINT, 0); 2860 assert(ret >= 0); 2861 2862 if (xhci->msi) { 2863 ret = msi_init(&xhci->pci_dev, 0x70, 1, true, false); 2864 assert(ret >= 0); 2865 } 2866 2867 return 0; 2868 } 2869 2870 static void xhci_write_config(PCIDevice *dev, uint32_t addr, uint32_t val, 2871 int len) 2872 { 2873 XHCIState *xhci = DO_UPCAST(XHCIState, pci_dev, dev); 2874 2875 pci_default_write_config(dev, addr, val, len); 2876 if (xhci->msi) { 2877 msi_write_config(dev, addr, val, len); 2878 } 2879 } 2880 2881 static const VMStateDescription vmstate_xhci = { 2882 .name = "xhci", 2883 .unmigratable = 1, 2884 }; 2885 2886 static Property xhci_properties[] = { 2887 DEFINE_PROP_UINT32("msi", XHCIState, msi, 0), 2888 DEFINE_PROP_END_OF_LIST(), 2889 }; 2890 2891 static void xhci_class_init(ObjectClass *klass, void *data) 2892 { 2893 PCIDeviceClass *k = PCI_DEVICE_CLASS(klass); 2894 DeviceClass *dc = DEVICE_CLASS(klass); 2895 2896 dc->vmsd = &vmstate_xhci; 2897 dc->props = xhci_properties; 2898 k->init = usb_xhci_initfn; 2899 k->vendor_id = PCI_VENDOR_ID_NEC; 2900 k->device_id = PCI_DEVICE_ID_NEC_UPD720200; 2901 k->class_id = PCI_CLASS_SERIAL_USB; 2902 k->revision = 0x03; 2903 k->is_express = 1; 2904 k->config_write = xhci_write_config; 2905 } 2906 2907 static TypeInfo xhci_info = { 2908 .name = "nec-usb-xhci", 2909 .parent = TYPE_PCI_DEVICE, 2910 .instance_size = sizeof(XHCIState), 2911 .class_init = xhci_class_init, 2912 }; 2913 2914 static void xhci_register_types(void) 2915 { 2916 type_register_static(&xhci_info); 2917 } 2918 2919 type_init(xhci_register_types) 2920